//-------------------------------------------------------------------------
#include <TRef.h>
+#include <TBits.h>
#include "AliVTrack.h"
#include "AliAODVertex.h"
#include "AliAODRedCov.h"
#include "AliAODPid.h"
+
+
+class AliVVertex;
class AliAODTrack : public AliVTrack {
enum AODTrkBits_t {
kIsDCA=BIT(14), // set if fPosition is the DCA and not the position of the first point
kUsedForVtxFit=BIT(15), // set if this track was used to fit the vertex it is attached to
- kUsedForPrimVtxFit=BIT(16) // set if this track was used to fit the primary vertex
+ kUsedForPrimVtxFit=BIT(16), // set if this track was used to fit the primary vertex
+ kIsTPCOnly=BIT(17), // set if this track is a SA TPC track constrained to the SPD vertex, needs to be skipped in any track loop to avoid double counting
+ kIsHybridITSTPC=BIT(18), // set if this track can be used as a hybrid track i.e. Gbobal tracks with certain slecetion plus the TPC constrained tracks that did not pass the selection
+ kIsHybridTPC=BIT(19) // for TPC tracks that have been selected with a combination of cuts involving the ITS, tracks without ITS information are taken from TPC only
};
enum AODTrkPID_t {
virtual Double_t Zv() const { return GetProdVertex() ? GetProdVertex()->GetZ() : -999.; }
virtual Bool_t XvYvZv(Double_t x[3]) const { x[0] = Xv(); x[1] = Yv(); x[2] = Zv(); return kTRUE; }
- Double_t Chi2perNDF() const { return fChi2perNDF; }
+ Double_t Chi2perNDF() const { return fChi2perNDF; }
+ UShort_t GetTPCNcls() const { return fTPCClusterMap.CountBits();}
virtual Double_t M() const { return M(GetMostProbablePID()); }
Double_t M(AODTrkPID_t pid) const;
virtual Short_t Charge() const {return fCharge; }
+ virtual Bool_t PropagateToDCA(const AliVVertex *vtx,
+ Double_t b, Double_t maxd, Double_t dz[2], Double_t covar[3]);
+
// PID
virtual const Double_t *PID() const { return fPID; }
AODTrkPID_t GetMostProbablePID() const;
Bool_t IsPrimaryCandidate() const;
Bool_t GetUsedForVtxFit() const { return TestBit(kUsedForVtxFit); }
Bool_t GetUsedForPrimVtxFit() const { return TestBit(kUsedForPrimVtxFit); }
-
+ Bool_t IsHybridITSTPC() const { return TestBit(kIsHybridITSTPC); }
+ Bool_t IsHybridTPC() const { return TestBit(kIsHybridTPC); }
+ Bool_t IsTPCOnly() const { return TestBit(kIsTPCOnly); }
+ //
+ Int_t GetTOFBunchCrossing() const;
+ //
template <class T> void GetP(T *p) const {
p[0]=fMomentum[0]; p[1]=fMomentum[1]; p[2]=fMomentum[2];}
- template <class T> void GetPxPyPz(T *p) const {
- p[0] = Px(); p[1] = Py(); p[2] = Pz();}
+// template <class T> void GetPxPyPz(T *p) const {
+// p[0] = Px(); p[1] = Py(); p[2] = Pz();}
+ Bool_t GetPxPyPz(Double_t *p) const;
template <class T> Bool_t GetPosition(T *x) const {
x[0]=fPosition[0]; x[1]=fPosition[1]; x[2]=fPosition[2];
if(!fCovMatrix) return kFALSE;
fCovMatrix->GetCovMatrix(covMatrix); return kTRUE;}
+ Bool_t GetXYZ(Double_t *p) const {
+ return GetPosition(p); }
+
Bool_t GetCovarianceXYZPxPyPz(Double_t cv[21]) const {
return GetCovMatrix(cv);}
Double_t PAtDCA() const { return TMath::Sqrt(PxAtDCA()*PxAtDCA() + PyAtDCA()*PyAtDCA() + PzAtDCA()*PzAtDCA()); }
Bool_t PxPyPzAtDCA(Double_t p[3]) const { p[0] = PxAtDCA(); p[1] = PyAtDCA(); p[2] = PzAtDCA(); return kTRUE; }
+ Double_t GetRAtAbsorberEnd() const { return fRAtAbsorberEnd; }
+
UChar_t GetITSClusterMap() const { return (UChar_t)(fITSMuonClusterMap&0xff); }
+ Int_t GetITSNcls() const;
+ Bool_t HasPointOnITSLayer(Int_t i) const { return TESTBIT(GetITSClusterMap(),i); }
UShort_t GetHitsPatternInTrigCh() const { return (UShort_t)((fITSMuonClusterMap&0xff00)>>8); }
UInt_t GetMUONClusterMap() const { return (fITSMuonClusterMap&0x3ff0000)>>16; }
UInt_t GetITSMUONClusterMap() const { return fITSMuonClusterMap; }
Bool_t TestFilterBit(UInt_t filterBit) const {return (Bool_t) ((filterBit & fFilterMap) != 0);}
+ Bool_t TestFilterMask(UInt_t filterMask) const {return (Bool_t) ((filterMask & fFilterMap) == filterMask);}
+ void SetFilterMap(UInt_t i){fFilterMap = i;}
+ UInt_t GetFilterMap(){return fFilterMap;}
+
+ const TBits& GetTPCClusterMap() const {return fTPCClusterMap;}
+ Float_t GetTPCClusterInfo(Int_t nNeighbours=3, Int_t type=0, Int_t row0=0, Int_t row1=159) const;
+
+ const TBits& GetTPCSharedMap() const {return fTPCSharedMap;}
+ void SetTPCClusterMap(const TBits amap) {fTPCClusterMap = amap;}
+ void SetTPCSharedMap(const TBits amap) {fTPCSharedMap = amap;}
+ void SetTPCPointsF(UShort_t findable){fTPCnclsF = findable;}
+
+ UShort_t GetTPCNclsF() const { return fTPCnclsF;}
+
+ //pid signal interface
+ Double_t GetITSsignal() const { return fDetPid?fDetPid->GetITSsignal():0.; }
+ Double_t GetTPCsignal() const { return fDetPid?fDetPid->GetTPCsignal():0.; }
+ UShort_t GetTPCsignalN() const { return fDetPid?fDetPid->GetTPCsignalN():0; }
+ Double_t GetTPCmomentum() const { return fDetPid?fDetPid->GetTPCmomentum():0.; }
+ Double_t GetTOFsignal() const { return fDetPid?fDetPid->GetTOFsignal():0.; }
+ void GetIntegratedTimes(Double_t *times) const {if (fDetPid) fDetPid->GetIntegratedTimes(times); }
+ Double_t GetTRDslice(Int_t plane, Int_t slice) const;
+ Double_t GetTRDmomentum(Int_t plane, Double_t */*sp*/=0x0) const;
+ void GetHMPIDpid(Double_t *p) const { if (fDetPid) fDetPid->GetHMPIDprobs(p); }
+
AliAODPid *GetDetPid() const { return fDetPid; }
AliAODVertex *GetProdVertex() const { return (AliAODVertex*)fProdVertex.GetObject(); }
void SetDCA(Double_t d, Double_t z);
void SetUsedForVtxFit(Bool_t used = kTRUE) { used ? SetBit(kUsedForVtxFit) : ResetBit(kUsedForVtxFit); }
void SetUsedForPrimVtxFit(Bool_t used = kTRUE) { used ? SetBit(kUsedForPrimVtxFit) : ResetBit(kUsedForPrimVtxFit); }
+ void SetIsHybridITSTPC(Bool_t hybrid = kTRUE) { hybrid ? SetBit(kIsHybridITSTPC) : ResetBit(kIsHybridITSTPC); }
+ void SetIsHybridTPC(Bool_t hybrid = kTRUE) { hybrid ? SetBit(kIsHybridTPC) : ResetBit(kIsHybridTPC); }
+ void SetIsTPCOnly(Bool_t b = kTRUE) { b ? SetBit(kIsTPCOnly) : ResetBit(kIsTPCOnly); }
- void SetOneOverPt(Double_t oneOverPt) { fMomentum[0] = oneOverPt; }
+ void SetOneOverPt(Double_t oneOverPt) { fMomentum[0] = 1. / oneOverPt; }
void SetPt(Double_t pt) { fMomentum[0] = pt; };
void SetPhi(Double_t phi) { fMomentum[1] = phi; }
void SetTheta(Double_t theta) { fMomentum[2] = theta; }
void SetXYAtDCA(Double_t x, Double_t y) {fPositionAtDCA[0] = x; fPositionAtDCA[1] = y;}
void SetPxPyPzAtDCA(Double_t pX, Double_t pY, Double_t pZ) {fMomentumAtDCA[0] = pX; fMomentumAtDCA[1] = pY; fMomentumAtDCA[2] = pZ;}
+ void SetRAtAbsorberEnd(Double_t r) { fRAtAbsorberEnd = r; }
+
void SetCharge(Short_t q) { fCharge = q; }
void SetChi2perNDF(Double_t chi2perNDF) { fChi2perNDF = chi2perNDF; }
// 2 Muon track match Low pt cut
// 3 Muon track match High pt cut
void SetMatchTrigger(Int_t MatchTrigger);
- Int_t MatchTrigger() const { return (GetMatchTrigger()>0)?1:0; } // Muon track matches trigger track
- Int_t MatchTriggerAnyPt() const { return (GetMatchTrigger()>0)?1:0; } // Muon track matches trigger track
- Int_t MatchTriggerLowPt() const { return (GetMatchTrigger()>1)?1:0; } // Muon track matches trigger track and passes Low pt cut
- Int_t MatchTriggerHighPt() const { return (GetMatchTrigger()>2)?1:0; } // Muon track matches trigger track and passes High pt cut
+ Bool_t MatchTrigger() const { return (GetMatchTrigger()>0); } // Muon track matches trigger track
+ Bool_t MatchTriggerLowPt() const { return (GetMatchTrigger()>1); } // Muon track matches trigger track and passes Low pt cut
+ Bool_t MatchTriggerHighPt() const { return (GetMatchTrigger()>2); } // Muon track matches trigger track and passes High pt cut
+ Bool_t MatchTriggerDigits() const; // Muon track matches trigger digits
Double_t GetChi2MatchTrigger() const { return fChi2MatchTrigger;}
void SetChi2MatchTrigger(Double_t Chi2MatchTrigger) {fChi2MatchTrigger = Chi2MatchTrigger; }
- Int_t HitsMT(Int_t istation, Int_t iplane, Option_t *cathode=0); // Check if track hits Muon chambers
- Int_t HitsMuonChamber(Int_t MuonChamber); // Check if track hits Muon chambers
+ Bool_t HitsMuonChamber(Int_t MuonChamber, Int_t cathode = -1) const; // Check if track hits Muon chambers
Bool_t IsMuonTrack() const { return (GetMUONClusterMap()>0) ? kTRUE : kFALSE; }
+
+ void Connected(Bool_t flag) {flag ? SETBIT(fITSMuonClusterMap,26) : CLRBIT(fITSMuonClusterMap,26);}
+ Bool_t IsConnected() const {return TESTBIT(fITSMuonClusterMap,26);}
void SetProdVertex(TObject *vertex) { fProdVertex = vertex; }
void SetType(AODTrk_t ttype) { fType=ttype; }
+
+ // Dummy
+ Int_t PdgCode() const {return 0;}
+
private :
// Momentum & position
Double32_t fMomentumAtDCA[3]; // momentum (px,py,pz) at DCA
Double32_t fPositionAtDCA[2]; // trasverse position (x,y) at DCA
+ Double32_t fRAtAbsorberEnd; // transverse position r at the end of the muon absorber
+
Double32_t fChi2perNDF; // chi2/NDF of momentum fit
Double32_t fChi2MatchTrigger; // chi2 of trigger/track matching
Double32_t fPID[10]; // [0.,1.,8] pointer to PID object
// (ITS: bit 1-8, muon trigger: bit 9-16, muon tracker: bit 17-26, muon match trigger: bit 31-32)
UInt_t fFilterMap; // filter information, one bit per set of cuts
+ TBits fTPCClusterMap; // Map of clusters, one bit per padrow; 1 if has a cluster on given padrow
+ TBits fTPCSharedMap; // Map of clusters, one bit per padrow; 1 if has a shared cluster on given padrow
+ UShort_t fTPCnclsF; // findable clusters
+
Short_t fID; // unique track ID, points back to the ESD track
Char_t fCharge; // particle charge
Char_t fType; // Track Type
-
+
AliAODRedCov<6> *fCovMatrix; // covariance matrix (x, y, z, px, py, pz)
AliAODPid *fDetPid; // more detailed or detector specific pid information
TRef fProdVertex; // vertex of origin
- ClassDef(AliAODTrack,8);
+ ClassDef(AliAODTrack, 13);
};
inline Bool_t AliAODTrack::IsPrimaryCandidate() const
}
}
+inline Int_t AliAODTrack::GetITSNcls() const
+{
+ // Number of points in ITS
+ Int_t n=0;
+ for(Int_t i=0;i<6;i++) if(HasPointOnITSLayer(i)) n++;
+ return n;
+}
+
#endif