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annotate plugins/AdaptiveSpectrogram.h @ 107:07f92bbe68d1

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* Use a Window object instead of working it out "by hand"
author Chris Cannam <c.cannam@qmul.ac.uk>
date Wed, 13 May 2009 11:23:00 +0000
parents 35f2138c6891
children 42e4f785a636
rev   line source
c@92 1 /* -*- c-basic-offset: 4 indent-tabs-mode: nil -*- vi:set ts=8 sts=4 sw=4: */
c@92 2
c@92 3 /*
c@92 4 QM Vamp Plugin Set
c@92 5
c@92 6 Centre for Digital Music, Queen Mary, University of London.
c@92 7 All rights reserved.
c@92 8 */
c@92 9
c@92 10 #ifndef _ADAPTIVE_SPECTROGRAM_H_
c@92 11 #define _ADAPTIVE_SPECTROGRAM_H_
c@92 12
c@92 13 #include <vamp-sdk/Plugin.h>
c@92 14 #include <cmath>
c@92 15 #include <vector>
c@92 16
c@105 17 #include <dsp/transforms/FFT.h>//!!!
c@107 18 #include <base/Window.h>
c@105 19
c@104 20 #include "thread/Thread.h"
c@104 21
c@92 22 class AdaptiveSpectrogram : public Vamp::Plugin
c@92 23 {
c@92 24 public:
c@92 25 AdaptiveSpectrogram(float inputSampleRate);
c@92 26 virtual ~AdaptiveSpectrogram();
c@92 27
c@92 28 bool initialise(size_t channels, size_t stepSize, size_t blockSize);
c@92 29 void reset();
c@92 30
c@92 31 InputDomain getInputDomain() const { return TimeDomain; }
c@92 32
c@92 33 std::string getIdentifier() const;
c@92 34 std::string getName() const;
c@92 35 std::string getDescription() const;
c@92 36 std::string getMaker() const;
c@92 37 int getPluginVersion() const;
c@92 38 std::string getCopyright() const;
c@92 39
c@92 40 size_t getPreferredStepSize() const;
c@92 41 size_t getPreferredBlockSize() const;
c@92 42
c@92 43 ParameterList getParameterDescriptors() const;
c@92 44 float getParameter(std::string id) const;
c@92 45 void setParameter(std::string id, float value);
c@92 46
c@92 47 OutputList getOutputDescriptors() const;
c@92 48
c@92 49 FeatureSet process(const float *const *inputBuffers,
c@92 50 Vamp::RealTime timestamp);
c@92 51
c@92 52 FeatureSet getRemainingFeatures();
c@92 53
c@92 54 protected:
c@92 55 int m_w;
c@92 56 int m_n;
c@92 57
c@100 58 struct Spectrogram
c@100 59 {
c@100 60 int resolution;
c@100 61 int width;
c@100 62 double **data;
c@100 63
c@100 64 Spectrogram(int r, int w) :
c@100 65 resolution(r), width(w) {
c@100 66 data = new double *[width];
c@100 67 for (int i = 0; i < width; ++i) data[i] = new double[resolution];
c@100 68 }
c@100 69
c@100 70 ~Spectrogram() {
c@100 71 for (int i = 0; i < width; ++i) delete[] data[i];
c@100 72 delete[] data;
c@100 73 }
c@100 74 };
c@100 75
c@100 76 struct Spectrograms
c@100 77 {
c@100 78 int minres;
c@100 79 int maxres;
c@100 80 int n;
c@100 81 Spectrogram **spectrograms;
c@100 82
c@100 83 Spectrograms(int mn, int mx, int widthofmax) :
c@100 84 minres(mn), maxres(mx) {
c@100 85 n = log2(maxres/minres) + 1;
c@100 86 spectrograms = new Spectrogram *[n];
c@100 87 int r = mn;
c@100 88 for (int i = 0; i < n; ++i) {
c@100 89 spectrograms[i] = new Spectrogram(r, widthofmax * (mx / r));
c@100 90 r = r * 2;
c@100 91 }
c@100 92 }
c@100 93 ~Spectrograms() {
c@100 94 for (int i = 0; i < n; ++i) {
c@100 95 delete spectrograms[i];
c@100 96 }
c@100 97 delete[] spectrograms;
c@100 98 }
c@100 99 };
c@100 100
c@100 101 struct Cutting
c@100 102 {
c@100 103 enum Cut { Horizontal, Vertical, Finished };
c@100 104 Cut cut;
c@100 105 Cutting *first;
c@100 106 Cutting *second;
c@100 107 double cost;
c@100 108 double value;
c@100 109
c@100 110 ~Cutting() {
c@100 111 delete first;
c@100 112 delete second;
c@100 113 }
c@100 114 };
c@100 115
c@105 116 class FFTThread : public AsynchronousTask
c@104 117 {
c@104 118 public:
c@107 119 FFTThread(int w) :
c@107 120 m_window(HanningWindow, w) {
c@106 121 m_w = w;
c@106 122 m_fft = new FFTReal(m_w);
c@106 123 m_rin = new double[m_w];
c@106 124 m_rout = new double[m_w];
c@106 125 m_iout = new double[m_w];
c@106 126 }
c@106 127 ~FFTThread() {
c@106 128 delete[] m_rin;
c@106 129 delete[] m_rout;
c@106 130 delete[] m_iout;
c@106 131 delete m_fft;
c@106 132 }
c@106 133
c@106 134 int getW() const { return m_w; }
c@105 135
c@105 136 void calculate(const float *timeDomain, Spectrograms &s,
c@106 137 int res, int maxwidth) {
c@105 138 m_in = timeDomain;
c@105 139 m_s = &s;
c@105 140 m_res = res;
c@105 141 m_maxwid = maxwidth;
c@105 142 startTask();
c@105 143 }
c@105 144
c@105 145 void await() {
c@105 146 awaitTask();
c@105 147 }
c@105 148
c@105 149 protected:
c@105 150 void performTask() {
c@105 151 for (int i = 0; i < m_maxwid / m_w; ++i) {
c@105 152 int origin = m_maxwid/4 - m_w/4; // for 50% overlap
c@105 153 for (int j = 0; j < m_w; ++j) {
c@107 154 m_rin[j] = m_in[j];
c@105 155 }
c@107 156 m_window.cut(m_rin);
c@106 157 m_fft->process(false, m_rin, m_rout, m_iout);
c@105 158 for (int j = 0; j < m_w/2; ++j) {
c@105 159 int k = j+1; // include Nyquist but not DC
c@106 160 double mag = sqrt(m_rout[k] * m_rout[k] +
c@106 161 m_iout[k] * m_iout[k]);
c@105 162 double scaled = mag / (m_w/2);
c@105 163 m_s->spectrograms[m_res]->data[i][j] = scaled;
c@105 164 }
c@105 165 }
c@105 166 }
c@105 167
c@105 168 private:
c@107 169 Window<double> m_window;
c@106 170 FFTReal *m_fft;
c@105 171 const float *m_in;
c@106 172 double *m_rin;
c@106 173 double *m_rout;
c@106 174 double *m_iout;
c@105 175 Spectrograms *m_s;
c@105 176 int m_res;
c@105 177 int m_w;
c@105 178 int m_maxwid;
c@105 179 };
c@105 180
c@106 181 typedef std::map<int, FFTThread *> FFTMap;
c@106 182 FFTMap m_fftThreads;
c@105 183
c@105 184 class CutThread : public AsynchronousTask
c@105 185 {
c@105 186 public:
c@105 187 CutThread(const AdaptiveSpectrogram *as) : m_as(as), m_result(0) { }
c@104 188 ~CutThread() { }
c@105 189
c@104 190 void cut(const Spectrograms &s, int res, int x, int y, int h) {
c@104 191 m_s = &s;
c@104 192 m_res = res;
c@104 193 m_x = x;
c@104 194 m_y = y;
c@104 195 m_h = h;
c@105 196 startTask();
c@104 197 }
c@104 198
c@104 199 Cutting *get() {
c@105 200 awaitTask();
c@105 201 return m_result;
c@104 202 }
c@104 203
c@104 204 protected:
c@105 205 void performTask() {
c@105 206 m_result = m_as->cut(*m_s, m_res, m_x, m_y, m_h);
c@104 207 }
c@104 208
c@105 209 private:
c@104 210 const AdaptiveSpectrogram *m_as;
c@104 211 const Spectrograms *m_s;
c@104 212 int m_res;
c@104 213 int m_x;
c@104 214 int m_y;
c@104 215 int m_h;
c@104 216 Cutting *m_result;
c@104 217 };
c@105 218
c@104 219 mutable std::vector<CutThread *> m_cutThreads;//!!! mutable blargh
c@104 220
c@104 221 ///!!! Mutex m_threadMutex;
c@104 222 mutable bool m_first; //!!! gross
c@104 223
c@104 224 double xlogx(double x) const {
c@104 225 if (x == 0.0) return 0.0;
c@104 226 else return x * log(x);
c@104 227 }
c@104 228
c@104 229 double cost(const Spectrogram &s, int x, int y) const {
c@100 230 return xlogx(s.data[x][y]);
c@100 231 }
c@100 232
c@104 233 double value(const Spectrogram &s, int x, int y) const {
c@100 234 return s.data[x][y];
c@100 235 }
c@100 236
c@104 237 Cutting *cut(const Spectrograms &, int res, int x, int y, int h) const;
c@100 238
c@104 239 void getSubCuts(const Spectrograms &, int res, int x, int y, int h,
c@104 240 Cutting *&top, Cutting *&bottom,
c@104 241 Cutting *&left, Cutting *&right) const;
c@100 242
c@104 243 void printCutting(Cutting *, std::string) const;
c@104 244
c@104 245 void assemble(const Spectrograms &, const Cutting *,
c@104 246 std::vector<std::vector<float> > &,
c@104 247 int x, int y, int w, int h) const;
c@104 248 };
c@92 249
c@92 250
c@92 251 #endif