gecko-dev/content/media/webaudio/AudioBufferSourceNode.cpp
Ehsan Akhgari 1811db3407 Bug 873553 - Part 5: Port AudioBufferSourceNodeEngine to use the stream's sampling rate; r=roc
--HG--
extra : rebase_source : 13d1133fb34d3695eece432047b719b456961610
2013-05-24 13:13:31 -04:00

676 lines
24 KiB
C++

/* -*- 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 "AudioBufferSourceNode.h"
#include "mozilla/dom/AudioBufferSourceNodeBinding.h"
#include "nsMathUtils.h"
#include "AudioNodeEngine.h"
#include "PannerNode.h"
#include "GainProcessor.h"
#include "speex/speex_resampler.h"
#include <limits>
namespace mozilla {
namespace dom {
NS_IMPL_CYCLE_COLLECTION_UNLINK_BEGIN(AudioBufferSourceNode)
NS_IMPL_CYCLE_COLLECTION_UNLINK(mBuffer)
NS_IMPL_CYCLE_COLLECTION_UNLINK(mPlaybackRate)
NS_IMPL_CYCLE_COLLECTION_UNLINK(mGain)
if (tmp->Context()) {
// AudioNode's Unlink implementation disconnects us from the graph
// too, but we need to do this right here to make sure that
// UnregisterAudioBufferSourceNode can properly untangle us from
// the possibly connected PannerNodes.
tmp->DisconnectFromGraph();
tmp->Context()->UnregisterAudioBufferSourceNode(tmp);
}
NS_IMPL_CYCLE_COLLECTION_UNLINK_END_INHERITED(AudioNode)
NS_IMPL_CYCLE_COLLECTION_TRAVERSE_BEGIN_INHERITED(AudioBufferSourceNode, AudioNode)
NS_IMPL_CYCLE_COLLECTION_TRAVERSE(mBuffer)
NS_IMPL_CYCLE_COLLECTION_TRAVERSE(mPlaybackRate)
NS_IMPL_CYCLE_COLLECTION_TRAVERSE(mGain)
NS_IMPL_CYCLE_COLLECTION_TRAVERSE_END
NS_INTERFACE_MAP_BEGIN_CYCLE_COLLECTION_INHERITED(AudioBufferSourceNode)
NS_INTERFACE_MAP_END_INHERITING(AudioNode)
NS_IMPL_ADDREF_INHERITED(AudioBufferSourceNode, AudioNode)
NS_IMPL_RELEASE_INHERITED(AudioBufferSourceNode, AudioNode)
class AudioBufferSourceNodeEngine : public AudioNodeEngine,
public GainProcessor
{
public:
explicit AudioBufferSourceNodeEngine(AudioNode* aNode,
AudioDestinationNode* aDestination) :
AudioNodeEngine(aNode),
GainProcessor(aDestination),
mStart(0), mStop(TRACK_TICKS_MAX),
mResampler(nullptr),
mOffset(0), mDuration(0),
mLoopStart(0), mLoopEnd(0),
mBufferSampleRate(0), mPosition(0), mChannels(0), mPlaybackRate(1.0f),
mDopplerShift(1.0f),
mPlaybackRateTimeline(1.0f), mLoop(false)
{}
~AudioBufferSourceNodeEngine()
{
if (mResampler) {
speex_resampler_destroy(mResampler);
}
}
virtual void SetTimelineParameter(uint32_t aIndex,
const dom::AudioParamTimeline& aValue,
TrackRate aSampleRate) MOZ_OVERRIDE
{
switch (aIndex) {
case AudioBufferSourceNode::PLAYBACKRATE:
mPlaybackRateTimeline = aValue;
// If we have a simple value that is 1.0 (i.e. intrinsic speed), and our
// input buffer is already at the ideal audio rate, and we have a
// resampler, we can release it.
if (mResampler && mPlaybackRateTimeline.HasSimpleValue() &&
mPlaybackRateTimeline.GetValue() == 1.0 &&
mBufferSampleRate == aSampleRate) {
speex_resampler_destroy(mResampler);
mResampler = nullptr;
}
WebAudioUtils::ConvertAudioParamToTicks(mPlaybackRateTimeline, nullptr, mDestination);
break;
case AudioBufferSourceNode::GAIN:
SetGainParameter(aValue);
break;
default:
NS_ERROR("Bad AudioBufferSourceNodeEngine TimelineParameter");
}
}
virtual void SetStreamTimeParameter(uint32_t aIndex, TrackTicks aParam)
{
switch (aIndex) {
case AudioBufferSourceNode::START: mStart = aParam; break;
case AudioBufferSourceNode::STOP: mStop = aParam; break;
default:
NS_ERROR("Bad AudioBufferSourceNodeEngine StreamTimeParameter");
}
}
virtual void SetDoubleParameter(uint32_t aIndex, double aParam)
{
switch (aIndex) {
case AudioBufferSourceNode::DOPPLERSHIFT:
mDopplerShift = aParam;
break;
default:
NS_ERROR("Bad AudioBufferSourceNodeEngine double parameter.");
};
}
virtual void SetInt32Parameter(uint32_t aIndex, int32_t aParam)
{
switch (aIndex) {
case AudioBufferSourceNode::SAMPLE_RATE: mBufferSampleRate = aParam; break;
case AudioBufferSourceNode::OFFSET: mOffset = aParam; break;
case AudioBufferSourceNode::DURATION: mDuration = aParam; break;
case AudioBufferSourceNode::LOOP: mLoop = !!aParam; break;
case AudioBufferSourceNode::LOOPSTART: mLoopStart = aParam; break;
case AudioBufferSourceNode::LOOPEND: mLoopEnd = aParam; break;
default:
NS_ERROR("Bad AudioBufferSourceNodeEngine Int32Parameter");
}
}
virtual void SetBuffer(already_AddRefed<ThreadSharedFloatArrayBufferList> aBuffer)
{
mBuffer = aBuffer;
}
SpeexResamplerState* Resampler(AudioNodeStream* aStream, uint32_t aChannels)
{
if (aChannels != mChannels && mResampler) {
speex_resampler_destroy(mResampler);
mResampler = nullptr;
}
if (!mResampler) {
mChannels = aChannels;
mResampler = speex_resampler_init(mChannels, mBufferSampleRate,
ComputeFinalOutSampleRate(aStream->SampleRate()),
SPEEX_RESAMPLER_QUALITY_DEFAULT,
nullptr);
}
return mResampler;
}
// Borrow a full buffer of size WEBAUDIO_BLOCK_SIZE from the source buffer
// at offset aSourceOffset. This avoids copying memory.
void BorrowFromInputBuffer(AudioChunk* aOutput,
uint32_t aChannels,
uintptr_t aSourceOffset)
{
aOutput->mDuration = WEBAUDIO_BLOCK_SIZE;
aOutput->mBuffer = mBuffer;
aOutput->mChannelData.SetLength(aChannels);
for (uint32_t i = 0; i < aChannels; ++i) {
aOutput->mChannelData[i] = mBuffer->GetData(i) + aSourceOffset;
}
aOutput->mVolume = 1.0f;
aOutput->mBufferFormat = AUDIO_FORMAT_FLOAT32;
}
// Copy aNumberOfFrames frames from the source buffer at offset aSourceOffset
// and put it at offset aBufferOffset in the destination buffer.
void CopyFromInputBuffer(AudioChunk* aOutput,
uint32_t aChannels,
uintptr_t aSourceOffset,
uintptr_t aBufferOffset,
uint32_t aNumberOfFrames) {
for (uint32_t i = 0; i < aChannels; ++i) {
float* baseChannelData = static_cast<float*>(const_cast<void*>(aOutput->mChannelData[i]));
memcpy(baseChannelData + aBufferOffset,
mBuffer->GetData(i) + aSourceOffset,
aNumberOfFrames * sizeof(float));
}
}
// Resamples input data to an output buffer, according to |mBufferSampleRate| and
// the playbackRate.
// The number of frames consumed/produced depends on the amount of space
// remaining in both the input and output buffer, and the playback rate (that
// is, the ratio between the output samplerate and the input samplerate).
void CopyFromInputBufferWithResampling(AudioNodeStream* aStream,
AudioChunk* aOutput,
uint32_t aChannels,
uintptr_t aSourceOffset,
uintptr_t aBufferOffset,
uint32_t aAvailableInInputBuffer,
uint32_t& aFramesRead,
uint32_t& aFramesWritten) {
double finalPlaybackRate =
static_cast<double>(mBufferSampleRate) / ComputeFinalOutSampleRate(aStream->SampleRate());
uint32_t availableInOuputBuffer = WEBAUDIO_BLOCK_SIZE - aBufferOffset;
uint32_t inputSamples, outputSamples;
// Check if we are short on input or output buffer.
if (aAvailableInInputBuffer < availableInOuputBuffer * finalPlaybackRate) {
outputSamples = ceil(aAvailableInInputBuffer / finalPlaybackRate);
inputSamples = aAvailableInInputBuffer;
} else {
inputSamples = ceil(availableInOuputBuffer * finalPlaybackRate);
outputSamples = availableInOuputBuffer;
}
SpeexResamplerState* resampler = Resampler(aStream, aChannels);
for (uint32_t i = 0; i < aChannels; ++i) {
uint32_t inSamples = inputSamples;
uint32_t outSamples = outputSamples;
const float* inputData = mBuffer->GetData(i) + aSourceOffset;
float* outputData =
static_cast<float*>(const_cast<void*>(aOutput->mChannelData[i])) +
aBufferOffset;
speex_resampler_process_float(resampler, i,
inputData, &inSamples,
outputData, &outSamples);
aFramesRead = inSamples;
aFramesWritten = outSamples;
}
}
/**
* Fill aOutput with as many zero frames as we can, and advance
* aOffsetWithinBlock and aCurrentPosition based on how many frames we write.
* This will never advance aOffsetWithinBlock past WEBAUDIO_BLOCK_SIZE or
* aCurrentPosition past aMaxPos. This function knows when it needs to
* allocate the output buffer, and also optimizes the case where it can avoid
* memory allocations.
*/
void FillWithZeroes(AudioChunk* aOutput,
uint32_t aChannels,
uint32_t* aOffsetWithinBlock,
TrackTicks* aCurrentPosition,
TrackTicks aMaxPos)
{
uint32_t numFrames = std::min(WEBAUDIO_BLOCK_SIZE - *aOffsetWithinBlock,
uint32_t(aMaxPos - *aCurrentPosition));
if (numFrames == WEBAUDIO_BLOCK_SIZE) {
aOutput->SetNull(numFrames);
} else {
if (aOutput->IsNull()) {
AllocateAudioBlock(aChannels, aOutput);
}
WriteZeroesToAudioBlock(aOutput, *aOffsetWithinBlock, numFrames);
}
*aOffsetWithinBlock += numFrames;
*aCurrentPosition += numFrames;
}
/**
* Copy as many frames as possible from the source buffer to aOutput, and
* advance aOffsetWithinBlock and aCurrentPosition based on how many frames
* we copy. This will never advance aOffsetWithinBlock past
* WEBAUDIO_BLOCK_SIZE, or aCurrentPosition past mStop. It takes data from
* the buffer at aBufferOffset, and never takes more data than aBufferMax.
* This function knows when it needs to allocate the output buffer, and also
* optimizes the case where it can avoid memory allocations.
*/
void CopyFromBuffer(AudioNodeStream* aStream,
AudioChunk* aOutput,
uint32_t aChannels,
uint32_t* aOffsetWithinBlock,
TrackTicks* aCurrentPosition,
uint32_t aBufferOffset,
uint32_t aBufferMax)
{
uint32_t numFrames = std::min(std::min(WEBAUDIO_BLOCK_SIZE - *aOffsetWithinBlock,
aBufferMax - aBufferOffset),
uint32_t(mStop - *aCurrentPosition));
if (numFrames == WEBAUDIO_BLOCK_SIZE && !ShouldResample(aStream->SampleRate())) {
BorrowFromInputBuffer(aOutput, aChannels, aBufferOffset);
*aOffsetWithinBlock += numFrames;
*aCurrentPosition += numFrames;
mPosition += numFrames;
} else {
if (aOutput->IsNull()) {
MOZ_ASSERT(*aOffsetWithinBlock == 0);
AllocateAudioBlock(aChannels, aOutput);
}
if (!ShouldResample(aStream->SampleRate())) {
CopyFromInputBuffer(aOutput, aChannels, aBufferOffset, *aOffsetWithinBlock, numFrames);
*aOffsetWithinBlock += numFrames;
*aCurrentPosition += numFrames;
mPosition += numFrames;
} else {
uint32_t framesRead, framesWritten, availableInInputBuffer;
availableInInputBuffer = aBufferMax - aBufferOffset;
CopyFromInputBufferWithResampling(aStream, aOutput, aChannels, aBufferOffset, *aOffsetWithinBlock, availableInInputBuffer, framesRead, framesWritten);
*aOffsetWithinBlock += framesWritten;
*aCurrentPosition += framesRead;
mPosition += framesRead;
}
}
}
TrackTicks GetPosition(AudioNodeStream* aStream)
{
if (aStream->GetCurrentPosition() < mStart) {
return aStream->GetCurrentPosition();
}
return mStart + mPosition;
}
uint32_t ComputeFinalOutSampleRate(TrackRate aStreamSampleRate)
{
if (mPlaybackRate <= 0 || mPlaybackRate != mPlaybackRate) {
mPlaybackRate = 1.0f;
}
if (mDopplerShift <= 0 || mDopplerShift != mDopplerShift) {
mDopplerShift = 1.0f;
}
return WebAudioUtils::TruncateFloatToInt<uint32_t>(aStreamSampleRate /
(mPlaybackRate * mDopplerShift));
}
bool ShouldResample(TrackRate aStreamSampleRate) const
{
return !(mPlaybackRate == 1.0 &&
mDopplerShift == 1.0 &&
mBufferSampleRate == aStreamSampleRate);
}
void UpdateSampleRateIfNeeded(AudioNodeStream* aStream, uint32_t aChannels)
{
if (mPlaybackRateTimeline.HasSimpleValue()) {
mPlaybackRate = mPlaybackRateTimeline.GetValue();
} else {
mPlaybackRate = mPlaybackRateTimeline.GetValueAtTime(aStream->GetCurrentPosition());
}
// Make sure the playback rate and the doppler shift are something
// our resampler can work with.
if (ComputeFinalOutSampleRate(aStream->SampleRate()) == 0) {
mPlaybackRate = 1.0;
mDopplerShift = 1.0;
}
uint32_t currentOutSampleRate, currentInSampleRate;
if (ShouldResample(aStream->SampleRate())) {
SpeexResamplerState* resampler = Resampler(aStream, aChannels);
speex_resampler_get_rate(resampler, &currentInSampleRate, &currentOutSampleRate);
uint32_t finalSampleRate = ComputeFinalOutSampleRate(aStream->SampleRate());
if (currentOutSampleRate != finalSampleRate) {
speex_resampler_set_rate(resampler, currentInSampleRate, finalSampleRate);
speex_resampler_skip_zeros(mResampler);
}
}
}
virtual void ProduceAudioBlock(AudioNodeStream* aStream,
const AudioChunk& aInput,
AudioChunk* aOutput,
bool* aFinished)
{
if (!mBuffer)
return;
uint32_t channels = mBuffer->GetChannels();
if (!channels) {
aOutput->SetNull(WEBAUDIO_BLOCK_SIZE);
return;
}
// WebKit treats the playbackRate as a k-rate parameter in their code,
// despite the spec saying that it should be an a-rate parameter. We treat
// it as k-rate. Spec bug: https://www.w3.org/Bugs/Public/show_bug.cgi?id=21592
UpdateSampleRateIfNeeded(aStream, channels);
uint32_t written = 0;
TrackTicks currentPosition = GetPosition(aStream);
while (written < WEBAUDIO_BLOCK_SIZE) {
if (mStop != TRACK_TICKS_MAX &&
currentPosition >= mStop) {
FillWithZeroes(aOutput, channels, &written, &currentPosition, TRACK_TICKS_MAX);
continue;
}
if (currentPosition < mStart) {
FillWithZeroes(aOutput, channels, &written, &currentPosition, mStart);
continue;
}
TrackTicks t = currentPosition - mStart;
if (mLoop) {
if (mOffset + t < mLoopEnd) {
CopyFromBuffer(aStream, aOutput, channels, &written, &currentPosition, mOffset + t, mLoopEnd);
} else {
uint32_t offsetInLoop = (mOffset + t - mLoopEnd) % (mLoopEnd - mLoopStart);
CopyFromBuffer(aStream, aOutput, channels, &written, &currentPosition, mLoopStart + offsetInLoop, mLoopEnd);
}
} else {
if (mOffset + t < mDuration) {
CopyFromBuffer(aStream, aOutput, channels, &written, &currentPosition, mOffset + t, mDuration);
} else {
FillWithZeroes(aOutput, channels, &written, &currentPosition, TRACK_TICKS_MAX);
}
}
}
// Process the gain on the AudioBufferSourceNode
if (!aOutput->IsNull()) {
if (!mGain.HasSimpleValue() &&
aOutput->mBuffer == mBuffer) {
// If we have borrowed out buffer, make sure to allocate a new one in case
// the gain value is not a simple value.
nsTArray<const void*> oldChannels;
oldChannels.AppendElements(aOutput->mChannelData);
AllocateAudioBlock(channels, aOutput);
ProcessGain(aStream, 1.0f, oldChannels, aOutput);
} else {
ProcessGain(aStream, 1.0f, aOutput->mChannelData, aOutput);
}
}
// We've finished if we've gone past mStop, or if we're past mDuration when
// looping is disabled.
if (currentPosition >= mStop ||
(!mLoop && currentPosition - mStart + mOffset > mDuration)) {
*aFinished = true;
}
}
TrackTicks mStart;
TrackTicks mStop;
nsRefPtr<ThreadSharedFloatArrayBufferList> mBuffer;
SpeexResamplerState* mResampler;
int32_t mOffset;
int32_t mDuration;
int32_t mLoopStart;
int32_t mLoopEnd;
int32_t mBufferSampleRate;
uint32_t mPosition;
uint32_t mChannels;
float mPlaybackRate;
float mDopplerShift;
AudioParamTimeline mPlaybackRateTimeline;
bool mLoop;
};
AudioBufferSourceNode::AudioBufferSourceNode(AudioContext* aContext)
: AudioNode(aContext,
2,
ChannelCountMode::Max,
ChannelInterpretation::Speakers)
, mLoopStart(0.0)
, mLoopEnd(0.0)
, mOffset(0.0)
, mDuration(std::numeric_limits<double>::min())
, mPlaybackRate(new AudioParam(this, SendPlaybackRateToStream, 1.0f))
, mGain(new AudioParam(this, SendGainToStream, 1.0f))
, mLoop(false)
, mStartCalled(false)
, mStopped(false)
{
AudioBufferSourceNodeEngine* engine =
new AudioBufferSourceNodeEngine(this, aContext->Destination());
mStream = aContext->Graph()->CreateAudioNodeStream(engine, MediaStreamGraph::INTERNAL_STREAM);
engine->SetSourceStream(static_cast<AudioNodeStream*> (mStream.get()));
mStream->AddMainThreadListener(this);
}
AudioBufferSourceNode::~AudioBufferSourceNode()
{
if (Context()) {
Context()->UnregisterAudioBufferSourceNode(this);
}
}
JSObject*
AudioBufferSourceNode::WrapObject(JSContext* aCx, JS::Handle<JSObject*> aScope)
{
return AudioBufferSourceNodeBinding::Wrap(aCx, aScope, this);
}
void
AudioBufferSourceNode::Start(double aWhen, double aOffset,
const Optional<double>& aDuration, ErrorResult& aRv)
{
if (mStartCalled) {
aRv.Throw(NS_ERROR_DOM_INVALID_STATE_ERR);
return;
}
mStartCalled = true;
AudioNodeStream* ns = static_cast<AudioNodeStream*>(mStream.get());
if (!ns) {
// Nothing to play, or we're already dead for some reason
return;
}
if (mBuffer) {
double duration = aDuration.WasPassed() ?
aDuration.Value() :
std::numeric_limits<double>::min();
SendOffsetAndDurationParametersToStream(ns, aOffset, duration);
} else {
// Remember our arguments so that we can use them once we have a buffer
mOffset = aOffset;
mDuration = aDuration.WasPassed() ?
aDuration.Value() :
std::numeric_limits<double>::min();
}
// Don't set parameter unnecessarily
if (aWhen > 0.0) {
ns->SetStreamTimeParameter(START, Context()->DestinationStream(), aWhen);
}
MOZ_ASSERT(!mPlayingRef, "We can only accept a successful start() call once");
mPlayingRef.Take(this);
}
void
AudioBufferSourceNode::SendBufferParameterToStream(JSContext* aCx)
{
AudioNodeStream* ns = static_cast<AudioNodeStream*>(mStream.get());
MOZ_ASSERT(ns, "Why don't we have a stream here?");
if (mBuffer) {
float rate = mBuffer->SampleRate();
nsRefPtr<ThreadSharedFloatArrayBufferList> data =
mBuffer->GetThreadSharedChannelsForRate(aCx);
ns->SetBuffer(data.forget());
ns->SetInt32Parameter(SAMPLE_RATE, rate);
} else {
ns->SetBuffer(nullptr);
}
SendOffsetAndDurationParametersToStream(ns, mOffset, mDuration);
}
void
AudioBufferSourceNode::SendOffsetAndDurationParametersToStream(AudioNodeStream* aStream,
double aOffset,
double aDuration)
{
float rate = mBuffer ? mBuffer->SampleRate() : Context()->SampleRate();
int32_t lengthSamples = mBuffer ? mBuffer->Length() : 0;
double length = double(lengthSamples) / rate;
double offset = std::max(0.0, aOffset);
double endOffset = aDuration == std::numeric_limits<double>::min() ?
length : std::min(aOffset + aDuration, length);
if (offset >= endOffset) {
// The offset falls past the end of the buffer. In this case, we need to
// stop the playback immediately if it's in progress. No need to check
// mStartCalled here, since Stop() does that for us.
ErrorResult rv;
Stop(0.0, rv);
return;
}
int32_t offsetTicks = NS_lround(offset*rate);
// Don't set parameter unnecessarily
if (offsetTicks > 0) {
aStream->SetInt32Parameter(OFFSET, offsetTicks);
}
aStream->SetInt32Parameter(DURATION, NS_lround(endOffset*rate) - offsetTicks);
}
void
AudioBufferSourceNode::Stop(double aWhen, ErrorResult& aRv, bool aShuttingDown)
{
if (!mStartCalled) {
aRv.Throw(NS_ERROR_DOM_INVALID_STATE_ERR);
return;
}
if (!mBuffer || aShuttingDown) {
// We don't have a buffer, so the stream is never marked as finished.
// This can also happen if the AudioContext is being shut down.
// Therefore we need to drop our playing ref right now.
mPlayingRef.Drop(this);
}
AudioNodeStream* ns = static_cast<AudioNodeStream*>(mStream.get());
if (!ns || !Context()) {
// We've already stopped and had our stream shut down
return;
}
ns->SetStreamTimeParameter(STOP, Context()->DestinationStream(),
std::max(0.0, aWhen));
}
void
AudioBufferSourceNode::NotifyMainThreadStateChanged()
{
if (mStream->IsFinished()) {
class EndedEventDispatcher : public nsRunnable
{
public:
explicit EndedEventDispatcher(AudioBufferSourceNode* aNode)
: mNode(aNode) {}
NS_IMETHODIMP Run()
{
// If it's not safe to run scripts right now, schedule this to run later
if (!nsContentUtils::IsSafeToRunScript()) {
nsContentUtils::AddScriptRunner(this);
return NS_OK;
}
mNode->DispatchTrustedEvent(NS_LITERAL_STRING("ended"));
return NS_OK;
}
private:
nsRefPtr<AudioBufferSourceNode> mNode;
};
if (!mStopped) {
// Only dispatch the ended event once
NS_DispatchToMainThread(new EndedEventDispatcher(this));
mStopped = true;
}
// Drop the playing reference
// Warning: The below line might delete this.
mPlayingRef.Drop(this);
}
}
void
AudioBufferSourceNode::SendPlaybackRateToStream(AudioNode* aNode)
{
AudioBufferSourceNode* This = static_cast<AudioBufferSourceNode*>(aNode);
SendTimelineParameterToStream(This, PLAYBACKRATE, *This->mPlaybackRate);
}
void
AudioBufferSourceNode::SendGainToStream(AudioNode* aNode)
{
AudioBufferSourceNode* This = static_cast<AudioBufferSourceNode*>(aNode);
SendTimelineParameterToStream(This, GAIN, *This->mGain);
}
void
AudioBufferSourceNode::SendDopplerShiftToStream(double aDopplerShift)
{
SendDoubleParameterToStream(DOPPLERSHIFT, aDopplerShift);
}
void
AudioBufferSourceNode::SendLoopParametersToStream()
{
// Don't compute and set the loop parameters unnecessarily
if (mLoop && mBuffer) {
float rate = mBuffer->SampleRate();
double length = (double(mBuffer->Length()) / mBuffer->SampleRate());
double actualLoopStart, actualLoopEnd;
if (((mLoopStart != 0.0) || (mLoopEnd != 0.0)) &&
mLoopStart >= 0.0 && mLoopEnd > 0.0 &&
mLoopStart < mLoopEnd) {
actualLoopStart = (mLoopStart > length) ? 0.0 : mLoopStart;
actualLoopEnd = std::min(mLoopEnd, length);
} else {
actualLoopStart = 0.0;
actualLoopEnd = length;
}
int32_t loopStartTicks = NS_lround(actualLoopStart * rate);
int32_t loopEndTicks = NS_lround(actualLoopEnd * rate);
if (loopStartTicks < loopEndTicks) {
SendInt32ParameterToStream(LOOPSTART, loopStartTicks);
SendInt32ParameterToStream(LOOPEND, loopEndTicks);
SendInt32ParameterToStream(LOOP, 1);
}
} else if (!mLoop) {
SendInt32ParameterToStream(LOOP, 0);
}
}
}
}