Mercurial > hg > qm-dsp
view dsp/onsets/DetectionFunction.cpp @ 272:330c2e11f8a9
* Build fixes for gcc 4.3.2
* _Maybe_, but probably not, fix crash in tempo tracker... let's see how
we get on
| author | Chris Cannam <c.cannam@qmul.ac.uk> |
|---|---|
| date | Mon, 10 Nov 2008 14:01:55 +0000 |
| parents | a98dd8ec96f8 |
| children | 5bec06ecc88a |
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/* -*- c-basic-offset: 4 indent-tabs-mode: nil -*- vi:set ts=8 sts=4 sw=4: */ /* QM DSP Library Centre for Digital Music, Queen Mary, University of London. This file copyright 2005-2006 Christian Landone. All rights reserved. */ #include "DetectionFunction.h" #include <cstring> ////////////////////////////////////////////////////////////////////// // Construction/Destruction ////////////////////////////////////////////////////////////////////// DetectionFunction::DetectionFunction( DFConfig Config ) : m_window(0) { m_magHistory = NULL; m_phaseHistory = NULL; m_phaseHistoryOld = NULL; m_magPeaks = NULL; initialise( Config ); } DetectionFunction::~DetectionFunction() { deInitialise(); } void DetectionFunction::initialise( DFConfig Config ) { m_dataLength = Config.frameLength; m_halfLength = m_dataLength/2; m_DFType = Config.DFType; m_stepSecs = Config.stepSecs; m_stepSize = Config.stepSize; m_whiten = Config.adaptiveWhitening; m_whitenRelaxCoeff = Config.whiteningRelaxCoeff; m_whitenFloor = Config.whiteningFloor; if (m_whitenRelaxCoeff < 0) m_whitenRelaxCoeff = 0.9997; if (m_whitenFloor < 0) m_whitenFloor = 0.01; m_magHistory = new double[ m_halfLength ]; memset(m_magHistory,0, m_halfLength*sizeof(double)); m_phaseHistory = new double[ m_halfLength ]; memset(m_phaseHistory,0, m_halfLength*sizeof(double)); m_phaseHistoryOld = new double[ m_halfLength ]; memset(m_phaseHistoryOld,0, m_halfLength*sizeof(double)); m_magPeaks = new double[ m_halfLength ]; memset(m_magPeaks,0, m_halfLength*sizeof(double)); m_phaseVoc = new PhaseVocoder; m_DFWindowedFrame = new double[ m_dataLength ]; m_magnitude = new double[ m_halfLength ]; m_thetaAngle = new double[ m_halfLength ]; m_window = new Window<double>(HanningWindow, m_dataLength); } void DetectionFunction::deInitialise() { delete [] m_magHistory ; delete [] m_phaseHistory ; delete [] m_phaseHistoryOld ; delete [] m_magPeaks ; delete m_phaseVoc; delete [] m_DFWindowedFrame; delete [] m_magnitude; delete [] m_thetaAngle; delete m_window; } double DetectionFunction::process( double *TDomain ) { m_window->cut( TDomain, m_DFWindowedFrame ); m_phaseVoc->process( m_dataLength, m_DFWindowedFrame, m_magnitude, m_thetaAngle ); if (m_whiten) whiten(); return runDF(); } double DetectionFunction::process( double *magnitudes, double *phases ) { for (size_t i = 0; i < m_halfLength; ++i) { m_magnitude[i] = magnitudes[i]; m_thetaAngle[i] = phases[i]; } if (m_whiten) whiten(); return runDF(); } void DetectionFunction::whiten() { for (unsigned int i = 0; i < m_halfLength; ++i) { double m = m_magnitude[i]; if (m < m_magPeaks[i]) { m = m + (m_magPeaks[i] - m) * m_whitenRelaxCoeff; } if (m < m_whitenFloor) m = m_whitenFloor; m_magPeaks[i] = m; m_magnitude[i] /= m; } } double DetectionFunction::runDF() { double retVal = 0; switch( m_DFType ) { case DF_HFC: retVal = HFC( m_halfLength, m_magnitude); break; case DF_SPECDIFF: retVal = specDiff( m_halfLength, m_magnitude); break; case DF_PHASEDEV: retVal = phaseDev( m_halfLength, m_thetaAngle); break; case DF_COMPLEXSD: retVal = complexSD( m_halfLength, m_magnitude, m_thetaAngle); break; case DF_BROADBAND: retVal = broadband( m_halfLength, m_magnitude); break; } return retVal; } double DetectionFunction::HFC(unsigned int length, double *src) { unsigned int i; double val = 0; for( i = 0; i < length; i++) { val += src[ i ] * ( i + 1); } return val; } double DetectionFunction::specDiff(unsigned int length, double *src) { unsigned int i; double val = 0.0; double temp = 0.0; double diff = 0.0; for( i = 0; i < length; i++) { temp = fabs( (src[ i ] * src[ i ]) - (m_magHistory[ i ] * m_magHistory[ i ]) ); diff= sqrt(temp); // (See note in phaseDev below.) val += diff; m_magHistory[ i ] = src[ i ]; } return val; } double DetectionFunction::phaseDev(unsigned int length, double *srcPhase) { unsigned int i; double tmpPhase = 0; double tmpVal = 0; double val = 0; double dev = 0; for( i = 0; i < length; i++) { tmpPhase = (srcPhase[ i ]- 2*m_phaseHistory[ i ]+m_phaseHistoryOld[ i ]); dev = MathUtilities::princarg( tmpPhase ); // A previous version of this code only counted the value here // if the magnitude exceeded 0.1. My impression is that // doesn't greatly improve the results for "loud" music (so // long as the peak picker is reasonably sophisticated), but // does significantly damage its ability to work with quieter // music, so I'm removing it and counting the result always. // Same goes for the spectral difference measure above. tmpVal = fabs(dev); val += tmpVal ; m_phaseHistoryOld[ i ] = m_phaseHistory[ i ] ; m_phaseHistory[ i ] = srcPhase[ i ]; } return val; } double DetectionFunction::complexSD(unsigned int length, double *srcMagnitude, double *srcPhase) { unsigned int i; double val = 0; double tmpPhase = 0; double tmpReal = 0; double tmpImag = 0; double dev = 0; ComplexData meas = ComplexData( 0, 0 ); ComplexData j = ComplexData( 0, 1 ); for( i = 0; i < length; i++) { tmpPhase = (srcPhase[ i ]- 2*m_phaseHistory[ i ]+m_phaseHistoryOld[ i ]); dev= MathUtilities::princarg( tmpPhase ); meas = m_magHistory[i] - ( srcMagnitude[ i ] * exp( j * dev) ); tmpReal = real( meas ); tmpImag = imag( meas ); val += sqrt( (tmpReal * tmpReal) + (tmpImag * tmpImag) ); m_phaseHistoryOld[ i ] = m_phaseHistory[ i ] ; m_phaseHistory[ i ] = srcPhase[ i ]; m_magHistory[ i ] = srcMagnitude[ i ]; } return val; } double DetectionFunction::broadband(unsigned int length, double *src) { double val = 0; for (unsigned int i = 0; i < length; ++i) { double sqrmag = src[i] * src[i]; if (m_magHistory[i] > 0.0) { double diff = 10.0 * log10(sqrmag / m_magHistory[i]); if (diff > m_dbRise) val = val + 1; } m_magHistory[i] = sqrmag; } return val; } double* DetectionFunction::getSpectrumMagnitude() { return m_magnitude; }