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annotate dsp/tempotracking/DownBeat.cpp @ 479:7e52c034cf62

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Untabify, indent, tidy
author Chris Cannam <cannam@all-day-breakfast.com>
date Fri, 31 May 2019 10:35:08 +0100
parents 00f66226db5b
children bb78ca3fe7de
rev   line source
c@279 1 /* -*- c-basic-offset: 4 indent-tabs-mode: nil -*- vi:set ts=8 sts=4 sw=4: */
c@279 2
c@279 3 /*
c@279 4 QM DSP Library
c@279 5
c@279 6 Centre for Digital Music, Queen Mary, University of London.
c@279 7 This file copyright 2008-2009 Matthew Davies and QMUL.
c@309 8
c@309 9 This program is free software; you can redistribute it and/or
c@309 10 modify it under the terms of the GNU General Public License as
c@309 11 published by the Free Software Foundation; either version 2 of the
c@309 12 License, or (at your option) any later version. See the file
c@309 13 COPYING included with this distribution for more information.
c@279 14 */
c@279 15
c@279 16 #include "DownBeat.h"
c@279 17
c@279 18 #include "maths/MathAliases.h"
c@279 19 #include "maths/MathUtilities.h"
c@280 20 #include "maths/KLDivergence.h"
c@279 21 #include "dsp/transforms/FFT.h"
c@279 22
c@279 23 #include <iostream>
c@279 24 #include <cstdlib>
c@279 25
c@279 26 DownBeat::DownBeat(float originalSampleRate,
c@279 27 size_t decimationFactor,
c@279 28 size_t dfIncrement) :
c@280 29 m_bpb(0),
c@279 30 m_rate(originalSampleRate),
c@279 31 m_factor(decimationFactor),
c@279 32 m_increment(dfIncrement),
c@279 33 m_decimator1(0),
c@279 34 m_decimator2(0),
c@279 35 m_buffer(0),
c@283 36 m_decbuf(0),
c@279 37 m_bufsiz(0),
c@279 38 m_buffill(0),
c@279 39 m_beatframesize(0),
c@279 40 m_beatframe(0)
c@279 41 {
c@279 42 // beat frame size is next power of two up from 1.3 seconds at the
c@279 43 // downsampled rate (happens to produce 4096 for 44100 or 48000 at
c@279 44 // 16x decimation, which is our expected normal situation)
c@280 45 m_beatframesize = MathUtilities::nextPowerOfTwo
c@280 46 (int((m_rate / decimationFactor) * 1.3));
c@387 47 if (m_beatframesize < 2) {
c@387 48 m_beatframesize = 2;
c@387 49 }
c@279 50 m_beatframe = new double[m_beatframesize];
c@279 51 m_fftRealOut = new double[m_beatframesize];
c@279 52 m_fftImagOut = new double[m_beatframesize];
c@289 53 m_fft = new FFTReal(m_beatframesize);
c@279 54 }
c@279 55
c@279 56 DownBeat::~DownBeat()
c@279 57 {
c@279 58 delete m_decimator1;
c@279 59 delete m_decimator2;
c@279 60 if (m_buffer) free(m_buffer);
c@279 61 delete[] m_decbuf;
c@279 62 delete[] m_beatframe;
c@279 63 delete[] m_fftRealOut;
c@279 64 delete[] m_fftImagOut;
c@289 65 delete m_fft;
c@279 66 }
c@279 67
c@279 68 void
c@280 69 DownBeat::setBeatsPerBar(int bpb)
c@280 70 {
c@280 71 m_bpb = bpb;
c@280 72 }
c@280 73
c@280 74 void
c@279 75 DownBeat::makeDecimators()
c@279 76 {
c@279 77 if (m_factor < 2) return;
c@302 78 size_t highest = Decimator::getHighestSupportedFactor();
c@279 79 if (m_factor <= highest) {
c@279 80 m_decimator1 = new Decimator(m_increment, m_factor);
c@279 81 return;
c@279 82 }
c@279 83 m_decimator1 = new Decimator(m_increment, highest);
c@279 84 m_decimator2 = new Decimator(m_increment / highest, m_factor / highest);
c@280 85 m_decbuf = new float[m_increment / highest];
c@279 86 }
c@279 87
c@279 88 void
c@280 89 DownBeat::pushAudioBlock(const float *audio)
c@279 90 {
c@279 91 if (m_buffill + (m_increment / m_factor) > m_bufsiz) {
c@279 92 if (m_bufsiz == 0) m_bufsiz = m_increment * 16;
c@279 93 else m_bufsiz = m_bufsiz * 2;
c@279 94 if (!m_buffer) {
c@280 95 m_buffer = (float *)malloc(m_bufsiz * sizeof(float));
c@279 96 } else {
c@280 97 m_buffer = (float *)realloc(m_buffer, m_bufsiz * sizeof(float));
c@279 98 }
c@279 99 }
cannam@479 100 if (!m_decimator1 && m_factor > 1) {
cannam@479 101 makeDecimators();
cannam@479 102 }
c@279 103 if (m_decimator2) {
c@279 104 m_decimator1->process(audio, m_decbuf);
c@279 105 m_decimator2->process(m_decbuf, m_buffer + m_buffill);
c@283 106 } else if (m_decimator1) {
c@283 107 m_decimator1->process(audio, m_buffer + m_buffill);
c@279 108 } else {
c@283 109 // just copy across (m_factor is presumably 1)
c@302 110 for (size_t i = 0; i < m_increment; ++i) {
c@283 111 (m_buffer + m_buffill)[i] = audio[i];
c@283 112 }
c@279 113 }
c@279 114 m_buffill += m_increment / m_factor;
c@279 115 }
c@279 116
c@280 117 const float *
c@279 118 DownBeat::getBufferedAudio(size_t &length) const
c@279 119 {
c@279 120 length = m_buffill;
c@279 121 return m_buffer;
c@279 122 }
c@279 123
c@279 124 void
c@280 125 DownBeat::resetAudioBuffer()
c@280 126 {
cannam@479 127 if (m_buffer) {
cannam@479 128 free(m_buffer);
cannam@479 129 }
c@283 130 m_buffer = 0;
c@280 131 m_buffill = 0;
c@280 132 m_bufsiz = 0;
c@280 133 }
c@280 134
c@280 135 void
c@280 136 DownBeat::findDownBeats(const float *audio,
c@279 137 size_t audioLength,
c@279 138 const d_vec_t &beats,
c@279 139 i_vec_t &downbeats)
c@279 140 {
c@279 141 // FIND DOWNBEATS BY PARTITIONING THE INPUT AUDIO FILE INTO BEAT SEGMENTS
c@279 142 // WHERE THE AUDIO FRAMES ARE DOWNSAMPLED BY A FACTOR OF 16 (fs ~= 2700Hz)
c@279 143 // THEN TAKING THE JENSEN-SHANNON DIVERGENCE BETWEEN BEAT SYNCHRONOUS SPECTRAL FRAMES
c@279 144
c@279 145 // IMPLEMENTATION (MOSTLY) FOLLOWS:
c@279 146 // DAVIES AND PLUMBLEY "A SPECTRAL DIFFERENCE APPROACH TO EXTRACTING DOWNBEATS IN MUSICAL AUDIO"
c@279 147 // EUSIPCO 2006, FLORENCE, ITALY
c@279 148
c@279 149 d_vec_t newspec(m_beatframesize / 2); // magnitude spectrum of current beat
c@279 150 d_vec_t oldspec(m_beatframesize / 2); // magnitude spectrum of previous beat
c@281 151
c@281 152 m_beatsd.clear();
c@279 153
c@279 154 if (audioLength == 0) return;
c@279 155
c@279 156 for (size_t i = 0; i + 1 < beats.size(); ++i) {
c@279 157
c@279 158 // Copy the extents of the current beat from downsampled array
c@279 159 // into beat frame buffer
c@279 160
c@279 161 size_t beatstart = (beats[i] * m_increment) / m_factor;
c@280 162 size_t beatend = (beats[i+1] * m_increment) / m_factor;
c@279 163 if (beatend >= audioLength) beatend = audioLength - 1;
c@279 164 if (beatend < beatstart) beatend = beatstart;
c@279 165 size_t beatlen = beatend - beatstart;
c@279 166
c@279 167 // Also apply a Hanning window to the beat frame buffer, sized
c@279 168 // to the beat extents rather than the frame size. (Because
c@279 169 // the size varies, it's easier to do this by hand than use
c@279 170 // our Window abstraction.)
c@279 171
c@283 172 for (size_t j = 0; j < beatlen && j < m_beatframesize; ++j) {
c@279 173 double mul = 0.5 * (1.0 - cos(TWO_PI * (double(j) / double(beatlen))));
c@279 174 m_beatframe[j] = audio[beatstart + j] * mul;
c@279 175 }
c@279 176
c@279 177 for (size_t j = beatlen; j < m_beatframesize; ++j) {
c@279 178 m_beatframe[j] = 0.0;
c@279 179 }
c@279 180
c@279 181 // Now FFT beat frame
c@279 182
c@339 183 m_fft->forward(m_beatframe, m_fftRealOut, m_fftImagOut);
c@279 184
c@279 185 // Calculate magnitudes
c@279 186
c@279 187 for (size_t j = 0; j < m_beatframesize/2; ++j) {
c@279 188 newspec[j] = sqrt(m_fftRealOut[j] * m_fftRealOut[j] +
c@279 189 m_fftImagOut[j] * m_fftImagOut[j]);
c@279 190 }
c@279 191
c@279 192 // Preserve peaks by applying adaptive threshold
c@279 193
c@279 194 MathUtilities::adaptiveThreshold(newspec);
c@279 195
c@279 196 // Calculate JS divergence between new and old spectral frames
c@279 197
c@281 198 if (i > 0) { // otherwise we have no previous frame
c@281 199 m_beatsd.push_back(measureSpecDiff(oldspec, newspec));
c@281 200 }
c@279 201
c@279 202 // Copy newspec across to old
c@279 203
c@279 204 for (size_t j = 0; j < m_beatframesize/2; ++j) {
c@279 205 oldspec[j] = newspec[j];
c@279 206 }
c@279 207 }
c@279 208
c@279 209 // We now have all spectral difference measures in specdiff
c@279 210
c@302 211 int timesig = m_bpb;
c@280 212 if (timesig == 0) timesig = 4;
c@280 213
c@279 214 d_vec_t dbcand(timesig); // downbeat candidates
c@279 215
c@280 216 for (int beat = 0; beat < timesig; ++beat) {
c@280 217 dbcand[beat] = 0;
c@280 218 }
c@280 219
c@301 220 // look for beat transition which leads to greatest spectral change
c@301 221 for (int beat = 0; beat < timesig; ++beat) {
c@301 222 int count = 0;
c@302 223 for (int example = beat-1; example < (int)m_beatsd.size(); example += timesig) {
c@301 224 if (example < 0) continue;
c@301 225 dbcand[beat] += (m_beatsd[example]) / timesig;
c@301 226 ++count;
c@301 227 }
cannam@479 228 if (count > 0) {
cannam@479 229 dbcand[beat] /= count;
cannam@479 230 }
c@301 231 }
c@280 232
c@279 233 // first downbeat is beat at index of maximum value of dbcand
c@279 234 int dbind = MathUtilities::getMax(dbcand);
c@279 235
c@279 236 // remaining downbeats are at timesig intervals from the first
c@302 237 for (int i = dbind; i < (int)beats.size(); i += timesig) {
c@279 238 downbeats.push_back(i);
c@279 239 }
c@279 240 }
c@279 241
c@279 242 double
c@279 243 DownBeat::measureSpecDiff(d_vec_t oldspec, d_vec_t newspec)
c@279 244 {
c@279 245 // JENSEN-SHANNON DIVERGENCE BETWEEN SPECTRAL FRAMES
c@279 246
c@295 247 unsigned int SPECSIZE = 512; // ONLY LOOK AT FIRST 512 SAMPLES OF SPECTRUM.
c@279 248 if (SPECSIZE > oldspec.size()/4) {
c@279 249 SPECSIZE = oldspec.size()/4;
c@279 250 }
c@279 251 double SD = 0.;
c@279 252 double sd1 = 0.;
c@279 253
c@279 254 double sumnew = 0.;
c@279 255 double sumold = 0.;
c@279 256
cannam@479 257 for (unsigned int i = 0;i < SPECSIZE;i++) {
cannam@479 258
c@279 259 newspec[i] +=EPS;
c@279 260 oldspec[i] +=EPS;
c@279 261
c@279 262 sumnew+=newspec[i];
c@279 263 sumold+=oldspec[i];
c@279 264 }
c@279 265
cannam@479 266 for (unsigned int i = 0;i < SPECSIZE;i++) {
cannam@479 267
c@279 268 newspec[i] /= (sumnew);
c@279 269 oldspec[i] /= (sumold);
c@279 270
c@279 271 // IF ANY SPECTRAL VALUES ARE 0 (SHOULDN'T BE ANY!) SET THEM TO 1
cannam@479 272 if (newspec[i] == 0) {
c@279 273 newspec[i] = 1.;
c@279 274 }
c@279 275
cannam@479 276 if (oldspec[i] == 0) {
c@279 277 oldspec[i] = 1.;
c@279 278 }
c@279 279
c@279 280 // JENSEN-SHANNON CALCULATION
cannam@479 281 sd1 = 0.5*oldspec[i] + 0.5*newspec[i];
cannam@479 282 SD = SD + (-sd1*log(sd1)) +
cannam@479 283 (0.5*(oldspec[i]*log(oldspec[i]))) +
cannam@479 284 (0.5*(newspec[i]*log(newspec[i])));
c@279 285 }
c@279 286
c@279 287 return SD;
c@279 288 }
c@279 289
c@281 290 void
c@281 291 DownBeat::getBeatSD(vector<double> &beatsd) const
c@281 292 {
cannam@479 293 for (int i = 0; i < (int)m_beatsd.size(); ++i) {
cannam@479 294 beatsd.push_back(m_beatsd[i]);
cannam@479 295 }
c@281 296 }
c@281 297