Mercurial > hg > svcore
view data/fft/FFTDataServer.cpp @ 856:8593a3fe50ac tonioni
Merge from branch "tonioni_multi_transform"
author | Chris Cannam |
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date | Wed, 04 Dec 2013 18:29:53 +0000 |
parents | 2d53205f70cd |
children | 166e3fc1e962 |
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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 and QMUL. 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 "FFTDataServer.h" #include "FFTFileCacheReader.h" #include "FFTFileCacheWriter.h" #include "FFTMemoryCache.h" #include "model/DenseTimeValueModel.h" #include "system/System.h" #include "base/StorageAdviser.h" #include "base/Exceptions.h" #include "base/Profiler.h" #include "base/Thread.h" // for debug mutex locker #include <QWriteLocker> //#define DEBUG_FFT_SERVER 1 //#define DEBUG_FFT_SERVER_FILL 1 #ifdef DEBUG_FFT_SERVER_FILL #ifndef DEBUG_FFT_SERVER #define DEBUG_FFT_SERVER 1 #endif #endif FFTDataServer::ServerMap FFTDataServer::m_servers; FFTDataServer::ServerQueue FFTDataServer::m_releasedServers; QMutex FFTDataServer::m_serverMapMutex; FFTDataServer * FFTDataServer::getInstance(const DenseTimeValueModel *model, int channel, WindowType windowType, size_t windowSize, size_t windowIncrement, size_t fftSize, bool polar, StorageAdviser::Criteria criteria, size_t fillFromColumn) { QString n = generateFileBasename(model, channel, windowType, windowSize, windowIncrement, fftSize, polar); FFTDataServer *server = 0; MutexLocker locker(&m_serverMapMutex, "FFTDataServer::getInstance::m_serverMapMutex"); if ((server = findServer(n))) { return server; } QString npn = generateFileBasename(model, channel, windowType, windowSize, windowIncrement, fftSize, !polar); if ((server = findServer(npn))) { return server; } try { server = new FFTDataServer(n, model, channel, windowType, windowSize, windowIncrement, fftSize, polar, criteria, fillFromColumn); } catch (InsufficientDiscSpace) { delete server; server = 0; } if (server) { m_servers[n] = ServerCountPair(server, 1); } return server; } FFTDataServer * FFTDataServer::getFuzzyInstance(const DenseTimeValueModel *model, int channel, WindowType windowType, size_t windowSize, size_t windowIncrement, size_t fftSize, bool polar, StorageAdviser::Criteria criteria, size_t fillFromColumn) { // Fuzzy matching: // // -- if we're asked for polar and have non-polar, use it (and // vice versa). This one is vital, and we do it for non-fuzzy as // well (above). // // -- if we're asked for an instance with a given fft size and we // have one already with a multiple of that fft size but the same // window size and type (and model), we can draw the results from // it (e.g. the 1st, 2nd, 3rd etc bins of a 512-sample FFT are the // same as the the 1st, 5th, 9th etc of a 2048-sample FFT of the // same window plus zero padding). // // -- if we're asked for an instance with a given window type and // size and fft size and we have one already the same but with a // smaller increment, we can draw the results from it (provided // our increment is a multiple of its) // // The FFTModel knows how to interpret these things. In // both cases we require that the larger one is a power-of-two // multiple of the smaller (e.g. even though in principle you can // draw the results at increment 256 from those at increment 768 // or 1536, the model doesn't support this). { MutexLocker locker(&m_serverMapMutex, "FFTDataServer::getFuzzyInstance::m_serverMapMutex"); ServerMap::iterator best = m_servers.end(); int bestdist = -1; for (ServerMap::iterator i = m_servers.begin(); i != m_servers.end(); ++i) { FFTDataServer *server = i->second.first; if (server->getModel() == model && (server->getChannel() == channel || model->getChannelCount() == 1) && server->getWindowType() == windowType && server->getWindowSize() == windowSize && server->getWindowIncrement() <= windowIncrement && server->getFFTSize() >= fftSize) { if ((windowIncrement % server->getWindowIncrement()) != 0) continue; int ratio = windowIncrement / server->getWindowIncrement(); bool poweroftwo = true; while (ratio > 1) { if (ratio & 0x1) { poweroftwo = false; break; } ratio >>= 1; } if (!poweroftwo) continue; if ((server->getFFTSize() % fftSize) != 0) continue; ratio = server->getFFTSize() / fftSize; while (ratio > 1) { if (ratio & 0x1) { poweroftwo = false; break; } ratio >>= 1; } if (!poweroftwo) continue; int distance = 0; if (server->getPolar() != polar) distance += 1; distance += ((windowIncrement / server->getWindowIncrement()) - 1) * 15; distance += ((server->getFFTSize() / fftSize) - 1) * 10; if (server->getFillCompletion() < 50) distance += 100; #ifdef DEBUG_FFT_SERVER std::cerr << "FFTDataServer::getFuzzyInstance: Distance for server " << server << " is " << distance << ", best is " << bestdist << std::endl; #endif if (bestdist == -1 || distance < bestdist) { bestdist = distance; best = i; } } } if (bestdist >= 0) { FFTDataServer *server = best->second.first; #ifdef DEBUG_FFT_SERVER std::cerr << "FFTDataServer::getFuzzyInstance: We like server " << server << " (with distance " << bestdist << ")" << std::endl; #endif claimInstance(server, false); return server; } } // Nothing found, make a new one return getInstance(model, channel, windowType, windowSize, windowIncrement, fftSize, polar, criteria, fillFromColumn); } FFTDataServer * FFTDataServer::findServer(QString n) { #ifdef DEBUG_FFT_SERVER std::cerr << "FFTDataServer::findServer(\"" << n << "\")" << std::endl; #endif if (m_servers.find(n) != m_servers.end()) { FFTDataServer *server = m_servers[n].first; #ifdef DEBUG_FFT_SERVER std::cerr << "FFTDataServer::findServer(\"" << n << "\"): found " << server << std::endl; #endif claimInstance(server, false); return server; } #ifdef DEBUG_FFT_SERVER std::cerr << "FFTDataServer::findServer(\"" << n << "\"): not found" << std::endl; #endif return 0; } void FFTDataServer::claimInstance(FFTDataServer *server) { claimInstance(server, true); } void FFTDataServer::claimInstance(FFTDataServer *server, bool needLock) { MutexLocker locker(needLock ? &m_serverMapMutex : 0, "FFTDataServer::claimInstance::m_serverMapMutex"); #ifdef DEBUG_FFT_SERVER std::cerr << "FFTDataServer::claimInstance(" << server << ")" << std::endl; #endif for (ServerMap::iterator i = m_servers.begin(); i != m_servers.end(); ++i) { if (i->second.first == server) { for (ServerQueue::iterator j = m_releasedServers.begin(); j != m_releasedServers.end(); ++j) { if (*j == server) { #ifdef DEBUG_FFT_SERVER std::cerr << "FFTDataServer::claimInstance: found in released server list, removing from it" << std::endl; #endif m_releasedServers.erase(j); break; } } ++i->second.second; #ifdef DEBUG_FFT_SERVER std::cerr << "FFTDataServer::claimInstance: new refcount is " << i->second.second << std::endl; #endif return; } } cerr << "ERROR: FFTDataServer::claimInstance: instance " << server << " unknown!" << endl; } void FFTDataServer::releaseInstance(FFTDataServer *server) { releaseInstance(server, true); } void FFTDataServer::releaseInstance(FFTDataServer *server, bool needLock) { MutexLocker locker(needLock ? &m_serverMapMutex : 0, "FFTDataServer::releaseInstance::m_serverMapMutex"); #ifdef DEBUG_FFT_SERVER std::cerr << "FFTDataServer::releaseInstance(" << server << ")" << std::endl; #endif // -- if ref count > 0, decrement and return // -- if the instance hasn't been used at all, delete it immediately // -- if fewer than N instances (N = e.g. 3) remain with zero refcounts, // leave them hanging around // -- if N instances with zero refcounts remain, delete the one that // was last released first // -- if we run out of disk space when allocating an instance, go back // and delete the spare N instances before trying again // -- have an additional method to indicate that a model has been // destroyed, so that we can delete all of its fft server instances for (ServerMap::iterator i = m_servers.begin(); i != m_servers.end(); ++i) { if (i->second.first == server) { if (i->second.second == 0) { cerr << "ERROR: FFTDataServer::releaseInstance(" << server << "): instance not allocated" << endl; } else if (--i->second.second == 0) { /*!!! if (server->m_lastUsedCache == -1) { // never used #ifdef DEBUG_FFT_SERVER std::cerr << "FFTDataServer::releaseInstance: instance " << server << " has never been used, erasing" << std::endl; #endif delete server; m_servers.erase(i); } else { */ #ifdef DEBUG_FFT_SERVER std::cerr << "FFTDataServer::releaseInstance: instance " << server << " no longer in use, marking for possible collection" << std::endl; #endif bool found = false; for (ServerQueue::iterator j = m_releasedServers.begin(); j != m_releasedServers.end(); ++j) { if (*j == server) { cerr << "ERROR: FFTDataServer::releaseInstance(" << server << "): server is already in " << "released servers list" << endl; found = true; } } if (!found) m_releasedServers.push_back(server); server->suspend(); purgeLimbo(); //!!! } } else { #ifdef DEBUG_FFT_SERVER std::cerr << "FFTDataServer::releaseInstance: instance " << server << " now has refcount " << i->second.second << std::endl; #endif } return; } } cerr << "ERROR: FFTDataServer::releaseInstance(" << server << "): " << "instance not found" << endl; } void FFTDataServer::purgeLimbo(int maxSize) { #ifdef DEBUG_FFT_SERVER std::cerr << "FFTDataServer::purgeLimbo(" << maxSize << "): " << m_releasedServers.size() << " candidates" << std::endl; #endif while (int(m_releasedServers.size()) > maxSize) { FFTDataServer *server = *m_releasedServers.begin(); bool found = false; #ifdef DEBUG_FFT_SERVER std::cerr << "FFTDataServer::purgeLimbo: considering candidate " << server << std::endl; #endif for (ServerMap::iterator i = m_servers.begin(); i != m_servers.end(); ++i) { if (i->second.first == server) { found = true; if (i->second.second > 0) { cerr << "ERROR: FFTDataServer::purgeLimbo: Server " << server << " is in released queue, but still has non-zero refcount " << i->second.second << endl; // ... so don't delete it break; } #ifdef DEBUG_FFT_SERVER std::cerr << "FFTDataServer::purgeLimbo: looks OK, erasing it" << std::endl; #endif m_servers.erase(i); delete server; break; } } if (!found) { cerr << "ERROR: FFTDataServer::purgeLimbo: Server " << server << " is in released queue, but not in server map!" << endl; delete server; } m_releasedServers.pop_front(); } #ifdef DEBUG_FFT_SERVER std::cerr << "FFTDataServer::purgeLimbo(" << maxSize << "): " << m_releasedServers.size() << " remain" << std::endl; #endif } void FFTDataServer::modelAboutToBeDeleted(Model *model) { MutexLocker locker(&m_serverMapMutex, "FFTDataServer::modelAboutToBeDeleted::m_serverMapMutex"); #ifdef DEBUG_FFT_SERVER std::cerr << "FFTDataServer::modelAboutToBeDeleted(" << model << ")" << std::endl; #endif for (ServerMap::iterator i = m_servers.begin(); i != m_servers.end(); ++i) { FFTDataServer *server = i->second.first; if (server->getModel() == model) { #ifdef DEBUG_FFT_SERVER std::cerr << "FFTDataServer::modelAboutToBeDeleted: server is " << server << std::endl; #endif if (i->second.second > 0) { cerr << "WARNING: FFTDataServer::modelAboutToBeDeleted: Model " << model << " (\"" << model->objectName() << "\") is about to be deleted, but is still being referred to by FFT server " << server << " with non-zero refcount " << i->second.second << endl; server->suspendWrites(); return; } for (ServerQueue::iterator j = m_releasedServers.begin(); j != m_releasedServers.end(); ++j) { if (*j == server) { #ifdef DEBUG_FFT_SERVER std::cerr << "FFTDataServer::modelAboutToBeDeleted: erasing from released servers" << std::endl; #endif m_releasedServers.erase(j); break; } } #ifdef DEBUG_FFT_SERVER std::cerr << "FFTDataServer::modelAboutToBeDeleted: erasing server" << std::endl; #endif m_servers.erase(i); delete server; return; } } } FFTDataServer::FFTDataServer(QString fileBaseName, const DenseTimeValueModel *model, int channel, WindowType windowType, size_t windowSize, size_t windowIncrement, size_t fftSize, bool polar, StorageAdviser::Criteria criteria, size_t fillFromColumn) : m_fileBaseName(fileBaseName), m_model(model), m_channel(channel), m_windower(windowType, windowSize), m_windowSize(windowSize), m_windowIncrement(windowIncrement), m_fftSize(fftSize), m_polar(polar), m_width(0), m_height(0), m_cacheWidth(0), m_cacheWidthPower(0), m_cacheWidthMask(0), m_criteria(criteria), m_fftInput(0), m_exiting(false), m_suspended(true), //!!! or false? m_fillThread(0) { #ifdef DEBUG_FFT_SERVER cerr << "FFTDataServer(" << this << " [" << (void *)QThread::currentThreadId() << "])::FFTDataServer" << endl; #endif //!!! end is not correct until model finished reading -- what to do??? size_t start = m_model->getStartFrame(); size_t end = m_model->getEndFrame(); m_width = (end - start) / m_windowIncrement + 1; m_height = m_fftSize / 2 + 1; // DC == 0, Nyquist == fftsize/2 #ifdef DEBUG_FFT_SERVER cerr << "FFTDataServer(" << this << "): dimensions are " << m_width << "x" << m_height << endl; #endif size_t maxCacheSize = 20 * 1024 * 1024; size_t columnSize = m_height * sizeof(fftsample) * 2 + sizeof(fftsample); if (m_width * columnSize < maxCacheSize * 2) m_cacheWidth = m_width; else m_cacheWidth = maxCacheSize / columnSize; #ifdef DEBUG_FFT_SERVER cerr << "FFTDataServer(" << this << "): cache width nominal " << m_cacheWidth << ", actual "; #endif int bits = 0; while (m_cacheWidth > 1) { m_cacheWidth >>= 1; ++bits; } m_cacheWidthPower = bits + 1; m_cacheWidth = 2; while (bits) { m_cacheWidth <<= 1; --bits; } m_cacheWidthMask = m_cacheWidth - 1; #ifdef DEBUG_FFT_SERVER cerr << m_cacheWidth << " (power " << m_cacheWidthPower << ", mask " << m_cacheWidthMask << ")" << endl; #endif if (m_criteria == StorageAdviser::NoCriteria) { // assume "spectrogram" criteria for polar ffts, and "feature // extraction" criteria for rectangular ones. if (m_polar) { m_criteria = StorageAdviser::Criteria (StorageAdviser::SpeedCritical | StorageAdviser::LongRetentionLikely); } else { m_criteria = StorageAdviser::Criteria (StorageAdviser::PrecisionCritical); } } for (size_t i = 0; i <= m_width / m_cacheWidth; ++i) { m_caches.push_back(0); } m_fftInput = (fftsample *) fftf_malloc(fftSize * sizeof(fftsample)); m_fftOutput = (fftf_complex *) fftf_malloc((fftSize/2 + 1) * sizeof(fftf_complex)); m_workbuffer = (float *) fftf_malloc((fftSize+2) * sizeof(float)); m_fftPlan = fftf_plan_dft_r2c_1d(m_fftSize, m_fftInput, m_fftOutput, FFTW_MEASURE); if (!m_fftPlan) { cerr << "ERROR: fftf_plan_dft_r2c_1d(" << m_windowSize << ") failed!" << endl; throw(0); } m_fillThread = new FillThread(*this, fillFromColumn); } FFTDataServer::~FFTDataServer() { #ifdef DEBUG_FFT_SERVER cerr << "FFTDataServer(" << this << " [" << (void *)QThread::currentThreadId() << "])::~FFTDataServer()" << endl; #endif m_suspended = false; m_exiting = true; m_condition.wakeAll(); if (m_fillThread) { m_fillThread->wait(); delete m_fillThread; } // MutexLocker locker(&m_writeMutex, // "FFTDataServer::~FFTDataServer::m_writeMutex"); QMutexLocker mlocker(&m_fftBuffersLock); QWriteLocker wlocker(&m_cacheVectorLock); for (CacheVector::iterator i = m_caches.begin(); i != m_caches.end(); ++i) { if (*i) { delete *i; } } deleteProcessingData(); } void FFTDataServer::deleteProcessingData() { #ifdef DEBUG_FFT_SERVER cerr << "FFTDataServer(" << this << " [" << (void *)QThread::currentThreadId() << "]): deleteProcessingData" << endl; #endif if (m_fftInput) { fftf_destroy_plan(m_fftPlan); fftf_free(m_fftInput); fftf_free(m_fftOutput); fftf_free(m_workbuffer); } m_fftInput = 0; } void FFTDataServer::suspend() { #ifdef DEBUG_FFT_SERVER cerr << "FFTDataServer(" << this << " [" << (void *)QThread::currentThreadId() << "]): suspend" << endl; #endif Profiler profiler("FFTDataServer::suspend", false); QMutexLocker locker(&m_fftBuffersLock); m_suspended = true; } void FFTDataServer::suspendWrites() { #ifdef DEBUG_FFT_SERVER cerr << "FFTDataServer(" << this << " [" << (void *)QThread::currentThreadId() << "]): suspendWrites" << endl; #endif Profiler profiler("FFTDataServer::suspendWrites", false); m_suspended = true; } void FFTDataServer::resume() { #ifdef DEBUG_FFT_SERVER cerr << "FFTDataServer(" << this << " [" << (void *)QThread::currentThreadId() << "]): resume" << endl; #endif Profiler profiler("FFTDataServer::resume", false); m_suspended = false; if (m_fillThread) { if (m_fillThread->isFinished()) { delete m_fillThread; m_fillThread = 0; deleteProcessingData(); } else if (!m_fillThread->isRunning()) { m_fillThread->start(); } else { m_condition.wakeAll(); } } } void FFTDataServer::getStorageAdvice(size_t w, size_t h, bool &memoryCache, bool &compactCache) { int cells = w * h; int minimumSize = (cells / 1024) * sizeof(uint16_t); // kb int maximumSize = (cells / 1024) * sizeof(float); // kb // We don't have a compact rectangular representation, and compact // of course is never precision-critical bool canCompact = true; if ((m_criteria & StorageAdviser::PrecisionCritical) || !m_polar) { canCompact = false; minimumSize = maximumSize; // don't use compact } StorageAdviser::Recommendation recommendation; try { recommendation = StorageAdviser::recommend(m_criteria, minimumSize, maximumSize); } catch (InsufficientDiscSpace s) { // Delete any unused servers we may have been leaving around // in case we wanted them again purgeLimbo(0); // This time we don't catch InsufficientDiscSpace -- we // haven't allocated anything yet and can safely let the // exception out to indicate to the caller that we can't // handle it. recommendation = StorageAdviser::recommend(m_criteria, minimumSize, maximumSize); } // cerr << "Recommendation was: " << recommendation << endl; memoryCache = false; if ((recommendation & StorageAdviser::UseMemory) || (recommendation & StorageAdviser::PreferMemory)) { memoryCache = true; } compactCache = canCompact && (recommendation & StorageAdviser::ConserveSpace); #ifdef DEBUG_FFT_SERVER cerr << "FFTDataServer: memory cache = " << memoryCache << ", compact cache = " << compactCache << endl; cerr << "Width " << w << " of " << m_width << ", height " << h << ", size " << w * h << endl; #endif } bool FFTDataServer::makeCache(int c) { // Creating the cache could take a significant amount of time. We // don't want to block readers on m_cacheVectorLock while this is // happening, but we do want to block any further calls to // makeCache. So we use this lock solely to serialise this // particular function -- it isn't used anywhere else. QMutexLocker locker(&m_cacheCreationMutex); m_cacheVectorLock.lockForRead(); if (m_caches[c]) { // someone else must have created the cache between our // testing for it and taking the mutex m_cacheVectorLock.unlock(); return true; } m_cacheVectorLock.unlock(); // Now m_cacheCreationMutex is held, but m_cacheVectorLock is not // -- readers can proceed, but callers to this function will block CacheBlock *cb = new CacheBlock; QString name = QString("%1-%2").arg(m_fileBaseName).arg(c); size_t width = m_cacheWidth; if (c * m_cacheWidth + width > m_width) { width = m_width - c * m_cacheWidth; } bool memoryCache = false; bool compactCache = false; getStorageAdvice(width, m_height, memoryCache, compactCache); bool success = false; if (memoryCache) { try { cb->memoryCache = new FFTMemoryCache (compactCache ? FFTCache::Compact : m_polar ? FFTCache::Polar : FFTCache::Rectangular, width, m_height); success = true; } catch (std::bad_alloc) { delete cb->memoryCache; cb->memoryCache = 0; cerr << "WARNING: Memory allocation failed when creating" << " FFT memory cache no. " << c << " of " << width << "x" << m_height << " (of total width " << m_width << "): falling back to disc cache" << endl; memoryCache = false; } } if (!memoryCache) { try { cb->fileCacheWriter = new FFTFileCacheWriter (name, compactCache ? FFTCache::Compact : m_polar ? FFTCache::Polar : FFTCache::Rectangular, width, m_height); success = true; } catch (std::exception &e) { delete cb->fileCacheWriter; cb->fileCacheWriter = 0; cerr << "ERROR: Failed to construct disc cache for FFT data: " << e.what() << endl; throw; } } m_cacheVectorLock.lockForWrite(); m_caches[c] = cb; m_cacheVectorLock.unlock(); return success; } bool FFTDataServer::makeCacheReader(int c) { // preconditions: m_caches[c] exists and contains a file writer; // m_cacheVectorLock is not locked by this thread #ifdef DEBUG_FFT_SERVER std::cerr << "FFTDataServer::makeCacheReader(" << c << ")" << std::endl; #endif QThread *me = QThread::currentThread(); QWriteLocker locker(&m_cacheVectorLock); CacheBlock *cb(m_caches.at(c)); if (!cb || !cb->fileCacheWriter) return false; try { cb->fileCacheReader[me] = new FFTFileCacheReader(cb->fileCacheWriter); } catch (std::exception &e) { delete cb->fileCacheReader[me]; cb->fileCacheReader.erase(me); cerr << "ERROR: Failed to construct disc cache reader for FFT data: " << e.what() << endl; return false; } // erase a reader that looks like it may no longer going to be // used by this thread for a while (leaving alone the current // and previous cache readers) int deleteCandidate = c - 2; if (deleteCandidate < 0) deleteCandidate = c + 2; if (deleteCandidate >= m_caches.size()) { return true; } cb = m_caches.at(deleteCandidate); if (cb && cb->fileCacheReader.find(me) != cb->fileCacheReader.end()) { #ifdef DEBUG_FFT_SERVER std::cerr << "FFTDataServer::makeCacheReader: Deleting probably unpopular reader " << deleteCandidate << " for this thread (as I create reader " << c << ")" << std::endl; #endif delete cb->fileCacheReader[me]; cb->fileCacheReader.erase(me); } return true; } float FFTDataServer::getMagnitudeAt(size_t x, size_t y) { Profiler profiler("FFTDataServer::getMagnitudeAt", false); if (x >= m_width || y >= m_height) return 0; float val = 0; try { size_t col; FFTCacheReader *cache = getCacheReader(x, col); if (!cache) return 0; if (!cache->haveSetColumnAt(col)) { Profiler profiler("FFTDataServer::getMagnitudeAt: filling"); #ifdef DEBUG_FFT_SERVER std::cerr << "FFTDataServer::getMagnitudeAt: calling fillColumn(" << x << ")" << std::endl; #endif fillColumn(x); } val = cache->getMagnitudeAt(col, y); } catch (std::exception &e) { m_error = e.what(); } return val; } bool FFTDataServer::getMagnitudesAt(size_t x, float *values, size_t minbin, size_t count, size_t step) { Profiler profiler("FFTDataServer::getMagnitudesAt", false); if (x >= m_width) return false; if (minbin >= m_height) minbin = m_height - 1; if (count == 0) count = (m_height - minbin) / step; else if (minbin + count * step > m_height) { count = (m_height - minbin) / step; } try { size_t col; FFTCacheReader *cache = getCacheReader(x, col); if (!cache) return false; if (!cache->haveSetColumnAt(col)) { Profiler profiler("FFTDataServer::getMagnitudesAt: filling"); fillColumn(x); } cache->getMagnitudesAt(col, values, minbin, count, step); } catch (std::exception &e) { m_error = e.what(); return false; } return true; } float FFTDataServer::getNormalizedMagnitudeAt(size_t x, size_t y) { Profiler profiler("FFTDataServer::getNormalizedMagnitudeAt", false); if (x >= m_width || y >= m_height) return 0; float val = 0; try { size_t col; FFTCacheReader *cache = getCacheReader(x, col); if (!cache) return 0; if (!cache->haveSetColumnAt(col)) { Profiler profiler("FFTDataServer::getNormalizedMagnitudeAt: filling"); fillColumn(x); } val = cache->getNormalizedMagnitudeAt(col, y); } catch (std::exception &e) { m_error = e.what(); } return val; } bool FFTDataServer::getNormalizedMagnitudesAt(size_t x, float *values, size_t minbin, size_t count, size_t step) { Profiler profiler("FFTDataServer::getNormalizedMagnitudesAt", false); if (x >= m_width) return false; if (minbin >= m_height) minbin = m_height - 1; if (count == 0) count = (m_height - minbin) / step; else if (minbin + count * step > m_height) { count = (m_height - minbin) / step; } try { size_t col; FFTCacheReader *cache = getCacheReader(x, col); if (!cache) return false; if (!cache->haveSetColumnAt(col)) { Profiler profiler("FFTDataServer::getNormalizedMagnitudesAt: filling"); fillColumn(x); } for (size_t i = 0; i < count; ++i) { values[i] = cache->getNormalizedMagnitudeAt(col, i * step + minbin); } } catch (std::exception &e) { m_error = e.what(); return false; } return true; } float FFTDataServer::getMaximumMagnitudeAt(size_t x) { Profiler profiler("FFTDataServer::getMaximumMagnitudeAt", false); if (x >= m_width) return 0; float val = 0; try { size_t col; FFTCacheReader *cache = getCacheReader(x, col); if (!cache) return 0; if (!cache->haveSetColumnAt(col)) { Profiler profiler("FFTDataServer::getMaximumMagnitudeAt: filling"); fillColumn(x); } val = cache->getMaximumMagnitudeAt(col); } catch (std::exception &e) { m_error = e.what(); } return val; } float FFTDataServer::getPhaseAt(size_t x, size_t y) { Profiler profiler("FFTDataServer::getPhaseAt", false); if (x >= m_width || y >= m_height) return 0; float val = 0; try { size_t col; FFTCacheReader *cache = getCacheReader(x, col); if (!cache) return 0; if (!cache->haveSetColumnAt(col)) { Profiler profiler("FFTDataServer::getPhaseAt: filling"); fillColumn(x); } val = cache->getPhaseAt(col, y); } catch (std::exception &e) { m_error = e.what(); } return val; } bool FFTDataServer::getPhasesAt(size_t x, float *values, size_t minbin, size_t count, size_t step) { Profiler profiler("FFTDataServer::getPhasesAt", false); if (x >= m_width) return false; if (minbin >= m_height) minbin = m_height - 1; if (count == 0) count = (m_height - minbin) / step; else if (minbin + count * step > m_height) { count = (m_height - minbin) / step; } try { size_t col; FFTCacheReader *cache = getCacheReader(x, col); if (!cache) return false; if (!cache->haveSetColumnAt(col)) { Profiler profiler("FFTDataServer::getPhasesAt: filling"); fillColumn(x); } for (size_t i = 0; i < count; ++i) { values[i] = cache->getPhaseAt(col, i * step + minbin); } } catch (std::exception &e) { m_error = e.what(); return false; } return true; } void FFTDataServer::getValuesAt(size_t x, size_t y, float &real, float &imaginary) { Profiler profiler("FFTDataServer::getValuesAt", false); if (x >= m_width || y >= m_height) { real = 0; imaginary = 0; return; } try { size_t col; FFTCacheReader *cache = getCacheReader(x, col); if (!cache) { real = 0; imaginary = 0; return; } if (!cache->haveSetColumnAt(col)) { Profiler profiler("FFTDataServer::getValuesAt: filling"); #ifdef DEBUG_FFT_SERVER std::cerr << "FFTDataServer::getValuesAt(" << x << ", " << y << "): filling" << std::endl; #endif fillColumn(x); } cache->getValuesAt(col, y, real, imaginary); } catch (std::exception &e) { m_error = e.what(); } } bool FFTDataServer::getValuesAt(size_t x, float *reals, float *imaginaries, size_t minbin, size_t count, size_t step) { Profiler profiler("FFTDataServer::getValuesAt", false); if (x >= m_width) return false; if (minbin >= m_height) minbin = m_height - 1; if (count == 0) count = (m_height - minbin) / step; else if (minbin + count * step > m_height) { count = (m_height - minbin) / step; } try { size_t col; FFTCacheReader *cache = getCacheReader(x, col); if (!cache) return false; if (!cache->haveSetColumnAt(col)) { Profiler profiler("FFTDataServer::getValuesAt: filling"); fillColumn(x); } for (size_t i = 0; i < count; ++i) { cache->getValuesAt(col, i * step + minbin, reals[i], imaginaries[i]); } } catch (std::exception &e) { m_error = e.what(); return false; } return true; } bool FFTDataServer::isColumnReady(size_t x) { Profiler profiler("FFTDataServer::isColumnReady", false); if (x >= m_width) return true; if (!haveCache(x)) { /*!!! if (m_lastUsedCache == -1) { if (m_suspended) { std::cerr << "FFTDataServer::isColumnReady(" << x << "): no cache, calling resume" << std::endl; resume(); } m_fillThread->start(); } */ return false; } try { size_t col; FFTCacheReader *cache = getCacheReader(x, col); if (!cache) return true; return cache->haveSetColumnAt(col); } catch (std::exception &e) { m_error = e.what(); return false; } } void FFTDataServer::fillColumn(size_t x) { Profiler profiler("FFTDataServer::fillColumn", false); if (!m_model->isReady()) { cerr << "WARNING: FFTDataServer::fillColumn(" << x << "): model not yet ready" << endl; return; } /* if (!m_fftInput) { cerr << "WARNING: FFTDataServer::fillColumn(" << x << "): " << "input has already been completed and discarded?" << endl; return; } */ if (x >= m_width) { cerr << "WARNING: FFTDataServer::fillColumn(" << x << "): " << "x > width (" << x << " > " << m_width << ")" << endl; return; } size_t col; #ifdef DEBUG_FFT_SERVER_FILL cout << "FFTDataServer::fillColumn(" << x << ")" << endl; #endif FFTCacheWriter *cache = getCacheWriter(x, col); if (!cache) return; int winsize = m_windowSize; int fftsize = m_fftSize; int hs = fftsize/2; int pfx = 0; int off = (fftsize - winsize) / 2; int startFrame = m_windowIncrement * x; int endFrame = startFrame + m_windowSize; startFrame -= winsize / 2; endFrame -= winsize / 2; #ifdef DEBUG_FFT_SERVER_FILL std::cerr << "FFTDataServer::fillColumn: requesting frames " << startFrame + pfx << " -> " << endFrame << " ( = " << endFrame - (startFrame + pfx) << ") at index " << off + pfx << " in buffer of size " << m_fftSize << " with window size " << m_windowSize << " from channel " << m_channel << std::endl; #endif QMutexLocker locker(&m_fftBuffersLock); // We may have been called from a function that wanted to obtain a // column using an FFTCacheReader. Before calling us, it checked // whether the column was available already, and the reader // reported that it wasn't. Now we test again, with the mutex // held, to avoid a race condition in case another thread has // called fillColumn at the same time. if (cache->haveSetColumnAt(x & m_cacheWidthMask)) { return; } if (!m_fftInput) { cerr << "WARNING: FFTDataServer::fillColumn(" << x << "): " << "input has already been completed and discarded?" << endl; return; } for (int i = 0; i < off; ++i) { m_fftInput[i] = 0.0; } for (int i = 0; i < off; ++i) { m_fftInput[fftsize - i - 1] = 0.0; } if (startFrame < 0) { pfx = -startFrame; for (int i = 0; i < pfx; ++i) { m_fftInput[off + i] = 0.0; } } int count = 0; if (endFrame > startFrame + pfx) count = endFrame - (startFrame + pfx); int got = m_model->getData(m_channel, startFrame + pfx, count, m_fftInput + off + pfx); while (got + pfx < winsize) { m_fftInput[off + got + pfx] = 0.0; ++got; } if (m_channel == -1) { int channels = m_model->getChannelCount(); if (channels > 1) { for (int i = 0; i < winsize; ++i) { m_fftInput[off + i] /= channels; } } } m_windower.cut(m_fftInput + off); for (int i = 0; i < hs; ++i) { fftsample temp = m_fftInput[i]; m_fftInput[i] = m_fftInput[i + hs]; m_fftInput[i + hs] = temp; } fftf_execute(m_fftPlan); float factor = 0.f; if (cache->getStorageType() == FFTCache::Compact || cache->getStorageType() == FFTCache::Polar) { for (int i = 0; i <= hs; ++i) { fftsample real = m_fftOutput[i][0]; fftsample imag = m_fftOutput[i][1]; float mag = sqrtf(real * real + imag * imag); m_workbuffer[i] = mag; m_workbuffer[i + hs + 1] = atan2f(imag, real); if (mag > factor) factor = mag; } } else { for (int i = 0; i <= hs; ++i) { m_workbuffer[i] = m_fftOutput[i][0]; m_workbuffer[i + hs + 1] = m_fftOutput[i][1]; } } Profiler subprof("FFTDataServer::fillColumn: set to cache"); if (cache->getStorageType() == FFTCache::Compact || cache->getStorageType() == FFTCache::Polar) { cache->setColumnAt(col, m_workbuffer, m_workbuffer + hs + 1, factor); } else { cache->setColumnAt(col, m_workbuffer, m_workbuffer + hs + 1); } if (m_suspended) { // std::cerr << "FFTDataServer::fillColumn(" << x << "): calling resume" << std::endl; // resume(); } } void FFTDataServer::fillComplete() { for (int i = 0; i < int(m_caches.size()); ++i) { if (!m_caches[i]) continue; if (m_caches[i]->memoryCache) { m_caches[i]->memoryCache->allColumnsWritten(); } if (m_caches[i]->fileCacheWriter) { m_caches[i]->fileCacheWriter->allColumnsWritten(); } } } QString FFTDataServer::getError() const { if (m_error != "") return m_error; else if (m_fillThread) return m_fillThread->getError(); else return ""; } size_t FFTDataServer::getFillCompletion() const { if (m_fillThread) return m_fillThread->getCompletion(); else return 100; } size_t FFTDataServer::getFillExtent() const { if (m_fillThread) return m_fillThread->getExtent(); else return m_model->getEndFrame(); } QString FFTDataServer::generateFileBasename() const { return generateFileBasename(m_model, m_channel, m_windower.getType(), m_windowSize, m_windowIncrement, m_fftSize, m_polar); } QString FFTDataServer::generateFileBasename(const DenseTimeValueModel *model, int channel, WindowType windowType, size_t windowSize, size_t windowIncrement, size_t fftSize, bool polar) { char buffer[200]; sprintf(buffer, "%u-%u-%u-%u-%u-%u%s", (unsigned int)XmlExportable::getObjectExportId(model), (unsigned int)(channel + 1), (unsigned int)windowType, (unsigned int)windowSize, (unsigned int)windowIncrement, (unsigned int)fftSize, polar ? "-p" : "-r"); return buffer; } void FFTDataServer::FillThread::run() { #ifdef DEBUG_FFT_SERVER_FILL std::cerr << "FFTDataServer::FillThread::run()" << std::endl; #endif m_extent = 0; m_completion = 0; while (!m_server.m_model->isReady() && !m_server.m_exiting) { #ifdef DEBUG_FFT_SERVER_FILL std::cerr << "FFTDataServer::FillThread::run(): waiting for model " << m_server.m_model << " to be ready" << std::endl; #endif sleep(1); } if (m_server.m_exiting) return; size_t start = m_server.m_model->getStartFrame(); size_t end = m_server.m_model->getEndFrame(); size_t remainingEnd = end; int counter = 0; int updateAt = 1; int maxUpdateAt = (end / m_server.m_windowIncrement) / 20; if (maxUpdateAt < 100) maxUpdateAt = 100; if (m_fillFrom > start) { for (size_t f = m_fillFrom; f < end; f += m_server.m_windowIncrement) { try { m_server.fillColumn(int((f - start) / m_server.m_windowIncrement)); } catch (std::exception &e) { std::cerr << "FFTDataServer::FillThread::run: exception: " << e.what() << std::endl; m_error = e.what(); m_server.fillComplete(); m_completion = 100; m_extent = end; return; } if (m_server.m_exiting) return; while (m_server.m_suspended) { #ifdef DEBUG_FFT_SERVER cerr << "FFTDataServer(" << this << " [" << (void *)QThread::currentThreadId() << "]): suspended, waiting..." << endl; #endif MutexLocker locker(&m_server.m_fftBuffersLock, "FFTDataServer::run::m_fftBuffersLock [1]"); if (m_server.m_suspended && !m_server.m_exiting) { m_server.m_condition.wait(&m_server.m_fftBuffersLock, 10000); } #ifdef DEBUG_FFT_SERVER cerr << "FFTDataServer(" << this << " [" << (void *)QThread::currentThreadId() << "]): waited" << endl; #endif if (m_server.m_exiting) return; } if (++counter == updateAt) { m_extent = f; m_completion = size_t(100 * fabsf(float(f - m_fillFrom) / float(end - start))); counter = 0; if (updateAt < maxUpdateAt) { updateAt *= 2; if (updateAt > maxUpdateAt) updateAt = maxUpdateAt; } } } remainingEnd = m_fillFrom; if (remainingEnd > start) --remainingEnd; else remainingEnd = start; } size_t baseCompletion = m_completion; for (size_t f = start; f < remainingEnd; f += m_server.m_windowIncrement) { try { m_server.fillColumn(int((f - start) / m_server.m_windowIncrement)); } catch (std::exception &e) { std::cerr << "FFTDataServer::FillThread::run: exception: " << e.what() << std::endl; m_error = e.what(); m_server.fillComplete(); m_completion = 100; m_extent = end; return; } if (m_server.m_exiting) return; while (m_server.m_suspended) { #ifdef DEBUG_FFT_SERVER cerr << "FFTDataServer(" << this << " [" << (void *)QThread::currentThreadId() << "]): suspended, waiting..." << endl; #endif { MutexLocker locker(&m_server.m_fftBuffersLock, "FFTDataServer::run::m_fftBuffersLock [2]"); if (m_server.m_suspended && !m_server.m_exiting) { m_server.m_condition.wait(&m_server.m_fftBuffersLock, 10000); } } if (m_server.m_exiting) return; } if (++counter == updateAt) { m_extent = f; m_completion = baseCompletion + size_t(100 * fabsf(float(f - start) / float(end - start))); counter = 0; if (updateAt < maxUpdateAt) { updateAt *= 2; if (updateAt > maxUpdateAt) updateAt = maxUpdateAt; } } } m_server.fillComplete(); m_completion = 100; m_extent = end; #ifdef DEBUG_FFT_SERVER std::cerr << "FFTDataServer::FillThread::run exiting" << std::endl; #endif }