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/*
* Copyright (C) 2011 Google Inc. All rights reserved.
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* modification, are permitted provided that the following conditions
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*
* 1. Redistributions of source code must retain the above copyright
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* notice, this list of conditions and the following disclaimer in the
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* 3. Neither the name of Apple Inc. ("Apple") nor the names of
* its contributors may be used to endorse or promote products derived
* from this software without specific prior written permission.
*
* THIS SOFTWARE IS PROVIDED BY APPLE AND ITS CONTRIBUTORS "AS IS" AND ANY
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#include "config.h"
#if ENABLE(WEB_AUDIO)
#include "DynamicsCompressorKernel.h"
#include "AudioUtilities.h"
#include "DenormalDisabler.h"
#include <algorithm>
#include <wtf/MathExtras.h>
namespace WebCore {
using namespace AudioUtilities;
// Metering hits peaks instantly, but releases this fast (in seconds).
constexpr float meteringReleaseTimeConstant = 0.325f;
DynamicsCompressorKernel::DynamicsCompressorKernel(float sampleRate, unsigned numberOfChannels)
: m_sampleRate(sampleRate)
{
setNumberOfChannels(numberOfChannels);
// Initializes most member variables
reset();
m_meteringReleaseK = static_cast<float>(discreteTimeConstantForSampleRate(meteringReleaseTimeConstant, sampleRate));
}
void DynamicsCompressorKernel::setNumberOfChannels(unsigned numberOfChannels)
{
if (m_preDelayBuffers.size() == numberOfChannels)
return;
m_preDelayBuffers.clear();
m_preDelayBuffers.reserveInitialCapacity(numberOfChannels);
for (unsigned i = 0; i < numberOfChannels; ++i)
m_preDelayBuffers.uncheckedAppend(makeUnique<AudioFloatArray>(MaxPreDelayFrames));
}
void DynamicsCompressorKernel::setPreDelayTime(float preDelayTime)
{
// Re-configure look-ahead section pre-delay if delay time has changed.
unsigned preDelayFrames = preDelayTime * sampleRate();
if (preDelayFrames > MaxPreDelayFrames - 1)
preDelayFrames = MaxPreDelayFrames - 1;
if (m_lastPreDelayFrames != preDelayFrames) {
m_lastPreDelayFrames = preDelayFrames;
for (unsigned i = 0; i < m_preDelayBuffers.size(); ++i)
m_preDelayBuffers[i]->zero();
m_preDelayReadIndex = 0;
m_preDelayWriteIndex = preDelayFrames;
}
}
// Exponential curve for the knee.
// It is 1st derivative matched at m_linearThreshold and asymptotically approaches the value m_linearThreshold + 1 / k.
float DynamicsCompressorKernel::kneeCurve(float x, float k)
{
// Linear up to threshold.
if (x < m_linearThreshold)
return x;
return m_linearThreshold + (1 - expf(-k * (x - m_linearThreshold))) / k;
}
// Full compression curve with constant ratio after knee.
float DynamicsCompressorKernel::saturate(float x, float k)
{
float y;
if (x < m_kneeThreshold)
y = kneeCurve(x, k);
else {
// Constant ratio after knee.
float xDb = linearToDecibels(x);
float yDb = m_ykneeThresholdDb + m_slope * (xDb - m_kneeThresholdDb);
y = decibelsToLinear(yDb);
}
return y;
}
// Approximate 1st derivative with input and output expressed in dB.
// This slope is equal to the inverse of the compression "ratio".
// In other words, a compression ratio of 20 would be a slope of 1/20.
float DynamicsCompressorKernel::slopeAt(float x, float k)
{
if (x < m_linearThreshold)
return 1;
float x2 = x * 1.001;
float xDb = linearToDecibels(x);
float x2Db = linearToDecibels(x2);
float yDb = linearToDecibels(kneeCurve(x, k));
float y2Db = linearToDecibels(kneeCurve(x2, k));
float m = (y2Db - yDb) / (x2Db - xDb);
return m;
}
float DynamicsCompressorKernel::kAtSlope(float desiredSlope)
{
float xDb = m_dbThreshold + m_dbKnee;
float x = decibelsToLinear(xDb);
// Approximate k given initial values.
float minK = 0.1;
float maxK = 10000;
float k = 5;
for (int i = 0; i < 15; ++i) {
// A high value for k will more quickly asymptotically approach a slope of 0.
float slope = slopeAt(x, k);
if (slope < desiredSlope) {
// k is too high.
maxK = k;
} else {
// k is too low.
minK = k;
}
// Re-calculate based on geometric mean.
k = sqrtf(minK * maxK);
}
return k;
}
float DynamicsCompressorKernel::updateStaticCurveParameters(float dbThreshold, float dbKnee, float ratio)
{
if (dbThreshold != m_dbThreshold || dbKnee != m_dbKnee || ratio != m_ratio) {
// Threshold and knee.
m_dbThreshold = dbThreshold;
m_linearThreshold = decibelsToLinear(dbThreshold);
m_dbKnee = dbKnee;
// Compute knee parameters.
m_ratio = ratio;
m_slope = 1 / m_ratio;
float k = kAtSlope(1 / m_ratio);
m_kneeThresholdDb = dbThreshold + dbKnee;
m_kneeThreshold = decibelsToLinear(m_kneeThresholdDb);
m_ykneeThresholdDb = linearToDecibels(kneeCurve(m_kneeThreshold, k));
m_K = k;
}
return m_K;
}
void DynamicsCompressorKernel::process(const float* sourceChannels[],
float* destinationChannels[],
unsigned numberOfChannels,
unsigned framesToProcess,
float dbThreshold,
float dbKnee,
float ratio,
float attackTime,
float releaseTime,
float preDelayTime,
float dbPostGain,
float effectBlend, /* equal power crossfade */
float releaseZone1,
float releaseZone2,
float releaseZone3,
float releaseZone4
)
{
ASSERT(m_preDelayBuffers.size() == numberOfChannels);
float sampleRate = this->sampleRate();
float dryMix = 1 - effectBlend;
float wetMix = effectBlend;
float k = updateStaticCurveParameters(dbThreshold, dbKnee, ratio);
// Makeup gain.
float fullRangeGain = saturate(1, k);
float fullRangeMakeupGain = 1 / fullRangeGain;
// Empirical/perceptual tuning.
fullRangeMakeupGain = powf(fullRangeMakeupGain, 0.6f);
float masterLinearGain = decibelsToLinear(dbPostGain) * fullRangeMakeupGain;
// Attack parameters.
attackTime = std::max(0.001f, attackTime);
float attackFrames = attackTime * sampleRate;
// Release parameters.
float releaseFrames = sampleRate * releaseTime;
// Detector release time.
float satReleaseTime = 0.0025f;
float satReleaseFrames = satReleaseTime * sampleRate;
// Create a smooth function which passes through four points.
// Polynomial of the form
// y = a + b*x + c*x^2 + d*x^3 + e*x^4;
float y1 = releaseFrames * releaseZone1;
float y2 = releaseFrames * releaseZone2;
float y3 = releaseFrames * releaseZone3;
float y4 = releaseFrames * releaseZone4;
// All of these coefficients were derived for 4th order polynomial curve fitting where the y values
// match the evenly spaced x values as follows: (y1 : x == 0, y2 : x == 1, y3 : x == 2, y4 : x == 3)
float kA = 0.9999999999999998f*y1 + 1.8432219684323923e-16f*y2 - 1.9373394351676423e-16f*y3 + 8.824516011816245e-18f*y4;
float kB = -1.5788320352845888f*y1 + 2.3305837032074286f*y2 - 0.9141194204840429f*y3 + 0.1623677525612032f*y4;
float kC = 0.5334142869106424f*y1 - 1.272736789213631f*y2 + 0.9258856042207512f*y3 - 0.18656310191776226f*y4;
float kD = 0.08783463138207234f*y1 - 0.1694162967925622f*y2 + 0.08588057951595272f*y3 - 0.00429891410546283f*y4;
float kE = -0.042416883008123074f*y1 + 0.1115693827987602f*y2 - 0.09764676325265872f*y3 + 0.028494263462021576f*y4;
// x ranges from 0 -> 3 0 1 2 3
// -15 -10 -5 0db
// y calculates adaptive release frames depending on the amount of compression.
setPreDelayTime(preDelayTime);
const int nDivisionFrames = 32;
const int nDivisions = framesToProcess / nDivisionFrames;
unsigned frameIndex = 0;
for (int i = 0; i < nDivisions; ++i) {
// ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
// Calculate desired gain
// ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
// Fix gremlins.
if (std::isnan(m_detectorAverage))
m_detectorAverage = 1;
if (std::isinf(m_detectorAverage))
m_detectorAverage = 1;
float desiredGain = m_detectorAverage;
// Pre-warp so we get desiredGain after sin() warp below.
float scaledDesiredGain = asinf(desiredGain) / (0.5f * piFloat);
// ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
// Deal with envelopes
// ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
// envelopeRate is the rate we slew from current compressor level to the desired level.
// The exact rate depends on if we're attacking or releasing and by how much.
float envelopeRate;
bool isReleasing = scaledDesiredGain > m_compressorGain;
// compressionDiffDb is the difference between current compression level and the desired level.
float compressionDiffDb = linearToDecibels(m_compressorGain / scaledDesiredGain);
if (isReleasing) {
// Release mode - compressionDiffDb should be negative dB
m_maxAttackCompressionDiffDb = -1;
// Fix gremlins.
if (std::isnan(compressionDiffDb))
compressionDiffDb = -1;
if (std::isinf(compressionDiffDb))
compressionDiffDb = -1;
// Adaptive release - higher compression (lower compressionDiffDb) releases faster.
// Contain within range: -12 -> 0 then scale to go from 0 -> 3
float x = compressionDiffDb;
x = std::max(-12.0f, x);
x = std::min(0.0f, x);
x = 0.25f * (x + 12);
// Compute adaptive release curve using 4th order polynomial.
// Normal values for the polynomial coefficients would create a monotonically increasing function.
float x2 = x * x;
float x3 = x2 * x;
float x4 = x2 * x2;
float releaseFrames = kA + kB * x + kC * x2 + kD * x3 + kE * x4;
#define kSpacingDb 5
float dbPerFrame = kSpacingDb / releaseFrames;
envelopeRate = decibelsToLinear(dbPerFrame);
} else {
// Attack mode - compressionDiffDb should be positive dB
// Fix gremlins.
if (std::isnan(compressionDiffDb))
compressionDiffDb = 1;
if (std::isinf(compressionDiffDb))
compressionDiffDb = 1;
// As long as we're still in attack mode, use a rate based off
// the largest compressionDiffDb we've encountered so far.
if (m_maxAttackCompressionDiffDb == -1 || m_maxAttackCompressionDiffDb < compressionDiffDb)
m_maxAttackCompressionDiffDb = compressionDiffDb;
float effAttenDiffDb = std::max(0.5f, m_maxAttackCompressionDiffDb);
float x = 0.25f / effAttenDiffDb;
envelopeRate = 1 - powf(x, 1 / attackFrames);
}
// ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
// Inner loop - calculate shaped power average - apply compression.
// ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
{
int preDelayReadIndex = m_preDelayReadIndex;
int preDelayWriteIndex = m_preDelayWriteIndex;
float detectorAverage = m_detectorAverage;
float compressorGain = m_compressorGain;
int loopFrames = nDivisionFrames;
while (loopFrames--) {
float compressorInput = 0;
// Predelay signal, computing compression amount from un-delayed version.
for (unsigned i = 0; i < numberOfChannels; ++i) {
float* delayBuffer = m_preDelayBuffers[i]->data();
float undelayedSource = sourceChannels[i][frameIndex];
delayBuffer[preDelayWriteIndex] = undelayedSource;
float absUndelayedSource = undelayedSource > 0 ? undelayedSource : -undelayedSource;
if (compressorInput < absUndelayedSource)
compressorInput = absUndelayedSource;
}
// Calculate shaped power on undelayed input.
float scaledInput = compressorInput;
float absInput = scaledInput > 0 ? scaledInput : -scaledInput;
// Put through shaping curve.
// This is linear up to the threshold, then enters a "knee" portion followed by the "ratio" portion.
// The transition from the threshold to the knee is smooth (1st derivative matched).
// The transition from the knee to the ratio portion is smooth (1st derivative matched).
float shapedInput = saturate(absInput, k);
float attenuation = absInput <= 0.0001f ? 1 : shapedInput / absInput;
float attenuationDb = -linearToDecibels(attenuation);
attenuationDb = std::max(2.0f, attenuationDb);
float dbPerFrame = attenuationDb / satReleaseFrames;
float satReleaseRate = decibelsToLinear(dbPerFrame) - 1;
bool isRelease = (attenuation > detectorAverage);
float rate = isRelease ? satReleaseRate : 1;
detectorAverage += (attenuation - detectorAverage) * rate;
detectorAverage = std::min(1.0f, detectorAverage);
// Fix gremlins.
if (std::isnan(detectorAverage))
detectorAverage = 1;
if (std::isinf(detectorAverage))
detectorAverage = 1;
// Exponential approach to desired gain.
if (envelopeRate < 1) {
// Attack - reduce gain to desired.
compressorGain += (scaledDesiredGain - compressorGain) * envelopeRate;
} else {
// Release - exponentially increase gain to 1.0
compressorGain *= envelopeRate;
compressorGain = std::min(1.0f, compressorGain);
}
// Warp pre-compression gain to smooth out sharp exponential transition points.
float postWarpCompressorGain = sinf(0.5f * piFloat * compressorGain);
// Calculate total gain using master gain and effect blend.
float totalGain = dryMix + wetMix * masterLinearGain * postWarpCompressorGain;
// Calculate metering.
float dbRealGain = 20 * log10(postWarpCompressorGain);
if (dbRealGain < m_meteringGain)
m_meteringGain = dbRealGain;
else
m_meteringGain += (dbRealGain - m_meteringGain) * m_meteringReleaseK;
// Apply final gain.
for (unsigned i = 0; i < numberOfChannels; ++i) {
float* delayBuffer = m_preDelayBuffers[i]->data();
destinationChannels[i][frameIndex] = delayBuffer[preDelayReadIndex] * totalGain;
}
frameIndex++;
preDelayReadIndex = (preDelayReadIndex + 1) & MaxPreDelayFramesMask;
preDelayWriteIndex = (preDelayWriteIndex + 1) & MaxPreDelayFramesMask;
}
// Locals back to member variables.
m_preDelayReadIndex = preDelayReadIndex;
m_preDelayWriteIndex = preDelayWriteIndex;
m_detectorAverage = DenormalDisabler::flushDenormalFloatToZero(detectorAverage);
m_compressorGain = DenormalDisabler::flushDenormalFloatToZero(compressorGain);
}
}
}
void DynamicsCompressorKernel::reset()
{
m_detectorAverage = 0;
m_compressorGain = 1;
m_meteringGain = 1;
// Predelay section.
for (unsigned i = 0; i < m_preDelayBuffers.size(); ++i)
m_preDelayBuffers[i]->zero();
m_preDelayReadIndex = 0;
m_preDelayWriteIndex = DefaultPreDelayFrames;
m_maxAttackCompressionDiffDb = -1; // uninitialized state
}
double DynamicsCompressorKernel::tailTime() const
{
// The reduction value of the compressor is computed from the gain using an exponential filter
// with a time constant of |meteringReleaseTimeConstant|. We need to keep he compressor running
// for some time after the inputs go away so that the reduction value approaches 0. This is a
// tradeoff between how long we keep the node alive and how close we approach the final value.
// A value of 5 to 10 times the time constant is a reasonable trade-off.
return 5 * meteringReleaseTimeConstant;
}
} // namespace WebCore
#endif // ENABLE(WEB_AUDIO)