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author | Daniel Baumann <daniel.baumann@progress-linux.org> | 2024-04-19 01:47:29 +0000 |
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committer | Daniel Baumann <daniel.baumann@progress-linux.org> | 2024-04-19 01:47:29 +0000 |
commit | 0ebf5bdf043a27fd3dfb7f92e0cb63d88954c44d (patch) | |
tree | a31f07c9bcca9d56ce61e9a1ffd30ef350d513aa /dom/media/webaudio/blink/PeriodicWave.cpp | |
parent | Initial commit. (diff) | |
download | firefox-esr-0ebf5bdf043a27fd3dfb7f92e0cb63d88954c44d.tar.xz firefox-esr-0ebf5bdf043a27fd3dfb7f92e0cb63d88954c44d.zip |
Adding upstream version 115.8.0esr.upstream/115.8.0esr
Signed-off-by: Daniel Baumann <daniel.baumann@progress-linux.org>
Diffstat (limited to 'dom/media/webaudio/blink/PeriodicWave.cpp')
-rw-r--r-- | dom/media/webaudio/blink/PeriodicWave.cpp | 353 |
1 files changed, 353 insertions, 0 deletions
diff --git a/dom/media/webaudio/blink/PeriodicWave.cpp b/dom/media/webaudio/blink/PeriodicWave.cpp new file mode 100644 index 0000000000..52113a2d07 --- /dev/null +++ b/dom/media/webaudio/blink/PeriodicWave.cpp @@ -0,0 +1,353 @@ +/* + * Copyright (C) 2012 Google Inc. All rights reserved. + * + * Redistribution and use in source and binary forms, with or without + * modification, are permitted provided that the following conditions + * are met: + * + * 1. Redistributions of source code must retain the above copyright + * notice, this list of conditions and the following disclaimer. + * 2. Redistributions in binary form must reproduce the above copyright + * notice, this list of conditions and the following disclaimer in the + * documentation and/or other materials provided with the distribution. + * 3. Neither the name of Apple Computer, 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 + * EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED + * WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE + * DISCLAIMED. IN NO EVENT SHALL APPLE OR ITS CONTRIBUTORS BE LIABLE FOR ANY + * DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES + * (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; + * LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND + * ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT + * (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF + * THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. + */ + +#include "PeriodicWave.h" +#include <algorithm> +#include <cmath> +#include <limits> +#include "mozilla/FFTBlock.h" + +const unsigned MinPeriodicWaveSize = 4096; // This must be a power of two. +const unsigned MaxPeriodicWaveSize = 8192; // This must be a power of two. +const float CentsPerRange = 1200 / 3; // 1/3 Octave. + +using namespace mozilla; +using mozilla::dom::OscillatorType; + +namespace WebCore { + +already_AddRefed<PeriodicWave> PeriodicWave::create(float sampleRate, + const float* real, + const float* imag, + size_t numberOfComponents, + bool disableNormalization) { + bool isGood = real && imag && numberOfComponents > 0; + MOZ_ASSERT(isGood); + if (isGood) { + RefPtr<PeriodicWave> periodicWave = + new PeriodicWave(sampleRate, numberOfComponents, disableNormalization); + + // Limit the number of components used to those for frequencies below the + // Nyquist of the fixed length inverse FFT. + size_t halfSize = periodicWave->m_periodicWaveSize / 2; + numberOfComponents = std::min(numberOfComponents, halfSize); + periodicWave->m_numberOfComponents = numberOfComponents; + periodicWave->m_realComponents = + MakeUnique<AudioFloatArray>(numberOfComponents); + periodicWave->m_imagComponents = + MakeUnique<AudioFloatArray>(numberOfComponents); + memcpy(periodicWave->m_realComponents->Elements(), real, + numberOfComponents * sizeof(float)); + memcpy(periodicWave->m_imagComponents->Elements(), imag, + numberOfComponents * sizeof(float)); + + return periodicWave.forget(); + } + return nullptr; +} + +already_AddRefed<PeriodicWave> PeriodicWave::createSine(float sampleRate) { + RefPtr<PeriodicWave> periodicWave = + new PeriodicWave(sampleRate, MinPeriodicWaveSize, false); + periodicWave->generateBasicWaveform(OscillatorType::Sine); + return periodicWave.forget(); +} + +already_AddRefed<PeriodicWave> PeriodicWave::createSquare(float sampleRate) { + RefPtr<PeriodicWave> periodicWave = + new PeriodicWave(sampleRate, MinPeriodicWaveSize, false); + periodicWave->generateBasicWaveform(OscillatorType::Square); + return periodicWave.forget(); +} + +already_AddRefed<PeriodicWave> PeriodicWave::createSawtooth(float sampleRate) { + RefPtr<PeriodicWave> periodicWave = + new PeriodicWave(sampleRate, MinPeriodicWaveSize, false); + periodicWave->generateBasicWaveform(OscillatorType::Sawtooth); + return periodicWave.forget(); +} + +already_AddRefed<PeriodicWave> PeriodicWave::createTriangle(float sampleRate) { + RefPtr<PeriodicWave> periodicWave = + new PeriodicWave(sampleRate, MinPeriodicWaveSize, false); + periodicWave->generateBasicWaveform(OscillatorType::Triangle); + return periodicWave.forget(); +} + +PeriodicWave::PeriodicWave(float sampleRate, size_t numberOfComponents, + bool disableNormalization) + : m_sampleRate(sampleRate), + m_centsPerRange(CentsPerRange), + m_maxPartialsInBandLimitedTable(0), + m_normalizationScale(1.0f), + m_disableNormalization(disableNormalization) { + float nyquist = 0.5 * m_sampleRate; + + if (numberOfComponents <= MinPeriodicWaveSize) { + m_periodicWaveSize = MinPeriodicWaveSize; + } else { + unsigned npow2 = + exp2f(floorf(logf(numberOfComponents - 1.0) / logf(2.0f) + 1.0f)); + m_periodicWaveSize = std::min(MaxPeriodicWaveSize, npow2); + } + + m_numberOfRanges = (unsigned)(3.0f * logf(m_periodicWaveSize) / logf(2.0f)); + m_bandLimitedTables.SetLength(m_numberOfRanges); + m_lowestFundamentalFrequency = nyquist / maxNumberOfPartials(); + m_rateScale = m_periodicWaveSize / m_sampleRate; +} + +size_t PeriodicWave::sizeOfIncludingThis( + mozilla::MallocSizeOf aMallocSizeOf) const { + size_t amount = aMallocSizeOf(this); + + amount += m_bandLimitedTables.ShallowSizeOfExcludingThis(aMallocSizeOf); + for (size_t i = 0; i < m_bandLimitedTables.Length(); i++) { + if (m_bandLimitedTables[i]) { + amount += + m_bandLimitedTables[i]->ShallowSizeOfIncludingThis(aMallocSizeOf); + } + } + + return amount; +} + +void PeriodicWave::waveDataForFundamentalFrequency( + float fundamentalFrequency, float*& lowerWaveData, float*& higherWaveData, + float& tableInterpolationFactor) { + // Negative frequencies are allowed, in which case we alias + // to the positive frequency. + fundamentalFrequency = fabsf(fundamentalFrequency); + + // We only need to rebuild to the tables if the new fundamental + // frequency is low enough to allow for more partials below the + // Nyquist frequency. + unsigned numberOfPartials = numberOfPartialsForRange(0); + float nyquist = 0.5 * m_sampleRate; + if (fundamentalFrequency != 0.0) { + numberOfPartials = + std::min(numberOfPartials, (unsigned)(nyquist / fundamentalFrequency)); + } + if (numberOfPartials > m_maxPartialsInBandLimitedTable) { + for (unsigned rangeIndex = 0; rangeIndex < m_numberOfRanges; ++rangeIndex) { + m_bandLimitedTables[rangeIndex] = 0; + } + + // We need to create the first table to determine the normalization + // constant. + createBandLimitedTables(fundamentalFrequency, 0); + m_maxPartialsInBandLimitedTable = numberOfPartials; + } + + // Calculate the pitch range. + float ratio = fundamentalFrequency > 0 + ? fundamentalFrequency / m_lowestFundamentalFrequency + : 0.5; + float centsAboveLowestFrequency = logf(ratio) / logf(2.0f) * 1200; + + // Add one to round-up to the next range just in time to truncate + // partials before aliasing occurs. + float pitchRange = 1 + centsAboveLowestFrequency / m_centsPerRange; + + pitchRange = std::max(pitchRange, 0.0f); + pitchRange = std::min(pitchRange, static_cast<float>(m_numberOfRanges - 1)); + + // The words "lower" and "higher" refer to the table data having + // the lower and higher numbers of partials. It's a little confusing + // since the range index gets larger the more partials we cull out. + // So the lower table data will have a larger range index. + unsigned rangeIndex1 = static_cast<unsigned>(pitchRange); + unsigned rangeIndex2 = + rangeIndex1 < m_numberOfRanges - 1 ? rangeIndex1 + 1 : rangeIndex1; + + if (!m_bandLimitedTables[rangeIndex1].get()) + createBandLimitedTables(fundamentalFrequency, rangeIndex1); + + if (!m_bandLimitedTables[rangeIndex2].get()) + createBandLimitedTables(fundamentalFrequency, rangeIndex2); + + lowerWaveData = m_bandLimitedTables[rangeIndex2]->Elements(); + higherWaveData = m_bandLimitedTables[rangeIndex1]->Elements(); + + // Ranges from 0 -> 1 to interpolate between lower -> higher. + tableInterpolationFactor = rangeIndex2 - pitchRange; +} + +unsigned PeriodicWave::maxNumberOfPartials() const { + return m_periodicWaveSize / 2; +} + +unsigned PeriodicWave::numberOfPartialsForRange(unsigned rangeIndex) const { + // Number of cents below nyquist where we cull partials. + float centsToCull = rangeIndex * m_centsPerRange; + + // A value from 0 -> 1 representing what fraction of the partials to keep. + float cullingScale = exp2(-centsToCull / 1200); + + // The very top range will have all the partials culled. + unsigned numberOfPartials = cullingScale * maxNumberOfPartials(); + + return numberOfPartials; +} + +// Convert into time-domain wave buffers. +// One table is created for each range for non-aliasing playback +// at different playback rates. Thus, higher ranges have more +// high-frequency partials culled out. +void PeriodicWave::createBandLimitedTables(float fundamentalFrequency, + unsigned rangeIndex) { + unsigned fftSize = m_periodicWaveSize; + unsigned i; + + const float* realData = m_realComponents->Elements(); + const float* imagData = m_imagComponents->Elements(); + + // This FFTBlock is used to cull partials (represented by frequency bins). + FFTBlock frame(fftSize); + + // Find the starting bin where we should start culling the aliasing + // partials for this pitch range. We need to clear out the highest + // frequencies to band-limit the waveform. + unsigned numberOfPartials = numberOfPartialsForRange(rangeIndex); + // Also limit to the number of components that are provided. + numberOfPartials = std::min(numberOfPartials, m_numberOfComponents - 1); + + // Limit number of partials to those below Nyquist frequency + float nyquist = 0.5 * m_sampleRate; + if (fundamentalFrequency != 0.0) { + numberOfPartials = + std::min(numberOfPartials, (unsigned)(nyquist / fundamentalFrequency)); + } + + // Copy from loaded frequency data and generate complex conjugate + // because of the way the inverse FFT is defined. + // The coefficients of higher partials remain zero, as initialized in + // the FFTBlock constructor. + for (i = 0; i < numberOfPartials + 1; ++i) { + frame.RealData(i) = realData[i]; + frame.ImagData(i) = -imagData[i]; + } + + // Clear any DC-offset. + frame.RealData(0) = 0; + // Clear value which has no effect. + frame.ImagData(0) = 0; + + // Create the band-limited table. + m_bandLimitedTables[rangeIndex] = + MakeUnique<AlignedAudioFloatArray>(m_periodicWaveSize); + + // Apply an inverse FFT to generate the time-domain table data. + float* data = m_bandLimitedTables[rangeIndex]->Elements(); + frame.GetInverseWithoutScaling(data); + + // For the first range (which has the highest power), calculate + // its peak value then compute normalization scale. + if (m_disableNormalization) { + // See Bug 1424906, results need to be scaled by 0.5 even + // when normalization is disabled. + m_normalizationScale = 0.5; + } else if (!rangeIndex) { + float maxValue; + maxValue = AudioBufferPeakValue(data, m_periodicWaveSize); + + if (maxValue) m_normalizationScale = 1.0f / maxValue; + } + + // Apply normalization scale. + AudioBufferInPlaceScale(data, m_normalizationScale, m_periodicWaveSize); +} + +void PeriodicWave::generateBasicWaveform(OscillatorType shape) { + const float piFloat = float(M_PI); + unsigned fftSize = periodicWaveSize(); + unsigned halfSize = fftSize / 2; + + m_numberOfComponents = halfSize; + m_realComponents = MakeUnique<AudioFloatArray>(halfSize); + m_imagComponents = MakeUnique<AudioFloatArray>(halfSize); + float* realP = m_realComponents->Elements(); + float* imagP = m_imagComponents->Elements(); + + // Clear DC and imag value which is ignored. + realP[0] = 0; + imagP[0] = 0; + + for (unsigned n = 1; n < halfSize; ++n) { + float omega = 2 * piFloat * n; + float invOmega = 1 / omega; + + // Fourier coefficients according to standard definition. + float a; // Coefficient for cos(). + float b; // Coefficient for sin(). + + // Calculate Fourier coefficients depending on the shape. + // Note that the overall scaling (magnitude) of the waveforms + // is normalized in createBandLimitedTables(). + switch (shape) { + case OscillatorType::Sine: + // Standard sine wave function. + a = 0; + b = (n == 1) ? 1 : 0; + break; + case OscillatorType::Square: + // Square-shaped waveform with the first half its maximum value + // and the second half its minimum value. + a = 0; + b = invOmega * ((n & 1) ? 2 : 0); + break; + case OscillatorType::Sawtooth: + // Sawtooth-shaped waveform with the first half ramping from + // zero to maximum and the second half from minimum to zero. + a = 0; + b = -invOmega * cos(0.5 * omega); + break; + case OscillatorType::Triangle: + // Triangle-shaped waveform going from its maximum value to + // its minimum value then back to the maximum value. + a = 0; + if (n & 1) { + b = 2 * (2 / (n * piFloat) * 2 / (n * piFloat)) * + ((((n - 1) >> 1) & 1) ? -1 : 1); + } else { + b = 0; + } + break; + default: + MOZ_ASSERT_UNREACHABLE("invalid oscillator type"); + a = 0; + b = 0; + break; + } + + realP[n] = a; + imagP[n] = b; + } +} + +} // namespace WebCore |