TEST (LowPassFilterTest, WorksOnRepetitiveWaves) { // make two sine waves, but this time, several seconds long unsigned int samples = frameRate * 5; KeyFinder::AudioData a; a.setChannels(1); a.setFrameRate(frameRate); a.addToSampleCount(samples); for (unsigned int i = 0; i < samples; i++) { float sample = 0.0; sample += sine_wave(i, highFrequency, frameRate, magnitude); // high freq sample += sine_wave(i, lowFrequency, frameRate, magnitude); // low freq a.setSample(i, sample); // ensure repetition of sine waves is perfect... if (i >= frameRate) { ASSERT_NEAR(a.getSample(i), a.getSample(i - frameRate), tolerance); } } KeyFinder::LowPassFilter* lpf = new KeyFinder::LowPassFilter(filterOrder, frameRate, cornerFrequency, filterFFT); KeyFinder::Workspace w; lpf->filter(a, w); delete lpf; // test for lower wave only for (unsigned int i = 0; i < samples; i++) { float expected = sine_wave(i, lowFrequency, frameRate, magnitude); ASSERT_NEAR(expected, a.getSample(i), tolerance); } }
TEST (AudioDataTest, SampleInitialisation) { KeyFinder::AudioData a; a.addToSampleCount(100); ASSERT_EQ(100, a.getSampleCount()); // init values for (int i = 0; i < 100; i++) { ASSERT_FLOAT_EQ(0.0, a.getSample(i)); } }
TEST (AudioDataTest, DownsamplerInsistsOnMonophonicAudio) { KeyFinder::AudioData a; a.setChannels(2); a.setFrameRate(100); a.addToSampleCount(10); ASSERT_THROW(a.downsample(5), KeyFinder::Exception); a.reduceToMono(); ASSERT_NO_THROW(a.downsample(5)); }
TEST(AudioDataTest, SamplesBasic){ KeyFinder::AudioData a; a.addToSampleCount(100); ASSERT_EQ(100, a.getSampleCount()); // init values for(int i=0; i<100; i++){ ASSERT_EQ(0.0, a.getSample(i)); } a.setSample(0, 10.0); ASSERT_EQ(10.0, a.getSample(0)); }
TEST (AudioDataTest, SampleMutatorBounds) { KeyFinder::AudioData a; a.addToSampleCount(5); ASSERT_THROW(a.getSample(-1), KeyFinder::Exception); ASSERT_THROW(a.getSample(5), KeyFinder::Exception); ASSERT_THROW(a.setSample(-1, 1.0), KeyFinder::Exception); ASSERT_THROW(a.setSample(5, 1.0), KeyFinder::Exception); ASSERT_THROW(a.setSample(0, INFINITY), KeyFinder::Exception); ASSERT_THROW(a.setSample(0, NAN), KeyFinder::Exception); }
TEST (LowPassFilterTest, InsistsOnMonophonicAudio) { KeyFinder::AudioData a; a.setChannels(2); a.setFrameRate(frameRate); a.addToSampleCount(frameRate); KeyFinder::LowPassFilter* lpf = new KeyFinder::LowPassFilter(filterOrder, frameRate, cornerFrequency, filterFFT); KeyFinder::Workspace w; ASSERT_THROW(lpf->filter(a, w), KeyFinder::Exception); a.reduceToMono(); ASSERT_NO_THROW(lpf->filter(a, w)); delete lpf; }
TEST (LowPassFilterTest, InitialisesNullBuffer) { KeyFinder::AudioData a; a.setChannels(1); a.setFrameRate(frameRate); a.addToSampleCount(frameRate); KeyFinder::LowPassFilter* lpf = new KeyFinder::LowPassFilter(filterOrder, frameRate, cornerFrequency, filterFFT); KeyFinder::Workspace w; std::vector<double>* nullPtr = NULL; ASSERT_EQ(nullPtr, w.lpfBuffer); lpf->filter(a, w); ASSERT_NE(nullPtr, w.lpfBuffer); }
TEST (AudioDataTest, MakeMono) { KeyFinder::AudioData a; a.setChannels(2); a.addToSampleCount(20); for (int i = 0; i < 10; i++) { a.setSample(i * 2, 100.0); } a.reduceToMono(); ASSERT_EQ(10, a.getSampleCount()); for (int i = 0; i < 10; i++) { ASSERT_FLOAT_EQ(50.0, a.getSample(i)); } }
TEST (LowPassFilterTest, DoesntAlterAudioMetadata) { KeyFinder::AudioData a; a.setChannels(1); a.setFrameRate(frameRate); a.addToSampleCount(frameRate); KeyFinder::LowPassFilter* lpf = new KeyFinder::LowPassFilter(filterOrder, frameRate, cornerFrequency, filterFFT); KeyFinder::Workspace w; lpf->filter(a, w); delete lpf; ASSERT_EQ(1, a.getChannels()); ASSERT_EQ(frameRate, a.getFrameRate()); ASSERT_EQ(frameRate, a.getSampleCount()); }
TEST (AudioDataTest, DownsamplerResamplesIntegralRelationship) { KeyFinder::AudioData a; a.setChannels(1); a.setFrameRate(100); a.addToSampleCount(10); for (unsigned int i = 0; i < 5; i++) a.setSample(i, 100.0); for (unsigned int i = 5; i < 10; i++) a.setSample(i, 500.0); a.downsample(5); ASSERT_EQ(20, a.getFrameRate()); ASSERT_EQ(2, a.getSampleCount()); ASSERT_FLOAT_EQ(100.0, a.getSample(0)); ASSERT_FLOAT_EQ(500.0, a.getSample(1)); }
TEST (AudioDataTest, DownsamplerResamplesNonintegralRelationship) { KeyFinder::AudioData a; a.setChannels(1); a.setFrameRate(100); a.addToSampleCount(12); for (unsigned int i = 0; i < 5; i++) a.setSample(i, 100.0); for (unsigned int i = 5; i < 10; i++) a.setSample(i, 500.0); for (unsigned int i = 10; i < 12; i++) a.setSample(i, 1000.0); a.downsample(5); ASSERT_EQ(3, a.getSampleCount()); ASSERT_FLOAT_EQ(100.0, a.getSample(0)); ASSERT_FLOAT_EQ(500.0, a.getSample(1)); // this doesn't make total mathematical sense but I'm taking a shortcut for performance ASSERT_FLOAT_EQ(1000.0, a.getSample(2)); }
TEST (LowPassFilterTest, KillsHigherFreqs) { // make a high frequency sine wave, one second long KeyFinder::AudioData a; a.setChannels(1); a.setFrameRate(frameRate); a.addToSampleCount(frameRate); for (unsigned int i = 0; i < frameRate; i++) { a.setSample(i, sine_wave(i, highFrequency, frameRate, magnitude)); } KeyFinder::LowPassFilter* lpf = new KeyFinder::LowPassFilter(filterOrder, frameRate, cornerFrequency, filterFFT); KeyFinder::Workspace w; lpf->filter(a, w); delete lpf; // test for near silence for (unsigned int i = 0; i < frameRate; i++) { ASSERT_NEAR(0.0, a.getSample(i), tolerance); } }
TEST (LowPassFilterTest, MaintainsLowerFreqs) { // make a low frequency sine wave, one second long KeyFinder::AudioData a; a.setChannels(1); a.setFrameRate(frameRate); a.addToSampleCount(frameRate); for (unsigned int i = 0; i < frameRate; i++) { a.setSample(i, sine_wave(i, lowFrequency, frameRate, magnitude)); } KeyFinder::LowPassFilter* lpf = new KeyFinder::LowPassFilter(filterOrder, frameRate, cornerFrequency, filterFFT); KeyFinder::Workspace w; lpf->filter(a, w); delete lpf; // test for near perfect reproduction for (unsigned int i = 0; i < frameRate; i++) { float expected = sine_wave(i, lowFrequency, frameRate, magnitude); ASSERT_NEAR(expected, a.getSample(i), tolerance); } }
TEST (AudioDataTest, Iterators) { KeyFinder::AudioData a; a.setChannels(1); a.setFrameRate(1); a.addToSampleCount(10); a.setSample(0, 10.0); a.setSample(1, 20.0); a.setSample(3, 50.0); a.resetIterators(); // this is required before each use ASSERT_FLOAT_EQ(10.0, a.getSampleAtReadIterator()); a.setSampleAtWriteIterator(15.0); ASSERT_FLOAT_EQ(15.0, a.getSampleAtReadIterator()); a.advanceReadIterator(); a.advanceWriteIterator(); ASSERT_FLOAT_EQ(20.0, a.getSampleAtReadIterator()); a.setSampleAtWriteIterator(25.0); ASSERT_FLOAT_EQ(25.0, a.getSampleAtReadIterator()); a.advanceReadIterator(2); a.advanceWriteIterator(2); ASSERT_FLOAT_EQ(50.0, a.getSampleAtReadIterator()); a.setSampleAtWriteIterator(55.0); ASSERT_FLOAT_EQ(55.0, a.getSampleAtReadIterator()); a.resetIterators(); ASSERT_FLOAT_EQ(15.0, a.getSampleAtReadIterator()); a.setSampleAtWriteIterator(150.0); ASSERT_FLOAT_EQ(150.0, a.getSampleAtReadIterator()); ASSERT_TRUE(a.readIteratorWithinUpperBound()); ASSERT_TRUE(a.writeIteratorWithinUpperBound()); a.advanceReadIterator(10); a.advanceWriteIterator(10); ASSERT_FALSE(a.readIteratorWithinUpperBound()); ASSERT_FALSE(a.writeIteratorWithinUpperBound()); }
TEST(AudioDataTest, Frames){ KeyFinder::AudioData a; a.addToSampleCount(4); ASSERT_THROW(a.getSample(0,0), KeyFinder::Exception); a.setChannels(2); ASSERT_EQ(0.0, a.getSample(0,0)); ASSERT_EQ(0.0, a.getSample(0,1)); ASSERT_THROW(a.getSample(-1, 0), KeyFinder::Exception); ASSERT_THROW(a.getSample(-1, 1), KeyFinder::Exception); ASSERT_THROW(a.getSample( 2, 0), KeyFinder::Exception); ASSERT_THROW(a.getSample( 2, 1), KeyFinder::Exception); ASSERT_THROW(a.getSample( 0,-1), KeyFinder::Exception); ASSERT_THROW(a.getSample( 0, 2), KeyFinder::Exception); a.setSample(0,0, 10.0); ASSERT_EQ(10.0, a.getSample(0,0)); a.setSample(1,0, 20.0); ASSERT_EQ(20.0, a.getSample(2)); }
TEST (AudioDataTest, DownsamplerResamplesSineWave) { unsigned int frameRate = 10000; unsigned int frames = frameRate * 4; float freq = 20; float magnitude = 32768.0; unsigned int factor = 5; KeyFinder::AudioData a; a.setChannels(1); a.setFrameRate(frameRate); a.addToSampleCount(frames); for (unsigned int i = 0; i < frames; i++) a.setSample(i, sine_wave(i, freq, frameRate, magnitude)); a.downsample(factor); unsigned int newFrameRate = frameRate / factor; unsigned int newFrames = frames / factor; ASSERT_EQ(newFrameRate, a.getFrameRate()); ASSERT_EQ(newFrames, a.getSampleCount()); for (unsigned int i = 0; i < newFrames; i++) ASSERT_NEAR(sine_wave(i, freq, newFrameRate, magnitude), a.getSample(i), magnitude * 0.05); }
TEST (LowPassFilterTest, DoesBothAtOnce) { // make two sine waves, one second long KeyFinder::AudioData a; a.setChannels(1); a.setFrameRate(frameRate); a.addToSampleCount(frameRate); for (unsigned int i = 0; i < frameRate; i++) { float sample = 0.0; sample += sine_wave(i, highFrequency, frameRate, magnitude); // high freq sample += sine_wave(i, lowFrequency, frameRate, magnitude); // low freq a.setSample(i, sample); } KeyFinder::LowPassFilter* lpf = new KeyFinder::LowPassFilter(filterOrder, frameRate, cornerFrequency, filterFFT); KeyFinder::Workspace w; lpf->filter(a, w); delete lpf; // test for lower wave only for (unsigned int i = 0; i < frameRate; i++) { float expected = sine_wave(i, lowFrequency, frameRate, magnitude); ASSERT_NEAR(expected, a.getSample(i), tolerance); } }
TEST (AudioDataTest, SampleMutator) { KeyFinder::AudioData a; a.addToSampleCount(1); a.setSample(0, 10.0); ASSERT_FLOAT_EQ(10.0, a.getSample(0)); }
const char* kfinder_get_key(short signed int *samples, unsigned int nb_samples, short unsigned int frame_rate, short unsigned int nb_channels) { // Check input parameter. if ((samples == NULL) || (nb_samples == 0) || (frame_rate == 0) || (nb_channels == 0)) { return ""; } // Build the main computing object. KeyFinder::KeyFinder k; // Build an empty audio object KeyFinder::AudioData a; // Prepare the object for your audio stream a.setFrameRate(frame_rate); a.setChannels(nb_channels); a.addToSampleCount(nb_samples); // Copy your audio into the object (as float). for (unsigned int i = 0; i < nb_samples; i++) { a.setSample(i, (float)samples[i]); } // Run the analysis KeyFinder::key_t r; try { r = k.keyOfAudio(a); } catch(const std::exception& e) { cerr << "libKeyFinder: exception: " << e.what() << endl; return ""; } catch(...) { cerr << "libKeyFinder: unknown exception" << endl; return ""; } // And do something with the result! switch(r) { case KeyFinder::A_MAJOR: return "AM"; case KeyFinder::A_MINOR: return "Am"; case KeyFinder::B_FLAT_MAJOR: return "BbM"; case KeyFinder::B_FLAT_MINOR: return "Bbm"; case KeyFinder::B_MAJOR: return "BM"; case KeyFinder::B_MINOR: return "Bm"; case KeyFinder::C_MAJOR: return "CM"; case KeyFinder::C_MINOR: return "Cm"; case KeyFinder::D_FLAT_MAJOR: return "DbM"; case KeyFinder::D_FLAT_MINOR: return "Dbm"; case KeyFinder::D_MAJOR: return "DM"; case KeyFinder::D_MINOR: return "Dm"; case KeyFinder::E_FLAT_MAJOR: return "EbM"; case KeyFinder::E_FLAT_MINOR: return "Ebm"; case KeyFinder::E_MAJOR: return "EM"; case KeyFinder::E_MINOR: return "Em"; case KeyFinder::F_MAJOR: return "FM"; case KeyFinder::F_MINOR: return "Fm"; case KeyFinder::G_FLAT_MAJOR: return "GbM"; case KeyFinder::G_FLAT_MINOR: return "Gbm"; case KeyFinder::G_MAJOR: return "GM"; case KeyFinder::G_MINOR: return "Gm"; case KeyFinder::A_FLAT_MAJOR: return "AbM"; case KeyFinder::A_FLAT_MINOR: return "Abm"; case KeyFinder::SILENCE: return ""; default: return ""; } }
TEST (AudioDataTest, FrameAccessBeforeChannelsInitialised) { KeyFinder::AudioData a; a.addToSampleCount(4); ASSERT_THROW(a.getSampleByFrame(0, 0), KeyFinder::Exception); }