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Quelle DAV1DDecoder.cpp Sprache: C |
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/* -*- Mode: C++; tab-width: 2; indent-tabs-mode: nil; c-basic-offset: 2 -*- */ /* vim:set ts=2 sw=2 sts=2 et cindent: */ /* This Source Code Form is subject to the terms of the Mozilla Public * License, v. 2.0. If a copy of the MPL was not distributed with this * file, You can obtain one at http://mozilla.org/MPL/2.0/. */ #include "DAV1DDecoder.h" #include "gfxUtils.h" #include "ImageContainer.h" #include "mozilla/StaticPrefs_media.h" #include "mozilla/TaskQueue.h" #include "nsThreadUtils.h" #include "PerformanceRecorder.h" #include "VideoUtils.h" #undef LOG #define LOG(arg, ...) \ DDMOZ_LOG(sPDMLog, mozilla::LogLevel::Debug, "::%s: " arg, __func__, \ ##__VA_ARGS__) namespace mozilla { static int GetDecodingThreadCount(uint32_t aCodedHeight) { /** * Based on the result we print out from the dav1decoder [1], the * following information shows the number of tiles for AV1 videos served on * Youtube. Each Tile can be decoded in parallel, so we would like to make * sure we at least use enough threads to match the number of tiles. * * ---------------------------- * | resolution row col total | * | 480p 2 1 2 | * | 720p 2 2 4 | * | 1080p 4 2 8 | * | 1440p 4 2 8 | * | 2160p 8 4 32 | * ---------------------------- * * Besides the tile thread count, the frame thread count also needs to be * considered. As we didn't find anything about what the best number is for * the count of frame thread, just simply use 2 for parallel jobs, which * is similar with Chromium's implementation. They uses 3 frame threads for * 720p+ but less tile threads, so we will still use more total threads. In * addition, their data is measured on 2019, our data should be closer to the * current real world situation. * [1] * https://searchfox.org/mozilla-central/rev/2f5ed7b7244172d46f538051250b14fb4d8f1 */ int tileThreads = 2, frameThreads = 2; if (aCodedHeight >= 2160) { tileThreads = 32; } else if (aCodedHeight >= 1080) { tileThreads = 8; } else if (aCodedHeight >= 720) { tileThreads = 4; } return tileThreads * frameThreads; } DAV1DDecoder::DAV1DDecoder(const CreateDecoderParams& aParams) : mInfo(aParams.VideoConfig()), mTaskQueue(TaskQueue::Create( GetMediaThreadPool(MediaThreadType::PLATFORM_DECODER), "Dav1dDecoder")), mImageContainer(aParams.mImageContainer), mImageAllocator(aParams.mKnowsCompositor), mTrackingId(aParams.mTrackingId), mLowLatency( aParams.mOptions.contains(CreateDecoderParams::Option::LowLatency)) {} DAV1DDecoder::~DAV1DDecoder() = default; RefPtr<MediaDataDecoder::InitPromise> DAV1DDecoder::Init() { Dav1dSettings settings; dav1d_default_settings(&settings); if (mLowLatency) { settings.max_frame_delay = 1; } size_t decoder_threads = 2; if (mInfo.mDisplay.width >= 2048) { decoder_threads = 8; } else if (mInfo.mDisplay.width >= 1024) { decoder_threads = 4; } if (StaticPrefs::media_av1_new_thread_count_strategy()) { decoder_threads = GetDecodingThreadCount(mInfo.mImage.Height()); } // Still need to consider the amount of physical cores in order to achieve // best performance. settings.n_threads = static_cast<int>(std::min(decoder_threads, GetNumberOfProcessors())); if (int32_t count = StaticPrefs::media_av1_force_thread_count(); count > 0) { settings.n_threads = count; } int res = dav1d_open(&mContext, &settings); if (res < 0) { return DAV1DDecoder::InitPromise::CreateAndReject( MediaResult(NS_ERROR_DOM_MEDIA_FATAL_ERR, RESULT_DETAIL("Couldn't get dAV1d decoder interface.")), __func__); } return DAV1DDecoder::InitPromise::CreateAndResolve(TrackInfo::kVideoTrack, __func__); } RefPtr<MediaDataDecoder::DecodePromise> DAV1DDecoder::Decode( MediaRawData* aSample) { return InvokeAsync<MediaRawData*>(mTaskQueue, this, __func__, &DAV1DDecoder::InvokeDecode, aSample); } void ReleaseDataBuffer_s(const uint8_t* buf, void* user_data) { MOZ_ASSERT(user_data); MOZ_ASSERT(buf); DAV1DDecoder* d = static_cast<DAV1DDecoder*>(user_data); d->ReleaseDataBuffer(buf); } void DAV1DDecoder::ReleaseDataBuffer(const uint8_t* buf) { // The release callback may be called on a different thread defined by the // third party dav1d execution. In that case post a task into TaskQueue to // ensure that mDecodingBuffers is only ever accessed on the TaskQueue. RefPtr<DAV1DDecoder> self = this; auto releaseBuffer = [self, buf] { MOZ_ASSERT(self->mTaskQueue->IsCurrentThreadIn()); DebugOnly<bool> found = self->mDecodingBuffers.Remove(buf); MOZ_ASSERT(found); }; if (mTaskQueue->IsCurrentThreadIn()) { releaseBuffer(); } else { nsresult rv = mTaskQueue->Dispatch(NS_NewRunnableFunction( "DAV1DDecoder::ReleaseDataBuffer", std::move(releaseBuffer))); MOZ_DIAGNOSTIC_ASSERT(NS_SUCCEEDED(rv)); Unused << rv; } } RefPtr<MediaDataDecoder::DecodePromise> DAV1DDecoder::InvokeDecode( MediaRawData* aSample) { MOZ_ASSERT(mTaskQueue->IsCurrentThreadIn()); MOZ_ASSERT(aSample); MediaInfoFlag flag = MediaInfoFlag::None; flag |= (aSample->mKeyframe ? MediaInfoFlag::KeyFrame : MediaInfoFlag::NonKeyFrame); flag |= MediaInfoFlag::SoftwareDecoding; flag |= MediaInfoFlag::VIDEO_AV1; mTrackingId.apply([&](const auto& aId) { mPerformanceRecorder.Start(aSample->mTimecode.ToMicroseconds(), "DAV1DDecoder"_ns, aId, flag); }); // Add the buffer to the hashtable in order to increase // the ref counter and keep it alive. When dav1d does not // need it any more will call it's release callback. Remove // the buffer, in there, to reduce the ref counter and eventually // free it. We need a hashtable and not an array because the // release callback are not coming in the same order that the // buffers have been added in the decoder (threading ordering // inside decoder) mDecodingBuffers.InsertOrUpdate(aSample->Data(), RefPtr{aSample}); Dav1dData data; int res = dav1d_data_wrap(&data, aSample->Data(), aSample->Size(), ReleaseDataBuffer_s, this); data.m.timestamp = aSample->mTimecode.ToMicroseconds(); data.m.duration = aSample->mDuration.ToMicroseconds(); data.m.offset = aSample->mOffset; if (res < 0) { LOG("Create decoder data error."); return DecodePromise::CreateAndReject( MediaResult(NS_ERROR_OUT_OF_MEMORY, __func__), __func__); } DecodedData results; do { res = dav1d_send_data(mContext, &data); if (res < 0 && res != DAV1D_ERR(EAGAIN)) { LOG("Decode error: %d", res); return DecodePromise::CreateAndReject( MediaResult(NS_ERROR_DOM_MEDIA_DECODE_ERR, __func__), __func__); } // Alway consume the whole buffer on success. // At this point only DAV1D_ERR(EAGAIN) is expected. MOZ_ASSERT((res == 0 && !data.sz) || (res == DAV1D_ERR(EAGAIN) && data.sz == aSample->Size())); Result<already_AddRefed<VideoData>, MediaResult> r = GetPicture(); if (r.isOk()) { results.AppendElement(r.unwrap()); } else { MediaResult rs = r.unwrapErr(); if (rs.Code() == NS_ERROR_DOM_MEDIA_WAITING_FOR_DATA) { // No frames ready to return. This is not an error, in some // circumstances, we need to feed it with a certain amount of frames // before we get a picture. continue; } // Skip if rs is NS_OK, which can happen if picture layout is I400. if (NS_FAILED(rs.Code())) { return DecodePromise::CreateAndReject(rs, __func__); } } } while (data.sz > 0); return DecodePromise::CreateAndResolve(std::move(results), __func__); } Result<already_AddRefed<VideoData>, MediaResult> DAV1DDecoder::GetPicture() { class Dav1dPictureWrapper { public: Dav1dPicture* operator&() { return &p; } const Dav1dPicture& operator*() const { return p; } ~Dav1dPictureWrapper() { dav1d_picture_unref(&p); } private: Dav1dPicture p = Dav1dPicture(); }; Dav1dPictureWrapper picture; int res = dav1d_get_picture(mContext, &picture); if (res < 0) { auto r = MediaResult(res == DAV1D_ERR(EAGAIN) ? NS_ERROR_DOM_MEDIA_WAITING_FOR_DATA : NS_ERROR_DOM_MEDIA_DECODE_ERR, RESULT_DETAIL("dav1d_get_picture: %d", res)); LOG("%s", r.Message().get()); return Err(r); } if ((*picture).p.layout == DAV1D_PIXEL_LAYOUT_I400) { // Use NS_OK to indicate that this picture should be skipped. auto r = MediaResult( NS_OK, RESULT_DETAIL("I400 picture: No chroma data to construct an image")); LOG("%s", r.Message().get()); return Err(r); } Result<already_AddRefed<VideoData>, MediaResult> r = ConstructImage(*picture); return r.mapErr([&](const MediaResult& aResult) { LOG("ConstructImage (%ux%u display %ux%u picture %ux%u ) error - %s: %s", (*picture).p.w, (*picture).p.h, mInfo.mDisplay.width, mInfo.mDisplay.height, mInfo.mImage.width, mInfo.mImage.height, aResult.ErrorName().get(), aResult.Message().get()); return aResult; }); } /* static */ Maybe<gfx::YUVColorSpace> DAV1DDecoder::GetColorSpace( const Dav1dPicture& aPicture, LazyLogModule& aLogger) { // When returning Nothing(), the caller chooses the appropriate default. if (!aPicture.seq_hdr || !aPicture.seq_hdr->color_description_present) { return Nothing(); } return gfxUtils::CicpToColorSpace( static_cast<gfx::CICP::MatrixCoefficients>(aPicture.seq_hdr->mtrx), static_cast<gfx::CICP::ColourPrimaries>(aPicture.seq_hdr->pri), aLogger); } /* static */ Maybe<gfx::ColorSpace2> DAV1DDecoder::GetColorPrimaries( const Dav1dPicture& aPicture, LazyLogModule& aLogger) { // When returning Nothing(), the caller chooses the appropriate default. if (!aPicture.seq_hdr || !aPicture.seq_hdr->color_description_present) { return Nothing(); } return gfxUtils::CicpToColorPrimaries( static_cast<gfx::CICP::ColourPrimaries>(aPicture.seq_hdr->pri), aLogger); } Result<already_AddRefed<VideoData>, MediaResult> DAV1DDecoder::ConstructImage( const Dav1dPicture& aPicture) { VideoData::YCbCrBuffer b; if (aPicture.p.bpc == 10) { b.mColorDepth = gfx::ColorDepth::COLOR_10; } else if (aPicture.p.bpc == 12) { b.mColorDepth = gfx::ColorDepth::COLOR_12; } else { b.mColorDepth = gfx::ColorDepth::COLOR_8; } b.mYUVColorSpace = DAV1DDecoder::GetColorSpace(aPicture, sPDMLog) .valueOr(DefaultColorSpace({aPicture.p.w, aPicture.p.h})); b.mColorPrimaries = DAV1DDecoder::GetColorPrimaries(aPicture, sPDMLog) .valueOr(gfx::ColorSpace2::BT709); b.mColorRange = aPicture.seq_hdr->color_range ? gfx::ColorRange::FULL : gfx::ColorRange::LIMITED; b.mPlanes[0].mData = static_cast<uint8_t*>(aPicture.data[0]); b.mPlanes[0].mStride = aPicture.stride[0]; b.mPlanes[0].mHeight = aPicture.p.h; b.mPlanes[0].mWidth = aPicture.p.w; b.mPlanes[0].mSkip = 0; b.mPlanes[1].mData = static_cast<uint8_t*>(aPicture.data[1]); b.mPlanes[1].mStride = aPicture.stride[1]; b.mPlanes[1].mSkip = 0; b.mPlanes[2].mData = static_cast<uint8_t*>(aPicture.data[2]); b.mPlanes[2].mStride = aPicture.stride[1]; b.mPlanes[2].mSkip = 0; // https://code.videolan.org/videolan/dav1d/blob/master/tools/output/yuv.c#L67 const int ss_ver = aPicture.p.layout == DAV1D_PIXEL_LAYOUT_I420; const int ss_hor = aPicture.p.layout != DAV1D_PIXEL_LAYOUT_I444; b.mPlanes[1].mHeight = (aPicture.p.h + ss_ver) >> ss_ver; b.mPlanes[1].mWidth = (aPicture.p.w + ss_hor) >> ss_hor; b.mPlanes[2].mHeight = (aPicture.p.h + ss_ver) >> ss_ver; b.mPlanes[2].mWidth = (aPicture.p.w + ss_hor) >> ss_hor; if (ss_ver) { b.mChromaSubsampling = gfx::ChromaSubsampling::HALF_WIDTH_AND_HEIGHT; } else if (ss_hor) { b.mChromaSubsampling = gfx::ChromaSubsampling::HALF_WIDTH; } // Timestamp, duration and offset used here are wrong. // We need to take those values from the decoder. Latest // dav1d version allows for that. media::TimeUnit timecode = media::TimeUnit::FromMicroseconds(aPicture.m.timestamp); media::TimeUnit duration = media::TimeUnit::FromMicroseconds(aPicture.m.duration); int64_t offset = aPicture.m.offset; bool keyframe = aPicture.frame_hdr->frame_type == DAV1D_FRAME_TYPE_KEY; mPerformanceRecorder.Record(aPicture.m.timestamp, [&](DecodeStage& aStage) { aStage.SetResolution(aPicture.p.w, aPicture.p.h); auto format = [&]() -> Maybe<DecodeStage::ImageFormat> { switch (aPicture.p.layout) { case DAV1D_PIXEL_LAYOUT_I420: return Some(DecodeStage::YUV420P); case DAV1D_PIXEL_LAYOUT_I422: return Some(DecodeStage::YUV422P); case DAV1D_PIXEL_LAYOUT_I444: return Some(DecodeStage::YUV444P); default: return Nothing(); } }(); format.apply([&](auto& aFmt) { aStage.SetImageFormat(aFmt); aStage.SetYUVColorSpace(b.mYUVColorSpace); aStage.SetColorRange(b.mColorRange); aStage.SetColorDepth(b.mColorDepth); aStage.SetStartTimeAndEndTime(aPicture.m.timestamp, aPicture.m.timestamp + aPicture.m.duration); }); return VideoData::CreateAndCopyData( mInfo, mImageContainer, offset, timecode, duration, b, keyframe, timecode, mInfo.ScaledImageRect(aPicture.p.w, aPicture.p.h), mImageAllocator); } RefPtr<MediaDataDecoder::DecodePromise> DAV1DDecoder::Drain() { RefPtr<DAV1DDecoder> self = this; return InvokeAsync(mTaskQueue, __func__, [self, this] { DecodedData results; while (true) { Result<already_AddRefed<VideoData>, MediaResult> r = GetPicture(); if (r.isOk()) { results.AppendElement(r.unwrap()); } else { MediaResult rs = r.unwrapErr(); if (rs.Code() == NS_ERROR_DOM_MEDIA_WAITING_FOR_DATA) { break; } // Skip if rs is NS_OK, which can happen if picture layout is I400. if (NS_FAILED(rs.Code())) { return DecodePromise::CreateAndReject(rs, __func__); } } } return DecodePromise::CreateAndResolve(std::move(results), __func__); }); } RefPtr<MediaDataDecoder::FlushPromise> DAV1DDecoder::Flush() { RefPtr<DAV1DDecoder> self = this; return InvokeAsync(mTaskQueue, __func__, [this, self]() { dav1d_flush(self->mContext); mPerformanceRecorder.Record(std::numeric_limits<int64_t>::max()); return FlushPromise::CreateAndResolve(true, __func__); }); } RefPtr<ShutdownPromise> DAV1DDecoder::Shutdown() { RefPtr<DAV1DDecoder> self = this; return InvokeAsync(mTaskQueue, __func__, [self]() { dav1d_close(&self->mContext); return self->mTaskQueue->BeginShutdown(); }); } } // namespace mozilla #undef LOG
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2026-04-04