/* ======================================================================== *\ ! ! * ! * This file is part of MARS, the MAGIC Analysis and Reconstruction ! * Software. It is distributed to you in the hope that it can be a useful ! * and timesaving tool in analysing Data of imaging Cerenkov telescopes. ! * It is distributed WITHOUT ANY WARRANTY. ! * ! * Permission to use, copy, modify and distribute this software and its ! * documentation for any purpose is hereby granted without fee, ! * provided that the above copyright notice appear in all copies and ! * that both that copyright notice and this permission notice appear ! * in supporting documentation. It is provided "as is" without express ! * or implied warranty. ! * ! ! ! Author(s): Thomas Bretz, 11/2002 ! ! Copyright: MAGIC Software Development, 2000-2003 ! ! \* ======================================================================== */ ///////////////////////////////////////////////////////////////////////////// // // MCT1ReadPreProc // // Reads a output file of the CT1 preproc. // // Implements usage of a selector (see MRead) Use such a filter to skip // events before reading! But never use a filter which needs read data // as input... // // Input Containers: // -/- // // Output Containers: // MCerPhotEvt the data container for all data. // MPedPhotCam CT1 pedestals // MMcEvt monte carlo data container for MC files // MMcTrig mc data container for trigger information // MSrcPosCam source position in the camera // MBlindPixels Array holding blind pixels // ///////////////////////////////////////////////////////////////////////////// #include "MCT1ReadPreProc.h" #include #include #include #define LINUX #define HISTO void #define HBOOK_FILE int #include "defines.h" #include "structures.h" #include "MLog.h" #include "MLogManip.h" #include "MTime.h" #include "MFilter.h" #include "MParList.h" #include "MCerPhotEvt.h" #include "MPedPhotPix.h" #include "MPedPhotCam.h" #include "MGeomCam.h" #include "MSrcPosCam.h" #include "MBlindPixels.h" #include "MRawRunHeader.h" #include "MTaskList.h" #include "MMcEvt.hxx" #include "MMcTrig.hxx" #include "MBinning.h" #include "TRandom3.h" #include "MParameters.h" ClassImp(MCT1ReadPreProc); using namespace std; // -------------------------------------------------------------------------- // // Default constructor. Creates an array which stores the file names of // the files which should be read. If a filename is given it is added // to the list. // MCT1ReadPreProc::MCT1ReadPreProc(const char *fname, const char *name, const char *title) : fIn(NULL), fEntries(0) { fName = name ? name : "MRead"; fTitle = title ? title : "Reads a CT1 preproc data file"; // // remember file name for opening the file in the preprocessor // fFileNames = new TList; fFileNames->SetOwner(); if (fname) AddFile(fname); } // -------------------------------------------------------------------------- // // Delete the filename list and the input stream if one exists. // MCT1ReadPreProc::~MCT1ReadPreProc() { delete fFileNames; if (fIn) delete fIn; } // -------------------------------------------------------------------------- // // Add this file as the last entry in the chain // Int_t MCT1ReadPreProc::AddFile(const char *txt, int) { const char *name = gSystem->ExpandPathName(txt); TString fname(name); delete [] name; if (!CheckHeader(fname)) { *fLog << warn << "WARNING - Problem reading header... ignored." << endl; return 0; } const Int_t n = GetNumEvents(fname); if (n==0) { *fLog << warn << "WARNING - File contains no data... ignored." << endl; return 0; } fEntries += n; *fLog << inf << "File " << txt << " contains " << n << " events (Total=" << fEntries << ")" << endl; fFileNames->AddLast(new TNamed(txt, "")); return 1; } // -------------------------------------------------------------------------- // // Print data from the header to the screen and analyse the header data, // means store and copy the needed data into Mars structures and // data members // void MCT1ReadPreProc::ProcessRunHeader(const struct outputpars &outpars) { if (outpars.inumpixels != iMAXNUMPIX) *fLog << warn << "WARNING! File doesn't contain " << iMAXNUMPIX << " Pixels... maybe corrupt." << endl; fNumEventsInRun = 0; // // ------------------- Output some stuff ----------------------- // // int itelescope; // number of the CT which took the data *fLog << inf << "Telescope: CT" << outpars.itelescope; // float flongitude_deg; // longitude (counted positive towards West) of CT position */ // float flatitude_deg; // latitude (counted positive towards North) of CT position */ *fLog << " located @ Longitude=" << outpars.flongitude_deg; *fLog << "deg Latitude=" << outpars.flatitude_deg << "deg" << endl; // int irunnum; // run number (from parameters file) fRawRunHeader->SetRunNumber(outpars.irunnum); fRawRunHeader->SetReadyToSave(); // enum onoroff {NEITHER_ON_NOR_OFF, OFF_SOURCE, ON_SOURCE} eruntype; // runtype *fLog << "Run: #" << outpars.irunnum << " ("; switch (outpars.eruntype) { case NEITHER_ON_NOR_OFF: *fLog << "unknown"; break; case OFF_SOURCE: *fLog << "off-source"; break; case ON_SOURCE: *fLog << "on-source"; break; default: *fLog << (int)outpars.eruntype; break; } *fLog << ", "; switch (outpars.etrackmode) { case NORMAL: *fLog << "normal tracking"; break; case REVERSE: *fLog << "reverse tracking"; break; case DUNNO: *fLog << "unknown tracking"; break; default: *fLog << (int)outpars.etrackmode; break; } *fLog << ")" << endl; //double dsourcera_hours; // right ascension of observed source in hours //double dsourcedec_deg; // declination of observed source in degrees *fLog << "Source: RA=" << outpars.dsourcera_hours << "h DEC="; *fLog << outpars.dsourcedec_deg << "deg" << endl; //int inummuonpixels; // number of pixels in the muon shield //int inumcointdcs; // number of coincidence tdcs recorded in the runfile //float fpixdiameter_deg; // smallest pixel diameter (degrees) (from parameters file) */ // enum axes {RA, DEC, ALT, AZ} ese1_is; // name of the axis to which shaft encoder 1 is attached (implies the type of mount) *fLog << "Shaftencoder 1 @ "; switch (outpars.ese1_is) { case RA: *fLog << "RA"; break; case DEC: *fLog << "DEC"; break; case ALT: *fLog << "ALT"; break; case AZ: *fLog << "AZ"; break; default: *fLog << (int)outpars.ese1_is; break; } *fLog << endl; // int isezeropos[2]; // zero position of shaftencoders 1 and 2 (from parameters file) *fLog << "SE Zero: SE(1)=" << outpars.isezeropos[0] << " "; *fLog << "SE(2)=" << outpars.isezeropos[1] << endl; // int iaz_rev_track_corr; // correction for the azimuth shaft encoder (ALT/AZ mount only) in reverse tracking mode // int ialt_rev_track_corr; // correction for the altitude shaft encoder (ALT/AZ mount only) in reverse tracking mode *fLog << "Reverse tracking corrections: SE(az)=" << outpars.iaz_rev_track_corr; *fLog << " SE(alt)=" << outpars.ialt_rev_track_corr << endl; // float fbendingcorr; // bending correction factor (ALT/AZ mount only) // float fextinction; // atmospheric extinction (typically taken from the Carlsberg Meridian Circle data) *fLog << "Bending: Correction factor=" << outpars.fbendingcorr << " "; *fLog << "Extinction=" << outpars.fextinction << endl; // Boolean bdontusepix[iMAXNUMPIX]; // bdontusepix is set true if the pixel should not be used in image analysis, otherwise it is true; fBlinds->Clear(); *fLog << "Don't use pixels: "; for (int i=0; iSetPixelBlind(i); } *fLog << endl; *fLog << "Exclude pixels: "; // Boolean bexcludepix[iMAXNUMPIX]; for (int i=0; iSetPixelBlind(i); } *fLog << endl; // save blind pixels for all events of this run fBlnd.Set(iMAXNUMPIX); for (int i=0; iIsBlind(i) ? 1 : 0; fBlinds->SetReadyToSave(); /* bexcludepix[] is set TRUE (== exclude from pedestal, Laser * calibration and the further analysis) when the Mean value * of a pixel inside a pedestal Run is larger than 50 or ( || ) * if the pedestal RMS value of this pixel is larger than 5.0 * This is reflected in the (new for versions >= 0.4) * variable "pixonoff" in the ntuple written by preproc: * preproc.nt.hbook * * When the pixel is excluded by the user it will get a -2 otherwise * pixonoff = 0. * Additive to this a -1 is added when preproc excludes the pixel * for a given Run. So the actual value tells you whether you caught * it already by hand or not. * * A plot of pixonoff may also be handy to tell you the status of your * ADC equipment. */ // float fphotoel_per_adccnt[iMAXNUMPIX]; // conversion factors for the pixel signals */ /* float padc = outpars.fphotoel_per_adccnt[0]; *fLog << "Phe/ADC (pixel 0): " << padc << endl; for (int i=0; iSetXY(-outpars.fypointcorr_deg/fGeom->GetConvMm2Deg(), -outpars.fxpointcorr_deg/fGeom->GetConvMm2Deg()); fSrcPos->SetReadyToSave(); /* --- USEFULL? NEEDED? --- float fcamera_align_angle_deg; // the angle between the camera y-axis and the meridian when a culminating object is observed (defined counter-clockwise looking at the sky) int iratecalc_numevents_odd; // number of events used in the rate calculation (must be odd) int inumpedfile; // number of the pedestal file used int inumpedrun; // number of the pedestal run used in the file (starting at 0) int inumcalfile; // number of the calibration file used int inumlaserrun; // number of the laserrun used in the file (starting at 0) int inumtellogfile; // number of the TelLog file to be used int inumtellogrun; // number of the tellog entry (Runnumber) used from the log file int imcparticle; // CORSIKA-coded Monte Carlo particle type. */ // ----- preprocessing results ----- // int istart_mjdate_day; // MJD of run start (first event) */ // int iend_mjdate_day; // MJD of run end (last event) */ // int irunduration_secs; // difference between start and end time (secs) */ *fLog << "Run Time: From " << outpars.istart_mjdate_day << " to "; *fLog << outpars.iend_mjdate_day << " (MJD), Duration="; *fLog << outpars.irunduration_secs/3600 << "h"; *fLog << (outpars.irunduration_secs/60)%60 << "m"; *fLog << outpars.irunduration_secs%60 << "s" << endl; fRawRunHeader->SetRunTime(outpars.istart_mjdate_day, outpars.iend_mjdate_day); fRawRunHeader->SetReadyToSave(); /* --- USEFULL? NEEDED? --- int iproc_mjdate; // MJD of data processing (i.e. creation of this file) */ // int iproc_evts; // number of events processed */ *fLog << "Number of processed events: " << outpars.iproc_evts << endl; // --- USEFULL? NEEDED? --- // double dactual_sourcera_hours; // for off runs: the false source (that should have been) observed */ // float frms_pedsig_phot[iMAXNUMPIX]; // standard deviation of the calibrated signals from the pedestal run */ fPedest->InitSize(iMAXNUMPIX); fPedRMS.Set(iMAXNUMPIX); *fLog << "PedestalRMS : "; for (Int_t i=0; iSetReadyToSave(); // Used to communicate the mean over all pixels // pedestal RMS into the Runs NTuple, as it might // be used for e.g. quality cuts. // float fpedrms_mean; *fLog << "Pedestal RMS: " << outpars.fpedrms_mean << endl; // The average current over the active pixels // for this run. This is done separately for // ON and OF runs. //float fcurrent_mean; // enum eERRORTOLERANCE {CAUTIOUS=0, GOODPHYSICS, TANK} eerrortolerance; /* 0 == "cautious", exits on any reason (but tells in * the .err file, * 1 == "goodphysics", exits when physics could be affected * by the error, * 2 == "tank", never exits except on coredumps and when * all files have been processed. Do not use such files for * physics analysis! * * NOTE: the capital letter words are the enums, the small letter * words must be used inside the parameter file. */ // enum eMCTRIGGERFLAG {ALL=0, FLAG, NOFLAG} emctriggerflag; /* all: all events which survive the filter are written to the * events NTuple. * flag: When Dorota's triggerflag is set to 1 for a particular * event, it shall be written to the output. All others shall * just be disregarded. (Default) * noflag: Opposite of 'flag': only events with triggerflag = 0 shall * be treated further. */ *fLog << "Particle Id #" << outpars.imcparticle << endl; *fLog << "Right Ascension: " << outpars.dsourcera_hours << "h" << endl; *fLog << "Declination: " << outpars.dsourcedec_deg << "deg" << endl; // Next statement commented out because bmontecarlo was set wrongly //fIsMcFile = outpars.bmontecarlo==TRUE; fIsMcFile = (outpars.dsourcera_hours==0 && outpars.dsourcedec_deg==0 && outpars.imcparticle != 0); if (fIsMcFile != (outpars.bmontecarlo==TRUE)) { *fLog << "File tells you that it is a "; *fLog << (outpars.bmontecarlo ? "Monte Carlo" : "Real Data"); *fLog << " file." << endl; } *fLog << "File detected as a "; *fLog << (fIsMcFile ? "Monte Carlo" : "Real Data"); *fLog << " file." << endl; *fLog << " " << endl; } // -------------------------------------------------------------------------- // // Read CT1 PreProc File Header: // Int_t MCT1ReadPreProc::ReadRunHeader() { char cheadertitle[iHEADERTITLELENGTH]; fIn->read(cheadertitle, iHEADERTITLELENGTH); TString s = cheadertitle; TString m = cTITLE_TEMPLATE; if (!s.BeginsWith(m(0, m.First('%')))) return kFALSE; *fLog << cheadertitle << flush; // cTITLE_TEMPLATE "PREPROC V%f/S%f CT %d RUN %d %d PROCMJD %d\n" struct outputpars outpars; int dummy; Float_t fpreprocversion, structversion; sscanf(cheadertitle, cTITLE_TEMPLATE, &fpreprocversion, &structversion, &outpars.itelescope, &outpars.irunnum, &dummy/*&outpars.eruntype*/, &outpars.iproc_mjdate); if (fpreprocversion<0.6) { *fLog << err << "Sorry, only files from PreProc V0.6 and newer are supported." << endl; return kFALSE; } // // This is a stupid way of getting rid of numerical uncertanties when // comparing floating point numbers (Argh...) // TString s1 = Form("%.2f", structversion); TString s2 = Form("%.2f", STRUCT_VERSION); if (s1 != s2) { *fLog << warn << "WARNING: Version of C-structures of file (V"; *fLog << s1 << ") not identical with current structures (V"; *fLog << s2 << ")" << endl; } fIn->read((char*)&outpars, sizeof(struct outputpars)); ProcessRunHeader(outpars); //rwagner: ReInit whenever new run commences // rc==-1 means: ReInit didn't work out MTaskList *tlist = (MTaskList*)fParList->FindCreateObj("MTaskList"); if (!tlist) return -1; if (!tlist->ReInit(fParList)) return -1; return kTRUE; } Int_t MCT1ReadPreProc::ReadRunFooter() { char cheadertitle[iHEADERTITLELENGTH]; fIn->read(cheadertitle, iHEADERTITLELENGTH); /* sscanf(cheadertitle, cEND_EVENTS_TEMPLATE, &filterres.ifilter_passed_evts); */ TString s = cheadertitle; TString m = cEND_EVENTS_TEMPLATE; Int_t p = m.First('%'); if (!s.BeginsWith(m(0,p))) { fIn->seekg(-iHEADERTITLELENGTH, ios::cur); return 0; } *fLog << inf << cheadertitle << flush; struct filterresults filterres; fIn->read((char*)&filterres, sizeof(struct filterresults)); /* int imax_alt_arcs; // maximum altitude reached during the run int iaz_at_max_alt_arcs; // azimuth at the time the max. alt. was reached int itimeaverage_alt_arcs; // altitude averaged over the runtime int icoord_inconsist_evts; // number of events with time-coordinate inconsistency in this run int ifilter_passed_evts; // number of events which passed the filter int imuon_fail_evts; // number of events rejected as muons (other filters passed) int i2out_fail_evts; // number of events which failed in the two out of all pixels software trigger int imuon_and_2out_fail_evts; // number of events failing in both muon and 2out filter int isum_fail_evts; // number of events which failed the sum-of-all-calibrated ADC counts filter int isum_and_muon_fail_evts; // number of events which failed in both the sum and the muon filter int isum_and_2out_fail_evts; // number of events which failed in both the sum and the 2out filter int iall_filters_fail_evts; // number of events which failed in all filters float favg_event_rate_hz; // average rate before filtering float fstddev_event_rate_hz; // standard deviation of the rate before filtering */ if (fNumEventsInRun!=(UInt_t)filterres.ifilter_passed_evts) { *fLog << err << "ERROR! Number of events in run (" << (UInt_t)filterres.ifilter_passed_evts; *fLog << ") doesn't match number of read events ("; *fLog << fNumEventsInRun << ")" << endl; *fLog << " File corrupted." << endl; return -1; } fNumFilterEvts += fNumEventsInRun; fNumRuns++; *fLog << inf << "Read " << fNumEventsInRun << " events from run (Total="; *fLog << fNumFilterEvts << "/" << fEntries << " ["; *fLog << 100*fNumFilterEvts/fEntries << "%], Runs=" << fNumRuns << ")"; *fLog << endl; return 1; } // -------------------------------------------------------------------------- // // This opens the next file in the list and deletes its name from the list. // Bool_t MCT1ReadPreProc::OpenNextFile() { // // open the input stream and check if it is really open (file exists?) // if (fIn) delete fIn; fIn = NULL; // // Check for the existence of a next file to read // if (fNumFile >= (UInt_t)fFileNames->GetSize()) return kFALSE; TNamed *file = (TNamed*)fFileNames->At(fNumFile); //TNamed *file = (TNamed*)fFileNames->GetFirst(); //if (!file) // return kFALSE; // // open the file which is the first one in the chain // const TString name = file->GetName(); const char *expname = gSystem->ExpandPathName(name); const TString fname(expname); delete [] expname; // // Remove this file from the list of pending files // //fFileNames->Remove(file); *fLog << inf << "Open file: '" << name << "'" << endl; if (!CheckHeader(fname)) return kFALSE; fNumFile++; fIn = new ifstream(fname); *fLog << inf << "-----------------------------------------------------------------------" << endl; switch (ReadRunHeader()) { case kFALSE: *fLog << warn << "Unable to read first run header... skipping file." << endl; return kFALSE; case -1: *fLog << warn << "ReInit of Tasklist didn't succeed." << endl; return kFALSE; default: *fLog << "After opening next file: Number of Events #" << fNumEventsInRun << endl; return kTRUE; } } Bool_t MCT1ReadPreProc::CheckHeader(const TString fname) const { ifstream fin(fname); if (!fin) { *fLog << dbginf << err << "ERROR - Cannot open file '" << fname << "'" << endl; return kFALSE; } char cheadertitle[iHEADERTITLELENGTH]; fin.read(cheadertitle, iHEADERTITLELENGTH); Float_t fpreprocversion, structversion; Int_t dummyi; sscanf(cheadertitle, cTITLE_TEMPLATE, &fpreprocversion, &structversion, &dummyi, &dummyi, &dummyi, &dummyi); if (fpreprocversion < 0.6) { *fLog << dbginf << err << "ERROR - You must use PreProc V0.6 or higher." << endl; return kFALSE; } if (STRUCT_VERSION > structversion) { *fLog << warn << "WARNING: Version of C-structures of file (V"; *fLog << structversion << ") newer than current structures (V"; *fLog << STRUCT_VERSION << ")" << endl; } *fLog << "Current structures: " << STRUCT_VERSION << " "; *fLog << "Structures in file: " << structversion << " "; *fLog << "Used preproc version: " << fpreprocversion << endl; return kTRUE; } Int_t MCT1ReadPreProc::GetNumEvents(const TString fname) const { *fLog << inf << "Scanning file " << fname << " for size" << flush; ifstream fin(fname); if (!fin) { *fLog << dbginf << err << "ERROR - Opening file." << endl; return 0; } const TString m(cEND_EVENTS_TEMPLATE); const Int_t p = m.First('%'); const TString test = m(0, p); Int_t nevts = 0; Int_t nruns = 0; while (!fin.eof() && fin.peek()!=EOF) { fin.seekg(iHEADERTITLELENGTH, ios::cur); fin.seekg(sizeof(struct outputpars), ios::cur); while (1) { if (fin.peek()==cEND_EVENTS_TEMPLATE[0]) { char cheadertitle[iHEADERTITLELENGTH]; fin.read(cheadertitle, iHEADERTITLELENGTH); const TString s = cheadertitle; if (s.BeginsWith(test)) { fin.seekg(sizeof(struct filterresults), ios::cur); nruns++; break; } fin.seekg(-iHEADERTITLELENGTH, ios::cur); } fin.seekg(sizeof(struct eventrecord), ios::cur); if (fin.eof()) break; nevts++; } *fLog << "." << flush; } *fLog << "done." << endl; *fLog << "Found " << nevts << " events in " << nruns << " runs." << endl; return nevts; } Bool_t MCT1ReadPreProc::Rewind() { fNumFilterEvts = 0; fNumEvents = 0; fNumRuns = 0; fNumFile = 0; if (fIn) delete fIn; fIn=NULL; return kTRUE; } // -------------------------------------------------------------------------- // // Open the first file in the list. Check for the output containers or create // them if they don't exist. // // Initialize the size of the MPedPhotCam container to 127 pixels (CT1 camera) // Int_t MCT1ReadPreProc::PreProcess(MParList *pList) { fParList = pList; // // look for the HourAngle container in the plist // fHourAngle = (MParameterD*)pList->FindCreateObj("MParameterD", "HourAngle"); if (!fHourAngle) return kFALSE; fHourAngle->SetTitle("Store the CT1 hour angle [deg]"); // // look for the ThetaOrig container in the plist // fThetaOrig = (MParameterD*)pList->FindCreateObj("MParameterD", "ThetaOrig"); if (!fThetaOrig) return kFALSE; fThetaOrig->SetTitle("Store the original CT1 zenith angle [rad]"); // // look for the MCerPhotEvt class in the plist // fNphot = (MCerPhotEvt*)pList->FindCreateObj("MCerPhotEvt"); if (!fNphot) return kFALSE; // // look for the pedestal class in the plist // fPedest = (MPedPhotCam*)pList->FindCreateObj("MPedPhotCam"); if (!fPedest) return kFALSE; // // look for the time class in the plist // fTime = (MTime*)pList->FindCreateObj("MTime"); if (!fTime) return kFALSE; // // look for the pedestal class in the plist // fBlinds = (MBlindPixels*)pList->FindCreateObj("MBlindPixels"); if (!fBlinds) return kFALSE; // // look for the source position in the camera // fSrcPos = (MSrcPosCam*)pList->FindCreateObj("MSrcPosCam"); if (!fSrcPos) return kFALSE; // // look for the camera geometry // fGeom = (MGeomCam*)pList->FindCreateObj("MGeomCamCT1", "MGeomCam"); if (!fGeom) return kFALSE; // // look for the mc event class // fMcEvt = (MMcEvt*)pList->FindCreateObj("MMcEvt"); if (!fMcEvt) return kFALSE; // // look for the mc trigger class // fMcTrig = (MMcTrig*)pList->FindCreateObj("MMcTrig"); if (!fMcTrig) return kFALSE; // // look for the raw run header class // fRawRunHeader = (MRawRunHeader*)pList->FindCreateObj("MRawRunHeader"); if (!fRawRunHeader) return kFALSE; fBinningT = (MBinning*)pList->FindObject("BinningTheta"); Rewind(); fPedest->InitSize(iMAXNUMPIX); return GetSelector() ? GetSelector()->CallPreProcess(pList) : kTRUE; } // -------------------------------------------------------------------------- // // Smear Theta uniformly in a bin of Theta // theta [rad] // SmearTheta [rad] // Double_t MCT1ReadPreProc::SmearTheta(Double_t theta) { if (!fBinningT) return theta; const Int_t bin = fBinningT->FindLoEdge(theta * 180/TMath::Pi()); if (bin<0) return theta; // smear Theta within the Theta bin const Double_t low = fBinningT->GetEdges()[bin]; const Double_t up = fBinningT->GetEdges()[bin+1]; // "up-": Do not allow the upper edge return (up - gRandom->Uniform() * (up-low)) * TMath::Pi()/180; } // -------------------------------------------------------------------------- // // Discretize Theta according to the binning in Theta // theta [rad] // DiscreteTheta [rad] (= bin center) // Double_t MCT1ReadPreProc::DiscreteTheta(Double_t theta) { if (!fBinningT) return theta; const Int_t bin = fBinningT->FindLoEdge(theta * 180/TMath::Pi()); if (bin<0) return theta; const Double_t low = fBinningT->GetEdges()[bin]; const Double_t up = fBinningT->GetEdges()[bin+1]; return 0.5*(up+low) * TMath::Pi()/180; } // -------------------------------------------------------------------------- // // Analyse the event data, means store and copy the needed data into // Mars structures and data members // Bool_t MCT1ReadPreProc::ProcessEvent(const struct eventrecord &event) { /* if (fRawRunHeader->GetRunNumber() == 1) { *fLog << "eventrecord" << endl; *fLog << "isecs_since_midday = " << event.isecs_since_midday << endl; *fLog << "isecfrac_200ns = " << event.isecfrac_200ns << endl; *fLog << "snot_ok_flags = " << event.snot_ok_flags << endl; *fLog << "ialt_arcs = " << event.ialt_arcs << endl; *fLog << "iaz_arcs = " << event.iaz_arcs << endl; *fLog << "ipreproc_alt_arcs = " << event.ipreproc_alt_arcs << endl; *fLog << "ipreproc_az_arcs = " << event.ipreproc_az_arcs << endl; *fLog << "ifieldrot_arcs = " << event.ifieldrot_arcs << endl; *fLog << "srate_millihz = " << event.srate_millihz << endl; *fLog << "fhourangle = " << event.fhourangle << endl; *fLog << "fmcenergy_tev = " << event.fmcenergy_tev << endl; *fLog << "fmcsize_phel = " << event.fmcsize_phel << endl; *fLog << "imcimpact_m = " << event.imcimpact_m << endl; *fLog << "imcparticle = " << event.imcparticle << endl; *fLog << "imctriggerflag = " << event.imctriggerflag << endl; } */ // reset blind pixels for this event fBlinds->Clear(); for (int i=0; iSetPixelBlind(i); } // reset pedestal RMS for this event for (Int_t i=0; iSetCT1Time((UInt_t)fRawRunHeader->GetRunStart().GetMjd(), event.isecfrac_200ns, event.isecs_since_midday); fTime->SetReadyToSave(); /* --- USEFULL? NEEDED? --- short snot_ok_flags; // the bits in these two bytes are flags for additional information on the event: Everything OK =: all Bits = 0 // for ALT-AZ mount telescopes: rotation angle of the field of // view; this angle is defined mathematically positive looking // towards the sky as the angle between the hour circle through // the object being tracked and the line through pixel 1 and 2 int ifieldrot_arcs; // event rate in milli Hertz before filtering calculated by // iratecalc_numevents_odd/(time[i+iratecalc_numevents_odd/2] - // time[i-iratecalc_numevents_odd/2]) // For the first and the last iratecalc_numevents_odd/2 // events the rate is assumed to be constant unsigned short srate_millihz; // This is the angle between the observation of this event and the // culmination point. It is going to be written into the events NTuple. float fhourangle; */ // // read in the number of cerenkov photons and add the 'new' pixel // too the list with it's id, number of photons and error // number of photoelectrons measured in each pixel only the // actual number of pixels (outputpars.inumpixels) is written out // short spixsig_10thphot[iMAXNUMPIX]; // for (Int_t i=0; iAddPixel(i, 0.1*event.spixsig_10thphot[i], (*fPedest)[i].GetRms()); } fNphot->FixSize(); fNphot->SetReadyToSave(); // int ipreproc_alt_arcs; // "should be" alt according to preproc (arcseconds) // int ipreproc_az_arcs; // "should be" az according to preproc (arcseconds) // smear Theta in its Theta bin const Double_t theta = TMath::Pi()*(0.5-1./180*event.ialt_arcs/3600); fThetaOrig->SetVal(theta); // store hour angle fHourAngle->SetVal(event.fhourangle); fMcEvt->Fill(event.isecs_since_midday, //0, /*fEvtNum*/ fIsMcFile ? event.imcparticle : 0, /*corsika particle type*/ fIsMcFile ? event.fmcenergy_tev*1000 : 0, 0, /* fThi0 */ 0, /* fFirTar */ 0, /* fzFirInt */ // 0, /* fThet*/ // rwagner: The following should be theta, right? Check with // altitude fill some lines down... 0, // altitude (arcseconds) 0, /* fPhii */ 0, /* fCorD */ 0, /* fCorX */ 0, /* fCorY */ fIsMcFile ? event.imcimpact_m*100 : 0, TMath::Pi()/180*event.iaz_arcs/3600, // azimuth (arcseconds) // fIsMcFile ? SmearTheta(theta) : theta, DiscreteTheta(theta), 0, /* fTFirst */ 0, /* fTLast */ 0, /* fL_Nmax */ 0, /* fL_t0 */ 0, /* fL_tmax */ 0, /* fL_a */ 0, /* fL_b */ 0, /* fL_c */ 0, /* fL_chi2 */ 0, /* uiPin */ 0, /* uiPat */ 0, /* uiPre */ 0, /* uiPco */ 0, /* uiPelS */ (int)(fIsMcFile ? event.fmcsize_phel : 0), /* uiPelC, Simulated SIZE */ 0, /* elec */ 0, /* muon */ 0 /* other */ ); fMcTrig->SetFirstLevel(event.imctriggerflag); // MC data from Dorota get a triggerflag: 1 means triggered, 0 not. */ fMcTrig->SetReadyToSave(); fMcEvt->SetReadyToSave(); return kTRUE; } // -------------------------------------------------------------------------- // // Because of the file format of the preproc output we have to check at any // event where in the file stream we are... // Bool_t MCT1ReadPreProc::CheckFilePosition() { // // Means: If no file is open (first call) try to open the first file // if (!fIn) return kFALSE; // // Because we can have 0-event runs in the file we loop as often // as we don't find a new footer-header combination. // while (1) { // // If the first character isn't the first of the footer it must be // an event // if (fIn->peek()!=cEND_EVENTS_TEMPLATE[0]) return kTRUE; // // Try reading the footer. If this isn't successful... // must be an event // switch (ReadRunFooter()) { case -1: return kFALSE; case 0: return kTRUE; } *fLog << inf << "Footer found." << endl; const char c = fIn->peek(); // // No after reading the footer check if we reached the end of the file // if (fIn->eof() || c==EOF) { *fLog << "End of file." << endl; return kFALSE; } // // If the eof isn't reached a new header must follow. Check for it. // if (c!=cTITLE_TEMPLATE[0]) { *fLog << inf << "Error finding new run header in file (possible EOF)... skipping rest of file." << endl; return kFALSE; } *fLog << "-----------------------------------------------------------------------" << endl; if (ReadRunHeader() < 0) { *fLog << warn << "ReInit of Tasklist didn't succeed." << endl; return kFALSE; } } } // -------------------------------------------------------------------------- // // Check for the event number and depending on this number decide if // pedestals or event data has to be read. // // If the end of the file is reached try to open the next in the list. If // there is now next file stop the eventloop. // Int_t MCT1ReadPreProc::Process() { // // Check where in the file we are. If neither a new event, nor a // footer/header combination is detected go to the next file. // if (!CheckFilePosition()) if (!OpenNextFile()) return kFALSE; // // Check for a selector. If one is given and returns kFALSE // skip this event. // if (GetSelector()) { // // Make sure selector is processed // if (!GetSelector()->CallProcess()) { *fLog << err << dbginf << "Processing Selector failed." << endl; return kFALSE; } // // Skip Event // if (!GetSelector()->IsConditionTrue()) { fIn->seekg(sizeof(struct eventrecord), ios::cur); fNumEvents++; fNumEventsInRun++; return kCONTINUE; } } // event data to be read from the file struct eventrecord event; // read the eventrecord from the file fIn->read((char*)&event, sizeof(struct eventrecord)); switch (ProcessEvent(event)) { case kFALSE: return kFALSE; case kCONTINUE: return kCONTINUE; } fNumEvents++; fNumEventsInRun++; return kTRUE; } Int_t MCT1ReadPreProc::PostProcess() { *fLog << all; *fLog << "Number events passed the filter: " << fNumFilterEvts << endl; *fLog << "Number of Events read from file: " << fNumEvents << endl; *fLog << "Number of Runs read from file: " << fNumRuns << endl; *fLog << "Number of events detected first: " << fEntries << endl; if (fNumEvents!=fNumFilterEvts) { *fLog << warn << "WARNING! Number of events in file doesn't match number of read events..." << endl; *fLog << " File might be corrupt." << endl; } delete fIn; fIn = NULL; return GetSelector() ? GetSelector()->CallPostProcess() : kTRUE; }