Mercurial > hg > chp
changeset 1:ab0b04e1c56b
Implement the plugin!
author | Chris Cannam |
---|---|
date | Fri, 07 Mar 2014 15:51:20 +0000 |
parents | f559ab000b67 |
children | ee3cf00cfa4c |
files | ConstrainedHarmonicPeak.cpp ConstrainedHarmonicPeak.h Makefile.inc |
diffstat | 3 files changed, 108 insertions(+), 3 deletions(-) [+] |
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--- a/ConstrainedHarmonicPeak.cpp Fri Mar 07 14:34:50 2014 +0000 +++ b/ConstrainedHarmonicPeak.cpp Fri Mar 07 15:51:20 2014 +0000 @@ -12,7 +12,8 @@ Plugin(inputSampleRate), m_blockSize(0), m_minFreq(0), - m_maxFreq(inputSampleRate/2) + m_maxFreq(inputSampleRate/2), + m_harmonics(5) { } @@ -113,6 +114,17 @@ d.isQuantized = false; list.push_back(d); + d.identifier = "harmonics"; + d.name = "Harmonics"; + d.description = "Maximum number of harmonics to consider"; + d.unit = ""; + d.minValue = 1; + d.maxValue = 20; + d.defaultValue = 5; + d.isQuantized = true; + d.quantizeStep = 1; + list.push_back(d); + return list; } @@ -123,6 +135,8 @@ return m_minFreq; } else if (identifier == "maxfreq") { return m_maxFreq; + } else if (identifier == "harmonics") { + return m_harmonics; } return 0; } @@ -134,6 +148,8 @@ m_minFreq = value; } else if (identifier == "maxfreq") { m_maxFreq = value; + } else if (identifier == "harmonics") { + m_harmonics = int(round(value)); } } @@ -193,11 +209,98 @@ { } +double +ConstrainedHarmonicPeak::findInterpolatedPeak(const double *in, + int peakbin, + int bins) +{ + // duplicate with SimpleCepstrum plugin + // after jos, + // https://ccrma.stanford.edu/~jos/sasp/Quadratic_Interpolation_Spectral_Peaks.html + + if (peakbin < 1 || peakbin > bins - 2) { + return peakbin; + } + + double alpha = in[peakbin-1]; + double beta = in[peakbin]; + double gamma = in[peakbin+1]; + + double denom = (alpha - 2*beta + gamma); + + if (denom == 0) { + // flat + return peakbin; + } + + double p = ((alpha - gamma) / denom) / 2.0; + + return double(peakbin) + p; +} + ConstrainedHarmonicPeak::FeatureSet ConstrainedHarmonicPeak::process(const float *const *inputBuffers, Vamp::RealTime timestamp) { FeatureSet fs; + int hs = m_blockSize/2; + + double *mags = new double[hs+1]; + for (int i = 0; i <= hs; ++i) { + mags[i] = sqrtf(inputBuffers[0][i*2] * inputBuffers[0][i*2] + + inputBuffers[0][i*2+1] * inputBuffers[0][i*2+1]); + } + + // bin freq is bin * samplerate / fftsize + + int minbin = int(floor((m_minFreq * m_blockSize) / m_inputSampleRate)); + int maxbin = int(ceil((m_maxFreq * m_blockSize) / m_inputSampleRate)); + if (minbin > hs) minbin = hs; + if (maxbin > hs) maxbin = hs; + if (maxbin <= minbin) return fs; + + double *hps = new double[maxbin - minbin + 1]; + + // HPS in dB after MzHarmonicSpectrum + + for (int bin = minbin; bin <= maxbin; ++bin) { + + int i = bin - minbin; + hps[i] = 1.0; + + int contributing = 0; + + for (int j = 1; j <= m_harmonics; ++j) { + if (j * bin > hs) break; + hps[i] *= mags[j * bin]; + ++contributing; + } + + if (hps[i] <= 0.0) { + hps[i] = -120.0; + } else { + hps[i] = 20.0 / contributing * log10(hps[i]); + } + } + + double maxdb = -120.0; + int maxidx = 0; + for (int i = 0; i <= maxbin - minbin; ++i) { + if (hps[i] > maxdb) { + maxdb = hps[i]; + maxidx = i; + } + } + + double interpolated = findInterpolatedPeak(hps, maxidx, maxbin - minbin + 1); + interpolated = interpolated + minbin; + + double freq = interpolated * m_inputSampleRate / m_blockSize; + + Feature f; + f.values.push_back(freq); + fs[0].push_back(f); + return fs; } @@ -205,7 +308,6 @@ ConstrainedHarmonicPeak::getRemainingFeatures() { FeatureSet fs; - return fs; }