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annotate src/BTrack.cpp @ 98:3b24b01fbe15

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More tidying...
author Adam Stark <adamstark.uk@gmail.com>
date Sat, 12 Aug 2017 13:54:35 +0100
parents 6a4dd7478954
children 6aea5918992d
rev   line source
adamstark@46 1 //=======================================================================
adamstark@46 2 /** @file BTrack.cpp
adamstark@47 3 * @brief BTrack - a real-time beat tracker
adamstark@46 4 * @author Adam Stark
adamstark@46 5 * @copyright Copyright (C) 2008-2014 Queen Mary University of London
adamstark@46 6 *
adamstark@46 7 * This program is free software: you can redistribute it and/or modify
adamstark@46 8 * it under the terms of the GNU General Public License as published by
adamstark@46 9 * the Free Software Foundation, either version 3 of the License, or
adamstark@46 10 * (at your option) any later version.
adamstark@46 11 *
adamstark@46 12 * This program is distributed in the hope that it will be useful,
adamstark@46 13 * but WITHOUT ANY WARRANTY; without even the implied warranty of
adamstark@46 14 * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
adamstark@46 15 * GNU General Public License for more details.
adamstark@46 16 *
adamstark@46 17 * You should have received a copy of the GNU General Public License
adamstark@46 18 * along with this program. If not, see <http://www.gnu.org/licenses/>.
adamstark@46 19 */
adamstark@46 20 //=======================================================================
adamstark@46 21
adamstark@46 22 #include <cmath>
adamstark@52 23 #include <algorithm>
adamstark@97 24 #include <numeric>
adamstark@46 25 #include "BTrack.h"
adamstark@46 26 #include "samplerate.h"
adamstark@89 27 #include <iostream>
adamstark@46 28
adamstark@55 29 //=======================================================================
adamstark@91 30 BTrack::BTrack()
adamstark@91 31 : odf (512, 1024, ComplexSpectralDifferenceHWR, HanningWindow)
adamstark@55 32 {
adamstark@93 33 initialise (512, 1024);
adamstark@55 34 }
adamstark@46 35
adamstark@51 36 //=======================================================================
adamstark@91 37 BTrack::BTrack (int hopSize_)
adamstark@97 38 : odf (hopSize_, 2 * hopSize_, ComplexSpectralDifferenceHWR, HanningWindow)
adamstark@46 39 {
adamstark@97 40 initialise (hopSize_, 2 * hopSize_);
adamstark@55 41 }
adamstark@55 42
adamstark@55 43 //=======================================================================
adamstark@91 44 BTrack::BTrack (int hopSize_, int frameSize_)
adamstark@91 45 : odf (hopSize_, frameSize_, ComplexSpectralDifferenceHWR, HanningWindow)
adamstark@55 46 {
adamstark@91 47 initialise (hopSize_, frameSize_);
adamstark@55 48 }
adamstark@55 49
adamstark@55 50 //=======================================================================
adamstark@88 51 BTrack::~BTrack()
adamstark@88 52 {
adamstark@93 53 #ifdef USE_FFTW
adamstark@88 54 // destroy fft plan
adamstark@91 55 fftw_destroy_plan (acfForwardFFT);
adamstark@91 56 fftw_destroy_plan (acfBackwardFFT);
adamstark@91 57 fftw_free (complexIn);
adamstark@91 58 fftw_free (complexOut);
adamstark@93 59 #endif
adamstark@93 60
adamstark@93 61 #ifdef USE_KISS_FFT
adamstark@93 62 free (cfgForwards);
adamstark@93 63 free (cfgBackwards);
adamstark@93 64 delete [] fftIn;
adamstark@93 65 delete [] fftOut;
adamstark@93 66 #endif
adamstark@88 67 }
adamstark@88 68
adamstark@88 69 //=======================================================================
adamstark@91 70 double BTrack::getBeatTimeInSeconds (long frameNumber, int hopSize, int fs)
adamstark@55 71 {
adamstark@55 72 double hop = (double) hopSize;
adamstark@55 73 double samplingFrequency = (double) fs;
adamstark@55 74 double frameNum = (double) frameNumber;
adamstark@55 75
adamstark@55 76 return ((hop / samplingFrequency) * frameNum);
adamstark@55 77 }
adamstark@55 78
adamstark@55 79 //=======================================================================
adamstark@91 80 double BTrack::getBeatTimeInSeconds (int frameNumber, int hopSize, int fs)
adamstark@55 81 {
adamstark@55 82 long frameNum = (long) frameNumber;
adamstark@55 83
adamstark@91 84 return getBeatTimeInSeconds (frameNum, hopSize, fs);
adamstark@55 85 }
adamstark@55 86
adamstark@55 87
adamstark@55 88
adamstark@55 89 //=======================================================================
adamstark@91 90 void BTrack::initialise (int hopSize_, int frameSize_)
adamstark@55 91 {
adamstark@97 92 // set vector sizes
adamstark@97 93 resampledOnsetDF.resize (512);
adamstark@97 94 acf.resize (512);
adamstark@97 95 weightingVector.resize (128);
adamstark@97 96 combFilterBankOutput.resize (128);
adamstark@97 97 tempoObservationVector.resize (41);
adamstark@97 98 delta.resize (41);
adamstark@97 99 prevDelta.resize (41);
adamstark@97 100 prevDeltaFixed.resize (41);
adamstark@97 101
adamstark@98 102 double rayleighParameter = 43;
adamstark@54 103 double pi = 3.14159265;
adamstark@46 104
adamstark@46 105
adamstark@46 106 // initialise parameters
adamstark@46 107 tightness = 5;
adamstark@46 108 alpha = 0.9;
adamstark@46 109 tempo = 120;
adamstark@58 110 estimatedTempo = 120.0;
adamstark@59 111 tempoToLagFactor = 60.*44100./512.;
adamstark@46 112
adamstark@46 113 m0 = 10;
adamstark@58 114 beatCounter = -1;
adamstark@46 115
adamstark@57 116 beatDueInFrame = false;
adamstark@46 117
adamstark@58 118
adamstark@46 119 // create rayleigh weighting vector
adamstark@91 120 for (int n = 0; n < 128; n++)
adamstark@98 121 weightingVector[n] = ((double) n / pow (rayleighParameter, 2)) * exp((-1 * pow((double) - n, 2)) / (2 * pow (rayleighParameter, 2)));
adamstark@46 122
adamstark@97 123 // initialise prev_delta
adamstark@97 124 std::fill (prevDelta.begin(), prevDelta.end(), 1);
adamstark@97 125
adamstark@54 126 double t_mu = 41/2;
adamstark@54 127 double m_sig;
adamstark@54 128 double x;
adamstark@46 129 // create tempo transition matrix
adamstark@46 130 m_sig = 41/8;
adamstark@46 131 for (int i = 0;i < 41;i++)
adamstark@46 132 {
adamstark@46 133 for (int j = 0;j < 41;j++)
adamstark@46 134 {
adamstark@46 135 x = j+1;
adamstark@46 136 t_mu = i+1;
adamstark@58 137 tempoTransitionMatrix[i][j] = (1 / (m_sig * sqrt(2*pi))) * exp( (-1*pow((x-t_mu),2)) / (2*pow(m_sig,2)) );
adamstark@46 138 }
adamstark@55 139 }
adamstark@46 140
adamstark@46 141 // tempo is not fixed
adamstark@58 142 tempoFixed = false;
adamstark@58 143
adamstark@58 144 // initialise latest cumulative score value
adamstark@58 145 // in case it is requested before any processing takes place
adamstark@58 146 latestCumulativeScoreValue = 0;
adamstark@55 147
adamstark@55 148 // initialise algorithm given the hopsize
adamstark@57 149 setHopSize(hopSize_);
adamstark@88 150
adamstark@88 151
adamstark@88 152 // Set up FFT for calculating the auto-correlation function
adamstark@88 153 FFTLengthForACFCalculation = 1024;
adamstark@88 154
adamstark@93 155 #ifdef USE_FFTW
adamstark@91 156 complexIn = (fftw_complex*) fftw_malloc (sizeof(fftw_complex) * FFTLengthForACFCalculation); // complex array to hold fft data
adamstark@91 157 complexOut = (fftw_complex*) fftw_malloc (sizeof(fftw_complex) * FFTLengthForACFCalculation); // complex array to hold fft data
adamstark@88 158
adamstark@91 159 acfForwardFFT = fftw_plan_dft_1d (FFTLengthForACFCalculation, complexIn, complexOut, FFTW_FORWARD, FFTW_ESTIMATE); // FFT plan initialisation
adamstark@91 160 acfBackwardFFT = fftw_plan_dft_1d (FFTLengthForACFCalculation, complexOut, complexIn, FFTW_BACKWARD, FFTW_ESTIMATE); // FFT plan initialisation
adamstark@93 161 #endif
adamstark@93 162
adamstark@93 163 #ifdef USE_KISS_FFT
adamstark@93 164 fftIn = new kiss_fft_cpx[FFTLengthForACFCalculation];
adamstark@93 165 fftOut = new kiss_fft_cpx[FFTLengthForACFCalculation];
adamstark@93 166 cfgForwards = kiss_fft_alloc (FFTLengthForACFCalculation, 0, 0, 0);
adamstark@93 167 cfgBackwards = kiss_fft_alloc (FFTLengthForACFCalculation, 1, 0, 0);
adamstark@93 168 #endif
adamstark@46 169 }
adamstark@46 170
adamstark@51 171 //=======================================================================
adamstark@91 172 void BTrack::setHopSize (int hopSize_)
adamstark@46 173 {
adamstark@57 174 hopSize = hopSize_;
adamstark@97 175 onsetDFBufferSize = (512 * 512) / hopSize; // calculate df buffer size
adamstark@46 176
adamstark@57 177 beatPeriod = round(60/((((double) hopSize)/44100)*tempo));
adamstark@63 178
adamstark@63 179 // set size of onset detection function buffer
adamstark@91 180 onsetDF.resize (onsetDFBufferSize);
adamstark@63 181
adamstark@63 182 // set size of cumulative score buffer
adamstark@91 183 cumulativeScore.resize (onsetDFBufferSize);
adamstark@46 184
adamstark@46 185 // initialise df_buffer to zeros
adamstark@91 186 for (int i = 0; i < onsetDFBufferSize; i++)
adamstark@46 187 {
adamstark@58 188 onsetDF[i] = 0;
adamstark@58 189 cumulativeScore[i] = 0;
adamstark@46 190
adamstark@57 191 if ((i % ((int) round(beatPeriod))) == 0)
adamstark@46 192 {
adamstark@58 193 onsetDF[i] = 1;
adamstark@46 194 }
adamstark@46 195 }
adamstark@46 196 }
adamstark@46 197
adamstark@51 198 //=======================================================================
adamstark@91 199 void BTrack::updateHopAndFrameSize (int hopSize_, int frameSize_)
adamstark@65 200 {
adamstark@65 201 // update the onset detection function object
adamstark@91 202 odf.initialise (hopSize_, frameSize_);
adamstark@65 203
adamstark@65 204 // update the hop size being used by the beat tracker
adamstark@91 205 setHopSize (hopSize_);
adamstark@65 206 }
adamstark@65 207
adamstark@65 208 //=======================================================================
adamstark@57 209 bool BTrack::beatDueInCurrentFrame()
adamstark@57 210 {
adamstark@57 211 return beatDueInFrame;
adamstark@57 212 }
adamstark@57 213
adamstark@57 214 //=======================================================================
adamstark@78 215 double BTrack::getCurrentTempoEstimate()
adamstark@78 216 {
adamstark@78 217 return estimatedTempo;
adamstark@78 218 }
adamstark@78 219
adamstark@78 220 //=======================================================================
adamstark@57 221 int BTrack::getHopSize()
adamstark@57 222 {
adamstark@57 223 return hopSize;
adamstark@57 224 }
adamstark@57 225
adamstark@57 226 //=======================================================================
adamstark@58 227 double BTrack::getLatestCumulativeScoreValue()
adamstark@58 228 {
adamstark@58 229 return latestCumulativeScoreValue;
adamstark@58 230 }
adamstark@58 231
adamstark@58 232 //=======================================================================
adamstark@91 233 void BTrack::processAudioFrame (double* frame)
adamstark@55 234 {
adamstark@55 235 // calculate the onset detection function sample for the frame
adamstark@91 236 double sample = odf.calculateOnsetDetectionFunctionSample (frame);
adamstark@55 237
adamstark@55 238 // process the new onset detection function sample in the beat tracking algorithm
adamstark@91 239 processOnsetDetectionFunctionSample (sample);
adamstark@55 240 }
adamstark@55 241
adamstark@55 242 //=======================================================================
adamstark@91 243 void BTrack::processOnsetDetectionFunctionSample (double newSample)
adamstark@56 244 {
adamstark@56 245 // we need to ensure that the onset
adamstark@56 246 // detection function sample is positive
adamstark@91 247 newSample = fabs (newSample);
adamstark@56 248
adamstark@56 249 // add a tiny constant to the sample to stop it from ever going
adamstark@56 250 // to zero. this is to avoid problems further down the line
adamstark@56 251 newSample = newSample + 0.0001;
adamstark@56 252
adamstark@46 253 m0--;
adamstark@58 254 beatCounter--;
adamstark@57 255 beatDueInFrame = false;
adamstark@90 256
adamstark@46 257 // add new sample at the end
adamstark@91 258 onsetDF.addSampleToEnd (newSample);
adamstark@46 259
adamstark@46 260 // update cumulative score
adamstark@91 261 updateCumulativeScore (newSample);
adamstark@46 262
adamstark@97 263 // if we are halfway between beats, predict a beat
adamstark@46 264 if (m0 == 0)
adamstark@97 265 predictBeat();
adamstark@46 266
adamstark@46 267 // if we are at a beat
adamstark@58 268 if (beatCounter == 0)
adamstark@46 269 {
adamstark@57 270 beatDueInFrame = true; // indicate a beat should be output
adamstark@46 271
adamstark@46 272 // recalculate the tempo
adamstark@57 273 resampleOnsetDetectionFunction();
adamstark@57 274 calculateTempo();
adamstark@46 275 }
adamstark@46 276 }
adamstark@46 277
adamstark@51 278 //=======================================================================
adamstark@91 279 void BTrack::setTempo (double tempo)
adamstark@97 280 {
adamstark@46 281 /////////// TEMPO INDICATION RESET //////////////////
adamstark@46 282
adamstark@46 283 // firstly make sure tempo is between 80 and 160 bpm..
adamstark@46 284 while (tempo > 160)
adamstark@97 285 tempo = tempo / 2;
adamstark@46 286
adamstark@46 287 while (tempo < 80)
adamstark@97 288 tempo = tempo * 2;
adamstark@46 289
adamstark@46 290 // convert tempo from bpm value to integer index of tempo probability
adamstark@46 291 int tempo_index = (int) round((tempo - 80)/2);
adamstark@46 292
adamstark@97 293 // now set previous tempo observations to zero and set desired tempo index to 1
adamstark@97 294 std::fill (prevDelta.begin(), prevDelta.end(), 0);
adamstark@58 295 prevDelta[tempo_index] = 1;
adamstark@46 296
adamstark@46 297 /////////// CUMULATIVE SCORE ARTIFICAL TEMPO UPDATE //////////////////
adamstark@46 298
adamstark@46 299 // calculate new beat period
adamstark@97 300 int newBeatPeriod = (int) round (60 / ((((double) hopSize) / 44100) * tempo));
adamstark@46 301
adamstark@97 302 int k = 1;
adamstark@97 303
adamstark@97 304 // initialise onset detection function with delta functions spaced
adamstark@97 305 // at the new beat period
adamstark@97 306 for (int i = onsetDFBufferSize - 1; i >= 0; i--)
adamstark@46 307 {
adamstark@97 308 if (k == 1)
adamstark@46 309 {
adamstark@58 310 cumulativeScore[i] = 150;
adamstark@58 311 onsetDF[i] = 150;
adamstark@46 312 }
adamstark@46 313 else
adamstark@46 314 {
adamstark@58 315 cumulativeScore[i] = 10;
adamstark@58 316 onsetDF[i] = 10;
adamstark@46 317 }
adamstark@46 318
adamstark@97 319 k++;
adamstark@46 320
adamstark@97 321 if (k > newBeatPeriod)
adamstark@46 322 {
adamstark@97 323 k = 1;
adamstark@46 324 }
adamstark@46 325 }
adamstark@46 326
adamstark@46 327 /////////// INDICATE THAT THIS IS A BEAT //////////////////
adamstark@46 328
adamstark@46 329 // beat is now
adamstark@58 330 beatCounter = 0;
adamstark@46 331
adamstark@46 332 // offbeat is half of new beat period away
adamstark@97 333 m0 = (int) round (((double) newBeatPeriod) / 2);
adamstark@46 334 }
adamstark@46 335
adamstark@51 336 //=======================================================================
adamstark@91 337 void BTrack::fixTempo (double tempo)
adamstark@46 338 {
adamstark@46 339 // firstly make sure tempo is between 80 and 160 bpm..
adamstark@46 340 while (tempo > 160)
adamstark@46 341 {
adamstark@46 342 tempo = tempo/2;
adamstark@46 343 }
adamstark@46 344
adamstark@46 345 while (tempo < 80)
adamstark@46 346 {
adamstark@46 347 tempo = tempo * 2;
adamstark@46 348 }
adamstark@46 349
adamstark@46 350 // convert tempo from bpm value to integer index of tempo probability
adamstark@46 351 int tempo_index = (int) round((tempo - 80)/2);
adamstark@46 352
adamstark@46 353 // now set previous fixed previous tempo observation values to zero
adamstark@46 354 for (int i=0;i < 41;i++)
adamstark@46 355 {
adamstark@58 356 prevDeltaFixed[i] = 0;
adamstark@46 357 }
adamstark@46 358
adamstark@46 359 // set desired tempo index to 1
adamstark@58 360 prevDeltaFixed[tempo_index] = 1;
adamstark@46 361
adamstark@46 362 // set the tempo fix flag
adamstark@58 363 tempoFixed = true;
adamstark@46 364 }
adamstark@46 365
adamstark@51 366 //=======================================================================
adamstark@57 367 void BTrack::doNotFixTempo()
adamstark@46 368 {
adamstark@46 369 // set the tempo fix flag
adamstark@58 370 tempoFixed = false;
adamstark@46 371 }
adamstark@46 372
adamstark@51 373 //=======================================================================
adamstark@57 374 void BTrack::resampleOnsetDetectionFunction()
adamstark@46 375 {
adamstark@46 376 float output[512];
adamstark@58 377 float input[onsetDFBufferSize];
adamstark@54 378
adamstark@58 379 for (int i = 0;i < onsetDFBufferSize;i++)
adamstark@58 380 input[i] = (float) onsetDF[i];
adamstark@89 381
adamstark@97 382 double ratio = 512.0 / ((double) onsetDFBufferSize);
adamstark@97 383 int bufferLength = onsetDFBufferSize;
adamstark@97 384 int outputLength = 512;
adamstark@89 385
adamstark@97 386 SRC_DATA src_data;
adamstark@89 387 src_data.data_in = input;
adamstark@97 388 src_data.input_frames = bufferLength;
adamstark@97 389 src_data.src_ratio = ratio;
adamstark@89 390 src_data.data_out = output;
adamstark@97 391 src_data.output_frames = outputLength;
adamstark@89 392
adamstark@89 393 src_simple (&src_data, SRC_SINC_BEST_QUALITY, 1);
adamstark@89 394
adamstark@97 395 for (int i = 0; i < outputLength; i++)
adamstark@89 396 resampledOnsetDF[i] = (double) src_data.data_out[i];
adamstark@46 397 }
adamstark@46 398
adamstark@51 399 //=======================================================================
adamstark@57 400 void BTrack::calculateTempo()
adamstark@46 401 {
adamstark@46 402 // adaptive threshold on input
adamstark@97 403 adaptiveThreshold (resampledOnsetDF, 512);
adamstark@46 404
adamstark@46 405 // calculate auto-correlation function of detection function
adamstark@97 406 calculateBalancedACF (&resampledOnsetDF[0]);
adamstark@46 407
adamstark@46 408 // calculate output of comb filterbank
adamstark@57 409 calculateOutputOfCombFilterBank();
adamstark@46 410
adamstark@46 411 // adaptive threshold on rcf
adamstark@97 412 adaptiveThreshold (combFilterBankOutput, 128);
adamstark@46 413
adamstark@46 414
adamstark@46 415 int t_index;
adamstark@46 416 int t_index2;
adamstark@59 417 // calculate tempo observation vector from beat period observation vector
adamstark@46 418 for (int i = 0;i < 41;i++)
adamstark@46 419 {
adamstark@91 420 t_index = (int) round (tempoToLagFactor / ((double) ((2*i)+80)));
adamstark@91 421 t_index2 = (int) round (tempoToLagFactor / ((double) ((4*i)+160)));
adamstark@46 422
adamstark@46 423
adamstark@58 424 tempoObservationVector[i] = combFilterBankOutput[t_index-1] + combFilterBankOutput[t_index2-1];
adamstark@46 425 }
adamstark@46 426
adamstark@46 427
adamstark@54 428 double maxval;
adamstark@54 429 double maxind;
adamstark@54 430 double curval;
adamstark@46 431
adamstark@46 432 // if tempo is fixed then always use a fixed set of tempi as the previous observation probability function
adamstark@58 433 if (tempoFixed)
adamstark@46 434 {
adamstark@46 435 for (int k = 0;k < 41;k++)
adamstark@46 436 {
adamstark@58 437 prevDelta[k] = prevDeltaFixed[k];
adamstark@46 438 }
adamstark@46 439 }
adamstark@46 440
adamstark@46 441 for (int j=0;j < 41;j++)
adamstark@46 442 {
adamstark@46 443 maxval = -1;
adamstark@46 444 for (int i = 0;i < 41;i++)
adamstark@46 445 {
adamstark@91 446 curval = prevDelta[i] * tempoTransitionMatrix[i][j];
adamstark@46 447
adamstark@46 448 if (curval > maxval)
adamstark@46 449 {
adamstark@46 450 maxval = curval;
adamstark@46 451 }
adamstark@46 452 }
adamstark@46 453
adamstark@91 454 delta[j] = maxval * tempoObservationVector[j];
adamstark@46 455 }
adamstark@46 456
adamstark@46 457
adamstark@97 458 normaliseArray (delta);
adamstark@46 459
adamstark@46 460 maxind = -1;
adamstark@46 461 maxval = -1;
adamstark@46 462
adamstark@46 463 for (int j=0;j < 41;j++)
adamstark@46 464 {
adamstark@46 465 if (delta[j] > maxval)
adamstark@46 466 {
adamstark@46 467 maxval = delta[j];
adamstark@46 468 maxind = j;
adamstark@46 469 }
adamstark@46 470
adamstark@58 471 prevDelta[j] = delta[j];
adamstark@46 472 }
adamstark@46 473
adamstark@91 474 beatPeriod = round ((60.0*44100.0)/(((2*maxind)+80)*((double) hopSize)));
adamstark@46 475
adamstark@57 476 if (beatPeriod > 0)
adamstark@46 477 {
adamstark@91 478 estimatedTempo = 60.0/((((double) hopSize) / 44100.0) * beatPeriod);
adamstark@46 479 }
adamstark@46 480 }
adamstark@46 481
adamstark@51 482 //=======================================================================
adamstark@97 483 void BTrack::adaptiveThreshold (std::vector<double>& x, int N)
adamstark@46 484 {
adamstark@46 485 int i = 0;
adamstark@46 486 int k,t = 0;
adamstark@54 487 double x_thresh[N];
adamstark@46 488
adamstark@46 489 int p_post = 7;
adamstark@46 490 int p_pre = 8;
adamstark@46 491
adamstark@52 492 t = std::min(N,p_post); // what is smaller, p_post of df size. This is to avoid accessing outside of arrays
adamstark@46 493
adamstark@46 494 // find threshold for first 't' samples, where a full average cannot be computed yet
adamstark@97 495 for (i = 0; i <= t; i++)
adamstark@46 496 {
adamstark@97 497 k = std::min ((i + p_pre), N);
adamstark@97 498 x_thresh[i] = calculateMeanOfArray (x, 1, k);
adamstark@46 499 }
adamstark@46 500 // find threshold for bulk of samples across a moving average from [i-p_pre,i+p_post]
adamstark@97 501 for (i = t + 1; i < N - p_post; i++)
adamstark@46 502 {
adamstark@97 503 x_thresh[i] = calculateMeanOfArray (x, i - p_pre, i + p_post);
adamstark@46 504 }
adamstark@46 505 // for last few samples calculate threshold, again, not enough samples to do as above
adamstark@97 506 for (i = N - p_post; i < N; i++)
adamstark@46 507 {
adamstark@97 508 k = std::max ((i - p_post), 1);
adamstark@97 509 x_thresh[i] = calculateMeanOfArray (x, k, N);
adamstark@46 510 }
adamstark@46 511
adamstark@46 512 // subtract the threshold from the detection function and check that it is not less than 0
adamstark@91 513 for (i = 0; i < N; i++)
adamstark@46 514 {
adamstark@46 515 x[i] = x[i] - x_thresh[i];
adamstark@46 516 if (x[i] < 0)
adamstark@46 517 {
adamstark@46 518 x[i] = 0;
adamstark@46 519 }
adamstark@46 520 }
adamstark@46 521 }
adamstark@46 522
adamstark@51 523 //=======================================================================
adamstark@57 524 void BTrack::calculateOutputOfCombFilterBank()
adamstark@46 525 {
adamstark@46 526 int numelem;
adamstark@46 527
adamstark@46 528 for (int i = 0;i < 128;i++)
adamstark@46 529 {
adamstark@58 530 combFilterBankOutput[i] = 0;
adamstark@46 531 }
adamstark@46 532
adamstark@46 533 numelem = 4;
adamstark@46 534
adamstark@91 535 for (int i = 2; i <= 127; i++) // max beat period
adamstark@46 536 {
adamstark@91 537 for (int a = 1; a <= numelem; a++) // number of comb elements
adamstark@46 538 {
adamstark@91 539 for (int b = 1-a; b <= a-1; b++) // general state using normalisation of comb elements
adamstark@46 540 {
adamstark@58 541 combFilterBankOutput[i-1] = combFilterBankOutput[i-1] + (acf[(a*i+b)-1]*weightingVector[i-1])/(2*a-1); // calculate value for comb filter row
adamstark@46 542 }
adamstark@46 543 }
adamstark@46 544 }
adamstark@46 545 }
adamstark@46 546
adamstark@51 547 //=======================================================================
adamstark@91 548 void BTrack::calculateBalancedACF (double* onsetDetectionFunction)
adamstark@46 549 {
adamstark@88 550 int onsetDetectionFunctionLength = 512;
adamstark@88 551
adamstark@93 552 #ifdef USE_FFTW
adamstark@88 553 // copy into complex array and zero pad
adamstark@88 554 for (int i = 0;i < FFTLengthForACFCalculation;i++)
adamstark@88 555 {
adamstark@88 556 if (i < onsetDetectionFunctionLength)
adamstark@88 557 {
adamstark@88 558 complexIn[i][0] = onsetDetectionFunction[i];
adamstark@88 559 complexIn[i][1] = 0.0;
adamstark@88 560 }
adamstark@88 561 else
adamstark@88 562 {
adamstark@88 563 complexIn[i][0] = 0.0;
adamstark@88 564 complexIn[i][1] = 0.0;
adamstark@88 565 }
adamstark@88 566 }
adamstark@88 567
adamstark@88 568 // perform the fft
adamstark@91 569 fftw_execute (acfForwardFFT);
adamstark@88 570
adamstark@88 571 // multiply by complex conjugate
adamstark@88 572 for (int i = 0;i < FFTLengthForACFCalculation;i++)
adamstark@88 573 {
adamstark@88 574 complexOut[i][0] = complexOut[i][0]*complexOut[i][0] + complexOut[i][1]*complexOut[i][1];
adamstark@88 575 complexOut[i][1] = 0.0;
adamstark@88 576 }
adamstark@88 577
adamstark@88 578 // perform the ifft
adamstark@91 579 fftw_execute (acfBackwardFFT);
adamstark@88 580
adamstark@93 581 #endif
adamstark@93 582
adamstark@93 583 #ifdef USE_KISS_FFT
adamstark@93 584 // copy into complex array and zero pad
adamstark@93 585 for (int i = 0;i < FFTLengthForACFCalculation;i++)
adamstark@93 586 {
adamstark@93 587 if (i < onsetDetectionFunctionLength)
adamstark@93 588 {
adamstark@93 589 fftIn[i].r = onsetDetectionFunction[i];
adamstark@93 590 fftIn[i].i = 0.0;
adamstark@93 591 }
adamstark@93 592 else
adamstark@93 593 {
adamstark@93 594 fftIn[i].r = 0.0;
adamstark@93 595 fftIn[i].i = 0.0;
adamstark@93 596 }
adamstark@93 597 }
adamstark@93 598
adamstark@93 599 // execute kiss fft
adamstark@93 600 kiss_fft (cfgForwards, fftIn, fftOut);
adamstark@93 601
adamstark@93 602 // multiply by complex conjugate
adamstark@93 603 for (int i = 0;i < FFTLengthForACFCalculation;i++)
adamstark@93 604 {
adamstark@93 605 fftOut[i].r = fftOut[i].r * fftOut[i].r + fftOut[i].i * fftOut[i].i;
adamstark@93 606 fftOut[i].i = 0.0;
adamstark@93 607 }
adamstark@93 608
adamstark@93 609 // perform the ifft
adamstark@93 610 kiss_fft (cfgBackwards, fftOut, fftIn);
adamstark@93 611
adamstark@93 612 #endif
adamstark@88 613
adamstark@88 614 double lag = 512;
adamstark@88 615
adamstark@91 616 for (int i = 0; i < 512; i++)
adamstark@88 617 {
adamstark@93 618 #ifdef USE_FFTW
adamstark@88 619 // calculate absolute value of result
adamstark@91 620 double absValue = sqrt (complexIn[i][0]*complexIn[i][0] + complexIn[i][1]*complexIn[i][1]);
adamstark@93 621 #endif
adamstark@88 622
adamstark@93 623 #ifdef USE_KISS_FFT
adamstark@93 624 // calculate absolute value of result
adamstark@93 625 double absValue = sqrt (fftIn[i].r * fftIn[i].r + fftIn[i].i * fftIn[i].i);
adamstark@93 626 #endif
adamstark@88 627 // divide by inverse lad to deal with scale bias towards small lags
adamstark@88 628 acf[i] = absValue / lag;
adamstark@88 629
adamstark@88 630 // this division by 1024 is technically unnecessary but it ensures the algorithm produces
adamstark@88 631 // exactly the same ACF output as the old time domain implementation. The time difference is
adamstark@88 632 // minimal so I decided to keep it
adamstark@88 633 acf[i] = acf[i] / 1024.;
adamstark@88 634
adamstark@88 635 lag = lag - 1.;
adamstark@88 636 }
adamstark@46 637 }
adamstark@46 638
adamstark@51 639 //=======================================================================
adamstark@97 640 double BTrack::calculateMeanOfArray (std::vector<double>& array, int startIndex, int endIndex)
adamstark@46 641 {
adamstark@97 642 int length = endIndex - startIndex;
adamstark@97 643 double sum = std::accumulate (array.begin() + startIndex, array.begin() + endIndex, 0.0);
adamstark@47 644
adamstark@47 645 if (length > 0)
adamstark@97 646 return sum / static_cast<double> (length); // average and return
adamstark@47 647 else
adamstark@47 648 return 0;
adamstark@46 649 }
adamstark@46 650
adamstark@51 651 //=======================================================================
adamstark@97 652 void BTrack::normaliseArray (std::vector<double>& array)
adamstark@46 653 {
adamstark@97 654 double sum = std::accumulate (array.begin(), array.end(), 0.0);
adamstark@46 655
adamstark@46 656 if (sum > 0)
adamstark@97 657 {
adamstark@97 658 for (int i = 0; i < array.size(); i++)
adamstark@97 659 array[i] = array[i] / sum;
adamstark@97 660 }
adamstark@46 661 }
adamstark@46 662
adamstark@51 663 //=======================================================================
adamstark@91 664 void BTrack::updateCumulativeScore (double odfSample)
adamstark@98 665 {
adamstark@98 666 int start = onsetDFBufferSize - round (2. * beatPeriod);
adamstark@98 667 int end = onsetDFBufferSize - round (beatPeriod / 2.);
adamstark@98 668 int windowSize = end - start + 1;
adamstark@46 669
adamstark@98 670 double w1[windowSize];
adamstark@97 671 double v = -2. * beatPeriod;
adamstark@98 672 double weightedCumulativeScore;
adamstark@46 673
adamstark@46 674 // create window
adamstark@98 675 for (int i = 0; i < windowSize; i++)
adamstark@46 676 {
adamstark@98 677 double a = tightness * log (-v / beatPeriod);
adamstark@98 678 w1[i] = exp ((-1. * a * a) / 2.);
adamstark@98 679 v = v + 1.;
adamstark@46 680 }
adamstark@46 681
adamstark@46 682 // calculate new cumulative score value
adamstark@98 683 double maxValue = 0;
adamstark@46 684 int n = 0;
adamstark@98 685 for (int i = start; i <= end; i++)
adamstark@46 686 {
adamstark@98 687 weightedCumulativeScore = cumulativeScore[i] * w1[n];
adamstark@46 688
adamstark@98 689 if (weightedCumulativeScore > maxValue)
adamstark@98 690 maxValue = weightedCumulativeScore;
adamstark@98 691
adamstark@46 692 n++;
adamstark@46 693 }
adamstark@46 694
adamstark@98 695 latestCumulativeScoreValue = ((1 - alpha) * odfSample) + (alpha * maxValue);
adamstark@91 696 cumulativeScore.addSampleToEnd (latestCumulativeScoreValue);
adamstark@46 697 }
adamstark@46 698
adamstark@51 699 //=======================================================================
adamstark@57 700 void BTrack::predictBeat()
adamstark@46 701 {
adamstark@58 702 int windowSize = (int) beatPeriod;
adamstark@58 703 double futureCumulativeScore[onsetDFBufferSize + windowSize];
adamstark@58 704 double w2[windowSize];
adamstark@93 705
adamstark@46 706 // copy cumscore to first part of fcumscore
adamstark@58 707 for (int i = 0;i < onsetDFBufferSize;i++)
adamstark@46 708 {
adamstark@58 709 futureCumulativeScore[i] = cumulativeScore[i];
adamstark@46 710 }
adamstark@46 711
adamstark@46 712 // create future window
adamstark@54 713 double v = 1;
adamstark@91 714 for (int i = 0; i < windowSize; i++)
adamstark@46 715 {
adamstark@57 716 w2[i] = exp((-1*pow((v - (beatPeriod/2)),2)) / (2*pow((beatPeriod/2) ,2)));
adamstark@46 717 v++;
adamstark@46 718 }
adamstark@46 719
adamstark@46 720 // create past window
adamstark@57 721 v = -2*beatPeriod;
adamstark@58 722 int start = onsetDFBufferSize - round(2*beatPeriod);
adamstark@58 723 int end = onsetDFBufferSize - round(beatPeriod/2);
adamstark@46 724 int pastwinsize = end-start+1;
adamstark@54 725 double w1[pastwinsize];
adamstark@46 726
adamstark@46 727 for (int i = 0;i < pastwinsize;i++)
adamstark@46 728 {
adamstark@57 729 w1[i] = exp((-1*pow(tightness*log(-v/beatPeriod),2))/2);
adamstark@46 730 v = v+1;
adamstark@46 731 }
adamstark@46 732
adamstark@46 733 // calculate future cumulative score
adamstark@54 734 double max;
adamstark@46 735 int n;
adamstark@54 736 double wcumscore;
adamstark@91 737 for (int i = onsetDFBufferSize; i < (onsetDFBufferSize + windowSize); i++)
adamstark@46 738 {
adamstark@91 739 start = i - round (2*beatPeriod);
adamstark@91 740 end = i - round (beatPeriod/2);
adamstark@46 741
adamstark@46 742 max = 0;
adamstark@46 743 n = 0;
adamstark@46 744 for (int k=start;k <= end;k++)
adamstark@46 745 {
adamstark@58 746 wcumscore = futureCumulativeScore[k]*w1[n];
adamstark@46 747
adamstark@46 748 if (wcumscore > max)
adamstark@46 749 {
adamstark@46 750 max = wcumscore;
adamstark@46 751 }
adamstark@46 752 n++;
adamstark@46 753 }
adamstark@46 754
adamstark@58 755 futureCumulativeScore[i] = max;
adamstark@46 756 }
adamstark@46 757
adamstark@46 758 // predict beat
adamstark@46 759 max = 0;
adamstark@46 760 n = 0;
adamstark@46 761
adamstark@91 762 for (int i = onsetDFBufferSize; i < (onsetDFBufferSize + windowSize); i++)
adamstark@46 763 {
adamstark@58 764 wcumscore = futureCumulativeScore[i]*w2[n];
adamstark@46 765
adamstark@46 766 if (wcumscore > max)
adamstark@46 767 {
adamstark@46 768 max = wcumscore;
adamstark@58 769 beatCounter = n;
adamstark@46 770 }
adamstark@46 771
adamstark@46 772 n++;
adamstark@46 773 }
adamstark@46 774
adamstark@46 775 // set next prediction time
adamstark@91 776 m0 = beatCounter + round (beatPeriod / 2);
adamstark@97 777 }