Mercurial > hg > constant-q-cpp
view test/TestCQFrequency.cpp @ 144:88b8d34bfc77
Small rearrangement
| author | Chris Cannam <c.cannam@qmul.ac.uk> |
|---|---|
| date | Tue, 20 May 2014 12:38:13 +0100 |
| parents | 9bf76fc43844 |
| children |
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/* -*- c-basic-offset: 4 indent-tabs-mode: nil -*- vi:set ts=8 sts=4 sw=4: */ #include "cq/CQSpectrogram.h" #include "dsp/Window.h" #include <cmath> #include <vector> #include <iostream> using std::vector; using std::cerr; using std::endl; #define BOOST_TEST_DYN_LINK #define BOOST_TEST_MAIN #include <boost/test/unit_test.hpp> BOOST_AUTO_TEST_SUITE(TestCQFrequency) // The principle here is to feed a single windowed sinusoid into a // small CQ transform and check that the output has its peak bin at // the correct frequency. // Set up fs/2 = 50, frequency range 10 -> 40 i.e. 2 octaves, fixed // duration of 2 seconds static const double sampleRate = 100; static const double cqmin = 11.8921; static const double cqmax = 40; static const double bpo = 4; static const int duration = sampleRate * 2; // Threshold below which to ignore a column completely static const double threshold = 0.08; int binForFrequency(double freq) { int bin = (bpo * 2) - round(bpo * log2(freq / cqmin)) - 1; return bin; } void checkCQFreqColumn(int i, vector<double> column, double freq, CQSpectrogram::Interpolation interp) { double maxval = 0.0; int maxidx = -1; int height = column.size(); int nonZeroHeight = ((i % 2 == 1) ? height/2 : height); for (int j = 0; j < nonZeroHeight; ++j) { if (j == 0 || column[j] > maxval) { maxval = column[j]; maxidx = j; } } int expected = binForFrequency(freq); if (maxval < threshold) { return; // ignore these columns at start and end } else if (expected < nonZeroHeight && maxidx != expected) { cerr << "ERROR: In column " << i << " with interpolation " << interp << ", maximum value for frequency " << freq << "\n found at index " << maxidx << " (expected index " << expected << ")" << endl; cerr << "column contains: "; for (int j = 0; j < height; ++j) { cerr << column[j] << " "; } cerr << endl; BOOST_CHECK_EQUAL(maxidx, expected); } } void testCQFrequencyWith(CQParameters params, CQSpectrogram::Interpolation interp, double freq) { CQSpectrogram cq(params, interp); BOOST_CHECK_EQUAL(cq.getBinsPerOctave(), bpo); BOOST_CHECK_EQUAL(cq.getOctaves(), 2); BOOST_CHECK_CLOSE(cq.getBinFrequency(0), 40, 1e-10); BOOST_CHECK_CLOSE(cq.getBinFrequency(4), 20, 1e-10); BOOST_CHECK_CLOSE(cq.getBinFrequency(7), cqmin, 1e-3); vector<double> input; for (int i = 0; i < duration; ++i) { input.push_back(sin((i * 2 * M_PI * freq) / sampleRate)); } Window<double>(HanningWindow, duration).cut(input.data()); CQSpectrogram::RealBlock output = cq.process(input); CQSpectrogram::RealBlock rest = cq.getRemainingOutput(); output.insert(output.end(), rest.begin(), rest.end()); BOOST_CHECK_EQUAL(output[0].size(), cq.getBinsPerOctave() * cq.getOctaves()); for (int i = 0; i < int(output.size()); ++i) { checkCQFreqColumn(i, output[i], freq, interp); } } void testCQFrequency(double freq) { vector<CQSpectrogram::Interpolation> interpolationTypes; interpolationTypes.push_back(CQSpectrogram::InterpolateZeros); interpolationTypes.push_back(CQSpectrogram::InterpolateHold); interpolationTypes.push_back(CQSpectrogram::InterpolateLinear); for (int k = 0; k < int(interpolationTypes.size()); ++k) { CQSpectrogram::Interpolation interp = interpolationTypes[k]; CQParameters params(sampleRate, cqmin, cqmax, bpo); testCQFrequencyWith(params, interp, freq); } } BOOST_AUTO_TEST_CASE(freq_11) { testCQFrequency(11); } BOOST_AUTO_TEST_CASE(freq_17) { testCQFrequency(17); } BOOST_AUTO_TEST_CASE(freq_24) { testCQFrequency(24); } BOOST_AUTO_TEST_CASE(freq_27) { testCQFrequency(27); } BOOST_AUTO_TEST_CASE(freq_33) { testCQFrequency(33); } BOOST_AUTO_TEST_CASE(freq_40) { testCQFrequency(40); } BOOST_AUTO_TEST_SUITE_END()