/* ============================================================================== This file is part of the JUCE library. Copyright (c) 2020 - Raw Material Software Limited JUCE is an open source library subject to commercial or open-source licensing. By using JUCE, you agree to the terms of both the JUCE 6 End-User License Agreement and JUCE Privacy Policy (both effective as of the 16th June 2020). End User License Agreement: www.juce.com/juce-6-licence Privacy Policy: www.juce.com/juce-privacy-policy Or: You may also use this code under the terms of the GPL v3 (see www.gnu.org/licenses). JUCE IS PROVIDED "AS IS" WITHOUT ANY WARRANTY, AND ALL WARRANTIES, WHETHER EXPRESSED OR IMPLIED, INCLUDING MERCHANTABILITY AND FITNESS FOR PURPOSE, ARE DISCLAIMED. ============================================================================== */ namespace juce { namespace dsp { //============================================================================== template DryWetMixer::DryWetMixer() : DryWetMixer (0) { } template DryWetMixer::DryWetMixer (int maximumWetLatencyInSamplesIn) : dryDelayLine (maximumWetLatencyInSamplesIn), maximumWetLatencyInSamples (maximumWetLatencyInSamplesIn) { dryDelayLine.setDelay (0); update(); reset(); } //============================================================================== template void DryWetMixer::setMixingRule (MixingRule newRule) { currentMixingRule = newRule; update(); } template void DryWetMixer::setWetMixProportion (SampleType newWetMixProportion) { jassert (isPositiveAndNotGreaterThan (newWetMixProportion, 1.0)); mix = jlimit (static_cast (0.0), static_cast (1.0), newWetMixProportion); update(); } template void DryWetMixer::setWetLatency (SampleType wetLatencySamples) { dryDelayLine.setDelay (wetLatencySamples); } //============================================================================== template void DryWetMixer::prepare (const ProcessSpec& spec) { jassert (spec.sampleRate > 0); jassert (spec.numChannels > 0); sampleRate = spec.sampleRate; dryDelayLine.prepare (spec); bufferDry.setSize ((int) spec.numChannels, (int) spec.maximumBlockSize, false, false, true); update(); reset(); } template void DryWetMixer::reset() { dryVolume.reset (sampleRate, 0.05); wetVolume.reset (sampleRate, 0.05); dryDelayLine.reset(); fifo = SingleThreadedAbstractFifo (nextPowerOfTwo (bufferDry.getNumSamples())); bufferDry.setSize (bufferDry.getNumChannels(), fifo.getSize(), false, false, true); } //============================================================================== template void DryWetMixer::pushDrySamples (const AudioBlock drySamples) { jassert (drySamples.getNumChannels() <= (size_t) bufferDry.getNumChannels()); jassert (drySamples.getNumSamples() <= (size_t) fifo.getRemainingSpace()); auto offset = 0; for (const auto& range : fifo.write ((int) drySamples.getNumSamples())) { if (range.getLength() == 0) continue; auto block = AudioBlock (bufferDry).getSubsetChannelBlock (0, drySamples.getNumChannels()) .getSubBlock ((size_t) range.getStart(), (size_t) range.getLength()); auto inputBlock = drySamples.getSubBlock ((size_t) offset, (size_t) range.getLength()); if (maximumWetLatencyInSamples == 0) block.copyFrom (inputBlock); else dryDelayLine.process (ProcessContextNonReplacing (inputBlock, block)); offset += range.getLength(); } } template void DryWetMixer::mixWetSamples (AudioBlock inOutBlock) { inOutBlock.multiplyBy (wetVolume); jassert (inOutBlock.getNumSamples() <= (size_t) fifo.getNumReadable()); auto offset = 0; for (const auto& range : fifo.read ((int) inOutBlock.getNumSamples())) { if (range.getLength() == 0) continue; auto block = AudioBlock (bufferDry).getSubsetChannelBlock (0, inOutBlock.getNumChannels()) .getSubBlock ((size_t) range.getStart(), (size_t) range.getLength()); block.multiplyBy (dryVolume); inOutBlock.getSubBlock ((size_t) offset).add (block); offset += range.getLength(); } } //============================================================================== template void DryWetMixer::update() { SampleType dryValue, wetValue; switch (currentMixingRule) { case MixingRule::balanced: dryValue = static_cast (2.0) * jmin (static_cast (0.5), static_cast (1.0) - mix); wetValue = static_cast (2.0) * jmin (static_cast (0.5), mix); break; case MixingRule::linear: dryValue = static_cast (1.0) - mix; wetValue = mix; break; case MixingRule::sin3dB: dryValue = static_cast (std::sin (0.5 * MathConstants::pi * (1.0 - mix))); wetValue = static_cast (std::sin (0.5 * MathConstants::pi * mix)); break; case MixingRule::sin4p5dB: dryValue = static_cast (std::pow (std::sin (0.5 * MathConstants::pi * (1.0 - mix)), 1.5)); wetValue = static_cast (std::pow (std::sin (0.5 * MathConstants::pi * mix), 1.5)); break; case MixingRule::sin6dB: dryValue = static_cast (std::pow (std::sin (0.5 * MathConstants::pi * (1.0 - mix)), 2.0)); wetValue = static_cast (std::pow (std::sin (0.5 * MathConstants::pi * mix), 2.0)); break; case MixingRule::squareRoot3dB: dryValue = std::sqrt (static_cast (1.0) - mix); wetValue = std::sqrt (mix); break; case MixingRule::squareRoot4p5dB: dryValue = static_cast (std::pow (std::sqrt (1.0 - mix), 1.5)); wetValue = static_cast (std::pow (std::sqrt (mix), 1.5)); break; default: dryValue = jmin (static_cast (0.5), static_cast (1.0) - mix); wetValue = jmin (static_cast (0.5), mix); break; } dryVolume.setTargetValue (dryValue); wetVolume.setTargetValue (wetValue); } //============================================================================== template class DryWetMixer; template class DryWetMixer; //============================================================================== //============================================================================== #if JUCE_UNIT_TESTS struct DryWetMixerTests : public UnitTest { DryWetMixerTests() : UnitTest ("DryWetMixer", UnitTestCategories::dsp) {} enum class Kind { down, up }; static auto getRampBuffer (ProcessSpec spec, Kind kind) { AudioBuffer buffer ((int) spec.numChannels, (int) spec.maximumBlockSize); for (uint32_t sample = 0; sample < spec.maximumBlockSize; ++sample) { for (uint32_t channel = 0; channel < spec.numChannels; ++channel) { const auto ramp = kind == Kind::up ? sample : spec.maximumBlockSize - sample; buffer.setSample ((int) channel, (int) sample, jmap ((float) ramp, 0.0f, (float) spec.maximumBlockSize, 0.0f, 1.0f)); } } return buffer; } void runTest() override { constexpr ProcessSpec spec { 44100.0, 512, 2 }; constexpr auto numBlocks = 5; const auto wetBuffer = getRampBuffer (spec, Kind::up); const auto dryBuffer = getRampBuffer (spec, Kind::down); for (auto maxLatency : { 0, 100, 200, 512 }) { beginTest ("Mixer can push multiple small buffers"); { DryWetMixer mixer (maxLatency); mixer.setWetMixProportion (0.5f); mixer.prepare (spec); for (auto block = 0; block < numBlocks; ++block) { // Push samples one-by-one for (uint32_t sample = 0; sample < spec.maximumBlockSize; ++sample) mixer.pushDrySamples (AudioBlock (dryBuffer).getSubBlock (sample, 1)); // Mix wet samples in one go auto outputBlock = wetBuffer; mixer.mixWetSamples ({ outputBlock }); // The output block should contain the wet and dry samples averaged for (uint32_t sample = 0; sample < spec.maximumBlockSize; ++sample) { for (uint32_t channel = 0; channel < spec.numChannels; ++channel) { const auto outputValue = outputBlock.getSample ((int) channel, (int) sample); expectWithinAbsoluteError (outputValue, 0.5f, 0.0001f); } } } } beginTest ("Mixer can pop multiple small buffers"); { DryWetMixer mixer (maxLatency); mixer.setWetMixProportion (0.5f); mixer.prepare (spec); for (auto block = 0; block < numBlocks; ++block) { // Push samples in one go mixer.pushDrySamples ({ dryBuffer }); // Process wet samples one-by-one for (uint32_t sample = 0; sample < spec.maximumBlockSize; ++sample) { AudioBuffer outputBlock ((int) spec.numChannels, 1); AudioBlock (wetBuffer).getSubBlock (sample, 1).copyTo (outputBlock); mixer.mixWetSamples ({ outputBlock }); // The output block should contain the wet and dry samples averaged for (uint32_t channel = 0; channel < spec.numChannels; ++channel) { const auto outputValue = outputBlock.getSample ((int) channel, 0); expectWithinAbsoluteError (outputValue, 0.5f, 0.0001f); } } } } beginTest ("Mixer can push and pop multiple small buffers"); { DryWetMixer mixer (maxLatency); mixer.setWetMixProportion (0.5f); mixer.prepare (spec); for (auto block = 0; block < numBlocks; ++block) { // Push dry samples and process wet samples one-by-one for (uint32_t sample = 0; sample < spec.maximumBlockSize; ++sample) { mixer.pushDrySamples (AudioBlock (dryBuffer).getSubBlock (sample, 1)); AudioBuffer outputBlock ((int) spec.numChannels, 1); AudioBlock (wetBuffer).getSubBlock (sample, 1).copyTo (outputBlock); mixer.mixWetSamples ({ outputBlock }); // The output block should contain the wet and dry samples averaged for (uint32_t channel = 0; channel < spec.numChannels; ++channel) { const auto outputValue = outputBlock.getSample ((int) channel, 0); expectWithinAbsoluteError (outputValue, 0.5f, 0.0001f); } } } } beginTest ("Mixer can push and pop full-sized blocks after encountering a shorter block"); { DryWetMixer mixer (maxLatency); mixer.setWetMixProportion (0.5f); mixer.prepare (spec); constexpr auto shortBlockLength = spec.maximumBlockSize / 2; AudioBuffer shortBlock (spec.numChannels, shortBlockLength); mixer.pushDrySamples (AudioBlock (dryBuffer).getSubBlock (shortBlockLength)); mixer.mixWetSamples ({ shortBlock }); for (auto block = 0; block < numBlocks; ++block) { // Push a full block of dry samples mixer.pushDrySamples ({ dryBuffer }); // Mix a full block of wet samples auto outputBlock = wetBuffer; mixer.mixWetSamples ({ outputBlock }); // The output block should contain the wet and dry samples averaged for (uint32_t sample = 0; sample < spec.maximumBlockSize; ++sample) { for (uint32_t channel = 0; channel < spec.numChannels; ++channel) { const auto outputValue = outputBlock.getSample ((int) channel, (int) sample); expectWithinAbsoluteError (outputValue, 0.5f, 0.0001f); } } } } } } }; static const DryWetMixerTests dryWetMixerTests; #endif } // namespace dsp } // namespace juce