Auxiliary program to convert multiple Monte Carlo events to DAQ timeslices. More...

#include <string>
#include <iostream>
#include <fstream>
#include "TRandom3.h"
#include "km3net-dataformat/offline/Head.hh"
#include "km3net-dataformat/offline/MultiHead.hh"
#include "km3net-dataformat/offline/Evt.hh"
#include "km3net-dataformat/offline/Hit.hh"
#include "JAAnet/JAAnetToolkit.hh"
#include "JAAnet/JEvtEvaluator.hh"
#include "JDetector/JCLBDefaultSimulator.hh"
#include "JDetector/JDetector.hh"
#include "JDetector/JDetectorSimulator.hh"
#include "JDetector/JDetectorToolkit.hh"
#include "JDetector/JPMTParametersMap.hh"
#include "JDetector/JK40DefaultSimulator.hh"
#include "JDetector/JPMTDefaultSimulator.hh"
#include "JDAQ/JDAQSummarysliceIO.hh"
#include "JDAQ/JDAQTimesliceIO.hh"
#include "JTimeslice/JEventTimeslice.hh"
#include "JTimeslice/JRandomTimeslice.hh"
#include "JSupport/JFileRecorder.hh"
#include "JSupport/JMeta.hh"
#include "JSupport/JMonteCarloFileSupportkit.hh"
#include "JSupport/JMultipleFileScanner.hh"
#include "JSupport/JSupport.hh"
#include "JSupport/JTreeScanner.hh"
#include "JSupport/JTreeScannerInterface.hh"
#include "Jeep/JParser.hh"
#include "Jeep/JMessage.hh"

Functions
int	main (int argc, char **argv)

Detailed Description

Auxiliary program to convert multiple Monte Carlo events to DAQ timeslices.

Events are timed according to a given rate (if > 0), otherwise they are timed according to Evt::mc_t.

Author: mdejong, mlincett

Definition in file JEventTimesliceWriter.cc.

Function Documentation

◆ main()

int main	(	int	argc,
		char **	argv
	)

Definition at line 46 of file JEventTimesliceWriter.cc.

 {
   using namespace std;
   using namespace JPP;
   using namespace KM3NETDAQ;
  
  
   JMultipleFileScanner<JAAnetTypes_t>  inputFile;
   JFileRecorder       <JTYPELIST<JAAnetTypes_t, JDAQTimesliceL0, JMeta, JRootTypes_t>::typelist>  outputFile;
   JLimit_t&              numberOfEvents = inputFile.getLimit();
   string                 detectorFile;
   int                    run;
   JPMTParametersMap      pmtParameters;
   JK40Rates              rates_Hz;
   double                 eventRate_Hz;
   UInt_t                 seed;
   int                    debug;
  
   try { 
  
     JParser<> zap("Auxiliary program to convert multiple Monte Carlo events to time slices.");
     
     zap['f'] = make_field(inputFile);
     zap['o'] = make_field(outputFile)          = "timeslice.root";
     zap['n'] = make_field(numberOfEvents)      = JLimit::max();
     zap['a'] = make_field(detectorFile);
     zap['R'] = make_field(run)                 = 1;
     zap['P'] = make_field(pmtParameters)       = JPARSER::initialised();
     zap['B'] = make_field(rates_Hz)            = JPARSER::initialised();
     zap['r'] = make_field(eventRate_Hz);
     zap['S'] = make_field(seed)                = 0;
     zap['d'] = make_field(debug)               = 0;
     
     zap(argc, argv);
   }
   catch(const exception &error) {
     FATAL(error.what() << endl);
   }
  
   gRandom->SetSeed(seed);
  
  
   setDAQLongprint(debug >= JEEP::debug_t);
   
   if (pmtParameters.getQE() != 1.0) {
  
     WARNING("Correct background rates with global efficiency " << pmtParameters.getQE() << endl);
     
     rates_Hz.correct(pmtParameters.getQE());
   }
  
   // parameters
  
   DEBUG("PMT paramaters: " << endl << pmtParameters << endl);
   DEBUG("K40 rates:      " << endl << rates_Hz      << endl);
  
   if (eventRate_Hz < 0.0) {
     FATAL("Invalid event rate " << eventRate_Hz << "; consider using JRandomTimesliceWriter." << endl);
   }
   
   // detector
   
   JDetector detector;
  
   try {
     load(detectorFile, detector);
   }
   catch(const JException& error) {
     FATAL(error);
   }
   
   // header
   
   Head header;
   
   try {
     header = getHeader(inputFile);
   }
   catch (const exception& error) {
     FATAL("Monte Carlo header is invalid");
   }
   
   double liveTimeMC = JHead(header).livetime.numberOfSeconds;
  
   if (liveTimeMC < 0) {
     FATAL("Monte Carlo live time is negative; input file may be corrupted.");
   }
  
   // background simulator
  
   JPMTParametersMap::Throw(false);
  
   JDetectorSimulator simbad(detector);
  
   simbad.reset(new JPMTDefaultSimulator(pmtParameters, detector));
   simbad.reset(new JK40DefaultSimulator(rates_Hz));
   simbad.reset(new JCLBDefaultSimulator());
  
   // output file
   
   outputFile.open();
  
   if (!outputFile.is_open()) {
     FATAL("Error opening file " << outputFile << endl);
   }
   
   outputFile.put(*gRandom);
   outputFile.put(JMeta(argc, argv));
   outputFile.put(header);
  
   // input stream;
   
   bool absTime = false;
   
   JTreeScannerInterface<Evt>* scan;
  
   if (eventRate_Hz == 0.0 && liveTimeMC == 0.0) {
     
     NOTICE("Event will be timed according to absolute MC time." << endl);
     
     absTime = true;
     
     // sorted access;
     scan = new JTreeScanner<Evt, JEvtEvaluator>(inputFile);
     JTreeScanner<Evt, JEvtEvaluator>::debug = debug;
     
   } else {
     
     // unsorted access;
     scan = new JTreeScanner<Evt>(inputFile);
     JTreeScanner<Evt>::debug = debug;
     
     if (eventRate_Hz == 0.0 && liveTimeMC > 0.0) {
       int nEntries = scan->getEntries();
       eventRate_Hz = nEntries / liveTimeMC;
       DEBUG(nEntries << " events to be written." << endl);
       NOTICE("MC live time is " << liveTimeMC << " s" << endl);
       NOTICE("Event rate set to " <<  eventRate_Hz << " Hz from MC header." << endl);
     } 
   }
   
   // begin timeslice generation;
   
   // state variables;
   bool pendingEvt       = false;
   bool pendingTimeslice = false;
   
   Evt* event = NULL; // pending event;
   
   JTimeRange timeRange;
   double tDAQ = 0; // DAQ event time;
   double tOff = 0; // hit production time offset;
   
   int frame_index = 0;
   JDAQChronometer chronometer;
   JRandomTimeslice timeslice; 
   
   counter_type evtCount = 0;
  
   while (pendingEvt || scan->hasNext()) {
  
     if (!pendingTimeslice) {
       // update background timeslice;
       frame_index++;
       chronometer = JDAQChronometer(detector.getID(), run, frame_index, JDAQUTCExtended(getTimeOfFrame(frame_index)));
       timeslice = JRandomTimeslice(chronometer, simbad);
       DEBUG("evt count: " << setw(10) << evtCount << endl); 
       STATUS("frame index: " << setw(10) << frame_index << " | evt count: " << setw(10) << evtCount << "\r"); DEBUG(endl);
       pendingTimeslice = true;
     }
     
     if (!pendingEvt) {
       // get new event;
       event = scan->next();
       timeRange = getTimeRange(*event);
       tOff = timeRange.is_valid() ? timeRange.getLowerLimit() : 0;
       // update DAQ time according to absolute or random;
       if (absTime)
         tDAQ  = getEvtValue(*event) + tOff;
       else
         tDAQ += gRandom->Exp(1.0e9 / eventRate_Hz);
       
       DEBUG("event time [s] " << setprecision(5) << tDAQ * 1.0e-9 << endl);
       pendingEvt = true;
     }
     
     // DEBUG("tDAQ : " << tDAQ << " - frame index: " << frame_index << " - DAQ frame index " << getFrameIndex(tDAQ) << endl);
     if (getFrameIndex(tDAQ) == frame_index) {
       
       // process event;
       if (timeRange.is_valid()) {
         DEBUG(*event << endl);
         // real start time of the hits will be always tDAQ;
         event->mc_t = tDAQ - tOff;
         timeslice.add(JEventTimeslice(chronometer, simbad, *event));
         evtCount++;
       }
       // event processed;
       outputFile.put(*event);
       pendingEvt = false;
     } else {
       // event time is past end of timeslice;
       DEBUG(timeslice << endl);
       outputFile.put(timeslice);
       pendingTimeslice = false;
     }
     
   }
   
   if (pendingTimeslice) {
     DEBUG(timeslice << endl);
     outputFile.put(timeslice);
     pendingTimeslice = false;
   }
   
   STATUS(endl);
  
   outputFile.put(*gRandom);
   outputFile.close();
   
   NOTICE(evtCount << " events written over " << frame_index << " timeslices. " << endl);
 }

Functions

Detailed Description

Function Documentation

◆ main()