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annotate src/Silvet.cpp @ 178:a53c713b2a4a

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Restore (and fix) the time-frequency distribution output (filtered CQ); tidy up the bottom-octave handling in draft mode
author Chris Cannam
date Thu, 22 May 2014 12:11:33 +0100
parents 8af9b6cd7451
children 825193ef09d2
rev   line source
Chris@31 1 /* -*- c-basic-offset: 4 indent-tabs-mode: nil -*- vi:set ts=8 sts=4 sw=4: */
Chris@31 2
Chris@31 3 /*
Chris@31 4 Silvet
Chris@31 5
Chris@31 6 A Vamp plugin for note transcription.
Chris@31 7 Centre for Digital Music, Queen Mary University of London.
Chris@31 8
Chris@31 9 This program is free software; you can redistribute it and/or
Chris@31 10 modify it under the terms of the GNU General Public License as
Chris@31 11 published by the Free Software Foundation; either version 2 of the
Chris@31 12 License, or (at your option) any later version. See the file
Chris@31 13 COPYING included with this distribution for more information.
Chris@31 14 */
Chris@31 15
Chris@31 16 #include "Silvet.h"
Chris@34 17 #include "EM.h"
Chris@31 18
Chris@152 19 #include <cq/CQSpectrogram.h>
Chris@31 20
Chris@152 21 #include "MedianFilter.h"
Chris@152 22 #include "constant-q-cpp/src/dsp/Resampler.h"
Chris@31 23
Chris@31 24 #include <vector>
Chris@31 25
Chris@32 26 #include <cstdio>
Chris@32 27
Chris@31 28 using std::vector;
Chris@48 29 using std::cout;
Chris@31 30 using std::cerr;
Chris@31 31 using std::endl;
Chris@40 32 using Vamp::RealTime;
Chris@31 33
Chris@31 34 static int processingSampleRate = 44100;
Chris@31 35 static int processingBPO = 60;
Chris@170 36
Chris@31 37 Silvet::Silvet(float inputSampleRate) :
Chris@31 38 Plugin(inputSampleRate),
Chris@161 39 m_instruments(InstrumentPack::listInstrumentPacks()),
Chris@31 40 m_resampler(0),
Chris@110 41 m_cq(0),
Chris@162 42 m_hqMode(true),
Chris@166 43 m_fineTuning(false),
Chris@178 44 m_instrument(0),
Chris@178 45 m_colsPerSec(50)
Chris@31 46 {
Chris@31 47 }
Chris@31 48
Chris@31 49 Silvet::~Silvet()
Chris@31 50 {
Chris@31 51 delete m_resampler;
Chris@31 52 delete m_cq;
Chris@41 53 for (int i = 0; i < (int)m_postFilter.size(); ++i) {
Chris@41 54 delete m_postFilter[i];
Chris@41 55 }
Chris@31 56 }
Chris@31 57
Chris@31 58 string
Chris@31 59 Silvet::getIdentifier() const
Chris@31 60 {
Chris@31 61 return "silvet";
Chris@31 62 }
Chris@31 63
Chris@31 64 string
Chris@31 65 Silvet::getName() const
Chris@31 66 {
Chris@31 67 return "Silvet Note Transcription";
Chris@31 68 }
Chris@31 69
Chris@31 70 string
Chris@31 71 Silvet::getDescription() const
Chris@31 72 {
Chris@31 73 // Return something helpful here!
Chris@31 74 return "";
Chris@31 75 }
Chris@31 76
Chris@31 77 string
Chris@31 78 Silvet::getMaker() const
Chris@31 79 {
Chris@31 80 // Your name here
Chris@31 81 return "";
Chris@31 82 }
Chris@31 83
Chris@31 84 int
Chris@31 85 Silvet::getPluginVersion() const
Chris@31 86 {
Chris@31 87 return 1;
Chris@31 88 }
Chris@31 89
Chris@31 90 string
Chris@31 91 Silvet::getCopyright() const
Chris@31 92 {
Chris@31 93 // This function is not ideally named. It does not necessarily
Chris@31 94 // need to say who made the plugin -- getMaker does that -- but it
Chris@31 95 // should indicate the terms under which it is distributed. For
Chris@31 96 // example, "Copyright (year). All Rights Reserved", or "GPL"
Chris@31 97 return "";
Chris@31 98 }
Chris@31 99
Chris@31 100 Silvet::InputDomain
Chris@31 101 Silvet::getInputDomain() const
Chris@31 102 {
Chris@31 103 return TimeDomain;
Chris@31 104 }
Chris@31 105
Chris@31 106 size_t
Chris@31 107 Silvet::getPreferredBlockSize() const
Chris@31 108 {
Chris@31 109 return 0;
Chris@31 110 }
Chris@31 111
Chris@31 112 size_t
Chris@31 113 Silvet::getPreferredStepSize() const
Chris@31 114 {
Chris@31 115 return 0;
Chris@31 116 }
Chris@31 117
Chris@31 118 size_t
Chris@31 119 Silvet::getMinChannelCount() const
Chris@31 120 {
Chris@31 121 return 1;
Chris@31 122 }
Chris@31 123
Chris@31 124 size_t
Chris@31 125 Silvet::getMaxChannelCount() const
Chris@31 126 {
Chris@31 127 return 1;
Chris@31 128 }
Chris@31 129
Chris@31 130 Silvet::ParameterList
Chris@31 131 Silvet::getParameterDescriptors() const
Chris@31 132 {
Chris@31 133 ParameterList list;
Chris@110 134
Chris@110 135 ParameterDescriptor desc;
Chris@110 136 desc.identifier = "mode";
Chris@110 137 desc.name = "Processing mode";
Chris@110 138 desc.unit = "";
Chris@110 139 desc.description = "Determines the tradeoff of processing speed against transcription quality";
Chris@110 140 desc.minValue = 0;
Chris@110 141 desc.maxValue = 1;
Chris@113 142 desc.defaultValue = 1;
Chris@110 143 desc.isQuantized = true;
Chris@110 144 desc.quantizeStep = 1;
Chris@166 145 desc.valueNames.push_back("Draft (faster)");
Chris@165 146 desc.valueNames.push_back("Intensive (higher quality)");
Chris@161 147 list.push_back(desc);
Chris@161 148
Chris@176 149 desc.identifier = "instrument";
Chris@176 150 desc.name = "Instrument";
Chris@161 151 desc.unit = "";
Chris@162 152 desc.description = "The instrument known to be present in the recording, if there is only one";
Chris@161 153 desc.minValue = 0;
Chris@162 154 desc.maxValue = m_instruments.size()-1;
Chris@162 155 desc.defaultValue = 0;
Chris@161 156 desc.isQuantized = true;
Chris@161 157 desc.quantizeStep = 1;
Chris@161 158 desc.valueNames.clear();
Chris@162 159 for (int i = 0; i < int(m_instruments.size()); ++i) {
Chris@162 160 desc.valueNames.push_back(m_instruments[i].name);
Chris@162 161 }
Chris@166 162 list.push_back(desc);
Chris@161 163
Chris@166 164 desc.identifier = "finetune";
Chris@166 165 desc.name = "Return fine pitch estimates";
Chris@166 166 desc.unit = "";
Chris@166 167 desc.description = "Return pitch estimates at finer than semitone resolution (works only in Intensive mode)";
Chris@166 168 desc.minValue = 0;
Chris@166 169 desc.maxValue = 1;
Chris@166 170 desc.defaultValue = 0;
Chris@166 171 desc.isQuantized = true;
Chris@166 172 desc.quantizeStep = 1;
Chris@166 173 desc.valueNames.clear();
Chris@110 174 list.push_back(desc);
Chris@110 175
Chris@31 176 return list;
Chris@31 177 }
Chris@31 178
Chris@31 179 float
Chris@31 180 Silvet::getParameter(string identifier) const
Chris@31 181 {
Chris@110 182 if (identifier == "mode") {
Chris@110 183 return m_hqMode ? 1.f : 0.f;
Chris@166 184 } else if (identifier == "finetune") {
Chris@166 185 return m_fineTuning ? 1.f : 0.f;
Chris@176 186 } else if (identifier == "instrument") {
Chris@162 187 return m_instrument;
Chris@110 188 }
Chris@31 189 return 0;
Chris@31 190 }
Chris@31 191
Chris@31 192 void
Chris@31 193 Silvet::setParameter(string identifier, float value)
Chris@31 194 {
Chris@110 195 if (identifier == "mode") {
Chris@110 196 m_hqMode = (value > 0.5);
Chris@166 197 } else if (identifier == "finetune") {
Chris@166 198 m_fineTuning = (value > 0.5);
Chris@176 199 } else if (identifier == "instrument") {
Chris@162 200 m_instrument = lrintf(value);
Chris@110 201 }
Chris@31 202 }
Chris@31 203
Chris@31 204 Silvet::ProgramList
Chris@31 205 Silvet::getPrograms() const
Chris@31 206 {
Chris@31 207 ProgramList list;
Chris@31 208 return list;
Chris@31 209 }
Chris@31 210
Chris@31 211 string
Chris@31 212 Silvet::getCurrentProgram() const
Chris@31 213 {
Chris@31 214 return "";
Chris@31 215 }
Chris@31 216
Chris@31 217 void
Chris@31 218 Silvet::selectProgram(string name)
Chris@31 219 {
Chris@31 220 }
Chris@31 221
Chris@31 222 Silvet::OutputList
Chris@31 223 Silvet::getOutputDescriptors() const
Chris@31 224 {
Chris@31 225 OutputList list;
Chris@31 226
Chris@31 227 OutputDescriptor d;
Chris@51 228 d.identifier = "notes";
Chris@51 229 d.name = "Note transcription";
Chris@162 230 d.description = "Overall note transcription across selected instruments";
Chris@41 231 d.unit = "Hz";
Chris@31 232 d.hasFixedBinCount = true;
Chris@31 233 d.binCount = 2;
Chris@41 234 d.binNames.push_back("Frequency");
Chris@31 235 d.binNames.push_back("Velocity");
Chris@31 236 d.hasKnownExtents = false;
Chris@31 237 d.isQuantized = false;
Chris@31 238 d.sampleType = OutputDescriptor::VariableSampleRate;
Chris@51 239 d.sampleRate = m_inputSampleRate / (m_cq ? m_cq->getColumnHop() : 62);
Chris@31 240 d.hasDuration = true;
Chris@32 241 m_notesOutputNo = list.size();
Chris@32 242 list.push_back(d);
Chris@32 243
Chris@178 244 d.identifier = "timefreq";
Chris@178 245 d.name = "Time-frequency distribution";
Chris@178 246 d.description = "Filtered constant-Q time-frequency distribution used as input to the expectation-maximisation algorithm";
Chris@178 247 d.unit = "";
Chris@178 248 d.hasFixedBinCount = true;
Chris@178 249 d.binCount = m_instruments[0].templateHeight;
Chris@178 250 d.binNames.clear();
Chris@178 251 if (m_cq) {
Chris@178 252 char name[20];
Chris@178 253 for (int i = 0; i < m_instruments[0].templateHeight; ++i) {
Chris@178 254 // We have a 600-bin (10 oct 60-bin CQ) of which the
Chris@178 255 // lowest-frequency 55 bins have been dropped, for a
Chris@178 256 // 545-bin template. The native CQ bins go high->low
Chris@178 257 // frequency though, so these are still the first 545 bins
Chris@178 258 // as reported by getBinFrequency, though in reverse order
Chris@178 259 float freq = m_cq->getBinFrequency
Chris@178 260 (m_instruments[0].templateHeight - i - 1);
Chris@178 261 sprintf(name, "%.1f Hz", freq);
Chris@178 262 d.binNames.push_back(name);
Chris@178 263 }
Chris@178 264 }
Chris@178 265 d.hasKnownExtents = false;
Chris@178 266 d.isQuantized = false;
Chris@178 267 d.sampleType = OutputDescriptor::FixedSampleRate;
Chris@178 268 d.sampleRate = m_colsPerSec;
Chris@178 269 d.hasDuration = false;
Chris@178 270 m_fcqOutputNo = list.size();
Chris@178 271 list.push_back(d);
Chris@178 272
Chris@31 273 return list;
Chris@31 274 }
Chris@31 275
Chris@38 276 std::string
Chris@175 277 Silvet::noteName(int note, int shift, int shiftCount) const
Chris@38 278 {
Chris@38 279 static const char *names[] = {
Chris@38 280 "A", "A#", "B", "C", "C#", "D", "D#", "E", "F", "F#", "G", "G#"
Chris@38 281 };
Chris@38 282
Chris@175 283 const char *n = names[note % 12];
Chris@38 284
Chris@175 285 int oct = (note + 9) / 12;
Chris@38 286
Chris@175 287 char buf[30];
Chris@175 288
Chris@175 289 float pshift = 0.f;
Chris@175 290 if (shiftCount > 1) {
Chris@175 291 // see noteFrequency below
Chris@175 292 pshift =
Chris@175 293 float((shiftCount - shift) - int(shiftCount / 2) - 1) / shiftCount;
Chris@175 294 }
Chris@175 295
Chris@175 296 if (pshift > 0.f) {
Chris@175 297 sprintf(buf, "%s%d+%dc", n, oct, int(round(pshift * 100)));
Chris@175 298 } else if (pshift < 0.f) {
Chris@175 299 sprintf(buf, "%s%d-%dc", n, oct, int(round((-pshift) * 100)));
Chris@175 300 } else {
Chris@175 301 sprintf(buf, "%s%d", n, oct);
Chris@175 302 }
Chris@38 303
Chris@38 304 return buf;
Chris@38 305 }
Chris@38 306
Chris@41 307 float
Chris@168 308 Silvet::noteFrequency(int note, int shift, int shiftCount) const
Chris@41 309 {
Chris@169 310 // Convert shift number to a pitch shift. The given shift number
Chris@169 311 // is an offset into the template array, which starts with some
Chris@169 312 // zeros, followed by the template, then some trailing zeros.
Chris@169 313 //
Chris@169 314 // Example: if we have templateMaxShift == 2 and thus shiftCount
Chris@169 315 // == 5, then the number will be in the range 0-4 and the template
Chris@169 316 // will have 2 zeros at either end. Thus number 2 represents the
Chris@169 317 // template "as recorded", for a pitch shift of 0; smaller indices
Chris@169 318 // represent moving the template *up* in pitch (by introducing
Chris@169 319 // zeros at the start, which is the low-frequency end), for a
Chris@169 320 // positive pitch shift; and higher values represent moving it
Chris@169 321 // down in pitch, for a negative pitch shift.
Chris@169 322
Chris@175 323 float pshift = 0.f;
Chris@175 324 if (shiftCount > 1) {
Chris@175 325 pshift =
Chris@175 326 float((shiftCount - shift) - int(shiftCount / 2) - 1) / shiftCount;
Chris@175 327 }
Chris@169 328
Chris@169 329 return float(27.5 * pow(2.0, (note + pshift) / 12.0));
Chris@41 330 }
Chris@41 331
Chris@31 332 bool
Chris@31 333 Silvet::initialise(size_t channels, size_t stepSize, size_t blockSize)
Chris@31 334 {
Chris@31 335 if (channels < getMinChannelCount() ||
Chris@31 336 channels > getMaxChannelCount()) return false;
Chris@31 337
Chris@31 338 if (stepSize != blockSize) {
Chris@31 339 cerr << "Silvet::initialise: Step size must be the same as block size ("
Chris@31 340 << stepSize << " != " << blockSize << ")" << endl;
Chris@31 341 return false;
Chris@31 342 }
Chris@31 343
Chris@31 344 m_blockSize = blockSize;
Chris@31 345
Chris@31 346 reset();
Chris@31 347
Chris@31 348 return true;
Chris@31 349 }
Chris@31 350
Chris@31 351 void
Chris@31 352 Silvet::reset()
Chris@31 353 {
Chris@31 354 delete m_resampler;
Chris@31 355 delete m_cq;
Chris@31 356
Chris@31 357 if (m_inputSampleRate != processingSampleRate) {
Chris@31 358 m_resampler = new Resampler(m_inputSampleRate, processingSampleRate);
Chris@31 359 } else {
Chris@31 360 m_resampler = 0;
Chris@31 361 }
Chris@31 362
Chris@173 363 double minFreq = 27.5;
Chris@173 364
Chris@173 365 if (!m_hqMode) {
Chris@173 366 // We don't actually return any notes from the bottom octave,
Chris@173 367 // so we can just pad with zeros
Chris@173 368 minFreq *= 2;
Chris@173 369 }
Chris@173 370
Chris@154 371 CQParameters params(processingSampleRate,
Chris@173 372 minFreq,
Chris@154 373 processingSampleRate / 3,
Chris@154 374 processingBPO);
Chris@154 375
Chris@155 376 params.q = 0.95; // MIREX code uses 0.8, but it seems 0.9 or lower
Chris@155 377 // drops the FFT size to 512 from 1024 and alters
Chris@155 378 // some other processing parameters, making
Chris@155 379 // everything much, much slower. Could be a flaw
Chris@155 380 // in the CQ parameter calculations, must check
Chris@154 381 params.atomHopFactor = 0.3;
Chris@154 382 params.threshold = 0.0005;
Chris@172 383 params.window = CQParameters::Hann;
Chris@154 384
Chris@154 385 m_cq = new CQSpectrogram(params, CQSpectrogram::InterpolateLinear);
Chris@31 386
Chris@165 387 m_colsPerSec = m_hqMode ? 50 : 25;
Chris@165 388
Chris@41 389 for (int i = 0; i < (int)m_postFilter.size(); ++i) {
Chris@41 390 delete m_postFilter[i];
Chris@41 391 }
Chris@41 392 m_postFilter.clear();
Chris@176 393 for (int i = 0; i < m_instruments[0].templateNoteCount; ++i) {
Chris@41 394 m_postFilter.push_back(new MedianFilter<double>(3));
Chris@41 395 }
Chris@41 396 m_pianoRoll.clear();
Chris@32 397 m_columnCount = 0;
Chris@40 398 m_startTime = RealTime::zeroTime;
Chris@31 399 }
Chris@31 400
Chris@31 401 Silvet::FeatureSet
Chris@31 402 Silvet::process(const float *const *inputBuffers, Vamp::RealTime timestamp)
Chris@31 403 {
Chris@40 404 if (m_columnCount == 0) {
Chris@40 405 m_startTime = timestamp;
Chris@40 406 }
Chris@40 407
Chris@31 408 vector<double> data;
Chris@40 409 for (int i = 0; i < m_blockSize; ++i) {
Chris@40 410 data.push_back(inputBuffers[0][i]);
Chris@40 411 }
Chris@31 412
Chris@31 413 if (m_resampler) {
Chris@31 414 data = m_resampler->process(data.data(), data.size());
Chris@31 415 }
Chris@31 416
Chris@32 417 Grid cqout = m_cq->process(data);
Chris@51 418 FeatureSet fs = transcribe(cqout);
Chris@51 419 return fs;
Chris@34 420 }
Chris@34 421
Chris@34 422 Silvet::FeatureSet
Chris@34 423 Silvet::getRemainingFeatures()
Chris@34 424 {
Chris@145 425 Grid cqout = m_cq->getRemainingOutput();
Chris@51 426 FeatureSet fs = transcribe(cqout);
Chris@51 427 return fs;
Chris@34 428 }
Chris@34 429
Chris@34 430 Silvet::FeatureSet
Chris@34 431 Silvet::transcribe(const Grid &cqout)
Chris@34 432 {
Chris@32 433 Grid filtered = preProcess(cqout);
Chris@31 434
Chris@32 435 FeatureSet fs;
Chris@32 436
Chris@104 437 if (filtered.empty()) return fs;
Chris@170 438
Chris@170 439 const InstrumentPack &pack = m_instruments[m_instrument];
Chris@104 440
Chris@178 441 for (int i = 0; i < (int)filtered.size(); ++i) {
Chris@178 442 Feature f;
Chris@178 443 for (int j = 0; j < pack.templateHeight; ++j) {
Chris@178 444 f.values.push_back(float(filtered[i][j]));
Chris@178 445 }
Chris@178 446 fs[m_fcqOutputNo].push_back(f);
Chris@178 447 }
Chris@178 448
Chris@34 449 int width = filtered.size();
Chris@34 450
Chris@164 451 int iterations = m_hqMode ? 20 : 10;
Chris@34 452
Chris@170 453 //!!! pitches or notes? [terminology]
Chris@176 454 Grid localPitches(width, vector<double>(pack.templateNoteCount, 0.0));
Chris@170 455
Chris@170 456 bool wantShifts = m_hqMode && m_fineTuning;
Chris@170 457 int shiftCount = 1;
Chris@170 458 if (wantShifts) {
Chris@170 459 shiftCount = pack.templateMaxShift * 2 + 1;
Chris@170 460 }
Chris@170 461
Chris@170 462 vector<vector<int> > localBestShifts;
Chris@170 463 if (wantShifts) {
Chris@170 464 localBestShifts =
Chris@176 465 vector<vector<int> >(width, vector<int>(pack.templateNoteCount, 0));
Chris@170 466 }
Chris@170 467
Chris@170 468 vector<bool> present(width, false);
Chris@37 469
Chris@123 470 #pragma omp parallel for
Chris@123 471 for (int i = 0; i < width; ++i) {
Chris@104 472
Chris@170 473 double sum = 0.0;
Chris@176 474 for (int j = 0; j < pack.templateHeight; ++j) {
Chris@170 475 sum += filtered.at(i).at(j);
Chris@170 476 }
Chris@170 477 if (sum < 1e-5) continue;
Chris@170 478
Chris@170 479 present[i] = true;
Chris@170 480
Chris@170 481 EM em(&pack, m_hqMode);
Chris@170 482
Chris@170 483 for (int j = 0; j < iterations; ++j) {
Chris@170 484 em.iterate(filtered.at(i).data());
Chris@37 485 }
Chris@37 486
Chris@170 487 const float *pitchDist = em.getPitchDistribution();
Chris@170 488 const float *const *shiftDist = em.getShifts();
Chris@37 489
Chris@176 490 for (int j = 0; j < pack.templateNoteCount; ++j) {
Chris@104 491
Chris@170 492 localPitches[i][j] = pitchDist[j] * sum;
Chris@170 493
Chris@170 494 int bestShift = 0;
Chris@170 495 int bestShiftValue = 0.0;
Chris@170 496 if (wantShifts) {
Chris@170 497 for (int k = 0; k < shiftCount; ++k) {
Chris@170 498 if (k == 0 || shiftDist[k][j] > bestShiftValue) {
Chris@170 499 bestShiftValue = shiftDist[k][j];
Chris@170 500 bestShift = k;
Chris@170 501 }
Chris@170 502 }
Chris@170 503 localBestShifts[i][j] = bestShift;
Chris@170 504 }
Chris@123 505 }
Chris@123 506 }
Chris@166 507
Chris@166 508 for (int i = 0; i < width; ++i) {
Chris@37 509
Chris@170 510 if (!present[i]) {
Chris@170 511 // silent column
Chris@176 512 for (int j = 0; j < pack.templateNoteCount; ++j) {
Chris@170 513 m_postFilter[j]->push(0.0);
Chris@170 514 }
Chris@168 515 m_pianoRoll.push_back(map<int, double>());
Chris@170 516 if (wantShifts) {
Chris@168 517 m_pianoRollShifts.push_back(map<int, int>());
Chris@168 518 }
Chris@166 519 continue;
Chris@166 520 }
Chris@166 521
Chris@170 522 postProcess(localPitches[i], localBestShifts[i], wantShifts);
Chris@166 523
Chris@168 524 FeatureList noteFeatures = noteTrack(shiftCount);
Chris@38 525
Chris@123 526 for (FeatureList::const_iterator fi = noteFeatures.begin();
Chris@123 527 fi != noteFeatures.end(); ++fi) {
Chris@123 528 fs[m_notesOutputNo].push_back(*fi);
Chris@40 529 }
Chris@34 530 }
Chris@34 531
Chris@32 532 return fs;
Chris@31 533 }
Chris@31 534
Chris@32 535 Silvet::Grid
Chris@32 536 Silvet::preProcess(const Grid &in)
Chris@32 537 {
Chris@32 538 int width = in.size();
Chris@32 539
Chris@165 540 int spacing = processingSampleRate / m_colsPerSec;
Chris@32 541
Chris@165 542 // need to be careful that col spacing is an integer number of samples!
Chris@165 543 assert(spacing * m_colsPerSec == processingSampleRate);
Chris@32 544
Chris@32 545 Grid out;
Chris@32 546
Chris@58 547 // We count the CQ latency in terms of processing hops, but
Chris@58 548 // actually it probably isn't an exact number of hops so this
Chris@58 549 // isn't quite accurate. But the small constant offset is
Chris@165 550 // practically irrelevant compared to the jitter from the frame
Chris@165 551 // size we reduce to in a moment
Chris@33 552 int latentColumns = m_cq->getLatency() / m_cq->getColumnHop();
Chris@33 553
Chris@176 554 const InstrumentPack &pack = m_instruments[m_instrument];
Chris@176 555
Chris@32 556 for (int i = 0; i < width; ++i) {
Chris@32 557
Chris@33 558 if (m_columnCount < latentColumns) {
Chris@33 559 ++m_columnCount;
Chris@33 560 continue;
Chris@33 561 }
Chris@33 562
Chris@32 563 int prevSampleNo = (m_columnCount - 1) * m_cq->getColumnHop();
Chris@32 564 int sampleNo = m_columnCount * m_cq->getColumnHop();
Chris@32 565
Chris@32 566 bool select = (sampleNo / spacing != prevSampleNo / spacing);
Chris@32 567
Chris@32 568 if (select) {
Chris@32 569 vector<double> inCol = in[i];
Chris@176 570 vector<double> outCol(pack.templateHeight);
Chris@32 571
Chris@178 572 // In HQ mode, the CQ returns 600 bins and we ignore the
Chris@178 573 // lowest 55 of them.
Chris@178 574 //
Chris@178 575 // In draft mode the CQ is an octave shorter, returning
Chris@178 576 // 540 bins, so we instead pad them with an additional 5
Chris@178 577 // zeros.
Chris@178 578 //
Chris@178 579 // We also need to reverse the column as we go, since the
Chris@178 580 // raw CQ has the high frequencies first and we need it
Chris@178 581 // the other way around.
Chris@32 582
Chris@178 583 if (m_hqMode) {
Chris@178 584 for (int j = 0; j < pack.templateHeight; ++j) {
Chris@178 585 int ix = inCol.size() - j - 55;
Chris@178 586 outCol[j] = inCol[ix];
Chris@178 587 }
Chris@178 588 } else {
Chris@178 589 for (int j = 0; j < 5; ++j) {
Chris@178 590 outCol[j] = 0.0;
Chris@178 591 }
Chris@178 592 for (int j = 5; j < pack.templateHeight; ++j) {
Chris@178 593 int ix = inCol.size() - j + 4;
Chris@178 594 outCol[j] = inCol[ix];
Chris@178 595 }
Chris@46 596 }
Chris@32 597
Chris@46 598 vector<double> noiseLevel1 =
Chris@46 599 MedianFilter<double>::filter(40, outCol);
Chris@176 600 for (int j = 0; j < pack.templateHeight; ++j) {
Chris@46 601 noiseLevel1[j] = std::min(outCol[j], noiseLevel1[j]);
Chris@46 602 }
Chris@32 603
Chris@46 604 vector<double> noiseLevel2 =
Chris@46 605 MedianFilter<double>::filter(40, noiseLevel1);
Chris@176 606 for (int j = 0; j < pack.templateHeight; ++j) {
Chris@46 607 outCol[j] = std::max(outCol[j] - noiseLevel2[j], 0.0);
Chris@32 608 }
Chris@32 609
Chris@165 610 out.push_back(outCol);
Chris@32 611 }
Chris@32 612
Chris@32 613 ++m_columnCount;
Chris@32 614 }
Chris@32 615
Chris@32 616 return out;
Chris@32 617 }
Chris@32 618
Chris@168 619 void
Chris@170 620 Silvet::postProcess(const vector<double> &pitches,
Chris@170 621 const vector<int> &bestShifts,
Chris@170 622 bool wantShifts)
Chris@166 623 {
Chris@176 624 const InstrumentPack &pack = m_instruments[m_instrument];
Chris@176 625
Chris@41 626 vector<double> filtered;
Chris@41 627
Chris@176 628 for (int j = 0; j < pack.templateNoteCount; ++j) {
Chris@170 629 m_postFilter[j]->push(pitches[j]);
Chris@41 630 filtered.push_back(m_postFilter[j]->get());
Chris@41 631 }
Chris@41 632
Chris@41 633 // Threshold for level and reduce number of candidate pitches
Chris@41 634
Chris@41 635 int polyphony = 5;
Chris@150 636
Chris@150 637 //!!! make this a parameter (was 4.8, try adjusting, compare levels against matlab code)
Chris@150 638 double threshold = 6;
Chris@154 639 // double threshold = 4.8;
Chris@41 640
Chris@41 641 typedef std::multimap<double, int> ValueIndexMap;
Chris@41 642
Chris@41 643 ValueIndexMap strengths;
Chris@166 644
Chris@176 645 for (int j = 0; j < pack.templateNoteCount; ++j) {
Chris@166 646 double strength = filtered[j];
Chris@166 647 if (strength < threshold) continue;
Chris@168 648 strengths.insert(ValueIndexMap::value_type(strength, j));
Chris@168 649 }
Chris@166 650
Chris@168 651 ValueIndexMap::const_iterator si = strengths.end();
Chris@167 652
Chris@168 653 map<int, double> active;
Chris@168 654 map<int, int> activeShifts;
Chris@168 655
Chris@168 656 while (int(active.size()) < polyphony && si != strengths.begin()) {
Chris@168 657
Chris@168 658 --si;
Chris@168 659
Chris@168 660 double strength = si->first;
Chris@168 661 int j = si->second;
Chris@168 662
Chris@168 663 active[j] = strength;
Chris@168 664
Chris@170 665 if (wantShifts) {
Chris@170 666 activeShifts[j] = bestShifts[j];
Chris@167 667 }
Chris@41 668 }
Chris@41 669
Chris@168 670 m_pianoRoll.push_back(active);
Chris@170 671
Chris@170 672 if (wantShifts) {
Chris@168 673 m_pianoRollShifts.push_back(activeShifts);
Chris@41 674 }
Chris@166 675 }
Chris@166 676
Chris@166 677 Vamp::Plugin::FeatureList
Chris@168 678 Silvet::noteTrack(int shiftCount)
Chris@166 679 {
Chris@41 680 // Minimum duration pruning, and conversion to notes. We can only
Chris@41 681 // report notes that have just ended (i.e. that are absent in the
Chris@168 682 // latest active set but present in the prior set in the piano
Chris@41 683 // roll) -- any notes that ended earlier will have been reported
Chris@41 684 // already, and if they haven't ended, we don't know their
Chris@41 685 // duration.
Chris@41 686
Chris@168 687 int width = m_pianoRoll.size() - 1;
Chris@168 688
Chris@168 689 const map<int, double> &active = m_pianoRoll[width];
Chris@41 690
Chris@165 691 double columnDuration = 1.0 / m_colsPerSec;
Chris@165 692
Chris@165 693 // only keep notes >= 100ms or thereabouts
Chris@165 694 int durationThreshold = floor(0.1 / columnDuration); // columns
Chris@165 695 if (durationThreshold < 1) durationThreshold = 1;
Chris@41 696
Chris@41 697 FeatureList noteFeatures;
Chris@41 698
Chris@41 699 if (width < durationThreshold + 1) {
Chris@41 700 return noteFeatures;
Chris@41 701 }
Chris@41 702
Chris@150 703 //!!! try: repeated note detection? (look for change in first derivative of the pitch matrix)
Chris@150 704
Chris@55 705 for (map<int, double>::const_iterator ni = m_pianoRoll[width-1].begin();
Chris@41 706 ni != m_pianoRoll[width-1].end(); ++ni) {
Chris@41 707
Chris@55 708 int note = ni->first;
Chris@41 709
Chris@41 710 if (active.find(note) != active.end()) {
Chris@41 711 // the note is still playing
Chris@41 712 continue;
Chris@41 713 }
Chris@41 714
Chris@41 715 // the note was playing but just ended
Chris@41 716 int end = width;
Chris@41 717 int start = end-1;
Chris@41 718
Chris@41 719 while (m_pianoRoll[start].find(note) != m_pianoRoll[start].end()) {
Chris@41 720 --start;
Chris@41 721 }
Chris@41 722 ++start;
Chris@41 723
Chris@169 724 if ((end - start) < durationThreshold) {
Chris@41 725 continue;
Chris@41 726 }
Chris@41 727
Chris@169 728 emitNote(start, end, note, shiftCount, noteFeatures);
Chris@41 729 }
Chris@41 730
Chris@62 731 // cerr << "returning " << noteFeatures.size() << " complete note(s) " << endl;
Chris@41 732
Chris@41 733 return noteFeatures;
Chris@41 734 }
Chris@41 735
Chris@169 736 void
Chris@169 737 Silvet::emitNote(int start, int end, int note, int shiftCount,
Chris@169 738 FeatureList &noteFeatures)
Chris@169 739 {
Chris@169 740 int partStart = start;
Chris@169 741 int partShift = 0;
Chris@169 742 int partVelocity = 0;
Chris@169 743
Chris@169 744 Feature f;
Chris@169 745 f.hasTimestamp = true;
Chris@169 746 f.hasDuration = true;
Chris@169 747
Chris@169 748 double columnDuration = 1.0 / m_colsPerSec;
Chris@169 749 int postFilterLatency = int(m_postFilter[0]->getSize() / 2);
Chris@169 750 int partThreshold = floor(0.05 / columnDuration);
Chris@169 751
Chris@169 752 for (int i = start; i != end; ++i) {
Chris@169 753
Chris@169 754 double strength = m_pianoRoll[i][note];
Chris@169 755
Chris@169 756 int shift = 0;
Chris@169 757
Chris@169 758 if (shiftCount > 1) {
Chris@169 759
Chris@169 760 shift = m_pianoRollShifts[i][note];
Chris@169 761
Chris@169 762 if (i == partStart) {
Chris@169 763 partShift = shift;
Chris@169 764 }
Chris@169 765
Chris@169 766 if (i > partStart + partThreshold && shift != partShift) {
Chris@169 767
Chris@169 768 // cerr << "i = " << i << ", partStart = " << partStart << ", shift = " << shift << ", partShift = " << partShift << endl;
Chris@169 769
Chris@169 770 // pitch has changed, emit an intermediate note
Chris@169 771 f.timestamp = RealTime::fromSeconds
Chris@169 772 (columnDuration * (partStart - postFilterLatency) + 0.02);
Chris@169 773 f.duration = RealTime::fromSeconds
Chris@169 774 (columnDuration * (i - partStart));
Chris@169 775 f.values.clear();
Chris@169 776 f.values.push_back
Chris@169 777 (noteFrequency(note, partShift, shiftCount));
Chris@169 778 f.values.push_back(partVelocity);
Chris@175 779 f.label = noteName(note, partShift, shiftCount);
Chris@169 780 noteFeatures.push_back(f);
Chris@169 781 partStart = i;
Chris@169 782 partShift = shift;
Chris@169 783 partVelocity = 0;
Chris@169 784 }
Chris@169 785 }
Chris@169 786
Chris@169 787 int v = strength * 2;
Chris@169 788 if (v > 127) v = 127;
Chris@169 789
Chris@169 790 if (v > partVelocity) {
Chris@169 791 partVelocity = v;
Chris@169 792 }
Chris@169 793 }
Chris@169 794
Chris@169 795 if (end >= partStart + partThreshold) {
Chris@169 796 f.timestamp = RealTime::fromSeconds
Chris@169 797 (columnDuration * (partStart - postFilterLatency) + 0.02);
Chris@169 798 f.duration = RealTime::fromSeconds
Chris@169 799 (columnDuration * (end - partStart));
Chris@169 800 f.values.clear();
Chris@169 801 f.values.push_back
Chris@169 802 (noteFrequency(note, partShift, shiftCount));
Chris@169 803 f.values.push_back(partVelocity);
Chris@175 804 f.label = noteName(note, partShift, shiftCount);
Chris@169 805 noteFeatures.push_back(f);
Chris@169 806 }
Chris@169 807 }