#ifndef ALIANALYSISTASKELECHADRONCORREL_H #define ALIANALYSISTASKELECHADRONCORREL_H /* Copyright(c) 1998-1999, ALICE Experiment at CERN, All rights reserved. * * See cxx source for full Copyright notice */ //////////////////////////////////////////////////////////////////////// // // // Task for Heavy Flavour Electron-Hadron DeltaPhi Correlation // // // // Author: Deepa Thomas (Utrecht University) // // // //////////////////////////////////////////////////////////////////////// class THnSparse; class TH2F; class TLorentzVector; class AliEMCALTrack; class AliMagF; class AliESDEvent; class AliAODEvent; class AliEMCALGeometry; class AliEMCALRecoUtils; class AliAnalysisFilter; class AliESDtrackCuts; class AliESDtrack; class AliAODTrack; class AliHFEcontainer; class AliHFEcuts; class AliHFEpid; class AliHFEpidQAmanager; class AliCFManager; //class AliEventPoolManager; #include "AliLog.h" #include "AliAnalysisTaskSE.h" #include "AliCentrality.h" class AliAnalysisTaskElecHadronCorrel : public AliAnalysisTaskSE { public: AliAnalysisTaskElecHadronCorrel(); AliAnalysisTaskElecHadronCorrel(const char *name); virtual ~AliAnalysisTaskElecHadronCorrel(); virtual void UserCreateOutputObjects(); virtual void UserExec(Option_t *option); virtual void Terminate(Option_t *); Bool_t IsAODanalysis() const { return TestBit(kAODanalysis); }; Bool_t IsESDanalysis() const { return !TestBit(kAODanalysis); }; void SetHFECuts(AliHFEcuts * const cuts) { fCuts = cuts; }; void SetInvariantMassCut (Double_t invmass) {fInvmassCut = invmass;}; AliHFEpid *GetPID() const { return fPID; } void SetRejectKinkMother(Bool_t rejectKinkMother = kFALSE) { fRejectKinkMother = rejectKinkMother; }; void SelectPhotonicElectron(Int_t itrack, AliVTrack *track, Bool_t &fFlagPhotonicElec); void ElectronHadCorrel(Int_t itrack, AliVTrack *track, TH2F *DphiPt, TH2F *DphiPt1,TH2F *DphiPt2,TH2F *DphiPt3,TH2F *DphiPt4); void ElectronHadCorrelNoPartner(Int_t itrack,Int_t jtrack, AliVTrack *track, TH2F *DphiPtNew,TH2F *DphiPtNew1,TH2F *DphiPtNew2,TH2F *DphiPtNew3,TH2F *DphiPtNew4); void HadronInfo(Int_t itrack); void SetCentralityParameters(Double_t CentralityMin, Double_t CentralityMax, const char* CentralityMethod); //select centrality void CheckCentrality(AliVEvent *event,Bool_t ¢ralitypass); //to use only events with the correct centrality.... void SetAODAnalysis() { SetBit(kAODanalysis, kTRUE); }; void SetESDAnalysis() { SetBit(kAODanalysis, kFALSE); }; /* void MixedEvent(AliAODTrack *track, TH2F *DphiPt, TH2F *DphiPt1, TH2F *DphiPt2); TObjArray* CloneAndReduceTrackList(); */ private: enum{ kAODanalysis = BIT(20), }; Bool_t ProcessCutStep(Int_t cutStep, AliVParticle *track); AliVEvent *fVevent; //V event object AliESDEvent *fESD; //ESD object AliAODEvent *fAOD; //AOD object AliEMCALGeometry *fGeom; // emcal geometry TList *fOutputList; //output list AliESDtrackCuts *fTrackCuts1; //ESD track cuts AliESDtrackCuts *fTrackCuts2; //ESD track cuts AliHFEcuts *fCuts; //Cut Collection Bool_t fIdentifiedAsOutInz; //Out Of Range in z Bool_t fPassTheEventCut; //Pass The Event Cut Bool_t fRejectKinkMother; //Reject Kink Mother Double_t fVz; //z position of the primary vertex AliCFManager *fCFM; //!Correction Framework Manager AliHFEpid *fPID; //PID AliHFEpidQAmanager *fPIDqa; //! PID QA manager Double_t fInvmassCut; //invariant mass cut value Double_t fCentrality; // event centrality for QA Double_t fCentralityMin; // lower bound of cenrality bin Double_t fCentralityMax; // upper bound of centrality bin const char *fkCentralityMethod; // method used to determine centrality (V0 by default) // AliEventPoolManager* fPoolMgr; //! event pool manager TH1F *fNoEvents; //no of events // TH1F *fTrkpt; //track pt TH2F *fTrkEovPBef; //track E/p before HFE pid TH2F *fTrkEovPBefHad; //track E/p before HFE pid // TH2F *fdEdxBef; //track dEdx vs p before HFE pid TH2F *fSemiIncElecDphi; //Semi Inclusive elec - had DPhi TH2F *fSemiIncElecDphi1; //Semi Inclusive elec - had DPhi TH2F *fSemiIncElecDphi2; //Semi Inclusive elec - had DPhi TH2F *fSemiIncElecDphi3; //Semi Inclusive elec - had DPhi TH2F *fSemiIncElecDphi4; //Semi Inclusive elec - had DPhi TH2F *fPhotElecDphi; //Photon elec - had DPhi TH2F *fPhotElecDphi1; //Photon elec - had DPhi TH2F *fPhotElecDphi2; //Photon elec - had DPhi TH2F *fPhotElecDphi3; //Photon elec - had DPhi TH2F *fPhotElecDphi4; //Photon elec - had DPhi TH2F *fInclusiveElecDphi; //Inclusive elec - had DPhi TH2F *fInclusiveElecDphi1; //Inclusive elec - had DPhi TH2F *fInclusiveElecDphi2; //Inclusive elec - had DPhi TH2F *fInclusiveElecDphi3; //Inclusive elec - had DPhi TH2F *fInclusiveElecDphi4; //Inclusive elec - had DPhi TH2F *fDphiULSMassLow; //Dphi - ULS, mass< mass cut TH2F *fDphiULSMassLow1; //Dphi - ULS, mass< mass cut TH2F *fDphiULSMassLow2; //Dphi - ULS, mass< mass cut TH2F *fDphiULSMassLow3; //Dphi - ULS, mass< mass cut TH2F *fDphiULSMassLow4; //Dphi - ULS, mass< mass cut TH2F *fDphiLSMassLow; //Dphi - LS, mass< mass cut TH2F *fDphiLSMassLow1; //Dphi - LS, mass< mass cut TH2F *fDphiLSMassLow2; //Dphi - LS, mass< mass cut TH2F *fDphiLSMassLow3; //Dphi - LS, mass< mass cut TH2F *fDphiLSMassLow4; //Dphi - LS, mass< mass cut TH2F *fDphiULSMassLowNoPartner; //Dphi - ULS, mass< mass cut no partner TH2F *fDphiULSMassLowNoPartner1; //Dphi - ULS, mass< mass cut no partner TH2F *fDphiULSMassLowNoPartner2; //Dphi - ULS, mass< mass cut no partner TH2F *fDphiULSMassLowNoPartner3; //Dphi - ULS, mass< mass cut no partner TH2F *fDphiULSMassLowNoPartner4; //Dphi - ULS, mass< mass cut no partner TH2F *fDphiLSMassLowNoPartner; //Dphi - LS, mass< mass cut TH2F *fDphiLSMassLowNoPartner1; //Dphi - LS, mass< mass cut TH2F *fDphiLSMassLowNoPartner2; //Dphi - LS, mass< mass cut TH2F *fDphiLSMassLowNoPartner3; //Dphi - LS, mass< mass cut TH2F *fDphiLSMassLowNoPartner4; //Dphi - LS, mass< mass cut TH1F *fPhotoElecPt; //photonic elec pt TH1F *fSemiInclElecPt; //Semi inclusive ele pt TH1F *fInclusiveElecPt; // Inclusive elec pt TH1F *fULSElecPt; //ULS elec Pt TH1F *fLSElecPt;// LS elec pt TH1F *fTrackPtBefTrkCuts; //Track pt before track cuts TH1F *fTrackPtAftTrkCuts; //Track pt after track cuts TH2F *fTPCnsigma; //TPC n sigma vs p TH1F *fNCellv1; //No of cells in cluster, all EMCAL cluster TH1F *fClsEv1; //Cluster energy, all EMCAL cluster TH1F *fNClusv1; //No of clusters in event, all EMCAL cluster TH1F *fInvmassLS1; //LS Invmass for all rec par TH1F *fInvmassLS2; //LS Invmass for all rec par TH1F *fInvmassLS3; //LS Invmass for all rec par TH1F *fInvmassLS4; //LS Invmass for all rec par TH1F *fInvmassLS5; //LS Invmass for all rec par TH1F *fInvmassULS1;//ULS Invmass for all rec par TH1F *fInvmassULS2;//ULS Invmass for all rec par TH1F *fInvmassULS3;//ULS Invmass for all rec par TH1F *fInvmassULS4;//ULS Invmass for all rec par TH1F *fInvmassULS5;//ULS Invmass for all rec par TH1F *fcentrality;// TH1F *fElecPhi;// TH1F *fElecPhiTPChalf;// TH2F *fElecPhiPt;// // TH1F *fElecPhiTPC;// // TH1F *fElecPhiTPCEovP;// TH1F *fHadronPhi;// TH1F *fHadronPhiTPChalf;// TH2F *fHadronPhiPt;// /* TH1F *fTrackHFEcuts;// TH1F *fTrakPhiSPD1;// TH1F *fTrakPhiSPD2;// TH1F *fTrakPhiSPDOr;// TH1F *fTrakPhiSPDAnd;// TH1F *fTrackHFEcutsITS;// */ /* TH1F *fNoMixedEvents;// TH2F *fMixStat; //no of events in pool vs multplicity TH2F *fMixStat1; //no of events in pool vs zvtx TH2F *fMixedIncElecDphi; //Mixed event - inclusive elec DPhi TH2F *fMixedIncElecDphi1; //Mixed event - inclusive elec DPhi TH2F *fMixedIncElecDphi2; //Mixed event - inclusive elec DPhi TH2F *fMixedPhotElecDphi; // TH2F *fMixedPhotElecDphi1; // TH2F *fMixedPhotElecDphi2; // TH2F *fMixedSemiIncElecDphi; // TH2F *fMixedSemiIncElecDphi1; // TH2F *fMixedSemiIncElecDphi2; // TH2F *fMixedDphiULSMassLow;// TH2F *fMixedDphiULSMassLow1;// TH2F *fMixedDphiULSMassLow2;// TH2F *fMixedDphiLSMassLow;// TH2F *fMixedDphiLSMassLow1;// TH2F *fMixedDphiLSMassLow2;// */ TH1F *fHadronPt;// TH1F *fCentralityPass; // ! QA histogram of events that pass centrality cut TH1F *fCentralityNoPass; //! QA histogram of events that do not pass centrality cut // THnSparse *fSparseElectron;//!Electron info // Double_t *fvalueElectron;//!Electron info AliAnalysisTaskElecHadronCorrel(const AliAnalysisTaskElecHadronCorrel&); // not implemented AliAnalysisTaskElecHadronCorrel& operator=(const AliAnalysisTaskElecHadronCorrel&); // not implemented ClassDef(AliAnalysisTaskElecHadronCorrel, 2); //!example of analysis }; /* class AliehDPhiBasicParticle : public AliVParticle { public: AliehDPhiBasicParticle(Float_t eta, Float_t phi, Float_t pt, Short_t charge) : fEta(eta), fPhi(phi), fpT(pt), fCharge(charge) { } ~AliehDPhiBasicParticle() {} // kinematics virtual Double_t Px() const { AliFatal("Not implemented"); return 0; } virtual Double_t Py() const { AliFatal("Not implemented"); return 0; } virtual Double_t Pz() const { AliFatal("Not implemented"); return 0; } virtual Double_t Pt() const { return fpT; } virtual Double_t P() const { AliFatal("Not implemented"); return 0; } virtual Bool_t PxPyPz(Double_t[3]) const { AliFatal("Not implemented"); return 0; } virtual Double_t Xv() const { AliFatal("Not implemented"); return 0; } virtual Double_t Yv() const { AliFatal("Not implemented"); return 0; } virtual Double_t Zv() const { AliFatal("Not implemented"); return 0; } virtual Bool_t XvYvZv(Double_t[3]) const { AliFatal("Not implemented"); return 0; } virtual Double_t OneOverPt() const { AliFatal("Not implemented"); return 0; } virtual Double_t Phi() const { return fPhi; } virtual Double_t Theta() const { AliFatal("Not implemented"); return 0; } virtual Double_t E() const { AliFatal("Not implemented"); return 0; } virtual Double_t M() const { AliFatal("Not implemented"); return 0; } virtual Double_t Eta() const { return fEta; } virtual Double_t Y() const { AliFatal("Not implemented"); return 0; } virtual Short_t Charge() const { return fCharge; } virtual Int_t GetLabel() const { AliFatal("Not implemented"); return 0; } // PID virtual Int_t PdgCode() const { AliFatal("Not implemented"); return 0; } virtual const Double_t *PID() const { AliFatal("Not implemented"); return 0; } private: Float_t fEta; // eta Float_t fPhi; // phi Float_t fpT; // pT Short_t fCharge; // charge ClassDef( AliehDPhiBasicParticle, 1); // class which contains only quantities requires for this analysis to reduce memory consumption for event mixing }; */ #endif