gecko/content/media/webaudio/OscillatorNode.cpp
Karl Tomlinson fa7c6ec5b6 b=923106 recompute frequency dependent parameters when OscillatorType changes r=padenot
mSquare, mTriangle, and mSaw are not initialized in the OscillatorNodeEngine
constructor, just like they are not initialized when switching to
OscillatorType::Sine.  These parameters are initialized if and when switching
to the OscillatorTypes that use them.

mFinalFrequency, mNumberOfHarmonics, mSignalPeriod, mAmplitudeAtZero,
mPhaseIncrement, mPhaseWrap are not initialized in the OscillatorNodeEngine
constructor, just like they are not initialized immediately on switching
OscillatorType.  These parameters are initialized in
UpdateParametersIfNeeded(), conditional on mRecomputeParameters.

--HG--
extra : transplant_source : a%C1%83%03%03%5CJ%88%99j%A0%93%05%92%06%CA%D6%8B%00%21
2013-10-15 13:10:02 +13:00

649 lines
19 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 "OscillatorNode.h"
#include "AudioNodeEngine.h"
#include "AudioNodeStream.h"
#include "AudioDestinationNode.h"
#include "WebAudioUtils.h"
#include "blink/PeriodicWave.h"
namespace mozilla {
namespace dom {
NS_IMPL_CYCLE_COLLECTION_INHERITED_3(OscillatorNode, AudioNode,
mPeriodicWave, mFrequency, mDetune)
NS_INTERFACE_MAP_BEGIN_CYCLE_COLLECTION_INHERITED(OscillatorNode)
NS_INTERFACE_MAP_END_INHERITING(AudioNode)
NS_IMPL_ADDREF_INHERITED(OscillatorNode, AudioNode)
NS_IMPL_RELEASE_INHERITED(OscillatorNode, AudioNode)
static const float sLeak = 0.995f;
class DCBlocker
{
public:
// These are sane defauts when the initial mPhase is zero
DCBlocker(float aLastInput = 0.0f,
float aLastOutput = 0.0f,
float aPole = 0.995)
:mLastInput(aLastInput),
mLastOutput(aLastOutput),
mPole(aPole)
{
MOZ_ASSERT(aPole > 0);
}
inline float Process(float aInput)
{
float out;
out = mLastOutput * mPole + aInput - mLastInput;
mLastOutput = out;
mLastInput = aInput;
return out;
}
private:
float mLastInput;
float mLastOutput;
float mPole;
};
class OscillatorNodeEngine : public AudioNodeEngine
{
public:
OscillatorNodeEngine(AudioNode* aNode, AudioDestinationNode* aDestination)
: AudioNodeEngine(aNode)
, mSource(nullptr)
, mDestination(static_cast<AudioNodeStream*> (aDestination->Stream()))
, mStart(-1)
, mStop(TRACK_TICKS_MAX)
// Keep the default values in sync with OscillatorNode::OscillatorNode.
, mFrequency(440.f)
, mDetune(0.f)
, mType(OscillatorType::Sine)
, mPhase(0.)
// mSquare, mTriangle, and mSaw are not used for default type "sine".
// They are initialized if and when switching to the OscillatorTypes that
// use them.
// mFinalFrequency, mNumberOfHarmonics, mSignalPeriod, mAmplitudeAtZero,
// mPhaseIncrement, and mPhaseWrap are initialized in
// UpdateParametersIfNeeded() when mRecomputeParameters is set.
, mRecomputeParameters(true)
, mCustomLength(0)
{
}
void SetSourceStream(AudioNodeStream* aSource)
{
mSource = aSource;
}
enum Parameters {
FREQUENCY,
DETUNE,
TYPE,
PERIODICWAVE,
START,
STOP,
};
void SetTimelineParameter(uint32_t aIndex,
const AudioParamTimeline& aValue,
TrackRate aSampleRate) MOZ_OVERRIDE
{
mRecomputeParameters = true;
switch (aIndex) {
case FREQUENCY:
MOZ_ASSERT(mSource && mDestination);
mFrequency = aValue;
WebAudioUtils::ConvertAudioParamToTicks(mFrequency, mSource, mDestination);
break;
case DETUNE:
MOZ_ASSERT(mSource && mDestination);
mDetune = aValue;
WebAudioUtils::ConvertAudioParamToTicks(mDetune, mSource, mDestination);
break;
default:
NS_ERROR("Bad OscillatorNodeEngine TimelineParameter");
}
}
virtual void SetStreamTimeParameter(uint32_t aIndex, TrackTicks aParam)
{
switch (aIndex) {
case START: mStart = aParam; break;
case STOP: mStop = aParam; break;
default:
NS_ERROR("Bad OscillatorNodeEngine StreamTimeParameter");
}
}
virtual void SetInt32Parameter(uint32_t aIndex, int32_t aParam)
{
switch (aIndex) {
case TYPE:
// Set the new type.
mType = static_cast<OscillatorType>(aParam);
if (mType != OscillatorType::Custom) {
// Forget any previous custom data.
mCustomLength = 0;
mCustom = nullptr;
mPeriodicWave = nullptr;
mRecomputeParameters = true;
}
// Update BLIT integrators with the new initial conditions.
switch (mType) {
case OscillatorType::Sine:
mPhase = 0.0;
break;
case OscillatorType::Square:
mPhase = 0.0;
// Initial integration condition is -0.5, because our
// square has 50% duty cycle.
mSquare = -0.5;
break;
case OscillatorType::Triangle:
// Initial mPhase and related integration condition so the
// triangle is in the middle of the first upward slope.
// XXX actually do the maths and put the right number here.
mPhase = (float)(M_PI / 2);
mSquare = 0.5;
mTriangle = 0.0;
break;
case OscillatorType::Sawtooth:
// Initial mPhase so the oscillator starts at the
// middle of the ramp, per spec.
mPhase = (float)(M_PI / 2);
// mSaw = 0 when mPhase = pi/2.
mSaw = 0.0;
break;
case OscillatorType::Custom:
// Custom waveforms don't use BLIT.
break;
default:
NS_ERROR("Bad OscillatorNodeEngine type parameter.");
}
// End type switch.
break;
case PERIODICWAVE:
MOZ_ASSERT(aParam >= 0, "negative custom array length");
mCustomLength = static_cast<uint32_t>(aParam);
break;
default:
NS_ERROR("Bad OscillatorNodeEngine Int32Parameter.");
}
// End index switch.
}
virtual void SetBuffer(already_AddRefed<ThreadSharedFloatArrayBufferList> aBuffer)
{
MOZ_ASSERT(mCustomLength, "Custom buffer sent before length");
mCustom = aBuffer;
MOZ_ASSERT(mCustom->GetChannels() == 2,
"PeriodicWave should have sent two channels");
mPeriodicWave = WebCore::PeriodicWave::create(mSource->SampleRate(),
mCustom->GetData(0), mCustom->GetData(1), mCustomLength);
}
void IncrementPhase()
{
mPhase += mPhaseIncrement;
if (mPhase > mPhaseWrap) {
mPhase -= mPhaseWrap;
}
}
// Square and triangle are using a bipolar band-limited impulse train, saw is
// using a normal band-limited impulse train.
bool UsesBipolarBLIT() {
return mType == OscillatorType::Square || mType == OscillatorType::Triangle;
}
void UpdateParametersIfNeeded(TrackTicks ticks, size_t count)
{
double frequency, detune;
bool simpleFrequency = mFrequency.HasSimpleValue();
bool simpleDetune = mDetune.HasSimpleValue();
// Shortcut if frequency-related AudioParam are not automated, and we
// already have computed the frequency information and related parameters.
if (simpleFrequency && simpleDetune && !mRecomputeParameters) {
return;
}
if (simpleFrequency) {
frequency = mFrequency.GetValue();
} else {
frequency = mFrequency.GetValueAtTime(ticks, count);
}
if (simpleDetune) {
detune = mDetune.GetValue();
} else {
detune = mDetune.GetValueAtTime(ticks, count);
}
mFinalFrequency = frequency * pow(2., detune / 1200.);
mRecomputeParameters = false;
// When using bipolar BLIT, we divide the signal period by two, because we
// are using two BLIT out of phase.
mSignalPeriod = UsesBipolarBLIT() ? 0.5 * mSource->SampleRate() / mFinalFrequency
: mSource->SampleRate() / mFinalFrequency;
// Wrap the phase accordingly:
mPhaseWrap = UsesBipolarBLIT() || mType == OscillatorType::Sine ? 2 * M_PI
: M_PI;
// Even number of harmonics for bipolar blit, odd otherwise.
mNumberOfHarmonics = UsesBipolarBLIT() ? 2 * floor(0.5 * mSignalPeriod)
: 2 * floor(0.5 * mSignalPeriod) + 1;
mPhaseIncrement = mType == OscillatorType::Sine ? 2 * M_PI / mSignalPeriod
: M_PI / mSignalPeriod;
mAmplitudeAtZero = mNumberOfHarmonics / mSignalPeriod;
}
void FillBounds(float* output, TrackTicks ticks,
uint32_t& start, uint32_t& end)
{
MOZ_ASSERT(output);
static_assert(TrackTicks(WEBAUDIO_BLOCK_SIZE) < UINT_MAX,
"WEBAUDIO_BLOCK_SIZE overflows interator bounds.");
start = 0;
if (ticks < mStart) {
start = mStart - ticks;
for (uint32_t i = 0; i < start; ++i) {
output[i] = 0.0;
}
}
end = WEBAUDIO_BLOCK_SIZE;
if (ticks + end > mStop) {
end = mStop - ticks;
for (uint32_t i = end; i < WEBAUDIO_BLOCK_SIZE; ++i) {
output[i] = 0.0;
}
}
}
float BipolarBLIT()
{
float blit;
float denom = sin(mPhase);
if (fabs(denom) < std::numeric_limits<float>::epsilon()) {
if (mPhase < 0.1f || mPhase > 2 * M_PI - 0.1f) {
blit = mAmplitudeAtZero;
} else {
blit = -mAmplitudeAtZero;
}
} else {
blit = sin(mNumberOfHarmonics * mPhase);
blit /= mSignalPeriod * denom;
}
return blit;
}
float UnipolarBLIT()
{
float blit;
float denom = sin(mPhase);
if (fabs(denom) <= std::numeric_limits<float>::epsilon()) {
blit = mAmplitudeAtZero;
} else {
blit = sin(mNumberOfHarmonics * mPhase);
blit /= mSignalPeriod * denom;
}
return blit;
}
void ComputeSine(float * aOutput, TrackTicks ticks, uint32_t aStart, uint32_t aEnd)
{
for (uint32_t i = aStart; i < aEnd; ++i) {
UpdateParametersIfNeeded(ticks, i);
aOutput[i] = sin(mPhase);
IncrementPhase();
}
}
void ComputeSquare(float * aOutput, TrackTicks ticks, uint32_t aStart, uint32_t aEnd)
{
for (uint32_t i = aStart; i < aEnd; ++i) {
UpdateParametersIfNeeded(ticks, i);
// Integration to get us a square. It turns out we can have a
// pure integrator here.
mSquare += BipolarBLIT();
aOutput[i] = mSquare;
// maybe we want to apply a gain, the wg has not decided yet
aOutput[i] *= 1.5;
IncrementPhase();
}
}
void ComputeSawtooth(float * aOutput, TrackTicks ticks, uint32_t aStart, uint32_t aEnd)
{
float dcoffset;
for (uint32_t i = aStart; i < aEnd; ++i) {
UpdateParametersIfNeeded(ticks, i);
// DC offset so the Saw does not ramp up to infinity when integrating.
dcoffset = mFinalFrequency / mSource->SampleRate();
// Integrate and offset so we get mAmplitudeAtZero sawtooth. We have a
// very low frequency component somewhere here, but I'm not sure where.
mSaw += UnipolarBLIT() - dcoffset;
// reverse the saw so we are spec compliant
aOutput[i] = -mSaw * 1.5;
IncrementPhase();
}
}
void ComputeTriangle(float * aOutput, TrackTicks ticks, uint32_t aStart, uint32_t aEnd)
{
for (uint32_t i = aStart; i < aEnd; ++i) {
UpdateParametersIfNeeded(ticks, i);
// Integrate to get a square
mSquare += BipolarBLIT();
// Leaky integrate to get a triangle. We get too much dc offset if we don't
// leaky integrate here.
// C6 = k0 / period
// (period is samplingrate / frequency, k0 = (PI/2)/(2*PI)) = 0.25
float C6 = 0.25 / (mSource->SampleRate() / mFinalFrequency);
mTriangle = mTriangle * sLeak + mSquare + C6;
// DC Block, and scale back to [-1.0; 1.0]
aOutput[i] = mDCBlocker.Process(mTriangle) / (mSignalPeriod/2) * 1.5;
IncrementPhase();
}
}
void ComputeCustom(float* aOutput,
TrackTicks ticks,
uint32_t aStart,
uint32_t aEnd)
{
MOZ_ASSERT(mPeriodicWave, "No custom waveform data");
uint32_t periodicWaveSize = mPeriodicWave->periodicWaveSize();
float* higherWaveData = nullptr;
float* lowerWaveData = nullptr;
float tableInterpolationFactor;
float rate = 1.0 / mSource->SampleRate();
for (uint32_t i = aStart; i < aEnd; ++i) {
UpdateParametersIfNeeded(ticks, i);
mPeriodicWave->waveDataForFundamentalFrequency(mFinalFrequency,
lowerWaveData,
higherWaveData,
tableInterpolationFactor);
// mPhase runs 0..periodicWaveSize here instead of 0..2*M_PI.
mPhase += periodicWaveSize * mFinalFrequency * rate;
if (mPhase >= periodicWaveSize) {
mPhase -= periodicWaveSize;
}
// Bilinear interpolation between adjacent samples in each table.
uint32_t j1 = floor(mPhase);
uint32_t j2 = j1 + 1;
if (j2 >= periodicWaveSize) {
j2 -= periodicWaveSize;
}
float sampleInterpolationFactor = mPhase - j1;
float lower = sampleInterpolationFactor * lowerWaveData[j1] +
(1 - sampleInterpolationFactor) * lowerWaveData[j2];
float higher = sampleInterpolationFactor * higherWaveData[j1] +
(1 - sampleInterpolationFactor) * higherWaveData[j2];
aOutput[i] = tableInterpolationFactor * lower +
(1 - tableInterpolationFactor) * higher;
}
}
void ComputeSilence(AudioChunk *aOutput)
{
aOutput->SetNull(WEBAUDIO_BLOCK_SIZE);
}
virtual void ProduceAudioBlock(AudioNodeStream* aStream,
const AudioChunk& aInput,
AudioChunk* aOutput,
bool* aFinished) MOZ_OVERRIDE
{
MOZ_ASSERT(mSource == aStream, "Invalid source stream");
TrackTicks ticks = aStream->GetCurrentPosition();
if (mStart == -1) {
ComputeSilence(aOutput);
return;
}
if (ticks >= mStop) {
// We've finished playing.
ComputeSilence(aOutput);
*aFinished = true;
return;
}
if (ticks + WEBAUDIO_BLOCK_SIZE < mStart) {
// We're not playing yet.
ComputeSilence(aOutput);
return;
}
AllocateAudioBlock(1, aOutput);
float* output = static_cast<float*>(
const_cast<void*>(aOutput->mChannelData[0]));
uint32_t start, end;
FillBounds(output, ticks, start, end);
// Synthesize the correct waveform.
switch(mType) {
case OscillatorType::Sine:
ComputeSine(output, ticks, start, end);
break;
case OscillatorType::Square:
ComputeSquare(output, ticks, start, end);
break;
case OscillatorType::Triangle:
ComputeTriangle(output, ticks, start, end);
break;
case OscillatorType::Sawtooth:
ComputeSawtooth(output, ticks, start, end);
break;
case OscillatorType::Custom:
ComputeCustom(output, ticks, start, end);
break;
default:
ComputeSilence(aOutput);
};
}
DCBlocker mDCBlocker;
AudioNodeStream* mSource;
AudioNodeStream* mDestination;
TrackTicks mStart;
TrackTicks mStop;
AudioParamTimeline mFrequency;
AudioParamTimeline mDetune;
OscillatorType mType;
float mPhase;
float mFinalFrequency;
uint32_t mNumberOfHarmonics;
float mSignalPeriod;
float mAmplitudeAtZero;
float mPhaseIncrement;
float mSquare;
float mTriangle;
float mSaw;
float mPhaseWrap;
bool mRecomputeParameters;
nsRefPtr<ThreadSharedFloatArrayBufferList> mCustom;
uint32_t mCustomLength;
nsAutoPtr<WebCore::PeriodicWave> mPeriodicWave;
};
OscillatorNode::OscillatorNode(AudioContext* aContext)
: AudioNode(aContext,
2,
ChannelCountMode::Max,
ChannelInterpretation::Speakers)
, mType(OscillatorType::Sine)
, mFrequency(new AudioParam(MOZ_THIS_IN_INITIALIZER_LIST(),
SendFrequencyToStream, 440.0f))
, mDetune(new AudioParam(MOZ_THIS_IN_INITIALIZER_LIST(),
SendDetuneToStream, 0.0f))
, mStartCalled(false)
, mStopped(false)
{
OscillatorNodeEngine* engine = new OscillatorNodeEngine(this, aContext->Destination());
mStream = aContext->Graph()->CreateAudioNodeStream(engine, MediaStreamGraph::SOURCE_STREAM);
engine->SetSourceStream(static_cast<AudioNodeStream*> (mStream.get()));
mStream->AddMainThreadListener(this);
}
OscillatorNode::~OscillatorNode()
{
}
JSObject*
OscillatorNode::WrapObject(JSContext* aCx, JS::Handle<JSObject*> aScope)
{
return OscillatorNodeBinding::Wrap(aCx, aScope, this);
}
void
OscillatorNode::SendFrequencyToStream(AudioNode* aNode)
{
OscillatorNode* This = static_cast<OscillatorNode*>(aNode);
SendTimelineParameterToStream(This, OscillatorNodeEngine::FREQUENCY, *This->mFrequency);
}
void
OscillatorNode::SendDetuneToStream(AudioNode* aNode)
{
OscillatorNode* This = static_cast<OscillatorNode*>(aNode);
SendTimelineParameterToStream(This, OscillatorNodeEngine::DETUNE, *This->mDetune);
}
void
OscillatorNode::SendTypeToStream()
{
if (mType == OscillatorType::Custom) {
// The engine assumes we'll send the custom data before updating the type.
SendPeriodicWaveToStream();
}
SendInt32ParameterToStream(OscillatorNodeEngine::TYPE, static_cast<int32_t>(mType));
}
void OscillatorNode::SendPeriodicWaveToStream()
{
NS_ASSERTION(mType == OscillatorType::Custom,
"Sending custom waveform to engine thread with non-custom type");
AudioNodeStream* ns = static_cast<AudioNodeStream*>(mStream.get());
MOZ_ASSERT(ns, "Missing node stream.");
MOZ_ASSERT(mPeriodicWave, "Send called without PeriodicWave object.");
SendInt32ParameterToStream(OscillatorNodeEngine::PERIODICWAVE,
mPeriodicWave->DataLength());
nsRefPtr<ThreadSharedFloatArrayBufferList> data =
mPeriodicWave->GetThreadSharedBuffer();
ns->SetBuffer(data.forget());
}
void
OscillatorNode::Start(double aWhen, ErrorResult& aRv)
{
if (!WebAudioUtils::IsTimeValid(aWhen)) {
aRv.Throw(NS_ERROR_DOM_NOT_SUPPORTED_ERR);
return;
}
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;
}
// TODO: Perhaps we need to do more here.
ns->SetStreamTimeParameter(OscillatorNodeEngine::START,
Context()->DestinationStream(),
aWhen);
MarkActive();
}
void
OscillatorNode::Stop(double aWhen, ErrorResult& aRv)
{
if (!WebAudioUtils::IsTimeValid(aWhen)) {
aRv.Throw(NS_ERROR_DOM_NOT_SUPPORTED_ERR);
return;
}
if (!mStartCalled) {
aRv.Throw(NS_ERROR_DOM_INVALID_STATE_ERR);
return;
}
AudioNodeStream* ns = static_cast<AudioNodeStream*>(mStream.get());
if (!ns || !Context()) {
// We've already stopped and had our stream shut down
return;
}
// TODO: Perhaps we need to do more here.
ns->SetStreamTimeParameter(OscillatorNodeEngine::STOP,
Context()->DestinationStream(),
std::max(0.0, aWhen));
}
void
OscillatorNode::NotifyMainThreadStateChanged()
{
if (mStream->IsFinished()) {
class EndedEventDispatcher : public nsRunnable
{
public:
explicit EndedEventDispatcher(OscillatorNode* 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<OscillatorNode> 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.
MarkInactive();
}
}
}
}