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-rw-r--r--ffmpeg-rpi/APKBUILD114
-rw-r--r--ffmpeg-rpi/ffmpeg-99.1001-Call-get_format-to-fix-an-issue-with-MMAL-ren.patch55
-rw-r--r--ffmpeg-rpi/ffmpeg-99.1002-mpeg4video-Signal-unsupported-GMC-with-more-than-one.patch48
-rw-r--r--ffmpeg-rpi/ffmpeg-99.1003-pfcd_hevc_optimisations.patch44620
-rw-r--r--ffmpeg-rpi/ffmpeg-99.1004-added_upstream_mvc_patches.patch284
-rw-r--r--ffmpeg-rpi/ffmpeg-99.1008-dav1d-enable-av1.patch407
-rw-r--r--ffmpeg-rpi/ffmpeg-99.1009-dav1d-fix-multithreaded-av1-sw-decoding.patch60
-rw-r--r--ffmpeg-rpi/ffmpeg-99.1010-yuv2rgb-logspam.patch13
-rw-r--r--ffmpeg/0001-libavutil-clean-up-unused-FF_SYMVER-macro.patch55
-rw-r--r--ffmpeg/APKBUILD178
10 files changed, 45601 insertions, 233 deletions
diff --git a/ffmpeg-rpi/APKBUILD b/ffmpeg-rpi/APKBUILD
new file mode 100644
index 0000000..65bc4cc
--- /dev/null
+++ b/ffmpeg-rpi/APKBUILD
@@ -0,0 +1,114 @@
+# Contributor: Sergei Lukin <sergej.lukin@gmail.com>
+# Contributor: Łukasz Jendrysik <scadu@yandex.com>
+# Contributor: Jakub Skrzypnik <j.skrzypnik@openmailbox.org>
+# Maintainer: Natanael Copa <ncopa@alpinelinux.org>
+pkgname=ffmpeg-rpi
+pkgver="4.0.4-Leia-18.4"
+pkgrel=0
+pkgdesc="Complete and free Internet live audio and video broadcasting solution for Linux/Unix - Raspberry Pi"
+url="https://ffmpeg.org/"
+arch="aarch64"
+license="GPL-2.0-or-later AND LGPL-2.1-or-later"
+options="!check" # tests/data/hls-lists.append.m3u8 fails
+subpackages="$pkgname-dev $pkgname-doc $pkgname-libs"
+provides="ffmpeg"
+makedepends="
+ alsa-lib-dev
+ coreutils
+ bzip2-dev
+ gnutls-dev
+ imlib2-dev
+ lame-dev
+ libass-dev
+ libssh-dev
+ libtheora-dev
+ libvorbis-dev
+ libvpx-dev
+ libxfixes-dev
+ opus-dev
+ perl-dev
+ sdl2-dev
+ v4l-utils-dev
+ x264-dev
+ x265-dev
+ xvidcore-dev
+ yasm
+ zlib-dev
+ raspberrypi-dev
+ "
+checkdepends="rsync"
+source="https://github.com/xbmc/FFmpeg/archive/$pkgver.tar.gz
+ ffmpeg-99.1001-Call-get_format-to-fix-an-issue-with-MMAL-ren.patch
+ ffmpeg-99.1002-mpeg4video-Signal-unsupported-GMC-with-more-than-one.patch
+ ffmpeg-99.1003-pfcd_hevc_optimisations.patch
+ ffmpeg-99.1004-added_upstream_mvc_patches.patch
+ ffmpeg-99.1008-dav1d-enable-av1.patch
+ ffmpeg-99.1009-dav1d-fix-multithreaded-av1-sw-decoding.patch
+ ffmpeg-99.1010-yuv2rgb-logspam.patch
+"
+
+# add support for AV1 codec for all archies except armhf and armv7
+# as aom is not available on them
+_aom="";
+
+build() {
+ local _dbg="--disable-debug"
+ [ -n "$DEBUG" ] && _dbg="--enable-debug"
+
+ ./configure \
+ --prefix=/usr \
+ --enable-avresample \
+ --enable-avfilter \
+ --enable-gnutls \
+ --enable-gpl \
+ --enable-libass \
+ --enable-libmp3lame \
+ --enable-libvorbis \
+ --enable-libvpx \
+ --enable-libxvid \
+ --enable-libx264 \
+ --enable-libx265 \
+ --enable-libtheora \
+ --enable-libv4l2 \
+ --enable-postproc \
+ --enable-pic \
+ --enable-pthreads \
+ --enable-shared \
+ --enable-libxcb \
+ --enable-libssh \
+ --disable-stripping \
+ --disable-static \
+ --disable-librtmp \
+ --disable-vaapi \
+ --disable-vdpau \
+ --disable-libopus \
+ --enable-rpi \
+ --extra-cflags="-I/opt/vc/include/IL" \
+ --extra-ldflags="-L/opt/vc/lib" \
+ --extra-libs="-lbcm_host -lvcos -lvchiq_arm -lmmal -lmmal_core -lmmal_util -lvcsm" \
+ $_dbg
+ make
+ ${CC:-gcc} -o tools/qt-faststart $CFLAGS tools/qt-faststart.c
+ make doc/ffmpeg.1 doc/ffplay.1
+}
+
+package() {
+ make DESTDIR="$pkgdir" install install-man
+ install -D -m755 tools/qt-faststart "$pkgdir/usr/bin/qt-faststart"
+}
+
+libs() {
+ pkgdesc="Libraries for ffmpeg"
+ replaces="ffmpeg"
+ mkdir -p "$subpkgdir"/usr
+ mv "$pkgdir"/usr/lib "$subpkgdir"/usr
+}
+
+sha512sums="c6dd75dbff7119adeeda246cfb640b5e8d3b4c242ef83e5ba070207b60f0c715c3fe3cb328d87687b70a133f122a03aba990f0e95f3aac7d5dbcee25bec59078 4.0.4-Leia-18.4.tar.gz
+b0d3441b8dcb457254dcb965fbfedcb5bd2bc3bb9b6ae18aacba12d314e01d39a42bc25a4d927413e2783dd9e900a00801a9de254e9fbceb5e6e8b5532fdf31e ffmpeg-99.1001-Call-get_format-to-fix-an-issue-with-MMAL-ren.patch
+4ff179c139ec878a9022ebfba69a515bff4c6f8dcfbe1c9b65e7be818a4a4a087589cc33e9164030cff71dda81ce3751038b90f778feba4b7817c5f8341641dd ffmpeg-99.1002-mpeg4video-Signal-unsupported-GMC-with-more-than-one.patch
+9c946a401283b7d2b4e4a9691c25a52ca988fba75414f8453a38998747496377f0556994564388ad18453282b003c70bbd11433bf79d65cd12197a213028848e ffmpeg-99.1003-pfcd_hevc_optimisations.patch
+5a34fe204e7e488db6b6abca01518a946739c1a57e67e8e56c8fa3c78395f04447780773f7b7f5713a009945b34c6993ac5231073961ae514223c1f351919764 ffmpeg-99.1004-added_upstream_mvc_patches.patch
+eb7e71371f395a37c179876f500857132f8b4e5dc3bc8641cbfbd897302808fc31c4fec329fcb1974aba19a5f64fcbf23d6f6a21b9e6fdac5beb94e6aab31c8d ffmpeg-99.1008-dav1d-enable-av1.patch
+36c8814d90cff693dbe6a7c6eb50682a0edceef6dfa435e4ef24f42c7d478693bdae9294178ab3e91b7eb2365bed6ef3580d3eec229392d27c83c610eebb3362 ffmpeg-99.1009-dav1d-fix-multithreaded-av1-sw-decoding.patch
+19b4d4bbdaa0ed64f37eae87d9b68e593e645569df11692fbbb3d3d2d53f627d3820a28a643e36216ea5780f8c5c18ed24cc66ef6ef1b898716fe57750decfbd ffmpeg-99.1010-yuv2rgb-logspam.patch"
diff --git a/ffmpeg-rpi/ffmpeg-99.1001-Call-get_format-to-fix-an-issue-with-MMAL-ren.patch b/ffmpeg-rpi/ffmpeg-99.1001-Call-get_format-to-fix-an-issue-with-MMAL-ren.patch
new file mode 100644
index 0000000..37b53e8
--- /dev/null
+++ b/ffmpeg-rpi/ffmpeg-99.1001-Call-get_format-to-fix-an-issue-with-MMAL-ren.patch
@@ -0,0 +1,55 @@
+From 7adc8f706efab65d8d7e5f960690faca3d5c190d Mon Sep 17 00:00:00 2001
+From: popcornmix <popcornmix@gmail.com>
+Date: Sat, 4 Mar 2017 19:24:02 +0000
+Subject: [PATCH] ffmpeg: Call get_format to fix an issue with MMAL rendering
+
+---
+ libavcodec/dvdec.c | 7 +++++++
+ libavcodec/rv34.c | 6 +++++-
+ 2 files changed, 12 insertions(+), 1 deletion(-)
+
+diff --git a/libavcodec/dvdec.c b/libavcodec/dvdec.c
+index 0b4c1bc..00081ef 100644
+--- a/libavcodec/dvdec.c
++++ b/libavcodec/dvdec.c
+@@ -49,6 +49,7 @@
+ #include "internal.h"
+ #include "put_bits.h"
+ #include "simple_idct.h"
++#include "thread.h"
+
+ typedef struct BlockInfo {
+ const uint32_t *factor_table;
+@@ -196,6 +197,12 @@ static av_cold int dvvideo_decode_init(AVCodecContext *avctx)
+ s->idct_put[0] = idsp.idct_put;
+ s->idct_put[1] = ff_simple_idct248_put;
+
++ static const enum AVPixelFormat pix_fmts[] = {
++ AV_PIX_FMT_YUV420P,
++ AV_PIX_FMT_NONE
++ };
++ avctx->pix_fmt = ff_get_format(avctx, pix_fmts);
++
+ return ff_dvvideo_init(avctx);
+ }
+
+diff --git a/libavcodec/rv34.c b/libavcodec/rv34.c
+index aca8382..f473f6c 100644
+--- a/libavcodec/rv34.c
++++ b/libavcodec/rv34.c
+@@ -1493,7 +1493,11 @@ av_cold int ff_rv34_decode_init(AVCodecContext *avctx)
+ ff_mpv_decode_init(s, avctx);
+ s->out_format = FMT_H263;
+
+- avctx->pix_fmt = AV_PIX_FMT_YUV420P;
++ static const enum AVPixelFormat pix_fmts[] = {
++ AV_PIX_FMT_YUV420P,
++ AV_PIX_FMT_NONE
++ };
++ avctx->pix_fmt = ff_get_format(avctx, pix_fmts);
+ avctx->has_b_frames = 1;
+ s->low_delay = 0;
+
+--
+2.7.4
+
diff --git a/ffmpeg-rpi/ffmpeg-99.1002-mpeg4video-Signal-unsupported-GMC-with-more-than-one.patch b/ffmpeg-rpi/ffmpeg-99.1002-mpeg4video-Signal-unsupported-GMC-with-more-than-one.patch
new file mode 100644
index 0000000..6721c8d
--- /dev/null
+++ b/ffmpeg-rpi/ffmpeg-99.1002-mpeg4video-Signal-unsupported-GMC-with-more-than-one.patch
@@ -0,0 +1,48 @@
+From d8bdcc8791c501921ee8961f3b0de0bd47668ebf Mon Sep 17 00:00:00 2001
+From: popcornmix <popcornmix@gmail.com>
+Date: Fri, 5 Jun 2015 22:48:33 +0100
+Subject: [PATCH] mpeg4video: Signal unsupported GMC with more than one warp
+ point
+
+---
+ libavcodec/avcodec.h | 1 +
+ libavcodec/mpeg4videodec.c | 4 ++++
+ 2 files changed, 5 insertions(+)
+
+diff --git a/libavcodec/avcodec.h b/libavcodec/avcodec.h
+index c26b6d607c..6c4b011b5c 100644
+--- a/libavcodec/avcodec.h
++++ b/libavcodec/avcodec.h
+@@ -2965,6 +2965,7 @@ typedef struct AVCodecContext {
+ #define FF_BUG_MS 8192 ///< Work around various bugs in Microsoft's broken decoders.
+ #define FF_BUG_TRUNCATED 16384
+ #define FF_BUG_IEDGE 32768
++#define FF_BUG_GMC_UNSUPPORTED (1<<30)
+
+ /**
+ * strictly follow the standard (MPEG-4, ...).
+diff --git a/libavcodec/mpeg4videodec.c b/libavcodec/mpeg4videodec.c
+index cd39131d55..d8c8227cb4 100644
+--- a/libavcodec/mpeg4videodec.c
++++ b/libavcodec/mpeg4videodec.c
+@@ -2250,6 +2250,9 @@ int ff_mpeg4_workaround_bugs(AVCodecContext *avctx)
+
+ if (ctx->divx_version >= 0)
+ s->workaround_bugs |= FF_BUG_HPEL_CHROMA;
++
++ if (ctx->num_sprite_warping_points > 1)
++ s->workaround_bugs |= FF_BUG_GMC_UNSUPPORTED;
+ }
+
+ if (s->workaround_bugs & FF_BUG_STD_QPEL) {
+@@ -2274,6 +2277,7 @@ int ff_mpeg4_workaround_bugs(AVCodecContext *avctx)
+ s->workaround_bugs, ctx->lavc_build, ctx->xvid_build,
+ ctx->divx_version, ctx->divx_build, s->divx_packed ? "p" : "");
+
++ avctx->workaround_bugs = s->workaround_bugs;
+ if (CONFIG_MPEG4_DECODER && ctx->xvid_build >= 0 &&
+ s->codec_id == AV_CODEC_ID_MPEG4 &&
+ avctx->idct_algo == FF_IDCT_AUTO) {
+--
+2.14.1
+
diff --git a/ffmpeg-rpi/ffmpeg-99.1003-pfcd_hevc_optimisations.patch b/ffmpeg-rpi/ffmpeg-99.1003-pfcd_hevc_optimisations.patch
new file mode 100644
index 0000000..c64d5e5
--- /dev/null
+++ b/ffmpeg-rpi/ffmpeg-99.1003-pfcd_hevc_optimisations.patch
@@ -0,0 +1,44620 @@
+diff --git a/.gitignore b/.gitignore
+index 0e57cb0b4c..b2e3374fea 100644
+--- a/.gitignore
++++ b/.gitignore
+@@ -1,6 +1,7 @@
+ *.a
+ *.o
+ *.o.*
++*.bin
+ *.d
+ *.def
+ *.dll
+@@ -26,6 +27,7 @@
+ .\#*
+ /.config
+ /.version
++/build/
+ /ffmpeg
+ /ffplay
+ /ffprobe
+diff --git a/configure b/configure
+index 827abfe694..28f630068e 100755
+--- a/configure
++++ b/configure
+@@ -318,6 +318,7 @@ External library support:
+ --enable-libmfx enable Intel MediaSDK (AKA Quick Sync Video) code via libmfx [no]
+ --enable-libnpp enable Nvidia Performance Primitives-based code [no]
+ --enable-mmal enable Broadcom Multi-Media Abstraction Layer (Raspberry Pi) via MMAL [no]
++ --enable-rpi enable other rpi specific stuff [no]
+ --disable-nvdec disable Nvidia video decoding acceleration (via hwaccel) [autodetect]
+ --disable-nvenc disable Nvidia video encoding code [autodetect]
+ --enable-omx enable OpenMAX IL code [no]
+@@ -1776,6 +1777,7 @@ FEATURE_LIST="
+ gray
+ hardcoded_tables
+ omx_rpi
++ rpi
+ runtime_cpudetect
+ safe_bitstream_reader
+ shared
+@@ -2293,6 +2295,7 @@ CONFIG_EXTRA="
+ rtpdec
+ rtpenc_chain
+ rv34dsp
++ sand
+ sinewin
+ snappy
+ srtp
+@@ -2610,6 +2613,8 @@ hap_decoder_select="snappy texturedsp"
+ hap_encoder_deps="libsnappy"
+ hap_encoder_select="texturedspenc"
+ hevc_decoder_select="bswapdsp cabac golomb hevcparse videodsp"
++hevc_rpi_decoder_deps="rpi"
++hevc_rpi_decoder_select="hevc_decoder sand"
+ huffyuv_decoder_select="bswapdsp huffyuvdsp llviddsp"
+ huffyuv_encoder_select="bswapdsp huffman huffyuvencdsp llvidencdsp"
+ iac_decoder_select="imc_decoder"
+@@ -3393,6 +3398,8 @@ tinterlace_filter_deps="gpl"
+ tinterlace_merge_test_deps="tinterlace_filter"
+ tinterlace_pad_test_deps="tinterlace_filter"
+ tonemap_filter_deps="const_nan"
++unsand_filter_deps="rpi"
++unsand_filter_select="sand"
+ unsharp_opencl_filter_deps="opencl"
+ uspp_filter_deps="gpl avcodec"
+ vaguedenoiser_filter_deps="gpl"
+diff --git a/fftools/ffmpeg.c b/fftools/ffmpeg.c
+index c0214c42d8..faaea5772a 100644
+--- a/fftools/ffmpeg.c
++++ b/fftools/ffmpeg.c
+@@ -24,6 +24,12 @@
+ */
+
+ #include "config.h"
++
++#if CONFIG_RPI
++#define RPI_DISPLAY
++#define RPI_DISPLAY_ALL 0
++#endif
++
+ #include <ctype.h>
+ #include <string.h>
+ #include <math.h>
+@@ -70,6 +76,25 @@
+ # include "libavfilter/buffersrc.h"
+ # include "libavfilter/buffersink.h"
+
++#ifdef RPI_DISPLAY
++#pragma GCC diagnostic push
++// Many many redundant decls in the header files
++#pragma GCC diagnostic ignored "-Wredundant-decls"
++#include <bcm_host.h>
++#include <interface/mmal/mmal.h>
++#include <interface/mmal/mmal_parameters_camera.h>
++#include <interface/mmal/mmal_buffer.h>
++#include <interface/mmal/mmal_port.h>
++#include <interface/mmal/util/mmal_util.h>
++#include <interface/mmal/util/mmal_default_components.h>
++#include <interface/mmal/util/mmal_connection.h>
++#include <interface/mmal/util/mmal_util_params.h>
++#pragma GCC diagnostic pop
++#include "libavcodec/rpi_qpu.h"
++#include "libavutil/rpi_sand_fns.h"
++#include "libavcodec/rpi_zc.h"
++#endif
++
+ #if HAVE_SYS_RESOURCE_H
+ #include <sys/time.h>
+ #include <sys/types.h>
+@@ -162,6 +187,241 @@ static int restore_tty;
+ static void free_input_threads(void);
+ #endif
+
++#ifdef RPI_DISPLAY
++
++#define NUM_BUFFERS 4
++
++
++typedef struct rpi_display_env_s
++{
++ MMAL_COMPONENT_T* display;
++ MMAL_COMPONENT_T* isp;
++ MMAL_PORT_T * port_in; // Input port of either isp or display depending on pipe setup
++ MMAL_CONNECTION_T * conn;
++
++ MMAL_POOL_T *rpi_pool;
++ volatile int rpi_display_count;
++ enum AVPixelFormat avfmt;
++} rpi_display_env_t;
++
++static rpi_display_env_t * rpi_display_env = NULL;
++
++
++static MMAL_POOL_T* display_alloc_pool(MMAL_PORT_T* port)
++{
++ MMAL_POOL_T* pool;
++ mmal_port_parameter_set_boolean(port, MMAL_PARAMETER_ZERO_COPY, MMAL_TRUE); // Does this mark that the buffer contains a vc_handle? Would have expected a vc_image?
++ pool = mmal_port_pool_create(port, NUM_BUFFERS, 0);
++ assert(pool);
++
++ return pool;
++}
++
++static void display_cb_input(MMAL_PORT_T *port, MMAL_BUFFER_HEADER_T *buffer) {
++ rpi_display_env_t *const de = (rpi_display_env_t *)port->userdata;
++ av_rpi_zc_unref(buffer->user_data);
++ atomic_fetch_add(&de->rpi_display_count, -1);
++ mmal_buffer_header_release(buffer);
++}
++
++static void display_cb_control(MMAL_PORT_T *port,MMAL_BUFFER_HEADER_T *buffer) {
++ mmal_buffer_header_release(buffer);
++}
++
++#define DISPLAY_PORT_DEPTH 4
++
++static rpi_display_env_t *
++display_init(const enum AVPixelFormat req_fmt, size_t x, size_t y, size_t w, size_t h)
++{
++ MMAL_STATUS_T err;
++ MMAL_DISPLAYREGION_T region =
++ {
++ .hdr = {MMAL_PARAMETER_DISPLAYREGION, sizeof(region)},
++ .set = MMAL_DISPLAY_SET_LAYER | MMAL_DISPLAY_SET_FULLSCREEN | MMAL_DISPLAY_SET_DEST_RECT,
++ .layer = 2,
++ .fullscreen = 0,
++ .dest_rect = {x, y, w, h}
++ };
++#if RPI_ZC_SAND_8_IN_10_BUF
++ const enum AVPixelFormat fmt = (req_fmt == AV_PIX_FMT_YUV420P10 || av_rpi_is_sand_format(req_fmt)) ? AV_PIX_FMT_SAND128 : req_fmt;
++#else
++ const enum AVPixelFormat fmt = (req_fmt == AV_PIX_FMT_YUV420P10) ? AV_PIX_FMT_SAND128 : req_fmt;
++#endif
++ const AVRpiZcFrameGeometry geo = av_rpi_zc_frame_geometry(fmt, w, h);
++ rpi_display_env_t * de;
++ int isp_req = (fmt == AV_PIX_FMT_SAND64_10);
++
++ bcm_host_init(); // Needs to be done by someone...
++
++ if ((de = av_mallocz(sizeof(*de))) == NULL) {
++ return NULL;
++ }
++
++ mmal_component_create(MMAL_COMPONENT_DEFAULT_VIDEO_RENDERER, &de->display);
++ av_assert0(de->display);
++ de->port_in = de->display->input[0];
++
++ if (isp_req)
++ {
++ mmal_component_create("vc.ril.isp", &de->isp);
++ de->port_in = de->isp->input[0];
++ }
++
++ mmal_port_parameter_set(de->display->input[0], &region.hdr);
++
++ {
++ MMAL_PORT_T * const port = de->port_in;
++ MMAL_ES_FORMAT_T* const format = port->format;
++ port->userdata = (struct MMAL_PORT_USERDATA_T *)de;
++ port->buffer_num = DISPLAY_PORT_DEPTH;
++ format->encoding = fmt == AV_PIX_FMT_SAND128 ? MMAL_ENCODING_YUVUV128 :
++ fmt == AV_PIX_FMT_SAND64_10 ? MMAL_ENCODING_YUVUV64_16 :
++ MMAL_ENCODING_I420;
++ format->es->video.width = geo.stride_y;
++ format->es->video.height = (fmt == AV_PIX_FMT_SAND128 || fmt == AV_PIX_FMT_SAND64_10) ?
++ (h + 15) & ~15 : geo.height_y; // Magic
++ format->es->video.crop.x = 0;
++ format->es->video.crop.y = 0;
++ format->es->video.crop.width = w;
++ format->es->video.crop.height = h;
++ mmal_port_format_commit(port);
++ }
++
++ de->rpi_pool = display_alloc_pool(de->port_in);
++ mmal_port_enable(de->port_in,display_cb_input);
++
++ if (isp_req) {
++ MMAL_PORT_T * const port_out = de->isp->output[0];
++ mmal_log_dump_port(de->port_in);
++ mmal_format_copy(port_out->format, de->port_in->format);
++ if (fmt == AV_PIX_FMT_SAND64_10) {
++ if ((err = mmal_port_parameter_set_int32(de->port_in, MMAL_PARAMETER_CCM_SHIFT, 5)) != MMAL_SUCCESS ||
++ (err = mmal_port_parameter_set_int32(port_out, MMAL_PARAMETER_OUTPUT_SHIFT, 1)) != MMAL_SUCCESS)
++ {
++ av_log(NULL, AV_LOG_WARNING, "Failed to set ISP output port shift\n");
++ }
++ else
++ av_log(NULL, AV_LOG_WARNING, "Set ISP output port shift OK\n");
++
++ }
++ port_out->format->encoding = MMAL_ENCODING_I420;
++ mmal_log_dump_port(port_out);
++ if ((err = mmal_port_format_commit(port_out)) != MMAL_SUCCESS)
++ {
++ av_log(NULL, AV_LOG_ERROR, "Failed to set ISP output port format\n");
++ goto fail;
++ }
++ if ((err = mmal_connection_create(&de->conn, port_out, de->display->input[0], MMAL_CONNECTION_FLAG_TUNNELLING)) != MMAL_SUCCESS) {
++ av_log(NULL, AV_LOG_ERROR, "Failed to create connection\n");
++ goto fail;
++ }
++ if ((err = mmal_connection_enable(de->conn)) != MMAL_SUCCESS) {
++ av_log(NULL, AV_LOG_ERROR, "Failed to enable connection\n");
++ goto fail;
++ }
++ mmal_port_enable(de->isp->control,display_cb_control);
++ mmal_component_enable(de->isp);
++ }
++
++ mmal_component_enable(de->display);
++ mmal_port_enable(de->display->control,display_cb_control);
++ de->avfmt = fmt;
++
++ printf("Allocated display %dx%d in %dx%d, fmt=%d\n", w, h, geo.stride_y, geo.height_y, fmt);
++
++ return de;
++
++fail:
++ // **** Free stuff
++ return NULL;
++}
++
++static void display_frame(struct AVCodecContext * const s, rpi_display_env_t * const de, const AVFrame* const fr)
++{
++ MMAL_BUFFER_HEADER_T* buf;
++
++ if (de == NULL)
++ return;
++
++ if (atomic_load(&de->rpi_display_count) >= DISPLAY_PORT_DEPTH - 1) {
++ av_log(s, AV_LOG_VERBOSE, "Frame dropped\n");
++ return;
++ }
++
++ buf = mmal_queue_get(de->rpi_pool->queue);
++ if (!buf) {
++ // Running too fast so drop the frame
++ printf("Q alloc failure\n");
++ return;
++ }
++ assert(buf);
++ buf->cmd = 0;
++ buf->offset = 0; // Offset to valid data
++ buf->flags = 0;
++ {
++ const AVRpiZcRefPtr fr_buf = av_rpi_zc_ref(s, fr, de->avfmt, 1);
++ if (fr_buf == NULL) {
++ mmal_buffer_header_release(buf);
++ return;
++ }
++
++ buf->user_data = fr_buf;
++ buf->data = (uint8_t *)av_rpi_zc_vc_handle(fr_buf); // Cast our handle to a pointer for mmal
++ buf->offset = av_rpi_zc_offset(fr_buf);
++ buf->length = av_rpi_zc_length(fr_buf);
++ buf->alloc_size = av_rpi_zc_numbytes(fr_buf);
++ atomic_fetch_add(&de->rpi_display_count, 1);
++ }
++#if RPI_DISPLAY_ALL
++ while (atomic_load(&de->rpi_display_count) >= DISPLAY_PORT_DEPTH - 1) {
++ usleep(5000);
++ }
++#endif
++
++ if (mmal_port_send_buffer(de->port_in, buf) != MMAL_SUCCESS)
++ {
++ av_log(s, AV_LOG_ERROR, "mmal_port_send_buffer failed: depth=%d\n", de->rpi_display_count);
++ display_cb_input(de->port_in, buf);
++ }
++}
++
++static void display_exit(rpi_display_env_t ** const pde)
++{
++ rpi_display_env_t * const de = *pde;
++ *pde = NULL;
++
++ if (de != NULL) {
++// sleep(120);
++
++ if (de->port_in != NULL) {
++ mmal_port_disable(de->port_in);
++ }
++
++ // The above disable should kick out all buffers - check that
++ if (atomic_load(&de->rpi_display_count) != 0) {
++ av_log(NULL, AV_LOG_WARNING, "Exiting with display count non-zero:%d\n", atomic_load(&de->rpi_display_count));
++ }
++
++ if (de->conn != NULL) {
++ mmal_connection_destroy(de->conn);
++ }
++ if (de->rpi_pool != NULL) {
++ mmal_port_pool_destroy(de->display->input[0], de->rpi_pool);
++ }
++ if (de->isp != NULL) {
++ mmal_component_destroy(de->isp);
++ }
++ if (de->display != NULL) {
++ mmal_component_destroy(de->display);
++ }
++
++ av_free(de);
++ }
++}
++
++#endif
++
++
+ /* sub2video hack:
+ Convert subtitles to video with alpha to insert them in filter graphs.
+ This is a temporary solution until libavfilter gets real subtitles support.
+@@ -583,6 +843,11 @@ static void ffmpeg_cleanup(int ret)
+ avformat_close_input(&input_files[i]->ctx);
+ av_freep(&input_files[i]);
+ }
++
++#ifdef RPI_DISPLAY
++ display_exit(&rpi_display_env);
++#endif
++
+ for (i = 0; i < nb_input_streams; i++) {
+ InputStream *ist = input_streams[i];
+
+@@ -594,7 +859,9 @@ static void ffmpeg_cleanup(int ret)
+ av_freep(&ist->filters);
+ av_freep(&ist->hwaccel_device);
+ av_freep(&ist->dts_buffer);
+-
++#ifdef RPI_DISPLAY
++ av_rpi_zc_uninit(ist->dec_ctx);
++#endif
+ avcodec_free_context(&ist->dec_ctx);
+
+ av_freep(&input_streams[i]);
+@@ -625,6 +892,7 @@ static void ffmpeg_cleanup(int ret)
+ }
+ term_exit();
+ ffmpeg_exited = 1;
++
+ }
+
+ void remove_avoptions(AVDictionary **a, AVDictionary *b)
+@@ -1060,6 +1328,17 @@ static void do_video_out(OutputFile *of,
+ if (ost->source_index >= 0)
+ ist = input_streams[ost->source_index];
+
++#ifdef RPI_DISPLAY
++ if (next_picture && ist != NULL)
++ {
++ if (rpi_display_env == NULL)
++ rpi_display_env = display_init(next_picture->format, 0, 0,
++ next_picture->width - next_picture->crop_right,
++ next_picture->height - next_picture->crop_bottom);
++ display_frame(ist->dec_ctx, rpi_display_env, next_picture);
++ }
++#endif
++
+ frame_rate = av_buffersink_get_frame_rate(filter);
+ if (frame_rate.num > 0 && frame_rate.den > 0)
+ duration = 1/(av_q2d(frame_rate) * av_q2d(enc->time_base));
+@@ -2132,8 +2411,8 @@ static int ifilter_send_frame(InputFilter *ifilter, AVFrame *frame)
+ ifilter->channel_layout != frame->channel_layout;
+ break;
+ case AVMEDIA_TYPE_VIDEO:
+- need_reinit |= ifilter->width != frame->width ||
+- ifilter->height != frame->height;
++ need_reinit |= ifilter->width != av_frame_cropped_width(frame) ||
++ ifilter->height != av_frame_cropped_height(frame);
+ break;
+ }
+
+@@ -2891,6 +3170,12 @@ static int init_input_stream(int ist_index, char *error, int error_len)
+ ist->dec_ctx->opaque = ist;
+ ist->dec_ctx->get_format = get_format;
+ ist->dec_ctx->get_buffer2 = get_buffer;
++
++#ifdef RPI_DISPLAY
++ // Overrides the above get_buffer2
++ av_rpi_zc_init(ist->dec_ctx);
++#endif
++
+ ist->dec_ctx->thread_safe_callbacks = 1;
+
+ av_opt_set_int(ist->dec_ctx, "refcounted_frames", 1, 0);
+diff --git a/fftools/ffmpeg_filter.c b/fftools/ffmpeg_filter.c
+index 877fd670e6..1efd3a43a8 100644
+--- a/fftools/ffmpeg_filter.c
++++ b/fftools/ffmpeg_filter.c
+@@ -1179,8 +1179,8 @@ int ifilter_parameters_from_frame(InputFilter *ifilter, const AVFrame *frame)
+
+ ifilter->format = frame->format;
+
+- ifilter->width = frame->width;
+- ifilter->height = frame->height;
++ ifilter->width = av_frame_cropped_width(frame);
++ ifilter->height = av_frame_cropped_height(frame);
+ ifilter->sample_aspect_ratio = frame->sample_aspect_ratio;
+
+ ifilter->sample_rate = frame->sample_rate;
+diff --git a/fftools/ffmpeg_opt.c b/fftools/ffmpeg_opt.c
+index d7a7eb0662..3949c9e76b 100644
+--- a/fftools/ffmpeg_opt.c
++++ b/fftools/ffmpeg_opt.c
+@@ -684,11 +684,19 @@ static AVCodec *choose_decoder(OptionsContext *o, AVFormatContext *s, AVStream *
+
+ MATCH_PER_STREAM_OPT(codec_names, str, codec_name, s, st);
+ if (codec_name) {
++ if (strcmp("hevc_rpi", codec_name) == 0) {
++ return avcodec_find_decoder_by_id_and_fmt(AV_CODEC_ID_HEVC, st->codecpar->format);
++ }
+ AVCodec *codec = find_codec_or_die(codec_name, st->codecpar->codec_type, 0);
+ st->codecpar->codec_id = codec->id;
+ return codec;
+ } else
++ {
++ if (st->codecpar->codec_id == AV_CODEC_ID_HEVC) {
++ return avcodec_find_decoder_by_id_and_fmt(st->codecpar->codec_id, st->codecpar->format);
++ }
+ return avcodec_find_decoder(st->codecpar->codec_id);
++ }
+ }
+
+ /* Add all the streams from the given input file to the global
+diff --git a/libavcodec/Makefile b/libavcodec/Makefile
+index 4b8ad121db..f6e6784e5a 100644
+--- a/libavcodec/Makefile
++++ b/libavcodec/Makefile
+@@ -6,6 +6,7 @@ HEADERS = ac3_parser.h \
+ avcodec.h \
+ avdct.h \
+ avfft.h \
++ rpi_zc.h \
+ d3d11va.h \
+ dirac.h \
+ dv_profile.h \
+@@ -128,6 +129,7 @@ OBJS-$(CONFIG_QSVDEC) += qsvdec.o
+ OBJS-$(CONFIG_QSVENC) += qsvenc.o
+ OBJS-$(CONFIG_RANGECODER) += rangecoder.o
+ OBJS-$(CONFIG_RDFT) += rdft.o
++OBJS-$(CONFIG_RPI) += rpi_qpu.o rpi_mailbox.o rpi_zc.o
+ OBJS-$(CONFIG_RV34DSP) += rv34dsp.o
+ OBJS-$(CONFIG_SHARED) += log2_tab.o reverse.o
+ OBJS-$(CONFIG_SINEWIN) += sinewin.o sinewin_fixed.o
+@@ -360,6 +362,13 @@ OBJS-$(CONFIG_HAP_ENCODER) += hapenc.o hap.o
+ OBJS-$(CONFIG_HEVC_DECODER) += hevcdec.o hevc_mvs.o \
+ hevc_cabac.o hevc_refs.o hevcpred.o \
+ hevcdsp.o hevc_filter.o hevc_data.o
++OBJS-$(CONFIG_HEVC_RPI_DECODER) += rpi_hevcdec.o rpi_hevc_mvs.o \
++ rpi_hevc_cabac.o rpi_hevc_refs.o rpi_hevcpred.o \
++ rpi_hevcdsp.o rpi_hevc_filter.o rpi_hevc_data.o \
++ rpi_hevc_shader.o rpi_hevc_shader_template.o \
++ rpi_hevc_parse.o h2645_parse.o rpi_hevc_ps.o \
++ rpi_hevc_sei.o rpi_hevc_data.o
++OBJS-$(CONFIG_HEVC_CUVID_DECODER) += cuvid.o
+ OBJS-$(CONFIG_HEVC_AMF_ENCODER) += amfenc_hevc.o
+ OBJS-$(CONFIG_HEVC_CUVID_DECODER) += cuviddec.o
+ OBJS-$(CONFIG_HEVC_MEDIACODEC_DECODER) += mediacodecdec.o
+@@ -1188,3 +1197,31 @@ $(SUBDIR)qdm2.o: $(SUBDIR)qdm2_tables.h
+ $(SUBDIR)sinewin.o: $(SUBDIR)sinewin_tables.h
+ $(SUBDIR)sinewin_fixed.o: $(SUBDIR)sinewin_fixed_tables.h
+ endif
++
++ifdef CONFIG_HEVC_RPI_DECODER
++QASM_PY := ../local/bin/qasm.py
++VASMVIDCORE := ../local/bin/vasmvidcore_std
++
++ifneq ("$(wildcard $(QASM_PY))","")
++$(SUBDIR)rpi_hevc_shader.c: $(SUBDIR)rpi_hevc_shader.qasm
++ $(QASM_PY) -mc_c:rpi_hevc_shader,rpi_hevc_shader,ff_hevc_rpi_shader $< > $@
++
++$(SUBDIR)rpi_hevc_shader.h: $(SUBDIR)rpi_hevc_shader.qasm
++ $(QASM_PY) -mc_h:rpi_hevc_shader,rpi_hevc_shader,ff_hevc_rpi_shader $< > $@
++endif
++
++ifneq ("$(wildcard $(VASMVIDCORE))","")
++$(SUBDIR)rpi_hevc_transform8.bin: $(SUBDIR)rpi_hevc_transform.s
++ $(VASMVIDCORE) -Fbin -DBIT_DEPTH=8 $< -o $@
++$(SUBDIR)rpi_hevc_transform10.bin: $(SUBDIR)rpi_hevc_transform.s
++ $(VASMVIDCORE) -Fbin -DBIT_DEPTH=10 $< -o $@
++
++$(SUBDIR)rpi_hevc_transform8.h: $(SUBDIR)rpi_hevc_transform8.bin
++ python pi-util/make_array.py $<
++$(SUBDIR)rpi_hevc_transform10.h: $(SUBDIR)rpi_hevc_transform10.bin
++ python pi-util/make_array.py $<
++endif
++
++$(SUBDIR)rpi_qpu.o: $(SUBDIR)rpi_hevc_transform8.h $(SUBDIR)rpi_hevc_transform10.h
++$(SUBDIR)rpi_hevcdec.o $(SUBDIR)rpi_shader_template.o $(SUBDIR)rpi_qpu.o: $(SUBDIR)rpi_hevc_shader.h
++endif
+diff --git a/libavcodec/allcodecs.c b/libavcodec/allcodecs.c
+index 4d4ef530e4..fba8776c9f 100644
+--- a/libavcodec/allcodecs.c
++++ b/libavcodec/allcodecs.c
+@@ -142,6 +142,7 @@ extern AVCodec ff_h264_qsv_decoder;
+ extern AVCodec ff_h264_rkmpp_decoder;
+ extern AVCodec ff_hap_encoder;
+ extern AVCodec ff_hap_decoder;
++extern AVCodec ff_hevc_rpi_decoder;
+ extern AVCodec ff_hevc_decoder;
+ extern AVCodec ff_hevc_qsv_decoder;
+ extern AVCodec ff_hevc_rkmpp_decoder;
+@@ -833,6 +834,41 @@ static enum AVCodecID remap_deprecated_codec_id(enum AVCodecID id)
+ }
+ }
+
++static int codec_supports_format(const AVCodec * const p, const enum AVPixelFormat fmt)
++{
++ const enum AVPixelFormat *pf = p->pix_fmts;
++
++ // Assume good if we lack info
++ if (pf == NULL)
++ return 1;
++ if (fmt == AV_PIX_FMT_NONE)
++ return 0;
++
++ for (; *pf != AV_PIX_FMT_NONE; ++pf) {
++ if (*pf == fmt)
++ return 1;
++ }
++ return 0;
++}
++
++AVCodec *avcodec_find_decoder_by_id_and_fmt(enum AVCodecID id, enum AVPixelFormat fmt)
++{
++ const AVCodec *p, *experimental = NULL;
++ void *i = 0;
++
++ id= remap_deprecated_codec_id(id);
++ while ((p = av_codec_iterate(&i))) {
++ if (av_codec_is_decoder(p) && p->id == id && codec_supports_format(p, fmt)) {
++ if (p->capabilities & AV_CODEC_CAP_EXPERIMENTAL && !experimental) {
++ experimental = p;
++ } else
++ return (AVCodec *)p;
++ }
++ p = p->next;
++ }
++ return (AVCodec *)experimental;
++}
++
+ static AVCodec *find_codec(enum AVCodecID id, int (*x)(const AVCodec *))
+ {
+ const AVCodec *p, *experimental = NULL;
+diff --git a/libavcodec/arm/Makefile b/libavcodec/arm/Makefile
+index e656011c3c..f8801dfab6 100644
+--- a/libavcodec/arm/Makefile
++++ b/libavcodec/arm/Makefile
+@@ -40,6 +40,8 @@ OBJS-$(CONFIG_AAC_DECODER) += arm/aacpsdsp_init_arm.o \
+ arm/sbrdsp_init_arm.o
+ OBJS-$(CONFIG_DCA_DECODER) += arm/synth_filter_init_arm.o
+ OBJS-$(CONFIG_HEVC_DECODER) += arm/hevcdsp_init_arm.o
++OBJS-$(CONFIG_HEVC_RPI_DECODER) += arm/rpi_hevcdsp_init_arm.o \
++ arm/rpi_hevcpred_init_arm.o
+ OBJS-$(CONFIG_MLP_DECODER) += arm/mlpdsp_init_arm.o
+ OBJS-$(CONFIG_RV40_DECODER) += arm/rv40dsp_init_arm.o
+ OBJS-$(CONFIG_SBC_ENCODER) += arm/sbcdsp_init_arm.o
+@@ -136,10 +138,24 @@ NEON-OBJS-$(CONFIG_AAC_DECODER) += arm/aacpsdsp_neon.o \
+ NEON-OBJS-$(CONFIG_LLAUDDSP) += arm/lossless_audiodsp_neon.o
+ NEON-OBJS-$(CONFIG_DCA_DECODER) += arm/synth_filter_neon.o
+ NEON-OBJS-$(CONFIG_HEVC_DECODER) += arm/hevcdsp_init_neon.o \
++ arm/hevcdsp_idct_neon.o \
+ arm/hevcdsp_deblock_neon.o \
+ arm/hevcdsp_idct_neon.o \
+ arm/hevcdsp_qpel_neon.o \
+ arm/hevcdsp_sao_neon.o
++NEON-OBJS-$(CONFIG_HEVC_RPI_DECODER) += arm/rpi_hevcdsp_init_neon.o \
++ arm/rpi_hevc_misc_neon.o \
++ arm/rpi_hevcdsp_deblock_neon.o \
++ arm/rpi_hevcdsp_idct_neon.o \
++ arm/rpi_hevcdsp_res8_neon.o \
++ arm/rpi_hevcdsp_res16_neon.o \
++ arm/rpi_hevcdsp_sao_neon.o \
++ arm/rpi_hevcpred_init_neon.o \
++ arm/rpi_hevcpred_intra_angular_neon.o \
++ arm/rpi_hevcpred_intra_dc_neon.o \
++ arm/rpi_hevcpred_intra_filter_neon.o \
++ arm/rpi_hevcpred_intra_hv_neon.o \
++ arm/rpi_hevcpred_intra_planar_neon.o
+ NEON-OBJS-$(CONFIG_RV30_DECODER) += arm/rv34dsp_neon.o
+ NEON-OBJS-$(CONFIG_RV40_DECODER) += arm/rv34dsp_neon.o \
+ arm/rv40dsp_neon.o
+diff --git a/libavcodec/arm/cabac.h b/libavcodec/arm/cabac.h
+index fdbf86b45e..4755f20e2e 100644
+--- a/libavcodec/arm/cabac.h
++++ b/libavcodec/arm/cabac.h
+@@ -26,83 +26,209 @@
+ #include "libavutil/internal.h"
+ #include "libavcodec/cabac.h"
+
++
+ #define get_cabac_inline get_cabac_inline_arm
+ static av_always_inline int get_cabac_inline_arm(CABACContext *c,
+- uint8_t *const state)
++ uint8_t *state)
+ {
+- int bit;
+- void *reg_b, *reg_c, *tmp;
++ const uint8_t *mlps_tables = ff_h264_cabac_tables + H264_MLPS_STATE_OFFSET + 128;
++ int bit, ptr, low, tmp1, tmp2;
++ __asm__ volatile (
++ "ldr %[bit], [%[c], %[range_off]] \n\t"
++ "ldrb %[ptr], [%[state]] \n\t"
++ "sub %[tmp1], %[mlps_tables], %[lps_off] \n\t"
++ "and %[tmp2], %[bit], #0xc0 \n\t"
++ "add %[tmp1], %[tmp1], %[ptr] \n\t"
++ "ldr %[low], [%[c], %[low_off]] \n\t"
++ "ldrb %[tmp2], [%[tmp1], %[tmp2], lsl #1] \n\t"
++ "sub %[bit], %[bit], %[tmp2] \n\t"
++ "mov %[tmp1], %[bit] \n\t"
++ "cmp %[low], %[bit], lsl #17 \n\t"
++ "itt ge \n\t"
++ "movge %[tmp1], %[tmp2] \n\t"
++ "mvnge %[ptr], %[ptr] \n\t"
++ "clz %[tmp2], %[tmp1] \n\t"
++ "it ge \n\t"
++ "subge %[low], %[low], %[bit], lsl #17 \n\t"
++ "sub %[tmp2], %[tmp2], #23 \n\t"
++ "and %[bit], %[ptr], #1 \n\t"
++ "ldrb %[mlps_tables], [%[mlps_tables], %[ptr]] \n\t"
++ "lsl %[low], %[low], %[tmp2] \n\t"
++ "lsls %[ptr], %[low], #16 \n\t"
++ "bne 1f \n\t"
++ "ldr %[ptr], [%[c], %[ptr_off]] \n\t"
++ "lsl %[tmp2], %[tmp1], %[tmp2] \n\t"
++#if UNCHECKED_BITSTREAM_READER
++ "strb %[mlps_tables], [%[state]] \n\t"
++ "rbit %[state], %[low] \n\t"
++ "ldrh %[tmp1], [%[ptr]], #2 \n\t"
++#else
++ "ldr %[tmp1], [%[c], %[end_off]] \n\t"
++ "strb %[mlps_tables], [%[state]] \n\t"
++ "rbit %[state], %[low] \n\t"
++ "cmp %[tmp1], %[ptr] \n\t"
++#if CONFIG_THUMB
++ "it cs \n\t"
++ "ldrhcs %[tmp1], [%[ptr]], #2 \n\t"
++#else
++ "ldrcsh %[tmp1], [%[ptr]], #2 \n\t"
++#endif
++#endif
++ "clz %[state], %[state] \n\t"
++ "movw %[mlps_tables], #0xffff \n\t"
++ "sub %[state], %[state], #16 \n\t"
++ "str %[tmp2], [%[c], %[range_off]] \n\t"
++ "rev %[tmp1], %[tmp1] \n\t"
++ "str %[ptr], [%[c], %[ptr_off]] \n\t"
++ "lsr %[tmp1], %[tmp1], #15 \n\t"
++ "sub %[tmp1], %[tmp1], %[mlps_tables] \n\t"
++#if CONFIG_THUMB
++ "lsl %[tmp1], %[tmp1], %[state] \n\t"
++ "add %[low], %[low], %[tmp1] \n\t"
++#else
++ "add %[low], %[low], %[tmp1], lsl %[state] \n\t"
++#endif
++ "str %[low], [%[c], %[low_off]] \n\t"
++ "b 2f \n\t"
++ "1: \n\t"
++ "strb %[mlps_tables], [%[state]] \n\t"
++ "lsl %[tmp1], %[tmp1], %[tmp2] \n\t"
++ "str %[low], [%[c], %[low_off]] \n\t"
++ "str %[tmp1], [%[c], %[range_off]] \n\t"
++ "2: \n\t"
++ : // Outputs
++ [state]"+r"(state),
++ [mlps_tables]"+r"(mlps_tables),
++ [bit]"=&r"(bit),
++ [ptr]"=&r"(ptr),
++ [low]"=&r"(low),
++ [tmp1]"=&r"(tmp1),
++ [tmp2]"=&r"(tmp2)
++ : // Inputs
++ [c]"r"(c),
++ [low_off]"J"(offsetof(CABACContext, low)),
++ [range_off]"J"(offsetof(CABACContext, range)),
++ [ptr_off]"J"(offsetof(CABACContext, bytestream)),
++ [end_off]"J"(offsetof(CABACContext, bytestream_end)),
++ [lps_off]"I"((H264_MLPS_STATE_OFFSET + 128) - H264_LPS_RANGE_OFFSET)
++ : // Clobbers
++ "cc", "memory"
++ );
++ return bit;
++}
+
+- __asm__ volatile(
+- "ldrb %[bit] , [%[state]] \n\t"
+- "add %[r_b] , %[tables] , %[lps_off] \n\t"
+- "mov %[tmp] , %[range] \n\t"
+- "and %[range] , %[range] , #0xC0 \n\t"
+- "add %[r_b] , %[r_b] , %[bit] \n\t"
+- "ldrb %[range] , [%[r_b], %[range], lsl #1] \n\t"
+- "add %[r_b] , %[tables] , %[norm_off] \n\t"
+- "sub %[r_c] , %[tmp] , %[range] \n\t"
+- "lsl %[tmp] , %[r_c] , #17 \n\t"
+- "cmp %[tmp] , %[low] \n\t"
+- "it gt \n\t"
+- "movgt %[range] , %[r_c] \n\t"
+- "itt cc \n\t"
+- "mvncc %[bit] , %[bit] \n\t"
+- "subcc %[low] , %[low] , %[tmp] \n\t"
+- "add %[r_c] , %[tables] , %[mlps_off] \n\t"
+- "ldrb %[tmp] , [%[r_b], %[range]] \n\t"
+- "ldrb %[r_b] , [%[r_c], %[bit]] \n\t"
+- "lsl %[low] , %[low] , %[tmp] \n\t"
+- "lsl %[range] , %[range] , %[tmp] \n\t"
+- "uxth %[r_c] , %[low] \n\t"
+- "strb %[r_b] , [%[state]] \n\t"
+- "tst %[r_c] , %[r_c] \n\t"
+- "bne 2f \n\t"
+- "ldr %[r_c] , [%[c], %[byte]] \n\t"
++#define get_cabac_bypass get_cabac_bypass_arm
++static inline int get_cabac_bypass_arm(CABACContext * const c)
++{
++ uint32_t low = c->low, range, ptr, tmp;
++ int rv;
++ __asm volatile (
++ "ldr %[range] , [%[c], %[range_off]] \n\t"
++ "mov %[rv] , #0 \n\t"
++ "ldr %[ptr] , [%[c], %[ptr_off]] \n\t"
++ "lsl %[low] , #1 \n\t"
++#if !UNCHECKED_BITSTREAM_READER
++ "ldr %[tmp] , [%[c], %[end_off]] \n\t"
++#endif
++ "cmp %[low] , %[range], lsl #17 \n\t"
++ "itt cs \n\t"
++ "subcs %[low] , %[low], %[range], lsl #17 \n\t"
++ "movcs %[rv] , #1 \n\t"
+ #if UNCHECKED_BITSTREAM_READER
+- "ldrh %[tmp] , [%[r_c]] \n\t"
+- "add %[r_c] , %[r_c] , #2 \n\t"
+- "str %[r_c] , [%[c], %[byte]] \n\t"
++ "ldrh %[tmp] , [%[ptr]], #2 \n\t"
++#else
++ "cmp %[tmp] , %[ptr] \n\t"
++#if CONFIG_THUMB
++ "it cs \n\t"
++ "ldrhcs %[tmp] , [%[ptr]], #2 \n\t"
+ #else
+- "ldr %[r_b] , [%[c], %[end]] \n\t"
+- "ldrh %[tmp] , [%[r_c]] \n\t"
+- "cmp %[r_c] , %[r_b] \n\t"
+- "itt lt \n\t"
+- "addlt %[r_c] , %[r_c] , #2 \n\t"
+- "strlt %[r_c] , [%[c], %[byte]] \n\t"
++ "ldrcsh %[tmp] , [%[ptr]], #2 \n\t"
++#endif
+ #endif
+- "sub %[r_c] , %[low] , #1 \n\t"
+- "add %[r_b] , %[tables] , %[norm_off] \n\t"
+- "eor %[r_c] , %[low] , %[r_c] \n\t"
+- "rev %[tmp] , %[tmp] \n\t"
+- "lsr %[r_c] , %[r_c] , #15 \n\t"
+- "lsr %[tmp] , %[tmp] , #15 \n\t"
+- "ldrb %[r_c] , [%[r_b], %[r_c]] \n\t"
+- "movw %[r_b] , #0xFFFF \n\t"
+- "sub %[tmp] , %[tmp] , %[r_b] \n\t"
+- "rsb %[r_c] , %[r_c] , #7 \n\t"
+- "lsl %[tmp] , %[tmp] , %[r_c] \n\t"
+- "add %[low] , %[low] , %[tmp] \n\t"
+- "2: \n\t"
+- : [bit]"=&r"(bit),
+- [low]"+&r"(c->low),
+- [range]"+&r"(c->range),
+- [r_b]"=&r"(reg_b),
+- [r_c]"=&r"(reg_c),
+- [tmp]"=&r"(tmp)
+- : [c]"r"(c),
+- [state]"r"(state),
+- [tables]"r"(ff_h264_cabac_tables),
+- [byte]"M"(offsetof(CABACContext, bytestream)),
+- [end]"M"(offsetof(CABACContext, bytestream_end)),
+- [norm_off]"I"(H264_NORM_SHIFT_OFFSET),
+- [lps_off]"I"(H264_LPS_RANGE_OFFSET),
+- [mlps_off]"I"(H264_MLPS_STATE_OFFSET + 128)
+- : "memory", "cc"
+- );
++ "lsls %[range] , %[low], #16 \n\t"
++ "bne 1f \n\t"
+
+- return bit & 1;
++ "str %[ptr] , [%[c], %[ptr_off]] \n\t"
++ "rev %[tmp] , %[tmp] \n\t"
++ "add %[low] , %[low], %[tmp], lsr #15 \n\t"
++ "movw %[tmp] , 0xFFFF \n\t"
++ "sub %[low] , %[tmp] \n\t"
++ "1: \n\t"
++ "str %[low] , [%[c], %[low_off]] \n\t"
++ : // Outputs
++ [rv]"=&r"(rv),
++ [low]"+r"(low),
++ [range]"=&r"(range),
++ [ptr]"=&r"(ptr),
++ [tmp]"=&r"(tmp)
++ : // Inputs
++ [c]"r"(c),
++ [low_off]"J"(offsetof(CABACContext, low)),
++ [range_off]"J"(offsetof(CABACContext, range)),
++ [ptr_off]"J"(offsetof(CABACContext, bytestream)),
++ [end_off]"J"(offsetof(CABACContext, bytestream_end))
++ : // Clobbers
++ "memory", "cc"
++ );
++ return rv;
+ }
++
++
++#define get_cabac_bypass_sign get_cabac_bypass_sign_arm
++static inline int get_cabac_bypass_sign_arm(CABACContext * const c, int rv)
++{
++ uint32_t low = c->low, range, ptr, tmp;
++ __asm volatile (
++ "ldr %[range] , [%[c], %[range_off]] \n\t"
++ "ldr %[ptr] , [%[c], %[ptr_off]] \n\t"
++ "lsl %[low] , #1 \n\t"
++#if !UNCHECKED_BITSTREAM_READER
++ "ldr %[tmp] , [%[c], %[end_off]] \n\t"
++#endif
++ "cmp %[low] , %[range], lsl #17 \n\t"
++ "it cs \n\t"
++ "subcs %[low] , %[low], %[range], lsl #17 \n\t"
++ "it cc \n\t"
++ "rsbcc %[rv] , %[rv], #0 \n\t"
++#if UNCHECKED_BITSTREAM_READER
++ "ldrh %[tmp] , [%[ptr]], #2 \n\t"
++#else
++ "cmp %[tmp] , %[ptr] \n\t"
++#if CONFIG_THUMB
++ "it cs \n\t"
++ "ldrhcs %[tmp] , [%[ptr]], #2 \n\t"
++#else
++ "ldrcsh %[tmp] , [%[ptr]], #2 \n\t"
++#endif
++#endif
++ "lsls %[range] , %[low], #16 \n\t"
++ "bne 1f \n\t"
++
++ "str %[ptr] , [%[c], %[ptr_off]] \n\t"
++ "rev %[tmp] , %[tmp] \n\t"
++ "add %[low] , %[low], %[tmp], lsr #15 \n\t"
++ "movw %[tmp] , 0xFFFF \n\t"
++ "sub %[low] , %[tmp] \n\t"
++ "1: \n\t"
++ "str %[low] , [%[c], %[low_off]] \n\t"
++ : // Outputs
++ [rv]"+r"(rv),
++ [low]"+r"(low),
++ [range]"=&r"(range),
++ [ptr]"=&r"(ptr),
++ [tmp]"=&r"(tmp)
++ : // Inputs
++ [c]"r"(c),
++ [low_off]"J"(offsetof(CABACContext, low)),
++ [range_off]"J"(offsetof(CABACContext, range)),
++ [ptr_off]"J"(offsetof(CABACContext, bytestream)),
++ [end_off]"J"(offsetof(CABACContext, bytestream_end))
++ : // Clobbers
++ "memory", "cc"
++ );
++ return rv;
++}
++
+ #endif /* HAVE_ARMV6T2_INLINE */
+
+ #endif /* AVCODEC_ARM_CABAC_H */
+diff --git a/libavcodec/arm/rpi_hevc_cabac.h b/libavcodec/arm/rpi_hevc_cabac.h
+new file mode 100644
+index 0000000000..c7df9f1e5a
+--- /dev/null
++++ b/libavcodec/arm/rpi_hevc_cabac.h
+@@ -0,0 +1,605 @@
++/*
++ * This file is part of FFmpeg.
++ *
++ * FFmpeg is free software; you can redistribute it and/or
++ * modify it under the terms of the GNU Lesser General Public
++ * License as published by the Free Software Foundation; either
++ * version 2.1 of the License, or (at your option) any later version.
++ *
++ * FFmpeg is distributed in the hope that it will be useful,
++ * but WITHOUT ANY WARRANTY; without even the implied warranty of
++ * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
++ * Lesser General Public License for more details.
++ *
++ * You should have received a copy of the GNU Lesser General Public
++ * License along with FFmpeg; if not, write to the Free Software
++ * Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA
++ */
++
++#ifndef AVCODEC_ARM_HEVC_CABAC_H
++#define AVCODEC_ARM_HEVC_CABAC_H
++
++#include "config.h"
++#if HAVE_ARMV6T2_INLINE
++
++#define hevc_mem_bits32 hevc_mem_bits32_arm
++static inline uint32_t hevc_mem_bits32_arm(const void * p, const unsigned int bits)
++{
++ unsigned int n;
++ __asm__ (
++ "rev %[n], %[x] \n\t"
++ : [n]"=r"(n)
++ : [x]"r"(*(const uint32_t *)((const uint8_t *)p + (bits >> 3)))
++ :
++ );
++ return n << (bits & 7);
++}
++
++
++// ---------------------------------------------------------------------------
++//
++// Helper fns - little bits of code where ARM has an instraction that the
++// compiler doesn't know about / use
++
++#define trans_scale_sat trans_scale_sat_arm
++static inline int trans_scale_sat_arm(const int level, const unsigned int scale, const unsigned int scale_m, const unsigned int shift)
++{
++ int rv;
++ int t = ((level * (int)(scale * scale_m)) >> shift) + 1;
++
++ __asm__ (
++ "ssat %[rv], #16, %[t], ASR #1 \n\t"
++ : [rv]"=r"(rv)
++ : [t]"r"(t)
++ :
++ );
++ return rv;
++}
++
++#define update_rice update_rice_arm
++static inline void update_rice_arm(uint8_t * const stat_coeff,
++ const unsigned int last_coeff_abs_level_remaining,
++ const unsigned int c_rice_param)
++{
++ int t = last_coeff_abs_level_remaining << 1;
++ __asm__ (
++ "lsrs %[t], %[t], %[shift] \n\t"
++
++ "it eq \n\t"
++ "subeq %[stat], %[stat], #1 \n\t"
++ "cmp %[t], #6 \n\t"
++ "adc %[stat], %[stat], #0 \n\t"
++ "usat %[stat], #8, %[stat] \n\t"
++ : [stat]"+r"(*stat_coeff),
++ [t]"+r"(t)
++ : [shift]"r"(c_rice_param)
++ : "cc"
++ );
++}
++
++// ---------------------------------------------------------------------------
++//
++// CABAC get loops
++//
++// Where the loop is simple enough we can normally do 10-30% better than the
++// compiler
++
++// Get the residual greater than 1 bits
++
++#define get_cabac_greater1_bits get_cabac_greater1_bits_arm
++static inline unsigned int get_cabac_greater1_bits_arm(CABACContext * const c, const unsigned int n,
++ uint8_t * const state0)
++{
++ unsigned int i, reg_b, st, tmp, bit, rv;
++ __asm__ (
++ "mov %[i] , #0 \n\t"
++ "mov %[rv] , #0 \n\t"
++ "1: \n\t"
++ "add %[i] , %[i] , #1 \n\t"
++ "cmp %[rv] , #0 \n\t"
++ "ite eq \n\t"
++ "usateq %[st] , #2 , %[i] \n\t"
++ "movne %[st] , #0 \n\t"
++ "sub %[r_b] , %[mlps_tables], %[lps_off] \n\t"
++ "and %[tmp] , %[range] , #0xC0 \n\t"
++
++ "ldrb %[bit] , [%[state0], %[st]] \n\t"
++ "add %[r_b] , %[r_b] , %[bit] \n\t"
++ "ldrb %[tmp] , [%[r_b], %[tmp], lsl #1] \n\t"
++ "sub %[range] , %[range] , %[tmp] \n\t"
++
++ "cmp %[low] , %[range], lsl #17 \n\t"
++ "ittt ge \n\t"
++ "subge %[low] , %[low] , %[range], lsl #17 \n\t"
++ "movge %[range] , %[tmp] \n\t"
++ "mvnge %[bit] , %[bit] \n\t"
++
++ "clz %[tmp] , %[range] \n\t"
++ "sub %[tmp] , #23 \n\t"
++ "ldrb %[r_b] , [%[mlps_tables], %[bit]] \n\t"
++ "and %[bit] , %[bit] , #1 \n\t"
++ "strb %[r_b] , [%[state0], %[st]] \n\t"
++ "lsl %[low] , %[low] , %[tmp] \n\t"
++ "orr %[rv] , %[bit] , %[rv], lsl #1 \n\t"
++ "lsl %[range] , %[range] , %[tmp] \n\t"
++
++// There is a small speed gain from combining both conditions, using a single
++// branch and then working out what that meant later
++ "lsls %[tmp] , %[low] , #16 \n\t"
++ "it ne \n\t"
++ "cmpne %[n] , %[i] \n\t"
++ "bne 1b \n\t"
++
++// If reload is not required then we must have run out of flags to decode
++ "tst %[tmp] , %[tmp] \n\t"
++ "bne 2f \n\t"
++
++// Do reload
++ "ldrh %[tmp] , [%[bptr]] , #2 \n\t"
++ "rbit %[bit] , %[low] \n\t"
++ "movw %[r_b] , #0xFFFF \n\t"
++ "clz %[bit] , %[bit] \n\t"
++ "rev %[tmp] , %[tmp] \n\t"
++ "sub %[bit] , %[bit] , #16 \n\t"
++ "cmp %[n] , %[i] \n\t"
++ "rsb %[tmp] , %[r_b] , %[tmp], lsr #15 \n\t"
++
++#if CONFIG_THUMB
++ "lsl %[tmp] , %[tmp] , %[bit] \n\t"
++ "add %[low] , %[low] , %[tmp] \n\t"
++#else
++ "add %[low] , %[low] , %[tmp], lsl %[bit] \n\t"
++#endif
++
++ "bne 1b \n\t"
++ "2: \n\t"
++ : [bit]"=&r"(bit),
++ [low]"+r"(c->low),
++ [range]"+r"(c->range),
++ [r_b]"=&r"(reg_b),
++ [bptr]"+r"(c->bytestream),
++ [i]"=&r"(i),
++ [tmp]"=&r"(tmp),
++ [st]"=&r"(st),
++ [rv]"=&r"(rv)
++ : [state0]"r"(state0),
++ [n]"r"(n),
++ [mlps_tables]"r"(ff_h264_cabac_tables + H264_MLPS_STATE_OFFSET + 128),
++ [lps_off]"I"((H264_MLPS_STATE_OFFSET + 128) - H264_LPS_RANGE_OFFSET)
++ : "memory", "cc"
++ );
++ return rv;
++}
++
++
++// n must be > 0 on entry
++#define get_cabac_sig_coeff_flag_idxs get_cabac_sig_coeff_flag_idxs_arm
++static inline uint8_t * get_cabac_sig_coeff_flag_idxs_arm(CABACContext * const c, uint8_t * const state0,
++ unsigned int n,
++ const uint8_t const * ctx_map,
++ uint8_t * p)
++{
++ unsigned int reg_b, tmp, st, bit;
++ __asm__ (
++// Get bin from map
++#if CONFIG_THUMB
++ "add %[ctx_map] , %[n] \n\t"
++ "ldrb %[st] , [%[ctx_map]] \n\t"
++#else
++ "ldrb %[st] , [%[ctx_map], %[n]]! \n\t"
++#endif
++ "1: \n\t"
++
++// Load state & ranges
++ "ldrb %[bit] , [%[state0], %[st]] \n\t"
++ "and %[tmp] , %[range] , #0xC0 \n\t"
++ "sub %[r_b] , %[mlps_tables], %[lps_off] \n\t"
++ "add %[r_b] , %[r_b] , %[tmp], lsl #1 \n\t"
++ "ldrb %[tmp] , [%[r_b], %[bit]] \n\t"
++ "sub %[range] , %[range] , %[tmp] \n\t"
++
++ "cmp %[low] , %[range], lsl #17 \n\t"
++ "ittt ge \n\t"
++ "mvnge %[bit] , %[bit] \n\t"
++ "subge %[low] , %[low] , %[range], lsl #17 \n\t"
++ "movge %[range] , %[tmp] \n\t"
++
++// Renorm
++ "clz %[tmp] , %[range] \n\t"
++ "ldrb %[r_b] , [%[mlps_tables], %[bit]] \n\t"
++ "sub %[tmp] , #23 \n\t"
++ "strb %[r_b] , [%[state0], %[st]] \n\t"
++ "tst %[bit] , #1 \n\t"
++ "ldrb %[st] , [%[ctx_map], #-1]! \n\t"
++ "lsl %[low] , %[low] , %[tmp] \n\t"
++// GCC asm seems to need strbne written differently for thumb and arm
++#if CONFIG_THUMB
++ "it ne \n\t"
++ "strbne %[n] , [%[idx]] , #1 \n\t"
++#else
++ "strneb %[n] , [%[idx]] , #1 \n\t"
++#endif
++
++// There is a small speed gain from combining both conditions, using a single
++// branch and then working out what that meant later
++ "subs %[n] , %[n] , #1 \n\t"
++ "lsl %[range] , %[range] , %[tmp] \n\t"
++#if CONFIG_THUMB
++ "itt ne \n\t"
++ "lslsne %[tmp] , %[low] , #16 \n\t"
++#else
++ "lslnes %[tmp] , %[low] , #16 \n\t"
++#endif
++ "bne 1b \n\t"
++
++// If we have bits left then n must be 0 so give up now
++ "lsls %[tmp] , %[low] , #16 \n\t"
++ "bne 2f \n\t"
++
++// Do reload
++ "ldrh %[tmp] , [%[bptr]] , #2 \n\t"
++ "rbit %[bit] , %[low] \n\t"
++ "movw %[r_b] , #0xFFFF \n\t"
++ "clz %[bit] , %[bit] \n\t"
++ "cmp %[n] , #0 \n\t"
++ "rev %[tmp] , %[tmp] \n\t"
++ "sub %[bit] , %[bit] , #16 \n\t"
++ "rsb %[tmp] , %[r_b] , %[tmp], lsr #15 \n\t"
++
++#if CONFIG_THUMB
++ "lsl %[tmp] , %[tmp] , %[bit] \n\t"
++ "add %[low] , %[low] , %[tmp] \n\t"
++#else
++ "add %[low] , %[low] , %[tmp], lsl %[bit] \n\t"
++#endif
++
++// Check to see if we still have more to do
++ "bne 1b \n\t"
++ "2: \n\t"
++ : [bit]"=&r"(bit),
++ [low]"+r"(c->low),
++ [range]"+r"(c->range),
++ [r_b]"=&r"(reg_b),
++ [bptr]"+r"(c->bytestream),
++ [idx]"+r"(p),
++ [n]"+r"(n),
++ [tmp]"=&r"(tmp),
++ [st]"=&r"(st),
++ [ctx_map]"+r"(ctx_map)
++ : [state0]"r"(state0),
++ [mlps_tables]"r"(ff_h264_cabac_tables + H264_MLPS_STATE_OFFSET + 128),
++ [lps_off]"I"((H264_MLPS_STATE_OFFSET + 128) - H264_LPS_RANGE_OFFSET)
++ : "memory", "cc"
++ );
++
++ return p;
++}
++
++// ---------------------------------------------------------------------------
++//
++// CABAC_BY22 functions
++
++
++#define get_cabac_by22_start get_cabac_by22_start_arm
++static inline void get_cabac_by22_start_arm(CABACContext * const c)
++{
++ const uint8_t *ptr = c->bytestream;
++ register uint32_t low __asm__("r1"), range __asm__("r2");
++ uint32_t m, range8, bits;
++#if !USE_BY22_DIV
++ uintptr_t inv;
++#endif
++
++ av_assert2(offsetof (CABACContext, low) == 0);
++ av_assert2(offsetof (CABACContext, range) == 4);
++ av_assert2(offsetof (CABACContext, by22.range) == offsetof (CABACContext, by22.bits) + 2);
++ __asm__ volatile (
++ "ldmia %[c], {%[low], %[range]} \n\t"
++ : // Outputs
++ [low]"=r"(low),
++ [range]"=r"(range)
++ : // Inputs
++ [c]"r"(c)
++ : // Clobbers
++ );
++#if !USE_BY22_DIV
++ inv = (uintptr_t)cabac_by22_inv_range;
++#endif
++ __asm__ volatile (
++ "ldr %[m], [%[ptr]], #-("AV_STRINGIFY(CABAC_BITS)"/8) \n\t"
++#if !USE_BY22_DIV
++ "uxtb %[range8], %[range] \n\t"
++#endif
++ "rbit %[bits], %[low] \n\t"
++ "lsl %[low], %[low], #22 - "AV_STRINGIFY(CABAC_BITS)" \n\t"
++ "clz %[bits], %[bits] \n\t"
++ "str %[ptr], [%[c], %[ptr_off]] \n\t"
++ "rev %[m], %[m] \n\t"
++ "rsb %[ptr], %[bits], #9 + "AV_STRINGIFY(CABAC_BITS)" \n\t"
++ "eor %[m], %[m], #0x80000000 \n\t"
++#if !USE_BY22_DIV
++ "ldr %[inv], [%[inv], %[range8], lsl #2] \n\t"
++ "pkhbt %[range], %[bits], %[range], lsl #16 \n\t"
++ "str %[range], [%[c], %[bits_off]] \n\t"
++#else
++ "strh %[bits], [%[c], %[bits_off]] \n\t"
++#endif
++#if CONFIG_THUMB
++ "lsr %[m], %[ptr] \n\t"
++ "eor %[range], %[low], %[m] \n\t"
++#else
++ "eor %[range], %[low], %[m], lsr %[ptr] \n\t"
++#endif
++ : // Outputs
++ [ptr]"+&r"(ptr),
++ [low]"+&r"(low),
++ [range]"+&r"(range),
++#if !USE_BY22_DIV
++ [inv]"+&r"(inv),
++#endif
++ [m]"=&r"(m),
++ [range8]"=&r"(range8),
++ [bits]"=&r"(bits)
++ : // Inputs
++ [c]"r"(c),
++ [bits_off]"J"(offsetof (CABACContext, by22.bits)),
++ [ptr_off]"J"(offsetof (CABACContext, bytestream))
++ : // Clobbers
++ "memory"
++ );
++ c->low = range;
++#if !USE_BY22_DIV
++ c->range = inv;
++#endif
++}
++
++#define get_cabac_by22_peek get_cabac_by22_peek_arm
++static inline uint32_t get_cabac_by22_peek_arm(const CABACContext *const c)
++{
++ uint32_t rv = c->low &~ 1, tmp;
++ __asm__ (
++ "cmp %[inv] , #0 \n\t"
++ "it ne \n\t"
++ "umullne %[tmp] , %[rv] , %[inv], %[rv] \n\t"
++ : // Outputs
++ [rv]"+r"(rv),
++ [tmp]"=r"(tmp)
++ : // Inputs
++ [inv]"r"(c->range)
++ : // Clobbers
++ "cc"
++ );
++ return rv << 1;
++}
++
++#define get_cabac_by22_flush get_cabac_by22_flush_arm
++static inline void get_cabac_by22_flush_arm(CABACContext *const c, const unsigned int n, uint32_t val)
++{
++ uint32_t bits, ptr, tmp1, tmp2;
++ __asm__ volatile (
++ "ldrh %[bits], [%[cc], %[bits_off]] \n\t"
++ "ldr %[ptr], [%[cc], %[ptr_off]] \n\t"
++ "rsb %[tmp1], %[n], #32 \n\t"
++ "add %[bits], %[bits], %[n] \n\t"
++ "ldrh %[tmp2], [%[cc], %[range_off]] \n\t"
++ "lsr %[tmp1], %[val], %[tmp1] \n\t"
++ "ldr %[val], [%[cc], %[low_off]] \n\t"
++#if CONFIG_THUMB
++ "add %[ptr], %[ptr], %[bits], lsr #3 \n\t"
++ "ldr %[ptr], [%[ptr]] \n\t"
++#else
++ "ldr %[ptr], [%[ptr], %[bits], lsr #3] \n\t"
++#endif
++ "mul %[tmp1], %[tmp2], %[tmp1] \n\t"
++ "and %[tmp2], %[bits], #7 \n\t"
++ "strh %[bits], [%[cc], %[bits_off]] \n\t"
++ "rev %[ptr], %[ptr] \n\t"
++ "lsl %[tmp1], %[tmp1], #23 \n\t"
++#if CONFIG_THUMB
++ "lsl %[val], %[n] \n\t"
++ "sub %[val], %[tmp1] \n\t"
++#else
++ "rsb %[val], %[tmp1], %[val], lsl %[n] \n\t"
++#endif
++ "lsl %[ptr], %[ptr], %[tmp2] \n\t"
++ "orr %[val], %[val], %[ptr], lsr #9 \n\t"
++ "str %[val], [%[cc], %[low_off]] \n\t"
++ : // Outputs
++ [val]"+r"(val),
++ [bits]"=&r"(bits),
++ [ptr]"=&r"(ptr),
++ [tmp1]"=&r"(tmp1),
++ [tmp2]"=&r"(tmp2)
++ : // Inputs
++ [cc]"r"(c),
++ [n]"r"(n),
++ [bits_off]"J"(offsetof(CABACContext, by22.bits)),
++ [ptr_off]"J"(offsetof(CABACContext, bytestream)),
++ [range_off]"J"(offsetof(CABACContext, by22.range)),
++ [low_off]"J"(offsetof(CABACContext, low))
++ : // Clobbers
++ "memory"
++ );
++}
++
++#define coeff_abs_level_remaining_decode_bypass coeff_abs_level_remaining_decode_bypass_arm
++static inline int coeff_abs_level_remaining_decode_bypass_arm(CABACContext *const c, unsigned int rice_param)
++{
++ uint32_t last_coeff_abs_level_remaining;
++ uint32_t prefix, n1, range, n2, ptr, tmp1, tmp2;
++ __asm__ volatile (
++ "ldr %[remain], [%[cc], %[low_off]] \n\t"
++ "ldr %[prefix], [%[cc], %[range_off]] \n\t"
++ "bic %[remain], %[remain], #1 \n\t"
++ "ldrh %[tmp2], [%[cc], %[by22_bits_off]] \n\t"
++ "ldr %[ptr], [%[cc], %[ptr_off]] \n\t"
++ "cmp %[prefix], #0 \n\t"
++ "it ne \n\t"
++ "umullne %[prefix], %[remain], %[prefix], %[remain] \n\t"
++ "ldrh %[range], [%[cc], %[by22_range_off]] \n\t"
++ "lsl %[remain], %[remain], #1 \n\t"
++ "mvn %[prefix], %[remain] \n\t"
++ "clz %[prefix], %[prefix] \n\t"
++ "rsbs %[n1], %[prefix], #2 \n\t"
++ "bcc 1f \n\t"
++ "adc %[n1], %[rice], %[prefix] \n\t"
++ "add %[tmp2], %[tmp2], %[n1] \n\t"
++ "rsb %[n2], %[n1], #32 \n\t"
++ "and %[tmp1], %[tmp2], #7 \n\t"
++ "strh %[tmp2], [%[cc], %[by22_bits_off]] \n\t"
++ "lsr %[tmp2], %[tmp2], #3 \n\t"
++ "lsr %[n2], %[remain], %[n2] \n\t"
++ "mul %[n2], %[range], %[n2] \n\t"
++ "ldr %[range], [%[cc], %[low_off]] \n\t"
++ "ldr %[ptr], [%[ptr], %[tmp2]] \n\t"
++ "rsb %[tmp2], %[rice], #31 \n\t"
++ "lsl %[remain], %[remain], %[prefix] \n\t"
++ "lsl %[n2], %[n2], #23 \n\t"
++#if CONFIG_THUMB
++ "lsl %[range], %[n1] \n\t"
++ "sub %[range], %[n2] \n\t"
++#else
++ "rsb %[range], %[n2], %[range], lsl %[n1] \n\t"
++#endif
++ "rev %[ptr], %[ptr] \n\t"
++ "lsl %[n2], %[prefix], %[rice] \n\t"
++#if CONFIG_THUMB
++ "lsr %[remain], %[tmp2] \n\t"
++ "add %[remain], %[n2] \n\t"
++#else
++ "add %[remain], %[n2], %[remain], lsr %[tmp2] \n\t"
++#endif
++ "b 3f \n\t"
++ "1: \n\t"
++ "add %[n2], %[rice], %[prefix], lsl #1 \n\t"
++ "cmp %[n2], %[peek_bits_plus_2] \n\t"
++ "bhi 2f \n\t"
++ "sub %[n1], %[n2], #2 \n\t"
++ "add %[tmp2], %[tmp2], %[n1] \n\t"
++ "rsb %[n2], %[n1], #32 \n\t"
++ "strh %[tmp2], [%[cc], %[by22_bits_off]] \n\t"
++ "lsr %[tmp1], %[tmp2], #3 \n\t"
++ "lsr %[n2], %[remain], %[n2] \n\t"
++ "mul %[n2], %[range], %[n2] \n\t"
++ "rsb %[range], %[rice], #34 \n\t"
++ "ldr %[ptr], [%[ptr], %[tmp1]] \n\t"
++ "and %[tmp1], %[tmp2], #7 \n\t"
++ "lsl %[remain], %[remain], %[prefix] \n\t"
++ "ldr %[tmp2], [%[cc], %[low_off]] \n\t"
++ "rsb %[prefix], %[prefix], %[range] \n\t"
++ "orr %[remain], %[remain], #0x80000000 \n\t"
++ "rev %[ptr], %[ptr] \n\t"
++ "lsl %[n2], %[n2], #23 \n\t"
++ "mov %[range], #2 \n\t"
++#if CONFIG_THUMB
++ "lsl %[tmp2], %[n1] \n\t"
++ "sub %[tmp2], %[n2] \n\t"
++#else
++ "rsb %[tmp2], %[n2], %[tmp2], lsl %[n1] \n\t"
++#endif
++ "lsl %[ptr], %[ptr], %[tmp1] \n\t"
++ "lsl %[rice], %[range], %[rice] \n\t"
++ "orr %[range], %[tmp2], %[ptr], lsr #9 \n\t"
++#if CONFIG_THUMB
++ "lsr %[remain], %[prefix] \n\t"
++ "add %[remain], %[rice] \n\t"
++#else
++ "add %[remain], %[rice], %[remain], lsr %[prefix] \n\t"
++#endif
++ "b 4f \n\t"
++ "2: \n\t"
++ "add %[n1], %[tmp2], %[prefix] \n\t"
++#if CONFIG_THUMB
++ "add %[tmp2], %[ptr], %[n1], lsr #3 \n\t"
++ "ldr %[tmp2], [%[tmp2]] \n\t"
++#else
++ "ldr %[tmp2], [%[ptr], %[n1], lsr #3] \n\t"
++#endif
++ "rsb %[tmp1], %[prefix], #32 \n\t"
++ "push {%[rice]} \n\t"
++ "and %[rice], %[n1], #7 \n\t"
++ "lsr %[tmp1], %[remain], %[tmp1] \n\t"
++ "ldr %[ptr], [%[cc], %[low_off]] \n\t"
++ "mul %[remain], %[range], %[tmp1] \n\t"
++ "rev %[tmp2], %[tmp2] \n\t"
++ "rsb %[n2], %[prefix], %[n2] \n\t"
++ "ldr %[tmp1], [%[cc], %[range_off]] \n\t"
++ "lsl %[rice], %[tmp2], %[rice] \n\t"
++ "sub %[tmp2], %[n2], #2 \n\t"
++ "lsl %[remain], %[remain], #23 \n\t"
++#if CONFIG_THUMB
++ "lsl %[ptr], %[prefix] \n\t"
++ "rsb %[remain], %[ptr] \n\t"
++#else
++ "rsb %[remain], %[remain], %[ptr], lsl %[prefix] \n\t"
++#endif
++ "orr %[remain], %[remain], %[rice], lsr #9 \n\t"
++ "add %[prefix], %[n1], %[tmp2] \n\t"
++ "bic %[n1], %[remain], #1 \n\t"
++ "ldr %[ptr], [%[cc], %[ptr_off]] \n\t"
++ "cmp %[tmp1], #0 \n\t"
++ "rsb %[rice], %[tmp2], #32 \n\t"
++ "it ne \n\t"
++ "umullne %[tmp1], %[n1], %[tmp1], %[n1] \n\t"
++ "and %[tmp1], %[prefix], #7 \n\t"
++#if CONFIG_THUMB
++ "add %[ptr], %[ptr], %[prefix], lsr #3 \n\t"
++ "ldr %[ptr], [%[ptr]] \n\t"
++#else
++ "ldr %[ptr], [%[ptr], %[prefix], lsr #3] \n\t"
++#endif
++ "lsl %[n1], %[n1], #1 \n\t"
++ "lsr %[rice], %[n1], %[rice] \n\t"
++ "rsb %[n2], %[n2], #34 \n\t"
++ "mul %[range], %[range], %[rice] \n\t"
++ "pop {%[rice]} \n\t"
++ "rev %[ptr], %[ptr] \n\t"
++ "orr %[n1], %[n1], #0x80000000 \n\t"
++ "strh %[prefix], [%[cc], %[by22_bits_off]] \n\t"
++ "mov %[prefix], #2 \n\t"
++ "lsl %[range], %[range], #23 \n\t"
++#if CONFIG_THUMB
++ "lsl %[remain], %[tmp2] \n\t"
++ "rsb %[range], %[remain] \n\t"
++#else
++ "rsb %[range], %[range], %[remain], lsl %[tmp2] \n\t"
++#endif
++ "lsl %[remain], %[prefix], %[rice] \n\t"
++#if CONFIG_THUMB
++ "lsr %[n1], %[n2] \n\t"
++ "add %[remain], %[n1] \n\t"
++#else
++ "add %[remain], %[remain], %[n1], lsr %[n2] \n\t"
++#endif
++ "3: \n\t"
++ "lsl %[ptr], %[ptr], %[tmp1] \n\t"
++ "orr %[range], %[range], %[ptr], lsr #9 \n\t"
++ "4: \n\t"
++ "str %[range], [%[cc], %[low_off]] \n\t"
++ : // Outputs
++ [remain]"=&r"(last_coeff_abs_level_remaining),
++ [rice]"+r"(rice_param),
++ [prefix]"=&r"(prefix),
++ [n1]"=&r"(n1),
++ [range]"=&r"(range),
++ [n2]"=&r"(n2),
++ [ptr]"=&r"(ptr),
++ [tmp1]"=&r"(tmp1),
++ [tmp2]"=&r"(tmp2)
++ : // Inputs
++ [cc]"r"(c),
++ [peek_bits_plus_2]"I"(CABAC_BY22_PEEK_BITS + 2),
++ [low_off]"J"(offsetof(CABACContext, low)),
++ [range_off]"J"(offsetof(CABACContext, range)),
++ [by22_bits_off]"J"(offsetof(CABACContext, by22.bits)),
++ [by22_range_off]"J"(offsetof(CABACContext, by22.range)),
++ [ptr_off]"J"(offsetof(CABACContext, bytestream))
++ : // Clobbers
++ "cc", "memory"
++ );
++ return last_coeff_abs_level_remaining;
++}
++
++#endif /* HAVE_ARMV6T2_INLINE */
++
++#endif /* AVCODEC_ARM_HEVC_CABAC_H */
+diff --git a/libavcodec/arm/rpi_hevc_idct_fn_neon.S b/libavcodec/arm/rpi_hevc_idct_fn_neon.S
+new file mode 100644
+index 0000000000..0211e447a8
+--- /dev/null
++++ b/libavcodec/arm/rpi_hevc_idct_fn_neon.S
+@@ -0,0 +1,161 @@
++@ Included multiple times from hevc_idct_neon.S
++@ Macros defined there
++
++#define DC_SHIFT (15 - BIT_DEPTH)
++#define DC_ADD (1 | (1 << (14 - BIT_DEPTH)))
++#define TRN_SHIFT (20 - BIT_DEPTH)
++
++function JOIN(ff_hevc_rpi_idct_4x4_dc_neon_, BIT_DEPTH), export=1
++ ldrsh r1, [r0]
++ add r1, #DC_ADD
++ asr r1, #DC_SHIFT
++ vdup.16 q0, r1
++ vdup.16 q1, r1
++ vst1.16 {q0, q1}, [r0]
++ bx lr
++endfunc
++
++function JOIN(ff_hevc_rpi_idct_8x8_dc_neon_, BIT_DEPTH), export=1
++ ldrsh r1, [r0]
++ add r2, r0, #32
++ mov r3, #64
++ add r1, #DC_ADD
++ asr r1, #DC_SHIFT
++ vdup.16 q8, r1
++ vdup.16 q9, r1
++ vst1.16 {q8, q9}, [r0], r3
++ vst1.16 {q8, q9}, [r2], r3
++ vst1.16 {q8, q9}, [r0]
++ vst1.16 {q8, q9}, [r2]
++ bx lr
++endfunc
++
++function JOIN(ff_hevc_rpi_idct_16x16_dc_neon_, BIT_DEPTH), export=1
++ ldrsh r1, [r0]
++ add r2, r0, #32
++ mov r3, #64
++ add r1, #DC_ADD
++ mov ip, #16*16
++ asr r1, #DC_SHIFT
++ vdup.16 q8, r1
++ vdup.16 q9, r1
++1: vst1.16 {q8, q9}, [r0], r3
++ subs ip, ip, #32
++ vst1.16 {q8, q9}, [r2], r3
++ bhi 1b
++ bx lr
++endfunc
++
++function JOIN(ff_hevc_rpi_idct_32x32_dc_neon_, BIT_DEPTH), export=1
++ ldrsh r1, [r0]
++ add r2, r0, #32
++ mov r3, #64
++ add r1, #DC_ADD
++ mov ip, #32*32
++ asr r1, #DC_SHIFT
++ vdup.16 q8, r1
++ vdup.16 q9, r1
++1: vst1.16 {q8, q9}, [r0], r3
++ subs ip, ip, #32
++ vst1.16 {q8, q9}, [r2], r3
++ bhi 1b
++ bx lr
++endfunc
++
++
++function JOIN(ff_hevc_rpi_transform_4x4_neon_, BIT_DEPTH), export=1
++ vldr.i32 s0, =0x00240053 // 36 and 83
++ vld1.16 {q14, q15}, [r0 :256] // coeffs
++
++ tr4_shift #7
++
++ vzip.16 d28, d29
++ vzip.16 d30, d31
++ vzip.32 q14, q15
++
++ tr4_shift #TRN_SHIFT
++
++ vst4.16 {q14, q15}, [r0 :256]
++ bx lr
++
++ .ltorg
++endfunc
++
++
++
++function JOIN(ff_hevc_rpi_transform_luma_4x4_neon_, BIT_DEPTH), export=1
++ vmov.i32 d0, #0x4a // 74
++ vld1.16 {q14, q15}, [r0 :256] // coeffs
++ vmov.i32 d1, #0x1d // 29
++ vmov.i32 d2, #0x37 // 55
++
++ tr4_luma_shift #7
++
++ vzip.16 d28, d29
++ vzip.16 d30, d31
++ vzip.32 q14, q15
++
++ tr4_luma_shift #TRN_SHIFT
++
++ vst4.16 {q14, q15}, [r0 :256]
++ bx lr
++endfunc
++
++function JOIN(ff_hevc_rpi_transform_8x8_neon_, BIT_DEPTH), export=1
++ add r2, r0, #16
++ adr r3, tr4f
++ vpush {d8-d15}
++ vld1.16 {d0, d1}, [r3]
++ mov r3, #32
++
++ tr8_vert d16, d17, d18, d19, d24, d25, d26, d27, q8, q9, \
++ "sub r0, r0, #128-8", \
++ "sub r2, r2, #128-8", \
++ "cmp r1, #4"
++ ble 2f
++
++ tr8_vert d20, d21, d22, d23, d28, d29, d30, d31, q10, q11, \
++ "sub r0, r0, #128+8", \
++ "sub r2, r2, #128+8+16-32", \
++ "mov r3, #64"
++
++ vzip.16 d16, d17
++ vzip.16 d18, d19
++
++ vzip.16 d20, d21
++ vzip.16 d22, d23
++ vzip.16 d28, d29
++ vzip.16 d30, d31
++ vzip.32 q10, q11
++ vzip.32 q14, q15
++1:
++ vzip.16 d24, d25
++ vzip.16 d26, d27
++ vzip.32 q8, q9
++ vzip.32 q12, q13
++
++ tr8_horiz d16, d17, d18, d19, d20, d21, d22, d23, q8, q9, TRN_SHIFT
++ tr8_horiz d24, d25, d26, d27, d28, d29, d30, d31, q12, q13, TRN_SHIFT
++
++ vpop {d8-d15}
++ bx lr
++
++2: vmov.i64 q10, #0
++ sub r0, r0, #8
++ vmov.i64 q11, #0
++ sub r2, r2, #8+16-32
++ vmov.i64 q14, #0
++ mov r3, #64
++ vmov.i64 q15, #0
++
++ vzip.16 d16, d17
++ vzip.16 d18, d19
++
++ b 1b
++
++endfunc
++
++#undef DC_SHIFT
++#undef DC_ADD
++#undef TRN_SHIFT
++
+diff --git a/libavcodec/arm/rpi_hevc_misc_neon.S b/libavcodec/arm/rpi_hevc_misc_neon.S
+new file mode 100644
+index 0000000000..200eac416e
+--- /dev/null
++++ b/libavcodec/arm/rpi_hevc_misc_neon.S
+@@ -0,0 +1,238 @@
++#include "libavutil/arm/asm.S"
++#include "neon.S"
++
++@ rpi_zap_coeff_vals_neon(
++@ uint16_t * buf, [r0]
++@ unsigned int log_n_m2) [r1]
++
++function rpi_zap_coeff_vals_neon, export=1
++ mov ip, #1
++ vmov.i64 q0, #0
++ teq r1, #0
++ vmov.i64 q1, #0
++ beq 2f
++
++ lsl ip, r1 @ 2, 4 or 8
++ add r2, r0, #32
++ lsl ip, r1 @ 4, 16 or 64 = number of 32-byte blocks to zero
++ mov r3, #64
++1: vst1.8 {q0,q1}, [r0:256], r3
++ subs ip, #2
++ vst1.8 {q0,q1}, [r2:256], r3
++ bne 1b
++ bx lr
++
++2: vst1.8 {q0,q1}, [r0:256]
++ bx lr
++endfunc
++
++@ PIC jump tables are more expensive than absolute for A32 code
++.set jent_pic, CONFIG_PIC || CONFIG_THUMB
++
++@ Jump table entry - if in neon mode the bottom bit must be set
++@ ? There is probably a real asm instruction to do this but I haven't found it
++.macro jent lab
++.if jent_pic
++T .short ((0 + \lab) - (0 + 98b)) / 2
++A .short (0 + \lab) - (4 + 98b)
++.else
++T .word 1 + \lab
++A .word \lab
++.endif
++.endm
++
++.set expected_next, 0
++
++.macro cpy_compound val, p1, p2, drop_thru=0
++.if \p1 + \p2 != \val
++.error "Bad addition! \p1 + \p2 != \val"
++.endif
++.if expected_next != 0 && expected_next != \val
++.error "Drop thru failure"
++.endif
++\val\():
++ push {r0-r3}
++ bl 100\p1\()b
++ pop {r0-r3}
++ add r0, #\p1
++ add r2, #\p1
++.if \drop_thru == 0
++ b \p2\()b
++.set expected_next, 0
++.else
++.set expected_next, \p2
++.endif
++.endm
++
++@ ff_hevc_cpy_blks8x4_neon(
++@ dst [r0]
++@ dst_stride [r1]
++@ src [r2]
++@ src_stride [r3]
++@ width [sp, #0] (bytes)
++@ height) [sp, #4]
++@
++@ Power of 2 widths are directly coded, all others are done in stripes
++@ We expect the vast majority of calls to be power of 2
++@
++@ Currently has min width of 8, but we could make that 4 without issue
++@ Min height is 4
++
++function ff_hevc_rpi_cpy_blks8x4_neon, export=1
++ ldr r12, [sp, #0]
++ push {r11, lr}
++.if jent_pic
++A adr lr, 98f - 2
++.else
++A adr lr, 98f - 4
++.endif
++ lsr r12, #3
++ ldr r11, [sp, #(8 + 4)]
++.if jent_pic
++A lsl r12, #1
++A ldrsh lr, [lr, r12]
++A add pc, lr
++T tbh [pc, r12, lsl #1]
++.else
++ @ A32 only, Thumb is always PIC
++ ldr pc, [lr, r12, lsl #2]
++.endif
++
++98:
++T .short 0 @ unused
++ jent 8f
++ jent 16f
++ jent 24f
++ jent 32f
++ jent 40f
++ jent 48f
++ jent 56f
++ jent 64f
++ jent 72f
++ jent 80f
++ jent 88f
++ jent 96f
++ jent 104f
++ jent 112f
++ jent 120f
++ jent 128f
++
++1008:
++ push {r11, lr}
++8:
++ add lr, r2, r3
++ lsl r3, #1
++ add r12, r0, r1
++ lsl r1, #1
++1:
++ vld1.32 {d0 }, [r2], r3
++ vld1.32 {d1 }, [lr], r3
++ vld1.32 {d2 }, [r2], r3
++ vld1.32 {d3 }, [lr], r3
++ subs r11, #4
++ vst1.32 {d0 }, [r0], r1
++ vst1.32 {d1 }, [r12], r1
++ vst1.32 {d2 }, [r0], r1
++ vst1.32 {d3 }, [r12], r1
++ bgt 1b
++ pop {r11, pc}
++
++10016:
++ push {r11, lr}
++16:
++ add lr, r2, r3
++ lsl r3, #1
++ add r12, r0, r1
++ lsl r1, #1
++1:
++ vld1.32 {q0 }, [r2], r3
++ vld1.32 {q1 }, [lr], r3
++ vld1.32 {q2 }, [r2], r3
++ vld1.32 {q3 }, [lr], r3
++ subs r11, #4
++ vst1.32 {q0 }, [r0], r1
++ vst1.32 {q1 }, [r12], r1
++ vst1.32 {q2 }, [r0], r1
++ vst1.32 {q3 }, [r12], r1
++ bgt 1b
++ pop {r11, pc}
++
++10032:
++ push {r11, lr}
++32:
++ add lr, r2, r3
++ lsl r3, #1
++ add r12, r0, r1
++ lsl r1, #1
++1:
++ vld1.32 {q8, q9 }, [r2], r3
++ vld1.32 {q10, q11}, [lr], r3
++ vld1.32 {q12, q13}, [r2], r3
++ vld1.32 {q14, q15}, [lr], r3
++ subs r11, #4
++ vst1.32 {q8, q9 }, [r0], r1
++ vst1.32 {q10, q11}, [r12], r1
++ vst1.32 {q12, q13}, [r0], r1
++ vst1.32 {q14, q15}, [r12], r1
++ bgt 1b
++ pop {r11, pc}
++
++10064:
++ push {r11, lr}
++64:
++ add lr, r2, #32
++ add r12, r0, #32
++1:
++ vld1.32 {q8, q9 }, [r2], r3
++ vld1.32 {q10, q11}, [lr], r3
++ vld1.32 {q12, q13}, [r2], r3
++ vld1.32 {q14, q15}, [lr], r3
++ subs r11, #2
++ vst1.32 {q8, q9 }, [r0], r1
++ vst1.32 {q10, q11}, [r12], r1
++ vst1.32 {q12, q13}, [r0], r1
++ vst1.32 {q14, q15}, [r12], r1
++ bgt 1b
++ pop {r11, pc}
++
++128:
++ push {r4, r5}
++ @ We could do this with fewer registers if we jump around but I
++ @ have a primative urge to load sequentially
++ mov r4, #64
++ add lr, r2, #32
++ add r12, r0, #32
++ sub r3, r4
++ sub r1, r4
++1:
++ vld1.32 {q8, q9 }, [r2], r4
++ vld1.32 {q10, q11}, [lr], r4
++ vld1.32 {q12, q13}, [r2], r3
++ vld1.32 {q14, q15}, [lr], r3
++ subs r11, #1
++ vst1.32 {q8, q9 }, [r0], r4
++ vst1.32 {q10, q11}, [r12], r4
++ vst1.32 {q12, q13}, [r0], r1
++ vst1.32 {q14, q15}, [r12], r1
++ bgt 1b
++ pop {r4, r5, r11, pc}
++
++@ Use drop_thru where we can
++cpy_compound 104, 64, 40, 1
++cpy_compound 40, 32, 8
++
++cpy_compound 112, 64, 48, 1
++cpy_compound 48, 32, 16
++
++cpy_compound 120, 64, 56, 1
++cpy_compound 56, 32, 24, 1
++cpy_compound 24, 16, 8
++
++cpy_compound 72, 64, 8
++cpy_compound 80, 64, 16
++cpy_compound 88, 64, 24
++cpy_compound 96, 64, 32
++
++
++endfunc
++
+diff --git a/libavcodec/arm/rpi_hevc_misc_neon.h b/libavcodec/arm/rpi_hevc_misc_neon.h
+new file mode 100644
+index 0000000000..9d21f6a882
+--- /dev/null
++++ b/libavcodec/arm/rpi_hevc_misc_neon.h
+@@ -0,0 +1,438 @@
++/*
++ * This file is part of FFmpeg.
++ *
++ * FFmpeg is free software; you can redistribute it and/or
++ * modify it under the terms of the GNU Lesser General Public
++ * License as published by the Free Software Foundation; either
++ * version 2.1 of the License, or (at your option) any later version.
++ *
++ * FFmpeg is distributed in the hope that it will be useful,
++ * but WITHOUT ANY WARRANTY; without even the implied warranty of
++ * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
++ * Lesser General Public License for more details.
++ *
++ * You should have received a copy of the GNU Lesser General Public
++ * License along with FFmpeg; if not, write to the Free Software
++ * Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA
++ */
++
++#ifndef AVCODEC_ARM_RPI_HEVC_MISC_H
++#define AVCODEC_ARM_RPI_HEVC_MISC_H
++
++#include "config.h"
++#if HAVE_NEON_INLINE && !CONFIG_THUMB
++
++static av_noinline void ff_hevc_rpi_copy_vert_v2h_neon(uint8_t *dst, const uint8_t *src,
++ int pixel_shift, int height,
++ ptrdiff_t stride_src)
++{
++ const uint8_t *src2 = src + stride_src;
++ stride_src <<= 1;
++ switch (pixel_shift)
++ {
++ case 2:
++ __asm__ volatile (
++ "vld1.32 {d0[0]}, [%[src]], %[stride_src] \n\t"
++ "vld1.32 {d0[1]}, [%[src2]], %[stride_src] \n\t"
++ "vld1.32 {d1[0]}, [%[src]], %[stride_src] \n\t"
++ "subs %[height], #4 \n\t"
++ "vld1.32 {d1[1]}, [%[src2]], %[stride_src] \n\t"
++ "beq 2f \n\t"
++ "1: \n\t"
++ "vld1.32 {d2[0]}, [%[src]], %[stride_src] \n\t"
++ "vld1.32 {d2[1]}, [%[src2]], %[stride_src] \n\t"
++ "vld1.32 {d3[0]}, [%[src]], %[stride_src] \n\t"
++ "vld1.32 {d3[1]}, [%[src2]], %[stride_src] \n\t"
++ "subs %[height], #4 \n\t"
++ "vst1.32 {q0}, [%[dst]]! \n\t"
++ "beq 3f \n\t"
++ "vld1.32 {d0[0]}, [%[src]], %[stride_src] \n\t"
++ "vld1.32 {d0[1]}, [%[src2]], %[stride_src] \n\t"
++ "vld1.32 {d1[0]}, [%[src]], %[stride_src] \n\t"
++ "vld1.32 {d1[1]}, [%[src2]], %[stride_src] \n\t"
++ "subs %[height], #4 \n\t"
++ "vst1.32 {q1}, [%[dst]]! \n\t"
++ "bne 1b \n\t"
++ "2: \n\t"
++ "vst1.32 {q0}, [%[dst]] \n\t"
++ "b 4f \n\t"
++ "3: \n\t"
++ "vst1.32 {q1}, [%[dst]] \n\t"
++ "4: \n\t"
++ : // Outputs
++ [src]"+r"(src),
++ [src2]"+r"(src2),
++ [dst]"+r"(dst),
++ [height]"+r"(height)
++ : // Inputs
++ [stride_src]"r"(stride_src)
++ : // Clobbers
++ "cc", "memory"
++ );
++ break;
++ case 1:
++ __asm__ volatile (
++ "vld1.16 {d0[0]}, [%[src]], %[stride_src] \n\t"
++ "vld1.16 {d1[0]}, [%[src2]], %[stride_src] \n\t"
++ "vld1.16 {d0[1]}, [%[src]], %[stride_src] \n\t"
++ "subs %[height], #4 \n\t"
++ "vld1.16 {d1[1]}, [%[src2]], %[stride_src] \n\t"
++ "beq 2f \n\t"
++ "1: \n\t"
++ "vld1.16 {d2[0]}, [%[src]], %[stride_src] \n\t"
++ "vld1.16 {d3[0]}, [%[src2]], %[stride_src] \n\t"
++ "vld1.16 {d2[1]}, [%[src]], %[stride_src] \n\t"
++ "vld1.16 {d3[1]}, [%[src2]], %[stride_src] \n\t"
++ "vzip.16 d0, d1 \n\t"
++ "subs %[height], #4 \n\t"
++ "vst1.16 {d0}, [%[dst]]! \n\t"
++ "beq 3f \n\t"
++ "vld1.16 {d0[0]}, [%[src]], %[stride_src] \n\t"
++ "vld1.16 {d1[0]}, [%[src2]], %[stride_src] \n\t"
++ "vld1.16 {d0[1]}, [%[src]], %[stride_src] \n\t"
++ "vld1.16 {d1[1]}, [%[src2]], %[stride_src] \n\t"
++ "vzip.16 d2, d3 \n\t"
++ "subs %[height], #4 \n\t"
++ "vst1.16 {d2}, [%[dst]]! \n\t"
++ "bne 1b \n\t"
++ "2: \n\t"
++ "vzip.16 d0, d1 \n\t"
++ "vst1.16 {d0}, [%[dst]] \n\t"
++ "b 4f \n\t"
++ "3: \n\t"
++ "vzip.16 d2, d3 \n\t"
++ "vst1.16 {d2}, [%[dst]] \n\t"
++ "4: \n\t"
++ : // Outputs
++ [src]"+r"(src),
++ [src2]"+r"(src2),
++ [dst]"+r"(dst),
++ [height]"+r"(height)
++ : // Inputs
++ [stride_src]"r"(stride_src)
++ : // Clobbers
++ "cc", "memory"
++ );
++ break;
++ default:
++ __asm__ volatile (
++ "vld1.8 {d0[0]}, [%[src]], %[stride_src] \n\t"
++ "vld1.8 {d1[0]}, [%[src2]], %[stride_src] \n\t"
++ "vld1.8 {d0[1]}, [%[src]], %[stride_src] \n\t"
++ "vld1.8 {d1[1]}, [%[src2]], %[stride_src] \n\t"
++ "vld1.8 {d0[2]}, [%[src]], %[stride_src] \n\t"
++ "vld1.8 {d1[2]}, [%[src2]], %[stride_src] \n\t"
++ "vld1.8 {d0[3]}, [%[src]], %[stride_src] \n\t"
++ "subs %[height], #8 \n\t"
++ "vld1.8 {d1[3]}, [%[src2]], %[stride_src] \n\t"
++ "beq 2f \n\t"
++ "1: \n\t"
++ "vld1.8 {d2[0]}, [%[src]], %[stride_src] \n\t"
++ "vld1.8 {d3[0]}, [%[src2]], %[stride_src] \n\t"
++ "vld1.8 {d2[1]}, [%[src]], %[stride_src] \n\t"
++ "vld1.8 {d3[1]}, [%[src2]], %[stride_src] \n\t"
++ "vld1.8 {d2[2]}, [%[src]], %[stride_src] \n\t"
++ "vld1.8 {d3[2]}, [%[src2]], %[stride_src] \n\t"
++ "vld1.8 {d2[3]}, [%[src]], %[stride_src] \n\t"
++ "vld1.8 {d3[3]}, [%[src2]], %[stride_src] \n\t"
++ "vzip.8 d0, d1 \n\t"
++ "subs %[height], #8 \n\t"
++ "vst1.8 {d0}, [%[dst]]! \n\t"
++ "beq 3f \n\t"
++ "vld1.8 {d0[0]}, [%[src]], %[stride_src] \n\t"
++ "vld1.8 {d1[0]}, [%[src2]], %[stride_src] \n\t"
++ "vld1.8 {d0[1]}, [%[src]], %[stride_src] \n\t"
++ "vld1.8 {d1[1]}, [%[src2]], %[stride_src] \n\t"
++ "vld1.8 {d0[2]}, [%[src]], %[stride_src] \n\t"
++ "vld1.8 {d1[2]}, [%[src2]], %[stride_src] \n\t"
++ "vld1.8 {d0[3]}, [%[src]], %[stride_src] \n\t"
++ "vld1.8 {d1[3]}, [%[src2]], %[stride_src] \n\t"
++ "vzip.8 d2, d3 \n\t"
++ "subs %[height], #8 \n\t"
++ "vst1.8 {d2}, [%[dst]]! \n\t"
++ "bne 1b \n\t"
++ "2: \n\t"
++ "vzip.8 d0, d1 \n\t"
++ "vst1.8 {d0}, [%[dst]] \n\t"
++ "b 4f \n\t"
++ "3: \n\t"
++ "vzip.8 d2, d3 \n\t"
++ "vst1.8 {d2}, [%[dst]] \n\t"
++ "4: \n\t"
++ : // Outputs
++ [src]"+r"(src),
++ [src2]"+r"(src2),
++ [dst]"+r"(dst),
++ [height]"+r"(height)
++ : // Inputs
++ [stride_src]"r"(stride_src)
++ : // Clobbers
++ "cc", "memory"
++ );
++ break;
++ }
++}
++
++static av_noinline void ff_hevc_rpi_copy_vert_h2v_neon(uint8_t *dst, const uint8_t *src,
++ int pixel_shift, int height,
++ ptrdiff_t stride_dst)
++{
++ uint8_t *dst2 = dst + stride_dst;
++ stride_dst <<= 1;
++ switch (pixel_shift)
++ {
++ case 2:
++ __asm__ volatile (
++ "subs %[height], #4 \n\t"
++ "vld1.32 {q0}, [%[src]]! \n\t"
++ "beq 2f \n\t"
++ "1: \n\t"
++ "vld1.32 {q1}, [%[src]]! \n\t"
++ "vst1.32 {d0[0]}, [%[dst]], %[stride_dst] \n\t"
++ "vst1.32 {d0[1]}, [%[dst2]], %[stride_dst] \n\t"
++ "vst1.32 {d1[0]}, [%[dst]], %[stride_dst] \n\t"
++ "subs %[height], #4 \n\t"
++ "vst1.32 {d1[1]}, [%[dst2]], %[stride_dst] \n\t"
++ "beq 3f \n\t"
++ "vld1.32 {q0}, [%[src]]! \n\t"
++ "vst1.32 {d2[0]}, [%[dst]], %[stride_dst] \n\t"
++ "vst1.32 {d2[1]}, [%[dst2]], %[stride_dst] \n\t"
++ "vst1.32 {d3[0]}, [%[dst]], %[stride_dst] \n\t"
++ "subs %[height], #4 \n\t"
++ "vst1.32 {d3[1]}, [%[dst2]], %[stride_dst] \n\t"
++ "bne 1b \n\t"
++ "2: \n\t"
++ "vst1.32 {d0[0]}, [%[dst]], %[stride_dst] \n\t"
++ "vst1.32 {d0[1]}, [%[dst2]], %[stride_dst] \n\t"
++ "vst1.32 {d1[0]}, [%[dst]] \n\t"
++ "vst1.32 {d1[1]}, [%[dst2]] \n\t"
++ "b 4f \n\t"
++ "3: \n\t"
++ "vst1.32 {d2[0]}, [%[dst]], %[stride_dst] \n\t"
++ "vst1.32 {d2[1]}, [%[dst2]], %[stride_dst] \n\t"
++ "vst1.32 {d3[0]}, [%[dst]] \n\t"
++ "vst1.32 {d3[1]}, [%[dst2]] \n\t"
++ "4: \n\t"
++ : // Outputs
++ [dst]"+r"(dst),
++ [dst2]"+r"(dst2),
++ [src]"+r"(src),
++ [height]"+r"(height)
++ : // Inputs
++ [stride_dst]"r"(stride_dst)
++ : // Clobbers
++ "cc", "memory"
++ );
++ break;
++ case 1:
++ __asm__ volatile (
++ "subs %[height], #4 \n\t"
++ "vld1.16 {d0}, [%[src]]! \n\t"
++ "beq 2f \n\t"
++ "1: \n\t"
++ "vld1.16 {d2}, [%[src]]! \n\t"
++ "vst1.16 {d0[0]}, [%[dst]], %[stride_dst] \n\t"
++ "vst1.16 {d0[1]}, [%[dst2]], %[stride_dst] \n\t"
++ "vst1.16 {d0[2]}, [%[dst]], %[stride_dst] \n\t"
++ "subs %[height], #4 \n\t"
++ "vst1.16 {d0[3]}, [%[dst2]], %[stride_dst] \n\t"
++ "beq 3f \n\t"
++ "vld1.16 {d0}, [%[src]]! \n\t"
++ "vst1.16 {d2[0]}, [%[dst]], %[stride_dst] \n\t"
++ "vst1.16 {d2[1]}, [%[dst2]], %[stride_dst] \n\t"
++ "vst1.16 {d2[2]}, [%[dst]], %[stride_dst] \n\t"
++ "subs %[height], #4 \n\t"
++ "vst1.16 {d2[3]}, [%[dst2]], %[stride_dst] \n\t"
++ "bne 1b \n\t"
++ "2: \n\t"
++ "vst1.16 {d0[0]}, [%[dst]], %[stride_dst] \n\t"
++ "vst1.16 {d0[1]}, [%[dst2]], %[stride_dst] \n\t"
++ "vst1.16 {d0[2]}, [%[dst]] \n\t"
++ "vst1.16 {d0[3]}, [%[dst2]] \n\t"
++ "b 4f \n\t"
++ "3: \n\t"
++ "vst1.16 {d2[0]}, [%[dst]], %[stride_dst] \n\t"
++ "vst1.16 {d2[1]}, [%[dst2]], %[stride_dst] \n\t"
++ "vst1.16 {d2[2]}, [%[dst]] \n\t"
++ "vst1.16 {d2[3]}, [%[dst2]] \n\t"
++ "4: \n\t"
++ : // Outputs
++ [dst]"+r"(dst),
++ [dst2]"+r"(dst2),
++ [src]"+r"(src),
++ [height]"+r"(height)
++ : // Inputs
++ [stride_dst]"r"(stride_dst)
++ : // Clobbers
++ "cc", "memory"
++ );
++ break;
++ default:
++ __asm__ volatile (
++ "subs %[height], #8 \n\t"
++ "vld1.8 {d0}, [%[src]]! \n\t"
++ "beq 2f \n\t"
++ "1: \n\t"
++ "vld1.8 {d2}, [%[src]]! \n\t"
++ "vst1.8 {d0[0]}, [%[dst]], %[stride_dst] \n\t"
++ "vst1.8 {d0[1]}, [%[dst2]], %[stride_dst] \n\t"
++ "vst1.8 {d0[2]}, [%[dst]], %[stride_dst] \n\t"
++ "vst1.8 {d0[3]}, [%[dst2]], %[stride_dst] \n\t"
++ "vst1.8 {d0[4]}, [%[dst]], %[stride_dst] \n\t"
++ "vst1.8 {d0[5]}, [%[dst2]], %[stride_dst] \n\t"
++ "vst1.8 {d0[6]}, [%[dst]], %[stride_dst] \n\t"
++ "subs %[height], #8 \n\t"
++ "vst1.8 {d0[7]}, [%[dst2]], %[stride_dst] \n\t"
++ "beq 3f \n\t"
++ "vld1.8 {d0}, [%[src]]! \n\t"
++ "vst1.8 {d2[0]}, [%[dst]], %[stride_dst] \n\t"
++ "vst1.8 {d2[1]}, [%[dst2]], %[stride_dst] \n\t"
++ "vst1.8 {d2[2]}, [%[dst]], %[stride_dst] \n\t"
++ "vst1.8 {d2[3]}, [%[dst2]], %[stride_dst] \n\t"
++ "vst1.8 {d2[4]}, [%[dst]], %[stride_dst] \n\t"
++ "vst1.8 {d2[5]}, [%[dst2]], %[stride_dst] \n\t"
++ "vst1.8 {d2[6]}, [%[dst]], %[stride_dst] \n\t"
++ "subs %[height], #8 \n\t"
++ "vst1.8 {d2[7]}, [%[dst2]], %[stride_dst] \n\t"
++ "bne 1b \n\t"
++ "2: \n\t"
++ "vst1.8 {d0[0]}, [%[dst]], %[stride_dst] \n\t"
++ "vst1.8 {d0[1]}, [%[dst2]], %[stride_dst] \n\t"
++ "vst1.8 {d0[2]}, [%[dst]], %[stride_dst] \n\t"
++ "vst1.8 {d0[3]}, [%[dst2]], %[stride_dst] \n\t"
++ "vst1.8 {d0[4]}, [%[dst]], %[stride_dst] \n\t"
++ "vst1.8 {d0[5]}, [%[dst2]], %[stride_dst] \n\t"
++ "vst1.8 {d0[6]}, [%[dst]] \n\t"
++ "vst1.8 {d0[7]}, [%[dst2]] \n\t"
++ "b 4f \n\t"
++ "3: \n\t"
++ "vst1.8 {d2[0]}, [%[dst]], %[stride_dst] \n\t"
++ "vst1.8 {d2[1]}, [%[dst2]], %[stride_dst] \n\t"
++ "vst1.8 {d2[2]}, [%[dst]], %[stride_dst] \n\t"
++ "vst1.8 {d2[3]}, [%[dst2]], %[stride_dst] \n\t"
++ "vst1.8 {d2[4]}, [%[dst]], %[stride_dst] \n\t"
++ "vst1.8 {d2[5]}, [%[dst2]], %[stride_dst] \n\t"
++ "vst1.8 {d2[6]}, [%[dst]] \n\t"
++ "vst1.8 {d2[7]}, [%[dst2]] \n\t"
++ "4: \n\t"
++ : // Outputs
++ [dst]"+r"(dst),
++ [dst2]"+r"(dst2),
++ [src]"+r"(src),
++ [height]"+r"(height)
++ : // Inputs
++ [stride_dst]"r"(stride_dst)
++ : // Clobbers
++ "cc", "memory"
++ );
++ break;
++ }
++}
++
++static av_noinline void ff_hevc_rpi_copy_vert_v2v_neon(uint8_t *dst, const uint8_t *src,
++ int pixel_shift, int height,
++ ptrdiff_t stride_dst, ptrdiff_t stride_src)
++{
++ int x, y;
++ switch (pixel_shift)
++ {
++ case 2:
++ __asm__ volatile (
++ "ldr %[x], [%[src]], %[stride_src] \n\t"
++ "ldr %[y], [%[src]], %[stride_src] \n\t"
++ "str %[x], [%[dst]], %[stride_dst] \n\t"
++ "sub %[height], #2 \n\t"
++ "1: \n\t"
++ "ldr %[x], [%[src]], %[stride_src] \n\t"
++ "str %[y], [%[dst]], %[stride_dst] \n\t"
++ "ldr %[y], [%[src]], %[stride_src] \n\t"
++ "subs %[height], #2 \n\t"
++ "str %[x], [%[dst]], %[stride_dst] \n\t"
++ "bne 1b \n\t"
++ "str %[y], [%[dst]] \n\t"
++ : // Outputs
++ [x]"=&r"(x),
++ [y]"=&r"(y),
++ [src]"+r"(src),
++ [dst]"+r"(dst),
++ [height]"+r"(height)
++ : // Inputs
++ [stride_src]"r"(stride_src),
++ [stride_dst]"r"(stride_dst)
++ : // Clobbers
++ "cc", "memory"
++ );
++ break;
++ case 1:
++ __asm__ volatile (
++ "ldrh %[x], [%[src]], %[stride_src] \n\t"
++ "ldrh %[y], [%[src]], %[stride_src] \n\t"
++ "strh %[x], [%[dst]], %[stride_dst] \n\t"
++ "sub %[height], #2 \n\t"
++ "1: \n\t"
++ "ldrh %[x], [%[src]], %[stride_src] \n\t"
++ "strh %[y], [%[dst]], %[stride_dst] \n\t"
++ "ldrh %[y], [%[src]], %[stride_src] \n\t"
++ "subs %[height], #2 \n\t"
++ "strh %[x], [%[dst]], %[stride_dst] \n\t"
++ "bne 1b \n\t"
++ "strh %[y], [%[dst]] \n\t"
++ : // Outputs
++ [x]"=&r"(x),
++ [y]"=&r"(y),
++ [src]"+r"(src),
++ [dst]"+r"(dst),
++ [height]"+r"(height)
++ : // Inputs
++ [stride_src]"r"(stride_src),
++ [stride_dst]"r"(stride_dst)
++ : // Clobbers
++ "cc", "memory"
++ );
++ break;
++ default:
++ __asm__ volatile (
++ "ldrb %[x], [%[src]], %[stride_src] \n\t"
++ "ldrb %[y], [%[src]], %[stride_src] \n\t"
++ "strb %[x], [%[dst]], %[stride_dst] \n\t"
++ "sub %[height], #2 \n\t"
++ "1: \n\t"
++ "ldrb %[x], [%[src]], %[stride_src] \n\t"
++ "strb %[y], [%[dst]], %[stride_dst] \n\t"
++ "ldrb %[y], [%[src]], %[stride_src] \n\t"
++ "subs %[height], #2 \n\t"
++ "strb %[x], [%[dst]], %[stride_dst] \n\t"
++ "bne 1b \n\t"
++ "strb %[y], [%[dst]] \n\t"
++ : // Outputs
++ [x]"=&r"(x),
++ [y]"=&r"(y),
++ [src]"+r"(src),
++ [dst]"+r"(dst),
++ [height]"+r"(height)
++ : // Inputs
++ [stride_src]"r"(stride_src),
++ [stride_dst]"r"(stride_dst)
++ : // Clobbers
++ "cc", "memory"
++ );
++ break;
++ }
++}
++
++#define ff_hevc_rpi_copy_vert ff_hevc_rpi_copy_vert_neon
++static inline void ff_hevc_rpi_copy_vert_neon(uint8_t *dst, const uint8_t *src,
++ int pixel_shift, int height,
++ ptrdiff_t stride_dst, ptrdiff_t stride_src)
++{
++ if (stride_dst == 1 << pixel_shift)
++ ff_hevc_rpi_copy_vert_v2h_neon(dst, src, pixel_shift, height, stride_src);
++ else if (stride_src == 1 << pixel_shift)
++ ff_hevc_rpi_copy_vert_h2v_neon(dst, src, pixel_shift, height, stride_dst);
++ else
++ ff_hevc_rpi_copy_vert_v2v_neon(dst, src, pixel_shift, height, stride_dst, stride_src);
++}
++
++#endif /* HAVE_NEON_INLINE */
++
++#endif /* AVCODEC_ARM_RPI_HEVC_MISC_H */
+diff --git a/libavcodec/arm/rpi_hevc_mv_arm.h b/libavcodec/arm/rpi_hevc_mv_arm.h
+new file mode 100644
+index 0000000000..c73de55a48
+--- /dev/null
++++ b/libavcodec/arm/rpi_hevc_mv_arm.h
+@@ -0,0 +1,64 @@
++#ifndef AVCODEC_ARM_RPI_HEVC_MV_H
++#define AVCODEC_ARM_RPI_HEVC_MV_H
++
++#if HAVE_ARMV6T2_INLINE
++static inline MvXY mvxy_add_arm(const MvXY a, const MvXY b)
++{
++ MvXY r;
++ __asm__ (
++ "sadd16 %[r], %[a], %[b] \n\t"
++ : [r]"=r"(r)
++ : [a]"r"(a),
++ [b]"r"(b)
++ :
++ );
++ return r;
++}
++#define mvxy_add mvxy_add_arm
++#endif
++
++#if HAVE_ARMV6T2_INLINE
++#if (defined(__ARM_ARCH_EXT_IDIV__) || defined (__ARM_FEATURE_IDIV))
++static inline int32_t mv_scale_xy_arm(int32_t xy, int td, int tb)
++{
++ int t;
++ __asm__ (
++ "ssat %[td], #8, %[td] \n\t"
++ "ssat %[tb], #8, %[tb] \n\t"
++ "eor %[t], %[td], %[td], asr #31 \n\t"
++ "adds %[t], %[t], %[td], lsr #31 \n\t"
++ "asr %[t], #1 \n\t"
++ "add %[t], #0x4000 \n\t"
++ "it ne \n\t"
++ "sdivne %[t], %[t], %[td] \n\t"
++ "mov %[td], #32 \n\t"
++ "smlabb %[td], %[t], %[tb], %[td] \n\t"
++ "ssat %[td], #13, %[td], asr #6 \n\t"
++ "mov %[tb], #127 \n\t"
++ "smlatb %[t], %[xy], %[td], %[tb] \n\t"
++ "smlabb %[tb], %[xy], %[td], %[tb] \n\t"
++// This takes the sign of x & y for rounding at the "wrong" point
++// (i.e. after adding 127) but for the range of values (-1,-127)
++// where it does the wrong thing you get the right answer (0) anyway
++ "add %[t], %[t], %[t], lsr #31 \n\t"
++ "add %[xy], %[tb], %[tb], lsr #31 \n\t"
++ "ssat %[t], #16, %[t], asr #8 \n\t"
++ "ssat %[xy], #16, %[xy], asr #8 \n\t"
++ "pkhbt %[xy], %[xy], %[t], lsl #16 \n\t"
++ :
++ [t]"=&r"(t),
++ [xy]"+r"(xy),
++ [td]"+r"(td),
++ [tb]"+r"(tb)
++ :
++ :
++ "cc"
++ );
++ return xy;
++}
++#define mv_scale_xy mv_scale_xy_arm
++#endif
++#endif
++
++#endif // AVCODEC_ARM_RPI_HEVC_MV_H
++
+diff --git a/libavcodec/arm/rpi_hevcdsp_arm.h b/libavcodec/arm/rpi_hevcdsp_arm.h
+new file mode 100644
+index 0000000000..62b9326532
+--- /dev/null
++++ b/libavcodec/arm/rpi_hevcdsp_arm.h
+@@ -0,0 +1,26 @@
++/*
++ * This file is part of FFmpeg.
++ *
++ * FFmpeg is free software; you can redistribute it and/or
++ * modify it under the terms of the GNU Lesser General Public
++ * License as published by the Free Software Foundation; either
++ * version 2.1 of the License, or (at your option) any later version.
++ *
++ * FFmpeg is distributed in the hope that it will be useful,
++ * but WITHOUT ANY WARRANTY; without even the implied warranty of
++ * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
++ * Lesser General Public License for more details.
++ *
++ * You should have received a copy of the GNU Lesser General Public
++ * License along with FFmpeg; if not, write to the Free Software
++ * Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA
++ */
++
++#ifndef AVCODEC_ARM_HEVCDSP_ARM_H
++#define AVCODEC_ARM_HEVCDSP_ARM_H
++
++#include "libavcodec/rpi_hevcdsp.h"
++
++void ff_hevcdsp_rpi_init_neon(HEVCDSPContext *c, const int bit_depth);
++
++#endif /* AVCODEC_ARM_HEVCDSP_ARM_H */
+diff --git a/libavcodec/arm/rpi_hevcdsp_deblock_neon.S b/libavcodec/arm/rpi_hevcdsp_deblock_neon.S
+new file mode 100644
+index 0000000000..18a76a4112
+--- /dev/null
++++ b/libavcodec/arm/rpi_hevcdsp_deblock_neon.S
+@@ -0,0 +1,1633 @@
++/*
++ * Copyright (c) 2014 Seppo Tomperi <seppo.tomperi@vtt.fi>
++ *
++ * This file is part of FFmpeg.
++ *
++ * FFmpeg is free software; you can redistribute it and/or
++ * modify it under the terms of the GNU Lesser General Public
++ * License as published by the Free Software Foundation; either
++ * version 2.1 of the License, or (at your option) any later version.
++ *
++ * FFmpeg is distributed in the hope that it will be useful,
++ * but WITHOUT ANY WARRANTY; without even the implied warranty of
++ * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
++ * Lesser General Public License for more details.
++ *
++ * You should have received a copy of the GNU Lesser General Public
++ * License along with FFmpeg; if not, write to the Free Software
++ * Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1
++ */
++
++
++#include "libavutil/arm/asm.S"
++#include "neon.S"
++
++.macro hevc_loop_filter_uv_body1 P1a, P0a, Q0a, Q1a, I1, I2, I3, I4, I5, I6, I7, I8
++ vsubl.u8 q0, \Q0a, \P0a
++ vsubl.u8 q1, \P1a, \Q1a
++ vdup.16 d4, r2
++ \I1
++ vshl.i16 q0, #2
++ \I2
++ vadd.i16 q0, q1
++ \I3
++ vmovl.u8 q2, d4
++ \I4
++ vneg.s16 q1, q2
++ \I5
++ vrshr.s16 q0, #3
++ \I6
++ \I7
++ \I8
++ vmin.s16 q0, q2
++ vmovl.u8 q2, \Q0a
++ vmax.s16 q0, q1
++ vaddw.u8 q1, q0, \P0a
++ vsub.i16 q0, q2, q0
++ vqmovun.s16 \P0a, q1
++ vqmovun.s16 \Q0a, q0
++.endm
++
++
++.macro hevc_loop_filter_uv_body2 P1a, P1b, P0a, P0b, Q0a, Q0b, Q1a, Q1b, I1, I2, I3, I4, I5, I6, I7
++ vsubl.u8 q0, \Q0a, \P0a @ q0a - p0a
++ lsr r12, r2, #16
++ vsubl.u8 q1, \Q0b, \P0b @ q0b - p0b
++ vsubl.u8 q2, \P1a, \Q1a @ p1a - q1a
++ vsubl.u8 q3, \P1b, \Q1b @ p1b - q1b
++ vshl.i16 q0, #2 @ (q0a - p0a) * 4
++ vshl.i16 q1, #2 @ (q0b - p0b) * 4
++ vadd.i16 q0, q2 @ ((q0a - p0a) * 4) + p1a - q1a
++ vadd.i16 q1, q3 @ ((q0b - p0b) * 4) + p1b - q1b
++ vdup.16 d4, r2 @ tc0a, tc0b
++ vdup.16 d6, r12 @ tc1a, tc1b
++ vrshr.s16 q0, #3 @ (((q0a - p0a) * 4) + p1a - q1a + 4) >> 3
++ \I1
++ vrshr.s16 q1, #3 @ (((q0b - p0b) * 4) + p1b - q1b + 4) >> 3
++ \I2
++ vmovl.u8 q2, d4 @ tc0a, tc0b
++ \I3
++ vmovl.u8 q3, d6 @ tc1a, tc1b
++ \I4
++ vmin.s16 q0, q2
++ \I5
++ vneg.s16 q2, q2 @ -tc0a, -tc0b
++ \I6
++ vmin.s16 q1, q3
++ \I7
++ vneg.s16 q3, q3 @ -tc1a, -tc1b
++ vmax.s16 q0, q2 @ delta0a
++ vmovl.u8 q2, \Q0a
++ vmax.s16 q1, q3 @ delta0b
++ vaddw.u8 q3, q0, \P0a @ p0a + delta0a
++ vsub.i16 q0, q2, q0 @ q0a - delta0a
++ vmovl.u8 q2, \Q0b
++ vsub.i16 q2, q1 @ q0b - delta0b
++ vaddw.u8 q1, \P0b @ p0b + delta0b
++ vqmovun.s16 \Q0a, q0
++ vqmovun.s16 \P0a, q3
++ vqmovun.s16 \Q0b, q2
++ vqmovun.s16 \P0b, q1
++.endm
++
++
++@ Preserves r12
++@ Clobbers r2
++@ P0a et al all contain UVUVUVUV
++@ r2 (tc4) contains
++@ [0..7] tc U a
++@ [8..15] tc V a
++
++.macro hevc_loop_filter_uv_body1_16 P1a, P0a, Q0a, Q1a, bit_depth, I1, I2, I3, I4, I5, I6, I7, I8
++ vsub.i16 q0, \Q0a, \P0a
++ vsub.i16 q1, \P1a, \Q1a
++ vdup.16 d4, r2
++ \I1
++ vshl.i16 q0, #2
++ \I2
++ vadd.i16 q0, q1
++ \I3
++ vshll.u8 q2, d4, #\bit_depth - 8
++ \I4
++ vneg.s16 q1, q2
++ \I5
++ vrshr.s16 q0, #3
++ \I6
++ \I7
++ \I8
++ vmin.s16 q0, q2
++ vmov.i16 q2, #0
++ vmax.s16 q0, q1
++ vadd.i16 \P0a, q0
++ vsub.i16 \Q0a, q0
++ vmov.i16 q1, #(1 << \bit_depth) - 1
++ vmax.s16 \P0a, q2
++ vmax.s16 \Q0a, q2
++ vmin.s16 \P0a, q1
++ vmin.s16 \Q0a, q1
++.endm
++
++@ Clobbers r2, r12
++@ P0a et al all contain UVUVUVUV
++@ r2 (tc4) contains
++@ [0..7] tc U a
++@ [8..15] tc V a
++@ [16..23] tc U b
++@ [24..31] tc V b
++
++.macro hevc_loop_filter_uv_body2_16 P1a, P1b, P0a, P0b, Q0a, Q0b, Q1a, Q1b, bit_depth, I1, I2, I3, I4, I5, I6, I7
++ vsub.i16 q0, \Q0a, \P0a @ q0a - p0a
++ lsr r12, r2, #16
++ vsub.i16 q1, \Q0b, \P0b @ q0b - p0b
++ vsub.i16 q2, \P1a, \Q1a @ p1a - q1a
++ vsub.i16 q3, \P1b, \Q1b @ p1b - q1b
++ vshl.i16 q0, #2 @ (q0a - p0a) * 4
++ vshl.i16 q1, #2 @ (q0b - p0b) * 4
++ vadd.i16 q0, q2 @ ((q0a - p0a) * 4) + p1a - q1a
++ vadd.i16 q1, q3 @ ((q0b - p0b) * 4) + p1b - q1b
++ vdup.16 d4, r2 @ tc0a, tc0b
++ vdup.16 d6, r12 @ tc1a, tc1b
++ vrshr.s16 q0, #3 @ (((q0a - p0a) * 4) + p1a - q1a + 4) >> 3
++ \I1
++ vrshr.s16 q1, #3 @ (((q0b - p0b) * 4) + p1b - q1b + 4) >> 3
++ \I2
++ vshll.u8 q2, d4, #\bit_depth - 8 @ tc0a, tc0b
++ \I3
++ vshll.u8 q3, d6, #\bit_depth - 8 @ tc1a, tc1b
++ \I4
++ vmin.s16 q0, q2
++ \I5
++ vneg.s16 q2, q2 @ -tc0a, -tc0b
++ \I6
++ vmin.s16 q1, q3
++ \I7
++ vneg.s16 q3, q3 @ -tc1a, -tc1b
++ vmax.s16 q0, q2 @ delta0a
++ vadd.i16 \P0a, q0 @ p0a + delta0a
++ vsub.i16 \Q0a, q0 @ q0a - delta0a
++ vmax.s16 q1, q3 @ delta0b
++ vadd.i16 \P0b, q1 @ p0b + delta0b
++ vsub.i16 \Q0b, q1 @ q0b - delta0b
++ vmov.i16 q2, #0
++ vmov.i16 q3, #(1 << \bit_depth) - 1
++ vmax.s16 \P0a, q2
++ vmax.s16 \Q0a, q2
++ vmax.s16 \P0b, q2
++ vmax.s16 \Q0b, q2
++ vmin.s16 \P0a, q3
++ vmin.s16 \Q0a, q3
++ vmin.s16 \P0b, q3
++ vmin.s16 \Q0b, q3
++.endm
++
++
++
++@ uint8_t *_no_p, [sp+0]
++@ uint8_t *_no_q) [sp+4]
++
++.macro hevc_loop_filter_luma_start
++ ldr r12, [r3]
++ ldr r3, [r3, #4]
++ orrs r3, r12, r3, lsl #16
++ it eq
++ bxeq lr
++ push {r4-r10,lr} @ 32 bytes
++ ldrd r4, r5, [sp, #32] @ &_no_p
++ ldrb r4, [r4]
++ ldrb r5, [r5]
++ movs r10, r4
++ it ne
++ movne r10, #1
++ cmp r5, #0
++ it ne
++ orrne r10, #2
++.endm
++
++@ Input:
++@ r2 beta (raw: needs shift for bitdepth > 8)
++@ r3[ 0:15] tc[0] (raw: needs shift for bitdepth > 8)
++@ r3[16:31] tc[1] (raw: needs shift for bitdepth > 8)
++@
++@ Input & output
++@ 8-bit: d16-d23 (Q3,Q2,Q1,Q0,P0,P1,P2,P3)
++@ 16-bit: q8-q15
++@
++@ r1 -r1
++@ r10 b1->C, b0->N (r10 junk)
++@
++@ Junks:
++@ r5, r6, r7, r8, r9
++
++.macro m_filter_luma bit_depth, Q11, Q15
++.if \bit_depth == 8
++ vmovl.u8 q14, d22 @ q2,7 q2,6 ... q2,0 = TQ2' ... Q2' TQ2 ... Q2
++ vmovl.u8 q13, d21 @ q1,7 q1,6 ... q1,0 = TQ1' ... Q1' TQ1 ... Q1
++ vmovl.u8 q12, d20 @ q0,7 q0,6 ... q0,0 = TQ0' ... Q0' TQ0 ... Q0
++ vmovl.u8 \Q11, d19 @ p0,7 p0,6 ... p0,0 = TP0' ... P0' TP0 ... P0
++ vmovl.u8 q10, d18 @ p1,7 p1,6 ... p1,0 = TP1' ... P1' TP1 ... P1
++ vmovl.u8 q9, d17 @ p2,7 p2,6 ... p2,0 = TP2' ... P2' TP2 ... P2
++.endif
++ vadd.i16 q0, q9, \Q11 @ P2 + P0
++.if \bit_depth > 8
++ lsl r3, r3, #(\bit_depth - 8)
++.endif
++ vadd.i16 q1, q14, q12 @ Q2 + Q0
++.if \bit_depth > 8
++ lsl r2, r2, #(\bit_depth - 8)
++.endif
++ vsub.i16 q0, q10 @ P2 - P1 + P0
++ lsr r5, r3, #16
++ vsub.i16 q1, q13 @ Q2 - Q1 + Q0
++.if \bit_depth == 8
++ vmovl.u8 q8, d16 @ p3,7 p3,6 ... p3,0 = TP3' ... P3' TP3 ... P3
++ vmovl.u8 \Q15, d23 @ q3,7 q3,6 ... q3,0 = TQ3' ... Q3' TQ3 ... Q3
++.endif
++ vabd.s16 q0, q10 @ dp0 = abs(P2 - 2 * P1 + P0)
++ vabd.s16 q1, q13 @ dq0 = abs(Q2 - 2 * Q1 + Q0)
++ vmov.i64 q2, #0xffffffff0000
++ vbic q0, q2 @ only dp0(') and dp3(')
++ vbic q1, q2 @ only dq0(') and dq3(')
++ vsra.u64 q0, #16
++ vsra.u64 q1, #16
++ vdup.16 q3, r2 @ beta
++ vdup.16 d14, r3 @ tC[0]
++ vdup.16 d15, r5 @ tC[1]
++ vabd.s16 q4, q8, \Q11 @ abs(TP3'-TP0' ... P3'-P0' TP3-TP0 ... P3-P0)
++ vmovn.i32 d0, q0 @ dp3' dp0' dp3 dp0
++ vmovn.i32 d1, q1 @ dq3' dq0' dq3 dq0
++ vadd.i16 d5, d0, d1 @ d3'=dp3'+dq3' d0'=dp0'+dq0' d3=dp3+dq3 d0=dp0+dq0
++ vabd.s16 q5, \Q11, q12 @ abs(TP0'-TQ0' ... P0'-Q0' TP0-TQ0 ... P0-Q0)
++ vaba.s16 q4, \Q15, q12 @ +abs(TQ3'-TQ0' ... Q3'-Q0' TQ3-TQ0 ... Q3-Q0)
++ vpadd.i16 d2, d5, d5 @ dontcare dontcare d0'+d3' d0+d3
++ vshl.s16 q6, q7, #2 @ tC[] * 4
++ vrhadd.s16 q6, q7 @ tc25 = (tc[] * 5 + 1) >> 1
++ vcgt.s16 d2, d6, d2 @ if (d0 + d3 < beta)
++ vmov r7, s4 @ (d2) r7 = mask of blocks to apply filtering (16b/block)
++ vshr.s16 q1, q3, #3 @ beta_3 = beta >> 3
++ cmp r7, #0
++ beq .Lbypasswrite
++
++ vcgt.s16 q5, q6, q5 @ if < tc25
++ vcgt.s16 q4, q1, q4 @ if (abs({T}P[0-3]{'}-{T}P[0-3]{'})+abs({T}Q[0-3]{'}-{T}Q[0-3]{'}) < beta_3)
++ vand q4, q5
++ vbic d8, d4
++ vbic d9, d4
++ vshr.s16 q3, #2 @ beta_2 = beta >> 2
++ vsra.u64 q4, #16
++ vshl.s16 d5, #1 @ d3'<<1 d0'<<1 d3<<1 d0<<1
++ vshl.i16 q7, #1 @ tc2 = tC[] << 1
++ vcgt.s16 d6, d5 @ if (d3'<<1 < beta_2) etc
++ vmovn.i32 d8, q4 @ beta_3 && tc25 tests, prime block in ms half
++ vand d6, d8 @ && beta_2 tests, prime in ms half
++ vpadd.i16 d0, d1 @ dq0'+dq3' dq0+dq3 dp0'+dp3' dp0+dp3
++ vneg.s16 q6, q7 @ -tc2
++ vmovn.i32 d8, q3
++ vshrn.i32 d6, q3, #16
++ vand d6, d8
++ vmov r5, r6, d0 @ r5 = dp0'+dp3' dp0+dp3 r6 = dq0'+dq3' dq0+dq3
++ vmov r8, s12 @ (d6) r8 = mask of strong filtering blocks (16b/block)
++ vadd.i16 q0, \Q11, q12 @ p0 + q0
++ ands r9, r7, r8
++ beq 1f
++
++ vadd.i16 q2, q0, q10 @ p1 + p0 + q0
++ vadd.i16 q3, q0, q13 @ p0 + q0 + q1
++ lsr r3, r9, #16
++ vadd.i16 q1, q2, q9 @ p2 + p1 + p0 + q0 (new P1 before clipping)
++ vadd.i16 q4, q3, q14 @ p0 + q0 + q1 + q2 (new Q1 before clipping)
++ vadd.i16 q0, q8, q9 @ p3 + p2
++ vadd.i16 q5, \Q15, q14 @ q2 + q3
++ vadd.i16 q2, q1 @ p2 + 2 * p1 + 2 * p0 + 2 * q0
++ vadd.i16 q3, q4 @ 2 * p0 + 2 * q0 + 2 * q1 + q2
++ vshl.i16 q0, #1 @ 2 * p3 + 2 * p2
++ vshl.i16 q5, #1 @ 2 * q2 + 2 * q3
++ vadd.i16 q0, q1 @ 2 * p3 + 3 * p2 + p1 + p0 + q0 (new P2 before clipping)
++ vadd.i16 q5, q4 @ p0 + q0 + q1 + 3 * q2 + 2 * q3 (new Q2 before clipping)
++ vadd.i16 q2, q13 @ p2 + 2 * p1 + 2 * p0 + 2 * q0 + q1 (new P0 before clipping)
++ vadd.i16 q3, q10 @ p1 + 2 * p0 + 2 * q0 + 2 * q1 + q2 (new Q0 before clipping)
++ vrshr.s16 q0, #3 @ scale, with rounding
++ vrshr.s16 q5, #3
++ vrshr.s16 q1, #2
++ vrshr.s16 q4, #2
++ vrshr.s16 q2, #3
++ vrshr.s16 q3, #3
++ vsub.i16 q0, q9 @ find difference
++ vsub.i16 q5, q14
++ vsub.i16 q1, q10
++ vsub.i16 q4, q13
++ vsub.i16 q2, \Q11
++ vsub.i16 q3, q12
++ vmax.s16 q0, q6 @ clip difference to -tc2 .. tc2
++ vmax.s16 q5, q6
++ vmax.s16 q1, q6
++ vmax.s16 q4, q6
++ vmax.s16 q2, q6
++ vmax.s16 q3, q6
++ vdup.16 d12, r9 @ expand mask, reuse q6 due to register pressure
++ vdup.16 d13, r3
++ vmin.s16 q0, q7
++ vmin.s16 q5, q7
++ vmin.s16 q1, q7
++ vmin.s16 q4, q7
++ vmin.s16 q2, q7
++ vmin.s16 q3, q7
++ vadd.i16 q0, q9 @ apply difference
++ vadd.i16 q5, q14
++ vadd.i16 q1, q10
++ vadd.i16 q4, q13
++ vadd.i16 q2, \Q11
++ vadd.i16 q3, q12
++ vbit q9, q0, q6 @ apply filtered values according to mask
++ vbit q14, q5, q6
++ vbit q10, q1, q6
++ vbit q13, q4, q6
++ vbit \Q11, q2, q6
++ vbit q12, q3, q6
++ vneg.s16 q6, q7 @ restore -tc2
++
++1:
++ bics r9, r7, r8
++ beq 2f
++
++ vsub.i16 q0, q12, \Q11 @ q0 - p0
++ vsub.i16 q1, q13, q10 @ q1 - p1
++ lsr r3, r9, #16
++ vshl.i16 q2, q0, #3
++ lsr r7, r5, #16
++ vadd.i16 q3, q0, q2 @ 9 * (q0 - p0)
++ lsr r8, r6, #16
++ vshl.i16 q2, q1, #1
++ vadd.i16 q4, q1, q2 @ 3 * (q1 - p1)
++ vshr.s16 q6, #1 @ -tc = -tc2 >> 1
++ vsub.i16 q5, q3, q4
++ vrhadd.s16 q1, q9, \Q11 @ (p2 + p0 + 1) >> 1
++ vrhadd.s16 q3, q14, q12 @ (q2 + q0 + 1) >> 1
++ vrshr.s16 q5, #4 @ delta0 = (9 * (q0 - p0) - 3 * (q1 - p1) + 8) >> 4
++ vsub.i16 q1, q10 @ ((p2 + p0 + 1) >> 1) - p1
++ vsub.i16 q3, q13 @ ((q2 + q0 + 1) >> 1) - q1
++ vmax.s16 q6, q5 @
++ vshr.s16 q4, q7, #1 @ tc = tc2 >> 1
++ vdup.16 q0, r2 @ beta
++ vmin.s16 q6, q4 @ delta0 clamped to [-tc, tc]
++ vshr.s16 q4, #1 @ tc_2 = tc >> 1
++ vhadd.s16 q1, q6 @ (((p2 + p0 + 1) >> 1) - p1 + delta0) >> 1
++ vhsub.s16 q3, q6 @ (((q2 + q0 + 1) >> 1) - q1 - delta0) >> 1
++ vshr.s16 q2, q0, #1 @ beta >> 1
++ vadd.i16 q2, q0 @ beta + (beta >> 1)
++ vneg.s16 q0, q4 @ -tc_2
++ vabs.s16 q5, q5 @ abs(original delta0)
++ vshr.s16 q2, #3 @ (beta + (beta >> 1)) >> 3
++ vmax.s16 q1, q0
++ vmax.s16 q3, q0
++ vshl.s16 q0, q7, #2 @ 8 * tc
++ vadd.i16 q7, q0 @ 10 * tc
++ vdup.16 d0, r9
++ vdup.16 d1, r3 @ q0 = mask of blocks to apply filtering
++ vmin.s16 q1, q4 @ deltap1 = av_clip((((p2 + p0 + 1) >> 1) - p1 + delta0) >> 1, -tc_2, tc_2)
++ vmin.s16 q3, q4 @ deltaq1 = av_clip((((q2 + q0 + 1) >> 1) - q1 + delta0) >> 1, -tc_2, tc_2)
++ vdup.16 d8, r5 @ dp0 + dp3
++ vdup.16 d9, r7 @ dp0' + dp3'
++ vcgt.s16 q7, q5 @ if ((10 * tc) > abs(delta0))
++ vdup.16 d10, r6 @ dq0 + dq3
++ vdup.16 d11, r8 @ dq0' + dq3'
++ vand q7, q0 @ AND block and line masks
++ vcgt.s16 q4, q2, q4 @ if (((beta + (beta >> 1)) >> 3) > dp0 + dp3), i.e. if (nd_p > 1)
++ vadd.i16 q0, q1, q10 @ p1 + deltap1
++ vcgt.s16 q5, q2, q5 @ if (((beta + (beta >> 1)) >> 3) > dq0 + dq3), i.e. if (nd_q > 1)
++ vadd.i16 q3, q3, q13 @ q1 + deltaq1
++ vadd.i16 q1, \Q11, q6 @ p0 + delta0
++ vsub.i16 q2, q12, q6 @ q0 - delta0
++ vand q4, q7 @ AND nd_p test with block/line masks
++ vand q5, q7 @ AND nd_q test with block/line masks
++ vbit q10, q0, q4
++ vbit \Q11, q1, q7
++ vbit q12, q2, q7
++ vbit q13, q3, q5
++
++2:
++.if \bit_depth == 8
++ vmovn.i16 d16, q8
++ vmovn.i16 d23, \Q15
++ neg r1, r1
++ vqmovun.s16 d17, q9
++ vqmovun.s16 d18, q10
++ vqmovun.s16 d19, \Q11
++ lsls r10, #31
++ vqmovun.s16 d20, q12
++ vqmovun.s16 d21, q13
++ vqmovun.s16 d22, q14
++.else
++ vmov.i16 q0, #0
++ vmov.i16 q1, #(1 << \bit_depth - 1)
++ @ q8 & q15 should be unaltered and so don't require clipping
++ neg r1, r1
++ vmax.s16 q9, q0
++ vmax.s16 q10, q0
++ vmax.s16 q11, q0
++ vmax.s16 q12, q0
++ vmax.s16 q13, q0
++ vmax.s16 q14, q0
++ lsls r10, #31
++ vmin.s16 q9, q1
++ vmin.s16 q10, q1
++ vmin.s16 q11, q1
++ vmin.s16 q12, q1
++ vmin.s16 q13, q1
++ vmin.s16 q14, q1
++.endif
++ bx lr
++.endm
++
++function hevc_loop_filter_luma_body
++ m_filter_luma 8, q15, q11
++endfunc
++
++@ void ff_hevc_rpi_v_loop_filter_luma_neon_8(
++@ uint8_t *_pix, [r0]
++@ ptrdiff_t _stride, [r1]
++@ int _beta, [r2]
++@ int *_tc, [r3]
++@ uint8_t *_no_p, [sp+0]
++@ uint8_t *_no_q) [sp+4]
++
++function ff_hevc_rpi_v_loop_filter_luma_neon_8, export=1
++ hevc_loop_filter_luma_start
++
++ sub r4, r0, #4
++ b .Lv_loop_luma_common
++endfunc
++
++@ void ff_hevc_rpi_v_loop_filter2_luma_neon(
++@ uint8_t * pix_r, [r0]
++@ ptrdiff_t _stride, [r1]
++@ int _beta, [r2]
++@ int tc2, [r3]
++@ int no_f, [sp+0]
++@ uint8_t * pix_l) [sp+4]
++
++function ff_hevc_rpi_v_loop_filter_luma2_neon_8, export=1
++ cmp r3, #0
++ it eq
++ bxeq lr
++ push {r4-r10,lr} @ 32 bytes
++ ldr r4, [sp, #36]
++ ldr r10, [sp, #32]
++
++.Lv_loop_luma_common:
++ vpush {d8-d15}
++
++ @ It's slightly faster to do unlaned loads and transpose in the
++ @ 8-bit case, even though it needs more instructions, because
++ @ VLD4.8 is a really slow way to read from memory.
++ vld1.32 {d16[0]}, [r4:32], r1
++ vld1.32 {d20[0]}, [r0:32], r1
++ vld1.32 {d16[1]}, [r4:32], r1
++ vld1.32 {d20[1]}, [r0:32], r1
++ vld1.32 {d17[0]}, [r4:32], r1
++ vld1.32 {d21[0]}, [r0:32], r1
++ vld1.32 {d17[1]}, [r4:32], r1
++ vld1.32 {d21[1]}, [r0:32], r1
++ vld1.32 {d18[0]}, [r4:32], r1
++ vld1.32 {d22[0]}, [r0:32], r1
++ vld1.32 {d18[1]}, [r4:32], r1
++ vld1.32 {d22[1]}, [r0:32], r1
++ vld1.32 {d19[0]}, [r4:32], r1
++ vld1.32 {d23[0]}, [r0:32], r1
++ vld1.32 {d19[1]}, [r4:32]
++ vld1.32 {d23[1]}, [r0:32]
++ vuzp.16 q8, q9
++ vuzp.16 q10, q11
++ vuzp.8 q8, q9
++ vuzp.8 q10, q11
++ vswp d17, d18
++ vswp d21, d22
++
++ bl hevc_loop_filter_luma_body
++
++ add r6, r4, r1
++ add r2, r0, r1
++ lsl r1, #1
++
++ vpop {d8-d15}
++
++ @ no_p[1]
++ bmi 1f
++ vst4.8 {d16[7],d17[7],d18[7],d19[7]}, [r4:32], r1
++ vst4.8 {d16[6],d17[6],d18[6],d19[6]}, [r6:32], r1
++ vst4.8 {d16[5],d17[5],d18[5],d19[5]}, [r4:32], r1
++ vst4.8 {d16[4],d17[4],d18[4],d19[4]}, [r6:32], r1
++
++ vst4.8 {d16[3],d17[3],d18[3],d19[3]}, [r4:32], r1
++ vst4.8 {d16[2],d17[2],d18[2],d19[2]}, [r6:32], r1
++ vst4.8 {d16[1],d17[1],d18[1],d19[1]}, [r4:32], r1
++ vst4.8 {d16[0],d17[0],d18[0],d19[0]}, [r6:32]
++1:
++ @ no_q[1]
++ bcs 1f
++ vst4.8 {d20[7],d21[7],d22[7],d23[7]}, [r0:32], r1
++ vst4.8 {d20[6],d21[6],d22[6],d23[6]}, [r2:32], r1
++ vst4.8 {d20[5],d21[5],d22[5],d23[5]}, [r0:32], r1
++ vst4.8 {d20[4],d21[4],d22[4],d23[4]}, [r2:32], r1
++
++ vst4.8 {d20[3],d21[3],d22[3],d23[3]}, [r0:32], r1
++ vst4.8 {d20[2],d21[2],d22[2],d23[2]}, [r2:32], r1
++ vst4.8 {d20[1],d21[1],d22[1],d23[1]}, [r0:32], r1
++ vst4.8 {d20[0],d21[0],d22[0],d23[0]}, [r2:32]
++1:
++ pop {r4-r10,pc}
++
++.Lbypasswrite:
++ vpop {d8-d15}
++ pop {r4-r10,pc}
++endfunc
++
++.macro m_filter_v_luma_16 bit_depth
++ vpush {d8-d15}
++
++ @ Uses slightly fewer instructions to do laned loads than unlaned
++ @ and transpose. This also means that we can use the same code for
++ @ both split & unsplit deblock
++ vld4.16 {d16[0], d18[0], d20[0], d22[0]}, [r4], r1
++ vld4.16 {d24[0], d26[0], d28[0], d30[0]}, [r0], r1
++
++ vld4.16 {d16[1], d18[1], d20[1], d22[1]}, [r4], r1
++ vld4.16 {d24[1], d26[1], d28[1], d30[1]}, [r0], r1
++
++ vld4.16 {d16[2], d18[2], d20[2], d22[2]}, [r4], r1
++ vld4.16 {d24[2], d26[2], d28[2], d30[2]}, [r0], r1
++
++ vld4.16 {d16[3], d18[3], d20[3], d22[3]}, [r4], r1
++ vld4.16 {d24[3], d26[3], d28[3], d30[3]}, [r0], r1
++
++ vld4.16 {d17[0], d19[0], d21[0], d23[0]}, [r4], r1
++ vld4.16 {d25[0], d27[0], d29[0], d31[0]}, [r0], r1
++
++ vld4.16 {d17[1], d19[1], d21[1], d23[1]}, [r4], r1
++ vld4.16 {d25[1], d27[1], d29[1], d31[1]}, [r0], r1
++
++ vld4.16 {d17[2], d19[2], d21[2], d23[2]}, [r4], r1
++ vld4.16 {d25[2], d27[2], d29[2], d31[2]}, [r0], r1
++
++ vld4.16 {d17[3], d19[3], d21[3], d23[3]}, [r4]
++ vld4.16 {d25[3], d27[3], d29[3], d31[3]}, [r0]
++
++ bl hevc_loop_filter_luma_body_\bit_depth
++
++ add r6, r4, r1
++ add r2, r0, r1
++ lsl r1, #1
++
++ vpop {d8-d15}
++
++ @ p[1]
++ bmi 1f
++ vst4.16 {d17[3], d19[3], d21[3], d23[3]}, [r4], r1
++ vst4.16 {d17[2], d19[2], d21[2], d23[2]}, [r6], r1
++ vst4.16 {d17[1], d19[1], d21[1], d23[1]}, [r4], r1
++ vst4.16 {d17[0], d19[0], d21[0], d23[0]}, [r6], r1
++ vst4.16 {d16[3], d18[3], d20[3], d22[3]}, [r4], r1
++ vst4.16 {d16[2], d18[2], d20[2], d22[2]}, [r6], r1
++ vst4.16 {d16[1], d18[1], d20[1], d22[1]}, [r4], r1
++ vst4.16 {d16[0], d18[0], d20[0], d22[0]}, [r6]
++1:
++ @ q[1]
++ bcs 1f
++ vst4.16 {d25[3], d27[3], d29[3], d31[3]}, [r0], r1
++ vst4.16 {d25[2], d27[2], d29[2], d31[2]}, [r2], r1
++ vst4.16 {d25[1], d27[1], d29[1], d31[1]}, [r0], r1
++ vst4.16 {d25[0], d27[0], d29[0], d31[0]}, [r2], r1
++ vst4.16 {d24[3], d26[3], d28[3], d30[3]}, [r0], r1
++ vst4.16 {d24[2], d26[2], d28[2], d30[2]}, [r2], r1
++ vst4.16 {d24[1], d26[1], d28[1], d30[1]}, [r0], r1
++ vst4.16 {d24[0], d26[0], d28[0], d30[0]}, [r2]
++1:
++ pop {r4-r10,pc}
++.endm
++
++
++
++
++@ void (*hevc_h_loop_filter_luma)(uint8_t *pix, [r0]
++@ ptrdiff_t stride, [r1]
++@ int beta, [r2]
++@ int32_t *tc, [r3]
++@ uint8_t *no_p, sp[0]
++@ uint8_t *no_q); sp[4]
++@
++@ Src should always be on 8 byte boundry & all in the same slice
++
++function ff_hevc_rpi_h_loop_filter_luma_neon_8, export=1
++ hevc_loop_filter_luma_start
++ b .Lh_loop_filter_luma_common_8
++endfunc
++
++function ff_hevc_rpi_h_loop_filter_luma2_neon_8, export=1
++ cmp r3, #0
++ it eq
++ bxeq lr
++ push {r4-r10,lr} @ 32 bytes
++ ldr r10, [sp, #32]
++
++.Lh_loop_filter_luma_common_8:
++ sub r4, r0, r1, lsl #2
++ add r0, r4, r1
++ lsl r1, #1
++ vpush {d8-d15}
++
++ vld1.8 {d16}, [r4], r1
++ vld1.8 {d17}, [r0], r1
++ vld1.8 {d18}, [r4], r1
++ vld1.8 {d19}, [r0], r1
++ vld1.8 {d20}, [r4], r1
++ vld1.8 {d21}, [r0], r1
++ vld1.8 {d22}, [r4]
++ vld1.8 {d23}, [r0]
++
++ bl hevc_loop_filter_luma_body
++
++ add r0, r0, r1, lsl #1
++ add r2, r4, r1, lsl #1
++ add r6, r4, r1, asr #1
++ vpop {d8-d15}
++
++ @ P2-P0
++ bcs 1f
++ vst1.8 {d22}, [r4], r1
++ vst1.8 {d21}, [r6]
++ vst1.8 {d20}, [r4]
++1:
++ @ Q0-Q2
++ bmi 1f
++ vst1.8 {d19}, [r0], r1
++ vst1.8 {d18}, [r2]
++ vst1.8 {d17}, [r0]
++1:
++ pop {r4-r10,pc}
++endfunc
++
++
++.macro m_filter_h_luma_16 bit_depth
++ sub r4, r0, r1, lsl #2
++ add r0, r4, r1
++ lsl r1, #1
++ vpush {d8-d15}
++
++ vld1.16 { q8}, [r4], r1
++ vld1.16 { q9}, [r0], r1
++ vld1.16 {q10}, [r4], r1
++ vld1.16 {q11}, [r0], r1
++ vld1.16 {q12}, [r4], r1
++ vld1.16 {q13}, [r0], r1
++ vld1.16 {q14}, [r4]
++ vld1.16 {q15}, [r0]
++
++ bl hevc_loop_filter_luma_body_\bit_depth
++
++ add r0, r0, r1, lsl #1
++ add r2, r4, r1, lsl #1
++ add r6, r4, r1, asr #1
++ vpop {d8-d15}
++
++ @ P2-P0
++ bcs 1f
++ vst1.16 {q14}, [r4], r1
++ vst1.16 {q13}, [r6]
++ vst1.16 {q12}, [r4]
++1:
++ bmi 1f
++ vst1.16 {q11}, [r0], r1
++ vst1.16 {q10}, [r2]
++ vst1.16 { q9}, [r0]
++1:
++ pop {r4-r10,pc}
++.endm
++
++
++@ void ff_hevc_rpi_h_loop_filter_uv_neon(uint8_t * src_r, // r0
++@ unsigned int stride, // r1
++@ uint32_t tc4, // r2
++@ unsigned int no_f); // r3
++@
++@ no_f
++@ 0 tl P0
++@ 1 tr P1
++@ 2 bl Q0
++@ 3 br Q1
++@
++@ Probably not worth having the P/Qa only special case in this direction
++@ Given layout we won't save any memory reads or avoid any cache dirtying
++@ We would save a bit of computation but I expect the partials to be less
++@ common in the H direction than V due to how we arrange deblock.
++
++function ff_hevc_rpi_h_loop_filter_uv_neon_8, export=1
++ sub r12, r0, r1
++ cmp r2, #0
++ it eq
++ bxeq lr
++ vld1.8 {d26,d27}, [r0]
++ lsl r1, #1
++ sub r0, r1
++ vld1.8 {d18,d19}, [r12], r1
++ vld1.8 {d16,d17}, [r0], r1
++ vld1.8 {d28,d29}, [r12]
++
++ hevc_loop_filter_uv_body2 d16, d17, d18, d19, d26, d27, d28, d29, \
++ "sub r12, r0, r1, asr #1"
++
++ lsls r3, #29 @ b2 -> N, b3 -> C
++ it pl
++ vstrpl d26, [r0, #0]
++ it cc
++ vstrcc d27, [r0, #8]
++ lsls r3, #2 @ b0 -> N, b1 -> C
++ it pl
++ vstrpl d18, [r12, #0]
++ it cc
++ vstrcc d19, [r12, #8]
++ bx lr
++
++endfunc
++
++
++@ void ff_hevc_rpi_h_loop_filter_uv_neon_10(uint8_t * src_r, // r0
++@ unsigned int stride, // r1
++@ uint32_t tc4, // r2
++@ unsigned int no_f); // r3
++@
++@ no-F = b0:no_p[0], b1:no_p[1], b2:no_q[0], b3:no_q[1]
++@
++@ Macro here actual function near bottom
++
++.macro m_filter_h_uv_16 bit_depth
++ sub r12, r0, r1
++ cmp r2, #0
++ it eq
++ bxeq lr
++ vld1.16 {q12, q13}, [r0]
++ lsl r1, #1
++ sub r0, r1
++ vld1.16 {q10, q11}, [r12], r1
++ vld1.16 {q8, q9 }, [r0], r1
++ vld1.16 {q14, q15}, [r12]
++
++ hevc_loop_filter_uv_body2_16 q8, q9, q10, q11, q12, q13, q14, q15, \bit_depth, \
++ "sub r12, r0, r1, asr #1", \
++ "cmp r3, #0"
++
++ bne 1f
++ vst1.16 {q10, q11}, [r12]
++ vst1.16 {q12, q13}, [r0]
++ bx lr
++
++ @ At least one no_f bit is set
++ @ Which means we need to break this apart in an ugly fashion
++1:
++ lsls r3, #29 @ b2 -> N, b3 -> C
++ itt pl
++ vstrpl d24, [r0, #0]
++ vstrpl d25, [r0, #8]
++ itt cc
++ vstrcc d26, [r0, #16]
++ vstrcc d27, [r0, #24]
++ lsls r3, #2 @ b0 -> N, b1 -> C
++ itt pl
++ vstrpl d20, [r12, #0]
++ vstrpl d21, [r12, #8]
++ itt cc
++ vstrcc d22, [r12, #16]
++ vstrcc d23, [r12, #24]
++ bx lr
++.endm
++
++
++@ void ff_hevc_rpi_v_loop_filter_uv2_neon(uint8_t * src_r, // r0
++@ unsigned int stride, // r1
++@ uint32_t tc4, // r2
++@ uint8_t * src_l, // r3
++@ unsigned int no_f); // sp[0]
++@
++@ no_f:
++@ 0 tl P0
++@ 1 tr Q0
++@ 2 bl P1
++@ 3 br Q1
++
++function ff_hevc_rpi_v_loop_filter_uv2_neon_8, export=1
++ cmp r2, #0
++ it eq
++ bxeq lr
++ push {lr}
++ vld2.16 {d16[0], d18[0]}, [r3], r1
++ vld2.16 {d20[0], d22[0]}, [r0], r1
++
++ cmp r2, #0x10000
++ vld2.16 {d16[1], d18[1]}, [r3], r1
++ vld2.16 {d20[1], d22[1]}, [r0], r1
++
++ vld2.16 {d16[2], d18[2]}, [r3], r1
++ vld2.16 {d20[2], d22[2]}, [r0], r1
++
++ vld2.16 {d16[3], d18[3]}, [r3], r1
++ vld2.16 {d20[3], d22[3]}, [r0], r1
++ blo 10f
++
++ vld2.16 {d17[0], d19[0]}, [r3], r1
++ vld2.16 {d21[0], d23[0]}, [r0], r1
++
++ sub ip, r0, r3
++ vld2.16 {d17[1], d19[1]}, [r3], r1
++ vld2.16 {d21[1], d23[1]}, [r0], r1
++
++ cmp ip, #4
++ vld2.16 {d17[2], d19[2]}, [r3], r1
++ vld2.16 {d21[2], d23[2]}, [r0], r1
++
++ vld2.16 {d17[3], d19[3]}, [r3]
++ vld2.16 {d21[3], d23[3]}, [r0]
++
++ hevc_loop_filter_uv_body2 d16, d17, d18, d19, d20, d21, d22, d23 \
++ "ldr lr, [sp, #4]", \
++ "neg r1, r1", \
++ "it eq; cmpeq lr, #0", \
++ "add r3, #2", \
++ "add ip, r3, r1", \
++ "add r2, r0, r1", \
++ "lsl r1, #1"
++
++ bne 1f
++
++@ Much/most of the time r0 == r3 + 4 and no_f == 0
++@ so it is worth having this special case
++ vst2.16 {d19[3], d21[3]}, [r3], r1 @ P0b, Q0b
++ vst2.16 {d19[2], d21[2]}, [ip], r1
++ vst2.16 {d19[1], d21[1]}, [r3], r1
++ vst2.16 {d19[0], d21[0]}, [ip], r1
++ vst2.16 {d18[3], d20[3]}, [r3], r1 @ P0a, Q0a
++ vst2.16 {d18[2], d20[2]}, [ip], r1
++ vst2.16 {d18[1], d20[1]}, [r3]
++ vst2.16 {d18[0], d20[0]}, [ip]
++ pop {pc}
++
++@ Either split or partial
++1:
++ lsls lr, #29 @ b3 (Q0b) -> C, b2 (P0b) -> N & b31, b1 (Q0a) -> b30, b0 (P0a) -> b29
++ ittt cs
++ addcs r0, r0, r1, lsl #1
++ addcs r2, r2, r1, lsl #1
++ bcs 1f
++ @ Q0b
++ vst1.16 {d21[3]}, [r0], r1
++ vst1.16 {d21[2]}, [r2], r1
++ vst1.16 {d21[1]}, [r0], r1
++ vst1.16 {d21[0]}, [r2], r1
++1:
++ ittt mi
++ addmi r3, r3, r1, lsl #1
++ addmi ip, ip, r1, lsl #1
++ bmi 1f
++ @ P0b
++ vst1.16 {d19[3]}, [r3], r1
++ vst1.16 {d19[2]}, [ip], r1
++ vst1.16 {d19[1]}, [r3], r1
++ vst1.16 {d19[0]}, [ip], r1
++1:
++ lsls lr, #2 @ b30 (Q0a) -> C, b29 (P0a) -> N & b31
++ bcs 1f
++ @ Q0a
++ vst1.16 {d20[3]}, [r0], r1
++ vst1.16 {d20[2]}, [r2], r1
++ vst1.16 {d20[1]}, [r0]
++ vst1.16 {d20[0]}, [r2]
++1:
++ it mi
++ popmi {pc}
++ @ P0a
++ vst1.16 {d18[3]}, [r3], r1
++ vst1.16 {d18[2]}, [ip], r1
++ vst1.16 {d18[1]}, [r3]
++ vst1.16 {d18[0]}, [ip]
++ pop {pc}
++
++@ Single lump (rather than double)
++10:
++ @ As we have post inced r0/r3 in the load the easiest thing to do is
++ @ to subtract and write forwards, rather than backwards (as above)
++ @ b0 (P0a) -> N, b1 (Q0a) -> C
++
++ hevc_loop_filter_uv_body1 d16, d18, d20, d22 \
++ "ldr lr, [sp, #4]", \
++ "add r3, #2", \
++ "sub r0, r0, r1, lsl #2", \
++ "sub r3, r3, r1, lsl #2", \
++ "lsls lr, #31", \
++ "add r2, r0, r1", \
++ "add ip, r3, r1", \
++ "lsl r1, #1"
++
++ bcs 3f
++ @ Q0a
++ vst1.16 {d20[0]}, [r0], r1
++ vst1.16 {d20[1]}, [r2], r1
++ vst1.16 {d20[2]}, [r0]
++ vst1.16 {d20[3]}, [r2]
++3:
++ it mi
++ popmi {pc}
++ @ P0a
++ vst1.16 {d18[0]}, [r3], r1
++ vst1.16 {d18[1]}, [ip], r1
++ vst1.16 {d18[2]}, [r3]
++ vst1.16 {d18[3]}, [ip]
++ pop {pc}
++
++endfunc
++
++
++@ void ff_hevc_rpi_v_loop_filter_uv2_neon(uint8_t * src_r, // r0
++@ unsigned int stride, // r1
++@ uint32_t tc4, // r2
++@ uint8_t * src_l, // r3
++@ unsigned int no_f); // sp[0]
++@
++
++@ no_f
++@ 0 tl P0a
++@ 1 tr Q0a
++@ 2 bl P0b
++@ 3 br Q0b
++
++@ P1: q8, q12
++@ P0: q9, q13
++@ Q0: q10, q14
++@ Q1: q11, q15
++
++.macro m_filter_v_uv2_16 bit_depth
++ cmp r2, #0
++ it eq
++ bxeq lr
++ push {lr}
++ vld2.32 {d16[0], d18[0]}, [r3], r1
++ vld2.32 {d20[0], d22[0]}, [r0], r1
++
++ cmp r2, #0x10000
++ vld2.32 {d16[1], d18[1]}, [r3], r1
++ vld2.32 {d20[1], d22[1]}, [r0], r1
++
++ vld2.32 {d17[0], d19[0]}, [r3], r1
++ vld2.32 {d21[0], d23[0]}, [r0], r1
++
++ vld2.32 {d17[1], d19[1]}, [r3], r1
++ vld2.32 {d21[1], d23[1]}, [r0], r1
++ blo 10f
++
++ vld2.32 {d24[0], d26[0]}, [r3], r1
++ vld2.32 {d28[0], d30[0]}, [r0], r1
++
++ sub ip, r0, r3
++ vld2.32 {d24[1], d26[1]}, [r3], r1
++ vld2.32 {d28[1], d30[1]}, [r0], r1
++
++ cmp ip, #8
++ vld2.32 {d25[0], d27[0]}, [r3], r1
++ vld2.32 {d29[0], d31[0]}, [r0], r1
++
++ vld2.32 {d25[1], d27[1]}, [r3]
++ vld2.32 {d29[1], d31[1]}, [r0]
++
++ hevc_loop_filter_uv_body2_16 q8, q12, q9, q13, q10, q14, q11, q15, \bit_depth, \
++ "ldr lr, [sp, #4]", \
++ "neg r1, r1", \
++ "it eq; cmpeq lr, #0", \
++ "add r3, #4", \
++ "add ip, r3, r1", \
++ "add r2, r0, r1", \
++ "lsl r1, #1"
++
++ bne 1f
++
++@ Much/most of the time r0 == r3 + 8 and no_f == 0
++@ so it is worth having this special case
++ vst2.32 {d27[1], d29[1]}, [r3], r1 @ P0b, Q0b
++ vst2.32 {d27[0], d29[0]}, [ip], r1
++ vst2.32 {d26[1], d28[1]}, [r3], r1
++ vst2.32 {d26[0], d28[0]}, [ip], r1
++ vst2.32 {d19[1], d21[1]}, [r3], r1 @ P0a, Q0a
++ vst2.32 {d19[0], d21[0]}, [ip], r1
++ vst2.32 {d18[1], d20[1]}, [r3]
++ vst2.32 {d18[0], d20[0]}, [ip]
++ pop {pc}
++
++@ Either split or partial
++1:
++ lsls lr, #29 @ b3 (Q0b) -> C, b2 (P0b) -> N & b31, b1 (Q0a) -> b30, b0 (P0a) -> b29
++ ittt cs
++ addcs r0, r0, r1, lsl #1
++ addcs r2, r2, r1, lsl #1
++ bcs 1f
++ @ Q0b
++ vst1.32 {d29[1]}, [r0], r1
++ vst1.32 {d29[0]}, [r2], r1
++ vst1.32 {d28[1]}, [r0], r1
++ vst1.32 {d28[0]}, [r2], r1
++1:
++ ittt mi
++ addmi r3, r3, r1, lsl #1
++ addmi ip, ip, r1, lsl #1
++ bmi 1f
++ @ P0b
++ vst1.32 {d27[1]}, [r3], r1
++ vst1.32 {d27[0]}, [ip], r1
++ vst1.32 {d26[1]}, [r3], r1
++ vst1.32 {d26[0]}, [ip], r1
++1:
++ lsls lr, #2 @ b30 (Q0a) -> C, b29 (P0a) -> N & b31
++ bcs 1f
++ @ Q0a
++ vst1.32 {d21[1]}, [r0], r1
++ vst1.32 {d21[0]}, [r2], r1
++ vst1.32 {d20[1]}, [r0]
++ vst1.32 {d20[0]}, [r2]
++1:
++ it mi
++ popmi {pc}
++ @ P0a
++ vst1.32 {d19[1]}, [r3], r1
++ vst1.32 {d19[0]}, [ip], r1
++ vst1.32 {d18[1]}, [r3]
++ vst1.32 {d18[0]}, [ip]
++ pop {pc}
++
++@ Single lump (rather than double)
++10:
++ @ As we have post inced r0/r3 in the load the easiest thing to do is
++ @ to subtract and write forwards, rather than backwards (as above)
++ @ b0 (P0a) -> N, b1 (Q0a) -> C
++
++ hevc_loop_filter_uv_body1_16 q8, q9, q10, q11, \bit_depth, \
++ "ldr lr, [sp, #4]", \
++ "add r3, #4", \
++ "sub r0, r0, r1, lsl #2", \
++ "sub r3, r3, r1, lsl #2", \
++ "lsls lr, #31", \
++ "add r2, r0, r1", \
++ "add ip, r3, r1", \
++ "lsl r1, #1"
++
++ bcs 3f
++ @ Q0a
++ vst1.32 {d20[0]}, [r0], r1
++ vst1.32 {d20[1]}, [r2], r1
++ vst1.32 {d21[0]}, [r0]
++ vst1.32 {d21[1]}, [r2]
++3:
++ it mi
++ popmi {pc}
++ @ P0a
++ vst1.32 {d18[0]}, [r3], r1
++ vst1.32 {d18[1]}, [ip], r1
++ vst1.32 {d19[0]}, [r3]
++ vst1.32 {d19[1]}, [ip]
++ pop {pc}
++.endm
++
++
++@ The NEON version is faster under ideal circumstances (i.e. everything in L1)
++@ But in real world testing it is ~20% slower, presumably due to code size
++
++#if 0 // NEON version
++
++/* uint32_t ff_hevc_rpi_deblocking_boundary_strengths_neon(int pus, int dup, const HEVCRpiMvField *curr, const HEVCRpiMvField *neigh,
++ * const int *curr_rpl0, const int *curr_rpl1, const int *neigh_rpl0, const int *neigh_rpl1,
++ * int in_inc0, int in_inc1)
++ */
++function ff_hevc_rpi_deblocking_boundary_strengths_neon, export=1
++ mov ip, sp
++ push {a1-a3,v1-v8,lr}
++ ldm ip, {v1-v6}
++ cmp a1, #2
++ bls 2f
++ vpush {d8-d13}
++ sub v5, v5, #10
++ sub v6, v6, #10
++1:
++ vld2.32 {d0[0], d2[0]}, [a3]!
++ vld2.32 {d4[0], d6[0]}, [a4]!
++ vmov.u8 q12, #0
++ ldrb a2, [a3], #1
++ ldrb ip, [a4], #1
++ ldrb v8, [a3], #1
++ ldrb lr, [a4], #1
++ add a2, v1, a2, lsl #2
++ vld1.8 {d24[0]}, [a3], v5
++ add ip, v3, ip, lsl #2
++ vld1.8 {d25[0]}, [a4], v6
++ add v8, v2, v8, lsl #2
++ vld1.32 {d16[0]}, [a2]
++ add lr, v4, lr, lsl #2
++ vld1.32 {d20[0]}, [ip]
++ vld1.32 {d18[0]}, [v8]
++ vld1.32 {d22[0]}, [lr]
++
++ vld2.32 {d0[1], d2[1]}, [a3]!
++ vld2.32 {d4[1], d6[1]}, [a4]!
++ ldrb a2, [a3], #1
++ vmov.u16 d12, #1
++ ldrb ip, [a4], #1
++ vmov.u16 d13, #2
++ ldrb v8, [a3], #1
++ vmov.u16 d27, #4
++ ldrb lr, [a4], #1
++ add a2, v1, a2, lsl #2
++ vld1.8 {d24[2]}, [a3], v5
++ add ip, v3, ip, lsl #2
++ vld1.8 {d25[2]}, [a4], v6
++ add v8, v2, v8, lsl #2
++ vld1.32 {d16[1]}, [a2]
++ add lr, v4, lr, lsl #2
++ vld1.32 {d20[1]}, [ip]
++ vld1.32 {d18[1]}, [v8]
++ vld1.32 {d22[1]}, [lr]
++
++ vld2.32 {d1[0], d3[0]}, [a3]!
++ vld2.32 {d5[0], d7[0]}, [a4]!
++ ldrb a2, [a3], #1
++ ldrb ip, [a4], #1
++ ldrb lr, [a4], #1
++ ldrb v8, [a3], #1
++ add a2, v1, a2, lsl #2
++ vld1.8 {d24[4]}, [a3], v5
++ add ip, v3, ip, lsl #2
++ vld1.8 {d25[4]}, [a4], v6
++ add v8, v2, v8, lsl #2
++ vld1.32 {d17[0]}, [a2]
++ add lr, v4, lr, lsl #2
++ vld1.32 {d21[0]}, [ip]
++ vld1.32 {d19[0]}, [v8]
++ vld1.32 {d23[0]}, [lr]
++
++ vld2.32 {d1[1], d3[1]}, [a3]!
++ vld2.32 {d5[1], d7[1]}, [a4]!
++ ldrb a2, [a3], #1
++ ldrb ip, [a4], #1
++ ldrb v8, [a3], #1
++ ldrb lr, [a4], #1
++ add a2, v1, a2, lsl #2
++ vld1.8 {d24[6]}, [a3], v5
++ add ip, v3, ip, lsl #2
++ vld1.8 {d25[6]}, [a4], v6
++ add v8, v2, v8, lsl #2
++ vld1.32 {d17[1]}, [a2]
++ add lr, v4, lr, lsl #2
++ vld1.32 {d21[1]}, [ip]
++ vld1.32 {d19[1]}, [v8]
++ vld1.32 {d23[1]}, [lr]
++
++ @ So now we have:
++ @ q0.32[i] = curr[i].mv[0]
++ @ q1.32[i] = curr[i].mv[1]
++ @ q2.32[i] = neigh[i].mv[0]
++ @ q3.32[i] = neigh[i].mv[1]
++ @ q8.32[i] = curr_rpl0[curr[i].ref_idx[0]]
++ @ q9.32[i] = curr_rpl1[curr[i].ref_idx[1]]
++ @ q10.32[i] = neigh_rpl0[neigh[i].ref_idx[0]]
++ @ q11.32[i] = neigh_rpl1[neigh[i].ref_idx[1]]
++ @ d24.16[i] = curr[i].pred_flag
++ @ d25.16[i] = neigh[i].pred_flag
++
++ vtst.16 d28, d24, d12
++ vtst.16 d29, d24, d13
++ vadd.i16 d8, d24, d12
++ vadd.i16 d9, d25, d12
++ vtst.16 d30, d25, d12
++ vtst.16 d31, d25, d13
++ veor d26, d8, d9
++ ldr lr, [sp, 6*8 + 1*4]
++ vmovl.s16 q4, d28
++ vmovl.s16 q5, d29
++ teq lr, #1
++ vmovl.s16 q14, d30
++ it ne
++ lslne v1, lr, #1
++ vmovl.s16 q15, d31
++ it ne
++ rsbne v2, v1, #32
++ vbif q0, q1, q4
++ vbif q2, q3, q14
++ vbif q1, q0, q5
++ vbif q3, q2, q15
++ vabd.s16 q12, q0, q2
++ vabd.s16 q2, q1
++ vabd.s16 q0, q3
++ vabd.s16 q1, q3
++ vbif q8, q9, q4
++ vbif q10, q11, q14
++ vbif q9, q8, q5
++ vbif q11, q10, q15
++ vclt.u16 d6, d24, d27
++ vclt.u16 d8, d2, d27
++ vclt.u16 d7, d25, d27
++ vclt.u16 d9, d3, d27
++ vclt.u16 d2, d0, d27
++ vclt.u16 d0, d4, d27
++ vclt.u16 d3, d1, d27
++ vclt.u16 d1, d5, d27
++ vceq.i32 q12, q10, q8
++ vceq.i32 q10, q9
++ vceq.i32 q8, q11
++ vceq.i32 q9, q11
++ vshrn.i32 d6, q3, #8
++ vshrn.i32 d7, q4, #8
++ vshrn.i32 d8, q1, #8
++ vshrn.i32 d9, q0, #8
++ vmovn.i32 d4, q12
++ vmovn.i32 d2, q10
++ vmovn.i32 d3, q8
++ vmovn.i32 d5, q9
++ vand q2, q3
++ vrev16.8 q3, q3
++ vand q2, q3
++ vand q1, q4
++ vrev16.8 q4, q4
++ vand q1, q4
++ vand d4, d5
++ vand d2, d3
++ vbic d0, d12, d4
++ vshr.u16 d26, #2
++ vbic d0, d2
++ vmov.i16 d1, #0x5555
++ vorr d0, d26
++ bne 10f
++
++ @ Merge results into result word, no duplicates
++ vmov a2, s0
++ vmov v8, s1
++ vmov.u16 ip, d0[1]
++ vmov.u16 lr, d0[3]
++ lsl a2, #30
++ lsl v8, #30
++ lsl ip, #30
++ lsl lr, #30
++ orr a2, ip, a2, lsr #2
++ orr v8, lr, v8, lsr #2
++ orr a2, v8, a2, lsr #4
++ subs a1, #4
++ orr v7, a2, v7, lsr #8
++ bhi 1b
++
++ mov a1, #32
++ ldr a3, [sp, #6*8]
++ vpop {d8-d13}
++ sub a1, a1, a3, lsl #1
++ mov a1, v7, lsr a1
++ pop {a2-a4,v1-v8,pc}
++10:
++ @ Merge results into result word, with duplicates
++ vmul.i16 d0, d1
++ vmov a2, s0
++ vmov v8, s1
++ vmov.u16 ip, d0[1]
++ vmov.u16 lr, d0[3]
++ lsl a2, v2
++ subs a1, #4
++ lsl v8, v2
++ lsl ip, v2
++ lsl lr, v2
++ ldr v2, [sp, #6*8 + 12*4 + 1*4]
++T lsr a2, v1
++T orr a2, ip, a2
++A orr a2, ip, a2, lsr v1
++ lsl ip, v1, #1
++T lsr v8, v1
++T orr v8, lr, v8
++A orr v8, lr, v8, lsr v1
++ lsl lr, v1, #2
++T lsr a2, ip
++T orr a2, v8, a2
++A orr a2, v8, a2, lsr ip
++ ldr v1, [sp, #6*8 + 12*4]
++T lsr v7, lr
++T orr v7, a2, v7
++A orr v7, a2, v7, lsr lr
++ bhi 1b
++
++ mov a1, #32
++ ldrd a3, a4, [sp, #6*8]
++ vpop {d8-d13}
++ mls a1, a3, a4, a1
++ mls a1, a3, a4, a1
++ mov a1, v7, lsr a1
++ pop {a2-a4,v1-v8,pc}
++
++
++2:
++ sub v5, v5, #10
++ sub v6, v6, #10
++ vmov.u8 d16, #0
++ blo 3f
++ vld2.32 {d0[0], d1[0]}, [a3]!
++ vld2.32 {d2[0], d3[0]}, [a4]!
++ ldrb a2, [a3], #1
++ ldrb ip, [a4], #1
++ ldrb lr, [a4], #1
++ ldrb v8, [a3], #1
++ add a2, v1, a2, lsl #2
++ vld1.8 {d16[0]}, [a3], v5
++ add ip, v3, ip, lsl #2
++ vld1.8 {d16[4]}, [a4], v6
++ add v8, v2, v8, lsl #2
++ vld1.32 {d4[0]}, [a2]
++ add lr, v4, lr, lsl #2
++ vld1.32 {d5[0]}, [ip]
++ vld1.32 {d6[0]}, [v8]
++ vld1.32 {d7[0]}, [lr]
++
++3:
++ vld2.32 {d0[1], d1[1]}, [a3]!
++ vld2.32 {d2[1], d3[1]}, [a4]!
++ ldrb a2, [a3], #1
++ vmov.u16 d17, #1
++ ldrb ip, [a4], #1
++ vmov.u16 d18, #2
++ ldrb v8, [a3], #1
++ vmov.u16 d19, #4
++ ldrb lr, [a4], #1
++ add a2, v1, a2, lsl #2
++ vld1.8 {d16[2]}, [a3], v5
++ add ip, v3, ip, lsl #2
++ vld1.8 {d16[6]}, [a4], v6
++ add v8, v2, v8, lsl #2
++ vld1.32 {d4[1]}, [a2]
++ add lr, v4, lr, lsl #2
++ vld1.32 {d5[1]}, [ip]
++ vld1.32 {d6[1]}, [v8]
++ vld1.32 {d7[1]}, [lr]
++
++ @ So now we have:
++ @ d0.32[i] = curr[i].mv[0]
++ @ d1.32[i] = curr[i].mv[1]
++ @ d2.32[i] = neigh[i].mv[0]
++ @ d3.32[i] = neigh[i].mv[1]
++ @ d4.32[i] = curr_rpl0[curr[i].ref_idx[0]]
++ @ d5.32[i] = neigh_rpl0[neigh[i].ref_idx[0]]
++ @ d6.32[i] = curr_rpl1[curr[i].ref_idx[1]]
++ @ d7.32[i] = neigh_rpl1[neigh[i].ref_idx[1]]
++ @ d16.16[i] = curr[i].pred_flag
++ @ d16.16[2+i] = neigh[i].pred_flag
++
++ vtst.16 d20, d16, d17
++ vtst.16 d22, d16, d18
++ vadd.i16 d30, d16, d17
++ vswp d2, d3
++ ldr lr, [sp, #1*4]
++ vmovl.s16 q10, d20
++ teq lr, #1
++ vmovl.s16 q11, d22
++ it ne
++ lslne v1, lr, #1
++ vbif d0, d1, d20
++ vbif d4, d6, d20
++ vbif d3, d2, d21
++ vbif d5, d7, d21
++ vbif d1, d0, d22
++ vbif d6, d4, d22
++ vbif d2, d3, d23
++ vbif d7, d5, d23
++ vshr.u16 d30, #2
++ vabd.s16 d24, d0, d3
++ vabd.s16 d25, d1, d2
++ vabd.s16 q0, q0, q1
++ vceq.i32 d2, d4, d5
++ vceq.i32 d20, d5, d6
++ vceq.i32 d21, d4, d7
++ vceq.i32 d3, d6, d7
++ vclt.u16 d6, d24, d19
++ vclt.u16 d7, d25, d19
++ vclt.u16 d22, d1, d19
++ vclt.u16 d23, d0, d19
++ vshrn.i32 d6, q3, #8
++ vmovn.i32 d2, q1
++ vshrn.i32 d7, q11, #8
++ vmovn.i32 d3, q10
++ vand q0, q3, q1
++ it ne
++ rsbne v2, v1, #32
++ vrev16.8 q3, q3
++ vand q0, q3
++ vsra.u64 d30, #32
++ vshr.u64 q1, q0, #32
++ vand q0, q1
++ vbic d0, d17, d0
++ vand d30, d30, d17
++ vbic d0, d1
++ vmov.i16 d1, #0x5555
++ vorr d0, d30
++ bne 10f
++
++ @ Construct result word, no duplicates
++ cmp a1, #2
++ vmov.u16 a1, d0[1]
++ vmov.u16 a2, d0[0]
++ it eq
++ orreq a1, a2, a1, lsl #2
++ pop {a2-a4,v1-v8,pc}
++10:
++ @ Construct result word, with duplicates
++ cmp a1, #2
++ vmul.i16 d0, d1
++ vmov a2, s0
++ vmov.u16 a1, d0[1]
++ lsl a2, #16
++ pkhbt a1, a1, a1, lsl #16
++ lsr a2, v2
++ lsr a1, v2
++T itt eq
++T lsleq a1, v1
++T orreq a1, a2, a1
++A orreq a1, a2, a1, lsl v1
++ pop {a2-a4,v1-v8,pc}
++endfunc
++
++
++
++#else // non-NEON version
++
++
++/* uint32_t ff_hevc_rpi_deblocking_boundary_strengths_neon(int pus, int dup, const HEVCRpiMvField *curr, const HEVCRpiMvField *neigh,
++ * const int *curr_rpl0, const int *curr_rpl1, const int *neigh_rpl0, const int *neigh_rpl1,
++ * int in_inc0, in_inc1)
++ */
++function ff_hevc_rpi_deblocking_boundary_strengths_neon, export=1
++ add ip, sp, #4*4
++ push {a2-a4,v1-v8,lr}
++ mov v6, #32
++1: ldmdb ip, {v1-v4}
++ ldrsb v5, [a3, #8] @ curr->ref_idx
++ ldrsb v8, [a3, #9]
++ ldrsb ip, [a4, #8] @ neigh->ref_idx
++ ldrsb lr, [a4, #9]
++ ldr v1, [v1, v5, lsl #2]
++ ldrb v5, [a3, #10] @ curr->pred_flag
++ ldr v2, [v2, v8, lsl #2]
++ ldrb v8, [a4, #10] @ neigh->pred_flag
++ ldr v3, [v3, ip, lsl #2]
++ ldr v4, [v4, lr, lsl #2]
++ teq v5, #3
++ beq 20f
++ teq v8, #3
++ beq 90f
++
++ tst v5, #1
++ itee ne
++ ldrne v5, [a3, #0] @ curr->mv[0]
++ moveq v1, v2
++ ldreq v5, [a3, #4] @ curr->mv[1]
++ tst v8, #1
++ itee ne
++ ldrne v8, [a4, #0] @ neigh->mv[0]
++ moveq v3, v4
++ ldreq v8, [a4, #4] @ neigh->mv[1]
++ teq v1, v3
++ bne 10f
++ ldr lr, =0xFFFCFFFC
++ ssub16 ip, v8, v5
++ ssub16 v5, v5, v8
++ sel v5, v5, ip
++ ands v5, v5, lr
++ @ drop through
++10: it ne
++ movne v5, #1<<30
++11:
++ sub v6, v6, #2
++T mov v7, v7, lsr #2
++ subs a2, a2, #1
++A orr v7, v5, v7, lsr #2
++T orr v7, v5, v7
++ bhi 11b
++
++ ldrd v3, v4, [sp, #16*4]
++ ldr a2, [sp]
++ add ip, sp, #16*4
++ subs a1, a1, #1
++ add a3, a3, v3
++ add a4, a4, v4
++ bhi 1b
++ mov a1, v7, lsr v6
++ pop {a2-a4,v1-v8,pc}
++
++20: teq v8, #3
++ bne 10b
++
++ teq v1, v3
++ it eq
++ teqeq v2, v4
++ bne 40f
++ teq v1, v2
++ bne 30f
++
++ ldrd v1, v2, [a3] @ curr->mv
++ ldrd v3, v4, [a4] @ neigh->mv
++ ldr lr, =0xFFFCFFFC
++ ssub16 ip, v3, v1
++ ssub16 v5, v1, v3
++ sel v5, v5, ip
++ ands v5, v5, lr
++ bne 25f
++ ssub16 ip, v4, v2
++ ssub16 v5, v2, v4
++ sel v5, v5, ip
++ ands v5, v5, lr
++ beq 11b
++ @ drop through
++25: ssub16 ip, v4, v1
++ ssub16 v5, v1, v4
++ sel v5, v5, ip
++ ands v5, v5, lr
++ bne 10b
++ ssub16 ip, v3, v2
++ ssub16 v5, v2, v3
++ sel v5, v5, ip
++ ands v5, v5, lr
++ b 10b
++
++30: ldrd v1, v2, [a3] @ curr->mv
++ ldrd v3, v4, [a4] @ neigh->mv
++ ldr lr, =0xFFFCFFFC
++ ssub16 ip, v3, v1
++ ssub16 v5, v1, v3
++ sel v5, v5, ip
++ ands v5, v5, lr
++ bne 10b
++ ssub16 ip, v4, v2
++ ssub16 v5, v2, v4
++ sel v5, v5, ip
++ ands v5, v5, lr
++ b 10b
++
++40: teq v1, v4
++ ite eq
++ teqeq v2, v3
++ bne 10b
++
++ ldrd v1, v2, [a3] @ curr->mv
++ ldrd v3, v4, [a4] @ neigh->mv
++ ldr lr, =0xFFFCFFFC
++ b 25b
++
++90:
++ mov v5, #1<<30
++ b 11b
++endfunc
++
++
++#endif
++
++
++@ =============================================================================
++@
++@ 10 bit
++
++function hevc_loop_filter_luma_body_10
++ m_filter_luma 10, q11, q15
++endfunc
++
++function ff_hevc_rpi_h_loop_filter_luma_neon_10, export=1
++ hevc_loop_filter_luma_start
++ b .Lh_loop_luma_common_10
++endfunc
++
++function ff_hevc_rpi_h_loop_filter_luma2_neon_10, export=1
++ cmp r3, #0
++ it eq
++ bxeq lr
++ push {r4-r10,lr} @ 32 bytes
++ ldr r10, [sp, #32]
++.Lh_loop_luma_common_10:
++ m_filter_h_luma_16 10
++endfunc
++
++function ff_hevc_rpi_v_loop_filter_luma_neon_10, export=1
++ hevc_loop_filter_luma_start
++ sub r4, r0, #8
++ b .Lv_loop_luma_common_10
++endfunc
++
++function ff_hevc_rpi_v_loop_filter_luma2_neon_10, export=1
++ cmp r3, #0
++ it eq
++ bxeq lr
++ push {r4-r10,lr} @ 32 bytes
++ ldr r4, [sp, #36]
++ ldr r10, [sp, #32]
++
++.Lv_loop_luma_common_10:
++ m_filter_v_luma_16 10
++endfunc
++
++function ff_hevc_rpi_h_loop_filter_uv_neon_10, export=1
++ m_filter_h_uv_16 10
++endfunc
++
++function ff_hevc_rpi_v_loop_filter_uv2_neon_10, export=1
++ m_filter_v_uv2_16 10
++endfunc
++
+diff --git a/libavcodec/arm/rpi_hevcdsp_idct_neon.S b/libavcodec/arm/rpi_hevcdsp_idct_neon.S
+new file mode 100644
+index 0000000000..db10da16d3
+--- /dev/null
++++ b/libavcodec/arm/rpi_hevcdsp_idct_neon.S
+@@ -0,0 +1,183 @@
++/*
++ * Copyright (c) 2014 Seppo Tomperi <seppo.tomperi@vtt.fi>
++ *
++ * This file is part of FFmpeg.
++ *
++ * FFmpeg is free software; you can redistribute it and/or
++ * modify it under the terms of the GNU Lesser General Public
++ * License as published by the Free Software Foundation; either
++ * version 2.1 of the License, or (at your option) any later version.
++ *
++ * FFmpeg is distributed in the hope that it will be useful,
++ * but WITHOUT ANY WARRANTY; without even the implied warranty of
++ * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
++ * Lesser General Public License for more details.
++ *
++ * You should have received a copy of the GNU Lesser General Public
++ * License along with FFmpeg; if not, write to the Free Software
++ * Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA
++ */
++
++#include "libavutil/arm/asm.S"
++#include "neon.S"
++
++/* uses registers q8 - q13 for temp values */
++.macro tr4_luma_shift shift
++ vaddl.s16 q8, d28, d30 // c0 = src0 + src2
++ vaddl.s16 q9, d30, d31 // c1 = src2 + src3
++ vsubl.s16 q10, d28, d31 // c2 = src0 - src3
++ vaddl.s16 q11, d28, d31 // src0 + src3
++
++ vmul.i32 q12, q8, d1[0] // 29 * c0
++ vmul.i32 q13, q10, d2[0] // 55 * c2
++ vmul.i32 q8, q8, d2[0] // 55 * c0
++ vmull.s16 q14, d29, d0[0] // c3 = 74 * src1
++
++ vsubw.s16 q11, q11, d30 // src0 - src2 + src3
++ vmla.i32 q12, q9, d2[0] // 29 * c0 + 55 * c1
++ vmls.i32 q13, q9, d1[0] // 55 * c2 - 29 * c1
++ vmla.i32 q8, q10, d1[0] // 55 * c0 + 29 * c2
++
++ vmul.i32 q11, q11, d0[0] // dst2 = 74 * (src0 - src2 + src3)
++ vadd.i32 q12, q12, q14 // dst0 = 29 * c0 + 55 * c1 + c3
++ vadd.i32 q13, q13, q14 // dst1 = 55 * c2 - 29 * c1 + c3
++ vsub.i32 q8, q8, q14 // dst3 = 55 * c0 + 29 * c2 - c3
++
++ vqrshrn.s32 d28, q12, \shift
++ vqrshrn.s32 d29, q13, \shift
++ vqrshrn.s32 d30, q11, \shift
++ vqrshrn.s32 d31, q8, \shift
++.endm
++
++/* uses registers q8 - q11 for temp values */
++.macro tr4_shift shift
++ vmull.s16 q9, d29, d0[0] // 83 * src1
++ vmull.s16 q8, d29, d0[1] // 36 * src1
++ vshll.s16 q14, d28, #6 // 64 * src0
++ vshll.s16 q10, d30, #6 // 64 * src2
++ vmlal.s16 q9, d31, d0[1] // 83 * src1 + 36 * src3 o0
++ vmlsl.s16 q8, d31, d0[0] // 36 * src1 - 83 * src3 o1
++ vadd.s32 q11, q14, q10 // 64 * (src0 + src2) e0
++ vsub.s32 q10, q14, q10 // 64 * (src0 - src2) e1
++ vadd.s32 q14, q11, q9 // e0 + o0
++ vadd.s32 q15, q10, q8 // e1 + o1
++ vsub.s32 q8, q10, q8 // e1 - o1
++ vsub.s32 q9, q11, q9 // e0 - o0
++
++ vqrshrn.s32 d28, q14, \shift
++ vqrshrn.s32 d29, q15, \shift
++ vqrshrn.s32 d30, q8, \shift
++ vqrshrn.s32 d31, q9, \shift
++.endm
++
++.macro tr8_process d0, d1, d2, d3, d4, d5, d6, d7, \
++ tmp0, /* Q reg which doesn't alias with d4, d6 or d7 */ \
++ tmp1, /* Q reg which doesn't alias with d7 or d0 */ \
++ shift, I1, I2, I3
++
++ vmull.s16 q4, \d1, d1[1] // 89 * src1
++ \I1
++ vmull.s16 q5, \d1, d1[0] // 75 * src1
++ \I2
++ vmull.s16 q6, \d1, d1[3] // 50 * src1
++ \I3
++ vmull.s16 q7, \d1, d1[2] // 18 * src1
++ vmlal.s16 q4, \d3, d1[0] // 75 * src3
++ vmlsl.s16 q5, \d3, d1[2] //-18 * src3
++ vmlsl.s16 q6, \d3, d1[1] //-89 * src3
++ vmlsl.s16 q7, \d3, d1[3] //-50 * src3
++
++ // tr4
++ vmull.s16 q1, \d2, d0[0] // 83 * src(1*2)
++ vmull.s16 q2, \d2, d0[1] // 36 * src(1*2)
++
++ vmlal.s16 q4, \d5, d1[3] // 50 * src5
++ vmlsl.s16 q5, \d5, d1[1] //-89 * src5
++ vmlal.s16 q6, \d5, d1[2] // 18 * src5
++ vmlal.s16 q7, \d5, d1[0] // 75 * src5
++
++ vshll.s16 q3, \d0, #6 // 64 * src(0*2)
++ vshll.s16 \tmp0, \d4, #6 // 64 * src(2*2)
++ vmlal.s16 q1, \d6, d0[1] // 83 * src(1*2) + 36 * src(3*2) o0
++ vmlsl.s16 q2, \d6, d0[0] // 36 * src(1*2) - 83 * src(3*2) o1
++ vadd.i32 \tmp1, q3, \tmp0 // 64 * (src(0*2) + src(2*2)) e0
++ vsub.i32 \tmp0, q3, \tmp0 // 64 * (src(0*2) - src(2*2)) e1
++
++ vmlal.s16 q4, \d7, d1[2] // 18 * src7
++ vmlsl.s16 q5, \d7, d1[3] //-50 * src7
++ vmlal.s16 q6, \d7, d1[0] // 75 * src7
++ vmlsl.s16 q7, \d7, d1[1] //-89 * src7
++
++ vsub.i32 q3, \tmp1, q1 // e0 - o0
++ vadd.i32 \tmp1, \tmp1, q1 // e0 + o0
++ vadd.i32 q1, \tmp0, q2 // e1 + o1
++ vsub.i32 q2, \tmp0, q2 // e1 - o1
++
++ vadd.i32 \tmp0, \tmp1, q4 // e_8[0] + o_8[0], dst[0]
++ vsub.i32 q4, \tmp1, q4 // e_8[0] - o_8[0], dst[7]
++ vsub.i32 \tmp1, q3, q7 // e_8[3] - o_8[3], dst[4]
++ vadd.i32 q7, q3, q7 // e_8[3] + o_8[3], dst[3]
++ vadd.i32 q3, q1, q5 // e_8[1] + o_8[1], dst[1]
++ vsub.i32 q5, q1, q5 // e_8[1] - o_8[1], dst[6]
++ vsub.i32 q1, q2, q6 // e_8[2] - o_8[2], dst[5]
++ vadd.i32 q6, q2, q6 // e_8[2] + o_8[2], dst[2]
++ vqrshrn.s32 \d0, \tmp0, #\shift
++ vqrshrn.s32 \d4, \tmp1, #\shift
++ vqrshrn.s32 \d1, q3, #\shift
++ vqrshrn.s32 \d5, q1, #\shift
++ vqrshrn.s32 \d2, q6, #\shift
++ vqrshrn.s32 \d6, q5, #\shift
++ vqrshrn.s32 \d3, q7, #\shift
++ vqrshrn.s32 \d7, q4, #\shift
++.endm
++
++.macro tr8_vert d0, d1, d2, d3, d4, d5, d6, d7, q01, q23, I1, I2, I3
++ vld1.16 {\d0}, [r0 :64], r3
++ vld1.16 {\d1}, [r2 :64], r3
++ vld1.16 {\d2}, [r0 :64], r3
++ vld1.16 {\d3}, [r2 :64], r3
++ vld1.16 {\d4}, [r0 :64], r3
++ vld1.16 {\d5}, [r2 :64], r3
++ vld1.16 {\d6}, [r0 :64], r3
++ vld1.16 {\d7}, [r2 :64], r3
++
++ tr8_process \
++ \d0, \d1, \d2, \d3, \d4, \d5, \d6, \d7, \
++ \q01, \q23, 7, "\I1", "\I2", "\I3"
++.endm
++
++.macro tr8_horiz d0, d1, d2, d3, d4, d5, d6, d7, q01, q23, shift
++ tr8_process \
++ \d0, \d1, \d2, \d3, \d4, \d5, \d6, \d7, \
++ \q01, \q23, \shift
++
++ vzip.16 \d0, \d4
++ vzip.16 \d1, \d5
++ vzip.16 \d2, \d6
++ vzip.16 \d3, \d7
++ vst4.16 {\d0-\d3}, [r0 :128], r3
++ vst4.16 {\d4-\d7}, [r2 :128], r3
++.endm
++
++#define BIT_DEPTH 8
++#include "rpi_hevc_idct_fn_neon.S"
++
++.text
++
++.align 4
++tr4f:
++.word 0x00240053 // 36 and d1[0] = 83
++.word 0x00000000
++tr8f:
++.word 0x0059004b // 89, d0[0] = 75
++.word 0x00320012 // 50, d0[2] = 18
++tr16:
++.word 0x005a0057 // 90, d2[0] = 87
++.word 0x00500046 // 80, d2[2] = 70
++.word 0x0039002b // 57, d2[0] = 43
++.word 0x00190009 // 25, d2[2] = 9
++
++#undef BIT_DEPTH
++#define BIT_DEPTH 10
++#include "rpi_hevc_idct_fn_neon.S"
++
+diff --git a/libavcodec/arm/rpi_hevcdsp_init_arm.c b/libavcodec/arm/rpi_hevcdsp_init_arm.c
+new file mode 100644
+index 0000000000..109fa98c29
+--- /dev/null
++++ b/libavcodec/arm/rpi_hevcdsp_init_arm.c
+@@ -0,0 +1,32 @@
++/*
++ * Copyright (c) 2014 Seppo Tomperi <seppo.tomperi@vtt.fi>
++ *
++ * This file is part of FFmpeg.
++ *
++ * FFmpeg is free software; you can redistribute it and/or
++ * modify it under the terms of the GNU Lesser General Public
++ * License as published by the Free Software Foundation; either
++ * version 2.1 of the License, or (at your option) any later version.
++ *
++ * FFmpeg is distributed in the hope that it will be useful,
++ * but WITHOUT ANY WARRANTY; without even the implied warranty of
++ * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
++ * Lesser General Public License for more details.
++ *
++ * You should have received a copy of the GNU Lesser General Public
++ * License along with FFmpeg; if not, write to the Free Software
++ * Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA
++ */
++
++#include "libavutil/attributes.h"
++#include "libavutil/arm/cpu.h"
++#include "libavcodec/rpi_hevcdsp.h"
++#include "rpi_hevcdsp_arm.h"
++
++av_cold void ff_hevcdsp_rpi_init_arm(HEVCDSPContext *c, const int bit_depth)
++{
++ int cpu_flags = av_get_cpu_flags();
++
++ if (have_neon(cpu_flags))
++ ff_hevcdsp_rpi_init_neon(c, bit_depth);
++}
+diff --git a/libavcodec/arm/rpi_hevcdsp_init_neon.c b/libavcodec/arm/rpi_hevcdsp_init_neon.c
+new file mode 100644
+index 0000000000..9294ab8010
+--- /dev/null
++++ b/libavcodec/arm/rpi_hevcdsp_init_neon.c
+@@ -0,0 +1,467 @@
++/*
++ * Copyright (c) 2014 Seppo Tomperi <seppo.tomperi@vtt.fi>
++ *
++ * This file is part of FFmpeg.
++ *
++ * FFmpeg is free software; you can redistribute it and/or
++ * modify it under the terms of the GNU Lesser General Public
++ * License as published by the Free Software Foundation; either
++ * version 2.1 of the License, or (at your option) any later version.
++ *
++ * FFmpeg is distributed in the hope that it will be useful,
++ * but WITHOUT ANY WARRANTY; without even the implied warranty of
++ * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
++ * Lesser General Public License for more details.
++ *
++ * You should have received a copy of the GNU Lesser General Public
++ * License along with FFmpeg; if not, write to the Free Software
++ * Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA
++ */
++
++#include "config.h"
++#include "libavutil/attributes.h"
++#include "libavutil/arm/cpu.h"
++#include "libavcodec/rpi_hevcdsp.h"
++#include "rpi_hevcdsp_arm.h"
++#include "libavcodec/avcodec.h"
++#include "libavcodec/bit_depth_template.c"
++
++// NEON inter pred fns for qpel & epel (non-sand) exist in the git repo but
++// have been removed from head as we never use them.
++
++void ff_hevc_rpi_v_loop_filter_luma_neon_8(uint8_t *_pix, ptrdiff_t _stride, int _beta, int *_tc, uint8_t *_no_p, uint8_t *_no_q);
++void ff_hevc_rpi_h_loop_filter_luma_neon_8(uint8_t *_pix, ptrdiff_t _stride, int _beta, int *_tc, uint8_t *_no_p, uint8_t *_no_q);
++
++void ff_hevc_rpi_v_loop_filter_luma_neon_10(uint8_t *_pix, ptrdiff_t _stride, int _beta, int *_tc, uint8_t *_no_p, uint8_t *_no_q);
++void ff_hevc_rpi_h_loop_filter_luma_neon_10(uint8_t *_pix, ptrdiff_t _stride, int _beta, int *_tc, uint8_t *_no_p, uint8_t *_no_q);
++
++void ff_hevc_rpi_h_loop_filter_luma2_neon_8(uint8_t * _pix_r,
++ unsigned int _stride, unsigned int beta, unsigned int tc2, unsigned int no_f);
++void ff_hevc_rpi_v_loop_filter_luma2_neon_8(uint8_t * _pix_r,
++ unsigned int _stride, unsigned int beta, unsigned int tc2, unsigned int no_f,
++ uint8_t * _pix_l);
++void ff_hevc_rpi_h_loop_filter_uv_neon_8(uint8_t * src, unsigned int stride, uint32_t tc4,
++ unsigned int no_f);
++void ff_hevc_rpi_v_loop_filter_uv2_neon_8(uint8_t * src_r, unsigned int stride, uint32_t tc4,
++ uint8_t * src_l,
++ unsigned int no_f);
++
++void ff_hevc_rpi_h_loop_filter_luma2_neon_10(uint8_t * _pix_r,
++ unsigned int _stride, unsigned int beta, unsigned int tc2, unsigned int no_f);
++void ff_hevc_rpi_v_loop_filter_luma2_neon_10(uint8_t * _pix_r,
++ unsigned int _stride, unsigned int beta, unsigned int tc2, unsigned int no_f,
++ uint8_t * _pix_l);
++void ff_hevc_rpi_h_loop_filter_uv_neon_10(uint8_t * src, unsigned int stride, uint32_t tc4,
++ unsigned int no_f);
++void ff_hevc_rpi_v_loop_filter_uv2_neon_10(uint8_t * src_r, unsigned int stride, uint32_t tc4,
++ uint8_t * src_l,
++ unsigned int no_f);
++
++void ff_hevc_rpi_transform_4x4_neon_8(int16_t *coeffs, int col_limit);
++void ff_hevc_rpi_transform_8x8_neon_8(int16_t *coeffs, int col_limit);
++void ff_hevc_rpi_idct_4x4_dc_neon_8(int16_t *coeffs);
++void ff_hevc_rpi_idct_8x8_dc_neon_8(int16_t *coeffs);
++void ff_hevc_rpi_idct_16x16_dc_neon_8(int16_t *coeffs);
++void ff_hevc_rpi_idct_32x32_dc_neon_8(int16_t *coeffs);
++void ff_hevc_rpi_transform_luma_4x4_neon_8(int16_t *coeffs);
++
++void ff_hevc_rpi_transform_4x4_neon_10(int16_t *coeffs, int col_limit);
++void ff_hevc_rpi_transform_8x8_neon_10(int16_t *coeffs, int col_limit);
++void ff_hevc_rpi_idct_4x4_dc_neon_10(int16_t *coeffs);
++void ff_hevc_rpi_idct_8x8_dc_neon_10(int16_t *coeffs);
++void ff_hevc_rpi_idct_16x16_dc_neon_10(int16_t *coeffs);
++void ff_hevc_rpi_idct_32x32_dc_neon_10(int16_t *coeffs);
++void ff_hevc_rpi_transform_luma_4x4_neon_10(int16_t *coeffs);
++
++void ff_hevc_rpi_add_residual_4x4_neon_8(uint8_t *_dst, int16_t *coeffs,
++ ptrdiff_t stride);
++void ff_hevc_rpi_add_residual_8x8_neon_8(uint8_t *_dst, int16_t *coeffs,
++ ptrdiff_t stride);
++void ff_hevc_rpi_add_residual_16x16_neon_8(uint8_t *_dst, int16_t *coeffs,
++ ptrdiff_t stride);
++void ff_hevc_rpi_add_residual_32x32_neon_8(uint8_t *_dst, int16_t *coeffs,
++ ptrdiff_t stride);
++
++void ff_hevc_rpi_add_residual_4x4_dc_neon_8(uint8_t *_dst, ptrdiff_t stride, int dc);
++void ff_hevc_rpi_add_residual_8x8_dc_neon_8(uint8_t *_dst, ptrdiff_t stride, int dc);
++void ff_hevc_rpi_add_residual_16x16_dc_neon_8(uint8_t *_dst, ptrdiff_t stride, int dc);
++void ff_hevc_rpi_add_residual_32x32_dc_neon_8(uint8_t *_dst, ptrdiff_t stride, int dc);
++
++
++void ff_hevc_rpi_add_residual_4x4_neon_10(uint8_t *_dst, int16_t *coeffs,
++ ptrdiff_t stride);
++void ff_hevc_rpi_add_residual_8x8_neon_10(uint8_t *_dst, int16_t *coeffs,
++ ptrdiff_t stride);
++void ff_hevc_rpi_add_residual_16x16_neon_10(uint8_t *_dst, int16_t *coeffs,
++ ptrdiff_t stride);
++void ff_hevc_rpi_add_residual_32x32_neon_10(uint8_t *_dst, int16_t *coeffs,
++ ptrdiff_t stride);
++
++void ff_hevc_rpi_add_residual_4x4_dc_neon_10(uint8_t *_dst, ptrdiff_t stride, int dc);
++void ff_hevc_rpi_add_residual_8x8_dc_neon_10(uint8_t *_dst, ptrdiff_t stride, int dc);
++void ff_hevc_rpi_add_residual_16x16_dc_neon_10(uint8_t *_dst, ptrdiff_t stride, int dc);
++void ff_hevc_rpi_add_residual_32x32_dc_neon_10(uint8_t *_dst, ptrdiff_t stride, int dc);
++
++
++void ff_hevc_rpi_add_residual_4x4_u_neon_8(uint8_t *_dst, const int16_t * residual,
++ ptrdiff_t stride, int dc_v);
++void ff_hevc_rpi_add_residual_8x8_u_neon_8(uint8_t *_dst, const int16_t * residual,
++ ptrdiff_t stride, int dc_v);
++void ff_hevc_rpi_add_residual_16x16_u_neon_8(uint8_t *_dst, const int16_t * residual,
++ ptrdiff_t stride, int dc_v);
++void ff_hevc_rpi_add_residual_4x4_v_neon_8(uint8_t *_dst, const int16_t * residual,
++ ptrdiff_t stride, int dc_u);
++void ff_hevc_rpi_add_residual_8x8_v_neon_8(uint8_t *_dst, const int16_t * residual,
++ ptrdiff_t stride, int dc_u);
++void ff_hevc_rpi_add_residual_16x16_v_neon_8(uint8_t *_dst, const int16_t * residual,
++ ptrdiff_t stride, int dc_u);
++void ff_hevc_rpi_add_residual_4x4_c_neon_8(uint8_t *_dst, const int16_t * residual,
++ ptrdiff_t stride);
++void ff_hevc_rpi_add_residual_8x8_c_neon_8(uint8_t *_dst, const int16_t * residual,
++ ptrdiff_t stride);
++void ff_hevc_rpi_add_residual_16x16_c_neon_8(uint8_t *_dst, const int16_t * residual,
++ ptrdiff_t stride);
++void ff_hevc_rpi_add_residual_4x4_dc_c_neon_8(uint8_t *_dst, ptrdiff_t stride, int32_t dc);
++void ff_hevc_rpi_add_residual_8x8_dc_c_neon_8(uint8_t *_dst, ptrdiff_t stride, int32_t dc);
++void ff_hevc_rpi_add_residual_16x16_dc_c_neon_8(uint8_t *_dst, ptrdiff_t stride, int32_t dc);
++
++
++void ff_hevc_rpi_add_residual_4x4_u_neon_10(uint8_t *_dst, const int16_t * residual,
++ ptrdiff_t stride, int dc_v);
++void ff_hevc_rpi_add_residual_8x8_u_neon_10(uint8_t *_dst, const int16_t * residual,
++ ptrdiff_t stride, int dc_v);
++void ff_hevc_rpi_add_residual_16x16_u_neon_10(uint8_t *_dst, const int16_t * residual,
++ ptrdiff_t stride, int dc_v);
++void ff_hevc_rpi_add_residual_4x4_v_neon_10(uint8_t *_dst, const int16_t * residual,
++ ptrdiff_t stride, int dc_u);
++void ff_hevc_rpi_add_residual_8x8_v_neon_10(uint8_t *_dst, const int16_t * residual,
++ ptrdiff_t stride, int dc_u);
++void ff_hevc_rpi_add_residual_16x16_v_neon_10(uint8_t *_dst, const int16_t * residual,
++ ptrdiff_t stride, int dc_u);
++void ff_hevc_rpi_add_residual_4x4_c_neon_10(uint8_t *_dst, const int16_t * residual,
++ ptrdiff_t stride);
++void ff_hevc_rpi_add_residual_8x8_c_neon_10(uint8_t *_dst, const int16_t * residual,
++ ptrdiff_t stride);
++void ff_hevc_rpi_add_residual_16x16_c_neon_10(uint8_t *_dst, const int16_t * residual,
++ ptrdiff_t stride);
++void ff_hevc_rpi_add_residual_4x4_dc_c_neon_10(uint8_t *_dst, ptrdiff_t stride, int32_t dc);
++void ff_hevc_rpi_add_residual_8x8_dc_c_neon_10(uint8_t *_dst, ptrdiff_t stride, int32_t dc);
++void ff_hevc_rpi_add_residual_16x16_dc_c_neon_10(uint8_t *_dst, ptrdiff_t stride, int32_t dc);
++
++void ff_hevc_rpi_sao_edge_8_neon_8(uint8_t *_dst, uint8_t *_src, ptrdiff_t stride_dst, int16_t *_sao_offset_val, int eo, int width, int height);
++void ff_hevc_rpi_sao_edge_16_neon_8(uint8_t *_dst, uint8_t *_src, ptrdiff_t stride_dst, int16_t *_sao_offset_val, int eo, int width, int height);
++void ff_hevc_rpi_sao_edge_32_neon_8(uint8_t *_dst, uint8_t *_src, ptrdiff_t stride_dst, int16_t *_sao_offset_val, int eo, int width, int height);
++void ff_hevc_rpi_sao_edge_64_neon_8(uint8_t *_dst, uint8_t *_src, ptrdiff_t stride_dst, int16_t *_sao_offset_val, int eo, int width, int height);
++
++void ff_hevc_rpi_sao_edge_8_neon_10(uint8_t *_dst, uint8_t *_src, ptrdiff_t stride_dst, int16_t *_sao_offset_val, int eo, int width, int height);
++void ff_hevc_rpi_sao_edge_16_neon_10(uint8_t *_dst, uint8_t *_src, ptrdiff_t stride_dst, int16_t *_sao_offset_val, int eo, int width, int height);
++void ff_hevc_rpi_sao_edge_32_neon_10(uint8_t *_dst, uint8_t *_src, ptrdiff_t stride_dst, int16_t *_sao_offset_val, int eo, int width, int height);
++void ff_hevc_rpi_sao_edge_64_neon_10(uint8_t *_dst, uint8_t *_src, ptrdiff_t stride_dst, int16_t *_sao_offset_val, int eo, int width, int height);
++
++void ff_hevc_rpi_sao_edge_c_8_neon_8(uint8_t *_dst, const uint8_t *_src, ptrdiff_t stride_dst,
++ const int16_t *_sao_offset_val_u, const int16_t *_sao_offset_val_v,
++ int eo, int width, int height);
++void ff_hevc_rpi_sao_edge_c_16_neon_8(uint8_t *_dst, const uint8_t *_src, ptrdiff_t stride_dst,
++ const int16_t *_sao_offset_val_u, const int16_t *_sao_offset_val_v,
++ int eo, int width, int height);
++void ff_hevc_rpi_sao_edge_c_32_neon_8(uint8_t *_dst, const uint8_t *_src, ptrdiff_t stride_dst,
++ const int16_t *_sao_offset_val_u, const int16_t *_sao_offset_val_v,
++ int eo, int width, int height);
++
++void ff_hevc_rpi_sao_edge_c_8_neon_10(uint8_t *_dst, const uint8_t *_src, ptrdiff_t stride_dst,
++ const int16_t *_sao_offset_val_u, const int16_t *_sao_offset_val_v,
++ int eo, int width, int height);
++void ff_hevc_rpi_sao_edge_c_16_neon_10(uint8_t *_dst, const uint8_t *_src, ptrdiff_t stride_dst,
++ const int16_t *_sao_offset_val_u, const int16_t *_sao_offset_val_v,
++ int eo, int width, int height);
++void ff_hevc_rpi_sao_edge_c_32_neon_10(uint8_t *_dst, const uint8_t *_src, ptrdiff_t stride_dst,
++ const int16_t *_sao_offset_val_u, const int16_t *_sao_offset_val_v,
++ int eo, int width, int height);
++
++void ff_hevc_rpi_sao_band_c_8_neon_8(uint8_t *_dst, const uint8_t *_src,
++ ptrdiff_t stride_dst, ptrdiff_t stride_src,
++ const int16_t *sao_offset_val_u, int sao_left_class_u,
++ const int16_t *sao_offset_val_v, int sao_left_class_v,
++ int width, int height);
++void ff_hevc_rpi_sao_band_c_16_neon_8(uint8_t *_dst, const uint8_t *_src,
++ ptrdiff_t stride_dst, ptrdiff_t stride_src,
++ const int16_t *sao_offset_val_u, int sao_left_class_u,
++ const int16_t *sao_offset_val_v, int sao_left_class_v,
++ int width, int height);
++void ff_hevc_rpi_sao_band_c_32_neon_8(uint8_t *_dst, const uint8_t *_src,
++ ptrdiff_t stride_dst, ptrdiff_t stride_src,
++ const int16_t *sao_offset_val_u, int sao_left_class_u,
++ const int16_t *sao_offset_val_v, int sao_left_class_v,
++ int width, int height);
++
++void ff_hevc_rpi_sao_band_c_8_neon_10(uint8_t *_dst, const uint8_t *_src,
++ ptrdiff_t stride_dst, ptrdiff_t stride_src,
++ const int16_t *sao_offset_val_u, int sao_left_class_u,
++ const int16_t *sao_offset_val_v, int sao_left_class_v,
++ int width, int height);
++void ff_hevc_rpi_sao_band_c_16_neon_10(uint8_t *_dst, const uint8_t *_src,
++ ptrdiff_t stride_dst, ptrdiff_t stride_src,
++ const int16_t *sao_offset_val_u, int sao_left_class_u,
++ const int16_t *sao_offset_val_v, int sao_left_class_v,
++ int width, int height);
++void ff_hevc_rpi_sao_band_c_32_neon_10(uint8_t *_dst, const uint8_t *_src,
++ ptrdiff_t stride_dst, ptrdiff_t stride_src,
++ const int16_t *sao_offset_val_u, int sao_left_class_u,
++ const int16_t *sao_offset_val_v, int sao_left_class_v,
++ int width, int height);
++
++void ff_hevc_rpi_sao_band_8_neon_8(uint8_t *_dst, uint8_t *_src, ptrdiff_t stride_dst, ptrdiff_t stride_src,
++ int16_t *sao_offset_val, int sao_left_class, int width, int height);
++void ff_hevc_rpi_sao_band_16_neon_8(uint8_t *_dst, uint8_t *_src, ptrdiff_t stride_dst, ptrdiff_t stride_src,
++ int16_t *sao_offset_val, int sao_left_class, int width, int height);
++void ff_hevc_rpi_sao_band_32_neon_8(uint8_t *_dst, uint8_t *_src, ptrdiff_t stride_dst, ptrdiff_t stride_src,
++ int16_t *sao_offset_val, int sao_left_class, int width, int height);
++void ff_hevc_rpi_sao_band_64_neon_8(uint8_t *_dst, uint8_t *_src, ptrdiff_t stride_dst, ptrdiff_t stride_src,
++ int16_t *sao_offset_val, int sao_left_class, int width, int height);
++
++void ff_hevc_rpi_sao_band_8_neon_10(uint8_t *_dst, uint8_t *_src, ptrdiff_t stride_dst, ptrdiff_t stride_src,
++ int16_t *sao_offset_val, int sao_left_class, int width, int height);
++void ff_hevc_rpi_sao_band_16_neon_10(uint8_t *_dst, uint8_t *_src, ptrdiff_t stride_dst, ptrdiff_t stride_src,
++ int16_t *sao_offset_val, int sao_left_class, int width, int height);
++void ff_hevc_rpi_sao_band_32_neon_10(uint8_t *_dst, uint8_t *_src, ptrdiff_t stride_dst, ptrdiff_t stride_src,
++ int16_t *sao_offset_val, int sao_left_class, int width, int height);
++void ff_hevc_rpi_sao_band_64_neon_10(uint8_t *_dst, uint8_t *_src, ptrdiff_t stride_dst, ptrdiff_t stride_src,
++ int16_t *sao_offset_val, int sao_left_class, int width, int height);
++
++
++uint32_t ff_hevc_rpi_deblocking_boundary_strengths_neon(int pus, int dup, const struct HEVCRpiMvField *curr, const struct HEVCRpiMvField *neigh,
++ const int *curr_rpl0, const int *curr_rpl1, const int *neigh_rpl0, const int *neigh_rpl1,
++ int in_inc0, int in_inc1);
++void ff_hevc_rpi_cpy_blks8x4_neon(uint8_t *dst, unsigned int stride_dst, const uint8_t *src, unsigned stride_src, unsigned int width, unsigned int height);
++
++
++static void ff_hevc_rpi_sao_edge_48_neon_8(uint8_t *_dst, uint8_t *_src, ptrdiff_t stride_dst, int16_t *_sao_offset_val, int eo, int width, int height)
++{
++ ff_hevc_rpi_sao_edge_32_neon_8(_dst, _src, stride_dst, _sao_offset_val, eo, 32, height);
++ ff_hevc_rpi_sao_edge_16_neon_8(_dst + 32, _src + 32, stride_dst, _sao_offset_val, eo, 16, height);
++}
++static void ff_hevc_rpi_sao_edge_48_neon_10(uint8_t *_dst, uint8_t *_src, ptrdiff_t stride_dst, int16_t *_sao_offset_val, int eo, int width, int height)
++{
++ ff_hevc_rpi_sao_edge_32_neon_10(_dst, _src, stride_dst, _sao_offset_val, eo, 32, height);
++ ff_hevc_rpi_sao_edge_16_neon_10(_dst + 64, _src + 64, stride_dst, _sao_offset_val, eo, 16, height);
++}
++
++static void ff_hevc_rpi_sao_band_48_neon_8(uint8_t *_dst, uint8_t *_src, ptrdiff_t stride_dst, ptrdiff_t stride_src,
++ int16_t *sao_offset_val, int sao_left_class, int width, int height)
++{
++ ff_hevc_rpi_sao_band_32_neon_8(_dst, _src, stride_dst, stride_src, sao_offset_val, sao_left_class, 32, height);
++ ff_hevc_rpi_sao_band_16_neon_8(_dst + 32, _src + 32, stride_dst, stride_src, sao_offset_val, sao_left_class, 16, height);
++}
++static void ff_hevc_rpi_sao_band_48_neon_10(uint8_t *_dst, uint8_t *_src, ptrdiff_t stride_dst, ptrdiff_t stride_src,
++ int16_t *sao_offset_val, int sao_left_class, int width, int height)
++{
++ ff_hevc_rpi_sao_band_32_neon_10(_dst, _src, stride_dst, stride_src, sao_offset_val, sao_left_class, 32, height);
++ ff_hevc_rpi_sao_band_16_neon_10(_dst + 64, _src + 64, stride_dst, stride_src, sao_offset_val, sao_left_class, 16, height);
++}
++
++#if SAO_FILTER_N == 6
++static void ff_hevc_rpi_sao_edge_24_neon_8(uint8_t *_dst, uint8_t *_src, ptrdiff_t stride_dst, int16_t *_sao_offset_val, int eo, int width, int height)
++{
++ ff_hevc_rpi_sao_edge_16_neon_8(_dst, _src, stride_dst, _sao_offset_val, eo, 16, height);
++ ff_hevc_rpi_sao_edge_8_neon_8(_dst + 16, _src + 16, stride_dst, _sao_offset_val, eo, 8, height);
++}
++static void ff_hevc_rpi_sao_edge_24_neon_10(uint8_t *_dst, uint8_t *_src, ptrdiff_t stride_dst, int16_t *_sao_offset_val, int eo, int width, int height)
++{
++ ff_hevc_rpi_sao_edge_16_neon_10(_dst, _src, stride_dst, _sao_offset_val, eo, 16, height);
++ ff_hevc_rpi_sao_edge_8_neon_10(_dst + 32, _src + 32, stride_dst, _sao_offset_val, eo, 8, height);
++}
++
++static void ff_hevc_rpi_sao_band_24_neon_8(uint8_t *_dst, uint8_t *_src, ptrdiff_t stride_dst, ptrdiff_t stride_src,
++ int16_t *sao_offset_val, int sao_left_class, int width, int height)
++{
++ ff_hevc_rpi_sao_band_16_neon_8(_dst, _src, stride_dst, stride_src, sao_offset_val, sao_left_class, 16, height);
++ ff_hevc_rpi_sao_band_8_neon_8(_dst + 16, _src + 16, stride_dst, stride_src, sao_offset_val, sao_left_class, 8, height);
++}
++static void ff_hevc_rpi_sao_band_24_neon_10(uint8_t *_dst, uint8_t *_src, ptrdiff_t stride_dst, ptrdiff_t stride_src,
++ int16_t *sao_offset_val, int sao_left_class, int width, int height)
++{
++ ff_hevc_rpi_sao_band_16_neon_10(_dst, _src, stride_dst, stride_src, sao_offset_val, sao_left_class, 16, height);
++ ff_hevc_rpi_sao_band_8_neon_10(_dst + 32, _src + 32, stride_dst, stride_src, sao_offset_val, sao_left_class, 8, height);
++}
++
++static void ff_hevc_rpi_sao_edge_c_24_neon_8(uint8_t *_dst, const uint8_t *_src, ptrdiff_t stride_dst,
++ const int16_t *_sao_offset_val_u, const int16_t *_sao_offset_val_v,
++ int eo, int width, int height)
++{
++ ff_hevc_rpi_sao_edge_c_16_neon_8(_dst, _src, stride_dst, _sao_offset_val_u, _sao_offset_val_v, eo, 16, height);
++ ff_hevc_rpi_sao_edge_c_8_neon_8(_dst + 32, _src + 32, stride_dst, _sao_offset_val_u, _sao_offset_val_v, eo, 8, height);
++}
++static void ff_hevc_rpi_sao_edge_c_24_neon_10(uint8_t *_dst, const uint8_t *_src, ptrdiff_t stride_dst,
++ const int16_t *_sao_offset_val_u, const int16_t *_sao_offset_val_v,
++ int eo, int width, int height)
++{
++ ff_hevc_rpi_sao_edge_c_16_neon_10(_dst, _src, stride_dst, _sao_offset_val_u, _sao_offset_val_v, eo, 16, height);
++ ff_hevc_rpi_sao_edge_c_8_neon_10(_dst + 64, _src + 64, stride_dst, _sao_offset_val_u, _sao_offset_val_v, eo, 8, height);
++}
++
++static void ff_hevc_rpi_sao_band_c_24_neon_8(uint8_t *_dst, const uint8_t *_src,
++ ptrdiff_t stride_dst, ptrdiff_t stride_src,
++ const int16_t *sao_offset_val_u, int sao_left_class_u,
++ const int16_t *sao_offset_val_v, int sao_left_class_v,
++ int width, int height)
++{
++ ff_hevc_rpi_sao_band_c_16_neon_8(_dst, _src, stride_dst, stride_src,
++ sao_offset_val_u, sao_left_class_u, sao_offset_val_v, sao_left_class_v, 16, height);
++ ff_hevc_rpi_sao_band_c_8_neon_8(_dst + 32, _src + 32, stride_dst, stride_src,
++ sao_offset_val_u, sao_left_class_u, sao_offset_val_v, sao_left_class_v, 8, height);
++}
++static void ff_hevc_rpi_sao_band_c_24_neon_10(uint8_t *_dst, const uint8_t *_src,
++ ptrdiff_t stride_dst, ptrdiff_t stride_src,
++ const int16_t *sao_offset_val_u, int sao_left_class_u,
++ const int16_t *sao_offset_val_v, int sao_left_class_v,
++ int width, int height)
++{
++ ff_hevc_rpi_sao_band_c_16_neon_10(_dst, _src, stride_dst, stride_src,
++ sao_offset_val_u, sao_left_class_u, sao_offset_val_v, sao_left_class_v, 16, height);
++ ff_hevc_rpi_sao_band_c_8_neon_10(_dst + 64, _src + 64, stride_dst, stride_src,
++ sao_offset_val_u, sao_left_class_u, sao_offset_val_v, sao_left_class_v, 8, height);
++}
++#endif
++
++
++
++#if RPI_HEVC_SAO_BUF_STRIDE != 160
++#error SAO edge src stride not 160 - value used in .S
++#endif
++
++av_cold void ff_hevcdsp_rpi_init_neon(HEVCDSPContext *c, const int bit_depth)
++{
++ if (bit_depth == 8) {
++ c->hevc_v_loop_filter_luma = ff_hevc_rpi_v_loop_filter_luma_neon_8;
++ c->hevc_v_loop_filter_luma_c = ff_hevc_rpi_v_loop_filter_luma_neon_8;
++ c->hevc_h_loop_filter_luma = ff_hevc_rpi_h_loop_filter_luma_neon_8;
++ c->hevc_h_loop_filter_luma_c = ff_hevc_rpi_h_loop_filter_luma_neon_8;
++ c->hevc_h_loop_filter_luma2 = ff_hevc_rpi_h_loop_filter_luma2_neon_8;
++ c->hevc_v_loop_filter_luma2 = ff_hevc_rpi_v_loop_filter_luma2_neon_8;
++ c->hevc_h_loop_filter_uv = ff_hevc_rpi_h_loop_filter_uv_neon_8;
++ c->hevc_v_loop_filter_uv2 = ff_hevc_rpi_v_loop_filter_uv2_neon_8;
++ c->idct[0] = ff_hevc_rpi_transform_4x4_neon_8;
++ c->idct[1] = ff_hevc_rpi_transform_8x8_neon_8;
++ c->idct_dc[0] = ff_hevc_rpi_idct_4x4_dc_neon_8;
++ c->idct_dc[1] = ff_hevc_rpi_idct_8x8_dc_neon_8;
++ c->idct_dc[2] = ff_hevc_rpi_idct_16x16_dc_neon_8;
++ c->idct_dc[3] = ff_hevc_rpi_idct_32x32_dc_neon_8;
++ c->add_residual[0] = ff_hevc_rpi_add_residual_4x4_neon_8;
++ c->add_residual[1] = ff_hevc_rpi_add_residual_8x8_neon_8;
++ c->add_residual[2] = ff_hevc_rpi_add_residual_16x16_neon_8;
++ c->add_residual[3] = ff_hevc_rpi_add_residual_32x32_neon_8;
++ c->add_residual_dc[0] = ff_hevc_rpi_add_residual_4x4_dc_neon_8;
++ c->add_residual_dc[1] = ff_hevc_rpi_add_residual_8x8_dc_neon_8;
++ c->add_residual_dc[2] = ff_hevc_rpi_add_residual_16x16_dc_neon_8;
++ c->add_residual_dc[3] = ff_hevc_rpi_add_residual_32x32_dc_neon_8;
++ c->add_residual_u[0] = ff_hevc_rpi_add_residual_4x4_u_neon_8;
++ c->add_residual_u[1] = ff_hevc_rpi_add_residual_8x8_u_neon_8;
++ c->add_residual_u[2] = ff_hevc_rpi_add_residual_16x16_u_neon_8;
++ c->add_residual_v[0] = ff_hevc_rpi_add_residual_4x4_v_neon_8;
++ c->add_residual_v[1] = ff_hevc_rpi_add_residual_8x8_v_neon_8;
++ c->add_residual_v[2] = ff_hevc_rpi_add_residual_16x16_v_neon_8;
++ c->add_residual_c[0] = ff_hevc_rpi_add_residual_4x4_c_neon_8;
++ c->add_residual_c[1] = ff_hevc_rpi_add_residual_8x8_c_neon_8;
++ c->add_residual_c[2] = ff_hevc_rpi_add_residual_16x16_c_neon_8;
++ c->add_residual_dc_c[0] = ff_hevc_rpi_add_residual_4x4_dc_c_neon_8;
++ c->add_residual_dc_c[1] = ff_hevc_rpi_add_residual_8x8_dc_c_neon_8;
++ c->add_residual_dc_c[2] = ff_hevc_rpi_add_residual_16x16_dc_c_neon_8;
++ c->transform_4x4_luma = ff_hevc_rpi_transform_luma_4x4_neon_8;
++ c->sao_band_filter[0] = ff_hevc_rpi_sao_band_8_neon_8;
++ c->sao_band_filter[1] = ff_hevc_rpi_sao_band_16_neon_8;
++ c->sao_band_filter[2] = ff_hevc_rpi_sao_band_32_neon_8;
++ c->sao_band_filter[3] = ff_hevc_rpi_sao_band_48_neon_8;
++ c->sao_band_filter[4] = ff_hevc_rpi_sao_band_64_neon_8;
++ c->sao_edge_filter[0] = ff_hevc_rpi_sao_edge_8_neon_8;
++ c->sao_edge_filter[1] = ff_hevc_rpi_sao_edge_16_neon_8;
++ c->sao_edge_filter[2] = ff_hevc_rpi_sao_edge_32_neon_8;
++ c->sao_edge_filter[3] = ff_hevc_rpi_sao_edge_48_neon_8;
++ c->sao_edge_filter[4] = ff_hevc_rpi_sao_edge_64_neon_8;
++#if SAO_FILTER_N == 6
++ c->sao_band_filter[5] = ff_hevc_rpi_sao_band_24_neon_8;
++ c->sao_edge_filter[5] = ff_hevc_rpi_sao_edge_24_neon_8;
++#endif
++ c->sao_band_filter_c[0] = ff_hevc_rpi_sao_band_c_8_neon_8;
++ c->sao_band_filter_c[1] = ff_hevc_rpi_sao_band_c_16_neon_8;
++ c->sao_band_filter_c[2] = ff_hevc_rpi_sao_band_c_32_neon_8;
++
++ c->sao_edge_filter_c[0] = ff_hevc_rpi_sao_edge_c_8_neon_8;
++ c->sao_edge_filter_c[1] = ff_hevc_rpi_sao_edge_c_16_neon_8;
++ c->sao_edge_filter_c[2] = ff_hevc_rpi_sao_edge_c_32_neon_8;
++
++#if SAO_FILTER_N == 6
++ c->sao_band_filter_c[5] = ff_hevc_rpi_sao_band_c_24_neon_8;
++ c->sao_edge_filter_c[5] = ff_hevc_rpi_sao_edge_c_24_neon_8;
++#endif
++ }
++ else if (bit_depth == 10) {
++ c->hevc_v_loop_filter_luma = ff_hevc_rpi_v_loop_filter_luma_neon_10;
++ c->hevc_v_loop_filter_luma_c = ff_hevc_rpi_v_loop_filter_luma_neon_10;
++ c->hevc_h_loop_filter_luma = ff_hevc_rpi_h_loop_filter_luma_neon_10;
++ c->hevc_h_loop_filter_luma_c = ff_hevc_rpi_h_loop_filter_luma_neon_10;
++ c->hevc_h_loop_filter_luma2 = ff_hevc_rpi_h_loop_filter_luma2_neon_10;
++ c->hevc_v_loop_filter_luma2 = ff_hevc_rpi_v_loop_filter_luma2_neon_10;
++ c->hevc_h_loop_filter_uv = ff_hevc_rpi_h_loop_filter_uv_neon_10;
++ c->hevc_v_loop_filter_uv2 = ff_hevc_rpi_v_loop_filter_uv2_neon_10;
++ c->idct[0] = ff_hevc_rpi_transform_4x4_neon_10;
++ c->idct[1] = ff_hevc_rpi_transform_8x8_neon_10;
++ c->idct_dc[0] = ff_hevc_rpi_idct_4x4_dc_neon_10;
++ c->idct_dc[1] = ff_hevc_rpi_idct_8x8_dc_neon_10;
++ c->idct_dc[2] = ff_hevc_rpi_idct_16x16_dc_neon_10;
++ c->idct_dc[3] = ff_hevc_rpi_idct_32x32_dc_neon_10;
++ c->add_residual[0] = ff_hevc_rpi_add_residual_4x4_neon_10;
++ c->add_residual[1] = ff_hevc_rpi_add_residual_8x8_neon_10;
++ c->add_residual[2] = ff_hevc_rpi_add_residual_16x16_neon_10;
++ c->add_residual[3] = ff_hevc_rpi_add_residual_32x32_neon_10;
++ c->add_residual_dc[0] = ff_hevc_rpi_add_residual_4x4_dc_neon_10;
++ c->add_residual_dc[1] = ff_hevc_rpi_add_residual_8x8_dc_neon_10;
++ c->add_residual_dc[2] = ff_hevc_rpi_add_residual_16x16_dc_neon_10;
++ c->add_residual_dc[3] = ff_hevc_rpi_add_residual_32x32_dc_neon_10;
++ c->add_residual_u[0] = ff_hevc_rpi_add_residual_4x4_u_neon_10;
++ c->add_residual_u[1] = ff_hevc_rpi_add_residual_8x8_u_neon_10;
++ c->add_residual_u[2] = ff_hevc_rpi_add_residual_16x16_u_neon_10;
++ c->add_residual_v[0] = ff_hevc_rpi_add_residual_4x4_v_neon_10;
++ c->add_residual_v[1] = ff_hevc_rpi_add_residual_8x8_v_neon_10;
++ c->add_residual_v[2] = ff_hevc_rpi_add_residual_16x16_v_neon_10;
++ c->add_residual_c[0] = ff_hevc_rpi_add_residual_4x4_c_neon_10;
++ c->add_residual_c[1] = ff_hevc_rpi_add_residual_8x8_c_neon_10;
++ c->add_residual_c[2] = ff_hevc_rpi_add_residual_16x16_c_neon_10;
++ c->add_residual_dc_c[0] = ff_hevc_rpi_add_residual_4x4_dc_c_neon_10;
++ c->add_residual_dc_c[1] = ff_hevc_rpi_add_residual_8x8_dc_c_neon_10;
++ c->add_residual_dc_c[2] = ff_hevc_rpi_add_residual_16x16_dc_c_neon_10;
++ c->transform_4x4_luma = ff_hevc_rpi_transform_luma_4x4_neon_10;
++ c->sao_band_filter[0] = ff_hevc_rpi_sao_band_8_neon_10;
++ c->sao_band_filter[1] = ff_hevc_rpi_sao_band_16_neon_10;
++ c->sao_band_filter[2] = ff_hevc_rpi_sao_band_32_neon_10;
++ c->sao_band_filter[3] = ff_hevc_rpi_sao_band_48_neon_10;
++ c->sao_band_filter[4] = ff_hevc_rpi_sao_band_64_neon_10;
++
++ c->sao_edge_filter[0] = ff_hevc_rpi_sao_edge_8_neon_10;
++ c->sao_edge_filter[1] = ff_hevc_rpi_sao_edge_16_neon_10;
++ c->sao_edge_filter[2] = ff_hevc_rpi_sao_edge_32_neon_10;
++ c->sao_edge_filter[3] = ff_hevc_rpi_sao_edge_48_neon_10;
++ c->sao_edge_filter[4] = ff_hevc_rpi_sao_edge_64_neon_10;
++#if SAO_FILTER_N == 6
++ c->sao_band_filter[5] = ff_hevc_rpi_sao_band_24_neon_10;
++ c->sao_edge_filter[5] = ff_hevc_rpi_sao_edge_24_neon_10;
++#endif
++ c->sao_band_filter_c[0] = ff_hevc_rpi_sao_band_c_8_neon_10;
++ c->sao_band_filter_c[1] = ff_hevc_rpi_sao_band_c_16_neon_10;
++ c->sao_band_filter_c[2] = ff_hevc_rpi_sao_band_c_32_neon_10;
++
++ c->sao_edge_filter_c[0] = ff_hevc_rpi_sao_edge_c_8_neon_10;
++ c->sao_edge_filter_c[1] = ff_hevc_rpi_sao_edge_c_16_neon_10;
++ c->sao_edge_filter_c[2] = ff_hevc_rpi_sao_edge_c_32_neon_10;
++
++#if SAO_FILTER_N == 6
++ c->sao_band_filter_c[5] = ff_hevc_rpi_sao_band_c_24_neon_10;
++ c->sao_edge_filter_c[5] = ff_hevc_rpi_sao_edge_c_24_neon_10;
++#endif
++ }
++
++ assert(offsetof(HEVCRpiMvField, mv) == 0);
++ assert(offsetof(HEVCRpiMvField, ref_idx) == 8);
++ assert(offsetof(HEVCRpiMvField, pred_flag) == 10);
++ c->hevc_deblocking_boundary_strengths = ff_hevc_rpi_deblocking_boundary_strengths_neon;
++ c->cpy_blk = ff_hevc_rpi_cpy_blks8x4_neon;
++}
+diff --git a/libavcodec/arm/rpi_hevcdsp_res16_neon.S b/libavcodec/arm/rpi_hevcdsp_res16_neon.S
+new file mode 100644
+index 0000000000..f831e55a6d
+--- /dev/null
++++ b/libavcodec/arm/rpi_hevcdsp_res16_neon.S
+@@ -0,0 +1,591 @@
++#include "libavutil/arm/asm.S"
++#include "neon.S"
++
++ .arch_extension mp @ enable PLDW
++
++#define BIT_DEPTH 10
++
++.macro clip16_4 Q0, Q1, Q2, Q3, Q_MIN, Q_MAX
++ vmax.s16 \Q0, \Q_MIN
++ vmax.s16 \Q1, \Q_MIN
++ vmax.s16 \Q2, \Q_MIN
++ vmax.s16 \Q3, \Q_MIN
++ vmin.s16 \Q0, \Q_MAX
++ vmin.s16 \Q1, \Q_MAX
++ vmin.s16 \Q2, \Q_MAX
++ vmin.s16 \Q3, \Q_MAX
++.endm
++
++@ add_residual4x4(
++@ uint16_t *_dst, [r0]
++@ int16_t *res, [r1]
++@ ptrdiff_t stride) [r2]
++
++function JOIN(ff_hevc_rpi_add_residual_4x4_neon_, BIT_DEPTH), export=1
++ add ip, r0, r2
++ vld1.16 {q10, q11}, [r1]
++ lsl r2, #1
++ vld1.16 {d0}, [r0 :64], r2
++ vld1.16 {d1}, [ip :64], r2
++ vld1.16 {d2}, [r0 :64]
++ vld1.16 {d3}, [ip :64]
++ sub r0, r2
++ vqadd.s16 q0, q10
++ sub ip, r2
++ vqadd.s16 q1, q11
++ vmov.i16 q8, #0
++ vmov.i16 q9, #(1 << BIT_DEPTH) - 1
++ vmax.s16 q0, q0, q8
++ vmax.s16 q1, q1, q8
++ vmin.s16 q0, q0, q9
++ vmin.s16 q1, q1, q9
++ vst1.16 {d0}, [r0 :64], r2
++ vst1.16 {d1}, [ip :64], r2
++ vst1.16 {d2}, [r0 :64]
++ vst1.16 {d3}, [ip :64]
++ bx lr
++
++endfunc
++
++@ add_residual4x4_dc(
++@ uint16_t *_dst, [r0]
++@ ptrdiff_t stride, [r1]
++@ int dc) [r2]
++
++function JOIN(ff_hevc_rpi_add_residual_4x4_dc_neon_, BIT_DEPTH), export=1
++ add ip, r0, r1
++ vdup.16 q15, r2
++ lsl r1, #1
++ vld1.16 {d0}, [r0 :64], r1
++ vld1.16 {d1}, [ip :64], r1
++ vld1.16 {d2}, [r0 :64]
++ vld1.16 {d3}, [ip :64]
++ sub r0, r1
++ vqadd.s16 q0, q15
++ sub ip, r1
++ vqadd.s16 q1, q15
++ vmov.i16 q8, #0
++ vmov.i16 q9, #(1 << BIT_DEPTH) - 1
++ vmax.s16 q0, q0, q8
++ vmax.s16 q1, q1, q8
++ vmin.s16 q0, q0, q9
++ vmin.s16 q1, q1, q9
++ vst1.16 {d0}, [r0 :64], r1
++ vst1.16 {d1}, [ip :64], r1
++ vst1.16 {d2}, [r0 :64]
++ vst1.16 {d3}, [ip :64]
++ bx lr
++
++endfunc
++
++
++@ add_residual8x8(
++@ uint16_t *_dst, [r0]
++@ int16_t *res, [r1]
++@ ptrdiff_t stride) [r2]
++
++function JOIN(ff_hevc_rpi_add_residual_8x8_neon_, BIT_DEPTH), export=1
++ mov r3, #8
++ vmov.i64 q8, #0
++ add ip, r0, r2
++ vmov.i16 q9, #(1 << BIT_DEPTH) - 1
++ lsl r2, #1
++1:
++ vldm r1!, {q10-q13}
++ vld1.16 {q0}, [r0 :128], r2
++ vld1.16 {q1}, [ip :128], r2
++ vld1.16 {q2}, [r0 :128]
++ vld1.16 {q3}, [ip :128]
++ sub r0, r2
++ vqadd.s16 q0, q10
++ sub ip, r2
++ vqadd.s16 q1, q11
++ subs r3, #4
++ vqadd.s16 q2, q12
++ vqadd.s16 q3, q13
++ clip16_4 q0, q1, q2, q3, q8, q9
++ vst1.16 {q0}, [r0 :128], r2
++ vst1.16 {q1}, [ip :128], r2
++ vst1.16 {q2}, [r0 :128], r2
++ vst1.16 {q3}, [ip :128], r2
++ bne 1b
++ bx lr
++
++endfunc
++
++@ add_residual4x4_dc_c(
++@ uint16_t *_dst, [r0]
++@ ptrdiff_t stride, [r1]
++@ int dc_uv) [r2]
++
++function JOIN(ff_hevc_rpi_add_residual_4x4_dc_c_neon_, BIT_DEPTH), export=1
++ mov r3, #4
++ vdup.32 q15, r2
++ b 9f
++endfunc
++
++@ add_residual8x8_dc(
++@ uint16_t *_dst, [r0]
++@ ptrdiff_t stride, [r1]
++@ int dc) [r2]
++
++function JOIN(ff_hevc_rpi_add_residual_8x8_dc_neon_, BIT_DEPTH), export=1
++ vdup.16 q15, r2
++ mov r3, #8
++9:
++ vmov.i16 q8, #0
++ add ip, r0, r1
++ vmov.i16 q9, #(1 << BIT_DEPTH) - 1
++ lsl r1, #1
++1:
++ vld1.16 {q0}, [r0 :128], r1
++ vld1.16 {q1}, [ip :128], r1
++ vld1.16 {q2}, [r0 :128]
++ vld1.16 {q3}, [ip :128]
++ sub r0, r1
++ vqadd.s16 q0, q15
++ sub ip, r1
++ vqadd.s16 q1, q15
++ subs r3, #4
++ vqadd.s16 q2, q15
++ vqadd.s16 q3, q15
++ clip16_4 q0, q1, q2, q3, q8, q9
++ vst1.16 {q0}, [r0 :128], r1
++ vst1.16 {q1}, [ip :128], r1
++ vst1.16 {q2}, [r0 :128], r1
++ vst1.16 {q3}, [ip :128], r1
++ bne 1b
++ bx lr
++
++endfunc
++
++@ add_residual16x16(
++@ uint16_t *_dst, [r0]
++@ int16_t *res, [r1]
++@ ptrdiff_t stride) [r2]
++
++function JOIN(ff_hevc_rpi_add_residual_16x16_neon_, BIT_DEPTH), export=1
++ add ip, r0, r2
++ vmov.i16 q8, #0
++ lsl r2, #1
++ vmov.i16 q9, #(1 << BIT_DEPTH) - 1
++ mov r3, #16
++1:
++ vldm r1!, {q10-q13}
++ @ For RPI Sand we could guarantee :256 but not for general
++ @ non-RPI allocation. :128 is as good as we can claim
++ vld1.16 {q0, q1}, [r0 :128]
++ subs r3, #2
++ vld1.16 {q2, q3}, [ip :128]
++ vqadd.s16 q0, q10
++ vqadd.s16 q1, q11
++ vqadd.s16 q2, q12
++ vqadd.s16 q3, q13
++ clip16_4 q0, q1, q2, q3, q8, q9
++ vst1.16 {q0, q1}, [r0 :128], r2
++ vst1.16 {q2, q3}, [ip :128], r2
++ bne 1b
++ bx lr
++endfunc
++
++@ add_residual8x8_dc_c(
++@ uint16_t *_dst, [r0]
++@ ptrdiff_t stride, [r1]
++@ int dc_uv) [r2]
++
++function JOIN(ff_hevc_rpi_add_residual_8x8_dc_c_neon_, BIT_DEPTH), export=1
++ mov r3, #8
++ vdup.32 q15, r2
++ b 9f
++endfunc
++
++@ add_residual16x16_dc(
++@ uint16_t *_dst, [r0]
++@ ptrdiff_t stride, [r1]
++@ int dc) [r2]
++
++function JOIN(ff_hevc_rpi_add_residual_16x16_dc_neon_, BIT_DEPTH), export=1
++ vdup.i16 q15, r2
++ mov r3, #16
++9:
++ vmov.i16 q8, #0
++ add ip, r0, r1
++ vmov.i16 q9, #(1 << BIT_DEPTH) - 1
++ lsl r1, #1
++1:
++ @ For RPI Sand we could guarantee :256 but not for general
++ @ non-RPI allocation. :128 is as good as we can claim
++ vld1.16 {q0, q1}, [r0 :128]
++ subs r3, #2
++ vqadd.s16 q0, q15
++ vqadd.s16 q1, q15
++ vld1.16 {q2, q3}, [ip :128]
++ vqadd.s16 q2, q15
++ vqadd.s16 q3, q15
++ clip16_4 q0, q1, q2, q3, q8, q9
++ vst1.16 {q0, q1}, [r0 :128], r1
++ vst1.16 {q2, q3}, [ip :128], r1
++ bne 1b
++ bx lr
++
++endfunc
++
++
++@ add_residual32x32(
++@ uint16_t *_dst, [r0]
++@ int16_t *res, [r1]
++@ ptrdiff_t stride) [r2]
++
++function JOIN(ff_hevc_rpi_add_residual_32x32_neon_, BIT_DEPTH), export=1
++ push {lr}
++ mov r3, #32
++ vmov.i16 q8, #0
++ add lr, r0, r2
++ vmov.i16 q9, #(1 << BIT_DEPTH) - 1
++ add ip, r0, #32
++1:
++ vldm r1!, {q10-q13}
++ vldm r0, {q0-q3}
++ vqadd.s16 q0, q10
++ pldw [lr]
++ vqadd.s16 q1, q11
++ add lr, r2
++ vqadd.s16 q2, q12
++ subs r3, #1
++ vqadd.s16 q3, q13
++ clip16_4 q0, q1, q2, q3, q8, q9
++ vst1.16 {q0-q1}, [r0], r2
++ vst1.16 {q2-q3}, [ip], r2
++ bne 1b
++ pop {pc}
++
++endfunc
++
++@ add_residual16x16_dc_c(
++@ uint16_t *_dst, [r0]
++@ ptrdiff_t stride, [r1]
++@ int dc_uv) [r2]
++
++function JOIN(ff_hevc_rpi_add_residual_16x16_dc_c_neon_, BIT_DEPTH), export=1
++ mov r3, #16
++ vdup.32 q15, r2
++ b 9f
++endfunc
++
++@ add_residual32x32_dc(
++@ uint16_t *_dst, [r0]
++@ ptrdiff_t stride, [r1]
++@ int dc) [r2]
++
++function JOIN(ff_hevc_rpi_add_residual_32x32_dc_neon_, BIT_DEPTH), export=1
++ vdup.16 q15, r2
++ mov r3, #32
++9:
++ vmov.i16 q8, #0
++ vmov.i16 q9, #(1 << BIT_DEPTH) - 1
++ add ip, r0, #32
++1:
++ vldm r0, {q0-q3}
++ vqadd.s16 q0, q15
++ subs r3, #1
++ vqadd.s16 q1, q15
++ vqadd.s16 q2, q15
++ vqadd.s16 q3, q15
++ clip16_4 q0, q1, q2, q3, q8, q9
++ vst1.16 {q0-q1}, [r0], r1
++ vst1.16 {q2-q3}, [ip], r1
++ bne 1b
++ bx lr
++
++endfunc
++
++@ ============================================================================
++@ U add
++
++@ add_residual4x4_u(
++@ uint16_t *_dst, [r0]
++@ const int16_t *res, [r1]
++@ ptrdiff_t stride, [r2]
++@ int dc) [r3]
++
++function JOIN(ff_hevc_rpi_add_residual_4x4_u_neon_, BIT_DEPTH), export=1
++ vdup.16 q15, r3
++ add ip, r0, r2
++ vld1.16 {q10, q11}, [r1 :256]
++ lsl r2, #1
++ vld2.16 {d0, d2}, [r0 :128], r2
++ vld2.16 {d1, d3}, [ip :128], r2
++ vld2.16 {d4, d6}, [r0 :128]
++ vld2.16 {d5, d7}, [ip :128]
++ sub r0, r2
++ vmov.i16 q8, #0
++ sub ip, r2
++ vmov.i16 q9, #(1 << BIT_DEPTH) - 1
++
++ vqadd.s16 q0, q10
++ vqadd.s16 q1, q15
++ vqadd.s16 q2, q11
++ vqadd.s16 q3, q15
++ clip16_4 q0, q1, q2, q3, q8, q9
++
++ vst2.16 {d0, d2}, [r0 :128], r2
++ vst2.16 {d1, d3}, [ip :128], r2
++ vst2.16 {d4, d6}, [r0 :128]
++ vst2.16 {d5, d7}, [ip :128]
++ bx lr
++endfunc
++
++@ add_residual8x8_u(
++@ uint16_t *_dst, [r0]
++@ const int16_t *res, [r1]
++@ ptrdiff_t stride, [r2]
++@ int dc) [r3]
++
++function JOIN(ff_hevc_rpi_add_residual_8x8_u_neon_, BIT_DEPTH), export=1
++ vdup.16 q15, r3
++ mov r3, #8
++ vmov.i16 q8, #0
++ add ip, r0, r2
++ vmov.i16 q9, #(1 << BIT_DEPTH) - 1
++ lsl r2, #1
++1:
++ vld2.16 {q0, q1}, [r0 :256]
++ subs r3, #2
++ vld2.16 {q2, q3}, [ip :256]
++ vld1.16 {q10, q11}, [r1 :256]!
++ vqadd.s16 q0, q10
++ vqadd.s16 q1, q15
++ vqadd.s16 q2, q11
++ vqadd.s16 q3, q15
++ clip16_4 q0, q1, q2, q3, q8, q9
++ vst2.16 {q0, q1}, [r0 :256], r2
++ vst2.16 {q2, q3}, [ip :256], r2
++ bne 1b
++ bx lr
++endfunc
++
++@ add_residual16x16_u(
++@ uint16_t *_dst, [r0]
++@ const int16_t *res, [r1]
++@ ptrdiff_t stride, [r2]
++@ int dc) [r3]
++
++function JOIN(ff_hevc_rpi_add_residual_16x16_u_neon_, BIT_DEPTH), export=1
++ push {lr}
++ vdup.16 q15, r3
++ mov r3, #16
++ vmov.i16 q8, #0
++ add lr, r0, r2
++ vmov.i16 q9, #(1 << BIT_DEPTH) - 1
++ add ip, r0, #32
++1:
++ vld2.16 {q0, q1}, [r0 :256]
++ vld2.16 {q2, q3}, [ip :256]
++ vld1.16 {q10, q11}, [r1 :256]!
++ vqadd.s16 q0, q10
++ pldw [lr]
++ vqadd.s16 q1, q15
++ add lr, r2
++ vqadd.s16 q2, q11
++ subs r3, #1
++ vqadd.s16 q3, q15
++ clip16_4 q0, q1, q2, q3, q8, q9
++ vst2.16 {q0, q1}, [r0 :256], r2
++ vst2.16 {q2, q3}, [ip :256], r2
++ bne 1b
++ pop {pc}
++endfunc
++
++@ ============================================================================
++@ V add
++
++@ add_residual4x4_v(
++@ uint16_t *_dst, [r0]
++@ const int16_t *res, [r1]
++@ ptrdiff_t stride, [r2]
++@ int dc) [r3]
++
++function JOIN(ff_hevc_rpi_add_residual_4x4_v_neon_, BIT_DEPTH), export=1
++ vdup.16 q15, r3
++ add ip, r0, r2
++ vld1.16 {q10, q11}, [r1 :256]
++ lsl r2, #1
++ vld2.16 {d0, d2}, [r0 :128], r2
++ vld2.16 {d1, d3}, [ip :128], r2
++ vld2.16 {d4, d6}, [r0 :128]
++ vld2.16 {d5, d7}, [ip :128]
++ sub r0, r2
++ vmov.i16 q8, #0
++ sub ip, r2
++ vmov.i16 q9, #(1 << BIT_DEPTH) - 1
++
++ vqadd.s16 q0, q15
++ vqadd.s16 q1, q10
++ vqadd.s16 q2, q15
++ vqadd.s16 q3, q11
++ clip16_4 q0, q1, q2, q3, q8, q9
++
++ vst2.16 {d0, d2}, [r0 :128], r2
++ vst2.16 {d1, d3}, [ip :128], r2
++ vst2.16 {d4, d6}, [r0 :128]
++ vst2.16 {d5, d7}, [ip :128]
++ bx lr
++endfunc
++
++@ add_residual8x8_v(
++@ uint16_t *_dst, [r0]
++@ const int16_t *res, [r1]
++@ ptrdiff_t stride, [r2]
++@ int dc) [r3]
++
++function JOIN(ff_hevc_rpi_add_residual_8x8_v_neon_, BIT_DEPTH), export=1
++ vdup.16 q15, r3
++ mov r3, #8
++ vmov.i16 q8, #0
++ add ip, r0, r2
++ vmov.i16 q9, #(1 << BIT_DEPTH) - 1
++ lsl r2, #1
++1:
++ vld2.16 {q0, q1}, [r0 :256]
++ subs r3, #2
++ vld2.16 {q2, q3}, [ip :256]
++ vld1.16 {q10, q11}, [r1 :256]!
++ vqadd.s16 q0, q15
++ vqadd.s16 q1, q10
++ vqadd.s16 q2, q15
++ vqadd.s16 q3, q11
++ clip16_4 q0, q1, q2, q3, q8, q9
++ vst2.16 {q0, q1}, [r0 :256], r2
++ vst2.16 {q2, q3}, [ip :256], r2
++ bne 1b
++ bx lr
++endfunc
++
++@ add_residual16x16_v(
++@ uint16_t *_dst, [r0]
++@ const int16_t *res, [r1]
++@ ptrdiff_t stride, [r2]
++@ int dc) [r3]
++
++function JOIN(ff_hevc_rpi_add_residual_16x16_v_neon_, BIT_DEPTH), export=1
++ push {lr}
++ vdup.16 q15, r3
++ mov r3, #16
++ vmov.i16 q8, #0
++ add lr, r0, r2
++ vmov.i16 q9, #(1 << BIT_DEPTH) - 1
++ add ip, r0, #32
++1:
++ vld2.16 {q0, q1}, [r0 :256]
++ vld2.16 {q2, q3}, [ip :256]
++ vld1.16 {q10, q11}, [r1 :256]!
++ vqadd.s16 q0, q15
++ pldw [lr]
++ vqadd.s16 q1, q10
++ add lr, r2
++ vqadd.s16 q2, q15
++ subs r3, #1
++ vqadd.s16 q3, q11
++ clip16_4 q0, q1, q2, q3, q8, q9
++ vst2.16 {q0, q1}, [r0 :256], r2
++ vst2.16 {q2, q3}, [ip :256], r2
++ bne 1b
++ pop {pc}
++endfunc
++
++@ ============================================================================
++@ U & V add
++
++@ add_residual4x4_c(
++@ uint16_t *_dst, [r0]
++@ const int16_t *res, [r1]
++@ ptrdiff_t stride) [r2]
++
++function JOIN(ff_hevc_rpi_add_residual_4x4_c_neon_, BIT_DEPTH), export=1
++ vmov.i16 q8, #0
++ add ip, r0, r2
++ vmov.i16 q9, #(1 << BIT_DEPTH) - 1
++ lsl r2, #1
++ vldm r1, {q10-q13}
++ vld2.16 {d0, d2}, [r0 :128], r2
++ vld2.16 {d1, d3}, [ip :128], r2
++ vld2.16 {d4, d6}, [r0 :128]
++ vld2.16 {d5, d7}, [ip :128]
++
++ sub r0, r2
++ vqadd.s16 q0, q10
++ sub ip, r2
++ vqadd.s16 q1, q12
++ vqadd.s16 q2, q11
++ vqadd.s16 q3, q13
++ clip16_4 q0, q1, q2, q3, q8, q9
++
++ vst2.16 {d0, d2}, [r0 :128], r2
++ vst2.16 {d1, d3}, [ip :128], r2
++ vst2.16 {d4, d6}, [r0 :128]
++ vst2.16 {d5, d7}, [ip :128]
++ bx lr
++endfunc
++
++@ add_residual8x8_c(
++@ uint16_t *_dst, [r0]
++@ const int16_t *res, [r1]
++@ ptrdiff_t stride) [r2]
++
++function JOIN(ff_hevc_rpi_add_residual_8x8_c_neon_, BIT_DEPTH), export=1
++ push {lr}
++ add ip, r0, r2
++ lsl r2, #1
++ vmov.i16 q8, #0
++ add r3, r1, #(8*8*2) @ Offset to V
++ vmov.i16 q9, #(1 << BIT_DEPTH) - 1
++ mov lr, #8
++1:
++ vld1.16 {q10, q11}, [r1 :256]!
++ subs lr, #2
++ vld2.16 {q0, q1}, [r0 :256]
++ vld2.16 {q2, q3}, [ip :256]
++ vld1.16 {q12, q13}, [r3 :256]!
++ vqadd.s16 q0, q10
++ vqadd.s16 q1, q12
++ vqadd.s16 q2, q11
++ vqadd.s16 q3, q13
++ clip16_4 q0, q1, q2, q3, q8, q9
++ vst2.16 {q0, q1}, [r0 :256], r2
++ vst2.16 {q2, q3}, [ip :256], r2
++ bne 1b
++ pop {pc}
++endfunc
++
++@ add_residual16x16_c(
++@ uint16_t *_dst, [r0]
++@ const int16_t *res, [r1]
++@ ptrdiff_t stride) [r2]
++
++function JOIN(ff_hevc_rpi_add_residual_16x16_c_neon_, BIT_DEPTH), export=1
++ push {r4, lr}
++ vmov.i16 q8, #0
++ add r3, r1, #(16*16*2) @ Offset to V
++ vmov.i16 q9, #(1 << BIT_DEPTH) - 1
++ add ip, r0, #32
++ add r4, r0, r2
++ mov lr, #16
++1:
++ vld2.16 {q0, q1}, [r0 :256]
++ vld2.16 {q2, q3}, [ip :256]
++ vld1.16 {q10, q11}, [r1 :256]!
++ vld1.16 {q12, q13}, [r3 :256]!
++ vqadd.s16 q0, q10
++ pldw [r4]
++ vqadd.s16 q1, q12
++ add r4, r2
++ vqadd.s16 q2, q11
++ subs lr, #1
++ vqadd.s16 q3, q13
++ clip16_4 q0, q1, q2, q3, q8, q9
++ vst2.16 {q0, q1}, [r0 :256], r2
++ vst2.16 {q2, q3}, [ip :256], r2
++ bne 1b
++ pop {r4,pc}
++endfunc
++
+diff --git a/libavcodec/arm/rpi_hevcdsp_res8_neon.S b/libavcodec/arm/rpi_hevcdsp_res8_neon.S
+new file mode 100644
+index 0000000000..ea3b3faf6f
+--- /dev/null
++++ b/libavcodec/arm/rpi_hevcdsp_res8_neon.S
+@@ -0,0 +1,712 @@
++#include "libavutil/arm/asm.S"
++#include "neon.S"
++
++ .arch_extension mp @ enable PLDW
++
++@ General notes:
++@
++@ Residual is generally only guaranteed to be clipped to 16 bits.
++@ This means that we do need to do vmovl, vqadd, vqmovun
++@ rather than vaddw, vqmovun (if we were clipped to 15 then we could get away
++@ with this).
++@
++@ There is an exception for the DC case because its transform is guaranteed
++@ to be small enough that overflow cannot occur during the first add.
++
++@ ============================================================================
++@ Y add
++
++function ff_hevc_rpi_add_residual_4x4_neon_8, export=1
++ add ip, r0, r2
++ vld1.16 {q0, q1}, [r1]
++ lsl r2, #1
++ vld1.32 d4[0], [r0], r2
++ rsb r3, r2, #0
++ vld1.32 d4[1], [ip], r2
++ vld1.32 d5[0], [r0], r3
++ vld1.32 d5[1], [ip], r3
++ vmovl.u8 q8, d4
++ vmovl.u8 q9, d5
++ vqadd.s16 q0, q8
++ vqadd.s16 q1, q9
++ vqmovun.s16 d0, q0
++ vqmovun.s16 d1, q1
++ vst1.32 d0[0], [r0], r2
++ vst1.32 d0[1], [ip], r2
++ vst1.32 d1[0], [r0]
++ vst1.32 d1[1], [ip]
++ bx lr
++endfunc
++
++function ff_hevc_rpi_add_residual_8x8_neon_8, export=1
++ push {r4, lr}
++ vld1.16 {q0, q1}, [r1]!
++ add ip, r0, r2
++ vld1.8 {d6}, [r0]
++ add r4, r0, r2, lsl #1
++ vld1.8 {d7}, [ip]
++ add lr, ip, r2, lsl #1
++ lsl r2, #1
++ mov r3, #8-2
++ vmovl.u8 q2, d6
++ vmovl.u8 q3, d7
++ vqadd.s16 q2, q0
++ vqadd.s16 q3, q1
++1:
++ vld1.16 {q0, q1}, [r1]!
++ subs r3, #2
++ vqmovun.s16 d4, q2
++ vqmovun.s16 d5, q3
++ vld1.8 {d6}, [r4], r2
++ vld1.8 {d7}, [lr], r2
++ vst1.8 {d4}, [r0], r2
++ vst1.8 {d5}, [ip], r2
++ vmovl.u8 q2, d6
++ pldw [r4]
++ vmovl.u8 q3, d7
++ vqadd.s16 q2, q0
++ vqadd.s16 q3, q1
++ bne 1b
++
++ vqmovun.s16 d4, q2
++ vqmovun.s16 d5, q3
++ vst1.8 {d4}, [r0]
++ vst1.8 {d5}, [ip]
++ pop {r4, pc}
++endfunc
++
++function ff_hevc_rpi_add_residual_16x16_neon_8, export=1
++ vld1.16 {q0, q1}, [r1]!
++ add ip, r0, r2
++ vld1.8 {q3}, [r0]
++ mov r3, #16-1
++ vmovl.u8 q2, d6
++ vmovl.u8 q3, d7
++ vqadd.s16 q2, q0
++ vqadd.s16 q3, q1
++1:
++ vld1.16 {q0, q1}, [r1]!
++ subs r3, #1
++ vqmovun.s16 d4, q2
++ vqmovun.s16 d5, q3
++ vld1.8 {q3}, [ip], r2
++ vst1.8 {q2}, [r0], r2
++ vmovl.u8 q2, d6
++ pldw [ip]
++ vmovl.u8 q3, d7
++ vqadd.s16 q2, q0
++ vqadd.s16 q3, q1
++ bne 1b
++
++ vqmovun.s16 d4, q2
++ vqmovun.s16 d5, q3
++ vst1.8 {q2}, [r0]
++ bx lr
++endfunc
++
++function ff_hevc_rpi_add_residual_32x32_neon_8, export=1
++ vldm r1!, {q0-q3}
++ vld1.8 {q8, q9}, [r0]
++ add ip, r0, r2
++ vmovl.u8 q10, d16
++ mov r3, #32-1
++ vmovl.u8 q11, d17
++ vmovl.u8 q12, d18
++ vmovl.u8 q13, d19
++ vqadd.s16 q10, q0
++ vqadd.s16 q11, q1
++ vqadd.s16 q12, q2
++ vqadd.s16 q13, q3
++1:
++ vldm r1!, {q0-q3}
++ vqmovun.s16 d20, q10
++ vqmovun.s16 d21, q11
++ vqmovun.s16 d22, q12
++ vqmovun.s16 d23, q13
++ vld1.8 {q8, q9}, [ip], r2
++ subs r3, #1
++ vst1.8 {q10, q11}, [r0], r2
++ vmovl.u8 q10, d16
++ pldw [ip]
++ vmovl.u8 q11, d17
++ vmovl.u8 q12, d18
++ vmovl.u8 q13, d19
++ vqadd.s16 q10, q0
++ vqadd.s16 q11, q1
++ vqadd.s16 q12, q2
++ vqadd.s16 q13, q3
++ bne 1b
++
++ vqmovun.s16 d20, q10
++ vqmovun.s16 d21, q11
++ vqmovun.s16 d22, q12
++ vqmovun.s16 d23, q13
++ vst1.8 {q10, q11}, [r0]
++ bx lr
++endfunc
++
++
++@ ff_hevc_rpi_add_residual_4x4_dc_neon_8(
++@ uint8_t * dst, // [r0]
++@ unsigned int stride, // [r1]
++@ int dc) // [r2]
++
++function ff_hevc_rpi_add_residual_4x4_dc_neon_8, export=1
++ add ip, r0, r1
++ vdup.16 q15, r2
++ lsl r1, #1
++ vld1.32 d4[0], [r0], r1
++ rsb r3, r1, #0
++ vld1.32 d4[1], [ip], r1
++ vld1.32 d5[0], [r0], r3
++ vld1.32 d5[1], [ip], r3
++ vaddw.u8 q0, q15, d4
++ vaddw.u8 q1, q15, d5
++ vqmovun.s16 d0, q0
++ vqmovun.s16 d1, q1
++ vst1.32 d0[0], [r0], r1
++ vst1.32 d0[1], [ip], r1
++ vst1.32 d1[0], [r0]
++ vst1.32 d1[1], [ip]
++ bx lr
++endfunc
++
++@ ============================================================================
++@ DC Y or C add
++
++@ ff_hevc_rpi_add_residual_4x4_dc_c_neon_8(
++@ uint8_t * dst, // [r0]
++@ unsigned int stride, // [r1]
++@ int dc) // [r2]
++
++function ff_hevc_rpi_add_residual_4x4_dc_c_neon_8, export=1
++ mov r3, #4-2
++ vdup.32 q15, r2
++ b 1f
++endfunc
++
++@ ff_hevc_rpi_add_residual_8x8_dc_neon_8(
++@ uint8_t * dst, // [r0]
++@ unsigned int stride, // [r1]
++@ int dc) // [r2]
++
++function ff_hevc_rpi_add_residual_8x8_dc_neon_8, export=1
++ vdup.16 q15, r2
++ mov r3, #8-2
++1: vld1.8 d16, [r0]
++ add ip, r0, r1
++ push {r4, lr}
++ vld1.8 d17, [ip]
++ add r4, r0, r1, lsl #1
++ vaddw.u8 q0, q15, d16
++ lsl r1, #1
++ vaddw.u8 q1, q15, d17
++ add lr, ip, r1
++1:
++ vld1.8 {d16}, [r4], r1
++ vld1.8 {d17}, [lr], r1
++ subs r3, #2
++ vqmovun.s16 d4, q0
++ vqmovun.s16 d5, q1
++ vaddw.u8 q0, q15, d16
++ vaddw.u8 q1, q15, d17
++ vst1.8 {d4}, [r0], r1
++ vst1.8 {d5}, [ip], r1
++ bne 1b
++
++ vqmovun.s16 d4, q0
++ vqmovun.s16 d5, q1
++ vst1.8 {d4}, [r0]
++ vst1.8 {d5}, [ip]
++ pop {r4, pc}
++endfunc
++
++
++@ ff_hevc_rpi_add_residual_8x8_dc_c_neon_8(
++@ uint8_t * dst, // [r0]
++@ unsigned int stride, // [r1]
++@ int dc) // [r2]
++
++function ff_hevc_rpi_add_residual_8x8_dc_c_neon_8, export=1
++ mov r3, #8-1
++ vdup.32 q15, r2
++ b 1f
++endfunc
++
++@ ff_hevc_rpi_add_residual_16x16_dc_neon_8(
++@ uint8_t * dst, // [r0]
++@ unsigned int stride, // [r1]
++@ int dc) // [r2]
++
++function ff_hevc_rpi_add_residual_16x16_dc_neon_8, export=1
++ vdup.16 q15, r2
++ mov r3, #16-1
++1: vld1.8 {q8}, [r0]
++ add ip, r0, r1
++ vaddw.u8 q0, q15, d16
++ vaddw.u8 q1, q15, d17
++1:
++ vld1.8 {q8}, [ip], r1
++ subs r3, #1
++ vqmovun.s16 d4, q0
++ vqmovun.s16 d5, q1
++ vaddw.u8 q0, q15, d16
++ vaddw.u8 q1, q15, d17
++ vst1.8 {q2}, [r0], r1
++ bne 1b
++
++ vqmovun.s16 d4, q0
++ vqmovun.s16 d5, q1
++ vst1.8 {q2}, [r0]
++ bx lr
++endfunc
++
++
++@ ff_hevc_rpi_add_residual_16x16_dc_c_neon_8(
++@ uint8_t * dst, // [r0]
++@ unsigned int stride, // [r1]
++@ int dc) // [r2]
++
++function ff_hevc_rpi_add_residual_16x16_dc_c_neon_8, export=1
++ mov r3, #16-1
++ vdup.32 q15, r2
++ b 1f
++endfunc
++
++@ ff_hevc_rpi_add_residual_32x32_dc_neon_8(
++@ uint8_t * dst, // [r0]
++@ unsigned int stride, // [r1]
++@ int dc) // [r2]
++
++function ff_hevc_rpi_add_residual_32x32_dc_neon_8, export=1
++ vdup.16 q15, r2
++ mov r3, #32-1
++1: vld1.8 {q8, q9}, [r0]
++ add ip, r0, r1
++ vaddw.u8 q0, q15, d16
++ vaddw.u8 q1, q15, d17
++ vaddw.u8 q2, q15, d18
++ vaddw.u8 q3, q15, d19
++1:
++ vqmovun.s16 d20, q0
++ vqmovun.s16 d21, q1
++ vqmovun.s16 d22, q2
++ vqmovun.s16 d23, q3
++ vld1.8 {q8, q9}, [ip], r1
++ subs r3, #1
++ vaddw.u8 q0, q15, d16
++ vaddw.u8 q1, q15, d17
++ vaddw.u8 q2, q15, d18
++ vaddw.u8 q3, q15, d19
++ vst1.8 {q10, q11}, [r0], r1
++ bne 1b
++
++ vqmovun.s16 d20, q0
++ vqmovun.s16 d21, q1
++ vqmovun.s16 d22, q2
++ vqmovun.s16 d23, q3
++ vst1.8 {q10, q11}, [r0]
++ bx lr
++endfunc
++
++@ ============================================================================
++@ U add
++
++@ add_residual4x4_c(
++@ uint8_t *_dst, [r0]
++@ const int16_t *res, [r1]
++@ ptrdiff_t stride, [r2]
++@ int dc_v) [r3]
++
++function ff_hevc_rpi_add_residual_4x4_u_neon_8, export=1
++ add ip, r0, r2
++ vld1.16 {q0, q1}, [r1]
++ lsl r2, #1
++ vld1.8 {d16}, [r0 :64], r2
++ vld1.8 {d17}, [ip :64], r2
++ vld1.8 {d18}, [r0 :64]
++ sub r0, r2
++ vld1.8 {d19}, [ip :64]
++ sub ip, r2
++ vdup.16 q2, r3
++ vdup.16 q3, r3
++ vmovl.u8 q10, d16
++ vmovl.u8 q11, d17
++ vmovl.u8 q12, d18
++ vmovl.u8 q13, d19
++ vzip.16 q0, q2
++ vzip.16 q1, q3
++ vqadd.s16 q0, q10
++ vqadd.s16 q2, q11
++ vqadd.s16 q1, q12
++ vqadd.s16 q3, q13
++ vqmovun.s16 d0, q0
++ vqmovun.s16 d1, q2
++ vqmovun.s16 d2, q1
++ vqmovun.s16 d3, q3
++ vst1.8 {d0}, [r0 :64], r2
++ vst1.8 {d1}, [ip :64], r2
++ vst1.8 {d2}, [r0 :64]
++ vst1.8 {d3}, [ip :64]
++ bx lr
++endfunc
++
++@ add_residual8x8_c(
++@ uint8_t *_dst, [r0]
++@ const int16_t *res, [r1]
++@ ptrdiff_t stride) [r2]
++@ int dc_v) [r3]
++
++function ff_hevc_rpi_add_residual_8x8_u_neon_8, export=1
++ vdup.16 q15, r3
++ add ip, r0, r2
++ push {r4, lr}
++ vld2.8 {d16, d17}, [r0 :128]
++ lsl r2, #1
++ vld2.8 {d18, d19}, [ip :128]
++ mov r3, #8-2
++ vld1.16 {q0, q1}, [r1 :256]!
++ add r4, r0, r2
++ vmovl.u8 q10, d16
++ add lr, ip, r2
++ vmovl.u8 q11, d18
++ vqadd.s16 q0, q10
++ vaddw.u8 q2, q15, d17
++ vqadd.s16 q1, q11
++ vaddw.u8 q3, q15, d19
++1:
++ vqmovun.s16 d20, q0
++ vqmovun.s16 d21, q2
++ vld2.8 {d16, d17}, [r4 :128], r2
++ subs r3, #2
++ vqmovun.s16 d22, q1
++ vqmovun.s16 d23, q3
++ vst2.8 {d20, d21}, [r0 :128], r2
++ vld2.8 {d18, d19}, [lr :128], r2
++ vst2.8 {d22, d23}, [ip :128], r2
++ vld1.16 {q0, q1}, [r1 :256]!
++ vmovl.u8 q10, d16
++ vmovl.u8 q11, d18
++ vqadd.s16 q0, q10
++ vaddw.u8 q2, q15, d17
++ vqadd.s16 q1, q11
++ vaddw.u8 q3, q15, d19
++ bne 1b
++
++ vqmovun.s16 d20, q0
++ vqmovun.s16 d21, q2
++ vqmovun.s16 d22, q1
++ vqmovun.s16 d23, q3
++ vst2.8 {d20, d21}, [r0 :128]
++ vst2.8 {d22, d23}, [ip :128]
++ pop {r4, pc}
++endfunc
++
++@ add_residual16x16_u(
++@ uint8_t *_dst, [r0]
++@ const int16_t *res, [r1]
++@ ptrdiff_t stride) [r2]
++@ int dc_v) [r3]
++
++function ff_hevc_rpi_add_residual_16x16_u_neon_8, export=1
++ vdup.16 q15, r3
++ add ip, r0, r2
++ vld2.8 {q8, q9}, [r0 :256]
++ mov r3, #16-1
++ vld1.16 {q0, q1}, [r1 :256]!
++ vmovl.u8 q11, d16
++ vmovl.u8 q12, d17
++ vqadd.s16 q0, q11
++ vaddw.u8 q11, q15, d18
++ vqadd.s16 q1, q12
++ vaddw.u8 q12, q15, d19
++1:
++ vld2.8 {q8, q9}, [ip :256], r2
++ subs r3, #1
++ vqmovun.s16 d20, q0
++ vqmovun.s16 d22, q11
++ vqmovun.s16 d21, q1
++ vqmovun.s16 d23, q12
++ vld1.16 {q0, q1}, [r1 :256]!
++ vst2.8 {q10, q11}, [r0 :256], r2
++ vmovl.u8 q11, d16
++ pldw [ip]
++ vmovl.u8 q12, d17
++ vqadd.s16 q0, q11
++ vaddw.u8 q11, q15, d18
++ vqadd.s16 q1, q12
++ vaddw.u8 q12, q15, d19
++ bne 1b
++
++ vqmovun.s16 d20, q0
++ vqmovun.s16 d22, q11
++ vqmovun.s16 d21, q1
++ vqmovun.s16 d23, q12
++ vst2.8 {q10, q11}, [r0 :256]
++ bx lr
++endfunc
++
++@ ============================================================================
++@ V add
++
++@ add_residual4x4_v(
++@ uint8_t *_dst, [r0]
++@ const int16_t *res, [r1]
++@ ptrdiff_t stride) [r2]
++
++function ff_hevc_rpi_add_residual_4x4_v_neon_8, export=1
++ add ip, r0, r2
++ vld1.16 {q2, q3}, [r1]
++ lsl r2, #1
++ vld1.8 {d16}, [r0 :64], r2
++ vld1.8 {d17}, [ip :64], r2
++ vld1.8 {d18}, [r0 :64]
++ sub r0, r2
++ vld1.8 {d19}, [ip :64]
++ sub ip, r2
++ vdup.16 q0, r3
++ vdup.16 q1, r3
++ vmovl.u8 q10, d16
++ vmovl.u8 q11, d17
++ vmovl.u8 q12, d18
++ vmovl.u8 q13, d19
++ vzip.16 q0, q2
++ vzip.16 q1, q3
++ vqadd.s16 q0, q10
++ vqadd.s16 q2, q11
++ vqadd.s16 q1, q12
++ vqadd.s16 q3, q13
++ vqmovun.s16 d0, q0
++ vqmovun.s16 d1, q2
++ vqmovun.s16 d2, q1
++ vqmovun.s16 d3, q3
++ vst1.8 {d0}, [r0 :64], r2
++ vst1.8 {d1}, [ip :64], r2
++ vst1.8 {d2}, [r0 :64]
++ vst1.8 {d3}, [ip :64]
++ bx lr
++endfunc
++
++@ add_residual8x8_v(
++@ uint8_t *_dst, [r0]
++@ const int16_t *res, [r1]
++@ ptrdiff_t stride) [r2]
++
++function ff_hevc_rpi_add_residual_8x8_v_neon_8, export=1
++ vdup.16 q15, r3
++ add ip, r0, r2
++ push {r4, lr}
++ vld2.8 {d16, d17}, [r0 :128]
++ lsl r2, #1
++ vld2.8 {d18, d19}, [ip :128]
++ mov r3, #8-2
++ vld1.16 {q0, q1}, [r1 :256]!
++ add r4, r0, r2
++ vmovl.u8 q10, d17
++ add lr, ip, r2
++ vmovl.u8 q11, d19
++ vqadd.s16 q0, q10
++ vaddw.u8 q2, q15, d16
++ vqadd.s16 q1, q11
++ vaddw.u8 q3, q15, d18
++1:
++ vqmovun.s16 d20, q2
++ vqmovun.s16 d21, q0
++ vld2.8 {d16, d17}, [r4 :128], r2
++ subs r3, #2
++ vqmovun.s16 d22, q3
++ vqmovun.s16 d23, q1
++ vst2.8 {d20, d21}, [r0 :128], r2
++ vld2.8 {d18, d19}, [lr :128], r2
++ vst2.8 {d22, d23}, [ip :128], r2
++ vld1.16 {q0, q1}, [r1 :256]!
++ vmovl.u8 q10, d17
++ vmovl.u8 q11, d19
++ vqadd.s16 q0, q10
++ vaddw.u8 q2, q15, d16
++ vqadd.s16 q1, q11
++ vaddw.u8 q3, q15, d18
++ bne 1b
++
++ vqmovun.s16 d20, q2
++ vqmovun.s16 d21, q0
++ vqmovun.s16 d22, q3
++ vqmovun.s16 d23, q1
++ vst2.8 {d20, d21}, [r0 :128]
++ vst2.8 {d22, d23}, [ip :128]
++ pop {r4, pc}
++endfunc
++
++@ add_residual16x16_v(
++@ uint8_t *_dst, [r0]
++@ const int16_t *res, [r1]
++@ ptrdiff_t stride) [r2]
++
++function ff_hevc_rpi_add_residual_16x16_v_neon_8, export=1
++ vdup.16 q15, r3
++ add ip, r0, r2
++ vld2.8 {q8, q9}, [r0 :256]
++ mov r3, #16-1
++ vld1.16 {q0, q1}, [r1 :256]!
++ vmovl.u8 q11, d18
++ vmovl.u8 q12, d19
++ vqadd.s16 q0, q11
++ vaddw.u8 q11, q15, d16
++ vqadd.s16 q1, q12
++ vaddw.u8 q12, q15, d17
++1:
++ vld2.8 {q8, q9}, [ip :256], r2
++ subs r3, #1
++ vqmovun.s16 d20, q11
++ vqmovun.s16 d22, q0
++ vqmovun.s16 d21, q12
++ vqmovun.s16 d23, q1
++ vld1.16 {q0, q1}, [r1 :256]!
++ vst2.8 {q10, q11}, [r0 :256], r2
++ vmovl.u8 q11, d18
++ pldw [ip]
++ vmovl.u8 q12, d19
++ vqadd.s16 q0, q11
++ vaddw.u8 q11, q15, d16
++ vqadd.s16 q1, q12
++ vaddw.u8 q12, q15, d17
++ bne 1b
++
++ vqmovun.s16 d20, q11
++ vqmovun.s16 d22, q0
++ vqmovun.s16 d21, q12
++ vqmovun.s16 d23, q1
++ vst2.8 {q10, q11}, [r0 :256]
++ bx lr
++endfunc
++
++@ ============================================================================
++@ U & V add
++
++@ add_residual4x4_c(
++@ uint8_t *_dst, [r0]
++@ const int16_t *res, [r1]
++@ ptrdiff_t stride) [r2]
++
++function ff_hevc_rpi_add_residual_4x4_c_neon_8, export=1
++ add ip, r0, r2
++ vld1.16 {q0, q1}, [r1]! @ all of U
++ lsl r2, #1
++ vld1.8 {d16}, [r0 :64], r2
++ rsb r3, r2, #0
++ vld1.8 {d17}, [ip :64], r2
++ vld1.16 {q2, q3}, [r1] @ all of V
++ vld1.8 {d18}, [r0 :64], r3
++ vld1.8 {d19}, [ip :64], r3
++ vmovl.u8 q10, d16
++ vmovl.u8 q11, d17
++ vmovl.u8 q12, d18
++ vmovl.u8 q13, d19
++ vzip.16 q0, q2
++ vzip.16 q1, q3
++ vqadd.s16 q0, q10
++ vqadd.s16 q2, q11
++ vqadd.s16 q1, q12
++ vqadd.s16 q3, q13
++ vqmovun.s16 d0, q0
++ vqmovun.s16 d1, q2
++ vqmovun.s16 d2, q1
++ vqmovun.s16 d3, q3
++ vst1.8 {d0}, [r0 :64], r2
++ vst1.8 {d1}, [ip :64], r2
++ vst1.8 {d2}, [r0 :64]
++ vst1.8 {d3}, [ip :64]
++ bx lr
++endfunc
++
++@ add_residual8x8_c(
++@ uint8_t *_dst, [r0]
++@ const int16_t *res, [r1]
++@ ptrdiff_t stride) [r2]
++
++function ff_hevc_rpi_add_residual_8x8_c_neon_8, export=1
++ vld2.8 {d16, d17}, [r0 :128]
++ add r3, r1, #(8*8*2) @ Offset to V
++ vld1.16 {q0}, [r1 :128]!
++ add ip, r0, r2
++ vld1.16 {q1}, [r3 :128]!
++ vmovl.u8 q10, d16
++ push {lr}
++ vmovl.u8 q8, d17
++ mov lr, #8-1
++ vqadd.s16 q10, q0
++ vqadd.s16 q1, q8
++1:
++ vld2.8 {d16, d17}, [ip :128], r2
++ subs lr, #1
++ vld1.16 {q0}, [r1 :128]!
++ vqmovun.s16 d20, q10
++ vqmovun.s16 d21, q1
++ vld1.16 {q1}, [r3 :128]!
++ vst2.8 {d20, d21}, [r0 :128], r2
++ vmovl.u8 q10, d16
++ pldw [ip]
++ vmovl.u8 q8, d17
++ vqadd.s16 q10, q0
++ vqadd.s16 q1, q8
++ bne 1b
++
++ vqmovun.s16 d20, q10
++ vqmovun.s16 d21, q1
++ vst2.8 {d20, d21}, [r0 :128]
++ pop {pc}
++endfunc
++
++@ add_residual16x16_c(
++@ uint8_t *_dst, [r0]
++@ const int16_t *res, [r1]
++@ ptrdiff_t stride) [r2]
++
++function ff_hevc_rpi_add_residual_16x16_c_neon_8, export=1
++ vld2.8 {q8, q9}, [r0 :256]
++ add r3, r1, #(16*16*2) @ Offset to V
++ vld1.16 {q0, q1}, [r1 :256]!
++ add ip, r0, r2
++ vld1.16 {q2, q3}, [r3 :256]!
++ vmovl.u8 q10, d16
++ push {lr}
++ vmovl.u8 q8, d17
++ mov lr, #16-1
++ vmovl.u8 q11, d18
++ vmovl.u8 q9, d19
++ vqadd.s16 q0, q10
++ vqadd.s16 q1, q8
++ vqadd.s16 q2, q11
++ vqadd.s16 q3, q9
++1:
++ vld2.8 {q8, q9}, [ip :256], r2
++ subs lr, #1
++ vqmovun.s16 d20, q0
++ vqmovun.s16 d22, q2
++ vqmovun.s16 d21, q1
++ vqmovun.s16 d23, q3
++ vld1.16 {q0, q1}, [r1 :256]!
++ vst2.8 {d20-d23}, [r0 :256], r2
++ vld1.16 {q2, q3}, [r3 :256]!
++ vmovl.u8 q10, d16
++ pldw [ip]
++ vmovl.u8 q8, d17
++ vmovl.u8 q11, d18
++ vmovl.u8 q9, d19
++ vqadd.s16 q0, q10
++ vqadd.s16 q1, q8
++ vqadd.s16 q2, q11
++ vqadd.s16 q3, q9
++ bne 1b
++
++ vqmovun.s16 d20, q0
++ vqmovun.s16 d22, q2
++ vqmovun.s16 d21, q1
++ vqmovun.s16 d23, q3
++ vst2.8 {d20-d23}, [r0 :256]
++ pop {pc}
++endfunc
++
++@ 32x32 chroma never occurs so NIF
++
++@ ============================================================================
+diff --git a/libavcodec/arm/rpi_hevcdsp_sao_neon.S b/libavcodec/arm/rpi_hevcdsp_sao_neon.S
+new file mode 100644
+index 0000000000..b56e0f9644
+--- /dev/null
++++ b/libavcodec/arm/rpi_hevcdsp_sao_neon.S
+@@ -0,0 +1,2245 @@
++/*
++ * Copyright (c) 2014 - 2015 Seppo Tomperi <seppo.tomperi@vtt.fi>
++ * 2017 John Cox <jc@kynesim.co.uk> (for Raspberry Pi)
++ *
++ * This file is part of FFmpeg.
++ *
++ * FFmpeg is free software; you can redistribute it and/or
++ * modify it under the terms of the GNU Lesser General Public
++ * License as published by the Free Software Foundation; either
++ * version 2.1 of the License, or (at your option) any later version.
++ *
++ * FFmpeg is distributed in the hope that it will be useful,
++ * but WITHOUT ANY WARRANTY; without even the implied warranty of
++ * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
++ * Lesser General Public License for more details.
++ *
++ * You should have received a copy of the GNU Lesser General Public
++ * License along with FFmpeg; if not, write to the Free Software
++ * Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA
++ */
++
++#include "libavutil/arm/asm.S"
++#include "neon.S"
++
++.set EDGE_SRC_STRIDE, 160
++
++@ PIC jump tables are fractionally more expensive than absolute in our code
++.set jent_pic, CONFIG_PIC
++
++
++.macro sao_band_64b_8 XLAT0, XLAT1, Q_K128, I1, I2, I3, I4
++ vshr.u8 q12, q8, #3
++ \I1
++ vadd.i8 q8, \Q_K128
++ \I2
++ vshr.u8 q13, q9, #3
++ \I3
++ vadd.i8 q9, \Q_K128
++ \I4
++ vtbl.8 d24, \XLAT0, d24
++ vtbl.8 d25, \XLAT0, d25
++ vtbl.8 d26, \XLAT1, d26
++ vtbl.8 d27, \XLAT1, d27
++
++ vqadd.s8 q8, q12
++ vshr.u8 q12, q10, #3
++ vadd.i8 q10, \Q_K128
++ vqadd.s8 q9, q13
++ vshr.u8 q13, q11, #3
++ vadd.i8 q11, \Q_K128
++
++ vtbl.8 d24, \XLAT0, d24
++ vtbl.8 d25, \XLAT0, d25
++ vtbl.8 d26, \XLAT1, d26
++ vtbl.8 d27, \XLAT1, d27
++ vqadd.s8 q10, q12
++ vsub.i8 q8, \Q_K128
++ vqadd.s8 q11, q13
++ vsub.i8 q9, \Q_K128
++ vsub.i8 q10, \Q_K128
++ vsub.i8 q11, \Q_K128
++.endm
++
++.macro sao_band_16b_8 XLAT0, XLAT1, Q_K128, L1, L2, L3, L4, L5, S1, S2, S3, S4
++ \L1
++ \L2
++ \L3
++ \L4
++ \L5
++ vadd.i8 q12, q8, \Q_K128
++ vshr.u8 q8, #3
++ vtbl.8 d16, \XLAT0, d16
++ vtbl.8 d17, \XLAT1, d17
++ vqadd.s8 q12, q8
++ bmi 2f
++1: \L1
++ \L2
++ \L3
++ \L4
++ \L5
++ vsub.i8 q13, q12, \Q_K128
++ vadd.i8 q12, q8, \Q_K128
++ vshr.u8 q8, #3
++ \S1
++ \S2
++ \S3
++ \S4
++ vtbl.8 d16, \XLAT0, d16
++ vtbl.8 d17, \XLAT1, d17
++ vqadd.s8 q12, q8
++ bpl 1b
++2: vsub.i8 q13, q12, \Q_K128
++ \S1
++ \S2
++ \S3
++ \S4
++.endm
++
++
++.macro clip16_4 Q0, Q1, Q2, Q3, Q_MIN, Q_MAX
++ vmax.s16 \Q0, \Q_MIN
++ vmax.s16 \Q1, \Q_MIN
++ vmax.s16 \Q2, \Q_MIN
++ vmax.s16 \Q3, \Q_MIN
++ vmin.s16 \Q0, \Q_MAX
++ vmin.s16 \Q1, \Q_MAX
++ vmin.s16 \Q2, \Q_MAX
++ vmin.s16 \Q3, \Q_MAX
++.endm
++
++@ Clobbers q12, q13
++.macro sao_band_64b_16 Q0, Q1, Q2, Q3, XLAT0, XLAT1, Q_MIN, Q_MAX, bit_depth, I1, I2
++ vshrn.i16 d24, \Q0, #(\bit_depth - 5)
++ vshrn.i16 d25, \Q1, #(\bit_depth - 5)
++ vshrn.i16 d26, \Q2, #(\bit_depth - 5)
++ \I1
++ vtbl.8 d24, \XLAT0, d24
++ vshrn.i16 d27, \Q3, #(\bit_depth - 5)
++ vtbl.8 d25, \XLAT1, d25
++ \I2
++ vtbl.8 d26, \XLAT0, d26
++ vtbl.8 d27, \XLAT1, d27
++ vaddw.s8 \Q0, d24
++ vaddw.s8 \Q1, d25
++ vaddw.s8 \Q2, d26
++ vaddw.s8 \Q3, d27
++ clip16_4 \Q0, \Q1, \Q2, \Q3, \Q_MIN, \Q_MAX
++.endm
++
++@ Clobbers q10, q11, q12
++.macro sao_band_32b_16 Q0, Q1, XLAT0, XLAT1, Q_MIN, Q_MAX, bit_depth, L1, L2, L3, L4, L5, S1, S2, S3, S4
++ \L1
++ \L2
++ \L3
++ \L4
++ \L5
++ vshrn.i16 d24, \Q0, #\bit_depth - 5
++ vshrn.i16 d25, \Q1, #\bit_depth - 5
++ vtbl.8 d24, \XLAT0, d24
++ vtbl.8 d25, \XLAT1, d25
++ vaddw.s8 q10, \Q0, d24
++ vaddw.s8 q11, \Q1, d25
++ bmi 2f
++1: \L1
++ \L2
++ \L3
++ \L4
++ \L5
++ vmax.s16 q10, \Q_MIN
++ vmax.s16 q11, \Q_MIN
++ vshrn.i16 d24, \Q0, #\bit_depth - 5
++ vshrn.i16 d25, \Q1, #\bit_depth - 5
++ vmin.s16 q10, \Q_MAX
++ vmin.s16 q11, \Q_MAX
++ \S1
++ \S2
++ \S3
++ \S4
++ vtbl.8 d24, \XLAT0, d24
++ vtbl.8 d25, \XLAT1, d25
++ vaddw.s8 q10, \Q0, d24
++ vaddw.s8 q11, \Q1, d25
++ bpl 1b
++2: vmax.s16 q10, \Q_MIN
++ vmax.s16 q11, \Q_MIN
++ vmin.s16 q10, \Q_MAX
++ vmin.s16 q11, \Q_MAX
++ \S1
++ \S2
++ \S3
++ \S4
++.endm
++
++
++@ Standard coding rules for sao_offset_abs limit it to 0-31 (Table 9-38)
++@ so we are quite safe stuffing it into a byte array
++@ There may be a subsequent shl by log2_sao_offset_scale_luma/chroma
++@ (7.4.3.3.2 && 7-70) but we should still be safe to at least 12 bits of
++@ precision
++
++@ This, somewhat nasty, bit of code builds the {d0-d3} translation
++@ array via the stack
++@ Given that sao_left_class > 28 can cause wrap we can't just poke
++@ all 4 bytes in at once
++@
++@ It also loads other common regs
++
++@ Beware that the offset read here overrreads by 6 bytes so source must be sized appropriately
++function band_load_y
++ ldr ip, [sp, #16] @ &sao_offset_val[0]
++ ldr r4, [sp, #20] @ sao_left_class
++ vmov.i64 d4, #0
++ vmov.i64 q0, #0
++ pld [r1]
++ vld2.8 {q8}, [ip]
++ sub ip, sp, #8*5
++ vmov.i64 q1, #0
++ add r4, ip, r4
++ vpush {d0-d4} @ Put zero array on stack
++ vshr.u64 d16, d16, #8 @ 1st interesting val is [1]
++ ldr ip, [ip, #8*5 + 28] @ height
++ vst1.32 {d16[0]}, [r4]
++ add r4, r1, r3
++ vpop {d0-d4} @ Pop modified array
++ sub ip, ip, #1
++ vorr d0, d0, d4
++ bx lr
++endfunc
++
++@ Beware that offset reads here overrread by 6 bytes so source must be sized appropriately
++function band_load_c
++ ldr ip, [sp, #16] @ &sao_offset_val1[0]
++ ldr r4, [sp, #20] @ sao_left_class1
++ vmov.i64 d24, #0
++ vmov.i64 q10, #0
++ pld [r1]
++ vld2.8 {q8}, [ip]
++ sub ip, sp, #8*5
++ vmov.i64 q11, #0
++ add r4, ip, r4
++ ldr ip, [sp, #24] @ &sao_offset_val2[0]
++ vpush {d20-d24} @ Put zero array on stack
++ vld2.8 {q9}, [ip]
++ vshr.u64 d16, d16, #8 @ 1st interesting val is [1]
++ ldr ip, [sp, #8*5 + 28] @ sao_left_class2
++ vst1.32 {d16[0]}, [r4]
++ add ip, sp, ip
++ vshr.u64 d18, d18, #8 @ 1st interesting val is [1]
++ vldmia sp, {d0-d3} @ Load modified array
++ vldr d16, [sp, #8*4]
++ add r4, r1, r3
++ vstmia sp, {d20-d24} @ Put zero array on stack (again)
++ vst1.32 {d18[0]}, [ip]
++ vorr d0, d0, d16
++ vldmia sp, {d4-d7} @ Load modified array
++ vldr d18, [sp, #8*4]
++ ldr ip, [sp, #8*5 + 36] @ height
++ add sp, sp, #8*5
++ vorr d4, d4, d18
++ sub ip, ip, #1
++ bx lr
++endfunc
++
++
++@ ff_hevc_rpi_sao_band_64_neon_8 (
++@ uint8_t *_dst, [r0]
++@ uint8_t *_src, [r1]
++@ ptrdiff_t stride_dst, [r2]
++@ ptrdiff_t stride_src, [r3]
++@ int16_t *sao_offset_val, [sp, #0]
++@ int sao_left_class, [sp, #4]
++@ int width, [sp, #8]
++@ int height) [sp, #12]
++
++function ff_hevc_rpi_sao_band_64_neon_8, export=1
++ push {r4-r6, lr}
++ vmov.u8 q15, #128
++ bl band_load_y
++
++1: vldmia r1, {q8-q11}
++ sao_band_64b_8 {d0-d3}, {d0-d3}, q15, \
++ "pld [r4]", \
++ "subs ip, #1", \
++ "it ne; addne r4, r3", \
++ "add r1, r3"
++ vstmia r0, {q8-q11}
++ add r0, r2
++ bpl 1b
++
++ pop {r4-r6, pc}
++endfunc
++
++@ ff_hevc_rpi_sao_band_32_neon_8 (
++@ uint8_t *_dst, [r0]
++@ uint8_t *_src, [r1]
++@ ptrdiff_t stride_dst, [r2]
++@ ptrdiff_t stride_src, [r3]
++@ int16_t *sao_offset_val, [sp, #0]
++@ int sao_left_class, [sp, #4]
++@ int width, [sp, #8]
++@ int height) [sp, #12]
++
++function ff_hevc_rpi_sao_band_32_neon_8, export=1
++ push {r4-r6, lr}
++ add r5, r0, r2
++ add r6, r1, r3
++ lsl r2, #1
++ lsl r3, #1
++ vmov.u8 q15, #128
++ bl band_load_y
++
++1: vld1.8 { q8, q9 }, [r1, :128], r3
++ subs ip, #2
++ vld1.8 {q10, q11}, [r6, :128], r3
++
++ sao_band_64b_8 {d0-d3}, {d0-d3}, q15
++
++ vst1.8 { q8, q9 }, [r0, :128], r2
++ vst1.8 {q10, q11}, [r5, :128], r2
++ bpl 1b
++
++ pop {r4-r6, pc}
++endfunc
++
++@ ff_hevc_rpi_sao_band_16_neon_8 (
++@ uint8_t *_dst, [r0]
++@ uint8_t *_src, [r1]
++@ ptrdiff_t stride_dst, [r2]
++@ ptrdiff_t stride_src, [r3]
++@ int16_t *sao_offset_val, [sp, #0]
++@ int sao_left_class, [sp, #4]
++@ int width, [sp, #8]
++@ int height) [sp, #12]
++
++function ff_hevc_rpi_sao_band_16_neon_8, export=1
++ push {r4-r6, lr}
++ add r5, r0, r2
++ add r6, r1, r3
++ lsl r2, #1
++ lsl r3, #1
++ vmov.u8 q15, #128
++ bl band_load_y
++
++1: vld1.8 { q8}, [r1, :128], r3
++ subs ip, #4
++ vld1.8 { q9}, [r6, :128], r3
++ vld1.8 {q10}, [r1, :128], r3
++ vld1.8 {q11}, [r6, :128], r3
++
++ sao_band_64b_8 {d0-d3}, {d0-d3}, q15
++
++ vst1.8 { q8}, [r0, :128], r2
++ vst1.8 { q9}, [r5, :128], r2
++ vst1.8 {q10}, [r0, :128], r2
++ vst1.8 {q11}, [r5, :128], r2
++ bpl 1b
++
++ pop {r4-r6, pc}
++endfunc
++
++@ ff_hevc_rpi_sao_band_8_neon_8 (
++@ uint8_t *_dst, [r0]
++@ uint8_t *_src, [r1]
++@ ptrdiff_t stride_dst, [r2]
++@ ptrdiff_t stride_src, [r3]
++@ int16_t *sao_offset_val, [sp, #0]
++@ int sao_left_class, [sp, #4]
++@ int width, [sp, #8]
++@ int height) [sp, #12]
++
++function ff_hevc_rpi_sao_band_8_neon_8, export=1
++ ldr ip, [sp, #8] @ width
++ push {r4-r6, lr}
++ vmov.u8 q15, #128
++ cmp ip, #8
++ bl band_load_y
++ add r5, r0, r2
++ add r6, r1, r3
++ lsl r2, #1
++ lsl r3, #1
++ blt 4f
++
++ sao_band_16b_8 {d0-d3}, {d0-d3}, q15, \
++ "vld1.8 {d16}, [r1, :64], r3", \
++ "subs ip, #2", \
++ "vld1.8 {d17}, [r6, :64], r3", \
++ "", \
++ "", \
++ "vst1.8 {d26}, [r0, :64], r2", \
++ "vst1.8 {d27}, [r5, :64], r2"
++ pop {r4-r6, pc}
++4:
++ sao_band_16b_8 {d0-d3}, {d0-d3}, q15, \
++ "vld1.32 {d16[0]}, [r1, :32], r3", \
++ "subs ip, #4", \
++ "vld1.32 {d16[1]}, [r6, :32], r3", \
++ "vld1.32 {d17[0]}, [r1, :32], r3", \
++ "vld1.32 {d17[1]}, [r6, :32], r3", \
++ "vst1.32 {d26[0]}, [r0, :32], r2", \
++ "vst1.32 {d26[1]}, [r5, :32], r2", \
++ "vst1.32 {d27[0]}, [r0, :32], r2", \
++ "vst1.32 {d27[1]}, [r5, :32], r2"
++ pop {r4-r6, pc}
++endfunc
++
++@ ff_hevc_rpi_sao_band_c_32_neon_8(
++@ uint8_t * dst [r0]
++@ uint8_t * src [r1]
++@ uint32_t dst_stride [r2]
++@ uint32_t src_stride [r3]
++@ const int16_t * table1 sp[0]
++@ uint32_t offset1 sp[4]
++@ const int16_t * table2 sp[8]
++@ uint32_t offset2 sp[12]
++@ int width sp[16]
++@ int height sp[20]
++
++function ff_hevc_rpi_sao_band_c_32_neon_8, export=1
++ push {r4-r6, lr}
++ add r5, r0, #32
++ add r6, r1, #32
++ vmov.u8 q15, #128
++ bl band_load_c
++
++1: vld2.8 { q8, q9 }, [r1, :128], r3
++ subs ip, #1
++ vld2.8 {q10, q11}, [r6, :128], r3
++
++ sao_band_64b_8 {d0-d3}, {d4-d7}, q15, \
++ "pld [r4]", \
++ "it ne; addne r4, r3"
++
++ vst2.8 { q8, q9 }, [r0, :128], r2
++ vst2.8 {q10, q11}, [r5, :128], r2
++ bpl 1b
++
++ pop {r4-r6, pc}
++endfunc
++
++@ ff_hevc_rpi_sao_band_c_16_neon_8(
++@ uint8_t * dst [r0]
++@ uint8_t * src [r1]
++@ uint32_t dst_stride [r2]
++@ uint32_t src_stride [r3]
++@ const int16_t * table1 sp[0]
++@ uint32_t offset1 sp[4]
++@ const int16_t * table2 sp[8]
++@ uint32_t offset2 sp[12]
++@ int width sp[16]
++@ int height sp[20]
++
++function ff_hevc_rpi_sao_band_c_16_neon_8, export=1
++ push {r4-r6, lr}
++ add r5, r0, r2
++ add r6, r1, r3
++ lsl r2, #1
++ lsl r3, #1
++ vmov.u8 q15, #128
++ bl band_load_c
++
++1: vld2.8 { q8, q9 }, [r1, :128], r3
++ subs ip, #2
++ vld2.8 {q10, q11}, [r6, :128], r3
++
++ sao_band_64b_8 {d0-d3}, {d4-d7}, q15
++
++ vst2.8 { q8, q9 }, [r0, :128], r2
++ vst2.8 {q10, q11}, [r5, :128], r2
++ bpl 1b
++
++ pop {r4-r6, pc}
++endfunc
++
++@ ff_hevc_rpi_sao_band_c_8_neon_8(
++@ uint8_t * dst [r0]
++@ uint8_t * src [r1]
++@ uint32_t dst_stride [r2]
++@ uint32_t src_stride [r3]
++@ const int16_t * table1 sp[0]
++@ uint32_t offset1 sp[4]
++@ const int16_t * table2 sp[8]
++@ uint32_t offset2 sp[12]
++@ int width sp[16]
++@ int height sp[20]
++
++function ff_hevc_rpi_sao_band_c_8_neon_8, export=1
++ ldr ip, [sp, #16] @ width
++ push {r4-r6, lr}
++ vmov.u8 q15, #128
++ cmp ip, #8
++ bl band_load_c
++ blt 4f
++
++ sao_band_16b_8 {d0-d3}, {d4-d7}, q15, \
++ "vld2.8 {d16-d17}, [r1, :128], r3", \
++ "subs ip, #1", \
++ "", \
++ "", \
++ "", \
++ "vst2.8 {d26-d27}, [r0, :128], r2"
++ pop {r4-r6, pc}
++4:
++ add r5, r0, r2
++ add r6, r1, r3
++ lsl r2, #1
++ lsl r3, #1
++ sao_band_16b_8 {d0-d3}, {d4-d7}, q15, \
++ "vld1.8 {d16}, [r1, :64], r3", \
++ "subs ip, #2", \
++ "vld1.8 {d17}, [r6, :64], r3", \
++ "vuzp.8 d16, d17", \
++ "", \
++ "vzip.8 d26, d27", \
++ "vst1.8 {d26}, [r0, :64], r2", \
++ "vst1.8 {d27}, [r5, :64], r2"
++ pop {r4-r6, pc}
++endfunc
++
++
++@ ff_hevc_rpi_sao_band_64_neon_10 (
++@ uint8_t *_dst, [r0]
++@ uint8_t *_src, [r1]
++@ ptrdiff_t stride_dst, [r2]
++@ ptrdiff_t stride_src, [r3]
++@ int16_t *sao_offset_val, [sp, #0]
++@ int sao_left_class, [sp, #4]
++@ int width, [sp, #8]
++@ int height) [sp, #12]
++
++.macro band_64_16 bit_depth
++ push {r4-r6, lr}
++ vmov.i64 q2, #0
++ vmov.i16 q3, #(1 << \bit_depth) - 1
++ bl band_load_y
++ vpush {q4-q7}
++
++1: vldm r1, {q4-q11}
++ sao_band_64b_16 q4, q5, q6, q7, {d0-d3}, {d0-d3}, q2, q3, \bit_depth, \
++ "subs ip, #1", \
++ "add r1, r3"
++ sao_band_64b_16 q8, q9, q10, q11, {d0-d3}, {d0-d3}, q2, q3, \bit_depth
++ vstm r0, {q4-q11}
++ add r0, r2
++ bpl 1b
++
++ vpop {q4-q7}
++ pop {r4-r6, pc}
++.endm
++
++function ff_hevc_rpi_sao_band_64_neon_10, export=1
++ band_64_16 10
++endfunc
++
++@ ff_hevc_rpi_sao_band_32_neon_10 (
++@ uint8_t *_dst, [r0]
++@ uint8_t *_src, [r1]
++@ ptrdiff_t stride_dst, [r2]
++@ ptrdiff_t stride_src, [r3]
++@ int16_t *sao_offset_val, [sp, #0]
++@ int sao_left_class, [sp, #4]
++@ int width, [sp, #8]
++@ int height) [sp, #12]
++
++.macro band_32_16 bit_depth
++ push {r4-r6, lr}
++ vmov.i64 q2, #0
++ vmov.i16 q3, #(1 << \bit_depth) - 1
++ bl band_load_y
++
++1: vldm r1, {q8-q11}
++ sao_band_64b_16 q8, q9, q10, q11, {d0-d3}, {d0-d3}, q2, q3, \bit_depth, \
++ "subs ip, #1", \
++ "add r1, r3"
++ vstm r0, {q8-q11}
++ add r0, r2
++ bpl 1b
++
++ pop {r4-r6, pc}
++.endm
++
++function ff_hevc_rpi_sao_band_32_neon_10, export=1
++ band_32_16 10
++endfunc
++
++@ ff_hevc_rpi_sao_band_16_neon_10 (
++@ uint8_t *_dst, [r0]
++@ uint8_t *_src, [r1]
++@ ptrdiff_t stride_dst, [r2]
++@ ptrdiff_t stride_src, [r3]
++@ int16_t *sao_offset_val, [sp, #0]
++@ int sao_left_class, [sp, #4]
++@ int width, [sp, #8]
++@ int height) [sp, #12]
++
++.macro band_16_16 bit_depth
++ push {r4-r6, lr}
++ add r5, r0, r2
++ add r6, r1, r3
++ lsl r2, #1
++ lsl r3, #1
++ vmov.i64 q14, #0
++ vmov.i16 q15, #(1 << \bit_depth) - 1
++ bl band_load_y
++
++1: vld1.16 { q8, q9 }, [r1, :128], r3
++ subs r12, #2
++ vld1.16 {q10, q11}, [r6, :128], r3
++ sao_band_64b_16 q8, q9, q10, q11, {d0-d3}, {d0-d3}, q14, q15, \bit_depth
++ vst1.16 { q8, q9 }, [r0, :128], r2
++ vst1.16 {q10, q11}, [r5, :128], r2
++ bpl 1b
++
++ pop {r4-r6, pc}
++.endm
++
++function ff_hevc_rpi_sao_band_16_neon_10, export=1
++ band_16_16 10
++endfunc
++
++@ ff_hevc_rpi_sao_band_8_neon_10 (
++@ uint8_t *_dst, [r0]
++@ uint8_t *_src, [r1]
++@ ptrdiff_t stride_dst, [r2]
++@ ptrdiff_t stride_src, [r3]
++@ int16_t *sao_offset_val, [sp, #0]
++@ int sao_left_class, [sp, #4]
++@ int width, [sp, #8]
++@ int height) [sp, #12]
++
++.macro band_8_16 bit_depth
++ ldr ip, [sp, #8] @ width
++ push {r4-r6, lr}
++ vmov.i64 q14, #0
++ cmp ip, #8
++ vmov.i16 q15, #(1 << \bit_depth) - 1
++ bl band_load_y
++ add r5, r0, r2
++ add r6, r1, r3
++ lsl r2, #1
++ lsl r3, #1
++ blt 4f
++
++ sao_band_32b_16 q8, q9, {d0-d3}, {d0-d3}, q14, q15, \bit_depth, \
++ "vld1.16 {q8}, [r1, :128], r3", \
++ "subs ip, #2", \
++ "vld1.16 {q9}, [r6, :128], r3", \
++ "", \
++ "", \
++ "vst1.16 {q10}, [r0, :128], r2", \
++ "vst1.16 {q11}, [r5, :128], r2"
++ pop {r4-r6, pc}
++4:
++ sao_band_32b_16 q8, q9, {d0-d3}, {d0-d3}, q14, q15, \bit_depth, \
++ "vld1.16 {d16}, [r1, :64], r3", \
++ "subs ip, #4", \
++ "vld1.16 {d17}, [r6, :64], r3", \
++ "vld1.16 {d18}, [r1, :64], r3", \
++ "vld1.16 {d19}, [r6, :64], r3", \
++ "vst1.16 {d20}, [r0, :64], r2", \
++ "vst1.16 {d21}, [r5, :64], r2", \
++ "vst1.16 {d22}, [r0, :64], r2", \
++ "vst1.16 {d23}, [r5, :64], r2"
++ pop {r4-r6, pc}
++.endm
++
++function ff_hevc_rpi_sao_band_8_neon_10, export=1
++ band_8_16 10
++endfunc
++
++
++@ ff_hevc_rpi_sao_band_c_32_neon_10(
++@ uint8_t * dst [r0]
++@ uint8_t * src [r1]
++@ uint32_t dst_stride [r2]
++@ uint32_t src_stride [r3]
++@ const int16_t * table1 sp[0]
++@ uint32_t offset1 sp[4]
++@ const int16_t * table2 sp[8]
++@ uint32_t offset2 sp[12]
++@ int width sp[16]
++@ int height sp[20]
++
++.macro band_c_32_16 bit_depth
++ push {r4-r6, lr}
++ add r5, r0, #32
++ add r6, r1, #32
++ sub r2, #64
++ sub r3, #64
++ vmov.i64 q14, #0
++ vmov.i16 q15, #(1 << \bit_depth) - 1
++ bl band_load_c
++ mov lr, #64
++ vpush {q4-q7}
++
++1: vld2.16 { q4, q5 }, [r1, :128], lr
++ subs ip, #1
++ vld2.16 { q6, q7 }, [r6, :128], lr
++ vld2.16 { q8, q9 }, [r1, :128], r3
++ vld2.16 {q10, q11}, [r6, :128], r3
++
++ sao_band_64b_16 q4, q5, q6, q7, {d0-d3}, {d4-d7}, q14, q15, \bit_depth, \
++ "pld [r4]", \
++ "it ne; addne r4, r3"
++ sao_band_64b_16 q8, q9, q10, q11, {d0-d3}, {d4-d7}, q14, q15, \bit_depth
++
++ vst2.16 { q4, q5 }, [r0, :128], lr
++ vst2.16 { q6, q7 }, [r5, :128], lr
++ vst2.16 { q8, q9 }, [r0, :128], r2
++ vst2.16 {q10, q11}, [r5, :128], r2
++
++ bpl 1b
++
++ vpop {q4-q7}
++ pop {r4-r6, pc}
++.endm
++
++function ff_hevc_rpi_sao_band_c_32_neon_10, export=1
++ band_c_32_16 10
++endfunc
++
++
++@ ff_hevc_rpi_sao_band_c_16_neon_10(
++@ uint8_t * dst [r0]
++@ uint8_t * src [r1]
++@ uint32_t dst_stride [r2]
++@ uint32_t src_stride [r3]
++@ const int16_t * table1 sp[0]
++@ uint32_t offset1 sp[4]
++@ const int16_t * table2 sp[8]
++@ uint32_t offset2 sp[12]
++@ int width sp[16]
++@ int height sp[20]
++
++.macro band_c_16_16 bit_depth
++ push {r4-r6, lr}
++ add r5, r0, #32
++ add r6, r1, #32
++ vmov.i64 q14, #0
++ vmov.i16 q15, #(1 << \bit_depth) - 1
++ bl band_load_c
++
++1: vld2.16 { q8, q9 }, [r1, :128], r3
++ subs ip, #1
++ vld2.16 {q10, q11}, [r6, :128], r3
++
++ sao_band_64b_16 q4, q5, q6, q7, {d0-d3}, {d4-d7}, q14, q15, \bit_depth
++ sao_band_64b_16 q8, q9, q10, q11, {d0-d3}, {d4-d7}, q14, q15, \bit_depth
++
++ vst2.16 { q8, q9 }, [r0, :128], r2
++ vst2.16 {q10, q11}, [r5, :128], r2
++
++ bpl 1b
++ pop {r4-r6, pc}
++.endm
++
++function ff_hevc_rpi_sao_band_c_16_neon_10, export=1
++ band_c_16_16 10
++endfunc
++
++
++@ ff_hevc_rpi_sao_band_c_8_neon_10(
++@ uint8_t * dst [r0]
++@ uint8_t * src [r1]
++@ uint32_t dst_stride [r2]
++@ uint32_t src_stride [r3]
++@ const int16_t * table1 sp[0]
++@ uint32_t offset1 sp[4]
++@ const int16_t * table2 sp[8]
++@ uint32_t offset2 sp[12]
++@ int width sp[16]
++@ int height sp[20]
++
++.macro band_c_8_16 bit_depth
++ ldr ip, [sp, #16] @ width
++ push {r4-r6, lr}
++ vmov.i64 q14, #0
++ cmp ip, #8
++ vmov.i16 q15, #(1 << \bit_depth) - 1
++ bl band_load_c
++ blt 4f
++
++ sao_band_32b_16 q8, q9, {d0-d3}, {d4-d7}, q14, q15, \bit_depth, \
++ "vld2.16 {q8,q9}, [r1, :128], r3", \
++ "subs ip, #1", \
++ "", \
++ "", \
++ "", \
++ "vst2.16 {q10,q11}, [r0, :128], r2"
++ pop {r4-r6, pc}
++4:
++ add r5, r0, r2
++ add r6, r1, r3
++ lsl r2, #1
++ lsl r3, #1
++ sao_band_32b_16 q8, q9, {d0-d3}, {d4-d7}, q14, q15, \bit_depth, \
++ "vld2.16 {d16,d18}, [r1, :128], r3", \
++ "subs ip, #2", \
++ "vld2.16 {d17,d19}, [r6, :128], r3", \
++ "", \
++ "", \
++ "vst2.16 {d20,d22}, [r0, :128], r2", \
++ "vst2.16 {d21,d23}, [r5, :128], r2"
++ pop {r4-r6, pc}
++.endm
++
++function ff_hevc_rpi_sao_band_c_8_neon_10, export=1
++ band_c_8_16 10
++endfunc
++
++
++@ =============================================================================
++@ SAO EDGE
++
++@ r0 destination address
++@ r2 stride to post-increment r0 with
++@ [r5] translate values
++@
++@ a <- c <- b
++@ a in q0 - q3
++@ c in q4 - q7
++@ b in q8 - q11
++@
++@ q12-15 used as temp
++@
++@ Can be used for both Y & C as we unzip/zip the deltas and
++@ transform "u/v" separately via d26/d27. For Y d26=d27
++
++function edge_64b_body_8
++
++ vcgt.u8 q12, q4, q0 @ c > a -> -1 , otherwise 0
++ vcgt.u8 q13, q5, q1
++ vcgt.u8 q14, q6, q2
++ vcgt.u8 q15, q7, q3
++
++ vcgt.u8 q0, q4 @ a > c -> -1 , otherwise 0
++ vcgt.u8 q1, q5
++ vcgt.u8 q2, q6
++ vcgt.u8 q3, q7
++
++ vsub.s8 q0, q12 @ a = sign(c-a)
++ vsub.s8 q1, q13
++ vsub.s8 q2, q14
++ vsub.s8 q3, q15
++
++ vcgt.u8 q12, q4, q8 @ c > b -> -1 , otherwise 0
++ vcgt.u8 q13, q5, q9
++ vcgt.u8 q14, q6, q10
++ vcgt.u8 q15, q7, q11
++
++ vsub.s8 q0, q12
++ vsub.s8 q1, q13
++ vsub.s8 q2, q14
++ vsub.s8 q3, q15
++
++ vcgt.u8 q12, q8, q4 @ c < b -> -1 , otherwise 0
++ vcgt.u8 q13, q9, q5
++ vcgt.u8 q14, q10, q6
++ vcgt.u8 q15, q11, q7
++
++ vadd.s8 q0, q12 @ a = sign(c-a) + sign(c-b)
++ vadd.s8 q1, q13
++ vmov.u8 q12, #2
++ vadd.s8 q2, q14
++ vadd.s8 q3, q15
++
++ vadd.s8 q0, q12
++ vadd.s8 q1, q12
++
++ vld1.8 {d26, d27}, [r5]
++
++ vadd.s8 q2, q12
++ vuzp.8 q0, q1
++ vmov.u8 q15, #128
++ vadd.s8 q3, q12 @ a = 2 + sign(c-a) + sign(c-b)
++
++ vtbl.8 d0, {d26}, d0
++ vadd.s8 q12, q4, q15 @ Add -128 so we can use saturating signed add
++
++ vtbl.8 d1, {d26}, d1
++ vadd.s8 q14, q5, q15
++
++ vtbl.8 d2, {d27}, d2
++ vuzp.8 q2, q3
++
++ vtbl.8 d3, {d27}, d3
++
++ vtbl.8 d4, {d26}, d4
++ vzip.8 q0, q1
++
++ vtbl.8 d5, {d26}, d5
++ vqadd.s8 q0, q12
++ vqadd.s8 q1, q14
++ vadd.s8 q12, q6, q15 @ Add -128 so we can use saturating signed add
++
++ vtbl.8 d6, {d27}, d6
++ vtbl.8 d7, {d27}, d7
++ vadd.s8 q14, q7, q15 @ Add -128 so we can use saturating signed add
++ vzip.8 q2, q3
++
++ vsub.s8 q0, q15
++ vqadd.s8 q2, q12
++ vqadd.s8 q3, q14
++ vsub.s8 q1, q15
++ vsub.s8 q2, q15
++ vsub.s8 q3, q15
++
++ bx lr
++endfunc
++
++@ r0 destination address
++@ r2 stride to post-increment r0 with
++@ r4 upper clip value
++@ [r5] translate values
++@
++@ a <- c <- b
++@ a in q0 - q3
++@ c in q4 - q7
++@ b in q8 - q11
++@
++@ q12-15 used as temp
++@
++@ Can be used for both Y & C as we unzip/zip the deltas and
++@ transform "u/v" separately via d26/d27. For Y d26=d27
++
++function edge_64b_body_16
++
++ vcgt.u16 q12, q4, q0 // c > a -> -1 , otherwise 0
++ vcgt.u16 q13, q5, q1
++ vcgt.u16 q14, q6, q2
++ vcgt.u16 q15, q7, q3
++
++ vcgt.u16 q0, q0, q4 // a > c -> -1 , otherwise 0
++ vcgt.u16 q1, q1, q5
++ vcgt.u16 q2, q2, q6
++ vcgt.u16 q3, q3, q7
++
++ vsub.s16 q0, q0, q12 // a = sign(c-a)
++ vsub.s16 q1, q1, q13
++ vsub.s16 q2, q2, q14
++ vsub.s16 q3, q3, q15
++
++ vcgt.u16 q12, q4, q8 // c > b -> -1 , otherwise 0
++ vcgt.u16 q13, q5, q9
++ vcgt.u16 q14, q6, q10
++ vcgt.u16 q15, q7, q11
++
++ vsub.s16 q0, q0, q12
++ vsub.s16 q1, q1, q13
++ vsub.s16 q2, q2, q14
++ vsub.s16 q3, q3, q15
++
++ vcgt.u16 q12, q8, q4 // c < b -> -1 , otherwise 0
++ vcgt.u16 q13, q9, q5
++ vcgt.u16 q14, q10, q6
++ vcgt.u16 q15, q11, q7
++
++ vadd.s16 q0, q0, q12 // a = sign(c-a) + sign(c-b)
++ vadd.s16 q1, q1, q13
++ vadd.s16 q2, q2, q14
++ vadd.s16 q3, q3, q15
++
++ vmov.u8 q12, #2
++
++ vmovn.s16 d0, q0
++ vmovn.s16 d1, q1
++ vmovn.s16 d2, q2
++ vmovn.s16 d3, q3
++
++ vldr d26, [r5]
++
++ vuzp.8 q0, q1
++
++ vldr d27, [r5, #8]
++
++ vadd.s8 q0, q0, q12
++ vadd.s8 q1, q1, q12
++
++ vmov.i64 q12, #0
++
++ vtbl.8 d0, {d26}, d0
++ vtbl.8 d1, {d26}, d1
++ vtbl.8 d2, {d27}, d2
++ vtbl.8 d3, {d27}, d3
++
++ vdup.i16 q13, r4
++
++ vzip.8 q0, q1
++
++ @ Avoid overwrite whilst widening
++ vaddw.s8 q2, q6, d2
++ vaddw.s8 q3, q7, d3
++ vaddw.s8 q1, q5, d1
++ vaddw.s8 q0, q4, d0
++
++ @ now clip
++ clip16_4 q2, q3, q1, q0, q12, q13
++
++ bx lr
++endfunc
++
++
++@ a <- c <- b
++@ a in q0
++@ c in q1
++@ b in q2
++@ Temp q3, q9, q10
++@
++@ d16, d17 (q8) xlat U, V
++@ q14.u8 #2
++@ q15.u8 #128
++
++function edge_16b_body_8
++ vcgt.u8 q9, q0, q1 @ a > c -> -1 , otherwise 0
++ vadd.u8 q9, q14, q9
++ vcgt.u8 q0, q1, q0 @ c > a -> -1 , otherwise 0
++ vsub.u8 q9, q9, q0
++ vcgt.u8 q0, q2, q1 @ c < b -> -1 , otherwise 0
++ vadd.u8 q9, q9, q0
++ vcgt.u8 q0, q1, q2 @ c > b -> -1 , otherwise 0
++ vsub.u8 q0, q9, q0
++
++ vadd.s8 q3, q1, q15 @ Add -128 so we can use saturating signed add
++
++ vuzp.8 d0, d1
++
++ vtbl.8 d0, {d16}, d0
++ vtbl.8 d1, {d17}, d1
++
++ vzip.8 d0, d1
++ vqadd.s8 q0, q3
++ vsub.s8 q0, q15
++
++ bx lr
++endfunc
++
++@ a <- c <- b
++@ a in q0
++@ c in q1
++@ b in q2
++@ Temp q3
++@
++@ q12, #0
++@ d16, d17 xlat U, V
++@ q14.u8 #2
++@ q15.u16 max
++function edge_16b_body_16
++ vcgt.u16 q9, q0, q1 @ a > c -> -1 , otherwise 0
++ vadd.u16 q9, q14, q9
++ vcgt.u16 q0, q1, q0 @ c > a -> -1 , otherwise 0
++ vsub.u16 q9, q9, q0
++ vcgt.u16 q0, q2, q1 @ c < b -> -1 , otherwise 0
++ vadd.u16 q9, q9, q0
++ vcgt.u16 q0, q1, q2 @ c > b -> -1 , otherwise 0
++ vsub.u16 q0, q9, q0
++
++ vmovn.s16 d0, q0
++ @ d1 will have random contents that we transform but
++ @ that doesn't matter as we then discard them
++ vuzp.8 d0, d1
++
++ vtbl.8 d0, {d16}, d0
++ vtbl.8 d1, {d17}, d1
++
++ vzip.8 d0, d1
++
++ vaddw.s8 q0, q1, d0
++
++ @ now clip
++ vmax.s16 q0, q12
++ vmin.s16 q0, q15
++ bx lr
++endfunc
++
++
++@ ff_hevc_rpi_sao_edge_[c_]xx_neon(
++@ uint8_t *_dst, [r0]
++@ const uint8_t *_src, [r1]
++@ ptrdiff_t stride_dst, [r2]
++@ const int16_t *_sao_offset_val_u, [r3]
++@ const int16_t *_sao_offset_val_v, [sp, #0] // Chroma only
++@ int eo, [sp, #sp_base + 0]
++@ int width, [sp, #sp_base + 4]
++@ int height) [sp, #sp_base + 8]
++
++@ Jumps via jump_tab with
++@ uint8_t *_dst, [r0]
++@ const uint8_t *_src, [r1]
++@ ptrdiff_t stride_dst, [r2]
++@ EDGE_SRC_STRIDE [r3]
++@ (1 << \bit_depth) - 1 [r4]
++@ * xlat_table [r5] // setup_64b only
++@ int height [r12]
++@
++@ 0 [q12] // > 8 bit
++@ 2 [q14]
++@ 128 [q15] // = 8 bit
++@ r4 [q15] // > 8 bit
++
++.macro edge_xxb_init, bit_depth, is_chroma, jump_tab, setup_64b = 0, setup_16b = 0, check_w4 = 0, do2 = 0, xjump = 0
++
++@ Build translate registers
++@ As translate values can only be 0-4 we don't care about junk in the rest
++@ of the register
++.if \is_chroma
++ ldr ip, [sp, #0]
++ push {r4-r6, lr} @ 16 bytes
++ vld1.8 {d16[2]}, [r3]
++ add r3, r3, #2
++ vld1.8 {d17[2]}, [ip]
++ add ip, ip, #2
++ vld1.8 {d16[0]}, [r3]
++ add r3, r3, #2
++ vld1.8 {d17[0]}, [ip]
++ add ip, ip, #2
++ vld1.8 {d16[1]}, [r3]
++ add r3, r3, #2
++ vld1.8 {d17[1]}, [ip]
++ add ip, ip, #2
++ vld1.8 {d16[3]}, [r3]
++ add r3, r3, #2
++ vld1.8 {d17[3]}, [ip]
++ add ip, ip, #2
++ vld1.8 {d16[4]}, [r3]
++ vld1.8 {d17[4]}, [ip]
++ movw r3, EDGE_SRC_STRIDE
++.set sp_base, 20
++.else
++ add ip, r3, #4
++ vld1.8 {d16[1]}, [r3]
++ add r3, r3, #2
++ vld1.8 {d17[0]}, [ip]
++ add ip, ip, #2
++ vld1.8 {d16[0]}, [r3]
++ add r3, r3, #6
++ vld1.8 {d17[1]}, [ip]
++ vld1.8 {d16[2]}, [r3]
++ movw r3, EDGE_SRC_STRIDE
++ push {r4-r6, lr} @ 16 bytes
++ vzip.8 d16, d17
++ vmov d17, d16
++.set sp_base, 16
++.endif
++
++@ If setup_64b we need the xlat table on the stack
++.if \setup_64b
++ sub r5, sp, #16
++.endif
++
++@ Get jump address
++@ We have a special case for width 4 as the calling code doesn't detect it
++@ If we may have w4 then we add a 2nd jump table after the 1st
++.if \check_w4
++ ldr r12, [sp, #sp_base + 4] @ width
++ adr r6, \jump_tab
++ ldr lr, [sp, #sp_base + 0] @ e0
++ cmp r12, #8
++ it lt
++ addlt r6, #16
++.else
++ ldr lr, [sp, #sp_base + 0] @ e0
++ adr r6, \jump_tab
++.endif
++
++ ldr r12, [sp, #sp_base + 8] @ height
++
++.if \bit_depth > 8
++ movw r4, (1 << \bit_depth) - 1
++.endif
++.if \setup_16b
++.if \bit_depth > 8
++ vmov.i64 q12, #0
++ vdup.16 q15, r4
++ vmov.u16 q14, #2
++.else
++ vmov.u8 q15, #128
++ vmov.u8 q14, #2
++.endif
++.endif
++
++@ If setup_64b we need q4-q7 saved.
++.if \setup_64b
++ vpush {q4-q8} @ 80 bytes, q8 pushed first
++.set sp_base, sp_base + 80
++.endif
++
++ ldr r6, [r6, lr, lsl #2]
++
++@ For 16 bit width 64 (or chroma 32) we need to do this in 2 passes
++.if \do2
++ push {r0, r1, r6, r12}
++.if jent_pic
++ bl 98f
++.else
++ blx r6
++.endif
++ pop {r0, r1, r6, r12}
++
++ add r0, #64
++ add r1, #64
++.endif
++
++.if jent_pic
++ bl 98f
++.else
++ blx r6
++.endif
++
++@ Tidy up & return
++.if \setup_64b
++ vpop {q4-q8} @ spurious but harmless load of q8
++.endif
++ pop {r4-r6, pc}
++
++.if jent_pic && !\xjump
++@ Magic label - used as 98b in jent macro
++98:
++ add pc, r6
++.endif
++.endm
++
++
++.macro edge_16b_init, bit_depth, is_chroma, check_w4, jump_tab
++ edge_xxb_init \bit_depth, \is_chroma, \jump_tab, check_w4=\check_w4, setup_16b=1
++.endm
++
++.macro edge_64b_init, bit_depth, is_chroma, do2, jump_tab, xjump=0
++ edge_xxb_init \bit_depth, \is_chroma, \jump_tab, do2=\do2, setup_64b=1, xjump=\xjump
++.endm
++
++
++.macro edge_64b_e0, body_fn, pb
++ sub r1, #8
++ mov r6, lr
++1: vldm r1, {d7-d16}
++ // load a
++ vext.8 q0, q3, q4, #(16 - \pb)
++ add r1, r3
++ vext.8 q1, q4, q5, #(16 - \pb)
++ subs r12, #1
++ vext.8 q2, q5, q6, #(16 - \pb)
++ vext.8 q3, q6, q7, #(16 - \pb)
++ pld [r1]
++ // load b
++ vext.8 q11, q7, q8, #\pb @ Avoid overwrite
++ pld [r1, #64]
++ vext.8 q8, q4, q5, #\pb
++ vext.8 q9, q5, q6, #\pb
++ vext.8 q10, q6, q7, #\pb
++ bl \body_fn
++ vstm r0, {q0-q3}
++ add r0, r0, r2
++ bgt 1b
++ bx r6
++.endm
++
++.macro edge_32bx2_e0, body_fn, pb
++ add r6, r1, r3
++ push {r7,lr}
++ sub r1, #8
++ add r7, r0, r2
++ lsl r2, #1
++1: vldmia r1, {d7-d12}
++ // load a
++ vext.8 q0, q3, q4, #16 - \pb
++ add r1, r1, r3, lsl #1
++ vext.8 q1, q4, q5, #16 - \pb
++ subs r12, #2
++ // load b
++ vext.8 q8, q4, q5, #\pb
++ vext.8 q9, q5, q6, #\pb
++ vldr d25, [r6, #-8]
++ vldmia r6, {d12-d15}
++ vldr d26, [r6, #32]
++ // load a
++ vext.8 q2, q12, q6, #16 - \pb
++ add r6, r6, r3, lsl #1
++ vext.8 q3, q6, q7, #16 - \pb
++ // load b
++ vext.8 q10, q6, q7, #\pb
++ vext.8 q11, q7, q13, #\pb
++ bl \body_fn
++ vst1.8 {q0-q1}, [r0, :256], r2
++ vst1.8 {q2-q3}, [r7, :256], r2
++ bgt 1b
++ pop {r7,pc}
++.endm
++
++.macro edge_16b_e0, body_fn, pb
++ sub r1, #8
++ mov r6, lr
++1: vldmia r1, {d1-d4}
++ add r1, r3
++ subs r12, #1
++ vext.8 q0, q0, q1, #16 - \pb
++ vext.8 q2, q1, q2, #\pb
++
++ bl \body_fn
++ vst1.8 {q0}, [r0, :128], r2
++ bgt 1b
++ bx r6
++.endm
++
++.macro edge_8bx2_e0, body_fn, pb
++ add r6, r1, r3
++ push {r7,lr}
++ sub r1, #8
++ add r7, r0, r2
++ lsl r2, #1
++1: vldmia r1, {d1-d2}
++ vldmia r6, {d3-d4}
++ vldr d6, [r1, #16]
++ subs r12, #2
++ vldr d7, [r6, #-8]
++ add r1, r1, r3, lsl #1
++ vext.8 d0, d1, d2, #8 - \pb
++ add r6, r6, r3, lsl #1
++ vext.8 d5, d3, d4, #\pb
++ vext.8 d4, d2, d6, #\pb
++ vext.8 d1, d7, d3, #8 - \pb
++
++ bl \body_fn
++ vst1.8 {d0}, [r0, :64], r2
++ vst1.8 {d1}, [r7, :64], r2
++ bgt 1b
++ pop {r7,pc}
++.endm
++
++.macro edge_4bx4_e0, body_fn, pb
++ add r6, r1, r3
++ push {r7,lr}
++ add r7, r0, r2
++ lsl r2, #1
++
++ tst r1, #4
++ bne 2f
++1: // r1 (and assumed r6) are 64-bit aligned
++ vldr d2, [r1]
++ vldr d0, [r1, #-8]
++ add r1, r1, r3, lsl #1
++ vldr d20, [r6]
++ subs r12, #4
++ vldr d18, [r6, #-8]
++ add r6, r6, r3, lsl #1
++ vldr d3, [r1]
++ vshr.u64 d4, d2, #\pb * 8
++ vldr d1, [r1, #-8]
++ add r1, r1, r3, lsl #1
++ vldr d21, [r6]
++ vext.8 d0, d0, d2, #8 - \pb
++ vldr d19, [r6,#-8]
++ add r6, r6, r3, lsl #1
++ vshr.u64 d22, d20, #\pb * 8
++ vext.8 d18, d18, d20, #8 - \pb
++ vshr.u64 d5, d3, #\pb * 8
++ vext.8 d1, d1, d3, #8 - \pb
++ vshr.u64 d23, d21, #\pb * 8
++ vext.8 d19, d19, d21, #8 - \pb
++ vsli.64 q1, q10, #32
++ vsli.64 q2, q11, #32
++ vsli.64 q0, q9, #32
++
++ bl \body_fn
++ vst1.32 {d0[0]}, [r0, :32], r2
++ vst1.32 {d0[1]}, [r7, :32], r2
++ vst1.32 {d1[0]}, [r0, :32], r2
++ vst1.32 {d1[1]}, [r7, :32], r2
++ bgt 1b
++ pop {r7,pc}
++
++2: // r1 (and assumed r6) are 32-bit but not 64-bit aligned
++ vldr d20, [r1, #-4]
++ vldr d22, [r1, #4]
++ add r1, r1, r3, lsl #1
++ vldr d2, [r6, #-4]
++ subs r12, #4
++ vldr d4, [r6, #4]
++ add r6, r6, r3, lsl #1
++ vldr d21, [r1, #-4]
++ vshl.i64 d18, d20, #\pb * 8
++ vldr d23, [r1, #4]
++ add r1, r1, r3, lsl #1
++ vldr d3, [r6, #-4]
++ vext.8 d22, d20, d22, #\pb
++ vldr d5, [r6, #4]
++ add r6, r6, r3, lsl #1
++ vshl.i64 d0, d2, #\pb * 8
++ vext.8 d4, d2, d4, #\pb
++ vshl.i64 d19, d21, #\pb * 8
++ vext.8 d23, d21, d23, #\pb
++ vshl.i64 d1, d3, #\pb * 8
++ vext.8 d5, d3, d5, #\pb
++ vsri.64 q1, q10, #32
++ vsri.64 q0, q9, #32
++ vsri.64 q2, q11, #32
++
++ bl \body_fn
++ vst1.32 {d0[0]}, [r0, :32], r2
++ vst1.32 {d0[1]}, [r7, :32], r2
++ vst1.32 {d1[0]}, [r0, :32], r2
++ vst1.32 {d1[1]}, [r7, :32], r2
++ bgt 2b
++ pop {r7,pc}
++.endm
++
++
++.macro edge_64b_e1, body_fn
++ sub r1, r3
++ push {lr}
++ add r6, r1, #32
++ // load a
++ vld1.8 {q0-q1}, [r1, :256], r3
++ vld1.8 {q2-q3}, [r6, :256], r3
++ // load c
++ vld1.8 {q4-q5}, [r1, :256], r3
++ vld1.8 {q6-q7}, [r6, :256], r3
++1: // load b
++ vld1.8 {q8-q9}, [r1, :256], r3
++ subs r12, #1
++ vld1.8 {q10-q11}, [r6, :256], r3
++ bl \body_fn
++ vstm r0, {q0-q3}
++ // copy c to a
++ vmov.64 q0, q4
++ pld [r1, r3]
++ vmov.64 q1, q5
++ it le
++ pople {lr}
++ vmov.64 q2, q6
++ it le
++ bxle lr
++ vmov.64 q3, q7
++ add r0, r0, r2
++ // copy b to c
++ vmov.64 q4, q8
++ vmov.64 q5, q9
++ vmov.64 q6, q10
++ vmov.64 q7, q11
++ b 1b
++.endm
++
++.macro edge_32bx2_e1, body_fn
++ sub r6, r1, r3
++ vld1.8 {q2-q3}, [r1, :256], r3
++ vld1.8 {q0-q1}, [r6, :256]
++ mov r6, lr
++
++1: @ Given the data duplication here we could obviously do better than
++ @ using the generic body_fn but it almost certainly isn't worth it
++ vld1.8 {q8-q9}, [r1, :256], r3
++ subs r12, #2
++ vmov q4, q2
++ vmov q5, q3
++ vld1.8 {q10-q11}, [r1, :256], r3
++ vmov q6, q8
++ vmov q7, q9
++
++ bl \body_fn
++
++ vst1.8 {q0-q1}, [r0, :256], r2
++ // copy b to a
++ vmov q0, q8
++ vmov q1, q9
++ vst1.8 {q2-q3}, [r0, :256], r2
++ vmov q2, q10
++ it le
++ bxle r6
++ vmov q3, q11
++ b 1b
++.endm
++
++.macro edge_16b_e1, body_fn
++ sub r6, r1, r3
++ // load c
++ vld1.8 {q1}, [r1, :128], r3
++ // load a
++ vld1.8 {q0}, [r6, :128]
++ mov r6, lr
++1: // load b
++ vld1.8 {q2}, [r1, :128], r3
++ bl \body_fn
++ vst1.8 {q0}, [r0, :128], r2
++ subs r12, #1
++ // copy c to a
++ vmov.64 q0, q1
++ it le
++ bxle r6
++ // copy b to c
++ vmov.64 q1, q2
++ b 1b
++.endm
++
++.macro edge_8bx2_e1, body_fn
++ sub r6, r1, r3
++ lsl r3, #1
++ push {r7, lr}
++ vld1.8 {d1}, [r1, :64], r3
++ vld1.8 {d0}, [r6, :64], r3
++ add r7, r0, r2
++ lsl r2, #1
++1: @ Given the data duplication here we could obviously do better than
++ @ using the generic body_fn but it almost certainly isn't worth it
++ vld1.8 {d4}, [r6, :64], r3
++ vmov d2, d1
++ vld1.8 {d5}, [r1, :64], r3
++ subs r12, #2
++ vmov d3, d4
++
++ bl \body_fn
++
++ vst1.8 {d0}, [r0, :64], r2
++ vst1.8 {d1}, [r7, :64], r2
++
++ // copy b to a
++ vmov q0, q2
++ bgt 1b
++ pop {r7, pc}
++.endm
++
++.macro edge_4bx4_e1, body_fn
++ sub r6, r1, r3
++ lsl r3, #1
++ push {r7, lr}
++ vld1.32 {d0[1]}, [r1, :32], r3
++ add r7, r0, r2
++ vld1.32 {d0[0]}, [r6, :32], r3
++ lsl r2, #1
++ vld1.32 {d4[1]}, [r1, :32], r3
++ vld1.32 {d4[0]}, [r6, :32], r3
++ vld1.32 {d5[1]}, [r1, :32], r3
++ vld1.32 {d5[0]}, [r6, :32], r3
++ vmov d1, d4
++ vext.32 d2, d0, d4, #1
++ subs r12, #4
++ vmov d22, d5
++ vext.32 d3, d4, d5, #1
++ b 2f
++
++1: vst1.32 {d0[0]}, [r0, :32], r2
++ vext.32 d2, d22, d4, #1
++ vst1.32 {d0[1]}, [r7, :32], r2
++ vmov d0, d22
++ vst1.32 {d1[0]}, [r0, :32], r2
++ vext.32 d3, d4, d5, #1
++ vst1.32 {d1[1]}, [r7, :32], r2
++ vmov d1, d4
++ vmov d22, d5
++2: @ Given the data duplication here we could probably do better than
++ @ using the generic body_fn but it almost certainly isn't worth it
++ bl \body_fn
++ ble 3f
++ vld1.32 {d4[0]}, [r6, :32], r3
++ subs r12, #4
++ vld1.32 {d4[1]}, [r1, :32], r3
++ vld1.32 {d5[0]}, [r6, :32], r3
++ vld1.32 {d5[1]}, [r1, :32], r3
++ b 1b
++
++3: vst1.32 {d0[0]}, [r0, :32], r2
++ vst1.32 {d0[1]}, [r7, :32], r2
++ vst1.32 {d1[0]}, [r0, :32]
++ vst1.32 {d1[1]}, [r7, :32]
++ pop {r7, pc}
++.endm
++
++.macro edge_64b_e2, body_fn, pb
++ push {lr}
++ sub r6, r1, r3
++ // load c and a
++ vld1.8 {q4-q5}, [r1, :128]
++ vldr d25, [r6, #-8]
++ vldmia r6, {d16-d23}
++ vext.8 q0, q12, q8, #16 - \pb
++ add r6, r1, #32
++ vext.8 q1, q8, q9, #16 - \pb
++ add r1, r1, r3
++ vext.8 q2, q9, q10, #16 - \pb
++ vld1.8 {q6-q7}, [r6, :128]
++ sub r6, r1, r3
++ vext.8 q3, q10, q11, #16 - \pb
++
++1: // load b
++ vldmia r1, {d16-d24}
++ vext.8 q8, q8, q9, #\pb
++ pld [r1, r3]
++ vext.8 q9, q9, q10, #\pb
++ subs r12, #1
++ vext.8 q10, q10, q11, #\pb
++ vext.8 q11, q11, q12, #\pb
++ bl \body_fn
++ // next a is mostly available in c
++ vldr d25, [r6, #-8]
++ vstmia r0, {q0-q3}
++ vext.8 q3, q6, q7, #16 - \pb
++ it le
++ pople {lr}
++ vext.8 q2, q5, q6, #16 - \pb
++ it le
++ bxle lr
++ vext.8 q1, q4, q5, #16 - \pb
++ add r6, r6, r3
++ vext.8 q0, q12, q4, #16 - \pb
++ add r0, r0, r2
++ // next c is mostly available in b
++ vldr d8, [r1]
++ vext.8 d9, d16, d17, #8 - \pb
++ vext.8 q5, q8, q9, #16 - \pb
++ add r1, r1, r3
++ vext.8 q6, q9, q10, #16 - \pb
++ pld [r6, #-8]
++ vext.8 q7, q10, q11, #16 - \pb
++ b 1b
++.endm
++
++.macro edge_32bx2_e2, body_fn, pb
++ sub r6, r1, r3
++ push {r7, lr}
++ add r7, r0, r2
++ lsl r2, #1
++ // load a and first 32b of c
++ vld1.8 {q4-q5}, [r1, :256]
++ vldr d25, [r6, #-8]
++ vld1.8 {q13-q14}, [r6, :256]
++ vldr d31, [r1, #-8]
++ add r6, r6, r3, lsl #1
++ vext.8 q0, q12, q13, #16 - \pb
++ add r1, r1, r3, lsl #1
++ vext.8 q1, q13, q14, #16 - \pb
++ vext.8 q2, q15, q4, #16 - \pb
++ vext.8 q3, q4, q5, #16 - \pb
++1:
++ // load second 32b of c and second 32b of b
++ vldmia r6, {d12-d16}
++ vldmia r1, {d20-d24}
++ // first 32b of b is mostly available in second 32b of c
++ vext.8 q9, q7, q8, #\pb
++ subs r12, #2
++ vext.8 q8, q6, q7, #\pb
++ vext.8 q10, q10, q11, #\pb
++ vext.8 q11, q11, q12, #\pb
++
++ bl \body_fn
++
++ vst1.8 {q0-q1}, [r0, :256], r2
++ vst1.8 {q2-q3}, [r7, :256], r2
++ ble 2f
++
++ vldr d25, [r6, #-8]
++ add r6, r6, r3, lsl #1
++ vldr d8, [r1]
++ vext.8 d9, d20, d21, #8 - \pb
++ vldr d31, [r1, #-8]
++ add r1, r1, r3, lsl #1
++ // first 32b of a is mostly available in second 32b of c
++ vext.8 q1, q6, q7, #16 - \pb
++ vext.8 q0, q12, q6, #16 - \pb
++ // first 32b of c is mostly available in second 32b of b
++ vext.8 q5, q10, q11, #16 - \pb
++ // second 32b of a is mostly available in first 32b of c
++ vext.8 q2, q15, q4, #16 - \pb
++ vext.8 q3, q4, q5, #16 - \pb
++ b 1b
++
++2: pop {r7, pc}
++.endm
++
++.macro edge_16b_e2, body_fn, pb
++ push {lr}
++ sub r6, r1, r3
++ vld1.8 {q1}, [r1, :128], r3
++ vldr d19, [r6, #-8]
++ vld1.8 {q10}, [r6, :128], r3
++
++1: vldmia r1, {d4-d6}
++ vext.8 q0, q9, q10, #16 - \pb
++ subs r12, #1
++ vext.8 q2, q2, q3, #\pb
++ bl \body_fn
++ vst1.8 {q0}, [r0, :128], r2
++ ble 2f
++ vmov q10, q1
++ vldr d2, [r1]
++ add r1, r1, r3
++ vldr d19, [r6, #-8]
++ add r6, r6, r3
++ vext.8 d3, d4, d5, #8 - \pb
++ b 1b
++
++2: pop {pc}
++.endm
++
++.macro edge_8bx2_e2, body_fn, pb
++ sub r6, r1, r3
++ push {r7, lr}
++ add r7, r0, r2
++ lsl r2, #1
++ vldr d18, [r6, #-8]
++ vldr d19, [r6]
++ add r6, r6, r3, lsl #1
++ vldr d20, [r1, #-8]
++ vldr d2, [r1]
++ add r1, r1, r3, lsl #1
++ vldmia r6, {d3-d4}
++ vld1.8 {d21-d22}, [r1, :128]
++
++1: vext.8 d0, d18, d19, #8 - \pb
++ vext.8 d4, d3, d4, #\pb
++ vext.8 d1, d20, d2, #8 - \pb
++ subs r12, #2
++ vext.8 d5, d21, d22, #\pb
++
++ bl \body_fn
++
++ vst1.8 {d0}, [r0, :64], r2
++ vst1.8 {d1}, [r7, :64], r2
++ ble 2f
++
++ vldr d18, [r6, #-8]
++ add r6, r6, r3, lsl #1
++ vldr d20, [r1, #-8]
++ vmov d19, d3
++ vldr d2, [r1]
++ add r1, r1, r3, lsl #1
++ vldmia r6, {d3-d4}
++ vld1.8 {d21-d22}, [r1, :128]
++ b 1b
++
++2: pop {r7, pc}
++.endm
++
++.macro edge_4bx4_e2, body_fn, pb
++ sub r6, r1, r3
++ push {r7-r9, lr}
++ add r8, r1, r3
++ sub r6, r6, #\pb
++ add r8, r8, #\pb
++ add r7, r0, r2
++ lsl r2, #1
++
++1: vld1.32 {d0[0]}, [r6], r3
++ subs r12, #4
++ vld1.32 {d2[0]}, [r1], r3
++ vld1.32 {d4[0]}, [r8], r3
++ vld1.32 {d0[1]}, [r6], r3
++ vld1.32 {d2[1]}, [r1], r3
++ vld1.32 {d4[1]}, [r8], r3
++ vld1.32 {d1[0]}, [r6], r3
++ vld1.32 {d3[0]}, [r1], r3
++ vld1.32 {d5[0]}, [r8], r3
++ vld1.32 {d1[1]}, [r6], r3
++ vld1.32 {d3[1]}, [r1], r3
++ vld1.32 {d5[1]}, [r8], r3
++
++ bl \body_fn
++
++ vst1.32 {d0[0]}, [r0, :32], r2
++ vst1.32 {d0[1]}, [r7, :32], r2
++ vst1.32 {d1[0]}, [r0, :32], r2
++ vst1.32 {d1[1]}, [r7, :32], r2
++ bgt 1b
++
++ pop {r7-r9,pc}
++.endm
++
++.macro edge_64b_e3, body_fn, pb
++ push {lr}
++ sub r6, r1, r3
++ // load c and a
++ vld1.8 {q4-q5}, [r1, :128]
++ vldmia r6, {d16-d24}
++ vext.8 q0, q8, q9, #\pb
++ add r6, r1, #32
++ vext.8 q1, q9, q10, #\pb
++ add r1, r1, r3
++ vext.8 q2, q10, q11, #\pb
++ vld1.8 {q6-q7}, [r6, :128]
++ sub r6, r1, r3
++ vext.8 q3, q11, q12, #\pb
++
++1: // load b
++ vldr d17, [r1, #-8]
++ vldmia r1, {d18-d25}
++ vext.8 q8, q8, q9, #16 - \pb
++ pld [r1, r3]
++ vext.8 q9, q9, q10, #16 - \pb
++ subs r12, #1
++ vext.8 q10, q10, q11, #16 - \pb
++ vext.8 q11, q11, q12, #16 - \pb
++ bl \body_fn
++ // next a is mostly available in c
++ vldr d24, [r6, #64]
++ vstmia r0, {q0-q3}
++ vext.8 q0, q4, q5, #\pb
++ it le
++ pople {lr}
++ vext.8 q1, q5, q6, #\pb
++ it le
++ bxle lr
++ vext.8 q2, q6, q7, #\pb
++ add r6, r6, r3
++ vext.8 q3, q7, q12, #\pb
++ add r0, r0, r2
++ // next c is mostly available in b
++ vext.8 d14, d22, d23, #\pb
++ vldr d15, [r1, #56]
++ vext.8 q4, q8, q9, #\pb
++ add r1, r1, r3
++ vext.8 q5, q9, q10, #\pb
++ vext.8 q6, q10, q11, #\pb
++ b 1b
++.endm
++
++.macro edge_32bx2_e3, body_fn, pb
++ sub r6, r1, r3
++ push {r7, lr}
++ add r7, r0, r2
++ lsl r2, #1
++ // load a and first 32b of c
++ vldmia r1, {d8-d12}
++ vldmia r6, {d24-d28}
++ vext.8 q2, q4, q5, #\pb
++ add r6, r6, r3, lsl #1
++ vext.8 q3, q5, q6, #\pb
++ add r1, r1, r3, lsl #1
++ vext.8 q0, q12, q13, #\pb
++ vext.8 q1, q13, q14, #\pb
++1:
++ // load second 32b of c and second 32b of b
++ vldr d25, [r6, #-8]
++ subs r12, #2
++ vldmia r6, {d12-d15}
++ vldr d27, [r1, #-8]
++ vldmia r1, {d20-d23}
++ // first 32b of b is mostly available in second 32b of c
++ vext.8 q8, q12, q6, #16 - \pb
++ vext.8 q9, q6, q7, #16 - \pb
++ vext.8 q11, q10, q11, #16 - \pb
++ vext.8 q10, q13, q10, #16 - \pb
++
++ bl \body_fn
++
++ vst1.8 {q0-q1}, [r0, :256], r2
++ vst1.8 {q2-q3}, [r7, :256], r2
++ ble 2f
++
++ vldr d24, [r6, #32]
++ add r6, r6, r3, lsl #1
++ vldr d11, [r1, #24]
++ vext.8 d10, d22, d23, #\pb
++ vldr d30, [r1, #32]
++ add r1, r1, r3, lsl #1
++ // first 32b of a is mostly available in second 32b of c
++ vext.8 q0, q6, q7, #\pb
++ vext.8 q1, q7, q12, #\pb
++ // first 32b of c is mostly available in second 32b of b
++ vext.8 q4, q10, q11, #\pb
++ // second 32b of a is mostly available in first 32b of c
++ vext.8 q3, q5, q15, #\pb
++ vext.8 q2, q4, q5, #\pb
++ b 1b
++
++2: pop {r7, pc}
++.endm
++
++.macro edge_16b_e3, body_fn, pb
++ push {lr}
++ sub r6, r1, r3
++ vld1.8 {q1}, [r1, :128], r3
++ vldmia r6, {d18-d20}
++ add r6, r6, r3
++
++1: vldr d5, [r1, #-8]
++ vld1.8 {q3}, [r1, :128]
++ subs r12, #1
++ vext.8 q0, q9, q10, #\pb
++ vext.8 q2, q2, q3, #16 - \pb
++ bl \body_fn
++ vst1.8 {q0}, [r0, :128], r2
++ ble 2f
++ vmov q9, q1
++ vldr d3, [r1, #8]
++ add r1, r1, r3
++ vldr d20, [r6, #16]
++ add r6, r6, r3
++ vext.8 d2, d4, d5, #\pb
++ b 1b
++
++2: pop {pc}
++.endm
++
++.macro edge_8bx2_e3, body_fn, pb
++ sub r6, r1, r3
++ push {r7, lr}
++ add r7, r0, r2
++ lsl r2, #1
++ vld1.8 {d18-d19}, [r6]
++ add r6, r6, r3, lsl #1
++ vldr d20, [r1, #8]
++ vldr d2, [r1]
++ add r1, r1, r3, lsl #1
++ vldr d4, [r6, #-8]
++ vldr d3, [r6]
++ vldr d21, [r1, #-8]
++ vldr d22, [r1]
++
++1: vext.8 d0, d18, d19, #\pb
++ vext.8 d4, d4, d3, #8 - \pb
++ vext.8 d1, d2, d20, #\pb
++ subs r12, #2
++ vext.8 d5, d21, d22, #8 - \pb
++
++ bl \body_fn
++
++ vst1.8 {d0}, [r0, :64], r2
++ vst1.8 {d1}, [r7, :64], r2
++ ble 2f
++
++ vldr d19, [r6, #8]
++ add r6, r6, r3, lsl #1
++ vldr d20, [r1, #8]
++ vmov d18, d3
++ vldr d2, [r1]
++ add r1, r1, r3, lsl #1
++ vldr d4, [r6, #-8]
++ vldr d3, [r6]
++ vldr d21, [r1, #-8]
++ vldr d22, [r1]
++ b 1b
++
++2: pop {r7, pc}
++.endm
++
++.macro edge_4bx4_e3, body_fn, pb
++ @ e3 is the same as e2 but with the X offset reversed
++ edge_4bx4_e2 \body_fn, (-\pb)
++.endm
++
++@ Jump table entry - if in neon mode the bottom bit must be set
++@ ? There is probably a real asm instruction to do this but I haven't found it
++.macro jent lab
++.if jent_pic
++@ Could use .short here but due to A32 not supporting ldrh [lsl#1] it is
++@ simpler and clearer in the code to stick with .word
++T .word (0 + \lab) - (4 + 98b)
++A .word (0 + \lab) - (8 + 98b)
++.else
++T .word 1 + \lab
++A .word \lab
++.endif
++.endm
++
++.macro edge_64b_bodies, body_fn, pb
++ jent 0f
++ jent 10f
++ jent 20f
++ jent 30f
++
++0: edge_64b_e0 \body_fn, \pb
++10: edge_64b_e1 \body_fn
++20: edge_64b_e2 \body_fn, \pb
++30: edge_64b_e3 \body_fn, \pb
++.endm
++
++.macro edge_32bx2_bodies, body_fn, pb
++ jent 0f
++ jent 10f
++ jent 20f
++ jent 30f
++
++0: edge_32bx2_e0 \body_fn, \pb
++10: edge_32bx2_e1 \body_fn
++20: edge_32bx2_e2 \body_fn, \pb
++30: edge_32bx2_e3 \body_fn, \pb
++.endm
++
++.macro edge_16b_bodies, body_fn, pb
++ jent 0f
++ jent 10f
++ jent 20f
++ jent 30f
++
++0: edge_16b_e0 \body_fn, \pb
++10: edge_16b_e1 \body_fn
++20: edge_16b_e2 \body_fn, \pb
++30: edge_16b_e3 \body_fn, \pb
++.endm
++
++.macro edge_32bx2_16b_bodies, body_fn_64b, body_fn_16b, pb
++ jent 0f
++ jent 10f
++ jent 20f
++ jent 30f
++ jent 5f
++ jent 15f
++ jent 25f
++ jent 35f
++
++0: edge_32bx2_e0 \body_fn_64b, \pb
++10: edge_32bx2_e1 \body_fn_64b
++20: edge_32bx2_e2 \body_fn_64b, \pb
++30: edge_32bx2_e3 \body_fn_64b, \pb
++5: edge_16b_e0 \body_fn_16b, \pb
++15: edge_16b_e1 \body_fn_16b
++25: edge_16b_e2 \body_fn_16b, \pb
++35: edge_16b_e3 \body_fn_16b, \pb
++.endm
++
++.macro edge_16b_8bx2_bodies, body_fn, pb
++ jent 0f
++ jent 10f
++ jent 20f
++ jent 30f
++ jent 5f
++ jent 15f
++ jent 25f
++ jent 35f
++
++0: edge_16b_e0 \body_fn, \pb
++10: edge_16b_e1 \body_fn
++20: edge_16b_e2 \body_fn, \pb
++30: edge_16b_e3 \body_fn, \pb
++5: edge_8bx2_e0 \body_fn, \pb
++15: edge_8bx2_e1 \body_fn
++25: edge_8bx2_e2 \body_fn, \pb
++35: edge_8bx2_e3 \body_fn, \pb
++.endm
++
++.macro edge_8bx2_4bx4_bodies, body_fn, pb
++ jent 0f
++ jent 10f
++ jent 20f
++ jent 30f
++ jent 5f
++ jent 15f
++ jent 25f
++ jent 35f
++
++0: edge_8bx2_e0 \body_fn, \pb
++10: edge_8bx2_e1 \body_fn
++20: edge_8bx2_e2 \body_fn, \pb
++30: edge_8bx2_e3 \body_fn, \pb
++5: edge_4bx4_e0 \body_fn, \pb
++15: edge_4bx4_e1 \body_fn
++25: edge_4bx4_e2 \body_fn, \pb
++35: edge_4bx4_e3 \body_fn, \pb
++.endm
++
++@ void ff_hevc_rpi_sao_edge_8_neon_8(
++@ uint8_t *_dst, [r0]
++@ uint8_t *_src, [r1]
++@ int stride_dst, [r2]
++@ int16_t *_sao_offset_val, [r3]
++@ int eo, [sp, #0]
++@ int width, [sp, #4]
++@ int height) [sp, #8]
++
++function ff_hevc_rpi_sao_edge_8_neon_8, export=1
++ edge_16b_init 8, 0, 1, 99f
++99:
++ edge_8bx2_4bx4_bodies edge_16b_body_8, 1
++endfunc
++
++@ void ff_hevc_rpi_sao_edge_16_neon_8(
++@ uint8_t *_dst, [r0]
++@ uint8_t *_src, [r1]
++@ int stride_dst, [r2]
++@ int16_t *_sao_offset_val, [r3]
++@ int eo, [sp, #0]
++@ int width, [sp, #4]
++@ int height) [sp, #8]
++
++function ff_hevc_rpi_sao_edge_16_neon_8, export=1
++ edge_16b_init 8, 0, 0, 99f
++99:
++ edge_16b_bodies edge_16b_body_8, 1
++endfunc
++
++@ void ff_hevc_rpi_sao_edge_32_neon_8(
++@ uint8_t *_dst, [r0]
++@ uint8_t *_src, [r1]
++@ int stride_dst, [r2]
++@ int16_t *_sao_offset_val, [r3]
++@ int eo, [sp, #0]
++@ int width, [sp, #4]
++@ int height) [sp, #8]
++
++function ff_hevc_rpi_sao_edge_32_neon_8, export=1
++ edge_64b_init 8, 0, 0, 99f
++99:
++ edge_32bx2_bodies edge_64b_body_8, 1
++endfunc
++
++@ void ff_hevc_rpi_sao_edge_64_neon_8(
++@ uint8_t *_dst, [r0]
++@ uint8_t *_src, [r1]
++@ int stride_dst, [r2]
++@ int16_t *_sao_offset_val, [r3]
++@ int eo, [sp, #0]
++@ int width, [sp, #4]
++@ int height) [sp, #8]
++
++function ff_hevc_rpi_sao_edge_64_neon_8, export=1
++ edge_64b_init 8, 0, 0, 99f
++99:
++ edge_64b_bodies edge_64b_body_8, 1
++endfunc
++
++@ ff_hevc_rpi_sao_edge_c_8_neon_8(
++@ uint8_t *_dst, [r0]
++@ const uint8_t *_src, [r1]
++@ ptrdiff_t stride_dst, [r2]
++@ const int16_t *_sao_offset_val_u, [r3]
++@ const int16_t *_sao_offset_val_v, [sp, #0]
++@ int eo, [sp, #4]
++@ int width, [sp, #8]
++@ int height) [sp, #12]
++
++function ff_hevc_rpi_sao_edge_c_8_neon_8, export=1
++ edge_16b_init 8, 1, 1, 99f
++99:
++ edge_16b_8bx2_bodies edge_16b_body_8, 2
++endfunc
++
++@ ff_hevc_rpi_sao_edge_c_16_neon_8(
++@ uint8_t *_dst, [r0]
++@ const uint8_t *_src, [r1]
++@ ptrdiff_t stride_dst, [r2]
++@ const int16_t *_sao_offset_val_u, [r3]
++@ const int16_t *_sao_offset_val_v, [sp, #0]
++@ int eo, [sp, #4]
++@ int width, [sp, #8]
++@ int height) [sp, #12]
++
++function ff_hevc_rpi_sao_edge_c_16_neon_8, export=1
++ edge_64b_init 8, 1, 0, 99f
++99:
++ edge_32bx2_bodies edge_64b_body_8, 2
++endfunc
++
++@ ff_hevc_rpi_sao_edge_c_32_neon_8(
++@ uint8_t *_dst, [r0]
++@ const uint8_t *_src, [r1]
++@ ptrdiff_t stride_dst, [r2]
++@ const int16_t *_sao_offset_val_u, [r3]
++@ const int16_t *_sao_offset_val_v, [sp, #0]
++@ int eo, [sp, #4]
++@ int width, [sp, #8]
++@ int height) [sp, #12]
++
++function ff_hevc_rpi_sao_edge_c_32_neon_8, export=1
++ edge_64b_init 8, 1, 0, 99f
++99:
++ edge_64b_bodies edge_64b_body_8, 2
++endfunc
++
++@ void ff_hevc_rpi_sao_edge_8_neon_10(
++@ uint8_t *_dst, [r0]
++@ uint8_t *_src, [r1]
++@ int stride_dst, [r2]
++@ int16_t *_sao_offset_val, [r3]
++@ int eo, [sp, #0]
++@ int width, [sp, #4]
++@ int height) [sp, #8]
++
++function ff_hevc_rpi_sao_edge_8_neon_10, export=1
++ edge_16b_init 10, 0, 1, 99f
++99:
++ edge_16b_8bx2_bodies edge_16b_body_16, 2
++endfunc
++
++@ void ff_hevc_rpi_sao_edge_16_neon_10(
++@ uint8_t *_dst, [r0]
++@ uint8_t *_src, [r1]
++@ int stride_dst, [r2]
++@ int16_t *_sao_offset_val, [r3]
++@ int eo, [sp, #0]
++@ int width, [sp, #4]
++@ int height) [sp, #8]
++
++function ff_hevc_rpi_sao_edge_16_neon_10, export=1
++ edge_64b_init 10, 0, 0, 99f
++99:
++ edge_32bx2_bodies edge_64b_body_16, 2
++endfunc
++
++@ void ff_hevc_rpi_sao_edge_64_neon_10(
++@ uint8_t *_dst, [r0]
++@ uint8_t *_src, [r1]
++@ int stride_dst, [r2]
++@ int16_t *_sao_offset_val, [r3]
++@ int eo, [sp, #0]
++@ int width, [sp, #4]
++@ int height) [sp, #8]
++
++@ We simply split the 32 case into 2 vertical stripes
++@ and call the fns for w32
++@
++@ Calling code will always have src != dst so we don't have to worry
++@ about edge effects
++
++function ff_hevc_rpi_sao_edge_64_neon_10, export=1
++ edge_64b_init 10, 0, 1, 99f, xjump=1
++endfunc
++
++@ void ff_hevc_rpi_sao_edge_32_neon_10(
++@ uint8_t *_dst, [r0]
++@ uint8_t *_src, [r1]
++@ int stride_dst, [r2]
++@ int16_t *_sao_offset_val, [r3]
++@ int eo, [sp, #0]
++@ int width, [sp, #4]
++@ int height) [sp, #8]
++
++function ff_hevc_rpi_sao_edge_32_neon_10, export=1
++ edge_64b_init 10, 0, 0, 99f
++99:
++ edge_64b_bodies edge_64b_body_16, 2
++endfunc
++
++@ ff_hevc_rpi_sao_edge_c_8_neon_10(
++@ uint8_t *_dst, [r0]
++@ const uint8_t *_src, [r1]
++@ ptrdiff_t stride_dst, [r2]
++@ const int16_t *_sao_offset_val_u, [r3]
++@ const int16_t *_sao_offset_val_v, [sp, #0]
++@ int eo, [sp, #4]
++@ int width, [sp, #8]
++@ int height) [sp, #12]
++
++function ff_hevc_rpi_sao_edge_c_8_neon_10, export=1
++ edge_xxb_init 10, 1, 99f, check_w4=1, setup_16b=1, setup_64b=1
++99:
++ edge_32bx2_16b_bodies edge_64b_body_16, edge_16b_body_16, 4
++endfunc
++
++@ ff_hevc_rpi_sao_edge_c_32_neon_10(
++@ uint8_t *_dst, [r0]
++@ const uint8_t *_src, [r1]
++@ ptrdiff_t stride_dst, [r2]
++@ const int16_t *_sao_offset_val_u, [r3]
++@ const int16_t *_sao_offset_val_v, [sp, #0]
++@ int eo, [sp, #4]
++@ int width, [sp, #8]
++@ int height) [sp, #12]
++
++function ff_hevc_rpi_sao_edge_c_32_neon_10, export=1
++ edge_64b_init 10, 1, 1, 99f, xjump=1
++endfunc
++
++
++@ ff_hevc_rpi_sao_edge_c_16_neon_10(
++@ uint8_t *_dst, [r0]
++@ const uint8_t *_src, [r1]
++@ ptrdiff_t stride_dst, [r2]
++@ const int16_t *_sao_offset_val_u, [r3]
++@ const int16_t *_sao_offset_val_v, [sp, #0]
++@ int eo, [sp, #4]
++@ int width, [sp, #8]
++@ int height) [sp, #12]
++
++function ff_hevc_rpi_sao_edge_c_16_neon_10, export=1
++ edge_64b_init 10, 1, 0, 99f
++99:
++ edge_64b_bodies edge_64b_body_16, 4
++endfunc
++
+diff --git a/libavcodec/arm/rpi_hevcpred_arm.h b/libavcodec/arm/rpi_hevcpred_arm.h
+new file mode 100644
+index 0000000000..36a23a5bf9
+--- /dev/null
++++ b/libavcodec/arm/rpi_hevcpred_arm.h
+@@ -0,0 +1,28 @@
++/*
++ * This file is part of FFmpeg.
++ *
++ * FFmpeg is free software; you can redistribute it and/or
++ * modify it under the terms of the GNU Lesser General Public
++ * License as published by the Free Software Foundation; either
++ * version 2.1 of the License, or (at your option) any later version.
++ *
++ * FFmpeg is distributed in the hope that it will be useful,
++ * but WITHOUT ANY WARRANTY; without even the implied warranty of
++ * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
++ * Lesser General Public License for more details.
++ *
++ * You should have received a copy of the GNU Lesser General Public
++ * License along with FFmpeg; if not, write to the Free Software
++ * Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA
++ */
++
++#ifndef AVCODEC_ARM_HEVCPRED_ARM_H
++#define AVCODEC_ARM_HEVCPRED_ARM_H
++
++#include "libavcodec/rpi_hevcpred.h"
++
++void ff_hevc_rpi_pred_init_arm(HEVCRpiPredContext * const c, const int bit_depth);
++void ff_hevc_rpi_pred_init_neon(HEVCRpiPredContext * const c, const int bit_depth);
++
++#endif /* AVCODEC_ARM_HEVCPRED_ARM_H */
++
+diff --git a/libavcodec/arm/rpi_hevcpred_init_arm.c b/libavcodec/arm/rpi_hevcpred_init_arm.c
+new file mode 100644
+index 0000000000..80724d4cf3
+--- /dev/null
++++ b/libavcodec/arm/rpi_hevcpred_init_arm.c
+@@ -0,0 +1,35 @@
++/*
++ * Copyright (c) 2018 John Cox (for Raspberry Pi)
++ *
++ * This file is part of FFmpeg.
++ *
++ * FFmpeg is free software; you can redistribute it and/or
++ * modify it under the terms of the GNU Lesser General Public
++ * License as published by the Free Software Foundation; either
++ * version 2.1 of the License, or (at your option) any later version.
++ *
++ * FFmpeg is distributed in the hope that it will be useful,
++ * but WITHOUT ANY WARRANTY; without even the implied warranty of
++ * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
++ * Lesser General Public License for more details.
++ *
++ * You should have received a copy of the GNU Lesser General Public
++ * License along with FFmpeg; if not, write to the Free Software
++ * Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA
++ */
++
++#include "libavutil/attributes.h"
++#include "libavutil/cpu.h"
++#include "libavutil/arm/cpu.h"
++
++#include "libavcodec/rpi_hevcpred.h"
++#include "rpi_hevcpred_arm.h"
++
++av_cold void ff_hevc_rpi_pred_init_arm(HEVCRpiPredContext * const c, const int bit_depth)
++{
++ int cpu_flags = av_get_cpu_flags();
++
++ if (have_neon(cpu_flags))
++ ff_hevc_rpi_pred_init_neon(c, bit_depth);
++}
++
+diff --git a/libavcodec/arm/rpi_hevcpred_init_neon.c b/libavcodec/arm/rpi_hevcpred_init_neon.c
+new file mode 100644
+index 0000000000..21e7700174
+--- /dev/null
++++ b/libavcodec/arm/rpi_hevcpred_init_neon.c
+@@ -0,0 +1,210 @@
++/*
++ * Copyright (c) 2018 John Cox (for Raspberry Pi)
++ *
++ * This file is part of FFmpeg.
++ *
++ * FFmpeg is free software; you can redistribute it and/or
++ * modify it under the terms of the GNU Lesser General Public
++ * License as published by the Free Software Foundation; either
++ * version 2.1 of the License, or (at your option) any later version.
++ *
++ * FFmpeg is distributed in the hope that it will be useful,
++ * but WITHOUT ANY WARRANTY; without even the implied warranty of
++ * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
++ * Lesser General Public License for more details.
++ *
++ * You should have received a copy of the GNU Lesser General Public
++ * License along with FFmpeg; if not, write to the Free Software
++ * Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA
++ */
++
++#include "rpi_hevcpred_arm.h"
++
++intra_filter_fn_t ff_hevc_rpi_intra_filter_4_neon_8;
++intra_filter_fn_t ff_hevc_rpi_intra_filter_8_neon_8;
++intra_filter_fn_t ff_hevc_rpi_intra_filter_4_neon_16;
++intra_filter_fn_t ff_hevc_rpi_intra_filter_8_neon_16;
++intra_filter_fn_t ff_hevc_rpi_intra_filter_16_neon_16;
++intra_filter_fn_t ff_hevc_rpi_intra_filter_4_neon_32;
++intra_filter_fn_t ff_hevc_rpi_intra_filter_8_neon_32;
++intra_filter_fn_t ff_hevc_rpi_intra_filter_16_neon_32;
++
++void ff_hevc_rpi_pred_angular_4_neon_8(uint8_t *src, const uint8_t *top, const uint8_t *left, ptrdiff_t stride, int mode);
++void ff_hevc_rpi_pred_angular_8_neon_8(uint8_t *src, const uint8_t *top, const uint8_t *left, ptrdiff_t stride, int mode);
++void ff_hevc_rpi_pred_angular_16_neon_8(uint8_t *src, const uint8_t *top, const uint8_t *left, ptrdiff_t stride, int mode);
++void ff_hevc_rpi_pred_angular_32_neon_8(uint8_t *src, const uint8_t *top, const uint8_t *left, ptrdiff_t stride, int mode);
++void ff_hevc_rpi_pred_angular_c_4_neon_8(uint8_t *src, const uint8_t *top, const uint8_t *left, ptrdiff_t stride, int mode);
++void ff_hevc_rpi_pred_angular_c_8_neon_8(uint8_t *src, const uint8_t *top, const uint8_t *left, ptrdiff_t stride, int mode);
++void ff_hevc_rpi_pred_angular_c_16_neon_8(uint8_t *src, const uint8_t *top, const uint8_t *left, ptrdiff_t stride, int mode);
++void ff_hevc_rpi_pred_angular_4_neon_10(uint8_t *src, const uint8_t *top, const uint8_t *left, ptrdiff_t stride, int mode);
++void ff_hevc_rpi_pred_angular_8_neon_10(uint8_t *src, const uint8_t *top, const uint8_t *left, ptrdiff_t stride, int mode);
++void ff_hevc_rpi_pred_angular_16_neon_10(uint8_t *src, const uint8_t *top, const uint8_t *left, ptrdiff_t stride, int mode);
++void ff_hevc_rpi_pred_angular_32_neon_10(uint8_t *src, const uint8_t *top, const uint8_t *left, ptrdiff_t stride, int mode);
++void ff_hevc_rpi_pred_angular_c_4_neon_10(uint8_t *src, const uint8_t *top, const uint8_t *left, ptrdiff_t stride, int mode);
++void ff_hevc_rpi_pred_angular_c_8_neon_10(uint8_t *src, const uint8_t *top, const uint8_t *left, ptrdiff_t stride, int mode);
++void ff_hevc_rpi_pred_angular_c_16_neon_10(uint8_t *src, const uint8_t *top, const uint8_t *left, ptrdiff_t stride, int mode);
++
++void ff_hevc_rpi_pred_vertical_4_neon_8(uint8_t *src, const uint8_t *top, const uint8_t *left, ptrdiff_t stride, int mode);
++void ff_hevc_rpi_pred_vertical_8_neon_8(uint8_t *src, const uint8_t *top, const uint8_t *left, ptrdiff_t stride, int mode);
++void ff_hevc_rpi_pred_vertical_16_neon_8(uint8_t *src, const uint8_t *top, const uint8_t *left, ptrdiff_t stride, int mode);
++void ff_hevc_rpi_pred_vertical_32_neon_8(uint8_t *src, const uint8_t *top, const uint8_t *left, ptrdiff_t stride, int mode);
++void ff_hevc_rpi_pred_vertical_c_4_neon_8(uint8_t *src, const uint8_t *top, const uint8_t *left, ptrdiff_t stride, int mode);
++void ff_hevc_rpi_pred_vertical_c_8_neon_8(uint8_t *src, const uint8_t *top, const uint8_t *left, ptrdiff_t stride, int mode);
++void ff_hevc_rpi_pred_vertical_c_16_neon_8(uint8_t *src, const uint8_t *top, const uint8_t *left, ptrdiff_t stride, int mode);
++void ff_hevc_rpi_pred_vertical_4_neon_10(uint8_t *src, const uint8_t *top, const uint8_t *left, ptrdiff_t stride, int mode);
++void ff_hevc_rpi_pred_vertical_8_neon_10(uint8_t *src, const uint8_t *top, const uint8_t *left, ptrdiff_t stride, int mode);
++void ff_hevc_rpi_pred_vertical_16_neon_10(uint8_t *src, const uint8_t *top, const uint8_t *left, ptrdiff_t stride, int mode);
++void ff_hevc_rpi_pred_vertical_32_neon_10(uint8_t *src, const uint8_t *top, const uint8_t *left, ptrdiff_t stride, int mode);
++void ff_hevc_rpi_pred_vertical_c_4_neon_10(uint8_t *src, const uint8_t *top, const uint8_t *left, ptrdiff_t stride, int mode);
++void ff_hevc_rpi_pred_vertical_c_8_neon_10(uint8_t *src, const uint8_t *top, const uint8_t *left, ptrdiff_t stride, int mode);
++void ff_hevc_rpi_pred_vertical_c_16_neon_10(uint8_t *src, const uint8_t *top, const uint8_t *left, ptrdiff_t stride, int mode);
++
++void ff_hevc_rpi_pred_horizontal_4_neon_8(uint8_t *src, const uint8_t *top, const uint8_t *left, ptrdiff_t stride, int mode);
++void ff_hevc_rpi_pred_horizontal_8_neon_8(uint8_t *src, const uint8_t *top, const uint8_t *left, ptrdiff_t stride, int mode);
++void ff_hevc_rpi_pred_horizontal_16_neon_8(uint8_t *src, const uint8_t *top, const uint8_t *left, ptrdiff_t stride, int mode);
++void ff_hevc_rpi_pred_horizontal_32_neon_8(uint8_t *src, const uint8_t *top, const uint8_t *left, ptrdiff_t stride, int mode);
++void ff_hevc_rpi_pred_horizontal_c_4_neon_8(uint8_t *src, const uint8_t *top, const uint8_t *left, ptrdiff_t stride, int mode);
++void ff_hevc_rpi_pred_horizontal_c_8_neon_8(uint8_t *src, const uint8_t *top, const uint8_t *left, ptrdiff_t stride, int mode);
++void ff_hevc_rpi_pred_horizontal_c_16_neon_8(uint8_t *src, const uint8_t *top, const uint8_t *left, ptrdiff_t stride, int mode);
++void ff_hevc_rpi_pred_horizontal_4_neon_10(uint8_t *src, const uint8_t *top, const uint8_t *left, ptrdiff_t stride, int mode);
++void ff_hevc_rpi_pred_horizontal_8_neon_10(uint8_t *src, const uint8_t *top, const uint8_t *left, ptrdiff_t stride, int mode);
++void ff_hevc_rpi_pred_horizontal_16_neon_10(uint8_t *src, const uint8_t *top, const uint8_t *left, ptrdiff_t stride, int mode);
++void ff_hevc_rpi_pred_horizontal_32_neon_10(uint8_t *src, const uint8_t *top, const uint8_t *left, ptrdiff_t stride, int mode);
++void ff_hevc_rpi_pred_horizontal_c_4_neon_10(uint8_t *src, const uint8_t *top, const uint8_t *left, ptrdiff_t stride, int mode);
++void ff_hevc_rpi_pred_horizontal_c_8_neon_10(uint8_t *src, const uint8_t *top, const uint8_t *left, ptrdiff_t stride, int mode);
++void ff_hevc_rpi_pred_horizontal_c_16_neon_10(uint8_t *src, const uint8_t *top, const uint8_t *left, ptrdiff_t stride, int mode);
++
++void ff_hevc_rpi_pred_planar_4_neon_8(uint8_t *src, const uint8_t *top, const uint8_t *left, ptrdiff_t stride);
++void ff_hevc_rpi_pred_planar_8_neon_8(uint8_t *src, const uint8_t *top, const uint8_t *left, ptrdiff_t stride);
++void ff_hevc_rpi_pred_planar_16_neon_8(uint8_t *src, const uint8_t *top, const uint8_t *left, ptrdiff_t stride);
++void ff_hevc_rpi_pred_planar_32_neon_8(uint8_t *src, const uint8_t *top, const uint8_t *left, ptrdiff_t stride);
++void ff_hevc_rpi_pred_planar_c_4_neon_8(uint8_t *src, const uint8_t *top, const uint8_t *left, ptrdiff_t stride);
++void ff_hevc_rpi_pred_planar_c_8_neon_8(uint8_t *src, const uint8_t *top, const uint8_t *left, ptrdiff_t stride);
++void ff_hevc_rpi_pred_planar_c_16_neon_8(uint8_t *src, const uint8_t *top, const uint8_t *left, ptrdiff_t stride);
++void ff_hevc_rpi_pred_planar_4_neon_10(uint8_t *src, const uint8_t *top, const uint8_t *left, ptrdiff_t stride);
++void ff_hevc_rpi_pred_planar_8_neon_10(uint8_t *src, const uint8_t *top, const uint8_t *left, ptrdiff_t stride);
++void ff_hevc_rpi_pred_planar_16_neon_10(uint8_t *src, const uint8_t *top, const uint8_t *left, ptrdiff_t stride);
++void ff_hevc_rpi_pred_planar_32_neon_10(uint8_t *src, const uint8_t *top, const uint8_t *left, ptrdiff_t stride);
++void ff_hevc_rpi_pred_planar_c_4_neon_10(uint8_t *src, const uint8_t *top, const uint8_t *left, ptrdiff_t stride);
++void ff_hevc_rpi_pred_planar_c_8_neon_10(uint8_t *src, const uint8_t *top, const uint8_t *left, ptrdiff_t stride);
++void ff_hevc_rpi_pred_planar_c_16_neon_10(uint8_t *src, const uint8_t *top, const uint8_t *left, ptrdiff_t stride);
++
++void ff_hevc_rpi_pred_dc_4_neon_8(uint8_t *src, const uint8_t *top, const uint8_t *left, ptrdiff_t stride);
++void ff_hevc_rpi_pred_dc_8_neon_8(uint8_t *src, const uint8_t *top, const uint8_t *left, ptrdiff_t stride);
++void ff_hevc_rpi_pred_dc_16_neon_8(uint8_t *src, const uint8_t *top, const uint8_t *left, ptrdiff_t stride);
++void ff_hevc_rpi_pred_dc_32_neon_8(uint8_t *src, const uint8_t *top, const uint8_t *left, ptrdiff_t stride);
++void ff_hevc_rpi_pred_dc_c_4_neon_8(uint8_t *src, const uint8_t *top, const uint8_t *left, ptrdiff_t stride);
++void ff_hevc_rpi_pred_dc_c_8_neon_8(uint8_t *src, const uint8_t *top, const uint8_t *left, ptrdiff_t stride);
++void ff_hevc_rpi_pred_dc_c_16_neon_8(uint8_t *src, const uint8_t *top, const uint8_t *left, ptrdiff_t stride);
++void ff_hevc_rpi_pred_dc_4_neon_10(uint8_t *src, const uint8_t *top, const uint8_t *left, ptrdiff_t stride);
++void ff_hevc_rpi_pred_dc_8_neon_10(uint8_t *src, const uint8_t *top, const uint8_t *left, ptrdiff_t stride);
++void ff_hevc_rpi_pred_dc_16_neon_10(uint8_t *src, const uint8_t *top, const uint8_t *left, ptrdiff_t stride);
++void ff_hevc_rpi_pred_dc_32_neon_10(uint8_t *src, const uint8_t *top, const uint8_t *left, ptrdiff_t stride);
++void ff_hevc_rpi_pred_dc_c_4_neon_10(uint8_t *src, const uint8_t *top, const uint8_t *left, ptrdiff_t stride);
++void ff_hevc_rpi_pred_dc_c_8_neon_10(uint8_t *src, const uint8_t *top, const uint8_t *left, ptrdiff_t stride);
++void ff_hevc_rpi_pred_dc_c_16_neon_10(uint8_t *src, const uint8_t *top, const uint8_t *left, ptrdiff_t stride);
++
++void ff_hevc_rpi_pred_init_neon(HEVCRpiPredContext * const c, const int bit_depth)
++{
++ switch (bit_depth)
++ {
++ case 8:
++ c->intra_filter[0] = ff_hevc_rpi_intra_filter_4_neon_8;
++ c->intra_filter[1] = ff_hevc_rpi_intra_filter_8_neon_8;
++ c->intra_filter_c[0] = ff_hevc_rpi_intra_filter_4_neon_16; // Equivalent to c_4_neon_8
++ c->intra_filter_c[1] = ff_hevc_rpi_intra_filter_8_neon_16;
++ c->intra_filter_c[2] = ff_hevc_rpi_intra_filter_16_neon_16;
++
++ c->pred_angular[0] = ff_hevc_rpi_pred_angular_4_neon_8;
++ c->pred_angular[1] = ff_hevc_rpi_pred_angular_8_neon_8;
++ c->pred_angular[2] = ff_hevc_rpi_pred_angular_16_neon_8;
++ c->pred_angular[3] = ff_hevc_rpi_pred_angular_32_neon_8;
++ c->pred_angular_c[0] = ff_hevc_rpi_pred_angular_c_4_neon_8;
++ c->pred_angular_c[1] = ff_hevc_rpi_pred_angular_c_8_neon_8;
++ c->pred_angular_c[2] = ff_hevc_rpi_pred_angular_c_16_neon_8;
++
++ c->pred_horizontal[0] = ff_hevc_rpi_pred_horizontal_4_neon_8;
++ c->pred_horizontal[1] = ff_hevc_rpi_pred_horizontal_8_neon_8;
++ c->pred_horizontal[2] = ff_hevc_rpi_pred_horizontal_16_neon_8;
++ c->pred_horizontal[3] = ff_hevc_rpi_pred_horizontal_32_neon_8;
++ c->pred_horizontal_c[0] = ff_hevc_rpi_pred_horizontal_c_4_neon_8;
++ c->pred_horizontal_c[1] = ff_hevc_rpi_pred_horizontal_c_8_neon_8;
++ c->pred_horizontal_c[2] = ff_hevc_rpi_pred_horizontal_c_16_neon_8;
++
++ c->pred_vertical[0] = ff_hevc_rpi_pred_vertical_4_neon_8;
++ c->pred_vertical[1] = ff_hevc_rpi_pred_vertical_8_neon_8;
++ c->pred_vertical[2] = ff_hevc_rpi_pred_vertical_16_neon_8;
++ c->pred_vertical[3] = ff_hevc_rpi_pred_vertical_32_neon_8;
++ c->pred_vertical_c[0] = ff_hevc_rpi_pred_vertical_c_4_neon_8;
++ c->pred_vertical_c[1] = ff_hevc_rpi_pred_vertical_c_8_neon_8;
++ c->pred_vertical_c[2] = ff_hevc_rpi_pred_vertical_c_16_neon_8;
++
++ c->pred_planar[0] = ff_hevc_rpi_pred_planar_4_neon_8;
++ c->pred_planar[1] = ff_hevc_rpi_pred_planar_8_neon_8;
++ c->pred_planar[2] = ff_hevc_rpi_pred_planar_16_neon_8;
++ c->pred_planar[3] = ff_hevc_rpi_pred_planar_32_neon_8;
++ c->pred_planar_c[0] = ff_hevc_rpi_pred_planar_c_4_neon_8;
++ c->pred_planar_c[1] = ff_hevc_rpi_pred_planar_c_8_neon_8;
++ c->pred_planar_c[2] = ff_hevc_rpi_pred_planar_c_16_neon_8;
++
++ c->pred_dc[0] = ff_hevc_rpi_pred_dc_4_neon_8;
++ c->pred_dc[1] = ff_hevc_rpi_pred_dc_8_neon_8;
++ c->pred_dc[2] = ff_hevc_rpi_pred_dc_16_neon_8;
++ c->pred_dc[3] = ff_hevc_rpi_pred_dc_32_neon_8;
++ c->pred_dc_c[0] = ff_hevc_rpi_pred_dc_c_4_neon_8;
++ c->pred_dc_c[1] = ff_hevc_rpi_pred_dc_c_8_neon_8;
++ c->pred_dc_c[2] = ff_hevc_rpi_pred_dc_c_16_neon_8;
++ break;
++ case 10:
++ c->intra_filter[0] = ff_hevc_rpi_intra_filter_4_neon_16;
++ c->intra_filter[1] = ff_hevc_rpi_intra_filter_8_neon_16;
++ c->intra_filter[2] = ff_hevc_rpi_intra_filter_16_neon_16;
++ c->intra_filter_c[0] = ff_hevc_rpi_intra_filter_4_neon_32;
++ c->intra_filter_c[1] = ff_hevc_rpi_intra_filter_8_neon_32;
++ c->intra_filter_c[2] = ff_hevc_rpi_intra_filter_16_neon_32;
++
++ c->pred_angular[0] = ff_hevc_rpi_pred_angular_4_neon_10;
++ c->pred_angular[1] = ff_hevc_rpi_pred_angular_8_neon_10;
++ c->pred_angular[2] = ff_hevc_rpi_pred_angular_16_neon_10;
++ c->pred_angular[3] = ff_hevc_rpi_pred_angular_32_neon_10;
++ c->pred_angular_c[0] = ff_hevc_rpi_pred_angular_c_4_neon_10;
++ c->pred_angular_c[1] = ff_hevc_rpi_pred_angular_c_8_neon_10;
++ c->pred_angular_c[2] = ff_hevc_rpi_pred_angular_c_16_neon_10;
++
++ c->pred_horizontal[0] = ff_hevc_rpi_pred_horizontal_4_neon_10;
++ c->pred_horizontal[1] = ff_hevc_rpi_pred_horizontal_8_neon_10;
++ c->pred_horizontal[2] = ff_hevc_rpi_pred_horizontal_16_neon_10;
++ c->pred_horizontal[3] = ff_hevc_rpi_pred_horizontal_32_neon_10;
++ c->pred_horizontal_c[0] = ff_hevc_rpi_pred_horizontal_c_4_neon_10;
++ c->pred_horizontal_c[1] = ff_hevc_rpi_pred_horizontal_c_8_neon_10;
++ c->pred_horizontal_c[2] = ff_hevc_rpi_pred_horizontal_c_16_neon_10;
++
++ c->pred_vertical[0] = ff_hevc_rpi_pred_vertical_4_neon_10;
++ c->pred_vertical[1] = ff_hevc_rpi_pred_vertical_8_neon_10;
++ c->pred_vertical[2] = ff_hevc_rpi_pred_vertical_16_neon_10;
++ c->pred_vertical[3] = ff_hevc_rpi_pred_vertical_32_neon_10;
++ c->pred_vertical_c[0] = ff_hevc_rpi_pred_vertical_c_4_neon_10;
++ c->pred_vertical_c[1] = ff_hevc_rpi_pred_vertical_c_8_neon_10;
++ c->pred_vertical_c[2] = ff_hevc_rpi_pred_vertical_c_16_neon_10;
++
++ c->pred_planar[0] = ff_hevc_rpi_pred_planar_4_neon_10;
++ c->pred_planar[1] = ff_hevc_rpi_pred_planar_8_neon_10;
++ c->pred_planar[2] = ff_hevc_rpi_pred_planar_16_neon_10;
++ c->pred_planar[3] = ff_hevc_rpi_pred_planar_32_neon_10;
++ c->pred_planar_c[0] = ff_hevc_rpi_pred_planar_c_4_neon_10;
++ c->pred_planar_c[1] = ff_hevc_rpi_pred_planar_c_8_neon_10;
++ c->pred_planar_c[2] = ff_hevc_rpi_pred_planar_c_16_neon_10;
++
++ c->pred_dc[0] = ff_hevc_rpi_pred_dc_4_neon_10;
++ c->pred_dc[1] = ff_hevc_rpi_pred_dc_8_neon_10;
++ c->pred_dc[2] = ff_hevc_rpi_pred_dc_16_neon_10;
++ c->pred_dc[3] = ff_hevc_rpi_pred_dc_32_neon_10;
++ c->pred_dc_c[0] = ff_hevc_rpi_pred_dc_c_4_neon_10;
++ c->pred_dc_c[1] = ff_hevc_rpi_pred_dc_c_8_neon_10;
++ c->pred_dc_c[2] = ff_hevc_rpi_pred_dc_c_16_neon_10;
++ break;
++ default:
++ break;
++ }
++}
++
+diff --git a/libavcodec/arm/rpi_hevcpred_intra_angular_neon.S b/libavcodec/arm/rpi_hevcpred_intra_angular_neon.S
+new file mode 100644
+index 0000000000..3dd9246a16
+--- /dev/null
++++ b/libavcodec/arm/rpi_hevcpred_intra_angular_neon.S
+@@ -0,0 +1,2975 @@
++/*
++ * Copyright (c) 2018 John Cox <jc@kynesim.co.uk> (for Raspberry Pi)
++ *
++ * This file is part of FFmpeg.
++ *
++ * FFmpeg is free software; you can redistribute it and/or
++ * modify it under the terms of the GNU Lesser General Public
++ * License as published by the Free Software Foundation; either
++ * version 2.1 of the License, or (at your option) any later version.
++ *
++ * FFmpeg is distributed in the hope that it will be useful,
++ * but WITHOUT ANY WARRANTY; without even the implied warranty of
++ * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
++ * Lesser General Public License for more details.
++ *
++ * You should have received a copy of the GNU Lesser General Public
++ * License along with FFmpeg; if not, write to the Free Software
++ * Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA
++ */
++
++/*
++ * General angular pred
++ *
++ * Horizontal (10) & Vertical (26) cases have their own file
++ * and are not dealt with properly here (luma filtering is missing)
++ *
++ * The inv_angle calculations are annoying - if it wasn't for the +128
++ * rounding step then the result would simply be the loop counter :-(
++ */
++
++
++#include "libavutil/arm/asm.S"
++#include "neon.S"
++
++.text
++
++@ Horizontal Patch functions
++@ These need a transpose before store so exist as smaller patches
++@ Patches can be called repeatedly without any intermediate setup
++@ to generate a horizontal block
++@
++@ It is almost certainly the case that larger patch fns can be built
++@ and they would be a little faster, but we would still need the small
++@ fns and code size (or at least instruction cache size) is an issue
++@ given how much code we already have here
++
++@ Generate 8x8 luma 8 patch
++@
++@ r3 Out stride
++@ r4 Angle add
++@ r7 Inv angle (_up only)
++@
++@ In/Out (updated)
++@ r0 Out pointer - on exit point to start of next patch horizontally (i.e. r0 + patch width)
++@ r2 Left ptr - updated
++@ r10 Inv angle accumulator (_up only)
++@ r12 32 - angle frac (_down) or angle frac (_up)
++@ d0 Older reference samples
++@ d1=r8+r9 Newer reference samples
++@ d2 32 - angle frac
++@ d3 Angle frac
++@ q2 Partially computed next result (_up only)
++@
++@ Temps
++@ r5 Loop counter
++@ r6
++@ r7 (_down only)
++@ r11 (_up only)
++@ q2, q8-q11
++
++patch_h_down_8x8_8:
++ ldrd r8, r9, [r2] @ Left
++ rsb r12, r6, #32
++ vmov d0, r8, r9
++ vdup.8 d3, r6
++ lsr r8, #8
++ vdup.8 d2, r12
++ orr r8, r8, r9, lsl #24
++ ldr r9, [r2, #5]!
++ vmov d1, r8, r9
++ // drop through...
++patch_h_down_8x8_8_continue:
++ mov r5, #8
++1:
++ subs r12, r4
++ vmull.u8 q2, d0, d2
++ it mi
++ addmi r12, #32
++ vmlal.u8 q2, d1, d3
++ rsb r6, r12, #32
++ vext.8 q8, q8, q9, #8
++ itt mi
++ lsrmi r7, r8, #8
++ vmovmi d0, r8, r9
++ vdup.8 d2, r12
++ vext.8 q9, q9, q10, #8
++ it mi
++ orrmi r8, r7, r9, lsl #24
++ vext.8 q10, q10, q11, #8
++ it mi
++ ldrmi r9, [r2, #1]!
++ vmov d22, d23
++ vrshrn.u16 d23, q2, #5
++ it mi
++ vmovmi d1, r8, r9
++ subs r5, #1
++ vdup.8 d3, r6
++ bne 1b
++ // drop through...
++store_tran_8x8_8:
++ vzip.8 d16, d17
++ add r6, r0, r3
++ vzip.8 d18, d19
++ lsl r3, #1
++ vzip.8 d20, d21
++ add r5, r0, r3
++ vzip.8 d22, d23
++ vzip.16 q8, q9
++ vzip.16 q10, q11
++ vzip.32 q8, q10
++ vzip.32 q9, q11
++ vst1.8 {d16}, [r0]!
++ vst1.8 {d17}, [r6], r3
++ vst1.8 {d20}, [r5], r3
++ vst1.8 {d21}, [r6], r3
++ vst1.8 {d18}, [r5], r3
++ vst1.8 {d19}, [r6], r3
++ vst1.8 {d22}, [r5]
++ asr r3, #1
++ vst1.8 {d23}, [r6]
++
++ bx lr
++
++patch_h_up_8x8_8:
++ ldrd r8, r9, [r2]
++ rsb r6, r4, #32
++ vmov d0, r8, r9
++ vdup.8 d3, r4
++ lsr r11, r8, #24
++ vdup.8 d2, r6
++ ldr r8, [r2, #-1]!
++ orr r9, r11, r9, lsl #8
++ vmov d1, r8, r9
++ mov r12, r4
++ vmull.u8 q2, d0, d2
++ vmlal.u8 q2, d1, d3
++patch_h_up_8x8_8_continue:
++ mov r5, #8
++1:
++ add r12, r4
++ mov r11, #0
++ cmp r12, #33
++ it cs
++ addcs r10, r7
++ vext.8 q8, q8, q9, #8
++ itt cs
++ subcs r12, #32
++ tstcs r10, #1<<31
++ rsb r6, r12, #32
++ it eq
++ asreq r11, r10, #8
++ it cs
++ vmovcs d0, r8, r9
++ vdup.8 d2, r6
++ it cs
++ lsrcs r6, r8, #24
++ vext.8 q9, q9, q10, #8
++ itt cs
++ orrcs r9, r6, r9, lsl #8
++ ldrbcs r11, [r1, r11]
++ vdup.8 d3, r12
++ vext.8 q10, q10, q11, #8
++ it hi
++ ldrbhi r11, [r2, #-1]!
++ vmov d22, d23
++ vrshrn.u16 d23, q2, #5
++ itt cs
++ orrcs r8, r11, r8, lsl #8
++ vmovcs d1, r8, r9
++ vmull.u8 q2, d0, d2
++ subs r5, #1
++ vmlal.u8 q2, d1, d3
++ bne 1b
++
++ b store_tran_8x8_8
++
++
++.macro ADRT reg, val
++@ adr in T32 has enough range but not in A32
++A adrl \reg, \val
++T adr \reg, \val
++.endm
++
++@ ff_hevc_rpi_pred_angular_4_neon_8
++@ uint8_t *_src, [r0]
++@ const uint8_t *_top, [r1]
++@ const uint8_t *_left, [r2]
++@ ptrdiff_t stride [r3]
++@ unsigned int mode [sp, #0] 2..34
++
++function ff_hevc_rpi_pred_angular_4_neon_8, export=1
++ ldr r12, [sp]
++ push {r4-r8, lr}
++ ADRT r4, angle_2 - 2
++ ADRT r7, inv_angle - 11*2
++ add r7, r7, r12, lsl #1
++ ldrsb r6, [r4, r12]
++ cmp r12, #26
++ ldrsb r4, [r4, r12]
++ bge 26f
++ cmp r12, #18
++ bge 18f
++ cmp r12, #10
++ bge 10f
++
++@ Down of Horizontal - works down left
++ ldr lr, [r2], #1 @ Top
++ rsb r12, r6, #32
++ vmov s0, lr
++ vdup.8 d3, r6
++ ldr lr, [r2], #1
++ vdup.8 d2, r12
++ vmov s2, lr
++ subs r12, r4
++ vmull.u8 q2, d0, d2
++ it mi
++ addmi r12, #32
++ vmlal.u8 q2, d1, d3
++ rsb r6, r12, #32
++ itt mi
++ vmovmi s0, lr
++ ldrmi lr, [r2], #1
++ vdup.8 d2, r12
++ it mi
++ vmovmi s2, lr
++ vdup.8 d3, r6
++ mov r5, #2
++1:
++ vrshrn.u16 d20, q2, #5
++ subs r12, r4
++ vmull.u8 q2, d0, d2
++ it mi
++ addmi r12, #32
++ vmlal.u8 q2, d1, d3
++ rsb r6, r12, #32
++ vext.64 q8, q8, q9, #1
++ it mi
++ vmovmi s0, lr
++ vext.64 q9, q9, q10, #1
++ it mi
++ ldrmi lr, [r2], #1
++ vdup.8 d2, r12
++ it mi
++ vmovmi s2, lr
++ subs r5, #1
++ vdup.8 d3, r6
++ bne 1b
++
++ vrshrn.u16 d20, q2, #5
++ vmull.u8 q2, d0, d2
++ add r12, r0, r3
++ vmlal.u8 q2, d1, d3
++ lsl r3, #1
++ vext.64 q8, q8, q9, #1
++ vext.64 q9, q9, q10, #1
++ vrshrn.u16 d20, q2, #5
++
++98:
++ vst4.8 {d17[0], d18[0], d19[0], d20[0]}, [r0], r3
++ vst4.8 {d17[1], d18[1], d19[1], d20[1]}, [r12], r3
++ vst4.8 {d17[2], d18[2], d19[2], d20[2]}, [r0]
++ vst4.8 {d17[3], d18[3], d19[3], d20[3]}, [r12]
++ pop {r4-r8, pc}
++
++@ Up of Horizontal - works down up
++10:
++ ldrh r7, [r7]
++ rsb r12, r6, #32
++ ldr lr, [r2] @ Left
++ ldrb r2, [r2, #-1] @ Top-left
++ vmov s0, lr
++ vdup.8 d2, r12
++ vdup.8 d3, r6
++ orr lr, r2, lr, lsl #8
++ vmov s2, lr
++ sub r8, r7, #128
++ mov r5, #3
++2:
++ vmull.u8 q2, d0, d2
++ subs r12, r4
++ vmlal.u8 q2, d1, d3
++T it mi
++ addmi r12, #32
++T asr r6, r8, #8
++T it mi
++T ldrbmi r2, [r1, r6]
++A ldrbmi r2, [r1, r8, asr #8]
++ rsb r6, r12, #32
++ vdup.8 d2, r12
++ ittt mi
++ vmovmi s0, lr
++ orrmi lr, r2, lr, lsl #8
++ vmovmi s2, lr
++ vrshrn.u16 d20, q2, #5
++ vdup.8 d3, r6
++ it mi
++ addmi r8, r7
++ subs r5, #1
++ vext.64 q8, q8, q9, #1
++ vext.64 q9, q9, q10, #1
++ bne 2b
++
++ vmull.u8 q2, d0, d2
++ add r12, r0, r3
++ vmlal.u8 q2, d1, d3
++ lsl r3, #1
++ vrshrn.u16 d20, q2, #5
++ b 98b
++
++@ Left of vertical - works down left
++18:
++ ldrh r7, [r7]
++ rsb r12, r6, #32
++ ldr lr, [r1] @ Top
++ ldrb r1, [r2, #-1] @ Top-left
++ vmov s0, lr
++ vdup.8 d2, r12
++ vdup.8 d3, r6
++ orr lr, r1, lr, lsl #8
++ vmov s2, lr
++ sub r8, r7, #128
++ mov r5, #3
++2:
++ vmull.u8 q2, d0, d2
++ subs r12, r4
++ vmlal.u8 q2, d1, d3
++T it mi
++ addmi r12, #32
++T asr r6, r8, #8
++T it mi
++T ldrbmi r1, [r2, r6]
++A ldrbmi r1, [r2, r8, asr #8]
++ rsb r6, r12, #32
++ vdup.8 d2, r12
++ ittt mi
++ vmovmi s0, lr
++ orrmi lr, r1, lr, lsl #8
++ vmovmi s2, lr
++ vrshrn.u16 d4, q2, #5
++ vdup.8 d3, r6
++ it mi
++ addmi r8, r7
++ subs r5, #1
++ vst1.32 {d4[0]}, [r0], r3
++ bne 2b
++
++ vmull.u8 q2, d0, d2
++ vmlal.u8 q2, d1, d3
++ vrshrn.u16 d4, q2, #5
++ vst1.32 {d4[0]}, [r0]
++
++ pop {r4-r8, pc}
++
++@ Right of vertical - works along top - left unused
++26:
++ ldr lr, [r1], #1 @ Top
++ rsb r12, r6, #32
++ vmov s0, lr
++ vdup.8 d3, r6
++ ldr lr, [r1], #1
++ vdup.8 d2, r12
++ vmov s2, lr
++ subs r12, r4
++ vmull.u8 q2, d0, d2
++ it mi
++ addmi r12, #32
++ vmlal.u8 q2, d1, d3
++ rsb r6, r12, #32
++ itt mi
++ vmovmi s0, lr
++ ldrmi lr, [r1], #1
++ vdup.8 d2, r12
++ it mi
++ vmovmi s2, lr
++ vdup.8 d3, r6
++ mov r5, #2
++1:
++ vrshrn.u16 d6, q2, #5
++ subs r12, r4
++ vmull.u8 q2, d0, d2
++ it mi
++ addmi r12, #32
++ vmlal.u8 q2, d1, d3
++ rsb r6, r12, #32
++ vst1.32 {d6[0]}, [r0], r3
++ itt mi
++ vmovmi s0, lr
++ ldrmi lr, [r1], #1
++ vdup.8 d2, r12
++ it mi
++ vmovmi s2, lr
++ subs r5, #1
++ vdup.8 d3, r6
++ bne 1b
++
++ vrshrn.u16 d6, q2, #5
++ vmull.u8 q2, d0, d2
++ vmlal.u8 q2, d1, d3
++ vst1.32 {d6[0]}, [r0], r3
++ vrshrn.u16 d6, q2, #5
++ vst1.32 {d6[0]}, [r0]
++
++ pop {r4-r8, pc}
++
++endfunc
++
++
++
++@ ff_hevc_rpi_pred_angular_8_neon_8
++@ uint8_t *_src, [r0]
++@ const uint8_t *_top, [r1]
++@ const uint8_t *_left, [r2]
++@ ptrdiff_t stride [r3]
++@ unsigned int mode [sp, #0] 2..34
++
++function ff_hevc_rpi_pred_angular_8_neon_8, export=1
++ ldr r12, [sp]
++ push {r4-r11, lr}
++ ADRT r4, angle_2 - 2
++ ADRT r7, inv_angle - 11*2
++ add r7, r7, r12, lsl #1
++ ldrsb r6, [r4, r12]
++ cmp r12, #26
++ ldrsb r4, [r4, r12]
++ bge 26f
++ cmp r12, #18
++ bge 18f
++ cmp r12, #10
++ bge 10f
++
++@ Down of Horizontal - works down left
++ bl patch_h_down_8x8_8
++ pop {r4-r11, pc}
++
++@ Up of Horizontal - works down up
++10:
++ ldrh r7, [r7]
++ mov r10, #-128
++ bl patch_h_up_8x8_8
++ pop {r4-r11, pc}
++
++@ Left of vertical - works down left
++18:
++ ldrd r8, r9, [r1] @ Top
++ rsb r12, r6, #32
++ ldrb lr, [r2, #-1] @ Top-left
++ ldrh r7, [r7]
++ vmov d0, r8, r9
++ lsl r9, r9, #8
++ vdup.8 d2, r12
++ orr r9, r9, r8, lsr #24
++ orr r8, lr, r8, lsl #8
++ vmov d1, r8, r9
++ sub r1, r7, #128
++ mov r5, #7
++1:
++ vdup.8 d3, r6
++ vmull.u8 q2, d0, d2
++ subs r12, r12, r4
++ vmlal.u8 q2, d1, d3
++ ittt mi
++ addmi lr, r2, r1, asr #8
++ addmi r12, r12, #32
++ vmovmi d0, r8, r9
++ rsb r6, r12, #32
++ itt mi
++ lslmi r9, r9, #8
++ ldrbmi lr, [lr]
++ vdup.8 d2, r12
++ vrshrn.u16 d4, q2, #5
++ itttt mi
++ orrmi r9, r9, r8, lsr #24
++ orrmi r8, lr, r8, lsl #8
++ vmovmi d1, r8, r9
++ addmi r1, r1, r7
++ subs r5, r5, #1
++ vst1.8 {d4}, [r0], r3
++ bne 1b
++
++ vdup.8 d3, r6
++ vmull.u8 q2, d0, d2
++ vmlal.u8 q2, d1, d3
++ vrshrn.u16 d4, q2, #5
++ vst1.8 {d4}, [r0]
++
++ pop {r4-r11, pc}
++
++@ Right of vertical - works along top - left unused
++26:
++ ldrd r8, r9, [r1] @ Top
++ rsb r12, r6, #32
++ vmov d0, r8, r9
++ vdup.8 d3, r6
++ mov r5, #7
++ lsr r8, #8
++ vdup.8 d2, r12
++ orr r8, r8, r9, lsl #24
++ ldr r9, [r1, #5]!
++ vmov d1, r8, r9
++1:
++ vmull.u8 q2, d0, d2
++ subs r12, r4
++ vmlal.u8 q2, d1, d3
++ it mi
++ addmi r12, #32
++ rsb r6, r12, #32
++ itt mi
++ vmovmi d0, r8, r9
++ lsrmi r8, #8
++ vdup.8 d2, r12
++ itt mi
++ orrmi r8, r8, r9, lsl #24
++ ldrmi r9, [r1, #1]!
++ vrshrn.u16 d6, q2, #5
++ it mi
++ vmovmi d1, r8, r9
++ vdup.8 d3, r6
++ subs r5, #1
++ vst1.8 {d6}, [r0], r3
++ bne 1b
++
++ vmull.u8 q2, d0, d2
++ vmlal.u8 q2, d1, d3
++ vrshrn.u16 d6, q2, #5
++ vst1.8 {d6}, [r0]
++
++ pop {r4-r11, pc}
++
++endfunc
++
++
++@ ff_hevc_rpi_pred_angular_16_neon_8
++@ uint8_t *_src, [r0]
++@ const uint8_t *_top, [r1]
++@ const uint8_t *_left, [r2]
++@ ptrdiff_t stride [r3]
++@ unsigned int mode [sp, #0] 2..34
++
++function ff_hevc_rpi_pred_angular_16_neon_8, export=1
++ ldr r12, [sp]
++ push {r4-r11, lr}
++ ADRT r4, angle_2 - 2
++ ADRT r7, inv_angle - 11*2
++ add r7, r7, r12, lsl #1
++ ldrsb r6, [r4, r12]
++ cmp r12, #26
++ ldrsb r4, [r4, r12]
++ bge 26f
++ cmp r12, #18
++ bge 18f
++ cmp r12, #10
++ bge 10f
++
++@ Down of Horizontal - works down left
++ mov r1, r2 @ save r2 - r1 unused by patch_down
++
++ bl patch_h_down_8x8_8
++ bl patch_h_down_8x8_8_continue
++
++ add r2, r1, #8 @ restore r2, but 8 rows further down left
++ sub r0, #16
++ mov r6, r4
++ add r0, r0, r3, lsl #3
++
++ bl patch_h_down_8x8_8
++ bl patch_h_down_8x8_8_continue
++
++ pop {r4-r11, pc}
++
++@ Up of Horizontal - works down up
++10:
++ ldrh r7, [r7]
++ mov r10, #-128
++
++ push {r2}
++ bl patch_h_up_8x8_8
++ bl patch_h_up_8x8_8_continue
++ pop {r2}
++
++ sub r0, #16
++ mov r10, #-128
++ add r2, #8
++ add r0, r0, r3, lsl #3
++ sub r10, r10, r7, lsl #3
++
++ bl patch_h_up_8x8_8
++ bl patch_h_up_8x8_8_continue
++
++ pop {r4-r11, pc}
++
++@ Left of vertical - works down left
++18:
++ vld1.8 {q9}, [r1]
++ sub r1, r2, #1
++ rsb r12, r6, #32
++ ldrh r7, [r7]
++ vdup.8 d6, r6
++ vext.8 q8, q9, q9, #15
++ sub r8, r7, #128
++ vld1.8 {d16[0]}, [r1]
++ vdup.8 d7, r12
++ mov r5, #15
++1:
++ vmull.u8 q0, d18, d7
++ subs r12, r4
++ vmlal.u8 q0, d16, d6
++ it cc
++ addcc r12, #32
++ vmull.u8 q1, d19, d7
++ it cc
++ addcc r1, r2, r8, asr #8
++ vmlal.u8 q1, d17, d6
++ rsb r6, r12, #32
++ vext.8 q10, q8, q8, #15
++ sub r5, #1
++ vld1.8 {d20[0]}, [r1]
++ it cc
++ addcc r8, r7
++ vmov q11, q8
++ teq r5, #0
++ vrshrn.u16 d0, q0, #5
++ vrshrn.u16 d1, q1, #5
++ vdup.8 d6, r6
++ vdup.8 d7, r12
++ vst1.8 {q0}, [r0], r3
++ bhi 1b
++ beq 4f
++2:
++ vmull.u8 q0, d22, d7
++ subs r12, r4
++ vmlal.u8 q0, d20, d6
++ it cc
++ addcc r12, #32
++ vmull.u8 q1, d23, d7
++ it cc
++ addcc r1, r2, r8, asr #8
++ vmlal.u8 q1, d21, d6
++ rsb r6, r12, #32
++ vext.8 q8, q10, q10, #15
++ sub r5, #1
++ vld1.8 {d16[0]}, [r1]
++ it cc
++ addcc r8, r7
++ vmov q9, q10
++ teq r5, #0
++ vrshrn.u16 d0, q0, #5
++ vrshrn.u16 d1, q1, #5
++ vdup.8 d6, r6
++ vdup.8 d7, r12
++ vst1.8 {q0}, [r0], r3
++ bhi 2b
++ bne 1b
++ bcc 5f
++3:
++ vmull.u8 q0, d22, d7
++ vmlal.u8 q0, d20, d6
++ vmull.u8 q1, d23, d7
++ vmlal.u8 q1, d21, d6
++ vrshrn.u16 d0, q0, #5
++ vrshrn.u16 d1, q1, #5
++ vst1.8 {q0}, [r0]
++
++ pop {r4-r11, pc}
++4:
++ bcc 3b
++5:
++ vmull.u8 q0, d18, d7
++ vmlal.u8 q0, d16, d6
++ vmull.u8 q1, d19, d7
++ vmlal.u8 q1, d17, d6
++ vrshrn.u16 d0, q0, #5
++ vrshrn.u16 d1, q1, #5
++ vst1.8 {q0}, [r0]
++
++ pop {r4-r11, pc}
++
++@ Right of vertical - works along top - left unused
++26:
++ vld1.8 {q9}, [r1]!
++ rsb r12, r6, #32
++ vdup.8 d6, r6
++ vdup.8 d7, r12
++ vext.8 q8, q9, q9, #1
++ vld1.8 {d17[7]}, [r1]!
++ mov r5, #15
++1:
++ vmull.u8 q0, d16, d6
++ subs r12, r4
++ vmlal.u8 q0, d18, d7
++ it cc
++ addcc r12, #32
++ vmull.u8 q1, d17, d6
++ rsb r6, r12, #32
++ vmlal.u8 q1, d19, d7
++ sub r5, #1
++ vext.8 q10, q8, q8, #1
++ teq r5, #0
++ vld1.8 {d21[7]}, [r1]
++ it cc
++ addcc r1, #1
++ vmov q11, q8
++ vrshrn.u16 d0, q0, #5
++ vrshrn.u16 d1, q1, #5
++ vdup.8 d6, r6
++ vdup.8 d7, r12
++ vst1.8 {q0}, [r0], r3
++ bhi 1b
++ beq 4f
++2:
++ vmull.u8 q0, d20, d6
++ subs r12, r4
++ vmlal.u8 q0, d22, d7
++ it cc
++ addcc r12, #32
++ vmull.u8 q1, d21, d6
++ rsb r6, r12, #32
++ vmlal.u8 q1, d23, d7
++ sub r5, #1
++ vext.8 q8, q10, q10, #1
++ teq r5, #0
++ vld1.8 {d17[7]}, [r1]
++ it cc
++ addcc r1, #1
++ vmov q9, q10
++ vrshrn.u16 d0, q0, #5
++ vrshrn.u16 d1, q1, #5
++ vdup.8 d6, r6
++ vdup.8 d7, r12
++ vst1.8 {q0}, [r0], r3
++ bhi 2b
++ bne 1b
++ bcc 5f
++3:
++ vmull.u8 q0, d20, d6
++ vmlal.u8 q0, d22, d7
++ vmull.u8 q1, d21, d6
++ vmlal.u8 q1, d23, d7
++ vrshrn.u16 d0, q0, #5
++ vrshrn.u16 d1, q1, #5
++ vst1.8 {q0}, [r0]
++
++ pop {r4-r11, pc}
++4:
++ bcc 3b
++5:
++ vmull.u8 q0, d16, d6
++ vmlal.u8 q0, d18, d7
++ vmull.u8 q1, d17, d6
++ vmlal.u8 q1, d19, d7
++ vrshrn.u16 d0, q0, #5
++ vrshrn.u16 d1, q1, #5
++ vst1.8 {q0}, [r0]
++
++ pop {r4-r11, pc}
++
++endfunc
++
++
++@ ff_hevc_rpi_pred_angular_32_neon_8
++@ uint8_t *_src, [r0]
++@ const uint8_t *_top, [r1]
++@ const uint8_t *_left, [r2]
++@ ptrdiff_t stride [r3]
++@ unsigned int mode [sp, #0] 2..34
++
++function ff_hevc_rpi_pred_angular_32_neon_8, export=1
++ ldr r12, [sp]
++ push {r4-r11, lr}
++ ADRT r4, angle_2 - 2
++ ADRT r7, inv_angle - 11*2
++ add r7, r7, r12, lsl #1
++ ldrsb r6, [r4, r12]
++ cmp r12, #26
++ ldrsb r4, [r4, r12]
++ bge 26f
++ cmp r12, #18
++ bge 18f
++ cmp r12, #10
++ bge 10f
++
++@ Down of Horizontal - works down left
++ mov r10, #4
++ mov r1, r2
++1:
++ bl patch_h_down_8x8_8
++ bl patch_h_down_8x8_8_continue
++ bl patch_h_down_8x8_8_continue
++ bl patch_h_down_8x8_8_continue
++
++ add r2, r1, #8 @ restore r2, but 8 rows further down left
++ add r1, r1, #8
++ mov r6, r4
++ sub r0, #32
++ subs r10, #1
++ add r0, r0, r3, lsl #3
++ bne 1b
++
++ pop {r4-r11, pc}
++
++@ Up of Horizontal - works down up
++10:
++ ldrh r7, [r7]
++ mov r10, #-128
++ vmov.i8 d6, #1<<2
++1:
++ push {r2,r10}
++ bl patch_h_up_8x8_8
++ bl patch_h_up_8x8_8_continue
++ bl patch_h_up_8x8_8_continue
++ bl patch_h_up_8x8_8_continue
++ pop {r2,r10}
++
++ vmov r8, s12
++ sub r0, #32
++ add r2, #8
++ add r0, r0, r3, lsl #3
++ sub r10, r10, r7, lsl #3
++ vshr.u8 d6, #1
++ teq r8, #0
++ bne 1b
++
++ pop {r4-r11, pc}
++
++@ Left of vertical - works down left
++18:
++ vld1.8 {q0-q1}, [r1]
++ sub r9, r2, #1
++ rsb r12, r6, #32
++ ldrh r7, [r7]
++ mov r8, #-128
++ vdup.8 d18, r6
++ vdup.8 d19, r12
++ mov r5, #32
++1:
++ vld1.8 {d17[7]}, [r9]
++ add r8, r7
++ vmov q2, q0
++ vmov q3, q1
++ add r9, r2, r8, asr #8
++ vext.8 q1, q0, q1, #15
++ vext.8 q0, q8, q0, #15
++2:
++ vmull.u8 q10, d4, d19
++ subs r12, r4
++ vmlal.u8 q10, d0, d18
++ it cc
++ addcc r12, #32
++ vmull.u8 q11, d5, d19
++ rsb r6, r12, #32
++ vmlal.u8 q11, d1, d18
++ sub r5, #1
++ vmull.u8 q12, d6, d19
++ teq r5, #0
++ vmlal.u8 q12, d2, d18
++ vmull.u8 q13, d7, d19
++ vmlal.u8 q13, d3, d18
++ vdup.8 d18, r6
++ vdup.8 d19, r12
++ vrshrn.u16 d20, q10, #5
++ vrshrn.u16 d21, q11, #5
++ vrshrn.u16 d22, q12, #5
++ vrshrn.u16 d23, q13, #5
++ vst1.8 {q10-q11}, [r0], r3
++ bhi 2b
++ bne 1b
++
++ pop {r4-r11, pc}
++
++@ Right of vertical - works along top - left unused
++26:
++ add r5, r1, #32
++ vld1.8 {q0-q1}, [r1]!
++ rsb r12, r6, #32
++ vld1.8 {d16[0]}, [r5]
++ mov r5, #32
++ vdup.8 d18, r6
++ vdup.8 d19, r12
++1:
++ vmov q2, q0
++ add r1, #1
++ vmov q3, q1
++ vext.8 q0, q0, q1, #1
++ vext.8 q1, q1, q8, #1
++2:
++ vmull.u8 q10, d0, d18
++ subs r12, r4
++ vmlal.u8 q10, d4, d19
++ it cc
++ addcc r12, #32
++ vmull.u8 q11, d1, d18
++ rsb r6, r12, #32
++ vmlal.u8 q11, d5, d19
++ sub r5, #1
++ vmull.u8 q12, d2, d18
++ teq r5, #0
++ vmlal.u8 q12, d6, d19
++ vmull.u8 q13, d3, d18
++ vmlal.u8 q13, d7, d19
++ vld1.8 {d16[0]}, [r1]
++ vdup.8 d18, r6
++ vdup.8 d19, r12
++ vrshrn.u16 d20, q10, #5
++ vrshrn.u16 d21, q11, #5
++ vrshrn.u16 d22, q12, #5
++ vrshrn.u16 d23, q13, #5
++ vst1.8 {q10-q11}, [r0], r3
++ bhi 2b
++ bne 1b
++
++ pop {r4-r11, pc}
++
++endfunc
++
++
++@ Chroma 8 bit 4x4 patch fns
++ .text
++
++patch_h_down_c_4x4_8:
++ ldrd r8, r9, [r2] @ Left
++ rsb r12, r6, #32
++ vmov d0, r8, r9
++ vdup.8 d3, r6
++ lsr r8, #16
++ vdup.8 d2, r12
++ orr r8, r8, r9, lsl #16
++ ldr r9, [r2, #6]!
++ vmov d1, r8, r9
++ // drop through...
++patch_h_down_c_4x4_8_continue:
++ mov r5, #4
++1:
++ subs r12, r4
++ vmull.u8 q2, d0, d2
++ it mi
++ addmi r12, #32
++ vmlal.u8 q2, d1, d3
++ rsb r6, r12, #32
++ vext.8 q8, q8, q9, #8
++ it mi
++ lsrmi r7, r8, #16
++ vmov d18, d19
++ it mi
++ vmovmi d0, r8, r9
++ vdup.8 d2, r12
++ it mi
++ orrmi r8, r7, r9, lsl #16
++ vrshrn.u16 d19, q2, #5
++ itt mi
++ ldrmi r9, [r2, #2]!
++ vmovmi d1, r8, r9
++ subs r5, #1
++ vdup.8 d3, r6
++ bne 1b
++ // drop through...
++store_tran_c_4x4_8:
++ vzip.16 d16, d17
++ add r6, r0, r3
++ vzip.16 d18, d19
++ lsl r3, #1
++ vzip.32 q8, q9
++ add r5, r0, r3
++ vst1.16 {d16}, [r0]!
++ vst1.16 {d17}, [r6], r3
++ vst1.16 {d18}, [r5]
++ asr r3, #1
++ vst1.16 {d19}, [r6]
++
++ bx lr
++
++patch_h_up_c_4x4_8:
++ ldrd r8, r9, [r2]
++ rsb r6, r4, #32
++ vmov d0, r8, r9
++ vdup.8 d3, r4
++ lsr r11, r8, #16
++ vdup.8 d2, r6
++ ldr r8, [r2, #-2]!
++ orr r9, r11, r9, lsl #16
++ vmov d1, r8, r9
++ mov r12, r4
++ vmull.u8 q2, d0, d2
++ vmlal.u8 q2, d1, d3
++patch_h_up_c_4x4_8_continue:
++ mov r5, #4
++1:
++ add r12, r4
++ cmp r12, #33
++ it cs
++ addcs r10, r7
++ mov r11, #0
++ itt cs
++ subcs r12, #32
++ tstcs r10, #1<<31
++ rsb r6, r12, #32
++ it eq
++ asreq r11, r10, #7
++ it cs
++ vmovcs d0, r8, r9
++ it eq
++ biceq r11, #1
++ vdup.8 d2, r6
++ it cs
++ lsrcs r6, r8, #16
++ vdup.8 d3, r12
++ vext.8 q8, q8, q9, #8
++ itt cs
++ orrcs r9, r6, r9, lsl #16
++ ldrhcs r11, [r1, r11]
++ vmov d18, d19
++ it hi
++ ldrhhi r11, [r2, #-2]!
++ vrshrn.u16 d19, q2, #5
++ itt cs
++ orrcs r8, r11, r8, lsl #16
++ vmovcs d1, r8, r9
++ vmull.u8 q2, d0, d2
++ subs r5, #1
++ vmlal.u8 q2, d1, d3
++ bne 1b
++
++ b store_tran_c_4x4_8
++
++
++@ ff_hevc_rpi_pred_angular_c_4_neon_8
++@ uint8_t *_src, [r0]
++@ const uint8_t *_top, [r1]
++@ const uint8_t *_left, [r2]
++@ ptrdiff_t stride [r3]
++@ unsigned int mode [sp, #0] 2..34
++
++function ff_hevc_rpi_pred_angular_c_4_neon_8, export=1
++ ldr r12, [sp]
++ push {r4-r11, lr}
++ ADRT r4, angle_2 - 2
++ ADRT r7, inv_angle - 11*2
++ add r7, r7, r12, lsl #1
++ lsl r3, #1
++ ldrsb r6, [r4, r12]
++ cmp r12, #26
++ ldrsb r4, [r4, r12]
++ bge 26f
++ cmp r12, #18
++ bge 18f
++ cmp r12, #10
++ bge 10f
++
++@ Down of Horizontal - works down left
++ bl patch_h_down_c_4x4_8
++ pop {r4-r11, pc}
++
++@ Up of Horizontal - works down up
++10:
++ ldrh r7, [r7]
++ mov r10, #-128
++ bl patch_h_up_c_4x4_8
++ pop {r4-r11, pc}
++
++@ Left of vertical - works down left
++18:
++ ldrd r8, r9, [r1] @ Top
++ rsb r12, r6, #32
++ ldrh lr, [r2, #-2] @ Top-left
++ ldrh r7, [r7]
++ vmov d0, r8, r9
++ lsl r9, r9, #16
++ vdup.8 d2, r12
++ orr r9, r9, r8, lsr #16
++ orr r8, lr, r8, lsl #16
++ vmov d1, r8, r9
++ sub r1, r7, #128
++ mov r5, #3
++1:
++ vdup.8 d3, r6
++ vmull.u8 q2, d0, d2
++ subs r12, r12, r4
++ vmlal.u8 q2, d1, d3
++ itttt mi
++ addmi lr, r2, r1, asr #7
++ bicmi lr, #1
++ addmi r12, r12, #32
++ vmovmi d0, r8, r9
++ rsb r6, r12, #32
++ itt mi
++ lslmi r9, r9, #16
++ ldrhmi lr, [lr]
++ vdup.8 d2, r12
++ vrshrn.u16 d4, q2, #5
++ itttt mi
++ orrmi r9, r9, r8, lsr #16
++ orrmi r8, lr, r8, lsl #16
++ vmovmi d1, r8, r9
++ addmi r1, r1, r7
++ subs r5, r5, #1
++ vst1.16 {d4}, [r0], r3
++ bne 1b
++
++ vdup.8 d3, r6
++ vmull.u8 q2, d0, d2
++ vmlal.u8 q2, d1, d3
++ vrshrn.u16 d4, q2, #5
++ vst1.16 {d4}, [r0]
++
++ pop {r4-r11, pc}
++
++@ Right of vertical - works along top - left unused
++26:
++ ldrd r8, r9, [r1] @ Top
++ rsb r12, r6, #32
++ vmov d0, r8, r9
++ vdup.8 d3, r6
++ mov r5, #3
++ lsr r8, #16
++ vdup.8 d2, r12
++ orr r8, r8, r9, lsl #16
++ ldr r9, [r1, #6]!
++ vmov d1, r8, r9
++1:
++ vmull.u8 q2, d0, d2
++ subs r12, r4
++ vmlal.u8 q2, d1, d3
++ it mi
++ addmi r12, #32
++ rsb r6, r12, #32
++ itt mi
++ vmovmi d0, r8, r9
++ lsrmi r8, #16
++ vdup.8 d2, r12
++ itt mi
++ orrmi r8, r8, r9, lsl #16
++ ldrmi r9, [r1, #2]!
++ vrshrn.u16 d6, q2, #5
++ it mi
++ vmovmi d1, r8, r9
++ vdup.8 d3, r6
++ subs r5, #1
++ vst1.16 {d6}, [r0], r3
++ bne 1b
++
++ vmull.u8 q2, d0, d2
++ vmlal.u8 q2, d1, d3
++ vrshrn.u16 d6, q2, #5
++ vst1.16 {d6}, [r0]
++
++ pop {r4-r11, pc}
++
++endfunc
++
++
++@ ff_hevc_rpi_pred_angular_c_8_neon_8
++@ uint8_t *_src, [r0]
++@ const uint8_t *_top, [r1]
++@ const uint8_t *_left, [r2]
++@ ptrdiff_t stride [r3]
++@ unsigned int mode [sp, #0] 2..34
++
++function ff_hevc_rpi_pred_angular_c_8_neon_8, export=1
++ ldr r12, [sp]
++ push {r4-r11, lr}
++ ADRT r4, angle_2 - 2
++ ADRT r7, inv_angle - 11*2
++ add r7, r7, r12, lsl #1
++ lsl r3, #1
++ ldrsb r6, [r4, r12]
++ cmp r12, #26
++ ldrsb r4, [r4, r12]
++ bge 26f
++ cmp r12, #18
++ bge 18f
++ cmp r12, #10
++ bge 10f
++
++@ Down of Horizontal - works down left
++ mov r1, r2 @ save r2 - r1 unused by patch_down
++
++ bl patch_h_down_c_4x4_8
++ bl patch_h_down_c_4x4_8_continue
++
++ add r2, r1, #4*2 @ restore r2, but 4 rows further down left
++ sub r0, #16
++ mov r6, r4
++ add r0, r0, r3, lsl #2
++
++ bl patch_h_down_c_4x4_8
++ bl patch_h_down_c_4x4_8_continue
++
++ pop {r4-r11, pc}
++
++@ Up of Horizontal - works down up
++10:
++ ldrh r7, [r7]
++ mov r10, #-128
++
++ push {r2}
++ bl patch_h_up_c_4x4_8
++ bl patch_h_up_c_4x4_8_continue
++ pop {r2}
++
++ sub r0, #16
++ mov r10, #-128
++ add r2, #8
++ add r0, r0, r3, lsl #2
++ sub r10, r10, r7, lsl #2
++
++ bl patch_h_up_c_4x4_8
++ bl patch_h_up_c_4x4_8_continue
++
++ pop {r4-r11, pc}
++
++@ Left of vertical - works down left
++18:
++ vld1.8 {q9}, [r1]
++ sub r1, r2, #2
++ rsb r12, r6, #32
++ ldrh r7, [r7]
++ vdup.8 d6, r6
++ vext.8 q8, q9, q9, #14
++ sub r8, r7, #128
++ vld1.16 {d16[0]}, [r1]
++ vdup.8 d7, r12
++ mov r5, #7
++1:
++ subs r12, r4
++ vmull.u8 q0, d18, d7
++ it cc
++ asrcc r1, r8, #8
++ vmlal.u8 q0, d16, d6
++ it cc
++ addcc r12, #32
++ vmull.u8 q1, d19, d7
++ it cc
++ addcc r1, r2, r1, lsl #1
++ vmlal.u8 q1, d17, d6
++ rsb r6, r12, #32
++ vext.8 q10, q8, q8, #14
++ sub r5, #1
++ vld1.16 {d20[0]}, [r1]
++ it cc
++ addcc r8, r7
++ vmov q11, q8
++ teq r5, #0
++ vrshrn.u16 d0, q0, #5
++ vrshrn.u16 d1, q1, #5
++ vdup.8 d6, r6
++ vdup.8 d7, r12
++ vst1.8 {q0}, [r0], r3
++ bhi 1b
++ beq 4f
++2:
++ subs r12, r4
++ vmull.u8 q0, d22, d7
++ it cc
++ asrcc r1, r8, #8
++ vmlal.u8 q0, d20, d6
++ it cc
++ addcc r12, #32
++ vmull.u8 q1, d23, d7
++ it cc
++ addcc r1, r2, r1, lsl #1
++ vmlal.u8 q1, d21, d6
++ rsb r6, r12, #32
++ vext.8 q8, q10, q10, #14
++ sub r5, #1
++ vld1.16 {d16[0]}, [r1]
++ it cc
++ addcc r8, r7
++ vmov q9, q10
++ teq r5, #0
++ vrshrn.u16 d0, q0, #5
++ vrshrn.u16 d1, q1, #5
++ vdup.8 d6, r6
++ vdup.8 d7, r12
++ vst1.8 {q0}, [r0], r3
++ bhi 2b
++ bne 1b
++ bcc 5f
++3:
++ vmull.u8 q0, d22, d7
++ vmlal.u8 q0, d20, d6
++ vmull.u8 q1, d23, d7
++ vmlal.u8 q1, d21, d6
++ vrshrn.u16 d0, q0, #5
++ vrshrn.u16 d1, q1, #5
++ vst1.8 {q0}, [r0]
++
++ pop {r4-r11, pc}
++4:
++ bcc 3b
++5:
++ vmull.u8 q0, d18, d7
++ vmlal.u8 q0, d16, d6
++ vmull.u8 q1, d19, d7
++ vmlal.u8 q1, d17, d6
++ vrshrn.u16 d0, q0, #5
++ vrshrn.u16 d1, q1, #5
++ vst1.8 {q0}, [r0]
++
++ pop {r4-r11, pc}
++
++@ Right of vertical - works along top - left unused
++26:
++ vld1.8 {q9}, [r1]!
++ rsb r12, r6, #32
++ vdup.8 d6, r6
++ vdup.8 d7, r12
++ vext.8 q8, q9, q9, #2
++ vld1.16 {d17[3]}, [r1]!
++ mov r5, #7
++1:
++ vmull.u8 q0, d16, d6
++ subs r12, r4
++ vmlal.u8 q0, d18, d7
++ it cc
++ addcc r12, #32
++ vmull.u8 q1, d17, d6
++ rsb r6, r12, #32
++ vmlal.u8 q1, d19, d7
++ sub r5, #1
++ vext.8 q10, q8, q8, #2
++ teq r5, #0
++ vld1.16 {d21[3]}, [r1]
++ it cc
++ addcc r1, #2
++ vmov q11, q8
++ vrshrn.u16 d0, q0, #5
++ vrshrn.u16 d1, q1, #5
++ vdup.8 d6, r6
++ vdup.8 d7, r12
++ vst1.8 {q0}, [r0], r3
++ bhi 1b
++ beq 4f
++2:
++ vmull.u8 q0, d20, d6
++ subs r12, r4
++ vmlal.u8 q0, d22, d7
++ it cc
++ addcc r12, #32
++ vmull.u8 q1, d21, d6
++ rsb r6, r12, #32
++ vmlal.u8 q1, d23, d7
++ sub r5, #1
++ vext.8 q8, q10, q10, #2
++ teq r5, #0
++ vld1.16 {d17[3]}, [r1]
++ it cc
++ addcc r1, #2
++ vmov q9, q10
++ vrshrn.u16 d0, q0, #5
++ vrshrn.u16 d1, q1, #5
++ vdup.8 d6, r6
++ vdup.8 d7, r12
++ vst1.8 {q0}, [r0], r3
++ bhi 2b
++ bne 1b
++ bcc 5f
++3:
++ vmull.u8 q0, d20, d6
++ vmlal.u8 q0, d22, d7
++ vmull.u8 q1, d21, d6
++ vmlal.u8 q1, d23, d7
++ vrshrn.u16 d0, q0, #5
++ vrshrn.u16 d1, q1, #5
++ vst1.8 {q0}, [r0]
++
++ pop {r4-r11, pc}
++4:
++ bcc 3b
++5:
++ vmull.u8 q0, d16, d6
++ vmlal.u8 q0, d18, d7
++ vmull.u8 q1, d17, d6
++ vmlal.u8 q1, d19, d7
++ vrshrn.u16 d0, q0, #5
++ vrshrn.u16 d1, q1, #5
++ vst1.8 {q0}, [r0]
++
++ pop {r4-r11, pc}
++
++endfunc
++
++
++@ ff_hevc_rpi_pred_angular_c_16_neon_8
++@ uint8_t *_src, [r0]
++@ const uint8_t *_top, [r1]
++@ const uint8_t *_left, [r2]
++@ ptrdiff_t stride [r3]
++@ unsigned int mode [sp, #0] 2..34
++
++function ff_hevc_rpi_pred_angular_c_16_neon_8, export=1
++ ldr r12, [sp]
++ push {r4-r11, lr}
++ ADRT r4, angle_2 - 2
++ ADRT r7, inv_angle - 11*2
++ add r7, r7, r12, lsl #1
++ lsl r3, #1
++ ldrsb r6, [r4, r12]
++ cmp r12, #26
++ ldrsb r4, [r4, r12]
++ bge 26f
++ cmp r12, #18
++ bge 18f
++ cmp r12, #10
++ bge 10f
++
++@ Down of Horizontal - works down left
++ mov r10, #4
++ mov r1, r2
++1:
++ bl patch_h_down_c_4x4_8
++ bl patch_h_down_c_4x4_8_continue
++ bl patch_h_down_c_4x4_8_continue
++ bl patch_h_down_c_4x4_8_continue
++
++ add r2, r1, #4*2 @ restore r2, but 4 rows further down left
++ add r1, r1, #4*2
++ mov r6, r4
++ sub r0, #32
++ subs r10, #1
++ add r0, r0, r3, lsl #2
++ bne 1b
++
++ pop {r4-r11, pc}
++
++@ Up of Horizontal - works down up
++10:
++ ldrh r7, [r7]
++ mov r10, #-128
++ vmov.i8 d6, #1<<2
++1:
++ push {r2, r10}
++ bl patch_h_up_c_4x4_8
++ bl patch_h_up_c_4x4_8_continue
++ bl patch_h_up_c_4x4_8_continue
++ bl patch_h_up_c_4x4_8_continue
++ pop {r2, r10}
++
++ vmov r8, s12
++ sub r0, #32
++ add r2, #8
++ add r0, r0, r3, lsl #2
++ sub r10, r10, r7, lsl #2
++ vshr.u8 d6, #1
++ teq r8, #0
++ bne 1b
++
++ pop {r4-r11, pc}
++
++@ Left of vertical - works down left
++18:
++ vld1.8 {q0-q1}, [r1]
++ sub r9, r2, #2
++ rsb r12, r6, #32
++ ldrh r7, [r7]
++ mov r8, #-128
++ vdup.8 d18, r6
++ vdup.8 d19, r12
++ mov r5, #16
++1:
++ vld1.16 {d17[3]}, [r9]
++ add r8, r7
++ vmov q2, q0
++ vmov q3, q1
++ asr r9, r8, #8
++ vext.8 q1, q0, q1, #14
++ add r9, r2, r9, lsl #1
++ vext.8 q0, q8, q0, #14
++2:
++ vmull.u8 q10, d4, d19
++ subs r12, r4
++ vmlal.u8 q10, d0, d18
++ it cc
++ addcc r12, #32
++ vmull.u8 q11, d5, d19
++ rsb r6, r12, #32
++ vmlal.u8 q11, d1, d18
++ sub r5, #1
++ vmull.u8 q12, d6, d19
++ teq r5, #0
++ vmlal.u8 q12, d2, d18
++ vmull.u8 q13, d7, d19
++ vmlal.u8 q13, d3, d18
++ vdup.8 d18, r6
++ vdup.8 d19, r12
++ vrshrn.u16 d20, q10, #5
++ vrshrn.u16 d21, q11, #5
++ vrshrn.u16 d22, q12, #5
++ vrshrn.u16 d23, q13, #5
++ vst1.8 {q10-q11}, [r0], r3
++ bhi 2b
++ bne 1b
++
++ pop {r4-r11, pc}
++
++@ Right of vertical - works along top - left unused
++26:
++ add r5, r1, #32
++ vld1.8 {q0-q1}, [r1]!
++ rsb r12, r6, #32
++ vld1.16 {d16[0]}, [r5]
++ mov r5, #16
++ vdup.8 d18, r6
++ vdup.8 d19, r12
++1:
++ vmov q2, q0
++ add r1, #2
++ vmov q3, q1
++ vext.8 q0, q0, q1, #2
++ vext.8 q1, q1, q8, #2
++2:
++ vmull.u8 q10, d0, d18
++ subs r12, r4
++ vmlal.u8 q10, d4, d19
++ it cc
++ addcc r12, #32
++ vmull.u8 q11, d1, d18
++ rsb r6, r12, #32
++ vmlal.u8 q11, d5, d19
++ sub r5, #1
++ vmull.u8 q12, d2, d18
++ teq r5, #0
++ vmlal.u8 q12, d6, d19
++ vmull.u8 q13, d3, d18
++ vmlal.u8 q13, d7, d19
++ vld1.16 {d16[0]}, [r1]
++ vdup.8 d18, r6
++ vdup.8 d19, r12
++ vrshrn.u16 d20, q10, #5
++ vrshrn.u16 d21, q11, #5
++ vrshrn.u16 d22, q12, #5
++ vrshrn.u16 d23, q13, #5
++ vst1.8 {q10-q11}, [r0], r3
++ bhi 2b
++ bne 1b
++
++ pop {r4-r11, pc}
++
++endfunc
++
++@------------------------------------------------------------------------------
++@ Data
++
++ .text
++ .balign 64
++angle_2:
++ .byte 32
++ .byte 26, 21, 17, 13, 9, 5, 2, 0
++ @ Sign inverted from standards table
++ .byte 2, 5, 9, 13, 17, 21, 26, 32
++ .byte 26, 21, 17, 13, 9, 5, 2, 0
++ @ Standard sign
++ .byte 2, 5, 9, 13, 17, 21, 26, 32
++
++ .balign 2
++
++ @ Sign inverted from standards table
++inv_angle:
++ .short 4096, 1638, 910, 630, 482, 390, 315
++ .short 256
++ .short 315, 390, 482, 630, 910, 1638, 4096
++
++@------------------------------------------------------------------------------
++@
++@ 10 bit fns
++@ Should work for 9 & 11 bit as there is no actual bit-depth specific code
++@ but runs out of register width for 12+ bit
++
++ .text
++ .balign 64
++
++patch_h_down_4x4_10:
++ ldrd r8, r9, [r2] @ Left
++ rsb r12, r6, #32
++ vmov d0, r8, r9
++ vdup.16 d3, r6
++ lsr r8, #16
++ vdup.16 d2, r12
++ orr r8, r8, r9, lsl #16
++ ldr r9, [r2, #6]!
++ vmov d1, r8, r9
++ // drop through...
++patch_h_down_4x4_10_continue:
++ mov r5, #4
++1:
++ subs r12, r4
++ vmul.u16 d4, d0, d2
++ it mi
++ addmi r12, #32
++ vmla.u16 d4, d1, d3
++ rsb r6, r12, #32
++ vext.16 q8, q8, q9, #4
++ it mi
++ lsrmi r7, r8, #16
++ vmov d18, d19
++ it mi
++ vmovmi d0, r8, r9
++ vdup.16 d2, r12
++ it mi
++ orrmi r8, r7, r9, lsl #16
++ vrshr.u16 d19, d4, #5
++ itt mi
++ ldrmi r9, [r2, #2]!
++ vmovmi d1, r8, r9
++ subs r5, #1
++ vdup.16 d3, r6
++ bne 1b
++ // drop through...
++store_tran_4x4_10:
++ vzip.16 d16, d17
++ add r6, r0, r3
++ vzip.16 d18, d19
++ lsl r3, #1
++ vzip.32 q8, q9
++ add r5, r0, r3
++ vst1.16 {d16}, [r0]!
++ vst1.16 {d17}, [r6], r3
++ vst1.16 {d18}, [r5]
++ asr r3, #1
++ vst1.16 {d19}, [r6]
++
++ bx lr
++
++patch_h_up_4x4_10:
++ ldrd r8, r9, [r2]
++ rsb r6, r4, #32
++ vmov d0, r8, r9
++ vdup.16 d3, r4
++ lsr r11, r8, #16
++ vdup.16 d2, r6
++ ldr r8, [r2, #-2]!
++ orr r9, r11, r9, lsl #16
++ vmov d1, r8, r9
++ mov r12, r4
++ vmul.u16 d4, d0, d2
++ vmla.u16 d4, d1, d3
++patch_h_up_4x4_10_continue:
++ mov r5, #4
++1:
++ add r12, r4
++ cmp r12, #33
++ it cs
++ addcs r10, r7
++ mov r11, #0
++ itt cs
++ subcs r12, #32
++ tstcs r10, #1<<31
++ rsb r6, r12, #32
++ it eq
++ asreq r11, r10, #7
++ it cs
++ vmovcs d0, r8, r9
++ it eq
++ biceq r11, #1
++ vdup.16 d2, r6
++ it cs
++ lsrcs r6, r8, #16
++ vdup.16 d3, r12
++ vext.16 q8, q8, q9, #4
++ itt cs
++ orrcs r9, r6, r9, lsl #16
++ ldrhcs r11, [r1, r11]
++ vmov d18, d19
++ it hi
++ ldrhhi r11, [r2, #-2]!
++ vrshr.u16 d19, d4, #5
++ itt cs
++ orrcs r8, r11, r8, lsl #16
++ vmovcs d1, r8, r9
++ vmul.u16 d4, d0, d2
++ subs r5, #1
++ vmla.u16 d4, d1, d3
++ bne 1b
++
++ b store_tran_4x4_10
++
++
++@ ff_hevc_rpi_pred_angular_4_neon_10
++@ uint8_t *_src, [r0]
++@ const uint8_t *_top, [r1]
++@ const uint8_t *_left, [r2]
++@ ptrdiff_t stride [r3]
++@ unsigned int mode [sp, #0] 2..34
++
++function ff_hevc_rpi_pred_angular_4_neon_10, export=1
++ ldr r12, [sp]
++ push {r4-r11, lr}
++ ADRT r4, angle_2 - 2
++ ADRT r7, inv_angle - 11*2
++ add r7, r7, r12, lsl #1
++ lsl r3, #1
++ ldrsb r6, [r4, r12]
++ cmp r12, #26
++ ldrsb r4, [r4, r12]
++ bge 26f
++ cmp r12, #18
++ bge 18f
++ cmp r12, #10
++ bge 10f
++
++@ Down of Horizontal - works down left
++ bl patch_h_down_4x4_10
++ pop {r4-r11, pc}
++
++@ Up of Horizontal - works down up
++10:
++ ldrh r7, [r7]
++ mov r10, #-128
++ bl patch_h_up_4x4_10
++ pop {r4-r11, pc}
++
++@ Left of vertical - works down left
++18:
++ ldrd r8, r9, [r1] @ Top
++ rsb r12, r6, #32
++ ldrh lr, [r2, #-2] @ Top-left
++ ldrh r7, [r7]
++ vmov d0, r8, r9
++ lsl r9, r9, #16
++ vdup.16 d2, r12
++ orr r9, r9, r8, lsr #16
++ orr r8, lr, r8, lsl #16
++ vmov d1, r8, r9
++ sub r1, r7, #128
++ mov r5, #3
++1:
++ sel lr, lr, lr @ force pipeline 0 on Cortex-A53
++ vdup.16 d3, r6
++ vmul.u16 d4, d0, d2
++ subs r12, r12, r4
++ vmla.u16 d4, d1, d3
++ itttt mi
++ addmi lr, r2, r1, asr #7
++ bicmi lr, #1
++ addmi r12, r12, #32
++ vmovmi d0, r8, r9
++ rsb r6, r12, #32
++ itt mi
++ lslmi r9, r9, #16
++ ldrhmi lr, [lr]
++ vdup.16 d2, r12
++ vrshr.u16 d4, d4, #5
++ itttt mi
++ orrmi r9, r9, r8, lsr #16
++ orrmi r8, lr, r8, lsl #16
++ vmovmi d1, r8, r9
++ addmi r1, r1, r7
++ subs r5, r5, #1
++ vst1.16 {d4}, [r0], r3
++ bne 1b
++
++ vdup.16 d3, r6
++ nop @ force next insn into pipeline 0 to enable
++ vmul.u16 d4, d0, d2 @ vmla to execute back-to-back on Cortex-A53
++ vmla.u16 d4, d1, d3
++ vrshr.u16 d4, d4, #5
++ vst1.16 {d4}, [r0]
++
++ pop {r4-r11, pc}
++
++@ Right of vertical - works along top - left unused
++26:
++ ldrd r8, r9, [r1] @ Top
++ rsb r12, r6, #32
++ vmov d0, r8, r9
++ vdup.16 d3, r6
++ lsr r8, #16
++ vdup.16 d2, r12
++ orr r8, r8, r9, lsl #16
++ ldr r9, [r1, #6]!
++ vmov d1, r8, r9
++ mov r5, #3
++1:
++ vmul.u16 d4, d0, d2
++ subs r12, r4
++ vmla.u16 d4, d1, d3
++ it mi
++ addmi r12, #32
++ rsb r6, r12, #32
++ itt mi
++ vmovmi d0, r8, r9
++ lsrmi r8, #16
++ vdup.16 d2, r12
++ itt mi
++ orrmi r8, r8, r9, lsl #16
++ ldrmi r9, [r1, #2]!
++ vrshr.u16 d4, d4, #5
++ it mi
++ vmovmi d1, r8, r9
++ vdup.16 d3, r6
++ subs r5, #1
++ vst1.16 {d4}, [r0], r3
++ bne 1b
++
++ vmul.u16 d4, d0, d2
++ vmla.u16 d4, d1, d3
++ vrshr.u16 d4, d4, #5
++ vst1.16 {d4}, [r0]
++
++ pop {r4-r11, pc}
++
++endfunc
++
++
++@ ff_hevc_rpi_pred_angular_8_neon_10
++@ uint8_t *_src, [r0]
++@ const uint8_t *_top, [r1]
++@ const uint8_t *_left, [r2]
++@ ptrdiff_t stride [r3]
++@ unsigned int mode [sp, #0] 2..34
++
++function ff_hevc_rpi_pred_angular_8_neon_10, export=1
++ ldr r12, [sp]
++ push {r4-r11, lr}
++ ADRT r4, angle_2 - 2
++ ADRT r7, inv_angle - 11*2
++ add r7, r7, r12, lsl #1
++ lsl r3, #1
++ ldrsb r6, [r4, r12]
++ cmp r12, #26
++ ldrsb r4, [r4, r12]
++ bge 26f
++ cmp r12, #18
++ bge 18f
++ cmp r12, #10
++ bge 10f
++
++@ Down of Horizontal - works down left
++ mov r1, r2 @ save r2 - r1 unused by patch_down
++
++ bl patch_h_down_4x4_10
++ bl patch_h_down_4x4_10_continue
++
++ add r2, r1, #4*2 @ restore r2, but 4 rows further down left
++ sub r0, #16
++ mov r6, r4
++ add r0, r0, r3, lsl #2
++
++ bl patch_h_down_4x4_10
++ bl patch_h_down_4x4_10_continue
++
++ pop {r4-r11, pc}
++
++@ Up of Horizontal - works down up
++10:
++ ldrh r7, [r7]
++ mov r10, #-128
++
++ push {r2}
++ bl patch_h_up_4x4_10
++ bl patch_h_up_4x4_10_continue
++ pop {r2}
++
++ sub r0, #16
++ mov r10, #-128
++ add r2, #8
++ add r0, r0, r3, lsl #2
++ sub r10, r10, r7, lsl #2
++
++ bl patch_h_up_4x4_10
++ bl patch_h_up_4x4_10_continue
++
++ pop {r4-r11, pc}
++
++@ Left of vertical - works down left
++18:
++ vld1.16 {q9}, [r1]
++ sub r1, r2, #2
++ rsb r12, r6, #32
++ ldrh r7, [r7]
++ vdup.16 q2, r6
++ vext.16 q8, q9, q9, #7
++ sub r8, r7, #128
++ vld1.16 {d16[0]}, [r1]
++ vdup.16 q3, r12
++ mov r5, #7
++1:
++ vmul.u16 q0, q9, q3
++ subs r12, r4
++ vmla.u16 q0, q8, q2
++ ittt cc
++ asrcc r1, r8, #8
++ addcc r12, #32
++ addcc r1, r2, r1, lsl #1
++ vext.16 q10, q8, q8, #7
++ rsb r6, r12, #32
++ vmov q11, q8
++ sub r5, #1
++ vrshr.u16 q0, q0, #5
++ it cc
++ addcc r8, r7
++ vld1.16 {d20[0]}, [r1]
++ teq r5, #0
++ vdup.16 q2, r6
++ vdup.16 q3, r12
++ vst1.16 {q0}, [r0], r3
++ bhi 1b
++ beq 4f
++2:
++ vmul.u16 q0, q11, q3
++ subs r12, r4
++ vmla.u16 q0, q10, q2
++ ittt cc
++ asrcc r1, r8, #8
++ addcc r12, #32
++ addcc r1, r2, r1, lsl #1
++ vext.16 q8, q10, q10, #7
++ rsb r6, r12, #32
++ vmov q9, q10
++ sub r5, #1
++ vrshr.u16 q0, q0, #5
++ it cc
++ addcc r8, r7
++ vld1.16 {d16[0]}, [r1]
++ teq r5, #0
++ vdup.16 q2, r6
++ vdup.16 q3, r12
++ vst1.16 {q0}, [r0], r3
++ bhi 2b
++ bne 1b
++ bcc 5f
++3:
++ vmul.u16 q0, q11, q3
++ vmla.u16 q0, q10, q2
++ vrshr.u16 q0, q0, #5
++ vst1.16 {q0}, [r0]
++
++ pop {r4-r11, pc}
++4:
++ bcc 3b
++5:
++ vmul.u16 q0, q9, q3
++ vmla.u16 q0, q8, q2
++ vrshr.u16 q0, q0, #5
++ vst1.16 {q0}, [r0]
++
++ pop {r4-r11, pc}
++
++@ Right of vertical - works along top - left unused
++26:
++ vld1.16 {q9}, [r1]!
++ rsb r12, r6, #32
++ vdup.16 q2, r6
++ vdup.16 q3, r12
++ vext.16 q8, q9, q9, #1
++ vld1.16 {d17[3]}, [r1]!
++ mov r5, #7
++1:
++ vmul.u16 q0, q8, q2
++ subs r12, r4
++ vmla.u16 q0, q9, q3
++ it cc
++ addcc r12, #32
++ vext.16 q10, q8, q8, #1
++ rsb r6, r12, #32
++ vld1.16 {d21[3]}, [r1]
++ sub r5, #1
++ vmov q11, q8
++ teq r5, #0
++ vrshr.u16 q0, q0, #5
++ it cc
++ addcc r1, #2
++ vdup.16 q2, r6
++ vdup.16 q3, r12
++ vst1.16 {q0}, [r0], r3
++ bhi 1b
++ beq 4f
++2:
++ vmul.u16 q0, q10, q2
++ subs r12, r4
++ vmla.u16 q0, q11, q3
++ it cc
++ addcc r12, #32
++ vext.16 q8, q10, q10, #1
++ rsb r6, r12, #32
++ vld1.16 {d17[3]}, [r1]
++ sub r5, #1
++ vmov q9, q10
++ teq r5, #0
++ vrshr.u16 q0, q0, #5
++ it cc
++ addcc r1, #2
++ vdup.16 q2, r6
++ vdup.16 q3, r12
++ vst1.16 {q0}, [r0], r3
++ bhi 2b
++ bne 1b
++ bcc 5f
++3:
++ vmul.u16 q0, q10, q2
++ vmla.u16 q0, q11, q3
++ vrshr.u16 q0, q0, #5
++ vst1.16 {q0}, [r0]
++
++ pop {r4-r11, pc}
++4:
++ bcc 3b
++5:
++ vmul.u16 q0, q8, q2
++ vmla.u16 q0, q9, q3
++ vrshr.u16 q0, q0, #5
++ vst1.16 {q0}, [r0]
++
++ pop {r4-r11, pc}
++
++endfunc
++
++
++@ ff_hevc_rpi_pred_angular_16_neon_10
++@ uint8_t *_src, [r0]
++@ const uint8_t *_top, [r1]
++@ const uint8_t *_left, [r2]
++@ ptrdiff_t stride [r3]
++@ unsigned int mode [sp, #0] 2..34
++
++function ff_hevc_rpi_pred_angular_16_neon_10, export=1
++ ldr r12, [sp]
++ push {r4-r11, lr}
++ ADRT r4, angle_2 - 2
++ ADRT r7, inv_angle - 11*2
++ add r7, r7, r12, lsl #1
++ lsl r3, #1
++ ldrsb r6, [r4, r12]
++ cmp r12, #26
++ ldrsb r4, [r4, r12]
++ bge 26f
++ cmp r12, #18
++ bge 18f
++ cmp r12, #10
++ bge 10f
++
++@ Down of Horizontal - works down left
++ mov r10, #4
++ mov r1, r2
++1:
++ bl patch_h_down_4x4_10
++ bl patch_h_down_4x4_10_continue
++ bl patch_h_down_4x4_10_continue
++ bl patch_h_down_4x4_10_continue
++
++ add r2, r1, #4*2 @ restore r2, but 4 rows further down left
++ add r1, r1, #4*2
++ mov r6, r4
++ sub r0, #32
++ subs r10, #1
++ add r0, r0, r3, lsl #2
++ bne 1b
++
++ pop {r4-r11, pc}
++
++@ Up of Horizontal - works down up
++10:
++ ldrh r7, [r7]
++ mov r10, #-128
++ vmov.i8 d6, #1<<2
++1:
++ push {r2, r10}
++ bl patch_h_up_4x4_10
++ bl patch_h_up_4x4_10_continue
++ bl patch_h_up_4x4_10_continue
++ bl patch_h_up_4x4_10_continue
++ pop {r2, r10}
++
++ vmov r8, s12
++ sub r0, #32
++ add r2, #8
++ add r0, r0, r3, lsl #2
++ sub r10, r10, r7, lsl #2
++ vshr.u8 d6, #1
++ teq r8, #0
++ bne 1b
++
++ pop {r4-r11, pc}
++
++@ Left of vertical - works down left
++18:
++ vld1.16 {q0-q1}, [r1]
++ sub r9, r2, #2
++ rsb r12, r6, #32
++ ldrh r7, [r7]
++ mov r8, #-128
++ vdup.16 q9, r6
++ vdup.16 q10, r12
++ mov r5, #16
++1:
++ vld1.16 {d17[3]}, [r9]
++ add r8, r7
++ vmov q2, q0
++ vmov q3, q1
++ asr r9, r8, #8
++ vext.16 q1, q0, q1, #7
++ add r9, r2, r9, lsl #1
++ vext.16 q0, q8, q0, #7
++2:
++ vmul.u16 q11, q2, q10
++ subs r12, r4
++ vmla.u16 q11, q0, q9
++ it cc
++ addcc r12, #32
++ vmul.u16 q12, q3, q10
++ rsb r6, r12, #32
++ vmla.u16 q12, q1, q9
++ sub r5, #1
++ teq r5, #0
++ vdup.16 q9, r6
++ vdup.16 q10, r12
++ vrshr.u16 q11, q11, #5
++ vrshr.u16 q12, q12, #5
++ vst1.16 {q11-q12}, [r0], r3
++ bhi 2b
++ bne 1b
++
++ pop {r4-r11, pc}
++
++@ Right of vertical - works along top - left unused
++26:
++ add r5, r1, #32
++ vld1.16 {q0-q1}, [r1]!
++ rsb r12, r6, #32
++ vld1.16 {d16[0]}, [r5]
++ mov r5, #16
++ vdup.16 q9, r6
++ vdup.16 q10, r12
++1:
++ vmov q2, q0
++ add r1, #2
++ vmov q3, q1
++ vext.16 q0, q0, q1, #1
++ vext.16 q1, q1, q8, #1
++2:
++ vmul.u16 q11, q0, q9
++ subs r12, r4
++ vmla.u16 q11, q2, q10
++ it cc
++ addcc r12, #32
++ vmul.u16 q12, q1, q9
++ rsb r6, r12, #32
++ vmla.u16 q12, q3, q10
++ sub r5, #1
++ vld1.16 {d16[0]}, [r1]
++ teq r5, #0
++ vdup.16 q9, r6
++ vdup.16 q10, r12
++ vrshr.u16 q11, q11, #5
++ vrshr.u16 q12, q12, #5
++ vst1.16 {q11-q12}, [r0], r3
++ bhi 2b
++ bne 1b
++
++ pop {r4-r11, pc}
++
++endfunc
++
++
++@ ff_hevc_rpi_pred_angular_32_neon_10
++@ uint8_t *_src, [r0]
++@ const uint8_t *_top, [r1]
++@ const uint8_t *_left, [r2]
++@ ptrdiff_t stride [r3]
++@ unsigned int mode [sp, #0] 2..34
++
++function ff_hevc_rpi_pred_angular_32_neon_10, export=1
++ ldr r12, [sp]
++ push {r4-r11, lr}
++ ADRT r4, angle_2 - 2
++ ADRT r7, inv_angle - 11*2
++ add r7, r7, r12, lsl #1
++ lsl r3, #1
++ vpush {d8}
++ ldrsb r6, [r4, r12]
++ cmp r12, #26
++ ldrsb r4, [r4, r12]
++ bge 26f
++ cmp r12, #18
++ bge 18f
++ cmp r12, #10
++ bge 10f
++
++@ Down of Horizontal - works down left
++ add sp, #8
++ mov r10, #8
++ mov r1, r2
++1:
++ bl patch_h_down_4x4_10
++ bl patch_h_down_4x4_10_continue
++ bl patch_h_down_4x4_10_continue
++ bl patch_h_down_4x4_10_continue
++ bl patch_h_down_4x4_10_continue
++ bl patch_h_down_4x4_10_continue
++ bl patch_h_down_4x4_10_continue
++ bl patch_h_down_4x4_10_continue
++
++ add r2, r1, #4*2 @ restore r2, but 4 rows further down left
++ add r1, r1, #4*2
++ mov r6, r4
++ sub r0, #64
++ subs r10, #1
++ add r0, r0, r3, lsl #2
++ bne 1b
++
++ pop {r4-r11, pc}
++
++@ Up of Horizontal - works down up
++10:
++ add sp, #8
++ ldrh r7, [r7]
++ mov r10, #-128
++ vmov.i8 d6, #1<<6
++1:
++ push {r2, r10}
++ bl patch_h_up_4x4_10
++ bl patch_h_up_4x4_10_continue
++ bl patch_h_up_4x4_10_continue
++ bl patch_h_up_4x4_10_continue
++ bl patch_h_up_4x4_10_continue
++ bl patch_h_up_4x4_10_continue
++ bl patch_h_up_4x4_10_continue
++ bl patch_h_up_4x4_10_continue
++ pop {r2, r10}
++
++ vmov r8, s12
++ sub r0, #64
++ add r2, #8
++ add r0, r0, r3, lsl #2
++ sub r10, r10, r7, lsl #2
++ vshr.u8 d6, #1
++ teq r8, #0
++ bne 1b
++
++ pop {r4-r11, pc}
++
++@ Left of vertical - works down left
++18:
++ add r5, r1, #32
++ vld1.16 {q1-q2}, [r1]
++ rsb r12, r6, r6, lsl #16
++ vld1.16 {q3-q4}, [r5]
++ sub r9, r2, #2
++ rsb r4, r12, #0
++ rsb r12, r12, #32 << 16
++ ldrh r7, [r7]
++ mov r8, #-128
++ vmov d0, d9
++ vmov s2, r12
++ add r10, r0, #32
++ mov r5, #32
++1:
++ vld1.16 {d1[3]}, [r9]
++ add r8, r7
++ vmov q11, q4
++ vmov q10, q3
++ asr r9, r8, #8
++ vmov q9, q2
++ add r9, r2, r9, lsl #1
++ vmov q8, q1
++ vext.16 q4, q3, q4, #7
++ vext.16 q3, q2, q3, #7
++ vext.16 q2, q1, q2, #7
++ vext.16 q1, q0, q1, #7
++2:
++ vmul.u16 q12, q8, d1[1]
++ adds r12, r4
++ vmla.u16 q12, q1, d1[0]
++ it cc
++ addcc r12, #32 << 16
++ vmul.u16 q13, q9, d1[1]
++ it cc
++ subcc r12, #32
++ vmla.u16 q13, q2, d1[0]
++ sub r5, #1
++ vmul.u16 q14, q10, d1[1]
++ teq r5, #0
++ vmla.u16 q14, q3, d1[0]
++ vmul.u16 q15, q11, d1[1]
++ vmla.u16 q15, q4, d1[0]
++ vmov s2, r12
++ vrshr.u16 q12, q12, #5
++ vrshr.u16 q13, q13, #5
++ vrshr.u16 q14, q14, #5
++ vrshr.u16 q15, q15, #5
++ vst1.16 {q12-q13}, [r0], r3
++ vst1.16 {q14-q15}, [r10], r3
++ bhi 2b
++ bne 1b
++
++ vpop {d8}
++ vmov d9, d0
++ pop {r4-r11, pc}
++
++@ Right of vertical - works along top - left unused
++26:
++ add r5, r1, #32
++ vld1.16 {q1-q2}, [r1]
++ rsb r12, r6, r6, lsl #16
++ vld1.16 {q3-q4}, [r5]
++ add r1, r1, #64
++ rsb r4, r12, #0
++ rsb r12, r12, #32 << 16
++ vmov d1, d9
++ vmov s1, r12
++ add r10, r0, #32
++ mov r5, #32
++1:
++ vld1.16 {d0[0]}, [r1]!
++ vmov q8, q1
++ vmov q9, q2
++ vmov q10, q3
++ vmov q11, q4
++ vext.16 q1, q1, q2, #1
++ vext.16 q2, q2, q3, #1
++ vext.16 q3, q3, q4, #1
++ vext.16 q4, q4, q0, #1
++2:
++ vmul.u16 q12, q1, d0[2]
++ adds r12, r4
++ vmla.u16 q12, q8, d0[3]
++ it cc
++ addcc r12, #32 << 16
++ vmul.u16 q13, q2, d0[2]
++ it cc
++ subcc r12, #32
++ vmla.u16 q13, q9, d0[3]
++ sub r5, #1
++ vmul.u16 q14, q3, d0[2]
++ teq r5, #0
++ vmla.u16 q14, q10, d0[3]
++ vmul.u16 q15, q4, d0[2]
++ vmla.u16 q15, q11, d0[3]
++ vmov s1, r12
++ vrshr.u16 q12, q12, #5
++ vrshr.u16 q13, q13, #5
++ vrshr.u16 q14, q14, #5
++ vrshr.u16 q15, q15, #5
++ vst1.16 {q12-q13}, [r0], r3
++ vst1.16 {q14-q15}, [r10], r3
++ bhi 2b
++ bne 1b
++
++ vpop {d8}
++ vmov d9, d1
++ pop {r4-r11, pc}
++
++endfunc
++
++
++
++@ Generate 4x4 chroma patch
++@
++@ In (const)
++@ r1 Up ptr (_up only)
++@ r3 Out stride
++@ r4 Angle add
++@ r7 Inv angle (_up only)
++@
++@ In/Out (updated)
++@ r0 Out pointer - on exit point to start of next patch horizontally (i.e. r0 + patch width)
++@ r2 Left ptr - updated
++@ r6 Angle frac (init to r4 + 32)
++@ r8 Inv angle accumulator
++@ q2 Cur Line - load before 1st call for down - set by _up
++@ q8 Cur Line - load before 1st call for up - set by _down
++@
++@ Temps
++@ r5 Loop counter
++@ r12
++@ d0, q1, q12-q15
++
++patch_h_down_c_4x4_10:
++ vld1.16 {q12}, [r2]!
++ rsb r12, r6, #32
++ vdup.16 q2, r6
++ vdup.16 q3, r12
++ mov r5, #4
++1:
++ vmov q13, q12
++ vext.16 q12, q12, q12, #2
++ vld1.32 {d25[1]}, [r2]!
++patch_h_down_c_4x4_10_continue:
++2:
++ vmov q8, q9
++ subs r12, r4
++ vmul.u16 q0, q13, q3
++ it cc
++ addcc r12, #32
++ vmla.u16 q0, q12, q2
++ rsb r6, r12, #32
++ vmov q9, q10
++ sub r5, #1
++ vmov q10, q11
++ teq r5, #0
++ vdup.16 q2, r6
++ vdup.16 q3, r12
++ vrshr.u16 q11, q0, #5
++ bhi 2b
++ bne 1b
++
++ bcs 3f
++ vmov q13, q12
++ vext.16 q12, q12, q12, #2
++ vld1.32 {d25[1]}, [r2]!
++3:
++
++store_tran_c_4x4_10:
++T add r6, r0, r3
++ vzip.32 q8, q10
++A add r6, r0, r3
++T lsl r3, #1
++ vzip.32 q9, q11
++A add r5, r0, r3, lsl #1
++T add r5, r0, r3
++ vst2.32 {d16,d18}, [r0]!
++A lsl r3, #1
++ vst2.32 {d17,d19}, [r6], r3
++ asr r3, #1
++ vst2.32 {d20,d22}, [r5]
++ mov r5, #4
++ vst2.32 {d21,d23}, [r6]
++ bx lr
++
++patch_h_up_c_4x4_10:
++ vld1.16 {q1}, [r2]
++ rsb r12, r6, #32
++ vdup.16 q2, r6
++ vdup.16 q3, r12
++ mov r5, #4
++1:
++ adds r8, r7
++ vmov q12, q1
++ it mi
++ ldrmi r6, [r2, #-4]!
++ vext.16 q1, q1, q1, #6
++ itt pl
++ asrpl r6, r8, #8
++ ldrpl r6, [r1, r6, lsl #2]
++ vmov s4, r6
++patch_h_up_c_4x4_10_continue:
++2:
++ vmov q8, q9
++ subs r12, r4
++ vmul.u16 q0, q12, q3
++ it cc
++ addcc r12, #32
++ vmla.u16 q0, q1, q2
++ rsb r6, r12, #32
++ vmov q9, q10
++ sub r5, #1
++ vmov q10, q11
++ teq r5, #0
++ vdup.16 q2, r6
++ vdup.16 q3, r12
++ vrshr.u16 q11, q0, #5
++ bhi 2b
++ bne 1b
++
++ bcs store_tran_c_4x4_10
++ adds r8, r7
++ vmov q12, q1
++ it mi
++ ldrmi r6, [r2, #-4]!
++ vext.16 q1, q1, q1, #6
++ itt pl
++ asrpl r6, r8, #8
++ ldrpl r6, [r1, r6, lsl #2]
++ vmov s4, r6
++ b store_tran_c_4x4_10
++
++
++@ ff_hevc_rpi_pred_angular_c_4_neon_10
++@ uint8_t *_src, [r0]
++@ const uint8_t *_top, [r1]
++@ const uint8_t *_left, [r2]
++@ ptrdiff_t stride [r3]
++@ unsigned int mode [sp, #0] 2..34
++
++function ff_hevc_rpi_pred_angular_c_4_neon_10, export=1
++ ldr r12, [sp]
++ push {r4-r8, lr}
++ ADRT r4, angle_2 - 2
++ ADRT r7, inv_angle - 11*2
++ add r7, r7, r12, lsl #1
++ lsl r3, #2
++ ldrsb r6, [r4, r12]
++ cmp r12, #26
++ ldrsb r4, [r4, r12]
++ bge 26f
++ cmp r12, #18
++ bge 18f
++ cmp r12, #10
++ bge 10f
++
++@ Down of Horizontal - works down left
++ bl patch_h_down_c_4x4_10
++ pop {r4-r8, pc}
++
++@ Up of Horizontal - works down up
++10:
++ ldrh r7, [r7]
++ mov r8, #-128
++ sub r8, r7
++ bl patch_h_up_c_4x4_10
++ pop {r4-r8, pc}
++
++@ Left of vertical - works down left
++18:
++ vld1.16 {q9}, [r1]
++ sub r1, r2, #4
++ rsb r12, r6, #32
++ ldrh r7, [r7]
++ vdup.16 q2, r6
++ vext.16 q8, q9, q9, #6
++ sub r8, r7, #128
++ vld1.32 {d16[0]}, [r1]
++ vdup.16 q3, r12
++ mov r5, #3
++1:
++ vmul.u16 q0, q9, q3
++ subs r12, r4
++ vmla.u16 q0, q8, q2
++ ittt cc
++ asrcc r1, r8, #8
++ addcc r12, #32
++ addcc r1, r2, r1, lsl #2
++ vext.16 q10, q8, q8, #6
++ rsb r6, r12, #32
++ vmov q11, q8
++ sub r5, #1
++ vrshr.u16 q0, q0, #5
++ it cc
++ addcc r8, r7
++ vld1.32 {d20[0]}, [r1]
++ teq r5, #0
++ vdup.16 q2, r6
++ vdup.16 q3, r12
++ vst1.16 {q0}, [r0], r3
++ bhi 1b
++ beq 4f
++2:
++ vmul.u16 q0, q11, q3
++ subs r12, r4
++ vmla.u16 q0, q10, q2
++ ittt cc
++ asrcc r1, r8, #8
++ addcc r12, #32
++ addcc r1, r2, r1, lsl #2
++ vext.16 q8, q10, q10, #6
++ rsb r6, r12, #32
++ vmov q9, q10
++ sub r5, #1
++ vrshr.u16 q0, q0, #5
++ it cc
++ addcc r8, r7
++ vld1.32 {d16[0]}, [r1]
++ teq r5, #0
++ vdup.16 q2, r6
++ vdup.16 q3, r12
++ vst1.16 {q0}, [r0], r3
++ bhi 2b
++ bne 1b
++ bcc 5f
++3:
++ vmul.u16 q0, q11, q3
++ vmla.u16 q0, q10, q2
++ vrshr.u16 q0, q0, #5
++ vst1.16 {q0}, [r0]
++
++ pop {r4-r8, pc}
++4:
++ bcc 3b
++5:
++ vmul.u16 q0, q9, q3
++ vmla.u16 q0, q8, q2
++ vrshr.u16 q0, q0, #5
++ vst1.16 {q0}, [r0]
++
++ pop {r4-r8, pc}
++
++@ Right of vertical - works along top - left unused
++26:
++ vld1.16 {q9}, [r1]!
++ rsb r12, r6, #32
++ vdup.16 q2, r6
++ vdup.16 q3, r12
++ vext.16 q8, q9, q9, #2
++ vld1.32 {d17[1]}, [r1]!
++ mov r5, #3
++1:
++ vmul.u16 q0, q8, q2
++ subs r12, r4
++ vmla.u16 q0, q9, q3
++ it cc
++ addcc r12, #32
++ vext.16 q10, q8, q8, #2
++ rsb r6, r12, #32
++ vld1.32 {d21[1]}, [r1]
++ sub r5, #1
++ vmov q11, q8
++ teq r5, #0
++ vrshr.u16 q0, q0, #5
++ it cc
++ addcc r1, #4
++ vdup.16 q2, r6
++ vdup.16 q3, r12
++ vst1.16 {q0}, [r0], r3
++ bhi 1b
++ beq 4f
++2:
++ vmul.u16 q0, q10, q2
++ subs r12, r4
++ vmla.u16 q0, q11, q3
++ it cc
++ addcc r12, #32
++ vext.16 q8, q10, q10, #2
++ rsb r6, r12, #32
++ vld1.32 {d17[1]}, [r1]
++ sub r5, #1
++ vmov q9, q10
++ teq r5, #0
++ vrshr.u16 q0, q0, #5
++ it cc
++ addcc r1, #4
++ vdup.16 q2, r6
++ vdup.16 q3, r12
++ vst1.16 {q0}, [r0], r3
++ bhi 2b
++ bne 1b
++ bcc 5f
++3:
++ vmul.u16 q0, q10, q2
++ vmla.u16 q0, q11, q3
++ vrshr.u16 q0, q0, #5
++ vst1.16 {q0}, [r0]
++
++ pop {r4-r8, pc}
++4:
++ bcc 3b
++5:
++ vmul.u16 q0, q8, q2
++ vmla.u16 q0, q9, q3
++ vrshr.u16 q0, q0, #5
++ vst1.16 {q0}, [r0]
++
++ pop {r4-r8, pc}
++
++endfunc
++
++
++@ ff_hevc_rpi_pred_angular_c_8_neon_10
++@ uint8_t *_src, [r0]
++@ const uint8_t *_top, [r1]
++@ const uint8_t *_left, [r2]
++@ ptrdiff_t stride [r3]
++@ unsigned int mode [sp, #0] 2..34
++
++function ff_hevc_rpi_pred_angular_c_8_neon_10, export=1
++ ldr r12, [sp]
++ push {r4-r8, lr}
++ ADRT r4, angle_2 - 2
++ ADRT r7, inv_angle - 11*2
++ add r7, r7, r12, lsl #1
++ lsl r3, #2
++ ldrsb r6, [r4, r12]
++ cmp r12, #26
++ ldrsb r4, [r4, r12]
++ bge 26f
++ cmp r12, #18
++ bge 18f
++ cmp r12, #10
++ bge 10f
++
++@ Down of Horizontal - works down left
++ mov r1, r2 @ save r2 - r1 unused by patch_down
++
++ bl patch_h_down_c_4x4_10
++ bl patch_h_down_c_4x4_10_continue
++
++ add r2, r1, #4*4 @ restore r2, but 4 rows further down left
++ sub r0, #32
++ mov r6, r4
++ add r0, r0, r3, lsl #2
++
++ bl patch_h_down_c_4x4_10
++ bl patch_h_down_c_4x4_10_continue
++
++ pop {r4-r8, pc}
++
++@ Up of Horizontal - works down up
++10:
++ ldrh r7, [r7]
++ mov r8, #-128
++ sub r8, r7
++
++ push {r2, r8}
++ bl patch_h_up_c_4x4_10
++ bl patch_h_up_c_4x4_10_continue
++ pop {r2, r8}
++
++ sub r0, #32
++ mov r6, r4
++ add r2, #16
++ sub r8, r8, r7, lsl #2
++ add r0, r0, r3, lsl #2
++
++ bl patch_h_up_c_4x4_10
++ bl patch_h_up_c_4x4_10_continue
++
++ pop {r4-r8, pc}
++
++@ Left of vertical - works down left
++18:
++ vld1.16 {q0-q1}, [r1]
++ sub r9, r2, #4
++ rsb r12, r6, #32
++ ldrh r7, [r7]
++ mov r8, #-128
++ vdup.16 q9, r6
++ vdup.16 q10, r12
++ mov r5, #8
++1:
++ vld1.32 {d17[1]}, [r9]
++ add r8, r7
++ vmov q2, q0
++ vmov q3, q1
++ asr r9, r8, #8
++ vext.16 q1, q0, q1, #6
++ add r9, r2, r9, lsl #2
++ vext.16 q0, q8, q0, #6
++2:
++ vmul.u16 q11, q2, q10
++ subs r12, r4
++ vmla.u16 q11, q0, q9
++ it cc
++ addcc r12, #32
++ vmul.u16 q12, q3, q10
++ rsb r6, r12, #32
++ vmla.u16 q12, q1, q9
++ sub r5, #1
++ teq r5, #0
++ vdup.16 q9, r6
++ vdup.16 q10, r12
++ vrshr.u16 q11, q11, #5
++ vrshr.u16 q12, q12, #5
++ vst1.16 {q11-q12}, [r0], r3
++ bhi 2b
++ bne 1b
++
++ pop {r4-r8, pc}
++
++@ Right of vertical - works along top - left unused
++26:
++ add r5, r1, #32
++ vld1.16 {q0-q1}, [r1]!
++ rsb r12, r6, #32
++ vld1.32 {d16[0]}, [r5]
++ mov r5, #8
++ vdup.16 q9, r6
++ vdup.16 q10, r12
++1:
++ vmov q2, q0
++ add r1, #4
++ vmov q3, q1
++ vext.16 q0, q0, q1, #2
++ vext.16 q1, q1, q8, #2
++2:
++ vmul.u16 q11, q0, q9
++ subs r12, r4
++ vmla.u16 q11, q2, q10
++ it cc
++ addcc r12, #32
++ vmul.u16 q12, q1, q9
++ rsb r6, r12, #32
++ vmla.u16 q12, q3, q10
++ sub r5, #1
++ vld1.32 {d16[0]}, [r1]
++ teq r5, #0
++ vdup.16 q9, r6
++ vdup.16 q10, r12
++ vrshr.u16 q11, q11, #5
++ vrshr.u16 q12, q12, #5
++ vst1.16 {q11-q12}, [r0], r3
++ bhi 2b
++ bne 1b
++
++ pop {r4-r8, pc}
++
++endfunc
++
++
++@ ff_hevc_rpi_pred_angular_c_16_neon_10
++@ uint8_t *_src, [r0]
++@ const uint8_t *_top, [r1]
++@ const uint8_t *_left, [r2]
++@ ptrdiff_t stride [r3]
++@ unsigned int mode [sp, #0] 2..34
++
++function ff_hevc_rpi_pred_angular_c_16_neon_10, export=1
++ ldr r12, [sp]
++ push {r4-r10, lr}
++ ADRT r4, angle_2 - 2
++ ADRT r7, inv_angle - 11*2
++ add r7, r7, r12, lsl #1
++ lsl r3, #2
++ vpush {d8}
++ ldrsb r6, [r4, r12]
++ cmp r12, #26
++ ldrsb r4, [r4, r12]
++ bge 26f
++ cmp r12, #18
++ bge 18f
++ cmp r12, #10
++ bge 10f
++
++@ Down of Horizontal - works down left
++ add sp, #8
++ mov r10, #4
++ mov r1, r2
++1:
++ bl patch_h_down_c_4x4_10
++ bl patch_h_down_c_4x4_10_continue
++ bl patch_h_down_c_4x4_10_continue
++ bl patch_h_down_c_4x4_10_continue
++
++ add r2, r1, #4*4 @ restore r2, but 4 rows further down left
++ add r1, r1, #4*4
++ mov r6, r4
++ sub r0, #64
++ subs r10, #1
++ add r0, r0, r3, lsl #2
++ bne 1b
++
++ pop {r4-r10, pc}
++
++@ Up of Horizontal - works down up
++10:
++ add sp, #8
++ mov r10, #4
++ ldrh r7, [r7]
++ mov r8, #-128
++ sub r8, r7
++2:
++ push {r2, r8}
++ bl patch_h_up_c_4x4_10
++ bl patch_h_up_c_4x4_10_continue
++ bl patch_h_up_c_4x4_10_continue
++ bl patch_h_up_c_4x4_10_continue
++ pop {r2, r8}
++
++ sub r0, #64
++ mov r6, r4
++ add r2, #16
++ sub r8, r8, r7, lsl #2
++ add r0, r0, r3, lsl #2
++ subs r10, #1
++ bne 2b
++
++ pop {r4-r10, pc}
++
++@ Left of vertical - works down left
++18:
++ add r5, r1, #32
++ vld1.16 {q1-q2}, [r1]
++ rsb r12, r6, r6, lsl #16
++ vld1.16 {q3-q4}, [r5]
++ sub r9, r2, #4
++ rsb r4, r12, #0
++ rsb r12, r12, #32 << 16
++ ldrh r7, [r7]
++ mov r8, #-128
++ vmov d0, d9
++ vmov s2, r12
++ add r10, r0, #32
++ mov r5, #16
++1:
++ vld1.32 {d1[1]}, [r9]
++ add r8, r7
++ vmov q11, q4
++ vmov q10, q3
++ asr r9, r8, #8
++ vmov q9, q2
++ add r9, r2, r9, lsl #2
++ vmov q8, q1
++ vext.16 q4, q3, q4, #6
++ vext.16 q3, q2, q3, #6
++ vext.16 q2, q1, q2, #6
++ vext.16 q1, q0, q1, #6
++2:
++ vmul.u16 q12, q8, d1[1]
++ adds r12, r4
++ vmla.u16 q12, q1, d1[0]
++ it cc
++ addcc r12, #32 << 16
++ vmul.u16 q13, q9, d1[1]
++ it cc
++ subcc r12, #32
++ vmla.u16 q13, q2, d1[0]
++ sub r5, #1
++ vmul.u16 q14, q10, d1[1]
++ teq r5, #0
++ vmla.u16 q14, q3, d1[0]
++ vmul.u16 q15, q11, d1[1]
++ vmla.u16 q15, q4, d1[0]
++ vmov s2, r12
++ vrshr.u16 q12, q12, #5
++ vrshr.u16 q13, q13, #5
++ vrshr.u16 q14, q14, #5
++ vrshr.u16 q15, q15, #5
++ vst1.16 {q12-q13}, [r0], r3
++ vst1.16 {q14-q15}, [r10], r3
++ bhi 2b
++ bne 1b
++
++ vpop {d8}
++ vmov d9, d0
++ pop {r4-r10, pc}
++
++@ Right of vertical - works along top - left unused
++26:
++ add r5, r1, #32
++ vld1.16 {q1-q2}, [r1]
++ rsb r12, r6, r6, lsl #16
++ vld1.16 {q3-q4}, [r5]
++ add r1, r1, #64
++ rsb r4, r12, #0
++ rsb r12, r12, #32 << 16
++ vmov d1, d9
++ vmov s1, r12
++ add r10, r0, #32
++ mov r5, #16
++1:
++ vld1.32 {d0[0]}, [r1]!
++ vmov q8, q1
++ vmov q9, q2
++ vmov q10, q3
++ vmov q11, q4
++ vext.16 q1, q1, q2, #2
++ vext.16 q2, q2, q3, #2
++ vext.16 q3, q3, q4, #2
++ vext.16 q4, q4, q0, #2
++2:
++ vmul.u16 q12, q1, d0[2]
++ adds r12, r4
++ vmla.u16 q12, q8, d0[3]
++ it cc
++ addcc r12, #32 << 16
++ vmul.u16 q13, q2, d0[2]
++ it cc
++ subcc r12, #32
++ vmla.u16 q13, q9, d0[3]
++ sub r5, #1
++ vmul.u16 q14, q3, d0[2]
++ teq r5, #0
++ vmla.u16 q14, q10, d0[3]
++ vmul.u16 q15, q4, d0[2]
++ vmla.u16 q15, q11, d0[3]
++ vmov s1, r12
++ vrshr.u16 q12, q12, #5
++ vrshr.u16 q13, q13, #5
++ vrshr.u16 q14, q14, #5
++ vrshr.u16 q15, q15, #5
++ vst1.16 {q12-q13}, [r0], r3
++ vst1.16 {q14-q15}, [r10], r3
++ bhi 2b
++ bne 1b
++
++ vpop {d8}
++ vmov d9, d1
++ pop {r4-r10, pc}
++
++endfunc
+diff --git a/libavcodec/arm/rpi_hevcpred_intra_dc_neon.S b/libavcodec/arm/rpi_hevcpred_intra_dc_neon.S
+new file mode 100644
+index 0000000000..75a1789c25
+--- /dev/null
++++ b/libavcodec/arm/rpi_hevcpred_intra_dc_neon.S
+@@ -0,0 +1,695 @@
++/*
++ * Copyright (c) 2017 John Cox <jc@kynesim.co.uk> (for Raspberry Pi)
++ *
++ * This file is part of FFmpeg.
++ *
++ * FFmpeg is free software; you can redistribute it and/or
++ * modify it under the terms of the GNU Lesser General Public
++ * License as published by the Free Software Foundation; either
++ * version 2.1 of the License, or (at your option) any later version.
++ *
++ * FFmpeg is distributed in the hope that it will be useful,
++ * but WITHOUT ANY WARRANTY; without even the implied warranty of
++ * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
++ * Lesser General Public License for more details.
++ *
++ * You should have received a copy of the GNU Lesser General Public
++ * License along with FFmpeg; if not, write to the Free Software
++ * Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA
++ */
++
++#include "libavutil/arm/asm.S"
++#include "neon.S"
++
++
++@ ff_hevc_rpi_pred_dc_4_neon_8
++@ uint8_t *_src, [r0]
++@ const uint8_t *_top, [r1]
++@ const uint8_t *_left, [r2]
++@ ptrdiff_t stride) [r3]
++
++function ff_hevc_rpi_pred_dc_4_neon_8, export=1
++
++ @ Average the els of top & left
++ ldr r2, [r2]
++ vld1.32 {d0[0]}, [r1]
++ mov r1, #2
++ vmov s1, r2
++ vmov s2, r2
++ vmov.i16 q2, #3
++ add r2, r0, r3
++ vaddl.u8 q1, d0, d1 @ d2[0] = top[0] + left[0]
++ lsl r3, #1
++ vmovl.u8 q0, d0
++ vmov.i64 d7, #0xffff
++ vmov.16 d4[0], r1 @ 2, 3, 3, 3...
++ vpadd.i16 d6, d2, d2 @ 2 (top & bottom of vector the same)
++ vbit d0, d2, d7 @ q0 = top[0]+left[0], top[1..3], left[0..3]
++
++ @ top line gets some smoothing
++ @ (top[i] + 3*dc + 2) >> 2
++ @ as does left
++ @ top_line[0] is extra special
++ @ (top[0] + left[0] + 2*dc + 2) >> 2
++
++ vmov.i64 d7, #0xff
++ vpadd.i16 d6, d6 @ 1 (all the same)
++ vrshr.u16 d6, #3
++ vmla.i16 q0, q2, d6[0]
++ vdup.8 d6, d6[0]
++ vrshrn.i16 d0, q0, #2
++
++ @ Store top line
++ vst1.32 {d0[0]}, [r0], r3
++
++ @ Store the rest
++ vshr.u64 d1, d0, #5*8
++ vshr.u64 d2, d0, #6*8
++ vshr.u64 d3, d0, #7*8
++ vbif d1, d6, d7
++ vbif d2, d6, d7
++ vst1.32 {d1[0]}, [r2], r3
++ vbif d3, d6, d7
++ vst1.32 {d2[0]}, [r0]
++ vst1.32 {d3[0]}, [r2]
++
++ bx lr
++endfunc
++
++
++@ ff_hevc_rpi_pred_dc_c_4_neon_8
++@ uint8_t *_src, [r0]
++@ const uint8_t *_top, [r1]
++@ const uint8_t *_left, [r2]
++@ ptrdiff_t stride) [r3]
++
++function ff_hevc_rpi_pred_dc_c_4_neon_8, export=1
++
++ @ Average the els of top & left
++ vld1.8 {d0}, [r1]
++ vld1.8 {d1}, [r2]
++A add r2, r0, r3, lsl #1
++A lsl r3, #2
++T lsl r3, #1
++T add r2, r0, r3
++T lsl r3, #1
++ vaddl.u8 q0, d0, d1
++ vadd.i16 d0, d1 @ d0 has 2 val pairs
++ vpadd.i32 d2, d0, d0 @ This adds U & V separately
++ vpadd.i32 d3, d0, d0
++ vrshrn.u16 d0, q1, #3
++
++ @ Store
++ vst1.8 {d0}, [r0], r3
++ vst1.8 {d0}, [r2], r3
++ vst1.8 {d0}, [r0]
++ vst1.8 {d0}, [r2]
++
++ bx lr
++endfunc
++
++
++@ ff_hevc_rpi_pred_dc_8_neon_8
++@ uint8_t *_src, [r0]
++@ const uint8_t *_top, [r1]
++@ const uint8_t *_left, [r2]
++@ ptrdiff_t stride) [r3]
++
++function ff_hevc_rpi_pred_dc_8_neon_8, export=1
++
++ @ Average the els of top & left
++ vld1.8 {d0}, [r1]
++ mov r1, #2
++ vld1.8 {d16}, [r2]
++ vmov.i16 q2, #3
++ vmov.i64 d7, #0xffff
++ vaddl.u8 q1, d0, d16 @ d2[0] = top[0] + left[0]
++ vmovl.u8 q0, d0
++ vadd.i16 d6, d2, d3 @ d6 has 4 vals
++ vmov.16 d4[0], r1 @ 2, 3, 3, 3...
++ vbit d0, d2, d7 @ q0 = top[0]+left[0], top[1..7]
++
++ @ top line gets some smoothing
++ @ (top[i] + 3*dc + 2) >> 2
++ @ as does left
++ @ top_line[0] is extra special
++ @ (top[0] + left[0] + 2*dc + 2) >> 2
++
++ vmov.i64 d7, #0xff
++ vmovl.u8 q1, d16
++ vpadd.i16 d6, d6 @ 2 (top & bottom of vector the same)
++ vpadd.i16 d6, d6 @ 1 (all the same)
++ vrshr.u16 d6, #4
++ vmla.i16 q1, q2, d6[0]
++ vmla.i16 q0, q2, d6[0]
++ vdup.8 d6, d6[0]
++ vrshrn.i16 d2, q1, #2
++ vrshrn.i16 d0, q0, #2
++
++ @ Store top line
++ vst1.8 {d0}, [r0], r3
++
++ @ Store the rest
++ vshr.u64 d2, #8
++ vbit d6, d2, d7
++ vshr.u64 d2, #8
++ vst1.8 {d6}, [r0], r3
++ mov r1, #6
++1:
++ vbit d6, d2, d7
++ vshr.u64 d2, #8
++ vst1.8 {d6}, [r0], r3
++ subs r1, #2
++ vbit d6, d2, d7
++ vshr.u64 d2, #8
++ vst1.8 {d6}, [r0], r3
++ bne 1b
++
++ bx lr
++endfunc
++
++
++@ ff_hevc_rpi_pred_dc_c_8_neon_8
++@ uint8_t *_src, [r0]
++@ const uint8_t *_top, [r1]
++@ const uint8_t *_left, [r2]
++@ ptrdiff_t stride) [r3]
++
++function ff_hevc_rpi_pred_dc_c_8_neon_8, export=1
++
++ @ Average the els of top & left
++ vld1.8 {q0}, [r1]
++ mov r1, #8
++ vld1.8 {q1}, [r2]
++T lsl r3, #1
++ vaddl.u8 q0, d0, d1
++A add r2, r0, r3, lsl #1
++A lsl r3, #2
++T add r2, r0, r3
++T lsl r3, #1
++ vaddl.u8 q1, d2, d3
++ vadd.i16 q1, q0
++ vadd.i16 d3, d2 @ d3 has 2 val pairs
++ vpadd.i32 d2, d3, d3 @ This add U & V separately
++ vpadd.i32 d3, d3, d3
++ vrshrn.u16 d0, q1, #4
++ vrshrn.u16 d1, q1, #4
++
++ @ Store
++1:
++ vst1.8 {q0}, [r0], r3
++ subs r1, #4
++ vst1.8 {q0}, [r2], r3
++ vst1.8 {q0}, [r0], r3
++ vst1.8 {q0}, [r2], r3
++ bne 1b
++
++ bx lr
++endfunc
++
++
++@ ff_hevc_rpi_pred_dc_16_neon_8
++@ uint8_t *_src, [r0]
++@ const uint8_t *_top, [r1]
++@ const uint8_t *_left, [r2]
++@ ptrdiff_t stride) [r3]
++
++function ff_hevc_rpi_pred_dc_16_neon_8, export=1
++
++ @ Average the els of top & left
++ vld1.8 {q8}, [r1]
++ mov r1, #2
++ vld1.8 {q9}, [r2]
++ vaddl.u8 q10, d16, d17
++ vaddl.u8 q11, d16, d18
++ vaddl.u8 q0, d18, d19
++ vmov.i16 q1, #3
++ vadd.i16 q10, q0
++ vmovl.u8 q0, d18
++ vadd.i16 d20, d21
++ vmov.i16 d2[0], r1 @ 2, 3, 3, 3...
++
++ @ top line gets some smoothing
++ @ (top[i] + 3*dc + 2) >> 2
++ @ as does left
++ @ top_line[0] is extra special
++ @ (top[0] + left[0] + 2*dc + 2) >> 2
++
++ vmovl.u8 q2, d16
++ vmovl.u8 q9, d19
++ vpadd.i16 d20, d20 @ 2 (top & bottom of vector the same)
++ vmov.i64 d7, #0xffff
++ vmovl.u8 q8, d17
++ vbit d4, d22, d7 @ q2 = top[0]+left[0], top[1..7]
++ vmov.i64 d7, #0xff
++ vpadd.i16 d20, d20 @ 1 (all the same)
++ vrshr.u16 d21, d20, #5
++ vrshr.u16 d20, d20, #5
++ vmla.i16 q0, q10, d2[1]
++ vmla.i16 q9, q10, d2[1]
++ vmla.i16 q2, q10, q1
++ vmla.i16 q8, q10, d2[1]
++ vdup.8 q1, d20[0]
++ vrshrn.i16 d0, q0, #2
++ vrshrn.i16 d1, q9, #2
++ vrshrn.i16 d4, q2, #2
++ vrshrn.i16 d5, q8, #2
++ vext.8 q0, q0, q0, #1
++
++ @ Store top line
++ vst1.8 {q2}, [r0], r3
++
++ @ Store the rest
++ mov r1, #15
++1:
++ vbit d2, d0, d7
++ vext.8 q0, q0, q0, #1
++ subs r1, #1
++ vst1.8 {q1}, [r0], r3
++ bne 1b
++
++ bx lr
++endfunc
++
++
++@ ff_hevc_rpi_pred_dc_c_16_neon_8
++@ uint8_t *_src, [r0]
++@ const uint8_t *_top, [r1]
++@ const uint8_t *_left, [r2]
++@ ptrdiff_t stride) [r3]
++
++function ff_hevc_rpi_pred_dc_c_16_neon_8, export=1
++
++ @ Average the els of top & left
++ vld1.8 {q0-q1}, [r1]
++ mov r1, #16
++ vld1.8 {q2-q3}, [r2]
++T lsl r3, #1
++ vaddl.u8 q0, d0, d1
++A add r2, r0, r3, lsl #1
++T add r2, r0, r3
++ vaddl.u8 q1, d2, d3
++A lsl r3, #2
++T lsl r3, #1
++ vaddl.u8 q2, d4, d5
++ vaddl.u8 q3, d6, d7
++ vadd.i16 q0, q1
++ vadd.i16 q2, q3
++ vadd.i16 q0, q2
++ vadd.i16 d0, d1 @ d0 has 2 val pairs
++ vpadd.i32 d4, d0, d0 @ This adds U & V separately
++ vpadd.i32 d5, d0, d0
++ vrshrn.u16 d0, q2, #5
++ vrshrn.u16 d1, q2, #5
++ vrshrn.u16 d2, q2, #5
++ vrshrn.u16 d3, q2, #5
++
++ @ Store
++1:
++ vst1.8 {q0-q1}, [r0], r3
++ subs r1, #2
++ vst1.8 {q0-q1}, [r2], r3
++ bne 1b
++
++ bx lr
++endfunc
++
++
++@ ff_hevc_rpi_pred_dc_32_neon_8
++@ uint8_t *_src, [r0]
++@ const uint8_t *_top, [r1]
++@ const uint8_t *_left, [r2]
++@ ptrdiff_t stride) [r3]
++
++function ff_hevc_rpi_pred_dc_32_neon_8, export=1
++
++ @ Average the els of top & left
++ vld1.8 {q0-q1}, [r1]
++ mov r1, #32
++ vld1.8 {q2-q3}, [r2]
++ add r2, r0, r3
++ vaddl.u8 q0, d0, d1
++ lsl r3, #1
++ vaddl.u8 q1, d2, d3
++ vaddl.u8 q2, d4, d5
++ vaddl.u8 q3, d6, d7
++ vadd.i16 q0, q1
++ vadd.i16 q2, q3
++ vadd.i16 q0, q2
++ vadd.i16 d0, d1 @ d0 has 4 vals
++ vpadd.i16 d0, d0 @ 2 (top & bottom the same)
++ vpadd.i16 d4, d0, d0 @ 1 (all the same)
++ vpadd.i16 d5, d0, d0
++ vrshrn.u16 d0, q2, #6
++ vrshrn.u16 d1, q2, #6
++ vrshrn.u16 d2, q2, #6
++ vrshrn.u16 d3, q2, #6
++
++ @ Store
++1:
++ vst1.8 {q0-q1}, [r0], r3
++ subs r1, #2
++ vst1.8 {q0-q1}, [r2], r3
++ bne 1b
++
++ bx lr
++endfunc
++
++
++@ -----------------------------------------------------------------------------
++@
++@ 10 Bit versions
++@
++@ There is no actual bit depth dependency in this code except that our
++@ intermediate results will overflow the 16 bits they are stored in
++@ All there functions are good to 10 bits - with the worst case being
++@ in dc_32 where we use all 16 bits.
++
++
++@ ff_hevc_rpi_pred_dc_4_neon_10
++@ uint8_t *_src, [r0]
++@ const uint8_t *_top, [r1]
++@ const uint8_t *_left, [r2]
++@ ptrdiff_t stride) [r3]
++
++function ff_hevc_rpi_pred_dc_4_neon_10, export=1
++
++ @ Average the els of top & left
++ vld1.16 {d0}, [r1]
++ mov r1, #2
++ vld1.16 {d1}, [r2]
++T lsl r3, #1
++ vmov.i16 q2, #3
++A add r2, r0, r3, lsl #1
++T add r2, r0, r3
++ vadd.u16 d2, d0, d1 @ d2[0] = top[0] + left[0]
++A lsl r3, #2
++T lsl r3, #1
++ vmov.16 d4[0], r1 @ 2, 3, 3, 3...
++ vmov.i64 d7, #0xffff
++ vbit d0, d2, d7 @ q0 = top[0]+left[0], top[1..3], left[0..3]
++
++ @ top line gets some smoothing
++ @ (top[i] + 3*dc + 2) >> 2
++ @ as does left
++ @ top_line[0] is extra special
++ @ (top[0] + left[0] + 2*dc + 2) >> 2
++
++ vpadd.i16 d6, d2, d2 @ 2 (top & bottom of vector the same)
++ vpadd.i16 d6, d6 @ 1 (all the same)
++ vrshr.u16 d6, #3
++ vmla.i16 q0, q2, d6[0]
++ vrshr.u16 q0, #2
++
++ @ Store top line
++ vst1.16 {d0}, [r0], r3
++
++ @ Store the rest
++ vshr.u64 d3, d1, #1*16
++ vshr.u64 d4, d1, #2*16
++ vshr.u64 d5, d1, #3*16
++ vbif d3, d6, d7
++ vbif d4, d6, d7
++ vst1.16 {d3}, [r2], r3
++ vbif d5, d6, d7
++ vst1.16 {d4}, [r0]
++ vst1.16 {d5}, [r2]
++
++ bx lr
++endfunc
++
++
++@ ff_hevc_rpi_pred_dc_c_4_neon_10
++@ uint8_t *_src, [r0]
++@ const uint8_t *_top, [r1]
++@ const uint8_t *_left, [r2]
++@ ptrdiff_t stride) [r3] (In pels - needs * 4)
++
++function ff_hevc_rpi_pred_dc_c_4_neon_10, export=1
++
++ @ Average the els of top & left
++ vld1.8 {q0}, [r1]
++ vld1.8 {q1}, [r2]
++A add r2, r0, r3, lsl #2
++A lsl r3, #3
++T lsl r3, #2
++T add r2, r0, r3
++T lsl r3, #1
++ vadd.i16 q0, q1
++ vadd.i16 d0, d1 @ d0 has 2 val pairs
++ vpadd.i32 d2, d0, d0 @ This adds U & V separately
++ vpadd.i32 d3, d0, d0
++ vrshr.u16 q0, q1, #3
++
++ vst1.16 {q0}, [r0], r3
++ vst1.16 {q0}, [r2], r3
++ vst1.16 {q0}, [r0]
++ vst1.16 {q0}, [r2]
++
++ bx lr
++endfunc
++
++
++@ ff_hevc_rpi_pred_dc_8_neon_10
++@ uint8_t *_src, [r0]
++@ const uint8_t *_top, [r1]
++@ const uint8_t *_left, [r2]
++@ ptrdiff_t stride) [r3]
++
++function ff_hevc_rpi_pred_dc_8_neon_10, export=1
++
++ @ Average the els of top & left
++ vld1.16 {q0}, [r1]
++ mov r1, #2
++ vld1.16 {q8}, [r2]
++T lsl r3, #1
++ vmov.i16 q2, #3
++A add r2, r0, r3, lsl #1
++T add r2, r0, r3
++ vadd.i16 q1, q0, q8 @ q1[0] = top[0] + left[0]
++A lsl r3, #2
++T lsl r3, #1
++ vmov.i64 d7, #0xffff
++ vmov.16 d4[0], r1 @ 2, 3, 3, 3...
++ vadd.i16 d6, d2, d3 @ d6 has 4 vals
++ vbit d0, d2, d7 @ q0 = top[0]+left[0], top[1..7]
++
++ @ top line gets some smoothing
++ @ (top[i] + 3*dc + 2) >> 2
++ @ as does left
++ @ top_line[0] is extra special
++ @ (top[0] + left[0] + 2*dc + 2) >> 2
++
++ vpadd.i16 d6, d6 @ 2 (top & bottom of vector the same)
++ vpadd.i16 d6, d6 @ 1 (all the same)
++ vrshr.u16 d6, #4
++ vmla.i16 q8, q2, d6[0]
++ vmla.i16 q0, q2, d6[0]
++ vdup.16 q2, d6[0]
++ vdup.16 q9, d6[0]
++ vrshr.u16 q8, q8, #2
++ vrshr.u16 q0, q0, #2
++ vext.16 q1, q8, q8, #1
++
++ @ Store top line
++ vst1.16 {q0}, [r0], r3
++
++ @ Store the rest
++ vbit d18, d2, d7
++ vst1.16 {q9}, [r2], r3
++ mov r1, #6
++1:
++ vext.16 q8, q8, q8, #2
++ subs r1, #2
++ vext.16 q1, q1, q1, #2
++ vbit d4, d16, d7
++ vst1.16 {q2}, [r0], r3
++ vbit d18, d2, d7
++ vst1.16 {q9}, [r2], r3
++ bne 1b
++
++ bx lr
++endfunc
++
++
++@ ff_hevc_rpi_pred_dc_c_8_neon_10
++@ uint8_t *_src, [r0]
++@ const uint8_t *_top, [r1]
++@ const uint8_t *_left, [r2]
++@ ptrdiff_t stride) [r3] (In pels - needs * 4)
++
++function ff_hevc_rpi_pred_dc_c_8_neon_10, export=1
++
++ @ Average the els of top & left
++ vld1.16 {q0-q1}, [r1]
++ mov r1, #8
++ vld1.16 {q2-q3}, [r2]
++T lsl r3, #2
++ vadd.i16 q1, q0
++A add r2, r0, r3, lsl #2
++A lsl r3, #3
++T add r2, r0, r3
++T lsl r3, #1
++ vadd.i16 q2, q3
++ vadd.i16 q1, q2
++ vadd.i16 d3, d2 @ d3 has 2 val pairs
++ vpadd.i32 d2, d3, d3 @ This add U & V separately
++ vpadd.i32 d3, d3, d3
++ vrshr.u16 q0, q1, #4
++ vrshr.u16 q1, q1, #4
++
++ @ Store
++1:
++ vst1.8 {q0-q1}, [r0], r3
++ subs r1, #2
++ vst1.8 {q0-q1}, [r2], r3
++ bne 1b
++
++ bx lr
++endfunc
++
++
++@ ff_hevc_rpi_pred_dc_16_neon_10
++@ uint8_t *_src, [r0]
++@ const uint8_t *_top, [r1]
++@ const uint8_t *_left, [r2]
++@ ptrdiff_t stride) [r3]
++
++function ff_hevc_rpi_pred_dc_16_neon_10, export=1
++
++ @ Average the els of top & left
++ vld1.16 {q8-q9}, [r1]
++ mov r1, #2
++ vld1.16 {q10-q11}, [r2]
++ lsl r3, #1 @ stride given in pels
++ vadd.i16 q0, q8, q9
++ vadd.i16 q1, q10, q11
++ vmov.i16 q3, #3
++ vadd.i16 q1, q0
++ vadd.i16 d0, d16, d20
++ vmov.i64 d31, #0xffff
++ vadd.i16 d3, d2
++ vmov.16 d6[0], r1 @ 2, 3, 3, 3...
++
++ @ top line gets some smoothing
++ @ (top[i] + 3*dc + 2) >> 2
++ @ as does left
++ @ topline[0] is extra special
++ @ (top[0] + left[0] + 2*dc + 2) >> 2
++
++ vbit d16, d0, d31 @ q8 = top[0]+left[0], top[1..7]
++ vpadd.i16 d3, d3 @ 2 (top & bottom of vector the same)
++ vpadd.i16 d3, d3 @ 1 (all the same)
++ vrshr.u16 d2, d3, #5
++ vrshr.u16 d3, d3, #5
++ vmov q0, q1
++ vmla.i16 q10, q1, d6[1]
++ vmla.i16 q11, q1, d6[1]
++ vmla.i16 q8, q1, q3
++ vmla.i16 q9, q1, d6[1]
++ vrshr.u16 q2, q10, #2
++ vrshr.u16 q3, q11, #2
++ vrshr.u16 q8, #2
++ vrshr.u16 q9, #2
++ vext.16 q2, q2, q2, #1
++ mov r1, #7<<29
++
++ @ Store top line
++ vst1.16 {q8-q9}, [r0], r3
++
++ @ Store the rest
++1:
++ vbit d0, d4, d31
++ vext.16 q2, q2, q2, #1
++ subs r1, #1<<29
++ vst1.16 {q0-q1}, [r0], r3
++ bne 1b
++1:
++ vbit d0, d6, d31
++ vext.16 q3, q3, q3, #1
++ subs r1, #1<<29
++ vst1.16 {q0-q1}, [r0], r3
++ bne 1b
++
++ bx lr
++endfunc
++
++
++@ ff_hevc_rpi_pred_dc_c_16_neon_10
++@ uint8_t *_src, [r0]
++@ const uint8_t *_top, [r1]
++@ const uint8_t *_left, [r2]
++@ ptrdiff_t stride) [r3] (In pels - needs * 4)
++
++function ff_hevc_rpi_pred_dc_c_16_neon_10, export=1
++
++ @ Average the els of top & left
++ vldm r1, {q0-q3}
++ vldm r2, {q8-q11}
++ vadd.i16 q0, q1
++ mov r1, #16
++ vadd.i16 q2, q3
++ add r2, r0, #32
++ vadd.i16 q8, q9
++ lsl r3, #2
++ vadd.i16 q10, q11
++ vadd.u16 q0, q2
++ vadd.u16 q8, q10
++ vadd.i16 q0, q8
++ vadd.i16 d0, d1 @ d0 has 2 val pairs
++ vpadd.i32 d4, d0, d0 @ This adds U & V separately
++ vpadd.i32 d5, d0, d0
++ vrshr.u16 q0, q2, #5
++ vrshr.u16 q1, q2, #5
++
++ @ Store
++1:
++ vst1.16 {q0-q1}, [r0], r3
++ subs r1, #1
++ vst1.16 {q0-q1}, [r2], r3
++ bne 1b
++
++ bx lr
++endfunc
++
++
++@ ff_hevc_rpi_pred_dc_32_neon_10
++@ uint8_t *_src, [r0]
++@ const uint8_t *_top, [r1]
++@ const uint8_t *_left, [r2]
++@ ptrdiff_t stride) [r3] (In pels)
++
++function ff_hevc_rpi_pred_dc_32_neon_10, export=1
++
++ @ Average the els of top & left
++ @ With 10 bits we are (just) safe from overflow in i16
++ vldm r1, {q0-q3}
++ vldm r2, {q8-q11}
++ vadd.i16 q0, q1
++ mov r1, #32
++ vadd.i16 q2, q3
++ add r2, r0, #32
++ vadd.i16 q8, q9
++ lsl r3, #1
++ vadd.i16 q10, q11
++ vadd.u16 q0, q2
++ vadd.u16 q8, q10
++ vadd.i16 q0, q8
++ vadd.i16 d0, d1 @ d0 has 4 vals
++ vpadd.i16 d0, d0 @ 2 (top & bottom the same)
++ vpadd.i16 d4, d0, d0 @ 1 (all the same)
++ vpadd.i16 d5, d0, d0
++ vrshr.u16 q0, q2, #6
++ vrshr.u16 q1, q2, #6
++
++ @ Store
++1:
++ vst1.16 {q0-q1}, [r0], r3
++ subs r1, #1
++ vst1.16 {q0-q1}, [r2], r3
++ bne 1b
++
++ bx lr
++endfunc
++
++
+diff --git a/libavcodec/arm/rpi_hevcpred_intra_filter_neon.S b/libavcodec/arm/rpi_hevcpred_intra_filter_neon.S
+new file mode 100644
+index 0000000000..21cd28c709
+--- /dev/null
++++ b/libavcodec/arm/rpi_hevcpred_intra_filter_neon.S
+@@ -0,0 +1,872 @@
++/*
++ * Copyright (c) 2018 John Cox <jc@kynesim.co.uk> (for Raspberry Pi)
++ *
++ * This file is part of FFmpeg.
++ *
++ * FFmpeg is free software; you can redistribute it and/or
++ * modify it under the terms of the GNU Lesser General Public
++ * License as published by the Free Software Foundation; either
++ * version 2.1 of the License, or (at your option) any later version.
++ *
++ * FFmpeg is distributed in the hope that it will be useful,
++ * but WITHOUT ANY WARRANTY; without even the implied warranty of
++ * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
++ * Lesser General Public License for more details.
++ *
++ * You should have received a copy of the GNU Lesser General Public
++ * License along with FFmpeg; if not, write to the Free Software
++ * Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA
++ */
++
++#include "libavutil/arm/asm.S"
++#include "neon.S"
++
++@ All functions have the call
++@
++@ int ff_hevc_rpi_intra_filter_N_neon_PW(
++@ pixel * const left, [r0]
++@ pixel * const top, [r1]
++@ const unsigned int req, [r2]
++@ const unsigned int avail, [r3]
++@ const pixel * const src_l, [sp, #0]
++@ const pixel * const src_u, [sp, #4]
++@ const pixel * const src_ur, [sp, #8]
++@ const unsigned int stride, [sp, #12] (pels)
++@ const unsigned int top_right_size, [sp, #16]
++@ const unsigned int down_left_size) [sp, #20]
++@
++@ Assumptions:
++@ (that wouldn't apply to all frame layoouts but do apply to sand, so beware
++@ if reuseing this code)
++@
++@ Min ctb size is 8 so we don't need to worry about tr_size or dl_size for
++@ N==4, but do for chroma N>=8. As we share Y/C fns that means we can ignore
++@ N==8,PW=8 (chroma always PW>8) but have to cope for larger
++@
++@ We always have at least 64 pixel H frame width rounding - this lets us
++@ load UR widthout having to worry about exactly how many pixels are actually
++@ within the frame. As partial loads will only occur very occasionally this
++@ should be a win in nearly all cases.
++@
++@ 16 bit fns can be used as 8 bit chroma fns as chroma never filters
++@ so we do no maths on the contents
++@
++@ No filtering in 32bit fns as they are chroma only
++
++
++.equ AVAIL_UR, 1
++.equ AVAIL_U, 2
++.equ AVAIL_UL, 4
++.equ AVAIL_L, 8
++.equ AVAIL_DL, 16
++
++.equ FILTER_LIGHT, 0x40
++.equ FILTER_STRONG, 0x80
++
++.equ AVAIL_S_UR_N_U_C, 32 - 1
++.equ AVAIL_S_U_N_UL_C, 32 - 2
++.equ AVAIL_S_UL_N_L_C, 32 - 3
++.equ AVAIL_S_L_N_DL_C, 32 - 4
++
++.equ AVAIL_S_U_DL_CPSR, 31 - 4 @ Shift for u..dl to go into flags via cpsr
++
++@ On entry
++@ r2 req
++@ r3 avail
++@ [sp, #sp_offset...] args
++@
++@ On Exit:
++@
++@ Extend values:
++@ d_l scalar contains value for L & DL
++@ if DL avail then this is is DL[0] so we don't need to load that
++@ d_ul scalar containing value for UL
++@ d_u scalar containing value for U
++@ d_ur scalar containing value for UR
++@ If DL avail then d_l == b_dl elif L avail then d_l == a_l else...
++@ This means that L-light-filter works even if nreq DL (we never filter
++@ req-DL without req-L, but we do filter req-L without req-DL)
++@ If UR avail then d_ur == a_ur so U-filter good too
++@
++@ Data load pointers (only load if req & avail):
++@ r4 DL + stride
++@ r10 L
++@ r6 U
++@ r5 UR
++@
++@ Others:
++@ r2 req
++@ r7 req & avail
++@ r3 L + stride
++@ r8 DL + stride * 2
++@ r9 stride * 2
++@ cs Load U
++@ mi Load UR
++@
++@ Clobbered:
++@ r12
++
++.macro load_pointers pw_s, log2_s, sp_offset, d_type, d_l, d_ul, d_u, d_ur
++
++.equ src_l\@, \sp_offset + 0
++.equ src_u\@, \sp_offset + 4
++.equ src_ur\@, \sp_offset + 8
++.equ stride\@, \sp_offset + 12
++.equ pw\@, (1 << \pw_s) @ pel width in bytes
++.equ b_size\@, (1 << (\pw_s + \log2_s)) @ size in bytes
++
++@ r9 stride
++@ r7 = ab_ul, r6 = a_u, r5 = a_ur
++@ r4 = b_dl, r10 = b_l, r8 = b_u
++
++ ldr r5, [sp, #src_ur\@]
++ lsl r12, r3, #AVAIL_S_U_DL_CPSR
++ ldr r10, [sp, #src_l\@]
++ ldr r9, [sp, #stride\@]
++ ldr r6, [sp, #src_u\@]
++
++ @ This is quite a slow instruction but it replaces
++ @ a decent number of tests that yield a max of 2 flags/op
++ @ It is annoying we can't branch on Q!
++ @ If L navail (ne) then DL must be navail (pl)
++ msr APSR_nzcvq, r12 @ n=dl, z=l, c=ul, v=u, q=ur
++
++ mov r4, r5
++ sub r7, r10, r9
++ it vs
++ movvs r4, r6
++ add r8, r6, #b_size\@ - pw\@
++ it cs
++ movcs r4, r7
++ ite ne
++ movne r10, r4
++ addeq r4, r7, r9, lsl #\log2_s
++ it cc
++ movcc r7, r10
++ it mi
++ addmi r4, r10, r9, lsl #\log2_s
++ vld1.\d_type {\d_ul}, [r7]
++ itt vc
++ movvc r8, r7
++ movvc r6, r7
++ vld1.\d_type {\d_l }, [r4], r9
++ tst r3, #AVAIL_UR
++ vld1.\d_type {\d_u }, [r6]
++ it eq
++ moveq r5, r8
++ and r7, r2, r3
++ add r8, r4, r9
++ vld1.\d_type {\d_ur}, [r5]
++ lsls r12, r7, #AVAIL_S_UR_N_U_C
++ add r3, r10, r9
++ lsl r9, #1
++.endm
++
++
++
++@ int ff_hevc_rpi_intra_filter_4_neon_8(
++@ pixel * const left, [r0]
++@ pixel * const top, [r1]
++@ const unsigned int req, [r2]
++@ const unsigned int avail, [r3]
++@ const pixel * const src_l, [sp, #0]
++@ const pixel * const src_u, [sp, #4]
++@ const pixel * const src_ur, [sp, #8]
++@ const unsigned int stride, [sp, #12] (pels)
++@ const unsigned int top_right_size, [sp, #16]
++@ const unsigned int down_left_size) [sp, #20]
++
++.set sp_base, 8*4
++.set pw_s, 0
++.set pw, (1 << pw_s)
++.set log2_s, 2
++
++function ff_hevc_rpi_intra_filter_4_neon_8, export=1
++ push {r4-r10, lr}
++ load_pointers pw_s, log2_s, sp_base, 8, d0[], d31[7], d1[], d2[]
++
++ it cs
++ vldrcs s2, [r6]
++ ite pl
++ vmovpl s3, s4
++ vldrmi s3, [r5]
++
++ lsls r7, #AVAIL_S_L_N_DL_C
++ add r12, r0, #-pw
++ bpl 1f
++
++ vld1.8 {d0[0]}, [r10], r9
++ vld1.8 {d0[1]}, [r3], r9
++ vld1.8 {d0[2]}, [r10]
++ vld1.8 {d0[3]}, [r3]
++1:
++ bcc 1f
++ vld1.8 {d0[5]}, [r4], r9
++ vld1.8 {d0[6]}, [r8]
++ vld1.8 {d0[7]}, [r4]
++1:
++ vstr d1, [r1] @ Up
++ vst1.8 {d31[7]}, [r12]
++ vstr d0, [r0] @ Left
++ pop {r4-r10, pc}
++endfunc
++
++
++@ int ff_hevc_rpi_intra_filter_4_neon_16(
++@ pixel * const left, [r0]
++@ pixel * const top, [r1]
++@ const unsigned int req, [r2]
++@ const unsigned int avail, [r3]
++@ const pixel * const src_l, [sp, #0]
++@ const pixel * const src_u, [sp, #4]
++@ const pixel * const src_ur, [sp, #8]
++@ const unsigned int stride, [sp, #12] (pels)
++@ const unsigned int top_right_size, [sp, #16]
++@ const unsigned int down_left_size) [sp, #20]
++
++.set sp_base, 8*4
++.set pw_s, 1
++.set pw, (1 << pw_s)
++.set log2_s, 2
++
++function ff_hevc_rpi_intra_filter_4_neon_16, export=1
++ push {r4-r10, lr}
++ load_pointers pw_s, log2_s, sp_base, 16, "d0[],d1[]", d31[3], d2[], d3[]
++
++ it cs
++ vldrcs d2, [r6]
++ it mi
++ vldrmi d3, [r5]
++ lsls r7, #AVAIL_S_L_N_DL_C
++ add r12, r0, #-pw
++ bpl 1f
++ vld1.16 {d0[0]}, [r10], r9
++ vld1.16 {d0[1]}, [r3], r9
++ vld1.16 {d0[2]}, [r10]
++ vld1.16 {d0[3]}, [r3]
++1:
++ bcc 1f
++ vld1.16 {d1[1]}, [r4], r9
++ vld1.16 {d1[2]}, [r8]
++ vld1.16 {d1[3]}, [r4]
++1:
++ vst1.16 {q1}, [r1] @ Up
++ vst1.16 {d31[3]}, [r12]
++ vst1.16 {q0}, [r0] @ Left
++ pop {r4-r10, pc}
++endfunc
++
++
++@ int ff_hevc_rpi_intra_filter_8_neon_8(
++@ pixel * const left, [r0]
++@ pixel * const top, [r1]
++@ const unsigned int req, [r2]
++@ const unsigned int avail, [r3]
++@ const pixel * const src_l, [sp, #0]
++@ const pixel * const src_u, [sp, #4]
++@ const pixel * const src_ur, [sp, #8]
++@ const unsigned int stride, [sp, #12] (pels)
++@ const unsigned int top_right_size, [sp, #16]
++@ const unsigned int down_left_size) [sp, #20]
++
++.set sp_base, 8*4
++.set pw_s, 0
++.set pw, (1 << pw_s)
++.set log2_s, 3
++
++function ff_hevc_rpi_intra_filter_8_neon_8, export=1
++ push {r4-r10, lr}
++ load_pointers pw_s, log2_s, sp_base, 8, "d0[],d1[]", d31[7], d4[], d5[]
++
++ it cs
++ vldrcs d4, [r6]
++ it mi
++ vldrmi d5, [r5]
++
++ lsls r7, #AVAIL_S_L_N_DL_C
++ bpl 1f
++ vld1.8 {d0[0]}, [r10], r9
++ vld1.8 {d0[1]}, [r3], r9
++ vld1.8 {d0[2]}, [r10], r9
++ vld1.8 {d0[3]}, [r3], r9
++ vld1.8 {d0[4]}, [r10], r9
++ vld1.8 {d0[5]}, [r3], r9
++ vld1.8 {d0[6]}, [r10]
++ vld1.8 {d0[7]}, [r3]
++1:
++ bcc 1f
++ vld1.8 {d1[1]}, [r4], r9
++ vld1.8 {d1[2]}, [r8], r9
++ vld1.8 {d1[3]}, [r4], r9
++ vld1.8 {d1[4]}, [r8], r9
++ vld1.8 {d1[5]}, [r4], r9
++ vld1.8 {d1[6]}, [r8]
++ vld1.8 {d1[7]}, [r4]
++1:
++ tst r2, #FILTER_LIGHT
++ add r12, r0, #-pw
++ beq 10f
++
++ @ Luma light filter
++ vext.8 q8, q15, q2, #15
++ vext.8 q12, q15, q0, #15
++ vaddl.u8 q9, d17, d5
++ vaddl.u8 q8, d16, d4
++ vaddl.u8 q13, d25, d1
++ vaddl.u8 q12, d24, d0
++ vmov.u8 r3, d5[7] @ Save final pel
++ vmov.u8 r2, d1[7] @ Save final pel
++
++ vext.16 q2, q8, q9, #1
++ vext.16 q3, q9, q9, #1
++ vext.16 q0, q12, q13, #1
++ vext.16 q1, q13, q13, #1
++ vadd.u16 d30, d16, d24 @ d30[0] = l[0] + 2ul + u[0]
++ vadd.u16 q2, q8
++ vadd.u16 q3, q9
++ vadd.u16 q0, q12
++ vadd.u16 q1, q13
++
++ vrshrn.u16 d4, q2, #2
++ vrshrn.u16 d5, q3, #2
++ vrshrn.u16 d0, q0, #2
++ vrshrn.u16 d1, q1, #2
++ vrshr.u16 d30, #2
++ vmov.u8 d5[7], r3 @ Restore final pel
++ vmov.u8 d1[7], r2 @ Restore final pel
++ vdup.u8 d31, d30[0] @ d31[3] = d30[0]
++
++10:
++ vst1.8 {q2 }, [r1] @ Up
++ vst1.8 {d31[7]}, [r12] @ Up-left
++ vst1.8 {q0 }, [r0] @ Left
++ pop {r4-r10, pc}
++endfunc
++
++
++@ int ff_hevc_rpi_intra_filter_8_neon_16(
++@ pixel * const left, [r0]
++@ pixel * const top, [r1]
++@ const unsigned int req, [r2]
++@ const unsigned int avail, [r3]
++@ const pixel * const src_l, [sp, #0]
++@ const pixel * const src_u, [sp, #4]
++@ const pixel * const src_ur, [sp, #8]
++@ const unsigned int stride, [sp, #12] (pels)
++@ const unsigned int top_right_size, [sp, #16]
++@ const unsigned int down_left_size) [sp, #20]
++
++.set sp_base, 8*4
++.set ur_size, sp_base + 16
++.set dl_size, sp_base + 20
++.set pw_s, 1
++.set pw, (1 << pw_s)
++.set log2_s, 3
++.set p_size, (1 << log2_s) @ size in pels
++
++function ff_hevc_rpi_intra_filter_8_neon_16, export=1
++ push {r4-r10, lr}
++ load_pointers pw_s, log2_s, sp_base, 16, "d0[],d1[]", d31[3], "d4[],d5[]", "d6[],d7[]"
++
++ it cs
++ vldmcs r6, {d4, d5}
++ ldr r12, [sp, #ur_size]
++ bpl 1f
++ cmp r12, #4
++ vldm r5, {d6, d7}
++ bgt 1f
++ vdup.16 d7, d6[3]
++1:
++ lsls r12, r7, #AVAIL_S_L_N_DL_C
++ vdup.16 q1, d0[0]
++ bpl 1f
++ vld1.16 {d0[0]}, [r10], r9
++ vld1.16 {d0[1]}, [r3], r9
++ vld1.16 {d0[2]}, [r10], r9
++ vld1.16 {d0[3]}, [r3], r9
++ vld1.16 {d1[0]}, [r10], r9
++ vld1.16 {d1[1]}, [r3], r9
++ vld1.16 {d1[2]}, [r10]
++ vld1.16 {d1[3]}, [r3]
++1:
++ bcc 1f
++ ldr r12, [sp, #dl_size]
++ vld1.16 {d2[1]}, [r4], r9
++ cmp r12, #p_size
++ vld1.16 {d2[2]}, [r8], r9
++ vld1.16 {d2[3]}, [r4], r9
++ blt 2f
++ vld1.16 {d3[0]}, [r8], r9
++ vld1.16 {d3[1]}, [r4], r9
++ vld1.16 {d3[2]}, [r8]
++ vld1.16 {d3[3]}, [r4]
++ b 1f
++2:
++ vdup.16 d3, d2[3]
++1:
++ tst r2, #FILTER_LIGHT
++ add r12, r0, #-pw
++ beq 10f
++
++ @ Luma light filter
++ vext.16 q9, q2, q3, #7
++ vext.16 q8, q15, q2, #7
++ vext.16 q13, q0, q1, #7
++ vext.16 q12, q15, q0, #7
++ vadd.u16 q9, q3
++ vadd.u16 q8, q2
++ vadd.u16 q13, q1
++ vadd.u16 q12, q0
++ vmov.u16 r3, d7[3] @ Save final pel
++ vmov.u16 r2, d3[3] @ Save final pel
++
++ vext.16 q2, q8, q9, #1
++ vext.16 q3, q9, q9, #1
++ vext.16 q0, q12, q13, #1
++ vext.16 q1, q13, q13, #1
++ vadd.u16 d30, d16, d24 @ d30[0] = l[0] + 2ul + u[0]
++ vadd.u16 q2, q8
++ vadd.u16 q3, q9
++ vadd.u16 q0, q12
++ vadd.u16 q1, q13
++
++ vrshr.u16 q2, #2
++ vrshr.u16 q3, #2
++ vrshr.u16 q0, #2
++ vrshr.u16 q1, #2
++ vrshr.u16 d30, #2
++ vmov.u16 d7[3], r3 @ Restore final pel
++ vmov.u16 d3[3], r2 @ Restore final pel
++ vdup.u16 d31, d30[0] @ d31[3] = d30[0]
++
++10:
++ vst1.16 {q2, q3}, [r1] @ Up
++ vst1.16 {d31[3]}, [r12] @ Up-left
++ vst1.16 {q0, q1}, [r0] @ Left
++ pop {r4-r10, pc}
++endfunc
++
++@ int ff_hevc_rpi_intra_filter_16_neon_16(
++@ pixel * const left, [r0]
++@ pixel * const top, [r1]
++@ const unsigned int req, [r2]
++@ const unsigned int avail, [r3]
++@ const pixel * const src_l, [sp, #0]
++@ const pixel * const src_u, [sp, #4]
++@ const pixel * const src_ur, [sp, #8]
++@ const unsigned int stride, [sp, #12] (pels)
++@ const unsigned int top_right_size, [sp, #16]
++@ const unsigned int down_left_size) [sp, #20]
++
++.set sp_base, 8*4
++.set ur_size, sp_base + 16
++.set dl_size, sp_base + 20
++.set pw_s, 1
++.set pw, (1 << pw_s)
++.set log2_s, 4
++.set p_size, (1 << log2_s) @ size in pels
++
++function ff_hevc_rpi_intra_filter_16_neon_16, export=1
++ push {r4-r10, lr}
++ load_pointers pw_s, log2_s, sp_base, 16, "d0[],d1[]", d31[3], "d16[],d17[]", "d20[],d21[]"
++
++ vdup.16 q9, d16[0]
++ vdup.16 q11, d20[0]
++
++ it cs
++ vldmcs r6, {d16-d19}
++ ldr r12, [sp, #ur_size]
++ bpl 1f
++ cmp r12, #12
++ @ Given chroma frame layout, if UR exists then it is always legit to
++ @ load all of it even if most of it is outside the frame.
++ vldm r5, {d20-d23}
++ bgt 1f
++ bge 4f
++ cmp r12, #8
++ bge 3f
++ vdup.16 d21, d20[3]
++3: vdup.16 d22, d21[3]
++4: vdup.16 d23, d22[3]
++
++1:
++ lsls r7, #AVAIL_S_L_N_DL_C
++ ldr r12, [sp, #dl_size]
++ vdup.16 q1, d0[0]
++ vdup.16 q2, d0[0]
++ vdup.16 q3, d0[0]
++ bpl 1f
++ vld1.16 {d0[0]}, [r10], r9
++ vld1.16 {d0[1]}, [r3], r9
++ vld1.16 {d0[2]}, [r10], r9
++ vld1.16 {d0[3]}, [r3], r9
++ vld1.16 {d1[0]}, [r10], r9
++ vld1.16 {d1[1]}, [r3], r9
++ vld1.16 {d1[2]}, [r10], r9
++ vld1.16 {d1[3]}, [r3], r9
++ vld1.16 {d2[0]}, [r10], r9
++ vld1.16 {d2[1]}, [r3], r9
++ vld1.16 {d2[2]}, [r10], r9
++ vld1.16 {d2[3]}, [r3], r9
++ vld1.16 {d3[0]}, [r10], r9
++ vld1.16 {d3[1]}, [r3], r9
++ vld1.16 {d3[2]}, [r10]
++ vld1.16 {d3[3]}, [r3]
++1:
++ bcc 1f
++ vld1.16 {d4[1]}, [r4], r9
++ cmp r12, #4
++ vld1.16 {d4[2]}, [r8], r9
++ vld1.16 {d4[3]}, [r4], r9
++ ble 2f
++ vld1.16 {d5[0]}, [r8], r9
++ vld1.16 {d5[1]}, [r4], r9
++ cmp r12, #12
++ vld1.16 {d5[2]}, [r8], r9
++ vld1.16 {d5[3]}, [r4], r9
++ blt 3f
++ vld1.16 {d6[0]}, [r8], r9
++ vld1.16 {d6[1]}, [r4], r9
++ vld1.16 {d6[2]}, [r8], r9
++ vld1.16 {d6[3]}, [r4], r9
++ ble 4f
++ vld1.16 {d7[0]}, [r8], r9
++ vld1.16 {d7[1]}, [r4], r9
++ vld1.16 {d7[2]}, [r8]
++ vld1.16 {d7[3]}, [r4]
++ b 1f
++2: vdup.16 d5, d4[3]
++3: vdup.16 d6, d5[3]
++4: vdup.16 d7, d6[3]
++1:
++ tst r2, #FILTER_LIGHT
++ add r12, r0, #-pw
++ beq 10f
++
++ vpush {q5}
++ @ Luma light filter
++ @ Left
++ vext.16 q5, q2, q3, #7
++ vext.16 q14, q1, q2, #7
++ vext.16 q13, q0, q1, #7
++ vext.16 q12, q15, q0, #7
++
++ vadd.u16 q5, q3
++ vadd.u16 q14, q2
++ vadd.u16 q13, q1
++ vadd.u16 q12, q0
++ vmov.u16 r2, d7[3] @ Save final pel
++
++ vext.16 q0, q12, q13, #1
++ vext.16 q1, q13, q14, #1
++ vext.16 q2, q14, q5, #1
++ vext.16 q3, q5, q5, #1
++
++ vmov d30, d24 @ d30[0] = l[0] + ul
++ vadd.u16 q0, q12
++ vadd.u16 q1, q13
++ vadd.u16 q2, q14
++ vadd.u16 q3, q5
++
++ vrshr.u16 q0, #2
++ vrshr.u16 q1, #2
++ vrshr.u16 q2, #2
++ vrshr.u16 q3, #2
++
++ @ Up
++ vext.16 q5, q10, q11, #7
++ vext.16 q14, q9, q10, #7
++ vext.16 q13, q8, q9, #7
++ vext.16 q12, q15, q8, #7
++
++ vadd.u16 q5, q11
++ vadd.u16 q14, q10
++ vadd.u16 q13, q9
++ vadd.u16 q12, q8
++ vmov.u16 r3, d23[3] @ Save final pel
++
++ vext.16 q8, q12, q13, #1
++ vext.16 q9, q13, q14, #1
++ vext.16 q10, q14, q5, #1
++ vext.16 q11, q5, q5, #1
++
++ vadd.u16 d30, d24 @ d30[0] = l[0] + 2ul + u[0]
++ vadd.u16 q8, q12
++ vadd.u16 q9, q13
++ vadd.u16 q10, q14
++ vadd.u16 q11, q5
++
++ vrshr.u16 q8, #2
++ vrshr.u16 q9, #2
++ vrshr.u16 q10, #2
++ vrshr.u16 q11, #2
++
++ @ Misc
++ vrshr.u16 d30, #2
++ vmov.u16 d7[3], r2 @ Restore final pel
++ vmov.u16 d23[3], r3 @ Restore final pel
++ vdup.u16 d31, d30[0] @ d31[3] = d30[0]
++ vpop {q5}
++
++10:
++ vstm r1, {d16-d23} @ Up
++ vst1.16 {d31[3]}, [r12] @ Up-left
++ vstm r0, { d0-d7 } @ Left
++ pop {r4-r10, pc}
++endfunc
++
++@ int ff_hevc_rpi_intra_filter_4_neon_32(
++@ pixel * const left, [r0]
++@ pixel * const top, [r1]
++@ const unsigned int req, [r2]
++@ const unsigned int avail, [r3]
++@ const pixel * const src_l, [sp, #0]
++@ const pixel * const src_u, [sp, #4]
++@ const pixel * const src_ur, [sp, #8]
++@ const unsigned int stride, [sp, #12] (pels)
++@ const unsigned int top_right_size, [sp, #16]
++@ const unsigned int down_left_size) [sp, #20]
++
++.set sp_base, 8*4
++.set pw_s, 2
++.set pw, (1 << pw_s)
++.set log2_s, 2
++
++function ff_hevc_rpi_intra_filter_4_neon_32, export=1
++ push {r4-r10, lr}
++ load_pointers pw_s, log2_s, sp_base, 32, "d0[],d1[]", d31[1], "d4[],d5[]", "d6[],d7[]"
++
++ it cs
++ vldmcs r6, {d4, d5}
++ it mi
++ vldmmi r5, {d6, d7}
++ lsls r7, #AVAIL_S_L_N_DL_C
++ vdup.32 q1, d0[0]
++ add r12, r0, #-pw
++ bpl 1f
++ vld1.32 {d0[0]}, [r10], r9
++ vld1.32 {d0[1]}, [r3], r9
++ vld1.32 {d1[0]}, [r10]
++ vld1.32 {d1[1]}, [r3]
++1:
++ bcc 1f
++ vld1.32 {d2[1]}, [r4], r9
++ vld1.32 {d3[0]}, [r8]
++ vld1.32 {d3[1]}, [r4]
++1:
++ vst1.32 {q2, q3 }, [r1] @ Up
++ vst1.32 {d31[1]}, [r12]
++ vst1.32 {q0, q1 }, [r0] @ Left
++ pop {r4-r10, pc}
++endfunc
++
++
++@ int ff_hevc_rpi_intra_filter_8_neon_32(
++@ pixel * const left, [r0]
++@ pixel * const top, [r1]
++@ const unsigned int req, [r2]
++@ const unsigned int avail, [r3]
++@ const pixel * const src_l, [sp, #0]
++@ const pixel * const src_u, [sp, #4]
++@ const pixel * const src_ur, [sp, #8]
++@ const unsigned int stride, [sp, #12] (pels)
++@ const unsigned int top_right_size, [sp, #16]
++@ const unsigned int down_left_size) [sp, #20]
++
++.set sp_base, 8*4
++.set ur_size, sp_base + 16
++.set dl_size, sp_base + 20
++.set pw_s, 2
++.set pw, (1 << pw_s)
++.set log2_s, 3
++.set p_size, (1 << log2_s) @ size in pels
++
++function ff_hevc_rpi_intra_filter_8_neon_32, export=1
++ push {r4-r10, lr}
++ load_pointers pw_s, log2_s, sp_base, 32, "d0[],d1[]", d31[1], "d16[],d17[]", "d20[],d21[]"
++
++ vdup.32 q9, d16[0]
++ vdup.32 q11, d20[0]
++
++ it cs
++ vldmcs r6, {q8, q9 }
++ ldr r12, [sp, #ur_size]
++ bpl 1f
++ cmp r12, #p_size
++ vldm r5, {q10, q11}
++ bge 1f
++ vdup.32 q11, d21[1]
++1:
++ lsls r7, #AVAIL_S_L_N_DL_C
++ vdup.32 q1, d0[0]
++ vdup.32 q2, d0[0]
++ vdup.32 q3, d0[0]
++ bpl 1f
++ vld1.32 {d0[0]}, [r10], r9
++ vld1.32 {d0[1]}, [r3], r9
++ vld1.32 {d1[0]}, [r10], r9
++ vld1.32 {d1[1]}, [r3], r9
++ vld1.32 {d2[0]}, [r10], r9
++ vld1.32 {d2[1]}, [r3], r9
++ vld1.32 {d3[0]}, [r10]
++ vld1.32 {d3[1]}, [r3]
++1:
++ bcc 1f
++ ldr r12, [sp, #dl_size]
++ vld1.32 {d4[1]}, [r4], r9
++ cmp r12, #p_size
++ vld1.32 {d5[0]}, [r8], r9
++ vld1.32 {d5[1]}, [r4], r9
++ blt 2f
++ vld1.32 {d6[0]}, [r8], r9
++ vld1.32 {d6[1]}, [r4], r9
++ vld1.32 {d7[0]}, [r8]
++ vld1.32 {d7[1]}, [r4]
++ b 1f
++2:
++ vdup.32 q3, d5[1]
++1:
++ add r12, r0, #-pw
++ vstm r1, { q8-q11} @ Up
++ vst1.32 {d31[1]}, [r12]
++ vstm r0, { q0-q3 } @ Left
++ pop {r4-r10, pc}
++endfunc
++
++
++@ int ff_hevc_rpi_intra_filter_16_neon_32(
++@ pixel * const left, [r0]
++@ pixel * const top, [r1]
++@ const unsigned int req, [r2]
++@ const unsigned int avail, [r3]
++@ const pixel * const src_l, [sp, #0]
++@ const pixel * const src_u, [sp, #4]
++@ const pixel * const src_ur, [sp, #8]
++@ const unsigned int stride, [sp, #12] (pels)
++@ const unsigned int top_right_size, [sp, #16]
++@ const unsigned int down_left_size) [sp, #20]
++
++.set sp_base, 8*4
++.set ur_size, sp_base + 16
++.set dl_size, sp_base + 20
++.set pw_s, 2
++.set pw, (1 << pw_s)
++.set log2_s, 4
++.set p_size, (1 << log2_s) @ size in pels
++
++function ff_hevc_rpi_intra_filter_16_neon_32, export=1
++ push {r4-r10, lr}
++ load_pointers pw_s, log2_s, sp_base, 32, d30[0], d30[1], d31[0], d31[1]
++
++ @ Once we get this big we have run out of neon regs to store
++ @ everything at once so do in pieces
++
++ @ Up (have)
++ it cs
++ vldmcs r6, { q0-q3 }
++ ldr r12, [sp, #ur_size]
++ it mi
++ vldmmi r5, { q8-q11}
++ it cs
++ vstmcs r1, { q0-q3 }
++ bpl 1f
++ cmp r12, #12
++ add lr, r1, #(pw << log2_s)
++ bgt 2f
++ cmp r12, #8
++ bge 3f
++ vdup.16 q9, d17[1]
++4: vdup.16 d10, d19[1]
++3: vdup.16 q11, d21[1]
++2: vstm lr, { q8-q11}
++1:
++
++ @ Left (have)
++ add lr, r0, #-pw
++ lsls r12, r7, #AVAIL_S_L_N_DL_C
++ vst1.32 {d30[1]}, [lr] @ UL
++ bpl 1f
++ vld1.32 { d0[0]}, [r10], r9
++ vld1.32 { d0[1]}, [r3], r9
++ vld1.32 { d1[0]}, [r10], r9
++ vld1.32 { d1[1]}, [r3], r9
++ vld1.32 { d2[0]}, [r10], r9
++ vld1.32 { d2[1]}, [r3], r9
++ vld1.32 { d3[0]}, [r10], r9
++ vld1.32 { d3[1]}, [r3], r9
++ vld1.32 { d4[0]}, [r10], r9
++ vld1.32 { d4[1]}, [r3], r9
++ vld1.32 { d5[0]}, [r10], r9
++ vld1.32 { d5[1]}, [r3], r9
++ vld1.32 { d6[0]}, [r10], r9
++ vld1.32 { d6[1]}, [r3], r9
++ vld1.32 { d7[0]}, [r10]
++ vld1.32 { d7[1]}, [r3]
++ vstm r0, { q0-q3 }
++1:
++ bcc 1f
++ ldr r12, [sp, #dl_size]
++ vdup.32 d16, d30[0] @ d16[0] = d30[0]
++ add lr, r0, #(pw << log2_s)
++ vld1.32 {d16[1]}, [r4], r9
++ cmp r12, #4
++ vld1.32 {d17[0]}, [r8], r9
++ vld1.32 {d17[1]}, [r4], r9
++ ble 2f
++ vld1.32 {d18[0]}, [r8], r9
++ vld1.32 {d18[1]}, [r4], r9
++ cmp r12, #12
++ vld1.32 {d19[0]}, [r8], r9
++ vld1.32 {d19[1]}, [r4], r9
++ blt 3f
++ vld1.32 {d20[0]}, [r8], r9
++ vld1.32 {d20[1]}, [r4], r9
++ vld1.32 {d21[0]}, [r8], r9
++ vld1.32 {d21[1]}, [r4], r9
++ ble 4f
++ vld1.32 {d22[0]}, [r8], r9
++ vld1.32 {d22[1]}, [r4], r9
++ vld1.32 {d23[0]}, [r8]
++ vld1.32 {d23[1]}, [r4]
++ b 5f
++2: vdup.32 q9, d17[1]
++3: vdup.32 q10, d19[1]
++4: vdup.32 q11, d21[1]
++5: vstm lr, { q8-q11}
++1:
++ eors r7, r2
++ beq 99f
++
++ lsls r12, r7, #AVAIL_S_UR_N_U_C
++ vdup.32 q0, d31[0]
++ vdup.32 q1, d31[0]
++ vdup.32 q2, d31[0]
++ vdup.32 q3, d31[0]
++ add lr, r1, #(pw << log2_s)
++ vdup.32 q8, d31[1]
++ vdup.32 q9, d31[1]
++ vdup.32 q10, d31[1]
++ vdup.32 q11, d31[1]
++ it cs
++ vstmcs r1, { q0-q3 }
++ it mi
++ vstmmi lr, { q8-q11}
++
++ lsls r7, #AVAIL_S_L_N_DL_C
++ vdup.32 q0, d30[0]
++ vdup.32 q1, d30[0]
++ vdup.32 q2, d30[0]
++ vdup.32 q3, d30[0]
++ add lr, r0, #(pw << log2_s)
++ it mi
++ vstmmi r0, { q0-q3 }
++ it cs
++ vstmcs lr, { q0-q3 }
++
++99:
++ pop {r4-r10, pc}
++endfunc
++
++
++
++
+diff --git a/libavcodec/arm/rpi_hevcpred_intra_hv_neon.S b/libavcodec/arm/rpi_hevcpred_intra_hv_neon.S
+new file mode 100644
+index 0000000000..67192e7213
+--- /dev/null
++++ b/libavcodec/arm/rpi_hevcpred_intra_hv_neon.S
+@@ -0,0 +1,911 @@
++/*
++ * Copyright (c) 2018 John Cox <jc@kynesim.co.uk> (for Raspberry Pi)
++ *
++ * This file is part of FFmpeg.
++ *
++ * FFmpeg is free software; you can redistribute it and/or
++ * modify it under the terms of the GNU Lesser General Public
++ * License as published by the Free Software Foundation; either
++ * version 2.1 of the License, or (at your option) any later version.
++ *
++ * FFmpeg is distributed in the hope that it will be useful,
++ * but WITHOUT ANY WARRANTY; without even the implied warranty of
++ * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
++ * Lesser General Public License for more details.
++ *
++ * You should have received a copy of the GNU Lesser General Public
++ * License along with FFmpeg; if not, write to the Free Software
++ * Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA
++ */
++
++/*
++ * Horizontal & Vertical special cases of angular intra pred
++ *
++ * Split out because:
++ * Vertical, at least, is relatively common
++ * Much simpler code than the general angular case
++ * Luma with size < 32 has extra filtering that doesn't happen anywhere else
++ *
++ * *** Currently luma filtering is mandatory where it occurs, but there are
++ * cases where it should be turned off (rdpcm & an extension sps flag).
++ * These don't occur in the standard conformance suite for Main Profile
++ */
++
++#include "libavutil/arm/asm.S"
++#include "neon.S"
++
++@ ff_hevc_rpi_pred_vertical_4_neon_8
++@ uint8_t *_src, [r0]
++@ const uint8_t *_top, [r1]
++@ const uint8_t *_left, [r2]
++@ ptrdiff_t stride) [r3]
++
++function ff_hevc_rpi_pred_vertical_4_neon_8, export=1
++ ldrb ip, [r2, #-1] @ Top-left
++ vld1.32 {d0[0]}, [r2 :32] @ Left
++ add r2, r0, r3
++ vld1.8 {d1[]}, [r1]
++ lsl r3, #1
++ vdup.8 d4, ip
++ vmov.i8 d2, #128
++ vhsub.u8 d4, d0, d4
++ veor d1, d2
++ vld1.32 {d0[0]}, [r1 :32] @ Top
++ vqadd.s8 d1, d4
++ vmov.i64 d3, #0xff
++ vmov d4, d0
++ veor d5, d1, d2
++ veor d1, d1, d2
++ vbit d0, d1, d3
++ vshr.u64 d5, #8
++ vst1.32 {d0[0]}, [r0], r3
++ vshr.u64 d1, #16
++ vbit d4, d5, d3
++ vshr.u64 d5, #16
++ vst1.32 {d4[0]}, [r2], r3
++ vbit d0, d1, d3
++ vst1.32 {d0[0]}, [r0]
++ vbit d4, d5, d3
++ vst1.32 {d4[0]}, [r2]
++
++ bx lr
++endfunc
++
++
++@ ff_hevc_rpi_pred_vertical_8_neon_8
++@ uint8_t *_src, [r0]
++@ const uint8_t *_top, [r1]
++@ const uint8_t *_left, [r2]
++@ ptrdiff_t stride) [r3]
++
++function ff_hevc_rpi_pred_vertical_8_neon_8, export=1
++ ldrb ip, [r2, #-1] @ Top-left
++ vld1.8 {d0}, [r2 :64] @ Left
++ vmov.i8 d1, #128
++ vld1.8 {d2[]}, [r1]
++ vld1.8 {d3}, [r1 :64] @ Top
++ vdup.8 d4, ip
++ vhsub.u8 d4, d0, d4
++ veor d2, d1
++ vmov.i64 d0, #0xff
++ mov r1, #8
++ vqadd.s8 d2, d4, d2
++ veor d1, d2, d1
++1:
++ vbit d3, d1, d0
++ vshr.u64 d1, #8
++ vst1.8 {d3}, [r0 :64], r3
++ subs r1, #2
++ vbit d3, d1, d0
++ vshr.u64 d1, #8
++ vst1.8 {d3}, [r0 :64], r3
++ bne 1b
++
++ bx lr
++endfunc
++
++
++@ ff_hevc_rpi_pred_vertical_16_neon_8
++@ uint8_t *_src, [r0]
++@ const uint8_t *_top, [r1]
++@ const uint8_t *_left, [r2]
++@ ptrdiff_t stride) [r3]
++
++function ff_hevc_rpi_pred_vertical_16_neon_8, export=1
++ ldrb ip, [r2, #-1] @ Top-left
++ vld1.8 {q0}, [r2 :128] @ Left
++ vdup.8 q1, ip
++ vld1.8 {d4[],d5[]}, [r1]
++ vhsub.u8 q0, q1
++ vmov.i8 q1, #128
++ veor q2, q1
++ vmov.i64 d16, #0xff
++ vqadd.s8 q0, q2
++ vld1.8 {q3}, [r1 :128] @ Top
++ mov r1, #16
++ veor q0, q1
++ vmov q1, q3
++ vext.8 q2, q0, q0, #1
++1:
++ vbit d2, d0, d16
++ vbit d6, d4, d16
++ vext.8 q0, q0, q0, #2
++ subs r1, #2
++ vst1.8 {q1}, [r0 :128], r3
++ vext.8 q2, q2, q2, #2
++ vst1.8 {q3}, [r0 :128], r3
++ bne 1b
++
++ bx lr
++endfunc
++
++
++@ ff_hevc_rpi_pred_vert_32_neon_8
++@ uint8_t *_src, [r0]
++@ const uint8_t *_top, [r1]
++@ const uint8_t *_left, [r2]
++@ ptrdiff_t stride) [r3]
++
++function ff_hevc_rpi_pred_vertical_32_neon_8, export=1
++ vld1.8 {q0, q1 }, [r1 :128] @ Up
++ add r2, r0, r3
++ lsl r3, #1
++ mov r1, #16
++1:
++ vst1.8 {q0, q1 }, [r0 :128], r3
++ subs r1, #1
++ vst1.8 {q0, q1 }, [r2 :128], r3
++ bne 1b
++
++ bx lr
++endfunc
++
++
++@ ff_hevc_rpi_pred_vertical_c_4_neon_8
++@ uint8_t *_src, [r0]
++@ const uint8_t *_top, [r1]
++@ const uint8_t *_left, [r2]
++@ ptrdiff_t stride) [r3]
++
++function ff_hevc_rpi_pred_vertical_c_4_neon_8, export=1
++ vld1.16 {d0 }, [r1 :64] @ Up
++ add r2, r0, r3, lsl #1
++ lsl r3, #2
++
++ vst1.16 {d0 }, [r0 :64], r3
++ vst1.16 {d0 }, [r2 :64], r3
++ vst1.16 {d0 }, [r0 :64]
++ vst1.16 {d0 }, [r2 :64]
++
++ bx lr
++endfunc
++
++
++@ ff_hevc_rpi_pred_vertical_c_8_neon_8
++@ uint8_t *_src, [r0]
++@ const uint8_t *_top, [r1]
++@ const uint8_t *_left, [r2]
++@ ptrdiff_t stride) [r3]
++
++function ff_hevc_rpi_pred_vertical_c_8_neon_8, export=1
++ vld1.16 {q0 }, [r1 :128] @ Up
++ add r2, r0, r3, lsl #1
++ lsl r3, #2
++ mov r1, #4
++1:
++ vst1.16 {q0 }, [r0 :128], r3
++ subs r1, #2
++ vst1.16 {q0 }, [r2 :128], r3
++ vst1.16 {q0 }, [r0 :128], r3
++ vst1.16 {q0 }, [r2 :128], r3
++ bne 1b
++
++ bx lr
++endfunc
++
++
++@ ff_hevc_rpi_pred_vertical_c_16_neon_8
++@ uint8_t *_src, [r0]
++@ const uint8_t *_top, [r1]
++@ const uint8_t *_left, [r2]
++@ ptrdiff_t stride) [r3]
++
++function ff_hevc_rpi_pred_vertical_c_16_neon_8, export=1
++ vld1.16 {q0, q1 }, [r1 :128] @ Up
++ add r2, r0, r3, lsl #1
++ lsl r3, #2
++ mov r1, #8
++1:
++ vst1.16 {q0, q1 }, [r0 :128], r3
++ subs r1, #1
++ vst1.16 {q0, q1 }, [r2 :128], r3
++ bne 1b
++
++ bx lr
++endfunc
++
++
++@ ff_hevc_rpi_pred_horizontalal_4_neon_8
++@ uint8_t *_src, [r0]
++@ const uint8_t *_top, [r1]
++@ const uint8_t *_left, [r2]
++@ ptrdiff_t stride) [r3]
++
++@ ? Might be faster as simple arm
++
++function ff_hevc_rpi_pred_horizontal_4_neon_8, export=1
++ ldrb ip, [r2, #-1] @ Top-left
++ vld1.32 {d0[0]}, [r1 :32] @ Top
++ add r1, r2, #3
++ vld1.8 {d1[]}, [r2]!
++ vdup.8 d2, ip
++ vmov.i8 d3, #128
++ vhsub.u8 d0, d2
++ veor d1, d3
++ vld1.8 {d2[]}, [r2]!
++ add ip, r0, r3
++ vqadd.s8 d0, d0, d1
++ lsl r3, #1
++ vld1.8 {d1[]}, [r2]
++ vld1.8 {d4[]}, [r1]
++ veor d0, d3
++ vst1.32 {d0[0]}, [r0 :32], r3
++ vst1.32 {d2[0]}, [ip :32], r3
++ vst1.32 {d1[0]}, [r0 :32]
++ vst1.32 {d4[0]}, [ip :32]
++
++ bx lr
++endfunc
++
++
++@ ff_hevc_rpi_pred_horizontal_8_neon_8
++@ uint8_t *_src, [r0]
++@ const uint8_t *_top, [r1]
++@ const uint8_t *_left, [r2]
++@ ptrdiff_t stride) [r3]
++
++function ff_hevc_rpi_pred_horizontal_8_neon_8, export=1
++ ldrb ip, [r2, #-1] @ Top-left
++ vld1.8 {d0}, [r1 :64] @ Top
++ vmov.i8 d1, #128
++ vld1.8 {d2[]}, [r2]!
++ mov r1, #8-2
++ vdup.8 d3, ip
++ vhsub.u8 d0, d3
++ veor d2, d1
++ vqadd.s8 d0, d2
++ vld1.8 {d2[]}, [r2]!
++ veor d0, d1
++ vst1.8 {d0}, [r0], r3
++1:
++ vld1.8 {d0[]}, [r2]!
++ subs r1, #2
++ vst1.8 {d2}, [r0 :64], r3
++ vld1.8 {d2[]}, [r2]!
++ vst1.8 {d0}, [r0 :64], r3
++ bne 1b
++
++ vst1.8 {d2}, [r0 :64]
++ bx lr
++endfunc
++
++
++@ ff_hevc_rpi_pred_horizontal_16_neon_8
++@ uint8_t *_src, [r0]
++@ const uint8_t *_top, [r1]
++@ const uint8_t *_left, [r2]
++@ ptrdiff_t stride) [r3]
++
++function ff_hevc_rpi_pred_horizontal_16_neon_8, export=1
++ ldrb ip, [r2, #-1] @ Top-left
++ vld1.8 {q0}, [r1 :64] @ Top
++ mov r1, #16-2
++ vld1.8 {d4[],d5[]}, [r2]!
++ vdup.8 q3, ip
++ vhsub.u8 q0, q3
++ vmov.i8 q1, #128
++ veor q2, q1
++ vqadd.s8 q0, q2
++ vld1.8 {d4[],d5[]}, [r2]!
++ veor q0, q1
++ vst1.8 {q0}, [r0], r3
++1:
++ vld1.8 {d0[],d1[]}, [r2]!
++ subs r1, #2
++ vst1.8 {q2}, [r0 :64], r3
++ vld1.8 {d4[],d5[]}, [r2]!
++ vst1.8 {q0}, [r0 :64], r3
++ bne 1b
++
++ vst1.8 {q2}, [r0 :64]
++ bx lr
++endfunc
++
++
++@ ff_hevc_rpi_pred_horizontal_32_neon_8
++@ uint8_t *_src, [r0]
++@ const uint8_t *_top, [r1]
++@ const uint8_t *_left, [r2]
++@ ptrdiff_t stride) [r3]
++
++function ff_hevc_rpi_pred_horizontal_32_neon_8, export=1
++ vld1.8 {d0[],d1[]}, [r2]!
++ add ip, r0, #16
++ mov r1, #32-2
++ vld1.8 {d2[],d3[]}, [r2]!
++ vst1.8 {q0}, [r0 :128], r3
++ vst1.8 {q0}, [ip :128], r3
++1:
++ vld1.8 {d0[],d1[]}, [r2]!
++ subs r1, #2
++ vst1.8 {q1}, [r0 :128], r3
++ vst1.8 {q1}, [ip :128], r3
++ vld1.8 {d2[],d3[]}, [r2]!
++ vst1.8 {q0}, [r0 :128], r3
++ vst1.8 {q0}, [ip :128], r3
++ bne 1b
++
++ vst1.8 {q1}, [r0 :128]
++ vst1.8 {q1}, [ip :128]
++ bx lr
++endfunc
++
++
++@ ff_hevc_rpi_pred_horizontal_c_4_neon_8
++@ uint8_t *_src, [r0]
++@ const uint8_t *_top, [r1]
++@ const uint8_t *_left, [r2]
++@ ptrdiff_t stride) [r3]
++
++function ff_hevc_rpi_pred_horizontal_c_4_neon_8, export=1
++ add r1, r2, #2
++ vld1.16 {d0[]}, [r2]
++ add r2, #4
++ vld1.16 {d1[]}, [r1]
++ add r1, #4
++ vld1.16 {d2[]}, [r2]
++A add r2, r0, r3, lsl #1
++T lsl r3, #1
++T add r2, r0, r3
++ vld1.16 {d3[]}, [r1]
++A lsl r3, #2
++T lsl r3, #1
++ vst1.16 {d0}, [r0 :64], r3
++ vst1.16 {d1}, [r2 :64], r3
++ vst1.16 {d2}, [r0 :64]
++ vst1.16 {d3}, [r2 :64]
++
++ bx lr
++endfunc
++
++
++@ ff_hevc_rpi_pred_horizontal_c_8_neon_8
++@ uint8_t *_src, [r0]
++@ const uint8_t *_top, [r1]
++@ const uint8_t *_left, [r2]
++@ ptrdiff_t stride) [r3]
++
++function ff_hevc_rpi_pred_horizontal_c_8_neon_8, export=1
++ vld1.16 {d0[],d1[]}, [r2]!
++ lsl r3, #1
++ vld1.16 {d2[],d3[]}, [r2]!
++ mov r1, #8-2
++ vst1.16 {q0}, [r0 :64], r3
++1:
++ vld1.16 {d0[],d1[]}, [r2]!
++ subs r1, #2
++ vst1.16 {q1}, [r0 :64], r3
++ vld1.16 {d2[],d3[]}, [r2]!
++ vst1.16 {q0}, [r0 :64], r3
++ bne 1b
++
++ vst1.16 {q1}, [r0 :64]
++ bx lr
++endfunc
++
++
++@ ff_hevc_rpi_pred_horizontal_c_16_neon_8
++@ uint8_t *_src, [r0]
++@ const uint8_t *_top, [r1]
++@ const uint8_t *_left, [r2]
++@ ptrdiff_t stride) [r3]
++
++function ff_hevc_rpi_pred_horizontal_c_16_neon_8, export=1
++ vld1.16 {d0[],d1[]}, [r2]!
++ lsl r3, #1
++ add ip, r0, #16
++ mov r1, #16-2
++ vld1.16 {d2[],d3[]}, [r2]!
++ vst1.16 {q0}, [r0 :128], r3
++ vst1.16 {q0}, [ip :128], r3
++1:
++ vld1.16 {d0[],d1[]}, [r2]!
++ subs r1, #2
++ vst1.16 {q1}, [r0 :128], r3
++ vst1.16 {q1}, [ip :128], r3
++ vld1.16 {d2[],d3[]}, [r2]!
++ vst1.16 {q0}, [r0 :128], r3
++ vst1.16 {q0}, [ip :128], r3
++ bne 1b
++
++ vst1.16 {q1}, [r0 :128]
++ vst1.16 {q1}, [ip :128]
++ bx lr
++endfunc
++
++
++@------------------------------------------------------------------------------
++@
++@ 10 Bit
++@ Has clipping constants so 10-bit only but could easily be macroed up to
++@ 14-bit before we run out of bits
++
++
++@ ff_hevc_rpi_pred_vertical_4_neon_10
++@ uint8_t *_src, [r0]
++@ const uint8_t *_top, [r1]
++@ const uint8_t *_left, [r2]
++@ ptrdiff_t stride) [r3]
++
++function ff_hevc_rpi_pred_vertical_4_neon_10, export=1
++ ldrh ip, [r2, #-2] @ Top-left
++ vld1.16 {d0}, [r2 :64] @ Left
++ vmov.i16 d2, #0
++ vld1.16 {d1[]}, [r1]
++T lsl r3, #1
++ vdup.16 d4, ip
++ vmov.i16 d3, #0x3ff
++ vld1.16 {d5}, [r1 :64] @ Top
++ vhsub.u16 d4, d0, d4
++ vmov.i64 d0, #0xffff
++A add r2, r0, r3, lsl #1
++T add r2, r0, r3
++ vadd.i16 d1, d1, d4
++ vmov d6, d5
++ vmax.s16 d1, d1, d2
++ vmin.s16 d2, d1, d3
++ vmin.s16 d1, d1, d3
++ vbit d5, d1, d0
++A lsl r3, #2
++T lsl r3, #1
++ vshr.u64 d2, #16
++ vshr.u64 d1, #32
++ vbit d6, d2, d0
++ vst1.16 {d5}, [r0], r3
++ vshr.u64 d2, #32
++ vst1.16 {d6}, [r2], r3
++ vbit d5, d1, d0
++ vst1.16 {d5}, [r0]
++ vbit d6, d2, d0
++ vst1.16 {d6}, [r2]
++ bx lr
++endfunc
++
++
++@ ff_hevc_rpi_pred_vertical_8_neon_10
++@ uint8_t *_src, [r0]
++@ const uint8_t *_top, [r1]
++@ const uint8_t *_left, [r2]
++@ ptrdiff_t stride) [r3]
++
++function ff_hevc_rpi_pred_vertical_8_neon_10, export=1
++ ldrh ip, [r2, #-2] @ Top-left
++ vld1.16 {q0}, [r2 :128] @ Left
++ lsl r3, #1
++ vdup.16 q1, ip
++ vld1.16 {d4[],d5[]}, [r1]
++ vhsub.u16 q0, q0, q1
++ vmov.i16 q1, #0
++ vadd.i16 q0, q2
++ vmov.i16 q2, #0x3ff
++ vld1.16 {q3}, [r1 :128] @ Top
++ mov r1, #8
++ vmax.s16 q0, q1
++ vmov q1, q3
++ vmin.s16 q0, q2
++ vmov.i64 d16, #0xffff
++ vext.16 q2, q0, q0, #1
++1:
++ vbit d2, d0, d16
++ vbit d6, d4, d16
++ vext.16 q0, q0, q0, #2
++ subs r1, #2
++ vst1.16 {q1}, [r0 :128], r3
++ vext.16 q2, q2, q2, #2
++ vst1.16 {q3}, [r0 :128], r3
++ bne 1b
++
++ bx lr
++endfunc
++
++
++@ ff_hevc_rpi_pred_vertical_16_neon_10
++@ uint8_t *_src, [r0]
++@ const uint8_t *_top, [r1]
++@ const uint8_t *_left, [r2]
++@ ptrdiff_t stride) [r3]
++
++function ff_hevc_rpi_pred_vertical_16_neon_10, export=1
++ ldrh ip, [r2, #-2] @ Top-left
++ vld1.16 {q0-q1}, [r2 :128] @ Left
++T lsl r3, #1
++ vdup.16 q2, ip
++A add r2, r0, r3, lsl #1
++T add r2, r0, r3
++ vld1.16 {d6[],d7[]}, [r1]
++A lsl r3, #2
++T lsl r3, #1
++ vhsub.u16 q0, q2
++ vhsub.u16 q1, q2
++ vadd.i16 q0, q3
++ vadd.i16 q1, q3
++ vmov.i16 q2, #0
++ vld1.16 {q8-q9}, [r1 :128] @ Top
++ mov r1, #0
++ vmov.i16 q3, #0x3ff
++ vmax.s16 q0, q2
++ vmax.s16 q1, q2
++ vmin.s16 q0, q3
++ vmin.s16 q1, q3
++ vmov q10, q8
++ vmov q11, q9
++ vext.16 q2, q0, q1, #1
++ vext.16 q3, q1, q1, #1
++ vmov.i64 d24, #0xffff
++1:
++ vbit d16, d0, d24
++ vbit d20, d4, d24
++ vext.16 q0, q0, q0, #2
++ subs r1, #1<<30
++ vst1.16 {q8-q9}, [r0 :128], r3
++ vext.16 q2, q2, q2, #2
++ vst1.16 {q10-q11}, [r2 :128], r3
++ bne 1b
++1:
++ vbit d16, d2, d24
++ vbit d20, d6, d24
++ vext.16 q1, q1, q1, #2
++ subs r1, #1<<30
++ vst1.16 {q8-q9}, [r0 :128], r3
++ vext.16 q3, q3, q3, #2
++ vst1.16 {q10-q11}, [r2 :128], r3
++ bne 1b
++
++ bx lr
++endfunc
++
++
++@ ff_hevc_rpi_pred_vertical_32_neon_10
++@ uint8_t *_src, [r0]
++@ const uint8_t *_top, [r1]
++@ const uint8_t *_left, [r2]
++@ ptrdiff_t stride) [r3]
++
++function ff_hevc_rpi_pred_vertical_32_neon_10, export=1
++ vldm r1, { q0-q3 } @ Up
++ lsl r3, #1
++ mov r1, #32
++ add r2, r0, #32
++1:
++ vst1.16 {q0-q1}, [r0 :128], r3
++ subs r1, #1
++ vst1.16 {q2-q3}, [r2 :128], r3
++ bne 1b
++
++ bx lr
++endfunc
++
++
++@ ff_hevc_rpi_pred_vertical_c_4_neon_10
++@ uint8_t *_src, [r0]
++@ const uint8_t *_top, [r1]
++@ const uint8_t *_left, [r2]
++@ ptrdiff_t stride) [r3]
++
++function ff_hevc_rpi_pred_vertical_c_4_neon_10, export=1
++ vld1.16 {q0 }, [r1 :128] @ Up
++ add r2, r0, r3, lsl #2
++ lsl r3, #3
++
++ vst1.16 {q0 }, [r0 :128], r3
++ vst1.16 {q0 }, [r2 :128], r3
++ vst1.16 {q0 }, [r0 :128]
++ vst1.16 {q0 }, [r2 :128]
++
++ bx lr
++endfunc
++
++
++@ ff_hevc_rpi_pred_vertical_c_8_neon_10
++@ uint8_t *_src, [r0]
++@ const uint8_t *_top, [r1]
++@ const uint8_t *_left, [r2]
++@ ptrdiff_t stride) [r3]
++
++function ff_hevc_rpi_pred_vertical_c_8_neon_10, export=1
++ vld1.16 {q0, q1 }, [r1 :128] @ Up
++ add r2, r0, r3, lsl #2
++ lsl r3, #3
++ mov r1, #4
++1:
++ vst1.16 {q0, q1 }, [r0 :128], r3
++ subs r1, #1
++ vst1.16 {q0, q1 }, [r2 :128], r3
++ bne 1b
++
++ bx lr
++endfunc
++
++
++@ ff_hevc_rpi_pred_vertical_c_16_neon_10
++@ uint8_t *_src, [r0]
++@ const uint8_t *_top, [r1]
++@ const uint8_t *_left, [r2]
++@ ptrdiff_t stride) [r3]
++
++function ff_hevc_rpi_pred_vertical_c_16_neon_10, export=1
++ vldm r1, { q0-q3 } @ Up
++ lsl r3, #2
++ mov r1, #16
++ add r2, r0, #32
++1:
++ vst1.16 {q0-q1}, [r0 :128], r3
++ subs r1, #1
++ vst1.16 {q2-q3}, [r2 :128], r3
++ bne 1b
++
++ bx lr
++endfunc
++
++@ ff_hevc_rpi_pred_horizontal_4_neon_10
++@ uint8_t *_src, [r0]
++@ const uint8_t *_top, [r1]
++@ const uint8_t *_left, [r2]
++@ ptrdiff_t stride) [r3]
++
++function ff_hevc_rpi_pred_horizontal_4_neon_10, export=1
++ ldrh ip, [r2, #-2] @ Top-left
++ vld1.16 {d0}, [r1 :64] @ Top
++ vmov.i16 d1, #0
++ vld1.16 {d2[]}, [r2]!
++T lsl r3, #1
++ vdup.16 d3, ip
++ vmov.i16 d4, #0x3ff
++ vhsub.u16 d0, d3
++A add ip, r0, r3, lsl #1
++T add ip, r0, r3
++ vld1.16 {d3[]}, [r2]!
++A lsl r3, #2
++T lsl r3, #1
++ vadd.i16 d0, d2
++ vld1.16 {d2[]}, [r2]!
++ vmax.s16 d0, d1
++ vld1.16 {d1[]}, [r2]
++ vmin.s16 d0, d4
++ vst1.16 {d0}, [r0 :64], r3
++ vst1.16 {d3}, [ip :64], r3
++ vst1.16 {d2}, [r0 :64]
++ vst1.16 {d1}, [ip :64]
++
++ bx lr
++endfunc
++
++
++@ ff_hevc_rpi_pred_horizontal_8_neon_10
++@ uint8_t *_src, [r0]
++@ const uint8_t *_top, [r1]
++@ const uint8_t *_left, [r2]
++@ ptrdiff_t stride) [r3]
++
++function ff_hevc_rpi_pred_horizontal_8_neon_10, export=1
++ ldrh ip, [r2, #-2] @ Top-left
++ vld1.16 {q0}, [r1 :128] @ Top
++ lsl r3, #1
++ vdup.16 q1, ip
++ mov r1, #8-2
++ vhsub.u16 q0, q1
++ vld1.16 {d2[],d3[]}, [r2]!
++ vmov.i16 q2, #0
++ vadd.i16 q0, q1
++ vmov.i16 q1, #0x3ff
++ vmax.s16 q0, q2
++ vld1.16 {d4[],d5[]}, [r2]!
++ vmin.s16 q0, q1
++ vst1.16 {q0}, [r0 :128], r3
++1:
++ vld1.16 {d0[],d1[]}, [r2]!
++ subs r1, #2
++ vst1.16 {q2}, [r0 :128], r3
++ vld1.16 {d4[],d5[]}, [r2]!
++ vst1.16 {q0}, [r0 :128], r3
++ bne 1b
++
++ vst1.16 {q2}, [r0 :128]
++ bx lr
++endfunc
++
++
++@ ff_hevc_rpi_pred_horizontalal_16_neon_10
++@ uint8_t *_src, [r0]
++@ const uint8_t *_top, [r1]
++@ const uint8_t *_left, [r2]
++@ ptrdiff_t stride) [r3]
++
++function ff_hevc_rpi_pred_horizontal_16_neon_10, export=1
++ ldrh ip, [r2, #-2] @ Top-left
++ vld1.16 {q0-q1}, [r1 :128] @ Top
++ lsl r3, #1
++ vdup.16 q2, ip
++ add ip, r0, r3
++ vhsub.u16 q0, q2
++ add ip, #16
++ vhsub.u16 q1, q2
++ mov r1, #16-2
++ vld1.16 {d4[],d5[]}, [r2]!
++ vmov.i16 q3, #0
++ vadd.u16 q0, q2
++ vadd.i16 q1, q2
++ vmov.i16 q2, #0x3ff
++ vmax.s16 q0, q3
++ vmax.s16 q1, q3
++ vld1.16 {d6[],d7[]}, [r2]!
++ vmin.s16 q0, q2
++ vmin.s16 q1, q2
++ vst1.16 {q0-q1}, [r0 :128], r3
++1:
++ vld1.16 {d0[],d1[]}, [r2]!
++ subs r1, #2
++ vst1.16 {q3}, [r0 :128], r3
++ vst1.16 {q3}, [ip :128], r3
++ vld1.16 {d6[],d7[]}, [r2]!
++ vst1.16 {q0}, [r0 :128], r3
++ vst1.16 {q0}, [ip :128], r3
++ bne 1b
++
++ vst1.16 {q3}, [r0 :128]
++ vst1.16 {q3}, [ip :128]
++ bx lr
++endfunc
++
++
++@ ff_hevc_rpi_pred_horizontal_32_neon_10
++@ uint8_t *_src, [r0]
++@ const uint8_t *_top, [r1]
++@ const uint8_t *_left, [r2]
++@ ptrdiff_t stride) [r3]
++
++function ff_hevc_rpi_pred_horizontal_32_neon_10, export=1
++ vld1.16 {d0[],d1[]}, [r2]!
++ add ip, r0, #16
++ push {lr}
++ mov lr, #32
++ vld1.16 {d2[],d3[]}, [r2]!
++ lsl r3, #1
++ vst1.16 {q0}, [r0 :128], lr
++ sub r3, #32
++ vst1.16 {q0}, [ip :128], lr
++ mov r1, #32-2
++ vst1.16 {q0}, [r0 :128], r3
++ vst1.16 {q0}, [ip :128], r3
++1:
++ vld1.16 {d0[],d1[]}, [r2]!
++ subs r1, #2
++ vst1.16 {q1}, [r0 :128], lr
++ vst1.16 {q1}, [ip :128], lr
++ vst1.16 {q1}, [r0 :128], r3
++ vst1.16 {q1}, [ip :128], r3
++ vld1.16 {d2[],d3[]}, [r2]!
++ vst1.16 {q0}, [r0 :128], lr
++ vst1.16 {q0}, [ip :128], lr
++ vst1.16 {q0}, [r0 :128], r3
++ vst1.16 {q0}, [ip :128], r3
++ bne 1b
++
++ vst1.16 {q1}, [r0 :128], lr
++ vst1.16 {q1}, [ip :128], lr
++ vst1.16 {q1}, [r0 :128]
++ vst1.16 {q1}, [ip :128]
++ pop {pc}
++endfunc
++
++
++@ ff_hevc_rpi_pred_horizontal_c_4_neon_10
++@ uint8_t *_src, [r0]
++@ const uint8_t *_top, [r1]
++@ const uint8_t *_left, [r2]
++@ ptrdiff_t stride) [r3]
++
++function ff_hevc_rpi_pred_horizontal_c_4_neon_10, export=1
++ add r1, r2, #4
++ vld1.32 {d0[],d1[]}, [r2]
++ add r2, #8
++ vld1.32 {d2[],d3[]}, [r1]
++ add r1, #8
++ vld1.32 {d4[],d5[]}, [r2]
++A add r2, r0, r3, lsl #2
++T lsl r3, #2
++T add r2, r0, r3
++ vld1.32 {d6[],d7[]}, [r1]
++A lsl r3, #3
++T lsl r3, #1
++ vst1.32 {q0}, [r0 :128], r3
++ vst1.32 {q1}, [r2 :128], r3
++ vst1.32 {q2}, [r0 :128]
++ vst1.32 {q3}, [r2 :128]
++
++ bx lr
++endfunc
++
++
++@ ff_hevc_rpi_pred_horizontal_c_8_neon_10
++@ uint8_t *_src, [r0]
++@ const uint8_t *_top, [r1]
++@ const uint8_t *_left, [r2]
++@ ptrdiff_t stride) [r3]
++
++function ff_hevc_rpi_pred_horizontal_c_8_neon_10, export=1
++ vld1.32 {d0[],d1[]}, [r2]!
++ lsl r3, #2
++ add ip, r0, #16
++ mov r1, #8-2
++ vld1.32 {d2[],d3[]}, [r2]!
++ vst1.32 {q0}, [r0 :128], r3
++ vst1.32 {q0}, [ip :128], r3
++1:
++ vld1.32 {d0[],d1[]}, [r2]!
++ subs r1, #2
++ vst1.32 {q1}, [r0 :128], r3
++ vst1.32 {q1}, [ip :128], r3
++ vld1.32 {d2[],d3[]}, [r2]!
++ vst1.32 {q0}, [r0 :128], r3
++ vst1.32 {q0}, [ip :128], r3
++ bne 1b
++
++ vst1.32 {q1}, [r0 :128]
++ vst1.32 {q1}, [ip :128]
++ bx lr
++endfunc
++
++
++@ ff_hevc_rpi_pred_horizontal_c_16_neon_10
++@ uint8_t *_src, [r0]
++@ const uint8_t *_top, [r1]
++@ const uint8_t *_left, [r2]
++@ ptrdiff_t stride) [r3]
++
++function ff_hevc_rpi_pred_horizontal_c_16_neon_10, export=1
++ vld1.32 {d0[],d1[]}, [r2]!
++ add ip, r0, #16
++ push {lr}
++ mov lr, #32
++ vld1.32 {d2[],d3[]}, [r2]!
++ lsl r3, #2
++ vst1.32 {q0}, [r0 :128], lr
++ sub r3, #32
++ vst1.32 {q0}, [ip :128], lr
++ mov r1, #16-2
++ vst1.32 {q0}, [r0 :128], r3
++ vst1.32 {q0}, [ip :128], r3
++1:
++ vld1.32 {d0[],d1[]}, [r2]!
++ subs r1, #2
++ vst1.32 {q1}, [r0 :128], lr
++ vst1.32 {q1}, [ip :128], lr
++ vst1.32 {q1}, [r0 :128], r3
++ vst1.32 {q1}, [ip :128], r3
++ vld1.32 {d2[],d3[]}, [r2]!
++ vst1.32 {q0}, [r0 :128], lr
++ vst1.32 {q0}, [ip :128], lr
++ vst1.32 {q0}, [r0 :128], r3
++ vst1.32 {q0}, [ip :128], r3
++ bne 1b
++
++ vst1.32 {q1}, [r0 :128], lr
++ vst1.32 {q1}, [ip :128], lr
++ vst1.32 {q1}, [r0 :128]
++ vst1.32 {q1}, [ip :128]
++ pop {pc}
++endfunc
++
++
++
+diff --git a/libavcodec/arm/rpi_hevcpred_intra_planar_neon.S b/libavcodec/arm/rpi_hevcpred_intra_planar_neon.S
+new file mode 100644
+index 0000000000..e35896a102
+--- /dev/null
++++ b/libavcodec/arm/rpi_hevcpred_intra_planar_neon.S
+@@ -0,0 +1,1034 @@
++/*
++ * Copyright (c) 2017 John Cox <jc@kynesim.co.uk> (for Raspberry Pi)
++ *
++ * This file is part of FFmpeg.
++ *
++ * FFmpeg is free software; you can redistribute it and/or
++ * modify it under the terms of the GNU Lesser General Public
++ * License as published by the Free Software Foundation; either
++ * version 2.1 of the License, or (at your option) any later version.
++ *
++ * FFmpeg is distributed in the hope that it will be useful,
++ * but WITHOUT ANY WARRANTY; without even the implied warranty of
++ * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
++ * Lesser General Public License for more details.
++ *
++ * You should have received a copy of the GNU Lesser General Public
++ * License along with FFmpeg; if not, write to the Free Software
++ * Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA
++ */
++
++#include "libavutil/arm/asm.S"
++#include "neon.S"
++
++@ Planar intra pred (8.4.4.2.4)
++@
++@ predSamples[ x ][ y ] =
++@ ( ( nTbS - 1 - x ) * p[ -1 ][ y ] +
++@ ( x + 1 ) * p[ nTbS ][ -1 ] +
++@ ( nTbS - 1 - y ) * p[ x ][ -1 ] +
++@ ( y + 1 ) * p[ -1 ][ nTbS ] + nTbS ) >> ( Log2( nTbS ) + 1 )
++
++@ All 10-bit functions would work with 9
++
++
++@ ff_hevc_rpi_pred_planar_8_neon_8
++@ uint8_t *_src, [r0]
++@ const uint8_t *_top, [r1]
++@ const uint8_t *_left, [r2]
++@ ptrdiff_t stride) [r3]
++
++function ff_hevc_rpi_pred_planar_4_neon_8, export=1
++
++ vld1.8 {d0}, [r1] @ Top
++ adr ip, nb_3_0_1_4
++ vld1.8 {d1}, [r2] @ Left
++ vmov.i64 d2, #0xffffffff
++ vldr d3, [ip, #8] @ {1,2,3,4,1,2,3,4}
++ add r1, r0, r3
++ vdup.32 d4, d0[0] @ {t0,t1,t2,t3,t0,t1,t2,t3}
++ vdup.8 d0, d0[4] @ {t4,t4,t4,t4,t4,t4,t4,t4}
++ vdup.8 d5, d1[4] @ {l4,l4,l4,l4,l4,l4,l4,l4}
++ vdup.8 d6, d1[0] @ {l0,l0,l0,l0,l0,l0,l0,l0}
++ vshll.u8 q8, d4, #2
++ lsl r3, #1
++ vsubl.u8 q2, d5, d4
++ vmlal.u8 q8, d0, d3
++ vld1.8 {d0}, [ip] @ {3,2,1,0,3,2,1,0}
++ vdup.8 d7, d1[1] @ {l1,l1,l1,l1,l1,l1,l1,l1}
++ vshl.s16 q9, q2, #1
++ vbif d6, d7, d2 @ {l0,l0,l0,l0,l1,l1,l1,l1}
++ vadd.i16 d16, d4
++ vdup.8 d7, d1[2] @ {l2,l2,l2,l2,l2,l2,l2,l2}
++ vadd.i16 d17, d18
++ vdup.8 d1, d1[3] @ {l3,l3,l3,l3,l3,l3,l3,l3}
++ vadd.i16 q2, q8, q9
++ vmlal.u8 q8, d0, d6
++ vbif d7, d1, d2 @ {l2,l2,l2,l2,l3,l3,l3,l3}
++ vmlal.u8 q2, d0, d7
++ vrshrn.i16 d0, q8, #3
++ vst1.32 d0[0], [r0 :32], r3
++ vst1.32 d0[1], [r1 :32], r3
++ vrshrn.i16 d0, q2, #3
++ vst1.32 d0[0], [r0 :32]
++ vst1.32 d0[1], [r1 :32]
++
++ bx lr
++endfunc
++
++
++@ ff_hevc_rpi_pred_planar_4_neon_10
++@ uint8_t *_src, [r0]
++@ const uint8_t *_top, [r1]
++@ const uint8_t *_left, [r2]
++@ ptrdiff_t stride) [r3]
++
++function ff_hevc_rpi_pred_planar_4_neon_10, export=1
++ @ Load from bytes & expand later - at the very least this uses less
++ @ memory than having a short table
++ vld1.16 {q0}, [r1 :64] @ Top
++ adr ip, nbh_3_0_1_4
++ vldr d2, [r2, #8] @ Left (lower)
++ vldr d3, [ip, #8] @ {1,2,3,4}
++T lsl r3, #1
++ vshl.s16 d4, d0, #2
++ vdup.16 d1, d1[0] @ {t4,t4,t4,t4}
++ vldr d5, [r2] @ Left (upper)
++ vdup.16 d2, d2[0] @ {l4,l4,l4,l4}
++ vldr d6, [ip] @ {3,2,1,0}
++ vmla.i16 d4, d3, d1 @ Acc set up
++ vsub.i16 d0, d2, d0 @ Add set up
++ vmov d7, d6
++ vdup.16 d2, d5[0]
++ vdup.16 d3, d5[1]
++ vdup.16 d16, d5[2]
++ vadd.i16 d18, d0, d4
++ vshl.s16 d0, #1 @ x2
++ vadd.i16 d19, d0, d4
++ vdup.16 d17, d5[3]
++ vadd.i16 d4, d0, d18
++A add r1, r0, r3, lsl #1
++T add r1, r0, r3
++ vadd.i16 d5, d0, d19
++A lsl r3, #2
++T lsl r3, #1
++ vmla.i16 q9, q1, q3
++ vmla.i16 q2, q8, q3
++ vrshr.u16 q0, q9, #3
++ vst1.16 {d0}, [r0], r3
++ vrshr.u16 d2, d4, #3
++ vst1.16 {d1}, [r1], r3
++ vrshr.u16 d3, d5, #3
++ vst1.16 {d2}, [r0]
++ vst1.16 {d3}, [r1]
++
++ bx lr
++endfunc
++
++
++@ ff_hevc_rpi_pred_planar_8_neon_8
++@ uint8_t *_src, [r0]
++@ const uint8_t *_top, [r1]
++@ const uint8_t *_left, [r2]
++@ ptrdiff_t stride) [r3]
++
++function ff_hevc_rpi_pred_planar_8_neon_8, export=1
++
++ vld1.8 {q0}, [r1] @ Top
++ adr ip, nb_7_0_1_8
++ vldr d2, [r2, #8] @ Left (lower)
++ mov r1, #8
++ vldr d3, [ip, #8] @ {1,2,3,4,5,6,7,8}
++ vshll.u8 q2, d0, #3
++ vdup.8 d1, d1[0] @ {t8,t8,t8,t8,t8,t8,t8,t8}
++ vdup.8 d2, d2[0] @ {l8,l8,l8,l8,l8,l8,l8,l8}
++ vldr d6, [r2] @ Left (upper)
++ vmlal.u8 q2, d3, d1
++ vsubl.u8 q0, d2, d0
++ vldr d7, [ip] @ {7,6,5,4,3,2,1,0}
++
++@ u8 7..0 [1] d7
++@ u8 left[y] [1] d6
++@ u16 acc [2] q2 (even rows) or q8 (odd rows) = (x+1)*p[nTbS][-1] + 32*p[x][-1] initially
++@ u16 add [2] q0 = p[-1][nTbs] - p[x][-1]
++
++ vdup.8 d2, d6[0]
++ vadd.i16 q2, q0
++ vdup.8 d3, d6[1]
++ vadd.i16 q8, q2, q0
++1:
++ vmlal.u8 q2, d7, d2
++ subs r1, #2
++ vadd.i16 q9, q8, q0
++ vmlal.u8 q8, d7, d3
++ vdup.8 d2, d6[2]
++ vdup.8 d3, d6[3]
++ vrshrn.i16 d20, q2, #4
++ vshr.u64 d6, #16
++ vmov q2, q9
++ vst1.8 {d20}, [r0], r3
++ vrshrn.i16 d20, q8, #4
++ vadd.i16 q8, q2, q0
++ vst1.8 {d20}, [r0], r3
++ bne 1b
++
++ bx lr
++
++endfunc
++
++
++@ ff_hevc_rpi_pred_planar_8_neon_10
++@ uint8_t *_src, [r0]
++@ const uint8_t *_top, [r1]
++@ const uint8_t *_left, [r2]
++@ ptrdiff_t stride) [r3]
++
++function ff_hevc_rpi_pred_planar_8_neon_10, export=1
++
++ adr ip, nb_7_0_1_8
++ vld1.16 {q0}, [r1 :128]! @ Top (left)
++ lsl r3, #1
++ vld1.16 {q1}, [ip :128] @ {7,6,5,4,3,2,1,0,1,2,3,4,5,6,7,8}
++ add ip, r2, #16
++ vld1.16 {d4[],d5[]}, [r1] @ Top (right)
++ mov r1, #8-2
++ vshl.s16 q3, q0, #3
++ vmovl.u8 q8, d3 @ {1,2,3,4,5,6,7,8}
++ vld1.16 {d18[],d19[]}, [ip] @ Left (lower)
++ vmla.i16 q3, q8, q2 @ Acc set up
++ vsub.i16 q0, q9, q0 @ Add set up
++ vmovl.u8 q1, d2 @ {7,6,5,4,3,2,1,0}
++ vadd.i16 q2, q3, q0
++
++@ u16 7..0 [1] q1
++@ u32 left[y] [1] [r2]
++@ u16 acc [1] q3 = (x+1)*p[nTbS][-1] + 32*p[x][-1] initially
++@ u16 add [1] q0 = p[-1][nTbs] - p[x][-1]
++
++ vld1.16 {d6[],d7[]}, [r2]!
++ vadd.i16 q8, q2, q0
++ vld1.16 {d18[],d19[]}, [r2]!
++ vmla.i16 q2, q1, q3
++ vadd.i16 q3, q8, q0
++ vmla.i16 q8, q1, q9
++1:
++ vrshr.u16 q9, q2, #4
++ subs r1, #2
++ vmov q2, q3
++ vrshr.u16 q10, q8, #4
++ vld1.16 {d6[],d7[]}, [r2]!
++ vst1.16 {q9}, [r0 :128], r3
++ vadd.i16 q8, q2, q0
++ vld1.16 {d18[],d19[]}, [r2]!
++ vmla.i16 q2, q1, q3
++ vadd.i16 q3, q8, q0
++ vmla.i16 q8, q1, q9
++ vst1.16 {q10}, [r0 :128], r3
++ bne 1b
++
++ vrshr.u16 q9, q2, #4
++ add r3, r0
++ vrshr.u16 q10, q8, #4
++ vst1.16 {q9}, [r0 :128]
++ vst1.16 {q10}, [r3 :128]
++
++ bx lr
++endfunc
++
++
++@------------------------------------------------------------------------------
++@
++@ Data - has to be in two lumps to ensure we can always reach using adr
++
++ .balign 64
++
++nb_31_0_1_32:
++ .byte 31, 30, 29, 28, 27, 26, 25, 24
++ .byte 23, 22, 21, 20, 19, 18, 17, 16
++nb_15_0_1_16:
++ .byte 15, 14, 13, 12, 11, 10, 9, 8
++ .byte 7, 6, 5, 4, 3, 2, 1, 0
++ .byte 1, 2, 3, 4, 5, 6, 7, 8
++ .byte 9, 10, 11, 12, 13, 14, 15, 16
++ .byte 17, 18, 19, 20, 21, 22, 23, 24
++ .byte 25, 26, 27, 28, 29, 30, 31, 32
++
++ @ should be back on a 64-byte boundary here
++
++ @ These could be extracted from the above array, but separate out
++ @ out for better (16 byte) alignment
++nb_3_0_1_4:
++ .byte 3, 2, 1, 0, 3, 2, 1, 0
++ .byte 1, 2, 3, 4, 1, 2, 3, 4
++nb_7_0_1_8:
++ .byte 7, 6, 5, 4, 3, 2, 1, 0
++ .byte 1, 2, 3, 4, 5, 6, 7, 8
++nbh_3_0_1_4:
++ .short 3, 2, 1, 0, 1, 2, 3, 4
++
++@------------------------------------------------------------------------------
++
++
++@ ff_hevc_rpi_pred_planar_16_neon_8
++@ uint8_t *_src, [r0]
++@ const uint8_t *_top, [r1]
++@ const uint8_t *_left, [r2]
++@ ptrdiff_t stride) [r3]
++
++function ff_hevc_rpi_pred_planar_16_neon_8, export=1
++
++ adr ip, nb_15_0_1_16 + 16
++ vld1.8 {q0}, [r1 :128]! @ Top (left)
++ add r2, #16
++ vld1.8 {q1}, [ip: 128] @ {1,2,3...16}
++ vld1.8 {d4[]}, [r1] @ Top (right)
++ sub ip, #16
++ vshll.u8 q3, d0, #4
++ mov r1, #16
++ vshll.u8 q8, d1, #4
++ vld1.8 {d5[]}, [r2] @ Left (lower)
++ sub r2, #16
++ vmlal.u8 q3, d2, d4
++ vmlal.u8 q8, d3, d4 @ Acc set up
++ vsubl.u8 q1, d5, d0
++ vsubl.u8 q0, d5, d1 @ Add set up
++ vld1.8 {q2}, [ip :128] @ {15,14,13...0}
++
++@ u8 15..0 [1] q2
++@ u8 left[y] [1] [r2]
++@ u16 acc [2] q3,q8 = (x+1)*p[nTbS][-1] + 32*p[x][-1] initially
++@ u16 add [2] q1,q0 = p[-1][nTbs] - p[x][-1]
++
++ vadd.i16 q3, q1
++ vadd.i16 q8, q0
++1:
++ vadd.i16 q10, q3, q1
++ subs r1, #2
++ vld1.8 {d18[]}, [r2]!
++ vadd.i16 q11, q8, q0
++ vld1.8 {d19[]}, [r2]!
++ vmlal.u8 q3, d4, d18
++ vmlal.u8 q8, d5, d18
++ vadd.i16 q12, q10, q1
++ vmlal.u8 q10, d4, d19
++ vadd.i16 q13, q11, q0
++ vmlal.u8 q11, d5, d19
++ vrshrn.u16 d18, q3, #5
++ vrshrn.u16 d19, q8, #5
++ vmov q3, q12
++ vst1.8 {q9}, [r0 :128], r3
++ vrshrn.u16 d18, q10, #5
++ vrshrn.u16 d19, q11, #5
++ vmov q8, q13
++ vst1.8 {q9}, [r0 :128], r3
++ bne 1b
++
++ bx lr
++
++endfunc
++
++
++@ ff_hevc_rpi_pred_planar_16_neon_10
++@ uint8_t *_src, [r0]
++@ const uint8_t *_top, [r1]
++@ const uint8_t *_left, [r2]
++@ ptrdiff_t stride) [r3]
++
++function ff_hevc_rpi_pred_planar_16_neon_10, export=1
++
++ @ Load from bytes & expand later - at the very least this uses less
++ @ memory than having a short table
++ adr ip, nb_15_0_1_16 + 16
++ vld1.16 {q0-q1}, [r1 :128]! @ Top (left)
++ add r2, #32
++ vld1.8 {q2}, [ip :128] @ {1,2,3...16}
++ lsl r3, #1
++ vld1.16 {d6[],d7[]}, [r1] @ Top (right)
++ sub ip, #16
++ vmovl.u8 q8, d4
++ mov r1, #16
++ vshl.i16 q9, q0, #4
++ vmovl.u8 q2, d5
++ vshl.i16 q10, q1, #4
++ vld1.16 {d22[],d23[]}, [r2] @ Left (lower)
++ sub r2, #32
++ vld1.8 {q12}, [ip] @ {15,14,13...0}
++ vmla.i16 q9, q8, q3
++ vmla.i16 q10, q2, q3 @ Acc set up
++ vsub.i16 q0, q11, q0
++ vsub.i16 q1, q11, q1 @ Add set up
++ vadd.i16 q2, q9, q0
++ vadd.i16 q3, q10, q1
++ vmovl.u8 q8, d24
++ vmovl.u8 q9, d25
++
++@ u16 15..0 [2] q8,q9
++@ u32 left[y] [2] [r2]
++@ u16 acc [2] q2,q3 = (x+1)*p[nTbS][-1] + 32*p[x][-1] initially
++@ u16 add [2] q0,q1 = p[-1][nTbs] - p[x][-1]
++
++1:
++ vadd.i16 q10, q2, q0
++ subs r1, #2
++ vld1.16 {d24[],d25[]}, [r2]!
++ vadd.i16 q11, q3, q1
++ vld1.16 {d28[],d29[]}, [r2]!
++ vmla.i16 q2, q8, q12
++ vmla.i16 q3, q9, q12
++ vadd.i16 q12, q10, q0
++ vmla.i16 q10, q8, q14
++ vadd.i16 q13, q11, q1
++ vmla.i16 q11, q9, q14
++ vrshr.u16 q14, q2, #5
++ vrshr.u16 q15, q3, #5
++ vmov q2, q12
++ vst1.16 {q14-q15}, [r0 :128], r3
++ vrshr.u16 q14, q10, #5
++ vrshr.u16 q15, q11, #5
++ vmov q3, q13
++ vst1.16 {q14-q15}, [r0 :128], r3
++ bne 1b
++
++ bx lr
++endfunc
++
++
++@ ff_hevc_rpi_pred_planar_32_neon_8
++@ uint8_t *_src, [r0]
++@ const uint8_t *_top, [r1]
++@ const uint8_t *_left, [r2]
++@ ptrdiff_t stride) [r3]
++
++function ff_hevc_rpi_pred_planar_32_neon_8, export=1
++
++ vld1.8 {q0-q1}, [r1 :128]! @ Top (left)
++ adr ip, nb_31_0_1_32 + 32
++ vpush {d8-d12}
++ vld1.8 {q2-q3}, [ip :128] @ {1,2,3...32}
++ add r2, #32
++ vld1.8 {d8[]}, [r1] @ Top (right)
++ sub ip, #32
++ vshll.u8 q8, d0, #5
++ mov r1, #32
++ vld1.8 {d9[]}, [r2] @ Left (lower)
++ sub r2, #32
++ vshll.u8 q9, d1, #5
++ vshll.u8 q10, d2, #5
++ vshll.u8 q11, d3, #5
++ vmlal.u8 q8, d4, d8
++ vsubl.u8 q12, d9, d0
++ vmlal.u8 q9, d5, d8
++ vsubl.u8 q13, d9, d1
++ vmlal.u8 q10, d6, d8
++ vsubl.u8 q14, d9, d2
++ vmlal.u8 q11, d7, d8 @ Acc set up
++ vsubl.u8 q15, d9, d3 @ Add set up
++ vadd.i16 q8, q12
++ vadd.i16 q9, q13
++ vadd.i16 q10, q14
++ vadd.i16 q11, q15
++ vld1.8 {q4-q5}, [ip :128] @ {31,30,29...0}
++
++@ u8 31..0 [2] q4,q5
++@ u8 left[y] [2] [r2]
++@ u16 acc [4] q8-q11 = (x+1)*p[nTbS][-1] + 32*p[x][-1] initially
++@ u16 add [4] q12-q15 = p[-1][nTbs] - p[x][-1]
++
++ vld1.8 {d12[]}, [r2]!
++ vadd.i16 q0, q8, q12
++ b 2f
++1:
++ vld1.8 {d12[]}, [r2]!
++ vrshrn.u16 d3, q1, #6
++ vrshrn.u16 d2, q0, #6
++ vadd.i16 q0, q8, q12
++ vrshrn.u16 d4, q2, #6
++ vrshrn.u16 d5, q3, #6
++ vst1.8 {q1-q2}, [r0 :128], r3
++2: vadd.i16 q1, q9, q13
++ subs r1, #2
++ vadd.i16 q2, q10, q14
++ vadd.i16 q3, q11, q15
++ vmlal.u8 q8, d8, d12
++ vmlal.u8 q9, d9, d12
++ vmlal.u8 q10, d10, d12
++ vmlal.u8 q11, d11, d12
++ vld1.8 {d12[]}, [r2]!
++ vrshrn.u16 d19, q9, #6
++ vrshrn.u16 d18, q8, #6
++ vadd.i16 q8, q0, q12
++ vrshrn.u16 d20, q10, #6
++ vrshrn.u16 d21, q11, #6
++ vst1.8 {q9-q10}, [r0 :128], r3
++ vadd.i16 q9, q1, q13
++ vadd.i16 q10, q2, q14
++ vadd.i16 q11, q3, q15
++ vmlal.u8 q0, d8, d12
++ vmlal.u8 q1, d9, d12
++ vmlal.u8 q2, d10, d12
++ vmlal.u8 q3, d11, d12
++
++ bne 1b
++
++ vpop {d8-d12}
++
++ vrshrn.u16 d3, q1, #6
++ vrshrn.u16 d2, q0, #6
++ vrshrn.u16 d4, q2, #6
++ vrshrn.u16 d5, q3, #6
++ vst1.8 {q1-q2}, [r0 :128]
++
++ bx lr
++
++endfunc
++
++
++@ ff_hevc_rpi_pred_planar_32_neon_10
++@ uint8_t *_src, [r0]
++@ const uint8_t *_top, [r1]
++@ const uint8_t *_left, [r2]
++@ ptrdiff_t stride) [r3]
++
++function ff_hevc_rpi_pred_planar_32_neon_10, export=1
++
++ @ Load from bytes & expand later - at the very least this uses less
++ @ memory than having a short table
++ vld1.16 {q0-q1}, [r1 :128]! @ Top (left)
++ adr ip, nb_31_0_1_32 + 32
++ vpush {q4-q7}
++ vld1.16 {q2-q3}, [r1 :128]! @ Top (centre)
++ add r2, #64
++ vld1.8 {q14-q15}, [ip :128] @ {1,2,3...32}
++T lsl r3, #1
++ vld1.16 {d8[],d9[]}, [r1] @ Top (right)
++ sub ip, #32
++ vmovl.u8 q12, d28
++ mov r1, #32
++ vmovl.u8 q13, d29
++ vld1.8 {q6-q7}, [ip :128] @ {31,30,29...0}
++ vmovl.u8 q14, d30
++ vmovl.u8 q15, d31
++ vld1.16 {d10[],d11[]}, [r2] @ Left (lower)
++ sub r2, #64
++ vshl.i16 q8, q0, #5
++ vshl.i16 q9, q1, #5
++ vshl.i16 q10, q2, #5
++ vshl.i16 q11, q3, #5
++ vmla.i16 q8, q12, q4
++ vsub.i16 q0, q5, q0
++ vmla.i16 q9, q13, q4
++ vsub.i16 q1, q5, q1
++ vmla.i16 q10, q14, q4
++ vmov.u16 ip, d0[0]
++ vsub.i16 q2, q5, q2
++ vmla.i16 q11, q15, q4 @ Acc set up
++ vsub.i16 q3, q5, q3 @ Add set up
++ vadd.i16 q8, q0
++ vadd.i16 q9, q1
++ vadd.i16 q10, q2
++ vadd.i16 q11, q3
++ vmovl.u8 q4, d12
++ vmovl.u8 q5, d13
++ vmovl.u8 q6, d14
++ vmovl.u8 q7, d15
++
++@ u16 31..0 [4] q4-q7
++@ u16 left[y] [4] [r2]
++@ u16 acc [4] q8-q11 = (x+1)*p[nTbS][-1] + 32*p[x][-1] initially
++@ u16 add [4] q0-q3 = p[-1][nTbs] - p[x][-1]
++
++ vadd.i16 q12, q8, q0
++A sub r0, r0, r3, lsl #1
++T sub r0, r3
++1:
++ vld1.16 {d0[0]}, [r2]!
++A add r0, r0, r3, lsl #1
++T add r0, r3
++ vadd.i16 q13, q9, q1
++ subs r1, #2
++ vadd.i16 q14, q10, q2
++ vadd.i16 q15, q11, q3
++ vmla.i16 q8, q4, d0[0]
++ vmla.i16 q9, q5, d0[0]
++ vmla.i16 q10, q6, d0[0]
++ vmla.i16 q11, q7, d0[0]
++ vmov.16 d0[0], ip
++ vrshr.u16 q8, #6
++ vrshr.u16 q9, #6
++ vrshr.u16 q10, #6
++ vrshr.u16 q11, #6
++ vstm r0, {q8-q11}
++ vadd.i16 q8, q12, q0
++A add r0, r0, r3, lsl #1
++T add r0, r3
++ vld1.16 {d0[0]}, [r2]!
++ vadd.i16 q9, q13, q1
++ vadd.i16 q10, q14, q2
++ vadd.i16 q11, q15, q3
++ vmla.i16 q12, q4, d0[0]
++ vmla.i16 q13, q5, d0[0]
++ vmla.i16 q14, q6, d0[0]
++ vmla.i16 q15, q7, d0[0]
++ vmov.16 d0[0], ip
++ vrshr.u16 q12, #6
++ vrshr.u16 q13, #6
++ vrshr.u16 q14, #6
++ vrshr.u16 q15, #6
++ vstm r0, {q12-q15}
++ vadd.i16 q12, q8, q0
++ bne 1b
++
++ vpop {q4-q7}
++ bx lr
++
++endfunc
++
++
++@ ff_hevc_rpi_pred_planar_c_4_neon_8
++@ uint8_t *_src, [r0]
++@ const uint8_t *_top, [r1]
++@ const uint8_t *_left, [r2]
++@ ptrdiff_t stride) [r3]
++
++function ff_hevc_rpi_pred_planar_c_4_neon_8, export=1
++
++ vld1.8 {q0}, [r1] @ Top
++ adr ip, nbx2_3_0_1_4
++ vldr d2, [r2, #8] @ Left (lower)
++ mov r1, #4
++ vldr d3, [ip, #8] @ {1,1,2,2,3,3,4,4}
++ lsl r3, #1
++ vshll.u8 q2, d0, #2
++ vdup.16 d1, d1[0] @ {t4,t4,t4,t4,t4,t4,t4,t4}
++ vdup.16 d2, d2[0] @ {l4,l4,l4,l4,l4,l4,l4,l4}
++ vldr d6, [r2] @ Left (upper)
++ vmlal.u8 q2, d3, d1
++ vsubl.u8 q0, d2, d0
++ vldr d7, [ip] @ {3,3,2,2,1,1,0,0}
++
++@ u8 3..0 [1] d7
++@ u8 left[y] [1] d6
++@ u16 acc [2] q2 (even rows) or q8 (odd rows) = (x+1)*p[nTbS][-1] + 32*p[x][-1] initially
++@ u16 add [2] q0 = p[-1][nTbs] - p[x][-1]
++
++ vdup.16 d2, d6[0]
++ vadd.i16 q2, q0
++ vdup.16 d3, d6[1]
++ vadd.i16 q8, q2, q0
++1:
++ vmlal.u8 q2, d7, d2
++ subs r1, #2
++ vadd.i16 q9, q8, q0
++ vmlal.u8 q8, d7, d3
++ vdup.16 d2, d6[2]
++ vdup.16 d3, d6[3]
++ vrshrn.i16 d20, q2, #3
++ vmov q2, q9
++ vst1.8 {d20}, [r0], r3
++ vrshrn.i16 d20, q8, #3
++ vadd.i16 q8, q2, q0
++ vst1.8 {d20}, [r0], r3
++ bne 1b
++
++ bx lr
++
++endfunc
++
++
++@ ff_hevc_rpi_pred_planar_c_4_neon_10
++@ uint8_t *_src, [r0]
++@ const uint8_t *_top, [r1]
++@ const uint8_t *_left, [r2]
++@ ptrdiff_t stride) [r3]
++
++function ff_hevc_rpi_pred_planar_c_4_neon_10, export=1
++
++ adr ip, nbx2_3_0_1_4
++ vld1.16 {q0}, [r1 :128]! @ Top (left)
++ lsl r3, #2
++ vld1.16 {q1}, [ip :128] @ {3,3,2,2,1,1,0,0,1,1,2,2,3,3,4,4}
++ add ip, r2, #16
++ vld1.32 {d4[],d5[]}, [r1] @ Top (right)
++ vshl.s16 q3, q0, #2
++ vmovl.u8 q8, d3 @ {1,1,2,2,3,3,4,4}
++ vld1.32 {d18[],d19[]}, [ip] @ Left (lower)
++ vmla.i16 q3, q8, q2 @ Acc set up
++ vsub.i16 q0, q9, q0 @ Add set up
++ vmovl.u8 q1, d2 @ {3,3,2,2,1,1,0,0}
++ vadd.i16 q2, q3, q0
++
++@ u16 3..0 [1] q1
++@ u32 left[y] [1] [r2]
++@ u16 acc [1] q3 = (x+1)*p[nTbS][-1] + 32*p[x][-1] initially
++@ u16 add [1] q0 = p[-1][nTbs] - p[x][-1]
++
++ vld1.32 {d6[],d7[]}, [r2]!
++ vadd.i16 q8, q2, q0
++ vld1.32 {d18[],d19[]}, [r2]!
++ vmla.i16 q2, q1, q3
++ vadd.i16 q3, q8, q0
++ vmla.i16 q8, q1, q9
++
++ vrshr.u16 q9, q2, #3
++ vmov q2, q3
++ vrshr.u16 q10, q8, #3
++ vld1.32 {d6[],d7[]}, [r2]!
++ vst1.16 {q9}, [r0 :128], r3
++ vadd.i16 q8, q2, q0
++ vld1.32 {d18[],d19[]}, [r2]!
++ vmla.i16 q2, q1, q3
++ vadd.i16 q3, q8, q0
++ vmla.i16 q8, q1, q9
++ vst1.16 {q10}, [r0 :128], r3
++
++ vrshr.u16 q9, q2, #3
++ add r3, r0
++ vrshr.u16 q10, q8, #3
++ vst1.16 {q9}, [r0 :128]
++ vst1.16 {q10}, [r3 :128]
++
++ bx lr
++endfunc
++
++
++@ ff_hevc_rpi_pred_planar_c_8_neon_8
++@ uint8_t *_src, [r0]
++@ const uint8_t *_top, [r1]
++@ const uint8_t *_left, [r2]
++@ ptrdiff_t stride) [r3]
++
++function ff_hevc_rpi_pred_planar_c_8_neon_8, export=1
++
++ adr ip, nbx2_7_0_1_8 + 16
++ vld1.8 {q0}, [r1 :128]! @ Top (left)
++ add r2, #16
++ vld1.8 {q1}, [ip: 128] @ {1,1,2,2,3,3...8,8}
++ lsl r3, #1
++ vld1.16 {d4[]}, [r1] @ Top (right)
++ sub ip, #16
++ vshll.u8 q3, d0, #3
++ mov r1, #8
++ vshll.u8 q8, d1, #3
++ vld1.16 {d5[]}, [r2] @ Left (lower)
++ sub r2, #16
++ vmlal.u8 q3, d2, d4
++ vmlal.u8 q8, d3, d4 @ Acc set up
++ vsubl.u8 q1, d5, d0
++ vsubl.u8 q0, d5, d1 @ Add set up
++ vld1.8 {q2}, [ip :128] @ {7,7,6,6,5,5...0,0}
++
++@ u8 7..0 [1] q2
++@ u8 left[y] [1] [r2]
++@ u16 acc [2] q3,q8 = (x+1)*p[nTbS][-1] + 32*p[x][-1] initially
++@ u16 add [2] q1,q0 = p[-1][nTbs] - p[x][-1]
++
++ vadd.i16 q3, q1
++ vadd.i16 q8, q0
++1:
++ vadd.i16 q10, q3, q1
++ subs r1, #2
++ vld1.16 {d18[]}, [r2]!
++ vadd.i16 q11, q8, q0
++ vld1.16 {d19[]}, [r2]!
++ vmlal.u8 q3, d4, d18
++ vmlal.u8 q8, d5, d18
++ vadd.i16 q12, q10, q1
++ vmlal.u8 q10, d4, d19
++ vadd.i16 q13, q11, q0
++ vmlal.u8 q11, d5, d19
++ vrshrn.u16 d18, q3, #4
++ vrshrn.u16 d19, q8, #4
++ vmov q3, q12
++ vst1.8 {q9}, [r0 :128], r3
++ vrshrn.u16 d18, q10, #4
++ vrshrn.u16 d19, q11, #4
++ vmov q8, q13
++ vst1.8 {q9}, [r0 :128], r3
++ bne 1b
++
++ bx lr
++
++endfunc
++
++
++@------------------------------------------------------------------------------
++@
++@ Data - has to be in two lumps to ensure we can always reach using adr
++
++ .balign 64
++
++nbx2_15_0_1_16:
++ .byte 15, 15, 14, 14, 13, 13, 12, 12
++ .byte 11, 11, 10, 10, 9, 9, 8, 8
++nbx2_7_0_1_8:
++ .byte 7, 7, 6, 6, 5, 5, 4, 4
++ .byte 3, 3, 2, 2, 1, 1, 0, 0
++ .byte 1, 1, 2, 2, 3, 3, 4, 4
++ .byte 5, 5, 6, 6, 7, 7, 8, 8
++ .byte 9, 9, 10, 10, 11, 11, 12, 12
++ .byte 13, 13, 14, 14, 15, 15, 16, 16
++
++ @ should be back on a 64-byte boundary here
++
++nbx2_3_0_1_4:
++ .byte 3, 3, 2, 2, 1, 1, 0, 0
++ .byte 1, 1, 2, 2, 3, 3, 4, 4
++
++@------------------------------------------------------------------------------
++
++
++@ ff_hevc_rpi_pred_planar_c_8_neon_10
++@ uint8_t *_src, [r0]
++@ const uint8_t *_top, [r1]
++@ const uint8_t *_left, [r2]
++@ ptrdiff_t stride) [r3]
++
++function ff_hevc_rpi_pred_planar_c_8_neon_10, export=1
++
++ @ Load from bytes & expand later - at the very least this uses less
++ @ memory than having a short table
++ adr ip, nbx2_7_0_1_8 + 16
++ vld1.16 {q0-q1}, [r1 :128]! @ Top (left)
++ add r2, #32
++ vld1.8 {q2}, [ip :128] @ {1,1,2,2,3,3...8,8}
++ lsl r3, #2
++ vld1.32 {d6[],d7[]}, [r1] @ Top (right)
++ sub ip, #16
++ vmovl.u8 q8, d4
++ mov r1, #8
++ vshl.i16 q9, q0, #3
++ vmovl.u8 q2, d5
++ vshl.i16 q10, q1, #3
++ vld1.32 {d22[],d23[]}, [r2] @ Left (lower)
++ sub r2, #32
++ vld1.8 {q12}, [ip] @ {7,7,6,6,5,5...0,0}
++ vmla.i16 q9, q8, q3
++ vmla.i16 q10, q2, q3 @ Acc set up
++ vsub.i16 q0, q11, q0
++ vsub.i16 q1, q11, q1 @ Add set up
++ vadd.i16 q2, q9, q0
++ vadd.i16 q3, q10, q1
++ vmovl.u8 q8, d24
++ vmovl.u8 q9, d25
++
++@ u16 7..0 [2] q8,q9
++@ u32 left[y] [2] [r2]
++@ u16 acc [2] q2,q3 = (x+1)*p[nTbS][-1] + 32*p[x][-1] initially
++@ u16 add [2] q0,q1 = p[-1][nTbs] - p[x][-1]
++
++1:
++ vadd.i16 q10, q2, q0
++ subs r1, #2
++ vld1.32 {d24[],d25[]}, [r2]!
++ vadd.i16 q11, q3, q1
++ vld1.32 {d28[],d29[]}, [r2]!
++ vmla.i16 q2, q8, q12
++ vmla.i16 q3, q9, q12
++ vadd.i16 q12, q10, q0
++ vmla.i16 q10, q8, q14
++ vadd.i16 q13, q11, q1
++ vmla.i16 q11, q9, q14
++ vrshr.u16 q14, q2, #4
++ vrshr.u16 q15, q3, #4
++ vmov q2, q12
++ vst1.16 {q14-q15}, [r0 :128], r3
++ vrshr.u16 q14, q10, #4
++ vrshr.u16 q15, q11, #4
++ vmov q3, q13
++ vst1.16 {q14-q15}, [r0 :128], r3
++ bne 1b
++
++ bx lr
++endfunc
++
++
++@ ff_hevc_rpi_pred_planar_c_16_neon_8
++@ uint8_t *_src, [r0]
++@ const uint8_t *_top, [r1]
++@ const uint8_t *_left, [r2]
++@ ptrdiff_t stride) [r3]
++
++function ff_hevc_rpi_pred_planar_c_16_neon_8, export=1
++
++ vld1.8 {q0-q1}, [r1 :128]! @ Top (left)
++ adr ip, nbx2_15_0_1_16 + 32
++ vpush {d8-d12}
++ vld1.8 {q2-q3}, [ip :128] @ {1,1,2,2,3,3...16,16}
++ add r2, #32
++ vld1.16 {d8[]}, [r1] @ Top (right)
++ sub ip, #32
++ vshll.u8 q8, d0, #4
++ mov r1, #16
++ vld1.16 {d9[]}, [r2] @ Left (lower)
++ sub r2, #32
++ vshll.u8 q9, d1, #4
++ lsl r3, #1
++ vshll.u8 q10, d2, #4
++ vshll.u8 q11, d3, #4
++ vmlal.u8 q8, d4, d8
++ vsubl.u8 q12, d9, d0
++ vmlal.u8 q9, d5, d8
++ vsubl.u8 q13, d9, d1
++ vmlal.u8 q10, d6, d8
++ vsubl.u8 q14, d9, d2
++ vmlal.u8 q11, d7, d8 @ Acc set up
++ vsubl.u8 q15, d9, d3 @ Add set up
++ vadd.i16 q8, q12
++ vadd.i16 q9, q13
++ vadd.i16 q10, q14
++ vadd.i16 q11, q15
++ vld1.8 {q4-q5}, [ip :128] @ {15,15,14,14,13,13...0,0}
++
++@ u8 15..0 [2] q4,q5
++@ u8 left[y] [2] [r2]
++@ u16 acc [4] q8-q11 = (x+1)*p[nTbS][-1] + 32*p[x][-1] initially
++@ u16 add [4] q12-q15 = p[-1][nTbs] - p[x][-1]
++
++ vld1.16 {d12[]}, [r2]!
++ vadd.i16 q0, q8, q12
++ b 2f
++1:
++ vld1.16 {d12[]}, [r2]!
++ vrshrn.u16 d3, q1, #5
++ vrshrn.u16 d2, q0, #5
++ vadd.i16 q0, q8, q12
++ vrshrn.u16 d4, q2, #5
++ vrshrn.u16 d5, q3, #5
++ vst1.8 {q1-q2}, [r0 :128], r3
++2: vadd.i16 q1, q9, q13
++ subs r1, #2
++ vadd.i16 q2, q10, q14
++ vadd.i16 q3, q11, q15
++ vmlal.u8 q8, d8, d12
++ vmlal.u8 q9, d9, d12
++ vmlal.u8 q10, d10, d12
++ vmlal.u8 q11, d11, d12
++ vld1.16 {d12[]}, [r2]!
++ vrshrn.u16 d19, q9, #5
++ vrshrn.u16 d18, q8, #5
++ vadd.i16 q8, q0, q12
++ vrshrn.u16 d20, q10, #5
++ vrshrn.u16 d21, q11, #5
++ vst1.8 {q9-q10}, [r0 :128], r3
++ vadd.i16 q9, q1, q13
++ vadd.i16 q10, q2, q14
++ vadd.i16 q11, q3, q15
++ vmlal.u8 q0, d8, d12
++ vmlal.u8 q1, d9, d12
++ vmlal.u8 q2, d10, d12
++ vmlal.u8 q3, d11, d12
++
++ bne 1b
++
++ vpop {d8-d12}
++
++ vrshrn.u16 d3, q1, #5
++ vrshrn.u16 d2, q0, #5
++ vrshrn.u16 d4, q2, #5
++ vrshrn.u16 d5, q3, #5
++ vst1.8 {q1-q2}, [r0 :128]
++
++ bx lr
++
++endfunc
++
++
++@ ff_hevc_rpi_pred_planar_c_16_neon_10
++@ uint8_t *_src, [r0]
++@ const uint8_t *_top, [r1]
++@ const uint8_t *_left, [r2]
++@ ptrdiff_t stride) [r3]
++
++function ff_hevc_rpi_pred_planar_c_16_neon_10, export=1
++
++ @ Load from bytes & expand later - at the very least this uses less
++ @ memory than having a short table
++ vld1.16 {q0-q1}, [r1 :128]! @ Top (left)
++ adr ip, nbx2_15_0_1_16 + 32
++ vpush {q4-q7}
++ vld1.16 {q2-q3}, [r1 :128]! @ Top (centre)
++ add r2, #64
++ vld1.8 {q14-q15}, [ip :128] @ {1,1,2,2,3,3...16,16}
++T lsl r3, #2
++ vld1.32 {d8[],d9[]}, [r1] @ Top (right)
++ sub ip, #32
++ vmovl.u8 q12, d28
++ mov r1, #16
++ vmovl.u8 q13, d29
++ vld1.8 {q6-q7}, [ip :128] @ {15,15,14,14,13,13...0,0}
++ vmovl.u8 q14, d30
++ vmovl.u8 q15, d31
++ vld1.32 {d10[],d11[]}, [r2] @ Left (lower)
++ sub r2, #64
++ vshl.i16 q8, q0, #4
++ vshl.i16 q9, q1, #4
++ vshl.i16 q10, q2, #4
++ vshl.i16 q11, q3, #4
++ vmla.i16 q8, q12, q4
++ vsub.i16 q0, q5, q0
++ vmla.i16 q9, q13, q4
++ vpush {q0}
++ vsub.i16 q1, q5, q1
++ vmla.i16 q10, q14, q4
++ vsub.i16 q2, q5, q2
++ vmla.i16 q11, q15, q4 @ Acc set up
++ vsub.i16 q3, q5, q3 @ Add set up
++ vadd.i16 q8, q0
++ vadd.i16 q9, q1
++ vadd.i16 q10, q2
++ vadd.i16 q11, q3
++ vmovl.u8 q4, d12
++ vmovl.u8 q5, d13
++ vmovl.u8 q6, d14
++ vmovl.u8 q7, d15
++
++@ u16 31..0 [4] q4-q7
++@ u16 left[y] [4] [r2]
++@ u16 acc [4] q8-q11 = (x+1)*p[nTbS][-1] + 32*p[x][-1] initially
++@ u16 add [4] q0-q3 = p[-1][nTbs] - p[x][-1]
++
++ vadd.i16 q12, q8, q0
++A sub r0, r0, r3, lsl #2
++T sub r0, r3
++1:
++ vld1.32 {d0[],d1[]}, [r2]!
++A add r0, r0, r3, lsl #2
++T add r0, r3
++ vadd.i16 q13, q9, q1
++ subs r1, #2
++ vadd.i16 q14, q10, q2
++ vadd.i16 q15, q11, q3
++ vmla.i16 q8, q4, q0
++ vmla.i16 q9, q5, q0
++ vmla.i16 q10, q6, q0
++ vmla.i16 q11, q7, q0
++ vld1.16 {q0}, [sp]
++ vrshr.u16 q8, #5
++ vrshr.u16 q9, #5
++ vrshr.u16 q10, #5
++ vrshr.u16 q11, #5
++ vstm r0, {q8-q11}
++ vadd.i16 q8, q12, q0
++A add r0, r0, r3, lsl #2
++T add r0, r3
++ vld1.32 {d0[],d1[]}, [r2]!
++ vadd.i16 q9, q13, q1
++ vadd.i16 q10, q14, q2
++ vadd.i16 q11, q15, q3
++ vmla.i16 q12, q4, q0
++ vmla.i16 q13, q5, q0
++ vmla.i16 q14, q6, q0
++ vmla.i16 q15, q7, q0
++ vld1.16 {q0}, [sp]
++ vrshr.u16 q12, #5
++ vrshr.u16 q13, #5
++ vrshr.u16 q14, #5
++ vrshr.u16 q15, #5
++ vstm r0, {q12-q15}
++ vadd.i16 q12, q8, q0
++ bne 1b
++
++ vpop {q3-q7}
++ bx lr
++
++endfunc
+diff --git a/libavcodec/avcodec.h b/libavcodec/avcodec.h
+index fb0c6fae70..9f2ebb16f3 100644
+--- a/libavcodec/avcodec.h
++++ b/libavcodec/avcodec.h
+@@ -3208,7 +3208,13 @@ typedef struct AVCodecContext {
+ #endif
+
+ /**
+- * Audio only. The amount of padding (in samples) appended by the encoder to
++ * Opaque pointer for use by replacement get_buffer2 code
++ *
++ * @author jc (08/02/2016)
++ */
++ void * get_buffer_context;
++
++ /* Audio only. The amount of padding (in samples) appended by the encoder to
+ * the end of the audio. I.e. this number of decoded samples must be
+ * discarded by the caller from the end of the stream to get the original
+ * audio without any trailing padding.
+@@ -4593,6 +4599,17 @@ void av_packet_rescale_ts(AVPacket *pkt, AVRational tb_src, AVRational tb_dst);
+ */
+ AVCodec *avcodec_find_decoder(enum AVCodecID id);
+
++/**
++ * Find a registered decoder with a matching codec ID and pix_fmt.
++ * A decoder will pix_fmt set to NULL will match any fmt.
++ * A fmt of AV_PIX_FMT_NONE will only match a decoder will px_fmt NULL.
++ *
++ * @param id AVCodecID of the requested decoder
++ * @param fmt AVPixelForma that msut be supported by decoder
++ * @return A decoder if one was found, NULL otherwise.
++ */
++AVCodec *avcodec_find_decoder_by_id_and_fmt(enum AVCodecID id, enum AVPixelFormat fmt);
++
+ /**
+ * Find a registered decoder with the specified name.
+ *
+diff --git a/libavcodec/cabac.h b/libavcodec/cabac.h
+index 1bf1c620d6..ccfa991f60 100644
+--- a/libavcodec/cabac.h
++++ b/libavcodec/cabac.h
+@@ -43,7 +43,14 @@ extern const uint8_t ff_h264_cabac_tables[512 + 4*2*64 + 4*64 + 63];
+ typedef struct CABACContext{
+ int low;
+ int range;
+- int outstanding_count;
++ union
++ {
++ int outstanding_count;
++ struct {
++ uint16_t bits;
++ uint16_t range;
++ } by22;
++ };
+ const uint8_t *bytestream_start;
+ const uint8_t *bytestream;
+ const uint8_t *bytestream_end;
+diff --git a/libavcodec/mmaldec.c b/libavcodec/mmaldec.c
+index 647a22ef7c..4ed35d1126 100644
+--- a/libavcodec/mmaldec.c
++++ b/libavcodec/mmaldec.c
+@@ -24,6 +24,9 @@
+ * MMAL Video Decoder
+ */
+
++#pragma GCC diagnostic push
++// Many many redundant decls in the header files
++#pragma GCC diagnostic ignored "-Wredundant-decls"
+ #include <bcm_host.h>
+ #include <interface/mmal/mmal.h>
+ #include <interface/mmal/mmal_parameters_video.h>
+@@ -31,6 +34,7 @@
+ #include <interface/mmal/util/mmal_util_params.h>
+ #include <interface/mmal/util/mmal_default_components.h>
+ #include <interface/mmal/vc/mmal_vc_api.h>
++#pragma GCC diagnostic pop
+ #include <stdatomic.h>
+
+ #include "avcodec.h"
+diff --git a/libavcodec/raw.c b/libavcodec/raw.c
+index 8da2a9735e..9089f9b4ea 100644
+--- a/libavcodec/raw.c
++++ b/libavcodec/raw.c
+@@ -283,6 +283,10 @@ const PixelFormatTag ff_raw_pix_fmt_tags[] = {
+ { AV_PIX_FMT_YUV444P16LE, MKTAG('I', '4', 'F', 'L') },
+ { AV_PIX_FMT_YUV444P16BE, MKTAG('I', '4', 'F', 'B') },
+
++ /* RPI (Might as well define for everything) */
++ { AV_PIX_FMT_SAND128, MKTAG('S', 'A', 'N', 'D') },
++ { AV_PIX_FMT_SAND64_10, MKTAG('S', 'N', 'D', 'A') },
++
+ /* special */
+ { AV_PIX_FMT_RGB565LE,MKTAG( 3 , 0 , 0 , 0 ) }, /* flipped RGB565LE */
+ { AV_PIX_FMT_YUV444P, MKTAG('Y', 'V', '2', '4') }, /* YUV444P, swapped UV */
+diff --git a/libavcodec/rawenc.c b/libavcodec/rawenc.c
+index d181b74570..c52c450956 100644
+--- a/libavcodec/rawenc.c
++++ b/libavcodec/rawenc.c
+@@ -24,6 +24,7 @@
+ * Raw Video Encoder
+ */
+
++#include "config.h"
+ #include "avcodec.h"
+ #include "raw.h"
+ #include "internal.h"
+@@ -31,6 +32,10 @@
+ #include "libavutil/intreadwrite.h"
+ #include "libavutil/imgutils.h"
+ #include "libavutil/internal.h"
++#include "libavutil/avassert.h"
++#if CONFIG_SAND
++#include "libavutil/rpi_sand_fns.h"
++#endif
+
+ static av_cold int raw_encode_init(AVCodecContext *avctx)
+ {
+@@ -49,6 +54,55 @@ FF_ENABLE_DEPRECATION_WARNINGS
+ return 0;
+ }
+
++#if CONFIG_SAND
++static int raw_sand8_as_yuv420(AVCodecContext *avctx, AVPacket *pkt,
++ const AVFrame *frame)
++{
++ const int width = av_frame_cropped_width(frame);
++ const int height = av_frame_cropped_height(frame);
++ const int x0 = frame->crop_left;
++ const int y0 = frame->crop_top;
++ const int size = width * height * 3 / 2;
++ uint8_t * dst;
++ int ret;
++
++ if ((ret = ff_alloc_packet2(avctx, pkt, size, size)) < 0)
++ return ret;
++
++ dst = pkt->data;
++
++ av_rpi_sand_to_planar_y8(dst, width, frame->data[0], frame->linesize[0], frame->linesize[3], x0, y0, width, height);
++ dst += width * height;
++ av_rpi_sand_to_planar_c8(dst, width / 2, dst + width * height / 4, width / 2,
++ frame->data[1], frame->linesize[1], av_rpi_sand_frame_stride2(frame), x0 / 2, y0 / 2, width / 2, height / 2);
++ return 0;
++}
++
++static int raw_sand16_as_yuv420(AVCodecContext *avctx, AVPacket *pkt,
++ const AVFrame *frame)
++{
++ const int width = av_frame_cropped_width(frame);
++ const int height = av_frame_cropped_height(frame);
++ const int x0 = frame->crop_left;
++ const int y0 = frame->crop_top;
++ const int size = width * height * 3;
++ uint8_t * dst;
++ int ret;
++
++ if ((ret = ff_alloc_packet2(avctx, pkt, size, size)) < 0)
++ return ret;
++
++ dst = pkt->data;
++
++ av_rpi_sand_to_planar_y16(dst, width * 2, frame->data[0], frame->linesize[0], frame->linesize[3], x0 * 2, y0, width * 2, height);
++ dst += width * height * 2;
++ av_rpi_sand_to_planar_c16(dst, width, dst + width * height / 2, width,
++ frame->data[1], frame->linesize[1], av_rpi_sand_frame_stride2(frame), x0, y0 / 2, width, height / 2);
++ return 0;
++}
++#endif
++
++
+ static int raw_encode(AVCodecContext *avctx, AVPacket *pkt,
+ const AVFrame *frame, int *got_packet)
+ {
+@@ -58,6 +112,14 @@ static int raw_encode(AVCodecContext *avctx, AVPacket *pkt,
+ if (ret < 0)
+ return ret;
+
++#if CONFIG_SAND
++ if (av_rpi_is_sand_frame(frame)) {
++ ret = av_rpi_is_sand8_frame(frame) ? raw_sand8_as_yuv420(avctx, pkt, frame) : raw_sand16_as_yuv420(avctx, pkt, frame);
++ *got_packet = (ret == 0);
++ return ret;
++ }
++#endif
++
+ if ((ret = ff_alloc_packet2(avctx, pkt, ret, ret)) < 0)
+ return ret;
+ if ((ret = av_image_copy_to_buffer(pkt->data, pkt->size,
+diff --git a/libavcodec/rpi_hevc_cabac.c b/libavcodec/rpi_hevc_cabac.c
+new file mode 100644
+index 0000000000..552c2e349e
+--- /dev/null
++++ b/libavcodec/rpi_hevc_cabac.c
+@@ -0,0 +1,2255 @@
++/*
++ * HEVC CABAC decoding
++ *
++ * Copyright (C) 2012 - 2013 Guillaume Martres
++ * Copyright (C) 2012 - 2013 Gildas Cocherel
++ *
++ * This file is part of FFmpeg.
++ *
++ * FFmpeg is free software; you can redistribute it and/or
++ * modify it under the terms of the GNU Lesser General Public
++ * License as published by the Free Software Foundation; either
++ * version 2.1 of the License, or (at your option) any later version.
++ *
++ * FFmpeg is distributed in the hope that it will be useful,
++ * but WITHOUT ANY WARRANTY; without even the implied warranty of
++ * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
++ * Lesser General Public License for more details.
++ *
++ * You should have received a copy of the GNU Lesser General Public
++ * License along with FFmpeg; if not, write to the Free Software
++ * Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA
++ */
++
++#define UNCHECKED_BITSTREAM_READER 1
++
++#include "libavutil/attributes.h"
++#include "libavutil/common.h"
++
++#include "cabac_functions.h"
++#include "rpi_hevc_data.h"
++#include "hevc.h"
++#include "rpi_hevcdec.h"
++#include "rpi_hevc_cabac_fns.h"
++
++#include "libavutil/rpi_sand_fns.h"
++
++// BY22 is probably faster than simple bypass if the processor has
++// either a fast 32-bit divide or a fast 32x32->64[63:32] instruction
++// x86 has fast int divide
++// Arm doesn't have divide or general fast 64 bit, but does have the multiply
++// * Beware: ARCH_xxx isn't set if configure --disable-asm is used
++#define USE_BY22 (HAVE_FAST_64BIT || ARCH_ARM || ARCH_X86)
++// Use native divide if we have a fast one - otherwise use mpy 1/x
++// x86 has a fast integer divide - arm doesn't - unsure about other
++// architectures
++#define USE_BY22_DIV ARCH_X86
++
++// Special case blocks with a single significant ceoff
++// Decreases the complexity of the code for a common case but increases the
++// code size.
++#define USE_N_END_1 1
++
++#if !USE_BY22_DIV
++// * 1/x @ 32 bits gets us 22 bits of accuracy
++#define CABAC_BY22_PEEK_BITS 22
++#else
++// A real 32-bit divide gets us another bit
++// If we have a 64 bit int & a unit time divider then we should get a lot
++// of bits (55) but that is untested and it is unclear if it would give
++// us a large advantage
++#define CABAC_BY22_PEEK_BITS 23
++#endif
++
++#define CABAC_MAX_BIN 31
++
++
++#if USE_BY22 && !USE_BY22_DIV
++#define I(x) (uint32_t)((0x10000000000ULL / (uint64_t)(x)) + 1ULL)
++
++static const uint32_t cabac_by22_inv_range[256] = {
++ 0, I(257), I(258), I(259),
++ I(260), I(261), I(262), I(263), I(264), I(265), I(266), I(267), I(268), I(269),
++ I(270), I(271), I(272), I(273), I(274), I(275), I(276), I(277), I(278), I(279),
++ I(280), I(281), I(282), I(283), I(284), I(285), I(286), I(287), I(288), I(289),
++ I(290), I(291), I(292), I(293), I(294), I(295), I(296), I(297), I(298), I(299),
++ I(300), I(301), I(302), I(303), I(304), I(305), I(306), I(307), I(308), I(309),
++ I(310), I(311), I(312), I(313), I(314), I(315), I(316), I(317), I(318), I(319),
++ I(320), I(321), I(322), I(323), I(324), I(325), I(326), I(327), I(328), I(329),
++ I(330), I(331), I(332), I(333), I(334), I(335), I(336), I(337), I(338), I(339),
++ I(340), I(341), I(342), I(343), I(344), I(345), I(346), I(347), I(348), I(349),
++ I(350), I(351), I(352), I(353), I(354), I(355), I(356), I(357), I(358), I(359),
++ I(360), I(361), I(362), I(363), I(364), I(365), I(366), I(367), I(368), I(369),
++ I(370), I(371), I(372), I(373), I(374), I(375), I(376), I(377), I(378), I(379),
++ I(380), I(381), I(382), I(383), I(384), I(385), I(386), I(387), I(388), I(389),
++ I(390), I(391), I(392), I(393), I(394), I(395), I(396), I(397), I(398), I(399),
++ I(400), I(401), I(402), I(403), I(404), I(405), I(406), I(407), I(408), I(409),
++ I(410), I(411), I(412), I(413), I(414), I(415), I(416), I(417), I(418), I(419),
++ I(420), I(421), I(422), I(423), I(424), I(425), I(426), I(427), I(428), I(429),
++ I(430), I(431), I(432), I(433), I(434), I(435), I(436), I(437), I(438), I(439),
++ I(440), I(441), I(442), I(443), I(444), I(445), I(446), I(447), I(448), I(449),
++ I(450), I(451), I(452), I(453), I(454), I(455), I(456), I(457), I(458), I(459),
++ I(460), I(461), I(462), I(463), I(464), I(465), I(466), I(467), I(468), I(469),
++ I(470), I(471), I(472), I(473), I(474), I(475), I(476), I(477), I(478), I(479),
++ I(480), I(481), I(482), I(483), I(484), I(485), I(486), I(487), I(488), I(489),
++ I(490), I(491), I(492), I(493), I(494), I(495), I(496), I(497), I(498), I(499),
++ I(500), I(501), I(502), I(503), I(504), I(505), I(506), I(507), I(508), I(509),
++ I(510), I(511)
++};
++#undef I
++#endif // USE_BY22
++
++#if ARCH_ARM
++#include "arm/rpi_hevc_cabac.h"
++#endif
++
++/**
++ * number of bin by SyntaxElement.
++ */
++static const int8_t num_bins_in_se[] = {
++ 1, // sao_merge_flag
++ 1, // sao_type_idx
++ 0, // sao_eo_class
++ 0, // sao_band_position
++ 0, // sao_offset_abs
++ 0, // sao_offset_sign
++ 0, // end_of_slice_flag
++ 3, // split_coding_unit_flag
++ 1, // cu_transquant_bypass_flag
++ 3, // skip_flag
++ 3, // cu_qp_delta
++ 1, // pred_mode
++ 4, // part_mode
++ 0, // pcm_flag
++ 1, // prev_intra_luma_pred_mode
++ 0, // mpm_idx
++ 0, // rem_intra_luma_pred_mode
++ 2, // intra_chroma_pred_mode
++ 1, // merge_flag
++ 1, // merge_idx
++ 5, // inter_pred_idc
++ 2, // ref_idx_l0
++ 2, // ref_idx_l1
++ 2, // abs_mvd_greater0_flag
++ 2, // abs_mvd_greater1_flag
++ 0, // abs_mvd_minus2
++ 0, // mvd_sign_flag
++ 1, // mvp_lx_flag
++ 1, // no_residual_data_flag
++ 3, // split_transform_flag
++ 2, // cbf_luma
++ 4, // cbf_cb, cbf_cr
++ 2, // transform_skip_flag[][]
++ 2, // explicit_rdpcm_flag[][]
++ 2, // explicit_rdpcm_dir_flag[][]
++ 18, // last_significant_coeff_x_prefix
++ 18, // last_significant_coeff_y_prefix
++ 0, // last_significant_coeff_x_suffix
++ 0, // last_significant_coeff_y_suffix
++ 4, // significant_coeff_group_flag
++ 44, // significant_coeff_flag
++ 24, // coeff_abs_level_greater1_flag
++ 6, // coeff_abs_level_greater2_flag
++ 0, // coeff_abs_level_remaining
++ 0, // coeff_sign_flag
++ 8, // log2_res_scale_abs
++ 2, // res_scale_sign_flag
++ 1, // cu_chroma_qp_offset_flag
++ 1, // cu_chroma_qp_offset_idx
++};
++
++/**
++ * Offset to ctxIdx 0 in init_values and states, indexed by SyntaxElement.
++ */
++static const int elem_offset[sizeof(num_bins_in_se)] = {
++ 0, // sao_merge_flag
++ 1, // sao_type_idx
++ 2, // sao_eo_class
++ 2, // sao_band_position
++ 2, // sao_offset_abs
++ 2, // sao_offset_sign
++ 2, // end_of_slice_flag
++ 2, // split_coding_unit_flag
++ 5, // cu_transquant_bypass_flag
++ 6, // skip_flag
++ 9, // cu_qp_delta
++ 12, // pred_mode
++ 13, // part_mode
++ 17, // pcm_flag
++ 17, // prev_intra_luma_pred_mode
++ 18, // mpm_idx
++ 18, // rem_intra_luma_pred_mode
++ 18, // intra_chroma_pred_mode
++ 20, // merge_flag
++ 21, // merge_idx
++ 22, // inter_pred_idc
++ 27, // ref_idx_l0
++ 29, // ref_idx_l1
++ 31, // abs_mvd_greater0_flag
++ 33, // abs_mvd_greater1_flag
++ 35, // abs_mvd_minus2
++ 35, // mvd_sign_flag
++ 35, // mvp_lx_flag
++ 36, // no_residual_data_flag
++ 37, // split_transform_flag
++ 40, // cbf_luma
++ 42, // cbf_cb, cbf_cr
++ 46, // transform_skip_flag[][]
++ 48, // explicit_rdpcm_flag[][]
++ 50, // explicit_rdpcm_dir_flag[][]
++ 52, // last_significant_coeff_x_prefix
++ 70, // last_significant_coeff_y_prefix
++ 88, // last_significant_coeff_x_suffix
++ 88, // last_significant_coeff_y_suffix
++ 88, // significant_coeff_group_flag
++ 92, // significant_coeff_flag
++ 136, // coeff_abs_level_greater1_flag
++ 160, // coeff_abs_level_greater2_flag
++ 166, // coeff_abs_level_remaining
++ 166, // coeff_sign_flag
++ 166, // log2_res_scale_abs
++ 174, // res_scale_sign_flag
++ 176, // cu_chroma_qp_offset_flag
++ 177, // cu_chroma_qp_offset_idx
++};
++
++#define CNU 154
++/**
++ * Indexed by init_type
++ */
++static const uint8_t init_values[3][HEVC_CONTEXTS] = {
++ { // sao_merge_flag
++ 153,
++ // sao_type_idx
++ 200,
++ // split_coding_unit_flag
++ 139, 141, 157,
++ // cu_transquant_bypass_flag
++ 154,
++ // skip_flag
++ CNU, CNU, CNU,
++ // cu_qp_delta
++ 154, 154, 154,
++ // pred_mode
++ CNU,
++ // part_mode
++ 184, CNU, CNU, CNU,
++ // prev_intra_luma_pred_mode
++ 184,
++ // intra_chroma_pred_mode
++ 63, 139,
++ // merge_flag
++ CNU,
++ // merge_idx
++ CNU,
++ // inter_pred_idc
++ CNU, CNU, CNU, CNU, CNU,
++ // ref_idx_l0
++ CNU, CNU,
++ // ref_idx_l1
++ CNU, CNU,
++ // abs_mvd_greater1_flag
++ CNU, CNU,
++ // abs_mvd_greater1_flag
++ CNU, CNU,
++ // mvp_lx_flag
++ CNU,
++ // no_residual_data_flag
++ CNU,
++ // split_transform_flag
++ 153, 138, 138,
++ // cbf_luma
++ 111, 141,
++ // cbf_cb, cbf_cr
++ 94, 138, 182, 154,
++ // transform_skip_flag
++ 139, 139,
++ // explicit_rdpcm_flag
++ 139, 139,
++ // explicit_rdpcm_dir_flag
++ 139, 139,
++ // last_significant_coeff_x_prefix
++ 110, 110, 124, 125, 140, 153, 125, 127, 140, 109, 111, 143, 127, 111,
++ 79, 108, 123, 63,
++ // last_significant_coeff_y_prefix
++ 110, 110, 124, 125, 140, 153, 125, 127, 140, 109, 111, 143, 127, 111,
++ 79, 108, 123, 63,
++ // significant_coeff_group_flag
++ 91, 171, 134, 141,
++ // significant_coeff_flag
++ 111, 111, 125, 110, 110, 94, 124, 108, 124, 107, 125, 141, 179, 153,
++ 125, 107, 125, 141, 179, 153, 125, 107, 125, 141, 179, 153, 125, 140,
++ 139, 182, 182, 152, 136, 152, 136, 153, 136, 139, 111, 136, 139, 111,
++ 141, 111,
++ // coeff_abs_level_greater1_flag
++ 140, 92, 137, 138, 140, 152, 138, 139, 153, 74, 149, 92, 139, 107,
++ 122, 152, 140, 179, 166, 182, 140, 227, 122, 197,
++ // coeff_abs_level_greater2_flag
++ 138, 153, 136, 167, 152, 152,
++ // log2_res_scale_abs
++ 154, 154, 154, 154, 154, 154, 154, 154,
++ // res_scale_sign_flag
++ 154, 154,
++ // cu_chroma_qp_offset_flag
++ 154,
++ // cu_chroma_qp_offset_idx
++ 154,
++ },
++ { // sao_merge_flag
++ 153,
++ // sao_type_idx
++ 185,
++ // split_coding_unit_flag
++ 107, 139, 126,
++ // cu_transquant_bypass_flag
++ 154,
++ // skip_flag
++ 197, 185, 201,
++ // cu_qp_delta
++ 154, 154, 154,
++ // pred_mode
++ 149,
++ // part_mode
++ 154, 139, 154, 154,
++ // prev_intra_luma_pred_mode
++ 154,
++ // intra_chroma_pred_mode
++ 152, 139,
++ // merge_flag
++ 110,
++ // merge_idx
++ 122,
++ // inter_pred_idc
++ 95, 79, 63, 31, 31,
++ // ref_idx_l0
++ 153, 153,
++ // ref_idx_l1
++ 153, 153,
++ // abs_mvd_greater1_flag
++ 140, 198,
++ // abs_mvd_greater1_flag
++ 140, 198,
++ // mvp_lx_flag
++ 168,
++ // no_residual_data_flag
++ 79,
++ // split_transform_flag
++ 124, 138, 94,
++ // cbf_luma
++ 153, 111,
++ // cbf_cb, cbf_cr
++ 149, 107, 167, 154,
++ // transform_skip_flag
++ 139, 139,
++ // explicit_rdpcm_flag
++ 139, 139,
++ // explicit_rdpcm_dir_flag
++ 139, 139,
++ // last_significant_coeff_x_prefix
++ 125, 110, 94, 110, 95, 79, 125, 111, 110, 78, 110, 111, 111, 95,
++ 94, 108, 123, 108,
++ // last_significant_coeff_y_prefix
++ 125, 110, 94, 110, 95, 79, 125, 111, 110, 78, 110, 111, 111, 95,
++ 94, 108, 123, 108,
++ // significant_coeff_group_flag
++ 121, 140, 61, 154,
++ // significant_coeff_flag
++ 155, 154, 139, 153, 139, 123, 123, 63, 153, 166, 183, 140, 136, 153,
++ 154, 166, 183, 140, 136, 153, 154, 166, 183, 140, 136, 153, 154, 170,
++ 153, 123, 123, 107, 121, 107, 121, 167, 151, 183, 140, 151, 183, 140,
++ 140, 140,
++ // coeff_abs_level_greater1_flag
++ 154, 196, 196, 167, 154, 152, 167, 182, 182, 134, 149, 136, 153, 121,
++ 136, 137, 169, 194, 166, 167, 154, 167, 137, 182,
++ // coeff_abs_level_greater2_flag
++ 107, 167, 91, 122, 107, 167,
++ // log2_res_scale_abs
++ 154, 154, 154, 154, 154, 154, 154, 154,
++ // res_scale_sign_flag
++ 154, 154,
++ // cu_chroma_qp_offset_flag
++ 154,
++ // cu_chroma_qp_offset_idx
++ 154,
++ },
++ { // sao_merge_flag
++ 153,
++ // sao_type_idx
++ 160,
++ // split_coding_unit_flag
++ 107, 139, 126,
++ // cu_transquant_bypass_flag
++ 154,
++ // skip_flag
++ 197, 185, 201,
++ // cu_qp_delta
++ 154, 154, 154,
++ // pred_mode
++ 134,
++ // part_mode
++ 154, 139, 154, 154,
++ // prev_intra_luma_pred_mode
++ 183,
++ // intra_chroma_pred_mode
++ 152, 139,
++ // merge_flag
++ 154,
++ // merge_idx
++ 137,
++ // inter_pred_idc
++ 95, 79, 63, 31, 31,
++ // ref_idx_l0
++ 153, 153,
++ // ref_idx_l1
++ 153, 153,
++ // abs_mvd_greater1_flag
++ 169, 198,
++ // abs_mvd_greater1_flag
++ 169, 198,
++ // mvp_lx_flag
++ 168,
++ // no_residual_data_flag
++ 79,
++ // split_transform_flag
++ 224, 167, 122,
++ // cbf_luma
++ 153, 111,
++ // cbf_cb, cbf_cr
++ 149, 92, 167, 154,
++ // transform_skip_flag
++ 139, 139,
++ // explicit_rdpcm_flag
++ 139, 139,
++ // explicit_rdpcm_dir_flag
++ 139, 139,
++ // last_significant_coeff_x_prefix
++ 125, 110, 124, 110, 95, 94, 125, 111, 111, 79, 125, 126, 111, 111,
++ 79, 108, 123, 93,
++ // last_significant_coeff_y_prefix
++ 125, 110, 124, 110, 95, 94, 125, 111, 111, 79, 125, 126, 111, 111,
++ 79, 108, 123, 93,
++ // significant_coeff_group_flag
++ 121, 140, 61, 154,
++ // significant_coeff_flag
++ 170, 154, 139, 153, 139, 123, 123, 63, 124, 166, 183, 140, 136, 153,
++ 154, 166, 183, 140, 136, 153, 154, 166, 183, 140, 136, 153, 154, 170,
++ 153, 138, 138, 122, 121, 122, 121, 167, 151, 183, 140, 151, 183, 140,
++ 140, 140,
++ // coeff_abs_level_greater1_flag
++ 154, 196, 167, 167, 154, 152, 167, 182, 182, 134, 149, 136, 153, 121,
++ 136, 122, 169, 208, 166, 167, 154, 152, 167, 182,
++ // coeff_abs_level_greater2_flag
++ 107, 167, 91, 107, 107, 167,
++ // log2_res_scale_abs
++ 154, 154, 154, 154, 154, 154, 154, 154,
++ // res_scale_sign_flag
++ 154, 154,
++ // cu_chroma_qp_offset_flag
++ 154,
++ // cu_chroma_qp_offset_idx
++ 154,
++ },
++};
++
++static const uint8_t scan_1x1[1] = {
++ 0,
++};
++
++static const uint8_t horiz_scan2x2_x[4] = {
++ 0, 1, 0, 1,
++};
++
++static const uint8_t horiz_scan2x2_y[4] = {
++ 0, 0, 1, 1
++};
++
++static const uint8_t horiz_scan4x4_x[16] = {
++ 0, 1, 2, 3,
++ 0, 1, 2, 3,
++ 0, 1, 2, 3,
++ 0, 1, 2, 3,
++};
++
++static const uint8_t horiz_scan4x4_y[16] = {
++ 0, 0, 0, 0,
++ 1, 1, 1, 1,
++ 2, 2, 2, 2,
++ 3, 3, 3, 3,
++};
++
++static const uint8_t horiz_scan8x8_inv[8][8] = {
++ { 0, 1, 2, 3, 16, 17, 18, 19, },
++ { 4, 5, 6, 7, 20, 21, 22, 23, },
++ { 8, 9, 10, 11, 24, 25, 26, 27, },
++ { 12, 13, 14, 15, 28, 29, 30, 31, },
++ { 32, 33, 34, 35, 48, 49, 50, 51, },
++ { 36, 37, 38, 39, 52, 53, 54, 55, },
++ { 40, 41, 42, 43, 56, 57, 58, 59, },
++ { 44, 45, 46, 47, 60, 61, 62, 63, },
++};
++
++static const uint8_t diag_scan2x2_x[4] = {
++ 0, 0, 1, 1,
++};
++
++static const uint8_t diag_scan2x2_y[4] = {
++ 0, 1, 0, 1,
++};
++
++static const uint8_t diag_scan2x2_inv[2][2] = {
++ { 0, 2, },
++ { 1, 3, },
++};
++
++static const uint8_t diag_scan4x4_inv[4][4] = {
++ { 0, 2, 5, 9, },
++ { 1, 4, 8, 12, },
++ { 3, 7, 11, 14, },
++ { 6, 10, 13, 15, },
++};
++
++static const uint8_t diag_scan8x8_inv[8][8] = {
++ { 0, 2, 5, 9, 14, 20, 27, 35, },
++ { 1, 4, 8, 13, 19, 26, 34, 42, },
++ { 3, 7, 12, 18, 25, 33, 41, 48, },
++ { 6, 11, 17, 24, 32, 40, 47, 53, },
++ { 10, 16, 23, 31, 39, 46, 52, 57, },
++ { 15, 22, 30, 38, 45, 51, 56, 60, },
++ { 21, 29, 37, 44, 50, 55, 59, 62, },
++ { 28, 36, 43, 49, 54, 58, 61, 63, },
++};
++
++
++typedef struct
++{
++ uint16_t coeff;
++ uint16_t scale;
++} xy_off_t;
++
++#define XYT_C(x,y,t) ((x) + ((y) << (t)))
++#define SCALE_TRAFO(t) ((t) > 3 ? 3 : (t))
++#define SCALE_SHR(t) ((t) - SCALE_TRAFO(t))
++#define XYT_S(x,y,t) (((x) >> SCALE_SHR(t)) + (((y) >> SCALE_SHR(t)) << SCALE_TRAFO(t)))
++
++#define XYT(x,y,t) {XYT_C(x,y,t), XYT_S(x,y,t)}
++
++#define OFF_DIAG(t) {\
++ XYT(0,0,t), XYT(0,1,t), XYT(1,0,t), XYT(0,2,t),\
++ XYT(1,1,t), XYT(2,0,t), XYT(0,3,t), XYT(1,2,t),\
++ XYT(2,1,t), XYT(3,0,t), XYT(1,3,t), XYT(2,2,t),\
++ XYT(3,1,t), XYT(2,3,t), XYT(3,2,t), XYT(3,3,t)\
++}
++
++#define OFF_HORIZ(t) {\
++ XYT(0,0,t), XYT(1,0,t), XYT(2,0,t), XYT(3,0,t),\
++ XYT(0,1,t), XYT(1,1,t), XYT(2,1,t), XYT(3,1,t),\
++ XYT(0,2,t), XYT(1,2,t), XYT(2,2,t), XYT(3,2,t),\
++ XYT(0,3,t), XYT(1,3,t), XYT(2,3,t), XYT(3,3,t)\
++}
++
++#define OFF_VERT(t) {\
++ XYT(0,0,t), XYT(0,1,t), XYT(0,2,t), XYT(0,3,t),\
++ XYT(1,0,t), XYT(1,1,t), XYT(1,2,t), XYT(1,3,t),\
++ XYT(2,0,t), XYT(2,1,t), XYT(2,2,t), XYT(2,3,t),\
++ XYT(3,0,t), XYT(3,1,t), XYT(3,2,t), XYT(3,3,t)\
++}
++
++static const xy_off_t off_xys[3][4][16] =
++{
++ {OFF_DIAG(2), OFF_DIAG(3), OFF_DIAG(4), OFF_DIAG(5)},
++ {OFF_HORIZ(2), OFF_HORIZ(3), OFF_HORIZ(4), OFF_HORIZ(5)},
++ {OFF_VERT(2), OFF_VERT(3), OFF_VERT(4), OFF_VERT(5)}
++};
++
++
++// Helper fns
++#ifndef hevc_mem_bits32
++static av_always_inline uint32_t hevc_mem_bits32(const void * buf, const unsigned int offset)
++{
++ return AV_RB32((const uint8_t *)buf + (offset >> 3)) << (offset & 7);
++}
++#endif
++
++#if AV_GCC_VERSION_AT_LEAST(3,4) && !defined(hevc_clz32)
++#define hevc_clz32 hevc_clz32_builtin
++static av_always_inline unsigned int hevc_clz32_builtin(const uint32_t x)
++{
++ // __builtin_clz says it works on ints - so adjust if int is >32 bits long
++ return __builtin_clz(x) - (sizeof(int) * 8 - 32);
++}
++#endif
++
++// It is unlikely that we will ever need this but include for completeness
++#ifndef hevc_clz32
++static inline unsigned int hevc_clz32(unsigned int x)
++{
++ unsigned int n = 1;
++ if ((x & 0xffff0000) == 0) {
++ n += 16;
++ x <<= 16;
++ }
++ if ((x & 0xff000000) == 0) {
++ n += 8;
++ x <<= 8;
++ }
++ if ((x & 0xf0000000) == 0) {
++ n += 4;
++ x <<= 4;
++ }
++ if ((x & 0xc0000000) == 0) {
++ n += 2;
++ x <<= 2;
++ }
++ return n - ((x >> 31) & 1);
++}
++#endif
++
++static inline int cabac_overflow(const CABACContext * const cc)
++{
++ av_assert0(cc->bytestream >= cc->bytestream_start);
++ return cc->bytestream >= cc->bytestream_end + 4;
++}
++
++int ff_hevc_rpi_cabac_overflow(const HEVCRpiLocalContext * const lc)
++{
++ return cabac_overflow(&lc->cc);
++}
++
++#if !USE_BY22
++// If no by22 then _by22 functions will revert to normal and so _peek/_flush
++// will no longer be called but the setup calls will still exist and we want
++// to null them out
++#define bypass_start(s)
++#define bypass_finish(s)
++#else
++// Use BY22 for residual bypass block
++
++#define bypass_start(cc) get_cabac_by22_start(cc)
++#define bypass_finish(cc) get_cabac_by22_finish(cc)
++
++// BY22 notes that bypass is simply a divide into the bitstream and so we
++// can peek out large quantities of bits at once and treat the result as if
++// it was VLC. In many cases this will lead to O(1) processing rather than
++// O(n) though the setup and teardown is sufficiently expensive that it is
++// only worth using if we expect to be dealing with more than a few bits
++// The definition of "a few bits" will vary from platform to platform but
++// tests on ARM show that it probably isn't worth it for a single coded
++// residual, but is for >1 - it also seems likely that if there are
++// more residuals then they are likely to be bigger and this will make the
++// O(1) nature of the code more worthwhile.
++
++
++// Bypass block start
++// Must be called before _by22_peek is used as it sets the CABAC environment
++// into the correct state. _by22_finish must be called to return to 'normal'
++// (i.e. non-bypass) cabac decoding
++#ifndef get_cabac_by22_start
++static inline void get_cabac_by22_start(CABACContext * const c)
++{
++ const unsigned int bits = __builtin_ctz(c->low);
++ const uint32_t m = hevc_mem_bits32(c->bytestream, 0);
++ uint32_t x = (c->low << (22 - CABAC_BITS)) ^ ((m ^ 0x80000000U) >> (9 + CABAC_BITS - bits));
++#if !USE_BY22_DIV
++ const uint32_t inv = cabac_by22_inv_range[c->range & 0xff];
++#endif
++
++ c->bytestream -= (CABAC_BITS / 8);
++ c->by22.bits = bits;
++#if !USE_BY22_DIV
++ c->by22.range = c->range;
++ c->range = inv;
++#endif
++ c->low = x;
++}
++#endif
++
++// Bypass block finish
++// Must be called at the end of the bypass block to return to normal operation
++static inline void get_cabac_by22_finish(CABACContext * const c)
++{
++ unsigned int used = c->by22.bits;
++ unsigned int bytes_used = (used / CABAC_BITS) * (CABAC_BITS / 8);
++ unsigned int bits_used = used & (CABAC_BITS == 16 ? 15 : 7);
++
++ c->bytestream += bytes_used + (CABAC_BITS / 8);
++ c->low = (((uint32_t)c->low >> (22 - CABAC_BITS + bits_used)) | 1) << bits_used;
++#if !USE_BY22_DIV
++ c->range = c->by22.range;
++#endif
++}
++
++// Peek bypass bits
++// _by22_start must be called before _by22_peek is called and _by22_flush
++// must be called afterwards to flush any used bits
++// The actual number of valid bits returned is
++// min(<coded bypass block length>, CABAC_BY22_PEEK_BITS). CABAC_BY22_PEEK_BITS
++// will be at least 22 which should be long enough for any prefix or suffix
++// though probably not long enough for the worst case combination
++#ifndef get_cabac_by22_peek
++static inline uint32_t get_cabac_by22_peek(const CABACContext * const c)
++{
++#if USE_BY22_DIV
++ return ((unsigned int)c->low / (unsigned int)c->range) << 9;
++#else
++ uint32_t x = c->low & ~1U;
++ const uint32_t inv = c->range;
++
++ if (inv != 0)
++ x = (uint32_t)(((uint64_t)x * (uint64_t)inv) >> 32);
++
++ return x << 1;
++#endif
++}
++#endif
++
++// Flush bypass bits peeked by _by22_peek
++// Flush n bypass bits. n must be >= 1 to guarantee correct operation
++// val is an unmodified copy of whatever _by22_peek returned
++#ifndef get_cabac_by22_flush
++static inline void get_cabac_by22_flush(CABACContext * c, const unsigned int n, const uint32_t val)
++{
++ // Subtract the bits used & reshift up to the top of the word
++#if USE_BY22_DIV
++ const uint32_t low = (((unsigned int)c->low << n) - (((val >> (32 - n)) * (unsigned int)c->range) << 23));
++#else
++ const uint32_t low = (((uint32_t)c->low << n) - (((val >> (32 - n)) * c->by22.range) << 23));
++#endif
++
++ // and refill lower bits
++ // We will probably OR over some existing bits but that doesn't matter
++ c->by22.bits += n;
++ c->low = low | (hevc_mem_bits32(c->bytestream, c->by22.bits) >> 9);
++}
++#endif
++
++#endif // USE_BY22
++
++
++void ff_hevc_rpi_save_states(HEVCRpiContext *s, const HEVCRpiLocalContext * const lc)
++{
++ memcpy(s->cabac_save->rice, lc->stat_coeff, 4);
++ memcpy(s->cabac_save->state, lc->cabac_state, HEVC_CONTEXTS);
++}
++
++static void load_states(const HEVCRpiContext * const s, HEVCRpiLocalContext * const lc)
++{
++ memcpy(lc->stat_coeff, s->cabac_save->rice, 4);
++ memcpy(lc->cabac_state, s->cabac_save->state, HEVC_CONTEXTS);
++}
++
++int ff_hevc_rpi_cabac_init_decoder(HEVCRpiLocalContext * const lc)
++{
++ GetBitContext * const gb = &lc->gb;
++ skip_bits(gb, 1);
++ align_get_bits(gb);
++ return ff_init_cabac_decoder(&lc->cc,
++ gb->buffer + get_bits_count(gb) / 8,
++ (get_bits_left(gb) + 7) / 8);
++}
++
++static void cabac_init_state(const HEVCRpiContext * const s, HEVCRpiLocalContext * const lc)
++{
++ int init_type = 2 - s->sh.slice_type;
++ int i;
++
++ if (s->sh.cabac_init_flag && s->sh.slice_type != HEVC_SLICE_I)
++ init_type ^= 3;
++
++ for (i = 0; i < HEVC_CONTEXTS; i++) {
++ int init_value = init_values[init_type][i];
++ int m = (init_value >> 4) * 5 - 45;
++ int n = ((init_value & 15) << 3) - 16;
++ int pre = 2 * (((m * av_clip(s->sh.slice_qp, 0, 51)) >> 4) + n) - 127;
++
++ pre ^= pre >> 31;
++ if (pre > 124)
++ pre = 124 + (pre & 1);
++ lc->cabac_state[i] = pre;
++ }
++
++ for (i = 0; i < 4; i++)
++ lc->stat_coeff[i] = 0;
++}
++
++void ff_hevc_rpi_cabac_init(const HEVCRpiContext * const s, HEVCRpiLocalContext *const lc, const unsigned int ctb_flags)
++{
++ if (lc->cabac_init_req == 1 || (ctb_flags & CTB_TS_FLAGS_CIREQ) != 0)
++ {
++ lc->qPy_pred = s->sh.slice_qp;
++ cabac_init_state(s, lc);
++ }
++ else if ((ctb_flags & CTB_TS_FLAGS_CLOAD) != 0)
++ {
++ lc->qPy_pred = s->sh.slice_qp;
++ load_states(s, lc);
++ }
++ lc->cabac_init_req = 0;
++}
++
++#define GET_CABAC_LC(ctx) get_cabac(&lc->cc, lc->cabac_state + (ctx))
++
++int ff_hevc_rpi_get_cabac(CABACContext * const c, uint8_t * const state)
++{
++ return get_cabac_inline(c, state);
++}
++
++int ff_hevc_rpi_get_cabac_terminate(CABACContext * const c)
++{
++ return get_cabac_terminate(c);
++}
++
++int ff_hevc_rpi_sao_type_idx_decode(HEVCRpiLocalContext * const lc)
++{
++ if (!GET_CABAC_LC(elem_offset[SAO_TYPE_IDX]))
++ return 0;
++
++ if (!get_cabac_bypass(&lc->cc))
++ return SAO_BAND;
++ return SAO_EDGE;
++}
++
++int ff_hevc_rpi_sao_band_position_decode(HEVCRpiLocalContext * const lc)
++{
++ int i;
++ int value = get_cabac_bypass(&lc->cc);
++
++ for (i = 0; i < 4; i++)
++ value = (value << 1) | get_cabac_bypass(&lc->cc);
++ return value;
++}
++
++int ff_hevc_rpi_sao_offset_abs_decode(const HEVCRpiContext * const s, HEVCRpiLocalContext * const lc)
++{
++ int i = 0;
++ int length = (1 << (FFMIN(s->ps.sps->bit_depth, 10) - 5)) - 1;
++
++ while (i < length && get_cabac_bypass(&lc->cc))
++ i++;
++ return i;
++}
++
++int ff_hevc_rpi_sao_offset_sign_decode(HEVCRpiLocalContext * const lc)
++{
++ return get_cabac_bypass(&lc->cc);
++}
++
++int ff_hevc_rpi_sao_eo_class_decode(HEVCRpiLocalContext * const lc)
++{
++ int ret = get_cabac_bypass(&lc->cc) << 1;
++ ret |= get_cabac_bypass(&lc->cc);
++ return ret;
++}
++
++int ff_hevc_rpi_cu_qp_delta(HEVCRpiLocalContext * const lc)
++{
++ int val = 1;
++
++ if (get_cabac(&lc->cc, lc->cabac_state + HEVC_BIN_CU_QP_DELTA) == 0)
++ return 0;
++
++ while (val < 5 &&
++ get_cabac(&lc->cc, lc->cabac_state + HEVC_BIN_CU_QP_DELTA + 1) != 0)
++ val++;
++
++ if (val >= 5) {
++ unsigned int k = 0;
++ while (k < CABAC_MAX_BIN && get_cabac_bypass(&lc->cc)) {
++ val += 1 << k;
++ k++;
++ }
++// if (k == CABAC_MAX_BIN)
++// av_log(s->avctx, AV_LOG_ERROR, "CABAC_MAX_BIN : %d\n", k);
++
++ while (k--)
++ val += get_cabac_bypass(&lc->cc) << k;
++ }
++ return get_cabac_bypass(&lc->cc) ? -val : val;
++}
++
++int ff_hevc_rpi_cu_chroma_qp_offset_idx(const HEVCRpiContext * const s, HEVCRpiLocalContext * const lc)
++{
++ int c_max= FFMAX(5, s->ps.pps->chroma_qp_offset_list_len_minus1);
++ int i = 0;
++
++ while (i < c_max && GET_CABAC_LC(elem_offset[CU_CHROMA_QP_OFFSET_IDX]))
++ i++;
++
++ return i;
++}
++
++int ff_hevc_rpi_part_mode_decode(const HEVCRpiContext * const s, HEVCRpiLocalContext * const lc, const int log2_cb_size)
++{
++ if (GET_CABAC_LC(elem_offset[PART_MODE])) // 1
++ return PART_2Nx2N;
++ if (log2_cb_size == s->ps.sps->log2_min_cb_size) {
++ if (lc->cu.pred_mode == MODE_INTRA) // 0
++ return PART_NxN;
++ if (GET_CABAC_LC(elem_offset[PART_MODE] + 1)) // 01
++ return PART_2NxN;
++ if (log2_cb_size == 3) // 00
++ return PART_Nx2N;
++ if (GET_CABAC_LC(elem_offset[PART_MODE] + 2)) // 001
++ return PART_Nx2N;
++ return PART_NxN; // 000
++ }
++
++ if (!s->ps.sps->amp_enabled_flag) {
++ if (GET_CABAC_LC(elem_offset[PART_MODE] + 1)) // 01
++ return PART_2NxN;
++ return PART_Nx2N;
++ }
++
++ if (GET_CABAC_LC(elem_offset[PART_MODE] + 1)) { // 01X, 01XX
++ if (GET_CABAC_LC(elem_offset[PART_MODE] + 3)) // 011
++ return PART_2NxN;
++ if (get_cabac_bypass(&lc->cc)) // 0101
++ return PART_2NxnD;
++ return PART_2NxnU; // 0100
++ }
++
++ if (GET_CABAC_LC(elem_offset[PART_MODE] + 3)) // 001
++ return PART_Nx2N;
++ if (get_cabac_bypass(&lc->cc)) // 0001
++ return PART_nRx2N;
++ return PART_nLx2N; // 0000
++}
++
++int ff_hevc_rpi_mpm_idx_decode(HEVCRpiLocalContext * const lc)
++{
++ int i = 0;
++ while (i < 2 && get_cabac_bypass(&lc->cc))
++ i++;
++ return i;
++}
++
++int ff_hevc_rpi_rem_intra_luma_pred_mode_decode(HEVCRpiLocalContext * const lc)
++{
++ int i;
++ int value = get_cabac_bypass(&lc->cc);
++
++ for (i = 0; i < 4; i++)
++ value = (value << 1) | get_cabac_bypass(&lc->cc);
++ return value;
++}
++
++int ff_hevc_rpi_intra_chroma_pred_mode_decode(HEVCRpiLocalContext * const lc)
++{
++ int ret;
++ if (!GET_CABAC_LC(elem_offset[INTRA_CHROMA_PRED_MODE]))
++ return 4;
++
++ ret = get_cabac_bypass(&lc->cc) << 1;
++ ret |= get_cabac_bypass(&lc->cc);
++ return ret;
++}
++
++int ff_hevc_rpi_merge_idx_decode(const HEVCRpiContext * const s, HEVCRpiLocalContext * const lc)
++{
++ int i = GET_CABAC_LC(elem_offset[MERGE_IDX]);
++
++ if (i != 0) {
++ while (i < s->sh.max_num_merge_cand-1 && get_cabac_bypass(&lc->cc))
++ i++;
++ }
++ return i;
++}
++
++int ff_hevc_rpi_inter_pred_idc_decode(HEVCRpiLocalContext * const lc, int nPbW, int nPbH)
++{
++ if (nPbW + nPbH == 12)
++ return GET_CABAC_LC(elem_offset[INTER_PRED_IDC] + 4);
++ if (GET_CABAC_LC(elem_offset[INTER_PRED_IDC] + lc->ct_depth))
++ return PRED_BI;
++
++ return GET_CABAC_LC(elem_offset[INTER_PRED_IDC] + 4);
++}
++
++int ff_hevc_rpi_ref_idx_lx_decode(HEVCRpiLocalContext * const lc, const int num_ref_idx_lx)
++{
++ int i = 0;
++ int max = num_ref_idx_lx - 1;
++ int max_ctx = FFMIN(max, 2);
++
++ while (i < max_ctx && GET_CABAC_LC(elem_offset[REF_IDX_L0] + i))
++ i++;
++ if (i == 2) {
++ while (i < max && get_cabac_bypass(&lc->cc))
++ i++;
++ }
++
++ return i;
++}
++
++static av_always_inline int abs_mvd_greater0_flag_decode(HEVCRpiLocalContext * const lc)
++{
++ return GET_CABAC_LC(elem_offset[ABS_MVD_GREATER0_FLAG]);
++}
++
++static av_always_inline int abs_mvd_greater1_flag_decode(HEVCRpiLocalContext * const lc)
++{
++ return GET_CABAC_LC(elem_offset[ABS_MVD_GREATER1_FLAG] + 1);
++}
++
++#if !USE_BY22
++static av_always_inline int mvd_decode(HEVCRpiLocalContext * const lc)
++{
++ int ret = 2;
++ int k = 1;
++
++ while (k < CABAC_MAX_BIN && get_cabac_bypass(&lc->cc)) {
++ ret += 1U << k;
++ k++;
++ }
++ if (k == CABAC_MAX_BIN) {
++ av_log(NULL, AV_LOG_ERROR, "CABAC_MAX_BIN : %d\n", k);
++ return 0;
++ }
++
++ while (k--)
++ ret += get_cabac_bypass(&lc->cc) << k;
++ return get_cabac_bypass_sign(&lc->cc, -ret);
++}
++#endif
++
++static av_always_inline int mvd_sign_flag_decode(HEVCRpiLocalContext * const lc)
++{
++ return get_cabac_bypass_sign(&lc->cc, -1);
++}
++
++static int hevc_transform_skip_flag_decode(HEVCRpiLocalContext * const lc, int c_idx_nz)
++{
++ return GET_CABAC_LC(elem_offset[TRANSFORM_SKIP_FLAG] + c_idx_nz);
++}
++
++static int explicit_rdpcm_flag_decode(HEVCRpiLocalContext * const lc, int c_idx_nz)
++{
++ return GET_CABAC_LC(elem_offset[EXPLICIT_RDPCM_FLAG] + c_idx_nz);
++}
++
++static int explicit_rdpcm_dir_flag_decode(HEVCRpiLocalContext * const lc, int c_idx_nz)
++{
++ return GET_CABAC_LC(elem_offset[EXPLICIT_RDPCM_DIR_FLAG] + c_idx_nz);
++}
++
++
++int ff_hevc_rpi_log2_res_scale_abs(HEVCRpiLocalContext * const lc, const int idx) {
++ int i =0;
++
++ while (i < 4 && GET_CABAC_LC(elem_offset[LOG2_RES_SCALE_ABS] + 4 * idx + i))
++ i++;
++
++ return i;
++}
++
++static av_always_inline void last_significant_coeff_xy_prefix_decode(HEVCRpiLocalContext * const lc, int c_idx_nz,
++ int log2_size, int *last_scx_prefix, int *last_scy_prefix)
++{
++ int i = 0;
++ int max = (log2_size << 1) - 1;
++ int ctx_offset, ctx_shift;
++
++ if (!c_idx_nz) {
++ ctx_offset = 3 * (log2_size - 2) + ((log2_size - 1) >> 2);
++ ctx_shift = (log2_size + 1) >> 2;
++ } else {
++ ctx_offset = 15;
++ ctx_shift = log2_size - 2;
++ }
++ while (i < max &&
++ GET_CABAC_LC(elem_offset[LAST_SIGNIFICANT_COEFF_X_PREFIX] + (i >> ctx_shift) + ctx_offset))
++ i++;
++ *last_scx_prefix = i;
++
++ i = 0;
++ while (i < max &&
++ GET_CABAC_LC(elem_offset[LAST_SIGNIFICANT_COEFF_Y_PREFIX] + (i >> ctx_shift) + ctx_offset))
++ i++;
++ *last_scy_prefix = i;
++}
++
++static av_always_inline int last_significant_coeff_suffix_decode(HEVCRpiLocalContext * const lc,
++ int last_significant_coeff_prefix)
++{
++ int i;
++ int length = (last_significant_coeff_prefix >> 1) - 1;
++ int value = get_cabac_bypass(&lc->cc);
++
++ for (i = 1; i < length; i++)
++ value = (value << 1) | get_cabac_bypass(&lc->cc);
++ return value;
++}
++
++static av_always_inline int significant_coeff_group_flag_decode(HEVCRpiLocalContext * const lc, int c_idx_nz, int ctx_cg)
++{
++ int inc;
++
++ inc = (ctx_cg != 0) + (c_idx_nz << 1);
++
++ return GET_CABAC_LC(elem_offset[SIGNIFICANT_COEFF_GROUP_FLAG] + inc);
++}
++
++static av_always_inline int significant_coeff_flag_decode_0(HEVCRpiLocalContext * const lc, int offset)
++{
++ return GET_CABAC_LC(elem_offset[SIGNIFICANT_COEFF_FLAG] + offset);
++}
++
++#if !USE_BY22
++#define coeff_abs_level_remaining_decode_bypass(s,r) coeff_abs_level_remaining_decode(s, r)
++#endif
++
++
++#ifndef coeff_abs_level_remaining_decode_bypass
++static int coeff_abs_level_remaining_decode_bypass(CABACContext * const c, const unsigned int rice_param)
++{
++ uint32_t y;
++ unsigned int prefix;
++ unsigned int last_coeff_abs_level_remaining;
++ unsigned int n;
++
++ y = get_cabac_by22_peek(c);
++ prefix = hevc_clz32(~y);
++ // y << prefix will always have top bit 0
++
++ if (prefix < 3) {
++ const unsigned int suffix = (y << prefix) >> (31 - rice_param);
++ last_coeff_abs_level_remaining = (prefix << rice_param) + suffix;
++ n = prefix + 1 + rice_param;
++ }
++ else if (prefix * 2 + rice_param <= CABAC_BY22_PEEK_BITS + 2)
++ {
++ const uint32_t suffix = ((y << prefix) | 0x80000000) >> (34 - (prefix + rice_param));
++
++ last_coeff_abs_level_remaining = (2 << rice_param) + suffix;
++ n = prefix * 2 + rice_param - 2;
++ }
++ else {
++ unsigned int suffix;
++
++ get_cabac_by22_flush(c, prefix, y);
++ y = get_cabac_by22_peek(c);
++
++ suffix = (y | 0x80000000) >> (34 - (prefix + rice_param));
++ last_coeff_abs_level_remaining = (2 << rice_param) + suffix;
++ n = prefix + rice_param - 2;
++ }
++
++ get_cabac_by22_flush(c, n, y);
++
++ return last_coeff_abs_level_remaining;
++}
++#endif
++
++static int coeff_abs_level_remaining_decode(CABACContext * const c, int rc_rice_param)
++{
++ int prefix = 0;
++ int suffix = 0;
++ int last_coeff_abs_level_remaining;
++ int i;
++
++ while (prefix < CABAC_MAX_BIN && get_cabac_bypass(c))
++ prefix++;
++ if (prefix == CABAC_MAX_BIN) {
++// av_log(s->avctx, AV_LOG_ERROR, "CABAC_MAX_BIN : %d\n", prefix);
++ return 0;
++ }
++
++ if (prefix < 3) {
++ for (i = 0; i < rc_rice_param; i++)
++ suffix = (suffix << 1) | get_cabac_bypass(c);
++ last_coeff_abs_level_remaining = (prefix << rc_rice_param) + suffix;
++ } else {
++ int prefix_minus3 = prefix - 3;
++ for (i = 0; i < prefix_minus3 + rc_rice_param; i++)
++ suffix = (suffix << 1) | get_cabac_bypass(c);
++ last_coeff_abs_level_remaining = (((1 << prefix_minus3) + 3 - 1)
++ << rc_rice_param) + suffix;
++ }
++
++ return last_coeff_abs_level_remaining;
++}
++
++#if !USE_BY22
++#define coeff_sign_flag_decode_bypass coeff_sign_flag_decode
++static inline uint32_t coeff_sign_flag_decode(CABACContext * const c, const unsigned int nb)
++{
++ unsigned int i;
++ uint32_t ret = 0;
++
++ for (i = 0; i < nb; i++)
++ ret = (ret << 1) | get_cabac_bypass(c);
++
++ return ret << (32 - nb);
++}
++#endif
++
++#ifndef coeff_sign_flag_decode_bypass
++static inline uint32_t coeff_sign_flag_decode_bypass(CABACContext * const c, const unsigned int nb)
++{
++ uint32_t y;
++ y = get_cabac_by22_peek(c);
++ get_cabac_by22_flush(c, nb, y);
++ return y & ~(0xffffffffU >> nb);
++}
++#endif
++
++
++#ifndef get_cabac_greater1_bits
++static inline unsigned int get_cabac_greater1_bits(CABACContext * const c, const unsigned int n,
++ uint8_t * const state0)
++{
++ unsigned int i;
++ unsigned int rv = 0;
++ for (i = 0; i != n; ++i) {
++ const unsigned int idx = rv != 0 ? 0 : i < 3 ? i + 1 : 3;
++ const unsigned int b = get_cabac(c, state0 + idx);
++ rv = (rv << 1) | b;
++ }
++ return rv;
++}
++#endif
++
++
++// N.B. levels returned are the values assuming coeff_abs_level_remaining
++// is uncoded, so 1 must be added if it is coded. sum_abs also reflects
++// this version of events.
++static inline uint32_t get_greaterx_bits(HEVCRpiLocalContext * const lc, const unsigned int n_end, int * const levels,
++ int * const pprev_subset_coded, int * const psum,
++ const unsigned int idx0_gt1, const unsigned int idx_gt2)
++{
++ CABACContext * const c = &lc->cc;
++ uint8_t * const state0 = lc->cabac_state + idx0_gt1;
++ uint8_t * const state_gt2 = lc->cabac_state + idx_gt2;
++ unsigned int rv;
++ unsigned int i;
++ const unsigned int n = FFMIN(n_end, 8);
++
++ // Really this is i != n but the simple unconditional loop is cheaper
++ // and faster
++ for (i = 0; i != 8; ++i)
++ levels[i] = 1;
++
++ rv = get_cabac_greater1_bits(c, n, state0);
++
++ *pprev_subset_coded = 0;
++ *psum = n;
++
++ rv <<= (32 - n);
++ if (rv != 0)
++ {
++ *pprev_subset_coded = 1;
++ *psum = n + 1;
++ i = hevc_clz32(rv);
++ levels[i] = 2;
++ if (get_cabac(c, state_gt2) == 0)
++ {
++ // Unset first coded bit
++ rv &= ~(0x80000000U >> i);
++ }
++ }
++
++ if (n_end > 8) {
++ const unsigned int g8 = n_end - 8;
++ rv |= ((1 << g8) - 1) << (24 - g8);
++ for (i = 0; i != g8; ++i) {
++ levels[i + 8] = 0;
++ }
++ }
++
++ return rv;
++}
++
++// extended_precision_processing_flag must be false given we are
++// putting the result into a 16-bit array
++// So trans_coeff_level must fit in 16 bits too (7.4.9.1 definition of coeff_abs_level_remaining)
++// scale_m is uint8_t
++//
++// scale is [40 - 72] << [0..12] based on qp- worst case is (45 << 12)
++// or it can be 2 (if we have transquant_bypass)
++// shift is set to one less than we really want but would normally be
++// s->ps.sps->bit_depth (max 16, min 8) + log2_trafo_size (max 5, min 2?) - 5 = max 16 min 5?
++// however the scale shift is substracted from shift to a min 0 so scale_m worst = 45 << 6
++// This can still theoretically lead to overflow but the coding would have to be very odd (& inefficient)
++// to achieve it
++
++#ifndef trans_scale_sat
++static inline int trans_scale_sat(const int level, const unsigned int scale, const unsigned int scale_m, const unsigned int shift)
++{
++ return av_clip_int16((((level * (int)(scale * scale_m)) >> shift) + 1) >> 1);
++}
++#endif
++
++
++#ifndef update_rice
++static inline void update_rice(uint8_t * const stat_coeff,
++ const unsigned int last_coeff_abs_level_remaining,
++ const unsigned int c_rice_param)
++{
++ const unsigned int x = (last_coeff_abs_level_remaining << 1) >> c_rice_param;
++ if (x >= 6)
++ (*stat_coeff)++;
++ else if (x == 0 && *stat_coeff > 0)
++ (*stat_coeff)--;
++}
++#endif
++
++
++// n must be > 0 on entry
++#ifndef get_cabac_sig_coeff_flag_idxs
++static inline uint8_t * get_cabac_sig_coeff_flag_idxs(CABACContext * const c, uint8_t * const state0,
++ unsigned int n,
++ const uint8_t const * ctx_map,
++ uint8_t * p)
++{
++ do {
++ if (get_cabac(c, state0 + ctx_map[n]))
++ *p++ = n;
++ } while (--n != 0);
++ return p;
++}
++#endif
++
++
++static int get_sig_coeff_flag_idxs(CABACContext * const c, uint8_t * const state0,
++ unsigned int n,
++ const uint8_t const * ctx_map,
++ uint8_t * const flag_idx)
++{
++ int rv;
++
++ rv = get_cabac_sig_coeff_flag_idxs(c, state0, n, ctx_map, flag_idx) - flag_idx;
++
++ return rv;
++}
++
++#define H4x4(x0, x1, x2, x3, x4, x5, x6, x7, x8, x9, x10, x11, x12, x13, x14, x15) {\
++ x0, x1, x2, x3,\
++ x4, x5, x6, x7,\
++ x8, x9, x10, x11,\
++ x12, x13, x14, x15}
++
++#define V4x4(x0, x1, x2, x3, x4, x5, x6, x7, x8, x9, x10, x11, x12, x13, x14, x15) {\
++ x0, x4, x8, x12,\
++ x1, x5, x9, x13,\
++ x2, x6, x10, x14,\
++ x3, x7, x11, x15}
++
++#define D4x4(x0, x1, x2, x3, x4, x5, x6, x7, x8, x9, x10, x11, x12, x13, x14, x15) {\
++ x0, x4, x1, x8,\
++ x5, x2, x12, x9,\
++ x6, x3, x13, x10,\
++ x7, x14, x11, x15}
++
++
++static inline int next_subset(HEVCRpiLocalContext * const lc, int i, const int c_idx_nz,
++ uint8_t * const significant_coeff_group_flag,
++ const uint8_t * const scan_x_cg, const uint8_t * const scan_y_cg,
++ int * const pPrev_sig)
++{
++ while (--i >= 0) {
++ uint8_t * const gf_y = scan_y_cg[i] + significant_coeff_group_flag;
++ const unsigned int x_cg = scan_x_cg[i];
++
++ // For the flag decode we only care about Z/NZ but
++ // we use the full Right * 2 + Down when calculating
++ // significant coeff flags so we obtain it here.
++ //
++ // The group flag array is one longer than it needs to
++ // be so we don't need to check for y_cg limits
++ const unsigned int prev_sig = ((gf_y[0] >> x_cg) & 2) | ((gf_y[1] >> x_cg) & 1);
++
++ if (i == 0 ||
++ significant_coeff_group_flag_decode(lc, c_idx_nz, prev_sig))
++ {
++ gf_y[0] |= (1 << x_cg);
++ *pPrev_sig = prev_sig;
++ break;
++ }
++ }
++
++ return i;
++}
++
++static void rpi_add_residual(const HEVCRpiContext *const s, HEVCRpiJob * const jb,
++ const unsigned int log2_trafo_size, const unsigned int c_idx,
++ const unsigned int x0, const unsigned int y0, const int16_t * const coeffs)
++{
++ const AVFrame * const frame = s->frame;
++ const unsigned int stride = frame_stride1(s->frame, c_idx);
++ const unsigned int x = x0 >> ctx_hshift(s, c_idx);
++ const unsigned int y = y0 >> ctx_vshift(s, c_idx);
++ const int is_sliced = 1; // av_rpi_is_sand_frame(frame);
++ uint8_t * const dst = !is_sliced ?
++ s->frame->data[c_idx] + y * stride + (x << s->ps.sps->pixel_shift) :
++ c_idx == 0 ?
++ av_rpi_sand_frame_pos_y(frame, x, y) :
++ av_rpi_sand_frame_pos_c(frame, x, y);
++
++ const unsigned int i = jb->intra.n;
++ HEVCPredCmd *const pc = jb->intra.cmds + i - 1;
++
++ if (i != 0 && c_idx == 2 && pc->type == RPI_PRED_ADD_RESIDUAL_U &&
++ pc->ta.dst == dst)
++ {
++ av_assert1(pc->size == log2_trafo_size &&
++ pc->c_idx == 1 &&
++ pc->ta.stride == stride);
++
++ pc->type = RPI_PRED_ADD_RESIDUAL_C;
++ }
++ else if (i != 0 && c_idx == 2 && pc->type == RPI_PRED_ADD_DC_U &&
++ pc->dc.dst == dst)
++ {
++ const int16_t dc = (int16_t)pc->dc.dc; // Discard top bits
++ av_assert1(pc->size == log2_trafo_size &&
++ pc->c_idx == 1 &&
++ pc->dc.stride == stride);
++
++ // Rewrite as add residual - must rewrite all fields as different union member
++ pc->type = RPI_PRED_ADD_RESIDUAL_V;
++ pc->ta.buf = coeffs;
++ pc->ta.dst = dst;
++ pc->ta.stride = stride;
++ pc->ta.dc = dc;
++ }
++ else
++ {
++ HEVCPredCmd * const cmd = pc + 1;
++ jb->intra.n = i + 1;
++
++ cmd->type = RPI_PRED_ADD_RESIDUAL + (is_sliced ? c_idx : 0);
++ cmd->size = log2_trafo_size;
++ cmd->ta.buf = coeffs;
++ cmd->ta.dst = dst;
++ cmd->ta.stride = stride;
++ cmd->ta.dc = 0;
++ }
++}
++
++
++static void rpi_add_dc(const HEVCRpiContext * const s, HEVCRpiJob * const jb,
++ const unsigned int log2_trafo_size, const unsigned int c_idx,
++ const unsigned int x0, const unsigned int y0, const int16_t * const coeffs)
++{
++ const AVFrame * const frame = s->frame;
++ const unsigned int stride = frame_stride1(s->frame, c_idx);
++ const unsigned int x = x0 >> ctx_hshift(s, c_idx);
++ const unsigned int y = y0 >> ctx_vshift(s, c_idx);
++ const int is_sliced = 1;
++ uint8_t * const dst = !is_sliced ?
++ s->frame->data[c_idx] + y * stride + (x << s->ps.sps->pixel_shift) :
++ c_idx == 0 ?
++ av_rpi_sand_frame_pos_y(frame, x, y) :
++ av_rpi_sand_frame_pos_c(frame, x, y);
++
++ const unsigned int shift = FFMAX(14 - s->ps.sps->bit_depth, 0);
++ const int coeff = (coeffs[0] + (1 | (1 << shift))) >> (shift + 1);
++
++ const unsigned int i = jb->intra.n;
++ HEVCPredCmd *const pc = jb->intra.cmds + i - 1;
++
++ if (i != 0 && c_idx == 2 && pc->type == RPI_PRED_ADD_RESIDUAL_U &&
++ pc->ta.dst == dst)
++ {
++ av_assert1(pc->size == log2_trafo_size &&
++ pc->c_idx == 1 &&
++ pc->ta.stride == stride);
++
++ pc->ta.dc = (int16_t)coeff;
++ }
++ else if (i != 0 && c_idx == 2 && pc->type == RPI_PRED_ADD_DC_U &&
++ pc->dc.dst == dst)
++ {
++ av_assert1(pc->size == log2_trafo_size &&
++ pc->c_idx == 1 &&
++ pc->dc.stride == stride &&
++ (pc->dc.dc & ~0xffff) == 0);
++
++ pc->dc.dc |= (coeff << 16);
++ }
++ else
++ {
++ HEVCPredCmd * const cmd = pc + 1;
++ jb->intra.n = i + 1;
++
++ cmd->type = RPI_PRED_ADD_DC + c_idx;
++ cmd->size = log2_trafo_size;
++ cmd->dc.dst = dst;
++ cmd->dc.stride = stride;
++ cmd->dc.dc = c_idx == 0 ? coeff : c_idx == 2 ? coeff << 16 : coeff & 0xffff;
++ }
++}
++
++
++void ff_hevc_rpi_hls_residual_coding(const HEVCRpiContext * const s, HEVCRpiLocalContext * const lc,
++ const int x0, const int y0,
++ const int log2_trafo_size, const enum ScanType scan_idx,
++ const int c_idx)
++{
++ int trans_skip_or_bypass = lc->cu.cu_transquant_bypass_flag;
++
++ int last_significant_coeff_x, last_significant_coeff_y;
++ int num_coeff = 0;
++ int prev_subset_coded = 0;
++
++ int num_last_subset;
++ int x_cg_last_sig, y_cg_last_sig;
++
++ const uint8_t *scan_x_cg, *scan_y_cg;
++ const xy_off_t * const scan_xy_off = off_xys[scan_idx][log2_trafo_size - 2];
++
++ int use_vpu;
++#if RPI_COMPRESS_COEFFS
++ int num_nonzero = 0;
++ int use_compress = 0;
++ int *coeffs32;
++#endif
++ int use_dc = 0;
++ int16_t *coeffs;
++ uint8_t significant_coeff_group_flag[9] = {0}; // Allow 1 final byte that is always zero
++ int explicit_rdpcm_flag = 0;
++ int explicit_rdpcm_dir_flag;
++
++ int i;
++ int shift,scale;
++ const uint8_t *scale_matrix = NULL;
++ uint8_t dc_scale;
++ const int c_idx_nz = (c_idx != 0);
++ const int pred_mode_intra = c_idx_nz ? lc->tu.intra_pred_mode_c : lc->tu.intra_pred_mode;
++ int prev_sig = 0;
++ int may_hide_sign;
++
++ int16_t dummy_coeffs[16];
++
++ // Derive QP for dequant
++ if (!lc->cu.cu_transquant_bypass_flag) {
++ may_hide_sign = s->ps.pps->sign_data_hiding_flag;
++
++ if (s->ps.pps->transform_skip_enabled_flag &&
++ log2_trafo_size <= s->ps.pps->log2_max_transform_skip_block_size) {
++ int transform_skip_flag = hevc_transform_skip_flag_decode(lc, c_idx_nz);
++ if (transform_skip_flag) {
++ trans_skip_or_bypass = 1;
++ if (lc->cu.pred_mode == MODE_INTRA &&
++ s->ps.sps->implicit_rdpcm_enabled_flag &&
++ (pred_mode_intra == 10 || pred_mode_intra == 26)) {
++ may_hide_sign = 0;
++ }
++ }
++ }
++
++ {
++ static const uint8_t level_scale[8] = {
++ 40, 45, 51, 57, 64, 72, 0, 0 // Pad to 8
++ };
++ const int qp6 = (int8_t)lc->tu.qp_divmod6[c_idx][lc->qp_y];
++
++ // Shift is set to one less than will actually occur as the scale
++ // and saturate step adds 1 and then shifts right again
++ scale = level_scale[qp6 & 7];
++// shift = s->ps.sps->bit_depth + log2_trafo_size - (int)(qp6 >> 3);
++ shift = log2_trafo_size - (qp6 >> 3);
++
++ if (shift < 0) {
++ scale <<= -shift;
++ shift = 0;
++ }
++ }
++
++ if (s->ps.sps->scaling_list_enable_flag && !(trans_skip_or_bypass && log2_trafo_size > 2)) {
++ const ScalingList * const sl = s->ps.pps->scaling_list_data_present_flag ?
++ &s->ps.pps->scaling_list : &s->ps.sps->scaling_list;
++ const unsigned int matrix_id =
++ lc->cu.pred_mode != MODE_INTRA ? 3 + c_idx : c_idx;
++
++ scale_matrix = sl->sl[log2_trafo_size - 2][matrix_id];
++ dc_scale = scale_matrix[0];
++ if (log2_trafo_size >= 4)
++ dc_scale = sl->sl_dc[log2_trafo_size - 4][matrix_id];
++ }
++ else
++ {
++ static const uint8_t sixteen_scale[64] = {
++ 16, 16, 16, 16, 16, 16, 16, 16,
++ 16, 16, 16, 16, 16, 16, 16, 16,
++ 16, 16, 16, 16, 16, 16, 16, 16,
++ 16, 16, 16, 16, 16, 16, 16, 16,
++ 16, 16, 16, 16, 16, 16, 16, 16,
++ 16, 16, 16, 16, 16, 16, 16, 16,
++ 16, 16, 16, 16, 16, 16, 16, 16,
++ 16, 16, 16, 16, 16, 16, 16, 16
++ };
++ scale_matrix = sixteen_scale;
++ dc_scale = 16;
++ }
++ } else {
++ static const uint8_t unit_scale[64] = {
++ 1, 1, 1, 1, 1, 1, 1, 1,
++ 1, 1, 1, 1, 1, 1, 1, 1,
++ 1, 1, 1, 1, 1, 1, 1, 1,
++ 1, 1, 1, 1, 1, 1, 1, 1,
++ 1, 1, 1, 1, 1, 1, 1, 1,
++ 1, 1, 1, 1, 1, 1, 1, 1,
++ 1, 1, 1, 1, 1, 1, 1, 1,
++ 1, 1, 1, 1, 1, 1, 1, 1,
++ };
++ scale_matrix = unit_scale;
++ shift = 0;
++ scale = 2; // We will shift right to kill this
++ dc_scale = 1;
++
++ may_hide_sign = 0;
++ }
++
++
++
++
++ if (lc->cu.pred_mode == MODE_INTER && s->ps.sps->explicit_rdpcm_enabled_flag &&
++ trans_skip_or_bypass) {
++ explicit_rdpcm_flag = explicit_rdpcm_flag_decode(lc, c_idx_nz);
++ if (explicit_rdpcm_flag) {
++ may_hide_sign = 0;
++ explicit_rdpcm_dir_flag = explicit_rdpcm_dir_flag_decode(lc, c_idx_nz);
++ }
++ }
++
++ last_significant_coeff_xy_prefix_decode(lc, c_idx_nz, log2_trafo_size,
++ &last_significant_coeff_x, &last_significant_coeff_y);
++
++ if (last_significant_coeff_x > 3) {
++ int suffix = last_significant_coeff_suffix_decode(lc, last_significant_coeff_x);
++ last_significant_coeff_x = (1 << ((last_significant_coeff_x >> 1) - 1)) *
++ (2 + (last_significant_coeff_x & 1)) +
++ suffix;
++ }
++
++ if (last_significant_coeff_y > 3) {
++ int suffix = last_significant_coeff_suffix_decode(lc, last_significant_coeff_y);
++ last_significant_coeff_y = (1 << ((last_significant_coeff_y >> 1) - 1)) *
++ (2 + (last_significant_coeff_y & 1)) +
++ suffix;
++ }
++
++ if (scan_idx == SCAN_VERT)
++ FFSWAP(int, last_significant_coeff_x, last_significant_coeff_y);
++
++ x_cg_last_sig = last_significant_coeff_x >> 2;
++ y_cg_last_sig = last_significant_coeff_y >> 2;
++
++ switch (scan_idx) {
++ case SCAN_DIAG: {
++ int last_x_c = last_significant_coeff_x & 3;
++ int last_y_c = last_significant_coeff_y & 3;
++
++ num_coeff = diag_scan4x4_inv[last_y_c][last_x_c];
++
++ switch (log2_trafo_size) {
++ case 2:
++ scan_x_cg = scan_1x1;
++ scan_y_cg = scan_1x1;
++ break;
++ case 3:
++ num_coeff += diag_scan2x2_inv[y_cg_last_sig][x_cg_last_sig] << 4;
++ scan_x_cg = diag_scan2x2_x;
++ scan_y_cg = diag_scan2x2_y;
++ break;
++ case 4:
++ num_coeff += diag_scan4x4_inv[y_cg_last_sig][x_cg_last_sig] << 4;
++ scan_x_cg = ff_hevc_rpi_diag_scan4x4_x;
++ scan_y_cg = ff_hevc_rpi_diag_scan4x4_y;
++ break;
++ case 5:
++ default:
++ num_coeff += diag_scan8x8_inv[y_cg_last_sig][x_cg_last_sig] << 4;
++ scan_x_cg = ff_hevc_rpi_diag_scan8x8_x;
++ scan_y_cg = ff_hevc_rpi_diag_scan8x8_y;
++ break;
++ }
++ break;
++ }
++ case SCAN_HORIZ:
++ scan_x_cg = horiz_scan2x2_x;
++ scan_y_cg = horiz_scan2x2_y;
++ num_coeff = horiz_scan8x8_inv[last_significant_coeff_y][last_significant_coeff_x];
++ break;
++ default: //SCAN_VERT
++ scan_x_cg = horiz_scan2x2_y;
++ scan_y_cg = horiz_scan2x2_x;
++ num_coeff = horiz_scan8x8_inv[last_significant_coeff_x][last_significant_coeff_y];
++ break;
++ }
++ num_coeff++;
++ num_last_subset = (num_coeff - 1) >> 4;
++
++ significant_coeff_group_flag[y_cg_last_sig] = 1 << x_cg_last_sig; // 1st subset always significant
++
++ {
++ const unsigned int ccount = 1 << (log2_trafo_size * 2);
++ const int special = trans_skip_or_bypass /* || lc->tu.cross_pf */; // These need special processing
++ use_vpu = 0;
++ use_dc = (num_coeff == 1) && !special &&
++ !(lc->cu.pred_mode == MODE_INTRA && c_idx == 0 && log2_trafo_size == 2);
++
++ if (use_dc) {
++ // Just need a little empty space
++ coeffs = dummy_coeffs;
++ // No need to clear
++ }
++ else
++ {
++ use_vpu = !special && log2_trafo_size >= 4;
++#if RPI_COMPRESS_COEFFS
++ use_compress = use_vpu && lc->jb0->coeffs.s[log2_trafo_size - 2].packed;
++#endif
++ coeffs = rpi_alloc_coeff_buf(lc->jb0, !use_vpu ? 0 : log2_trafo_size - 2, ccount);
++#if RPI_COMPRESS_COEFFS
++ coeffs32 = (int*)coeffs;
++ if (!use_compress)
++#endif
++#if HAVE_NEON
++ rpi_zap_coeff_vals_neon(coeffs, log2_trafo_size - 2);
++#else
++ memset(coeffs, 0, ccount * sizeof(int16_t));
++#endif
++ }
++ }
++
++ i = num_last_subset;
++ do {
++ int implicit_non_zero_coeff = 0;
++ int n_end;
++
++ uint8_t significant_coeff_flag_idx[16];
++ unsigned int nb_significant_coeff_flag = 0;
++
++ if (i == num_last_subset) {
++ // First time through
++ int last_scan_pos = num_coeff - (i << 4) - 1;
++ n_end = last_scan_pos - 1;
++ significant_coeff_flag_idx[0] = last_scan_pos;
++ nb_significant_coeff_flag = 1;
++ } else {
++ n_end = 15;
++ implicit_non_zero_coeff = (i != 0);
++ }
++
++ if (n_end >= 0) {
++ static const uint8_t ctx_idx_maps_ts2[3][16] = {
++ D4x4(0, 1, 4, 5, 2, 3, 4, 5, 6, 6, 8, 8, 7, 7, 8, 8), // log2_trafo_size == 2
++ H4x4(0, 1, 4, 5, 2, 3, 4, 5, 6, 6, 8, 8, 7, 7, 8, 8), // log2_trafo_size == 2
++ V4x4(0, 1, 4, 5, 2, 3, 4, 5, 6, 6, 8, 8, 7, 7, 8, 8) // log2_trafo_size == 2
++ };
++ // N.B. prev_sig = Right * 2 + Down
++ static const uint8_t ctx_idx_maps[3][4][16] = {
++ {
++ D4x4(1, 1, 1, 0, 1, 1, 0, 0, 1, 0, 0, 0, 0, 0, 0, 0), // prev_sig == 0
++ D4x4(2, 1, 0, 0, 2, 1, 0, 0, 2, 1, 0, 0, 2, 1, 0, 0), // prev_sig == 1
++ D4x4(2, 2, 2, 2, 1, 1, 1, 1, 0, 0, 0, 0, 0, 0, 0, 0), // prev_sig == 2
++ D4x4(2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2) // prev_sig == 3, default
++ },
++ {
++ H4x4(1, 1, 1, 0, 1, 1, 0, 0, 1, 0, 0, 0, 0, 0, 0, 0), // prev_sig == 0
++ H4x4(2, 1, 0, 0, 2, 1, 0, 0, 2, 1, 0, 0, 2, 1, 0, 0), // prev_sig == 1
++ H4x4(2, 2, 2, 2, 1, 1, 1, 1, 0, 0, 0, 0, 0, 0, 0, 0), // prev_sig == 2
++ H4x4(2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2) // prev_sig == 3, default
++ },
++ {
++ V4x4(1, 1, 1, 0, 1, 1, 0, 0, 1, 0, 0, 0, 0, 0, 0, 0), // prev_sig == 0
++ V4x4(2, 1, 0, 0, 2, 1, 0, 0, 2, 1, 0, 0, 2, 1, 0, 0), // prev_sig == 1
++ V4x4(2, 2, 2, 2, 1, 1, 1, 1, 0, 0, 0, 0, 0, 0, 0, 0), // prev_sig == 2
++ V4x4(2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2) // prev_sig == 3, default
++ }
++ };
++ const uint8_t *ctx_idx_map_p;
++ int scf_offset = 0;
++
++ if (s->ps.sps->transform_skip_context_enabled_flag && trans_skip_or_bypass) {
++ ctx_idx_map_p = ctx_idx_maps[0][3];
++ scf_offset = 40 + c_idx_nz;
++ } else {
++ if (c_idx_nz != 0)
++ scf_offset = 27;
++
++ if (log2_trafo_size == 2) {
++ ctx_idx_map_p = ctx_idx_maps_ts2[scan_idx];
++ } else {
++ ctx_idx_map_p = ctx_idx_maps[scan_idx][prev_sig];
++ if (!c_idx_nz) {
++ if (i != 0)
++ scf_offset += 3;
++
++ if (log2_trafo_size == 3) {
++ scf_offset += (scan_idx == SCAN_DIAG) ? 9 : 15;
++ } else {
++ scf_offset += 21;
++ }
++ } else {
++ if (log2_trafo_size == 3)
++ scf_offset += 9;
++ else
++ scf_offset += 12;
++ }
++ }
++ }
++
++ if (n_end > 0) {
++ int cnt = get_sig_coeff_flag_idxs(&lc->cc,
++ lc->cabac_state + elem_offset[SIGNIFICANT_COEFF_FLAG] + scf_offset,
++ n_end, ctx_idx_map_p,
++ significant_coeff_flag_idx + nb_significant_coeff_flag);
++
++ nb_significant_coeff_flag += cnt;
++ if (cnt != 0) {
++ implicit_non_zero_coeff = 0;
++ }
++ }
++
++ if (implicit_non_zero_coeff == 0) {
++ if (s->ps.sps->transform_skip_context_enabled_flag && trans_skip_or_bypass) {
++ scf_offset = 42 + c_idx_nz;
++ } else {
++ if (i == 0) {
++ scf_offset = c_idx_nz ? 27 : 0;
++ } else {
++ scf_offset = 2 + scf_offset;
++ }
++ }
++ if (significant_coeff_flag_decode_0(lc, scf_offset) == 1) {
++ significant_coeff_flag_idx[nb_significant_coeff_flag] = 0;
++ nb_significant_coeff_flag++;
++ }
++ } else {
++ significant_coeff_flag_idx[nb_significant_coeff_flag] = 0;
++ nb_significant_coeff_flag++;
++ }
++ }
++#if RPI_COMPRESS_COEFFS
++ if (use_compress && (nb_significant_coeff_flag + num_nonzero + 1 >= (1<<(2*log2_trafo_size-1)))) { // Overflow when half-full!
++ int16_t temp[32*32];
++ const unsigned int ccount = 1 << (log2_trafo_size * 2);
++ lc->jb0->coeffs.s[log2_trafo_size - 2].packed = 0;
++ lc->jb0->coeffs.s[log2_trafo_size - 2].packed_n = lc->jb0->coeffs.s[log2_trafo_size - 2].n - ccount; // Don't want to unpack the last buffer
++ memcpy(temp, coeffs, sizeof(int)*num_nonzero);
++ coeffs32 = (int *)temp;
++ memset(coeffs, 0, ccount * sizeof(int16_t));
++ num_nonzero--;
++ while (num_nonzero >= 0) {
++ const unsigned int res = coeffs32[num_nonzero];
++ const unsigned int offset = res & 0xffff;
++ coeffs[ offset ] = res >> 16;
++ num_nonzero--;
++ }
++ use_compress = 0;
++ }
++#endif
++
++ if (nb_significant_coeff_flag != 0) {
++ const unsigned int gt1_idx_delta = (c_idx_nz << 2) |
++ ((i != 0 && !c_idx_nz) ? 2 : 0) |
++ prev_subset_coded;
++ const unsigned int idx0_gt1 = elem_offset[COEFF_ABS_LEVEL_GREATER1_FLAG] +
++ (gt1_idx_delta << 2);
++ const unsigned int idx_gt2 = elem_offset[COEFF_ABS_LEVEL_GREATER2_FLAG] +
++ gt1_idx_delta;
++
++ const unsigned int x_cg = scan_x_cg[i];
++ const unsigned int y_cg = scan_y_cg[i];
++ int16_t * const blk_coeffs = coeffs +
++ ((x_cg + (y_cg << log2_trafo_size)) << 2);
++ // This calculation is 'wrong' for log2_traffo_size == 2
++ // but that doesn't matter as in this case x_cg & y_cg
++ // are always 0 so result is correct (0) anyway
++ const uint8_t * const blk_scale = scale_matrix +
++ (((x_cg + (y_cg << 3)) << (5 - log2_trafo_size)));
++
++ // * The following code block doesn't deal with these flags:
++ // (nor did the one it replaces)
++ //
++ // cabac_bypass_alignment_enabled_flag
++ // This should be easy but I can't find a test case
++ // extended_precision_processing_flag
++ // This can extend the required precision past 16bits
++ // so is probably tricky - also no example found yet
++
++#if USE_N_END_1
++ if (nb_significant_coeff_flag == 1) {
++ // There is a small gain to be had from special casing the single
++ // transform coefficient case. The reduction in complexity
++ // makes up for the code duplicatioon.
++
++ int trans_coeff_level = 1;
++ int coeff_sign_flag;
++ int coded_val = 0;
++
++ // initialize first elem of coeff_bas_level_greater1_flag
++ prev_subset_coded = 0;
++
++ if (get_cabac(&lc->cc, lc->cabac_state + idx0_gt1 + 1)) {
++ trans_coeff_level = 2;
++ prev_subset_coded = 1;
++ coded_val = get_cabac(&lc->cc, lc->cabac_state + idx_gt2);
++ }
++
++ // Probably not worth the overhead of starting by22 for just one value
++ coeff_sign_flag = get_cabac_bypass(&lc->cc);
++
++ if (coded_val)
++ {
++ if (!s->ps.sps->persistent_rice_adaptation_enabled_flag) {
++ trans_coeff_level = 3 + coeff_abs_level_remaining_decode(&lc->cc, 0);
++ } else {
++ uint8_t * const stat_coeff =
++ lc->stat_coeff + trans_skip_or_bypass + 2 - ((c_idx_nz) << 1);
++ const unsigned int c_rice_param = *stat_coeff >> 2;
++ const int last_coeff_abs_level_remaining = coeff_abs_level_remaining_decode(&lc->cc, c_rice_param);
++
++ trans_coeff_level = 3 + last_coeff_abs_level_remaining;
++ update_rice(stat_coeff, last_coeff_abs_level_remaining, c_rice_param);
++ }
++ }
++
++ {
++ const xy_off_t * const xy_off = scan_xy_off + significant_coeff_flag_idx[0];
++ const int k = (int32_t)(coeff_sign_flag << 31) >> 31;
++ const unsigned int scale_m = blk_scale[xy_off->scale];
++ const int res = trans_scale_sat(
++ (trans_coeff_level ^ k) - k, // Apply sign
++ scale,
++ i == 0 && xy_off->coeff == 0 ? dc_scale : scale_m,
++ shift);
++#if RPI_COMPRESS_COEFFS
++ if (use_compress)
++ coeffs32[num_nonzero++] = (res<<16) + (&blk_coeffs[xy_off->coeff] - coeffs);
++ else
++#endif
++ blk_coeffs[xy_off->coeff] = res;
++ }
++ }
++ else
++#endif
++ {
++ int sign_hidden = may_hide_sign;
++ int levels[16]; // Should be able to get away with int16_t but that fails some tests
++ uint32_t coeff_sign_flags;
++ uint32_t coded_vals = 0;
++ // Sum(abs(level[]))
++ // In fact we only need the bottom bit and in some future
++ // version that may be all we calculate
++ unsigned int sum_abs;
++
++ coded_vals = get_greaterx_bits(lc, nb_significant_coeff_flag, levels,
++ &prev_subset_coded, &sum_abs, idx0_gt1, idx_gt2);
++
++ if (significant_coeff_flag_idx[0] - significant_coeff_flag_idx[nb_significant_coeff_flag - 1] <= 3)
++ sign_hidden = 0;
++
++ // -- Start bypass block
++
++ bypass_start(&lc->cc);
++
++ coeff_sign_flags = coeff_sign_flag_decode_bypass(&lc->cc, nb_significant_coeff_flag - sign_hidden);
++
++ if (coded_vals != 0)
++ {
++ const int rice_adaptation_enabled = s->ps.sps->persistent_rice_adaptation_enabled_flag;
++ uint8_t * stat_coeff = !rice_adaptation_enabled ? NULL :
++ lc->stat_coeff + trans_skip_or_bypass + 2 - ((c_idx_nz) << 1);
++ int c_rice_param = !rice_adaptation_enabled ? 0 : *stat_coeff >> 2;
++ int * level = levels - 1;
++
++ do {
++ {
++ const unsigned int z = hevc_clz32(coded_vals) + 1;
++ level += z;
++ coded_vals <<= z;
++ }
++
++ {
++ const int last_coeff_abs_level_remaining = coeff_abs_level_remaining_decode_bypass(&lc->cc, c_rice_param);
++ const int trans_coeff_level = *level + last_coeff_abs_level_remaining + 1;
++
++ sum_abs += last_coeff_abs_level_remaining + 1;
++ *level = trans_coeff_level;
++
++ if (stat_coeff != NULL)
++ update_rice(stat_coeff, last_coeff_abs_level_remaining, c_rice_param);
++ stat_coeff = NULL;
++
++ if (trans_coeff_level > (3 << c_rice_param) &&
++ (c_rice_param < 4 || rice_adaptation_enabled))
++ ++c_rice_param;
++ }
++ } while (coded_vals != 0);
++ }
++
++ // sign_hidden = 0 or 1 so we can combine the tests
++ if ((sign_hidden & sum_abs) != 0) {
++ levels[nb_significant_coeff_flag - 1] = -levels[nb_significant_coeff_flag - 1];
++ }
++
++ bypass_finish(&lc->cc);
++
++ // -- Finish bypass block
++
++ // Scale loop
++ {
++ int m = nb_significant_coeff_flag - 1;
++
++ // Deal with DC component (if any) first
++ if (i == 0 && significant_coeff_flag_idx[m] == 0)
++ {
++ const int k = (int32_t)(coeff_sign_flags << m) >> 31;
++ const int res = trans_scale_sat(
++ (levels[m] ^ k) - k, scale, dc_scale, shift);
++#if RPI_COMPRESS_COEFFS
++ if (use_compress)
++ {
++ coeffs32[num_nonzero++] = (res<<16) + (blk_coeffs - coeffs);
++ }
++ else
++#endif
++ {
++ blk_coeffs[0] = res;
++ }
++ --m;
++ }
++
++#if !USE_N_END_1
++ // If N_END_1 set then m was at least 1 initially
++ if (m >= 0)
++#endif
++ {
++ do {
++ const xy_off_t * const xy_off = scan_xy_off +
++ significant_coeff_flag_idx[m];
++ const int k = (int32_t)(coeff_sign_flags << m) >> 31;
++ const int res = trans_scale_sat(
++ (levels[m] ^ k) - k,
++ scale,
++ blk_scale[xy_off->scale],
++ shift);
++#if RPI_COMPRESS_COEFFS
++ if (use_compress) {
++ coeffs32[num_nonzero++] = (res<<16) + (&blk_coeffs[xy_off->coeff] - coeffs);
++ } else
++#endif
++ blk_coeffs[xy_off->coeff] = res;
++ } while (--m >= 0);
++ }
++ }
++
++ }
++ }
++ } while ((i = next_subset(lc, i, c_idx_nz,
++ significant_coeff_group_flag, scan_x_cg, scan_y_cg, &prev_sig)) >= 0 &&
++ !cabac_overflow(&lc->cc));
++
++ if (lc->cu.cu_transquant_bypass_flag) {
++ if (explicit_rdpcm_flag || (s->ps.sps->implicit_rdpcm_enabled_flag &&
++ (pred_mode_intra == 10 || pred_mode_intra == 26))) {
++ int mode = s->ps.sps->implicit_rdpcm_enabled_flag ? (pred_mode_intra == 26) : explicit_rdpcm_dir_flag;
++
++ s->hevcdsp.transform_rdpcm(coeffs, log2_trafo_size, mode);
++ }
++ } else {
++ if (trans_skip_or_bypass) { // Must be trans_skip as we've already dealt with bypass
++ int rot = s->ps.sps->transform_skip_rotation_enabled_flag &&
++ log2_trafo_size == 2 &&
++ lc->cu.pred_mode == MODE_INTRA;
++ if (rot) {
++ for (i = 0; i < 8; i++)
++ FFSWAP(int16_t, coeffs[i], coeffs[16 - i - 1]);
++ }
++
++ s->hevcdsp.dequant(coeffs, log2_trafo_size);
++
++ if (explicit_rdpcm_flag || (s->ps.sps->implicit_rdpcm_enabled_flag &&
++ lc->cu.pred_mode == MODE_INTRA &&
++ (pred_mode_intra == 10 || pred_mode_intra == 26))) {
++ int mode = explicit_rdpcm_flag ? explicit_rdpcm_dir_flag : (pred_mode_intra == 26);
++
++ s->hevcdsp.transform_rdpcm(coeffs, log2_trafo_size, mode);
++ }
++ } else if (lc->cu.pred_mode == MODE_INTRA && c_idx == 0 && log2_trafo_size == 2) {
++ s->hevcdsp.transform_4x4_luma(coeffs);
++ }
++ else if (!use_vpu)
++ {
++ int max_xy = FFMAX(last_significant_coeff_x, last_significant_coeff_y);
++ if (max_xy == 0)
++ {
++ if (use_dc)
++ rpi_add_dc(s, lc->jb0, log2_trafo_size, c_idx, x0, y0, coeffs);
++ else
++ s->hevcdsp.idct_dc[log2_trafo_size - 2](coeffs);
++ }
++ else {
++ int col_limit = last_significant_coeff_x + last_significant_coeff_y + 4;
++ if (max_xy < 4)
++ col_limit = FFMIN(4, col_limit);
++ else if (max_xy < 8)
++ col_limit = FFMIN(8, col_limit);
++ else if (max_xy < 12)
++ col_limit = FFMIN(24, col_limit);
++ s->hevcdsp.idct[log2_trafo_size - 2](coeffs, col_limit);
++ }
++ }
++ }
++
++#if 0
++ // Mildly rotted - we support no mode where cross is valid
++ if (lc->tu.cross_pf) {
++ int16_t * const coeffs_y = (int16_t*)lc->edge_emu_buffer;
++ const int ccount = 1 << (log2_trafo_size * 2);
++
++ for (i = 0; i < ccount; i++) {
++ coeffs[i] = coeffs[i] + ((lc->tu.res_scale_val * coeffs_y[i]) >> 3);
++ }
++ }
++#endif
++
++ if (!use_dc) {
++#if RPI_COMPRESS_COEFFS
++ if (use_compress) {
++ coeffs32[num_nonzero] = 0;
++ }
++#endif
++ rpi_add_residual(s, lc->jb0, log2_trafo_size, c_idx, x0, y0, coeffs);
++ }
++}
++
++#if !USE_BY22
++// Stores results to lc
++MvXY ff_hevc_rpi_hls_mvd_coding(HEVCRpiLocalContext * const lc)
++{
++ int x = abs_mvd_greater0_flag_decode(lc);
++ int y = abs_mvd_greater0_flag_decode(lc);
++
++ if (x)
++ x += abs_mvd_greater1_flag_decode(lc);
++ if (y)
++ y += abs_mvd_greater1_flag_decode(lc);
++
++ switch (x) {
++ case 2: x = mvd_decode(lc); break;
++ case 1: x = mvd_sign_flag_decode(lc); break;
++ case 0: x = 0; break;
++ }
++
++ switch (y) {
++ case 2: y = mvd_decode(lc); break;
++ case 1: y = mvd_sign_flag_decode(lc); break;
++ case 0: y = 0; break;
++ }
++ return MV_XY(x,y);
++}
++#else
++MvXY ff_hevc_rpi_hls_mvd_coding(HEVCRpiLocalContext * const lc)
++{
++ int x = abs_mvd_greater0_flag_decode(lc);
++ int y = abs_mvd_greater0_flag_decode(lc);
++
++ if ((x | y) == 0)
++ return 0;
++
++ if (x != 0)
++ x += abs_mvd_greater1_flag_decode(lc);
++ if (y != 0)
++ y += abs_mvd_greater1_flag_decode(lc);
++
++ if ((x | y) == 1)
++ {
++ // Not worth starting BY22
++ if (x != 0)
++ x = mvd_sign_flag_decode(lc);
++ if (y != 0)
++ y = mvd_sign_flag_decode(lc);
++ }
++ else
++ {
++ CABACContext * const cc = &lc->cc;
++ uint32_t val;
++ uint32_t b;
++ unsigned int n = 0;
++
++ bypass_start(cc);
++ b = val = get_cabac_by22_peek(cc);
++
++ if (x == 1) {
++ x = ((int32_t)b >> 31) | 1;
++ n = 1;
++ b <<= 1;
++ }
++ else if (x == 2) {
++ // EG1 so we have (leading one bits + 1) of suffix
++ // This makes prefix & suffix lengths the same
++ const unsigned int k = hevc_clz32(~b) + 1;
++ int s;
++
++ av_assert2(k <= 15);
++
++ b <<= k;
++ n = 2 * k + 1; // Includes suffix & sign
++
++ // We need to have k*2 + 2 (prefix, suffix, sign, y-sign) bits peeked
++ // if we are going to do this without a flush
++ if (k > CABAC_BY22_PEEK_BITS / 2 - 1)
++ {
++ // Need too many bits - flush
++ // n = k
++ get_cabac_by22_flush(cc, k, val);
++ b = val = get_cabac_by22_peek(cc);
++ n = k + 1;
++ }
++
++ x = (b >> (32 - k)) + (1 << k);
++ b <<= k;
++ s = (int32_t)b >> 31;
++ x = (x ^ s) - s;
++ b <<= 1;
++
++ // Max abs value of an mv is 2^15 - 1 (i.e. a prefix len of 15 bits)
++ if (y > 1 && n > CABAC_BY22_PEEK_BITS - 15)
++ {
++ get_cabac_by22_flush(cc, n, val);
++ b = val = get_cabac_by22_peek(cc);
++ n = 0;
++ }
++ }
++
++ if (y == 1) {
++ y = ((int32_t)b >> 31) | 1;
++ ++n;
++ // don't care about b anymore
++ }
++ else if (y == 2) {
++ const unsigned int k = hevc_clz32(~b) + 1;
++ int s;
++
++ av_assert2(k <= 15);
++
++ // We need to have k*2 + 1 (prefix, suffix, sign) bits peeked
++ // if we are going to do this without a flush
++ b <<= k;
++ n += 2 * k + 1;
++
++ if (n > CABAC_BY22_PEEK_BITS)
++ {
++ // Need too many bits - flush
++ get_cabac_by22_flush(cc, n - (k + 1), val);
++ b = val = get_cabac_by22_peek(cc);
++ n = k + 1;
++ }
++
++ y = (b >> (32 - k)) + (1 << k);
++ s = (int32_t)(b << k) >> 31;
++ y = (y ^ s) - s;
++ // don't care about b anymore
++ }
++
++ get_cabac_by22_flush(cc, n, val);
++ bypass_finish(cc);
++ }
++
++ return MV_XY(x, y);
++}
++#endif
+diff --git a/libavcodec/rpi_hevc_cabac_fns.h b/libavcodec/rpi_hevc_cabac_fns.h
+new file mode 100644
+index 0000000000..a6587616ae
+--- /dev/null
++++ b/libavcodec/rpi_hevc_cabac_fns.h
+@@ -0,0 +1,191 @@
++#ifndef AVCODEC_RPI_HEVC_CABAC_FNS_H
++#define AVCODEC_RPI_HEVC_CABAC_FNS_H
++
++#include "config.h"
++#include "rpi_hevcdec.h"
++
++void ff_hevc_rpi_save_states(HEVCRpiContext *s, const HEVCRpiLocalContext * const lc);
++int ff_hevc_rpi_cabac_init_decoder(HEVCRpiLocalContext * const lc);
++void ff_hevc_rpi_cabac_init(const HEVCRpiContext * const s, HEVCRpiLocalContext *const lc, const unsigned int ctb_flags);
++int ff_hevc_rpi_sao_type_idx_decode(HEVCRpiLocalContext * const lc);
++int ff_hevc_rpi_sao_band_position_decode(HEVCRpiLocalContext * const lc);
++int ff_hevc_rpi_sao_offset_abs_decode(const HEVCRpiContext * const s, HEVCRpiLocalContext * const lc);
++int ff_hevc_rpi_sao_offset_sign_decode(HEVCRpiLocalContext * const lc);
++int ff_hevc_rpi_sao_eo_class_decode(HEVCRpiLocalContext * const lc);
++int ff_hevc_rpi_part_mode_decode(const HEVCRpiContext * const s, HEVCRpiLocalContext * const lc, const int log2_cb_size);
++int ff_hevc_rpi_mpm_idx_decode(HEVCRpiLocalContext * const lc);
++int ff_hevc_rpi_rem_intra_luma_pred_mode_decode(HEVCRpiLocalContext * const lc);
++int ff_hevc_rpi_intra_chroma_pred_mode_decode(HEVCRpiLocalContext * const lc);
++int ff_hevc_rpi_merge_idx_decode(const HEVCRpiContext * const s, HEVCRpiLocalContext * const lc);
++int ff_hevc_rpi_inter_pred_idc_decode(HEVCRpiLocalContext * const lc, int nPbW, int nPbH);
++int ff_hevc_rpi_ref_idx_lx_decode(HEVCRpiLocalContext * const lc, const int num_ref_idx_lx);
++int ff_hevc_rpi_log2_res_scale_abs(HEVCRpiLocalContext * const lc, const int idx);
++
++//int ff_hevc_rpi_cu_qp_delta_sign_flag(HEVCRpiLocalContext * const lc);
++int ff_hevc_rpi_cu_qp_delta(HEVCRpiLocalContext * const lc);
++int ff_hevc_rpi_cu_chroma_qp_offset_idx(const HEVCRpiContext * const s, HEVCRpiLocalContext * const lc);
++void ff_hevc_rpi_hls_residual_coding(const HEVCRpiContext * const s, HEVCRpiLocalContext * const lc,
++ const int x0, const int y0,
++ const int log2_trafo_size, const enum ScanType scan_idx,
++ const int c_idx);
++
++MvXY ff_hevc_rpi_hls_mvd_coding(HEVCRpiLocalContext * const lc);
++int ff_hevc_rpi_cabac_overflow(const HEVCRpiLocalContext * const lc);
++
++#define HEVC_BIN_SAO_MERGE_FLAG 0
++#define HEVC_BIN_SAO_TYPE_IDX 1
++#define HEVC_BIN_SAO_EO_CLASS 2
++#define HEVC_BIN_SAO_BAND_POSITION 2
++#define HEVC_BIN_SAO_OFFSET_ABS 2
++#define HEVC_BIN_SAO_OFFSET_SIGN 2
++#define HEVC_BIN_END_OF_SLICE_FLAG 2
++#define HEVC_BIN_SPLIT_CODING_UNIT_FLAG 2
++#define HEVC_BIN_CU_TRANSQUANT_BYPASS_FLAG 5
++#define HEVC_BIN_SKIP_FLAG 6
++#define HEVC_BIN_CU_QP_DELTA 9
++#define HEVC_BIN_PRED_MODE 12
++#define HEVC_BIN_PART_MODE 13
++#define HEVC_BIN_PCM_FLAG 17
++#define HEVC_BIN_PREV_INTRA_LUMA_PRED_MODE 17
++#define HEVC_BIN_MPM_IDX 18
++#define HEVC_BIN_REM_INTRA_LUMA_PRED_MODE 18
++#define HEVC_BIN_INTRA_CHROMA_PRED_MODE 18
++#define HEVC_BIN_MERGE_FLAG 20
++#define HEVC_BIN_MERGE_IDX 21
++#define HEVC_BIN_INTER_PRED_IDC 22
++#define HEVC_BIN_REF_IDX_L0 27
++#define HEVC_BIN_REF_IDX_L1 29
++#define HEVC_BIN_ABS_MVD_GREATER0_FLAG 31
++#define HEVC_BIN_ABS_MVD_GREATER1_FLAG 33
++#define HEVC_BIN_ABS_MVD_MINUS2 35
++#define HEVC_BIN_MVD_SIGN_FLAG 35
++#define HEVC_BIN_MVP_LX_FLAG 35
++#define HEVC_BIN_NO_RESIDUAL_DATA_FLAG 36
++#define HEVC_BIN_SPLIT_TRANSFORM_FLAG 37
++#define HEVC_BIN_CBF_LUMA 40
++#define HEVC_BIN_CBF_CB_CR 42
++#define HEVC_BIN_TRANSFORM_SKIP_FLAG 46
++#define HEVC_BIN_EXPLICIT_RDPCM_FLAG 48
++#define HEVC_BIN_EXPLICIT_RDPCM_DIR_FLAG 50
++#define HEVC_BIN_LAST_SIGNIFICANT_COEFF_X_PREFIX 52
++#define HEVC_BIN_LAST_SIGNIFICANT_COEFF_Y_PREFIX 70
++#define HEVC_BIN_LAST_SIGNIFICANT_COEFF_X_SUFFIX 88
++#define HEVC_BIN_LAST_SIGNIFICANT_COEFF_Y_SUFFIX 88
++#define HEVC_BIN_SIGNIFICANT_COEFF_GROUP_FLAG 88
++#define HEVC_BIN_SIGNIFICANT_COEFF_FLAG 92
++#define HEVC_BIN_COEFF_ABS_LEVEL_GREATER1_FLAG 136
++#define HEVC_BIN_COEFF_ABS_LEVEL_GREATER2_FLAG 160
++#define HEVC_BIN_COEFF_ABS_LEVEL_REMAINING 166
++#define HEVC_BIN_COEFF_SIGN_FLAG 166
++#define HEVC_BIN_LOG2_RES_SCALE_ABS 166
++#define HEVC_BIN_RES_SCALE_SIGN_FLAG 174
++#define HEVC_BIN_CU_CHROMA_QP_OFFSET_FLAG 176
++#define HEVC_BIN_CU_CHROMA_QP_OFFSET_IDX 177
++
++
++int ff_hevc_rpi_get_cabac(CABACContext * const c, uint8_t * const state);
++int ff_hevc_rpi_get_cabac_terminate(CABACContext * const c);
++
++static inline const uint8_t* ff_hevc_rpi_cabac_skip_bytes(CABACContext * const c, int n) {
++ const uint8_t *ptr = c->bytestream;
++
++ if (c->low & 0x1)
++ ptr--;
++#if CABAC_BITS == 16
++ if (c->low & 0x1FF)
++ ptr--;
++#endif
++ if ((int) (c->bytestream_end - ptr) < n)
++ return NULL;
++ if (ff_init_cabac_decoder(c, ptr + n, c->bytestream_end - ptr - n) < 0)
++ return NULL;
++
++ return ptr;
++}
++
++static inline int ff_hevc_rpi_sao_merge_flag_decode(HEVCRpiLocalContext * const lc)
++{
++ return ff_hevc_rpi_get_cabac(&lc->cc, lc->cabac_state + HEVC_BIN_SAO_MERGE_FLAG);
++}
++
++static inline int ff_hevc_rpi_cu_transquant_bypass_flag_decode(HEVCRpiLocalContext * const lc)
++{
++ return ff_hevc_rpi_get_cabac(&lc->cc, lc->cabac_state + HEVC_BIN_CU_TRANSQUANT_BYPASS_FLAG);
++}
++
++static inline int ff_hevc_rpi_cu_chroma_qp_offset_flag(HEVCRpiLocalContext * const lc)
++{
++ return ff_hevc_rpi_get_cabac(&lc->cc, lc->cabac_state + HEVC_BIN_CU_CHROMA_QP_OFFSET_FLAG);
++}
++
++static inline int ff_hevc_rpi_split_coding_unit_flag_decode(const HEVCRpiContext * const s, HEVCRpiLocalContext * const lc,
++ const unsigned int ct_depth,
++ const unsigned int x0, const unsigned int y0)
++{
++ return ff_hevc_rpi_get_cabac(&lc->cc, lc->cabac_state + HEVC_BIN_SPLIT_CODING_UNIT_FLAG +
++ ((s->cabac_stash_left[y0 >> 3] >> 1) > ct_depth) +
++ ((s->cabac_stash_up[x0 >> 3] >> 1) > ct_depth));
++}
++
++static inline int ff_hevc_rpi_skip_flag_decode(const HEVCRpiContext * const s, HEVCRpiLocalContext * const lc,
++ const int x0, const int y0, const int x_cb, const int y_cb)
++{
++ return ff_hevc_rpi_get_cabac(&lc->cc, lc->cabac_state + HEVC_BIN_SKIP_FLAG +
++ (s->cabac_stash_left[y0 >> 3] & 1) +
++ (s->cabac_stash_up[x0 >> 3] & 1));
++}
++
++static inline int ff_hevc_rpi_pred_mode_decode(HEVCRpiLocalContext * const lc)
++{
++ return ff_hevc_rpi_get_cabac(&lc->cc, lc->cabac_state + HEVC_BIN_PRED_MODE);
++}
++
++static inline int ff_hevc_rpi_pcm_flag_decode(HEVCRpiLocalContext * const lc)
++{
++ return ff_hevc_rpi_get_cabac_terminate(&lc->cc);
++}
++
++static inline int ff_hevc_rpi_prev_intra_luma_pred_flag_decode(HEVCRpiLocalContext * const lc)
++{
++ return ff_hevc_rpi_get_cabac(&lc->cc, lc->cabac_state + HEVC_BIN_PREV_INTRA_LUMA_PRED_MODE);
++}
++
++static inline int ff_hevc_rpi_merge_flag_decode(HEVCRpiLocalContext * const lc)
++{
++ return ff_hevc_rpi_get_cabac(&lc->cc, lc->cabac_state + HEVC_BIN_MERGE_FLAG);
++}
++
++static inline int ff_hevc_rpi_mvp_lx_flag_decode(HEVCRpiLocalContext * const lc)
++{
++ return ff_hevc_rpi_get_cabac(&lc->cc, lc->cabac_state + HEVC_BIN_MVP_LX_FLAG);
++}
++
++static inline int ff_hevc_rpi_no_residual_syntax_flag_decode(HEVCRpiLocalContext * const lc)
++{
++ return ff_hevc_rpi_get_cabac(&lc->cc, lc->cabac_state + HEVC_BIN_NO_RESIDUAL_DATA_FLAG);
++}
++
++static inline int ff_hevc_rpi_cbf_cb_cr_decode(HEVCRpiLocalContext * const lc, const int trafo_depth)
++{
++ return ff_hevc_rpi_get_cabac(&lc->cc, lc->cabac_state + HEVC_BIN_CBF_CB_CR + trafo_depth);
++}
++
++static inline int ff_hevc_rpi_cbf_luma_decode(HEVCRpiLocalContext * const lc, const int trafo_depth)
++{
++ return ff_hevc_rpi_get_cabac(&lc->cc, lc->cabac_state + HEVC_BIN_CBF_LUMA + !trafo_depth);
++}
++
++static inline int ff_hevc_rpi_split_transform_flag_decode(HEVCRpiLocalContext * const lc, const int log2_trafo_size)
++{
++ return ff_hevc_rpi_get_cabac(&lc->cc, lc->cabac_state + HEVC_BIN_SPLIT_TRANSFORM_FLAG + 5 - log2_trafo_size);
++}
++
++static inline int ff_hevc_rpi_res_scale_sign_flag(HEVCRpiLocalContext *const lc, const int idx)
++{
++ return ff_hevc_rpi_get_cabac(&lc->cc, lc->cabac_state + HEVC_BIN_RES_SCALE_SIGN_FLAG + idx);
++}
++
++
++
++#endif
++
+diff --git a/libavcodec/rpi_hevc_data.c b/libavcodec/rpi_hevc_data.c
+new file mode 100644
+index 0000000000..341bb77d9d
+--- /dev/null
++++ b/libavcodec/rpi_hevc_data.c
+@@ -0,0 +1,75 @@
++/*
++ * HEVC shared tables
++ *
++ * This file is part of FFmpeg.
++ *
++ * FFmpeg is free software; you can redistribute it and/or
++ * modify it under the terms of the GNU Lesser General Public
++ * License as published by the Free Software Foundation; either
++ * version 2.1 of the License, or (at your option) any later version.
++ *
++ * FFmpeg is distributed in the hope that it will be useful,
++ * but WITHOUT ANY WARRANTY; without even the implied warranty of
++ * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
++ * Lesser General Public License for more details.
++ *
++ * You should have received a copy of the GNU Lesser General Public
++ * License along with FFmpeg; if not, write to the Free Software
++ * Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA
++ */
++
++#include <stdint.h>
++
++#include "rpi_hevc_data.h"
++
++const uint8_t ff_hevc_rpi_diag_scan4x4_x[16] = {
++ 0, 0, 1, 0,
++ 1, 2, 0, 1,
++ 2, 3, 1, 2,
++ 3, 2, 3, 3,
++};
++
++const uint8_t ff_hevc_rpi_diag_scan4x4_y[16] = {
++ 0, 1, 0, 2,
++ 1, 0, 3, 2,
++ 1, 0, 3, 2,
++ 1, 3, 2, 3,
++};
++
++const uint8_t ff_hevc_rpi_diag_scan8x8_x[64] = {
++ 0, 0, 1, 0,
++ 1, 2, 0, 1,
++ 2, 3, 0, 1,
++ 2, 3, 4, 0,
++ 1, 2, 3, 4,
++ 5, 0, 1, 2,
++ 3, 4, 5, 6,
++ 0, 1, 2, 3,
++ 4, 5, 6, 7,
++ 1, 2, 3, 4,
++ 5, 6, 7, 2,
++ 3, 4, 5, 6,
++ 7, 3, 4, 5,
++ 6, 7, 4, 5,
++ 6, 7, 5, 6,
++ 7, 6, 7, 7,
++};
++
++const uint8_t ff_hevc_rpi_diag_scan8x8_y[64] = {
++ 0, 1, 0, 2,
++ 1, 0, 3, 2,
++ 1, 0, 4, 3,
++ 2, 1, 0, 5,
++ 4, 3, 2, 1,
++ 0, 6, 5, 4,
++ 3, 2, 1, 0,
++ 7, 6, 5, 4,
++ 3, 2, 1, 0,
++ 7, 6, 5, 4,
++ 3, 2, 1, 7,
++ 6, 5, 4, 3,
++ 2, 7, 6, 5,
++ 4, 3, 7, 6,
++ 5, 4, 7, 6,
++ 5, 7, 6, 7,
++};
+diff --git a/libavcodec/rpi_hevc_data.h b/libavcodec/rpi_hevc_data.h
+new file mode 100644
+index 0000000000..0aee673d8b
+--- /dev/null
++++ b/libavcodec/rpi_hevc_data.h
+@@ -0,0 +1,31 @@
++/*
++ * HEVC shared data tables
++ *
++ * This file is part of FFmpeg.
++ *
++ * FFmpeg is free software; you can redistribute it and/or
++ * modify it under the terms of the GNU Lesser General Public
++ * License as published by the Free Software Foundation; either
++ * version 2.1 of the License, or (at your option) any later version.
++ *
++ * FFmpeg is distributed in the hope that it will be useful,
++ * but WITHOUT ANY WARRANTY; without even the implied warranty of
++ * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
++ * Lesser General Public License for more details.
++ *
++ * You should have received a copy of the GNU Lesser General Public
++ * License along with FFmpeg; if not, write to the Free Software
++ * Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA
++ */
++
++#ifndef AVCODEC_RPI_HEVC_DATA_H
++#define AVCODEC_RPI_HEVC_DATA_H
++
++#include <stdint.h>
++
++extern const uint8_t ff_hevc_rpi_diag_scan4x4_x[16];
++extern const uint8_t ff_hevc_rpi_diag_scan4x4_y[16];
++extern const uint8_t ff_hevc_rpi_diag_scan8x8_x[64];
++extern const uint8_t ff_hevc_rpi_diag_scan8x8_y[64];
++
++#endif /* AVCODEC_RPI_HEVC_DATA_H */
+diff --git a/libavcodec/rpi_hevc_filter.c b/libavcodec/rpi_hevc_filter.c
+new file mode 100644
+index 0000000000..dd5f65b5c4
+--- /dev/null
++++ b/libavcodec/rpi_hevc_filter.c
+@@ -0,0 +1,1206 @@
++/*
++ * HEVC video decoder
++ *
++ * Copyright (C) 2012 - 2013 Guillaume Martres
++ * Copyright (C) 2013 Seppo Tomperi
++ * Copyright (C) 2013 Wassim Hamidouche
++ *
++ * This file is part of FFmpeg.
++ *
++ * FFmpeg is free software; you can redistribute it and/or
++ * modify it under the terms of the GNU Lesser General Public
++ * License as published by the Free Software Foundation; either
++ * version 2.1 of the License, or (at your option) any later version.
++ *
++ * FFmpeg is distributed in the hope that it will be useful,
++ * but WITHOUT ANY WARRANTY; without even the implied warranty of
++ * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
++ * Lesser General Public License for more details.
++ *
++ * You should have received a copy of the GNU Lesser General Public
++ * License along with FFmpeg; if not, write to the Free Software
++ * Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA
++ */
++
++//#define DISABLE_SAO
++//#define DISABLE_DEBLOCK
++//#define DISABLE_STRENGTHS
++// define DISABLE_DEBLOCK_NONREF for a 6% speed boost (by skipping deblocking on unimportant frames)
++//#define DISABLE_DEBLOCK_NONREF
++
++#include "libavutil/common.h"
++#include "libavutil/internal.h"
++
++#include "rpi_hevcdec.h"
++
++#include "bit_depth_template.c"
++
++#include "rpi_qpu.h"
++#include "rpi_zc.h"
++#include "libavutil/rpi_sand_fns.h"
++
++#define LUMA 0
++#define CB 1
++#define CR 2
++
++// tcoffset: -12,12; qp: 0,51; (bs-1)*2: 0,2
++// so -12,75 overall
++static const uint8_t tctablex[] = {
++ 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, // -ve quant padding
++ 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0,
++ 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0,
++ 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0,
++
++ 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, // -12..-1
++ 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 1, // QP 0...18
++ 1, 1, 1, 1, 1, 1, 1, 1, 2, 2, 2, 2, 3, 3, 3, 3, 4, 4, 4, // QP 19...37
++ 5, 5, 6, 6, 7, 8, 9, 10, 11, 13, 14, 16, 18, 20, 22, 24, // QP 38...53
++ 24, 24, 24, 24, 24, 24, 24, 24, 24, 24, 24, 24 // 54..75
++};
++#define tctable (tctablex + 12 + 6*8)
++
++static const uint8_t betatablex[] = {
++ 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, // -ve quant padding
++ 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0,
++ 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0,
++ 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0,
++
++ 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, // -12..-1
++ 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 6, 7, 8, // QP 0...18
++ 9, 10, 11, 12, 13, 14, 15, 16, 17, 18, 20, 22, 24, 26, 28, 30, 32, 34, 36, // QP 19...37
++ 38, 40, 42, 44, 46, 48, 50, 52, 54, 56, 58, 60, 62, 64, // QP 38...51
++ 64, 64, 64, 64, 64, 64, 64, 64, 64, 64, 64, 64 // 52..73
++};
++#define betatable (betatablex + 12 + 6*8)
++
++static inline int chroma_tc(const HEVCRpiContext * const s, const int qp_y,
++ const int c_idx, const int tc_offset)
++{
++ return tctable[(int)s->ps.pps->qp_dblk_x[c_idx][qp_y] + tc_offset + 2];
++}
++
++static inline int get_qPy_pred(const HEVCRpiContext * const s, const HEVCRpiLocalContext * const lc,
++ const unsigned int xBase, const unsigned int yBase)
++{
++ const unsigned int ctb_size_mask = (1 << s->ps.sps->log2_ctb_size) - 1;
++ const unsigned int MinCuQpDeltaSizeMask = ~0U << s->ps.pps->log2_min_cu_qp_delta_size;
++ const unsigned int xQgBase = xBase & MinCuQpDeltaSizeMask;
++ const unsigned int yQgBase = yBase & MinCuQpDeltaSizeMask;
++ const unsigned int min_cb_width = s->ps.sps->min_cb_width;
++ const unsigned int x_cb = xQgBase >> s->ps.sps->log2_min_cb_size;
++ const unsigned int y_cb = yQgBase >> s->ps.sps->log2_min_cb_size;
++ const int qPy_pred = lc->qPy_pred;
++
++ return (((xQgBase & ctb_size_mask) == 0 ? qPy_pred :
++ s->qp_y_tab[(x_cb - 1) + y_cb * min_cb_width]) +
++ ((yQgBase & ctb_size_mask) == 0 ? qPy_pred :
++ s->qp_y_tab[x_cb + (y_cb - 1) * min_cb_width]) + 1) >> 1;
++}
++
++// * Only called from bitstream decode in foreground
++// so should be safe
++void ff_hevc_rpi_set_qPy(const HEVCRpiContext * const s, HEVCRpiLocalContext * const lc, int xBase, int yBase)
++{
++ const int qp_y = get_qPy_pred(s, lc, xBase, yBase);
++
++ if (lc->tu.cu_qp_delta != 0) {
++ // ?? I suspect that the -bd_offset here leads to us adding it elsewhere
++ int off = s->ps.sps->qp_bd_offset;
++ lc->qp_y = FFUMOD(qp_y + lc->tu.cu_qp_delta + 52 + 2 * off,
++ 52 + off) - off;
++ } else
++ lc->qp_y = qp_y;
++}
++
++static inline unsigned int pixel_shift(const HEVCRpiContext * const s, const unsigned int c_idx)
++{
++ return c_idx != 0 ? 1 + s->ps.sps->pixel_shift : s->ps.sps->pixel_shift;
++}
++
++// "DSP" these?
++static void copy_pixel(uint8_t *dst, const uint8_t *src, int pixel_shift)
++{
++ switch (pixel_shift)
++ {
++ case 2:
++ *(uint32_t *)dst = *(uint32_t *)src;
++ break;
++ case 1:
++ *(uint16_t *)dst = *(uint16_t *)src;
++ break;
++ default:
++ *dst = *src;
++ break;
++ }
++}
++
++static void copy_CTB_to_hv(const HEVCRpiContext * const s, const uint8_t * const src,
++ ptrdiff_t stride_src, int x, int y, int width, int height,
++ int c_idx, int x_ctb, int y_ctb)
++{
++ const unsigned int sh = pixel_shift(s, c_idx);
++ const unsigned int w = s->ps.sps->width >> ctx_hshift(s, c_idx);
++ const unsigned int h = s->ps.sps->height >> ctx_vshift(s, c_idx);
++
++ /* copy horizontal edges */
++ memcpy(s->sao_pixel_buffer_h[c_idx] + (((2 * y_ctb) * w + x) << sh),
++ src, width << sh);
++ memcpy(s->sao_pixel_buffer_h[c_idx] + (((2 * y_ctb + 1) * w + x) << sh),
++ src + stride_src * (height - 1), width << sh);
++
++ /* copy vertical edges */
++ ff_hevc_rpi_copy_vert(s->sao_pixel_buffer_v[c_idx] + (((2 * x_ctb) * h + y) << sh), src, sh, height, 1 << sh, stride_src);
++
++ ff_hevc_rpi_copy_vert(s->sao_pixel_buffer_v[c_idx] + (((2 * x_ctb + 1) * h + y) << sh), src + ((width - 1) << sh), sh, height, 1 << sh, stride_src);
++}
++
++// N.B. Src & dst are swapped as this is a restore!
++// x0 & y0 are in luma coords
++// Width & height are in Y/C pels as appropriate
++// * Clear scope for optimsation here but not used enough to be worth it
++static void restore_tqb_pixels(const HEVCRpiContext * const s,
++ uint8_t *src1, const uint8_t *dst1,
++ const ptrdiff_t stride_src, const ptrdiff_t stride_dst,
++ const unsigned int x0, const unsigned int y0,
++ const unsigned int width, const int height,
++ const int c_idx)
++{
++ if (s->ps.pps->transquant_bypass_enable_flag ||
++ s->ps.sps->pcm.loop_filter_disable_flag)
++ {
++ const uint8_t *pcm = s->is_pcm + (x0 >> 6) + (y0 >> 3) * s->ps.sps->pcm_width;
++ int blks_y = height >> (c_idx == 0 ? 3 : 2);
++ const unsigned int bwidth = 8 << s->ps.sps->pixel_shift; // Y & C have the same width in sand
++ const unsigned int bheight = (c_idx == 0) ? 8 : 4;
++ const unsigned int sh = ((x0 >> 3) & 7);
++ const unsigned int mask = (1 << (width >> (c_idx == 0 ? 3 : 2))) - 1;
++
++ do {
++ unsigned int m = (*pcm >> sh) & mask;
++ uint8_t * bd = src1;
++ const uint8_t * bs = dst1;
++ while (m != 0) {
++ if ((m & 1) != 0) {
++ s->hevcdsp.cpy_blk(bd, stride_src, bs, stride_dst, bwidth, bheight);
++ }
++ m >>= 1;
++ bs += bwidth;
++ bd += bwidth;
++ }
++ src1 += stride_src * bheight;
++ dst1 += stride_dst * bheight;
++ pcm += s->ps.sps->pcm_width;
++ } while (--blks_y > 0);
++ }
++}
++
++#define CTB(tab, x, y) ((tab)[(y) * s->ps.sps->ctb_width + (x)])
++
++static void sao_filter_CTB(const HEVCRpiContext * const s, const int x, const int y)
++{
++#if SAO_FILTER_N == 5
++ static const uint8_t sao_tab[8] = { 0 /* 8 */, 1 /* 16 */, 2 /* 24 */, 2 /* 32 */, 3, 3 /* 48 */, 4, 4 /* 64 */};
++#elif SAO_FILTER_N == 6
++ static const uint8_t sao_tab[8] = { 0 /* 8 */, 1 /* 16 */, 5 /* 24 */, 2 /* 32 */, 3, 3 /* 48 */, 4, 4 /* 64 */};
++#else
++#error Confused by size of sao fn array
++#endif
++ int c_idx;
++ int edges[4]; // 0 left 1 top 2 right 3 bottom
++ int x_ctb = x >> s->ps.sps->log2_ctb_size;
++ int y_ctb = y >> s->ps.sps->log2_ctb_size;
++ int ctb_addr_rs = y_ctb * s->ps.sps->ctb_width + x_ctb;
++ int ctb_addr_ts = s->ps.pps->ctb_addr_rs_to_ts[ctb_addr_rs];
++ RpiSAOParams *sao = &CTB(s->sao, x_ctb, y_ctb);
++ // flags indicating unfilterable edges
++ uint8_t vert_edge[] = { 0, 0 };
++ uint8_t horiz_edge[] = { 0, 0 };
++ uint8_t diag_edge[] = { 0, 0, 0, 0 };
++ uint8_t lfase = CTB(s->filter_slice_edges, x_ctb, y_ctb);
++ uint8_t no_tile_filter = s->ps.pps->tiles_enabled_flag &&
++ !s->ps.pps->loop_filter_across_tiles_enabled_flag;
++ uint8_t restore = no_tile_filter || !lfase;
++ uint8_t left_tile_edge = 0;
++ uint8_t right_tile_edge = 0;
++ uint8_t up_tile_edge = 0;
++ uint8_t bottom_tile_edge = 0;
++ const int sliced = 1;
++ const int plane_count = sliced ? 2 : (ctx_cfmt(s) != 0 ? 3 : 1);
++
++ edges[0] = x_ctb == 0;
++ edges[1] = y_ctb == 0;
++ edges[2] = x_ctb == s->ps.sps->ctb_width - 1;
++ edges[3] = y_ctb == s->ps.sps->ctb_height - 1;
++
++#ifdef DISABLE_SAO
++ return;
++#endif
++
++ if (restore) {
++ if (!edges[0]) {
++ left_tile_edge = no_tile_filter && s->ps.pps->tile_id[ctb_addr_ts] != s->ps.pps->tile_id[s->ps.pps->ctb_addr_rs_to_ts[ctb_addr_rs-1]];
++ vert_edge[0] = (!lfase && CTB(s->tab_slice_address, x_ctb, y_ctb) != CTB(s->tab_slice_address, x_ctb - 1, y_ctb)) || left_tile_edge;
++ }
++ if (!edges[2]) {
++ right_tile_edge = no_tile_filter && s->ps.pps->tile_id[ctb_addr_ts] != s->ps.pps->tile_id[s->ps.pps->ctb_addr_rs_to_ts[ctb_addr_rs+1]];
++ vert_edge[1] = (!lfase && CTB(s->tab_slice_address, x_ctb, y_ctb) != CTB(s->tab_slice_address, x_ctb + 1, y_ctb)) || right_tile_edge;
++ }
++ if (!edges[1]) {
++ up_tile_edge = no_tile_filter && s->ps.pps->tile_id[ctb_addr_ts] != s->ps.pps->tile_id[s->ps.pps->ctb_addr_rs_to_ts[ctb_addr_rs - s->ps.sps->ctb_width]];
++ horiz_edge[0] = (!lfase && CTB(s->tab_slice_address, x_ctb, y_ctb) != CTB(s->tab_slice_address, x_ctb, y_ctb - 1)) || up_tile_edge;
++ }
++ if (!edges[3]) {
++ bottom_tile_edge = no_tile_filter && s->ps.pps->tile_id[ctb_addr_ts] != s->ps.pps->tile_id[s->ps.pps->ctb_addr_rs_to_ts[ctb_addr_rs + s->ps.sps->ctb_width]];
++ horiz_edge[1] = (!lfase && CTB(s->tab_slice_address, x_ctb, y_ctb) != CTB(s->tab_slice_address, x_ctb, y_ctb + 1)) || bottom_tile_edge;
++ }
++ if (!edges[0] && !edges[1]) {
++ diag_edge[0] = (!lfase && CTB(s->tab_slice_address, x_ctb, y_ctb) != CTB(s->tab_slice_address, x_ctb - 1, y_ctb - 1)) || left_tile_edge || up_tile_edge;
++ }
++ if (!edges[1] && !edges[2]) {
++ diag_edge[1] = (!lfase && CTB(s->tab_slice_address, x_ctb, y_ctb) != CTB(s->tab_slice_address, x_ctb + 1, y_ctb - 1)) || right_tile_edge || up_tile_edge;
++ }
++ if (!edges[2] && !edges[3]) {
++ diag_edge[2] = (!lfase && CTB(s->tab_slice_address, x_ctb, y_ctb) != CTB(s->tab_slice_address, x_ctb + 1, y_ctb + 1)) || right_tile_edge || bottom_tile_edge;
++ }
++ if (!edges[0] && !edges[3]) {
++ diag_edge[3] = (!lfase && CTB(s->tab_slice_address, x_ctb, y_ctb) != CTB(s->tab_slice_address, x_ctb - 1, y_ctb + 1)) || left_tile_edge || bottom_tile_edge;
++ }
++ }
++
++ for (c_idx = 0; c_idx < plane_count; c_idx++) {
++ const unsigned int vshift = ctx_vshift(s, c_idx);
++ const unsigned int hshift = ctx_hshift(s, c_idx);
++ const int x0 = x >> hshift;
++ const int y0 = y >> vshift;
++ const ptrdiff_t stride_src = frame_stride1(s->frame, c_idx);
++ const int ctb_size_h = (1 << (s->ps.sps->log2_ctb_size)) >> hshift;
++ const int ctb_size_v = (1 << (s->ps.sps->log2_ctb_size)) >> vshift;
++ const int width = FFMIN(ctb_size_h, (s->ps.sps->width >> hshift) - x0);
++ const int height = FFMIN(ctb_size_v, (s->ps.sps->height >> vshift) - y0);
++ int tab = sao_tab[(FFALIGN(width, 8) >> 3) - 1];
++ ptrdiff_t stride_dst;
++ uint8_t *dst;
++
++ const unsigned int sh = s->ps.sps->pixel_shift + (sliced && c_idx != 0);
++ const int wants_lr = sao->type_idx[c_idx] == SAO_EDGE && sao->eo_class[c_idx] != 1 /* Vertical */;
++ uint8_t * const src = !sliced ?
++ &s->frame->data[c_idx][y0 * stride_src + (x0 << sh)] :
++ c_idx == 0 ?
++ av_rpi_sand_frame_pos_y(s->frame, x0, y0) :
++ av_rpi_sand_frame_pos_c(s->frame, x0, y0);
++ const uint8_t * const src_l = edges[0] || !wants_lr ? NULL :
++ !sliced ? src - (1 << sh) :
++ c_idx == 0 ?
++ av_rpi_sand_frame_pos_y(s->frame, x0 - 1, y0) :
++ av_rpi_sand_frame_pos_c(s->frame, x0 - 1, y0);
++ const uint8_t * const src_r = edges[2] || !wants_lr ? NULL :
++ !sliced ? src + (width << sh) :
++ c_idx == 0 ?
++ av_rpi_sand_frame_pos_y(s->frame, x0 + width, y0) :
++ av_rpi_sand_frame_pos_c(s->frame, x0 + width, y0);
++
++ if (sliced && c_idx > 1) {
++ break;
++ }
++
++// if (c_idx == 1)
++// printf("%d: %dx%d %d,%d: lr=%d\n", c_idx, width, height, x0, y0, wants_lr);
++
++ switch (sao->type_idx[c_idx]) {
++ case SAO_BAND:
++ copy_CTB_to_hv(s, src, stride_src, x0, y0, width, height, c_idx,
++ x_ctb, y_ctb);
++ if (s->ps.pps->transquant_bypass_enable_flag ||
++ s->ps.sps->pcm.loop_filter_disable_flag)
++ {
++ // Can't use the edge buffer here as it may be in use by the foreground
++ DECLARE_ALIGNED(64, uint8_t, dstbuf)
++ [2*MAX_PB_SIZE*MAX_PB_SIZE];
++ dst = dstbuf;
++ stride_dst = 2*MAX_PB_SIZE;
++ s->hevcdsp.cpy_blk(dst, stride_dst, src, stride_src, width << sh, height);
++ if (sliced && c_idx != 0)
++ {
++ s->hevcdsp.sao_band_filter_c[tab](src, dst, stride_src, stride_dst,
++ sao->offset_val[1], sao->band_position[1],
++ sao->offset_val[2], sao->band_position[2],
++ width, height);
++ }
++ else
++ {
++ s->hevcdsp.sao_band_filter[tab](src, dst, stride_src, stride_dst,
++ sao->offset_val[c_idx], sao->band_position[c_idx],
++ width, height);
++ }
++ restore_tqb_pixels(s, src, dst, stride_src, stride_dst,
++ x, y, width, height, c_idx);
++ } else {
++ if (sliced && c_idx != 0)
++ {
++ s->hevcdsp.sao_band_filter_c[tab](src, src, stride_src, stride_src,
++ sao->offset_val[1], sao->band_position[1],
++ sao->offset_val[2], sao->band_position[2],
++ width, height);
++ }
++ else
++ {
++ s->hevcdsp.sao_band_filter[tab](src, src, stride_src, stride_src,
++ sao->offset_val[c_idx], sao->band_position[c_idx],
++ width, height);
++ }
++ }
++ sao->type_idx[c_idx] = SAO_APPLIED;
++ break;
++ case SAO_EDGE:
++ {
++ const int w = s->ps.sps->width >> hshift;
++ const int h = s->ps.sps->height >> vshift;
++ int top_edge = edges[1];
++ int bottom_edge = edges[3];
++ // Can't use the edge buffer here as it may be in use by the foreground
++ DECLARE_ALIGNED(64, uint8_t, dstbuf)
++ [RPI_HEVC_SAO_BUF_STRIDE * (MAX_PB_SIZE + 2) + 64];
++
++ stride_dst = RPI_HEVC_SAO_BUF_STRIDE;
++ dst = dstbuf + stride_dst + 32;
++
++ if (!top_edge) {
++ uint8_t *dst1;
++ int src_idx;
++ const uint8_t * const src_spb = s->sao_pixel_buffer_h[c_idx] + (((2 * y_ctb - 1) * w + x0) << sh);
++
++ dst1 = dst - stride_dst;
++
++ if (src_l != NULL) {
++ src_idx = (CTB(s->sao, x_ctb-1, y_ctb-1).type_idx[c_idx] ==
++ SAO_APPLIED);
++ copy_pixel(dst1 - (1 << sh), src_idx ? src_spb - (1 << sh) : src_l - stride_src, sh);
++ }
++
++ src_idx = (CTB(s->sao, x_ctb, y_ctb-1).type_idx[c_idx] ==
++ SAO_APPLIED);
++ memcpy(dst1, src_idx ? src_spb : src - stride_src, width << sh);
++
++ if (src_r != NULL) {
++ src_idx = (CTB(s->sao, x_ctb+1, y_ctb-1).type_idx[c_idx] ==
++ SAO_APPLIED);
++ copy_pixel(dst1 + (width << sh), src_idx ? src_spb + (width << sh) : src_r - stride_src, sh);
++ }
++ }
++ if (!bottom_edge) {
++ uint8_t * const dst1 = dst + height * stride_dst;
++ int src_idx;
++ const uint8_t * const src_spb = s->sao_pixel_buffer_h[c_idx] + (((2 * y_ctb + 2) * w + x0) << sh);
++ const unsigned int hoff = height * stride_src;
++
++ if (src_l != NULL) {
++ src_idx = (CTB(s->sao, x_ctb-1, y_ctb+1).type_idx[c_idx] ==
++ SAO_APPLIED);
++ copy_pixel(dst1 - (1 << sh), src_idx ? src_spb - (1 << sh) : src_l + hoff, sh);
++ }
++
++ src_idx = (CTB(s->sao, x_ctb, y_ctb+1).type_idx[c_idx] ==
++ SAO_APPLIED);
++ memcpy(dst1, src_idx ? src_spb : src + hoff, width << sh);
++
++ if (src_r != NULL) {
++ src_idx = (CTB(s->sao, x_ctb+1, y_ctb+1).type_idx[c_idx] ==
++ SAO_APPLIED);
++ copy_pixel(dst1 + (width << sh), src_idx ? src_spb + (width << sh) : src_r + hoff, sh);
++ }
++ }
++ if (src_l != NULL) {
++ if (CTB(s->sao, x_ctb-1, y_ctb).type_idx[c_idx] == SAO_APPLIED) {
++ ff_hevc_rpi_copy_vert(dst - (1 << sh),
++ s->sao_pixel_buffer_v[c_idx] + (((2 * x_ctb - 1) * h + y0) << sh),
++ sh, height, stride_dst, 1 << sh);
++ } else {
++ ff_hevc_rpi_copy_vert(dst - (1 << sh),
++ src_l,
++ sh, height, stride_dst, stride_src);
++ }
++ }
++ if (src_r != NULL) {
++ if (CTB(s->sao, x_ctb+1, y_ctb).type_idx[c_idx] == SAO_APPLIED) {
++ ff_hevc_rpi_copy_vert(dst + (width << sh),
++ s->sao_pixel_buffer_v[c_idx] + (((2 * x_ctb + 2) * h + y0) << sh),
++ sh, height, stride_dst, 1 << sh);
++ } else {
++ ff_hevc_rpi_copy_vert(dst + (width << sh),
++ src_r,
++ sh, height, stride_dst, stride_src);
++ }
++ }
++
++ s->hevcdsp.cpy_blk(dst, stride_dst, src, stride_src, width << sh, height);
++
++ copy_CTB_to_hv(s, src, stride_src, x0, y0, width, height, c_idx,
++ x_ctb, y_ctb);
++ if (sliced && c_idx != 0)
++ {
++ // Class always the same for both U & V (which is just as well :-))
++ s->hevcdsp.sao_edge_filter_c[tab](src, dst, stride_src,
++ sao->offset_val[1], sao->offset_val[2], sao->eo_class[1],
++ width, height);
++ s->hevcdsp.sao_edge_restore_c[restore](src, dst,
++ stride_src, stride_dst,
++ sao,
++ edges, width,
++ height, c_idx,
++ vert_edge,
++ horiz_edge,
++ diag_edge);
++ }
++ else
++ {
++ s->hevcdsp.sao_edge_filter[tab](src, dst, stride_src, sao->offset_val[c_idx],
++ sao->eo_class[c_idx], width, height);
++ s->hevcdsp.sao_edge_restore[restore](src, dst,
++ stride_src, stride_dst,
++ sao,
++ edges, width,
++ height, c_idx,
++ vert_edge,
++ horiz_edge,
++ diag_edge);
++ }
++ restore_tqb_pixels(s, src, dst, stride_src, stride_dst,
++ x, y, width, height, c_idx);
++ sao->type_idx[c_idx] = SAO_APPLIED;
++ break;
++ }
++ }
++ }
++
++#if RPI_ZC_SAND_8_IN_10_BUF
++ if (s->frame->format == AV_PIX_FMT_SAND64_10 && s->frame->buf[RPI_ZC_SAND_8_IN_10_BUF] != NULL &&
++ (((x + (1 << (s->ps.sps->log2_ctb_size))) & 255) == 0 || edges[2]))
++ {
++ const unsigned int stride1 = frame_stride1(s->frame, 1);
++ const unsigned int stride2 = av_rpi_sand_frame_stride2(s->frame);
++ const unsigned int xoff = (x >> 8) * stride2 * stride1;
++ const unsigned int ctb_size = (1 << s->ps.sps->log2_ctb_size);
++ const uint8_t * const sy = s->frame->data[0] + xoff * 4 + y * stride1;
++ uint8_t * const dy = s->frame->buf[4]->data + xoff * 2 + y * stride1;
++ const uint8_t * const sc = s->frame->data[1] + xoff * 4 + (y >> 1) * stride1;
++ uint8_t * const dc = s->frame->buf[4]->data + (s->frame->data[1] - s->frame->data[0]) + xoff * 2 + (y >> 1) * stride1;
++ const unsigned int wy = !edges[2] ? 256 : s->ps.sps->width - (x & ~255);
++ const unsigned int hy = !edges[3] ? ctb_size : s->ps.sps->height - y;
++
++// printf("dy=%p/%p, stride1=%d, stride2=%d, sy=%p/%p, wy=%d, hy=%d, x=%d, y=%d, cs=%d\n", dy, dc, stride1, stride2, sy, sc, wy, hy, x, y, ctb_size);
++ av_rpi_sand16_to_sand8(dy, stride1, stride2, sy, stride1, stride2, wy, hy, 3);
++ av_rpi_sand16_to_sand8(dc, stride1, stride2, sc, stride1, stride2, wy, hy >> 1, 3);
++ }
++#endif
++}
++
++// When bits are delivered to deblock we want them
++//#define TL 1
++//#define TR 2
++//#define BL 4
++//#define BR 8
++
++// pcm4 returns them as b0 = tl, b1 = tr, b16 = bl, b17 = br
++// so we need to rearrange before passing on
++
++static inline uint32_t pcm4(const HEVCRpiContext * const s, const unsigned int x, const unsigned int y)
++{
++ const uint8_t * const pcm = s->is_pcm + (x >> 6) + (y >> 3) * s->ps.sps->pcm_width;
++ return (pcm[0] |
++ (pcm[1] << 8) |
++ (pcm[s->ps.sps->pcm_width] << 16) |
++ (pcm[s->ps.sps->pcm_width + 1] << 24)) >> ((x >> 3) & 7);
++}
++
++static inline uint32_t pcm2(const HEVCRpiContext * const s, const unsigned int x, const unsigned int y)
++{
++ const uint8_t * const pcm = s->is_pcm + (x >> 6) + (y >> 3) * s->ps.sps->pcm_width;
++ return (pcm[0] | (pcm[1] << 8)) >> ((x >> 3) & 7);
++}
++
++// We cast away const here as we want this to work for both get and set
++static inline uint32_t * bs_ptr32(const uint8_t * bs, const unsigned int stride2, const unsigned int x, const unsigned int y)
++{
++ return (uint32_t *)(bs +
++#if (~3U & (HEVC_RPI_BS_STRIDE1_PEL_MASK >> HEVC_RPI_BS_PELS_PER_BYTE_SHIFT)) != 0
++#warning Unexpected masks
++ // As it happens we end up with stride1 = sizeof(uint32_t) so this expr vanishes
++ ((x >> HEVC_RPI_BS_PELS_PER_BYTE_SHIFT) &
++ (~3 & (HEVC_RPI_BS_STRIDE1_PEL_MASK >> HEVC_RPI_BS_PELS_PER_BYTE_SHIFT))) +
++#elif HEVC_RPI_BS_STRIDE1_BYTES < 4
++#error Stride1 < return size
++#endif
++ ((y >> HEVC_RPI_BS_Y_SHR) << HEVC_RPI_BS_STRIDE1_BYTE_SHIFT) +
++ (x >> HEVC_RPI_BS_STRIDE1_PEL_SHIFT) * stride2);
++}
++
++static inline uint8_t * bs_ptr8(const uint8_t * bs, const unsigned int stride2, const unsigned int x, const unsigned int y)
++{
++ return (uint8_t *)(bs +
++ ((x >> HEVC_RPI_BS_PELS_PER_BYTE_SHIFT) &
++ (HEVC_RPI_BS_STRIDE1_PEL_MASK >> HEVC_RPI_BS_PELS_PER_BYTE_SHIFT)) +
++ ((y >> HEVC_RPI_BS_Y_SHR) << HEVC_RPI_BS_STRIDE1_BYTE_SHIFT) +
++ (x >> HEVC_RPI_BS_STRIDE1_PEL_SHIFT) * stride2);
++}
++
++
++// Get block strength
++// Given how we call we will always get within the 32bit boundries
++static inline uint32_t bs_get32(const uint8_t * bs, unsigned int stride2,
++ unsigned int xl, unsigned int xr, const unsigned int y)
++{
++ if (xr <= xl) {
++ return 0;
++ }
++ else
++ {
++#if HAVE_ARMV6T2_INLINE
++#if (~3U & (HEVC_RPI_BS_STRIDE1_PEL_MASK >> HEVC_RPI_BS_PELS_PER_BYTE_SHIFT)) != 0
++#error This case not yet handled in bs_get32
++#elif HEVC_RPI_BS_STRIDE1_BYTES < 4
++#error Stride1 < return size
++#endif
++ uint32_t tmp;
++ __asm__ (
++ "lsr %[tmp], %[xl], %[xl_shift] \n\t"
++ "rsb %[xr], %[xl], %[xr] \n\t"
++ "mla %[stride2], %[stride2], %[tmp], %[bs] \n\t"
++ "add %[xr], %[xr], #7 \n\t"
++ "lsr %[bs], %[y], %[y_shift1] \n\t"
++ "bic %[xr], %[xr], #7 \n\t"
++ "ubfx %[xl], %[xl], #1, #5 \n\t"
++ "lsr %[xr], %[xr], #1 \n\t"
++ "cmp %[xr], #32 \n\t"
++ "mvn %[tmp], #0 \n\t"
++ "ldr %[bs], [%[stride2], %[bs], lsl %[y_shift2]] \n\t"
++ "lsl %[tmp], %[tmp], %[xr] \n\t"
++ "lsr %[xl], %[bs], %[xl] \n\t"
++ "it ne \n\t"
++ "bicne %[bs], %[xl], %[tmp] \n\t"
++ : // Outputs
++ [bs]"+r"(bs),
++ [stride2]"+r"(stride2),
++ [xl]"+r"(xl),
++ [xr]"+r"(xr),
++ [tmp]"=&r"(tmp)
++ : // Inputs
++ [y]"r"(y),
++ [xl_shift]"M"(HEVC_RPI_BS_STRIDE1_PEL_SHIFT),
++ [y_shift1]"M"(HEVC_RPI_BS_Y_SHR),
++ [y_shift2]"M"(HEVC_RPI_BS_STRIDE1_BYTE_SHIFT)
++ : // Clobbers
++ "cc"
++ );
++ return (uint32_t) bs;
++#else
++ const uint32_t a = *bs_ptr32(bs, stride2, xl, y);
++ const unsigned int n = ((xr - xl + 7) & ~7) >> 1;
++
++ return n == 32 ? a :
++ (a >> ((xl >> 1) & 31)) & ~(~0U << n);
++#endif
++ }
++}
++
++static inline uint32_t hbs_get32(const HEVCRpiContext * const s, const unsigned int xl, const unsigned int xr, const unsigned int y)
++{
++ av_assert2(((xl ^ (xr - 1)) >> s->ps.sps->log2_ctb_size) == 0);
++ return bs_get32(s->bs_horizontal, s->bs_stride2, xl, xr, y);
++}
++
++static inline uint32_t vbs_get32(const HEVCRpiContext * const s, const unsigned int xl, const unsigned int xr, const unsigned int y)
++{
++ av_assert2(((xl ^ (xr - 1)) >> s->ps.sps->log2_ctb_size) == 0);
++ return bs_get32(s->bs_vertical, s->bs_stride2, xl, xr, y);
++}
++
++
++static void deblock_y_blk(const HEVCRpiContext * const s, const RpiBlk bounds, const int end_x, const int end_y)
++{
++ const unsigned int log2_ctb_size = s->ps.sps->log2_ctb_size;
++ const unsigned int log2_min_cb_size = s->ps.sps->log2_min_cb_size;
++ const unsigned int ctb_size = (1 << log2_ctb_size);
++ const unsigned int cb_r = FFMIN(bounds.x + bounds.w, s->ps.sps->width) - (end_x ? 0 : 1);
++ const unsigned int ctb_n = (bounds.x + bounds.y * s->ps.sps->ctb_width) >> log2_ctb_size;
++ const DBParams * cb_dbp = s->deblock + ctb_n;
++ const unsigned int b_b = FFMIN(bounds.y + bounds.h, s->ps.sps->height) - (end_y ? 0 : 8);
++
++ unsigned int cb_x;
++
++ // Do in CTB-shaped blocks
++ for (cb_x = bounds.x; cb_x < cb_r; cb_x += ctb_size, ++cb_dbp)
++ {
++ const unsigned int bv_r = FFMIN(cb_x + ctb_size, cb_r);
++ const unsigned int bv_l = FFMAX(cb_x, 8);
++ const unsigned int bh_r = cb_x + ctb_size >= cb_r ? cb_r - 8 : cb_x + ctb_size - 9;
++ const unsigned int bh_l = bv_l - 8;
++ unsigned int y;
++
++ // Main body
++ for (y = (bounds.y == 0 ? 0 : bounds.y - 8); y < b_b; y += 8)
++ {
++ uint32_t vbs = vbs_get32(s, bv_l, bv_r, y);
++
++ const DBParams * const dbp = y < bounds.y ? cb_dbp - s->ps.sps->ctb_width : cb_dbp;
++ const int8_t * const qta = s->qp_y_tab + ((y - 1) >> log2_min_cb_size) * s->ps.sps->min_cb_width;
++ const int8_t * const qtb = s->qp_y_tab + (y >> log2_min_cb_size) * s->ps.sps->min_cb_width;
++
++ if (vbs != 0)
++ {
++ const uint8_t * const tcv = tctable + dbp->tc_offset;
++ const uint8_t * const betav = betatable + dbp->beta_offset;
++ unsigned int pcmfa = pcm2(s, bv_l - 1, y);
++ unsigned int x;
++
++ for (x = bv_l; vbs != 0; x += 8, vbs >>= 4, pcmfa >>= 1)
++ {
++ if ((vbs & 0xf) != 0 && (pcmfa & 3) != 3)
++ {
++ const int qp = (qtb[(x - 1) >> log2_min_cb_size] + qtb[x >> log2_min_cb_size] + 1) >> 1;
++ s->hevcdsp.hevc_v_loop_filter_luma2(av_rpi_sand_frame_pos_y(s->frame, x, y),
++ frame_stride1(s->frame, LUMA),
++ betav[qp],
++ ((vbs & 3) == 0 ? 0 : tcv[qp + (int)(vbs & 2)]) |
++ (((vbs & 0xc) == 0 ? 0 : tcv[qp + (int)((vbs >> 2) & 2)]) << 16),
++ pcmfa & 3,
++ av_rpi_sand_frame_pos_y(s->frame, x - 4, y));
++ }
++ }
++ }
++
++ if (y != 0)
++ {
++ uint32_t hbs;
++
++ // H left - mostly separated out so we only need a uint32_t hbs
++ if ((hbs = hbs_get32(s, bh_l, cb_x, y)) != 0)
++ {
++ const unsigned int x = bh_l;
++ const unsigned int pcmfa = pcm4(s, bh_l, y - 1);
++ const int qp = (qta[x >> log2_min_cb_size] + qtb[x >> log2_min_cb_size] + 1) >> 1;
++ const DBParams * const dbph = dbp - 1;
++ const uint8_t * const tc = tctable + dbph->tc_offset + qp;
++
++ av_assert2(cb_x - bh_l == 8);
++
++ s->hevcdsp.hevc_h_loop_filter_luma2(av_rpi_sand_frame_pos_y(s->frame, x, y),
++ frame_stride1(s->frame, LUMA),
++ betatable[qp + dbph->beta_offset],
++ ((hbs & 3) == 0 ? 0 : tc[hbs & 2]) |
++ (((hbs & 0xc) == 0 ? 0 : tc[(hbs >> 2) & 2]) << 16),
++ (pcmfa & 1) | ((pcmfa & 0x10000) >> 15));
++ }
++
++ // H
++ if ((hbs = hbs_get32(s, cb_x, bh_r + 1, y)) != 0) // Will give (x <= bh_r) in for loop
++ {
++ unsigned int x;
++ unsigned int pcmfa = pcm4(s, cb_x, y - 1);
++
++ for (x = cb_x; hbs != 0; x += 8, hbs >>= 4, pcmfa >>= 1)
++ {
++ if ((hbs & 0xf) != 0 && (~pcmfa & 0x10001) != 0)
++ {
++ const int qp = (qta[x >> log2_min_cb_size] + qtb[x >> log2_min_cb_size] + 1) >> 1;
++ const uint8_t * const tc = tctable + dbp->tc_offset + qp;
++ s->hevcdsp.hevc_h_loop_filter_luma2(av_rpi_sand_frame_pos_y(s->frame, x, y),
++ frame_stride1(s->frame, LUMA),
++ betatable[qp + dbp->beta_offset],
++ ((hbs & 3) == 0 ? 0 : tc[hbs & 2]) |
++ (((hbs & 0xc) == 0 ? 0 : tc[(hbs >> 2) & 2]) << 16),
++ (pcmfa & 1) | ((pcmfa & 0x10000) >> 15));
++ }
++ }
++ }
++ }
++
++ }
++ }
++}
++
++static av_always_inline int q2h(const HEVCRpiContext * const s, const unsigned int x, const unsigned int y)
++{
++ const unsigned int log2_min_cb_size = s->ps.sps->log2_min_cb_size;
++ const int8_t * const qt = s->qp_y_tab + (y >> log2_min_cb_size) * s->ps.sps->min_cb_width;
++ return (qt[(x - 1) >> log2_min_cb_size] + qt[x >> log2_min_cb_size] + 1) >> 1;
++}
++
++static void deblock_uv_blk(const HEVCRpiContext * const s, const RpiBlk bounds, const int end_x, const int end_y)
++{
++ const unsigned int log2_ctb_size = s->ps.sps->log2_ctb_size;
++ const unsigned int log2_min_cb_size = s->ps.sps->log2_min_cb_size;
++ const unsigned int ctb_size = (1 << log2_ctb_size);
++ const unsigned int cb_r = FFMIN(bounds.x + bounds.w, s->ps.sps->width) - (end_x ? 0 : 8);
++ const unsigned int ctb_n = (bounds.x + bounds.y * s->ps.sps->ctb_width) >> log2_ctb_size;
++ const DBParams * dbp = s->deblock + ctb_n;
++ const unsigned int b_b = FFMIN(bounds.y + bounds.h, s->ps.sps->height) - (end_y ? 0 : 8);
++ const uint8_t * const tcq_u = s->ps.pps->qp_dblk_x[1];
++ const uint8_t * const tcq_v = s->ps.pps->qp_dblk_x[2];
++
++ unsigned int cb_x;
++
++ av_assert1((bounds.x & (ctb_size - 1)) == 0);
++ av_assert1((bounds.y & (ctb_size - 1)) == 0);
++ av_assert1(bounds.h <= ctb_size);
++
++ // Do in CTB-shaped blocks
++ for (cb_x = bounds.x; cb_x < cb_r; cb_x += ctb_size, ++dbp) {
++ const unsigned int bv_r = FFMIN(cb_x + ctb_size, cb_r);
++ const unsigned int bv_l = FFMAX(cb_x, 16);
++ unsigned int y;
++
++ // V above
++ if (bounds.y != 0) {
++ // Deblock V up 8
++ // CTB above current
++ // Top-half only (tc4 & ~0xffff == 0) is special cased in asm
++ const unsigned int y = bounds.y - 8;
++ uint32_t vbs = vbs_get32(s, bv_l, bv_r, y) & 0x02020202U;
++
++ if (vbs != 0)
++ {
++ unsigned int pcmfa = pcm2(s, bv_l - 1, y);
++ const uint8_t * const tc = tctable + 2 + (dbp - s->ps.sps->ctb_width)->tc_offset;
++ unsigned int x;
++
++ for (x = bv_l; vbs != 0; x += 16, vbs >>= 8, pcmfa >>= 2)
++ {
++ if ((vbs & 2) != 0 && (~pcmfa & 3) != 0)
++ {
++ const int qp0 = q2h(s, x, y);
++ s->hevcdsp.hevc_v_loop_filter_uv2(av_rpi_sand_frame_pos_c(s->frame, x >> 1, y >> 1),
++ frame_stride1(s->frame, 1),
++ tc[tcq_u[qp0]] | (tc[tcq_v[qp0]] << 8),
++ av_rpi_sand_frame_pos_c(s->frame, (x >> 1) - 2, y >> 1),
++ pcmfa & 3);
++ }
++ }
++ }
++ }
++
++ for (y = bounds.y; y < b_b; y += 16)
++ {
++ uint32_t vbs = (vbs_get32(s, bv_l, bv_r, y) & 0x02020202U) |
++ (y + 16 > b_b ? 0 : (vbs_get32(s, bv_l, bv_r, y + 8) & 0x02020202U) << 4);
++
++ // V
++ if (vbs != 0)
++ {
++ unsigned int x;
++ unsigned int pcmfa =
++ (y + 16 > b_b ?
++ pcm2(s, bv_l - 1, y) | 0xffff0000 :
++ pcm4(s, bv_l - 1, y));
++ const uint8_t * const tc = tctable + 2 + dbp->tc_offset;
++
++ for (x = bv_l; vbs != 0; x += 16, vbs >>= 8, pcmfa >>= 2)
++ {
++ if ((vbs & 0xff) != 0 && (~pcmfa & 0x30003) != 0)
++ {
++ const int qp0 = q2h(s, x, y);
++ const int qp1 = q2h(s, x, y + 8);
++ s->hevcdsp.hevc_v_loop_filter_uv2(av_rpi_sand_frame_pos_c(s->frame, x >> 1, y >> 1),
++ frame_stride1(s->frame, 1),
++ ((vbs & 2) == 0 ? 0 : (tc[tcq_u[qp0]] << 0) | (tc[tcq_v[qp0]] << 8)) |
++ ((vbs & 0x20) == 0 ? 0 : (tc[tcq_u[qp1]] << 16) | (tc[tcq_v[qp1]] << 24)),
++ av_rpi_sand_frame_pos_c(s->frame, (x >> 1) - 2, y >> 1),
++ (pcmfa & 3) | ((pcmfa >> 14) & 0xc));
++ }
++ }
++ }
++
++ // H
++ if (y != 0)
++ {
++ uint32_t hbs;
++ const unsigned int bh_l = bv_l - 16;
++ const unsigned int bh_r = cb_x + ctb_size >= cb_r ? cb_r : cb_x + ctb_size - 16;
++ const int8_t * const qta = s->qp_y_tab + ((y - 1) >> log2_min_cb_size) * s->ps.sps->min_cb_width;
++ const int8_t * const qtb = s->qp_y_tab + (y >> log2_min_cb_size) * s->ps.sps->min_cb_width;
++
++ // H left - mostly separated out so we only need a uint32_t hbs
++ // Stub is width 8 to the left of bounds, but width 16 internally
++ if ((hbs = hbs_get32(s, bh_l, cb_x, y) & 0x22U) != 0)
++ {
++ unsigned int pcmfa = pcm4(s, bh_l, y - 1);
++
++ // Chop off bits we don't want...
++ if (bh_l < bounds.x) {
++ pcmfa |= 0x10001; // TL|BL pre rearrangement
++ hbs &= ~3; // Make BS 0
++ }
++
++ // Double check we still want this
++ if (hbs != 0 && (~pcmfa & 0x30003) != 0)
++ {
++ const unsigned int x = bh_l;
++ const int qp0 = (qta[x >> log2_min_cb_size] + qtb[x >> log2_min_cb_size] + 1) >> 1;
++ const int qp1 = (qta[(x + 8) >> log2_min_cb_size] + qtb[(x + 8) >> log2_min_cb_size] + 1) >> 1;
++ const uint8_t * const tc = tctable + 2 + (dbp - 1)->tc_offset;
++
++ s->hevcdsp.hevc_h_loop_filter_uv(av_rpi_sand_frame_pos_c(s->frame, x >> 1, y >> 1),
++ frame_stride1(s->frame, 1),
++ ((hbs & 2) == 0 ? 0 : (tc[tcq_u[qp0]] << 0) | (tc[tcq_v[qp0]] << 8)) |
++ ((hbs & 0x20) == 0 ? 0 : (tc[tcq_u[qp1]] << 16) | (tc[tcq_v[qp1]] << 24)),
++ (pcmfa & 3) | ((pcmfa >> 14) & 0xc));
++ }
++ }
++
++ // H main
++ if ((hbs = (hbs_get32(s, cb_x, bh_r, y) & 0x22222222U)) != 0)
++ {
++ unsigned int x;
++ unsigned int pcmfa = pcm4(s, cb_x, y - 1); // Might like to mask out far right writes but probably not worth it
++
++ for (x = cb_x; hbs != 0; x += 16, hbs >>= 8, pcmfa >>= 2)
++ {
++ if ((hbs & 0xff) != 0 && (~pcmfa & 0x30003) != 0)
++ {
++ const int qp0 = (qta[x >> log2_min_cb_size] + qtb[x >> log2_min_cb_size] + 1) >> 1;
++ const int qp1 = (qta[(x + 8) >> log2_min_cb_size] + qtb[(x + 8) >> log2_min_cb_size] + 1) >> 1;
++ const uint8_t * const tc = tctable + 2 + dbp->tc_offset;
++
++ s->hevcdsp.hevc_h_loop_filter_uv(av_rpi_sand_frame_pos_c(s->frame, x >> 1, y >> 1),
++ frame_stride1(s->frame, 1),
++ ((hbs & 2) == 0 ? 0 : (tc[tcq_u[qp0]] << 0) | (tc[tcq_v[qp0]] << 8)) |
++ ((hbs & 0x20) == 0 ? 0 : (tc[tcq_u[qp1]] << 16) | (tc[tcq_v[qp1]] << 24)),
++ (pcmfa & 3) | ((pcmfa >> 14) & 0xc));
++ }
++ }
++ }
++ }
++ }
++ }
++}
++
++static inline unsigned int off_boundary(const unsigned int x, const unsigned int log2_n)
++{
++ return x & ~(~0U << log2_n);
++}
++
++static inline void hbs_set(const HEVCRpiContext * const s, const unsigned int x, const unsigned int y, const uint32_t mask, uint32_t bsf)
++{
++ av_assert2((y & 7) == 0);
++
++ // This doesn't have the same simultainious update issues that bsf_stash
++ // does (other threads will have a different y) so we can do it the easy way
++ if ((bsf &= mask) != 0)
++ *bs_ptr32(s->bs_horizontal, s->bs_stride2, x, y) |= bsf << ((x >> 1) & 31);
++}
++
++
++static void vbs_set(const HEVCRpiContext * const s, const unsigned int x, const unsigned int y, const uint32_t mask, uint32_t bsf)
++{
++ // We arrange this in a slightly odd fashion but it lines up with
++ // how we are going to use it in the actual deblock code & it is easier
++ // to do the contortions here than there
++ //
++ // Arrange (LE) {x0y0, x0y4, x8y0, x8,y4}, {x16y0, x16y4, x24y0, x24y4},...
++
++ av_assert2((x & 7) == 0);
++
++ if ((bsf &= mask) != 0)
++ {
++ uint8_t *p = bs_ptr8(s->bs_vertical, s->bs_stride2, x, y);
++ const unsigned int sh = ((x & 8) | (y & 4)) >> 1;
++
++ if (mask <= 0xf)
++ {
++ *p |= (bsf << sh);
++ }
++ else
++ {
++ do {
++ *p |= (bsf & 0xf) << sh;
++ p += HEVC_RPI_BS_STRIDE1_BYTES;
++ } while ((bsf >>= 4) != 0);
++ }
++ }
++}
++
++static inline uint32_t bsf_mv(const HEVCRpiContext * const s,
++ const unsigned int rep, const unsigned int dup,
++ const unsigned int mvf_stride0,
++ const unsigned int mvf_stride1,
++ const RefPicList * const rpl_p, const RefPicList * const rpl_q,
++ const HEVCRpiMvField * const mvf_p, const HEVCRpiMvField * const mvf_q)
++{
++ return s->hevcdsp.hevc_deblocking_boundary_strengths(rep, dup,
++ mvf_p, mvf_q,
++ rpl_p[0].list, rpl_p[1].list, rpl_q[0].list, rpl_q[1].list,
++ sizeof(HEVCRpiMvField) * mvf_stride0, sizeof(HEVCRpiMvField) * mvf_stride1);
++}
++
++
++void ff_hevc_rpi_deblocking_boundary_strengths(const HEVCRpiContext * const s,
++ const HEVCRpiLocalContext * const lc,
++ const unsigned int x0, const unsigned int y0,
++ const unsigned int log2_trafo_size,
++ const int is_coded_block)
++{
++ const HEVCRpiMvField * const mvf_curr = mvf_stash_ptr(s, lc, x0, y0);
++ const unsigned int log2_min_pu_size = LOG2_MIN_PU_SIZE;
++ const RefPicList * const rpl = s->refPicList;
++ // Rep count for bsf_mv when running with min_pu chuncks
++ const unsigned int log2_rep_min_pu = log2_trafo_size <= log2_min_pu_size ? 0 : log2_trafo_size - log2_min_pu_size;
++ const unsigned int boundary_flags = s->sh.no_dblk_boundary_flags & lc->boundary_flags;
++ const unsigned int trafo_size = (1U << log2_trafo_size);
++ const uint32_t bsf_mask = log2_trafo_size > 5 ? ~0U : (1U << (trafo_size >> 1)) - 1;
++ const uint32_t bsf_cbf = (bsf_mask & 0x55555555);
++
++ // Do we cover a pred split line?
++ const int has_x_split = x0 < lc->cu.x_split && x0 + trafo_size > lc->cu.x_split;
++ const int has_y_split = y0 < lc->cu.y_split && y0 + trafo_size > lc->cu.y_split;
++
++ uint32_t bsf_h;
++ uint32_t bsf_v;
++
++#ifdef DISABLE_STRENGTHS
++ return;
++#endif
++
++ // We are always on a size boundary
++ av_assert2((x0 & (trafo_size - 1)) == 0);
++ av_assert2((y0 & (trafo_size - 1)) == 0);
++ // log2_trafo_size not really a transform size; we can have to deal
++ // with size 2^6 blocks
++ av_assert2(log2_trafo_size >= 2 && log2_trafo_size <= 6);
++
++ // Retrieve and update coded (b0), intra (b1) bs flags
++ //
++ // Store on min width (rather than uint32_t) to avoid possible issues
++ // with another thread on another core running wpp using the same
++ // memory (min CTB = 16 pels = 4 bsf els = 8 bits)
++ //
++ // In bsf BS=2 is represented by 3 as it is much easier to test & set
++ // and the actual deblock code tests for 0 and b1 set/not-set so 2 and
++ // 3 will work the same
++ {
++ // Given where we are called from is_cbf_luma & is_intra will be constant over the block
++ const uint32_t bsf0 = (lc->cu.pred_mode == MODE_INTRA) ? bsf_mask : is_coded_block ? bsf_cbf : 0;
++ uint8_t *const p = s->bsf_stash_up + (x0 >> 4);
++ uint8_t *const q = s->bsf_stash_left + (y0 >> 4);
++
++ switch (log2_trafo_size)
++ {
++ case 2:
++ case 3:
++ {
++ const unsigned int sh_h = (x0 >> 1) & 7;
++ const unsigned int sh_v = (y0 >> 1) & 7;
++ bsf_h = *p;
++ bsf_v = *q;
++ *p = (bsf_h & ~(bsf_mask << sh_h)) | (bsf0 << sh_h);
++ *q = (bsf_v & ~(bsf_mask << sh_v)) | (bsf0 << sh_v);
++ bsf_h >>= sh_h;
++ bsf_v >>= sh_v;
++ break;
++ }
++ case 4:
++ bsf_h = *p;
++ bsf_v = *q;
++ *p = bsf0;
++ *q = bsf0;
++ break;
++ case 5:
++ bsf_h = *(uint16_t *)p;
++ bsf_v = *(uint16_t *)q;
++ *(uint16_t *)p = bsf0;
++ *(uint16_t *)q = bsf0;
++ break;
++ case 6:
++ default:
++ bsf_h = *(uint32_t *)p;
++ bsf_v = *(uint32_t *)q;
++ *(uint32_t *)p = bsf0;
++ *(uint32_t *)q = bsf0;
++ break;
++ }
++
++ bsf_h |= bsf0;
++ bsf_v |= bsf0;
++ }
++
++ // Do Horizontal
++ if ((y0 & 7) == 0)
++ {
++ // Boundary upper
++ if (y0 != 0 &&
++ (off_boundary(y0, s->ps.sps->log2_ctb_size) ||
++ (boundary_flags & (BOUNDARY_UPPER_SLICE | BOUNDARY_UPPER_TILE)) == 0))
++ {
++ // Look at MVs (BS=1) if we don't already has a full set of bs bits
++ if ((~bsf_h & bsf_cbf) != 0 && (y0 == lc->cu.y || y0 == lc->cu.y_split))
++ {
++ // If we aren't on the top boundary we must be in the middle
++ // and in that case we know where mvf can change
++ const unsigned int log2_rep = (y0 == lc->cu.y) ? log2_rep_min_pu : has_x_split ? 1 : 0;
++ const RefPicList *const rpl_top = !off_boundary(y0, s->ps.sps->log2_ctb_size) ?
++ s->rpl_up[x0 >> s->ps.sps->log2_ctb_size] :
++ rpl;
++
++ bsf_h |= bsf_mv(s, 1 << log2_rep, trafo_size >> (2 + log2_rep),
++ trafo_size >> (log2_min_pu_size + log2_rep),
++ trafo_size >> (log2_min_pu_size + log2_rep),
++ rpl, rpl_top,
++ mvf_curr, mvf_ptr(s, lc, x0, y0, x0, y0 - 1));
++ }
++
++ // Finally put the results into bs
++ hbs_set(s, x0, y0, bsf_mask, bsf_h);
++ }
++
++ // Max of 1 pu internal split - ignore if not on 8pel boundary
++ if (has_y_split && !off_boundary(lc->cu.y_split, 3))
++ {
++ const HEVCRpiMvField * const mvf = mvf_stash_ptr(s, lc, x0, lc->cu.y_split);
++ // If we have the x split as well then it must be in the middle
++ const unsigned int log2_rep = has_x_split ? 1 : 0;
++
++ hbs_set(s, x0, lc->cu.y_split, bsf_mask,
++ bsf_mv(s, 1 << log2_rep, trafo_size >> (2 + log2_rep),
++ trafo_size >> (log2_min_pu_size + log2_rep),
++ trafo_size >> (log2_min_pu_size + log2_rep),
++ rpl, rpl,
++ mvf, mvf - MVF_STASH_WIDTH_PU));
++ }
++ }
++
++ // And again for vertical - same logic as horizontal just in the other direction
++ if ((x0 & 7) == 0)
++ {
++ // Boundary left
++ if (x0 != 0 &&
++ (off_boundary(x0, s->ps.sps->log2_ctb_size) ||
++ (boundary_flags & (BOUNDARY_LEFT_SLICE | BOUNDARY_LEFT_TILE)) == 0))
++ {
++ if ((~bsf_v & bsf_cbf) != 0 && (x0 == lc->cu.x || x0 == lc->cu.x_split))
++ {
++ const unsigned int log2_rep = (x0 == lc->cu.x) ? log2_rep_min_pu : has_y_split ? 1 : 0;
++ const RefPicList *const rpl_left = !off_boundary(x0, s->ps.sps->log2_ctb_size) ?
++ s->rpl_left[y0 >> s->ps.sps->log2_ctb_size] :
++ rpl;
++
++ bsf_v |= bsf_mv(s, 1 << log2_rep, trafo_size >> (2 + log2_rep),
++ (MVF_STASH_WIDTH_PU << log2_trafo_size) >> (log2_min_pu_size + log2_rep),
++ (mvf_left_stride(s, x0, x0 - 1) << log2_trafo_size) >> (log2_min_pu_size + log2_rep),
++ rpl, rpl_left,
++ mvf_curr, mvf_ptr(s, lc, x0, y0, x0 - 1, y0));
++ }
++
++ vbs_set(s, x0, y0, bsf_mask, bsf_v);
++ }
++
++ if (has_x_split && !off_boundary(lc->cu.x_split, 3))
++ {
++ const HEVCRpiMvField *const mvf = mvf_stash_ptr(s, lc, lc->cu.x_split, y0);
++ const unsigned int log2_rep = has_y_split ? 1 : 0;
++
++ vbs_set(s, lc->cu.x_split, y0, bsf_mask,
++ bsf_mv(s, 1 << log2_rep, trafo_size >> (2 + log2_rep),
++ (MVF_STASH_WIDTH_PU << log2_trafo_size) >> (log2_min_pu_size + log2_rep),
++ (MVF_STASH_WIDTH_PU << log2_trafo_size) >> (log2_min_pu_size + log2_rep),
++ rpl, rpl,
++ mvf, mvf - 1));
++ }
++ }
++}
++
++#undef LUMA
++#undef CB
++#undef CR
++
++static inline unsigned int ussub(const unsigned int a, const unsigned int b)
++{
++ return a < b ? 0 : a - b;
++}
++
++static inline int cache_boundry(const AVFrame * const frame, const unsigned int x)
++{
++ return ((x >> av_rpi_sand_frame_xshl(frame)) & ~63) == 0;
++}
++
++int ff_hevc_rpi_hls_filter_blk(const HEVCRpiContext * const s, const RpiBlk bounds, const int eot)
++{
++ const int ctb_size = (1 << s->ps.sps->log2_ctb_size);
++ int x, y;
++
++ const unsigned int br = FFMIN(bounds.x + bounds.w, s->ps.sps->width);
++ const unsigned int bb = FFMIN(bounds.y + bounds.h, s->ps.sps->height);
++
++ const int x_end = (br >= s->ps.sps->width);
++ const int y_end = (bb >= s->ps.sps->height);
++
++ // Deblock may not touch the edges of the bound as they are still needed
++ // for Intra pred
++ //
++ // Deblock is disabled with a per-slice flag
++ // Given that bounds may cover multiple slices & we dblock outside bounds
++ // anyway we can't avoid deblock using that flag - about the only thing we
++ // could do is have a "no deblock seen yet" flag but it doesn't really
++ // seem worth the effort
++
++ deblock_y_blk(s, bounds, x_end, y_end);
++ deblock_uv_blk(s, bounds, x_end, y_end);
++
++ // SAO needs
++ // (a) CTB alignment
++ // (b) Valid pixels all the way around the CTB in particular it needs the DR pixel
++ {
++ const unsigned int xo = bounds.x - ((bounds.x - 16) & ~(ctb_size - 1));
++ const unsigned int yo = bounds.y - ((bounds.y - 16) & ~(ctb_size - 1));
++ const unsigned int yt = ussub(bounds.y, yo);
++ const unsigned int yb = y_end ? bb : ussub(bb, yo);
++ const unsigned int xl = ussub(bounds.x, xo);
++ const unsigned int xr = x_end ? br : ussub(br, xo);
++
++ if (s->ps.sps->sao_enabled)
++ {
++ for (y = yt; y < yb; y += ctb_size) {
++ for (x = xl; x < xr; x += ctb_size) {
++ sao_filter_CTB(s, x, y);
++ }
++ }
++ }
++
++ // Cache invalidate
++ y = 0;
++ if (xr != 0 && yb != 0)
++ {
++ const unsigned int llen =
++ (av_rpi_sand_frame_stride1(s->frame) >> av_rpi_sand_frame_xshl(s->frame));
++ const unsigned int mask = ~(llen - 1);
++ const unsigned int il = (xl == 0) ? 0 : (xl - 1) & mask;
++ const unsigned int ir = x_end || !cache_boundry(s->frame, br) ? br : (xr - 1) & mask;
++ const unsigned int it = ussub(yt, 1);
++ const unsigned int ib = y_end ? bb : yb - 1;
++
++ if (il < ir) {
++ rpi_cache_buf_t cbuf;
++ rpi_cache_flush_env_t * const rfe = rpi_cache_flush_init(&cbuf);
++ rpi_cache_flush_add_frame_block(rfe, s->frame, RPI_CACHE_FLUSH_MODE_WB_INVALIDATE,
++ il, it, ir - il, ib - it,
++ ctx_vshift(s, 1), 1, 1);
++
++ // If we have to commit the right hand tile boundry due to
++ // cache boundry considerations then at EoTile we must commit
++ // that boundry to bottom of tile (bounds)
++ if (ib != bb && ir == br && eot) {
++ rpi_cache_flush_add_frame_block(rfe, s->frame, RPI_CACHE_FLUSH_MODE_WB_INVALIDATE,
++ br - 1, ib, 1, bb - ib,
++ ctx_vshift(s, 1), 1, 1);
++ }
++
++ rpi_cache_flush_finish(rfe);
++
++ if (x_end)
++ y = y_end ? INT_MAX : ib;
++
++// printf("Flush: %4d,%4d -> %4d,%4d: signal: %d\n", il, it, ir, ib, y - 1);
++ }
++ }
++ }
++
++ return y;
++}
++
+diff --git a/libavcodec/rpi_hevc_mv.h b/libavcodec/rpi_hevc_mv.h
+new file mode 100644
+index 0000000000..6b36f5e737
+--- /dev/null
++++ b/libavcodec/rpi_hevc_mv.h
+@@ -0,0 +1,71 @@
++#ifndef AVCODEC_RPI_HEVC_MV_H
++#define AVCODEC_RPI_HEVC_MV_H
++
++#include "config.h"
++
++typedef int32_t MvXY;
++
++typedef struct HEVCRpiMvField {
++ MvXY xy[2];
++ int8_t ref_idx[2];
++ int8_t pred_flag;
++ int8_t dummy; // To 12 bytes
++} HEVCRpiMvField;
++
++
++#define MV_X(xy) (((xy) << 16) >> 16)
++#define MV_Y(xy) ((xy) >> 16)
++#define MV_XY(x, y) ((x & 0xffff) | ((y) << 16))
++
++#if ARCH_ARM
++#include "arm/rpi_hevc_mv_arm.h"
++#endif
++
++#ifndef mvxy_add
++static inline MvXY mvxy_add(const MvXY a, const MvXY b)
++{
++ return MV_XY(MV_X(a) + MV_X(b), MV_Y(a) + MV_Y(b));
++}
++#endif
++
++
++#ifndef mv_scale_xy
++static inline MvXY mv_scale_xy(const MvXY const src, int td, int tb)
++{
++ int tx, scale_factor;
++
++ td = td == 0 ? 1 : av_clip_int8(td);
++ tb = av_clip_int8(tb);
++ tx = (0x4000 + (abs(td) >> 1)) / td;
++ scale_factor = av_clip_intp2((tb * tx + 32) >> 6, 12);
++ return MV_XY(
++ av_clip_int16((scale_factor * MV_X(src) + 127 +
++ (scale_factor * MV_X(src) < 0)) >> 8),
++ av_clip_int16((scale_factor * MV_Y(src) + 127 +
++ (scale_factor * MV_Y(src) < 0)) >> 8));
++}
++#endif
++
++// 8.3.1 states that the bitstream may not contain poc diffs that do not
++// fit in 16 bits, so given that we don't care about the high bits we only
++// store the low 16 + LT & Inter flags
++
++#define COL_POC_INTRA 0
++#define COL_POC_INTER (1 << 16)
++#define COL_POC_LT (1 << 17)
++#define COL_POC_DIFF(x,y) ((int16_t)((x) - (y)))
++#define COL_POC_MAKE_INTER(lt,poc) (COL_POC_INTER | ((lt) ? COL_POC_LT : 0) | ((poc) & 0xffff))
++#define COL_POC_IS_LT(x) (((x) & COL_POC_LT) != 0)
++
++typedef struct ColMv_s {
++ int32_t poc;
++ int32_t xy;
++} ColMv;
++
++typedef struct ColMvField_s {
++ ColMv L[2];
++} ColMvField;
++
++
++
++#endif // AVCODEC_RPI_HEVC_MV_H
+diff --git a/libavcodec/rpi_hevc_mvs.c b/libavcodec/rpi_hevc_mvs.c
+new file mode 100644
+index 0000000000..221755fb6e
+--- /dev/null
++++ b/libavcodec/rpi_hevc_mvs.c
+@@ -0,0 +1,486 @@
++/*
++ * HEVC video decoder
++ *
++ * Copyright (C) 2012 - 2013 Guillaume Martres
++ * Copyright (C) 2013 Anand Meher Kotra
++ *
++ * This file is part of FFmpeg.
++ *
++ * FFmpeg is free software; you can redistribute it and/or
++ * modify it under the terms of the GNU Lesser General Public
++ * License as published by the Free Software Foundation; either
++ * version 2.1 of the License, or (at your option) any later version.
++ *
++ * FFmpeg is distributed in the hope that it will be useful,
++ * but WITHOUT ANY WARRANTY; without even the implied warranty of
++ * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
++ * Lesser General Public License for more details.
++ *
++ * You should have received a copy of the GNU Lesser General Public
++ * License along with FFmpeg; if not, write to the Free Software
++ * Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA
++ */
++
++#include "hevc.h"
++#include "rpi_hevcdec.h"
++
++static av_always_inline int
++is_eq_mer(const unsigned int plevel,
++ const unsigned int xN, const unsigned int yN,
++ const unsigned int xP, const unsigned int yP)
++{
++ return (((xN ^ xP) | (yN ^ yP)) >> plevel) == 0;
++}
++
++// check if the mv's and refidx are the same between A and B
++static av_always_inline int compare_mv_ref_idx(const HEVCRpiMvField * const a, const HEVCRpiMvField * const b)
++{
++ return a->pred_flag == b->pred_flag &&
++ ((a->pred_flag & PF_L0) == 0 || (a->ref_idx[0] == b->ref_idx[0] && a->xy[0] == b->xy[0])) &&
++ ((a->pred_flag & PF_L1) == 0 || (a->ref_idx[1] == b->ref_idx[1] && a->xy[1] == b->xy[1]));
++ return 0;
++}
++
++/*
++ * 8.5.3.1.7 temporal luma motion vector prediction
++ */
++static int temporal_luma_motion_vector(const HEVCRpiContext * const s,
++ const HEVCRpiLocalContext * const lc, const int x0, const int y0,
++ const int nPbW, const int nPbH, const int refIdxLx,
++ MvXY * const mvLXCol, const int X)
++{
++ int x, y;
++ const ColMv * cmv = NULL;
++
++ HEVCRpiFrame * const col_ref = s->ref->collocated_ref;
++ const RefPicList * const refPicList = s->refPicList + X;
++ const int cur_lt = refPicList->isLongTerm[refIdxLx];
++
++ *mvLXCol = 0;
++ // Unlikely but we might have a col_ref IDR frame!
++ if (col_ref->col_mvf == NULL)
++ return 0;
++
++ ff_hevc_rpi_progress_wait_mv(s, lc->jb0, col_ref, y0 + nPbH);
++
++ //bottom right collocated motion vector
++ x = x0 + nPbW;
++ y = y0 + nPbH;
++
++ if ((y0 >> s->ps.sps->log2_ctb_size) == (y >> s->ps.sps->log2_ctb_size) &&
++ y < s->ps.sps->height &&
++ x < s->ps.sps->width)
++ {
++ const ColMvField * const col = col_ref->col_mvf + (x >> 4) +
++ (y >> 4) * s->col_mvf_stride;
++
++ if (col->L[0].poc != COL_POC_INTRA &&
++ (col->L[1].poc == COL_POC_INTRA ||
++ (s->no_backward_pred_flag ? s->sh.collocated_list == L1 : X == 0)))
++ {
++ cmv = col->L + 0;
++ }
++ else if (col->L[1].poc != COL_POC_INTRA)
++ {
++ cmv = col->L + 1;
++ }
++ }
++
++ // derive center collocated motion vector
++ if (cmv == NULL || COL_POC_IS_LT(cmv->poc) != cur_lt)
++ {
++ cmv = NULL;
++ x = x0 + (nPbW >> 1);
++ y = y0 + (nPbH >> 1);
++
++ {
++ const ColMvField * const col = col_ref->col_mvf + (x >> 4) +
++ (y >> 4) * s->col_mvf_stride;
++
++ if (col->L[0].poc != COL_POC_INTRA &&
++ (col->L[1].poc == COL_POC_INTRA ||
++ (s->no_backward_pred_flag ? s->sh.collocated_list == L1 : X == 0)))
++ {
++ cmv = col->L + 0;
++ }
++ else if (col->L[1].poc != COL_POC_INTRA)
++ {
++ cmv = col->L + 1;
++ }
++ }
++ }
++
++ if (cmv == NULL || cur_lt != COL_POC_IS_LT(cmv->poc))
++ return 0;
++
++ {
++ const int col_poc = col_ref->poc;
++ const int ref_poc = refPicList->list[refIdxLx];
++
++ *mvLXCol = (cur_lt ||
++ cmv->poc == col_poc ||
++ COL_POC_DIFF(col_poc, cmv->poc) == s->poc - ref_poc) ?
++ cmv->xy :
++ mv_scale_xy(cmv->xy, COL_POC_DIFF(col_poc, cmv->poc), s->poc - ref_poc);
++ }
++
++ return cmv != NULL;
++}
++
++static inline int mvf_eq(const HEVCRpiMvField * const a, const HEVCRpiMvField * const b)
++{
++ return b != NULL && compare_mv_ref_idx(a, b);
++}
++
++
++
++/*
++ * 8.5.3.1.2 Derivation process for spatial merging candidates
++ */
++static inline const HEVCRpiMvField *
++derive_spatial_merge_candidates(
++ const HEVCRpiContext * const s,
++ const HEVCRpiLocalContext * const lc,
++ const unsigned int x0, const unsigned int y0,
++ const unsigned int nPbW, const unsigned int nPbH,
++ const unsigned int avail,
++ const unsigned int part_idx,
++ const unsigned int merge_idx,
++ HEVCRpiMvField * const mvf_t)
++{
++ const unsigned int parts_a1 = (1 << PART_Nx2N) | (1 << PART_nLx2N) | (1 << PART_nRx2N);
++ const unsigned int parts_b1 = (1 << PART_2NxN) | (1<< PART_2NxnU) | (1 << PART_2NxnD);
++
++ const HEVCRpiMvField * mvf_a1 = mvf_ptr(s, lc, x0, y0, x0 - 1, y0 + nPbH - 1);
++ const HEVCRpiMvField * mvf_a0 = mvf_a1 + mvf_left_stride(s, x0, x0 - 1);
++ const HEVCRpiMvField * mvf_b1 = mvf_ptr(s, lc, x0, y0, x0 + nPbW - 1, y0 - 1);
++ const HEVCRpiMvField * mvf_b0 = mvf_b1 + 1;
++ const unsigned int plevel = s->ps.pps->log2_parallel_merge_level;
++ const unsigned int part_mode = lc->cu.part_mode;
++
++ const HEVCRpiMvField * perm[4];
++ unsigned int nb_merge_cand = 0;
++
++ // singleMCLFlag => part_idx == 0 so no need to test for it
++ if ((avail & AVAIL_L) == 0 ||
++ (part_idx == 1 &&
++ ((parts_a1 >> part_mode) & 1) != 0 ||
++ is_eq_mer(plevel, x0 - 1, y0 + nPbH - 1, x0, y0)) ||
++ mvf_a1->pred_flag == PF_INTRA)
++ {
++ mvf_a1 = NULL;
++ }
++ else
++ {
++ if (merge_idx == nb_merge_cand)
++ return mvf_a1;
++ perm[nb_merge_cand++] = mvf_a1;
++ }
++
++ if ((avail & AVAIL_U) == 0 ||
++ (part_idx == 1 &&
++ ((parts_b1 >> part_mode) & 1) != 0 ||
++ is_eq_mer(plevel, x0 + nPbW - 1, y0 - 1, x0, y0)) ||
++ mvf_b1->pred_flag == PF_INTRA)
++ {
++ mvf_b1 = NULL;
++ }
++ else if (!mvf_eq(mvf_b1, mvf_a1))
++ {
++ if (merge_idx == nb_merge_cand)
++ return mvf_b1;
++ perm[nb_merge_cand++] = mvf_b1;
++ }
++
++ // above right spatial merge candidate
++ // Never need mvf_b0 again so don't bother zeroing if navail
++ if ((avail & AVAIL_UR) != 0 &&
++ !is_eq_mer(plevel, x0 + nPbW, y0 - 1, x0, y0) &&
++ mvf_b0->pred_flag != PF_INTRA &&
++ !mvf_eq(mvf_b0, mvf_b1))
++ {
++ if (merge_idx == nb_merge_cand)
++ return mvf_b0;
++ perm[nb_merge_cand++] = mvf_b0;
++ }
++
++ // left bottom spatial merge candidate
++ // Never need mvf_a0 again so don't bother zeroing if navail
++ if ((avail & AVAIL_DL) != 0 &&
++ !is_eq_mer(plevel, x0 - 1, y0 + nPbH, x0, y0) &&
++ mvf_a0->pred_flag != PF_INTRA &&
++ !mvf_eq(mvf_a0, mvf_a1))
++ {
++ if (merge_idx == nb_merge_cand)
++ return mvf_a0;
++ perm[nb_merge_cand++] = mvf_a0;
++ }
++
++ // above left spatial merge candidate
++ if (nb_merge_cand != 4 &&
++ (avail & AVAIL_UL) != 0 &&
++ !is_eq_mer(plevel, x0 - 1, y0 - 1, x0, y0))
++ {
++ const HEVCRpiMvField * mvf_b2 = mvf_ptr(s, lc, x0, y0, x0 - 1, y0 - 1); // UL
++
++ if (mvf_b2->pred_flag != PF_INTRA &&
++ !mvf_eq(mvf_b2, mvf_a1) &&
++ !mvf_eq(mvf_b2, mvf_b1))
++ {
++ if (merge_idx == nb_merge_cand)
++ return mvf_b2;
++ perm[nb_merge_cand++] = mvf_b2;
++ }
++ }
++
++ // temporal motion vector candidate
++ if (s->sh.slice_temporal_mvp_enabled_flag)
++ {
++ static const HEVCRpiMvField mvf_z = {{0}};
++
++ *mvf_t = mvf_z;
++
++ if (temporal_luma_motion_vector(s, lc, x0, y0, nPbW, nPbH,
++ 0, mvf_t->xy + 0, 0))
++ mvf_t->pred_flag = PF_L0;
++
++ if (s->sh.slice_type == HEVC_SLICE_B &&
++ temporal_luma_motion_vector(s, lc, x0, y0, nPbW, nPbH,
++ 0, mvf_t->xy + 1, 1))
++ mvf_t->pred_flag |= PF_L1;
++
++ if (mvf_t->pred_flag != 0)
++ {
++ if (merge_idx == nb_merge_cand)
++ return mvf_t;
++ perm[nb_merge_cand++] = mvf_t;
++ }
++ }
++
++ // combined bi-predictive merge candidates (applies for B slices)
++ if (s->sh.slice_type == HEVC_SLICE_B && nb_merge_cand > 1)
++ {
++ unsigned int comb_idx = 0;
++ const unsigned int cand_count = nb_merge_cand * (nb_merge_cand - 1);
++ const RefPicList * const refPicList = s->refPicList;
++
++ for (comb_idx = 0; comb_idx < cand_count; comb_idx++)
++ {
++ static const uint8_t l0_l1_cand_idx[12][2] = {
++ { 0, 1, },
++ { 1, 0, },
++ { 0, 2, },
++ { 2, 0, },
++ { 1, 2, },
++ { 2, 1, },
++ { 0, 3, },
++ { 3, 0, },
++ { 1, 3, },
++ { 3, 1, },
++ { 2, 3, },
++ { 3, 2, },
++ };
++
++ const unsigned int l0_cand_idx = l0_l1_cand_idx[comb_idx][0];
++ const unsigned int l1_cand_idx = l0_l1_cand_idx[comb_idx][1];
++ const HEVCRpiMvField * const mvf_c0 = perm[l0_cand_idx];
++ const HEVCRpiMvField * const mvf_c1 = perm[l1_cand_idx];
++
++ if ((mvf_c0->pred_flag & PF_L0) != 0 &&
++ (mvf_c1->pred_flag & PF_L1) != 0 &&
++ (refPicList[0].list[mvf_c0->ref_idx[0]] != refPicList[1].list[mvf_c1->ref_idx[1]] ||
++ mvf_c0->xy[0] != mvf_c1->xy[1]))
++ {
++ if (merge_idx == nb_merge_cand++)
++ {
++ // Need to be a bit careful as we will construct mvf_t and we
++ // may already be using that as one of our condidates
++ // so build & copy rather than build in place
++ const HEVCRpiMvField mvf_m = {
++ .xy = {
++ mvf_c0->xy[0],
++ mvf_c1->xy[1]},
++ .ref_idx = {
++ mvf_c0->ref_idx[0],
++ mvf_c1->ref_idx[1]},
++ .pred_flag = PF_BI
++ };
++ *mvf_t = mvf_m;
++ return mvf_t;
++ }
++ }
++ }
++ }
++
++ // "append" Zero motion vector candidates
++ {
++ const unsigned int nb_refs = (s->sh.slice_type == HEVC_SLICE_B) ?
++ FFMIN(s->sh.nb_refs[0], s->sh.nb_refs[1]) : s->sh.nb_refs[0];
++ const unsigned int zero_idx = merge_idx - nb_merge_cand;
++
++ const HEVCRpiMvField mvf_m = {
++ .xy = {0, 0},
++ .ref_idx = {
++ zero_idx < nb_refs ? zero_idx : 0,
++ (s->sh.slice_type == HEVC_SLICE_B && zero_idx < nb_refs) ? zero_idx : 0},
++ .pred_flag = (s->sh.slice_type == HEVC_SLICE_B) ? PF_BI : PF_L0
++ };
++
++ *mvf_t = mvf_m;
++ return mvf_t;
++ }
++}
++
++
++// 8.5.3.1.1 Derivation process of luma Mvs for merge mode
++void ff_hevc_rpi_luma_mv_merge_mode(const HEVCRpiContext * const s, HEVCRpiLocalContext * const lc, int x0, int y0, int nPbW,
++ int nPbH, int log2_cb_size, int part_idx,
++ int merge_idx, HEVCRpiMvField * const mv)
++{
++ const HEVCRpiMvField * mvf_m = (s->ps.pps->log2_parallel_merge_level > 2 && log2_cb_size == 3) ?
++ derive_spatial_merge_candidates(s, lc, lc->cu.x, lc->cu.y, 8, 8,
++ ff_hevc_rpi_tb_avail_flags(s, lc, lc->cu.x, lc->cu.y, 8, 8),
++ 0, merge_idx, mv) :
++ derive_spatial_merge_candidates(s, lc, x0, y0, nPbW, nPbH,
++ ff_hevc_rpi_tb_avail_flags(s, lc, x0, y0, nPbW, nPbH),
++ part_idx, merge_idx, mv);
++
++ if (mvf_m != mv)
++ *mv = *mvf_m;
++
++ if (mv->pred_flag == PF_BI && (nPbW + nPbH) == 12)
++ mv->pred_flag = PF_L0;
++}
++
++
++static av_always_inline const MvXY *
++mvf_same_poc(const RefPicList * const rpl, const unsigned int pfi0, const unsigned int pfi1, const int poc0, const HEVCRpiMvField * const mvf)
++{
++ if (mvf != NULL)
++ {
++ if (((mvf->pred_flag >> pfi0) & 1) != 0 && rpl[pfi0].list[mvf->ref_idx[pfi0]] == poc0)
++ return mvf->xy + pfi0;
++ if (((mvf->pred_flag >> pfi1) & 1) != 0 && rpl[pfi1].list[mvf->ref_idx[pfi1]] == poc0)
++ return mvf->xy + pfi1;
++ }
++ return NULL;
++}
++
++static av_always_inline const MvXY *
++mvf_other_poc(const RefPicList * const rpl, const unsigned int pfi0, const unsigned int pfi1,
++ const int islt0, const int poc0, const int poc_cur,
++ MvXY * const mv_t, const HEVCRpiMvField * const mvf)
++{
++ if (mvf != NULL)
++ {
++ if (((mvf->pred_flag >> pfi0) & 1) != 0 && rpl[pfi0].isLongTerm[mvf->ref_idx[pfi0]] == islt0)
++ {
++ const int poc1 = rpl[pfi0].list[mvf->ref_idx[pfi0]];
++ if (islt0 || poc1 == poc0) {
++ return mvf->xy + pfi0;
++ }
++ *mv_t = mv_scale_xy(mvf->xy[pfi0], poc_cur - poc1, poc_cur - poc0);
++ return mv_t;
++ }
++ if (((mvf->pred_flag >> pfi1) & 1) != 0 && rpl[pfi1].isLongTerm[mvf->ref_idx[pfi1]] == islt0)
++ {
++ const int poc1 = rpl[pfi1].list[mvf->ref_idx[pfi1]];
++ if (islt0 || poc1 == poc0) {
++ return mvf->xy + pfi1;
++ }
++ *mv_t = mv_scale_xy(mvf->xy[pfi1], poc_cur - poc1, poc_cur - poc0);
++ return mv_t;
++ }
++ }
++ return NULL;
++}
++
++void ff_hevc_rpi_luma_mv_mvp_mode(const HEVCRpiContext * const s, HEVCRpiLocalContext * const lc,
++ const unsigned int x0, const unsigned int y0,
++ const unsigned int nPbW, const unsigned int nPbH,
++ const unsigned int avail,
++ HEVCRpiMvField * const mv,
++ const unsigned int mvp_lx_flag, const unsigned int LX)
++{
++ const unsigned int pfi0 = LX;
++ const unsigned int pfi1 = LX == 0 ? 1 : 0;
++ const RefPicList * const rpl = s->refPicList;
++ const int poc0 = rpl[LX].list[mv->ref_idx[LX]];
++ const int poc_cur = s->poc;
++ const int islt0 = rpl[LX].isLongTerm[mv->ref_idx[LX]];
++
++ const HEVCRpiMvField * mvf_a1 = mvf_ptr(s, lc, x0, y0, x0 - 1, y0 + nPbH - 1);
++ const HEVCRpiMvField * mvf_a0 = mvf_a1 + mvf_left_stride(s, x0, x0 - 1);
++ const HEVCRpiMvField * mvf_b2 = mvf_ptr(s, lc, x0, y0, x0 - 1, y0 - 1); // UL
++ const HEVCRpiMvField * mvf_b1 = mvf_ptr(s, lc, x0, y0, x0 + nPbW - 1, y0 - 1);
++ const HEVCRpiMvField * mvf_b0 = mvf_b1 + 1;
++ const MvXY * mva = NULL;
++ const MvXY * mvb;
++ MvXY * const mv_rv = mv->xy + LX;
++ MvXY mvt_a, mvt_b;
++
++ *mv_rv = 0;
++
++ if ((avail & AVAIL_DL) == 0 || mvf_a0->pred_flag == PF_INTRA)
++ mvf_a0 = NULL;
++ else if ((mva = mvf_same_poc(rpl, pfi0, pfi1, poc0, mvf_a0)) != NULL && mvp_lx_flag == 0)
++ goto use_mva;
++
++ if ((avail & AVAIL_L) == 0 || mvf_a1->pred_flag == PF_INTRA)
++ mvf_a1 = NULL;
++
++ if (mva == NULL &&
++ (mva = mvf_same_poc(rpl, pfi0, pfi1, poc0, mvf_a1)) == NULL &&
++ (mva = mvf_other_poc(rpl, pfi0, pfi1, islt0, poc0, poc_cur, &mvt_a, mvf_a0)) == NULL)
++ mva = mvf_other_poc(rpl, pfi0, pfi1, islt0, poc0, poc_cur, &mvt_a, mvf_a1);
++
++ if (mvp_lx_flag == 0 && mva != NULL)
++ goto use_mva;
++
++ if ((avail & AVAIL_UR) == 0 || mvf_b0->pred_flag == PF_INTRA)
++ mvf_b0 = NULL;
++ if ((avail & AVAIL_U) == 0 || mvf_b1->pred_flag == PF_INTRA)
++ mvf_b1 = NULL;
++ if ((avail & AVAIL_UL) == 0 || mvf_b2->pred_flag == PF_INTRA)
++ mvf_b2 = NULL;
++
++ if ((mvb = mvf_same_poc(rpl, pfi0, pfi1, poc0, mvf_b0)) == NULL &&
++ (mvb = mvf_same_poc(rpl, pfi0, pfi1, poc0, mvf_b1)) == NULL)
++ mvb = mvf_same_poc(rpl, pfi0, pfi1, poc0, mvf_b2);
++
++ if (mvf_a0 == NULL && mvf_a1 == NULL) {
++ mva = mvb;
++ if (mvp_lx_flag == 0 && mva != NULL)
++ goto use_mva;
++
++ if ((mvb = mvf_other_poc(rpl, pfi0, pfi1, islt0, poc0, poc_cur, &mvt_b, mvf_b0)) == NULL &&
++ (mvb = mvf_other_poc(rpl, pfi0, pfi1, islt0, poc0, poc_cur, &mvt_b, mvf_b1)) == NULL)
++ mvb = mvf_other_poc(rpl, pfi0, pfi1, islt0, poc0, poc_cur, &mvt_b, mvf_b2);
++ }
++
++ if (mva == NULL) {
++ mva = mvb;
++ mvb = NULL;
++ }
++
++ if (mvb != NULL && *mva == *mvb) // If A == B then ignore B
++ mvb = NULL;
++
++ if (mvp_lx_flag == 0 && mva != NULL) {
++ goto use_mva;
++ }
++ else if (mvp_lx_flag != 0 && mvb != NULL) {
++ *mv_rv = *mvb;
++ }
++ else if (s->sh.slice_temporal_mvp_enabled_flag && ((mvp_lx_flag == 0 && mva == NULL) || (mvp_lx_flag != 0 && mva != NULL))) {
++ temporal_luma_motion_vector(s, lc, x0, y0, nPbW,
++ nPbH, mv->ref_idx[LX],
++ mv_rv, LX);
++ }
++ return;
++
++use_mva:
++ *mv_rv = *mva;
++ return;
++}
++
+diff --git a/libavcodec/rpi_hevc_parse.c b/libavcodec/rpi_hevc_parse.c
+new file mode 100644
+index 0000000000..04f9231acc
+--- /dev/null
++++ b/libavcodec/rpi_hevc_parse.c
+@@ -0,0 +1,142 @@
++/*
++ * This file is part of FFmpeg.
++ *
++ * FFmpeg is free software; you can redistribute it and/or
++ * modify it under the terms of the GNU Lesser General Public
++ * License as published by the Free Software Foundation; either
++ * version 2.1 of the License, or (at your option) any later version.
++ *
++ * FFmpeg is distributed in the hope that it will be useful,
++ * but WITHOUT ANY WARRANTY; without even the implied warranty of
++ * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
++ * Lesser General Public License for more details.
++ *
++ * You should have received a copy of the GNU Lesser General Public
++ * License along with FFmpeg; if not, write to the Free Software
++ * Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA
++ */
++
++#include "bytestream.h"
++#include "h2645_parse.h"
++#include "hevc.h"
++#include "rpi_hevc_parse.h"
++
++static int hevc_decode_nal_units(const uint8_t *buf, int buf_size, HEVCRpiParamSets *ps,
++ HEVCSEIContext *sei, int is_nalff, int nal_length_size,
++ int err_recognition, int apply_defdispwin, void *logctx)
++{
++ int i;
++ int ret = 0;
++ H2645Packet pkt = { 0 };
++
++ ret = ff_h2645_packet_split(&pkt, buf, buf_size, logctx, is_nalff, nal_length_size, AV_CODEC_ID_HEVC, 1);
++ if (ret < 0) {
++ goto done;
++ }
++
++ for (i = 0; i < pkt.nb_nals; i++) {
++ H2645NAL *nal = &pkt.nals[i];
++
++ /* ignore everything except parameter sets and VCL NALUs */
++ switch (nal->type) {
++ case HEVC_NAL_VPS:
++ ret = ff_hevc_rpi_decode_nal_vps(&nal->gb, logctx, ps);
++ if (ret < 0)
++ goto done;
++ break;
++ case HEVC_NAL_SPS:
++ ret = ff_hevc_rpi_decode_nal_sps(&nal->gb, logctx, ps, apply_defdispwin);
++ if (ret < 0)
++ goto done;
++ break;
++ case HEVC_NAL_PPS:
++ ret = ff_hevc_rpi_decode_nal_pps(&nal->gb, logctx, ps);
++ if (ret < 0)
++ goto done;
++ break;
++ case HEVC_NAL_SEI_PREFIX:
++ case HEVC_NAL_SEI_SUFFIX:
++ ret = ff_hevc_rpi_decode_nal_sei(&nal->gb, logctx, sei, ps, nal->type);
++ if (ret < 0)
++ goto done;
++ break;
++ default:
++ av_log(logctx, AV_LOG_VERBOSE, "Ignoring NAL type %d in extradata\n", nal->type);
++ break;
++ }
++ }
++
++done:
++ ff_h2645_packet_uninit(&pkt);
++ if (err_recognition & AV_EF_EXPLODE)
++ return ret;
++
++ return 0;
++}
++
++int ff_hevc_rpi_decode_extradata(const uint8_t *data, int size, HEVCRpiParamSets *ps,
++ HEVCSEIContext *sei, int *is_nalff, int *nal_length_size,
++ int err_recognition, int apply_defdispwin, void *logctx)
++{
++ int ret = 0;
++ GetByteContext gb;
++
++ bytestream2_init(&gb, data, size);
++
++ if (size > 3 && (data[0] || data[1] || data[2] > 1)) {
++ /* It seems the extradata is encoded as hvcC format.
++ * Temporarily, we support configurationVersion==0 until 14496-15 3rd
++ * is finalized. When finalized, configurationVersion will be 1 and we
++ * can recognize hvcC by checking if avctx->extradata[0]==1 or not. */
++ int i, j, num_arrays, nal_len_size;
++
++ *is_nalff = 1;
++
++ bytestream2_skip(&gb, 21);
++ nal_len_size = (bytestream2_get_byte(&gb) & 3) + 1;
++ num_arrays = bytestream2_get_byte(&gb);
++
++ /* nal units in the hvcC always have length coded with 2 bytes,
++ * so put a fake nal_length_size = 2 while parsing them */
++ *nal_length_size = 2;
++
++ /* Decode nal units from hvcC. */
++ for (i = 0; i < num_arrays; i++) {
++ int type = bytestream2_get_byte(&gb) & 0x3f;
++ int cnt = bytestream2_get_be16(&gb);
++
++ for (j = 0; j < cnt; j++) {
++ // +2 for the nal size field
++ int nalsize = bytestream2_peek_be16(&gb) + 2;
++ if (bytestream2_get_bytes_left(&gb) < nalsize) {
++ av_log(logctx, AV_LOG_ERROR,
++ "Invalid NAL unit size in extradata.\n");
++ return AVERROR_INVALIDDATA;
++ }
++
++ ret = hevc_decode_nal_units(gb.buffer, nalsize, ps, sei, *is_nalff,
++ *nal_length_size, err_recognition, apply_defdispwin,
++ logctx);
++ if (ret < 0) {
++ av_log(logctx, AV_LOG_ERROR,
++ "Decoding nal unit %d %d from hvcC failed\n",
++ type, i);
++ return ret;
++ }
++ bytestream2_skip(&gb, nalsize);
++ }
++ }
++
++ /* Now store right nal length size, that will be used to parse
++ * all other nals */
++ *nal_length_size = nal_len_size;
++ } else {
++ *is_nalff = 0;
++ ret = hevc_decode_nal_units(data, size, ps, sei, *is_nalff, *nal_length_size,
++ err_recognition, apply_defdispwin, logctx);
++ if (ret < 0)
++ return ret;
++ }
++
++ return ret;
++}
+diff --git a/libavcodec/rpi_hevc_parse.h b/libavcodec/rpi_hevc_parse.h
+new file mode 100644
+index 0000000000..4b4d032a16
+--- /dev/null
++++ b/libavcodec/rpi_hevc_parse.h
+@@ -0,0 +1,36 @@
++/*
++ * This file is part of FFmpeg.
++ *
++ * FFmpeg is free software; you can redistribute it and/or
++ * modify it under the terms of the GNU Lesser General Public
++ * License as published by the Free Software Foundation; either
++ * version 2.1 of the License, or (at your option) any later version.
++ *
++ * FFmpeg is distributed in the hope that it will be useful,
++ * but WITHOUT ANY WARRANTY; without even the implied warranty of
++ * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
++ * Lesser General Public License for more details.
++ *
++ * You should have received a copy of the GNU Lesser General Public
++ * License along with FFmpeg; if not, write to the Free Software
++ * Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA
++ */
++
++/**
++ * @file
++ * H.265 parser code
++ */
++
++#ifndef AVCODEC_RPI_HEVC_PARSE_H
++#define AVCODEC_RPI_HEVC_PARSE_H
++
++#include <stdint.h>
++
++#include "rpi_hevc_ps.h"
++#include "rpi_hevc_sei.h"
++
++int ff_hevc_rpi_decode_extradata(const uint8_t *data, int size, HEVCRpiParamSets *ps,
++ HEVCSEIContext *sei, int *is_nalff, int *nal_length_size,
++ int err_recognition, int apply_defdispwin, void *logctx);
++
++#endif /* AVCODEC_RPI_HEVC_PARSE_H */
+diff --git a/libavcodec/rpi_hevc_ps.c b/libavcodec/rpi_hevc_ps.c
+new file mode 100644
+index 0000000000..891e3a900c
+--- /dev/null
++++ b/libavcodec/rpi_hevc_ps.c
+@@ -0,0 +1,1936 @@
++/*
++ * HEVC Parameter Set decoding
++ *
++ * Copyright (C) 2012 - 2103 Guillaume Martres
++ * Copyright (C) 2012 - 2103 Mickael Raulet
++ * Copyright (C) 2012 - 2013 Gildas Cocherel
++ * Copyright (C) 2013 Vittorio Giovara
++ *
++ * This file is part of FFmpeg.
++ *
++ * FFmpeg is free software; you can redistribute it and/or
++ * modify it under the terms of the GNU Lesser General Public
++ * License as published by the Free Software Foundation; either
++ * version 2.1 of the License, or (at your option) any later version.
++ *
++ * FFmpeg is distributed in the hope that it will be useful,
++ * but WITHOUT ANY WARRANTY; without even the implied warranty of
++ * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
++ * Lesser General Public License for more details.
++ *
++ * You should have received a copy of the GNU Lesser General Public
++ * License along with FFmpeg; if not, write to the Free Software
++ * Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA
++ */
++
++#include "libavutil/imgutils.h"
++#include "golomb.h"
++#include "rpi_hevc_data.h"
++#include "rpi_hevc_ps.h"
++#include "rpi_hevcdec.h"
++
++static const uint8_t default_scaling_list_intra[] = {
++ 16, 16, 16, 16, 17, 18, 21, 24,
++ 16, 16, 16, 16, 17, 19, 22, 25,
++ 16, 16, 17, 18, 20, 22, 25, 29,
++ 16, 16, 18, 21, 24, 27, 31, 36,
++ 17, 17, 20, 24, 30, 35, 41, 47,
++ 18, 19, 22, 27, 35, 44, 54, 65,
++ 21, 22, 25, 31, 41, 54, 70, 88,
++ 24, 25, 29, 36, 47, 65, 88, 115
++};
++
++static const uint8_t default_scaling_list_inter[] = {
++ 16, 16, 16, 16, 17, 18, 20, 24,
++ 16, 16, 16, 17, 18, 20, 24, 25,
++ 16, 16, 17, 18, 20, 24, 25, 28,
++ 16, 17, 18, 20, 24, 25, 28, 33,
++ 17, 18, 20, 24, 25, 28, 33, 41,
++ 18, 20, 24, 25, 28, 33, 41, 54,
++ 20, 24, 25, 28, 33, 41, 54, 71,
++ 24, 25, 28, 33, 41, 54, 71, 91
++};
++
++static const AVRational vui_sar[] = {
++ { 0, 1 },
++ { 1, 1 },
++ { 12, 11 },
++ { 10, 11 },
++ { 16, 11 },
++ { 40, 33 },
++ { 24, 11 },
++ { 20, 11 },
++ { 32, 11 },
++ { 80, 33 },
++ { 18, 11 },
++ { 15, 11 },
++ { 64, 33 },
++ { 160, 99 },
++ { 4, 3 },
++ { 3, 2 },
++ { 2, 1 },
++};
++
++
++// pps_cb_qp_offset: -12,+12
++// slice_cb_qp_offset: -12,+12 also
++// "The value of pps_cb_qp_offset + slice_cb_qp_offset shall be in the range of -12 to +12, inclusive."
++// cr_qp_offset_list[n]: -12,+12
++// So worst case total offset: -24,+24
++
++#define T(n) ((((48+(n))/6-10)<<3) | (48+(n))%6)
++#define C(B,n) T(B*6+(n) < 0 ? -B*6 : (n) > 51 ? 51 : (n))
++#define M(B,n) C(B,(-n))
++
++// Sizeof the QP_START_BLOCK
++#define QP_OFFSET_0 (8*6 + 12*2)
++#define QP_START(B) \
++ M(B,48), M(B,48), M(B,48), M(B,48), M(B,48), M(B,48),\
++ M(B,48), M(B,48), M(B,48), M(B,48), M(B,48), M(B,48),\
++ M(B,48), M(B,48), M(B,48), M(B,48), M(B,48), M(B,48),\
++ M(B,48), M(B,48), M(B,48), M(B,48), M(B,48), M(B,48),\
++\
++ M(B,48), M(B,47), M(B,46), M(B,45), M(B,44), M(B,43),\
++ M(B,42), M(B,41), M(B,40), M(B,39), M(B,38), M(B,37),\
++ M(B,36), M(B,35), M(B,34), M(B,33), M(B,32), M(B,31),\
++ M(B,30), M(B,29), M(B,28), M(B,27), M(B,26), M(B,25),\
++ M(B,24), M(B,23), M(B,22), M(B,21), M(B,20), M(B,19),\
++ M(B,18), M(B,17), M(B,16), M(B,15), M(B,14), M(B,13),\
++ M(B,12), M(B,11), M(B,10), M(B, 9), M(B, 8), M(B, 7),\
++ M(B, 6), M(B, 5), M(B, 4), M(B, 3), M(B, 2), M(B, 1)
++#define QP_END(B) \
++ C(B,51), C(B,51), C(B,51), C(B,51), C(B,51), C(B,51),\
++ C(B,51), C(B,51), C(B,51), C(B,51), C(B,51), C(B,51),\
++ C(B,51), C(B,51), C(B,51), C(B,51), C(B,51), C(B,51)
++
++#define T1(B)\
++{\
++ QP_START(B),\
++ C(B, 0), C(B, 1), C(B, 2), C(B, 3), C(B, 4), C(B, 5), C(B, 6), C(B, 7), C(B, 8), C(B, 9),\
++ C(B,10), C(B,11), C(B,12), C(B,13), C(B,14), C(B,15), C(B,16), C(B,17), C(B,18), C(B,19),\
++ C(B,20), C(B,21), C(B,22), C(B,23), C(B,24), C(B,25), C(B,26), C(B,27), C(B,28), C(B,29),\
++ C(B,29), C(B,30), C(B,31), C(B,32), C(B,33), C(B,33), C(B,34), C(B,34), C(B,35), C(B,35),\
++ C(B,36), C(B,36), C(B,37), C(B,37), C(B,38), C(B,39), C(B,40), C(B,41), C(B,42), C(B,43),\
++ C(B,44), C(B,45),\
++ C(B,46), C(B,47), C(B,48), C(B,49), C(B,50), C(B,51),\
++ QP_END(B)\
++}
++#define T0(B)\
++{\
++ QP_START(B),\
++ C(B, 0), C(B, 1), C(B, 2), C(B, 3), C(B, 4), C(B, 5), C(B, 6), C(B, 7), C(B, 8), C(B, 9),\
++ C(B,10), C(B,11), C(B,12), C(B,13), C(B,14), C(B,15), C(B,16), C(B,17), C(B,18), C(B,19),\
++ C(B,20), C(B,21), C(B,22), C(B,23), C(B,24), C(B,25), C(B,26), C(B,27), C(B,28), C(B,29),\
++ C(B,30), C(B,31), C(B,32), C(B,33), C(B,34), C(B,35), C(B,36), C(B,37), C(B,38), C(B,39),\
++ C(B,40), C(B,41), C(B,42), C(B,43), C(B,44), C(B,45), C(B,46), C(B,47), C(B,48), C(B,49),\
++ C(B,50), C(B,51),\
++ C(B,51), C(B,51), C(B,51), C(B,51), C(B,51), C(B,51),\
++ QP_END(B)\
++}
++
++#define QP_TABLE_SIZE (QP_OFFSET_0 + 52 + 12*2)
++
++static const int8_t qp_c_bd_0[8][QP_TABLE_SIZE] = {T0(0),T0(1),T0(2),T0(3),T0(4),T0(5),T0(6),T0(7)};
++static const int8_t qp_c_bd_1[8][QP_TABLE_SIZE] = {T1(0),T1(1),T1(2),T1(3),T1(4),T1(5),T1(6),T1(7)};
++
++#undef T
++#undef C
++#undef QP_END
++
++#define C(B,n) ((n)<0?0:(n)>51?51:(n))
++// We do need a lot of -ve padding to cope with high bit depths that give -ve qps
++#define QP_DBLK_OFFSET_0 QP_OFFSET_0
++#define QP_END(B)\
++ 51, 51, 51, 51, 51, 51
++
++// These don't need all the padding we have here (12 top/bottom would be enough)
++static const uint8_t qp_c_dblk_0[] = T0(0);
++static const uint8_t qp_c_dblk_1[] = T1(0);
++
++#undef T
++#undef M
++#undef C
++#undef QP_END
++#undef QP_START
++
++
++static void remove_pps(HEVCRpiParamSets * const s, const int id)
++{
++ if (s->pps_list[id] && s->pps == (const HEVCRpiPPS*)s->pps_list[id]->data)
++ s->pps = NULL;
++ av_buffer_unref(&s->pps_list[id]);
++}
++
++static void remove_sps(HEVCRpiParamSets * const s, const int id)
++{
++ int i;
++ if (s->sps_list[id]) {
++ if (s->sps == (const HEVCRpiSPS*)s->sps_list[id]->data)
++ s->sps = NULL;
++
++ /* drop all PPS that depend on this SPS */
++ for (i = 0; i < FF_ARRAY_ELEMS(s->pps_list); i++)
++ if (s->pps_list[i] && ((HEVCRpiPPS*)s->pps_list[i]->data)->sps_id == id)
++ remove_pps(s, i);
++
++ av_assert0(!(s->sps_list[id] && s->sps == (HEVCRpiSPS*)s->sps_list[id]->data));
++ }
++ av_buffer_unref(&s->sps_list[id]);
++}
++
++static void remove_vps(HEVCRpiParamSets * const s, const int id)
++{
++ int i;
++ if (s->vps_list[id]) {
++ if (s->vps == (const HEVCRpiVPS*)s->vps_list[id]->data)
++ s->vps = NULL;
++
++ for (i = 0; i < FF_ARRAY_ELEMS(s->sps_list); i++)
++ if (s->sps_list[i] && ((HEVCRpiSPS*)s->sps_list[i]->data)->vps_id == id)
++ remove_sps(s, i);
++ }
++ av_buffer_unref(&s->vps_list[id]);
++}
++
++int ff_hevc_rpi_decode_short_term_rps(GetBitContext * const gb, AVCodecContext * const avctx,
++ ShortTermRPS * const rps, const HEVCRpiSPS * const sps, const int is_slice_header)
++{
++ uint8_t rps_predict = 0;
++ int delta_poc;
++ int k0 = 0;
++ int k1 = 0;
++ int k = 0;
++ int i;
++
++ if (rps != sps->st_rps && sps->nb_st_rps)
++ rps_predict = get_bits1(gb);
++
++ if (rps_predict) {
++ const ShortTermRPS *rps_ridx;
++ int delta_rps;
++ unsigned abs_delta_rps;
++ uint8_t use_delta_flag = 0;
++ uint8_t delta_rps_sign;
++
++ if (is_slice_header) {
++ unsigned int delta_idx = get_ue_golomb_long(gb) + 1;
++ if (delta_idx > sps->nb_st_rps) {
++ av_log(avctx, AV_LOG_ERROR,
++ "Invalid value of delta_idx in slice header RPS: %d > %d.\n",
++ delta_idx, sps->nb_st_rps);
++ return AVERROR_INVALIDDATA;
++ }
++ rps_ridx = &sps->st_rps[sps->nb_st_rps - delta_idx];
++ rps->rps_idx_num_delta_pocs = rps_ridx->num_delta_pocs;
++ } else
++ rps_ridx = &sps->st_rps[rps - sps->st_rps - 1];
++
++ delta_rps_sign = get_bits1(gb);
++ abs_delta_rps = get_ue_golomb_long(gb) + 1;
++ if (abs_delta_rps < 1 || abs_delta_rps > 32768) {
++ av_log(avctx, AV_LOG_ERROR,
++ "Invalid value of abs_delta_rps: %d\n",
++ abs_delta_rps);
++ return AVERROR_INVALIDDATA;
++ }
++ delta_rps = (1 - (delta_rps_sign << 1)) * abs_delta_rps;
++ for (i = 0; i <= rps_ridx->num_delta_pocs; i++) {
++ int used = rps->used[k] = get_bits1(gb);
++
++ if (!used)
++ use_delta_flag = get_bits1(gb);
++
++ if (used || use_delta_flag) {
++ if (i < rps_ridx->num_delta_pocs)
++ delta_poc = delta_rps + rps_ridx->delta_poc[i];
++ else
++ delta_poc = delta_rps;
++ rps->delta_poc[k] = delta_poc;
++ if (delta_poc < 0)
++ k0++;
++ else
++ k1++;
++ k++;
++ }
++ }
++
++ if (k >= FF_ARRAY_ELEMS(rps->used)) {
++ av_log(avctx, AV_LOG_ERROR,
++ "Invalid num_delta_pocs: %d\n", k);
++ return AVERROR_INVALIDDATA;
++ }
++
++ rps->num_delta_pocs = k;
++ rps->num_negative_pics = k0;
++ // sort in increasing order (smallest first)
++ if (rps->num_delta_pocs != 0) {
++ int used, tmp;
++ for (i = 1; i < rps->num_delta_pocs; i++) {
++ delta_poc = rps->delta_poc[i];
++ used = rps->used[i];
++ for (k = i - 1; k >= 0; k--) {
++ tmp = rps->delta_poc[k];
++ if (delta_poc < tmp) {
++ rps->delta_poc[k + 1] = tmp;
++ rps->used[k + 1] = rps->used[k];
++ rps->delta_poc[k] = delta_poc;
++ rps->used[k] = used;
++ }
++ }
++ }
++ }
++ if ((rps->num_negative_pics >> 1) != 0) {
++ int used;
++ k = rps->num_negative_pics - 1;
++ // flip the negative values to largest first
++ for (i = 0; i < rps->num_negative_pics >> 1; i++) {
++ delta_poc = rps->delta_poc[i];
++ used = rps->used[i];
++ rps->delta_poc[i] = rps->delta_poc[k];
++ rps->used[i] = rps->used[k];
++ rps->delta_poc[k] = delta_poc;
++ rps->used[k] = used;
++ k--;
++ }
++ }
++ } else {
++ unsigned int prev, nb_positive_pics;
++ rps->num_negative_pics = get_ue_golomb_long(gb);
++ nb_positive_pics = get_ue_golomb_long(gb);
++
++ if (rps->num_negative_pics >= HEVC_MAX_REFS ||
++ nb_positive_pics >= HEVC_MAX_REFS) {
++ av_log(avctx, AV_LOG_ERROR, "Too many refs in a short term RPS.\n");
++ return AVERROR_INVALIDDATA;
++ }
++
++ rps->num_delta_pocs = rps->num_negative_pics + nb_positive_pics;
++ if (rps->num_delta_pocs) {
++ prev = 0;
++ for (i = 0; i < rps->num_negative_pics; i++) {
++ delta_poc = get_ue_golomb_long(gb) + 1;
++ if (delta_poc < 1 || delta_poc > 32768) {
++ av_log(avctx, AV_LOG_ERROR,
++ "Invalid value of delta_poc: %d\n",
++ delta_poc);
++ return AVERROR_INVALIDDATA;
++ }
++ prev -= delta_poc;
++ rps->delta_poc[i] = prev;
++ rps->used[i] = get_bits1(gb);
++ }
++ prev = 0;
++ for (i = 0; i < nb_positive_pics; i++) {
++ delta_poc = get_ue_golomb_long(gb) + 1;
++ if (delta_poc < 1 || delta_poc > 32768) {
++ av_log(avctx, AV_LOG_ERROR,
++ "Invalid value of delta_poc: %d\n",
++ delta_poc);
++ return AVERROR_INVALIDDATA;
++ }
++ prev += delta_poc;
++ rps->delta_poc[rps->num_negative_pics + i] = prev;
++ rps->used[rps->num_negative_pics + i] = get_bits1(gb);
++ }
++ }
++ }
++ return 0;
++}
++
++
++static int decode_profile_tier_level(GetBitContext * const gb, AVCodecContext * const avctx,
++ PTLCommon * const ptl)
++{
++ int i;
++
++ if (get_bits_left(gb) < 2+1+5 + 32 + 4 + 16 + 16 + 12)
++ return -1;
++
++ ptl->profile_space = get_bits(gb, 2);
++ ptl->tier_flag = get_bits1(gb);
++ ptl->profile_idc = get_bits(gb, 5);
++ if (ptl->profile_idc == FF_PROFILE_HEVC_MAIN)
++ av_log(avctx, AV_LOG_DEBUG, "Main profile bitstream\n");
++ else if (ptl->profile_idc == FF_PROFILE_HEVC_MAIN_10)
++ av_log(avctx, AV_LOG_DEBUG, "Main 10 profile bitstream\n");
++ else if (ptl->profile_idc == FF_PROFILE_HEVC_MAIN_STILL_PICTURE)
++ av_log(avctx, AV_LOG_DEBUG, "Main Still Picture profile bitstream\n");
++ else if (ptl->profile_idc == FF_PROFILE_HEVC_REXT)
++ av_log(avctx, AV_LOG_DEBUG, "Range Extension profile bitstream\n");
++ else
++ av_log(avctx, AV_LOG_WARNING, "Unknown HEVC profile: %d\n", ptl->profile_idc);
++
++ for (i = 0; i < 32; i++) {
++ ptl->profile_compatibility_flag[i] = get_bits1(gb);
++
++ if (ptl->profile_idc == 0 && i > 0 && ptl->profile_compatibility_flag[i])
++ ptl->profile_idc = i;
++ }
++ ptl->progressive_source_flag = get_bits1(gb);
++ ptl->interlaced_source_flag = get_bits1(gb);
++ ptl->non_packed_constraint_flag = get_bits1(gb);
++ ptl->frame_only_constraint_flag = get_bits1(gb);
++
++ skip_bits(gb, 16); // XXX_reserved_zero_44bits[0..15]
++ skip_bits(gb, 16); // XXX_reserved_zero_44bits[16..31]
++ skip_bits(gb, 12); // XXX_reserved_zero_44bits[32..43]
++
++ return 0;
++}
++
++static int parse_ptl(GetBitContext * const gb, AVCodecContext * const avctx,
++ PTL * const ptl, const int max_num_sub_layers)
++{
++ int i;
++ if (decode_profile_tier_level(gb, avctx, &ptl->general_ptl) < 0 ||
++ get_bits_left(gb) < 8 + (8*2 * (max_num_sub_layers - 1 > 0))) {
++ av_log(avctx, AV_LOG_ERROR, "PTL information too short\n");
++ return -1;
++ }
++
++ ptl->general_ptl.level_idc = get_bits(gb, 8);
++
++ for (i = 0; i < max_num_sub_layers - 1; i++) {
++ ptl->sub_layer_profile_present_flag[i] = get_bits1(gb);
++ ptl->sub_layer_level_present_flag[i] = get_bits1(gb);
++ }
++
++ if (max_num_sub_layers - 1> 0)
++ for (i = max_num_sub_layers - 1; i < 8; i++)
++ skip_bits(gb, 2); // reserved_zero_2bits[i]
++ for (i = 0; i < max_num_sub_layers - 1; i++) {
++ if (ptl->sub_layer_profile_present_flag[i] &&
++ decode_profile_tier_level(gb, avctx, &ptl->sub_layer_ptl[i]) < 0) {
++ av_log(avctx, AV_LOG_ERROR,
++ "PTL information for sublayer %i too short\n", i);
++ return -1;
++ }
++ if (ptl->sub_layer_level_present_flag[i]) {
++ if (get_bits_left(gb) < 8) {
++ av_log(avctx, AV_LOG_ERROR,
++ "Not enough data for sublayer %i level_idc\n", i);
++ return -1;
++ } else
++ ptl->sub_layer_ptl[i].level_idc = get_bits(gb, 8);
++ }
++ }
++
++ return 0;
++}
++
++static void decode_sublayer_hrd(GetBitContext * const gb, const unsigned int nb_cpb,
++ const int subpic_params_present)
++{
++ int i;
++
++ for (i = 0; i < nb_cpb; i++) {
++ get_ue_golomb_long(gb); // bit_rate_value_minus1
++ get_ue_golomb_long(gb); // cpb_size_value_minus1
++
++ if (subpic_params_present) {
++ get_ue_golomb_long(gb); // cpb_size_du_value_minus1
++ get_ue_golomb_long(gb); // bit_rate_du_value_minus1
++ }
++ skip_bits1(gb); // cbr_flag
++ }
++}
++
++static int decode_hrd(GetBitContext * const gb, const int common_inf_present,
++ const int max_sublayers)
++{
++ int nal_params_present = 0, vcl_params_present = 0;
++ int subpic_params_present = 0;
++ int i;
++
++ if (common_inf_present) {
++ nal_params_present = get_bits1(gb);
++ vcl_params_present = get_bits1(gb);
++
++ if (nal_params_present || vcl_params_present) {
++ subpic_params_present = get_bits1(gb);
++
++ if (subpic_params_present) {
++ skip_bits(gb, 8); // tick_divisor_minus2
++ skip_bits(gb, 5); // du_cpb_removal_delay_increment_length_minus1
++ skip_bits(gb, 1); // sub_pic_cpb_params_in_pic_timing_sei_flag
++ skip_bits(gb, 5); // dpb_output_delay_du_length_minus1
++ }
++
++ skip_bits(gb, 4); // bit_rate_scale
++ skip_bits(gb, 4); // cpb_size_scale
++
++ if (subpic_params_present)
++ skip_bits(gb, 4); // cpb_size_du_scale
++
++ skip_bits(gb, 5); // initial_cpb_removal_delay_length_minus1
++ skip_bits(gb, 5); // au_cpb_removal_delay_length_minus1
++ skip_bits(gb, 5); // dpb_output_delay_length_minus1
++ }
++ }
++
++ for (i = 0; i < max_sublayers; i++) {
++ int low_delay = 0;
++ unsigned int nb_cpb = 1;
++ int fixed_rate = get_bits1(gb);
++
++ if (!fixed_rate)
++ fixed_rate = get_bits1(gb);
++
++ if (fixed_rate)
++ get_ue_golomb_long(gb); // elemental_duration_in_tc_minus1
++ else
++ low_delay = get_bits1(gb);
++
++ if (!low_delay) {
++ nb_cpb = get_ue_golomb_long(gb) + 1;
++ if (nb_cpb < 1 || nb_cpb > 32) {
++ av_log(NULL, AV_LOG_ERROR, "nb_cpb %d invalid\n", nb_cpb);
++ return AVERROR_INVALIDDATA;
++ }
++ }
++
++ if (nal_params_present)
++ decode_sublayer_hrd(gb, nb_cpb, subpic_params_present);
++ if (vcl_params_present)
++ decode_sublayer_hrd(gb, nb_cpb, subpic_params_present);
++ }
++ return 0;
++}
++
++int ff_hevc_rpi_decode_nal_vps(GetBitContext * const gb, AVCodecContext * const avctx,
++ HEVCRpiParamSets * const ps)
++{
++ int i,j;
++ int vps_id = 0;
++ ptrdiff_t nal_size;
++ HEVCRpiVPS *vps;
++ AVBufferRef *vps_buf = av_buffer_allocz(sizeof(*vps));
++
++ if (!vps_buf)
++ return AVERROR(ENOMEM);
++ vps = (HEVCRpiVPS*)vps_buf->data;
++
++ av_log(avctx, AV_LOG_DEBUG, "Decoding VPS\n");
++
++ nal_size = gb->buffer_end - gb->buffer;
++ if (nal_size > sizeof(vps->data)) {
++ av_log(avctx, AV_LOG_WARNING, "Truncating likely oversized VPS "
++ "(%"PTRDIFF_SPECIFIER" > %"SIZE_SPECIFIER")\n",
++ nal_size, sizeof(vps->data));
++ vps->data_size = sizeof(vps->data);
++ } else {
++ vps->data_size = nal_size;
++ }
++ memcpy(vps->data, gb->buffer, vps->data_size);
++
++ vps_id = get_bits(gb, 4);
++ if (vps_id >= HEVC_MAX_VPS_COUNT) {
++ av_log(avctx, AV_LOG_ERROR, "VPS id out of range: %d\n", vps_id);
++ goto err;
++ }
++
++ if (get_bits(gb, 2) != 3) { // vps_reserved_three_2bits
++ av_log(avctx, AV_LOG_ERROR, "vps_reserved_three_2bits is not three\n");
++ goto err;
++ }
++
++ vps->vps_max_layers = get_bits(gb, 6) + 1;
++ vps->vps_max_sub_layers = get_bits(gb, 3) + 1;
++ vps->vps_temporal_id_nesting_flag = get_bits1(gb);
++
++ if (get_bits(gb, 16) != 0xffff) { // vps_reserved_ffff_16bits
++ av_log(avctx, AV_LOG_ERROR, "vps_reserved_ffff_16bits is not 0xffff\n");
++ goto err;
++ }
++
++ if (vps->vps_max_sub_layers > HEVC_MAX_SUB_LAYERS) {
++ av_log(avctx, AV_LOG_ERROR, "vps_max_sub_layers out of range: %d\n",
++ vps->vps_max_sub_layers);
++ goto err;
++ }
++
++ if (parse_ptl(gb, avctx, &vps->ptl, vps->vps_max_sub_layers) < 0)
++ goto err;
++
++ vps->vps_sub_layer_ordering_info_present_flag = get_bits1(gb);
++
++ i = vps->vps_sub_layer_ordering_info_present_flag ? 0 : vps->vps_max_sub_layers - 1;
++ for (; i < vps->vps_max_sub_layers; i++) {
++ vps->vps_max_dec_pic_buffering[i] = get_ue_golomb_long(gb) + 1;
++ vps->vps_num_reorder_pics[i] = get_ue_golomb_long(gb);
++ vps->vps_max_latency_increase[i] = get_ue_golomb_long(gb) - 1;
++
++ if (vps->vps_max_dec_pic_buffering[i] > HEVC_MAX_DPB_SIZE || !vps->vps_max_dec_pic_buffering[i]) {
++ av_log(avctx, AV_LOG_ERROR, "vps_max_dec_pic_buffering_minus1 out of range: %d\n",
++ vps->vps_max_dec_pic_buffering[i] - 1);
++ goto err;
++ }
++ if (vps->vps_num_reorder_pics[i] > vps->vps_max_dec_pic_buffering[i] - 1) {
++ av_log(avctx, AV_LOG_WARNING, "vps_max_num_reorder_pics out of range: %d\n",
++ vps->vps_num_reorder_pics[i]);
++ if (avctx->err_recognition & AV_EF_EXPLODE)
++ goto err;
++ }
++ }
++
++ vps->vps_max_layer_id = get_bits(gb, 6);
++ vps->vps_num_layer_sets = get_ue_golomb_long(gb) + 1;
++ if (vps->vps_num_layer_sets < 1 || vps->vps_num_layer_sets > 1024 ||
++ (vps->vps_num_layer_sets - 1LL) * (vps->vps_max_layer_id + 1LL) > get_bits_left(gb)) {
++ av_log(avctx, AV_LOG_ERROR, "too many layer_id_included_flags\n");
++ goto err;
++ }
++
++ for (i = 1; i < vps->vps_num_layer_sets; i++)
++ for (j = 0; j <= vps->vps_max_layer_id; j++)
++ skip_bits(gb, 1); // layer_id_included_flag[i][j]
++
++ vps->vps_timing_info_present_flag = get_bits1(gb);
++ if (vps->vps_timing_info_present_flag) {
++ vps->vps_num_units_in_tick = get_bits_long(gb, 32);
++ vps->vps_time_scale = get_bits_long(gb, 32);
++ vps->vps_poc_proportional_to_timing_flag = get_bits1(gb);
++ if (vps->vps_poc_proportional_to_timing_flag)
++ vps->vps_num_ticks_poc_diff_one = get_ue_golomb_long(gb) + 1;
++ vps->vps_num_hrd_parameters = get_ue_golomb_long(gb);
++ if (vps->vps_num_hrd_parameters > (unsigned)vps->vps_num_layer_sets) {
++ av_log(avctx, AV_LOG_ERROR,
++ "vps_num_hrd_parameters %d is invalid\n", vps->vps_num_hrd_parameters);
++ goto err;
++ }
++ for (i = 0; i < vps->vps_num_hrd_parameters; i++) {
++ int common_inf_present = 1;
++
++ get_ue_golomb_long(gb); // hrd_layer_set_idx
++ if (i)
++ common_inf_present = get_bits1(gb);
++ decode_hrd(gb, common_inf_present, vps->vps_max_sub_layers);
++ }
++ }
++ get_bits1(gb); /* vps_extension_flag */
++
++ if (get_bits_left(gb) < 0) {
++ av_log(avctx, AV_LOG_ERROR,
++ "Overread VPS by %d bits\n", -get_bits_left(gb));
++ if (ps->vps_list[vps_id])
++ goto err;
++ }
++
++ if (ps->vps_list[vps_id] &&
++ !memcmp(ps->vps_list[vps_id]->data, vps_buf->data, vps_buf->size)) {
++ av_buffer_unref(&vps_buf);
++ } else {
++ remove_vps(ps, vps_id);
++ ps->vps_list[vps_id] = vps_buf;
++ }
++
++ return 0;
++
++err:
++ av_buffer_unref(&vps_buf);
++ return AVERROR_INVALIDDATA;
++}
++
++static void decode_vui(GetBitContext * const gb, AVCodecContext * const avctx,
++ const int apply_defdispwin, HEVCRpiSPS * const sps)
++{
++ VUI backup_vui, * const vui = &sps->vui;
++ GetBitContext backup;
++ int sar_present, alt = 0;
++
++ av_log(avctx, AV_LOG_DEBUG, "Decoding VUI\n");
++
++ sar_present = get_bits1(gb);
++ if (sar_present) {
++ uint8_t sar_idx = get_bits(gb, 8);
++ if (sar_idx < FF_ARRAY_ELEMS(vui_sar))
++ vui->sar = vui_sar[sar_idx];
++ else if (sar_idx == 255) {
++ vui->sar.num = get_bits(gb, 16);
++ vui->sar.den = get_bits(gb, 16);
++ } else
++ av_log(avctx, AV_LOG_WARNING,
++ "Unknown SAR index: %u.\n", sar_idx);
++ }
++
++ vui->overscan_info_present_flag = get_bits1(gb);
++ if (vui->overscan_info_present_flag)
++ vui->overscan_appropriate_flag = get_bits1(gb);
++
++ vui->video_signal_type_present_flag = get_bits1(gb);
++ if (vui->video_signal_type_present_flag) {
++ vui->video_format = get_bits(gb, 3);
++ vui->video_full_range_flag = get_bits1(gb);
++ vui->colour_description_present_flag = get_bits1(gb);
++ if (vui->video_full_range_flag && sps->pix_fmt == AV_PIX_FMT_YUV420P)
++ sps->pix_fmt = AV_PIX_FMT_YUVJ420P;
++ if (vui->colour_description_present_flag) {
++ vui->colour_primaries = get_bits(gb, 8);
++ vui->transfer_characteristic = get_bits(gb, 8);
++ vui->matrix_coeffs = get_bits(gb, 8);
++
++ // Set invalid values to "unspecified"
++ if (!av_color_primaries_name(vui->colour_primaries))
++ vui->colour_primaries = AVCOL_PRI_UNSPECIFIED;
++ if (!av_color_transfer_name(vui->transfer_characteristic))
++ vui->transfer_characteristic = AVCOL_TRC_UNSPECIFIED;
++ if (!av_color_space_name(vui->matrix_coeffs))
++ vui->matrix_coeffs = AVCOL_SPC_UNSPECIFIED;
++ if (vui->matrix_coeffs == AVCOL_SPC_RGB) {
++ switch (sps->pix_fmt) {
++ case AV_PIX_FMT_YUV444P:
++ sps->pix_fmt = AV_PIX_FMT_GBRP;
++ break;
++ case AV_PIX_FMT_YUV444P10:
++ sps->pix_fmt = AV_PIX_FMT_GBRP10;
++ break;
++ case AV_PIX_FMT_YUV444P12:
++ sps->pix_fmt = AV_PIX_FMT_GBRP12;
++ break;
++ }
++ }
++ }
++ }
++
++ vui->chroma_loc_info_present_flag = get_bits1(gb);
++ if (vui->chroma_loc_info_present_flag) {
++ vui->chroma_sample_loc_type_top_field = get_ue_golomb_long(gb);
++ vui->chroma_sample_loc_type_bottom_field = get_ue_golomb_long(gb);
++ }
++
++ vui->neutra_chroma_indication_flag = get_bits1(gb);
++ vui->field_seq_flag = get_bits1(gb);
++ vui->frame_field_info_present_flag = get_bits1(gb);
++
++ // Backup context in case an alternate header is detected
++ memcpy(&backup, gb, sizeof(backup));
++ memcpy(&backup_vui, vui, sizeof(backup_vui));
++ if (get_bits_left(gb) >= 68 && show_bits_long(gb, 21) == 0x100000) {
++ vui->default_display_window_flag = 0;
++ av_log(avctx, AV_LOG_WARNING, "Invalid default display window\n");
++ } else
++ vui->default_display_window_flag = get_bits1(gb);
++
++ if (vui->default_display_window_flag) {
++ int vert_mult = 1 + (sps->chroma_format_idc < 2);
++ int horiz_mult = 1 + (sps->chroma_format_idc < 3);
++ vui->def_disp_win.left_offset = get_ue_golomb_long(gb) * horiz_mult;
++ vui->def_disp_win.right_offset = get_ue_golomb_long(gb) * horiz_mult;
++ vui->def_disp_win.top_offset = get_ue_golomb_long(gb) * vert_mult;
++ vui->def_disp_win.bottom_offset = get_ue_golomb_long(gb) * vert_mult;
++
++ if (apply_defdispwin &&
++ avctx->flags2 & AV_CODEC_FLAG2_IGNORE_CROP) {
++ av_log(avctx, AV_LOG_DEBUG,
++ "discarding vui default display window, "
++ "original values are l:%u r:%u t:%u b:%u\n",
++ vui->def_disp_win.left_offset,
++ vui->def_disp_win.right_offset,
++ vui->def_disp_win.top_offset,
++ vui->def_disp_win.bottom_offset);
++
++ vui->def_disp_win.left_offset =
++ vui->def_disp_win.right_offset =
++ vui->def_disp_win.top_offset =
++ vui->def_disp_win.bottom_offset = 0;
++ }
++ }
++
++timing_info:
++ vui->vui_timing_info_present_flag = get_bits1(gb);
++
++ if (vui->vui_timing_info_present_flag) {
++ if( get_bits_left(gb) < 66 && !alt) {
++ // The alternate syntax seem to have timing info located
++ // at where def_disp_win is normally located
++ av_log(avctx, AV_LOG_WARNING,
++ "Strange VUI timing information, retrying...\n");
++ memcpy(vui, &backup_vui, sizeof(backup_vui));
++ memcpy(gb, &backup, sizeof(backup));
++ alt = 1;
++ goto timing_info;
++ }
++ vui->vui_num_units_in_tick = get_bits_long(gb, 32);
++ vui->vui_time_scale = get_bits_long(gb, 32);
++ if (alt) {
++ av_log(avctx, AV_LOG_INFO, "Retry got %"PRIu32"/%"PRIu32" fps\n",
++ vui->vui_time_scale, vui->vui_num_units_in_tick);
++ }
++ vui->vui_poc_proportional_to_timing_flag = get_bits1(gb);
++ if (vui->vui_poc_proportional_to_timing_flag)
++ vui->vui_num_ticks_poc_diff_one_minus1 = get_ue_golomb_long(gb);
++ vui->vui_hrd_parameters_present_flag = get_bits1(gb);
++ if (vui->vui_hrd_parameters_present_flag)
++ decode_hrd(gb, 1, sps->max_sub_layers);
++ }
++
++ vui->bitstream_restriction_flag = get_bits1(gb);
++ if (vui->bitstream_restriction_flag) {
++ if (get_bits_left(gb) < 8 && !alt) {
++ av_log(avctx, AV_LOG_WARNING,
++ "Strange VUI bitstream restriction information, retrying"
++ " from timing information...\n");
++ memcpy(vui, &backup_vui, sizeof(backup_vui));
++ memcpy(gb, &backup, sizeof(backup));
++ alt = 1;
++ goto timing_info;
++ }
++ vui->tiles_fixed_structure_flag = get_bits1(gb);
++ vui->motion_vectors_over_pic_boundaries_flag = get_bits1(gb);
++ vui->restricted_ref_pic_lists_flag = get_bits1(gb);
++ vui->min_spatial_segmentation_idc = get_ue_golomb_long(gb);
++ vui->max_bytes_per_pic_denom = get_ue_golomb_long(gb);
++ vui->max_bits_per_min_cu_denom = get_ue_golomb_long(gb);
++ vui->log2_max_mv_length_horizontal = get_ue_golomb_long(gb);
++ vui->log2_max_mv_length_vertical = get_ue_golomb_long(gb);
++ }
++
++ if (get_bits_left(gb) < 1 && !alt) {
++ // XXX: Alternate syntax when sps_range_extension_flag != 0?
++ av_log(avctx, AV_LOG_WARNING,
++ "Overread in VUI, retrying from timing information...\n");
++ memcpy(vui, &backup_vui, sizeof(backup_vui));
++ memcpy(gb, &backup, sizeof(backup));
++ alt = 1;
++ goto timing_info;
++ }
++}
++
++static void set_default_scaling_list_data(ScalingList * const sl)
++{
++ int matrixId;
++
++ for (matrixId = 0; matrixId < 6; matrixId++) {
++ // 4x4 default is 16
++ memset(sl->sl[0][matrixId], 16, 16);
++ sl->sl_dc[0][matrixId] = 16; // default for 16x16
++ sl->sl_dc[1][matrixId] = 16; // default for 32x32
++ }
++
++ memcpy(sl->sl[1][0], default_scaling_list_intra, 64);
++ memcpy(sl->sl[1][1], default_scaling_list_intra, 64);
++ memcpy(sl->sl[1][2], default_scaling_list_intra, 64);
++
++ memcpy(sl->sl[1][3], default_scaling_list_inter, 64);
++ memcpy(sl->sl[1][4], default_scaling_list_inter, 64);
++ memcpy(sl->sl[1][5], default_scaling_list_inter, 64);
++
++ memcpy(sl->sl[2][0], default_scaling_list_intra, 64);
++ memcpy(sl->sl[2][1], default_scaling_list_intra, 64);
++ memcpy(sl->sl[2][2], default_scaling_list_intra, 64);
++
++ memcpy(sl->sl[2][3], default_scaling_list_inter, 64);
++ memcpy(sl->sl[2][4], default_scaling_list_inter, 64);
++ memcpy(sl->sl[2][5], default_scaling_list_inter, 64);
++
++ memcpy(sl->sl[3][0], default_scaling_list_intra, 64);
++ memcpy(sl->sl[3][1], default_scaling_list_intra, 64);
++ memcpy(sl->sl[3][2], default_scaling_list_intra, 64);
++
++ memcpy(sl->sl[3][3], default_scaling_list_inter, 64);
++ memcpy(sl->sl[3][4], default_scaling_list_inter, 64);
++ memcpy(sl->sl[3][5], default_scaling_list_inter, 64);
++}
++
++static int scaling_list_data(GetBitContext * const gb, AVCodecContext * const avctx, ScalingList * const sl,
++ const HEVCRpiSPS * const sps)
++{
++ uint8_t scaling_list_pred_mode_flag;
++ int32_t scaling_list_dc_coef[2][6];
++ int size_id, matrix_id, pos;
++ int i;
++
++ for (size_id = 0; size_id < 4; size_id++)
++ for (matrix_id = 0; matrix_id < 6; matrix_id += ((size_id == 3) ? 3 : 1)) {
++ scaling_list_pred_mode_flag = get_bits1(gb);
++ if (!scaling_list_pred_mode_flag) {
++ unsigned int delta = get_ue_golomb_long(gb);
++ /* Only need to handle non-zero delta. Zero means default,
++ * which should already be in the arrays. */
++ if (delta) {
++ // Copy from previous array.
++ delta *= (size_id == 3) ? 3 : 1;
++ if (matrix_id < delta) {
++ av_log(avctx, AV_LOG_ERROR,
++ "Invalid delta in scaling list data: %d.\n", delta);
++ return AVERROR_INVALIDDATA;
++ }
++
++ memcpy(sl->sl[size_id][matrix_id],
++ sl->sl[size_id][matrix_id - delta],
++ size_id > 0 ? 64 : 16);
++ if (size_id > 1)
++ sl->sl_dc[size_id - 2][matrix_id] = sl->sl_dc[size_id - 2][matrix_id - delta];
++ }
++ } else {
++ int next_coef, coef_num;
++ int32_t scaling_list_delta_coef;
++
++ next_coef = 8;
++ coef_num = FFMIN(64, 1 << (4 + (size_id << 1)));
++ if (size_id > 1) {
++ scaling_list_dc_coef[size_id - 2][matrix_id] = get_se_golomb(gb) + 8;
++ next_coef = scaling_list_dc_coef[size_id - 2][matrix_id];
++ sl->sl_dc[size_id - 2][matrix_id] = next_coef;
++ }
++ for (i = 0; i < coef_num; i++) {
++ if (size_id == 0)
++ pos = 4 * ff_hevc_rpi_diag_scan4x4_y[i] +
++ ff_hevc_rpi_diag_scan4x4_x[i];
++ else
++ pos = 8 * ff_hevc_rpi_diag_scan8x8_y[i] +
++ ff_hevc_rpi_diag_scan8x8_x[i];
++
++ scaling_list_delta_coef = get_se_golomb(gb);
++ next_coef = (next_coef + 256U + scaling_list_delta_coef) % 256;
++ sl->sl[size_id][matrix_id][pos] = next_coef;
++ }
++ }
++ }
++
++ if (sps->chroma_format_idc == 3) {
++ for (i = 0; i < 64; i++) {
++ sl->sl[3][1][i] = sl->sl[2][1][i];
++ sl->sl[3][2][i] = sl->sl[2][2][i];
++ sl->sl[3][4][i] = sl->sl[2][4][i];
++ sl->sl[3][5][i] = sl->sl[2][5][i];
++ }
++ sl->sl_dc[1][1] = sl->sl_dc[0][1];
++ sl->sl_dc[1][2] = sl->sl_dc[0][2];
++ sl->sl_dc[1][4] = sl->sl_dc[0][4];
++ sl->sl_dc[1][5] = sl->sl_dc[0][5];
++ }
++
++
++ return 0;
++}
++
++static int map_pixel_format(HEVCRpiSPS * const sps)
++{
++ const int cfmt = sps->chroma_format_idc;
++
++ sps->pix_fmt = AV_PIX_FMT_NONE;
++ switch (sps->bit_depth) {
++ case 8:
++ if (cfmt == 1)
++ sps->pix_fmt = AV_PIX_FMT_SAND128;
++ break;
++ case 10:
++ if (cfmt == 1)
++ sps->pix_fmt = AV_PIX_FMT_SAND64_10;
++ break;
++ default:
++ break;
++ }
++
++ sps->hshift[0] = sps->vshift[0] = 0;
++ sps->hshift[2] = sps->hshift[1] = cfmt > 2 ? 0 : 1; // 1 unless 4:4:4
++ sps->vshift[2] = sps->vshift[1] = cfmt > 1 ? 0 : 1; // 1 unless 4:4:4 or 4:2:2
++
++ sps->pixel_shift = sps->bit_depth > 8 ? 1 : 0;
++
++ return 0;
++}
++
++static int ff_hevc_rpi_parse_sps(HEVCRpiSPS * const sps, GetBitContext * const gb, unsigned int * const sps_id,
++ const int apply_defdispwin, AVBufferRef * const * const vps_list, AVCodecContext * const avctx)
++{
++ HEVCRpiWindow *ow;
++ int ret = 0;
++ int log2_diff_max_min_transform_block_size;
++ int bit_depth_chroma, start, vui_present, sublayer_ordering_info;
++ int i;
++
++ // Coded parameters
++
++ sps->vps_id = get_bits(gb, 4);
++ if (sps->vps_id >= HEVC_MAX_VPS_COUNT) {
++ av_log(avctx, AV_LOG_ERROR, "VPS id out of range: %d\n", sps->vps_id);
++ return AVERROR_INVALIDDATA;
++ }
++
++ if (vps_list && !vps_list[sps->vps_id]) {
++ av_log(avctx, AV_LOG_ERROR, "VPS %d does not exist\n",
++ sps->vps_id);
++ return AVERROR_INVALIDDATA;
++ }
++
++ sps->max_sub_layers = get_bits(gb, 3) + 1;
++ if (sps->max_sub_layers > HEVC_MAX_SUB_LAYERS) {
++ av_log(avctx, AV_LOG_ERROR, "sps_max_sub_layers out of range: %d\n",
++ sps->max_sub_layers);
++ return AVERROR_INVALIDDATA;
++ }
++
++ sps->temporal_id_nesting_flag = get_bits(gb, 1);
++
++ if ((ret = parse_ptl(gb, avctx, &sps->ptl, sps->max_sub_layers)) < 0)
++ return ret;
++
++ *sps_id = get_ue_golomb_long(gb);
++ if (*sps_id >= HEVC_MAX_SPS_COUNT) {
++ av_log(avctx, AV_LOG_ERROR, "SPS id out of range: %d\n", *sps_id);
++ return AVERROR_INVALIDDATA;
++ }
++
++ sps->chroma_format_idc = get_ue_golomb_long(gb);
++ if (sps->chroma_format_idc > 3U) {
++ av_log(avctx, AV_LOG_ERROR, "chroma_format_idc %d is invalid\n", sps->chroma_format_idc);
++ return AVERROR_INVALIDDATA;
++ }
++
++ if (sps->chroma_format_idc == 3)
++ sps->separate_colour_plane_flag = get_bits1(gb);
++
++ if (sps->separate_colour_plane_flag)
++ sps->chroma_format_idc = 0;
++
++ sps->width = get_ue_golomb_long(gb);
++ sps->height = get_ue_golomb_long(gb);
++ if ((ret = av_image_check_size(sps->width,
++ sps->height, 0, avctx)) < 0)
++ return ret;
++
++ if (get_bits1(gb)) { // pic_conformance_flag
++ int vert_mult = 1 + (sps->chroma_format_idc < 2);
++ int horiz_mult = 1 + (sps->chroma_format_idc < 3);
++ sps->pic_conf_win.left_offset = get_ue_golomb_long(gb) * horiz_mult;
++ sps->pic_conf_win.right_offset = get_ue_golomb_long(gb) * horiz_mult;
++ sps->pic_conf_win.top_offset = get_ue_golomb_long(gb) * vert_mult;
++ sps->pic_conf_win.bottom_offset = get_ue_golomb_long(gb) * vert_mult;
++
++ if (avctx->flags2 & AV_CODEC_FLAG2_IGNORE_CROP) {
++ av_log(avctx, AV_LOG_DEBUG,
++ "discarding sps conformance window, "
++ "original values are l:%u r:%u t:%u b:%u\n",
++ sps->pic_conf_win.left_offset,
++ sps->pic_conf_win.right_offset,
++ sps->pic_conf_win.top_offset,
++ sps->pic_conf_win.bottom_offset);
++
++ sps->pic_conf_win.left_offset =
++ sps->pic_conf_win.right_offset =
++ sps->pic_conf_win.top_offset =
++ sps->pic_conf_win.bottom_offset = 0;
++ }
++ sps->output_window = sps->pic_conf_win;
++ }
++
++ sps->bit_depth = get_ue_golomb_long(gb) + 8;
++ bit_depth_chroma = get_ue_golomb_long(gb) + 8;
++ if (sps->chroma_format_idc && bit_depth_chroma != sps->bit_depth) {
++ av_log(avctx, AV_LOG_ERROR,
++ "Luma bit depth (%d) is different from chroma bit depth (%d), "
++ "this is unsupported.\n",
++ sps->bit_depth, bit_depth_chroma);
++ return AVERROR_INVALIDDATA;
++ }
++
++ ret = map_pixel_format(sps);
++ if (ret < 0)
++ return ret;
++
++ sps->log2_max_poc_lsb = get_ue_golomb_long(gb) + 4;
++ if (sps->log2_max_poc_lsb > 16) {
++ av_log(avctx, AV_LOG_ERROR, "log2_max_pic_order_cnt_lsb_minus4 out range: %d\n",
++ sps->log2_max_poc_lsb - 4);
++ return AVERROR_INVALIDDATA;
++ }
++
++ sublayer_ordering_info = get_bits1(gb);
++ start = sublayer_ordering_info ? 0 : sps->max_sub_layers - 1;
++ for (i = start; i < sps->max_sub_layers; i++) {
++ sps->temporal_layer[i].max_dec_pic_buffering = get_ue_golomb_long(gb) + 1;
++ sps->temporal_layer[i].num_reorder_pics = get_ue_golomb_long(gb);
++ sps->temporal_layer[i].max_latency_increase = get_ue_golomb_long(gb) - 1;
++ if (sps->temporal_layer[i].max_dec_pic_buffering > (unsigned)HEVC_MAX_DPB_SIZE) {
++ av_log(avctx, AV_LOG_ERROR, "sps_max_dec_pic_buffering_minus1 out of range: %d\n",
++ sps->temporal_layer[i].max_dec_pic_buffering - 1U);
++ return AVERROR_INVALIDDATA;
++ }
++ if (sps->temporal_layer[i].num_reorder_pics > sps->temporal_layer[i].max_dec_pic_buffering - 1) {
++ av_log(avctx, AV_LOG_WARNING, "sps_max_num_reorder_pics out of range: %d\n",
++ sps->temporal_layer[i].num_reorder_pics);
++ if (avctx->err_recognition & AV_EF_EXPLODE ||
++ sps->temporal_layer[i].num_reorder_pics > HEVC_MAX_DPB_SIZE - 1) {
++ return AVERROR_INVALIDDATA;
++ }
++ sps->temporal_layer[i].max_dec_pic_buffering = sps->temporal_layer[i].num_reorder_pics + 1;
++ }
++ }
++
++ if (!sublayer_ordering_info) {
++ for (i = 0; i < start; i++) {
++ sps->temporal_layer[i].max_dec_pic_buffering = sps->temporal_layer[start].max_dec_pic_buffering;
++ sps->temporal_layer[i].num_reorder_pics = sps->temporal_layer[start].num_reorder_pics;
++ sps->temporal_layer[i].max_latency_increase = sps->temporal_layer[start].max_latency_increase;
++ }
++ }
++
++ sps->log2_min_cb_size = get_ue_golomb_long(gb) + 3;
++ sps->log2_diff_max_min_coding_block_size = get_ue_golomb_long(gb);
++ sps->log2_min_tb_size = get_ue_golomb_long(gb) + 2;
++ log2_diff_max_min_transform_block_size = get_ue_golomb_long(gb);
++ sps->log2_max_trafo_size = log2_diff_max_min_transform_block_size +
++ sps->log2_min_tb_size;
++
++ if (sps->log2_min_cb_size < 3 || sps->log2_min_cb_size > 30) {
++ av_log(avctx, AV_LOG_ERROR, "Invalid value %d for log2_min_cb_size", sps->log2_min_cb_size);
++ return AVERROR_INVALIDDATA;
++ }
++
++ if (sps->log2_diff_max_min_coding_block_size > 30) {
++ av_log(avctx, AV_LOG_ERROR, "Invalid value %d for log2_diff_max_min_coding_block_size", sps->log2_diff_max_min_coding_block_size);
++ return AVERROR_INVALIDDATA;
++ }
++
++ if (sps->log2_min_tb_size >= sps->log2_min_cb_size || sps->log2_min_tb_size < 2) {
++ av_log(avctx, AV_LOG_ERROR, "Invalid value for log2_min_tb_size");
++ return AVERROR_INVALIDDATA;
++ }
++
++ if (log2_diff_max_min_transform_block_size < 0 || log2_diff_max_min_transform_block_size > 30) {
++ av_log(avctx, AV_LOG_ERROR, "Invalid value %d for log2_diff_max_min_transform_block_size", log2_diff_max_min_transform_block_size);
++ return AVERROR_INVALIDDATA;
++ }
++
++ {
++ const unsigned int CtbLog2SizeY = sps->log2_min_cb_size + sps->log2_diff_max_min_coding_block_size;
++ // Not a bitstream limitation, but all profiles
++ if (CtbLog2SizeY < 4 || CtbLog2SizeY > HEVC_MAX_LOG2_CTB_SIZE) {
++ av_log(avctx, AV_LOG_ERROR, "Invalid value %d for CtbLog2SizeY", CtbLog2SizeY);
++ return AVERROR_INVALIDDATA;
++ }
++
++ if (sps->log2_max_trafo_size > FFMIN(5, CtbLog2SizeY)) {
++ av_log(avctx, AV_LOG_ERROR, "Invalid value %d for MaxTbLog2SizeY", sps->log2_max_trafo_size);
++ return AVERROR_INVALIDDATA;
++ }
++
++ // Inferred parameters
++ sps->log2_ctb_size = CtbLog2SizeY;
++// sps->log2_min_pu_size = sps->log2_min_cb_size - 1;
++ }
++
++ sps->max_transform_hierarchy_depth_inter = get_ue_golomb_long(gb);
++ sps->max_transform_hierarchy_depth_intra = get_ue_golomb_long(gb);
++
++ sps->scaling_list_enable_flag = get_bits1(gb);
++ if (sps->scaling_list_enable_flag) {
++ set_default_scaling_list_data(&sps->scaling_list);
++
++ if (get_bits1(gb)) {
++ ret = scaling_list_data(gb, avctx, &sps->scaling_list, sps);
++ if (ret < 0)
++ return ret;
++ }
++ }
++
++ sps->amp_enabled_flag = get_bits1(gb);
++ sps->sao_enabled = get_bits1(gb);
++
++ // Set pcm defaults (0) so we don't have to test _enabled when we
++ // want to use them
++ memset(&sps->pcm, 0, sizeof(sps->pcm));
++
++ if (get_bits1(gb)) // pcm_enabled_flag
++ {
++ const unsigned int limit_max_pcm = FFMIN(5,
++ sps->log2_min_cb_size + sps->log2_diff_max_min_coding_block_size);
++ sps->pcm.bit_depth = get_bits(gb, 4) + 1;
++ sps->pcm.bit_depth_chroma = get_bits(gb, 4) + 1;
++ sps->pcm.log2_min_pcm_cb_size = get_ue_golomb_long(gb) + 3;
++ sps->pcm.log2_max_pcm_cb_size = sps->pcm.log2_min_pcm_cb_size +
++ get_ue_golomb_long(gb);
++ if (FFMAX(sps->pcm.bit_depth, sps->pcm.bit_depth_chroma) > sps->bit_depth) {
++ av_log(avctx, AV_LOG_ERROR,
++ "PCM bit depth (%d, %d) is greater than normal bit depth (%d)\n",
++ sps->pcm.bit_depth, sps->pcm.bit_depth_chroma, sps->bit_depth);
++ return AVERROR_INVALIDDATA;
++ }
++ if (sps->pcm.log2_min_pcm_cb_size < sps->log2_min_cb_size ||
++ sps->pcm.log2_max_pcm_cb_size > limit_max_pcm) {
++ av_log(avctx, AV_LOG_ERROR, "Bad PCM CB min/max size (%d->%d)",
++ sps->pcm.log2_min_pcm_cb_size, sps->pcm.log2_max_pcm_cb_size);
++ return AVERROR_INVALIDDATA;
++ }
++
++ sps->pcm.loop_filter_disable_flag = get_bits1(gb);
++ }
++
++ // Could be based on min_pcm_cb_size but much easier logic if we just stick
++ // with 8 (and costs us little)
++ sps->pcm_width = (sps->width + 63) >> 6; // 8 for min size, 8 bits per byte - round up
++ sps->pcm_height = (sps->height + 7) >> 3;
++
++ sps->nb_st_rps = get_ue_golomb_long(gb);
++ if (sps->nb_st_rps > HEVC_MAX_SHORT_TERM_REF_PIC_SETS) {
++ av_log(avctx, AV_LOG_ERROR, "Too many short term RPS: %d.\n",
++ sps->nb_st_rps);
++ return AVERROR_INVALIDDATA;
++ }
++ for (i = 0; i < sps->nb_st_rps; i++) {
++ if ((ret = ff_hevc_rpi_decode_short_term_rps(gb, avctx, &sps->st_rps[i],
++ sps, 0)) < 0)
++ return ret;
++ }
++
++ sps->long_term_ref_pics_present_flag = get_bits1(gb);
++ if (sps->long_term_ref_pics_present_flag) {
++ sps->num_long_term_ref_pics_sps = get_ue_golomb_long(gb);
++ if (sps->num_long_term_ref_pics_sps > HEVC_MAX_LONG_TERM_REF_PICS) {
++ av_log(avctx, AV_LOG_ERROR, "num_long_term_ref_pics_sps %d is out of range.\n",
++ sps->num_long_term_ref_pics_sps);
++ return AVERROR_INVALIDDATA;
++ }
++ for (i = 0; i < sps->num_long_term_ref_pics_sps; i++) {
++ sps->lt_ref_pic_poc_lsb_sps[i] = get_bits(gb, sps->log2_max_poc_lsb);
++ sps->used_by_curr_pic_lt_sps_flag[i] = get_bits1(gb);
++ }
++ }
++
++ sps->sps_temporal_mvp_enabled_flag = get_bits1(gb);
++ sps->sps_strong_intra_smoothing_enable_flag = get_bits1(gb);
++ sps->vui.sar = (AVRational){0, 1};
++ vui_present = get_bits1(gb);
++ if (vui_present)
++ decode_vui(gb, avctx, apply_defdispwin, sps);
++
++ if (get_bits1(gb)) { // sps_extension_flag
++ int sps_extension_flag[1];
++ for (i = 0; i < 1; i++)
++ sps_extension_flag[i] = get_bits1(gb);
++ skip_bits(gb, 7); //sps_extension_7bits = get_bits(gb, 7);
++ if (sps_extension_flag[0]) {
++ int extended_precision_processing_flag;
++ int cabac_bypass_alignment_enabled_flag;
++
++ sps->transform_skip_rotation_enabled_flag = get_bits1(gb);
++ sps->transform_skip_context_enabled_flag = get_bits1(gb);
++ sps->implicit_rdpcm_enabled_flag = get_bits1(gb);
++
++ sps->explicit_rdpcm_enabled_flag = get_bits1(gb);
++
++ extended_precision_processing_flag = get_bits1(gb);
++ if (extended_precision_processing_flag)
++ av_log(avctx, AV_LOG_WARNING,
++ "extended_precision_processing_flag not yet implemented\n");
++
++ sps->intra_smoothing_disabled_flag = get_bits1(gb);
++ sps->high_precision_offsets_enabled_flag = get_bits1(gb);
++ sps->persistent_rice_adaptation_enabled_flag = get_bits1(gb);
++
++ cabac_bypass_alignment_enabled_flag = get_bits1(gb);
++ if (cabac_bypass_alignment_enabled_flag)
++ av_log(avctx, AV_LOG_WARNING,
++ "cabac_bypass_alignment_enabled_flag not yet implemented\n");
++ }
++ }
++ if (apply_defdispwin) {
++ sps->output_window.left_offset += sps->vui.def_disp_win.left_offset;
++ sps->output_window.right_offset += sps->vui.def_disp_win.right_offset;
++ sps->output_window.top_offset += sps->vui.def_disp_win.top_offset;
++ sps->output_window.bottom_offset += sps->vui.def_disp_win.bottom_offset;
++ }
++
++ ow = &sps->output_window;
++ if (ow->left_offset >= INT_MAX - ow->right_offset ||
++ ow->top_offset >= INT_MAX - ow->bottom_offset ||
++ ow->left_offset + ow->right_offset >= sps->width ||
++ ow->top_offset + ow->bottom_offset >= sps->height) {
++ av_log(avctx, AV_LOG_WARNING, "Invalid cropping offsets: %u/%u/%u/%u\n",
++ ow->left_offset, ow->right_offset, ow->top_offset, ow->bottom_offset);
++ if (avctx->err_recognition & AV_EF_EXPLODE) {
++ return AVERROR_INVALIDDATA;
++ }
++ av_log(avctx, AV_LOG_WARNING,
++ "Displaying the whole video surface.\n");
++ memset(ow, 0, sizeof(*ow));
++ memset(&sps->pic_conf_win, 0, sizeof(sps->pic_conf_win));
++ }
++
++ // Inferred parameters
++
++ sps->ctb_width = (sps->width + (1 << sps->log2_ctb_size) - 1) >> sps->log2_ctb_size;
++ sps->ctb_height = (sps->height + (1 << sps->log2_ctb_size) - 1) >> sps->log2_ctb_size;
++ sps->ctb_size = sps->ctb_width * sps->ctb_height;
++
++ sps->min_cb_width = sps->width >> sps->log2_min_cb_size;
++ sps->min_cb_height = sps->height >> sps->log2_min_cb_size;
++ sps->min_tb_width = sps->width >> sps->log2_min_tb_size;
++ sps->min_tb_height = sps->height >> sps->log2_min_tb_size;
++ sps->min_pu_width = sps->width >> LOG2_MIN_PU_SIZE;
++ sps->min_pu_height = sps->height >> LOG2_MIN_PU_SIZE;
++ sps->tb_mask = (1 << (sps->log2_ctb_size - sps->log2_min_tb_size)) - 1;
++
++ sps->qp_bd_offset = 6 * (sps->bit_depth - 8);
++ sps->wp_offset_half_range = (1U << (sps->high_precision_offsets_enabled_flag ? sps->bit_depth - 1 : 7));
++
++ if (av_mod_uintp2(sps->width, sps->log2_min_cb_size) ||
++ av_mod_uintp2(sps->height, sps->log2_min_cb_size)) {
++ av_log(avctx, AV_LOG_ERROR, "Invalid coded frame dimensions.\n");
++ return AVERROR_INVALIDDATA;
++ }
++
++ if (sps->max_transform_hierarchy_depth_inter > sps->log2_ctb_size - sps->log2_min_tb_size) {
++ av_log(avctx, AV_LOG_ERROR, "max_transform_hierarchy_depth_inter out of range: %d\n",
++ sps->max_transform_hierarchy_depth_inter);
++ return AVERROR_INVALIDDATA;
++ }
++ if (sps->max_transform_hierarchy_depth_intra > sps->log2_ctb_size - sps->log2_min_tb_size) {
++ av_log(avctx, AV_LOG_ERROR, "max_transform_hierarchy_depth_intra out of range: %d\n",
++ sps->max_transform_hierarchy_depth_intra);
++ return AVERROR_INVALIDDATA;
++ }
++ if (sps->log2_max_trafo_size > FFMIN(sps->log2_ctb_size, 5)) {
++ av_log(avctx, AV_LOG_ERROR,
++ "max transform block size out of range: %d\n",
++ sps->log2_max_trafo_size);
++ return AVERROR_INVALIDDATA;
++ }
++
++ if (get_bits_left(gb) < 0) {
++ av_log(avctx, AV_LOG_ERROR,
++ "Overread SPS by %d bits\n", -get_bits_left(gb));
++ return AVERROR_INVALIDDATA;
++ }
++
++ return 0;
++}
++
++int ff_hevc_rpi_decode_nal_sps(GetBitContext *gb, AVCodecContext *avctx,
++ HEVCRpiParamSets *ps, int apply_defdispwin)
++{
++ HEVCRpiSPS *sps;
++ AVBufferRef *sps_buf = av_buffer_allocz(sizeof(*sps));
++ unsigned int sps_id;
++ int ret;
++ ptrdiff_t nal_size;
++
++ if (!sps_buf)
++ return AVERROR(ENOMEM);
++ sps = (HEVCRpiSPS*)sps_buf->data;
++
++ av_log(avctx, AV_LOG_DEBUG, "Decoding SPS\n");
++
++ nal_size = gb->buffer_end - gb->buffer;
++ if (nal_size > sizeof(sps->data)) {
++ av_log(avctx, AV_LOG_WARNING, "Truncating likely oversized SPS "
++ "(%"PTRDIFF_SPECIFIER" > %"SIZE_SPECIFIER")\n",
++ nal_size, sizeof(sps->data));
++ sps->data_size = sizeof(sps->data);
++ } else {
++ sps->data_size = nal_size;
++ }
++ memcpy(sps->data, gb->buffer, sps->data_size);
++
++ ret = ff_hevc_rpi_parse_sps(sps, gb, &sps_id,
++ apply_defdispwin,
++ ps->vps_list, avctx);
++ if (ret < 0) {
++ av_buffer_unref(&sps_buf);
++ return ret;
++ }
++
++ if (avctx->debug & FF_DEBUG_BITSTREAM) {
++ av_log(avctx, AV_LOG_DEBUG,
++ "Parsed SPS: id %d; coded wxh: %dx%d; "
++ "cropped wxh: %dx%d; pix_fmt: %s.\n",
++ sps_id, sps->width, sps->height,
++ sps->width - (sps->output_window.left_offset + sps->output_window.right_offset),
++ sps->height - (sps->output_window.top_offset + sps->output_window.bottom_offset),
++ av_get_pix_fmt_name(sps->pix_fmt));
++ }
++
++ /* check if this is a repeat of an already parsed SPS, then keep the
++ * original one.
++ * otherwise drop all PPSes that depend on it */
++ if (ps->sps_list[sps_id] &&
++ !memcmp(ps->sps_list[sps_id]->data, sps_buf->data, sps_buf->size)) {
++ av_buffer_unref(&sps_buf);
++ } else {
++ remove_sps(ps, sps_id);
++ ps->sps_list[sps_id] = sps_buf;
++ }
++
++ return 0;
++}
++
++static void hevc_pps_free(void *opaque, uint8_t *data)
++{
++ HEVCRpiPPS *pps = (HEVCRpiPPS*)data;
++
++ av_freep(&pps->column_width);
++ av_freep(&pps->row_height);
++ av_freep(&pps->col_bd);
++ av_freep(&pps->row_bd);
++ av_freep(&pps->col_idxX);
++ av_freep(&pps->ctb_addr_rs_to_ts);
++ av_freep(&pps->ctb_addr_ts_to_rs);
++ av_freep(&pps->tile_pos_ts);
++ av_freep(&pps->tile_size);
++ av_freep(&pps->tile_id);
++ av_freep(&pps->ctb_ts_flags);
++
++ av_freep(&pps);
++}
++
++static int get_offset_list(GetBitContext * const gb, AVCodecContext * const avctx, unsigned int n_minus_1, int8_t * offsets)
++{
++ do
++ {
++ const int offset = get_se_golomb_long(gb);
++ if (offset < -12 || offset > 12) {
++ av_log(avctx, AV_LOG_ERROR, "qp_offset_list[]: %d out of range\n", offset);
++ return AVERROR_INVALIDDATA;
++ }
++ *offsets++ = offset;
++ } while (n_minus_1-- != 0);
++ return 0;
++}
++
++static int pps_range_extensions(GetBitContext * const gb, AVCodecContext * const avctx,
++ HEVCRpiPPS * const pps, const HEVCRpiSPS * const sps)
++{
++ if (pps->transform_skip_enabled_flag) {
++ pps->log2_max_transform_skip_block_size = get_ue_golomb_long(gb) + 2;
++ }
++ pps->cross_component_prediction_enabled_flag = get_bits1(gb);
++ if (pps->cross_component_prediction_enabled_flag &&
++ (sps->chroma_format_idc != 3 || sps->separate_colour_plane_flag))
++ {
++ av_log(avctx, AV_LOG_ERROR, "cross_component_prediction_enabled but chroma_format_idc != 3\n");
++ return AVERROR_INVALIDDATA;
++ }
++ pps->chroma_qp_offset_list_enabled_flag = get_bits1(gb);
++ if (pps->chroma_qp_offset_list_enabled_flag) {
++ int err;
++
++ pps->diff_cu_chroma_qp_offset_depth = get_ue_golomb_long(gb);
++ pps->chroma_qp_offset_list_len_minus1 = get_ue_golomb_long(gb);
++ if (pps->chroma_qp_offset_list_len_minus1 > 5) {
++ av_log(avctx, AV_LOG_ERROR,
++ "chroma_qp_offset_list_len_minus1 shall be in the range [0, 5].\n");
++ return AVERROR_INVALIDDATA;
++ }
++ av_log(avctx, AV_LOG_WARNING, "cb_qp_offset_list not tested yet.\n");
++
++ if ((err = get_offset_list(gb, avctx, pps->chroma_qp_offset_list_len_minus1, pps->cb_qp_offset_list)) != 0 ||
++ (err = get_offset_list(gb, avctx, pps->chroma_qp_offset_list_len_minus1, pps->cr_qp_offset_list)) != 0)
++ return err;
++ }
++
++ {
++ const unsigned int max_offset = sps->bit_depth > 10 ? sps->bit_depth - 10 : 0;
++
++ pps->log2_sao_offset_scale_luma = get_ue_golomb_long(gb);
++ if (pps->log2_sao_offset_scale_luma > max_offset) {
++ av_log(avctx, AV_LOG_ERROR, "log2_sao_offset_scale_luma invalid");
++ return AVERROR_INVALIDDATA;
++ }
++ pps->log2_sao_offset_scale_chroma = get_ue_golomb_long(gb);
++ if (pps->log2_sao_offset_scale_chroma > max_offset) {
++ av_log(avctx, AV_LOG_ERROR, "log2_sao_offset_scale_chroma invalid");
++ return AVERROR_INVALIDDATA;
++ }
++ }
++
++ return(0);
++}
++
++static inline int setup_pps(AVCodecContext * const avctx,
++ HEVCRpiPPS * const pps, const HEVCRpiSPS * const sps)
++{
++ int pic_area_in_ctbs;
++ int i, j, x, y, ctb_addr_rs, tile_id;
++
++ // Inferred parameters
++
++ // qp_y -> qp_u/qp_v tables
++ // The tables have at least -24,+24 overrun after adding offset here
++ // which should allow for clipless offseting
++
++ pps->qp_dblk_x[0] = qp_c_dblk_0 + QP_DBLK_OFFSET_0; // No offset for luma, but may be useful for general code
++ pps->qp_bd_x[0] = qp_c_bd_0[sps->bit_depth - 8] + QP_OFFSET_0;
++
++ if (sps->chroma_format_idc == 1) {
++ pps->qp_dblk_x[1] = qp_c_dblk_1 + pps->cb_qp_offset + QP_DBLK_OFFSET_0;
++ pps->qp_bd_x[1] = qp_c_bd_1[sps->bit_depth - 8] + pps->cb_qp_offset + QP_OFFSET_0;
++ pps->qp_dblk_x[2] = qp_c_dblk_1 + pps->cr_qp_offset + QP_DBLK_OFFSET_0;
++ pps->qp_bd_x[2] = qp_c_bd_1[sps->bit_depth - 8] + pps->cr_qp_offset + QP_OFFSET_0;
++ }
++ else
++ {
++ pps->qp_dblk_x[1] = qp_c_dblk_0 + pps->cb_qp_offset + QP_DBLK_OFFSET_0;
++ pps->qp_bd_x[1] = qp_c_bd_0[sps->bit_depth - 8] + pps->cb_qp_offset + QP_OFFSET_0;
++ pps->qp_dblk_x[2] = qp_c_dblk_0 + pps->cr_qp_offset + QP_DBLK_OFFSET_0;
++ pps->qp_bd_x[2] = qp_c_bd_0[sps->bit_depth - 8] + pps->cr_qp_offset + QP_OFFSET_0;
++ }
++
++ pps->col_bd = av_malloc_array(pps->num_tile_columns + 1, sizeof(*pps->col_bd));
++ pps->row_bd = av_malloc_array(pps->num_tile_rows + 1, sizeof(*pps->row_bd));
++ pps->col_idxX = av_malloc_array(sps->ctb_width, sizeof(*pps->col_idxX));
++ if (!pps->col_bd || !pps->row_bd || !pps->col_idxX)
++ return AVERROR(ENOMEM);
++
++ if (pps->uniform_spacing_flag) {
++ if (!pps->column_width) {
++ pps->column_width = av_malloc_array(pps->num_tile_columns, sizeof(*pps->column_width));
++ pps->row_height = av_malloc_array(pps->num_tile_rows, sizeof(*pps->row_height));
++ }
++ if (!pps->column_width || !pps->row_height)
++ return AVERROR(ENOMEM);
++
++ for (i = 0; i < pps->num_tile_columns; i++) {
++ pps->column_width[i] = ((i + 1) * sps->ctb_width) / pps->num_tile_columns -
++ (i * sps->ctb_width) / pps->num_tile_columns;
++ }
++
++ for (i = 0; i < pps->num_tile_rows; i++) {
++ pps->row_height[i] = ((i + 1) * sps->ctb_height) / pps->num_tile_rows -
++ (i * sps->ctb_height) / pps->num_tile_rows;
++ }
++ }
++
++ {
++ const unsigned int td_mask = 63 >> (sps->log2_ctb_size + sps->pixel_shift);
++ pps->col_bd[0] = 0;
++ pps->tile_wpp_inter_disable = 0;
++ for (i = 0; i < pps->num_tile_columns; i++)
++ {
++ pps->col_bd[i + 1] = pps->col_bd[i] + pps->column_width[i];
++
++ // Avoid trying tile parallel if the columns don't fall on cache boundries
++ // (this causes too much pain syncing flushes with the QPU)
++ // Ignore the final (RHS of pic) tile boundry
++ if ((pps->col_bd[i] & td_mask) != 0) {
++ pps->tile_wpp_inter_disable = 1;
++ }
++ }
++
++ // If we can start the next row before finishing the first line of
++ // this one then we must wait at the end of the tile
++ // * if this happens a lot then there are better but more complicated
++ // conditions that we could apply
++ if (pps->tile_wpp_inter_disable) {
++ for (i = 0; i < pps->num_tile_rows; i++)
++ {
++ if (pps->row_height[i] <= RPI_MAX_JOBS) {
++ pps->tile_wpp_inter_disable = 2;
++ break;
++ }
++ }
++ }
++ }
++
++ pps->row_bd[0] = 0;
++ for (i = 0; i < pps->num_tile_rows; i++)
++ pps->row_bd[i + 1] = pps->row_bd[i] + pps->row_height[i];
++
++ for (i = 0, j = 0; i < sps->ctb_width; i++) {
++ if (i >= pps->col_bd[j + 1])
++ j++;
++ pps->col_idxX[i] = j;
++ }
++
++ /**
++ * 6.5
++ */
++ pic_area_in_ctbs = sps->ctb_size;
++
++ pps->ctb_addr_rs_to_ts = av_malloc_array(pic_area_in_ctbs, sizeof(*pps->ctb_addr_rs_to_ts));
++ pps->ctb_addr_ts_to_rs = av_malloc_array(pic_area_in_ctbs, sizeof(*pps->ctb_addr_ts_to_rs));
++ pps->tile_id = av_malloc_array(pic_area_in_ctbs, sizeof(*pps->tile_id));
++ pps->tile_size = av_malloc_array(pps->num_tile_columns * pps->num_tile_rows, sizeof(*pps->tile_size));
++ pps->tile_pos_ts = av_malloc_array(pps->num_tile_columns * pps->num_tile_rows, sizeof(*pps->tile_pos_ts));
++ pps->ctb_ts_flags = av_malloc_array(pic_area_in_ctbs, sizeof(*pps->ctb_ts_flags));
++ if (!pps->ctb_addr_rs_to_ts || !pps->ctb_addr_ts_to_rs ||
++ !pps->tile_id || pps->tile_pos_ts == NULL || pps->tile_size == NULL) {
++ return AVERROR(ENOMEM);
++ }
++
++ memset(pps->ctb_ts_flags, 0, pic_area_in_ctbs * sizeof(*pps->ctb_ts_flags));
++
++ for (ctb_addr_rs = 0; ctb_addr_rs < pic_area_in_ctbs; ctb_addr_rs++) {
++ int tb_x = ctb_addr_rs % sps->ctb_width;
++ int tb_y = ctb_addr_rs / sps->ctb_width;
++ int tile_x = 0;
++ int tile_y = 0;
++ int val = 0;
++
++ for (i = 0; i < pps->num_tile_columns; i++) {
++ if (tb_x < pps->col_bd[i + 1]) {
++ tile_x = i;
++ break;
++ }
++ }
++
++ for (i = 0; i < pps->num_tile_rows; i++) {
++ if (tb_y < pps->row_bd[i + 1]) {
++ tile_y = i;
++ break;
++ }
++ }
++
++ for (i = 0; i < tile_x; i++)
++ val += pps->row_height[tile_y] * pps->column_width[i];
++ for (i = 0; i < tile_y; i++)
++ val += sps->ctb_width * pps->row_height[i];
++
++ val += (tb_y - pps->row_bd[tile_y]) * pps->column_width[tile_x] +
++ tb_x - pps->col_bd[tile_x];
++
++ pps->ctb_addr_rs_to_ts[ctb_addr_rs] = val;
++ pps->ctb_addr_ts_to_rs[val] = ctb_addr_rs;
++ }
++
++ {
++ uint8_t * pflags = pps->ctb_ts_flags;
++ uint16_t * ptid = pps->tile_id;
++
++ for (j = 0, tile_id = 0; j < pps->num_tile_rows; j++)
++ {
++ for (i = 0; i < pps->num_tile_columns; i++, tile_id++)
++ {
++ const unsigned int tile_w = pps->column_width[i];
++
++ pflags[0] |= CTB_TS_FLAGS_CIREQ;
++
++ for (x = 0; x != tile_w; ++x) {
++ pflags[x] |= CTB_TS_FLAGS_TOT;
++ }
++
++ for (y = pps->row_bd[j]; y < pps->row_bd[j + 1]; y++)
++ {
++ pflags[0] |= CTB_TS_FLAGS_SOTL;
++
++ if (pps->entropy_coding_sync_enabled_flag)
++ {
++ if (pps->column_width[i] != 1)
++ pflags[1] |= CTB_TS_FLAGS_CSAVE;
++ else
++ pflags[0] |= CTB_TS_FLAGS_CIREQ;
++
++ if ((pflags[0] & CTB_TS_FLAGS_CIREQ) == 0)
++ pflags[0] |= CTB_TS_FLAGS_CLOAD;
++ }
++
++ for (x = 0; x != tile_w; ++x)
++ *ptid++ = tile_id;
++
++ pflags += tile_w;
++ pflags[-1] |= CTB_TS_FLAGS_EOTL;
++ if (i + 1 == pps->num_tile_columns)
++ pflags[-1] |= CTB_TS_FLAGS_EOL;
++ }
++
++ pflags[-1] |= CTB_TS_FLAGS_EOT;
++ }
++ }
++ }
++
++ {
++ unsigned int ts = 0;
++ for (j = 0; j < pps->num_tile_rows; j++)
++ for (i = 0; i < pps->num_tile_columns; i++)
++ {
++ const unsigned int size = pps->column_width[i] * pps->row_height[j];
++ pps->tile_size[j * pps->num_tile_columns + i] = size;
++ pps->tile_pos_ts[j * pps->num_tile_columns + i] = ts;
++ ts += size;
++ }
++ }
++
++ return 0;
++}
++
++int ff_hevc_rpi_decode_nal_pps(GetBitContext * const gb, AVCodecContext * const avctx,
++ HEVCRpiParamSets * const ps)
++{
++ const HEVCRpiSPS *sps = NULL;
++ int i, ret = 0;
++ unsigned int pps_id = 0;
++ ptrdiff_t nal_size;
++ unsigned log2_parallel_merge_level_minus2;
++
++ AVBufferRef *pps_buf;
++ HEVCRpiPPS *pps = av_mallocz(sizeof(*pps));
++
++ if (!pps)
++ return AVERROR(ENOMEM);
++
++ pps_buf = av_buffer_create((uint8_t *)pps, sizeof(*pps),
++ hevc_pps_free, NULL, 0);
++ if (!pps_buf) {
++ av_freep(&pps);
++ return AVERROR(ENOMEM);
++ }
++
++ av_log(avctx, AV_LOG_DEBUG, "Decoding PPS\n");
++
++ nal_size = gb->buffer_end - gb->buffer;
++ if (nal_size > sizeof(pps->data)) {
++ av_log(avctx, AV_LOG_WARNING, "Truncating likely oversized PPS "
++ "(%"PTRDIFF_SPECIFIER" > %"SIZE_SPECIFIER")\n",
++ nal_size, sizeof(pps->data));
++ pps->data_size = sizeof(pps->data);
++ } else {
++ pps->data_size = nal_size;
++ }
++ memcpy(pps->data, gb->buffer, pps->data_size);
++
++ // Default values
++ pps->loop_filter_across_tiles_enabled_flag = 1;
++ pps->num_tile_columns = 1;
++ pps->num_tile_rows = 1;
++ pps->uniform_spacing_flag = 1;
++ pps->disable_dbf = 0;
++ pps->beta_offset = 0;
++ pps->tc_offset = 0;
++ pps->log2_max_transform_skip_block_size = 2;
++
++ // Coded parameters
++ pps_id = get_ue_golomb_long(gb);
++ if (pps_id >= HEVC_MAX_PPS_COUNT) {
++ av_log(avctx, AV_LOG_ERROR, "PPS id out of range: %d\n", pps_id);
++ ret = AVERROR_INVALIDDATA;
++ goto err;
++ }
++ pps->sps_id = get_ue_golomb_long(gb);
++ if (pps->sps_id >= HEVC_MAX_SPS_COUNT) {
++ av_log(avctx, AV_LOG_ERROR, "SPS id out of range: %d\n", pps->sps_id);
++ ret = AVERROR_INVALIDDATA;
++ goto err;
++ }
++ if (!ps->sps_list[pps->sps_id]) {
++ av_log(avctx, AV_LOG_ERROR, "SPS %u does not exist.\n", pps->sps_id);
++ ret = AVERROR_INVALIDDATA;
++ goto err;
++ }
++ sps = (HEVCRpiSPS *)ps->sps_list[pps->sps_id]->data;
++
++ pps->dependent_slice_segments_enabled_flag = get_bits1(gb);
++ pps->output_flag_present_flag = get_bits1(gb);
++ pps->num_extra_slice_header_bits = get_bits(gb, 3);
++
++ pps->sign_data_hiding_flag = get_bits1(gb);
++
++ pps->cabac_init_present_flag = get_bits1(gb);
++
++ pps->num_ref_idx_l0_default_active = get_ue_golomb_long(gb) + 1;
++ if (pps->num_ref_idx_l0_default_active < 1 || pps->num_ref_idx_l0_default_active > 15) {
++ av_log(avctx, AV_LOG_ERROR, "pps->num_ref_idx_l0_default_active invalid\n");
++ ret = AVERROR_INVALIDDATA;
++ goto err;
++ }
++ pps->num_ref_idx_l1_default_active = get_ue_golomb_long(gb) + 1;
++ if (pps->num_ref_idx_l1_default_active < 1 || pps->num_ref_idx_l1_default_active > 15) {
++ av_log(avctx, AV_LOG_ERROR, "pps->num_ref_idx_l1_default_active invalid\n");
++ ret = AVERROR_INVALIDDATA;
++ goto err;
++ }
++
++ pps->pic_init_qp_minus26 = get_se_golomb(gb);
++ if (pps->pic_init_qp_minus26 > 25 || pps->pic_init_qp_minus26 < -(26 + sps->qp_bd_offset)) {
++ av_log(avctx, AV_LOG_ERROR,
++ "init_qp_minus26 %d is outside the valid range "
++ "[%d, %d].\n",
++ pps->pic_init_qp_minus26,
++ -(26 + sps->qp_bd_offset), 25);
++ ret = AVERROR_INVALIDDATA;
++ goto err;
++ }
++
++ pps->constrained_intra_pred_flag = get_bits1(gb);
++ pps->transform_skip_enabled_flag = get_bits1(gb);
++
++ pps->cu_qp_delta_enabled_flag = get_bits1(gb);
++ pps->log2_min_cu_qp_delta_size = sps->log2_ctb_size;
++ if (pps->cu_qp_delta_enabled_flag)
++ {
++ const unsigned int diff_cu_qp_delta_depth = get_ue_golomb_long(gb);
++
++ if (diff_cu_qp_delta_depth > sps->log2_diff_max_min_coding_block_size) {
++ av_log(avctx, AV_LOG_ERROR, "diff_cu_qp_delta_depth %d is invalid\n",
++ diff_cu_qp_delta_depth);
++ ret = AVERROR_INVALIDDATA;
++ goto err;
++ }
++
++ pps->log2_min_cu_qp_delta_size = sps->log2_ctb_size - diff_cu_qp_delta_depth;
++ }
++
++ pps->cb_qp_offset = get_se_golomb(gb);
++ if (pps->cb_qp_offset < -12 || pps->cb_qp_offset > 12) {
++ av_log(avctx, AV_LOG_ERROR, "pps_cb_qp_offset out of range: %d\n",
++ pps->cb_qp_offset);
++ ret = AVERROR_INVALIDDATA;
++ goto err;
++ }
++ pps->cr_qp_offset = get_se_golomb(gb);
++ if (pps->cr_qp_offset < -12 || pps->cr_qp_offset > 12) {
++ av_log(avctx, AV_LOG_ERROR, "pps_cr_qp_offset out of range: %d\n",
++ pps->cr_qp_offset);
++ ret = AVERROR_INVALIDDATA;
++ goto err;
++ }
++ pps->pic_slice_level_chroma_qp_offsets_present_flag = get_bits1(gb);
++
++ pps->weighted_pred_flag = get_bits1(gb);
++ pps->weighted_bipred_flag = get_bits1(gb);
++
++ pps->transquant_bypass_enable_flag = get_bits1(gb);
++ pps->tiles_enabled_flag = get_bits1(gb);
++ pps->entropy_coding_sync_enabled_flag = get_bits1(gb);
++
++ if (pps->tiles_enabled_flag) {
++ pps->num_tile_columns = get_ue_golomb_long(gb) + 1;
++ pps->num_tile_rows = get_ue_golomb_long(gb) + 1;
++ if (pps->num_tile_columns <= 0 ||
++ pps->num_tile_columns >= sps->width) {
++ av_log(avctx, AV_LOG_ERROR, "num_tile_columns_minus1 out of range: %d\n",
++ pps->num_tile_columns - 1);
++ ret = AVERROR_INVALIDDATA;
++ goto err;
++ }
++ if (pps->num_tile_rows <= 0 ||
++ pps->num_tile_rows >= sps->height) {
++ av_log(avctx, AV_LOG_ERROR, "num_tile_rows_minus1 out of range: %d\n",
++ pps->num_tile_rows - 1);
++ ret = AVERROR_INVALIDDATA;
++ goto err;
++ }
++
++ pps->column_width = av_malloc_array(pps->num_tile_columns, sizeof(*pps->column_width));
++ pps->row_height = av_malloc_array(pps->num_tile_rows, sizeof(*pps->row_height));
++ if (!pps->column_width || !pps->row_height) {
++ ret = AVERROR(ENOMEM);
++ goto err;
++ }
++
++ pps->uniform_spacing_flag = get_bits1(gb);
++ if (!pps->uniform_spacing_flag) {
++ uint64_t sum = 0;
++ for (i = 0; i < pps->num_tile_columns - 1; i++) {
++ pps->column_width[i] = get_ue_golomb_long(gb) + 1;
++ sum += pps->column_width[i];
++ }
++ if (sum >= sps->ctb_width) {
++ av_log(avctx, AV_LOG_ERROR, "Invalid tile widths.\n");
++ ret = AVERROR_INVALIDDATA;
++ goto err;
++ }
++ pps->column_width[pps->num_tile_columns - 1] = sps->ctb_width - sum;
++
++ sum = 0;
++ for (i = 0; i < pps->num_tile_rows - 1; i++) {
++ pps->row_height[i] = get_ue_golomb_long(gb) + 1;
++ sum += pps->row_height[i];
++ }
++ if (sum >= sps->ctb_height) {
++ av_log(avctx, AV_LOG_ERROR, "Invalid tile heights.\n");
++ ret = AVERROR_INVALIDDATA;
++ goto err;
++ }
++ pps->row_height[pps->num_tile_rows - 1] = sps->ctb_height - sum;
++ }
++ pps->loop_filter_across_tiles_enabled_flag = get_bits1(gb);
++ }
++
++ pps->seq_loop_filter_across_slices_enabled_flag = get_bits1(gb);
++
++ pps->deblocking_filter_control_present_flag = get_bits1(gb);
++ if (pps->deblocking_filter_control_present_flag) {
++ pps->deblocking_filter_override_enabled_flag = get_bits1(gb);
++ pps->disable_dbf = get_bits1(gb);
++ if (!pps->disable_dbf) {
++ int beta_offset_div2 = get_se_golomb(gb);
++ int tc_offset_div2 = get_se_golomb(gb) ;
++ if (beta_offset_div2 < -6 || beta_offset_div2 > 6) {
++ av_log(avctx, AV_LOG_ERROR, "pps_beta_offset_div2 out of range: %d\n",
++ beta_offset_div2);
++ ret = AVERROR_INVALIDDATA;
++ goto err;
++ }
++ if (tc_offset_div2 < -6 || tc_offset_div2 > 6) {
++ av_log(avctx, AV_LOG_ERROR, "pps_tc_offset_div2 out of range: %d\n",
++ tc_offset_div2);
++ ret = AVERROR_INVALIDDATA;
++ goto err;
++ }
++ pps->beta_offset = 2 * beta_offset_div2;
++ pps->tc_offset = 2 * tc_offset_div2;
++ }
++ }
++
++ pps->scaling_list_data_present_flag = get_bits1(gb);
++ if (pps->scaling_list_data_present_flag) {
++ set_default_scaling_list_data(&pps->scaling_list);
++ ret = scaling_list_data(gb, avctx, &pps->scaling_list, sps);
++ if (ret < 0)
++ goto err;
++ }
++ pps->lists_modification_present_flag = get_bits1(gb);
++ log2_parallel_merge_level_minus2 = get_ue_golomb_long(gb);
++ if (log2_parallel_merge_level_minus2 > sps->log2_ctb_size) {
++ av_log(avctx, AV_LOG_ERROR, "log2_parallel_merge_level_minus2 out of range: %d\n",
++ log2_parallel_merge_level_minus2);
++ ret = AVERROR_INVALIDDATA;
++ goto err;
++ }
++ pps->log2_parallel_merge_level = log2_parallel_merge_level_minus2 + 2;
++
++ pps->slice_header_extension_present_flag = get_bits1(gb);
++
++ if (get_bits1(gb)) { // pps_extension_present_flag
++ int pps_range_extensions_flag = get_bits1(gb);
++ /* int pps_extension_7bits = */ get_bits(gb, 7);
++ if (sps->ptl.general_ptl.profile_idc == FF_PROFILE_HEVC_REXT && pps_range_extensions_flag) {
++ if ((ret = pps_range_extensions(gb, avctx, pps, sps)) < 0)
++ goto err;
++ }
++ }
++
++ ret = setup_pps(avctx, pps, sps);
++ if (ret < 0)
++ goto err;
++
++ if (get_bits_left(gb) < 0) {
++ av_log(avctx, AV_LOG_ERROR,
++ "Overread PPS by %d bits\n", -get_bits_left(gb));
++ ret = AVERROR_INVALIDDATA;
++ goto err;
++ }
++
++ remove_pps(ps, pps_id);
++ ps->pps_list[pps_id] = pps_buf;
++
++ return 0;
++
++err:
++ av_buffer_unref(&pps_buf);
++ return ret;
++}
++
++int ff_hevc_rpi_compute_poc(const HEVCRpiSPS *sps, int pocTid0, int poc_lsb, int nal_unit_type)
++{
++ int max_poc_lsb = 1 << sps->log2_max_poc_lsb;
++ int prev_poc_lsb = pocTid0 % max_poc_lsb;
++ int prev_poc_msb = pocTid0 - prev_poc_lsb;
++ int poc_msb;
++
++ if (poc_lsb < prev_poc_lsb && prev_poc_lsb - poc_lsb >= max_poc_lsb / 2)
++ poc_msb = prev_poc_msb + max_poc_lsb;
++ else if (poc_lsb > prev_poc_lsb && poc_lsb - prev_poc_lsb > max_poc_lsb / 2)
++ poc_msb = prev_poc_msb - max_poc_lsb;
++ else
++ poc_msb = prev_poc_msb;
++
++ // For BLA picture types, POCmsb is set to 0.
++ if (nal_unit_type == HEVC_NAL_BLA_W_LP ||
++ nal_unit_type == HEVC_NAL_BLA_W_RADL ||
++ nal_unit_type == HEVC_NAL_BLA_N_LP)
++ poc_msb = 0;
++
++ return poc_msb + poc_lsb;
++}
+diff --git a/libavcodec/rpi_hevc_ps.h b/libavcodec/rpi_hevc_ps.h
+new file mode 100644
+index 0000000000..712464a075
+--- /dev/null
++++ b/libavcodec/rpi_hevc_ps.h
+@@ -0,0 +1,447 @@
++/*
++ * HEVC parameter set parsing
++ *
++ * This file is part of FFmpeg.
++ *
++ * FFmpeg is free software; you can redistribute it and/or
++ * modify it under the terms of the GNU Lesser General Public
++ * License as published by the Free Software Foundation; either
++ * version 2.1 of the License, or (at your option) any later version.
++ *
++ * FFmpeg is distributed in the hope that it will be useful,
++ * but WITHOUT ANY WARRANTY; without even the implied warranty of
++ * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
++ * Lesser General Public License for more details.
++ *
++ * You should have received a copy of the GNU Lesser General Public
++ * License along with FFmpeg; if not, write to the Free Software
++ * Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA
++ */
++
++#ifndef AVCODEC_RPI_HEVC_PS_H
++#define AVCODEC_RPI_HEVC_PS_H
++
++#include <stdint.h>
++
++#include "libavutil/buffer.h"
++#include "libavutil/pixfmt.h"
++#include "libavutil/rational.h"
++
++#include "avcodec.h"
++#include "get_bits.h"
++#include "hevc.h"
++
++typedef struct ShortTermRPS {
++ unsigned int num_negative_pics;
++ int num_delta_pocs;
++ int rps_idx_num_delta_pocs;
++ int32_t delta_poc[32];
++ uint8_t used[32];
++} ShortTermRPS;
++
++typedef struct LongTermRPS {
++ int poc[32];
++ uint8_t used[32];
++ uint8_t nb_refs;
++} LongTermRPS;
++
++typedef struct RpiSliceHeader {
++ unsigned int pps_id;
++
++ ///< address (in raster order) of the first block in the current slice segment
++ unsigned int slice_segment_addr;
++ ///< address (in raster order) of the first block in the current slice
++ unsigned int slice_addr;
++
++ enum HEVCSliceType slice_type;
++
++ int pic_order_cnt_lsb;
++
++ uint8_t first_slice_in_pic_flag;
++ uint8_t dependent_slice_segment_flag;
++ uint8_t pic_output_flag;
++ uint8_t colour_plane_id;
++
++ ///< RPS coded in the slice header itself is stored here
++ int short_term_ref_pic_set_sps_flag;
++ int short_term_ref_pic_set_size;
++ ShortTermRPS slice_rps;
++ const ShortTermRPS *short_term_rps;
++ int long_term_ref_pic_set_size;
++ LongTermRPS long_term_rps;
++ unsigned int list_entry_lx[2][32];
++
++ uint8_t rpl_modification_flag[2];
++ uint8_t no_output_of_prior_pics_flag;
++ uint8_t slice_temporal_mvp_enabled_flag;
++
++ unsigned int nb_refs[2];
++
++ uint8_t slice_sample_adaptive_offset_flag[3];
++ uint8_t mvd_l1_zero_flag;
++
++ uint8_t cabac_init_flag;
++ uint8_t disable_deblocking_filter_flag; ///< slice_header_disable_deblocking_filter_flag
++ uint8_t slice_loop_filter_across_slices_enabled_flag;
++ uint8_t collocated_list;
++
++ uint8_t no_dblk_boundary_flags;
++
++ unsigned int collocated_ref_idx;
++
++ int slice_qp_delta;
++ int slice_cb_qp_offset; // -12, +12
++ int slice_cr_qp_offset; // -12, +12
++
++ uint8_t cu_chroma_qp_offset_enabled_flag;
++
++ int beta_offset; ///< beta_offset_div2 * 2
++ int tc_offset; ///< tc_offset_div2 * 2
++
++ unsigned int max_num_merge_cand; ///< 5 - 5_minus_max_num_merge_cand
++
++ unsigned *entry_point_offset;
++ int * offset;
++ int * size;
++ int num_entry_point_offsets;
++ int offsets_allocated;
++
++ uint8_t offload_wpp;
++ uint8_t offload_tiles;
++
++ int8_t slice_qp;
++
++ uint8_t luma_log2_weight_denom;
++ uint8_t chroma_log2_weight_denom;
++
++ int16_t luma_weight_l0[16]; // -128, +255
++ int16_t luma_offset_l0[16];
++ int16_t chroma_weight_l0[16][2];
++ int16_t chroma_offset_l0[16][2];
++
++ int16_t luma_weight_l1[16];
++ int16_t luma_offset_l1[16];
++ int16_t chroma_weight_l1[16][2];
++ int16_t chroma_offset_l1[16][2];
++
++} RpiSliceHeader;
++
++typedef struct HEVCRpiWindow {
++ uint16_t left_offset;
++ uint16_t right_offset;
++ uint16_t top_offset;
++ uint16_t bottom_offset;
++} HEVCRpiWindow;
++
++typedef struct VUI {
++ AVRational sar;
++
++ int overscan_info_present_flag;
++ int overscan_appropriate_flag;
++
++ int video_signal_type_present_flag;
++ int video_format;
++ int video_full_range_flag;
++ int colour_description_present_flag;
++ uint8_t colour_primaries;
++ uint8_t transfer_characteristic;
++ uint8_t matrix_coeffs;
++
++ int chroma_loc_info_present_flag;
++ int chroma_sample_loc_type_top_field;
++ int chroma_sample_loc_type_bottom_field;
++ int neutra_chroma_indication_flag;
++
++ int field_seq_flag;
++ int frame_field_info_present_flag;
++
++ int default_display_window_flag;
++ HEVCRpiWindow def_disp_win;
++
++ int vui_timing_info_present_flag;
++ uint32_t vui_num_units_in_tick;
++ uint32_t vui_time_scale;
++ int vui_poc_proportional_to_timing_flag;
++ int vui_num_ticks_poc_diff_one_minus1;
++ int vui_hrd_parameters_present_flag;
++
++ int bitstream_restriction_flag;
++ int tiles_fixed_structure_flag;
++ int motion_vectors_over_pic_boundaries_flag;
++ int restricted_ref_pic_lists_flag;
++ int min_spatial_segmentation_idc;
++ int max_bytes_per_pic_denom;
++ int max_bits_per_min_cu_denom;
++ int log2_max_mv_length_horizontal;
++ int log2_max_mv_length_vertical;
++} VUI;
++
++typedef struct PTLCommon {
++ uint8_t profile_space;
++ uint8_t tier_flag;
++ uint8_t profile_idc;
++ uint8_t profile_compatibility_flag[32];
++ uint8_t level_idc;
++ uint8_t progressive_source_flag;
++ uint8_t interlaced_source_flag;
++ uint8_t non_packed_constraint_flag;
++ uint8_t frame_only_constraint_flag;
++} PTLCommon;
++
++typedef struct PTL {
++ PTLCommon general_ptl;
++ PTLCommon sub_layer_ptl[HEVC_MAX_SUB_LAYERS];
++
++ uint8_t sub_layer_profile_present_flag[HEVC_MAX_SUB_LAYERS];
++ uint8_t sub_layer_level_present_flag[HEVC_MAX_SUB_LAYERS];
++} PTL;
++
++typedef struct HEVCRpiVPS {
++ uint8_t vps_temporal_id_nesting_flag;
++ int vps_max_layers;
++ int vps_max_sub_layers; ///< vps_max_temporal_layers_minus1 + 1
++
++ PTL ptl;
++ int vps_sub_layer_ordering_info_present_flag;
++ unsigned int vps_max_dec_pic_buffering[HEVC_MAX_SUB_LAYERS];
++ unsigned int vps_num_reorder_pics[HEVC_MAX_SUB_LAYERS];
++ unsigned int vps_max_latency_increase[HEVC_MAX_SUB_LAYERS];
++ int vps_max_layer_id;
++ int vps_num_layer_sets; ///< vps_num_layer_sets_minus1 + 1
++ uint8_t vps_timing_info_present_flag;
++ uint32_t vps_num_units_in_tick;
++ uint32_t vps_time_scale;
++ uint8_t vps_poc_proportional_to_timing_flag;
++ int vps_num_ticks_poc_diff_one; ///< vps_num_ticks_poc_diff_one_minus1 + 1
++ int vps_num_hrd_parameters;
++
++ uint8_t data[4096];
++ int data_size;
++} HEVCRpiVPS;
++
++typedef struct ScalingList {
++ /* This is a little wasteful, since sizeID 0 only needs 8 coeffs,
++ * and size ID 3 only has 2 arrays, not 6. */
++ uint8_t sl[4][6][64];
++ uint8_t sl_dc[2][6];
++} ScalingList;
++
++typedef struct HEVCRpiSPS {
++ unsigned vps_id;
++ uint8_t chroma_format_idc;
++ uint8_t separate_colour_plane_flag;
++
++ HEVCRpiWindow output_window;
++
++ HEVCRpiWindow pic_conf_win;
++
++ uint16_t wp_offset_half_range; // WpOffsetHalfRange
++
++ uint8_t bit_depth;
++
++// int bit_depth_chroma; // We only support lum_bit_depth = chroma_bit_depth
++ uint8_t pixel_shift;
++ enum AVPixelFormat pix_fmt;
++
++ unsigned int log2_max_poc_lsb;
++
++ int max_sub_layers;
++ struct {
++ int max_dec_pic_buffering;
++ int num_reorder_pics;
++ int max_latency_increase;
++ } temporal_layer[HEVC_MAX_SUB_LAYERS];
++ uint8_t temporal_id_nesting_flag;
++
++ uint8_t scaling_list_enable_flag;
++ ScalingList scaling_list;
++
++ unsigned int nb_st_rps;
++ ShortTermRPS st_rps[HEVC_MAX_SHORT_TERM_REF_PIC_SETS];
++
++ uint8_t amp_enabled_flag;
++ uint8_t sao_enabled;
++
++ uint8_t long_term_ref_pics_present_flag;
++ uint16_t lt_ref_pic_poc_lsb_sps[HEVC_MAX_LONG_TERM_REF_PICS];
++ uint8_t used_by_curr_pic_lt_sps_flag[HEVC_MAX_LONG_TERM_REF_PICS];
++ uint8_t num_long_term_ref_pics_sps;
++
++ struct {
++ uint8_t bit_depth;
++ uint8_t bit_depth_chroma;
++ uint8_t log2_min_pcm_cb_size;
++ uint8_t log2_max_pcm_cb_size;
++ uint8_t loop_filter_disable_flag;
++ } pcm;
++ uint8_t sps_temporal_mvp_enabled_flag;
++ uint8_t sps_strong_intra_smoothing_enable_flag;
++
++ unsigned int log2_min_cb_size; // 3..6
++ unsigned int log2_diff_max_min_coding_block_size;
++ unsigned int log2_min_tb_size; // 2..5
++ unsigned int log2_max_trafo_size;
++ unsigned int log2_ctb_size; // 4..6
++// unsigned int log2_min_pu_size; // 2..5 (min_cb_size - 1)
++#define LOG2_MIN_PU_SIZE 2
++#define LOG2_MIN_CU_SIZE 3
++
++ int max_transform_hierarchy_depth_inter;
++ int max_transform_hierarchy_depth_intra;
++
++ int transform_skip_rotation_enabled_flag;
++ int transform_skip_context_enabled_flag;
++ int implicit_rdpcm_enabled_flag;
++ int explicit_rdpcm_enabled_flag;
++ int intra_smoothing_disabled_flag;
++ int high_precision_offsets_enabled_flag;
++ int persistent_rice_adaptation_enabled_flag;
++
++ ///< coded frame dimension in various units
++ int width;
++ int height;
++ int ctb_width;
++ int ctb_height;
++ int ctb_size; // Pic size in CTBs not size of a CTB
++ int min_cb_width;
++ int min_cb_height;
++ int min_tb_width;
++ int min_tb_height;
++ int min_pu_width;
++ int min_pu_height;
++ int pcm_width;
++ int pcm_height;
++ int tb_mask;
++
++ int hshift[3];
++ int vshift[3];
++
++ int qp_bd_offset;
++
++ uint8_t data[4096];
++ int data_size;
++
++ VUI vui;
++ PTL ptl;
++} HEVCRpiSPS;
++
++#define CTB_TS_FLAGS_SOTL (1U << 0) // X start of tile line
++#define CTB_TS_FLAGS_EOTL (1U << 1) // Last CTB of a tile line
++#define CTB_TS_FLAGS_EOL (1U << 2) // Last CTB of a complete line
++#define CTB_TS_FLAGS_EOT (1U << 3) // Last CTB of a tile
++#define CTB_TS_FLAGS_CSAVE (1U << 4)
++#define CTB_TS_FLAGS_CIREQ (1U << 5) // Cabac init request
++#define CTB_TS_FLAGS_TOT (1U << 6) // CTB on top row of a tile
++#define CTB_TS_FLAGS_CLOAD (1U << 7)
++
++typedef struct HEVCRpiPPS {
++ unsigned int sps_id; ///< seq_parameter_set_id
++
++ uint8_t sign_data_hiding_flag;
++
++ uint8_t cabac_init_present_flag;
++
++ int num_ref_idx_l0_default_active; ///< num_ref_idx_l0_default_active_minus1 + 1
++ int num_ref_idx_l1_default_active; ///< num_ref_idx_l1_default_active_minus1 + 1
++ int pic_init_qp_minus26;
++
++ uint8_t constrained_intra_pred_flag;
++ uint8_t transform_skip_enabled_flag;
++
++ uint8_t cu_qp_delta_enabled_flag;
++ uint8_t log2_min_cu_qp_delta_size;
++ int cb_qp_offset; // -12..12
++ int cr_qp_offset; // -12..12
++ const uint8_t * qp_dblk_x[3];
++ const int8_t * qp_bd_x[3];
++
++ uint8_t pic_slice_level_chroma_qp_offsets_present_flag;
++ uint8_t weighted_pred_flag;
++ uint8_t weighted_bipred_flag;
++ uint8_t output_flag_present_flag;
++ uint8_t transquant_bypass_enable_flag;
++
++ uint8_t dependent_slice_segments_enabled_flag;
++ uint8_t tiles_enabled_flag;
++ uint8_t entropy_coding_sync_enabled_flag;
++
++ uint8_t tile_wpp_inter_disable;
++ int num_tile_columns; ///< num_tile_columns_minus1 + 1
++ int num_tile_rows; ///< num_tile_rows_minus1 + 1
++ uint8_t uniform_spacing_flag;
++ uint8_t loop_filter_across_tiles_enabled_flag;
++
++ uint8_t seq_loop_filter_across_slices_enabled_flag;
++
++ uint8_t deblocking_filter_control_present_flag;
++ uint8_t deblocking_filter_override_enabled_flag;
++ uint8_t disable_dbf;
++ int beta_offset; ///< beta_offset_div2 * 2
++ int tc_offset; ///< tc_offset_div2 * 2
++
++ uint8_t scaling_list_data_present_flag;
++ ScalingList scaling_list;
++
++ uint8_t lists_modification_present_flag;
++ int log2_parallel_merge_level; ///< log2_parallel_merge_level_minus2 + 2
++ int num_extra_slice_header_bits;
++ uint8_t slice_header_extension_present_flag;
++ uint8_t log2_max_transform_skip_block_size;
++ uint8_t cross_component_prediction_enabled_flag;
++ uint8_t chroma_qp_offset_list_enabled_flag;
++ uint8_t diff_cu_chroma_qp_offset_depth;
++ uint8_t chroma_qp_offset_list_len_minus1;
++ int8_t cb_qp_offset_list[6];
++ int8_t cr_qp_offset_list[6];
++ uint8_t log2_sao_offset_scale_luma;
++ uint8_t log2_sao_offset_scale_chroma;
++
++ // Inferred parameters
++ uint16_t *column_width; ///< ColumnWidth
++ uint16_t *row_height; ///< RowHeight
++ uint16_t *col_bd; ///< ColBd
++ uint16_t *row_bd; ///< RowBd
++ uint16_t *col_idxX;
++
++ // We can limit these to uint16_t given our other size limits
++ uint16_t *ctb_addr_rs_to_ts; ///< CtbAddrRSToTS
++ uint16_t *ctb_addr_ts_to_rs; ///< CtbAddrTSToRS
++ uint16_t *tile_id; ///< TileId
++ uint16_t *tile_pos_ts; ///< TilePosRS
++ uint16_t *tile_size; ///< TileSize
++ uint8_t * ctb_ts_flags;
++
++ uint8_t data[4096];
++ int data_size;
++} HEVCRpiPPS;
++
++typedef struct HEVCRpiParamSets {
++ /* currently active parameter sets */
++ const HEVCRpiVPS *vps;
++ const HEVCRpiSPS *sps;
++ const HEVCRpiPPS *pps;
++
++ AVBufferRef *vps_list[HEVC_MAX_VPS_COUNT];
++ AVBufferRef *sps_list[HEVC_MAX_SPS_COUNT];
++ AVBufferRef *pps_list[HEVC_MAX_PPS_COUNT];
++} HEVCRpiParamSets;
++
++int ff_hevc_rpi_decode_nal_vps(GetBitContext *gb, AVCodecContext *avctx,
++ HEVCRpiParamSets *ps);
++int ff_hevc_rpi_decode_nal_sps(GetBitContext *gb, AVCodecContext *avctx,
++ HEVCRpiParamSets *ps, int apply_defdispwin);
++int ff_hevc_rpi_decode_nal_pps(GetBitContext *gb, AVCodecContext *avctx,
++ HEVCRpiParamSets *ps);
++
++int ff_hevc_rpi_decode_short_term_rps(GetBitContext *gb, AVCodecContext *avctx,
++ ShortTermRPS *rps, const HEVCRpiSPS *sps, int is_slice_header);
++
++int ff_hevc_rpi_encode_nal_vps(HEVCRpiVPS *vps, unsigned int id,
++ uint8_t *buf, int buf_size);
++
++/**
++ * Compute POC of the current frame and return it.
++ */
++int ff_hevc_rpi_compute_poc(const HEVCRpiSPS *sps, int pocTid0, int poc_lsb, int nal_unit_type);
++
++#endif /* AVCODEC_RPI_HEVC_PS_H */
+diff --git a/libavcodec/rpi_hevc_refs.c b/libavcodec/rpi_hevc_refs.c
+new file mode 100644
+index 0000000000..8cc5796cf0
+--- /dev/null
++++ b/libavcodec/rpi_hevc_refs.c
+@@ -0,0 +1,485 @@
++/*
++ * HEVC video decoder
++ *
++ * Copyright (C) 2012 - 2013 Guillaume Martres
++ * Copyright (C) 2012 - 2013 Gildas Cocherel
++ *
++ * This file is part of FFmpeg.
++ *
++ * FFmpeg is free software; you can redistribute it and/or
++ * modify it under the terms of the GNU Lesser General Public
++ * License as published by the Free Software Foundation; either
++ * version 2.1 of the License, or (at your option) any later version.
++ *
++ * FFmpeg is distributed in the hope that it will be useful,
++ * but WITHOUT ANY WARRANTY; without even the implied warranty of
++ * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
++ * Lesser General Public License for more details.
++ *
++ * You should have received a copy of the GNU Lesser General Public
++ * License along with FFmpeg; if not, write to the Free Software
++ * Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA
++ */
++
++#include "libavutil/avassert.h"
++#include "libavutil/pixdesc.h"
++#include "libavutil/rpi_sand_fns.h"
++#include "internal.h"
++#include "thread.h"
++#include "hevc.h"
++#include "rpi_hevcdec.h"
++
++void ff_hevc_rpi_unref_frame(HEVCRpiContext *s, HEVCRpiFrame *frame, int flags)
++{
++ /* frame->frame can be NULL if context init failed */
++ if (!frame->frame || !frame->frame->buf[0])
++ return;
++
++ frame->flags &= ~flags;
++ if (!frame->flags) {
++ ff_thread_release_buffer(s->avctx, &frame->tf);
++
++ av_buffer_unref(&frame->col_mvf_buf); // OK if already NULL
++ frame->col_mvf = NULL;
++
++ frame->collocated_ref = NULL;
++ }
++}
++
++void ff_hevc_rpi_clear_refs(HEVCRpiContext *s)
++{
++ int i;
++ for (i = 0; i < FF_ARRAY_ELEMS(s->DPB); i++)
++ ff_hevc_rpi_unref_frame(s, &s->DPB[i],
++ HEVC_FRAME_FLAG_SHORT_REF |
++ HEVC_FRAME_FLAG_LONG_REF);
++}
++
++void ff_hevc_rpi_flush_dpb(HEVCRpiContext *s)
++{
++ int i;
++ for (i = 0; i < FF_ARRAY_ELEMS(s->DPB); i++)
++ ff_hevc_rpi_unref_frame(s, &s->DPB[i], ~0);
++}
++
++static HEVCRpiFrame *alloc_frame(HEVCRpiContext * const s)
++{
++ int i, ret;
++ for (i = 0; i < FF_ARRAY_ELEMS(s->DPB); i++) {
++ HEVCRpiFrame * const frame = &s->DPB[i];
++ if (frame->frame->buf[0])
++ continue;
++
++ ret = ff_thread_get_buffer(s->avctx, &frame->tf,
++ AV_GET_BUFFER_FLAG_REF);
++ if (ret < 0)
++ return NULL;
++
++ frame->col_mvf = NULL;
++ frame->col_mvf_buf = NULL;
++ if (s->used_for_ref && !s->is_irap)
++ {
++ frame->col_mvf_buf = av_buffer_pool_get(s->col_mvf_pool);
++ if (!frame->col_mvf_buf)
++ goto fail;
++ frame->col_mvf = (ColMvField *)frame->col_mvf_buf->data;
++ }
++
++ frame->frame->top_field_first = s->sei.picture_timing.picture_struct == AV_PICTURE_STRUCTURE_TOP_FIELD;
++ frame->frame->interlaced_frame = (s->sei.picture_timing.picture_struct == AV_PICTURE_STRUCTURE_TOP_FIELD) || (s->sei.picture_timing.picture_struct == AV_PICTURE_STRUCTURE_BOTTOM_FIELD);
++
++ return frame;
++
++fail:
++ ff_hevc_rpi_unref_frame(s, frame, ~0);
++ return NULL;
++ }
++ av_log(s->avctx, AV_LOG_ERROR, "Error allocating frame, DPB full.\n");
++ return NULL;
++}
++
++int ff_hevc_rpi_set_new_ref(HEVCRpiContext *s, AVFrame **frame, int poc)
++{
++ HEVCRpiFrame *ref;
++ int i;
++
++ /* check that this POC doesn't already exist */
++ for (i = 0; i < FF_ARRAY_ELEMS(s->DPB); i++) {
++ HEVCRpiFrame *frame = &s->DPB[i];
++
++ if (frame->frame->buf[0] && frame->sequence == s->seq_decode &&
++ frame->poc == poc) {
++ av_log(s->avctx, AV_LOG_ERROR, "Duplicate POC in a sequence: %d.\n",
++ poc);
++ return AVERROR_INVALIDDATA;
++ }
++ }
++
++ ref = alloc_frame(s);
++ if (!ref)
++ return AVERROR(ENOMEM);
++
++ *frame = ref->frame;
++ s->ref = ref;
++
++ if (s->sh.pic_output_flag)
++ ref->flags = HEVC_FRAME_FLAG_OUTPUT | HEVC_FRAME_FLAG_SHORT_REF;
++ else
++ ref->flags = HEVC_FRAME_FLAG_SHORT_REF;
++
++ ref->poc = poc;
++ ref->sequence = s->seq_decode;
++ ref->frame->crop_left = s->ps.sps->output_window.left_offset;
++ ref->frame->crop_right = s->ps.sps->output_window.right_offset;
++ ref->frame->crop_top = s->ps.sps->output_window.top_offset;
++ ref->frame->crop_bottom = s->ps.sps->output_window.bottom_offset;
++
++ return 0;
++}
++
++int ff_hevc_rpi_output_frame(HEVCRpiContext *s, AVFrame *out, int flush)
++{
++ do {
++ int nb_output = 0;
++ int min_poc = INT_MAX;
++ int i, min_idx, ret;
++
++ if (s->sh.no_output_of_prior_pics_flag == 1 && s->no_rasl_output_flag == 1) {
++ for (i = 0; i < FF_ARRAY_ELEMS(s->DPB); i++) {
++ HEVCRpiFrame *frame = &s->DPB[i];
++ if (!(frame->flags & HEVC_FRAME_FLAG_BUMPING) && frame->poc != s->poc &&
++ frame->sequence == s->seq_output) {
++ ff_hevc_rpi_unref_frame(s, frame, HEVC_FRAME_FLAG_OUTPUT);
++ }
++ }
++ }
++
++ for (i = 0; i < FF_ARRAY_ELEMS(s->DPB); i++) {
++ HEVCRpiFrame *frame = &s->DPB[i];
++ if ((frame->flags & HEVC_FRAME_FLAG_OUTPUT) &&
++ frame->sequence == s->seq_output) {
++ nb_output++;
++ if (frame->poc < min_poc || nb_output == 1) {
++ min_poc = frame->poc;
++ min_idx = i;
++ }
++ }
++ }
++
++ /* wait for more frames before output */
++ if (!flush && s->seq_output == s->seq_decode && s->ps.sps &&
++ nb_output <= s->ps.sps->temporal_layer[s->ps.sps->max_sub_layers - 1].num_reorder_pics)
++ return 0;
++
++ if (nb_output) {
++ HEVCRpiFrame *frame = &s->DPB[min_idx];
++ if (frame->frame->format == AV_PIX_FMT_VIDEOTOOLBOX && frame->frame->buf[0]->size == 1)
++ return 0;
++
++ ret = av_frame_ref(out, frame->frame);
++ if (frame->flags & HEVC_FRAME_FLAG_BUMPING)
++ ff_hevc_rpi_unref_frame(s, frame, HEVC_FRAME_FLAG_OUTPUT | HEVC_FRAME_FLAG_BUMPING);
++ else
++ ff_hevc_rpi_unref_frame(s, frame, HEVC_FRAME_FLAG_OUTPUT);
++ if (ret < 0)
++ return ret;
++ av_log(s->avctx, AV_LOG_DEBUG,
++ "Output frame with POC %d.\n", frame->poc);
++ return 1;
++ }
++
++ if (s->seq_output != s->seq_decode)
++ s->seq_output = (s->seq_output + 1) & 0xff;
++ else
++ break;
++ } while (1);
++
++ return 0;
++}
++
++void ff_hevc_rpi_bump_frame(HEVCRpiContext *s)
++{
++ int dpb = 0;
++ int min_poc = INT_MAX;
++ int i;
++
++ for (i = 0; i < FF_ARRAY_ELEMS(s->DPB); i++) {
++ HEVCRpiFrame *frame = &s->DPB[i];
++ if ((frame->flags) &&
++ frame->sequence == s->seq_output &&
++ frame->poc != s->poc) {
++ dpb++;
++ }
++ }
++
++ if (s->ps.sps && dpb >= s->ps.sps->temporal_layer[s->ps.sps->max_sub_layers - 1].max_dec_pic_buffering) {
++ for (i = 0; i < FF_ARRAY_ELEMS(s->DPB); i++) {
++ HEVCRpiFrame *frame = &s->DPB[i];
++ if ((frame->flags) &&
++ frame->sequence == s->seq_output &&
++ frame->poc != s->poc) {
++ if (frame->flags == HEVC_FRAME_FLAG_OUTPUT && frame->poc < min_poc) {
++ min_poc = frame->poc;
++ }
++ }
++ }
++
++ for (i = 0; i < FF_ARRAY_ELEMS(s->DPB); i++) {
++ HEVCRpiFrame *frame = &s->DPB[i];
++ if (frame->flags & HEVC_FRAME_FLAG_OUTPUT &&
++ frame->sequence == s->seq_output &&
++ frame->poc <= min_poc) {
++ frame->flags |= HEVC_FRAME_FLAG_BUMPING;
++ }
++ }
++
++ dpb--;
++ }
++}
++
++static int init_slice_rpl(HEVCRpiContext *s)
++{
++ if (s->slice_idx >= s->rpl_tab_size)
++ return AVERROR_INVALIDDATA;
++
++ s->refPicList = s->rpl_tab[s->slice_idx].refPicList + 0;
++ return 0;
++}
++
++int ff_hevc_rpi_slice_rpl(HEVCRpiContext *s)
++{
++ RpiSliceHeader *sh = &s->sh;
++
++ uint8_t nb_list = sh->slice_type == HEVC_SLICE_B ? 2 : 1;
++ uint8_t list_idx;
++ int i, j, ret;
++
++ ret = init_slice_rpl(s);
++ if (ret < 0)
++ return ret;
++
++ if (!(s->rps[ST_CURR_BEF].nb_refs + s->rps[ST_CURR_AFT].nb_refs +
++ s->rps[LT_CURR].nb_refs)) {
++ av_log(s->avctx, AV_LOG_ERROR, "Zero refs in the frame RPS.\n");
++ return AVERROR_INVALIDDATA;
++ }
++
++ for (list_idx = 0; list_idx < nb_list; list_idx++) {
++ RefPicList rpl_tmp = { { 0 } };
++ RefPicList *rpl = &s->refPicList[list_idx];
++
++ /* The order of the elements is
++ * ST_CURR_BEF - ST_CURR_AFT - LT_CURR for the L0 and
++ * ST_CURR_AFT - ST_CURR_BEF - LT_CURR for the L1 */
++ int cand_lists[3] = { list_idx ? ST_CURR_AFT : ST_CURR_BEF,
++ list_idx ? ST_CURR_BEF : ST_CURR_AFT,
++ LT_CURR };
++
++ /* concatenate the candidate lists for the current frame */
++ while (rpl_tmp.nb_refs < sh->nb_refs[list_idx]) {
++ for (i = 0; i < FF_ARRAY_ELEMS(cand_lists); i++) {
++ RefPicList *rps = &s->rps[cand_lists[i]];
++ for (j = 0; j < rps->nb_refs && rpl_tmp.nb_refs < HEVC_MAX_REFS; j++) {
++ rpl_tmp.list[rpl_tmp.nb_refs] = rps->list[j];
++ rpl_tmp.ref[rpl_tmp.nb_refs] = rps->ref[j];
++ rpl_tmp.isLongTerm[rpl_tmp.nb_refs] = i == 2;
++ rpl_tmp.nb_refs++;
++ }
++ }
++ }
++
++ /* reorder the references if necessary */
++ if (sh->rpl_modification_flag[list_idx]) {
++ for (i = 0; i < sh->nb_refs[list_idx]; i++) {
++ int idx = sh->list_entry_lx[list_idx][i];
++
++ if (idx >= rpl_tmp.nb_refs) {
++ av_log(s->avctx, AV_LOG_ERROR, "Invalid reference index.\n");
++ return AVERROR_INVALIDDATA;
++ }
++
++ rpl->list[i] = rpl_tmp.list[idx];
++ rpl->ref[i] = rpl_tmp.ref[idx];
++ rpl->isLongTerm[i] = rpl_tmp.isLongTerm[idx];
++ rpl->nb_refs++;
++ }
++ } else {
++ memcpy(rpl, &rpl_tmp, sizeof(*rpl));
++ rpl->nb_refs = FFMIN(rpl->nb_refs, sh->nb_refs[list_idx]);
++ }
++
++ if (sh->collocated_list == list_idx &&
++ sh->collocated_ref_idx < rpl->nb_refs)
++ s->ref->collocated_ref = rpl->ref[sh->collocated_ref_idx];
++ }
++
++ return 0;
++}
++
++static HEVCRpiFrame *find_ref_idx(HEVCRpiContext *s, int poc)
++{
++ int i;
++ int LtMask = (1 << s->ps.sps->log2_max_poc_lsb) - 1;
++
++ for (i = 0; i < FF_ARRAY_ELEMS(s->DPB); i++) {
++ HEVCRpiFrame *ref = &s->DPB[i];
++ if (ref->frame->buf[0] && (ref->sequence == s->seq_decode)) {
++ if ((ref->poc & LtMask) == poc)
++ return ref;
++ }
++ }
++
++ for (i = 0; i < FF_ARRAY_ELEMS(s->DPB); i++) {
++ HEVCRpiFrame *ref = &s->DPB[i];
++ if (ref->frame->buf[0] && ref->sequence == s->seq_decode) {
++ if (ref->poc == poc || (ref->poc & LtMask) == poc)
++ return ref;
++ }
++ }
++
++ if (s->nal_unit_type != HEVC_NAL_CRA_NUT && !IS_BLA(s))
++ av_log(s->avctx, AV_LOG_ERROR,
++ "Could not find ref with POC %d\n", poc);
++ return NULL;
++}
++
++static void mark_ref(HEVCRpiFrame *frame, int flag)
++{
++ frame->flags &= ~(HEVC_FRAME_FLAG_LONG_REF | HEVC_FRAME_FLAG_SHORT_REF);
++ frame->flags |= flag;
++}
++
++static HEVCRpiFrame *generate_missing_ref(HEVCRpiContext *s, int poc)
++{
++ HEVCRpiFrame *frame;
++ int i, x, y;
++
++ frame = alloc_frame(s);
++ if (!frame)
++ return NULL;
++
++ if (!s->ps.sps->pixel_shift) {
++ for (i = 0; frame->frame->buf[i]; i++)
++ memset(frame->frame->buf[i]->data, 1 << (s->ps.sps->bit_depth - 1),
++ frame->frame->buf[i]->size);
++ } else {
++ for (i = 0; frame->frame->data[i]; i++)
++ for (y = 0; y < (s->ps.sps->height >> s->ps.sps->vshift[i]); y++)
++ for (x = 0; x < (s->ps.sps->width >> s->ps.sps->hshift[i]); x++) {
++ AV_WN16(frame->frame->data[i] + y * frame_stride1(frame->frame, 1) + 2 * x,
++ 1 << (s->ps.sps->bit_depth - 1));
++ }
++ }
++
++ frame->poc = poc;
++ frame->sequence = s->seq_decode;
++ frame->flags = 0;
++
++ ff_hevc_rpi_progress_set_all_done(frame);
++
++ return frame;
++}
++
++/* add a reference with the given poc to the list and mark it as used in DPB */
++static int add_candidate_ref(HEVCRpiContext *s, RefPicList *list,
++ int poc, int ref_flag)
++{
++ HEVCRpiFrame *ref = find_ref_idx(s, poc);
++
++ if (ref == s->ref || list->nb_refs >= HEVC_MAX_REFS)
++ return AVERROR_INVALIDDATA;
++
++ if (!ref) {
++ ref = generate_missing_ref(s, poc);
++ if (!ref)
++ return AVERROR(ENOMEM);
++ }
++
++ list->list[list->nb_refs] = ref->poc;
++ list->ref[list->nb_refs] = ref;
++ list->nb_refs++;
++
++ mark_ref(ref, ref_flag);
++ return 0;
++}
++
++int ff_hevc_rpi_frame_rps(HEVCRpiContext *s)
++{
++ const ShortTermRPS *short_rps = s->sh.short_term_rps;
++ const LongTermRPS *long_rps = &s->sh.long_term_rps;
++ RefPicList *rps = s->rps;
++ int i, ret = 0;
++
++ if (!short_rps) {
++ rps[0].nb_refs = rps[1].nb_refs = 0;
++ return 0;
++ }
++
++ /* clear the reference flags on all frames except the current one */
++ for (i = 0; i < FF_ARRAY_ELEMS(s->DPB); i++) {
++ HEVCRpiFrame *frame = &s->DPB[i];
++
++ if (frame == s->ref)
++ continue;
++
++ mark_ref(frame, 0);
++ }
++
++ for (i = 0; i < NB_RPS_TYPE; i++)
++ rps[i].nb_refs = 0;
++
++ /* add the short refs */
++ for (i = 0; i < short_rps->num_delta_pocs; i++) {
++ int poc = s->poc + short_rps->delta_poc[i];
++ int list;
++
++ if (!short_rps->used[i])
++ list = ST_FOLL;
++ else if (i < short_rps->num_negative_pics)
++ list = ST_CURR_BEF;
++ else
++ list = ST_CURR_AFT;
++
++ ret = add_candidate_ref(s, &rps[list], poc, HEVC_FRAME_FLAG_SHORT_REF);
++ if (ret < 0)
++ goto fail;
++ }
++
++ /* add the long refs */
++ for (i = 0; i < long_rps->nb_refs; i++) {
++ int poc = long_rps->poc[i];
++ int list = long_rps->used[i] ? LT_CURR : LT_FOLL;
++
++ ret = add_candidate_ref(s, &rps[list], poc, HEVC_FRAME_FLAG_LONG_REF);
++ if (ret < 0)
++ goto fail;
++ }
++
++fail:
++ /* release any frames that are now unused */
++ for (i = 0; i < FF_ARRAY_ELEMS(s->DPB); i++)
++ ff_hevc_rpi_unref_frame(s, &s->DPB[i], 0);
++
++ return ret;
++}
++
++int ff_hevc_rpi_frame_nb_refs(HEVCRpiContext *s)
++{
++ int ret = 0;
++ int i;
++ const ShortTermRPS *rps = s->sh.short_term_rps;
++ LongTermRPS *long_rps = &s->sh.long_term_rps;
++
++ if (rps) {
++ for (i = 0; i < rps->num_negative_pics; i++)
++ ret += !!rps->used[i];
++ for (; i < rps->num_delta_pocs; i++)
++ ret += !!rps->used[i];
++ }
++
++ if (long_rps) {
++ for (i = 0; i < long_rps->nb_refs; i++)
++ ret += !!long_rps->used[i];
++ }
++ return ret;
++}
+diff --git a/libavcodec/rpi_hevc_sei.c b/libavcodec/rpi_hevc_sei.c
+new file mode 100644
+index 0000000000..cd8149d58e
+--- /dev/null
++++ b/libavcodec/rpi_hevc_sei.c
+@@ -0,0 +1,368 @@
++/*
++ * HEVC Supplementary Enhancement Information messages
++ *
++ * Copyright (C) 2012 - 2013 Guillaume Martres
++ * Copyright (C) 2012 - 2013 Gildas Cocherel
++ * Copyright (C) 2013 Vittorio Giovara
++ *
++ * This file is part of FFmpeg.
++ *
++ * FFmpeg is free software; you can redistribute it and/or
++ * modify it under the terms of the GNU Lesser General Public
++ * License as published by the Free Software Foundation; either
++ * version 2.1 of the License, or (at your option) any later version.
++ *
++ * FFmpeg is distributed in the hope that it will be useful,
++ * but WITHOUT ANY WARRANTY; without even the implied warranty of
++ * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
++ * Lesser General Public License for more details.
++ *
++ * You should have received a copy of the GNU Lesser General Public
++ * License along with FFmpeg; if not, write to the Free Software
++ * Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA
++ */
++
++#include "golomb.h"
++#include "rpi_hevc_ps.h"
++#include "rpi_hevc_sei.h"
++
++static int decode_nal_sei_decoded_picture_hash(HEVCSEIPictureHash *s, GetBitContext *gb)
++{
++ int cIdx, i;
++ uint8_t hash_type;
++ //uint16_t picture_crc;
++ //uint32_t picture_checksum;
++ hash_type = get_bits(gb, 8);
++
++ for (cIdx = 0; cIdx < 3/*((s->sps->chroma_format_idc == 0) ? 1 : 3)*/; cIdx++) {
++ if (hash_type == 0) {
++ s->is_md5 = 1;
++ for (i = 0; i < 16; i++)
++ s->md5[cIdx][i] = get_bits(gb, 8);
++ } else if (hash_type == 1) {
++ // picture_crc = get_bits(gb, 16);
++ skip_bits(gb, 16);
++ } else if (hash_type == 2) {
++ // picture_checksum = get_bits_long(gb, 32);
++ skip_bits(gb, 32);
++ }
++ }
++ return 0;
++}
++
++static int decode_nal_sei_mastering_display_info(HEVCSEIMasteringDisplay *s, GetBitContext *gb)
++{
++ int i;
++ // Mastering primaries
++ for (i = 0; i < 3; i++) {
++ s->display_primaries[i][0] = get_bits(gb, 16);
++ s->display_primaries[i][1] = get_bits(gb, 16);
++ }
++ // White point (x, y)
++ s->white_point[0] = get_bits(gb, 16);
++ s->white_point[1] = get_bits(gb, 16);
++
++ // Max and min luminance of mastering display
++ s->max_luminance = get_bits_long(gb, 32);
++ s->min_luminance = get_bits_long(gb, 32);
++
++ // As this SEI message comes before the first frame that references it,
++ // initialize the flag to 2 and decrement on IRAP access unit so it
++ // persists for the coded video sequence (e.g., between two IRAPs)
++ s->present = 2;
++ return 0;
++}
++
++static int decode_nal_sei_content_light_info(HEVCSEIContentLight *s, GetBitContext *gb)
++{
++ // Max and average light levels
++ s->max_content_light_level = get_bits_long(gb, 16);
++ s->max_pic_average_light_level = get_bits_long(gb, 16);
++ // As this SEI message comes before the first frame that references it,
++ // initialize the flag to 2 and decrement on IRAP access unit so it
++ // persists for the coded video sequence (e.g., between two IRAPs)
++ s->present = 2;
++ return 0;
++}
++
++static int decode_nal_sei_frame_packing_arrangement(HEVCSEIFramePacking *s, GetBitContext *gb)
++{
++ get_ue_golomb_long(gb); // frame_packing_arrangement_id
++ s->present = !get_bits1(gb);
++
++ if (s->present) {
++ s->arrangement_type = get_bits(gb, 7);
++ s->quincunx_subsampling = get_bits1(gb);
++ s->content_interpretation_type = get_bits(gb, 6);
++
++ // spatial_flipping_flag, frame0_flipped_flag, field_views_flag
++ skip_bits(gb, 3);
++ s->current_frame_is_frame0_flag = get_bits1(gb);
++ // frame0_self_contained_flag, frame1_self_contained_flag
++ skip_bits(gb, 2);
++
++ if (!s->quincunx_subsampling && s->arrangement_type != 5)
++ skip_bits(gb, 16); // frame[01]_grid_position_[xy]
++ skip_bits(gb, 8); // frame_packing_arrangement_reserved_byte
++ skip_bits1(gb); // frame_packing_arrangement_persistence_flag
++ }
++ skip_bits1(gb); // upsampled_aspect_ratio_flag
++ return 0;
++}
++
++static int decode_nal_sei_display_orientation(HEVCSEIDisplayOrientation *s, GetBitContext *gb)
++{
++ s->present = !get_bits1(gb);
++
++ if (s->present) {
++ s->hflip = get_bits1(gb); // hor_flip
++ s->vflip = get_bits1(gb); // ver_flip
++
++ s->anticlockwise_rotation = get_bits(gb, 16);
++ skip_bits1(gb); // display_orientation_persistence_flag
++ }
++
++ return 0;
++}
++
++static int decode_nal_sei_pic_timing(HEVCSEIContext *s, GetBitContext *gb, const HEVCRpiParamSets *ps,
++ void *logctx, int size)
++{
++ HEVCSEIPictureTiming *h = &s->picture_timing;
++ HEVCRpiSPS *sps;
++
++ if (!ps->sps_list[s->active_seq_parameter_set_id])
++ return(AVERROR(ENOMEM));
++ sps = (HEVCRpiSPS*)ps->sps_list[s->active_seq_parameter_set_id]->data;
++
++ if (sps->vui.frame_field_info_present_flag) {
++ int pic_struct = get_bits(gb, 4);
++ h->picture_struct = AV_PICTURE_STRUCTURE_UNKNOWN;
++ if (pic_struct == 2 || pic_struct == 10 || pic_struct == 12) {
++ av_log(logctx, AV_LOG_DEBUG, "BOTTOM Field\n");
++ h->picture_struct = AV_PICTURE_STRUCTURE_BOTTOM_FIELD;
++ } else if (pic_struct == 1 || pic_struct == 9 || pic_struct == 11) {
++ av_log(logctx, AV_LOG_DEBUG, "TOP Field\n");
++ h->picture_struct = AV_PICTURE_STRUCTURE_TOP_FIELD;
++ }
++ get_bits(gb, 2); // source_scan_type
++ get_bits(gb, 1); // duplicate_flag
++ skip_bits1(gb);
++ size--;
++ }
++ skip_bits_long(gb, 8 * size);
++
++ return 0;
++}
++
++static int decode_registered_user_data_closed_caption(HEVCSEIA53Caption *s, GetBitContext *gb,
++ int size)
++{
++ int flag;
++ int user_data_type_code;
++ int cc_count;
++
++ if (size < 3)
++ return AVERROR(EINVAL);
++
++ user_data_type_code = get_bits(gb, 8);
++ if (user_data_type_code == 0x3) {
++ skip_bits(gb, 1); // reserved
++
++ flag = get_bits(gb, 1); // process_cc_data_flag
++ if (flag) {
++ skip_bits(gb, 1);
++ cc_count = get_bits(gb, 5);
++ skip_bits(gb, 8); // reserved
++ size -= 2;
++
++ if (cc_count && size >= cc_count * 3) {
++ const uint64_t new_size = (s->a53_caption_size + cc_count
++ * UINT64_C(3));
++ int i, ret;
++
++ if (new_size > INT_MAX)
++ return AVERROR(EINVAL);
++
++ /* Allow merging of the cc data from two fields. */
++ ret = av_reallocp(&s->a53_caption, new_size);
++ if (ret < 0)
++ return ret;
++
++ for (i = 0; i < cc_count; i++) {
++ s->a53_caption[s->a53_caption_size++] = get_bits(gb, 8);
++ s->a53_caption[s->a53_caption_size++] = get_bits(gb, 8);
++ s->a53_caption[s->a53_caption_size++] = get_bits(gb, 8);
++ }
++ skip_bits(gb, 8); // marker_bits
++ }
++ }
++ } else {
++ int i;
++ for (i = 0; i < size - 1; i++)
++ skip_bits(gb, 8);
++ }
++
++ return 0;
++}
++
++static int decode_nal_sei_user_data_registered_itu_t_t35(HEVCSEIContext *s, GetBitContext *gb,
++ int size)
++{
++ uint32_t country_code;
++ uint32_t user_identifier;
++
++ if (size < 7)
++ return AVERROR(EINVAL);
++ size -= 7;
++
++ country_code = get_bits(gb, 8);
++ if (country_code == 0xFF) {
++ skip_bits(gb, 8);
++ size--;
++ }
++
++ skip_bits(gb, 8);
++ skip_bits(gb, 8);
++
++ user_identifier = get_bits_long(gb, 32);
++
++ switch (user_identifier) {
++ case MKBETAG('G', 'A', '9', '4'):
++ return decode_registered_user_data_closed_caption(&s->a53_caption, gb, size);
++ default:
++ skip_bits_long(gb, size * 8);
++ break;
++ }
++ return 0;
++}
++
++static int decode_nal_sei_active_parameter_sets(HEVCSEIContext *s, GetBitContext *gb, void *logctx)
++{
++ int num_sps_ids_minus1;
++ int i;
++ unsigned active_seq_parameter_set_id;
++
++ get_bits(gb, 4); // active_video_parameter_set_id
++ get_bits(gb, 1); // self_contained_cvs_flag
++ get_bits(gb, 1); // num_sps_ids_minus1
++ num_sps_ids_minus1 = get_ue_golomb_long(gb); // num_sps_ids_minus1
++
++ if (num_sps_ids_minus1 < 0 || num_sps_ids_minus1 > 15) {
++ av_log(logctx, AV_LOG_ERROR, "num_sps_ids_minus1 %d invalid\n", num_sps_ids_minus1);
++ return AVERROR_INVALIDDATA;
++ }
++
++ active_seq_parameter_set_id = get_ue_golomb_long(gb);
++ if (active_seq_parameter_set_id >= HEVC_MAX_SPS_COUNT) {
++ av_log(logctx, AV_LOG_ERROR, "active_parameter_set_id %d invalid\n", active_seq_parameter_set_id);
++ return AVERROR_INVALIDDATA;
++ }
++ s->active_seq_parameter_set_id = active_seq_parameter_set_id;
++
++ for (i = 1; i <= num_sps_ids_minus1; i++)
++ get_ue_golomb_long(gb); // active_seq_parameter_set_id[i]
++
++ return 0;
++}
++
++static int decode_nal_sei_alternative_transfer(HEVCSEIAlternativeTransfer *s, GetBitContext *gb)
++{
++ s->present = 1;
++ s->preferred_transfer_characteristics = get_bits(gb, 8);
++ return 0;
++}
++
++static int decode_nal_sei_prefix(GetBitContext *gb, void *logctx, HEVCSEIContext *s, const HEVCRpiParamSets *ps,
++ int type, int size)
++{
++ switch (type) {
++ case 256: // Mismatched value from HM 8.1
++ return decode_nal_sei_decoded_picture_hash(&s->picture_hash, gb);
++ case HEVC_SEI_TYPE_FRAME_PACKING:
++ return decode_nal_sei_frame_packing_arrangement(&s->frame_packing, gb);
++ case HEVC_SEI_TYPE_DISPLAY_ORIENTATION:
++ return decode_nal_sei_display_orientation(&s->display_orientation, gb);
++ case HEVC_SEI_TYPE_PICTURE_TIMING:
++ return decode_nal_sei_pic_timing(s, gb, ps, logctx, size);
++ case HEVC_SEI_TYPE_MASTERING_DISPLAY_INFO:
++ return decode_nal_sei_mastering_display_info(&s->mastering_display, gb);
++ case HEVC_SEI_TYPE_CONTENT_LIGHT_LEVEL_INFO:
++ return decode_nal_sei_content_light_info(&s->content_light, gb);
++ case HEVC_SEI_TYPE_ACTIVE_PARAMETER_SETS:
++ return decode_nal_sei_active_parameter_sets(s, gb, logctx);
++ case HEVC_SEI_TYPE_USER_DATA_REGISTERED_ITU_T_T35:
++ return decode_nal_sei_user_data_registered_itu_t_t35(s, gb, size);
++ case HEVC_SEI_TYPE_ALTERNATIVE_TRANSFER_CHARACTERISTICS:
++ return decode_nal_sei_alternative_transfer(&s->alternative_transfer, gb);
++ default:
++ av_log(logctx, AV_LOG_DEBUG, "Skipped PREFIX SEI %d\n", type);
++ skip_bits_long(gb, 8 * size);
++ return 0;
++ }
++}
++
++static int decode_nal_sei_suffix(GetBitContext *gb, void *logctx, HEVCSEIContext *s,
++ int type, int size)
++{
++ switch (type) {
++ case HEVC_SEI_TYPE_DECODED_PICTURE_HASH:
++ return decode_nal_sei_decoded_picture_hash(&s->picture_hash, gb);
++ default:
++ av_log(logctx, AV_LOG_DEBUG, "Skipped SUFFIX SEI %d\n", type);
++ skip_bits_long(gb, 8 * size);
++ return 0;
++ }
++}
++
++static int decode_nal_sei_message(GetBitContext * const gb, void * const logctx, HEVCSEIContext * const s,
++ const HEVCRpiParamSets * const ps, const int nal_unit_type)
++{
++ int payload_type = 0;
++ int payload_size = 0;
++ int byte = 0xFF;
++ av_log(logctx, AV_LOG_DEBUG, "Decoding SEI\n");
++
++ while (byte == 0xFF) {
++ if (get_bits_left(gb) < 16 || payload_type > INT_MAX - 255)
++ return AVERROR_INVALIDDATA;
++ byte = get_bits(gb, 8);
++ payload_type += byte;
++ }
++ byte = 0xFF;
++ while (byte == 0xFF) {
++ if (get_bits_left(gb) < 8 + 8LL*payload_size)
++ return AVERROR_INVALIDDATA;
++ byte = get_bits(gb, 8);
++ payload_size += byte;
++ }
++ if (nal_unit_type == HEVC_NAL_SEI_PREFIX) {
++ return decode_nal_sei_prefix(gb, logctx, s, ps, payload_type, payload_size);
++ } else { /* nal_unit_type == NAL_SEI_SUFFIX */
++ return decode_nal_sei_suffix(gb, logctx, s, payload_type, payload_size);
++ }
++}
++
++static int more_rbsp_data(GetBitContext *gb)
++{
++ return get_bits_left(gb) > 0 && show_bits(gb, 8) != 0x80;
++}
++
++int ff_hevc_rpi_decode_nal_sei(GetBitContext *gb, void *logctx, HEVCSEIContext *s,
++ const HEVCRpiParamSets *ps, int type)
++{
++ int ret;
++
++ do {
++ ret = decode_nal_sei_message(gb, logctx, s, ps, type);
++ if (ret < 0)
++ return ret;
++ } while (more_rbsp_data(gb));
++ return 1;
++}
++
++void ff_hevc_rpi_reset_sei(HEVCSEIContext *s)
++{
++ s->a53_caption.a53_caption_size = 0;
++ av_freep(&s->a53_caption.a53_caption);
++}
+diff --git a/libavcodec/rpi_hevc_sei.h b/libavcodec/rpi_hevc_sei.h
+new file mode 100644
+index 0000000000..d4ac348df9
+--- /dev/null
++++ b/libavcodec/rpi_hevc_sei.h
+@@ -0,0 +1,135 @@
++/*
++ * HEVC Supplementary Enhancement Information messages
++ *
++ * This file is part of FFmpeg.
++ *
++ * FFmpeg is free software; you can redistribute it and/or
++ * modify it under the terms of the GNU Lesser General Public
++ * License as published by the Free Software Foundation; either
++ * version 2.1 of the License, or (at your option) any later version.
++ *
++ * FFmpeg is distributed in the hope that it will be useful,
++ * but WITHOUT ANY WARRANTY; without even the implied warranty of
++ * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
++ * Lesser General Public License for more details.
++ *
++ * You should have received a copy of the GNU Lesser General Public
++ * License along with FFmpeg; if not, write to the Free Software
++ * Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA
++ */
++
++#ifndef AVCODEC_RPI_HEVC_SEI_H
++#define AVCODEC_RPI_HEVC_SEI_H
++
++#include <stdint.h>
++
++#include "libavutil/md5.h"
++
++#include "get_bits.h"
++
++/**
++ * SEI message types
++ */
++typedef enum {
++ HEVC_SEI_TYPE_BUFFERING_PERIOD = 0,
++ HEVC_SEI_TYPE_PICTURE_TIMING = 1,
++ HEVC_SEI_TYPE_PAN_SCAN_RECT = 2,
++ HEVC_SEI_TYPE_FILLER_PAYLOAD = 3,
++ HEVC_SEI_TYPE_USER_DATA_REGISTERED_ITU_T_T35 = 4,
++ HEVC_SEI_TYPE_USER_DATA_UNREGISTERED = 5,
++ HEVC_SEI_TYPE_RECOVERY_POINT = 6,
++ HEVC_SEI_TYPE_SCENE_INFO = 9,
++ HEVC_SEI_TYPE_FULL_FRAME_SNAPSHOT = 15,
++ HEVC_SEI_TYPE_PROGRESSIVE_REFINEMENT_SEGMENT_START = 16,
++ HEVC_SEI_TYPE_PROGRESSIVE_REFINEMENT_SEGMENT_END = 17,
++ HEVC_SEI_TYPE_FILM_GRAIN_CHARACTERISTICS = 19,
++ HEVC_SEI_TYPE_POST_FILTER_HINT = 22,
++ HEVC_SEI_TYPE_TONE_MAPPING_INFO = 23,
++ HEVC_SEI_TYPE_FRAME_PACKING = 45,
++ HEVC_SEI_TYPE_DISPLAY_ORIENTATION = 47,
++ HEVC_SEI_TYPE_SOP_DESCRIPTION = 128,
++ HEVC_SEI_TYPE_ACTIVE_PARAMETER_SETS = 129,
++ HEVC_SEI_TYPE_DECODING_UNIT_INFO = 130,
++ HEVC_SEI_TYPE_TEMPORAL_LEVEL0_INDEX = 131,
++ HEVC_SEI_TYPE_DECODED_PICTURE_HASH = 132,
++ HEVC_SEI_TYPE_SCALABLE_NESTING = 133,
++ HEVC_SEI_TYPE_REGION_REFRESH_INFO = 134,
++ HEVC_SEI_TYPE_MASTERING_DISPLAY_INFO = 137,
++ HEVC_SEI_TYPE_CONTENT_LIGHT_LEVEL_INFO = 144,
++ HEVC_SEI_TYPE_ALTERNATIVE_TRANSFER_CHARACTERISTICS = 147,
++} HEVC_SEI_Type;
++
++typedef struct HEVCSEIPictureHash {
++ uint8_t md5[3][16];
++ uint8_t is_md5;
++} HEVCSEIPictureHash;
++
++typedef struct HEVCSEIFramePacking {
++ int present;
++ int arrangement_type;
++ int content_interpretation_type;
++ int quincunx_subsampling;
++ int current_frame_is_frame0_flag;
++} HEVCSEIFramePacking;
++
++typedef struct HEVCSEIDisplayOrientation {
++ int present;
++ int anticlockwise_rotation;
++ int hflip, vflip;
++} HEVCSEIDisplayOrientation;
++
++typedef struct HEVCSEIPictureTiming {
++ int picture_struct;
++} HEVCSEIPictureTiming;
++
++typedef struct HEVCSEIA53Caption {
++ int a53_caption_size;
++ uint8_t *a53_caption;
++} HEVCSEIA53Caption;
++
++typedef struct HEVCSEIMasteringDisplay {
++ int present;
++ uint16_t display_primaries[3][2];
++ uint16_t white_point[2];
++ uint32_t max_luminance;
++ uint32_t min_luminance;
++} HEVCSEIMasteringDisplay;
++
++typedef struct HEVCSEIContentLight {
++ int present;
++ uint16_t max_content_light_level;
++ uint16_t max_pic_average_light_level;
++} HEVCSEIContentLight;
++
++typedef struct HEVCSEIAlternativeTransfer {
++ int present;
++ int preferred_transfer_characteristics;
++} HEVCSEIAlternativeTransfer;
++
++typedef struct HEVCSEIContext {
++ HEVCSEIPictureHash picture_hash;
++ HEVCSEIFramePacking frame_packing;
++ HEVCSEIDisplayOrientation display_orientation;
++ HEVCSEIPictureTiming picture_timing;
++ HEVCSEIA53Caption a53_caption;
++ HEVCSEIMasteringDisplay mastering_display;
++ HEVCSEIContentLight content_light;
++ int active_seq_parameter_set_id;
++ HEVCSEIAlternativeTransfer alternative_transfer;
++} HEVCSEIContext;
++
++struct HEVCRpiParamSets;
++
++int ff_hevc_rpi_decode_nal_sei(GetBitContext *gb, void *logctx, HEVCSEIContext *s,
++ const struct HEVCRpiParamSets *ps, int type);
++
++/**
++ * Reset SEI values that are stored on the Context.
++ * e.g. Caption data that was extracted during NAL
++ * parsing.
++ *
++ * @param s HEVCRpiContext.
++ */
++void ff_hevc_rpi_reset_sei(HEVCSEIContext *s);
++
++#endif /* AVCODEC_RPI_HEVC_SEI_H */
+diff --git a/libavcodec/rpi_hevc_shader.c b/libavcodec/rpi_hevc_shader.c
+new file mode 100644
+index 0000000000..23b49a99ae
+--- /dev/null
++++ b/libavcodec/rpi_hevc_shader.c
+@@ -0,0 +1,1537 @@
++#include "rpi_hevc_shader.h"
++
++#ifdef _MSC_VER
++ #include <stdint.h>
++ /* cast through uintptr_t to avoid warnings */
++ #define POINTER_TO_UINT(X) ((unsigned int)(uintptr_t)(X))
++#else
++ #define POINTER_TO_UINT(X) ((unsigned int)(X))
++#endif
++
++#ifdef __cplusplus
++extern "C" { /* the types are probably wrong... */
++#endif
++#ifdef __cplusplus
++}
++#endif
++
++#ifdef _MSC_VER
++__declspec(align(8))
++#elif defined(__GNUC__)
++__attribute__((aligned(8)))
++#endif
++unsigned int ff_hevc_rpi_shader[] = {
++// ::mc_setup_c_q0
++// ::mc_start
++/* [0x00000000] */ 0x0000000c, 0xe80009e7, // mov dst, srel(i)
++// ::mc_setup_c_qn
++/* [0x00000008] */ 0x95801ff6, 0xd0025900, // mov tmurs, 1 ; mov ra0, unif
++/* [0x00000010] */ 0xaaaaff00, 0xe6020827, // mov r0, [0,2,0,2,0,2,0,2,1,3,1,3,1,3,1,3]
++/* [0x00000018] */ 0x9181e1f6, 0xd00250d8, // shl rb_ef, r0, i_shift30 ; mov ra_base, unif
++/* [0x00000020] */ 0x0d801dc0, 0xd0020827, // sub r0, unif, 1
++/* [0x00000028] */ 0x119c11c0, 0xd00216a7, // shl rb_max_x, r0, v_x_shift
++/* [0x00000030] */ 0x0d801dc0, 0xd00217a7, // sub rb_max_y, unif, 1
++/* [0x00000038] */ 0xff800100, 0xe0020527, // mov ra_kff800100, 0xff800100
++/* [0x00000040] */ 0x000000ff, 0xe0021627, // mov rb_pmask, v_pmask
++/* [0x00000048] */ 0x001000ff, 0xe00205e7, // mov ra_blk_height_pmax, ((1 << v_bit_depth) - 1) | (v_blk_height << 16)
++/* [0x00000050] */ 0x00004000, 0xe00217e7, // mov rb_fir_off_h, (FIR_OFFSET << (v_bit_depth - 8))
++/* [0x00000058] */ 0x4000000e, 0xe0020667, // mov ra_fir_off_val_wt_den_p7, (FIR_OFFSET << 16) | (DENOM + 15 - v_bit_depth)
++/* [0x00000060] */ 0x95803ff6, 0x10024754, // mov ra_ef, rb_ef ; mov rb_xpitch, unif
++/* [0x00000068] */ 0x15827d80, 0x10021427, // mov rb_pitch, unif
++/* [0x00000070] */ 0xc0000000, 0xe0020867, // mov r1, vdw_setup_1(0)
++/* [0x00000078] */ 0x0c9d03c0, 0x10021667, // add rb_dma1_base, r1, rb_pitch
++/* [0x00000080] */ 0x14981f80, 0xd0020827, // and r0, 1, elem_num
++/* [0x00000088] */ 0x409c5007, 0xd00049e0, // nop ; mul24 r0, r0, 5
++/* [0x00000090] */ 0x0c9a7180, 0x100210a7, // add rb_elem_x, r0, elem_num
++/* [0x00000098] */ 0x11001dc0, 0xd4020827, // shl r0, ra0.16b, v_x_shift
++/* [0x000000a0] */ 0x0c9c21c0, 0x10020827, // add r0, r0, rb_elem_x
++/* [0x000000a8] */ 0x930001f6, 0xd2225811, // max r0, r0, 0 ; mov ra_y, ra0.16a
++/* [0x000000b0] */ 0x129da1c0, 0x10020827, // min r0, r0, rb_max_x
++/* [0x000000b8] */ 0x119c31c0, 0xd0220567, // shl ra_xshift_next, r0, 3
++/* [0x000000c0] */ 0x149dc1c0, 0xd0020827, // and r0, r0, -4
++/* [0x000000c8] */ 0x0d510dc0, 0x18020867, // sub r1, ra_k0, rb_pitch
++/* [0x000000d0] */ 0x149e7040, 0x10020867, // and r1, r0, r1
++/* [0x000000d8] */ 0x569d404f, 0x10024821, // xor r0, r0, r1 ; mul24 r1, r1, rb_xpitch
++/* [0x000000e0] */ 0x8c827076, 0x10025800, // add r0, r0, r1 ; mov ra0, unif
++/* [0x000000e8] */ 0x0c627c00, 0x10020627, // add ra_base, ra_base, r0
++/* [0x000000f0] */ 0x159e6fc0, 0x100208a7, // mov r2, qpu_num
++/* [0x000000f8] */ 0x0f9c25c0, 0xd0020867, // asr r1, r2, 2
++/* [0x00000100] */ 0x119c63c0, 0xd0020867, // shl r1, r1, 6
++/* [0x00000108] */ 0x149c35c0, 0xd0020827, // and r0, r2, 3
++/* [0x00000110] */ 0x159e7040, 0x10020827, // or r0, r0, r1
++/* [0x00000118] */ 0x00004800, 0xe0020867, // mov r1, vpm_setup(0, 4, h8p(0, 0))
++/* [0x00000120] */ 0x0c9e7040, 0x10021727, // add r_vpm, r0, r1
++/* [0x00000128] */ 0x80004004, 0xe0020867, // mov r1, vdw_setup_0(0, 0, dma_h8p(0,0,0))
++/* [0x00000130] */ 0x119c51c0, 0xd0020827, // shl r0, r0, 5
++/* [0x00000138] */ 0x0c9e7040, 0x100216e7, // add r_dma, r0, r1
++/* [0x00000140] */ 0x11001dc0, 0xd4020827, // shl r0, ra0.16b, v_x_shift
++/* [0x00000148] */ 0x8c0021f6, 0x12125811, // add r0, r0, rb_elem_x ; mov ra_y2, ra0.16a
++/* [0x00000150] */ 0x938001f6, 0xd002480f, // max r0, r0, 0 ; mov rb_base2, unif
++/* [0x00000158] */ 0x129da1c0, 0x10020827, // min r0, r0, rb_max_x
++/* [0x00000160] */ 0x119c31c0, 0xd0021067, // shl rb_xshift2_next, r0, 3
++/* [0x00000168] */ 0x149dc1c0, 0xd0020827, // and r0, r0, -4
++/* [0x00000170] */ 0x0d510dc0, 0x18020867, // sub r1, ra_k0, rb_pitch
++/* [0x00000178] */ 0x949c307f, 0xd0024863, // and r1, r0, r1 ; mov r3, PREREAD
++/* [0x00000180] */ 0x569d404f, 0x10024821, // xor r0, r0, r1 ; mul24 r1, r1, rb_xpitch
++/* [0x00000188] */ 0x8c467076, 0x12024822, // add r0, r0, r1 ; mov r2, ra_y2
++/* [0x00000190] */ 0x8c44fe36, 0x140253e0, // add rb_base2, rb_base2, r0 ; mov r0, ra_y
++// :1
++/* [0x00000198] */ 0x0d9c17c0, 0xd00228e7, // sub.setf r3, r3, 1
++/* [0x000001a0] */ 0x139c01c0, 0xd0020867, // max r1, r0, 0
++/* [0x000001a8] */ 0x129de3c0, 0x10020867, // min r1, r1, rb_max_y
++/* [0x000001b0] */ 0x4c51018f, 0x1a024821, // add r0, r0, ra_k1 ; mul24 r1, r1, rb_pitch
++/* [0x000001b8] */ 0x8c627c40, 0x10225e11, // add t0s, ra_base, r1 ; mov ra_y, r0
++/* [0x000001c0] */ 0x139c05c0, 0xd0020867, // max r1, r2, 0
++/* [0x000001c8] */ 0xffffffb0, 0xf03809e7, // brr.anynz -, r:1b
++/* [0x000001d0] */ 0x129de3c0, 0x10020867, // min r1, r1, rb_max_y
++/* [0x000001d8] */ 0x4c51058f, 0x1a0248a1, // add r2, r2, ra_k1 ; mul24 r1, r1, rb_pitch
++/* [0x000001e0] */ 0x8c9cfe52, 0x10125f11, // add t1s, rb_base2, r1 ; mov ra_y2, r2
++/* [0x000001e8] */ 0x15827d80, 0x100207a7, // mov ra_link, unif
++/* [0x000001f0] */ 0x00000000, 0xe0024104, // mov ra4, 0 ; mov rb4, 0
++/* [0x000001f8] */ 0x00000000, 0xf0f7c9e7, // bra -, ra_link
++/* [0x00000200] */ 0x00000000, 0xe0024145, // mov ra5, 0 ; mov rb5, 0
++/* [0x00000208] */ 0x00000000, 0xe0024186, // mov ra6, 0 ; mov rb6, 0
++/* [0x00000210] */ 0x00000000, 0xe00241c7, // mov ra7, 0 ; mov rb7, 0
++// ::mc_filter_c_p
++/* [0x00000218] */ 0x9581cff6, 0x10025c42, // mov vw_setup, rb_vpm_init ; mov ra2, unif
++/* [0x00000220] */ 0x8c803ff6, 0x100269e3, // add.setf -, rb_ef, rb_ef ; mov r3, unif
++/* [0x00000228] */ 0xf1081dc0, 0xd4024825, // shl r0, ra2.16b, v_x_shift ; v8subs r5rep, r0, r0
++/* [0x00000230] */ 0x8c8021f6, 0x10025810, // add r0, r0, rb_elem_x ; mov ra_width_height, unif
++/* [0x00000238] */ 0x8d810bf6, 0x10025840, // sub r1, r5, rb_pitch ; mov ra0, unif
++/* [0x00000240] */ 0x93567176, 0x14024800, // max r0, r0, r5 ; mov vrx_xshift, vrx_xshift_next
++/* [0x00000248] */ 0x9209a1f6, 0x12225813, // min r0, r0, rb_max_x ; mov vra_y_next, ra2.16a
++/* [0x00000250] */ 0x119c31c0, 0xd0220567, // shl vrx_xshift_next, r0, 3
++/* [0x00000258] */ 0x149dc1c0, 0xd0020827, // and r0, r0, -4
++/* [0x00000260] */ 0x54402077, 0xd4024862, // and r1, r0, r1 ; mul24 r2, ra_width, v_x_mul
++/* [0x00000268] */ 0x569d404f, 0x10024821, // xor r0, r0, r1 ; mul24 r1, r1, rb_xpitch
++/* [0x00000270] */ 0x8c827076, 0x10025803, // add r0, r0, r1 ; mov ra3, unif
++/* [0x00000278] */ 0x8c427636, 0x120246a1, // add vrx_base_next, r3, r0 ; mov r1, ra_height
++/* [0x00000280] */ 0x8d819eb6, 0x10025756, // sub rb_dma1, rb_dma1_base, r2 ; mov ra_wt_off_mul_l0, unif
++/* [0x00000288] */ 0x8c5dc3ce, 0xdc025461, // add rb_i_tmu, r1, (3-4) - PREREAD ; v8min r1, r1, ra_blk_height
++/* [0x00000290] */ 0x8c81f3f6, 0xd0039496, // add rb_lcount, r1, (3-4) ; mov.ifc ra_wt_off_mul_l0, unif
++/* [0x00000298] */ 0x918073f6, 0xd002581c, // shl r0, r1, v_dma_h_shift ; mov ra_dest, unif
++/* [0x000002a0] */ 0x8c6670b6, 0x14024822, // add r0, r0, r2 ; mov r2, ra_fir_off_val
++/* [0x000002a8] */ 0x910d01f6, 0xdc02480a, // shl r0, r0, v_dma_wh_shift ; mov rb10, ra3.8c
++/* [0x000002b0] */ 0x8c59b1f6, 0x140246e1, // add ra_dma0, r0, rb_dma0_base ; mov r1, ra_wt_off_l0
++/* [0x000002b8] */ 0x5158c3d6, 0xd2024860, // shl r1, r1, i_wt_den_p5 ; mul24 r0, r2, ra_wt_mul_l0
++/* [0x000002c0] */ 0x8d667236, 0x14025320, // sub rb_wt_off, r1, r0 ; mov r0, ra_kmul_add
++/* [0x000002c8] */ 0x8c59cc3f, 0xd21245a5, // add ra_wt_mul_l0, ra_wt_mul_l0, r0 ; mov r5rep, -4
++/* [0x000002d0] */ 0x950e0dbf, 0x1e0252de, // mov rb11, ra3.8d ; mov ra_link, unif
++// :1
++/* [0x000002d8] */ 0x8d151bf6, 0xa00269c4, // sub.setf -, r5, rb_i_tmu ; mov rb4, ra5 ; ldtmu0
++/* [0x000002e0] */ 0x8e4c09f6, 0x140288a3, // shr r2, r4, vrx_xshift ; mov.ifz r3, vra_y_next
++/* [0x000002e8] */ 0x8e4485f6, 0xd402c863, // shr r1, r2, v_v_shift ; mov.ifnz r3, vra_y
++/* [0x000002f0] */ 0x8c683ff6, 0x1002b9d8, // add.setf -, rb_ef, rb_ef ; mov.ifz vra_base, vrx_base_next
++/* [0x000002f8] */ 0x8c531789, 0xda224460, // add vra_y, r3, ra_k1 ; mov r0, r1 << 15
++/* [0x00000300] */ 0x9353f792, 0xd803c8e1, // max r3, r3, ra_k0 ; mov.ifnc r1, r2 << 1
++/* [0x00000308] */ 0x929de7d2, 0x1003c8e0, // min r3, r3, rb_max_y ; mov.ifnc r0, r2
++/* [0x00000310] */ 0x545d039f, 0x12024863, // and r1, r1, ra_pmax ; mul24 r3, r3, rb_pitch
++/* [0x00000318] */ 0x8c618cc7, 0x10024e20, // add vr_txs, vra_base, r3 ; v8min r0, r0, rb_pmask
++/* [0x00000320] */ 0x4c001bf0, 0xd8025963, // add r5rep, r5, 1 ; mul24 r3, ra0.8a, r0
++/* [0x00000328] */ 0x4d01fef1, 0x1e0248a3, // sub r2, rb_fir_off_h, r3 ; mul24 r3, ra0.8d, r1
++/* [0x00000330] */ 0x4d03e4f0, 0xda0248a3, // sub r2, r2, r3 ; mul24 r3, ra0.8b << 2, r0 << 2 @ "mul_used", 0
++/* [0x00000338] */ 0x40034031, 0xda0109e3, // nop ; mul24.ifn r3, ra0.8b << 12, r1 << 12 @ "mul_used", 0
++/* [0x00000340] */ 0x4c03c4f0, 0xdc0248a3, // add r2, r2, r3 ; mul24 r3, ra0.8c << 4, r0 << 4 @ "mul_used", 0
++/* [0x00000348] */ 0x4c032b71, 0xdc0329e3, // add.setf -, r5, r5 ; mul24.ifn r3, ra0.8c << 14, r1 << 14 @ "mul_used", 0
++/* [0x00000350] */ 0xffffff68, 0xf06809e7, // brr.anyn -, r:1b
++/* [0x00000358] */ 0x4c1ca4f7, 0x100248a0, // add r2, r2, r3 ; mul24 r0, ra7, rb10
++/* [0x00000360] */ 0x550c6ffe, 0x1a024161, // mov ra5, rb6 ; mul24 r1, rb6, ra3.8b
++/* [0x00000368] */ 0x8f1c05f6, 0xd00241c6, // asr ra7, r2, v_bit_depth - 8 ; mov rb6, ra7
++/* [0x00000370] */ 0x4c0c423e, 0x18024860, // add r1, r1, r0 ; mul24 r0, rb4, ra3.8a
++/* [0x00000378] */ 0x4d1cb237, 0x10024860, // sub r1, r1, r0 ; mul24 r0, ra7, rb11
++/* [0x00000380] */ 0x0d9e7200, 0x10020867, // sub r1, r1, r0
++/* [0x00000388] */ 0x8f5c63f6, 0xdc024863, // asr r1, r1, 6 ; mov r3, ra_blk_height
++/* [0x00000390] */ 0x4d592bce, 0x120269e0, // sub.setf -, r5, rb_lcount ; mul24 r0, r1, ra_wt_mul_l0
++/* [0x00000398] */ 0x4c64c1ce, 0x14024821, // add r0, r0, rb_wt_off ; mul24 r1, r1, ra_kmul_add
++/* [0x000003a0] */ 0xed427073, 0x12024860, // sub r1, r0, r1 ; v8subs r0, ra_height, r3
++/* [0x000003a8] */ 0xffffff10, 0xf06809e7, // brr.anyn -, r:1b
++/* [0x000003b0] */ 0x0f9cd3c0, 0xd0020867, // asr r1, r1, i_wt_den_p6
++/* [0x000003b8] */ 0x925f23bf, 0x12020867, // min r1, r1, ra_pmax ; mov -, vw_wait
++/* [0x000003c0] */ 0x5351039f, 0x18024c22, // max vpm, r1, ra_k0 ; mul24 r2, r3, rb_pitch
++/* [0x000003c8] */ 0x956e7036, 0x10126431, // mov.setf ra_height, r0 ; mov vw_setup, ra_dma0
++/* [0x000003d0] */ 0x00000000, 0xf027c9e7, // bra.anyz -, ra_link
++/* [0x000003d8] */ 0x929dd0ff, 0x10024831, // min r0, r0, r3 ; mov vw_setup, rb_dma1
++/* [0x000003e0] */ 0x8d7270f6, 0x10024872, // sub r1, r0, r3 ; mov vw_addr, ra_dest
++/* [0x000003e8] */ 0x119d73c0, 0xd0020867, // shl r1, r1, i_shift23
++/* [0x000003f0] */ 0xfffffec8, 0xf0f809e7, // brr -, r:1b
++/* [0x000003f8] */ 0x0c9d2e00, 0x100214a7, // add rb_lcount, rb_lcount, r0
++/* [0x00000400] */ 0x0c6e7c40, 0x100206e7, // add ra_dma0, ra_dma0, r1
++/* [0x00000408] */ 0x8c71ccbf, 0x10024731, // add ra_dest, ra_dest, r2 ; mov vw_setup, rb_vpm_init
++// ::mc_filter_c_p_l1
++/* [0x00000410] */ 0x9581cff6, 0x10025c42, // mov vw_setup, rb_vpm_init ; mov ra2, unif
++/* [0x00000418] */ 0x8c803ff6, 0x100269e3, // add.setf -, rb_ef, rb_ef ; mov r3, unif
++/* [0x00000420] */ 0xf1081dc0, 0xd4024825, // shl r0, ra2.16b, v_x_shift ; v8subs r5rep, r0, r0
++/* [0x00000428] */ 0x8c8021f6, 0x10025810, // add r0, r0, rb_elem_x ; mov ra_width_height, unif
++/* [0x00000430] */ 0x8d810bf6, 0x10025840, // sub r1, r5, rb_pitch ; mov ra0, unif
++/* [0x00000438] */ 0x939c117f, 0x10125815, // max r0, r0, r5 ; mov vrx_xshift, vrx_xshift_next
++/* [0x00000440] */ 0x9209a1f6, 0x12125813, // min r0, r0, rb_max_x ; mov vra_y_next, ra2.16a
++/* [0x00000448] */ 0x119c31c0, 0xd0021067, // shl vrx_xshift_next, r0, 3
++/* [0x00000450] */ 0x149dc1c0, 0xd0020827, // and r0, r0, -4
++/* [0x00000458] */ 0x54402077, 0xd4024862, // and r1, r0, r1 ; mul24 r2, ra_width, v_x_mul
++/* [0x00000460] */ 0x569d404f, 0x10024821, // xor r0, r0, r1 ; mul24 r1, r1, rb_xpitch
++/* [0x00000468] */ 0x8c827076, 0x10025803, // add r0, r0, r1 ; mov ra3, unif
++/* [0x00000470] */ 0x8c427636, 0x120254e1, // add vrx_base_next, r3, r0 ; mov r1, ra_height
++/* [0x00000478] */ 0x8d819eb6, 0x10025756, // sub rb_dma1, rb_dma1_base, r2 ; mov ra_wt_off_mul_l0, unif
++/* [0x00000480] */ 0x8c5dc3ce, 0xdc025461, // add rb_i_tmu, r1, (3-4) - PREREAD ; v8min r1, r1, ra_blk_height
++/* [0x00000488] */ 0x8c81f3f6, 0xd0039496, // add rb_lcount, r1, (3-4) ; mov.ifc ra_wt_off_mul_l0, unif
++/* [0x00000490] */ 0x918073f6, 0xd002581c, // shl r0, r1, v_dma_h_shift ; mov ra_dest, unif
++/* [0x00000498] */ 0x8c6670b6, 0x14024822, // add r0, r0, r2 ; mov r2, ra_fir_off_val
++/* [0x000004a0] */ 0x910d01f6, 0xdc02480a, // shl r0, r0, v_dma_wh_shift ; mov rb10, ra3.8c
++/* [0x000004a8] */ 0x8c59b1f6, 0x140246e1, // add ra_dma0, r0, rb_dma0_base ; mov r1, ra_wt_off_l0
++/* [0x000004b0] */ 0x5158c3d6, 0xd2024860, // shl r1, r1, i_wt_den_p5 ; mul24 r0, r2, ra_wt_mul_l0
++/* [0x000004b8] */ 0x8d667236, 0x14025320, // sub rb_wt_off, r1, r0 ; mov r0, ra_kmul_add
++/* [0x000004c0] */ 0x8c59cc3f, 0xd21245a5, // add ra_wt_mul_l0, ra_wt_mul_l0, r0 ; mov r5rep, -4
++/* [0x000004c8] */ 0x950e0dbf, 0x1e0252de, // mov rb11, ra3.8d ; mov ra_link, unif
++// :1
++/* [0x000004d0] */ 0x8d151bf6, 0xb00269c4, // sub.setf -, r5, rb_i_tmu ; mov rb4, ra5 ; ldtmu1
++/* [0x000004d8] */ 0x8e5539bf, 0x1202888f, // shr r2, r4, vrx_xshift ; mov.ifz vra_base, vrx_base_next
++/* [0x000004e0] */ 0x8e4485f6, 0xd202c863, // shr r1, r2, v_v_shift ; mov.ifnz r3, vra_y
++/* [0x000004e8] */ 0x8c4c3ff6, 0x1202a9e3, // add.setf -, rb_ef, rb_ef ; mov.ifz r3, vra_y_next
++/* [0x000004f0] */ 0x8c531789, 0xda124460, // add vra_y, r3, ra_k1 ; mov r0, r1 << 15
++/* [0x000004f8] */ 0x9353f792, 0xd803c8e1, // max r3, r3, ra_k0 ; mov.ifnc r1, r2 << 1
++/* [0x00000500] */ 0x929de7d2, 0x1003c8e0, // min r3, r3, rb_max_y ; mov.ifnc r0, r2
++/* [0x00000508] */ 0x545d039f, 0x12024863, // and r1, r1, ra_pmax ; mul24 r3, r3, rb_pitch
++/* [0x00000510] */ 0x8c5cfec6, 0x12024f20, // add vr_txs, vra_base, r3 ; v8min r0, r0, ra_pmax
++/* [0x00000518] */ 0x4c001bf0, 0xd8025963, // add r5rep, r5, 1 ; mul24 r3, ra0.8a, r0
++/* [0x00000520] */ 0x4d01fef1, 0x1e0248a3, // sub r2, rb_fir_off_h, r3 ; mul24 r3, ra0.8d, r1
++/* [0x00000528] */ 0x4d03e4f0, 0xda0248a3, // sub r2, r2, r3 ; mul24 r3, ra0.8b << 2, r0 << 2 @ "mul_used", 0
++/* [0x00000530] */ 0x40034031, 0xda0109e3, // nop ; mul24.ifn r3, ra0.8b << 12, r1 << 12 @ "mul_used", 0
++/* [0x00000538] */ 0x4c03c4f0, 0xdc0248a3, // add r2, r2, r3 ; mul24 r3, ra0.8c << 4, r0 << 4 @ "mul_used", 0
++/* [0x00000540] */ 0x4c032b71, 0xdc0329e3, // add.setf -, r5, r5 ; mul24.ifn r3, ra0.8c << 14, r1 << 14 @ "mul_used", 0
++/* [0x00000548] */ 0xffffff68, 0xf06809e7, // brr.anyn -, r:1b
++/* [0x00000550] */ 0x4c1ca4f7, 0x100248a0, // add r2, r2, r3 ; mul24 r0, ra7, rb10
++/* [0x00000558] */ 0x550c6ffe, 0x1a024161, // mov ra5, rb6 ; mul24 r1, rb6, ra3.8b
++/* [0x00000560] */ 0x8f1c05f6, 0xd00241c6, // asr ra7, r2, v_bit_depth - 8 ; mov rb6, ra7
++/* [0x00000568] */ 0x4c0c423e, 0x18024860, // add r1, r1, r0 ; mul24 r0, rb4, ra3.8a
++/* [0x00000570] */ 0x4d1cb237, 0x10024860, // sub r1, r1, r0 ; mul24 r0, ra7, rb11
++/* [0x00000578] */ 0x0d9e7200, 0x10020867, // sub r1, r1, r0
++/* [0x00000580] */ 0x8f5c63f6, 0xdc024863, // asr r1, r1, 6 ; mov r3, ra_blk_height
++/* [0x00000588] */ 0x4d592bce, 0x120269e0, // sub.setf -, r5, rb_lcount ; mul24 r0, r1, ra_wt_mul_l0
++/* [0x00000590] */ 0x4c64c1ce, 0x14024821, // add r0, r0, rb_wt_off ; mul24 r1, r1, ra_kmul_add
++/* [0x00000598] */ 0xed427073, 0x12024860, // sub r1, r0, r1 ; v8subs r0, ra_height, r3
++/* [0x000005a0] */ 0xffffff10, 0xf06809e7, // brr.anyn -, r:1b
++/* [0x000005a8] */ 0x0f9cd3c0, 0xd0020867, // asr r1, r1, i_wt_den_p6
++/* [0x000005b0] */ 0x925f23bf, 0x12020867, // min r1, r1, ra_pmax ; mov -, vw_wait
++/* [0x000005b8] */ 0x5351039f, 0x18024c22, // max vpm, r1, ra_k0 ; mul24 r2, r3, rb_pitch
++/* [0x000005c0] */ 0x956e7036, 0x10126431, // mov.setf ra_height, r0 ; mov vw_setup, ra_dma0
++/* [0x000005c8] */ 0x00000000, 0xf027c9e7, // bra.anyz -, ra_link
++/* [0x000005d0] */ 0x929dd0ff, 0x10024831, // min r0, r0, r3 ; mov vw_setup, rb_dma1
++/* [0x000005d8] */ 0x8d7270f6, 0x10024872, // sub r1, r0, r3 ; mov vw_addr, ra_dest
++/* [0x000005e0] */ 0x119d73c0, 0xd0020867, // shl r1, r1, i_shift23
++/* [0x000005e8] */ 0xfffffec8, 0xf0f809e7, // brr -, r:1b
++/* [0x000005f0] */ 0x0c9d2e00, 0x100214a7, // add rb_lcount, rb_lcount, r0
++/* [0x000005f8] */ 0x0c6e7c40, 0x100206e7, // add ra_dma0, ra_dma0, r1
++/* [0x00000600] */ 0x8c71ccbf, 0x10024731, // add ra_dest, ra_dest, r2 ; mov vw_setup, rb_vpm_init
++// ::mc_filter_c_b
++/* [0x00000608] */ 0x9581cff6, 0x10025c42, // mov vw_setup, rb_vpm_init ; mov ra2, unif
++/* [0x00000610] */ 0x8c803ff6, 0x100269e3, // add.setf -, rb_ef, rb_ef ; mov r3, unif
++/* [0x00000618] */ 0xf1081dc9, 0xd4024825, // shl r0, ra2.16b, v_x_shift ; v8subs r5rep, r1, r1
++/* [0x00000620] */ 0x8c0821f6, 0x12225813, // add r0, r0, rb_elem_x ; mov ra_y_next, ra2.16a
++/* [0x00000628] */ 0x8d810bf6, 0x10025850, // sub r1, r5, rb_pitch ; mov ra_width_height, unif
++/* [0x00000630] */ 0x93567176, 0x14125815, // max r0, r0, r5 ; mov ra_xshift, ra_xshift_next
++/* [0x00000638] */ 0x9281a1f6, 0x10025800, // min r0, r0, rb_max_x ; mov ra0, unif
++/* [0x00000640] */ 0x119c31c0, 0xd0220567, // shl ra_xshift_next, r0, 3
++/* [0x00000648] */ 0x9481c1f6, 0xd0025802, // and r0, r0, -4 ; mov ra2, unif
++/* [0x00000650] */ 0x54402077, 0xd4024862, // and r1, r0, r1 ; mul24 r2, ra_width, v_x_mul
++/* [0x00000658] */ 0x569d404f, 0x10024821, // xor r0, r0, r1 ; mul24 r1, r1, rb_xpitch
++/* [0x00000660] */ 0x8c427076, 0x12024821, // add r0, r0, r1 ; mov r1, ra_height
++/* [0x00000668] */ 0x8c9c163f, 0x10024680, // add ra_base_next, r3, r0 ; mov rb_xshift2, rb_xshift2_next
++/* [0x00000670] */ 0x8d819eb6, 0x10025756, // sub rb_dma1, rb_dma1_base, r2 ; mov ra_wt_off_mul_l0, unif
++/* [0x00000678] */ 0x8c5dc3ce, 0xdc025461, // add rb_i_tmu, r1, (3-4) - PREREAD ; v8min r1, r1, ra_blk_height
++/* [0x00000680] */ 0x8c59f3f6, 0xd4139496, // add rb_lcount, r1, (3-4) ; mov.ifc ra_wt_mul_l0, ra_wt_off_l0
++/* [0x00000688] */ 0x918073f6, 0xd0025803, // shl r0, r1, v_dma_h_shift ; mov ra3, unif
++/* [0x00000690] */ 0x8c8270b6, 0x10024823, // add r0, r0, r2 ; mov r3, unif
++/* [0x00000698] */ 0x910d01f6, 0xd2125813, // shl r0, r0, v_dma_wh_shift ; mov ra_y2_next, ra3.16a
++/* [0x000006a0] */ 0x8c0db1f6, 0x140246e0, // add ra_dma0, r0, rb_dma0_base ; mov r0, ra3.16b
++/* [0x000006a8] */ 0x918011f6, 0xd0025801, // shl r0, r0, v_x_shift ; mov ra1, unif
++/* [0x000006b0] */ 0x8c8021f6, 0x10025803, // add r0, r0, rb_elem_x ; mov ra3, unif
++/* [0x000006b8] */ 0x8d810bf6, 0x10025852, // sub r1, r5, rb_pitch ; mov ra_wt_off_mul_l1, unif
++/* [0x000006c0] */ 0x939de17f, 0x10025809, // max r0, r0, r5 ; mov ra9, rb_max_y
++/* [0x000006c8] */ 0x9265a1f6, 0x14024822, // min r0, r0, rb_max_x ; mov r2, ra_kmul_add
++/* [0x000006d0] */ 0x119c31c0, 0xd0021067, // shl rb_xshift2_next, r0, 3
++/* [0x000006d8] */ 0x9481c1f6, 0xd0039812, // and r0, r0, -4 ; mov.ifc ra_wt_off_mul_l1, unif
++/* [0x000006e0] */ 0x949dc07f, 0xd0024865, // and r1, r0, r1 ; mov r5rep, -4
++/* [0x000006e8] */ 0x569d404f, 0x10024821, // xor r0, r0, r1 ; mul24 r1, r1, rb_xpitch
++/* [0x000006f0] */ 0x8c827076, 0x1002581c, // add r0, r0, r1 ; mov ra_dest, unif
++/* [0x000006f8] */ 0x8c667636, 0x140254e0, // add rb_base2_next, r3, r0 ; mov r0, ra_fir_off_val
++/* [0x00000700] */ 0x4c5a7c86, 0x121245a1, // add ra_wt_mul_l0, ra_wt_mul_l0, r2 ; mul24 r1, r0, ra_wt_mul_l0
++/* [0x00000708] */ 0x4c4a7c86, 0x121244a0, // add ra_wt_mul_l1, ra_wt_mul_l1, r2 ; mul24 r0, r0, ra_wt_mul_l1
++/* [0x00000710] */ 0x8c4a7076, 0x14024821, // add r0, r0, r1 ; mov r1, ra_wt_off_l1
++/* [0x00000718] */ 0x910cd3f6, 0xde02484b, // shl r1, r1, i_wt_den_p6 ; mov rb11, ra3.8d
++/* [0x00000720] */ 0x8d827236, 0x1002531e, // sub rb_wt_off, r1, r0 ; mov ra_link, unif
++/* [0x00000728] */ 0x95080ff6, 0x1e024287, // mov ra10, rb_xshift2 ; mov rb7, ra2.8d
++// :1
++/* [0x00000730] */ 0x0d9d1bc0, 0xa00229e7, // sub.setf -, r5, rb_i_tmu ; nop ; ldtmu0
++/* [0x00000738] */ 0x8e5539bf, 0x1202888f, // shr r2, r4, ra_xshift ; mov.ifz rb_base2, rb_base2_next
++/* [0x00000740] */ 0x8e4c85f6, 0xd0029851, // shr r1, r2, v_v_shift ; mov.ifz ra_y_y2, ra_y_y2_next
++/* [0x00000748] */ 0x8c683ff6, 0x1002b9d8, // add.setf -, rb_ef, rb_ef ; mov.ifz ra_base, ra_base_next
++/* [0x00000750] */ 0x8c441fb6, 0xd4224463, // add ra_y, 1, ra_y ; mov r3, ra_y
++/* [0x00000758] */ 0x93531789, 0xd80248e0, // max r3, r3, ra_k0 ; mov r0, r1 << 15
++/* [0x00000760] */ 0x9227f792, 0xd003c8e1, // min r3, r3, ra9 ; mov.ifnc r1, r2 << 1
++/* [0x00000768] */ 0x559d049f, 0x100e4823, // mov.ifnc r0, r2 ; mul24 r3, r3, rb_pitch
++/* [0x00000770] */ 0x8c618cc7, 0x10024e20, // add t0s, ra_base, r3 ; v8min r0, r0, rb_pmask
++/* [0x00000778] */ 0x540183f0, 0x18024862, // and r1, r1, rb_pmask ; mul24 r2, ra0.8a, r0
++/* [0x00000780] */ 0x4d01feb1, 0x1e0248a3, // sub r2, rb_fir_off_h, r2 ; mul24 r3, ra0.8d, r1
++/* [0x00000788] */ 0x4d03e4f0, 0xda0248a3, // sub r2, r2, r3 ; mul24 r3, ra0.8b << 2, r0 << 2 @ "mul_used", 0
++/* [0x00000790] */ 0x40034031, 0xda0109e3, // nop ; mul24.ifn r3, ra0.8b << 12, r1 << 12 @ "mul_used", 0
++/* [0x00000798] */ 0x4c03c4f0, 0xdc0248a3, // add r2, r2, r3 ; mul24 r3, ra0.8c << 4, r0 << 4 @ "mul_used", 0
++/* [0x000007a0] */ 0x40032031, 0xdc0109e3, // nop ; mul24.ifn r3, ra0.8c << 14, r1 << 14 @ "mul_used", 0
++/* [0x000007a8] */ 0x4c0854fe, 0xb8025804, // add r0, r2, r3 ; mul24 ra4, rb5, ra2.8a ; ldtmu1
++/* [0x000007b0] */ 0x8e2869bf, 0x10024885, // shr r2, r4, ra10 ; mov rb5, rb6
++/* [0x000007b8] */ 0x8e4485f6, 0xd2024863, // shr r1, r2, v_v_shift ; mov r3, ra_y2
++/* [0x000007c0] */ 0x8e1c01f6, 0xd00241c6, // shr ra7, r0, v_bit_depth - 8 ; mov rb6, ra7
++/* [0x000007c8] */ 0x8c531789, 0xda124460, // add ra_y2, r3, ra_k1 ; mov r0, r1 << 15
++/* [0x000007d0] */ 0x9353f792, 0xd803c8e1, // max r3, r3, ra_k0 ; mov.ifnc r1, r2 << 1
++/* [0x000007d8] */ 0x925de7ce, 0x120248e1, // min r3, r3, rb_max_y ; v8min r1, r1, ra_pmax
++/* [0x000007e0] */ 0x559d049f, 0x100e4823, // mov.ifnc r0, r2 ; mul24 r3, r3, rb_pitch
++/* [0x000007e8] */ 0x8c5cfec6, 0x12024f20, // add t1s, rb_base2, r3 ; v8min r0, r0, ra_pmax
++/* [0x000007f0] */ 0x4c041bf0, 0xd8025962, // add r5rep, r5, 1 ; mul24 r2, ra1.8a, r0
++/* [0x000007f8] */ 0x4d05feb1, 0x1e0248a3, // sub r2, rb_fir_off_h, r2 ; mul24 r3, ra1.8d, r1
++/* [0x00000800] */ 0x4d07e4f0, 0xda0248a3, // sub r2, r2, r3 ; mul24 r3, ra1.8b << 2, r0 << 2 @ "mul_used", 0
++/* [0x00000808] */ 0x40074031, 0xda0109e3, // nop ; mul24.ifn r3, ra1.8b << 12, r1 << 12 @ "mul_used", 0
++/* [0x00000810] */ 0x4c07c6b0, 0xdc0248a3, // add r2, r3, r2 ; mul24 r3, ra1.8c << 4, r0 << 4 @ "mul_used", 0
++/* [0x00000818] */ 0x4c072b71, 0xdc0329e3, // add.setf -, r5, r5 ; mul24.ifn r3, ra1.8c << 14, r1 << 14 @ "mul_used", 0
++/* [0x00000820] */ 0xfffffef0, 0xf06809e7, // brr.anyn -, r:1b
++/* [0x00000828] */ 0x4c0c94fe, 0x180248a0, // add r2, r2, r3 ; mul24 r0, rb9, ra3.8a
++/* [0x00000830] */ 0x550caffe, 0x1a025261, // mov rb9, rb10 ; mul24 r1, rb10, ra3.8b
++/* [0x00000838] */ 0x8e2c05f6, 0xd00242ca, // shr ra11, r2, v_bit_depth - 8 ; mov rb10, ra11
++/* [0x00000840] */ 0x4d08523e, 0x1a0248a1, // sub r2, r1, r0 ; mul24 r1, rb5, ra2.8b
++/* [0x00000848] */ 0x8d112bf6, 0x100269e0, // sub.setf -, r5, rb_lcount ; mov r0, ra4
++/* [0x00000850] */ 0x4d08623e, 0x1c024860, // sub r1, r1, r0 ; mul24 r0, rb6, ra2.8c
++/* [0x00000858] */ 0x4c1c7237, 0x10024860, // add r1, r1, r0 ; mul24 r0, ra7, rb7
++/* [0x00000860] */ 0x4d0ca23e, 0x1c024860, // sub r1, r1, r0 ; mul24 r0, rb10, ra3.8c
++/* [0x00000868] */ 0x4c2cb437, 0x100248a0, // add r2, r2, r0 ; mul24 r0, ra11, rb11
++/* [0x00000870] */ 0x0d9e7400, 0x100208a7, // sub r2, r2, r0
++/* [0x00000878] */ 0x0e9c63c0, 0xd0020867, // shr r1, r1, 6
++/* [0x00000880] */ 0x4e5865ce, 0xd20248a0, // shr r2, r2, 6 ; mul24 r0, r1, ra_wt_mul_l0
++/* [0x00000888] */ 0x4c4a7456, 0x120248a1, // add r2, r2, r1 ; mul24 r1, r2, ra_wt_mul_l1
++/* [0x00000890] */ 0x4c667216, 0x14024862, // add r1, r1, r0 ; mul24 r2, r2, ra_kmul_add
++/* [0x00000898] */ 0x8d5e72b6, 0x1c024863, // sub r1, r1, r2 ; mov r3, ra_blk_height
++/* [0x000008a0] */ 0xec40c3f3, 0x12024860, // add r1, r1, rb_wt_off ; v8subs r0, ra_height, r3
++/* [0x000008a8] */ 0xfffffe68, 0xf06809e7, // brr.anyn -, r:1b
++/* [0x000008b0] */ 0x0f667380, 0x18020867, // asr r1, r1, ra_wt_den_p7
++/* [0x000008b8] */ 0x925f23bf, 0x12020867, // min r1, r1, ra_pmax ; mov -, vw_wait
++/* [0x000008c0] */ 0x5351039f, 0x18024c22, // max vpm, r1, ra_k0 ; mul24 r2, r3, rb_pitch
++/* [0x000008c8] */ 0x956e7036, 0x10126431, // mov.setf ra_height, r0 ; mov vw_setup, ra_dma0
++/* [0x000008d0] */ 0x00000000, 0xf027c9e7, // bra.anyz -, ra_link
++/* [0x000008d8] */ 0x929dd0ff, 0x10024831, // min r0, r0, r3 ; mov vw_setup, rb_dma1
++/* [0x000008e0] */ 0x8d7270f6, 0x10024872, // sub r1, r0, r3 ; mov vw_addr, ra_dest
++/* [0x000008e8] */ 0x119d73c0, 0xd0020867, // shl r1, r1, i_shift23
++/* [0x000008f0] */ 0xfffffe20, 0xf0f809e7, // brr -, r:1b
++/* [0x000008f8] */ 0x0c9d2e00, 0x100214a7, // add rb_lcount, rb_lcount, r0
++/* [0x00000900] */ 0x0c6e7c40, 0x100206e7, // add ra_dma0, ra_dma0, r1
++/* [0x00000908] */ 0x8c71ccbf, 0x10024731, // add ra_dest, ra_dest, r2 ; mov vw_setup, rb_vpm_init
++// ::mc_sync_q0
++/* [0x00000910] */ 0x15827d80, 0x100207a7, // mov ra_link, unif
++/* [0x00000918] */ 0x159f2fc0, 0x100009e7, // mov -, vw_wait
++/* [0x00000920] */ 0x00000010, 0xe80009e7, // mov dst, sacq(i)
++/* [0x00000928] */ 0x00000010, 0xe80009e7, // mov dst, sacq(i)
++/* [0x00000930] */ 0x00000010, 0xe80009e7, // mov dst, sacq(i)
++/* [0x00000938] */ 0x00000000, 0xf0f7c9e7, // bra -, ra_link
++/* [0x00000940] */ 0x0000001c, 0xe80009e7, // mov dst, sacq(i)
++/* [0x00000948] */ 0x00000001, 0xe80009e7, // mov dst, srel(i)
++/* [0x00000950] */ 0x0000000d, 0xe80009e7, // mov dst, srel(i)
++// ::mc_sync_q1
++/* [0x00000958] */ 0x15827d80, 0x100207a7, // mov ra_link, unif
++/* [0x00000960] */ 0x159f2fc0, 0x100009e7, // mov -, vw_wait
++/* [0x00000968] */ 0x00000000, 0xf0f7c9e7, // bra -, ra_link
++/* [0x00000970] */ 0x00000000, 0xe80009e7, // mov dst, srel(i)
++/* [0x00000978] */ 0x00000011, 0xe80009e7, // mov dst, sacq(i)
++/* [0x00000980] */ 0x00000002, 0xe80009e7, // mov dst, srel(i)
++// ::mc_sync_q2
++/* [0x00000988] */ 0x15827d80, 0x100207a7, // mov ra_link, unif
++/* [0x00000990] */ 0x159f2fc0, 0x100009e7, // mov -, vw_wait
++/* [0x00000998] */ 0x00000000, 0xf0f7c9e7, // bra -, ra_link
++/* [0x000009a0] */ 0x00000000, 0xe80009e7, // mov dst, srel(i)
++/* [0x000009a8] */ 0x00000012, 0xe80009e7, // mov dst, sacq(i)
++/* [0x000009b0] */ 0x00000003, 0xe80009e7, // mov dst, srel(i)
++// ::mc_sync_q3
++/* [0x000009b8] */ 0x15827d80, 0x100207a7, // mov ra_link, unif
++/* [0x000009c0] */ 0x159f2fc0, 0x100009e7, // mov -, vw_wait
++/* [0x000009c8] */ 0x00000000, 0xf0f7c9e7, // bra -, ra_link
++/* [0x000009d0] */ 0x00000000, 0xe80009e7, // mov dst, srel(i)
++/* [0x000009d8] */ 0x00000013, 0xe80009e7, // mov dst, sacq(i)
++/* [0x000009e0] */ 0x009e7000, 0x100009e7, // nop
++// ::mc_sync_q4
++/* [0x000009e8] */ 0x15827d80, 0x100207a7, // mov ra_link, unif
++/* [0x000009f0] */ 0x159f2fc0, 0x100009e7, // mov -, vw_wait
++/* [0x000009f8] */ 0x00000014, 0xe80009e7, // mov dst, sacq(i)
++/* [0x00000a00] */ 0x00000014, 0xe80009e7, // mov dst, sacq(i)
++/* [0x00000a08] */ 0x00000014, 0xe80009e7, // mov dst, sacq(i)
++/* [0x00000a10] */ 0x00000000, 0xf0f7c9e7, // bra -, ra_link
++/* [0x00000a18] */ 0x0000001d, 0xe80009e7, // mov dst, sacq(i)
++/* [0x00000a20] */ 0x00000005, 0xe80009e7, // mov dst, srel(i)
++/* [0x00000a28] */ 0x0000000e, 0xe80009e7, // mov dst, srel(i)
++// ::mc_sync_q5
++/* [0x00000a30] */ 0x15827d80, 0x100207a7, // mov ra_link, unif
++/* [0x00000a38] */ 0x159f2fc0, 0x100009e7, // mov -, vw_wait
++/* [0x00000a40] */ 0x00000000, 0xf0f7c9e7, // bra -, ra_link
++/* [0x00000a48] */ 0x00000004, 0xe80009e7, // mov dst, srel(i)
++/* [0x00000a50] */ 0x00000015, 0xe80009e7, // mov dst, sacq(i)
++/* [0x00000a58] */ 0x00000006, 0xe80009e7, // mov dst, srel(i)
++// ::mc_sync_q6
++/* [0x00000a60] */ 0x15827d80, 0x100207a7, // mov ra_link, unif
++/* [0x00000a68] */ 0x159f2fc0, 0x100009e7, // mov -, vw_wait
++/* [0x00000a70] */ 0x00000000, 0xf0f7c9e7, // bra -, ra_link
++/* [0x00000a78] */ 0x00000004, 0xe80009e7, // mov dst, srel(i)
++/* [0x00000a80] */ 0x00000016, 0xe80009e7, // mov dst, sacq(i)
++/* [0x00000a88] */ 0x00000007, 0xe80009e7, // mov dst, srel(i)
++// ::mc_sync_q7
++/* [0x00000a90] */ 0x15827d80, 0x100207a7, // mov ra_link, unif
++/* [0x00000a98] */ 0x159f2fc0, 0x100009e7, // mov -, vw_wait
++/* [0x00000aa0] */ 0x00000000, 0xf0f7c9e7, // bra -, ra_link
++/* [0x00000aa8] */ 0x00000004, 0xe80009e7, // mov dst, srel(i)
++/* [0x00000ab0] */ 0x00000017, 0xe80009e7, // mov dst, sacq(i)
++/* [0x00000ab8] */ 0x009e7000, 0x100009e7, // nop
++// ::mc_sync_q8
++/* [0x00000ac0] */ 0x15827d80, 0x100207a7, // mov ra_link, unif
++/* [0x00000ac8] */ 0x159f2fc0, 0x100009e7, // mov -, vw_wait
++/* [0x00000ad0] */ 0x00000018, 0xe80009e7, // mov dst, sacq(i)
++/* [0x00000ad8] */ 0x00000018, 0xe80009e7, // mov dst, sacq(i)
++/* [0x00000ae0] */ 0x00000018, 0xe80009e7, // mov dst, sacq(i)
++/* [0x00000ae8] */ 0x00000000, 0xf0f7c9e7, // bra -, ra_link
++/* [0x00000af0] */ 0x0000001e, 0xe80009e7, // mov dst, sacq(i)
++/* [0x00000af8] */ 0x00000009, 0xe80009e7, // mov dst, srel(i)
++/* [0x00000b00] */ 0x0000000c, 0xe80009e7, // mov dst, srel(i)
++// ::mc_sync_q9
++/* [0x00000b08] */ 0x15827d80, 0x100207a7, // mov ra_link, unif
++/* [0x00000b10] */ 0x159f2fc0, 0x100009e7, // mov -, vw_wait
++/* [0x00000b18] */ 0x00000000, 0xf0f7c9e7, // bra -, ra_link
++/* [0x00000b20] */ 0x00000008, 0xe80009e7, // mov dst, srel(i)
++/* [0x00000b28] */ 0x00000019, 0xe80009e7, // mov dst, sacq(i)
++/* [0x00000b30] */ 0x0000000a, 0xe80009e7, // mov dst, srel(i)
++// ::mc_sync_q10
++/* [0x00000b38] */ 0x15827d80, 0x100207a7, // mov ra_link, unif
++/* [0x00000b40] */ 0x159f2fc0, 0x100009e7, // mov -, vw_wait
++/* [0x00000b48] */ 0x00000000, 0xf0f7c9e7, // bra -, ra_link
++/* [0x00000b50] */ 0x00000008, 0xe80009e7, // mov dst, srel(i)
++/* [0x00000b58] */ 0x0000001a, 0xe80009e7, // mov dst, sacq(i)
++/* [0x00000b60] */ 0x0000000b, 0xe80009e7, // mov dst, srel(i)
++// ::mc_sync_q11
++/* [0x00000b68] */ 0x15827d80, 0x100207a7, // mov ra_link, unif
++/* [0x00000b70] */ 0x159f2fc0, 0x100009e7, // mov -, vw_wait
++/* [0x00000b78] */ 0x00000000, 0xf0f7c9e7, // bra -, ra_link
++/* [0x00000b80] */ 0x00000008, 0xe80009e7, // mov dst, srel(i)
++/* [0x00000b88] */ 0x0000001b, 0xe80009e7, // mov dst, sacq(i)
++/* [0x00000b90] */ 0x009e7000, 0x100009e7, // nop
++// ::mc_exit_c_qn
++// ::mc_exit_y_qn
++/* [0x00000b98] */ 0x00000002, 0xe00228e7, // mov.setf r3, PREREAD - 1
++// :1
++/* [0x00000ba0] */ 0xffffffe0, 0xf03809e7, // brr.anynz -, r:1b
++/* [0x00000ba8] */ 0x009e7000, 0xa00009e7, // nop ; nop ; ldtmu0
++/* [0x00000bb0] */ 0x009e7000, 0xb00009e7, // nop ; nop ; ldtmu1
++/* [0x00000bb8] */ 0x0d9c17c0, 0xd00228e7, // sub.setf r3, r3, 1
++/* [0x00000bc0] */ 0x159f2fc0, 0x100009e7, // mov -, vw_wait
++/* [0x00000bc8] */ 0x009e7000, 0x300009e7, // nop ; nop ; thrend
++/* [0x00000bd0] */ 0x009e7000, 0x100009e7, // nop
++/* [0x00000bd8] */ 0x009e7000, 0x100009e7, // nop
++// ::mc_exit_c_q0
++// ::mc_exit_y_q0
++/* [0x00000be0] */ 0x00000002, 0xe00228e7, // mov.setf r3, PREREAD - 1
++// :1
++/* [0x00000be8] */ 0xffffffe0, 0xf03809e7, // brr.anynz -, r:1b
++/* [0x00000bf0] */ 0x009e7000, 0xa00009e7, // nop ; nop ; ldtmu0
++/* [0x00000bf8] */ 0x009e7000, 0xb00009e7, // nop ; nop ; ldtmu1
++/* [0x00000c00] */ 0x0d9c17c0, 0xd00228e7, // sub.setf r3, r3, 1
++/* [0x00000c08] */ 0x159f2fc0, 0x100009e7, // mov -, vw_wait
++/* [0x00000c10] */ 0x0000001c, 0xe80009e7, // mov dst, sacq(i)
++/* [0x00000c18] */ 0x009e7000, 0x300009e7, // nop ; nop ; thrend
++/* [0x00000c20] */ 0x00000001, 0xe00209a7, // mov interrupt, 1
++/* [0x00000c28] */ 0x009e7000, 0x100009e7, // nop
++// ::mc_setup_y_q0
++/* [0x00000c30] */ 0x0000000c, 0xe80009e7, // mov dst, srel(i)
++// ::mc_setup_y_qn
++/* [0x00000c38] */ 0x95801ff6, 0xd0025900, // mov tmurs, 1 ; mov ra0, unif
++/* [0x00000c40] */ 0x15827d80, 0x10020267, // mov ra9, unif
++/* [0x00000c48] */ 0x15827d80, 0x10020067, // mov ra1, unif
++/* [0x00000c50] */ 0xaaaaff00, 0xe6020827, // mov r0, [0,2,0,2,0,2,0,2,1,3,1,3,1,3,1,3]
++/* [0x00000c58] */ 0x9181e1f6, 0xd00250cb, // shl rb_ef, r0, i_shift30 ; mov ra11, unif
++/* [0x00000c60] */ 0xff800100, 0xe0020527, // mov ra_kff800100, 0xff800100
++/* [0x00000c68] */ 0x000000ff, 0xe0021627, // mov rb_pmask, v_pmask
++/* [0x00000c70] */ 0x001000ff, 0xe00205e7, // mov ra_blk_height_pmax, ((1 << v_bit_depth) - 1) | (v_blk_height << 16)
++/* [0x00000c78] */ 0x00004000, 0xe00217e7, // mov rb_fir_off_h, (FIR_OFFSET << (v_bit_depth - 8))
++/* [0x00000c80] */ 0x4000000e, 0xe0020667, // mov ra_fir_off_val_wt_den_p7, (FIR_OFFSET << 16) | (DENOM + 15 - v_bit_depth)
++/* [0x00000c88] */ 0x050b0a00, 0xe0021567, // mov rb_y_coeffs_2, 0x050b0a00
++/* [0x00000c90] */ 0x11283a40, 0xe00215a7, // mov rb_y_coeffs_3, 0x11283a40
++/* [0x00000c98] */ 0x0a0b0500, 0xe00215e7, // mov rb_y_coeffs_5, 0x0a0b0500
++/* [0x00000ca0] */ 0x15827d80, 0x100200e7, // mov ra3, unif
++/* [0x00000ca8] */ 0x95803ff6, 0x10024754, // mov ra_ef, rb_ef ; mov rb_xpitch, unif
++/* [0x00000cb0] */ 0x0d0c1dc0, 0xd40216a7, // sub rb_max_x, ra3.16b, 1
++/* [0x00000cb8] */ 0x0d0c1dc0, 0xd20217a7, // sub rb_max_y, ra3.16a, 1
++/* [0x00000cc0] */ 0x959a0dbf, 0x100248d0, // mov r3, elem_num ; mov rb_pitch, unif
++/* [0x00000cc8] */ 0xc0000000, 0xe0020867, // mov r1, vdw_setup_1(0)
++/* [0x00000cd0] */ 0x159d03c0, 0x10021667, // or rb_dma1_base, r1, rb_pitch
++/* [0x00000cd8] */ 0x0c027cc0, 0x14020827, // add r0, ra0.16b, r3
++/* [0x00000ce0] */ 0x139c01c0, 0xd0020827, // max r0, r0, 0
++/* [0x00000ce8] */ 0x129da1c0, 0x10020827, // min r0, r0, rb_max_x
++/* [0x00000cf0] */ 0x119c31c0, 0xd0220567, // shl ra_xshift_next, r0, 3
++/* [0x00000cf8] */ 0xf49dc1d2, 0xd0024822, // and r0, r0, -4 ; v8subs r2, r2, r2
++/* [0x00000d00] */ 0x0d9d05c0, 0x100208a7, // sub r2, r2, rb_pitch
++/* [0x00000d08] */ 0x149e7080, 0x10020867, // and r1, r0, r2
++/* [0x00000d10] */ 0x569d404f, 0x10024821, // xor r0, r0, r1 ; mul24 r1, r1, rb_xpitch
++/* [0x00000d18] */ 0x0c9e7040, 0x10020827, // add r0, r0, r1
++/* [0x00000d20] */ 0x0c267c00, 0x10020627, // add ra_base, ra9, r0
++/* [0x00000d28] */ 0x0c067cc0, 0x14020827, // add r0, ra1.16b, r3
++/* [0x00000d30] */ 0x139c01c0, 0xd0020827, // max r0, r0, 0
++/* [0x00000d38] */ 0x129da1c0, 0x10020827, // min r0, r0, rb_max_x
++/* [0x00000d40] */ 0x119c31c0, 0xd0021067, // shl rb_xshift2_next, r0, 3
++/* [0x00000d48] */ 0x149dc1c0, 0xd0020827, // and r0, r0, -4
++/* [0x00000d50] */ 0x149e7080, 0x10020867, // and r1, r0, r2
++/* [0x00000d58] */ 0x569d404f, 0x10024821, // xor r0, r0, r1 ; mul24 r1, r1, rb_xpitch
++/* [0x00000d60] */ 0x0c9e7040, 0x10020827, // add r0, r0, r1
++/* [0x00000d68] */ 0x0c2e7c00, 0x100213e7, // add rb_base2, ra11, r0
++/* [0x00000d70] */ 0x80027036, 0x120049e0, // nop ; mov r0, ra0.16a
++/* [0x00000d78] */ 0x95043ff6, 0xd20248e2, // mov r3, PREREAD ; mov r2, ra1.16a
++// :1
++/* [0x00000d80] */ 0x0d9c17c0, 0xd00228e7, // sub.setf r3, r3, 1
++/* [0x00000d88] */ 0x139c01c0, 0xd0020867, // max r1, r0, 0
++/* [0x00000d90] */ 0x129de3c0, 0x10020867, // min r1, r1, rb_max_y
++/* [0x00000d98] */ 0x4c51018f, 0x1a024821, // add r0, r0, ra_k1 ; mul24 r1, r1, rb_pitch
++/* [0x00000da0] */ 0x8c627c40, 0x10225e11, // add t0s, ra_base, r1 ; mov ra_y, r0
++/* [0x00000da8] */ 0x139c05c0, 0xd0020867, // max r1, r2, 0
++/* [0x00000db0] */ 0xffffffb0, 0xf03809e7, // brr.anynz -, r:1b
++/* [0x00000db8] */ 0x129de3c0, 0x10020867, // min r1, r1, rb_max_y
++/* [0x00000dc0] */ 0x4c51058f, 0x1a0248a1, // add r2, r2, ra_k1 ; mul24 r1, r1, rb_pitch
++/* [0x00000dc8] */ 0x8c9cfe52, 0x10125f11, // add t1s, rb_base2, r1 ; mov ra_y2, r2
++/* [0x00000dd0] */ 0x159e6fc0, 0x100208a7, // mov r2, qpu_num
++/* [0x00000dd8] */ 0x0f9c25c0, 0xd0020867, // asr r1, r2, 2
++/* [0x00000de0] */ 0x119c63c0, 0xd0020867, // shl r1, r1, 6
++/* [0x00000de8] */ 0x149c35c0, 0xd0020827, // and r0, r2, 3
++/* [0x00000df0] */ 0x159e7040, 0x10020827, // or r0, r0, r1
++/* [0x00000df8] */ 0x00004800, 0xe0020867, // mov r1, vpm_setup(0, 4, h8p(0, 0))
++/* [0x00000e00] */ 0x0c9e7040, 0x10021727, // add r_vpm, r0, r1
++/* [0x00000e08] */ 0x80004004, 0xe0020867, // mov r1, vdw_setup_0(0, 0, dma_h8p(0,0,0))
++/* [0x00000e10] */ 0x119c51c0, 0xd0020827, // shl r0, r0, 5
++/* [0x00000e18] */ 0x0c9e7040, 0x100216e7, // add r_dma, r0, r1
++/* [0x00000e20] */ 0x15827d80, 0x100207a7, // mov ra_link, unif
++/* [0x00000e28] */ 0x00000000, 0xe0024208, // mov ra8, 0 ; mov rb8, 0
++/* [0x00000e30] */ 0x00000000, 0xf0f7c9e7, // bra -, ra_link
++/* [0x00000e38] */ 0x00000000, 0xe0024249, // mov ra9, 0 ; mov rb9, 0
++/* [0x00000e40] */ 0x00000000, 0xe002428a, // mov ra10, 0 ; mov rb10, 0
++/* [0x00000e48] */ 0x00000000, 0xe00242cb, // mov ra11, 0 ; mov rb11, 0
++// :per_block_setup_8
++/* [0x00000e50] */ 0x93567176, 0x14125815, // max r0, r0, r5 ; mov ra_xshift, ra_xshift_next
++/* [0x00000e58] */ 0x129da1c0, 0x10020827, // min r0, r0, rb_max_x
++/* [0x00000e60] */ 0x119c31c0, 0xd0220567, // shl ra_xshift_next, r0, 3
++/* [0x00000e68] */ 0x149dc1c0, 0xd0020827, // and r0, r0, -4
++/* [0x00000e70] */ 0x8d810bf6, 0x1002589a, // sub r2, r5, rb_pitch ; mov ra_base_next, unif
++/* [0x00000e78] */ 0x940270b6, 0x12225853, // and r1, r0, r2 ; mov ra_y_next, ra0.16a
++/* [0x00000e80] */ 0x569d404f, 0x10024821, // xor r0, r0, r1 ; mul24 r1, r1, rb_xpitch
++/* [0x00000e88] */ 0x8c827076, 0x10025801, // add r0, r0, r1 ; mov ra1, unif
++/* [0x00000e90] */ 0x0c6a7c00, 0x100206a7, // add ra_base_next, ra_base_next, r0
++/* [0x00000e98] */ 0x0c067cc0, 0x14020827, // add r0, ra1.16b, r3
++/* [0x00000ea0] */ 0x93067176, 0x12125813, // max r0, r0, r5 ; mov ra_y2_next, ra1.16a
++/* [0x00000ea8] */ 0x9281a1f6, 0x10024813, // min r0, r0, rb_max_x ; mov rb_base2_next, unif
++/* [0x00000eb0] */ 0x119c31c0, 0xd0021067, // shl rb_xshift2_next, r0, 3
++/* [0x00000eb8] */ 0x9481c1f6, 0xd0025810, // and r0, r0, -4 ; mov ra_width_height, unif
++/* [0x00000ec0] */ 0x949dc0bf, 0x10024871, // and r1, r0, r2 ; mov vw_setup, rb_vpm_init
++/* [0x00000ec8] */ 0x569d404f, 0x10024821, // xor r0, r0, r1 ; mul24 r1, r1, rb_xpitch
++/* [0x00000ed0] */ 0x4c401077, 0xd4024821, // add r0, r0, r1 ; mul24 r1, ra_width, v_x_mul
++/* [0x00000ed8] */ 0x0c9d3e00, 0x100214e7, // add rb_base2_next, rb_base2_next, r0
++/* [0x00000ee0] */ 0x8d419e76, 0x12025760, // sub rb_dma1, rb_dma1_base, r1 ; mov r0, ra_height
++/* [0x00000ee8] */ 0x8c5dc1c6, 0xdc025460, // add rb_i_tmu, r0, (7-8) - PREREAD ; v8min r0, r0, ra_blk_height
++/* [0x00000ef0] */ 0x0c9df1c0, 0xd00214a7, // add rb_lcount, r0, (7-8)
++/* [0x00000ef8] */ 0x916471f6, 0xd4024823, // shl r0, r0, v_dma_h_shift ; mov r3, ra_kmul_add
++/* [0x00000f00] */ 0x0c9e7040, 0x10020827, // add r0, r0, r1
++/* [0x00000f08] */ 0x916501f6, 0xd4024822, // shl r0, r0, v_dma_wh_shift ; mov r2, ra_fir_off_val
++/* [0x00000f10] */ 0x8c81b1f6, 0x100246e0, // add ra_dma0, r0, rb_dma0_base ; mov r0, unif
++/* [0x00000f18] */ 0x918101f6, 0xd00a5816, // shl.ifnn r0, r0, i_shift16 ; mov ra_wt_off_mul_l0, unif
++/* [0x00000f20] */ 0x915031f6, 0xde024205, // shl ra8, r0, 3 ; mov rb5, ra_k255
++/* [0x00000f28] */ 0x01040400, 0xe0020867, // mov r1, 0x01040400
++/* [0x00000f30] */ 0x10227380, 0x1e5200a7, // ror ra2.8b, r1, ra8.8d
++/* [0x00000f38] */ 0x10227380, 0x1c520027, // ror ra0.8b, r1, ra8.8c
++/* [0x00000f40] */ 0x10215f80, 0x1e6200a7, // ror ra2.8c, rb_y_coeffs_2, ra8.8d
++/* [0x00000f48] */ 0x10215f80, 0x1c620027, // ror ra0.8c, rb_y_coeffs_2, ra8.8c
++/* [0x00000f50] */ 0x00010100, 0xe0020867, // mov r1,0x00010100
++/* [0x00000f58] */ 0x902203bf, 0x1e025812, // ror r0, r1, ra8.8d ; mov ra_wt_off_mul_l1, unif
++/* [0x00000f60] */ 0x90205387, 0x1c424004, // ror ra0.8a, r1, ra8.8c ; v8min rb4, r0, rb5
++/* [0x00000f68] */ 0x914883f6, 0xd0031856, // shl r1, r1, 8 ; mov.ifn ra_wt_off_mul_l0, ra_wt_off_mul_l1
++/* [0x00000f70] */ 0x902203bf, 0x1e02581c, // ror r0, r1, ra8.8d ; mov ra_dest, unif
++/* [0x00000f78] */ 0x90205387, 0x1c72404b, // ror ra1.8d, r1, ra8.8c ; v8min rb11, r0, rb5
++/* [0x00000f80] */ 0x10216f80, 0x1e7200a7, // ror ra2.8d, rb_y_coeffs_3, ra8.8d
++/* [0x00000f88] */ 0x10216f80, 0x1c720027, // ror ra0.8d, rb_y_coeffs_3, ra8.8c
++/* [0x00000f90] */ 0x10217f80, 0x1e5200e7, // ror ra3.8b, rb_y_coeffs_5, ra8.8d
++/* [0x00000f98] */ 0x10217f80, 0x1c520067, // ror ra1.8b, rb_y_coeffs_5, ra8.8c
++/* [0x00000fa0] */ 0x04040100, 0xe0020867, // mov r1,0x04040100
++/* [0x00000fa8] */ 0x10227380, 0x1e6200e7, // ror ra3.8c, r1, ra8.8d
++/* [0x00000fb0] */ 0x902183bf, 0xdc624065, // ror ra1.8c, r1, ra8.8c ; mov r5rep, -8
++/* [0x00000fb8] */ 0x00000000, 0xf0f7c9e7, // bra -, ra_link
++/* [0x00000fc0] */ 0x3a281100, 0xe0020867, // mov r1,0x3a281100
++/* [0x00000fc8] */ 0x902203bf, 0x1e02581e, // ror r0, r1, ra8.8d ; mov ra_link, unif
++/* [0x00000fd0] */ 0x90205387, 0x1c424048, // ror ra1.8a, r1, ra8.8c ; v8min rb8, r0, rb5
++// ::mc_filter_y_pxx
++/* [0x00000fd8] */ 0xfffffe58, 0xf0f807a7, // brr ra_link, r:per_block_setup_8
++/* [0x00000fe0] */ 0x959a0ff6, 0x10024023, // mov ra0, unif ; mov r3, elem_num
++/* [0x00000fe8] */ 0xec9c3fd2, 0x100269e5, // add.setf -, rb_ef, rb_ef ; v8subs r5rep, r2, r2
++/* [0x00000ff0] */ 0x8c001cff, 0x14024800, // add r0, ra0.16b, r3 ; mov rb_xshift2, rb_xshift2_next
++/* [0x00000ff8] */ 0x1158cdc0, 0xd4020867, // shl r1, ra_wt_off_l0, i_wt_den_p5
++/* [0x00001000] */ 0x4c5a7cd6, 0x121245a0, // add ra_wt_mul_l0, ra_wt_mul_l0, r3 ; mul24 r0, r2, ra_wt_mul_l0
++/* [0x00001008] */ 0x8d9c423f, 0x1042531d, // sub rb_wt_off, r1, r0 ; mov ra_ef.8a, rb4
++// :1
++/* [0x00001010] */ 0x4c745dbe, 0x100279c4, // add.setf -, ra_ef, ra_ef ; mul24 ra4, rb5, ra_ef
++/* [0x00001018] */ 0x93440dff, 0xd40248a1, // max r2, ra_y, 0 ; mov r1, 0
++/* [0x00001020] */ 0x9251e5f6, 0x1a0248a3, // min r2, r2, rb_max_y ; mov r3, ra_k1
++/* [0x00001028] */ 0x4c450cd7, 0xa4224462, // add ra_y, ra_y, r3 ; mul24 r2, r2, rb_pitch ; ldtmu0
++/* [0x00001030] */ 0x8c606cbf, 0x10024e05, // add t0s, ra_base, r2 ; mov rb5, rb6
++/* [0x00001038] */ 0x8e5479bf, 0x12024806, // shr r0, r4, ra_xshift ; mov rb6, rb7
++/* [0x00001040] */ 0x93458c47, 0xb20248a0, // max r2, ra_y2, r1 ; v8min r0, r0, rb_pmask ; ldtmu1
++/* [0x00001048] */ 0x8e2009f6, 0x10024847, // shr r1, r4, rb_xshift2 ; mov rb7, ra8
++/* [0x00001050] */ 0x925de5ce, 0x120248a1, // min r2, r2, rb_max_y ; v8min r1, r1, ra_pmax
++/* [0x00001058] */ 0x4c450cd7, 0x12124462, // add ra_y2, ra_y2, r3 ; mul24 r2, r2, rb_pitch
++/* [0x00001060] */ 0x8c24feb6, 0x10025f08, // add t1s, rb_base2, r2 ; mov ra8, ra9
++/* [0x00001068] */ 0x4c038af1, 0xd8025962, // add r5rep, r5, r3 ; mul24 r2, ra0.8a << 8, r1 << 8 @ "mul_used", 0
++/* [0x00001070] */ 0x5501fff0, 0x180348e2, // mov r3, rb_fir_off_h ; mul24.ifnn r2, ra0.8a, r0
++/* [0x00001078] */ 0x4d03f6b0, 0xda0248a3, // sub r2, r3, r2 ; mul24 r3, ra0.8b << 1, r0 << 1 @ "mul_used", 0
++/* [0x00001080] */ 0x40037031, 0xda0109e3, // nop ; mul24.ifn r3, ra0.8b << 9, r1 << 9 @ "mul_used", 0
++/* [0x00001088] */ 0x4c03e4f0, 0xdc0248a3, // add r2, r2, r3 ; mul24 r3, ra0.8c << 2, r0 << 2 @ "mul_used", 0
++/* [0x00001090] */ 0x40036031, 0xdc0109e3, // nop ; mul24.ifn r3, ra0.8c << 10, r1 << 10 @ "mul_used", 0
++/* [0x00001098] */ 0x4d03d4f0, 0xde0248a3, // sub r2, r2, r3 ; mul24 r3, ra0.8d << 3, r0 << 3 @ "mul_used", 0
++/* [0x000010a0] */ 0x40035031, 0xde0109e3, // nop ; mul24.ifn r3, ra0.8d << 11, r1 << 11 @ "mul_used", 0
++/* [0x000010a8] */ 0x4c07c4f0, 0xd80248a3, // add r2, r2, r3 ; mul24 r3, ra1.8a << 4, r0 << 4 @ "mul_used", 0
++/* [0x000010b0] */ 0x40074031, 0xd80109e3, // nop ; mul24.ifn r3, ra1.8a << 12, r1 << 12 @ "mul_used", 0
++/* [0x000010b8] */ 0x4c07b4f0, 0xda0248a3, // add r2, r2, r3 ; mul24 r3, ra1.8b << 5, r0 << 5 @ "mul_used", 0
++/* [0x000010c0] */ 0x40073031, 0xda0109e3, // nop ; mul24.ifn r3, ra1.8b << 13, r1 << 13 @ "mul_used", 0
++/* [0x000010c8] */ 0x4d07a4f0, 0xdc0248a3, // sub r2, r2, r3 ; mul24 r3, ra1.8c << 6, r0 << 6 @ "mul_used", 0
++/* [0x000010d0] */ 0x40072031, 0xdc0109e3, // nop ; mul24.ifn r3, ra1.8c << 14, r1 << 14 @ "mul_used", 0
++/* [0x000010d8] */ 0x4c0794f0, 0xde0248a3, // add r2, r2, r3 ; mul24 r3, ra1.8d << 7, r0 << 7 @ "mul_used", 0
++/* [0x000010e0] */ 0x4c071b71, 0xde0329e3, // add.setf -, r5, r5 ; mul24.ifn r3, ra1.8d << 15, r1 << 15 @ "mul_used", 0
++/* [0x000010e8] */ 0xffffff08, 0xf06809e7, // brr.anyn -, r:1b
++/* [0x000010f0] */ 0x4d0854fe, 0x1a0248a1, // sub r2, r2, r3 ; mul24 r1, rb5, ra2.8b
++/* [0x000010f8] */ 0x550caffe, 0x1a024260, // mov ra9, rb10 ; mul24 r0, rb10, ra3.8b
++/* [0x00001100] */ 0x8f2c05f6, 0xd00242ca, // asr ra11, r2, v_bit_depth - 8 ; mov rb10, ra11
++/* [0x00001108] */ 0x4d08623e, 0x1c024860, // sub r1, r1, r0 ; mul24 r0, rb6, ra2.8c
++/* [0x00001110] */ 0x4d08723e, 0x1e024860, // sub r1, r1, r0 ; mul24 r0, rb7, ra2.8d
++/* [0x00001118] */ 0x4c208237, 0x10024860, // add r1, r1, r0 ; mul24 r0, ra8, rb8
++/* [0x00001120] */ 0x4c0ca23e, 0x1c024860, // add r1, r1, r0 ; mul24 r0, rb10, ra3.8c
++/* [0x00001128] */ 0x4c2cb237, 0x10024860, // add r1, r1, r0 ; mul24 r0, ra11, rb11
++/* [0x00001130] */ 0x8d5d1bf6, 0x1c0269e3, // sub.setf -, r5, rb_i_tmu ; mov r3, ra_blk_height
++/* [0x00001138] */ 0x8d1133bf, 0x1002884f, // sub r1, r1, ra4 ; mov.ifz rb_base2, rb_base2_next
++/* [0x00001140] */ 0x8d6a7236, 0x10029858, // sub r1, r1, r0 ; mov.ifz ra_base, ra_base_next
++/* [0x00001148] */ 0x8f4c63f6, 0xd0029851, // asr r1, r1, 6 ; mov.ifz ra_y_y2, ra_y_y2_next
++/* [0x00001150] */ 0x4d592bce, 0x120269e0, // sub.setf -, r5, rb_lcount ; mul24 r0, r1, ra_wt_mul_l0
++/* [0x00001158] */ 0x4c64c1ce, 0x14024821, // add r0, r0, rb_wt_off ; mul24 r1, r1, ra_kmul_add
++/* [0x00001160] */ 0xed427073, 0x12024860, // sub r1, r0, r1 ; v8subs r0, ra_height, r3
++/* [0x00001168] */ 0xfffffe88, 0xf06809e7, // brr.anyn -, r:1b
++/* [0x00001170] */ 0x0f9cd3c0, 0xd0020867, // asr r1, r1, i_wt_den_p6
++/* [0x00001178] */ 0x925f23bf, 0x12020867, // min r1, r1, ra_pmax ; mov -, vw_wait
++/* [0x00001180] */ 0x5351039f, 0x18024c22, // max vpm, r1, ra_k0 ; mul24 r2, r3, rb_pitch
++/* [0x00001188] */ 0x956e7036, 0x10126431, // mov.setf ra_height, r0 ; mov vw_setup, ra_dma0
++/* [0x00001190] */ 0x00000000, 0xf027c9e7, // bra.anyz -, ra_link
++/* [0x00001198] */ 0x929dd0ff, 0x10024831, // min r0, r0, r3 ; mov vw_setup, rb_dma1
++/* [0x000011a0] */ 0x8d7270f6, 0x10024872, // sub r1, r0, r3 ; mov vw_addr, ra_dest
++/* [0x000011a8] */ 0x119d73c0, 0xd0020867, // shl r1, r1, i_shift23
++/* [0x000011b0] */ 0xfffffe40, 0xf0f809e7, // brr -, r:1b
++/* [0x000011b8] */ 0x0c9d2e00, 0x100214a7, // add rb_lcount, rb_lcount, r0
++/* [0x000011c0] */ 0x0c6e7c40, 0x100206e7, // add ra_dma0, ra_dma0, r1
++/* [0x000011c8] */ 0x8c71ccbf, 0x10024731, // add ra_dest, ra_dest, r2 ; mov vw_setup, rb_vpm_init
++// ::mc_filter_y_bxx
++/* [0x000011d0] */ 0xfffffc60, 0xf0f807a7, // brr ra_link, r:per_block_setup_8
++/* [0x000011d8] */ 0x959a0ff6, 0x10024023, // mov ra0, unif ; mov r3, elem_num
++/* [0x000011e0] */ 0xec9c3fd2, 0x100269e5, // add.setf -, rb_ef, rb_ef ; v8subs r5rep, r2, r2
++/* [0x000011e8] */ 0x8c001cff, 0x14024800, // add r0, ra0.16b, r3 ; mov rb_xshift2, rb_xshift2_next
++/* [0x000011f0] */ 0x1158ddc0, 0xd4020867, // shl r1, ra_wt_off_l0, i_wt_den_p6
++/* [0x000011f8] */ 0x4c5a7cd6, 0x121245a0, // add ra_wt_mul_l0, ra_wt_mul_l0, r3 ; mul24 r0, r2, ra_wt_mul_l0
++/* [0x00001200] */ 0x4d4a7216, 0x12024860, // sub r1, r1, r0 ; mul24 r0, r2, ra_wt_mul_l1
++/* [0x00001208] */ 0x8d9c423f, 0x1042531d, // sub rb_wt_off, r1, r0 ; mov ra_ef.8a, rb4
++// :1
++/* [0x00001210] */ 0x4c745dbe, 0x100279c4, // add.setf -, ra_ef, ra_ef ; mul24 ra4, rb5, ra_ef
++/* [0x00001218] */ 0x93440dff, 0xd40248a1, // max r2, ra_y, 0 ; mov r1, 0
++/* [0x00001220] */ 0x9251e5f6, 0x1a0248a3, // min r2, r2, rb_max_y ; mov r3, ra_k1
++/* [0x00001228] */ 0x4c450cd7, 0xa4224462, // add ra_y, ra_y, r3 ; mul24 r2, r2, rb_pitch ; ldtmu0
++/* [0x00001230] */ 0x8c606cbf, 0x10024e05, // add t0s, ra_base, r2 ; mov rb5, rb6
++/* [0x00001238] */ 0x8e5479bf, 0x12024806, // shr r0, r4, ra_xshift ; mov rb6, rb7
++/* [0x00001240] */ 0x93458c47, 0xb20248a0, // max r2, ra_y2, r1 ; v8min r0, r0, rb_pmask ; ldtmu1
++/* [0x00001248] */ 0x8e2009f6, 0x10024847, // shr r1, r4, rb_xshift2 ; mov rb7, ra8
++/* [0x00001250] */ 0x925de5ce, 0x120248a1, // min r2, r2, rb_max_y ; v8min r1, r1, ra_pmax
++/* [0x00001258] */ 0x4c450cd7, 0x12124462, // add ra_y2, ra_y2, r3 ; mul24 r2, r2, rb_pitch
++/* [0x00001260] */ 0x8c24feb6, 0x10025f08, // add t1s, rb_base2, r2 ; mov ra8, ra9
++/* [0x00001268] */ 0x4c038af1, 0xd8025962, // add r5rep, r5, r3 ; mul24 r2, ra0.8a << 8, r1 << 8 @ "mul_used", 0
++/* [0x00001270] */ 0x5501fff0, 0x180348e2, // mov r3, rb_fir_off_h ; mul24.ifnn r2, ra0.8a, r0
++/* [0x00001278] */ 0x4d03f6b0, 0xda0248a3, // sub r2, r3, r2 ; mul24 r3, ra0.8b << 1, r0 << 1 @ "mul_used", 0
++/* [0x00001280] */ 0x40037031, 0xda0109e3, // nop ; mul24.ifn r3, ra0.8b << 9, r1 << 9 @ "mul_used", 0
++/* [0x00001288] */ 0x4c03e4f0, 0xdc0248a3, // add r2, r2, r3 ; mul24 r3, ra0.8c << 2, r0 << 2 @ "mul_used", 0
++/* [0x00001290] */ 0x40036031, 0xdc0109e3, // nop ; mul24.ifn r3, ra0.8c << 10, r1 << 10 @ "mul_used", 0
++/* [0x00001298] */ 0x4d03d4f0, 0xde0248a3, // sub r2, r2, r3 ; mul24 r3, ra0.8d << 3, r0 << 3 @ "mul_used", 0
++/* [0x000012a0] */ 0x40035031, 0xde0109e3, // nop ; mul24.ifn r3, ra0.8d << 11, r1 << 11 @ "mul_used", 0
++/* [0x000012a8] */ 0x4c07c4f0, 0xd80248a3, // add r2, r2, r3 ; mul24 r3, ra1.8a << 4, r0 << 4 @ "mul_used", 0
++/* [0x000012b0] */ 0x40074031, 0xd80109e3, // nop ; mul24.ifn r3, ra1.8a << 12, r1 << 12 @ "mul_used", 0
++/* [0x000012b8] */ 0x4c07b4f0, 0xda0248a3, // add r2, r2, r3 ; mul24 r3, ra1.8b << 5, r0 << 5 @ "mul_used", 0
++/* [0x000012c0] */ 0x40073031, 0xda0109e3, // nop ; mul24.ifn r3, ra1.8b << 13, r1 << 13 @ "mul_used", 0
++/* [0x000012c8] */ 0x4d07a4f0, 0xdc0248a3, // sub r2, r2, r3 ; mul24 r3, ra1.8c << 6, r0 << 6 @ "mul_used", 0
++/* [0x000012d0] */ 0x40072031, 0xdc0109e3, // nop ; mul24.ifn r3, ra1.8c << 14, r1 << 14 @ "mul_used", 0
++/* [0x000012d8] */ 0x4c0794f0, 0xde0248a3, // add r2, r2, r3 ; mul24 r3, ra1.8d << 7, r0 << 7 @ "mul_used", 0
++/* [0x000012e0] */ 0x4c071b71, 0xde0329e3, // add.setf -, r5, r5 ; mul24.ifn r3, ra1.8d << 15, r1 << 15 @ "mul_used", 0
++/* [0x000012e8] */ 0xffffff08, 0xf06809e7, // brr.anyn -, r:1b
++/* [0x000012f0] */ 0x4d0854fe, 0x1a0248a1, // sub r2, r2, r3 ; mul24 r1, rb5, ra2.8b
++/* [0x000012f8] */ 0x550caffe, 0x1a024260, // mov ra9, rb10 ; mul24 r0, rb10, ra3.8b
++/* [0x00001300] */ 0x8f2c05f6, 0xd00242ca, // asr ra11, r2, v_bit_depth - 8 ; mov rb10, ra11
++/* [0x00001308] */ 0x4d08623e, 0x1c024860, // sub r1, r1, r0 ; mul24 r0, rb6, ra2.8c
++/* [0x00001310] */ 0x4d08723e, 0x1e024860, // sub r1, r1, r0 ; mul24 r0, rb7, ra2.8d
++/* [0x00001318] */ 0x4c208237, 0x10024860, // add r1, r1, r0 ; mul24 r0, ra8, rb8
++/* [0x00001320] */ 0x4c0ca23e, 0x1c024860, // add r1, r1, r0 ; mul24 r0, rb10, ra3.8c
++/* [0x00001328] */ 0x4c2cb237, 0x10024860, // add r1, r1, r0 ; mul24 r0, ra11, rb11
++/* [0x00001330] */ 0x0d127380, 0x10020867, // sub r1, r1, ra4
++/* [0x00001338] */ 0x8d9cc23f, 0x10024862, // sub r1, r1, r0 ; mov r2, rb_wt_off
++/* [0x00001340] */ 0x0f9c63c0, 0xd0020867, // asr r1, r1, 6
++/* [0x00001348] */ 0x4d591bce, 0x120269e0, // sub.setf -, r5, rb_i_tmu ; mul24 r0, r1, ra_wt_mul_l0
++/* [0x00001350] */ 0x55653fce, 0x140453e1, // mov.ifz rb_base2, rb_base2_next ; mul24 r1, r1, ra_kmul_add
++/* [0x00001358] */ 0x8d4e7076, 0x10029851, // sub r1, r0, r1 ; mov.ifz ra_y_y2, ra_y_y2_next
++/* [0x00001360] */ 0x8d692bf6, 0x1002b9d8, // sub.setf -, r5, rb_lcount ; mov.ifz ra_base, ra_base_next
++/* [0x00001368] */ 0x8c9f8289, 0xd0024860, // add r1, r1, r2 ; mov r0, r1 << 8
++/* [0x00001370] */ 0x8c5e7236, 0x1c024863, // add r1, r1, r0 ; mov r3, ra_blk_height
++/* [0x00001378] */ 0xfffffe78, 0xf06809e7, // brr.anyn -, r:1b
++/* [0x00001380] */ 0x4f65039f, 0x18024862, // asr r1, r1, ra_wt_den_p7 ; mul24 r2, r3, rb_pitch
++/* [0x00001388] */ 0x925f23bf, 0x12020867, // min r1, r1, ra_pmax ; mov -, vw_wait
++/* [0x00001390] */ 0xf34003f3, 0xd2024c20, // max vpm, r1, 0 ; v8subs r0, ra_height, r3
++/* [0x00001398] */ 0x956e7036, 0x10126431, // mov.setf ra_height, r0 ; mov vw_setup, ra_dma0
++/* [0x000013a0] */ 0x00000000, 0xf027c9e7, // bra.anyz -, ra_link
++/* [0x000013a8] */ 0x929dd0ff, 0x10024831, // min r0, r0, r3 ; mov vw_setup, rb_dma1
++/* [0x000013b0] */ 0x8d7270f6, 0x10024872, // sub r1, r0, r3 ; mov vw_addr, ra_dest
++/* [0x000013b8] */ 0x119d73c0, 0xd0020867, // shl r1, r1, i_shift23
++/* [0x000013c0] */ 0xfffffe30, 0xf0f809e7, // brr -, r:1b
++/* [0x000013c8] */ 0x0c9d2e00, 0x100214a7, // add rb_lcount, rb_lcount, r0
++/* [0x000013d0] */ 0x0c6e7c40, 0x100206e7, // add ra_dma0, ra_dma0, r1
++/* [0x000013d8] */ 0x8c71ccbf, 0x10024731, // add ra_dest, ra_dest, r2 ; mov vw_setup, rb_vpm_init
++// ::mc_filter_y_p00
++/* [0x000013e0] */ 0x959a0ff6, 0x10024020, // mov ra0, unif ; mov r0, elem_num
++/* [0x000013e8] */ 0xf5567dad, 0x14124565, // mov ra_xshift, ra_xshift_next ; v8subs r5rep, r5, r5
++/* [0x000013f0] */ 0x8c020c3f, 0x1402581a, // add r0, ra0.16b, r0 ; mov ra_base_next, unif
++/* [0x000013f8] */ 0x93027176, 0x12225813, // max r0, r0, r5 ; mov ra_y_next, ra0.16a
++/* [0x00001400] */ 0x9281a1f6, 0x10025810, // min r0, r0, rb_max_x ; mov ra_width_height, unif
++/* [0x00001408] */ 0x119c31c0, 0xd0220567, // shl ra_xshift_next, r0, 3
++/* [0x00001410] */ 0x149dc1c0, 0xd0020827, // and r0, r0, -4
++/* [0x00001418] */ 0x8d810bf6, 0x10025896, // sub r2, r5, rb_pitch ; mov ra_wt_off_mul_l0, unif
++/* [0x00001420] */ 0x149e7080, 0x10020867, // and r1, r0, r2
++/* [0x00001428] */ 0x569d404f, 0x10024821, // xor r0, r0, r1 ; mul24 r1, r1, rb_xpitch
++/* [0x00001430] */ 0x8c827076, 0x1002581c, // add r0, r0, r1 ; mov ra_dest, unif
++/* [0x00001438] */ 0x8c69cc3f, 0x100246b1, // add ra_base_next, ra_base_next, r0 ; mov vw_setup, rb_vpm_init
++/* [0x00001440] */ 0x11400dc0, 0xd4020867, // shl r1, ra_width, v_x_shift
++/* [0x00001448] */ 0x8d419e76, 0x12025760, // sub rb_dma1, rb_dma1_base, r1 ; mov r0, ra_height
++/* [0x00001450] */ 0x8d5c31c6, 0xdc025460, // sub rb_i_tmu, r0, PREREAD ; v8min r0, r0, ra_blk_height
++/* [0x00001458] */ 0x919c71c0, 0xd0024812, // shl r0, r0, v_dma_h_shift ; mov rb_lcount, r0
++/* [0x00001460] */ 0x0c9e7040, 0x10020827, // add r0, r0, r1
++/* [0x00001468] */ 0x1158edc0, 0xd4021327, // shl rb_wt_off, ra_wt_off_l0, DENOM + 7
++/* [0x00001470] */ 0x918101f6, 0xd002581e, // shl r0, r0, v_dma_wh_shift ; mov ra_link, unif
++/* [0x00001478] */ 0x0c9db1c0, 0x100206e7, // add ra_dma0, r0, rb_dma0_base
++// :1
++/* [0x00001480] */ 0xcd511bee, 0x1a0269e5, // sub.setf -, r5, rb_i_tmu ; v8adds r5rep, r5, ra_k1
++/* [0x00001488] */ 0x804e7036, 0xa42099d1, // nop ; mov.ifz ra_y, ra_y_next ; ldtmu0
++/* [0x00001490] */ 0x8e5509bf, 0x12024823, // shr r0, r4, ra_xshift ; mov r3, rb_pitch
++/* [0x00001498] */ 0x13440dc0, 0xd40208a7, // max r2, ra_y, 0
++/* [0x000014a0] */ 0x9269e5f6, 0x10029898, // min r2, r2, rb_max_y ; mov.ifz ra_base, ra_base_next
++/* [0x000014a8] */ 0x4c441dd3, 0xd4224462, // add ra_y, ra_y, 1 ; mul24 r2, r2, r3
++/* [0x000014b0] */ 0x8c618c87, 0x10024e20, // add t0s, ra_base, r2 ; v8min r0, r0, rb_pmask
++/* [0x000014b8] */ 0x4d592bc6, 0x120269e1, // sub.setf -, r5, rb_lcount ; mul24 r1, r0, ra_wt_mul_l0
++/* [0x000014c0] */ 0x915c83f6, 0xdc024863, // shl r1, r1, 8 ; mov r3, ra_blk_height
++/* [0x000014c8] */ 0xec40c3f3, 0x12024860, // add r1, r1, rb_wt_off ; v8subs r0, ra_height, r3
++/* [0x000014d0] */ 0xffffff90, 0xf06809e7, // brr.anyn -, r:1b
++/* [0x000014d8] */ 0x0f9cf3c0, 0xd0020867, // asr r1, r1, DENOM + 8
++/* [0x000014e0] */ 0x925f23bf, 0x12020867, // min r1, r1, ra_pmax ; mov -, vw_wait
++/* [0x000014e8] */ 0x5351039f, 0x18024c22, // max vpm, r1, ra_k0 ; mul24 r2, r3, rb_pitch
++/* [0x000014f0] */ 0x956e7036, 0x10126431, // mov.setf ra_height, r0 ; mov vw_setup, ra_dma0
++/* [0x000014f8] */ 0x00000000, 0xf027c9e7, // bra.anyz -, ra_link
++/* [0x00001500] */ 0x929dd0ff, 0x10024831, // min r0, r0, r3 ; mov vw_setup, rb_dma1
++/* [0x00001508] */ 0x8d7270f6, 0x10024872, // sub r1, r0, r3 ; mov vw_addr, ra_dest
++/* [0x00001510] */ 0x119d73c0, 0xd0020867, // shl r1, r1, i_shift23
++/* [0x00001518] */ 0xffffff48, 0xf0f809e7, // brr -, r:1b
++/* [0x00001520] */ 0x0c9d2e00, 0x100214a7, // add rb_lcount, rb_lcount, r0
++/* [0x00001528] */ 0x0c6e7c40, 0x100206e7, // add ra_dma0, ra_dma0, r1
++/* [0x00001530] */ 0x8c71ccbf, 0x10024731, // add ra_dest, ra_dest, r2 ; mov vw_setup, rb_vpm_init
++// ::mc_filter_y_b00
++/* [0x00001538] */ 0xfffff8f8, 0xf0f807a7, // brr ra_link, r:per_block_setup_8
++/* [0x00001540] */ 0x959a0ff6, 0x10024023, // mov ra0, unif ; mov r3, elem_num
++/* [0x00001548] */ 0xec9c3fd2, 0x100269e5, // add.setf -, rb_ef, rb_ef ; v8subs r5rep, r2, r2
++/* [0x00001550] */ 0x8c001cff, 0x14024800, // add r0, ra0.16b, r3 ; mov rb_xshift2, rb_xshift2_next
++/* [0x00001558] */ 0x00000001, 0xe00208a7, // mov r2, 1
++/* [0x00001560] */ 0x8c591eb6, 0x10025461, // add rb_i_tmu, rb_i_tmu, r2 ; mov r1, ra_wt_off_mul_l0
++/* [0x00001568] */ 0xf158fded, 0xd4025325, // shl rb_wt_off, ra_wt_off_l0, DENOM + 8 ; v8subs r5quad, r5, r5
++/* [0x00001570] */ 0x809f8009, 0xd000d9d6, // nop ; mov.ifnz ra_wt_off_mul_l0, r1 << 8
++// :1
++/* [0x00001578] */ 0x0d9d1bc0, 0xb00229e7, // sub.setf -, r5, rb_i_tmu ; nop ; ldtmu1
++/* [0x00001580] */ 0x8e4c09f6, 0xa0029851, // shr r1, r4, rb_xshift2 ; mov.ifz ra_y_y2, ra_y_y2_next ; ldtmu0
++/* [0x00001588] */ 0x8e5509bf, 0x12024823, // shr r0, r4, ra_xshift ; mov r3, rb_pitch
++/* [0x00001590] */ 0x13440dc0, 0xd40208a7, // max r2, ra_y, 0
++/* [0x00001598] */ 0x9269e5f6, 0x10029898, // min r2, r2, rb_max_y ; mov.ifz ra_base, ra_base_next
++/* [0x000015a0] */ 0x4c441dd3, 0xd4224462, // add ra_y, ra_y, 1 ; mul24 r2, r2, r3
++/* [0x000015a8] */ 0x8c613cbf, 0x10028e0f, // add t0s, ra_base, r2 ; mov.ifz rb_base2, rb_base2_next
++/* [0x000015b0] */ 0x13440dc0, 0xd20208a7, // max r2, ra_y2, 0
++/* [0x000015b8] */ 0x129de5c0, 0x100208a7, // min r2, r2, rb_max_y
++/* [0x000015c0] */ 0x4c441dd3, 0xd2124462, // add ra_y2, ra_y2, 1 ; mul24 r2, r2, r3
++/* [0x000015c8] */ 0x8c5cfe86, 0x12024f20, // add t1s, rb_base2, r2 ; v8min r0, r0, ra_pmax
++/* [0x000015d0] */ 0x545983c6, 0x12024860, // and r1, r1, rb_pmask ; mul24 r0, r0, ra_wt_mul_l0
++/* [0x000015d8] */ 0x4d492bce, 0x120269e1, // sub.setf -, r5, rb_lcount ; mul24 r1, r1, ra_wt_mul_l1
++/* [0x000015e0] */ 0xcc52706e, 0x1a024865, // add r1, r0, r1 ; v8adds r5rep, r5, ra_k1
++/* [0x000015e8] */ 0x915c83f6, 0xdc024863, // shl r1, r1, 8 ; mov r3, ra_blk_height
++/* [0x000015f0] */ 0xec40c3f3, 0x12024860, // add r1, r1, rb_wt_off ; v8subs r0, ra_height, r3
++/* [0x000015f8] */ 0xffffff60, 0xf06809e7, // brr.anyn -, r:1b
++/* [0x00001600] */ 0x0f9d03c0, 0xd0020867, // asr r1, r1, (DENOM + 9) - 32
++/* [0x00001608] */ 0x925f23bf, 0x12020867, // min r1, r1, ra_pmax ; mov -, vw_wait
++/* [0x00001610] */ 0x5351039f, 0x18024c22, // max vpm, r1, ra_k0 ; mul24 r2, r3, rb_pitch
++/* [0x00001618] */ 0x956e7036, 0x10126431, // mov.setf ra_height, r0 ; mov vw_setup, ra_dma0
++/* [0x00001620] */ 0x00000000, 0xf027c9e7, // bra.anyz -, ra_link
++/* [0x00001628] */ 0x929dd0ff, 0x10024831, // min r0, r0, r3 ; mov vw_setup, rb_dma1
++/* [0x00001630] */ 0x8d7270f6, 0x10024872, // sub r1, r0, r3 ; mov vw_addr, ra_dest
++/* [0x00001638] */ 0x119d73c0, 0xd0020867, // shl r1, r1, i_shift23
++/* [0x00001640] */ 0xffffff18, 0xf0f809e7, // brr -, r:1b
++/* [0x00001648] */ 0x0c9d2e00, 0x100214a7, // add rb_lcount, rb_lcount, r0
++/* [0x00001650] */ 0x0c6e7c40, 0x100206e7, // add ra_dma0, ra_dma0, r1
++/* [0x00001658] */ 0x8c71ccbf, 0x10024731, // add ra_dest, ra_dest, r2 ; mov vw_setup, rb_vpm_init
++// ::mc_setup_c10_q0
++/* [0x00001660] */ 0x0000000c, 0xe80009e7, // mov dst, srel(i)
++// ::mc_setup_c10_qn
++/* [0x00001668] */ 0x95801ff6, 0xd0025900, // mov tmurs, 1 ; mov ra0, unif
++/* [0x00001670] */ 0xaaaaff00, 0xe6020827, // mov r0, [0,2,0,2,0,2,0,2,1,3,1,3,1,3,1,3]
++/* [0x00001678] */ 0x9181e1f6, 0xd00250d8, // shl rb_ef, r0, i_shift30 ; mov ra_base, unif
++/* [0x00001680] */ 0x0d801dc0, 0xd0020827, // sub r0, unif, 1
++/* [0x00001688] */ 0x119c21c0, 0xd00216a7, // shl rb_max_x, r0, v_x_shift
++/* [0x00001690] */ 0x0d801dc0, 0xd00217a7, // sub rb_max_y, unif, 1
++/* [0x00001698] */ 0xff800100, 0xe0020527, // mov ra_kff800100, 0xff800100
++/* [0x000016a0] */ 0x0000ffff, 0xe0021627, // mov rb_pmask, v_pmask
++/* [0x000016a8] */ 0x000803ff, 0xe00205e7, // mov ra_blk_height_pmax, ((1 << v_bit_depth) - 1) | (v_blk_height << 16)
++/* [0x000016b0] */ 0x00010000, 0xe00217e7, // mov rb_fir_off_h, (FIR_OFFSET << (v_bit_depth - 8))
++/* [0x000016b8] */ 0x4000000c, 0xe0020667, // mov ra_fir_off_val_wt_den_p7, (FIR_OFFSET << 16) | (DENOM + 15 - v_bit_depth)
++/* [0x000016c0] */ 0x95803ff6, 0x10024754, // mov ra_ef, rb_ef ; mov rb_xpitch, unif
++/* [0x000016c8] */ 0x15827d80, 0x10021427, // mov rb_pitch, unif
++/* [0x000016d0] */ 0xc0000000, 0xe0020867, // mov r1, vdw_setup_1(0)
++/* [0x000016d8] */ 0x0c9d03c0, 0x10021667, // add rb_dma1_base, r1, rb_pitch
++/* [0x000016e0] */ 0x14981f80, 0xd0020827, // and r0, 1, elem_num
++/* [0x000016e8] */ 0x409c5007, 0xd00049e0, // nop ; mul24 r0, r0, 5
++/* [0x000016f0] */ 0x0c9a7180, 0x10020827, // add r0, r0, elem_num
++/* [0x000016f8] */ 0x0c9e7000, 0x100210a7, // add rb_elem_x, r0, r0
++/* [0x00001700] */ 0x11002dc0, 0xd4020827, // shl r0, ra0.16b, v_x_shift
++/* [0x00001708] */ 0x0c9c21c0, 0x10020827, // add r0, r0, rb_elem_x
++/* [0x00001710] */ 0x930001f6, 0xd2225811, // max r0, r0, 0 ; mov ra_y, ra0.16a
++/* [0x00001718] */ 0x129da1c0, 0x10020827, // min r0, r0, rb_max_x
++/* [0x00001720] */ 0x00000000, 0xe0224541, // mov ra_xshift_next, 0 ; mov rb_xshift2_next, 0
++/* [0x00001728] */ 0x0d510dc0, 0x18020867, // sub r1, ra_k0, rb_pitch
++/* [0x00001730] */ 0x149e7040, 0x10020867, // and r1, r0, r1
++/* [0x00001738] */ 0x569d404f, 0x10024821, // xor r0, r0, r1 ; mul24 r1, r1, rb_xpitch
++/* [0x00001740] */ 0x8c827076, 0x10025800, // add r0, r0, r1 ; mov ra0, unif
++/* [0x00001748] */ 0x0c627c00, 0x10020627, // add ra_base, ra_base, r0
++/* [0x00001750] */ 0x159e6fc0, 0x100208a7, // mov r2, qpu_num
++/* [0x00001758] */ 0x0f9c15c0, 0xd0020867, // asr r1, r2, 1
++/* [0x00001760] */ 0x119c43c0, 0xd0020867, // shl r1, r1, 4
++/* [0x00001768] */ 0x149c15c0, 0xd0020827, // and r0, r2, 1
++/* [0x00001770] */ 0x159e7040, 0x10020827, // or r0, r0, r1
++/* [0x00001778] */ 0x00002900, 0xe0020867, // mov r1, vpm_setup(0, 2, h16p(0, 0))
++/* [0x00001780] */ 0x0c9e7040, 0x10021727, // add r_vpm, r0, r1
++/* [0x00001788] */ 0x80004002, 0xe0020867, // mov r1, vdw_setup_0(0, 0, dma_h16p(0,0,0))
++/* [0x00001790] */ 0x119c61c0, 0xd0020827, // shl r0, r0, 6
++/* [0x00001798] */ 0x0c9e7040, 0x100216e7, // add r_dma, r0, r1
++/* [0x000017a0] */ 0x11002dc0, 0xd4020827, // shl r0, ra0.16b, v_x_shift
++/* [0x000017a8] */ 0x8c0021f6, 0x12125811, // add r0, r0, rb_elem_x ; mov ra_y2, ra0.16a
++/* [0x000017b0] */ 0x938001f6, 0xd002480f, // max r0, r0, 0 ; mov rb_base2, unif
++/* [0x000017b8] */ 0x129da1c0, 0x10020827, // min r0, r0, rb_max_x
++/* [0x000017c0] */ 0x0d510dc0, 0x18020867, // sub r1, ra_k0, rb_pitch
++/* [0x000017c8] */ 0x949c307f, 0xd0024863, // and r1, r0, r1 ; mov r3, PREREAD
++/* [0x000017d0] */ 0x569d404f, 0x10024821, // xor r0, r0, r1 ; mul24 r1, r1, rb_xpitch
++/* [0x000017d8] */ 0x8c467076, 0x12024822, // add r0, r0, r1 ; mov r2, ra_y2
++/* [0x000017e0] */ 0x8c44fe36, 0x140253e0, // add rb_base2, rb_base2, r0 ; mov r0, ra_y
++// :1
++/* [0x000017e8] */ 0x0d9c17c0, 0xd00228e7, // sub.setf r3, r3, 1
++/* [0x000017f0] */ 0x139c01c0, 0xd0020867, // max r1, r0, 0
++/* [0x000017f8] */ 0x129de3c0, 0x10020867, // min r1, r1, rb_max_y
++/* [0x00001800] */ 0x4c51018f, 0x1a024821, // add r0, r0, ra_k1 ; mul24 r1, r1, rb_pitch
++/* [0x00001808] */ 0x8c627c40, 0x10225e11, // add t0s, ra_base, r1 ; mov ra_y, r0
++/* [0x00001810] */ 0x139c05c0, 0xd0020867, // max r1, r2, 0
++/* [0x00001818] */ 0xffffffb0, 0xf03809e7, // brr.anynz -, r:1b
++/* [0x00001820] */ 0x129de3c0, 0x10020867, // min r1, r1, rb_max_y
++/* [0x00001828] */ 0x4c51058f, 0x1a0248a1, // add r2, r2, ra_k1 ; mul24 r1, r1, rb_pitch
++/* [0x00001830] */ 0x8c9cfe52, 0x10125f11, // add t1s, rb_base2, r1 ; mov ra_y2, r2
++/* [0x00001838] */ 0x15827d80, 0x100207a7, // mov ra_link, unif
++/* [0x00001840] */ 0x00000000, 0xe0024104, // mov ra4, 0 ; mov rb4, 0
++/* [0x00001848] */ 0x00000000, 0xf0f7c9e7, // bra -, ra_link
++/* [0x00001850] */ 0x00000000, 0xe0024145, // mov ra5, 0 ; mov rb5, 0
++/* [0x00001858] */ 0x00000000, 0xe0024186, // mov ra6, 0 ; mov rb6, 0
++/* [0x00001860] */ 0x00000000, 0xe00241c7, // mov ra7, 0 ; mov rb7, 0
++// ::mc_filter_c10_p
++/* [0x00001868] */ 0x9581cff6, 0x10025c42, // mov vw_setup, rb_vpm_init ; mov ra2, unif
++/* [0x00001870] */ 0x8c803ff6, 0x100269e3, // add.setf -, rb_ef, rb_ef ; mov r3, unif
++/* [0x00001878] */ 0xf1082dc0, 0xd4024825, // shl r0, ra2.16b, v_x_shift ; v8subs r5rep, r0, r0
++/* [0x00001880] */ 0x8c8021f6, 0x10025810, // add r0, r0, rb_elem_x ; mov ra_width_height, unif
++/* [0x00001888] */ 0x8d810bf6, 0x10025840, // sub r1, r5, rb_pitch ; mov ra0, unif
++/* [0x00001890] */ 0x93567176, 0x14024800, // max r0, r0, r5 ; mov vrx_xshift, vrx_xshift_next
++/* [0x00001898] */ 0x9209a1f6, 0x12225813, // min r0, r0, rb_max_x ; mov vra_y_next, ra2.16a
++/* [0x000018a0] */ 0x54404077, 0xd4024862, // and r1, r0, r1 ; mul24 r2, ra_width, v_x_mul
++/* [0x000018a8] */ 0x569d404f, 0x10024821, // xor r0, r0, r1 ; mul24 r1, r1, rb_xpitch
++/* [0x000018b0] */ 0x8c827076, 0x10025803, // add r0, r0, r1 ; mov ra3, unif
++/* [0x000018b8] */ 0x8c427636, 0x120246a1, // add vrx_base_next, r3, r0 ; mov r1, ra_height
++/* [0x000018c0] */ 0x8d819eb6, 0x10025756, // sub rb_dma1, rb_dma1_base, r2 ; mov ra_wt_off_mul_l0, unif
++/* [0x000018c8] */ 0x8c5dc3ce, 0xdc025461, // add rb_i_tmu, r1, (3-4) - PREREAD ; v8min r1, r1, ra_blk_height
++/* [0x000018d0] */ 0x8c81f3f6, 0xd0039496, // add rb_lcount, r1, (3-4) ; mov.ifc ra_wt_off_mul_l0, unif
++/* [0x000018d8] */ 0x918083f6, 0xd002581c, // shl r0, r1, v_dma_h_shift ; mov ra_dest, unif
++/* [0x000018e0] */ 0x8c6670b6, 0x14024822, // add r0, r0, r2 ; mov r2, ra_fir_off_val
++/* [0x000018e8] */ 0x910cf1f6, 0xdc02480a, // shl r0, r0, v_dma_wh_shift ; mov rb10, ra3.8c
++/* [0x000018f0] */ 0x8c59b1f6, 0x140246e1, // add ra_dma0, r0, rb_dma0_base ; mov r1, ra_wt_off_l0
++/* [0x000018f8] */ 0x5158a3d6, 0xd2024860, // shl r1, r1, i_wt_den_p5 ; mul24 r0, r2, ra_wt_mul_l0
++/* [0x00001900] */ 0x8d667236, 0x14025320, // sub rb_wt_off, r1, r0 ; mov r0, ra_kmul_add
++/* [0x00001908] */ 0x8c59cc3f, 0xd21245a5, // add ra_wt_mul_l0, ra_wt_mul_l0, r0 ; mov r5rep, -4
++/* [0x00001910] */ 0x950e0dbf, 0x1e0252de, // mov rb11, ra3.8d ; mov ra_link, unif
++// :1
++/* [0x00001918] */ 0x8d151bf6, 0xa00269c4, // sub.setf -, r5, rb_i_tmu ; mov rb4, ra5 ; ldtmu0
++/* [0x00001920] */ 0x8e4c09f6, 0x140288a3, // shr r2, r4, vrx_xshift ; mov.ifz r3, vra_y_next
++/* [0x00001928] */ 0x8e4505f6, 0xd402c863, // shr r1, r2, v_v_shift ; mov.ifnz r3, vra_y
++/* [0x00001930] */ 0x8c683ff6, 0x1002b9d8, // add.setf -, rb_ef, rb_ef ; mov.ifz vra_base, vrx_base_next
++/* [0x00001938] */ 0x8c531789, 0xda224460, // add vra_y, r3, ra_k1 ; mov r0, r1 << 15
++/* [0x00001940] */ 0x9353f792, 0xd803c8e1, // max r3, r3, ra_k0 ; mov.ifnc r1, r2 << 1
++/* [0x00001948] */ 0x929de7d2, 0x1003c8e0, // min r3, r3, rb_max_y ; mov.ifnc r0, r2
++/* [0x00001950] */ 0x545d039f, 0x12024863, // and r1, r1, ra_pmax ; mul24 r3, r3, rb_pitch
++/* [0x00001958] */ 0x8c618cc7, 0x10024e20, // add vr_txs, vra_base, r3 ; v8min r0, r0, rb_pmask
++/* [0x00001960] */ 0x4c001bf0, 0xd8025963, // add r5rep, r5, 1 ; mul24 r3, ra0.8a, r0
++/* [0x00001968] */ 0x4d01fef1, 0x1e0248a3, // sub r2, rb_fir_off_h, r3 ; mul24 r3, ra0.8d, r1
++/* [0x00001970] */ 0x4d03e4f0, 0xda0248a3, // sub r2, r2, r3 ; mul24 r3, ra0.8b << 2, r0 << 2 @ "mul_used", 0
++/* [0x00001978] */ 0x40034031, 0xda0109e3, // nop ; mul24.ifn r3, ra0.8b << 12, r1 << 12 @ "mul_used", 0
++/* [0x00001980] */ 0x4c03c4f0, 0xdc0248a3, // add r2, r2, r3 ; mul24 r3, ra0.8c << 4, r0 << 4 @ "mul_used", 0
++/* [0x00001988] */ 0x4c032b71, 0xdc0329e3, // add.setf -, r5, r5 ; mul24.ifn r3, ra0.8c << 14, r1 << 14 @ "mul_used", 0
++/* [0x00001990] */ 0xffffff68, 0xf06809e7, // brr.anyn -, r:1b
++/* [0x00001998] */ 0x4c1ca4f7, 0x100248a0, // add r2, r2, r3 ; mul24 r0, ra7, rb10
++/* [0x000019a0] */ 0x550c6ffe, 0x1a024161, // mov ra5, rb6 ; mul24 r1, rb6, ra3.8b
++/* [0x000019a8] */ 0x8f1c25f6, 0xd00241c6, // asr ra7, r2, v_bit_depth - 8 ; mov rb6, ra7
++/* [0x000019b0] */ 0x4c0c423e, 0x18024860, // add r1, r1, r0 ; mul24 r0, rb4, ra3.8a
++/* [0x000019b8] */ 0x4d1cb237, 0x10024860, // sub r1, r1, r0 ; mul24 r0, ra7, rb11
++/* [0x000019c0] */ 0x0d9e7200, 0x10020867, // sub r1, r1, r0
++/* [0x000019c8] */ 0x8f5c63f6, 0xdc024863, // asr r1, r1, 6 ; mov r3, ra_blk_height
++/* [0x000019d0] */ 0x4d592bce, 0x120269e0, // sub.setf -, r5, rb_lcount ; mul24 r0, r1, ra_wt_mul_l0
++/* [0x000019d8] */ 0x4c64c1ce, 0x14024821, // add r0, r0, rb_wt_off ; mul24 r1, r1, ra_kmul_add
++/* [0x000019e0] */ 0xed427073, 0x12024860, // sub r1, r0, r1 ; v8subs r0, ra_height, r3
++/* [0x000019e8] */ 0xffffff10, 0xf06809e7, // brr.anyn -, r:1b
++/* [0x000019f0] */ 0x0f9cb3c0, 0xd0020867, // asr r1, r1, i_wt_den_p6
++/* [0x000019f8] */ 0x925f23bf, 0x12020867, // min r1, r1, ra_pmax ; mov -, vw_wait
++/* [0x00001a00] */ 0x5351039f, 0x18024c22, // max vpm, r1, ra_k0 ; mul24 r2, r3, rb_pitch
++/* [0x00001a08] */ 0x956e7036, 0x10126431, // mov.setf ra_height, r0 ; mov vw_setup, ra_dma0
++/* [0x00001a10] */ 0x00000000, 0xf027c9e7, // bra.anyz -, ra_link
++/* [0x00001a18] */ 0x929dd0ff, 0x10024831, // min r0, r0, r3 ; mov vw_setup, rb_dma1
++/* [0x00001a20] */ 0x8d7270f6, 0x10024872, // sub r1, r0, r3 ; mov vw_addr, ra_dest
++/* [0x00001a28] */ 0x119d73c0, 0xd0020867, // shl r1, r1, i_shift23
++/* [0x00001a30] */ 0xfffffec8, 0xf0f809e7, // brr -, r:1b
++/* [0x00001a38] */ 0x0c9d2e00, 0x100214a7, // add rb_lcount, rb_lcount, r0
++/* [0x00001a40] */ 0x0c6e7c40, 0x100206e7, // add ra_dma0, ra_dma0, r1
++/* [0x00001a48] */ 0x8c71ccbf, 0x10024731, // add ra_dest, ra_dest, r2 ; mov vw_setup, rb_vpm_init
++// ::mc_filter_c10_p_l1
++/* [0x00001a50] */ 0x9581cff6, 0x10025c42, // mov vw_setup, rb_vpm_init ; mov ra2, unif
++/* [0x00001a58] */ 0x8c803ff6, 0x100269e3, // add.setf -, rb_ef, rb_ef ; mov r3, unif
++/* [0x00001a60] */ 0xf1082dc0, 0xd4024825, // shl r0, ra2.16b, v_x_shift ; v8subs r5rep, r0, r0
++/* [0x00001a68] */ 0x8c8021f6, 0x10025810, // add r0, r0, rb_elem_x ; mov ra_width_height, unif
++/* [0x00001a70] */ 0x8d810bf6, 0x10025840, // sub r1, r5, rb_pitch ; mov ra0, unif
++/* [0x00001a78] */ 0x939c117f, 0x10125815, // max r0, r0, r5 ; mov vrx_xshift, vrx_xshift_next
++/* [0x00001a80] */ 0x9209a1f6, 0x12125813, // min r0, r0, rb_max_x ; mov vra_y_next, ra2.16a
++/* [0x00001a88] */ 0x54404077, 0xd4024862, // and r1, r0, r1 ; mul24 r2, ra_width, v_x_mul
++/* [0x00001a90] */ 0x569d404f, 0x10024821, // xor r0, r0, r1 ; mul24 r1, r1, rb_xpitch
++/* [0x00001a98] */ 0x8c827076, 0x10025803, // add r0, r0, r1 ; mov ra3, unif
++/* [0x00001aa0] */ 0x8c427636, 0x120254e1, // add vrx_base_next, r3, r0 ; mov r1, ra_height
++/* [0x00001aa8] */ 0x8d819eb6, 0x10025756, // sub rb_dma1, rb_dma1_base, r2 ; mov ra_wt_off_mul_l0, unif
++/* [0x00001ab0] */ 0x8c5dc3ce, 0xdc025461, // add rb_i_tmu, r1, (3-4) - PREREAD ; v8min r1, r1, ra_blk_height
++/* [0x00001ab8] */ 0x8c81f3f6, 0xd0039496, // add rb_lcount, r1, (3-4) ; mov.ifc ra_wt_off_mul_l0, unif
++/* [0x00001ac0] */ 0x918083f6, 0xd002581c, // shl r0, r1, v_dma_h_shift ; mov ra_dest, unif
++/* [0x00001ac8] */ 0x8c6670b6, 0x14024822, // add r0, r0, r2 ; mov r2, ra_fir_off_val
++/* [0x00001ad0] */ 0x910cf1f6, 0xdc02480a, // shl r0, r0, v_dma_wh_shift ; mov rb10, ra3.8c
++/* [0x00001ad8] */ 0x8c59b1f6, 0x140246e1, // add ra_dma0, r0, rb_dma0_base ; mov r1, ra_wt_off_l0
++/* [0x00001ae0] */ 0x5158a3d6, 0xd2024860, // shl r1, r1, i_wt_den_p5 ; mul24 r0, r2, ra_wt_mul_l0
++/* [0x00001ae8] */ 0x8d667236, 0x14025320, // sub rb_wt_off, r1, r0 ; mov r0, ra_kmul_add
++/* [0x00001af0] */ 0x8c59cc3f, 0xd21245a5, // add ra_wt_mul_l0, ra_wt_mul_l0, r0 ; mov r5rep, -4
++/* [0x00001af8] */ 0x950e0dbf, 0x1e0252de, // mov rb11, ra3.8d ; mov ra_link, unif
++// :1
++/* [0x00001b00] */ 0x8d151bf6, 0xb00269c4, // sub.setf -, r5, rb_i_tmu ; mov rb4, ra5 ; ldtmu1
++/* [0x00001b08] */ 0x8e5539bf, 0x1202888f, // shr r2, r4, vrx_xshift ; mov.ifz vra_base, vrx_base_next
++/* [0x00001b10] */ 0x8e4505f6, 0xd202c863, // shr r1, r2, v_v_shift ; mov.ifnz r3, vra_y
++/* [0x00001b18] */ 0x8c4c3ff6, 0x1202a9e3, // add.setf -, rb_ef, rb_ef ; mov.ifz r3, vra_y_next
++/* [0x00001b20] */ 0x8c531789, 0xda124460, // add vra_y, r3, ra_k1 ; mov r0, r1 << 15
++/* [0x00001b28] */ 0x9353f792, 0xd803c8e1, // max r3, r3, ra_k0 ; mov.ifnc r1, r2 << 1
++/* [0x00001b30] */ 0x929de7d2, 0x1003c8e0, // min r3, r3, rb_max_y ; mov.ifnc r0, r2
++/* [0x00001b38] */ 0x545d039f, 0x12024863, // and r1, r1, ra_pmax ; mul24 r3, r3, rb_pitch
++/* [0x00001b40] */ 0x8c5cfec6, 0x12024f20, // add vr_txs, vra_base, r3 ; v8min r0, r0, ra_pmax
++/* [0x00001b48] */ 0x4c001bf0, 0xd8025963, // add r5rep, r5, 1 ; mul24 r3, ra0.8a, r0
++/* [0x00001b50] */ 0x4d01fef1, 0x1e0248a3, // sub r2, rb_fir_off_h, r3 ; mul24 r3, ra0.8d, r1
++/* [0x00001b58] */ 0x4d03e4f0, 0xda0248a3, // sub r2, r2, r3 ; mul24 r3, ra0.8b << 2, r0 << 2 @ "mul_used", 0
++/* [0x00001b60] */ 0x40034031, 0xda0109e3, // nop ; mul24.ifn r3, ra0.8b << 12, r1 << 12 @ "mul_used", 0
++/* [0x00001b68] */ 0x4c03c4f0, 0xdc0248a3, // add r2, r2, r3 ; mul24 r3, ra0.8c << 4, r0 << 4 @ "mul_used", 0
++/* [0x00001b70] */ 0x4c032b71, 0xdc0329e3, // add.setf -, r5, r5 ; mul24.ifn r3, ra0.8c << 14, r1 << 14 @ "mul_used", 0
++/* [0x00001b78] */ 0xffffff68, 0xf06809e7, // brr.anyn -, r:1b
++/* [0x00001b80] */ 0x4c1ca4f7, 0x100248a0, // add r2, r2, r3 ; mul24 r0, ra7, rb10
++/* [0x00001b88] */ 0x550c6ffe, 0x1a024161, // mov ra5, rb6 ; mul24 r1, rb6, ra3.8b
++/* [0x00001b90] */ 0x8f1c25f6, 0xd00241c6, // asr ra7, r2, v_bit_depth - 8 ; mov rb6, ra7
++/* [0x00001b98] */ 0x4c0c423e, 0x18024860, // add r1, r1, r0 ; mul24 r0, rb4, ra3.8a
++/* [0x00001ba0] */ 0x4d1cb237, 0x10024860, // sub r1, r1, r0 ; mul24 r0, ra7, rb11
++/* [0x00001ba8] */ 0x0d9e7200, 0x10020867, // sub r1, r1, r0
++/* [0x00001bb0] */ 0x8f5c63f6, 0xdc024863, // asr r1, r1, 6 ; mov r3, ra_blk_height
++/* [0x00001bb8] */ 0x4d592bce, 0x120269e0, // sub.setf -, r5, rb_lcount ; mul24 r0, r1, ra_wt_mul_l0
++/* [0x00001bc0] */ 0x4c64c1ce, 0x14024821, // add r0, r0, rb_wt_off ; mul24 r1, r1, ra_kmul_add
++/* [0x00001bc8] */ 0xed427073, 0x12024860, // sub r1, r0, r1 ; v8subs r0, ra_height, r3
++/* [0x00001bd0] */ 0xffffff10, 0xf06809e7, // brr.anyn -, r:1b
++/* [0x00001bd8] */ 0x0f9cb3c0, 0xd0020867, // asr r1, r1, i_wt_den_p6
++/* [0x00001be0] */ 0x925f23bf, 0x12020867, // min r1, r1, ra_pmax ; mov -, vw_wait
++/* [0x00001be8] */ 0x5351039f, 0x18024c22, // max vpm, r1, ra_k0 ; mul24 r2, r3, rb_pitch
++/* [0x00001bf0] */ 0x956e7036, 0x10126431, // mov.setf ra_height, r0 ; mov vw_setup, ra_dma0
++/* [0x00001bf8] */ 0x00000000, 0xf027c9e7, // bra.anyz -, ra_link
++/* [0x00001c00] */ 0x929dd0ff, 0x10024831, // min r0, r0, r3 ; mov vw_setup, rb_dma1
++/* [0x00001c08] */ 0x8d7270f6, 0x10024872, // sub r1, r0, r3 ; mov vw_addr, ra_dest
++/* [0x00001c10] */ 0x119d73c0, 0xd0020867, // shl r1, r1, i_shift23
++/* [0x00001c18] */ 0xfffffec8, 0xf0f809e7, // brr -, r:1b
++/* [0x00001c20] */ 0x0c9d2e00, 0x100214a7, // add rb_lcount, rb_lcount, r0
++/* [0x00001c28] */ 0x0c6e7c40, 0x100206e7, // add ra_dma0, ra_dma0, r1
++/* [0x00001c30] */ 0x8c71ccbf, 0x10024731, // add ra_dest, ra_dest, r2 ; mov vw_setup, rb_vpm_init
++// ::mc_filter_c10_b
++/* [0x00001c38] */ 0x9581cff6, 0x10025c42, // mov vw_setup, rb_vpm_init ; mov ra2, unif
++/* [0x00001c40] */ 0x8c803ff6, 0x100269e3, // add.setf -, rb_ef, rb_ef ; mov r3, unif
++/* [0x00001c48] */ 0xf1082dc9, 0xd4024825, // shl r0, ra2.16b, v_x_shift ; v8subs r5rep, r1, r1
++/* [0x00001c50] */ 0x8c0821f6, 0x12225813, // add r0, r0, rb_elem_x ; mov ra_y_next, ra2.16a
++/* [0x00001c58] */ 0x8d810bf6, 0x10025850, // sub r1, r5, rb_pitch ; mov ra_width_height, unif
++/* [0x00001c60] */ 0x93567176, 0x14125815, // max r0, r0, r5 ; mov ra_xshift, ra_xshift_next
++/* [0x00001c68] */ 0x9281a1f6, 0x10025800, // min r0, r0, rb_max_x ; mov ra0, unif
++/* [0x00001c70] */ 0x9481c1f6, 0xd0025802, // and r0, r0, -4 ; mov ra2, unif
++/* [0x00001c78] */ 0x54404077, 0xd4024862, // and r1, r0, r1 ; mul24 r2, ra_width, v_x_mul
++/* [0x00001c80] */ 0x569d404f, 0x10024821, // xor r0, r0, r1 ; mul24 r1, r1, rb_xpitch
++/* [0x00001c88] */ 0x8c427076, 0x12024821, // add r0, r0, r1 ; mov r1, ra_height
++/* [0x00001c90] */ 0x8c9c163f, 0x10024680, // add ra_base_next, r3, r0 ; mov rb_xshift2, rb_xshift2_next
++/* [0x00001c98] */ 0x8d819eb6, 0x10025756, // sub rb_dma1, rb_dma1_base, r2 ; mov ra_wt_off_mul_l0, unif
++/* [0x00001ca0] */ 0x8c5dc3ce, 0xdc025461, // add rb_i_tmu, r1, (3-4) - PREREAD ; v8min r1, r1, ra_blk_height
++/* [0x00001ca8] */ 0x8c59f3f6, 0xd4139496, // add rb_lcount, r1, (3-4) ; mov.ifc ra_wt_mul_l0, ra_wt_off_l0
++/* [0x00001cb0] */ 0x918083f6, 0xd0025803, // shl r0, r1, v_dma_h_shift ; mov ra3, unif
++/* [0x00001cb8] */ 0x8c8270b6, 0x10024823, // add r0, r0, r2 ; mov r3, unif
++/* [0x00001cc0] */ 0x910cf1f6, 0xd2125813, // shl r0, r0, v_dma_wh_shift ; mov ra_y2_next, ra3.16a
++/* [0x00001cc8] */ 0x8c0db1f6, 0x140246e0, // add ra_dma0, r0, rb_dma0_base ; mov r0, ra3.16b
++/* [0x00001cd0] */ 0x918021f6, 0xd0025801, // shl r0, r0, v_x_shift ; mov ra1, unif
++/* [0x00001cd8] */ 0x8c8021f6, 0x10025803, // add r0, r0, rb_elem_x ; mov ra3, unif
++/* [0x00001ce0] */ 0x8d810bf6, 0x10025852, // sub r1, r5, rb_pitch ; mov ra_wt_off_mul_l1, unif
++/* [0x00001ce8] */ 0x939de17f, 0x10025809, // max r0, r0, r5 ; mov ra9, rb_max_y
++/* [0x00001cf0] */ 0x9265a1f6, 0x14024822, // min r0, r0, rb_max_x ; mov r2, ra_kmul_add
++/* [0x00001cf8] */ 0x9481c1f6, 0xd0039812, // and r0, r0, -4 ; mov.ifc ra_wt_off_mul_l1, unif
++/* [0x00001d00] */ 0x949dc07f, 0xd0024865, // and r1, r0, r1 ; mov r5rep, -4
++/* [0x00001d08] */ 0x569d404f, 0x10024821, // xor r0, r0, r1 ; mul24 r1, r1, rb_xpitch
++/* [0x00001d10] */ 0x8c827076, 0x1002581c, // add r0, r0, r1 ; mov ra_dest, unif
++/* [0x00001d18] */ 0x8c667636, 0x140254e0, // add rb_base2_next, r3, r0 ; mov r0, ra_fir_off_val
++/* [0x00001d20] */ 0x4c5a7c86, 0x121245a1, // add ra_wt_mul_l0, ra_wt_mul_l0, r2 ; mul24 r1, r0, ra_wt_mul_l0
++/* [0x00001d28] */ 0x4c4a7c86, 0x121244a0, // add ra_wt_mul_l1, ra_wt_mul_l1, r2 ; mul24 r0, r0, ra_wt_mul_l1
++/* [0x00001d30] */ 0x8c4a7076, 0x14024821, // add r0, r0, r1 ; mov r1, ra_wt_off_l1
++/* [0x00001d38] */ 0x910cb3f6, 0xde02484b, // shl r1, r1, i_wt_den_p6 ; mov rb11, ra3.8d
++/* [0x00001d40] */ 0x8d827236, 0x1002531e, // sub rb_wt_off, r1, r0 ; mov ra_link, unif
++/* [0x00001d48] */ 0x95080ff6, 0x1e024287, // mov ra10, rb_xshift2 ; mov rb7, ra2.8d
++// :1
++/* [0x00001d50] */ 0x0d9d1bc0, 0xa00229e7, // sub.setf -, r5, rb_i_tmu ; nop ; ldtmu0
++/* [0x00001d58] */ 0x8e5539bf, 0x1202888f, // shr r2, r4, ra_xshift ; mov.ifz rb_base2, rb_base2_next
++/* [0x00001d60] */ 0x8e4d05f6, 0xd0029851, // shr r1, r2, v_v_shift ; mov.ifz ra_y_y2, ra_y_y2_next
++/* [0x00001d68] */ 0x8c683ff6, 0x1002b9d8, // add.setf -, rb_ef, rb_ef ; mov.ifz ra_base, ra_base_next
++/* [0x00001d70] */ 0x8c441fb6, 0xd4224463, // add ra_y, 1, ra_y ; mov r3, ra_y
++/* [0x00001d78] */ 0x93531789, 0xd80248e0, // max r3, r3, ra_k0 ; mov r0, r1 << 15
++/* [0x00001d80] */ 0x9227f792, 0xd003c8e1, // min r3, r3, ra9 ; mov.ifnc r1, r2 << 1
++/* [0x00001d88] */ 0x559d049f, 0x100e4823, // mov.ifnc r0, r2 ; mul24 r3, r3, rb_pitch
++/* [0x00001d90] */ 0x8c618cc7, 0x10024e20, // add t0s, ra_base, r3 ; v8min r0, r0, rb_pmask
++/* [0x00001d98] */ 0x540183f0, 0x18024862, // and r1, r1, rb_pmask ; mul24 r2, ra0.8a, r0
++/* [0x00001da0] */ 0x4d01feb1, 0x1e0248a3, // sub r2, rb_fir_off_h, r2 ; mul24 r3, ra0.8d, r1
++/* [0x00001da8] */ 0x4d03e4f0, 0xda0248a3, // sub r2, r2, r3 ; mul24 r3, ra0.8b << 2, r0 << 2 @ "mul_used", 0
++/* [0x00001db0] */ 0x40034031, 0xda0109e3, // nop ; mul24.ifn r3, ra0.8b << 12, r1 << 12 @ "mul_used", 0
++/* [0x00001db8] */ 0x4c03c4f0, 0xdc0248a3, // add r2, r2, r3 ; mul24 r3, ra0.8c << 4, r0 << 4 @ "mul_used", 0
++/* [0x00001dc0] */ 0x40032031, 0xdc0109e3, // nop ; mul24.ifn r3, ra0.8c << 14, r1 << 14 @ "mul_used", 0
++/* [0x00001dc8] */ 0x4c0854fe, 0xb8025804, // add r0, r2, r3 ; mul24 ra4, rb5, ra2.8a ; ldtmu1
++/* [0x00001dd0] */ 0x8e2869bf, 0x10024885, // shr r2, r4, ra10 ; mov rb5, rb6
++/* [0x00001dd8] */ 0x8e4505f6, 0xd2024863, // shr r1, r2, v_v_shift ; mov r3, ra_y2
++/* [0x00001de0] */ 0x8e1c21f6, 0xd00241c6, // shr ra7, r0, v_bit_depth - 8 ; mov rb6, ra7
++/* [0x00001de8] */ 0x8c531789, 0xda124460, // add ra_y2, r3, ra_k1 ; mov r0, r1 << 15
++/* [0x00001df0] */ 0x9353f792, 0xd803c8e1, // max r3, r3, ra_k0 ; mov.ifnc r1, r2 << 1
++/* [0x00001df8] */ 0x925de7ce, 0x120248e1, // min r3, r3, rb_max_y ; v8min r1, r1, ra_pmax
++/* [0x00001e00] */ 0x559d049f, 0x100e4823, // mov.ifnc r0, r2 ; mul24 r3, r3, rb_pitch
++/* [0x00001e08] */ 0x8c5cfec6, 0x12024f20, // add t1s, rb_base2, r3 ; v8min r0, r0, ra_pmax
++/* [0x00001e10] */ 0x4c041bf0, 0xd8025962, // add r5rep, r5, 1 ; mul24 r2, ra1.8a, r0
++/* [0x00001e18] */ 0x4d05feb1, 0x1e0248a3, // sub r2, rb_fir_off_h, r2 ; mul24 r3, ra1.8d, r1
++/* [0x00001e20] */ 0x4d07e4f0, 0xda0248a3, // sub r2, r2, r3 ; mul24 r3, ra1.8b << 2, r0 << 2 @ "mul_used", 0
++/* [0x00001e28] */ 0x40074031, 0xda0109e3, // nop ; mul24.ifn r3, ra1.8b << 12, r1 << 12 @ "mul_used", 0
++/* [0x00001e30] */ 0x4c07c6b0, 0xdc0248a3, // add r2, r3, r2 ; mul24 r3, ra1.8c << 4, r0 << 4 @ "mul_used", 0
++/* [0x00001e38] */ 0x4c072b71, 0xdc0329e3, // add.setf -, r5, r5 ; mul24.ifn r3, ra1.8c << 14, r1 << 14 @ "mul_used", 0
++/* [0x00001e40] */ 0xfffffef0, 0xf06809e7, // brr.anyn -, r:1b
++/* [0x00001e48] */ 0x4c0c94fe, 0x180248a0, // add r2, r2, r3 ; mul24 r0, rb9, ra3.8a
++/* [0x00001e50] */ 0x550caffe, 0x1a025261, // mov rb9, rb10 ; mul24 r1, rb10, ra3.8b
++/* [0x00001e58] */ 0x8e2c25f6, 0xd00242ca, // shr ra11, r2, v_bit_depth - 8 ; mov rb10, ra11
++/* [0x00001e60] */ 0x4d08523e, 0x1a0248a1, // sub r2, r1, r0 ; mul24 r1, rb5, ra2.8b
++/* [0x00001e68] */ 0x8d112bf6, 0x100269e0, // sub.setf -, r5, rb_lcount ; mov r0, ra4
++/* [0x00001e70] */ 0x4d08623e, 0x1c024860, // sub r1, r1, r0 ; mul24 r0, rb6, ra2.8c
++/* [0x00001e78] */ 0x4c1c7237, 0x10024860, // add r1, r1, r0 ; mul24 r0, ra7, rb7
++/* [0x00001e80] */ 0x4d0ca23e, 0x1c024860, // sub r1, r1, r0 ; mul24 r0, rb10, ra3.8c
++/* [0x00001e88] */ 0x4c2cb437, 0x100248a0, // add r2, r2, r0 ; mul24 r0, ra11, rb11
++/* [0x00001e90] */ 0x0d9e7400, 0x100208a7, // sub r2, r2, r0
++/* [0x00001e98] */ 0x0e9c63c0, 0xd0020867, // shr r1, r1, 6
++/* [0x00001ea0] */ 0x4e5865ce, 0xd20248a0, // shr r2, r2, 6 ; mul24 r0, r1, ra_wt_mul_l0
++/* [0x00001ea8] */ 0x4c4a7456, 0x120248a1, // add r2, r2, r1 ; mul24 r1, r2, ra_wt_mul_l1
++/* [0x00001eb0] */ 0x4c667216, 0x14024862, // add r1, r1, r0 ; mul24 r2, r2, ra_kmul_add
++/* [0x00001eb8] */ 0x8d5e72b6, 0x1c024863, // sub r1, r1, r2 ; mov r3, ra_blk_height
++/* [0x00001ec0] */ 0xec40c3f3, 0x12024860, // add r1, r1, rb_wt_off ; v8subs r0, ra_height, r3
++/* [0x00001ec8] */ 0xfffffe68, 0xf06809e7, // brr.anyn -, r:1b
++/* [0x00001ed0] */ 0x0f667380, 0x18020867, // asr r1, r1, ra_wt_den_p7
++/* [0x00001ed8] */ 0x925f23bf, 0x12020867, // min r1, r1, ra_pmax ; mov -, vw_wait
++/* [0x00001ee0] */ 0x5351039f, 0x18024c22, // max vpm, r1, ra_k0 ; mul24 r2, r3, rb_pitch
++/* [0x00001ee8] */ 0x956e7036, 0x10126431, // mov.setf ra_height, r0 ; mov vw_setup, ra_dma0
++/* [0x00001ef0] */ 0x00000000, 0xf027c9e7, // bra.anyz -, ra_link
++/* [0x00001ef8] */ 0x929dd0ff, 0x10024831, // min r0, r0, r3 ; mov vw_setup, rb_dma1
++/* [0x00001f00] */ 0x8d7270f6, 0x10024872, // sub r1, r0, r3 ; mov vw_addr, ra_dest
++/* [0x00001f08] */ 0x119d73c0, 0xd0020867, // shl r1, r1, i_shift23
++/* [0x00001f10] */ 0xfffffe20, 0xf0f809e7, // brr -, r:1b
++/* [0x00001f18] */ 0x0c9d2e00, 0x100214a7, // add rb_lcount, rb_lcount, r0
++/* [0x00001f20] */ 0x0c6e7c40, 0x100206e7, // add ra_dma0, ra_dma0, r1
++/* [0x00001f28] */ 0x8c71ccbf, 0x10024731, // add ra_dest, ra_dest, r2 ; mov vw_setup, rb_vpm_init
++// ::mc_sync10_q0
++/* [0x00001f30] */ 0x15827d80, 0x100207a7, // mov ra_link, unif
++/* [0x00001f38] */ 0x159f2fc0, 0x100009e7, // mov -, vw_wait
++/* [0x00001f40] */ 0x00000010, 0xe80009e7, // mov dst, sacq(i)
++/* [0x00001f48] */ 0x00000010, 0xe80009e7, // mov dst, sacq(i)
++/* [0x00001f50] */ 0x00000010, 0xe80009e7, // mov dst, sacq(i)
++/* [0x00001f58] */ 0x00000000, 0xf0f7c9e7, // bra -, ra_link
++/* [0x00001f60] */ 0x0000001c, 0xe80009e7, // mov dst, sacq(i)
++/* [0x00001f68] */ 0x00000001, 0xe80009e7, // mov dst, srel(i)
++/* [0x00001f70] */ 0x0000000d, 0xe80009e7, // mov dst, srel(i)
++// ::mc_sync10_q1
++/* [0x00001f78] */ 0x15827d80, 0x100207a7, // mov ra_link, unif
++/* [0x00001f80] */ 0x159f2fc0, 0x100009e7, // mov -, vw_wait
++/* [0x00001f88] */ 0x00000000, 0xf0f7c9e7, // bra -, ra_link
++/* [0x00001f90] */ 0x00000000, 0xe80009e7, // mov dst, srel(i)
++/* [0x00001f98] */ 0x00000011, 0xe80009e7, // mov dst, sacq(i)
++/* [0x00001fa0] */ 0x00000002, 0xe80009e7, // mov dst, srel(i)
++// ::mc_sync10_q2
++/* [0x00001fa8] */ 0x15827d80, 0x100207a7, // mov ra_link, unif
++/* [0x00001fb0] */ 0x159f2fc0, 0x100009e7, // mov -, vw_wait
++/* [0x00001fb8] */ 0x00000000, 0xf0f7c9e7, // bra -, ra_link
++/* [0x00001fc0] */ 0x00000000, 0xe80009e7, // mov dst, srel(i)
++/* [0x00001fc8] */ 0x00000012, 0xe80009e7, // mov dst, sacq(i)
++/* [0x00001fd0] */ 0x00000003, 0xe80009e7, // mov dst, srel(i)
++// ::mc_sync10_q3
++/* [0x00001fd8] */ 0x15827d80, 0x100207a7, // mov ra_link, unif
++/* [0x00001fe0] */ 0x159f2fc0, 0x100009e7, // mov -, vw_wait
++/* [0x00001fe8] */ 0x00000000, 0xf0f7c9e7, // bra -, ra_link
++/* [0x00001ff0] */ 0x00000000, 0xe80009e7, // mov dst, srel(i)
++/* [0x00001ff8] */ 0x00000013, 0xe80009e7, // mov dst, sacq(i)
++/* [0x00002000] */ 0x009e7000, 0x100009e7, // nop
++// ::mc_sync10_q4
++/* [0x00002008] */ 0x15827d80, 0x100207a7, // mov ra_link, unif
++/* [0x00002010] */ 0x159f2fc0, 0x100009e7, // mov -, vw_wait
++/* [0x00002018] */ 0x00000014, 0xe80009e7, // mov dst, sacq(i)
++/* [0x00002020] */ 0x00000014, 0xe80009e7, // mov dst, sacq(i)
++/* [0x00002028] */ 0x00000014, 0xe80009e7, // mov dst, sacq(i)
++/* [0x00002030] */ 0x00000000, 0xf0f7c9e7, // bra -, ra_link
++/* [0x00002038] */ 0x0000001d, 0xe80009e7, // mov dst, sacq(i)
++/* [0x00002040] */ 0x00000005, 0xe80009e7, // mov dst, srel(i)
++/* [0x00002048] */ 0x0000000e, 0xe80009e7, // mov dst, srel(i)
++// ::mc_sync10_q5
++/* [0x00002050] */ 0x15827d80, 0x100207a7, // mov ra_link, unif
++/* [0x00002058] */ 0x159f2fc0, 0x100009e7, // mov -, vw_wait
++/* [0x00002060] */ 0x00000000, 0xf0f7c9e7, // bra -, ra_link
++/* [0x00002068] */ 0x00000004, 0xe80009e7, // mov dst, srel(i)
++/* [0x00002070] */ 0x00000015, 0xe80009e7, // mov dst, sacq(i)
++/* [0x00002078] */ 0x00000006, 0xe80009e7, // mov dst, srel(i)
++// ::mc_sync10_q6
++/* [0x00002080] */ 0x15827d80, 0x100207a7, // mov ra_link, unif
++/* [0x00002088] */ 0x159f2fc0, 0x100009e7, // mov -, vw_wait
++/* [0x00002090] */ 0x00000000, 0xf0f7c9e7, // bra -, ra_link
++/* [0x00002098] */ 0x00000004, 0xe80009e7, // mov dst, srel(i)
++/* [0x000020a0] */ 0x00000016, 0xe80009e7, // mov dst, sacq(i)
++/* [0x000020a8] */ 0x00000007, 0xe80009e7, // mov dst, srel(i)
++// ::mc_sync10_q7
++/* [0x000020b0] */ 0x15827d80, 0x100207a7, // mov ra_link, unif
++/* [0x000020b8] */ 0x159f2fc0, 0x100009e7, // mov -, vw_wait
++/* [0x000020c0] */ 0x00000000, 0xf0f7c9e7, // bra -, ra_link
++/* [0x000020c8] */ 0x00000004, 0xe80009e7, // mov dst, srel(i)
++/* [0x000020d0] */ 0x00000017, 0xe80009e7, // mov dst, sacq(i)
++/* [0x000020d8] */ 0x009e7000, 0x100009e7, // nop
++// ::mc_sync10_q8
++/* [0x000020e0] */ 0x15827d80, 0x100207a7, // mov ra_link, unif
++/* [0x000020e8] */ 0x159f2fc0, 0x100009e7, // mov -, vw_wait
++/* [0x000020f0] */ 0x00000018, 0xe80009e7, // mov dst, sacq(i)
++/* [0x000020f8] */ 0x00000018, 0xe80009e7, // mov dst, sacq(i)
++/* [0x00002100] */ 0x00000018, 0xe80009e7, // mov dst, sacq(i)
++/* [0x00002108] */ 0x00000000, 0xf0f7c9e7, // bra -, ra_link
++/* [0x00002110] */ 0x0000001e, 0xe80009e7, // mov dst, sacq(i)
++/* [0x00002118] */ 0x00000009, 0xe80009e7, // mov dst, srel(i)
++/* [0x00002120] */ 0x0000000c, 0xe80009e7, // mov dst, srel(i)
++// ::mc_sync10_q9
++/* [0x00002128] */ 0x15827d80, 0x100207a7, // mov ra_link, unif
++/* [0x00002130] */ 0x159f2fc0, 0x100009e7, // mov -, vw_wait
++/* [0x00002138] */ 0x00000000, 0xf0f7c9e7, // bra -, ra_link
++/* [0x00002140] */ 0x00000008, 0xe80009e7, // mov dst, srel(i)
++/* [0x00002148] */ 0x00000019, 0xe80009e7, // mov dst, sacq(i)
++/* [0x00002150] */ 0x0000000a, 0xe80009e7, // mov dst, srel(i)
++// ::mc_sync10_q10
++/* [0x00002158] */ 0x15827d80, 0x100207a7, // mov ra_link, unif
++/* [0x00002160] */ 0x159f2fc0, 0x100009e7, // mov -, vw_wait
++/* [0x00002168] */ 0x00000000, 0xf0f7c9e7, // bra -, ra_link
++/* [0x00002170] */ 0x00000008, 0xe80009e7, // mov dst, srel(i)
++/* [0x00002178] */ 0x0000001a, 0xe80009e7, // mov dst, sacq(i)
++/* [0x00002180] */ 0x0000000b, 0xe80009e7, // mov dst, srel(i)
++// ::mc_sync10_q11
++/* [0x00002188] */ 0x15827d80, 0x100207a7, // mov ra_link, unif
++/* [0x00002190] */ 0x159f2fc0, 0x100009e7, // mov -, vw_wait
++/* [0x00002198] */ 0x00000000, 0xf0f7c9e7, // bra -, ra_link
++/* [0x000021a0] */ 0x00000008, 0xe80009e7, // mov dst, srel(i)
++/* [0x000021a8] */ 0x0000001b, 0xe80009e7, // mov dst, sacq(i)
++/* [0x000021b0] */ 0x009e7000, 0x100009e7, // nop
++// ::mc_exit_c10_q0
++// ::mc_exit_y10_q0
++/* [0x000021b8] */ 0x00000002, 0xe00228e7, // mov.setf r3, PREREAD - 1
++// :1
++/* [0x000021c0] */ 0xffffffe0, 0xf03809e7, // brr.anynz -, r:1b
++/* [0x000021c8] */ 0x009e7000, 0xa00009e7, // nop ; nop ; ldtmu0
++/* [0x000021d0] */ 0x009e7000, 0xb00009e7, // nop ; nop ; ldtmu1
++/* [0x000021d8] */ 0x0d9c17c0, 0xd00228e7, // sub.setf r3, r3, 1
++/* [0x000021e0] */ 0x159f2fc0, 0x100009e7, // mov -, vw_wait
++/* [0x000021e8] */ 0x0000001c, 0xe80009e7, // mov dst, sacq(i)
++/* [0x000021f0] */ 0x009e7000, 0x300009e7, // nop ; nop ; thrend
++/* [0x000021f8] */ 0x00000001, 0xe00209a7, // mov interrupt, 1
++/* [0x00002200] */ 0x009e7000, 0x100009e7, // nop
++// ::mc_exit_c10_qn
++// ::mc_exit_y10_qn
++/* [0x00002208] */ 0x00000002, 0xe00228e7, // mov.setf r3, PREREAD - 1
++// :1
++/* [0x00002210] */ 0xffffffe0, 0xf03809e7, // brr.anynz -, r:1b
++/* [0x00002218] */ 0x009e7000, 0xa00009e7, // nop ; nop ; ldtmu0
++/* [0x00002220] */ 0x009e7000, 0xb00009e7, // nop ; nop ; ldtmu1
++/* [0x00002228] */ 0x0d9c17c0, 0xd00228e7, // sub.setf r3, r3, 1
++/* [0x00002230] */ 0x159f2fc0, 0x100009e7, // mov -, vw_wait
++/* [0x00002238] */ 0x009e7000, 0x300009e7, // nop ; nop ; thrend
++/* [0x00002240] */ 0x009e7000, 0x100009e7, // nop
++/* [0x00002248] */ 0x009e7000, 0x100009e7, // nop
++// ::mc_setup_y10_q0
++/* [0x00002250] */ 0x0000000c, 0xe80009e7, // mov dst, srel(i)
++// ::mc_setup_y10_qn
++/* [0x00002258] */ 0x95801ff6, 0xd0025900, // mov tmurs, 1 ; mov ra0, unif
++/* [0x00002260] */ 0x15827d80, 0x10020267, // mov ra9, unif
++/* [0x00002268] */ 0x15827d80, 0x10020067, // mov ra1, unif
++/* [0x00002270] */ 0xaaaaff00, 0xe6020827, // mov r0, [0,2,0,2,0,2,0,2,1,3,1,3,1,3,1,3]
++/* [0x00002278] */ 0x9181e1f6, 0xd00250cb, // shl rb_ef, r0, i_shift30 ; mov ra11, unif
++/* [0x00002280] */ 0xff800100, 0xe0020527, // mov ra_kff800100, 0xff800100
++/* [0x00002288] */ 0x0000ffff, 0xe0021627, // mov rb_pmask, v_pmask
++/* [0x00002290] */ 0x000803ff, 0xe00205e7, // mov ra_blk_height_pmax, ((1 << v_bit_depth) - 1) | (v_blk_height << 16)
++/* [0x00002298] */ 0x00010000, 0xe00217e7, // mov rb_fir_off_h, (FIR_OFFSET << (v_bit_depth - 8))
++/* [0x000022a0] */ 0x4000000c, 0xe0020667, // mov ra_fir_off_val_wt_den_p7, (FIR_OFFSET << 16) | (DENOM + 15 - v_bit_depth)
++/* [0x000022a8] */ 0x050b0a00, 0xe0021567, // mov rb_y_coeffs_2, 0x050b0a00
++/* [0x000022b0] */ 0x11283a40, 0xe00215a7, // mov rb_y_coeffs_3, 0x11283a40
++/* [0x000022b8] */ 0x0a0b0500, 0xe00215e7, // mov rb_y_coeffs_5, 0x0a0b0500
++/* [0x000022c0] */ 0x15827d80, 0x100200e7, // mov ra3, unif
++/* [0x000022c8] */ 0x95803ff6, 0x10024754, // mov ra_ef, rb_ef ; mov rb_xpitch, unif
++/* [0x000022d0] */ 0x0d0c1dc0, 0xd4020827, // sub r0, ra3.16b, 1
++/* [0x000022d8] */ 0x119c11c0, 0xd00216a7, // shl rb_max_x, r0, v_x_shift
++/* [0x000022e0] */ 0x0d0c1dc0, 0xd20217a7, // sub rb_max_y, ra3.16a, 1
++/* [0x000022e8] */ 0x959a0dbf, 0x100248d0, // mov r3, elem_num ; mov rb_pitch, unif
++/* [0x000022f0] */ 0xc0000000, 0xe0020867, // mov r1, vdw_setup_1(0)
++/* [0x000022f8] */ 0x159d03c0, 0x10021667, // or rb_dma1_base, r1, rb_pitch
++/* [0x00002300] */ 0x0c027cc0, 0x14020827, // add r0, ra0.16b, r3
++/* [0x00002308] */ 0x119c11c0, 0xd0020827, // shl r0, r0, v_x_shift
++/* [0x00002310] */ 0x139c01c0, 0xd0020827, // max r0, r0, 0
++/* [0x00002318] */ 0x129da1c0, 0x10020827, // min r0, r0, rb_max_x
++/* [0x00002320] */ 0x119c31c0, 0xd0220567, // shl ra_xshift_next, r0, 3
++/* [0x00002328] */ 0xf49dc1d2, 0xd0024822, // and r0, r0, -4 ; v8subs r2, r2, r2
++/* [0x00002330] */ 0x0d9d05c0, 0x100208a7, // sub r2, r2, rb_pitch
++/* [0x00002338] */ 0x149e7080, 0x10020867, // and r1, r0, r2
++/* [0x00002340] */ 0x569d404f, 0x10024821, // xor r0, r0, r1 ; mul24 r1, r1, rb_xpitch
++/* [0x00002348] */ 0x0c9e7040, 0x10020827, // add r0, r0, r1
++/* [0x00002350] */ 0x0c267c00, 0x10020627, // add ra_base, ra9, r0
++/* [0x00002358] */ 0x0c067cc0, 0x14020827, // add r0, ra1.16b, r3
++/* [0x00002360] */ 0x119c11c0, 0xd0020827, // shl r0, r0, v_x_shift
++/* [0x00002368] */ 0x139c01c0, 0xd0020827, // max r0, r0, 0
++/* [0x00002370] */ 0x129da1c0, 0x10020827, // min r0, r0, rb_max_x
++/* [0x00002378] */ 0x119c31c0, 0xd0021067, // shl rb_xshift2_next, r0, 3
++/* [0x00002380] */ 0x149dc1c0, 0xd0020827, // and r0, r0, -4
++/* [0x00002388] */ 0x149e7080, 0x10020867, // and r1, r0, r2
++/* [0x00002390] */ 0x569d404f, 0x10024821, // xor r0, r0, r1 ; mul24 r1, r1, rb_xpitch
++/* [0x00002398] */ 0x0c9e7040, 0x10020827, // add r0, r0, r1
++/* [0x000023a0] */ 0x0c2e7c00, 0x100213e7, // add rb_base2, ra11, r0
++/* [0x000023a8] */ 0x80027036, 0x120049e0, // nop ; mov r0, ra0.16a
++/* [0x000023b0] */ 0x95043ff6, 0xd20248e2, // mov r3, PREREAD ; mov r2, ra1.16a
++// :1
++/* [0x000023b8] */ 0x0d9c17c0, 0xd00228e7, // sub.setf r3, r3, 1
++/* [0x000023c0] */ 0x139c01c0, 0xd0020867, // max r1, r0, 0
++/* [0x000023c8] */ 0x129de3c0, 0x10020867, // min r1, r1, rb_max_y
++/* [0x000023d0] */ 0x4c51018f, 0x1a024821, // add r0, r0, ra_k1 ; mul24 r1, r1, rb_pitch
++/* [0x000023d8] */ 0x8c627c40, 0x10225e11, // add t0s, ra_base, r1 ; mov ra_y, r0
++/* [0x000023e0] */ 0x139c05c0, 0xd0020867, // max r1, r2, 0
++/* [0x000023e8] */ 0xffffffb0, 0xf03809e7, // brr.anynz -, r:1b
++/* [0x000023f0] */ 0x129de3c0, 0x10020867, // min r1, r1, rb_max_y
++/* [0x000023f8] */ 0x4c51058f, 0x1a0248a1, // add r2, r2, ra_k1 ; mul24 r1, r1, rb_pitch
++/* [0x00002400] */ 0x8c9cfe52, 0x10125f11, // add t1s, rb_base2, r1 ; mov ra_y2, r2
++/* [0x00002408] */ 0x159e6fc0, 0x100208a7, // mov r2, qpu_num
++/* [0x00002410] */ 0x0f9c15c0, 0xd0020867, // asr r1, r2, 1
++/* [0x00002418] */ 0x119c43c0, 0xd0020867, // shl r1, r1, 4
++/* [0x00002420] */ 0x149c15c0, 0xd0020827, // and r0, r2, 1
++/* [0x00002428] */ 0x159e7040, 0x10020827, // or r0, r0, r1
++/* [0x00002430] */ 0x00002900, 0xe0020867, // mov r1, vpm_setup(0, 2, h16p(0, 0))
++/* [0x00002438] */ 0x0c9e7040, 0x10021727, // add r_vpm, r0, r1
++/* [0x00002440] */ 0x80004002, 0xe0020867, // mov r1, vdw_setup_0(0, 0, dma_h16p(0,0,0))
++/* [0x00002448] */ 0x119c61c0, 0xd0020827, // shl r0, r0, 6
++/* [0x00002450] */ 0x0c9e7040, 0x100216e7, // add r_dma, r0, r1
++/* [0x00002458] */ 0x15827d80, 0x100207a7, // mov ra_link, unif
++/* [0x00002460] */ 0x00000000, 0xe0024208, // mov ra8, 0 ; mov rb8, 0
++/* [0x00002468] */ 0x00000000, 0xf0f7c9e7, // bra -, ra_link
++/* [0x00002470] */ 0x00000000, 0xe0024249, // mov ra9, 0 ; mov rb9, 0
++/* [0x00002478] */ 0x00000000, 0xe002428a, // mov ra10, 0 ; mov rb10, 0
++/* [0x00002480] */ 0x00000000, 0xe00242cb, // mov ra11, 0 ; mov rb11, 0
++// :per_block_setup_10
++/* [0x00002488] */ 0x119c11c0, 0xd0020827, // shl r0, r0, v_x_shift
++/* [0x00002490] */ 0x93567176, 0x14125815, // max r0, r0, r5 ; mov ra_xshift, ra_xshift_next
++/* [0x00002498] */ 0x129da1c0, 0x10020827, // min r0, r0, rb_max_x
++/* [0x000024a0] */ 0x119c31c0, 0xd0220567, // shl ra_xshift_next, r0, 3
++/* [0x000024a8] */ 0x149dc1c0, 0xd0020827, // and r0, r0, -4
++/* [0x000024b0] */ 0x8d810bf6, 0x1002589a, // sub r2, r5, rb_pitch ; mov ra_base_next, unif
++/* [0x000024b8] */ 0x940270b6, 0x12225853, // and r1, r0, r2 ; mov ra_y_next, ra0.16a
++/* [0x000024c0] */ 0x569d404f, 0x10024821, // xor r0, r0, r1 ; mul24 r1, r1, rb_xpitch
++/* [0x000024c8] */ 0x8c827076, 0x10025801, // add r0, r0, r1 ; mov ra1, unif
++/* [0x000024d0] */ 0x0c6a7c00, 0x100206a7, // add ra_base_next, ra_base_next, r0
++/* [0x000024d8] */ 0x0c067cc0, 0x14020827, // add r0, ra1.16b, r3
++/* [0x000024e0] */ 0x119c11c0, 0xd0020827, // shl r0, r0, v_x_shift
++/* [0x000024e8] */ 0x93067176, 0x12125813, // max r0, r0, r5 ; mov ra_y2_next, ra1.16a
++/* [0x000024f0] */ 0x9281a1f6, 0x10024813, // min r0, r0, rb_max_x ; mov rb_base2_next, unif
++/* [0x000024f8] */ 0x119c31c0, 0xd0021067, // shl rb_xshift2_next, r0, 3
++/* [0x00002500] */ 0x9481c1f6, 0xd0025810, // and r0, r0, -4 ; mov ra_width_height, unif
++/* [0x00002508] */ 0x949dc0bf, 0x10024871, // and r1, r0, r2 ; mov vw_setup, rb_vpm_init
++/* [0x00002510] */ 0x569d404f, 0x10024821, // xor r0, r0, r1 ; mul24 r1, r1, rb_xpitch
++/* [0x00002518] */ 0x4c402077, 0xd4024821, // add r0, r0, r1 ; mul24 r1, ra_width, v_x_mul
++/* [0x00002520] */ 0x0c9d3e00, 0x100214e7, // add rb_base2_next, rb_base2_next, r0
++/* [0x00002528] */ 0x8d419e76, 0x12025760, // sub rb_dma1, rb_dma1_base, r1 ; mov r0, ra_height
++/* [0x00002530] */ 0x8c5dc1c6, 0xdc025460, // add rb_i_tmu, r0, (7-8) - PREREAD ; v8min r0, r0, ra_blk_height
++/* [0x00002538] */ 0x0c9df1c0, 0xd00214a7, // add rb_lcount, r0, (7-8)
++/* [0x00002540] */ 0x916481f6, 0xd4024823, // shl r0, r0, v_dma_h_shift ; mov r3, ra_kmul_add
++/* [0x00002548] */ 0x0c9e7040, 0x10020827, // add r0, r0, r1
++/* [0x00002550] */ 0x9164f1f6, 0xd4024822, // shl r0, r0, v_dma_wh_shift ; mov r2, ra_fir_off_val
++/* [0x00002558] */ 0x8c81b1f6, 0x100246e0, // add ra_dma0, r0, rb_dma0_base ; mov r0, unif
++/* [0x00002560] */ 0x918101f6, 0xd00a5816, // shl.ifnn r0, r0, i_shift16 ; mov ra_wt_off_mul_l0, unif
++/* [0x00002568] */ 0x915031f6, 0xde024205, // shl ra8, r0, 3 ; mov rb5, ra_k255
++/* [0x00002570] */ 0x01040400, 0xe0020867, // mov r1, 0x01040400
++/* [0x00002578] */ 0x10227380, 0x1e5200a7, // ror ra2.8b, r1, ra8.8d
++/* [0x00002580] */ 0x10227380, 0x1c520027, // ror ra0.8b, r1, ra8.8c
++/* [0x00002588] */ 0x10215f80, 0x1e6200a7, // ror ra2.8c, rb_y_coeffs_2, ra8.8d
++/* [0x00002590] */ 0x10215f80, 0x1c620027, // ror ra0.8c, rb_y_coeffs_2, ra8.8c
++/* [0x00002598] */ 0x00010100, 0xe0020867, // mov r1,0x00010100
++/* [0x000025a0] */ 0x902203bf, 0x1e025812, // ror r0, r1, ra8.8d ; mov ra_wt_off_mul_l1, unif
++/* [0x000025a8] */ 0x90205387, 0x1c424004, // ror ra0.8a, r1, ra8.8c ; v8min rb4, r0, rb5
++/* [0x000025b0] */ 0x914883f6, 0xd0031856, // shl r1, r1, 8 ; mov.ifn ra_wt_off_mul_l0, ra_wt_off_mul_l1
++/* [0x000025b8] */ 0x902203bf, 0x1e02581c, // ror r0, r1, ra8.8d ; mov ra_dest, unif
++/* [0x000025c0] */ 0x90205387, 0x1c72404b, // ror ra1.8d, r1, ra8.8c ; v8min rb11, r0, rb5
++/* [0x000025c8] */ 0x10216f80, 0x1e7200a7, // ror ra2.8d, rb_y_coeffs_3, ra8.8d
++/* [0x000025d0] */ 0x10216f80, 0x1c720027, // ror ra0.8d, rb_y_coeffs_3, ra8.8c
++/* [0x000025d8] */ 0x10217f80, 0x1e5200e7, // ror ra3.8b, rb_y_coeffs_5, ra8.8d
++/* [0x000025e0] */ 0x10217f80, 0x1c520067, // ror ra1.8b, rb_y_coeffs_5, ra8.8c
++/* [0x000025e8] */ 0x04040100, 0xe0020867, // mov r1,0x04040100
++/* [0x000025f0] */ 0x10227380, 0x1e6200e7, // ror ra3.8c, r1, ra8.8d
++/* [0x000025f8] */ 0x902183bf, 0xdc624065, // ror ra1.8c, r1, ra8.8c ; mov r5rep, -8
++/* [0x00002600] */ 0x00000000, 0xf0f7c9e7, // bra -, ra_link
++/* [0x00002608] */ 0x3a281100, 0xe0020867, // mov r1,0x3a281100
++/* [0x00002610] */ 0x902203bf, 0x1e02581e, // ror r0, r1, ra8.8d ; mov ra_link, unif
++/* [0x00002618] */ 0x90205387, 0x1c424048, // ror ra1.8a, r1, ra8.8c ; v8min rb8, r0, rb5
++// ::mc_filter_y10_pxx
++/* [0x00002620] */ 0xfffffe48, 0xf0f807a7, // brr ra_link, r:per_block_setup_10
++/* [0x00002628] */ 0x959a0ff6, 0x10024023, // mov ra0, unif ; mov r3, elem_num
++/* [0x00002630] */ 0xec9c3fd2, 0x100269e5, // add.setf -, rb_ef, rb_ef ; v8subs r5rep, r2, r2
++/* [0x00002638] */ 0x8c001cff, 0x14024800, // add r0, ra0.16b, r3 ; mov rb_xshift2, rb_xshift2_next
++/* [0x00002640] */ 0x1158adc0, 0xd4020867, // shl r1, ra_wt_off_l0, i_wt_den_p5
++/* [0x00002648] */ 0x4c5a7cd6, 0x121245a0, // add ra_wt_mul_l0, ra_wt_mul_l0, r3 ; mul24 r0, r2, ra_wt_mul_l0
++/* [0x00002650] */ 0x8d9c423f, 0x1042531d, // sub rb_wt_off, r1, r0 ; mov ra_ef.8a, rb4
++// :1
++/* [0x00002658] */ 0x4c745dbe, 0x100279c4, // add.setf -, ra_ef, ra_ef ; mul24 ra4, rb5, ra_ef
++/* [0x00002660] */ 0x93440dff, 0xd40248a1, // max r2, ra_y, 0 ; mov r1, 0
++/* [0x00002668] */ 0x9251e5f6, 0x1a0248a3, // min r2, r2, rb_max_y ; mov r3, ra_k1
++/* [0x00002670] */ 0x4c450cd7, 0xa4224462, // add ra_y, ra_y, r3 ; mul24 r2, r2, rb_pitch ; ldtmu0
++/* [0x00002678] */ 0x8c606cbf, 0x10024e05, // add t0s, ra_base, r2 ; mov rb5, rb6
++/* [0x00002680] */ 0x8e5479bf, 0x12024806, // shr r0, r4, ra_xshift ; mov rb6, rb7
++/* [0x00002688] */ 0x93458c47, 0xb20248a0, // max r2, ra_y2, r1 ; v8min r0, r0, rb_pmask ; ldtmu1
++/* [0x00002690] */ 0x8e2009f6, 0x10024847, // shr r1, r4, rb_xshift2 ; mov rb7, ra8
++/* [0x00002698] */ 0x925de5ce, 0x120248a1, // min r2, r2, rb_max_y ; v8min r1, r1, ra_pmax
++/* [0x000026a0] */ 0x4c450cd7, 0x12124462, // add ra_y2, ra_y2, r3 ; mul24 r2, r2, rb_pitch
++/* [0x000026a8] */ 0x8c24feb6, 0x10025f08, // add t1s, rb_base2, r2 ; mov ra8, ra9
++/* [0x000026b0] */ 0x4c038af1, 0xd8025962, // add r5rep, r5, r3 ; mul24 r2, ra0.8a << 8, r1 << 8 @ "mul_used", 0
++/* [0x000026b8] */ 0x5501fff0, 0x180348e2, // mov r3, rb_fir_off_h ; mul24.ifnn r2, ra0.8a, r0
++/* [0x000026c0] */ 0x4d03f6b0, 0xda0248a3, // sub r2, r3, r2 ; mul24 r3, ra0.8b << 1, r0 << 1 @ "mul_used", 0
++/* [0x000026c8] */ 0x40037031, 0xda0109e3, // nop ; mul24.ifn r3, ra0.8b << 9, r1 << 9 @ "mul_used", 0
++/* [0x000026d0] */ 0x4c03e4f0, 0xdc0248a3, // add r2, r2, r3 ; mul24 r3, ra0.8c << 2, r0 << 2 @ "mul_used", 0
++/* [0x000026d8] */ 0x40036031, 0xdc0109e3, // nop ; mul24.ifn r3, ra0.8c << 10, r1 << 10 @ "mul_used", 0
++/* [0x000026e0] */ 0x4d03d4f0, 0xde0248a3, // sub r2, r2, r3 ; mul24 r3, ra0.8d << 3, r0 << 3 @ "mul_used", 0
++/* [0x000026e8] */ 0x40035031, 0xde0109e3, // nop ; mul24.ifn r3, ra0.8d << 11, r1 << 11 @ "mul_used", 0
++/* [0x000026f0] */ 0x4c07c4f0, 0xd80248a3, // add r2, r2, r3 ; mul24 r3, ra1.8a << 4, r0 << 4 @ "mul_used", 0
++/* [0x000026f8] */ 0x40074031, 0xd80109e3, // nop ; mul24.ifn r3, ra1.8a << 12, r1 << 12 @ "mul_used", 0
++/* [0x00002700] */ 0x4c07b4f0, 0xda0248a3, // add r2, r2, r3 ; mul24 r3, ra1.8b << 5, r0 << 5 @ "mul_used", 0
++/* [0x00002708] */ 0x40073031, 0xda0109e3, // nop ; mul24.ifn r3, ra1.8b << 13, r1 << 13 @ "mul_used", 0
++/* [0x00002710] */ 0x4d07a4f0, 0xdc0248a3, // sub r2, r2, r3 ; mul24 r3, ra1.8c << 6, r0 << 6 @ "mul_used", 0
++/* [0x00002718] */ 0x40072031, 0xdc0109e3, // nop ; mul24.ifn r3, ra1.8c << 14, r1 << 14 @ "mul_used", 0
++/* [0x00002720] */ 0x4c0794f0, 0xde0248a3, // add r2, r2, r3 ; mul24 r3, ra1.8d << 7, r0 << 7 @ "mul_used", 0
++/* [0x00002728] */ 0x4c071b71, 0xde0329e3, // add.setf -, r5, r5 ; mul24.ifn r3, ra1.8d << 15, r1 << 15 @ "mul_used", 0
++/* [0x00002730] */ 0xffffff08, 0xf06809e7, // brr.anyn -, r:1b
++/* [0x00002738] */ 0x4d0854fe, 0x1a0248a1, // sub r2, r2, r3 ; mul24 r1, rb5, ra2.8b
++/* [0x00002740] */ 0x550caffe, 0x1a024260, // mov ra9, rb10 ; mul24 r0, rb10, ra3.8b
++/* [0x00002748] */ 0x8f2c25f6, 0xd00242ca, // asr ra11, r2, v_bit_depth - 8 ; mov rb10, ra11
++/* [0x00002750] */ 0x4d08623e, 0x1c024860, // sub r1, r1, r0 ; mul24 r0, rb6, ra2.8c
++/* [0x00002758] */ 0x4d08723e, 0x1e024860, // sub r1, r1, r0 ; mul24 r0, rb7, ra2.8d
++/* [0x00002760] */ 0x4c208237, 0x10024860, // add r1, r1, r0 ; mul24 r0, ra8, rb8
++/* [0x00002768] */ 0x4c0ca23e, 0x1c024860, // add r1, r1, r0 ; mul24 r0, rb10, ra3.8c
++/* [0x00002770] */ 0x4c2cb237, 0x10024860, // add r1, r1, r0 ; mul24 r0, ra11, rb11
++/* [0x00002778] */ 0x8d5d1bf6, 0x1c0269e3, // sub.setf -, r5, rb_i_tmu ; mov r3, ra_blk_height
++/* [0x00002780] */ 0x8d1133bf, 0x1002884f, // sub r1, r1, ra4 ; mov.ifz rb_base2, rb_base2_next
++/* [0x00002788] */ 0x8d6a7236, 0x10029858, // sub r1, r1, r0 ; mov.ifz ra_base, ra_base_next
++/* [0x00002790] */ 0x8f4c63f6, 0xd0029851, // asr r1, r1, 6 ; mov.ifz ra_y_y2, ra_y_y2_next
++/* [0x00002798] */ 0x4d592bce, 0x120269e0, // sub.setf -, r5, rb_lcount ; mul24 r0, r1, ra_wt_mul_l0
++/* [0x000027a0] */ 0x4c64c1ce, 0x14024821, // add r0, r0, rb_wt_off ; mul24 r1, r1, ra_kmul_add
++/* [0x000027a8] */ 0xed427073, 0x12024860, // sub r1, r0, r1 ; v8subs r0, ra_height, r3
++/* [0x000027b0] */ 0xfffffe88, 0xf06809e7, // brr.anyn -, r:1b
++/* [0x000027b8] */ 0x0f9cb3c0, 0xd0020867, // asr r1, r1, i_wt_den_p6
++/* [0x000027c0] */ 0x925f23bf, 0x12020867, // min r1, r1, ra_pmax ; mov -, vw_wait
++/* [0x000027c8] */ 0x5351039f, 0x18024c22, // max vpm, r1, ra_k0 ; mul24 r2, r3, rb_pitch
++/* [0x000027d0] */ 0x956e7036, 0x10126431, // mov.setf ra_height, r0 ; mov vw_setup, ra_dma0
++/* [0x000027d8] */ 0x00000000, 0xf027c9e7, // bra.anyz -, ra_link
++/* [0x000027e0] */ 0x929dd0ff, 0x10024831, // min r0, r0, r3 ; mov vw_setup, rb_dma1
++/* [0x000027e8] */ 0x8d7270f6, 0x10024872, // sub r1, r0, r3 ; mov vw_addr, ra_dest
++/* [0x000027f0] */ 0x119d73c0, 0xd0020867, // shl r1, r1, i_shift23
++/* [0x000027f8] */ 0xfffffe40, 0xf0f809e7, // brr -, r:1b
++/* [0x00002800] */ 0x0c9d2e00, 0x100214a7, // add rb_lcount, rb_lcount, r0
++/* [0x00002808] */ 0x0c6e7c40, 0x100206e7, // add ra_dma0, ra_dma0, r1
++/* [0x00002810] */ 0x8c71ccbf, 0x10024731, // add ra_dest, ra_dest, r2 ; mov vw_setup, rb_vpm_init
++// ::mc_filter_y10_p00
++/* [0x00002818] */ 0x959a0ff6, 0x10024020, // mov ra0, unif ; mov r0, elem_num
++/* [0x00002820] */ 0xf5567dad, 0x14124565, // mov ra_xshift, ra_xshift_next ; v8subs r5rep, r5, r5
++/* [0x00002828] */ 0x8c020c3f, 0x1402581a, // add r0, ra0.16b, r0 ; mov ra_base_next, unif
++/* [0x00002830] */ 0x119c11c0, 0xd0020827, // shl r0, r0, v_x_shift
++/* [0x00002838] */ 0x93027176, 0x12225813, // max r0, r0, r5 ; mov ra_y_next, ra0.16a
++/* [0x00002840] */ 0x9281a1f6, 0x10025810, // min r0, r0, rb_max_x ; mov ra_width_height, unif
++/* [0x00002848] */ 0x119c31c0, 0xd0220567, // shl ra_xshift_next, r0, 3
++/* [0x00002850] */ 0x149dc1c0, 0xd0020827, // and r0, r0, -4
++/* [0x00002858] */ 0x8d810bf6, 0x10025896, // sub r2, r5, rb_pitch ; mov ra_wt_off_mul_l0, unif
++/* [0x00002860] */ 0x149e7080, 0x10020867, // and r1, r0, r2
++/* [0x00002868] */ 0x569d404f, 0x10024821, // xor r0, r0, r1 ; mul24 r1, r1, rb_xpitch
++/* [0x00002870] */ 0x8c827076, 0x1002581c, // add r0, r0, r1 ; mov ra_dest, unif
++/* [0x00002878] */ 0x8c69cc3f, 0x100246b1, // add ra_base_next, ra_base_next, r0 ; mov vw_setup, rb_vpm_init
++/* [0x00002880] */ 0x11401dc0, 0xd4020867, // shl r1, ra_width, v_x_shift
++/* [0x00002888] */ 0x8d419e76, 0x12025760, // sub rb_dma1, rb_dma1_base, r1 ; mov r0, ra_height
++/* [0x00002890] */ 0x8d5c31c6, 0xdc025460, // sub rb_i_tmu, r0, PREREAD ; v8min r0, r0, ra_blk_height
++/* [0x00002898] */ 0x919c81c0, 0xd0024812, // shl r0, r0, v_dma_h_shift ; mov rb_lcount, r0
++/* [0x000028a0] */ 0x0c9e7040, 0x10020827, // add r0, r0, r1
++/* [0x000028a8] */ 0x1158edc0, 0xd4021327, // shl rb_wt_off, ra_wt_off_l0, DENOM + 7
++/* [0x000028b0] */ 0x9180f1f6, 0xd002581e, // shl r0, r0, v_dma_wh_shift ; mov ra_link, unif
++/* [0x000028b8] */ 0x0c9db1c0, 0x100206e7, // add ra_dma0, r0, rb_dma0_base
++// :1
++/* [0x000028c0] */ 0xcd511bee, 0x1a0269e5, // sub.setf -, r5, rb_i_tmu ; v8adds r5rep, r5, ra_k1
++/* [0x000028c8] */ 0x804e7036, 0xa42099d1, // nop ; mov.ifz ra_y, ra_y_next ; ldtmu0
++/* [0x000028d0] */ 0x8e5509bf, 0x12024823, // shr r0, r4, ra_xshift ; mov r3, rb_pitch
++/* [0x000028d8] */ 0x13440dc0, 0xd40208a7, // max r2, ra_y, 0
++/* [0x000028e0] */ 0x9269e5f6, 0x10029898, // min r2, r2, rb_max_y ; mov.ifz ra_base, ra_base_next
++/* [0x000028e8] */ 0x4c441dd3, 0xd4224462, // add ra_y, ra_y, 1 ; mul24 r2, r2, r3
++/* [0x000028f0] */ 0x8c618c87, 0x10024e20, // add t0s, ra_base, r2 ; v8min r0, r0, rb_pmask
++/* [0x000028f8] */ 0x4d592bc6, 0x120269e1, // sub.setf -, r5, rb_lcount ; mul24 r1, r0, ra_wt_mul_l0
++/* [0x00002900] */ 0x915c83f6, 0xdc024863, // shl r1, r1, 8 ; mov r3, ra_blk_height
++/* [0x00002908] */ 0xec40c3f3, 0x12024860, // add r1, r1, rb_wt_off ; v8subs r0, ra_height, r3
++/* [0x00002910] */ 0xffffff90, 0xf06809e7, // brr.anyn -, r:1b
++/* [0x00002918] */ 0x0f9cf3c0, 0xd0020867, // asr r1, r1, DENOM + 8
++/* [0x00002920] */ 0x925f23bf, 0x12020867, // min r1, r1, ra_pmax ; mov -, vw_wait
++/* [0x00002928] */ 0x5351039f, 0x18024c22, // max vpm, r1, ra_k0 ; mul24 r2, r3, rb_pitch
++/* [0x00002930] */ 0x956e7036, 0x10126431, // mov.setf ra_height, r0 ; mov vw_setup, ra_dma0
++/* [0x00002938] */ 0x00000000, 0xf027c9e7, // bra.anyz -, ra_link
++/* [0x00002940] */ 0x929dd0ff, 0x10024831, // min r0, r0, r3 ; mov vw_setup, rb_dma1
++/* [0x00002948] */ 0x8d7270f6, 0x10024872, // sub r1, r0, r3 ; mov vw_addr, ra_dest
++/* [0x00002950] */ 0x119d73c0, 0xd0020867, // shl r1, r1, i_shift23
++/* [0x00002958] */ 0xffffff48, 0xf0f809e7, // brr -, r:1b
++/* [0x00002960] */ 0x0c9d2e00, 0x100214a7, // add rb_lcount, rb_lcount, r0
++/* [0x00002968] */ 0x0c6e7c40, 0x100206e7, // add ra_dma0, ra_dma0, r1
++/* [0x00002970] */ 0x8c71ccbf, 0x10024731, // add ra_dest, ra_dest, r2 ; mov vw_setup, rb_vpm_init
++// ::mc_filter_y10_bxx
++/* [0x00002978] */ 0xfffffaf0, 0xf0f807a7, // brr ra_link, r:per_block_setup_10
++/* [0x00002980] */ 0x959a0ff6, 0x10024023, // mov ra0, unif ; mov r3, elem_num
++/* [0x00002988] */ 0xec9c3fd2, 0x100269e5, // add.setf -, rb_ef, rb_ef ; v8subs r5rep, r2, r2
++/* [0x00002990] */ 0x8c001cff, 0x14024800, // add r0, ra0.16b, r3 ; mov rb_xshift2, rb_xshift2_next
++/* [0x00002998] */ 0x1158bdc0, 0xd4020867, // shl r1, ra_wt_off_l0, i_wt_den_p6
++/* [0x000029a0] */ 0x4c5a7cd6, 0x121245a0, // add ra_wt_mul_l0, ra_wt_mul_l0, r3 ; mul24 r0, r2, ra_wt_mul_l0
++/* [0x000029a8] */ 0x4d4a7216, 0x12024860, // sub r1, r1, r0 ; mul24 r0, r2, ra_wt_mul_l1
++/* [0x000029b0] */ 0x8d9c423f, 0x1042531d, // sub rb_wt_off, r1, r0 ; mov ra_ef.8a, rb4
++// :1
++/* [0x000029b8] */ 0x4c745dbe, 0x100279c4, // add.setf -, ra_ef, ra_ef ; mul24 ra4, rb5, ra_ef
++/* [0x000029c0] */ 0x93440dff, 0xd40248a1, // max r2, ra_y, 0 ; mov r1, 0
++/* [0x000029c8] */ 0x9251e5f6, 0x1a0248a3, // min r2, r2, rb_max_y ; mov r3, ra_k1
++/* [0x000029d0] */ 0x4c450cd7, 0xa4224462, // add ra_y, ra_y, r3 ; mul24 r2, r2, rb_pitch ; ldtmu0
++/* [0x000029d8] */ 0x8c606cbf, 0x10024e05, // add t0s, ra_base, r2 ; mov rb5, rb6
++/* [0x000029e0] */ 0x8e5479bf, 0x12024806, // shr r0, r4, ra_xshift ; mov rb6, rb7
++/* [0x000029e8] */ 0x93458c47, 0xb20248a0, // max r2, ra_y2, r1 ; v8min r0, r0, rb_pmask ; ldtmu1
++/* [0x000029f0] */ 0x8e2009f6, 0x10024847, // shr r1, r4, rb_xshift2 ; mov rb7, ra8
++/* [0x000029f8] */ 0x925de5ce, 0x120248a1, // min r2, r2, rb_max_y ; v8min r1, r1, ra_pmax
++/* [0x00002a00] */ 0x4c450cd7, 0x12124462, // add ra_y2, ra_y2, r3 ; mul24 r2, r2, rb_pitch
++/* [0x00002a08] */ 0x8c24feb6, 0x10025f08, // add t1s, rb_base2, r2 ; mov ra8, ra9
++/* [0x00002a10] */ 0x4c038af1, 0xd8025962, // add r5rep, r5, r3 ; mul24 r2, ra0.8a << 8, r1 << 8 @ "mul_used", 0
++/* [0x00002a18] */ 0x5501fff0, 0x180348e2, // mov r3, rb_fir_off_h ; mul24.ifnn r2, ra0.8a, r0
++/* [0x00002a20] */ 0x4d03f6b0, 0xda0248a3, // sub r2, r3, r2 ; mul24 r3, ra0.8b << 1, r0 << 1 @ "mul_used", 0
++/* [0x00002a28] */ 0x40037031, 0xda0109e3, // nop ; mul24.ifn r3, ra0.8b << 9, r1 << 9 @ "mul_used", 0
++/* [0x00002a30] */ 0x4c03e4f0, 0xdc0248a3, // add r2, r2, r3 ; mul24 r3, ra0.8c << 2, r0 << 2 @ "mul_used", 0
++/* [0x00002a38] */ 0x40036031, 0xdc0109e3, // nop ; mul24.ifn r3, ra0.8c << 10, r1 << 10 @ "mul_used", 0
++/* [0x00002a40] */ 0x4d03d4f0, 0xde0248a3, // sub r2, r2, r3 ; mul24 r3, ra0.8d << 3, r0 << 3 @ "mul_used", 0
++/* [0x00002a48] */ 0x40035031, 0xde0109e3, // nop ; mul24.ifn r3, ra0.8d << 11, r1 << 11 @ "mul_used", 0
++/* [0x00002a50] */ 0x4c07c4f0, 0xd80248a3, // add r2, r2, r3 ; mul24 r3, ra1.8a << 4, r0 << 4 @ "mul_used", 0
++/* [0x00002a58] */ 0x40074031, 0xd80109e3, // nop ; mul24.ifn r3, ra1.8a << 12, r1 << 12 @ "mul_used", 0
++/* [0x00002a60] */ 0x4c07b4f0, 0xda0248a3, // add r2, r2, r3 ; mul24 r3, ra1.8b << 5, r0 << 5 @ "mul_used", 0
++/* [0x00002a68] */ 0x40073031, 0xda0109e3, // nop ; mul24.ifn r3, ra1.8b << 13, r1 << 13 @ "mul_used", 0
++/* [0x00002a70] */ 0x4d07a4f0, 0xdc0248a3, // sub r2, r2, r3 ; mul24 r3, ra1.8c << 6, r0 << 6 @ "mul_used", 0
++/* [0x00002a78] */ 0x40072031, 0xdc0109e3, // nop ; mul24.ifn r3, ra1.8c << 14, r1 << 14 @ "mul_used", 0
++/* [0x00002a80] */ 0x4c0794f0, 0xde0248a3, // add r2, r2, r3 ; mul24 r3, ra1.8d << 7, r0 << 7 @ "mul_used", 0
++/* [0x00002a88] */ 0x4c071b71, 0xde0329e3, // add.setf -, r5, r5 ; mul24.ifn r3, ra1.8d << 15, r1 << 15 @ "mul_used", 0
++/* [0x00002a90] */ 0xffffff08, 0xf06809e7, // brr.anyn -, r:1b
++/* [0x00002a98] */ 0x4d0854fe, 0x1a0248a1, // sub r2, r2, r3 ; mul24 r1, rb5, ra2.8b
++/* [0x00002aa0] */ 0x550caffe, 0x1a024260, // mov ra9, rb10 ; mul24 r0, rb10, ra3.8b
++/* [0x00002aa8] */ 0x8f2c25f6, 0xd00242ca, // asr ra11, r2, v_bit_depth - 8 ; mov rb10, ra11
++/* [0x00002ab0] */ 0x4d08623e, 0x1c024860, // sub r1, r1, r0 ; mul24 r0, rb6, ra2.8c
++/* [0x00002ab8] */ 0x4d08723e, 0x1e024860, // sub r1, r1, r0 ; mul24 r0, rb7, ra2.8d
++/* [0x00002ac0] */ 0x4c208237, 0x10024860, // add r1, r1, r0 ; mul24 r0, ra8, rb8
++/* [0x00002ac8] */ 0x4c0ca23e, 0x1c024860, // add r1, r1, r0 ; mul24 r0, rb10, ra3.8c
++/* [0x00002ad0] */ 0x4c2cb237, 0x10024860, // add r1, r1, r0 ; mul24 r0, ra11, rb11
++/* [0x00002ad8] */ 0x0d127380, 0x10020867, // sub r1, r1, ra4
++/* [0x00002ae0] */ 0x8d9cc23f, 0x10024862, // sub r1, r1, r0 ; mov r2, rb_wt_off
++/* [0x00002ae8] */ 0x0f9c63c0, 0xd0020867, // asr r1, r1, 6
++/* [0x00002af0] */ 0x4d591bce, 0x120269e0, // sub.setf -, r5, rb_i_tmu ; mul24 r0, r1, ra_wt_mul_l0
++/* [0x00002af8] */ 0x55653fce, 0x140453e1, // mov.ifz rb_base2, rb_base2_next ; mul24 r1, r1, ra_kmul_add
++/* [0x00002b00] */ 0x8d4e7076, 0x10029851, // sub r1, r0, r1 ; mov.ifz ra_y_y2, ra_y_y2_next
++/* [0x00002b08] */ 0x8d692bf6, 0x1002b9d8, // sub.setf -, r5, rb_lcount ; mov.ifz ra_base, ra_base_next
++/* [0x00002b10] */ 0x8c9f8289, 0xd0024860, // add r1, r1, r2 ; mov r0, r1 << 8
++/* [0x00002b18] */ 0x8c5e7236, 0x1c024863, // add r1, r1, r0 ; mov r3, ra_blk_height
++/* [0x00002b20] */ 0xfffffe78, 0xf06809e7, // brr.anyn -, r:1b
++/* [0x00002b28] */ 0x4f65039f, 0x18024862, // asr r1, r1, ra_wt_den_p7 ; mul24 r2, r3, rb_pitch
++/* [0x00002b30] */ 0x925f23bf, 0x12020867, // min r1, r1, ra_pmax ; mov -, vw_wait
++/* [0x00002b38] */ 0xf34003f3, 0xd2024c20, // max vpm, r1, 0 ; v8subs r0, ra_height, r3
++/* [0x00002b40] */ 0x956e7036, 0x10126431, // mov.setf ra_height, r0 ; mov vw_setup, ra_dma0
++/* [0x00002b48] */ 0x00000000, 0xf027c9e7, // bra.anyz -, ra_link
++/* [0x00002b50] */ 0x929dd0ff, 0x10024831, // min r0, r0, r3 ; mov vw_setup, rb_dma1
++/* [0x00002b58] */ 0x8d7270f6, 0x10024872, // sub r1, r0, r3 ; mov vw_addr, ra_dest
++/* [0x00002b60] */ 0x119d73c0, 0xd0020867, // shl r1, r1, i_shift23
++/* [0x00002b68] */ 0xfffffe30, 0xf0f809e7, // brr -, r:1b
++/* [0x00002b70] */ 0x0c9d2e00, 0x100214a7, // add rb_lcount, rb_lcount, r0
++/* [0x00002b78] */ 0x0c6e7c40, 0x100206e7, // add ra_dma0, ra_dma0, r1
++/* [0x00002b80] */ 0x8c71ccbf, 0x10024731, // add ra_dest, ra_dest, r2 ; mov vw_setup, rb_vpm_init
++// ::mc_filter_y10_b00
++/* [0x00002b88] */ 0xfffff8e0, 0xf0f807a7, // brr ra_link, r:per_block_setup_10
++/* [0x00002b90] */ 0x959a0ff6, 0x10024023, // mov ra0, unif ; mov r3, elem_num
++/* [0x00002b98] */ 0xec9c3fd2, 0x100269e5, // add.setf -, rb_ef, rb_ef ; v8subs r5rep, r2, r2
++/* [0x00002ba0] */ 0x8c001cff, 0x14024800, // add r0, ra0.16b, r3 ; mov rb_xshift2, rb_xshift2_next
++/* [0x00002ba8] */ 0x00000001, 0xe00208a7, // mov r2, 1
++/* [0x00002bb0] */ 0x8c591eb6, 0x10025461, // add rb_i_tmu, rb_i_tmu, r2 ; mov r1, ra_wt_off_mul_l0
++/* [0x00002bb8] */ 0xf158fded, 0xd4025325, // shl rb_wt_off, ra_wt_off_l0, DENOM + 8 ; v8subs r5quad, r5, r5
++/* [0x00002bc0] */ 0x809f8009, 0xd000d9d6, // nop ; mov.ifnz ra_wt_off_mul_l0, r1 << 8
++// :1
++/* [0x00002bc8] */ 0x0d9d1bc0, 0xb00229e7, // sub.setf -, r5, rb_i_tmu ; nop ; ldtmu1
++/* [0x00002bd0] */ 0x8e4c09f6, 0xa0029851, // shr r1, r4, rb_xshift2 ; mov.ifz ra_y_y2, ra_y_y2_next ; ldtmu0
++/* [0x00002bd8] */ 0x8e5509bf, 0x12024823, // shr r0, r4, ra_xshift ; mov r3, rb_pitch
++/* [0x00002be0] */ 0x13440dc0, 0xd40208a7, // max r2, ra_y, 0
++/* [0x00002be8] */ 0x9269e5f6, 0x10029898, // min r2, r2, rb_max_y ; mov.ifz ra_base, ra_base_next
++/* [0x00002bf0] */ 0x4c441dd3, 0xd4224462, // add ra_y, ra_y, 1 ; mul24 r2, r2, r3
++/* [0x00002bf8] */ 0x8c613cbf, 0x10028e0f, // add t0s, ra_base, r2 ; mov.ifz rb_base2, rb_base2_next
++/* [0x00002c00] */ 0x13440dc0, 0xd20208a7, // max r2, ra_y2, 0
++/* [0x00002c08] */ 0x129de5c0, 0x100208a7, // min r2, r2, rb_max_y
++/* [0x00002c10] */ 0x4c441dd3, 0xd2124462, // add ra_y2, ra_y2, 1 ; mul24 r2, r2, r3
++/* [0x00002c18] */ 0x8c5cfe86, 0x12024f20, // add t1s, rb_base2, r2 ; v8min r0, r0, ra_pmax
++/* [0x00002c20] */ 0x545983c6, 0x12024860, // and r1, r1, rb_pmask ; mul24 r0, r0, ra_wt_mul_l0
++/* [0x00002c28] */ 0x4d492bce, 0x120269e1, // sub.setf -, r5, rb_lcount ; mul24 r1, r1, ra_wt_mul_l1
++/* [0x00002c30] */ 0xcc52706e, 0x1a024865, // add r1, r0, r1 ; v8adds r5rep, r5, ra_k1
++/* [0x00002c38] */ 0x915c83f6, 0xdc024863, // shl r1, r1, 8 ; mov r3, ra_blk_height
++/* [0x00002c40] */ 0xec40c3f3, 0x12024860, // add r1, r1, rb_wt_off ; v8subs r0, ra_height, r3
++/* [0x00002c48] */ 0xffffff60, 0xf06809e7, // brr.anyn -, r:1b
++/* [0x00002c50] */ 0x0f9d03c0, 0xd0020867, // asr r1, r1, (DENOM + 9) - 32
++/* [0x00002c58] */ 0x925f23bf, 0x12020867, // min r1, r1, ra_pmax ; mov -, vw_wait
++/* [0x00002c60] */ 0x5351039f, 0x18024c22, // max vpm, r1, ra_k0 ; mul24 r2, r3, rb_pitch
++/* [0x00002c68] */ 0x956e7036, 0x10126431, // mov.setf ra_height, r0 ; mov vw_setup, ra_dma0
++/* [0x00002c70] */ 0x00000000, 0xf027c9e7, // bra.anyz -, ra_link
++/* [0x00002c78] */ 0x929dd0ff, 0x10024831, // min r0, r0, r3 ; mov vw_setup, rb_dma1
++/* [0x00002c80] */ 0x8d7270f6, 0x10024872, // sub r1, r0, r3 ; mov vw_addr, ra_dest
++/* [0x00002c88] */ 0x119d73c0, 0xd0020867, // shl r1, r1, i_shift23
++/* [0x00002c90] */ 0xffffff18, 0xf0f809e7, // brr -, r:1b
++/* [0x00002c98] */ 0x0c9d2e00, 0x100214a7, // add rb_lcount, rb_lcount, r0
++/* [0x00002ca0] */ 0x0c6e7c40, 0x100206e7, // add ra_dma0, ra_dma0, r1
++/* [0x00002ca8] */ 0x8c71ccbf, 0x10024731, // add ra_dest, ra_dest, r2 ; mov vw_setup, rb_vpm_init
++// ::mc_end
++};
++#ifdef __HIGHC__
++#pragma Align_to(8, ff_hevc_rpi_shader)
++#endif
+diff --git a/libavcodec/rpi_hevc_shader.h b/libavcodec/rpi_hevc_shader.h
+new file mode 100644
+index 0000000000..79651c9b6c
+--- /dev/null
++++ b/libavcodec/rpi_hevc_shader.h
+@@ -0,0 +1,63 @@
++#ifndef rpi_hevc_shader_H
++#define rpi_hevc_shader_H
++
++extern unsigned int ff_hevc_rpi_shader[];
++
++#define mc_setup_c_q0 (ff_hevc_rpi_shader + 0)
++#define mc_start (ff_hevc_rpi_shader + 0)
++#define mc_setup_c_qn (ff_hevc_rpi_shader + 2)
++#define mc_filter_c_p (ff_hevc_rpi_shader + 134)
++#define mc_filter_c_p_l1 (ff_hevc_rpi_shader + 260)
++#define mc_filter_c_b (ff_hevc_rpi_shader + 386)
++#define mc_sync_q0 (ff_hevc_rpi_shader + 580)
++#define mc_sync_q1 (ff_hevc_rpi_shader + 598)
++#define mc_sync_q2 (ff_hevc_rpi_shader + 610)
++#define mc_sync_q3 (ff_hevc_rpi_shader + 622)
++#define mc_sync_q4 (ff_hevc_rpi_shader + 634)
++#define mc_sync_q5 (ff_hevc_rpi_shader + 652)
++#define mc_sync_q6 (ff_hevc_rpi_shader + 664)
++#define mc_sync_q7 (ff_hevc_rpi_shader + 676)
++#define mc_sync_q8 (ff_hevc_rpi_shader + 688)
++#define mc_sync_q9 (ff_hevc_rpi_shader + 706)
++#define mc_sync_q10 (ff_hevc_rpi_shader + 718)
++#define mc_sync_q11 (ff_hevc_rpi_shader + 730)
++#define mc_exit_c_qn (ff_hevc_rpi_shader + 742)
++#define mc_exit_y_qn (ff_hevc_rpi_shader + 742)
++#define mc_exit_c_q0 (ff_hevc_rpi_shader + 760)
++#define mc_exit_y_q0 (ff_hevc_rpi_shader + 760)
++#define mc_setup_y_q0 (ff_hevc_rpi_shader + 780)
++#define mc_setup_y_qn (ff_hevc_rpi_shader + 782)
++#define mc_filter_y_pxx (ff_hevc_rpi_shader + 1014)
++#define mc_filter_y_bxx (ff_hevc_rpi_shader + 1140)
++#define mc_filter_y_p00 (ff_hevc_rpi_shader + 1272)
++#define mc_filter_y_b00 (ff_hevc_rpi_shader + 1358)
++#define mc_setup_c10_q0 (ff_hevc_rpi_shader + 1432)
++#define mc_setup_c10_qn (ff_hevc_rpi_shader + 1434)
++#define mc_filter_c10_p (ff_hevc_rpi_shader + 1562)
++#define mc_filter_c10_p_l1 (ff_hevc_rpi_shader + 1684)
++#define mc_filter_c10_b (ff_hevc_rpi_shader + 1806)
++#define mc_sync10_q0 (ff_hevc_rpi_shader + 1996)
++#define mc_sync10_q1 (ff_hevc_rpi_shader + 2014)
++#define mc_sync10_q2 (ff_hevc_rpi_shader + 2026)
++#define mc_sync10_q3 (ff_hevc_rpi_shader + 2038)
++#define mc_sync10_q4 (ff_hevc_rpi_shader + 2050)
++#define mc_sync10_q5 (ff_hevc_rpi_shader + 2068)
++#define mc_sync10_q6 (ff_hevc_rpi_shader + 2080)
++#define mc_sync10_q7 (ff_hevc_rpi_shader + 2092)
++#define mc_sync10_q8 (ff_hevc_rpi_shader + 2104)
++#define mc_sync10_q9 (ff_hevc_rpi_shader + 2122)
++#define mc_sync10_q10 (ff_hevc_rpi_shader + 2134)
++#define mc_sync10_q11 (ff_hevc_rpi_shader + 2146)
++#define mc_exit_c10_q0 (ff_hevc_rpi_shader + 2158)
++#define mc_exit_y10_q0 (ff_hevc_rpi_shader + 2158)
++#define mc_exit_c10_qn (ff_hevc_rpi_shader + 2178)
++#define mc_exit_y10_qn (ff_hevc_rpi_shader + 2178)
++#define mc_setup_y10_q0 (ff_hevc_rpi_shader + 2196)
++#define mc_setup_y10_qn (ff_hevc_rpi_shader + 2198)
++#define mc_filter_y10_pxx (ff_hevc_rpi_shader + 2440)
++#define mc_filter_y10_p00 (ff_hevc_rpi_shader + 2566)
++#define mc_filter_y10_bxx (ff_hevc_rpi_shader + 2654)
++#define mc_filter_y10_b00 (ff_hevc_rpi_shader + 2786)
++#define mc_end (ff_hevc_rpi_shader + 2860)
++
++#endif
+diff --git a/libavcodec/rpi_hevc_shader.qasm b/libavcodec/rpi_hevc_shader.qasm
+new file mode 100644
+index 0000000000..77946a0443
+--- /dev/null
++++ b/libavcodec/rpi_hevc_shader.qasm
+@@ -0,0 +1,1821 @@
++# Inter pred asm
++#
++# Logic here should be good to 14 bits without modification
++# but only 8 & 10 are currently instantiated & tested
++# 15 & 16 bits have different shift1, shift2 calc & I also suspect overflow
++# in _p00 & _b00
++
++# The @ "mul_used", 0 annotations that occur by various mul blocks suppress
++# the warning that we are using rotation & ra/rb registers. r0..3 can be
++# rotated through all 16 elems ra regs can only be rotated through their
++# local 4. As it happens this is what is wanted here as we do not want the
++# constants from the other half of the calc.
++
++# Number limits in P/B calculation
++#
++# In order to avoid issues with mul24 being an unsigned 24->32 bit multiplier
++# we offset our intermediates s.t. they always end up +ve before the next
++# multiply (may be -ve whilst summing but that doesn't matter).
++#
++# Range calc for up to 14 bits (Y-B pred):
++#
++# denom: [0, 7]
++# bmax = (1 << bits) - 1
++# off: [-(1 << (bits-1)), (1 << (bits-1)) - 1]
++#
++# wt_mul: [-128, 255]
++# wt_off = off * 2 + 1: [-bmax, bmax]
++#
++# pel: [0, bmax]
++# H-filter: [(-22*pel + 88*pel) >> (bits-8) + 0x4000] = [0x2a00, 0x97ff]
++# V-filter: [(-22*hf + 88*hf) >> 6] = [0x580, 0xc28e]
++# mul_t = (V_L0 + V_l1) * (wt_mul + 128): [0, 0x24624e6]
++# mul_t - (V_l0 + V_l1)* 128: [-0xc28e00, 0x18396e4]
++# adj_wt_off = (wt_off << ((denom + 6) - (bits - 8))) - 0x4000 * (wt_mul * 2):
++# [wt_off << (21 - bits)] - [wt_mul << 15] = [-0x1fffff, 0x1fffff] - [-0x400000, 0x7f8000]
++#
++# This all looks good and is mostly bit depth independant - and as we manage
++# to do unsigned multiplies everywhere (now) this should be good for any bit
++# depth up to 14 (we could probably do 16 - but that requires a few tweaks
++# to the shifts we don't currently have logic for)
++
++# PREREAD is the number of requests that we have sitting in the TMU request
++# queue.
++#
++# There are 8 slots availible in the TMU request Q for tm0s requests, but
++# only 4 output FIFO entries and overflow is bad (corruption or crash)
++# (If threaded then only 2 out FIFO entries, but we aren't.)
++# In s/w we are effectively limited to the min vertical read which is >= 4
++# so output FIFO is the limit.
++#
++# As the test for read-next is is the main part of the Luma loop (rather than
++# the preload FIFO part) we are limited to min_luma_height - 1
++# Min_luma_height is 4 so we can only have a preload of 3
++# Beware that min_chroma_height (and_width) is 2 so we can't do the same trick
++# in chroma without abandoning preload pretty much entirely (which would be bad)
++#
++# Timing tests vs preload of 4 suggests this doesn't hurt us much
++# Could have preread 4 for Chroma but when tested it didn't help
++
++.set PREREAD, 3
++
++# Offset added (effectively) at the exit of the H FIR filter
++# This is enough to force the result +ve
++# Is good if it is a power of 2 as that allows for >> without loss
++#
++# Worst case for a single Y FIR is *-22 so we need an offset of 256*22
++# But we need twice offset to survive both H & V = 256*22*2 = 0x2c00
++# Round up to next power of 2
++
++.set FIR_OFFSET, 0x4000
++
++# Block heights - 8 & 16 are the only numbers we currently support
++
++.set C_BLK_HEIGHT_8, 16
++.set C_BLK_HEIGHT_16, 8
++.set Y_BLK_HEIGHT_8, 16
++.set Y_BLK_HEIGHT_16, 8
++
++# QPU counts - depend on block size
++# If we have a 2-byte format & block_size > 8 then can only afford
++# 8 QPUs
++# These numbers must match the numbers in ff_hevc_rpi_shader_cmd.h
++
++.set N_QPU_8, 12
++.set N_QPU_16, 12
++
++# Value to add to the weight multiplier to convert it into an unsigned value
++# Should be power of two for convienience
++
++.set LOG2_MUL_ADD, 14
++.set MUL_ADD, (1 << LOG2_MUL_ADD)
++
++# Fixed denom (max that it can be set to)
++.set DENOM, 7
++
++# register allocation
++#
++
++# ra0-3
++# Used as temp and may be loop filter coeffs (split into .8s)
++# or temp in loop. Check usage on an individual basis.
++
++# ra4-11
++# V FIFO / temp / free
++
++# -- free -- ra12
++
++# -- free -- ra13
++
++# -- free -- ra14
++
++# -- free -- ra15
++
++# uniform: width:height
++.set ra_width_height, ra16
++.set ra_width, ra16.16b
++.set ra_height, ra16.16a
++
++# y:y2 same layout as y_y2_next so we can update both together
++.set ra_y_y2, ra17
++.set ra_y2, ra17.16a
++.set ra_y, ra17.16b
++
++# uniform: L1 weight (U on left, V on right)
++# Only used in Y B
++.set ra_wt_off_mul_l1, ra18
++.set ra_wt_off_l1, ra18.16b
++.set ra_wt_mul_l1, ra18.16a
++
++# y_next:y2_next same layout as y_y2 so we can update both together
++.set ra_y_y2_next, ra19
++.set ra_y_next, ra19.16b
++.set ra_y2_next, ra19.16a
++
++# Setup: consts - subdivide a single register
++.set ra_kff800100, ra20
++.set ra_k256, ra20.16a
++.set ra_k0, ra20.8a
++.set ra_k1, ra20.8b
++.set ra_k128, ra20.8c
++.set ra_k255, ra20.8d
++
++# Loop: xshifts
++.set ra_xshift, ra21.16a
++.set ra_xshift_next, ra21.16b
++
++# Loop var: L0 weight (U on left, V on right)
++# _off_ is not used in loop as we want to modify it before use
++.set ra_wt_off_mul_l0, ra22
++.set ra_wt_mul_l0, ra22.16a
++.set ra_wt_off_l0, ra22.16b
++
++# Max pel value (for 8 bit we can get away with sat ops but not 9+)
++# * Could merge with rb_pmask. For 10 bit Logically pmask needs 0xff in the
++# 2nd byte but as the source should never be > 3 there 0x3ff should do
++.set ra_blk_height_pmax, ra23
++.set ra_pmax, ra23.16a
++.set ra_blk_height, ra23.8c
++# --free -- ra23.8d
++
++# Loop: src frame base (L0)
++.set ra_base, ra24
++
++# Misc offsets
++.set ra_fir_off_val_wt_den_p7, ra25
++.set ra_wt_den_p7, ra25.8a
++# -- free -- ra25.8b
++.set ra_fir_off_val, ra25.16b
++
++# As it happens these constants are the same
++.if FIR_OFFSET == MUL_ADD
++# Weight multiplier unsigned add
++.set ra_kmul_add, ra_fir_off_val
++.else
++.error "FIR_OFFSET != MUL_ADD: Need new register & init"
++.endif
++
++# Loop: next src frame base (L0)
++.set ra_base_next, ra26
++
++# Loop: height<<23 + width<<16 + vdw_setup_0
++.set ra_dma0, ra27
++
++# Loop: destination address
++.set ra_dest, ra28
++
++# Setup: Dup of rb_ef
++# Lo bits are used as Y coeff 0 as that lefts us combine test & coeff mul
++# (top bits are ignored by mul24)
++.set ra_ef, ra29
++
++# Use an even numbered register as a link register to avoid corrupting flags
++.set ra_link, ra30
++
++# -- free -- ra31
++
++.set rb_xshift2, rb0
++.set rb_xshift2_next, rb1
++
++# C: (elem & 1) == 0 ? elem * 2 : (elem + 4) * 2
++.set rb_elem_x, rb2
++
++# El Flags
++# After adding to self we to have el even/odd on nc/c and lo/hi on nn/n
++# Duped into ra_ef as sometimes that is easier to use
++.set rb_ef, rb3
++
++# rb4-11
++# Loop: V filter FIFO or V filter coeff
++
++# Loop var: offset to add before shift (round + weighting offsets)
++# Exact value varies by loop
++.set rb_wt_off, rb12
++
++# -- free -- rb13
++
++# -- free -- rb14
++
++# Loop: src frame base (L1)
++.set rb_base2, rb15
++
++# Line pitch (128 for sand128)
++.set rb_pitch, rb16
++
++# Loop count - 2 (set up TMU for next xfer)
++.set rb_i_tmu, rb17
++
++# Loop count for min(height, 16)
++# Y will reset & loop again if height > 16
++.set rb_lcount, rb18
++
++# frame_base2_next
++.set rb_base2_next, rb19
++
++# Setup: Height of Y+C in sand, (x&mask)*xpitch will give
++# offset to the slice
++.set rb_xpitch, rb20
++
++# These 3 consts each save 1 instruction in Y loop setup
++# so whilst they are worthwhile they should be the 1st to die if we need
++# another b reg
++.set rb_y_coeffs_2, rb21 # 0x050b0a00
++.set rb_y_coeffs_3, rb22 # 0x11283a40
++.set rb_y_coeffs_5, rb23 # 0x0a0b0500
++
++# Setup: 0xff (8-bit) / 0xffff (9+ bit)
++.set rb_pmask, rb24
++
++# vdw_setup_1(dst_pitch)
++.set rb_dma1_base, rb25
++
++# Setup: pic width - 1
++# In bytes so 8 bit luma is (width - 1)*1, 16 bit chroma is (width -1)*4 etc.
++.set rb_max_x, rb26
++
++# vdw_setup_0 (depends on QPU number)
++.set rb_dma0_base, rb27
++
++# Setup: vw_setup value to reset VPM write pointer
++.set rb_vpm_init, rb28
++
++# Loop: vdw_setup_1(dst_pitch-width) = stride
++.set rb_dma1, rb29
++
++# Setup: pic_height - 1
++.set rb_max_y, rb30
++
++# Setup: FIR H offset
++.set rb_fir_off_h, rb31
++
++
++# With shifts only the bottom 5 bits are considered so -16=16, -15=17 etc.
++.set i_shift16, -16
++.set i_shift21, -11
++.set i_shift23, -9
++.set i_shift30, -2
++
++# Much of the setup code is common between Y & C
++# Macros that express this - obviously these can't be overlapped
++# so are probably unsuitable for loop code
++
++.macro m_calc_dma_regs, v_bit_depth, v_blk_height, r_vpm, r_dma
++ mov r2, qpu_num
++.if v_bit_depth <= 8
++ # 8 bit version
++ asr r1, r2, 2
++ shl r1, r1, 6
++ and r0, r2, 3
++ or r0, r0, r1
++
++ mov r1, vpm_setup(0, 4, h8p(0, 0)) # 4 is stride - stride acts on ADDR which is Y[5:0],B[1:0] for 8 bit
++ add r_vpm, r0, r1 # VPM 8bit storage
++
++ mov r1, vdw_setup_0(0, 0, dma_h8p(0,0,0)) # height,width added later
++ shl r0, r0, 5
++
++.else
++ # 16 bit version
++ # Limited to 8 QPUs if blk height > 8
++ asr r1, r2, 1
++.if v_blk_height <= 8
++ shl r1, r1, 4
++.else
++ shl r1, r1, 5
++.endif
++ and r0, r2, 1
++ or r0, r0, r1
++
++ mov r1, vpm_setup(0, 2, h16p(0, 0)) # 2 is stride - stride acts on ADDR
++ add r_vpm, r0, r1
++
++ # X = H * 8 so the YH from VPMVCD_WR_SETUP[ADDR] drops into
++ # XY VPMVCD_WR_SETUP[VPMBASE] if shifted left 3 (+ 3 for pos of field in reg)
++ mov r1, vdw_setup_0(0, 0, dma_h16p(0,0,0)) # height,width added later
++ shl r0, r0, 6
++.endif
++ add r_dma, r0, r1 # DMA out
++.endm
++
++
++.macro m_setup_q0
++ srel -, 12
++.endm
++
++# Code start label
++::mc_start
++
++################################################################################
++# mc_setup_c
++#
++# typedef struct qpu_mc_pred_c_s_s {
++# int16_t y;
++# int16_t x;
++# uint32_t base;
++# uint32_t pic_cw; // C Width (== Y width / 2)
++# uint32_t pic_ch; // C Height (== Y Height / 2)
++# uint32_t stride2;
++# uint32_t stride1;
++# uint32_t wdenom;
++# int16_t y2;
++# int16_t x2;
++# uint32_t base2;
++# uint32_t next_fn;
++# } qpu_mc_pred_c_s_t;
++
++.macro m_setup_c, v_bit_depth
++
++# Cannot use mul24 on x as x might be -ve, so must use shift
++.if v_bit_depth <= 8
++.set v_x_shift, 1
++.set v_pmask, 0xff
++.set v_blk_height, C_BLK_HEIGHT_8
++.else
++.set v_x_shift, 2
++.set v_pmask, 0xffff
++.set v_blk_height, C_BLK_HEIGHT_16
++.endif
++
++ mov tmurs, 1 ; mov ra0, unif # No TMU swap ; x_y
++
++ mov r0, [0,2,0,2,0,2,0,2,1,3,1,3,1,3,1,3]
++ shl rb_ef, r0, i_shift30 ; mov ra_base, unif # ; ref_c_base
++
++# Read image dimensions
++ sub r0, unif, 1 # pic c width
++ shl rb_max_x, r0, v_x_shift # rb_max_x in bytes
++ sub rb_max_y, unif, 1 # pic c height
++
++# load constants
++ mov ra_kff800100, 0xff800100
++ mov rb_pmask, v_pmask
++ mov ra_blk_height_pmax, ((1 << v_bit_depth) - 1) | (v_blk_height << 16)
++ mov rb_fir_off_h, (FIR_OFFSET << (v_bit_depth - 8))
++ mov ra_fir_off_val_wt_den_p7, (FIR_OFFSET << 16) | (DENOM + 15 - v_bit_depth)
++
++# get source pitch
++ mov ra_ef, rb_ef ; mov rb_xpitch, unif # ; stride2
++ mov rb_pitch, unif # stride1
++ mov r1, vdw_setup_1(0) # [rb_pitch delay] Merged with dst_stride shortly
++ add rb_dma1_base, r1, rb_pitch # vdw_setup_1
++
++ and r0, 1, elem_num
++ nop ; mul24 r0, r0, 5
++.if v_bit_depth <= 8
++ add rb_elem_x, r0, elem_num
++.else
++ add r0, r0, elem_num
++ add rb_elem_x, r0, r0
++.endif
++
++# Compute base address for first and second access
++# ra_base ends up with t0s base
++# ra_base2 ends up with t1s base
++
++ shl r0, ra0.16b, v_x_shift # [rb_elem_x delay]
++ add r0, r0, rb_elem_x # Add elem no to x to get X for this slice
++ max r0, r0, 0 ; mov ra_y, ra0.16a # ; stash Y
++ min r0, r0, rb_max_x
++
++# Get shift
++# Shift will always calculate as 0 for 9+ bit
++# Ideally we can optimize the shift out of the code in these cases but for now
++# it is tidier to leave it in
++.if v_bit_depth <= 8
++ shl ra_xshift_next, r0, 3
++.else
++ mov ra_xshift_next, 0 ; mov rb_xshift2_next, 0
++.endif
++
++# In a single 32 bit word we get 1 or 2 UV pairs so mask bottom bits of xs if we need to
++
++.if v_bit_depth <= 8
++ and r0, r0, -4
++.endif
++ sub r1, ra_k0, rb_pitch
++ and r1, r0, r1
++ xor r0, r0, r1 ; mul24 r1, r1, rb_xpitch
++ add r0, r0, r1 ; mov ra0, unif # ; next_x2_y2
++ add ra_base, ra_base, r0
++
++# Compute part of VPM to use for DMA output
++# * We only get 8 QPUs if 16 bit - maybe reduce height and auto-loop?
++ m_calc_dma_regs v_bit_depth, v_blk_height, rb_vpm_init, rb_dma0_base
++
++# And again for L1, but only worrying about frame2 stuff
++
++# Compute base address for first and second access
++# ra_base ends up with t0s base
++# rb_base2 ends up with t1s base
++
++ shl r0, ra0.16b, v_x_shift
++ add r0, r0, rb_elem_x ; mov ra_y2, ra0.16a # Add QPU slice offset
++ max r0, r0, 0 ; mov rb_base2, unif # ref_c_base2
++ min r0, r0, rb_max_x
++
++# Get shift (already zero if 9+ bit so ignore)
++.if v_bit_depth <= 8
++ shl rb_xshift2_next, r0, 3
++.endif
++
++# In a single 32 bit word we get 2 UV pairs so mask bottom bit of xs
++
++.if v_bit_depth <= 8
++ and r0, r0, -4
++.endif
++ sub r1, ra_k0, rb_pitch
++ and r1, r0, r1 ; mov r3, PREREAD
++ xor r0, r0, r1 ; mul24 r1, r1, rb_xpitch
++ add r0, r0, r1 ; mov r2, ra_y2
++ add rb_base2, rb_base2, r0 ; mov r0, ra_y
++
++# Do preloads
++# r0 = ra_y, r2 = ra_y2, r3 = PREREAD
++
++:1
++ sub.setf r3, r3, 1
++ max r1, r0, 0
++ min r1, r1, rb_max_y
++ add r0, r0, ra_k1 ; mul24 r1, r1, rb_pitch
++ add t0s, ra_base, r1 ; mov ra_y, r0
++
++ max r1, r2, 0
++ brr.anynz -, r:1b
++ min r1, r1, rb_max_y
++ add r2, r2, ra_k1 ; mul24 r1, r1, rb_pitch
++ add t1s, rb_base2, r1 ; mov ra_y2, r2
++# >>> .anynz 1b
++
++ mov ra_link, unif # link
++# touch registers to keep simulator happy (and fills in delay slots)
++ mov ra4, 0 ; mov rb4, 0
++ bra -, ra_link
++ mov ra5, 0 ; mov rb5, 0
++ mov ra6, 0 ; mov rb6, 0
++ mov ra7, 0 ; mov rb7, 0
++# >>> ra_link
++.endm
++
++::mc_setup_c_q0
++ m_setup_q0
++::mc_setup_c_qn
++ m_setup_c 8
++
++################################################################################
++#
++# mc_filter_c_p
++#
++# typedef struct qpu_mc_pred_c_p_s {
++# int16_t y;
++# int16_t x;
++# uint32_t base;
++# uint16_t h;
++# uint16_t w;
++# uint32_t coeffs_x;
++# uint32_t coeffs_y;
++# uint32_t wo_u;
++# uint32_t wo_v;
++# uint32_t dst_addr_c;
++# uint32_t next_fn;
++# } qpu_mc_pred_c_p_t;
++
++.macro m_filter_c_p, v_tmu, v_bit_depth
++
++.if v_bit_depth <= 8
++.set v_x_shift, 1
++.set v_x_mul, 2
++.set v_v_shift, 8
++# Shifts to get width & height in the right place in rb_dma0
++.set v_dma_h_shift, 7
++.set v_dma_wh_shift, i_shift16
++.else
++.set v_x_shift, 2
++.set v_x_mul, 4
++.set v_v_shift, i_shift16
++# Shifts to get width & height in the right place in rb_dma0
++.set v_dma_h_shift, 8
++.set v_dma_wh_shift, 15
++.endif
++
++.if v_tmu == 0
++.set vrx_xshift, rb_xshift2 # b side more convienient
++.set vrx_xshift_next, ra_xshift_next
++.set vra_y_next, ra_y_next
++.set vrx_base_next, ra_base_next
++.set vra_y, ra_y
++.set vra_base, ra_base
++.set vr_txs, t0s
++.else
++.set vrx_xshift, ra_xshift # a side more convienient
++.set vrx_xshift_next, rb_xshift2_next
++.set vra_y_next, ra_y2_next
++.set vrx_base_next, rb_base2_next
++.set vra_y, ra_y2
++.set vra_base, rb_base2
++.set vr_txs, t1s
++.endif
++
++# denom shift values
++.set i_wt_den_p5, (DENOM + 13 - v_bit_depth)
++.set i_wt_den_p6, (DENOM + 14 - v_bit_depth)
++
++# per-channel shifts were calculated on the *previous* invocation
++# get base addresses and per-channel shifts for *next* invocation
++ mov vw_setup, rb_vpm_init ; mov ra2, unif # ; x_y
++
++ add.setf -, rb_ef, rb_ef ; mov r3, unif # [ra2 delay] ; base
++
++ shl r0, ra2.16b, v_x_shift ; v8subs r5rep, r0, r0 # r5 = 0
++ add r0, r0, rb_elem_x ; mov ra_width_height, unif # r1=pitch2 mask ; width_height
++ sub r1, r5, rb_pitch ; mov ra0, unif # ; H filter coeffs
++ max r0, r0, r5 ; mov vrx_xshift, vrx_xshift_next
++ min r0, r0, rb_max_x ; mov vra_y_next, ra2.16a
++
++.if v_bit_depth <= 8
++ shl vrx_xshift_next, r0, 3
++ and r0, r0, -4
++.endif
++ and r1, r0, r1 ; mul24 r2, ra_width, v_x_mul # r2=w*2 (we are working in pel pairs) ** x*2 already calced!
++ xor r0, r0, r1 ; mul24 r1, r1, rb_xpitch
++ add r0, r0, r1 ; mov ra3, unif # ; V filter coeffs
++ add vrx_base_next, r3, r0 ; mov r1, ra_height
++
++# set up VPM write
++ sub rb_dma1, rb_dma1_base, r2 ; mov ra_wt_off_mul_l0, unif # Compute vdw_setup1(dst_pitch-width) ; U offset/weight
++ add rb_i_tmu, r1, (3-4) - PREREAD ; v8min r1, r1, ra_blk_height
++ add rb_lcount, r1, (3-4) ; mov.ifc ra_wt_off_mul_l0, unif # ; V offset/weight
++
++# Misc final setup...
++
++ shl r0, r1, v_dma_h_shift ; mov ra_dest, unif # ; dst_addr
++ add r0, r0, r2 ; mov r2, ra_fir_off_val # Combine width and height of destination area (r0=h<<8, r2=w*2)
++ shl r0, r0, v_dma_wh_shift ; mov rb10, ra3.8c # Shift into bits 16 upwards of the vdw_setup0 register
++ add ra_dma0, r0, rb_dma0_base ; mov r1, ra_wt_off_l0 # ; r1=weight
++ shl r1, r1, i_wt_den_p5 ; mul24 r0, r2, ra_wt_mul_l0
++ sub rb_wt_off, r1, r0 ; mov r0, ra_kmul_add
++ add ra_wt_mul_l0, ra_wt_mul_l0, r0 ; mov r5rep, -4 # ; loop counter (V FIFO fill = 4)
++ mov rb11, ra3.8d ; mov ra_link, unif # ; Link
++
++# r5 = -4 (loop counter)
++# ra_wt_mul_l0 = weight L0 + 128 (now unsigned)
++# rb_wt_off = (offset * 2 + 1) << (wt_den + 5)
++# rb31 = FIR value offset
++
++# FIFO: rb4, ra5, rb6, ra7
++# Coeffs in ra3.8a, ra3.8b, rb10, rb11
++
++# We want (r0r1)
++# U0U3 : V0V3 : U1U4 : V1V4 : U2U5 : V2U5 : ...
++# We fetch (after shift)
++# C0 : C3 : C1 : C4 : C2 : C5 : ...
++
++:1
++# retrieve texture results and pick out bytes
++# then submit two more texture requests
++
++.if v_tmu == 0
++ sub.setf -, r5, rb_i_tmu ; mov rb4, ra5 ; ldtmu0
++ shr r2, r4, vrx_xshift ; mov.ifz r3, vra_y_next
++ shr r1, r2, v_v_shift ; mov.ifnz r3, vra_y
++ add.setf -, rb_ef, rb_ef ; mov.ifz vra_base, vrx_base_next
++.else
++ sub.setf -, r5, rb_i_tmu ; mov rb4, ra5 ; ldtmu1
++ shr r2, r4, vrx_xshift ; mov.ifz vra_base, vrx_base_next
++ shr r1, r2, v_v_shift ; mov.ifnz r3, vra_y
++ add.setf -, rb_ef, rb_ef ; mov.ifz r3, vra_y_next # [r1 << delay]
++.endif
++
++ add vra_y, r3, ra_k1 ; mov r0, r1 << 15
++ max r3, r3, ra_k0 ; mov.ifnc r1, r2 << 1
++ min r3, r3, rb_max_y ; mov.ifnc r0, r2
++
++ and r1, r1, ra_pmax ; mul24 r3, r3, rb_pitch
++.if v_tmu == 0
++ add vr_txs, vra_base, r3 ; v8min r0, r0, rb_pmask # ; mask bytes
++.else
++ add vr_txs, vra_base, r3 ; v8min r0, r0, ra_pmax # ; mask bytes
++.endif
++
++# apply horizontal filter
++# The filter coeffs for the two halves of this are the same (unlike in the
++# Y case) so it doesn't matter which ra0 we get them from
++# Also as the two halves are locked together we don't need to separate the 1st
++# r0 mul or the last r1 mul as they are valid for all QPUs
++
++ add r5rep, r5, 1 ; mul24 r3, ra0.8a, r0
++ sub r2, rb_fir_off_h, r3 ; mul24 r3, ra0.8d, r1
++ sub r2, r2, r3 ; mul24 r3, ra0.8b << 2, r0 << 2 @ "mul_used", 0
++ nop ; mul24.ifn r3, ra0.8b << 12, r1 << 12 @ "mul_used", 0
++ add r2, r2, r3 ; mul24 r3, ra0.8c << 4, r0 << 4 @ "mul_used", 0
++ add.setf -, r5, r5 ; mul24.ifn r3, ra0.8c << 14, r1 << 14 @ "mul_used", 0
++
++# V filter = - r4 * a + r5 * b + r6 * c - r7 * d (post FIFO shift)
++# We would like to save the r5->r4 shift but we need a delay slot
++# for both r7 & r6 which we can't find anything to put in if we have
++# already multiplied r4 & r5!
++ brr.anyn -, r:1b
++ add r2, r2, r3 ; mul24 r0, ra7, rb10 # r6 post
++ mov ra5, rb6 ; mul24 r1, rb6, ra3.8b # r5 post
++ asr ra7, r2, v_bit_depth - 8 ; mov rb6, ra7
++# >>> .anyn 1b
++
++ add r1, r1, r0 ; mul24 r0, rb4, ra3.8a # [ra7 delay]
++ sub r1, r1, r0 ; mul24 r0, ra7, rb11
++ sub r1, r1, r0
++
++ asr r1, r1, 6 ; mov r3, ra_blk_height # ; NxtLoop
++ sub.setf -, r5, rb_lcount ; mul24 r0, r1, ra_wt_mul_l0
++ add r0, r0, rb_wt_off ; mul24 r1, r1, ra_kmul_add
++ sub r1, r0, r1 ; v8subs r0, ra_height, r3 # ; NxtLoop
++ brr.anyn -, r:1b
++ asr r1, r1, i_wt_den_p6
++ min r1, r1, ra_pmax ; mov -, vw_wait
++ max vpm, r1, ra_k0 ; mul24 r2, r3, rb_pitch # ; NxtLoop
++# >>> .anyn 1b
++
++# r0 = remaining height (min 0)
++# r2 = r3 * rb_pitch
++# r3 = block_height
++
++# If looping again then we consumed 16 height last loop
++# rb_dma1 (stride) remains constant
++# rb_i_tmu remains const (based on total height)
++# recalc ra_dma0, rb_lcount based on new segment height
++
++ mov.setf ra_height, r0 ; mov vw_setup, ra_dma0 # VDW setup 0
++
++# DMA out
++ bra.anyz -, ra_link
++ min r0, r0, r3 ; mov vw_setup, rb_dma1 # Stride
++ sub r1, r0, r3 ; mov vw_addr, ra_dest # start the VDW
++ shl r1, r1, i_shift23
++# >>> .anyz ra_link
++
++# Here r1 = cur_blk_height - 16 so it will be 0 or -ve
++# We add to dma0 to reduce the number of output lines in the final block
++ brr -, r:1b
++ add rb_lcount, rb_lcount, r0
++ add ra_dma0, ra_dma0, r1
++ add ra_dest, ra_dest, r2 ; mov vw_setup, rb_vpm_init # ; Reset our VDM write pointer
++# >>> 1b
++.endm
++
++::mc_filter_c_p
++ m_filter_c_p 0, 8
++
++::mc_filter_c_p_l1
++ m_filter_c_p 1, 8
++
++################################################################################
++#
++# mc_filter_c_b
++#
++# typedef struct qpu_mc_pred_c_b_s {
++# int16_t y;
++# int16_t x;
++# uint32_t base;
++# uint16_t h;
++# uint16_t w;
++# uint32_t coeffs_x1;
++# uint32_t coeffs_y1;
++# int16_t weight_u1;
++# int16_t weight_v1;
++# int16_t y2;
++# int16_t x2;
++# uint32_t base2;
++# uint32_t coeffs_x2;
++# uint32_t coeffs_y2;
++# uint32_t wo_u2;
++# uint32_t wo_v2;
++# uint32_t dst_addr_c;
++# uint32_t next_fn;
++# } qpu_mc_pred_c_b_t;
++
++.macro m_filter_c_b, v_bit_depth
++
++.if v_bit_depth <= 8
++.set v_x_shift, 1
++.set v_v_shift, 8
++# Shifts to get width & height in the right place in ra_dma0
++.set v_dma_h_shift, 7
++.set v_dma_wh_shift, i_shift16
++.else
++.set v_x_shift, 2
++.set v_v_shift, i_shift16
++# Shifts to get width & height in the right place in ra_dma0
++.set v_dma_h_shift, 8
++.set v_dma_wh_shift, 15
++.endif
++.set v_x_mul, (1 << v_x_shift)
++
++# denom shift values
++.set i_wt_den_p5, (DENOM + 13 - v_bit_depth)
++.set i_wt_den_p6, (DENOM + 14 - v_bit_depth)
++
++# per-channel shifts were calculated on the *previous* invocation
++
++# get base addresses and per-channel shifts for *next* invocation
++ mov vw_setup, rb_vpm_init ; mov ra2, unif # ; x_y
++
++ add.setf -, rb_ef, rb_ef ; mov r3, unif # [ra2 delay] ; r3=base
++
++ shl r0, ra2.16b, v_x_shift ; v8subs r5rep, r1, r1 # x ; r5=0
++ add r0, r0, rb_elem_x ; mov ra_y_next, ra2.16a
++ sub r1, r5, rb_pitch ; mov ra_width_height, unif # r1=pitch2 mask ; width_height
++ max r0, r0, r5 ; mov ra_xshift, ra_xshift_next
++ min r0, r0, rb_max_x ; mov ra0, unif # ; L0 H filter coeffs
++
++.if v_bit_depth <= 8
++ shl ra_xshift_next, r0, 3
++.endif
++
++ and r0, r0, -4 ; mov ra2, unif # ; L0 V filter coeffs
++ and r1, r0, r1 ; mul24 r2, ra_width, v_x_mul # r2=x*2 (we are working in pel pairs)
++ xor r0, r0, r1 ; mul24 r1, r1, rb_xpitch
++ add r0, r0, r1 ; mov r1, ra_height # Add stripe offsets ; r1=height
++ add ra_base_next, r3, r0 ; mov rb_xshift2, rb_xshift2_next # ; xshift2 used because B
++
++# set up VPM write
++
++ sub rb_dma1, rb_dma1_base, r2 ; mov ra_wt_off_mul_l0, unif # Compute vdw_setup1(dst_pitch-width) ; U weight
++ add rb_i_tmu, r1, (3-4) - PREREAD ; v8min r1, r1, ra_blk_height
++ add rb_lcount, r1, (3-4) ; mov.ifc ra_wt_mul_l0, ra_wt_off_l0 # ; V weight
++
++ shl r0, r1, v_dma_h_shift ; mov ra3, unif # ; x2_y2
++ add r0, r0, r2 ; mov r3, unif # [ra3 delay] ; base
++ shl r0, r0, v_dma_wh_shift ; mov ra_y2_next, ra3.16a # Shift into bits 16 upwards of the vdw_setup0 register
++ add ra_dma0, r0, rb_dma0_base ; mov r0, ra3.16b # r0=x
++
++# L1 - uniform layout could possibly be optimized
++
++ shl r0, r0, v_x_shift ; mov ra1, unif # r0=x<<shift ; L1 H filter coeffs
++ add r0, r0, rb_elem_x ; mov ra3, unif # ; L1 V filter coeffs
++ sub r1, r5, rb_pitch ; mov ra_wt_off_mul_l1, unif # [ra3 delay] r1=pitch2 mask ; U offset/weight
++ max r0, r0, r5 ; mov ra9, rb_max_y
++ min r0, r0, rb_max_x ; mov r2, ra_kmul_add
++
++.if v_bit_depth <= 8
++ shl rb_xshift2_next, r0, 3
++.endif
++
++ and r0, r0, -4 ; mov.ifc ra_wt_off_mul_l1, unif # ; V offset/weight
++ and r1, r0, r1 ; mov r5rep, -4
++ xor r0, r0, r1 ; mul24 r1, r1, rb_xpitch
++ add r0, r0, r1 ; mov ra_dest, unif # Add stripe offsets ; dst_addr
++ add rb_base2_next, r3, r0 ; mov r0, ra_fir_off_val
++
++ add ra_wt_mul_l0, ra_wt_mul_l0, r2 ; mul24 r1, r0, ra_wt_mul_l0
++ add ra_wt_mul_l1, ra_wt_mul_l1, r2 ; mul24 r0, r0, ra_wt_mul_l1
++ add r0, r0, r1 ; mov r1, ra_wt_off_l1 # ; L0 off unset
++ shl r1, r1, i_wt_den_p6 ; mov rb11, ra3.8d
++ sub rb_wt_off, r1, r0 ; mov ra_link, unif # ; link
++
++ mov ra10, rb_xshift2 ; mov rb7, ra2.8d
++
++# r5 loop counter (-4)
++# ra0 H coeffs L0
++# ra1 H coeffs L1
++# ra2 V coeffs L0
++# ra3 V coeffs L1
++# ra9 rb_max_y alias
++# ra10 rb_xshift2 alias
++
++:1
++# retrieve texture results and pick out bytes
++# then submit two more texture requests
++ sub.setf -, r5, rb_i_tmu ; nop ; ldtmu0
++ shr r2, r4, ra_xshift ; mov.ifz rb_base2, rb_base2_next
++ shr r1, r2, v_v_shift ; mov.ifz ra_y_y2, ra_y_y2_next
++ add.setf -, rb_ef, rb_ef ; mov.ifz ra_base, ra_base_next # [ra_y delay]
++ add ra_y, 1, ra_y ; mov r3, ra_y
++
++ max r3, r3, ra_k0 ; mov r0, r1 << 15
++ min r3, r3, ra9 ; mov.ifnc r1, r2 << 1
++
++ mov.ifnc r0, r2 ; mul24 r3, r3, rb_pitch
++ add t0s, ra_base, r3 ; v8min r0, r0, rb_pmask # ; masks bytes
++
++# L0 H-filter (-ra4*, +rb5, +rb6, -ra7)
++
++ and r1, r1, rb_pmask ; mul24 r2, ra0.8a, r0
++ sub r2, rb_fir_off_h, r2 ; mul24 r3, ra0.8d, r1
++ sub r2, r2, r3 ; mul24 r3, ra0.8b << 2, r0 << 2 @ "mul_used", 0
++ nop ; mul24.ifn r3, ra0.8b << 12, r1 << 12 @ "mul_used", 0
++ add r2, r2, r3 ; mul24 r3, ra0.8c << 4, r0 << 4 @ "mul_used", 0
++ nop ; mul24.ifn r3, ra0.8c << 14, r1 << 14 @ "mul_used", 0
++
++ add r0, r2, r3 ; mul24 ra4, rb5, ra2.8a ; ldtmu1
++
++ shr r2, r4, ra10 ; mov rb5, rb6
++ shr r1, r2, v_v_shift ; mov r3, ra_y2
++ shr ra7, r0, v_bit_depth - 8 ; mov rb6, ra7 # [r1 << delay]
++
++ add ra_y2, r3, ra_k1 ; mov r0, r1 << 15
++ max r3, r3, ra_k0 ; mov.ifnc r1, r2 << 1
++ min r3, r3, rb_max_y ; v8min r1, r1, ra_pmax
++
++ mov.ifnc r0, r2 ; mul24 r3, r3, rb_pitch
++ add t1s, rb_base2, r3 ; v8min r0, r0, ra_pmax # ; masks bytes
++
++# L1 H-filter (-r0*, +rb9, +rb10, -ra11)
++
++ add r5rep, r5, 1 ; mul24 r2, ra1.8a, r0
++ sub r2, rb_fir_off_h, r2 ; mul24 r3, ra1.8d, r1
++ sub r2, r2, r3 ; mul24 r3, ra1.8b << 2, r0 << 2 @ "mul_used", 0
++ nop ; mul24.ifn r3, ra1.8b << 12, r1 << 12 @ "mul_used", 0
++ add r2, r3, r2 ; mul24 r3, ra1.8c << 4, r0 << 4 @ "mul_used", 0
++ add.setf -, r5, r5 ; mul24.ifn r3, ra1.8c << 14, r1 << 14 @ "mul_used", 0
++
++ brr.anyn -, r:1b
++ add r2, r2, r3 ; mul24 r0, rb9, ra3.8a
++ mov rb9, rb10 ; mul24 r1, rb10, ra3.8b
++ shr ra11, r2, v_bit_depth - 8 ; mov rb10, ra11
++# >>> .anyn 1b
++
++ sub r2, r1, r0 ; mul24 r1, rb5, ra2.8b # L1 ; L0
++ sub.setf -, r5, rb_lcount ; mov r0, ra4
++ sub r1, r1, r0 ; mul24 r0, rb6, ra2.8c
++ add r1, r1, r0 ; mul24 r0, ra7, rb7
++
++ sub r1, r1, r0 ; mul24 r0, rb10, ra3.8c # L1
++ add r2, r2, r0 ; mul24 r0, ra11, rb11 # L1
++ sub r2, r2, r0
++
++ shr r1, r1, 6
++ shr r2, r2, 6 ; mul24 r0, r1, ra_wt_mul_l0
++ add r2, r2, r1 ; mul24 r1, r2, ra_wt_mul_l1
++ add r1, r1, r0 ; mul24 r2, r2, ra_kmul_add
++ sub r1, r1, r2 ; mov r3, ra_blk_height # ; NxtLoop
++ add r1, r1, rb_wt_off ; v8subs r0, ra_height, r3 # ; NxtLoop
++
++ brr.anyn -, r:1b
++ asr r1, r1, ra_wt_den_p7
++ min r1, r1, ra_pmax ; mov -, vw_wait
++ max vpm, r1, ra_k0 ; mul24 r2, r3, rb_pitch # ; NxtLoop
++# >>> .anyn 1b
++
++# r0 = remaining height (min 0)
++# r2 = r3 * rb_pitch
++# r3 = block_height
++
++# If looping again then we consumed 16 height last loop
++# rb_dma1 (stride) remains constant
++# rb_i_tmu remains const (based on total height)
++# recalc ra_dma0, rb_lcount based on new segment height
++
++ mov.setf ra_height, r0 ; mov vw_setup, ra_dma0 # ; VDW setup 0
++
++# DMA out
++ bra.anyz -, ra_link
++ min r0, r0, r3 ; mov vw_setup, rb_dma1 # ; Stride
++ sub r1, r0, r3 ; mov vw_addr, ra_dest # ; start the VDW
++ shl r1, r1, i_shift23
++# >>> .anyz ra_link
++
++# Here r1 = cur_blk_height - 16 so it will be 0 or -ve
++# We add to dma0 to reduce the number of output lines in the final block
++ brr -, r:1b
++ add rb_lcount, rb_lcount, r0
++ add ra_dma0, ra_dma0, r1
++ add ra_dest, ra_dest, r2 ; mov vw_setup, rb_vpm_init # ; Reset our VDM write pointer
++# >>> 1b
++.endm
++
++::mc_filter_c_b
++ m_filter_c_b 8
++
++################################################################################
++# Exit code used by both Luma & Chroma so place between them to avoid I-cache
++# conflicts
++
++.macro m_exit_drain
++.if PREREAD == 2
++# Special case 2 as loop is wasteful
++ nop ; nop ; ldtmu0
++ nop ; nop ; ldtmu1
++ nop ; nop ; ldtmu0
++ mov -, vw_wait ; nop ; ldtmu1
++.else
++ mov.setf r3, PREREAD - 1
++:1
++ brr.anynz -, r:1b
++ nop ; nop ; ldtmu0
++ nop ; nop ; ldtmu1
++ sub.setf r3, r3, 1
++ # >>>
++ mov -, vw_wait
++.endif
++.endm
++
++# This sync layout groups QPUs 0-3, 4-7, 8-11 (i.e. 1 group per TMU pair)
++# All qpus start at the beginning and after that (group - 1) must have finished
++# before (group) can start
++#
++# Requires setup code for QPU 0 to srel sem 12 (m_setup_q0) to start the chain
++# Exit code will sacq sem 12 so everything is @ 0 on exit (this is important -
++# lockup otherwise)
++#
++# There is some, currently ill defined, potential lockup if we have the VDM active
++# whilst doing sem stuff so we wait first. ?? QPU stall from sem stalls VDM pipe too ??
++#
++# The code stalled when I had many waiters on a single sem so we have a
++# "ripple" of srels to restart. Unsure why, may have been bug, but this works
++# and we currently have both the memory & sems to support it.
++.macro m_sync_q, n_qpu, n_quads
++# Do not generate code for qpu >= quads * 4 - fns should never be called
++.if n_qpu < n_quads * 4
++ mov ra_link, unif # Can only branch to an a reg (not r0)
++ mov -, vw_wait # [ra_link delay]
++
++.set n_sem_sync, n_qpu - (n_qpu % 4)
++.set n_sem_in, n_qpu
++.set n_sem_out, n_qpu + 1
++
++.if n_qpu % 4 == 0
++
++.set n_sem_quad_in, 12 + n_qpu / 4
++.set n_sem_quad_out, 12 + (((n_qpu / 4) + 1) % n_quads)
++
++ sacq -, n_sem_sync
++ sacq -, n_sem_sync
++ sacq -, n_sem_sync
++ bra -, ra_link
++ sacq -, n_sem_quad_in
++ srel -, n_sem_out
++ srel -, n_sem_quad_out
++
++.else
++ bra -, ra_link
++ srel -, n_sem_sync
++ sacq -, n_sem_in
++.if n_sem_out % 4 != 0
++ srel -, n_sem_out
++.else
++ nop
++.endif
++.endif
++.endif
++.endm
++
++.set v_quads8, N_QPU_8 / 4
++
++::mc_sync_q0
++ m_sync_q 0, v_quads8
++::mc_sync_q1
++ m_sync_q 1, v_quads8
++::mc_sync_q2
++ m_sync_q 2, v_quads8
++::mc_sync_q3
++ m_sync_q 3, v_quads8
++::mc_sync_q4
++ m_sync_q 4, v_quads8
++::mc_sync_q5
++ m_sync_q 5, v_quads8
++::mc_sync_q6
++ m_sync_q 6, v_quads8
++::mc_sync_q7
++ m_sync_q 7, v_quads8
++::mc_sync_q8
++ m_sync_q 8, v_quads8
++::mc_sync_q9
++ m_sync_q 9, v_quads8
++::mc_sync_q10
++ m_sync_q 10, v_quads8
++::mc_sync_q11
++ m_sync_q 11, v_quads8
++
++# mc_exit()
++# Chroma & Luma the same now
++
++.macro m_exit_qn
++ m_exit_drain
++ nop ; nop ; thrend
++ nop
++ nop
++# >>> thrend <<<
++.endm
++
++::mc_exit_c_qn
++::mc_exit_y_qn
++ m_exit_qn
++
++
++
++# mc_interrupt_exit12()
++
++.macro m_exit_q0
++ m_exit_drain
++ sacq -, 12
++ nop ; nop ; thrend
++ mov interrupt, 1
++ nop
++# >>> thrend <<<
++.endm
++
++::mc_exit_c_q0
++::mc_exit_y_q0
++ m_exit_q0
++
++# LUMA CODE
++
++# The idea is to form B predictions by doing 8 pixels from ref0 in parallel with 8 pixels from ref1.
++# For P frames we make the second x,y coordinates offset by +8
++
++
++################################################################################
++# mc_setup
++#
++# typedef struct qpu_mc_pred_y_s_s {
++# qpu_mc_src_t next_src1;
++# qpu_mc_src_t next_src2;
++# uint16_t pic_h;
++# uint16_t pic_w;
++# uint32_t stride2;
++# uint32_t stride1;
++# uint32_t wdenom;
++# uint32_t next_fn;
++# } qpu_mc_pred_y_s_t;
++
++.macro m_setup_y, v_bit_depth
++
++# Cannot use mul24 on x as x might be -ve, so must use shift
++.if v_bit_depth <= 8
++.set v_x_shift, 0
++.set v_pmask, 0xff
++.set v_blk_height, Y_BLK_HEIGHT_8
++.else
++.set v_x_shift, 1
++.set v_pmask, 0xffff
++.set v_blk_height, Y_BLK_HEIGHT_16
++.endif
++
++
++ # Need to save these because we need to know the frame dimensions before computing texture coordinates
++ mov tmurs, 1 ; mov ra0, unif # No TMU swap ; x_y
++ mov ra9, unif # ref_y_base
++ mov ra1, unif # x2_y2
++
++
++# load constants
++ mov r0, [0,2,0,2,0,2,0,2,1,3,1,3,1,3,1,3]
++ shl rb_ef, r0, i_shift30 ; mov ra11, unif # ; ref_y2_base
++
++ mov ra_kff800100, 0xff800100
++ mov rb_pmask, v_pmask
++ mov ra_blk_height_pmax, ((1 << v_bit_depth) - 1) | (v_blk_height << 16)
++ mov rb_fir_off_h, (FIR_OFFSET << (v_bit_depth - 8))
++ mov ra_fir_off_val_wt_den_p7, (FIR_OFFSET << 16) | (DENOM + 15 - v_bit_depth)
++ mov rb_y_coeffs_2, 0x050b0a00
++ mov rb_y_coeffs_3, 0x11283a40
++ mov rb_y_coeffs_5, 0x0a0b0500
++
++# Compute part of VPM to use
++
++# Read image dimensions
++ mov ra3, unif # width_height
++ mov ra_ef, rb_ef ; mov rb_xpitch, unif # [ra3 delay] ; stride2
++.if v_x_shift == 0
++ sub rb_max_x, ra3.16b, 1
++.else
++ sub r0, ra3.16b, 1
++ shl rb_max_x, r0, v_x_shift
++.endif
++ sub rb_max_y, ra3.16a, 1
++ mov r3, elem_num ; mov rb_pitch, unif # stride1
++
++# get destination pitch
++ mov r1, vdw_setup_1(0) # [rb_pitch delay]
++ or rb_dma1_base, r1, rb_pitch
++
++# Compute base address for first and second access
++ add r0, ra0.16b, r3 # Load x + elem_num
++.if v_x_shift != 0
++ shl r0, r0, v_x_shift
++.endif
++ max r0, r0, 0
++ min r0, r0, rb_max_x
++ shl ra_xshift_next, r0, 3 # Compute shifts
++
++# X is byte offset - we can only load words - mask
++
++ and r0, r0, -4 ; v8subs r2, r2, r2
++ sub r2, r2, rb_pitch
++ and r1, r0, r2
++ xor r0, r0, r1 ; mul24 r1, r1, rb_xpitch
++ add r0, r0, r1 # Add stripe offsets
++ add ra_base, ra9, r0
++
++ # r3 still contains elem_num
++ add r0, ra1.16b, r3 # Load x
++.if v_x_shift != 0
++ shl r0, r0, v_x_shift
++.endif
++ max r0, r0, 0
++ min r0, r0, rb_max_x
++ shl rb_xshift2_next, r0, 3 # Compute shifts
++
++ # r2 still contains mask
++ and r0, r0, -4
++ and r1, r0, r2
++ xor r0, r0, r1 ; mul24 r1, r1, rb_xpitch
++ add r0, r0, r1 # Add stripe offsets
++ add rb_base2, ra11, r0
++
++# Do preloads
++ nop ; mov r0, ra0.16a # ; r0 = y
++ mov r3, PREREAD ; mov r2, ra1.16a # ; r2 = y2
++
++:1
++ sub.setf r3, r3, 1
++ max r1, r0, 0
++ min r1, r1, rb_max_y
++ add r0, r0, ra_k1 ; mul24 r1, r1, rb_pitch
++ add t0s, ra_base, r1 ; mov ra_y, r0
++
++ max r1, r2, 0
++ brr.anynz -, r:1b
++ min r1, r1, rb_max_y
++ add r2, r2, ra_k1 ; mul24 r1, r1, rb_pitch
++ add t1s, rb_base2, r1 ; mov ra_y2, r2
++# >>> .anynz 1b
++
++ m_calc_dma_regs v_bit_depth, v_blk_height, rb_vpm_init, rb_dma0_base
++
++ mov ra_link, unif # Next fn
++
++# touch vertical context to keep simulator happy
++ mov ra8, 0 ; mov rb8, 0 # [ra_link delay]
++ bra -, ra_link
++ mov ra9, 0 ; mov rb9, 0
++ mov ra10, 0 ; mov rb10, 0
++ mov ra11, 0 ; mov rb11, 0
++# >>> ra_link
++.endm
++
++::mc_setup_y_q0
++ m_setup_q0
++::mc_setup_y_qn
++ m_setup_y 8
++
++################################################################################
++#
++# Start of per-block setup code
++# P and B blocks share the same setup code to save on Icache space
++
++# get base addresses and per-channel shifts for *next* invocation
++# per-channel shifts were calculated on the *previous* invocation
++
++# 1st 3 instructions of per_block-setup in branch delay
++#
++# typedef struct qpu_mc_pred_y_p_s {
++# qpu_mc_src_t next_src1;
++# qpu_mc_src_t next_src2;
++# uint16_t h;
++# uint16_t w;
++# uint32_t mymx21;
++# uint32_t wo1;
++# uint32_t wo2;
++# uint32_t dst_addr;
++# uint32_t next_fn;
++# } qpu_mc_pred_y_p_t;
++#
++
++.macro m_luma_setup, v_bit_depth
++# Hack - QASM may well have have label pasting but I have no idea how...
++.if v_bit_depth == 8
++ brr ra_link, r:per_block_setup_8
++.elif v_bit_depth == 10
++ brr ra_link, r:per_block_setup_10
++.endif
++ mov ra0, unif ; mov r3, elem_num # y_x ; elem_num has implicit unpack??
++ add.setf -, rb_ef, rb_ef ; v8subs r5rep, r2, r2 # [ra0 delay] ; r5 = 0
++ add r0, ra0.16b, r3 ; mov rb_xshift2, rb_xshift2_next
++.endm
++
++.macro m_per_block_setup, v_bit_depth
++
++.if v_bit_depth <= 8
++.set v_x_shift, 0
++.set v_x_mul, 1
++# Shifts to get width & height in the right place in ra_dma0
++.set v_dma_h_shift, 7
++.set v_dma_wh_shift, i_shift16
++.else
++.set v_x_shift, 1
++.set v_x_mul, 2
++# Shifts to get width & height in the right place in ra_dma0
++.set v_dma_h_shift, 8
++.set v_dma_wh_shift, 15
++.endif
++
++.if v_x_shift != 0
++ shl r0, r0, v_x_shift
++.endif
++ max r0, r0, r5 ; mov ra_xshift, ra_xshift_next
++ min r0, r0, rb_max_x
++
++ shl ra_xshift_next, r0, 3 # Compute shifts
++ and r0, r0, -4
++ sub r2, r5, rb_pitch ; mov ra_base_next, unif # ; src1.base
++ and r1, r0, r2 ; mov ra_y_next, ra0.16a
++ xor r0, r0, r1 ; mul24 r1, r1, rb_xpitch
++ add r0, r0, r1 ; mov ra1, unif # Add stripe offsets ; src2.x_y
++ add ra_base_next, ra_base_next, r0 # [ra1 delay]
++
++ add r0, ra1.16b, r3 # Load x2
++.if v_x_shift != 0
++ shl r0, r0, v_x_shift
++.endif
++ max r0, r0, r5 ; mov ra_y2_next, ra1.16a
++ min r0, r0, rb_max_x ; mov rb_base2_next, unif # ; src2.base
++ shl rb_xshift2_next, r0, 3 # Compute shifts
++ and r0, r0, -4 ; mov ra_width_height, unif # ; width_height
++ and r1, r0, r2 ; mov vw_setup, rb_vpm_init # ; set up VPM write
++ xor r0, r0, r1 ; mul24 r1, r1, rb_xpitch
++ add r0, r0, r1 ; mul24 r1, ra_width, v_x_mul # Add stripe offsets ; r1 = x in bytes
++ add rb_base2_next, rb_base2_next, r0
++
++# get width,height of block (unif load above), r1 = width * pel_size
++ sub rb_dma1, rb_dma1_base, r1 ; mov r0, ra_height # Compute vdw_setup1(dst_pitch-width)
++ add rb_i_tmu, r0, (7-8) - PREREAD ; v8min r0, r0, ra_blk_height
++ add rb_lcount, r0, (7-8)
++ shl r0, r0, v_dma_h_shift ; mov r3, ra_kmul_add # ; r3 return val
++ add r0, r0, r1 # Combine width and height of destination area
++ shl r0, r0, v_dma_wh_shift ; mov r2, ra_fir_off_val # Shift into bits 16 upwards of the vdw_setup0 register ; r2 return val
++ add ra_dma0, r0, rb_dma0_base ; mov r0, unif # ; Packed filter offsets
++
++# get filter coefficients and discard unused B frame values
++ shl.ifnn r0, r0, i_shift16 ; mov ra_wt_off_mul_l0, unif # Pick half to use ; L0 offset/weight
++ shl ra8, r0, 3 ; mov rb5, ra_k255
++
++# Coeffs are all abs values here as that means mul24 works (no sign extend from .8)
++
++# 2nd half coeffs same as first if we can swap 8<->24 in the rotate val
++# but I can't see a way of doing that that is cheap enough to be worth it
++
++# Picked out in a slightly random order to space out uniform loads
++
++ # 1
++ mov r1, 0x01040400 # [ra8 delay]
++ ror ra2.8b, r1, ra8.8d
++ ror ra0.8b, r1, ra8.8c
++ # 2
++ ror ra2.8c, rb_y_coeffs_2, ra8.8d
++ ror ra0.8c, rb_y_coeffs_2, ra8.8c
++ # 0
++ mov r1,0x00010100 # -ve [ra8 delay]
++ ror r0, r1, ra8.8d ; mov ra_wt_off_mul_l1, unif # ; L1 Wt/Offset
++ ror ra0.8a, r1, ra8.8c ; v8min rb4, r0, rb5
++ # 7
++ shl r1, r1, 8 ; mov.ifn ra_wt_off_mul_l0, ra_wt_off_mul_l1 # r1 = 0x01010000
++ ror r0, r1, ra8.8d ; mov ra_dest, unif # ; Destination address
++ ror ra1.8d, r1, ra8.8c ; v8min rb11, r0, rb5
++ # 3
++ ror ra2.8d, rb_y_coeffs_3, ra8.8d
++ ror ra0.8d, rb_y_coeffs_3, ra8.8c
++ # 5
++ ror ra3.8b, rb_y_coeffs_5, ra8.8d
++ ror ra1.8b, rb_y_coeffs_5, ra8.8c
++ # 6
++ mov r1,0x04040100
++ ror ra3.8c, r1, ra8.8d
++ ror ra1.8c, r1, ra8.8c ; mov r5rep, -8 # ; r5 return val
++
++ bra -, ra_link
++ # 4
++ mov r1,0x3a281100
++ ror r0, r1, ra8.8d ; mov ra_link, unif # ; link - load after we've used its previous val
++ ror ra1.8a, r1, ra8.8c ; v8min rb8, r0, rb5
++# >>> branch ra_link
++
++# r5 = -8
++# r2 = fir_off_val
++# r3 = 128
++.endm
++
++:per_block_setup_8
++ m_per_block_setup 8
++
++
++
++################################################################################
++#
++# mc_filter_y_pxx
++#
++# Setup (& therefore uniform struct) shared with _bxx
++# Struct in m_luma_setup
++#
++# We can have 2 separate P reqs here as long as they mate to generate a
++# rectangular output block (i.e. h0 = h1, w0 = 8)
++#
++# At this point we have already issued PREREAD pairs of texture requests for the current block
++
++.macro m_filter_y_pxx, v_bit_depth
++
++# denom shift values
++.set i_wt_den_p5, (DENOM + 13 - v_bit_depth)
++.set i_wt_den_p6, (DENOM + 14 - v_bit_depth)
++
++ m_luma_setup v_bit_depth
++
++ shl r1, ra_wt_off_l0, i_wt_den_p5
++ add ra_wt_mul_l0, ra_wt_mul_l0, r3 ; mul24 r0, r2, ra_wt_mul_l0 # r2 = 0x4000 so mul24 safe even with -ve wt_mul
++ sub rb_wt_off, r1, r0 ; mov ra_ef.8a, rb4
++
++# retrieve texture results and pick out bytes
++# then submit two more texture requests
++
++# This loop is identical to the B loop from here --->
++:1
++ add.setf -, ra_ef, ra_ef ; mul24 ra4, rb5, ra_ef
++
++ max r2, ra_y, 0 ; mov r1, 0
++ min r2, r2, rb_max_y ; mov r3, ra_k1
++ add ra_y, ra_y, r3 ; mul24 r2, r2, rb_pitch ; ldtmu0
++ add t0s, ra_base, r2 ; mov rb5, rb6
++ shr r0, r4, ra_xshift ; mov rb6, rb7
++
++ max r2, ra_y2, r1 ; v8min r0, r0, rb_pmask ; ldtmu1 # ; masks out all but wanted bytes
++ shr r1, r4, rb_xshift2 ; mov rb7, ra8
++ min r2, r2, rb_max_y ; v8min r1, r1, ra_pmax
++ add ra_y2, ra_y2, r3 ; mul24 r2, r2, rb_pitch
++ add t1s, rb_base2, r2 ; mov ra8, ra9
++
++# apply horizontal filter
++ add r5rep, r5, r3 ; mul24 r2, ra0.8a << 8, r1 << 8 @ "mul_used", 0
++ mov r3, rb_fir_off_h ; mul24.ifnn r2, ra0.8a, r0
++ sub r2, r3, r2 ; mul24 r3, ra0.8b << 1, r0 << 1 @ "mul_used", 0
++ nop ; mul24.ifn r3, ra0.8b << 9, r1 << 9 @ "mul_used", 0
++ add r2, r2, r3 ; mul24 r3, ra0.8c << 2, r0 << 2 @ "mul_used", 0
++ nop ; mul24.ifn r3, ra0.8c << 10, r1 << 10 @ "mul_used", 0
++ sub r2, r2, r3 ; mul24 r3, ra0.8d << 3, r0 << 3 @ "mul_used", 0
++ nop ; mul24.ifn r3, ra0.8d << 11, r1 << 11 @ "mul_used", 0
++ add r2, r2, r3 ; mul24 r3, ra1.8a << 4, r0 << 4 @ "mul_used", 0
++ nop ; mul24.ifn r3, ra1.8a << 12, r1 << 12 @ "mul_used", 0
++ add r2, r2, r3 ; mul24 r3, ra1.8b << 5, r0 << 5 @ "mul_used", 0
++ nop ; mul24.ifn r3, ra1.8b << 13, r1 << 13 @ "mul_used", 0
++ sub r2, r2, r3 ; mul24 r3, ra1.8c << 6, r0 << 6 @ "mul_used", 0
++ nop ; mul24.ifn r3, ra1.8c << 14, r1 << 14 @ "mul_used", 0
++ add r2, r2, r3 ; mul24 r3, ra1.8d << 7, r0 << 7 @ "mul_used", 0
++ add.setf -, r5, r5 ; mul24.ifn r3, ra1.8d << 15, r1 << 15 @ "mul_used", 0
++
++ brr.anyn -, r:1b
++ sub r2, r2, r3 ; mul24 r1, rb5, ra2.8b
++ mov ra9, rb10 ; mul24 r0, rb10, ra3.8b
++ asr ra11, r2, v_bit_depth - 8 ; mov rb10, ra11
++ # >>> .anyn 1b (r5 + r5)
++
++ # apply vertical filter and write to VPM
++ # - r4* + r5 - r6 + r7 + r8 - r9 + r10 - r11
++
++ sub r1, r1, r0 ; mul24 r0, rb6, ra2.8c
++ sub r1, r1, r0 ; mul24 r0, rb7, ra2.8d
++ add r1, r1, r0 ; mul24 r0, ra8, rb8
++ add r1, r1, r0 ; mul24 r0, rb10, ra3.8c
++ add r1, r1, r0 ; mul24 r0, ra11, rb11
++# <--- to here
++ sub.setf -, r5, rb_i_tmu ; mov r3, ra_blk_height # ; NxtLoop: r3 = block height
++ sub r1, r1, ra4 ; mov.ifz rb_base2, rb_base2_next
++ sub r1, r1, r0 ; mov.ifz ra_base, ra_base_next
++
++ asr r1, r1, 6 ; mov.ifz ra_y_y2, ra_y_y2_next
++ sub.setf -, r5, rb_lcount ; mul24 r0, r1, ra_wt_mul_l0
++ add r0, r0, rb_wt_off ; mul24 r1, r1, ra_kmul_add
++ sub r1, r0, r1 ; v8subs r0, ra_height, r3 # ; NxtLoop: r0 = remaining height (0 saturate)
++
++ brr.anyn -, r:1b
++ asr r1, r1, i_wt_den_p6
++ min r1, r1, ra_pmax ; mov -, vw_wait
++ max vpm, r1, ra_k0 ; mul24 r2, r3, rb_pitch # ; NxtLoop
++# >>> branch.anyn 1b (r5 - rb_lcount)
++
++# r0 = remaining height (min 0)
++# r2 = r3 * rb_pitch
++# r3 = block_height
++
++# If looping again then we consumed 16 height last loop
++# rb_dma1 (stride) remains constant
++# rb_i_tmu remains const (based on total height)
++# recalc ra_dma0, rb_lcount based on new segment height
++
++ mov.setf ra_height, r0 ; mov vw_setup, ra_dma0 # VDW setup 0
++
++# DMA out
++ bra.anyz -, ra_link
++ min r0, r0, r3 ; mov vw_setup, rb_dma1 # Stride
++ sub r1, r0, r3 ; mov vw_addr, ra_dest # start the VDW
++ shl r1, r1, i_shift23
++# >>> .anyz ra_link
++
++# Here r1 = cur_blk_height - 16 so it will be 0 or -ve
++# We add to dma0 to reduce the number of output lines in the final block
++ brr -, r:1b
++ add rb_lcount, rb_lcount, r0
++ add ra_dma0, ra_dma0, r1
++ add ra_dest, ra_dest, r2 ; mov vw_setup, rb_vpm_init # ; Reset our VDM write pointer
++# >>> 1b
++.endm
++
++::mc_filter_y_pxx
++ m_filter_y_pxx 8
++
++
++################################################################################
++
++# mc_filter_b(y_x, base, y2_x2, base2, width_height, my2_mx2_my_mx, offsetweight0, this_dst, next_kernel)
++#
++# Setup (& therefore uniform struct) shared with _pxx
++# Struct in m_luma_setup
++#
++# l0 calc in els 0-7, L1 in 8-15
++# Only els 0-7 write data that is stored back to ram (els 8-15 may write tosh)
++#
++# At this point we have already issued PREREAD pairs of texture requests for the current block
++
++.macro m_filter_y_bxx, v_bit_depth
++
++# denom shift values
++.set i_wt_den_p5, (DENOM + 13 - v_bit_depth)
++.set i_wt_den_p6, (DENOM + 14 - v_bit_depth)
++
++ m_luma_setup v_bit_depth
++
++ shl r1, ra_wt_off_l0, i_wt_den_p6
++ add ra_wt_mul_l0, ra_wt_mul_l0, r3 ; mul24 r0, r2, ra_wt_mul_l0
++ sub r1, r1, r0 ; mul24 r0, r2, ra_wt_mul_l1
++ sub rb_wt_off, r1, r0 ; mov ra_ef.8a, rb4
++
++# This loop is identical to the P loop from here --->
++:1
++ add.setf -, ra_ef, ra_ef ; mul24 ra4, rb5, ra_ef
++
++ max r2, ra_y, 0 ; mov r1, 0
++ min r2, r2, rb_max_y ; mov r3, ra_k1
++ add ra_y, ra_y, r3 ; mul24 r2, r2, rb_pitch ; ldtmu0
++ add t0s, ra_base, r2 ; mov rb5, rb6
++ shr r0, r4, ra_xshift ; mov rb6, rb7
++
++ max r2, ra_y2, r1 ; v8min r0, r0, rb_pmask ; ldtmu1 # ; masks out all but wanted bytes
++ shr r1, r4, rb_xshift2 ; mov rb7, ra8
++ min r2, r2, rb_max_y ; v8min r1, r1, ra_pmax
++ add ra_y2, ra_y2, r3 ; mul24 r2, r2, rb_pitch
++ add t1s, rb_base2, r2 ; mov ra8, ra9
++
++# apply horizontal filter
++ add r5rep, r5, r3 ; mul24 r2, ra0.8a << 8, r1 << 8 @ "mul_used", 0
++ mov r3, rb_fir_off_h ; mul24.ifnn r2, ra0.8a, r0
++ sub r2, r3, r2 ; mul24 r3, ra0.8b << 1, r0 << 1 @ "mul_used", 0
++ nop ; mul24.ifn r3, ra0.8b << 9, r1 << 9 @ "mul_used", 0
++ add r2, r2, r3 ; mul24 r3, ra0.8c << 2, r0 << 2 @ "mul_used", 0
++ nop ; mul24.ifn r3, ra0.8c << 10, r1 << 10 @ "mul_used", 0
++ sub r2, r2, r3 ; mul24 r3, ra0.8d << 3, r0 << 3 @ "mul_used", 0
++ nop ; mul24.ifn r3, ra0.8d << 11, r1 << 11 @ "mul_used", 0
++ add r2, r2, r3 ; mul24 r3, ra1.8a << 4, r0 << 4 @ "mul_used", 0
++ nop ; mul24.ifn r3, ra1.8a << 12, r1 << 12 @ "mul_used", 0
++ add r2, r2, r3 ; mul24 r3, ra1.8b << 5, r0 << 5 @ "mul_used", 0
++ nop ; mul24.ifn r3, ra1.8b << 13, r1 << 13 @ "mul_used", 0
++ sub r2, r2, r3 ; mul24 r3, ra1.8c << 6, r0 << 6 @ "mul_used", 0
++ nop ; mul24.ifn r3, ra1.8c << 14, r1 << 14 @ "mul_used", 0
++ add r2, r2, r3 ; mul24 r3, ra1.8d << 7, r0 << 7 @ "mul_used", 0
++ add.setf -, r5, r5 ; mul24.ifn r3, ra1.8d << 15, r1 << 15 @ "mul_used", 0
++
++ brr.anyn -, r:1b
++ sub r2, r2, r3 ; mul24 r1, rb5, ra2.8b
++ mov ra9, rb10 ; mul24 r0, rb10, ra3.8b
++ asr ra11, r2, v_bit_depth - 8 ; mov rb10, ra11
++ # >>> .anyn 1b (r5 + r5)
++
++ # apply vertical filter and write to VPM
++ # - r4* + r5 - r6 + r7 + r8 - r9 + r10 - r11
++
++ sub r1, r1, r0 ; mul24 r0, rb6, ra2.8c
++ sub r1, r1, r0 ; mul24 r0, rb7, ra2.8d
++ add r1, r1, r0 ; mul24 r0, ra8, rb8
++ add r1, r1, r0 ; mul24 r0, rb10, ra3.8c
++ add r1, r1, r0 ; mul24 r0, ra11, rb11
++# <--- to here
++ sub r1, r1, ra4
++ sub r1, r1, r0 ; mov r2, rb_wt_off
++
++ asr r1, r1, 6
++ sub.setf -, r5, rb_i_tmu ; mul24 r0, r1, ra_wt_mul_l0
++ mov.ifz rb_base2, rb_base2_next ; mul24 r1, r1, ra_kmul_add
++ sub r1, r0, r1 ; mov.ifz ra_y_y2, ra_y_y2_next
++ sub.setf -, r5, rb_lcount ; mov.ifz ra_base, ra_base_next
++ add r1, r1, r2 ; mov r0, r1 << 8
++ add r1, r1, r0 ; mov r3, ra_blk_height # ; NxtLoop: r3 = block height
++
++ brr.anyn -, r:1b
++ asr r1, r1, ra_wt_den_p7 ; mul24 r2, r3, rb_pitch # ; NxtLoop
++ min r1, r1, ra_pmax ; mov -, vw_wait
++ max vpm, r1, 0 ; v8subs r0, ra_height, r3 # ; NxtLoop: r0 = remaining height (0 saturate)
++# >>> branch.anyn 1b (r5 - rb_lcount)
++
++# r0 = remaining height (min 0)
++# r2 = r3 * rb_pitch
++# r3 = block_height
++
++# If looping again then we consumed block_height last loop
++# rb_dma1 (stride) remains constant
++# rb_i_tmu remains const (based on total height)
++# recalc ra_dma0, rb_lcount based on new segment height
++
++ mov.setf ra_height, r0 ; mov vw_setup, ra_dma0 # VDW setup 0
++
++# DMA out
++ bra.anyz -, ra_link
++ min r0, r0, r3 ; mov vw_setup, rb_dma1 # Stride
++ sub r1, r0, r3 ; mov vw_addr, ra_dest # start the VDW
++ shl r1, r1, i_shift23
++# >>> .anyz ra_link (ra_height - remaining height)
++
++# Here r1 = cur_blk_height - blk_height so it will be 0 or -ve
++# We add to dma0 to reduce the number of output lines in the final block
++ brr -, r:1b
++ add rb_lcount, rb_lcount, r0
++ add ra_dma0, ra_dma0, r1
++ add ra_dest, ra_dest, r2 ; mov vw_setup, rb_vpm_init # ; Reset our VDM write pointer
++# >>> 1b
++.endm
++
++::mc_filter_y_bxx
++ m_filter_y_bxx 8
++
++################################################################################
++#
++# typedef struct qpu_mc_pred_y_p00_s {
++# qpu_mc_src_t next_src1;
++# uint16_t h;
++# uint16_t w;
++# uint32_t wo1;
++# uint32_t dst_addr;
++# uint32_t next_fn;
++# } qpu_mc_pred_y_p00_t;
++
++.macro m_filter_y_p00, v_bit_depth
++
++.if v_bit_depth <= 8
++.set v_x_shift, 0
++.set v_x_mul, 1
++# Shifts to get width & height in the right place in ra_dma0
++.set v_dma_h_shift, 7
++.set v_dma_wh_shift, i_shift16
++.else
++.set v_x_shift, 1
++.set v_x_mul, 2
++# Shifts to get width & height in the right place in ra_dma0
++.set v_dma_h_shift, 8
++.set v_dma_wh_shift, 15
++.endif
++
++ mov ra0, unif ; mov r0, elem_num # y_x
++ mov ra_xshift, ra_xshift_next ; v8subs r5rep, r5, r5 # [ra0 delay] ; r5 = 0
++ add r0, ra0.16b, r0 ; mov ra_base_next, unif # ; src1.base
++.if v_x_shift != 0
++ shl r0, r0, v_x_shift
++.endif
++
++ max r0, r0, r5 ; mov ra_y_next, ra0.16a # ; width_height
++ min r0, r0, rb_max_x ; mov ra_width_height, unif
++
++ shl ra_xshift_next, r0, 3 # Compute shifts
++ and r0, r0, -4
++ sub r2, r5, rb_pitch ; mov ra_wt_off_mul_l0, unif # ; weight_offset
++ and r1, r0, r2
++ xor r0, r0, r1 ; mul24 r1, r1, rb_xpitch
++ add r0, r0, r1 ; mov ra_dest, unif # Add stripe offsets ; dest addr
++ add ra_base_next, ra_base_next, r0 ; mov vw_setup, rb_vpm_init # [ra_width delay] ; set up VPM write
++
++# get width,height of block (unif load above)
++# Compute vdw_setup1(dst_pitch-width)
++ shl r1, ra_width, v_x_shift
++ sub rb_dma1, rb_dma1_base, r1 ; mov r0, ra_height
++ sub rb_i_tmu, r0, PREREAD ; v8min r0, r0, ra_blk_height
++ shl r0, r0, v_dma_h_shift ; mov rb_lcount, r0
++ add r0, r0, r1 # Combine width and height of destination area
++ shl rb_wt_off, ra_wt_off_l0, DENOM + 7
++ shl r0, r0, v_dma_wh_shift ; mov ra_link, unif # Shift into bits 16 upwards of the vdw_setup0 register ; link
++ add ra_dma0, r0, rb_dma0_base
++
++:1
++ sub.setf -, r5, rb_i_tmu ; v8adds r5rep, r5, ra_k1
++ nop ; mov.ifz ra_y, ra_y_next ; ldtmu0
++ shr r0, r4, ra_xshift ; mov r3, rb_pitch
++
++ max r2, ra_y, 0 # y
++ min r2, r2, rb_max_y ; mov.ifz ra_base, ra_base_next
++ add ra_y, ra_y, 1 ; mul24 r2, r2, r3
++ add t0s, ra_base, r2 ; v8min r0, r0, rb_pmask
++
++ sub.setf -, r5, rb_lcount ; mul24 r1, r0, ra_wt_mul_l0
++ shl r1, r1, 8 ; mov r3, ra_blk_height
++ add r1, r1, rb_wt_off ; v8subs r0, ra_height, r3
++
++ brr.anyn -, r:1b
++ asr r1, r1, DENOM + 8
++ min r1, r1, ra_pmax ; mov -, vw_wait
++ max vpm, r1, ra_k0 ; mul24 r2, r3, rb_pitch
++# >>> branch.anyn 1b
++
++# r0 = remaining height (min 0)
++# r2 = r3 * rb_pitch
++# r3 = block_height
++
++# If looping again then we consumed 16 height last loop
++# rb_dma1 (stride) remains constant
++# rb_i_tmu remains const (based on total height)
++# recalc ra_dma0, rb_lcount based on new segment height
++
++ mov.setf ra_height, r0 ; mov vw_setup, ra_dma0 # VDW setup 0
++
++# DMA out
++ bra.anyz -, ra_link
++ min r0, r0, r3 ; mov vw_setup, rb_dma1 # Stride
++ sub r1, r0, r3 ; mov vw_addr, ra_dest # start the VDW
++ shl r1, r1, i_shift23
++# >>> .anyz ra_link
++
++# Here r1 = cur_blk_height - 16 so it will be 0 or -ve
++# We add to dma0 to reduce the number of output lines in the final block
++ brr -, r:1b
++ add rb_lcount, rb_lcount, r0
++ add ra_dma0, ra_dma0, r1
++ add ra_dest, ra_dest, r2 ; mov vw_setup, rb_vpm_init # ; Reset our VDM write pointer
++# >>> 1b
++.endm
++
++::mc_filter_y_p00
++ m_filter_y_p00 8
++
++################################################################################
++
++.macro m_filter_y_b00, v_bit_depth
++# luma setup does a fair bit more than we need calculating filter coeffs
++# that we will never use but it saves I-cache to use it (also simple!)
++ m_luma_setup v_bit_depth
++
++# Fix up vals that were expecting a filter (somewhat icky)
++ mov r2, 1
++ add rb_i_tmu, rb_i_tmu, r2 ; mov r1, ra_wt_off_mul_l0 # Need in rX rather than raX for <<8 to do what we want
++ shl rb_wt_off, ra_wt_off_l0, DENOM + 8 ; v8subs r5quad, r5, r5 # [r1 << delay] ; r5quad OK for zero
++ nop ; mov.ifnz ra_wt_off_mul_l0, r1 << 8
++
++:1
++ sub.setf -, r5, rb_i_tmu ; nop ; ldtmu1
++ shr r1, r4, rb_xshift2 ; mov.ifz ra_y_y2, ra_y_y2_next ; ldtmu0
++ shr r0, r4, ra_xshift ; mov r3, rb_pitch
++
++ max r2, ra_y, 0 # y
++ min r2, r2, rb_max_y ; mov.ifz ra_base, ra_base_next
++ add ra_y, ra_y, 1 ; mul24 r2, r2, r3
++ add t0s, ra_base, r2 ; mov.ifz rb_base2, rb_base2_next
++
++ max r2, ra_y2, 0
++ min r2, r2, rb_max_y
++ add ra_y2, ra_y2, 1 ; mul24 r2, r2, r3
++ add t1s, rb_base2, r2 ; v8min r0, r0, ra_pmax # v8subs masks out all but bottom byte
++ and r1, r1, rb_pmask ; mul24 r0, r0, ra_wt_mul_l0
++
++ sub.setf -, r5, rb_lcount ; mul24 r1, r1, ra_wt_mul_l1
++ add r1, r0, r1 ; v8adds r5rep, r5, ra_k1
++
++ shl r1, r1, 8 ; mov r3, ra_blk_height
++ add r1, r1, rb_wt_off ; v8subs r0, ra_height, r3
++
++ brr.anyn -, r:1b
++ asr r1, r1, (DENOM + 9) - 32 # -32 to get valid shift immediate
++ min r1, r1, ra_pmax ; mov -, vw_wait
++ max vpm, r1, ra_k0 ; mul24 r2, r3, rb_pitch
++# >>> branch.anyn 1b
++
++# r0 = remaining height (min 0)
++# r2 = r3 * rb_pitch
++# r3 = block_height
++
++# If looping again then we consumed 16 height last loop
++# rb_dma1 (stride) remains constant
++# rb_i_tmu remains const (based on total height)
++# recalc ra_dma0, rb_lcount based on new segment height
++
++ mov.setf ra_height, r0 ; mov vw_setup, ra_dma0 # ; VDW setup 0
++
++# DMA out
++ bra.anyz -, ra_link
++ min r0, r0, r3 ; mov vw_setup, rb_dma1 # ; Stride
++ sub r1, r0, r3 ; mov vw_addr, ra_dest # ; start the VDW
++ shl r1, r1, i_shift23
++# >>> .anyz ra_link
++
++# Here r1 = cur_blk_height - 16 so it will be 0 or -ve
++# We add to dma0 to reduce the number of output lines in the final block
++ brr -, r:1b
++ add rb_lcount, rb_lcount, r0
++ add ra_dma0, ra_dma0, r1
++ add ra_dest, ra_dest, r2 ; mov vw_setup, rb_vpm_init # ; Reset our VDM write pointer
++# >>> 1b
++.endm
++
++::mc_filter_y_b00
++ m_filter_y_b00 8
++
++################################################################################
++################################################################################
++# 10 BIT
++
++::mc_setup_c10_q0
++ m_setup_q0
++::mc_setup_c10_qn
++ m_setup_c 10
++
++::mc_filter_c10_p
++ m_filter_c_p 0, 10
++
++::mc_filter_c10_p_l1
++ m_filter_c_p 1, 10
++
++
++::mc_filter_c10_b
++ m_filter_c_b 10
++
++# Even if these fns are the same as for other bit depths we want our own copy
++# to keep the code we are using in a single lump to avoid (direct map) cache
++# thrashing
++.set v_quads10, N_QPU_16 / 4
++
++::mc_sync10_q0
++ m_sync_q 0, v_quads10
++::mc_sync10_q1
++ m_sync_q 1, v_quads10
++::mc_sync10_q2
++ m_sync_q 2, v_quads10
++::mc_sync10_q3
++ m_sync_q 3, v_quads10
++::mc_sync10_q4
++ m_sync_q 4, v_quads10
++::mc_sync10_q5
++ m_sync_q 5, v_quads10
++::mc_sync10_q6
++ m_sync_q 6, v_quads10
++::mc_sync10_q7
++ m_sync_q 7, v_quads10
++::mc_sync10_q8
++ m_sync_q 8, v_quads10
++::mc_sync10_q9
++ m_sync_q 9, v_quads10
++::mc_sync10_q10
++ m_sync_q 10, v_quads10
++::mc_sync10_q11
++ m_sync_q 11, v_quads10
++
++::mc_exit_y10_q0
++::mc_exit_c10_q0
++ m_exit_q0
++
++::mc_exit_y10_qn
++::mc_exit_c10_qn
++ m_exit_qn
++
++::mc_setup_y10_q0
++ m_setup_q0
++::mc_setup_y10_qn
++ m_setup_y 10
++
++:per_block_setup_10
++ m_per_block_setup 10
++
++::mc_filter_y10_pxx
++ m_filter_y_pxx 10
++
++::mc_filter_y10_p00
++ m_filter_y_p00 10
++
++::mc_filter_y10_bxx
++ m_filter_y_bxx 10
++
++::mc_filter_y10_b00
++ m_filter_y_b00 10
++
++
++
++::mc_end
++# Do not add code here because mc_end must appear after all other code.
+diff --git a/libavcodec/rpi_hevc_shader_cmd.h b/libavcodec/rpi_hevc_shader_cmd.h
+new file mode 100644
+index 0000000000..2f06987bb9
+--- /dev/null
++++ b/libavcodec/rpi_hevc_shader_cmd.h
+@@ -0,0 +1,128 @@
++#ifndef RPI_SHADER_CMD_H
++#define RPI_SHADER_CMD_H
++
++#pragma pack(push, 4)
++
++#if RPI_QPU_EMU_C && RPI_QPU_EMU_Y
++// If mixed then we are just confused and get a lot of warnings....
++typedef const uint8_t * qpu_mc_src_addr_t;
++typedef uint8_t * qpu_mc_dst_addr_t;
++#else
++typedef uint32_t qpu_mc_src_addr_t;
++typedef uint32_t qpu_mc_dst_addr_t;
++#endif
++
++typedef struct qpu_mc_src_s
++{
++ int16_t y;
++ int16_t x;
++ qpu_mc_src_addr_t base;
++} qpu_mc_src_t;
++
++
++typedef struct qpu_mc_pred_c_p_s {
++ qpu_mc_src_t next_src;
++ uint16_t h;
++ uint16_t w;
++ uint32_t coeffs_x;
++ uint32_t coeffs_y;
++ uint32_t wo_u;
++ uint32_t wo_v;
++ qpu_mc_dst_addr_t dst_addr_c;
++ uint32_t next_fn;
++} qpu_mc_pred_c_p_t;
++
++typedef struct qpu_mc_pred_c_b_s {
++ qpu_mc_src_t next_src1;
++ uint16_t h;
++ uint16_t w;
++ uint32_t coeffs_x1;
++ uint32_t coeffs_y1;
++ int16_t weight_u1;
++ int16_t weight_v1;
++ qpu_mc_src_t next_src2;
++ uint32_t coeffs_x2;
++ uint32_t coeffs_y2;
++ uint32_t wo_u2;
++ uint32_t wo_v2;
++ qpu_mc_dst_addr_t dst_addr_c;
++ uint32_t next_fn;
++} qpu_mc_pred_c_b_t;
++
++typedef struct qpu_mc_pred_c_s_s {
++ qpu_mc_src_t next_src1;
++ uint32_t pic_cw; // C Width (== Y width / 2)
++ uint32_t pic_ch; // C Height (== Y Height / 2)
++ uint32_t stride2;
++ uint32_t stride1;
++ qpu_mc_src_t next_src2;
++ uint32_t next_fn;
++} qpu_mc_pred_c_s_t;
++
++typedef struct qpu_mc_pred_c_s {
++ union {
++ qpu_mc_pred_c_p_t p;
++ qpu_mc_pred_c_b_t b;
++ qpu_mc_pred_c_s_t s;
++ };
++} qpu_mc_pred_c_t;
++
++
++typedef struct qpu_mc_pred_y_p_s {
++ qpu_mc_src_t next_src1;
++ qpu_mc_src_t next_src2;
++ uint16_t h;
++ uint16_t w;
++ uint32_t mymx21;
++ uint32_t wo1;
++ uint32_t wo2;
++ qpu_mc_dst_addr_t dst_addr;
++ uint32_t next_fn;
++} qpu_mc_pred_y_p_t;
++
++typedef struct qpu_mc_pred_y_p00_s {
++ qpu_mc_src_t next_src1;
++ uint16_t h;
++ uint16_t w;
++ uint32_t wo1;
++ qpu_mc_dst_addr_t dst_addr;
++ uint32_t next_fn;
++} qpu_mc_pred_y_p00_t;
++
++typedef struct qpu_mc_pred_y_s_s {
++ qpu_mc_src_t next_src1;
++ qpu_mc_src_t next_src2;
++ uint16_t pic_h;
++ uint16_t pic_w;
++ uint32_t stride2;
++ uint32_t stride1;
++ uint32_t next_fn;
++} qpu_mc_pred_y_s_t;
++
++// Only a useful structure in that it allows us to return something other than a void *
++typedef struct qpu_mc_pred_y_s {
++ union {
++ qpu_mc_pred_y_p_t p;
++ qpu_mc_pred_y_p00_t p00;
++ qpu_mc_pred_y_s_t s;
++ };
++} qpu_mc_pred_y_t;
++
++typedef union qpu_mc_pred_cmd_u {
++ qpu_mc_pred_y_t y;
++ qpu_mc_pred_c_t c;
++ uint32_t data[1];
++} qpu_mc_pred_cmd_t;
++
++#define QPU_MC_PRED_N_Y8 12
++#define QPU_MC_PRED_N_C8 12
++
++#define QPU_MC_PRED_N_Y10 12
++#define QPU_MC_PRED_N_C10 12
++
++#define QPU_MC_DENOM 7
++
++#pragma pack(pop)
++
++#endif
++
+diff --git a/libavcodec/rpi_hevc_shader_template.c b/libavcodec/rpi_hevc_shader_template.c
+new file mode 100644
+index 0000000000..577850a6b4
+--- /dev/null
++++ b/libavcodec/rpi_hevc_shader_template.c
+@@ -0,0 +1,61 @@
++#include "hevc.h"
++#include "rpi_hevcdec.h"
++#include "libavutil/rpi_sand_fns.h"
++#include "rpi_hevc_shader_cmd.h"
++#include "rpi_hevc_shader_template.h"
++
++typedef struct shader_track_s
++{
++ const union qpu_mc_pred_cmd_u *qpu_mc_curr;
++ const struct qpu_mc_src_s *last_l0;
++ const struct qpu_mc_src_s *last_l1;
++ uint32_t width; // pic_width * PW
++ uint32_t height;
++ uint32_t stride2;
++ uint32_t stride1;
++} shader_track_t;
++
++static int wtoidx(const unsigned int w)
++{
++ static const uint8_t pel_weight[65] = { [2] = 0, [4] = 1, [6] = 2, [8] = 3, [12] = 4, [16] = 5, [24] = 6, [32] = 7, [48] = 8, [64] = 9 };
++ return pel_weight[w];
++}
++
++static const int fctom(uint32_t x)
++{
++ int rv;
++ // As it happens we can take the 2nd filter term & divide it by 8
++ // (dropping fractions) to get the fractional move
++ rv = 8 - ((x >> 11) & 0xf);
++ av_assert2(rv >= 0 && rv <= 7);
++ return rv;
++}
++
++static inline int32_t ext(int32_t x, unsigned int shl, unsigned int shr)
++{
++ return (x << shl) >> shr;
++}
++
++static inline int woff_p(HEVCRpiContext *const s, int32_t x)
++{
++ return ext(x, 0, 17 + s->ps.sps->bit_depth - 8);
++}
++
++static inline int woff_b(HEVCRpiContext *const s, int32_t x)
++{
++ return ext(x - 0x10000, 0, 16 + s->ps.sps->bit_depth - 8);
++}
++
++static inline int wweight(int32_t x)
++{
++ return ext(x, 16, 16);
++}
++
++
++#define PW 1
++#include "rpi_hevc_shader_template_fn.h"
++
++#undef PW
++#define PW 2
++#include "rpi_hevc_shader_template_fn.h"
++
+diff --git a/libavcodec/rpi_hevc_shader_template.h b/libavcodec/rpi_hevc_shader_template.h
+new file mode 100644
+index 0000000000..304d73ea4a
+--- /dev/null
++++ b/libavcodec/rpi_hevc_shader_template.h
+@@ -0,0 +1,22 @@
++#ifndef LIBAVCODEC_RPI_SHADER_TEMPLATE_H
++#define LIBAVCODEC_RPI_SHADER_TEMPLATE_H
++
++struct HEVCRpiContext;
++struct HEVCRpiInterPredEnv;
++
++void ff_hevc_rpi_shader_c8(struct HEVCRpiContext *const s,
++ const struct HEVCRpiInterPredEnv *const ipe_y,
++ const struct HEVCRpiInterPredEnv *const ipe_c);
++
++void ff_hevc_rpi_shader_c16(struct HEVCRpiContext *const s,
++ const struct HEVCRpiInterPredEnv *const ipe_y,
++ const struct HEVCRpiInterPredEnv *const ipe_c);
++
++void rpi_sand_dump8(const char * const name,
++ const uint8_t * const base, const int stride1, const int stride2, int x, int y, int w, int h, const int is_c);
++
++void rpi_sand_dump16(const char * const name,
++ const uint8_t * const base, const int stride1, const int stride2, int x, int y, int w, int h, const int is_c);
++
++#endif
++
+diff --git a/libavcodec/rpi_hevc_shader_template_fn.h b/libavcodec/rpi_hevc_shader_template_fn.h
+new file mode 100644
+index 0000000000..59b00d537b
+--- /dev/null
++++ b/libavcodec/rpi_hevc_shader_template_fn.h
+@@ -0,0 +1,475 @@
++#define STRCAT(x,y) x##y
++
++#if PW == 1
++#define pixel uint8_t
++#define FUNC(f) STRCAT(f, 8)
++#elif PW == 2
++#define pixel uint16_t
++#define FUNC(f) STRCAT(f, 16)
++#else
++#error Unexpected PW
++#endif
++
++#define PATCH_STRIDE (16 * PW)
++
++static void FUNC(dup_lr)(uint8_t * dst, const uint8_t * src, unsigned int w, unsigned int h, unsigned int stride)
++{
++ for (unsigned int i = 0; i != h; ++i, dst += stride, src += stride) {
++ const pixel s = *(const pixel *)src;
++ pixel * d = (pixel *)dst;
++ for (unsigned int j = 0; j < w; j += PW) {
++ *d++ = s;
++ }
++ }
++}
++
++static void FUNC(dup_tb)(uint8_t * dst, const uint8_t * src, unsigned int w, unsigned int h, unsigned int stride)
++{
++ for (unsigned int i = 0; i != h; ++i, dst += stride) {
++ memcpy(dst, src, w);
++ }
++}
++
++static void FUNC(get_patch_y)(const shader_track_t * const st,
++ uint8_t * dst, const unsigned int dst_stride,
++ const qpu_mc_src_t *src,
++ unsigned int _w, unsigned int _h)
++{
++ int x = src->x * PW;
++ int y = src->y;
++ int w = _w * PW;
++ int h = _h;
++ int dl = 0;
++ int dr = 0;
++ int dt = 0;
++ int db = 0;
++
++ if (x < 0) {
++ if (-x >= w)
++ x = PW - w;
++ dl = -x;
++ w += x;
++ x = 0;
++ }
++ if (x + w > st->width) {
++ if (x >= st->width)
++ x = st->width - PW;
++ dr = (x + w) - st->width;
++ w = st->width - x;
++ }
++
++ // Y
++ if (y < 0) {
++ if (-y >= h)
++ y = 1 - h;
++ dt = -y;
++ h += y;
++ y = 0;
++ }
++ if (y + h > st->height) {
++ if (y >= st->height)
++ y = st->height - 1;
++ db = (y + h) - st->height;
++ h = st->height - y;
++ }
++
++ dst += dl + dt * dst_stride;
++ FUNC(av_rpi_sand_to_planar_y)(dst, dst_stride, (const uint8_t *)src->base, st->stride1, st->stride2, x, y, w, h);
++
++ // Edge dup
++ if (dl != 0)
++ FUNC(dup_lr)(dst - dl, dst, dl, h, dst_stride);
++ if (dr != 0)
++ FUNC(dup_lr)(dst + w, dst + w - PW, dr, h, dst_stride);
++ w += dl + dr;
++ dst -= dl;
++
++ if (dt != 0)
++ FUNC(dup_tb)(dst - dt * dst_stride, dst, w, dt, dst_stride);
++ if (db != 0)
++ FUNC(dup_tb)(dst + h * dst_stride, dst + (h - 1) * dst_stride, w, db, dst_stride);
++}
++
++
++
++static void FUNC(get_patch_c)(const shader_track_t * const st,
++ uint8_t * dst_u, uint8_t * dst_v, const unsigned int dst_stride,
++ const qpu_mc_src_t *src,
++ unsigned int _w, unsigned int _h)
++{
++ int x = src->x * PW;
++ int y = src->y;
++ int w = _w * PW;
++ int h = _h;
++ int dl = 0;
++ int dr = 0;
++ int dt = 0;
++ int db = 0;
++ const int width = st->width;
++ const int height = st->height;
++
++ if (x < 0) {
++ if (-x >= w)
++ x = PW - w;
++ dl = -x;
++ w += x;
++ x = 0;
++ }
++ if (x + w > width) {
++ if (x >= width)
++ x = width - PW;
++ dr = (x + w) - width;
++ w = width - x;
++ }
++
++ // Y
++ if (y < 0) {
++ if (-y >= h)
++ y = 1 - h;
++ dt = -y;
++ h += y;
++ y = 0;
++ }
++ if (y + h > height) {
++ if (y >= height)
++ y = height - 1;
++ db = (y + h) - height;
++ h = height - y;
++ }
++
++ dst_u += dl + dt * dst_stride;
++ dst_v += dl + dt * dst_stride;
++ FUNC(av_rpi_sand_to_planar_c)(dst_u, dst_stride, dst_v, dst_stride, (const uint8_t *)src->base, st->stride1, st->stride2, x, y, w, h);
++
++ // Edge dup
++ if (dl != 0)
++ {
++ FUNC(dup_lr)(dst_u - dl, dst_u, dl, h, dst_stride);
++ FUNC(dup_lr)(dst_v - dl, dst_v, dl, h, dst_stride);
++ }
++ if (dr != 0)
++ {
++ FUNC(dup_lr)(dst_u + w, dst_u + w - PW, dr, h, dst_stride);
++ FUNC(dup_lr)(dst_v + w, dst_v + w - PW, dr, h, dst_stride);
++ }
++ w += dl + dr;
++ dst_u -= dl;
++ dst_v -= dl;
++
++ if (dt != 0)
++ {
++ FUNC(dup_tb)(dst_u - dt * dst_stride, dst_u, w, dt, dst_stride);
++ FUNC(dup_tb)(dst_v - dt * dst_stride, dst_v, w, dt, dst_stride);
++ }
++ if (db != 0)
++ {
++ FUNC(dup_tb)(dst_u + h * dst_stride, dst_u + (h - 1) * dst_stride, w, db, dst_stride);
++ FUNC(dup_tb)(dst_v + h * dst_stride, dst_v + (h - 1) * dst_stride, w, db, dst_stride);
++ }
++}
++
++// w, y, w, h in pixels
++// stride1, stride2 in bytes
++void FUNC(rpi_sand_dump)(const char * const name,
++ const uint8_t * const base, const int stride1, const int stride2, int x, int y, int w, int h, const int is_c)
++{
++ const int mask = stride2 == 0 ? ~0 : stride1 - 1;
++
++ printf("%s (%d,%d) %dx%d\n", name, x, y, w, h);
++
++ if (is_c) {
++ x *= 2;
++ w *= 2;
++ }
++
++ for (int i = y; i != y + h; ++i) {
++ for (int j = x; j != x + w; ++j) {
++ const uint8_t * p = base + ((j*PW) & mask) + i * stride1 + ((j*PW) & ~mask) * stride2;
++ char sep = is_c && (j & 1) == 0 ? ':' : ' ';
++#if PW == 1
++ if (j < 0 || i < 0)
++ printf("..%c", sep);
++ else
++ printf("%02x%c", *(const pixel*)p, sep);
++#else
++ if (j < 0 || i < 0)
++ printf("...%c", sep);
++ else
++ printf("%03x%c", *(const pixel*)p, sep);
++#endif
++ }
++ printf("\n");
++ }
++}
++
++
++void FUNC(ff_hevc_rpi_shader_c)(HEVCRpiContext *const s,
++ const HEVCRpiInterPredEnv *const ipe_y,
++ const HEVCRpiInterPredEnv *const ipe_c)
++{
++ for (int c_idx = 0; c_idx < 2; ++c_idx)
++ {
++ const HEVCRpiInterPredEnv *const ipe = c_idx == 0 ? ipe_y : ipe_c;
++ shader_track_t tracka[QPU_N_MAX] = {{NULL}};
++ unsigned int exit_n = 0;
++
++ if (ipe == NULL || !ipe->used) {
++ continue;
++ }
++
++ do {
++ for (unsigned int i = 0; i != ipe->n; ++i) {
++ const HEVCRpiInterPredQ * const q = ipe->q + i;
++ shader_track_t * const st = tracka + i;
++ const qpu_mc_pred_cmd_t * cmd = st->qpu_mc_curr == NULL ? q->qpu_mc_base : st->qpu_mc_curr;
++
++ for (;;) {
++ const uint32_t link = (cmd == q->qpu_mc_base) ? q->code_setup : ((uint32_t *)cmd)[-1];
++
++ if (link == q->code_setup) {
++ if (c_idx == 0) {
++ // Luma
++ const qpu_mc_pred_y_s_t *const c = &cmd->y.s;
++
++ st->height = c->pic_h;
++ st->width = c->pic_w * PW;
++ st->stride1 = c->stride1;
++ st->stride2 = c->stride2;
++ st->last_l0 = &c->next_src1;
++ st->last_l1 = &c->next_src2;
++ cmd = (const qpu_mc_pred_cmd_t *)(c + 1);
++ }
++ else {
++ // Chroma
++ const qpu_mc_pred_c_s_t *const c = &cmd->c.s;
++
++ st->height = c->pic_ch;
++ st->width = c->pic_cw * PW;
++ st->stride1 = c->stride1;
++ st->stride2 = c->stride2;
++ st->last_l0 = &c->next_src1;
++ st->last_l1 = &c->next_src2;
++ cmd = (const qpu_mc_pred_cmd_t *)(c + 1);
++ }
++ }
++ else if (link == s->qpu.y_pxx) {
++ const qpu_mc_pred_y_p_t *const c = &cmd->y.p;
++ const int w1 = FFMIN(c->w, 8);
++ const int w2 = c->w - w1;
++
++ uint8_t patch_y1[PATCH_STRIDE * 72]; // (Max width + 8) * (max height + 8)
++ uint8_t patch_y2[PATCH_STRIDE * 72]; // (Max width + 8) * (max height + 8)
++
++ FUNC(get_patch_y)(st,
++ patch_y1, PATCH_STRIDE,
++ st->last_l0,
++ 16, c->h + 7);
++ if (w2 > 0) {
++ FUNC(get_patch_y)(st,
++ patch_y2, PATCH_STRIDE,
++ st->last_l1,
++ 16, c->h + 7);
++ }
++
++ // wo[offset] = offset*2+1
++ s->hevcdsp.put_hevc_qpel_uni_w[wtoidx(w1)][(c->mymx21 & 0xff00) != 0][(c->mymx21 & 0xff) != 0](
++ (uint8_t *)c->dst_addr, st->stride1, patch_y1 + 3 * (PATCH_STRIDE + PW), PATCH_STRIDE,
++ c->h, QPU_MC_DENOM, wweight(c->wo1), woff_p(s, c->wo1), (c->mymx21 & 0xff), ((c->mymx21 >> 8) & 0xff), w1);
++ if (w2 > 0) {
++ s->hevcdsp.put_hevc_qpel_uni_w[wtoidx(w2)][(c->mymx21 & 0xff000000) != 0][(c->mymx21 & 0xff0000) != 0](
++ (uint8_t *)c->dst_addr + 8 * PW, st->stride1, patch_y2 + 3 * (PATCH_STRIDE + PW), PATCH_STRIDE,
++ c->h, QPU_MC_DENOM, wweight(c->wo2), woff_p(s, c->wo2), ((c->mymx21 >> 16) & 0xff), ((c->mymx21 >> 24) & 0xff), w2);
++ }
++ st->last_l0 = &c->next_src1;
++ st->last_l1 = &c->next_src2;
++ cmd = (const qpu_mc_pred_cmd_t *)(c + 1);
++ }
++ else if (link == s->qpu.y_bxx) {
++ const qpu_mc_pred_y_p_t *const c = &cmd->y.p;
++
++ uint8_t patch_y1[PATCH_STRIDE * 72]; // (Max width + 8) * (max height + 8)
++ uint8_t patch_y2[PATCH_STRIDE * 72]; // (Max width + 8) * (max height + 8)
++ int16_t patch_y3[MAX_PB_SIZE * MAX_PB_SIZE];
++
++ FUNC(get_patch_y)(st,
++ patch_y1, PATCH_STRIDE,
++ st->last_l0,
++ 16, c->h + 7);
++ FUNC(get_patch_y)(st,
++ patch_y2, PATCH_STRIDE,
++ st->last_l1,
++ 16, c->h + 7);
++
++ s->hevcdsp.put_hevc_qpel[wtoidx(c->w)][(c->mymx21 & 0xff00) != 0][(c->mymx21 & 0xff) != 0](
++ patch_y3, patch_y1+ 3 * (PATCH_STRIDE + PW), PATCH_STRIDE,
++ c->h, (c->mymx21 & 0xff), ((c->mymx21 >> 8) & 0xff), c->w);
++
++ s->hevcdsp.put_hevc_qpel_bi_w[wtoidx(c->w)][(c->mymx21 & 0xff000000) != 0][(c->mymx21 & 0xff0000) != 0](
++ (uint8_t *)c->dst_addr, st->stride1, patch_y2 + 3 * (PATCH_STRIDE + PW), PATCH_STRIDE, patch_y3,
++ c->h, QPU_MC_DENOM, wweight(c->wo1), wweight(c->wo2),
++ 0, woff_b(s, c->wo2), ((c->mymx21 >> 16) & 0xff), ((c->mymx21 >> 24) & 0xff), c->w);
++ st->last_l0 = &c->next_src1;
++ st->last_l1 = &c->next_src2;
++ cmd = (const qpu_mc_pred_cmd_t *)(c + 1);
++ }
++ else if (link == s->qpu.y_p00) {
++ const qpu_mc_pred_y_p00_t *const c = &cmd->y.p00;
++
++ uint8_t patch_y1[PATCH_STRIDE * 72]; // (Max width + 8) * (max height + 8)
++
++ FUNC(get_patch_y)(st,
++ patch_y1, PATCH_STRIDE,
++ st->last_l0,
++ 16, c->h + 7);
++
++ // wo[offset] = offset*2+1
++ s->hevcdsp.put_hevc_qpel_uni_w[wtoidx(c->w)][0][0](
++ (uint8_t *)c->dst_addr, st->stride1, patch_y1, PATCH_STRIDE,
++ c->h, QPU_MC_DENOM, wweight(c->wo1), woff_p(s, c->wo1), 0, 0, c->w);
++
++ st->last_l0 = &c->next_src1;
++ cmd = (const qpu_mc_pred_cmd_t *)(c + 1);
++ }
++ else if (link == s->qpu.y_b00) {
++ const qpu_mc_pred_y_p_t *const c = &cmd->y.p;
++
++ uint8_t patch_y1[PATCH_STRIDE * 72]; // (Max width + 8) * (max height + 8)
++ uint8_t patch_y2[PATCH_STRIDE * 72]; // (Max width + 8) * (max height + 8)
++ int16_t patch_y3[MAX_PB_SIZE * MAX_PB_SIZE];
++
++ av_assert0(c->w <= 16 && c->h <= 64);
++
++ FUNC(get_patch_y)(st,
++ patch_y1, PATCH_STRIDE,
++ st->last_l0,
++ 16, c->h);
++ FUNC(get_patch_y)(st,
++ patch_y2, PATCH_STRIDE,
++ st->last_l1,
++ 16, c->h);
++
++ s->hevcdsp.put_hevc_qpel[wtoidx(c->w)][0][0](
++ patch_y3, patch_y1, PATCH_STRIDE,
++ c->h, 0, 0, c->w);
++
++ s->hevcdsp.put_hevc_qpel_bi_w[wtoidx(c->w)][0][0](
++ (uint8_t *)c->dst_addr, st->stride1, patch_y2, PATCH_STRIDE, patch_y3,
++ c->h, QPU_MC_DENOM, wweight(c->wo1), wweight(c->wo2),
++ 0, woff_b(s, c->wo2), 0, 0, c->w);
++ st->last_l0 = &c->next_src1;
++ st->last_l1 = &c->next_src2;
++ cmd = (const qpu_mc_pred_cmd_t *)(c + 1);
++ }
++ else if (link == s->qpu.c_pxx) {
++ const qpu_mc_pred_c_p_t *const c = &cmd->c.p;
++ const int mx = fctom(c->coeffs_x);
++ const int my = fctom(c->coeffs_y);
++
++ uint8_t patch_u1[PATCH_STRIDE * 72]; // (Max width + 8) * (max height + 8)
++ uint8_t patch_v1[PATCH_STRIDE * 72]; // (Max width + 8) * (max height + 8)
++ uint8_t patch_u3[8 * 16 * PW];
++ uint8_t patch_v3[8 * 16 * PW];
++
++ FUNC(get_patch_c)(st, patch_u1, patch_v1, PATCH_STRIDE, st->last_l0, 8+3, c->h + 3);
++
++ s->hevcdsp.put_hevc_epel_uni_w[wtoidx(c->w)][my != 0][mx != 0](
++ patch_u3, 8 * PW, patch_u1 + PATCH_STRIDE + PW, PATCH_STRIDE,
++ c->h, QPU_MC_DENOM, wweight(c->wo_u), woff_p(s, c->wo_u), mx, my, c->w);
++ s->hevcdsp.put_hevc_epel_uni_w[wtoidx(c->w)][my != 0][mx != 0](
++ patch_v3, 8 * PW, patch_v1 + PATCH_STRIDE + PW, PATCH_STRIDE,
++ c->h, QPU_MC_DENOM, wweight(c->wo_v), woff_p(s, c->wo_v), mx, my, c->w);
++
++ FUNC(av_rpi_planar_to_sand_c)((uint8_t *)c->dst_addr_c, st->stride1, st->stride2, patch_u3, 8 * PW, patch_v3, 8 * PW, 0, 0, c->w * PW, c->h);
++
++ st->last_l0 = &c->next_src;
++ cmd = (const qpu_mc_pred_cmd_t *)(c + 1);
++ }
++ else if (link == s->qpu.c_pxx_l1) {
++ const qpu_mc_pred_c_p_t *const c = &cmd->c.p;
++ const int mx = fctom(c->coeffs_x);
++ const int my = fctom(c->coeffs_y);
++
++ uint8_t patch_u1[PATCH_STRIDE * 72]; // (Max width + 8) * (max height + 8)
++ uint8_t patch_v1[PATCH_STRIDE * 72]; // (Max width + 8) * (max height + 8)
++ uint8_t patch_u3[8 * 16 * PW];
++ uint8_t patch_v3[8 * 16 * PW];
++
++ FUNC(get_patch_c)(st, patch_u1, patch_v1, PATCH_STRIDE, st->last_l1, 8+3, c->h + 3);
++
++ s->hevcdsp.put_hevc_epel_uni_w[wtoidx(c->w)][my != 0][mx != 0](
++ patch_u3, 8 * PW, patch_u1 + PATCH_STRIDE + PW, PATCH_STRIDE,
++ c->h, QPU_MC_DENOM, wweight(c->wo_u), woff_p(s, c->wo_u), mx, my, c->w);
++ s->hevcdsp.put_hevc_epel_uni_w[wtoidx(c->w)][my != 0][mx != 0](
++ patch_v3, 8 * PW, patch_v1 + PATCH_STRIDE + PW, PATCH_STRIDE,
++ c->h, QPU_MC_DENOM, wweight(c->wo_v), woff_p(s, c->wo_v), mx, my, c->w);
++
++ FUNC(av_rpi_planar_to_sand_c)((uint8_t *)c->dst_addr_c, st->stride1, st->stride2, patch_u3, 8 * PW, patch_v3, 8 * PW, 0, 0, c->w * PW, c->h);
++
++ st->last_l1 = &c->next_src;
++ cmd = (const qpu_mc_pred_cmd_t *)(c + 1);
++ }
++ else if (link == s->qpu.c_bxx) {
++ const qpu_mc_pred_c_b_t *const c = &cmd->c.b;
++ const int mx1 = fctom(c->coeffs_x1);
++ const int my1 = fctom(c->coeffs_y1);
++ const int mx2 = fctom(c->coeffs_x2);
++ const int my2 = fctom(c->coeffs_y2);
++
++ uint8_t patch_u1[PATCH_STRIDE * 72];
++ uint8_t patch_v1[PATCH_STRIDE * 72];
++ uint8_t patch_u2[PATCH_STRIDE * 72];
++ uint8_t patch_v2[PATCH_STRIDE * 72];
++ uint8_t patch_u3[8 * 16 * PW];
++ uint8_t patch_v3[8 * 16 * PW];
++ uint16_t patch_u4[MAX_PB_SIZE * MAX_PB_SIZE];
++ uint16_t patch_v4[MAX_PB_SIZE * MAX_PB_SIZE];
++
++ FUNC(get_patch_c)(st, patch_u1, patch_v1, PATCH_STRIDE, st->last_l0, 8+3, c->h + 3);
++ FUNC(get_patch_c)(st, patch_u2, patch_v2, PATCH_STRIDE, st->last_l1, 8+3, c->h + 3);
++
++ s->hevcdsp.put_hevc_epel[wtoidx(c->w)][my1 != 0][mx1 != 0](
++ patch_u4, patch_u1 + PATCH_STRIDE + PW, PATCH_STRIDE,
++ c->h, mx1, my1, c->w);
++ s->hevcdsp.put_hevc_epel[wtoidx(c->w)][my1 != 0][mx1 != 0](
++ patch_v4, patch_v1 + PATCH_STRIDE + PW, PATCH_STRIDE,
++ c->h, mx1, my1, c->w);
++
++ s->hevcdsp.put_hevc_epel_bi_w[wtoidx(c->w)][my2 != 0][mx2 != 0](
++ patch_u3, 8 * PW, patch_u2 + PATCH_STRIDE + PW, PATCH_STRIDE, patch_u4,
++ c->h, QPU_MC_DENOM, c->weight_u1, wweight(c->wo_u2),
++ 0, woff_b(s, c->wo_u2), mx2, my2, c->w);
++ s->hevcdsp.put_hevc_epel_bi_w[wtoidx(c->w)][my2 != 0][mx2 != 0](
++ patch_v3, 8 * PW, patch_v2 + PATCH_STRIDE + PW, PATCH_STRIDE, patch_v4,
++ c->h, QPU_MC_DENOM, c->weight_v1, wweight(c->wo_v2),
++ 0, woff_b(s, c->wo_v2), mx2, my2, c->w);
++
++ FUNC(av_rpi_planar_to_sand_c)((uint8_t *)c->dst_addr_c, st->stride1, st->stride2, patch_u3, 8 * PW, patch_v3, 8 * PW, 0, 0, c->w * PW, c->h);
++
++ st->last_l0 = &c->next_src1;
++ st->last_l1 = &c->next_src2;
++ cmd = (const qpu_mc_pred_cmd_t *)(c + 1);
++ }
++ else if (link == q->code_sync) {
++ cmd = (const qpu_mc_pred_cmd_t *)((uint32_t *)cmd + 1);
++ break;
++ }
++ else if (link == q->code_exit) {
++ // We expect exit to occur without other sync
++ av_assert0(i == exit_n);
++ ++exit_n;
++ break;
++ }
++ else {
++ av_assert0(0);
++ }
++ }
++
++ st->qpu_mc_curr = cmd;
++ }
++ } while (exit_n == 0);
++ }
++}
++
++#undef FUNC
++#undef pixel
++
+diff --git a/libavcodec/rpi_hevc_transform.s b/libavcodec/rpi_hevc_transform.s
+new file mode 100644
+index 0000000000..3caef20137
+--- /dev/null
++++ b/libavcodec/rpi_hevc_transform.s
+@@ -0,0 +1,444 @@
++# ******************************************************************************
++# Argon Design Ltd.
++# (c) Copyright 2015 Argon Design Ltd. All rights reserved.
++#
++# Module : HEVC
++# Author : Peter de Rivaz
++# ******************************************************************************
++
++# USE_STACK = 1 means temporary data stored on the stack (requires build with larger stack)
++# USE_STACK = 0 means temporary data stored in fixed per-VPU data buffers (requires modifications to vasm to handle instruction encoding for PC relative instructions)
++.set USE_STACK, 0
++
++# Lines that fail to assemble start with #:
++# The script insert_magic_opcodes.sh inserts the machine code directly for these.
++# HEVC VPU Transform
++#
++# Transform matrix can be thought of as
++# output row vector = input row vector * transMatrix2
++#
++# The even rows of the matrix are symmetric
++# The odd rows of the matrix are antisymmetric
++#
++# So only need to compute the first half of the results, then can compute the remainder with a butterfly
++#
++# EXAMPLE
++# (a b c d) (1 2 2 1)
++# (3 4 -4 -3)
++# (5 6 6 5)
++# (7 8 -8 -7)
++#
++# x=(a c)(1 2) = 1a+5c 2a+6c
++# (5 6)
++#
++# y=(b d)(3 4) = 3b+7d 4b+8d
++# (7 8)
++#
++# u=x+y = 1a+5c+3b+7d 2a+4b+6c+8d
++# v=x-y = 1a+5c-3b-7d 2a+6c-4b-8d
++#
++# Final results are (u , v[::-1])
++#
++#
++# For 32x1 input, load even rows into HX(0++,0), odd rows into HX(16++,0)
++# Apply the even matrix first and stop before rounding
++# Then apply the odd matrix in a full manner:
++#
++# First step is to compute partial products with the first input (16 cycles)
++# 1a 3b 5c 7d 16x1 input coefficients produce 16x16 output
++# 2a 4b 6c 8d
++# 2a -4b 6c -8d
++# 1a -3b 5c -7d
++#
++# Second step is to sum partial products into final position (8 cycles)
++# 1a+3b+5c+7d
++# 2a+4b+6c+8d
++# 2a-4b+6c-8d
++# 1a-3b+5c-7d
++#
++# Then can apply butterfly to combine even results and odd results + rounding to produce 16 rows of output at a time (need to save in transposed format)
++#
++# For 16x16 no butterfly is required and can store final results in original location (Could do 2 16x16s in parallel to make use of the trick - saves on the adds)
++#
++# For 8x8 we could compute two in parallel.
++#
++#
++
++# Columns are transformed first
++#
++# Store top left half of transMatrix2 in
++# Store bottom left half of transMatrix2 in HX(32,32)
++#
++# For 16x16
++# HX(0:15,0) contains input data before transform
++# HY(0:15,0) contains 32bit output data after transform
++# HX(32,0) contains even rows of left half of transMatrix2
++# HX(32,32) contains odd rows of left half of transMatrix2
++# HY(48,0) contains partial products ready for summing
++#
++
++
++# hevc_trans_16x16(short *transMatrix2, short *coeffs, int num) # TODO add size so we can branch to correct implementation (or perhaps have coeffs32 and num32 as secondary inputs!)
++# transMatrix2: address of the constant matrix (must be at 32 byte aligned address in Videocore memory)
++# coeffs: address of the transform coefficients (must be at 32 byte aligned address in Videocore memory)
++# num: number of 16x16 transforms to be done
++# coeffs32
++# num32: number of 32x32 transforms
++# command 0 for transform, 1 for memclear16(int16_t *dst,num16)
++#
++
++.equ TRANS_SHIFT, 20 - BIT_DEPTH
++.equ TRANS_RND2, 1 << (TRANS_SHIFT - 1)
++.equ TRANS_ASL2, 16 - TRANS_SHIFT
++
++
++hevc_trans_16x16:
++ push r6-r15, lr # TODO cut down number of used registers
++ mov r14,r3 # coeffs32
++ mov r15,r4 # num32
++ mov r3, 16*2 # Stride of transMatrix2 in bytes
++ vldh HX(32++,0),(r0 += r3) REP 16 # This is the 16x16 matrix, a transform is equivalent to multiplying input row vector * matrix
++
++ add r0, 16*16*2 # For 32x32 transforms we also need this matrix
++ vldh HX(32++,32),(r0 += r3) REP 16 # This is the odd 16x16 matrix
++
++ # Now use r0 to describe which matrix we are working on.
++ # Allows us to prefetch the next block of coefficients for efficiency.
++ mov r0,0 # This describes the location where we read our coefficients from
++ mov r3,16*2 # Stride of coefficients in bytes (TODO remove)
++ mov r7,16*16*2 # Total block size
++ mov r8,64*16 # Value used to swap from current to next VRF location
++ mov r4,64 # Constant used for rounding first pass
++ mov r5,TRANS_RND2 # Constant used for rounding second pass
++
++ sub sp,sp,64+16*16*2 # Move on stack pointer in case interrupt occurs and uses stack
++
++ add r11,sp,64 # Space for 32 bytes before, and rounding
++ lsr r11,5
++ lsl r11,5 # Make sure r11 is rounded to multiple of 2**5==32
++
++ lsr r10, r2, 16 # Number of compressed blocks stored in top short
++ extu r2,16
++ # At start of block r0,r1 point to the current block (that has already been loaded)
++ # r0 VRF location of current block
++ # r1 address of current block
++ # r2 number of 16*16 transforms to do
++ # r3 Stride of coefficients (==32)
++ # r4 TRANS_RND1 (64)
++ # r5 TRANS_RND2
++ # r6 temporary used inside col_trans16
++ # r7 16*16*2 total bytes in block
++ # r8 64*16 VRF switch locations
++ # r9 temporary in unpack_coeff for index
++ # r10 number of 16x16 transforms using compression
++ # r11 unpacked data buffer (16*16 shorts) (preceded by 16 shorts of packed data buffer)
++ # r12 temporary counter in unpack_coeff
++ # r13
++ # r14 Save information for 32 bit transform (coeffs location)
++ # r15 Save information for 32 bit transform (number of transforms)
++ cmp r2,0
++ beq done16x16s
++block_loop:
++ # With compressed coefficients, we don't use prefetch as we don't want to issue unnecessary memory requests
++ cmp r10,0
++ mov r6, r1
++ beq not_compressed
++ sub r10, 1
++ bl unpack16x16
++not_compressed:
++ #mov r6,r1 # DEBUG without compress
++ vldh HX(0++,0)+r0,(r6 += r3) REP 16
++ #eor r0,r8
++ #add r1,r7
++ # Prefetch the next block
++ #bl unpack16x16
++ #vldh HX(0++,0)+r0,(r6 += r3) REP 16
++ #vmov HX(0++,0)+r0,0 REP 16 # DEBUG
++ #eor r0,r8
++ #sub r1,r7
++
++ # Transform the current block
++ bl col_trans_16
++ vadd HY(0++,0)+r0,HY(0++,0)+r0,r4 REP 16 # Now add on rounding, shift down by 7, and saturate
++ #vsasls HY(0++,0)+r0,HY(0++,0)+r0,9 REP 16 # 9+7=16 so this ends up with the output saturated and in the top half of the word.
++ vasl HY(0++,0)+r0,HY(0++,0)+r0,9 REP 16 # This should be saturating, but the instruction above does not assemble?
++ vmov VX(0,0++)+r0, HX(0++,32)+r0 REP 16 # For simplicity transpose this back to the original position
++
++ bl col_trans_16
++ vadd HY(0++,0)+r0,HY(0++,0)+r0,r5 REP 16 # Now add on rounding, shift down by 7, and saturate
++ #vsasls HY(0++,0)+r0,HY(0++,0)+r0,4 REP 16 # 4+12=16 so this ends up with the output saturated and in the top half of the word.
++ vasl HY(0++,0)+r0,HY(0++,0)+r0,TRANS_ASL2 REP 16 # This should be saturating, but the instruction above does not assemble? (Probably because it ends with ls which is interpreted as a condition flag)
++
++ # Save results - note there has been a transposition during the processing so we save columns
++ vsth VX(0,32++)+r0, (r1 += r3) REP 16
++
++ # Move onto next block
++ eor r0,r8
++ add r1,r7
++
++ addcmpbgt r2,-1,0,block_loop
++done16x16s:
++
++ add sp,sp,64+16*16*2 # Move on stack pointer in case interrupt occurs and uses stack
++ # Now go and do any 32x32 transforms
++ b hevc_trans_32x32
++
++ pop r6-r15, pc
++# This returns a value in r6 that says where to load the data from.
++# We load data 16 shorts at a time from memory (uncached), and store to stack space to allow us to process it.
++unpack16x16:
++# Clear out destination
++ vmov HX(0,0)+r0,0
++ mov r6, r11
++ vsth HX(0,0)+r0,(r6 += r3) REP 16
++ mov r5, r1 # Moving pointer to input coefficients
++unpack_outer_loop:
++ # Loop until we find the end
++ vldh HX(0,0)+r0,(r5) # TODO would prefetch help here while unpacking previous?
++ sub r6,r11,32
++ #add r6,pc,packed_data-$ # Packed data
++ vsth HX(0,0)+r0,(r6) # Store into packed data
++ mov r12,0
++unpack_loop:
++ ld r4,(r6)
++ add r6,r6,4
++ lsr r9,r4,16 # r9 is destination value
++ cmp r4,0 # {value,index}
++ extu r4,8
++ beq done_unpack
++ sth r9,(r11, r4)
++ addcmpblt r12,1,8,unpack_loop
++# # Read next 16
++ add r5,32
++ b unpack_outer_loop
++done_unpack:
++# # Set new load location
++ mov r6, r11
++ #add r6,pc,unpacked_data-$
++# # Restore constants
++ mov r4,64
++ mov r5,TRANS_RND2
++# pop r6-r15, pc
++ b lr
++
++# r1,r2,r3 r7,r8 should be preserved
++# HX(0++,0)+r0 is the block to be transformed
++# HX(32++,0)+r6 is the 16x16 matrix of transform coefficients
++# Use HY(48,0) for intermediate results
++# r0 can be used, but should be returned to its original value at the end
++col_trans_16:
++ add r6,r0,16 # Final value for this loop
++col_trans_16_loop:
++ # First compute partial products for a single column
++ vmul32s HY(48++,0), VX(0,0)+r0, VX(32,0++) REP 16
++ # Then sum up the results and place back
++ vadd VY(0,0)+r0, VY(48,0++), VY(48,8++) REP 8 CLRA SACC
++ addcmpblt r0,1,r6,col_trans_16_loop
++ sub r0,16 # put r0 back to its original value
++ b lr
++
++col_trans_odd_16:
++ add r6,r0,16 # Final value for this loop
++col_trans_odd_16_loop:
++ # First compute partial products for a single column
++ vmul32s HY(48++,0), VX(0,0)+r0, VX(32,32++) REP 16
++ # Then sum up the results and place back
++ vadd VY(0,0)+r0, VY(48,0++), VY(48,8++) REP 8 CLRA SACC
++ addcmpblt r0,1,r6,col_trans_odd_16_loop
++ sub r0,16 # put r0 back to its original value
++ b lr
++
++# r1/r10 input pointer
++# r0,r4,r5,r6 free
++# r8/r9 output storage
++#
++# Store packed coefficients at r9-32
++# Store unpacked at r9+32*32 (because transform works on even/odd rows on input, but writes all rows)
++unpack32x32:
++# Clear out destination
++ vmov HX(0,0),0
++ add r0, r9, 32*32*2 # Unpacked buffer
++ mov r4, 32
++ vsth HX(0,0),(r0 += r4) REP 64
++unpack_outer_loop32:
++ # Loop until we find the end
++ vldh HX(0,0),(r1) # TODO would prefetch help here while unpacking previous?
++ sub r6,r9,32
++ #add r6,pc,packed_data-$ # Packed data
++ vsth HX(0,0),(r6) # Store into packed data
++ mov r8,0
++unpack_loop32:
++ ld r4,(r6)
++ add r6,r6,4
++ lsr r5,r4,16 # r5 is destination value
++ cmp r4,0 # {value,index}
++ extu r4,10
++ beq done_unpack
++ sth r5,(r0, r4)
++ addcmpblt r8,1,8,unpack_loop32
++# # Read next 16
++ add r1,32
++ b unpack_outer_loop32
++done_unpack32:
++ b lr
++# hevc_trans_32x32(short *transMatrix2, short *coeffs, int num)
++# transMatrix2: address of the constant matrix (must be at 32 byte aligned address in Videocore memory) Even followed by odd
++# coeffs: address of the transform coefficients (must be at 32 byte aligned address in Videocore memory)
++# num: number of 16x16 transforms to be done in low 16, number of packed in high 16
++#
++# Note that the 32x32 transforms are stored in reverse order, this means that the unpacked ones appear first!
++hevc_trans_32x32:
++ mov r1,r14 # coeffs
++ mov r2,r15 # num
++ lsr r15,r15,16 # Number that are packed
++ extu r2,16 # Total number
++
++ # Fetch odd transform matrix
++ #mov r3, 16*2 # Stride of transMatrix2 in bytes (and of coefficients)
++ #vldh HX(32++,0),(r0 += r3) REP 16 # This is the even 16x16 matrix
++ #add r0, 16*16*2
++ #vldh HX(32++,32),(r0 += r3) REP 16 # This is the odd 16x16 matrix
++
++ mov r3, 32*2*2 # Stride used to fetch alternate rows of our input coefficient buffer
++ mov r7, 16*16*2 # Total block size
++
++.if USE_STACK
++ # Stack base allocation
++ sub sp,sp,32*32*4+64 # Allocate some space on the stack for us to store 32*32 shorts as temporary results (needs to be aligned) and another 32*32 for unpacking
++ # set r8 to 32byte aligned stack pointer with 32 bytes of space before it
++ add r8,sp,63
++ lsr r8,5
++ lsl r8,5
++.else
++#:version r8
++ .half 0x00e8 #AUTOINSERTED
++ btst r8,16
++#:add r8,pc,intermediate_results-$
++ .half 0xbfe8
++ .half intermediate_results-($-2)
++ beq on_vpu1
++ add r8,r8,32*32*2*2+16*2 # Move to secondary storage
++on_vpu1:
++.endif
++ mov r9,r8 # Backup of the temporary storage
++ mov r10,r1 # Backup of the coefficient buffer
++
++ cmp r2,0
++ beq done32x32s
++block_loop32:
++
++ # Transform the first 16 columns
++ mov r1,r10 # Input Coefficient buffer
++ mov r8,r9 # Output temporary storage
++ # Unpacked are first, so need to only do unpacking when r2(=num left) <= r15 (=num packed)
++ cmp r2,r15
++ bgt not_compressed_32
++ bl unpack32x32
++ add r1,r9,32*32*2 # Uncompressed into temporary storage
++ mov r8,r9 # Transform into here
++not_compressed_32:
++ # COLUMN TRANSFORM
++ mov r4, 64 # Constant used for rounding first pass
++ mov r5, 9 # left shift used for rounding first pass
++
++ bl trans32
++ # Transform the second 16 columns
++ add r8,32*16*2
++ add r1,32
++ bl trans32
++
++ # ROW TRANSFORM
++ mov r4, TRANS_RND2 # Constant used for rounding second pass
++ mov r5, TRANS_ASL2 # left shift used for rounding second pass
++
++ mov r1,r9 # Input temporary storage
++ mov r8,r10 # Output Coefficient buffer
++ bl trans32
++ # Transform the second 16 columns
++ add r8,32*16*2
++ add r1,32
++ bl trans32
++
++ add r10, 32*32*2 # move onto next block of coefficients
++ addcmpbgt r2,-1,0,block_loop32
++done32x32s:
++
++.if USE_STACK
++ add sp,sp,32*32*4+64# Restore stack
++.endif
++
++ pop r6-r15, pc
++
++trans32:
++ push lr
++ # We can no longer afford the VRF space to do prefetching when doing 32x32
++ # Fetch the even rows
++ vldh HX(0++,0),(r1 += r3) REP 16
++ # Fetch the odd rows
++ vldh HX(16++,0),64(r1 += r3) REP 16 # First odd row is 32 shorts ahead of r1
++
++ # Transform the even rows using even matrix
++ mov r0, 0 # Even rows
++ bl col_trans_16
++
++ # Now transform the odd rows using odd matrix
++ mov r0, 64*16 # Odd rows
++ bl col_trans_odd_16
++
++ # Now apply butterfly to compute the first 16 results
++ vadd HY(48++,0),HY(0++,0),HY(16++,0) REP 16
++ vadd HY(48++,0),HY(48++,0),r4 REP 16 # add on rounding,
++ vasl HY(48++,0),HY(48++,0),r5 REP 16 # shift down by 7, and saturate
++ # 16bit results now in HX(48,32)
++ mov r0,r8
++ mov r6,32*2
++ vsth VX(48,32++),(r0+=r6) REP 16
++
++ # Now apply butterfly to compute the second 16 results (in reverse order)
++ vsub HY(63,0),HY(0 ,0),HY(16,0)
++ vsub HY(62,0),HY(1 ,0),HY(17,0)
++ vsub HY(61,0),HY(2 ,0),HY(18,0)
++ vsub HY(60,0),HY(3 ,0),HY(19,0)
++ vsub HY(59,0),HY(4 ,0),HY(20,0)
++ vsub HY(58,0),HY(5 ,0),HY(21,0)
++ vsub HY(57,0),HY(6 ,0),HY(22,0)
++ vsub HY(56,0),HY(7 ,0),HY(23,0)
++ vsub HY(55,0),HY(8 ,0),HY(24,0)
++ vsub HY(54,0),HY(9 ,0),HY(25,0)
++ vsub HY(53,0),HY(10,0),HY(26,0)
++ vsub HY(52,0),HY(11,0),HY(27,0)
++ vsub HY(51,0),HY(12,0),HY(28,0)
++ vsub HY(50,0),HY(13,0),HY(29,0)
++ vsub HY(49,0),HY(14,0),HY(30,0)
++ vsub HY(48,0),HY(15,0),HY(31,0)
++ vadd HY(48++,0),HY(48++,0),r4 REP 16 # add on rounding,
++ vasl HY(48++,0),HY(48++,0),r5 REP 16 # shift down by 7, and saturate
++ add r0,r8,32
++ vsth VX(48,32++),(r0+=r6) REP 16
++ pop pc
++
++.if USE_STACK == 0
++ .balign 32
++
++# .space directives generate 0's in the bin so avoid unnecessary padding by
++# just setting to appropriate value
++.equ intermediate_results, $+16*2
++
++# Layout goes:
++#
++#packed_buffer:
++# .space 16*2
++#intermediate_results:
++# .space 32*32*2
++#unpacked_buffer:
++# .space 32*32*2
++#
++#packed_buffer2:
++# .space 16*2
++#intermediate_results2:
++# .space 32*32*2
++#unpacked_buffer2:
++# .space 32*32*2
++.endif
++
++
+diff --git a/libavcodec/rpi_hevc_transform10.h b/libavcodec/rpi_hevc_transform10.h
+new file mode 100644
+index 0000000000..1c364492d0
+--- /dev/null
++++ b/libavcodec/rpi_hevc_transform10.h
+@@ -0,0 +1,94 @@
++static const unsigned char rpi_hevc_transform10 [] = {
++0xa9, 0x03, 0x3e, 0x40, 0x4f, 0x40, 0x03, 0xb0, // 0000
++0x20, 0x00, 0x0c, 0xf8, 0x38, 0x88, 0x80, 0x03, // 0008
++0xc0, 0xf8, 0x00, 0x00, 0x40, 0xb0, 0x00, 0x02, // 0010
++0x0c, 0xf8, 0x38, 0xa8, 0x80, 0x03, 0xc0, 0xf8, // 0018
++0x00, 0x00, 0x00, 0x60, 0x03, 0xb0, 0x20, 0x00, // 0020
++0x07, 0xb0, 0x00, 0x02, 0x08, 0xb0, 0x00, 0x04, // 0028
++0x04, 0xb0, 0x40, 0x00, 0x05, 0xb0, 0x00, 0x02, // 0030
++0x59, 0xb0, 0xc0, 0xfd, 0x0b, 0x12, 0x5b, 0x7a, // 0038
++0x5b, 0x7c, 0x4a, 0xc3, 0x50, 0x17, 0x02, 0x6f, // 0040
++0x02, 0x6a, 0x32, 0x18, 0x0a, 0x6a, 0x16, 0x40, // 0048
++0x04, 0x18, 0x1a, 0x66, 0x80, 0x90, 0x32, 0x00, // 0050
++0x0c, 0xf8, 0x38, 0x80, 0x80, 0x03, 0xc0, 0x08, // 0058
++0x18, 0x00, 0x80, 0x90, 0x51, 0x00, 0x04, 0xff, // 0060
++0x30, 0xc0, 0x80, 0x03, 0x20, 0x08, 0x10, 0x00, // 0068
++0x4c, 0xfe, 0x30, 0xc0, 0x09, 0x04, 0x20, 0x08, // 0070
++0x00, 0x00, 0x04, 0xfc, 0x38, 0x90, 0x80, 0x02, // 0078
++0xc0, 0x0b, 0x02, 0x00, 0x80, 0x90, 0x40, 0x00, // 0080
++0x04, 0xff, 0x30, 0xc0, 0x80, 0x03, 0x20, 0x08, // 0088
++0x14, 0x00, 0x4c, 0xfe, 0x30, 0xc0, 0x06, 0x04, // 0090
++0x20, 0x08, 0x00, 0x00, 0x8c, 0xf8, 0x2c, 0xe0, // 0098
++0x80, 0x03, 0x20, 0x30, 0x04, 0x00, 0x80, 0x45, // 00a0
++0x71, 0x42, 0xf2, 0x8c, 0xd1, 0xc0, 0x59, 0xb0, // 00a8
++0x40, 0x02, 0x00, 0x9e, 0x6d, 0x00, 0x29, 0x03, // 00b0
++0x00, 0xf4, 0x38, 0x80, 0x00, 0x0c, 0xb6, 0x40, // 00b8
++0x8c, 0xf8, 0x20, 0xe0, 0x80, 0x03, 0x00, 0x30, // 00c0
++0x18, 0x00, 0x15, 0x40, 0x08, 0xf0, 0x38, 0x80, // 00c8
++0x85, 0x0b, 0x66, 0xb5, 0xe0, 0xff, 0x88, 0xf0, // 00d0
++0x24, 0xe0, 0x86, 0x03, 0x0c, 0x60, 0x64, 0x08, // 00d8
++0x46, 0x62, 0x49, 0xc3, 0x50, 0x27, 0x04, 0x6a, // 00e0
++0x84, 0x6e, 0x07, 0x18, 0x69, 0xa0, 0x04, 0x5f, // 00e8
++0x1c, 0x8b, 0xf7, 0xc8, 0x45, 0x76, 0x6b, 0x1f, // 00f0
++0xb6, 0x40, 0x04, 0xb0, 0x40, 0x00, 0x05, 0xb0, // 00f8
++0x00, 0x02, 0x5a, 0x00, 0x06, 0xb4, 0x10, 0x00, // 0100
++0xa4, 0xff, 0x24, 0xcc, 0x60, 0x02, 0x00, 0xf8, // 0108
++0x3e, 0x00, 0x03, 0xff, 0x37, 0xd0, 0x78, 0x03, // 0110
++0xe0, 0x03, 0xbe, 0x0b, 0x10, 0x8b, 0xf6, 0x5b, // 0118
++0x00, 0x67, 0x5a, 0x00, 0x06, 0xb4, 0x10, 0x00, // 0120
++0xa4, 0xff, 0x24, 0xcc, 0xe0, 0x02, 0x00, 0xf8, // 0128
++0x3e, 0x00, 0x03, 0xff, 0x37, 0xd0, 0x78, 0x03, // 0130
++0xe0, 0x03, 0xbe, 0x0b, 0x10, 0x8b, 0xf6, 0x5b, // 0138
++0x00, 0x67, 0x5a, 0x00, 0x00, 0xf4, 0x38, 0x80, // 0140
++0x00, 0x04, 0x20, 0xb5, 0x00, 0x08, 0x04, 0xb0, // 0148
++0x20, 0x00, 0x8e, 0xf8, 0x20, 0xe0, 0x80, 0x03, // 0150
++0xc0, 0x43, 0x00, 0x00, 0x08, 0xf0, 0x38, 0x80, // 0158
++0x81, 0x03, 0x26, 0xb5, 0xe0, 0xff, 0x88, 0xf0, // 0160
++0x20, 0xe0, 0x86, 0x03, 0x08, 0x60, 0x64, 0x08, // 0168
++0x46, 0x62, 0x45, 0xc3, 0x50, 0x27, 0x04, 0x6a, // 0170
++0xa4, 0x6e, 0x7f, 0x90, 0xbf, 0xff, 0x65, 0xa0, // 0178
++0x04, 0x07, 0x18, 0x8b, 0xf6, 0xc8, 0x41, 0x76, // 0180
++0x6a, 0x1f, 0x5a, 0x00, 0xe1, 0x40, 0xf2, 0x40, // 0188
++0x0f, 0x7b, 0x02, 0x6f, 0x03, 0xb0, 0x80, 0x00, // 0190
++0x07, 0xb0, 0x00, 0x02, 0xe8, 0x00, 0x08, 0x6d, // 0198
++0xe8, 0xbf, 0x60, 0x01, 0x03, 0x18, 0x48, 0xb0, // 01a0
++0x20, 0x10, 0x89, 0x40, 0x1a, 0x40, 0x02, 0x6a, // 01a8
++0x24, 0x18, 0xa1, 0x40, 0x98, 0x40, 0xf2, 0x4a, // 01b0
++0x06, 0x1e, 0xff, 0x9f, 0xc5, 0xff, 0x21, 0xb5, // 01b8
++0x00, 0x08, 0x98, 0x40, 0x04, 0xb0, 0x40, 0x00, // 01c0
++0x95, 0x60, 0x80, 0x90, 0x18, 0x00, 0x48, 0xb0, // 01c8
++0x00, 0x04, 0x41, 0x76, 0x80, 0x90, 0x13, 0x00, // 01d0
++0x04, 0xb0, 0x00, 0x02, 0x65, 0x60, 0x91, 0x40, // 01d8
++0xa8, 0x40, 0x80, 0x90, 0x0c, 0x00, 0x48, 0xb0, // 01e0
++0x00, 0x04, 0x41, 0x76, 0x80, 0x90, 0x07, 0x00, // 01e8
++0x4a, 0xb0, 0x00, 0x08, 0xf2, 0x8c, 0xdf, 0xc0, // 01f0
++0x29, 0x03, 0xef, 0x03, 0x0c, 0xf8, 0x38, 0x80, // 01f8
++0x80, 0x03, 0xc0, 0xf8, 0x04, 0x00, 0x0c, 0xf8, // 0200
++0x38, 0x84, 0xc0, 0x03, 0xc0, 0xf8, 0x04, 0x00, // 0208
++0x00, 0x60, 0xff, 0x9f, 0x79, 0xff, 0x00, 0xb0, // 0210
++0x00, 0x04, 0xff, 0x9f, 0x85, 0xff, 0x04, 0xff, // 0218
++0x30, 0xcc, 0x10, 0x03, 0xe0, 0xfb, 0x3e, 0x00, // 0220
++0x04, 0xff, 0x33, 0xcc, 0x80, 0x03, 0xe0, 0xfb, // 0228
++0x10, 0x00, 0x4c, 0xfe, 0x33, 0xcc, 0x80, 0x03, // 0230
++0xe0, 0xfb, 0x14, 0x00, 0x80, 0x40, 0x06, 0xb0, // 0238
++0x40, 0x00, 0x8c, 0xf8, 0x2f, 0xe0, 0x80, 0x03, // 0240
++0xe0, 0x63, 0x00, 0x00, 0x20, 0xf7, 0xf0, 0xcf, // 0248
++0x10, 0x03, 0x20, 0xf7, 0xb0, 0xcf, 0x11, 0x13, // 0250
++0x20, 0xf7, 0x70, 0xcf, 0x12, 0x23, 0x20, 0xf7, // 0258
++0x30, 0xcf, 0x13, 0x33, 0x20, 0xf7, 0xf0, 0xce, // 0260
++0x14, 0x43, 0x20, 0xf7, 0xb0, 0xce, 0x15, 0x53, // 0268
++0x20, 0xf7, 0x70, 0xce, 0x16, 0x63, 0x20, 0xf7, // 0270
++0x30, 0xce, 0x17, 0x73, 0x20, 0xf7, 0xf0, 0xcd, // 0278
++0x18, 0x83, 0x20, 0xf7, 0xb0, 0xcd, 0x19, 0x93, // 0280
++0x20, 0xf7, 0x70, 0xcd, 0x1a, 0xa3, 0x20, 0xf7, // 0288
++0x30, 0xcd, 0x1b, 0xb3, 0x20, 0xf7, 0xf0, 0xcc, // 0290
++0x1c, 0xc3, 0x20, 0xf7, 0xb0, 0xcc, 0x1d, 0xd3, // 0298
++0x20, 0xf7, 0x70, 0xcc, 0x1e, 0xe3, 0x20, 0xf7, // 02a0
++0x30, 0xcc, 0x1f, 0xf3, 0x04, 0xff, 0x33, 0xcc, // 02a8
++0x80, 0x03, 0xe0, 0xfb, 0x10, 0x00, 0x4c, 0xfe, // 02b0
++0x33, 0xcc, 0x80, 0x03, 0xe0, 0xfb, 0x14, 0x00, // 02b8
++0x00, 0xb5, 0x20, 0x00, 0x8c, 0xf8, 0x2f, 0xe0, // 02c0
++0x80, 0x03, 0xe0, 0x63, 0x00, 0x00, 0x6f, 0x03, // 02c8
++0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, // 02d0
++0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, // 02d8
++};
+diff --git a/libavcodec/rpi_hevc_transform8.h b/libavcodec/rpi_hevc_transform8.h
+new file mode 100644
+index 0000000000..1128a2c054
+--- /dev/null
++++ b/libavcodec/rpi_hevc_transform8.h
+@@ -0,0 +1,94 @@
++static const unsigned char rpi_hevc_transform8 [] = {
++0xa9, 0x03, 0x3e, 0x40, 0x4f, 0x40, 0x03, 0xb0, // 0000
++0x20, 0x00, 0x0c, 0xf8, 0x38, 0x88, 0x80, 0x03, // 0008
++0xc0, 0xf8, 0x00, 0x00, 0x40, 0xb0, 0x00, 0x02, // 0010
++0x0c, 0xf8, 0x38, 0xa8, 0x80, 0x03, 0xc0, 0xf8, // 0018
++0x00, 0x00, 0x00, 0x60, 0x03, 0xb0, 0x20, 0x00, // 0020
++0x07, 0xb0, 0x00, 0x02, 0x08, 0xb0, 0x00, 0x04, // 0028
++0x04, 0xb0, 0x40, 0x00, 0x05, 0xb0, 0x00, 0x08, // 0030
++0x59, 0xb0, 0xc0, 0xfd, 0x0b, 0x12, 0x5b, 0x7a, // 0038
++0x5b, 0x7c, 0x4a, 0xc3, 0x50, 0x17, 0x02, 0x6f, // 0040
++0x02, 0x6a, 0x32, 0x18, 0x0a, 0x6a, 0x16, 0x40, // 0048
++0x04, 0x18, 0x1a, 0x66, 0x80, 0x90, 0x32, 0x00, // 0050
++0x0c, 0xf8, 0x38, 0x80, 0x80, 0x03, 0xc0, 0x08, // 0058
++0x18, 0x00, 0x80, 0x90, 0x51, 0x00, 0x04, 0xff, // 0060
++0x30, 0xc0, 0x80, 0x03, 0x20, 0x08, 0x10, 0x00, // 0068
++0x4c, 0xfe, 0x30, 0xc0, 0x09, 0x04, 0x20, 0x08, // 0070
++0x00, 0x00, 0x04, 0xfc, 0x38, 0x90, 0x80, 0x02, // 0078
++0xc0, 0x0b, 0x02, 0x00, 0x80, 0x90, 0x40, 0x00, // 0080
++0x04, 0xff, 0x30, 0xc0, 0x80, 0x03, 0x20, 0x08, // 0088
++0x14, 0x00, 0x4c, 0xfe, 0x30, 0xc0, 0x04, 0x04, // 0090
++0x20, 0x08, 0x00, 0x00, 0x8c, 0xf8, 0x2c, 0xe0, // 0098
++0x80, 0x03, 0x20, 0x30, 0x04, 0x00, 0x80, 0x45, // 00a0
++0x71, 0x42, 0xf2, 0x8c, 0xd1, 0xc0, 0x59, 0xb0, // 00a8
++0x40, 0x02, 0x00, 0x9e, 0x6d, 0x00, 0x29, 0x03, // 00b0
++0x00, 0xf4, 0x38, 0x80, 0x00, 0x0c, 0xb6, 0x40, // 00b8
++0x8c, 0xf8, 0x20, 0xe0, 0x80, 0x03, 0x00, 0x30, // 00c0
++0x18, 0x00, 0x15, 0x40, 0x08, 0xf0, 0x38, 0x80, // 00c8
++0x85, 0x0b, 0x66, 0xb5, 0xe0, 0xff, 0x88, 0xf0, // 00d0
++0x24, 0xe0, 0x86, 0x03, 0x0c, 0x60, 0x64, 0x08, // 00d8
++0x46, 0x62, 0x49, 0xc3, 0x50, 0x27, 0x04, 0x6a, // 00e0
++0x84, 0x6e, 0x07, 0x18, 0x69, 0xa0, 0x04, 0x5f, // 00e8
++0x1c, 0x8b, 0xf7, 0xc8, 0x45, 0x76, 0x6b, 0x1f, // 00f0
++0xb6, 0x40, 0x04, 0xb0, 0x40, 0x00, 0x05, 0xb0, // 00f8
++0x00, 0x08, 0x5a, 0x00, 0x06, 0xb4, 0x10, 0x00, // 0100
++0xa4, 0xff, 0x24, 0xcc, 0x60, 0x02, 0x00, 0xf8, // 0108
++0x3e, 0x00, 0x03, 0xff, 0x37, 0xd0, 0x78, 0x03, // 0110
++0xe0, 0x03, 0xbe, 0x0b, 0x10, 0x8b, 0xf6, 0x5b, // 0118
++0x00, 0x67, 0x5a, 0x00, 0x06, 0xb4, 0x10, 0x00, // 0120
++0xa4, 0xff, 0x24, 0xcc, 0xe0, 0x02, 0x00, 0xf8, // 0128
++0x3e, 0x00, 0x03, 0xff, 0x37, 0xd0, 0x78, 0x03, // 0130
++0xe0, 0x03, 0xbe, 0x0b, 0x10, 0x8b, 0xf6, 0x5b, // 0138
++0x00, 0x67, 0x5a, 0x00, 0x00, 0xf4, 0x38, 0x80, // 0140
++0x00, 0x04, 0x20, 0xb5, 0x00, 0x08, 0x04, 0xb0, // 0148
++0x20, 0x00, 0x8e, 0xf8, 0x20, 0xe0, 0x80, 0x03, // 0150
++0xc0, 0x43, 0x00, 0x00, 0x08, 0xf0, 0x38, 0x80, // 0158
++0x81, 0x03, 0x26, 0xb5, 0xe0, 0xff, 0x88, 0xf0, // 0160
++0x20, 0xe0, 0x86, 0x03, 0x08, 0x60, 0x64, 0x08, // 0168
++0x46, 0x62, 0x45, 0xc3, 0x50, 0x27, 0x04, 0x6a, // 0170
++0xa4, 0x6e, 0x7f, 0x90, 0xbf, 0xff, 0x65, 0xa0, // 0178
++0x04, 0x07, 0x18, 0x8b, 0xf6, 0xc8, 0x41, 0x76, // 0180
++0x6a, 0x1f, 0x5a, 0x00, 0xe1, 0x40, 0xf2, 0x40, // 0188
++0x0f, 0x7b, 0x02, 0x6f, 0x03, 0xb0, 0x80, 0x00, // 0190
++0x07, 0xb0, 0x00, 0x02, 0xe8, 0x00, 0x08, 0x6d, // 0198
++0xe8, 0xbf, 0x60, 0x01, 0x03, 0x18, 0x48, 0xb0, // 01a0
++0x20, 0x10, 0x89, 0x40, 0x1a, 0x40, 0x02, 0x6a, // 01a8
++0x24, 0x18, 0xa1, 0x40, 0x98, 0x40, 0xf2, 0x4a, // 01b0
++0x06, 0x1e, 0xff, 0x9f, 0xc5, 0xff, 0x21, 0xb5, // 01b8
++0x00, 0x08, 0x98, 0x40, 0x04, 0xb0, 0x40, 0x00, // 01c0
++0x95, 0x60, 0x80, 0x90, 0x18, 0x00, 0x48, 0xb0, // 01c8
++0x00, 0x04, 0x41, 0x76, 0x80, 0x90, 0x13, 0x00, // 01d0
++0x04, 0xb0, 0x00, 0x08, 0x45, 0x60, 0x91, 0x40, // 01d8
++0xa8, 0x40, 0x80, 0x90, 0x0c, 0x00, 0x48, 0xb0, // 01e0
++0x00, 0x04, 0x41, 0x76, 0x80, 0x90, 0x07, 0x00, // 01e8
++0x4a, 0xb0, 0x00, 0x08, 0xf2, 0x8c, 0xdf, 0xc0, // 01f0
++0x29, 0x03, 0xef, 0x03, 0x0c, 0xf8, 0x38, 0x80, // 01f8
++0x80, 0x03, 0xc0, 0xf8, 0x04, 0x00, 0x0c, 0xf8, // 0200
++0x38, 0x84, 0xc0, 0x03, 0xc0, 0xf8, 0x04, 0x00, // 0208
++0x00, 0x60, 0xff, 0x9f, 0x79, 0xff, 0x00, 0xb0, // 0210
++0x00, 0x04, 0xff, 0x9f, 0x85, 0xff, 0x04, 0xff, // 0218
++0x30, 0xcc, 0x10, 0x03, 0xe0, 0xfb, 0x3e, 0x00, // 0220
++0x04, 0xff, 0x33, 0xcc, 0x80, 0x03, 0xe0, 0xfb, // 0228
++0x10, 0x00, 0x4c, 0xfe, 0x33, 0xcc, 0x80, 0x03, // 0230
++0xe0, 0xfb, 0x14, 0x00, 0x80, 0x40, 0x06, 0xb0, // 0238
++0x40, 0x00, 0x8c, 0xf8, 0x2f, 0xe0, 0x80, 0x03, // 0240
++0xe0, 0x63, 0x00, 0x00, 0x20, 0xf7, 0xf0, 0xcf, // 0248
++0x10, 0x03, 0x20, 0xf7, 0xb0, 0xcf, 0x11, 0x13, // 0250
++0x20, 0xf7, 0x70, 0xcf, 0x12, 0x23, 0x20, 0xf7, // 0258
++0x30, 0xcf, 0x13, 0x33, 0x20, 0xf7, 0xf0, 0xce, // 0260
++0x14, 0x43, 0x20, 0xf7, 0xb0, 0xce, 0x15, 0x53, // 0268
++0x20, 0xf7, 0x70, 0xce, 0x16, 0x63, 0x20, 0xf7, // 0270
++0x30, 0xce, 0x17, 0x73, 0x20, 0xf7, 0xf0, 0xcd, // 0278
++0x18, 0x83, 0x20, 0xf7, 0xb0, 0xcd, 0x19, 0x93, // 0280
++0x20, 0xf7, 0x70, 0xcd, 0x1a, 0xa3, 0x20, 0xf7, // 0288
++0x30, 0xcd, 0x1b, 0xb3, 0x20, 0xf7, 0xf0, 0xcc, // 0290
++0x1c, 0xc3, 0x20, 0xf7, 0xb0, 0xcc, 0x1d, 0xd3, // 0298
++0x20, 0xf7, 0x70, 0xcc, 0x1e, 0xe3, 0x20, 0xf7, // 02a0
++0x30, 0xcc, 0x1f, 0xf3, 0x04, 0xff, 0x33, 0xcc, // 02a8
++0x80, 0x03, 0xe0, 0xfb, 0x10, 0x00, 0x4c, 0xfe, // 02b0
++0x33, 0xcc, 0x80, 0x03, 0xe0, 0xfb, 0x14, 0x00, // 02b8
++0x00, 0xb5, 0x20, 0x00, 0x8c, 0xf8, 0x2f, 0xe0, // 02c0
++0x80, 0x03, 0xe0, 0x63, 0x00, 0x00, 0x6f, 0x03, // 02c8
++0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, // 02d0
++0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, // 02d8
++};
+diff --git a/libavcodec/rpi_hevcdec.c b/libavcodec/rpi_hevcdec.c
+new file mode 100644
+index 0000000000..39a63c77de
+--- /dev/null
++++ b/libavcodec/rpi_hevcdec.c
+@@ -0,0 +1,6016 @@
++/*
++ * HEVC video Decoder
++ *
++ * Copyright (C) 2012 - 2013 Guillaume Martres
++ * Copyright (C) 2012 - 2013 Mickael Raulet
++ * Copyright (C) 2012 - 2013 Gildas Cocherel
++ * Copyright (C) 2012 - 2013 Wassim Hamidouche
++ *
++ * This file is part of FFmpeg.
++ *
++ * FFmpeg is free software; you can redistribute it and/or
++ * modify it under the terms of the GNU Lesser General Public
++ * License as published by the Free Software Foundation; either
++ * version 2.1 of the License, or (at your option) any later version.
++ *
++ * FFmpeg is distributed in the hope that it will be useful,
++ * but WITHOUT ANY WARRANTY; without even the implied warranty of
++ * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
++ * Lesser General Public License for more details.
++ *
++ * You should have received a copy of the GNU Lesser General Public
++ * License along with FFmpeg; if not, write to the Free Software
++ * Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA
++ */
++
++#include "libavutil/attributes.h"
++#include "libavutil/common.h"
++#include "libavutil/display.h"
++#include "libavutil/internal.h"
++#include "libavutil/mastering_display_metadata.h"
++#include "libavutil/md5.h"
++#include "libavutil/opt.h"
++#include "libavutil/pixdesc.h"
++#include "libavutil/stereo3d.h"
++
++#include "bswapdsp.h"
++#include "bytestream.h"
++#include "golomb.h"
++#include "hevc.h"
++#include "rpi_hevc_data.h"
++#include "rpi_hevc_parse.h"
++#include "rpi_hevcdec.h"
++#include "rpi_hevc_cabac_fns.h"
++#include "profiles.h"
++#include "hwaccel.h"
++
++#include "rpi_qpu.h"
++#include "rpi_hevc_shader.h"
++#include "rpi_hevc_shader_cmd.h"
++#include "rpi_hevc_shader_template.h"
++#include "rpi_zc.h"
++#include "libavutil/rpi_sand_fns.h"
++
++#include "pthread.h"
++#include <stdatomic.h>
++
++#define DEBUG_DECODE_N 0 // 0 = do all, n = frames idr onwards
++
++#define PACK2(hi,lo) (((hi) << 16) | ((lo) & 0xffff))
++
++#ifndef av_mod_uintp2
++static av_always_inline av_const unsigned av_mod_uintp2_c(unsigned a, unsigned p)
++{
++ return a & ((1 << p) - 1);
++}
++# define av_mod_uintp2 av_mod_uintp2_c
++#endif
++
++const uint8_t ff_hevc_rpi_pel_weight[65] = { [2] = 0, [4] = 1, [6] = 2, [8] = 3, [12] = 4, [16] = 5, [24] = 6, [32] = 7, [48] = 8, [64] = 9 };
++static void rpi_begin(const HEVCRpiContext * const s, HEVCRpiJob * const jb, const unsigned int ctu_ts_first);
++
++#define MC_DUMMY_X (-32)
++#define MC_DUMMY_Y (-32)
++
++// UV & Y both have min 4x4 pred (no 2x2 chroma)
++// Allow for even spread +1 for setup, +1 for rounding
++// As we have load sharing this can (in theory) be exceeded so we have to
++// check after each CTU, but it is a good base size
++
++// Worst case (all 4x4) commands per CTU
++#define QPU_Y_CMD_PER_CTU_MAX (16 * 16)
++#define QPU_C_CMD_PER_CTU_MAX (8 * 8)
++
++#define QPU_MAX_CTU_PER_LINE ((HEVC_RPI_MAX_WIDTH + 63) / 64)
++
++#define QPU_GRPS (QPU_N_MAX / QPU_N_GRP)
++#define QPU_CTU_PER_GRP ((QPU_MAX_CTU_PER_LINE + QPU_GRPS - 1) / QPU_GRPS)
++
++#define QPU_Y_CMD_SLACK_PER_Q (QPU_Y_CMD_PER_CTU_MAX / 2)
++#define QPU_C_CMD_SLACK_PER_Q (QPU_C_CMD_PER_CTU_MAX / 2)
++
++// Total cmds to allocate - allow for slack & setup
++#define QPU_Y_COMMANDS (QPU_CTU_PER_GRP * QPU_GRPS * QPU_Y_CMD_PER_CTU_MAX + (1 + QPU_Y_CMD_SLACK_PER_Q) * QPU_N_MAX)
++#define QPU_C_COMMANDS (QPU_CTU_PER_GRP * QPU_GRPS * QPU_C_CMD_PER_CTU_MAX + (1 + QPU_C_CMD_SLACK_PER_Q) * QPU_N_MAX)
++
++#define QPU_Y_SYNCS (QPU_N_MAX * (16 + 2))
++#define QPU_C_SYNCS (QPU_N_MAX * (8 + 2))
++
++// The QPU code for UV blocks only works up to a block width of 8
++#define RPI_CHROMA_BLOCK_WIDTH 8
++
++#define ENCODE_COEFFS(c0, c1, c2, c3) (((c0) & 0xff) | ((c1) & 0xff) << 8 | ((c2) & 0xff) << 16 | ((c3) & 0xff) << 24)
++
++
++// Actual filter goes -ve, +ve, +ve, -ve using these values
++static const uint32_t rpi_filter_coefs[8] = {
++ ENCODE_COEFFS( 0, 64, 0, 0),
++ ENCODE_COEFFS( 2, 58, 10, 2),
++ ENCODE_COEFFS( 4, 54, 16, 2),
++ ENCODE_COEFFS( 6, 46, 28, 4),
++ ENCODE_COEFFS( 4, 36, 36, 4),
++ ENCODE_COEFFS( 4, 28, 46, 6),
++ ENCODE_COEFFS( 2, 16, 54, 4),
++ ENCODE_COEFFS( 2, 10, 58, 2)
++};
++
++// Function arrays by QPU
++
++static const int * const inter_pred_setup_c_qpu[12] = {
++ mc_setup_c_q0, mc_setup_c_qn, mc_setup_c_qn, mc_setup_c_qn,
++ mc_setup_c_qn, mc_setup_c_qn, mc_setup_c_qn, mc_setup_c_qn,
++ mc_setup_c_qn, mc_setup_c_qn, mc_setup_c_qn, mc_setup_c_qn
++};
++
++static const int * const inter_pred_setup_c10_qpu[12] = {
++ mc_setup_c10_q0, mc_setup_c10_qn, mc_setup_c10_qn, mc_setup_c10_qn,
++ mc_setup_c10_qn, mc_setup_c10_qn, mc_setup_c10_qn, mc_setup_c10_qn,
++ mc_setup_c10_qn, mc_setup_c10_qn, mc_setup_c10_qn, mc_setup_c10_qn
++};
++
++static const int * const inter_pred_setup_y_qpu[12] = {
++ mc_setup_y_q0, mc_setup_y_qn, mc_setup_y_qn, mc_setup_y_qn,
++ mc_setup_y_qn, mc_setup_y_qn, mc_setup_y_qn, mc_setup_y_qn,
++ mc_setup_y_qn, mc_setup_y_qn, mc_setup_y_qn, mc_setup_y_qn
++};
++
++static const int * const inter_pred_setup_y10_qpu[12] = {
++ mc_setup_y10_q0, mc_setup_y10_qn, mc_setup_y10_qn, mc_setup_y10_qn,
++ mc_setup_y10_qn, mc_setup_y10_qn, mc_setup_y10_qn, mc_setup_y10_qn,
++ mc_setup_y10_qn, mc_setup_y10_qn, mc_setup_y10_qn, mc_setup_y10_qn
++};
++
++static const int * const inter_pred_sync_qpu[12] = {
++ mc_sync_q0, mc_sync_q1, mc_sync_q2, mc_sync_q3,
++ mc_sync_q4, mc_sync_q5, mc_sync_q6, mc_sync_q7,
++ mc_sync_q8, mc_sync_q9, mc_sync_q10, mc_sync_q11
++};
++
++static const int * const inter_pred_sync10_qpu[12] = {
++ mc_sync10_q0, mc_sync10_q1, mc_sync10_q2, mc_sync10_q3,
++ mc_sync10_q4, mc_sync10_q5, mc_sync10_q6, mc_sync10_q7,
++ mc_sync10_q8, mc_sync10_q9, mc_sync10_q10, mc_sync10_q11
++};
++
++static const int * const inter_pred_exit_c_qpu[12] = {
++ mc_exit_c_q0, mc_exit_c_qn, mc_exit_c_qn, mc_exit_c_qn,
++ mc_exit_c_qn, mc_exit_c_qn, mc_exit_c_qn, mc_exit_c_qn,
++ mc_exit_c_qn, mc_exit_c_qn, mc_exit_c_qn, mc_exit_c_qn
++};
++
++static const int * const inter_pred_exit_c10_qpu[12] = {
++ mc_exit_c10_q0, mc_exit_c10_qn, mc_exit_c10_qn, mc_exit_c10_qn,
++ mc_exit_c10_qn, mc_exit_c10_qn, mc_exit_c10_qn, mc_exit_c10_qn,
++ mc_exit_c10_qn, mc_exit_c10_qn, mc_exit_c10_qn, mc_exit_c10_qn
++};
++
++static const int * const inter_pred_exit_y_qpu[12] = {
++ mc_exit_y_q0, mc_exit_y_qn, mc_exit_y_qn, mc_exit_y_qn,
++ mc_exit_y_qn, mc_exit_y_qn, mc_exit_y_qn, mc_exit_y_qn,
++ mc_exit_y_qn, mc_exit_y_qn, mc_exit_y_qn, mc_exit_y_qn
++};
++
++static const int * const inter_pred_exit_y10_qpu[12] = {
++ mc_exit_y10_q0, mc_exit_y10_qn, mc_exit_y10_qn, mc_exit_y10_qn,
++ mc_exit_y10_qn, mc_exit_y10_qn, mc_exit_y10_qn, mc_exit_y10_qn,
++ mc_exit_y10_qn, mc_exit_y10_qn, mc_exit_y10_qn, mc_exit_y10_qn
++};
++
++typedef struct ipe_chan_info_s
++{
++ const uint8_t bit_depth;
++ const uint8_t n;
++ const int * const * setup_fns;
++ const int * const * sync_fns;
++ const int * const * exit_fns;
++} ipe_chan_info_t;
++
++typedef struct ipe_init_info_s
++{
++ ipe_chan_info_t luma;
++ ipe_chan_info_t chroma;
++} ipe_init_info_t;
++
++static void set_bytes(uint8_t * b, const unsigned int stride, const int ln, unsigned int a)
++{
++ switch (ln)
++ {
++ default: // normally 0
++ *b = a;
++ break;
++ case 1:
++ a |= a << 8;
++ *(uint16_t *)b = a;
++ b += stride;
++ *(uint16_t *)b = a;
++ break;
++ case 2:
++ a |= a << 8;
++ a |= a << 16;
++ *(uint32_t *)b = a;
++ b += stride;
++ *(uint32_t *)b = a;
++ b += stride;
++ *(uint32_t *)b = a;
++ b += stride;
++ *(uint32_t *)b = a;
++ break;
++ case 3:
++ {
++ unsigned int i;
++ uint64_t d;
++ a |= a << 8;
++ a |= a << 16;
++ d = ((uint64_t)a << 32) | a;
++ for (i = 0; i != 8; ++i, b += stride)
++ *(uint64_t *)b = d;
++ break;
++ }
++ case 4:
++ {
++ unsigned int i;
++ uint64_t d;
++ a |= a << 8;
++ a |= a << 16;
++ d = ((uint64_t)a << 32) | a;
++ for (i = 0; i != 16; ++i, b += stride)
++ {
++ *(uint64_t *)b = d;
++ *(uint64_t *)(b + 8) = d;
++ }
++ break;
++ }
++ }
++}
++
++// We expect this to be called with ln = (log2_cb_size - 3) so range = -1..3
++// (4 not required)
++static void set_stash2(uint8_t * b_u, uint8_t * b_l, const int ln, unsigned int a)
++{
++ switch (ln)
++ {
++ default: // 0 or -1
++ *b_u = a;
++ *b_l = a;
++ break;
++ case 1:
++ a |= a << 8;
++ *(uint16_t *)b_u = a;
++ *(uint16_t *)b_l = a;
++ break;
++ case 2:
++ a |= a << 8;
++ a |= a << 16;
++ *(uint32_t *)b_u = a;
++ *(uint32_t *)b_l = a;
++ break;
++ case 3:
++ a |= a << 8;
++ a |= a << 16;
++ *(uint32_t *)b_u = a;
++ *(uint32_t *)(b_u + 4) = a;
++ *(uint32_t *)b_l = a;
++ *(uint32_t *)(b_l + 4) = a;
++ break;
++ case 4:
++ a |= a << 8;
++ a |= a << 16;
++ *(uint32_t *)b_u = a;
++ *(uint32_t *)(b_u + 4) = a;
++ *(uint32_t *)(b_u + 8) = a;
++ *(uint32_t *)(b_u + 12) = a;
++ *(uint32_t *)b_l = a;
++ *(uint32_t *)(b_l + 4) = a;
++ *(uint32_t *)(b_l + 8) = a;
++ *(uint32_t *)(b_l + 12) = a;
++ break;
++ }
++}
++
++static void zap_cabac_stash(uint8_t * b, const int ln)
++{
++ switch (ln)
++ {
++ default: // 0
++ *b = 0;
++ break;
++ case 1:
++ *(uint16_t *)b = 0;
++ break;
++ case 2:
++ *(uint32_t *)b = 0;
++ break;
++ case 3:
++ *(uint32_t *)b = 0;
++ *(uint32_t *)(b + 4) = 0;
++ break;
++ }
++}
++
++
++
++// Set a small square block of bits in a bitmap
++// Bits must be aligned on their size boundry (which will be true of all split CBs)
++static void set_bits(uint8_t * f, const unsigned int x, const unsigned int stride, const unsigned int ln)
++{
++ unsigned int n;
++ const unsigned int sh = (x & 7);
++
++ f += (x >> 3);
++
++ av_assert2(ln <= 3);
++ av_assert2((x & ((1 << ln) - 1)) == 0);
++
++ switch (ln)
++ {
++ default: // 1
++ f[0] |= 1 << sh;
++ break;
++ case 1: // 3 * 2
++ n = 3 << sh;
++ f[0] |= n;
++ f[stride] |= n;
++ break;
++ case 2: // 0xf * 4
++ n = 0xf << sh;
++ f[0] |= n;
++ f[stride] |= n;
++ f[stride * 2] |= n;
++ f[stride * 3] |= n;
++ break;
++ case 3: // 0xff * 8
++ for (n = 0; n != 8; ++n, f += stride)
++ *f = 0xff;
++ break;
++ }
++}
++
++static const ipe_init_info_t ipe_init_infos[9] = { // Alloc for bit depths of 8-16
++ { // 8
++ .luma = {8, QPU_MC_PRED_N_Y8, inter_pred_setup_y_qpu, inter_pred_sync_qpu, inter_pred_exit_y_qpu},
++ .chroma = {8, QPU_MC_PRED_N_C8, inter_pred_setup_c_qpu, inter_pred_sync_qpu, inter_pred_exit_c_qpu}
++ },
++ { // 9
++ .luma = {0},
++ .chroma = {0}
++ },
++ { // 10
++ .luma = {10, QPU_MC_PRED_N_Y10, inter_pred_setup_y10_qpu, inter_pred_sync10_qpu, inter_pred_exit_y10_qpu},
++ .chroma = {10, QPU_MC_PRED_N_C10, inter_pred_setup_c10_qpu, inter_pred_sync10_qpu, inter_pred_exit_c10_qpu}
++ }
++
++};
++
++static void set_ipe_from_ici(HEVCRpiInterPredEnv * const ipe, const ipe_chan_info_t * const ici)
++{
++ const unsigned int n = ici->n;
++ const unsigned int q1_size = (ipe->gptr.numbytes / n) & ~3; // Round down to word
++
++ ipe->n = n;
++ ipe->max_fill = q1_size - ipe->min_gap;
++ for(unsigned int i = 0; i < n; i++) {
++ HEVCRpiInterPredQ * const q = ipe->q + i;
++ q->qpu_mc_curr = q->qpu_mc_base =
++ (qpu_mc_pred_cmd_t *)(ipe->gptr.arm + i * q1_size);
++ q->code_setup = qpu_fn(ici->setup_fns[i]);
++ q->code_sync = qpu_fn(ici->sync_fns[i]);
++ q->code_exit = qpu_fn(ici->exit_fns[i]);
++ }
++}
++
++static void rpi_hevc_qpu_set_fns(HEVCRpiContext * const s, const unsigned int bit_depth)
++{
++ av_assert0(bit_depth >= 8 && bit_depth <= 16);
++
++ rpi_hevc_qpu_init_fn(&s->qpu, bit_depth);
++}
++
++// Unsigned Trivial MOD
++static inline unsigned int utmod(const unsigned int x, const unsigned int n)
++{
++ return x >= n ? x - n : x;
++}
++
++// returns pq->job_n++
++static inline unsigned int pass_queue_inc_job_n(HEVCRpiPassQueue * const pq)
++{
++ unsigned int const x2 = pq->job_n;
++ pq->job_n = utmod(x2 + 1, RPI_MAX_JOBS);
++ return x2;
++}
++
++static void pass_queue_init(HEVCRpiPassQueue * const pq, HEVCRpiContext * const s, HEVCRpiWorkerFn * const worker, sem_t * const psem_out, const int n)
++{
++ pq->terminate = 0;
++ pq->job_n = 0;
++ pq->context = s;
++ pq->worker = worker;
++ pq->psem_out = psem_out;
++ pq->pass_n = n;
++ pq->started = 0;
++ sem_init(&pq->sem_in, 0, 0);
++}
++
++static void pass_queue_kill(HEVCRpiPassQueue * const pq)
++{
++ sem_destroy(&pq->sem_in);
++}
++
++static inline void rpi_sem_wait(sem_t * const sem)
++{
++ while (sem_wait(sem) != 0) {
++ av_assert0(errno == EINTR);
++ }
++}
++
++static void pass_queue_submit_job(HEVCRpiPassQueue * const pq)
++{
++ sem_post(&pq->sem_in);
++}
++
++static inline void pass_queue_do_all(HEVCRpiContext * const s, HEVCRpiJob * const jb)
++{
++ // Do the various passes - common with the worker code
++ for (unsigned int i = 0; i != RPI_PASSES; ++i) {
++ s->passq[i].worker(s, jb);
++ }
++}
++
++
++#if 0
++static void dump_jbc(const HEVCRpiJobCtl *const jbc, const char * const func)
++{
++ int x;
++ sem_getvalue((sem_t *)&jbc->sem_out, &x);
++ printf("%s: jbc: in=%d, out=%d, sum=%d\n", func, jbc->offload_in, jbc->offload_out, x);
++}
++#endif
++
++
++static HEVCRpiJob * job_alloc(HEVCRpiJobCtl * const jbc, HEVCRpiLocalContext * const lc)
++{
++ HEVCRpiJob * jb;
++ HEVCRpiJobGlobal * const jbg = jbc->jbg;
++
++ pthread_mutex_lock(&jbg->lock);
++ // Check local 1st
++ if ((jb = jbc->jb1) != NULL)
++ {
++ // Only 1 - very easy :-)
++ jbc->jb1 = NULL;
++ }
++ else
++ {
++ // Now look for global free chain
++ if ((jb = jbg->free1) != NULL)
++ {
++ // Found one - unlink it
++ jbg->free1 = jb->next;
++ jb->next = NULL;
++ }
++ else
++ {
++ // Out of places to look - wait for one to become free - add to Qs
++
++ // Global
++ // If "good" lc then add after the last "good" el in the chain
++ // otherwise add to the tail
++ if (jbg->wait_tail == NULL || jbg->wait_tail->last_progress_good || !lc->last_progress_good)
++ {
++ // Add to end as we had to wait last time or wait Q empty
++ if ((lc->jw_prev = jbg->wait_tail) == NULL)
++ jbg->wait_head = lc;
++ else
++ lc->jw_prev->jw_next = lc;
++ lc->jw_next = NULL;
++ jbg->wait_tail = lc;
++ }
++ else
++ {
++ // This is a "good" lc that we need to poke into the middle
++ // of the Q
++ // We know that the Q isn't empty and there is at least one
++ // !last_progess_good el in it from the previous test
++
++ HEVCRpiLocalContext * const p = jbg->wait_good; // Insert after
++
++ if (p == NULL)
++ {
++ // No current good els - add to head
++ lc->jw_next = jbg->wait_head;
++ jbg->wait_head = lc;
++ }
++ else
++ {
++ lc->jw_next = p->jw_next;
++ p->jw_next = lc;
++ }
++
++ lc->jw_next->jw_prev = lc;
++ lc->jw_prev = p;
++ }
++
++ // If "good" then we are now the last good waiting el
++ if (lc->last_progress_good)
++ jbg->wait_good = lc;
++
++ // Local
++ if ((lc->ljw_prev = jbc->lcw_tail) == NULL)
++ jbc->lcw_head = lc;
++ else
++ lc->ljw_prev->ljw_next = lc;
++ lc->ljw_next = NULL;
++ jbc->lcw_tail = lc;
++ }
++ }
++
++ pthread_mutex_unlock(&jbg->lock);
++
++ if (jb == NULL) // Need to wait
++ {
++ rpi_sem_wait(&lc->jw_sem);
++ jb = lc->jw_job; // Set by free code
++ }
++
++ return jb;
++}
++
++
++static void job_free(HEVCRpiJobCtl * const jbc0, HEVCRpiJob * const jb)
++{
++ HEVCRpiJobGlobal * const jbg = jbc0->jbg; // This jbc only used to find jbg so we can get the lock
++ HEVCRpiJobCtl * jbc = jb->jbc_local;
++ HEVCRpiLocalContext * lc = NULL;
++
++ pthread_mutex_lock(&jbg->lock);
++
++ if (jbc != NULL)
++ {
++ av_assert1(jbc->jb1 == NULL);
++
++ // Release to Local if nothing waiting there
++ if ((lc = jbc->lcw_head) == NULL)
++ jbc->jb1 = jb;
++ }
++ else
++ {
++ // Release to global if nothing waiting there
++ if ((lc = jbg->wait_head) == NULL)
++ {
++ jb->next = jbg->free1;
++ jbg->free1 = jb;
++ }
++ else
++ {
++ // ? seems somehow mildy ugly...
++ jbc = lc->context->jbc;
++ }
++ }
++
++ if (lc != NULL)
++ {
++ // Something was waiting
++
++ // Unlink
++ // Global
++ if (lc->jw_next == NULL)
++ jbg->wait_tail = lc->jw_prev;
++ else
++ lc->jw_next->jw_prev = lc->jw_prev;
++
++ if (lc->jw_prev == NULL)
++ jbg->wait_head = lc->jw_next;
++ else
++ lc->jw_prev->jw_next = lc->jw_next;
++
++ // Local
++ if (lc->ljw_next == NULL)
++ jbc->lcw_tail = lc->ljw_prev;
++ else
++ lc->ljw_next->ljw_prev = lc->ljw_prev;
++
++ if (lc->ljw_prev == NULL)
++ jbc->lcw_head = lc->ljw_next;
++ else
++ lc->ljw_prev->ljw_next = lc->ljw_next;
++
++ // Update good if required
++ if (jbg->wait_good == lc)
++ jbg->wait_good = lc->jw_prev;
++
++ // Prod
++ lc->jw_job = jb;
++ sem_post(&lc->jw_sem);
++ }
++
++ pthread_mutex_unlock(&jbg->lock);
++}
++
++static void job_lc_kill(HEVCRpiLocalContext * const lc)
++{
++ sem_destroy(&lc->jw_sem);
++}
++
++static void job_lc_init(HEVCRpiLocalContext * const lc)
++{
++ lc->jw_next = NULL;
++ lc->jw_prev = NULL;
++ lc->ljw_next = NULL;
++ lc->ljw_prev = NULL;
++ lc->jw_job = NULL;
++ sem_init(&lc->jw_sem, 0, 0);
++}
++
++// Returns:
++// 0 if we have waited for MV or expect to wait for recon
++// 1 if we haven't waited for MV & do not need to wait for recon
++static int progress_good(const HEVCRpiContext *const s, const HEVCRpiJob * const jb)
++{
++ if (jb->waited) // reset by rpi_begin
++ return 0;
++ for (unsigned int i = 0; i != FF_ARRAY_ELEMS(jb->progress_req); ++i)
++ {
++ if (jb->progress_req[i] >= 0 && s->DPB[i].tf.progress != NULL &&
++ ((volatile int *)(s->DPB[i].tf.progress->data))[0] < jb->progress_req[i])
++ return 0;
++ }
++ return 1;
++}
++
++// Submit job if it is full (indicated by having ctu_ts_last set >= 0)
++static inline void worker_submit_job(HEVCRpiContext *const s, HEVCRpiLocalContext * const lc)
++{
++ HEVCRpiJobCtl *const jbc = s->jbc;
++ HEVCRpiJob * const jb = lc->jb0;
++
++ av_assert1(jb != NULL);
++
++ if (jb->ctu_ts_last < 0) {
++ return;
++ }
++
++ lc->last_progress_good = progress_good(s, jb);
++ jb->waited = !lc->last_progress_good;
++ lc->jb0 = NULL;
++
++ if (s->offload_recon)
++ {
++ pthread_mutex_lock(&jbc->in_lock);
++ jbc->offloadq[jbc->offload_in] = jb;
++ jbc->offload_in = utmod(jbc->offload_in + 1, RPI_MAX_JOBS);
++ pthread_mutex_unlock(&jbc->in_lock);
++
++ pass_queue_submit_job(s->passq + 0); // Consumes job eventually
++ }
++ else
++ {
++ pass_queue_do_all(s, jb); // Consumes job before return
++ }
++}
++
++
++// Call worker_pass0_ready to wait until the s->pass0_job slot becomes
++// available to receive the next job.
++//
++// Now safe against multiple callers - needed for tiles
++// "normal" and WPP will only call here one at a time
++static inline void worker_pass0_ready(const HEVCRpiContext * const s, HEVCRpiLocalContext * const lc)
++{
++ HEVCRpiJobCtl * const jbc = s->jbc;
++
++ // It is legit for us to already have a job allocated - do nothing in this case
++ if (lc->jb0 != NULL)
++ return;
++
++ if (s->offload_recon)
++ rpi_sem_wait(&jbc->sem_out); // This sem will stop this frame grabbing too much
++
++ lc->jb0 = job_alloc(jbc, lc);
++
++ rpi_begin(s, lc->jb0, lc->ts);
++}
++
++// Free up a job without submission
++static void worker_free(const HEVCRpiContext * const s, HEVCRpiLocalContext * const lc)
++{
++ HEVCRpiJobCtl * const jbc = s->jbc;
++ HEVCRpiJob * const jb = lc->jb0;
++
++ if (jb == NULL) {
++ return;
++ }
++
++ lc->jb0 = NULL;
++
++ job_free(jbc, jb);
++
++ // If offload then poke sem_out too
++ if (s->offload_recon) {
++ sem_post(&jbc->sem_out);
++ }
++}
++
++
++// Call this to wait for all jobs to have completed at the end of a frame
++// Slightly icky as there is no clean way to wait for a sem to count up
++// Not reentrant - call on main thread only
++static void worker_wait(const HEVCRpiContext * const s, HEVCRpiLocalContext * const lc)
++{
++ HEVCRpiJobCtl * const jbc = s->jbc;
++ int i = 0;
++
++ // We shouldn't reach here with an unsubmitted job
++ av_assert1(lc->jb0 == NULL);
++
++ // If no offload then there can't be anything to wait for
++ if (!s->offload_recon) {
++ return;
++ }
++
++ if (sem_getvalue(&jbc->sem_out, &i) == 0 && i < RPI_MAX_JOBS)
++ {
++ for (i = 0; i != RPI_MAX_JOBS; ++i) {
++ rpi_sem_wait(&jbc->sem_out);
++ }
++ for (i = 0; i != RPI_MAX_JOBS; ++i) {
++ sem_post(&jbc->sem_out);
++ }
++ }
++}
++
++static void * pass_worker(void *arg)
++{
++ HEVCRpiPassQueue *const pq = (HEVCRpiPassQueue *)arg;
++ HEVCRpiContext *const s = pq->context;
++
++ for (;;)
++ {
++ rpi_sem_wait(&pq->sem_in);
++
++ if (pq->terminate)
++ break;
++
++ pq->worker(s, s->jbc->offloadq[pass_queue_inc_job_n(pq)]);
++ // * should really set jb->passes_done here
++
++ sem_post(pq->psem_out);
++ }
++ return NULL;
++}
++
++static void pass_queues_start_all(HEVCRpiContext *const s)
++{
++ unsigned int i;
++ HEVCRpiPassQueue * const pqs = s->passq;
++
++ for (i = 0; i != RPI_PASSES; ++i)
++ {
++ av_assert0(pthread_create(&pqs[i].thread, NULL, pass_worker, pqs + i) == 0);
++ pqs[i].started = 1;
++ }
++}
++
++static void pass_queues_term_all(HEVCRpiContext *const s)
++{
++ unsigned int i;
++ HEVCRpiPassQueue * const pqs = s->passq;
++
++ for (i = 0; i != RPI_PASSES; ++i)
++ pqs[i].terminate = 1;
++ for (i = 0; i != RPI_PASSES; ++i)
++ {
++ if (pqs[i].started)
++ sem_post(&pqs[i].sem_in);
++ }
++ for (i = 0; i != RPI_PASSES; ++i)
++ {
++ if (pqs[i].started) {
++ pthread_join(pqs[i].thread, NULL);
++ pqs[i].started = 0;
++ }
++ }
++}
++
++static void pass_queues_kill_all(HEVCRpiContext *const s)
++{
++ unsigned int i;
++ HEVCRpiPassQueue * const pqs = s->passq;
++
++ for (i = 0; i != RPI_PASSES; ++i)
++ pass_queue_kill(pqs + i);
++}
++
++
++static void worker_pic_free_one(HEVCRpiJob * const jb)
++{
++ // Free coeff stuff - allocation not the same for all buffers
++ HEVCRpiCoeffsEnv * const cf = &jb->coeffs;
++
++ if (cf->s[0].buf != NULL)
++ av_freep(&cf->mptr);
++ if (cf->s[2].buf != NULL)
++ gpu_free(&cf->gptr);
++ memset(cf, 0, sizeof(*cf));
++}
++
++static int worker_pic_alloc_one(HEVCRpiJob * const jb, const unsigned int coeff_count)
++{
++ HEVCRpiCoeffsEnv * const cf = &jb->coeffs;
++
++ if (gpu_malloc_cached((coeff_count + 32*32) * sizeof(cf->s[2].buf[0]), &cf->gptr) != 0)
++ goto fail;
++ cf->s[2].buf = (int16_t *)cf->gptr.arm;
++ cf->s[3].buf = cf->s[2].buf + coeff_count;
++
++ // Must be 64 byte aligned for our zero zapping code so over-allocate &
++ // round
++ if ((cf->mptr = av_malloc(coeff_count * sizeof(cf->s[0].buf[0]) + 63)) == NULL)
++ goto fail;
++ cf->s[0].buf = (void *)(((intptr_t)cf->mptr + 63) & ~63);
++ return 0;
++
++fail:
++ av_log(NULL, AV_LOG_ERROR, "%s: Allocation failed\n", __func__);
++ worker_pic_free_one(jb);
++ return -1;
++}
++
++static void worker_pic_reset(HEVCRpiCoeffsEnv * const cf)
++{
++ unsigned int i;
++ for (i = 0; i != 4; ++i) {
++ cf->s[i].n = 0;
++#if RPI_COMPRESS_COEFFS
++ cf->s[i].packed = 1;
++ cf->s[i].packed_n = 0;
++#endif
++ }
++}
++
++int16_t * rpi_alloc_coeff_buf(HEVCRpiJob * const jb, const int buf_no, const int n)
++{
++ HEVCRpiCoeffEnv *const cfe = jb->coeffs.s + buf_no;
++ int16_t * const coeffs = (buf_no != 3) ? cfe->buf + cfe->n : cfe->buf - (cfe->n + n);
++ cfe->n += n;
++ return coeffs;
++}
++
++void ff_hevc_rpi_progress_wait_field(const HEVCRpiContext * const s, HEVCRpiJob * const jb,
++ const HEVCRpiFrame * const ref, const int val, const int field)
++{
++ if (ref->tf.progress != NULL && ((int *)ref->tf.progress->data)[field] < val) {
++ HEVCRpiContext *const fs = ref->tf.owner[field]->priv_data;
++ HEVCRpiFrameProgressState * const pstate = fs->progress_states + field;
++ sem_t * sem = NULL;
++
++ av_assert0(pthread_mutex_lock(&pstate->lock) == 0);
++ if (((volatile int *)ref->tf.progress->data)[field] < val) {
++ HEVCRpiFrameProgressWait * const pwait = &jb->progress_wait;
++
++ av_assert1(pwait->req == -1 && pwait->next == NULL);
++ jb->waited = 1; // Remember that we had to wait for later scheduling
++
++ pwait->req = val;
++ pwait->next = NULL;
++ if (pstate->first == NULL)
++ pstate->first = pwait;
++ else
++ pstate->last->next = pwait;
++ pstate->last = pwait;
++ sem = &pwait->sem;
++ }
++ pthread_mutex_unlock(&pstate->lock);
++
++ if (sem != NULL) {
++ rpi_sem_wait(sem);
++ }
++ }
++}
++
++void ff_hevc_rpi_progress_signal_field(HEVCRpiContext * const s, const int val, const int field)
++{
++ HEVCRpiFrameProgressState *const pstate = s->progress_states + field;
++
++ ((int *)s->ref->tf.progress->data)[field] = val;
++
++ av_assert0(pthread_mutex_lock(&pstate->lock) == 0);
++ {
++ HEVCRpiFrameProgressWait ** ppwait = &pstate->first;
++ HEVCRpiFrameProgressWait * pwait;
++
++ while ((pwait = *ppwait) != NULL) {
++ if (pwait->req > val)
++ {
++ ppwait = &pwait->next;
++ pstate->last = pwait;
++ }
++ else
++ {
++ *ppwait = pwait->next;
++ pwait->req = -1;
++ pwait->next = NULL;
++ sem_post(&pwait->sem);
++ }
++ }
++ }
++ pthread_mutex_unlock(&pstate->lock);
++}
++
++static void ff_hevc_rpi_progress_init_state(HEVCRpiFrameProgressState * const pstate)
++{
++ pstate->first = NULL;
++ pstate->last = NULL;
++ pthread_mutex_init(&pstate->lock, NULL);
++}
++
++static void ff_hevc_rpi_progress_init_wait(HEVCRpiFrameProgressWait * const pwait)
++{
++ pwait->req = -1;
++ pwait->next = NULL;
++ sem_init(&pwait->sem, 0, 0);
++}
++
++static void ff_hevc_rpi_progress_kill_state(HEVCRpiFrameProgressState * const pstate)
++{
++ av_assert1(pstate->first == NULL);
++ pthread_mutex_destroy(&pstate->lock);
++}
++
++static void ff_hevc_rpi_progress_kill_wait(HEVCRpiFrameProgressWait * const pwait)
++{
++ sem_destroy(&pwait->sem);
++}
++
++
++/**
++ * NOTE: Each function hls_foo correspond to the function foo in the
++ * specification (HLS stands for High Level Syntax).
++ */
++
++/**
++ * Section 5.7
++ */
++
++// Realloc the entry point arrays
++static int alloc_entry_points(RpiSliceHeader * const sh, const int n)
++{
++ if (sh->entry_point_offset == NULL || n > sh->offsets_allocated || n == 0)
++ {
++ // Round up alloc to multiple of 32
++ int a = (n + 31) & ~31;
++
++ // We don't care about the previous contents so probably fastest to simply discard
++ av_freep(&sh->entry_point_offset);
++ av_freep(&sh->offset);
++ av_freep(&sh->size);
++
++ if (a != 0)
++ {
++ sh->entry_point_offset = av_malloc_array(a, sizeof(unsigned));
++ sh->offset = av_malloc_array(a, sizeof(int));
++ sh->size = av_malloc_array(a, sizeof(int));
++
++ if (!sh->entry_point_offset || !sh->offset || !sh->size) {
++ sh->num_entry_point_offsets = 0;
++ sh->offsets_allocated = 0;
++ return AVERROR(ENOMEM);
++ }
++ }
++
++ sh->offsets_allocated = a;
++ }
++
++ return 0;
++}
++
++/* free everything allocated by pic_arrays_init() */
++static void pic_arrays_free(HEVCRpiContext *s)
++{
++ av_freep(&s->sao);
++ av_freep(&s->deblock);
++
++ av_freep(&s->cabac_stash_up);
++ s->cabac_stash_left = NULL; // freed with _up
++
++ av_freep(&s->mvf_up);
++ av_freep(&s->mvf_left);
++
++ av_freep(&s->is_pcm);
++ av_freep(&s->is_intra_store);
++ s->is_intra = NULL;
++ av_freep(&s->rpl_tab);
++ s->rpl_tab_size = 0;
++
++ av_freep(&s->qp_y_tab);
++ av_freep(&s->tab_slice_address);
++ av_freep(&s->filter_slice_edges);
++
++ av_freep(&s->bs_horizontal);
++ s->bs_vertical = NULL; // freed with H
++ av_freep(&s->bsf_stash_left);
++ av_freep(&s->bsf_stash_up);
++
++ av_freep(&s->rpl_up);
++ av_freep(&s->rpl_left);
++
++ alloc_entry_points(&s->sh, 0);
++
++ av_buffer_pool_uninit(&s->col_mvf_pool);
++}
++
++/* allocate arrays that depend on frame dimensions */
++static int pic_arrays_init(HEVCRpiContext * const s, const HEVCRpiSPS * const sps)
++{
++ const unsigned int log2_min_cb_size = sps->log2_min_cb_size;
++ const unsigned int width = sps->width;
++ const unsigned int height = sps->height;
++ const unsigned int pic_size_in_cb = ((width >> log2_min_cb_size) + 1) *
++ ((height >> log2_min_cb_size) + 1);
++ const unsigned int ctb_count = sps->ctb_size;
++
++ {
++ unsigned int w = ((width + HEVC_RPI_BS_STRIDE1_PEL_MASK) & ~HEVC_RPI_BS_STRIDE1_PEL_MASK);
++ unsigned int h = ((height + 15) & ~15);
++
++ s->bs_stride2 = h >> HEVC_RPI_BS_COL_BYTES_SHR; // Column size
++ s->bs_size = s->bs_stride2 * (w >> HEVC_RPI_BS_STRIDE1_PEL_SHIFT); // col size * cols
++ }
++
++ s->sao = av_mallocz(ctb_count * sizeof(*s->sao) + 8); // Our sao code overreads this array slightly
++ s->deblock = av_mallocz_array(ctb_count, sizeof(*s->deblock));
++ if (!s->sao || !s->deblock)
++ goto fail;
++
++ s->cabac_stash_up = av_malloc((((width + 63) & ~63) >> 3) + (((height + 63) & ~63) >> 3));
++ s->cabac_stash_left = s->cabac_stash_up + (((width + 63) & ~63) >> 3);
++ if (s->cabac_stash_up == NULL)
++ goto fail;
++
++ // Round width up to max ctb size
++ s->mvf_up = av_malloc((((width + 63) & ~63) >> LOG2_MIN_PU_SIZE) * sizeof(*s->mvf_up));
++ // * Only needed if we have H tiles
++ s->mvf_left = av_malloc((((height + 63) & ~63) >> LOG2_MIN_PU_SIZE) * sizeof(*s->mvf_up));
++
++ // We can overread by 1 line & one byte in deblock so alloc & zero
++ // We don't need to zero the extra @ start of frame as it will never be
++ // written
++ s->is_pcm = av_mallocz(sps->pcm_width * (sps->pcm_height + 1) + 1);
++ s->is_intra_store = av_mallocz(sps->pcm_width * (sps->pcm_height + 1) + 1);
++ if (s->is_pcm == NULL || s->is_intra_store == NULL)
++ goto fail;
++
++ s->filter_slice_edges = av_mallocz(ctb_count);
++ s->tab_slice_address = av_malloc_array(ctb_count,
++ sizeof(*s->tab_slice_address));
++ s->qp_y_tab = av_malloc_array(pic_size_in_cb,
++ sizeof(*s->qp_y_tab));
++ if (!s->qp_y_tab || !s->filter_slice_edges || !s->tab_slice_address)
++ goto fail;
++
++ s->bs_horizontal = av_mallocz(s->bs_size * 2);
++ s->bs_vertical = s->bs_horizontal + s->bs_size;
++ if (s->bs_horizontal == NULL)
++ goto fail;
++
++ s->rpl_up = av_mallocz(sps->ctb_width * sizeof(*s->rpl_up));
++ s->rpl_left = av_mallocz(sps->ctb_height * sizeof(*s->rpl_left));
++ if (s->rpl_left == NULL || s->rpl_up == NULL)
++ goto fail;
++
++ if ((s->bsf_stash_left = av_mallocz(((height + 63) & ~63) >> 4)) == NULL ||
++ (s->bsf_stash_up = av_mallocz(((width + 63) & ~63) >> 4)) == NULL)
++ goto fail;
++
++ s->col_mvf_stride = (width + 15) >> 4;
++ s->col_mvf_pool = av_buffer_pool_init(((height + 15) >> 4) * s->col_mvf_stride * sizeof(ColMvField),
++ av_buffer_allocz);
++ if (s->col_mvf_pool == NULL)
++ goto fail;
++
++ return 0;
++
++fail:
++ pic_arrays_free(s);
++ return AVERROR(ENOMEM);
++}
++
++static void default_pred_weight_table(HEVCRpiContext * const s)
++{
++ unsigned int i;
++ const unsigned int wt = 1 << QPU_MC_DENOM;
++ s->sh.luma_log2_weight_denom = 0;
++ s->sh.chroma_log2_weight_denom = 0;
++ for (i = 0; i < s->sh.nb_refs[L0]; i++) {
++ s->sh.luma_weight_l0[i] = wt;
++ s->sh.luma_offset_l0[i] = 0;
++ s->sh.chroma_weight_l0[i][0] = wt;
++ s->sh.chroma_weight_l0[i][1] = wt;
++ s->sh.chroma_offset_l0[i][0] = 0;
++ s->sh.chroma_offset_l0[i][1] = 0;
++ }
++ for (i = 0; i < s->sh.nb_refs[L1]; i++) {
++ s->sh.luma_weight_l1[i] = wt;
++ s->sh.luma_offset_l1[i] = 0;
++ s->sh.chroma_weight_l1[i][0] = wt;
++ s->sh.chroma_weight_l1[i][1] = wt;
++ s->sh.chroma_offset_l1[i][0] = 0;
++ s->sh.chroma_offset_l1[i][1] = 0;
++ }
++}
++
++static int get_weights(HEVCRpiContext * const s, GetBitContext * const gb,
++ const unsigned int refs,
++ int16_t * luma_weight, int16_t * luma_offset,
++ int16_t * chroma_weight, int16_t * chroma_offset)
++{
++ unsigned int luma_flags;
++ unsigned int chroma_flags;
++ unsigned int i;
++ const unsigned int wp_offset_bd_shift = s->ps.sps->high_precision_offsets_enabled_flag ? 0 : (s->ps.sps->bit_depth - 8);
++ const int wp_offset_half_range = s->ps.sps->wp_offset_half_range;
++ const unsigned int luma_weight_base = 1 << QPU_MC_DENOM;
++ const unsigned int chroma_weight_base = 1 << QPU_MC_DENOM;
++ const unsigned int luma_weight_shift = (QPU_MC_DENOM - s->sh.luma_log2_weight_denom);
++ const unsigned int chroma_weight_shift = (QPU_MC_DENOM - s->sh.chroma_log2_weight_denom);
++
++ if (refs == 0)
++ return 0;
++
++ luma_flags = get_bits(gb, refs);
++ chroma_flags = ctx_cfmt(s) == 0 ? 0 : get_bits(gb, refs);
++ i = 1 << (refs - 1);
++
++ do
++ {
++ if ((luma_flags & i) != 0)
++ {
++ const int delta_weight = get_se_golomb(gb);
++ const int offset = get_se_golomb(gb);
++ if (delta_weight < -128 || delta_weight > 127 ||
++ offset < -wp_offset_half_range || offset >= wp_offset_half_range)
++ {
++ return AVERROR_INVALIDDATA;
++ }
++ *luma_weight++ = luma_weight_base + (delta_weight << luma_weight_shift);
++ *luma_offset++ = offset << wp_offset_bd_shift;
++ }
++ else
++ {
++ *luma_weight++ = luma_weight_base;
++ *luma_offset++ = 0;
++ }
++
++ if ((chroma_flags & i) != 0)
++ {
++ unsigned int j;
++ for (j = 0; j != 2; ++j)
++ {
++ const int delta_weight = get_se_golomb(gb);
++ const int delta_offset = get_se_golomb(gb);
++
++ if (delta_weight < -128 || delta_weight > 127 ||
++ delta_offset < -4 * wp_offset_half_range || delta_offset >= 4 * wp_offset_half_range)
++ {
++ return AVERROR_INVALIDDATA;
++ }
++
++ *chroma_weight++ = chroma_weight_base + (delta_weight << chroma_weight_shift);
++ *chroma_offset++ = av_clip(
++ wp_offset_half_range + delta_offset -
++ ((wp_offset_half_range * ((1 << s->sh.chroma_log2_weight_denom) + delta_weight)) >> s->sh.chroma_log2_weight_denom),
++ -wp_offset_half_range, wp_offset_half_range - 1) << wp_offset_bd_shift;
++ }
++ }
++ else
++ {
++ *chroma_weight++ = chroma_weight_base;
++ *chroma_weight++ = chroma_weight_base;
++ *chroma_offset++ = 0;
++ *chroma_offset++ = 0;
++ }
++ } while ((i >>= 1) != 0);
++
++ return 0;
++}
++
++static int pred_weight_table(HEVCRpiContext *s, GetBitContext *gb)
++{
++ int err;
++ const unsigned int luma_log2_weight_denom = get_ue_golomb_long(gb);
++ const unsigned int chroma_log2_weight_denom = (ctx_cfmt(s) == 0) ? 0 : luma_log2_weight_denom + get_se_golomb(gb);
++
++ if (luma_log2_weight_denom > 7 ||
++ chroma_log2_weight_denom > 7)
++ {
++ av_log(s->avctx, AV_LOG_ERROR, "Invalid prediction weight denom: luma=%d, chroma=%d\n",
++ luma_log2_weight_denom, chroma_log2_weight_denom);
++ return AVERROR_INVALIDDATA;
++ }
++
++ s->sh.luma_log2_weight_denom = luma_log2_weight_denom;
++ s->sh.chroma_log2_weight_denom = chroma_log2_weight_denom;
++
++ if ((err = get_weights(s, gb, s->sh.nb_refs[L0],
++ s->sh.luma_weight_l0, s->sh.luma_offset_l0,
++ s->sh.chroma_weight_l0[0], s->sh.chroma_offset_l0[0])) != 0 ||
++ (err = get_weights(s, gb, s->sh.nb_refs[L1],
++ s->sh.luma_weight_l1, s->sh.luma_offset_l1,
++ s->sh.chroma_weight_l1[0], s->sh.chroma_offset_l1[0])) != 0)
++ {
++ av_log(s->avctx, AV_LOG_ERROR, "Invalid prediction weight or offset\n");
++ return err;
++ }
++
++ return 0;
++}
++
++static int decode_lt_rps(HEVCRpiContext *s, LongTermRPS *rps, GetBitContext *gb)
++{
++ const HEVCRpiSPS *sps = s->ps.sps;
++ int max_poc_lsb = 1 << sps->log2_max_poc_lsb;
++ int prev_delta_msb = 0;
++ unsigned int nb_sps = 0, nb_sh;
++ int i;
++
++ rps->nb_refs = 0;
++ if (!sps->long_term_ref_pics_present_flag)
++ return 0;
++
++ if (sps->num_long_term_ref_pics_sps > 0)
++ nb_sps = get_ue_golomb_long(gb);
++ nb_sh = get_ue_golomb_long(gb);
++
++ if (nb_sps > sps->num_long_term_ref_pics_sps)
++ return AVERROR_INVALIDDATA;
++ if (nb_sh + (uint64_t)nb_sps > FF_ARRAY_ELEMS(rps->poc))
++ return AVERROR_INVALIDDATA;
++
++ rps->nb_refs = nb_sh + nb_sps;
++
++ for (i = 0; i < rps->nb_refs; i++) {
++ uint8_t delta_poc_msb_present;
++
++ if (i < nb_sps) {
++ uint8_t lt_idx_sps = 0;
++
++ if (sps->num_long_term_ref_pics_sps > 1)
++ lt_idx_sps = get_bits(gb, av_ceil_log2(sps->num_long_term_ref_pics_sps));
++
++ rps->poc[i] = sps->lt_ref_pic_poc_lsb_sps[lt_idx_sps];
++ rps->used[i] = sps->used_by_curr_pic_lt_sps_flag[lt_idx_sps];
++ } else {
++ rps->poc[i] = get_bits(gb, sps->log2_max_poc_lsb);
++ rps->used[i] = get_bits1(gb);
++ }
++
++ delta_poc_msb_present = get_bits1(gb);
++ if (delta_poc_msb_present) {
++ int64_t delta = get_ue_golomb_long(gb);
++ int64_t poc;
++
++ if (i && i != nb_sps)
++ delta += prev_delta_msb;
++
++ poc = rps->poc[i] + s->poc - delta * max_poc_lsb - s->sh.pic_order_cnt_lsb;
++ if (poc != (int32_t)poc)
++ return AVERROR_INVALIDDATA;
++ rps->poc[i] = poc;
++ prev_delta_msb = delta;
++ }
++ }
++
++ return 0;
++}
++
++static void export_stream_params(AVCodecContext *avctx, const HEVCRpiParamSets *ps,
++ const HEVCRpiSPS *sps)
++{
++ const HEVCRpiVPS *vps = (const HEVCRpiVPS*)ps->vps_list[sps->vps_id]->data;
++ const HEVCRpiWindow *ow = &sps->output_window;
++ unsigned int num = 0, den = 0;
++
++ avctx->pix_fmt = sps->pix_fmt;
++ avctx->coded_width = sps->width;
++ avctx->coded_height = sps->height;
++ avctx->width = sps->width - ow->left_offset - ow->right_offset;
++ avctx->height = sps->height - ow->top_offset - ow->bottom_offset;
++ avctx->has_b_frames = sps->temporal_layer[sps->max_sub_layers - 1].num_reorder_pics;
++ avctx->profile = sps->ptl.general_ptl.profile_idc;
++ avctx->level = sps->ptl.general_ptl.level_idc;
++
++ ff_set_sar(avctx, sps->vui.sar);
++
++ if (sps->vui.video_signal_type_present_flag)
++ avctx->color_range = sps->vui.video_full_range_flag ? AVCOL_RANGE_JPEG
++ : AVCOL_RANGE_MPEG;
++ else
++ avctx->color_range = AVCOL_RANGE_MPEG;
++
++ if (sps->vui.colour_description_present_flag) {
++ avctx->color_primaries = sps->vui.colour_primaries;
++ avctx->color_trc = sps->vui.transfer_characteristic;
++ avctx->colorspace = sps->vui.matrix_coeffs;
++ } else {
++ avctx->color_primaries = AVCOL_PRI_UNSPECIFIED;
++ avctx->color_trc = AVCOL_TRC_UNSPECIFIED;
++ avctx->colorspace = AVCOL_SPC_UNSPECIFIED;
++ }
++
++ if (vps->vps_timing_info_present_flag) {
++ num = vps->vps_num_units_in_tick;
++ den = vps->vps_time_scale;
++ } else if (sps->vui.vui_timing_info_present_flag) {
++ num = sps->vui.vui_num_units_in_tick;
++ den = sps->vui.vui_time_scale;
++ }
++
++ if (num != 0 && den != 0)
++ av_reduce(&avctx->framerate.den, &avctx->framerate.num,
++ num, den, 1 << 30);
++}
++
++static enum AVPixelFormat get_format(HEVCRpiContext *s, const HEVCRpiSPS *sps)
++{
++ enum AVPixelFormat pix_fmts[4], *fmt = pix_fmts;
++
++ // Admit to no h/w formats
++
++ *fmt++ = sps->pix_fmt;
++ *fmt = AV_PIX_FMT_NONE;
++
++ return pix_fmts[0] == AV_PIX_FMT_NONE ? AV_PIX_FMT_NONE: ff_thread_get_format(s->avctx, pix_fmts);
++}
++
++static int is_sps_supported(const HEVCRpiSPS * const sps)
++{
++ return av_rpi_is_sand_format(sps->pix_fmt) &&
++ sps->width <= HEVC_RPI_MAX_WIDTH &&
++ sps->height <= HEVC_RPI_MAX_HEIGHT;
++}
++
++static int set_sps(HEVCRpiContext * const s, const HEVCRpiSPS * const sps,
++ const enum AVPixelFormat pix_fmt)
++{
++ int ret;
++
++ pic_arrays_free(s);
++ s->ps.sps = NULL;
++ s->ps.vps = NULL;
++
++ if (sps == NULL)
++ return 0;
++
++ if (!is_sps_supported(sps))
++ return AVERROR_DECODER_NOT_FOUND;
++
++ ret = pic_arrays_init(s, sps);
++ if (ret < 0)
++ goto fail;
++
++ export_stream_params(s->avctx, &s->ps, sps);
++
++ s->avctx->pix_fmt = pix_fmt;
++
++ ff_hevc_rpi_pred_init(&s->hpc, sps->bit_depth);
++ ff_hevc_rpi_dsp_init (&s->hevcdsp, sps->bit_depth);
++
++ // * We don't support cross_component_prediction_enabled_flag but as that
++ // must be 0 unless we have 4:4:4 there is no point testing for it as we
++ // only deal with sand which is never 4:4:4
++ // [support wouldn't be hard]
++
++ rpi_hevc_qpu_set_fns(s, sps->bit_depth);
++
++ av_freep(&s->sao_pixel_buffer_h[0]);
++ av_freep(&s->sao_pixel_buffer_v[0]);
++
++ if (sps->sao_enabled)
++ {
++ const unsigned int c_count = (ctx_cfmt(s) != 0) ? 3 : 1;
++ unsigned int c_idx;
++ size_t vsize[3] = {0};
++ size_t hsize[3] = {0};
++
++ for(c_idx = 0; c_idx < c_count; c_idx++) {
++ int w = sps->width >> ctx_hshift(s, c_idx);
++ int h = sps->height >> ctx_vshift(s, c_idx);
++ // ctb height & width are a min of 8 so this must a multiple of 16
++ // so no point rounding up!
++ hsize[c_idx] = (w * 2 * sps->ctb_height) << sps->pixel_shift;
++ vsize[c_idx] = (h * 2 * sps->ctb_width) << sps->pixel_shift;
++ }
++
++ // Allocate as a single lump so we can extend h[1] & v[1] into h[2] & v[2]
++ // when we have plaited chroma
++ s->sao_pixel_buffer_h[0] = av_malloc(hsize[0] + hsize[1] + hsize[2]);
++ s->sao_pixel_buffer_v[0] = av_malloc(vsize[0] + vsize[1] + vsize[2]);
++ s->sao_pixel_buffer_h[1] = s->sao_pixel_buffer_h[0] + hsize[0];
++ s->sao_pixel_buffer_h[2] = s->sao_pixel_buffer_h[1] + hsize[1];
++ s->sao_pixel_buffer_v[1] = s->sao_pixel_buffer_v[0] + vsize[0];
++ s->sao_pixel_buffer_v[2] = s->sao_pixel_buffer_v[1] + vsize[1];
++ }
++
++ s->ps.sps = sps;
++ s->ps.vps = (HEVCRpiVPS*) s->ps.vps_list[s->ps.sps->vps_id]->data;
++
++ return 0;
++
++fail:
++ pic_arrays_free(s);
++ s->ps.sps = NULL;
++ return ret;
++}
++
++static inline int qp_offset_valid(const int qp_offset)
++{
++ return qp_offset >= -12 && qp_offset <= 12;
++}
++
++static int hls_slice_header(HEVCRpiContext * const s)
++{
++ GetBitContext * const gb = &s->HEVClc->gb;
++ RpiSliceHeader * const sh = &s->sh;
++ int i, ret;
++
++ // Coded parameters
++ sh->first_slice_in_pic_flag = get_bits1(gb);
++ if ((IS_IDR(s) || IS_BLA(s)) && sh->first_slice_in_pic_flag) {
++ s->seq_decode = (s->seq_decode + 1) & 0xff;
++ s->max_ra = INT_MAX;
++ if (IS_IDR(s))
++ ff_hevc_rpi_clear_refs(s);
++ }
++ sh->no_output_of_prior_pics_flag = 0;
++ if (IS_IRAP(s))
++ sh->no_output_of_prior_pics_flag = get_bits1(gb);
++
++ sh->pps_id = get_ue_golomb_long(gb);
++ if (sh->pps_id >= HEVC_MAX_PPS_COUNT || !s->ps.pps_list[sh->pps_id]) {
++ av_log(s->avctx, AV_LOG_ERROR, "PPS id out of range: %d\n", sh->pps_id);
++ return AVERROR_INVALIDDATA;
++ }
++ if (!sh->first_slice_in_pic_flag &&
++ s->ps.pps != (HEVCRpiPPS*)s->ps.pps_list[sh->pps_id]->data) {
++ av_log(s->avctx, AV_LOG_ERROR, "PPS changed between slices.\n");
++ return AVERROR_INVALIDDATA;
++ }
++ s->ps.pps = (HEVCRpiPPS*)s->ps.pps_list[sh->pps_id]->data;
++ if (s->nal_unit_type == HEVC_NAL_CRA_NUT && s->last_eos == 1)
++ sh->no_output_of_prior_pics_flag = 1;
++
++ if (s->ps.sps != (HEVCRpiSPS*)s->ps.sps_list[s->ps.pps->sps_id]->data) {
++ const HEVCRpiSPS *sps = (HEVCRpiSPS*)s->ps.sps_list[s->ps.pps->sps_id]->data;
++ const HEVCRpiSPS *last_sps = s->ps.sps;
++ enum AVPixelFormat pix_fmt;
++
++ if (last_sps && IS_IRAP(s) && s->nal_unit_type != HEVC_NAL_CRA_NUT) {
++ if (sps->width != last_sps->width || sps->height != last_sps->height ||
++ sps->temporal_layer[sps->max_sub_layers - 1].max_dec_pic_buffering !=
++ last_sps->temporal_layer[last_sps->max_sub_layers - 1].max_dec_pic_buffering)
++ sh->no_output_of_prior_pics_flag = 0;
++ }
++ ff_hevc_rpi_clear_refs(s);
++
++ ret = set_sps(s, sps, sps->pix_fmt);
++ if (ret < 0)
++ return ret;
++
++ pix_fmt = get_format(s, sps);
++ if (pix_fmt < 0)
++ return pix_fmt;
++
++// ret = set_sps(s, sps, pix_fmt);
++// if (ret < 0)
++// return ret;
++
++ s->avctx->pix_fmt = pix_fmt;
++
++ s->seq_decode = (s->seq_decode + 1) & 0xff;
++ s->max_ra = INT_MAX;
++ }
++
++ sh->dependent_slice_segment_flag = 0;
++ if (!sh->first_slice_in_pic_flag) {
++ int slice_address_length;
++
++ if (s->ps.pps->dependent_slice_segments_enabled_flag)
++ sh->dependent_slice_segment_flag = get_bits1(gb);
++
++ slice_address_length = av_ceil_log2(s->ps.sps->ctb_size);
++ sh->slice_segment_addr = get_bitsz(gb, slice_address_length);
++ if (sh->slice_segment_addr >= s->ps.sps->ctb_size) {
++ av_log(s->avctx, AV_LOG_ERROR,
++ "Invalid slice segment address: %u.\n",
++ sh->slice_segment_addr);
++ return AVERROR_INVALIDDATA;
++ }
++
++ if (!sh->dependent_slice_segment_flag) {
++ sh->slice_addr = sh->slice_segment_addr;
++ s->slice_idx++;
++ }
++ } else {
++ sh->slice_segment_addr = sh->slice_addr = 0;
++ s->slice_idx = 0;
++ s->slice_initialized = 0;
++ }
++
++ if (!sh->dependent_slice_segment_flag) {
++ s->slice_initialized = 0;
++
++ for (i = 0; i < s->ps.pps->num_extra_slice_header_bits; i++)
++ skip_bits(gb, 1); // slice_reserved_undetermined_flag[]
++
++ sh->slice_type = get_ue_golomb_long(gb);
++ if (!(sh->slice_type == HEVC_SLICE_I ||
++ sh->slice_type == HEVC_SLICE_P ||
++ sh->slice_type == HEVC_SLICE_B)) {
++ av_log(s->avctx, AV_LOG_ERROR, "Unknown slice type: %d.\n",
++ sh->slice_type);
++ return AVERROR_INVALIDDATA;
++ }
++ if (IS_IRAP(s) && sh->slice_type != HEVC_SLICE_I) {
++ av_log(s->avctx, AV_LOG_ERROR, "Inter slices in an IRAP frame.\n");
++ return AVERROR_INVALIDDATA;
++ }
++
++ // when flag is not present, picture is inferred to be output
++ sh->pic_output_flag = 1;
++ if (s->ps.pps->output_flag_present_flag)
++ sh->pic_output_flag = get_bits1(gb);
++
++ if (s->ps.sps->separate_colour_plane_flag)
++ sh->colour_plane_id = get_bits(gb, 2);
++
++ if (!IS_IDR(s)) {
++ int poc, pos;
++
++ sh->pic_order_cnt_lsb = get_bits(gb, s->ps.sps->log2_max_poc_lsb);
++ poc = ff_hevc_rpi_compute_poc(s->ps.sps, s->pocTid0, sh->pic_order_cnt_lsb, s->nal_unit_type);
++ if (!sh->first_slice_in_pic_flag && poc != s->poc) {
++ av_log(s->avctx, AV_LOG_WARNING,
++ "Ignoring POC change between slices: %d -> %d\n", s->poc, poc);
++ if (s->avctx->err_recognition & AV_EF_EXPLODE)
++ return AVERROR_INVALIDDATA;
++ poc = s->poc;
++ }
++ s->poc = poc;
++
++ sh->short_term_ref_pic_set_sps_flag = get_bits1(gb);
++ pos = get_bits_left(gb);
++ if (!sh->short_term_ref_pic_set_sps_flag) {
++ ret = ff_hevc_rpi_decode_short_term_rps(gb, s->avctx, &sh->slice_rps, s->ps.sps, 1);
++ if (ret < 0)
++ return ret;
++
++ sh->short_term_rps = &sh->slice_rps;
++ } else {
++ int numbits, rps_idx;
++
++ if (!s->ps.sps->nb_st_rps) {
++ av_log(s->avctx, AV_LOG_ERROR, "No ref lists in the SPS.\n");
++ return AVERROR_INVALIDDATA;
++ }
++
++ numbits = av_ceil_log2(s->ps.sps->nb_st_rps);
++ rps_idx = numbits > 0 ? get_bits(gb, numbits) : 0;
++ sh->short_term_rps = &s->ps.sps->st_rps[rps_idx];
++ }
++ sh->short_term_ref_pic_set_size = pos - get_bits_left(gb);
++
++ pos = get_bits_left(gb);
++ ret = decode_lt_rps(s, &sh->long_term_rps, gb);
++ if (ret < 0) {
++ av_log(s->avctx, AV_LOG_WARNING, "Invalid long term RPS.\n");
++ if (s->avctx->err_recognition & AV_EF_EXPLODE)
++ return AVERROR_INVALIDDATA;
++ }
++ sh->long_term_ref_pic_set_size = pos - get_bits_left(gb);
++
++ if (s->ps.sps->sps_temporal_mvp_enabled_flag)
++ sh->slice_temporal_mvp_enabled_flag = get_bits1(gb);
++ else
++ sh->slice_temporal_mvp_enabled_flag = 0;
++ } else {
++ s->sh.short_term_rps = NULL;
++ s->poc = 0;
++ }
++
++ /* 8.3.1 */
++ if (sh->first_slice_in_pic_flag && s->temporal_id == 0 &&
++ s->nal_unit_type != HEVC_NAL_TRAIL_N &&
++ s->nal_unit_type != HEVC_NAL_TSA_N &&
++ s->nal_unit_type != HEVC_NAL_STSA_N &&
++ s->nal_unit_type != HEVC_NAL_RADL_N &&
++ s->nal_unit_type != HEVC_NAL_RADL_R &&
++ s->nal_unit_type != HEVC_NAL_RASL_N &&
++ s->nal_unit_type != HEVC_NAL_RASL_R)
++ s->pocTid0 = s->poc;
++
++ if (s->ps.sps->sao_enabled) {
++ sh->slice_sample_adaptive_offset_flag[0] = get_bits1(gb);
++ if (ctx_cfmt(s) != 0) {
++ sh->slice_sample_adaptive_offset_flag[1] =
++ sh->slice_sample_adaptive_offset_flag[2] = get_bits1(gb);
++ }
++ } else {
++ sh->slice_sample_adaptive_offset_flag[0] = 0;
++ sh->slice_sample_adaptive_offset_flag[1] = 0;
++ sh->slice_sample_adaptive_offset_flag[2] = 0;
++ }
++
++ sh->nb_refs[L0] = sh->nb_refs[L1] = 0;
++ if (sh->slice_type == HEVC_SLICE_P || sh->slice_type == HEVC_SLICE_B) {
++ int nb_refs;
++
++ sh->nb_refs[L0] = s->ps.pps->num_ref_idx_l0_default_active;
++ if (sh->slice_type == HEVC_SLICE_B)
++ sh->nb_refs[L1] = s->ps.pps->num_ref_idx_l1_default_active;
++
++ if (get_bits1(gb)) { // num_ref_idx_active_override_flag
++ sh->nb_refs[L0] = get_ue_golomb_long(gb) + 1;
++ if (sh->slice_type == HEVC_SLICE_B)
++ sh->nb_refs[L1] = get_ue_golomb_long(gb) + 1;
++ }
++ if (sh->nb_refs[L0] > HEVC_MAX_REFS || sh->nb_refs[L1] > HEVC_MAX_REFS) {
++ av_log(s->avctx, AV_LOG_ERROR, "Too many refs: %d/%d.\n",
++ sh->nb_refs[L0], sh->nb_refs[L1]);
++ return AVERROR_INVALIDDATA;
++ }
++
++ sh->rpl_modification_flag[0] = 0;
++ sh->rpl_modification_flag[1] = 0;
++ nb_refs = ff_hevc_rpi_frame_nb_refs(s);
++ if (!nb_refs) {
++ av_log(s->avctx, AV_LOG_ERROR, "Zero refs for a frame with P or B slices.\n");
++ return AVERROR_INVALIDDATA;
++ }
++
++ if (s->ps.pps->lists_modification_present_flag && nb_refs > 1) {
++ sh->rpl_modification_flag[0] = get_bits1(gb);
++ if (sh->rpl_modification_flag[0]) {
++ for (i = 0; i < sh->nb_refs[L0]; i++)
++ sh->list_entry_lx[0][i] = get_bits(gb, av_ceil_log2(nb_refs));
++ }
++
++ if (sh->slice_type == HEVC_SLICE_B) {
++ sh->rpl_modification_flag[1] = get_bits1(gb);
++ if (sh->rpl_modification_flag[1] == 1)
++ for (i = 0; i < sh->nb_refs[L1]; i++)
++ sh->list_entry_lx[1][i] = get_bits(gb, av_ceil_log2(nb_refs));
++ }
++ }
++
++ if (sh->slice_type == HEVC_SLICE_B)
++ sh->mvd_l1_zero_flag = get_bits1(gb);
++
++ if (s->ps.pps->cabac_init_present_flag)
++ sh->cabac_init_flag = get_bits1(gb);
++ else
++ sh->cabac_init_flag = 0;
++
++ sh->collocated_ref_idx = 0;
++ if (sh->slice_temporal_mvp_enabled_flag) {
++ sh->collocated_list = L0;
++ if (sh->slice_type == HEVC_SLICE_B)
++ sh->collocated_list = !get_bits1(gb);
++
++ if (sh->nb_refs[sh->collocated_list] > 1) {
++ sh->collocated_ref_idx = get_ue_golomb_long(gb);
++ if (sh->collocated_ref_idx >= sh->nb_refs[sh->collocated_list]) {
++ av_log(s->avctx, AV_LOG_ERROR,
++ "Invalid collocated_ref_idx: %d.\n",
++ sh->collocated_ref_idx);
++ return AVERROR_INVALIDDATA;
++ }
++ }
++ }
++
++ if ((s->ps.pps->weighted_pred_flag && sh->slice_type == HEVC_SLICE_P) ||
++ (s->ps.pps->weighted_bipred_flag && sh->slice_type == HEVC_SLICE_B))
++ {
++ if ((ret = pred_weight_table(s, gb)) != 0)
++ return ret;
++ }
++ else
++ {
++ // Give us unit weights
++ default_pred_weight_table(s);
++ }
++
++ sh->max_num_merge_cand = 5 - get_ue_golomb_long(gb);
++ if (sh->max_num_merge_cand < 1 || sh->max_num_merge_cand > 5) {
++ av_log(s->avctx, AV_LOG_ERROR,
++ "Invalid number of merging MVP candidates: %d.\n",
++ sh->max_num_merge_cand);
++ return AVERROR_INVALIDDATA;
++ }
++ }
++
++ sh->slice_qp_delta = get_se_golomb(gb);
++
++ if (s->ps.pps->pic_slice_level_chroma_qp_offsets_present_flag) {
++ sh->slice_cb_qp_offset = get_se_golomb(gb);
++ sh->slice_cr_qp_offset = get_se_golomb(gb);
++ if (!qp_offset_valid(sh->slice_cb_qp_offset) ||
++ !qp_offset_valid(s->ps.pps->cb_qp_offset + sh->slice_cb_qp_offset) ||
++ !qp_offset_valid(sh->slice_cr_qp_offset) ||
++ !qp_offset_valid(s->ps.pps->cr_qp_offset + sh->slice_cr_qp_offset))
++ {
++ av_log(s->avctx, AV_LOG_ERROR, "Bad chroma offset (pps:%d/%d; slice=%d/%d\n",
++ sh->slice_cr_qp_offset, sh->slice_cr_qp_offset,
++ s->ps.pps->cb_qp_offset, s->ps.pps->cr_qp_offset);
++ return AVERROR_INVALIDDATA;
++ }
++ } else
++ {
++ sh->slice_cb_qp_offset = 0;
++ sh->slice_cr_qp_offset = 0;
++ }
++
++ if (s->ps.pps->chroma_qp_offset_list_enabled_flag)
++ sh->cu_chroma_qp_offset_enabled_flag = get_bits1(gb);
++ else
++ sh->cu_chroma_qp_offset_enabled_flag = 0;
++
++ if (s->ps.pps->deblocking_filter_control_present_flag) {
++ int deblocking_filter_override_flag = 0;
++
++ if (s->ps.pps->deblocking_filter_override_enabled_flag)
++ deblocking_filter_override_flag = get_bits1(gb);
++
++ if (deblocking_filter_override_flag) {
++ sh->disable_deblocking_filter_flag = get_bits1(gb);
++ if (!sh->disable_deblocking_filter_flag) {
++ int beta_offset_div2 = get_se_golomb(gb);
++ int tc_offset_div2 = get_se_golomb(gb) ;
++ if (beta_offset_div2 < -6 || beta_offset_div2 > 6 ||
++ tc_offset_div2 < -6 || tc_offset_div2 > 6) {
++ av_log(s->avctx, AV_LOG_ERROR,
++ "Invalid deblock filter offsets: %d, %d\n",
++ beta_offset_div2, tc_offset_div2);
++ return AVERROR_INVALIDDATA;
++ }
++ sh->beta_offset = beta_offset_div2 * 2;
++ sh->tc_offset = tc_offset_div2 * 2;
++ }
++ } else {
++ sh->disable_deblocking_filter_flag = s->ps.pps->disable_dbf;
++ sh->beta_offset = s->ps.pps->beta_offset;
++ sh->tc_offset = s->ps.pps->tc_offset;
++ }
++ } else {
++ sh->disable_deblocking_filter_flag = 0;
++ sh->beta_offset = 0;
++ sh->tc_offset = 0;
++ }
++
++ if (s->ps.pps->seq_loop_filter_across_slices_enabled_flag &&
++ (sh->slice_sample_adaptive_offset_flag[0] ||
++ sh->slice_sample_adaptive_offset_flag[1] ||
++ !sh->disable_deblocking_filter_flag)) {
++ sh->slice_loop_filter_across_slices_enabled_flag = get_bits1(gb);
++ } else {
++ sh->slice_loop_filter_across_slices_enabled_flag = s->ps.pps->seq_loop_filter_across_slices_enabled_flag;
++ }
++ sh->no_dblk_boundary_flags =
++ (sh->slice_loop_filter_across_slices_enabled_flag ? 0 :
++ BOUNDARY_UPPER_SLICE | BOUNDARY_LEFT_SLICE) |
++ (s->ps.pps->loop_filter_across_tiles_enabled_flag ? 0 :
++ BOUNDARY_UPPER_TILE | BOUNDARY_LEFT_TILE);
++
++
++ } else if (!s->slice_initialized) {
++ av_log(s->avctx, AV_LOG_ERROR, "Independent slice segment missing.\n");
++ return AVERROR_INVALIDDATA;
++ }
++
++ sh->num_entry_point_offsets = 0;
++ sh->offload_wpp = 0;
++ sh->offload_tiles = 0;
++
++ if (s->ps.pps->tiles_enabled_flag || s->ps.pps->entropy_coding_sync_enabled_flag) {
++ unsigned num_entry_point_offsets = get_ue_golomb_long(gb);
++ // It would be possible to bound this tighter but this here is simpler
++ if (num_entry_point_offsets > get_bits_left(gb)) {
++ av_log(s->avctx, AV_LOG_ERROR, "num_entry_point_offsets %d is invalid\n", num_entry_point_offsets);
++ return AVERROR_INVALIDDATA;
++ }
++
++ sh->num_entry_point_offsets = num_entry_point_offsets;
++ if (sh->num_entry_point_offsets > 0) {
++ int offset_len = get_ue_golomb_long(gb) + 1;
++
++ if (offset_len < 1 || offset_len > 32) {
++ sh->num_entry_point_offsets = 0;
++ av_log(s->avctx, AV_LOG_ERROR, "offset_len %d is invalid\n", offset_len);
++ return AVERROR_INVALIDDATA;
++ }
++
++ if ((ret = alloc_entry_points(sh, sh->num_entry_point_offsets)) < 0)
++ {
++ av_log(s->avctx, AV_LOG_ERROR, "Failed to allocate memory\n");
++ return ret;
++ }
++
++ for (i = 0; i < sh->num_entry_point_offsets; i++) {
++ uint32_t val_minus1 = get_bits_long(gb, offset_len);
++ if (val_minus1 > (1 << 28))
++ {
++ // We can declare offsets of > 2^28 bad without loss of generality
++ // Will check actual bounds wrt NAL later, but this keeps
++ // the values within bounds we can deal with easily
++ av_log(s->avctx, AV_LOG_ERROR, "entry_point_offset_minus1 %d invalid\n", val_minus1);
++ return AVERROR_INVALIDDATA;
++ }
++ sh->entry_point_offset[i] = val_minus1 + 1; // +1 to get the size
++ }
++
++ // Do we want to offload this
++ if (s->threads_type != 0)
++ {
++ sh->offload_tiles = (!s->ps.pps->tile_wpp_inter_disable || sh->slice_type == HEVC_SLICE_I) &&
++ s->ps.pps->num_tile_columns > 1;
++ // * We only cope with WPP in a single column
++ // Probably want to deal with that case as tiles rather than WPP anyway
++ // ?? Not actually sure that the main code deals with WPP + multi-col correctly
++ sh->offload_wpp = s->ps.pps->entropy_coding_sync_enabled_flag &&
++ s->ps.pps->num_tile_columns == 1;
++ }
++ }
++ }
++
++ if (s->ps.pps->slice_header_extension_present_flag) {
++ unsigned int length = get_ue_golomb_long(gb);
++ if (length*8LL > get_bits_left(gb)) {
++ av_log(s->avctx, AV_LOG_ERROR, "too many slice_header_extension_data_bytes\n");
++ return AVERROR_INVALIDDATA;
++ }
++ for (i = 0; i < length; i++)
++ skip_bits(gb, 8); // slice_header_extension_data_byte
++ }
++
++ // Inferred parameters
++ sh->slice_qp = 26U + s->ps.pps->pic_init_qp_minus26 + sh->slice_qp_delta;
++ if (sh->slice_qp > 51 ||
++ sh->slice_qp < -s->ps.sps->qp_bd_offset) {
++ av_log(s->avctx, AV_LOG_ERROR,
++ "The slice_qp %d is outside the valid range "
++ "[%d, 51].\n",
++ sh->slice_qp,
++ -s->ps.sps->qp_bd_offset);
++ return AVERROR_INVALIDDATA;
++ }
++
++ if (get_bits_left(gb) < 0) {
++ av_log(s->avctx, AV_LOG_ERROR,
++ "Overread slice header by %d bits\n", -get_bits_left(gb));
++ return AVERROR_INVALIDDATA;
++ }
++
++ s->slice_initialized = 1;
++ return 0;
++}
++
++static void hls_sao_param(const HEVCRpiContext *s, HEVCRpiLocalContext * const lc, const int rx, const int ry)
++{
++ RpiSAOParams * const sao = s->sao + rx + ry * s->ps.sps->ctb_width;
++ int c_idx, i;
++
++ if (s->sh.slice_sample_adaptive_offset_flag[0] ||
++ s->sh.slice_sample_adaptive_offset_flag[1]) {
++ if ((lc->ctb_avail & AVAIL_L) != 0)
++ {
++ const int sao_merge_left_flag = ff_hevc_rpi_sao_merge_flag_decode(lc);
++ if (sao_merge_left_flag) {
++ *sao = sao[-1];
++ return;
++ }
++ }
++ if ((lc->ctb_avail & AVAIL_U) != 0)
++ {
++ const int sao_merge_up_flag = ff_hevc_rpi_sao_merge_flag_decode(lc);
++ if (sao_merge_up_flag) {
++ *sao = sao[-(int)s->ps.sps->ctb_width];
++ return;
++ }
++ }
++ }
++
++ for (c_idx = 0; c_idx < (ctx_cfmt(s) != 0 ? 3 : 1); c_idx++) {
++ const unsigned int log2_sao_offset_scale = c_idx == 0 ? s->ps.pps->log2_sao_offset_scale_luma :
++ s->ps.pps->log2_sao_offset_scale_chroma;
++ int offset_abs[4];
++ char offset_sign[4] = {0};
++
++ if (!s->sh.slice_sample_adaptive_offset_flag[c_idx]) {
++ sao->type_idx[c_idx] = SAO_NOT_APPLIED;
++ continue;
++ }
++
++ if (c_idx == 2) {
++ sao->type_idx[2] = sao->type_idx[1];
++ sao->eo_class[2] = sao->eo_class[1];
++ } else {
++ sao->type_idx[c_idx] = ff_hevc_rpi_sao_type_idx_decode(lc);
++ }
++
++ // ** Could use BY22 here quite plausibly - this is all bypass stuff
++ // though only per CTB so not very timing critical
++
++ if (sao->type_idx[c_idx] == SAO_NOT_APPLIED)
++ continue;
++
++ for (i = 0; i < 4; i++)
++ offset_abs[i] = ff_hevc_rpi_sao_offset_abs_decode(s, lc);
++
++ if (sao->type_idx[c_idx] == SAO_BAND) {
++ for (i = 0; i < 4; i++) {
++ if (offset_abs[i] != 0)
++ offset_sign[i] = ff_hevc_rpi_sao_offset_sign_decode(lc);
++ }
++ sao->band_position[c_idx] = ff_hevc_rpi_sao_band_position_decode(lc);
++ } else if (c_idx != 2) {
++ sao->eo_class[c_idx] = ff_hevc_rpi_sao_eo_class_decode(lc);
++ }
++
++ // Inferred parameters
++ sao->offset_val[c_idx][0] = 0;
++ for (i = 0; i < 4; i++) {
++ sao->offset_val[c_idx][i + 1] = offset_abs[i] << log2_sao_offset_scale;
++ if (sao->type_idx[c_idx] == SAO_EDGE) {
++ if (i > 1)
++ sao->offset_val[c_idx][i + 1] = -sao->offset_val[c_idx][i + 1];
++ } else if (offset_sign[i]) {
++ sao->offset_val[c_idx][i + 1] = -sao->offset_val[c_idx][i + 1];
++ }
++ }
++ }
++}
++
++#if 0
++static int hls_cross_component_pred(HEVCRpiLocalContext * const lc, const int idx) {
++ int log2_res_scale_abs_plus1 = ff_hevc_rpi_log2_res_scale_abs(lc, idx); // 0..4
++
++ if (log2_res_scale_abs_plus1 != 0) {
++ int res_scale_sign_flag = ff_hevc_rpi_res_scale_sign_flag(lc, idx);
++ lc->tu.res_scale_val = (1 << (log2_res_scale_abs_plus1 - 1)) *
++ (1 - 2 * res_scale_sign_flag);
++ } else {
++ lc->tu.res_scale_val = 0;
++ }
++
++
++ return 0;
++}
++#endif
++
++static inline HEVCPredCmd * rpi_new_intra_cmd(HEVCRpiJob * const jb)
++{
++ return jb->intra.cmds + jb->intra.n++;
++}
++
++#define A0(x, y, U, L, UL, UR, DL) \
++ [(x)+(y)*16] = (((U) ? AVAIL_U : 0) | ((L) ? AVAIL_L : 0) | ((UL) ? AVAIL_UL : 0) | ((UR) ? AVAIL_UR : 0) | ((DL) ? AVAIL_DL : 0))
++
++#define A1(x, y, U, L, UL, UR, DL) \
++ A0((x) + 0, (y) + 0, (U), (L), (UL), (U), (L) ), A0((x) + 1, (y) + 0, (U), 1, (U), (UR), 0 ),\
++ A0((x) + 0, (y) + 1, 1, (L), (L), 1, (DL)), A0((x) + 1, (y) + 1, 1, 1, 1, 0, 0 )
++
++#define A2(x, y, U, L, UL, UR, DL) \
++ A1((x) + 0, (y) + 0, (U), (L), (UL), (U), (L) ), A1((x) + 2, (y) + 0, (U), 1, (U), (UR), 0 ),\
++ A1((x) + 0, (y) + 2, 1, (L), (L), 1, (DL)), A1((x) + 2, (y) + 2, 1, 1, 1, 0, 0 )
++
++#define A3(x, y, U, L, UL, UR, DL) \
++ A2((x) + 0, (y) + 0, (U), (L), (UL), (U), (L) ), A2((x) + 4, (y) + 0, (U), 1, (U), (UR), 0 ),\
++ A2((x) + 0, (y) + 4, 1, (L), (L), 1, (DL)), A2((x) + 4, (y) + 4, 1, 1, 1, 0, 0 )
++
++#define A4(x, y, U, L, UL, UR, DL) \
++ A3((x) + 0, (y) + 0, (U), (L), (UL), (U), (L) ), A3((x) + 8, (y) + 0, (U), 1, (U), (UR), 0 ),\
++ A3((x) + 0, (y) + 8, 1, (L), (L), 1, (DL)), A3((x) + 8, (y) + 8, 1, 1, 1, 0, 0 )
++
++static const uint8_t tb_flags[16 * 16] = {A4(0, 0, 0, 0, 0, 0, 0)};
++
++unsigned int ff_hevc_rpi_tb_avail_flags(
++ const HEVCRpiContext * const s, const HEVCRpiLocalContext * const lc,
++ const unsigned int x, const unsigned int y, const unsigned int w, const unsigned int h)
++{
++ const unsigned int ctb_mask = ~0U << s->ps.sps->log2_ctb_size;
++ const unsigned int tb_x = x & ~ctb_mask;
++ const unsigned int tb_y = y & ~ctb_mask;
++ const unsigned int ctb_avail = lc->ctb_avail;
++
++ const uint8_t * const tb_f = tb_flags + (tb_x >> 2) + (tb_y >> 2) * 16;
++
++ unsigned int f = (ctb_avail | tb_f[0]) & (AVAIL_L | AVAIL_U | AVAIL_UL);
++
++ // This deals with both the U & L edges
++ if ((tb_x | tb_y) != 0 && (~f & (AVAIL_L | AVAIL_U)) == 0)
++ f |= AVAIL_UL;
++
++ if (x + w < lc->end_of_ctb_x)
++ f |= (tb_y == 0 ? ctb_avail >> (AVAIL_S_U - AVAIL_S_UR) : tb_f[(w - 1) >> 2]) & AVAIL_UR;
++ else if (tb_y == 0)
++ f |= (ctb_avail & AVAIL_UR);
++#if AVAIL_S_U - AVAIL_S_UR < 0
++#error Shift problem
++#endif
++
++ // Never any D if Y beyond eoctb
++ if (y + h < lc->end_of_ctb_y)
++ f |= (tb_x == 0 ? ctb_avail << (AVAIL_S_DL - AVAIL_S_L) : tb_f[((h - 1) >> 2) * 16]) & AVAIL_DL;
++#if AVAIL_S_DL - AVAIL_S_L < 0
++#error Shift problem
++#endif
++
++// printf("(%#x, %#x): %dx%d ca=%02x, ful=%02x, ftr=%02x, fdl=%02x, eox=%#x, eoy=%#x\n", x, y, w, h,
++// lc->ctb_avail, tb_f[0], tb_f[(w - 1) >> 2], tb_f[((h - 1) >> 2) * 16],
++// lc->end_of_ctb_x, lc->end_of_ctb_y);
++
++ return f;
++}
++
++#undef A0
++#undef A1
++#undef A2
++#undef A3
++#undef A4
++
++static void do_intra_pred(const HEVCRpiContext * const s, HEVCRpiLocalContext * const lc, int log2_trafo_size, int x0, int y0, int c_idx,
++ unsigned int avail)
++{
++ // If rpi_enabled then sand - U & V done on U call
++ if (c_idx <= 1)
++ {
++ HEVCPredCmd *const cmd = rpi_new_intra_cmd(lc->jb0);
++ cmd->type = RPI_PRED_INTRA + c_idx;
++ cmd->size = log2_trafo_size;
++ cmd->avail = avail;
++ cmd->i_pred.x = x0;
++ cmd->i_pred.y = y0;
++ cmd->i_pred.mode = c_idx ? lc->tu.intra_pred_mode_c : lc->tu.intra_pred_mode;
++
++// printf("(%#x, %#x) c_idx=%d, s=%d, a=%#x\n", x0, y0, c_idx, 1 << log2_trafo_size, avail);
++ }
++}
++
++#define CBF_CB0_S 0
++#define CBF_CB1_S 1 // CB1 must be CB0 + 1
++#define CBF_CR0_S 2
++#define CBF_CR1_S 3
++
++#define CBF_CB0 (1 << CBF_CB0_S)
++#define CBF_CR0 (1 << CBF_CR0_S)
++#define CBF_CB1 (1 << CBF_CB1_S)
++#define CBF_CR1 (1 << CBF_CR1_S)
++
++// * Only good for chroma_idx == 1
++static int hls_transform_unit(const HEVCRpiContext * const s, HEVCRpiLocalContext * const lc,
++ const unsigned int x0, const unsigned int y0,
++ const unsigned int log2_cb_size, const unsigned int log2_trafo_size,
++ const unsigned int blk_idx, const int cbf_luma,
++ const unsigned int const cbf_chroma)
++{
++ const unsigned int log2_trafo_size_c = FFMAX(2, log2_trafo_size - 1);
++ const unsigned int x0_c = x0 & ~7;
++ const unsigned int y0_c = y0 & ~7;
++
++ enum ScanType scan_idx = SCAN_DIAG;
++ enum ScanType scan_idx_c = SCAN_DIAG;
++
++ if (lc->cu.pred_mode == MODE_INTRA)
++ {
++ const unsigned int trafo_size = 1 << log2_trafo_size;
++ const unsigned int avail = ff_hevc_rpi_tb_avail_flags(s, lc, x0, y0, trafo_size, trafo_size);
++
++ do_intra_pred(s, lc, log2_trafo_size, x0, y0, 0, avail);
++
++ if (log2_trafo_size > 2)
++ do_intra_pred(s, lc, log2_trafo_size_c, x0_c, y0_c, 1, avail);
++ else if (blk_idx == 3)
++ do_intra_pred(s, lc, log2_trafo_size_c, x0_c, y0_c, 1,
++ ff_hevc_rpi_tb_avail_flags(s, lc, x0_c, y0_c, 8, 8));
++
++ if (log2_trafo_size < 4) {
++ if (lc->tu.intra_pred_mode >= 6 &&
++ lc->tu.intra_pred_mode <= 14) {
++ scan_idx = SCAN_VERT;
++ } else if (lc->tu.intra_pred_mode >= 22 &&
++ lc->tu.intra_pred_mode <= 30) {
++ scan_idx = SCAN_HORIZ;
++ }
++
++ if (lc->tu.intra_pred_mode_c >= 6 &&
++ lc->tu.intra_pred_mode_c <= 14) {
++ scan_idx_c = SCAN_VERT;
++ } else if (lc->tu.intra_pred_mode_c >= 22 &&
++ lc->tu.intra_pred_mode_c <= 30) {
++ scan_idx_c = SCAN_HORIZ;
++ }
++ }
++ }
++
++ if (!cbf_luma && cbf_chroma == 0)
++ return 0;
++
++ if (lc->tu.is_cu_qp_delta_wanted)
++ {
++ const int qp_delta = ff_hevc_rpi_cu_qp_delta(lc);
++ const unsigned int cb_mask = ~0U << log2_cb_size;
++
++ if (qp_delta < -(26 + (s->ps.sps->qp_bd_offset >> 1)) ||
++ qp_delta > (25 + (s->ps.sps->qp_bd_offset >> 1)))
++ {
++ av_log(s->avctx, AV_LOG_ERROR,
++ "The cu_qp_delta %d is outside the valid range "
++ "[%d, %d].\n",
++ qp_delta,
++ -(26 + (s->ps.sps->qp_bd_offset >> 1)),
++ (25 + (s->ps.sps->qp_bd_offset >> 1)));
++ return AVERROR_INVALIDDATA;
++ }
++
++ lc->tu.is_cu_qp_delta_wanted = 0;
++ lc->tu.cu_qp_delta = qp_delta;
++ ff_hevc_rpi_set_qPy(s, lc, x0 & cb_mask, y0 & cb_mask);
++ }
++
++ // * Not main profile & untested due to no conform streams
++ if (lc->tu.cu_chroma_qp_offset_wanted && cbf_chroma &&
++ !lc->cu.cu_transquant_bypass_flag) {
++ int cu_chroma_qp_offset_flag = ff_hevc_rpi_cu_chroma_qp_offset_flag(lc);
++ if (cu_chroma_qp_offset_flag) {
++ int cu_chroma_qp_offset_idx = 0;
++ if (s->ps.pps->chroma_qp_offset_list_len_minus1 > 0) {
++ cu_chroma_qp_offset_idx = ff_hevc_rpi_cu_chroma_qp_offset_idx(s, lc);
++ }
++ lc->tu.qp_divmod6[1] += s->ps.pps->cb_qp_offset_list[cu_chroma_qp_offset_idx];
++ lc->tu.qp_divmod6[2] += s->ps.pps->cr_qp_offset_list[cu_chroma_qp_offset_idx];
++ }
++ lc->tu.cu_chroma_qp_offset_wanted = 0;
++ }
++
++ if (cbf_luma)
++ ff_hevc_rpi_hls_residual_coding(s, lc, x0, y0, log2_trafo_size, scan_idx, 0);
++
++ if (log2_trafo_size > 2 || blk_idx == 3)
++ {
++ if ((cbf_chroma & CBF_CB0) != 0)
++ ff_hevc_rpi_hls_residual_coding(s, lc, x0_c, y0_c,
++ log2_trafo_size_c, scan_idx_c, 1);
++ if ((cbf_chroma & CBF_CR0) != 0)
++ ff_hevc_rpi_hls_residual_coding(s, lc, x0_c, y0_c,
++ log2_trafo_size_c, scan_idx_c, 2);
++ }
++
++ return 0;
++}
++
++static inline void set_deblocking_bypass(const HEVCRpiContext * const s, const int x0, const int y0, const int log2_cb_size)
++{
++ set_bits(s->is_pcm + (y0 >> 3) * s->ps.sps->pcm_width, x0 >> 3, s->ps.sps->pcm_width, log2_cb_size - 3);
++}
++
++
++static int hls_transform_tree(const HEVCRpiContext * const s, HEVCRpiLocalContext * const lc,
++ const unsigned int x0, const unsigned int y0,
++ const unsigned int log2_trafo_size,
++ const unsigned int trafo_depth, const unsigned int blk_idx,
++ const unsigned int cbf_c0)
++{
++ // When trafo_size == 2 hls_transform_unit uses c0 so put in c1
++ unsigned int cbf_c1 = cbf_c0;
++ int split_transform_flag;
++ int ret;
++
++ if (lc->cu.intra_split_flag) {
++ if (trafo_depth == 1) {
++ lc->tu.intra_pred_mode = lc->pu.intra_pred_mode[blk_idx];
++ if (ctx_cfmt(s) == 3) {
++ lc->tu.intra_pred_mode_c = lc->pu.intra_pred_mode_c[blk_idx];
++ lc->tu.chroma_mode_c = lc->pu.chroma_mode_c[blk_idx];
++ } else {
++ lc->tu.intra_pred_mode_c = lc->pu.intra_pred_mode_c[0];
++ lc->tu.chroma_mode_c = lc->pu.chroma_mode_c[0];
++ }
++ }
++ } else {
++ lc->tu.intra_pred_mode = lc->pu.intra_pred_mode[0];
++ lc->tu.intra_pred_mode_c = lc->pu.intra_pred_mode_c[0];
++ lc->tu.chroma_mode_c = lc->pu.chroma_mode_c[0];
++ }
++
++ if (log2_trafo_size <= s->ps.sps->log2_max_trafo_size &&
++ log2_trafo_size > s->ps.sps->log2_min_tb_size &&
++ trafo_depth < lc->cu.max_trafo_depth &&
++ !(lc->cu.intra_split_flag && trafo_depth == 0))
++ {
++ split_transform_flag = ff_hevc_rpi_split_transform_flag_decode(lc, log2_trafo_size);
++ } else {
++ int inter_split = s->ps.sps->max_transform_hierarchy_depth_inter == 0 &&
++ lc->cu.pred_mode == MODE_INTER &&
++ lc->cu.part_mode != PART_2Nx2N &&
++ trafo_depth == 0;
++
++ split_transform_flag = log2_trafo_size > s->ps.sps->log2_max_trafo_size ||
++ (lc->cu.intra_split_flag && trafo_depth == 0) ||
++ inter_split;
++ }
++
++ if (log2_trafo_size > 2 || ctx_cfmt(s) == 3)
++ {
++ const int wants_c1 = ctx_cfmt(s) == 2 && (!split_transform_flag || log2_trafo_size == 3);
++ cbf_c1 = 0;
++
++ if ((cbf_c0 & CBF_CB0) != 0)
++ {
++ cbf_c1 = ff_hevc_rpi_cbf_cb_cr_decode(lc, trafo_depth) << CBF_CB0_S;
++ if (wants_c1)
++ cbf_c1 |= ff_hevc_rpi_cbf_cb_cr_decode(lc, trafo_depth) << CBF_CB1_S;
++ }
++
++ if ((cbf_c0 & CBF_CR0) != 0)
++ {
++ cbf_c1 |= ff_hevc_rpi_cbf_cb_cr_decode(lc, trafo_depth) << CBF_CR0_S;
++ if (wants_c1)
++ cbf_c1 |= ff_hevc_rpi_cbf_cb_cr_decode(lc, trafo_depth) << CBF_CR1_S;
++ }
++ }
++
++ if (split_transform_flag) {
++ const int trafo_size_split = 1 << (log2_trafo_size - 1);
++ const int x1 = x0 + trafo_size_split;
++ const int y1 = y0 + trafo_size_split;
++
++#define SUBDIVIDE(x, y, idx) \
++do { \
++ ret = hls_transform_tree(s, lc, x, y, \
++ log2_trafo_size - 1, trafo_depth + 1, idx, \
++ cbf_c1); \
++ if (ret < 0) \
++ return ret; \
++} while (0)
++
++ SUBDIVIDE(x0, y0, 0);
++ SUBDIVIDE(x1, y0, 1);
++ SUBDIVIDE(x0, y1, 2);
++ SUBDIVIDE(x1, y1, 3);
++
++#undef SUBDIVIDE
++ } else {
++ // If trafo_size == 2 then we should have cbf_c == 0 here but as we can't have
++ // trafo_size == 2 with depth == 0 the issue is moot
++ const int cbf_luma = ((lc->cu.pred_mode != MODE_INTRA && trafo_depth == 0 && cbf_c1 == 0) ||
++ ff_hevc_rpi_cbf_luma_decode(lc, trafo_depth));
++
++ ret = hls_transform_unit(s, lc, x0, y0,
++ log2_trafo_size + trafo_depth, log2_trafo_size,
++ blk_idx, cbf_luma, cbf_c1);
++ if (ret < 0)
++ return ret;
++
++ if (!s->sh.disable_deblocking_filter_flag) {
++ ff_hevc_rpi_deblocking_boundary_strengths(s, lc, x0, y0, log2_trafo_size, cbf_luma);
++ }
++ }
++ return 0;
++}
++
++
++static int pcm_extract(const HEVCRpiContext * const s, const uint8_t * pcm, const int length, const int x0, const int y0, const int cb_size)
++{
++ GetBitContext gb;
++ int ret;
++
++ ret = init_get_bits(&gb, pcm, length);
++ if (ret < 0)
++ return ret;
++
++ s->hevcdsp.put_pcm(av_rpi_sand_frame_pos_y(s->frame, x0, y0),
++ frame_stride1(s->frame, 0),
++ cb_size, cb_size, &gb, s->ps.sps->pcm.bit_depth);
++
++ s->hevcdsp.put_pcm_c(av_rpi_sand_frame_pos_c(s->frame, x0 >> ctx_hshift(s, 1), y0 >> ctx_vshift(s, 1)),
++ s->frame->linesize[1],
++ cb_size >> ctx_hshift(s, 1),
++ cb_size >> ctx_vshift(s, 1),
++ &gb, s->ps.sps->pcm.bit_depth_chroma);
++
++ return 0;
++}
++
++
++// x * 2^(y*2)
++static inline unsigned int xyexp2(const unsigned int x, const unsigned int y)
++{
++ return x << (y * 2);
++}
++
++static int hls_pcm_sample(const HEVCRpiContext * const s, HEVCRpiLocalContext * const lc, const int x0, const int y0, unsigned int log2_cb_size)
++{
++ // Length in bits
++ const unsigned int length = xyexp2(s->ps.sps->pcm.bit_depth, log2_cb_size) +
++ xyexp2(s->ps.sps->pcm.bit_depth_chroma, log2_cb_size - ctx_vshift(s, 1)) +
++ xyexp2(s->ps.sps->pcm.bit_depth_chroma, log2_cb_size - ctx_vshift(s, 2));
++
++ const uint8_t * const pcm = ff_hevc_rpi_cabac_skip_bytes(&lc->cc, (length + 7) >> 3);
++
++ if (!s->sh.disable_deblocking_filter_flag)
++ ff_hevc_rpi_deblocking_boundary_strengths(s, lc, x0, y0, log2_cb_size, 0);
++
++ // Copy coeffs
++ {
++ const int blen = (length + 7) >> 3;
++ // Round allocated bytes up to nearest 32 to avoid alignment confusion
++ // Allocation is in int16_t s
++ // As we are only using 1 byte per sample and the coeff buffer allows 2 per
++ // sample this rounding doesn't affect the total size we need to allocate for
++ // the coeff buffer
++ int16_t * const coeffs = rpi_alloc_coeff_buf(lc->jb0, 0, ((blen + 31) & ~31) >> 1);
++ memcpy(coeffs, pcm, blen);
++
++ // Our coeff stash assumes that any partially allocated 64byte lump
++ // is zeroed so make that true.
++ {
++ uint8_t * const eopcm = (uint8_t *)coeffs + blen;
++ if ((-(intptr_t)eopcm & 63) != 0)
++ memset(eopcm, 0, -(intptr_t)eopcm & 63);
++ }
++
++ // Add command
++ {
++ HEVCPredCmd *const cmd = rpi_new_intra_cmd(lc->jb0);
++ cmd->type = RPI_PRED_I_PCM;
++ cmd->size = log2_cb_size;
++ cmd->i_pcm.src = coeffs;
++ cmd->i_pcm.x = x0;
++ cmd->i_pcm.y = y0;
++ cmd->i_pcm.src_len = length;
++ }
++ return 0;
++ }
++}
++
++
++static void hevc_await_progress(const HEVCRpiContext * const s, HEVCRpiLocalContext * const lc, const HEVCRpiFrame * const ref,
++ const MvXY xy, const int y0, const int height)
++{
++ if (s->threads_type != 0) {
++ const int y = FFMAX(0, (MV_Y(xy) >> 2) + y0 + height + 9);
++
++ // Progress has to be attached to current job as the actual wait
++ // is in worker_core which can't use lc
++ int16_t *const pr = lc->jb0->progress_req + ref->dpb_no;
++ if (*pr < y) {
++ *pr = y;
++ }
++ }
++}
++
++static void hevc_luma_mv_mvp_mode(const HEVCRpiContext * const s, HEVCRpiLocalContext * const lc,
++ const int x0, const int y0, const int nPbW,
++ const int nPbH,
++ HEVCRpiMvField * const mv)
++{
++ enum InterPredIdc inter_pred_idc = PRED_L0;
++ int mvp_flag;
++ const unsigned int avail = ff_hevc_rpi_tb_avail_flags(s, lc, x0, y0, nPbW, nPbH);
++
++ mv->pred_flag = 0;
++ if (s->sh.slice_type == HEVC_SLICE_B)
++ inter_pred_idc = ff_hevc_rpi_inter_pred_idc_decode(lc, nPbW, nPbH);
++
++ if (inter_pred_idc != PRED_L1) {
++ MvXY mvd;
++
++ if (s->sh.nb_refs[L0])
++ mv->ref_idx[0]= ff_hevc_rpi_ref_idx_lx_decode(lc, s->sh.nb_refs[L0]);
++
++ mv->pred_flag = PF_L0;
++ mvd = ff_hevc_rpi_hls_mvd_coding(lc);
++ mvp_flag = ff_hevc_rpi_mvp_lx_flag_decode(lc);
++ ff_hevc_rpi_luma_mv_mvp_mode(s, lc, x0, y0, nPbW, nPbH, avail,
++ mv, mvp_flag, 0);
++ mv->xy[0] = mvxy_add(mv->xy[0], mvd);
++ }
++
++ if (inter_pred_idc != PRED_L0) {
++ MvXY mvd = 0;
++
++ if (s->sh.nb_refs[L1])
++ mv->ref_idx[1] = ff_hevc_rpi_ref_idx_lx_decode(lc, s->sh.nb_refs[L1]);
++
++ if (s->sh.mvd_l1_zero_flag != 1 || inter_pred_idc != PRED_BI)
++ mvd = ff_hevc_rpi_hls_mvd_coding(lc);
++
++ mv->pred_flag += PF_L1;
++ mvp_flag = ff_hevc_rpi_mvp_lx_flag_decode(lc);
++ ff_hevc_rpi_luma_mv_mvp_mode(s, lc, x0, y0, nPbW, nPbH, avail,
++ mv, mvp_flag, 1);
++ mv->xy[1] = mvxy_add(mv->xy[1], mvd);
++ }
++}
++
++
++static HEVCRpiInterPredQ *
++rpi_nxt_pred(HEVCRpiInterPredEnv * const ipe, const unsigned int load_val, const uint32_t fn)
++{
++ HEVCRpiInterPredQ * yp = NULL;
++ HEVCRpiInterPredQ * ypt = ipe->q + ipe->curr;
++ const unsigned int max_fill = ipe->max_fill;
++ unsigned int load = UINT_MAX;
++
++ for (unsigned int i = 0; i != ipe->n_grp; ++i, ++ypt) {
++ // We will always have enough room between the Qs but if we are
++ // running critically low due to poor scheduling then use fill size
++ // rather than load to determine QPU. This has obvious dire
++ // performance implications but (a) it is better than crashing
++ // and (b) it should (almost) never happen
++ const unsigned int tfill = (char *)ypt->qpu_mc_curr - (char *)ypt->qpu_mc_base;
++ const unsigned int tload = tfill > max_fill ? tfill + 0x1000000 : ypt->load;
++
++ if (tload < load)
++ {
++ yp = ypt;
++ load = tload;
++ }
++ }
++
++ yp->load += load_val;
++ ipe->used_grp = 1;
++ yp->qpu_mc_curr->data[-1] = fn; // Link is always last el of previous cmd
++
++ return yp;
++}
++
++
++static void rpi_inter_pred_sync(HEVCRpiInterPredEnv * const ipe)
++{
++ for (unsigned int i = 0; i != ipe->n; ++i) {
++ HEVCRpiInterPredQ * const q = ipe->q + i;
++ const unsigned int qfill = (char *)q->qpu_mc_curr - (char *)q->qpu_mc_base;
++
++ q->qpu_mc_curr->data[-1] = q->code_sync;
++ q->qpu_mc_curr = (qpu_mc_pred_cmd_t *)(q->qpu_mc_curr->data + 1);
++ q->load = (qfill >> 7); // Have a mild preference for emptier Qs to balance memory usage
++ }
++}
++
++// Returns 0 on success
++// We no longer check for Q fullness as wew have emergncy code in ctu alloc
++// * However it might be an idea to have some means of spotting that we've used it
++static int rpi_inter_pred_next_ctu(HEVCRpiInterPredEnv * const ipe)
++{
++ if (!ipe->used_grp)
++ return 0;
++
++ if ((ipe->curr += ipe->n_grp) >= ipe->n)
++ {
++ ipe->curr = 0;
++ rpi_inter_pred_sync(ipe);
++ }
++ ipe->used = 1;
++ ipe->used_grp = 0;
++
++ return 0;
++}
++
++static void rpi_inter_pred_reset(HEVCRpiInterPredEnv * const ipe)
++{
++ unsigned int i;
++
++ ipe->curr = 0;
++ ipe->used = 0;
++ ipe->used_grp = 0;
++ for (i = 0; i != ipe->n; ++i) {
++ HEVCRpiInterPredQ * const q = ipe->q + i;
++ q->qpu_mc_curr = q->qpu_mc_base;
++ q->load = 0;
++ q->last_l0 = NULL;
++ q->last_l1 = NULL;
++ }
++}
++
++static void rpi_inter_pred_alloc(HEVCRpiInterPredEnv * const ipe,
++ const unsigned int n_max, const unsigned int n_grp,
++ const unsigned int total_size, const unsigned int min_gap)
++{
++ memset(ipe, 0, sizeof(*ipe));
++ av_assert0((ipe->q = av_mallocz(n_max * sizeof(*ipe->q))) != NULL);
++ ipe->n_grp = n_grp;
++ ipe->min_gap = min_gap;
++
++ gpu_malloc_cached(total_size, &ipe->gptr);
++}
++
++
++#if RPI_QPU_EMU_Y
++#define get_mc_address_y(f) ((f)->data[0])
++#else
++#define get_mc_address_y(f) get_vc_address_y(f)
++#endif
++#if RPI_QPU_EMU_C
++#define get_mc_address_u(f) ((f)->data[1])
++#else
++#define get_mc_address_u(f) get_vc_address_u(f)
++#endif
++
++static inline uint32_t pack_wo_p(const int off, const int mul)
++{
++ return PACK2(off * 2 + 1, mul);
++}
++
++static inline uint32_t pack_wo_b(const int off0, const int off1, const int mul)
++{
++ return PACK2(off0 + off1 + 1, mul);
++}
++
++
++static void
++rpi_pred_y(const HEVCRpiContext *const s, HEVCRpiJob * const jb,
++ const int x0, const int y0,
++ const int nPbW, const int nPbH,
++ const MvXY mv_xy,
++ const int weight_mul,
++ const int weight_offset,
++ AVFrame *const src_frame)
++{
++ const unsigned int y_off = av_rpi_sand_frame_off_y(s->frame, x0, y0);
++ const unsigned int mx = MV_X(mv_xy) & 3;
++ const unsigned int my = MV_Y(mv_xy) & 3;
++ const unsigned int my_mx = (my << 8) | mx;
++ const uint32_t my2_mx2_my_mx = (my_mx << 16) | my_mx;
++ const qpu_mc_src_addr_t src_vc_address_y = get_mc_address_y(src_frame);
++ qpu_mc_dst_addr_t dst_addr = get_mc_address_y(s->frame) + y_off;
++ const uint32_t wo = pack_wo_p(weight_offset, weight_mul);
++ HEVCRpiInterPredEnv * const ipe = &jb->luma_ip;
++ const unsigned int xshl = av_rpi_sand_frame_xshl(s->frame);
++
++ if (my_mx == 0)
++ {
++ const int x1 = x0 + (MV_X(mv_xy) >> 2);
++ const int y1 = y0 + (MV_Y(mv_xy) >> 2);
++ const int bh = nPbH;
++
++ for (int start_x = 0; start_x < nPbW; start_x += 16)
++ {
++ const int bw = FFMIN(nPbW - start_x, 16);
++ HEVCRpiInterPredQ *const yp = rpi_nxt_pred(ipe, bh, s->qpu.y_p00);
++ qpu_mc_src_t *const src1 = yp->last_l0;
++ qpu_mc_pred_y_p00_t *const cmd_y = &yp->qpu_mc_curr->y.p00;
++
++#if RPI_TSTATS
++ {
++ HEVCRpiStats *const ts = (HEVCRpiStats *)&s->tstats;
++ ++ts->y_pred1_x0y0;
++
++ if (nPbW > 8)
++ ++ts->y_pred1_wgt8;
++ else
++ ++ts->y_pred1_wle8;
++
++ if (nPbH > 16)
++ ++ts->y_pred1_hgt16;
++ else
++ ++ts->y_pred1_hle16;
++ }
++#endif
++
++ src1->x = x1 + start_x;
++ src1->y = y1;
++ src1->base = src_vc_address_y;
++ cmd_y->w = bw;
++ cmd_y->h = bh;
++ cmd_y->wo1 = wo;
++ cmd_y->dst_addr = dst_addr + (start_x << xshl);
++ yp->last_l0 = &cmd_y->next_src1;
++ yp->qpu_mc_curr = (qpu_mc_pred_cmd_t *)(cmd_y + 1);
++ }
++ }
++ else
++ {
++ const int x1_m3 = x0 + (MV_X(mv_xy) >> 2) - 3;
++ const int y1_m3 = y0 + (MV_Y(mv_xy) >> 2) - 3;
++ const unsigned int bh = nPbH;
++ int start_x = 0;
++
++#if 1
++ // As Y-pred operates on two independant 8-wide src blocks we can merge
++ // this pred with the previous one if it the previous one is 8 pel wide,
++ // the same height as the current block, immediately to the left of our
++ // current dest block and mono-pred.
++
++ qpu_mc_pred_y_p_t *const last_y8_p = jb->last_y8_p;
++ if (last_y8_p != NULL && last_y8_p->h == bh && last_y8_p->dst_addr + (8 << xshl) == dst_addr)
++ {
++ const int bw = FFMIN(nPbW, 8);
++ qpu_mc_src_t *const last_y8_src2 = jb->last_y8_l1;
++
++ last_y8_src2->x = x1_m3;
++ last_y8_src2->y = y1_m3;
++ last_y8_src2->base = src_vc_address_y;
++ last_y8_p->w += bw;
++ last_y8_p->mymx21 = PACK2(my2_mx2_my_mx, last_y8_p->mymx21);
++ last_y8_p->wo2 = wo;
++
++ jb->last_y8_p = NULL;
++ jb->last_y8_l1 = NULL;
++ start_x = bw;
++#if RPI_TSTATS
++ ++((HEVCRpiStats *)&s->tstats)->y_pred1_y8_merge;
++#endif
++ }
++#endif
++
++ for (; start_x < nPbW; start_x += 16)
++ {
++ const int bw = FFMIN(nPbW - start_x, 16);
++ HEVCRpiInterPredQ *const yp = rpi_nxt_pred(ipe, bh + 7, s->qpu.y_pxx);
++ qpu_mc_src_t *const src1 = yp->last_l0;
++ qpu_mc_src_t *const src2 = yp->last_l1;
++ qpu_mc_pred_y_p_t *const cmd_y = &yp->qpu_mc_curr->y.p;
++#if RPI_TSTATS
++ {
++ HEVCRpiStats *const ts = (HEVCRpiStats *)&s->tstats;
++ if (mx == 0 && my == 0)
++ ++ts->y_pred1_x0y0;
++ else if (mx == 0)
++ ++ts->y_pred1_x0;
++ else if (my == 0)
++ ++ts->y_pred1_y0;
++ else
++ ++ts->y_pred1_xy;
++
++ if (nPbW > 8)
++ ++ts->y_pred1_wgt8;
++ else
++ ++ts->y_pred1_wle8;
++
++ if (nPbH > 16)
++ ++ts->y_pred1_hgt16;
++ else
++ ++ts->y_pred1_hle16;
++ }
++#endif
++ src1->x = x1_m3 + start_x;
++ src1->y = y1_m3;
++ src1->base = src_vc_address_y;
++ if (bw <= 8)
++ {
++ src2->x = MC_DUMMY_X;
++ src2->y = MC_DUMMY_Y;
++#if RPI_QPU_EMU_Y
++ src2->base = s->qpu_dummy_frame_emu;
++#else
++ src2->base = s->qpu_dummy_frame_qpu;
++#endif
++ }
++ else
++ {
++ src2->x = x1_m3 + start_x + 8;
++ src2->y = y1_m3;
++ src2->base = src_vc_address_y;
++ }
++ cmd_y->w = bw;
++ cmd_y->h = bh;
++ cmd_y->mymx21 = my2_mx2_my_mx;
++ cmd_y->wo1 = wo;
++ cmd_y->wo2 = wo;
++ cmd_y->dst_addr = dst_addr + (start_x << xshl);
++ yp->last_l0 = &cmd_y->next_src1;
++ yp->last_l1 = &cmd_y->next_src2;
++ yp->qpu_mc_curr = (qpu_mc_pred_cmd_t *)(cmd_y + 1);
++
++ if (bw == 8) {
++ jb->last_y8_l1 = src2;
++ jb->last_y8_p = cmd_y;
++ }
++ }
++ }
++}
++
++static void
++rpi_pred_y_b(const HEVCRpiContext * const s, HEVCRpiJob * const jb,
++ const int x0, const int y0,
++ const int nPbW, const int nPbH,
++ const struct HEVCRpiMvField *const mv_field,
++ const AVFrame *const src_frame,
++ const AVFrame *const src_frame2)
++{
++ const unsigned int y_off = av_rpi_sand_frame_off_y(s->frame, x0, y0);
++ const MvXY const mv = mv_field->xy[0];
++ const MvXY const mv2 = mv_field->xy[1];
++
++ const unsigned int mx = MV_X(mv) & 3;
++ const unsigned int my = MV_Y(mv) & 3;
++ const unsigned int my_mx = (my<<8) | mx;
++ const unsigned int mx2 = MV_X(mv2) & 3;
++ const unsigned int my2 = MV_Y(mv2) & 3;
++ const unsigned int my2_mx2 = (my2<<8) | mx2;
++ const uint32_t my2_mx2_my_mx = (my2_mx2 << 16) | my_mx;
++ const unsigned int ref_idx0 = mv_field->ref_idx[0];
++ const unsigned int ref_idx1 = mv_field->ref_idx[1];
++ const uint32_t wo1 = pack_wo_b(s->sh.luma_offset_l0[ref_idx0], s->sh.luma_offset_l1[ref_idx1], s->sh.luma_weight_l0[ref_idx0]);
++ const uint32_t wo2 = pack_wo_b(s->sh.luma_offset_l0[ref_idx0], s->sh.luma_offset_l1[ref_idx1], s->sh.luma_weight_l1[ref_idx1]);
++
++ const unsigned int xshl = av_rpi_sand_frame_xshl(s->frame);
++ qpu_mc_dst_addr_t dst = get_mc_address_y(s->frame) + y_off;
++ const qpu_mc_src_addr_t src1_base = get_mc_address_y(src_frame);
++ const qpu_mc_src_addr_t src2_base = get_mc_address_y(src_frame2);
++ HEVCRpiInterPredEnv * const ipe = &jb->luma_ip;
++
++ if (my2_mx2_my_mx == 0)
++ {
++ const int x1 = x0 + (MV_X(mv) >> 2);
++ const int y1 = y0 + (MV_Y(mv) >> 2);
++ const int x2 = x0 + (MV_X(mv2) >> 2);
++ const int y2 = y0 + (MV_Y(mv2) >> 2);
++ const int bh = nPbH;
++
++ // Can do chunks a full 16 wide if we don't want the H filter
++ for (int start_x=0; start_x < nPbW; start_x += 16)
++ {
++ HEVCRpiInterPredQ *const yp = rpi_nxt_pred(ipe, bh, s->qpu.y_b00);
++ qpu_mc_src_t *const src1 = yp->last_l0;
++ qpu_mc_src_t *const src2 = yp->last_l1;
++ qpu_mc_pred_y_p_t *const cmd_y = &yp->qpu_mc_curr->y.p;
++#if RPI_TSTATS
++ {
++ HEVCRpiStats *const ts = (HEVCRpiStats *)&s->tstats;
++ ++ts->y_pred2_x0y0;
++
++ if (nPbH > 16)
++ ++ts->y_pred2_hgt16;
++ else
++ ++ts->y_pred2_hle16;
++ }
++#endif
++ src1->x = x1 + start_x;
++ src1->y = y1;
++ src1->base = src1_base;
++ src2->x = x2 + start_x;
++ src2->y = y2;
++ src2->base = src2_base;
++ cmd_y->w = FFMIN(nPbW - start_x, 16);
++ cmd_y->h = bh;
++ cmd_y->mymx21 = 0;
++ cmd_y->wo1 = wo1;
++ cmd_y->wo2 = wo2;
++ cmd_y->dst_addr = dst + (start_x << xshl);
++ yp->last_l0 = &cmd_y->next_src1;
++ yp->last_l1 = &cmd_y->next_src2;
++ yp->qpu_mc_curr = (qpu_mc_pred_cmd_t *)(cmd_y + 1);
++ }
++ }
++ else
++ {
++ // Filter requires a run-up of 3
++ const int x1 = x0 + (MV_X(mv) >> 2) - 3;
++ const int y1 = y0 + (MV_Y(mv) >> 2) - 3;
++ const int x2 = x0 + (MV_X(mv2) >> 2) - 3;
++ const int y2 = y0 + (MV_Y(mv2) >> 2) - 3;
++ const int bh = nPbH;
++
++ for (int start_x=0; start_x < nPbW; start_x += 8)
++ { // B blocks work 8 at a time
++ // B weights aren't doubled as the QPU code does the same
++ // amount of work as it does for P
++ HEVCRpiInterPredQ *const yp = rpi_nxt_pred(ipe, bh + 7, s->qpu.y_bxx);
++ qpu_mc_src_t *const src1 = yp->last_l0;
++ qpu_mc_src_t *const src2 = yp->last_l1;
++ qpu_mc_pred_y_p_t *const cmd_y = &yp->qpu_mc_curr->y.p;
++#if RPI_TSTATS
++ {
++ HEVCRpiStats *const ts = (HEVCRpiStats *)&s->tstats;
++ const unsigned int mmx = mx | mx2;
++ const unsigned int mmy = my | my2;
++ if (mmx == 0 && mmy == 0)
++ ++ts->y_pred2_x0y0;
++ else if (mmx == 0)
++ ++ts->y_pred2_x0;
++ else if (mmy == 0)
++ ++ts->y_pred2_y0;
++ else
++ ++ts->y_pred2_xy;
++
++ if (nPbH > 16)
++ ++ts->y_pred2_hgt16;
++ else
++ ++ts->y_pred2_hle16;
++ }
++#endif
++ src1->x = x1 + start_x;
++ src1->y = y1;
++ src1->base = src1_base;
++ src2->x = x2 + start_x;
++ src2->y = y2;
++ src2->base = src2_base;
++ cmd_y->w = FFMIN(nPbW - start_x, 8);
++ cmd_y->h = bh;
++ cmd_y->mymx21 = my2_mx2_my_mx;
++ cmd_y->wo1 = wo1;
++ cmd_y->wo2 = wo2;
++ cmd_y->dst_addr = dst + (start_x << xshl);
++ yp->last_l0 = &cmd_y->next_src1;
++ yp->last_l1 = &cmd_y->next_src2;
++ yp->qpu_mc_curr = (qpu_mc_pred_cmd_t *)(cmd_y + 1);
++ }
++ }
++}
++
++// h/v shifts fixed at one as that is all the qasm copes with
++static void
++rpi_pred_c(const HEVCRpiContext * const s, HEVCRpiJob * const jb,
++ const unsigned int lx, const int x0_c, const int y0_c,
++ const int nPbW_c, const int nPbH_c,
++ const MvXY const mv,
++ const int16_t * const c_weights,
++ const int16_t * const c_offsets,
++ AVFrame * const src_frame)
++{
++ const unsigned int c_off = av_rpi_sand_frame_off_c(s->frame, x0_c, y0_c);
++ const int hshift = 1; // = s->ps.sps->hshift[1];
++ const int vshift = 1; // = s->ps.sps->vshift[1];
++
++ const int x1_c = x0_c + (MV_X(mv) >> (2 + hshift)) - 1;
++ const int y1_c = y0_c + (MV_Y(mv) >> (2 + hshift)) - 1;
++ const qpu_mc_src_addr_t src_base_u = get_mc_address_u(src_frame);
++ const uint32_t x_coeffs = rpi_filter_coefs[av_mod_uintp2(MV_X(mv), 2 + hshift) << (1 - hshift)];
++ const uint32_t y_coeffs = rpi_filter_coefs[av_mod_uintp2(MV_Y(mv), 2 + vshift) << (1 - vshift)];
++ const uint32_t wo_u = pack_wo_p(c_offsets[0], c_weights[0]);
++ const uint32_t wo_v = pack_wo_p(c_offsets[1], c_weights[1]);
++ qpu_mc_dst_addr_t dst_base_u = get_mc_address_u(s->frame) + c_off;
++ HEVCRpiInterPredEnv * const ipe = &jb->chroma_ip;
++ const unsigned int xshl = av_rpi_sand_frame_xshl(s->frame) + 1;
++ const unsigned int bh = nPbH_c;
++ const uint32_t qfn = lx == 0 ? s->qpu.c_pxx : s->qpu.c_pxx_l1;
++
++ for(int start_x=0; start_x < nPbW_c; start_x+=RPI_CHROMA_BLOCK_WIDTH)
++ {
++ HEVCRpiInterPredQ * const cp = rpi_nxt_pred(ipe, bh + 3, qfn);
++ qpu_mc_pred_c_p_t * const cmd_c = &cp->qpu_mc_curr->c.p;
++ qpu_mc_src_t ** const plast_lx = (lx == 0) ? &cp->last_l0 : &cp->last_l1;
++ qpu_mc_src_t * const last_lx = *plast_lx;
++ const int bw = FFMIN(nPbW_c-start_x, RPI_CHROMA_BLOCK_WIDTH);
++
++ last_lx->x = x1_c + start_x;
++ last_lx->y = y1_c;
++ last_lx->base = src_base_u;
++ cmd_c->h = bh;
++ cmd_c->w = bw;
++ cmd_c->coeffs_x = x_coeffs;
++ cmd_c->coeffs_y = y_coeffs;
++ cmd_c->wo_u = wo_u;
++ cmd_c->wo_v = wo_v;
++ cmd_c->dst_addr_c = dst_base_u + (start_x << xshl);
++ *plast_lx = &cmd_c->next_src;
++ cp->qpu_mc_curr = (qpu_mc_pred_cmd_t *)(cmd_c + 1);
++ }
++ return;
++}
++
++// h/v shifts fixed at one as that is all the qasm copes with
++static void
++rpi_pred_c_b(const HEVCRpiContext * const s, HEVCRpiJob * const jb,
++ const int x0_c, const int y0_c,
++ const int nPbW_c, const int nPbH_c,
++ const struct HEVCRpiMvField * const mv_field,
++ const int16_t * const c_weights,
++ const int16_t * const c_offsets,
++ const int16_t * const c_weights2,
++ const int16_t * const c_offsets2,
++ AVFrame * const src_frame,
++ AVFrame * const src_frame2)
++{
++ const unsigned int c_off = av_rpi_sand_frame_off_c(s->frame, x0_c, y0_c);
++ const int hshift = 1; // s->ps.sps->hshift[1];
++ const int vshift = 1; // s->ps.sps->vshift[1];
++ const MvXY const mv = mv_field->xy[0];
++ const MvXY const mv2 = mv_field->xy[1];
++
++ const unsigned int mx = av_mod_uintp2(MV_X(mv), 2 + hshift);
++ const unsigned int my = av_mod_uintp2(MV_Y(mv), 2 + vshift);
++ const uint32_t coefs0_x = rpi_filter_coefs[mx << (1 - hshift)];
++ const uint32_t coefs0_y = rpi_filter_coefs[my << (1 - vshift)]; // Fractional part of motion vector
++ const int x1_c = x0_c + (MV_X(mv) >> (2 + hshift)) - 1;
++ const int y1_c = y0_c + (MV_Y(mv) >> (2 + hshift)) - 1;
++
++ const unsigned int mx2 = av_mod_uintp2(MV_X(mv2), 2 + hshift);
++ const unsigned int my2 = av_mod_uintp2(MV_Y(mv2), 2 + vshift);
++ const uint32_t coefs1_x = rpi_filter_coefs[mx2 << (1 - hshift)];
++ const uint32_t coefs1_y = rpi_filter_coefs[my2 << (1 - vshift)]; // Fractional part of motion vector
++
++ const int x2_c = x0_c + (MV_X(mv2) >> (2 + hshift)) - 1;
++ const int y2_c = y0_c + (MV_Y(mv2) >> (2 + hshift)) - 1;
++
++ const uint32_t wo_u2 = pack_wo_b(c_offsets[0], c_offsets2[0], c_weights2[0]);
++ const uint32_t wo_v2 = pack_wo_b(c_offsets[1], c_offsets2[1], c_weights2[1]);
++
++ const qpu_mc_dst_addr_t dst_base_u = get_mc_address_u(s->frame) + c_off;
++ const qpu_mc_src_addr_t src1_base = get_mc_address_u(src_frame);
++ const qpu_mc_src_addr_t src2_base = get_mc_address_u(src_frame2);
++ HEVCRpiInterPredEnv * const ipe = &jb->chroma_ip;
++ const unsigned int xshl = av_rpi_sand_frame_xshl(s->frame) + 1;
++ const unsigned int bh = nPbH_c;
++
++ for (int start_x=0; start_x < nPbW_c; start_x += RPI_CHROMA_BLOCK_WIDTH)
++ {
++ const unsigned int bw = FFMIN(nPbW_c-start_x, RPI_CHROMA_BLOCK_WIDTH);
++
++ HEVCRpiInterPredQ * const cp = rpi_nxt_pred(ipe, bh * 2 + 3, s->qpu.c_bxx);
++ qpu_mc_pred_c_b_t * const u = &cp->qpu_mc_curr->c.b;
++ qpu_mc_src_t * const src_l0 = cp->last_l0;
++ qpu_mc_src_t * const src_l1 = cp->last_l1;
++
++ src_l0->x = x1_c + start_x;
++ src_l0->y = y1_c;
++ src_l0->base = src1_base;
++ src_l1->x = x2_c + start_x;
++ src_l1->y = y2_c;
++ src_l1->base = src2_base;
++
++ u[0].h = bh;
++ u[0].w = bw;
++ u[0].coeffs_x1 = coefs0_x;
++ u[0].coeffs_y1 = coefs0_y;
++ u[0].weight_u1 = c_weights[0]; // Weight L0 U
++ u[0].weight_v1 = c_weights[1]; // Weight L0 V
++ u[0].coeffs_x2 = coefs1_x;
++ u[0].coeffs_y2 = coefs1_y;
++ u[0].wo_u2 = wo_u2;
++ u[0].wo_v2 = wo_v2;
++ u[0].dst_addr_c = dst_base_u + (start_x << xshl);
++
++ cp->last_l0 = &u[0].next_src1;
++ cp->last_l1 = &u[0].next_src2;
++ cp->qpu_mc_curr = (qpu_mc_pred_cmd_t *)(u + 1);
++ }
++}
++
++
++static inline void
++col_stash(const HEVCRpiContext * const s,
++ const unsigned int x0, const unsigned int y0, const unsigned int w0, const unsigned int h0,
++ const HEVCRpiMvField * const mvf)
++{
++ ColMvField * const col_mvf = s->ref->col_mvf;
++ const unsigned int x = (x0 + 15) >> 4;
++ const unsigned int y = (y0 + 15) >> 4;
++ const unsigned int w = ((x0 + 15 + w0) >> 4) - x;
++ const unsigned int h = ((y0 + 15 + h0) >> 4) - y;
++
++ if (col_mvf != NULL && w != 0 && h != 0)
++ {
++ // Only record MV from the top left of the 16x16 block
++
++ const RefPicList * const rpl = s->refPicList;
++ const ColMvField cmv = {
++ .L = {
++ {
++ .poc = (mvf->pred_flag & PF_L0) == 0 ?
++ COL_POC_INTRA :
++ COL_POC_MAKE_INTER(rpl[0].isLongTerm[mvf->ref_idx[0]], rpl[0].list[mvf->ref_idx[0]]),
++ .xy = mvf->xy[0]
++ },
++ {
++ .poc = (mvf->pred_flag & PF_L1) == 0 ?
++ COL_POC_INTRA :
++ COL_POC_MAKE_INTER(rpl[1].isLongTerm[mvf->ref_idx[1]], rpl[1].list[mvf->ref_idx[1]]),
++ .xy = mvf->xy[1]
++ }
++ }
++ };
++
++ ColMvField * p = col_mvf + y * s->col_mvf_stride + x;
++ const unsigned int stride = s->col_mvf_stride - w;
++ unsigned int j = h;
++
++ do
++ {
++ unsigned int k = w;
++ do
++ {
++ *p++ = cmv;
++ } while (--k != 0);
++ p += stride;
++ } while (--j != 0);
++ }
++}
++
++static void hls_prediction_unit(const HEVCRpiContext * const s, HEVCRpiLocalContext * const lc,
++ const unsigned int x0, const unsigned int y0,
++ const unsigned int nPbW, const unsigned int nPbH,
++ const unsigned int log2_cb_size, const unsigned int partIdx, const unsigned int idx)
++{
++ HEVCRpiJob * const jb = lc->jb0;
++
++ struct HEVCRpiMvField current_mv = {{0}};
++ const RefPicList *const refPicList = s->refPicList;
++ const HEVCRpiFrame *ref0 = NULL, *ref1 = NULL;
++
++ if (lc->cu.pred_mode != MODE_SKIP)
++ lc->pu.merge_flag = ff_hevc_rpi_merge_flag_decode(lc);
++
++ if (lc->cu.pred_mode == MODE_SKIP || lc->pu.merge_flag) {
++ const unsigned int merge_idx = s->sh.max_num_merge_cand <= 1 ? 0 :
++ ff_hevc_rpi_merge_idx_decode(s, lc);
++
++ ff_hevc_rpi_luma_mv_merge_mode(s, lc, x0, y0, nPbW, nPbH, log2_cb_size,
++ partIdx, merge_idx, &current_mv);
++ } else {
++ hevc_luma_mv_mvp_mode(s, lc, x0, y0, nPbW, nPbH, &current_mv);
++ }
++
++ {
++ HEVCRpiMvField * p = mvf_stash_ptr(s, lc, x0, y0);
++ unsigned int i, j;
++
++ for (j = 0; j < nPbH >> LOG2_MIN_PU_SIZE; j++)
++ {
++ for (i = 0; i < nPbW >> LOG2_MIN_PU_SIZE; i++)
++ p[i] = current_mv;
++ p += MVF_STASH_WIDTH_PU;
++ }
++ }
++
++ col_stash(s, x0, y0, nPbW, nPbH, &current_mv);
++
++ if (current_mv.pred_flag & PF_L0) {
++ ref0 = refPicList[0].ref[current_mv.ref_idx[0]];
++ if (!ref0)
++ return;
++ hevc_await_progress(s, lc, ref0, current_mv.xy[0], y0, nPbH);
++ }
++ if (current_mv.pred_flag & PF_L1) {
++ ref1 = refPicList[1].ref[current_mv.ref_idx[1]];
++ if (!ref1)
++ return;
++ hevc_await_progress(s, lc, ref1, current_mv.xy[1], y0, nPbH);
++ }
++
++ if (current_mv.pred_flag == PF_L0) {
++ const int x0_c = x0 >> ctx_hshift(s, 1);
++ const int y0_c = y0 >> ctx_vshift(s, 1);
++ const int nPbW_c = nPbW >> ctx_hshift(s, 1);
++ const int nPbH_c = nPbH >> ctx_vshift(s, 1);
++
++ rpi_pred_y(s, jb, x0, y0, nPbW, nPbH, current_mv.xy[0],
++ s->sh.luma_weight_l0[current_mv.ref_idx[0]], s->sh.luma_offset_l0[current_mv.ref_idx[0]],
++ ref0->frame);
++
++ if (ctx_cfmt(s) != 0) {
++ rpi_pred_c(s, jb, 0, x0_c, y0_c, nPbW_c, nPbH_c, current_mv.xy[0],
++ s->sh.chroma_weight_l0[current_mv.ref_idx[0]], s->sh.chroma_offset_l0[current_mv.ref_idx[0]],
++ ref0->frame);
++ return;
++ }
++ } else if (current_mv.pred_flag == PF_L1) {
++ const int x0_c = x0 >> ctx_hshift(s, 1);
++ const int y0_c = y0 >> ctx_vshift(s, 1);
++ const int nPbW_c = nPbW >> ctx_hshift(s, 1);
++ const int nPbH_c = nPbH >> ctx_vshift(s, 1);
++
++ rpi_pred_y(s, jb, x0, y0, nPbW, nPbH, current_mv.xy[1],
++ s->sh.luma_weight_l1[current_mv.ref_idx[1]], s->sh.luma_offset_l1[current_mv.ref_idx[1]],
++ ref1->frame);
++
++ if (ctx_cfmt(s) != 0) {
++ rpi_pred_c(s, jb, 1, x0_c, y0_c, nPbW_c, nPbH_c, current_mv.xy[1],
++ s->sh.chroma_weight_l1[current_mv.ref_idx[1]], s->sh.chroma_offset_l1[current_mv.ref_idx[1]],
++ ref1->frame);
++ return;
++ }
++ } else if (current_mv.pred_flag == PF_BI) {
++ const int x0_c = x0 >> ctx_hshift(s, 1);
++ const int y0_c = y0 >> ctx_vshift(s, 1);
++ const int nPbW_c = nPbW >> ctx_hshift(s, 1);
++ const int nPbH_c = nPbH >> ctx_vshift(s, 1);
++
++ rpi_pred_y_b(s, jb, x0, y0, nPbW, nPbH, &current_mv, ref0->frame, ref1->frame);
++
++ if (ctx_cfmt(s) != 0) {
++ rpi_pred_c_b(s, jb, x0_c, y0_c, nPbW_c, nPbH_c,
++ &current_mv,
++ s->sh.chroma_weight_l0[current_mv.ref_idx[0]],
++ s->sh.chroma_offset_l0[current_mv.ref_idx[0]],
++ s->sh.chroma_weight_l1[current_mv.ref_idx[1]],
++ s->sh.chroma_offset_l1[current_mv.ref_idx[1]],
++ ref0->frame,
++ ref1->frame);
++ return;
++ }
++ }
++}
++
++static void set_ipm(const HEVCRpiContext * const s, HEVCRpiLocalContext * const lc,
++ const unsigned int x0, const unsigned int y0,
++ const unsigned int log2_cb_size,
++ const unsigned int ipm)
++{
++ const unsigned int x_pu = x0 >> LOG2_MIN_PU_SIZE;
++ const unsigned int y_pu = y0 >> LOG2_MIN_PU_SIZE;
++
++ {
++ const unsigned int ctb_mask = ~(~0U << (s->ps.sps->log2_ctb_size - LOG2_MIN_PU_SIZE));
++ set_stash2(lc->ipm_left + (y_pu & ctb_mask), lc->ipm_up + (x_pu & ctb_mask), log2_cb_size - LOG2_MIN_PU_SIZE, ipm);
++ }
++
++ // If IRAP then everything is Intra & we avoid ever looking at these
++ // stashes so don't bother setting them
++ if (!s->is_irap && lc->cu.pred_mode == MODE_INTRA)
++ {
++ if (s->is_intra != NULL)
++ {
++ set_bits(s->is_intra + (y0 >> LOG2_MIN_CU_SIZE) * s->ps.sps->pcm_width, x0 >> LOG2_MIN_CU_SIZE, s->ps.sps->pcm_width, log2_cb_size - LOG2_MIN_CU_SIZE);
++ }
++
++ {
++ HEVCRpiMvField * p = mvf_stash_ptr(s, lc, x0, y0);
++ const unsigned int size_in_pus = (1 << log2_cb_size) >> LOG2_MIN_PU_SIZE; // min_pu <= log2_cb so >= 1
++ unsigned int n = size_in_pus;
++
++ do
++ {
++ memset(p, 0, size_in_pus * sizeof(*p));
++ p += MVF_STASH_WIDTH_PU;
++ } while (--n != 0);
++ }
++
++
++ if (s->ref->col_mvf != NULL && ((x0 | y0) & 0xf) == 0)
++ {
++ // Only record top left stuff
++ // Blocks should always be alinged on size boundries
++ // so cannot have overflow from a small block
++
++ ColMvField * p = s->ref->col_mvf + (y0 >> 4) * s->col_mvf_stride + (x0 >> 4);
++ const unsigned int size_in_col = log2_cb_size < 4 ? 1 : (1 << (log2_cb_size - 4));
++ const unsigned int stride = s->col_mvf_stride - size_in_col;
++ unsigned int j = size_in_col;
++
++ do
++ {
++ unsigned int k = size_in_col;
++ do
++ {
++ p->L[0].poc = COL_POC_INTRA;
++ p->L[0].xy = 0;
++ p->L[1].poc = COL_POC_INTRA;
++ p->L[1].xy = 0;
++ ++p;
++ } while (--k != 0);
++ p += stride;
++ } while (--j != 0);
++ }
++ }
++}
++
++static inline void intra_prediction_unit_default_value(const HEVCRpiContext * const s, HEVCRpiLocalContext * const lc,
++ const unsigned int x0, const unsigned int y0,
++ const unsigned int log2_cb_size)
++{
++ set_ipm(s, lc, x0, y0, log2_cb_size, INTRA_DC);
++}
++
++
++/**
++ * 8.4.1
++ */
++static int luma_intra_pred_mode(const HEVCRpiContext * const s, HEVCRpiLocalContext * const lc,
++ int x0, int y0, int log2_pu_size,
++ int prev_intra_luma_pred_flag,
++ const unsigned int idx)
++{
++ const unsigned int ctb_mask = ~(~0U << s->ps.sps->log2_ctb_size);
++ const unsigned int xb_pu = (x0 & ctb_mask) >> LOG2_MIN_PU_SIZE;
++ const unsigned int yb_pu = (y0 & ctb_mask) >> LOG2_MIN_PU_SIZE;
++
++ // Up does not cross boundries so as we always scan 1 slice-tile-line in an
++ // lc we can just keep 1 CTB lR stashes
++ // Left is reset to DC @ Start of Line/Tile/Slice in fill_job
++ const unsigned int cand_up = yb_pu == 0 ? INTRA_DC : lc->ipm_up[xb_pu];
++ const unsigned int cand_left = lc->ipm_left[yb_pu];
++
++ unsigned int intra_pred_mode;
++ unsigned int a, b, c;
++
++ if (cand_left == cand_up) {
++ if (cand_left < 2) {
++ a = INTRA_PLANAR;
++ b = INTRA_DC;
++ c = INTRA_ANGULAR_26;
++ } else {
++ a = cand_left;
++ b = 2 + ((cand_left - 2 - 1 + 32) & 31);
++ c = 2 + ((cand_left - 2 + 1) & 31);
++ }
++ } else {
++ a = cand_left;
++ b = cand_up;
++ c = (cand_left != INTRA_PLANAR && cand_up != INTRA_PLANAR) ?
++ INTRA_PLANAR :
++ (cand_left != INTRA_DC && cand_up != INTRA_DC) ?
++ INTRA_DC :
++ INTRA_ANGULAR_26;
++ }
++
++ if (prev_intra_luma_pred_flag) {
++ intra_pred_mode = idx == 0 ? a : idx == 1 ? b : c;
++ } else {
++ // Sort lowest 1st
++ if (a > b)
++ FFSWAP(int, a, b);
++ if (a > c)
++ FFSWAP(int, a, c);
++ if (b > c)
++ FFSWAP(int, b, c);
++
++ intra_pred_mode = idx;
++ if (intra_pred_mode >= a)
++ intra_pred_mode++;
++ if (intra_pred_mode >= b)
++ intra_pred_mode++;
++ if (intra_pred_mode >= c)
++ intra_pred_mode++;
++ }
++
++ /* write the intra prediction units into the mv array */
++ set_ipm(s, lc, x0, y0, log2_pu_size, intra_pred_mode);
++ return intra_pred_mode;
++}
++
++static const uint8_t tab_mode_idx[] = {
++ 0, 1, 2, 2, 2, 2, 3, 5, 7, 8, 10, 12, 13, 15, 17, 18, 19, 20,
++ 21, 22, 23, 23, 24, 24, 25, 25, 26, 27, 27, 28, 28, 29, 29, 30, 31};
++
++static void intra_prediction_unit(const HEVCRpiContext * const s, HEVCRpiLocalContext * const lc,
++ const unsigned int x0, const unsigned int y0,
++ const unsigned int log2_cb_size)
++{
++ static const uint8_t intra_chroma_table[4] = { 0, 26, 10, 1 };
++ uint8_t prev_intra_luma_pred_flag[4];
++ int split = lc->cu.part_mode == PART_NxN;
++ const unsigned int split_size = (1 << (log2_cb_size - 1));
++ int chroma_mode;
++ const unsigned int n = split ? 4 : 1;
++ unsigned int i;
++
++ for (i = 0; i != n; i++)
++ prev_intra_luma_pred_flag[i] = ff_hevc_rpi_prev_intra_luma_pred_flag_decode(lc);
++
++ for (i = 0; i < n; i++) {
++ // depending on mode idx is mpm or luma_pred_mode
++ const unsigned int idx = prev_intra_luma_pred_flag[i] ?
++ ff_hevc_rpi_mpm_idx_decode(lc) :
++ ff_hevc_rpi_rem_intra_luma_pred_mode_decode(lc);
++
++ lc->pu.intra_pred_mode[i] =
++ luma_intra_pred_mode(s, lc,
++ x0 + ((i & 1) == 0 ? 0 : split_size),
++ y0 + ((i & 2) == 0 ? 0 : split_size),
++ log2_cb_size - split,
++ prev_intra_luma_pred_flag[i], idx);
++ }
++
++ if (ctx_cfmt(s) == 3) {
++ for (i = 0; i < n; i++) {
++ lc->pu.chroma_mode_c[i] = chroma_mode = ff_hevc_rpi_intra_chroma_pred_mode_decode(lc);
++ if (chroma_mode != 4) {
++ if (lc->pu.intra_pred_mode[i] == intra_chroma_table[chroma_mode])
++ lc->pu.intra_pred_mode_c[i] = 34;
++ else
++ lc->pu.intra_pred_mode_c[i] = intra_chroma_table[chroma_mode];
++ } else {
++ lc->pu.intra_pred_mode_c[i] = lc->pu.intra_pred_mode[i];
++ }
++ }
++ } else if (ctx_cfmt(s) == 2) {
++ int mode_idx;
++ lc->pu.chroma_mode_c[0] = chroma_mode = ff_hevc_rpi_intra_chroma_pred_mode_decode(lc);
++ if (chroma_mode != 4) {
++ if (lc->pu.intra_pred_mode[0] == intra_chroma_table[chroma_mode])
++ mode_idx = 34;
++ else
++ mode_idx = intra_chroma_table[chroma_mode];
++ } else {
++ mode_idx = lc->pu.intra_pred_mode[0];
++ }
++ lc->pu.intra_pred_mode_c[0] = tab_mode_idx[mode_idx];
++ } else if (ctx_cfmt(s) != 0) {
++ chroma_mode = ff_hevc_rpi_intra_chroma_pred_mode_decode(lc);
++ if (chroma_mode != 4) {
++ if (lc->pu.intra_pred_mode[0] == intra_chroma_table[chroma_mode])
++ lc->pu.intra_pred_mode_c[0] = 34;
++ else
++ lc->pu.intra_pred_mode_c[0] = intra_chroma_table[chroma_mode];
++ } else {
++ lc->pu.intra_pred_mode_c[0] = lc->pu.intra_pred_mode[0];
++ }
++ }
++}
++
++static int hls_coding_unit(const HEVCRpiContext * const s, HEVCRpiLocalContext * const lc,
++ const unsigned int x0, const unsigned int y0, const unsigned int log2_cb_size)
++{
++ const unsigned int cb_size = 1 << log2_cb_size;
++ const unsigned int log2_min_cb_size = s->ps.sps->log2_min_cb_size;
++ const unsigned int min_cb_width = s->ps.sps->min_cb_width;
++ const unsigned int x_cb = x0 >> log2_min_cb_size;
++ const unsigned int y_cb = y0 >> log2_min_cb_size;
++ const unsigned int idx = log2_cb_size - 2;
++ const unsigned int qp_block_mask = (1 << s->ps.pps->log2_min_cu_qp_delta_size) - 1;
++ int skip_flag = 0;
++
++ lc->cu.x = x0;
++ lc->cu.y = y0;
++ lc->cu.x_split = x0;
++ lc->cu.y_split = y0;
++
++ lc->cu.pred_mode = MODE_INTRA;
++ lc->cu.part_mode = PART_2Nx2N;
++ lc->cu.intra_split_flag = 0;
++ lc->cu.cu_transquant_bypass_flag = 0;
++ lc->pu.intra_pred_mode[0] = 1;
++ lc->pu.intra_pred_mode[1] = 1;
++ lc->pu.intra_pred_mode[2] = 1;
++ lc->pu.intra_pred_mode[3] = 1;
++
++ if (s->ps.pps->transquant_bypass_enable_flag) {
++ lc->cu.cu_transquant_bypass_flag = ff_hevc_rpi_cu_transquant_bypass_flag_decode(lc);
++ if (lc->cu.cu_transquant_bypass_flag)
++ set_deblocking_bypass(s, x0, y0, log2_cb_size);
++ }
++
++ if (s->sh.slice_type != HEVC_SLICE_I) {
++ lc->cu.pred_mode = MODE_INTER;
++ skip_flag = ff_hevc_rpi_skip_flag_decode(s, lc, x0, y0, x_cb, y_cb);
++ }
++
++ if (skip_flag) {
++ lc->cu.pred_mode = MODE_SKIP;
++
++ hls_prediction_unit(s, lc, x0, y0, cb_size, cb_size, log2_cb_size, 0, idx);
++ intra_prediction_unit_default_value(s, lc, x0, y0, log2_cb_size);
++
++ if (!s->sh.disable_deblocking_filter_flag)
++ ff_hevc_rpi_deblocking_boundary_strengths(s, lc, x0, y0, log2_cb_size, 0);
++ } else {
++ int pcm_flag = 0;
++
++ if (s->sh.slice_type != HEVC_SLICE_I)
++ lc->cu.pred_mode = ff_hevc_rpi_pred_mode_decode(lc);
++ if (lc->cu.pred_mode != MODE_INTRA ||
++ log2_cb_size == s->ps.sps->log2_min_cb_size) {
++ lc->cu.part_mode = ff_hevc_rpi_part_mode_decode(s, lc, log2_cb_size);
++ lc->cu.intra_split_flag = lc->cu.part_mode == PART_NxN &&
++ lc->cu.pred_mode == MODE_INTRA;
++ }
++
++ if (lc->cu.pred_mode == MODE_INTRA) {
++ if (lc->cu.part_mode == PART_2Nx2N &&
++ log2_cb_size <= s->ps.sps->pcm.log2_max_pcm_cb_size && // 0 if not enabled
++ log2_cb_size >= s->ps.sps->pcm.log2_min_pcm_cb_size &&
++ ff_hevc_rpi_pcm_flag_decode(lc) != 0)
++ {
++ int ret;
++ pcm_flag = 1;
++ intra_prediction_unit_default_value(s, lc, x0, y0, log2_cb_size);
++ if ((ret = hls_pcm_sample(s, lc, x0, y0, log2_cb_size)) < 0)
++ return ret;
++
++ if (s->ps.sps->pcm.loop_filter_disable_flag)
++ set_deblocking_bypass(s, x0, y0, log2_cb_size);
++ } else {
++ intra_prediction_unit(s, lc, x0, y0, log2_cb_size);
++ }
++ } else {
++ intra_prediction_unit_default_value(s, lc, x0, y0, log2_cb_size);
++ switch (lc->cu.part_mode) {
++ case PART_2Nx2N:
++ hls_prediction_unit(s, lc, x0, y0, cb_size, cb_size, log2_cb_size, 0, idx);
++ break;
++ case PART_2NxN:
++ hls_prediction_unit(s, lc, x0, y0, cb_size, cb_size / 2, log2_cb_size, 0, idx);
++ lc->cu.y_split = y0 + cb_size / 2;
++ hls_prediction_unit(s, lc, x0, y0 + cb_size / 2, cb_size, cb_size / 2, log2_cb_size, 1, idx);
++ break;
++ case PART_Nx2N:
++ hls_prediction_unit(s, lc, x0, y0, cb_size / 2, cb_size, log2_cb_size, 0, idx - 1);
++ lc->cu.x_split = x0 + cb_size / 2;
++ hls_prediction_unit(s, lc, x0 + cb_size / 2, y0, cb_size / 2, cb_size, log2_cb_size, 1, idx - 1);
++ break;
++ case PART_2NxnU:
++ hls_prediction_unit(s, lc, x0, y0, cb_size, cb_size / 4, log2_cb_size, 0, idx);
++ lc->cu.y_split = y0 + cb_size / 4;
++ hls_prediction_unit(s, lc, x0, y0 + cb_size / 4, cb_size, cb_size / 4 * 3, log2_cb_size, 1, idx);
++ break;
++ case PART_2NxnD:
++ hls_prediction_unit(s, lc, x0, y0, cb_size, cb_size / 4 * 3, log2_cb_size, 0, idx);
++ lc->cu.y_split = y0 + cb_size / 4 * 3;
++ hls_prediction_unit(s, lc, x0, y0 + cb_size / 4 * 3, cb_size, cb_size / 4, log2_cb_size, 1, idx);
++ break;
++ case PART_nLx2N:
++ hls_prediction_unit(s, lc, x0, y0, cb_size / 4, cb_size, log2_cb_size, 0, idx - 2);
++ lc->cu.x_split = x0 + cb_size / 4;
++ hls_prediction_unit(s, lc, x0 + cb_size / 4, y0, cb_size * 3 / 4, cb_size, log2_cb_size, 1, idx - 2);
++ break;
++ case PART_nRx2N:
++ hls_prediction_unit(s, lc, x0, y0, cb_size / 4 * 3, cb_size, log2_cb_size, 0, idx - 2);
++ lc->cu.x_split = x0 + cb_size / 4 * 3;
++ hls_prediction_unit(s, lc, x0 + cb_size / 4 * 3, y0, cb_size / 4, cb_size, log2_cb_size, 1, idx - 2);
++ break;
++ case PART_NxN:
++ hls_prediction_unit(s, lc, x0, y0, cb_size / 2, cb_size / 2, log2_cb_size, 0, idx - 1);
++ lc->cu.x_split = x0 + cb_size / 2;
++ hls_prediction_unit(s, lc, x0 + cb_size / 2, y0, cb_size / 2, cb_size / 2, log2_cb_size, 1, idx - 1);
++ lc->cu.y_split = y0 + cb_size / 2;
++ hls_prediction_unit(s, lc, x0, y0 + cb_size / 2, cb_size / 2, cb_size / 2, log2_cb_size, 2, idx - 1);
++ hls_prediction_unit(s, lc, x0 + cb_size / 2, y0 + cb_size / 2, cb_size / 2, cb_size / 2, log2_cb_size, 3, idx - 1);
++ break;
++ }
++ }
++
++ if (!pcm_flag) {
++ int rqt_root_cbf = 1;
++
++ if (lc->cu.pred_mode != MODE_INTRA &&
++ !(lc->cu.part_mode == PART_2Nx2N && lc->pu.merge_flag)) {
++ rqt_root_cbf = ff_hevc_rpi_no_residual_syntax_flag_decode(lc);
++ }
++ if (rqt_root_cbf) {
++ const unsigned int cbf_c = ctx_cfmt(s) == 0 ? 0 : (CBF_CR0 | CBF_CB0);
++ int ret;
++
++ lc->cu.max_trafo_depth = lc->cu.pred_mode == MODE_INTRA ?
++ s->ps.sps->max_transform_hierarchy_depth_intra + lc->cu.intra_split_flag :
++ s->ps.sps->max_transform_hierarchy_depth_inter;
++ // transform_tree does deblock_boundary_strengths
++ ret = hls_transform_tree(s, lc, x0, y0,
++ log2_cb_size, 0, 0, cbf_c);
++ if (ret < 0)
++ return ret;
++ } else {
++ if (!s->sh.disable_deblocking_filter_flag)
++ ff_hevc_rpi_deblocking_boundary_strengths(s, lc, x0, y0, log2_cb_size, 0);
++ }
++ }
++ }
++
++ // If the delta is still wanted then we haven't read the delta & therefore need to set qp here
++ if (lc->tu.is_cu_qp_delta_wanted)
++ ff_hevc_rpi_set_qPy(s, lc, x0, y0);
++
++ if(((x0 + (1<<log2_cb_size)) & qp_block_mask) == 0 &&
++ ((y0 + (1<<log2_cb_size)) & qp_block_mask) == 0) {
++ lc->qPy_pred = lc->qp_y;
++ }
++
++ set_bytes(s->qp_y_tab + y_cb * min_cb_width + x_cb, min_cb_width, log2_cb_size - log2_min_cb_size, lc->qp_y & 0xff);
++
++ set_stash2(s->cabac_stash_up + (x0 >> 3), s->cabac_stash_left + (y0 >> 3), log2_cb_size - 3, (lc->ct_depth << 1) | skip_flag);
++
++ return 0;
++}
++
++// Returns:
++// < 0 Error
++// 0 More data wanted
++// 1 EoSlice / EoPicture
++static int hls_coding_quadtree(const HEVCRpiContext * const s, HEVCRpiLocalContext * const lc, const int x0, const int y0,
++ const int log2_cb_size, const unsigned int cb_depth)
++{
++ const int cb_size = 1 << log2_cb_size;
++ int ret;
++ int split_cu;
++
++ lc->ct_depth = cb_depth;
++ split_cu = (log2_cb_size > s->ps.sps->log2_min_cb_size);
++ if (x0 + cb_size <= s->ps.sps->width &&
++ y0 + cb_size <= s->ps.sps->height &&
++ split_cu)
++ {
++ split_cu = ff_hevc_rpi_split_coding_unit_flag_decode(s, lc, cb_depth, x0, y0);
++ }
++
++ // Qp delta (and offset) need to remain wanted if cb_size < min until
++ // a coded block is found so we still initial state at depth 0 (outside
++ // this fn) and only reset here
++ if (s->ps.pps->cu_qp_delta_enabled_flag &&
++ log2_cb_size >= s->ps.pps->log2_min_cu_qp_delta_size)
++ {
++ lc->tu.is_cu_qp_delta_wanted = 1;
++ lc->tu.cu_qp_delta = 0;
++ }
++ if (s->sh.cu_chroma_qp_offset_enabled_flag &&
++ log2_cb_size >= s->ps.pps->log2_min_cu_qp_delta_size)
++ {
++ lc->tu.cu_chroma_qp_offset_wanted = 1;
++ }
++
++ lc->tu.qp_divmod6[0] = s->ps.pps->qp_bd_x[0];
++ lc->tu.qp_divmod6[1] = s->ps.pps->qp_bd_x[1] + s->sh.slice_cb_qp_offset;
++ lc->tu.qp_divmod6[2] = s->ps.pps->qp_bd_x[2] + s->sh.slice_cr_qp_offset;
++
++ if (split_cu) {
++ int qp_block_mask = (1 << s->ps.pps->log2_min_cu_qp_delta_size) - 1;
++ const int cb_size_split = cb_size >> 1;
++ const int x1 = x0 + cb_size_split;
++ const int y1 = y0 + cb_size_split;
++
++ int more_data = 0;
++
++ more_data = hls_coding_quadtree(s, lc, x0, y0, log2_cb_size - 1, cb_depth + 1);
++ if (more_data < 0)
++ return more_data;
++
++ if (more_data && x1 < s->ps.sps->width) {
++ more_data = hls_coding_quadtree(s, lc, x1, y0, log2_cb_size - 1, cb_depth + 1);
++ if (more_data < 0)
++ return more_data;
++ }
++ if (more_data && y1 < s->ps.sps->height) {
++ more_data = hls_coding_quadtree(s, lc, x0, y1, log2_cb_size - 1, cb_depth + 1);
++ if (more_data < 0)
++ return more_data;
++ }
++ if (more_data && x1 < s->ps.sps->width &&
++ y1 < s->ps.sps->height) {
++ more_data = hls_coding_quadtree(s, lc, x1, y1, log2_cb_size - 1, cb_depth + 1);
++ if (more_data < 0)
++ return more_data;
++ }
++
++ if(((x0 + (1<<log2_cb_size)) & qp_block_mask) == 0 &&
++ ((y0 + (1<<log2_cb_size)) & qp_block_mask) == 0)
++ lc->qPy_pred = lc->qp_y;
++
++ if (more_data)
++ return ((x1 + cb_size_split) < s->ps.sps->width ||
++ (y1 + cb_size_split) < s->ps.sps->height);
++ else
++ return 0;
++ } else {
++ ret = hls_coding_unit(s, lc, x0, y0, log2_cb_size);
++ if (ret < 0)
++ return ret;
++ if ((!((x0 + cb_size) %
++ (1 << (s->ps.sps->log2_ctb_size))) ||
++ (x0 + cb_size >= s->ps.sps->width)) &&
++ (!((y0 + cb_size) %
++ (1 << (s->ps.sps->log2_ctb_size))) ||
++ (y0 + cb_size >= s->ps.sps->height))) {
++ int end_of_slice_flag = ff_hevc_rpi_get_cabac_terminate(&lc->cc);
++ return !end_of_slice_flag;
++ } else {
++ return 1;
++ }
++ }
++
++ return 0; // NEVER
++}
++
++static void hls_decode_neighbour(const HEVCRpiContext * const s, HEVCRpiLocalContext * const lc,
++ const int x_ctb, const int y_ctb, const int ctb_addr_ts)
++{
++ const unsigned int ctb_size = 1 << s->ps.sps->log2_ctb_size;
++ const unsigned int ctb_addr_rs = s->ps.pps->ctb_addr_ts_to_rs[ctb_addr_ts];
++ const unsigned int ctb_addr_rs_in_slice = ctb_addr_rs - s->sh.slice_addr; // slice_addr = RS addr of start of slice
++ const unsigned int ctb_flags = s->ps.pps->ctb_ts_flags[ctb_addr_ts];
++ const unsigned int line_w = s->ps.sps->ctb_width;
++
++ s->tab_slice_address[ctb_addr_rs] = s->sh.slice_addr;
++
++ lc->end_of_ctb_x = FFMIN(x_ctb + ctb_size, s->ps.sps->width);
++ lc->end_of_ctb_y = FFMIN(y_ctb + ctb_size, s->ps.sps->height);
++
++ lc->boundary_flags = 0;
++
++ if ((ctb_flags & CTB_TS_FLAGS_SOTL) != 0)
++ lc->boundary_flags |= BOUNDARY_LEFT_TILE;
++ if (x_ctb > 0 && s->tab_slice_address[ctb_addr_rs] != s->tab_slice_address[ctb_addr_rs - 1])
++ lc->boundary_flags |= BOUNDARY_LEFT_SLICE;
++ if ((ctb_flags & CTB_TS_FLAGS_TOT) != 0)
++ lc->boundary_flags |= BOUNDARY_UPPER_TILE;
++ if (y_ctb > 0 && s->tab_slice_address[ctb_addr_rs] != s->tab_slice_address[ctb_addr_rs - line_w])
++ lc->boundary_flags |= BOUNDARY_UPPER_SLICE;
++
++ // Use line width rather than tile width for addr_in_slice test as
++ // addr_in_slice is in raster units
++
++ lc->ctb_avail =
++ ((lc->boundary_flags & (BOUNDARY_LEFT_SLICE | BOUNDARY_LEFT_TILE)) == 0 ? AVAIL_L : 0) |
++ ((lc->boundary_flags & (BOUNDARY_UPPER_SLICE | BOUNDARY_UPPER_TILE)) == 0 ? AVAIL_U : 0) |
++ ((lc->boundary_flags & (BOUNDARY_LEFT_TILE | BOUNDARY_UPPER_TILE)) == 0 &&
++ (ctb_addr_rs_in_slice > line_w) ? AVAIL_UL : 0) |
++ ((ctb_flags & (CTB_TS_FLAGS_EOTL | CTB_TS_FLAGS_TOT)) == 0 &&
++ (ctb_addr_rs_in_slice + 1 >= line_w) ? AVAIL_UR : 0);
++ // Down-left never avail at CTB level
++}
++
++
++static void rpi_execute_dblk_cmds(const HEVCRpiContext * const s, HEVCRpiJob * const jb)
++{
++ int y = ff_hevc_rpi_hls_filter_blk(s, jb->bounds,
++ (s->ps.pps->ctb_ts_flags[jb->ctu_ts_last] & CTB_TS_FLAGS_EOT) != 0);
++
++ // Signal
++ if (y > 0) {
++ // Cast away const as progress is held in s, but this really shouldn't confuse anything
++ ff_hevc_rpi_progress_signal_recon((HEVCRpiContext *)s, y - 1);
++ }
++
++ // Job done now
++ // ? Move outside this fn
++ job_free(s->jbc, jb);
++}
++
++// I-pred, transform_and_add for all blocks types done here
++// All ARM
++static void rpi_execute_pred_cmds(const HEVCRpiContext * const s, HEVCRpiJob * const jb)
++{
++ unsigned int i;
++ HEVCRpiIntraPredEnv * const iap = &jb->intra;
++ const HEVCPredCmd *cmd = iap->cmds;
++
++#if !RPI_WORKER_WAIT_PASS_0
++ rpi_sem_wait(&jb->sem);
++ rpi_cache_flush_execute(jb->rfe); // Invalidate data set up in pass1
++#endif
++
++ for (i = iap->n; i > 0; i--, cmd++)
++ {
++ switch (cmd->type)
++ {
++ case RPI_PRED_INTRA:
++ s->hpc.intra_pred[cmd->size - 2](s, cmd->i_pred.mode, cmd->i_pred.x, cmd->i_pred.y, cmd->avail);
++ break;
++ case RPI_PRED_INTRA_C:
++ s->hpc.intra_pred_c[cmd->size - 2](s, cmd->i_pred.mode, cmd->i_pred.x, cmd->i_pred.y, cmd->avail);
++ break;
++ case RPI_PRED_ADD_RESIDUAL:
++ s->hevcdsp.add_residual[cmd->size - 2](cmd->ta.dst, (int16_t *)cmd->ta.buf, cmd->ta.stride);
++ break;
++ case RPI_PRED_ADD_DC:
++ s->hevcdsp.add_residual_dc[cmd->size - 2](cmd->dc.dst, cmd->dc.stride, cmd->dc.dc);
++ break;
++ case RPI_PRED_ADD_RESIDUAL_U:
++ s->hevcdsp.add_residual_u[cmd->size - 2](cmd->ta.dst, (int16_t *)cmd->ta.buf, cmd->ta.stride, cmd->ta.dc);
++ break;
++ case RPI_PRED_ADD_RESIDUAL_V:
++ s->hevcdsp.add_residual_v[cmd->size - 2](cmd->ta.dst, (int16_t *)cmd->ta.buf, cmd->ta.stride, cmd->ta.dc);
++ break;
++ case RPI_PRED_ADD_RESIDUAL_C:
++ s->hevcdsp.add_residual_c[cmd->size - 2](cmd->ta.dst, (int16_t *)cmd->ta.buf, cmd->ta.stride);
++ break;
++ case RPI_PRED_ADD_DC_U:
++ case RPI_PRED_ADD_DC_V:
++ s->hevcdsp.add_residual_dc_c[cmd->size - 2](cmd->dc.dst, cmd->dc.stride, cmd->dc.dc);
++ break;
++
++ case RPI_PRED_I_PCM:
++ pcm_extract(s, cmd->i_pcm.src, cmd->i_pcm.src_len, cmd->i_pcm.x, cmd->i_pcm.y, 1 << cmd->size);
++ break;
++
++ default:
++ av_log(s->avctx, AV_LOG_PANIC, "Bad command %d in worker pred Q\n", cmd->type);
++ abort();
++ }
++ }
++
++ // Mark done
++ iap->n = 0;
++}
++
++
++// Set initial uniform job values & zero ctu_count
++static void rpi_begin(const HEVCRpiContext * const s, HEVCRpiJob * const jb, const unsigned int ctu_ts_first)
++{
++ unsigned int i;
++ HEVCRpiInterPredEnv *const cipe = &jb->chroma_ip;
++ HEVCRpiInterPredEnv *const yipe = &jb->luma_ip;
++ const HEVCRpiSPS * const sps = s->ps.sps;
++
++ const uint16_t pic_width_y = sps->width;
++ const uint16_t pic_height_y = sps->height;
++
++ const uint16_t pic_width_c = sps->width >> ctx_hshift(s, 1);
++ const uint16_t pic_height_c = sps->height >> ctx_vshift(s, 1);
++
++ // We expect the pointer to change if we use another sps
++ if (sps != jb->sps)
++ {
++ worker_pic_free_one(jb);
++
++ set_ipe_from_ici(cipe, &ipe_init_infos[s->ps.sps->bit_depth - 8].chroma);
++ set_ipe_from_ici(yipe, &ipe_init_infos[s->ps.sps->bit_depth - 8].luma);
++
++ {
++ const int coefs_per_luma = HEVC_MAX_CTB_SIZE * HEVC_RPI_MAX_WIDTH;
++ const int coefs_per_chroma = (coefs_per_luma * 2) >> (ctx_vshift(s, 1) + ctx_hshift(s, 1));
++ worker_pic_alloc_one(jb, coefs_per_luma + coefs_per_chroma);
++ }
++
++ jb->sps = sps;
++ }
++
++ jb->waited = 0;
++ jb->ctu_ts_first = ctu_ts_first;
++ jb->ctu_ts_last = -1;
++
++ rpi_inter_pred_reset(cipe);
++ for (i = 0; i < cipe->n; i++) {
++ HEVCRpiInterPredQ * const cp = cipe->q + i;
++ qpu_mc_pred_c_s_t * const u = &cp->qpu_mc_base->c.s;
++
++ u->next_src1.x = 0;
++ u->next_src1.y = 0;
++ u->next_src1.base = 0;
++ u->pic_cw = pic_width_c;
++ u->pic_ch = pic_height_c;
++ u->stride2 = av_rpi_sand_frame_stride2(s->frame);
++ u->stride1 = av_rpi_sand_frame_stride1(s->frame);
++ cp->last_l0 = &u->next_src1;
++
++ u->next_fn = 0;
++ u->next_src2.x = 0;
++ u->next_src2.y = 0;
++ u->next_src2.base = 0;
++ cp->last_l1 = &u->next_src2;
++
++ cp->qpu_mc_curr = (qpu_mc_pred_cmd_t *)(u + 1);
++ }
++
++ rpi_inter_pred_reset(yipe);
++ for (i = 0; i < yipe->n; i++) {
++ HEVCRpiInterPredQ * const yp = yipe->q + i;
++ qpu_mc_pred_y_s_t * const y = &yp->qpu_mc_base->y.s;
++
++ y->next_src1.x = 0;
++ y->next_src1.y = 0;
++ y->next_src1.base = 0;
++ y->next_src2.x = 0;
++ y->next_src2.y = 0;
++ y->next_src2.base = 0;
++ y->pic_h = pic_height_y;
++ y->pic_w = pic_width_y;
++ y->stride2 = av_rpi_sand_frame_stride2(s->frame);
++ y->stride1 = av_rpi_sand_frame_stride1(s->frame);
++ y->next_fn = 0;
++ yp->last_l0 = &y->next_src1;
++ yp->last_l1 = &y->next_src2;
++
++ yp->qpu_mc_curr = (qpu_mc_pred_cmd_t *)(y + 1);
++ }
++
++ jb->last_y8_p = NULL;
++ jb->last_y8_l1 = NULL;
++
++ for (i = 0; i != FF_ARRAY_ELEMS(jb->progress_req); ++i) {
++ jb->progress_req[i] = -1;
++ }
++
++ worker_pic_reset(&jb->coeffs);
++}
++
++
++#if !RPI_QPU_EMU_Y || !RPI_QPU_EMU_C
++static unsigned int mc_terminate_add_qpu(const HEVCRpiContext * const s,
++ const vpu_qpu_job_h vqj,
++ rpi_cache_flush_env_t * const rfe,
++ HEVCRpiInterPredEnv * const ipe)
++{
++ unsigned int i;
++ uint32_t mail[QPU_N_MAX][QPU_MAIL_EL_VALS];
++ unsigned int max_block = 0;
++
++ if (!ipe->used) {
++ return 0;
++ }
++
++ if (ipe->curr != 0) {
++ rpi_inter_pred_sync(ipe);
++ }
++
++ // Add final commands to Q
++ for(i = 0; i != ipe->n; ++i) {
++ HEVCRpiInterPredQ * const yp = ipe->q + i;
++ qpu_mc_src_t *const p0 = yp->last_l0;
++ qpu_mc_src_t *const p1 = yp->last_l1;
++ const unsigned int block_size = (char *)yp->qpu_mc_curr - (char *)yp->qpu_mc_base;
++
++ if (block_size > max_block)
++ max_block = block_size;
++
++ yp->qpu_mc_curr->data[-1] = yp->code_exit;
++
++ // Need to set the srcs for L0 & L1 to something that can be (pointlessly) prefetched
++ p0->x = MC_DUMMY_X;
++ p0->y = MC_DUMMY_Y;
++ p0->base = s->qpu_dummy_frame_qpu;
++ p1->x = MC_DUMMY_X;
++ p1->y = MC_DUMMY_Y;
++ p1->base = s->qpu_dummy_frame_qpu;
++
++ yp->last_l0 = NULL;
++ yp->last_l1 = NULL;
++
++ // Add to mailbox list
++ mail[i][0] = ipe->gptr.vc + ((uint8_t *)yp->qpu_mc_base - ipe->gptr.arm);
++ mail[i][1] = yp->code_setup;
++ }
++
++ // We don't need invalidate here as the uniforms aren't changed by the QPU
++ // and leaving them in ARM cache avoids (pointless) pre-reads when writing
++ // new values which seems to give us a small performance advantage
++ //
++ // In most cases we will not have a completely packed set of uniforms and as
++ // we have a 2d invalidate we writeback all uniform Qs to the depth of the
++ // fullest
++ rpi_cache_flush_add_gm_blocks(rfe, &ipe->gptr, RPI_CACHE_FLUSH_MODE_WRITEBACK,
++ (uint8_t *)ipe->q[0].qpu_mc_base - ipe->gptr.arm, max_block,
++ ipe->n, ipe->max_fill + ipe->min_gap);
++ vpu_qpu_job_add_qpu(vqj, ipe->n, (uint32_t *)mail);
++
++ return 1;
++}
++#endif
++
++#if RPI_QPU_EMU_Y || RPI_QPU_EMU_C
++static unsigned int mc_terminate_add_emu(const HEVCRpiContext * const s,
++ const vpu_qpu_job_h vqj,
++ rpi_cache_flush_env_t * const rfe,
++ HEVCRpiInterPredEnv * const ipe)
++{
++ unsigned int i;
++ if (!ipe->used) {
++ return 0;
++ }
++
++ if (ipe->curr != 0) {
++ rpi_inter_pred_sync(ipe);
++ }
++
++ // Add final commands to Q
++ for(i = 0; i != ipe->n; ++i) {
++ HEVCRpiInterPredQ * const yp = ipe->q + i;
++ qpu_mc_src_t *const p0 = yp->last_l0;
++ qpu_mc_src_t *const p1 = yp->last_l1;
++
++ yp->qpu_mc_curr->data[-1] = yp->code_exit;
++
++ // Need to set the srcs for L0 & L1 to something that can be (pointlessly) prefetched
++ p0->x = MC_DUMMY_X;
++ p0->y = MC_DUMMY_Y;
++ p0->base = s->qpu_dummy_frame_emu;
++ p1->x = MC_DUMMY_X;
++ p1->y = MC_DUMMY_Y;
++ p1->base = s->qpu_dummy_frame_emu;
++
++ yp->last_l0 = NULL;
++ yp->last_l1 = NULL;
++ }
++
++ return 1;
++}
++#endif
++
++
++#if RPI_QPU_EMU_Y
++#define mc_terminate_add_y mc_terminate_add_emu
++#else
++#define mc_terminate_add_y mc_terminate_add_qpu
++#endif
++#if RPI_QPU_EMU_C
++#define mc_terminate_add_c mc_terminate_add_emu
++#else
++#define mc_terminate_add_c mc_terminate_add_qpu
++#endif
++
++
++static void flush_frame(HEVCRpiContext *s,AVFrame *frame)
++{
++ rpi_cache_buf_t cbuf;
++ rpi_cache_flush_env_t * rfe = rpi_cache_flush_init(&cbuf);
++ rpi_cache_flush_add_frame(rfe, frame, RPI_CACHE_FLUSH_MODE_WB_INVALIDATE);
++ rpi_cache_flush_finish(rfe);
++}
++
++static void job_gen_bounds(const HEVCRpiContext * const s, HEVCRpiJob * const jb)
++{
++ const unsigned int rs0 = s->ps.pps->ctb_addr_ts_to_rs[jb->ctu_ts_first];
++ const unsigned int rs1 = s->ps.pps->ctb_addr_ts_to_rs[jb->ctu_ts_last];
++ const unsigned int ctb_width = s->ps.sps->ctb_width;
++ RpiBlk *const bounds = &jb->bounds;
++ av_assert1(jb->ctu_ts_first <= jb->ctu_ts_last);
++ bounds->x = (rs0 % ctb_width) << s->ps.sps->log2_ctb_size;
++ bounds->y = (rs0 / ctb_width) << s->ps.sps->log2_ctb_size;
++ bounds->w = ((rs1 - rs0) % ctb_width + 1) << s->ps.sps->log2_ctb_size;
++ bounds->h = ((rs1 - rs0) / ctb_width + 1) << s->ps.sps->log2_ctb_size;
++}
++
++#if RPI_PASSES == 2
++static void worker_core2(HEVCRpiContext * const s, HEVCRpiJob * const jb)
++{
++ // Perform intra prediction and residual reconstruction
++ rpi_execute_pred_cmds(s, jb);
++
++ // Perform deblocking for CTBs in this row
++ rpi_execute_dblk_cmds(s, jb);
++}
++#endif
++
++// Core execution tasks
++static void worker_core(const HEVCRpiContext * const s, HEVCRpiJob * const jb)
++{
++ int pred_y, pred_c;
++ vpu_qpu_job_env_t qvbuf;
++ const vpu_qpu_job_h vqj = vpu_qpu_job_init(&qvbuf);
++#if RPI_WORKER_WAIT_PASS_0
++ int do_wait;
++#endif
++
++ {
++ const HEVCRpiCoeffsEnv * const cf = &jb->coeffs;
++ if (cf->s[3].n + cf->s[2].n != 0)
++ {
++ const unsigned int csize = sizeof(cf->s[3].buf[0]);
++ const unsigned int offset32 = ((cf->s[3].buf - cf->s[2].buf) - cf->s[3].n) * csize;
++ unsigned int n16 = (cf->s[2].n >> 8);
++ unsigned int n32 = (cf->s[3].n >> 10);
++#if RPI_COMPRESS_COEFFS
++ if (cf->s[2].packed) {
++ n16 = n16 | (n16<<16);
++ } else {
++ const unsigned int npack16 = (cf->s[2].packed_n>>8);
++ n16 = n16 | (npack16<<16);
++ }
++ if (cf->s[3].packed) {
++ n32 = n32 | (n32<<16);
++ } else {
++ const unsigned int npack32 = (cf->s[3].packed_n>>10);
++ n32 = n32 | (npack32<<16);
++ }
++#endif
++ vpu_qpu_job_add_vpu(vqj,
++ vpu_get_fn(s->ps.sps->bit_depth),
++ vpu_get_constants(),
++ cf->gptr.vc,
++ n16,
++ cf->gptr.vc + offset32,
++ n32,
++ 0);
++
++ rpi_cache_flush_add_gm_range(jb->rfe, &cf->gptr, RPI_CACHE_FLUSH_MODE_WB_INVALIDATE, 0, cf->s[2].n * csize);
++ rpi_cache_flush_add_gm_range(jb->rfe, &cf->gptr, RPI_CACHE_FLUSH_MODE_WB_INVALIDATE, offset32, cf->s[3].n * csize);
++ }
++ }
++
++ pred_c = mc_terminate_add_c(s, vqj, jb->rfe, &jb->chroma_ip);
++
++// We could take a sync here and try to locally overlap QPU processing with ARM
++// but testing showed a slightly negative benefit with noticable extra complexity
++
++ pred_y = mc_terminate_add_y(s, vqj, jb->rfe, &jb->luma_ip);
++
++ // Returns 0 if nothing to do, 1 if sync added
++#if RPI_WORKER_WAIT_PASS_0
++ do_wait = vpu_qpu_job_add_sync_sem(vqj, &jb->sem);
++#else
++ if (vpu_qpu_job_add_sync_sem(vqj, &jb->sem) == 0)
++ sem_post(&jb->sem);
++#endif
++
++ rpi_cache_flush_execute(jb->rfe);
++
++ // Await progress as required
++ // jb->waited will only be clear if we have already tested the progress values
++ // (in worker_submit_job) and found we don't have to wait
++ if (jb->waited)
++ {
++ unsigned int i;
++ for (i = 0; i != FF_ARRAY_ELEMS(jb->progress_req); ++i) {
++ if (jb->progress_req[i] >= 0) {
++ ff_hevc_rpi_progress_wait_recon(s, jb, s->DPB + i, jb->progress_req[i]);
++ }
++ }
++ }
++
++ vpu_qpu_job_finish(vqj);
++
++ // We always work on a rectangular block
++ if (pred_y || pred_c)
++ {
++ rpi_cache_flush_add_frame_block(jb->rfe, s->frame, RPI_CACHE_FLUSH_MODE_INVALIDATE,
++ jb->bounds.x, jb->bounds.y, jb->bounds.w, jb->bounds.h,
++ ctx_vshift(s, 1), pred_y, pred_c);
++ }
++
++ // If we have emulated VPU ops - do it here
++#if RPI_QPU_EMU_Y || RPI_QPU_EMU_C
++ if (av_rpi_is_sand8_frame(s->frame))
++ {
++#if RPI_QPU_EMU_Y && RPI_QPU_EMU_C
++ ff_hevc_rpi_shader_c8(s, &jb->luma_ip, &jb->chroma_ip);
++#elif RPI_QPU_EMU_Y
++ ff_hevc_rpi_shader_c8(s, &jb->luma_ip, NULL);
++#else
++ ff_hevc_rpi_shader_c8(s, NULL, &jb->chroma_ip);
++#endif
++ }
++ else
++ {
++#if RPI_QPU_EMU_Y && RPI_QPU_EMU_C
++ ff_hevc_rpi_shader_c16(s, &jb->luma_ip, &jb->chroma_ip);
++#elif RPI_QPU_EMU_Y
++ ff_hevc_rpi_shader_c16(s, &jb->luma_ip, NULL);
++#else
++ ff_hevc_rpi_shader_c16(s, NULL, &jb->chroma_ip);
++#endif
++ }
++#endif
++
++#if RPI_WORKER_WAIT_PASS_0
++ if (do_wait)
++ rpi_sem_wait(&jb->sem);
++ rpi_cache_flush_execute(jb->rfe);
++#endif
++}
++
++
++static void rpi_free_inter_pred(HEVCRpiInterPredEnv * const ipe)
++{
++ av_freep(&ipe->q);
++ gpu_free(&ipe->gptr);
++}
++
++static HEVCRpiJob * job_new(void)
++{
++ HEVCRpiJob * const jb = av_mallocz(sizeof(HEVCRpiJob));
++
++ sem_init(&jb->sem, 0, 0);
++ jb->rfe = rpi_cache_flush_init(&jb->flush_buf);
++ ff_hevc_rpi_progress_init_wait(&jb->progress_wait);
++
++ jb->intra.n = 0;
++ jb->intra.cmds = av_mallocz(sizeof(HEVCPredCmd) * RPI_MAX_PRED_CMDS);
++
++ // * Sizeof the union structure might be overkill but at the moment it
++ // is correct (it certainly isn't going to be too small)
++ // Set max fill to slack/2 from the end of the Q
++ // If we exceed this in any Q then we will schedule by size (which should
++ // mean that we never use that Q again part from syncs)
++ // * Given how agressive the overflow resonse is we could maybe put the
++ // threshold even nearer the end, but I don't expect us to ever hit
++ // it on any real stream anyway.
++
++ rpi_inter_pred_alloc(&jb->chroma_ip,
++ QPU_N_MAX, QPU_N_GRP,
++ QPU_C_COMMANDS * sizeof(qpu_mc_pred_c_t) + QPU_C_SYNCS * sizeof(uint32_t),
++ QPU_C_CMD_SLACK_PER_Q * sizeof(qpu_mc_pred_c_t) / 2);
++ rpi_inter_pred_alloc(&jb->luma_ip,
++ QPU_N_MAX, QPU_N_GRP,
++ QPU_Y_COMMANDS * sizeof(qpu_mc_pred_y_t) + QPU_Y_SYNCS * sizeof(uint32_t),
++ QPU_Y_CMD_SLACK_PER_Q * sizeof(qpu_mc_pred_y_t) / 2);
++
++ return jb;
++}
++
++static void job_delete(HEVCRpiJob * const jb)
++{
++ worker_pic_free_one(jb);
++ ff_hevc_rpi_progress_kill_wait(&jb->progress_wait);
++ av_freep(&jb->intra.cmds);
++ rpi_free_inter_pred(&jb->chroma_ip);
++ rpi_free_inter_pred(&jb->luma_ip);
++ rpi_cache_flush_finish(jb->rfe); // Not really needed - should do nothing
++ sem_destroy(&jb->sem);
++ av_free(jb);
++}
++
++static void jbg_delete(HEVCRpiJobGlobal * const jbg)
++{
++ HEVCRpiJob * jb;
++
++ if (jbg == NULL)
++ return;
++
++ jb = jbg->free1;
++ while (jb != NULL)
++ {
++ HEVCRpiJob * const jb2 = jb;
++ jb = jb2->next;
++ job_delete(jb2);
++ }
++
++ pthread_mutex_destroy(&jbg->lock);
++ av_free(jbg);
++}
++
++static HEVCRpiJobGlobal * jbg_new(unsigned int job_count)
++{
++ HEVCRpiJobGlobal * const jbg = av_mallocz(sizeof(HEVCRpiJobGlobal));
++ if (jbg == NULL)
++ return NULL;
++
++ pthread_mutex_init(&jbg->lock, NULL);
++
++ while (job_count-- != 0)
++ {
++ HEVCRpiJob * const jb = job_new();
++ if (jb == NULL)
++ goto fail;
++
++ jb->next = jbg->free1;
++ jbg->free1 = jb;
++ }
++
++ return jbg;
++
++fail:
++ jbg_delete(jbg);
++ return NULL;
++}
++
++static void rpi_job_ctl_delete(HEVCRpiJobCtl * const jbc)
++{
++ HEVCRpiJobGlobal * jbg;
++
++ if (jbc == NULL)
++ return;
++
++ jbg = jbc->jbg;
++
++ if (jbc->jb1 != NULL)
++ job_delete(jbc->jb1);
++
++ pthread_mutex_destroy(&jbc->in_lock);
++ sem_destroy(&jbc->sem_out);
++ av_free(jbc);
++
++ // Deref the global job context
++ if (jbg != NULL && atomic_fetch_add(&jbg->ref_count, -1) == 1)
++ jbg_delete(jbg);
++}
++
++static HEVCRpiJobCtl * rpi_job_ctl_new(HEVCRpiJobGlobal *const jbg)
++{
++ HEVCRpiJobCtl * const jbc = av_mallocz(sizeof(HEVCRpiJobCtl));
++
++ if (jbc == NULL)
++ return NULL;
++
++ jbc->jbg = jbg;
++ atomic_fetch_add(&jbg->ref_count, 1);
++
++ sem_init(&jbc->sem_out, 0, RPI_MAX_JOBS);
++ pthread_mutex_init(&jbc->in_lock, NULL);
++
++ if ((jbc->jb1 = job_new()) == NULL)
++ goto fail;
++ jbc->jb1->jbc_local = jbc;
++
++ return jbc;
++
++fail:
++ rpi_job_ctl_delete(jbc);
++ return NULL;
++}
++
++
++
++static av_cold void hevc_init_worker(HEVCRpiContext * const s)
++{
++#if RPI_PASSES == 2
++ pass_queue_init(s->passq + 1, s, worker_core2, &s->jbc->sem_out, 1);
++#elif RPI_PASSES == 3
++ pass_queue_init(s->passq + 2, s, rpi_execute_dblk_cmds, &s->jbc->sem_out, 2);
++ pass_queue_init(s->passq + 1, s, rpi_execute_pred_cmds, &s->passq[2].sem_in, 1);
++#else
++#error Passes confused
++#endif
++ pass_queue_init(s->passq + 0, s, worker_core, &s->passq[1].sem_in, 0);
++
++ pass_queues_start_all(s);
++}
++
++static av_cold void hevc_exit_worker(HEVCRpiContext *s)
++{
++ pass_queues_term_all(s);
++
++ pass_queues_kill_all(s);
++
++ rpi_job_ctl_delete(s->jbc);
++ s->jbc = NULL;
++}
++
++
++static int slice_start(const HEVCRpiContext * const s, HEVCRpiLocalContext *const lc)
++{
++ const int ctb_addr_ts = s->ps.pps->ctb_addr_rs_to_ts[s->sh.slice_segment_addr];
++ const int tiles = s->ps.pps->num_tile_rows * s->ps.pps->num_tile_columns;
++ const unsigned int tile_id = s->ps.pps->tile_id[ctb_addr_ts];
++
++ // Check for obvious disasters
++ if (ctb_addr_ts == 0 && s->sh.dependent_slice_segment_flag) {
++ av_log(s->avctx, AV_LOG_ERROR, "Impossible initial tile.\n");
++ return AVERROR_INVALIDDATA;
++ }
++
++ // If dependant then ctb_addr_ts != 0 from previous check
++ if (s->sh.dependent_slice_segment_flag) {
++ int prev_rs = s->ps.pps->ctb_addr_ts_to_rs[ctb_addr_ts - 1];
++ if (s->tab_slice_address[prev_rs] != s->sh.slice_addr) {
++ av_log(s->avctx, AV_LOG_ERROR, "Previous slice segment missing\n");
++ return AVERROR_INVALIDDATA;
++ }
++ }
++
++ if (!s->ps.pps->entropy_coding_sync_enabled_flag &&
++ tile_id + s->sh.num_entry_point_offsets >= tiles)
++ {
++ av_log(s->avctx, AV_LOG_ERROR, "Entry points exceed tiles\n");
++ return AVERROR_INVALIDDATA;
++ }
++
++ // Tiled stuff must start at start of tile if it has multiple entry points
++ if (!s->ps.pps->entropy_coding_sync_enabled_flag &&
++ s->sh.num_entry_point_offsets != 0 &&
++ ctb_addr_ts != s->ps.pps->tile_pos_ts[tile_id])
++ {
++ av_log(s->avctx, AV_LOG_ERROR, "Multiple tiles in slice; slice start != tile start\n");
++ return AVERROR_INVALIDDATA;
++ }
++
++ ff_hevc_rpi_cabac_init_decoder(lc);
++
++ // Setup any required decode vars
++ lc->cabac_init_req = !s->sh.dependent_slice_segment_flag;
++
++// printf("SS: req=%d, sol=%d, sot=%d\n", lc->cabac_init_req, sol, sot);
++ lc->qp_y = s->sh.slice_qp;
++
++ // General setup
++ lc->bt_line_no = 0;
++ lc->ts = ctb_addr_ts;
++ return 0;
++}
++
++static int gen_entry_points(HEVCRpiContext * const s, const H2645NAL * const nal)
++{
++ const GetBitContext * const gb = &s->HEVClc->gb;
++ RpiSliceHeader * const sh = &s->sh;
++ int i, j;
++
++ const unsigned int length = nal->size;
++ unsigned int offset = ((gb->index) >> 3) + 1; // We have a bit & align still to come = +1 byte
++ unsigned int cmpt;
++ unsigned int startheader;
++
++ if (sh->num_entry_point_offsets == 0) {
++ s->data = NULL;
++ return 0;
++ }
++
++ // offset in slice header includes emulation prevention bytes.
++ // Unfortunately those have been removed by the time we get here so we
++ // have to compensate. The nal layer keeps a track of where they were.
++ for (j = 0, cmpt = 0, startheader = offset + sh->entry_point_offset[0]; j < nal->skipped_bytes; j++) {
++ if (nal->skipped_bytes_pos[j] >= offset && nal->skipped_bytes_pos[j] < startheader) {
++ startheader--;
++ cmpt++;
++ }
++ }
++
++ for (i = 1; i < sh->num_entry_point_offsets; i++) {
++ offset += (sh->entry_point_offset[i - 1] - cmpt);
++ for (j = 0, cmpt = 0, startheader = offset + sh->entry_point_offset[i]; j < nal->skipped_bytes; j++) {
++ if (nal->skipped_bytes_pos[j] >= offset && nal->skipped_bytes_pos[j] < startheader) {
++ startheader--;
++ cmpt++;
++ }
++ }
++ if (sh->entry_point_offset[i] <= cmpt) {
++ av_log(s->avctx, AV_LOG_ERROR, "entry point offset <= skipped bytes\n");
++ return AVERROR_INVALIDDATA;
++ }
++ sh->size[i - 1] = sh->entry_point_offset[i] - cmpt;
++ sh->offset[i - 1] = offset;
++ }
++
++ offset += sh->entry_point_offset[sh->num_entry_point_offsets - 1] - cmpt;
++ if (length < offset) {
++ av_log(s->avctx, AV_LOG_ERROR, "entry_point_offset table is corrupted\n");
++ return AVERROR_INVALIDDATA;
++ }
++ sh->size[sh->num_entry_point_offsets - 1] = length - offset;
++ sh->offset[sh->num_entry_point_offsets - 1] = offset;
++
++ // Remember data start pointer as we won't have nal later
++ s->data = nal->data;
++ return 0;
++}
++
++
++// Return
++// < 0 Error
++// 0 OK
++//
++// jb->ctu_ts_last < 0 Job still filling
++// jb->ctu_ts_last >= 0 Job ready
++
++static int fill_job(HEVCRpiContext * const s, HEVCRpiLocalContext *const lc, unsigned int max_blocks)
++{
++ const unsigned int log2_ctb_size = s->ps.sps->log2_ctb_size;
++ const unsigned int ctb_size = (1 << log2_ctb_size);
++ HEVCRpiJob * const jb = lc->jb0;
++ int more_data = 1;
++ unsigned int ctb_addr_ts = lc->ts;
++ unsigned int ctb_addr_rs = s->ps.pps->ctb_addr_ts_to_rs[ctb_addr_ts];
++ unsigned int x_ctb = (ctb_addr_rs % s->ps.sps->ctb_width) << log2_ctb_size;
++ const unsigned int y_ctb = (ctb_addr_rs / s->ps.sps->ctb_width) << log2_ctb_size;
++
++ lc->unit_done = 0;
++
++ while (more_data && ctb_addr_ts < s->ps.sps->ctb_size)
++ {
++ int q_full;
++ const unsigned int ctb_flags = s->ps.pps->ctb_ts_flags[ctb_addr_ts];
++
++ hls_decode_neighbour(s, lc, x_ctb, y_ctb, ctb_addr_ts);
++
++ ff_hevc_rpi_cabac_init(s, lc, ctb_flags);
++
++ hls_sao_param(s, lc, x_ctb >> log2_ctb_size, y_ctb >> log2_ctb_size);
++
++ s->deblock[ctb_addr_rs].beta_offset = s->sh.beta_offset;
++ s->deblock[ctb_addr_rs].tc_offset = s->sh.tc_offset;
++ s->filter_slice_edges[ctb_addr_rs] = s->sh.slice_loop_filter_across_slices_enabled_flag;
++
++ // Zap stashes if navail
++ if ((lc->ctb_avail & AVAIL_U) == 0)
++ zap_cabac_stash(s->cabac_stash_up + (x_ctb >> 3), log2_ctb_size - 3);
++ if ((lc->ctb_avail & AVAIL_L) == 0)
++ {
++ memset(lc->ipm_left, INTRA_DC, IPM_TAB_SIZE);
++ zap_cabac_stash(s->cabac_stash_left + (y_ctb >> 3), log2_ctb_size - 3);
++ }
++#if MVF_STASH_WIDTH > 64
++ // Restore left mvf stash at start of tile if not at start of line
++ if ((ctb_flags & CTB_TS_FLAGS_SOTL) != 0 && x_ctb != 0 && !s->is_irap)
++ {
++ unsigned int i;
++ HEVCRpiMvField * dst = mvf_stash_ptr(s, lc, x_ctb - 1, 0);
++ const HEVCRpiMvField * src = s->mvf_left + (y_ctb >> LOG2_MIN_PU_SIZE);
++ for (i = 0; i != ctb_size >> LOG2_MIN_PU_SIZE; ++i)
++ {
++ *dst = *src++;
++ dst += MVF_STASH_WIDTH_PU;
++ }
++ }
++#endif
++
++ // Set initial tu states
++ lc->tu.cu_qp_delta = 0;
++ lc->tu.is_cu_qp_delta_wanted = 0;
++ lc->tu.cu_chroma_qp_offset_wanted = 0;
++
++ // Decode
++ more_data = hls_coding_quadtree(s, lc, x_ctb, y_ctb, log2_ctb_size, 0);
++
++ if (ff_hevc_rpi_cabac_overflow(lc))
++ {
++ av_log(s->avctx, AV_LOG_ERROR, "Quadtree bitstream overread\n ");
++ more_data = AVERROR_INVALIDDATA;
++ }
++
++ if (more_data < 0) {
++ s->tab_slice_address[ctb_addr_rs] = TAB_SLICE_ADDR_BROKEN; // Mark slice as broken
++ return more_data;
++ }
++
++ if (more_data && ((ctb_flags & CTB_TS_FLAGS_EOT) != 0 ||
++ (s->ps.pps->entropy_coding_sync_enabled_flag && (ctb_flags & CTB_TS_FLAGS_EOTL) != 0)))
++ {
++ if (ff_hevc_rpi_get_cabac_terminate(&lc->cc) < 0 ||
++ ff_hevc_rpi_cabac_skip_bytes(&lc->cc, 0) == NULL)
++ {
++ av_log(s->avctx, AV_LOG_ERROR, "Error reading terminate el\n ");
++ return -1;
++ }
++ }
++
++ // --- Post CTB processing
++
++ // Stash rpl top/left for deblock that needs to remember such things cross-slice
++ s->rpl_up[x_ctb >> log2_ctb_size] = s->refPicList;
++ s->rpl_left[y_ctb >> log2_ctb_size] = s->refPicList;
++
++ if (!s->is_irap)
++ {
++ // Copy MVF up to up-left & stash to up
++ {
++ const HEVCRpiMvField * src = mvf_stash_ptr(s, lc, x_ctb, ctb_size - 1);
++ HEVCRpiMvField * dst = s->mvf_up + (x_ctb >> LOG2_MIN_PU_SIZE);
++
++ // printf("Stash: %d,%d, ctb_size=%d, %p->%p\n", x_ctb, y_ctb, ctb_size, src, dst);
++
++ lc->mvf_ul[0] = dst[(ctb_size - 1) >> LOG2_MIN_PU_SIZE];
++ memcpy(dst, src, (sizeof(*src)*ctb_size) >> LOG2_MIN_PU_SIZE);
++ }
++ // Stash sideways if end of tile line but not end of line (no point)
++ // ** Could/should do this @ end of fn
++#if MVF_STASH_WIDTH > 64
++ if ((ctb_flags & (CTB_TS_FLAGS_EOTL | CTB_TS_FLAGS_EOL)) == CTB_TS_FLAGS_EOTL)
++#endif
++ {
++ unsigned int i;
++ const HEVCRpiMvField * src = mvf_stash_ptr(s, lc, x_ctb + ctb_size - 1, 0);
++ HEVCRpiMvField * dst = s->mvf_left + (y_ctb >> LOG2_MIN_PU_SIZE);
++ for (i = 0; i != ctb_size >> LOG2_MIN_PU_SIZE; ++i)
++ {
++ *dst++ = *src;
++ src += MVF_STASH_WIDTH_PU;
++ }
++ }
++ }
++
++ if ((ctb_flags & CTB_TS_FLAGS_CSAVE) != 0)
++ ff_hevc_rpi_save_states(s, lc);
++
++ // Report progress so we can use our MVs in other frames
++ if ((ctb_flags & CTB_TS_FLAGS_EOL) != 0)
++ ff_hevc_rpi_progress_signal_mv(s, y_ctb + ctb_size - 1);
++
++ // End of line || End of tile line || End of tile
++ // (EoL covers end of frame for our purposes here)
++ q_full = ((ctb_flags & CTB_TS_FLAGS_EOTL) != 0);
++
++ // Allocate QPU chunks on fixed size 64 pel boundries rather than
++ // whatever ctb_size is today.
++ // * We might quite like to continue to 64 pel vertical too but that
++ // currently confuses WPP
++ if (((x_ctb + ctb_size) & 63) == 0 || q_full)
++ {
++ int overflow = 0;
++ if (rpi_inter_pred_next_ctu(&jb->luma_ip) != 0)
++ overflow = 1;
++ if (rpi_inter_pred_next_ctu(&jb->chroma_ip) != 0)
++ overflow = 1;
++ if (overflow)
++ {
++ // * This is very annoying (and slow) to cope with in WPP so
++ // we treat it as an error there (no known stream triggers this
++ // with the current buffer sizes). Non-wpp should cope fine.
++ av_log(s->avctx, AV_LOG_WARNING, "%s: Q full before EoL\n", __func__);
++ q_full = 1;
++ }
++ }
++
++ // Inc TS to next.
++ ctb_addr_ts++;
++ ctb_addr_rs++;
++ x_ctb += ctb_size;
++
++ if (q_full)
++ {
++ // Do job
++ // Prep for submission
++ jb->ctu_ts_last = ctb_addr_ts - 1; // Was pre-inced
++ job_gen_bounds(s, jb);
++ break;
++ }
++
++ // If max_blocks started as 0 then this will never be true
++ if (--max_blocks == 0)
++ break;
++ }
++
++ lc->unit_done = (more_data <= 0);
++ lc->ts = ctb_addr_ts;
++ return 0;
++}
++
++static void bt_lc_init(HEVCRpiContext * const s, HEVCRpiLocalContext * const lc, const unsigned int n)
++{
++ lc->context = s;
++ lc->jb0 = NULL;
++ lc->lc_n = n;
++ lc->bt_terminate = 0;
++ lc->bt_psem_out = NULL;
++ sem_init(&lc->bt_sem_in, 0, 0);
++}
++
++#define TRACE_WPP 0
++#if RPI_EXTRA_BIT_THREADS > 0
++static inline unsigned int line_ts_width(const HEVCRpiContext * const s, unsigned int ts)
++{
++ unsigned int rs = s->ps.pps->ctb_addr_ts_to_rs[ts];
++ return s->ps.pps->column_width[s->ps.pps->col_idxX[rs % s->ps.sps->ctb_width]];
++}
++
++// Move local context parameters from an aux bit thread back to the main
++// thread at the end of a slice as processing is going to continue there.
++static void movlc(HEVCRpiLocalContext *const dst_lc, HEVCRpiLocalContext *const src_lc, const int is_dep)
++{
++ if (src_lc == dst_lc) {
++ return;
++ }
++
++ // Move the job
++ // We will still have an active job if the final line terminates early
++ // Dest should always be null by now
++ av_assert1(dst_lc->jb0 == NULL);
++ dst_lc->jb0 = src_lc->jb0;
++ src_lc->jb0 = NULL;
++
++ // Always need to store where we are in the bitstream
++ dst_lc->ts = src_lc->ts;
++ dst_lc->gb = src_lc->gb;
++ // Cabac init request will be built at start of next slice
++
++ // Need to store context if we might have a dependent seg
++ if (is_dep)
++ {
++ dst_lc->qPy_pred = src_lc->qPy_pred;
++ memcpy(dst_lc->ipm_left, src_lc->ipm_left, sizeof(src_lc->ipm_left));
++ memcpy(dst_lc->cabac_state, src_lc->cabac_state, sizeof(src_lc->cabac_state));
++ memcpy(dst_lc->stat_coeff, src_lc->stat_coeff, sizeof(src_lc->stat_coeff));
++ }
++}
++
++static inline int wait_bt_sem_in(HEVCRpiLocalContext * const lc)
++{
++ rpi_sem_wait(&lc->bt_sem_in);
++ return lc->bt_terminate;
++}
++
++// Do one WPP line
++// Will not work correctly over horizontal tile boundries - vertical should be OK
++static int rpi_run_one_line(HEVCRpiContext *const s, HEVCRpiLocalContext * const lc, const int is_first)
++{
++ const int is_tile = lc->bt_is_tile;
++ const unsigned int tile_id = s->ps.pps->tile_id[lc->ts];
++ const unsigned int line = lc->bt_line_no;
++ const unsigned int line_inc = lc->bt_line_inc;
++ const int is_last = (line >= lc->bt_last_line);
++
++ const unsigned int ts_eol = lc->ts + (is_tile ? s->ps.pps->tile_size[tile_id] : lc->bt_line_width);
++ const unsigned int ts_next =
++ line + line_inc > (unsigned int)s->sh.num_entry_point_offsets ?
++ INT_MAX :
++ is_tile ?
++ s->ps.pps->tile_pos_ts[tile_id + line_inc] :
++ lc->ts + lc->bt_line_width * line_inc;
++ // Tile wants line, WPP a few CTUs (must be >= 2 for cabac context to work)
++ const unsigned int partial_size = is_tile ? line_ts_width(s, lc->ts) : 2;
++ unsigned int ts_prev;
++ int loop_n = 0;
++ int err = 0;
++
++ av_assert1(line <= s->sh.num_entry_point_offsets);
++
++#if TRACE_WPP
++ printf("%s[%d]: Start %s: tile=%d, line=%d/%d/%d, ts=%d/%d/%d, width=%d, jb=%p\n", __func__,
++ lc->lc_n, is_tile ? "Tile" : "WPP", tile_id,
++ line, lc->bt_last_line, s->sh.num_entry_point_offsets,
++ lc->ts, ts_eol, ts_next, partial_size, lc->jb0);
++#endif
++ if (line != 0)
++ {
++ const uint8_t * const data = s->data + s->sh.offset[line - 1];
++ const unsigned int len = s->sh.size[line - 1];
++ if ((err = init_get_bits8(&lc->gb, data, len)) < 0)
++ return err;
++
++ ff_init_cabac_decoder(&lc->cc, data, len);
++ }
++
++ // We should never be processing a dependent slice here so reset is good
++ // ?? These probably shouldn't be needed (as they should be set by later
++ // logic) but do seem to be required
++ lc->qp_y = s->sh.slice_qp;
++
++ do
++ {
++ if (!is_last && loop_n > 1) {
++#if TRACE_WPP
++ printf("%s[%d]: %sPoke %p\n", __func__, lc->lc_n, err == 0 ? "" : "ERR: ", lc->bt_psem_out);
++#endif
++ sem_post(lc->bt_psem_out);
++ }
++ // The wait for loop_n == 0 has been done in bit_thread
++ if (!is_first && loop_n != 0)
++ {
++#if TRACE_WPP
++ printf("%s[%d]: %sWait %p\n", __func__, lc->lc_n, err == 0 ? "" : "ERR: ", &lc->bt_sem_in);
++#endif
++ if (wait_bt_sem_in(lc) != 0)
++ return AVERROR_EXIT;
++ }
++
++#if TRACE_WPP
++ {
++ int n;
++ sem_getvalue(&lc->bt_sem_in, &n);
++ printf("%s[%d]: ts=%d, sem=%d %p\n", __func__, lc->lc_n, lc->ts, n, &lc->bt_sem_in);
++ }
++#endif
++
++ ts_prev = lc->ts;
++
++ // If we have had an error - do no further decode but do continue
++ // moving signals around so the other threads continue to operate
++ // correctly (or at least as correctly as they can with this line missing)
++ //
++ // Errors in WPP/Tile are less fatal than normal as we have a good idea
++ // of how to restart on the next line so there is no need to give up totally
++ if (err != 0)
++ {
++ lc->unit_done = 0;
++ lc->ts += partial_size;
++ }
++ else
++ {
++ worker_pass0_ready(s, lc);
++
++ if ((err = fill_job(s, lc, partial_size)) < 0 ||
++ (lc->ts < ts_eol && !is_last && (lc->ts != ts_prev + partial_size || lc->unit_done)))
++ {
++ if (err == 0) {
++ av_log(s->avctx, AV_LOG_ERROR, "Unexpected end of tile/wpp section\n");
++ err = AVERROR_INVALIDDATA;
++ }
++ worker_free(s, lc);
++ lc->ts = ts_prev + partial_size; // Pretend we did all that
++ lc->unit_done = 0;
++ }
++ else if (is_tile)
++ {
++ worker_submit_job(s, lc);
++ }
++ }
++
++ ++loop_n;
++ } while (lc->ts < ts_eol && !lc->unit_done);
++
++ // If we are on the last line & we didn't get a whole line we must wait for
++ // and sink the sem_posts from the line above / tile to the left.
++ while ((ts_prev += partial_size) < ts_eol)
++ {
++#if TRACE_WPP
++ printf("%s[%d]: EOL Wait: ts=%d %p\n", __func__, lc->lc_n, ts_prev, &lc->bt_sem_in);
++#endif
++ if (wait_bt_sem_in(lc) != 0)
++ return AVERROR_EXIT;
++ }
++
++ lc->bt_line_no += line_inc;
++
++ if (!is_tile && err == 0)
++ worker_submit_job(s, lc);
++
++ if (!is_last) {
++ lc->ts = ts_next;
++
++#if TRACE_WPP
++ printf("%s[%d]: Poke post submit %p\n", __func__, lc->lc_n, lc->bt_psem_out);
++#endif
++ sem_post(lc->bt_psem_out);
++ if (loop_n > 1) {
++#if TRACE_WPP
++ printf("%s[%d]: Poke post submit2 %p\n", __func__, lc->lc_n, lc->bt_psem_out);
++#endif
++ sem_post(lc->bt_psem_out);
++ }
++ }
++ else
++ {
++ movlc(s->HEVClcList[0], lc, s->ps.pps->dependent_slice_segments_enabled_flag); // * & not EoT
++#if MVF_STASH_WIDTH > 64
++ // Horrid calculations to work out what we want but luckily this should almost never execute
++ // **** Move to movlc
++ if (!s->is_irap)
++ {
++ const unsigned int ctb_flags = s->ps.pps->ctb_ts_flags[lc->ts];
++ if ((ctb_flags & CTB_TS_FLAGS_EOTL) == 0) // If EOTL then we have already stashed mvf
++ {
++ const unsigned int x_ctb = ((s->ps.pps->ctb_addr_ts_to_rs[lc->ts] % s->ps.sps->ctb_width) << s->ps.sps->log2_ctb_size) - 1;
++ unsigned int i;
++ const HEVCRpiMvField *s_mvf = lc->mvf_stash + ((x_ctb >> LOG2_MIN_PU_SIZE) & (MVF_STASH_WIDTH_PU - 1));
++ HEVCRpiMvField *d_mvf = s->HEVClcList[0]->mvf_stash + ((x_ctb >> LOG2_MIN_PU_SIZE) & (MVF_STASH_WIDTH_PU - 1));
++
++ for (i = 0; i != MVF_STASH_HEIGHT_PU; ++i)
++ {
++ *d_mvf = *s_mvf;
++ d_mvf += MVF_STASH_WIDTH_PU;
++ s_mvf += MVF_STASH_WIDTH_PU;
++ }
++
++ }
++ }
++#endif
++ // When all done poke the thread 0 sem_in one final time
++#if TRACE_WPP
++ printf("%s[%d]: Poke final %p\n", __func__, lc->lc_n, &s->HEVClcList[0]->bt_sem_in);
++#endif
++ sem_post(&s->HEVClcList[0]->bt_sem_in);
++ }
++
++#if TRACE_WPP
++ printf("%s[%d]: End. dep=%d\n", __func__, lc->lc_n, s->ps.pps->dependent_slice_segments_enabled_flag);
++#endif
++ return err;
++}
++
++static void wpp_setup_lcs(HEVCRpiContext * const s)
++{
++ unsigned int ts = s->ps.pps->ctb_addr_rs_to_ts[s->sh.slice_segment_addr];
++ const unsigned int line_width = line_ts_width(s, ts);
++
++ for (int i = 0; i <= s->sh.num_entry_point_offsets && i < RPI_BIT_THREADS; ++i)
++ {
++ HEVCRpiLocalContext * const lc = s->HEVClcList[i];
++ lc->ts = ts;
++ lc->bt_is_tile = 0;
++ lc->bt_line_no = i;
++ lc->bt_line_width = line_width;
++ lc->bt_last_line = s->sh.num_entry_point_offsets;
++ lc->bt_line_inc = RPI_BIT_THREADS;
++ ts += line_width;
++ }
++}
++
++
++// Can only process tile single row at once
++static void tile_one_row_setup_lcs(HEVCRpiContext * const s, unsigned int slice_row)
++{
++ const HEVCRpiPPS * const pps = s->ps.pps;
++ const unsigned int ts0 = pps->ctb_addr_rs_to_ts[s->sh.slice_segment_addr];
++ const unsigned int tile0 = pps->tile_id[ts0];
++ const unsigned int col0 = tile0 % pps->num_tile_columns;
++
++ const unsigned int col = (slice_row == 0) ? col0 : 0;
++ unsigned int line = slice_row * pps->num_tile_columns - col0 + col;
++ const unsigned int last_line = FFMIN(
++ line + pps->num_tile_columns - 1 - col, s->sh.num_entry_point_offsets);
++
++ const unsigned int par =
++ FFMIN(RPI_BIT_THREADS, last_line + 1 - line);
++#if TRACE_WPP
++ printf("ts0=%d, ents=%d, row=%d, tiles=%dx%d, col=%d, par=%d, line=%d/%d\n", ts0, s->sh.num_entry_point_offsets, slice_row,
++ pps->num_tile_columns, pps->num_tile_rows, col, par, line, last_line);
++#endif
++ for (unsigned int i = 0; i != par; ++i, ++line)
++ {
++ HEVCRpiLocalContext * const lc = s->HEVClcList[i];
++ const unsigned int tile = tile0 + line;
++
++ lc->ts = pps->tile_pos_ts[tile];
++ lc->bt_line_no = line;
++ lc->bt_is_tile = 1;
++ lc->bt_line_width = line_ts_width(s, lc->ts);
++ lc->bt_last_line = last_line;
++ lc->bt_line_inc = par;
++ }
++}
++
++
++static void * bit_thread(void * v)
++{
++ HEVCRpiLocalContext * const lc = v;
++ HEVCRpiContext *const s = lc->context;
++
++ while (wait_bt_sem_in(lc) == 0)
++ {
++ int err;
++
++ if ((err = rpi_run_one_line(s, lc, 0)) < 0) { // Never first tile/wpp
++ if (lc->bt_terminate) {
++ av_log(s->avctx, AV_LOG_ERROR, "%s: Unexpected termination\n", __func__);
++ break;
++ }
++ av_log(s->avctx, AV_LOG_WARNING, "%s: Decode failure: %d\n", __func__, err);
++ }
++ }
++
++ return NULL;
++}
++
++static int bit_threads_start(HEVCRpiContext * const s)
++{
++ if (s->bt_started)
++ return 0;
++
++ for (int i = 1; i < RPI_BIT_THREADS; ++i)
++ {
++ // lc[0] belongs to the main thread - this sets up lc[1..RPI_BIT_THREADS]
++ if (s->HEVClcList[i] == NULL) {
++ if ((s->HEVClcList[i] = av_mallocz(sizeof(*s->HEVClcList[0]))) == NULL)
++ return -1;
++ }
++
++ bt_lc_init(s, s->HEVClcList[i], i);
++ job_lc_init(s->HEVClcList[i]);
++ }
++
++ // Link the sems in a circle
++ for (int i = 0; i < RPI_BIT_THREADS - 1; ++i)
++ s->HEVClcList[i]->bt_psem_out = &s->HEVClcList[i + 1]->bt_sem_in;
++ s->HEVClcList[RPI_BIT_THREADS - 1]->bt_psem_out = &s->HEVClcList[0]->bt_sem_in;
++
++ // Init all lc before starting any threads
++ for (int i = 0; i < RPI_EXTRA_BIT_THREADS; ++i)
++ {
++ if (pthread_create(s->bit_threads + i, NULL, bit_thread, s->HEVClcList[i + 1]) < 0)
++ return -1;
++ }
++
++ s->bt_started = 1;
++ return 0;
++}
++
++static int bit_threads_kill(HEVCRpiContext * const s)
++{
++ if (!s->bt_started)
++ return 0;
++ s->bt_started = 0;
++
++ for (int i = 0; i < RPI_EXTRA_BIT_THREADS; ++i)
++ {
++ HEVCRpiLocalContext *const lc = s->HEVClcList[i + 1];
++ if (lc == NULL)
++ break;
++
++ lc->bt_terminate = 1;
++ sem_post(&lc->bt_sem_in);
++ pthread_join(s->bit_threads[i], NULL);
++
++ sem_destroy(&lc->bt_sem_in);
++ job_lc_kill(lc);
++ }
++ return 0;
++}
++#endif
++
++
++// If we are at EoT and the row is shorter than the number of jobs
++// we can Q we have to wait for it finish otherwise we risk cache/QPU
++// disasters
++static inline int tile_needs_wait(const HEVCRpiContext * const s, const int n)
++{
++ return
++ s->ps.pps->tile_wpp_inter_disable >= 2 &&
++ s->sh.slice_type != HEVC_SLICE_I &&
++ n >= 0 &&
++ (s->ps.pps->ctb_ts_flags[n] & (CTB_TS_FLAGS_EOT | CTB_TS_FLAGS_EOL)) == CTB_TS_FLAGS_EOT;
++}
++
++static int rpi_decode_entry(AVCodecContext *avctxt, void *isFilterThread)
++{
++ HEVCRpiContext * const s = avctxt->priv_data;
++ HEVCRpiLocalContext * const lc = s->HEVClc;
++ int err;
++
++ // Start of slice
++ if ((err = slice_start(s, lc)) != 0)
++ return err;
++
++#if RPI_EXTRA_BIT_THREADS > 0
++
++ if (s->sh.offload_tiles)
++ {
++ unsigned int slice_row = 0;
++
++#if TRACE_WPP
++ printf("%s: Do Tiles\n", __func__);
++#endif
++ // Generate & start extra bit threads if they aren't already running
++ bit_threads_start(s);
++
++ do
++ {
++ // Reset lc lines etc.
++ tile_one_row_setup_lcs(s, slice_row);
++
++#if TRACE_WPP
++ printf("%s: Row %d: Do 1st: line=%d/%d/%d\n",
++ __func__, slice_row, lc->bt_line_no, lc->bt_last_line, s->sh.num_entry_point_offsets);
++#endif
++
++ rpi_run_one_line(s, lc, 1); // Kicks off the other threads
++#if TRACE_WPP
++ printf("%s: Row %d: Done 1st: line=%d/%d/%d\n",
++ __func__, slice_row, lc->bt_line_no, lc->bt_last_line, s->sh.num_entry_point_offsets);
++#endif
++
++ while (lc->bt_line_no <= lc->bt_last_line) {
++ rpi_sem_wait(&lc->bt_sem_in);
++ rpi_run_one_line(s, lc, 0);
++ }
++#if TRACE_WPP
++ printf("%s: Done body\n", __func__);
++#endif
++
++ // Wait for everything else to finish
++ rpi_sem_wait(&lc->bt_sem_in);
++
++ ++slice_row;
++ } while (lc->bt_last_line < s->sh.num_entry_point_offsets);
++
++
++#if TRACE_WPP
++ printf("%s: Done wait: ts=%d\n", __func__, lc->ts);
++#endif
++ }
++ else if (s->sh.offload_wpp)
++ {
++#if TRACE_WPP
++ printf("%s: Do WPP\n", __func__);
++#endif
++ // Generate & start extra bit threads if they aren't already running
++ bit_threads_start(s);
++
++ // Reset lc lines etc.
++ wpp_setup_lcs(s);
++
++ rpi_run_one_line(s, lc, 1); // Kicks off the other threads
++#if TRACE_WPP
++ printf("%s: Done 1st\n", __func__);
++#endif
++
++ while (lc->bt_line_no <= s->sh.num_entry_point_offsets) {
++ rpi_sem_wait(&lc->bt_sem_in);
++ rpi_run_one_line(s, lc, 0);
++ }
++#if TRACE_WPP
++ printf("%s: Done body\n", __func__);
++#endif
++
++ // Wait for everything else to finish
++ rpi_sem_wait(&lc->bt_sem_in);
++
++#if TRACE_WPP
++ printf("%s: Done wait: ts=%d\n", __func__, lc->ts);
++#endif
++ }
++ else
++#endif
++ {
++#if TRACE_WPP
++ printf("%s: Single start: ts=%d\n", __func__, lc->ts);
++#endif
++ // Single bit thread
++ do {
++ // Make sure we have space to prepare the next job
++ worker_pass0_ready(s, lc);
++
++ if ((err = fill_job(s, lc, 0)) < 0)
++ goto fail;
++
++ worker_submit_job(s, lc);
++
++ if (tile_needs_wait(s, lc->ts - 1))
++ worker_wait(s, lc);
++
++ } while (!lc->unit_done);
++
++#if TRACE_WPP
++ printf("%s: Single end: ts=%d\n", __func__, lc->ts);
++#endif
++ }
++
++ // If we have reached the end of the frame or
++ // then wait for the worker to finish all its jobs
++ if (lc->ts >= s->ps.sps->ctb_size)
++ worker_wait(s, lc);
++
++#if RPI_TSTATS
++ {
++ HEVCRpiStats *const ts = &s->tstats;
++
++ printf("=== P: xy00:%5d/%5d/%5d/%5d h16gl:%5d/%5d w8gl:%5d/%5d y8m:%d\n B: xy00:%5d/%5d/%5d/%5d h16gl:%5d/%5d\n",
++ ts->y_pred1_xy, ts->y_pred1_x0, ts->y_pred1_y0, ts->y_pred1_x0y0,
++ ts->y_pred1_hgt16, ts->y_pred1_hle16, ts->y_pred1_wgt8, ts->y_pred1_wle8, ts->y_pred1_y8_merge,
++ ts->y_pred2_xy, ts->y_pred2_x0, ts->y_pred2_y0, ts->y_pred2_x0y0,
++ ts->y_pred2_hgt16, ts->y_pred2_hle16);
++ memset(ts, 0, sizeof(*ts));
++ }
++#endif
++
++ return lc->ts;
++
++fail:
++ // Cleanup
++ av_log(s->avctx, AV_LOG_ERROR, "%s failed: err=%d\n", __func__, err);
++ // Free our job & wait for temination
++ worker_free(s, lc);
++ worker_wait(s, lc);
++ return err;
++}
++
++
++static void set_no_backward_pred(HEVCRpiContext * const s)
++{
++ int i, j;
++ const RefPicList *const refPicList = s->refPicList;
++
++ s->no_backward_pred_flag = 0;
++ if (s->sh.slice_type != HEVC_SLICE_B || !s->sh.slice_temporal_mvp_enabled_flag)
++ return;
++
++ for (j = 0; j < 2; j++) {
++ for (i = 0; i < refPicList[j].nb_refs; i++) {
++ if (refPicList[j].list[i] > s->poc) {
++ s->no_backward_pred_flag = 1;
++ return;
++ }
++ }
++ }
++}
++
++static int hls_slice_data(HEVCRpiContext * const s, const H2645NAL * const nal)
++{
++ int err;
++ if ((err = gen_entry_points(s, nal)) < 0)
++ return err;
++
++ set_no_backward_pred(s);
++
++ return rpi_decode_entry(s->avctx, NULL);
++}
++
++static int set_side_data(HEVCRpiContext *s)
++{
++ AVFrame *out = s->ref->frame;
++
++ if (s->sei.frame_packing.present &&
++ s->sei.frame_packing.arrangement_type >= 3 &&
++ s->sei.frame_packing.arrangement_type <= 5 &&
++ s->sei.frame_packing.content_interpretation_type > 0 &&
++ s->sei.frame_packing.content_interpretation_type < 3) {
++ AVStereo3D *stereo = av_stereo3d_create_side_data(out);
++ if (!stereo)
++ return AVERROR(ENOMEM);
++
++ switch (s->sei.frame_packing.arrangement_type) {
++ case 3:
++ if (s->sei.frame_packing.quincunx_subsampling)
++ stereo->type = AV_STEREO3D_SIDEBYSIDE_QUINCUNX;
++ else
++ stereo->type = AV_STEREO3D_SIDEBYSIDE;
++ break;
++ case 4:
++ stereo->type = AV_STEREO3D_TOPBOTTOM;
++ break;
++ case 5:
++ stereo->type = AV_STEREO3D_FRAMESEQUENCE;
++ break;
++ }
++
++ if (s->sei.frame_packing.content_interpretation_type == 2)
++ stereo->flags = AV_STEREO3D_FLAG_INVERT;
++
++ if (s->sei.frame_packing.arrangement_type == 5) {
++ if (s->sei.frame_packing.current_frame_is_frame0_flag)
++ stereo->view = AV_STEREO3D_VIEW_LEFT;
++ else
++ stereo->view = AV_STEREO3D_VIEW_RIGHT;
++ }
++ }
++
++ if (s->sei.display_orientation.present &&
++ (s->sei.display_orientation.anticlockwise_rotation ||
++ s->sei.display_orientation.hflip || s->sei.display_orientation.vflip)) {
++ double angle = s->sei.display_orientation.anticlockwise_rotation * 360 / (double) (1 << 16);
++ AVFrameSideData *rotation = av_frame_new_side_data(out,
++ AV_FRAME_DATA_DISPLAYMATRIX,
++ sizeof(int32_t) * 9);
++ if (!rotation)
++ return AVERROR(ENOMEM);
++
++ av_display_rotation_set((int32_t *)rotation->data, angle);
++ av_display_matrix_flip((int32_t *)rotation->data,
++ s->sei.display_orientation.hflip,
++ s->sei.display_orientation.vflip);
++ }
++
++ // Decrement the mastering display flag when IRAP frame has no_rasl_output_flag=1
++ // so the side data persists for the entire coded video sequence.
++ if (s->sei.mastering_display.present > 0 &&
++ IS_IRAP(s) && s->no_rasl_output_flag) {
++ s->sei.mastering_display.present--;
++ }
++ if (s->sei.mastering_display.present) {
++ // HEVC uses a g,b,r ordering, which we convert to a more natural r,g,b
++ const int mapping[3] = {2, 0, 1};
++ const int chroma_den = 50000;
++ const int luma_den = 10000;
++ int i;
++ AVMasteringDisplayMetadata *metadata =
++ av_mastering_display_metadata_create_side_data(out);
++ if (!metadata)
++ return AVERROR(ENOMEM);
++
++ for (i = 0; i < 3; i++) {
++ const int j = mapping[i];
++ metadata->display_primaries[i][0].num = s->sei.mastering_display.display_primaries[j][0];
++ metadata->display_primaries[i][0].den = chroma_den;
++ metadata->display_primaries[i][1].num = s->sei.mastering_display.display_primaries[j][1];
++ metadata->display_primaries[i][1].den = chroma_den;
++ }
++ metadata->white_point[0].num = s->sei.mastering_display.white_point[0];
++ metadata->white_point[0].den = chroma_den;
++ metadata->white_point[1].num = s->sei.mastering_display.white_point[1];
++ metadata->white_point[1].den = chroma_den;
++
++ metadata->max_luminance.num = s->sei.mastering_display.max_luminance;
++ metadata->max_luminance.den = luma_den;
++ metadata->min_luminance.num = s->sei.mastering_display.min_luminance;
++ metadata->min_luminance.den = luma_den;
++ metadata->has_luminance = 1;
++ metadata->has_primaries = 1;
++
++ av_log(s->avctx, AV_LOG_DEBUG, "Mastering Display Metadata:\n");
++ av_log(s->avctx, AV_LOG_DEBUG,
++ "r(%5.4f,%5.4f) g(%5.4f,%5.4f) b(%5.4f %5.4f) wp(%5.4f, %5.4f)\n",
++ av_q2d(metadata->display_primaries[0][0]),
++ av_q2d(metadata->display_primaries[0][1]),
++ av_q2d(metadata->display_primaries[1][0]),
++ av_q2d(metadata->display_primaries[1][1]),
++ av_q2d(metadata->display_primaries[2][0]),
++ av_q2d(metadata->display_primaries[2][1]),
++ av_q2d(metadata->white_point[0]), av_q2d(metadata->white_point[1]));
++ av_log(s->avctx, AV_LOG_DEBUG,
++ "min_luminance=%f, max_luminance=%f\n",
++ av_q2d(metadata->min_luminance), av_q2d(metadata->max_luminance));
++ }
++ // Decrement the mastering display flag when IRAP frame has no_rasl_output_flag=1
++ // so the side data persists for the entire coded video sequence.
++ if (s->sei.content_light.present > 0 &&
++ IS_IRAP(s) && s->no_rasl_output_flag) {
++ s->sei.content_light.present--;
++ }
++ if (s->sei.content_light.present) {
++ AVContentLightMetadata *metadata =
++ av_content_light_metadata_create_side_data(out);
++ if (!metadata)
++ return AVERROR(ENOMEM);
++ metadata->MaxCLL = s->sei.content_light.max_content_light_level;
++ metadata->MaxFALL = s->sei.content_light.max_pic_average_light_level;
++
++ av_log(s->avctx, AV_LOG_DEBUG, "Content Light Level Metadata:\n");
++ av_log(s->avctx, AV_LOG_DEBUG, "MaxCLL=%d, MaxFALL=%d\n",
++ metadata->MaxCLL, metadata->MaxFALL);
++ }
++
++ if (s->sei.a53_caption.a53_caption) {
++ AVFrameSideData* sd = av_frame_new_side_data(out,
++ AV_FRAME_DATA_A53_CC,
++ s->sei.a53_caption.a53_caption_size);
++ if (sd)
++ memcpy(sd->data, s->sei.a53_caption.a53_caption, s->sei.a53_caption.a53_caption_size);
++ av_freep(&s->sei.a53_caption.a53_caption);
++ s->sei.a53_caption.a53_caption_size = 0;
++ s->avctx->properties |= FF_CODEC_PROPERTY_CLOSED_CAPTIONS;
++ }
++
++ if (s->sei.alternative_transfer.present &&
++ av_color_transfer_name(s->sei.alternative_transfer.preferred_transfer_characteristics) &&
++ s->sei.alternative_transfer.preferred_transfer_characteristics != AVCOL_TRC_UNSPECIFIED) {
++ s->avctx->color_trc = out->color_trc = s->sei.alternative_transfer.preferred_transfer_characteristics;
++ }
++
++ return 0;
++}
++
++static int hevc_frame_start(HEVCRpiContext * const s)
++{
++ int ret;
++
++ memset(s->bs_horizontal, 0, s->bs_size * 2); // Does V too
++ memset(s->is_pcm, 0, s->ps.sps->pcm_width * s->ps.sps->pcm_height);
++ memset(s->tab_slice_address, -1, s->ps.sps->ctb_size * sizeof(*s->tab_slice_address));
++
++ // Only need to remember intra for CIP
++ if (!s->ps.pps->constrained_intra_pred_flag || s->is_irap)
++ s->is_intra = NULL;
++ else
++ {
++ s->is_intra = s->is_intra_store;
++ memset(s->is_intra, 0, s->ps.sps->pcm_width * s->ps.sps->pcm_height);
++ }
++
++ s->is_decoded = 0;
++ s->first_nal_type = s->nal_unit_type;
++
++ s->no_rasl_output_flag = IS_IDR(s) || IS_BLA(s) || (s->nal_unit_type == HEVC_NAL_CRA_NUT && s->last_eos);
++
++ if (s->pkt.nb_nals > s->rpl_tab_size)
++ {
++ // In most cases it will be faster to free & realloc as that doesn't
++ // require (an unwanted) copy
++ av_freep(&s->rpl_tab);
++ s->rpl_tab_size = 0;
++ if ((s->rpl_tab = av_malloc(s->pkt.nb_nals * sizeof(*s->rpl_tab))) == NULL)
++ goto fail;
++ s->rpl_tab_size = s->pkt.nb_nals;
++ }
++ memset(s->rpl_tab, 0, s->pkt.nb_nals * sizeof(*s->rpl_tab));
++
++ ret = ff_hevc_rpi_set_new_ref(s, &s->frame, s->poc);
++ if (ret < 0)
++ goto fail;
++
++ // Resize rpl_tab to max that we might want
++ ret = ff_hevc_rpi_frame_rps(s);
++ if (ret < 0) {
++ av_log(s->avctx, AV_LOG_ERROR, "Error constructing the frame RPS.\n");
++ goto fail;
++ }
++
++ s->ref->frame->key_frame = IS_IRAP(s);
++
++ ret = set_side_data(s);
++ if (ret < 0)
++ goto fail;
++
++ s->frame->pict_type = 3 - s->sh.slice_type;
++
++ if (!IS_IRAP(s))
++ ff_hevc_rpi_bump_frame(s);
++
++ av_frame_unref(s->output_frame);
++ ret = ff_hevc_rpi_output_frame(s, s->output_frame, 0);
++ if (ret < 0)
++ goto fail;
++
++ ff_thread_finish_setup(s->avctx);
++
++ return 0;
++
++fail:
++ if (s->ref)
++ ff_hevc_rpi_unref_frame(s, s->ref, ~0);
++ s->ref = NULL;
++ return ret;
++}
++
++static int decode_nal_unit(HEVCRpiContext *s, const H2645NAL *nal)
++{
++ GetBitContext * const gb = &s->HEVClc->gb;
++ int ctb_addr_ts, ret;
++
++ *gb = nal->gb;
++ s->nal_unit_type = nal->type;
++ s->temporal_id = nal->temporal_id;
++
++ switch (s->nal_unit_type) {
++ case HEVC_NAL_VPS:
++ ret = ff_hevc_rpi_decode_nal_vps(gb, s->avctx, &s->ps);
++ if (ret < 0)
++ goto fail;
++ break;
++ case HEVC_NAL_SPS:
++ ret = ff_hevc_rpi_decode_nal_sps(gb, s->avctx, &s->ps,
++ s->apply_defdispwin);
++ if (ret < 0)
++ goto fail;
++ break;
++ case HEVC_NAL_PPS:
++ ret = ff_hevc_rpi_decode_nal_pps(gb, s->avctx, &s->ps);
++ if (ret < 0)
++ goto fail;
++ break;
++ case HEVC_NAL_SEI_PREFIX:
++ case HEVC_NAL_SEI_SUFFIX:
++ ret = ff_hevc_rpi_decode_nal_sei(gb, s->avctx, &s->sei, &s->ps, s->nal_unit_type);
++ if (ret < 0)
++ goto fail;
++ break;
++ case HEVC_NAL_TRAIL_R:
++ case HEVC_NAL_TRAIL_N:
++ case HEVC_NAL_TSA_N:
++ case HEVC_NAL_TSA_R:
++ case HEVC_NAL_STSA_N:
++ case HEVC_NAL_STSA_R:
++ case HEVC_NAL_BLA_W_LP:
++ case HEVC_NAL_BLA_W_RADL:
++ case HEVC_NAL_BLA_N_LP:
++ case HEVC_NAL_IDR_W_RADL:
++ case HEVC_NAL_IDR_N_LP:
++ case HEVC_NAL_CRA_NUT:
++ case HEVC_NAL_RADL_N:
++ case HEVC_NAL_RADL_R:
++ case HEVC_NAL_RASL_N:
++ case HEVC_NAL_RASL_R:
++ ret = hls_slice_header(s);
++ if (ret < 0)
++ return ret;
++
++ // The definition of _N unit types is "non-reference for other frames
++ // with the same temporal_id" so they may/will be ref frames for pics
++ // with a higher temporal_id.
++ s->used_for_ref = s->ps.sps->max_sub_layers > s->temporal_id + 1 ||
++ !(s->nal_unit_type == HEVC_NAL_TRAIL_N ||
++ s->nal_unit_type == HEVC_NAL_TSA_N ||
++ s->nal_unit_type == HEVC_NAL_STSA_N ||
++ s->nal_unit_type == HEVC_NAL_RADL_N ||
++ s->nal_unit_type == HEVC_NAL_RASL_N);
++ s->offload_recon = s->threads_type != 0 && s->used_for_ref;
++ s->is_irap = IS_IRAP(s);
++
++#if DEBUG_DECODE_N
++ {
++ static int z = 0;
++ if (IS_IDR(s)) {
++ z = 1;
++ }
++ if (z != 0 && z++ > DEBUG_DECODE_N) {
++ s->is_decoded = 0;
++ break;
++ }
++ }
++#endif
++ if (
++ (s->avctx->skip_frame >= AVDISCARD_NONREF && !s->used_for_ref) ||
++ (s->avctx->skip_frame >= AVDISCARD_BIDIR && s->sh.slice_type == HEVC_SLICE_B) ||
++ (s->avctx->skip_frame >= AVDISCARD_NONINTRA && s->sh.slice_type != HEVC_SLICE_I) ||
++ (s->avctx->skip_frame >= AVDISCARD_NONKEY && !IS_IDR(s)))
++ {
++ s->is_decoded = 0;
++ break;
++ }
++
++ if (s->sh.first_slice_in_pic_flag) {
++ if (s->max_ra == INT_MAX) {
++ if (s->nal_unit_type == HEVC_NAL_CRA_NUT || IS_BLA(s)) {
++ s->max_ra = s->poc;
++ } else {
++ if (IS_IDR(s))
++ s->max_ra = INT_MIN;
++ }
++ }
++
++ if ((s->nal_unit_type == HEVC_NAL_RASL_R || s->nal_unit_type == HEVC_NAL_RASL_N) &&
++ s->poc <= s->max_ra) {
++ s->is_decoded = 0;
++ break;
++ } else {
++ if (s->nal_unit_type == HEVC_NAL_RASL_R && s->poc > s->max_ra)
++ s->max_ra = INT_MIN;
++ }
++
++ ret = hevc_frame_start(s);
++ if (ret < 0)
++ return ret;
++ } else if (!s->ref) {
++ av_log(s->avctx, AV_LOG_ERROR, "First slice in a frame missing.\n");
++ goto fail;
++ }
++
++ if (s->nal_unit_type != s->first_nal_type) {
++ av_log(s->avctx, AV_LOG_ERROR,
++ "Non-matching NAL types of the VCL NALUs: %d %d\n",
++ s->first_nal_type, s->nal_unit_type);
++ return AVERROR_INVALIDDATA;
++ }
++
++ if (!s->sh.dependent_slice_segment_flag &&
++ s->sh.slice_type != HEVC_SLICE_I) {
++ ret = ff_hevc_rpi_slice_rpl(s);
++ if (ret < 0) {
++ av_log(s->avctx, AV_LOG_WARNING,
++ "Error constructing the reference lists for the current slice.\n");
++ goto fail;
++ }
++ }
++
++ ctb_addr_ts = hls_slice_data(s, nal);
++ if (ctb_addr_ts >= s->ps.sps->ctb_size) {
++ s->is_decoded = 1;
++ }
++
++ if (ctb_addr_ts < 0) {
++ ret = ctb_addr_ts;
++ goto fail;
++ }
++ break;
++ case HEVC_NAL_EOS_NUT:
++ case HEVC_NAL_EOB_NUT:
++ s->seq_decode = (s->seq_decode + 1) & 0xff;
++ s->max_ra = INT_MAX;
++ break;
++ case HEVC_NAL_AUD:
++ case HEVC_NAL_FD_NUT:
++ break;
++ default:
++ av_log(s->avctx, AV_LOG_INFO,
++ "Skipping NAL unit %d\n", s->nal_unit_type);
++ }
++
++ return 0;
++fail:
++ if (s->avctx->err_recognition & AV_EF_EXPLODE)
++ return ret;
++ return 0;
++}
++
++static int decode_nal_units(HEVCRpiContext *s, const uint8_t *buf, int length)
++{
++ int i, ret = 0;
++ int eos_at_start = 1;
++
++ s->ref = NULL;
++ s->last_eos = s->eos;
++ s->eos = 0;
++
++ /* split the input packet into NAL units, so we know the upper bound on the
++ * number of slices in the frame */
++ ret = ff_h2645_packet_split(&s->pkt, buf, length, s->avctx, s->is_nalff,
++ s->nal_length_size, s->avctx->codec_id, 0);
++ if (ret < 0) {
++ av_log(s->avctx, AV_LOG_ERROR,
++ "Error splitting the input into NAL units.\n");
++ return ret;
++ }
++
++ for (i = 0; i < s->pkt.nb_nals; i++) {
++ if (s->pkt.nals[i].type == HEVC_NAL_EOB_NUT ||
++ s->pkt.nals[i].type == HEVC_NAL_EOS_NUT) {
++ if (eos_at_start) {
++ s->last_eos = 1;
++ } else {
++ s->eos = 1;
++ }
++ } else {
++ eos_at_start = 0;
++ }
++ }
++
++ /* decode the NAL units */
++ for (i = 0; i < s->pkt.nb_nals; i++) {
++ ret = decode_nal_unit(s, &s->pkt.nals[i]);
++ if (ret < 0) {
++ av_log(s->avctx, AV_LOG_WARNING,
++ "Error parsing NAL unit #%d.\n", i);
++ goto fail;
++ }
++ }
++
++fail: // Also success path
++ if (s->ref != NULL) {
++ if (s->used_for_ref && s->threads_type != 0) {
++ ff_hevc_rpi_progress_signal_all_done(s);
++ }
++ else {
++ // Flush frame to real memory as we expect to be able to pass
++ // it straight on to mmal
++ flush_frame(s, s->frame);
++ }
++ }
++ return ret;
++}
++
++static void print_md5(void *log_ctx, int level, uint8_t md5[16])
++{
++ int i;
++ for (i = 0; i < 16; i++)
++ av_log(log_ctx, level, "%02"PRIx8, md5[i]);
++}
++
++static int verify_md5(HEVCRpiContext *s, AVFrame *frame)
++{
++ const AVPixFmtDescriptor *desc = av_pix_fmt_desc_get(frame->format);
++ int pixel_shift;
++ int i, j;
++
++ if (!desc)
++ return AVERROR(EINVAL);
++
++ pixel_shift = desc->comp[0].depth > 8;
++
++ av_log(s->avctx, AV_LOG_DEBUG, "Verifying checksum for frame with POC %d: ",
++ s->poc);
++
++ /* the checksums are LE, so we have to byteswap for >8bpp formats
++ * on BE arches */
++#if HAVE_BIGENDIAN
++ if (pixel_shift && !s->checksum_buf) {
++ av_fast_malloc(&s->checksum_buf, &s->checksum_buf_size,
++ FFMAX3(frame->linesize[0], frame->linesize[1],
++ frame->linesize[2]));
++ if (!s->checksum_buf)
++ return AVERROR(ENOMEM);
++ }
++#endif
++
++ for (i = 0; frame->data[i]; i++) {
++ int width = s->avctx->coded_width;
++ int height = s->avctx->coded_height;
++ int w = (i == 1 || i == 2) ? (width >> desc->log2_chroma_w) : width;
++ int h = (i == 1 || i == 2) ? (height >> desc->log2_chroma_h) : height;
++ uint8_t md5[16];
++
++ av_md5_init(s->md5_ctx);
++ for (j = 0; j < h; j++) {
++ const uint8_t *src = frame->data[i] + j * frame_stride1(frame, 1);
++#if HAVE_BIGENDIAN
++ if (pixel_shift) {
++ s->bdsp.bswap16_buf((uint16_t *) s->checksum_buf,
++ (const uint16_t *) src, w);
++ src = s->checksum_buf;
++ }
++#endif
++ av_md5_update(s->md5_ctx, src, w << pixel_shift);
++ }
++ av_md5_final(s->md5_ctx, md5);
++
++ if (!memcmp(md5, s->sei.picture_hash.md5[i], 16)) {
++ av_log (s->avctx, AV_LOG_DEBUG, "plane %d - correct ", i);
++ print_md5(s->avctx, AV_LOG_DEBUG, md5);
++ av_log (s->avctx, AV_LOG_DEBUG, "; ");
++ } else {
++ av_log (s->avctx, AV_LOG_ERROR, "mismatching checksum of plane %d - ", i);
++ print_md5(s->avctx, AV_LOG_ERROR, md5);
++ av_log (s->avctx, AV_LOG_ERROR, " != ");
++ print_md5(s->avctx, AV_LOG_ERROR, s->sei.picture_hash.md5[i]);
++ av_log (s->avctx, AV_LOG_ERROR, "\n");
++ return AVERROR_INVALIDDATA;
++ }
++ }
++
++ av_log(s->avctx, AV_LOG_DEBUG, "\n");
++
++ return 0;
++}
++
++static int all_sps_supported(const HEVCRpiContext * const s)
++{
++ for (unsigned int i = 0; i < FF_ARRAY_ELEMS(s->ps.sps_list); i++) {
++ if (s->ps.sps_list[i] != NULL)
++ {
++ const HEVCRpiSPS * const sps = (const HEVCRpiSPS*)s->ps.sps_list[i]->data;
++ if (!is_sps_supported(sps))
++ return 0;
++ }
++ }
++ return 1;
++}
++
++static int hevc_rpi_decode_extradata(HEVCRpiContext *s, uint8_t *buf, int length, int first)
++{
++ int ret, i;
++
++ ret = ff_hevc_rpi_decode_extradata(buf, length, &s->ps, &s->sei, &s->is_nalff,
++ &s->nal_length_size, s->avctx->err_recognition,
++ s->apply_defdispwin, s->avctx);
++ if (ret < 0)
++ return ret;
++
++ /* export stream parameters from the first SPS */
++ for (i = 0; i < FF_ARRAY_ELEMS(s->ps.sps_list); i++) {
++ if (first && s->ps.sps_list[i]) {
++ const HEVCRpiSPS *sps = (const HEVCRpiSPS*)s->ps.sps_list[i]->data;
++ export_stream_params(s->avctx, &s->ps, sps);
++ break;
++ }
++ }
++
++ return 0;
++}
++
++static int hevc_rpi_decode_frame(AVCodecContext *avctx, void *data, int *got_output,
++ AVPacket *avpkt)
++{
++ int ret;
++ int new_extradata_size;
++ uint8_t *new_extradata;
++ HEVCRpiContext *s = avctx->priv_data;
++
++ if (!avpkt->size) {
++ ret = ff_hevc_rpi_output_frame(s, data, 1);
++ if (ret < 0)
++ return ret;
++
++ *got_output = ret;
++ return 0;
++ }
++
++ new_extradata = av_packet_get_side_data(avpkt, AV_PKT_DATA_NEW_EXTRADATA,
++ &new_extradata_size);
++ if (new_extradata && new_extradata_size > 0) {
++ ret = hevc_rpi_decode_extradata(s, new_extradata, new_extradata_size, 0);
++ if (ret < 0)
++ return ret;
++ }
++
++ s->ref = NULL;
++ ret = decode_nal_units(s, avpkt->data, avpkt->size);
++ if (ret < 0)
++ return ret;
++
++ /* verify the SEI checksum */
++ if (avctx->err_recognition & AV_EF_CRCCHECK && s->is_decoded &&
++ s->sei.picture_hash.is_md5) {
++ ret = verify_md5(s, s->ref->frame);
++ if (ret < 0 && avctx->err_recognition & AV_EF_EXPLODE) {
++ ff_hevc_rpi_unref_frame(s, s->ref, ~0);
++ return ret;
++ }
++ }
++ s->sei.picture_hash.is_md5 = 0;
++
++ if (s->is_decoded) {
++ av_log(avctx, AV_LOG_DEBUG, "Decoded frame with POC %d.\n", s->poc);
++ s->is_decoded = 0;
++ }
++
++ if (s->output_frame->buf[0]) {
++ av_frame_move_ref(data, s->output_frame);
++ *got_output = 1;
++ }
++
++ return avpkt->size;
++}
++
++static int hevc_ref_frame(HEVCRpiContext *s, HEVCRpiFrame *dst, HEVCRpiFrame *src)
++{
++ int ret;
++
++ ret = ff_thread_ref_frame(&dst->tf, &src->tf);
++ if (ret < 0)
++ return ret;
++
++ if (src->col_mvf_buf != NULL)
++ {
++ dst->col_mvf_buf = av_buffer_ref(src->col_mvf_buf);
++ if (!dst->col_mvf_buf)
++ goto fail;
++ }
++ dst->col_mvf = src->col_mvf;
++
++ dst->poc = src->poc;
++ dst->flags = src->flags;
++ dst->sequence = src->sequence;
++ return 0;
++
++fail:
++ ff_hevc_rpi_unref_frame(s, dst, ~0);
++ return AVERROR(ENOMEM);
++}
++
++
++static av_cold int hevc_decode_free(AVCodecContext *avctx)
++{
++ HEVCRpiContext * const s = avctx->priv_data;
++ int i;
++
++ pic_arrays_free(s);
++
++ av_freep(&s->md5_ctx);
++
++ av_freep(&s->cabac_save);
++
++#if RPI_EXTRA_BIT_THREADS
++ bit_threads_kill(s);
++#endif
++
++ hevc_exit_worker(s);
++ vpu_qpu_term();
++ for (i = 0; i != 2; ++i) {
++ ff_hevc_rpi_progress_kill_state(s->progress_states + i);
++ }
++ job_lc_kill(s->HEVClc);
++
++ av_freep(&s->sao_pixel_buffer_h[0]); // [1] & [2] allocated with [0]
++ av_freep(&s->sao_pixel_buffer_v[0]);
++ av_frame_free(&s->output_frame);
++
++ for (i = 0; i < FF_ARRAY_ELEMS(s->DPB); i++) {
++ ff_hevc_rpi_unref_frame(s, &s->DPB[i], ~0);
++ av_frame_free(&s->DPB[i].frame);
++ }
++
++ for (i = 0; i < FF_ARRAY_ELEMS(s->ps.vps_list); i++)
++ av_buffer_unref(&s->ps.vps_list[i]);
++ for (i = 0; i < FF_ARRAY_ELEMS(s->ps.sps_list); i++)
++ av_buffer_unref(&s->ps.sps_list[i]);
++ for (i = 0; i < FF_ARRAY_ELEMS(s->ps.pps_list); i++)
++ av_buffer_unref(&s->ps.pps_list[i]);
++ s->ps.sps = NULL;
++ s->ps.pps = NULL;
++ s->ps.vps = NULL;
++
++ // Free separately from sLists as used that way by RPI WPP
++ for (i = 0; i < MAX_NB_THREADS && s->HEVClcList[i] != NULL; ++i) {
++ av_freep(s->HEVClcList + i);
++ }
++ s->HEVClc = NULL; // Allocated as part of HEVClcList
++
++ ff_h2645_packet_uninit(&s->pkt);
++
++ // This must be after we free off the DPB
++ // * If the outer code is still holding any frames hopefully it will
++ // have its own ref to zc
++ av_rpi_zc_uninit(avctx);
++
++ return 0;
++}
++
++
++static av_cold int hevc_init_context(AVCodecContext *avctx)
++{
++ HEVCRpiContext *s = avctx->priv_data;
++ int i;
++
++ s->avctx = avctx;
++
++ s->HEVClc = av_mallocz(sizeof(HEVCRpiLocalContext));
++ if (!s->HEVClc)
++ goto fail;
++ s->HEVClcList[0] = s->HEVClc;
++
++ // Whilst FFmpegs init fn is only called once the close fn is called as
++ // many times as we have threads (init_thread_copy is called for the
++ // threads). So to match init & term put the init here where it will be
++ // called by both init & copy
++ av_rpi_zc_init(avctx);
++
++ if (vpu_qpu_init() != 0)
++ goto fail;
++
++#if RPI_QPU_EMU_Y || RPI_QPU_EMU_C
++ {
++ static const uint32_t dframe[1] = {0x80808080};
++ s->qpu_dummy_frame_emu = (const uint8_t *)dframe;
++ }
++#endif
++#if !RPI_QPU_EMU_Y || !RPI_QPU_EMU_C
++ s->qpu_dummy_frame_qpu = qpu_dummy();
++#endif
++
++ bt_lc_init(s, s->HEVClc, 0);
++ job_lc_init(s->HEVClc);
++
++ for (i = 0; i != 2; ++i) {
++ ff_hevc_rpi_progress_init_state(s->progress_states + i);
++ }
++
++ if ((s->cabac_save = av_malloc(sizeof(*s->cabac_save))) == NULL)
++ goto fail;
++
++ if ((s->output_frame = av_frame_alloc()) == NULL)
++ goto fail;
++
++ for (i = 0; i < FF_ARRAY_ELEMS(s->DPB); i++) {
++ s->DPB[i].frame = av_frame_alloc();
++ if (!s->DPB[i].frame)
++ goto fail;
++ s->DPB[i].tf.f = s->DPB[i].frame;
++ s->DPB[i].dpb_no = i;
++ }
++
++ s->max_ra = INT_MAX;
++
++ if ((s->md5_ctx = av_md5_alloc()) == NULL)
++ goto fail;
++
++ s->context_initialized = 1;
++ s->eos = 0;
++
++ ff_hevc_rpi_reset_sei(&s->sei);
++
++ return 0;
++
++fail:
++ av_log(s->avctx, AV_LOG_ERROR, "%s: Failed\n", __func__);
++ hevc_decode_free(avctx);
++ return AVERROR(ENOMEM);
++}
++
++static int hevc_update_thread_context(AVCodecContext *dst,
++ const AVCodecContext *src)
++{
++ HEVCRpiContext *s = dst->priv_data;
++ HEVCRpiContext *s0 = src->priv_data;
++ int i, ret;
++
++ if (!s->context_initialized) {
++ ret = hevc_init_context(dst);
++ if (ret < 0)
++ return ret;
++ }
++
++ for (i = 0; i < FF_ARRAY_ELEMS(s->DPB); i++) {
++ ff_hevc_rpi_unref_frame(s, &s->DPB[i], ~0);
++ if (s0->DPB[i].frame->buf[0]) {
++ ret = hevc_ref_frame(s, &s->DPB[i], &s0->DPB[i]);
++ if (ret < 0)
++ return ret;
++ }
++ }
++
++ if (s->ps.sps != s0->ps.sps)
++ s->ps.sps = NULL;
++ for (i = 0; i < FF_ARRAY_ELEMS(s->ps.vps_list); i++) {
++ av_buffer_unref(&s->ps.vps_list[i]);
++ if (s0->ps.vps_list[i]) {
++ s->ps.vps_list[i] = av_buffer_ref(s0->ps.vps_list[i]);
++ if (!s->ps.vps_list[i])
++ return AVERROR(ENOMEM);
++ }
++ }
++
++ for (i = 0; i < FF_ARRAY_ELEMS(s->ps.sps_list); i++) {
++ av_buffer_unref(&s->ps.sps_list[i]);
++ if (s0->ps.sps_list[i]) {
++ s->ps.sps_list[i] = av_buffer_ref(s0->ps.sps_list[i]);
++ if (!s->ps.sps_list[i])
++ return AVERROR(ENOMEM);
++ }
++ }
++
++ for (i = 0; i < FF_ARRAY_ELEMS(s->ps.pps_list); i++) {
++ av_buffer_unref(&s->ps.pps_list[i]);
++ if (s0->ps.pps_list[i]) {
++ s->ps.pps_list[i] = av_buffer_ref(s0->ps.pps_list[i]);
++ if (!s->ps.pps_list[i])
++ return AVERROR(ENOMEM);
++ }
++ }
++
++ if (s->ps.sps != s0->ps.sps)
++ if ((ret = set_sps(s, s0->ps.sps, src->pix_fmt)) < 0)
++ return ret;
++
++ s->seq_decode = s0->seq_decode;
++ s->seq_output = s0->seq_output;
++ s->pocTid0 = s0->pocTid0;
++ s->max_ra = s0->max_ra;
++ s->eos = s0->eos;
++ s->no_rasl_output_flag = s0->no_rasl_output_flag;
++
++ s->is_nalff = s0->is_nalff;
++ s->nal_length_size = s0->nal_length_size;
++
++ s->threads_type = s0->threads_type;
++
++ if (s0->eos) {
++ s->seq_decode = (s->seq_decode + 1) & 0xff;
++ s->max_ra = INT_MAX;
++ }
++
++ s->sei.frame_packing = s0->sei.frame_packing;
++ s->sei.display_orientation = s0->sei.display_orientation;
++ s->sei.mastering_display = s0->sei.mastering_display;
++ s->sei.content_light = s0->sei.content_light;
++ s->sei.alternative_transfer = s0->sei.alternative_transfer;
++
++ // * We do this here as it allows us to easily locate our parents
++ // global job pool, but there really should be a less nasty way
++ if (s->jbc == NULL)
++ {
++ av_assert0((s->jbc = rpi_job_ctl_new(s0->jbc->jbg)) != NULL);
++ hevc_init_worker(s);
++ }
++
++ return 0;
++}
++
++static av_cold int hevc_decode_init(AVCodecContext *avctx)
++{
++ HEVCRpiContext *s = avctx->priv_data;
++ int ret;
++
++ avctx->internal->allocate_progress = 1;
++
++ {
++ HEVCRpiJobGlobal * const jbg = jbg_new(FFMAX(avctx->thread_count * 3, 5));
++ if (jbg == NULL)
++ {
++ av_log(s->avctx, AV_LOG_ERROR, "%s: Job global init failed\n", __func__);
++ return -1;
++ }
++
++ if ((s->jbc = rpi_job_ctl_new(jbg)) == NULL)
++ {
++ av_log(s->avctx, AV_LOG_ERROR, "%s: Job ctl init failed\n", __func__);
++ return -1;
++ }
++ }
++
++ ret = hevc_init_context(avctx);
++ if (ret < 0)
++ return ret;
++
++ hevc_init_worker(s);
++
++ s->sei.picture_timing.picture_struct = 0;
++ s->eos = 1;
++
++ atomic_init(&s->wpp_err, 0);
++
++ if (avctx->extradata_size > 0 && avctx->extradata) {
++ ret = hevc_rpi_decode_extradata(s, avctx->extradata, avctx->extradata_size, 1);
++
++ if (ret == 0 && !all_sps_supported(s))
++ ret = AVERROR_DECODER_NOT_FOUND;
++
++ if (ret < 0)
++ {
++ hevc_decode_free(avctx);
++ return ret;
++ }
++ }
++
++ if((avctx->active_thread_type & FF_THREAD_FRAME) && avctx->thread_count > 1)
++ s->threads_type = FF_THREAD_FRAME;
++ else
++ s->threads_type = 0;
++
++ return 0;
++}
++
++static av_cold int hevc_init_thread_copy(AVCodecContext *avctx)
++{
++ HEVCRpiContext *s = avctx->priv_data;
++ int ret;
++
++ memset(s, 0, sizeof(*s));
++
++ ret = hevc_init_context(avctx);
++ if (ret < 0)
++ return ret;
++
++ return 0;
++}
++
++static void hevc_decode_flush(AVCodecContext *avctx)
++{
++ HEVCRpiContext *s = avctx->priv_data;
++ ff_hevc_rpi_flush_dpb(s);
++ s->max_ra = INT_MAX;
++ s->eos = 1;
++}
++
++#define OFFSET(x) offsetof(HEVCRpiContext, x)
++#define PAR (AV_OPT_FLAG_DECODING_PARAM | AV_OPT_FLAG_VIDEO_PARAM)
++
++
++static const AVOption options[] = {
++ { "apply_defdispwin", "Apply default display window from VUI", OFFSET(apply_defdispwin),
++ AV_OPT_TYPE_BOOL, {.i64 = 0}, 0, 1, PAR },
++ { "strict-displaywin", "stricly apply default display window size", OFFSET(apply_defdispwin),
++ AV_OPT_TYPE_BOOL, {.i64 = 0}, 0, 1, PAR },
++ { NULL },
++};
++
++static const AVClass hevc_rpi_decoder_class = {
++ .class_name = "HEVC RPI decoder",
++ .item_name = av_default_item_name,
++ .option = options,
++ .version = LIBAVUTIL_VERSION_INT,
++};
++
++static const enum AVPixelFormat hevc_rpi_pix_fmts[] = {
++ AV_PIX_FMT_SAND128,
++ AV_PIX_FMT_SAND64_10,
++ AV_PIX_FMT_NONE
++};
++
++//static const AVCodecHWConfigInternal *hevc_rpi_hw_configs[] = {
++// HW_CONFIG_INTERNAL(HEVC_RPI),
++// NULL
++//};
++
++
++AVCodec ff_hevc_rpi_decoder = {
++ .name = "hevc_rpi",
++ .long_name = NULL_IF_CONFIG_SMALL("HEVC (rpi)"),
++ .type = AVMEDIA_TYPE_VIDEO,
++ .id = AV_CODEC_ID_HEVC,
++ .priv_data_size = sizeof(HEVCRpiContext),
++ .priv_class = &hevc_rpi_decoder_class,
++ .init = hevc_decode_init,
++ .close = hevc_decode_free,
++ .decode = hevc_rpi_decode_frame,
++ .flush = hevc_decode_flush,
++ .update_thread_context = hevc_update_thread_context,
++ .init_thread_copy = hevc_init_thread_copy,
++ .capabilities = AV_CODEC_CAP_DR1 | AV_CODEC_CAP_DELAY |
++// AV_CODEC_CAP_HARDWARE |
++#if 0
++ // Debugging is often easier without threads getting in the way
++ 0,
++#warning H265 threading turned off
++#else
++ // We only have decent optimisation for frame - so only admit to that
++ AV_CODEC_CAP_FRAME_THREADS,
++#endif
++ .caps_internal = FF_CODEC_CAP_INIT_THREADSAFE | FF_CODEC_CAP_EXPORTS_CROPPING,
++ .pix_fmts = hevc_rpi_pix_fmts,
++ .profiles = NULL_IF_CONFIG_SMALL(ff_hevc_profiles),
++// .hw_configs = hevc_rpi_hw_configs,
++// .wrapper_name = "hevc_rpi",
++};
++
+diff --git a/libavcodec/rpi_hevcdec.h b/libavcodec/rpi_hevcdec.h
+new file mode 100644
+index 0000000000..d324aa273c
+--- /dev/null
++++ b/libavcodec/rpi_hevcdec.h
+@@ -0,0 +1,1087 @@
++/*
++ * HEVC video decoder
++ *
++ * Copyright (C) 2012 - 2013 Guillaume Martres
++ *
++ * This file is part of FFmpeg.
++ *
++ * FFmpeg is free software; you can redistribute it and/or
++ * modify it under the terms of the GNU Lesser General Public
++ * License as published by the Free Software Foundation; either
++ * version 2.1 of the License, or (at your option) any later version.
++ *
++ * FFmpeg is distributed in the hope that it will be useful,
++ * but WITHOUT ANY WARRANTY; without even the implied warranty of
++ * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
++ * Lesser General Public License for more details.
++ *
++ * You should have received a copy of the GNU Lesser General Public
++ * License along with FFmpeg; if not, write to the Free Software
++ * Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA
++ */
++
++#ifndef AVCODEC_RPI_HEVCDEC_H
++#define AVCODEC_RPI_HEVCDEC_H
++
++#include "config.h"
++
++#include <stdatomic.h>
++
++#include "libavutil/buffer.h"
++
++#include "avcodec.h"
++#include "bswapdsp.h"
++#include "cabac.h"
++#include "get_bits.h"
++#include "rpi_hevcpred.h"
++#include "h2645_parse.h"
++#include "hevc.h"
++#include "rpi_hevc_mv.h"
++#include "rpi_hevc_ps.h"
++#include "rpi_hevc_sei.h"
++#include "rpi_hevcdsp.h"
++#include "internal.h"
++#include "thread.h"
++#include "videodsp.h"
++
++#if ARCH_ARM
++#include "arm/rpi_hevc_misc_neon.h"
++#endif
++
++#define MAX_NB_THREADS 16
++#define SHIFT_CTB_WPP 2
++
++//TODO: check if this is really the maximum
++#define MAX_TRANSFORM_DEPTH 5
++
++#define MAX_TB_SIZE 32
++#define MAX_QP 51
++#define DEFAULT_INTRA_TC_OFFSET 2
++
++#define HEVC_CONTEXTS 199
++
++#define MRG_MAX_NUM_CANDS 5
++
++#define HEVC_MAX_CTB_SIZE (1 << HEVC_MAX_LOG2_CTB_SIZE) // 64
++
++// Size of DPB array
++#define HEVC_DPB_ELS 32
++
++#define L0 0
++#define L1 1
++
++#define EPEL_EXTRA_BEFORE 1
++#define EPEL_EXTRA_AFTER 2
++#define EPEL_EXTRA 3
++#define QPEL_EXTRA_BEFORE 3
++#define QPEL_EXTRA_AFTER 4
++#define QPEL_EXTRA 7
++
++#define EDGE_EMU_BUFFER_STRIDE 80
++
++#include <semaphore.h>
++#include "rpi_qpu.h"
++
++// Max jobs per frame thread. Actual usage will be limited by the size
++// of the global job pool
++// ?? Limits
++#define RPI_MAX_JOBS 8
++
++// This is the number of _extra_ bit threads - we will have
++// RPI_EXTRA_BIT_THREADS+1 threads actually doing the processing
++//
++// 0 is legitimate and will disable our WPP processing
++//#define RPI_EXTRA_BIT_THREADS 0
++#define RPI_EXTRA_BIT_THREADS 2
++
++// Number of separate threads/passes in worker
++// 2 and 3 are the currently valid numbers
++// At the moment 3 seems fractionally faster
++//#define RPI_PASSES 2
++#define RPI_PASSES 3
++
++// Print out various usage stats
++#define RPI_TSTATS 0
++
++// Define RPI_COMPRESS_COEFFS to 1 to send coefficients in compressed form
++#define RPI_COMPRESS_COEFFS 1
++
++// Wait for VPU/QPU to finish in worker pass 0
++// If 0 then the wait is in pass 1
++//
++// One might expect the better place to wait would be in pass 1 however
++// testing shows that pass 0 produces overall faster decode.
++// Interestingly it is QPU/VPU limited streams that seem to suffer
++// from pass 1 waits, CPU limited ones tend to show a very mild gain.
++// This define exists so it is easy to test this.
++#define RPI_WORKER_WAIT_PASS_0 1
++
++// Use ARM emulation of QPU pred
++// These are for debug only as the emulation makes only limited
++// effort to be fast
++#define RPI_QPU_EMU_Y 0
++#define RPI_QPU_EMU_C 0
++
++// Max width & height we are prepared to consider
++// Sand frame shape calc becomes confused with large frames
++// Some buffer alloc also depends on this
++#define HEVC_RPI_MAX_WIDTH 2048
++#define HEVC_RPI_MAX_HEIGHT 1088
++
++
++// Min CTB size is 16
++#define HEVC_RPI_MAX_CTBS ((HEVC_RPI_MAX_WIDTH + 15) / 16) * ((HEVC_RPI_MAX_HEIGHT + 15) / 16)
++
++/**
++ * Value of the luma sample at position (x, y) in the 2D array tab.
++ */
++#define SAMPLE(tab, x, y) ((tab)[(y) * s->sps->width + (x)])
++#define SAMPLE_CTB(tab, x, y) ((tab)[(y) * min_cb_width + (x)])
++
++#define IS_IDR(s) ((s)->nal_unit_type == HEVC_NAL_IDR_W_RADL || (s)->nal_unit_type == HEVC_NAL_IDR_N_LP)
++#define IS_BLA(s) ((s)->nal_unit_type == HEVC_NAL_BLA_W_RADL || (s)->nal_unit_type == HEVC_NAL_BLA_W_LP || \
++ (s)->nal_unit_type == HEVC_NAL_BLA_N_LP)
++#define IS_IRAP(s) ((s)->nal_unit_type >= 16 && (s)->nal_unit_type <= 23)
++
++enum RPSType {
++ ST_CURR_BEF = 0,
++ ST_CURR_AFT,
++ ST_FOLL,
++ LT_CURR,
++ LT_FOLL,
++ NB_RPS_TYPE,
++};
++
++enum SyntaxElement {
++ SAO_MERGE_FLAG = 0,
++ SAO_TYPE_IDX,
++ SAO_EO_CLASS,
++ SAO_BAND_POSITION,
++ SAO_OFFSET_ABS,
++ SAO_OFFSET_SIGN,
++ END_OF_SLICE_FLAG,
++ SPLIT_CODING_UNIT_FLAG,
++ CU_TRANSQUANT_BYPASS_FLAG,
++ SKIP_FLAG,
++ CU_QP_DELTA,
++ PRED_MODE_FLAG,
++ PART_MODE,
++ PCM_FLAG,
++ PREV_INTRA_LUMA_PRED_FLAG,
++ MPM_IDX,
++ REM_INTRA_LUMA_PRED_MODE,
++ INTRA_CHROMA_PRED_MODE,
++ MERGE_FLAG,
++ MERGE_IDX,
++ INTER_PRED_IDC,
++ REF_IDX_L0,
++ REF_IDX_L1,
++ ABS_MVD_GREATER0_FLAG,
++ ABS_MVD_GREATER1_FLAG,
++ ABS_MVD_MINUS2,
++ MVD_SIGN_FLAG,
++ MVP_LX_FLAG,
++ NO_RESIDUAL_DATA_FLAG,
++ SPLIT_TRANSFORM_FLAG,
++ CBF_LUMA,
++ CBF_CB_CR,
++ TRANSFORM_SKIP_FLAG,
++ EXPLICIT_RDPCM_FLAG,
++ EXPLICIT_RDPCM_DIR_FLAG,
++ LAST_SIGNIFICANT_COEFF_X_PREFIX,
++ LAST_SIGNIFICANT_COEFF_Y_PREFIX,
++ LAST_SIGNIFICANT_COEFF_X_SUFFIX,
++ LAST_SIGNIFICANT_COEFF_Y_SUFFIX,
++ SIGNIFICANT_COEFF_GROUP_FLAG,
++ SIGNIFICANT_COEFF_FLAG,
++ COEFF_ABS_LEVEL_GREATER1_FLAG,
++ COEFF_ABS_LEVEL_GREATER2_FLAG,
++ COEFF_ABS_LEVEL_REMAINING,
++ COEFF_SIGN_FLAG,
++ LOG2_RES_SCALE_ABS,
++ RES_SCALE_SIGN_FLAG,
++ CU_CHROMA_QP_OFFSET_FLAG,
++ CU_CHROMA_QP_OFFSET_IDX,
++};
++
++enum PartMode {
++ PART_2Nx2N = 0,
++ PART_2NxN = 1,
++ PART_Nx2N = 2,
++ PART_NxN = 3,
++ PART_2NxnU = 4,
++ PART_2NxnD = 5,
++ PART_nLx2N = 6,
++ PART_nRx2N = 7,
++};
++
++enum PredMode {
++ MODE_INTER = 0,
++ MODE_INTRA,
++ MODE_SKIP,
++};
++
++enum InterPredIdc {
++ PRED_L0 = 0,
++ PRED_L1,
++ PRED_BI,
++};
++
++enum PredFlag {
++ PF_INTRA = 0,
++ PF_L0,
++ PF_L1,
++ PF_BI,
++};
++
++enum SAOType {
++ SAO_NOT_APPLIED = 0,
++ SAO_BAND,
++ SAO_EDGE,
++ SAO_APPLIED
++};
++
++enum SAOEOClass {
++ SAO_EO_HORIZ = 0,
++ SAO_EO_VERT,
++ SAO_EO_135D,
++ SAO_EO_45D,
++};
++
++enum ScanType {
++ SCAN_DIAG = 0,
++ SCAN_HORIZ,
++ SCAN_VERT,
++};
++
++typedef struct RefPicList {
++ struct HEVCRpiFrame *ref[HEVC_MAX_REFS];
++ int list[HEVC_MAX_REFS];
++ uint8_t isLongTerm[HEVC_MAX_REFS];
++ int nb_refs;
++} RefPicList;
++
++typedef struct RefPicListTab {
++ RefPicList refPicList[2];
++} RefPicListTab;
++
++typedef struct RpiCodingUnit {
++ unsigned int x; // Passed to deblock
++ unsigned int y;
++ unsigned int x_split;
++ unsigned int y_split;
++
++ enum PredMode pred_mode; ///< PredMode
++ enum PartMode part_mode; ///< PartMode
++
++ // Inferred parameters
++ uint8_t intra_split_flag; ///< IntraSplitFlag
++ uint8_t max_trafo_depth; ///< MaxTrafoDepth
++ uint8_t cu_transquant_bypass_flag;
++} RpiCodingUnit;
++
++typedef struct RpiPredictionUnit {
++ uint8_t intra_pred_mode[4];
++ uint8_t intra_pred_mode_c[4];
++ uint8_t chroma_mode_c[4];
++ uint8_t merge_flag;
++} RpiPredictionUnit;
++
++typedef struct HEVCRpiTransformUnit {
++ int8_t cu_qp_delta;
++
++ // Inferred parameters;
++ uint8_t intra_pred_mode;
++ uint8_t intra_pred_mode_c;
++ uint8_t chroma_mode_c;
++ uint8_t is_cu_qp_delta_wanted;
++ uint8_t cu_chroma_qp_offset_wanted;
++ const int8_t * qp_divmod6[3];
++} HEVCRpiTransformUnit;
++
++typedef struct DBParams {
++ int8_t beta_offset; // -12 to +12
++ int8_t tc_offset; // -12 to +12
++} DBParams;
++
++#define HEVC_FRAME_FLAG_OUTPUT (1 << 0)
++#define HEVC_FRAME_FLAG_SHORT_REF (1 << 1)
++#define HEVC_FRAME_FLAG_LONG_REF (1 << 2)
++#define HEVC_FRAME_FLAG_BUMPING (1 << 3)
++
++struct HEVCRpiJob;
++
++typedef struct HEVCRpiFrame {
++ AVFrame *frame;
++ ThreadFrame tf;
++ ColMvField *col_mvf;
++ int poc;
++ struct HEVCRpiFrame *collocated_ref;
++
++ AVBufferRef *col_mvf_buf;
++
++ /**
++ * A sequence counter, so that old frames are output first
++ * after a POC reset
++ */
++ uint16_t sequence;
++
++ /**
++ * A combination of HEVC_FRAME_FLAG_*
++ */
++ uint8_t flags;
++
++ // Entry no in DPB - can be used as a small unique
++ // frame identifier (within the current thread)
++ uint8_t dpb_no;
++} HEVCRpiFrame;
++
++typedef struct HEVCRpiLocalContext {
++ HEVCRpiTransformUnit tu;
++
++ CABACContext cc;
++
++ // Vars that allow us to locate everything from just an lc
++ struct HEVCRpiContext * context; // ??? make const ???
++ unsigned int lc_n; // lc list el no
++
++ // Job wait links
++ struct HEVCRpiLocalContext * jw_next;
++ struct HEVCRpiLocalContext * jw_prev;
++ struct HEVCRpiLocalContext * ljw_next;
++ struct HEVCRpiLocalContext * ljw_prev;
++ struct HEVCRpiJob * volatile jw_job;
++ sem_t jw_sem;
++
++ // ?? Wrap in structure ??
++ sem_t bt_sem_in;
++ sem_t * bt_psem_out;
++ volatile int bt_terminate;
++ unsigned int ts;
++ unsigned int bt_last_line; // Last line in this bit_thread chunk
++ unsigned int bt_line_no;
++ unsigned int bt_line_width;
++ unsigned int bt_line_inc;
++
++ struct HEVCRpiJob * jb0;
++ char unit_done; // Set once we have dealt with this slice
++ char bt_is_tile;
++ char last_progress_good;
++ char cabac_init_req;
++
++ uint8_t cabac_state[HEVC_CONTEXTS];
++ uint8_t stat_coeff[4];
++ GetBitContext gb;
++
++ uint8_t ct_depth;
++ int8_t qp_y;
++ int8_t curr_qp_y;
++ int8_t qPy_pred;
++
++// N.B. Used by asm (neon) - do not change
++#define AVAIL_S_UR 0
++#define AVAIL_S_U 1
++#define AVAIL_S_UL 2
++#define AVAIL_S_L 3
++#define AVAIL_S_DL 4
++
++#define AVAIL_U (1 << AVAIL_S_U)
++#define AVAIL_L (1 << AVAIL_S_L)
++#define AVAIL_UL (1 << AVAIL_S_UL)
++#define AVAIL_UR (1 << AVAIL_S_UR)
++#define AVAIL_DL (1 << AVAIL_S_DL)
++
++ uint8_t ctb_avail;
++ int end_of_ctb_x;
++ int end_of_ctb_y;
++
++ RpiCodingUnit cu;
++ RpiPredictionUnit pu;
++
++#define BOUNDARY_LEFT_SLICE (1 << 0)
++#define BOUNDARY_LEFT_TILE (1 << 1)
++#define BOUNDARY_UPPER_SLICE (1 << 2)
++#define BOUNDARY_UPPER_TILE (1 << 3)
++ /* properties of the boundary of the current CTB for the purposes
++ * of the deblocking filter */
++ unsigned int boundary_flags;
++
++#define IPM_TAB_SIZE (HEVC_MAX_CTB_SIZE >> LOG2_MIN_PU_SIZE)
++ uint8_t ipm_left[IPM_TAB_SIZE];
++ uint8_t ipm_up[IPM_TAB_SIZE];
++
++//#define MVF_STASH_WIDTH 128
++#define MVF_STASH_WIDTH 64
++#define MVF_STASH_HEIGHT 64
++#define MVF_STASH_WIDTH_PU (MVF_STASH_WIDTH >> LOG2_MIN_PU_SIZE)
++#define MVF_STASH_HEIGHT_PU (MVF_STASH_HEIGHT >> LOG2_MIN_PU_SIZE)
++ HEVCRpiMvField mvf_ul[1];
++ HEVCRpiMvField mvf_stash[MVF_STASH_WIDTH_PU * MVF_STASH_HEIGHT_PU];
++
++ /* +7 is for subpixel interpolation, *2 for high bit depths */
++// DECLARE_ALIGNED(32, uint8_t, edge_emu_buffer)[(MAX_PB_SIZE + 7) * EDGE_EMU_BUFFER_STRIDE * 2];
++ /* The extended size between the new edge emu buffer is abused by SAO */
++// DECLARE_ALIGNED(32, uint8_t, edge_emu_buffer2)[(MAX_PB_SIZE + 7) * EDGE_EMU_BUFFER_STRIDE * 2];
++// DECLARE_ALIGNED(32, int16_t, tmp [MAX_PB_SIZE * MAX_PB_SIZE]);
++
++} HEVCRpiLocalContext;
++
++// Each block can have an intra prediction and an add_residual command
++// noof-cmds(2) * max-ctu height(64) / min-transform(4) * planes(3) * MAX_WIDTH
++
++// Sand only has 2 planes (Y/C)
++#define RPI_MAX_PRED_CMDS (2*(HEVC_MAX_CTB_SIZE/4)*2*(HEVC_RPI_MAX_WIDTH/4))
++
++// Command for intra prediction and transform_add of predictions to coefficients
++enum rpi_pred_cmd_e
++{
++ RPI_PRED_ADD_RESIDUAL,
++ RPI_PRED_ADD_RESIDUAL_U, // = RPI_PRED_TRANSFORM_ADD + c_idx
++ RPI_PRED_ADD_RESIDUAL_V, // = RPI_PRED_TRANSFORM_ADD + c_idx
++ RPI_PRED_ADD_RESIDUAL_C, // Merged U+V
++ RPI_PRED_ADD_DC,
++ RPI_PRED_ADD_DC_U, // Both U & V are effectively C
++ RPI_PRED_ADD_DC_V,
++ RPI_PRED_INTRA,
++ RPI_PRED_INTRA_C,
++ RPI_PRED_I_PCM,
++ RPI_PRED_CMD_MAX
++};
++
++typedef struct HEVCPredCmd {
++ uint8_t type;
++ uint8_t size; // log2 "size" used by all variants
++ uint8_t avail; // i_pred - but left here as they pack well
++ uint8_t dummy;
++ union {
++ struct { // TRANSFORM_ADD
++ uint8_t * dst;
++ const int16_t * buf;
++ uint16_t stride; // Should be good enough for all pic fmts we use
++ int16_t dc;
++ } ta;
++ struct {
++ uint8_t * dst;
++ uint32_t stride;
++ int dc;
++ } dc;
++ struct { // INTRA
++ uint16_t x;
++ uint16_t y;
++ enum IntraPredMode mode;
++ } i_pred;
++ struct { // I_PCM
++ uint16_t x;
++ uint16_t y;
++ const void * src;
++ uint32_t src_len;
++ } i_pcm;
++ };
++} HEVCPredCmd;
++
++union qpu_mc_pred_cmd_s;
++struct qpu_mc_pred_y_p_s;
++struct qpu_mc_src_s;
++
++typedef struct HEVCRpiInterPredQ
++{
++ union qpu_mc_pred_cmd_u *qpu_mc_base;
++ union qpu_mc_pred_cmd_u *qpu_mc_curr;
++ struct qpu_mc_src_s *last_l0;
++ struct qpu_mc_src_s *last_l1;
++ unsigned int load;
++ uint32_t code_setup;
++ uint32_t code_sync;
++ uint32_t code_exit;
++} HEVCRpiInterPredQ;
++
++typedef struct HEVCRpiInterPredEnv
++{
++ HEVCRpiInterPredQ * q;
++ uint8_t n; // Number of Qs
++ uint8_t n_grp; // Number of Q in a group
++ uint8_t curr; // Current Q number (0..n-1)
++ uint8_t used; // 0 if nothing in any Q, 1 otherwise
++ uint8_t used_grp; // 0 if nothing in any Q in the current group
++ unsigned int max_fill;
++ unsigned int min_gap;
++ GPU_MEM_PTR_T gptr;
++} HEVCRpiInterPredEnv;
++
++typedef struct HEVCRpiIntraPredEnv {
++ unsigned int n; // Number of commands
++ HEVCPredCmd * cmds;
++} HEVCRpiIntraPredEnv;
++
++typedef struct HEVCRpiCoeffEnv {
++ unsigned int n;
++#if RPI_COMPRESS_COEFFS
++ unsigned int packed; // Equal to 1 if coefficients should be being packed
++ unsigned int packed_n; // Value of n when packed was set equal to 0 (i.e. the amount that is sent compressed). Only valid if packed==0
++#endif
++ int16_t * buf;
++} HEVCRpiCoeffEnv;
++
++typedef struct HEVCRpiCoeffsEnv {
++ HEVCRpiCoeffEnv s[4];
++ GPU_MEM_PTR_T gptr;
++ void * mptr;
++} HEVCRpiCoeffsEnv;
++
++typedef struct HEVCRpiFrameProgressWait {
++ int req;
++ struct HEVCRpiFrameProgressWait * next;
++ sem_t sem;
++} HEVCRpiFrameProgressWait;
++
++typedef struct HEVCRpiFrameProgressState {
++ struct HEVCRpiFrameProgressWait * first;
++ struct HEVCRpiFrameProgressWait * last;
++ pthread_mutex_t lock;
++} HEVCRpiFrameProgressState;
++
++typedef struct RpiBlk
++{
++ unsigned int x;
++ unsigned int y;
++ unsigned int w;
++ unsigned int h;
++} RpiBlk;
++
++typedef struct HEVCRpiJob {
++ struct HEVCRpiJob * next; // Free chain
++ struct HEVCRpiJobCtl * jbc_local;
++ const HEVCRpiSPS * sps; // sps used to set up this job
++
++ int waited;
++ int ctu_ts_first;
++ int ctu_ts_last;
++ RpiBlk bounds; // Bounding box of job
++
++ struct qpu_mc_pred_y_p_s * last_y8_p;
++ struct qpu_mc_src_s * last_y8_l1;
++ rpi_cache_flush_env_t * rfe;
++
++ HEVCRpiInterPredEnv chroma_ip;
++ HEVCRpiInterPredEnv luma_ip;
++ int16_t progress_req[HEVC_DPB_ELS]; // index by dpb_no
++ HEVCRpiIntraPredEnv intra;
++ HEVCRpiCoeffsEnv coeffs;
++ HEVCRpiFrameProgressWait progress_wait;
++ sem_t sem;
++ rpi_cache_buf_t flush_buf;
++} HEVCRpiJob;
++
++struct HEVCRpiContext;
++
++typedef void HEVCRpiWorkerFn(const struct HEVCRpiContext * const s, HEVCRpiJob * const jb);
++
++typedef struct HEVCRpiPassQueue
++{
++// int pending;
++ volatile int terminate;
++ sem_t sem_in;
++ sem_t * psem_out;
++ unsigned int job_n;
++ struct HEVCRpiContext * context; // Context pointer as we get to pass a single "void * this" to the thread
++ HEVCRpiWorkerFn * worker;
++ pthread_t thread;
++ uint8_t pass_n; // Pass number - debug
++ uint8_t started;
++} HEVCRpiPassQueue;
++
++
++struct HEVCRpiJobGlobal;
++
++typedef struct HEVCRpiJobCtl
++{
++ sem_t sem_out;
++
++ HEVCRpiJob * volatile jb1; // The job associated with this frame if unallocated - NULL if allocated
++ struct HEVCRpiJobGlobal * jbg;
++
++ HEVCRpiLocalContext * lcw_head;
++ HEVCRpiLocalContext * lcw_tail;
++
++ pthread_mutex_t in_lock;
++ int offload_in;
++
++ HEVCRpiJob *offloadq[RPI_MAX_JOBS];
++} HEVCRpiJobCtl;
++
++
++typedef struct HEVCRpiJobGlobal
++{
++ intptr_t ref_count;
++ pthread_mutex_t lock;
++ HEVCRpiJob * free1; // Singly linked list of free jobs
++ HEVCRpiLocalContext * wait_head; // Double linked list of lcs waiting for a job
++ HEVCRpiLocalContext * wait_good; // Last good tail
++ HEVCRpiLocalContext * wait_tail;
++
++} HEVCRpiJobGlobal;
++
++#define RPI_BIT_THREADS (RPI_EXTRA_BIT_THREADS + 1)
++
++#if RPI_TSTATS
++typedef struct HEVCRpiStats {
++ int y_pred1_y8_merge;
++ int y_pred1_xy;
++ int y_pred1_x0;
++ int y_pred1_y0;
++ int y_pred1_x0y0;
++ int y_pred1_wle8;
++ int y_pred1_wgt8;
++ int y_pred1_hle16;
++ int y_pred1_hgt16;
++ int y_pred2_xy;
++ int y_pred2_x0;
++ int y_pred2_y0;
++ int y_pred2_x0y0;
++ int y_pred2_hle16;
++ int y_pred2_hgt16;
++} HEVCRpiStats;
++#endif
++
++typedef struct HEVCRpiCabacState
++{
++ uint8_t rice[4];
++ uint8_t state[HEVC_CONTEXTS];
++} HEVCRpiCabacState;
++
++#define HEVC_RPI_BS_STRIDE1_PEL_SHIFT 6 // 64 pels
++#define HEVC_RPI_BS_STRIDE1_PELS (1U << HEVC_RPI_BS_STRIDE1_PEL_SHIFT)
++#define HEVC_RPI_BS_STRIDE1_PEL_MASK (HEVC_RPI_BS_STRIDE1_PELS - 1)
++#define HEVC_RPI_BS_ELS_PER_BYTE_SHIFT 2 // 4 els per byte
++#define HEVC_RPI_BS_PELS_PER_EL_SHIFT 2 // 4 pels per el
++#define HEVC_RPI_BS_PELS_PER_BYTE_SHIFT (HEVC_RPI_BS_PELS_PER_EL_SHIFT + HEVC_RPI_BS_ELS_PER_BYTE_SHIFT)
++#define HEVC_RPI_BS_STRIDE1_BYTE_SHIFT (HEVC_RPI_BS_STRIDE1_PEL_SHIFT - HEVC_RPI_BS_PELS_PER_BYTE_SHIFT)
++#define HEVC_RPI_BS_STRIDE1_BYTES (1U << HEVC_RPI_BS_STRIDE1_BYTE_SHIFT)
++#define HEVC_RPI_BS_Y_SHR 3 // 8 vertical pels per row
++#define HEVC_RPI_BS_COL_BYTES_SHR (HEVC_RPI_BS_Y_SHR - HEVC_RPI_BS_STRIDE1_BYTE_SHIFT)
++
++typedef struct HEVCRpiContext {
++ const AVClass *c; // needed by private avoptions
++ AVCodecContext *avctx;
++
++ uint8_t threads_type;
++
++ /** 1 if the independent slice segment header was successfully parsed */
++ uint8_t slice_initialized;
++ char used_for_ref; // rpi
++ char is_irap;
++ char offload_recon;
++ uint8_t eos; ///< current packet contains an EOS/EOB NAL
++ uint8_t last_eos; ///< last packet contains an EOS/EOB NAL
++ uint8_t no_backward_pred_flag;
++ uint8_t is_decoded;
++ uint8_t no_rasl_output_flag;
++
++
++ /**
++ * Sequence counters for decoded and output frames, so that old
++ * frames are output first after a POC reset
++ */
++ uint16_t seq_decode;
++ uint16_t seq_output;
++
++ int width;
++ int height;
++
++ HEVCRpiJobCtl * jbc;
++ // cabac stash
++ // b0 skip flag
++ // b1+ ct_depth
++ uint8_t * cabac_stash_left;
++ uint8_t * cabac_stash_up;
++
++ // Function pointers
++#if RPI_QPU_EMU_Y || RPI_QPU_EMU_C
++ const uint8_t * qpu_dummy_frame_emu;
++#endif
++#if !RPI_QPU_EMU_Y || !RPI_QPU_EMU_C
++ uint32_t qpu_dummy_frame_qpu; // Not a frame - just a bit of memory
++#endif
++ HEVCRpiQpu qpu;
++
++ HEVCRpiFrameProgressState progress_states[2];
++
++ HEVCRpiCabacState *cabac_save;
++
++ AVFrame *frame;
++ AVFrame *output_frame;
++ uint8_t *sao_pixel_buffer_h[3];
++ uint8_t *sao_pixel_buffer_v[3];
++
++ unsigned int col_mvf_stride;
++ AVBufferPool *col_mvf_pool;
++
++ RpiSAOParams *sao;
++ DBParams *deblock;
++ enum HEVCNALUnitType nal_unit_type;
++ int temporal_id; ///< temporal_id_plus1 - 1
++ HEVCRpiFrame *ref;
++ int poc;
++ int pocTid0;
++ int slice_idx; ///< number of the slice being currently decoded
++ int max_ra;
++
++ int8_t *qp_y_tab;
++
++ // Deblocking block strength bitmaps
++ unsigned int bs_stride2;
++ unsigned int bs_size;
++ uint8_t *bs_horizontal;
++ uint8_t *bs_vertical;
++ uint8_t *bsf_stash_up;
++ uint8_t *bsf_stash_left;
++
++#if HEVC_RPI_MAX_CTBS >= 0xffff
++#define TAB_SLICE_ADDR_BROKEN ~(uint32_t)0
++ uint32_t *tab_slice_address;
++#else
++#define TAB_SLICE_ADDR_BROKEN ~(uint16_t)0
++ uint16_t *tab_slice_address;
++#endif
++
++ // Bitfield 1 bit per 8 pels (min pcm size)
++ uint8_t *is_pcm;
++ // Bitfield 1 bit per 8 pels (min cb size)
++ // Only needed for CIP as CIP processing is async to the main thread
++ uint8_t *is_intra;
++
++ // PU
++ HEVCRpiMvField *mvf_up;
++ HEVCRpiMvField *mvf_left;
++
++ const RefPicList **rpl_up;
++ const RefPicList **rpl_left;
++ RefPicList * refPicList;
++
++ // CTB-level flags affecting loop filter operation
++ uint8_t *filter_slice_edges;
++
++ /** used on BE to byteswap the lines for checksumming */
++ uint8_t *checksum_buf;
++ int checksum_buf_size;
++
++ atomic_int wpp_err;
++
++ const uint8_t *data;
++
++ H2645Packet pkt;
++ // type of the first VCL NAL of the current frame
++ enum HEVCNALUnitType first_nal_type;
++
++ uint8_t context_initialized;
++ int is_nalff; ///< this flag is != 0 if bitstream is encapsulated
++ ///< as a format defined in 14496-15
++ int apply_defdispwin;
++
++ int nal_length_size; ///< Number of bytes used for nal length (1, 2 or 4)
++ int nuh_layer_id;
++
++ struct AVMD5 *md5_ctx;
++
++ RefPicListTab * rpl_tab;
++ unsigned int rpl_tab_size;
++
++ uint8_t *is_intra_store;
++
++ RpiSliceHeader sh;
++
++ HEVCRpiParamSets ps;
++
++ HEVCRpiLocalContext *HEVClc;
++ HEVCRpiLocalContext *HEVClcList[MAX_NB_THREADS];
++
++ HEVCRpiFrame DPB[HEVC_DPB_ELS];
++
++ ///< candidate references for the current frame
++ RefPicList rps[5];
++
++ HEVCRpiPredContext hpc;
++ HEVCDSPContext hevcdsp;
++
++ HEVCSEIContext sei;
++
++ // Put structures that allocate non-trivial storage at the end
++ // These are mostly used indirectly so position in the structure doesn't matter
++ HEVCRpiPassQueue passq[RPI_PASSES];
++#if RPI_EXTRA_BIT_THREADS > 0
++ int bt_started;
++ // This simply contains thread descriptors - task setup is held elsewhere
++ pthread_t bit_threads[RPI_EXTRA_BIT_THREADS];
++#endif
++#if RPI_TSTATS
++ HEVCRpiStats tstats;
++#endif
++} HEVCRpiContext;
++
++/**
++ * Mark all frames in DPB as unused for reference.
++ */
++void ff_hevc_rpi_clear_refs(HEVCRpiContext *s);
++
++/**
++ * Drop all frames currently in DPB.
++ */
++void ff_hevc_rpi_flush_dpb(HEVCRpiContext *s);
++
++/**
++ * Construct the reference picture sets for the current frame.
++ */
++int ff_hevc_rpi_frame_rps(HEVCRpiContext *s);
++
++/**
++ * Construct the reference picture list(s) for the current slice.
++ */
++int ff_hevc_rpi_slice_rpl(HEVCRpiContext *s);
++
++
++/**
++ * Get the number of candidate references for the current frame.
++ */
++int ff_hevc_rpi_frame_nb_refs(HEVCRpiContext *s);
++
++int ff_hevc_rpi_set_new_ref(HEVCRpiContext *s, AVFrame **frame, int poc);
++
++/**
++ * Find next frame in output order and put a reference to it in frame.
++ * @return 1 if a frame was output, 0 otherwise
++ */
++int ff_hevc_rpi_output_frame(HEVCRpiContext *s, AVFrame *frame, int flush);
++
++void ff_hevc_rpi_bump_frame(HEVCRpiContext *s);
++
++void ff_hevc_rpi_unref_frame(HEVCRpiContext *s, HEVCRpiFrame *frame, int flags);
++
++unsigned int ff_hevc_rpi_tb_avail_flags(
++ const HEVCRpiContext * const s, const HEVCRpiLocalContext * const lc,
++ const unsigned int x, const unsigned int y, const unsigned int w, const unsigned int h);
++
++void ff_hevc_rpi_luma_mv_merge_mode(const HEVCRpiContext * const s, HEVCRpiLocalContext * const lc, int x0, int y0, int nPbW,
++ int nPbH, int log2_cb_size, int part_idx,
++ int merge_idx, HEVCRpiMvField * const mv);
++void ff_hevc_rpi_luma_mv_mvp_mode(const HEVCRpiContext * const s, HEVCRpiLocalContext * const lc,
++ const unsigned int x0, const unsigned int y0,
++ const unsigned int nPbW, const unsigned int nPbH,
++ const unsigned int avail,
++ HEVCRpiMvField * const mv,
++ const unsigned int mvp_lx_flag, const unsigned int LX);
++void ff_hevc_rpi_set_qPy(const HEVCRpiContext * const s, HEVCRpiLocalContext * const lc, int xBase, int yBase);
++void ff_hevc_rpi_deblocking_boundary_strengths(const HEVCRpiContext * const s, const HEVCRpiLocalContext * const lc,
++ const unsigned int x0, const unsigned int y0,
++ const unsigned int log2_trafo_size, const int is_coded_block);
++int ff_hevc_rpi_hls_filter_blk(const HEVCRpiContext * const s, const RpiBlk bounds, const int eot);
++
++extern const uint8_t ff_hevc_rpi_qpel_extra_before[4];
++extern const uint8_t ff_hevc_rpi_qpel_extra_after[4];
++extern const uint8_t ff_hevc_rpi_qpel_extra[4];
++
++int16_t * rpi_alloc_coeff_buf(HEVCRpiJob * const jb, const int buf_no, const int n);
++
++// arm/hevc_misc_neon.S
++// Neon coeff zap fn
++#if HAVE_NEON
++extern void rpi_zap_coeff_vals_neon(int16_t * dst, unsigned int l2ts_m2);
++#endif
++
++void ff_hevc_rpi_progress_wait_field(const HEVCRpiContext * const s, HEVCRpiJob * const jb,
++ const HEVCRpiFrame * const ref, const int val, const int field);
++
++void ff_hevc_rpi_progress_signal_field(HEVCRpiContext * const s, const int val, const int field);
++
++// All of these expect that s->threads_type == FF_THREAD_FRAME
++
++static inline void ff_hevc_rpi_progress_wait_mv(const HEVCRpiContext * const s, HEVCRpiJob * const jb,
++ const HEVCRpiFrame * const ref, const int y)
++{
++ if (s->threads_type != 0)
++ ff_hevc_rpi_progress_wait_field(s, jb, ref, y, 1);
++}
++
++static inline void ff_hevc_rpi_progress_signal_mv(HEVCRpiContext * const s, const int y)
++{
++ if (s->used_for_ref && s->threads_type != 0)
++ ff_hevc_rpi_progress_signal_field(s, y, 1);
++}
++
++static inline void ff_hevc_rpi_progress_wait_recon(const HEVCRpiContext * const s, HEVCRpiJob * const jb,
++ const HEVCRpiFrame * const ref, const int y)
++{
++ ff_hevc_rpi_progress_wait_field(s, jb, ref, y, 0);
++}
++
++static inline void ff_hevc_rpi_progress_signal_recon(HEVCRpiContext * const s, const int y)
++{
++ if (s->used_for_ref && s->threads_type != 0)
++ {
++ ff_hevc_rpi_progress_signal_field(s, y, 0);
++ }
++}
++
++static inline void ff_hevc_rpi_progress_signal_all_done(HEVCRpiContext * const s)
++{
++ ff_hevc_rpi_progress_signal_field(s, INT_MAX, 0);
++ ff_hevc_rpi_progress_signal_field(s, INT_MAX, 1);
++}
++
++
++// Set all done - signal nothing (used in missing refs)
++// Works for both rpi & non-rpi
++static inline void ff_hevc_rpi_progress_set_all_done(HEVCRpiFrame * const ref)
++{
++ if (ref->tf.progress != NULL)
++ {
++ int * const p = (int *)ref->tf.progress->data;
++ p[0] = INT_MAX;
++ p[1] = INT_MAX;
++ }
++}
++
++#define HEVC_RPI_420_ONLY 1
++#define HEVC_RPI_SAND128_ONLY 1
++
++static inline unsigned int ctx_hshift(const HEVCRpiContext * const s, const int cidx)
++{
++#if HEVC_RPI_420_ONLY
++ return cidx == 0 ? 0 : 1;
++#else
++ return s->ps.sps->hshift[cidx];
++#endif
++}
++
++static inline unsigned int ctx_vshift(const HEVCRpiContext * const s, const int cidx)
++{
++#if HEVC_RPI_420_ONLY
++ return cidx == 0 ? 0 : 1;
++#else
++ return s->ps.sps->vshift[cidx];
++#endif
++}
++
++static inline int ctx_cfmt(const HEVCRpiContext * const s)
++{
++#if HEVC_RPI_420_ONLY
++ return 1;
++#else
++ return s->ps.sps->chroma_format_idc;
++#endif
++}
++
++static inline int frame_stride1(const AVFrame * const frame, const int c_idx)
++{
++#if HEVC_RPI_SAND128_ONLY
++ return 128;
++#else
++ return frame->linesize[c_idx];
++#endif
++}
++
++#if HEVC_RPI_SAND128_ONLY
++// Propagate this decision to later zc includes
++#define RPI_ZC_SAND128_ONLY 1
++#endif
++
++#ifndef ff_hevc_rpi_copy_vert
++static inline void ff_hevc_rpi_copy_vert(uint8_t *dst, const uint8_t *src,
++ int pixel_shift, int height,
++ ptrdiff_t stride_dst, ptrdiff_t stride_src)
++{
++ int i;
++ switch (pixel_shift)
++ {
++ case 2:
++ for (i = 0; i < height; i++) {
++ *(uint32_t *)dst = *(uint32_t *)src;
++ dst += stride_dst;
++ src += stride_src;
++ }
++ break;
++ case 1:
++ for (i = 0; i < height; i++) {
++ *(uint16_t *)dst = *(uint16_t *)src;
++ dst += stride_dst;
++ src += stride_src;
++ }
++ break;
++ default:
++ for (i = 0; i < height; i++) {
++ *dst = *src;
++ dst += stride_dst;
++ src += stride_src;
++ }
++ break;
++ }
++}
++#endif
++
++
++#if MVF_STASH_WIDTH == 64
++static inline HEVCRpiMvField* mvf_stash_ptr(const HEVCRpiContext *const s, const HEVCRpiLocalContext * const lc,
++ const unsigned int x, const unsigned int y)
++{
++ const unsigned int mask_cs_hi = (~0U << s->ps.sps->log2_ctb_size);
++ return (HEVCRpiMvField*)(lc->mvf_stash + ((y & ~mask_cs_hi) >> LOG2_MIN_PU_SIZE) * MVF_STASH_WIDTH_PU + ((x & ~mask_cs_hi) >> LOG2_MIN_PU_SIZE));
++}
++
++static inline HEVCRpiMvField* mvf_ptr(const HEVCRpiContext *const s, const HEVCRpiLocalContext * const lc,
++ const unsigned int x0, const unsigned int y0,
++ const unsigned int x, const unsigned int y)
++{
++ const unsigned int mask_cs_hi = (~0U << s->ps.sps->log2_ctb_size);
++ const unsigned int x0_ctb = x0 & mask_cs_hi;
++ const unsigned int y0_ctb = y0 & mask_cs_hi;
++
++ return (HEVCRpiMvField *)((y < y0_ctb) ?
++ (x < x0_ctb ? lc->mvf_ul : s->mvf_up + (x >> LOG2_MIN_PU_SIZE)) :
++ (x < x0_ctb ? s->mvf_left + (y >> LOG2_MIN_PU_SIZE) :
++ lc->mvf_stash +
++ ((y & ~mask_cs_hi) >> LOG2_MIN_PU_SIZE) * MVF_STASH_WIDTH_PU +
++ ((x & ~mask_cs_hi) >> LOG2_MIN_PU_SIZE)));
++}
++
++static inline unsigned int mvf_left_stride(const HEVCRpiContext *const s,
++ const unsigned int x0,
++ const unsigned int x)
++{
++ const unsigned int mask_cs_hi = (~0U << s->ps.sps->log2_ctb_size);
++ const unsigned int x0_ctb = x0 & mask_cs_hi;
++ return x < x0_ctb ? 1 : MVF_STASH_WIDTH_PU;
++}
++
++#else
++static inline HEVCRpiMvField* mvf_stash_ptr(const HEVCRpiContext *const s, const HEVCRpiLocalContext * const lc,
++ const unsigned int x, const unsigned int y)
++{
++ const unsigned int mask_cs_hi = (~0U << s->ps.sps->log2_ctb_size);
++ return (HEVCRpiMvField*)(lc->mvf_stash + ((y & ~mask_cs_hi) >> LOG2_MIN_PU_SIZE) * MVF_STASH_WIDTH_PU + ((x >> LOG2_MIN_PU_SIZE) & (MVF_STASH_WIDTH_PU - 1)));
++}
++
++static inline HEVCRpiMvField* mvf_ptr(const HEVCRpiContext *const s, const HEVCRpiLocalContext * const lc,
++ const unsigned int x0, const unsigned int y0,
++ const unsigned int x, const unsigned int y)
++{
++ const unsigned int mask_cs_hi = (~0U << s->ps.sps->log2_ctb_size);
++
++ const unsigned int x0_ctb = x0 & mask_cs_hi;
++ const unsigned int y0_ctb = y0 & mask_cs_hi;
++
++ // If not in the same CTB for Y assume up
++ if (y < y0_ctb) {
++ // If not in the same CTB for X too assume up-left
++ return (HEVCRpiMvField *)(x < x0_ctb ? lc->mvf_ul : s->mvf_up + (x >> LOG2_MIN_PU_SIZE));
++ }
++ return mvf_stash_ptr(s, lc, x, y);
++}
++
++static inline unsigned int mvf_left_stride(const HEVCRpiContext *const s,
++ const unsigned int x0,
++ const unsigned int x)
++{
++ return MVF_STASH_WIDTH_PU;
++}
++#endif
++
++#endif /* AVCODEC_RPI_HEVCDEC_H */
+diff --git a/libavcodec/rpi_hevcdsp.c b/libavcodec/rpi_hevcdsp.c
+new file mode 100644
+index 0000000000..ac29789e7f
+--- /dev/null
++++ b/libavcodec/rpi_hevcdsp.c
+@@ -0,0 +1,450 @@
++/*
++ * HEVC video decoder
++ *
++ * Copyright (C) 2012 - 2013 Guillaume Martres
++ * Copyright (C) 2013 - 2014 Pierre-Edouard Lepere
++ *
++ *
++ * This file is part of FFmpeg.
++ *
++ * FFmpeg is free software; you can redistribute it and/or
++ * modify it under the terms of the GNU Lesser General Public
++ * License as published by the Free Software Foundation; either
++ * version 2.1 of the License, or (at your option) any later version.
++ *
++ * FFmpeg is distributed in the hope that it will be useful,
++ * but WITHOUT ANY WARRANTY; without even the implied warranty of
++ * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
++ * Lesser General Public License for more details.
++ *
++ * You should have received a copy of the GNU Lesser General Public
++ * License along with FFmpeg; if not, write to the Free Software
++ * Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA
++ */
++
++#include "rpi_hevcdsp.h"
++#include "rpi_hevc_mv.h"
++
++static const int8_t transform[32][32] = {
++ { 64, 64, 64, 64, 64, 64, 64, 64, 64, 64, 64, 64, 64, 64, 64, 64,
++ 64, 64, 64, 64, 64, 64, 64, 64, 64, 64, 64, 64, 64, 64, 64, 64 },
++ { 90, 90, 88, 85, 82, 78, 73, 67, 61, 54, 46, 38, 31, 22, 13, 4,
++ -4, -13, -22, -31, -38, -46, -54, -61, -67, -73, -78, -82, -85, -88, -90, -90 },
++ { 90, 87, 80, 70, 57, 43, 25, 9, -9, -25, -43, -57, -70, -80, -87, -90,
++ -90, -87, -80, -70, -57, -43, -25, -9, 9, 25, 43, 57, 70, 80, 87, 90 },
++ { 90, 82, 67, 46, 22, -4, -31, -54, -73, -85, -90, -88, -78, -61, -38, -13,
++ 13, 38, 61, 78, 88, 90, 85, 73, 54, 31, 4, -22, -46, -67, -82, -90 },
++ { 89, 75, 50, 18, -18, -50, -75, -89, -89, -75, -50, -18, 18, 50, 75, 89,
++ 89, 75, 50, 18, -18, -50, -75, -89, -89, -75, -50, -18, 18, 50, 75, 89 },
++ { 88, 67, 31, -13, -54, -82, -90, -78, -46, -4, 38, 73, 90, 85, 61, 22,
++ -22, -61, -85, -90, -73, -38, 4, 46, 78, 90, 82, 54, 13, -31, -67, -88 },
++ { 87, 57, 9, -43, -80, -90, -70, -25, 25, 70, 90, 80, 43, -9, -57, -87,
++ -87, -57, -9, 43, 80, 90, 70, 25, -25, -70, -90, -80, -43, 9, 57, 87 },
++ { 85, 46, -13, -67, -90, -73, -22, 38, 82, 88, 54, -4, -61, -90, -78, -31,
++ 31, 78, 90, 61, 4, -54, -88, -82, -38, 22, 73, 90, 67, 13, -46, -85 },
++ { 83, 36, -36, -83, -83, -36, 36, 83, 83, 36, -36, -83, -83, -36, 36, 83,
++ 83, 36, -36, -83, -83, -36, 36, 83, 83, 36, -36, -83, -83, -36, 36, 83 },
++ { 82, 22, -54, -90, -61, 13, 78, 85, 31, -46, -90, -67, 4, 73, 88, 38,
++ -38, -88, -73, -4, 67, 90, 46, -31, -85, -78, -13, 61, 90, 54, -22, -82 },
++ { 80, 9, -70, -87, -25, 57, 90, 43, -43, -90, -57, 25, 87, 70, -9, -80,
++ -80, -9, 70, 87, 25, -57, -90, -43, 43, 90, 57, -25, -87, -70, 9, 80 },
++ { 78, -4, -82, -73, 13, 85, 67, -22, -88, -61, 31, 90, 54, -38, -90, -46,
++ 46, 90, 38, -54, -90, -31, 61, 88, 22, -67, -85, -13, 73, 82, 4, -78 },
++ { 75, -18, -89, -50, 50, 89, 18, -75, -75, 18, 89, 50, -50, -89, -18, 75,
++ 75, -18, -89, -50, 50, 89, 18, -75, -75, 18, 89, 50, -50, -89, -18, 75 },
++ { 73, -31, -90, -22, 78, 67, -38, -90, -13, 82, 61, -46, -88, -4, 85, 54,
++ -54, -85, 4, 88, 46, -61, -82, 13, 90, 38, -67, -78, 22, 90, 31, -73 },
++ { 70, -43, -87, 9, 90, 25, -80, -57, 57, 80, -25, -90, -9, 87, 43, -70,
++ -70, 43, 87, -9, -90, -25, 80, 57, -57, -80, 25, 90, 9, -87, -43, 70 },
++ { 67, -54, -78, 38, 85, -22, -90, 4, 90, 13, -88, -31, 82, 46, -73, -61,
++ 61, 73, -46, -82, 31, 88, -13, -90, -4, 90, 22, -85, -38, 78, 54, -67 },
++ { 64, -64, -64, 64, 64, -64, -64, 64, 64, -64, -64, 64, 64, -64, -64, 64,
++ 64, -64, -64, 64, 64, -64, -64, 64, 64, -64, -64, 64, 64, -64, -64, 64 },
++ { 61, -73, -46, 82, 31, -88, -13, 90, -4, -90, 22, 85, -38, -78, 54, 67,
++ -67, -54, 78, 38, -85, -22, 90, 4, -90, 13, 88, -31, -82, 46, 73, -61 },
++ { 57, -80, -25, 90, -9, -87, 43, 70, -70, -43, 87, 9, -90, 25, 80, -57,
++ -57, 80, 25, -90, 9, 87, -43, -70, 70, 43, -87, -9, 90, -25, -80, 57 },
++ { 54, -85, -4, 88, -46, -61, 82, 13, -90, 38, 67, -78, -22, 90, -31, -73,
++ 73, 31, -90, 22, 78, -67, -38, 90, -13, -82, 61, 46, -88, 4, 85, -54 },
++ { 50, -89, 18, 75, -75, -18, 89, -50, -50, 89, -18, -75, 75, 18, -89, 50,
++ 50, -89, 18, 75, -75, -18, 89, -50, -50, 89, -18, -75, 75, 18, -89, 50 },
++ { 46, -90, 38, 54, -90, 31, 61, -88, 22, 67, -85, 13, 73, -82, 4, 78,
++ -78, -4, 82, -73, -13, 85, -67, -22, 88, -61, -31, 90, -54, -38, 90, -46 },
++ { 43, -90, 57, 25, -87, 70, 9, -80, 80, -9, -70, 87, -25, -57, 90, -43,
++ -43, 90, -57, -25, 87, -70, -9, 80, -80, 9, 70, -87, 25, 57, -90, 43 },
++ { 38, -88, 73, -4, -67, 90, -46, -31, 85, -78, 13, 61, -90, 54, 22, -82,
++ 82, -22, -54, 90, -61, -13, 78, -85, 31, 46, -90, 67, 4, -73, 88, -38 },
++ { 36, -83, 83, -36, -36, 83, -83, 36, 36, -83, 83, -36, -36, 83, -83, 36,
++ 36, -83, 83, -36, -36, 83, -83, 36, 36, -83, 83, -36, -36, 83, -83, 36 },
++ { 31, -78, 90, -61, 4, 54, -88, 82, -38, -22, 73, -90, 67, -13, -46, 85,
++ -85, 46, 13, -67, 90, -73, 22, 38, -82, 88, -54, -4, 61, -90, 78, -31 },
++ { 25, -70, 90, -80, 43, 9, -57, 87, -87, 57, -9, -43, 80, -90, 70, -25,
++ -25, 70, -90, 80, -43, -9, 57, -87, 87, -57, 9, 43, -80, 90, -70, 25 },
++ { 22, -61, 85, -90, 73, -38, -4, 46, -78, 90, -82, 54, -13, -31, 67, -88,
++ 88, -67, 31, 13, -54, 82, -90, 78, -46, 4, 38, -73, 90, -85, 61, -22 },
++ { 18, -50, 75, -89, 89, -75, 50, -18, -18, 50, -75, 89, -89, 75, -50, 18,
++ 18, -50, 75, -89, 89, -75, 50, -18, -18, 50, -75, 89, -89, 75, -50, 18 },
++ { 13, -38, 61, -78, 88, -90, 85, -73, 54, -31, 4, 22, -46, 67, -82, 90,
++ -90, 82, -67, 46, -22, -4, 31, -54, 73, -85, 90, -88, 78, -61, 38, -13 },
++ { 9, -25, 43, -57, 70, -80, 87, -90, 90, -87, 80, -70, 57, -43, 25, -9,
++ -9, 25, -43, 57, -70, 80, -87, 90, -90, 87, -80, 70, -57, 43, -25, 9 },
++ { 4, -13, 22, -31, 38, -46, 54, -61, 67, -73, 78, -82, 85, -88, 90, -90,
++ 90, -90, 88, -85, 82, -78, 73, -67, 61, -54, 46, -38, 31, -22, 13, -4 },
++};
++
++DECLARE_ALIGNED(16, const int8_t, ff_hevc_rpi_epel_filters[7][4]) = {
++ { -2, 58, 10, -2},
++ { -4, 54, 16, -2},
++ { -6, 46, 28, -4},
++ { -4, 36, 36, -4},
++ { -4, 28, 46, -6},
++ { -2, 16, 54, -4},
++ { -2, 10, 58, -2},
++};
++
++DECLARE_ALIGNED(16, const int8_t, ff_hevc_rpi_qpel_filters[3][16]) = {
++ { -1, 4,-10, 58, 17, -5, 1, 0, -1, 4,-10, 58, 17, -5, 1, 0},
++ { -1, 4,-11, 40, 40,-11, 4, -1, -1, 4,-11, 40, 40,-11, 4, -1},
++ { 0, 1, -5, 17, 58,-10, 4, -1, 0, 1, -5, 17, 58,-10, 4, -1}
++};
++
++#define BIT_DEPTH 8
++#include "rpi_hevcdsp_template.c"
++#undef BIT_DEPTH
++
++#define BIT_DEPTH 9
++#include "rpi_hevcdsp_template.c"
++#undef BIT_DEPTH
++
++#define BIT_DEPTH 10
++#include "rpi_hevcdsp_template.c"
++#undef BIT_DEPTH
++
++#define BIT_DEPTH 12
++#include "rpi_hevcdsp_template.c"
++#undef BIT_DEPTH
++
++static uint32_t hevc_deblocking_boundary_strengths(int pus, int dup, const HEVCRpiMvField *curr, const HEVCRpiMvField *neigh,
++ const int *curr_rpl0, const int *curr_rpl1, const int *neigh_rpl0, const int *neigh_rpl1,
++ int in_inc0, int in_inc1)
++{
++ int shift = 32;
++ uint32_t bs = 0;
++ for (; pus > 0; pus--) {
++ int strength, out;
++ int curr_refL0 = curr_rpl0[curr->ref_idx[0]];
++ int curr_refL1 = curr_rpl1[curr->ref_idx[1]];
++ int nr_idx0 = neigh->ref_idx[0];
++ int nr_idx1 = neigh->ref_idx[1];
++ int neigh_refL0 = neigh_rpl0[nr_idx0];
++ int neigh_refL1 = neigh_rpl1[nr_idx1];
++
++ av_assert0(nr_idx0 >= 0 && nr_idx0 <=31);
++ av_assert0(nr_idx1 >= 0 && nr_idx1 <=31);
++
++#if 1 // This more directly matches the original implementation
++ if (curr->pred_flag == PF_BI && neigh->pred_flag == PF_BI) {
++ // same L0 and L1
++ if (curr_refL0 == neigh_refL0 &&
++ curr_refL0 == curr_refL1 &&
++ neigh_refL0 == neigh_refL1) {
++ if ((FFABS(MV_X(neigh->xy[0]) - MV_X(curr->xy[0])) >= 4 || FFABS(MV_Y(neigh->xy[0]) - MV_Y(curr->xy[0])) >= 4 ||
++ FFABS(MV_X(neigh->xy[1]) - MV_X(curr->xy[1])) >= 4 || FFABS(MV_Y(neigh->xy[1]) - MV_Y(curr->xy[1])) >= 4) &&
++ (FFABS(MV_X(neigh->xy[1]) - MV_X(curr->xy[0])) >= 4 || FFABS(MV_Y(neigh->xy[1]) - MV_Y(curr->xy[0])) >= 4 ||
++ FFABS(MV_X(neigh->xy[0]) - MV_X(curr->xy[1])) >= 4 || FFABS(MV_Y(neigh->xy[0]) - MV_Y(curr->xy[1])) >= 4))
++ strength = 1;
++ else
++ strength = 0;
++ } else if (neigh_refL0 == curr_refL0 &&
++ neigh_refL1 == curr_refL1) {
++ if (FFABS(MV_X(neigh->xy[0]) - MV_X(curr->xy[0])) >= 4 || FFABS(MV_Y(neigh->xy[0]) - MV_Y(curr->xy[0])) >= 4 ||
++ FFABS(MV_X(neigh->xy[1]) - MV_X(curr->xy[1])) >= 4 || FFABS(MV_Y(neigh->xy[1]) - MV_Y(curr->xy[1])) >= 4)
++ strength = 1;
++ else
++ strength = 0;
++ } else if (neigh_refL1 == curr_refL0 &&
++ neigh_refL0 == curr_refL1) {
++ if (FFABS(MV_X(neigh->xy[1]) - MV_X(curr->xy[0])) >= 4 || FFABS(MV_Y(neigh->xy[1]) - MV_Y(curr->xy[0])) >= 4 ||
++ FFABS(MV_X(neigh->xy[0]) - MV_X(curr->xy[1])) >= 4 || FFABS(MV_Y(neigh->xy[0]) - MV_Y(curr->xy[1])) >= 4)
++ strength = 1;
++ else
++ strength = 0;
++ } else {
++ strength = 1;
++ }
++ } else if ((curr->pred_flag != PF_BI) && (neigh->pred_flag != PF_BI)){ // 1 MV
++ MvXY curr_mv0, neigh_mv0;
++
++ if (curr->pred_flag & 1) {
++ curr_mv0 = curr->xy[0];
++ } else {
++ curr_mv0 = curr->xy[1];
++ curr_refL0 = curr_refL1;
++ }
++
++ if (neigh->pred_flag & 1) {
++ neigh_mv0 = neigh->xy[0];
++ } else {
++ neigh_mv0 = neigh->xy[1];
++ neigh_refL0 = neigh_refL1;
++ }
++
++ if (curr_refL0 == neigh_refL0) {
++ if (FFABS(MV_X(curr_mv0) - MV_X(neigh_mv0)) >= 4 || FFABS(MV_Y(curr_mv0) - MV_Y(neigh_mv0)) >= 4)
++ strength = 1;
++ else
++ strength = 0;
++ } else
++ strength = 1;
++ } else
++ strength = 1;
++#else // This has exactly the same effect, but is more suitable for vectorisation
++ MvXY curr_mv[2];
++ MvXY neigh_mv[2];
++ memcpy(curr_mv, curr->xy, sizeof curr_mv);
++ memcpy(neigh_mv, neigh->xy, sizeof neigh_mv);
++
++ if (!(curr->pred_flag & 2)) {
++ curr_mv[1] = curr_mv[0];
++ curr_refL1 = curr_refL0;
++ }
++ if (!(neigh->pred_flag & 2)) {
++ neigh_mv[1] = neigh_mv[0];
++ neigh_refL1 = neigh_refL0;
++ }
++ if (!(curr->pred_flag & 1)) {
++ curr_mv[0] = curr_mv[1];
++ curr_refL0 = curr_refL1;
++ }
++ if (!(neigh->pred_flag & 1)) {
++ neigh_mv[0] = neigh_mv[1];
++ neigh_refL0 = neigh_refL1;
++ }
++
++ strength = 1;
++
++ strength &= (neigh_refL0 != curr_refL0) | (neigh_refL1 != curr_refL1) |
++ (FFABS(MV_X(neigh_mv[0]) - MV_X(curr_mv[0])) >= 4) | (FFABS(MV_Y(neigh_mv[0]) - MV_Y(curr_mv[0])) >= 4) |
++ (FFABS(MV_X(neigh_mv[1]) - MV_X(curr_mv[1])) >= 4) | (FFABS(MV_Y(neigh_mv[1]) - MV_Y(curr_mv[1])) >= 4);
++
++ strength &= (neigh_refL1 != curr_refL0) | (neigh_refL0 != curr_refL1) |
++ (FFABS(MV_X(neigh_mv[1]) - MV_X(curr_mv[0])) >= 4) | (FFABS(MV_Y(neigh_mv[1]) - MV_Y(curr_mv[0])) >= 4) |
++ (FFABS(MV_X(neigh_mv[0]) - MV_X(curr_mv[1])) >= 4) | (FFABS(MV_Y(neigh_mv[0]) - MV_Y(curr_mv[1])) >= 4);
++
++ strength |= (((curr->pred_flag + 1) ^ (neigh->pred_flag + 1)) >> 2);
++#endif
++
++ curr += in_inc0 / sizeof (HEVCRpiMvField);
++ neigh += in_inc1 / sizeof (HEVCRpiMvField);
++
++ for (out = dup; out > 0; out--)
++ {
++ bs = (bs >> 2) | (strength << 30);
++ shift -= 2;
++ }
++ }
++ return bs >> shift;
++}
++
++
++static void cpy_blk(uint8_t *dst, unsigned int stride_dst, const uint8_t *src, unsigned stride_src, unsigned int width, unsigned int height)
++{
++ unsigned int i, j;
++
++ if (((intptr_t)dst | (intptr_t)src | stride_dst | stride_src) & 15) {
++ for (i = 0; i < height; i++) {
++ for (j = 0; j < width; j+=8)
++ AV_COPY64U(dst+j, src+j);
++ dst += stride_dst;
++ src += stride_src;
++ }
++ } else {
++ for (i = 0; i < height; i++) {
++ for (j = 0; j < width; j+=16)
++ AV_COPY128(dst+j, src+j);
++ dst += stride_dst;
++ src += stride_src;
++ }
++ }
++}
++
++
++
++void ff_hevc_rpi_dsp_init(HEVCDSPContext *hevcdsp, int bit_depth)
++{
++#undef FUNC
++#define FUNC(a, depth) a ## _ ## depth
++
++#undef PEL_FUNC
++#define PEL_FUNC(dst1, idx1, idx2, a, depth) \
++ for(i = 0 ; i < 10 ; i++) \
++{ \
++ hevcdsp->dst1[i][idx1][idx2] = a ## _ ## depth; \
++}
++
++#undef EPEL_FUNCS
++#define EPEL_FUNCS(depth) \
++ PEL_FUNC(put_hevc_epel, 0, 0, put_hevc_pel_pixels, depth); \
++ PEL_FUNC(put_hevc_epel, 0, 1, put_hevc_epel_h, depth); \
++ PEL_FUNC(put_hevc_epel, 1, 0, put_hevc_epel_v, depth); \
++ PEL_FUNC(put_hevc_epel, 1, 1, put_hevc_epel_hv, depth)
++
++#undef EPEL_UNI_FUNCS
++#define EPEL_UNI_FUNCS(depth) \
++ PEL_FUNC(put_hevc_epel_uni, 0, 0, put_hevc_pel_uni_pixels, depth); \
++ PEL_FUNC(put_hevc_epel_uni, 0, 1, put_hevc_epel_uni_h, depth); \
++ PEL_FUNC(put_hevc_epel_uni, 1, 0, put_hevc_epel_uni_v, depth); \
++ PEL_FUNC(put_hevc_epel_uni, 1, 1, put_hevc_epel_uni_hv, depth); \
++ PEL_FUNC(put_hevc_epel_uni_w, 0, 0, put_hevc_pel_uni_w_pixels, depth); \
++ PEL_FUNC(put_hevc_epel_uni_w, 0, 1, put_hevc_epel_uni_w_h, depth); \
++ PEL_FUNC(put_hevc_epel_uni_w, 1, 0, put_hevc_epel_uni_w_v, depth); \
++ PEL_FUNC(put_hevc_epel_uni_w, 1, 1, put_hevc_epel_uni_w_hv, depth)
++
++#undef EPEL_BI_FUNCS
++#define EPEL_BI_FUNCS(depth) \
++ PEL_FUNC(put_hevc_epel_bi, 0, 0, put_hevc_pel_bi_pixels, depth); \
++ PEL_FUNC(put_hevc_epel_bi, 0, 1, put_hevc_epel_bi_h, depth); \
++ PEL_FUNC(put_hevc_epel_bi, 1, 0, put_hevc_epel_bi_v, depth); \
++ PEL_FUNC(put_hevc_epel_bi, 1, 1, put_hevc_epel_bi_hv, depth); \
++ PEL_FUNC(put_hevc_epel_bi_w, 0, 0, put_hevc_pel_bi_w_pixels, depth); \
++ PEL_FUNC(put_hevc_epel_bi_w, 0, 1, put_hevc_epel_bi_w_h, depth); \
++ PEL_FUNC(put_hevc_epel_bi_w, 1, 0, put_hevc_epel_bi_w_v, depth); \
++ PEL_FUNC(put_hevc_epel_bi_w, 1, 1, put_hevc_epel_bi_w_hv, depth)
++
++#undef QPEL_FUNCS
++#define QPEL_FUNCS(depth) \
++ PEL_FUNC(put_hevc_qpel, 0, 0, put_hevc_pel_pixels, depth); \
++ PEL_FUNC(put_hevc_qpel, 0, 1, put_hevc_qpel_h, depth); \
++ PEL_FUNC(put_hevc_qpel, 1, 0, put_hevc_qpel_v, depth); \
++ PEL_FUNC(put_hevc_qpel, 1, 1, put_hevc_qpel_hv, depth)
++
++#undef QPEL_UNI_FUNCS
++#define QPEL_UNI_FUNCS(depth) \
++ PEL_FUNC(put_hevc_qpel_uni, 0, 0, put_hevc_pel_uni_pixels, depth); \
++ PEL_FUNC(put_hevc_qpel_uni, 0, 1, put_hevc_qpel_uni_h, depth); \
++ PEL_FUNC(put_hevc_qpel_uni, 1, 0, put_hevc_qpel_uni_v, depth); \
++ PEL_FUNC(put_hevc_qpel_uni, 1, 1, put_hevc_qpel_uni_hv, depth); \
++ PEL_FUNC(put_hevc_qpel_uni_w, 0, 0, put_hevc_pel_uni_w_pixels, depth); \
++ PEL_FUNC(put_hevc_qpel_uni_w, 0, 1, put_hevc_qpel_uni_w_h, depth); \
++ PEL_FUNC(put_hevc_qpel_uni_w, 1, 0, put_hevc_qpel_uni_w_v, depth); \
++ PEL_FUNC(put_hevc_qpel_uni_w, 1, 1, put_hevc_qpel_uni_w_hv, depth)
++
++#undef QPEL_BI_FUNCS
++#define QPEL_BI_FUNCS(depth) \
++ PEL_FUNC(put_hevc_qpel_bi, 0, 0, put_hevc_pel_bi_pixels, depth); \
++ PEL_FUNC(put_hevc_qpel_bi, 0, 1, put_hevc_qpel_bi_h, depth); \
++ PEL_FUNC(put_hevc_qpel_bi, 1, 0, put_hevc_qpel_bi_v, depth); \
++ PEL_FUNC(put_hevc_qpel_bi, 1, 1, put_hevc_qpel_bi_hv, depth); \
++ PEL_FUNC(put_hevc_qpel_bi_w, 0, 0, put_hevc_pel_bi_w_pixels, depth); \
++ PEL_FUNC(put_hevc_qpel_bi_w, 0, 1, put_hevc_qpel_bi_w_h, depth); \
++ PEL_FUNC(put_hevc_qpel_bi_w, 1, 0, put_hevc_qpel_bi_w_v, depth); \
++ PEL_FUNC(put_hevc_qpel_bi_w, 1, 1, put_hevc_qpel_bi_w_hv, depth)
++
++#define SLICED_ADD_RESIDUAL(depth)\
++ hevcdsp->add_residual_u[0] = FUNC(add_residual4x4_u, depth); \
++ hevcdsp->add_residual_u[1] = FUNC(add_residual8x8_u, depth); \
++ hevcdsp->add_residual_u[2] = FUNC(add_residual16x16_u, depth); \
++ hevcdsp->add_residual_u[3] = FUNC(add_residual32x32_u, depth); \
++ hevcdsp->add_residual_v[0] = FUNC(add_residual4x4_v, depth); \
++ hevcdsp->add_residual_v[1] = FUNC(add_residual8x8_v, depth); \
++ hevcdsp->add_residual_v[2] = FUNC(add_residual16x16_v, depth); \
++ hevcdsp->add_residual_v[3] = FUNC(add_residual32x32_v, depth); \
++ hevcdsp->add_residual_c[0] = FUNC(add_residual4x4_c, depth); \
++ hevcdsp->add_residual_c[1] = FUNC(add_residual8x8_c, depth); \
++ hevcdsp->add_residual_c[2] = FUNC(add_residual16x16_c, depth); \
++ hevcdsp->add_residual_c[3] = FUNC(add_residual32x32_c, depth); \
++ hevcdsp->add_residual_dc_c[0] = FUNC(add_residual4x4_dc_c, depth); \
++ hevcdsp->add_residual_dc_c[1] = FUNC(add_residual8x8_dc_c, depth); \
++ hevcdsp->add_residual_dc_c[2] = FUNC(add_residual16x16_dc_c, depth); \
++ hevcdsp->add_residual_dc_c[3] = FUNC(add_residual32x32_dc_c, depth); \
++ hevcdsp->put_pcm_c = FUNC(put_pcm_c, depth)
++#define SLICED_LOOP_FILTERS(depth)\
++ hevcdsp->hevc_h_loop_filter_luma2 = FUNC(hevc_h_loop_filter_luma2, depth); \
++ hevcdsp->hevc_v_loop_filter_luma2 = FUNC(hevc_v_loop_filter_luma2, depth); \
++ hevcdsp->hevc_h_loop_filter_uv = FUNC(hevc_h_loop_filter_uv, depth); \
++ hevcdsp->hevc_v_loop_filter_uv2 = FUNC(hevc_v_loop_filter_uv2, depth)
++#define SLICED_SAO(depth)\
++ for (i = 0; i != SAO_FILTER_N; ++i) { \
++ hevcdsp->sao_band_filter_c[i] = FUNC(sao_band_filter_c, depth); \
++ hevcdsp->sao_edge_filter_c[i] = FUNC(sao_edge_filter_c, depth); \
++ } \
++ hevcdsp->sao_edge_restore_c[0] = FUNC(sao_edge_restore_c_0, depth); \
++ hevcdsp->sao_edge_restore_c[1] = FUNC(sao_edge_restore_c_1, depth)
++
++#define HEVC_DSP(depth) \
++ hevcdsp->put_pcm = FUNC(put_pcm, depth); \
++ hevcdsp->add_residual[0] = FUNC(add_residual4x4, depth); \
++ hevcdsp->add_residual[1] = FUNC(add_residual8x8, depth); \
++ hevcdsp->add_residual[2] = FUNC(add_residual16x16, depth); \
++ hevcdsp->add_residual[3] = FUNC(add_residual32x32, depth); \
++ hevcdsp->add_residual_dc[0] = FUNC(add_residual4x4_dc, depth); \
++ hevcdsp->add_residual_dc[1] = FUNC(add_residual8x8_dc, depth); \
++ hevcdsp->add_residual_dc[2] = FUNC(add_residual16x16_dc, depth); \
++ hevcdsp->add_residual_dc[3] = FUNC(add_residual32x32_dc, depth); \
++ SLICED_ADD_RESIDUAL(depth); \
++ hevcdsp->dequant = FUNC(dequant, depth); \
++ hevcdsp->transform_rdpcm = FUNC(transform_rdpcm, depth); \
++ hevcdsp->transform_4x4_luma = FUNC(transform_4x4_luma, depth); \
++ hevcdsp->idct[0] = FUNC(idct_4x4, depth); \
++ hevcdsp->idct[1] = FUNC(idct_8x8, depth); \
++ hevcdsp->idct[2] = FUNC(idct_16x16, depth); \
++ hevcdsp->idct[3] = FUNC(idct_32x32, depth); \
++ \
++ hevcdsp->idct_dc[0] = FUNC(idct_4x4_dc, depth); \
++ hevcdsp->idct_dc[1] = FUNC(idct_8x8_dc, depth); \
++ hevcdsp->idct_dc[2] = FUNC(idct_16x16_dc, depth); \
++ hevcdsp->idct_dc[3] = FUNC(idct_32x32_dc, depth); \
++ \
++ for (i = 0; i != SAO_FILTER_N; ++i) { \
++ hevcdsp->sao_band_filter[i] = FUNC(sao_band_filter, depth); \
++ hevcdsp->sao_edge_filter[i] = FUNC(sao_edge_filter, depth); \
++ } \
++ hevcdsp->sao_edge_restore[0] = FUNC(sao_edge_restore_0, depth); \
++ hevcdsp->sao_edge_restore[1] = FUNC(sao_edge_restore_1, depth); \
++ SLICED_SAO(depth); \
++ \
++ QPEL_FUNCS(depth); \
++ QPEL_UNI_FUNCS(depth); \
++ QPEL_BI_FUNCS(depth); \
++ EPEL_FUNCS(depth); \
++ EPEL_UNI_FUNCS(depth); \
++ EPEL_BI_FUNCS(depth); \
++ \
++ SLICED_LOOP_FILTERS(depth); \
++ hevcdsp->hevc_h_loop_filter_luma = FUNC(hevc_h_loop_filter_luma, depth); \
++ hevcdsp->hevc_v_loop_filter_luma = FUNC(hevc_v_loop_filter_luma, depth); \
++ hevcdsp->hevc_h_loop_filter_chroma = FUNC(hevc_h_loop_filter_chroma, depth); \
++ hevcdsp->hevc_v_loop_filter_chroma = FUNC(hevc_v_loop_filter_chroma, depth); \
++ hevcdsp->hevc_h_loop_filter_luma_c = FUNC(hevc_h_loop_filter_luma, depth); \
++ hevcdsp->hevc_v_loop_filter_luma_c = FUNC(hevc_v_loop_filter_luma, depth); \
++ hevcdsp->hevc_h_loop_filter_chroma_c = FUNC(hevc_h_loop_filter_chroma, depth); \
++ hevcdsp->hevc_v_loop_filter_chroma_c = FUNC(hevc_v_loop_filter_chroma, depth)
++int i = 0;
++
++ switch (bit_depth) {
++ case 9:
++ HEVC_DSP(9);
++ break;
++ case 10:
++ HEVC_DSP(10);
++ break;
++ case 12:
++ HEVC_DSP(12);
++ break;
++ default:
++ HEVC_DSP(8);
++ break;
++ }
++
++ hevcdsp->hevc_deblocking_boundary_strengths = hevc_deblocking_boundary_strengths;
++ hevcdsp->cpy_blk = cpy_blk;
++
++ if (ARCH_PPC)
++ ff_hevc_rpi_dsp_init_ppc(hevcdsp, bit_depth);
++ if (ARCH_X86)
++ ff_hevc_rpi_dsp_init_x86(hevcdsp, bit_depth);
++ if (ARCH_ARM)
++ ff_hevcdsp_rpi_init_arm(hevcdsp, bit_depth);
++ if (ARCH_MIPS)
++ ff_hevc_rpi_dsp_init_mips(hevcdsp, bit_depth);
++}
+diff --git a/libavcodec/rpi_hevcdsp.h b/libavcodec/rpi_hevcdsp.h
+new file mode 100644
+index 0000000000..5a7cdeeb66
+--- /dev/null
++++ b/libavcodec/rpi_hevcdsp.h
+@@ -0,0 +1,177 @@
++/*
++ * HEVC video decoder
++ *
++ * Copyright (C) 2012 - 2013 Guillaume Martres
++ * Copyright (C) 2013 - 2014 Pierre-Edouard Lepere
++ *
++ *
++ * This file is part of FFmpeg.
++ *
++ * FFmpeg is free software; you can redistribute it and/or
++ * modify it under the terms of the GNU Lesser General Public
++ * License as published by the Free Software Foundation; either
++ * version 2.1 of the License, or (at your option) any later version.
++ *
++ * FFmpeg is distributed in the hope that it will be useful,
++ * but WITHOUT ANY WARRANTY; without even the implied warranty of
++ * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
++ * Lesser General Public License for more details.
++ *
++ * You should have received a copy of the GNU Lesser General Public
++ * License along with FFmpeg; if not, write to the Free Software
++ * Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA
++ */
++
++#ifndef AVCODEC_RPI_HEVCDSP_H
++#define AVCODEC_RPI_HEVCDSP_H
++
++#include "hevc.h"
++#include "get_bits.h"
++
++struct HEVCRpiMvField;
++
++#define MAX_PB_SIZE 64
++
++#define RPI_HEVC_SAO_BUF_STRIDE 160
++
++
++typedef struct RpiSAOParams {
++ uint8_t band_position[3]; ///< sao_band_position (Y,U,V)
++ uint8_t eo_class[3]; ///< sao_eo_class (Y,U=V)
++ uint8_t type_idx[3]; ///< sao_type_idx (Y,U=V)
++
++ int16_t offset_val[3][5]; ///<SaoOffsetVal (Y,U,V)
++
++} RpiSAOParams;
++
++
++// This controls how many sao dsp functions there are
++// N=5 has width = 8, 16, 32, 48, 64
++// N=6 adds a function for width=24 (in fn array el 5 so existing code should
++// still work)
++#define SAO_FILTER_N 6
++
++
++typedef struct HEVCDSPContext {
++ void (*put_pcm)(uint8_t *_dst, ptrdiff_t _stride, int width, int height,
++ struct GetBitContext *gb, int pcm_bit_depth);
++
++ void (*add_residual[4])(uint8_t *dst, int16_t *res, ptrdiff_t stride);
++ void (*add_residual_dc[4])(uint8_t *dst, ptrdiff_t stride, int dc);
++ void (*add_residual_u[4])(uint8_t *dst, const int16_t *res, ptrdiff_t stride, int dc_v);
++ void (*add_residual_v[4])(uint8_t *dst, const int16_t *res, ptrdiff_t stride, int dc_u);
++
++ void (*add_residual_c[4])(uint8_t *dst, const int16_t *res, ptrdiff_t stride);
++ void (*add_residual_dc_c[4])(uint8_t *dst, ptrdiff_t stride, int32_t dc_uv);
++ void (*put_pcm_c)(uint8_t *_dst, ptrdiff_t _stride, int width, int height,
++ struct GetBitContext *gb, int pcm_bit_depth);
++
++ void (*dequant)(int16_t *coeffs, int16_t log2_size);
++
++ void (*transform_rdpcm)(int16_t *coeffs, int16_t log2_size, int mode);
++
++ void (*transform_4x4_luma)(int16_t *coeffs);
++
++ void (*idct[4])(int16_t *coeffs, int col_limit);
++
++ void (*idct_dc[4])(int16_t *coeffs);
++
++ void (*sao_band_filter[SAO_FILTER_N])(uint8_t *_dst, uint8_t *_src, ptrdiff_t _stride_dst, ptrdiff_t _stride_src,
++ int16_t *sao_offset_val, int sao_left_class, int width, int height);
++ void (*sao_band_filter_c[SAO_FILTER_N])(uint8_t *_dst, const uint8_t *_src, ptrdiff_t _stride_dst, ptrdiff_t _stride_src,
++ const int16_t *sao_offset_val_u, int sao_left_class_u,
++ const int16_t *sao_offset_val_v, int sao_left_class_v,
++ int width, int height);
++
++ /* implicit stride_src parameter has value of 2 * MAX_PB_SIZE + AV_INPUT_BUFFER_PADDING_SIZE */
++ void (*sao_edge_filter[SAO_FILTER_N])(uint8_t *_dst /* align 16 */, uint8_t *_src /* align 32 */, ptrdiff_t stride_dst,
++ int16_t *sao_offset_val, int sao_eo_class, int width, int height);
++ void (*sao_edge_filter_c[SAO_FILTER_N])(uint8_t *_dst /* align 16 */, const uint8_t *_src /* align 32 */, ptrdiff_t stride_dst,
++ const int16_t *sao_offset_val_u, const int16_t *sao_offset_val_v, int sao_eo_class, int width, int height);
++
++ void (*sao_edge_restore[2])(uint8_t *_dst, uint8_t *_src, ptrdiff_t _stride_dst, ptrdiff_t _stride_src,
++ struct RpiSAOParams *sao, int *borders, int _width, int _height, int c_idx,
++ uint8_t *vert_edge, uint8_t *horiz_edge, uint8_t *diag_edge);
++ void (*sao_edge_restore_c[2])(uint8_t *_dst, uint8_t *_src, ptrdiff_t _stride_dst, ptrdiff_t _stride_src,
++ struct RpiSAOParams *sao, int *borders, int _width, int _height, int c_idx,
++ uint8_t *vert_edge, uint8_t *horiz_edge, uint8_t *diag_edge);
++
++ void (*put_hevc_qpel[10][2][2])(int16_t *dst, uint8_t *src, ptrdiff_t srcstride,
++ int height, intptr_t mx, intptr_t my, int width);
++ void (*put_hevc_qpel_uni[10][2][2])(uint8_t *dst, ptrdiff_t dststride, uint8_t *src, ptrdiff_t srcstride,
++ int height, intptr_t mx, intptr_t my, int width);
++ void (*put_hevc_qpel_uni_w[10][2][2])(uint8_t *_dst, ptrdiff_t _dststride, uint8_t *_src, ptrdiff_t _srcstride,
++ int height, int denom, int wx, int ox, intptr_t mx, intptr_t my, int width);
++
++ void (*put_hevc_qpel_bi[10][2][2])(uint8_t *dst, ptrdiff_t dststride, uint8_t *_src, ptrdiff_t _srcstride,
++ int16_t *src2,
++ int height, intptr_t mx, intptr_t my, int width);
++ void (*put_hevc_qpel_bi_w[10][2][2])(uint8_t *dst, ptrdiff_t dststride, uint8_t *_src, ptrdiff_t _srcstride,
++ int16_t *src2,
++ int height, int denom, int wx0, int wx1,
++ int ox0, int ox1, intptr_t mx, intptr_t my, int width);
++ void (*put_hevc_epel[10][2][2])(int16_t *dst, uint8_t *src, ptrdiff_t srcstride,
++ int height, intptr_t mx, intptr_t my, int width);
++
++ void (*put_hevc_epel_uni[10][2][2])(uint8_t *dst, ptrdiff_t dststride, uint8_t *_src, ptrdiff_t _srcstride,
++ int height, intptr_t mx, intptr_t my, int width);
++ void (*put_hevc_epel_uni_w[10][2][2])(uint8_t *_dst, ptrdiff_t _dststride, uint8_t *_src, ptrdiff_t _srcstride,
++ int height, int denom, int wx, int ox, intptr_t mx, intptr_t my, int width);
++ void (*put_hevc_epel_bi[10][2][2])(uint8_t *dst, ptrdiff_t dststride, uint8_t *_src, ptrdiff_t _srcstride,
++ int16_t *src2,
++ int height, intptr_t mx, intptr_t my, int width);
++ void (*put_hevc_epel_bi_w[10][2][2])(uint8_t *dst, ptrdiff_t dststride, uint8_t *_src, ptrdiff_t _srcstride,
++ int16_t *src2,
++ int height, int denom, int wx0, int ox0, int wx1,
++ int ox1, intptr_t mx, intptr_t my, int width);
++
++ void (*hevc_h_loop_filter_luma)(uint8_t *pix, ptrdiff_t stride,
++ int beta, int32_t *tc,
++ uint8_t *no_p, uint8_t *no_q);
++ void (*hevc_v_loop_filter_luma)(uint8_t *pix, ptrdiff_t stride,
++ int beta, int32_t *tc,
++ uint8_t *no_p, uint8_t *no_q);
++ void (*hevc_h_loop_filter_chroma)(uint8_t *pix, ptrdiff_t stride,
++ int32_t *tc, uint8_t *no_p, uint8_t *no_q);
++ void (*hevc_v_loop_filter_chroma)(uint8_t *pix, ptrdiff_t stride,
++ int32_t *tc, uint8_t *no_p, uint8_t *no_q);
++ void (*hevc_h_loop_filter_luma_c)(uint8_t *pix, ptrdiff_t stride,
++ int beta, int32_t *tc,
++ uint8_t *no_p, uint8_t *no_q);
++ void (*hevc_v_loop_filter_luma_c)(uint8_t *pix, ptrdiff_t stride,
++ int beta, int32_t *tc,
++ uint8_t *no_p, uint8_t *no_q);
++ void (*hevc_h_loop_filter_chroma_c)(uint8_t *pix, ptrdiff_t stride,
++ int32_t *tc, uint8_t *no_p,
++ uint8_t *no_q);
++ void (*hevc_v_loop_filter_chroma_c)(uint8_t *pix, ptrdiff_t stride,
++ int32_t *tc, uint8_t *no_p,
++ uint8_t *no_q);
++ void (*hevc_h_loop_filter_luma2)(uint8_t * _pix_r,
++ unsigned int _stride, unsigned int beta, unsigned int tc2, unsigned int no_f);
++ void (*hevc_v_loop_filter_luma2)(uint8_t * _pix_r,
++ unsigned int _stride, unsigned int beta, unsigned int tc2, unsigned int no_f,
++ uint8_t * _pix_l);
++ void (*hevc_h_loop_filter_uv)(uint8_t * src, unsigned int stride, uint32_t tc4,
++ unsigned int no_f);
++ void (*hevc_v_loop_filter_uv2)(uint8_t * src_r, unsigned int stride, uint32_t tc4,
++ uint8_t * src_l,
++ unsigned int no_f);
++
++ uint32_t (*hevc_deblocking_boundary_strengths)(int pus, int dup, const struct HEVCRpiMvField *curr, const struct HEVCRpiMvField *neigh,
++ const int *curr_rpl0, const int *curr_rpl1, const int *neigh_rpl0, const int *neigh_rpl1,
++ int in_inc0, int inc_inc1);
++
++ void (* cpy_blk)(uint8_t * dst, unsigned int dst_stride, const uint8_t * src, unsigned int src_stride, unsigned int width, unsigned int height);
++} HEVCDSPContext;
++
++void ff_hevc_rpi_dsp_init(HEVCDSPContext *hpc, int bit_depth);
++
++extern const int8_t ff_hevc_rpi_epel_filters[7][4];
++extern const int8_t ff_hevc_rpi_qpel_filters[3][16];
++
++void ff_hevc_rpi_dsp_init_ppc(HEVCDSPContext *c, const int bit_depth);
++void ff_hevc_rpi_dsp_init_x86(HEVCDSPContext *c, const int bit_depth);
++void ff_hevcdsp_rpi_init_arm(HEVCDSPContext *c, const int bit_depth);
++void ff_hevc_rpi_dsp_init_mips(HEVCDSPContext *c, const int bit_depth);
++#endif /* AVCODEC_RPI_HEVCDSP_H */
+diff --git a/libavcodec/rpi_hevcdsp_template.c b/libavcodec/rpi_hevcdsp_template.c
+new file mode 100644
+index 0000000000..d1196a4440
+--- /dev/null
++++ b/libavcodec/rpi_hevcdsp_template.c
+@@ -0,0 +1,2278 @@
++/*
++ * HEVC video decoder
++ *
++ * Copyright (C) 2012 - 2013 Guillaume Martres
++ *
++ * This file is part of FFmpeg.
++ *
++ * FFmpeg is free software; you can redistribute it and/or
++ * modify it under the terms of the GNU Lesser General Public
++ * License as published by the Free Software Foundation; either
++ * version 2.1 of the License, or (at your option) any later version.
++ *
++ * FFmpeg is distributed in the hope that it will be useful,
++ * but WITHOUT ANY WARRANTY; without even the implied warranty of
++ * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
++ * Lesser General Public License for more details.
++ *
++ * You should have received a copy of the GNU Lesser General Public
++ * License along with FFmpeg; if not, write to the Free Software
++ * Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA
++ */
++
++#include "get_bits.h"
++#include "rpi_hevcdec.h"
++
++#include "bit_depth_template.c"
++#include "rpi_hevcdsp.h"
++
++#include "rpi_hevc_shader_template.h"
++
++static void FUNC(put_pcm)(uint8_t *_dst, ptrdiff_t stride, int width, int height,
++ GetBitContext *gb, int pcm_bit_depth)
++{
++ int x, y;
++ pixel *dst = (pixel *)_dst;
++
++ stride /= sizeof(pixel);
++
++ for (y = 0; y < height; y++) {
++ for (x = 0; x < width; x++)
++ dst[x] = get_bits(gb, pcm_bit_depth) << (BIT_DEPTH - pcm_bit_depth);
++ dst += stride;
++ }
++}
++
++static void FUNC(put_pcm_c)(uint8_t *_dst, ptrdiff_t stride, int width, int height,
++ GetBitContext *gb, int pcm_bit_depth)
++{
++ int x, y;
++ pixel *dst = (pixel *)_dst;
++
++ stride /= sizeof(pixel);
++
++ for (y = 0; y < height; y++) {
++ for (x = 0; x < width; x++)
++ dst[x*2] = get_bits(gb, pcm_bit_depth) << (BIT_DEPTH - pcm_bit_depth);
++ dst += stride;
++ }
++
++ dst = (pixel *)_dst + 1;
++ for (y = 0; y < height; y++) {
++ for (x = 0; x < width; x++)
++ dst[x*2] = get_bits(gb, pcm_bit_depth) << (BIT_DEPTH - pcm_bit_depth);
++ dst += stride;
++ }
++}
++
++static av_always_inline void FUNC(add_residual)(uint8_t *_dst, int16_t *res,
++ ptrdiff_t stride, int size)
++{
++ int x, y;
++ pixel *dst = (pixel *)_dst;
++
++ stride /= sizeof(pixel);
++
++ for (y = 0; y < size; y++) {
++ for (x = 0; x < size; x++) {
++ dst[x] = av_clip_pixel(dst[x] + *res);
++ res++;
++ }
++ dst += stride;
++ }
++}
++
++static av_always_inline void FUNC(add_residual_dc)(uint8_t *_dst, ptrdiff_t stride, const int dc, int size)
++{
++ int x, y;
++ pixel *dst = (pixel *)_dst;
++
++ stride /= sizeof(pixel);
++
++ for (y = 0; y < size; y++) {
++ for (x = 0; x < size; x++) {
++ dst[x] = av_clip_pixel(dst[x] + dc);
++ }
++ dst += stride;
++ }
++}
++
++
++static av_always_inline void FUNC(add_residual_u)(uint8_t *_dst, const int16_t *res,
++ ptrdiff_t stride, const int dc_v, int size)
++{
++ int x, y;
++ pixel *dst = (pixel *)_dst;
++
++ stride /= sizeof(pixel);
++
++ for (y = 0; y < size; y++) {
++ for (x = 0; x < size * 2; x += 2) {
++ dst[x] = av_clip_pixel(dst[x] + *res);
++ dst[x + 1] = av_clip_pixel(dst[x + 1] + dc_v);
++ res++;
++ }
++ dst += stride;
++ }
++}
++
++static av_always_inline void FUNC(add_residual_v)(uint8_t *_dst, const int16_t *res,
++ ptrdiff_t stride, const int dc_u, int size)
++{
++ int x, y;
++ pixel *dst = (pixel *)_dst;
++
++ stride /= sizeof(pixel);
++
++ for (y = 0; y < size; y++) {
++ for (x = 0; x < size * 2; x += 2) {
++ dst[x] = av_clip_pixel(dst[x] + dc_u);
++ dst[x + 1] = av_clip_pixel(dst[x + 1] + *res);
++ res++;
++ }
++ dst += stride;
++ }
++}
++
++static av_always_inline void FUNC(add_residual_c)(uint8_t *_dst, const int16_t *res,
++ ptrdiff_t stride, unsigned int size)
++{
++ unsigned int x, y;
++ pixel *dst = (pixel *)_dst;
++ const int16_t * ru = res;
++ const int16_t * rv = res + size * size;
++
++// rpi_sand_dump16("ARC In Pred", _dst, stride, 0, 0, 0, size, size, 1);
++// rpi_sand_dump16("ARC In RU", ru, size * 2, 0, 0, 0, size, size, 0);
++// rpi_sand_dump16("ARC In RV", rv, size * 2, 0, 0, 0, size, size, 0);
++
++ stride /= sizeof(pixel);
++
++ for (y = 0; y < size; y++) {
++ for (x = 0; x < size * 2; x += 2) {
++ dst[x + 0] = av_clip_pixel(dst[x + 0] + *ru++);
++ dst[x + 1] = av_clip_pixel(dst[x + 1] + *rv++);
++ }
++ dst += stride;
++ }
++
++// rpi_sand_dump16("ARC Out", _dst, stride * 2, 0, 0, 0, size, size, 1);
++}
++
++
++static av_always_inline void FUNC(add_residual_dc_c)(uint8_t *_dst, ptrdiff_t stride, const int32_t dc, int size)
++{
++ int x, y;
++ pixel *dst = (pixel *)_dst;
++ const int dc_v = dc >> 16;
++ const int dc_u = (dc << 16) >> 16;
++
++ stride /= sizeof(pixel);
++
++ for (y = 0; y < size; y++) {
++ for (x = 0; x < size * 2; x += 2) {
++ dst[x] = av_clip_pixel(dst[x] + dc_u);
++ dst[x + 1] = av_clip_pixel(dst[x + 1] + dc_v);
++ }
++ dst += stride;
++ }
++}
++
++
++static void FUNC(add_residual4x4)(uint8_t *_dst, int16_t *res,
++ ptrdiff_t stride)
++{
++ FUNC(add_residual)(_dst, res, stride, 4);
++}
++
++static void FUNC(add_residual8x8)(uint8_t *_dst, int16_t *res,
++ ptrdiff_t stride)
++{
++ FUNC(add_residual)(_dst, res, stride, 8);
++}
++
++static void FUNC(add_residual16x16)(uint8_t *_dst, int16_t *res,
++ ptrdiff_t stride)
++{
++ FUNC(add_residual)(_dst, res, stride, 16);
++}
++
++static void FUNC(add_residual32x32)(uint8_t *_dst, int16_t *res,
++ ptrdiff_t stride)
++{
++ FUNC(add_residual)(_dst, res, stride, 32);
++}
++
++static void FUNC(add_residual4x4_dc)(uint8_t *_dst, ptrdiff_t stride, int dc)
++{
++ FUNC(add_residual_dc)(_dst, stride, dc, 4);
++}
++
++static void FUNC(add_residual8x8_dc)(uint8_t *_dst, ptrdiff_t stride, int dc)
++{
++ FUNC(add_residual_dc)(_dst, stride, dc, 8);
++}
++
++static void FUNC(add_residual16x16_dc)(uint8_t *_dst, ptrdiff_t stride, int dc)
++{
++ FUNC(add_residual_dc)(_dst, stride, dc, 16);
++}
++
++static void FUNC(add_residual32x32_dc)(uint8_t *_dst, ptrdiff_t stride, int dc)
++{
++ FUNC(add_residual_dc)(_dst, stride, dc, 32);
++}
++
++// -- U -- (plaited)
++
++static void FUNC(add_residual4x4_u)(uint8_t *_dst, const int16_t * res,
++ ptrdiff_t stride, int dc_u)
++{
++ FUNC(add_residual_u)(_dst, res, stride, dc_u, 4);
++}
++
++static void FUNC(add_residual8x8_u)(uint8_t *_dst, const int16_t * res,
++ ptrdiff_t stride, int dc_u)
++{
++ FUNC(add_residual_u)(_dst, res, stride, dc_u, 8);
++}
++
++static void FUNC(add_residual16x16_u)(uint8_t *_dst, const int16_t * res,
++ ptrdiff_t stride, int dc_u)
++{
++ FUNC(add_residual_u)(_dst, res, stride, dc_u, 16);
++}
++
++static void FUNC(add_residual32x32_u)(uint8_t *_dst, const int16_t * res,
++ ptrdiff_t stride, int dc_u)
++{
++ // Should never occur for 420, which is all that sand supports
++ av_assert0(0);
++}
++
++// -- V -- (plaited)
++
++static void FUNC(add_residual4x4_v)(uint8_t *_dst, const int16_t * res,
++ ptrdiff_t stride, int dc_v)
++{
++ FUNC(add_residual_v)(_dst, res, stride, dc_v, 4);
++}
++
++static void FUNC(add_residual8x8_v)(uint8_t *_dst, const int16_t * res,
++ ptrdiff_t stride, int dc_v)
++{
++ FUNC(add_residual_v)(_dst, res, stride, dc_v, 8);
++}
++
++static void FUNC(add_residual16x16_v)(uint8_t *_dst, const int16_t * res,
++ ptrdiff_t stride, int dc_v)
++{
++ FUNC(add_residual_v)(_dst, res, stride, dc_v, 16);
++}
++
++static void FUNC(add_residual32x32_v)(uint8_t *_dst, const int16_t * res,
++ ptrdiff_t stride, int dc_v)
++{
++ // Should never occur for 420, which is all that sand supports
++ av_assert0(0);
++}
++
++// -- C -- (plaited - both U & V)
++
++static void FUNC(add_residual4x4_c)(uint8_t *_dst, const int16_t * res,
++ ptrdiff_t stride)
++{
++ FUNC(add_residual_c)(_dst, res, stride, 4);
++}
++
++static void FUNC(add_residual8x8_c)(uint8_t *_dst, const int16_t * res,
++ ptrdiff_t stride)
++{
++ FUNC(add_residual_c)(_dst, res, stride, 8);
++}
++
++static void FUNC(add_residual16x16_c)(uint8_t *_dst, const int16_t * res,
++ ptrdiff_t stride)
++{
++ FUNC(add_residual_c)(_dst, res, stride, 16);
++}
++
++static void FUNC(add_residual32x32_c)(uint8_t *_dst, const int16_t * res,
++ ptrdiff_t stride)
++{
++ // Should never occur for 420, which is all that sand supports
++ av_assert0(0);
++}
++
++static void FUNC(add_residual4x4_dc_c)(uint8_t *_dst, ptrdiff_t stride, int32_t dc)
++{
++ FUNC(add_residual_dc_c)(_dst, stride, dc, 4);
++}
++
++static void FUNC(add_residual8x8_dc_c)(uint8_t *_dst, ptrdiff_t stride, int32_t dc)
++{
++ FUNC(add_residual_dc_c)(_dst, stride, dc, 8);
++}
++
++static void FUNC(add_residual16x16_dc_c)(uint8_t *_dst, ptrdiff_t stride, int32_t dc)
++{
++ FUNC(add_residual_dc_c)(_dst, stride, dc, 16);
++}
++
++static void FUNC(add_residual32x32_dc_c)(uint8_t *_dst, ptrdiff_t stride, int32_t dc)
++{
++ // Should never occur for 420, which is all that sand supports
++ av_assert0(0);
++}
++
++
++static void FUNC(transform_rdpcm)(int16_t *_coeffs, int16_t log2_size, int mode)
++{
++ int16_t *coeffs = (int16_t *) _coeffs;
++ int x, y;
++ int size = 1 << log2_size;
++
++ if (mode) {
++ coeffs += size;
++ for (y = 0; y < size - 1; y++) {
++ for (x = 0; x < size; x++)
++ coeffs[x] += coeffs[x - size];
++ coeffs += size;
++ }
++ } else {
++ for (y = 0; y < size; y++) {
++ for (x = 1; x < size; x++)
++ coeffs[x] += coeffs[x - 1];
++ coeffs += size;
++ }
++ }
++}
++
++static void FUNC(dequant)(int16_t *coeffs, int16_t log2_size)
++{
++ int shift = 15 - BIT_DEPTH - log2_size;
++ int x, y;
++ int size = 1 << log2_size;
++
++ if (shift > 0) {
++ int offset = 1 << (shift - 1);
++ for (y = 0; y < size; y++) {
++ for (x = 0; x < size; x++) {
++ *coeffs = (*coeffs + offset) >> shift;
++ coeffs++;
++ }
++ }
++ } else {
++ for (y = 0; y < size; y++) {
++ for (x = 0; x < size; x++) {
++ *coeffs = *coeffs << -shift;
++ coeffs++;
++ }
++ }
++ }
++}
++
++#define SET(dst, x) (dst) = (x)
++#define SCALE(dst, x) (dst) = av_clip_int16(((x) + add) >> shift)
++
++#define TR_4x4_LUMA(dst, src, step, assign) \
++ do { \
++ int c0 = src[0 * step] + src[2 * step]; \
++ int c1 = src[2 * step] + src[3 * step]; \
++ int c2 = src[0 * step] - src[3 * step]; \
++ int c3 = 74 * src[1 * step]; \
++ \
++ assign(dst[2 * step], 74 * (src[0 * step] - \
++ src[2 * step] + \
++ src[3 * step])); \
++ assign(dst[0 * step], 29 * c0 + 55 * c1 + c3); \
++ assign(dst[1 * step], 55 * c2 - 29 * c1 + c3); \
++ assign(dst[3 * step], 55 * c0 + 29 * c2 - c3); \
++ } while (0)
++
++static void FUNC(transform_4x4_luma)(int16_t *coeffs)
++{
++ int i;
++ int shift = 7;
++ int add = 1 << (shift - 1);
++ int16_t *src = coeffs;
++
++ for (i = 0; i < 4; i++) {
++ TR_4x4_LUMA(src, src, 4, SCALE);
++ src++;
++ }
++
++ shift = 20 - BIT_DEPTH;
++ add = 1 << (shift - 1);
++ for (i = 0; i < 4; i++) {
++ TR_4x4_LUMA(coeffs, coeffs, 1, SCALE);
++ coeffs += 4;
++ }
++}
++
++#undef TR_4x4_LUMA
++
++#define TR_4(dst, src, dstep, sstep, assign, end) \
++ do { \
++ const int e0 = 64 * src[0 * sstep] + 64 * src[2 * sstep]; \
++ const int e1 = 64 * src[0 * sstep] - 64 * src[2 * sstep]; \
++ const int o0 = 83 * src[1 * sstep] + 36 * src[3 * sstep]; \
++ const int o1 = 36 * src[1 * sstep] - 83 * src[3 * sstep]; \
++ \
++ assign(dst[0 * dstep], e0 + o0); \
++ assign(dst[1 * dstep], e1 + o1); \
++ assign(dst[2 * dstep], e1 - o1); \
++ assign(dst[3 * dstep], e0 - o0); \
++ } while (0)
++
++#define TR_8(dst, src, dstep, sstep, assign, end) \
++ do { \
++ int i, j; \
++ int e_8[4]; \
++ int o_8[4] = { 0 }; \
++ for (i = 0; i < 4; i++) \
++ for (j = 1; j < end; j += 2) \
++ o_8[i] += transform[4 * j][i] * src[j * sstep]; \
++ TR_4(e_8, src, 1, 2 * sstep, SET, 4); \
++ \
++ for (i = 0; i < 4; i++) { \
++ assign(dst[i * dstep], e_8[i] + o_8[i]); \
++ assign(dst[(7 - i) * dstep], e_8[i] - o_8[i]); \
++ } \
++ } while (0)
++
++#define TR_16(dst, src, dstep, sstep, assign, end) \
++ do { \
++ int i, j; \
++ int e_16[8]; \
++ int o_16[8] = { 0 }; \
++ for (i = 0; i < 8; i++) \
++ for (j = 1; j < end; j += 2) \
++ o_16[i] += transform[2 * j][i] * src[j * sstep]; \
++ TR_8(e_16, src, 1, 2 * sstep, SET, 8); \
++ \
++ for (i = 0; i < 8; i++) { \
++ assign(dst[i * dstep], e_16[i] + o_16[i]); \
++ assign(dst[(15 - i) * dstep], e_16[i] - o_16[i]); \
++ } \
++ } while (0)
++
++#define TR_32(dst, src, dstep, sstep, assign, end) \
++ do { \
++ int i, j; \
++ int e_32[16]; \
++ int o_32[16] = { 0 }; \
++ for (i = 0; i < 16; i++) \
++ for (j = 1; j < end; j += 2) \
++ o_32[i] += transform[j][i] * src[j * sstep]; \
++ TR_16(e_32, src, 1, 2 * sstep, SET, end / 2); \
++ \
++ for (i = 0; i < 16; i++) { \
++ assign(dst[i * dstep], e_32[i] + o_32[i]); \
++ assign(dst[(31 - i) * dstep], e_32[i] - o_32[i]); \
++ } \
++ } while (0)
++
++#define IDCT_VAR4(H) \
++ int limit2 = FFMIN(col_limit + 4, H)
++#define IDCT_VAR8(H) \
++ int limit = FFMIN(col_limit, H); \
++ int limit2 = FFMIN(col_limit + 4, H)
++#define IDCT_VAR16(H) IDCT_VAR8(H)
++#define IDCT_VAR32(H) IDCT_VAR8(H)
++
++#define IDCT(H) \
++static void FUNC(idct_ ## H ## x ## H )(int16_t *coeffs, \
++ int col_limit) \
++{ \
++ int i; \
++ int shift = 7; \
++ int add = 1 << (shift - 1); \
++ int16_t *src = coeffs; \
++ IDCT_VAR ## H(H); \
++ \
++ for (i = 0; i < H; i++) { \
++ TR_ ## H(src, src, H, H, SCALE, limit2); \
++ if (limit2 < H && i%4 == 0 && !!i) \
++ limit2 -= 4; \
++ src++; \
++ } \
++ \
++ shift = 20 - BIT_DEPTH; \
++ add = 1 << (shift - 1); \
++ for (i = 0; i < H; i++) { \
++ TR_ ## H(coeffs, coeffs, 1, 1, SCALE, limit); \
++ coeffs += H; \
++ } \
++}
++
++#define IDCT_DC(H) \
++static void FUNC(idct_ ## H ## x ## H ## _dc)(int16_t *coeffs) \
++{ \
++ int i, j; \
++ int shift = 14 - BIT_DEPTH; \
++ int add = 1 << (shift - 1); \
++ int coeff = (((coeffs[0] + 1) >> 1) + add) >> shift; \
++ \
++ for (j = 0; j < H; j++) { \
++ for (i = 0; i < H; i++) { \
++ coeffs[i + j * H] = coeff; \
++ } \
++ } \
++}
++
++IDCT( 4)
++IDCT( 8)
++IDCT(16)
++IDCT(32)
++
++IDCT_DC( 4)
++IDCT_DC( 8)
++IDCT_DC(16)
++IDCT_DC(32)
++
++#undef TR_4
++#undef TR_8
++#undef TR_16
++#undef TR_32
++
++#undef SET
++#undef SCALE
++
++static void FUNC(sao_band_filter)(uint8_t *_dst, uint8_t *_src,
++ ptrdiff_t stride_dst, ptrdiff_t stride_src,
++ int16_t *sao_offset_val, int sao_left_class,
++ int width, int height)
++{
++ pixel *dst = (pixel *)_dst;
++ pixel *src = (pixel *)_src;
++ int offset_table[32] = { 0 };
++ int k, y, x;
++ int shift = BIT_DEPTH - 5;
++
++ stride_dst /= sizeof(pixel);
++ stride_src /= sizeof(pixel);
++
++ for (k = 0; k < 4; k++)
++ offset_table[(k + sao_left_class) & 31] = sao_offset_val[k + 1];
++ for (y = 0; y < height; y++) {
++ for (x = 0; x < width; x++)
++ dst[x] = av_clip_pixel(src[x] + offset_table[src[x] >> shift]);
++ dst += stride_dst;
++ src += stride_src;
++ }
++}
++
++#define CMP(a, b) (((a) > (b)) - ((a) < (b)))
++
++static void FUNC(sao_edge_filter)(uint8_t *_dst, uint8_t *_src, ptrdiff_t stride_dst, int16_t *sao_offset_val,
++ int eo, int width, int height) {
++
++ static const uint8_t edge_idx[] = { 1, 2, 0, 3, 4 };
++ static const int8_t pos[4][2][2] = {
++ { { -1, 0 }, { 1, 0 } }, // horizontal
++ { { 0, -1 }, { 0, 1 } }, // vertical
++ { { -1, -1 }, { 1, 1 } }, // 45 degree
++ { { 1, -1 }, { -1, 1 } }, // 135 degree
++ };
++ pixel *dst = (pixel *)_dst;
++ pixel *src = (pixel *)_src;
++ int a_stride, b_stride;
++ int x, y;
++ const ptrdiff_t stride_src = RPI_HEVC_SAO_BUF_STRIDE / sizeof(pixel);
++ stride_dst /= sizeof(pixel);
++
++ a_stride = pos[eo][0][0] + pos[eo][0][1] * stride_src;
++ b_stride = pos[eo][1][0] + pos[eo][1][1] * stride_src;
++ for (y = 0; y < height; y++) {
++ for (x = 0; x < width; x++) {
++ int diff0 = CMP(src[x], src[x + a_stride]);
++ int diff1 = CMP(src[x], src[x + b_stride]);
++ int offset_val = edge_idx[2 + diff0 + diff1];
++ dst[x] = av_clip_pixel(src[x] + sao_offset_val[offset_val]);
++ }
++ src += stride_src;
++ dst += stride_dst;
++ }
++}
++
++
++#if BIT_DEPTH == 10
++// We need a 32 bit variation for the _c restores so hijack bit depth 10
++#undef pixel
++#undef BIT_DEPTH
++#define pixel uint32_t
++#define BIT_DEPTH 32
++// All 16 bit variations are the same
++#define sao_edge_restore_0_10 sao_edge_restore_0_9
++#define sao_edge_restore_1_10 sao_edge_restore_1_9
++#define sao_edge_restore_0_11 sao_edge_restore_0_9
++#define sao_edge_restore_1_11 sao_edge_restore_1_9
++#define sao_edge_restore_0_12 sao_edge_restore_0_9
++#define sao_edge_restore_1_12 sao_edge_restore_1_9
++#define sao_edge_restore_0_13 sao_edge_restore_0_9
++#define sao_edge_restore_1_13 sao_edge_restore_1_9
++#define sao_edge_restore_0_14 sao_edge_restore_0_9
++#define sao_edge_restore_1_14 sao_edge_restore_1_9
++#define sao_edge_restore_0_15 sao_edge_restore_0_9
++#define sao_edge_restore_1_15 sao_edge_restore_1_9
++#define sao_edge_restore_0_16 sao_edge_restore_0_9
++#define sao_edge_restore_1_16 sao_edge_restore_1_9
++#endif
++#if BIT_DEPTH <= 9 || BIT_DEPTH == 32
++static void FUNC(sao_edge_restore_0)(uint8_t *_dst, uint8_t *_src,
++ ptrdiff_t stride_dst, ptrdiff_t stride_src, RpiSAOParams *sao,
++ int *borders, int _width, int _height,
++ int c_idx, uint8_t *vert_edge,
++ uint8_t *horiz_edge, uint8_t *diag_edge)
++{
++ int x, y;
++ pixel *dst = (pixel *)_dst;
++ pixel *src = (pixel *)_src;
++ int sao_eo_class = sao->eo_class[c_idx];
++ int init_x = 0, width = _width, height = _height;
++
++ stride_dst /= sizeof(pixel);
++ stride_src /= sizeof(pixel);
++
++ if (sao_eo_class != SAO_EO_VERT) {
++ if (borders[0]) {
++ for (y = 0; y < height; y++) {
++ dst[y * stride_dst] = src[y * stride_src];
++ }
++ init_x = 1;
++ }
++ if (borders[2]) {
++ int offset = width - 1;
++ for (x = 0; x < height; x++) {
++ dst[x * stride_dst + offset] = src[x * stride_src + offset];
++ }
++ width--;
++ }
++ }
++ if (sao_eo_class != SAO_EO_HORIZ) {
++ if (borders[1]) {
++ for (x = init_x; x < width; x++)
++ dst[x] = src[x];
++ }
++ if (borders[3]) {
++ ptrdiff_t y_stride_dst = stride_dst * (height - 1);
++ ptrdiff_t y_stride_src = stride_src * (height - 1);
++ for (x = init_x; x < width; x++)
++ dst[x + y_stride_dst] = src[x + y_stride_src];
++ height--;
++ }
++ }
++}
++
++static void FUNC(sao_edge_restore_1)(uint8_t *_dst, uint8_t *_src,
++ ptrdiff_t stride_dst, ptrdiff_t stride_src, RpiSAOParams *sao,
++ int *borders, int _width, int _height,
++ int c_idx, uint8_t *vert_edge,
++ uint8_t *horiz_edge, uint8_t *diag_edge)
++{
++ int x, y;
++ pixel *dst = (pixel *)_dst;
++ pixel *src = (pixel *)_src;
++ int sao_eo_class = sao->eo_class[c_idx];
++ int init_x = 0, init_y = 0, width = _width, height = _height;
++
++ stride_dst /= sizeof(pixel);
++ stride_src /= sizeof(pixel);
++
++ if (sao_eo_class != SAO_EO_VERT) {
++ if (borders[0]) {
++ for (y = 0; y < height; y++) {
++ dst[y * stride_dst] = src[y * stride_src];
++ }
++ init_x = 1;
++ }
++ if (borders[2]) {
++ int offset = width - 1;
++ for (x = 0; x < height; x++) {
++ dst[x * stride_dst + offset] = src[x * stride_src + offset];
++ }
++ width--;
++ }
++ }
++ if (sao_eo_class != SAO_EO_HORIZ) {
++ if (borders[1]) {
++ for (x = init_x; x < width; x++)
++ dst[x] = src[x];
++ init_y = 1;
++ }
++ if (borders[3]) {
++ ptrdiff_t y_stride_dst = stride_dst * (height - 1);
++ ptrdiff_t y_stride_src = stride_src * (height - 1);
++ for (x = init_x; x < width; x++)
++ dst[x + y_stride_dst] = src[x + y_stride_src];
++ height--;
++ }
++ }
++
++ {
++ int save_upper_left = !diag_edge[0] && sao_eo_class == SAO_EO_135D && !borders[0] && !borders[1];
++ int save_upper_right = !diag_edge[1] && sao_eo_class == SAO_EO_45D && !borders[1] && !borders[2];
++ int save_lower_right = !diag_edge[2] && sao_eo_class == SAO_EO_135D && !borders[2] && !borders[3];
++ int save_lower_left = !diag_edge[3] && sao_eo_class == SAO_EO_45D && !borders[0] && !borders[3];
++
++ // Restore pixels that can't be modified
++ if(vert_edge[0] && sao_eo_class != SAO_EO_VERT) {
++ for(y = init_y+save_upper_left; y< height-save_lower_left; y++)
++ dst[y*stride_dst] = src[y*stride_src];
++ }
++ if(vert_edge[1] && sao_eo_class != SAO_EO_VERT) {
++ for(y = init_y+save_upper_right; y< height-save_lower_right; y++)
++ dst[y*stride_dst+width-1] = src[y*stride_src+width-1];
++ }
++
++ if(horiz_edge[0] && sao_eo_class != SAO_EO_HORIZ) {
++ for(x = init_x+save_upper_left; x < width-save_upper_right; x++)
++ dst[x] = src[x];
++ }
++ if(horiz_edge[1] && sao_eo_class != SAO_EO_HORIZ) {
++ for(x = init_x+save_lower_left; x < width-save_lower_right; x++)
++ dst[(height-1)*stride_dst+x] = src[(height-1)*stride_src+x];
++ }
++ if(diag_edge[0] && sao_eo_class == SAO_EO_135D)
++ dst[0] = src[0];
++ if(diag_edge[1] && sao_eo_class == SAO_EO_45D)
++ dst[width-1] = src[width-1];
++ if(diag_edge[2] && sao_eo_class == SAO_EO_135D)
++ dst[stride_dst*(height-1)+width-1] = src[stride_src*(height-1)+width-1];
++ if(diag_edge[3] && sao_eo_class == SAO_EO_45D)
++ dst[stride_dst*(height-1)] = src[stride_src*(height-1)];
++
++ }
++}
++#endif
++#if BIT_DEPTH == 32
++#undef BIT_DEPTH
++#undef pixel
++#define BIT_DEPTH 10
++#define pixel uint16_t
++#endif
++
++// --- Plaited chroma versions
++
++static void FUNC(sao_band_filter_c)(uint8_t *_dst, const uint8_t *_src,
++ ptrdiff_t stride_dst, ptrdiff_t stride_src,
++ const int16_t *sao_offset_val_u, int sao_left_class_u,
++ const int16_t *sao_offset_val_v, int sao_left_class_v,
++ int width, int height)
++{
++ pixel *dst = (pixel *)_dst;
++ pixel *src = (pixel *)_src;
++ int offset_table_u[32] = { 0 };
++ int offset_table_v[32] = { 0 };
++ int k, y, x;
++ int shift = BIT_DEPTH - 5;
++
++ stride_dst /= sizeof(pixel);
++ stride_src /= sizeof(pixel);
++ width *= 2;
++
++ for (k = 0; k < 4; k++)
++ {
++ offset_table_u[(k + sao_left_class_u) & 31] = sao_offset_val_u[k + 1];
++ offset_table_v[(k + sao_left_class_v) & 31] = sao_offset_val_v[k + 1];
++ }
++ for (y = 0; y < height; y++) {
++ for (x = 0; x < width; x += 2)
++ {
++// printf("dst=%p, src=%p, x=%d, shift=%d\n", dst, src, x, shift);
++// printf("offsets=%x,%x\n", src[x + 0], src[x + 1]);
++ // *** & 31 shouldn't be wanted but just now we generate broken input that
++ // crashes us in 10-bit world
++ dst[x + 0] = av_clip_pixel(src[x + 0] + offset_table_u[(src[x + 0] >> shift) & 31]);
++ dst[x + 1] = av_clip_pixel(src[x + 1] + offset_table_v[(src[x + 1] >> shift) & 31]);
++ }
++ dst += stride_dst;
++ src += stride_src;
++ }
++}
++
++static void FUNC(sao_edge_filter_c)(uint8_t *_dst, const uint8_t *_src, ptrdiff_t stride_dst,
++ const int16_t *sao_offset_val_u, const int16_t *sao_offset_val_v,
++ int eo, int width, int height) {
++
++ static const uint8_t edge_idx[] = { 1, 2, 0, 3, 4 };
++ static const int8_t pos[4][2][2] = {
++ { { -1, 0 }, { 1, 0 } }, // horizontal
++ { { 0, -1 }, { 0, 1 } }, // vertical
++ { { -1, -1 }, { 1, 1 } }, // 45 degree
++ { { 1, -1 }, { -1, 1 } }, // 135 degree
++ };
++ pixel *dst = (pixel *)_dst;
++ pixel *src = (pixel *)_src;
++ int a_stride, b_stride;
++ int x, y;
++ const ptrdiff_t stride_src = RPI_HEVC_SAO_BUF_STRIDE / sizeof(pixel);
++
++ stride_dst /= sizeof(pixel);
++ width *= 2;
++
++ av_assert0(width <= 64);
++
++ a_stride = pos[eo][0][0] * 2 + pos[eo][0][1] * stride_src;
++ b_stride = pos[eo][1][0] * 2 + pos[eo][1][1] * stride_src;
++ for (y = 0; y < height; y++) {
++ for (x = 0; x < width; x += 2) {
++ int diff0u = CMP(src[x], src[x + a_stride]);
++ int diff1u = CMP(src[x], src[x + b_stride]);
++ int offset_valu = edge_idx[2 + diff0u + diff1u];
++ int diff0v = CMP(src[x+1], src[x+1 + a_stride]);
++ int diff1v = CMP(src[x+1], src[x+1 + b_stride]);
++ int offset_valv = edge_idx[2 + diff0v + diff1v];
++ dst[x] = av_clip_pixel(src[x] + sao_offset_val_u[offset_valu]);
++ dst[x+1] = av_clip_pixel(src[x+1] + sao_offset_val_v[offset_valv]);
++ }
++ src += stride_src;
++ dst += stride_dst;
++ }
++}
++
++// Do once
++#if BIT_DEPTH == 8
++// Any old 2 byte 'normal' restore will work for these
++#define sao_edge_restore_c_0_8 sao_edge_restore_0_16
++#define sao_edge_restore_c_1_8 sao_edge_restore_1_16
++// We need 32 bit for 9 bit+
++#define sao_edge_restore_c_0_9 sao_edge_restore_0_32
++#define sao_edge_restore_c_1_9 sao_edge_restore_1_32
++#define sao_edge_restore_c_0_10 sao_edge_restore_0_32
++#define sao_edge_restore_c_1_10 sao_edge_restore_1_32
++#define sao_edge_restore_c_0_11 sao_edge_restore_0_32
++#define sao_edge_restore_c_1_11 sao_edge_restore_1_32
++#define sao_edge_restore_c_0_12 sao_edge_restore_0_32
++#define sao_edge_restore_c_1_12 sao_edge_restore_1_32
++#define sao_edge_restore_c_0_13 sao_edge_restore_0_32
++#define sao_edge_restore_c_1_13 sao_edge_restore_1_32
++#define sao_edge_restore_c_0_14 sao_edge_restore_0_32
++#define sao_edge_restore_c_1_14 sao_edge_restore_1_32
++#define sao_edge_restore_c_0_15 sao_edge_restore_0_32
++#define sao_edge_restore_c_1_15 sao_edge_restore_1_32
++#define sao_edge_restore_c_0_16 sao_edge_restore_0_32
++#define sao_edge_restore_c_1_16 sao_edge_restore_1_32
++#endif
++
++#undef CMP
++
++////////////////////////////////////////////////////////////////////////////////
++//
++////////////////////////////////////////////////////////////////////////////////
++static void FUNC(put_hevc_pel_pixels)(int16_t *dst,
++ uint8_t *_src, ptrdiff_t _srcstride,
++ int height, intptr_t mx, intptr_t my, int width)
++{
++ int x, y;
++ pixel *src = (pixel *)_src;
++ ptrdiff_t srcstride = _srcstride / sizeof(pixel);
++
++ for (y = 0; y < height; y++) {
++ for (x = 0; x < width; x++)
++ dst[x] = src[x] << (14 - BIT_DEPTH);
++ src += srcstride;
++ dst += MAX_PB_SIZE;
++ }
++}
++
++static void FUNC(put_hevc_pel_uni_pixels)(uint8_t *_dst, ptrdiff_t _dststride, uint8_t *_src, ptrdiff_t _srcstride,
++ int height, intptr_t mx, intptr_t my, int width)
++{
++ int y;
++ pixel *src = (pixel *)_src;
++ ptrdiff_t srcstride = _srcstride / sizeof(pixel);
++ pixel *dst = (pixel *)_dst;
++ ptrdiff_t dststride = _dststride / sizeof(pixel);
++
++ for (y = 0; y < height; y++) {
++ memcpy(dst, src, width * sizeof(pixel));
++ src += srcstride;
++ dst += dststride;
++ }
++}
++
++static void FUNC(put_hevc_pel_bi_pixels)(uint8_t *_dst, ptrdiff_t _dststride, uint8_t *_src, ptrdiff_t _srcstride,
++ int16_t *src2,
++ int height, intptr_t mx, intptr_t my, int width)
++{
++ int x, y;
++ pixel *src = (pixel *)_src;
++ ptrdiff_t srcstride = _srcstride / sizeof(pixel);
++ pixel *dst = (pixel *)_dst;
++ ptrdiff_t dststride = _dststride / sizeof(pixel);
++
++ int shift = 14 + 1 - BIT_DEPTH;
++#if BIT_DEPTH < 14
++ int offset = 1 << (shift - 1);
++#else
++ int offset = 0;
++#endif
++
++ for (y = 0; y < height; y++) {
++ for (x = 0; x < width; x++)
++ dst[x] = av_clip_pixel(((src[x] << (14 - BIT_DEPTH)) + src2[x] + offset) >> shift);
++ src += srcstride;
++ dst += dststride;
++ src2 += MAX_PB_SIZE;
++ }
++}
++
++static void FUNC(put_hevc_pel_uni_w_pixels)(uint8_t *_dst, ptrdiff_t _dststride, uint8_t *_src, ptrdiff_t _srcstride,
++ int height, int denom, int wx, int ox, intptr_t mx, intptr_t my, int width)
++{
++ int x, y;
++ pixel *src = (pixel *)_src;
++ ptrdiff_t srcstride = _srcstride / sizeof(pixel);
++ pixel *dst = (pixel *)_dst;
++ ptrdiff_t dststride = _dststride / sizeof(pixel);
++ int shift = denom + 14 - BIT_DEPTH;
++#if BIT_DEPTH < 14
++ int offset = 1 << (shift - 1);
++#else
++ int offset = 0;
++#endif
++
++ ox = ox * (1 << (BIT_DEPTH - 8));
++ for (y = 0; y < height; y++) {
++ for (x = 0; x < width; x++)
++ dst[x] = av_clip_pixel((((src[x] << (14 - BIT_DEPTH)) * wx + offset) >> shift) + ox);
++ src += srcstride;
++ dst += dststride;
++ }
++}
++
++static void FUNC(put_hevc_pel_bi_w_pixels)(uint8_t *_dst, ptrdiff_t _dststride, uint8_t *_src, ptrdiff_t _srcstride,
++ int16_t *src2,
++ int height, int denom, int wx0, int wx1,
++ int ox0, int ox1, intptr_t mx, intptr_t my, int width)
++{
++ int x, y;
++ pixel *src = (pixel *)_src;
++ ptrdiff_t srcstride = _srcstride / sizeof(pixel);
++ pixel *dst = (pixel *)_dst;
++ ptrdiff_t dststride = _dststride / sizeof(pixel);
++
++ int shift = 14 + 1 - BIT_DEPTH;
++ int log2Wd = denom + shift - 1;
++
++ ox0 = ox0 * (1 << (BIT_DEPTH - 8));
++ ox1 = ox1 * (1 << (BIT_DEPTH - 8));
++ for (y = 0; y < height; y++) {
++ for (x = 0; x < width; x++) {
++ dst[x] = av_clip_pixel(( (src[x] << (14 - BIT_DEPTH)) * wx1 + src2[x] * wx0 + (ox0 + ox1 + 1) * (1 << log2Wd)) >> (log2Wd + 1));
++ }
++ src += srcstride;
++ dst += dststride;
++ src2 += MAX_PB_SIZE;
++ }
++}
++
++////////////////////////////////////////////////////////////////////////////////
++//
++////////////////////////////////////////////////////////////////////////////////
++#define QPEL_FILTER(src, stride) \
++ (filter[0] * src[x - 3 * stride] + \
++ filter[1] * src[x - 2 * stride] + \
++ filter[2] * src[x - stride] + \
++ filter[3] * src[x ] + \
++ filter[4] * src[x + stride] + \
++ filter[5] * src[x + 2 * stride] + \
++ filter[6] * src[x + 3 * stride] + \
++ filter[7] * src[x + 4 * stride])
++
++static void FUNC(put_hevc_qpel_h)(int16_t *dst,
++ uint8_t *_src, ptrdiff_t _srcstride,
++ int height, intptr_t mx, intptr_t my, int width)
++{
++ int x, y;
++ pixel *src = (pixel*)_src;
++ ptrdiff_t srcstride = _srcstride / sizeof(pixel);
++ const int8_t *filter = ff_hevc_rpi_qpel_filters[mx - 1];
++ for (y = 0; y < height; y++) {
++ for (x = 0; x < width; x++)
++ dst[x] = QPEL_FILTER(src, 1) >> (BIT_DEPTH - 8);
++ src += srcstride;
++ dst += MAX_PB_SIZE;
++ }
++}
++
++static void FUNC(put_hevc_qpel_v)(int16_t *dst,
++ uint8_t *_src, ptrdiff_t _srcstride,
++ int height, intptr_t mx, intptr_t my, int width)
++{
++ int x, y;
++ pixel *src = (pixel*)_src;
++ ptrdiff_t srcstride = _srcstride / sizeof(pixel);
++ const int8_t *filter = ff_hevc_rpi_qpel_filters[my - 1];
++ for (y = 0; y < height; y++) {
++ for (x = 0; x < width; x++)
++ dst[x] = QPEL_FILTER(src, srcstride) >> (BIT_DEPTH - 8);
++ src += srcstride;
++ dst += MAX_PB_SIZE;
++ }
++}
++
++static void FUNC(put_hevc_qpel_hv)(int16_t *dst,
++ uint8_t *_src,
++ ptrdiff_t _srcstride,
++ int height, intptr_t mx,
++ intptr_t my, int width)
++{
++ int x, y;
++ const int8_t *filter;
++ pixel *src = (pixel*)_src;
++ ptrdiff_t srcstride = _srcstride / sizeof(pixel);
++ int16_t tmp_array[(MAX_PB_SIZE + QPEL_EXTRA) * MAX_PB_SIZE];
++ int16_t *tmp = tmp_array;
++
++ src -= QPEL_EXTRA_BEFORE * srcstride;
++ filter = ff_hevc_rpi_qpel_filters[mx - 1];
++ for (y = 0; y < height + QPEL_EXTRA; y++) {
++ for (x = 0; x < width; x++)
++ tmp[x] = QPEL_FILTER(src, 1) >> (BIT_DEPTH - 8);
++ src += srcstride;
++ tmp += MAX_PB_SIZE;
++ }
++
++ tmp = tmp_array + QPEL_EXTRA_BEFORE * MAX_PB_SIZE;
++ filter = ff_hevc_rpi_qpel_filters[my - 1];
++ for (y = 0; y < height; y++) {
++ for (x = 0; x < width; x++)
++ dst[x] = QPEL_FILTER(tmp, MAX_PB_SIZE) >> 6;
++ tmp += MAX_PB_SIZE;
++ dst += MAX_PB_SIZE;
++ }
++}
++
++static void FUNC(put_hevc_qpel_uni_h)(uint8_t *_dst, ptrdiff_t _dststride,
++ uint8_t *_src, ptrdiff_t _srcstride,
++ int height, intptr_t mx, intptr_t my, int width)
++{
++ int x, y;
++ pixel *src = (pixel*)_src;
++ ptrdiff_t srcstride = _srcstride / sizeof(pixel);
++ pixel *dst = (pixel *)_dst;
++ ptrdiff_t dststride = _dststride / sizeof(pixel);
++ const int8_t *filter = ff_hevc_rpi_qpel_filters[mx - 1];
++ int shift = 14 - BIT_DEPTH;
++
++#if BIT_DEPTH < 14
++ int offset = 1 << (shift - 1);
++#else
++ int offset = 0;
++#endif
++
++ for (y = 0; y < height; y++) {
++ for (x = 0; x < width; x++)
++ dst[x] = av_clip_pixel(((QPEL_FILTER(src, 1) >> (BIT_DEPTH - 8)) + offset) >> shift);
++ src += srcstride;
++ dst += dststride;
++ }
++}
++
++static void FUNC(put_hevc_qpel_bi_h)(uint8_t *_dst, ptrdiff_t _dststride, uint8_t *_src, ptrdiff_t _srcstride,
++ int16_t *src2,
++ int height, intptr_t mx, intptr_t my, int width)
++{
++ int x, y;
++ pixel *src = (pixel*)_src;
++ ptrdiff_t srcstride = _srcstride / sizeof(pixel);
++ pixel *dst = (pixel *)_dst;
++ ptrdiff_t dststride = _dststride / sizeof(pixel);
++
++ const int8_t *filter = ff_hevc_rpi_qpel_filters[mx - 1];
++
++ int shift = 14 + 1 - BIT_DEPTH;
++#if BIT_DEPTH < 14
++ int offset = 1 << (shift - 1);
++#else
++ int offset = 0;
++#endif
++
++ for (y = 0; y < height; y++) {
++ for (x = 0; x < width; x++)
++ dst[x] = av_clip_pixel(((QPEL_FILTER(src, 1) >> (BIT_DEPTH - 8)) + src2[x] + offset) >> shift);
++ src += srcstride;
++ dst += dststride;
++ src2 += MAX_PB_SIZE;
++ }
++}
++
++static void FUNC(put_hevc_qpel_uni_v)(uint8_t *_dst, ptrdiff_t _dststride,
++ uint8_t *_src, ptrdiff_t _srcstride,
++ int height, intptr_t mx, intptr_t my, int width)
++{
++ int x, y;
++ pixel *src = (pixel*)_src;
++ ptrdiff_t srcstride = _srcstride / sizeof(pixel);
++ pixel *dst = (pixel *)_dst;
++ ptrdiff_t dststride = _dststride / sizeof(pixel);
++ const int8_t *filter = ff_hevc_rpi_qpel_filters[my - 1];
++ int shift = 14 - BIT_DEPTH;
++
++#if BIT_DEPTH < 14
++ int offset = 1 << (shift - 1);
++#else
++ int offset = 0;
++#endif
++
++ for (y = 0; y < height; y++) {
++ for (x = 0; x < width; x++)
++ dst[x] = av_clip_pixel(((QPEL_FILTER(src, srcstride) >> (BIT_DEPTH - 8)) + offset) >> shift);
++ src += srcstride;
++ dst += dststride;
++ }
++}
++
++
++static void FUNC(put_hevc_qpel_bi_v)(uint8_t *_dst, ptrdiff_t _dststride, uint8_t *_src, ptrdiff_t _srcstride,
++ int16_t *src2,
++ int height, intptr_t mx, intptr_t my, int width)
++{
++ int x, y;
++ pixel *src = (pixel*)_src;
++ ptrdiff_t srcstride = _srcstride / sizeof(pixel);
++ pixel *dst = (pixel *)_dst;
++ ptrdiff_t dststride = _dststride / sizeof(pixel);
++
++ const int8_t *filter = ff_hevc_rpi_qpel_filters[my - 1];
++
++ int shift = 14 + 1 - BIT_DEPTH;
++#if BIT_DEPTH < 14
++ int offset = 1 << (shift - 1);
++#else
++ int offset = 0;
++#endif
++
++ for (y = 0; y < height; y++) {
++ for (x = 0; x < width; x++)
++ dst[x] = av_clip_pixel(((QPEL_FILTER(src, srcstride) >> (BIT_DEPTH - 8)) + src2[x] + offset) >> shift);
++ src += srcstride;
++ dst += dststride;
++ src2 += MAX_PB_SIZE;
++ }
++}
++
++static void FUNC(put_hevc_qpel_uni_hv)(uint8_t *_dst, ptrdiff_t _dststride,
++ uint8_t *_src, ptrdiff_t _srcstride,
++ int height, intptr_t mx, intptr_t my, int width)
++{
++ int x, y;
++ const int8_t *filter;
++ pixel *src = (pixel*)_src;
++ ptrdiff_t srcstride = _srcstride / sizeof(pixel);
++ pixel *dst = (pixel *)_dst;
++ ptrdiff_t dststride = _dststride / sizeof(pixel);
++ int16_t tmp_array[(MAX_PB_SIZE + QPEL_EXTRA) * MAX_PB_SIZE];
++ int16_t *tmp = tmp_array;
++ int shift = 14 - BIT_DEPTH;
++
++#if BIT_DEPTH < 14
++ int offset = 1 << (shift - 1);
++#else
++ int offset = 0;
++#endif
++
++ src -= QPEL_EXTRA_BEFORE * srcstride;
++ filter = ff_hevc_rpi_qpel_filters[mx - 1];
++ for (y = 0; y < height + QPEL_EXTRA; y++) {
++ for (x = 0; x < width; x++)
++ tmp[x] = QPEL_FILTER(src, 1) >> (BIT_DEPTH - 8);
++ src += srcstride;
++ tmp += MAX_PB_SIZE;
++ }
++
++ tmp = tmp_array + QPEL_EXTRA_BEFORE * MAX_PB_SIZE;
++ filter = ff_hevc_rpi_qpel_filters[my - 1];
++
++ for (y = 0; y < height; y++) {
++ for (x = 0; x < width; x++)
++ dst[x] = av_clip_pixel(((QPEL_FILTER(tmp, MAX_PB_SIZE) >> 6) + offset) >> shift);
++ tmp += MAX_PB_SIZE;
++ dst += dststride;
++ }
++}
++
++static void FUNC(put_hevc_qpel_bi_hv)(uint8_t *_dst, ptrdiff_t _dststride, uint8_t *_src, ptrdiff_t _srcstride,
++ int16_t *src2,
++ int height, intptr_t mx, intptr_t my, int width)
++{
++ int x, y;
++ const int8_t *filter;
++ pixel *src = (pixel*)_src;
++ ptrdiff_t srcstride = _srcstride / sizeof(pixel);
++ pixel *dst = (pixel *)_dst;
++ ptrdiff_t dststride = _dststride / sizeof(pixel);
++ int16_t tmp_array[(MAX_PB_SIZE + QPEL_EXTRA) * MAX_PB_SIZE];
++ int16_t *tmp = tmp_array;
++ int shift = 14 + 1 - BIT_DEPTH;
++#if BIT_DEPTH < 14
++ int offset = 1 << (shift - 1);
++#else
++ int offset = 0;
++#endif
++
++ src -= QPEL_EXTRA_BEFORE * srcstride;
++ filter = ff_hevc_rpi_qpel_filters[mx - 1];
++ for (y = 0; y < height + QPEL_EXTRA; y++) {
++ for (x = 0; x < width; x++)
++ tmp[x] = QPEL_FILTER(src, 1) >> (BIT_DEPTH - 8);
++ src += srcstride;
++ tmp += MAX_PB_SIZE;
++ }
++
++ tmp = tmp_array + QPEL_EXTRA_BEFORE * MAX_PB_SIZE;
++ filter = ff_hevc_rpi_qpel_filters[my - 1];
++
++ for (y = 0; y < height; y++) {
++ for (x = 0; x < width; x++)
++ dst[x] = av_clip_pixel(((QPEL_FILTER(tmp, MAX_PB_SIZE) >> 6) + src2[x] + offset) >> shift);
++ tmp += MAX_PB_SIZE;
++ dst += dststride;
++ src2 += MAX_PB_SIZE;
++ }
++}
++
++static void FUNC(put_hevc_qpel_uni_w_h)(uint8_t *_dst, ptrdiff_t _dststride,
++ uint8_t *_src, ptrdiff_t _srcstride,
++ int height, int denom, int wx, int ox,
++ intptr_t mx, intptr_t my, int width)
++{
++ int x, y;
++ pixel *src = (pixel*)_src;
++ ptrdiff_t srcstride = _srcstride / sizeof(pixel);
++ pixel *dst = (pixel *)_dst;
++ ptrdiff_t dststride = _dststride / sizeof(pixel);
++ const int8_t *filter = ff_hevc_rpi_qpel_filters[mx - 1];
++ int shift = denom + 14 - BIT_DEPTH;
++#if BIT_DEPTH < 14
++ int offset = 1 << (shift - 1);
++#else
++ int offset = 0;
++#endif
++
++ ox = ox * (1 << (BIT_DEPTH - 8));
++ for (y = 0; y < height; y++) {
++ for (x = 0; x < width; x++)
++ dst[x] = av_clip_pixel((((QPEL_FILTER(src, 1) >> (BIT_DEPTH - 8)) * wx + offset) >> shift) + ox);
++ src += srcstride;
++ dst += dststride;
++ }
++}
++
++static void FUNC(put_hevc_qpel_bi_w_h)(uint8_t *_dst, ptrdiff_t _dststride, uint8_t *_src, ptrdiff_t _srcstride,
++ int16_t *src2,
++ int height, int denom, int wx0, int wx1,
++ int ox0, int ox1, intptr_t mx, intptr_t my, int width)
++{
++ int x, y;
++ pixel *src = (pixel*)_src;
++ ptrdiff_t srcstride = _srcstride / sizeof(pixel);
++ pixel *dst = (pixel *)_dst;
++ ptrdiff_t dststride = _dststride / sizeof(pixel);
++
++ const int8_t *filter = ff_hevc_rpi_qpel_filters[mx - 1];
++
++ int shift = 14 + 1 - BIT_DEPTH;
++ int log2Wd = denom + shift - 1;
++
++ ox0 = ox0 * (1 << (BIT_DEPTH - 8));
++ ox1 = ox1 * (1 << (BIT_DEPTH - 8));
++ for (y = 0; y < height; y++) {
++ for (x = 0; x < width; x++)
++ dst[x] = av_clip_pixel(((QPEL_FILTER(src, 1) >> (BIT_DEPTH - 8)) * wx1 + src2[x] * wx0 +
++ ((ox0 + ox1 + 1) << log2Wd)) >> (log2Wd + 1));
++ src += srcstride;
++ dst += dststride;
++ src2 += MAX_PB_SIZE;
++ }
++}
++
++static void FUNC(put_hevc_qpel_uni_w_v)(uint8_t *_dst, ptrdiff_t _dststride,
++ uint8_t *_src, ptrdiff_t _srcstride,
++ int height, int denom, int wx, int ox,
++ intptr_t mx, intptr_t my, int width)
++{
++ int x, y;
++ pixel *src = (pixel*)_src;
++ ptrdiff_t srcstride = _srcstride / sizeof(pixel);
++ pixel *dst = (pixel *)_dst;
++ ptrdiff_t dststride = _dststride / sizeof(pixel);
++ const int8_t *filter = ff_hevc_rpi_qpel_filters[my - 1];
++ int shift = denom + 14 - BIT_DEPTH;
++#if BIT_DEPTH < 14
++ int offset = 1 << (shift - 1);
++#else
++ int offset = 0;
++#endif
++
++ ox = ox * (1 << (BIT_DEPTH - 8));
++ for (y = 0; y < height; y++) {
++ for (x = 0; x < width; x++)
++ dst[x] = av_clip_pixel((((QPEL_FILTER(src, srcstride) >> (BIT_DEPTH - 8)) * wx + offset) >> shift) + ox);
++ src += srcstride;
++ dst += dststride;
++ }
++}
++
++static void FUNC(put_hevc_qpel_bi_w_v)(uint8_t *_dst, ptrdiff_t _dststride, uint8_t *_src, ptrdiff_t _srcstride,
++ int16_t *src2,
++ int height, int denom, int wx0, int wx1,
++ int ox0, int ox1, intptr_t mx, intptr_t my, int width)
++{
++ int x, y;
++ pixel *src = (pixel*)_src;
++ ptrdiff_t srcstride = _srcstride / sizeof(pixel);
++ pixel *dst = (pixel *)_dst;
++ ptrdiff_t dststride = _dststride / sizeof(pixel);
++
++ const int8_t *filter = ff_hevc_rpi_qpel_filters[my - 1];
++
++ int shift = 14 + 1 - BIT_DEPTH;
++ int log2Wd = denom + shift - 1;
++
++ ox0 = ox0 * (1 << (BIT_DEPTH - 8));
++ ox1 = ox1 * (1 << (BIT_DEPTH - 8));
++ for (y = 0; y < height; y++) {
++ for (x = 0; x < width; x++)
++ dst[x] = av_clip_pixel(((QPEL_FILTER(src, srcstride) >> (BIT_DEPTH - 8)) * wx1 + src2[x] * wx0 +
++ ((ox0 + ox1 + 1) << log2Wd)) >> (log2Wd + 1));
++ src += srcstride;
++ dst += dststride;
++ src2 += MAX_PB_SIZE;
++ }
++}
++
++static void FUNC(put_hevc_qpel_uni_w_hv)(uint8_t *_dst, ptrdiff_t _dststride,
++ uint8_t *_src, ptrdiff_t _srcstride,
++ int height, int denom, int wx, int ox,
++ intptr_t mx, intptr_t my, int width)
++{
++ int x, y;
++ const int8_t *filter;
++ pixel *src = (pixel*)_src;
++ ptrdiff_t srcstride = _srcstride / sizeof(pixel);
++ pixel *dst = (pixel *)_dst;
++ ptrdiff_t dststride = _dststride / sizeof(pixel);
++ int16_t tmp_array[(MAX_PB_SIZE + QPEL_EXTRA) * MAX_PB_SIZE];
++ int16_t *tmp = tmp_array;
++ int shift = denom + 14 - BIT_DEPTH;
++#if BIT_DEPTH < 14
++ int offset = 1 << (shift - 1);
++#else
++ int offset = 0;
++#endif
++
++ src -= QPEL_EXTRA_BEFORE * srcstride;
++ filter = ff_hevc_rpi_qpel_filters[mx - 1];
++ for (y = 0; y < height + QPEL_EXTRA; y++) {
++ for (x = 0; x < width; x++)
++ tmp[x] = QPEL_FILTER(src, 1) >> (BIT_DEPTH - 8);
++ src += srcstride;
++ tmp += MAX_PB_SIZE;
++ }
++
++ tmp = tmp_array + QPEL_EXTRA_BEFORE * MAX_PB_SIZE;
++ filter = ff_hevc_rpi_qpel_filters[my - 1];
++
++ ox = ox * (1 << (BIT_DEPTH - 8));
++ for (y = 0; y < height; y++) {
++ for (x = 0; x < width; x++)
++ dst[x] = av_clip_pixel((((QPEL_FILTER(tmp, MAX_PB_SIZE) >> 6) * wx + offset) >> shift) + ox);
++ tmp += MAX_PB_SIZE;
++ dst += dststride;
++ }
++}
++
++static void FUNC(put_hevc_qpel_bi_w_hv)(uint8_t *_dst, ptrdiff_t _dststride, uint8_t *_src, ptrdiff_t _srcstride,
++ int16_t *src2,
++ int height, int denom, int wx0, int wx1,
++ int ox0, int ox1, intptr_t mx, intptr_t my, int width)
++{
++ int x, y;
++ const int8_t *filter;
++ pixel *src = (pixel*)_src;
++ ptrdiff_t srcstride = _srcstride / sizeof(pixel);
++ pixel *dst = (pixel *)_dst;
++ ptrdiff_t dststride = _dststride / sizeof(pixel);
++ int16_t tmp_array[(MAX_PB_SIZE + QPEL_EXTRA) * MAX_PB_SIZE];
++ int16_t *tmp = tmp_array;
++ int shift = 14 + 1 - BIT_DEPTH;
++ int log2Wd = denom + shift - 1;
++
++ src -= QPEL_EXTRA_BEFORE * srcstride;
++ filter = ff_hevc_rpi_qpel_filters[mx - 1];
++ for (y = 0; y < height + QPEL_EXTRA; y++) {
++ for (x = 0; x < width; x++)
++ tmp[x] = QPEL_FILTER(src, 1) >> (BIT_DEPTH - 8);
++ src += srcstride;
++ tmp += MAX_PB_SIZE;
++ }
++
++ tmp = tmp_array + QPEL_EXTRA_BEFORE * MAX_PB_SIZE;
++ filter = ff_hevc_rpi_qpel_filters[my - 1];
++
++ ox0 = ox0 * (1 << (BIT_DEPTH - 8));
++ ox1 = ox1 * (1 << (BIT_DEPTH - 8));
++ for (y = 0; y < height; y++) {
++ for (x = 0; x < width; x++)
++ dst[x] = av_clip_pixel(((QPEL_FILTER(tmp, MAX_PB_SIZE) >> 6) * wx1 + src2[x] * wx0 +
++ ((ox0 + ox1 + 1) << log2Wd)) >> (log2Wd + 1));
++ tmp += MAX_PB_SIZE;
++ dst += dststride;
++ src2 += MAX_PB_SIZE;
++ }
++}
++
++////////////////////////////////////////////////////////////////////////////////
++//
++////////////////////////////////////////////////////////////////////////////////
++#define EPEL_FILTER(src, stride) \
++ (filter[0] * src[x - stride] + \
++ filter[1] * src[x] + \
++ filter[2] * src[x + stride] + \
++ filter[3] * src[x + 2 * stride])
++
++static void FUNC(put_hevc_epel_h)(int16_t *dst,
++ uint8_t *_src, ptrdiff_t _srcstride,
++ int height, intptr_t mx, intptr_t my, int width)
++{
++ int x, y;
++ pixel *src = (pixel *)_src;
++ ptrdiff_t srcstride = _srcstride / sizeof(pixel);
++ const int8_t *filter = ff_hevc_rpi_epel_filters[mx - 1];
++ for (y = 0; y < height; y++) {
++ for (x = 0; x < width; x++)
++ dst[x] = EPEL_FILTER(src, 1) >> (BIT_DEPTH - 8);
++ src += srcstride;
++ dst += MAX_PB_SIZE;
++ }
++}
++
++static void FUNC(put_hevc_epel_v)(int16_t *dst,
++ uint8_t *_src, ptrdiff_t _srcstride,
++ int height, intptr_t mx, intptr_t my, int width)
++{
++ int x, y;
++ pixel *src = (pixel *)_src;
++ ptrdiff_t srcstride = _srcstride / sizeof(pixel);
++ const int8_t *filter = ff_hevc_rpi_epel_filters[my - 1];
++
++ for (y = 0; y < height; y++) {
++ for (x = 0; x < width; x++)
++ dst[x] = EPEL_FILTER(src, srcstride) >> (BIT_DEPTH - 8);
++ src += srcstride;
++ dst += MAX_PB_SIZE;
++ }
++}
++
++static void FUNC(put_hevc_epel_hv)(int16_t *dst,
++ uint8_t *_src, ptrdiff_t _srcstride,
++ int height, intptr_t mx, intptr_t my, int width)
++{
++ int x, y;
++ pixel *src = (pixel *)_src;
++ ptrdiff_t srcstride = _srcstride / sizeof(pixel);
++ const int8_t *filter = ff_hevc_rpi_epel_filters[mx - 1];
++ int16_t tmp_array[(MAX_PB_SIZE + EPEL_EXTRA) * MAX_PB_SIZE];
++ int16_t *tmp = tmp_array;
++
++ src -= EPEL_EXTRA_BEFORE * srcstride;
++
++ for (y = 0; y < height + EPEL_EXTRA; y++) {
++ for (x = 0; x < width; x++)
++ tmp[x] = EPEL_FILTER(src, 1) >> (BIT_DEPTH - 8);
++ src += srcstride;
++ tmp += MAX_PB_SIZE;
++ }
++
++ tmp = tmp_array + EPEL_EXTRA_BEFORE * MAX_PB_SIZE;
++ filter = ff_hevc_rpi_epel_filters[my - 1];
++
++ for (y = 0; y < height; y++) {
++ for (x = 0; x < width; x++)
++ dst[x] = EPEL_FILTER(tmp, MAX_PB_SIZE) >> 6;
++ tmp += MAX_PB_SIZE;
++ dst += MAX_PB_SIZE;
++ }
++}
++
++static void FUNC(put_hevc_epel_uni_h)(uint8_t *_dst, ptrdiff_t _dststride, uint8_t *_src, ptrdiff_t _srcstride,
++ int height, intptr_t mx, intptr_t my, int width)
++{
++ int x, y;
++ pixel *src = (pixel *)_src;
++ ptrdiff_t srcstride = _srcstride / sizeof(pixel);
++ pixel *dst = (pixel *)_dst;
++ ptrdiff_t dststride = _dststride / sizeof(pixel);
++ const int8_t *filter = ff_hevc_rpi_epel_filters[mx - 1];
++ int shift = 14 - BIT_DEPTH;
++#if BIT_DEPTH < 14
++ int offset = 1 << (shift - 1);
++#else
++ int offset = 0;
++#endif
++
++ for (y = 0; y < height; y++) {
++ for (x = 0; x < width; x++)
++ dst[x] = av_clip_pixel(((EPEL_FILTER(src, 1) >> (BIT_DEPTH - 8)) + offset) >> shift);
++ src += srcstride;
++ dst += dststride;
++ }
++}
++
++static void FUNC(put_hevc_epel_bi_h)(uint8_t *_dst, ptrdiff_t _dststride, uint8_t *_src, ptrdiff_t _srcstride,
++ int16_t *src2,
++ int height, intptr_t mx, intptr_t my, int width)
++{
++ int x, y;
++ pixel *src = (pixel *)_src;
++ ptrdiff_t srcstride = _srcstride / sizeof(pixel);
++ pixel *dst = (pixel *)_dst;
++ ptrdiff_t dststride = _dststride / sizeof(pixel);
++ const int8_t *filter = ff_hevc_rpi_epel_filters[mx - 1];
++ int shift = 14 + 1 - BIT_DEPTH;
++#if BIT_DEPTH < 14
++ int offset = 1 << (shift - 1);
++#else
++ int offset = 0;
++#endif
++
++ for (y = 0; y < height; y++) {
++ for (x = 0; x < width; x++) {
++ dst[x] = av_clip_pixel(((EPEL_FILTER(src, 1) >> (BIT_DEPTH - 8)) + src2[x] + offset) >> shift);
++ }
++ dst += dststride;
++ src += srcstride;
++ src2 += MAX_PB_SIZE;
++ }
++}
++
++static void FUNC(put_hevc_epel_uni_v)(uint8_t *_dst, ptrdiff_t _dststride, uint8_t *_src, ptrdiff_t _srcstride,
++ int height, intptr_t mx, intptr_t my, int width)
++{
++ int x, y;
++ pixel *src = (pixel *)_src;
++ ptrdiff_t srcstride = _srcstride / sizeof(pixel);
++ pixel *dst = (pixel *)_dst;
++ ptrdiff_t dststride = _dststride / sizeof(pixel);
++ const int8_t *filter = ff_hevc_rpi_epel_filters[my - 1];
++ int shift = 14 - BIT_DEPTH;
++#if BIT_DEPTH < 14
++ int offset = 1 << (shift - 1);
++#else
++ int offset = 0;
++#endif
++
++ for (y = 0; y < height; y++) {
++ for (x = 0; x < width; x++)
++ dst[x] = av_clip_pixel(((EPEL_FILTER(src, srcstride) >> (BIT_DEPTH - 8)) + offset) >> shift);
++ src += srcstride;
++ dst += dststride;
++ }
++}
++
++static void FUNC(put_hevc_epel_bi_v)(uint8_t *_dst, ptrdiff_t _dststride, uint8_t *_src, ptrdiff_t _srcstride,
++ int16_t *src2,
++ int height, intptr_t mx, intptr_t my, int width)
++{
++ int x, y;
++ pixel *src = (pixel *)_src;
++ ptrdiff_t srcstride = _srcstride / sizeof(pixel);
++ const int8_t *filter = ff_hevc_rpi_epel_filters[my - 1];
++ pixel *dst = (pixel *)_dst;
++ ptrdiff_t dststride = _dststride / sizeof(pixel);
++ int shift = 14 + 1 - BIT_DEPTH;
++#if BIT_DEPTH < 14
++ int offset = 1 << (shift - 1);
++#else
++ int offset = 0;
++#endif
++
++ for (y = 0; y < height; y++) {
++ for (x = 0; x < width; x++)
++ dst[x] = av_clip_pixel(((EPEL_FILTER(src, srcstride) >> (BIT_DEPTH - 8)) + src2[x] + offset) >> shift);
++ dst += dststride;
++ src += srcstride;
++ src2 += MAX_PB_SIZE;
++ }
++}
++
++static void FUNC(put_hevc_epel_uni_hv)(uint8_t *_dst, ptrdiff_t _dststride, uint8_t *_src, ptrdiff_t _srcstride,
++ int height, intptr_t mx, intptr_t my, int width)
++{
++ int x, y;
++ pixel *src = (pixel *)_src;
++ ptrdiff_t srcstride = _srcstride / sizeof(pixel);
++ pixel *dst = (pixel *)_dst;
++ ptrdiff_t dststride = _dststride / sizeof(pixel);
++ const int8_t *filter = ff_hevc_rpi_epel_filters[mx - 1];
++ int16_t tmp_array[(MAX_PB_SIZE + EPEL_EXTRA) * MAX_PB_SIZE];
++ int16_t *tmp = tmp_array;
++ int shift = 14 - BIT_DEPTH;
++#if BIT_DEPTH < 14
++ int offset = 1 << (shift - 1);
++#else
++ int offset = 0;
++#endif
++
++ src -= EPEL_EXTRA_BEFORE * srcstride;
++
++ for (y = 0; y < height + EPEL_EXTRA; y++) {
++ for (x = 0; x < width; x++)
++ tmp[x] = EPEL_FILTER(src, 1) >> (BIT_DEPTH - 8);
++ src += srcstride;
++ tmp += MAX_PB_SIZE;
++ }
++
++ tmp = tmp_array + EPEL_EXTRA_BEFORE * MAX_PB_SIZE;
++ filter = ff_hevc_rpi_epel_filters[my - 1];
++
++ for (y = 0; y < height; y++) {
++ for (x = 0; x < width; x++)
++ dst[x] = av_clip_pixel(((EPEL_FILTER(tmp, MAX_PB_SIZE) >> 6) + offset) >> shift);
++ tmp += MAX_PB_SIZE;
++ dst += dststride;
++ }
++}
++
++static void FUNC(put_hevc_epel_bi_hv)(uint8_t *_dst, ptrdiff_t _dststride, uint8_t *_src, ptrdiff_t _srcstride,
++ int16_t *src2,
++ int height, intptr_t mx, intptr_t my, int width)
++{
++ int x, y;
++ pixel *src = (pixel *)_src;
++ ptrdiff_t srcstride = _srcstride / sizeof(pixel);
++ pixel *dst = (pixel *)_dst;
++ ptrdiff_t dststride = _dststride / sizeof(pixel);
++ const int8_t *filter = ff_hevc_rpi_epel_filters[mx - 1];
++ int16_t tmp_array[(MAX_PB_SIZE + EPEL_EXTRA) * MAX_PB_SIZE];
++ int16_t *tmp = tmp_array;
++ int shift = 14 + 1 - BIT_DEPTH;
++#if BIT_DEPTH < 14
++ int offset = 1 << (shift - 1);
++#else
++ int offset = 0;
++#endif
++
++ src -= EPEL_EXTRA_BEFORE * srcstride;
++
++ for (y = 0; y < height + EPEL_EXTRA; y++) {
++ for (x = 0; x < width; x++)
++ tmp[x] = EPEL_FILTER(src, 1) >> (BIT_DEPTH - 8);
++ src += srcstride;
++ tmp += MAX_PB_SIZE;
++ }
++
++ tmp = tmp_array + EPEL_EXTRA_BEFORE * MAX_PB_SIZE;
++ filter = ff_hevc_rpi_epel_filters[my - 1];
++
++ for (y = 0; y < height; y++) {
++ for (x = 0; x < width; x++)
++ dst[x] = av_clip_pixel(((EPEL_FILTER(tmp, MAX_PB_SIZE) >> 6) + src2[x] + offset) >> shift);
++ tmp += MAX_PB_SIZE;
++ dst += dststride;
++ src2 += MAX_PB_SIZE;
++ }
++}
++
++static void FUNC(put_hevc_epel_uni_w_h)(uint8_t *_dst, ptrdiff_t _dststride, uint8_t *_src, ptrdiff_t _srcstride,
++ int height, int denom, int wx, int ox, intptr_t mx, intptr_t my, int width)
++{
++ int x, y;
++ pixel *src = (pixel *)_src;
++ ptrdiff_t srcstride = _srcstride / sizeof(pixel);
++ pixel *dst = (pixel *)_dst;
++ ptrdiff_t dststride = _dststride / sizeof(pixel);
++ const int8_t *filter = ff_hevc_rpi_epel_filters[mx - 1];
++ int shift = denom + 14 - BIT_DEPTH;
++#if BIT_DEPTH < 14
++ int offset = 1 << (shift - 1);
++#else
++ int offset = 0;
++#endif
++
++ ox = ox * (1 << (BIT_DEPTH - 8));
++ for (y = 0; y < height; y++) {
++ for (x = 0; x < width; x++) {
++ dst[x] = av_clip_pixel((((EPEL_FILTER(src, 1) >> (BIT_DEPTH - 8)) * wx + offset) >> shift) + ox);
++ }
++ dst += dststride;
++ src += srcstride;
++ }
++}
++
++static void FUNC(put_hevc_epel_bi_w_h)(uint8_t *_dst, ptrdiff_t _dststride, uint8_t *_src, ptrdiff_t _srcstride,
++ int16_t *src2,
++ int height, int denom, int wx0, int wx1,
++ int ox0, int ox1, intptr_t mx, intptr_t my, int width)
++{
++ int x, y;
++ pixel *src = (pixel *)_src;
++ ptrdiff_t srcstride = _srcstride / sizeof(pixel);
++ pixel *dst = (pixel *)_dst;
++ ptrdiff_t dststride = _dststride / sizeof(pixel);
++ const int8_t *filter = ff_hevc_rpi_epel_filters[mx - 1];
++ int shift = 14 + 1 - BIT_DEPTH;
++ int log2Wd = denom + shift - 1;
++
++ ox0 = ox0 * (1 << (BIT_DEPTH - 8));
++ ox1 = ox1 * (1 << (BIT_DEPTH - 8));
++ for (y = 0; y < height; y++) {
++ for (x = 0; x < width; x++)
++ dst[x] = av_clip_pixel(((EPEL_FILTER(src, 1) >> (BIT_DEPTH - 8)) * wx1 + src2[x] * wx0 +
++ ((ox0 + ox1 + 1) << log2Wd)) >> (log2Wd + 1));
++ src += srcstride;
++ dst += dststride;
++ src2 += MAX_PB_SIZE;
++ }
++}
++
++static void FUNC(put_hevc_epel_uni_w_v)(uint8_t *_dst, ptrdiff_t _dststride, uint8_t *_src, ptrdiff_t _srcstride,
++ int height, int denom, int wx, int ox, intptr_t mx, intptr_t my, int width)
++{
++ int x, y;
++ pixel *src = (pixel *)_src;
++ ptrdiff_t srcstride = _srcstride / sizeof(pixel);
++ pixel *dst = (pixel *)_dst;
++ ptrdiff_t dststride = _dststride / sizeof(pixel);
++ const int8_t *filter = ff_hevc_rpi_epel_filters[my - 1];
++ int shift = denom + 14 - BIT_DEPTH;
++#if BIT_DEPTH < 14
++ int offset = 1 << (shift - 1);
++#else
++ int offset = 0;
++#endif
++
++ ox = ox * (1 << (BIT_DEPTH - 8));
++ for (y = 0; y < height; y++) {
++ for (x = 0; x < width; x++) {
++ dst[x] = av_clip_pixel((((EPEL_FILTER(src, srcstride) >> (BIT_DEPTH - 8)) * wx + offset) >> shift) + ox);
++ }
++ dst += dststride;
++ src += srcstride;
++ }
++}
++
++static void FUNC(put_hevc_epel_bi_w_v)(uint8_t *_dst, ptrdiff_t _dststride, uint8_t *_src, ptrdiff_t _srcstride,
++ int16_t *src2,
++ int height, int denom, int wx0, int wx1,
++ int ox0, int ox1, intptr_t mx, intptr_t my, int width)
++{
++ int x, y;
++ pixel *src = (pixel *)_src;
++ ptrdiff_t srcstride = _srcstride / sizeof(pixel);
++ const int8_t *filter = ff_hevc_rpi_epel_filters[my - 1];
++ pixel *dst = (pixel *)_dst;
++ ptrdiff_t dststride = _dststride / sizeof(pixel);
++ int shift = 14 + 1 - BIT_DEPTH;
++ int log2Wd = denom + shift - 1;
++
++ ox0 = ox0 * (1 << (BIT_DEPTH - 8));
++ ox1 = ox1 * (1 << (BIT_DEPTH - 8));
++ for (y = 0; y < height; y++) {
++ for (x = 0; x < width; x++)
++ dst[x] = av_clip_pixel(((EPEL_FILTER(src, srcstride) >> (BIT_DEPTH - 8)) * wx1 + src2[x] * wx0 +
++ ((ox0 + ox1 + 1) << log2Wd)) >> (log2Wd + 1));
++ src += srcstride;
++ dst += dststride;
++ src2 += MAX_PB_SIZE;
++ }
++}
++
++static void FUNC(put_hevc_epel_uni_w_hv)(uint8_t *_dst, ptrdiff_t _dststride, uint8_t *_src, ptrdiff_t _srcstride,
++ int height, int denom, int wx, int ox, intptr_t mx, intptr_t my, int width)
++{
++ int x, y;
++ pixel *src = (pixel *)_src;
++ ptrdiff_t srcstride = _srcstride / sizeof(pixel);
++ pixel *dst = (pixel *)_dst;
++ ptrdiff_t dststride = _dststride / sizeof(pixel);
++ const int8_t *filter = ff_hevc_rpi_epel_filters[mx - 1];
++ int16_t tmp_array[(MAX_PB_SIZE + EPEL_EXTRA) * MAX_PB_SIZE];
++ int16_t *tmp = tmp_array;
++ int shift = denom + 14 - BIT_DEPTH;
++#if BIT_DEPTH < 14
++ int offset = 1 << (shift - 1);
++#else
++ int offset = 0;
++#endif
++
++ src -= EPEL_EXTRA_BEFORE * srcstride;
++
++ for (y = 0; y < height + EPEL_EXTRA; y++) {
++ for (x = 0; x < width; x++)
++ tmp[x] = EPEL_FILTER(src, 1) >> (BIT_DEPTH - 8);
++ src += srcstride;
++ tmp += MAX_PB_SIZE;
++ }
++
++ tmp = tmp_array + EPEL_EXTRA_BEFORE * MAX_PB_SIZE;
++ filter = ff_hevc_rpi_epel_filters[my - 1];
++
++ ox = ox * (1 << (BIT_DEPTH - 8));
++ for (y = 0; y < height; y++) {
++ for (x = 0; x < width; x++)
++ dst[x] = av_clip_pixel((((EPEL_FILTER(tmp, MAX_PB_SIZE) >> 6) * wx + offset) >> shift) + ox);
++ tmp += MAX_PB_SIZE;
++ dst += dststride;
++ }
++}
++
++static void FUNC(put_hevc_epel_bi_w_hv)(uint8_t *_dst, ptrdiff_t _dststride, uint8_t *_src, ptrdiff_t _srcstride,
++ int16_t *src2,
++ int height, int denom, int wx0, int wx1,
++ int ox0, int ox1, intptr_t mx, intptr_t my, int width)
++{
++ int x, y;
++ pixel *src = (pixel *)_src;
++ ptrdiff_t srcstride = _srcstride / sizeof(pixel);
++ pixel *dst = (pixel *)_dst;
++ ptrdiff_t dststride = _dststride / sizeof(pixel);
++ const int8_t *filter = ff_hevc_rpi_epel_filters[mx - 1];
++ int16_t tmp_array[(MAX_PB_SIZE + EPEL_EXTRA) * MAX_PB_SIZE];
++ int16_t *tmp = tmp_array;
++ int shift = 14 + 1 - BIT_DEPTH;
++ int log2Wd = denom + shift - 1;
++
++ src -= EPEL_EXTRA_BEFORE * srcstride;
++
++ for (y = 0; y < height + EPEL_EXTRA; y++) {
++ for (x = 0; x < width; x++)
++ tmp[x] = EPEL_FILTER(src, 1) >> (BIT_DEPTH - 8);
++ src += srcstride;
++ tmp += MAX_PB_SIZE;
++ }
++
++ tmp = tmp_array + EPEL_EXTRA_BEFORE * MAX_PB_SIZE;
++ filter = ff_hevc_rpi_epel_filters[my - 1];
++
++ ox0 = ox0 * (1 << (BIT_DEPTH - 8));
++ ox1 = ox1 * (1 << (BIT_DEPTH - 8));
++ for (y = 0; y < height; y++) {
++ for (x = 0; x < width; x++)
++ dst[x] = av_clip_pixel(((EPEL_FILTER(tmp, MAX_PB_SIZE) >> 6) * wx1 + src2[x] * wx0 +
++ ((ox0 + ox1 + 1) * (1 << log2Wd))) >> (log2Wd + 1));
++ tmp += MAX_PB_SIZE;
++ dst += dststride;
++ src2 += MAX_PB_SIZE;
++ }
++}
++
++// line zero
++#define P3 pix[-4 * xstride]
++#define P2 pix[-3 * xstride]
++#define P1 pix[-2 * xstride]
++#define P0 pix[-1 * xstride]
++#define Q0 pix[0 * xstride]
++#define Q1 pix[1 * xstride]
++#define Q2 pix[2 * xstride]
++#define Q3 pix[3 * xstride]
++
++// line three. used only for deblocking decision
++#define TP3 pix[-4 * xstride + 3 * ystride]
++#define TP2 pix[-3 * xstride + 3 * ystride]
++#define TP1 pix[-2 * xstride + 3 * ystride]
++#define TP0 pix[-1 * xstride + 3 * ystride]
++#define TQ0 pix[0 * xstride + 3 * ystride]
++#define TQ1 pix[1 * xstride + 3 * ystride]
++#define TQ2 pix[2 * xstride + 3 * ystride]
++#define TQ3 pix[3 * xstride + 3 * ystride]
++
++static void FUNC(hevc_loop_filter_luma)(uint8_t *_pix,
++ ptrdiff_t _xstride, ptrdiff_t _ystride,
++ int beta, int *_tc,
++ uint8_t *_no_p, uint8_t *_no_q)
++{
++ int d, j;
++ pixel *pix = (pixel *)_pix;
++ ptrdiff_t xstride = _xstride / sizeof(pixel);
++ ptrdiff_t ystride = _ystride / sizeof(pixel);
++
++ beta <<= BIT_DEPTH - 8;
++
++ for (j = 0; j < 2; j++) {
++ const int dp0 = abs(P2 - 2 * P1 + P0);
++ const int dq0 = abs(Q2 - 2 * Q1 + Q0);
++ const int dp3 = abs(TP2 - 2 * TP1 + TP0);
++ const int dq3 = abs(TQ2 - 2 * TQ1 + TQ0);
++ const int d0 = dp0 + dq0;
++ const int d3 = dp3 + dq3;
++ const int tc = _tc[j] << (BIT_DEPTH - 8);
++ const int no_p = _no_p[j];
++ const int no_q = _no_q[j];
++
++ if (d0 + d3 >= beta) {
++ pix += 4 * ystride;
++ continue;
++ } else {
++ const int beta_3 = beta >> 3;
++ const int beta_2 = beta >> 2;
++ const int tc25 = ((tc * 5 + 1) >> 1);
++
++ if (abs(P3 - P0) + abs(Q3 - Q0) < beta_3 && abs(P0 - Q0) < tc25 &&
++ abs(TP3 - TP0) + abs(TQ3 - TQ0) < beta_3 && abs(TP0 - TQ0) < tc25 &&
++ (d0 << 1) < beta_2 && (d3 << 1) < beta_2) {
++ // strong filtering
++ const int tc2 = tc << 1;
++ for (d = 0; d < 4; d++) {
++ const int p3 = P3;
++ const int p2 = P2;
++ const int p1 = P1;
++ const int p0 = P0;
++ const int q0 = Q0;
++ const int q1 = Q1;
++ const int q2 = Q2;
++ const int q3 = Q3;
++ if (!no_p) {
++ P0 = p0 + av_clip(((p2 + 2 * p1 + 2 * p0 + 2 * q0 + q1 + 4) >> 3) - p0, -tc2, tc2);
++ P1 = p1 + av_clip(((p2 + p1 + p0 + q0 + 2) >> 2) - p1, -tc2, tc2);
++ P2 = p2 + av_clip(((2 * p3 + 3 * p2 + p1 + p0 + q0 + 4) >> 3) - p2, -tc2, tc2);
++ }
++ if (!no_q) {
++ Q0 = q0 + av_clip(((p1 + 2 * p0 + 2 * q0 + 2 * q1 + q2 + 4) >> 3) - q0, -tc2, tc2);
++ Q1 = q1 + av_clip(((p0 + q0 + q1 + q2 + 2) >> 2) - q1, -tc2, tc2);
++ Q2 = q2 + av_clip(((2 * q3 + 3 * q2 + q1 + q0 + p0 + 4) >> 3) - q2, -tc2, tc2);
++ }
++ pix += ystride;
++ }
++ } else { // normal filtering
++ int nd_p = 1;
++ int nd_q = 1;
++ const int tc_2 = tc >> 1;
++ if (dp0 + dp3 < ((beta + (beta >> 1)) >> 3))
++ nd_p = 2;
++ if (dq0 + dq3 < ((beta + (beta >> 1)) >> 3))
++ nd_q = 2;
++
++ for (d = 0; d < 4; d++) {
++ const int p2 = P2;
++ const int p1 = P1;
++ const int p0 = P0;
++ const int q0 = Q0;
++ const int q1 = Q1;
++ const int q2 = Q2;
++ int delta0 = (9 * (q0 - p0) - 3 * (q1 - p1) + 8) >> 4;
++ if (abs(delta0) < 10 * tc) {
++ delta0 = av_clip(delta0, -tc, tc);
++ if (!no_p)
++ P0 = av_clip_pixel(p0 + delta0);
++ if (!no_q)
++ Q0 = av_clip_pixel(q0 - delta0);
++ if (!no_p && nd_p > 1) {
++ const int deltap1 = av_clip((((p2 + p0 + 1) >> 1) - p1 + delta0) >> 1, -tc_2, tc_2);
++ P1 = av_clip_pixel(p1 + deltap1);
++ }
++ if (!no_q && nd_q > 1) {
++ const int deltaq1 = av_clip((((q2 + q0 + 1) >> 1) - q1 - delta0) >> 1, -tc_2, tc_2);
++ Q1 = av_clip_pixel(q1 + deltaq1);
++ }
++ }
++ pix += ystride;
++ }
++ }
++ }
++ }
++}
++
++static void FUNC(hevc_loop_filter_chroma)(uint8_t *_pix, ptrdiff_t _xstride,
++ ptrdiff_t _ystride, int *_tc,
++ uint8_t *_no_p, uint8_t *_no_q)
++{
++ int d, j, no_p, no_q;
++ pixel *pix = (pixel *)_pix;
++ ptrdiff_t xstride = _xstride / sizeof(pixel);
++ ptrdiff_t ystride = _ystride / sizeof(pixel);
++
++ for (j = 0; j < 2; j++) {
++ const int tc = _tc[j] << (BIT_DEPTH - 8);
++ if (tc <= 0) {
++ pix += 4 * ystride;
++ continue;
++ }
++ no_p = _no_p[j];
++ no_q = _no_q[j];
++
++ for (d = 0; d < 4; d++) {
++ int delta0;
++ const int p1 = P1;
++ const int p0 = P0;
++ const int q0 = Q0;
++ const int q1 = Q1;
++ delta0 = av_clip((((q0 - p0) * 4) + p1 - q1 + 4) >> 3, -tc, tc);
++ if (!no_p)
++ P0 = av_clip_pixel(p0 + delta0);
++ if (!no_q)
++ Q0 = av_clip_pixel(q0 - delta0);
++ pix += ystride;
++ }
++ }
++}
++
++static void FUNC(hevc_h_loop_filter_chroma)(uint8_t *pix, ptrdiff_t stride,
++ int32_t *tc, uint8_t *no_p,
++ uint8_t *no_q)
++{
++ FUNC(hevc_loop_filter_chroma)(pix, stride, sizeof(pixel), tc, no_p, no_q);
++}
++
++static void FUNC(hevc_v_loop_filter_chroma)(uint8_t *pix, ptrdiff_t stride,
++ int32_t *tc, uint8_t *no_p,
++ uint8_t *no_q)
++{
++ FUNC(hevc_loop_filter_chroma)(pix, sizeof(pixel), stride, tc, no_p, no_q);
++}
++
++static void FUNC(hevc_h_loop_filter_luma)(uint8_t *pix, ptrdiff_t stride,
++ int beta, int32_t *tc, uint8_t *no_p,
++ uint8_t *no_q)
++{
++ FUNC(hevc_loop_filter_luma)(pix, stride, sizeof(pixel),
++ beta, tc, no_p, no_q);
++}
++
++static void FUNC(hevc_v_loop_filter_luma)(uint8_t *pix, ptrdiff_t stride,
++ int beta, int32_t *tc, uint8_t *no_p,
++ uint8_t *no_q)
++{
++ FUNC(hevc_loop_filter_luma)(pix, sizeof(pixel), stride,
++ beta, tc, no_p, no_q);
++}
++
++#undef P3
++#undef P2
++#undef P1
++#undef P0
++#undef Q0
++#undef Q1
++#undef Q2
++#undef Q3
++
++#undef TP3
++#undef TP2
++#undef TP1
++#undef TP0
++#undef TQ0
++#undef TQ1
++#undef TQ2
++#undef TQ3
++
++// line zero
++#define P3 pix_l[0 * xstride]
++#define P2 pix_l[1 * xstride]
++#define P1 pix_l[2 * xstride]
++#define P0 pix_l[3 * xstride]
++#define Q0 pix_r[0 * xstride]
++#define Q1 pix_r[1 * xstride]
++#define Q2 pix_r[2 * xstride]
++#define Q3 pix_r[3 * xstride]
++
++// line three. used only for deblocking decision
++#define TP3 pix_l[0 * xstride + 3 * ystride]
++#define TP2 pix_l[1 * xstride + 3 * ystride]
++#define TP1 pix_l[2 * xstride + 3 * ystride]
++#define TP0 pix_l[3 * xstride + 3 * ystride]
++#define TQ0 pix_r[0 * xstride + 3 * ystride]
++#define TQ1 pix_r[1 * xstride + 3 * ystride]
++#define TQ2 pix_r[2 * xstride + 3 * ystride]
++#define TQ3 pix_r[3 * xstride + 3 * ystride]
++
++// This is identical to hevc_loop_filter_luma except that the P/Q
++// components are on separate pointers
++static void FUNC(hevc_v_loop_filter_luma2)(uint8_t * _pix_r,
++ unsigned int _stride, unsigned int beta, unsigned int tc2, unsigned int no_f,
++ uint8_t * _pix_l)
++{
++ int d, j;
++ pixel *pix_l = (pixel *)_pix_l;
++ pixel *pix_r = (pixel *)_pix_r;
++ const ptrdiff_t xstride = 1;
++ const ptrdiff_t ystride = _stride / sizeof(pixel);
++
++ beta <<= BIT_DEPTH - 8;
++
++ for (j = 0; j < 2; j++) {
++ const int dp0 = abs(P2 - 2 * P1 + P0);
++ const int dq0 = abs(Q2 - 2 * Q1 + Q0);
++ const int dp3 = abs(TP2 - 2 * TP1 + TP0);
++ const int dq3 = abs(TQ2 - 2 * TQ1 + TQ0);
++ const int d0 = dp0 + dq0;
++ const int d3 = dp3 + dq3;
++ const int tc = ((tc2 >> (j << 4)) & 0xffff) << (BIT_DEPTH - 8);
++ const int no_p = no_f & 1;
++ const int no_q = no_f & 2;
++
++ if (d0 + d3 >= beta) {
++ pix_l += 4 * ystride;
++ pix_r += 4 * ystride;
++ continue;
++ } else {
++ const int beta_3 = beta >> 3;
++ const int beta_2 = beta >> 2;
++ const int tc25 = ((tc * 5 + 1) >> 1);
++
++ if (abs(P3 - P0) + abs(Q3 - Q0) < beta_3 && abs(P0 - Q0) < tc25 &&
++ abs(TP3 - TP0) + abs(TQ3 - TQ0) < beta_3 && abs(TP0 - TQ0) < tc25 &&
++ (d0 << 1) < beta_2 && (d3 << 1) < beta_2) {
++ // strong filtering
++ const int tc2 = tc << 1;
++ for (d = 0; d < 4; d++) {
++ const int p3 = P3;
++ const int p2 = P2;
++ const int p1 = P1;
++ const int p0 = P0;
++ const int q0 = Q0;
++ const int q1 = Q1;
++ const int q2 = Q2;
++ const int q3 = Q3;
++ if (!no_p) {
++ P0 = p0 + av_clip(((p2 + 2 * p1 + 2 * p0 + 2 * q0 + q1 + 4) >> 3) - p0, -tc2, tc2);
++ P1 = p1 + av_clip(((p2 + p1 + p0 + q0 + 2) >> 2) - p1, -tc2, tc2);
++ P2 = p2 + av_clip(((2 * p3 + 3 * p2 + p1 + p0 + q0 + 4) >> 3) - p2, -tc2, tc2);
++ }
++ if (!no_q) {
++ Q0 = q0 + av_clip(((p1 + 2 * p0 + 2 * q0 + 2 * q1 + q2 + 4) >> 3) - q0, -tc2, tc2);
++ Q1 = q1 + av_clip(((p0 + q0 + q1 + q2 + 2) >> 2) - q1, -tc2, tc2);
++ Q2 = q2 + av_clip(((2 * q3 + 3 * q2 + q1 + q0 + p0 + 4) >> 3) - q2, -tc2, tc2);
++ }
++ pix_l += ystride;
++ pix_r += ystride;
++ }
++ } else { // normal filtering
++ int nd_p = 1;
++ int nd_q = 1;
++ const int tc_2 = tc >> 1;
++ if (dp0 + dp3 < ((beta + (beta >> 1)) >> 3))
++ nd_p = 2;
++ if (dq0 + dq3 < ((beta + (beta >> 1)) >> 3))
++ nd_q = 2;
++
++ for (d = 0; d < 4; d++) {
++ const int p2 = P2;
++ const int p1 = P1;
++ const int p0 = P0;
++ const int q0 = Q0;
++ const int q1 = Q1;
++ const int q2 = Q2;
++ int delta0 = (9 * (q0 - p0) - 3 * (q1 - p1) + 8) >> 4;
++ if (abs(delta0) < 10 * tc) {
++ delta0 = av_clip(delta0, -tc, tc);
++ if (!no_p)
++ P0 = av_clip_pixel(p0 + delta0);
++ if (!no_q)
++ Q0 = av_clip_pixel(q0 - delta0);
++ if (!no_p && nd_p > 1) {
++ const int deltap1 = av_clip((((p2 + p0 + 1) >> 1) - p1 + delta0) >> 1, -tc_2, tc_2);
++ P1 = av_clip_pixel(p1 + deltap1);
++ }
++ if (!no_q && nd_q > 1) {
++ const int deltaq1 = av_clip((((q2 + q0 + 1) >> 1) - q1 - delta0) >> 1, -tc_2, tc_2);
++ Q1 = av_clip_pixel(q1 + deltaq1);
++ }
++ }
++ pix_l += ystride;
++ pix_r += ystride;
++ }
++ }
++ }
++ }
++}
++
++static void FUNC(hevc_h_loop_filter_luma2)(uint8_t * _pix_r,
++ unsigned int _stride, unsigned int beta, unsigned int tc2, unsigned int no_f)
++{
++ // Just call the non-2 function having massaged the parameters
++ int32_t tc[2] = {tc2 & 0xffff, tc2 >> 16};
++ uint8_t no_p[2] = {no_f & 1, no_f & 1};
++ uint8_t no_q[2] = {no_f & 2, no_f & 2};
++ FUNC(hevc_h_loop_filter_luma)(_pix_r, _stride, beta, tc, no_p, no_q);
++}
++
++#undef TP3
++#undef TP2
++#undef TP1
++#undef TP0
++#undef TQ0
++#undef TQ1
++#undef TQ2
++#undef TQ3
++
++#undef P3
++#undef P2
++#undef P1
++#undef P0
++#undef Q0
++#undef Q1
++#undef Q2
++#undef Q3
++
++#define P1 pix_l[0 * xstride]
++#define P0 pix_l[1 * xstride]
++#define Q0 pix_r[0 * xstride]
++#define Q1 pix_r[1 * xstride]
++
++static void FUNC(hevc_loop_filter_uv2)(uint8_t *_pix_l, ptrdiff_t _xstride,
++ ptrdiff_t _ystride, const int32_t *_tc,
++ const uint8_t *_no_p, const uint8_t *_no_q, uint8_t *_pix_r)
++{
++ int d, j, no_p, no_q;
++ pixel *pix_l = (pixel *)_pix_l;
++ pixel *pix_r = (pixel *)_pix_r;
++ ptrdiff_t xstride = _xstride / sizeof(pixel);
++ ptrdiff_t ystride = _ystride / sizeof(pixel);
++
++ for (j = 0; j < 2; j++) {
++ const int tc = _tc[j] << (BIT_DEPTH - 8);
++ if (tc <= 0) {
++ pix_l += 4 * ystride;
++ pix_r += 4 * ystride;
++ continue;
++ }
++ no_p = _no_p[j];
++ no_q = _no_q[j];
++
++ for (d = 0; d < 4; d++) {
++ int delta0;
++ const int p1 = P1;
++ const int p0 = P0;
++ const int q0 = Q0;
++ const int q1 = Q1;
++ delta0 = av_clip((((q0 - p0) * 4) + p1 - q1 + 4) >> 3, -tc, tc);
++ if (!no_p)
++ P0 = av_clip_pixel(p0 + delta0);
++ if (!no_q)
++ Q0 = av_clip_pixel(q0 - delta0);
++ pix_l += ystride;
++ pix_r += ystride;
++ }
++ }
++}
++
++static void FUNC(hevc_h_loop_filter_uv)(uint8_t * pix, unsigned int stride, uint32_t tc4,
++ unsigned int no_f)
++{
++ uint8_t no_p[2] = {no_f & 1, no_f & 2};
++ uint8_t no_q[2] = {no_f & 4, no_f & 8};
++ int32_t tc[4] = {tc4 & 0xff, (tc4 >> 8) & 0xff, (tc4 >> 16) & 0xff, tc4 >> 24};
++ FUNC(hevc_loop_filter_chroma)(pix, stride, sizeof(pixel) * 2, tc, no_p, no_q);
++ FUNC(hevc_loop_filter_chroma)(pix + sizeof(pixel), stride, sizeof(pixel) * 2, tc + 2, no_p, no_q);
++}
++
++static void FUNC(hevc_v_loop_filter_uv2)(uint8_t * src_r, unsigned int stride, uint32_t tc4,
++ uint8_t * src_l,
++ unsigned int no_f)
++{
++ uint8_t no_p[2] = {no_f & 1, no_f & 2};
++ uint8_t no_q[2] = {no_f & 4, no_f & 8};
++ int32_t tc[4] = {tc4 & 0xff, (tc4 >> 8) & 0xff, (tc4 >> 16) & 0xff, tc4 >> 24};
++ FUNC(hevc_loop_filter_uv2)(src_l, sizeof(pixel) * 2, stride, tc, no_p, no_q, src_r);
++ FUNC(hevc_loop_filter_uv2)(src_l + sizeof(pixel), sizeof(pixel) * 2, stride, tc + 2, no_p, no_q, src_r + sizeof(pixel));
++}
++
++#undef P1
++#undef P0
++#undef Q0
++#undef Q1
++
+diff --git a/libavcodec/rpi_hevcpred.c b/libavcodec/rpi_hevcpred.c
+new file mode 100644
+index 0000000000..62135b83c2
+--- /dev/null
++++ b/libavcodec/rpi_hevcpred.c
+@@ -0,0 +1,166 @@
++/*
++ * HEVC video Decoder
++ *
++ * Copyright (C) 2012 - 2013 Guillaume Martres
++ *
++ * This file is part of FFmpeg.
++ *
++ * FFmpeg is free software; you can redistribute it and/or
++ * modify it under the terms of the GNU Lesser General Public
++ * License as published by the Free Software Foundation; either
++ * version 2.1 of the License, or (at your option) any later version.
++ *
++ * FFmpeg is distributed in the hope that it will be useful,
++ * but WITHOUT ANY WARRANTY; without even the implied warranty of
++ * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
++ * Lesser General Public License for more details.
++ *
++ * You should have received a copy of the GNU Lesser General Public
++ * License along with FFmpeg; if not, write to the Free Software
++ * Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA
++ */
++
++#include "rpi_hevcdec.h"
++
++#include "rpi_hevcpred.h"
++#if (ARCH_ARM)
++#include "arm/rpi_hevcpred_arm.h"
++#endif
++
++#define PRED_C 0
++#define BIT_DEPTH 8
++#include "rpi_hevcpred_template.c"
++#undef BIT_DEPTH
++
++#define BIT_DEPTH 9
++#include "rpi_hevcpred_template.c"
++#undef BIT_DEPTH
++
++#define BIT_DEPTH 10
++#include "rpi_hevcpred_template.c"
++#undef BIT_DEPTH
++
++#define BIT_DEPTH 12
++#include "rpi_hevcpred_template.c"
++#undef BIT_DEPTH
++#undef PRED_C
++
++#define PRED_C 1
++#define BIT_DEPTH 8
++#include "rpi_hevcpred_template.c"
++#undef BIT_DEPTH
++
++#define BIT_DEPTH 9
++#include "rpi_hevcpred_template.c"
++#undef BIT_DEPTH
++
++#define BIT_DEPTH 10
++#include "rpi_hevcpred_template.c"
++#undef BIT_DEPTH
++
++#define BIT_DEPTH 12
++#include "rpi_hevcpred_template.c"
++#undef BIT_DEPTH
++#undef PRED_C
++
++void ff_hevc_rpi_pred_init(HEVCRpiPredContext *hpc, int bit_depth)
++{
++#undef FUNC
++#define FUNC(a, depth) a ## _ ## depth
++
++#undef FUNCC
++#define FUNCC(a, depth) a ## _ ## depth ## _c
++
++#define HEVC_PRED_Y(depth) \
++ hpc->intra_pred[0] = FUNC(intra_pred_2, depth); \
++ hpc->intra_pred[1] = FUNC(intra_pred_3, depth); \
++ hpc->intra_pred[2] = FUNC(intra_pred_4, depth); \
++ hpc->intra_pred[3] = FUNC(intra_pred_5, depth); \
++ hpc->intra_filter[0] = FUNC(intra_filter_2, depth); \
++ hpc->intra_filter[1] = FUNC(intra_filter_3, depth); \
++ hpc->intra_filter[2] = FUNC(intra_filter_4, depth); \
++ hpc->intra_filter[3] = FUNC(intra_filter_5, depth); \
++ hpc->pred_planar[0] = FUNC(pred_planar_0, depth); \
++ hpc->pred_planar[1] = FUNC(pred_planar_1, depth); \
++ hpc->pred_planar[2] = FUNC(pred_planar_2, depth); \
++ hpc->pred_planar[3] = FUNC(pred_planar_3, depth); \
++ hpc->pred_dc[0] = FUNC(pred_dc_0, depth); \
++ hpc->pred_dc[1] = FUNC(pred_dc_1, depth); \
++ hpc->pred_dc[2] = FUNC(pred_dc_2, depth); \
++ hpc->pred_dc[3] = FUNC(pred_dc_3, depth); \
++ hpc->pred_vertical[0] = FUNC(pred_angular_0, depth); \
++ hpc->pred_vertical[1] = FUNC(pred_angular_1, depth); \
++ hpc->pred_vertical[2] = FUNC(pred_angular_2, depth); \
++ hpc->pred_vertical[3] = FUNC(pred_angular_3, depth); \
++ hpc->pred_horizontal[0] = FUNC(pred_angular_0, depth); \
++ hpc->pred_horizontal[1] = FUNC(pred_angular_1, depth); \
++ hpc->pred_horizontal[2] = FUNC(pred_angular_2, depth); \
++ hpc->pred_horizontal[3] = FUNC(pred_angular_3, depth); \
++ hpc->pred_angular[0] = FUNC(pred_angular_0, depth); \
++ hpc->pred_angular[1] = FUNC(pred_angular_1, depth); \
++ hpc->pred_angular[2] = FUNC(pred_angular_2, depth); \
++ hpc->pred_angular[3] = FUNC(pred_angular_3, depth); \
++ hpc->pred_dc0[0] = FUNC(pred_dc0_0, depth); \
++ hpc->pred_dc0[1] = FUNC(pred_dc0_1, depth); \
++ hpc->pred_dc0[2] = FUNC(pred_dc0_2, depth); \
++ hpc->pred_dc0[3] = FUNC(pred_dc0_3, depth);
++
++#define HEVC_PRED_C(depth) \
++ hpc->intra_pred_c[0] = FUNCC(intra_pred_2, depth); \
++ hpc->intra_pred_c[1] = FUNCC(intra_pred_3, depth); \
++ hpc->intra_pred_c[2] = FUNCC(intra_pred_4, depth); \
++ hpc->intra_pred_c[3] = FUNCC(intra_pred_5, depth); \
++ hpc->intra_filter_c[0] = FUNCC(intra_filter_2, depth); \
++ hpc->intra_filter_c[1] = FUNCC(intra_filter_3, depth); \
++ hpc->intra_filter_c[2] = FUNCC(intra_filter_4, depth); \
++ hpc->intra_filter_c[3] = FUNCC(intra_filter_5, depth); \
++ hpc->pred_planar_c[0] = FUNCC(pred_planar_0, depth); \
++ hpc->pred_planar_c[1] = FUNCC(pred_planar_1, depth); \
++ hpc->pred_planar_c[2] = FUNCC(pred_planar_2, depth); \
++ hpc->pred_planar_c[3] = FUNCC(pred_planar_3, depth); \
++ hpc->pred_dc_c[0] = FUNCC(pred_dc_0, depth); \
++ hpc->pred_dc_c[1] = FUNCC(pred_dc_1, depth); \
++ hpc->pred_dc_c[2] = FUNCC(pred_dc_2, depth); \
++ hpc->pred_dc_c[3] = FUNCC(pred_dc_3, depth); \
++ hpc->pred_vertical_c[0] = FUNCC(pred_angular_0, depth); \
++ hpc->pred_vertical_c[1] = FUNCC(pred_angular_1, depth); \
++ hpc->pred_vertical_c[2] = FUNCC(pred_angular_2, depth); \
++ hpc->pred_vertical_c[3] = FUNCC(pred_angular_3, depth); \
++ hpc->pred_horizontal_c[0] = FUNCC(pred_angular_0, depth); \
++ hpc->pred_horizontal_c[1] = FUNCC(pred_angular_1, depth); \
++ hpc->pred_horizontal_c[2] = FUNCC(pred_angular_2, depth); \
++ hpc->pred_horizontal_c[3] = FUNCC(pred_angular_3, depth); \
++ hpc->pred_angular_c[0] = FUNCC(pred_angular_0, depth); \
++ hpc->pred_angular_c[1] = FUNCC(pred_angular_1, depth); \
++ hpc->pred_angular_c[2] = FUNCC(pred_angular_2, depth); \
++ hpc->pred_angular_c[3] = FUNCC(pred_angular_3, depth); \
++ hpc->pred_dc0_c[0] = FUNCC(pred_dc0_0, depth); \
++ hpc->pred_dc0_c[1] = FUNCC(pred_dc0_1, depth); \
++ hpc->pred_dc0_c[2] = FUNCC(pred_dc0_2, depth); \
++ hpc->pred_dc0_c[3] = FUNCC(pred_dc0_3, depth);
++
++#define HEVC_PRED(depth) \
++ HEVC_PRED_Y(depth); \
++ HEVC_PRED_C(depth);
++
++ switch (bit_depth) {
++ case 9:
++ HEVC_PRED(9);
++ break;
++ case 10:
++ HEVC_PRED(10);
++ break;
++ case 12:
++ HEVC_PRED(12);
++ break;
++ default:
++ HEVC_PRED(8);
++ break;
++ }
++
++#if (ARCH_ARM)
++ ff_hevc_rpi_pred_init_arm(hpc, bit_depth);
++#elif (ARCH_MIPS)
++ ff_hevc_rpi_pred_init_mips(hpc, bit_depth);
++#endif
++}
+diff --git a/libavcodec/rpi_hevcpred.h b/libavcodec/rpi_hevcpred.h
+new file mode 100644
+index 0000000000..6e594277c0
+--- /dev/null
++++ b/libavcodec/rpi_hevcpred.h
+@@ -0,0 +1,121 @@
++/*
++ * HEVC video Decoder
++ *
++ * Copyright (C) 2012 - 2013 Guillaume Martres
++ *
++ * This file is part of FFmpeg.
++ *
++ * FFmpeg is free software; you can redistribute it and/or
++ * modify it under the terms of the GNU Lesser General Public
++ * License as published by the Free Software Foundation; either
++ * version 2.1 of the License, or (at your option) any later version.
++ *
++ * FFmpeg is distributed in the hope that it will be useful,
++ * but WITHOUT ANY WARRANTY; without even the implied warranty of
++ * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
++ * Lesser General Public License for more details.
++ *
++ * You should have received a copy of the GNU Lesser General Public
++ * License along with FFmpeg; if not, write to the Free Software
++ * Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA
++ */
++
++#ifndef AVCODEC_RPI_HEVCPRED_H
++#define AVCODEC_RPI_HEVCPRED_H
++
++#include <stddef.h>
++#include <stdint.h>
++#include "config.h"
++
++struct HEVCRpiContext;
++struct HEVCRpiLocalContext;
++
++enum IntraPredMode {
++ INTRA_PLANAR = 0,
++ INTRA_DC,
++ INTRA_ANGULAR_2,
++ INTRA_ANGULAR_3,
++ INTRA_ANGULAR_4,
++ INTRA_ANGULAR_5,
++ INTRA_ANGULAR_6,
++ INTRA_ANGULAR_7,
++ INTRA_ANGULAR_8,
++ INTRA_ANGULAR_9,
++ INTRA_ANGULAR_10,
++ INTRA_ANGULAR_11,
++ INTRA_ANGULAR_12,
++ INTRA_ANGULAR_13,
++ INTRA_ANGULAR_14,
++ INTRA_ANGULAR_15,
++ INTRA_ANGULAR_16,
++ INTRA_ANGULAR_17,
++ INTRA_ANGULAR_18,
++ INTRA_ANGULAR_19,
++ INTRA_ANGULAR_20,
++ INTRA_ANGULAR_21,
++ INTRA_ANGULAR_22,
++ INTRA_ANGULAR_23,
++ INTRA_ANGULAR_24,
++ INTRA_ANGULAR_25,
++ INTRA_ANGULAR_26,
++ INTRA_ANGULAR_27,
++ INTRA_ANGULAR_28,
++ INTRA_ANGULAR_29,
++ INTRA_ANGULAR_30,
++ INTRA_ANGULAR_31,
++ INTRA_ANGULAR_32,
++ INTRA_ANGULAR_33,
++ INTRA_ANGULAR_34,
++};
++#define INTRA_ANGULAR_HORIZONTAL INTRA_ANGULAR_10
++#define INTRA_ANGULAR_VERTICAL INTRA_ANGULAR_26
++
++typedef void intra_filter_fn_t(
++ uint8_t * const left, uint8_t * const top,
++ const unsigned int req, const unsigned int avail,
++ const uint8_t * const src_l, const uint8_t * const src_u, const uint8_t * const src_ur,
++ const unsigned int stride,
++ const unsigned int top_right_size, const unsigned int down_left_size);
++
++typedef struct HEVCRpiPredContext {
++ void (*intra_pred[4])(const struct HEVCRpiContext * const s,
++ const enum IntraPredMode mode, const unsigned int x0, const unsigned int y0, const unsigned int avail);
++
++ intra_filter_fn_t *intra_filter[4];
++ void (*pred_planar[4])(uint8_t *src, const uint8_t *top,
++ const uint8_t *left, ptrdiff_t stride);
++ void (*pred_dc[4])(uint8_t *src, const uint8_t *top, const uint8_t *left,
++ ptrdiff_t stride);
++ void (*pred_angular[4])(uint8_t *src, const uint8_t *top,
++ const uint8_t *left, ptrdiff_t stride,
++ int mode);
++ void (*pred_vertical[4])(uint8_t *src, const uint8_t *top,
++ const uint8_t *left, ptrdiff_t stride,
++ int mode);
++ void (*pred_horizontal[4])(uint8_t *src, const uint8_t *top,
++ const uint8_t *left, ptrdiff_t stride,
++ int mode);
++ void (*pred_dc0[4])(uint8_t *src, ptrdiff_t stride);
++
++ void (*intra_pred_c[4])(const struct HEVCRpiContext * const s,
++ const enum IntraPredMode mode, const unsigned int x0, const unsigned int y0, const unsigned int avail);
++ intra_filter_fn_t *intra_filter_c[4];
++ void (*pred_planar_c[4])(uint8_t *src, const uint8_t *top,
++ const uint8_t *left, ptrdiff_t stride);
++ void (*pred_dc_c[4])(uint8_t *src, const uint8_t *top, const uint8_t *left,
++ ptrdiff_t stride);
++ void (*pred_angular_c[4])(uint8_t *src, const uint8_t *top,
++ const uint8_t *left, ptrdiff_t stride,
++ int mode);
++ void (*pred_vertical_c[4])(uint8_t *src, const uint8_t *top,
++ const uint8_t *left, ptrdiff_t stride,
++ int mode);
++ void (*pred_horizontal_c[4])(uint8_t *src, const uint8_t *top,
++ const uint8_t *left, ptrdiff_t stride,
++ int mode);
++ void (*pred_dc0_c[4])(uint8_t *src, ptrdiff_t stride);
++} HEVCRpiPredContext;
++
++void ff_hevc_rpi_pred_init(HEVCRpiPredContext *hpc, int bit_depth);
++
++#endif /* AVCODEC_RPI_HEVCPRED_H */
+diff --git a/libavcodec/rpi_hevcpred_template.c b/libavcodec/rpi_hevcpred_template.c
+new file mode 100644
+index 0000000000..2f710626cf
+--- /dev/null
++++ b/libavcodec/rpi_hevcpred_template.c
+@@ -0,0 +1,1522 @@
++/*
++ * HEVC video decoder
++ *
++ * Copyright (C) 2012 - 2013 Guillaume Martres
++ *
++ * This file is part of FFmpeg.
++ *
++ * FFmpeg is free software; you can redistribute it and/or
++ * modify it under the terms of the GNU Lesser General Public
++ * License as published by the Free Software Foundation; either
++ * version 2.1 of the License, or (at your option) any later version.
++ *
++ * FFmpeg is distributed in the hope that it will be useful,
++ * but WITHOUT ANY WARRANTY; without even the implied warranty of
++ * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
++ * Lesser General Public License for more details.
++ *
++ * You should have received a copy of the GNU Lesser General Public
++ * License along with FFmpeg; if not, write to the Free Software
++ * Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA
++ */
++
++#include "config.h"
++#include "libavutil/pixdesc.h"
++#include "libavutil/rpi_sand_fns.h"
++#include "bit_depth_template.c"
++
++#include "rpi_hevcdec.h"
++#include "rpi_hevcpred.h"
++
++#define DUMP_PRED 0
++
++#define POS(x, y) src[(x) + stride * (y)]
++
++// INCLUDED_ONCE defined at EOF
++#ifndef INCLUDED_ONCE
++typedef uint8_t (* c8_dst_ptr_t)[2];
++typedef const uint8_t (* c8_src_ptr_t)[2];
++typedef uint16_t (* c16_dst_ptr_t)[2];
++typedef const uint16_t (* c16_src_ptr_t)[2];
++
++// *** On ARM make these NEON registers
++typedef struct pixel4_16 {
++ uint16_t x[4];
++} pixel4_16;
++typedef struct pixel4_32 {
++ uint32_t x[4];
++} pixel4_32;
++static inline pixel4_16 PIXEL_SPLAT_X4_16(const uint16_t x)
++{
++ pixel4_16 t = {{x, x, x, x}};
++ return t;
++}
++static inline pixel4_32 PIXEL_SPLAT_X4_32(const uint32_t x)
++{
++ pixel4_32 t = {{x, x, x, x}};
++ return t;
++}
++#endif
++
++#if PRED_C
++// For chroma we double pixel size so we copy pairs
++#undef pixel
++#undef pixel2
++#undef pixel4
++#undef dctcoef
++#undef INIT_CLIP
++#undef no_rnd_avg_pixel4
++#undef rnd_avg_pixel4
++#undef AV_RN2P
++#undef AV_RN4P
++#undef AV_RN4PA
++#undef AV_WN2P
++#undef AV_WN4P
++#undef AV_WN4PA
++#undef CLIP
++#undef FUNC
++#undef FUNCC
++#undef av_clip_pixel
++#undef PIXEL_SPLAT_X4
++
++#if BIT_DEPTH == 8
++#define pixel uint16_t
++#define pixel4 pixel4_16
++#define PIXEL_SPLAT_X4 PIXEL_SPLAT_X4_16
++#define cpel uint8_t
++#define c_src_ptr_t c8_src_ptr_t
++#define c_dst_ptr_t c8_dst_ptr_t
++#else
++#define pixel uint32_t
++#define pixel4 pixel4_32
++#define PIXEL_SPLAT_X4 PIXEL_SPLAT_X4_32
++#define cpel uint16_t
++#define c_src_ptr_t c16_dst_ptr_t
++#define c_dst_ptr_t c16_dst_ptr_t
++#endif
++#define AV_RN4P(p) (*(pixel4*)(p))
++#define AV_WN4P(p,x) (*(pixel4*)(p) = (x))
++#define FUNC(a) FUNC2(a, BIT_DEPTH, _c)
++#endif
++
++
++// Get PW prior to horrid PRED_C trickery
++#if BIT_DEPTH == 8
++#define PW 1
++#else
++#define PW 2
++#endif
++
++
++#if DUMP_PRED && !defined(INCLUDED_ONCE)
++static void dump_pred_uv(const uint8_t * data, const unsigned int stride, const unsigned int size)
++{
++ for (unsigned int y = 0; y != size; y++, data += stride * 2) {
++ for (unsigned int x = 0; x != size; x++) {
++ printf("%4d", data[x * 2]);
++ }
++ printf("\n");
++ }
++ printf("\n");
++}
++#endif
++
++#ifndef INCLUDED_ONCE
++static inline void extend_8(void * ptr, const unsigned int v, unsigned int n)
++{
++ if ((n >>= 2) != 0) {
++ uint32_t v4 = v | (v << 8);
++ uint32_t * p = (uint32_t *)ptr;
++ v4 = v4 | (v4 << 16);
++ do {
++ *p++ = v4;
++ } while (--n != 0);
++ }
++}
++
++static inline void extend_16(void * ptr, const unsigned int v, unsigned int n)
++{
++ if ((n >>= 2) != 0) {
++ uint32_t v2 = v | (v << 16);
++ uint32_t * p = (uint32_t *)ptr;
++ do {
++ *p++ = v2;
++ *p++ = v2;
++ } while (--n != 0);
++ }
++}
++
++static inline void extend_32(void * ptr, const unsigned int v, unsigned int n)
++{
++ if ((n >>= 2) != 0) {
++ uint32_t * p = (uint32_t *)ptr;
++ do {
++ *p++ = v;
++ *p++ = v;
++ *p++ = v;
++ *p++ = v;
++ } while (--n != 0);
++ }
++}
++
++// Beware that this inverts the avail ordering
++// For CIP it seems easier this way round
++static unsigned int cip_avail_l(const uint8_t * is_intra, const int i_stride, const unsigned int i_mask,
++ const unsigned int log2_intra_bits, const unsigned int avail, unsigned int size,
++ unsigned int s0, unsigned int odd_s)
++{
++ const unsigned int n = 1 << log2_intra_bits;
++ unsigned int fa = 0;
++ unsigned int i;
++
++ size >>= 2; // Now in 4-pel units
++ s0 >>= 2;
++
++ if ((avail & AVAIL_DL) != 0)
++ fa |= ((1 << s0) - 1) << (size - s0);
++ if ((avail & AVAIL_L) != 0)
++ fa |= ((1 << size) - 1) << size;
++ if ((avail & AVAIL_UL) != 0)
++ fa |= 1 << (size << 1);
++
++ if (odd_s) {
++ if ((fa & 1) != 0 && (*is_intra & i_mask) == 0)
++ fa &= ~1;
++ is_intra += i_stride;
++ }
++
++ for (i = odd_s; (fa >> i) != 0; i += n, is_intra += i_stride) {
++ const unsigned int m = ((1 << n) - 1) << i;
++ if ((fa & m) != 0 && (*is_intra & i_mask) == 0)
++ fa &= ~m;
++ }
++
++ return fa;
++}
++
++static unsigned int cip_avail_u(const uint8_t * is_intra, unsigned int i_shift,
++ const unsigned int log2_intra_bits, const unsigned int avail, unsigned int size,
++ unsigned int s1, unsigned int odd_s)
++{
++ if ((avail & (AVAIL_U | AVAIL_UR)) == 0)
++ {
++ return 0;
++ }
++ else
++ {
++ const unsigned int n = 1 << log2_intra_bits;
++ unsigned int fa = 0;
++ unsigned int i;
++ unsigned int im = ((is_intra[1] << 8) | (is_intra[0])) >> i_shift;
++
++ size >>= 2; // Now in 4-pel units
++ s1 >>= 2;
++
++ if ((avail & AVAIL_U) != 0)
++ fa |= ((1 << size) - 1);
++ if ((avail & AVAIL_UR) != 0)
++ fa |= ((1 << s1) - 1) << size;
++
++ if (odd_s) {
++ fa &= im | ~1;
++ im >>= 1;
++ }
++
++ for (i = odd_s; (fa >> i) != 0; i += n, im >>= 1) {
++ const unsigned int m = ((1 << n) - 1) << i;
++ if ((im & 1) == 0)
++ fa &= ~m;
++ }
++ return fa;
++ }
++}
++
++
++
++static inline unsigned int rmbd(unsigned int x)
++{
++#if 1
++ return __builtin_ctz(x);
++#else
++ unsigned int n = 0;
++ if ((x & 0xffff) == 0) {
++ x >>= 16;
++ n += 16;
++ }
++ if ((x & 0xff) == 0) {
++ x >>= 8;
++ n += 8;
++ }
++ if ((x & 0xf) == 0) {
++ x >>= 4;
++ n += 4;
++ }
++ if ((x & 0x3) == 0) {
++ x >>= 2;
++ n += 2;
++ }
++
++ return (x & 1) == 0 ? n + 1 : n;
++#endif
++}
++#endif
++
++
++static void FUNC(cip_fill)(pixel * const left, pixel * const top,
++ const unsigned int avail_l, const unsigned int avail_u,
++ const pixel * const src_l, const pixel * const src_u, const pixel * const src_ur,
++ const unsigned int stride,
++ const unsigned int size)
++{
++ pixel a;
++ unsigned int i;
++
++ // 1st find DL value
++ if ((avail_l & 1) == 0) {
++ if (avail_l != 0)
++ a = src_l[((int)size * 2 - 1 - (int)rmbd(avail_l)*4) * (int)stride];
++ else
++ {
++ // (avail_l | avail_u) != 0 so this must be good
++ const unsigned int n = rmbd(avail_u)*4;
++ a = (n >= size) ? src_ur[n - size] : src_u[n];
++ }
++ }
++
++ // L
++ {
++ pixel * d = left + size * 2 - 1;
++ const pixel * s = src_l + (size * 2 - 1) * stride;
++ unsigned int x = avail_l;
++ for (i = 0; i < size * 2; i += 4, x >>= 1)
++ {
++ if ((x & 1) != 0) {
++ // Avail
++ *d-- = *s;
++ s -= stride;
++ *d-- = *s;
++ s -= stride;
++ *d-- = *s;
++ s -= stride;
++ *d-- = a = *s;
++ s -= stride;
++ }
++ else
++ {
++ *d-- = a;
++ *d-- = a;
++ *d-- = a;
++ *d-- = a;
++ s -= stride * 4;
++ }
++ }
++ // UL
++ *d = a = (x & 1) != 0 ? *s : a;
++ }
++
++ // U
++ {
++ pixel * d = top;
++ const pixel * s = src_u;
++ unsigned int x = avail_u;
++
++ for (i = 0; i < size; i += 4, x >>= 1)
++ {
++ if ((x & 1) != 0) {
++ // Avail
++ *d++ = *s++;
++ *d++ = *s++;
++ *d++ = *s++;
++ *d++ = a = *s++;
++ }
++ else
++ {
++ *d++ = a;
++ *d++ = a;
++ *d++ = a;
++ *d++ = a;
++ s += 4;
++ }
++ }
++
++ // UR
++ s = src_ur;
++ for (i = 0; i < size; i += 4, x >>= 1)
++ {
++ if ((x & 1) != 0) {
++ // Avail
++ *d++ = *s++;
++ *d++ = *s++;
++ *d++ = *s++;
++ *d++ = a = *s++;
++ }
++ else
++ {
++ *d++ = a;
++ *d++ = a;
++ *d++ = a;
++ *d++ = a;
++ s += 4;
++ }
++ }
++ }
++}
++
++
++#if !PRED_C && PW == 1
++#define EXTEND(ptr, val, len) extend_8(ptr, val, len)
++#elif (!PRED_C && PW == 2) || (PRED_C && PW == 1)
++#define EXTEND(ptr, val, len) extend_16(ptr, val, len)
++#else
++#define EXTEND(ptr, val, len) extend_32(ptr, val, len)
++#endif
++
++// Reqs:
++//
++// Planar: DL[0], L, ul, U, UR[0]
++// DC: dl, L, ul, U, ur
++// A2-9: DL, L, ul, u, ur
++// A10: dl, L, ul, u, ur
++// A11-17 dl, L, UL, U, ur
++// A18-25 dl, L, Ul, U, ur
++// A26 dl, l, ul, U, ur
++// A27-34 dl, l, ul, U, UR
++
++#ifndef INCLUDED_ONCE
++
++intra_filter_fn_t ff_hevc_rpi_intra_filter_8_neon_8;
++intra_filter_fn_t ff_hevc_rpi_intra_filter_4_neon_16;
++intra_filter_fn_t ff_hevc_rpi_intra_filter_8_neon_16;
++
++#define FILTER_LIGHT 0x40
++#define FILTER_STRONG 0x80
++#define FILTER_EITHER (FILTER_LIGHT | FILTER_STRONG)
++
++static const uint8_t req_avail_c[35] =
++{
++ AVAIL_DL | AVAIL_L | 0 | AVAIL_U | AVAIL_UR, // Planar (DL[0] & UR[0] only needed)
++ AVAIL_L | 0 | AVAIL_U, // DC
++ AVAIL_DL | AVAIL_L, // 2
++ AVAIL_DL | AVAIL_L, // 3
++ AVAIL_DL | AVAIL_L, // 4
++ AVAIL_DL | AVAIL_L, // 5
++ AVAIL_DL | AVAIL_L, // 6
++ AVAIL_DL | AVAIL_L, // 7
++ AVAIL_DL | AVAIL_L, // 8
++ AVAIL_DL | AVAIL_L, // 9
++ AVAIL_L, // 10 (H)
++ AVAIL_L | AVAIL_UL | AVAIL_U, // 11
++ AVAIL_L | AVAIL_UL | AVAIL_U, // 12
++ AVAIL_L | AVAIL_UL | AVAIL_U, // 13
++ AVAIL_L | AVAIL_UL | AVAIL_U, // 14
++ AVAIL_L | AVAIL_UL | AVAIL_U, // 15
++ AVAIL_L | AVAIL_UL | AVAIL_U, // 16
++ AVAIL_L | AVAIL_UL | AVAIL_U, // 17
++ AVAIL_L | AVAIL_UL | AVAIL_U, // 18
++ AVAIL_L | AVAIL_UL | AVAIL_U, // 19
++ AVAIL_L | AVAIL_UL | AVAIL_U, // 20
++ AVAIL_L | AVAIL_UL | AVAIL_U, // 21
++ AVAIL_L | AVAIL_UL | AVAIL_U, // 22
++ AVAIL_L | AVAIL_UL | AVAIL_U, // 23
++ AVAIL_L | AVAIL_UL | AVAIL_U, // 24
++ AVAIL_L | AVAIL_UL | AVAIL_U, // 25
++ AVAIL_U, // 26 (V)
++ AVAIL_U | AVAIL_UR, // 27
++ AVAIL_U | AVAIL_UR, // 28
++ AVAIL_U | AVAIL_UR, // 29
++ AVAIL_U | AVAIL_UR, // 30
++ AVAIL_U | AVAIL_UR, // 31
++ AVAIL_U | AVAIL_UR, // 32
++ AVAIL_U | AVAIL_UR, // 33
++ AVAIL_U | AVAIL_UR // 34
++};
++
++static const uint8_t req_avail[4][35] = {
++{
++ AVAIL_DL | AVAIL_L | 0 | AVAIL_U | AVAIL_UR, // Planar (DL[0] & UR[0] only needed)
++ AVAIL_L | 0 | AVAIL_U, // DC
++ AVAIL_DL | AVAIL_L, // 2
++ AVAIL_DL | AVAIL_L, // 3
++ AVAIL_DL | AVAIL_L, // 4
++ AVAIL_DL | AVAIL_L, // 5
++ AVAIL_DL | AVAIL_L, // 6
++ AVAIL_DL | AVAIL_L, // 7
++ AVAIL_DL | AVAIL_L, // 8
++ AVAIL_DL | AVAIL_L, // 9
++ AVAIL_L | AVAIL_UL | AVAIL_U, // 10 (H)
++ AVAIL_L | AVAIL_UL | AVAIL_U, // 11
++ AVAIL_L | AVAIL_UL | AVAIL_U, // 12
++ AVAIL_L | AVAIL_UL | AVAIL_U, // 13
++ AVAIL_L | AVAIL_UL | AVAIL_U, // 14
++ AVAIL_L | AVAIL_UL | AVAIL_U, // 15
++ AVAIL_L | AVAIL_UL | AVAIL_U, // 16
++ AVAIL_L | AVAIL_UL | AVAIL_U, // 17
++ AVAIL_L | AVAIL_UL | AVAIL_U, // 18
++ AVAIL_L | AVAIL_UL | AVAIL_U, // 19
++ AVAIL_L | AVAIL_UL | AVAIL_U, // 20
++ AVAIL_L | AVAIL_UL | AVAIL_U, // 21
++ AVAIL_L | AVAIL_UL | AVAIL_U, // 22
++ AVAIL_L | AVAIL_UL | AVAIL_U, // 23
++ AVAIL_L | AVAIL_UL | AVAIL_U, // 24
++ AVAIL_L | AVAIL_UL | AVAIL_U, // 25
++ AVAIL_L | AVAIL_UL | AVAIL_U, // 26 (V)
++ AVAIL_U | AVAIL_UR, // 27
++ AVAIL_U | AVAIL_UR, // 28
++ AVAIL_U | AVAIL_UR, // 29
++ AVAIL_U | AVAIL_UR, // 30
++ AVAIL_U | AVAIL_UR, // 31
++ AVAIL_U | AVAIL_UR, // 32
++ AVAIL_U | AVAIL_UR, // 33
++ AVAIL_U | AVAIL_UR // 34
++},
++{ // 3
++ AVAIL_DL | AVAIL_L | 0 | AVAIL_U | AVAIL_UR | FILTER_LIGHT, // Planar (DL[0] & UR[0] only needed)
++ AVAIL_L | 0 | AVAIL_U, // DC
++ AVAIL_DL | AVAIL_L | FILTER_LIGHT, // 2
++ AVAIL_DL | AVAIL_L | 0, // 3
++ AVAIL_DL | AVAIL_L | 0, // 4
++ AVAIL_DL | AVAIL_L | 0, // 5
++ AVAIL_DL | AVAIL_L | 0, // 6
++ AVAIL_DL | AVAIL_L | 0, // 7
++ AVAIL_DL | AVAIL_L | 0, // 8
++ AVAIL_DL | AVAIL_L | 0, // 9
++ AVAIL_L | AVAIL_UL | AVAIL_U | 0, // 10 (H)
++ AVAIL_L | AVAIL_UL | AVAIL_U | 0, // 11
++ AVAIL_L | AVAIL_UL | AVAIL_U | 0, // 12
++ AVAIL_L | AVAIL_UL | AVAIL_U | 0, // 13
++ AVAIL_L | AVAIL_UL | AVAIL_U | 0, // 14
++ AVAIL_L | AVAIL_UL | AVAIL_U | 0, // 15
++ AVAIL_L | AVAIL_UL | AVAIL_U | 0, // 16
++ AVAIL_L | AVAIL_UL | AVAIL_U | 0, // 17
++ AVAIL_L | AVAIL_UL | AVAIL_U | FILTER_LIGHT, // 18
++ AVAIL_L | AVAIL_UL | AVAIL_U | 0, // 19
++ AVAIL_L | AVAIL_UL | AVAIL_U | 0, // 20
++ AVAIL_L | AVAIL_UL | AVAIL_U | 0, // 21
++ AVAIL_L | AVAIL_UL | AVAIL_U | 0, // 22
++ AVAIL_L | AVAIL_UL | AVAIL_U | 0, // 23
++ AVAIL_L | AVAIL_UL | AVAIL_U | 0, // 24
++ AVAIL_L | AVAIL_UL | AVAIL_U | 0, // 25
++ AVAIL_L | AVAIL_UL | AVAIL_U | 0, // 26 (V)
++ AVAIL_U | AVAIL_UR | 0, // 27
++ AVAIL_U | AVAIL_UR | 0, // 28
++ AVAIL_U | AVAIL_UR | 0, // 29
++ AVAIL_U | AVAIL_UR | 0, // 30
++ AVAIL_U | AVAIL_UR | 0, // 31
++ AVAIL_U | AVAIL_UR | 0, // 32
++ AVAIL_U | AVAIL_UR | 0, // 33
++ AVAIL_U | AVAIL_UR | FILTER_LIGHT // 34
++},
++{ // 4
++ AVAIL_DL | AVAIL_L | 0 | AVAIL_U | AVAIL_UR | FILTER_LIGHT, // Planar (DL[0] & UR[0] only needed)
++ AVAIL_L | 0 | AVAIL_U, // DC
++ AVAIL_DL | AVAIL_L | FILTER_LIGHT, // 2
++ AVAIL_DL | AVAIL_L | FILTER_LIGHT, // 3
++ AVAIL_DL | AVAIL_L | FILTER_LIGHT, // 4
++ AVAIL_DL | AVAIL_L | FILTER_LIGHT, // 5
++ AVAIL_DL | AVAIL_L | FILTER_LIGHT, // 6
++ AVAIL_DL | AVAIL_L | FILTER_LIGHT, // 7
++ AVAIL_DL | AVAIL_L | FILTER_LIGHT, // 8
++ AVAIL_DL | AVAIL_L | 0, // 9
++ AVAIL_L | AVAIL_UL | AVAIL_U | 0, // 10 (H)
++ AVAIL_L | AVAIL_UL | AVAIL_U | 0, // 11
++ AVAIL_L | AVAIL_UL | AVAIL_U | FILTER_LIGHT, // 12
++ AVAIL_L | AVAIL_UL | AVAIL_U | FILTER_LIGHT, // 13
++ AVAIL_L | AVAIL_UL | AVAIL_U | FILTER_LIGHT, // 14
++ AVAIL_L | AVAIL_UL | AVAIL_U | FILTER_LIGHT, // 15
++ AVAIL_L | AVAIL_UL | AVAIL_U | FILTER_LIGHT, // 16
++ AVAIL_L | AVAIL_UL | AVAIL_U | FILTER_LIGHT, // 17
++ AVAIL_L | AVAIL_UL | AVAIL_U | FILTER_LIGHT, // 18
++ AVAIL_L | AVAIL_UL | AVAIL_U | FILTER_LIGHT, // 19
++ AVAIL_L | AVAIL_UL | AVAIL_U | FILTER_LIGHT, // 20
++ AVAIL_L | AVAIL_UL | AVAIL_U | FILTER_LIGHT, // 21
++ AVAIL_L | AVAIL_UL | AVAIL_U | FILTER_LIGHT, // 22
++ AVAIL_L | AVAIL_UL | AVAIL_U | FILTER_LIGHT, // 23
++ AVAIL_L | AVAIL_UL | AVAIL_U | FILTER_LIGHT, // 24
++ AVAIL_L | AVAIL_UL | AVAIL_U | 0, // 25
++ AVAIL_L | AVAIL_UL | AVAIL_U | 0, // 26 (V)
++ AVAIL_U | AVAIL_UR | 0, // 27
++ AVAIL_U | AVAIL_UR | FILTER_LIGHT, // 28
++ AVAIL_U | AVAIL_UR | FILTER_LIGHT, // 29
++ AVAIL_U | AVAIL_UR | FILTER_LIGHT, // 30
++ AVAIL_U | AVAIL_UR | FILTER_LIGHT, // 31
++ AVAIL_U | AVAIL_UR | FILTER_LIGHT, // 32
++ AVAIL_U | AVAIL_UR | FILTER_LIGHT, // 33
++ AVAIL_U | AVAIL_UR | FILTER_LIGHT // 34
++},
++{ // 5
++ AVAIL_DL | AVAIL_L | 0 | AVAIL_U | AVAIL_UR | FILTER_EITHER, // Planar (DL[0] & UR[0] only needed)
++ AVAIL_L | 0 | AVAIL_U, // DC
++ AVAIL_DL | AVAIL_L | FILTER_EITHER, // 2
++ AVAIL_DL | AVAIL_L | FILTER_EITHER, // 3
++ AVAIL_DL | AVAIL_L | FILTER_EITHER, // 4
++ AVAIL_DL | AVAIL_L | FILTER_EITHER, // 5
++ AVAIL_DL | AVAIL_L | FILTER_EITHER, // 6
++ AVAIL_DL | AVAIL_L | FILTER_EITHER, // 7
++ AVAIL_DL | AVAIL_L | FILTER_EITHER, // 8
++ AVAIL_DL | AVAIL_L | FILTER_EITHER, // 9
++ AVAIL_L | 0, // 10 (H)
++ AVAIL_L | AVAIL_UL | AVAIL_U | FILTER_EITHER, // 11
++ AVAIL_L | AVAIL_UL | AVAIL_U | FILTER_EITHER, // 12
++ AVAIL_L | AVAIL_UL | AVAIL_U | FILTER_EITHER, // 13
++ AVAIL_L | AVAIL_UL | AVAIL_U | FILTER_EITHER, // 14
++ AVAIL_L | AVAIL_UL | AVAIL_U | FILTER_EITHER, // 15
++ AVAIL_L | AVAIL_UL | AVAIL_U | FILTER_EITHER, // 16
++ AVAIL_L | AVAIL_UL | AVAIL_U | FILTER_EITHER, // 17
++ AVAIL_L | AVAIL_UL | AVAIL_U | FILTER_EITHER, // 18
++ AVAIL_L | AVAIL_UL | AVAIL_U | FILTER_EITHER, // 19
++ AVAIL_L | AVAIL_UL | AVAIL_U | FILTER_EITHER, // 20
++ AVAIL_L | AVAIL_UL | AVAIL_U | FILTER_EITHER, // 21
++ AVAIL_L | AVAIL_UL | AVAIL_U | FILTER_EITHER, // 22
++ AVAIL_L | AVAIL_UL | AVAIL_U | FILTER_EITHER, // 23
++ AVAIL_L | AVAIL_UL | AVAIL_U | FILTER_EITHER, // 24
++ AVAIL_L | AVAIL_UL | AVAIL_U | FILTER_EITHER, // 25
++ AVAIL_U | 0, // 26 (V)
++ AVAIL_U | AVAIL_UR | FILTER_EITHER, // 27
++ AVAIL_U | AVAIL_UR | FILTER_EITHER, // 28
++ AVAIL_U | AVAIL_UR | FILTER_EITHER, // 29
++ AVAIL_U | AVAIL_UR | FILTER_EITHER, // 30
++ AVAIL_U | AVAIL_UR | FILTER_EITHER, // 31
++ AVAIL_U | AVAIL_UR | FILTER_EITHER, // 32
++ AVAIL_U | AVAIL_UR | FILTER_EITHER, // 33
++ AVAIL_U | AVAIL_UR | FILTER_EITHER // 34
++}
++};
++
++
++#endif
++
++#define filter_light1 FUNC(filter_light1)
++static inline pixel filter_light1(pixel a, pixel b, pixel c)
++{
++ return (a + b*2 + c + 2) >> 2;
++}
++
++#define filter_light FUNC(filter_light)
++static inline void filter_light(pixel * dst, pixel p1, const pixel * src, const pixel pn, const int sstride, const unsigned int n)
++{
++ pixel p0;
++ pixel p2 = *src;
++ // Allow for final pel - it is just clearer to to have the call take the actual number of output pels
++ unsigned int n_minus_1 = n - 1;
++
++ do
++ {
++ src += sstride;
++ p0 = p1;
++ p1 = p2;
++ p2 = *src;
++ *dst++ = filter_light1(p0, p1, p2);
++ } while (--n_minus_1 != 0);
++ *dst = filter_light1(p1, p2, pn);
++}
++
++#define filter_strong FUNC(filter_strong)
++static inline void filter_strong(pixel * dst, const unsigned int p0, const unsigned int p1, unsigned int n)
++{
++ unsigned int a = 64 * p0 + 32;
++ const int v = p1 - p0;
++
++ do
++ {
++ *dst++ = (a += v) >> 6;
++ } while (--n != 0);
++}
++
++#define intra_filter FUNC(intra_filter)
++static av_always_inline void intra_filter(
++ pixel * const left, pixel * const top,
++ const unsigned int req, const unsigned int avail,
++ const pixel * const src_l, const pixel * const src_u, const pixel * const src_ur,
++ const unsigned int stride,
++ const unsigned int top_right_size, const unsigned int down_left_size,
++ const unsigned int log2_size)
++{
++ const unsigned int strong_threshold = 1 << (BIT_DEPTH - 5);
++ const unsigned int size = 1 << log2_size;
++
++ // a_ is the first pel in a section working round dl -> ur
++ // b_ is the last
++ // Beware that top & left work out from UL so usage of a_ & b_ may
++ // swap between them. It is a bad naming scheme but I have found no
++ // better
++ const pixel * a_dl = src_l + (down_left_size + size - 1) * stride;
++ const pixel * b_dl = src_l + size * stride;
++ const pixel * a_l = src_l + (size - 1) * stride;
++ const pixel * b_l = src_l;
++ const pixel * ab_ul = src_l - stride;
++ const pixel * a_u = src_u;
++ const pixel * b_u = src_u + size - 1;
++ const pixel * a_ur = src_ur;
++ const pixel * b_ur = src_ur + top_right_size - 1;
++
++ const unsigned int want = req & ~avail;
++ const unsigned int have = req & avail;
++ unsigned int i;
++
++ if ((avail & AVAIL_DL) == 0)
++ {
++ a_dl = a_ur;
++ if ((avail & AVAIL_U) != 0)
++ a_dl = a_u;
++ if ((avail & AVAIL_UL) != 0)
++ a_dl = ab_ul;
++ if ((avail & AVAIL_L) != 0)
++ a_dl = a_l;
++ b_dl = a_dl;
++ }
++
++ if ((avail & AVAIL_L) == 0)
++ {
++ a_l = b_dl;
++ b_l = b_dl;
++ }
++ if ((avail & AVAIL_UL) == 0)
++ {
++ ab_ul = b_l;
++ }
++ if ((avail & AVAIL_U) == 0)
++ {
++ a_u = ab_ul;
++ b_u = ab_ul;
++ }
++ if ((avail & AVAIL_UR) == 0)
++ {
++ a_ur = b_u;
++ b_ur = b_u;
++ }
++
++ if ((req & FILTER_LIGHT) == 0 || PRED_C || log2_size == 2) // PRED_C, log2_size compiler opt hints
++ {
++ if ((req & AVAIL_UL) != 0)
++ left[-1] = *ab_ul;
++
++ if ((want & AVAIL_L) != 0)
++ EXTEND(left, *a_l, size);
++ if ((want & AVAIL_DL) != 0)
++ EXTEND(left + size, *a_dl, size);
++ if ((want & AVAIL_U) != 0)
++ EXTEND(top, *a_u, size);
++ if ((want & AVAIL_UR) != 0)
++ EXTEND(top + size, *a_ur, size);
++
++ if ((have & AVAIL_U) != 0)
++ // Always good - even with sand
++ memcpy(top, a_u, size * sizeof(pixel));
++ if ((have & AVAIL_UR) != 0)
++ {
++ memcpy(top + size, a_ur, top_right_size * sizeof(pixel));
++ EXTEND(top + size + top_right_size, *b_ur,
++ size - top_right_size);
++ }
++ if ((have & AVAIL_L) != 0)
++ {
++ for (i = 0; i < size; i++)
++ left[i] = b_l[stride * i];
++ }
++ if ((have & AVAIL_DL) != 0)
++ {
++ for (i = 0; i < down_left_size; i++)
++ left[i + size] = b_dl[stride * i];
++ EXTEND(left + size + down_left_size, *a_dl,
++ size - down_left_size);
++ }
++ }
++ else if ((req & FILTER_STRONG) != 0 && log2_size == 5 && // log2_size compiler opt hint
++ FFABS((int)(*a_dl - *a_l * 2 + *ab_ul)) < strong_threshold &&
++ FFABS((int)(*ab_ul - *b_u * 2 + *b_ur)) < strong_threshold)
++ {
++ if ((req & (AVAIL_U | AVAIL_UR)) != 0)
++ filter_strong(top, *ab_ul, *b_ur, size * 2);
++ left[-1] = *ab_ul;
++ if ((req & (AVAIL_L | AVAIL_DL)) != 0)
++ filter_strong(left, *ab_ul, *a_dl, size*2);
++ }
++ else
++ {
++ // Same code for both have & want for UL
++ if ((req & AVAIL_UL) != 0)
++ {
++ left[-1] = filter_light1(*b_l, *ab_ul, *a_u);
++ }
++
++ if ((want & AVAIL_L) != 0)
++ {
++ EXTEND(left, *a_l, size);
++ left[0] = (*a_l * 3 + *ab_ul + 2) >> 2;
++ }
++ if ((want & AVAIL_DL) != 0)
++ {
++ // If we want DL then it cannot be avail so a_dl = a_l so no edge rounding
++ EXTEND(left + size, *a_l, size);
++ }
++ if ((want & AVAIL_U) != 0)
++ {
++ EXTEND(top, *a_u, size);
++ top[size - 1] = (*a_u * 3 + *a_ur + 2) >> 2;
++ }
++ if ((want & AVAIL_UR) != 0)
++ {
++ // If we want UR then it cannot be avail so a_ur = b_u so no edge rounding
++ EXTEND(top + size, *a_ur, size);
++ }
++
++ if ((have & AVAIL_U) != 0)
++ {
++ filter_light(top, *ab_ul, a_u, *a_ur, 1, size);
++ }
++ if ((have & AVAIL_UR) != 0) {
++ filter_light(top + size, *b_u, a_ur, *b_ur, 1, top_right_size);
++ top[size*2 - 1] = *b_ur;
++ EXTEND(top + size + top_right_size, *b_ur, size - top_right_size);
++ }
++ if ((have & AVAIL_L) != 0)
++ {
++ filter_light(left, *ab_ul, b_l, *b_dl, stride, size);
++ }
++ if ((have & AVAIL_DL) != 0)
++ {
++ filter_light(left + size, *a_l, b_dl, *a_dl, stride, down_left_size);
++ left[size*2 - 1] = *a_dl;
++ EXTEND(left + size + down_left_size, *a_dl, size - down_left_size);
++ }
++ }
++}
++
++#define INTRA_FILTER(log2_size) \
++static void FUNC(intra_filter_ ## log2_size)( \
++ uint8_t * const left, uint8_t * const top, \
++ const unsigned int req, const unsigned int avail, \
++ const uint8_t * const src_l, const uint8_t * const src_u, const uint8_t * const src_ur, \
++ const unsigned int stride, \
++ const unsigned int top_right_size, const unsigned int down_left_size) \
++{ \
++ intra_filter((pixel *)left, (pixel *)top, req, avail, \
++ (const pixel *)src_l, (const pixel *)src_u, (const pixel *)src_ur, stride / sizeof(pixel), top_right_size, down_left_size, log2_size); \
++}
++
++INTRA_FILTER(2)
++INTRA_FILTER(3)
++INTRA_FILTER(4)
++INTRA_FILTER(5)
++
++#undef intra_filter
++#undef INTRA_FILTER
++
++static av_always_inline void FUNC(intra_pred)(const HEVCRpiContext * const s,
++ const enum IntraPredMode mode, const unsigned int x0, const unsigned int y0, const unsigned int avail,
++ const unsigned int log2_size)
++{
++ // c_idx will alaways be 1 for _c versions and 0 for y
++ const unsigned int c_idx = PRED_C;
++ const unsigned int hshift = ctx_hshift(s, c_idx);
++ const unsigned int vshift = ctx_vshift(s, c_idx);
++ const unsigned int size = (1 << log2_size);
++ const unsigned int x = x0 >> hshift;
++ const unsigned int y = y0 >> vshift;
++
++ const ptrdiff_t stride = frame_stride1(s->frame, c_idx) / sizeof(pixel);
++ pixel *const src = c_idx == 0 ?
++ (pixel *)av_rpi_sand_frame_pos_y(s->frame, x, y) :
++ (pixel *)av_rpi_sand_frame_pos_c(s->frame, x, y);
++
++ // Align so we can do multiple loads in the asm
++ // Padded to 16 byte boundary so as not to confuse anything
++ DECLARE_ALIGNED(16, pixel, left_array[2 * MAX_TB_SIZE + 16 / sizeof(pixel)]);
++ DECLARE_ALIGNED(16, pixel, top_array[2 * MAX_TB_SIZE + 16 / sizeof(pixel)]);
++
++ pixel * const left = left_array + 16 / sizeof(pixel);
++ pixel * const top = top_array + 16 / sizeof(pixel);
++ const pixel * top_pred = top;
++
++ const pixel * src_l = src - 1;
++ const pixel * src_u = src - stride;
++ const pixel * src_ur = src_u + size;
++#if !PRED_C
++ unsigned int req = req_avail[log2_size - 2][mode];
++#else
++ unsigned int req = req_avail_c[mode];
++#endif
++
++ // If we have nothing to pred from then fill with grey
++ // This isn't a common case but dealing with it here means we don't have to
++ // test for it later
++ if (avail == 0)
++ {
++dc_only:
++#if !PRED_C
++ s->hpc.pred_dc0[log2_size - 2]((uint8_t *)src, stride);
++#else
++ s->hpc.pred_dc0_c[log2_size - 2]((uint8_t *)src, stride);
++#endif
++ return;
++ }
++
++ // There will be no filtering on C so no point worrying about disabling it
++#if !PRED_C
++ if (s->ps.sps->intra_smoothing_disabled_flag)
++ req &= ~FILTER_EITHER;
++ if (!s->ps.sps->sps_strong_intra_smoothing_enable_flag)
++ req &= ~FILTER_STRONG;
++#endif
++
++ {
++ // N.B. stride is in pixels (not bytes) or in the case of chroma pixel-pairs
++ const AVFrame * const frame = s->frame;
++ const unsigned int mask = stride - 1; // For chroma pixel=uint16 so stride_c is stride_y / 2
++ const unsigned int stripe_adj = (av_rpi_sand_frame_stride2(frame) - 1) * stride;
++ if ((x & mask) == 0)
++ src_l -= stripe_adj;
++ if (((x + size) & mask) == 0)
++ src_ur += stripe_adj;
++ }
++
++ // Can deal with I-slices in 'normal' code even if CIP
++ // This also means that we don't need to generate (elsewhere) is_intra
++ // for IRAP frames
++ if (s->ps.pps->constrained_intra_pred_flag == 1 &&
++ s->sh.slice_type != HEVC_SLICE_I)
++ {
++ // * If we ever actually care about CIP performance then we should
++ // special case out size 4 stuff (can be done by 'normal') and
++ // have 8-pel avail masks
++ unsigned int avail_l = cip_avail_l(s->is_intra + ((y + size * 2 - 1) >> (3 - vshift)) * s->ps.sps->pcm_width + ((x - 1) >> (6 - hshift)),
++ -(int)(s->ps.sps->pcm_width),
++ 1 << (((x - 1) >> (3 - hshift)) & 7),
++ 1 - hshift,
++ avail,
++ size,
++ FFMIN(size, ((s->ps.sps->height - y0) >> vshift) - size),
++ vshift != 0 ? 0 : (y >> 2) & 1);
++
++ unsigned int avail_u = cip_avail_u(s->is_intra + ((y - 1) >> (3 - vshift)) * s->ps.sps->pcm_width + (x >> (6 - hshift)),
++ (x >> (3 - hshift)) & 7,
++ 1 - hshift,
++ avail,
++ size,
++ FFMIN(size, ((s->ps.sps->width - x0) >> hshift) - size),
++ hshift != 0 ? 0 : (x >> 2) & 1);
++
++ // Anything left?
++ if ((avail_l | avail_u) == 0)
++ goto dc_only;
++
++ FUNC(cip_fill)(left, top, avail_l, avail_u, src_l, src_u, src_ur, stride, size);
++
++#if !PRED_C
++ if ((req & FILTER_LIGHT) != 0)
++ {
++ const unsigned threshold = 1 << (BIT_DEPTH - 5);
++ if ((req & FILTER_STRONG) != 0 &&
++ (int)(FFABS(left[-1] + top[63] - 2 * top[31])) < threshold &&
++ (int)(FFABS(left[-1] + left[63] - 2 * left[31])) < threshold)
++ {
++ filter_strong(top, left[-1], top[63], 64);
++ filter_strong(left, left[-1], left[63], 64);
++ } else
++ {
++ // LHS writes UL too so copy for top
++ const pixel p_ul = left[-1];
++ filter_light(left - 1, top[0], left - 1, left[2*size - 1], 1, 2*size);
++ filter_light(top, p_ul, top, top[2*size - 1], 1, 2*size - 1);
++ }
++ }
++#endif
++ }
++ else
++ {
++ const unsigned int ur_size = FFMIN(size, ((s->ps.sps->width - x0) >> hshift) - size);
++ if ((req & ~((AVAIL_UR | AVAIL_U) & avail)) == 0 &&
++ ((req & AVAIL_UR) == 0 || src_u + 2*size == src_ur + ur_size))
++ {
++ top_pred = src_u;
++ }
++ else
++ {
++#if !PRED_C
++ s->hpc.intra_filter[log2_size - 2]
++#else
++ s->hpc.intra_filter_c[log2_size - 2]
++#endif
++ ((uint8_t *)left, (uint8_t *)top, req, avail,
++ (const uint8_t *)src_l, (const uint8_t *)src_u, (const uint8_t *)src_ur, stride * sizeof(pixel),
++ ur_size,
++ FFMIN(size, ((s->ps.sps->height - y0) >> vshift) - size));
++ }
++ }
++
++
++#if !PRED_C
++ switch (mode) {
++ case INTRA_PLANAR:
++ s->hpc.pred_planar[log2_size - 2]((uint8_t *)src, (uint8_t *)top_pred,
++ (uint8_t *)left, stride);
++ break;
++ case INTRA_DC:
++ s->hpc.pred_dc[log2_size - 2]((uint8_t *)src, (uint8_t *)top_pred,
++ (uint8_t *)left, stride);
++ break;
++ case INTRA_ANGULAR_HORIZONTAL:
++ s->hpc.pred_horizontal[log2_size - 2]((uint8_t *)src, (uint8_t *)top_pred,
++ (uint8_t *)left, stride,
++ mode);
++ break;
++ case INTRA_ANGULAR_VERTICAL:
++ s->hpc.pred_vertical[log2_size - 2]((uint8_t *)src, (uint8_t *)top_pred,
++ (uint8_t *)left, stride,
++ mode);
++ break;
++ default:
++ s->hpc.pred_angular[log2_size - 2]((uint8_t *)src, (uint8_t *)top_pred,
++ (uint8_t *)left, stride,
++ mode);
++ break;
++ }
++#else
++ switch (mode) {
++ case INTRA_PLANAR:
++ s->hpc.pred_planar_c[log2_size - 2]((uint8_t *)src, (uint8_t *)top_pred,
++ (uint8_t *)left, stride);
++ break;
++ case INTRA_DC:
++ s->hpc.pred_dc_c[log2_size - 2]((uint8_t *)src, (uint8_t *)top_pred,
++ (uint8_t *)left, stride);
++ break;
++ case INTRA_ANGULAR_HORIZONTAL:
++ s->hpc.pred_horizontal_c[log2_size - 2]((uint8_t *)src, (uint8_t *)top_pred,
++ (uint8_t *)left, stride,
++ mode);
++ break;
++ case INTRA_ANGULAR_VERTICAL:
++ s->hpc.pred_vertical_c[log2_size - 2]((uint8_t *)src, (uint8_t *)top_pred,
++ (uint8_t *)left, stride,
++ mode);
++ break;
++ default:
++ s->hpc.pred_angular_c[log2_size - 2]((uint8_t *)src, (uint8_t *)top_pred,
++ (uint8_t *)left, stride,
++ mode);
++ break;
++ }
++
++#if DUMP_PRED
++ printf("U pred @ %d, %d: mode=%d\n", x, y, mode);
++ dump_pred_uv((uint8_t *)src, stride, 1 << log2_size);
++ printf("V pred @ %d, %d: mode=%d\n", x, y, mode);
++ dump_pred_uv((uint8_t *)src + 1, stride, 1 << log2_size);
++#endif
++#endif
++}
++
++#define INTRA_PRED(log2_size) \
++static void FUNC(intra_pred_ ## log2_size)(const struct HEVCRpiContext * const s, \
++ const enum IntraPredMode mode, const unsigned int x0, const unsigned int y0, const unsigned int avail) \
++{ \
++ FUNC(intra_pred)(s, mode, x0, y0, avail, log2_size); \
++}
++
++INTRA_PRED(2)
++INTRA_PRED(3)
++INTRA_PRED(4)
++INTRA_PRED(5)
++
++#undef INTRA_PRED
++
++#if !PRED_C
++static av_always_inline void FUNC(pred_planar)(uint8_t *_src, const uint8_t *_top,
++ const uint8_t *_left, ptrdiff_t stride,
++ int trafo_size)
++{
++ int x, y;
++ pixel *src = (pixel *)_src;
++ const pixel *top = (const pixel *)_top;
++ const pixel *left = (const pixel *)_left;
++ int size = 1 << trafo_size;
++ for (y = 0; y < size; y++)
++ for (x = 0; x < size; x++)
++ POS(x, y) = ((size - 1 - x) * left[y] + (x + 1) * top[size] +
++ (size - 1 - y) * top[x] + (y + 1) * left[size] + size) >> (trafo_size + 1);
++}
++#else
++static av_always_inline void FUNC(pred_planar)(uint8_t * _src, const uint8_t * _top,
++ const uint8_t * _left, ptrdiff_t stride,
++ int trafo_size)
++{
++ int x, y;
++ int size = 1 << trafo_size;
++ c_dst_ptr_t src = (c_dst_ptr_t)_src;
++ const c_src_ptr_t top = (c_src_ptr_t)_top;
++ const c_src_ptr_t left = (c_src_ptr_t)_left;
++
++ for (y = 0; y < size; y++, src += stride)
++ {
++ for (x = 0; x < size; x++)
++ {
++ src[x][0] = ((size - 1 - x) * left[y][0] + (x + 1) * top[size][0] +
++ (size - 1 - y) * top[x][0] + (y + 1) * left[size][0] + size) >> (trafo_size + 1);
++ src[x][1] = ((size - 1 - x) * left[y][1] + (x + 1) * top[size][1] +
++ (size - 1 - y) * top[x][1] + (y + 1) * left[size][1] + size) >> (trafo_size + 1);
++ }
++ }
++}
++#endif
++
++#define PRED_PLANAR(size)\
++static void FUNC(pred_planar_ ## size)(uint8_t *src, const uint8_t *top, \
++ const uint8_t *left, ptrdiff_t stride) \
++{ \
++ FUNC(pred_planar)(src, top, left, stride, size + 2); \
++}
++
++PRED_PLANAR(0)
++PRED_PLANAR(1)
++PRED_PLANAR(2)
++PRED_PLANAR(3)
++
++#undef PRED_PLANAR
++
++#if !PRED_C
++static void FUNC(pred_dc)(uint8_t *_src, const uint8_t *_top,
++ const uint8_t *_left,
++ ptrdiff_t stride, int log2_size)
++{
++ int i, j, x, y;
++ int size = (1 << log2_size);
++ pixel *src = (pixel *)_src;
++ const pixel *top = (const pixel *)_top;
++ const pixel *left = (const pixel *)_left;
++ int dc = size;
++ pixel4 a;
++ for (i = 0; i < size; i++)
++ dc += left[i] + top[i];
++
++ dc >>= log2_size + 1;
++
++ a = PIXEL_SPLAT_X4(dc);
++
++ for (i = 0; i < size; i++)
++ for (j = 0; j < size; j+=4)
++ AV_WN4P(&POS(j, i), a);
++
++// if (c_idx == 0 && size < 32)
++// As we now have separate fns for y & c - no need to test that
++ if (size < 32)
++ {
++ POS(0, 0) = (left[0] + 2 * dc + top[0] + 2) >> 2;
++ for (x = 1; x < size; x++)
++ POS(x, 0) = (top[x] + 3 * dc + 2) >> 2;
++ for (y = 1; y < size; y++)
++ POS(0, y) = (left[y] + 3 * dc + 2) >> 2;
++ }
++}
++#else
++static void FUNC(pred_dc)(uint8_t *_src, const uint8_t *_top,
++ const uint8_t *_left,
++ ptrdiff_t stride, int log2_size)
++{
++ unsigned int i, j;
++ const unsigned int size = (1 << log2_size);
++ c_dst_ptr_t src = (c_dst_ptr_t)_src;
++ const c_src_ptr_t top = (c_src_ptr_t)_top;
++ const c_src_ptr_t left = (c_src_ptr_t)_left;
++ unsigned int dc0 = size;
++ unsigned int dc1 = size;
++
++ for (i = 0; i < size; i++)
++ {
++ dc0 += left[i][0] + top[i][0];
++ dc1 += left[i][1] + top[i][1];
++ }
++
++ dc0 >>= log2_size + 1;
++ dc1 >>= log2_size + 1;
++
++ for (i = 0; i < size; i++, src += stride)
++ {
++ for (j = 0; j < size; ++j)
++ {
++ src[j][0] = dc0;
++ src[j][1] = dc1;
++
++ }
++ }
++}
++#endif
++
++#define PRED_DC(size)\
++static void FUNC(pred_dc_ ## size)(uint8_t *src, const uint8_t *top, \
++ const uint8_t *left, ptrdiff_t stride) \
++{ \
++ FUNC(pred_dc)(src, top, left, stride, size + 2); \
++}
++
++PRED_DC(0)
++PRED_DC(1)
++PRED_DC(2)
++PRED_DC(3)
++
++#undef PRED_DC
++
++
++
++
++#if !PRED_C
++static void FUNC(pred_dc0)(uint8_t *_src, ptrdiff_t stride, int log2_size)
++{
++ int i, j;
++ int size = (1 << log2_size);
++ pixel *src = (pixel *)_src;
++ pixel4 a = PIXEL_SPLAT_X4(1 << (BIT_DEPTH - 1));
++
++ for (i = 0; i < size; i++)
++ for (j = 0; j < size; j+=4)
++ AV_WN4P(&POS(j, i), a);
++}
++#else
++static void FUNC(pred_dc0)(uint8_t *_src, ptrdiff_t stride, int log2_size)
++{
++ unsigned int i, j;
++ const unsigned int size = (1 << log2_size);
++ c_dst_ptr_t src = (c_dst_ptr_t)_src;
++ const pixel a = (1 << (BIT_DEPTH - 1));
++
++ for (i = 0; i < size; i++, src += stride)
++ {
++ for (j = 0; j < size; ++j)
++ {
++ src[j][0] = a;
++ src[j][1] = a;
++ }
++ }
++}
++#endif
++
++#define PRED_DC0(size)\
++static void FUNC(pred_dc0_ ## size)(uint8_t *src, ptrdiff_t stride) \
++{ \
++ FUNC(pred_dc0)(src, stride, size + 2); \
++}
++
++PRED_DC0(0)
++PRED_DC0(1)
++PRED_DC0(2)
++PRED_DC0(3)
++
++#undef PRED_DC0
++
++
++
++
++#ifndef ANGLE_CONSTS
++#define ANGLE_CONSTS
++static const int intra_pred_angle[] = {
++ 32, 26, 21, 17, 13, 9, 5, 2, 0, -2, -5, -9, -13, -17, -21, -26, -32,
++ -26, -21, -17, -13, -9, -5, -2, 0, 2, 5, 9, 13, 17, 21, 26, 32
++};
++static const int inv_angle[] = {
++ -4096, -1638, -910, -630, -482, -390, -315, -256, -315, -390, -482,
++ -630, -910, -1638, -4096
++};
++#endif
++
++#if !PRED_C
++static av_always_inline void FUNC(pred_angular)(uint8_t *_src,
++ const uint8_t *_top,
++ const uint8_t *_left,
++ ptrdiff_t stride,
++ int mode, int size)
++{
++ int x, y;
++ pixel *src = (pixel *)_src;
++ const pixel *top = (const pixel *)_top;
++ const pixel *left = (const pixel *)_left;
++
++ int angle = intra_pred_angle[mode - 2];
++ pixel ref_array[3 * MAX_TB_SIZE + 4];
++ pixel *ref_tmp = ref_array + size;
++ const pixel *ref;
++ int last = (size * angle) >> 5;
++
++ if (mode >= 18) {
++ ref = top - 1;
++ if (angle < 0 && last < -1) {
++ for (x = 0; x <= size; x += 4)
++ AV_WN4P(&ref_tmp[x], AV_RN4P(&top[x - 1]));
++ for (x = last; x <= -1; x++)
++ ref_tmp[x] = left[-1 + ((x * inv_angle[mode - 11] + 128) >> 8)];
++ ref = ref_tmp;
++ }
++
++ for (y = 0; y < size; y++) {
++ int idx = ((y + 1) * angle) >> 5;
++ int fact = ((y + 1) * angle) & 31;
++ if (fact) {
++ for (x = 0; x < size; x += 4) {
++ POS(x , y) = ((32 - fact) * ref[x + idx + 1] +
++ fact * ref[x + idx + 2] + 16) >> 5;
++ POS(x + 1, y) = ((32 - fact) * ref[x + 1 + idx + 1] +
++ fact * ref[x + 1 + idx + 2] + 16) >> 5;
++ POS(x + 2, y) = ((32 - fact) * ref[x + 2 + idx + 1] +
++ fact * ref[x + 2 + idx + 2] + 16) >> 5;
++ POS(x + 3, y) = ((32 - fact) * ref[x + 3 + idx + 1] +
++ fact * ref[x + 3 + idx + 2] + 16) >> 5;
++ }
++ } else {
++ for (x = 0; x < size; x += 4)
++ AV_WN4P(&POS(x, y), AV_RN4P(&ref[x + idx + 1]));
++ }
++ }
++// if (mode == 26 && c_idx == 0 && size < 32) {
++ if (mode == 26 && size < 32) {
++ for (y = 0; y < size; y++)
++ POS(0, y) = av_clip_pixel(top[0] + ((left[y] - left[-1]) >> 1));
++ }
++
++ } else {
++ ref = left - 1;
++ if (angle < 0 && last < -1) {
++ for (x = 0; x <= size; x += 4)
++ AV_WN4P(&ref_tmp[x], AV_RN4P(&left[x - 1]));
++ for (x = last; x <= -1; x++)
++ ref_tmp[x] = top[-1 + ((x * inv_angle[mode - 11] + 128) >> 8)];
++ ref = ref_tmp;
++ }
++
++ for (x = 0; x < size; x++) {
++ int idx = ((x + 1) * angle) >> 5;
++ int fact = ((x + 1) * angle) & 31;
++ if (fact) {
++ for (y = 0; y < size; y++) {
++ POS(x, y) = ((32 - fact) * ref[y + idx + 1] +
++ fact * ref[y + idx + 2] + 16) >> 5;
++ }
++ } else {
++ for (y = 0; y < size; y++)
++ POS(x, y) = ref[y + idx + 1];
++ }
++ }
++// if (mode == 10 && c_idx == 0 && size < 32) {
++ if (mode == 10 && size < 32) {
++ for (x = 0; x < size; x += 4) {
++ POS(x, 0) = av_clip_pixel(left[0] + ((top[x ] - top[-1]) >> 1));
++ POS(x + 1, 0) = av_clip_pixel(left[0] + ((top[x + 1] - top[-1]) >> 1));
++ POS(x + 2, 0) = av_clip_pixel(left[0] + ((top[x + 2] - top[-1]) >> 1));
++ POS(x + 3, 0) = av_clip_pixel(left[0] + ((top[x + 3] - top[-1]) >> 1));
++ }
++ }
++ }
++
++
++
++#if BIT_DEPTH == 8 && 0
++ if ((size == 16 || size == 32) && mode != 10 && mode != 26) {
++ DECLARE_ALIGNED(16, uint8_t, a[64*32]);
++ void ff_hevc_rpi_pred_angular_16_neon_8(uint8_t *src, const uint8_t *top, const uint8_t *left, ptrdiff_t stride, int mode);
++// void ff_hevc_rpi_pred_angular_32_neon_10(uint8_t *src, const uint8_t *top, const uint8_t *left, ptrdiff_t stride, int mode);
++#if 1
++ src = (pixel *)_src;
++ printf("C: Mode=%d\n", mode);
++ for (y = 0; y < size; y++, src += stride)
++ {
++ printf("%2d: ", y);
++ for (x = 0; x < size; x++)
++ {
++ printf("%3x ", src[x]);
++ }
++ printf("\n");
++ }
++#endif
++// ff_hevc_rpi_pred_vertical_16_neon_8(a, _top, _left, size);
++ memset(a, 0, sizeof(a));
++// ff_hevc_rpi_pred_angular_32_neon_10(a, _top, _left, size, mode);
++ ff_hevc_rpi_pred_angular_16_neon_8(a, _top, _left, size, mode);
++#if 1
++ src = (pixel *)a;
++ printf("A:\n");
++ for (y = 0; y < size; y++, src += size)
++ {
++ printf("%2d: ", y);
++ for (x = 0; x < size; x++)
++ {
++ printf("%3x ", src[x]);
++ }
++ printf("\n");
++ }
++#endif
++ src = (pixel *)_src;
++ for (y = 0; y < size; y++, src += stride)
++ {
++ if (memcmp(src, a + size * sizeof(pixel) * y, size * sizeof(pixel)) != 0) {
++ printf("Fail at line %d\n", y);
++ av_assert0(0);
++ }
++ }
++ }
++#endif
++
++}
++#else
++static av_always_inline void FUNC(pred_angular)(uint8_t *_src,
++ const uint8_t *_top,
++ const uint8_t *_left,
++ ptrdiff_t stride,
++ int mode, int size)
++{
++ int x, y;
++ c_dst_ptr_t src = (c_dst_ptr_t)_src;
++ c_src_ptr_t top = (c_src_ptr_t)_top;
++ c_src_ptr_t left = (c_src_ptr_t)_left;
++
++ const int angle = intra_pred_angle[mode - 2];
++ cpel ref_array[3 * MAX_TB_SIZE + 4][2];
++ c_dst_ptr_t ref_tmp = ref_array + size;
++ c_src_ptr_t ref;
++ const int last = (size * angle) >> 5;
++
++ if (mode >= 18) {
++ ref = top - 1;
++ if (angle < 0 && last < -1) {
++ memcpy(ref_tmp, top - 1, (size + 1) * 2 * PW);
++ for (x = last; x <= -1; x++)
++ {
++ ref_tmp[x][0] = left[-1 + ((x * inv_angle[mode - 11] + 128) >> 8)][0];
++ ref_tmp[x][1] = left[-1 + ((x * inv_angle[mode - 11] + 128) >> 8)][1];
++ }
++ ref = (c_src_ptr_t)ref_tmp;
++ }
++
++ for (y = 0; y < size; y++, src += stride) {
++ const int idx = ((y + 1) * angle) >> 5;
++ const int fact = ((y + 1) * angle) & 31;
++ if (fact) {
++ for (x = 0; x < size; ++x) {
++ src[x][0] = ((32 - fact) * ref[x + idx + 1][0] +
++ fact * ref[x + idx + 2][0] + 16) >> 5;
++ src[x][1] = ((32 - fact) * ref[x + idx + 1][1] +
++ fact * ref[x + idx + 2][1] + 16) >> 5;
++ }
++ } else {
++ memcpy(src, ref + idx + 1, size * 2 * PW);
++ }
++ }
++ } else {
++ ref = left - 1;
++ if (angle < 0 && last < -1) {
++ memcpy(ref_tmp, left - 1, (size + 1) * 2 * PW);
++ for (x = last; x <= -1; x++)
++ {
++ ref_tmp[x][0] = top[-1 + ((x * inv_angle[mode - 11] + 128) >> 8)][0];
++ ref_tmp[x][1] = top[-1 + ((x * inv_angle[mode - 11] + 128) >> 8)][1];
++ }
++ ref = (c_src_ptr_t)ref_tmp;
++ }
++
++ for (x = 0; x < size; x++, src++) {
++ const int idx = ((x + 1) * angle) >> 5;
++ const int fact = ((x + 1) * angle) & 31;
++ if (fact) {
++ for (y = 0; y < size; y++) {
++ src[y * stride][0] = ((32 - fact) * ref[y + idx + 1][0] +
++ fact * ref[y + idx + 2][0] + 16) >> 5;
++ src[y * stride][1] = ((32 - fact) * ref[y + idx + 1][1] +
++ fact * ref[y + idx + 2][1] + 16) >> 5;
++ }
++ } else {
++ for (y = 0; y < size; y++)
++ {
++ src[y * stride][0] = ref[y + idx + 1][0];
++ src[y * stride][1] = ref[y + idx + 1][1];
++ }
++ }
++ }
++ }
++
++#if BIT_DEPTH == 10 && 0
++ if (size == 16 && mode != 10 && mode != 26) {
++ DECLARE_ALIGNED(16, uint8_t, a[64*32]);
++// void ff_hevc_rpi_pred_vertical_16_neon_8(uint8_t *src, const uint8_t *top, const uint8_t *left, ptrdiff_t stride);
++ void ff_hevc_rpi_pred_angular_c_16_neon_10(uint8_t *src, const uint8_t *top, const uint8_t *left, ptrdiff_t stride, int mode);
++
++ src = (c_dst_ptr_t)_src;
++ printf("C: mode=%d\n", mode);
++ for (y = 0; y < size; y++, src += stride)
++ {
++ for (x = 0; x < size; x++)
++ {
++ printf("%3x:%3x ", src[x][0], src[x][1]);
++ }
++ printf("\n");
++ }
++
++ memset(a, 0, sizeof(a));
++ ff_hevc_rpi_pred_angular_c_16_neon_10(a, _top, _left, size, mode);
++
++ src = (c_dst_ptr_t)a;
++ printf("A:\n");
++ for (y = 0; y < size; y++, src += size)
++ {
++ for (x = 0; x < size; x++)
++ {
++ printf("%3x:%3x ", src[x][0], src[x][1]);
++ }
++ printf("\n");
++ }
++
++ src = (c_dst_ptr_t)_src;
++ for (y = 0; y < size; y++, src += stride)
++ {
++ if (memcmp(src, a + size * sizeof(pixel) * y, size * sizeof(pixel)) != 0) {
++ printf("Fail at line %d\n", y);
++ av_assert0(0);
++ }
++ }
++
++ }
++#endif
++}
++#endif
++
++static void FUNC(pred_angular_0)(uint8_t *src, const uint8_t *top,
++ const uint8_t *left,
++ ptrdiff_t stride, int mode)
++{
++ FUNC(pred_angular)(src, top, left, stride, mode, 1 << 2);
++}
++
++static void FUNC(pred_angular_1)(uint8_t *src, const uint8_t *top,
++ const uint8_t *left,
++ ptrdiff_t stride, int mode)
++{
++ FUNC(pred_angular)(src, top, left, stride, mode, 1 << 3);
++}
++
++static void FUNC(pred_angular_2)(uint8_t *src, const uint8_t *top,
++ const uint8_t *left,
++ ptrdiff_t stride, int mode)
++{
++ FUNC(pred_angular)(src, top, left, stride, mode, 1 << 4);
++}
++
++static void FUNC(pred_angular_3)(uint8_t *src, const uint8_t *top,
++ const uint8_t *left,
++ ptrdiff_t stride, int mode)
++{
++ FUNC(pred_angular)(src, top, left, stride, mode, 1 << 5);
++}
++
++#undef cpel
++#undef c_src_ptr_t
++#undef c_dst_ptr_t
++
++#undef EXTEND
++#undef POS
++#undef PW
++
++#undef filter_light1
++#undef filter_light
++#undef filter_strong
++#undef ref_gen
++
++#ifndef INCLUDED_ONCE
++#define INCLUDED_ONCE
++#endif
++
+diff --git a/libavcodec/rpi_mailbox.c b/libavcodec/rpi_mailbox.c
+new file mode 100644
+index 0000000000..20f218f22c
+--- /dev/null
++++ b/libavcodec/rpi_mailbox.c
+@@ -0,0 +1,107 @@
++/*
++Copyright (c) 2012, Broadcom Europe Ltd.
++All rights reserved.
++
++Redistribution and use in source and binary forms, with or without
++modification, are permitted provided that the following conditions are met:
++ * Redistributions of source code must retain the above copyright
++ notice, this list of conditions and the following disclaimer.
++ * Redistributions in binary form must reproduce the above copyright
++ notice, this list of conditions and the following disclaimer in the
++ documentation and/or other materials provided with the distribution.
++ * Neither the name of the copyright holder nor the
++ names of its contributors may be used to endorse or promote products
++ derived from this software without specific prior written permission.
++
++THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND
++ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED
++WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE
++DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT HOLDER OR CONTRIBUTORS BE LIABLE FOR ANY
++DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES
++(INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES;
++LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND
++ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
++(INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS
++SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
++*/
++
++#include <stdio.h>
++#include <string.h>
++#include <stdlib.h>
++#include <fcntl.h>
++#include <unistd.h>
++#include <assert.h>
++#include <stdint.h>
++#include <sys/ioctl.h>
++
++#include <linux/ioctl.h>
++
++#define MAJOR_NUM 100
++#define IOCTL_MBOX_PROPERTY _IOWR(MAJOR_NUM, 0, char *)
++#define DEVICE_FILE_NAME "/dev/vcio"
++
++#include "rpi_mailbox.h"
++//#include <interface/vctypes/vc_image_structs.h>
++
++/*
++ * use ioctl to send mbox property message
++ */
++
++static int mbox_property(int file_desc, void *buf)
++{
++ int ret_val = ioctl(file_desc, IOCTL_MBOX_PROPERTY, buf);
++
++ if (ret_val < 0) {
++ printf("ioctl_set_msg failed:%d\n", ret_val);
++ }
++
++#ifdef DEBUG
++ unsigned *p = buf; int i; unsigned size = *(unsigned *)buf;
++ for (i=0; i<size/4; i++)
++ printf("%04x: 0x%08x\n", i*sizeof *p, p[i]);
++#endif
++ return ret_val;
++}
++
++#define GET_VCIMAGE_PARAMS 0x30044
++
++int mbox_get_image_params(int fd, VC_IMAGE_T * img)
++{
++ uint32_t buf[sizeof(*img) / sizeof(uint32_t) + 32];
++ uint32_t * p = buf;
++ void * rimg;
++ int rv;
++
++ *p++ = 0; // size
++ *p++ = 0; // process request
++ *p++ = GET_VCIMAGE_PARAMS;
++ *p++ = sizeof(*img);
++ *p++ = sizeof(*img);
++ rimg = p;
++ memcpy(p, img, sizeof(*img));
++ p += sizeof(*img) / sizeof(*p);
++ *p++ = 0; // End tag
++ buf[0] = (p - buf) * sizeof(*p);
++
++ rv = mbox_property(fd, buf);
++ memcpy(img, rimg, sizeof(*img));
++
++ return rv;
++}
++
++int mbox_open() {
++ int file_desc;
++
++ // open a char device file used for communicating with kernel mbox driver
++ file_desc = open(DEVICE_FILE_NAME, 0);
++ if (file_desc < 0) {
++ printf("Can't open device file: %s\n", DEVICE_FILE_NAME);
++ printf("Try creating a device file with: sudo mknod %s c %d 0\n", DEVICE_FILE_NAME, MAJOR_NUM);
++ }
++ return file_desc;
++}
++
++void mbox_close(int file_desc) {
++ close(file_desc);
++}
++
+diff --git a/libavcodec/rpi_mailbox.h b/libavcodec/rpi_mailbox.h
+new file mode 100644
+index 0000000000..06709d57fd
+--- /dev/null
++++ b/libavcodec/rpi_mailbox.h
+@@ -0,0 +1,55 @@
++#ifndef RPI_MAILBOX_H
++#define RPI_MAILBOX_H
++
++/* The image structure. */
++typedef struct vc_image_extra_uv_s {
++ void *u, *v;
++ int vpitch;
++} VC_IMAGE_EXTRA_UV_T;
++
++typedef union {
++ VC_IMAGE_EXTRA_UV_T uv;
++// VC_IMAGE_EXTRA_RGBA_T rgba;
++// VC_IMAGE_EXTRA_PAL_T pal;
++// VC_IMAGE_EXTRA_TF_T tf;
++// VC_IMAGE_EXTRA_BAYER_T bayer;
++// VC_IMAGE_EXTRA_MSBAYER_T msbayer;
++// VC_IMAGE_EXTRA_CODEC_T codec;
++// VC_IMAGE_EXTRA_OPENGL_T opengl;
++} VC_IMAGE_EXTRA_T;
++
++
++typedef struct VC_IMAGE_T {
++ unsigned short type; /* should restrict to 16 bits */
++ unsigned short info; /* format-specific info; zero for VC02 behaviour */
++ unsigned short width; /* width in pixels */
++ unsigned short height; /* height in pixels */
++ int pitch; /* pitch of image_data array in bytes */
++ int size; /* number of bytes available in image_data array */
++ void *image_data; /* pixel data */
++ VC_IMAGE_EXTRA_T extra; /* extra data like palette pointer */
++ void *metadata; /* metadata header for the image */
++ void *pool_object; /* nonNULL if image was allocated from a vc_pool */
++ int mem_handle; /* the mem handle for relocatable memory storage */
++ int metadata_size; /* size of metadata of each channel in bytes */
++ int channel_offset; /* offset of consecutive channels in bytes */
++ uint32_t video_timestamp;/* 90000 Hz RTP times domain - derived from audio timestamp */
++ uint8_t num_channels; /* number of channels (2 for stereo) */
++ uint8_t current_channel;/* the channel this header is currently pointing to */
++ uint8_t linked_multichann_flag;/* Indicate the header has the linked-multichannel structure*/
++ uint8_t is_channel_linked; /* Track if the above structure is been used to link the header
++ into a linked-mulitchannel image */
++ uint8_t channel_index; /* index of the channel this header represents while
++ it is being linked. */
++ uint8_t _dummy[3]; /* pad struct to 64 bytes */
++} VC_IMAGE_T;
++
++typedef int vc_image_t_size_check[(sizeof(VC_IMAGE_T) == 64) * 2 - 1];
++
++
++extern int mbox_open(void);
++extern void mbox_close(int file_desc);
++
++int mbox_get_image_params(int fd, VC_IMAGE_T * img);
++
++#endif
+diff --git a/libavcodec/rpi_qpu.c b/libavcodec/rpi_qpu.c
+new file mode 100644
+index 0000000000..f4498bf7b1
+--- /dev/null
++++ b/libavcodec/rpi_qpu.c
+@@ -0,0 +1,957 @@
++#include <stdio.h>
++#include <stdlib.h>
++#include <string.h>
++#include <stddef.h>
++#include <stdint.h>
++#include "libavutil/avassert.h"
++
++#include "config.h"
++
++#include <pthread.h>
++#include <time.h>
++
++#include <interface/vcsm/user-vcsm.h>
++
++#include "rpi_mailbox.h"
++#include "rpi_qpu.h"
++#include "rpi_hevc_shader.h"
++#include "rpi_hevc_transform8.h"
++#include "rpi_hevc_transform10.h"
++#include "libavutil/rpi_sand_fns.h"
++
++// Trace time spent waiting for GPU (VPU/QPU) (1=Yes, 0=No)
++#define RPI_TRACE_TIME_VPU_QPU_WAIT 0
++
++// Add profile flags to all QPU requests - generates output in "vcdbg log msg"
++// Beware this is expensive and will probably throw off all other timing by >10%
++#define RPI_TRACE_QPU_PROFILE_ALL 0
++
++// QPU "noflush" flags
++// a mixture of flushing & profiling
++
++#define QPU_FLAGS_NO_FLUSH_VPU 1 // If unset VPU cache will be flushed
++#define QPU_FLAGS_PROF_CLEAR_AND_ENABLE 2 // Clear & Enable detailed QPU profiling registers
++#define QPU_FLAGS_PROF_OUTPUT_COUNTS 4 // Print the results
++#define QPU_FLAGS_OUTPUT_QPU_TIMES 8 // Print QPU times - independant of the profiling
++#define QPU_FLAGS_NO_FLUSH_QPU 16 // If unset flush QPU caches & TMUs (uniforms always flushed)
++
++#define vcos_verify_ge0(x) ((x)>=0)
++
++// Size in 32bit words
++#define QPU_CODE_SIZE 4098
++#define VPU_CODE_SIZE 16384
++
++static const short rpi_transMatrix2even[32][16] = { // Even rows first
++{64, 64, 64, 64, 64, 64, 64, 64, 64, 64, 64, 64, 64, 64, 64, 64},
++{90, 87, 80, 70, 57, 43, 25, 9, -9, -25, -43, -57, -70, -80, -87, -90},
++{89, 75, 50, 18, -18, -50, -75, -89, -89, -75, -50, -18, 18, 50, 75, 89},
++{87, 57, 9, -43, -80, -90, -70, -25, 25, 70, 90, 80, 43, -9, -57, -87},
++{83, 36, -36, -83, -83, -36, 36, 83, 83, 36, -36, -83, -83, -36, 36, 83},
++{80, 9, -70, -87, -25, 57, 90, 43, -43, -90, -57, 25, 87, 70, -9, -80},
++{75, -18, -89, -50, 50, 89, 18, -75, -75, 18, 89, 50, -50, -89, -18, 75},
++{70, -43, -87, 9, 90, 25, -80, -57, 57, 80, -25, -90, -9, 87, 43, -70},
++{64, -64, -64, 64, 64, -64, -64, 64, 64, -64, -64, 64, 64, -64, -64, 64},
++{57, -80, -25, 90, -9, -87, 43, 70, -70, -43, 87, 9, -90, 25, 80, -57},
++{50, -89, 18, 75, -75, -18, 89, -50, -50, 89, -18, -75, 75, 18, -89, 50},
++{43, -90, 57, 25, -87, 70, 9, -80, 80, -9, -70, 87, -25, -57, 90, -43},
++{36, -83, 83, -36, -36, 83, -83, 36, 36, -83, 83, -36, -36, 83, -83, 36},
++{25, -70, 90, -80, 43, 9, -57, 87, -87, 57, -9, -43, 80, -90, 70, -25},
++{18, -50, 75, -89, 89, -75, 50, -18, -18, 50, -75, 89, -89, 75, -50, 18},
++{ 9, -25, 43, -57, 70, -80, 87, -90, 90, -87, 80, -70, 57, -43, 25, -9},
++// Odd rows
++{90, 90, 88, 85, 82, 78, 73, 67, 61, 54, 46, 38, 31, 22, 13, 4},
++{90, 82, 67, 46, 22, -4, -31, -54, -73, -85, -90, -88, -78, -61, -38, -13},
++{88, 67, 31, -13, -54, -82, -90, -78, -46, -4, 38, 73, 90, 85, 61, 22},
++{85, 46, -13, -67, -90, -73, -22, 38, 82, 88, 54, -4, -61, -90, -78, -31},
++{82, 22, -54, -90, -61, 13, 78, 85, 31, -46, -90, -67, 4, 73, 88, 38},
++{78, -4, -82, -73, 13, 85, 67, -22, -88, -61, 31, 90, 54, -38, -90, -46},
++{73, -31, -90, -22, 78, 67, -38, -90, -13, 82, 61, -46, -88, -4, 85, 54},
++{67, -54, -78, 38, 85, -22, -90, 4, 90, 13, -88, -31, 82, 46, -73, -61},
++{61, -73, -46, 82, 31, -88, -13, 90, -4, -90, 22, 85, -38, -78, 54, 67},
++{54, -85, -4, 88, -46, -61, 82, 13, -90, 38, 67, -78, -22, 90, -31, -73},
++{46, -90, 38, 54, -90, 31, 61, -88, 22, 67, -85, 13, 73, -82, 4, 78},
++{38, -88, 73, -4, -67, 90, -46, -31, 85, -78, 13, 61, -90, 54, 22, -82},
++{31, -78, 90, -61, 4, 54, -88, 82, -38, -22, 73, -90, 67, -13, -46, 85},
++{22, -61, 85, -90, 73, -38, -4, 46, -78, 90, -82, 54, -13, -31, 67, -88},
++{13, -38, 61, -78, 88, -90, 85, -73, 54, -31, 4, 22, -46, 67, -82, 90},
++{ 4, -13, 22, -31, 38, -46, 54, -61, 67, -73, 78, -82, 85, -88, 90, -90}
++};
++
++// Code/constants on GPU
++struct GPU
++{
++// unsigned int qpu_code[QPU_CODE_SIZE];
++ unsigned int vpu_code8[VPU_CODE_SIZE];
++ unsigned int vpu_code10[VPU_CODE_SIZE];
++ short transMatrix2even[16*16*2];
++};
++
++struct rpi_cache_flush_env_s {
++ struct vcsm_user_clean_invalid2_s v;
++};
++
++#define WAIT_COUNT_MAX 16
++
++typedef struct trace_time_one_s
++{
++ int count;
++ int64_t start[WAIT_COUNT_MAX];
++ int64_t total[WAIT_COUNT_MAX];
++} trace_time_one_t;
++
++typedef struct trace_time_wait_s
++{
++ unsigned int jcount;
++ int64_t start0;
++ int64_t last_update;
++ trace_time_one_t active;
++ trace_time_one_t wait;
++} trace_time_wait_t;
++
++typedef struct vq_wait_s
++{
++ sem_t sem;
++ struct vq_wait_s * next;
++} vq_wait_t;
++
++#define VQ_WAIT_POOL_SIZE 16
++typedef struct vq_wait_pool_s
++{
++ vq_wait_t * head;
++ vq_wait_t pool[VQ_WAIT_POOL_SIZE];
++} vq_wait_pool_t;
++
++static void vq_wait_pool_init(vq_wait_pool_t * const pool);
++static void vq_wait_pool_deinit(vq_wait_pool_t * const pool);
++
++typedef struct gpu_env_s
++{
++ int open_count;
++ int init_count;
++ int mb;
++ int vpu_i_cache_flushed;
++ GPU_MEM_PTR_T qpu_code_gm_ptr;
++ GPU_MEM_PTR_T code_gm_ptr;
++ GPU_MEM_PTR_T dummy_gm_ptr;
++ vq_wait_pool_t wait_pool;
++#if RPI_TRACE_TIME_VPU_QPU_WAIT
++ trace_time_wait_t ttw;
++#endif
++} gpu_env_t;
++
++// Stop more than one thread trying to allocate memory or use the processing resources at once
++static pthread_mutex_t gpu_mutex = PTHREAD_MUTEX_INITIALIZER;
++static gpu_env_t * gpu = NULL;
++
++#if RPI_TRACE_TIME_VPU_QPU_WAIT
++
++static int64_t ns_time(void)
++{
++ struct timespec ts;
++ clock_gettime(CLOCK_MONOTONIC, &ts);
++ return (int64_t)ts.tv_sec * (int64_t)1000000000 + ts.tv_nsec;
++}
++
++
++#define WAIT_TIME_PRINT_PERIOD (int64_t)2000000000
++
++#define T_MS(t) ((unsigned int)((t)/(int64_t)1000000) % 1000U)
++#define T_SEC(t) (unsigned int)((t)/(int64_t)1000000000)
++#define T_ARG(t) T_SEC(t), T_MS(t)
++#define T_FMT "%u.%03u"
++
++static void tto_print(trace_time_one_t * tto, const int64_t now, const int64_t start0, const char * const prefix)
++{
++ // Update totals for levels that are still pending
++ for (int i = 0; i < tto->count; ++i) {
++ tto->total[i] += now - tto->start[i];
++ tto->start[i] = now;
++ }
++
++ printf("%s: Idle:" T_FMT ", 1:" T_FMT ", 2:" T_FMT ", 3:" T_FMT ", 4:" T_FMT "\n",
++ prefix,
++ T_ARG(now - start0 - tto->total[0]),
++ T_ARG(tto->total[0]),
++ T_ARG(tto->total[1]),
++ T_ARG(tto->total[2]),
++ T_ARG(tto->total[3]));
++}
++
++
++static void tto_start(trace_time_one_t * const tto, const int64_t now)
++{
++ av_assert0(tto->count < WAIT_COUNT_MAX);
++ tto->start[tto->count++] = now;
++}
++
++static void tto_end(trace_time_one_t * const tto, const int64_t now)
++{
++ const int n = --tto->count;
++ av_assert0(n >= 0);
++ tto->total[n] += now - tto->start[n];
++}
++
++static void ttw_print(trace_time_wait_t * const ttw, const int64_t now)
++{
++ printf("Jobs:%d, Total time=" T_FMT "\n", ttw->jcount, T_ARG(now - ttw->start0));
++ tto_print(&ttw->active, now, ttw->start0, "Active");
++ tto_print(&ttw->wait, now, ttw->start0, " Wait");
++}
++
++#endif
++
++// GPU memory alloc fns (internal)
++
++static void gpu_free_internal(GPU_MEM_PTR_T * const p)
++{
++ if (p->arm != NULL)
++ vcsm_unlock_ptr(p->arm);
++ if (p->vcsm_handle != 0)
++ vcsm_free(p->vcsm_handle);
++ memset(p, 0, sizeof(*p)); // Ensure we crash hard if we try and use this again
++}
++
++
++static int gpu_malloc_internal(GPU_MEM_PTR_T * const p,
++ const int numbytes, const unsigned int cache_type, const char * const name)
++{
++ memset(p, 0, sizeof(*p));
++ p->numbytes = (numbytes + 255) & ~255; // Round up
++
++ if ((p->vcsm_handle = vcsm_malloc_cache(p->numbytes, cache_type | 0x80, (char *)name)) == 0 ||
++ (p->vc_handle = vcsm_vc_hdl_from_hdl(p->vcsm_handle)) == 0 ||
++ (p->arm = vcsm_lock(p->vcsm_handle)) == NULL ||
++ (p->vc = vcsm_vc_addr_from_hdl(p->vcsm_handle)) == 0)
++ {
++ gpu_free_internal(p);
++ return AVERROR(ENOMEM);
++ }
++ return 0;
++}
++
++
++// GPU init, free, lock, unlock
++
++static void gpu_term(void)
++{
++ gpu_env_t * const ge = gpu;
++
++ // We have to hope that eveything has terminated...
++ gpu = NULL;
++
++ vc_gpuserv_deinit();
++
++ gpu_free_internal(&ge->code_gm_ptr);
++ gpu_free_internal(&ge->qpu_code_gm_ptr);
++ gpu_free_internal(&ge->dummy_gm_ptr);
++
++ vcsm_exit();
++
++ mbox_close(ge->mb);
++
++ vq_wait_pool_deinit(&ge->wait_pool);
++
++ free(ge);
++}
++
++
++// Connect to QPU, returns 0 on success.
++static int gpu_init(gpu_env_t ** const gpu) {
++ volatile struct GPU* ptr;
++ gpu_env_t * const ge = calloc(1, sizeof(gpu_env_t));
++ int rv;
++ *gpu = NULL;
++
++ if (ge == NULL)
++ return -1;
++
++ if ((ge->mb = mbox_open()) < 0)
++ return -1;
++
++ vq_wait_pool_init(&ge->wait_pool);
++
++ vcsm_init();
++
++ // Now copy over the QPU code into GPU memory
++ if ((rv = gpu_malloc_internal(&ge->qpu_code_gm_ptr, QPU_CODE_SIZE * 4, VCSM_CACHE_TYPE_NONE, "ffmpeg qpu code")) != 0)
++ return rv;
++
++ {
++ int num_bytes = (char *)mc_end - (char *)ff_hevc_rpi_shader;
++ av_assert0(num_bytes<=QPU_CODE_SIZE*sizeof(unsigned int));
++ memcpy(ge->qpu_code_gm_ptr.arm, ff_hevc_rpi_shader, num_bytes);
++ memset(ge->qpu_code_gm_ptr.arm + num_bytes, 0, QPU_CODE_SIZE*4 - num_bytes);
++ }
++
++ // And the VPU code
++ if ((rv = gpu_malloc_internal(&ge->code_gm_ptr, sizeof(struct GPU), VCSM_CACHE_TYPE_VC, "ffmpeg vpu code")) != 0)
++ return rv;
++ ptr = (volatile struct GPU*)ge->code_gm_ptr.arm;
++
++ // Zero everything so we have zeros between the code bits
++ memset((void *)ptr, 0, sizeof(*ptr));
++ {
++ int num_bytes = sizeof(rpi_hevc_transform8);
++ av_assert0(num_bytes<=VPU_CODE_SIZE*sizeof(unsigned int));
++ memcpy((void*)ptr->vpu_code8, rpi_hevc_transform8, num_bytes);
++ }
++ {
++ int num_bytes = sizeof(rpi_hevc_transform10);
++ av_assert0(num_bytes<=VPU_CODE_SIZE*sizeof(unsigned int));
++ memcpy((void*)ptr->vpu_code10, rpi_hevc_transform10, num_bytes);
++ }
++ // And the transform coefficients
++ memcpy((void*)ptr->transMatrix2even, rpi_transMatrix2even, sizeof(rpi_transMatrix2even));
++
++ // Generate a dummy "frame" & fill with 0x80
++ // * Could reset to 1 <<bit_depth?
++ if ((rv = gpu_malloc_internal(&ge->dummy_gm_ptr, 0x4000, VCSM_CACHE_TYPE_NONE, "ffmpeg dummy frame")) != 0)
++ return rv;
++ memset(ge->dummy_gm_ptr.arm, 0x80, 0x4000);
++
++ *gpu = ge;
++ return 0;
++}
++
++
++
++static void gpu_unlock(void) {
++ pthread_mutex_unlock(&gpu_mutex);
++}
++
++// Make sure we have exclusive access to the mailbox, and enable qpu if necessary.
++static gpu_env_t * gpu_lock(void) {
++ pthread_mutex_lock(&gpu_mutex);
++
++ av_assert1(gpu != NULL);
++ return gpu;
++}
++
++static gpu_env_t * gpu_lock_ref(void)
++{
++ pthread_mutex_lock(&gpu_mutex);
++
++ if (gpu == NULL) {
++ int rv = gpu_init(&gpu);
++ if (rv != 0) {
++ gpu_unlock();
++ return NULL;
++ }
++ }
++
++ ++gpu->open_count;
++ return gpu;
++}
++
++static void gpu_unlock_unref(gpu_env_t * const ge)
++{
++ if (--ge->open_count == 0)
++ gpu_term();
++
++ gpu_unlock();
++}
++
++static inline gpu_env_t * gpu_ptr(void)
++{
++ av_assert1(gpu != NULL);
++ return gpu;
++}
++
++// Public gpu fns
++
++// Allocate memory on GPU
++// Fills in structure <p> containing ARM pointer, videocore handle, videocore memory address, numbytes
++// Returns 0 on success.
++// This allocates memory that will not be cached in ARM's data cache.
++// Therefore safe to use without data cache flushing.
++int gpu_malloc_uncached(int numbytes, GPU_MEM_PTR_T *p)
++{
++ return gpu_malloc_internal(p, numbytes, VCSM_CACHE_TYPE_NONE, "ffmpeg uncached");
++}
++
++// This allocates data that will be
++// Cached in ARM L2
++// Uncached in VPU L2
++int gpu_malloc_cached(int numbytes, GPU_MEM_PTR_T *p)
++{
++ return gpu_malloc_internal(p, numbytes, VCSM_CACHE_TYPE_HOST, "ffmpeg cached");
++}
++
++void gpu_free(GPU_MEM_PTR_T * const p) {
++ gpu_free_internal(p);
++}
++
++unsigned int vpu_get_fn(const unsigned int bit_depth) {
++ uint32_t a = 0;
++
++ // Make sure that the gpu is initialized
++ av_assert1(gpu != NULL);
++ switch (bit_depth){
++ case 8:
++ a = gpu->code_gm_ptr.vc + offsetof(struct GPU, vpu_code8);
++ break;
++ case 10:
++ a = gpu->code_gm_ptr.vc + offsetof(struct GPU, vpu_code10);
++ break;
++ default:
++ av_assert0(0);
++ }
++ return a;
++}
++
++unsigned int vpu_get_constants(void) {
++ av_assert1(gpu != NULL);
++ return (gpu->code_gm_ptr.vc + offsetof(struct GPU,transMatrix2even));
++}
++
++int gpu_get_mailbox(void)
++{
++ av_assert1(gpu);
++ return gpu->mb;
++}
++
++void gpu_ref(void)
++{
++ gpu_lock_ref();
++ gpu_unlock();
++}
++
++void gpu_unref(void)
++{
++ gpu_env_t * const ge = gpu_lock();
++ gpu_unlock_unref(ge);
++}
++
++// ----------------------------------------------------------------------------
++//
++// Cache flush functions
++
++#define CACHE_EL_MAX ((sizeof(rpi_cache_buf_t) - sizeof (struct vcsm_user_clean_invalid2_s)) / sizeof (struct vcsm_user_clean_invalid2_block_s))
++
++rpi_cache_flush_env_t * rpi_cache_flush_init(rpi_cache_buf_t * const buf)
++{
++ rpi_cache_flush_env_t * const rfe = (rpi_cache_flush_env_t *)buf;
++ rfe->v.op_count = 0;
++ return rfe;
++}
++
++void rpi_cache_flush_abort(rpi_cache_flush_env_t * const rfe)
++{
++ // Nothing needed
++}
++
++int rpi_cache_flush_execute(rpi_cache_flush_env_t * const rfe)
++{
++ int rc = 0;
++ if (rfe->v.op_count != 0) {
++ if (vcsm_clean_invalid2(&rfe->v) != 0)
++ {
++ av_log(NULL, AV_LOG_ERROR, "vcsm_clean_invalid2 failed: errno=%d\n", errno);
++ rc = -1;
++ }
++ rfe->v.op_count = 0;
++ }
++ return rc;
++}
++
++int rpi_cache_flush_finish(rpi_cache_flush_env_t * const rfe)
++{
++ int rc = rpi_cache_flush_execute(rfe);;
++
++ return rc;
++}
++
++inline void rpi_cache_flush_add_gm_blocks(rpi_cache_flush_env_t * const rfe, const GPU_MEM_PTR_T * const gm, const unsigned int mode,
++ const unsigned int offset0, const unsigned int block_size, const unsigned int blocks, const unsigned int block_stride)
++{
++ struct vcsm_user_clean_invalid2_block_s * const b = rfe->v.s + rfe->v.op_count++;
++
++ av_assert1(rfe->v.op_count <= CACHE_EL_MAX);
++
++ b->invalidate_mode = mode;
++ b->block_count = blocks;
++ b->start_address = gm->arm + offset0;
++ b->block_size = block_size;
++ b->inter_block_stride = block_stride;
++}
++
++void rpi_cache_flush_add_gm_range(rpi_cache_flush_env_t * const rfe, const GPU_MEM_PTR_T * const gm, const unsigned int mode,
++ const unsigned int offset, const unsigned int size)
++{
++ // Deal with empty pointer trivially
++ if (gm == NULL || size == 0)
++ return;
++
++ av_assert1(offset <= gm->numbytes);
++ av_assert1(size <= gm->numbytes);
++ av_assert1(offset + size <= gm->numbytes);
++
++ rpi_cache_flush_add_gm_blocks(rfe, gm, mode, offset, size, 1, 0);
++}
++
++void rpi_cache_flush_add_gm_ptr(rpi_cache_flush_env_t * const rfe, const GPU_MEM_PTR_T * const gm, const unsigned int mode)
++{
++ rpi_cache_flush_add_gm_blocks(rfe, gm, mode, 0, gm->numbytes, 1, 0);
++}
++
++
++void rpi_cache_flush_add_frame(rpi_cache_flush_env_t * const rfe, const AVFrame * const frame, const unsigned int mode)
++{
++#if !RPI_ONE_BUF
++#error Fixme! (NIF)
++#endif
++ if (gpu_is_buf1(frame)) {
++ rpi_cache_flush_add_gm_ptr(rfe, gpu_buf1_gmem(frame), mode);
++ }
++ else
++ {
++ rpi_cache_flush_add_gm_ptr(rfe, gpu_buf3_gmem(frame, 0), mode);
++ rpi_cache_flush_add_gm_ptr(rfe, gpu_buf3_gmem(frame, 1), mode);
++ rpi_cache_flush_add_gm_ptr(rfe, gpu_buf3_gmem(frame, 2), mode);
++ }
++}
++
++// Flush an area of a frame
++// Width, height, x0, y0 in luma pels
++void rpi_cache_flush_add_frame_block(rpi_cache_flush_env_t * const rfe, const AVFrame * const frame, const unsigned int mode,
++ const unsigned int x0, const unsigned int y0, const unsigned int width, const unsigned int height,
++ const unsigned int uv_shift, const int do_luma, const int do_chroma)
++{
++ const unsigned int y_offset = frame->linesize[0] * y0;
++ const unsigned int y_size = frame->linesize[0] * height;
++ // Round UV up/down to get everything
++ const unsigned int uv_rnd = (1U << uv_shift) >> 1;
++ const unsigned int uv_offset = frame->linesize[1] * (y0 >> uv_shift);
++ const unsigned int uv_size = frame->linesize[1] * ((y0 + height + uv_rnd) >> uv_shift) - uv_offset;
++
++#if 0
++ // *** frame->height is cropped height so not good
++ // As all unsigned they will also reject -ve
++ // Test individually as well as added to reject overflow
++ av_assert0(start_line <= (unsigned int)frame->height); // ***** frame height cropped
++ av_assert0(n <= (unsigned int)frame->height);
++ av_assert0(start_line + n <= (unsigned int)frame->height);
++#endif
++
++ if (!gpu_is_buf1(frame))
++ {
++ if (do_luma) {
++ rpi_cache_flush_add_gm_range(rfe, gpu_buf3_gmem(frame, 0), mode, y_offset, y_size);
++ }
++ if (do_chroma) {
++ rpi_cache_flush_add_gm_range(rfe, gpu_buf3_gmem(frame, 1), mode, uv_offset, uv_size);
++ rpi_cache_flush_add_gm_range(rfe, gpu_buf3_gmem(frame, 2), mode, uv_offset, uv_size);
++ }
++ }
++ else if (!av_rpi_is_sand_frame(frame))
++ {
++ const GPU_MEM_PTR_T * const gm = gpu_buf1_gmem(frame);
++ if (do_luma) {
++ rpi_cache_flush_add_gm_range(rfe, gm, mode, (frame->data[0] - gm->arm) + y_offset, y_size);
++ }
++ if (do_chroma) {
++ rpi_cache_flush_add_gm_range(rfe, gm, mode, (frame->data[1] - gm->arm) + uv_offset, uv_size);
++ rpi_cache_flush_add_gm_range(rfe, gm, mode, (frame->data[2] - gm->arm) + uv_offset, uv_size);
++ }
++ }
++ else
++ {
++ const unsigned int stride1 = av_rpi_sand_frame_stride1(frame);
++ const unsigned int stride2 = av_rpi_sand_frame_stride2(frame);
++ const unsigned int xshl = av_rpi_sand_frame_xshl(frame);
++ const unsigned int xleft = x0 & ~((stride1 >> xshl) - 1);
++ const unsigned int block_count = (((x0 + width - xleft) << xshl) + stride1 - 1) / stride1; // Same for Y & C
++ av_assert1(rfe->v.op_count + do_chroma + do_luma < CACHE_EL_MAX);
++
++ if (do_chroma)
++ {
++ struct vcsm_user_clean_invalid2_block_s * const b = rfe->v.s + rfe->v.op_count++;
++ b->invalidate_mode = mode;
++ b->block_count = block_count;
++ b->start_address = av_rpi_sand_frame_pos_c(frame, xleft >> 1, y0 >> 1);
++ b->block_size = uv_size;
++ b->inter_block_stride = stride1 * stride2;
++ }
++ if (do_luma)
++ {
++ struct vcsm_user_clean_invalid2_block_s * const b = rfe->v.s + rfe->v.op_count++;
++ b->invalidate_mode = mode;
++ b->block_count = block_count;
++ b->start_address = av_rpi_sand_frame_pos_y(frame, xleft, y0);
++ b->block_size = y_size;
++ b->inter_block_stride = stride1 * stride2;
++ }
++ }
++}
++
++// Call this to clean and invalidate a region of memory
++void rpi_cache_flush_one_gm_ptr(const GPU_MEM_PTR_T *const p, const rpi_cache_flush_mode_t mode)
++{
++ rpi_cache_buf_t cbuf;
++ rpi_cache_flush_env_t * rfe = rpi_cache_flush_init(&cbuf);
++ rpi_cache_flush_add_gm_ptr(rfe, p, mode);
++ rpi_cache_flush_finish(rfe);
++}
++
++
++// ----------------------------------------------------------------------------
++
++
++// Wait abstractions - mostly so we can easily add profile code
++static void vq_wait_pool_init(vq_wait_pool_t * const wp)
++{
++ unsigned int i;
++ for (i = 0; i != VQ_WAIT_POOL_SIZE; ++i) {
++ sem_init(&wp->pool[i].sem, 0, 0);
++ wp->pool[i].next = wp->pool + i + 1;
++ }
++ wp->head = wp->pool + 0;
++ wp->pool[VQ_WAIT_POOL_SIZE - 1].next = NULL;
++}
++
++static void vq_wait_pool_deinit(vq_wait_pool_t * const wp)
++{
++ unsigned int i;
++ wp->head = NULL;
++ for (i = 0; i != VQ_WAIT_POOL_SIZE; ++i) {
++ sem_destroy(&wp->pool[i].sem);
++ wp->pool[i].next = NULL;
++ }
++}
++
++
++// If sem_init actually takes time then maybe we want a pool...
++static vq_wait_t * vq_wait_new(void)
++{
++ gpu_env_t * const ge = gpu_lock_ref();
++ vq_wait_t * const wait = ge->wait_pool.head;
++ ge->wait_pool.head = wait->next;
++ wait->next = NULL;
++
++#if RPI_TRACE_TIME_VPU_QPU_WAIT
++ tto_start(&ge->ttw.active, ns_time());
++#endif
++
++ gpu_unlock();
++ return wait;
++}
++
++static void vq_wait_delete(vq_wait_t * const wait)
++{
++ gpu_env_t * const ge = gpu_lock();
++ wait->next = ge->wait_pool.head;
++ ge->wait_pool.head = wait;
++
++#if RPI_TRACE_TIME_VPU_QPU_WAIT
++ {
++ trace_time_wait_t * const ttw = &ge->ttw;
++ const int64_t now = ns_time();
++ ++ttw->jcount;
++ tto_end(&ttw->wait, now);
++
++ if (ttw->start0 == 0)
++ {
++ ttw->start0 = ttw->active.start[0];
++ ttw->last_update = ttw->start0;
++ }
++ if (now - ttw->last_update > WAIT_TIME_PRINT_PERIOD)
++ {
++ ttw->last_update += WAIT_TIME_PRINT_PERIOD;
++ ttw_print(ttw, now);
++ }
++ }
++#endif
++ gpu_unlock_unref(ge);
++}
++
++static void vq_wait_wait(vq_wait_t * const wait)
++{
++#if RPI_TRACE_TIME_VPU_QPU_WAIT
++ {
++ const int64_t now = ns_time();
++ gpu_env_t * const ge = gpu_lock();
++ tto_start(&ge->ttw.wait, now);
++ gpu_unlock();
++ }
++#endif
++
++ while (sem_wait(&wait->sem) == -1 && errno == EINTR)
++ /* loop */;
++}
++
++static void vq_wait_post(vq_wait_t * const wait)
++{
++#if RPI_TRACE_TIME_VPU_QPU_WAIT
++ {
++ gpu_env_t *const ge = gpu_lock();
++ tto_end(&ge->ttw.active, ns_time());
++ gpu_unlock();
++ }
++#endif
++
++ sem_post(&wait->sem);
++}
++
++
++
++// Header comments were wrong for these two
++#define VPU_QPU_MASK_QPU 1
++#define VPU_QPU_MASK_VPU 2
++
++typedef struct vpu_qpu_job_env_s vpu_qpu_job_env_t;
++
++vpu_qpu_job_env_t * vpu_qpu_job_init(vpu_qpu_job_env_t * const buf)
++{
++// vpu_qpu_job_env_t * vqj = calloc(1, sizeof(vpu_qpu_job_env_t));
++ vpu_qpu_job_env_t * vqj = buf;
++// memset(vqj, 0, sizeof(*vqj));
++ vqj->n = 0;
++ vqj->mask = 0;
++ return vqj;
++}
++
++void vpu_qpu_job_delete(vpu_qpu_job_env_t * const vqj)
++{
++// memset(vqj, 0, sizeof(*vqj));
++// free(vqj);
++}
++
++static inline struct gpu_job_s * new_job(vpu_qpu_job_env_t * const vqj)
++{
++ struct gpu_job_s * const j = vqj->j + vqj->n++;
++ av_assert1(vqj->n <= VPU_QPU_JOB_MAX);
++ return j;
++}
++
++void vpu_qpu_job_add_vpu(vpu_qpu_job_env_t * const vqj, const uint32_t vpu_code,
++ const unsigned r0, const unsigned r1, const unsigned r2, const unsigned r3, const unsigned r4, const unsigned r5)
++{
++ if (vpu_code != 0) {
++ struct gpu_job_s *const j = new_job(vqj);
++ vqj->mask |= VPU_QPU_MASK_VPU;
++
++ j->command = EXECUTE_VPU;
++ j->callback.func = 0;
++ j->callback.cookie = NULL;
++ // The bottom two bits of the execute address contain no-flush flags
++ // b0 will flush the VPU I-cache if unset so we nearly always want that set
++ // as we never reload code
++ j->u.v.q[0] = vpu_code | gpu->vpu_i_cache_flushed;
++ j->u.v.q[1] = r0;
++ j->u.v.q[2] = r1;
++ j->u.v.q[3] = r2;
++ j->u.v.q[4] = r3;
++ j->u.v.q[5] = r4;
++ j->u.v.q[6] = r5;
++ gpu->vpu_i_cache_flushed = 1;
++ }
++}
++
++// flags are QPU_FLAGS_xxx
++void vpu_qpu_job_add_qpu(vpu_qpu_job_env_t * const vqj, const unsigned int n, const uint32_t * const mail)
++{
++ if (n != 0) {
++ struct gpu_job_s *const j = new_job(vqj);
++ vqj->mask |= VPU_QPU_MASK_QPU;
++
++ j->command = EXECUTE_QPU;
++ j->callback.func = 0;
++ j->callback.cookie = NULL;
++
++ j->u.q.jobs = n;
++#if RPI_TRACE_QPU_PROFILE_ALL
++ j->u.q.noflush = QPU_FLAGS_NO_FLUSH_VPU | QPU_FLAGS_PROF_CLEAR_AND_ENABLE | QPU_FLAGS_PROF_OUTPUT_COUNTS;
++#else
++ j->u.q.noflush = QPU_FLAGS_NO_FLUSH_VPU;
++#endif
++ j->u.q.timeout = 5000;
++ memcpy(j->u.q.control, mail, n * QPU_MAIL_EL_VALS * sizeof(uint32_t));
++ }
++}
++
++// Convert callback to sem post
++static void vpu_qpu_job_callback_wait(void * v)
++{
++ vq_wait_post(v);
++}
++
++// Poke a user-supplied sem
++static void vpu_qpu_job_callback_sem(void * v)
++{
++ sem_post((sem_t *)v);
++}
++
++void vpu_qpu_job_add_sync_this(vpu_qpu_job_env_t * const vqj, vpu_qpu_wait_h * const wait_h)
++{
++ vq_wait_t * wait;
++
++ if (vqj->mask == 0) {
++ *wait_h = NULL;
++ return;
++ }
++
++ // We are going to want a sync object
++ wait = vq_wait_new();
++
++ // There are 2 VPU Qs & 1 QPU Q so we can collapse sync
++ // If we only posted one thing or only QPU jobs
++ if (vqj->n == 1 || vqj->mask == VPU_QPU_MASK_QPU)
++ {
++ struct gpu_job_s * const j = vqj->j + (vqj->n - 1);
++ av_assert1(j->callback.func == 0);
++
++ j->callback.func = vpu_qpu_job_callback_wait;
++ j->callback.cookie = wait;
++ }
++ else
++ {
++ struct gpu_job_s *const j = new_job(vqj);
++
++ j->command = EXECUTE_SYNC;
++ j->u.s.mask = vqj->mask;
++ j->callback.func = vpu_qpu_job_callback_wait;
++ j->callback.cookie = wait;
++ }
++
++ vqj->mask = 0;
++ *wait_h = wait;
++}
++
++// Returns 0 if no sync added ('cos Q empty), 1 if sync added
++int vpu_qpu_job_add_sync_sem(vpu_qpu_job_env_t * const vqj, sem_t * const sem)
++{
++ // If nothing on q then just return
++ if (vqj->mask == 0)
++ return 0;
++
++ // There are 2 VPU Qs & 1 QPU Q so we can collapse sync
++ // If we only posted one thing or only QPU jobs
++ if (vqj->n == 1 || vqj->mask == VPU_QPU_MASK_QPU)
++ {
++ struct gpu_job_s * const j = vqj->j + (vqj->n - 1);
++ av_assert1(j->callback.func == 0);
++
++ j->callback.func = vpu_qpu_job_callback_sem;
++ j->callback.cookie = sem;
++ }
++ else
++ {
++ struct gpu_job_s *const j = new_job(vqj);
++
++ j->command = EXECUTE_SYNC;
++ j->u.s.mask = vqj->mask;
++ j->callback.func = vpu_qpu_job_callback_sem;
++ j->callback.cookie = sem;
++ }
++
++ vqj->mask = 0;
++ return 1;
++}
++
++
++int vpu_qpu_job_start(vpu_qpu_job_env_t * const vqj)
++{
++ if (vqj->n == 0)
++ return 0;
++
++ return vc_gpuserv_execute_code(vqj->n, vqj->j);
++}
++
++// Simple wrapper of start + delete
++int vpu_qpu_job_finish(vpu_qpu_job_env_t * const vqj)
++{
++ int rv;
++ rv = vpu_qpu_job_start(vqj);
++ vpu_qpu_job_delete(vqj);
++ return rv;
++}
++
++void vpu_qpu_wait(vpu_qpu_wait_h * const wait_h)
++{
++ if (wait_h != NULL)
++ {
++ vq_wait_t * const wait = *wait_h;
++ if (wait != NULL) {
++ *wait_h = NULL;
++ vq_wait_wait(wait);
++ vq_wait_delete(wait);
++ }
++ }
++}
++
++int vpu_qpu_init()
++{
++ gpu_env_t * const ge = gpu_lock_ref();
++ if (ge == NULL)
++ return -1;
++
++ if (ge->init_count++ == 0)
++ {
++ vc_gpuserv_init();
++ }
++
++ gpu_unlock();
++ return 0;
++}
++
++void vpu_qpu_term()
++{
++ gpu_env_t * const ge = gpu_lock();
++
++ if (--ge->init_count == 0) {
++ vc_gpuserv_deinit();
++
++#if RPI_TRACE_TIME_VPU_QPU_WAIT
++ ttw_print(&ge->ttw, ns_time());
++#endif
++ }
++
++ gpu_unlock_unref(ge);
++}
++
++uint32_t qpu_fn(const int * const mc_fn)
++{
++ return gpu->qpu_code_gm_ptr.vc + ((const char *)mc_fn - (const char *)ff_hevc_rpi_shader);
++}
++
++uint32_t qpu_dummy(void)
++{
++ return gpu->dummy_gm_ptr.vc;
++}
++
++int rpi_hevc_qpu_init_fn(HEVCRpiQpu * const qf, const unsigned int bit_depth)
++{
++ // Dummy values we can catch with emulation
++ qf->y_pxx = ~1U;
++ qf->y_bxx = ~2U;
++ qf->y_p00 = ~3U;
++ qf->y_b00 = ~4U;
++ qf->c_pxx = ~5U;
++ qf->c_bxx = ~6U;
++
++ switch (bit_depth) {
++ case 8:
++ qf->y_pxx = qpu_fn(mc_filter_y_pxx);
++ qf->y_pxx = qpu_fn(mc_filter_y_pxx);
++ qf->y_bxx = qpu_fn(mc_filter_y_bxx);
++ qf->y_p00 = qpu_fn(mc_filter_y_p00);
++ qf->y_b00 = qpu_fn(mc_filter_y_b00);
++ qf->c_pxx = qpu_fn(mc_filter_c_p);
++ qf->c_pxx_l1 = qpu_fn(mc_filter_c_p_l1);
++ qf->c_bxx = qpu_fn(mc_filter_c_b);
++ break;
++ case 10:
++ qf->c_pxx = qpu_fn(mc_filter_c10_p);
++ qf->c_pxx_l1 = qpu_fn(mc_filter_c10_p_l1);
++ qf->c_bxx = qpu_fn(mc_filter_c10_b);
++ qf->y_pxx = qpu_fn(mc_filter_y10_pxx);
++ qf->y_bxx = qpu_fn(mc_filter_y10_bxx);
++ qf->y_p00 = qpu_fn(mc_filter_y10_p00);
++ qf->y_b00 = qpu_fn(mc_filter_y10_b00);
++ break;
++ default:
++ return -1;
++ }
++ return 0;
++}
++
+diff --git a/libavcodec/rpi_qpu.h b/libavcodec/rpi_qpu.h
+new file mode 100644
+index 0000000000..e1b4d9c39e
+--- /dev/null
++++ b/libavcodec/rpi_qpu.h
+@@ -0,0 +1,229 @@
++#ifndef RPI_QPU_H
++#define RPI_QPU_H
++
++#pragma GCC diagnostic push
++// Many many redundant decls in the header files
++#pragma GCC diagnostic ignored "-Wredundant-decls"
++#pragma GCC diagnostic ignored "-Wstrict-prototypes"
++#include "interface/vmcs_host/vc_vchi_gpuserv.h"
++#pragma GCC diagnostic pop
++
++
++#define RPI_ONE_BUF 1
++
++typedef struct gpu_mem_ptr_s {
++ unsigned char *arm; // Pointer to memory mapped on ARM side
++ int vc_handle; // Videocore handle of relocatable memory
++ int vcsm_handle; // Handle for use by VCSM
++ int vc; // Address for use in GPU code
++ int numbytes; // Size of memory block
++} GPU_MEM_PTR_T;
++
++// General GPU functions
++extern int gpu_malloc_cached(int numbytes, GPU_MEM_PTR_T *p);
++extern int gpu_malloc_uncached(int numbytes, GPU_MEM_PTR_T *p);
++extern void gpu_free(GPU_MEM_PTR_T * const p);
++
++#include "libavutil/frame.h"
++#if !RPI_ONE_BUF
++static inline uint32_t get_vc_address_y(const AVFrame * const frame) {
++ GPU_MEM_PTR_T *p = av_buffer_pool_opaque(frame->buf[0]);
++ return p->vc;
++}
++
++static inline uint32_t get_vc_address_u(const AVFrame * const frame) {
++ GPU_MEM_PTR_T *p = av_buffer_pool_opaque(frame->buf[1]);
++ return p->vc;
++}
++
++static inline uint32_t get_vc_address_v(const AVFrame * const frame) {
++ GPU_MEM_PTR_T *p = av_buffer_pool_opaque(frame->buf[2]);
++ return p->vc;
++}
++
++static inline GPU_MEM_PTR_T get_gpu_mem_ptr_y(const AVFrame * const frame) {
++ return *(GPU_MEM_PTR_T *)av_buffer_pool_opaque(frame->buf[0]);
++}
++
++static inline GPU_MEM_PTR_T get_gpu_mem_ptr_u(const AVFrame * const frame) {
++ return *(GPU_MEM_PTR_T *)av_buffer_pool_opaque(frame->buf[1]);
++}
++
++static inline GPU_MEM_PTR_T get_gpu_mem_ptr_v(const AVFrame * const frame) {
++ return *(GPU_MEM_PTR_T *)av_buffer_pool_opaque(frame->buf[2]);
++}
++
++#else
++
++static inline int gpu_is_buf1(const AVFrame * const frame)
++{
++ return frame->buf[1] == NULL;
++}
++
++static inline GPU_MEM_PTR_T * gpu_buf1_gmem(const AVFrame * const frame)
++{
++ return av_buffer_get_opaque(frame->buf[0]);
++}
++
++static inline GPU_MEM_PTR_T * gpu_buf3_gmem(const AVFrame * const frame, const unsigned int n)
++{
++ return av_buffer_pool_opaque(frame->buf[n]);
++}
++
++static inline uint32_t get_vc_address3(const AVFrame * const frame, const unsigned int n)
++{
++ const GPU_MEM_PTR_T * const gm = gpu_is_buf1(frame) ? gpu_buf1_gmem(frame) : gpu_buf3_gmem(frame, n);
++ return gm->vc + (frame->data[n] - gm->arm);
++}
++
++
++static inline uint32_t get_vc_address_y(const AVFrame * const frame) {
++ return get_vc_address3(frame, 0);
++}
++
++static inline uint32_t get_vc_address_u(const AVFrame * const frame) {
++ return get_vc_address3(frame, 1);
++}
++
++static inline uint32_t get_vc_address_v(const AVFrame * const frame) {
++ return get_vc_address3(frame, 2);
++}
++
++#if 0
++static inline GPU_MEM_PTR_T get_gpu_mem_ptr_y(const AVFrame * const frame) {
++ if (gpu_is_buf1(frame))
++ {
++ GPU_MEM_PTR_T g = *gpu_buf1_gmem(frame);
++ g.numbytes = frame->data[1] - frame->data[0];
++ return g;
++ }
++ else
++ return *gpu_buf3_gmem(frame, 0);
++}
++
++static inline GPU_MEM_PTR_T get_gpu_mem_ptr_u(const AVFrame * const frame) {
++ if (gpu_is_buf1(frame))
++ {
++ GPU_MEM_PTR_T g = *gpu_buf1_gmem(frame);
++ g.arm += frame->data[1] - frame->data[0];
++ g.vc += frame->data[1] - frame->data[0];
++ g.numbytes = frame->data[2] - frame->data[1]; // chroma size
++ return g;
++ }
++ else
++ return *gpu_buf3_gmem(frame, 1);
++}
++
++static inline GPU_MEM_PTR_T get_gpu_mem_ptr_v(const AVFrame * const frame) {
++ if (gpu_is_buf1(frame))
++ {
++ GPU_MEM_PTR_T g = *gpu_buf1_gmem(frame);
++ g.arm += frame->data[2] - frame->data[0];
++ g.vc += frame->data[2] - frame->data[0];
++ g.numbytes = frame->data[2] - frame->data[1]; // chroma size
++ return g;
++ }
++ else
++ return *gpu_buf3_gmem(frame, 2);
++}
++#endif
++#endif
++
++// Cache flush stuff
++
++struct rpi_cache_flush_env_s;
++typedef struct rpi_cache_flush_env_s rpi_cache_flush_env_t;
++
++typedef struct {uint32_t t[33];} rpi_cache_buf_t;
++
++rpi_cache_flush_env_t * rpi_cache_flush_init(rpi_cache_buf_t * const buf);
++// Free env without flushing
++void rpi_cache_flush_abort(rpi_cache_flush_env_t * const rfe);
++// Do the accumulated flush & clear but do not free the env
++int rpi_cache_flush_execute(rpi_cache_flush_env_t * const rfe);
++// Do the accumulated flush & free the env
++int rpi_cache_flush_finish(rpi_cache_flush_env_t * const rfe);
++
++typedef enum
++{
++ RPI_CACHE_FLUSH_MODE_INVALIDATE = 1,
++ RPI_CACHE_FLUSH_MODE_WRITEBACK = 2,
++ RPI_CACHE_FLUSH_MODE_WB_INVALIDATE = 3
++} rpi_cache_flush_mode_t;
++
++void rpi_cache_flush_add_gm_ptr(rpi_cache_flush_env_t * const rfe, const GPU_MEM_PTR_T * const gm, const rpi_cache_flush_mode_t mode);
++void rpi_cache_flush_add_gm_range(rpi_cache_flush_env_t * const rfe, const GPU_MEM_PTR_T * const gm, const rpi_cache_flush_mode_t mode,
++ const unsigned int offset, const unsigned int size);
++void rpi_cache_flush_add_gm_blocks(rpi_cache_flush_env_t * const rfe, const GPU_MEM_PTR_T * const gm, const unsigned int mode,
++ const unsigned int offset0, const unsigned int block_size, const unsigned int blocks, const unsigned int block_stride);
++void rpi_cache_flush_add_frame(rpi_cache_flush_env_t * const rfe, const AVFrame * const frame, const rpi_cache_flush_mode_t mode);
++void rpi_cache_flush_add_frame_block(rpi_cache_flush_env_t * const rfe, const AVFrame * const frame, const rpi_cache_flush_mode_t mode,
++ const unsigned int x0, const unsigned int y0, const unsigned int width, const unsigned int height,
++ const unsigned int uv_shift, const int do_luma, const int do_chroma);
++
++// init, add, finish for one gm ptr
++void rpi_cache_flush_one_gm_ptr(const GPU_MEM_PTR_T * const p, const rpi_cache_flush_mode_t mode);
++
++
++// QPU specific functions
++
++typedef struct HEVCRpiQpu {
++ uint32_t c_pxx;
++ uint32_t c_pxx_l1;
++ uint32_t c_bxx;
++ uint32_t y_pxx;
++ uint32_t y_bxx;
++ uint32_t y_p00;
++ uint32_t y_b00;
++} HEVCRpiQpu;
++
++int rpi_hevc_qpu_init_fn(HEVCRpiQpu * const qf, const unsigned int bit_depth);
++
++uint32_t qpu_fn(const int * const mc_fn);
++uint32_t qpu_dummy(void);
++
++#define QPU_N_GRP 4
++#define QPU_N_MAX 12
++
++#define QPU_MAIL_EL_VALS 2
++
++struct vpu_qpu_wait_s;
++typedef struct vq_wait_s * vpu_qpu_wait_h;
++
++// VPU specific functions
++
++struct vpu_qpu_job_env_s;
++typedef struct vpu_qpu_job_env_s * vpu_qpu_job_h;
++
++#define VPU_QPU_JOB_MAX 4
++struct vpu_qpu_job_env_s
++{
++ unsigned int n;
++ unsigned int mask;
++ struct gpu_job_s j[VPU_QPU_JOB_MAX];
++};
++typedef struct vpu_qpu_job_env_s vpu_qpu_job_env_t;
++
++vpu_qpu_job_h vpu_qpu_job_init(vpu_qpu_job_env_t * const buf);
++void vpu_qpu_job_delete(const vpu_qpu_job_h vqj);
++void vpu_qpu_job_add_vpu(const vpu_qpu_job_h vqj, const uint32_t vpu_code,
++ const unsigned r0, const unsigned r1, const unsigned r2, const unsigned r3, const unsigned r4, const unsigned r5);
++void vpu_qpu_job_add_qpu(const vpu_qpu_job_h vqj, const unsigned int n, const uint32_t * const mail);
++void vpu_qpu_job_add_sync_this(const vpu_qpu_job_h vqj, vpu_qpu_wait_h * const wait_h);
++int vpu_qpu_job_add_sync_sem(vpu_qpu_job_env_t * const vqj, sem_t * const sem);
++int vpu_qpu_job_start(const vpu_qpu_job_h vqj);
++int vpu_qpu_job_finish(const vpu_qpu_job_h vqj);
++
++extern unsigned int vpu_get_fn(const unsigned int bit_depth);
++extern unsigned int vpu_get_constants(void);
++
++// Waits for previous post_codee to complete and Will null out *wait_h after use
++void vpu_qpu_wait(vpu_qpu_wait_h * const wait_h);
++int vpu_qpu_init(void);
++void vpu_qpu_term(void);
++
++extern int gpu_get_mailbox(void);
++void gpu_ref(void);
++void gpu_unref(void);
++
++#endif
+diff --git a/libavcodec/rpi_zc.c b/libavcodec/rpi_zc.c
+new file mode 100644
+index 0000000000..185288da5a
+--- /dev/null
++++ b/libavcodec/rpi_zc.c
+@@ -0,0 +1,741 @@
++#include "libavcodec/avcodec.h"
++#include "rpi_qpu.h"
++#include "rpi_mailbox.h"
++#include "rpi_zc.h"
++#include "libavutil/avassert.h"
++#include "libavutil/rpi_sand_fns.h"
++#include <pthread.h>
++
++#include "libavutil/buffer_internal.h"
++#include <interface/vctypes/vc_image_types.h>
++
++#define TRACE_ALLOC 0
++
++struct ZcPoolEnt;
++
++typedef struct ZcPool
++{
++ int numbytes;
++ unsigned int n;
++ struct ZcPoolEnt * head;
++ pthread_mutex_t lock;
++} ZcPool;
++
++typedef struct ZcPoolEnt
++{
++ // It is important that we start with gmem as other bits of code will expect to see that
++ GPU_MEM_PTR_T gmem;
++ unsigned int n;
++ struct ZcPoolEnt * next;
++ struct ZcPool * pool;
++} ZcPoolEnt;
++
++#define ALLOC_PAD 0
++#define ALLOC_ROUND 0x1000
++#define ALLOC_N_OFFSET 0
++#define STRIDE_ROUND 64
++#define STRIDE_OR 0
++
++#define DEBUG_ZAP0_BUFFERS 0
++
++
++static ZcPoolEnt * zc_pool_ent_alloc(ZcPool * const pool, const unsigned int req_size)
++{
++ ZcPoolEnt * const zp = av_malloc(sizeof(ZcPoolEnt));
++
++ // Round up to 4k & add 4k
++ const unsigned int alloc_size = (req_size + ALLOC_PAD + ALLOC_ROUND - 1) & ~(ALLOC_ROUND - 1);
++
++ if (zp == NULL) {
++ av_log(NULL, AV_LOG_ERROR, "av_malloc(ZcPoolEnt) failed\n");
++ goto fail0;
++ }
++
++ if (gpu_malloc_cached(alloc_size, &zp->gmem) != 0)
++ {
++ av_log(NULL, AV_LOG_ERROR, "av_gpu_malloc_cached(%d) failed\n", alloc_size);
++ goto fail1;
++ }
++
++#if TRACE_ALLOC
++ printf("%s: Alloc %#x bytes @ %p\n", __func__, zp->gmem.numbytes, zp->gmem.arm);
++#endif
++
++ pool->numbytes = zp->gmem.numbytes;
++ zp->next = NULL;
++ zp->pool = pool;
++ zp->n = pool->n++;
++ return zp;
++
++fail1:
++ av_free(zp);
++fail0:
++ return NULL;
++}
++
++static void zc_pool_ent_free(ZcPoolEnt * const zp)
++{
++#if TRACE_ALLOC
++ printf("%s: Free %#x bytes @ %p\n", __func__, zp->gmem.numbytes, zp->gmem.arm);
++#endif
++
++ gpu_free(&zp->gmem);
++ av_free(zp);
++}
++
++static void zc_pool_flush(ZcPool * const pool)
++{
++ ZcPoolEnt * p = pool->head;
++ pool->head = NULL;
++ pool->numbytes = -1;
++
++ while (p != NULL)
++ {
++ ZcPoolEnt * const zp = p;
++ p = p->next;
++ zc_pool_ent_free(zp);
++ }
++}
++
++static ZcPoolEnt * zc_pool_alloc(ZcPool * const pool, const int req_bytes)
++{
++ ZcPoolEnt * zp;
++ int numbytes;
++
++ pthread_mutex_lock(&pool->lock);
++
++ numbytes = pool->numbytes;
++
++ // If size isn't close then dump the pool
++ // Close in this context means within 128k
++ if (req_bytes > numbytes || req_bytes + 0x20000 < numbytes)
++ {
++ zc_pool_flush(pool);
++ numbytes = req_bytes;
++ }
++
++ if (pool->head != NULL)
++ {
++ zp = pool->head;
++ pool->head = zp->next;
++ }
++ else
++ {
++ zp = zc_pool_ent_alloc(pool, numbytes);
++ }
++
++ pthread_mutex_unlock(&pool->lock);
++
++ // Start with our buffer empty of preconceptions
++// rpi_cache_flush_one_gm_ptr(&zp->gmem, RPI_CACHE_FLUSH_MODE_WB_INVALIDATE);
++
++ return zp;
++}
++
++static void zc_pool_free(ZcPoolEnt * const zp)
++{
++ ZcPool * const pool = zp == NULL ? NULL : zp->pool;
++ if (zp != NULL)
++ {
++ pthread_mutex_lock(&pool->lock);
++#if TRACE_ALLOC
++ printf("%s: Recycle %#x, %#x\n", __func__, pool->numbytes, zp->gmem.numbytes);
++#endif
++
++ if (pool->numbytes == zp->gmem.numbytes)
++ {
++ zp->next = pool->head;
++ pool->head = zp;
++ pthread_mutex_unlock(&pool->lock);
++ }
++ else
++ {
++ pthread_mutex_unlock(&pool->lock);
++ zc_pool_ent_free(zp);
++ }
++ }
++}
++
++static void
++zc_pool_init(ZcPool * const pool)
++{
++ pool->numbytes = -1;
++ pool->head = NULL;
++ pthread_mutex_init(&pool->lock, NULL);
++}
++
++static void
++zc_pool_destroy(ZcPool * const pool)
++{
++ pool->numbytes = -1;
++ zc_pool_flush(pool);
++ pthread_mutex_destroy(&pool->lock);
++}
++
++typedef struct ZcOldCtxVals
++{
++ int thread_safe_callbacks;
++ int (*get_buffer2)(struct AVCodecContext *s, AVFrame *frame, int flags);
++ void * get_buffer_context;
++} ZcOldCtxVals;
++
++typedef struct AVZcEnv
++{
++ unsigned int refcount;
++ ZcPool pool;
++ ZcOldCtxVals old;
++} ZcEnv;
++
++// Callback when buffer unrefed to zero
++static void rpi_free_display_buffer(void *opaque, uint8_t *data)
++{
++ ZcPoolEnt *const zp = opaque;
++// printf("%s: data=%p\n", __func__, data);
++ zc_pool_free(zp);
++}
++
++static inline GPU_MEM_PTR_T * pic_gm_ptr(AVBufferRef * const buf)
++{
++ // Kludge where we check the free fn to check this is really
++ // one of our buffers - can't think of a better way
++ return buf == NULL || buf->buffer->free != rpi_free_display_buffer ? NULL :
++ av_buffer_get_opaque(buf);
++}
++
++AVRpiZcFrameGeometry av_rpi_zc_frame_geometry(
++ const int format, const unsigned int video_width, const unsigned int video_height)
++{
++ AVRpiZcFrameGeometry geo;
++
++ switch (format)
++ {
++ case AV_PIX_FMT_YUV420P:
++ geo.stride_y = ((video_width + 32 + STRIDE_ROUND - 1) & ~(STRIDE_ROUND - 1)) | STRIDE_OR;
++ geo.stride_c = geo.stride_y / 2;
++ geo.height_y = (video_height + 32 + 31) & ~31;
++ geo.height_c = geo.height_y / 2;
++ geo.planes_c = 2;
++ geo.stripes = 1;
++ geo.bytes_per_pel = 1;
++ break;
++
++ case AV_PIX_FMT_YUV420P10:
++ geo.stride_y = ((video_width * 2 + 64 + STRIDE_ROUND - 1) & ~(STRIDE_ROUND - 1)) | STRIDE_OR;
++ geo.stride_c = geo.stride_y / 2;
++ geo.height_y = (video_height + 32 + 31) & ~31;
++ geo.height_c = geo.height_y / 2;
++ geo.planes_c = 2;
++ geo.stripes = 1;
++ geo.bytes_per_pel = 2;
++ break;
++
++ case AV_PIX_FMT_SAND128:
++ {
++ const unsigned int stripe_w = 128;
++
++ static pthread_mutex_t sand_lock = PTHREAD_MUTEX_INITIALIZER;
++ static VC_IMAGE_T img = {0};
++
++ // Given the overhead of calling the mailbox keep a stashed
++ // copy as we will almost certainly just want the same numbers again
++ // but that means we need a lock
++ pthread_mutex_lock(&sand_lock);
++
++ if (img.width != video_width || img.height != video_height)
++ {
++ VC_IMAGE_T new_img = {
++ .type = VC_IMAGE_YUV_UV,
++ .width = video_width,
++ .height = video_height
++ };
++
++ gpu_ref();
++ mbox_get_image_params(gpu_get_mailbox(), &new_img);
++ gpu_unref();
++ img = new_img;
++ }
++
++ geo.stride_y = stripe_w;
++ geo.stride_c = stripe_w;
++ geo.height_y = ((intptr_t)img.extra.uv.u - (intptr_t)img.image_data) / stripe_w;
++ geo.height_c = img.pitch / stripe_w - geo.height_y;
++ geo.planes_c = 1;
++ geo.stripes = (video_width + stripe_w - 1) / stripe_w;
++ geo.bytes_per_pel = 1;
++
++ pthread_mutex_unlock(&sand_lock);
++
++ av_assert0((int)geo.height_y > 0 && (int)geo.height_c > 0);
++ av_assert0(geo.height_y >= video_height && geo.height_c >= video_height / 2);
++ break;
++ }
++
++ case AV_PIX_FMT_SAND64_16:
++ case AV_PIX_FMT_SAND64_10:
++ {
++ const unsigned int stripe_w = 128; // bytes
++
++ static pthread_mutex_t sand_lock = PTHREAD_MUTEX_INITIALIZER;
++ static VC_IMAGE_T img = {0};
++
++ // Given the overhead of calling the mailbox keep a stashed
++ // copy as we will almost certainly just want the same numbers again
++ // but that means we need a lock
++ pthread_mutex_lock(&sand_lock);
++
++ if (img.width != video_width || img.height != video_height)
++ {
++ VC_IMAGE_T new_img = {
++ .type = VC_IMAGE_YUV_UV_16,
++ .width = video_width,
++ .height = video_height
++ };
++
++ gpu_ref();
++ mbox_get_image_params(gpu_get_mailbox(), &new_img);
++ gpu_unref();
++ img = new_img;
++ }
++
++ geo.stride_y = stripe_w;
++ geo.stride_c = stripe_w;
++ geo.height_y = ((intptr_t)img.extra.uv.u - (intptr_t)img.image_data) / stripe_w;
++ geo.height_c = img.pitch / stripe_w - geo.height_y;
++ geo.planes_c = 1;
++ geo.stripes = (video_width * 2 + stripe_w - 1) / stripe_w;
++ geo.bytes_per_pel = 2;
++
++ pthread_mutex_unlock(&sand_lock);
++ break;
++ }
++
++ default:
++ memset(&geo, 0, sizeof(geo));
++ break;
++ }
++ return geo;
++}
++
++
++static AVBufferRef * rpi_buf_pool_alloc(ZcPool * const pool, int size)
++{
++ ZcPoolEnt *const zp = zc_pool_alloc(pool, size);
++ AVBufferRef * buf;
++ intptr_t idata = (intptr_t)zp->gmem.arm;
++#if ALLOC_N_OFFSET != 0
++ intptr_t noff = (zp->n * ALLOC_N_OFFSET) & (ALLOC_PAD - 1);
++#endif
++
++ if (zp == NULL) {
++ av_log(NULL, AV_LOG_ERROR, "zc_pool_alloc(%d) failed\n", size);
++ goto fail0;
++ }
++
++#if ALLOC_N_OFFSET != 0
++ idata = ((idata & ~(ALLOC_PAD - 1)) | noff) + (((idata & (ALLOC_PAD - 1)) > noff) ? ALLOC_PAD : 0);
++#endif
++
++#if DEBUG_ZAP0_BUFFERS
++ memset((void*)idata, 0, size);
++#endif
++
++ if ((buf = av_buffer_create((void *)idata, size, rpi_free_display_buffer, zp, AV_BUFFER_FLAG_READONLY)) == NULL)
++ {
++ av_log(NULL, AV_LOG_ERROR, "av_buffer_create() failed\n");
++ goto fail2;
++ }
++
++ return buf;
++
++fail2:
++ zc_pool_free(zp);
++fail0:
++ return NULL;
++}
++
++static int rpi_get_display_buffer(ZcEnv *const zc, AVFrame * const frame)
++{
++ const AVRpiZcFrameGeometry geo = av_rpi_zc_frame_geometry(frame->format, frame->width, frame->height);
++ const unsigned int size_y = geo.stride_y * geo.height_y;
++ const unsigned int size_c = geo.stride_c * geo.height_c;
++ const unsigned int size_pic = (size_y + size_c * geo.planes_c) * geo.stripes;
++ AVBufferRef * buf;
++ unsigned int i;
++
++// printf("Do local alloc: format=%#x, %dx%d: %u\n", frame->format, frame->width, frame->height, size_pic);
++
++ if ((buf = rpi_buf_pool_alloc(&zc->pool, size_pic)) == NULL)
++ {
++ av_log(NULL, AV_LOG_ERROR, "rpi_get_display_buffer: Failed to get buffer from pool\n");
++ return AVERROR(ENOMEM);
++ }
++
++ for (i = 0; i < AV_NUM_DATA_POINTERS; i++) {
++ frame->buf[i] = NULL;
++ frame->data[i] = NULL;
++ frame->linesize[i] = 0;
++ }
++
++ frame->buf[0] = buf;
++
++ frame->linesize[0] = geo.stride_y;
++ frame->linesize[1] = geo.stride_c;
++ frame->linesize[2] = geo.stride_c;
++ // abuse: linesize[3] = "stripe stride"
++ // stripe_stride is NOT the stride between slices it is (that / geo.stride_y).
++ // In a general case this makes the calculation an xor and multiply rather
++ // than a divide and multiply
++ if (geo.stripes > 1)
++ frame->linesize[3] = geo.height_y + geo.height_c;
++
++ frame->data[0] = buf->data;
++ frame->data[1] = frame->data[0] + size_y;
++ if (geo.planes_c > 1)
++ frame->data[2] = frame->data[1] + size_c;
++
++ frame->extended_data = frame->data;
++ // Leave extended buf alone
++
++#if RPI_ZC_SAND_8_IN_10_BUF != 0
++ // *** If we intend to use this for real we will want a 2nd buffer pool
++ frame->buf[RPI_ZC_SAND_8_IN_10_BUF] = rpi_buf_pool_alloc(&zc->pool, size_pic); // *** 2 * wanted size - kludge
++#endif
++
++ return 0;
++}
++
++#define RPI_GET_BUFFER2 1
++
++int av_rpi_zc_get_buffer2(struct AVCodecContext *s, AVFrame *frame, int flags)
++{
++#if !RPI_GET_BUFFER2
++ return avcodec_default_get_buffer2(s, frame, flags);
++#else
++ int rv;
++
++ if ((s->codec->capabilities & AV_CODEC_CAP_DR1) == 0)
++ {
++// printf("Do default alloc: format=%#x\n", frame->format);
++ rv = avcodec_default_get_buffer2(s, frame, flags);
++ }
++ else if (frame->format == AV_PIX_FMT_YUV420P ||
++ av_rpi_is_sand_frame(frame))
++ {
++ rv = rpi_get_display_buffer(s->get_buffer_context, frame);
++ }
++ else
++ {
++ rv = avcodec_default_get_buffer2(s, frame, flags);
++ }
++
++#if 0
++ printf("%s: fmt:%d, %dx%d lsize=%d/%d/%d/%d data=%p/%p/%p bref=%p/%p/%p opaque[0]=%p\n", __func__,
++ frame->format, frame->width, frame->height,
++ frame->linesize[0], frame->linesize[1], frame->linesize[2], frame->linesize[3],
++ frame->data[0], frame->data[1], frame->data[2],
++ frame->buf[0], frame->buf[1], frame->buf[2],
++ av_buffer_get_opaque(frame->buf[0]));
++#endif
++ return rv;
++#endif
++}
++
++
++static AVBufferRef * zc_copy(struct AVCodecContext * const s,
++ const AVFrame * const src)
++{
++ AVFrame dest_frame;
++ AVFrame * const dest = &dest_frame;
++ unsigned int i;
++ uint8_t * psrc, * pdest;
++
++ dest->format = src->format;
++ dest->width = src->width;
++ dest->height = src->height;
++
++ if (rpi_get_display_buffer(s->get_buffer_context, dest) != 0)
++ {
++ return NULL;
++ }
++
++ for (i = 0, psrc = src->data[0], pdest = dest->data[0];
++ i != dest->height;
++ ++i, psrc += src->linesize[0], pdest += dest->linesize[0])
++ {
++ memcpy(pdest, psrc, dest->width);
++ }
++ for (i = 0, psrc = src->data[1], pdest = dest->data[1];
++ i != dest->height / 2;
++ ++i, psrc += src->linesize[1], pdest += dest->linesize[1])
++ {
++ memcpy(pdest, psrc, dest->width / 2);
++ }
++ for (i = 0, psrc = src->data[2], pdest = dest->data[2];
++ i != dest->height / 2;
++ ++i, psrc += src->linesize[2], pdest += dest->linesize[2])
++ {
++ memcpy(pdest, psrc, dest->width / 2);
++ }
++
++ return dest->buf[0];
++}
++
++
++static AVBufferRef * zc_420p10_to_sand128(struct AVCodecContext * const s,
++ const AVFrame * const src)
++{
++ AVFrame dest_frame;
++ AVFrame * const dest = &dest_frame;
++ unsigned int i;
++ uint8_t * psrc, * psrc2, * pdest;
++
++ memset(dest, 0, sizeof(*dest));
++ dest->format = AV_PIX_FMT_SAND128;
++ dest->width = src->width;
++ dest->height = src->height;
++
++ if (rpi_get_display_buffer(s->get_buffer_context, dest) != 0)
++ {
++ return NULL;
++ }
++
++ // Y
++ for (i = 0, psrc = src->data[0], pdest = dest->data[0];
++ i != dest->height;
++ ++i, psrc += src->linesize[0], pdest += dest->linesize[0])
++ {
++ uint16_t * s = (uint16_t*)psrc;
++ uint8_t * d = pdest;
++ for (unsigned int k = 0; k < dest->width; k += dest->linesize[0])
++ {
++ const unsigned int n = FFMIN(dest->linesize[0], dest->width - k);
++ for (unsigned int j = 0; j != n; ++j)
++ *d++ = (uint8_t)(*s++ >> 2);
++ d += (dest->linesize[3] - 1) * dest->linesize[0];
++ }
++ }
++
++ // C
++ for (i = 0, psrc = src->data[1], psrc2 = src->data[2], pdest = dest->data[1];
++ i != dest->height / 2;
++ ++i, psrc += src->linesize[1], psrc2 += src->linesize[2], pdest += dest->linesize[1])
++ {
++ const uint16_t * su = (uint16_t*)psrc;
++ const uint16_t * sv = (uint16_t*)psrc2;
++ uint8_t * d = pdest;
++ for (unsigned int k = 0; k < dest->width; k += dest->linesize[1])
++ {
++ const unsigned int n = FFMIN(dest->linesize[1], dest->width - k) / 2;
++ for (unsigned int j = 0; j != n; ++j)
++ {
++ *d++ = (uint8_t)(*su++ >> 2);
++ *d++ = (uint8_t)(*sv++ >> 2);
++ }
++ d += (dest->linesize[3] - 1) * dest->linesize[1];
++ }
++ }
++
++ return dest->buf[0];
++}
++
++
++static AVBufferRef * zc_sand64_16_to_sand128(struct AVCodecContext * const s,
++ const AVFrame * const src, const unsigned int src_bits)
++{
++ AVFrame dest_frame = {
++ .format = AV_PIX_FMT_SAND128,
++ .width = src->width,
++ .height = src->height
++ };
++ AVFrame * const dest = &dest_frame;
++ const unsigned int shr = src_bits - 8;
++
++ if (rpi_get_display_buffer(s->get_buffer_context, dest) != 0)
++ {
++ return NULL;
++ }
++
++ // Y
++ av_rpi_sand16_to_sand8(dest->data[0], dest->linesize[0], av_rpi_sand_frame_stride2(dest),
++ src->data[0], src->linesize[0], av_rpi_sand_frame_stride2(dest),
++ src->width, src->height, shr);
++ // C
++ av_rpi_sand16_to_sand8(dest->data[1], dest->linesize[1], av_rpi_sand_frame_stride2(dest),
++ src->data[1], src->linesize[1], av_rpi_sand_frame_stride2(dest),
++ src->width, src->height / 2, shr);
++
++ return dest->buf[0];
++}
++
++
++
++AVRpiZcRefPtr av_rpi_zc_ref(struct AVCodecContext * const s,
++ const AVFrame * const frame, const enum AVPixelFormat expected_format, const int maycopy)
++{
++ assert(s != NULL);
++
++ if (frame->format != AV_PIX_FMT_YUV420P &&
++ frame->format != AV_PIX_FMT_YUV420P10 &&
++ !av_rpi_is_sand_frame(frame))
++ {
++ av_log(s, AV_LOG_WARNING, "%s: *** Format not SAND/YUV420P: %d\n", __func__, frame->format);
++ return NULL;
++ }
++
++ if (frame->buf[1] != NULL || frame->format != expected_format)
++ {
++#if RPI_ZC_SAND_8_IN_10_BUF
++ if (frame->format == AV_PIX_FMT_SAND64_10 && expected_format == AV_PIX_FMT_SAND128 && frame->buf[RPI_ZC_SAND_8_IN_10_BUF] != NULL)
++ {
++// av_log(s, AV_LOG_INFO, "%s: --- found buf[4]\n", __func__);
++ return av_buffer_ref(frame->buf[RPI_ZC_SAND_8_IN_10_BUF]);
++ }
++#endif
++
++ if (maycopy)
++ {
++ if (frame->buf[1] != NULL)
++ av_log(s, AV_LOG_INFO, "%s: *** Not a single buf frame: copying\n", __func__);
++ else
++ av_log(s, AV_LOG_INFO, "%s: *** Unexpected frame format %d: copying to %d\n", __func__, frame->format, expected_format);
++
++ switch (frame->format)
++ {
++ case AV_PIX_FMT_YUV420P10:
++ return zc_420p10_to_sand128(s, frame);
++
++ case AV_PIX_FMT_SAND64_10:
++ return zc_sand64_16_to_sand128(s, frame, 10);
++
++ default:
++ return zc_copy(s, frame);
++ }
++ }
++ else
++ {
++ if (frame->buf[1] != NULL)
++ av_log(s, AV_LOG_WARNING, "%s: *** Not a single buf frame: buf[1] != NULL\n", __func__);
++ else
++ av_log(s, AV_LOG_INFO, "%s: *** Unexpected frame format: %d != %d\n", __func__, frame->format, expected_format);
++ return NULL;
++ }
++ }
++
++ if (pic_gm_ptr(frame->buf[0]) == NULL)
++ {
++ if (maycopy)
++ {
++ av_log(s, AV_LOG_INFO, "%s: *** Not one of our buffers: copying\n", __func__);
++ return zc_copy(s, frame);
++ }
++ else
++ {
++ av_log(s, AV_LOG_WARNING, "%s: *** Not one of our buffers: NULL\n", __func__);
++ return NULL;
++ }
++ }
++
++ return av_buffer_ref(frame->buf[0]);
++}
++
++int av_rpi_zc_vc_handle(const AVRpiZcRefPtr fr_ref)
++{
++ const GPU_MEM_PTR_T * const p = pic_gm_ptr(fr_ref);
++ return p == NULL ? -1 : p->vc_handle;
++}
++
++int av_rpi_zc_offset(const AVRpiZcRefPtr fr_ref)
++{
++ const GPU_MEM_PTR_T * const p = pic_gm_ptr(fr_ref);
++ return p == NULL ? 0 : fr_ref->data - p->arm;
++}
++
++int av_rpi_zc_length(const AVRpiZcRefPtr fr_ref)
++{
++ return fr_ref == NULL ? 0 : fr_ref->size;
++}
++
++
++int av_rpi_zc_numbytes(const AVRpiZcRefPtr fr_ref)
++{
++ const GPU_MEM_PTR_T * const p = pic_gm_ptr(fr_ref);
++ return p == NULL ? 0 : p->numbytes;
++}
++
++void av_rpi_zc_unref(AVRpiZcRefPtr fr_ref)
++{
++ if (fr_ref != NULL)
++ {
++ av_buffer_unref(&fr_ref);
++ }
++}
++
++AVZcEnvPtr av_rpi_zc_env_alloc(void)
++{
++ ZcEnv * const zc = av_mallocz(sizeof(ZcEnv));
++ if (zc == NULL)
++ {
++ av_log(NULL, AV_LOG_ERROR, "av_rpi_zc_env_alloc: Context allocation failed\n");
++ return NULL;
++ }
++
++ zc_pool_init(&zc->pool);
++ return zc;
++}
++
++void av_rpi_zc_env_free(AVZcEnvPtr zc)
++{
++ if (zc != NULL)
++ {
++ zc_pool_destroy(&zc->pool); ;
++ av_free(zc);
++ }
++}
++
++int av_rpi_zc_in_use(const struct AVCodecContext * const s)
++{
++ return s->get_buffer2 == av_rpi_zc_get_buffer2;
++}
++
++int av_rpi_zc_init(struct AVCodecContext * const s)
++{
++ if (av_rpi_zc_in_use(s))
++ {
++ ZcEnv * const zc = s->get_buffer_context;
++ ++zc->refcount;
++ }
++ else
++ {
++ ZcEnv *const zc = av_rpi_zc_env_alloc();
++ if (zc == NULL)
++ {
++ return AVERROR(ENOMEM);
++ }
++
++ zc->refcount = 1;
++ zc->old.get_buffer_context = s->get_buffer_context;
++ zc->old.get_buffer2 = s->get_buffer2;
++ zc->old.thread_safe_callbacks = s->thread_safe_callbacks;
++
++ s->get_buffer_context = zc;
++ s->get_buffer2 = av_rpi_zc_get_buffer2;
++ s->thread_safe_callbacks = 1;
++ }
++ return 0;
++}
++
++void av_rpi_zc_uninit(struct AVCodecContext * const s)
++{
++ if (av_rpi_zc_in_use(s))
++ {
++ ZcEnv * const zc = s->get_buffer_context;
++ if (--zc->refcount == 0)
++ {
++ s->get_buffer2 = zc->old.get_buffer2;
++ s->get_buffer_context = zc->old.get_buffer_context;
++ s->thread_safe_callbacks = zc->old.thread_safe_callbacks;
++ av_rpi_zc_env_free(zc);
++ }
++ }
++}
++
+diff --git a/libavcodec/rpi_zc.h b/libavcodec/rpi_zc.h
+new file mode 100644
+index 0000000000..26fb3be999
+--- /dev/null
++++ b/libavcodec/rpi_zc.h
+@@ -0,0 +1,105 @@
++#ifndef LIBAVCODEC_RPI_ZC_H
++#define LIBAVCODEC_RPI_ZC_H
++
++// Zero-Copy frame code for RPi
++// RPi needs Y/U/V planes to be contiguous for display. By default
++// ffmpeg will allocate separated planes so a memcpy is needed before
++// display. This code provides a method a making ffmpeg allocate a single
++// bit of memory for the frame when can then be reference counted until
++// display has finished with it.
++
++// Frame buffer number in which to stuff an 8-bit copy of a 16-bit frame
++// 0 disables
++// *** This option still in development
++// Only works if SAO active
++// Allocates buffers that are twice the required size
++#define RPI_ZC_SAND_8_IN_10_BUF 0
++
++struct AVBufferRef;
++struct AVFrame;
++struct AVCodecContext;
++enum AVPixelFormat;
++
++// "Opaque" pointer to whatever we are using as a buffer reference
++typedef struct AVBufferRef * AVRpiZcRefPtr;
++
++struct AVZcEnv;
++typedef struct AVZcEnv * AVZcEnvPtr;
++
++typedef struct AVRpiZcFrameGeometry
++{
++ unsigned int stride_y; // Luma stride (bytes)
++ unsigned int height_y; // Luma height (lines)
++ unsigned int stride_c; // Chroma stride (bytes)
++ unsigned int height_c; // Chroma stride (lines)
++ unsigned int planes_c; // Chroma plane count (U, V = 2, interleaved = 1)
++ unsigned int stripes; // Number of stripes (sand)
++ unsigned int bytes_per_pel;
++} AVRpiZcFrameGeometry;
++
++
++AVRpiZcFrameGeometry av_rpi_zc_frame_geometry(
++ const int format,
++ const unsigned int video_width, const unsigned int video_height);
++
++// Replacement fn for avctx->get_buffer2
++// Should be set before calling avcodec_decode_open2
++//
++// N.B. in addition to to setting avctx->get_buffer2, avctx->refcounted_frames
++// must be set to 1 as otherwise the buffer info is killed before being returned
++// by avcodec_decode_video2. Note also that this means that the AVFrame that is
++// returned must be manually derefed with av_frame_unref. This should be done
++// after av_rpi_zc_ref has been called.
++int av_rpi_zc_get_buffer2(struct AVCodecContext *s, AVFrame *frame, int flags);
++
++// Generate a ZC reference to the buffer(s) in this frame
++// If the buffer doesn't appear to be one allocated by _get_buffer_2
++// then the behaviour depends on maycopy:
++// If maycopy=0 then return NULL
++// If maycopy=1 && the src frame is in a form where we can easily copy
++// the data, then allocate a new buffer and copy the data into it
++// Otherwise return NULL
++AVRpiZcRefPtr av_rpi_zc_ref(struct AVCodecContext * const s,
++ const struct AVFrame * const frame, const enum AVPixelFormat expected_format, const int maycopy);
++
++// Get the vc_handle from the frame ref
++// Returns -1 if ref doesn't look valid
++int av_rpi_zc_vc_handle(const AVRpiZcRefPtr fr_ref);
++// Get offset from the start of the memory referenced
++// by the vc_handle to valid data
++int av_rpi_zc_offset(const AVRpiZcRefPtr fr_ref);
++// Length of buffer data
++int av_rpi_zc_length(const AVRpiZcRefPtr fr_ref);
++// Get the number of bytes allocated from the frame ref
++// Returns 0 if ref doesn't look valid
++int av_rpi_zc_numbytes(const AVRpiZcRefPtr fr_ref);
++
++// Unreference the buffer refed/allocated by _zc_ref
++// If fr_ref is NULL then this will NOP
++void av_rpi_zc_unref(AVRpiZcRefPtr fr_ref);
++
++// Allocate an environment for the buffer pool used by the ZC code
++// This should be put in avctx->get_buffer_context so it can be found by
++// av_rpi_zc_get_buffer2 when it is called from ffmpeg
++AVZcEnvPtr av_rpi_zc_env_alloc(void);
++
++// Allocate the environment used by the ZC code
++void av_rpi_zc_env_free(AVZcEnvPtr);
++
++// Test to see if the context is using zc (checks get_buffer2)
++int av_rpi_zc_in_use(const struct AVCodecContext * const s);
++
++// Init ZC into a context
++// There is nothing magic in this fn - it just packages setting
++// get_buffer2 & get_buffer_context
++int av_rpi_zc_init(struct AVCodecContext * const s);
++
++// Free ZC from a context
++// There is nothing magic in this fn - it just packages unsetting
++// get_buffer2 & get_buffer_context
++void av_rpi_zc_uninit(struct AVCodecContext * const s);
++
++
++
++#endif
++
+diff --git a/libavfilter/Makefile b/libavfilter/Makefile
+index bcd5d437ff..ccb49ec8c0 100644
+--- a/libavfilter/Makefile
++++ b/libavfilter/Makefile
+@@ -346,6 +346,7 @@ OBJS-$(CONFIG_TONEMAP_FILTER) += vf_tonemap.o
+ OBJS-$(CONFIG_TRANSPOSE_FILTER) += vf_transpose.o
+ OBJS-$(CONFIG_TRIM_FILTER) += trim.o
+ OBJS-$(CONFIG_UNPREMULTIPLY_FILTER) += vf_premultiply.o framesync.o
++OBJS-$(CONFIG_UNSAND_FILTER) += vf_unsand.o
+ OBJS-$(CONFIG_UNSHARP_FILTER) += vf_unsharp.o
+ OBJS-$(CONFIG_UNSHARP_OPENCL_FILTER) += vf_unsharp_opencl.o opencl.o \
+ opencl/unsharp.o
+diff --git a/libavfilter/allfilters.c b/libavfilter/allfilters.c
+index 68b2992027..3b059fce4e 100644
+--- a/libavfilter/allfilters.c
++++ b/libavfilter/allfilters.c
+@@ -338,6 +338,7 @@ extern AVFilter ff_vf_transpose;
+ extern AVFilter ff_vf_trim;
+ extern AVFilter ff_vf_unpremultiply;
+ extern AVFilter ff_vf_unsharp;
++extern AVFilter ff_vf_unsand;
+ extern AVFilter ff_vf_unsharp_opencl;
+ extern AVFilter ff_vf_uspp;
+ extern AVFilter ff_vf_vaguedenoiser;
+diff --git a/libavfilter/avfiltergraph.c b/libavfilter/avfiltergraph.c
+index 4cc6892404..9db92322a4 100644
+--- a/libavfilter/avfiltergraph.c
++++ b/libavfilter/avfiltergraph.c
+@@ -32,6 +32,9 @@
+ #include "libavutil/internal.h"
+ #include "libavutil/opt.h"
+ #include "libavutil/pixdesc.h"
++#if CONFIG_UNSAND_FILTER
++#include "libavutil/rpi_sand_fns.h"
++#endif
+
+ #define FF_INTERNAL_FIELDS 1
+ #include "framequeue.h"
+@@ -427,6 +430,19 @@ static int can_merge_formats(AVFilterFormats *a_arg,
+ }
+ }
+
++#if CONFIG_UNSAND_FILTER
++static int has_sand_format(const AVFilterFormats * const ff)
++{
++ int i;
++ for (i = 0; i != ff->nb_formats; ++i) {
++ if (av_rpi_is_sand_format(ff->formats[i])) {
++ return 1;
++ }
++ }
++ return 0;
++}
++#endif
++
+ /**
+ * Perform one round of query_formats() and merging formats lists on the
+ * filter graph.
+@@ -467,6 +483,7 @@ static int query_formats(AVFilterGraph *graph, AVClass *log_ctx)
+ for (j = 0; j < filter->nb_inputs; j++) {
+ AVFilterLink *link = filter->inputs[j];
+ int convert_needed = 0;
++ unsigned int extra_convert_tried = 0;
+
+ if (!link)
+ continue;
+@@ -514,11 +531,14 @@ static int query_formats(AVFilterGraph *graph, AVClass *log_ctx)
+ )
+ #undef MERGE_DISPATCH
+
+- if (convert_needed) {
++ while (convert_needed) {
+ AVFilterContext *convert;
+ const AVFilter *filter;
+ AVFilterLink *inlink, *outlink;
+ char inst_name[30];
++ int can_retry = 0;
++
++ convert_needed = 0;
+
+ if (graph->disable_auto_convert) {
+ av_log(log_ctx, AV_LOG_ERROR,
+@@ -531,19 +551,45 @@ static int query_formats(AVFilterGraph *graph, AVClass *log_ctx)
+ /* couldn't merge format lists. auto-insert conversion filter */
+ switch (link->type) {
+ case AVMEDIA_TYPE_VIDEO:
+- if (!(filter = avfilter_get_by_name("scale"))) {
+- av_log(log_ctx, AV_LOG_ERROR, "'scale' filter "
+- "not present, cannot convert pixel formats.\n");
+- return AVERROR(EINVAL);
+- }
+-
+- snprintf(inst_name, sizeof(inst_name), "auto_scaler_%d",
+- scaler_count++);
++#if CONFIG_UNSAND_FILTER
++ // Only try each extra conversion once
++ // The unsand output pad should never trigger has_sand_format
++ // but it is better to be safe
++ if ((extra_convert_tried & 1) == 0 && has_sand_format(link->in_formats)) {
++ if (!(filter = avfilter_get_by_name("unsand"))) {
++ av_log(log_ctx, AV_LOG_ERROR, "'unsand' filter "
++ "not present, cannot convert pixel formats.\n");
++ return AVERROR(EINVAL);
++ }
++
++ snprintf(inst_name, sizeof(inst_name), "auto_unsand_%d",
++ scaler_count++);
++
++ if ((ret = avfilter_graph_create_filter(&convert, filter,
++ inst_name, "", NULL,
++ graph)) < 0)
++ return ret;
+
+- if ((ret = avfilter_graph_create_filter(&convert, filter,
+- inst_name, graph->scale_sws_opts, NULL,
+- graph)) < 0)
+- return ret;
++ extra_convert_tried |= 1;
++ can_retry = 1;
++ }
++ else
++#endif
++ {
++ if (!(filter = avfilter_get_by_name("scale"))) {
++ av_log(log_ctx, AV_LOG_ERROR, "'scale' filter "
++ "not present, cannot convert pixel formats.\n");
++ return AVERROR(EINVAL);
++ }
++
++ snprintf(inst_name, sizeof(inst_name), "auto_scaler_%d",
++ scaler_count++);
++
++ if ((ret = avfilter_graph_create_filter(&convert, filter,
++ inst_name, graph->scale_sws_opts, NULL,
++ graph)) < 0)
++ return ret;
++ }
+ break;
+ case AVMEDIA_TYPE_AUDIO:
+ if (!(filter = avfilter_get_by_name("aresample"))) {
+@@ -585,9 +631,19 @@ static int query_formats(AVFilterGraph *graph, AVClass *log_ctx)
+ av_assert0(outlink-> in_channel_layouts->refcount > 0);
+ av_assert0(outlink->out_channel_layouts->refcount > 0);
+ }
+- if (!ff_merge_formats( inlink->in_formats, inlink->out_formats, inlink->type) ||
+- !ff_merge_formats(outlink->in_formats, outlink->out_formats, outlink->type))
++ // If we have added an extra filter we must merge the input
++ // side but we can have another go at the output
++ if (!ff_merge_formats( inlink->in_formats, inlink->out_formats, inlink->type))
++ ret = AVERROR(ENOSYS);
++ else if (!ff_merge_formats(outlink->in_formats, outlink->out_formats, outlink->type))
++ {
++ if (can_retry) {
++ link = outlink;
++ convert_needed = 1;
++ continue;
++ }
+ ret = AVERROR(ENOSYS);
++ }
+ if (inlink->type == AVMEDIA_TYPE_AUDIO &&
+ (!ff_merge_samplerates(inlink->in_samplerates,
+ inlink->out_samplerates) ||
+diff --git a/libavfilter/buffersrc.c b/libavfilter/buffersrc.c
+index cd56f8ca45..813a682aa1 100644
+--- a/libavfilter/buffersrc.c
++++ b/libavfilter/buffersrc.c
+@@ -207,7 +207,7 @@ static int av_buffersrc_add_frame_internal(AVFilterContext *ctx,
+
+ switch (ctx->outputs[0]->type) {
+ case AVMEDIA_TYPE_VIDEO:
+- CHECK_VIDEO_PARAM_CHANGE(ctx, s, frame->width, frame->height,
++ CHECK_VIDEO_PARAM_CHANGE(ctx, s, av_frame_cropped_width(frame), av_frame_cropped_height(frame),
+ frame->format);
+ break;
+ case AVMEDIA_TYPE_AUDIO:
+diff --git a/libavfilter/vf_unsand.c b/libavfilter/vf_unsand.c
+new file mode 100644
+index 0000000000..64578b7ac4
+--- /dev/null
++++ b/libavfilter/vf_unsand.c
+@@ -0,0 +1,232 @@
++/*
++ * Copyright (c) 2007 Bobby Bingham
++ *
++ * This file is part of FFmpeg.
++ *
++ * FFmpeg is free software; you can redistribute it and/or
++ * modify it under the terms of the GNU Lesser General Public
++ * License as published by the Free Software Foundation; either
++ * version 2.1 of the License, or (at your option) any later version.
++ *
++ * FFmpeg is distributed in the hope that it will be useful,
++ * but WITHOUT ANY WARRANTY; without even the implied warranty of
++ * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
++ * Lesser General Public License for more details.
++ *
++ * You should have received a copy of the GNU Lesser General Public
++ * License along with FFmpeg; if not, write to the Free Software
++ * Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA
++ */
++
++/**
++ * @file
++ * format and noformat video filters
++ */
++
++#include <string.h>
++
++#include "libavutil/internal.h"
++#include "libavutil/mem.h"
++#include "libavutil/pixdesc.h"
++#include "libavutil/opt.h"
++#include "libavutil/rpi_sand_fns.h"
++
++#include "avfilter.h"
++#include "formats.h"
++#include "internal.h"
++#include "video.h"
++
++typedef struct UnsandContext {
++ const AVClass *class;
++} UnsandContext;
++
++static av_cold void uninit(AVFilterContext *ctx)
++{
++// UnsandContext *s = ctx->priv;
++}
++
++static av_cold int init(AVFilterContext *ctx)
++{
++// UnsandContext *s = ctx->priv;
++
++ return 0;
++}
++
++
++static int filter_frame(AVFilterLink *link, AVFrame *in)
++{
++ AVFilterLink * const outlink = link->dst->outputs[0];
++ AVFrame *out = NULL;
++ int rv = 0;
++
++ if (outlink->format == in->format) {
++ // If nothing to do then do nothing
++ out = in;
++ }
++ else
++ {
++ if ((out = ff_get_video_buffer(outlink, av_frame_cropped_width(in), av_frame_cropped_height(in))) == NULL)
++ {
++ rv = AVERROR(ENOMEM);
++ goto fail;
++ }
++ if (av_rpi_sand_to_planar_frame(out, in) != 0)
++ {
++ rv = -1;
++ goto fail;
++ }
++
++ av_frame_free(&in);
++ }
++
++ return ff_filter_frame(outlink, out);
++
++fail:
++ av_frame_free(&out);
++ av_frame_free(&in);
++ return rv;
++}
++
++#if 0
++static void dump_fmts(const AVFilterFormats * fmts)
++{
++ int i;
++ if (fmts== NULL) {
++ printf("NULL\n");
++ return;
++ }
++ for (i = 0; i < fmts->nb_formats; ++i) {
++ printf(" %d", fmts->formats[i]);
++ }
++ printf("\n");
++}
++#endif
++
++static int query_formats(AVFilterContext *ctx)
++{
++// UnsandContext *s = ctx->priv;
++ int ret;
++
++ // If we aren't connected at both ends then just do nothing
++ if (ctx->inputs[0] == NULL || ctx->outputs[0] == NULL)
++ return 0;
++
++// printf("Unsand: %s in: ", __func__);
++// dump_fmts(ctx->inputs[0]->in_formats);
++// printf("Unsand: %s out: ", __func__);
++// dump_fmts(ctx->outputs[0]->out_formats);
++
++ // Our output formats depend on our input formats and we can't/don't
++ // want to convert between bit depths so we need to wait for the source
++ // to have an opinion before we do
++ if (ctx->inputs[0]->in_formats == NULL)
++ return AVERROR(EAGAIN);
++
++ // Accept anything
++ if (ctx->inputs[0]->out_formats == NULL &&
++ (ret = ff_formats_ref(ctx->inputs[0]->in_formats, &ctx->inputs[0]->out_formats)) < 0)
++ return ret;
++
++ // Filter out sand formats
++
++ // Generate a container if we don't already have one
++ if (ctx->outputs[0]->in_formats == NULL)
++ {
++ // Somewhat rubbish way of ensuring we have a good structure
++ const static enum AVPixelFormat out_fmts[] = {AV_PIX_FMT_YUV420P10, AV_PIX_FMT_YUV420P, AV_PIX_FMT_NONE};
++ AVFilterFormats *formats = ff_make_format_list(out_fmts);
++
++ if (formats == NULL)
++ return AVERROR(ENOMEM);
++ if ((ret = ff_formats_ref(formats, &ctx->outputs[0]->in_formats)) < 0)
++ return ret;
++ }
++
++ // Replace old format list with new filtered list derived from what our
++ // input says it can do
++ {
++ const AVFilterFormats * const src_ff = ctx->inputs[0]->out_formats;
++ AVFilterFormats * const dst_ff = ctx->outputs[0]->in_formats;
++ enum AVPixelFormat *dst_fmts = av_malloc(sizeof(enum AVPixelFormat) * src_ff->nb_formats);
++ int i;
++ int n = 0;
++ int seen_420p = 0;
++ int seen_420p10 = 0;
++
++ for (i = 0; i < src_ff->nb_formats; ++i) {
++ const enum AVPixelFormat f = src_ff->formats[i];
++
++ switch (f){
++ case AV_PIX_FMT_YUV420P:
++ case AV_PIX_FMT_SAND128:
++ if (!seen_420p) {
++ seen_420p = 1;
++ dst_fmts[n++] = AV_PIX_FMT_YUV420P;
++ }
++ break;
++ case AV_PIX_FMT_SAND64_10:
++ case AV_PIX_FMT_YUV420P10:
++ if (!seen_420p10) {
++ seen_420p10 = 1;
++ dst_fmts[n++] = AV_PIX_FMT_YUV420P10;
++ }
++ break;
++ default:
++ dst_fmts[n++] = f;
++ break;
++ }
++ }
++
++ av_freep(&dst_ff->formats);
++ dst_ff->formats = dst_fmts;
++ dst_ff->nb_formats = n;
++ }
++
++// printf("Unsand: %s calc: ", __func__);
++// dump_fmts(ctx->outputs[0]->in_formats);
++
++ return 0;
++}
++
++
++#define OFFSET(x) offsetof(UnsandContext, x)
++static const AVOption unsand_options[] = {
++ { NULL }
++};
++
++
++AVFILTER_DEFINE_CLASS(unsand);
++
++static const AVFilterPad avfilter_vf_unsand_inputs[] = {
++ {
++ .name = "default",
++ .type = AVMEDIA_TYPE_VIDEO,
++ .filter_frame = filter_frame,
++ },
++ { NULL }
++};
++
++static const AVFilterPad avfilter_vf_unsand_outputs[] = {
++ {
++ .name = "default",
++ .type = AVMEDIA_TYPE_VIDEO
++ },
++ { NULL }
++};
++
++AVFilter ff_vf_unsand = {
++ .name = "unsand",
++ .description = NULL_IF_CONFIG_SMALL("Convert sand pix fmt to yuv"),
++
++ .init = init,
++ .uninit = uninit,
++
++ .query_formats = query_formats,
++
++ .priv_size = sizeof(UnsandContext),
++ .priv_class = &unsand_class,
++
++ .inputs = avfilter_vf_unsand_inputs,
++ .outputs = avfilter_vf_unsand_outputs,
++};
++
+diff --git a/libavformat/utils.c b/libavformat/utils.c
+index c25eab4d49..4db44315c7 100644
+--- a/libavformat/utils.c
++++ b/libavformat/utils.c
+@@ -3005,6 +3005,40 @@ static int has_codec_parameters(AVStream *st, const char **errmsg_ptr)
+ return 1;
+ }
+
++#if CONFIG_HEVC_RPI_DECODER && CONFIG_HEVC_DECODER
++// This should be quite general purpose but avoid possible conflicts
++// by limiting usage to cases wehere we know it works.
++static int try_fallback_decoder(AVCodecContext * const avctx, const AVCodec *const old_codec, AVDictionary ** const opts)
++{
++ // Only try fallback if we know it is supported (HEVC only)
++ const AVCodec *const new_codec = old_codec->id != AV_CODEC_ID_HEVC ? NULL :
++ avcodec_find_decoder_by_id_and_fmt(old_codec->id, AV_PIX_FMT_NONE);
++ int err;
++
++ // Failed to find fallback or we are already at the fallback
++ if (new_codec == NULL || new_codec == old_codec)
++ {
++ return AVERROR_DECODER_NOT_FOUND;
++ }
++
++ // * This may be dodgy - header says to not use this fn,
++ // especially if we are going to reopen the context...
++ // (but it does seem to work for our cases)
++ if (avcodec_is_open(avctx)) {
++ avcodec_close(avctx);
++ }
++
++ if ((err = avcodec_open2(avctx, new_codec, opts)) < 0)
++ {
++ return err;
++ }
++
++ return 0;
++}
++#else
++#define try_fallback_decoder(avctx, old_codec, opts) (AVERROR_DECODER_NOT_FOUND)
++#endif
++
+ /* returns 1 or 0 if or if not decoded data was returned, or a negative error */
+ static int try_decode_frame(AVFormatContext *s, AVStream *st, AVPacket *avpkt,
+ AVDictionary **options)
+@@ -3039,7 +3073,11 @@ static int try_decode_frame(AVFormatContext *s, AVStream *st, AVPacket *avpkt,
+ av_dict_set(options ? options : &thread_opt, "threads", "1", 0);
+ if (s->codec_whitelist)
+ av_dict_set(options ? options : &thread_opt, "codec_whitelist", s->codec_whitelist, 0);
+- ret = avcodec_open2(avctx, codec, options ? options : &thread_opt);
++ if ((ret = avcodec_open2(avctx, codec, options ? options : &thread_opt)) == AVERROR_DECODER_NOT_FOUND)
++ {
++ // Try fallback if if looks worth a try
++ ret = try_fallback_decoder(avctx, codec, options ? options : &thread_opt);
++ }
+ if (!options)
+ av_dict_free(&thread_opt);
+ if (ret < 0) {
+@@ -3070,6 +3108,14 @@ static int try_decode_frame(AVFormatContext *s, AVStream *st, AVPacket *avpkt,
+ if (avctx->codec_type == AVMEDIA_TYPE_VIDEO ||
+ avctx->codec_type == AVMEDIA_TYPE_AUDIO) {
+ ret = avcodec_send_packet(avctx, &pkt);
++
++ // If we are going to want to fall back we should know here
++ if (ret == AVERROR_DECODER_NOT_FOUND) {
++ if ((ret = try_fallback_decoder(avctx, avctx->codec, options)) < 0)
++ break;
++ continue;
++ }
++
+ if (ret < 0 && ret != AVERROR(EAGAIN) && ret != AVERROR_EOF)
+ break;
+ if (ret >= 0)
+@@ -3663,9 +3709,20 @@ FF_ENABLE_DEPRECATION_WARNINGS
+ // Try to just open decoders, in case this is enough to get parameters.
+ if (!has_codec_parameters(st, NULL) && st->request_probe <= 0) {
+ if (codec && !avctx->codec)
+- if (avcodec_open2(avctx, codec, options ? &options[i] : &thread_opt) < 0)
+- av_log(ic, AV_LOG_WARNING,
+- "Failed to open codec in %s\n",__FUNCTION__);
++ {
++ int err;
++
++ if ((err = avcodec_open2(avctx, codec, options ? &options[i] : &thread_opt)) < 0)
++ {
++ if (err == AVERROR_DECODER_NOT_FOUND) {
++ err = try_fallback_decoder(avctx, codec, options ? &options[i] : &thread_opt);
++ }
++ if (err < 0) {
++ av_log(ic, AV_LOG_WARNING,
++ "Failed to open codec in %s\n",__FUNCTION__);
++ }
++ }
++ }
+ }
+ if (!options)
+ av_dict_free(&thread_opt);
+diff --git a/libavutil/Makefile b/libavutil/Makefile
+index a63ba523c9..4f9a19e800 100644
+--- a/libavutil/Makefile
++++ b/libavutil/Makefile
+@@ -164,6 +164,7 @@ OBJS-$(CONFIG_QSV) += hwcontext_qsv.o
+ OBJS-$(CONFIG_LIBDRM) += hwcontext_drm.o
+ OBJS-$(CONFIG_LZO) += lzo.o
+ OBJS-$(CONFIG_OPENCL) += hwcontext_opencl.o
++OBJS-$(CONFIG_SAND) += rpi_sand_fns.o
+ OBJS-$(CONFIG_VAAPI) += hwcontext_vaapi.o
+ OBJS-$(CONFIG_VIDEOTOOLBOX) += hwcontext_videotoolbox.o
+ OBJS-$(CONFIG_VDPAU) += hwcontext_vdpau.o
+diff --git a/libavutil/arm/Makefile b/libavutil/arm/Makefile
+index 5da44b0542..b74b7c4e2f 100644
+--- a/libavutil/arm/Makefile
++++ b/libavutil/arm/Makefile
+@@ -6,3 +6,4 @@ VFP-OBJS += arm/float_dsp_init_vfp.o \
+
+ NEON-OBJS += arm/float_dsp_init_neon.o \
+ arm/float_dsp_neon.o \
++ arm/rpi_sand_neon.o \
+diff --git a/libavutil/arm/rpi_sand_neon.S b/libavutil/arm/rpi_sand_neon.S
+new file mode 100644
+index 0000000000..dbffdaefa4
+--- /dev/null
++++ b/libavutil/arm/rpi_sand_neon.S
+@@ -0,0 +1,40 @@
++#include "libavutil/arm/asm.S"
++
++@ void rpi_sand128b_stripe_to_8_10(
++@ uint8_t * dest, [r0]
++@ const uint8_t * src1, [r1]
++@ const uint8_t * src2, [r2]
++@ unsigned int lines); [r3]
++
++.macro stripe2_to_8, bit_depth
++ vpush {q4-q7}
++1:
++ vldm r1!, {q0-q7}
++ subs r3, #1
++ vldm r2!, {q8-q15}
++ vqrshrn.u16 d0, q0, #\bit_depth - 8
++ vqrshrn.u16 d1, q1, #\bit_depth - 8
++ vqrshrn.u16 d2, q2, #\bit_depth - 8
++ vqrshrn.u16 d3, q3, #\bit_depth - 8
++ vqrshrn.u16 d4, q4, #\bit_depth - 8
++ vqrshrn.u16 d5, q5, #\bit_depth - 8
++ vqrshrn.u16 d6, q6, #\bit_depth - 8
++ vqrshrn.u16 d7, q7, #\bit_depth - 8
++ vqrshrn.u16 d8, q8, #\bit_depth - 8
++ vqrshrn.u16 d9, q9, #\bit_depth - 8
++ vqrshrn.u16 d10, q10, #\bit_depth - 8
++ vqrshrn.u16 d11, q11, #\bit_depth - 8
++ vqrshrn.u16 d12, q12, #\bit_depth - 8
++ vqrshrn.u16 d13, q13, #\bit_depth - 8
++ vqrshrn.u16 d14, q14, #\bit_depth - 8
++ vqrshrn.u16 d15, q15, #\bit_depth - 8
++ vstm r0!, {q0-q7}
++ bne 1b
++ vpop {q4-q7}
++ bx lr
++.endm
++
++function rpi_sand128b_stripe_to_8_10, export=1
++ stripe2_to_8 10
++endfunc
++
+diff --git a/libavutil/buffer.c b/libavutil/buffer.c
+index 8d1aa5fa84..649876db77 100644
+--- a/libavutil/buffer.c
++++ b/libavutil/buffer.c
+@@ -355,3 +355,9 @@ AVBufferRef *av_buffer_pool_get(AVBufferPool *pool)
+
+ return ret;
+ }
++
++// Return the opaque for the underlying frame (gives us a GPU_MEM_PTR_T)
++void *av_buffer_pool_opaque(AVBufferRef *ref) {
++ BufferPoolEntry *buf = av_buffer_get_opaque(ref);
++ return buf->opaque;
++}
+diff --git a/libavutil/buffer.h b/libavutil/buffer.h
+index 73b6bd0b14..d907de3f1c 100644
+--- a/libavutil/buffer.h
++++ b/libavutil/buffer.h
+@@ -284,6 +284,9 @@ void av_buffer_pool_uninit(AVBufferPool **pool);
+ */
+ AVBufferRef *av_buffer_pool_get(AVBufferPool *pool);
+
++// Return the opaque for the underlying frame
++void *av_buffer_pool_opaque(AVBufferRef *ref);
++
+ /**
+ * @}
+ */
+diff --git a/libavutil/frame.c b/libavutil/frame.c
+index 00215ac29a..d068f437e7 100644
+--- a/libavutil/frame.c
++++ b/libavutil/frame.c
+@@ -16,6 +16,8 @@
+ * Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA
+ */
+
++#include "config.h"
++
+ #include "channel_layout.h"
+ #include "avassert.h"
+ #include "buffer.h"
+@@ -25,6 +27,9 @@
+ #include "imgutils.h"
+ #include "mem.h"
+ #include "samplefmt.h"
++#if CONFIG_SAND
++#include "rpi_sand_fns.h"
++#endif
+
+ #if FF_API_FRAME_GET_SET
+ MAKE_ACCESSORS(AVFrame, frame, int64_t, best_effort_timestamp)
+@@ -885,6 +890,12 @@ int av_frame_apply_cropping(AVFrame *frame, int flags)
+ (frame->crop_top + frame->crop_bottom) >= frame->height)
+ return AVERROR(ERANGE);
+
++#if CONFIG_SAND
++ // Sand cannot be cropped - do not try
++ if (av_rpi_is_sand_format(frame->format))
++ return 0;
++#endif
++
+ desc = av_pix_fmt_desc_get(frame->format);
+ if (!desc)
+ return AVERROR_BUG;
+diff --git a/libavutil/frame.h b/libavutil/frame.h
+index 9d57d6ce66..1ade7bd707 100644
+--- a/libavutil/frame.h
++++ b/libavutil/frame.h
+@@ -886,6 +886,16 @@ int av_frame_apply_cropping(AVFrame *frame, int flags);
+ */
+ const char *av_frame_side_data_name(enum AVFrameSideDataType type);
+
++
++static inline int av_frame_cropped_width(const AVFrame * const frame)
++{
++ return frame->width - (frame->crop_left + frame->crop_right);
++}
++static inline int av_frame_cropped_height(const AVFrame * const frame)
++{
++ return frame->height - (frame->crop_top + frame->crop_bottom);
++}
++
+ /**
+ * @}
+ */
+diff --git a/libavutil/pixdesc.c b/libavutil/pixdesc.c
+index 8ed52751c1..71d6dd4250 100644
+--- a/libavutil/pixdesc.c
++++ b/libavutil/pixdesc.c
+@@ -2185,6 +2185,30 @@ static const AVPixFmtDescriptor av_pix_fmt_descriptors[AV_PIX_FMT_NB] = {
+ .name = "opencl",
+ .flags = AV_PIX_FMT_FLAG_HWACCEL,
+ },
++ [AV_PIX_FMT_SAND128] = {
++ .name = "sand128",
++ .nb_components = 3,
++ .log2_chroma_w = 1,
++ .log2_chroma_h = 1,
++ .comp = {
++ { 0, 1, 0, 0, 8, 0, 7, 1 }, /* Y */
++ { 1, 2, 0, 0, 8, 1, 7, 1 }, /* U */
++ { 1, 2, 1, 0, 8, 1, 7, 2 }, /* V */
++ },
++ .flags = 0,
++ },
++ [AV_PIX_FMT_SAND64_10] = {
++ .name = "sand64_10",
++ .nb_components = 3,
++ .log2_chroma_w = 1,
++ .log2_chroma_h = 1,
++ .comp = {
++ { 0, 2, 0, 0, 10, 0, 9, 1 }, /* Y */
++ { 1, 4, 0, 0, 10, 1, 9, 1 }, /* U */
++ { 1, 4, 1, 0, 10, 1, 9, 2 }, /* V */
++ },
++ .flags = 0,
++ },
+ };
+ #if FF_API_PLUS1_MINUS1
+ FF_ENABLE_DEPRECATION_WARNINGS
+diff --git a/libavutil/pixfmt.h b/libavutil/pixfmt.h
+index e184a56672..1078c192a6 100644
+--- a/libavutil/pixfmt.h
++++ b/libavutil/pixfmt.h
+@@ -330,6 +330,11 @@ enum AVPixelFormat {
+ */
+ AV_PIX_FMT_OPENCL,
+
++ // RPI - not on ifdef so can be got at by calling progs
++ AV_PIX_FMT_SAND128, ///< 4:2:0 8-bit 128x*Y stripe, 64x*UV stripe, then next x stripe, mysterious padding
++ AV_PIX_FMT_SAND64_10, ///< 4:2:0 10-bit 64x*Y stripe, 32x*UV stripe, then next x stripe, mysterious padding
++ AV_PIX_FMT_SAND64_16, ///< 4:2:0 16-bit 64x*Y stripe, 32x*UV stripe, then next x stripe, mysterious padding
++
+ AV_PIX_FMT_NB ///< number of pixel formats, DO NOT USE THIS if you want to link with shared libav* because the number of formats might differ between versions
+ };
+
+diff --git a/libavutil/rpi_sand_fn_pw.h b/libavutil/rpi_sand_fn_pw.h
+new file mode 100644
+index 0000000000..52d52a2a83
+--- /dev/null
++++ b/libavutil/rpi_sand_fn_pw.h
+@@ -0,0 +1,182 @@
++// * Included twice from rpi_sand_fn with different PW
++
++#define STRCAT(x,y) x##y
++
++#if PW == 1
++#define pixel uint8_t
++#define FUNC(f) STRCAT(f, 8)
++#elif PW == 2
++#define pixel uint16_t
++#define FUNC(f) STRCAT(f, 16)
++#else
++#error Unexpected PW
++#endif
++
++// Fetches a single patch - offscreen fixup not done here
++// w <= stride1
++// unclipped
++void FUNC(av_rpi_sand_to_planar_y)(uint8_t * dst, const unsigned int dst_stride,
++ const uint8_t * src,
++ unsigned int stride1, unsigned int stride2,
++ unsigned int _x, unsigned int y,
++ unsigned int _w, unsigned int h)
++{
++ const unsigned int x = _x;
++ const unsigned int w = _w;
++ const unsigned int mask = stride1 - 1;
++
++ if ((x & ~mask) == ((x + w) & ~mask)) {
++ // All in one sand stripe
++ const uint8_t * p = src + (x & mask) + y * stride1 + (x & ~mask) * stride2;
++ for (unsigned int i = 0; i != h; ++i, dst += dst_stride, p += stride1) {
++ memcpy(dst, p, w);
++ }
++ }
++ else
++ {
++ // Two+ stripe
++ const unsigned int sstride = stride1 * stride2;
++ const uint8_t * p1 = src + (x & mask) + y * stride1 + (x & ~mask) * stride2;
++ const uint8_t * p2 = p1 + sstride - (x & mask);
++ const unsigned int w1 = stride1 - (x & mask);
++ const unsigned int w3 = (x + w) & mask;
++ const unsigned int w2 = w - (w1 + w3);
++
++ for (unsigned int i = 0; i != h; ++i, dst += dst_stride, p1 += stride1, p2 += stride1) {
++ unsigned int j;
++ const uint8_t * p = p2;
++ uint8_t * d = dst;
++ memcpy(d, p1, w1);
++ d += w1;
++ for (j = 0; j < w2; j += stride1, d += stride1, p += sstride) {
++ memcpy(d, p, stride1);
++ }
++ memcpy(d, p, w3);
++ }
++ }
++}
++
++// x & w in bytes but not of interleave (i.e. offset = x*2 for U&V)
++
++void FUNC(av_rpi_sand_to_planar_c)(uint8_t * dst_u, const unsigned int dst_stride_u,
++ uint8_t * dst_v, const unsigned int dst_stride_v,
++ const uint8_t * src,
++ unsigned int stride1, unsigned int stride2,
++ unsigned int _x, unsigned int y,
++ unsigned int _w, unsigned int h)
++{
++ const unsigned int x = _x * 2;
++ const unsigned int w = _w * 2;
++ const unsigned int mask = stride1 - 1;
++
++ if ((x & ~mask) == ((x + w) & ~mask)) {
++ // All in one sand stripe
++ const uint8_t * p1 = src + (x & mask) + y * stride1 + (x & ~mask) * stride2;
++ for (unsigned int i = 0; i != h; ++i, dst_u += dst_stride_u, dst_v += dst_stride_v, p1 += stride1) {
++ pixel * du = (pixel *)dst_u;
++ pixel * dv = (pixel *)dst_v;
++ const pixel * p = (const pixel *)p1;
++ for (unsigned int k = 0; k < w; k += 2 * PW) {
++ *du++ = *p++;
++ *dv++ = *p++;
++ }
++ }
++ }
++ else
++ {
++ // Two+ stripe
++ const unsigned int sstride = stride1 * stride2;
++ const unsigned int sstride_p = (sstride - stride1) / PW;
++
++ const uint8_t * p1 = src + (x & mask) + y * stride1 + (x & ~mask) * stride2;
++ const uint8_t * p2 = p1 + sstride - (x & mask);
++ const unsigned int w1 = stride1 - (x & mask);
++ const unsigned int w3 = (x + w) & mask;
++ const unsigned int w2 = w - (w1 + w3);
++
++ for (unsigned int i = 0; i != h; ++i, dst_u += dst_stride_u, dst_v += dst_stride_v, p1 += stride1, p2 += stride1) {
++ unsigned int j;
++ const pixel * p = (const pixel *)p1;
++ pixel * du = (pixel *)dst_u;
++ pixel * dv = (pixel *)dst_v;
++ for (unsigned int k = 0; k < w1; k += 2 * PW) {
++ *du++ = *p++;
++ *dv++ = *p++;
++ }
++ for (j = 0, p = (const pixel *)p2; j < w2; j += stride1, p += sstride_p) {
++ for (unsigned int k = 0; k < stride1; k += 2 * PW) {
++ *du++ = *p++;
++ *dv++ = *p++;
++ }
++ }
++ for (unsigned int k = 0; k < w3; k += 2 * PW) {
++ *du++ = *p++;
++ *dv++ = *p++;
++ }
++ }
++ }
++}
++
++void FUNC(av_rpi_planar_to_sand_c)(uint8_t * dst_c,
++ unsigned int stride1, unsigned int stride2,
++ const uint8_t * src_u, const unsigned int src_stride_u,
++ const uint8_t * src_v, const unsigned int src_stride_v,
++ unsigned int _x, unsigned int y,
++ unsigned int _w, unsigned int h)
++{
++ const unsigned int x = _x * 2;
++ const unsigned int w = _w * 2;
++ const unsigned int mask = stride1 - 1;
++ if ((x & ~mask) == ((x + w) & ~mask)) {
++ // All in one sand stripe
++ uint8_t * p1 = dst_c + (x & mask) + y * stride1 + (x & ~mask) * stride2;
++ for (unsigned int i = 0; i != h; ++i, src_u += src_stride_u, src_v += src_stride_v, p1 += stride1) {
++ const pixel * su = (const pixel *)src_u;
++ const pixel * sv = (const pixel *)src_v;
++ pixel * p = (pixel *)p1;
++ for (unsigned int k = 0; k < w; k += 2 * PW) {
++ *p++ = *su++;
++ *p++ = *sv++;
++ }
++ }
++ }
++ else
++ {
++ // Two+ stripe
++ const unsigned int sstride = stride1 * stride2;
++ const unsigned int sstride_p = (sstride - stride1) / PW;
++
++ const uint8_t * p1 = dst_c + (x & mask) + y * stride1 + (x & ~mask) * stride2;
++ const uint8_t * p2 = p1 + sstride - (x & mask);
++ const unsigned int w1 = stride1 - (x & mask);
++ const unsigned int w3 = (x + w) & mask;
++ const unsigned int w2 = w - (w1 + w3);
++
++ for (unsigned int i = 0; i != h; ++i, src_u += src_stride_u, src_v += src_stride_v, p1 += stride1, p2 += stride1) {
++ unsigned int j;
++ const pixel * su = (const pixel *)src_u;
++ const pixel * sv = (const pixel *)src_v;
++ pixel * p = (pixel *)p1;
++ for (unsigned int k = 0; k < w1; k += 2 * PW) {
++ *p++ = *su++;
++ *p++ = *sv++;
++ }
++ for (j = 0, p = (pixel *)p2; j < w2; j += stride1, p += sstride_p) {
++ for (unsigned int k = 0; k < stride1; k += 2 * PW) {
++ *p++ = *su++;
++ *p++ = *sv++;
++ }
++ }
++ for (unsigned int k = 0; k < w3; k += 2 * PW) {
++ *p++ = *su++;
++ *p++ = *sv++;
++ }
++ }
++ }
++}
++
++
++#undef pixel
++#undef STRCAT
++#undef FUNC
++
+diff --git a/libavutil/rpi_sand_fns.c b/libavutil/rpi_sand_fns.c
+new file mode 100644
+index 0000000000..3e31ef77ec
+--- /dev/null
++++ b/libavutil/rpi_sand_fns.c
+@@ -0,0 +1,151 @@
++#include "config.h"
++#include <stdint.h>
++#include <string.h>
++#include "rpi_sand_fns.h"
++#include "avassert.h"
++#include "frame.h"
++
++#define PW 1
++#include "rpi_sand_fn_pw.h"
++#undef PW
++
++#define PW 2
++#include "rpi_sand_fn_pw.h"
++#undef PW
++
++#if HAVE_NEON
++void rpi_sand128b_stripe_to_8_10(uint8_t * dest, const uint8_t * src1, const uint8_t * src2, unsigned int lines);
++#endif
++
++#if 1
++// Simple round
++static void cpy16_to_8(uint8_t * dst, const uint8_t * _src, unsigned int n, const unsigned int shr)
++{
++ const unsigned int rnd = (1 << shr) >> 1;
++ const uint16_t * src = (const uint16_t *)_src;
++
++ for (; n != 0; --n) {
++ *dst++ = (*src++ + rnd) >> shr;
++ }
++}
++#else
++// Dithered variation
++static void cpy16_to_8(uint8_t * dst, const uint8_t * _src, unsigned int n, const unsigned int shr)
++{
++ unsigned int rnd = (1 << shr) >> 1;
++ const unsigned int mask = ((1 << shr) - 1);
++ const uint16_t * src = (const uint16_t *)_src;
++
++ for (; n != 0; --n) {
++ rnd = *src++ + (rnd & mask);
++ *dst++ = rnd >> shr;
++ }
++}
++#endif
++
++// w/h in pixels
++void av_rpi_sand16_to_sand8(uint8_t * dst, const unsigned int dst_stride1, const unsigned int dst_stride2,
++ const uint8_t * src, const unsigned int src_stride1, const unsigned int src_stride2,
++ unsigned int w, unsigned int h, const unsigned int shr)
++{
++ const unsigned int n = dst_stride1 / 2;
++ unsigned int j;
++
++ // This is true for our current layouts
++ av_assert0(dst_stride1 == src_stride1);
++
++ // As we have the same stride1 for src & dest and src is wider than dest
++ // then if we loop on src we can always write contiguously to dest
++ // We make no effort to copy an exact width - round up to nearest src stripe
++ // as we will always have storage in dest for that
++
++#if HAVE_NEON
++ if (shr == 3 && src_stride1 == 128) {
++ for (j = 0; j + n < w; j += dst_stride1) {
++ uint8_t * d = dst + j * dst_stride2;
++ const uint8_t * s1 = src + j * 2 * src_stride2;
++ const uint8_t * s2 = s1 + src_stride1 * src_stride2;
++
++ rpi_sand128b_stripe_to_8_10(d, s1, s2, h);
++ }
++ }
++ else
++#endif
++ {
++ for (j = 0; j + n < w; j += dst_stride1) {
++ uint8_t * d = dst + j * dst_stride2;
++ const uint8_t * s1 = src + j * 2 * src_stride2;
++ const uint8_t * s2 = s1 + src_stride1 * src_stride2;
++
++ for (unsigned int i = 0; i != h; ++i, s1 += src_stride1, s2 += src_stride1, d += dst_stride1) {
++ cpy16_to_8(d, s1, n, shr);
++ cpy16_to_8(d + n, s2, n, shr);
++ }
++ }
++ }
++
++ // Fix up a trailing dest half stripe
++ if (j < w) {
++ uint8_t * d = dst + j * dst_stride2;
++ const uint8_t * s1 = src + j * 2 * src_stride2;
++
++ for (unsigned int i = 0; i != h; ++i, s1 += src_stride1, d += dst_stride1) {
++ cpy16_to_8(d, s1, n, shr);
++ }
++ }
++}
++
++int av_rpi_sand_to_planar_frame(AVFrame * const dst, const AVFrame * const src)
++{
++ const int w = av_frame_cropped_width(src);
++ const int h = av_frame_cropped_height(src);
++ const int x = src->crop_left;
++ const int y = src->crop_top;
++
++ // We will crop as part of the conversion
++ dst->crop_top = 0;
++ dst->crop_left = 0;
++ dst->crop_bottom = 0;
++ dst->crop_right = 0;
++
++ switch (src->format){
++ case AV_PIX_FMT_SAND128:
++ switch (dst->format){
++ case AV_PIX_FMT_YUV420P:
++ av_rpi_sand_to_planar_y8(dst->data[0], dst->linesize[0],
++ src->data[0],
++ av_rpi_sand_frame_stride1(src), av_rpi_sand_frame_stride2(src),
++ x, y, w, h);
++ av_rpi_sand_to_planar_c8(dst->data[1], dst->linesize[1],
++ dst->data[2], dst->linesize[2],
++ src->data[1],
++ av_rpi_sand_frame_stride1(src), av_rpi_sand_frame_stride2(src),
++ x/2, y/2, w/2, h/2);
++ break;
++ default:
++ return -1;
++ }
++ break;
++ case AV_PIX_FMT_SAND64_10:
++ switch (dst->format){
++ case AV_PIX_FMT_YUV420P10:
++ av_rpi_sand_to_planar_y16(dst->data[0], dst->linesize[0],
++ src->data[0],
++ av_rpi_sand_frame_stride1(src), av_rpi_sand_frame_stride2(src),
++ x*2, y, w*2, h);
++ av_rpi_sand_to_planar_c16(dst->data[1], dst->linesize[1],
++ dst->data[2], dst->linesize[2],
++ src->data[1],
++ av_rpi_sand_frame_stride1(src), av_rpi_sand_frame_stride2(src),
++ x, y/2, w, h/2);
++ break;
++ default:
++ return -1;
++ }
++ break;
++ default:
++ return -1;
++ }
++
++ return av_frame_copy_props(dst, src);
++}
+diff --git a/libavutil/rpi_sand_fns.h b/libavutil/rpi_sand_fns.h
+new file mode 100644
+index 0000000000..1f50b68ea8
+--- /dev/null
++++ b/libavutil/rpi_sand_fns.h
+@@ -0,0 +1,136 @@
++#ifndef AVUTIL_RPI_SAND_FNS
++#define AVUTIL_RPI_SAND_FNS
++
++#include "libavutil/frame.h"
++
++// For all these fns _x & _w are measured as coord * PW
++// For the C fns coords are in chroma pels (so luma / 2)
++// Strides are in bytes
++
++void av_rpi_sand_to_planar_y8(uint8_t * dst, const unsigned int dst_stride,
++ const uint8_t * src,
++ unsigned int stride1, unsigned int stride2,
++ unsigned int _x, unsigned int y,
++ unsigned int _w, unsigned int h);
++void av_rpi_sand_to_planar_y16(uint8_t * dst, const unsigned int dst_stride,
++ const uint8_t * src,
++ unsigned int stride1, unsigned int stride2,
++ unsigned int _x, unsigned int y,
++ unsigned int _w, unsigned int h);
++
++void av_rpi_sand_to_planar_c8(uint8_t * dst_u, const unsigned int dst_stride_u,
++ uint8_t * dst_v, const unsigned int dst_stride_v,
++ const uint8_t * src,
++ unsigned int stride1, unsigned int stride2,
++ unsigned int _x, unsigned int y,
++ unsigned int _w, unsigned int h);
++void av_rpi_sand_to_planar_c16(uint8_t * dst_u, const unsigned int dst_stride_u,
++ uint8_t * dst_v, const unsigned int dst_stride_v,
++ const uint8_t * src,
++ unsigned int stride1, unsigned int stride2,
++ unsigned int _x, unsigned int y,
++ unsigned int _w, unsigned int h);
++
++void av_rpi_planar_to_sand_c8(uint8_t * dst_c,
++ unsigned int stride1, unsigned int stride2,
++ const uint8_t * src_u, const unsigned int src_stride_u,
++ const uint8_t * src_v, const unsigned int src_stride_v,
++ unsigned int _x, unsigned int y,
++ unsigned int _w, unsigned int h);
++void av_rpi_planar_to_sand_c16(uint8_t * dst_c,
++ unsigned int stride1, unsigned int stride2,
++ const uint8_t * src_u, const unsigned int src_stride_u,
++ const uint8_t * src_v, const unsigned int src_stride_v,
++ unsigned int _x, unsigned int y,
++ unsigned int _w, unsigned int h);
++
++// w/h in pixels
++void av_rpi_sand16_to_sand8(uint8_t * dst, const unsigned int dst_stride1, const unsigned int dst_stride2,
++ const uint8_t * src, const unsigned int src_stride1, const unsigned int src_stride2,
++ unsigned int w, unsigned int h, const unsigned int shr);
++
++
++// dst must contain required pixel format & allocated data buffers
++// Cropping on the src buffer will be honoured and dst crop will be set to zero
++int av_rpi_sand_to_planar_frame(AVFrame * const dst, const AVFrame * const src);
++
++
++static inline unsigned int av_rpi_sand_frame_stride1(const AVFrame * const frame)
++{
++#ifdef RPI_ZC_SAND128_ONLY
++ // If we are sure we only only support 128 byte sand formats replace the
++ // var with a constant which should allow for better optimisation
++ return 128;
++#else
++ return frame->linesize[0];
++#endif
++}
++
++static inline unsigned int av_rpi_sand_frame_stride2(const AVFrame * const frame)
++{
++ return frame->linesize[3];
++}
++
++
++static inline int av_rpi_is_sand_format(const int format)
++{
++ return (format >= AV_PIX_FMT_SAND128 && format <= AV_PIX_FMT_SAND64_16);
++}
++
++static inline int av_rpi_is_sand_frame(const AVFrame * const frame)
++{
++ return av_rpi_is_sand_format(frame->format);
++}
++
++static inline int av_rpi_is_sand8_frame(const AVFrame * const frame)
++{
++ return (frame->format == AV_PIX_FMT_SAND128);
++}
++
++static inline int av_rpi_is_sand16_frame(const AVFrame * const frame)
++{
++ return (frame->format >= AV_PIX_FMT_SAND64_10 && frame->format <= AV_PIX_FMT_SAND64_16);
++}
++
++static inline int av_rpi_sand_frame_xshl(const AVFrame * const frame)
++{
++ return av_rpi_is_sand8_frame(frame) ? 0 : 1;
++}
++
++// If x is measured in bytes (not pixels) then this works for sand64_16 as
++// well as sand128 - but in the general case we work that out
++
++static inline unsigned int av_rpi_sand_frame_off_y(const AVFrame * const frame, const unsigned int x_y, const unsigned int y)
++{
++ const unsigned int stride1 = av_rpi_sand_frame_stride1(frame);
++ const unsigned int stride2 = av_rpi_sand_frame_stride2(frame);
++ const unsigned int x = x_y << av_rpi_sand_frame_xshl(frame);
++ const unsigned int x1 = x & (stride1 - 1);
++ const unsigned int x2 = x ^ x1;
++
++ return x1 + stride1 * y + stride2 * x2;
++}
++
++static inline unsigned int av_rpi_sand_frame_off_c(const AVFrame * const frame, const unsigned int x_c, const unsigned int y_c)
++{
++ const unsigned int stride1 = av_rpi_sand_frame_stride1(frame);
++ const unsigned int stride2 = av_rpi_sand_frame_stride2(frame);
++ const unsigned int x = x_c << (av_rpi_sand_frame_xshl(frame) + 1);
++ const unsigned int x1 = x & (stride1 - 1);
++ const unsigned int x2 = x ^ x1;
++
++ return x1 + stride1 * y_c + stride2 * x2;
++}
++
++static inline uint8_t * av_rpi_sand_frame_pos_y(const AVFrame * const frame, const unsigned int x, const unsigned int y)
++{
++ return frame->data[0] + av_rpi_sand_frame_off_y(frame, x, y);
++}
++
++static inline uint8_t * av_rpi_sand_frame_pos_c(const AVFrame * const frame, const unsigned int x, const unsigned int y)
++{
++ return frame->data[1] + av_rpi_sand_frame_off_c(frame, x, y);
++}
++
++#endif
++
+diff --git a/pi-util/BUILD.txt b/pi-util/BUILD.txt
+new file mode 100644
+index 0000000000..b1e99a6a89
+--- /dev/null
++++ b/pi-util/BUILD.txt
+@@ -0,0 +1,25 @@
++Building Pi FFmpeg
++==================
++
++Configuration:
++=============
++
++pi-util/conf_pi2.sh
++
++contains suitable options to build the code for Pi2/3. It expects to find
++git clones of
++
++https://github.com/raspberrypi/tools
++https://github.com/raspberrypi/firmware
++
++in the parent of the FFmpeg directory. I recommend using --depth 1 to avoid a
++lot of history you don't want.
++
++If you have a copy of qasm.py in ../local/bin then the .qasm sources will be
++rebuilt. Otherwise the prebuilt .c & .h files will be used.
++Likewise ../local/bin/vasmvidcore_std will enable VPU code rebuild
++
++pi-util/conf_p1.sh should configure for Pi1. Beware that as of this time
++H265 QPU acceleration is broken on Pi1 and so it is disabled.
++
++
+diff --git a/pi-util/conf_h265.2016.csv b/pi-util/conf_h265.2016.csv
+new file mode 100644
+index 0000000000..3e90f6893f
+--- /dev/null
++++ b/pi-util/conf_h265.2016.csv
+@@ -0,0 +1,195 @@
++1,HEVC_v1/AMP_A_Samsung_7,AMP_A_Samsung_7.bin,AMP_A_Samsung_7.md5
++1,HEVC_v1/AMP_B_Samsung_7,AMP_B_Samsung_7.bin,AMP_B_Samsung_7.md5
++1,HEVC_v1/AMP_D_Hisilicon_3,AMP_D_Hisilicon.bit,AMP_D_Hisilicon_3.yuv.md5
++1,HEVC_v1/AMP_E_Hisilicon_3,AMP_E_Hisilicon.bit,AMP_E_Hisilicon_3.yuv.md5
++1,HEVC_v1/AMP_F_Hisilicon_3,AMP_F_Hisilicon_3.bit,AMP_F_Hisilicon_3.yuv.md5
++1,HEVC_v1/AMVP_A_MTK_4,AMVP_A_MTK_4.bit,AMVP_A_MTK_4.md5
++1,HEVC_v1/AMVP_B_MTK_4,AMVP_B_MTK_4.bit,AMVP_B_MTK_4.md5
++1,HEVC_v1/AMVP_C_Samsung_7,AMVP_C_Samsung_7.bin,AMVP_C_Samsung_7.md5
++1,HEVC_v1/BUMPING_A_ericsson_1,BUMPING_A_ericsson_1.bit,BUMPING_A_ericsson_1.md5
++1,HEVC_v1/CAINIT_A_SHARP_4,CAINIT_A_SHARP_4.bit,CAINIT_A_SHARP_4.md5
++1,HEVC_v1/CAINIT_B_SHARP_4,CAINIT_B_SHARP_4.bit,CAINIT_B_SHARP_4.md5
++1,HEVC_v1/CAINIT_C_SHARP_3,CAINIT_C_SHARP_3.bit,CAINIT_C_SHARP_3.md5
++1,HEVC_v1/CAINIT_D_SHARP_3,CAINIT_D_SHARP_3.bit,CAINIT_D_SHARP_3.md5
++1,HEVC_v1/CAINIT_E_SHARP_3,CAINIT_E_SHARP_3.bit,CAINIT_E_SHARP_3.md5
++1,HEVC_v1/CAINIT_F_SHARP_3,CAINIT_F_SHARP_3.bit,CAINIT_F_SHARP_3.md5
++1,HEVC_v1/CAINIT_G_SHARP_3,CAINIT_G_SHARP_3.bit,CAINIT_G_SHARP_3.md5
++1,HEVC_v1/CAINIT_H_SHARP_3,CAINIT_H_SHARP_3.bit,CAINIT_H_SHARP_3.md5
++1,HEVC_v1/CIP_A_Panasonic_3,CIP_A_Panasonic_3.bit,CIP_A_Panasonic_3_yuv.md5
++1,HEVC_v1/cip_B_NEC_3,cip_B_NEC_3.bit,cip_B_NEC_3.md5
++1,HEVC_v1/CIP_C_Panasonic_2,CIP_C_Panasonic_2.bit,CIP_C_Panasonic_2_yuv.md5
++1,HEVC_v1/CONFWIN_A_Sony_1,CONFWIN_A_Sony_1.bit,CONFWIN_A_Sony_1.md5
++1,HEVC_v1/DBLK_A_MAIN10_VIXS_4,DBLK_A_MAIN10_VIXS_4.bit,DBLK_A_MAIN10_VIXS_4.md5
++1,HEVC_v1/DBLK_A_SONY_3,DBLK_A_SONY_3.bit,DBLK_A_SONY_3.bit.yuv.md5
++1,HEVC_v1/DBLK_B_SONY_3,DBLK_B_SONY_3.bit,DBLK_B_SONY_3.bit.yuv.md5
++1,HEVC_v1/DBLK_C_SONY_3,DBLK_C_SONY_3.bit,DBLK_C_SONY_3.bit.yuv.md5
++1,HEVC_v1/DBLK_D_VIXS_2,DBLK_D_VIXS_2.bit,DBLK_D_VIXS_2_yuv.md5
++1,HEVC_v1/DBLK_E_VIXS_2,DBLK_E_VIXS_2.bit,DBLK_E_VIXS_2_yuv.md5
++1,HEVC_v1/DBLK_F_VIXS_2,DBLK_F_VIXS_2.bit,DBLK_F_VIXS_2_yuv.md5
++1,HEVC_v1/DBLK_G_VIXS_2,DBLK_G_VIXS_2.bit,DBLK_G_VIXS_2_yuv.md5
++1,HEVC_v1/DELTAQP_A_BRCM_4,DELTAQP_A_BRCM_4.bit,DELTAQP_A_BRCM_4_yuv.md5
++1,HEVC_v1/DELTAQP_B_SONY_3,DELTAQP_B_SONY_3.bit,DELTAQP_B_SONY_3.bit.yuv.md5
++1,HEVC_v1/DELTAQP_C_SONY_3,DELTAQP_C_SONY_3.bit,DELTAQP_C_SONY_3.bit.yuv.md5
++1,HEVC_v1/DSLICE_A_HHI_5,DSLICE_A_HHI_5.bin,DSLICE_A_HHI_5.md5
++1,HEVC_v1/DSLICE_B_HHI_5,DSLICE_B_HHI_5.bin,DSLICE_B_HHI_5.md5
++1,HEVC_v1/DSLICE_C_HHI_5,DSLICE_C_HHI_5.bin,DSLICE_C_HHI_5.md5
++1,HEVC_v1/ENTP_A_QUALCOMM_1,ENTP_A_Qualcomm_1.bit,ENTP_A_Qualcomm_1.md5
++1,HEVC_v1/ENTP_B_Qualcomm_1,ENTP_B_Qualcomm_1.bit,ENTP_B_Qualcomm_1.md5
++1,HEVC_v1/ENTP_C_Qualcomm_1,ENTP_C_Qualcomm_1.bit,ENTP_C_Qualcomm_1.md5
++1,HEVC_v1/EXT_A_ericsson_4,EXT_A_ericsson_4.bit,EXT_A_ericsson_4.md5
++1,HEVC_v1/FILLER_A_Sony_1,FILLER_A_Sony_1.bit,FILLER_A_Sony_1.md5
++1,HEVC_v1/HRD_A_Fujitsu_3,HRD_A_Fujitsu_3.bin,HRD_A_Fujitsu_3.md5
++1,HEVC_v1/INITQP_A_Sony_1,INITQP_A_Sony_1.bit,INITQP_A_Sony_1.md5
++1,HEVC_v1/INITQP_B_Main10_Sony_1,INITQP_B_Main10_Sony_1.bit,INITQP_B_Main10_Sony_1.md5
++1,HEVC_v1/ipcm_A_NEC_3,ipcm_A_NEC_3.bit,ipcm_A_NEC_3.md5
++1,HEVC_v1/ipcm_B_NEC_3,ipcm_B_NEC_3.bit,ipcm_B_NEC_3.md5
++1,HEVC_v1/ipcm_C_NEC_3,ipcm_C_NEC_3.bit,ipcm_C_NEC_3.md5
++1,HEVC_v1/ipcm_D_NEC_3,ipcm_D_NEC_3.bit,ipcm_D_NEC_3.md5
++1,HEVC_v1/ipcm_E_NEC_2,ipcm_E_NEC_2.bit,ipcm_E_NEC_2.md5
++1,HEVC_v1/IPRED_A_docomo_2,IPRED_A_docomo_2.bit,IPRED_A_docomo_2.md5
++1,HEVC_v1/IPRED_B_Nokia_3,IPRED_B_Nokia_3.bit,IPRED_B_Nokia_3_yuv.md5
++1,HEVC_v1/IPRED_C_Mitsubishi_3,IPRED_C_Mitsubishi_3.bit,IPRED_C_Mitsubishi_3_yuv.md5
++1,HEVC_v1/LS_A_Orange_2,LS_A_Orange_2.bit,LS_A_Orange_2_yuv.md5
++1,HEVC_v1/LS_B_Orange_4,LS_B_Orange_4.bit,LS_B_Orange_4_yuv.md5
++1,HEVC_v1/LTRPSPS_A_Qualcomm_1,LTRPSPS_A_Qualcomm_1.bit,LTRPSPS_A_Qualcomm_1.md5
++1,HEVC_v1/MAXBINS_A_TI_5,MAXBINS_A_TI_5.bit,MAXBINS_A_TI_5_yuv.md5
++1,HEVC_v1/MAXBINS_B_TI_5,MAXBINS_B_TI_5.bit,MAXBINS_B_TI_5_yuv.md5
++1,HEVC_v1/MAXBINS_C_TI_5,MAXBINS_C_TI_5.bit,MAXBINS_C_TI_5_yuv.md5
++1,HEVC_v1/MERGE_A_TI_3,MERGE_A_TI_3.bit,MERGE_A_TI_3.md5
++1,HEVC_v1/MERGE_B_TI_3,MERGE_B_TI_3.bit,MERGE_B_TI_3.md5
++1,HEVC_v1/MERGE_C_TI_3,MERGE_C_TI_3.bit,MERGE_C_TI_3.md5
++1,HEVC_v1/MERGE_D_TI_3,MERGE_D_TI_3.bit,MERGE_D_TI_3.md5
++1,HEVC_v1/MERGE_E_TI_3,MERGE_E_TI_3.bit,MERGE_E_TI_3.md5
++1,HEVC_v1/MERGE_F_MTK_4,MERGE_F_MTK_4.bit,MERGE_F_MTK_4.md5
++1,HEVC_v1/MERGE_G_HHI_4,MERGE_G_HHI_4.bit,MERGE_G_HHI_4.md5
++1,HEVC_v1/MVCLIP_A_qualcomm_3,MVCLIP_A_qualcomm_3.bit,MVCLIP_A_qualcomm_3.yuv.md5
++1,HEVC_v1/MVDL1ZERO_A_docomo_4,MVDL1ZERO_A_docomo_4.bit,MVDL1ZERO_A_docomo_4.md5
++1,HEVC_v1/MVEDGE_A_qualcomm_3,MVEDGE_A_qualcomm_3.bit,MVEDGE_A_qualcomm_3.yuv.md5
++1,HEVC_v1/NoOutPrior_A_Qualcomm_1,NoOutPrior_A_Qualcomm_1.bit,NoOutPrior_A_Qualcomm_1.md5
++1,HEVC_v1/NoOutPrior_B_Qualcomm_1,NoOutPrior_B_Qualcomm_1.bit,NoOutPrior_B_Qualcomm_1.md5
++1,HEVC_v1/NUT_A_ericsson_5,NUT_A_ericsson_5.bit,NUT_A_ericsson_5.md5
++1,HEVC_v1/OPFLAG_A_Qualcomm_1,OPFLAG_A_Qualcomm_1.bit,OPFLAG_A_Qualcomm_1.md5
++1,HEVC_v1/OPFLAG_B_Qualcomm_1,OPFLAG_B_Qualcomm_1.bit,OPFLAG_B_Qualcomm_1.md5
++1,HEVC_v1/OPFLAG_C_Qualcomm_1,OPFLAG_C_Qualcomm_1.bit,OPFLAG_C_Qualcomm_1.md5
++1,HEVC_v1/PICSIZE_A_Bossen_1,PICSIZE_A_Bossen_1.bin,PICSIZE_A_Bossen_1.md5
++1,HEVC_v1/PICSIZE_B_Bossen_1,PICSIZE_B_Bossen_1.bin,PICSIZE_B_Bossen_1.md5
++1,HEVC_v1/PICSIZE_C_Bossen_1,PICSIZE_C_Bossen_1.bin,PICSIZE_C_Bossen_1.md5
++1,HEVC_v1/PICSIZE_D_Bossen_1,PICSIZE_D_Bossen_1.bin,PICSIZE_D_Bossen_1.md5
++1,HEVC_v1/PMERGE_A_TI_3,PMERGE_A_TI_3.bit,PMERGE_A_TI_3.md5
++1,HEVC_v1/PMERGE_B_TI_3,PMERGE_B_TI_3.bit,PMERGE_B_TI_3.md5
++1,HEVC_v1/PMERGE_C_TI_3,PMERGE_C_TI_3.bit,PMERGE_C_TI_3.md5
++1,HEVC_v1/PMERGE_D_TI_3,PMERGE_D_TI_3.bit,PMERGE_D_TI_3.md5
++1,HEVC_v1/PMERGE_E_TI_3,PMERGE_E_TI_3.bit,PMERGE_E_TI_3.md5
++1,HEVC_v1/POC_A_Bossen_3,POC_A_Bossen_3.bin,POC_A_Bossen_3.md5
++1,HEVC_v1/PPS_A_qualcomm_7,PPS_A_qualcomm_7.bit,PPS_A_qualcomm_7.yuv.md5
++1,HEVC_v1/PS_B_VIDYO_3,PS_B_VIDYO_3.bit,PS_B_VIDYO_3_yuv.md5
++1,HEVC_v1/RAP_A_docomo_6,RAP_A_docomo_6.bit,RAP_A_docomo_6.md5
++1,HEVC_v1/RAP_B_Bossen_2,RAP_B_Bossen_2.bit,RAP_B_Bossen_2.md5
++1,HEVC_v1/RPLM_A_qualcomm_4,RPLM_A_qualcomm_4.bit,RPLM_A_qualcomm_4.yuv.md5
++1,HEVC_v1/RPLM_B_qualcomm_4,RPLM_B_qualcomm_4.bit,RPLM_B_qualcomm_4.yuv.md5
++1,HEVC_v1/RPS_A_docomo_5,RPS_A_docomo_5.bit,RPS_A_docomo_5.md5
++1,HEVC_v1/RPS_B_qualcomm_5,RPS_B_qualcomm_5.bit,RPS_B_qualcomm_5.yuv.md5
++1,HEVC_v1/RPS_C_ericsson_5,RPS_C_ericsson_5.bit,RPS_C_ericsson_5.md5
++1,HEVC_v1/RPS_D_ericsson_6,RPS_D_ericsson_6.bit,RPS_D_ericsson_6.md5
++1,HEVC_v1/RPS_E_qualcomm_5,RPS_E_qualcomm_5.bit,RPS_E_qualcomm_5.yuv.md5
++1,HEVC_v1/RPS_F_docomo_2,RPS_F_docomo_2.bit,RPS_F_docomo_2.md5
++1,HEVC_v1/RQT_A_HHI_4,RQT_A_HHI_4.bit,RQT_A_HHI_4.md5
++1,HEVC_v1/RQT_B_HHI_4,RQT_B_HHI_4.bit,RQT_B_HHI_4.md5
++1,HEVC_v1/RQT_C_HHI_4,RQT_C_HHI_4.bit,RQT_C_HHI_4.md5
++1,HEVC_v1/RQT_D_HHI_4,RQT_D_HHI_4.bit,RQT_D_HHI_4.md5
++1,HEVC_v1/RQT_E_HHI_4,RQT_E_HHI_4.bit,RQT_E_HHI_4.md5
++1,HEVC_v1/RQT_F_HHI_4,RQT_F_HHI_4.bit,RQT_F_HHI_4.md5
++1,HEVC_v1/RQT_G_HHI_4,RQT_G_HHI_4.bit,RQT_G_HHI_4.md5
++1,HEVC_v1/SAO_A_MediaTek_4,SAO_A_MediaTek_4.bit,SAO_A_MediaTek_4.md5
++1,HEVC_v1/SAO_B_MediaTek_5,SAO_B_MediaTek_5.bit,SAO_B_MediaTek_5.md5
++1,HEVC_v1/SAO_C_Samsung_5,SAO_C_Samsung_5.bin,SAO_C_Samsung_5.md5
++1,HEVC_v1/SAO_D_Samsung_5,SAO_D_Samsung_5.bin,SAO_D_Samsung_5.md5
++1,HEVC_v1/SAO_E_Canon_4,SAO_E_Canon_4.bit,SAO_E_Canon_4.md5
++1,HEVC_v1/SAO_F_Canon_3,SAO_F_Canon_3.bit,SAO_F_Canon_3.md5
++1,HEVC_v1/SAO_G_Canon_3,SAO_G_Canon_3.bit,SAO_G_Canon_3.md5
++1,HEVC_v1/SAO_H_Parabola_1,SAO_H_Parabola_1.bit,SAO_H_Parabola_1.md5
++1,HEVC_v1/SAODBLK_A_MainConcept_4,SAODBLK_A_MainConcept_4.bin,SAODBLK_A_MainConcept_4_md5.txt
++1,HEVC_v1/SAODBLK_B_MainConcept_4,SAODBLK_B_MainConcept_4.bin,SAODBLK_B_MainConcept_4_md5.txt
++1,HEVC_v1/SDH_A_Orange_4,SDH_A_Orange_4.bit,SDH_A_Orange_4_yuv.md5
++1,HEVC_v1/SLICES_A_Rovi_3,SLICES_A_Rovi_3.bin,SLICES_A_Rovi_3.md5
++1,HEVC_v1/SLIST_A_Sony_5,SLIST_A_Sony_5.bin,SLIST_A_Sony_5_yuv.md5
++1,HEVC_v1/SLIST_B_Sony_9,SLIST_B_Sony_9.bin,SLIST_B_Sony_9_yuv.md5
++1,HEVC_v1/SLIST_C_Sony_4,SLIST_C_Sony_4.bin,SLIST_C_Sony_4_yuv.md5
++1,HEVC_v1/SLIST_D_Sony_9,str.bin,SLIST_D_Sony_9_yuv.md5
++1,HEVC_v1/SLPPLP_A_VIDYO_2,SLPPLP_A_VIDYO_2.bit,SLPPLP_A_VIDYO_2_yuv.md5
++1,HEVC_v1/STRUCT_A_Samsung_7,STRUCT_A_Samsung_7.bin,STRUCT_A_Samsung_7.md5
++1,HEVC_v1/STRUCT_B_Samsung_7,STRUCT_B_Samsung_7.bin,STRUCT_B_Samsung_7.md5
++1,HEVC_v1/TILES_A_Cisco_2,TILES_A_Cisco_2.bin,TILES_A_Cisco_2_yuv.md5
++1,HEVC_v1/TILES_B_Cisco_1,TILES_B_Cisco_1.bin,TILES_B_Cisco_1_yuv.md5
++1,HEVC_v1/TMVP_A_MS_3,TMVP_A_MS_3.bit,TMVP_A_MS_3.yuv.md5
++1,HEVC_v1/TSCL_A_VIDYO_5,TSCL_A_VIDYO_5.bit,TSCL_A_VIDYO_5_yuv.md5
++1,HEVC_v1/TSCL_B_VIDYO_4,TSCL_B_VIDYO_4.bit,TSCL_B_VIDYO_4_yuv.md5
++1,HEVC_v1/TSKIP_A_MS_3,TSKIP_A_MS_3.bit,TSKIP_A_MS_3.yuv.md5
++3,HEVC_v1/TSUNEQBD_A_MAIN10_Technicolor_2,TSUNEQBD_A_MAIN10_Technicolor_2.bit,TSUNEQBD_A_MAIN10_Technicolor_2_yuv.md5, # unequal bit depth
++1,HEVC_v1/TUSIZE_A_Samsung_1,TUSIZE_A_Samsung_1.bin,TUSIZE_A_Samsung_1.md5
++1,HEVC_v1/VPSID_A_VIDYO_2,VPSID_A_VIDYO_2.bit,VPSID_A_VIDYO_2_yuv.md5
++3,HEVC_v1/VPSSPSPPS_A_MainConcept_1,VPSSPSPPS_A_MainConcept_1.bin,VPSSPSPPS_A_MainConcept_1_md5.txt, # ???
++1,HEVC_v1/WP_A_MAIN10_Toshiba_3,WP_A_MAIN10_Toshiba_3.bit,WP_A_MAIN10_Toshiba_3_yuv.md5
++1,HEVC_v1/WP_A_Toshiba_3,WP_A_Toshiba_3.bit,WP_A_Toshiba_3_yuv.md5
++1,HEVC_v1/WP_B_Toshiba_3,WP_B_Toshiba_3.bit,WP_B_Toshiba_3_yuv.md5
++1,HEVC_v1/WP_MAIN10_B_Toshiba_3,WP_MAIN10_B_Toshiba_3.bit,WP_MAIN10_B_Toshiba_3_yuv.md5
++1,HEVC_v1/WPP_A_ericsson_MAIN10_2,WPP_A_ericsson_MAIN10_2.bit,WPP_A_ericsson_MAIN10_yuv.md5
++1,HEVC_v1/WPP_A_ericsson_MAIN_2,WPP_A_ericsson_MAIN_2.bit,WPP_A_ericsson_MAIN_2_yuv.md5
++1,HEVC_v1/WPP_B_ericsson_MAIN10_2,WPP_B_ericsson_MAIN10_2.bit,WPP_B_ericsson_MAIN10_yuv.md5
++1,HEVC_v1/WPP_B_ericsson_MAIN_2,WPP_B_ericsson_MAIN_2.bit,WPP_B_ericsson_MAIN_2_yuv.md5
++1,HEVC_v1/WPP_C_ericsson_MAIN10_2,WPP_C_ericsson_MAIN10_2.bit,WPP_C_ericsson_MAIN10_yuv.md5
++1,HEVC_v1/WPP_C_ericsson_MAIN_2,WPP_C_ericsson_MAIN_2.bit,WPP_C_ericsson_MAIN_2_yuv.md5
++1,HEVC_v1/WPP_D_ericsson_MAIN10_2,WPP_D_ericsson_MAIN10_2.bit,WPP_D_ericsson_MAIN10_yuv.md5
++1,HEVC_v1/WPP_D_ericsson_MAIN_2,WPP_D_ericsson_MAIN_2.bit,WPP_D_ericsson_MAIN_2_yuv.md5
++1,HEVC_v1/WPP_E_ericsson_MAIN10_2,WPP_E_ericsson_MAIN10_2.bit,WPP_E_ericsson_MAIN10_yuv.md5
++1,HEVC_v1/WPP_E_ericsson_MAIN_2,WPP_E_ericsson_MAIN_2.bit,WPP_E_ericsson_MAIN_2_yuv.md5
++1,HEVC_v1/WPP_F_ericsson_MAIN10_2,WPP_F_ericsson_MAIN10_2.bit,WPP_F_ericsson_MAIN10_yuv.md5
++1,HEVC_v1/WPP_F_ericsson_MAIN_2,WPP_F_ericsson_MAIN_2.bit,WPP_F_ericsson_MAIN_2_yuv.md5
++1,RExt/ADJUST_IPRED_ANGLE_A_RExt_Mitsubishi_2,ADJUST_IPRED_ANGLE_A_RExt_Mitsubishi_2.bit,ADJUST_IPRED_ANGLE_A_RExt_Mitsubishi_yuv_2.md5
++0,RExt/Bitdepth_A_RExt_Sony_1,Bitdepth_A_RExt_Sony_1.bin,md5sum.txt
++0,RExt/Bitdepth_B_RExt_Sony_1,Bitdepth_B_RExt_Sony_1.bin,md5sum.txt
++0,RExt/CCP_10bit_RExt_QCOM,CCP_10bit_RExt_QCOM.bin,CCP_10bit_RExt_QCOM_md5sum.txt
++0,RExt/CCP_12bit_RExt_QCOM,CCP_12bit_RExt_QCOM.bin,CCP_12bit_RExt_QCOM_md5sum.txt
++0,RExt/CCP_8bit_RExt_QCOM,CCP_8bit_RExt_QCOM.bin,CCP_8bit_RExt_QCOM_md5sum.txt
++1,RExt/ExplicitRdpcm_A_BBC_1,ExplicitRdpcm_A_BBC_1.bit,md5sum.txt
++0,RExt/ExplicitRdpcm_B_BBC_2,ExplicitRdpcm_B_BBC_1.bit,md5sum.txt
++0,RExt/EXTPREC_HIGHTHROUGHPUT_444_16_INTRA_10BIT_RExt_Sony_1,EXTPREC_HIGHTHROUGHPUT_444_16_INTRA_10BIT_RExt_Sony_1.bit,EXTPREC_HIGHTHROUGHPUT_444_16_INTRA_10BIT_RExt_Sony_1.md5
++0,RExt/EXTPREC_HIGHTHROUGHPUT_444_16_INTRA_12BIT_RExt_Sony_1,EXTPREC_HIGHTHROUGHPUT_444_16_INTRA_12BIT_RExt_Sony_1.bit,EXTPREC_HIGHTHROUGHPUT_444_16_INTRA_12BIT_RExt_Sony_1.md5
++0,RExt/EXTPREC_HIGHTHROUGHPUT_444_16_INTRA_16BIT_RExt_Sony_1,EXTPREC_HIGHTHROUGHPUT_444_16_INTRA_16BIT_RExt_Sony_1.bit,EXTPREC_HIGHTHROUGHPUT_444_16_INTRA_16BIT_RExt_Sony_1.md5
++0,RExt/EXTPREC_HIGHTHROUGHPUT_444_16_INTRA_8BIT_RExt_Sony_1,EXTPREC_HIGHTHROUGHPUT_444_16_INTRA_8BIT_RExt_Sony_1.bit,EXTPREC_HIGHTHROUGHPUT_444_16_INTRA_8BIT_RExt_Sony_1.md5
++0,RExt/EXTPREC_MAIN_444_16_INTRA_10BIT_RExt_Sony_1,EXTPREC_MAIN_444_16_INTRA_10BIT_RExt_Sony_1.bit,EXTPREC_MAIN_444_16_INTRA_10BIT_RExt_Sony_1.md5
++0,RExt/EXTPREC_MAIN_444_16_INTRA_12BIT_RExt_Sony_1,EXTPREC_MAIN_444_16_INTRA_12BIT_RExt_Sony_1.bit,EXTPREC_MAIN_444_16_INTRA_12BIT_RExt_Sony_1.md5
++0,RExt/EXTPREC_MAIN_444_16_INTRA_16BIT_RExt_Sony_1,EXTPREC_MAIN_444_16_INTRA_16BIT_RExt_Sony_1.bit,EXTPREC_MAIN_444_16_INTRA_16BIT_RExt_Sony_1.md5
++0,RExt/EXTPREC_MAIN_444_16_INTRA_8BIT_RExt_Sony_1,EXTPREC_MAIN_444_16_INTRA_8BIT_RExt_Sony_1.bit,EXTPREC_MAIN_444_16_INTRA_8BIT_RExt_Sony_1.md5
++1,RExt/GENERAL_10b_420_RExt_Sony_1,GENERAL_10b_420_RExt_Sony_1.bit,GENERAL_10b_420_RExt_Sony_1.md5
++1,RExt/GENERAL_10b_422_RExt_Sony_1,GENERAL_10b_422_RExt_Sony_1.bit,GENERAL_10b_422_RExt_Sony_1.md5
++1,RExt/GENERAL_10b_444_RExt_Sony_2,GENERAL_10b_444_RExt_Sony_2.bit,GENERAL_10b_444_RExt_Sony_2.md5
++1,RExt/GENERAL_12b_400_RExt_Sony_1,GENERAL_12b_400_RExt_Sony_1.bit,GENERAL_12b_400_RExt_Sony_1.md5
++1,RExt/GENERAL_12b_420_RExt_Sony_1,GENERAL_12b_420_RExt_Sony_1.bit,GENERAL_12b_420_RExt_Sony_1.md5
++1,RExt/GENERAL_12b_422_RExt_Sony_1,GENERAL_12b_422_RExt_Sony_1.bit,GENERAL_12b_422_RExt_Sony_1.md5
++1,RExt/GENERAL_12b_444_RExt_Sony_2,GENERAL_12b_444_RExt_Sony_2.bit,GENERAL_12b_444_RExt_Sony_2.md5
++0,RExt/GENERAL_16b_400_RExt_Sony_1,GENERAL_16b_400_RExt_Sony_1.bit,GENERAL_16b_400_RExt_Sony_1.md5
++0,RExt/GENERAL_16b_444_highThroughput_RExt_Sony_2,GENERAL_16b_444_highThroughput_RExt_Sony_2.bit,GENERAL_16b_444_highThroughput_RExt_Sony_2.md5
++0,RExt/GENERAL_16b_444_RExt_Sony_2,GENERAL_16b_444_RExt_Sony_2.bit,GENERAL_16b_444_RExt_Sony_2.md5
++1,RExt/GENERAL_8b_400_RExt_Sony_1,GENERAL_8b_400_RExt_Sony_1.bit,GENERAL_8b_400_RExt_Sony_1.md5
++1,RExt/GENERAL_8b_420_RExt_Sony_1,GENERAL_8b_420_RExt_Sony_1.bit,GENERAL_8b_420_RExt_Sony_1.md5
++1,RExt/GENERAL_8b_444_RExt_Sony_2,GENERAL_8b_444_RExt_Sony_2.bit,GENERAL_8b_444_RExt_Sony_2.md5
++1,RExt/IPCM_A_RExt_NEC_2,IPCM_A_RExt_NEC_2.bit,IPCM_A_RExt_NEC_2_yuv.md5
++1,RExt/IPCM_B_RExt_NEC,IPCM_B_RExt_NEC.bit,IPCM_B_RExt_NEC_yuv.md5
++1,RExt/Main_422_10_A_RExt_Sony_2,Main_422_10_A_RExt_Sony_2.bin,md5sum.txt
++1,RExt/Main_422_10_B_RExt_Sony_2,Main_422_10_B_RExt_Sony_2.bin,md5sum.txt
++1,RExt/PERSIST_RPARAM_A_RExt_Sony_3,PERSIST_RPARAM_A_RExt_Sony_3.bit,PERSIST_RPARAM_A_RExt_Sony_3.md5
++1,RExt/QMATRIX_A_RExt_Sony_1,QMATRIX_A_RExt_Sony_1.bit,QMATRIX_A_RExt_Sony_1.md5
++0,RExt/SAO_A_RExt_MediaTek_1,SAO_A_RExt_MediaTek_1.bit,SAO_A_RExt_MediaTek_1.md5, # Runs out of memory - could be fixed
++0,RExt/TSCTX_10bit_I_RExt_SHARP_1,TSCTX_10bit_I_RExt_SHARP_1.bin,TSCTX_10bit_I_RExt_SHARP_1.md5
++0,RExt/TSCTX_10bit_RExt_SHARP_1,TSCTX_10bit_RExt_SHARP_1.bin,TSCTX_10bit_RExt_SHARP_1.md5
++0,RExt/TSCTX_12bit_I_RExt_SHARP_1,TSCTX_12bit_I_RExt_SHARP_1.bin,TSCTX_12bit_I_RExt_SHARP_1.md5
++0,RExt/TSCTX_12bit_RExt_SHARP_1,TSCTX_12bit_RExt_SHARP_1.bin,TSCTX_12bit_RExt_SHARP_1.md5
++0,RExt/TSCTX_8bit_I_RExt_SHARP_1,TSCTX_8bit_I_RExt_SHARP_1.bin,TSCTX_8bit_I_RExt_SHARP_1.md5
++0,RExt/TSCTX_8bit_RExt_SHARP_1,TSCTX_8bit_RExt_SHARP_1.bin,TSCTX_8bit_RExt_SHARP_1.md5
++0,RExt/WAVETILES_RExt_Sony_2,WAVETILES_RExt_Sony_2.bit,WAVETILES_RExt_Sony_2.md5
++1,local/sao_cu16_mobile_344x280,sao_cu16_mobile_344x280.265,sao_cu16_mobile_344x280.md5
++1,local/dblk_cu16_mobile_344x280,dblk_cu16_mobile_344x280.265,dblk_cu16_mobile_344x280.md5
++1,local/dblksao_cu16_mobile_344x280,dblksao_cu16_mobile_344x280.265,dblksao_cu16_mobile_344x280.md5
++1,local/dblk_pu32_horses_832x448,dblk_pu32_horses_832x448.265,dblk_pu32_horses_832x448.md5
++1,local/intra_pred_21_laps,intra_pred_21_laps.265,intra_pred_21_laps.md5
+diff --git a/pi-util/conf_h265.2016_HEVC_v1.csv b/pi-util/conf_h265.2016_HEVC_v1.csv
+new file mode 100644
+index 0000000000..6082641271
+--- /dev/null
++++ b/pi-util/conf_h265.2016_HEVC_v1.csv
+@@ -0,0 +1,147 @@
++1,AMP_A_Samsung_7,AMP_A_Samsung_7.bin,AMP_A_Samsung_7.md5
++1,AMP_B_Samsung_7,AMP_B_Samsung_7.bin,AMP_B_Samsung_7.md5
++1,AMP_D_Hisilicon_3,AMP_D_Hisilicon.bit,AMP_D_Hisilicon_3.yuv.md5
++1,AMP_E_Hisilicon_3,AMP_E_Hisilicon.bit,AMP_E_Hisilicon_3.yuv.md5
++1,AMP_F_Hisilicon_3,AMP_F_Hisilicon_3.bit,AMP_F_Hisilicon_3.yuv.md5
++1,AMVP_A_MTK_4,AMVP_A_MTK_4.bit,AMVP_A_MTK_4.md5
++1,AMVP_B_MTK_4,AMVP_B_MTK_4.bit,AMVP_B_MTK_4.md5
++1,AMVP_C_Samsung_7,AMVP_C_Samsung_7.bin,AMVP_C_Samsung_7.md5
++1,BUMPING_A_ericsson_1,BUMPING_A_ericsson_1.bit,BUMPING_A_ericsson_1.md5
++1,CAINIT_A_SHARP_4,CAINIT_A_SHARP_4.bit,CAINIT_A_SHARP_4.md5
++1,CAINIT_B_SHARP_4,CAINIT_B_SHARP_4.bit,CAINIT_B_SHARP_4.md5
++1,CAINIT_C_SHARP_3,CAINIT_C_SHARP_3.bit,CAINIT_C_SHARP_3.md5
++1,CAINIT_D_SHARP_3,CAINIT_D_SHARP_3.bit,CAINIT_D_SHARP_3.md5
++1,CAINIT_E_SHARP_3,CAINIT_E_SHARP_3.bit,CAINIT_E_SHARP_3.md5
++1,CAINIT_F_SHARP_3,CAINIT_F_SHARP_3.bit,CAINIT_F_SHARP_3.md5
++1,CAINIT_G_SHARP_3,CAINIT_G_SHARP_3.bit,CAINIT_G_SHARP_3.md5
++1,CAINIT_H_SHARP_3,CAINIT_H_SHARP_3.bit,CAINIT_H_SHARP_3.md5
++1,CIP_A_Panasonic_3,CIP_A_Panasonic_3.bit,CIP_A_Panasonic_3_yuv.md5
++1,cip_B_NEC_3,cip_B_NEC_3.bit,cip_B_NEC_3.md5
++1,CIP_C_Panasonic_2,CIP_C_Panasonic_2.bit,CIP_C_Panasonic_2_yuv.md5
++1,CONFWIN_A_Sony_1,CONFWIN_A_Sony_1.bit,CONFWIN_A_Sony_1.md5
++1,DBLK_A_MAIN10_VIXS_4,DBLK_A_MAIN10_VIXS_4.bit,DBLK_A_MAIN10_VIXS_4.md5
++1,DBLK_A_SONY_3,DBLK_A_SONY_3.bit,DBLK_A_SONY_3.bit.yuv.md5
++1,DBLK_B_SONY_3,DBLK_B_SONY_3.bit,DBLK_B_SONY_3.bit.yuv.md5
++1,DBLK_C_SONY_3,DBLK_C_SONY_3.bit,DBLK_C_SONY_3.bit.yuv.md5
++1,DBLK_D_VIXS_2,DBLK_D_VIXS_2.bit,DBLK_D_VIXS_2_yuv.md5
++1,DBLK_E_VIXS_2,DBLK_E_VIXS_2.bit,DBLK_E_VIXS_2_yuv.md5
++1,DBLK_F_VIXS_2,DBLK_F_VIXS_2.bit,DBLK_F_VIXS_2_yuv.md5
++1,DBLK_G_VIXS_2,DBLK_G_VIXS_2.bit,DBLK_G_VIXS_2_yuv.md5
++1,DELTAQP_A_BRCM_4,DELTAQP_A_BRCM_4.bit,DELTAQP_A_BRCM_4_yuv.md5
++1,DELTAQP_B_SONY_3,DELTAQP_B_SONY_3.bit,DELTAQP_B_SONY_3.bit.yuv.md5
++1,DELTAQP_C_SONY_3,DELTAQP_C_SONY_3.bit,DELTAQP_C_SONY_3.bit.yuv.md5
++1,DSLICE_A_HHI_5,DSLICE_A_HHI_5.bin,DSLICE_A_HHI_5.md5
++1,DSLICE_B_HHI_5,DSLICE_B_HHI_5.bin,DSLICE_B_HHI_5.md5
++1,DSLICE_C_HHI_5,DSLICE_C_HHI_5.bin,DSLICE_C_HHI_5.md5
++1,ENTP_A_QUALCOMM_1,ENTP_A_Qualcomm_1.bit,ENTP_A_Qualcomm_1.md5
++1,ENTP_B_Qualcomm_1,ENTP_B_Qualcomm_1.bit,ENTP_B_Qualcomm_1.md5
++1,ENTP_C_Qualcomm_1,ENTP_C_Qualcomm_1.bit,ENTP_C_Qualcomm_1.md5
++1,EXT_A_ericsson_4,EXT_A_ericsson_4.bit,EXT_A_ericsson_4.md5
++1,FILLER_A_Sony_1,FILLER_A_Sony_1.bit,FILLER_A_Sony_1.md5
++1,HRD_A_Fujitsu_3,HRD_A_Fujitsu_3.bin,HRD_A_Fujitsu_3.md5
++1,INITQP_A_Sony_1,INITQP_A_Sony_1.bit,INITQP_A_Sony_1.md5
++1,INITQP_B_Main10_Sony_1,INITQP_B_Main10_Sony_1.bit,INITQP_B_Main10_Sony_1.md5
++1,ipcm_A_NEC_3,ipcm_A_NEC_3.bit,ipcm_A_NEC_3.md5
++1,ipcm_B_NEC_3,ipcm_B_NEC_3.bit,ipcm_B_NEC_3.md5
++1,ipcm_C_NEC_3,ipcm_C_NEC_3.bit,ipcm_C_NEC_3.md5
++1,ipcm_D_NEC_3,ipcm_D_NEC_3.bit,ipcm_D_NEC_3.md5
++1,ipcm_E_NEC_2,ipcm_E_NEC_2.bit,ipcm_E_NEC_2.md5
++1,IPRED_A_docomo_2,IPRED_A_docomo_2.bit,IPRED_A_docomo_2.md5
++1,IPRED_B_Nokia_3,IPRED_B_Nokia_3.bit,IPRED_B_Nokia_3_yuv.md5
++1,IPRED_C_Mitsubishi_3,IPRED_C_Mitsubishi_3.bit,IPRED_C_Mitsubishi_3_yuv.md5
++1,LS_A_Orange_2,LS_A_Orange_2.bit,LS_A_Orange_2_yuv.md5
++1,LS_B_Orange_4,LS_B_Orange_4.bit,LS_B_Orange_4_yuv.md5
++1,LTRPSPS_A_Qualcomm_1,LTRPSPS_A_Qualcomm_1.bit,LTRPSPS_A_Qualcomm_1.md5
++1,MAXBINS_A_TI_5,MAXBINS_A_TI_5.bit,MAXBINS_A_TI_5_yuv.md5
++1,MAXBINS_B_TI_5,MAXBINS_B_TI_5.bit,MAXBINS_B_TI_5_yuv.md5
++1,MAXBINS_C_TI_5,MAXBINS_C_TI_5.bit,MAXBINS_C_TI_5_yuv.md5
++1,MERGE_A_TI_3,MERGE_A_TI_3.bit,MERGE_A_TI_3.md5
++1,MERGE_B_TI_3,MERGE_B_TI_3.bit,MERGE_B_TI_3.md5
++1,MERGE_C_TI_3,MERGE_C_TI_3.bit,MERGE_C_TI_3.md5
++1,MERGE_D_TI_3,MERGE_D_TI_3.bit,MERGE_D_TI_3.md5
++1,MERGE_E_TI_3,MERGE_E_TI_3.bit,MERGE_E_TI_3.md5
++1,MERGE_F_MTK_4,MERGE_F_MTK_4.bit,MERGE_F_MTK_4.md5
++1,MERGE_G_HHI_4,MERGE_G_HHI_4.bit,MERGE_G_HHI_4.md5
++1,MVCLIP_A_qualcomm_3,MVCLIP_A_qualcomm_3.bit,MVCLIP_A_qualcomm_3.yuv.md5
++1,MVDL1ZERO_A_docomo_4,MVDL1ZERO_A_docomo_4.bit,MVDL1ZERO_A_docomo_4.md5
++1,MVEDGE_A_qualcomm_3,MVEDGE_A_qualcomm_3.bit,MVEDGE_A_qualcomm_3.yuv.md5
++1,NoOutPrior_A_Qualcomm_1,NoOutPrior_A_Qualcomm_1.bit,NoOutPrior_A_Qualcomm_1.md5
++1,NoOutPrior_B_Qualcomm_1,NoOutPrior_B_Qualcomm_1.bit,NoOutPrior_B_Qualcomm_1.md5
++1,NUT_A_ericsson_5,NUT_A_ericsson_5.bit,NUT_A_ericsson_5.md5
++1,OPFLAG_A_Qualcomm_1,OPFLAG_A_Qualcomm_1.bit,OPFLAG_A_Qualcomm_1.md5
++1,OPFLAG_B_Qualcomm_1,OPFLAG_B_Qualcomm_1.bit,OPFLAG_B_Qualcomm_1.md5
++1,OPFLAG_C_Qualcomm_1,OPFLAG_C_Qualcomm_1.bit,OPFLAG_C_Qualcomm_1.md5
++1,PICSIZE_A_Bossen_1,PICSIZE_A_Bossen_1.bin,PICSIZE_A_Bossen_1.md5
++1,PICSIZE_B_Bossen_1,PICSIZE_B_Bossen_1.bin,PICSIZE_B_Bossen_1.md5
++1,PICSIZE_C_Bossen_1,PICSIZE_C_Bossen_1.bin,PICSIZE_C_Bossen_1.md5
++1,PICSIZE_D_Bossen_1,PICSIZE_D_Bossen_1.bin,PICSIZE_D_Bossen_1.md5
++1,PMERGE_A_TI_3,PMERGE_A_TI_3.bit,PMERGE_A_TI_3.md5
++1,PMERGE_B_TI_3,PMERGE_B_TI_3.bit,PMERGE_B_TI_3.md5
++1,PMERGE_C_TI_3,PMERGE_C_TI_3.bit,PMERGE_C_TI_3.md5
++1,PMERGE_D_TI_3,PMERGE_D_TI_3.bit,PMERGE_D_TI_3.md5
++1,PMERGE_E_TI_3,PMERGE_E_TI_3.bit,PMERGE_E_TI_3.md5
++1,POC_A_Bossen_3,POC_A_Bossen_3.bin,POC_A_Bossen_3.md5
++1,PPS_A_qualcomm_7,PPS_A_qualcomm_7.bit,PPS_A_qualcomm_7.yuv.md5
++1,PS_B_VIDYO_3,PS_B_VIDYO_3.bit,PS_B_VIDYO_3_yuv.md5
++1,RAP_A_docomo_6,RAP_A_docomo_6.bit,RAP_A_docomo_6.md5
++1,RAP_B_Bossen_2,RAP_B_Bossen_2.bit,RAP_B_Bossen_2.md5
++1,RPLM_A_qualcomm_4,RPLM_A_qualcomm_4.bit,RPLM_A_qualcomm_4.yuv.md5
++1,RPLM_B_qualcomm_4,RPLM_B_qualcomm_4.bit,RPLM_B_qualcomm_4.yuv.md5
++1,RPS_A_docomo_5,RPS_A_docomo_5.bit,RPS_A_docomo_5.md5
++1,RPS_B_qualcomm_5,RPS_B_qualcomm_5.bit,RPS_B_qualcomm_5.yuv.md5
++1,RPS_C_ericsson_5,RPS_C_ericsson_5.bit,RPS_C_ericsson_5.md5
++1,RPS_D_ericsson_6,RPS_D_ericsson_6.bit,RPS_D_ericsson_6.md5
++1,RPS_E_qualcomm_5,RPS_E_qualcomm_5.bit,RPS_E_qualcomm_5.yuv.md5
++1,RPS_F_docomo_2,RPS_F_docomo_2.bit,RPS_F_docomo_2.md5
++1,RQT_A_HHI_4,RQT_A_HHI_4.bit,RQT_A_HHI_4.md5
++1,RQT_B_HHI_4,RQT_B_HHI_4.bit,RQT_B_HHI_4.md5
++1,RQT_C_HHI_4,RQT_C_HHI_4.bit,RQT_C_HHI_4.md5
++1,RQT_D_HHI_4,RQT_D_HHI_4.bit,RQT_D_HHI_4.md5
++1,RQT_E_HHI_4,RQT_E_HHI_4.bit,RQT_E_HHI_4.md5
++1,RQT_F_HHI_4,RQT_F_HHI_4.bit,RQT_F_HHI_4.md5
++1,RQT_G_HHI_4,RQT_G_HHI_4.bit,RQT_G_HHI_4.md5
++1,SAO_A_MediaTek_4,SAO_A_MediaTek_4.bit,SAO_A_MediaTek_4.md5
++1,SAO_B_MediaTek_5,SAO_B_MediaTek_5.bit,SAO_B_MediaTek_5.md5
++1,SAO_C_Samsung_5,SAO_C_Samsung_5.bin,SAO_C_Samsung_5.md5
++1,SAO_D_Samsung_5,SAO_D_Samsung_5.bin,SAO_D_Samsung_5.md5
++1,SAO_E_Canon_4,SAO_E_Canon_4.bit,SAO_E_Canon_4.md5
++1,SAO_F_Canon_3,SAO_F_Canon_3.bit,SAO_F_Canon_3.md5
++1,SAO_G_Canon_3,SAO_G_Canon_3.bit,SAO_G_Canon_3.md5
++1,SAO_H_Parabola_1,SAO_H_Parabola_1.bit,SAO_H_Parabola_1.md5
++2,SAODBLK_A_MainConcept_4,SAODBLK_A_MainConcept_4.bin,SAODBLK_A_MainConcept_4_md5.txt
++2,SAODBLK_B_MainConcept_4,SAODBLK_B_MainConcept_4.bin,SAODBLK_B_MainConcept_4_md5.txt
++1,SDH_A_Orange_4,SDH_A_Orange_4.bit,SDH_A_Orange_4_yuv.md5
++1,SLICES_A_Rovi_3,SLICES_A_Rovi_3.bin,SLICES_A_Rovi_3.md5
++1,SLIST_A_Sony_5,SLIST_A_Sony_5.bin,SLIST_A_Sony_5_yuv.md5
++1,SLIST_B_Sony_9,SLIST_B_Sony_9.bin,SLIST_B_Sony_9_yuv.md5
++1,SLIST_C_Sony_4,SLIST_C_Sony_4.bin,SLIST_C_Sony_4_yuv.md5
++1,SLIST_D_Sony_9,str.bin,SLIST_D_Sony_9_yuv.md5
++1,SLPPLP_A_VIDYO_2,SLPPLP_A_VIDYO_2.bit,SLPPLP_A_VIDYO_2_yuv.md5
++1,STRUCT_A_Samsung_7,STRUCT_A_Samsung_7.bin,STRUCT_A_Samsung_7.md5
++1,STRUCT_B_Samsung_7,STRUCT_B_Samsung_7.bin,STRUCT_B_Samsung_7.md5
++1,TILES_A_Cisco_2,TILES_A_Cisco_2.bin,TILES_A_Cisco_2_yuv.md5
++1,TILES_B_Cisco_1,TILES_B_Cisco_1.bin,TILES_B_Cisco_1_yuv.md5
++1,TMVP_A_MS_3,TMVP_A_MS_3.bit,TMVP_A_MS_3.yuv.md5
++1,TSCL_A_VIDYO_5,TSCL_A_VIDYO_5.bit,TSCL_A_VIDYO_5_yuv.md5
++1,TSCL_B_VIDYO_4,TSCL_B_VIDYO_4.bit,TSCL_B_VIDYO_4_yuv.md5
++1,TSKIP_A_MS_3,TSKIP_A_MS_3.bit,TSKIP_A_MS_3.yuv.md5
++3,TSUNEQBD_A_MAIN10_Technicolor_2,TSUNEQBD_A_MAIN10_Technicolor_2.bit,TSUNEQBD_A_MAIN10_Technicolor_2_yuv.md5, # unequal bit depth
++1,TUSIZE_A_Samsung_1,TUSIZE_A_Samsung_1.bin,TUSIZE_A_Samsung_1.md5
++1,VPSID_A_VIDYO_2,VPSID_A_VIDYO_2.bit,VPSID_A_VIDYO_2_yuv.md5
++3,VPSSPSPPS_A_MainConcept_1,VPSSPSPPS_A_MainConcept_1.bin,VPSSPSPPS_A_MainConcept_1_md5.txt, # ???
++1,WP_A_MAIN10_Toshiba_3,WP_A_MAIN10_Toshiba_3.bit,WP_A_MAIN10_Toshiba_3_yuv.md5
++1,WP_A_Toshiba_3,WP_A_Toshiba_3.bit,WP_A_Toshiba_3_yuv.md5
++1,WP_B_Toshiba_3,WP_B_Toshiba_3.bit,WP_B_Toshiba_3_yuv.md5
++1,WP_MAIN10_B_Toshiba_3,WP_MAIN10_B_Toshiba_3.bit,WP_MAIN10_B_Toshiba_3_yuv.md5
++1,WPP_A_ericsson_MAIN10_2,WPP_A_ericsson_MAIN10_2.bit,WPP_A_ericsson_MAIN10_yuv.md5
++1,WPP_A_ericsson_MAIN_2,WPP_A_ericsson_MAIN_2.bit,WPP_A_ericsson_MAIN_2_yuv.md5
++1,WPP_B_ericsson_MAIN10_2,WPP_B_ericsson_MAIN10_2.bit,WPP_B_ericsson_MAIN10_yuv.md5
++1,WPP_B_ericsson_MAIN_2,WPP_B_ericsson_MAIN_2.bit,WPP_B_ericsson_MAIN_2_yuv.md5
++1,WPP_C_ericsson_MAIN10_2,WPP_C_ericsson_MAIN10_2.bit,WPP_C_ericsson_MAIN10_yuv.md5
++1,WPP_C_ericsson_MAIN_2,WPP_C_ericsson_MAIN_2.bit,WPP_C_ericsson_MAIN_2_yuv.md5
++1,WPP_D_ericsson_MAIN10_2,WPP_D_ericsson_MAIN10_2.bit,WPP_D_ericsson_MAIN10_yuv.md5
++1,WPP_D_ericsson_MAIN_2,WPP_D_ericsson_MAIN_2.bit,WPP_D_ericsson_MAIN_2_yuv.md5
++1,WPP_E_ericsson_MAIN10_2,WPP_E_ericsson_MAIN10_2.bit,WPP_E_ericsson_MAIN10_yuv.md5
++1,WPP_E_ericsson_MAIN_2,WPP_E_ericsson_MAIN_2.bit,WPP_E_ericsson_MAIN_2_yuv.md5
++1,WPP_F_ericsson_MAIN10_2,WPP_F_ericsson_MAIN10_2.bit,WPP_F_ericsson_MAIN10_yuv.md5
++1,WPP_F_ericsson_MAIN_2,WPP_F_ericsson_MAIN_2.bit,WPP_F_ericsson_MAIN_2_yuv.md5
+diff --git a/pi-util/conf_h265.csv b/pi-util/conf_h265.csv
+new file mode 100644
+index 0000000000..fc14f2a3c2
+--- /dev/null
++++ b/pi-util/conf_h265.csv
+@@ -0,0 +1,144 @@
++1,ADJUST_IPRED_ANGLE_A_RExt_Mitsubishi_1,ADJUST_IPRED_ANGLE_A_RExt_Mitsubishi_1.bit,ADJUST_IPRED_ANGLE_A_RExt_Mitsubishi_1.md5
++1,AMP_A_Samsung_6,AMP_A_Samsung_6.bin,AMP_A_Samsung_6.md5
++1,AMP_B_Samsung_6,AMP_B_Samsung_6.bin,AMP_B_Samsung_6.md5
++1,AMP_D_Hisilicon_3,AMP_D_Hisilicon.bit,AMP_D_Hisilicon_3.yuv.md5
++1,AMP_E_Hisilicon_3,AMP_E_Hisilicon.bit,AMP_E_Hisilicon_3.yuv.md5
++1,AMP_F_Hisilicon_3,AMP_F_Hisilicon_3.bit,AMP_F_Hisilicon_3.yuv.md5
++1,AMVP_A_MTK_4,AMVP_A_MTK_4.bit,AMVP_A_MTK_4.md5
++1,AMVP_B_MTK_4,AMVP_B_MTK_4.bit,AMVP_B_MTK_4.md5
++1,AMVP_C_Samsung_6,AMVP_C_Samsung_6.bin,AMVP_C_Samsung_6.md5
++1,BUMPING_A_ericsson_1,BUMPING_A_ericsson_1.bit,BUMPING_A_ericsson_1.md5
++1,CAINIT_A_SHARP_4,CAINIT_A_SHARP_4.bit,CAINIT_A_SHARP_4.md5
++1,CAINIT_B_SHARP_4,CAINIT_B_SHARP_4.bit,CAINIT_B_SHARP_4.md5
++1,CAINIT_C_SHARP_3,CAINIT_C_SHARP_3.bit,CAINIT_C_SHARP_3.md5
++1,CAINIT_D_SHARP_3,CAINIT_D_SHARP_3.bit,CAINIT_D_SHARP_3.md5
++1,CAINIT_E_SHARP_3,CAINIT_E_SHARP_3.bit,CAINIT_E_SHARP_3.md5
++1,CAINIT_F_SHARP_3,CAINIT_F_SHARP_3.bit,CAINIT_F_SHARP_3.md5
++1,CAINIT_G_SHARP_3,CAINIT_G_SHARP_3.bit,CAINIT_G_SHARP_3.md5
++1,CAINIT_H_SHARP_3,CAINIT_H_SHARP_3.bit,CAINIT_H_SHARP_3.md5
++1,CIP_A_Panasonic_3,CIP_A_Panasonic_3.bit,CIP_A_Panasonic_3_yuv.md5
++1,cip_B_NEC_3,cip_B_NEC_3.bit,cip_B_NEC_3.md5
++1,CIP_C_Panasonic_2,CIP_C_Panasonic_2.bit,CIP_C_Panasonic_2_yuv.md5
++1,CONFWIN_A_Sony_1,CONFWIN_A_Sony_1.bit,CONFWIN_A_Sony_1.md5
++1,DBLK_A_MAIN10_VIXS_3,DBLK_A_MAIN10_VIXS_3.bit,DBLK_A_MAIN10_VIXS_3.md5
++1,DBLK_A_SONY_3,DBLK_A_SONY_3.bit,DBLK_A_SONY_3.bit.yuv.md5
++1,DBLK_B_SONY_3,DBLK_B_SONY_3.bit,DBLK_B_SONY_3.bit.yuv.md5
++1,DBLK_C_SONY_3,DBLK_C_SONY_3.bit,DBLK_C_SONY_3.bit.yuv.md5
++1,DBLK_D_VIXS_2,DBLK_D_VIXS_2.bit,DBLK_D_VIXS_2_yuv.md5
++1,DBLK_E_VIXS_2,DBLK_E_VIXS_2.bit,DBLK_E_VIXS_2_yuv.md5
++1,DBLK_F_VIXS_2,DBLK_F_VIXS_2.bit,DBLK_F_VIXS_2_yuv.md5
++1,DBLK_G_VIXS_2,DBLK_G_VIXS_2.bit,DBLK_G_VIXS_2_yuv.md5
++1,DELTAQP_A_BRCM_4,DELTAQP_A_BRCM_4.bit,DELTAQP_A_BRCM_4_yuv.md5
++1,DELTAQP_B_SONY_3,DELTAQP_B_SONY_3.bit,DELTAQP_B_SONY_3.bit.yuv.md5
++1,DELTAQP_C_SONY_3,DELTAQP_C_SONY_3.bit,DELTAQP_C_SONY_3.bit.yuv.md5
++1,DSLICE_A_HHI_5,DSLICE_A_HHI_5.bin,DSLICE_A_HHI_5.md5
++1,DSLICE_B_HHI_5,DSLICE_B_HHI_5.bin,DSLICE_B_HHI_5.md5
++1,DSLICE_C_HHI_5,DSLICE_C_HHI_5.bin,DSLICE_C_HHI_5.md5
++1,ENTP_A_QUALCOMM_1,ENTP_A_Qualcomm_1.bit,ENTP_A_Qualcomm_1.md5
++1,ENTP_B_Qualcomm_1,ENTP_B_Qualcomm_1.bit,ENTP_B_Qualcomm_1.md5
++1,ENTP_C_Qualcomm_1,ENTP_C_Qualcomm_1.bit,ENTP_C_Qualcomm_1.md5
++1,EXT_A_ericsson_4,EXT_A_ericsson_4.bit,EXT_A_ericsson_4.md5
++1,FILLER_A_Sony_1,FILLER_A_Sony_1.bit,FILLER_A_Sony_1.md5
++1,HRD_A_Fujitsu_3,HRD_A_Fujitsu_3.bin,HRD_A_Fujitsu_3.md5
++1,INITQP_A_Sony_1,INITQP_A_Sony_1.bit,INITQP_A_Sony_1.md5
++1,INITQP_B_Main10_Sony_1,INITQP_B_Main10_Sony_1.bit,INITQP_B_Main10_Sony_1.md5
++1,ipcm_A_NEC_3,ipcm_A_NEC_3.bit,ipcm_A_NEC_3.md5
++1,ipcm_B_NEC_3,ipcm_B_NEC_3.bit,ipcm_B_NEC_3.md5
++1,ipcm_C_NEC_3,ipcm_C_NEC_3.bit,ipcm_C_NEC_3.md5
++1,ipcm_D_NEC_3,ipcm_D_NEC_3.bit,ipcm_D_NEC_3.md5
++1,ipcm_E_NEC_2,ipcm_E_NEC_2.bit,ipcm_E_NEC_2.md5
++1,IPRED_A_docomo_2,IPRED_A_docomo_2.bit,IPRED_A_docomo_2.md5
++1,IPRED_B_Nokia_3,IPRED_B_Nokia_3.bit,IPRED_B_Nokia_3_yuv.md5
++1,IPRED_C_Mitsubishi_3,IPRED_C_Mitsubishi_3.bit,IPRED_C_Mitsubishi_3_yuv.md5
++1,LS_A_Orange_2,LS_A_Orange_2.bit,LS_A_Orange_2_yuv.md5
++1,LS_B_Orange_4,LS_B_Orange_4.bit,LS_B_Orange_4_yuv.md5
++1,LTRPSPS_A_Qualcomm_1,LTRPSPS_A_Qualcomm_1.bit,LTRPSPS_A_Qualcomm_1.md5
++1,MAXBINS_A_TI_4,MAXBINS_A_TI_4.bit,MAXBINS_A_TI_4.md5
++1,MAXBINS_B_TI_4,MAXBINS_B_TI_4.bit,MAXBINS_B_TI_4.md5
++1,MAXBINS_C_TI_4,MAXBINS_C_TI_4.bit,MAXBINS_C_TI_4.md5
++1,MERGE_A_TI_3,MERGE_A_TI_3.bit,MERGE_A_TI_3.md5
++1,MERGE_B_TI_3,MERGE_B_TI_3.bit,MERGE_B_TI_3.md5
++1,MERGE_C_TI_3,MERGE_C_TI_3.bit,MERGE_C_TI_3.md5
++1,MERGE_D_TI_3,MERGE_D_TI_3.bit,MERGE_D_TI_3.md5
++1,MERGE_E_TI_3,MERGE_E_TI_3.bit,MERGE_E_TI_3.md5
++1,MERGE_F_MTK_4,MERGE_F_MTK_4.bit,MERGE_F_MTK_4.md5
++1,MERGE_G_HHI_4,MERGE_G_HHI_4.bit,MERGE_G_HHI_4.md5
++1,MVCLIP_A_qualcomm_3,MVCLIP_A_qualcomm_3.bit,MVCLIP_A_qualcomm_3.yuv.md5
++1,MVDL1ZERO_A_docomo_4,MVDL1ZERO_A_docomo_4.bit,MVDL1ZERO_A_docomo_4.md5
++1,MVEDGE_A_qualcomm_3,MVEDGE_A_qualcomm_3.bit,MVEDGE_A_qualcomm_3.yuv.md5
++1,NoOutPrior_A_Qualcomm_1,NoOutPrior_A_Qualcomm_1.bit,NoOutPrior_A_Qualcomm_1.md5
++1,NoOutPrior_B_Qualcomm_1,NoOutPrior_B_Qualcomm_1.bit,NoOutPrior_B_Qualcomm_1.md5
++1,NUT_A_ericsson_5,NUT_A_ericsson_5.bit,NUT_A_ericsson_5.md5
++1,OPFLAG_A_Qualcomm_1,OPFLAG_A_Qualcomm_1.bit,OPFLAG_A_Qualcomm_1.md5
++1,OPFLAG_B_Qualcomm_1,OPFLAG_B_Qualcomm_1.bit,OPFLAG_B_Qualcomm_1.md5
++1,OPFLAG_C_Qualcomm_1,OPFLAG_C_Qualcomm_1.bit,OPFLAG_C_Qualcomm_1.md5
++1,PICSIZE_A_Bossen_1,PICSIZE_A_Bossen_1.bin,PICSIZE_A_Bossen_1.md5
++1,PICSIZE_B_Bossen_1,PICSIZE_B_Bossen_1.bin,PICSIZE_B_Bossen_1.md5
++1,PICSIZE_C_Bossen_1,PICSIZE_C_Bossen_1.bin,PICSIZE_C_Bossen_1.md5
++1,PICSIZE_D_Bossen_1,PICSIZE_D_Bossen_1.bin,PICSIZE_D_Bossen_1.md5
++1,PMERGE_A_TI_3,PMERGE_A_TI_3.bit,PMERGE_A_TI_3.md5
++1,PMERGE_B_TI_3,PMERGE_B_TI_3.bit,PMERGE_B_TI_3.md5
++1,PMERGE_C_TI_3,PMERGE_C_TI_3.bit,PMERGE_C_TI_3.md5
++1,PMERGE_D_TI_3,PMERGE_D_TI_3.bit,PMERGE_D_TI_3.md5
++1,PMERGE_E_TI_3,PMERGE_E_TI_3.bit,PMERGE_E_TI_3.md5
++1,POC_A_Bossen_3,POC_A_Bossen_3.bin,POC_A_Bossen_3.md5
++1,PPS_A_qualcomm_7,PPS_A_qualcomm_7.bit,PPS_A_qualcomm_7.yuv.md5
++1,PS_B_VIDYO_3,PS_B_VIDYO_3.bit,PS_B_VIDYO_3_yuv.md5
++1,RAP_A_docomo_6,RAP_A_docomo_6.bit,RAP_A_docomo_6.md5
++1,RAP_B_Bossen_2,RAP_B_Bossen_2.bit,RAP_B_Bossen_2.md5
++1,RPLM_A_qualcomm_4,RPLM_A_qualcomm_4.bit,RPLM_A_qualcomm_4.yuv.md5
++1,RPLM_B_qualcomm_4,RPLM_B_qualcomm_4.bit,RPLM_B_qualcomm_4.yuv.md5
++1,RPS_A_docomo_5,RPS_A_docomo_5.bit,RPS_A_docomo_5.md5
++1,RPS_B_qualcomm_5,RPS_B_qualcomm_5.bit,RPS_B_qualcomm_5.yuv.md5
++1,RPS_C_ericsson_5,RPS_C_ericsson_5.bit,RPS_C_ericsson_5.md5
++1,RPS_D_ericsson_6,RPS_D_ericsson_6.bit,RPS_D_ericsson_6.md5
++1,RPS_E_qualcomm_5,RPS_E_qualcomm_5.bit,RPS_E_qualcomm_5.yuv.md5
++1,RPS_F_docomo_2,RPS_F_docomo_2.bit,RPS_F_docomo_2.md5
++1,RQT_A_HHI_4,RQT_A_HHI_4.bit,RQT_A_HHI_4.md5
++1,RQT_B_HHI_4,RQT_B_HHI_4.bit,RQT_B_HHI_4.md5
++1,RQT_C_HHI_4,RQT_C_HHI_4.bit,RQT_C_HHI_4.md5
++1,RQT_D_HHI_4,RQT_D_HHI_4.bit,RQT_D_HHI_4.md5
++1,RQT_E_HHI_4,RQT_E_HHI_4.bit,RQT_E_HHI_4.md5
++1,RQT_F_HHI_4,RQT_F_HHI_4.bit,RQT_F_HHI_4.md5
++1,RQT_G_HHI_4,RQT_G_HHI_4.bit,RQT_G_HHI_4.md5
++1,SAO_A_MediaTek_4,SAO_A_MediaTek_4.bit,SAO_A_MediaTek_4.md5
++1,SAO_B_MediaTek_5,SAO_B_MediaTek_5.bit,SAO_B_MediaTek_5.md5
++1,SAO_C_Samsung_5,SAO_C_Samsung_5.bin,SAO_C_Samsung_5.md5
++1,SAO_D_Samsung_5,SAO_D_Samsung_5.bin,SAO_D_Samsung_5.md5
++1,SAO_E_Canon_4,SAO_E_Canon_4.bit,SAO_E_Canon_4.md5
++1,SAO_F_Canon_3,SAO_F_Canon_3.bit,SAO_F_Canon_3.md5
++1,SAO_G_Canon_3,SAO_G_Canon_3.bit,SAO_G_Canon_3.md5
++1,SDH_A_Orange_4,SDH_A_Orange_4.bit,SDH_A_Orange_4_yuv.md5
++1,SLICES_A_Rovi_3,SLICES_A_Rovi_3.bin,SLICES_A_Rovi_3.md5
++1,SLIST_A_Sony_4,str.bin,SLIST_A_Sony_4_yuv.md5
++1,SLIST_B_Sony_8,str.bin,SLIST_B_Sony_8_yuv.md5
++1,SLIST_C_Sony_3,str.bin,SLIST_C_Sony_3_yuv.md5
++1,SLIST_D_Sony_9,str.bin,SLIST_D_Sony_9_yuv.md5
++1,SLPPLP_A_VIDYO_2,SLPPLP_A_VIDYO_2.bit,SLPPLP_A_VIDYO_2_yuv.md5
++1,STRUCT_A_Samsung_6,STRUCT_A_Samsung_6.bin,STRUCT_A_Samsung_6.md5
++1,STRUCT_B_Samsung_6,STRUCT_B_Samsung_6.bin,STRUCT_B_Samsung_6.md5
++1,TILES_A_Cisco_2,TILES_A_Cisco_2.bin,TILES_A_Cisco_2_yuv.md5
++1,TILES_B_Cisco_1,TILES_B_Cisco_1.bin,TILES_B_Cisco_1_yuv.md5
++1,TMVP_A_MS_3,TMVP_A_MS_3.bit,TMVP_A_MS_3.yuv.md5
++1,TSCL_A_VIDYO_5,TSCL_A_VIDYO_5.bit,TSCL_A_VIDYO_5_yuv.md5
++1,TSCL_B_VIDYO_4,TSCL_B_VIDYO_4.bit,TSCL_B_VIDYO_4_yuv.md5
++1,TSKIP_A_MS_3,TSKIP_A_MS_3.bit,TSKIP_A_MS_3.yuv.md5
++0,TSUNEQBD_A_MAIN10_Technicolor_2,TSUNEQBD_A_MAIN10_Technicolor_2.bit,TSUNEQBD_A_MAIN10_Technicolor_2_yuv.md5, # Y/C bit depth unmatched
++1,TUSIZE_A_Samsung_1,TUSIZE_A_Samsung_1.bin,TUSIZE_A_Samsung_1.md5
++1,VPSID_A_VIDYO_2,VPSID_A_VIDYO_2.bit,VPSID_A_VIDYO_2_yuv.md5
++1,WP_A_MAIN10_Toshiba_3,WP_A_MAIN10_Toshiba_3.bit,WP_A_MAIN10_Toshiba_3_yuv.md5
++1,WP_A_Toshiba_3,WP_A_Toshiba_3.bit,WP_A_Toshiba_3_yuv.md5
++1,WP_B_Toshiba_3,WP_B_Toshiba_3.bit,WP_B_Toshiba_3_yuv.md5
++1,WP_MAIN10_B_Toshiba_3,WP_MAIN10_B_Toshiba_3.bit,WP_MAIN10_B_Toshiba_3_yuv.md5
++1,WPP_A_ericsson_MAIN10_2,WPP_A_ericsson_MAIN10_2.bit,WPP_A_ericsson_MAIN10_yuv.md5
++1,WPP_A_ericsson_MAIN_2,WPP_A_ericsson_MAIN_2.bit,WPP_A_ericsson_MAIN_2_yuv.md5
++1,WPP_B_ericsson_MAIN10_2,WPP_B_ericsson_MAIN10_2.bit,WPP_B_ericsson_MAIN10_yuv.md5
++1,WPP_B_ericsson_MAIN_2,WPP_B_ericsson_MAIN_2.bit,WPP_B_ericsson_MAIN_2_yuv.md5
++1,WPP_C_ericsson_MAIN10_2,WPP_C_ericsson_MAIN10_2.bit,WPP_C_ericsson_MAIN10_yuv.md5
++1,WPP_C_ericsson_MAIN_2,WPP_C_ericsson_MAIN_2.bit,WPP_C_ericsson_MAIN_2_yuv.md5
++1,WPP_D_ericsson_MAIN10_2,WPP_D_ericsson_MAIN10_2.bit,WPP_D_ericsson_MAIN10_yuv.md5
++1,WPP_D_ericsson_MAIN_2,WPP_D_ericsson_MAIN_2.bit,WPP_D_ericsson_MAIN_2_yuv.md5
++1,WPP_E_ericsson_MAIN10_2,WPP_E_ericsson_MAIN10_2.bit,WPP_E_ericsson_MAIN10_yuv.md5
++1,WPP_E_ericsson_MAIN_2,WPP_E_ericsson_MAIN_2.bit,WPP_E_ericsson_MAIN_2_yuv.md5
++1,WPP_F_ericsson_MAIN10_2,WPP_F_ericsson_MAIN10_2.bit,WPP_F_ericsson_MAIN10_yuv.md5
++1,WPP_F_ericsson_MAIN_2,WPP_F_ericsson_MAIN_2.bit,WPP_F_ericsson_MAIN_2_yuv.md5
+diff --git a/pi-util/conf_pi1.sh b/pi-util/conf_pi1.sh
+new file mode 100755
+index 0000000000..59c0d3959e
+--- /dev/null
++++ b/pi-util/conf_pi1.sh
+@@ -0,0 +1,30 @@
++echo "Configure for Pi1"
++
++RPI_TOOLROOT=`pwd`/../tools/arm-bcm2708/arm-rpi-4.9.3-linux-gnueabihf
++RPI_OPT_VC=`pwd`/../firmware/opt/vc
++
++RPI_INCLUDES="-I$RPI_OPT_VC/include -I$RPI_OPT_VC/include/interface/vcos/pthreads -I$RPI_OPT_VC/include/interface/vmcs_host/linux"
++RPI_LIBDIRS="-L$RPI_TOOLROOT/lib -L$RPI_OPT_VC/lib"
++#RPI_KEEPS="-save-temps=obj"
++RPI_KEEPS=""
++
++./configure --enable-cross-compile\
++ --cpu=arm1176jzf-s\
++ --arch=arm\
++ --disable-neon\
++ --target-os=linux\
++ --disable-stripping\
++ --enable-mmal\
++ --extra-cflags="-g $RPI_KEEPS $RPI_INCLUDES"\
++ --extra-cxxflags="$RPI_INCLUDES"\
++ --extra-ldflags="$RPI_LIBDIRS -Wl,-rpath=/opt/vc/lib,-rpath-link=$RPI_OPT_VC/lib,-rpath=/lib,-rpath=/usr/lib,-rpath-link=$RPI_TOOLROOT/lib,-rpath-link=$RPI_TOOLROOT/lib"\
++ --extra-libs="-Wl,--start-group -lbcm_host -lmmal -lmmal_util -lmmal_core -lvcos -lvcsm -lvchostif -lvchiq_arm"\
++ --cross-prefix=$RPI_TOOLROOT/bin/arm-linux-gnueabihf-
++
++
++# --enable-extra-warnings\
++# --arch=armv71\
++# --enable-shared\
++
++# gcc option for getting asm listing
++# -Wa,-ahls
+diff --git a/pi-util/conf_pi2.sh b/pi-util/conf_pi2.sh
+new file mode 100755
+index 0000000000..40549a35e5
+--- /dev/null
++++ b/pi-util/conf_pi2.sh
+@@ -0,0 +1,32 @@
++echo "Configure for Pi2/3"
++
++RPI_TOOLROOT=`pwd`/../tools/arm-bcm2708/arm-rpi-4.9.3-linux-gnueabihf
++RPI_OPT_VC=`pwd`/../firmware/hardfp/opt/vc
++
++RPI_INCLUDES="-I$RPI_OPT_VC/include -I$RPI_OPT_VC/include/interface/vcos/pthreads -I$RPI_OPT_VC/include/interface/vmcs_host/linux"
++RPI_LIBDIRS="-L$RPI_TOOLROOT/lib -L$RPI_OPT_VC/lib"
++RPI_DEFINES="-D__VCCOREVER__=0x4000000 -mfpu=neon-vfpv4"
++#RPI_KEEPS="-save-temps=obj"
++RPI_KEEPS=""
++
++./configure --enable-cross-compile\
++ --arch=armv6t2\
++ --cpu=cortex-a7\
++ --target-os=linux\
++ --disable-stripping\
++ --disable-thumb\
++ --enable-mmal\
++ --enable-rpi\
++ --extra-cflags="-ggdb $RPI_KEEPS $RPI_DEFINES $RPI_INCLUDES"\
++ --extra-cxxflags="$RPI_DEFINES $RPI_INCLUDES"\
++ --extra-ldflags="$RPI_LIBDIRS -Wl,-rpath=/opt/vc/lib,-rpath-link=$RPI_OPT_VC/lib,-rpath=/lib,-rpath=/usr/lib,-rpath-link=$RPI_TOOLROOT/lib,-rpath-link=$RPI_TOOLROOT/lib"\
++ --extra-libs="-Wl,--start-group -lbcm_host -lmmal -lmmal_util -lmmal_core -lvcos -lvcsm -lvchostif -lvchiq_arm"\
++ --cross-prefix=$RPI_TOOLROOT/bin/arm-linux-gnueabihf-
++
++# --enable-decoder=hevc_rpi\
++# --enable-extra-warnings\
++# --arch=armv71\
++# --enable-shared\
++
++# gcc option for getting asm listing
++# -Wa,-ahls
+diff --git a/pi-util/ffconf.py b/pi-util/ffconf.py
+new file mode 100755
+index 0000000000..e9556f0837
+--- /dev/null
++++ b/pi-util/ffconf.py
+@@ -0,0 +1,175 @@
++#!/usr/bin/env python
++
++import string
++import os
++import subprocess
++import re
++import argparse
++import sys
++import csv
++from stat import *
++
++ffmpeg_exec = "./ffmpeg"
++
++def testone(fileroot, srcname, es_file, md5_file, vcodec):
++ tmp_root = "/tmp"
++
++ names = srcname.split('/')
++ while len(names) > 1:
++ tmp_root = os.path.join(tmp_root, names[0])
++ del names[0]
++ name = names[0]
++
++ if not os.path.exists(tmp_root):
++ os.makedirs(tmp_root)
++
++ dec_file = os.path.join(tmp_root, name + ".dec.md5")
++ try:
++ os.remove(dec_file)
++ except:
++ pass
++
++ flog = open(os.path.join(tmp_root, name + ".log"), "wt")
++
++ # Unaligned needed for cropping conformance
++ rstr = subprocess.call(
++ [ffmpeg_exec, "-flags", "unaligned", "-vcodec", vcodec, "-i", os.path.join(fileroot, es_file), "-f", "md5", dec_file],
++ stdout=flog, stderr=subprocess.STDOUT)
++
++ try:
++ m1 = None
++ m2 = None
++ with open(os.path.join(fileroot, md5_file)) as f:
++ for line in f:
++ m1 = re.search("[0-9a-f]{32}", line.lower())
++ if m1:
++ break
++
++ with open(dec_file) as f:
++ m2 = re.search("[0-9a-f]{32}", f.readline())
++ except:
++ pass
++
++ if m1 and m2 and m1.group() == m2.group():
++ print >> flog, "Match: " + m1.group()
++ rv = 0
++ elif not m1:
++ print >> flog, "****** Cannot find m1"
++ rv = 3
++ elif not m2:
++ print >> flog, "****** Cannot find m2"
++ rv = 2
++ else:
++ print >> flog, "****** Mismatch: " + m1.group() + " != " + m2.group()
++ rv = 1
++ flog.close()
++ return rv
++
++def scandir(root):
++ aconf = []
++ ents = os.listdir(root)
++ ents.sort(key=str.lower)
++ for name in ents:
++ test_path = os.path.join(root, name)
++ if S_ISDIR(os.stat(test_path).st_mode):
++ files = os.listdir(test_path)
++ es_file = "?"
++ md5_file = "?"
++ for f in files:
++ (base, ext) = os.path.splitext(f)
++ if base[0] == '.':
++ pass
++ elif ext == ".bit" or ext == ".bin":
++ es_file = f
++ elif ext == ".md5" or (ext == ".txt" and (base[-4:] == "_md5" or base[-6:] == "md5sum")):
++ if md5_file == "?":
++ md5_file = f
++ elif base[-3:] == "yuv":
++ md5_file = f
++ aconf.append((1, name, es_file, md5_file))
++ return aconf
++
++def runtest(name, tests):
++ if not tests:
++ return True
++ for t in tests:
++ if name[0:len(t)] == t or name.find("/" + t) != -1:
++ return True
++ return False
++
++def doconf(csva, tests, test_root, vcodec):
++ unx_failures = []
++ unx_success = []
++ failures = 0
++ successes = 0
++ for a in csva:
++ exp_test = int(a[0])
++ if (exp_test and runtest(a[1], tests)):
++ name = a[1]
++ print "==== ", name,
++ sys.stdout.flush()
++
++ rv = testone(os.path.join(test_root, name), name, a[2], a[3], vcodec=vcodec)
++ if (rv == 0):
++ successes += 1
++ else:
++ failures += 1
++
++ if (rv == 0):
++ if exp_test == 2:
++ print ": * OK *"
++ unx_success.append(name)
++ else:
++ print ": ok"
++ elif exp_test == 2 and rv == 1:
++ print ": fail"
++ elif exp_test == 3 and rv == 2:
++ # Call an expected "crash" an abort
++ print ": abort"
++ else:
++ unx_failures.append(name)
++ if rv == 1:
++ print ": * FAIL *"
++ elif (rv == 2) :
++ print ": * CRASH *"
++ elif (rv == 3) :
++ print ": * MD5 MISSING *"
++ else :
++ print ": * BANG *"
++
++ if unx_failures or unx_success:
++ print "Unexpected Failures:", unx_failures
++ print "Unexpected Success: ", unx_success
++ else:
++ print "All tests normal:", successes, "ok,", failures, "failed"
++
++
++class ConfCSVDialect(csv.Dialect):
++ delimiter = ','
++ doublequote = True
++ lineterminator = '\n'
++ quotechar='"'
++ quoting = csv.QUOTE_MINIMAL
++ skipinitialspace = True
++ strict = True
++
++if __name__ == '__main__':
++
++ argp = argparse.ArgumentParser(description="FFmpeg h265 conformance tester")
++ argp.add_argument("tests", nargs='*')
++ argp.add_argument("--test_root", default="/opt/conform/h265.2016", help="Root dir for test")
++ argp.add_argument("--csvgen", action='store_true', help="Generate CSV file for dir")
++ argp.add_argument("--csv", default="pi-util/conf_h265.2016.csv", help="CSV filename")
++ argp.add_argument("--vcodec", default="hevc_rpi", help="vcodec name to use")
++ args = argp.parse_args()
++
++ if args.csvgen:
++ csv.writer(sys.stdout).writerows(scandir(args.test_root))
++ exit(0)
++
++ with open(args.csv, 'rt') as csvfile:
++ csva = [a for a in csv.reader(csvfile, ConfCSVDialect())]
++
++
++ doconf(csva, args.tests, args.test_root, args.vcodec)
++
+diff --git a/pi-util/ffperf.py b/pi-util/ffperf.py
+new file mode 100755
+index 0000000000..8bb326943f
+--- /dev/null
++++ b/pi-util/ffperf.py
+@@ -0,0 +1,125 @@
++#!/usr/bin/env python3
++
++import time
++import string
++import os
++import tempfile
++import subprocess
++import re
++import argparse
++import sys
++import csv
++from stat import *
++
++class tstats:
++ close_threshold = 0.01
++
++ def __init__(self, stats_dict=None):
++ if stats_dict != None:
++ self.name = stats_dict["name"]
++ self.elapsed = float(stats_dict["elapsed"])
++ self.user = float(stats_dict["user"])
++ self.sys = float(stats_dict["sys"])
++
++ def times_str(self):
++ ctime = self.sys + self.user
++ return "time=%6.2f, cpu=%6.2f (%4.2f%%)" % (self.elapsed, ctime, (ctime * 100.0) / self.elapsed)
++
++ def dict(self):
++ return {"name":self.name, "elapsed":self.elapsed, "user":self.user, "sys":self.sys}
++
++ def is_close(self, other):
++ return abs(self.elapsed - other.elapsed) / self.elapsed < self.close_threshold
++
++ def __lt__(self, other):
++ return self.elapsed < other.elapsed
++ def __gt__(self, other):
++ return self.elapsed > other.elapsed
++
++ def time_file(name, prefix):
++ stats = tstats()
++ stats.name = name
++ start_time = time.clock_gettime(time.CLOCK_MONOTONIC);
++ cproc = subprocess.Popen(["./ffmpeg", "-t", "30", "-i", prefix + name,
++ "-f", "null", os.devnull], bufsize=-1, stdout=flog, stderr=flog);
++ pinfo = os.wait4(cproc.pid, 0)
++ end_time = time.clock_gettime(time.CLOCK_MONOTONIC);
++ stats.elapsed = end_time - start_time
++ stats.user = pinfo[2].ru_utime
++ stats.sys = pinfo[2].ru_stime
++ return stats
++
++
++def common_prefix(s1, s2):
++ for i in range(min(len(s1),len(s2))):
++ if s1[i] != s2[i]:
++ return s1[:i]
++ return s1[:i+1]
++
++def main():
++ global flog
++
++ argp = argparse.ArgumentParser(description="FFmpeg performance tester", epilog="""
++To blank the screen before starting use "xdg-screensaver activate"
++(For some reason this doesn't seem to work from within python).
++""")
++
++ argp.add_argument("streams", nargs='*')
++ argp.add_argument("--csv_out", default="ffperf_out.csv", help="CSV output filename")
++ argp.add_argument("--csv_in", help="CSV input filename")
++ argp.add_argument("--prefix", help="Filename prefix (include terminal '/' if a directory).")
++ argp.add_argument("--repeat", default=3, type=int, help="Run repeat count")
++
++ args = argp.parse_args()
++
++ csv_out = csv.DictWriter(open(args.csv_out, 'w', newline=''), ["name", "elapsed", "user", "sys"])
++ csv_out.writeheader()
++
++ stats_in = {}
++ if args.csv_in != None:
++ with open(args.csv_in, 'r', newline='') as f_in:
++ stats_in = {x["name"]:tstats(x) for x in csv.DictReader(f_in)}
++
++ flog = open(os.path.join(tempfile.gettempdir(), "ffperf.log"), "wt")
++
++ streams = args.streams
++ if not streams:
++ if not stats_in:
++ print ("No source streams specified")
++ return 1
++ prefix = "" if args.prefix == None else args.prefix
++ streams = [k for k in stats_in]
++ elif args.prefix != None:
++ prefix = args.prefix
++ else:
++ prefix = streams[0]
++ for f in streams[1:]:
++ prefix = common_prefix(prefix, f)
++ pp = prefix.rpartition(os.sep)
++ prefix = pp[0] + pp[1]
++ streams = [s[len(prefix):] for s in streams]
++
++ for f in sorted(streams, key=lambda x : "~" * x.count(os.sep) + x.lower()):
++ print ("====", f)
++
++ t0 = tstats({"name":f, "elapsed":999, "user":999, "sys":999})
++ for i in range(args.repeat):
++ t = tstats.time_file(f, prefix)
++ print ("...", t.times_str())
++ if t0 > t:
++ t0 = t
++
++ if t0.name in stats_in:
++ pstat = stats_in[t0.name]
++ print("---" if pstat.is_close(t0) else "<<<" if t0 < pstat else ">>>", pstat.times_str())
++
++ csv_out.writerow(t0.dict())
++
++ print ()
++
++ return 0
++
++
++if __name__ == '__main__':
++ exit(main())
++
+diff --git a/pi-util/make_array.py b/pi-util/make_array.py
+new file mode 100755
+index 0000000000..67b22d2d51
+--- /dev/null
++++ b/pi-util/make_array.py
+@@ -0,0 +1,23 @@
++#!/usr/bin/env python
++
++# Usage
++# make_array file.bin
++# Produces file.h with array of bytes.
++#
++import sys
++for file in sys.argv[1:]:
++ prefix,suffix = file.split('.')
++ assert suffix=='bin'
++ name=prefix.split('/')[-1]
++ print 'Converting',file
++ with open(prefix+'.h','wb') as out:
++ print >>out, 'static const unsigned char',name,'[] = {'
++ with open(file,'rb') as fd:
++ i = 0
++ for byte in fd.read():
++ print >>out, '0x%02x, ' % ord(byte),
++ i = i + 1
++ if i % 8 == 0:
++ print >>out, ' // %04x' % (i - 8)
++ print >>out,'};'
++
+diff --git a/pi-util/perfcmp.py b/pi-util/perfcmp.py
+new file mode 100644
+index 0000000000..e44cfa0c3c
+--- /dev/null
++++ b/pi-util/perfcmp.py
+@@ -0,0 +1,101 @@
++#!/usr/bin/env python3
++
++import time
++import string
++import os
++import tempfile
++import subprocess
++import re
++import argparse
++import sys
++import csv
++from stat import *
++
++class tstats:
++ close_threshold = 0.01
++
++ def __init__(self, stats_dict=None):
++ if stats_dict != None:
++ self.name = stats_dict["name"]
++ self.elapsed = float(stats_dict["elapsed"])
++ self.user = float(stats_dict["user"])
++ self.sys = float(stats_dict["sys"])
++
++ def times_str(self):
++ ctime = self.sys + self.user
++ return "time=%6.2f, cpu=%6.2f (%4.2f%%)" % (self.elapsed, ctime, (ctime * 100.0) / self.elapsed)
++
++ def dict(self):
++ return {"name":self.name, "elapsed":self.elapsed, "user":self.user, "sys":self.sys}
++
++ def is_close(self, other):
++ return abs(self.elapsed - other.elapsed) / self.elapsed < self.close_threshold
++
++ def __lt__(self, other):
++ return self.elapsed < other.elapsed
++ def __gt__(self, other):
++ return self.elapsed > other.elapsed
++
++ def time_file(name, prefix):
++ stats = tstats()
++ stats.name = name
++ start_time = time.clock_gettime(time.CLOCK_MONOTONIC);
++ cproc = subprocess.Popen(["./ffmpeg", "-t", "30", "-i", prefix + name,
++ "-f", "null", os.devnull], bufsize=-1, stdout=flog, stderr=flog);
++ pinfo = os.wait4(cproc.pid, 0)
++ end_time = time.clock_gettime(time.CLOCK_MONOTONIC);
++ stats.elapsed = end_time - start_time
++ stats.user = pinfo[2].ru_utime
++ stats.sys = pinfo[2].ru_stime
++ return stats
++
++
++def common_prefix(s1, s2):
++ for i in range(min(len(s1),len(s2))):
++ if s1[i] != s2[i]:
++ return s1[:i]
++ return s1[:i+1]
++
++def main():
++ argp = argparse.ArgumentParser(description="FFmpeg performance compare")
++
++ argp.add_argument("stream0", help="CSV to compare")
++ argp.add_argument("stream1", nargs='?', default="ffperf_out.csv", help="CSV to compare")
++
++ args = argp.parse_args()
++
++ with open(args.stream0, 'r', newline='') as f_in:
++ stats0 = {x["name"]:tstats(x) for x in csv.DictReader(f_in)}
++ with open(args.stream1, 'r', newline='') as f_in:
++ stats1 = {x["name"]:tstats(x) for x in csv.DictReader(f_in)}
++
++ print (args.stream0, "<<-->>", args.stream1)
++ print ()
++
++ for f in sorted(stats0.keys() | stats1.keys(), key=lambda x : "~" * x.count(os.sep) + x.lower()):
++ if not (f in stats0) :
++ print (" XX :", f)
++ continue
++ if not (f in stats1) :
++ print (" XX :", f)
++ continue
++
++ s0 = stats0[f]
++ s1 = stats1[f]
++
++ pcent = ((s0.elapsed - s1.elapsed) / s0.elapsed) * 100.0
++ thresh = 0.3
++ tc = 6
++
++ nchar = min(tc - 1, int(abs(pcent) / thresh))
++ cc = " -- " if nchar == 0 else "<" * nchar + " " * (tc - nchar) if pcent < 0 else " " * (tc - nchar) + ">" * nchar
++
++ print ("%6.2f %s%6.2f (%+5.2f) : %s" %
++ (s0.elapsed, cc, s1.elapsed, pcent, f))
++
++ return 0
++
++
++if __name__ == '__main__':
++ exit(main())
++
+diff --git a/pi-util/qem.sh b/pi-util/qem.sh
+new file mode 100755
+index 0000000000..a4dbb6eacd
+--- /dev/null
++++ b/pi-util/qem.sh
+@@ -0,0 +1,9 @@
++TARGET_DIR=../src/eupton_vc4dev_2012a/software/vc4/DEV/applications/tutorials/user_shader_example_tex
++QASM=python\ ../local/bin/qasm.py
++SRC_FILE=libavcodec/rpi_hevc_shader.qasm
++DST_BASE=shader
++
++cp libavcodec/rpi_hevc_shader_cmd.h $TARGET_DIR
++$QASM -mc_c:$DST_BASE,$DST_BASE,$DST_BASE $SRC_FILE > $TARGET_DIR/$DST_BASE.c
++$QASM -mc_h:$DST_BASE,$DST_BASE,$DST_BASE $SRC_FILE > $TARGET_DIR/$DST_BASE.h
++
+diff --git a/pi-util/v3dusage.py b/pi-util/v3dusage.py
+new file mode 100755
+index 0000000000..5935a11ca5
+--- /dev/null
++++ b/pi-util/v3dusage.py
+@@ -0,0 +1,128 @@
++#!/usr/bin/env python
++
++import sys
++import argparse
++import re
++
++def do_logparse(logname):
++
++ rmatch = re.compile(r'^([0-9]+\.[0-9]{3}): (done )?((vpu0)|(vpu1)|(qpu1)) ([A-Z_]+) cb:([0-9a-f]+) ')
++ rqcycle = re.compile(r'^([0-9]+\.[0-9]{3}): v3d: QPU Total clock cycles for all QPUs doing vertex/coordinate shading +([0-9]+)$')
++ rqtscycle = re.compile(r'^([0-9]+\.[0-9]{3}): v3d: QPU Total clock cycles for all QPUs stalled waiting for TMUs +([0-9]+)$')
++ rl2hits = re.compile(r'^([0-9]+\.[0-9]{3}): v3d: L2C Total Level 2 cache ([a-z]+) +([0-9]+)$')
++
++ ttotal = {'idle':0.0}
++ tstart = {}
++ qctotal = {}
++ qtstotal = {}
++ l2hits = {}
++ l2total = {}
++ time0 = None
++ idle_start = None
++ qpu_op_no = 0
++ op_count = 0
++
++ with open(logname, "rt") as infile:
++ for line in infile:
++ match = rmatch.match(line)
++ if match:
++# print match.group(1), ":", match.group(2), ":", match.group(3), ":", match.group(7), ":"
++ time = float(match.group(1))
++ unit = match.group(3)
++ opstart = not match.group(2)
++ optype = match.group(7)
++ hascb = match.group(8) != "0"
++
++ if unit == 'qpu1':
++ unit = unit + "." + str(qpu_op_no)
++ if not opstart:
++ if hascb or optype == 'EXECUTE_SYNC':
++ qpu_op_no = 0
++ else:
++ qpu_op_no += 1
++
++ # Ignore sync type
++ if optype == 'EXECUTE_SYNC':
++ continue
++
++ if not time0:
++ time0 = time
++
++ if opstart:
++ tstart[unit] = time;
++ elif unit in tstart:
++ op_count += 1
++ if not unit in ttotal:
++ ttotal[unit] = 0.0
++ ttotal[unit] += time - tstart[unit]
++ del tstart[unit]
++
++ if not idle_start and not tstart:
++ idle_start = time
++ elif idle_start and tstart:
++ ttotal['idle'] += time - idle_start
++ idle_start = None
++
++ match = rqcycle.match(line)
++ if match:
++ unit = "qpu1." + str(qpu_op_no)
++ if not unit in qctotal:
++ qctotal[unit] = 0
++ qctotal[unit] += int(match.group(2))
++
++ match = rqtscycle.match(line)
++ if match:
++ unit = "qpu1." + str(qpu_op_no)
++ if not unit in qtstotal:
++ qtstotal[unit] = 0
++ qtstotal[unit] += int(match.group(2))
++
++ match = rl2hits.match(line)
++ if match:
++ unit = "qpu1." + str(qpu_op_no)
++ if not unit in l2total:
++ l2total[unit] = 0
++ l2hits[unit] = 0
++ l2total[unit] += int(match.group(3))
++ if match.group(2) == "hits":
++ l2hits[unit] += int(match.group(3))
++
++
++ if not time0:
++ print "No v3d profile records found"
++ else:
++ tlogged = time - time0
++
++ print "Logged time:", tlogged, " Op count:", op_count
++ for unit in sorted(ttotal):
++ print b'%6s: %10.3f %7.3f%%' % (unit, ttotal[unit], ttotal[unit] * 100.0 / tlogged)
++ print
++ for unit in sorted(qctotal):
++ if not unit in qtstotal:
++ qtstotal[unit] = 0;
++ print b'%6s: Qcycles: %10d, TMU stall: %10d (%7.3f%%)' % (unit, qctotal[unit], qtstotal[unit], (qtstotal[unit] * 100.0)/qctotal[unit])
++ if unit in l2total:
++ print b' L2Total: %10d, hits: %10d (%7.3f%%)' % (l2total[unit], l2hits[unit], (l2hits[unit] * 100.0)/l2total[unit])
++
++
++
++if __name__ == '__main__':
++ argp = argparse.ArgumentParser(
++ formatter_class=argparse.RawDescriptionHelpFormatter,
++ description="QPU/VPU perf summary from VC logging",
++ epilog = """
++Will also summarise TMU stalls if logging requests set in qpu noflush param
++in the profiled code.
++
++Example use:
++ vcgencmd set_logging level=0xc0
++ <command to profile>
++ sudo vcdbg log msg >& t.log
++ v3dusage.py t.log
++""")
++
++ argp.add_argument("logfile")
++ args = argp.parse_args()
++
++ do_logparse(args.logfile)
++
diff --git a/ffmpeg-rpi/ffmpeg-99.1004-added_upstream_mvc_patches.patch b/ffmpeg-rpi/ffmpeg-99.1004-added_upstream_mvc_patches.patch
new file mode 100644
index 0000000..551a271
--- /dev/null
+++ b/ffmpeg-rpi/ffmpeg-99.1004-added_upstream_mvc_patches.patch
@@ -0,0 +1,284 @@
+From 20af7af23a9f366476e67669f14957dfaf58f141 Mon Sep 17 00:00:00 2001
+From: Hendrik Leppkes <h.leppkes@gmail.com>
+Date: Sat, 9 Jan 2016 16:34:09 +0100
+Subject: [PATCH 1/4] avcodec: add h264_mvc codec id and profiles
+
+---
+ libavcodec/avcodec.h | 3 +++
+ libavcodec/codec_desc.c | 7 +++++++
+ libavcodec/profiles.c | 1 +
+ libavformat/mpegts.c | 2 +-
+ 4 files changed, 12 insertions(+), 1 deletion(-)
+
+diff --git a/libavcodec/avcodec.h b/libavcodec/avcodec.h
+index d962b9cf0a..4c4581c895 100644
+--- a/libavcodec/avcodec.h
++++ b/libavcodec/avcodec.h
+@@ -447,6 +447,8 @@ enum AVCodecID {
+ AV_CODEC_ID_GDV,
+ AV_CODEC_ID_FITS,
+
++ AV_CODEC_ID_H264_MVC,
++
+ /* various PCM "codecs" */
+ AV_CODEC_ID_FIRST_AUDIO = 0x10000, ///< A dummy id pointing at the start of audio codecs
+ AV_CODEC_ID_PCM_S16LE = 0x10000,
+@@ -2895,6 +2897,7 @@ typedef struct AVCodecContext {
+ #define FF_PROFILE_H264_HIGH_444_PREDICTIVE 244
+ #define FF_PROFILE_H264_HIGH_444_INTRA (244|FF_PROFILE_H264_INTRA)
+ #define FF_PROFILE_H264_CAVLC_444 44
++#define FF_PROFILE_H264_MULTIVIEW_HIGH_DEPTH 138
+
+ #define FF_PROFILE_VC1_SIMPLE 0
+ #define FF_PROFILE_VC1_MAIN 1
+diff --git a/libavcodec/codec_desc.c b/libavcodec/codec_desc.c
+index 79552a910d..b55955476c 100644
+--- a/libavcodec/codec_desc.c
++++ b/libavcodec/codec_desc.c
+@@ -1647,6 +1647,13 @@ static const AVCodecDescriptor codec_descriptors[] = {
+ .long_name = NULL_IF_CONFIG_SMALL("FITS (Flexible Image Transport System)"),
+ .props = AV_CODEC_PROP_INTRA_ONLY | AV_CODEC_PROP_LOSSLESS,
+ },
++ {
++ .id = AV_CODEC_ID_H264_MVC,
++ .type = AVMEDIA_TYPE_VIDEO,
++ .name = "h264_mvc",
++ .long_name = NULL_IF_CONFIG_SMALL("H264 MVC"),
++ .props = AV_CODEC_PROP_LOSSY,
++ },
+
+ /* various PCM "codecs" */
+ {
+diff --git a/libavcodec/profiles.c b/libavcodec/profiles.c
+index d7dc960f36..e4651f12f9 100644
+--- a/libavcodec/profiles.c
++++ b/libavcodec/profiles.c
+@@ -72,6 +72,7 @@ const AVProfile ff_h264_profiles[] = {
+ { FF_PROFILE_H264_CAVLC_444, "CAVLC 4:4:4" },
+ { FF_PROFILE_H264_MULTIVIEW_HIGH, "Multiview High" },
+ { FF_PROFILE_H264_STEREO_HIGH, "Stereo High" },
++ { FF_PROFILE_H264_MULTIVIEW_HIGH_DEPTH, "Multiview High Depth" },
+ { FF_PROFILE_UNKNOWN },
+ };
+
+diff --git a/libavformat/mpegts.c b/libavformat/mpegts.c
+index 37a6aa8bff..52c5b659c4 100644
+--- a/libavformat/mpegts.c
++++ b/libavformat/mpegts.c
+@@ -701,7 +701,7 @@ static const StreamType ISO_types[] = {
+ #endif
+ { 0x1b, AVMEDIA_TYPE_VIDEO, AV_CODEC_ID_H264 },
+ { 0x1c, AVMEDIA_TYPE_AUDIO, AV_CODEC_ID_AAC },
+- { 0x20, AVMEDIA_TYPE_VIDEO, AV_CODEC_ID_H264 },
++ { 0x20, AVMEDIA_TYPE_VIDEO, AV_CODEC_ID_H264_MVC },
+ { 0x21, AVMEDIA_TYPE_VIDEO, AV_CODEC_ID_JPEG2000 },
+ { 0x24, AVMEDIA_TYPE_VIDEO, AV_CODEC_ID_HEVC },
+ { 0x42, AVMEDIA_TYPE_VIDEO, AV_CODEC_ID_CAVS },
+--
+2.17.0
+
+
+From 0f3fda4e348e6b12570f5d279713f6da46511846 Mon Sep 17 00:00:00 2001
+From: Hendrik Leppkes <h.leppkes@gmail.com>
+Date: Sat, 9 Jan 2016 16:34:40 +0100
+Subject: [PATCH 2/4] h264_parser: add support for parsing h264 mvc NALUs
+
+---
+ libavcodec/h264.h | 2 ++
+ libavcodec/h264_parser.c | 34 ++++++++++++++++++++++++++++++----
+ libavcodec/parser.c | 1 +
+ 3 files changed, 33 insertions(+), 4 deletions(-)
+
+diff --git a/libavcodec/h264.h b/libavcodec/h264.h
+index 650580bf3a..c44a0cbedd 100644
+--- a/libavcodec/h264.h
++++ b/libavcodec/h264.h
+@@ -41,7 +41,9 @@ enum {
+ H264_NAL_END_STREAM = 11,
+ H264_NAL_FILLER_DATA = 12,
+ H264_NAL_SPS_EXT = 13,
++ H264_NAL_SPS_SUBSET = 15,
+ H264_NAL_AUXILIARY_SLICE = 19,
++ H264_NAL_SLICE_EXT = 20,
+ };
+
+
+diff --git a/libavcodec/h264_parser.c b/libavcodec/h264_parser.c
+index 1a9840a62c..be8b9db9b0 100644
+--- a/libavcodec/h264_parser.c
++++ b/libavcodec/h264_parser.c
+@@ -62,6 +62,7 @@ typedef struct H264ParseContext {
+ int parse_last_mb;
+ int64_t reference_dts;
+ int last_frame_num, last_picture_structure;
++ int is_mvc;
+ } H264ParseContext;
+
+
+@@ -109,14 +110,18 @@ static int h264_find_frame_end(H264ParseContext *p, const uint8_t *buf,
+ } else if (state <= 5) {
+ int nalu_type = buf[i] & 0x1F;
+ if (nalu_type == H264_NAL_SEI || nalu_type == H264_NAL_SPS ||
+- nalu_type == H264_NAL_PPS || nalu_type == H264_NAL_AUD) {
++ nalu_type == H264_NAL_PPS || nalu_type == H264_NAL_AUD ||
++ nalu_type == H264_NAL_SPS_SUBSET) {
+ if (pc->frame_start_found) {
+ i++;
+ goto found;
+ }
+ } else if (nalu_type == H264_NAL_SLICE || nalu_type == H264_NAL_DPA ||
+- nalu_type == H264_NAL_IDR_SLICE) {
++ nalu_type == H264_NAL_IDR_SLICE || (p->is_mvc && nalu_type == H264_NAL_SLICE_EXT)) {
+ state += 8;
++
++ if (nalu_type == H264_NAL_SLICE_EXT)
++ i += 3; // skip mvc extension
+ continue;
+ }
+ state = 7;
+@@ -601,7 +606,8 @@ static int h264_parse(AVCodecParserContext *s,
+ }
+ }
+
+- parse_nal_units(s, avctx, buf, buf_size);
++ if (!p->is_mvc)
++ parse_nal_units(s, avctx, buf, buf_size);
+
+ if (avctx->framerate.num)
+ avctx->time_base = av_inv_q(av_mul_q(avctx->framerate, (AVRational){avctx->ticks_per_frame, 1}));
+@@ -658,7 +664,7 @@ static int h264_split(AVCodecContext *avctx,
+ if ((state & 0xFFFFFF00) != 0x100)
+ break;
+ nalu_type = state & 0x1F;
+- if (nalu_type == H264_NAL_SPS) {
++ if (nalu_type == H264_NAL_SPS || nalu_type == H264_NAL_SPS_SUBSET) {
+ has_sps = 1;
+ } else if (nalu_type == H264_NAL_PPS)
+ has_pps = 1;
+@@ -710,3 +716,23 @@ AVCodecParser ff_h264_parser = {
+ .parser_close = h264_close,
+ .split = h264_split,
+ };
++
++static av_cold int init_mvc(AVCodecParserContext *s)
++{
++ H264ParseContext *p = s->priv_data;
++ int ret = init(s);
++ if (ret < 0)
++ return ret;
++
++ p->is_mvc = 1;
++ return 0;
++}
++
++AVCodecParser ff_h264_mvc_parser = {
++ .codec_ids = { AV_CODEC_ID_H264_MVC },
++ .priv_data_size = sizeof(H264ParseContext),
++ .parser_init = init_mvc,
++ .parser_parse = h264_parse,
++ .parser_close = h264_close,
++ .split = h264_split,
++};
+diff --git a/libavcodec/parser.c b/libavcodec/parser.c
+index f43b197d5e..f96e005ef3 100644
+--- a/libavcodec/parser.c
++++ b/libavcodec/parser.c
+@@ -54,6 +54,7 @@ extern AVCodecParser ff_gsm_parser;
+ extern AVCodecParser ff_h261_parser;
+ extern AVCodecParser ff_h263_parser;
+ extern AVCodecParser ff_h264_parser;
++extern AVCodecParser ff_h264_mvc_parser;
+ extern AVCodecParser ff_hevc_parser;
+ extern AVCodecParser ff_mjpeg_parser;
+ extern AVCodecParser ff_mlp_parser;
+--
+2.17.0
+
+
+From cdd668dc436b9c78dcb31df477e329492356e7ec Mon Sep 17 00:00:00 2001
+From: Hendrik Leppkes <h.leppkes@gmail.com>
+Date: Tue, 28 Nov 2017 16:12:12 +0000
+Subject: [PATCH 3/4] h264_parser: force grabing a new timestamp until a frame
+ start was found
+
+---
+ libavcodec/h264_parser.c | 3 +++
+ 1 file changed, 3 insertions(+)
+
+diff --git a/libavcodec/h264_parser.c b/libavcodec/h264_parser.c
+index be8b9db9b0..81c9a1bbae 100644
+--- a/libavcodec/h264_parser.c
++++ b/libavcodec/h264_parser.c
+@@ -594,6 +594,9 @@ static int h264_parse(AVCodecParserContext *s,
+ } else {
+ next = h264_find_frame_end(p, buf, buf_size, avctx);
+
++ if (next == END_NOT_FOUND && pc->frame_start_found == 0)
++ s->fetch_timestamp = 1;
++
+ if (ff_combine_frame(pc, next, &buf, &buf_size) < 0) {
+ *poutbuf = NULL;
+ *poutbuf_size = 0;
+--
+2.17.0
+
+
+From fb0ec9a132d6eb8fd74348ef87b1176c7ca34a00 Mon Sep 17 00:00:00 2001
+From: popcornmix <popcornmix@gmail.com>
+Date: Mon, 28 May 2018 13:35:36 +0100
+Subject: [PATCH 4/4] fixup
+
+---
+ libavcodec/extract_extradata_bsf.c | 8 +++++---
+ 1 file changed, 5 insertions(+), 3 deletions(-)
+
+diff --git a/libavcodec/extract_extradata_bsf.c b/libavcodec/extract_extradata_bsf.c
+index 082b3e749b..7612749efc 100644
+--- a/libavcodec/extract_extradata_bsf.c
++++ b/libavcodec/extract_extradata_bsf.c
+@@ -59,7 +59,7 @@ static int extract_extradata_h2645(AVBSFContext *ctx, AVPacket *pkt,
+ HEVC_NAL_VPS, HEVC_NAL_SPS, HEVC_NAL_PPS,
+ };
+ static const int extradata_nal_types_h264[] = {
+- H264_NAL_SPS, H264_NAL_PPS,
++ H264_NAL_SPS, H264_NAL_SPS_SUBSET, H264_NAL_PPS,
+ };
+
+ ExtractExtradataContext *s = ctx->priv_data;
+@@ -90,7 +90,7 @@ static int extract_extradata_h2645(AVBSFContext *ctx, AVPacket *pkt,
+ if (nal->type == HEVC_NAL_SPS) has_sps = 1;
+ if (nal->type == HEVC_NAL_VPS) has_vps = 1;
+ } else {
+- if (nal->type == H264_NAL_SPS) has_sps = 1;
++ if (nal->type == H264_NAL_SPS || nal->type == H264_NAL_SPS_SUBSET) has_sps = 1;
+ }
+ } else if (s->remove) {
+ filtered_size += nal->raw_size + 3;
+@@ -99,7 +99,7 @@ static int extract_extradata_h2645(AVBSFContext *ctx, AVPacket *pkt,
+
+ if (extradata_size &&
+ ((ctx->par_in->codec_id == AV_CODEC_ID_HEVC && has_sps && has_vps) ||
+- (ctx->par_in->codec_id == AV_CODEC_ID_H264 && has_sps))) {
++ ((ctx->par_in->codec_id == AV_CODEC_ID_H264 || ctx->par_in->codec_id == AV_CODEC_ID_H264_MVC) && has_sps))) {
+ AVBufferRef *filtered_buf;
+ uint8_t *extradata, *filtered_data;
+
+@@ -253,6 +253,7 @@ static const struct {
+ } extract_tab[] = {
+ { AV_CODEC_ID_CAVS, extract_extradata_mpeg4 },
+ { AV_CODEC_ID_H264, extract_extradata_h2645 },
++ { AV_CODEC_ID_H264_MVC, extract_extradata_h2645 },
+ { AV_CODEC_ID_HEVC, extract_extradata_h2645 },
+ { AV_CODEC_ID_MPEG1VIDEO, extract_extradata_mpeg12 },
+ { AV_CODEC_ID_MPEG2VIDEO, extract_extradata_mpeg12 },
+@@ -317,6 +318,7 @@ static void extract_extradata_close(AVBSFContext *ctx)
+ static const enum AVCodecID codec_ids[] = {
+ AV_CODEC_ID_CAVS,
+ AV_CODEC_ID_H264,
++ AV_CODEC_ID_H264_MVC,
+ AV_CODEC_ID_HEVC,
+ AV_CODEC_ID_MPEG1VIDEO,
+ AV_CODEC_ID_MPEG2VIDEO,
+--
+2.17.0
+
diff --git a/ffmpeg-rpi/ffmpeg-99.1008-dav1d-enable-av1.patch b/ffmpeg-rpi/ffmpeg-99.1008-dav1d-enable-av1.patch
new file mode 100644
index 0000000..213c7c1
--- /dev/null
+++ b/ffmpeg-rpi/ffmpeg-99.1008-dav1d-enable-av1.patch
@@ -0,0 +1,407 @@
+diff -Nur a/configure b/configure
+--- a/configure 2018-11-23 12:03:27.041287929 -0500
++++ b/configure 2018-11-23 12:08:52.945786916 -0500
+@@ -226,6 +226,7 @@
+ --enable-libcelt enable CELT decoding via libcelt [no]
+ --enable-libcdio enable audio CD grabbing with libcdio [no]
+ --enable-libcodec2 enable codec2 en/decoding using libcodec2 [no]
++ --enable-libdav1d enable AV1 decoding via libdav1d [no]
+ --enable-libdc1394 enable IIDC-1394 grabbing using libdc1394
+ and libraw1394 [no]
+ --enable-libfdk-aac enable AAC de/encoding via libfdk-aac [no]
+@@ -1700,6 +1701,7 @@
+ libcaca
+ libcelt
+ libcodec2
++ libdav1d
+ libdc1394
+ libdrm
+ libflite
+@@ -3062,6 +3064,7 @@
+ libcelt_decoder_deps="libcelt"
+ libcodec2_decoder_deps="libcodec2"
+ libcodec2_encoder_deps="libcodec2"
++libdav1d_decoder_deps="libdav1d"
+ libfdk_aac_decoder_deps="libfdk_aac"
+ libfdk_aac_encoder_deps="libfdk_aac"
+ libfdk_aac_encoder_select="audio_frame_queue"
+@@ -6003,6 +6006,7 @@
+ die "ERROR: libcelt must be installed and version must be >= 0.11.0."; }
+ enabled libcaca && require_pkg_config libcaca caca caca.h caca_create_canvas
+ enabled libcodec2 && require libcodec2 codec2/codec2.h codec2_create -lcodec2
++enabled libdav1d && require_pkg_config libdav1d "dav1d >= 0.0.1" "dav1d/dav1d.h" dav1d_version
+ enabled libdc1394 && require_pkg_config libdc1394 libdc1394-2 dc1394/dc1394.h dc1394_new
+ enabled libdrm && require_pkg_config libdrm libdrm xf86drm.h drmGetVersion
+ enabled libfdk_aac && { check_pkg_config libfdk_aac fdk-aac "fdk-aac/aacenc_lib.h" aacEncOpen ||
+diff -Nur a/libavcodec/allcodecs.c b/libavcodec/allcodecs.c
+--- a/libavcodec/allcodecs.c 2018-11-23 12:03:27.041287929 -0500
++++ b/libavcodec/allcodecs.c 2018-11-23 12:11:08.584268221 -0500
+@@ -670,6 +670,7 @@
+ extern AVCodec ff_libcelt_decoder;
+ extern AVCodec ff_libcodec2_encoder;
+ extern AVCodec ff_libcodec2_decoder;
++extern AVCodec ff_libdav1d_decoder;
+ extern AVCodec ff_libfdk_aac_encoder;
+ extern AVCodec ff_libfdk_aac_decoder;
+ extern AVCodec ff_libgsm_encoder;
+diff -Nur a/libavcodec/libdav1d.c b/libavcodec/libdav1d.c
+--- a/libavcodec/libdav1d.c 1969-12-31 19:00:00.000000000 -0500
++++ b/libavcodec/libdav1d.c 2018-11-23 12:33:35.820468086 -0500
+@@ -0,0 +1,346 @@
++/*
++ * Copyright (c) 2018 Ronald S. Bultje <rsbultje gmail com>
++ * Copyright (c) 2018 James Almer <jamrial gmail com>
++ *
++ * This file is part of FFmpeg.
++ *
++ * FFmpeg is free software; you can redistribute it and/or
++ * modify it under the terms of the GNU Lesser General Public
++ * License as published by the Free Software Foundation; either
++ * version 2.1 of the License, or (at your option) any later version.
++ *
++ * FFmpeg is distributed in the hope that it will be useful,
++ * but WITHOUT ANY WARRANTY; without even the implied warranty of
++ * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
++ * Lesser General Public License for more details.
++ *
++ * You should have received a copy of the GNU Lesser General Public
++ * License along with FFmpeg; if not, write to the Free Software
++ * Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA
++ */
++
++#include <dav1d/dav1d.h>
++
++#include "libavutil/avassert.h"
++#include "libavutil/mastering_display_metadata.h"
++#include "libavutil/imgutils.h"
++#include "libavutil/opt.h"
++
++#include "avcodec.h"
++#include "decode.h"
++#include "internal.h"
++
++typedef struct Libdav1dContext {
++ AVClass *class;
++ Dav1dContext *c;
++ AVBufferPool *pool;
++ int pool_size;
++
++ Dav1dData data;
++ int tile_threads;
++ int apply_grain;
++} Libdav1dContext;
++
++static const enum AVPixelFormat pix_fmt[][3] = {
++ [DAV1D_PIXEL_LAYOUT_I400] = { AV_PIX_FMT_GRAY8, AV_PIX_FMT_GRAY10, AV_PIX_FMT_GRAY12 },
++ [DAV1D_PIXEL_LAYOUT_I420] = { AV_PIX_FMT_YUV420P, AV_PIX_FMT_YUV420P10, AV_PIX_FMT_YUV420P12 },
++ [DAV1D_PIXEL_LAYOUT_I422] = { AV_PIX_FMT_YUV422P, AV_PIX_FMT_YUV422P10, AV_PIX_FMT_YUV422P12 },
++ [DAV1D_PIXEL_LAYOUT_I444] = { AV_PIX_FMT_YUV444P, AV_PIX_FMT_YUV444P10, AV_PIX_FMT_YUV444P12 },
++};
++
++static void libdav1d_log_callback(void *opaque, const char *fmt, va_list vl)
++{
++ AVCodecContext *c = opaque;
++
++ av_vlog(c, AV_LOG_ERROR, fmt, vl);
++}
++
++static int libdav1d_picture_allocator(Dav1dPicture *p, void *cookie)
++{
++ Libdav1dContext *dav1d = cookie;
++ enum AVPixelFormat format = pix_fmt[p->p.layout][p->seq_hdr->hbd];
++ int ret, linesize[4], h = FFALIGN(p->p.h, 128);
++ uint8_t *aligned_ptr, *data[4];
++ AVBufferRef *buf;
++
++ ret = av_image_fill_arrays(data, linesize, NULL, format, FFALIGN(p->p.w, 128),
++ h, DAV1D_PICTURE_ALIGNMENT);
++ if (ret < 0)
++ return ret;
++
++ if (ret != dav1d->pool_size) {
++ av_buffer_pool_uninit(&dav1d->pool);
++ // Use twice the amount of required padding bytes for aligned_ptr below.
++ dav1d->pool = av_buffer_pool_init(ret + DAV1D_PICTURE_ALIGNMENT * 2, NULL);
++ if (!dav1d->pool) {
++ dav1d->pool_size = 0;
++ return AVERROR(ENOMEM);
++ }
++ dav1d->pool_size = ret;
++ }
++ buf = av_buffer_pool_get(dav1d->pool);
++ if (!buf)
++ return AVERROR(ENOMEM);
++
++ // libdav1d requires DAV1D_PICTURE_ALIGNMENT aligned buffers, which av_malloc()
++ // doesn't guarantee for example when AVX is disabled at configure time.
++ // Use the extra DAV1D_PICTURE_ALIGNMENT padding bytes in the buffer to align it
++ // if required.
++ aligned_ptr = (uint8_t *)FFALIGN((uintptr_t)buf->data, DAV1D_PICTURE_ALIGNMENT);
++ ret = av_image_fill_pointers(data, format, h, aligned_ptr, linesize);
++ if (ret < 0) {
++ av_buffer_unref(&buf);
++ return ret;
++ }
++
++ p->data[0] = data[0];
++ p->data[1] = data[1];
++ p->data[2] = data[2];
++ p->stride[0] = linesize[0];
++ p->stride[1] = linesize[1];
++ p->allocator_data = buf;
++
++ return 0;
++}
++
++static void libdav1d_picture_release(Dav1dPicture *p, void *cookie)
++{
++ AVBufferRef *buf = p->allocator_data;
++
++ av_buffer_unref(&buf);
++}
++
++static av_cold int libdav1d_init(AVCodecContext *c)
++{
++ Libdav1dContext *dav1d = c->priv_data;
++ Dav1dSettings s;
++ int res;
++
++ av_log(c, AV_LOG_INFO, "libdav1d %s\n", dav1d_version());
++
++ dav1d_default_settings(&s);
++ s.logger.cookie = c;
++ s.logger.callback = libdav1d_log_callback;
++ s.allocator.cookie = dav1d;
++ s.allocator.alloc_picture_callback = libdav1d_picture_allocator;
++ s.allocator.release_picture_callback = libdav1d_picture_release;
++ s.n_tile_threads = dav1d->tile_threads;
++ s.apply_grain = dav1d->apply_grain;
++ s.n_frame_threads = FFMIN(c->thread_count ? c->thread_count : av_cpu_count(), DAV1D_MAX_FRAME_THREADS);
++
++ res = dav1d_open(&dav1d->c, &s);
++ if (res < 0)
++ return AVERROR(ENOMEM);
++
++ return 0;
++}
++
++static void libdav1d_flush(AVCodecContext *c)
++{
++ Libdav1dContext *dav1d = c->priv_data;
++
++ dav1d_data_unref(&dav1d->data);
++ dav1d_flush(dav1d->c);
++}
++
++static void libdav1d_data_free(const uint8_t *data, void *opaque) {
++ AVBufferRef *buf = opaque;
++
++ av_buffer_unref(&buf);
++}
++
++static int libdav1d_receive_frame(AVCodecContext *c, AVFrame *frame)
++{
++ Libdav1dContext *dav1d = c->priv_data;
++ Dav1dData *data = &dav1d->data;
++ Dav1dPicture pic = { 0 }, *p = &pic;
++ int res;
++
++ if (!data->sz) {
++ AVPacket pkt = { 0 };
++
++ res = ff_decode_get_packet(c, &pkt);
++ if (res < 0 && res != AVERROR_EOF)
++ return res;
++
++ if (pkt.size) {
++ res = dav1d_data_wrap(data, pkt.data, pkt.size, libdav1d_data_free, pkt.buf);
++ if (res < 0) {
++ av_packet_unref(&pkt);
++ return res;
++ }
++
++ data->m.timestamp = pkt.pts;
++ data->m.offset = pkt.pos;
++ data->m.duration = pkt.duration;
++
++ pkt.buf = NULL;
++ av_packet_unref(&pkt);
++ }
++ }
++
++ res = dav1d_send_data(dav1d->c, data);
++ if (res < 0) {
++ if (res == AVERROR(EINVAL))
++ res = AVERROR_INVALIDDATA;
++ if (res != AVERROR(EAGAIN))
++ return res;
++ }
++
++ res = dav1d_get_picture(dav1d->c, p);
++ if (res < 0) {
++ if (res == AVERROR(EINVAL))
++ res = AVERROR_INVALIDDATA;
++ else if (res == AVERROR(EAGAIN) && c->internal->draining)
++ res = AVERROR_EOF;
++
++ return res;
++ }
++
++ av_assert0(p->data[0] != NULL);
++
++ // This requires the custom allocator above
++ frame->buf[0] = av_buffer_ref(p->allocator_data);
++ if (!frame->buf[0]) {
++ dav1d_picture_unref(p);
++ return AVERROR(ENOMEM);
++ }
++
++ frame->data[0] = p->data[0];
++ frame->data[1] = p->data[1];
++ frame->data[2] = p->data[2];
++ frame->linesize[0] = p->stride[0];
++ frame->linesize[1] = p->stride[1];
++ frame->linesize[2] = p->stride[1];
++
++ c->profile = p->seq_hdr->profile;
++ frame->format = c->pix_fmt = pix_fmt[p->p.layout][p->seq_hdr->hbd];
++ frame->width = p->p.w;
++ frame->height = p->p.h;
++ if (c->width != p->p.w || c->height != p->p.h) {
++ res = ff_set_dimensions(c, p->p.w, p->p.h);
++ if (res < 0)
++ goto fail;
++ }
++
++ switch (p->seq_hdr->chr) {
++ case DAV1D_CHR_VERTICAL:
++ frame->chroma_location = c->chroma_sample_location = AVCHROMA_LOC_LEFT;
++ break;
++ case DAV1D_CHR_COLOCATED:
++ frame->chroma_location = c->chroma_sample_location = AVCHROMA_LOC_TOPLEFT;
++ break;
++ }
++ frame->colorspace = c->colorspace = (enum AVColorSpace) p->seq_hdr->mtrx;
++ frame->color_primaries = c->color_primaries = (enum AVColorPrimaries) p->seq_hdr->pri;
++ frame->color_trc = c->color_trc = (enum AVColorTransferCharacteristic) p->seq_hdr->trc;
++ frame->color_range = c->color_range = p->seq_hdr->color_range ? AVCOL_RANGE_JPEG : AVCOL_RANGE_MPEG;
++
++ // match timestamps and packet size
++ frame->pts = frame->best_effort_timestamp = p->m.timestamp;
++#if FF_API_PKT_PTS
++FF_DISABLE_DEPRECATION_WARNINGS
++ frame->pkt_pts = p->m.timestamp;
++FF_ENABLE_DEPRECATION_WARNINGS
++#endif
++ frame->pkt_dts = p->m.timestamp;
++ frame->pkt_pos = p->m.offset;
++ frame->pkt_size = p->m.size;
++ frame->pkt_duration = p->m.duration;
++ frame->key_frame = p->frame_hdr->frame_type == DAV1D_FRAME_TYPE_KEY;
++
++ switch (p->frame_hdr->frame_type) {
++ case DAV1D_FRAME_TYPE_KEY:
++ case DAV1D_FRAME_TYPE_INTRA:
++ frame->pict_type = AV_PICTURE_TYPE_I;
++ break;
++ case DAV1D_FRAME_TYPE_INTER:
++ frame->pict_type = AV_PICTURE_TYPE_P;
++ break;
++ case DAV1D_FRAME_TYPE_SWITCH:
++ frame->pict_type = AV_PICTURE_TYPE_SP;
++ break;
++ default:
++ res = AVERROR_INVALIDDATA;
++ goto fail;
++ }
++
++ if (p->mastering_display) {
++ AVMasteringDisplayMetadata *mastering = av_mastering_display_metadata_create_side_data(frame);
++ if (!mastering) {
++ res = AVERROR(ENOMEM);
++ goto fail;
++ }
++
++ for (int i = 0; i < 3; i++) {
++ mastering->display_primaries[i][0] = av_make_q(p->mastering_display->primaries[i][0], 1 << 16);
++ mastering->display_primaries[i][1] = av_make_q(p->mastering_display->primaries[i][1], 1 << 16);
++ }
++ mastering->white_point[0] = av_make_q(p->mastering_display->white_point[0], 1 << 16);
++ mastering->white_point[1] = av_make_q(p->mastering_display->white_point[1], 1 << 16);
++
++ mastering->max_luminance = av_make_q(p->mastering_display->max_luminance, 1 << 8);
++ mastering->min_luminance = av_make_q(p->mastering_display->min_luminance, 1 << 14);
++
++ mastering->has_primaries = 1;
++ mastering->has_luminance = 1;
++ }
++ if (p->content_light) {
++ AVContentLightMetadata *light = av_content_light_metadata_create_side_data(frame);
++ if (!light) {
++ res = AVERROR(ENOMEM);
++ goto fail;
++ }
++ light->MaxCLL = p->content_light->max_content_light_level;
++ light->MaxFALL = p->content_light->max_frame_average_light_level;
++ }
++
++ res = 0;
++fail:
++ dav1d_picture_unref(p);
++ if (res < 0)
++ av_frame_unref(frame);
++ return res;
++}
++
++static av_cold int libdav1d_close(AVCodecContext *c)
++{
++ Libdav1dContext *dav1d = c->priv_data;
++
++ av_buffer_pool_uninit(&dav1d->pool);
++ dav1d_data_unref(&dav1d->data);
++ dav1d_close(&dav1d->c);
++
++ return 0;
++}
++
++#define OFFSET(x) offsetof(Libdav1dContext, x)
++#define VD AV_OPT_FLAG_VIDEO_PARAM | AV_OPT_FLAG_DECODING_PARAM
++static const AVOption libdav1d_options[] = {
++ { "tilethreads", "Tile threads", OFFSET(tile_threads), AV_OPT_TYPE_INT, { .i64 = 1 }, 1, DAV1D_MAX_TILE_THREADS, VD },
++ { "filmgrain", "Apply Film Grain", OFFSET(apply_grain), AV_OPT_TYPE_BOOL, { .i64 = 1 }, 0, 1, VD },
++ { NULL }
++};
++
++static const AVClass libdav1d_class = {
++ .class_name = "libdav1d decoder",
++ .item_name = av_default_item_name,
++ .option = libdav1d_options,
++ .version = LIBAVUTIL_VERSION_INT,
++};
++
++AVCodec ff_libdav1d_decoder = {
++ .name = "libdav1d",
++ .long_name = NULL_IF_CONFIG_SMALL("dav1d AV1 decoder by VideoLAN"),
++ .type = AVMEDIA_TYPE_VIDEO,
++ .id = AV_CODEC_ID_AV1,
++ .priv_data_size = sizeof(Libdav1dContext),
++ .init = libdav1d_init,
++ .close = libdav1d_close,
++ .flush = libdav1d_flush,
++ .receive_frame = libdav1d_receive_frame,
++ .capabilities = AV_CODEC_CAP_DELAY | AV_CODEC_CAP_AUTO_THREADS,
++ .caps_internal = FF_CODEC_CAP_INIT_THREADSAFE | FF_CODEC_CAP_SETS_PKT_DTS,
++ .priv_class = &libdav1d_class,
++ .wrapper_name = "libdav1d",
++};
+diff -Nur a/libavcodec/Makefile b/libavcodec/Makefile
+--- a/libavcodec/Makefile 2018-11-23 12:03:27.041287929 -0500
++++ b/libavcodec/Makefile 2018-11-23 12:10:28.676717867 -0500
+@@ -954,6 +954,7 @@
+ OBJS-$(CONFIG_LIBCELT_DECODER) += libcelt_dec.o
+ OBJS-$(CONFIG_LIBCODEC2_DECODER) += libcodec2.o codec2utils.o
+ OBJS-$(CONFIG_LIBCODEC2_ENCODER) += libcodec2.o codec2utils.o
++OBJS-$(CONFIG_LIBDAV1D_DECODER) += libdav1d.o
+ OBJS-$(CONFIG_LIBFDK_AAC_DECODER) += libfdk-aacdec.o
+ OBJS-$(CONFIG_LIBFDK_AAC_ENCODER) += libfdk-aacenc.o
+ OBJS-$(CONFIG_LIBGSM_DECODER) += libgsmdec.o
diff --git a/ffmpeg-rpi/ffmpeg-99.1009-dav1d-fix-multithreaded-av1-sw-decoding.patch b/ffmpeg-rpi/ffmpeg-99.1009-dav1d-fix-multithreaded-av1-sw-decoding.patch
new file mode 100644
index 0000000..1d087b4
--- /dev/null
+++ b/ffmpeg-rpi/ffmpeg-99.1009-dav1d-fix-multithreaded-av1-sw-decoding.patch
@@ -0,0 +1,60 @@
+From 0ae5ba3567a896af2b272e3a52ca574b7f41ec5a Mon Sep 17 00:00:00 2001
+From: Lukas Rusak <lorusak@gmail.com>
+Date: Wed, 10 Apr 2019 13:40:07 -0700
+Subject: [PATCH 0/1] *** SUBJECT HERE ***
+
+*** BLURB HERE ***
+
+Lukas Rusak (1):
+ libavcodec/libdav1d: add libdav1d_get_format method in order to call
+ ff_get_format
+
+ libavcodec/libdav1d.c | 12 +++++++++++-
+ 1 file changed, 11 insertions(+), 1 deletion(-)
+
+--
+2.20.1
+
+From 0ae5ba3567a896af2b272e3a52ca574b7f41ec5a Mon Sep 17 00:00:00 2001
+From: Lukas Rusak <lorusak@gmail.com>
+Date: Wed, 10 Apr 2019 13:39:21 -0700
+Subject: [PATCH 1/1] libavcodec/libdav1d: add libdav1d_get_format method in
+ order to call ff_get_format
+
+---
+ libavcodec/libdav1d.c | 12 +++++++++++-
+ 1 file changed, 11 insertions(+), 1 deletion(-)
+
+diff --git a/libavcodec/libdav1d.c b/libavcodec/libdav1d.c
+index 30c6eccfef..fa71834543 100644
+--- a/libavcodec/libdav1d.c
++++ b/libavcodec/libdav1d.c
+@@ -48,6 +48,16 @@ static const enum AVPixelFormat pix_fmt[][3] = {
+ [DAV1D_PIXEL_LAYOUT_I444] = { AV_PIX_FMT_YUV444P, AV_PIX_FMT_YUV444P10, AV_PIX_FMT_YUV444P12 },
+ };
+
++static enum AVPixelFormat libdav1d_get_format(AVCodecContext *avctx, const Dav1dPicture *p)
++{
++ enum AVPixelFormat pix_fmts[2], *fmt = pix_fmts;
++
++ *fmt++ = pix_fmt[p->p.layout][p->seq_hdr->hbd];
++ *fmt = AV_PIX_FMT_NONE;
++
++ return ff_get_format(avctx, pix_fmts);
++}
++
+ static void libdav1d_log_callback(void *opaque, const char *fmt, va_list vl)
+ {
+ AVCodecContext *c = opaque;
+@@ -214,7 +224,7 @@ static int libdav1d_receive_frame(AVCodecContext *c, AVFrame *frame)
+ frame->linesize[2] = p->stride[1];
+
+ c->profile = p->seq_hdr->profile;
+- frame->format = c->pix_fmt = pix_fmt[p->p.layout][p->seq_hdr->hbd];
++ frame->format = c->pix_fmt = libdav1d_get_format(c, p);
+ frame->width = p->p.w;
+ frame->height = p->p.h;
+ if (c->width != p->p.w || c->height != p->p.h) {
+--
+2.20.1
+
diff --git a/ffmpeg-rpi/ffmpeg-99.1010-yuv2rgb-logspam.patch b/ffmpeg-rpi/ffmpeg-99.1010-yuv2rgb-logspam.patch
new file mode 100644
index 0000000..2895d7a
--- /dev/null
+++ b/ffmpeg-rpi/ffmpeg-99.1010-yuv2rgb-logspam.patch
@@ -0,0 +1,13 @@
+--- a/libswscale/yuv2rgb.c 2018-07-22 10:00:00.000000000 +0100
++++ b/libswscale/yuv2rgb.c 2018-08-20 11:55:46.391543992 +0100
+@@ -687,10 +687,6 @@ SwsFunc ff_yuv2rgb_get_func_ptr(SwsConte
+ if (t)
+ return t;
+
+- av_log(c, AV_LOG_WARNING,
+- "No accelerated colorspace conversion found from %s to %s.\n",
+- av_get_pix_fmt_name(c->srcFormat), av_get_pix_fmt_name(c->dstFormat));
+-
+ switch (c->dstFormat) {
+ case AV_PIX_FMT_BGR48BE:
+ case AV_PIX_FMT_BGR48LE:
diff --git a/ffmpeg/0001-libavutil-clean-up-unused-FF_SYMVER-macro.patch b/ffmpeg/0001-libavutil-clean-up-unused-FF_SYMVER-macro.patch
deleted file mode 100644
index 9cc6fdf..0000000
--- a/ffmpeg/0001-libavutil-clean-up-unused-FF_SYMVER-macro.patch
+++ /dev/null
@@ -1,55 +0,0 @@
-From ab11be0becb90542f10d5713659b559842c53af2 Mon Sep 17 00:00:00 2001
-From: Natanael Copa <ncopa@alpinelinux.org>
-Date: Tue, 29 Mar 2016 15:15:17 +0200
-Subject: [PATCH] libavutil: clean up unused FF_SYMVER macro
-
-There is nothing using it since commit d63443b9 (lavc: drop the
-av_fast_{re,m}alloc compatibility wrappers).
-
-Signed-off-by: Natanael Copa <ncopa@alpinelinux.org>
----
- libavutil/internal.h | 28 ----------------------------
- 1 file changed, 28 deletions(-)
-
-diff --git a/libavutil/internal.h b/libavutil/internal.h
-index 61784b5..69d63d5 100644
---- a/libavutil/internal.h
-+++ b/libavutil/internal.h
-@@ -187,34 +187,6 @@
- #endif
-
- /**
-- * Define a function with only the non-default version specified.
-- *
-- * On systems with ELF shared libraries, all symbols exported from
-- * FFmpeg libraries are tagged with the name and major version of the
-- * library to which they belong. If a function is moved from one
-- * library to another, a wrapper must be retained in the original
-- * location to preserve binary compatibility.
-- *
-- * Functions defined with this macro will never be used to resolve
-- * symbols by the build-time linker.
-- *
-- * @param type return type of function
-- * @param name name of function
-- * @param args argument list of function
-- * @param ver version tag to assign function
-- */
--#if HAVE_SYMVER_ASM_LABEL
--# define FF_SYMVER(type, name, args, ver) \
-- type ff_##name args __asm__ (EXTERN_PREFIX #name "@" ver); \
-- type ff_##name args
--#elif HAVE_SYMVER_GNU_ASM
--# define FF_SYMVER(type, name, args, ver) \
-- __asm__ (".symver ff_" #name "," EXTERN_PREFIX #name "@" ver); \
-- type ff_##name args; \
-- type ff_##name args
--#endif
--
--/**
- * Return NULL if a threading library has not been enabled.
- * Used to disable threading functions in AVCodec definitions
- * when not needed.
---
-2.7.4
-
diff --git a/ffmpeg/APKBUILD b/ffmpeg/APKBUILD
deleted file mode 100644
index 2c82132..0000000
--- a/ffmpeg/APKBUILD
+++ /dev/null
@@ -1,178 +0,0 @@
-# Contributor: Sergei Lukin <sergej.lukin@gmail.com>
-# Contributor: Łukasz Jendrysik <scadu@yandex.com>
-# Contributor: Jakub Skrzypnik <j.skrzypnik@openmailbox.org>
-# Maintainer: Natanael Copa <ncopa@alpinelinux.org>
-pkgname=ffmpeg
-pkgver=4.2.2
-pkgrel=1
-pkgdesc="Complete and free Internet live audio and video broadcasting solution for Linux/Unix"
-url="https://ffmpeg.org/"
-arch="all"
-license="GPL-2.0-or-later AND LGPL-2.1-or-later"
-options="!check" # tests/data/hls-lists.append.m3u8 fails
-subpackages="$pkgname-dev $pkgname-doc $pkgname-libs"
-makedepends="
- alsa-lib-dev
- coreutils
- bzip2-dev
- gnutls-dev
- imlib2-dev
- lame-dev
- libass-dev
- libssh-dev
- libtheora-dev
- libva-dev
- libvdpau-dev
- libvorbis-dev
- libvpx-dev
- libxfixes-dev
- opus-dev
- perl-dev
- sdl2-dev
- v4l-utils-dev
- x264-dev
- x265-dev
- xvidcore-dev
- yasm
- zlib-dev
- "
-checkdepends="rsync"
-source="https://ffmpeg.org/releases/ffmpeg-$pkgver.tar.xz
- 0001-libavutil-clean-up-unused-FF_SYMVER-macro.patch
- "
-
-# secfixes:
-# 4.1.4-r0:
-# - CVE-2019-12730
-# 4.1.3-r0:
-# - CVE-2019-9718
-# - CVE-2019-9721
-# - CVE-2019-11338
-# - CVE-2019-11339
-# 4.1.1-r0:
-# - CVE-2019-1000016
-# 4.1-r0:
-# - CVE-2018-13305
-# - CVE-2018-15822
-# 4.0.2-r0:
-# - CVE-2018-13301
-# - CVE-2018-13303
-# - CVE-2018-13304
-# - CVE-2018-1999010
-# - CVE-2018-1999011
-# - CVE-2018-1999012
-# - CVE-2018-1999013
-# - CVE-2018-1999014
-# - CVE-2018-1999015
-# 4.0.1-r0:
-# - CVE-2018-12459
-# - CVE-2018-12460
-# 4.0.0-r0:
-# - CVE-2018-6912
-# - CVE-2018-7757
-# - CVE-2018-9841
-# 3.4.4-r0:
-# - CVE-2018-14395
-# 3.4.3-r0:
-# - CVE-2018-7557
-# - CVE-2018-7751
-# - CVE-2018-10001
-# - CVE-2018-12458
-# - CVE-2018-13300
-# - CVE-2018-13302
-# - CVE-2018-14394
-# 3.3.4-r0:
-# - CVE-2017-14054
-# - CVE-2017-14055
-# - CVE-2017-14056
-# - CVE-2017-14057
-# - CVE-2017-14058
-# - CVE-2017-14059
-# - CVE-2017-14169
-# - CVE-2017-14170
-# - CVE-2017-14171
-# - CVE-2017-14222
-# - CVE-2017-14223
-# - CVE-2017-14225
-
-# add support for AV1 codec for all archies except armhf and armv7
-# as aom is not available on them
-_aom="";
-_omx="";
-
-case "$CARCH" in
- x86|x86_64|aarch64|ppc64le|s390x )
- _aom="--enable-libaom"; makedepends="$makedepends aom-dev" ;;
-esac
-
-case "$CARCH" in
- aarch64|arm* )
- _omx="--enable-omx --enable-omx-rpi"; makedepends="$makedepends libomxil-bellagio-dev" ;;
-esac
-
-build() {
- local _dbg="--disable-debug"
- local _arch_opts=""
- [ -n "$DEBUG" ] && _dbg="--enable-debug"
-
- case "$CARCH" in
- x86) _asm="--disable-asm" ;;
- esac
-
- ./configure \
- --prefix=/usr \
- --enable-avresample \
- --enable-avfilter \
- --enable-gnutls \
- --enable-gpl \
- --enable-libass \
- --enable-libmp3lame \
- --enable-libvorbis \
- --enable-libvpx \
- --enable-libxvid \
- --enable-libx264 \
- --enable-libx265 \
- --enable-libtheora \
- --enable-libv4l2 \
- --enable-postproc \
- --enable-pic \
- --enable-pthreads \
- --enable-shared \
- --enable-libxcb \
- --enable-libssh \
- --disable-stripping \
- --disable-static \
- --disable-librtmp \
- --enable-vaapi \
- --enable-vdpau \
- --enable-libopus \
- $_asm $_aom $_omx $_dbg
- make
- ${CC:-gcc} -o tools/qt-faststart $CFLAGS tools/qt-faststart.c
- make doc/ffmpeg.1 doc/ffplay.1
-}
-
-# https://ffmpeg.org/fate.html
-check() {
- ./configure \
- --samples=fate-suite/
- make fate-rsync
- make fate-list
- make fate
-}
-
-package() {
- make DESTDIR="$pkgdir" install install-man
- install -D -m755 tools/qt-faststart "$pkgdir/usr/bin/qt-faststart"
-# strip --strip-debug "$pkgdir"/usr/lib/*.a
-}
-
-libs() {
- pkgdesc="Libraries for ffmpeg"
- replaces="ffmpeg"
- mkdir -p "$subpkgdir"/usr
- mv "$pkgdir"/usr/lib "$subpkgdir"/usr
-}
-
-sha512sums="381cd6732fa699eb89000621cf34256920596ed1f9de3c2194dbad35fdf2165269eb7d3a147a0eb75dc18fbb6d601382b5801750e09fc63547766842f84208e3 ffmpeg-4.2.2.tar.xz
-1047a23eda51b576ac200d5106a1cd318d1d5291643b3a69e025c0a7b6f3dbc9f6eb0e1e6faa231b7e38c8dd4e49a54f7431f87a93664da35825cc2e9e8aedf4 0001-libavutil-clean-up-unused-FF_SYMVER-macro.patch"