/* try to get video frame data in ARGB format, restore GXA state */ bool CScreenShot::GetData() { static OpenThreads::Mutex mutex; bool res = false; mutex.lock(); #ifdef USE_NEVIS_GXA CFrameBuffer::getInstance()->setActive(false); #endif if (videoDecoder->getBlank()) get_video = false; #if !HAVE_GENERIC_HARDWARE res = videoDecoder->GetScreenImage(pixel_data, xres, yres, get_video, get_osd, scale_to_video); #endif #ifdef USE_NEVIS_GXA /* sort of hack. GXA used to transfer/convert live image to RGB, * so setup GXA back */ CFrameBuffer::getInstance()->setupGXA(); //CFrameBuffer::getInstance()->add_gxa_sync_marker(); CFrameBuffer::getInstance()->setActive(true); #endif mutex.unlock(); if (!res) { printf("CScreenShot::Start: GetScreenImage failed\n"); return false; } printf("CScreenShot::GetData: data: %p %d x %d\n", pixel_data, xres, yres); return true; }
void SendThread::run() { #ifdef __linux__ prctl(PR_SET_NAME, "RRServer send", 0, 0, 0); #endif for (;;) { m_mutexData.lock(); m_condData.wait(&m_mutexData); if (m_rrdpy && m_b) { try { m_rrdpy->sendframe(m_b); m_rrdpy = NULL; m_b = NULL; } catch (...) { fprintf(stderr, "send failed, client disconnectd?\n"); } } else { // finish thread m_mutexData.unlock(); return; } m_mutexData.unlock(); } }
double ossimDtedElevationDatabase::getHeightAboveMSL(const ossimGpt& gpt) { if(!isSourceEnabled()) return ossim::nan(); double result = ossim::nan(); m_mutex.lock(); if(m_lastHandler.valid() && m_lastHandler->pointHasCoverage(gpt)) { result = m_lastHandler->getHeightAboveMSL(gpt); } else { m_lastHandler = getOrCreateCellHandler(gpt); if(m_lastHandler.valid()) result = m_lastHandler->getHeightAboveMSL(gpt); } #if 0 d_mutex.lock(); cout << "THREAD ID: "<<OpenThreads::Thread::CurrentThread()->getThreadId()<<" " <<"ossimDtedElevationDatabase @ "<<(unsigned long)this<<" m_lastHandler @ " <<(unsigned long)m_lastHandler.get()<<endl; //### TODO: for debug, remove d_mutex.unlock(); #endif m_mutex.unlock(); return result; }
void SendThread::stop() { m_mutexData.lock(); m_rrdpy = NULL; m_b = NULL; m_condData.signal(); m_mutexData.unlock(); }
void SendThread::send(rrdisplayclient *rrdpy, rrframe *b) { m_mutexData.lock(); m_rrdpy = rrdpy; m_b = b; m_condData.signal(); m_mutexData.unlock(); }
void DiskCache::cleanup() { cleanupLock.lock(); mapLock.lock(); for(std::list<std::pair<int,int> >::iterator it = _cleanupList.begin(); it != _cleanupList.end(); ) { #ifdef DC_PRINT_DEBUG std::cerr << "Cleanup f: " << it->first << " i: " << it->second << std::endl; #endif if(_cacheMap.find(it->first) == _cacheMap.end() || _cacheMap[it->first].find(it->second) == _cacheMap[it->first].end()) { #ifdef DC_PRINT_DEBUG std::cerr << "Double Cleanup f: " << it->first << " i: " << it->second << std::endl; #endif it = _cleanupList.erase(it); continue; } _cacheMap[it->first][it->second]->cji->lock.lock(); if(_cacheMap[it->first][it->second]->cji->refs <= 1) { _cacheMap[it->first][it->second]->cji->lock.unlock(); if(_cacheMap[it->first][it->second]->cji->data) { delete[] _cacheMap[it->first][it->second]->cji->data; } delete _cacheMap[it->first][it->second]->cji; delete _cacheMap[it->first][it->second]; _cacheMap[it->first].erase(it->second); it = _cleanupList.erase(it); } else { _cacheMap[it->first][it->second]->cji->lock.unlock(); it++; } } mapLock.unlock(); cleanupLock.unlock(); }
virtual void run() { helper::PerformanceMeasurer PM; PM.tic(); while(!is->done()) { _mutex.lock(); is->get(frame); if(frame.empty()) { loglni("[TrackThread] no valid frame, exit!!!"); OpenCVneedQuit = true; _mutex.unlock(); break; } cvtColor(frame, gray, CV_BGR2GRAY); double rms, ncc; if( needToInit ) { loglni("[TrackThread] INITing..."); Mat tmpH; if( findAprilTag(frame, 0, tmpH, true) ) { #if !USE_INTERNAL_DETECTOR Mat initH = tmpH * iHI; needToInit = !tracker.init(gray, initH, rms, ncc); #else needToInit=!tracker.init(gray,rms,ncc); #endif if(!needToInit) loglni("[TrackThread] ...INITed"); if(!needToInit) tracker.draw3D(frame); } } else { needToInit=!tracker(gray, rms, ncc, opencvDraw?&frame:0); if(!needToInit) tracker.GetCameraPose(camR,camT,false,true); } ++BkgModifyCnt; loglni("[TrackThread] fps="<<1.0/PM.toctic()); _mutex.unlock(); if(OpenCVneedQuit) { break; } ++framecnt; } OpenThreads::Thread::YieldCurrentThread(); loglni("[TrackThread] OpenCV quited..."); if(!videoFromWebcam) { loglni("[TrackThread] OpenCV notify OSG to quit..."); viewer.setDone(true); } }
void ossim::getFormattedTime( const std::string& format, bool gmtFlag, std::string& result ) { timeMutex.lock(); time_t rawTime; time(&rawTime); struct tm* timeInfo; if ( gmtFlag ) { timeInfo = gmtime(&rawTime); } else { timeInfo = localtime(&rawTime); } size_t size = 0; if ( timeInfo ) { const size_t STRING_SIZE = 196; // This is a big time string size. char outStr[STRING_SIZE]; size = strftime(outStr, STRING_SIZE, format.c_str(), timeInfo ); if ( size ) { // Per strftime spec not needed but null terminating anyway. outStr[STRING_SIZE-1] = '\0'; result = outStr; } } if ( !size ) { result.clear(); } timeMutex.unlock(); }
int DiskCache::add_file(const std::string& name) { int id; _fileAddLock.lock(); if(_fileIDMap.find(name) != _fileIDMap.end()) { id = _fileIDMap[name]; } else { listLock.lock(); _fileIDMap[name] = _nextID; id = _nextID; _cacheMap[id] = std::map<int,DiskCacheEntry*>(); _readList.push_back(std::list<std::pair<sph_task*, CopyJobInfo*> >()); for(int i = 0; i < _copyList.size(); i++) { _copyList[i].push_back(std::list<std::pair<sph_task*, CopyJobInfo*> >()); } listLock.unlock(); _nextID++; } _fileAddLock.unlock(); #ifdef DC_PRINT_DEBUG std::cerr << "add_file called with name: " << name << " given ID: " << id << std::endl; #endif return id; }
void DiskCache::add_task(sph_task * task) { /*int curPages = 0; mapLock.lock(); for(std::map<int, std::map<int,DiskCacheEntry*> >::iterator it = _cacheMap.begin(); it != _cacheMap.end(); it++) { curPages += it->second.size(); } mapLock.unlock(); std::cerr << "Actual Current Pages: " << curPages << std::endl;*/ cleanup(); if(!_running || (task->f != _currentFileL && task->f != _currentFileR)) { task->valid = false; loadsLock.lock(); task->cache->loads.insert(*task); loadsLock.unlock(); delete task; return; } if(_cacheIndexMap.find(task->cache) == _cacheIndexMap.end()) { listLock.lock(); int index = _cacheIndexMap.size(); _cacheIndexMap[task->cache] = index; _copyList.push_back(std::vector<std::list<std::pair<sph_task*, CopyJobInfo*> > >()); for(int i = 0; i < _fileIDMap.size(); i++) { _copyList.back().push_back(std::list<std::pair<sph_task*, CopyJobInfo*> >()); } listLock.unlock(); } mapLock.lock(); if(!_cacheMap[task->f][task->i]) { _cacheMap[task->f][task->i] = new DiskCacheEntry; _cacheMap[task->f][task->i]->timestamp = task->timestamp; _cacheMap[task->f][task->i]->f = task->f; _cacheMap[task->f][task->i]->i = task->i; CopyJobInfo * cji = new CopyJobInfo; cji->data = NULL; cji->size = 100; cji->valid = 0; cji->refs = 2; _cacheMap[task->f][task->i]->cji = cji; mapLock.unlock(); listLock.lock(); #ifdef DC_PRINT_DEBUG std::cerr << "Job started for task f: " << task->f << " i: " << task->i << " t: " << task->timestamp << std::endl; #endif _readList[task->f].push_back(std::pair<sph_task*, CopyJobInfo*>(task,cji)); listLock.unlock(); pageCountLock.lock(); _numPages++; /*while(_numPages >= _pages) { pageCountLock.unlock(); eject(); pageCountLock.lock(); }*/ pageCountLock.unlock(); } else { CopyJobInfo * cji = _cacheMap[task->f][task->i]->cji; cji->lock.lock(); if(!cji->size == 0) { _cacheMap[task->f][task->i]->timestamp = task->timestamp; cji->refs++; cji->lock.unlock(); mapLock.unlock(); #ifdef DC_PRINT_DEBUG std::cerr << "DiskCache Hit f: " << task->f << " i: " << task->i << " t: " << task->timestamp << std::endl; #endif listLock.lock(); _copyList[_cacheIndexMap[task->cache]][task->f].push_back(std::pair<sph_task*, CopyJobInfo*>(task,cji)); listLock.unlock(); } else { cji->lock.unlock(); mapLock.unlock(); #ifdef DC_PRINT_DEBUG std::cerr << "DiskCache Hit on deleting entry f: " << task->f << " i: " << task->i << std::endl; #endif task->valid = false; loadsLock.lock(); task->cache->loads.insert(*task); loadsLock.unlock(); delete task; } } int tries = 3; pageCountLock.lock(); while(_numPages >= _pages && tries > 0) { pageCountLock.unlock(); ejectLock.lock(); bool result = eject(); ejectLock.unlock(); // if you could not eject a page, stop trying if(!result) { break; } tries--; pageCountLock.lock(); } pageCountLock.unlock(); }
void SendThread::complete() { m_mutexData.lock(); m_mutexData.unlock(); }
bool CFfmpegDec::SetMetaData(FILE *_in, CAudioMetaData* m, bool save_cover) { if (!meta_data_valid) { if (!Init(_in, (const CFile::FileType) m->type)) return false; mutex.lock(); int ret = avformat_find_stream_info(avc, NULL); if (ret < 0) { mutex.unlock(); DeInit(); printf("avformat_find_stream_info error %d\n", ret); return false; } mutex.unlock(); if (!is_stream) { GetMeta(avc->metadata); for(unsigned int i = 0; i < avc->nb_streams; i++) { if (avc->streams[i]->codec->codec_type == AVMEDIA_TYPE_AUDIO) GetMeta(avc->streams[i]->metadata); } } //fseek((FILE *) in, 0, SEEK_SET); #ifdef FFDEC_DEBUG av_dump_format(avc, 0, "", 0); #endif codec = NULL; best_stream = av_find_best_stream(avc, AVMEDIA_TYPE_AUDIO, -1, -1, &codec, 0); if (best_stream < 0) { DeInit(); return false; } if (!codec) codec = avcodec_find_decoder(avc->streams[best_stream]->codec->codec_id); samplerate = avc->streams[best_stream]->codec->sample_rate; mChannels = av_get_channel_layout_nb_channels(avc->streams[best_stream]->codec->channel_layout); std::stringstream ss; if (codec && codec->long_name != NULL) type_info = codec->long_name; else if(codec && codec->name != NULL) type_info = codec->name; else type_info = "unknown"; ss << " / " << mChannels << " channel" << ( mChannels > 1 ? "s" : ""); type_info += ss.str(); bitrate = 0; total_time = 0; if (avc->duration != int64_t(AV_NOPTS_VALUE)) total_time = avc->duration / int64_t(AV_TIME_BASE); printf("CFfmpegDec: format %s (%s) duration %ld\n", avc->iformat->name, type_info.c_str(), total_time); for(unsigned int i = 0; i < avc->nb_streams; i++) { if (avc->streams[i]->codec->bit_rate > 0) bitrate += avc->streams[i]->codec->bit_rate; if (save_cover && (avc->streams[i]->disposition & AV_DISPOSITION_ATTACHED_PIC)) { mkdir(COVERDIR, 0755); std::string cover(COVERDIR); cover += "/" + to_string(cover_count++) + ".jpg"; FILE *f = fopen(cover.c_str(), "wb"); if (f) { AVPacket *pkt = &avc->streams[i]->attached_pic; fwrite(pkt->data, pkt->size, 1, f); fclose(f); m->cover = cover; m->cover_temporary = true; } } } if(!total_time && m->filesize && bitrate) total_time = 8 * m->filesize / bitrate; meta_data_valid = true; m->changed = true; } if (!is_stream) { m->title = title; m->artist = artist; m->date = date; m->album = album; m->genre = genre; m->total_time = total_time; } m->type_info = type_info; // make sure bitrate is set to prevent refresh metadata from gui, its a flag m->bitrate = bitrate ? bitrate : 1; m->samplerate = samplerate; return true; }
CBaseDec::RetCode CFfmpegDec::Decoder(FILE *_in, int /*OutputFd*/, State* state, CAudioMetaData* _meta_data, time_t* time_played, unsigned int* secondsToSkip) { in = _in; RetCode Status=OK; is_stream = fseek((FILE *)in, 0, SEEK_SET); if (!SetMetaData((FILE *)in, _meta_data, true)) { DeInit(); Status=DATA_ERR; return Status; } AVCodecContext *c = avc->streams[best_stream]->codec; mutex.lock(); int r = avcodec_open2(c, codec, NULL); mutex.unlock(); if (r) { DeInit(); Status=DATA_ERR; return Status; } SwrContext *swr = swr_alloc(); if (!swr) { mutex.lock(); avcodec_close(c); mutex.unlock(); DeInit(); Status=DATA_ERR; return Status; } mSampleRate = samplerate; mChannels = av_get_channel_layout_nb_channels(AV_CH_LAYOUT_STEREO); #if __BYTE_ORDER == __LITTLE_ENDIAN audioDecoder->PrepareClipPlay(mChannels, mSampleRate, 16, 1); #else audioDecoder->PrepareClipPlay(mChannels, mSampleRate, 16, 0); #endif AVFrame *frame = NULL; AVPacket rpacket; av_init_packet(&rpacket); av_opt_set_int(swr, "in_channel_layout", c->channel_layout, 0); //av_opt_set_int(swr, "out_channel_layout", c->channel_layout, 0); av_opt_set_int(swr, "out_channel_layout", AV_CH_LAYOUT_STEREO, 0); av_opt_set_int(swr, "in_sample_rate", c->sample_rate, 0); av_opt_set_int(swr, "out_sample_rate", c->sample_rate, 0); av_opt_set_int(swr, "in_sample_fmt", c->sample_fmt, 0); av_opt_set_int(swr, "out_sample_fmt", AV_SAMPLE_FMT_S16, 0); swr_init(swr); uint8_t *outbuf = NULL; int outsamples = 0; int outsamples_max = 0; int64_t pts = 0, start_pts = 0, next_skip_pts = 0; uint64_t skip = 0; int seek_flags = 0; do { int actSecsToSkip = *secondsToSkip; if (!is_stream && (actSecsToSkip || *state==FF || *state==REV) && avc->streams[best_stream]->time_base.num) { if (!next_skip_pts || pts >= next_skip_pts) { skip = avc->streams[best_stream]->time_base.den / avc->streams[best_stream]->time_base.num; if (actSecsToSkip) skip *= actSecsToSkip; if (*state == REV) { next_skip_pts = pts - skip; pts = next_skip_pts - skip/4; seek_flags = AVSEEK_FLAG_BACKWARD; if (pts < start_pts) { pts = start_pts; *state = PAUSE; } } else { pts += skip; next_skip_pts = pts + skip/4; seek_flags = 0; } av_seek_frame(avc, best_stream, pts, seek_flags); skip = 0; // if a custom value was set we only jump once if (actSecsToSkip != 0) { *state=PLAY; *secondsToSkip = 0; } } } while(*state==PAUSE && !is_stream) usleep(10000); if (av_read_frame(avc, &rpacket)) { Status=DATA_ERR; break; } if (rpacket.stream_index != best_stream) { av_free_packet(&rpacket); continue; } AVPacket packet = rpacket; while (packet.size > 0) { int got_frame = 0; if (!frame) { if (!(frame = avcodec_alloc_frame())) { Status=DATA_ERR; break; } } else avcodec_get_frame_defaults(frame); int len = avcodec_decode_audio4(c, frame, &got_frame, &packet); if (len < 0) { // skip frame packet.size = 0; avcodec_flush_buffers(c); mutex.lock(); avcodec_close(c); avcodec_open2(c, codec, NULL); mutex.unlock(); continue; } if (got_frame && *state!=PAUSE) { int out_samples; outsamples = av_rescale_rnd(swr_get_delay(swr, c->sample_rate) + frame->nb_samples, c->sample_rate, c->sample_rate, AV_ROUND_UP); if (outsamples > outsamples_max) { av_free(outbuf); if (av_samples_alloc(&outbuf, &out_samples, mChannels, //c->channels, frame->nb_samples, AV_SAMPLE_FMT_S16, 1) < 0) { Status=WRITE_ERR; packet.size = 0; break; } outsamples_max = outsamples; } outsamples = swr_convert(swr, &outbuf, outsamples, (const uint8_t **) &frame->data[0], frame->nb_samples); int outbuf_size = av_samples_get_buffer_size(&out_samples, mChannels, //c->channels, outsamples, AV_SAMPLE_FMT_S16, 1); if(audioDecoder->WriteClip((unsigned char*) outbuf, outbuf_size) != outbuf_size) { fprintf(stderr,"%s: PCM write error (%s).\n", ProgName, strerror(errno)); Status=WRITE_ERR; } pts = av_frame_get_best_effort_timestamp(frame); if (!start_pts) start_pts = pts; } packet.size -= len; packet.data += len; } if (time_played && avc->streams[best_stream]->time_base.den) *time_played = (pts - start_pts) * avc->streams[best_stream]->time_base.num / avc->streams[best_stream]->time_base.den; av_free_packet(&rpacket); } while (*state!=STOP_REQ && Status==OK); audioDecoder->StopClip(); meta_data_valid = false; swr_free(&swr); av_free(outbuf); av_free_packet(&rpacket); avcodec_free_frame(&frame); avcodec_close(c); //av_free(avcc); DeInit(); if (_meta_data->cover_temporary && !_meta_data->cover.empty()) { _meta_data->cover_temporary = false; unlink(_meta_data->cover.c_str()); } return Status; }
void JobThread::copy() { std::pair<sph_task*, CopyJobInfo*> taskpair; bool found = false; listLock.lock(); if(_copyList->size()) { _copyCacheNum = _copyCacheNum % _copyList->size(); _copyFileNum = _copyFileNum % _copyList->at(_copyCacheNum).size(); int lastFile = _copyFileNum; for(int i = 0; i < _copyList->size(); i++) { for(; _copyFileNum < _copyList->at(_copyCacheNum).size(); _copyFileNum++) { if(_copyList->at(_copyCacheNum)[_copyFileNum].size()) { for(std::list<std::pair<sph_task*, CopyJobInfo*> >::iterator it = _copyList->at(_copyCacheNum)[_copyFileNum].begin(); it != _copyList->at(_copyCacheNum)[_copyFileNum].end(); it++) { if(it->second->valid || !it->second->size) { taskpair = *it; _copyList->at(_copyCacheNum)[_copyFileNum].erase(it); found = true; break; } } if(found) { _copyFileNum++; break; } //taskpair = _copyList->at(_copyCacheNum)[_copyFileNum].front(); //_copyList->at(_copyCacheNum)[_copyFileNum].pop_front(); //found = true; //_copyFileNum++; //break; } } if(found) { if(_copyFileNum == _copyList->at(_copyCacheNum).size()) { _copyCacheNum++; _copyCacheNum = _copyCacheNum % _copyList->size(); _copyFileNum = 0; } break; } _copyFileNum = 0; _copyCacheNum++; _copyCacheNum = _copyCacheNum % _copyList->size(); } if(!found) { for(_copyFileNum = 0; _copyFileNum < lastFile; _copyFileNum++) { if(_copyList->at(_copyCacheNum)[_copyFileNum].size()) { for(std::list<std::pair<sph_task*, CopyJobInfo*> >::iterator it = _copyList->at(_copyCacheNum)[_copyFileNum].begin(); it != _copyList->at(_copyCacheNum)[_copyFileNum].end(); it++) { if(it->second->valid || !it->second->size) { taskpair = *it; _copyList->at(_copyCacheNum)[_copyFileNum].erase(it); found = true; break; } } if(found) { _copyFileNum++; break; } //taskpair = _copyList->at(_copyCacheNum)[_copyFileNum].front(); //_copyList->at(_copyCacheNum)[_copyFileNum].pop_front(); //found = true; //_copyFileNum++; //break; } } } } #ifdef DC_PRINT_DEBUG int cjobsize = 0; for(int i = 0; i < _copyList->size(); i++) { for(int j = 0; j < _copyList->at(i).size(); j++) { cjobsize += _copyList->at(i)[j].size(); } } if(cjobsize) { std::cerr << "Copy Jobs left: " << cjobsize << std::endl; } #endif /*if(_copyList->size()) { for(int i = 0; i < _copyList->size(); i++) { _copyIndex = _copyIndex % _copyList->size(); if(_copyList->at(_copyIndex).size()) { taskpair = _copyList->at(_copyIndex).front(); _copyList->at(_copyIndex).pop_front(); _copyIndex++; break; } _copyIndex++; } }*/ listLock.unlock(); if(taskpair.first) { #ifdef DC_PRINT_DEBUG std::cerr << "Copy thread: " << _id << " got task f: " << taskpair.first->f << " i: " << taskpair.first->i << std::endl; if(_jt == READ_THREAD) { std::cerr << "Copy done by read thread." << std::endl; } #endif unsigned char * currentP = taskpair.second->data; unsigned int currentCopied = 0; unsigned int size = 0; do { unsigned int currentValid; taskpair.second->lock.lock(); currentValid = taskpair.second->valid; size = taskpair.second->size; taskpair.second->lock.unlock(); if(currentCopied < currentValid) { unsigned char * dest = ((unsigned char*)taskpair.first->p) + currentCopied; unsigned char * src = taskpair.second->data + currentCopied; memcpy(dest,src,currentValid - currentCopied); currentCopied = currentValid; } } while(currentCopied < size); taskpair.second->lock.lock(); taskpair.second->refs--; if(!taskpair.second->size) { taskpair.first->valid = false; } loadsLock.lock(); taskpair.first->cache->loads.insert(*(taskpair.first)); loadsLock.unlock(); taskpair.second->lock.unlock(); #ifdef DC_PRINT_DEBUG std::cerr << "Copy thread: " << _id << " finished task f: " << taskpair.first->f << " i: " << taskpair.first->i << std::endl; #endif delete taskpair.first; } else { struct timespec ts; ts.tv_sec = 0; ts.tv_nsec = 2000000; nanosleep(&ts,NULL); } }
bool DiskCache::eject() { #ifdef DC_PRINT_DEBUG std::cerr << "DiskCache::eject()" << std::endl; #endif mapLock.lock(); // find oldest referenced page int f = -1; int i = -1; int mint = INT_MAX; for(std::map<int, std::map<int,DiskCacheEntry*> >::iterator it = _cacheMap.begin(); it != _cacheMap.end(); it++) { for(std::map<int,DiskCacheEntry*>::iterator it2 = it->second.begin(); it2 != it->second.end(); it2++) { if(!it2->second) { continue; } if(it2->second->timestamp < mint) { mint = it2->second->timestamp; f = it2->second->f; i = it2->second->i; } } } if(f == -1) { std::cerr << "No Min page found!?!?..." << std::endl; mapLock.unlock(); return false; } _cacheMap[f][i]->timestamp = INT_MAX; mapLock.unlock(); #ifdef DC_PRINT_DEBUG std::cerr << "Eject f: " << f << " i: " << i << " t: " << mint << std::endl; #endif _cacheMap[f][i]->cji->lock.lock(); if(!_cacheMap[f][i]->cji->size) { #ifdef DC_PRINT_DEBUG std::cerr << "Already Ejecting f: " << f << " i: " << i << " t: " << mint << std::endl; #endif _cacheMap[f][i]->cji->lock.unlock(); return false; } _cacheMap[f][i]->cji->size = 0; _cacheMap[f][i]->cji->lock.unlock(); std::queue<sph_task> tempq; loadsLock.lock(); for(std::map<sph_cache*,int>::iterator it = _cacheIndexMap.begin(); it != _cacheIndexMap.end(); it++) { while(!it->first->loads.empty()) { tempq.push(it->first->loads.remove()); if(tempq.front().f == f && tempq.front().i == i) { tempq.front().valid = false; } } while(tempq.size()) { it->first->loads.insert(tempq.front()); tempq.pop(); } } loadsLock.unlock(); cleanupLock.lock(); _cleanupList.push_back(std::pair<int,int>(f,i)); cleanupLock.unlock(); /*delete[] _cacheMap[f][i]->cji->data; delete _cacheMap[f][i]->cji; delete _cacheMap[f][i]; _cacheMap[f].erase(i);*/ pageCountLock.lock(); _numPages--; pageCountLock.unlock(); return true; }
void DiskCache::kill_tasks(int file) { if(file < 0 || file >= _readList.size()) { return; } listLock.lock(); std::queue<sph_task> tempq; loadsLock.lock(); for(std::map<sph_cache*,int>::iterator it = _cacheIndexMap.begin(); it != _cacheIndexMap.end(); it++) { while(!it->first->loads.empty()) { tempq.push(it->first->loads.remove()); if(tempq.front().f == file) { tempq.front().valid = false; } } while(tempq.size()) { it->first->loads.insert(tempq.front()); tempq.pop(); } } loadsLock.unlock(); for(int i = 0; i < _copyList.size(); i++) { for(std::list<std::pair<sph_task*, CopyJobInfo*> >::iterator it = _copyList[i][file].begin(); it != _copyList[i][file].end(); it++) { it->first->valid = false; loadsLock.lock(); it->first->cache->loads.insert(*(it->first)); loadsLock.unlock(); it->second->lock.lock(); it->second->refs--; it->second->lock.unlock(); delete it->first; } _copyList[i][file].clear(); } for(std::list<std::pair<sph_task*, CopyJobInfo*> >::iterator it = _readList[file].begin(); it != _readList[file].end(); it++) { it->first->valid = false; loadsLock.lock(); it->first->cache->loads.insert(*(it->first)); loadsLock.unlock(); bool ejecting; it->second->lock.lock(); it->second->refs--; if(it->second->size) { ejecting = false; it->second->size = 0; } else { ejecting = true; } it->second->lock.unlock(); if(!ejecting) { cleanupLock.lock(); _cleanupList.push_back(std::pair<int,int>(it->first->f,it->first->i)); cleanupLock.unlock(); } delete it->first; if(!ejecting) { pageCountLock.lock(); _numPages--; pageCountLock.unlock(); } /*if(!it->second->refs) { _cacheMap[it->first->f].erase(it->first->i); it->second->lock.unlock(); delete it->second; delete it->first; } else { it->second->size = 0; _cleanupList.push_back(std::pair<int,int>(it->first->f,it->first->i)); it->second->lock.unlock(); }*/ } _readList[file].clear(); listLock.unlock(); }
void JobThread::read() { CopyJobInfo * cji = NULL; sph_task * task = NULL; listLock.lock(); if(_readList->size()) { for(int i = 0; i < _readList->size(); i++) { _readIndex = _readIndex % _readList->size(); if(_readList->at(_readIndex).size()) { task = _readList->at(_readIndex).front().first; cji = _readList->at(_readIndex).front().second; _readList->at(_readIndex).pop_front(); #ifdef DC_PRINT_DEBUG std::cerr << "Read Thread grabbed job f: " << task->f << " i: " << task->i << " t: " << task->timestamp << std::endl; #endif _readIndex++; break; } _readIndex++; } } listLock.unlock(); if(task) { if (!task->cache->files[task->f].name.empty()) { if (TIFF *T = TIFFOpen(task->cache->files[task->f].name.c_str(), "r")) { if (up(T, task->i)) { uint32 w = task->cache->files[task->f].w; uint32 h = task->cache->files[task->f].h; uint16 c = task->cache->files[task->f].c; uint16 b = task->cache->files[task->f].b; readData(task, cji,T,w,h,c,b); #ifdef DC_PRINT_DEBUG std::cerr << "Done reading data f: " << task->f << " i: " << task->i << std::endl; #endif //task.load_texture(T, w, h, c, b); //task->cache->loads.insert(*task); } TIFFClose(T); } } else { delete task; } cji->lock.lock(); cji->refs--; cji->lock.unlock(); } else { // no read task, look for a copy one //std::cerr << "Read thread doing copy" << std::endl; copy(); } }
void JobThread::readData(sph_task * task, CopyJobInfo * cji, TIFF * T, uint32 w, uint32 h, uint16 c, uint16 b) { // Confirm the page format. uint32 W, H; uint16 C, B; TIFFGetField(T, TIFFTAG_IMAGEWIDTH, &W); TIFFGetField(T, TIFFTAG_IMAGELENGTH, &H); TIFFGetField(T, TIFFTAG_BITSPERSAMPLE, &B); TIFFGetField(T, TIFFTAG_SAMPLESPERPIXEL, &C); if (W == w && H == h && B == b && C == c) { cji->lock.lock(); cji->valid = 0; cji->refs++; if(cji->size == 0) { // if job is invalid, forward through to copy op task->valid = false; cji->lock.unlock(); listLock.lock(); _copyList->at((*_cacheIndexMap)[task->cache])[task->f].push_back(std::pair<sph_task*,CopyJobInfo*>(task,cji)); listLock.unlock(); return; } unsigned int linesize = TIFFScanlineSize(T); unsigned int totalData = W*H*4; unsigned char * data = new unsigned char[totalData]; unsigned int currentValid = 0; cji->data = data; cji->size = totalData; cji->lock.unlock(); listLock.lock(); _copyList->at((*_cacheIndexMap)[task->cache])[task->f].push_back(std::pair<sph_task*,CopyJobInfo*>(task,cji)); listLock.unlock(); // Pad a 24-bit image to 32-bit BGRA. if (c == 3 && b == 8) { if (void *q = malloc(linesize)) { const uint32 S = w * 4 * b / 8; for (uint32 r = 0; r < h; ++r) { TIFFReadScanline(T, q, r, 0); for (int j = w - 1; j >= 0; --j) { uint8 *s = (uint8 *) q + j * c * b / 8; uint8 *d = (uint8 *) data + r * S + j * 4 * b / 8; d[0] = s[2]; d[1] = s[1]; d[2] = s[0]; d[3] = 0xFF; } currentValid += S; cji->lock.lock(); cji->valid = currentValid; cji->lock.unlock(); } free(q); } } else { for (uint32 r = 0; r < h; ++r) { TIFFReadScanline(T, (uint8 *) data + r * linesize, r, 0); currentValid += linesize; cji->lock.lock(); cji->valid = currentValid; cji->lock.unlock(); } } } else { delete task; } }