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Carla/source/modules/juce_dsp/widgets/juce_Phaser.h

juce_Phaser.h 7.1KB
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Add a few juce modules useful to be used somewhere else..
1 year ago
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  1. /*

  2.   ==============================================================================

  3. 

  4.    This file is part of the JUCE library.

  5.    Copyright (c) 2022 - Raw Material Software Limited

  6. 

  7.    JUCE is an open source library subject to commercial or open-source

  8.    licensing.

  9. 

  10.    By using JUCE, you agree to the terms of both the JUCE 7 End-User License

  11.    Agreement and JUCE Privacy Policy.

  12. 

  13.    End User License Agreement: www.juce.com/juce-7-licence

  14.    Privacy Policy: www.juce.com/juce-privacy-policy

  15. 

  16.    Or: You may also use this code under the terms of the GPL v3 (see

  17.    www.gnu.org/licenses).

  18. 

  19.    JUCE IS PROVIDED "AS IS" WITHOUT ANY WARRANTY, AND ALL WARRANTIES, WHETHER

  20.    EXPRESSED OR IMPLIED, INCLUDING MERCHANTABILITY AND FITNESS FOR PURPOSE, ARE

  21.    DISCLAIMED.

  22. 

  23.   ==============================================================================

  24. */

  25. 

  26. namespace juce

  27. {

  28. namespace dsp

  29. {

  30. 

  31. /**

  32.     A 6 stage phaser that modulates first order all-pass filters to create sweeping

  33.     notches in the magnitude frequency response.

  34. 

  35.     This audio effect can be controlled with standard phaser parameters: the speed

  36.     and depth of the LFO controlling the frequency response, a mix control, a

  37.     feedback control, and the centre frequency of the modulation.

  38. 

  39.     @tags{DSP}

  40. */

  41. template <typename SampleType>

  42. class Phaser

  43. {

  44. public:

  45.     //==============================================================================

  46.     /** Constructor. */

  47.     Phaser();

  48. 

  49.     //==============================================================================

  50.     /** Sets the rate (in Hz) of the LFO modulating the phaser all-pass filters. This

  51.         rate must be lower than 100 Hz.

  52.     */

  53.     void setRate (SampleType newRateHz);

  54. 

  55.     /** Sets the volume (between 0 and 1) of the LFO modulating the phaser all-pass

  56.         filters.

  57.     */

  58.     void setDepth (SampleType newDepth);

  59. 

  60.     /** Sets the centre frequency (in Hz) of the phaser all-pass filters modulation.

  61.     */

  62.     void setCentreFrequency (SampleType newCentreHz);

  63. 

  64.     /** Sets the feedback volume (between -1 and 1) of the phaser. Negative can be

  65.         used to get specific phaser sounds.

  66.     */

  67.     void setFeedback (SampleType newFeedback);

  68. 

  69.     /** Sets the amount of dry and wet signal in the output of the phaser (between 0

  70.         for full dry and 1 for full wet).

  71.     */

  72.     void setMix (SampleType newMix);

  73. 

  74.     //==============================================================================

  75.     /** Initialises the processor. */

  76.     void prepare (const ProcessSpec& spec);

  77. 

  78.     /** Resets the internal state variables of the processor. */

  79.     void reset();

  80. 

  81.     //==============================================================================

  82.     /** Processes the input and output samples supplied in the processing context. */

  83.     template <typename ProcessContext>

  84.     void process (const ProcessContext& context) noexcept

  85.     {

  86.         const auto& inputBlock = context.getInputBlock();

  87.         auto& outputBlock      = context.getOutputBlock();

  88.         const auto numChannels = outputBlock.getNumChannels();

  89.         const auto numSamples  = outputBlock.getNumSamples();

  90. 

  91.         jassert (inputBlock.getNumChannels() == numChannels);

  92.         jassert (inputBlock.getNumChannels() == lastOutput.size());

  93.         jassert (inputBlock.getNumSamples()  == numSamples);

  94. 

  95.         if (context.isBypassed)

  96.         {

  97.             outputBlock.copyFrom (inputBlock);

  98.             return;

  99.         }

  100. 

  101.         int numSamplesDown = 0;

  102.         auto counter = updateCounter;

  103. 

  104.         for (size_t i = 0; i < numSamples; ++i)

  105.         {

  106.             if (counter == 0)

  107.                 numSamplesDown++;

  108. 

  109.             counter++;

  110. 

  111.             if (counter == maxUpdateCounter)

  112.                 counter = 0;

  113.         }

  114. 

  115.         if (numSamplesDown > 0)

  116.         {

  117.             auto freqBlock = AudioBlock<SampleType>(bufferFrequency).getSubBlock (0, (size_t) numSamplesDown);

  118.             auto contextFreq = ProcessContextReplacing<SampleType> (freqBlock);

  119.             freqBlock.clear();

  120. 

  121.             osc.process (contextFreq);

  122.             freqBlock.multiplyBy (oscVolume);

  123.         }

  124. 

  125.         auto* freqSamples = bufferFrequency.getWritePointer (0);

  126. 

  127.         for (int i = 0; i < numSamplesDown; ++i)

  128.         {

  129.             auto lfo = jlimit (static_cast<SampleType> (0.0),

  130.                                static_cast<SampleType> (1.0),

  131.                                freqSamples[i] + normCentreFrequency);

  132. 

  133.             freqSamples[i] = mapToLog10 (lfo, static_cast<SampleType> (20.0),

  134.                                          static_cast<SampleType> (jmin (20000.0, 0.49 * sampleRate)));

  135.         }

  136. 

  137.         auto currentFrequency = filters[0]->getCutoffFrequency();

  138.         dryWet.pushDrySamples (inputBlock);

  139. 

  140.         for (size_t channel = 0; channel < numChannels; ++channel)

  141.         {

  142.             counter = updateCounter;

  143.             int k = 0;

  144. 

  145.             auto* inputSamples  = inputBlock .getChannelPointer (channel);

  146.             auto* outputSamples = outputBlock.getChannelPointer (channel);

  147. 

  148.             for (size_t i = 0; i < numSamples; ++i)

  149.             {

  150.                 auto input = inputSamples[i];

  151.                 auto output = input - lastOutput[channel];

  152. 

  153.                 if (i == 0 && counter != 0)

  154.                     for (int n = 0; n < numStages; ++n)

  155.                         filters[n]->setCutoffFrequency (currentFrequency);

  156. 

  157.                 if (counter == 0)

  158.                 {

  159.                     for (int n = 0; n < numStages; ++n)

  160.                         filters[n]->setCutoffFrequency (freqSamples[k]);

  161. 

  162.                     k++;

  163.                 }

  164. 

  165.                 for (int n = 0; n < numStages; ++n)

  166.                     output = filters[n]->processSample ((int) channel, output);

  167. 

  168.                 outputSamples[i] = output;

  169.                 lastOutput[channel] = output * feedbackVolume[channel].getNextValue();

  170. 

  171.                 counter++;

  172. 

  173.                 if (counter == maxUpdateCounter)

  174.                     counter = 0;

  175.             }

  176.         }

  177. 

  178.         dryWet.mixWetSamples (outputBlock);

  179.         updateCounter = (updateCounter + (int) numSamples) % maxUpdateCounter;

  180.     }

  181. 

  182. private:

  183.     //==============================================================================

  184.     void update();

  185. 

  186.     //==============================================================================

  187.     Oscillator<SampleType> osc;

  188.     OwnedArray<FirstOrderTPTFilter<SampleType>> filters;

  189.     SmoothedValue<SampleType, ValueSmoothingTypes::Linear> oscVolume;

  190.     std::vector<SmoothedValue<SampleType, ValueSmoothingTypes::Linear>> feedbackVolume { 2 };

  191.     DryWetMixer<SampleType> dryWet;

  192.     std::vector<SampleType> lastOutput { 2 };

  193.     AudioBuffer<SampleType> bufferFrequency;

  194.     SampleType normCentreFrequency = 0.5;

  195.     double sampleRate = 44100.0;

  196. 

  197.     int updateCounter = 0;

  198.     static constexpr int maxUpdateCounter = 4;

  199. 

  200.     SampleType rate = 1.0, depth = 0.5, feedback = 0.0, mix = 0.5;

  201.     SampleType centreFrequency = 1300.0;

  202.     static constexpr int numStages = 6;

  203. };

  204. 

  205. } // namespace dsp

  206. } // namespace juce