/* ============================================================================== This file is part of the JUCE framework. Copyright (c) Raw Material Software Limited JUCE is an open source framework subject to commercial or open source licensing. By downloading, installing, or using the JUCE framework, or combining the JUCE framework with any other source code, object code, content or any other copyrightable work, you agree to the terms of the JUCE End User Licence Agreement, and all incorporated terms including the JUCE Privacy Policy and the JUCE Website Terms of Service, as applicable, which will bind you. If you do not agree to the terms of these agreements, we will not license the JUCE framework to you, and you must discontinue the installation or download process and cease use of the JUCE framework. JUCE End User Licence Agreement: https://juce.com/legal/juce-8-licence/ JUCE Privacy Policy: https://juce.com/juce-privacy-policy JUCE Website Terms of Service: https://juce.com/juce-website-terms-of-service/ Or: You may also use this code under the terms of the AGPLv3: https://www.gnu.org/licenses/agpl-3.0.en.html THE JUCE FRAMEWORK IS PROVIDED "AS IS" WITHOUT ANY WARRANTY, AND ALL WARRANTIES, WHETHER EXPRESSED OR IMPLIED, INCLUDING WARRANTY OF MERCHANTABILITY OR FITNESS FOR A PARTICULAR PURPOSE, ARE DISCLAIMED. ============================================================================== */ namespace juce { ResamplingAudioSource::ResamplingAudioSource (AudioSource* const inputSource, const bool deleteInputWhenDeleted, const int channels) : input (inputSource, deleteInputWhenDeleted), numChannels (channels) { jassert (input != nullptr); zeromem (coefficients, sizeof (coefficients)); } ResamplingAudioSource::~ResamplingAudioSource() {} void ResamplingAudioSource::setResamplingRatio (const double samplesInPerOutputSample) { jassert (samplesInPerOutputSample > 0); const SpinLock::ScopedLockType sl (ratioLock); ratio = jmax (0.0, samplesInPerOutputSample); } void ResamplingAudioSource::prepareToPlay (int samplesPerBlockExpected, double sampleRate) { const SpinLock::ScopedLockType sl (ratioLock); auto scaledBlockSize = roundToInt (samplesPerBlockExpected * ratio); input->prepareToPlay (scaledBlockSize, sampleRate * ratio); buffer.setSize (numChannels, scaledBlockSize + 32); filterStates.calloc (numChannels); srcBuffers.calloc (numChannels); destBuffers.calloc (numChannels); createLowPass (ratio); flushBuffers(); } void ResamplingAudioSource::flushBuffers() { const ScopedLock sl (callbackLock); buffer.clear(); bufferPos = 0; sampsInBuffer = 0; subSampleOffset = 0.0; resetFilters(); } void ResamplingAudioSource::releaseResources() { input->releaseResources(); buffer.setSize (numChannels, 0); } void ResamplingAudioSource::getNextAudioBlock (const AudioSourceChannelInfo& info) { const ScopedLock sl (callbackLock); double localRatio; { const SpinLock::ScopedLockType ratioSl (ratioLock); localRatio = ratio; } if (! approximatelyEqual (lastRatio, localRatio)) { createLowPass (localRatio); lastRatio = localRatio; } const int sampsNeeded = roundToInt (info.numSamples * localRatio) + 3; int bufferSize = buffer.getNumSamples(); if (bufferSize < sampsNeeded + 8) { bufferPos %= bufferSize; bufferSize = sampsNeeded + 32; buffer.setSize (buffer.getNumChannels(), bufferSize, true, true); } bufferPos %= bufferSize; int endOfBufferPos = bufferPos + sampsInBuffer; const int channelsToProcess = jmin (numChannels, info.buffer->getNumChannels()); while (sampsNeeded > sampsInBuffer) { endOfBufferPos %= bufferSize; int numToDo = jmin (sampsNeeded - sampsInBuffer, bufferSize - endOfBufferPos); AudioSourceChannelInfo readInfo (&buffer, endOfBufferPos, numToDo); input->getNextAudioBlock (readInfo); if (localRatio > 1.0001) { // for down-sampling, pre-apply the filter for (int i = channelsToProcess; --i >= 0;) applyFilter (buffer.getWritePointer (i, endOfBufferPos), numToDo, filterStates[i]); } sampsInBuffer += numToDo; endOfBufferPos += numToDo; } for (int channel = 0; channel < channelsToProcess; ++channel) { destBuffers[channel] = info.buffer->getWritePointer (channel, info.startSample); srcBuffers[channel] = buffer.getReadPointer (channel); } int nextPos = (bufferPos + 1) % bufferSize; for (int m = info.numSamples; --m >= 0;) { jassert (sampsInBuffer > 0 && nextPos != endOfBufferPos); const float alpha = (float) subSampleOffset; for (int channel = 0; channel < channelsToProcess; ++channel) *destBuffers[channel]++ = srcBuffers[channel][bufferPos] + alpha * (srcBuffers[channel][nextPos] - srcBuffers[channel][bufferPos]); subSampleOffset += localRatio; while (subSampleOffset >= 1.0) { if (++bufferPos >= bufferSize) bufferPos = 0; --sampsInBuffer; nextPos = (bufferPos + 1) % bufferSize; subSampleOffset -= 1.0; } } if (localRatio < 0.9999) { // for up-sampling, apply the filter after transposing for (int i = channelsToProcess; --i >= 0;) applyFilter (info.buffer->getWritePointer (i, info.startSample), info.numSamples, filterStates[i]); } else if (localRatio <= 1.0001 && info.numSamples > 0) { // if the filter's not currently being applied, keep it stoked with the last couple of samples to avoid discontinuities for (int i = channelsToProcess; --i >= 0;) { const float* const endOfBuffer = info.buffer->getReadPointer (i, info.startSample + info.numSamples - 1); FilterState& fs = filterStates[i]; if (info.numSamples > 1) { fs.y2 = fs.x2 = *(endOfBuffer - 1); } else { fs.y2 = fs.y1; fs.x2 = fs.x1; } fs.y1 = fs.x1 = *endOfBuffer; } } jassert (sampsInBuffer >= 0); } void ResamplingAudioSource::createLowPass (const double frequencyRatio) { const double proportionalRate = (frequencyRatio > 1.0) ? 0.5 / frequencyRatio : 0.5 * frequencyRatio; const double n = 1.0 / std::tan (MathConstants::pi * jmax (0.001, proportionalRate)); const double nSquared = n * n; const double c1 = 1.0 / (1.0 + MathConstants::sqrt2 * n + nSquared); setFilterCoefficients (c1, c1 * 2.0f, c1, 1.0, c1 * 2.0 * (1.0 - nSquared), c1 * (1.0 - MathConstants::sqrt2 * n + nSquared)); } void ResamplingAudioSource::setFilterCoefficients (double c1, double c2, double c3, double c4, double c5, double c6) { const double a = 1.0 / c4; c1 *= a; c2 *= a; c3 *= a; c5 *= a; c6 *= a; coefficients[0] = c1; coefficients[1] = c2; coefficients[2] = c3; coefficients[3] = c4; coefficients[4] = c5; coefficients[5] = c6; } void ResamplingAudioSource::resetFilters() { if (filterStates != nullptr) filterStates.clear ((size_t) numChannels); } void ResamplingAudioSource::applyFilter (float* samples, int num, FilterState& fs) { while (--num >= 0) { const double in = *samples; double out = coefficients[0] * in + coefficients[1] * fs.x1 + coefficients[2] * fs.x2 - coefficients[4] * fs.y1 - coefficients[5] * fs.y2; #if JUCE_INTEL if (! (out < -1.0e-8 || out > 1.0e-8)) out = 0; #endif fs.x2 = fs.x1; fs.x1 = in; fs.y2 = fs.y1; fs.y1 = out; *samples++ = (float) out; } } } // namespace juce