#ifndef ALIAODRECODECAY_H #define ALIAODRECODECAY_H /* Copyright(c) 1998-2006, ALICE Experiment at CERN, All rights reserved. * * See cxx source for full Copyright notice */ //*********************************************************** // Class AliAODRecoDecay // base class for AOD reconstructed decays // Author: A.Dainese, andrea.dainese@lnl.infn.it //*********************************************************** #include #include #include #include "AliAODVertex.h" #include "AliAODTrack.h" #include "AliVTrack.h" class AliAODRecoDecay : public AliVTrack { public: AliAODRecoDecay(); AliAODRecoDecay(AliAODVertex *vtx2,Int_t nprongs,Short_t charge, Double_t *px,Double_t *py,Double_t *pz, Double_t *d0); AliAODRecoDecay(AliAODVertex *vtx2,Int_t nprongs,Short_t charge, Double_t *d0); virtual ~AliAODRecoDecay(); AliAODRecoDecay(const AliAODRecoDecay& source); AliAODRecoDecay& operator=(const AliAODRecoDecay& source); // decay vertex Double_t GetSecVtxX() const {return GetSecondaryVtx()->GetX();} Double_t GetSecVtxY() const {return GetSecondaryVtx()->GetY();} Double_t GetSecVtxZ() const {return GetSecondaryVtx()->GetZ();} Double_t RadiusSecVtx() const; void SetSecondaryVtx(AliAODVertex *vtx2) {fSecondaryVtx=vtx2;} AliAODVertex* GetSecondaryVtx() const { return (((AliAODVertex*)fSecondaryVtx.GetObject()) ? (AliAODVertex*)fSecondaryVtx.GetObject() : GetOwnSecondaryVtx()); } void SetOwnSecondaryVtx(AliAODVertex *vtx2) {fOwnSecondaryVtx=vtx2;} AliAODVertex* GetOwnSecondaryVtx() const {return fOwnSecondaryVtx;} void GetSecondaryVtx(Double_t vtx[3]) const; Double_t GetReducedChi2() const {return GetSecondaryVtx()->GetChi2perNDF();} Short_t Charge() const {return fCharge;} Short_t GetCharge() const {return fCharge;} void SetCharge(Short_t charge=0) {fCharge=charge;} // Match to MC signal: // check if this candidate is matched to a MC signal // If no, return -1 // If yes, return label (>=0) of the AliAODMCParticle // if ndgCk>0, checks also daughters PDGs Int_t MatchToMC(Int_t pdgabs,TClonesArray *mcArray,Int_t ndgCk=0,Int_t *pdgDg=0) const; // PID void SetPID(Int_t nprongs,Double_t *pid); Double_t *GetPID() const { return fPID; } void GetPIDProng(Int_t ip,Double_t *pid) const; virtual const Double_t *PID() const { return fPID; } // prong-to-prong DCAs void SetDCAs(Int_t nDCA,Double_t *dca); void SetDCA(Double_t dca); // 2 prong Double_t GetDCA(Int_t i=0) const {return fDCA[i];} //event and run number void SetEventRunNumbers(Int_t en,Int_t rn) { fEventNumber=en; fRunNumber=rn; return; } Int_t GetEventNumber() const { return fEventNumber; } Int_t GetRunNumber() const { return fRunNumber; } // methods of AliVTrack virtual Int_t GetID() const { return -1; } virtual UChar_t GetITSClusterMap() const; virtual ULong_t GetStatus() const; virtual Bool_t GetXYZ(Double_t *p) const { return XvYvZv(p); } virtual Bool_t GetCovarianceXYZPxPyPz(Double_t cv[21]) const; // kinematics & topology Double_t Px() const; Double_t Py() const; Double_t Pz() const; Double_t P() const {return TMath::Sqrt(Px()*Px()+Py()*Py()+Pz()*Pz());} Double_t Pt() const {return TMath::Sqrt(Px()*Px()+Py()*Py());} Double_t OneOverPt() const {return (Pt() ? 1./Pt() : 0.);} Bool_t PxPyPz(Double_t p[3]) const { p[0] = Px(); p[1] = Py(); p[2] = Pz(); return kTRUE; } Double_t Phi() const {return TMath::Pi()+TMath::ATan2(-Py(),-Px());} Double_t Theta() const {return 0.5*TMath::Pi()-TMath::ATan(Pz()/(Pt()+1.e-13));} Double_t Eta() const {return 0.5*TMath::Log((P()+Pz())/(P()-Pz()+1.e-13));} Double_t Xv() const { return GetSecVtxX(); } Double_t Yv() const { return GetSecVtxY(); } Double_t Zv() const { return GetSecVtxZ(); } virtual Bool_t XvYvZv(Double_t x[3]) const { x[0] = Xv(); x[1] = Yv(); x[2] = Zv(); return kTRUE; } Double_t E(UInt_t pdg) const; Double_t Y(UInt_t pdg) const {return 0.5*TMath::Log((E(pdg)+Pz())/(E(pdg)-Pz()+1.e-13));} Double_t DecayLength(Double_t point[3]) const; Double_t DecayLength(AliAODVertex *vtx1) const {return GetSecondaryVtx()->DistanceToVertex(vtx1);} Double_t DecayLengthError(AliAODVertex *vtx1) const {return GetSecondaryVtx()->ErrorDistanceToVertex(vtx1);} Double_t NormalizedDecayLength(AliAODVertex *vtx1) const {return DecayLength(vtx1)/DecayLengthError(vtx1);} Double_t DecayLengthXY(Double_t point[3]) const; Double_t DecayLengthXY(AliAODVertex *vtx1) const {return GetSecondaryVtx()->DistanceXYToVertex(vtx1);} Double_t DecayLengthXYError(AliAODVertex *vtx1) const {return GetSecondaryVtx()->ErrorDistanceXYToVertex(vtx1);} Double_t NormalizedDecayLengthXY(AliAODVertex *vtx1) const {return DecayLengthXY(vtx1)/DecayLengthXYError(vtx1);} Double_t Ct(UInt_t pdg,Double_t point[3]) const; Double_t Ct(UInt_t pdg,AliAODVertex *vtx1) const; Double_t CosPointingAngle(Double_t point[3]) const; Double_t CosPointingAngle(AliAODVertex *vtx1) const; Double_t CosPointingAngleXY(Double_t point[3]) const; Double_t CosPointingAngleXY(AliAODVertex *vtx1) const; Double_t CosThetaStar(Int_t ip,UInt_t pdgvtx,UInt_t pdgprong0,UInt_t pdgprong1) const; Double_t InvMass(Int_t npdg,UInt_t *pdg) const; Double_t ImpParXY(Double_t point[3]) const; Double_t ImpParXY(AliAODVertex *vtx1) const; // prongs Int_t GetNProngs() const {return fNProngs;} Int_t GetNDaughters() const {return GetSecondaryVtx()->GetNDaughters();} TObject *GetDaughter(Int_t i) const {return (GetNDaughters()>i ? GetSecondaryVtx()->GetDaughter(i) : 0x0);} Short_t ChargeProng(Int_t ip) const; Double_t Getd0Prong(Int_t ip) const {return fd0[ip];} Double_t Prodd0d0(Int_t ip1=0,Int_t ip2=0) const {return fd0[ip1]*fd0[ip2];} Double_t PxProng(Int_t ip) const {return fPx[ip];} Double_t PyProng(Int_t ip) const {return fPy[ip];} Double_t PzProng(Int_t ip) const {return fPz[ip];} Double_t PtProng(Int_t ip) const; Double_t PProng(Int_t ip) const; Double_t PhiProng(Int_t ip) const {return TMath::ATan2(PyProng(ip),PxProng(ip));} Double_t ThetaProng(Int_t ip) const {return 0.5*TMath::Pi()-TMath::ATan(PzProng(ip)/(PtProng(ip)+1.e-13));} Double_t EtaProng(Int_t ip) const {return -TMath::Log(TMath::Tan(0.5*ThetaProng(ip)));} Double_t EProng(Int_t ip,UInt_t pdg) const; Double_t YProng(Int_t ip,UInt_t pdg) const {return 0.5*TMath::Log((EProng(ip,pdg)+PzProng(ip))/(EProng(ip,pdg)-PzProng(ip)+1.e-13));} Double_t Alpha() const; // for Armenteros-Podolanski plot (V0's) Double_t QlProng(Int_t ip) const; Double_t QtProng(Int_t ip=0) const; // for Armenteros-Podolanski plot (V0's) Double_t QlProngFlightLine(Int_t ip,Double_t point[3]) const; Double_t QlProngFlightLine(Int_t ip,AliAODVertex *vtx1) const; Double_t QtProngFlightLine(Int_t ip,Double_t point[3]) const; Double_t QtProngFlightLine(Int_t ip,AliAODVertex *vtx1) const; Double_t InvMass2Prongs(Int_t ip1,Int_t ip2,UInt_t pdg1,UInt_t pdg2) const; Double_t ProngsRelAngle(Int_t ip1=0,Int_t ip2=1) const; // relate to other objects //Double_t DistanceToVertex(AliAODVertex *vtx) // distance to a AliAODVertex //Double_t DistanceToTrack(AliAODTrack *trk) // distance to a AliAODTrack // print void Print(Option_t* option = "") const; //void PrintIndices() const {GetSecondaryVtx()->PrintIndices();} // dummy functions for inheritance from AliVParticle Double_t E() const {printf("Dummy function; use AliAODRecoDecay::E(UInt_t pdg) instead"); return (Double_t)-999.;} Double_t Y() const {printf("Dummy function; use AliAODRecoDecay::Y(UInt_t pdg) instead"); return (Double_t)-999.;} Double_t M() const {printf("Dummy function"); return (Double_t)-999.;} Int_t GetLabel() const {return -1;} protected: Int_t MatchToMC(Int_t pdgabs,TClonesArray *mcArray,Int_t dgLabels[10],Int_t ndg,Int_t ndgCk=0,Int_t *pdgDg=0) const; Int_t MatchToMC(Int_t pdgabs,TClonesArray *mcArray,Int_t dgLabels[10]) const { return MatchToMC(pdgabs,mcArray,dgLabels,GetNDaughters()); } TRef fSecondaryVtx; // decay vertex AliAODVertex *fOwnSecondaryVtx; // temporary solution (to work outside AliAODEvent) Short_t fCharge; // charge, use this convention for prongs charges: // if(charge== 0) even-index prongs are + // odd-index prongs are - // if(charge==+1) even-index prongs are + // odd-index prongs are - // if(charge==-1) even-index prongs are - // odd-index prongs are + // TEMPORARY, to be removed when we do analysis on AliAODEvent Int_t fNProngs; // number of prongs Int_t fNDCA; // number of dca's Int_t fNPID; // number of PID probabilities Double32_t *fPx; //[fNProngs] px of tracks at the vertex [GeV/c] Double32_t *fPy; //[fNProngs] py of tracks at the vertex [GeV/c] Double32_t *fPz; //[fNProngs] pz of tracks at the vertex [GeV/c] Double32_t *fd0; //[fNProngs] rphi impact params w.r.t. Primary Vtx [cm] Double32_t *fDCA; //[fNDCA] prong-to-prong DCA [cm] // convention:fDCA[0]=p0p1,fDCA[1]=p0p2,fDCA[2]=p1p2,... Double32_t *fPID; //[fNPID] combined pid // (combined detector response probabilities) // TEMPORARY, to be removed when we do analysis on AliAODEvent Int_t fEventNumber; Int_t fRunNumber; // TO BE PUT IN SPECIAL MC CLASS //Bool_t fSignal; // TRUE if signal, FALSE if background (for simulation) //Int_t fTrkNum[2]; // numbers of the two decay tracks //Int_t fPdg[2]; // PDG codes of the two tracks (for sim.) //Int_t fMum[2]; // PDG codes of the mothers (for sim.) // ClassDef(AliAODRecoDecay,4) // base class for AOD reconstructed decays }; inline Short_t AliAODRecoDecay::ChargeProng(Int_t ip) const { if(fCharge==0 || fCharge==+1) { if(ip%2==0) { return (Short_t)1; } else { return (Short_t)-1; } } else { // fCharge==-1 if(ip%2==0) { return (Short_t)-1; } else { return (Short_t)1; } } } inline Double_t AliAODRecoDecay::RadiusSecVtx() const { return TMath::Sqrt(GetSecVtxX()*GetSecVtxX()+GetSecVtxY()*GetSecVtxY()); } inline void AliAODRecoDecay::GetSecondaryVtx(Double_t vtx[3]) const { GetSecondaryVtx()->GetPosition(vtx); return; } inline Double_t AliAODRecoDecay::Px() const { Double_t px=0.; for(Int_t i=0;iGetPosition(v); return Ct(pdg,v); } inline Double_t AliAODRecoDecay::CosPointingAngle(AliAODVertex *vtx1) const { Double_t v[3]; vtx1->GetPosition(v); return CosPointingAngle(v); } inline Double_t AliAODRecoDecay::CosPointingAngleXY(AliAODVertex *vtx1) const { Double_t v[3]; vtx1->GetPosition(v); return CosPointingAngleXY(v); } inline Double_t AliAODRecoDecay::ImpParXY(AliAODVertex *vtx1) const { Double_t v[3]; vtx1->GetPosition(v); return ImpParXY(v); } inline Double_t AliAODRecoDecay::PtProng(Int_t ip) const { return TMath::Sqrt(PxProng(ip)*PxProng(ip)+PyProng(ip)*PyProng(ip)); } inline Double_t AliAODRecoDecay::PProng(Int_t ip) const { return TMath::Sqrt(PtProng(ip)*PtProng(ip)+PzProng(ip)*PzProng(ip)); } inline Double_t AliAODRecoDecay::QlProngFlightLine(Int_t ip,AliAODVertex *vtx1) const { Double_t v[3]; vtx1->GetPosition(v); return QlProngFlightLine(ip,v); } inline Double_t AliAODRecoDecay::QtProngFlightLine(Int_t ip,AliAODVertex *vtx1) const { Double_t v[3]; vtx1->GetPosition(v); return QtProngFlightLine(ip,v); } inline void AliAODRecoDecay::SetDCAs(Int_t nDCA,Double_t *dca) { if(nDCA!=(GetNProngs()*(GetNProngs()-1)/2)) { printf("Wrong number of DCAs, must be nProngs*(nProngs-1)/2"); return; } if(fDCA) delete [] fDCA; fNDCA = nDCA; fDCA = new Double32_t[nDCA]; for(Int_t i=0;i