Mercurial > hg > svcore
view data/fft/FFTMemoryCache.cpp @ 537:3cc4b7cd2aa5
* Merge from one-fftdataserver-per-fftmodel branch. This bit of
reworking (which is not described very accurately by the title of
the branch) turns the MatrixFile object into something that either
reads or writes, but not both, and separates the FFT file cache
reader and writer implementations separately. This allows the
FFT data server to have a single thread owning writers and one reader
per "customer" thread, and for all locking to be vastly simplified
and concentrated in the data server alone (because none of the
classes it makes use of is used in more than one thread at a time).
The result is faster and more trustworthy code.
| author | Chris Cannam |
|---|---|
| date | Tue, 27 Jan 2009 13:25:10 +0000 |
| parents | 115f60df1e4d |
| children | 1469caaa8e67 |
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/* -*- c-basic-offset: 4 indent-tabs-mode: nil -*- vi:set ts=8 sts=4 sw=4: */ /* Sonic Visualiser An audio file viewer and annotation editor. Centre for Digital Music, Queen Mary, University of London. This file copyright 2006 Chris Cannam. This program is free software; you can redistribute it and/or modify it under the terms of the GNU General Public License as published by the Free Software Foundation; either version 2 of the License, or (at your option) any later version. See the file COPYING included with this distribution for more information. */ #include "FFTMemoryCache.h" #include "system/System.h" #include <iostream> #include <cstdlib> //#define DEBUG_FFT_MEMORY_CACHE 1 FFTMemoryCache::FFTMemoryCache(FFTCache::StorageType storageType, size_t width, size_t height) : m_width(width), m_height(height), m_magnitude(0), m_phase(0), m_fmagnitude(0), m_fphase(0), m_freal(0), m_fimag(0), m_factor(0), m_storageType(storageType) { #ifdef DEBUG_FFT_MEMORY_CACHE std::cerr << "FFTMemoryCache[" << this << "]::FFTMemoryCache (type " << m_storageType << "), size " << m_width << "x" << m_height << std::endl; #endif initialise(); } FFTMemoryCache::~FFTMemoryCache() { #ifdef DEBUG_FFT_MEMORY_CACHE std::cerr << "FFTMemoryCache[" << this << "]::~FFTMemoryCache" << std::endl; #endif for (size_t i = 0; i < m_width; ++i) { if (m_magnitude && m_magnitude[i]) free(m_magnitude[i]); if (m_phase && m_phase[i]) free(m_phase[i]); if (m_fmagnitude && m_fmagnitude[i]) free(m_fmagnitude[i]); if (m_fphase && m_fphase[i]) free(m_fphase[i]); if (m_freal && m_freal[i]) free(m_freal[i]); if (m_fimag && m_fimag[i]) free(m_fimag[i]); } if (m_magnitude) free(m_magnitude); if (m_phase) free(m_phase); if (m_fmagnitude) free(m_fmagnitude); if (m_fphase) free(m_fphase); if (m_freal) free(m_freal); if (m_fimag) free(m_fimag); if (m_factor) free(m_factor); } void FFTMemoryCache::initialise() { Profiler profiler("FFTMemoryCache::initialise"); size_t width = m_width, height = m_height; #ifdef DEBUG_FFT_MEMORY_CACHE std::cerr << "FFTMemoryCache[" << this << "]::initialise(" << width << "x" << height << " = " << width*height << ")" << std::endl; #endif if (m_storageType == FFTCache::Compact) { initialise(m_magnitude); initialise(m_phase); } else if (m_storageType == FFTCache::Polar) { initialise(m_fmagnitude); initialise(m_fphase); } else { initialise(m_freal); initialise(m_fimag); } m_colset.resize(width); m_factor = (float *)realloc(m_factor, width * sizeof(float)); m_width = width; m_height = height; #ifdef DEBUG_FFT_MEMORY_CACHE std::cerr << "done, width = " << m_width << " height = " << m_height << std::endl; #endif } void FFTMemoryCache::initialise(uint16_t **&array) { array = (uint16_t **)malloc(m_width * sizeof(uint16_t *)); if (!array) throw std::bad_alloc(); MUNLOCK(array, m_width * sizeof(uint16_t *)); for (size_t i = 0; i < m_width; ++i) { array[i] = (uint16_t *)malloc(m_height * sizeof(uint16_t)); if (!array[i]) throw std::bad_alloc(); MUNLOCK(array[i], m_height * sizeof(uint16_t)); } } void FFTMemoryCache::initialise(float **&array) { array = (float **)malloc(m_width * sizeof(float *)); if (!array) throw std::bad_alloc(); MUNLOCK(array, m_width * sizeof(float *)); for (size_t i = 0; i < m_width; ++i) { array[i] = (float *)malloc(m_height * sizeof(float)); if (!array[i]) throw std::bad_alloc(); MUNLOCK(array[i], m_height * sizeof(float)); } } void FFTMemoryCache::setColumnAt(size_t x, float *mags, float *phases, float factor) { Profiler profiler("FFTMemoryCache::setColumnAt: from polar"); setNormalizationFactor(x, factor); if (m_storageType == FFTCache::Rectangular) { Profiler subprof("FFTMemoryCache::setColumnAt: polar to cart"); for (size_t y = 0; y < m_height; ++y) { m_freal[x][y] = mags[y] * cosf(phases[y]); m_fimag[x][y] = mags[y] * sinf(phases[y]); } } else { for (size_t y = 0; y < m_height; ++y) { setMagnitudeAt(x, y, mags[y]); setPhaseAt(x, y, phases[y]); } } m_colsetMutex.lock(); m_colset.set(x); m_colsetMutex.unlock(); } void FFTMemoryCache::setColumnAt(size_t x, float *reals, float *imags) { Profiler profiler("FFTMemoryCache::setColumnAt: from cart"); float max = 0.0; switch (m_storageType) { case FFTCache::Rectangular: for (size_t y = 0; y < m_height; ++y) { m_freal[x][y] = reals[y]; m_fimag[x][y] = imags[y]; float mag = sqrtf(reals[y] * reals[y] + imags[y] * imags[y]); if (mag > max) max = mag; } break; case FFTCache::Compact: case FFTCache::Polar: { Profiler subprof("FFTMemoryCache::setColumnAt: cart to polar"); for (size_t y = 0; y < m_height; ++y) { float mag = sqrtf(reals[y] * reals[y] + imags[y] * imags[y]); float phase = atan2f(imags[y], reals[y]); reals[y] = mag; imags[y] = phase; if (mag > max) max = mag; } break; } }; if (m_storageType == FFTCache::Rectangular) { m_factor[x] = max; m_colsetMutex.lock(); m_colset.set(x); m_colsetMutex.unlock(); } else { setColumnAt(x, reals, imags, max); } } size_t FFTMemoryCache::getCacheSize(size_t width, size_t height, FFTCache::StorageType type) { size_t sz = 0; switch (type) { case FFTCache::Compact: sz = (height * 2 + 1) * width * sizeof(uint16_t); case FFTCache::Polar: case FFTCache::Rectangular: sz = (height * 2 + 1) * width * sizeof(float); } return sz; }