void AudioNodeStream::ObtainInputBlock(AudioBlock& aTmpChunk, uint32_t aPortIndex) { uint32_t inputCount = mInputs.Length(); uint32_t outputChannelCount = 1; nsAutoTArray<const AudioBlock*,250> inputChunks; for (uint32_t i = 0; i < inputCount; ++i) { if (aPortIndex != mInputs[i]->InputNumber()) { // This input is connected to a different port continue; } MediaStream* s = mInputs[i]->GetSource(); AudioNodeStream* a = static_cast<AudioNodeStream*>(s); MOZ_ASSERT(a == s->AsAudioNodeStream()); if (a->IsAudioParamStream()) { continue; } const AudioBlock* chunk = &a->mLastChunks[mInputs[i]->OutputNumber()]; MOZ_ASSERT(chunk); if (chunk->IsNull() || chunk->mChannelData.IsEmpty()) { continue; } inputChunks.AppendElement(chunk); outputChannelCount = GetAudioChannelsSuperset(outputChannelCount, chunk->ChannelCount()); } outputChannelCount = ComputedNumberOfChannels(outputChannelCount); uint32_t inputChunkCount = inputChunks.Length(); if (inputChunkCount == 0 || (inputChunkCount == 1 && inputChunks[0]->ChannelCount() == 0)) { aTmpChunk.SetNull(WEBAUDIO_BLOCK_SIZE); return; } if (inputChunkCount == 1 && inputChunks[0]->ChannelCount() == outputChannelCount) { aTmpChunk = *inputChunks[0]; return; } if (outputChannelCount == 0) { aTmpChunk.SetNull(WEBAUDIO_BLOCK_SIZE); return; } aTmpChunk.AllocateChannels(outputChannelCount); // The static storage here should be 1KB, so it's fine nsAutoTArray<float, GUESS_AUDIO_CHANNELS*WEBAUDIO_BLOCK_SIZE> downmixBuffer; for (uint32_t i = 0; i < inputChunkCount; ++i) { AccumulateInputChunk(i, *inputChunks[i], &aTmpChunk, &downmixBuffer); } }
already_AddRefed<Promise> AudioContext::Close(ErrorResult& aRv) { nsCOMPtr<nsIGlobalObject> parentObject = do_QueryInterface(GetParentObject()); RefPtr<Promise> promise; promise = Promise::Create(parentObject, aRv); if (aRv.Failed()) { return nullptr; } if (mIsOffline) { promise->MaybeReject(NS_ERROR_DOM_NOT_SUPPORTED_ERR); return promise.forget(); } if (mAudioContextState == AudioContextState::Closed) { promise->MaybeResolve(NS_ERROR_DOM_INVALID_STATE_ERR); return promise.forget(); } if (Destination()) { Destination()->DestroyAudioChannelAgent(); } mPromiseGripArray.AppendElement(promise); // This can be called when freeing a document, and the streams are dead at // this point, so we need extra null-checks. MediaStream* ds = DestinationStream(); if (ds) { nsTArray<MediaStream*> streams; // If mSuspendCalled or mCloseCalled are true then we already suspended // all our streams, so don't suspend them again. But we still need to do // ApplyAudioContextOperation to ensure our new promise is resolved. if (!mSuspendCalled && !mCloseCalled) { streams = GetAllStreams(); } Graph()->ApplyAudioContextOperation(ds->AsAudioNodeStream(), streams, AudioContextOperation::Close, promise); } mCloseCalled = true; return promise.forget(); }
already_AddRefed<Promise> AudioContext::Close(ErrorResult& aRv) { nsCOMPtr<nsIGlobalObject> parentObject = do_QueryInterface(GetParentObject()); nsRefPtr<Promise> promise; promise = Promise::Create(parentObject, aRv); if (aRv.Failed()) { return nullptr; } if (mIsOffline) { promise->MaybeReject(NS_ERROR_DOM_NOT_SUPPORTED_ERR); return promise.forget(); } if (mAudioContextState == AudioContextState::Closed) { promise->MaybeResolve(NS_ERROR_DOM_INVALID_STATE_ERR); return promise.forget(); } mCloseCalled = true; if (Destination()) { Destination()->DestroyAudioChannelAgent(); } mPromiseGripArray.AppendElement(promise); // This can be called when freeing a document, and the streams are dead at // this point, so we need extra null-checks. MediaStream* ds = DestinationStream(); if (ds) { Graph()->ApplyAudioContextOperation(ds->AsAudioNodeStream(), AudioContextOperation::Close, promise); if (ds) { ds->BlockStreamIfNeeded(); } } return promise.forget(); }
void AudioNodeStream::ObtainInputBlock(AudioChunk& aTmpChunk, uint32_t aPortIndex) { uint32_t inputCount = mInputs.Length(); uint32_t outputChannelCount = 1; nsAutoTArray<AudioChunk*,250> inputChunks; for (uint32_t i = 0; i < inputCount; ++i) { if (aPortIndex != mInputs[i]->InputNumber()) { // This input is connected to a different port continue; } MediaStream* s = mInputs[i]->GetSource(); AudioNodeStream* a = static_cast<AudioNodeStream*>(s); MOZ_ASSERT(a == s->AsAudioNodeStream()); if (a->IsAudioParamStream()) { continue; } // It is possible for mLastChunks to be empty here, because `a` might be a // AudioNodeStream that has not been scheduled yet, because it is further // down the graph _but_ as a connection to this node. Because we enforce the // presence of at least one DelayNode, with at least one block of delay, and // because the output of a DelayNode when it has been fed less that // `delayTime` amount of audio is silence, we can simply continue here, // because this input would not influence the output of this node. Next // iteration, a->mLastChunks.IsEmpty() will be false, and everthing will // work as usual. if (a->mLastChunks.IsEmpty()) { continue; } AudioChunk* chunk = &a->mLastChunks[mInputs[i]->OutputNumber()]; MOZ_ASSERT(chunk); if (chunk->IsNull() || chunk->mChannelData.IsEmpty()) { continue; } inputChunks.AppendElement(chunk); outputChannelCount = GetAudioChannelsSuperset(outputChannelCount, chunk->mChannelData.Length()); } outputChannelCount = ComputedNumberOfChannels(outputChannelCount); uint32_t inputChunkCount = inputChunks.Length(); if (inputChunkCount == 0 || (inputChunkCount == 1 && inputChunks[0]->mChannelData.Length() == 0)) { aTmpChunk.SetNull(WEBAUDIO_BLOCK_SIZE); return; } if (inputChunkCount == 1 && inputChunks[0]->mChannelData.Length() == outputChannelCount) { aTmpChunk = *inputChunks[0]; return; } if (outputChannelCount == 0) { aTmpChunk.SetNull(WEBAUDIO_BLOCK_SIZE); return; } AllocateAudioBlock(outputChannelCount, &aTmpChunk); // The static storage here should be 1KB, so it's fine nsAutoTArray<float, GUESS_AUDIO_CHANNELS*WEBAUDIO_BLOCK_SIZE> downmixBuffer; for (uint32_t i = 0; i < inputChunkCount; ++i) { AccumulateInputChunk(i, *inputChunks[i], &aTmpChunk, &downmixBuffer); } }
AudioChunk* AudioNodeStream::ObtainInputBlock(AudioChunk* aTmpChunk) { uint32_t inputCount = mInputs.Length(); uint32_t outputChannelCount = 0; nsAutoTArray<AudioChunk*,250> inputChunks; for (uint32_t i = 0; i < inputCount; ++i) { MediaStream* s = mInputs[i]->GetSource(); AudioNodeStream* a = static_cast<AudioNodeStream*>(s); MOZ_ASSERT(a == s->AsAudioNodeStream()); if (a->IsFinishedOnGraphThread()) { continue; } AudioChunk* chunk = &a->mLastChunk; // XXX when we implement DelayNode, this will no longer be true and we'll // need to treat a null chunk (when the DelayNode hasn't had a chance // to produce data yet) as silence here. MOZ_ASSERT(chunk); if (chunk->IsNull()) { continue; } inputChunks.AppendElement(chunk); outputChannelCount = GetAudioChannelsSuperset(outputChannelCount, chunk->mChannelData.Length()); } uint32_t inputChunkCount = inputChunks.Length(); if (inputChunkCount == 0) { aTmpChunk->SetNull(WEBAUDIO_BLOCK_SIZE); return aTmpChunk; } if (inputChunkCount == 1) { return inputChunks[0]; } AllocateAudioBlock(outputChannelCount, aTmpChunk); for (uint32_t i = 0; i < inputChunkCount; ++i) { AudioChunk* chunk = inputChunks[i]; nsAutoTArray<const void*,GUESS_AUDIO_CHANNELS> channels; channels.AppendElements(chunk->mChannelData); if (channels.Length() < outputChannelCount) { AudioChannelsUpMix(&channels, outputChannelCount, nullptr); NS_ASSERTION(outputChannelCount == channels.Length(), "We called GetAudioChannelsSuperset to avoid this"); } for (uint32_t c = 0; c < channels.Length(); ++c) { const float* inputData = static_cast<const float*>(channels[c]); float* outputData = static_cast<float*>(const_cast<void*>(aTmpChunk->mChannelData[c])); if (inputData) { if (i == 0) { AudioBlockCopyChannelWithScale(inputData, chunk->mVolume, outputData); } else { AudioBlockAddChannelWithScale(inputData, chunk->mVolume, outputData); } } else { if (i == 0) { memset(outputData, 0, WEBAUDIO_BLOCK_SIZE*sizeof(float)); } } } } return aTmpChunk; }
void AudioNodeStream::ObtainInputBlock(AudioChunk& aTmpChunk, uint32_t aPortIndex) { uint32_t inputCount = mInputs.Length(); uint32_t outputChannelCount = 1; nsAutoTArray<AudioChunk*,250> inputChunks; for (uint32_t i = 0; i < inputCount; ++i) { if (aPortIndex != mInputs[i]->InputNumber()) { // This input is connected to a different port continue; } MediaStream* s = mInputs[i]->GetSource(); AudioNodeStream* a = static_cast<AudioNodeStream*>(s); MOZ_ASSERT(a == s->AsAudioNodeStream()); if (a->IsFinishedOnGraphThread() || a->IsAudioParamStream()) { continue; } AudioChunk* chunk = &a->mLastChunks[mInputs[i]->OutputNumber()]; MOZ_ASSERT(chunk); if (chunk->IsNull()) { continue; } inputChunks.AppendElement(chunk); outputChannelCount = GetAudioChannelsSuperset(outputChannelCount, chunk->mChannelData.Length()); } switch (mChannelCountMode) { case ChannelCountMode::Explicit: // Disregard the output channel count that we've calculated, and just use // mNumberOfInputChannels. outputChannelCount = mNumberOfInputChannels; break; case ChannelCountMode::Clamped_max: // Clamp the computed output channel count to mNumberOfInputChannels. outputChannelCount = std::min(outputChannelCount, mNumberOfInputChannels); break; case ChannelCountMode::Max: // Nothing to do here, just shut up the compiler warning. break; } uint32_t inputChunkCount = inputChunks.Length(); if (inputChunkCount == 0 || (inputChunkCount == 1 && inputChunks[0]->mChannelData.Length() == 0)) { aTmpChunk.SetNull(WEBAUDIO_BLOCK_SIZE); return; } if (inputChunkCount == 1 && inputChunks[0]->mChannelData.Length() == outputChannelCount) { aTmpChunk = *inputChunks[0]; return; } AllocateAudioBlock(outputChannelCount, &aTmpChunk); float silenceChannel[WEBAUDIO_BLOCK_SIZE] = {0.f}; // The static storage here should be 1KB, so it's fine nsAutoTArray<float, GUESS_AUDIO_CHANNELS*WEBAUDIO_BLOCK_SIZE> downmixBuffer; for (uint32_t i = 0; i < inputChunkCount; ++i) { AudioChunk* chunk = inputChunks[i]; nsAutoTArray<const void*,GUESS_AUDIO_CHANNELS> channels; channels.AppendElements(chunk->mChannelData); if (channels.Length() < outputChannelCount) { if (mChannelInterpretation == ChannelInterpretation::Speakers) { AudioChannelsUpMix(&channels, outputChannelCount, nullptr); NS_ASSERTION(outputChannelCount == channels.Length(), "We called GetAudioChannelsSuperset to avoid this"); } else { // Fill up the remaining channels by zeros for (uint32_t j = channels.Length(); j < outputChannelCount; ++j) { channels.AppendElement(silenceChannel); } } } else if (channels.Length() > outputChannelCount) { if (mChannelInterpretation == ChannelInterpretation::Speakers) { nsAutoTArray<float*,GUESS_AUDIO_CHANNELS> outputChannels; outputChannels.SetLength(outputChannelCount); downmixBuffer.SetLength(outputChannelCount * WEBAUDIO_BLOCK_SIZE); for (uint32_t j = 0; j < outputChannelCount; ++j) { outputChannels[j] = &downmixBuffer[j * WEBAUDIO_BLOCK_SIZE]; } AudioChannelsDownMix(channels, outputChannels.Elements(), outputChannelCount, WEBAUDIO_BLOCK_SIZE); channels.SetLength(outputChannelCount); for (uint32_t j = 0; j < channels.Length(); ++j) { channels[j] = outputChannels[j]; } } else { // Drop the remaining channels channels.RemoveElementsAt(outputChannelCount, channels.Length() - outputChannelCount); } } for (uint32_t c = 0; c < channels.Length(); ++c) { const float* inputData = static_cast<const float*>(channels[c]); float* outputData = static_cast<float*>(const_cast<void*>(aTmpChunk.mChannelData[c])); if (inputData) { if (i == 0) { AudioBlockCopyChannelWithScale(inputData, chunk->mVolume, outputData); } else { AudioBlockAddChannelWithScale(inputData, chunk->mVolume, outputData); } } else { if (i == 0) { memset(outputData, 0, WEBAUDIO_BLOCK_SIZE*sizeof(float)); } } } } }