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annotate src/EM.cpp @ 131:88e6066e80b5

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author Chris Cannam
date Thu, 08 May 2014 09:49:27 +0100
parents f25b8e7de0ed
children d2bc51cc7f57
rev   line source
Chris@34 1 /* -*- c-basic-offset: 4 indent-tabs-mode: nil -*- vi:set ts=8 sts=4 sw=4: */
Chris@34 2
Chris@34 3 /*
Chris@34 4 Silvet
Chris@34 5
Chris@34 6 A Vamp plugin for note transcription.
Chris@34 7 Centre for Digital Music, Queen Mary University of London.
Chris@34 8
Chris@34 9 This program is free software; you can redistribute it and/or
Chris@34 10 modify it under the terms of the GNU General Public License as
Chris@34 11 published by the Free Software Foundation; either version 2 of the
Chris@34 12 License, or (at your option) any later version. See the file
Chris@34 13 COPYING included with this distribution for more information.
Chris@34 14 */
Chris@34 15
Chris@34 16 #include "EM.h"
Chris@34 17
Chris@34 18 #include "data/include/templates.h"
Chris@34 19
Chris@36 20 #include <cstdlib>
Chris@42 21 #include <cmath>
Chris@36 22
Chris@36 23 #include <iostream>
Chris@36 24
Chris@91 25 #include "VectorOps.h"
Chris@91 26 #include "Allocators.h"
Chris@36 27
Chris@36 28 using std::vector;
Chris@36 29 using std::cerr;
Chris@36 30 using std::endl;
Chris@36 31
Chris@91 32 using namespace breakfastquay;
Chris@91 33
Chris@35 34 static double epsilon = 1e-16;
Chris@35 35
Chris@110 36 EM::EM(bool useShifts) :
Chris@45 37 m_noteCount(SILVET_TEMPLATE_NOTE_COUNT),
Chris@110 38 m_shiftCount(useShifts ? SILVET_TEMPLATE_MAX_SHIFT * 2 + 1 : 1),
Chris@45 39 m_binCount(SILVET_TEMPLATE_HEIGHT),
Chris@91 40 m_sourceCount(SILVET_TEMPLATE_COUNT),
Chris@42 41 m_pitchSparsity(1.1),
Chris@83 42 m_sourceSparsity(1.3),
Chris@83 43 m_lowestPitch(silvet_templates_lowest_note),
Chris@83 44 m_highestPitch(silvet_templates_highest_note)
Chris@35 45 {
Chris@91 46 m_pitches = allocate<double>(m_noteCount);
Chris@100 47 m_updatePitches = allocate<double>(m_noteCount);
Chris@55 48 for (int n = 0; n < m_noteCount; ++n) {
Chris@55 49 m_pitches[n] = drand48();
Chris@55 50 }
Chris@35 51
Chris@113 52 if (useShifts) {
Chris@113 53 m_shifts = allocate_channels<double>(m_shiftCount, m_noteCount);
Chris@113 54 m_updateShifts = allocate_channels<double>(m_shiftCount, m_noteCount);
Chris@113 55 for (int f = 0; f < m_shiftCount; ++f) {
Chris@113 56 for (int n = 0; n < m_noteCount; ++n) {
Chris@110 57 m_shifts[f][n] = drand48();
Chris@110 58 }
Chris@55 59 }
Chris@113 60 } else {
Chris@113 61 m_shifts = 0;
Chris@113 62 m_updateShifts = 0;
Chris@35 63 }
Chris@35 64
Chris@91 65 m_sources = allocate_channels<double>(m_sourceCount, m_noteCount);
Chris@100 66 m_updateSources = allocate_channels<double>(m_sourceCount, m_noteCount);
Chris@91 67 for (int i = 0; i < m_sourceCount; ++i) {
Chris@55 68 for (int n = 0; n < m_noteCount; ++n) {
Chris@35 69 m_sources[i][n] = (inRange(i, n) ? 1.0 : 0.0);
Chris@35 70 }
Chris@35 71 }
Chris@35 72
Chris@91 73 m_estimate = allocate<double>(m_binCount);
Chris@91 74 m_q = allocate<double>(m_binCount);
Chris@35 75 }
Chris@35 76
Chris@35 77 EM::~EM()
Chris@35 78 {
Chris@92 79 deallocate(m_q);
Chris@92 80 deallocate(m_estimate);
Chris@92 81 deallocate_channels(m_sources, m_sourceCount);
Chris@100 82 deallocate_channels(m_updateSources, m_sourceCount);
Chris@92 83 deallocate_channels(m_shifts, m_shiftCount);
Chris@100 84 deallocate_channels(m_updateShifts, m_shiftCount);
Chris@92 85 deallocate(m_pitches);
Chris@100 86 deallocate(m_updatePitches);
Chris@35 87 }
Chris@35 88
Chris@45 89 void
Chris@45 90 EM::rangeFor(int instrument, int &minPitch, int &maxPitch)
Chris@45 91 {
Chris@55 92 minPitch = silvet_templates[instrument].lowest;
Chris@55 93 maxPitch = silvet_templates[instrument].highest;
Chris@45 94 }
Chris@45 95
Chris@35 96 bool
Chris@45 97 EM::inRange(int instrument, int pitch)
Chris@35 98 {
Chris@45 99 int minPitch, maxPitch;
Chris@45 100 rangeFor(instrument, minPitch, maxPitch);
Chris@45 101 return (pitch >= minPitch && pitch <= maxPitch);
Chris@35 102 }
Chris@35 103
Chris@36 104 void
Chris@92 105 EM::normaliseColumn(double *column, int size)
Chris@36 106 {
Chris@92 107 double sum = v_sum(column, size);
Chris@92 108 v_scale(column, 1.0 / sum, size);
Chris@36 109 }
Chris@36 110
Chris@36 111 void
Chris@92 112 EM::normaliseGrid(double **grid, int size1, int size2)
Chris@53 113 {
Chris@122 114 double *denominators = allocate_and_zero<double>(size2);
Chris@122 115
Chris@92 116 for (int i = 0; i < size1; ++i) {
Chris@122 117 for (int j = 0; j < size2; ++j) {
Chris@122 118 denominators[j] += grid[i][j];
Chris@122 119 }
Chris@53 120 }
Chris@122 121
Chris@122 122 for (int i = 0; i < size1; ++i) {
Chris@122 123 v_divide(grid[i], denominators, size2);
Chris@122 124 }
Chris@122 125
Chris@122 126 deallocate(denominators);
Chris@53 127 }
Chris@53 128
Chris@53 129 void
Chris@92 130 EM::iterate(const double *column)
Chris@36 131 {
Chris@92 132 double *norm = allocate<double>(m_binCount);
Chris@92 133 v_copy(norm, column, m_binCount);
Chris@92 134 normaliseColumn(norm, m_binCount);
Chris@92 135 expectation(norm);
Chris@92 136 maximisation(norm);
Chris@95 137 deallocate(norm);
Chris@36 138 }
Chris@36 139
Chris@88 140 const double *
Chris@55 141 EM::templateFor(int instrument, int note, int shift)
Chris@45 142 {
Chris@113 143 if (m_shifts) {
Chris@110 144 return silvet_templates[instrument].data[note] + shift;
Chris@110 145 } else {
Chris@110 146 return silvet_templates[instrument].data[note] +
Chris@110 147 SILVET_TEMPLATE_MAX_SHIFT;
Chris@110 148 }
Chris@45 149 }
Chris@45 150
Chris@36 151 void
Chris@92 152 EM::expectation(const double *column)
Chris@36 153 {
Chris@62 154 // cerr << ".";
Chris@36 155
Chris@99 156 v_set(m_estimate, epsilon, m_binCount);
Chris@36 157
Chris@130 158 for (int f = 0; f < m_shiftCount; ++f) {
Chris@130 159
Chris@130 160 const double *shiftIn = m_shifts ? m_shifts[f] : 0;
Chris@130 161
Chris@130 162 for (int i = 0; i < m_sourceCount; ++i) {
Chris@130 163
Chris@130 164 const double *sourceIn = m_sources[i];
Chris@130 165
Chris@130 166 int lowest, highest;
Chris@130 167 rangeFor(i, lowest, highest);
Chris@130 168
Chris@130 169 for (int n = lowest; n <= highest; ++n) {
Chris@130 170
Chris@130 171 const double source = sourceIn[n];
Chris@130 172 const double shift = shiftIn ? shiftIn[n] : 1.0;
Chris@130 173 const double pitch = m_pitches[n];
Chris@130 174
Chris@130 175 const double factor = pitch * source * shift;
Chris@88 176 const double *w = templateFor(i, n, f);
Chris@130 177
Chris@111 178 v_add_with_gain(m_estimate, w, factor, m_binCount);
Chris@36 179 }
Chris@36 180 }
Chris@36 181 }
Chris@36 182
Chris@45 183 for (int i = 0; i < m_binCount; ++i) {
Chris@36 184 m_q[i] = column[i] / m_estimate[i];
Chris@36 185 }
Chris@36 186 }
Chris@36 187
Chris@36 188 void
Chris@92 189 EM::maximisation(const double *column)
Chris@36 190 {
Chris@100 191 v_set(m_updatePitches, epsilon, m_noteCount);
Chris@113 192
Chris@92 193 for (int i = 0; i < m_sourceCount; ++i) {
Chris@100 194 v_set(m_updateSources[i], epsilon, m_noteCount);
Chris@92 195 }
Chris@62 196
Chris@113 197 if (m_shifts) {
Chris@113 198 for (int i = 0; i < m_shiftCount; ++i) {
Chris@113 199 v_set(m_updateShifts[i], epsilon, m_noteCount);
Chris@113 200 }
Chris@113 201 }
Chris@113 202
Chris@94 203 double *contributions = allocate<double>(m_binCount);
Chris@36 204
Chris@130 205 for (int f = 0; f < m_shiftCount; ++f) {
Chris@85 206
Chris@130 207 const double *shiftIn = m_shifts ? m_shifts[f] : 0;
Chris@130 208 double *shiftOut = m_shifts ? m_updateShifts[f] : 0;
Chris@85 209
Chris@130 210 for (int i = 0; i < m_sourceCount; ++i) {
Chris@85 211
Chris@130 212 const double *sourceIn = m_sources[i];
Chris@130 213 double *sourceOut = m_updateSources[i];
Chris@85 214
Chris@130 215 int lowest, highest;
Chris@130 216 rangeFor(i, lowest, highest);
Chris@85 217
Chris@130 218 for (int n = lowest; n <= highest; ++n) {
Chris@130 219
Chris@130 220 const double shift = shiftIn ? shiftIn[n] : 1.0;
Chris@130 221 const double source = sourceIn[n];
Chris@130 222 const double pitch = m_pitches[n];
Chris@130 223
Chris@89 224 const double factor = pitch * source * shift;
Chris@88 225 const double *w = templateFor(i, n, f);
Chris@85 226
Chris@94 227 v_copy(contributions, w, m_binCount);
Chris@95 228 v_multiply(contributions, m_q, m_binCount);
Chris@94 229
Chris@119 230 double total = factor * v_sum(contributions, m_binCount);
Chris@94 231
Chris@130 232 m_updatePitches[n] += total;
Chris@130 233 sourceOut[n] += total;
Chris@85 234
Chris@130 235 if (shiftOut) {
Chris@130 236 shiftOut[n] += total;
Chris@113 237 }
Chris@42 238 }
Chris@36 239 }
Chris@36 240 }
Chris@36 241
Chris@103 242 if (m_pitchSparsity != 1.0) {
Chris@103 243 for (int n = 0; n < m_noteCount; ++n) {
Chris@103 244 m_updatePitches[n] =
Chris@103 245 pow(m_updatePitches[n], m_pitchSparsity);
Chris@62 246 }
Chris@103 247 }
Chris@103 248
Chris@103 249 if (m_sourceSparsity != 1.0) {
Chris@130 250 for (int i = 0; i < m_sourceCount; ++i) {
Chris@130 251 for (int n = 0; n < m_noteCount; ++n) {
Chris@103 252 m_updateSources[i][n] =
Chris@103 253 pow(m_updateSources[i][n], m_sourceSparsity);
Chris@62 254 }
Chris@62 255 }
Chris@62 256 }
Chris@85 257
Chris@100 258 normaliseColumn(m_updatePitches, m_noteCount);
Chris@112 259 std::swap(m_pitches, m_updatePitches);
Chris@112 260
Chris@113 261 normaliseGrid(m_updateSources, m_sourceCount, m_noteCount);
Chris@113 262 std::swap(m_sources, m_updateSources);
Chris@113 263
Chris@113 264 if (m_shifts) {
Chris@112 265 normaliseGrid(m_updateShifts, m_shiftCount, m_noteCount);
Chris@112 266 std::swap(m_shifts, m_updateShifts);
Chris@112 267 }
Chris@36 268 }
Chris@36 269
Chris@36 270