[u/mrichter/AliRoot.git] / PWG4 / macros / ConfigGammaConversion.C

/** VERSION NUMBER 1.1 */

/**************************************************************************
 * Copyright(c) 1998-1999, ALICE Experiment at CERN, All rights reserved. *
 *                                                                        *
 * Author: Ana Marin, Kathrin Koch, Kenneth Aamodt
 * Contact: kenneth.aamodt@cern.ch
 * Version 1.1                                                            *
 *                                                                        *
 * Permission to use, copy, modify and distribute this software and its   *
 * documentation strictly for non-commercial purposes is hereby granted   *
 * without fee, provided that the above copyright notice appears in all   *
 * copies and that both the copyright notice and this permission notice   *
 * appear in the supporting documentation. The authors make no claims     *
 * about the suitability of this software for any purpose. It is          *
 * provided "as is" without express or implied warranty.                  *
 **************************************************************************/

class AliAnalysisDataContainer;
class AliGammaConversionHistograms;
class AliAnalysisTaskGammaConversion;

// set this to a number if you want to analyze a set number of files
// if it is 0 it will analyze the files listed in the data list
Int_t kGCnumberOfFilesToAnalyze=0;

Bool_t kGCrunNeutralMeson = kTRUE;
Bool_t kGCrunJet          = kFALSE;
Bool_t kGCrunChic         = kFALSE;
Bool_t kGCrunCF           = kFALSE;

/** ---------------------------------- define cuts here ------------------------------------*/

Int_t kGCpidOfNegativeTrack=11;
Int_t kGCpidOfPositiveTrack=-11;

Double_t kGCmaxRCut   = 180.;
Double_t kGCetaCut    = 1.2;
Double_t kGCptCut     = 0.02;
Double_t kGCmaxZCut     = 240.;
Double_t kGCchi2CutConversion   = 30.;
Double_t kGCchi2CutMeson   = 50.;

Double_t kGCLineCutZRSlope = tan(2*atan(exp(-kGCetaCut)));
Double_t kGCLineCutZValue = 7.;


Double_t kGCxVertexCut = 0.;
Double_t kGCyVertexCut = 0.;
Double_t kGCzVertexCut = 0.;

Double_t kGCsigmaCutGammaMass=0.0001;

Bool_t kGCuseImprovedVertex = kTRUE;

Bool_t kGCUseOnFlyV0Finder = kTRUE;

// define masses of different particles, this will be used by the KF particle
// together with the width to set mass constraints. Units in GeV.
Double_t kGCelectronMass = 0.00051099892;
Double_t kGCgammaMass    = 0.;
Double_t kGCpi0Mass      = 0.1349766;
Double_t kGCetaMass      = 0.54751;

// define the width constraint used by KF particle.
Double_t kGCgammaWidth = 0.01;
Double_t kGCpi0Width   = 0.01;
Double_t kGCetaWidth   = 0.01;

// define the probability of track being an electron
Double_t kGCprobElectron = 0.002;

Double_t kGCminOpeningAngleGhostCut = 0.01;

/** ----------------------------------end define cuts here----------------------------------*/

/** -------------------------------- Phi/R Mapping ---------------------------------------*/
Int_t kGCnPhiIndex = 8;
Int_t kGCnRIndex   = 7;

Double_t kGCminRadius   = 0.;
Double_t kGCmaxRadius   = 200.;
Double_t kGCminPhi      = -TMath::Pi();
Double_t kGCmaxPhi      = TMath::Pi();
/** ------------------------------- end Phi/R Mapping ------------------------------------*/

Bool_t kGCdoOwnXYZCalculation = kFALSE;

Bool_t fWriteStandardAOD =kTRUE; // need to be true for train running? CKB

/** ------------------- define which histograms to plot here --------------------------------*/
/**   NB: to change the bin numbers, see below the histogram flags                           */

// NEUTRAL MESON PLOTS
Bool_t kGCplotMCConversionR             = kTRUE;
Bool_t kGCplotMCConversionZR            = kTRUE;
Bool_t kGCplotMCConversionXY            = kTRUE;
Bool_t kGCplotMCConversionOpeningAngle  = kTRUE;
Bool_t kGCplotMCConvGammaEAsymmetryP    = kTRUE;
Bool_t kGCplotMCConvGammaPAsymmetryP    = kTRUE;


Bool_t kGCplotMCEEnergy  = kTRUE;
Bool_t kGCplotMCEPt      = kTRUE;
Bool_t kGCplotMCEEta     = kTRUE;
Bool_t kGCplotMCEPhi     = kTRUE;

Bool_t kGCplotMCPEnergy  = kTRUE;
Bool_t kGCplotMCPPt      = kTRUE;
Bool_t kGCplotMCPEta     = kTRUE;
Bool_t kGCplotMCPPhi     = kTRUE;

Bool_t kGCplotMCallGammaEnergy = kTRUE;
Bool_t kGCplotMCallGammaPt     = kTRUE;
Bool_t kGCplotMCallGammaEta    = kTRUE;
Bool_t kGCplotMCallGammaPhi    = kTRUE;
Bool_t kGCplotMCallGammaRapid  = kTRUE;


Bool_t kGCplotMCConvGammaEnergy  = kTRUE;
Bool_t kGCplotMCConvGammaPt      = kTRUE;
Bool_t kGCplotMCConvGammaEta     = kTRUE;
Bool_t kGCplotMCConvGammaPhi     = kTRUE;
Bool_t kGCplotMCConvGammaRapid   = kTRUE;
Bool_t kGCplotMCConvGammaPtvsEta = kTRUE;

Bool_t kGCplotMCallDirectGammaEnergy  = kTRUE;
Bool_t kGCplotMCallDirectGammaPt      = kTRUE;
Bool_t kGCplotMCallDirectGammaEta     = kTRUE;
Bool_t kGCplotMCallDirectGammaPhi     = kTRUE;
Bool_t kGCplotMCallDirectGammaRapid   = kTRUE;

Bool_t kGCplotMCConvDirectGammaEnergy  = kTRUE;
Bool_t kGCplotMCConvDirectGammaPt      = kTRUE;
Bool_t kGCplotMCConvDirectGammaEta     = kTRUE;
Bool_t kGCplotMCConvDirectGammaPhi     = kTRUE;
Bool_t kGCplotMCConvDirectGammaRapid   = kTRUE;

Bool_t kGCplotMCMotherEta                                       = kTRUE;
Bool_t kGCplotMCMotherRapid                                = kTRUE;
Bool_t kGCplotMCMotherPhi                                       = kTRUE;
Bool_t kGCplotMCMotherPt                                        = kTRUE;
Bool_t kGCplotMCMotherEnergy                            = kTRUE;
Bool_t kGCplotMCMotherMass                                      = kTRUE;
Bool_t kGCplotMCMotherOpeningAngle                              = kTRUE;
Bool_t kGCplotMCMotherR                                 = kTRUE;
Bool_t kGCplotMCMotherZR                                        = kTRUE;
Bool_t kGCplotMCMotherXY                                        = kTRUE;
Bool_t kGCplotMCMotherPtvsEtaWithinAcceptance              = kTRUE;
Bool_t kGCplotMCMotherPtvsRapidWithinAcceptance            = kTRUE;
Bool_t kGCplotMCMotherPtvsEtaConvGammaWithinAcceptance     = kTRUE;
Bool_t kGCplotMCMotherPtvsRapidConvGammaWithinAcceptance   = kTRUE;
Bool_t kGCplotMCMotherSpectra                           = kTRUE;

Bool_t kGCplotMCPi0Eta                                  = kTRUE;
Bool_t kGCplotMCPi0Rapid                                   = kTRUE;
Bool_t kGCplotMCPi0Phi                                     = kTRUE;
Bool_t kGCplotMCPi0Pt                                      = kTRUE;
Bool_t kGCplotMCPi0Energy                                  = kTRUE;
Bool_t kGCplotMCPi0Mass                                    = kTRUE;
Bool_t kGCplotMCPi0OpeningAngle                            = kTRUE;
Bool_t kGCplotMCPi0R                                       = kTRUE;
Bool_t kGCplotMCPi0ZR                                      = kTRUE;
Bool_t kGCplotMCPi0XY                                      = kTRUE;
Bool_t kGCplotMCPi0PtvsEtaWithinAcceptance                 = kTRUE;
Bool_t kGCplotMCPi0PtvsRapidWithinAcceptance               = kTRUE;
Bool_t kGCplotMCPi0PtvsEtaConvGammaWithinAcceptance        = kTRUE;
Bool_t kGCplotMCPi0PtvsRapidConvGammaWithinAcceptance      = kTRUE;
Bool_t kGCplotMCPi0ZRConvGammaWithinAcceptance          = kTRUE;

Bool_t kGCplotMCPi0SecondaryEta                                = kTRUE;
Bool_t kGCplotMCPi0SecondaryRapid                              = kTRUE;
Bool_t kGCplotMCPi0SecondaryPhi                                = kTRUE;
Bool_t kGCplotMCPi0SecondaryPt                                 = kTRUE;
Bool_t kGCplotMCPi0SecondaryEnergy                             = kTRUE;
Bool_t kGCplotMCPi0SecondaryMass                               = kTRUE;
Bool_t kGCplotMCPi0SecondaryOpeningAngle                       = kTRUE;
Bool_t kGCplotMCPi0SecondaryR                                  = kTRUE;
Bool_t kGCplotMCPi0SecondaryZR                                 = kTRUE;
Bool_t kGCplotMCPi0SecondaryXY                                 = kTRUE;
Bool_t kGCplotMCPi0SecondaryPtvsEtaWithinAcceptance            = kTRUE;
Bool_t kGCplotMCPi0SecondaryPtvsRapidWithinAcceptance          = kTRUE;
Bool_t kGCplotMCPi0SecondaryPtvsEtaConvGammaWithinAcceptance   = kTRUE;
Bool_t kGCplotMCPi0SecondaryPtvsRapidConvGammaWithinAcceptance = kTRUE;

Bool_t kGCplotMCEtaEta                                = kTRUE;
Bool_t kGCplotMCEtaRapid                              = kTRUE;
Bool_t kGCplotMCEtaPhi                                = kTRUE;
Bool_t kGCplotMCEtaPt                                 = kTRUE;
Bool_t kGCplotMCEtaEnergy                             = kTRUE;
Bool_t kGCplotMCEtaMass                               = kTRUE;
Bool_t kGCplotMCEtaOpeningAngleGamma                  = kTRUE;
Bool_t kGCplotMCEtaR                                  = kTRUE;
Bool_t kGCplotMCEtaZR                                 = kTRUE;
Bool_t kGCplotMCEtaXY                                 = kTRUE;
Bool_t kGCplotMCEtaPtvsEtaWithinAcceptance                 = kTRUE;
Bool_t kGCplotMCEtaPtvsRapidWithinAcceptance       = kTRUE;
Bool_t kGCplotMCEtaPtvsEtaConvGammaWithinAcceptance   = kTRUE;
Bool_t kGCplotMCEtaPtvsRapidConvGammaWithinAcceptance = kTRUE;
Bool_t kGCplotMCEtaZRConvGammaWithinAcceptance = kTRUE;

// Histograms from esd tracks
Bool_t kGCplotESDConversionR                   = kTRUE;
Bool_t kGCplotESDConversionZR                  = kTRUE;
Bool_t kGCplotESDConversionXY                  = kTRUE;
Bool_t kGCplotESDConversionOpeningAngle        = kTRUE;
Bool_t kGCplotESDConvGammaCosPointingAngle     = kTRUE;
Bool_t kGCplotESDConvGammaDcaDaugthers         = kTRUE;
Bool_t kGCplotESDConvGammaNormDcaDistDaugthers = kTRUE;
Bool_t kGCplotESDConvGammaLikelihoodAP         = kTRUE;
Bool_t kGCplotESDConvGammaEAsymmetryP         = kTRUE;
Bool_t kGCplotESDConvGammaPAsymmetryP         = kTRUE;
Bool_t kGCplotESDConvGammaEdEdxP         = kTRUE;
Bool_t kGCplotESDConvGammaPdEdxP         = kTRUE;


Bool_t kGCplotESDEEnergy = kTRUE;
Bool_t kGCplotESDEPt     = kTRUE;
Bool_t kGCplotESDEEta    = kTRUE;
Bool_t kGCplotESDEPhi    = kTRUE;

Bool_t kGCplotESDPEnergy = kTRUE;
Bool_t kGCplotESDPPt     = kTRUE;
Bool_t kGCplotESDPEta    = kTRUE;
Bool_t kGCplotESDPPhi    = kTRUE;

Bool_t kGCplotESDConvGammaEnergy = kTRUE;
Bool_t kGCplotESDConvGammaPt     = kTRUE;
Bool_t kGCplotESDConvGammaEta    = kTRUE;
Bool_t kGCplotESDConvGammaPhi    = kTRUE;
Bool_t kGCplotESDConvGammaMass   = kTRUE;
Bool_t kGCplotESDConvGammaWidth  = kTRUE;
Bool_t kGCplotESDConvGammaChi2   = kTRUE;
Bool_t kGCplotESDConvGammaNDF    = kTRUE;
Bool_t kGCplotESDConvGammaRapid  = kTRUE;
Bool_t kGCplotESDConvGammaPtvsEta = kTRUE;
Bool_t kGCplotESDConvGammaPtvsChi2 = kTRUE;
Bool_t kGCplotESDConvGammaEtavsChi2 = kTRUE;



Bool_t kGCplotESDTrueConvGammaEnergy         = kTRUE;
Bool_t kGCplotESDTrueConvGammaPt             = kTRUE;
Bool_t kGCplotESDTrueConvGammaEta            = kTRUE;
Bool_t kGCplotESDTrueConvGammaPhi            = kTRUE;
Bool_t kGCplotESDTrueConvGammaMass           = kTRUE;
Bool_t kGCplotESDTrueConvGammaWidth          = kTRUE;
Bool_t kGCplotESDTrueConvGammaChi2           = kTRUE;
Bool_t kGCplotESDTrueConvGammaNDF            = kTRUE;
Bool_t kGCplotESDTrueConvGammaRapid          = kTRUE;
Bool_t kGCplotESDTrueConvGammaPtvsEta        = kTRUE;
Bool_t kGCplotESDTrueConversionR             = kTRUE;
Bool_t kGCplotESDTrueConversionZR            = kTRUE;
Bool_t kGCplotESDTrueConversionXY            = kTRUE;
Bool_t kGCplotESDTrueConversionOpeningAngle  = kTRUE;
Bool_t kGCplotESDTrueConvGammaCosPointingAngle     = kTRUE;
Bool_t kGCplotESDTrueConvGammaDcaDaugthers         = kTRUE;
Bool_t kGCplotESDTrueConvGammaNormDcaDistDaugthers = kTRUE;
Bool_t kGCplotESDTrueConvGammaLikelihoodAP         = kTRUE;
Bool_t kGCplotESDTrueConvGammaEAsymmetryP         = kTRUE;
Bool_t kGCplotESDTrueConvGammaPAsymmetryP         = kTRUE;
Bool_t kGCplotESDTrueConvGammaEdEdxP         = kTRUE;
Bool_t kGCplotESDTrueConvGammaPdEdxP         = kTRUE;


Bool_t kGCplotESDTrueConvGammaPtvsChi2       = kTRUE;
Bool_t kGCplotESDTrueConvGammaEtavsChi2      = kTRUE;
Bool_t kGCplotESDTrueConvGammaMCPtEta        = kTRUE;
Bool_t kGCplotESDTrueConversionMCZR          = kTRUE;
Bool_t kGCplotESDTrueConversionMCXY          = kTRUE;

Bool_t kGCplotESDNoCutConvGammaEnergy         = kTRUE;
Bool_t kGCplotESDNoCutConvGammaPt             = kTRUE;
Bool_t kGCplotESDNoCutConvGammaEta            = kTRUE;
Bool_t kGCplotESDNoCutConvGammaPhi            = kTRUE;
Bool_t kGCplotESDNoCutConvGammaMass           = kTRUE;
Bool_t kGCplotESDNoCutConvGammaWidth          = kTRUE;
Bool_t kGCplotESDNoCutConvGammaChi2           = kTRUE;
Bool_t kGCplotESDNoCutConvGammaNDF            = kTRUE;
Bool_t kGCplotESDNoCutConvGammaRapid          = kTRUE;
Bool_t kGCplotESDNoCutConvGammaPtvsEta        = kTRUE;
Bool_t kGCplotESDNoCutConversionR             = kTRUE;
Bool_t kGCplotESDNoCutConversionZR            = kTRUE;
Bool_t kGCplotESDNoCutConversionXY            = kTRUE;
Bool_t kGCplotESDNoCutConversionOpeningAngle  = kTRUE;
Bool_t kGCplotESDNoCutConvGammaCosPointingAngle     = kTRUE;
Bool_t kGCplotESDNoCutConvGammaDcaDaugthers         = kTRUE;
Bool_t kGCplotESDNoCutConvGammaNormDcaDistDaugthers = kTRUE;
Bool_t kGCplotESDNoCutConvGammaLikelihoodAP         = kTRUE;

Bool_t kGCplotESDNoCutConvGammaEAsymmetryP         = kTRUE;
Bool_t kGCplotESDNoCutConvGammaPAsymmetryP         = kTRUE;
Bool_t kGCplotESDNoCutConvGammaEdEdxP         = kTRUE;
Bool_t kGCplotESDNoCutConvGammaPdEdxP         = kTRUE;
Bool_t kGCplotESDNoCutConvGammaPtvsChi2       = kTRUE;
Bool_t kGCplotESDNoCutConvGammaEtavsChi2      = kTRUE;
Bool_t kGCplotESDNoCutConvGammaMCPtEta        = kTRUE;
Bool_t kGCplotESDNoCutConversionMCZR          = kTRUE;
Bool_t kGCplotESDNoCutConversionMCXY          = kTRUE;

Bool_t kGCplotESDMotherOpeningAngleGamma = kTRUE;
Bool_t kGCplotESDMotherEnergy            = kTRUE;
Bool_t kGCplotESDMotherPt                = kTRUE;
Bool_t kGCplotESDMotherEta               = kTRUE;
Bool_t kGCplotESDMotherPhi               = kTRUE;
Bool_t kGCplotESDMotherMass              = kTRUE;
Bool_t kGCplotESDMotherR                 = kTRUE;
Bool_t kGCplotESDMotherZR                = kTRUE;
Bool_t kGCplotESDMotherXY                = kTRUE;
Bool_t kGCplotESDMotherRapid             = kTRUE;

Bool_t kGCplotESDBackgroundOpeningAngleGamma = kTRUE;
Bool_t kGCplotESDBackgroundEnergy            = kTRUE;
Bool_t kGCplotESDBackgroundPt                = kTRUE;
Bool_t kGCplotESDBackgroundEta               = kTRUE;
Bool_t kGCplotESDBackgroundPhi               = kTRUE;
Bool_t kGCplotESDBackgroundMass              = kTRUE;
Bool_t kGCplotESDBackgroundR                 = kTRUE;
Bool_t kGCplotESDBackgroundZR                = kTRUE;
Bool_t kGCplotESDBackgroundXY                = kTRUE;
Bool_t kGCplotESDBackgroundRapid             = kTRUE;

Bool_t kGCplotMapping = kTRUE;       

Bool_t kGCplotResolutiondPt = kTRUE;
Bool_t kGCplotResolutiondR  = kTRUE;
Bool_t kGCplotResolutiondZ  = kTRUE;

Bool_t kGCplotResolutiondRdPt = kTRUE;

Bool_t kGCplotResolutionMCPt = kTRUE;
Bool_t kGCplotResolutionMCR  = kTRUE;
Bool_t kGCplotResolutionMCZ  = kTRUE;

Bool_t kGCplotResolutionESDPt = kTRUE;
Bool_t kGCplotResolutionESDR  = kTRUE;
Bool_t kGCplotResolutionESDZ  = kTRUE;

Bool_t kGCplotESDNumberOfV0s          = kTRUE;
Bool_t kGCplotESDNumberOfSurvivingV0s = kTRUE;
Bool_t kGCplotESDNumberOfContributorsVtx = kTRUE;

//  debug histograms
Bool_t kGCplotESDCutGetOnFly      = kTRUE;
Bool_t kGCplotESDCutNContributors = kTRUE;
Bool_t kGCplotESDCutLikeSign      = kTRUE;
Bool_t kGCplotESDCutRefit         = kTRUE;
Bool_t kGCplotESDCutKink          = kTRUE;
Bool_t kGCplotESDCutPIDProb       = kTRUE;
Bool_t kGCplotESDCutdedxSigmaElectronLine=kTRUE;
Bool_t kGCplotESDCutdedxSigmaPionLine=kTRUE;
Bool_t kGCplotESDCutR             = kTRUE;
Bool_t kGCplotESDCutLine          = kTRUE;
Bool_t kGCplotESDGoodV0s          = kTRUE;
Bool_t kGCplotESDCutNDF           = kTRUE;
Bool_t kGCplotESDCutChi2          = kTRUE;
Bool_t kGCplotESDCutEta           = kTRUE;
Bool_t kGCplotESDCutPt            = kTRUE;
Bool_t kGCplotESDTrueConvGammaTrackLength =kTRUE;
Bool_t kGCplotESDTrueConvGammaTrackLengthVSInvMass =kTRUE;

Bool_t kGCplotPi0Spectra = kTRUE;
Bool_t kGCplotEtaSpectra = kTRUE;

/////////////Chi_c Analysis//////////////////////////
Bool_t kGCplotStatsElectrons                                  = kTRUE;
Bool_t kGCplotRecENegJPsiPtDiff                               = kTRUE;
Bool_t kGCplotRecEPosJPsiPtDiff                               = kTRUE;
Bool_t kGCplotRecEPosENegR                                    = kTRUE;
Bool_t kGCplotRecEPosENegEta                                  = kTRUE;
Bool_t kGCplotESDInvMassePluseMinus                           = kTRUE;
Bool_t kGCplotESDInvMassGammaePluseMinusChiC                  = kTRUE;
Bool_t kGCplotESDInvMassGammaePluseMinusPi0                   = kTRUE;
Bool_t kGCplotESDElectronPosNegPt                             = kTRUE;
Bool_t kGCplotESDElectronPosNegEta                            = kTRUE;
Bool_t kGCplotESDElectronPosNegAngle                          = kTRUE;
Bool_t kGCplotMCElectronPosNegPt                              = kTRUE;
Bool_t kGCplotMCElectronPosNegEta                             = kTRUE;
Bool_t kGCplotMCElectronPosNegJPsiAngle                       = kTRUE;
Bool_t kGCplotESDElectronPosNegPi0Angle                       = kTRUE;
Bool_t kGCplotMCElectronPosNegPi0Angle                        = kTRUE;
Bool_t kGCplotTableElectrons                                  = kTRUE;
Bool_t kGCplotESDEPosBackground                               = kTRUE;
Bool_t kGCplotESDENegBackground                               = kTRUE;
Bool_t kGCplotESDEPosENegBackground                           = kTRUE;
Bool_t kGCplotESDEPosENegBackgroundCut                        = kTRUE;
Bool_t kGCplotESDePoseNegAngle                                = kTRUE;
Bool_t kGCplotESDEPosENegGammaBackgroundMX                    = kTRUE;
Bool_t kGCplotMCLabels                                        = kTRUE;
///////////////////////////////////////////////////////////////////

//---------------- Gamma Jet analysis ----------------------------
Bool_t kGCplotdPhiHdrGam            = kTRUE;
Bool_t kGCplotdPhiHdrGamIsolated    = kTRUE;
Bool_t kGCplotMinimumIsoDistance    = kTRUE;
Bool_t kGCplotFFzHdrGam             = kTRUE;
Bool_t kGCplotImbalanceHdrGam       = kTRUE;
//----------------------------------------------------------------


/** ----------------- end define which histograms to plot here -------------------------------*/



/** ----------- Define the binning for the different plot types here -------------------------*/
//R-plots
Int_t kGCnXBinsR = 500;
Double_t kGCfirstXBinR = 0.;
Double_t kGClastXBinR = 250.;

//ZR-plots
Int_t kGCnXBinsZR = 1200;
Double_t kGCfirstXBinZR = -300.;
Double_t kGClastXBinZR = 300.;
Int_t kGCnYBinsZR = 500;
Double_t kGCfirstYBinZR = 0.;
Double_t kGClastYBinZR = 250.;

//XY-plots
Int_t kGCnXBinsXY = 1000;
Double_t kGCfirstXBinXY = -250.;
Double_t kGClastXBinXY = 250.;
Int_t kGCnYBinsXY = 1000;
Double_t kGCfirstYBinXY = -250.;
Double_t kGClastYBinXY = 250.;

//OpenAngle-plots
Int_t kGCnXBinsOpeningAngle = 400;
Double_t kGCfirstXBinOpeningAngle = 0.;
Double_t kGClastXBinOpeningAngle = TMath::Pi();

//CosPointingAngle-plots
Int_t kGCnXBinsCosPointingAngle = 400;
Double_t kGCfirstXBinCosPointingAngle = 0.99;
Double_t kGClastXBinCosPointingAngle = 1.01;

//DCA Daugthers-plots
Int_t kGCnXBinsDcaDaughters = 400;
Double_t kGCfirstXBinDcaDaughters= 0.;
Double_t kGClastXBinDcaDaughters = 5.;

//Norm DCA dist Daugthers-plots
Int_t kGCnXBinsNormDcaDistDaughters = 400;
Double_t kGCfirstXBinNormDcaDistDaughters= 0.;
Double_t kGClastXBinNormDcaDistDaughters = 10.;

//LikelihoodAP Plots
Int_t kGCnXBinsLikelihoodAP = 400;
Double_t kGCfirstXBinLikelihoodAP= 0.;
Double_t kGClastXBinLikelihoodAP = 2.;


//Energy-plots
Int_t kGCnXBinsEnergy = 200;
Double_t kGCfirstXBinEnergy = 0.;
Double_t kGClastXBinEnergy = 50.;

//P-plots
Int_t kGCnXBinsP = 200;
Double_t kGCfirstXBinP = 0.;
Double_t kGClastXBinP = 50.;

//dEdx-plots
Int_t kGCnYBinsdEdx = 400;
Double_t kGCfirstYBindEdx = 0.;
Double_t kGClastYBindEdx = 400.;

//Asymmetry-plots
Int_t kGCnYBinsAsymmetry = 200;
Double_t kGCfirstYBinAsymmetry = 0.;
Double_t kGClastYBinAsymmetry = 1.;


//Pt-plots
Int_t kGCnXBinsPt = 200;
Double_t kGCfirstXBinPt = 0.;
Double_t kGClastXBinPt = 50.;

//Eta-plots
Int_t kGCnXBinsEta = 40;
Double_t kGCfirstXBinEta = -2.;
Double_t kGClastXBinEta = 2.;

//Rapidity
Int_t kGCnXBinsRapid = 200;
Double_t kGCfirstXBinRapid = -10.;
Double_t kGClastXBinRapid = 10.;

//Phi-plots
Int_t kGCnXBinsPhi = 72;
Double_t kGCfirstXBinPhi = -TMath::Pi();
Double_t kGClastXBinPhi = TMath::Pi();

//Mapping-plots
Int_t kGCnXBinsMapping = 400;
Double_t kGCfirstXBinMapping = -100.;
Double_t kGClastXBinMapping = 100.;
Int_t kGCnYBinsMapping = 40;
Double_t kGCfirstYBinMapping = -2;
Double_t kGClastYBinMapping = 2;

//ResolutionPlots
//RESdPt
Int_t kGCnXBinsResdPt=500;
Int_t kGCfirstXBinResdPt= 0;
Int_t kGClastXBinResdPt=5;
Int_t kGCnYBinsResdPt=1000;
Int_t kGCfirstYBinResdPt= -5;
Int_t kGClastYBinResdPt=5;

//RESdR
Int_t kGCnXBinsResdR=500;
Int_t kGCfirstXBinResdR= 0;
Int_t kGClastXBinResdR=250;
Int_t kGCnYBinsResdR=100;
Int_t kGCfirstYBinResdR= -25;
Int_t kGClastYBinResdR=25;

//RESdZ
Int_t kGCnXBinsResdZ=80;
Int_t kGCfirstXBinResdZ= -20;
Int_t kGClastXBinResdZ=20;
Int_t kGCnYBinsResdZ=80;
Int_t kGCfirstYBinResdZ= -20;
Int_t kGClastYBinResdZ=20;

//RESdRdPt
Int_t kGCnXBinsResdRdPt=440;
Int_t kGCfirstXBinResdRdPt= -22;
Int_t kGClastXBinResdRdPt=22;
Int_t kGCnYBinsResdRdPt=100;
Int_t kGCfirstYBinResdRdPt= -5;
Int_t kGClastYBinResdRdPt=5;

//RESMCPt
Int_t kGCnXBinsResPt=100;
Int_t kGCfirstXBinResPt= 0;
Int_t kGClastXBinResPt=5;

//RESMCR
Int_t kGCnXBinsResR=500;
Int_t kGCfirstXBinResR= 0;
Int_t kGClastXBinResR=250;

//RESMCZ
Int_t kGCnXBinsResZ=500;
Int_t kGCfirstXBinResZ= 0;
Int_t kGClastXBinResZ=250;

//GammaMass-plots
Int_t kGCnXBinsGammaMass = 4000;
Double_t kGCfirstXBinGammaMass = 0.;
Double_t kGClastXBinGammaMass = 1.;

//Pi0Mass-plots
Int_t kGCnXBinsPi0Mass = 100;
Double_t kGCfirstXBinPi0Mass = 0.;
Double_t kGClastXBinPi0Mass = 1.;

//EtaMass-plots
Int_t kGCnXBinsEtaMass = 100;
Double_t kGCfirstXBinEtaMass = 0.;
Double_t kGClastXBinEtaMass = 1.;

//GammaWidth-plots
Int_t kGCnXBinsGammaWidth = 100;
Double_t kGCfirstXBinGammaWidth = 0.;
Double_t kGClastXBinGammaWidth = 1.;

//GammaChi2-plots
Int_t kGCnXBinsGammaChi2 = 100;
Double_t kGCfirstXBinGammaChi2 = 0;
Double_t kGClastXBinGammaChi2 = 100.;

//GammaNDF-plots
Int_t kGCnXBinsGammaNDF = 10;
Double_t kGCfirstXBinGammaNDF = 0.;
Double_t kGClastXBinGammaNDF = 10.;

//Spectra-plots
Int_t kGCnXBinsSpectra = 500;
Double_t kGCfirstXBinSpectra = 0.;
Double_t kGClastXBinSpectra = 1.;
Int_t kGCnYBinsSpectra = 100;
Double_t kGCfirstYBinSpectra = 0.;
Double_t kGClastYBinSpectra = 50.;

//track length plots
Int_t kGCnXBinsTrackLength = 1000;
Double_t kGCfirstXBinTrackLength = 0;
Double_t kGClastXBinTrackLength = 500;

/////////Chic_Analysis///////////////////////////////////
Int_t kGCnXBinsEPt = 1000;
Double_t kGCfirstXBinEPt = 0.;
Double_t kGClastXBinJPsiPt  = 10;

Int_t kGCnXBinsJPsiMass = 1000;
Double_t kGCfirstXBinJPsiMass = 0.;
Double_t kGClastXBinJPsiMass = 10.;

Int_t kGCnXBinsChicMass = 1000;
Double_t kGCfirstXBinChicMass = 0.;
Double_t kGClastXBinChicMass  = 10.;

Int_t kGCnXBinsPi0Mass  = 1000;
Double_t kGCfirstXBinPi0Mass = 0.;
Double_t kGClastXBinPi0Mass  = 1.;

Int_t kGCnXBinsEPosNegPt = 1000;
Double_t kGCfirstXBinEPosNegPt = 0.;
Double_t kGClastXBinEPosNegPt  = 10.;

Int_t kGCnXBinsEPosNegEta = 200;
Double_t kGCfirstXBinEPosNegEta = -1.2;
Double_t kGClastXBinEPosNegEta  = 1.2;

Int_t kGCnXBinsEPosNegAngle = 200;
Double_t kGCfirstXBinEPosNegAngle = 0.;
Double_t kGClastXBinEPosNegAngle = TMath::Pi();

Int_t kGCnXBinsEBackground = 1000;
Double_t kGCfirstXBinEBackground = 0.;
Double_t kGClastXBinEBackground  = 10.;

Int_t kGCnXBinsEBackgroundCut = 100;
Double_t kGCfirstXBinEBackgroundCut = 0.;
Double_t kGClastXBinEBackgroundCut  = 0.015.;

Int_t kGCnXBinsMCLabels = 10;
Double_t kGCfirstXBinMCLabels = 0.;
Double_t kGClastXBinMCLabels  = 10.;

Int_t kGCnElementsElectronTable = 19;

//18 elements
const char * kGCelectronTable[] = {
  "Num. Events",  "MC e+ J/Psi |\\eta|<0.9","MC e- J/Psi |\\eta|<0.9","MC e+ e+ from J/Psi |\\eta|<0.9",
  "ESDtracks",    "Kink Cut",
  "Vertex Cut","TRDOut","TRDrefit","TPCrefit",
  "ITSrefit","TRDout+TPC+TPC+ITS+nsigma>3 Pass","pid!=0","ESDElec","ESD e+ JPsi",
  "ESD e- JPsi","ESD e+ e- JPSI","MC: gamma < 1.2","e+,e- < 0.9 g <1.2"
};


// for Gamma Jet analysis
Int_t kGCnXBinsdphiHdrGam = 100;
Double_t kGCfirstXBindphiHdrGam = -TMath::PiOver2();
Double_t kGClastXBindphiHdrGam = 3*TMath::PiOver2();

Int_t kGCnXBinsMinimumIsoDistance = 100;
Double_t kGCfirstXBinMinimumIsoDistance = 0.;
Double_t kGClastXBinMinimumIsoDistance = TMath::PiOver2();

Int_t kGCnXBinsFFzHdrGam = 100;
Double_t kGCfirstXBinFFzHdrGam = 0.;
Double_t kGClastXBinFFzHdrGam = 5;

Int_t kGCnXBinsImbalanceHdrGam = 100;
Double_t kGCfirstXBinImbalanceHdrGam = -5.;
Double_t kGClastXBinImbalanceHdrGam = 5.;
////////////////////////////////////////////////////////


/** ---------- end Define the binning for the different plot types here ----------------------*/


/************************************************************************************************
 *                                                                                              *
 *                                                                                              *
 *                     EVERYTHING BELOW IS FOR DEVELOPERS ONLY                                  *
 *                                                                                              *
 *                                                                                              *
 ************************************************************************************************/
TString kGCoutputFileName = "histogramsGammaConversion";
TString kGCoutputFileAppendix = "";
TString kGCdataList = "";
Bool_t kGCwriteNtuple = kFALSE;
// WE DOO NOT NEED TO CHANGE THIS (kGCusePWG4PartCorr) ANYMORE SINCE IT IS TAKEN CARE OF AUTOMATICALLY NOW
Bool_t kGCusePWG4PartCorr = kTRUE;

/** Flag to enable running on train  */
Bool_t kGCrunOnTrain = kFALSE;

/** ------------------------------ Monte Carlo flag -----------------------------------------*/
Bool_t kGCdoMCTruth = kTRUE;
/** ---------------------------- end Monte Carlo flag ---------------------------------------*/

/** ------------------------------ Selecting trigger CINT1B -----------------------------------*/
Bool_t kGCtriggerCINT1B = kFALSE;
/** ---------------------------- end Monte Carlo flag ---------------------------------------*/

/** ------------------------- Choose KFParticle OR ESDTrack  --------------------------------*/
Bool_t kGCuseKFParticle = kTRUE;
Bool_t kGCuseESDTrack   = kFALSE;
/** ----------------------- end Choose KFParticle OR ESDTrack  -----------------------------*/

/**------------------------------Flag to apply dEdx cut base on sigmas to electron line----------*/
Bool_t kGCdodEdxSigmaCut= kTRUE;
/**------------------------------end Flag to apply NsigmadEdx cut ----------*/
Double_t kGCPIDnSigmaAboveElectronLine=10;
Double_t kGCPIDnSigmaBelowElectronLine=-4;
Double_t kGCPIDnSigmaAbovePionLine=0;
Double_t kGCPIDMinPnSigmaAbovePionLine=5;
 


Bool_t kGCcalculateBackground = kTRUE;

Bool_t scanArguments(TString arguments){
  Bool_t iResult = kTRUE;
        
  TString allArgs=arguments;
  TString argument;
  int bMissingParam=0;
        
  TObjArray* pTokens=allArgs.Tokenize(" ");
  if (pTokens) {
                
    for(int i=0; i<pTokens->GetEntries() && iResult==kTRUE; i++) {
      argument=((TObjString*)pTokens->At(i))->GetString();
                        
      if(argument.IsNull()) continue;
      // -- deconvolute-time option
      if(argument.CompareTo("-data-list") == 0){
        if((bMissingParam=(++i>=pTokens->GetEntries()))) break;
        kGCdataList = ((TObjString*)pTokens->At(i))->GetString();
        if(kGCdataList.IsNull()){
          cout<<"-data-list is NULL"<<endl;
          iResult=kFALSE;
        }
        else{
          cout<<"Data list is set to: "<<kGCdataList<<endl;
        }
      }
      else if(argument.CompareTo("-output-file-name") == 0){
        if((bMissingParam=(++i>=pTokens->GetEntries()))) break;
        kGCoutputFileName = ((TObjString*)pTokens->At(i))->GetString();
        if(kGCoutputFileName.IsNull()){
          cout<<"-output-file-name is NULL"<<endl;
          iResult=kFALSE;
        }
        else{
          cout<<"Setting output file name to: "<<kGCoutputFileName<<endl;
        }
      }
      else if (argument.CompareTo("-bg-off") == 0){
        kGCcalculateBackground =kFALSE;
      }
      else if (argument.CompareTo("-use-offline-finder") == 0){
        kGCUseOnFlyV0Finder = kFALSE;
      }
      else if (argument.CompareTo("-write-ntuple") == 0){
        cout<<"Writing ntuple to file."<<endl;
        kGCwriteNtuple = kTRUE;
      }
      else if (argument.CompareTo("-run-on-train") == 0){
        cout<<"Running on train"<<endl;
        kGCrunOnTrain = kTRUE;
      }
      else if (argument.CompareTo("-run-jet") == 0){
        cout<<"Running jet analysis"<<endl;
        kGCrunJet = kTRUE;
      }
      else if (argument.CompareTo("-run-neutralmeson") == 0){
        cout<<"Running neutral meson analysis"<<endl;
        kGCrunNeutralMeson = kTRUE;
      }
      else if (argument.CompareTo("-run-neutral-meson") == 0){
        cout<<"Running neutral meson analysis"<<endl;
        kGCrunNeutralMeson = kTRUE;
      }
      else if (argument.CompareTo("-run-chic") == 0){
        cout<<"Running Chi_c analysis"<<endl;
        kGCrunChic = kTRUE;
      }
      else if (argument.CompareTo("-run-cf") == 0){
        cout<<"Running CF"<<endl;
        kGCrunCF = kTRUE;
      }

      else if (argument.CompareTo("-jet-off") == 0){
        cout<<"Skipping jet analysis"<<endl;
        kGCrunJet = kFALSE;
      }
      else if (argument.CompareTo("-neutralmeson-off") == 0){
        cout<<"Skipping neutral meson analysis"<<endl;
        kGCrunNeutralMeson = kFALSE;
      }
      else if (argument.CompareTo("-neutral-meson-off") == 0){
        cout<<"Skipping neutral meson analysis"<<endl;
        kGCrunNeutralMeson = kFALSE;
      }
      else if (argument.CompareTo("-chic-off") == 0){
        cout<<"Skipping Chi_c analysis"<<endl;
        kGCrunChic = kFALSE;
      }
      else if (argument.CompareTo("-mc-off") == 0){
        cout<<"Switching off kGCdoMCTruth"<<endl;
        kGCdoMCTruth = kFALSE;
      }
      else if (argument.CompareTo("-trigger-CINT1B") == 0){
        cout<<"Selecting ONLY kGCtriggerCINT1B"<<endl;
        kGCtriggerCINT1B = kTRUE;
      }
      else if (argument.CompareTo("-use-own-xyz") == 0){
        cout<<"Switching on use own xyz calculation"<<endl;
        kGCdoOwnXYZCalculation = kTRUE;
      }
      else if(argument.CompareTo("-append-to-output-file") == 0){
        if((bMissingParam=(++i>=pTokens->GetEntries()))) break;
        kGCoutputFileAppendix = TString("_")+((TObjString*)pTokens->At(i))->GetString();
        if(kGCoutputFileAppendix.IsNull()){
          cout<<"-appending-to-output-file is NULL"<<endl;
          iResult=kFALSE;
        }
        else{
          cout<<"Appending to the output file: "<<kGCoutputFileAppendix<<endl;
        }
      }
    }
    delete pTokens;
  }
  if (bMissingParam) {
    cout<<"Missing parameter for argument "<< argument.Data()<<endl;
    iResult=kFALSE;
  }
  return iResult;
}

void SetVersionLibrary(){
  // Check if the file $ALICE_ROOT/PWG4/GammaConv/AliAnalysisTaskGammaConversion.cxx exists.
  // If yes, we set kGCusePWG4PartCorr to false since we have a newer version
  // If no, kGCusePWG4PartCorr is true.
        
  TString file = gSystem->Getenv("ALICE_ROOT");
  file+="/PWG4/PartCorr/AliAnalysisTaskGammaConversion.cxx";
        
  ifstream stream;
  stream.open(file.Data());
        
  if(!stream){
    kGCusePWG4PartCorr=kFALSE;
  }
  else{
    kGCusePWG4PartCorr=kTRUE;
  }
  stream.close();
}



AliAnalysisTaskGammaConversion* ConfigGammaConversion(TString arguments,AliAnalysisDataContainer *cin_esd=NULL){
        
  if(!scanArguments(arguments)){
    break;
  }
        
  SetVersionLibrary(); // checks if PWG4GammaConv or PWG4PartCorr is used
        
  if(cin_esd == NULL && kGCrunOnTrain == kTRUE){
    cout<<"Error: kGCrunOnTrain flag is set to true but the input AliAnalysisDataContainer is NULL"<<endl;
    cout<<"       you must also supply the AliAnalysisDataContainer as an argument"<<endl;
    return;
  }
        
  if(cin_esd != NULL && kGCrunOnTrain == kFALSE){
    cout<<"Error: kGCrunOnTrain flag is set to false but the input AliAnalysisDataContainer is not null"<<endl;
    cout<<"       add -run-on-train to the arguments to turn switch kGCrunOnTrain to kTRUE"<<endl;
    return;
  }
  if(kGCrunOnTrain == kFALSE){
    if(kGCnumberOfFilesToAnalyze==0){
      ifstream dataInStream;
      dataInStream.open(kGCdataList.Data());
      if ( !dataInStream ){
        cout<<"Data list file does not exist: "<<kGCdataList.Data()<<endl;
        return 0;
      }
      string line;
      while ( !dataInStream.eof() )
        {
          getline(dataInStream, line);
          if(line.compare("") != 0){//checks if there is an empty line in the data list
            kGCnumberOfFilesToAnalyze++;
          }
        }
    }
    cout<<"Number Of files to analyze: "<<kGCnumberOfFilesToAnalyze<<endl;
                
    build();//build (if necessary) and load the libraries needed
                
    gROOT->LoadMacro("$ALICE_ROOT/PWG0/CreateESDChain.C"); // load the CreateChain macro
  }
                
  if(!kGCrunOnTrain){
    // for the train leave this to the steering macro
    AliLog::SetGlobalDebugLevel(0);
    AliLog::SetGlobalLogLevel(AliLog::kFatal);
  }
  // ------------------------------------------------------------------------
                
    // for CF
                
    //Container def.
    const Double_t ptmin = kGCfirstXBinPt;
    const Double_t ptmax = kGClastXBinPt;
    const Double_t etamin = kGCfirstXBinEta;
    const Double_t etamax = kGClastXBinEta;
    const Double_t massmin = kGCfirstXBinPi0Mass;
    const Double_t massmax = kGClastXBinPi0Mass;
                
                
    // sensitive variables
    UInt_t ipt = 0;
    UInt_t ieta = 1;
    UInt_t imass = 2;   
                
    //how many selection steps 
    UInt_t nstep = 15;
    const Int_t nvar = 3;
    const Int_t nbin0 = kGCnXBinsPt; 
    const Int_t nbin1 = kGCnXBinsEta;
    const Int_t nbin2 = kGCnXBinsPi0Mass;               
                
    //arrays for the number of bins in each dimension
    Int_t iBin[nvar];
    iBin[0] = nbin0;
    iBin[1] = nbin1;
    iBin[2] = nbin2;    
                
    //arrays for lower bounds
    Double_t *binLim0 = new Double_t[nbin0+1];
    Double_t *binLim1 = new Double_t[nbin1+1];  
    Double_t *binLim2 = new Double_t[nbin2+1];  
                
    // values for lower bounds
    for(Int_t i = 0; i <= nbin0; i++) binLim0[i] = ptmin + (ptmax - ptmin)/nbin0*i;
    for(Int_t i = 0; i <= nbin1; i++) binLim1[i] = etamin + (etamax - etamin)/nbin1*i;
    for(Int_t i = 0; i <= nbin2; i++) binLim2[i] = massmin + (massmax - massmin)/nbin2*i;
                
    // create container
    AliCFContainer *container = new AliCFContainer("container","container for gammaconversion", nstep,nvar,iBin);
    container->SetBinLimits(ipt,binLim0);
    container->SetBinLimits(ieta,binLim1);
    container->SetBinLimits(imass,binLim2);     
                
    AliCFManager *man = new AliCFManager();
    man->SetParticleContainer(container);
                
    // end ---------------------------------------------------------------------------
                
                

        
  AliGammaConversionHistograms* histograms = new AliGammaConversionHistograms();  
  AddHistograms(histograms);
        
  // Create the Analysis manager
  AliAnalysisManager *mgr =NULL;
  if(kGCrunOnTrain == kFALSE){
    mgr  = new AliAnalysisManager("My Manager", "My Analysis");
  }
  else{
    mgr = AliAnalysisManager::GetAnalysisManager();
  }
        
  if (!mgr) {
    ::Error("ConfigGammaConversion", "No analysis manager to connect to.");
    return NULL;
  }
  if(kGCrunOnTrain == kTRUE){
    if (!mgr->GetInputEventHandler()) {
      ::Error("ConfigGammaConversion", "This task requires an input event handler");
      return NULL;
    }
  }
  AliESDInputHandler* inpHandler = NULL;
        
  if(kGCrunOnTrain == kFALSE){
    // Define Input Event Handler 
    inpHandler = new AliESDInputHandler();
  }
  // Define MC Truth Event Handler
  AliMCEventHandler* mcHandler = NULL;
  if(kGCdoMCTruth){
    if(kGCrunOnTrain == kFALSE){
      mcHandler = new AliMCEventHandler();
    }
    else{
      mcHandler = (AliMCEventHandler*)mgr->GetMCtruthEventHandler();
    }
    if (!mcHandler) {
      ::Error("", "No MC handler connected");
      return NULL;
    }
  }
        
  // Define Output Event Handler and ad
  if(kGCrunOnTrain == kFALSE){
    if(fWriteStandardAOD == kTRUE){
      AliAODHandler* aodHandler = new AliAODHandler();
      TString fileOutAOD = "AOD_"+ kGCoutputFileName + kGCoutputFileAppendix + ".root";
      aodHandler->SetOutputFileName(fileOutAOD);
      mgr->SetOutputEventHandler (aodHandler);
    }
  }
        
  if(kGCrunOnTrain == kFALSE){
    mgr->SetInputEventHandler  (inpHandler);
    mgr->SetMCtruthEventHandler(mcHandler);
  }
  // Be sure you are told what you are doing
  // mgr->SetDebugLevel(10);
        
  // Declare Common Input Tchain
  AliAnalysisDataContainer *cinput1 = NULL;
  if(kGCusePWG4PartCorr){
    if(kGCrunOnTrain == kFALSE){
      cinput1 = mgr->CreateContainer("GammaConvChain",TChain::Class(),AliAnalysisManager::kInputContainer);
    }
    else{
      cinput1 = cin_esd;
    }
  }
  else{
      cinput1 = mgr->GetCommonInputContainer();
  }
        
  // Common Output Tree in common â\80\98defaultâ\80\99 output file
  // CKB kGCusePWG4PartCorr and writestandard are not mutually exclusive?
  AliAnalysisDataContainer *coutput1 = NULL;
  if(kGCusePWG4PartCorr){
    //    coutput1 = mgr->CreateContainer("GammaConvTree",TTree::Class(),AliAnalysisManager::kOutputContainer, "default");
    coutput1 = mgr->CreateContainer("GammaConvTree",TTree::Class(),AliAnalysisManager::kOutputContainer, "default");
  }
  else{
    if(fWriteStandardAOD){
      coutput1 = mgr->GetCommonOutputContainer();
    }
  }
        
  // Private output objects
  if(kGCoutputFileName.Contains(".root")){
    kGCoutputFileName.ReplaceAll(".root","");
  }
  if(kGCoutputFileAppendix.Contains(".root")){
    kGCoutputFileAppendix.ReplaceAll(".root","");
  }
  //TString fileOut = kGCoutputFileName + kGCoutputFileAppendix + ".root";

  TString outputfile = AliAnalysisManager::GetCommonFileName();  
  outputfile += ":PWG4_GammaConversion";
        
  AliAnalysisDataContainer *coutput2 = mgr->CreateContainer("histogramsAliGammaConversion", TList::Class(),AliAnalysisManager::kOutputContainer, outputfile);
  // for CF
  AliAnalysisDataContainer *coutput3 = mgr->CreateContainer("GammaConvccontainer0",AliCFContainer::Class(),AliAnalysisManager::kOutputContainer,outputfile);
        
  //------------------------ END: Define input/output handlers ---------------------------------------------------
        
  //check for errors in the specified data
  if(kGCuseKFParticle == kTRUE && kGCuseESDTrack == kTRUE){
    //Print warning, cannot use both
    ::Error("ConfigGammaConversion","Both kGCuseKFParticle and kGCuseESDTracks can be true at the same time")
      }
  if(kGCuseKFParticle == kFALSE && kGCuseESDTrack == kFALSE){
    //Print warning, one have to be specified
    ::Error("ConfigGammaConversion","Both kGCuseKFParticle and kGCuseESDTracks can be false at the same time")
      }
        
        
  //Create the V0Reader
  AliV0Reader * v0Reader = new AliV0Reader();
  if(kGCuseKFParticle){
    v0Reader->UseKFParticle();
  }
  else if(kGCuseESDTrack){
    v0Reader->UseESDTrack();
  }
  v0Reader->SetNegativeTrackPID(kGCpidOfNegativeTrack);
  v0Reader->SetPositiveTrackPID(kGCpidOfPositiveTrack);
  v0Reader->SetMaxRCut(kGCmaxRCut);
  v0Reader->SetEtaCut(kGCetaCut);
  v0Reader->SetPtCut(kGCptCut);
  v0Reader->SetLineCutZRSlope(kGCLineCutZRSlope);
  v0Reader->SetLineCutZValue(kGCLineCutZValue); 
  v0Reader->SetMaxZCut(kGCmaxZCut);     
  v0Reader->SetChi2CutConversion(kGCchi2CutConversion);
  v0Reader->SetChi2CutMeson(kGCchi2CutMeson);
  v0Reader->SetPIDProbability(kGCprobElectron);
  v0Reader->SetXVertexCut(kGCxVertexCut);
  v0Reader->SetYVertexCut(kGCyVertexCut);
  v0Reader->SetZVertexCut(kGCzVertexCut);
  v0Reader->SetSigmaMass(kGCsigmaCutGammaMass);
  v0Reader->SetUseImprovedVertex(kGCuseImprovedVertex);
  v0Reader->SetDoMCTruth(kGCdoMCTruth);
  v0Reader->SetUseOwnXYZCalculation(kGCdoOwnXYZCalculation);
  // for CF
  v0Reader->SetCFManager(man);
        
  // for dEdx N sigma Cut
  v0Reader->SetDodEdxSigmaCut(kGCdodEdxSigmaCut);
  v0Reader->SetPIDnSigmaAboveElectronLine(kGCPIDnSigmaAboveElectronLine);
  v0Reader->SetPIDnSigmaBelowElectronLine(kGCPIDnSigmaBelowElectronLine);
  v0Reader->SetPIDnSigmaAbovePionLine(kGCPIDnSigmaAbovePionLine);
  v0Reader->SetPIDMinPnSigmaAbovePionLine(kGCPIDMinPnSigmaAbovePionLine);
  v0Reader->SetOnFlyFlag(kGCUseOnFlyV0Finder);
        
  // Create the GammaConversionTask
  AliAnalysisTaskGammaConversion *gammaconversion = new AliAnalysisTaskGammaConversion("GammaConversionTask");
  gammaconversion->SetDebugLevel(0);
        
  gammaconversion->SetWriteNtuple(kGCwriteNtuple);
        
  gammaconversion->SetV0Reader(v0Reader);
  gammaconversion->SetCalculateBackground(kGCcalculateBackground);
  gammaconversion->Init();
        
  gammaconversion->SetElectronMass(kGCelectronMass);
  gammaconversion->SetGammaMass(kGCgammaMass);
  gammaconversion->SetPi0Mass(kGCpi0Mass);
  gammaconversion->SetEtaMass(kGCetaMass);
        
  gammaconversion->SetGammaWidth(kGCgammaWidth);
  gammaconversion->SetPi0Width(kGCpi0Width);
  gammaconversion->SetEtaWidth(kGCetaWidth);
        
  gammaconversion->SetMinOpeningAngleGhostCut(kGCminOpeningAngleGhostCut);
        
  // define the width constraint used by KF particle.
  Double_t gammaWidth = 0.01;
  Double_t pi0Width   = 0.01;
  Double_t etaWidth   = 0.01;
        
  gammaconversion->SetHistograms(histograms);
  v0Reader->SetHistograms(histograms);// also give the pointer to the v0reader, for debugging cuts

  gammaconversion->SetTriggerCINT1B(kGCtriggerCINT1B);
  gammaconversion->SetDoMCTruth(kGCdoMCTruth);
        
  gammaconversion->SetDoNeutralMeson(kGCrunNeutralMeson);
  gammaconversion->SetDoJet(kGCrunJet);
  gammaconversion->SetDoChic(kGCrunChic);

  // for CF
  gammaconversion->SetCFManager(man);
  gammaconversion->SetDoCF(kGCrunCF);
  v0Reader->SetDoCF(kGCrunCF);
        
  // Add task to the manager 
  mgr->AddTask(gammaconversion);
        
  // Connect I/O to the task
  mgr->ConnectInput (gammaconversion, 0, cinput1);
  

  // CKB Output slot 0 is NOT connected if WriteStandardAOD is false?
  if(fWriteStandardAOD){
    mgr->ConnectOutput(gammaconversion, 0, coutput1);
  }
  mgr->ConnectOutput(gammaconversion, 1, coutput2);
  mgr->ConnectOutput(gammaconversion, 2, coutput3);

  if(kGCrunOnTrain == kFALSE){
    if(kGCdataList.IsNull()){
      cout<<"Data list is not set, aborting."<<endl;
      return;
    }
                
    if(kGCrunOnTrain == kFALSE){
      TChain* chain= CreateESDChain(kGCdataList,kGCnumberOfFilesToAnalyze);
                        
      mgr->InitAnalysis();
                        
      mgr->PrintStatus();
                        
      mgr->StartAnalysis("local",chain);
    }
  }
  return gammaconversion;
}

void build() {
        
  TStopwatch timer;
  timer.Start();
  gSystem->Load("libTree.so");
  gSystem->Load("libGeom");
        
  ////
  //Setting up ESD.par//
  ////
  cout<<"compiling ESD"<<endl;
  setupPar("ESD");
  gSystem->Load("libVMC.so");
  gSystem->Load("libESD.so");
        
  ////
  ////
  //Setting up STEERBase.par//
  ////
  cout<<"compiling STEERBase"<<endl;
  setupPar("STEERBase");
  gSystem->Load("libSTEERBase.so");
        
  ////
  //Setting up AOD.par//
  ////
  cout<<"compiling AOD"<<endl;
  setupPar("AOD");
  gSystem->Load("libAOD.so");
        
  ////
  //Setting up ANALYSIS.par//
  ////
  cout<<"compiling ANALYSIS"<<endl;
  setupPar("ANALYSIS");
  gSystem->Load("libANALYSIS.so");
        
  ////
  //Setting up ANALYSISalice.par//
  ////
  cout<<"compiling ANALYSISalice"<<endl;
  setupPar("ANALYSISalice");
  gSystem->Load("libANALYSISalice.so");
        
  ////
  //Setting up CORRFW.par//
  ////
  cout<<"compiling CORRFW"<<endl;
  setupPar("CORRFW");
  gSystem->Load("CORRFW.so");
        
  ////
  //Setting up PWG4GammaConv.par//
  ////
  cout<<"compiling PWG4GammaConv"<<endl;
  setupPar("PWG4GammaConv");
  gSystem->Load("libPWG4GammaConv.so");
}

Int_t setupPar(const char* pararchivename) {
  ///////////////////
  // Setup PAR File//
  ///////////////////
  if (pararchivename) {
    char processline[1024];
    sprintf(processline,".! tar xvzf %s.par",pararchivename);
    gROOT->ProcessLine(processline);
    const char* ocwd = gSystem->WorkingDirectory();
    gSystem->ChangeDirectory(pararchivename);
                
    // check for BUILD.sh and execute
    if (!gSystem->AccessPathName("PROOF-INF/BUILD.sh")) {
      printf("*******************************\n");
      printf("*** Building PAR archive    ***\n");
      printf("*******************************\n");
                        
      if (gSystem->Exec("PROOF-INF/BUILD.sh")) {
        Error("runAnalysis","Cannot Build the PAR Archive! - Abort!");
        return -1;
      }
    }
    // check for SETUP.C and execute
    if (!gSystem->AccessPathName("PROOF-INF/SETUP.C")) {
      printf("*******************************\n");
      printf("*** Setup PAR archive       ***\n");
      printf("*******************************\n");
      gROOT->Macro("PROOF-INF/SETUP.C");
    }
                
    gSystem->ChangeDirectory("../");
  }                                                                                                                                               
  return 1;
}



void AddHistograms(AliGammaConversionHistograms *histograms){
  //---------------------------------------------- Jets ---------------------------------------------------------
  if(kGCrunJet == kTRUE){
    if (kGCplotdPhiHdrGam == kTRUE){
      histograms->AddHistogram("ESD_dphiHdrGam","ESD_dphiHdrGam", kGCnXBinsdphiHdrGam,kGCfirstXBindphiHdrGam,kGClastXBindphiHdrGam,"dphiHdrGam (rad)","Counts");
    }
                
    if (kGCplotdPhiHdrGamIsolated == kTRUE){
      histograms->AddHistogram("ESD_dphiHdrGamIsolated","ESD_dphiHdrGamIsolated",  kGCnXBinsdphiHdrGam,kGCfirstXBindphiHdrGam,kGClastXBindphiHdrGam,"dphiHdrGamIsolated (rad)","Counts");
    }
                
    if (kGCplotMinimumIsoDistance == kTRUE){
      histograms->AddHistogram("ESD_MinimumIsoDistance","ESD_MinimumIsoDistance", kGCnXBinsMinimumIsoDistance,kGCfirstXBinMinimumIsoDistance,kGClastXBinMinimumIsoDistance,"Minimum Iso Distance (rad)","Counts");
    }
                
    if (kGCplotFFzHdrGam == kTRUE){
      histograms->AddHistogram("ESD_FFzHdrGam","ESD_FFzHdrGam", kGCnXBinsFFzHdrGam, kGCfirstXBinFFzHdrGam,kGClastXBinFFzHdrGam,"FFz Hdr Gam","Counts");
    }
                
    if (kGCplotImbalanceHdrGam == kTRUE){
      histograms->AddHistogram("ESD_ImbalanceHdrGam","ESD_ImbalanceHdrGam", kGCnXBinsImbalanceHdrGam, kGCfirstXBinImbalanceHdrGam,kGClastXBinImbalanceHdrGam,"Imbalance Hdr Gam","Counts");
    }
  }//end if(kGCrunJet)
        
  //---------------------------------------------- Chi_c ---------------------------------------------------------
  if(kGCrunChic){
                
    if(kGCplotESDInvMassePluseMinus == kTRUE){histograms->AddHistogram("ESD_InvMass_ePluseMinus","",kGCnXBinsJPsiMass, kGCfirstXBinJPsiMass, kGClastXBinJPsiMass, "",
                                                                       "");}
    if(kGCplotESDInvMassePluseMinus == kTRUE){histograms->AddHistogram("ESD_InvMass_ePluseMinusTest","",kGCnXBinsJPsiMass, kGCfirstXBinJPsiMass, kGClastXBinJPsiMass,
                                                                       "","");}
    if(kGCplotESDInvMassePluseMinus == kTRUE){histograms->AddHistogram("ESD_InvMass_xPlusxMinus","",kGCnXBinsJPsiMass, kGCfirstXBinJPsiMass, kGClastXBinJPsiMass, "",
                                                                       "");}
    if(kGCplotESDElectronPosNegPt == kTRUE){histograms->AddHistogram("ESD_ElectronPosNegPt","",kGCnXBinsEPosNegPt,kGCfirstXBinEPosNegPt,kGClastXBinEPosNegPt,"","");}
    if(kGCplotESDElectronPosNegEta == kTRUE){histograms->AddHistogram("ESD_ElectronPosNegEta","",kGCnXBinsEPosNegEta,kGCfirstXBinEPosNegEta,kGClastXBinEPosNegEta,"","
                                                                                                                                                  ");}
                
    if(kGCplotESDElectronPosNegPt == kTRUE){histograms->AddHistogram("ESD_ElectronPosPt","",kGCnXBinsEPosNegPt,kGCfirstXBinEPosNegPt,kGClastXBinEPosNegPt,"","");}
    if(kGCplotESDElectronPosNegPt == kTRUE){histograms->AddHistogram("ESD_ElectronNegPt","",kGCnXBinsEPosNegPt,kGCfirstXBinEPosNegPt,kGClastXBinEPosNegPt,"","");}
                
    if(kGCplotESDElectronPosNegAngle == kTRUE){histograms->AddHistogram("ESD_ElectronPosNegJPsiAngle","",kGCnXBinsEPosNegAngle,kGCfirstXBinEPosNegAngle,kGClastXBinEPo
                                                                        sNegAngle,"","");}
    if(kGCplotMCElectronPosNegPt == kTRUE){histograms->AddHistogram("MC_ElectronPosNegPt","",kGCnXBinsEPosNegPt,kGCfirstXBinEPosNegPt,kGClastXBinEPosNegPt,"","");}
    if(kGCplotMCElectronPosNegEta == kTRUE){histograms->AddHistogram("MC_ElectronPosNegEta","",kGCnXBinsEPosNegEta,kGCfirstXBinEPosNegEta,kGClastXBinEPosNegEta,"","")
        ;}
    if(kGCplotMCElectronPosNegJPsiAngle == kTRUE){histograms->AddHistogram("MC_ElectronPosNegJPsiAngle","",kGCnXBinsEPosNegAngle,kGCfirstXBinEPosNegAngle,kGClastXBinE
                                                                           PosNegAngle,"","");}
    if(kGCplotESDePoseNegAngle == kTRUE){histograms->AddHistogram("ESD_eNegePosAngleBeforeCut","",kGCnXBinsEPosNegAngle,kGCfirstXBinEPosNegAngle,kGClastXBinEPosNegAngle,"","");}
    if(kGCplotESDePoseNegAngle == kTRUE){histograms->AddHistogram("ESD_eNegePosAngleAfterCut","",kGCnXBinsEPosNegAngle,kGCfirstXBinEPosNegAngle,kGClastXBinEPosNegAngle,"","");}
    if(kGCplotESDInvMassGammaePluseMinusChiC == kTRUE) {histograms->AddHistogram("ESD_InvMass_GammaePluseMinusChiC","",kGCnXBinsChicMass,kGCfirstXBinChicMass,kGClastXBinChicMass,"","");}
    if(kGCplotESDInvMassGammaePluseMinusChiC == kTRUE) {histograms->AddHistogram("ESD_InvMass_GammaePluseMinusChiCDiff","",kGCnXBinsChicMass,kGCfirstXBinChicMass,kGClastXBinChicMass,"","");}
    if(kGCplotESDInvMassGammaePluseMinusPi0 == kTRUE) {histograms->AddHistogram("ESD_InvMass_GammaePluseMinusPi0","",kGCnXBinsPi0Mass,kGCfirstXBinPi0Mass,kGClastXBinPi0Mass,"","");}
    if(kGCplotESDElectronPosNegPi0Angle == kTRUE){histograms->AddHistogram("ESD_ElectronPosNegPi0Angle","",kGCnXBinsEPosNegAngle,kGCfirstXBinEPosNegAngle,kGClastXBinEPosNegAngle,"","");}
    if(kGCplotMCElectronPosNegPi0Angle == kTRUE){histograms->AddHistogram("MC_ElectronPosNegPi0Angle","",kGCnXBinsEPosNegAngle,kGCfirstXBinEPosNegAngle,kGClastXBinEPosNegAngle,"","");}
                
    if(kGCplotESDEPosBackground == kTRUE){histograms->AddHistogram("ESD_EPosBackground","",kGCnXBinsEBackground,kGCfirstXBinEBackground,kGClastXBinEBackground,"","");}
                
    if(kGCplotESDEPosBackground == kTRUE){histograms->AddHistogram("ESD_EPosENegNoJPsiBG","",kGCnXBinsEBackground,kGCfirstXBinEBackground,kGClastXBinEBackground,"","");}
                
                
    if(kGCplotESDENegBackground == kTRUE){histograms->AddHistogram("ESD_ENegBackground","",kGCnXBinsEBackground,kGCfirstXBinEBackground,kGClastXBinEBackground,"","");}
    if(kGCplotESDEPosENegBackground == kTRUE){histograms->AddHistogram("ESD_EPosENegBackground","",kGCnXBinsEBackground,kGCfirstXBinEBackground,kGClastXBinEBackground,"","");}
    if(kGCplotESDEPosENegBackgroundCut == kTRUE){histograms->AddHistogram("ESD_EPosENegBackgroundCut","",kGCnXBinsEBackgroundCut,kGCfirstXBinEBackgroundCut,kGClastXBinEBackgroundCut,"","");}
                
    if(kGCplotESDEPosENegGammaBackgroundMX == kTRUE){histograms->AddHistogram("ESD_EPosENegGammaBackgroundMX","",kGCnXBinsEBackground,kGCfirstXBinEBackground,kGClastXBinEBackground,"","");}
    if(kGCplotESDEPosENegGammaBackgroundMX == kTRUE){histograms->AddHistogram("ESD_EPosENegGammaBackgroundMXDiff","",kGCnXBinsEBackground,kGCfirstXBinEBackground,kGClastXBinEBackground,"","");}
                
    if(kGCplotTableElectrons == kTRUE){ histograms->AddTable("Table_Electrons","",kGCnElementsElectronTable,kGCelectronTable);}
  }// end kGCrunChic
        
  //---------------------------------------------- Neutral Meson ---------------------------------------------------------
  if(kGCrunNeutralMeson){
    if(kGCplotMCConversionR == kTRUE){ histograms->AddHistogram("MC_Conversion_R","Radius of gamma conversion points",kGCnXBinsR, kGCfirstXBinR, kGClastXBinR,"counts","cm");}
    if(kGCplotMCConversionZR == kTRUE){ histograms->AddHistogram("MC_Conversion_ZR","Radius of gamma conversion points vs Z",kGCnXBinsZR, kGCfirstXBinZR, kGClastXBinZR, kGCnYBinsZR, kGCfirstYBinZR, kGClastYBinZR, "cm", "cm");}
    if(kGCplotMCConversionXY == kTRUE){ histograms->AddHistogram("MC_Conversion_XY","Gamma XY converison point.",kGCnXBinsXY, kGCfirstXBinXY, kGClastXBinXY, kGCnYBinsXY, kGCfirstYBinXY, kGClastYBinXY, "cm", "cm");}
    if(kGCplotMCConversionOpeningAngle == kTRUE){ histograms->AddHistogram("MC_Conversion_OpeningAngle","Opening angle of e+e- pairs from gamma conversion",kGCnXBinsOpeningAngle, kGCfirstXBinOpeningAngle, kGClastXBinOpeningAngle, "counts", "cm");}
    if(kGCplotMCConvGammaEAsymmetryP== kTRUE){ histograms->AddHistogram("MC_ConvGamma_E_AsymmetryP" ,"" ,kGCnXBinsP, kGCfirstXBinP, kGClastXBinP,kGCnYBinsAsymmetry, kGCfirstYBinAsymmetry, kGClastYBinAsymmetry,"", "");}
    if(kGCplotMCConvGammaPAsymmetryP== kTRUE){ histograms->AddHistogram("MC_ConvGamma_P_AsymmetryP" ,"" ,kGCnXBinsP, kGCfirstXBinP, kGClastXBinP,kGCnYBinsAsymmetry, kGCfirstYBinAsymmetry, kGClastYBinAsymmetry,"", "");}
                

    if(kGCplotMCEEnergy == kTRUE){ histograms->AddHistogram("MC_E_Energy" ,"" , kGCnXBinsEnergy, kGCfirstXBinEnergy, kGClastXBinEnergy, "", "");}
    if(kGCplotMCEPt == kTRUE){ histograms->AddHistogram("MC_E_Pt" ,"" , kGCnXBinsPt, kGCfirstXBinPt, kGClastXBinPt, "", "");}
    if(kGCplotMCEEta == kTRUE){ histograms->AddHistogram("MC_E_Eta" ,"" , kGCnXBinsEta, kGCfirstXBinEta, kGClastXBinEta, "", "");}
    if(kGCplotMCEPhi == kTRUE){ histograms->AddHistogram("MC_E_Phi" ,"" , kGCnXBinsPhi, kGCfirstXBinPhi, kGClastXBinPhi, "", "");}
                
    if(kGCplotMCPEnergy == kTRUE){ histograms->AddHistogram("MC_P_Energy" ,"" , kGCnXBinsEnergy, kGCfirstXBinEnergy, kGClastXBinEnergy, "", "");}
    if(kGCplotMCPPt == kTRUE){ histograms->AddHistogram("MC_P_Pt" ,"" , kGCnXBinsPt, kGCfirstXBinPt, kGClastXBinPt, "", "");}
    if(kGCplotMCPEta == kTRUE){ histograms->AddHistogram("MC_P_Eta" ,"" , kGCnXBinsEta, kGCfirstXBinEta, kGClastXBinEta, "", "");}
    if(kGCplotMCPPhi == kTRUE){ histograms->AddHistogram("MC_P_Phi" ,"" , kGCnXBinsPhi, kGCfirstXBinPhi, kGClastXBinPhi, "", "");}
                
    if(kGCplotMCallGammaEnergy == kTRUE){ histograms->AddHistogram("MC_allGamma_Energy" ,"" , kGCnXBinsEnergy, kGCfirstXBinEnergy, kGClastXBinEnergy, "", "");}
    if(kGCplotMCallGammaPt == kTRUE){ histograms->AddHistogram("MC_allGamma_Pt" ,"" , kGCnXBinsPt, kGCfirstXBinPt, kGClastXBinPt, "", "");}
    if(kGCplotMCallGammaEta == kTRUE){ histograms->AddHistogram("MC_allGamma_Eta" ,"" , kGCnXBinsEta, kGCfirstXBinEta, kGClastXBinEta, "", "");}
    if(kGCplotMCallGammaPhi == kTRUE){ histograms->AddHistogram("MC_allGamma_Phi" ,"" , kGCnXBinsPhi, kGCfirstXBinPhi, kGClastXBinPhi, "", "");}
    if(kGCplotMCallGammaRapid == kTRUE){ histograms->AddHistogram("MC_allGamma_Rapid" ,"" , kGCnXBinsRapid, kGCfirstXBinRapid, kGClastXBinRapid, "", "");}
                
    if(kGCplotMCConvGammaEnergy == kTRUE){ histograms->AddHistogram("MC_ConvGamma_Energy" ,"" , kGCnXBinsEnergy, kGCfirstXBinEnergy, kGClastXBinEnergy, "", "");}
    if(kGCplotMCConvGammaPt == kTRUE){ histograms->AddHistogram("MC_ConvGamma_Pt" ,"" , kGCnXBinsPt, kGCfirstXBinPt, kGClastXBinPt, "", "");}
    if(kGCplotMCConvGammaEta == kTRUE){ histograms->AddHistogram("MC_ConvGamma_Eta" ,"" , kGCnXBinsEta, kGCfirstXBinEta, kGClastXBinEta, "", "");}
    if(kGCplotMCConvGammaPhi == kTRUE){ histograms->AddHistogram("MC_ConvGamma_Phi" ,"" , kGCnXBinsPhi, kGCfirstXBinPhi, kGClastXBinPhi, "", "");}
    if(kGCplotMCConvGammaRapid == kTRUE){ histograms->AddHistogram("MC_ConvGamma_Rapid" ,"" , kGCnXBinsRapid, kGCfirstXBinRapid, kGClastXBinRapid, "", "");}
    if(kGCplotMCConvGammaPtvsEta == kTRUE){ histograms->AddHistogram("MC_ConvGamma_Pt_Eta","", kGCnXBinsPt, kGCfirstXBinPt, kGClastXBinPt,kGCnXBinsEta, kGCfirstXBinEta, kGClastXBinEta,"","");}
                
    if(kGCplotMCallDirectGammaEnergy == kTRUE){ histograms->AddHistogram("MC_allDirectGamma_Energy" ,"" , kGCnXBinsEnergy, kGCfirstXBinEnergy, kGClastXBinEnergy, "", "");}
    if(kGCplotMCallDirectGammaPt == kTRUE){ histograms->AddHistogram("MC_allDirectGamma_Pt" ,"" , kGCnXBinsPt, kGCfirstXBinPt, kGClastXBinPt, "", "");}
    if(kGCplotMCallDirectGammaEta == kTRUE){ histograms->AddHistogram("MC_allDirectGamma_Eta" ,"" , kGCnXBinsEta, kGCfirstXBinEta, kGClastXBinEta, "", "");}
    if(kGCplotMCallDirectGammaPhi == kTRUE){ histograms->AddHistogram("MC_allDirectGamma_Phi" ,"" , kGCnXBinsPhi, kGCfirstXBinPhi, kGClastXBinPhi, "", "");}
    if(kGCplotMCallDirectGammaRapid == kTRUE){ histograms->AddHistogram("MC_allDirectGamma_Rapid" ,"" , kGCnXBinsRapid, kGCfirstXBinRapid, kGClastXBinRapid, "", "");}
                
    if(kGCplotMCConvDirectGammaEnergy == kTRUE){ histograms->AddHistogram("MC_ConvDirectGamma_Energy" ,"" , kGCnXBinsEnergy, kGCfirstXBinEnergy, kGClastXBinEnergy, "", "");}
    if(kGCplotMCConvDirectGammaPt == kTRUE){ histograms->AddHistogram("MC_ConvDirectGamma_Pt" ,"" , kGCnXBinsPt, kGCfirstXBinPt, kGClastXBinPt, "", "");}
    if(kGCplotMCConvDirectGammaEta == kTRUE){ histograms->AddHistogram("MC_ConvDirectGamma_Eta" ,"" , kGCnXBinsEta, kGCfirstXBinEta, kGClastXBinEta, "", "");}
    if(kGCplotMCConvDirectGammaPhi == kTRUE){ histograms->AddHistogram("MC_ConvDirectGamma_Phi" ,"" , kGCnXBinsPhi, kGCfirstXBinPhi, kGClastXBinPhi, "", "");}
    if(kGCplotMCConvDirectGammaRapid == kTRUE){ histograms->AddHistogram("MC_ConvDirectGamma_Rapid" ,"" , kGCnXBinsRapid, kGCfirstXBinRapid, kGClastXBinRapid, "", "");}
                
    if(kGCplotMCMotherEta == kTRUE){ histograms->AddHistogram("MC_Mother_Eta" ,"" , kGCnXBinsEta, kGCfirstXBinEta, kGClastXBinEta, "", "");}
    if(kGCplotMCMotherPhi == kTRUE){ histograms->AddHistogram("MC_Mother_Phi" ,"" , kGCnXBinsPhi, kGCfirstXBinPhi, kGClastXBinPhi, "", "");}
    if(kGCplotMCMotherRapid == kTRUE){ histograms->AddHistogram("MC_Mother_Rapid" ,"" , kGCnXBinsRapid, kGCfirstXBinRapid, kGClastXBinRapid, "", "");}
    if(kGCplotMCMotherPt == kTRUE){ histograms->AddHistogram("MC_Mother_Pt" ,"" , kGCnXBinsPt, kGCfirstXBinPt, kGClastXBinPt, "", "");}
    if(kGCplotMCMotherEnergy == kTRUE){ histograms->AddHistogram("MC_Mother_Energy" ,"" , kGCnXBinsEnergy, kGCfirstXBinEnergy, kGClastXBinEnergy, "", "");}
    if(kGCplotMCMotherMass == kTRUE){ histograms->AddHistogram("MC_Mother_Mass" ,"" , kGCnXBinsGammaMass, kGCfirstXBinGammaMass, kGClastXBinGammaMass, "", "");}
    if(kGCplotMCMotherOpeningAngle == kTRUE){ histograms->AddHistogram("MC_Mother_GammaDaughter_OpeningAngle" ,"" , kGCnXBinsOpeningAngle, kGCfirstXBinOpeningAngle, kGClastXBinOpeningAngle, "", "");}
    if(kGCplotMCMotherR == kTRUE){ histograms->AddHistogram("MC_Mother_R" ,"" , kGCnXBinsR, kGCfirstXBinR, kGClastXBinR, "", "");}
    if(kGCplotMCMotherZR == kTRUE){ histograms->AddHistogram("MC_Mother_ZR" ,"" , kGCnXBinsZR, kGCfirstXBinZR, kGClastXBinZR, kGCnYBinsZR, kGCfirstYBinZR, kGClastYBinZR, "", "");}
    if(kGCplotMCMotherXY == kTRUE){ histograms->AddHistogram("MC_Mother_XY" ,"" , kGCnXBinsXY, kGCfirstXBinXY, kGClastXBinXY, kGCnYBinsXY, kGCfirstYBinXY, kGClastYBinXY, "", "");}
    if(kGCplotMCMotherPtvsEtaWithinAcceptance == kTRUE){ histograms->AddHistogram("MC_Mother_Pt_Eta_withinAcceptance" ,"" , kGCnXBinsPt, kGCfirstXBinPt, kGClastXBinPt, kGCnXBinsEta, kGCfirstXBinEta, kGClastXBinEta, "", "");}
    if(kGCplotMCMotherPtvsRapidWithinAcceptance == kTRUE){ histograms->AddHistogram("MC_Mother_Pt_Rapid_withinAcceptance" ,"" , kGCnXBinsPt, kGCfirstXBinPt, kGClastXBinPt, kGCnXBinsRapid, kGCfirstXBinRapid, kGClastXBinRapid, "", "");}
    if(kGCplotMCMotherPtvsEtaConvGammaWithinAcceptance == kTRUE){ histograms->AddHistogram("MC_Mother_Pt_Eta_ConvGamma_withinAcceptance" ,"" , kGCnXBinsPt, kGCfirstXBinPt, kGClastXBinPt, kGCnXBinsEta, kGCfirstXBinEta, kGClastXBinEta, "", "");}
    if(kGCplotMCMotherPtvsRapidConvGammaWithinAcceptance == kTRUE){ histograms->AddHistogram("MC_Mother_Pt_Rapid_ConvGamma_withinAcceptance" ,"" , kGCnXBinsPt, kGCfirstXBinPt, kGClastXBinPt, kGCnXBinsRapid, kGCfirstXBinRapid, kGClastXBinRapid, "", "");}
                
    if(kGCplotMCMotherSpectra == kTRUE){ 
      histograms->AddHistogram("MC_Mother_InvMass_vs_Pt" ,"" ,kGCnXBinsSpectra, kGCfirstXBinSpectra, kGClastXBinSpectra, kGCnYBinsSpectra, kGCfirstYBinSpectra, kGClastYBinSpectra, "", "");
      histograms->AddHistogram("MC_Mother_InvMass_vs_Pt_withinAcceptance" ,"" ,kGCnXBinsSpectra, kGCfirstXBinSpectra, kGClastXBinSpectra, kGCnYBinsSpectra, kGCfirstYBinSpectra, kGClastYBinSpectra, "", "");
      histograms->AddHistogram("MC_Mother_InvMass_vs_Pt_ConvGamma_withinAcceptance" ,"" ,kGCnXBinsSpectra, kGCfirstXBinSpectra, kGClastXBinSpectra, kGCnYBinsSpectra, kGCfirstYBinSpectra, kGClastYBinSpectra, "", "");
    }
                
                
    if(kGCplotMCPi0Eta == kTRUE){ histograms->AddHistogram("MC_Pi0_Eta" ,"" , kGCnXBinsEta, kGCfirstXBinEta, kGClastXBinEta, "", "");}  
    if(kGCplotMCPi0Rapid == kTRUE){ histograms->AddHistogram("MC_Pi0_Rapid" ,"" , kGCnXBinsRapid, kGCfirstXBinRapid, kGClastXBinRapid, "", "");}        
    if(kGCplotMCPi0Phi == kTRUE){ histograms->AddHistogram("MC_Pi0_Phi" ,"" , kGCnXBinsPhi, kGCfirstXBinPhi, kGClastXBinPhi, "", "");}
    if(kGCplotMCPi0Pt == kTRUE){ histograms->AddHistogram("MC_Pi0_Pt" ,"" , kGCnXBinsPt, kGCfirstXBinPt, kGClastXBinPt, "", "");}
    if(kGCplotMCPi0Energy == kTRUE){ histograms->AddHistogram("MC_Pi0_Energy" ,"" , kGCnXBinsEnergy, kGCfirstXBinEnergy, kGClastXBinEnergy, "", "");}
    if(kGCplotMCPi0Mass == kTRUE){ histograms->AddHistogram("MC_Pi0_Mass" ,"" , kGCnXBinsPi0Mass, kGCfirstXBinPi0Mass, kGClastXBinPi0Mass, "", "");}
    if(kGCplotMCPi0OpeningAngle == kTRUE){ histograms->AddHistogram("MC_Pi0_GammaDaughter_OpeningAngle" ,"" , kGCnXBinsOpeningAngle, kGCfirstXBinOpeningAngle, kGClastXBinOpeningAngle, "", "");}
    if(kGCplotMCPi0R == kTRUE){ histograms->AddHistogram("MC_Pi0_R" ,"" , kGCnXBinsR, kGCfirstXBinR, kGClastXBinR, "", "");}
    if(kGCplotMCPi0ZR == kTRUE){ histograms->AddHistogram("MC_Pi0_ZR" ,"" , kGCnXBinsZR, kGCfirstXBinZR, kGClastXBinZR, kGCnYBinsZR, kGCfirstYBinZR, kGClastYBinZR, "", "");}
    if(kGCplotMCPi0XY == kTRUE){ histograms->AddHistogram("MC_Pi0_XY" ,"" , kGCnXBinsXY, kGCfirstXBinXY, kGClastXBinXY, kGCnYBinsXY, kGCfirstYBinXY, kGClastYBinXY, "", "");}
    if(kGCplotMCPi0PtvsEtaWithinAcceptance == kTRUE){ histograms->AddHistogram("MC_Pi0_Pt_Eta_withinAcceptance" ,"" , kGCnXBinsPt, kGCfirstXBinPt, kGClastXBinPt, kGCnXBinsEta, kGCfirstXBinEta, kGClastXBinEta, "", "");}
    if(kGCplotMCPi0PtvsRapidWithinAcceptance == kTRUE){ histograms->AddHistogram("MC_Pi0_Pt_Rapid_withinAcceptance" ,"" , kGCnXBinsPt, kGCfirstXBinPt, kGClastXBinPt, kGCnXBinsRapid, kGCfirstXBinRapid, kGClastXBinRapid, "", "");}
    if(kGCplotMCPi0PtvsEtaConvGammaWithinAcceptance == kTRUE){ histograms->AddHistogram("MC_Pi0_Pt_Eta_ConvGamma_withinAcceptance" ,"" , kGCnXBinsPt, kGCfirstXBinPt, kGClastXBinPt, kGCnXBinsEta, kGCfirstXBinEta, kGClastXBinEta, "", "");}
    if(kGCplotMCPi0PtvsRapidConvGammaWithinAcceptance == kTRUE){ histograms->AddHistogram("MC_Pi0_Pt_Rapid_ConvGamma_withinAcceptance" ,"" , kGCnXBinsPt, kGCfirstXBinPt, kGClastXBinPt, kGCnXBinsRapid, kGCfirstXBinRapid, kGClastXBinRapid, "", "");}
    if(kGCplotMCPi0ZRConvGammaWithinAcceptance == kTRUE){ histograms->AddHistogram("MC_Pi0_ZR_ConvGamma_withinAcceptance" ,"" , kGCnXBinsZR, kGCfirstXBinZR, kGClastXBinZR, kGCnYBinsZR, kGCfirstYBinZR, kGClastYBinZR, "", "");}
                
                
    if(kGCplotMCPi0SecondaryEta == kTRUE){ histograms->AddHistogram("MC_Pi0_Secondaries_Eta" ,"" , kGCnXBinsEta, kGCfirstXBinEta, kGClastXBinEta, "", "");}
    if(kGCplotMCPi0SecondaryRapid == kTRUE){ histograms->AddHistogram("MC_Pi0_Secondaries_Rapid" ,"" , kGCnXBinsRapid, kGCfirstXBinRapid, kGClastXBinRapid, "", "");}
    if(kGCplotMCPi0SecondaryPhi == kTRUE){ histograms->AddHistogram("MC_Pi0_Secondaries_Phi" ,"" , kGCnXBinsPhi, kGCfirstXBinPhi, kGClastXBinPhi, "", "");}
    if(kGCplotMCPi0SecondaryPt == kTRUE){ histograms->AddHistogram("MC_Pi0_Secondaries_Pt" ,"" , kGCnXBinsPt, kGCfirstXBinPt, kGClastXBinPt, "", "");}
    if(kGCplotMCPi0SecondaryEnergy == kTRUE){ histograms->AddHistogram("MC_Pi0_Secondaries_Energy" ,"" , kGCnXBinsEnergy, kGCfirstXBinEnergy, kGClastXBinEnergy, "", "");}
    if(kGCplotMCPi0SecondaryMass == kTRUE){ histograms->AddHistogram("MC_Pi0_Secondaries_Mass" ,"" , kGCnXBinsPi0Mass, kGCfirstXBinPi0Mass, kGClastXBinPi0Mass, "", "");}
    if(kGCplotMCPi0SecondaryOpeningAngle == kTRUE){ histograms->AddHistogram("MC_Pi0_Secondaries_GammaDaughter_OpeningAngle" ,"" , kGCnXBinsOpeningAngle, kGCfirstXBinOpeningAngle, kGClastXBinOpeningAngle, "", "");}
    if(kGCplotMCPi0SecondaryR == kTRUE){ histograms->AddHistogram("MC_Pi0_Secondaries_R" ,"" , kGCnXBinsR, kGCfirstXBinR, kGClastXBinR, "", "");}
    if(kGCplotMCPi0SecondaryZR == kTRUE){ histograms->AddHistogram("MC_Pi0_Secondaries_ZR" ,"" , kGCnXBinsZR, kGCfirstXBinZR, kGClastXBinZR, kGCnYBinsZR, kGCfirstYBinZR, kGClastYBinZR, "", "");}
    if(kGCplotMCPi0SecondaryXY == kTRUE){ histograms->AddHistogram("MC_Pi0_Secondaries_XY" ,"" , kGCnXBinsXY, kGCfirstXBinXY, kGClastXBinXY, kGCnYBinsXY, kGCfirstYBinXY, kGClastYBinXY, "", "");}
    if(kGCplotMCPi0SecondaryPtvsEtaWithinAcceptance == kTRUE){ histograms->AddHistogram("MC_Pi0_Secondaries_Pt_Eta_withinAcceptance" ,"" , kGCnXBinsPt, kGCfirstXBinPt, kGClastXBinPt, kGCnXBinsEta, kGCfirstXBinEta, kGClastXBinEta, "", "");}
    if(kGCplotMCPi0SecondaryPtvsRapidWithinAcceptance == kTRUE){ histograms->AddHistogram("MC_Pi0_Secondaries_Pt_Rapid_withinAcceptance" ,"" , kGCnXBinsPt, kGCfirstXBinPt, kGClastXBinPt, kGCnXBinsRapid, kGCfirstXBinRapid, kGClastXBinRapid, "", "");}
    if(kGCplotMCPi0SecondaryPtvsEtaConvGammaWithinAcceptance == kTRUE){ histograms->AddHistogram("MC_Pi0_Secondaries_Pt_Eta_ConvGamma_withinAcceptance" ,"" , kGCnXBinsPt, kGCfirstXBinPt, kGClastXBinPt, kGCnXBinsEta, kGCfirstXBinEta, kGClastXBinEta, "", "");}
    if(kGCplotMCPi0SecondaryPtvsRapidConvGammaWithinAcceptance == kTRUE){ histograms->AddHistogram("MC_Pi0_Secondaries_Pt_Rapid_ConvGamma_withinAcceptance" ,"" , kGCnXBinsPt, kGCfirstXBinPt, kGClastXBinPt, kGCnXBinsRapid, kGCfirstXBinRapid, kGClastXBinRapid, "", "");}
                
                
                
    if(kGCplotMCEtaEta == kTRUE){ histograms->AddHistogram("MC_Eta_Eta" ,"" , kGCnXBinsEta, kGCfirstXBinEta, kGClastXBinEta, "", "");}
    if(kGCplotMCEtaRapid == kTRUE){ histograms->AddHistogram("MC_Eta_Rapid" ,"" , kGCnXBinsRapid, kGCfirstXBinRapid, kGClastXBinRapid, "", "");}
    if(kGCplotMCEtaPhi == kTRUE){ histograms->AddHistogram("MC_Eta_Phi" ,"" , kGCnXBinsPhi, kGCfirstXBinPhi, kGClastXBinPhi, "", "");}
    if(kGCplotMCEtaPt == kTRUE){ histograms->AddHistogram("MC_Eta_Pt" ,"" , kGCnXBinsPt, kGCfirstXBinPt, kGClastXBinPt, "", "");}
    if(kGCplotMCEtaEnergy == kTRUE){ histograms->AddHistogram("MC_Eta_Energy" ,"" , kGCnXBinsEnergy, kGCfirstXBinEnergy, kGClastXBinEnergy, "", "");}
    if(kGCplotMCEtaMass == kTRUE){ histograms->AddHistogram("MC_Eta_Mass" ,"" , kGCnXBinsEtaMass, kGCfirstXBinEtaMass, kGClastXBinEtaMass, "", "");}
    if(kGCplotMCEtaOpeningAngleGamma == kTRUE){ histograms->AddHistogram("MC_Eta_GammaDaughter_OpeningAngle" ,"" , kGCnXBinsOpeningAngle, kGCfirstXBinOpeningAngle, kGClastXBinOpeningAngle, "", "");}
    if(kGCplotMCEtaR == kTRUE){ histograms->AddHistogram("MC_Eta_R" ,"" , kGCnXBinsR, kGCfirstXBinR, kGClastXBinR, "", "");}
    if(kGCplotMCEtaZR == kTRUE){ histograms->AddHistogram("MC_Eta_ZR" ,"" , kGCnXBinsZR, kGCfirstXBinZR, kGClastXBinZR, kGCnYBinsZR, kGCfirstYBinZR, kGClastYBinZR, "", "");}
    if(kGCplotMCEtaXY == kTRUE){ histograms->AddHistogram("MC_Eta_XY" ,"" , kGCnXBinsXY, kGCfirstXBinXY, kGClastXBinXY, kGCnYBinsXY, kGCfirstYBinXY, kGClastYBinXY, "", "");}
    if(kGCplotMCEtaPtvsEtaWithinAcceptance == kTRUE){ histograms->AddHistogram("MC_Eta_Pt_Eta_withinAcceptance" ,"" , kGCnXBinsPt, kGCfirstXBinPt, kGClastXBinPt, kGCnXBinsEta, kGCfirstXBinEta, kGClastXBinEta, "", "");}
    if(kGCplotMCEtaPtvsRapidWithinAcceptance == kTRUE){ histograms->AddHistogram("MC_Eta_Pt_Rapid_withinAcceptance" ,"" , kGCnXBinsPt, kGCfirstXBinPt, kGClastXBinPt, kGCnXBinsRapid, kGCfirstXBinRapid, kGClastXBinRapid, "", "");}
    if(kGCplotMCEtaPtvsEtaConvGammaWithinAcceptance == kTRUE){ histograms->AddHistogram("MC_Eta_Pt_Eta_ConvGamma_withinAcceptance" ,"" , kGCnXBinsPt, kGCfirstXBinPt, kGClastXBinPt, kGCnXBinsEta, kGCfirstXBinEta, kGClastXBinEta, "", "");}
    if(kGCplotMCEtaPtvsRapidConvGammaWithinAcceptance == kTRUE){ histograms->AddHistogram("MC_Eta_Pt_Rapid_ConvGamma_withinAcceptance" ,"" , kGCnXBinsPt, kGCfirstXBinPt, kGClastXBinPt, kGCnXBinsRapid, kGCfirstXBinRapid, kGClastXBinRapid, "", "");}
    if(kGCplotMCEtaZRConvGammaWithinAcceptance == kTRUE){ histograms->AddHistogram("MC_Eta_ZR_ConvGamma_withinAcceptance" ,"" , kGCnXBinsZR, kGCfirstXBinZR, kGClastXBinZR, kGCnYBinsZR, kGCfirstYBinZR, kGClastYBinZR, "", "");}
                
                
    // Histograms from esd tracks       
    if(kGCplotESDEEnergy == kTRUE){ histograms->AddHistogram("ESD_E_Energy" ,"" , kGCnXBinsEnergy, kGCfirstXBinEnergy, kGClastXBinEnergy, "", "");}
    if(kGCplotESDEPt == kTRUE){ histograms->AddHistogram("ESD_E_Pt" ,"" , kGCnXBinsPt, kGCfirstXBinPt, kGClastXBinPt, "", "");}
    if(kGCplotESDEEta == kTRUE){ histograms->AddHistogram("ESD_E_Eta" ,"" , kGCnXBinsEta, kGCfirstXBinEta, kGClastXBinEta, "", "");}
    if(kGCplotESDEPhi == kTRUE){ histograms->AddHistogram("ESD_E_Phi" ,"" , kGCnXBinsPhi, kGCfirstXBinPhi, kGClastXBinPhi, "", "");}
                
    if(kGCplotESDPEnergy == kTRUE){ histograms->AddHistogram("ESD_P_Energy" ,"" , kGCnXBinsEnergy, kGCfirstXBinEnergy, kGClastXBinEnergy, "", "");}
    if(kGCplotESDPPt == kTRUE){ histograms->AddHistogram("ESD_P_Pt" ,"" , kGCnXBinsPt, kGCfirstXBinPt, kGClastXBinPt, "", "");}
    if(kGCplotESDPEta == kTRUE){ histograms->AddHistogram("ESD_P_Eta" ,"" , kGCnXBinsEta, kGCfirstXBinEta, kGClastXBinEta, "", "");}
    if(kGCplotESDPPhi == kTRUE){ histograms->AddHistogram("ESD_P_Phi" ,"" , kGCnXBinsPhi, kGCfirstXBinPhi, kGClastXBinPhi, "", "");}
                
    if(kGCplotESDConvGammaEnergy == kTRUE){ histograms->AddHistogram("ESD_ConvGamma_Energy" ,"" , kGCnXBinsEnergy, kGCfirstXBinEnergy, kGClastXBinEnergy, "", "");}
    if(kGCplotESDConvGammaPt == kTRUE){ histograms->AddHistogram("ESD_ConvGamma_Pt" ,"" , kGCnXBinsPt, kGCfirstXBinPt, kGClastXBinPt, "", "");}
    if(kGCplotESDConvGammaEta == kTRUE){ histograms->AddHistogram("ESD_ConvGamma_Eta" ,"" , kGCnXBinsEta, kGCfirstXBinEta, kGClastXBinEta, "", "");}
    if(kGCplotESDConvGammaPhi == kTRUE){ histograms->AddHistogram("ESD_ConvGamma_Phi" ,"" , kGCnXBinsPhi, kGCfirstXBinPhi, kGClastXBinPhi, "", "");}
    if(kGCplotESDConvGammaMass == kTRUE){ histograms->AddHistogram("ESD_ConvGamma_Mass" ,"" ,  kGCnXBinsGammaMass, kGCfirstXBinGammaMass, kGClastXBinGammaMass, "", "");}
    if(kGCplotESDConvGammaWidth == kTRUE){ histograms->AddHistogram("ESD_ConvGamma_Width" ,"" , kGCnXBinsGammaWidth, kGCfirstXBinGammaWidth, kGClastXBinGammaWidth, "", "");}
    if(kGCplotESDConvGammaChi2 == kTRUE){ histograms->AddHistogram("ESD_ConvGamma_Chi2" ,"" , kGCnXBinsGammaChi2, kGCfirstXBinGammaChi2, kGClastXBinGammaChi2, "", "");}
    if(kGCplotESDConvGammaNDF == kTRUE){ histograms->AddHistogram("ESD_ConvGamma_NDF" ,"" , kGCnXBinsGammaNDF, kGCfirstXBinGammaNDF, kGClastXBinGammaNDF, "", "");}
    if(kGCplotESDConvGammaRapid == kTRUE){ histograms->AddHistogram("ESD_ConvGamma_Rapid" ,"" , kGCnXBinsRapid, kGCfirstXBinRapid, kGClastXBinRapid, "", "");}
    if(kGCplotESDConvGammaPtvsEta == kTRUE){ histograms->AddHistogram("ESD_ConvGamma_Pt_Eta","", kGCnXBinsPt, kGCfirstXBinPt, kGClastXBinPt,kGCnXBinsEta, kGCfirstXBinEta, kGClastXBinEta,"","" );}
    if(kGCplotESDConvGammaPtvsChi2 == kTRUE){ histograms->AddHistogram("ESD_ConvGamma_Pt_Chi2" ,"" ,kGCnXBinsPt, kGCfirstXBinPt, kGClastXBinPt, kGCnXBinsGammaChi2, kGCfirstXBinGammaChi2, kGClastXBinGammaChi2, "", "");}
    if(kGCplotESDConvGammaEtavsChi2 == kTRUE){ histograms->AddHistogram("ESD_ConvGamma_Eta_Chi2" ,"" ,kGCnXBinsEta, kGCfirstXBinEta, kGClastXBinEta, kGCnXBinsGammaChi2, kGCfirstXBinGammaChi2, kGClastXBinGammaChi2, "", "");}
                
                
                
    if(kGCplotESDConversionR == kTRUE){ histograms->AddHistogram("ESD_Conversion_R" ,"" , kGCnXBinsR, kGCfirstXBinR, kGClastXBinR, "", "");}
    if(kGCplotESDConversionZR == kTRUE){ histograms->AddHistogram("ESD_Conversion_ZR" ,"" , kGCnXBinsZR, kGCfirstXBinZR, kGClastXBinZR, kGCnYBinsZR, kGCfirstYBinZR, kGClastYBinZR, "", "");}
    if(kGCplotESDConversionXY == kTRUE){ histograms->AddHistogram("ESD_Conversion_XY" ,"" , kGCnXBinsXY, kGCfirstXBinXY, kGClastXBinXY, kGCnYBinsXY, kGCfirstYBinXY, kGClastYBinXY, "", "");}
    if(kGCplotESDConversionOpeningAngle == kTRUE){ histograms->AddHistogram("ESD_Conversion_OpeningAngle" ,"" , kGCnXBinsOpeningAngle, kGCfirstXBinOpeningAngle, kGClastXBinOpeningAngle, "", "");}

    if(kGCplotESDConvGammaCosPointingAngle == kTRUE){ histograms->AddHistogram("ESD_ConvGamma_CosPointingAngle" ,"" , kGCnXBinsCosPointingAngle, kGCfirstXBinCosPointingAngle, kGClastXBinCosPointingAngle, "", "");}
    if(kGCplotESDConvGammaDcaDaugthers == kTRUE){ histograms->AddHistogram("ESD_ConvGamma_DcaDaughters" ,"" , kGCnXBinsDcaDaughters, kGCfirstXBinDcaDaughters, kGClastXBinDcaDaughters, "", "");}
    if(kGCplotESDConvGammaNormDcaDistDaugthers == kTRUE){ histograms->AddHistogram("ESD_ConvGamma_NormDcaDistDaughters" ,"" , kGCnXBinsNormDcaDistDaughters, kGCfirstXBinNormDcaDistDaughters, kGClastXBinNormDcaDistDaughters, "", "");}
    if(kGCplotESDConvGammaLikelihoodAP == kTRUE){ histograms->AddHistogram("ESD_ConvGamma_LikelihoodAP" ,"" , kGCnXBinsLikelihoodAP, kGCfirstXBinLikelihoodAP, kGClastXBinLikelihoodAP, "", "");}
    if(kGCplotESDConvGammaEAsymmetryP== kTRUE){ histograms->AddHistogram("ESD_ConvGamma_E_AsymmetryP" ,"" ,kGCnXBinsP, kGCfirstXBinP, kGClastXBinP,kGCnYBinsAsymmetry, kGCfirstYBinAsymmetry, kGClastYBinAsymmetry,"", "");}
    if(kGCplotESDConvGammaPAsymmetryP== kTRUE){ histograms->AddHistogram("ESD_ConvGamma_P_AsymmetryP" ,"" ,kGCnXBinsP, kGCfirstXBinP, kGClastXBinP,kGCnYBinsAsymmetry, kGCfirstYBinAsymmetry, kGClastYBinAsymmetry,"", "");}
    if(kGCplotESDConvGammaEdEdxP== kTRUE){ histograms->AddHistogram("ESD_ConvGamma_E_dEdxP" ,"" ,kGCnXBinsP, kGCfirstXBinP, kGClastXBinP,kGCnYBinsdEdx, kGCfirstYBindEdx, kGClastYBindEdx,"", "");}
    if(kGCplotESDConvGammaPdEdxP== kTRUE){ histograms->AddHistogram("ESD_ConvGamma_P_dEdxP" ,"" ,kGCnXBinsP, kGCfirstXBinP, kGClastXBinP,kGCnYBinsdEdx, kGCfirstYBindEdx, kGClastYBindEdx,"", "");}


                
                
    if(kGCplotESDTrueConvGammaEnergy == kTRUE){ histograms->AddHistogram("ESD_TrueConvGamma_Energy" ,"" , kGCnXBinsEnergy, kGCfirstXBinEnergy, kGClastXBinEnergy, "", "");}
    if(kGCplotESDTrueConvGammaPt == kTRUE){ histograms->AddHistogram("ESD_TrueConvGamma_Pt" ,"" , kGCnXBinsPt, kGCfirstXBinPt, kGClastXBinPt, "", "");}
    if(kGCplotESDTrueConvGammaEta == kTRUE){ histograms->AddHistogram("ESD_TrueConvGamma_Eta" ,"" , kGCnXBinsEta, kGCfirstXBinEta, kGClastXBinEta, "", "");}
    if(kGCplotESDTrueConvGammaPhi == kTRUE){ histograms->AddHistogram("ESD_TrueConvGamma_Phi" ,"" , kGCnXBinsPhi, kGCfirstXBinPhi, kGClastXBinPhi, "", "");}
    if(kGCplotESDTrueConvGammaMass == kTRUE){ histograms->AddHistogram("ESD_TrueConvGamma_Mass" ,"" ,  kGCnXBinsGammaMass, kGCfirstXBinGammaMass, kGClastXBinGammaMass, "", "");}
    if(kGCplotESDTrueConvGammaWidth == kTRUE){ histograms->AddHistogram("ESD_TrueConvGamma_Width" ,"" , kGCnXBinsGammaWidth, kGCfirstXBinGammaWidth, kGClastXBinGammaWidth, "", "");}
    if(kGCplotESDTrueConvGammaChi2 == kTRUE){ histograms->AddHistogram("ESD_TrueConvGamma_Chi2" ,"" , kGCnXBinsGammaChi2, kGCfirstXBinGammaChi2, kGClastXBinGammaChi2, "", "");}
    if(kGCplotESDTrueConvGammaNDF == kTRUE){ histograms->AddHistogram("ESD_TrueConvGamma_NDF" ,"" , kGCnXBinsGammaNDF, kGCfirstXBinGammaNDF, kGClastXBinGammaNDF, "", "");}
    if(kGCplotESDTrueConvGammaRapid == kTRUE){ histograms->AddHistogram("ESD_TrueConvGamma_Rapid" ,"" , kGCnXBinsRapid, kGCfirstXBinRapid, kGClastXBinRapid, "", "");}
    if(kGCplotESDTrueConvGammaPtvsEta == kTRUE){ histograms->AddHistogram("ESD_TrueConvGamma_Pt_Eta" ,"" , kGCnXBinsPt, kGCfirstXBinPt, kGClastXBinPt,kGCnXBinsEta, kGCfirstXBinEta, kGClastXBinEta, "", "");}
    if(kGCplotESDTrueConvGammaPtvsChi2 == kTRUE){ histograms->AddHistogram("ESD_TrueConvGamma_Pt_Chi2" ,"" ,kGCnXBinsPt, kGCfirstXBinPt, kGClastXBinPt, kGCnXBinsGammaChi2, kGCfirstXBinGammaChi2, kGClastXBinGammaChi2, "", "");}
    if(kGCplotESDTrueConvGammaEtavsChi2 == kTRUE){ histograms->AddHistogram("ESD_TrueConvGamma_Eta_Chi2" ,"" ,kGCnXBinsEta, kGCfirstXBinEta, kGClastXBinEta, kGCnXBinsGammaChi2, kGCfirstXBinGammaChi2, kGClastXBinGammaChi2, "", "");}
                
    if(kGCplotESDTrueConversionR == kTRUE){ histograms->AddHistogram("ESD_TrueConversion_R" ,"" , kGCnXBinsR, kGCfirstXBinR, kGClastXBinR, "", "");}
    if(kGCplotESDTrueConversionZR == kTRUE){ histograms->AddHistogram("ESD_TrueConversion_ZR" ,"" , kGCnXBinsZR, kGCfirstXBinZR, kGClastXBinZR, kGCnYBinsZR, kGCfirstYBinZR, kGClastYBinZR, "", "");}
    if(kGCplotESDTrueConversionXY == kTRUE){ histograms->AddHistogram("ESD_TrueConversion_XY" ,"" , kGCnXBinsXY, kGCfirstXBinXY, kGClastXBinXY, kGCnYBinsXY, kGCfirstYBinXY, kGClastYBinXY, "", "");}
    if(kGCplotESDTrueConversionOpeningAngle == kTRUE){ histograms->AddHistogram("ESD_TrueConversion_OpeningAngle" ,"" , kGCnXBinsOpeningAngle, kGCfirstXBinOpeningAngle, kGClastXBinOpeningAngle, "", "");}

    if(kGCplotESDTrueConvGammaCosPointingAngle == kTRUE){ histograms->AddHistogram("ESD_TrueConvGamma_CosPointingAngle" ,"" , kGCnXBinsCosPointingAngle, kGCfirstXBinCosPointingAngle, kGClastXBinCosPointingAngle, "", "");}
    if(kGCplotESDTrueConvGammaDcaDaugthers == kTRUE){ histograms->AddHistogram("ESD_TrueConvGamma_DcaDaughters" ,"" , kGCnXBinsDcaDaughters, kGCfirstXBinDcaDaughters, kGClastXBinDcaDaughters, "", "");}
    if(kGCplotESDTrueConvGammaNormDcaDistDaugthers == kTRUE){ histograms->AddHistogram("ESD_TrueConvGamma_NormDcaDistDaughters" ,"" , kGCnXBinsNormDcaDistDaughters, kGCfirstXBinNormDcaDistDaughters, kGClastXBinNormDcaDistDaughters, "", "");}
    if(kGCplotESDTrueConvGammaLikelihoodAP == kTRUE){ histograms->AddHistogram("ESD_TrueConvGamma_LikelihoodAP" ,"" , kGCnXBinsLikelihoodAP, kGCfirstXBinLikelihoodAP, kGClastXBinLikelihoodAP, "", "");}
    if(kGCplotESDTrueConvGammaEAsymmetryP== kTRUE){ histograms->AddHistogram("ESD_TrueConvGamma_E_AsymmetryP" ,"" ,kGCnXBinsP, kGCfirstXBinP, kGClastXBinP,kGCnYBinsAsymmetry, kGCfirstYBinAsymmetry, kGClastYBinAsymmetry,"", "");}
    if(kGCplotESDTrueConvGammaPAsymmetryP== kTRUE){ histograms->AddHistogram("ESD_TrueConvGamma_P_AsymmetryP" ,"" ,kGCnXBinsP, kGCfirstXBinP, kGClastXBinP,kGCnYBinsAsymmetry, kGCfirstYBinAsymmetry, kGClastYBinAsymmetry,"", "");}
    if(kGCplotESDTrueConvGammaEdEdxP== kTRUE){ histograms->AddHistogram("ESD_TrueConvGamma_E_dEdxP" ,"" ,kGCnXBinsP, kGCfirstXBinP, kGClastXBinP,kGCnYBinsdEdx, kGCfirstYBindEdx, kGClastYBindEdx,"", "");}
    if(kGCplotESDTrueConvGammaPdEdxP== kTRUE){ histograms->AddHistogram("ESD_TrueConvGamma_P_dEdxP" ,"" ,kGCnXBinsP, kGCfirstXBinP, kGClastXBinP,kGCnYBinsdEdx, kGCfirstYBindEdx, kGClastYBindEdx,"", "");}

                
    if(kGCplotESDTrueConvGammaMCPtEta == kTRUE){ histograms->AddHistogram("ESD_TrueConvGamma_MC_Pt_Eta" ,"" , kGCnXBinsPt, kGCfirstXBinPt, kGClastXBinPt, kGCnXBinsEta, kGCfirstXBinEta, kGClastXBinEta, "", "");}
    if(kGCplotESDTrueConversionMCZR == kTRUE){ histograms->AddHistogram("ESD_TrueConversion_MC_ZR" ,"" , kGCnXBinsZR, kGCfirstXBinZR, kGClastXBinZR, kGCnYBinsZR, kGCfirstYBinZR, kGClastYBinZR, "", "");}
    if(kGCplotESDTrueConversionMCXY == kTRUE){ histograms->AddHistogram("ESD_TrueConversion_MC_XY" ,"" , kGCnXBinsXY, kGCfirstXBinXY, kGClastXBinXY, kGCnYBinsXY, kGCfirstYBinXY, kGClastYBinXY, "", "");}
                
                
                
    if(kGCplotESDNoCutConvGammaEnergy == kTRUE){ histograms->AddHistogram("ESD_NoCutConvGamma_Energy" ,"" , kGCnXBinsEnergy, kGCfirstXBinEnergy, kGClastXBinEnergy, "", "");}
    if(kGCplotESDNoCutConvGammaPt == kTRUE){ histograms->AddHistogram("ESD_NoCutConvGamma_Pt" ,"" , kGCnXBinsPt, kGCfirstXBinPt, kGClastXBinPt, "", "");}
    if(kGCplotESDNoCutConvGammaEta == kTRUE){ histograms->AddHistogram("ESD_NoCutConvGamma_Eta" ,"" , kGCnXBinsEta, kGCfirstXBinEta, kGClastXBinEta, "", "");}
    if(kGCplotESDNoCutConvGammaPhi == kTRUE){ histograms->AddHistogram("ESD_NoCutConvGamma_Phi" ,"" , kGCnXBinsPhi, kGCfirstXBinPhi, kGClastXBinPhi, "", "");}
    if(kGCplotESDNoCutConvGammaMass == kTRUE){ histograms->AddHistogram("ESD_NoCutConvGamma_Mass" ,"" ,  kGCnXBinsGammaMass, kGCfirstXBinGammaMass, kGClastXBinGammaMass, "", "");}
    if(kGCplotESDNoCutConvGammaWidth == kTRUE){ histograms->AddHistogram("ESD_NoCutConvGamma_Width" ,"" , kGCnXBinsGammaWidth, kGCfirstXBinGammaWidth, kGClastXBinGammaWidth, "", "");}
    if(kGCplotESDNoCutConvGammaChi2 == kTRUE){ histograms->AddHistogram("ESD_NoCutConvGamma_Chi2" ,"" , kGCnXBinsGammaChi2, kGCfirstXBinGammaChi2, kGClastXBinGammaChi2, "", "");}
    if(kGCplotESDNoCutConvGammaNDF == kTRUE){ histograms->AddHistogram("ESD_NoCutConvGamma_NDF" ,"" , kGCnXBinsGammaNDF, kGCfirstXBinGammaNDF, kGClastXBinGammaNDF, "", "");}
    if(kGCplotESDNoCutConvGammaRapid == kTRUE){ histograms->AddHistogram("ESD_NoCutConvGamma_Rapid" ,"" , kGCnXBinsRapid, kGCfirstXBinRapid, kGClastXBinRapid, "", "");}
    if(kGCplotESDNoCutConvGammaPtvsEta == kTRUE){ histograms->AddHistogram("ESD_NoCutConvGamma_Pt_Eta" ,"" , kGCnXBinsPt, kGCfirstXBinPt, kGClastXBinPt,kGCnXBinsEta, kGCfirstXBinEta, kGClastXBinEta, "", "");}
    if(kGCplotESDNoCutConvGammaPtvsChi2 == kTRUE){ histograms->AddHistogram("ESD_NoCutConvGamma_Pt_Chi2" ,"" ,kGCnXBinsPt, kGCfirstXBinPt, kGClastXBinPt, kGCnXBinsGammaChi2, kGCfirstXBinGammaChi2, kGClastXBinGammaChi2, "", "");}
    if(kGCplotESDNoCutConvGammaEtavsChi2 == kTRUE){ histograms->AddHistogram("ESD_NoCutConvGamma_Eta_Chi2" ,"" ,kGCnXBinsEta, kGCfirstXBinEta, kGClastXBinEta, kGCnXBinsGammaChi2, kGCfirstXBinGammaChi2, kGClastXBinGammaChi2, "", "");}
                
    if(kGCplotESDNoCutConversionR == kTRUE){ histograms->AddHistogram("ESD_NoCutConversion_R" ,"" , kGCnXBinsR, kGCfirstXBinR, kGClastXBinR, "", "");}
    if(kGCplotESDNoCutConversionZR == kTRUE){ histograms->AddHistogram("ESD_NoCutConversion_ZR" ,"" , kGCnXBinsZR, kGCfirstXBinZR, kGClastXBinZR, kGCnYBinsZR, kGCfirstYBinZR, kGClastYBinZR, "", "");}
    if(kGCplotESDNoCutConversionXY == kTRUE){ histograms->AddHistogram("ESD_NoCutConversion_XY" ,"" , kGCnXBinsXY, kGCfirstXBinXY, kGClastXBinXY, kGCnYBinsXY, kGCfirstYBinXY, kGClastYBinXY, "", "");}
    if(kGCplotESDNoCutConversionOpeningAngle == kTRUE){ histograms->AddHistogram("ESD_NoCutConversion_OpeningAngle" ,"" , kGCnXBinsOpeningAngle, kGCfirstXBinOpeningAngle, kGClastXBinOpeningAngle, "", "");}

    if(kGCplotESDNoCutConvGammaCosPointingAngle == kTRUE){ histograms->AddHistogram("ESD_NoCutConvGamma_CosPointingAngle" ,"" , kGCnXBinsCosPointingAngle, kGCfirstXBinCosPointingAngle, kGClastXBinCosPointingAngle, "", "");}
    if(kGCplotESDNoCutConvGammaDcaDaugthers == kTRUE){ histograms->AddHistogram("ESD_NoCutConvGamma_DcaDaughters" ,"" , kGCnXBinsDcaDaughters, kGCfirstXBinDcaDaughters, kGClastXBinDcaDaughters, "", "");}
    if(kGCplotESDNoCutConvGammaNormDcaDistDaugthers == kTRUE){ histograms->AddHistogram("ESD_NoCutConvGamma_NormDcaDistDaughters" ,"" , kGCnXBinsNormDcaDistDaughters, kGCfirstXBinNormDcaDistDaughters, kGClastXBinNormDcaDistDaughters, "", "");}
    if(kGCplotESDNoCutConvGammaLikelihoodAP == kTRUE){ histograms->AddHistogram("ESD_NoCutConvGamma_LikelihoodAP" ,"" , kGCnXBinsLikelihoodAP, kGCfirstXBinLikelihoodAP, kGClastXBinLikelihoodAP, "", "");}
    if(kGCplotESDNoCutConvGammaEAsymmetryP== kTRUE){ histograms->AddHistogram("ESD_NoCutConvGamma_E_AsymmetryP" ,"" ,kGCnXBinsP, kGCfirstXBinP, kGClastXBinP,kGCnYBinsAsymmetry, kGCfirstYBinAsymmetry, kGClastYBinAsymmetry,"", "");}
    if(kGCplotESDNoCutConvGammaPAsymmetryP== kTRUE){ histograms->AddHistogram("ESD_NoCutConvGamma_P_AsymmetryP" ,"" ,kGCnXBinsP, kGCfirstXBinP, kGClastXBinP,kGCnYBinsAsymmetry, kGCfirstYBinAsymmetry, kGClastYBinAsymmetry,"", "");}


    if(kGCplotESDNoCutConvGammaEdEdxP== kTRUE){ histograms->AddHistogram("ESD_NoCutConvGamma_E_dEdxP" ,"" ,kGCnXBinsP, kGCfirstXBinP, kGClastXBinP,kGCnYBinsdEdx, kGCfirstYBindEdx, kGClastYBindEdx,"", "");}
    if(kGCplotESDNoCutConvGammaPdEdxP== kTRUE){ histograms->AddHistogram("ESD_NoCutConvGamma_P_dEdxP" ,"" ,kGCnXBinsP, kGCfirstXBinP, kGClastXBinP,kGCnYBinsdEdx, kGCfirstYBindEdx, kGClastYBindEdx,"", "");}

    if(kGCplotESDNoCutConvGammaMCPtEta == kTRUE){ histograms->AddHistogram("ESD_NoCutConvGamma_MC_Pt_Eta" ,"" , kGCnXBinsPt, kGCfirstXBinPt, kGClastXBinPt, kGCnXBinsEta, kGCfirstXBinEta, kGClastXBinEta, "", "");}
    if(kGCplotESDNoCutConversionMCZR == kTRUE){ histograms->AddHistogram("ESD_NoCutConversion_MC_ZR" ,"" , kGCnXBinsZR, kGCfirstXBinZR, kGClastXBinZR, kGCnYBinsZR, kGCfirstYBinZR, kGClastYBinZR, "", "");}
    if(kGCplotESDNoCutConversionMCXY == kTRUE){ histograms->AddHistogram("ESD_NoCutConversion_MC_XY" ,"" , kGCnXBinsXY, kGCfirstXBinXY, kGClastXBinXY, kGCnYBinsXY, kGCfirstYBinXY, kGClastYBinXY, "", "");}
                
                
                
    if(kGCplotESDMotherOpeningAngleGamma == kTRUE){ histograms->AddHistogram("ESD_Mother_GammaDaughter_OpeningAngle" ,"" , kGCnXBinsOpeningAngle, kGCfirstXBinOpeningAngle, kGClastXBinOpeningAngle, "", "");}
    if(kGCplotESDMotherEnergy == kTRUE){ histograms->AddHistogram("ESD_Mother_Energy" ,"" , kGCnXBinsEnergy, kGCfirstXBinEnergy, kGClastXBinEnergy, "", "");}
    if(kGCplotESDMotherPt == kTRUE){ histograms->AddHistogram("ESD_Mother_Pt" ,"" , kGCnXBinsPt, kGCfirstXBinPt, kGClastXBinPt, "", "");}
    if(kGCplotESDMotherEta == kTRUE){ histograms->AddHistogram("ESD_Mother_Eta" ,"" , kGCnXBinsEta, kGCfirstXBinEta, kGClastXBinEta, "", "");}
    if(kGCplotESDMotherPhi == kTRUE){ histograms->AddHistogram("ESD_Mother_Phi" ,"" , kGCnXBinsPhi, kGCfirstXBinPhi, kGClastXBinPhi, "", "");}
    if(kGCplotESDMotherMass == kTRUE){ histograms->AddHistogram("ESD_Mother_Mass" ,"" , kGCnXBinsPi0Mass, kGCfirstXBinPi0Mass, kGClastXBinPi0Mass, "", "");}
    if(kGCplotESDMotherR == kTRUE){ histograms->AddHistogram("ESD_Mother_R" ,"" , kGCnXBinsR, kGCfirstXBinR, kGClastXBinR, "", "");}
    if(kGCplotESDMotherZR == kTRUE){ histograms->AddHistogram("ESD_Mother_ZR" ,"" , kGCnXBinsZR, kGCfirstXBinZR, kGClastXBinZR, kGCnYBinsZR, kGCfirstYBinZR, kGClastYBinZR, "", "");}
    if(kGCplotESDMotherXY == kTRUE){ histograms->AddHistogram("ESD_Mother_XY" ,"" , kGCnXBinsXY, kGCfirstXBinXY, kGClastXBinXY, kGCnYBinsXY, kGCfirstYBinXY, kGClastYBinXY, "", "");}
    if(kGCplotESDMotherRapid == kTRUE){ histograms->AddHistogram("ESD_Mother_Rapid" ,"" , kGCnXBinsRapid, kGCfirstXBinRapid, kGClastXBinRapid, "", "");}
                
                
    if(kGCplotESDBackgroundOpeningAngleGamma == kTRUE){ histograms->AddHistogram("ESD_Background_GammaDaughter_OpeningAngle" ,"" , kGCnXBinsOpeningAngle, kGCfirstXBinOpeningAngle, kGClastXBinOpeningAngle, "", "");}
    if(kGCplotESDBackgroundEnergy == kTRUE){ histograms->AddHistogram("ESD_Background_Energy" ,"" , kGCnXBinsEnergy, kGCfirstXBinEnergy, kGClastXBinEnergy, "", "");}
    if(kGCplotESDBackgroundPt == kTRUE){ histograms->AddHistogram("ESD_Background_Pt" ,"" , kGCnXBinsPt, kGCfirstXBinPt, kGClastXBinPt, "", "");}
    if(kGCplotESDBackgroundEta == kTRUE){ histograms->AddHistogram("ESD_Background_Eta" ,"" , kGCnXBinsEta, kGCfirstXBinEta, kGClastXBinEta, "", "");}
    if(kGCplotESDBackgroundPhi == kTRUE){ histograms->AddHistogram("ESD_Background_Phi" ,"" , kGCnXBinsPhi, kGCfirstXBinPhi, kGClastXBinPhi, "", "");}
    if(kGCplotESDBackgroundMass == kTRUE){ histograms->AddHistogram("ESD_Background_Mass" ,"" , kGCnXBinsEtaMass, kGCfirstXBinEtaMass, kGClastXBinEtaMass, "", "");}
    if(kGCplotESDBackgroundR == kTRUE){ histograms->AddHistogram("ESD_Background_R" ,"" , kGCnXBinsR, kGCfirstXBinR, kGClastXBinR, "", "");}
    if(kGCplotESDBackgroundZR == kTRUE){ histograms->AddHistogram("ESD_Background_ZR" ,"" , kGCnXBinsZR, kGCfirstXBinZR, kGClastXBinZR, kGCnYBinsZR, kGCfirstYBinZR, kGClastYBinZR, "", "");}
    if(kGCplotESDBackgroundXY == kTRUE){ histograms->AddHistogram("ESD_Background_XY" ,"" , kGCnXBinsXY, kGCfirstXBinXY, kGClastXBinXY, kGCnYBinsXY, kGCfirstYBinXY, kGClastYBinXY, "", "");}
    if(kGCplotESDBackgroundRapid == kTRUE){ histograms->AddHistogram("ESD_Background_Rapid" ,"" , kGCnXBinsRapid, kGCfirstXBinRapid, kGClastXBinRapid, "", "");}
                
                
    if(kGCplotMapping == kTRUE){
      histograms->InitializeMappingValues(kGCnPhiIndex,kGCnRIndex,kGCnXBinsMapping,kGCminRadius,kGCmaxRadius,kGCnYBinsMapping,kGCminPhi,kGCmaxPhi);
      histograms->AddMappingHistograms(kGCnPhiIndex,kGCnRIndex,kGCnXBinsMapping,kGCfirstXBinMapping,kGClastXBinMapping,kGCnYBinsMapping,kGCfirstYBinMapping,kGClastYBinMapping);
      //      histograms->AddMappingHistograms(kGCnPhiIndex,kGCnRIndex,kGCnXBinsMapping,kGCminRadius,kGCmaxRadius,kGCnYBinsMapping,kGCminPhi,kGCmaxPhi);
    }
                
    if(kGCplotResolutiondPt == kTRUE){histograms->AddHistogram("Resolution_dPt" ,"" , kGCnXBinsResdPt, kGCfirstXBinResdPt, kGClastXBinResdPt, kGCnYBinsResdPt, kGCfirstYBinResdPt, kGClastYBinResdPt, "", "");}
    if(kGCplotResolutiondR == kTRUE){histograms->AddHistogram("Resolution_dR" ,"" , kGCnXBinsResdR, kGCfirstXBinResdR, kGClastXBinResdR, kGCnYBinsResdR, kGCfirstYBinResdR, kGClastYBinResdR, "", "");}
    if(kGCplotResolutiondZ == kTRUE){histograms->AddHistogram("Resolution_dZ" ,"" , kGCnXBinsResdZ, kGCfirstXBinResdZ, kGClastXBinResdZ, kGCnYBinsResdZ, kGCfirstYBinResdZ, kGClastYBinResdZ, "", "");}
                
    if(kGCplotResolutiondRdPt == kTRUE){histograms->AddHistogram("Resolution_dR_dPt" ,"" , kGCnXBinsResdRdPt, kGCfirstXBinResdRdPt, kGClastXBinResdRdPt, kGCnYBinsResdRdPt, kGCfirstYBinResdRdPt, kGClastYBinResdRdPt, "", "");}
                
    if(kGCplotResolutionMCPt == kTRUE){histograms->AddHistogram("Resolution_MC_Pt" ,"" , kGCnXBinsResPt, kGCfirstXBinResPt, kGClastXBinResPt,"","");}
    if(kGCplotResolutionMCR == kTRUE){histograms->AddHistogram("Resolution_MC_R" ,"" , kGCnXBinsResR, kGCfirstXBinResR, kGClastXBinResR,"","");}
    if(kGCplotResolutionMCZ == kTRUE){histograms->AddHistogram("Resolution_MC_Z" ,"" , kGCnXBinsResZ, kGCfirstXBinResZ, kGClastXBinResZ,"","");}
                
    if(kGCplotResolutionESDPt == kTRUE){histograms->AddHistogram("Resolution_ESD_Pt" ,"" , kGCnXBinsResPt, kGCfirstXBinResPt, kGClastXBinResPt,"","");}
    if(kGCplotResolutionESDR == kTRUE){histograms->AddHistogram("Resolution_ESD_R" ,"" , kGCnXBinsResR, kGCfirstXBinResR, kGClastXBinResR,"","");}
    if(kGCplotResolutionESDZ == kTRUE){histograms->AddHistogram("Resolution_ESD_Z" ,"" , kGCnXBinsResZ, kGCfirstXBinResZ, kGClastXBinResZ,"","");}
                
    if(kGCplotESDNumberOfV0s == kTRUE){histograms->AddHistogram("ESD_NumberOfV0s","Number of v0s",100, 0, 100,"","");}
    if(kGCplotESDNumberOfSurvivingV0s == kTRUE){histograms->AddHistogram("ESD_NumberOfSurvivingV0s","Number of surviving v0s",100, 0, 100,"","");}
    if(kGCplotESDNumberOfContributorsVtx == kTRUE){histograms->AddHistogram("ESD_NumberOfContributorsVtx","Number of contributors to vertex",100, 0, 100,"","");}
                
    //  debug histograms
    if(kGCplotESDCutGetOnFly == kTRUE){histograms->AddHistogram("ESD_CutGetOnFly_InvMass" ,"Not GetOnFly" , kGCnXBinsGammaMass, kGCfirstXBinGammaMass, kGClastXBinGammaMass,"","");}
    if(kGCplotESDCutNContributors == kTRUE){histograms->AddHistogram("ESD_CutNContributors_InvMass" ,"NContributors <= 0" , kGCnXBinsGammaMass, kGCfirstXBinGammaMass, kGClastXBinGammaMass,"","");}
    if(kGCplotESDCutLikeSign == kTRUE){histograms->AddHistogram("ESD_CutLikeSign_InvMass" ,"LikeSign" , kGCnXBinsGammaMass, kGCfirstXBinGammaMass, kGClastXBinGammaMass,"","");}
    if(kGCplotESDCutRefit == kTRUE){histograms->AddHistogram("ESD_CutRefit_InvMass" ,"No TPC refit" , kGCnXBinsGammaMass, kGCfirstXBinGammaMass, kGClastXBinGammaMass,"","");}
    if(kGCplotESDCutKink == kTRUE){histograms->AddHistogram("ESD_CutKink_InvMass" ,"Kinks" , kGCnXBinsGammaMass, kGCfirstXBinGammaMass, kGClastXBinGammaMass,"","");}
    if(kGCplotESDCutPIDProb == kTRUE){histograms->AddHistogram("ESD_CutPIDProb_InvMass" ,"wrong TPC PID" , kGCnXBinsGammaMass, kGCfirstXBinGammaMass, kGClastXBinGammaMass,"","");}

    if(kGCplotESDCutdedxSigmaElectronLine == kTRUE){histograms->AddHistogram("ESD_CutdEdxSigmaElectronLine_InvMass" ,"dedx ElectronLine" , kGCnXBinsGammaMass, kGCfirstXBinGammaMass, kGClastXBinGammaMass,"","");}
    if(kGCplotESDCutdedxSigmaPionLine == kTRUE){histograms->AddHistogram("ESD_CutdEdxSigmaPionLine_InvMass" ,"dedx PionLine" , kGCnXBinsGammaMass, kGCfirstXBinGammaMass, kGClastXBinGammaMass,"","");}

    if(kGCplotESDCutR == kTRUE){histograms->AddHistogram("ESD_CutR_InvMass" ,"Above RMax" , kGCnXBinsGammaMass, kGCfirstXBinGammaMass, kGClastXBinGammaMass,"","");}
    if(kGCplotESDCutNDF == kTRUE){histograms->AddHistogram("ESD_CutNDF_InvMass" ,"NDF <= 0" , kGCnXBinsGammaMass, kGCfirstXBinGammaMass, kGClastXBinGammaMass,"","");}
    if(kGCplotESDCutChi2 == kTRUE){histograms->AddHistogram("ESD_CutChi2_InvMass" ,"#chi^{2} > Max" , kGCnXBinsGammaMass, kGCfirstXBinGammaMass, kGClastXBinGammaMass,"","");}
    if(kGCplotESDCutEta == kTRUE){histograms->AddHistogram("ESD_CutEta_InvMass" ,"Above #eta max" , kGCnXBinsGammaMass, kGCfirstXBinGammaMass, kGClastXBinGammaMass,"","");}
    if(kGCplotESDCutPt == kTRUE){histograms->AddHistogram("ESD_CutPt_InvMass" ,"Below p_{t} min" , kGCnXBinsGammaMass, kGCfirstXBinGammaMass, kGClastXBinGammaMass,"","");}
    if(kGCplotESDCutLine == kTRUE){histograms->AddHistogram("ESD_CutLine_InvMass" ,"Out of reconstruction area" , kGCnXBinsGammaMass, kGCfirstXBinGammaMass, kGClastXBinGammaMass,"","");}
    if(kGCplotESDGoodV0s == kTRUE){histograms->AddHistogram("ESD_GoodV0s_InvMass" ,"Good V0s" , kGCnXBinsGammaMass, kGCfirstXBinGammaMass, kGClastXBinGammaMass,"","");}

    if(kGCplotESDTrueConvGammaTrackLength == kTRUE){histograms->AddHistogram("ESD_TrueConvGamma_TrackLength","Track length of TrueConvGamma",kGCnXBinsTrackLength,kGCfirstXBinTrackLength,kGClastXBinTrackLength,"","");}
    if(kGCplotESDTrueConvGammaTrackLengthVSInvMass == kTRUE){histograms->AddHistogram("ESD_TrueConvGamma_TrackLengthVSInvMass","Track length of TrueConvGamma vs Inv mass",kGCnXBinsTrackLength,kGCfirstXBinTrackLength,kGClastXBinTrackLength,kGCnXBinsPt, kGCfirstXBinPt, kGClastXBinPt,"","");}
                
                
    if(kGCplotPi0Spectra == kTRUE){
      histograms->AddHistogram("ESD_Mother_InvMass_vs_Pt" ,"Invariant Mass vs Pt" , kGCnXBinsSpectra, kGCfirstXBinSpectra, kGClastXBinSpectra,kGCnYBinsSpectra, kGCfirstYBinSpectra, kGClastYBinSpectra,"InvMass [GeV]","Pt [GeV]");
      histograms->AddHistogram("ESD_Mother_InvMass","Invariant mass",kGCnXBinsSpectra,kGCfirstXBinSpectra, kGClastXBinSpectra,"InvMass [GeV]","Counts");

      histograms->AddHistogram("ESD_Mother_InvMass_vs_Pt_Fiducial" ,"Invariant Mass vs Pt |eta|<0.9" , kGCnXBinsSpectra, kGCfirstXBinSpectra, kGClastXBinSpectra,kGCnYBinsSpectra, kGCfirstYBinSpectra, kGClastYBinSpectra,"InvMass [GeV]","Pt [GeV]");
      histograms->AddHistogram("ESD_Mother_InvMass_Fiducial","Invariant mass |eta|<0.9",kGCnXBinsSpectra,kGCfirstXBinSpectra, kGClastXBinSpectra,"InvMass [GeV]","Counts");


    }
    if(kGCplotPi0Spectra == kTRUE && kGCcalculateBackground == kTRUE){
      histograms->AddHistogram("ESD_Background_InvMass_vs_Pt" ,"Background Invariant Mass vs Pt" , kGCnXBinsSpectra, kGCfirstXBinSpectra, kGClastXBinSpectra,kGCnYBinsSpectra, kGCfirstYBinSpectra, kGClastYBinSpectra,"InvMass [GeV]","Pt [GeV]");
      histograms->AddHistogram("ESD_Background_InvMass","Invariant mass background",kGCnXBinsSpectra,kGCfirstXBinSpectra, kGClastXBinSpectra,"InvMass BG [GeV]","Counts");

      histograms->AddHistogram("ESD_Background_InvMass_vs_Pt_Fiducial" ,"Background Invariant Mass vs Pt |eta|<0.9" , kGCnXBinsSpectra, kGCfirstXBinSpectra, kGClastXBinSpectra,kGCnYBinsSpectra, kGCfirstYBinSpectra, kGClastYBinSpectra,"InvMass [GeV]","Pt [GeV]");
      histograms->AddHistogram("ESD_Background_InvMass_Fiducial","Invariant mass background |eta|<0.9",kGCnXBinsSpectra,kGCfirstXBinSpectra, kGClastXBinSpectra,"InvMass BG [GeV]","Counts");

    }
  }// end kGCrunNeutralMeson
}