/* -*- 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 "nsPrintfCString.h" #include "MediaQueue.h" #include "DecodedAudioDataSink.h" #include "VideoUtils.h" #include "AudioConverter.h" #include "mozilla/CheckedInt.h" #include "mozilla/DebugOnly.h" #include "gfxPrefs.h" namespace mozilla { extern LazyLogModule gMediaDecoderLog; #define SINK_LOG(msg, ...) \ MOZ_LOG(gMediaDecoderLog, LogLevel::Debug, \ ("DecodedAudioDataSink=%p " msg, this, ##__VA_ARGS__)) #define SINK_LOG_V(msg, ...) \ MOZ_LOG(gMediaDecoderLog, LogLevel::Verbose, \ ("DecodedAudioDataSink=%p " msg, this, ##__VA_ARGS__)) namespace media { // The amount of audio frames that is used to fuzz rounding errors. static const int64_t AUDIO_FUZZ_FRAMES = 1; // Amount of audio frames we will be processing ahead of use static const int32_t LOW_AUDIO_USECS = 300000; DecodedAudioDataSink::DecodedAudioDataSink(AbstractThread* aThread, MediaQueue& aAudioQueue, int64_t aStartTime, const AudioInfo& aInfo, dom::AudioChannel aChannel) : AudioSink(aAudioQueue) , mStartTime(aStartTime) , mLastGoodPosition(0) , mInfo(aInfo) , mChannel(aChannel) , mPlaying(true) , mMonitor("DecodedAudioDataSink") , mWritten(0) , mErrored(false) , mPlaybackComplete(false) , mOwnerThread(aThread) , mProcessedQueueLength(0) , mFramesParsed(0) , mLastEndTime(0) , mIsAudioDataAudible(false) { bool resampling = gfxPrefs::AudioSinkResampling(); if (resampling) { mOutputRate = gfxPrefs::AudioSinkResampleRate(); } else if (mInfo.mRate == 44100 || mInfo.mRate == 48000) { // The original rate is of good quality and we want to minimize unecessary // resampling. The common scenario being that the sampling rate is one or // the other, this allows to minimize audio quality regression and hoping // content provider want change from those rates mid-stream. mOutputRate = mInfo.mRate; } else { // We will resample all data to match cubeb's preferred sampling rate. mOutputRate = AudioStream::GetPreferredRate(); } MOZ_DIAGNOSTIC_ASSERT(mOutputRate, "output rate can't be 0."); bool monoAudioEnabled = gfxPrefs::MonoAudio(); mOutputChannels = monoAudioEnabled ? 1 : (gfxPrefs::AudioSinkForceStereo() ? 2 : mInfo.mChannels); } DecodedAudioDataSink::~DecodedAudioDataSink() { } RefPtr DecodedAudioDataSink::Init(const PlaybackParams& aParams) { MOZ_ASSERT(mOwnerThread->IsCurrentThreadIn()); mAudioQueueListener = mAudioQueue.PushEvent().Connect( mOwnerThread, this, &DecodedAudioDataSink::OnAudioPushed); mAudioQueueFinishListener = mAudioQueue.FinishEvent().Connect( mOwnerThread, this, &DecodedAudioDataSink::NotifyAudioNeeded); mProcessedQueueListener = mProcessedQueue.PopEvent().Connect( mOwnerThread, this, &DecodedAudioDataSink::OnAudioPopped); // To ensure at least one audio packet will be popped from AudioQueue and // ready to be played. NotifyAudioNeeded(); RefPtr p = mEndPromise.Ensure(__func__); nsresult rv = InitializeAudioStream(aParams); if (NS_FAILED(rv)) { mEndPromise.Reject(rv, __func__); } return p; } int64_t DecodedAudioDataSink::GetPosition() { int64_t pos; if (mAudioStream && (pos = mAudioStream->GetPosition()) >= 0) { NS_ASSERTION(pos >= mLastGoodPosition, "AudioStream position shouldn't go backward"); // Update the last good position when we got a good one. if (pos >= mLastGoodPosition) { mLastGoodPosition = pos; } } return mStartTime + mLastGoodPosition; } bool DecodedAudioDataSink::HasUnplayedFrames() { // Experimentation suggests that GetPositionInFrames() is zero-indexed, // so we need to add 1 here before comparing it to mWritten. int64_t total; { MonitorAutoLock mon(mMonitor); total = mWritten + (mCursor.get() ? mCursor->Available() : 0); } return mProcessedQueue.GetSize() || (mAudioStream && mAudioStream->GetPositionInFrames() + 1 < total); } void DecodedAudioDataSink::Shutdown() { MOZ_ASSERT(mOwnerThread->IsCurrentThreadIn()); mAudioQueueListener.Disconnect(); mAudioQueueFinishListener.Disconnect(); mProcessedQueueListener.Disconnect(); if (mAudioStream) { mAudioStream->Shutdown(); mAudioStream = nullptr; } mProcessedQueue.Reset(); mProcessedQueue.Finish(); mEndPromise.ResolveIfExists(true, __func__); } void DecodedAudioDataSink::SetVolume(double aVolume) { if (mAudioStream) { mAudioStream->SetVolume(aVolume); } } void DecodedAudioDataSink::SetPlaybackRate(double aPlaybackRate) { MOZ_ASSERT(aPlaybackRate != 0, "Don't set the playbackRate to 0 on AudioStream"); if (mAudioStream) { mAudioStream->SetPlaybackRate(aPlaybackRate); } } void DecodedAudioDataSink::SetPreservesPitch(bool aPreservesPitch) { if (mAudioStream) { mAudioStream->SetPreservesPitch(aPreservesPitch); } } void DecodedAudioDataSink::SetPlaying(bool aPlaying) { if (!mAudioStream || mPlaying == aPlaying || mPlaybackComplete) { return; } // pause/resume AudioStream as necessary. if (!aPlaying && !mAudioStream->IsPaused()) { mAudioStream->Pause(); } else if (aPlaying && mAudioStream->IsPaused()) { mAudioStream->Resume(); } mPlaying = aPlaying; } nsresult DecodedAudioDataSink::InitializeAudioStream(const PlaybackParams& aParams) { mAudioStream = new AudioStream(*this); nsresult rv = mAudioStream->Init(mOutputChannels, mOutputRate, mChannel); if (NS_FAILED(rv)) { mAudioStream->Shutdown(); mAudioStream = nullptr; return rv; } // Set playback params before calling Start() so they can take effect // as soon as the 1st DataCallback of the AudioStream fires. mAudioStream->SetVolume(aParams.mVolume); mAudioStream->SetPlaybackRate(aParams.mPlaybackRate); mAudioStream->SetPreservesPitch(aParams.mPreservesPitch); mAudioStream->Start(); return NS_OK; } int64_t DecodedAudioDataSink::GetEndTime() const { int64_t written; { MonitorAutoLock mon(mMonitor); written = mWritten; } CheckedInt64 playedUsecs = FramesToUsecs(written, mOutputRate) + mStartTime; if (!playedUsecs.isValid()) { NS_WARNING("Int overflow calculating audio end time"); return -1; } // As we may be resampling, rounding errors may occur. Ensure we never get // past the original end time. return std::min(mLastEndTime, playedUsecs.value()); } UniquePtr DecodedAudioDataSink::PopFrames(uint32_t aFrames) { class Chunk : public AudioStream::Chunk { public: Chunk(AudioData* aBuffer, uint32_t aFrames, AudioDataValue* aData) : mBuffer(aBuffer), mFrames(aFrames), mData(aData) {} Chunk() : mFrames(0), mData(nullptr) {} const AudioDataValue* Data() const { return mData; } uint32_t Frames() const { return mFrames; } uint32_t Channels() const { return mBuffer ? mBuffer->mChannels: 0; } uint32_t Rate() const { return mBuffer ? mBuffer->mRate : 0; } AudioDataValue* GetWritable() const { return mData; } private: const RefPtr mBuffer; const uint32_t mFrames; AudioDataValue* const mData; }; class SilentChunk : public AudioStream::Chunk { public: SilentChunk(uint32_t aFrames, uint32_t aChannels, uint32_t aRate) : mFrames(aFrames) , mChannels(aChannels) , mRate(aRate) , mData(MakeUnique(aChannels * aFrames)) { memset(mData.get(), 0, aChannels * aFrames * sizeof(AudioDataValue)); } const AudioDataValue* Data() const { return mData.get(); } uint32_t Frames() const { return mFrames; } uint32_t Channels() const { return mChannels; } uint32_t Rate() const { return mRate; } AudioDataValue* GetWritable() const { return mData.get(); } private: const uint32_t mFrames; const uint32_t mChannels; const uint32_t mRate; UniquePtr mData; }; bool needPopping = false; if (!mCurrentData) { // No data in the queue. Return an empty chunk. if (!mProcessedQueue.GetSize()) { return MakeUnique(); } // We need to update our values prior popping the processed queue in // order to prevent the pop event to fire too early (prior // mProcessedQueueLength being updated) or prevent HasUnplayedFrames // to incorrectly return true during the time interval betweeen the // when mProcessedQueue is read and mWritten is updated. needPopping = true; mCurrentData = mProcessedQueue.PeekFront(); { MonitorAutoLock mon(mMonitor); mCursor = MakeUnique(mCurrentData->mAudioData.get(), mCurrentData->mChannels, mCurrentData->mFrames); } MOZ_ASSERT(mCurrentData->mFrames > 0); mProcessedQueueLength -= FramesToUsecs(mCurrentData->mFrames, mOutputRate).value(); } auto framesToPop = std::min(aFrames, mCursor->Available()); SINK_LOG_V("playing audio at time=%lld offset=%u length=%u", mCurrentData->mTime, mCurrentData->mFrames - mCursor->Available(), framesToPop); UniquePtr chunk = MakeUnique(mCurrentData, framesToPop, mCursor->Ptr()); { MonitorAutoLock mon(mMonitor); mWritten += framesToPop; mCursor->Advance(framesToPop); } // All frames are popped. Reset mCurrentData so we can pop new elements from // the audio queue in next calls to PopFrames(). if (!mCursor->Available()) { mCurrentData = nullptr; } if (needPopping) { // We can now safely pop the audio packet from the processed queue. // This will fire the popped event, triggering a call to NotifyAudioNeeded. RefPtr releaseMe = mProcessedQueue.PopFront(); CheckIsAudible(releaseMe); } return chunk; } bool DecodedAudioDataSink::Ended() const { // Return true when error encountered so AudioStream can start draining. return mProcessedQueue.IsFinished() || mErrored; } void DecodedAudioDataSink::Drained() { SINK_LOG("Drained"); mPlaybackComplete = true; mEndPromise.ResolveIfExists(true, __func__); } void DecodedAudioDataSink::CheckIsAudible(const AudioData* aData) { MOZ_ASSERT(aData); bool isAudible = aData->IsAudible(); if (isAudible != mIsAudioDataAudible) { mIsAudioDataAudible = isAudible; mAudibleEvent.Notify(mIsAudioDataAudible); } } void DecodedAudioDataSink::OnAudioPopped(const RefPtr& aSample) { SINK_LOG_V("AudioStream has used an audio packet."); NotifyAudioNeeded(); } void DecodedAudioDataSink::OnAudioPushed(const RefPtr& aSample) { SINK_LOG_V("One new audio packet available."); NotifyAudioNeeded(); } void DecodedAudioDataSink::NotifyAudioNeeded() { MOZ_ASSERT(mOwnerThread->IsCurrentThreadIn(), "Not called from the owner's thread"); // Always ensure we have two processed frames pending to allow for processing // latency. while (AudioQueue().GetSize() && (AudioQueue().IsFinished() || mProcessedQueueLength < LOW_AUDIO_USECS || mProcessedQueue.GetSize() < 2)) { RefPtr data = dont_AddRef(AudioQueue().PopFront().take()->As()); // Ignore the element with 0 frames and try next. if (!data->mFrames) { continue; } if (!mConverter || (data->mRate != mConverter->InputConfig().Rate() || data->mChannels != mConverter->InputConfig().Channels())) { SINK_LOG_V("Audio format changed from %u@%uHz to %u@%uHz", mConverter? mConverter->InputConfig().Channels() : 0, mConverter ? mConverter->InputConfig().Rate() : 0, data->mChannels, data->mRate); DrainConverter(); // mFramesParsed indicates the current playtime in frames at the current // input sampling rate. Recalculate it per the new sampling rate. if (mFramesParsed) { // We minimize overflow. uint32_t oldRate = mConverter->InputConfig().Rate(); uint32_t newRate = data->mRate; CheckedInt64 result = SaferMultDiv(mFramesParsed, newRate, oldRate); if (!result.isValid()) { NS_WARNING("Int overflow in DecodedAudioDataSink"); mErrored = true; return; } mFramesParsed = result.value(); } mConverter = MakeUnique( AudioConfig(data->mChannels, data->mRate), AudioConfig(mOutputChannels, mOutputRate)); } // See if there's a gap in the audio. If there is, push silence into the // audio hardware, so we can play across the gap. // Calculate the timestamp of the next chunk of audio in numbers of // samples. CheckedInt64 sampleTime = UsecsToFrames(data->mTime - mStartTime, data->mRate); // Calculate the number of frames that have been pushed onto the audio hardware. CheckedInt64 missingFrames = sampleTime - mFramesParsed; if (!missingFrames.isValid()) { NS_WARNING("Int overflow in DecodedAudioDataSink"); mErrored = true; return; } if (missingFrames.value() > AUDIO_FUZZ_FRAMES) { // The next audio packet begins some time after the end of the last packet // we pushed to the audio hardware. We must push silence into the audio // hardware so that the next audio packet begins playback at the correct // time. missingFrames = std::min(INT32_MAX, missingFrames.value()); mFramesParsed += missingFrames.value(); // We need to calculate how many frames are missing at the output rate. missingFrames = SaferMultDiv(missingFrames.value(), mOutputRate, data->mRate); if (!missingFrames.isValid()) { NS_WARNING("Int overflow in DecodedAudioDataSink"); mErrored = true; return; } // We need to insert silence, first use drained frames if any. missingFrames -= DrainConverter(missingFrames.value()); // Insert silence if still needed. if (missingFrames.value()) { AlignedAudioBuffer silenceData(missingFrames.value() * mOutputChannels); if (!silenceData) { NS_WARNING("OOM in DecodedAudioDataSink"); mErrored = true; return; } RefPtr silence = CreateAudioFromBuffer(Move(silenceData), data); PushProcessedAudio(silence); } } mLastEndTime = data->GetEndTime(); mFramesParsed += data->mFrames; if (mConverter->InputConfig() != mConverter->OutputConfig()) { AlignedAudioBuffer convertedData = mConverter->Process(AudioSampleBuffer(Move(data->mAudioData))).Forget(); data = CreateAudioFromBuffer(Move(convertedData), data); } if (PushProcessedAudio(data)) { mLastProcessedPacket = Some(data); } } if (AudioQueue().IsFinished()) { // We have reached the end of the data, drain the resampler. DrainConverter(); mProcessedQueue.Finish(); } } uint32_t DecodedAudioDataSink::PushProcessedAudio(AudioData* aData) { if (!aData || !aData->mFrames) { return 0; } mProcessedQueue.Push(aData); mProcessedQueueLength += FramesToUsecs(aData->mFrames, mOutputRate).value(); return aData->mFrames; } already_AddRefed DecodedAudioDataSink::CreateAudioFromBuffer(AlignedAudioBuffer&& aBuffer, AudioData* aReference) { uint32_t frames = aBuffer.Length() / mOutputChannels; if (!frames) { return nullptr; } CheckedInt64 duration = FramesToUsecs(frames, mOutputRate); if (!duration.isValid()) { NS_WARNING("Int overflow in DecodedAudioDataSink"); mErrored = true; return nullptr; } RefPtr data = new AudioData(aReference->mOffset, aReference->mTime, duration.value(), frames, Move(aBuffer), mOutputChannels, mOutputRate); return data.forget(); } uint32_t DecodedAudioDataSink::DrainConverter(uint32_t aMaxFrames) { MOZ_ASSERT(mOwnerThread->IsCurrentThreadIn()); if (!mConverter || !mLastProcessedPacket || !aMaxFrames) { // nothing to drain. return 0; } RefPtr lastPacket = mLastProcessedPacket.ref(); mLastProcessedPacket.reset(); // To drain we simply provide an empty packet to the audio converter. AlignedAudioBuffer convertedData = mConverter->Process(AudioSampleBuffer(AlignedAudioBuffer())).Forget(); uint32_t frames = convertedData.Length() / mOutputChannels; if (!convertedData.SetLength(std::min(frames, aMaxFrames) * mOutputChannels)) { // This can never happen as we were reducing the length of convertData. mErrored = true; return 0; } RefPtr data = CreateAudioFromBuffer(Move(convertedData), lastPacket); if (!data) { return 0; } mProcessedQueue.Push(data); return data->mFrames; } } // namespace media } // namespace mozilla