annotate transform/BeatDetectionFunctionTransform.cpp @ 34:aaf73f7309f2

* Add "Export Audio File" option * Make note layer align in frequency with any spectrogram layer on the same view (if it's set to frequency mode) * Start to implement mouse editing for ranges of points by dragging the selection * First scrappy attempt at a vertical scale for time value layer
author Chris Cannam
date Mon, 27 Feb 2006 17:34:41 +0000
parents d86891498eef
children 39ae3dee27b9
rev   line source
Chris@0 1 /* -*- c-basic-offset: 4 -*- vi:set ts=8 sts=4 sw=4: */
Chris@0 2
Chris@0 3 /*
Chris@0 4 A waveform viewer and audio annotation editor.
Chris@2 5 Chris Cannam, Queen Mary University of London, 2005-2006
Chris@0 6
Chris@0 7 This is experimental software. Not for distribution.
Chris@0 8 */
Chris@0 9
Chris@0 10 #include "BeatDetectionFunctionTransform.h"
Chris@0 11
Chris@0 12 #include "model/DenseTimeValueModel.h"
Chris@0 13 #include "model/SparseTimeValueModel.h"
Chris@0 14
Chris@0 15 #include <iostream>
Chris@0 16 #include "dsp/onsets/DetectionFunction.h"
Chris@0 17 #include "dsp/tempotracking/TempoTrack.h"
Chris@0 18
Chris@0 19
Chris@0 20 BeatDetectionFunctionTransform::BeatDetectionFunctionTransform(Model *inputModel) :
Chris@0 21 Transform(inputModel)
Chris@0 22 {
Chris@0 23 m_output = new SparseTimeValueModel(inputModel->getSampleRate(), 1,
Chris@0 24 0.0, 0.0, false);
Chris@0 25 }
Chris@0 26
Chris@0 27 BeatDetectionFunctionTransform::~BeatDetectionFunctionTransform()
Chris@0 28 {
Chris@0 29 // parent does it all
Chris@0 30 }
Chris@0 31
Chris@0 32 TransformName
Chris@0 33 BeatDetectionFunctionTransform::getName()
Chris@0 34 {
Chris@0 35 return tr("Beat Detection Function");
Chris@0 36 }
Chris@0 37
Chris@0 38 void
Chris@0 39 BeatDetectionFunctionTransform::run()
Chris@0 40 {
Chris@0 41 SparseTimeValueModel *output = getOutput();
Chris@0 42 DenseTimeValueModel *input = getInput();
Chris@0 43 if (!input) {
Chris@0 44 std::cerr << "BeatDetectionFunctionTransform::run: WARNING: Input model is not conformable to DenseTimeValueModel" << std::endl;
Chris@0 45 return;
Chris@0 46 }
Chris@0 47
Chris@0 48 DFConfig config;
Chris@0 49
Chris@0 50 config.DFType = DF_COMPLEXSD;
Chris@0 51
Chris@0 52 // Step resolution for the detection function in seconds
Chris@0 53 config.stepSecs = 0.01161;
Chris@0 54
Chris@0 55 // Step resolution for the detection function in samples
Chris@0 56 config.stepSize = (unsigned int)floor((double)input->getSampleRate() *
Chris@0 57 config.stepSecs );
Chris@0 58
Chris@0 59 config.frameLength = 2 * config.stepSize;
Chris@0 60
Chris@0 61 unsigned int stepSize = config.stepSize;
Chris@0 62 unsigned int frameLength = config.frameLength;
Chris@0 63
Chris@0 64 output->setResolution(stepSize);
Chris@0 65
Chris@0 66 //Tempo Tracking Configuration Parameters
Chris@0 67 TTParams ttparams;
Chris@0 68
Chris@0 69 // Low Pass filter coefficients for detection function smoothing
Chris@0 70 double* aCoeffs = new double[3];
Chris@0 71 double* bCoeffs = new double[3];
Chris@0 72
Chris@0 73 aCoeffs[ 0 ] = 1;
Chris@0 74 aCoeffs[ 1 ] = -0.5949;
Chris@0 75 aCoeffs[ 2 ] = 0.2348;
Chris@0 76 bCoeffs[ 0 ] = 0.1600;
Chris@0 77 bCoeffs[ 1 ] = 0.3200;
Chris@0 78 bCoeffs[ 2 ] = 0.1600;
Chris@0 79
Chris@0 80 ttparams.winLength = 512;
Chris@0 81 ttparams.lagLength = 128;
Chris@0 82 ttparams.LPOrd = 2;
Chris@0 83 ttparams.LPACoeffs = aCoeffs;
Chris@0 84 ttparams.LPBCoeffs = bCoeffs;
Chris@0 85 ttparams.alpha = 9;
Chris@0 86 ttparams.WinT.post = 8;
Chris@0 87 ttparams.WinT.pre = 7;
Chris@0 88
Chris@0 89 ////////////////////////////////////////////////////////////
Chris@0 90 // DetectionFunction
Chris@0 91 ////////////////////////////////////////////////////////////
Chris@0 92 // Instantiate and configure detection function object
Chris@0 93
Chris@0 94 DetectionFunction df(config);
Chris@0 95
Chris@0 96 size_t origin = input->getStartFrame();
Chris@0 97 size_t frameCount = input->getEndFrame() - origin;
Chris@0 98 size_t blocks = (frameCount / stepSize);
Chris@0 99 if (blocks * stepSize < frameCount) ++blocks;
Chris@0 100
Chris@0 101 double *buffer = new double[frameLength];
Chris@0 102
Chris@0 103 // DF output with causal extension
Chris@0 104 unsigned int clen = blocks + ttparams.winLength;
Chris@0 105 double *dfOutput = new double[clen];
Chris@0 106
Chris@0 107 std::cerr << "Running beat detection function at step size " << stepSize << "..." << std::endl;
Chris@0 108
Chris@0 109 for (size_t i = 0; i < clen; ++i) {
Chris@0 110
Chris@0 111 // std::cerr << "block " << i << "/" << clen << std::endl;
Chris@0 112 // std::cerr << ".";
Chris@0 113
Chris@0 114 if (i < blocks) {
Chris@0 115 size_t got = input->getValues(-1, //!!! needs to come from parent layer -- which is not supposed to be in scope at this point
Chris@0 116 origin + i * stepSize,
Chris@0 117 origin + i * stepSize + frameLength,
Chris@0 118 buffer);
Chris@0 119 while (got < frameLength) buffer[got++] = 0.0;
Chris@0 120 dfOutput[i] = df.process(buffer);
Chris@0 121 } else {
Chris@0 122 dfOutput[i] = 0.0;
Chris@0 123 }
Chris@0 124
Chris@0 125 output->addPoint(SparseTimeValueModel::Point
Chris@0 126 (i * stepSize, dfOutput[i],
Chris@0 127 QString("%1").arg(dfOutput[i])));
Chris@0 128 // m_w->m_bdf->setCompletion(i * 99 / clen);
Chris@0 129 output->setCompletion(i * 99 / clen);
Chris@0 130
Chris@0 131 if (m_deleting) {
Chris@0 132 delete [] buffer;
Chris@0 133 delete [] dfOutput;
Chris@0 134 delete [] aCoeffs;
Chris@0 135 delete [] bCoeffs;
Chris@0 136 return;
Chris@0 137 }
Chris@0 138 }
Chris@0 139
Chris@0 140 output->setCompletion(100);
Chris@0 141 }
Chris@0 142
Chris@0 143 DenseTimeValueModel *
Chris@0 144 BeatDetectionFunctionTransform::getInput()
Chris@0 145 {
Chris@0 146 return dynamic_cast<DenseTimeValueModel *>(getInputModel());
Chris@0 147 }
Chris@0 148
Chris@0 149 SparseTimeValueModel *
Chris@0 150 BeatDetectionFunctionTransform::getOutput()
Chris@0 151 {
Chris@0 152 return static_cast<SparseTimeValueModel *>(getOutputModel());
Chris@0 153 }
Chris@0 154