206 lines
6.4 KiB
C++
206 lines
6.4 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 "MonoNoteHMM.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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MonoNoteHMM::MonoNoteHMM() :
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par()
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{
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build();
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}
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const vector<double>
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MonoNoteHMM::calculateObsProb(const vector<pair<double, double> > pitchProb)
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{
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// pitchProb is a list of pairs (pitches and their probabilities)
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size_t nCandidate = pitchProb.size();
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// what is the probability of pitched
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double pIsPitched = 0;
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for (size_t iCandidate = 0; iCandidate < nCandidate; ++iCandidate)
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{
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// pIsPitched = pitchProb[iCandidate].second > pIsPitched ? pitchProb[iCandidate].second : pIsPitched;
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pIsPitched += pitchProb[iCandidate].second;
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}
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// pIsPitched = std::pow(pIsPitched, (1-par.priorWeight)) * std::pow(par.priorPitchedProb, par.priorWeight);
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pIsPitched = pIsPitched * (1-par.priorWeight) + par.priorPitchedProb * par.priorWeight;
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vector<double> out = vector<double>(par.n);
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double tempProbSum = 0;
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for (size_t i = 0; i < par.n; ++i)
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{
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if (i % par.nSPP != 2)
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{
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// std::cerr << getMidiPitch(i) << std::endl;
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double tempProb = 0;
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if (nCandidate > 0)
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{
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double minDist = 10000.0;
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double minDistProb = 0;
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size_t minDistCandidate = 0;
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for (size_t iCandidate = 0; iCandidate < nCandidate; ++iCandidate)
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{
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double currDist = std::abs(getMidiPitch(i)-pitchProb[iCandidate].first);
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if (currDist < minDist)
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{
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minDist = currDist;
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minDistProb = pitchProb[iCandidate].second;
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minDistCandidate = iCandidate;
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}
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}
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tempProb = std::pow(minDistProb, par.yinTrust) *
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boost::math::pdf(pitchDistr[i],
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pitchProb[minDistCandidate].first);
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} else {
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tempProb = 1;
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}
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tempProbSum += tempProb;
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out[i] = tempProb;
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}
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}
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for (size_t i = 0; i < par.n; ++i)
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{
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if (i % par.nSPP != 2)
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{
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if (tempProbSum > 0)
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{
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out[i] = out[i] / tempProbSum * pIsPitched;
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}
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} else {
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out[i] = (1-pIsPitched) / (par.nPPS * par.nS);
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}
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}
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return(out);
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}
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void
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MonoNoteHMM::build()
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{
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// the states are organised as follows:
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// 0-2. lowest pitch
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// 0. attack state
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// 1. stable state
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// 2. silent state
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// 3-5. second-lowest pitch
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// 3. attack state
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// ...
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// observation distributions
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for (size_t iState = 0; iState < par.n; ++iState)
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{
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pitchDistr.push_back(boost::math::normal(0,1));
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if (iState % par.nSPP == 2)
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{
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// silent state starts tracking
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init.push_back(1.0/(par.nS * par.nPPS));
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} else {
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init.push_back(0.0);
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}
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}
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for (size_t iPitch = 0; iPitch < (par.nS * par.nPPS); ++iPitch)
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{
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size_t index = iPitch * par.nSPP;
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double mu = par.minPitch + iPitch * 1.0/par.nPPS;
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pitchDistr[index] = boost::math::normal(mu, par.sigmaYinPitchAttack);
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pitchDistr[index+1] = boost::math::normal(mu, par.sigmaYinPitchStable);
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pitchDistr[index+2] = boost::math::normal(mu, 1.0); // dummy
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}
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boost::math::normal noteDistanceDistr(0, par.sigma2Note);
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for (size_t iPitch = 0; iPitch < (par.nS * par.nPPS); ++iPitch)
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{
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// loop through all notes and set sparse transition probabilities
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size_t index = iPitch * par.nSPP;
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// transitions from attack state
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from.push_back(index);
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to.push_back(index);
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transProb.push_back(par.pAttackSelftrans);
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from.push_back(index);
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to.push_back(index+1);
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transProb.push_back(1-par.pAttackSelftrans);
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// transitions from stable state
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from.push_back(index+1);
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to.push_back(index+1); // to itself
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transProb.push_back(par.pStableSelftrans);
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from.push_back(index+1);
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to.push_back(index+2); // to silent
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transProb.push_back(par.pStable2Silent);
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// the "easy" transitions from silent state
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from.push_back(index+2);
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to.push_back(index+2);
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transProb.push_back(par.pSilentSelftrans);
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// the more complicated transitions from the silent
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double probSumSilent = 0;
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vector<double> tempTransProbSilent;
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for (size_t jPitch = 0; jPitch < (par.nS * par.nPPS); ++jPitch)
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{
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int fromPitch = iPitch;
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int toPitch = jPitch;
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double semitoneDistance =
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std::abs(fromPitch - toPitch) * 1.0 / par.nPPS;
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// if (std::fmod(semitoneDistance, 1) == 0 && semitoneDistance > par.minSemitoneDistance)
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if (semitoneDistance == 0 ||
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(semitoneDistance > par.minSemitoneDistance
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&& semitoneDistance < par.maxJump))
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{
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size_t toIndex = jPitch * par.nSPP; // note attack index
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double tempWeightSilent = boost::math::pdf(noteDistanceDistr,
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semitoneDistance);
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probSumSilent += tempWeightSilent;
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tempTransProbSilent.push_back(tempWeightSilent);
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from.push_back(index+2);
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to.push_back(toIndex);
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}
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}
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for (size_t i = 0; i < tempTransProbSilent.size(); ++i)
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{
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transProb.push_back((1-par.pSilentSelftrans) * tempTransProbSilent[i]/probSumSilent);
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}
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}
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}
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double
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MonoNoteHMM::getMidiPitch(size_t index)
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{
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return pitchDistr[index].mean();
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}
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double
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MonoNoteHMM::getFrequency(size_t index)
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{
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return 440 * pow(2, (pitchDistr[index].mean()-69)/12);
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}
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