/* ============================================================================== This file is part of the JUCE library. Copyright (c) 2013 - Raw Material Software Ltd. Permission is granted to use this software under the terms of either: a) the GPL v2 (or any later version) b) the Affero GPL v3 Details of these licenses can be found at: www.gnu.org/licenses JUCE is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License for more details. ------------------------------------------------------------------------------ To release a closed-source product which uses JUCE, commercial licenses are available: visit www.juce.com for more information. ============================================================================== */ ResamplingAudioSource::ResamplingAudioSource (AudioSource* const inputSource, const bool deleteInputWhenDeleted, const int channels) : input (inputSource, deleteInputWhenDeleted), ratio (1.0), lastRatio (1.0), bufferPos (0), sampsInBuffer (0), subSampleOffset (0), 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); const int scaledBlockSize = roundToInt (samplesPerBlockExpected * ratio); input->prepareToPlay (scaledBlockSize, sampleRate * ratio); buffer.setSize (numChannels, scaledBlockSize + 32); filterStates.calloc ((size_t) numChannels); srcBuffers.calloc ((size_t) numChannels); destBuffers.calloc ((size_t) numChannels); createLowPass (ratio); flushBuffers(); } void ResamplingAudioSource::flushBuffers() { 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) { double localRatio; { const SpinLock::ScopedLockType sl (ratioLock); localRatio = ratio; } if (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 (double_Pi * jmax (0.001, proportionalRate)); const double nSquared = n * n; const double c1 = 1.0 / (1.0 + std::sqrt (2.0) * n + nSquared); setFilterCoefficients (c1, c1 * 2.0f, c1, 1.0, c1 * 2.0 * (1.0 - nSquared), c1 * (1.0 - std::sqrt (2.0) * 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; } }