Mercurial > hg > vamp-tempogram

--- a/NoveltyCurveProcessor.cpp	Thu Sep 04 14:12:03 2014 +0100
+++ b/NoveltyCurveProcessor.cpp	Thu Sep 04 14:33:36 2014 +0100
@@ -37,9 +37,11 @@
     for (unsigned int band = 1; band < m_numberOfBands; band++){
         float lowFreq = 500*pow(2.5, (int)band-1);
         m_pBandBoundaries[band] = m_fftLength*lowFreq/m_samplingFrequency;
+	if (m_pBandBoundaries[band] > (int)m_blockSize) {
+	    m_pBandBoundaries[band] = m_blockSize;
+	}
     }
     m_pBandBoundaries[m_numberOfBands] = m_blockSize;
-
     m_pBandSum = new float [m_numberOfBands];
 }
--- a/SpectrogramProcessor.h	Thu Sep 04 14:12:03 2014 +0100
+++ b/SpectrogramProcessor.h	Thu Sep 04 14:33:36 2014 +0100
@@ -11,7 +11,7 @@
 #include <vector>
 #include <vamp-sdk/FFT.h>
 #include <cmath>
-#include <stddef.h>
+#include <cstddef>

 typedef std::vector <std::vector<float> > Spectrogram;
 typedef std::vector <std::vector<float> > SpectrogramTransposed;
--- a/TempogramPlugin.cpp	Thu Sep 04 14:12:03 2014 +0100
+++ b/TempogramPlugin.cpp	Thu Sep 04 14:33:36 2014 +0100
@@ -526,7 +526,18 @@
             float sum = 0;

             for (int j = 0; j < m_cyclicTempogramNumberOfOctaves; j++){
-                sum += tempogramDFT[block][logBins[j][i]];
+
+		if (block >= tempogramDFT.size()) {
+		    cerr << "ERROR: at block = " << block << ", i = " << i << ", j = " << j << ": block " << block << " >= tempogramDFT.size() " << tempogramDFT.size() << endl;
+		} else if (j > logBins.size()) {
+		    cerr << "ERROR: at block = " << block << ", i = " << i << ", j = " << j << ": j " << j << " >= logBins.size() " << logBins.size() << endl;
+		} else if (i > logBins[j].size()) {
+		    cerr << "ERROR: at block = " << block << ", i = " << i << ", j = " << j << ": i " << i << " >= logBins[j].size() " << logBins[j].size() << endl;
+		} else if (logBins[j][i] >= tempogramDFT[block].size()) {
+		    cerr << "ERROR: at block = " << block << ", i = " << i << ", j = " << j << ": logBins[j][i] " << logBins[j][i] << " >= tempogramDFT[block].size() " << tempogramDFT[block].size() << endl;
+		} else {
+		    sum += tempogramDFT[block][logBins[j][i]];
+		}
             }
             cyclicTempogramFeature.values.push_back(sum/m_cyclicTempogramNumberOfOctaves);
             assert(!isnan(cyclicTempogramFeature.values.back()));
@@ -601,9 +612,29 @@
     float tempogramInputSampleRate = (float)m_inputSampleRate/m_inputStepSize;
     m_tempogramMinBin = (max((int)floor(((m_tempogramMinBPM/60)/tempogramInputSampleRate)*m_tempogramFftLength), 0));
     m_tempogramMaxBin = (min((int)ceil(((m_tempogramMaxBPM/60)/tempogramInputSampleRate)*m_tempogramFftLength), (int)(m_tempogramFftLength/2)));
+
+    if (m_tempogramMaxBin < m_tempogramMinBin) {
+	cerr << "At audio sample rate " << m_inputSampleRate
+	     << ", tempogram sample rate " << tempogramInputSampleRate
+	     << " with bpm range " << m_tempogramMinBPM << " -> "
+	     << m_tempogramMaxBPM << ", min bin = " << m_tempogramMinBin
+	     << " > max bin " << m_tempogramMaxBin
+	     << ": can't proceed, failing initialise" << endl;
+	return false;
+    }

     m_tempogramMinLag = max((int)ceil((60/(m_inputStepSize * m_tempogramMaxBPM))*m_inputSampleRate), 0);
     m_tempogramMaxLag = min((int)floor((60/(m_inputStepSize * m_tempogramMinBPM))*m_inputSampleRate), (int)m_tempogramWindowLength);
+
+    if (m_tempogramMaxLag < m_tempogramMinLag) {
+	cerr << "At audio sample rate " << m_inputSampleRate
+	     << ", tempogram sample rate " << tempogramInputSampleRate
+	     << " with bpm range " << m_tempogramMinBPM << " -> "
+	     << m_tempogramMaxBPM << ", min bin = " << m_tempogramMinLag
+	     << " > max bin " << m_tempogramMaxLag
+	     << ": can't proceed, failing initialise" << endl;
+	return false;
+    }

     if (m_tempogramMinBPM > m_cyclicTempogramMinBPM) m_cyclicTempogramMinBPM = m_tempogramMinBPM; //m_cyclicTempogram can't be less than default = 30
     float cyclicTempogramMaxBPM = 480;