/* 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 "MediaEngineWebRTC.h" #include #include #include "mozilla/Assertions.h" // scoped_ptr.h uses FF #ifdef FF #undef FF #endif #include "webrtc/modules/audio_device/opensl/single_rw_fifo.h" #define CHANNELS 1 #define ENCODING "L16" #define DEFAULT_PORT 5555 #define SAMPLE_RATE 256000 #define SAMPLE_FREQUENCY 16000 #define SAMPLE_LENGTH ((SAMPLE_FREQUENCY*10)/1000) // These are restrictions from the webrtc.org code #define MAX_CHANNELS 2 #define MAX_SAMPLING_FREQ 48000 // Hz - multiple of 100 #define MAX_AEC_FIFO_DEPTH 200 // ms - multiple of 10 static_assert(!(MAX_AEC_FIFO_DEPTH % 10), "Invalid MAX_AEC_FIFO_DEPTH"); namespace mozilla { #ifdef LOG #undef LOG #endif #ifdef PR_LOGGING extern PRLogModuleInfo* GetMediaManagerLog(); #define LOG(msg) PR_LOG(GetMediaManagerLog(), PR_LOG_DEBUG, msg) #else #define LOG(msg) #endif /** * Webrtc audio source. */ NS_IMPL_ISUPPORTS0(MediaEngineWebRTCAudioSource) // XXX temp until MSG supports registration StaticAutoPtr gFarendObserver; AudioOutputObserver::AudioOutputObserver() : mPlayoutFreq(0) , mPlayoutChannels(0) , mChunkSize(0) , mSamplesSaved(0) { // Buffers of 10ms chunks mPlayoutFifo = new webrtc::SingleRwFifo(MAX_AEC_FIFO_DEPTH/10); } AudioOutputObserver::~AudioOutputObserver() { } void AudioOutputObserver::Clear() { while (mPlayoutFifo->size() > 0) { (void) mPlayoutFifo->Pop(); } } FarEndAudioChunk * AudioOutputObserver::Pop() { return (FarEndAudioChunk *) mPlayoutFifo->Pop(); } uint32_t AudioOutputObserver::Size() { return mPlayoutFifo->size(); } // static void AudioOutputObserver::InsertFarEnd(const AudioDataValue *aBuffer, uint32_t aSamples, bool aOverran, int aFreq, int aChannels, AudioSampleFormat aFormat) { if (mPlayoutChannels != 0) { if (mPlayoutChannels != static_cast(aChannels)) { MOZ_CRASH(); } } else { MOZ_ASSERT(aChannels <= MAX_CHANNELS); mPlayoutChannels = static_cast(aChannels); } if (mPlayoutFreq != 0) { if (mPlayoutFreq != static_cast(aFreq)) { MOZ_CRASH(); } } else { MOZ_ASSERT(aFreq <= MAX_SAMPLING_FREQ); MOZ_ASSERT(!(aFreq % 100), "Sampling rate for far end data should be multiple of 100."); mPlayoutFreq = aFreq; mChunkSize = aFreq/100; // 10ms } #ifdef LOG_FAREND_INSERTION static FILE *fp = fopen("insertfarend.pcm","wb"); #endif if (mSaved) { // flag overrun as soon as possible, and only once mSaved->mOverrun = aOverran; aOverran = false; } // Rechunk to 10ms. // The AnalyzeReverseStream() and WebRtcAec_BufferFarend() functions insist on 10ms // samples per call. Annoying... while (aSamples) { if (!mSaved) { mSaved = (FarEndAudioChunk *) moz_xmalloc(sizeof(FarEndAudioChunk) + (mChunkSize * aChannels - 1)*sizeof(int16_t)); mSaved->mSamples = mChunkSize; mSaved->mOverrun = aOverran; aOverran = false; } uint32_t to_copy = mChunkSize - mSamplesSaved; if (to_copy > aSamples) { to_copy = aSamples; } int16_t *dest = &(mSaved->mData[mSamplesSaved * aChannels]); ConvertAudioSamples(aBuffer, dest, to_copy * aChannels); #ifdef LOG_FAREND_INSERTION if (fp) { fwrite(&(mSaved->mData[mSamplesSaved * aChannels]), to_copy * aChannels, sizeof(int16_t), fp); } #endif aSamples -= to_copy; mSamplesSaved += to_copy; if (mSamplesSaved >= mChunkSize) { int free_slots = mPlayoutFifo->capacity() - mPlayoutFifo->size(); if (free_slots <= 0) { // XXX We should flag an overrun for the reader. We can't drop data from it due to // thread safety issues. break; } else { mPlayoutFifo->Push((int8_t *) mSaved.forget()); // takes ownership mSamplesSaved = 0; } } } } void MediaEngineWebRTCAudioSource::GetName(nsAString& aName) { if (mInitDone) { aName.Assign(mDeviceName); } return; } void MediaEngineWebRTCAudioSource::GetUUID(nsAString& aUUID) { if (mInitDone) { aUUID.Assign(mDeviceUUID); } return; } nsresult MediaEngineWebRTCAudioSource::Config(bool aEchoOn, uint32_t aEcho, bool aAgcOn, uint32_t aAGC, bool aNoiseOn, uint32_t aNoise, int32_t aPlayoutDelay) { LOG(("Audio config: aec: %d, agc: %d, noise: %d", aEchoOn ? aEcho : -1, aAgcOn ? aAGC : -1, aNoiseOn ? aNoise : -1)); bool update_echo = (mEchoOn != aEchoOn); bool update_agc = (mAgcOn != aAgcOn); bool update_noise = (mNoiseOn != aNoiseOn); mEchoOn = aEchoOn; mAgcOn = aAgcOn; mNoiseOn = aNoiseOn; if ((webrtc::EcModes) aEcho != webrtc::kEcUnchanged) { if (mEchoCancel != (webrtc::EcModes) aEcho) { update_echo = true; mEchoCancel = (webrtc::EcModes) aEcho; } } if ((webrtc::AgcModes) aAGC != webrtc::kAgcUnchanged) { if (mAGC != (webrtc::AgcModes) aAGC) { update_agc = true; mAGC = (webrtc::AgcModes) aAGC; } } if ((webrtc::NsModes) aNoise != webrtc::kNsUnchanged) { if (mNoiseSuppress != (webrtc::NsModes) aNoise) { update_noise = true; mNoiseSuppress = (webrtc::NsModes) aNoise; } } mPlayoutDelay = aPlayoutDelay; if (mInitDone) { int error; if (update_echo && 0 != (error = mVoEProcessing->SetEcStatus(mEchoOn, (webrtc::EcModes) aEcho))) { LOG(("%s Error setting Echo Status: %d ",__FUNCTION__, error)); // Overhead of capturing all the time is very low (<0.1% of an audio only call) if (mEchoOn) { if (0 != (error = mVoEProcessing->SetEcMetricsStatus(true))) { LOG(("%s Error setting Echo Metrics: %d ",__FUNCTION__, error)); } } } if (update_agc && 0 != (error = mVoEProcessing->SetAgcStatus(mAgcOn, (webrtc::AgcModes) aAGC))) { LOG(("%s Error setting AGC Status: %d ",__FUNCTION__, error)); } if (update_noise && 0 != (error = mVoEProcessing->SetNsStatus(mNoiseOn, (webrtc::NsModes) aNoise))) { LOG(("%s Error setting NoiseSuppression Status: %d ",__FUNCTION__, error)); } } return NS_OK; } nsresult MediaEngineWebRTCAudioSource::Allocate(const MediaEnginePrefs &aPrefs) { if (mState == kReleased) { if (mInitDone) { ScopedCustomReleasePtr ptrVoEHw(webrtc::VoEHardware::GetInterface(mVoiceEngine)); if (!ptrVoEHw || ptrVoEHw->SetRecordingDevice(mCapIndex)) { return NS_ERROR_FAILURE; } mState = kAllocated; LOG(("Audio device %d allocated", mCapIndex)); } else { LOG(("Audio device is not initalized")); return NS_ERROR_FAILURE; } } else if (mSources.IsEmpty()) { LOG(("Audio device %d reallocated", mCapIndex)); } else { LOG(("Audio device %d allocated shared", mCapIndex)); } return NS_OK; } nsresult MediaEngineWebRTCAudioSource::Deallocate() { if (mSources.IsEmpty()) { if (mState != kStopped && mState != kAllocated) { return NS_ERROR_FAILURE; } mState = kReleased; LOG(("Audio device %d deallocated", mCapIndex)); } else { LOG(("Audio device %d deallocated but still in use", mCapIndex)); } return NS_OK; } nsresult MediaEngineWebRTCAudioSource::Start(SourceMediaStream* aStream, TrackID aID) { if (!mInitDone || !aStream) { return NS_ERROR_FAILURE; } { MonitorAutoLock lock(mMonitor); mSources.AppendElement(aStream); } AudioSegment* segment = new AudioSegment(); aStream->AddTrack(aID, SAMPLE_FREQUENCY, 0, segment); aStream->AdvanceKnownTracksTime(STREAM_TIME_MAX); // XXX Make this based on the pref. aStream->RegisterForAudioMixing(); LOG(("Start audio for stream %p", aStream)); if (mState == kStarted) { MOZ_ASSERT(aID == mTrackID); return NS_OK; } mState = kStarted; mTrackID = aID; // Make sure logger starts before capture AsyncLatencyLogger::Get(true); // Register output observer // XXX MOZ_ASSERT(gFarendObserver); gFarendObserver->Clear(); // Configure audio processing in webrtc code Config(mEchoOn, webrtc::kEcUnchanged, mAgcOn, webrtc::kAgcUnchanged, mNoiseOn, webrtc::kNsUnchanged, mPlayoutDelay); if (mVoEBase->StartReceive(mChannel)) { return NS_ERROR_FAILURE; } if (mVoEBase->StartSend(mChannel)) { return NS_ERROR_FAILURE; } // Attach external media processor, so this::Process will be called. mVoERender->RegisterExternalMediaProcessing(mChannel, webrtc::kRecordingPerChannel, *this); return NS_OK; } nsresult MediaEngineWebRTCAudioSource::Stop(SourceMediaStream *aSource, TrackID aID) { { MonitorAutoLock lock(mMonitor); if (!mSources.RemoveElement(aSource)) { // Already stopped - this is allowed return NS_OK; } if (!mSources.IsEmpty()) { return NS_OK; } if (mState != kStarted) { return NS_ERROR_FAILURE; } if (!mVoEBase) { return NS_ERROR_FAILURE; } mState = kStopped; aSource->EndTrack(aID); } mVoERender->DeRegisterExternalMediaProcessing(mChannel, webrtc::kRecordingPerChannel); if (mVoEBase->StopSend(mChannel)) { return NS_ERROR_FAILURE; } if (mVoEBase->StopReceive(mChannel)) { return NS_ERROR_FAILURE; } return NS_OK; } void MediaEngineWebRTCAudioSource::NotifyPull(MediaStreamGraph* aGraph, SourceMediaStream *aSource, TrackID aID, StreamTime aDesiredTime, TrackTicks &aLastEndTime) { // Ignore - we push audio data #ifdef DEBUG TrackTicks target = TimeToTicksRoundUp(SAMPLE_FREQUENCY, aDesiredTime); TrackTicks delta = target - aLastEndTime; LOG(("Audio: NotifyPull: aDesiredTime %ld, target %ld, delta %ld",(int64_t) aDesiredTime, (int64_t) target, (int64_t) delta)); aLastEndTime = target; #endif } nsresult MediaEngineWebRTCAudioSource::Snapshot(uint32_t aDuration, nsIDOMFile** aFile) { return NS_ERROR_NOT_IMPLEMENTED; } void MediaEngineWebRTCAudioSource::Init() { mVoEBase = webrtc::VoEBase::GetInterface(mVoiceEngine); mVoEBase->Init(); mVoERender = webrtc::VoEExternalMedia::GetInterface(mVoiceEngine); if (!mVoERender) { return; } mVoENetwork = webrtc::VoENetwork::GetInterface(mVoiceEngine); if (!mVoENetwork) { return; } mVoEProcessing = webrtc::VoEAudioProcessing::GetInterface(mVoiceEngine); if (!mVoEProcessing) { return; } mVoECallReport = webrtc::VoECallReport::GetInterface(mVoiceEngine); if (!mVoECallReport) { return; } mChannel = mVoEBase->CreateChannel(); if (mChannel < 0) { return; } mNullTransport = new NullTransport(); if (mVoENetwork->RegisterExternalTransport(mChannel, *mNullTransport)) { return; } // Check for availability. ScopedCustomReleasePtr ptrVoEHw(webrtc::VoEHardware::GetInterface(mVoiceEngine)); if (!ptrVoEHw || ptrVoEHw->SetRecordingDevice(mCapIndex)) { return; } #ifndef MOZ_B2G // Because of the permission mechanism of B2G, we need to skip the status // check here. bool avail = false; ptrVoEHw->GetRecordingDeviceStatus(avail); if (!avail) { return; } #endif // MOZ_B2G // Set "codec" to PCM, 32kHz on 1 channel ScopedCustomReleasePtr ptrVoECodec(webrtc::VoECodec::GetInterface(mVoiceEngine)); if (!ptrVoECodec) { return; } webrtc::CodecInst codec; strcpy(codec.plname, ENCODING); codec.channels = CHANNELS; codec.rate = SAMPLE_RATE; codec.plfreq = SAMPLE_FREQUENCY; codec.pacsize = SAMPLE_LENGTH; codec.pltype = 0; // Default payload type if (!ptrVoECodec->SetSendCodec(mChannel, codec)) { mInitDone = true; } } void MediaEngineWebRTCAudioSource::Shutdown() { if (!mInitDone) { // duplicate these here in case we failed during Init() if (mChannel != -1) { mVoENetwork->DeRegisterExternalTransport(mChannel); } if (mNullTransport) { delete mNullTransport; } return; } if (mState == kStarted) { while (!mSources.IsEmpty()) { Stop(mSources[0], kAudioTrack); // XXX change to support multiple tracks } MOZ_ASSERT(mState == kStopped); } if (mState == kAllocated || mState == kStopped) { Deallocate(); } mVoEBase->Terminate(); if (mChannel != -1) { mVoENetwork->DeRegisterExternalTransport(mChannel); } if (mNullTransport) { delete mNullTransport; } mVoEProcessing = nullptr; mVoENetwork = nullptr; mVoERender = nullptr; mVoEBase = nullptr; mState = kReleased; mInitDone = false; } typedef int16_t sample; void MediaEngineWebRTCAudioSource::Process(int channel, webrtc::ProcessingTypes type, sample* audio10ms, int length, int samplingFreq, bool isStereo) { // On initial capture, throw away all far-end data except the most recent sample // since it's already irrelevant and we want to keep avoid confusing the AEC far-end // input code with "old" audio. if (!mStarted) { mStarted = true; while (gFarendObserver->Size() > 1) { FarEndAudioChunk *buffer = gFarendObserver->Pop(); // only call if size() > 0 free(buffer); } } while (gFarendObserver->Size() > 0) { FarEndAudioChunk *buffer = gFarendObserver->Pop(); // only call if size() > 0 if (buffer) { int length = buffer->mSamples; if (mVoERender->ExternalPlayoutData(buffer->mData, gFarendObserver->PlayoutFrequency(), gFarendObserver->PlayoutChannels(), mPlayoutDelay, length) == -1) { return; } } free(buffer); } #ifdef PR_LOGGING mSamples += length; if (mSamples > samplingFreq) { mSamples %= samplingFreq; // just in case mSamples >> samplingFreq if (PR_LOG_TEST(GetMediaManagerLog(), PR_LOG_DEBUG)) { webrtc::EchoStatistics echo; mVoECallReport->GetEchoMetricSummary(echo); #define DUMP_STATVAL(x) (x).min, (x).max, (x).average LOG(("Echo: ERL: %d/%d/%d, ERLE: %d/%d/%d, RERL: %d/%d/%d, NLP: %d/%d/%d", DUMP_STATVAL(echo.erl), DUMP_STATVAL(echo.erle), DUMP_STATVAL(echo.rerl), DUMP_STATVAL(echo.a_nlp))); } } #endif MonitorAutoLock lock(mMonitor); if (mState != kStarted) return; uint32_t len = mSources.Length(); for (uint32_t i = 0; i < len; i++) { nsRefPtr buffer = SharedBuffer::Create(length * sizeof(sample)); sample* dest = static_cast(buffer->Data()); memcpy(dest, audio10ms, length * sizeof(sample)); AudioSegment segment; nsAutoTArray channels; channels.AppendElement(dest); segment.AppendFrames(buffer.forget(), channels, length); TimeStamp insertTime; segment.GetStartTime(insertTime); SourceMediaStream *source = mSources[i]; if (source) { // This is safe from any thread, and is safe if the track is Finished // or Destroyed. // Make sure we include the stream and the track. // The 0:1 is a flag to note when we've done the final insert for a given input block. LogTime(AsyncLatencyLogger::AudioTrackInsertion, LATENCY_STREAM_ID(source, mTrackID), (i+1 < len) ? 0 : 1, insertTime); source->AppendToTrack(mTrackID, &segment); } } return; } }