/* ============================================================================== 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::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 final : 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 juce::dsp