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be74876e25
PrincipalHandle is a thread safe pointer to a holder of (the main-thread-only nsIPrincipal) that can be passed around the MSG. A MediaStreamTrack whose source has just updated its principal, sets the new principal aside (as its "pending principal"), and combines the new principal into its current principal. Then the source starts passing the new principal to the MediaStreamGraph as a PrincipalHandle. Changes to a track's PrincipalHandle on the MSG will be surfaced through the MediaStreamTrackListener API. These changes are dispatched to main thread and compared to a MediaStreamTrack's pending principal. In case of a match the track knows the correct principal is flowing and can move the pending principal to be the current principal and update any main thread principal observers. MozReview-Commit-ID: D0JXGWhQFFU --HG-- extra : rebase_source : 296e269bb46fc5a85a9c3f90dfc0dc40e53572bc
429 lines
15 KiB
C++
429 lines
15 KiB
C++
/* -*- Mode: C++; tab-width: 2; indent-tabs-mode: nil; c-basic-offset: 2 -*- */
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/* This Source Code Form is subject to the terms of the Mozilla Public
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* License, v. 2.0. If a copy of the MPL was not distributed with this file,
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* You can obtain one at http://mozilla.org/MPL/2.0/. */
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#ifndef MOZILLA_AUDIOSEGMENT_H_
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#define MOZILLA_AUDIOSEGMENT_H_
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#include "MediaSegment.h"
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#include "AudioSampleFormat.h"
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#include "AudioChannelFormat.h"
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#include "SharedBuffer.h"
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#include "WebAudioUtils.h"
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#ifdef MOZILLA_INTERNAL_API
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#include "mozilla/TimeStamp.h"
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#endif
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#include <float.h>
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namespace mozilla {
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template<typename T>
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class SharedChannelArrayBuffer : public ThreadSharedObject {
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public:
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explicit SharedChannelArrayBuffer(nsTArray<nsTArray<T> >* aBuffers)
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{
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mBuffers.SwapElements(*aBuffers);
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}
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size_t SizeOfExcludingThis(MallocSizeOf aMallocSizeOf) const override
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{
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size_t amount = 0;
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amount += mBuffers.ShallowSizeOfExcludingThis(aMallocSizeOf);
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for (size_t i = 0; i < mBuffers.Length(); i++) {
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amount += mBuffers[i].ShallowSizeOfExcludingThis(aMallocSizeOf);
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}
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return amount;
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}
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size_t SizeOfIncludingThis(MallocSizeOf aMallocSizeOf) const override
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{
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return aMallocSizeOf(this) + SizeOfExcludingThis(aMallocSizeOf);
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}
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nsTArray<nsTArray<T> > mBuffers;
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};
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class AudioMixer;
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/**
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* For auto-arrays etc, guess this as the common number of channels.
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*/
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const int GUESS_AUDIO_CHANNELS = 2;
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// We ensure that the graph advances in steps that are multiples of the Web
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// Audio block size
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const uint32_t WEBAUDIO_BLOCK_SIZE_BITS = 7;
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const uint32_t WEBAUDIO_BLOCK_SIZE = 1 << WEBAUDIO_BLOCK_SIZE_BITS;
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template <typename SrcT, typename DestT>
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static void
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InterleaveAndConvertBuffer(const SrcT* const* aSourceChannels,
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uint32_t aLength, float aVolume,
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uint32_t aChannels,
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DestT* aOutput)
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{
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DestT* output = aOutput;
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for (size_t i = 0; i < aLength; ++i) {
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for (size_t channel = 0; channel < aChannels; ++channel) {
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float v = AudioSampleToFloat(aSourceChannels[channel][i])*aVolume;
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*output = FloatToAudioSample<DestT>(v);
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++output;
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}
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}
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}
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template <typename SrcT, typename DestT>
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static void
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DeinterleaveAndConvertBuffer(const SrcT* aSourceBuffer,
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uint32_t aFrames, uint32_t aChannels,
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DestT** aOutput)
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{
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for (size_t i = 0; i < aChannels; i++) {
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size_t interleavedIndex = i;
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for (size_t j = 0; j < aFrames; j++) {
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ConvertAudioSample(aSourceBuffer[interleavedIndex],
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aOutput[i][j]);
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interleavedIndex += aChannels;
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}
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}
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}
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class SilentChannel
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{
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public:
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static const int AUDIO_PROCESSING_FRAMES = 640; /* > 10ms of 48KHz audio */
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static const uint8_t gZeroChannel[MAX_AUDIO_SAMPLE_SIZE*AUDIO_PROCESSING_FRAMES];
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// We take advantage of the fact that zero in float and zero in int have the
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// same all-zeros bit layout.
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template<typename T>
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static const T* ZeroChannel();
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};
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/**
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* Given an array of input channels (aChannelData), downmix to aOutputChannels,
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* interleave the channel data. A total of aOutputChannels*aDuration
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* interleaved samples will be copied to a channel buffer in aOutput.
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*/
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template <typename SrcT, typename DestT>
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void
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DownmixAndInterleave(const nsTArray<const SrcT*>& aChannelData,
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int32_t aDuration, float aVolume, uint32_t aOutputChannels,
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DestT* aOutput)
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{
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if (aChannelData.Length() == aOutputChannels) {
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InterleaveAndConvertBuffer(aChannelData.Elements(),
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aDuration, aVolume, aOutputChannels, aOutput);
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} else {
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AutoTArray<SrcT*,GUESS_AUDIO_CHANNELS> outputChannelData;
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AutoTArray<SrcT, SilentChannel::AUDIO_PROCESSING_FRAMES * GUESS_AUDIO_CHANNELS> outputBuffers;
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outputChannelData.SetLength(aOutputChannels);
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outputBuffers.SetLength(aDuration * aOutputChannels);
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for (uint32_t i = 0; i < aOutputChannels; i++) {
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outputChannelData[i] = outputBuffers.Elements() + aDuration * i;
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}
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AudioChannelsDownMix(aChannelData,
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outputChannelData.Elements(),
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aOutputChannels,
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aDuration);
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InterleaveAndConvertBuffer(outputChannelData.Elements(),
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aDuration, aVolume, aOutputChannels, aOutput);
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}
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}
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/**
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* An AudioChunk represents a multi-channel buffer of audio samples.
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* It references an underlying ThreadSharedObject which manages the lifetime
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* of the buffer. An AudioChunk maintains its own duration and channel data
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* pointers so it can represent a subinterval of a buffer without copying.
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* An AudioChunk can store its individual channels anywhere; it maintains
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* separate pointers to each channel's buffer.
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*/
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struct AudioChunk {
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typedef mozilla::AudioSampleFormat SampleFormat;
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AudioChunk() : mPrincipalHandle(PRINCIPAL_HANDLE_NONE) {}
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// Generic methods
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void SliceTo(StreamTime aStart, StreamTime aEnd)
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{
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MOZ_ASSERT(aStart >= 0 && aStart < aEnd && aEnd <= mDuration,
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"Slice out of bounds");
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if (mBuffer) {
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MOZ_ASSERT(aStart < INT32_MAX, "Can't slice beyond 32-bit sample lengths");
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for (uint32_t channel = 0; channel < mChannelData.Length(); ++channel) {
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mChannelData[channel] = AddAudioSampleOffset(mChannelData[channel],
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mBufferFormat, int32_t(aStart));
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}
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}
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mDuration = aEnd - aStart;
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}
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StreamTime GetDuration() const { return mDuration; }
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bool CanCombineWithFollowing(const AudioChunk& aOther) const
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{
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if (aOther.mBuffer != mBuffer) {
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return false;
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}
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if (mBuffer) {
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NS_ASSERTION(aOther.mBufferFormat == mBufferFormat,
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"Wrong metadata about buffer");
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NS_ASSERTION(aOther.mChannelData.Length() == mChannelData.Length(),
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"Mismatched channel count");
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if (mDuration > INT32_MAX) {
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return false;
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}
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for (uint32_t channel = 0; channel < mChannelData.Length(); ++channel) {
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if (aOther.mChannelData[channel] != AddAudioSampleOffset(mChannelData[channel],
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mBufferFormat, int32_t(mDuration))) {
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return false;
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}
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}
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}
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return true;
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}
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bool IsNull() const { return mBuffer == nullptr; }
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void SetNull(StreamTime aDuration)
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{
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mBuffer = nullptr;
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mChannelData.Clear();
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mDuration = aDuration;
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mVolume = 1.0f;
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mBufferFormat = AUDIO_FORMAT_SILENCE;
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mPrincipalHandle = PRINCIPAL_HANDLE_NONE;
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}
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size_t ChannelCount() const { return mChannelData.Length(); }
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bool IsMuted() const { return mVolume == 0.0f; }
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size_t SizeOfExcludingThisIfUnshared(MallocSizeOf aMallocSizeOf) const
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{
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return SizeOfExcludingThis(aMallocSizeOf, true);
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}
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size_t SizeOfExcludingThis(MallocSizeOf aMallocSizeOf, bool aUnshared) const
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{
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size_t amount = 0;
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// Possibly owned:
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// - mBuffer - Can hold data that is also in the decoded audio queue. If it
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// is not shared, or unshared == false it gets counted.
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if (mBuffer && (!aUnshared || !mBuffer->IsShared())) {
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amount += mBuffer->SizeOfIncludingThis(aMallocSizeOf);
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}
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// Memory in the array is owned by mBuffer.
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amount += mChannelData.ShallowSizeOfExcludingThis(aMallocSizeOf);
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return amount;
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}
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template<typename T>
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const nsTArray<const T*>& ChannelData()
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{
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MOZ_ASSERT(AudioSampleTypeToFormat<T>::Format == mBufferFormat);
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return *reinterpret_cast<nsTArray<const T*>*>(&mChannelData);
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}
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PrincipalHandle GetPrincipalHandle() const { return mPrincipalHandle; }
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StreamTime mDuration; // in frames within the buffer
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RefPtr<ThreadSharedObject> mBuffer; // the buffer object whose lifetime is managed; null means data is all zeroes
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nsTArray<const void*> mChannelData; // one pointer per channel; empty if and only if mBuffer is null
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float mVolume; // volume multiplier to apply (1.0f if mBuffer is nonnull)
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SampleFormat mBufferFormat; // format of frames in mBuffer (only meaningful if mBuffer is nonnull)
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#ifdef MOZILLA_INTERNAL_API
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mozilla::TimeStamp mTimeStamp; // time at which this has been fetched from the MediaEngine
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#endif
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// principalHandle for the data in this chunk.
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// This can be compared to an nsIPrincipal* when back on main thread.
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PrincipalHandle mPrincipalHandle;
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};
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/**
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* A list of audio samples consisting of a sequence of slices of SharedBuffers.
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* The audio rate is determined by the track, not stored in this class.
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*/
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class AudioSegment : public MediaSegmentBase<AudioSegment, AudioChunk> {
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public:
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typedef mozilla::AudioSampleFormat SampleFormat;
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AudioSegment() : MediaSegmentBase<AudioSegment, AudioChunk>(AUDIO) {}
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// Resample the whole segment in place.
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template<typename T>
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void Resample(SpeexResamplerState* aResampler, uint32_t aInRate, uint32_t aOutRate)
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{
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mDuration = 0;
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#ifdef DEBUG
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uint32_t segmentChannelCount = ChannelCount();
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#endif
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for (ChunkIterator ci(*this); !ci.IsEnded(); ci.Next()) {
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AutoTArray<nsTArray<T>, GUESS_AUDIO_CHANNELS> output;
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AutoTArray<const T*, GUESS_AUDIO_CHANNELS> bufferPtrs;
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AudioChunk& c = *ci;
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// If this chunk is null, don't bother resampling, just alter its duration
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if (c.IsNull()) {
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c.mDuration = (c.mDuration * aOutRate) / aInRate;
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mDuration += c.mDuration;
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continue;
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}
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uint32_t channels = c.mChannelData.Length();
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MOZ_ASSERT(channels == segmentChannelCount);
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output.SetLength(channels);
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bufferPtrs.SetLength(channels);
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uint32_t inFrames = c.mDuration;
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// Round up to allocate; the last frame may not be used.
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NS_ASSERTION((UINT32_MAX - aInRate + 1) / c.mDuration >= aOutRate,
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"Dropping samples");
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uint32_t outSize = (c.mDuration * aOutRate + aInRate - 1) / aInRate;
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for (uint32_t i = 0; i < channels; i++) {
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T* out = output[i].AppendElements(outSize);
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uint32_t outFrames = outSize;
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const T* in = static_cast<const T*>(c.mChannelData[i]);
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dom::WebAudioUtils::SpeexResamplerProcess(aResampler, i,
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in, &inFrames,
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out, &outFrames);
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MOZ_ASSERT(inFrames == c.mDuration);
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bufferPtrs[i] = out;
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output[i].SetLength(outFrames);
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}
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MOZ_ASSERT(channels > 0);
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c.mDuration = output[0].Length();
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c.mBuffer = new mozilla::SharedChannelArrayBuffer<T>(&output);
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for (uint32_t i = 0; i < channels; i++) {
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c.mChannelData[i] = bufferPtrs[i];
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}
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mDuration += c.mDuration;
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}
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}
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void ResampleChunks(SpeexResamplerState* aResampler,
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uint32_t aInRate,
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uint32_t aOutRate);
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void AppendFrames(already_AddRefed<ThreadSharedObject> aBuffer,
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const nsTArray<const float*>& aChannelData,
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int32_t aDuration, const PrincipalHandle& aPrincipalHandle)
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{
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AudioChunk* chunk = AppendChunk(aDuration);
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chunk->mBuffer = aBuffer;
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for (uint32_t channel = 0; channel < aChannelData.Length(); ++channel) {
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chunk->mChannelData.AppendElement(aChannelData[channel]);
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}
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chunk->mVolume = 1.0f;
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chunk->mBufferFormat = AUDIO_FORMAT_FLOAT32;
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#ifdef MOZILLA_INTERNAL_API
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chunk->mTimeStamp = TimeStamp::Now();
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#endif
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chunk->mPrincipalHandle = aPrincipalHandle;
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}
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void AppendFrames(already_AddRefed<ThreadSharedObject> aBuffer,
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const nsTArray<const int16_t*>& aChannelData,
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int32_t aDuration, const PrincipalHandle& aPrincipalHandle)
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{
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AudioChunk* chunk = AppendChunk(aDuration);
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chunk->mBuffer = aBuffer;
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for (uint32_t channel = 0; channel < aChannelData.Length(); ++channel) {
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chunk->mChannelData.AppendElement(aChannelData[channel]);
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}
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chunk->mVolume = 1.0f;
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chunk->mBufferFormat = AUDIO_FORMAT_S16;
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#ifdef MOZILLA_INTERNAL_API
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chunk->mTimeStamp = TimeStamp::Now();
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#endif
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chunk->mPrincipalHandle = aPrincipalHandle;
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}
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// Consumes aChunk, and returns a pointer to the persistent copy of aChunk
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// in the segment.
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AudioChunk* AppendAndConsumeChunk(AudioChunk* aChunk)
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{
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AudioChunk* chunk = AppendChunk(aChunk->mDuration);
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chunk->mBuffer = aChunk->mBuffer.forget();
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chunk->mChannelData.SwapElements(aChunk->mChannelData);
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chunk->mVolume = aChunk->mVolume;
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chunk->mBufferFormat = aChunk->mBufferFormat;
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#ifdef MOZILLA_INTERNAL_API
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chunk->mTimeStamp = TimeStamp::Now();
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#endif
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chunk->mPrincipalHandle = aChunk->mPrincipalHandle;
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return chunk;
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}
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void ApplyVolume(float aVolume);
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// Mix the segment into a mixer, interleaved. This is useful to output a
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// segment to a system audio callback. It up or down mixes to aChannelCount
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// channels.
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void WriteTo(uint64_t aID, AudioMixer& aMixer, uint32_t aChannelCount,
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uint32_t aSampleRate);
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// Mix the segment into a mixer, keeping it planar, up or down mixing to
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// aChannelCount channels.
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void Mix(AudioMixer& aMixer, uint32_t aChannelCount, uint32_t aSampleRate);
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int ChannelCount() {
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NS_WARN_IF_FALSE(!mChunks.IsEmpty(),
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"Cannot query channel count on a AudioSegment with no chunks.");
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// Find the first chunk that has non-zero channels. A chunk that hs zero
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// channels is just silence and we can simply discard it.
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for (ChunkIterator ci(*this); !ci.IsEnded(); ci.Next()) {
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if (ci->ChannelCount()) {
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return ci->ChannelCount();
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}
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}
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return 0;
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}
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bool IsNull() const {
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for (ChunkIterator ci(*const_cast<AudioSegment*>(this)); !ci.IsEnded();
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ci.Next()) {
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if (!ci->IsNull()) {
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return false;
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}
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}
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return true;
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}
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static Type StaticType() { return AUDIO; }
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size_t SizeOfIncludingThis(MallocSizeOf aMallocSizeOf) const override
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{
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return aMallocSizeOf(this) + SizeOfExcludingThis(aMallocSizeOf);
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}
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};
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template<typename SrcT>
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void WriteChunk(AudioChunk& aChunk,
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uint32_t aOutputChannels,
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AudioDataValue* aOutputBuffer)
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{
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AutoTArray<const SrcT*,GUESS_AUDIO_CHANNELS> channelData;
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channelData = aChunk.ChannelData<SrcT>();
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if (channelData.Length() < aOutputChannels) {
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// Up-mix. Note that this might actually make channelData have more
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// than aOutputChannels temporarily.
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AudioChannelsUpMix(&channelData, aOutputChannels, SilentChannel::ZeroChannel<SrcT>());
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}
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if (channelData.Length() > aOutputChannels) {
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// Down-mix.
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DownmixAndInterleave(channelData, aChunk.mDuration,
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aChunk.mVolume, aOutputChannels, aOutputBuffer);
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} else {
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InterleaveAndConvertBuffer(channelData.Elements(),
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aChunk.mDuration, aChunk.mVolume,
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aOutputChannels,
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aOutputBuffer);
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}
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}
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} // namespace mozilla
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#endif /* MOZILLA_AUDIOSEGMENT_H_ */
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