#include "dsp/spectrumvis.h" #include "gui/glspectrum.h" #include "dsp/dspcommands.h" #include "util/messagequeue.h" #define MAX_FFT_SIZE 4096 #ifdef _WIN32 double log2f(double n) { return log(n) / log(2.0); } #endif SpectrumVis::SpectrumVis(GLSpectrum* glSpectrum) : SampleSink(), m_fft(FFTEngine::create()), m_fftBuffer(MAX_FFT_SIZE), m_logPowerSpectrum(MAX_FFT_SIZE), m_fftBufferFill(0), m_glSpectrum(glSpectrum) { handleConfigure(1024, 10, FFTWindow::BlackmanHarris); } SpectrumVis::~SpectrumVis() { delete m_fft; } void SpectrumVis::configure(MessageQueue* msgQueue, int fftSize, int overlapPercent, FFTWindow::Function window) { Message* cmd = DSPConfigureSpectrumVis::create(fftSize, overlapPercent, window); cmd->submit(msgQueue, this); } void SpectrumVis::feed(SampleVector::const_iterator begin, SampleVector::const_iterator end, bool firstOfBurst) { // if no visualisation is set, send the samples to /dev/null if(m_glSpectrum == NULL) return; while(begin < end) { size_t todo = end - begin; size_t samplesNeeded = m_refillSize - m_fftBufferFill; if(todo >= samplesNeeded) { // fill up the buffer std::vector::iterator it = m_fftBuffer.begin() + m_fftBufferFill; for(size_t i = 0; i < samplesNeeded; ++i, ++begin) *it++ = Complex(begin->real() / 32768.0, begin->imag() / 32768.0); // apply fft window (and copy from m_fftBuffer to m_fftIn) m_window.apply(&m_fftBuffer[0], m_fft->in()); // calculate FFT m_fft->transform(); // extract power spectrum and reorder buckets Real ofs = 20.0f * log10f(1.0f / m_fftSize); Real mult = (10.0f / log2f(10.0f)); const Complex* fftOut = m_fft->out(); for(size_t i = 0; i < m_fftSize; i++) { Complex c = fftOut[((i + (m_fftSize >> 1)) & (m_fftSize - 1))]; Real v = c.real() * c.real() + c.imag() * c.imag(); v = mult * log2f(v) + ofs; m_logPowerSpectrum[i] = v; } // send new data to visualisation m_glSpectrum->newSpectrum(m_logPowerSpectrum, m_fftSize); // advance buffer respecting the fft overlap factor std::copy(m_fftBuffer.begin() + m_refillSize, m_fftBuffer.end(), m_fftBuffer.begin()); // start over m_fftBufferFill = m_overlapSize; } else { // not enough samples for FFT - just fill in new data and return for(std::vector::iterator it = m_fftBuffer.begin() + m_fftBufferFill; begin < end; ++begin) *it++ = Complex(begin->real() / 32768.0, begin->imag() / 32768.0); m_fftBufferFill += todo; } } } void SpectrumVis::start() { } void SpectrumVis::stop() { } bool SpectrumVis::handleMessage(Message* message) { if(DSPConfigureSpectrumVis::match(message)) { DSPConfigureSpectrumVis* conf = (DSPConfigureSpectrumVis*)message; handleConfigure(conf->getFFTSize(), conf->getOverlapPercent(), conf->getWindow()); message->completed(); return true; } else { return false; } } void SpectrumVis::handleConfigure(int fftSize, int overlapPercent, FFTWindow::Function window) { if(fftSize > MAX_FFT_SIZE) fftSize = MAX_FFT_SIZE; else if(fftSize < 64) fftSize = 64; if(overlapPercent > 100) m_overlapPercent = 100; else if(overlapPercent < 0) m_overlapPercent = 0; m_fftSize = fftSize; m_overlapPercent = overlapPercent; m_fft->configure(m_fftSize, false); m_window.create(window, m_fftSize); m_overlapSize = (m_fftSize * m_overlapPercent) / 100; m_refillSize = m_fftSize - m_overlapSize; m_fftBufferFill = m_overlapSize; }