Mercurial > hg > vamp-aubio-plugins
view plugins/Notes.cpp @ 3:4bfe0cf6e20a
* Compensate for 4*stepSize delay in onset detection with returned timestamps
* Discard onsets that occur within 4*stepSize of previous onset
| author | Chris Cannam <cannam@all-day-breakfast.com> |
|---|---|
| date | Wed, 17 May 2006 10:02:36 +0000 |
| parents | 76c1a7bd0416 |
| children | be376e1b36c3 |
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/* -*- c-basic-offset: 4 indent-tabs-mode: nil -*- vi:set ts=8 sts=4 sw=4: */ /* Vamp feature extraction plugins using Paul Brossier's Aubio library. Centre for Digital Music, Queen Mary, University of London. This file copyright 2006 Chris Cannam. 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 <math.h> #include "Notes.h" using std::string; using std::vector; using std::cerr; using std::endl; Notes::Notes(float inputSampleRate) : Plugin(inputSampleRate), m_ibuf(0), m_fftgrain(0), m_onset(0), m_pv(0), m_peakpick(0), m_onsetdet(0), m_onsettype(aubio_onset_complex), m_pitchdet(0), m_pitchtype(aubio_pitch_yinfft), m_pitchmode(aubio_pitchm_freq), m_threshold(0.3), m_silence(-90), m_median(6) { } Notes::~Notes() { if (m_onsetdet) aubio_onsetdetection_free(m_onsetdet); if (m_pitchdet) del_aubio_pitchdetection(m_pitchdet); if (m_ibuf) del_fvec(m_ibuf); if (m_onset) del_fvec(m_onset); if (m_fftgrain) del_cvec(m_fftgrain); if (m_pv) del_aubio_pvoc(m_pv); if (m_peakpick) del_aubio_peakpicker(m_peakpick); } string Notes::getName() const { return "aubionotes"; } string Notes::getDescription() const { return "Aubio Note Tracker"; } string Notes::getMaker() const { return "Paul Brossier (plugin by Chris Cannam)"; } int Notes::getPluginVersion() const { return 1; } string Notes::getCopyright() const { return "GPL"; } bool Notes::initialise(size_t channels, size_t stepSize, size_t blockSize) { m_channelCount = channels; m_stepSize = stepSize; m_blockSize = blockSize; size_t processingBlockSize; if (m_onsettype == aubio_onset_energy || m_onsettype == aubio_onset_hfc) { processingBlockSize = stepSize * 2; } else { processingBlockSize = stepSize * 4; } m_ibuf = new_fvec(stepSize, channels); m_onset = new_fvec(1, channels); m_fftgrain = new_cvec(processingBlockSize, channels); m_pv = new_aubio_pvoc(processingBlockSize, stepSize, channels); m_peakpick = new_aubio_peakpicker(m_threshold); m_onsetdet = new_aubio_onsetdetection(m_onsettype, processingBlockSize, channels); m_pitchdet = new_aubio_pitchdetection(processingBlockSize * 4, stepSize, channels, lrintf(m_inputSampleRate), m_pitchtype, m_pitchmode); m_count = 0; m_currentOnset = Vamp::RealTime::zeroTime; m_haveCurrent = false; return true; } void Notes::reset() { } size_t Notes::getPreferredStepSize() const { return 512; } size_t Notes::getPreferredBlockSize() const { return 4*getPreferredStepSize(); } Notes::ParameterList Notes::getParameterDescriptors() const { ParameterList list; ParameterDescriptor desc; desc.name = "onsettype"; desc.description = "Onset Detection Function Type"; desc.minValue = 0; desc.maxValue = 6; desc.defaultValue = (int)aubio_onset_complex; desc.isQuantized = true; desc.quantizeStep = 1; desc.valueNames.push_back("Energy Based"); desc.valueNames.push_back("Spectral Difference"); desc.valueNames.push_back("High-Frequency Content"); desc.valueNames.push_back("Complex Domain"); desc.valueNames.push_back("Phase Deviation"); desc.valueNames.push_back("Kullback-Liebler"); desc.valueNames.push_back("Modified Kullback-Liebler"); list.push_back(desc); desc = ParameterDescriptor(); desc.name = "pitchtype"; desc.description = "Pitch Detection Function Type"; desc.minValue = 0; desc.maxValue = 4; desc.defaultValue = (int)aubio_pitch_yinfft; desc.isQuantized = true; desc.quantizeStep = 1; desc.valueNames.push_back("YIN Frequency Estimator"); desc.valueNames.push_back("Spectral Comb"); desc.valueNames.push_back("Schmitt"); desc.valueNames.push_back("Fast Harmonic Comb"); desc.valueNames.push_back("YIN with FFT"); list.push_back(desc); desc = ParameterDescriptor(); desc.name = "peakpickthreshold"; desc.description = "Peak Picker Threshold"; desc.minValue = 0; desc.maxValue = 1; desc.defaultValue = 0.3; desc.isQuantized = false; list.push_back(desc); desc = ParameterDescriptor(); desc.name = "silencethreshold"; desc.description = "Silence Threshold"; desc.minValue = -120; desc.maxValue = 0; desc.defaultValue = -90; desc.unit = "dB"; desc.isQuantized = false; list.push_back(desc); return list; } float Notes::getParameter(std::string param) const { if (param == "onsettype") { return m_onsettype; } else if (param == "pitchtype") { return m_pitchtype; } else if (param == "peakpickthreshold") { return m_threshold; } else if (param == "silencethreshold") { return m_silence; } else { return 0.0; } } void Notes::setParameter(std::string param, float value) { if (param == "onsettype") { switch (lrintf(value)) { case 0: m_onsettype = aubio_onset_energy; break; case 1: m_onsettype = aubio_onset_specdiff; break; case 2: m_onsettype = aubio_onset_hfc; break; case 3: m_onsettype = aubio_onset_complex; break; case 4: m_onsettype = aubio_onset_phase; break; case 5: m_onsettype = aubio_onset_kl; break; case 6: m_onsettype = aubio_onset_mkl; break; } } else if (param == "pitchtype") { switch (lrintf(value)) { case 0: m_pitchtype = aubio_pitch_yin; break; case 1: m_pitchtype = aubio_pitch_mcomb; break; case 2: m_pitchtype = aubio_pitch_schmitt; break; case 3: m_pitchtype = aubio_pitch_fcomb; break; case 4: m_pitchtype = aubio_pitch_yinfft; break; } } else if (param == "peakpickthreshold") { m_threshold = value; } else if (param == "silencethreshold") { m_silence = value; } } Notes::OutputList Notes::getOutputDescriptors() const { OutputList list; OutputDescriptor d; d.name = "notes"; d.unit = "Hz"; d.description = "Notes"; d.hasFixedBinCount = true; d.binCount = 2; d.binNames.push_back("Frequency"); d.binNames.push_back("Duration"); d.binNames.push_back("Velocity"); d.hasKnownExtents = false; d.isQuantized = false; d.sampleType = OutputDescriptor::VariableSampleRate; d.sampleRate = 0; list.push_back(d); return list; } Notes::FeatureSet Notes::process(float **inputBuffers, Vamp::RealTime timestamp) { for (size_t i = 0; i < m_stepSize; ++i) { for (size_t j = 0; j < m_channelCount; ++j) { fvec_write_sample(m_ibuf, inputBuffers[j][i], j, i); } } aubio_pvoc_do(m_pv, m_ibuf, m_fftgrain); aubio_onsetdetection(m_onsetdet, m_fftgrain, m_onset); bool isonset = aubio_peakpick_pimrt(m_onset, m_peakpick); float frequency = aubio_pitchdetection(m_pitchdet, m_ibuf); m_notebuf.push_back(frequency); if (m_notebuf.size() > m_median) m_notebuf.pop_front(); float level = aubio_level_detection(m_ibuf, m_silence); FeatureSet returnFeatures; if (isonset) { if (level == 1.) { isonset = false; m_count = 0; if (m_haveCurrent) pushNote(returnFeatures, timestamp); } else { m_count = 1; } } else { if (m_count > 0) ++m_count; if (m_count == m_median) { if (m_haveCurrent) pushNote(returnFeatures, timestamp); m_currentOnset = timestamp; m_currentLevel = level; m_haveCurrent = true; } } m_lastTimeStamp = timestamp; return returnFeatures; } Notes::FeatureSet Notes::getRemainingFeatures() { FeatureSet returnFeatures; if (m_haveCurrent) pushNote(returnFeatures, m_lastTimeStamp); return returnFeatures; } void Notes::pushNote(FeatureSet &fs, const Vamp::RealTime &offTime) { std::deque<float> toSort = m_notebuf; std::sort(toSort.begin(), toSort.end()); float median = toSort[toSort.size()/2]; if (median < 45.0) return; Feature feature; feature.hasTimestamp = true; feature.timestamp = m_currentOnset; feature.values.push_back(median); // feature.values.push_back(FLOOR(aubio_freqtomidi(median) + 0.5)); feature.values.push_back (Vamp::RealTime::realTime2Frame(offTime, lrintf(m_inputSampleRate)) - Vamp::RealTime::realTime2Frame(m_currentOnset, lrintf(m_inputSampleRate))); feature.values.push_back(m_currentLevel); fs[0].push_back(feature); }