#ifndef ALIANAPARTCORRBASECLASS_H #define ALIANAPARTCORRBASECLASS_H /* Copyright(c) 1998-1999, ALICE Experiment at CERN, All rights reserved. * * See cxx source for full Copyright notice */ /* $Id: $ */ //_________________________________________________________________________ // Base class for analysis algorithms //-- Author: Gustavo Conesa (INFN-LNF) //-Add the possibality for event selection analysis based on vertex and multiplicity bins (Yaxian Mao, 10/10/2010) #include //ROOT class TClonesArray ; class TObjArray ; #include #include class TObjString; //Analysis class AliVCaloCells; #include "AliCaloTrackReader.h" #include "AliCaloPID.h" #include "AliFiducialCut.h" #include "AliIsolationCut.h" #include "AliMCAnalysisUtils.h" #include "AliNeutralMesonSelection.h" #include "AliCalorimeterUtils.h" class AliStack ; class AliHeader ; class AliGenEventHeader ; #include "AliAODPWG4ParticleCorrelation.h" class AliEMCALGeometry; class AliPHOSGeoUtils; #include "AliMixedEvent.h" #include "AliCentrality.h" #include "AliEventplane.h" class AliAnaPartCorrBaseClass : public TObject { public: AliAnaPartCorrBaseClass() ; // default ctor virtual ~AliAnaPartCorrBaseClass() ; //virtual dtor private: AliAnaPartCorrBaseClass(const AliAnaPartCorrBaseClass & g) ; // cpy ctor AliAnaPartCorrBaseClass & operator = (const AliAnaPartCorrBaseClass & g) ;//cpy assignment public: //General methods, to be declared in deriving classes if needed virtual void Init() {;} virtual void InitParameters() ; virtual void Print(const Option_t * ) const ; virtual void MakeAnalysisFillAOD() {;} virtual void MakeAnalysisFillHistograms() {;} virtual void Terminate(TList * /*outputList*/) {;} //Histograms, cuts virtual TList * GetCreateOutputObjects() { return (new TList) ; } virtual void AddToHistogramsName(TString add) { fAddToHistogramsName = add ; } virtual TString GetAddedHistogramsStringToName()const { return fAddToHistogramsName ; } virtual TObjString * GetAnalysisCuts() { return 0x0 ; } TString GetBaseParametersList(); //Getters, setters virtual Int_t GetDebug() const { return fDebug ; } virtual void SetDebug(Int_t d) { fDebug = d ; } virtual Int_t GetEventNumber() const ; virtual AliCaloTrackReader * GetReader() const { return fReader ; } virtual void SetReader(AliCaloTrackReader * const reader) { fReader = reader ; } //Calorimeter specific access methods AliCalorimeterUtils * GetCaloUtils() const { return fCaloUtils ; } void SetCaloUtils(AliCalorimeterUtils * caloutils) { fCaloUtils = caloutils ; } AliEMCALGeometry * GetEMCALGeometry() const { return fCaloUtils->GetEMCALGeometry() ; } AliPHOSGeoUtils * GetPHOSGeometry() const { return fCaloUtils->GetPHOSGeometry() ; } Int_t GetModuleNumberCellIndexes(const Int_t absId, const TString calo, Int_t & icol, Int_t & irow, Int_t &iRCU) const { return fCaloUtils->GetModuleNumberCellIndexes(absId, calo, icol, irow,iRCU);} Int_t GetModuleNumber(AliAODPWG4Particle * part) const { return fCaloUtils->GetModuleNumber(part, fReader->GetInputEvent());} Int_t GetModuleNumber(AliVCluster * cluster) const { return fCaloUtils->GetModuleNumber(cluster);} //Centrality AliCentrality* GetCentrality() const { return fReader->GetCentrality() ; } Int_t GetEventCentrality() const { return fReader->GetEventCentrality() ; } //Event plane AliEventplane* GetEventPlane() const { return fReader->GetEventPlane() ; } TString GetEventPlaneMethod() const { return fReader->GetEventPlaneMethod() ; } //AOD branch virtual void AddAODParticle(AliAODPWG4Particle part) ; virtual void ConnectInputOutputAODBranches(); virtual TClonesArray * GetCreateOutputAODBranch() ; virtual TString GetInputAODName() const { return fInputAODName ; } virtual void SetInputAODName(TString name) { fInputAODName = name ; } virtual TString GetOutputAODName() const { return fOutputAODName ; } virtual void SetOutputAODName(TString name) { fNewAOD = kTRUE ; fOutputAODName = name; } virtual Bool_t NewOutputAOD() const { return fNewAOD ; } virtual TString GetOutputAODClassName() const { return fOutputAODClassName ; } virtual void SetOutputAODClassName(TString name) { fOutputAODClassName = name ; } virtual TString GetAODObjArrayName() const { return fAODObjArrayName ; } virtual void SetAODObjArrayName(TString name) { fAODObjArrayName = name ; } virtual TClonesArray* GetInputAODBranch() const { return fInputAODBranch ; } virtual TClonesArray* GetOutputAODBranch() const { if(fNewAOD) return fOutputAODBranch; else return fInputAODBranch ; } virtual TClonesArray* GetAODBranch(TString aodBranchName) const ; //Track cluster arrays access methods virtual TClonesArray* GetAODCaloClusters() const ; virtual TClonesArray* GetAODTracks() const ; virtual AliVCaloCells* GetPHOSCells() const { return fReader->GetPHOSCells() ;} virtual AliVCaloCells* GetEMCALCells() const { return fReader->GetEMCALCells() ;} virtual TObjArray* GetCTSTracks() const ; virtual TObjArray* GetEMCALClusters() const ; virtual TObjArray* GetPHOSClusters() const ; //MC event acces methods virtual AliStack * GetMCStack() const ; virtual AliHeader* GetMCHeader() const ; virtual AliGenEventHeader * GetMCGenEventHeader() const ; //Analysis helpers classes pointers setters and getters virtual AliCaloPID * GetCaloPID() { if(!fCaloPID) fCaloPID = new AliCaloPID(); return fCaloPID ; } virtual AliFiducialCut * GetFiducialCut() { if(!fFidCut) fFidCut = new AliFiducialCut(); return fFidCut ; } virtual AliIsolationCut * GetIsolationCut() { if(!fIC) fIC = new AliIsolationCut(); return fIC ; } virtual AliMCAnalysisUtils * GetMCAnalysisUtils() { if(!fMCUtils) fMCUtils = new AliMCAnalysisUtils(); return fMCUtils ; } virtual AliNeutralMesonSelection * GetNeutralMesonSelection() { if(!fNMS) fNMS = new AliNeutralMesonSelection(); return fNMS ; } virtual void SetCaloPID(AliCaloPID * const pid) { fCaloPID = pid ; } virtual void SetFiducialCut(AliFiducialCut * const fc) { fFidCut = fc ; } virtual void SetIsolationCut(AliIsolationCut * const ic) { fIC = ic ; } virtual void SetMCAnalysisUtils(AliMCAnalysisUtils * const mcutils) { fMCUtils = mcutils ; } virtual void SetNeutralMesonSelection(AliNeutralMesonSelection * const nms) { fNMS = nms ; } virtual Bool_t IsDataMC() const { return fDataMC ; } virtual void SwitchOnDataMC() { fDataMC = kTRUE ; if(!fMCUtils)fMCUtils = new AliMCAnalysisUtils();} virtual void SwitchOffDataMC() { fDataMC = kFALSE ; } virtual Bool_t IsFiducialCutOn() const { return fCheckFidCut ; } virtual void SwitchOnFiducialCut() { fCheckFidCut = kTRUE; if(!fFidCut)fFidCut = new AliFiducialCut();} virtual void SwitchOffFiducialCut() { fCheckFidCut = kFALSE ; } virtual Bool_t IsCaloPIDOn() const { return fCheckCaloPID ; } virtual void SwitchOnCaloPID() { fCheckCaloPID = kTRUE; if(!fCaloPID)fCaloPID = new AliCaloPID();} virtual void SwitchOffCaloPID() { fCheckCaloPID = kFALSE ; } virtual Bool_t IsCaloPIDRecalculationOn() const { return fRecalculateCaloPID ; } virtual void SwitchOnCaloPIDRecalculation() { fRecalculateCaloPID = kTRUE ; } virtual void SwitchOffCaloPIDRecalculation() { fRecalculateCaloPID = kFALSE ; } //Cluster energy/momentum cut virtual Float_t GetMaxPt() const { return fMaxPt ; } virtual Float_t GetMinPt() const { return fMinPt ; } virtual void SetMaxPt(Float_t pt) { fMaxPt = pt ; } virtual void SetMinPt(Float_t pt) { fMinPt = pt ; } virtual void SetPtCutRange(Double_t ptmin, Double_t ptmax) { fMaxPt=ptmax; fMinPt=ptmin; } virtual Float_t GetMaxEnergy() const { return fMaxPt ; } virtual Float_t GetMinEnergy() const { return fMinPt ; } virtual void SetMaxEnergy(Float_t e) { fMaxPt = e ; } virtual void SetMinEnergy(Float_t e) { fMinPt = e ; } virtual void SetEnergyCutRange(Double_t emin, Double_t emax) { fMaxPt=emax; fMinPt=emin; } //Cluster Pairs Time cut virtual void SetPairTimeCut(Float_t t) { fPairTimeCut = t ; } //ns virtual Float_t GetPairTimeCut() const { return fPairTimeCut ; } //ns //Setters for parameters of event buffers virtual void SetMultiBin(Int_t n=1) { fMultiBin = n ;} //number of bins in Multiplicity virtual void SetNZvertBin(Int_t n=1) { fNZvertBin = n ;} //number of bins for vertex position virtual void SetNRPBin(Int_t n=1) { fNrpBin = n ;} //number of bins in reaction plain virtual void SetNCentrBin(Int_t n=1) { fNCentrBin = n ;} //number of bins in centrality virtual void SetNMaxEvMix(Int_t n=20) { fNmaxMixEv = n ;} //maximal number of events for mixing virtual void SetMultiplicity(Int_t multimin, Int_t multimax) {fMinMulti = multimin ; fMaxMulti = multimax ; } virtual void SwitchOnEventSelection() { fUseSelectEvent = kTRUE ; } virtual void SwitchOffEventSelection() { fUseSelectEvent = kFALSE ; } //Getters for event selection virtual Int_t GetMultiBin() const { return fMultiBin ; } //number of bins in Multiplicity virtual Int_t GetNZvertBin() const { return fNZvertBin ; } //number of bins in vertex virtual Int_t GetNRPBin() const { return fNrpBin ; } //number of bins in reaction plain virtual Int_t GetNCentrBin() const { return fNCentrBin ; } //number of bins in centrality virtual Int_t GetNMaxEvMix() const { return fNmaxMixEv ; } //maximal number of events for mixin virtual Float_t GetZvertexCut() const { return GetReader()->GetZvertexCut();} //cut on vertex position virtual Int_t GetMaxMulti() const { return fMaxMulti ; } virtual Int_t GetMinMulti() const { return fMinMulti ; } // Do correlation analysis with different event buffers virtual Bool_t DoEventSelect() const { return fUseSelectEvent ; } //Mixed event virtual AliMixedEvent * GetMixedEvent() { return GetReader()->GetMixedEvent() ; } virtual Int_t GetNMixedEvent() const { return GetReader()->GetNMixedEvent() ; } //Vertex methods virtual void GetVertex(Double_t vertex[3]) const { GetReader()->GetVertex(vertex) ; } virtual void GetVertex(Double_t vertex[3],const Int_t evtIndex) const { GetReader()->GetVertex(vertex,evtIndex) ; } virtual Double_t* GetVertex(const Int_t evtIndex) const { return GetReader()->GetVertex(evtIndex) ; } virtual Bool_t IsTrackMatched(const AliVCluster * cluster) const { return fCaloPID->IsTrackMatched(cluster, fCaloUtils) ; } //MULTIPLICITY Int_t GetTrackMultiplicity() const { return fReader->GetTrackMultiplicity() ; } //VZERO Int_t GetV0Signal(Int_t i ) const { return fReader->GetV0Signal(i) ; } Int_t GetV0Multiplicity(Int_t i ) const { return fReader->GetV0Multiplicity(i) ; } //Histogrammes setters and getters (move to independend class to hold the parameters soon) //Pt, Energy virtual void SetHistoPtRangeAndNBins(Float_t min, Float_t max, Int_t n) { fHistoPtBins = n ; fHistoPtMax = max ; fHistoPtMin = min ; } virtual Int_t GetHistoPtBins() const { return fHistoPtBins ; } virtual Float_t GetHistoPtMin() const { return fHistoPtMin ; } virtual Float_t GetHistoPtMax() const { return fHistoPtMax ; } virtual void SetHistoEnergyRangeAndNBins(Float_t min, Float_t max, Int_t n) { SetHistoPtRangeAndNBins(min, max, n); } virtual Int_t GetHistoEnergyBins() const { return fHistoPtBins ; } virtual Float_t GetHistoEnergyMin() const { return fHistoPtMin ; } virtual Float_t GetHistoEnergyMax() const { return fHistoPtMax ; } //Azimuthal angle virtual void SetHistoPhiRangeAndNBins(Float_t min, Float_t max, Int_t n) { fHistoPhiBins = n ; fHistoPhiMax = max ; fHistoPhiMin = min ; } virtual Int_t GetHistoPhiBins() const { return fHistoPhiBins; } virtual Float_t GetHistoPhiMin() const { return fHistoPhiMin ; } virtual Float_t GetHistoPhiMax() const { return fHistoPhiMax ; } //Pseudorapidity-rapidity virtual void SetHistoEtaRangeAndNBins(Float_t min, Float_t max, Int_t n) { fHistoEtaBins = n ; fHistoEtaMax = max ; fHistoEtaMin = min ; } virtual Int_t GetHistoEtaBins() const { return fHistoEtaBins; } virtual Float_t GetHistoEtaMin() const { return fHistoEtaMin ; } virtual Float_t GetHistoEtaMax() const { return fHistoEtaMax ; } //Mass virtual void SetHistoMassRangeAndNBins(Float_t min, Float_t max, Int_t n) { fHistoMassBins = n ; fHistoMassMax = max ; fHistoMassMin = min ; } virtual Int_t GetHistoMassBins() const { return fHistoMassBins ; } virtual Float_t GetHistoMassMin() const { return fHistoMassMin ; } virtual Float_t GetHistoMassMax() const { return fHistoMassMax ; } //Asymetry virtual void SetHistoAsymmetryRangeAndNBins(Float_t min, Float_t max, Int_t n) { fHistoAsymBins = n ; fHistoAsymMax = max ; fHistoAsymMin = min ; } virtual Int_t GetHistoAsymmetryBins() const { return fHistoAsymBins ; } virtual Float_t GetHistoAsymmetryMin() const { return fHistoAsymMin ; } virtual Float_t GetHistoAsymmetryMax() const { return fHistoAsymMax ; } //VZero virtual void SetHistoV0SignalRangeAndNBins(Int_t min, Int_t max, Int_t n) { fHistoV0SBins = n ; fHistoV0SMax = max ; fHistoV0SMin = min ; } virtual Int_t GetHistoV0SignalBins() const { return fHistoV0SBins ; } virtual Int_t GetHistoV0SignalMin() const { return fHistoV0SMin ; } virtual Int_t GetHistoV0SignalMax() const { return fHistoV0SMax ; } virtual void SetHistoV0MultiplicityRangeAndNBins(Int_t min, Int_t max, Int_t n) { fHistoV0MBins = n ; fHistoV0MMax = max ; fHistoV0MMin = min ; } virtual Int_t GetHistoV0MultiplicityBins() const { return fHistoV0MBins ; } virtual Int_t GetHistoV0MultiplicityMin() const { return fHistoV0MMin ; } virtual Int_t GetHistoV0MultiplicityMax() const { return fHistoV0MMax ; } virtual void SetHistoTrackMultiplicityRangeAndNBins(Int_t min, Int_t max, Int_t n) { fHistoTrMBins = n ; fHistoTrMMax = max ; fHistoTrMMin = min ; } virtual Int_t GetHistoTrackMultiplicityBins() const { return fHistoTrMBins ; } virtual Int_t GetHistoTrackMultiplicityMin() const { return fHistoTrMMin ; } virtual Int_t GetHistoTrackMultiplicityMax() const { return fHistoTrMMax ; } Int_t GetHistoFinePtBins() const { return fHistoFinePtBins ; } Float_t GetHistoFinePtMin() const { return fHistoFinePtMin ; } Float_t GetHistoFinePtMax() const { return fHistoFinePtMax ; } Int_t GetHistodEdxBins() const { return fHistodEdxBins ; } Float_t GetHistodEdxMin() const { return fHistodEdxMin ; } Float_t GetHistodEdxMax() const { return fHistodEdxMax ; } Int_t GetHistoNClusterCellBins() const { return fHistoNBins ; } Int_t GetHistoNClusterCellMin() const { return fHistoNMin ; } Int_t GetHistoNClusterCellMax() const { return fHistoNMax ; } Int_t GetHistoPOverEBins() const { return fHistoPOverEBins ; } Float_t GetHistoPOverEMin() const { return fHistoPOverEMin ; } Float_t GetHistoPOverEMax() const { return fHistoPOverEMax ; } Int_t GetHistodRBins() const { return fHistodRBins ; } Float_t GetHistodRMin() const { return fHistodRMin ; } Float_t GetHistodRMax() const { return fHistodRMax ; } Int_t GetHistoTimeBins() const { return fHistoTimeBins ; } Float_t GetHistoTimeMin() const { return fHistoTimeMin ; } Float_t GetHistoTimeMax() const { return fHistoTimeMax ; } Int_t GetHistoRatioBins() const { return fHistoRatioBins ; } Float_t GetHistoRatioMin() const { return fHistoRatioMin ; } Float_t GetHistoRatioMax() const { return fHistoRatioMax ; } Int_t GetHistoVertexDistBins() const { return fHistoVertexDistBins ; } Float_t GetHistoVertexDistMin() const { return fHistoVertexDistMin ; } Float_t GetHistoVertexDistMax() const { return fHistoVertexDistMax ; } Int_t GetHistoRBins() const { return fHistoRBins ; } Float_t GetHistoRMin() const { return fHistoRMin ; } Float_t GetHistoRMax() const { return fHistoRMax ; } Int_t GetHistoXBins() const { return fHistoXBins ; } Float_t GetHistoXMin() const { return fHistoXMin ; } Float_t GetHistoXMax() const { return fHistoXMax ; } Int_t GetHistoYBins() const { return fHistoYBins ; } Float_t GetHistoYMin() const { return fHistoYMin ; } Float_t GetHistoYMax() const { return fHistoYMax ; } Int_t GetHistoZBins() const { return fHistoZBins ; } Float_t GetHistoZMin() const { return fHistoZMin ; } Float_t GetHistoZMax() const { return fHistoZMax ; } Int_t GetHistoShowerShapeBins() const { return fHistoSSBins ; } Float_t GetHistoShowerShapeMin() const { return fHistoSSMin ; } Float_t GetHistoShowerShapeMax() const { return fHistoSSMax ; } Int_t GetHistoDiffTimeBins() const { return fHistoDiffTimeBins ; } Float_t GetHistoDiffTimeMin() const { return fHistoDiffTimeMin ; } Float_t GetHistoDiffTimeMax() const { return fHistoDiffTimeMax ; } virtual void SetHistoPOverERangeAndNBins (Float_t min, Float_t max, Int_t n) { fHistoPOverEBins = n ; fHistoPOverEMax = max ; fHistoPOverEMin = min ; } virtual void SetHistoFinePtRangeAndNBins (Float_t min, Float_t max, Int_t n) { fHistoFinePtBins = n ; fHistoFinePtMax = max ; fHistoFinePtMin = min ; } virtual void SetHistodEdxRangeAndNBins (Float_t min, Float_t max, Int_t n) { fHistodEdxBins = n ; fHistodEdxMax = max ; fHistodEdxMin = min ; } virtual void SetHistodRRangeAndNBins (Float_t min, Float_t max, Int_t n) { fHistodRBins = n ; fHistodRMax = max ; fHistodRMin = min ; } virtual void SetHistoTimeRangeAndNBins (Float_t min, Float_t max, Int_t n) { fHistoTimeBins = n ; fHistoTimeMax = max ; fHistoTimeMin = min ; } virtual void SetHistoNClusterCellRangeAndNBins(Int_t min, Int_t max, Int_t n) { fHistoNBins = n ; fHistoNMax = max ; fHistoNMin = min ; } virtual void SetHistoRatioRangeAndNBins (Float_t min, Float_t max, Int_t n) { fHistoRatioBins = n ; fHistoRatioMax = max ; fHistoRatioMin = min ; } virtual void SetHistoVertexDistRangeAndNBins (Float_t min, Float_t max, Int_t n) { fHistoVertexDistBins = n ; fHistoVertexDistMax = max ; fHistoVertexDistMin = min ; } virtual void SetHistoXRangeAndNBins (Float_t min, Float_t max, Int_t n) { fHistoXBins = n ; fHistoXMax = max ; fHistoXMin = min ; } virtual void SetHistoYRangeAndNBins (Float_t min, Float_t max, Int_t n) { fHistoYBins = n ; fHistoYMax = max ; fHistoYMin = min ; } virtual void SetHistoZRangeAndNBins (Float_t min, Float_t max, Int_t n) { fHistoZBins = n ; fHistoZMax = max ; fHistoZMin = min ; } virtual void SetHistoRRangeAndNBins (Float_t min, Float_t max, Int_t n) { fHistoRBins = n ; fHistoRMax = max ; fHistoRMin = min ; } virtual void SetHistoShowerShapeRangeAndNBins (Float_t min, Float_t max, Int_t n) { fHistoSSBins = n ; fHistoSSMax = max ; fHistoSSMin = min ; } void SetHistoDiffTimeRangeAndNBins(Float_t min, Float_t max, Int_t n) { fHistoDiffTimeBins = n ; fHistoDiffTimeMax = max ; fHistoDiffTimeMin = min ; } void SwitchOnPlotsMaking() { fMakePlots = kTRUE ; } void SwitchOffPlotsMaking() { fMakePlots = kFALSE ; } Bool_t MakePlotsOn() const { return fMakePlots ; } private: Bool_t fDataMC ; // Flag to access MC data when using ESD or AOD Int_t fDebug ; // Debug level Bool_t fCheckFidCut ; // Do analysis for clusters in defined region Bool_t fCheckCaloPID ; // Do analysis for calorimeters Bool_t fRecalculateCaloPID ; // Recalculate PID or use PID weights in calorimeters Float_t fMinPt ; // Maximum pt of (trigger) particles in the analysis Float_t fMaxPt ; // Minimum pt of (trigger) particles in the analysis Float_t fPairTimeCut; // Maximum difference between time of cluster pairs (ns) Int_t fMultiBin ; // Number of bins in event container for multiplicity Int_t fNZvertBin ; // Number of bins in event container for vertex position Int_t fNrpBin ; // Number of bins in event container for reaction plain Int_t fNCentrBin ; // Number of bins in event container for centrality Int_t fNmaxMixEv ; // Maximal number of events stored in buffer for mixing Int_t fMaxMulti ; // Maximum multiplicity of particles in the analysis Int_t fMinMulti ; // Maximum multiplicity of particles in the analysis Bool_t fUseSelectEvent ; // Select events based on multiplicity and vertex cuts Bool_t fMakePlots ; // Print plots AliCaloTrackReader * fReader; // Acces to ESD/AOD/MC data TClonesArray* fInputAODBranch ; //! Selected input particles branch TString fInputAODName ; // Name of input AOD branch; TClonesArray* fOutputAODBranch ; //! Selected output particles branch Bool_t fNewAOD ; // Flag, new aod branch added to the analysis or not. TString fOutputAODName ; // Name of output AOD branch; TString fOutputAODClassName; // Type of aod objects to be stored in the TClonesArray (AliAODPWG4Particle, AliAODPWG4ParticleCorrelation ...) TString fAODObjArrayName ; // Name of ref array kept in a TList in AliAODParticleCorrelation with clusters or track references. TString fAddToHistogramsName;// Add this string to histograms name //Analysis helper classes access pointers AliCaloPID * fCaloPID; // PID calculation AliFiducialCut * fFidCut; // Acceptance cuts AliIsolationCut * fIC; // Isolation cut AliMCAnalysisUtils * fMCUtils; // MonteCarlo Analysis utils AliNeutralMesonSelection * fNMS; // Neutral Meson Selection AliCalorimeterUtils * fCaloUtils ; // Pointer to CalorimeterUtils //Histograms binning and range Int_t fHistoPtBins ; // Number of bins in pt axis Float_t fHistoPtMax ; // Maximum value of pt histogram range Float_t fHistoPtMin ; // Minimum value of pt histogram range Int_t fHistoPhiBins ; // Number of bins in phi axis Float_t fHistoPhiMax ; // Maximum value of phi histogram range Float_t fHistoPhiMin ; // Minimum value of phi histogram range Int_t fHistoEtaBins ; // Number of bins in eta axis Float_t fHistoEtaMax ; // Maximum value of eta histogram range Float_t fHistoEtaMin ; // Minimum value of eta histogram range Int_t fHistoMassBins ; // Number of bins in mass axis Float_t fHistoMassMax ; // Maximum value of mass histogram range Float_t fHistoMassMin ; // Minimum value of mass histogram range Int_t fHistoAsymBins ; // Number of bins in asymmetry axis Float_t fHistoAsymMax ; // Maximum value of asymmetry histogram range Float_t fHistoAsymMin ; // Minimum value of asymmetry histogram range Int_t fHistoV0SBins ; // Number of bins in V0 signal axis Int_t fHistoV0SMax ; // Maximum value of V0 signal histogram range Int_t fHistoV0SMin ; // Minimum value of V0 signal histogram range Int_t fHistoV0MBins ; // Number of bins in V0 multiplicity axis Int_t fHistoV0MMax ; // Maximum value of V0 multiplicity histogram range Int_t fHistoV0MMin ; // Minimum value of V0 multiplicity histogram range Int_t fHistoTrMBins ; // Number of bins in V0 multiplicity axis Int_t fHistoTrMMax ; // Maximum value of track multiplicity histogram range Int_t fHistoTrMMin ; // Minimum value of track multiplicity histogram range Int_t fHistoFinePtBins; // fine binning for fhAmpId histogram Float_t fHistoFinePtMax; // maximum pt value for fhAmpId histogram Float_t fHistoFinePtMin; // minimum pt value for fhAmpId histogram Int_t fHistoPOverEBins; // p/E histogram number of bins Float_t fHistoPOverEMax; // p/E maximum value Float_t fHistoPOverEMin; // p/E minimum value Int_t fHistodEdxBins; // dEdx histogram number of bins Float_t fHistodEdxMax; // dEdx maximum value Float_t fHistodEdxMin; // dEdx minimum value Int_t fHistodRBins; // dR histogram number of bins Float_t fHistodRMax; // dR maximum value Float_t fHistodRMin; // dR minimum value Int_t fHistoTimeBins; // cell time histogram number of bins Float_t fHistoTimeMax; // cell time maximum value Float_t fHistoTimeMin; // cell time minimum value Int_t fHistoNBins; // number of clusters/cells histogram number of bins Int_t fHistoNMax; // number maximum value Int_t fHistoNMin; // number minimum value Int_t fHistoRatioBins; // ratio histogram number of bins Float_t fHistoRatioMax; // ratio maximum value Float_t fHistoRatioMin; // ratio minimum value Int_t fHistoVertexDistBins; // vertex distance histogram number of bins Float_t fHistoVertexDistMax; // vertex distance maximum value Float_t fHistoVertexDistMin; // vertex distance minimum value Int_t fHistoRBins; // r =sqrt(x^2+y^2+z^2) (cm) position histogram number of bins Float_t fHistoRMax; // r =sqrt(x^2+y^2+z^2) (cm) maximum value Float_t fHistoRMin; // r =sqrt(x^2+y^2+z^2) (cm) minimum value Int_t fHistoXBins; // x (cm) position histogram number of bins Float_t fHistoXMax; // x (cm) position maximum value Float_t fHistoXMin; // x (cm) position minimum value Int_t fHistoYBins; // y (cm) position histogram number of bins Float_t fHistoYMax; // y (cm) position maximum value Float_t fHistoYMin; // y (cm) position minimum value Int_t fHistoZBins; // z (cm) position histogram number of bins Float_t fHistoZMax; // z (cm) position maximum value Float_t fHistoZMin; // z (cm) position minimum value Int_t fHistoSSBins; // Shower Shape parameter histogram number of bins Float_t fHistoSSMax; // Shower Shape parameter position maximum value Float_t fHistoSSMin; // Shower Shape parameter position minimum value Int_t fHistoDiffTimeBins; // Difference cluster pair time parameter histogram number of bins Float_t fHistoDiffTimeMax; // Difference cluster pair time parameter position maximum value Float_t fHistoDiffTimeMin; // Difference cluster pair time parameter position minimum value ClassDef(AliAnaPartCorrBaseClass,18) } ; #endif //ALIANAPARTCORRBASECLASS_H