Chris@0: 
Chris@0: #include "ConstrainedHarmonicPeak.h"
Chris@0: 
Chris@0: #include <cmath>
Chris@0: #include <cstdio>
Chris@0: 
Chris@0: using std::cerr;
Chris@0: using std::endl;
Chris@0: using std::vector;
Chris@0: 
Chris@0: ConstrainedHarmonicPeak::ConstrainedHarmonicPeak(float inputSampleRate) :
Chris@0:     Plugin(inputSampleRate),
Chris@0:     m_blockSize(0),
Chris@0:     m_minFreq(0),
Chris@1:     m_maxFreq(inputSampleRate/2),
Chris@1:     m_harmonics(5)
Chris@0: {
Chris@0: }
Chris@0: 
Chris@0: ConstrainedHarmonicPeak::~ConstrainedHarmonicPeak()
Chris@0: {
Chris@0: }
Chris@0: 
Chris@0: string
Chris@0: ConstrainedHarmonicPeak::getIdentifier() const
Chris@0: {
Chris@0:     return "constrainedharmonicpeak";
Chris@0: }
Chris@0: 
Chris@0: string
Chris@0: ConstrainedHarmonicPeak::getName() const
Chris@0: {
Chris@0:     return "Frequency-Constrained Harmonic Peak";
Chris@0: }
Chris@0: 
Chris@0: string
Chris@0: ConstrainedHarmonicPeak::getDescription() const
Chris@0: {
Chris@0:     //!!! Return something helpful here!
Chris@0:     return "";
Chris@0: }
Chris@0: 
Chris@0: string
Chris@0: ConstrainedHarmonicPeak::getMaker() const
Chris@0: {
Chris@0:     return "Queen Mary, University of London";
Chris@0: }
Chris@0: 
Chris@0: int
Chris@0: ConstrainedHarmonicPeak::getPluginVersion() const
Chris@0: {
Chris@0:     return 1;
Chris@0: }
Chris@0: 
Chris@0: string
Chris@0: ConstrainedHarmonicPeak::getCopyright() const
Chris@0: {
Chris@0:     return "GPL";
Chris@0: }
Chris@0: 
Chris@0: ConstrainedHarmonicPeak::InputDomain
Chris@0: ConstrainedHarmonicPeak::getInputDomain() const
Chris@0: {
Chris@0:     return FrequencyDomain;
Chris@0: }
Chris@0: 
Chris@0: size_t
Chris@0: ConstrainedHarmonicPeak::getPreferredBlockSize() const
Chris@0: {
Chris@0:     return 2048;
Chris@0: }
Chris@0: 
Chris@0: size_t 
Chris@0: ConstrainedHarmonicPeak::getPreferredStepSize() const
Chris@0: {
Chris@0:     return 512;
Chris@0: }
Chris@0: 
Chris@0: size_t
Chris@0: ConstrainedHarmonicPeak::getMinChannelCount() const
Chris@0: {
Chris@0:     return 1;
Chris@0: }
Chris@0: 
Chris@0: size_t
Chris@0: ConstrainedHarmonicPeak::getMaxChannelCount() const
Chris@0: {
Chris@0:     return 1;
Chris@0: }
Chris@0: 
Chris@0: ConstrainedHarmonicPeak::ParameterList
Chris@0: ConstrainedHarmonicPeak::getParameterDescriptors() const
Chris@0: {
Chris@0:     ParameterList list;
Chris@0: 
Chris@0:     ParameterDescriptor d;
Chris@0:     d.identifier = "minfreq";
Chris@0:     d.name = "Minimum frequency";
Chris@0:     d.description = "";
Chris@0:     d.unit = "Hz";
Chris@0:     d.minValue = 0;
Chris@0:     d.maxValue = m_inputSampleRate/2;
Chris@0:     d.defaultValue = 0;
Chris@0:     d.isQuantized = false;
Chris@0:     list.push_back(d);
Chris@0: 
Chris@0:     d.identifier = "maxfreq";
Chris@0:     d.name = "Maximum frequency";
Chris@0:     d.description = "";
Chris@0:     d.unit = "Hz";
Chris@0:     d.minValue = 0;
Chris@0:     d.maxValue = m_inputSampleRate/2;
Chris@0:     d.defaultValue = 0;
Chris@0:     d.isQuantized = false;
Chris@0:     list.push_back(d);
Chris@0: 
Chris@1:     d.identifier = "harmonics";
Chris@1:     d.name = "Harmonics";
Chris@1:     d.description = "Maximum number of harmonics to consider";
Chris@1:     d.unit = "";
Chris@1:     d.minValue = 1;
Chris@1:     d.maxValue = 20;
Chris@1:     d.defaultValue = 5;
Chris@1:     d.isQuantized = true;
Chris@1:     d.quantizeStep = 1;
Chris@1:     list.push_back(d);
Chris@1: 
Chris@0:     return list;
Chris@0: }
Chris@0: 
Chris@0: float
Chris@0: ConstrainedHarmonicPeak::getParameter(string identifier) const
Chris@0: {
Chris@0:     if (identifier == "minfreq") {
Chris@0: 	return m_minFreq;
Chris@0:     } else if (identifier == "maxfreq") {
Chris@0: 	return m_maxFreq;
Chris@1:     } else if (identifier == "harmonics") {
Chris@1: 	return m_harmonics;
Chris@0:     }
Chris@0:     return 0;
Chris@0: }
Chris@0: 
Chris@0: void
Chris@0: ConstrainedHarmonicPeak::setParameter(string identifier, float value) 
Chris@0: {
Chris@0:     if (identifier == "minfreq") {
Chris@0: 	m_minFreq = value;
Chris@0:     } else if (identifier == "maxfreq") {
Chris@0: 	m_maxFreq = value;
Chris@1:     } else if (identifier == "harmonics") {
Chris@1: 	m_harmonics = int(round(value));
Chris@0:     }
Chris@0: }
Chris@0: 
Chris@0: ConstrainedHarmonicPeak::ProgramList
Chris@0: ConstrainedHarmonicPeak::getPrograms() const
Chris@0: {
Chris@0:     ProgramList list;
Chris@0:     return list;
Chris@0: }
Chris@0: 
Chris@0: string
Chris@0: ConstrainedHarmonicPeak::getCurrentProgram() const
Chris@0: {
Chris@0:     return ""; // no programs
Chris@0: }
Chris@0: 
Chris@0: void
Chris@0: ConstrainedHarmonicPeak::selectProgram(string name)
Chris@0: {
Chris@0: }
Chris@0: 
Chris@0: ConstrainedHarmonicPeak::OutputList
Chris@0: ConstrainedHarmonicPeak::getOutputDescriptors() const
Chris@0: {
Chris@0:     OutputList list;
Chris@0: 
Chris@0:     OutputDescriptor d;
Chris@0:     d.identifier = "peak";
Chris@0:     d.name = "Peak frequency";
Chris@0:     d.description = "";
Chris@0:     d.unit = "Hz";
Chris@0:     d.sampleType = OutputDescriptor::OneSamplePerStep;
Chris@0:     d.hasDuration = false;
Chris@0:     list.push_back(d);
Chris@0: 
Chris@0:     return list;
Chris@0: }
Chris@0: 
Chris@0: bool
Chris@0: ConstrainedHarmonicPeak::initialise(size_t channels, size_t stepSize, size_t blockSize)
Chris@0: {
Chris@0:     if (channels < getMinChannelCount() ||
Chris@0: 	channels > getMaxChannelCount()) {
Chris@0: 	cerr << "ConstrainedHarmonicPeak::initialise: ERROR: channels " << channels
Chris@0: 	     << " out of acceptable range " << getMinChannelCount()
Chris@0: 	     << " -> " << getMaxChannelCount() << endl;
Chris@0: 	return false;
Chris@0:     }
Chris@0: 
Chris@0:     m_blockSize = blockSize;
Chris@0: 
Chris@0:     return true;
Chris@0: }
Chris@0: 
Chris@0: void
Chris@0: ConstrainedHarmonicPeak::reset()
Chris@0: {
Chris@0: }
Chris@0: 
Chris@1: double
Chris@1: ConstrainedHarmonicPeak::findInterpolatedPeak(const double *in, 
Chris@1: 					      int peakbin,
Chris@1: 					      int bins)
Chris@1: {
Chris@1:     // duplicate with SimpleCepstrum plugin
Chris@1:     // after jos, 
Chris@1:     // https://ccrma.stanford.edu/~jos/sasp/Quadratic_Interpolation_Spectral_Peaks.html
Chris@1: 
Chris@1:     if (peakbin < 1 || peakbin > bins - 2) {
Chris@1:         return peakbin;
Chris@1:     }
Chris@1: 
Chris@1:     double alpha = in[peakbin-1];
Chris@1:     double beta  = in[peakbin];
Chris@1:     double gamma = in[peakbin+1];
Chris@1: 
Chris@1:     double denom = (alpha - 2*beta + gamma);
Chris@1: 
Chris@1:     if (denom == 0) {
Chris@1:         // flat
Chris@1:         return peakbin;
Chris@1:     }
Chris@1: 
Chris@1:     double p = ((alpha - gamma) / denom) / 2.0;
Chris@1: 
Chris@1:     return double(peakbin) + p;
Chris@1: }
Chris@1: 
Chris@0: ConstrainedHarmonicPeak::FeatureSet
Chris@0: ConstrainedHarmonicPeak::process(const float *const *inputBuffers, Vamp::RealTime timestamp)
Chris@0: {
Chris@0:     FeatureSet fs;
Chris@0: 
Chris@1:     int hs = m_blockSize/2;
Chris@1: 
Chris@1:     double *mags = new double[hs+1];
Chris@1:     for (int i = 0; i <= hs; ++i) {
Chris@1: 	mags[i] = sqrtf(inputBuffers[0][i*2] * inputBuffers[0][i*2] +
Chris@1: 			inputBuffers[0][i*2+1] * inputBuffers[0][i*2+1]);
Chris@1:     }
Chris@1: 
Chris@1:     // bin freq is bin * samplerate / fftsize
Chris@1: 
Chris@1:     int minbin = int(floor((m_minFreq * m_blockSize) / m_inputSampleRate));
Chris@1:     int maxbin = int(ceil((m_maxFreq * m_blockSize) / m_inputSampleRate));
Chris@1:     if (minbin > hs) minbin = hs;
Chris@1:     if (maxbin > hs) maxbin = hs;
Chris@1:     if (maxbin <= minbin) return fs;
Chris@1: 
Chris@1:     double *hps = new double[maxbin - minbin + 1];
Chris@1: 
Chris@1:     // HPS in dB after MzHarmonicSpectrum
Chris@1: 
Chris@1:     for (int bin = minbin; bin <= maxbin; ++bin) {
Chris@1: 
Chris@1: 	int i = bin - minbin;
Chris@1: 	hps[i] = 1.0;
Chris@1: 
Chris@1: 	int contributing = 0;
Chris@1: 
Chris@1: 	for (int j = 1; j <= m_harmonics; ++j) {
Chris@1: 	    if (j * bin > hs) break;
Chris@1: 	    hps[i] *= mags[j * bin];
Chris@1: 	    ++contributing;
Chris@1: 	}
Chris@1: 
Chris@1: 	if (hps[i] <= 0.0) {
Chris@1: 	    hps[i] = -120.0;
Chris@1: 	} else {
Chris@1: 	    hps[i] = 20.0 / contributing * log10(hps[i]);
Chris@1: 	}
Chris@1:     }
Chris@1: 
Chris@1:     double maxdb = -120.0;
Chris@1:     int maxidx = 0;
Chris@1:     for (int i = 0; i <= maxbin - minbin; ++i) {
Chris@1: 	if (hps[i] > maxdb) {
Chris@1: 	    maxdb = hps[i];
Chris@1: 	    maxidx = i;
Chris@1: 	}
Chris@1:     }
Chris@1: 
Chris@1:     double interpolated = findInterpolatedPeak(hps, maxidx, maxbin - minbin + 1);
Chris@1:     interpolated = interpolated + minbin;
Chris@1: 
Chris@1:     double freq = interpolated * m_inputSampleRate / m_blockSize;
Chris@1: 
Chris@1:     Feature f;
Chris@1:     f.values.push_back(freq);
Chris@1:     fs[0].push_back(f);
Chris@1: 
Chris@0:     return fs;
Chris@0: }
Chris@0: 
Chris@0: ConstrainedHarmonicPeak::FeatureSet
Chris@0: ConstrainedHarmonicPeak::getRemainingFeatures()
Chris@0: {
Chris@0:     FeatureSet fs;
Chris@0:     return fs;
Chris@0: }
Chris@0: