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annotate plugins/Notes.cpp @ 198:3a76aa26b578 tip master

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wscript: check for 64bit using sys.maxsize (closes #3)
author Paul Brossier <piem@piem.org>
date Mon, 04 Dec 2017 01:42:19 +0100
parents f80b207ccd15
children
rev   line source
cannam@0 1 /* -*- c-basic-offset: 4 indent-tabs-mode: nil -*- vi:set ts=8 sts=4 sw=4: */
cannam@0 2
cannam@0 3 /*
cannam@0 4 Vamp feature extraction plugins using Paul Brossier's Aubio library.
cannam@0 5
cannam@0 6 Centre for Digital Music, Queen Mary, University of London.
cannam@20 7 This file copyright 2006-2008 Chris Cannam and QMUL.
cannam@0 8
piem@112 9 This file is part of vamp-aubio-plugins.
piem@112 10
piem@112 11 vamp-aubio is free software: you can redistribute it and/or modify
piem@112 12 it under the terms of the GNU General Public License as published by
piem@112 13 the Free Software Foundation, either version 3 of the License, or
piem@112 14 (at your option) any later version.
piem@112 15
piem@112 16 vamp-aubio is distributed in the hope that it will be useful,
piem@112 17 but WITHOUT ANY WARRANTY; without even the implied warranty of
piem@112 18 MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
piem@112 19 GNU General Public License for more details.
piem@112 20
piem@112 21 You should have received a copy of the GNU General Public License
piem@112 22 along with aubio. If not, see <http://www.gnu.org/licenses/>.
cannam@0 23
cannam@0 24 */
cannam@0 25
piem@2 26 #include <math.h>
cannam@0 27 #include "Notes.h"
cannam@0 28
cannam@28 29 #include <algorithm>
cannam@28 30
cannam@0 31 using std::string;
cannam@0 32 using std::vector;
cannam@0 33 using std::cerr;
cannam@0 34 using std::endl;
cannam@0 35
cannam@31 36 Notes::Notes(float inputSampleRate) :
cannam@0 37 Plugin(inputSampleRate),
cannam@0 38 m_ibuf(0),
cannam@0 39 m_onset(0),
cannam@34 40 m_pitch(0),
cannam@0 41 m_onsetdet(0),
cannam@30 42 m_onsettype(OnsetComplex),
cannam@0 43 m_pitchdet(0),
cannam@30 44 m_pitchtype(PitchYinFFT),
cannam@0 45 m_threshold(0.3),
cannam@34 46 m_silence(-70),
cannam@34 47 m_minioi(4),
cannam@7 48 m_median(6),
cannam@36 49 m_minpitch(32),
cannam@7 50 m_maxpitch(95),
cannam@7 51 m_wrapRange(false),
cannam@7 52 m_avoidLeaps(false),
cannam@7 53 m_prevPitch(-1)
cannam@0 54 {
cannam@0 55 }
cannam@0 56
cannam@0 57 Notes::~Notes()
cannam@0 58 {
cannam@30 59 if (m_onsetdet) del_aubio_onset(m_onsetdet);
cannam@30 60 if (m_pitchdet) del_aubio_pitch(m_pitchdet);
cannam@0 61 if (m_ibuf) del_fvec(m_ibuf);
cannam@0 62 if (m_onset) del_fvec(m_onset);
cannam@34 63 if (m_pitch) del_fvec(m_pitch);
cannam@0 64 }
cannam@0 65
cannam@0 66 string
cannam@13 67 Notes::getIdentifier() const
cannam@0 68 {
cannam@0 69 return "aubionotes";
cannam@0 70 }
cannam@0 71
cannam@0 72 string
cannam@13 73 Notes::getName() const
cannam@13 74 {
cannam@13 75 return "Aubio Note Tracker";
cannam@13 76 }
cannam@13 77
cannam@13 78 string
cannam@0 79 Notes::getDescription() const
cannam@0 80 {
cannam@13 81 return "Estimate note onset positions, pitches and durations";
cannam@0 82 }
cannam@0 83
cannam@0 84 string
cannam@0 85 Notes::getMaker() const
cannam@0 86 {
cannam@0 87 return "Paul Brossier (plugin by Chris Cannam)";
cannam@0 88 }
cannam@0 89
cannam@0 90 int
cannam@0 91 Notes::getPluginVersion() const
cannam@0 92 {
cannam@31 93 return 4;
cannam@0 94 }
cannam@0 95
cannam@0 96 string
cannam@0 97 Notes::getCopyright() const
cannam@0 98 {
cannam@0 99 return "GPL";
cannam@0 100 }
cannam@0 101
cannam@0 102 bool
cannam@0 103 Notes::initialise(size_t channels, size_t stepSize, size_t blockSize)
cannam@0 104 {
cannam@32 105 if (channels != 1) {
cannam@32 106 std::cerr << "Notes::initialise: channels must be 1" << std::endl;
cannam@32 107 return false;
cannam@32 108 }
cannam@32 109
cannam@0 110 m_stepSize = stepSize;
cannam@0 111 m_blockSize = blockSize;
cannam@0 112
cannam@32 113 m_ibuf = new_fvec(stepSize);
cannam@32 114 m_onset = new_fvec(1);
cannam@34 115 m_pitch = new_fvec(1);
cannam@0 116
cannam@37 117 reset();
cannam@37 118
cannam@37 119 return true;
cannam@37 120 }
cannam@37 121
cannam@37 122 void
cannam@37 123 Notes::reset()
cannam@37 124 {
cannam@37 125 if (m_onsetdet) del_aubio_onset(m_onsetdet);
cannam@37 126 if (m_pitchdet) del_aubio_pitch(m_pitchdet);
cannam@37 127
cannam@34 128 m_onsetdet = new_aubio_onset
cannam@34 129 (const_cast<char *>(getAubioNameForOnsetType(m_onsettype)),
cannam@37 130 m_blockSize,
cannam@37 131 m_stepSize,
cannam@34 132 lrintf(m_inputSampleRate));
cannam@34 133
cannam@34 134 aubio_onset_set_threshold(m_onsetdet, m_threshold);
cannam@34 135 aubio_onset_set_silence(m_onsetdet, m_silence);
cannam@34 136 aubio_onset_set_minioi(m_onsetdet, m_minioi);
cannam@0 137
cannam@34 138 m_pitchdet = new_aubio_pitch
cannam@34 139 (const_cast<char *>(getAubioNameForPitchType(m_pitchtype)),
cannam@37 140 m_blockSize,
cannam@37 141 m_stepSize,
cannam@34 142 lrintf(m_inputSampleRate));
cannam@34 143
cannam@35 144 aubio_pitch_set_unit(m_pitchdet, const_cast<char *>("freq"));
cannam@0 145
cannam@0 146 m_count = 0;
piem@5 147 m_delay = Vamp::RealTime::frame2RealTime((4 + m_median) * m_stepSize,
piem@5 148 lrintf(m_inputSampleRate));
cannam@0 149 m_currentOnset = Vamp::RealTime::zeroTime;
cannam@0 150 m_haveCurrent = false;
cannam@7 151 m_prevPitch = -1;
cannam@0 152 }
cannam@0 153
cannam@0 154 size_t
cannam@0 155 Notes::getPreferredStepSize() const
cannam@0 156 {
piem@2 157 return 512;
cannam@0 158 }
cannam@0 159
cannam@0 160 size_t
cannam@0 161 Notes::getPreferredBlockSize() const
cannam@0 162 {
cannam@4 163 return 4 * getPreferredStepSize();
cannam@0 164 }
cannam@0 165
cannam@0 166 Notes::ParameterList
cannam@0 167 Notes::getParameterDescriptors() const
cannam@0 168 {
cannam@0 169 ParameterList list;
cannam@0 170
cannam@0 171 ParameterDescriptor desc;
cannam@13 172 desc.identifier = "onsettype";
cannam@13 173 desc.name = "Onset Detection Function Type";
piem@62 174 desc.description = "Type of onset detection function to use";
cannam@0 175 desc.minValue = 0;
cannam@34 176 desc.maxValue = 7;
cannam@34 177 desc.defaultValue = (int)OnsetComplex;
cannam@0 178 desc.isQuantized = true;
cannam@0 179 desc.quantizeStep = 1;
cannam@0 180 desc.valueNames.push_back("Energy Based");
cannam@0 181 desc.valueNames.push_back("Spectral Difference");
cannam@0 182 desc.valueNames.push_back("High-Frequency Content");
cannam@0 183 desc.valueNames.push_back("Complex Domain");
cannam@0 184 desc.valueNames.push_back("Phase Deviation");
cannam@0 185 desc.valueNames.push_back("Kullback-Liebler");
cannam@0 186 desc.valueNames.push_back("Modified Kullback-Liebler");
cannam@34 187 desc.valueNames.push_back("Spectral Flux");
cannam@0 188 list.push_back(desc);
cannam@0 189
cannam@0 190 desc = ParameterDescriptor();
cannam@13 191 desc.identifier = "pitchtype";
cannam@13 192 desc.name = "Pitch Detection Function Type";
piem@62 193 desc.description = "Type of pitch detection function to use";
cannam@0 194 desc.minValue = 0;
cannam@0 195 desc.maxValue = 4;
cannam@34 196 desc.defaultValue = (int)PitchYinFFT;
cannam@0 197 desc.isQuantized = true;
cannam@0 198 desc.quantizeStep = 1;
cannam@0 199 desc.valueNames.push_back("YIN Frequency Estimator");
cannam@0 200 desc.valueNames.push_back("Spectral Comb");
cannam@0 201 desc.valueNames.push_back("Schmitt");
cannam@0 202 desc.valueNames.push_back("Fast Harmonic Comb");
cannam@0 203 desc.valueNames.push_back("YIN with FFT");
cannam@0 204 list.push_back(desc);
cannam@0 205
cannam@0 206 desc = ParameterDescriptor();
cannam@13 207 desc.identifier = "minpitch";
cannam@13 208 desc.name = "Minimum Pitch";
piem@78 209 desc.description = "Lowest pitch value to look for";
cannam@7 210 desc.minValue = 0;
cannam@7 211 desc.maxValue = 127;
cannam@36 212 desc.defaultValue = 32;
cannam@7 213 desc.unit = "MIDI units";
cannam@7 214 desc.isQuantized = true;
cannam@7 215 desc.quantizeStep = 1;
cannam@7 216 list.push_back(desc);
cannam@7 217
cannam@7 218 desc = ParameterDescriptor();
cannam@13 219 desc.identifier = "maxpitch";
cannam@13 220 desc.name = "Maximum Pitch";
piem@62 221 desc.description = "Highest pitch value to look for";
cannam@7 222 desc.minValue = 0;
cannam@7 223 desc.maxValue = 127;
cannam@7 224 desc.defaultValue = 95;
cannam@7 225 desc.unit = "MIDI units";
cannam@7 226 desc.isQuantized = true;
cannam@7 227 desc.quantizeStep = 1;
cannam@7 228 list.push_back(desc);
cannam@7 229
cannam@7 230 desc = ParameterDescriptor();
cannam@13 231 desc.identifier = "wraprange";
cannam@13 232 desc.name = "Fold Higher or Lower Notes into Range";
piem@62 233 desc.description = "Notes detected outside the range will be transposed to higher or lower octaves";
cannam@7 234 desc.minValue = 0;
cannam@7 235 desc.maxValue = 1;
cannam@7 236 desc.defaultValue = 0;
cannam@7 237 desc.isQuantized = true;
cannam@7 238 desc.quantizeStep = 1;
cannam@7 239 list.push_back(desc);
cannam@7 240
cannam@7 241 desc = ParameterDescriptor();
cannam@13 242 desc.identifier = "avoidleaps";
cannam@13 243 desc.name = "Avoid Multi-Octave Jumps";
piem@62 244 desc.description = "Minimize octave jumps by transposing to the octave of the previously detected note";
cannam@7 245 desc.minValue = 0;
cannam@7 246 desc.maxValue = 1;
cannam@7 247 desc.defaultValue = 0;
cannam@7 248 desc.isQuantized = true;
cannam@7 249 desc.quantizeStep = 1;
cannam@7 250 list.push_back(desc);
cannam@7 251
cannam@7 252 desc = ParameterDescriptor();
cannam@13 253 desc.identifier = "peakpickthreshold";
cannam@13 254 desc.name = "Peak Picker Threshold";
piem@62 255 desc.description = "Peak picking threshold, the higher the least detection";
cannam@0 256 desc.minValue = 0;
cannam@0 257 desc.maxValue = 1;
cannam@0 258 desc.defaultValue = 0.3;
cannam@0 259 desc.isQuantized = false;
cannam@0 260 list.push_back(desc);
cannam@0 261
cannam@0 262 desc = ParameterDescriptor();
cannam@13 263 desc.identifier = "silencethreshold";
cannam@13 264 desc.name = "Silence Threshold";
piem@62 265 desc.description = "Silence threshold, the higher the least detection";
cannam@0 266 desc.minValue = -120;
cannam@0 267 desc.maxValue = 0;
cannam@34 268 desc.defaultValue = -70;
cannam@0 269 desc.unit = "dB";
cannam@0 270 desc.isQuantized = false;
cannam@0 271 list.push_back(desc);
cannam@0 272
cannam@34 273 desc = ParameterDescriptor();
cannam@34 274 desc.identifier = "minioi";
cannam@34 275 desc.name = "Minimum Inter-Onset Interval";
piem@62 276 desc.description = "Time interval below which two consecutive onsets should be merged";
cannam@34 277 desc.minValue = 0;
cannam@34 278 desc.maxValue = 40;
cannam@34 279 desc.defaultValue = 4;
cannam@34 280 desc.unit = "ms";
cannam@34 281 desc.isQuantized = true;
cannam@34 282 desc.quantizeStep = 1;
cannam@34 283 list.push_back(desc);
cannam@34 284
cannam@0 285 return list;
cannam@0 286 }
cannam@0 287
cannam@0 288 float
cannam@0 289 Notes::getParameter(std::string param) const
cannam@0 290 {
cannam@0 291 if (param == "onsettype") {
cannam@0 292 return m_onsettype;
cannam@0 293 } else if (param == "pitchtype") {
cannam@0 294 return m_pitchtype;
cannam@0 295 } else if (param == "peakpickthreshold") {
cannam@0 296 return m_threshold;
cannam@0 297 } else if (param == "silencethreshold") {
cannam@0 298 return m_silence;
cannam@7 299 } else if (param == "minpitch") {
cannam@7 300 return m_minpitch;
cannam@7 301 } else if (param == "maxpitch") {
cannam@7 302 return m_maxpitch;
cannam@7 303 } else if (param == "wraprange") {
cannam@7 304 return m_wrapRange ? 1.0 : 0.0;
cannam@7 305 } else if (param == "avoidleaps") {
cannam@7 306 return m_avoidLeaps ? 1.0 : 0.0;
cannam@34 307 } else if (param == "minioi") {
cannam@34 308 return m_minioi;
cannam@0 309 } else {
cannam@0 310 return 0.0;
cannam@0 311 }
cannam@0 312 }
cannam@0 313
cannam@0 314 void
cannam@0 315 Notes::setParameter(std::string param, float value)
cannam@0 316 {
cannam@0 317 if (param == "onsettype") {
cannam@0 318 switch (lrintf(value)) {
cannam@34 319 case 0: m_onsettype = OnsetEnergy; break;
cannam@34 320 case 1: m_onsettype = OnsetSpecDiff; break;
cannam@34 321 case 2: m_onsettype = OnsetHFC; break;
cannam@34 322 case 3: m_onsettype = OnsetComplex; break;
cannam@34 323 case 4: m_onsettype = OnsetPhase; break;
cannam@34 324 case 5: m_onsettype = OnsetKL; break;
cannam@34 325 case 6: m_onsettype = OnsetMKL; break;
cannam@34 326 case 7: m_onsettype = OnsetSpecFlux; break;
cannam@0 327 }
cannam@0 328 } else if (param == "pitchtype") {
cannam@0 329 switch (lrintf(value)) {
cannam@34 330 case 0: m_pitchtype = PitchYin; break;
cannam@34 331 case 1: m_pitchtype = PitchMComb; break;
cannam@34 332 case 2: m_pitchtype = PitchSchmitt; break;
cannam@34 333 case 3: m_pitchtype = PitchFComb; break;
cannam@34 334 case 4: m_pitchtype = PitchYinFFT; break;
cannam@0 335 }
cannam@0 336 } else if (param == "peakpickthreshold") {
cannam@0 337 m_threshold = value;
cannam@0 338 } else if (param == "silencethreshold") {
cannam@0 339 m_silence = value;
cannam@7 340 } else if (param == "minpitch") {
cannam@7 341 m_minpitch = lrintf(value);
cannam@7 342 } else if (param == "maxpitch") {
cannam@7 343 m_maxpitch = lrintf(value);
cannam@7 344 } else if (param == "wraprange") {
cannam@7 345 m_wrapRange = (value > 0.5);
cannam@7 346 } else if (param == "avoidleaps") {
cannam@7 347 m_avoidLeaps = (value > 0.5);
cannam@34 348 } else if (param == "minioi") {
cannam@34 349 m_minioi = value;
cannam@0 350 }
cannam@0 351 }
cannam@0 352
cannam@0 353 Notes::OutputList
cannam@0 354 Notes::getOutputDescriptors() const
cannam@0 355 {
cannam@0 356 OutputList list;
cannam@0 357
cannam@0 358 OutputDescriptor d;
cannam@13 359 d.identifier = "notes";
cannam@13 360 d.name = "Notes";
piem@63 361 d.description = "List of notes detected, with their frequency and velocity";
cannam@0 362 d.unit = "Hz";
cannam@0 363 d.hasFixedBinCount = true;
cannam@20 364
cannam@31 365 d.binCount = 2;
cannam@31 366 d.binNames.push_back("Frequency");
cannam@31 367 d.binNames.push_back("Velocity");
cannam@31 368 d.hasDuration = true;
cannam@20 369
cannam@0 370 d.hasKnownExtents = false;
cannam@0 371 d.isQuantized = false;
cannam@0 372 d.sampleType = OutputDescriptor::VariableSampleRate;
cannam@0 373 d.sampleRate = 0;
cannam@0 374 list.push_back(d);
cannam@0 375
cannam@0 376 return list;
cannam@0 377 }
cannam@0 378
cannam@0 379 Notes::FeatureSet
cannam@12 380 Notes::process(const float *const *inputBuffers, Vamp::RealTime timestamp)
cannam@0 381 {
cannam@0 382 for (size_t i = 0; i < m_stepSize; ++i) {
piem@52 383 fvec_set_sample(m_ibuf, inputBuffers[0][i], i);
cannam@0 384 }
cannam@0 385
cannam@34 386 aubio_onset_do(m_onsetdet, m_ibuf, m_onset);
cannam@34 387 aubio_pitch_do(m_pitchdet, m_ibuf, m_pitch);
cannam@0 388
cannam@34 389 bool isonset = m_onset->data[0];
cannam@34 390 float frequency = m_pitch->data[0];
cannam@0 391
cannam@0 392 m_notebuf.push_back(frequency);
cannam@0 393 if (m_notebuf.size() > m_median) m_notebuf.pop_front();
cannam@0 394
cannam@0 395 float level = aubio_level_detection(m_ibuf, m_silence);
cannam@0 396
cannam@0 397 FeatureSet returnFeatures;
cannam@0 398
cannam@0 399 if (isonset) {
cannam@0 400 if (level == 1.) {
cannam@0 401 isonset = false;
cannam@0 402 m_count = 0;
cannam@0 403 if (m_haveCurrent) pushNote(returnFeatures, timestamp);
cannam@0 404 } else {
cannam@0 405 m_count = 1;
cannam@0 406 }
cannam@0 407 } else {
cannam@0 408 if (m_count > 0) ++m_count;
cannam@0 409 if (m_count == m_median) {
cannam@0 410 if (m_haveCurrent) pushNote(returnFeatures, timestamp);
cannam@0 411 m_currentOnset = timestamp;
cannam@0 412 m_currentLevel = level;
cannam@0 413 m_haveCurrent = true;
cannam@0 414 }
cannam@0 415 }
cannam@0 416
cannam@0 417 m_lastTimeStamp = timestamp;
cannam@0 418 return returnFeatures;
cannam@0 419 }
cannam@0 420
cannam@0 421 Notes::FeatureSet
cannam@0 422 Notes::getRemainingFeatures()
cannam@0 423 {
cannam@0 424 FeatureSet returnFeatures;
cannam@0 425 if (m_haveCurrent) pushNote(returnFeatures, m_lastTimeStamp);
cannam@0 426 return returnFeatures;
cannam@0 427 }
cannam@0 428
cannam@0 429 void
cannam@0 430 Notes::pushNote(FeatureSet &fs, const Vamp::RealTime &offTime)
cannam@0 431 {
cannam@0 432 std::deque<float> toSort = m_notebuf;
cannam@0 433 std::sort(toSort.begin(), toSort.end());
cannam@0 434 float median = toSort[toSort.size()/2];
cannam@0 435 if (median < 45.0) return;
cannam@0 436
cannam@7 437 float freq = median;
cannam@15 438 int midiPitch = (int)floor(aubio_freqtomidi(freq) + 0.5);
cannam@7 439
cannam@7 440 if (m_avoidLeaps) {
cannam@7 441 if (m_prevPitch >= 0) {
cannam@7 442 while (midiPitch < m_prevPitch - 12) {
cannam@7 443 midiPitch += 12;
cannam@7 444 freq *= 2;
cannam@7 445 }
cannam@7 446 while (midiPitch > m_prevPitch + 12) {
cannam@7 447 midiPitch -= 12;
cannam@7 448 freq /= 2;
cannam@7 449 }
cannam@7 450 }
cannam@7 451 }
cannam@7 452
cannam@7 453 while (midiPitch < m_minpitch) {
cannam@7 454 if (!m_wrapRange) return;
cannam@7 455 midiPitch += 12;
cannam@7 456 freq *= 2;
cannam@7 457 }
cannam@7 458
cannam@7 459 while (midiPitch > m_maxpitch) {
cannam@7 460 if (!m_wrapRange) return;
cannam@7 461 midiPitch -= 12;
cannam@7 462 freq /= 2;
cannam@7 463 }
cannam@7 464
cannam@7 465 m_prevPitch = midiPitch;
cannam@7 466
cannam@0 467 Feature feature;
cannam@0 468 feature.hasTimestamp = true;
piem@5 469 if (m_currentOnset < m_delay) m_currentOnset = m_delay;
piem@5 470 feature.timestamp = m_currentOnset - m_delay;
cannam@7 471 feature.values.push_back(freq);
cannam@20 472
cannam@31 473 feature.values.push_back
cannam@31 474 (Vamp::RealTime::realTime2Frame
cannam@31 475 (offTime, lrintf(m_inputSampleRate)) -
cannam@31 476 Vamp::RealTime::realTime2Frame
cannam@31 477 (m_currentOnset, lrintf(m_inputSampleRate)));
cannam@31 478 feature.hasDuration = false;
cannam@20 479
cannam@0 480 feature.values.push_back(m_currentLevel);
cannam@0 481 fs[0].push_back(feature);
cannam@0 482 }
cannam@0 483