#ifndef FACT_EventBuilder #define FACT_EventBuilder #include "FAD.h" #include #include #include namespace std { class mutex; } /* global variables; to avoid race canoditions, only one thread is allowed to write the name of the variable defines which process shall write it: g_XXX : main control thread gi_XX : input thread (reading from camera) gw_XX : write thread (writing to disk) qp_XX : processing thread(s) (processing data, eg. soft-trig) */ extern int g_reset ; //>0 = reset different levels of eventbuilder extern size_t g_maxMem ; //maximum memory allowed for buffer extern uint16_t g_evtTimeout; //timeout (sec) for one event extern FACT_SOCK g_port[NBOARDS] ; // .port = baseport, .addr=string of IP-addr in dotted-decimal "ddd.ddd.ddd.ddd" extern uint gi_NumConnect[NBOARDS]; //4 crates * 10 boards class DrsCalibration; enum FileStatus_t { kFileNotYetOpen, kFileOpen, kFileClosed }; enum CloseRequest_t { kRequestNone = 0, kRequestManual = 1<<1, kRequestTimeout = 1<<2, kRequestConnectionChange = 1<<3, kRequestEventCheckFailed = 1<<4, kRequestMaxEvtsReached = 1<<5, kRequestMaxTimeReached = 1<<6 }; struct RUN_CTRL2 { int64_t runId ; // Run number time_t reportMem; // initMemory has reported no memory once (set outside of class) time_t openTime; // Time when first event (first board) was received time_t lastTime; // Time when last event was received (set when first board data received) time_t closeTime; // Time when run should be closed uint32_t night; // night as int as determined for this run uint32_t lastEvt; // number of events received (counted when the first board was received) uint32_t maxEvt; // maximum number which should be written to file uint16_t roi0; // roi for normal pixels uint16_t roi8; // roi for pixels8 std::string runType; FileStatus_t fileStat; std::array triggerCounter; std::shared_ptr calib; std::list> prevStart; // History for start cells of previous events (for step calibration) RUN_CTRL2() : runId(-1), reportMem(0), lastTime(0), lastEvt(0), maxEvt(1<<31), fileStat(kFileNotYetOpen) { triggerCounter.fill(0); // runId = -1; // fileId = kFileNotYetOpen; // lastEvt = 0; // Number of events partially started to read // actEvt = 0; // Number of written events // maxEvt = 1<<31; // max number events allowed (~2400min @ 250Hz) } //~RUN_CTRL2(); }; #define MAX_HEAD_MEM (NBOARDS * sizeof(PEVNT_HEADER)) #define MAX_TOT_MEM (sizeof(EVENT) + (NPIX+NTMARK)*1024*2 + MAX_HEAD_MEM) namespace Memory { extern uint64_t inuse; extern uint64_t allocated; extern uint64_t max_inuse; extern std::mutex mtx; extern std::forward_list memory; extern void *malloc(); extern void free(void *mem); }; struct EVT_CTRL2 { uint32_t runNum; // header->runnumber; uint32_t evNum; // header->fad_evt_counter uint32_t trgNum; // header->trigger_id uint32_t trgTyp; // header->trigger_type uint32_t fadLen; uint16_t nBoard; int16_t board[NBOARDS]; uint16_t nRoi; uint16_t nRoiTM; timeval time; PEVNT_HEADER *FADhead; // Pointer to the whole allocated memory EVENT *fEvent; // Pointer to the event data itself PEVNT_HEADER *header; // Pointer to a valid header within FADhead int closeRequest; std::array triggerCounter; std::shared_ptr runCtrl; // Be carefull with this constructor... writeEvt can seg fault // it gets an empty runCtrl EVT_CTRL2() : nBoard(0), FADhead(0), header(0), closeRequest(kRequestNone) { //flag all boards as unused std::fill(board, board+NBOARDS, -1); } /* EVT_CTRL2(CloseRequest_t req) : nBoard(0), FADhead(0), header(0), reportMem(false), closeRequest(req), runCtrl(new RUN_CTRL2) { //flag all boards as unused std::fill(board, board+NBOARDS, -1); }*/ EVT_CTRL2(int req, const std::shared_ptr &run) : nBoard(0), FADhead(0), header(0), closeRequest(req), runCtrl(run) { //flag all boards as unused std::fill(board, board+NBOARDS, -1); } ~EVT_CTRL2() { Memory::free(FADhead); } operator RUN_HEAD() const { RUN_HEAD rh; rh.Nroi = nRoi; rh.NroiTM = nRoiTM; rh.RunTime = time.tv_sec; rh.RunUsec = time.tv_usec; memcpy(rh.FADhead, FADhead, NBOARDS*sizeof(PEVNT_HEADER)); return rh; } bool valid() const { return header; } bool initMemory() { // We have a valid entry, but no memory has yet been allocated if (FADhead) return true; FADhead = (PEVNT_HEADER*)Memory::malloc(); if (!FADhead) return false; fEvent = reinterpret_cast(FADhead+NBOARDS); memset(FADhead, 0, (NPIX+NTMARK)*2*nRoi+NBOARDS*sizeof(PEVNT_HEADER)+sizeof(EVENT)); //flag all pixels as unused, flag all TMark as unused std::fill(fEvent->StartPix, fEvent->StartPix+NPIX, -1); std::fill(fEvent->StartTM, fEvent->StartTM +NTMARK, -1); fEvent->Roi = nRoi; fEvent->RoiTM = nRoiTM; fEvent->EventNum = evNum; fEvent->TriggerNum = trgNum; fEvent->TriggerType = trgTyp; return true; } }; #endif