Mercurial > hg > svapp

annotate audioio/IntegerTimeStretcher.cpp @ 33:3e0794460c4e

Find changesets by keywords (author, files, the commit message), revision number or hash, or revset expression.
* Ensure consistent ordering of layer text labels * Fix erroneous SR mismatch warning when adding a wave-file model when no other wave-file model is present (only models that don't assert any particular playback samplerate)
author Chris Cannam
date Thu, 27 Apr 2006 11:49:34 +0000
parents 2eb25a26390f
children 4ed2448582cc
rev   line source
Chris@27 1 /* -*- c-basic-offset: 4 indent-tabs-mode: nil -*- vi:set ts=8 sts=4 sw=4: */
Chris@27 2
Chris@27 3 /*
Chris@27 4 Sonic Visualiser
Chris@27 5 An audio file viewer and annotation editor.
Chris@27 6 Centre for Digital Music, Queen Mary, University of London.
Chris@27 7 This file copyright 2006 Chris Cannam.
Chris@27 8
Chris@27 9 This program is free software; you can redistribute it and/or
Chris@27 10 modify it under the terms of the GNU General Public License as
Chris@27 11 published by the Free Software Foundation; either version 2 of the
Chris@27 12 License, or (at your option) any later version. See the file
Chris@27 13 COPYING included with this distribution for more information.
Chris@27 14 */
Chris@27 15
Chris@27 16 #include "IntegerTimeStretcher.h"
Chris@27 17
Chris@27 18 #include <iostream>
Chris@27 19 #include <cassert>
Chris@27 20
Chris@27 21 //#define DEBUG_INTEGER_TIME_STRETCHER 1
Chris@27 22
Chris@27 23 IntegerTimeStretcher::IntegerTimeStretcher(size_t ratio,
Chris@27 24 size_t maxProcessInputBlockSize,
Chris@27 25 size_t inputIncrement,
Chris@27 26 size_t windowSize,
Chris@27 27 WindowType windowType) :
Chris@27 28 m_ratio(ratio),
Chris@27 29 m_n1(inputIncrement),
Chris@27 30 m_n2(m_n1 * ratio),
Chris@27 31 m_wlen(std::max(windowSize, m_n2 * 2)),
Chris@27 32 m_inbuf(m_wlen),
Chris@27 33 m_outbuf(maxProcessInputBlockSize * ratio)
Chris@27 34 {
Chris@27 35 m_window = new Window<double>(windowType, m_wlen),
Chris@27 36
Chris@27 37 m_time = (fftw_complex *)fftw_malloc(sizeof(fftw_complex) * m_wlen);
Chris@27 38 m_freq = (fftw_complex *)fftw_malloc(sizeof(fftw_complex) * m_wlen);
Chris@27 39 m_dbuf = (double *)fftw_malloc(sizeof(double) * m_wlen);
Chris@27 40
Chris@27 41 m_plan = fftw_plan_dft_1d(m_wlen, m_time, m_freq, FFTW_FORWARD, FFTW_ESTIMATE);
Chris@27 42 m_iplan = fftw_plan_dft_c2r_1d(m_wlen, m_freq, m_dbuf, FFTW_ESTIMATE);
Chris@27 43
Chris@27 44 m_mashbuf = new double[m_wlen];
Chris@27 45 for (int i = 0; i < m_wlen; ++i) {
Chris@27 46 m_mashbuf[i] = 0.0;
Chris@27 47 }
Chris@27 48 }
Chris@27 49
Chris@27 50 IntegerTimeStretcher::~IntegerTimeStretcher()
Chris@27 51 {
Chris@27 52 std::cerr << "IntegerTimeStretcher::~IntegerTimeStretcher" << std::endl;
Chris@27 53
Chris@27 54 fftw_destroy_plan(m_plan);
Chris@27 55 fftw_destroy_plan(m_iplan);
Chris@27 56
Chris@27 57 fftw_free(m_time);
Chris@27 58 fftw_free(m_freq);
Chris@27 59 fftw_free(m_dbuf);
Chris@27 60
Chris@27 61 delete m_window;
Chris@27 62 delete m_mashbuf;
Chris@27 63 }
Chris@27 64
Chris@27 65 size_t
Chris@27 66 IntegerTimeStretcher::getProcessingLatency() const
Chris@27 67 {
Chris@27 68 return getWindowSize() - getInputIncrement();
Chris@27 69 }
Chris@27 70
Chris@27 71 void
Chris@27 72 IntegerTimeStretcher::process(double *input, double *output, size_t samples)
Chris@27 73 {
Chris@27 74 // We need to add samples from input to our internal buffer. When
Chris@27 75 // we have m_windowSize samples in the buffer, we can process it,
Chris@27 76 // move the samples back by m_n1 and write the output onto our
Chris@27 77 // internal output buffer. If we have (samples * ratio) samples
Chris@27 78 // in that, we can write m_n2 of them back to output and return
Chris@27 79 // (otherwise we have to write zeroes).
Chris@27 80
Chris@27 81 // When we process, we write m_wlen to our fixed output buffer
Chris@27 82 // (m_mashbuf). We then pull out the first m_n2 samples from that
Chris@27 83 // buffer, push them into the output ring buffer, and shift
Chris@27 84 // m_mashbuf left by that amount.
Chris@27 85
Chris@27 86 // The processing latency is then m_wlen - m_n2.
Chris@27 87
Chris@27 88 size_t consumed = 0;
Chris@27 89
Chris@27 90 #ifdef DEBUG_INTEGER_TIME_STRETCHER
Chris@27 91 std::cerr << "IntegerTimeStretcher::process(" << samples << ", consumed = " << consumed << "), writable " << m_inbuf.getWriteSpace() <<", readable "<< m_outbuf.getReadSpace() << std::endl;
Chris@27 92 #endif
Chris@27 93
Chris@27 94 while (consumed < samples) {
Chris@27 95
Chris@27 96 size_t writable = m_inbuf.getWriteSpace();
Chris@27 97 writable = std::min(writable, samples - consumed);
Chris@27 98
Chris@27 99 if (writable == 0) {
Chris@27 100 //!!! then what? I don't think this should happen, but
Chris@27 101 std::cerr << "WARNING: IntegerTimeStretcher::process: writable == 0" << std::endl;
Chris@27 102 break;
Chris@27 103 }
Chris@27 104
Chris@27 105 #ifdef DEBUG_INTEGER_TIME_STRETCHER
Chris@27 106 std::cerr << "writing " << writable << " from index " << consumed << " to inbuf, consumed will be " << consumed + writable << std::endl;
Chris@27 107 #endif
Chris@27 108 m_inbuf.write(input + consumed, writable);
Chris@27 109 consumed += writable;
Chris@27 110
Chris@27 111 while (m_inbuf.getReadSpace() >= m_wlen &&
Chris@27 112 m_outbuf.getWriteSpace() >= m_n2) {
Chris@27 113
Chris@27 114 // We know we have at least m_wlen samples available
Chris@27 115 // in m_inbuf. We need to peek m_wlen of them for
Chris@27 116 // processing, and then read m_n1 to advance the read
Chris@27 117 // pointer.
Chris@27 118
Chris@27 119 size_t got = m_inbuf.peek(m_dbuf, m_wlen);
Chris@27 120 assert(got == m_wlen);
Chris@27 121
Chris@27 122 processBlock(m_dbuf, m_mashbuf);
Chris@27 123
Chris@27 124 #ifdef DEBUG_INTEGER_TIME_STRETCHER
Chris@27 125 std::cerr << "writing first " << m_n2 << " from mashbuf, skipping " << m_n1 << " on inbuf " << std::endl;
Chris@27 126 #endif
Chris@27 127 m_inbuf.skip(m_n1);
Chris@27 128 m_outbuf.write(m_mashbuf, m_n2);
Chris@27 129
Chris@27 130 for (size_t i = 0; i < m_wlen - m_n2; ++i) {
Chris@27 131 m_mashbuf[i] = m_mashbuf[i + m_n2];
Chris@27 132 }
Chris@27 133 for (size_t i = m_wlen - m_n2; i < m_wlen; ++i) {
Chris@27 134 m_mashbuf[i] = 0.0f;
Chris@27 135 }
Chris@27 136 }
Chris@27 137
Chris@27 138 // std::cerr << "WARNING: IntegerTimeStretcher::process: writespace not enough for output increment (" << m_outbuf.getWriteSpace() << " < " << m_n2 << ")" << std::endl;
Chris@27 139 // }
Chris@27 140
Chris@27 141 #ifdef DEBUG_INTEGER_TIME_STRETCHER
Chris@27 142 std::cerr << "loop ended: inbuf read space " << m_inbuf.getReadSpace() << ", outbuf write space " << m_outbuf.getWriteSpace() << std::endl;
Chris@27 143 #endif
Chris@27 144 }
Chris@27 145
Chris@27 146 if (m_outbuf.getReadSpace() < samples * m_ratio) {
Chris@27 147 std::cerr << "WARNING: IntegerTimeStretcher::process: not enough data (yet?) (" << m_outbuf.getReadSpace() << " < " << (samples * m_ratio) << ")" << std::endl;
Chris@27 148 size_t fill = samples * m_ratio - m_outbuf.getReadSpace();
Chris@27 149 for (size_t i = 0; i < fill; ++i) {
Chris@27 150 output[i] = 0.0;
Chris@27 151 }
Chris@27 152 m_outbuf.read(output + fill, m_outbuf.getReadSpace());
Chris@27 153 } else {
Chris@27 154 #ifdef DEBUG_INTEGER_TIME_STRETCHER
Chris@27 155 std::cerr << "enough data - writing " << samples * m_ratio << " from outbuf" << std::endl;
Chris@27 156 #endif
Chris@27 157 m_outbuf.read(output, samples * m_ratio);
Chris@27 158 }
Chris@27 159
Chris@27 160 #ifdef DEBUG_INTEGER_TIME_STRETCHER
Chris@27 161 std::cerr << "IntegerTimeStretcher::process returning" << std::endl;
Chris@27 162 #endif
Chris@27 163 }
Chris@27 164
Chris@27 165 void
Chris@27 166 IntegerTimeStretcher::processBlock(double *buf, double *out)
Chris@27 167 {
Chris@27 168 size_t i;
Chris@27 169
Chris@27 170 // buf contains m_wlen samples; out contains enough space for
Chris@27 171 // m_wlen * ratio samples (we mix into out, rather than replacing)
Chris@27 172
Chris@27 173 #ifdef DEBUG_INTEGER_TIME_STRETCHER
Chris@27 174 std::cerr << "IntegerTimeStretcher::processBlock" << std::endl;
Chris@27 175 #endif
Chris@27 176
Chris@27 177 m_window->cut(buf);
Chris@27 178
Chris@27 179 for (i = 0; i < m_wlen/2; ++i) {
Chris@27 180 double temp = buf[i];
Chris@27 181 buf[i] = buf[i + m_wlen/2];
Chris@27 182 buf[i + m_wlen/2] = temp;
Chris@27 183 }
Chris@27 184
Chris@27 185 for (i = 0; i < m_wlen; ++i) {
Chris@27 186 m_time[i][0] = buf[i];
Chris@27 187 m_time[i][1] = 0.0;
Chris@27 188 }
Chris@27 189
Chris@27 190 fftw_execute(m_plan); // m_time -> m_freq
Chris@27 191
Chris@27 192 for (i = 0; i < m_wlen; ++i) {
Chris@27 193
Chris@27 194 double mag = sqrt(m_freq[i][0] * m_freq[i][0] +
Chris@27 195 m_freq[i][1] * m_freq[i][1]);
Chris@27 196
Chris@27 197 double phase = atan2(m_freq[i][1], m_freq[i][0]);
Chris@27 198
Chris@27 199 phase = phase * m_ratio;
Chris@27 200
Chris@27 201 double real = mag * cos(phase);
Chris@27 202 double imag = mag * sin(phase);
Chris@27 203 m_freq[i][0] = real;
Chris@27 204 m_freq[i][1] = imag;
Chris@27 205 }
Chris@27 206
Chris@27 207 fftw_execute(m_iplan); // m_freq -> in, inverse fft
Chris@27 208
Chris@27 209 for (i = 0; i < m_wlen/2; ++i) {
Chris@27 210 double temp = buf[i] / m_wlen;
Chris@27 211 buf[i] = buf[i + m_wlen/2] / m_wlen;
Chris@27 212 buf[i + m_wlen/2] = temp;
Chris@27 213 }
Chris@27 214
Chris@27 215 m_window->cut(buf);
Chris@27 216
Chris@27 217 int div = m_wlen / m_n2;
Chris@27 218 if (div > 1) div /= 2;
Chris@27 219 for (i = 0; i < m_wlen; ++i) {
Chris@27 220 buf[i] /= div;
Chris@27 221 }
Chris@27 222
Chris@27 223 for (i = 0; i < m_wlen; ++i) {
Chris@27 224 out[i] += buf[i];
Chris@27 225 }
Chris@27 226 }