Mercurial > hg > segmenter-vamp-plugin
view songparts/plugins/ChromagramPlugin.cpp @ 1:f44aa6d29642
Plugin Code - The main file is songparts.cpp
| author | maxzanoni76 <max.zanoni@eecs.qmul.ac.uk> |
|---|---|
| date | Wed, 11 Apr 2012 09:31:28 +0100 |
| parents | |
| children |
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/* -*- c-basic-offset: 4 indent-tabs-mode: nil -*- vi:set ts=8 sts=4 sw=4: */ /* QM Vamp Plugin Set Centre for Digital Music, Queen Mary, University of London. This program is free software; you can redistribute it and/or modify it under the terms of the GNU General Public License as published by the Free Software Foundation; either version 2 of the License, or (at your option) any later version. See the file COPYING included with this distribution for more information. */ #include "ChromagramPlugin.h" #include <base/Pitch.h> #include <dsp/chromagram/Chromagram.h> using std::string; using std::vector; using std::cerr; using std::endl; ChromagramPlugin::ChromagramPlugin(float inputSampleRate) : Vamp::Plugin(inputSampleRate), m_chromagram(0), m_step(0), m_block(0) { m_minMIDIPitch = 36; m_maxMIDIPitch = 96; m_tuningFrequency = 440; m_normalise = MathUtilities::NormaliseNone; m_bpo = 12; setupConfig(); } void ChromagramPlugin::setupConfig() { m_config.FS = lrintf(m_inputSampleRate); m_config.min = Pitch::getFrequencyForPitch (m_minMIDIPitch, 0, m_tuningFrequency); m_config.max = Pitch::getFrequencyForPitch (m_maxMIDIPitch, 0, m_tuningFrequency); m_config.BPO = m_bpo; m_config.CQThresh = 0.0054; m_config.normalise = m_normalise; m_step = 0; m_block = 0; } ChromagramPlugin::~ChromagramPlugin() { delete m_chromagram; } string ChromagramPlugin::getIdentifier() const { return "qm-chromagram"; } string ChromagramPlugin::getName() const { return "Chromagram"; } string ChromagramPlugin::getDescription() const { return "Extract a series of tonal chroma vectors from the audio"; } string ChromagramPlugin::getMaker() const { return "Queen Mary, University of London"; } int ChromagramPlugin::getPluginVersion() const { return 4; } string ChromagramPlugin::getCopyright() const { return "Plugin by Chris Cannam and Christian Landone. Copyright (c) 2006-2009 QMUL - All Rights Reserved"; } ChromagramPlugin::ParameterList ChromagramPlugin::getParameterDescriptors() const { ParameterList list; ParameterDescriptor desc; desc.identifier = "minpitch"; desc.name = "Minimum Pitch"; desc.unit = "MIDI units"; desc.description = "MIDI pitch corresponding to the lowest frequency to be included in the chromagram"; desc.minValue = 0; desc.maxValue = 127; desc.defaultValue = 36; desc.isQuantized = true; desc.quantizeStep = 1; list.push_back(desc); desc.identifier = "maxpitch"; desc.name = "Maximum Pitch"; desc.unit = "MIDI units"; desc.description = "MIDI pitch corresponding to the highest frequency to be included in the chromagram"; desc.minValue = 0; desc.maxValue = 127; desc.defaultValue = 96; desc.isQuantized = true; desc.quantizeStep = 1; list.push_back(desc); desc.identifier = "tuning"; desc.name = "Tuning Frequency"; desc.unit = "Hz"; desc.description = "Frequency of concert A"; desc.minValue = 360; desc.maxValue = 500; desc.defaultValue = 440; desc.isQuantized = false; list.push_back(desc); desc.identifier = "bpo"; desc.name = "Bins per Octave"; desc.unit = "bins"; desc.description = "Number of constant-Q transform bins per octave, and the number of bins for the chromagram outputs"; desc.minValue = 2; desc.maxValue = 480; desc.defaultValue = 12; desc.isQuantized = true; desc.quantizeStep = 1; list.push_back(desc); desc.identifier = "normalization"; desc.name = "Normalization"; desc.unit = ""; desc.description = "Normalization for each chromagram output column"; desc.minValue = 0; desc.maxValue = 2; desc.defaultValue = 0; desc.isQuantized = true; desc.quantizeStep = 1; desc.valueNames.push_back("None"); desc.valueNames.push_back("Unit Sum"); desc.valueNames.push_back("Unit Maximum"); list.push_back(desc); return list; } float ChromagramPlugin::getParameter(std::string param) const { if (param == "minpitch") { return m_minMIDIPitch; } if (param == "maxpitch") { return m_maxMIDIPitch; } if (param == "tuning") { return m_tuningFrequency; } if (param == "bpo") { return m_bpo; } if (param == "normalization") { return int(m_normalise); } std::cerr << "WARNING: ChromagramPlugin::getParameter: unknown parameter \"" << param << "\"" << std::endl; return 0.0; } void ChromagramPlugin::setParameter(std::string param, float value) { if (param == "minpitch") { m_minMIDIPitch = lrintf(value); } else if (param == "maxpitch") { m_maxMIDIPitch = lrintf(value); } else if (param == "tuning") { m_tuningFrequency = value; } else if (param == "bpo") { m_bpo = lrintf(value); } else if (param == "normalization") { m_normalise = MathUtilities::NormaliseType(int(value + 0.0001)); } else { std::cerr << "WARNING: ChromagramPlugin::setParameter: unknown parameter \"" << param << "\"" << std::endl; } setupConfig(); } bool ChromagramPlugin::initialise(size_t channels, size_t stepSize, size_t blockSize) { if (m_chromagram) { delete m_chromagram; m_chromagram = 0; } if (channels < getMinChannelCount() || channels > getMaxChannelCount()) return false; m_chromagram = new Chromagram(m_config); m_binsums = vector<double>(m_config.BPO); for (int i = 0; i < m_config.BPO; ++i) { m_binsums[i] = 0.0; } m_count = 0; m_step = m_chromagram->getHopSize(); m_block = m_chromagram->getFrameSize(); if (m_step < 1) m_step = 1; if (blockSize != m_block) { std::cerr << "ChromagramPlugin::initialise: ERROR: supplied block size " << blockSize << " differs from required block size " << m_block << ", initialise failing" << std::endl; delete m_chromagram; m_chromagram = 0; return false; } if (stepSize != m_step) { std::cerr << "ChromagramPlugin::initialise: NOTE: supplied step size " << stepSize << " differs from expected step size " << m_step << " (for block size = " << m_block << ")" << std::endl; } return true; } void ChromagramPlugin::reset() { if (m_chromagram) { delete m_chromagram; m_chromagram = new Chromagram(m_config); for (int i = 0; i < m_config.BPO; ++i) { m_binsums[i] = 0.0; } m_count = 0; } } size_t ChromagramPlugin::getPreferredStepSize() const { if (!m_step) { Chromagram chroma(m_config); m_step = chroma.getHopSize(); m_block = chroma.getFrameSize(); if (m_step < 1) m_step = 1; } return m_step; } size_t ChromagramPlugin::getPreferredBlockSize() const { if (!m_block) { Chromagram chroma(m_config); m_step = chroma.getHopSize(); m_block = chroma.getFrameSize(); if (m_step < 1) m_step = 1; } return m_block; } ChromagramPlugin::OutputList ChromagramPlugin::getOutputDescriptors() const { OutputList list; OutputDescriptor d; d.identifier = "chromagram"; d.name = "Chromagram"; d.unit = ""; d.description = "Output of chromagram, as a single vector per process block"; d.hasFixedBinCount = true; d.binCount = m_config.BPO; const char *names[] = { "C", "C#", "D", "D#", "E", "F", "F#", "G", "G#", "A", "A#", "B" }; if (d.binCount % 12 == 0) { for (int i = 0; i < 12; ++i) { int ipc = m_minMIDIPitch % 12; int index = (i + ipc) % 12; d.binNames.push_back(names[index]); for (int j = 0; j < int(d.binCount) / 12 - 1; ++j) { d.binNames.push_back(""); } } } else { d.binNames.push_back(names[m_minMIDIPitch % 12]); } d.hasKnownExtents = (m_normalise != MathUtilities::NormaliseNone); d.minValue = 0.0; d.maxValue = (d.hasKnownExtents ? 1.0 : 0.0); d.isQuantized = false; d.sampleType = OutputDescriptor::OneSamplePerStep; list.push_back(d); d.identifier = "chromameans"; d.name = "Chroma Means"; d.description = "Mean values of chromagram bins across the duration of the input audio"; d.sampleType = OutputDescriptor::FixedSampleRate; d.sampleRate = 1; list.push_back(d); return list; } ChromagramPlugin::FeatureSet ChromagramPlugin::process(const float *const *inputBuffers, Vamp::RealTime timestamp) { if (!m_chromagram) { cerr << "ERROR: ChromagramPlugin::process: " << "Chromagram has not been initialised" << endl; return FeatureSet(); } double *real = new double[m_block]; double *imag = new double[m_block]; for (size_t i = 0; i <= m_block/2; ++i) { real[i] = inputBuffers[0][i*2]; if (i > 0) real[m_block - i] = real[i]; imag[i] = inputBuffers[0][i*2+1]; if (i > 0) imag[m_block - i] = imag[i]; } // cerr << "chromagram: timestamp = " << timestamp << endl; /* bool printThis = false; if (timestamp.sec == 3 && timestamp.nsec < 250000000) { printThis = true; } if (printThis) { cerr << "\n\nchromagram: timestamp " << timestamp << ": input data starts:" << endl; for (int i = 0; i < m_block && i < 1000; ++i) { cerr << real[i] << "," << imag[i] << " "; } cerr << endl << "values:" << endl; } */ double *output = m_chromagram->process(real, imag); delete[] real; delete[] imag; Feature feature; feature.hasTimestamp = false; for (size_t i = 0; i < m_config.BPO; ++i) { double value = output[i]; /* if (printThis) { cerr << value << " "; } */ if (ISNAN(value)) value = 0.0; m_binsums[i] += value; feature.values.push_back(value); } feature.label = ""; ++m_count; /* if (printThis) { cerr << endl; } */ FeatureSet returnFeatures; returnFeatures[0].push_back(feature); return returnFeatures; } ChromagramPlugin::FeatureSet ChromagramPlugin::getRemainingFeatures() { Feature feature; feature.hasTimestamp = true; feature.timestamp = Vamp::RealTime::zeroTime; for (size_t i = 0; i < m_config.BPO; ++i) { double v = m_binsums[i]; if (m_count > 0) v /= m_count; feature.values.push_back(v); } feature.label = "Chromagram bin means"; FeatureSet returnFeatures; returnFeatures[1].push_back(feature); return returnFeatures; }