Mercurial > hg > silvet

annotate src/Silvet.cpp @ 185:78212f764251 noteagent

Find changesets by keywords (author, files, the commit message), revision number or hash, or revset expression.
Merge from default branch
author Chris Cannam
date Wed, 28 May 2014 14:56:01 +0100
parents 9b9cdfccbd14 59e3cca75b8d
children 9d70d687e4eb
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@184 22 #include "AgentFeederPoly.h"
Chris@184 23 #include "NoteHypothesis.h"
Chris@184 24
Chris@152 25 #include "constant-q-cpp/src/dsp/Resampler.h"
Chris@31 26
Chris@31 27 #include <vector>
Chris@31 28
Chris@32 29 #include <cstdio>
Chris@32 30
Chris@31 31 using std::vector;
Chris@48 32 using std::cout;
Chris@31 33 using std::cerr;
Chris@31 34 using std::endl;
Chris@40 35 using Vamp::RealTime;
Chris@31 36
Chris@31 37 static int processingSampleRate = 44100;
Chris@31 38 static int processingBPO = 60;
Chris@170 39
Chris@31 40 Silvet::Silvet(float inputSampleRate) :
Chris@31 41 Plugin(inputSampleRate),
Chris@161 42 m_instruments(InstrumentPack::listInstrumentPacks()),
Chris@31 43 m_resampler(0),
Chris@110 44 m_cq(0),
Chris@162 45 m_hqMode(true),
Chris@166 46 m_fineTuning(false),
Chris@178 47 m_instrument(0),
Chris@184 48 m_colsPerSec(50),
Chris@184 49 m_agentFeeder(0)
Chris@31 50 {
Chris@31 51 }
Chris@31 52
Chris@31 53 Silvet::~Silvet()
Chris@31 54 {
Chris@31 55 delete m_resampler;
Chris@31 56 delete m_cq;
Chris@41 57 for (int i = 0; i < (int)m_postFilter.size(); ++i) {
Chris@41 58 delete m_postFilter[i];
Chris@41 59 }
Chris@184 60 delete m_agentFeeder;
Chris@31 61 }
Chris@31 62
Chris@31 63 string
Chris@31 64 Silvet::getIdentifier() const
Chris@31 65 {
Chris@31 66 return "silvet";
Chris@31 67 }
Chris@31 68
Chris@31 69 string
Chris@31 70 Silvet::getName() const
Chris@31 71 {
Chris@31 72 return "Silvet Note Transcription";
Chris@31 73 }
Chris@31 74
Chris@31 75 string
Chris@31 76 Silvet::getDescription() const
Chris@31 77 {
Chris@31 78 // Return something helpful here!
Chris@31 79 return "";
Chris@31 80 }
Chris@31 81
Chris@31 82 string
Chris@31 83 Silvet::getMaker() const
Chris@31 84 {
Chris@31 85 // Your name here
Chris@31 86 return "";
Chris@31 87 }
Chris@31 88
Chris@31 89 int
Chris@31 90 Silvet::getPluginVersion() const
Chris@31 91 {
Chris@31 92 return 1;
Chris@31 93 }
Chris@31 94
Chris@31 95 string
Chris@31 96 Silvet::getCopyright() const
Chris@31 97 {
Chris@31 98 // This function is not ideally named. It does not necessarily
Chris@31 99 // need to say who made the plugin -- getMaker does that -- but it
Chris@31 100 // should indicate the terms under which it is distributed. For
Chris@31 101 // example, "Copyright (year). All Rights Reserved", or "GPL"
Chris@31 102 return "";
Chris@31 103 }
Chris@31 104
Chris@31 105 Silvet::InputDomain
Chris@31 106 Silvet::getInputDomain() const
Chris@31 107 {
Chris@31 108 return TimeDomain;
Chris@31 109 }
Chris@31 110
Chris@31 111 size_t
Chris@31 112 Silvet::getPreferredBlockSize() const
Chris@31 113 {
Chris@31 114 return 0;
Chris@31 115 }
Chris@31 116
Chris@31 117 size_t
Chris@31 118 Silvet::getPreferredStepSize() const
Chris@31 119 {
Chris@31 120 return 0;
Chris@31 121 }
Chris@31 122
Chris@31 123 size_t
Chris@31 124 Silvet::getMinChannelCount() const
Chris@31 125 {
Chris@31 126 return 1;
Chris@31 127 }
Chris@31 128
Chris@31 129 size_t
Chris@31 130 Silvet::getMaxChannelCount() const
Chris@31 131 {
Chris@31 132 return 1;
Chris@31 133 }
Chris@31 134
Chris@31 135 Silvet::ParameterList
Chris@31 136 Silvet::getParameterDescriptors() const
Chris@31 137 {
Chris@31 138 ParameterList list;
Chris@110 139
Chris@110 140 ParameterDescriptor desc;
Chris@110 141 desc.identifier = "mode";
Chris@110 142 desc.name = "Processing mode";
Chris@110 143 desc.unit = "";
Chris@110 144 desc.description = "Determines the tradeoff of processing speed against transcription quality";
Chris@110 145 desc.minValue = 0;
Chris@110 146 desc.maxValue = 1;
Chris@113 147 desc.defaultValue = 1;
Chris@110 148 desc.isQuantized = true;
Chris@110 149 desc.quantizeStep = 1;
Chris@166 150 desc.valueNames.push_back("Draft (faster)");
Chris@165 151 desc.valueNames.push_back("Intensive (higher quality)");
Chris@161 152 list.push_back(desc);
Chris@161 153
Chris@176 154 desc.identifier = "instrument";
Chris@176 155 desc.name = "Instrument";
Chris@161 156 desc.unit = "";
Chris@162 157 desc.description = "The instrument known to be present in the recording, if there is only one";
Chris@161 158 desc.minValue = 0;
Chris@162 159 desc.maxValue = m_instruments.size()-1;
Chris@162 160 desc.defaultValue = 0;
Chris@161 161 desc.isQuantized = true;
Chris@161 162 desc.quantizeStep = 1;
Chris@161 163 desc.valueNames.clear();
Chris@162 164 for (int i = 0; i < int(m_instruments.size()); ++i) {
Chris@162 165 desc.valueNames.push_back(m_instruments[i].name);
Chris@162 166 }
Chris@166 167 list.push_back(desc);
Chris@161 168
Chris@166 169 desc.identifier = "finetune";
Chris@166 170 desc.name = "Return fine pitch estimates";
Chris@166 171 desc.unit = "";
Chris@166 172 desc.description = "Return pitch estimates at finer than semitone resolution (works only in Intensive mode)";
Chris@166 173 desc.minValue = 0;
Chris@166 174 desc.maxValue = 1;
Chris@166 175 desc.defaultValue = 0;
Chris@166 176 desc.isQuantized = true;
Chris@166 177 desc.quantizeStep = 1;
Chris@166 178 desc.valueNames.clear();
Chris@110 179 list.push_back(desc);
Chris@110 180
Chris@31 181 return list;
Chris@31 182 }
Chris@31 183
Chris@31 184 float
Chris@31 185 Silvet::getParameter(string identifier) const
Chris@31 186 {
Chris@110 187 if (identifier == "mode") {
Chris@110 188 return m_hqMode ? 1.f : 0.f;
Chris@166 189 } else if (identifier == "finetune") {
Chris@166 190 return m_fineTuning ? 1.f : 0.f;
Chris@176 191 } else if (identifier == "instrument") {
Chris@162 192 return m_instrument;
Chris@110 193 }
Chris@31 194 return 0;
Chris@31 195 }
Chris@31 196
Chris@31 197 void
Chris@31 198 Silvet::setParameter(string identifier, float value)
Chris@31 199 {
Chris@110 200 if (identifier == "mode") {
Chris@110 201 m_hqMode = (value > 0.5);
Chris@166 202 } else if (identifier == "finetune") {
Chris@166 203 m_fineTuning = (value > 0.5);
Chris@176 204 } else if (identifier == "instrument") {
Chris@162 205 m_instrument = lrintf(value);
Chris@110 206 }
Chris@31 207 }
Chris@31 208
Chris@31 209 Silvet::ProgramList
Chris@31 210 Silvet::getPrograms() const
Chris@31 211 {
Chris@31 212 ProgramList list;
Chris@31 213 return list;
Chris@31 214 }
Chris@31 215
Chris@31 216 string
Chris@31 217 Silvet::getCurrentProgram() const
Chris@31 218 {
Chris@31 219 return "";
Chris@31 220 }
Chris@31 221
Chris@31 222 void
Chris@31 223 Silvet::selectProgram(string name)
Chris@31 224 {
Chris@31 225 }
Chris@31 226
Chris@31 227 Silvet::OutputList
Chris@31 228 Silvet::getOutputDescriptors() const
Chris@31 229 {
Chris@31 230 OutputList list;
Chris@31 231
Chris@31 232 OutputDescriptor d;
Chris@51 233 d.identifier = "notes";
Chris@51 234 d.name = "Note transcription";
Chris@162 235 d.description = "Overall note transcription across selected instruments";
Chris@41 236 d.unit = "Hz";
Chris@31 237 d.hasFixedBinCount = true;
Chris@31 238 d.binCount = 2;
Chris@41 239 d.binNames.push_back("Frequency");
Chris@31 240 d.binNames.push_back("Velocity");
Chris@31 241 d.hasKnownExtents = false;
Chris@31 242 d.isQuantized = false;
Chris@31 243 d.sampleType = OutputDescriptor::VariableSampleRate;
Chris@51 244 d.sampleRate = m_inputSampleRate / (m_cq ? m_cq->getColumnHop() : 62);
Chris@31 245 d.hasDuration = true;
Chris@32 246 m_notesOutputNo = list.size();
Chris@32 247 list.push_back(d);
Chris@32 248
Chris@178 249 d.identifier = "timefreq";
Chris@178 250 d.name = "Time-frequency distribution";
Chris@178 251 d.description = "Filtered constant-Q time-frequency distribution used as input to the expectation-maximisation algorithm";
Chris@178 252 d.unit = "";
Chris@178 253 d.hasFixedBinCount = true;
Chris@178 254 d.binCount = m_instruments[0].templateHeight;
Chris@178 255 d.binNames.clear();
Chris@178 256 if (m_cq) {
Chris@178 257 char name[20];
Chris@178 258 for (int i = 0; i < m_instruments[0].templateHeight; ++i) {
Chris@178 259 // We have a 600-bin (10 oct 60-bin CQ) of which the
Chris@178 260 // lowest-frequency 55 bins have been dropped, for a
Chris@178 261 // 545-bin template. The native CQ bins go high->low
Chris@178 262 // frequency though, so these are still the first 545 bins
Chris@178 263 // as reported by getBinFrequency, though in reverse order
Chris@178 264 float freq = m_cq->getBinFrequency
Chris@178 265 (m_instruments[0].templateHeight - i - 1);
Chris@178 266 sprintf(name, "%.1f Hz", freq);
Chris@178 267 d.binNames.push_back(name);
Chris@178 268 }
Chris@178 269 }
Chris@178 270 d.hasKnownExtents = false;
Chris@178 271 d.isQuantized = false;
Chris@178 272 d.sampleType = OutputDescriptor::FixedSampleRate;
Chris@178 273 d.sampleRate = m_colsPerSec;
Chris@178 274 d.hasDuration = false;
Chris@178 275 m_fcqOutputNo = list.size();
Chris@178 276 list.push_back(d);
Chris@178 277
Chris@31 278 return list;
Chris@31 279 }
Chris@31 280
Chris@38 281 std::string
Chris@175 282 Silvet::noteName(int note, int shift, int shiftCount) const
Chris@38 283 {
Chris@38 284 static const char *names[] = {
Chris@38 285 "A", "A#", "B", "C", "C#", "D", "D#", "E", "F", "F#", "G", "G#"
Chris@38 286 };
Chris@38 287
Chris@175 288 const char *n = names[note % 12];
Chris@38 289
Chris@175 290 int oct = (note + 9) / 12;
Chris@38 291
Chris@175 292 char buf[30];
Chris@175 293
Chris@175 294 float pshift = 0.f;
Chris@175 295 if (shiftCount > 1) {
Chris@175 296 // see noteFrequency below
Chris@175 297 pshift =
Chris@175 298 float((shiftCount - shift) - int(shiftCount / 2) - 1) / shiftCount;
Chris@175 299 }
Chris@175 300
Chris@175 301 if (pshift > 0.f) {
Chris@175 302 sprintf(buf, "%s%d+%dc", n, oct, int(round(pshift * 100)));
Chris@175 303 } else if (pshift < 0.f) {
Chris@175 304 sprintf(buf, "%s%d-%dc", n, oct, int(round((-pshift) * 100)));
Chris@175 305 } else {
Chris@175 306 sprintf(buf, "%s%d", n, oct);
Chris@175 307 }
Chris@38 308
Chris@38 309 return buf;
Chris@38 310 }
Chris@38 311
Chris@41 312 float
Chris@168 313 Silvet::noteFrequency(int note, int shift, int shiftCount) const
Chris@41 314 {
Chris@169 315 // Convert shift number to a pitch shift. The given shift number
Chris@169 316 // is an offset into the template array, which starts with some
Chris@169 317 // zeros, followed by the template, then some trailing zeros.
Chris@169 318 //
Chris@169 319 // Example: if we have templateMaxShift == 2 and thus shiftCount
Chris@169 320 // == 5, then the number will be in the range 0-4 and the template
Chris@169 321 // will have 2 zeros at either end. Thus number 2 represents the
Chris@169 322 // template "as recorded", for a pitch shift of 0; smaller indices
Chris@169 323 // represent moving the template *up* in pitch (by introducing
Chris@169 324 // zeros at the start, which is the low-frequency end), for a
Chris@169 325 // positive pitch shift; and higher values represent moving it
Chris@169 326 // down in pitch, for a negative pitch shift.
Chris@169 327
Chris@175 328 float pshift = 0.f;
Chris@175 329 if (shiftCount > 1) {
Chris@175 330 pshift =
Chris@175 331 float((shiftCount - shift) - int(shiftCount / 2) - 1) / shiftCount;
Chris@175 332 }
Chris@169 333
Chris@169 334 return float(27.5 * pow(2.0, (note + pshift) / 12.0));
Chris@41 335 }
Chris@41 336
Chris@31 337 bool
Chris@31 338 Silvet::initialise(size_t channels, size_t stepSize, size_t blockSize)
Chris@31 339 {
Chris@31 340 if (channels < getMinChannelCount() ||
Chris@31 341 channels > getMaxChannelCount()) return false;
Chris@31 342
Chris@31 343 if (stepSize != blockSize) {
Chris@31 344 cerr << "Silvet::initialise: Step size must be the same as block size ("
Chris@31 345 << stepSize << " != " << blockSize << ")" << endl;
Chris@31 346 return false;
Chris@31 347 }
Chris@31 348
Chris@31 349 m_blockSize = blockSize;
Chris@31 350
Chris@31 351 reset();
Chris@31 352
Chris@31 353 return true;
Chris@31 354 }
Chris@31 355
Chris@31 356 void
Chris@31 357 Silvet::reset()
Chris@31 358 {
Chris@31 359 delete m_resampler;
Chris@31 360 delete m_cq;
Chris@184 361 delete m_agentFeeder;
Chris@31 362
Chris@31 363 if (m_inputSampleRate != processingSampleRate) {
Chris@31 364 m_resampler = new Resampler(m_inputSampleRate, processingSampleRate);
Chris@31 365 } else {
Chris@31 366 m_resampler = 0;
Chris@31 367 }
Chris@31 368
Chris@173 369 double minFreq = 27.5;
Chris@173 370
Chris@173 371 if (!m_hqMode) {
Chris@173 372 // We don't actually return any notes from the bottom octave,
Chris@173 373 // so we can just pad with zeros
Chris@173 374 minFreq *= 2;
Chris@173 375 }
Chris@173 376
Chris@154 377 CQParameters params(processingSampleRate,
Chris@173 378 minFreq,
Chris@154 379 processingSampleRate / 3,
Chris@154 380 processingBPO);
Chris@154 381
Chris@155 382 params.q = 0.95; // MIREX code uses 0.8, but it seems 0.9 or lower
Chris@155 383 // drops the FFT size to 512 from 1024 and alters
Chris@155 384 // some other processing parameters, making
Chris@155 385 // everything much, much slower. Could be a flaw
Chris@155 386 // in the CQ parameter calculations, must check
Chris@154 387 params.atomHopFactor = 0.3;
Chris@154 388 params.threshold = 0.0005;
Chris@172 389 params.window = CQParameters::Hann;
Chris@154 390
Chris@154 391 m_cq = new CQSpectrogram(params, CQSpectrogram::InterpolateLinear);
Chris@31 392
Chris@165 393 m_colsPerSec = m_hqMode ? 50 : 25;
Chris@165 394
Chris@41 395 for (int i = 0; i < (int)m_postFilter.size(); ++i) {
Chris@41 396 delete m_postFilter[i];
Chris@41 397 }
Chris@41 398 m_postFilter.clear();
Chris@176 399 for (int i = 0; i < m_instruments[0].templateNoteCount; ++i) {
Chris@41 400 m_postFilter.push_back(new MedianFilter<double>(3));
Chris@41 401 }
Chris@184 402
Chris@184 403 m_columnCountIn = 0;
Chris@184 404 m_columnCountOut = 0;
Chris@40 405 m_startTime = RealTime::zeroTime;
Chris@184 406
Chris@184 407 m_agentFeeder = new AgentFeederPoly<NoteHypothesis>();
Chris@31 408 }
Chris@31 409
Chris@31 410 Silvet::FeatureSet
Chris@31 411 Silvet::process(const float *const *inputBuffers, Vamp::RealTime timestamp)
Chris@31 412 {
Chris@184 413 if (m_columnCountIn == 0) {
Chris@40 414 m_startTime = timestamp;
Chris@40 415 }
Chris@40 416
Chris@31 417 vector<double> data;
Chris@40 418 for (int i = 0; i < m_blockSize; ++i) {
Chris@40 419 data.push_back(inputBuffers[0][i]);
Chris@40 420 }
Chris@31 421
Chris@31 422 if (m_resampler) {
Chris@31 423 data = m_resampler->process(data.data(), data.size());
Chris@31 424 }
Chris@31 425
Chris@32 426 Grid cqout = m_cq->process(data);
Chris@51 427 FeatureSet fs = transcribe(cqout);
Chris@51 428 return fs;
Chris@34 429 }
Chris@34 430
Chris@34 431 Silvet::FeatureSet
Chris@34 432 Silvet::getRemainingFeatures()
Chris@34 433 {
Chris@145 434 Grid cqout = m_cq->getRemainingOutput();
Chris@184 435
Chris@51 436 FeatureSet fs = transcribe(cqout);
Chris@184 437
Chris@184 438 m_agentFeeder->finish();
Chris@184 439
Chris@184 440 FeatureList noteFeatures = obtainNotes();
Chris@184 441 for (FeatureList::const_iterator fi = noteFeatures.begin();
Chris@184 442 fi != noteFeatures.end(); ++fi) {
Chris@184 443 fs[m_notesOutputNo].push_back(*fi);
Chris@184 444 }
Chris@184 445
Chris@51 446 return fs;
Chris@34 447 }
Chris@34 448
Chris@34 449 Silvet::FeatureSet
Chris@34 450 Silvet::transcribe(const Grid &cqout)
Chris@34 451 {
Chris@32 452 Grid filtered = preProcess(cqout);
Chris@31 453
Chris@32 454 FeatureSet fs;
Chris@32 455
Chris@104 456 if (filtered.empty()) return fs;
Chris@170 457
Chris@170 458 const InstrumentPack &pack = m_instruments[m_instrument];
Chris@104 459
Chris@178 460 for (int i = 0; i < (int)filtered.size(); ++i) {
Chris@178 461 Feature f;
Chris@178 462 for (int j = 0; j < pack.templateHeight; ++j) {
Chris@178 463 f.values.push_back(float(filtered[i][j]));
Chris@178 464 }
Chris@178 465 fs[m_fcqOutputNo].push_back(f);
Chris@178 466 }
Chris@178 467
Chris@34 468 int width = filtered.size();
Chris@34 469
Chris@164 470 int iterations = m_hqMode ? 20 : 10;
Chris@34 471
Chris@170 472 //!!! pitches or notes? [terminology]
Chris@176 473 Grid localPitches(width, vector<double>(pack.templateNoteCount, 0.0));
Chris@170 474
Chris@184 475 bool wantShifts = m_hqMode;
Chris@170 476 int shiftCount = 1;
Chris@170 477 if (wantShifts) {
Chris@170 478 shiftCount = pack.templateMaxShift * 2 + 1;
Chris@170 479 }
Chris@170 480
Chris@170 481 vector<vector<int> > localBestShifts;
Chris@170 482 if (wantShifts) {
Chris@170 483 localBestShifts =
Chris@176 484 vector<vector<int> >(width, vector<int>(pack.templateNoteCount, 0));
Chris@170 485 }
Chris@170 486
Chris@170 487 vector<bool> present(width, false);
Chris@37 488
Chris@123 489 #pragma omp parallel for
Chris@123 490 for (int i = 0; i < width; ++i) {
Chris@104 491
Chris@170 492 double sum = 0.0;
Chris@176 493 for (int j = 0; j < pack.templateHeight; ++j) {
Chris@170 494 sum += filtered.at(i).at(j);
Chris@170 495 }
Chris@170 496 if (sum < 1e-5) continue;
Chris@170 497
Chris@170 498 present[i] = true;
Chris@170 499
Chris@170 500 EM em(&pack, m_hqMode);
Chris@170 501
Chris@183 502 em.setPitchSparsity(pack.pitchSparsity);
Chris@183 503
Chris@170 504 for (int j = 0; j < iterations; ++j) {
Chris@170 505 em.iterate(filtered.at(i).data());
Chris@37 506 }
Chris@37 507
Chris@170 508 const float *pitchDist = em.getPitchDistribution();
Chris@170 509 const float *const *shiftDist = em.getShifts();
Chris@37 510
Chris@176 511 for (int j = 0; j < pack.templateNoteCount; ++j) {
Chris@104 512
Chris@170 513 localPitches[i][j] = pitchDist[j] * sum;
Chris@170 514
Chris@170 515 int bestShift = 0;
Chris@179 516 float bestShiftValue = 0.0;
Chris@170 517 if (wantShifts) {
Chris@170 518 for (int k = 0; k < shiftCount; ++k) {
Chris@179 519 float value = shiftDist[k][j];
Chris@179 520 if (k == 0 || value > bestShiftValue) {
Chris@179 521 bestShiftValue = value;
Chris@170 522 bestShift = k;
Chris@170 523 }
Chris@170 524 }
Chris@170 525 localBestShifts[i][j] = bestShift;
Chris@170 526 }
Chris@123 527 }
Chris@123 528 }
Chris@166 529
Chris@166 530 for (int i = 0; i < width; ++i) {
Chris@37 531
Chris@170 532 if (!present[i]) {
Chris@170 533 // silent column
Chris@176 534 for (int j = 0; j < pack.templateNoteCount; ++j) {
Chris@170 535 m_postFilter[j]->push(0.0);
Chris@170 536 }
Chris@166 537 continue;
Chris@166 538 }
Chris@166 539
Chris@184 540 postProcess(localPitches[i], localBestShifts[i],
Chris@184 541 wantShifts, shiftCount);
Chris@166 542
Chris@184 543 FeatureList noteFeatures = obtainNotes();
Chris@38 544
Chris@123 545 for (FeatureList::const_iterator fi = noteFeatures.begin();
Chris@123 546 fi != noteFeatures.end(); ++fi) {
Chris@123 547 fs[m_notesOutputNo].push_back(*fi);
Chris@40 548 }
Chris@34 549 }
Chris@34 550
Chris@32 551 return fs;
Chris@31 552 }
Chris@31 553
Chris@32 554 Silvet::Grid
Chris@32 555 Silvet::preProcess(const Grid &in)
Chris@32 556 {
Chris@32 557 int width = in.size();
Chris@32 558
Chris@165 559 int spacing = processingSampleRate / m_colsPerSec;
Chris@32 560
Chris@165 561 // need to be careful that col spacing is an integer number of samples!
Chris@165 562 assert(spacing * m_colsPerSec == processingSampleRate);
Chris@32 563
Chris@32 564 Grid out;
Chris@32 565
Chris@58 566 // We count the CQ latency in terms of processing hops, but
Chris@58 567 // actually it probably isn't an exact number of hops so this
Chris@58 568 // isn't quite accurate. But the small constant offset is
Chris@165 569 // practically irrelevant compared to the jitter from the frame
Chris@165 570 // size we reduce to in a moment
Chris@33 571 int latentColumns = m_cq->getLatency() / m_cq->getColumnHop();
Chris@33 572
Chris@176 573 const InstrumentPack &pack = m_instruments[m_instrument];
Chris@176 574
Chris@32 575 for (int i = 0; i < width; ++i) {
Chris@32 576
Chris@184 577 if (m_columnCountIn < latentColumns) {
Chris@184 578 ++m_columnCountIn;
Chris@33 579 continue;
Chris@33 580 }
Chris@33 581
Chris@184 582 int prevSampleNo = (m_columnCountIn - 1) * m_cq->getColumnHop();
Chris@184 583 int sampleNo = m_columnCountIn * m_cq->getColumnHop();
Chris@32 584
Chris@32 585 bool select = (sampleNo / spacing != prevSampleNo / spacing);
Chris@32 586
Chris@32 587 if (select) {
Chris@32 588 vector<double> inCol = in[i];
Chris@176 589 vector<double> outCol(pack.templateHeight);
Chris@32 590
Chris@178 591 // In HQ mode, the CQ returns 600 bins and we ignore the
Chris@178 592 // lowest 55 of them.
Chris@178 593 //
Chris@178 594 // In draft mode the CQ is an octave shorter, returning
Chris@178 595 // 540 bins, so we instead pad them with an additional 5
Chris@178 596 // zeros.
Chris@178 597 //
Chris@178 598 // We also need to reverse the column as we go, since the
Chris@178 599 // raw CQ has the high frequencies first and we need it
Chris@178 600 // the other way around.
Chris@32 601
Chris@178 602 if (m_hqMode) {
Chris@178 603 for (int j = 0; j < pack.templateHeight; ++j) {
Chris@178 604 int ix = inCol.size() - j - 55;
Chris@178 605 outCol[j] = inCol[ix];
Chris@178 606 }
Chris@178 607 } else {
Chris@178 608 for (int j = 0; j < 5; ++j) {
Chris@178 609 outCol[j] = 0.0;
Chris@178 610 }
Chris@178 611 for (int j = 5; j < pack.templateHeight; ++j) {
Chris@178 612 int ix = inCol.size() - j + 4;
Chris@178 613 outCol[j] = inCol[ix];
Chris@178 614 }
Chris@46 615 }
Chris@32 616
Chris@46 617 vector<double> noiseLevel1 =
Chris@46 618 MedianFilter<double>::filter(40, outCol);
Chris@176 619 for (int j = 0; j < pack.templateHeight; ++j) {
Chris@46 620 noiseLevel1[j] = std::min(outCol[j], noiseLevel1[j]);
Chris@46 621 }
Chris@32 622
Chris@46 623 vector<double> noiseLevel2 =
Chris@46 624 MedianFilter<double>::filter(40, noiseLevel1);
Chris@176 625 for (int j = 0; j < pack.templateHeight; ++j) {
Chris@46 626 outCol[j] = std::max(outCol[j] - noiseLevel2[j], 0.0);
Chris@32 627 }
Chris@32 628
Chris@165 629 out.push_back(outCol);
Chris@32 630 }
Chris@32 631
Chris@184 632 ++m_columnCountIn;
Chris@32 633 }
Chris@32 634
Chris@32 635 return out;
Chris@32 636 }
Chris@32 637
Chris@168 638 void
Chris@170 639 Silvet::postProcess(const vector<double> &pitches,
Chris@170 640 const vector<int> &bestShifts,
Chris@184 641 bool wantShifts,
Chris@184 642 int shiftCount)
Chris@166 643 {
Chris@176 644 const InstrumentPack &pack = m_instruments[m_instrument];
Chris@176 645
Chris@41 646 vector<double> filtered;
Chris@41 647
Chris@176 648 for (int j = 0; j < pack.templateNoteCount; ++j) {
Chris@170 649 m_postFilter[j]->push(pitches[j]);
Chris@41 650 filtered.push_back(m_postFilter[j]->get());
Chris@41 651 }
Chris@41 652
Chris@185 653 double threshold = 1; //!!! pack.levelThreshold
Chris@41 654
Chris@184 655 double columnDuration = 1.0 / m_colsPerSec;
Chris@184 656 int postFilterLatency = int(m_postFilter[0]->getSize() / 2);
Chris@184 657 RealTime t = RealTime::fromSeconds
Chris@184 658 (columnDuration * (m_columnCountOut - postFilterLatency) + 0.02);
Chris@166 659
Chris@176 660 for (int j = 0; j < pack.templateNoteCount; ++j) {
Chris@184 661
Chris@166 662 double strength = filtered[j];
Chris@184 663 if (strength < threshold) {
Chris@184 664 continue;
Chris@184 665 }
Chris@184 666
Chris@184 667 double freq;
Chris@184 668 if (wantShifts) {
Chris@184 669 freq = noteFrequency(j, bestShifts[j], shiftCount);
Chris@184 670 } else {
Chris@184 671 freq = noteFrequency(j, 0, shiftCount);
Chris@184 672 }
Chris@184 673
Chris@184 674 double confidence = strength / 50.0; //!!!???
Chris@184 675 if (confidence > 1.0) confidence = 1.0;
Chris@184 676
Chris@184 677 AgentHypothesis::Observation obs(freq, t, confidence);
Chris@184 678 m_agentFeeder->feed(obs);
Chris@168 679 }
Chris@166 680
Chris@184 681 m_columnCountOut ++;
Chris@166 682 }
Chris@166 683
Chris@166 684 Vamp::Plugin::FeatureList
Chris@184 685 Silvet::obtainNotes()
Chris@166 686 {
Chris@41 687 FeatureList noteFeatures;
Chris@41 688
Chris@184 689 typedef AgentFeederPoly<NoteHypothesis> NoteFeeder;
Chris@184 690
Chris@184 691 NoteFeeder *feeder = dynamic_cast<NoteFeeder *>(m_agentFeeder);
Chris@184 692
Chris@184 693 if (!feeder) {
Chris@184 694 cerr << "INTERNAL ERROR: Feeder is not a poly-note-hypothesis-feeder!"
Chris@184 695 << endl;
Chris@41 696 return noteFeatures;
Chris@41 697 }
Chris@150 698
Chris@184 699 std::set<NoteHypothesis> hh = feeder->getAcceptedHypotheses();
Chris@41 700
Chris@184 701 //!!! inefficient
Chris@184 702 for (std::set<NoteHypothesis>::const_iterator hi = hh.begin();
Chris@184 703 hi != hh.end(); ++hi) {
Chris@184 704
Chris@184 705 NoteHypothesis h(*hi);
Chris@184 706
Chris@184 707 if (m_emitted.find(h) != m_emitted.end()) {
Chris@184 708 continue; // already returned this one
Chris@41 709 }
Chris@41 710
Chris@184 711 m_emitted.insert(h);
Chris@41 712
Chris@184 713 NoteHypothesis::Note n = h.getAveragedNote();
Chris@41 714
Chris@184 715 int velocity = n.confidence * 127;
Chris@184 716 if (velocity > 127) velocity = 127;
Chris@41 717
Chris@184 718 Feature f;
Chris@184 719 f.hasTimestamp = true;
Chris@184 720 f.hasDuration = true;
Chris@184 721 f.timestamp = n.time;
Chris@184 722 f.duration = n.duration;
Chris@184 723 f.values.clear();
Chris@184 724 f.values.push_back(n.freq);
Chris@184 725 f.values.push_back(velocity);
Chris@184 726 // f.label = noteName(note, partShift, shiftCount);
Chris@184 727 noteFeatures.push_back(f);
Chris@41 728 }
Chris@41 729
Chris@41 730 return noteFeatures;
Chris@41 731 }