/* ======================================================================== *\ ! ! * ! * 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): Javier Lopez 12/2003 ! Author(s): Javier Rico 01/2004 ! Author(s): Wolfgang Wittek 02/2004 ! Author(s): Markus Gaug 04/2004 ! Author(s): Hendrik Bartko 08/2004 ! Author(s): Thomas Bretz 08/2004 ! ! Copyright: MAGIC Software Development, 2000-2006 ! ! \* ======================================================================== */ /////////////////////////////////////////////////////////////////////////////////// // // MCalibrateData // // This task takes the integrated charge from MExtractedSignal and applies // the calibration constants from MCalibrationCam to convert the summed FADC // slices into photons. The number of photons obtained is stored in MSignalCam. // Optionally, the calibration of pedestals from an MPedestalCam container into // an MPedPhotCam container can be chosen with the member functions // SetPedestalType(). Default is 'kRun', i.e. calibration of pedestals from a // dedicated pedestal run. // In case, the chosen pedestal type is kRun or kEvent, in ReInit() the MPedPhotCam // container is filled using the information from MPedestalCam, MExtractedSignalCam, // MCalibrationChargeCam and MCalibrationQECam // // Selection of different calibration methods is allowed through the // SetCalibrationMode() member function (default: kFfactor) // // The calibration modes which exclude non-valid pixels are the following: // // kFfactor: calibrates using the F-Factor method // kBlindpixel: calibrates using the BlindPixel method // kBlindpixel: calibrates using the BlindPixel method // kFlatCharge: perform a charge flat-flatfielding. Outer pixels are area-corrected. // kDummy: calibrates with fixed conversion factors of 1 and errors of 0. // // The calibration modes which include all pixels regardless of their validity is: // // kNone: calibrates with fixed conversion factors of 1 and errors of 0. // // Use the kDummy and kNone methods ONLY FOR DEBUGGING! // // // This class can calibrate data and/or pedestals. To switch off calibration of data // set the Calibration Mode to kSkip. To switch on pedestal calibration call either // SetPedestalFlag(MCalibrateData::kRun) (calibration is done once in ReInit) // SetPedestalFlag(MCalibrateData::kEvent) (calibration is done for each event) // // By calling AddPedestal() you can control the name of the // MPedestalCam and/or MPedPhotCam container which is used. // // Assume you want to calibrate "MPedestalCam" once and "MPedestalFromLoGain" [MPedestalCam] // event-by-event, so: // MCalibrateData cal1; // cal1.SetCalibrationMode(MCalibrateData::kSkip); // cal1.SetPedestalFlag(MCalibrateData::kRun); // MCalibrateData cal2; // cal2.SetCalibrationMode(MCalibrateData::kSkip); // cal2.AddPedestal("FromLoGain"); // cal2.SetPedestalFlag(MCalibrateData::kEvent); // // // Input Containers: // [MPedestalCam] // [MExtractedSignalCam] // [MCalibrationChargeCam] // [MCalibrationQECam] // MBadPixelsCam // // Output Containers: // [MPedPhotCam] // [MSignalCam] // // See also: MJCalibration, MJPedestal, MJExtractSignal, MJExtractCalibTest // ////////////////////////////////////////////////////////////////////////////// #include "MCalibrateData.h" #include #include #include "MLog.h" #include "MLogManip.h" #include "MParList.h" #include "MH.h" #include "MGeomCam.h" #include "MRawRunHeader.h" #include "MPedestalCam.h" #include "MPedestalPix.h" #include "MCalibrationChargeCam.h" #include "MCalibrationChargePix.h" #include "MCalibrationQECam.h" #include "MCalibrationQEPix.h" #include "MCalibConstCam.h" #include "MCalibConstPix.h" #include "MExtractedSignalCam.h" #include "MExtractedSignalPix.h" #include "MPedPhotCam.h" #include "MPedPhotPix.h" #include "MBadPixelsCam.h" #include "MBadPixelsPix.h" #include "MSignalCam.h" ClassImp(MCalibrateData); using namespace std; const Float_t MCalibrateData::gkCalibConvMinLimit = 0.01; const Float_t MCalibrateData::gkCalibConvMaxLimit = 5.; const MCalibrateData::CalibrationMode_t MCalibrateData::gkDefault = kFfactor; // -------------------------------------------------------------------------- // // Default constructor. // // Sets all pointers to NULL // // Initializes: // - fCalibrationMode to kDefault // - fPedestalFlag to kNo // MCalibrateData::MCalibrateData(CalibrationMode_t calmode,const char *name, const char *title) : fGeomCam(NULL), fBadPixels(NULL), fCalibrations(NULL), fQEs(NULL), fSignals(NULL), fCerPhotEvt(NULL), fCalibConstCam(NULL), fPedestalFlag(kNo), fSignalType(kPhot), fRenormFactor(1.), fScaleFactor(1) { fName = name ? name : "MCalibrateData"; fTitle = title ? title : "Task to calculate the number of photons in one event"; SetCalibrationMode(calmode); SetCalibConvMinLimit(); SetCalibConvMaxLimit(); fNamesPedestal.SetOwner(); } void MCalibrateData::AddPedestal(const char *name) { TString ped(name); TString pho(name); ped.Prepend("MPedestal"); pho.Prepend("MPedPhot"); fNamesPedestal.Add(new TNamed(ped, pho)); } void MCalibrateData::AddPedestal(const char *pedestal, const char *pedphot) { fNamesPedestal.Add(new TNamed(pedestal, pedphot)); } // -------------------------------------------------------------------------- // // The PreProcess searches for the following input containers: // // - MGeomCam // - MPedestalCam // - MCalibrationChargeCam // - MCalibrationQECam // - MExtractedSignalCam // - MBadPixelsCam // // The following output containers are also searched and created if // they were not found: // // - MPedPhotCam // - MSignalCam // Int_t MCalibrateData::PreProcess(MParList *pList) { // input containers fBadPixels = (MBadPixelsCam*)pList->FindObject(AddSerialNumber("MBadPixelsCam")); if (!fBadPixels) { *fLog << err << AddSerialNumber("MBadPixelsCam") << " not found ... aborting" << endl; return kFALSE; } fSignals = 0; fCerPhotEvt = 0; if (fCalibrationMode>kSkip) { fSignals = (MExtractedSignalCam*)pList->FindObject(AddSerialNumber("MExtractedSignalCam")); if (!fSignals) { *fLog << err << AddSerialNumber("MExtractedSignalCam") << " not found ... aborting" << endl; return kFALSE; } fCerPhotEvt = (MSignalCam*)pList->FindCreateObj(AddSerialNumber("MSignalCam")); if (!fCerPhotEvt) return kFALSE; fCalibConstCam = (MCalibConstCam*)pList->FindCreateObj(AddSerialNumber("MCalibConstCam")); if (!fCalibConstCam) return kFALSE; } fCalibrations = 0; fQEs = 0; if (fCalibrationMode>kNone) { fCalibrations = (MCalibrationChargeCam*)pList->FindObject(AddSerialNumber("MCalibrationChargeCam")); if (!fCalibrations) { *fLog << err << AddSerialNumber("MCalibrationChargeCam") << " not found ... aborting." << endl; return kFALSE; } fQEs = (MCalibrationQECam*)pList->FindObject(AddSerialNumber("MCalibrationQECam")); if (!fQEs) { *fLog << err << AddSerialNumber("MCalibrationQECam") << " not found ... aborting." << endl; return kFALSE; } } if (fNamesPedestal.GetSize()>0 && fPedestalFlag==kNo) { *fLog << warn << "Pedestal list contains entries, but mode is set to kNo... setting to kEvent." << endl; fPedestalFlag = kEvent; } if (fPedestalFlag!=kNo) { if (fNamesPedestal.GetSize()==0) { *fLog << inf << "No container names specified... using default: MPedestalCam and MPedPhotCam." << endl; AddPedestal(); } fPedestalCams.Clear(); fPedPhotCams.Clear(); TIter Next(&fNamesPedestal); TObject *o=0; while ((o=Next())) { TObject *pedcam = pList->FindObject(AddSerialNumber(o->GetName()), "MPedestalCam"); if (!pedcam) { *fLog << err << AddSerialNumber(o->GetName()) << " [MPedestalCam] not found ... aborting" << endl; return kFALSE; } TObject *pedphot = pList->FindCreateObj("MPedPhotCam", AddSerialNumber(o->GetTitle())); if (!pedphot) return kFALSE; fPedestalCams.Add(pedcam); fPedPhotCams.Add(pedphot); } } switch (fSignalType) { case kPhe: // // Average QE for C-photons, for pixels in the inner pixel region ("area 0"), // used later to convert from C-photons into "equivalent phes": // // Average areas not yet initialized? use default value fRenormFactor = MCalibrationQEPix::gkDefaultAverageQE; if (fQEs->GetAverageAreas() > 0) { MCalibrationQEPix& avqepix = (MCalibrationQEPix&)(fQEs->GetAverageArea(0)); fRenormFactor = avqepix.GetAverageQE(); } break; case kPhot: fRenormFactor = 1.; break; } fCalibConsts.Reset(); fCalibFFactors.Reset(); fHiLoConv.Reset(); fHiLoConvErr.Reset(); return kTRUE; } // -------------------------------------------------------------------------- // // The ReInit searches for the following input containers: // // - MGeomCam // // Check for validity of the selected calibration method, switch to a // different one in case of need // // Fill the MPedPhotCam container using the information from MPedestalCam, // MExtractedSignalCam and MCalibrationCam // Bool_t MCalibrateData::ReInit(MParList *pList) { MRawRunHeader *header = (MRawRunHeader*)pList->FindObject("MRawRunHeader"); if (!header) { *fLog << err << "MRawRunHeader not found... abort." << endl; return kFALSE; } fGeomCam = (MGeomCam*)pList->FindObject(AddSerialNumber("MGeomCam")); if (!fGeomCam) { *fLog << err << "No MGeomCam found... aborting." << endl; return kFALSE; } // Sizes might have changed if (fPedestalFlag!=kNo) { TIter Next(&fPedestalCams); MPedestalCam *cam=0; while ((cam=(MPedestalCam*)Next())) if ((Int_t)cam->GetSize() != fSignals->GetSize()) { *fLog << err << "Size mismatch of " << cam->GetDescriptor() << " and MCalibrationCam... abort." << endl; return kFALSE; } } if(fCalibrationMode == kBlindPixel && !fQEs->IsBlindPixelMethodValid()) { *fLog << warn << "Blind pixel calibration method not valid, switching to F-factor method" << endl; fCalibrationMode = kFfactor; } if(fCalibrationMode == kPinDiode && !fQEs->IsPINDiodeMethodValid()) { *fLog << warn << "PIN diode calibration method not valid, switching to F-factor method" << endl; fCalibrationMode = kFfactor; } if(fCalibrationMode == kCombined && !fQEs->IsCombinedMethodValid()) { *fLog << warn << "Combined calibration method not valid, switching to F-factor method" << endl; fCalibrationMode = kFfactor; } // // output information or warnings: // switch(fCalibrationMode) { case kBlindPixel: break; case kFfactor: break; case kPinDiode: *fLog << err << "PIN Diode Calibration mode not yet available!" << endl; return kFALSE; break; case kCombined: *fLog << err << "Combined Calibration mode not yet available!" << endl; return kFALSE; break; case kFlatCharge: *fLog << warn << "WARNING - Flat-fielding charges - only for muon calibration!" << endl; break; case kDummy: *fLog << warn << "WARNING - Dummy calibration, no calibration applied!" << endl; break; case kNone: *fLog << warn << "WARNING - No calibration applied!" << endl; break; default: *fLog << warn << "WARNING - Calibration mode value (" << fCalibrationMode << ") not known" << endl; return kFALSE; } // // output information or warnings: // switch (fSignalType) { case kPhe: *fLog << inf << "Calibrating in units of equivalent (outer/inner=4) photo-electrons." << endl; break; case kPhot: *fLog << inf << "Calibrating in units of photons." << endl; break; } if (header->IsMonteCarloRun()) { if (fScaleFactor!=1) *fLog << warn << "WARNING - Additional scale factor for MonteCarlo run not unity but " << fScaleFactor << endl; } else { if (!fFileNameScale.IsNull()) { if (gSystem->AccessPathName(fFileNameScale, kFileExists)) { *fLog << err << "ERROR - Configuration file '" << fFileNameScale << "' doesn't exist... abort." << endl; return kFALSE; } const Int_t p = header->GetRunStart().GetMagicPeriod(); const TString per = Form("%2d", p); TEnv rc(fFileNameScale); const Double_t scale = rc.GetValue(per, -1.); if (scale<=0) { *fLog << err << "ERROR - No valid entry for scale factor found for period " << p << " in " << fFileNameScale << "... abort." << endl; return kFALSE; } *fLog << inf << "New additional scale factor for period " << p << ": " << scale << endl; fScaleFactor = scale; } else *fLog << inf << "Additional scale factor set to: " << fScaleFactor << endl; } const Int_t npixels = fGeomCam->GetNumPixels(); if (fCalibrationMode > kNone) { if (fCalibrations->GetSize() != npixels) { *fLog << "Size mismatch between MGeomCam and MCalibrationChargeCam... abort!" << endl; return kFALSE; } if (fBadPixels->GetSize() != npixels) { *fLog << "Size mismatch between MGeomCam and MBadPixelsCam... abort!" << endl; return kFALSE; } } fCalibConsts .Set(npixels); fCalibFFactors.Set(npixels); fHiLoConv .Set(npixels); fHiLoConvErr .Set(npixels); if (!UpdateConversionFactors()) return kFALSE; if (TestPedestalFlag(kRun)) Calibrate(kFALSE, kTRUE); return kTRUE; } // -------------------------------------------------------------------------- // // Update the conversion factors and F-Factors from MCalibrationCams into // the arrays. Later, the here pre-calcualted conversion factors get simply // copied from memory. // // This function can be called from outside in case that the MCalibrationCams // have been updated... // Bool_t MCalibrateData::UpdateConversionFactors( const MCalibrationChargeCam *updatecam) { *fLog << inf << GetDescriptor() << ": Updating Conversion Factors... " << endl; fCalibConsts.Reset(); fCalibFFactors.Reset(); fHiLoConv.Reset(); fHiLoConvErr.Reset(); // // For the moment, we use only a dummy zenith for the calibration: // UInt_t skip = 0; for (UInt_t pixidx=0; pixidxGetNumPixels(); pixidx++) { Float_t hiloconv = 1.; Float_t hiloconverr = 0.; Float_t calibConv = 1.; Float_t calibConvVar = 0.; Float_t calibFFactor = 0.; Float_t calibQE = 1.; Float_t calibQEVar = 0.; Float_t calibUpdate = 1.; if(fCalibrationMode!=kNone) { if ((*fBadPixels)[pixidx].IsUnsuitable(MBadPixelsPix::kUnsuitableRun)) { skip++; continue; // calibConv will remain 0 } const MCalibrationChargePix &pix = (MCalibrationChargePix&)(*fCalibrations)[pixidx]; const MCalibrationChargePix &avpix = (MCalibrationChargePix&)fCalibrations->GetAverageArea(0); hiloconv = pix.GetConversionHiLo (); hiloconverr= pix.GetConversionHiLoSigma(); calibConv = pix.GetMeanConvFADC2Phe(); calibConvVar = pix.GetMeanConvFADC2PheVar(); calibFFactor = pix.GetMeanFFactorFADC2Phot(); const MCalibrationQEPix &qe = (MCalibrationQEPix&)(*fQEs)[pixidx]; if (updatecam) { const MCalibrationChargePix &upix = (MCalibrationChargePix&)(*updatecam)[pixidx]; // // Correct for the possible change in amplification of the individual pixels chain // const Float_t pixmean = upix.GetConvertedMean(); calibUpdate = pixmean==0 ? 1 : pix.GetConvertedMean()/pixmean; // // Correct for global shifts in light emission // const MCalibrationChargePix &ugpix = static_cast(updatecam->GetAverageArea(0)); const Float_t globmean = avpix.GetConvertedMean(); calibUpdate = globmean==0 ? 1 : ugpix.GetConvertedMean()/globmean; const MBadPixelsPix &ubad = static_cast(updatecam->GetAverageBadArea(0)); if (ubad.IsUncalibrated(MBadPixelsPix::kChargeIsPedestal)) { *fLog << warn << GetDescriptor() << ": Mean charge in inner pixels is smaller than 3 ped. RMS." << endl; *fLog << "Maybe calibration pulses have been lost!" << endl; calibUpdate = 1.; } } switch(fCalibrationMode) { case kFlatCharge: { calibConv = avpix.GetConvertedMean() / (pix.GetConvertedMean() * fGeomCam->GetPixRatio(pixidx)); calibConvVar = (avpix.GetMeanRelVar() + pix.GetMeanRelVar()) * calibConv * calibConv; if (pix.IsFFactorMethodValid()) { const Float_t convmin1 = qe.GetQECascadesFFactor()/pix.GetMeanConvFADC2Phe(); if (convmin1 > 0) calibFFactor *= TMath::Sqrt(convmin1); else calibFFactor = -1.; } break; } case kBlindPixel: if (!qe.IsBlindPixelMethodValid()) { skip++; continue; } calibQE = qe.GetQECascadesBlindPixel(); calibQEVar = qe.GetQECascadesBlindPixelVar(); break; case kPinDiode: if (!qe.IsPINDiodeMethodValid()) { skip++; continue; } calibQE = qe.GetQECascadesPINDiode(); calibQEVar = qe.GetQECascadesPINDiodeVar(); break; case kFfactor: if (!pix.IsFFactorMethodValid()) { skip++; continue; } calibQE = qe.GetQECascadesFFactor(); calibQEVar = qe.GetQECascadesFFactorVar(); break; case kCombined: if (!qe.IsCombinedMethodValid()) { skip++; continue; } calibQE = qe.GetQECascadesCombined(); calibQEVar = qe.GetQECascadesCombinedVar(); break; case kDummy: hiloconv = 1.; hiloconverr = 0.; calibUpdate = 1.; break; default: break; } /* switch calibration mode */ } /* if(fCalibrationMode!=kNone) */ else { calibConv = 1./fGeomCam->GetPixRatio(pixidx); } calibConv /= calibQE; if (calibConv > 0.00001 && calibQE > 0.00001) { calibConvVar = calibConvVar/(calibConv*calibConv) + calibQEVar/(calibQE*calibQE); calibConvVar *= (calibConv*calibConv); } calibConv *= fRenormFactor*fScaleFactor * calibUpdate; calibFFactor *= TMath::Sqrt(fRenormFactor*fScaleFactor); fHiLoConv [pixidx] = hiloconv; fHiLoConvErr [pixidx] = hiloconverr; fCalibConsts [pixidx] = calibConv; fCalibFFactors[pixidx] = calibFFactor; if (calibConv < fCalibConvMinLimit || calibConv > fCalibConvMaxLimit) { (*fBadPixels)[pixidx].SetUnsuitable(MBadPixelsPix::kUnsuitableRun); calibConv = -1.; calibFFactor = -1.; *fLog << warn << GetDescriptor() << ": "; *fLog << "Conv.factor " << calibConv << " of Pixel " << pixidx << " out of range ]"; *fLog << fCalibConvMinLimit << "," << fCalibConvMaxLimit << "[... set unsuitable. " << endl; } MCalibConstPix &cpix = (*fCalibConstCam)[pixidx]; cpix.SetCalibConst(calibConv); cpix.SetCalibFFactor(calibFFactor); } /* for (Int_t pixidx=0; pixidxGetNumPixels(); pixidx++) */ fCalibConstCam->SetReadyToSave(); if (skip>fGeomCam->GetNumPixels()*0.9) { *fLog << err << GetDescriptor() << ": ERROR - "; *fLog << "GetConversionFactor has skipped more than 90% of the " << fGeomCam->GetNumPixels() << " pixels... abort." << endl; return kFALSE; } return kTRUE; } // -------------------------------------------------------------------------- // // Apply the conversion factors and F-Factors from the arrays to the data. // // The flags 'data' and 'pedestal' decide whether the signal and/or the pedetals // shall be calibrated, respectively. // Int_t MCalibrateData::Calibrate(Bool_t data, Bool_t doped) const { if (!data && !doped) return kTRUE; const UInt_t npix = fSignals->GetSize(); // The number of used slices are just a mean value // the real number might change from event to event. // (up to 50%!) const Float_t slices = fSignals->GetNumUsedHiGainFADCSlices(); const Float_t sqrtslices = TMath::Sqrt(slices); Int_t numsatlo=0; Int_t numsathi=0; for (UInt_t pixidx=0; pixidx0.5) { signal = sig.GetExtractedSignalLoGain()*fHiLoConv[pixidx]; // signalErr = sig.GetExtractedSignalLoGain()*fHiLoConvErr[pixidx]; ok = kTRUE; } } // In this cases the signal extraction has failed. if (!ok) bpix.SetUnsuitable(MBadPixelsPix::kUnsuitableEvt); const Float_t nphot = signal * fCalibConsts [pixidx]; const Float_t nphotErr = TMath::Sqrt(TMath::Abs(nphot)) * fCalibFFactors[pixidx]; fCerPhotEvt->AddPixel(pixidx, nphot, nphotErr); if (!bpix.IsUnsuitable()) { if (sig.IsHiGainSaturated()) numsathi++; if (sig.IsLoGainSaturated()) numsatlo++; } } /* if (data) */ if (doped) { TIter NextPed(&fPedestalCams); TIter NextPhot(&fPedPhotCams); MPedestalCam *pedestal = 0; MPedPhotCam *pedphot = 0; const Float_t pedmeancalib = slices *fCalibConsts[pixidx]; const Float_t pedrmscalib = sqrtslices*fCalibConsts[pixidx]; while ((pedestal=(MPedestalCam*)NextPed()) && (pedphot =(MPedPhotCam*)NextPhot())) { // pedestals/(used FADC slices) in [number of photons] const Float_t mean = (*pedestal)[pixidx].GetPedestal() *pedmeancalib; const Float_t rms = (*pedestal)[pixidx].GetPedestalRms()*pedrmscalib; (*pedphot)[pixidx].Set(mean, rms); pedphot->SetReadyToSave(); //break; } } /* if (pedestal) */ } // Now we should take the bias (MPedPhotExtractor/Mean) and // pedestal rms (MPedPhotExtractorRndm/Rms) and store it // into MSignalPix if (data) { fCerPhotEvt->SetNumPixelsSaturated(numsathi, numsatlo); fCerPhotEvt->SetReadyToSave(); } return kTRUE; } // -------------------------------------------------------------------------- // // Apply the calibration factors to the extracted signal according to the // selected calibration method // Int_t MCalibrateData::Process() { return Calibrate(fCalibrationMode!=kSkip, TestPedestalFlag(kEvent)); } // -------------------------------------------------------------------------- // // Implementation of SavePrimitive. Used to write the call to a constructor // to a macro. In the original root implementation it is used to write // gui elements to a macro-file. // void MCalibrateData::StreamPrimitive(ostream &out) const { out << " " << ClassName() << " " << GetUniqueName() << "(\""; out << "\"" << fName << "\", \"" << fTitle << "\");" << endl; if (TestPedestalFlag(kEvent)) out << " " << GetUniqueName() << ".EnablePedestalType(MCalibrateData::kEvent)" << endl; if (TestPedestalFlag(kRun)) out << " " << GetUniqueName() << ".EnablePedestalType(MCalibrateData::kRun)" << endl; if (fCalibrationMode != gkDefault) { out << " " << GetUniqueName() << ".SetCalibrationMode(MCalibrateData::"; switch (fCalibrationMode) { case kSkip: out << "kSkip"; break; case kNone: out << "kNone"; break; case kFlatCharge: out << "kFlatCharge"; break; case kBlindPixel: out << "kBlindPixel"; break; case kFfactor: out << "kFfactor"; break; case kPinDiode: out << "kPinDiode"; break; case kCombined: out << "kCombined"; break; case kDummy: out << "kDummy"; break; default: out << (int)fCalibrationMode; break; } out << ")" << endl; } TIter Next(&fNamesPedestal); TObject *o=0; while ((o=Next())) { out << " " << GetUniqueName() << ".AddPedestal(\""; out << o->GetName() << "\", \"" << o->GetTitle() << "\");" << endl; } } // -------------------------------------------------------------------------- // // Read the setup from a TEnv, eg: // MJPedestal.MCalibrateDate.PedestalFlag: no,run,event // MJPedestal.MCalibrateDate.CalibrationMode: skip,none,flatcharge,blindpixel,ffactor,pindiode,combined,dummy,default // Int_t MCalibrateData::ReadEnv(const TEnv &env, TString prefix, Bool_t print) { Bool_t rc = kFALSE; if (IsEnvDefined(env, prefix, "PedestalFlag", print)) { rc = kTRUE; TString s = GetEnvValue(env, prefix, "PedestalFlag", ""); s.ToLower(); if (s.BeginsWith("no")) SetPedestalFlag(kNo); if (s.BeginsWith("run")) SetPedestalFlag(kRun); if (s.BeginsWith("event")) SetPedestalFlag(kEvent); } if (IsEnvDefined(env, prefix, "CalibrationMode", print)) { rc = kTRUE; TString s = GetEnvValue(env, prefix, "CalibrationMode", ""); s.ToLower(); if (s.BeginsWith("skip")) SetCalibrationMode(kSkip); if (s.BeginsWith("none")) SetCalibrationMode(kNone); if (s.BeginsWith("flatcharge")) SetCalibrationMode(kFlatCharge); if (s.BeginsWith("blindpixel")) SetCalibrationMode(kBlindPixel); if (s.BeginsWith("ffactor")) SetCalibrationMode(kFfactor); if (s.BeginsWith("pindiode")) SetCalibrationMode(kPinDiode); if (s.BeginsWith("combined")) SetCalibrationMode(kCombined); if (s.BeginsWith("dummy")) SetCalibrationMode(kDummy); if (s.BeginsWith("default")) SetCalibrationMode(); } if (IsEnvDefined(env, prefix, "SignalType", print)) { rc = kTRUE; TString s = GetEnvValue(env, prefix, "SignalType", ""); s.ToLower(); if (s.BeginsWith("phot")) SetSignalType(kPhot); if (s.BeginsWith("phe")) SetSignalType(kPhe); if (s.BeginsWith("default")) SetSignalType(); } if (IsEnvDefined(env, prefix, "CalibConvMinLimit", print)) { fCalibConvMinLimit = GetEnvValue(env, prefix, "CalibConvMinLimit", fCalibConvMinLimit); rc = kTRUE; } if (IsEnvDefined(env, prefix, "CalibConvMaxLimit", print)) { fCalibConvMaxLimit = GetEnvValue(env, prefix, "CalibConvMaxLimit", fCalibConvMaxLimit); rc = kTRUE; } if (IsEnvDefined(env, prefix, "ScaleFactor", print)) { fScaleFactor = GetEnvValue(env, prefix, "ScaleFactor", fScaleFactor); rc = kTRUE; } if (IsEnvDefined(env, prefix, "FileNameScale", print)) { fFileNameScale = GetEnvValue(env, prefix, "FileNameScale", fFileNameScale); rc = kTRUE; } return rc; } void MCalibrateData::Print(Option_t *o) const { *fLog << all << GetDescriptor() << ":" << endl; for (UInt_t pixidx=0; pixidxGetNumPixels(); pixidx++) { *fLog << all << "Pixel: " << Form("%3i",pixidx) << " CalibConst: " << Form("%4.2f",fCalibConsts[pixidx]) << " F-Factor: " << Form("%4.2f",fCalibFFactors[pixidx]) << " HiLoConv: " << Form("%4.2f",fHiLoConv[pixidx]) << endl; } }