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annotate src/Matcher.h @ 43:6a5d165e5ea4 refactors

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refactor: m_ prefix
author Chris Cannam
date Thu, 13 Nov 2014 13:53:52 +0000
parents 8dd16749c3c3
children c1112adfd270
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 plugin using the MATCH audio alignment
cannam@0 5 algorithm.
cannam@0 6
cannam@0 7 Centre for Digital Music, Queen Mary, University of London.
cannam@0 8 This file copyright 2007 Simon Dixon, Chris Cannam and QMUL.
cannam@0 9
cannam@0 10 This program is free software; you can redistribute it and/or
cannam@0 11 modify it under the terms of the GNU General Public License as
cannam@0 12 published by the Free Software Foundation; either version 2 of the
cannam@0 13 License, or (at your option) any later version. See the file
cannam@0 14 COPYING included with this distribution for more information.
cannam@0 15 */
cannam@0 16
cannam@0 17 #ifndef _MATCHER_H_
cannam@0 18 #define _MATCHER_H_
cannam@0 19
cannam@0 20 #include <vector>
cannam@0 21 #include <iostream>
cannam@0 22 #include <sstream>
cannam@0 23 #include <cmath>
cannam@0 24
cannam@0 25 #define ADVANCE_THIS 1
cannam@0 26 #define ADVANCE_OTHER 2
cannam@0 27 #define ADVANCE_BOTH 3
cannam@0 28 #define MASK 0xfc
cannam@0 29
Chris@26 30 #include "DistanceMetric.h"
Chris@38 31 #include "FeatureExtractor.h"
cannam@0 32
cannam@0 33 using std::vector;
cannam@0 34 using std::string;
cannam@0 35 using std::cerr;
cannam@0 36 using std::endl;
cannam@0 37
cannam@0 38 /** Represents an audio stream that can be matched to another audio
cannam@0 39 * stream of the same piece of music. The matching algorithm uses
cannam@0 40 * dynamic time warping. The distance metric is a Euclidean metric
cannam@0 41 * on the FFT data with the higher frequencies mapped onto a linear
cannam@0 42 * scale.
cannam@0 43 */
cannam@0 44 class Matcher
cannam@0 45 {
Chris@15 46 public:
Chris@15 47 struct Parameters {
Chris@15 48
Chris@15 49 Parameters(float rate_, double hopTime_, int fftSize_) :
Chris@15 50 sampleRate(rate_),
Chris@26 51 distanceNorm(DistanceMetric::NormaliseDistanceToLogSum),
Chris@29 52 distanceScale(90.0),
Chris@15 53 hopTime(hopTime_),
Chris@15 54 fftSize(fftSize_),
Chris@15 55 blockTime(10.0),
Chris@15 56 maxRunCount(3)
Chris@15 57 {}
Chris@15 58
Chris@15 59 /** Sample rate of audio */
Chris@15 60 float sampleRate;
Chris@15 61
Chris@15 62 /** Type of distance metric normalisation */
Chris@26 63 DistanceMetric::DistanceNormalisation distanceNorm;
Chris@15 64
Chris@29 65 /** Scaling factor for distance metric; must guarantee that the
Chris@29 66 * final value fits in the data type used, that is, unsigned
Chris@29 67 * char.
Chris@29 68 */
Chris@29 69 double distanceScale;
Chris@29 70
Chris@15 71 /** Spacing of audio frames (determines the amount of overlap or
Chris@15 72 * skip between frames). This value is expressed in
Chris@15 73 * seconds. */
Chris@15 74 double hopTime;
Chris@38 75
Chris@15 76 /** Size of an FFT frame in samples. Note that the data passed
Chris@15 77 * in to Matcher is already in the frequency domain, so this
Chris@15 78 * expresses the size of the frame that the caller will be
Chris@38 79 * providing. */
Chris@15 80 int fftSize;
Chris@38 81
Chris@15 82 /** The width of the search band (error margin) around the current
Chris@15 83 * match position, measured in seconds. Strictly speaking the
Chris@15 84 * width is measured backwards from the current point, since the
Chris@15 85 * algorithm has to work causally.
Chris@15 86 */
Chris@15 87 double blockTime;
Chris@15 88
Chris@15 89 /** Maximum number of frames sequentially processed by this
Chris@15 90 * matcher, without a frame of the other matcher being
Chris@15 91 * processed.
Chris@15 92 */
Chris@15 93 int maxRunCount;
Chris@15 94 };
Chris@15 95
cannam@0 96 /** Constructor for Matcher.
cannam@0 97 *
cannam@0 98 * @param p The Matcher representing the performance with which
cannam@0 99 * this one is going to be matched. Some information is shared
cannam@0 100 * between the two matchers (currently one possesses the distance
cannam@0 101 * matrix and optimal path matrix).
cannam@0 102 */
Chris@38 103 Matcher(Parameters parameters,
Chris@38 104 FeatureExtractor::Parameters featureParams,
Chris@38 105 Matcher *p);
cannam@0 106
Chris@23 107 /** Constructor for Matcher using externally supplied features.
Chris@23 108 * A Matcher made using this constructor will not carry out its
Chris@23 109 * own feature extraction from frequency-domain audio data, but
Chris@23 110 * instead will accept arbitrary feature frames calculated by
Chris@23 111 * some external code.
Chris@23 112 *
Chris@23 113 * @param p The Matcher representing the performance with which
Chris@23 114 * this one is going to be matched. Some information is shared
Chris@23 115 * between the two matchers (currently one possesses the distance
Chris@23 116 * matrix and optimal path matrix).
Chris@23 117 *
Chris@23 118 * @param featureSize Number of values in each feature vector.
Chris@23 119 */
Chris@23 120 Matcher(Parameters parameters, Matcher *p, int featureSize);
Chris@23 121
cannam@0 122 ~Matcher();
cannam@0 123
cannam@0 124 /** For debugging, outputs information about the Matcher to
cannam@0 125 * standard error.
cannam@0 126 */
cannam@0 127 void print();
cannam@0 128
cannam@0 129 /** Adds a link to the Matcher object representing the performance
cannam@0 130 * which is going to be matched to this one.
cannam@0 131 *
cannam@0 132 * @param p the Matcher representing the other performance
cannam@0 133 */
cannam@0 134 void setOtherMatcher(Matcher *p) {
Chris@43 135 m_otherMatcher = p;
cannam@0 136 } // setOtherMatcher()
cannam@0 137
cannam@0 138 int getFrameCount() {
Chris@43 139 return m_frameCount;
cannam@0 140 }
cannam@0 141
cannam@0 142 protected:
Chris@38 143 /** Create internal structures and reset. */
cannam@0 144 void init();
cannam@0 145
Chris@38 146 /** The distXSize value has changed: resize internal buffers. */
Chris@41 147 void size();
cannam@0 148
Chris@38 149 /** Process a frequency-domain frame of audio data using the
Chris@38 150 * built-in FeatureExtractor, then calculating the distance to
Chris@38 151 * all frames stored in the otherMatcher and storing them in the
Chris@38 152 * distance matrix, and finally updating the optimal path matrix
Chris@38 153 * using the dynamic time warping algorithm.
Chris@14 154 *
Chris@14 155 * Return value is the frame (post-processed, with warping,
Chris@14 156 * rectification, and normalisation as appropriate).
Chris@23 157 *
Chris@23 158 * The Matcher must have been constructed using the constructor
Chris@23 159 * without an external featureSize parameter in order to use this
Chris@23 160 * function. (Otherwise it will be expecting you to call
Chris@23 161 * consumeFeatureVector.)
cannam@0 162 */
Chris@21 163 std::vector<double> consumeFrame(double *reBuffer, double *imBuffer);
cannam@0 164
Chris@23 165 /** Processes a feature vector frame (presumably calculated from
Chris@23 166 * audio data by some external code). As consumeFrame, except
Chris@23 167 * that it does not calculate a feature from audio data but
Chris@23 168 * instead uses the supplied feature directly.
Chris@23 169 *
Chris@23 170 * The Matcher must have been constructed using the constructor
Chris@23 171 * that accepts an external featureSize parameter in order to
Chris@23 172 * use this function. The supplied feature must be of the size
Chris@23 173 * that was passed to the constructor.
Chris@23 174 */
Chris@23 175 void consumeFeatureVector(std::vector<double> feature);
Chris@23 176
cannam@0 177 /** Retrieves values from the minimum cost matrix.
cannam@0 178 *
cannam@0 179 * @param i the frame number of this Matcher
cannam@0 180 * @param j the frame number of the other Matcher
cannam@0 181 * @return the cost of the minimum cost path to this location
cannam@0 182 */
cannam@0 183 int getValue(int i, int j, bool firstAttempt);
cannam@0 184
cannam@0 185 /** Stores entries in the distance matrix and the optimal path matrix.
cannam@0 186 *
cannam@0 187 * @param i the frame number of this Matcher
cannam@0 188 * @param j the frame number of the other Matcher
cannam@0 189 * @param dir the direction from which this position is reached with
cannam@0 190 * minimum cost
cannam@0 191 * @param value the cost of the minimum path except the current step
cannam@0 192 * @param dMN the distance cost between the two frames
cannam@0 193 */
cannam@0 194 void setValue(int i, int j, int dir, int value, int dMN);
cannam@0 195
Chris@21 196 void calcAdvance();
Chris@21 197
Chris@42 198 /** Points to the other performance with which this one is being
Chris@42 199 * compared. The data for the distance metric and the dynamic
Chris@42 200 * time warping is shared between the two matchers. In the
Chris@42 201 * original version, only one of the two performance matchers
Chris@42 202 * contained the distance metric. (See <code>first</code>)
Chris@42 203 */
Chris@43 204 Matcher *m_otherMatcher;
Chris@42 205
Chris@42 206 /** Indicates which performance is considered primary (the
Chris@42 207 * score). This is the performance shown on the vertical axis,
Chris@42 208 * and referred to as "this" in the codes for the direction of
Chris@42 209 * DTW steps. */
Chris@43 210 bool m_firstPM;
Chris@42 211
Chris@42 212 /** Configuration parameters */
Chris@43 213 Parameters m_params;
Chris@42 214
Chris@42 215 /** Width of the search band in FFT frames (see <code>blockTime</code>) */
Chris@43 216 int m_blockSize;
Chris@42 217
Chris@42 218 /** The number of frames of audio data which have been read. */
Chris@43 219 int m_frameCount;
Chris@42 220
Chris@42 221 /** The number of frames sequentially processed by this matcher,
Chris@42 222 * without a frame of the other matcher being processed.
Chris@42 223 */
Chris@43 224 int m_runCount;
Chris@42 225
Chris@42 226 /** The number of values in a feature vector. */
Chris@43 227 int m_featureSize;
Chris@42 228
Chris@42 229 /** A block of previously seen frames are stored in this structure
Chris@42 230 * for calculation of the distance matrix as the new frames are
Chris@42 231 * read in. One can think of the structure of the array as a
Chris@42 232 * circular buffer of vectors. These are the frames with all
Chris@42 233 * applicable processing applied (e.g. spectral difference,
Chris@42 234 * normalisation), unlike prevFrame and newFrame. The total
Chris@42 235 * energy of frames[i] is stored in totalEnergies[i]. */
Chris@43 236 vector<vector<double> > m_frames;
Chris@42 237
Chris@42 238 /** The best path cost matrix. */
Chris@43 239 vector<vector<int> > m_bestPathCost;
Chris@42 240
Chris@42 241 /** The distance matrix. */
Chris@43 242 vector<vector<unsigned char> > m_distance;
Chris@42 243
Chris@42 244 /** The bounds of each row of data in the distance and path cost matrices.*/
Chris@43 245 vector<int> m_first;
Chris@43 246 vector<int> m_last;
Chris@42 247
Chris@42 248 /** Height of each column in distance and bestPathCost matrices */
Chris@43 249 vector<int> m_distYSizes;
Chris@42 250
Chris@42 251 /** Width of distance and bestPathCost matrices and first and last vectors */
Chris@43 252 int m_distXSize;
Chris@42 253
Chris@43 254 bool m_initialised;
Chris@42 255
Chris@43 256 FeatureExtractor m_featureExtractor;
Chris@43 257 DistanceMetric m_metric;
Chris@26 258
cannam@0 259 friend class MatchFeeder;
Chris@24 260 friend class MatchFeatureFeeder;
Chris@15 261 friend class Finder;
cannam@0 262
cannam@0 263 }; // class Matcher
cannam@0 264
cannam@0 265 #endif