#ifndef AliEmcalJet_H #define AliEmcalJet_H #include #include #include #include #include #include #include #include #include "AliVParticle.h" #include "AliVCluster.h" #include "AliVEvent.h" class AliEmcalJet : public AliVParticle { public: enum EFlavourTag{ kDStar = 1<<0, kD0 = 1<<1, kSig1 = 1<<2, kSig2 = 1<<3, kBckgrd1 = 1<<4, kBckgrd2 = 1<<5, kBckgrd3 = 1<<6 //..... }; AliEmcalJet(); AliEmcalJet(Double_t px, Double_t py, Double_t pz); AliEmcalJet(Double_t pt, Double_t eta, Double_t phi, Double_t m); AliEmcalJet(const AliEmcalJet &jet); AliEmcalJet& operator=(const AliEmcalJet &jet); Double_t Px() const { return fPt*TMath::Cos(fPhi); } Double_t Py() const { return fPt*TMath::Sin(fPhi); } Double_t Pz() const { return fPt*TMath::SinH(fEta); } Double_t Pt() const { return fPt; } Double_t P() const { return fPt*TMath::CosH(fEta); } Bool_t PxPyPz(Double_t p[3]) const { p[0]=Px();p[1]=Py();p[2]=Pz(); return 1; } Double_t Xv() const { return 0.; } Double_t Yv() const { return 0.; } Double_t Zv() const { return 0.; } Bool_t XvYvZv(Double_t x[3]) const { x[0]=0;x[1]=0;x[2]=0; return 1; } Double_t OneOverPt() const { return 1./fPt; } Double_t Phi() const { return fPhi; } Double_t Theta() const { return 2*TMath::ATan(TMath::Exp(-fEta)); } Double_t E() const { Double_t p=P(); return TMath::Sqrt(M()*M()+p*p); } Double_t M() const { return fM; } Double_t Eta() const { return fEta; } Double_t Y() const { return 0.5*TMath::Log((E()+Pz())/(E()-Pz())); } Short_t Charge() const { return 0; } Int_t GetLabel() const { return fLabel; } Int_t PdgCode() const { return 0; } const Double_t *PID() const { return 0; } void GetMom(TLorentzVector &vec) const; void Print(Option_t* option = "") const; Double_t Area() const { return fArea; } Double_t AreaPt() const { return fArea; } Double_t AreaEta() const { return fAreaEta; } Double_t AreaPhi() const { return fAreaPhi; } Double_t AreaEmc() const { return fAreaEmc; } Bool_t AxisInEmcal() const { return fAxisInEmcal; } Int_t Compare(const TObject* obj) const; Short_t ClusterAt(Int_t idx) const { return fClusterIDs.At(idx); } AliVCluster *ClusterAt(Int_t idx, TClonesArray *ca) const { if (!ca) return 0; return dynamic_cast(ca->At(ClusterAt(idx))); } AliVCluster *GetLeadingCluster(TClonesArray *clusters) const; UShort_t GetNumberOfClusters() const { return fClusterIDs.GetSize(); } UShort_t GetNumberOfTracks() const { return fTrackIDs.GetSize(); } UShort_t GetNumberOfConstituents() const { return GetNumberOfClusters()+GetNumberOfTracks(); } Double_t FracEmcalArea() const { return fAreaEmc/fArea; } Bool_t IsInsideEmcal() const { return (fAreaEmc/fArea>0.999); } Bool_t IsInEmcal() const { return (fAreaEmc>0); } Bool_t IsMC() const { return (Bool_t)(MCPt() > 0); } Bool_t IsSortable() const { return kTRUE; } Double_t MaxNeutralPt() const { return fMaxNPt; } Double_t MaxChargedPt() const { return fMaxCPt; } Double_t NEF() const { return fNEF; } UShort_t Nn() const { return fNn; } UShort_t Nch() const { return fNch; } UShort_t N() const { return Nch()+Nn(); } Int_t NEmc() const { return fNEmc; } Double_t MCPt() const { return fMCPt; } Double_t MaxClusterPt() const { return MaxNeutralPt(); } Double_t MaxTrackPt() const { return MaxChargedPt(); } Double_t MaxPartPt() const { return fMaxCPt < fMaxNPt ? fMaxNPt : fMaxCPt; } Double_t PtEmc() const { return fPtEmc; } Double_t PtSub() const { return fPtSub; } Double_t PtSub(Double_t rho) const { return fPt - fArea*rho; } Double_t PtSubVect(Double_t rho) const; Short_t TrackAt(Int_t idx) const { return fTrackIDs.At(idx); } AliVParticle *TrackAt(Int_t idx, TClonesArray *ta) const { if (!ta) return 0; return dynamic_cast(ta->At(TrackAt(idx))); } AliVParticle *GetLeadingTrack(TClonesArray *tracks) const; Int_t GetFlavour() const { return fFlavourTagging; } void AddClusterAt(Int_t clus, Int_t idx){ fClusterIDs.AddAt(clus, idx); } void AddFlavourTag(Int_t tag) { fFlavourTagging |= tag; } void AddTrackAt(Int_t track, Int_t idx) { fTrackIDs.AddAt(track, idx); } void Clear(Option_t */*option*/="") { fClusterIDs.Set(0); fTrackIDs.Set(0); fClosestJets[0] = 0; fClosestJets[1] = 0; fClosestJetsDist[0] = 0; fClosestJetsDist[1] = 0; fMatched = 0; fPtSub = 0; } Double_t DeltaR(const AliVParticle* part) const; void SetLabel(Int_t l) { fLabel = l; } void SetArea(Double_t a) { fArea = a; } void SetAreaEta(Double_t a) { fAreaEta = a; } void SetAreaPhi(Double_t a) { fAreaPhi = a; } void SetAreaEmc(Double_t a) { fAreaEmc = a; } void SetAxisInEmcal(Bool_t b) { fAxisInEmcal = b; } void SetFlavour(Int_t flavour) { fFlavourTagging = flavour; } void SetMaxNeutralPt(Double32_t t) { fMaxNPt = t; } void SetMaxChargedPt(Double32_t t) { fMaxCPt = t; } void SetNEF(Double_t nef) { fNEF = nef; } void SetNumberOfClusters(Int_t n) { fClusterIDs.Set(n); } void SetNumberOfTracks(Int_t n) { fTrackIDs.Set(n); } void SetNumberOfCharged(Int_t n) { fNch = n; } void SetNumberOfNeutrals(Int_t n) { fNn = n; } void SetMCPt(Double_t p) { fMCPt = p; } void SortConstituents(); std::vector SortConstituentsPt(TClonesArray *tracks) const; void SetNEmc(Int_t n) { fNEmc = n; } void SetPtEmc(Double_t pt) { fPtEmc = pt; } void SetPtSub(Double_t ps) { fPtSub = ps; } void SetPtSubVect(Double_t ps) { fPtVectSub = ps; } Bool_t TestFlavourTag(Int_t tag) { return (Bool_t)((tag & fFlavourTagging) !=0); } // Trigger Bool_t IsTriggerJet(UInt_t trigger=AliVEvent::kEMCEJE) const { return (Bool_t)((fTriggers & trigger) != 0); } void SetTrigger(UInt_t trigger) { fTriggers = trigger; } void AddTrigger(UInt_t trigger) { fTriggers |= trigger; } // Matching void SetClosestJet(AliEmcalJet *j, Double_t d) { fClosestJets[0] = j; fClosestJetsDist[0] = d ; } void SetSecondClosestJet(AliEmcalJet *j, Double_t d) { fClosestJets[1] = j; fClosestJetsDist[1] = d ; } void SetMatchedToClosest(UShort_t m) { fMatched = 0; fMatchingType = m ; } void SetMatchedToSecondClosest(UShort_t m) { fMatched = 1; fMatchingType = m ; } void ResetMatching(); AliEmcalJet* ClosestJet() const { return fClosestJets[0] ; } Double_t ClosestJetDistance() const { return fClosestJetsDist[0] ; } AliEmcalJet* SecondClosestJet() const { return fClosestJets[1] ; } Double_t SecondClosestJetDistance() const { return fClosestJetsDist[1] ; } AliEmcalJet* MatchedJet() const { return fMatched < 2 ? fClosestJets[fMatched] : 0; } UShort_t GetMatchingType() const { return fMatchingType ; } void SetTaggedJet(AliEmcalJet *j) { fTaggedJet = j ; } void SetTagStatus(Int_t i) { fTagStatus = i ; } AliEmcalJet* GetTaggedJet() const { return fTaggedJet ; } Int_t GetTagStatus() const { return fTagStatus ; } //jet shape derivatives //jet mass void SetFirstDerivative(Double_t d) { fJetShapeMassFirstDer = d ; } void SetSecondDerivative(Double_t d) { fJetShapeMassSecondDer = d ; } void SetFirstOrderSubtracted(Double_t d) { fJetShapeMassFirstSub = d ; } void SetSecondOrderSubtracted(Double_t d) { fJetShapeMassSecondSub = d ; } Double_t GetFirstDerivative() const { return fJetShapeMassFirstDer ; } Double_t GetSecondDerivative() const { return fJetShapeMassSecondDer ; } Double_t GetFirstOrderSubtracted() const { return fJetShapeMassFirstSub ; } Double_t GetSecondOrderSubtracted() const { return fJetShapeMassSecondSub ; } //jet structure function TArrayF GetGRNumerator() const { return fGRNumerator ; } TArrayF GetGRDenominator() const { return fGRDenominator ; } TArrayF GetGRNumeratorSub() const { return fGRNumeratorSub ; } TArrayF GetGRDenominatorSub() const { return fGRDenominatorSub ; } void AddGRNumAt(Float_t num, Int_t idx) { fGRNumerator.AddAt(num, idx) ; } void AddGRDenAt(Float_t den, Int_t idx) { fGRDenominator.AddAt(den, idx) ; } void SetGRNumSize(UInt_t s) { fGRNumerator.Set(s) ; } void SetGRDenSize(UInt_t s) { fGRDenominator.Set(s) ; } void AddGRNumSubAt(Float_t num, Int_t idx) { fGRNumeratorSub.AddAt(num, idx) ; } void AddGRDenSubAt(Float_t den, Int_t idx) { fGRDenominatorSub.AddAt(den, idx) ; } void SetGRNumSubSize(UInt_t s) { fGRNumeratorSub.Set(s) ; } void SetGRDenSubSize(UInt_t s) { fGRDenominatorSub.Set(s) ; } void PrintGR(); //Angularity void SetFirstDerivativeAngularity(Double_t d) { fJetShapeAngularityFirstDer = d ; } void SetSecondDerivativeAngularity(Double_t d) { fJetShapeAngularitySecondDer = d ; } void SetFirstOrderSubtractedAngularity(Double_t d) { fJetShapeAngularityFirstSub = d ; } void SetSecondOrderSubtractedAngularity(Double_t d) { fJetShapeAngularitySecondSub = d ; } Double_t GetFirstDerivativeAngularity() const { return fJetShapeAngularityFirstDer ; } Double_t GetSecondDerivativeAngularity() const { return fJetShapeAngularitySecondDer ; } Double_t GetFirstOrderSubtractedAngularity() const { return fJetShapeAngularityFirstSub ; } Double_t GetSecondOrderSubtractedAngularity() const { return fJetShapeAngularitySecondSub ; } //pTD void SetFirstDerivativepTD(Double_t d) { fJetShapepTDFirstDer = d ; } void SetSecondDerivativepTD(Double_t d) { fJetShapepTDSecondDer = d ; } void SetFirstOrderSubtractedpTD(Double_t d) { fJetShapepTDFirstSub = d ; } void SetSecondOrderSubtractedpTD(Double_t d) { fJetShapepTDSecondSub = d ; } Double_t GetFirstDerivativepTD() const { return fJetShapepTDFirstDer ; } Double_t GetSecondDerivativepTD() const { return fJetShapepTDSecondDer ; } Double_t GetFirstOrderSubtractedpTD() const { return fJetShapepTDFirstSub ; } Double_t GetSecondOrderSubtractedpTD() const { return fJetShapepTDSecondSub ; } //Circularity void SetFirstDerivativeCircularity(Double_t d) { fJetShapeCircularityFirstDer = d ; } void SetSecondDerivativeCircularity(Double_t d) { fJetShapeCircularitySecondDer = d ; } void SetFirstOrderSubtractedCircularity(Double_t d) { fJetShapeCircularityFirstSub = d ; } void SetSecondOrderSubtractedCircularity(Double_t d) { fJetShapeCircularitySecondSub = d ; } Double_t GetFirstDerivativeCircularity() const { return fJetShapeCircularityFirstDer ; } Double_t GetSecondDerivativeCircularity() const { return fJetShapeCircularitySecondDer ; } Double_t GetFirstOrderSubtractedCircularity() const { return fJetShapeCircularityFirstSub ; } Double_t GetSecondOrderSubtractedCircularity() const { return fJetShapeCircularitySecondSub ; } //number of contituents void SetFirstDerivativeConstituent(Double_t d) { fJetShapeConstituentFirstDer = d ; } void SetSecondDerivativeConstituent(Double_t d) { fJetShapeConstituentSecondDer = d ; } void SetFirstOrderSubtractedConstituent(Double_t d) { fJetShapeConstituentFirstSub = d ; } void SetSecondOrderSubtractedConstituent(Double_t d) { fJetShapeConstituentSecondSub = d ; } Double_t GetFirstDerivativeConstituent() const { return fJetShapeConstituentFirstDer ; } Double_t GetSecondDerivativeConstituent() const { return fJetShapeConstituentSecondDer ; } Double_t GetFirstOrderSubtractedConstituent() const { return fJetShapeConstituentFirstSub ; } Double_t GetSecondOrderSubtractedConstituent() const { return fJetShapeConstituentSecondSub ; } //leading minus subleading constituent void SetFirstDerivativeLeSub(Double_t d) { fJetShapeLeSubFirstDer = d ; } void SetSecondDerivativeLeSub(Double_t d) { fJetShapeLeSubSecondDer = d ; } void SetFirstOrderSubtractedLeSub(Double_t d) { fJetShapeLeSubFirstSub = d ; } void SetSecondOrderSubtractedLeSub(Double_t d) { fJetShapeLeSubSecondSub = d ; } Double_t GetFirstDerivativeLeSub() const { return fJetShapeLeSubFirstDer ; } Double_t GetSecondDerivativeLeSub() const { return fJetShapeLeSubSecondDer ; } Double_t GetFirstOrderSubtractedLeSub() const { return fJetShapeLeSubFirstSub ; } Double_t GetSecondOrderSubtractedLeSub() const { return fJetShapeLeSubSecondSub ; } protected: Double32_t fPt; //[0,0,12] pt Double32_t fEta; //[-1,1,12] eta Double32_t fPhi; //[0,6.3,12] phi Double32_t fM; //[0,0,8] mass Double32_t fNEF; //[0,1,8] neutral energy fraction Double32_t fArea; //[0,0,12] area Double32_t fAreaEta; //[0,0,12] area eta Double32_t fAreaPhi; //[0,0,12] area phi Double32_t fAreaEmc; //[0,0,12] area on EMCAL surface (determined from ghosts) Bool_t fAxisInEmcal; // =true if jet axis inside EMCAL acceptance Int_t fFlavourTagging; // tag jet with a falvour, bit 0 = no tag; bit 1= Dstar; bit 2 = D0 Double32_t fMaxCPt; //[0,0,12] pt of maximum charged constituent Double32_t fMaxNPt; //[0,0,12] pt of maximum neutral constituent Double32_t fMCPt; // pt from MC particles contributing to the jet Int_t fNn; // number of neutral constituents Int_t fNch; // number of charged constituents Double32_t fPtEmc; //[0,0,12] pt in EMCAL acceptance Int_t fNEmc; // number of constituents in EMCAL acceptance TArrayI fClusterIDs; // array containing ids of cluster constituents TArrayI fTrackIDs; // array containing ids of track constituents AliEmcalJet *fClosestJets[2]; //! if this is MC it contains the two closest detector level jets in order of distance and viceversa Double32_t fClosestJetsDist[2]; //! distance to closest jets (see above) UShort_t fMatched; //! 0,1 if it is matched with one of the closest jets; 2 if it is not matched UShort_t fMatchingType; //! matching type AliEmcalJet *fTaggedJet; //! jet tagged to this jet Int_t fTagStatus; //! status of tagging -1: NA 0: not tagged 1: tagged Double_t fPtSub; //! background subtracted pt (not stored set from outside) Double_t fPtVectSub; //! background vector subtracted pt (not stored set from outside) UInt_t fTriggers; //! triggers that the jet might have fired (AliVEvent::EOfflineTriggerTypes) Double_t fJetShapeMassFirstDer; //! result from shape derivatives for jet mass: 1st derivative Double_t fJetShapeMassSecondDer; //! result from shape derivatives for jet mass: 2nd derivative Double_t fJetShapeMassFirstSub; //! result from shape derivatives for jet mass: 1st order subtracted Double_t fJetShapeMassSecondSub; //! result from shape derivatives for jet mass: 2nd order subtracted Int_t fLabel; // label to inclusive jet for constituent subtracted jet TArrayF fGRNumerator; //! array with angular structure function numerator TArrayF fGRDenominator; //! array with angular structure function denominator TArrayF fGRNumeratorSub; //! array with angular structure function numerator TArrayF fGRDenominatorSub; //! array with angular structure function denominator Double_t fJetShapeAngularityFirstDer; //! result from shape derivatives for jet Angularity: 1st derivative Double_t fJetShapeAngularitySecondDer; //! result from shape derivatives for jet Angularity: 2nd derivative Double_t fJetShapeAngularityFirstSub; //! result from shape derivatives for jet Angularity: 1st order subtracted Double_t fJetShapeAngularitySecondSub; //! result from shape derivatives for jet Angularity: 2nd order subtracted Double_t fJetShapepTDFirstDer; //! result from shape derivatives for jet pTD: 1st derivative Double_t fJetShapepTDSecondDer; //! result from shape derivatives for jet pTD: 2nd derivative Double_t fJetShapepTDFirstSub; //! result from shape derivatives for jet pTD: 1st order subtracted Double_t fJetShapepTDSecondSub; //! result from shape derivatives for jet pTD: 2nd order subtracted Double_t fJetShapeCircularityFirstDer; //! result from shape derivatives for jet circularity: 1st derivative Double_t fJetShapeCircularitySecondDer; //! result from shape derivatives for jet circularity: 2nd derivative Double_t fJetShapeCircularityFirstSub; //! result from shape derivatives for jet circularity: 1st order subtracted Double_t fJetShapeCircularitySecondSub; //! result from shape derivatives for jetcircularity: 2nd order subtracted Double_t fJetShapeConstituentFirstDer; //! result from shape derivatives for jet const: 1st derivative Double_t fJetShapeConstituentSecondDer; //! result from shape derivatives for jet const: 2nd derivative Double_t fJetShapeConstituentFirstSub; //! result from shape derivatives for jet const: 1st order subtracted Double_t fJetShapeConstituentSecondSub; //! result from shape derivatives for jet const: 2nd order subtracted Double_t fJetShapeLeSubFirstDer; //! result from shape derivatives for jet LeSub: 1st derivative Double_t fJetShapeLeSubSecondDer; //! result from shape derivatives for jet LeSub: 2nd derivative Double_t fJetShapeLeSubFirstSub; //! result from shape derivatives for jet LeSub: 1st order subtracted Double_t fJetShapeLeSubSecondSub; //! result from shape derivatives for jet LeSub: 2nd order subtracted private: struct sort_descend { // sort in decreasing order // first value of the pair is Pt and the second is entry index bool operator () (const std::pair& p1, const std::pair& p2) { return p1.first > p2.first ; } }; ClassDef(AliEmcalJet,15) // Emcal jet class in cylindrical coordinates }; #endif