/********************************************************************\ DAQReadout.cc Main DAQ routines. Sebastian Commichau, Oliver Grimm \********************************************************************/ #include "DAQReadout.h" static char* daq_state_str[] = {"active", "stopped"}; static char* daq_runtype_str[] = {"data", "pedestal", "test"}; static struct CL_Struct { char *Name; void (DAQReadout::*CommandPointer)(); bool NeedNotBusy; char *Parameters; char *Help; } CommandList[] = {{"board", &DAQReadout::cmd_board, true, " [j] | " ,"Address board i, boards i-j, all boards"}, {"status", &DAQReadout::cmd_status, false, "[daq|drs]", "Show DAQ/DRS status information"}, {"freq", &DAQReadout::cmd_freq, true, "", "Set DRS sampling frequency"}, {"calib", &DAQReadout::cmd_calib, true, " [dir]", "Response calibration"}, {"trigger", &DAQReadout::cmd_trigger, true, "", "Hardware trigger on or off"}, {"delayed", &DAQReadout::cmd_delayed, true, "", "Switch delayed start on or off"}, {"wmode", &DAQReadout::cmd_wmode, true, "<0|1>", "Set DRS wave mode"}, {"rmode", &DAQReadout::cmd_rmode, true, "<0|1>", "Set DRS readout mode"}, {"mode", &DAQReadout::cmd_mode, true, "<0|1>", "Set DRS mode: 0 = single shot, 1 = continuous"}, {"read", &DAQReadout::cmd_read, true, " ", "Read current data from board, chip, channel"}, {"take", &DAQReadout::cmd_take, false, " [n] [source]", "Start run (data, pedestal or test) with n events"}, {"events", &DAQReadout::cmd_events, false, "", "Number of events in current run"}, {"start", &DAQReadout::cmd_start, true, "", "Start domino wave"}, {"stop", &DAQReadout::cmd_stop, false, "", "Issue soft trigger and stop DAQ"}, {"test", &DAQReadout::cmd_test, true, "[2e] [n]", "Test read access of VMEbus (n blocks)"}, {"regtest", &DAQReadout::cmd_regtest, true, "", "DRS register test"}, {"ramtest", &DAQReadout::cmd_ramtest, true, "", "DRS RAM integrity and speed test"}, {"led", &DAQReadout::cmd_led, true, "", "Turn LED on or off"}, {"config", &DAQReadout::cmd_config, false, "", "Print drsdaq configuration"}, {"serial", &DAQReadout::cmd_serial, true, " ", "Set serial# of board to (experts only)"}, {"disk", &DAQReadout::cmd_disk, false, "" ,"Remaining disk space"}, {"uptime", &DAQReadout::cmd_uptime, false, "", "Get DAQ uptime"}, {"exit", &DAQReadout::cmd_exit, false, "", "Exit program"}, {"fmode", &DAQReadout::cmd_fmode, false, "[off|active|targ]", "Set or get feedback mode"}, {"faverage", &DAQReadout::cmd_faverage, false, "[n]", "Set ot get number of averages for feedback"}, {"fgain", &DAQReadout::cmd_fgain, false, "[gain]", "Set ot get feedback gain"}, {"ftarget", &DAQReadout::cmd_ftarget, false, "[brd chip chan]", "Set or get target value"}, {"fresponse", &DAQReadout::cmd_fresponse, false, "[V1 V2]", "Start response measurement with voltages V1 and V2"}, {"fconfig", &DAQReadout::cmd_fconfig, false, "", "Print feedback configuration"}, {"help", &DAQReadout::cmd_help, false, "", "Print help"}}; // ----------------------------------------------- // ***** Constructor: Class initialisation ***** // ----------------------------------------------- // // Note that constructor cannot report error and should not fail DAQReadout::DAQReadout(const char *Configfile) { time(&StartTime); // Start time of DAQ Rawfile = NULL; // Initialize status structure daq_state = stopped; daq_runtype = data; Socket = -1; Exit = false; NumEvents = 0; NumEventsRequested = 100; NumCMCBoards = 0; FirstBoard = 0; LastBoard = -1; sprintf(Source,"DUMMY"); // Read configuration file FILE *File; if ((File = fopen(Configfile,"r")) == NULL) { printf("Error: Could not open drsdaq configuration file '%s'\n", Configfile); } else { printf("Reading drsdaq configuration file %s\n", Configfile); ReadCard("LogFile", fLogFile, 's', File); ReadCard("RawDataPath", fRawDataPath, 's', File); ReadCard("RotateWave", &fRotateWave, 'I', File); ReadCard("FirstSample", &fFirstSample, 'I', File); ReadCard("LastSample", &fLastSample, 'I', File); ReadCard("MinDiskSpaceMB", &fMinDiskSpaceMB, 'U', File); ReadCard("MaxFileSizeMB", &fMaxFileSizeMB, 'I', File); ReadCard("CCPort", &fCCPort, 'I', File); ReadCard("FirstVMESlot", &fFirstVMESlot, 'I', File); ReadCard("LastVMESlot", &fLastVMESlot, 'I', File); ReadCard("HVFeedbackConfig", fHVFeedbackConfig, 's', File); fclose(File); } if (fFirstSample < 0 || fFirstSample >= kNumberOfBins || fLastSample < 0 || fLastSample >= kNumberOfBins) { PrintMessage("Warning: Sample range in configuration beyond limits, setting to full range\n"); fFirstSample = 0; fLastSample = kNumberOfBins; } // Open log file if ((Logfile = fopen(fLogFile, "a")) == NULL) fprintf(stderr,"Warning: Could not open log file '%s'\n", fLogFile); else PrintMessage(MsgToLog,"********** Logging started **********\n"); cmd_config(); // Create DRS instance and perform initial scan drs = new DRS(); drs->SetFirstVMESlot(fFirstVMESlot); drs->SetLastVMESlot(fLastVMESlot); drs->InitialScan(); RHeader = new RunHeader; EHeader = new EventHeader; DRSFreq = new float [drs->GetNumberOfBoards()]; // Scan for DRS boards if (drs->GetNumberOfBoards()==0) PrintMessage("No DRS boards found - check VME crate and configuration file!\n"); for (int i=0; iGetNumberOfBoards(); i++) { PrintMessage("Init. mezz. board %2d on VME slot %2d %s, serial #%d, firmware revision %d\n", i, (drs->GetBoard(i)->GetSlotNumber() >> 1)+2, ((drs->GetBoard(i)->GetSlotNumber() & 1) == 0) ? "upper" : "lower", drs->GetBoard(i)->GetCMCSerialNumber(), drs->GetBoard(i)->GetFirmwareVersion()); NumCMCBoards++; LastBoard++; drs->GetBoard(i)->Init(); drs->GetBoard(i)->SetRotation(fRotateWave); DRSFreq[i] = 0; } BStruct = new BoardStructure [NumCMCBoards == 0 ? 1:drs->GetNumberOfBoards()]; WaveForm = new short [NumCMCBoards == 0 ? 1:NumCMCBoards][kNumberOfChips][kNumberOfChannels][kNumberOfBins]; // Create instance of HV feedback (must be after CMC board detection) HVFB = new HVFeedback(this, fHVFeedbackConfig); } // ------------------------ // ***** Destructor ***** // ------------------------ DAQReadout::~DAQReadout() { delete RHeader; delete EHeader; delete drs; delete HVFB; delete[] DRSFreq; delete[] BStruct; delete[] WaveForm; PrintMessage(MsgToLog,"********** Logging ended **********\n\n"); if(Logfile) { if(!fclose(Logfile)) printf("Closing logfile\n"); else perror("Error closing logfile"); } } // -------------------------------- // ***** Command evaluation ***** // -------------------------------- int DAQReadout::CommandControl(char *Command, bool FromSocket) { if (strlen(Command) < 2 ) return 0; // Ignore commands with only '/n' if (Command[strlen(Command)-1]=='\n') Command[strlen(Command)-1]='\0'; // Remove '/n' if(Command[0]=='.') { // Shell command system(&(Command[1])); return 0; } for(int i=0; i*CommandList[CmdNumber].CommandPointer)(); return 0; } PrintMessage("Unknown command: %s\n",Param[0]); return 0; } // Get uptime void DAQReadout::cmd_uptime() { time_t ActualT; time (&ActualT); PrintMessage("%d:%02d:%02d\n", (int) difftime(ActualT, StartTime)/3600, ((int) difftime(ActualT, StartTime)/60)%60, (int) difftime(ActualT, StartTime)%60); } // Print disk space void DAQReadout::cmd_disk() { PrintMessage("Free disk space (%s) [MB]: %lu\n", fRawDataPath, CheckDisk(fRawDataPath)); } // Print current number of events void DAQReadout::cmd_events() { if(daq_state != active) PrintMessage("DAQ not active.\n"); else PrintMessage("Current number of events: %d\n", NumEvents); } // Print DAQ configuration void DAQReadout::cmd_config() { PrintMessage("LogFile: %s\tRawDataPath: %s\n" "RotateWave: %d\t\tFirstSample: %d\t\tLastSample: %d\n" "MinDiskSpaceMB: %u\tMaxFileSizeMB: %d\tCCPort: %d\n" "FirstVMESlot: %d\t\tLastVMESlot: %d\n" "HVFeedbackConfig: \t%s\n", fLogFile,fRawDataPath,fRotateWave,fFirstSample,fLastSample,fMinDiskSpaceMB, fMaxFileSizeMB,fCCPort,fFirstVMESlot,fLastVMESlot,fHVFeedbackConfig); } // Start DAQ void DAQReadout::cmd_take() { if(!Match(Param[1],"test") && (IsDAQBusy() || NumCMCBoards==0)) { PrintMessage("DAQ is busy or no boards available.\n"); return; } if (!IsDRSFreqSet()) return; if (!IsCalibrationRead()) if(!ReadCalibration()) { PrintMessage("Problem with response calibration!\n"); return; } if (Match(Param[1],"data")) { HWTrigger(1); daq_runtype = data; } else if (Match(Param[1],"pedestal")) { HWTrigger(0); daq_runtype = pedestal; } else if (Match(Param[1],"test")) { daq_runtype = test; } else { PrintUsage(); return; } if (NParam==3 && atoi(Param[2])) NumEventsRequested = atoi(Param[2]); if (NParam==4) { if(atoi(Param[2])) NumEventsRequested = atoi(Param[2]); strcpy(Source, Param[3]); } if ((pthread_create(&thread_DAQ, NULL, (void * (*)(void *)) DAQ,(void *) this)) != 0) perror("pthread_create failed with DAQ thread"); else { daq_state = active; Stop = false; pthread_detach(thread_DAQ); } } // Start DRS void DAQReadout::cmd_start() { if (IsDRSFreqSet()) { StartDRS(); PrintMessage("Domino wave started\n"); } } // RAM test void DAQReadout::cmd_ramtest() { for (int i=FirstBoard; i<=LastBoard; i++) { PrintMessage("RAM integrity and speed test (board #%d):\n",i); (drs->GetBoard(i))->RAMTest(3); } } // Register test void DAQReadout::cmd_regtest() { for (int i=FirstBoard; i<=LastBoard; i++) { PrintMessage("Register test (board #%d):\n",i); (drs->GetBoard(i))->RegisterTest(); } } // Test VME transfer void DAQReadout::cmd_test() { int Type=-1, i; if (Match(Param[1], "2eblt64")) Type = 2; else if (Match(Param[1], "blt32")) Type = 0; else if (Match(Param[1], "blt64")) Type = 1; else { PrintMessage("Unknown type for testing.\n"); return; } if (NumCMCBoards) for (i=FirstBoard; i<=LastBoard; i++) { PrintMessage("BLT test started (board #%d)\n",i); (drs->GetBoard(i))->TestRead(Param[2][0] && atoi(Param[2])<=10000 && atoi(Param[2])>0 ? atoi(Param[2]):1, Type); } else PrintMessage("No DRS boards available\n"); } // Stop DAQ void DAQReadout::cmd_stop() { if(!IsDAQBusy() && !IsDRSBusy()) PrintMessage("Nothing to stop\n"); if (IsDAQBusy()) StopRun(); if (IsDRSBusy()) { StopDRS(); PrintMessage("Domino wave stopped\n"); } } // Read data void DAQReadout::cmd_read() { if (IsDRSBusy()) { PrintMessage("Domino wave is running, issue \"stop first\"\n"); return; } if (Param[1][0] && Param[2][0] && Param[3][0]) { if (IsDRSFreqSet()&& !IsCalibrationRead()) ReadCalibration(); ReadandPrintDRSData(atoi(Param[1]),atoi(Param[2]),atoi(Param[3])); } else PrintUsage(); } // Set Domino mode void DAQReadout::cmd_mode() { if (Match(Param[1],"continuous")) SetDOMINOMode(1); else if (Match(Param[1],"single")) SetDOMINOMode(0); else PrintUsage(); } // Set Domino readout mode void DAQReadout::cmd_rmode() { if (Match(Param[1],"1")) SetDOMINOReadMode(1); else if (Match(Param[1],"0")) SetDOMINOReadMode(0); else PrintUsage(); } // Set Domino wave mode void DAQReadout::cmd_wmode() { if (Match(Param[1],"1")) SetDOMINOWaveMode(1); else if (Match(Param[1],"0")) SetDOMINOWaveMode(0); else PrintUsage(); } // Switch delayed start on/off void DAQReadout::cmd_delayed() { if (Match(Param[1],"on")) SetDelayedStart(1); else if (Match(Param[1],"off")) SetDelayedStart(0); else PrintUsage(); } // Set trigger mode void DAQReadout::cmd_trigger() { if (Match(Param[1],"on")) HWTrigger(1); else if (Match(Param[1],"off")) HWTrigger(0); else PrintUsage(); } // Set serial number of board void DAQReadout::cmd_serial() { if (NParam==4 && Match(Param[3], "expert")) { if ((atoi(Param[1]) < FirstBoard) || (atoi(Param[1]) > LastBoard)) PrintMessage("Board number out of range (%d...%d)!\n",FirstBoard,LastBoard); else if (atoi(Param[2]) < 100 || atoi(Param[2]) >= 1000) PrintMessage("Serial number out of range (100...999)!\n"); else { PrintMessage("Flashing EEPROM of board %d...\n", atoi(Param[1])); (drs->GetBoard(atoi(Param[1])))->FlashEEPROM(atoi(Param[2])); } } else PrintMessage("You are not allowed to change the serial number!\n"); } // Do internal calibration void DAQReadout::cmd_calib() { if (NParam==4 && atof(Param[1]) && atof(Param[2])) CalibrateDRS(Param[3],atof(Param[1]),atof(Param[2])); else if (NParam==3 && atof(Param[1]) && atof(Param[2])) CalibrateDRS(NULL,atof(Param[1]),atof(Param[2])); else PrintUsage(); } // Set DRS sampling frequency void DAQReadout::cmd_freq() { if (NParam==3 && atof(Param[1]) && atoi(Param[2])) SetRegulatedDRSFrequency(atof(Param[1])); else if (NParam==2 && atof(Param[1])) SetDRSFrequency(atof(Param[1])); else PrintUsage(); } // Set LED void DAQReadout::cmd_led() { if (Match(Param[1], "on") || Match(Param[1], "off")) for (int i=FirstBoard; i<=LastBoard; i++) (drs->GetBoard(i))->SetLED(Match(Param[1], "on") ? 1 : 0); else PrintUsage(); } // Print status void DAQReadout::cmd_status() { double freq; if(NParam==1 || Match(Param[1],"daq")) { PrintMessage("********** DAQ STATUS **********\n" " DAQ: %s\n" " Run number: %d\n" " Run type: %c\n" " Event: %d\n" " Requested events per run: %d\n" " Storage directory: %s\n" " Disk space: %lu MByte\n" " Socket state: %s\n" " Total number of CMC boards: %d\n" " Active CMC boards: %d\n", daq_state_str[daq_state], daq_state==active ? (int) RunNumber:-1, daq_runtype_str[daq_runtype][0], NumEvents, NumEventsRequested, fRawDataPath, CheckDisk(fRawDataPath), Socket==-1 ? "disconnected":"connected", NumCMCBoards, LastBoard - FirstBoard + 1); for (int i=FirstBoard;i<=LastBoard;i++) PrintMessage(" Frequency of board %d set: %s\n",i,(DRSFreq[i]!=0 ? "yes":"no")); } if(NParam==1 || Match(Param[1],"drs")) { PrintMessage("\n********** DRS STATUS **********\n"); if (NumCMCBoards) { for (int i=FirstBoard; i<=LastBoard; i++) { PrintMessage(" Mezz. board index: %d\n" " Slot: %d %s\n",i,((drs->GetBoard(i))->GetSlotNumber() >> 1)+2,((drs->GetBoard(i))->GetSlotNumber() & 1)==0 ? "upper":"lower"); PrintMessage(" Chip version: DRS%d\n" " Board version: %d\n" " Serial number: %d\n" " Firmware revision: %d\n" " Temperature: %1.1lf C\n" " Status reg.: 0X%08X\n", (drs->GetBoard(i))->GetChipVersion(), (drs->GetBoard(i))->GetCMCVersion(), (drs->GetBoard(i))->GetCMCSerialNumber(), (drs->GetBoard(i))->GetFirmwareVersion(), (drs->GetBoard(i))->GetTemperature(), (drs->GetBoard(i))->GetStatusReg()); if ((drs->GetBoard(i))->GetStatusReg() & BIT_RUNNING) PrintMessage(" Domino wave running\n"); if ((drs->GetBoard(i))->GetStatusReg() & BIT_NEW_FREQ1) PrintMessage(" New Freq1 ready\n"); if ((drs->GetBoard(i))->GetStatusReg() & BIT_NEW_FREQ2) PrintMessage(" New Freq2 ready\n"); PrintMessage(" Control reg.: 0X%08X\n", (drs->GetBoard(i))->GetCtrlReg()); if ((drs->GetBoard(i))->GetCtrlReg() & BIT_AUTOSTART) PrintMessage(" AUTOSTART enabled\n"); if ((drs->GetBoard(i))->GetCtrlReg() & BIT_DMODE) PrintMessage(" DMODE circular\n"); else PrintMessage(" DMODE single shot\n"); if ((drs->GetBoard(i))->GetCtrlReg() & BIT_LED) PrintMessage(" LED\n"); if ((drs->GetBoard(i))->GetCtrlReg() & BIT_TCAL_EN) PrintMessage(" TCAL enabled\n"); if ((drs->GetBoard(i))->GetCtrlReg() & BIT_ZERO_SUPP) PrintMessage(" ZERO_SUPP enabled\n"); if ((drs->GetBoard(i))->GetCtrlReg() & BIT_FREQ_AUTO_ADJ) PrintMessage(" FREQ_AUTO_ADJ enabled\n"); if ((drs->GetBoard(i))->GetCtrlReg() & BIT_ENABLE_TRIGGER) PrintMessage(" ENABLE_TRIGGER\n"); if ((drs->GetBoard(i))->GetCtrlReg() & BIT_LONG_START_PULSE) PrintMessage(" LONG_START_PULSE\n"); if ((drs->GetBoard(i))->GetCtrlReg() & BIT_DELAYED_START) PrintMessage(" DELAYED_START\n"); if ((drs->GetBoard(i))->GetCtrlReg() & BIT_ACAL_EN) PrintMessage(" ACAL enabled\n"); PrintMessage(" Trigger bus: 0X%08X\n", (drs->GetBoard(i))->GetTriggerBus()); if ((drs->GetBoard(i))->IsBusy()) { (drs->GetBoard(i))->ReadFrequency(0, &freq); PrintMessage(" Frequency0: %1.4lf GHz\n", freq); (drs->GetBoard(i))->ReadFrequency(1, &freq); PrintMessage(" Frequency1: %1.4lf GHz\n", freq); } else PrintMessage(" Domino wave stopped\n"); } } else PrintMessage("No DRS boards available!\n\n"); } } // Adress DRS boards void DAQReadout::cmd_board() { if (Match(Param[1],"all")) { FirstBoard = 0; LastBoard = drs->GetNumberOfBoards()-1; } else if (NParam==2 && atoi(Param[1]) >= 0 && atoi(Param[1]) < NumCMCBoards) { FirstBoard = atoi(Param[1]); LastBoard = FirstBoard; } else if (NParam==3 && atoi(Param[1])>=0 && atoi(Param[1])0 && atoi(Param[2]) Execute shell command\n\n" "Items in <> are mandatory, in [] optional, | indicates mutual exclusive or.\n" "Test data can also be written if no DRS boards are available.\n" "Strings containing spaces have to be enclosed in \"double quotes\".\n"); } // Exit programm void DAQReadout::cmd_exit() { if (CmdFromSocket) { PrintMessage("Exit command not allowed over socket.\n"); return; } if (IsDAQBusy()) PrintMessage("Issue \"stop\" first to stop daq\n"); else { Exit = true; if(SocketThread != NULL) pthread_kill(*SocketThread, SIGUSR1); } } // Set/get mode of feedback void DAQReadout::cmd_fmode() { if(NParam==1) HVFB->GetFBMode(); else if(Match(Param[1],"off")) HVFB->SetFBMode(FB_Off); else if(Match(Param[1],"active")) HVFB->SetFBMode(FB_Active); else if(Match(Param[1],"targets")) HVFB->SetFBMode(FB_Targets); else PrintUsage(); } // Set/get current number of events void DAQReadout::cmd_faverage() { if(NParam==1) printf("Current number of feedback events: %u (acting when %u events are reached)\n", HVFB->GetCurrentCount(), HVFB->GetNumAverages()); else if(atoi(Param[1])>=0) HVFB->SetNumAverages(atoi(Param[1])); else PrintUsage(); } // Set/get feedback gain void DAQReadout::cmd_fgain() { if(NParam==1) printf("Feedback gain is %.2f\n", HVFB->GetGain()); else if(NParam==2) HVFB->SetGain(atof(Param[1])); else PrintUsage(); } // Set/get target value void DAQReadout::cmd_ftarget() { if(NParam==1) HVFB->GetTargets(); else if(NParam!=5) PrintUsage(); else { if(atoi(Param[1])>=0 && atoi(Param[1])=0 && atoi(Param[2])=0 && atoi(Param[3])SetTarget(atoi(Param[1]),atoi(Param[2]),atoi(Param[3]),atoi(Param[4])); else PrintMessage("Board, chip or channel number out of range.\n"); } } // Start response measurement void DAQReadout::cmd_fresponse() { if(NParam==1) HVFB->GetResponse(); else if(atof(Param[1]) && atof(Param[2])) HVFB->MeasureResponse(atof(Param[1]),atof(Param[2])); else PrintUsage(); } // Print feedback configuration void DAQReadout::cmd_fconfig() { HVFB->PrintConfig(); } // ---------------------------------------------- // ***** Utility function for DRS control ***** // ---------------------------------------------- // Start domino wave void DAQReadout::StartDRS() { for (int i=FirstBoard; i<=LastBoard; i++) drs->GetBoard(i)->StartDomino(); } // Stop domino wave void DAQReadout::StopDRS() { for (int i=FirstBoard; i<=LastBoard; i++) drs->GetBoard(i)->SoftTrigger(); } // Read current data void DAQReadout::ReadandPrintDRSData(int board, int chip, int channel) { if (board>LastBoard || boardkNumberOfChannels-1) { PrintMessage("Error: Select channel between %d and %d\n",0,kNumberOfChannels-1); return; } if (chip<0 || chip>1) { PrintMessage("Error: Select chip index between 0 and 1\n"); return; } PrintMessage("Waveform from board %d, chip %d, channel %d\n",board,chip,channel); PrintMessage("Note: The first number is the number of numbers that follows.\n"); ReadCalibratedDRSData(); // Note that all numbers must be separated by exactly one whitespace // to allow reading from client socket PrintMessage("==START== %d ",kNumberOfBins); for (int k=0; kGetBoard(i))->TransferWaves(kNumberOfChannels*kNumberOfChips); for (int ch=0; chGetBoard(i))->GetWave(0, ch, WaveForm[i][0][ch], true); // Chip #1 (drs->GetBoard(i))->GetWave(1, ch, WaveForm[i][1][ch], true); // Chip #2 } } } // Read calibration file bool DAQReadout::ReadCalibration() { char dir[MAX_COM_SIZE]; getcwd(dir, sizeof(dir)); strcat(dir,"/calib"); for (int i=FirstBoard; i<=LastBoard; i++) { (drs->GetBoard(i))->SetCalibrationDirectory(dir); PrintMessage("Reading response calibration file for board %d from: \"%s\"\n",i,dir); for (int Chip=0; ChipGetBoard(i)->GetResponseCalibration()->ReadCalibration(Chip)==false) return false; } return true; } // Check if calibration file has been read bool DAQReadout::IsCalibrationRead() { for (int i=FirstBoard; i<=LastBoard; i++) { for (int Chip=0; ChipGetBoard(i)->GetResponseCalibration()->IsRead(Chip))) { PrintMessage("Warning: Response calibration of board %d chip %d not yet read!\n",i,Chip); return false; } } return true; } // Stop DAQ void DAQReadout::StopRun() { if(daq_state != active) PrintMessage("DAQ is not active.\n"); else { Stop = true; PrintMessage("DAQ will stop.\n"); } } // Set DOMINO mode void DAQReadout::SetDOMINOMode(int mode) { if (NumCMCBoards) for (int i=FirstBoard; i<=LastBoard; i++) { (drs->GetBoard(i))->SetDominoMode(mode==1 ? 1:0); PrintMessage("Domino mode of board %d switched to %s.\n",i,mode==1 ? "continuous":"single shot"); } else PrintMessage("No DRS boards available\n"); } // Set DOMINO readout mode void DAQReadout::SetDOMINOReadMode(int mode) { if (NumCMCBoards) for (int i=FirstBoard; i<=LastBoard; i++) { (drs->GetBoard(i))->SetReadoutMode(mode==1 ? 1:0); PrintMessage("Start readout of board %d from %s.\n",i,mode==1 ? "first bin":"stop position"); } else PrintMessage("No DRS boards available\n"); } // Set DOMINO wave mode void DAQReadout::SetDOMINOWaveMode(int mode) { if (NumCMCBoards) for (int i=FirstBoard; i<=LastBoard; i++) { (drs->GetBoard(i))->SetDominoActive(mode==1 ? 1:0); PrintMessage("Domino wave of board %d is %s during readout\n",i,mode==1 ? "running":"stopped"); } else PrintMessage("No DRS boards available\n"); } // Delayed start on/off void DAQReadout::SetDelayedStart(int mode) { if (NumCMCBoards) for (int i=FirstBoard; i<=LastBoard; i++) { (drs->GetBoard(i))->SetDelayedStart(mode==1 ? 1:0); PrintMessage("Delayed start of board %d is %s\n",i,mode==1 ? "on":"off"); } else PrintMessage("No DRS boards available\n"); } // Enable hardware trigger of all boards void DAQReadout::HWTrigger(int mode) { if (NumCMCBoards) for (int i=FirstBoard; i<=LastBoard; i++) { drs->GetBoard(i)->EnableTrigger(mode==1 ? 1:0); PrintMessage("Hardware trigger of board %d %s\n",i,mode==1 ? "enabled":"disabled"); } else PrintMessage("No DRS boards available\n"); } // Read the frequency of all boards double DAQReadout::ReadDRSFrequency() { double freq = 0; if (NumCMCBoards) for (int i=FirstBoard; i<=LastBoard; i++) { (drs->GetBoard(i))->ReadFrequency(0, &freq); PrintMessage("Domino wave of board %d is running at %1.3lf GHz\n",i,freq); } else PrintMessage("No DRS boards available\n"); return freq; } // Set DRS sampling frequency void DAQReadout::SetDRSFrequency(double freq) { double currentfreq; if (NumCMCBoards) { PrintMessage("Setting frequency without regulation:\n"); for (int i=FirstBoard; i<=LastBoard; i++) { drs->GetBoard(i)->SetDebug(1); if (drs->GetBoard(i)->SetFrequency(freq)) { drs->GetBoard(i)->ReadFrequency(0, ¤tfreq); DRSFreq[i] = freq; PrintMessage("Domino wave of board %d is running at %1.3lf GHz\n",i,currentfreq); } else { DRSFreq[i] = 0; PrintMessage("Warning: domino wave of board %d has changed but not reached the requested value\n",i); } } } else PrintMessage("No DRS boards available\n"); } // Regulate DRS sampling frequency void DAQReadout::SetRegulatedDRSFrequency(double freq) { double currentfreq; if (NumCMCBoards) { PrintMessage("Setting frequency with regulation:\n"); for (int i=FirstBoard; i<=LastBoard; i++) { drs->GetBoard(i)->SetDebug(1); if (drs->GetBoard(i)->RegulateFrequency(freq)) { drs->GetBoard(i)->ReadFrequency(0, ¤tfreq); PrintMessage("Domino wave of board %d is running at %1.3lf GHz\n",i,currentfreq); DRSFreq[i] = freq;; } else DRSFreq[i] = 0; } } else PrintMessage("No DRS boards available\n"); } // Do internal calibration void DAQReadout::CalibrateDRS(char *dir, double trigfreq, double calibfreq) { int i,j; char str[MAX_COM_SIZE]; DIR *pdir; if (NumCMCBoards) { if(dir!=NULL) { if ((pdir=opendir(str))==0){ PrintMessage("Error: target directory \"%s\" does not exist!\n",str); return; } closedir(pdir); sprintf(str,"%s",dir); PrintMessage("Target: \"%s\"\n",str); } else { getcwd(str, sizeof(str)); strcat(str,"/calib"); PrintMessage("Taking default target: \"%s/\"\n",str); } for (i=FirstBoard; i<=LastBoard; i++) { drs->GetBoard(i)->Init(); drs->GetBoard(i)->SetFrequency(calibfreq); drs->GetBoard(i)->SoftTrigger(); PrintMessage("Creating calibration of board %d\n", drs->GetBoard(i)->GetCMCSerialNumber()); drs->GetBoard(i)->EnableTcal(1); PrintMessage("Tcal enabled"); if (drs->GetBoard(i)->GetChipVersion() == 3) drs->GetBoard(i)->GetResponseCalibration()->SetCalibrationParameters(1,21,0,20,0,0,0,0,0); else drs->GetBoard(i)->GetResponseCalibration()->SetCalibrationParameters(1,36,110,20,19,40,15,trigfreq,0); drs->GetBoard(i)->SetCalibrationDirectory(str); PrintMessage("Storage directory \"%s\"\n",str); for (j=0;j<2;j++) { drs->GetBoard(i)->GetResponseCalibration()->ResetCalibration(); PrintMessage("Calibration reset done.\n"); while (!drs->GetBoard(i)->GetResponseCalibration()->RecordCalibrationPoints(j)) {} PrintMessage("Record calibration points done.\n"); while (!drs->GetBoard(i)->GetResponseCalibration()->FitCalibrationPoints(j)) {} PrintMessage("Calibration points fitted.\n"); while (!drs->GetBoard(i)->GetResponseCalibration()->OffsetCalibration(j)) {} PrintMessage("Offset calibration done.\n"); if (!drs->GetBoard(i)->GetResponseCalibration()->WriteCalibration(j)) break; } drs->GetBoard(i)->Init(); // Reset linear range -0.2 ... 0.8 V } // Loop over boards } else PrintMessage("No DRS boards available\n"); } // Check if DAQ is busy bool DAQReadout::IsDAQBusy() { if (daq_state == active) { PrintMessage("DAQ is busy\n"); return true; } else return false; } // Check if DRS is sampling bool DAQReadout::IsDRSBusy() { for (int i=FirstBoard; i<=LastBoard; i++) if ((drs->GetBoard(i))->IsBusy()) return true; return false; } // Check if DRS frequency is set bool DAQReadout::IsDRSFreqSet() { for (int i=FirstBoard;i<=LastBoard;i++) if (DRSFreq[i]==0) { PrintMessage("DRS sampling frequency of board %d not set!\n",i); return false; } return true; } // Open new raw data file bool DAQReadout::OpenRawFile(int Part) { time_t rawtime; struct tm *timeinfo; char RunDate[MAX_COM_SIZE], Buffer[MAX_COM_SIZE], SystemCommand[MAX_COM_SIZE]; int TempDescriptor; // Write run date to status structure time(&rawtime); timeinfo = localtime(&rawtime); sprintf(RunDate,"%d%02d%02d",timeinfo->tm_year + 1900,timeinfo->tm_mon + 1,timeinfo->tm_mday); // Create direcory if not existing (ignore error if already existing) and change to it sprintf(Buffer, "%s/%s", fRawDataPath, RunDate); if(mkdir(Buffer, S_IRWXU|S_IRWXG)==-1 && errno!=EEXIST) { PrintMessage("\rError: Could not create direcory \"%s\" (%s)\n", Buffer, strerror(errno)); return false; } // Determine new run number in directory (only if first file in series) by finding the // last file in alphabetical order and assuming that run number starts at position 9 if(Part==0) { char *TmpName = tmpnam(NULL); sprintf(SystemCommand, "ls -1 %s/*.raw 2>/dev/null|tail -n-1 >%s", Buffer, TmpName); system(SystemCommand); if ((TempDescriptor=open(TmpName,O_RDONLY)) == -1) { PrintMessage("Error: Could not determine last run number (%s)\n",strerror(errno)); return false; } memset(Buffer,0,sizeof(Buffer)); read(TempDescriptor, Buffer, sizeof(Buffer)); close(TempDescriptor); remove(TmpName); if(sscanf(Buffer, "%*28c%u", &RunNumber) == 1) RunNumber++; else RunNumber = 0; } // Generate filename sprintf(FileName,"%s/%s/%s_%.8d_%s_%c_%d.raw", fRawDataPath, RunDate, RunDate,RunNumber,Source,daq_runtype_str[daq_runtype][0],Part); // Open file with rwx right for owner and group, never overwrite file TempDescriptor = open(FileName,O_WRONLY|O_CREAT|O_EXCL, S_IRWXU|S_IRWXG); if(TempDescriptor==-1) { PrintMessage("\rError: Could not open file \"%s\"\n",FileName); perror("Error"); return false; } Rawfile = fdopen(TempDescriptor,"w"); return true; } // Write run header and board structures void DAQReadout::WriteRunHeader() { time_t time_now_secs; struct tm *time_now; RHeader->MagicNum = MAGICNUM_FILE_OPEN; RHeader->DataFormat = DATA_FORMAT; strcpy(RHeader->DAQVersion, __DATE__); strcpy(RHeader->Source, Source); RHeader->Type = daq_runtype_str[daq_runtype][0]; RHeader->RunNumber = RunNumber; time(&time_now_secs); time_now = localtime(&time_now_secs); RHeader->StartYear = 1900 + time_now->tm_year; RHeader->StartMonth = 1 + time_now->tm_mon; RHeader->StartDay = time_now->tm_mday; RHeader->StartHour = time_now->tm_hour; RHeader->StartMinute = time_now->tm_min; RHeader->StartSecond = time_now->tm_sec; RHeader->SourceRA = -1; RHeader->SourceDEC = -1; RHeader->TelescopeRA = -1; RHeader->TelescopeDEC = -1; RHeader->NCMCBoards = NumCMCBoards==0 && daq_runtype==test ? 1 : (LastBoard - FirstBoard) + 1; RHeader->NChips = kNumberOfChips; RHeader->NChannels = kNumberOfChannels; RHeader->Offset = fFirstSample; RHeader->Samples = fLastSample - fFirstSample + 1; if(fwrite(RHeader, sizeof(RunHeader), 1, Rawfile) != 1) { PrintMessage("Error: Could not write run header, terminating run (%s)\n", strerror(errno)); Stop = true; } for (int i=FirstBoard; i<=LastBoard; i++) { BStruct[i].Index = i; BStruct[i].SerialNo = drs->GetBoard(i)->GetCMCSerialNumber(); BStruct[i].BoardTemp = drs->GetBoard(i)->GetTemperature(); BStruct[i].NomFreq = DRSFreq[i]; BStruct[i].ScaleFactor = drs->GetBoard(i)->GetPrecision(); } // In case no boards are available, dummy data is written for one board structure if (NumCMCBoards == 0) { LastBoard=0; BStruct[0].NomFreq = 1; BStruct[0].ScaleFactor = 0.1; } if(fwrite(BStruct, sizeof(BoardStructure), LastBoard-FirstBoard+1, Rawfile) != (unsigned int) (LastBoard-FirstBoard+1)) { PrintMessage("Error: Could not write (all) board structures, terminating run (%s)\n", strerror(errno)); Stop = true; } if (NumCMCBoards == 0) LastBoard=-1; } // Update the run header void DAQReadout::UpdateRunHeader(unsigned int Events) { time_t time_now_secs; struct tm *time_now; RHeader->MagicNum = MAGICNUM_FILE_CLOSED; RHeader->Events = Events; time(&time_now_secs); time_now = localtime(&time_now_secs); RHeader->EndYear = 1900 + time_now->tm_year; RHeader->EndMonth = 1 + time_now->tm_mon; RHeader->EndDay = time_now->tm_mday; RHeader->EndHour = time_now->tm_hour; RHeader->EndMinute = time_now->tm_min; RHeader->EndSecond = time_now->tm_sec; rewind(Rawfile); if(fwrite(RHeader, sizeof(RunHeader), 1, Rawfile) != 1) { PrintMessage("Error: Could not write updated run header, terminating run (%s)\n", strerror(errno)); Stop = true; } } // Write event header void DAQReadout::WriteEventHeader() { time_t time_now_secs; struct tm *time_now; struct timezone tz; struct timeval actual_time; strcpy(EHeader->Name,"EVTH"); EHeader->EventNumber = NumEvents; EHeader->TriggerType = 0XFFFF; time(&time_now_secs); time_now = localtime(&time_now_secs); gettimeofday(&actual_time, &tz); EHeader->TimeSec = time_now->tm_sec + actual_time.tv_usec/1000000.; if(fwrite(EHeader, sizeof(EventHeader), 1, Rawfile) != 1) { PrintMessage("Error: Could not write event header, terminating run (%s)\n", strerror(errno)); Stop = true; } } // Print usage text for command void DAQReadout::PrintUsage() { PrintMessage("Usage: %s %s\n", CommandList[CmdNumber].Name, CommandList[CmdNumber].Parameters); } // Print message to selected target void DAQReadout::PrintMessage(int Target, char *Format, ...) { va_list ArgumentPointer; va_start(ArgumentPointer, Format); PrintMessage(Target, Format, ArgumentPointer); va_end(ArgumentPointer); } // Print message to screen, log file and socket void DAQReadout::PrintMessage(char *Format, ...) { va_list ArgumentPointer; va_start(ArgumentPointer, Format); PrintMessage(MsgToConsole|MsgToLog|MsgToSocket, Format, ArgumentPointer); va_end(ArgumentPointer); } // Function doing the actual printing work void DAQReadout::PrintMessage(int Target, char *Format, va_list ArgumentPointer) { char Textbuffer[MAX_COM_SIZE]; memset(Textbuffer, 0, sizeof(Textbuffer)); vsprintf(Textbuffer, Format, ArgumentPointer); // Print to console and generate new prompt if(Target & MsgToConsole) { if(strlen(Textbuffer)>0 && Textbuffer[strlen(Textbuffer)-1]=='\n') printf("\r%s", Textbuffer); else printf("%s", Textbuffer); // New prompt only after newline if(Textbuffer[strlen(Textbuffer)-1]=='\n' || strlen(Textbuffer)==0) { if (NumCMCBoards == 0) printf("\rDAQ> "); else if (FirstBoard == LastBoard) printf("\rDAQ|B%d> ",FirstBoard); else printf("\rDAQ|B%d-%d> ",FirstBoard,LastBoard); fflush(stdout); } } // Print to log file and socket only if length not zero (then only prompt) if (strlen(Textbuffer)>0) { if((Target & MsgToLog) && Logfile!=NULL) { fprintf(Logfile, "%s", Textbuffer); fflush(Logfile); } if((Target & MsgToSocket) && Socket!=-1) write(Socket, Textbuffer, strlen(Textbuffer)); } } // --------------------------------------- // ***** Various utility functions ***** // --------------------------------------- // Check if two strings match (min 1 character must match) int Match(char *str, char *cmd) { return strncasecmp(str,cmd,strlen(str)==0 ? 1:strlen(str)) ? 0:1; } // Return current available storage space in given directory int CheckDisk(char *Directory) { struct statfs FileSystemStats; statfs(Directory, &FileSystemStats); return FileSystemStats.f_bavail / 1024 * (FileSystemStats.f_bsize / 1024); } // Parse command line for white space and double-quote separated tokens int ParseInput(char* Command, char *Param[]) { int Count=0; while(CountHVFB->ClearAverages(); m->NumEvents = 0; gettimeofday(&StartTime, NULL); m->PrintMessage("\rStarting run #%d (%s) on \"%s\" with %u event(s)\n",m->RunNumber,daq_runtype_str[m->daq_runtype],m->Source,m->NumEventsRequested); do { // Check if enough disk space is left if (CheckDisk(m->fRawDataPath) <= m->fMinDiskSpaceMB+m->fMaxFileSizeMB) { m->PrintMessage("\rError: Disk space after next file (max. %d MByte) below %d MByte\n",m->fMaxFileSizeMB,m->fMinDiskSpaceMB); break; } // Init run header, open raw file, write run header if (!m->OpenRawFile(Filepart)) break; m->PrintMessage("\rData file \"%s\" opened.\n",m->FileName); EventsInFile = 0; m->WriteRunHeader(); if (m->daq_runtype != test) m->StartDRS(); // Take data until finished, stopped or file too large while (m->NumEventsNumEventsRequested && !m->Stop && ftell (m->Rawfile)/1024/1024fMaxFileSizeMB) { if (m->daq_runtype == data) while (m->IsDRSBusy()); // Wait for hardware trigger (if DAQ stopped, DRS will not be busy anymore) else if (m->daq_runtype == pedestal) m->StopDRS(); // Wait for software trigger EventsInFile++; m->NumEvents++; m->WriteEventHeader(); // Read event data via VME or generate test data (for one board if no boards available) if (m->daq_runtype != test) { m->ReadCalibratedDRSData(); m->StartDRS(); // Restart here: writing data is in parallel to waiting for next trigger } else { double Period = ((double) rand())/RAND_MAX*20; for (long int i=0; i<(m->NumCMCBoards>0 ? m->NumCMCBoards : 1)*kNumberOfChips*kNumberOfChannels*kNumberOfBins; i++) *((short *) m->WaveForm+i) = (short) (sin(i/Period)*1000); } // Write data to disk for (int i=m->FirstBoard; i<=m->LastBoard + (m->NumCMCBoards==0); i++) { for (unsigned int k=0; kRHeader->NChips*m->RHeader->NChannels; k++) if(fwrite((short *) m->WaveForm[i] + m->RHeader->Offset + k*kNumberOfBins, sizeof(short), m->RHeader->Samples, m->Rawfile) != m->RHeader->Samples) { m->PrintMessage("Error: Could not write event data, terminating run ()\n", strerror(errno)); m->Stop = true; } } // Call feedback to process event m->HVFB->ProcessEvent(); } // Write updated run header, close file RunSize += ftell (m->Rawfile); m->UpdateRunHeader(EventsInFile); fclose(m->Rawfile); m->PrintMessage("Data file closed.\n"); Filepart += 1; } while(m->NumEvents < m->NumEventsRequested && !m->Stop); m->StopDRS(); m->PrintMessage("\r%s run #%d %s (%d event(s))\n",daq_runtype_str[m->daq_runtype],m->RunNumber,(m->NumEvents == m->NumEventsRequested) ? "completed":"stopped",m->NumEvents); if (m->NumEvents>0) { gettimeofday(&StopTime, NULL); float RunTime = StopTime.tv_sec-StartTime.tv_sec + (StopTime.tv_usec-StartTime.tv_usec)*1e-6; m->PrintMessage("Time for run %.2f seconds, trigger rate %.2f Hz.\n", RunTime, m->NumEvents/RunTime); m->PrintMessage("Run size %llu MByte, data rate %.1f MByte/s.\n", RunSize/1024/1024, RunSize/1024.0/1024/RunTime); } m->daq_state = stopped; }