152 lines
5.1 KiB
C++
152 lines
5.1 KiB
C++
/* -*- c-basic-offset: 4 indent-tabs-mode: nil -*- vi:set ts=8 sts=4 sw=4: */
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/*
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pYIN - A fundamental frequency estimator for monophonic audio
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Centre for Digital Music, Queen Mary, University of London.
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This program is free software; you can redistribute it and/or
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modify it under the terms of the GNU General Public License as
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published by the Free Software Foundation; either version 2 of the
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License, or (at your option) any later version. See the file
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COPYING included with this distribution for more information.
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*/
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#include "MonoPitchHMM.h"
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#include <cstdio>
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#include <cmath>
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using std::vector;
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using std::pair;
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MonoPitchHMM::MonoPitchHMM() :
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m_minFreq(61.735),
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m_nBPS(5),
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m_nPitch(0),
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m_transitionWidth(0),
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m_selfTrans(0.99),
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m_yinTrust(.5),
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m_freqs(0)
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{
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m_transitionWidth = 5*(m_nBPS/2) + 1;
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m_nPitch = 69 * m_nBPS;
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m_freqs = vector<double>(2*m_nPitch);
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for (size_t iPitch = 0; iPitch < m_nPitch; ++iPitch)
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{
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m_freqs[iPitch] = m_minFreq * std::pow(2, iPitch * 1.0 / (12 * m_nBPS));
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m_freqs[iPitch+m_nPitch] = -m_freqs[iPitch];
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}
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build();
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}
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const vector<double>
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MonoPitchHMM::calculateObsProb(const vector<pair<double, double> > pitchProb)
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{
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vector<double> out = vector<double>(2*m_nPitch+1);
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double probYinPitched = 0;
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// BIN THE PITCHES
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for (size_t iPair = 0; iPair < pitchProb.size(); ++iPair)
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{
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double freq = 440. * std::pow(2, (pitchProb[iPair].first - 69)/12);
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if (freq <= m_minFreq) continue;
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double d = 0;
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double oldd = 1000;
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for (size_t iPitch = 0; iPitch < m_nPitch; ++iPitch)
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{
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d = std::abs(freq-m_freqs[iPitch]);
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if (oldd < d && iPitch > 0)
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{
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// previous bin must have been the closest
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out[iPitch-1] = pitchProb[iPair].second;
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probYinPitched += out[iPitch-1];
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break;
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}
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oldd = d;
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}
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}
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double probReallyPitched = m_yinTrust * probYinPitched;
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// std::cerr << probReallyPitched << " " << probYinPitched << std::endl;
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// damn, I forget what this is all about...
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for (size_t iPitch = 0; iPitch < m_nPitch; ++iPitch)
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{
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if (probYinPitched > 0) out[iPitch] *= (probReallyPitched/probYinPitched) ;
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out[iPitch+m_nPitch] = (1 - probReallyPitched) / m_nPitch;
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}
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// out[2*m_nPitch] = m_yinTrust * (1 - probYinPitched);
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return(out);
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}
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void
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MonoPitchHMM::build()
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{
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// INITIAL VECTOR
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init = vector<double>(2*m_nPitch, 1.0 / 2*m_nPitch);
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// TRANSITIONS
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for (size_t iPitch = 0; iPitch < m_nPitch; ++iPitch)
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{
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int theoreticalMinNextPitch = static_cast<int>(iPitch)-static_cast<int>(m_transitionWidth/2);
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size_t minNextPitch = iPitch>m_transitionWidth/2 ? iPitch-m_transitionWidth/2 : 0;
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size_t maxNextPitch = iPitch<m_nPitch-m_transitionWidth/2 ? iPitch+m_transitionWidth/2 : m_nPitch-1;
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// WEIGHT VECTOR
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double weightSum = 0;
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vector<double> weights;
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for (size_t i = minNextPitch; i <= maxNextPitch; ++i)
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{
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if (i <= iPitch)
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{
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weights.push_back(i-theoreticalMinNextPitch+1);
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// weights.push_back(i-theoreticalMinNextPitch+1+m_transitionWidth/2);
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} else {
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weights.push_back(iPitch-theoreticalMinNextPitch+1-(i-iPitch));
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// weights.push_back(iPitch-theoreticalMinNextPitch+1-(i-iPitch)+m_transitionWidth/2);
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}
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weightSum += weights[weights.size()-1];
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}
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// std::cerr << minNextPitch << " " << maxNextPitch << std::endl;
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// TRANSITIONS TO CLOSE PITCH
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for (size_t i = minNextPitch; i <= maxNextPitch; ++i)
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{
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from.push_back(iPitch);
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to.push_back(i);
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transProb.push_back(weights[i-minNextPitch] / weightSum * m_selfTrans);
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from.push_back(iPitch);
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to.push_back(i+m_nPitch);
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transProb.push_back(weights[i-minNextPitch] / weightSum * (1-m_selfTrans));
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from.push_back(iPitch+m_nPitch);
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to.push_back(i+m_nPitch);
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transProb.push_back(weights[i-minNextPitch] / weightSum * m_selfTrans);
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// transProb.push_back(weights[i-minNextPitch] / weightSum * 0.5);
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from.push_back(iPitch+m_nPitch);
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to.push_back(i);
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transProb.push_back(weights[i-minNextPitch] / weightSum * (1-m_selfTrans));
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// transProb.push_back(weights[i-minNextPitch] / weightSum * 0.5);
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}
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// TRANSITION TO UNVOICED
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// from.push_back(iPitch+m_nPitch);
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// to.push_back(2*m_nPitch);
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// transProb.push_back(1-m_selfTrans);
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// TRANSITION FROM UNVOICED TO PITCH
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// from.push_back(2*m_nPitch);
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// to.push_back(iPitch+m_nPitch);
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// transProb.push_back(1.0/m_nPitch);
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}
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// UNVOICED SELFTRANSITION
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// from.push_back(2*m_nPitch);
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// to.push_back(2*m_nPitch);
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// transProb.push_back(m_selfTrans);
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// for (size_t i = 0; i < from.size(); ++i) {
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// std::cerr << "P(["<< from[i] << " --> " << to[i] << "]) = " << transProb[i] << std::endl;
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// }
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}
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