delete fFriendTrack; fFriendTrack=new AliESDfriendTrack(*t);
// CKB
}
+ void ReleaseESDfriendTrack() { delete fFriendTrack; fFriendTrack=0; }
void AddCalibObject(TObject * object); // add calib object to the list
TObject * GetCalibObject(Int_t index); // return calib objct at given position
void MakeMiniESDtrack();
Double_t GetIntegratedLength() const {return fTrackLength;}
void GetIntegratedTimes(Double_t *times) const;
Double_t GetMass() const;
+ Double_t M() const { return GetMass(); }
+ Double_t E() const;
+ Double_t Y() const;
Bool_t GetConstrainedPxPyPz(Double_t *p) const {
if (!fCp) return kFALSE;
void SetITSpid(const Double_t *p);
void GetITSpid(Double_t *p) const;
- Float_t GetITSsignal() const {return fITSsignal;}
- Float_t GetITSchi2() const {return fITSchi2;}
- Int_t GetITSclusters(Int_t *idx) const;
+ Double_t GetITSsignal() const {return fITSsignal;}
+ Double_t GetITSchi2() const {return fITSchi2;}
+ Char_t GetITSclusters(Int_t *idx) const;
UChar_t GetITSClusterMap() const {return fITSClusterMap;}
Int_t GetITSLabel() const {return fITSLabel;}
void SetITStrack(AliKalmanTrack * track){
for (Int_t i=0;i<4;i++) fTPCPoints[i]=points[i];
}
void SetTPCPointsF(UChar_t findable){fTPCnclsF = findable;}
- Int_t GetTPCNcls() const { return fTPCncls;}
- Int_t GetTPCNclsF() const { return fTPCnclsF;}
- Float_t GetTPCPoints(Int_t i) const {return fTPCPoints[i];}
+ UShort_t GetTPCNcls() const { return fTPCncls;}
+ UShort_t GetTPCNclsF() const { return fTPCnclsF;}
+ Double_t GetTPCPoints(Int_t i) const {return fTPCPoints[i];}
void SetKinkIndexes(Int_t points[3]) {
for (Int_t i=0;i<3;i++) fKinkIndexes[i] = points[i];
}
void SetTPCsignal(Float_t signal, Float_t sigma, UChar_t npoints){
fTPCsignal = signal; fTPCsignalS = sigma; fTPCsignalN = npoints;
}
- Float_t GetTPCsignal() const {return fTPCsignal;}
- Float_t GetTPCsignalSigma() const {return fTPCsignalS;}
+ Double_t GetTPCsignal() const {return fTPCsignal;}
+ Double_t GetTPCsignalSigma() const {return fTPCsignalS;}
UShort_t GetTPCsignalN() const {return fTPCsignalN;}
- Float_t GetTPCchi2() const {return fTPCchi2;}
- Int_t GetTPCclusters(Int_t *idx) const;
- Float_t GetTPCdensity(Int_t row0, Int_t row1) const;
+ Double_t GetTPCchi2() const {return fTPCchi2;}
+ UShort_t GetTPCclusters(Int_t *idx) const;
+ Double_t GetTPCdensity(Int_t row0, Int_t row1) const;
Int_t GetTPCLabel() const {return fTPCLabel;}
Int_t GetKinkIndex(Int_t i) const { return fKinkIndexes[i];}
Int_t GetV0Index(Int_t i) const { return fV0Indexes[i];}
// end A.Bercuci
void SetTRDQuality(Float_t quality){fTRDQuality=quality;}
- Float_t GetTRDQuality()const {return fTRDQuality;}
+ Double_t GetTRDQuality()const {return fTRDQuality;}
void SetTRDBudget(Float_t budget){fTRDBudget=budget;}
- Float_t GetTRDBudget()const {return fTRDBudget;}
+ Double_t GetTRDBudget()const {return fTRDBudget;}
void SetTRDsignals(Float_t dedx, Int_t i, Int_t j) {fTRDsignals[i][j]=dedx;}
void SetTRDTimBin(Int_t timbin, Int_t i) {fTRDTimBin[i]=timbin;}
void GetTRDpid(Double_t *p) const;
- Float_t GetTRDsignal() const {return fTRDsignal;}
- Float_t GetTRDsignals(Int_t iPlane, Int_t iSlice=-1) const { if (iSlice == -1)
+ Double_t GetTRDsignal() const {return fTRDsignal;}
+ Double_t GetTRDsignals(Int_t iPlane, Int_t iSlice=-1) const { if (iSlice == -1)
return (fTRDsignals[iPlane][0] + fTRDsignals[iPlane][1] + fTRDsignals[iPlane][2])/3.0;
return fTRDsignals[iPlane][iSlice];
}
- Int_t GetTRDTimBin(Int_t i) const {return fTRDTimBin[i];}
- Float_t GetTRDchi2() const {return fTRDchi2;}
- Int_t GetTRDclusters(Int_t *idx) const;
- Int_t GetTRDncls() const {return fTRDncls;}
+ Char_t GetTRDTimBin(Int_t i) const {return fTRDTimBin[i];}
+ Double_t GetTRDchi2() const {return fTRDchi2;}
+ UChar_t GetTRDclusters(Int_t *idx) const;
+ UChar_t GetTRDncls() const {return fTRDncls;}
void SetTRDpid(Int_t iSpecies, Float_t p);
- Float_t GetTRDpid(Int_t iSpecies) const;
+ Double_t GetTRDpid(Int_t iSpecies) const;
Int_t GetTRDLabel() const {return fTRDLabel;}
void SetTRDtrack(AliKalmanTrack * track){
}
void SetTOFsignal(Double_t tof) {fTOFsignal=tof;}
- Float_t GetTOFsignal() const {return fTOFsignal;}
+ Double_t GetTOFsignal() const {return fTOFsignal;}
void SetTOFsignalToT(Double_t ToT) {fTOFsignalToT=ToT;}
- Float_t GetTOFsignalToT() const {return fTOFsignalToT;}
+ Double_t GetTOFsignalToT() const {return fTOFsignalToT;}
void SetTOFsignalRaw(Double_t tof) {fTOFsignalRaw=tof;}
- Float_t GetTOFsignalRaw() const {return fTOFsignalRaw;}
+ Double_t GetTOFsignalRaw() const {return fTOFsignalRaw;}
void SetTOFsignalDz(Double_t dz) {fTOFsignalDz=dz;}
- Float_t GetTOFsignalDz() const {return fTOFsignalDz;}
- Float_t GetTOFchi2() const {return fTOFchi2;}
+ Double_t GetTOFsignalDz() const {return fTOFsignalDz;}
+ Double_t GetTOFchi2() const {return fTOFchi2;}
void SetTOFpid(const Double_t *p);
void SetTOFLabel(const Int_t *p);
void GetTOFpid(Double_t *p) const;
// HMPID methodes +++++++++++++++++++++++++++++++++ (kir)
void SetHMPIDsignal(Double_t theta) {fHMPIDsignal=theta;}
- Float_t GetHMPIDsignal() const {return fHMPIDsignal;}
+ Double_t GetHMPIDsignal() const {return fHMPIDsignal;}
void SetHMPIDpid(const Double_t *p);
void GetHMPIDpid(Double_t *p) const;
void SetHMPIDchi2(Double_t chi2) {fHMPIDchi2=chi2;}
- Float_t GetHMPIDchi2() const {return fHMPIDchi2;}
- void SetHMPIDcluster(Int_t index) {fHMPIDcluIdx=index;}
- Int_t GetHMPIDcluster() const {return fHMPIDcluIdx;}
+ Double_t GetHMPIDchi2() const {return fHMPIDchi2;}
void SetHMPIDcluIdx(Int_t ch,Int_t idx) {fHMPIDcluIdx=ch*1000000+idx;}
Int_t GetHMPIDcluIdx() const {return fHMPIDcluIdx;}
void SetHMPIDtrk(Float_t x, Float_t y, Float_t th, Float_t ph) {
enum {
kNPlane = 6,
kNSlice = 3,
- kEMCALNoMatch = -999999999
+ kEMCALNoMatch = -4096
};
protected:
+ AliExternalTrackParam *fCp; // Track parameters constrained to the primary vertex
+ AliExternalTrackParam *fIp; // Track parameters at the first measured point (TPC)
+ AliExternalTrackParam *fTPCInner; // Track parameters at the first measured point (TPC) - first itteration
+ AliExternalTrackParam *fOp; // Track parameters at the last measured point (TPC or TRD)
+ AliESDfriendTrack *fFriendTrack; //! All the complementary information
- ULong_t fFlags; // Reconstruction status flags
- Int_t fLabel; // Track label
- Int_t fID; // Unique ID of the track
- Float_t fTrackLength; // Track length
- Float_t fD; // Impact parameter in XY plane
- Float_t fZ; // Impact parameter in Z
- Float_t fCdd,fCdz,fCzz; // Covariance matrix of the impact parameters
- Float_t fTrackTime[AliPID::kSPECIES]; // TOFs estimated by the tracking
- Float_t fR[AliPID::kSPECIES]; // combined "detector response probability"
+ 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
- Int_t fStopVertex; // Index of the stop vertex
- AliExternalTrackParam *fCp; // Track parameters constrained to the primary vertex
- Double32_t fCchi2; // chi2 at the primary vertex
+ ULong_t fFlags; // Reconstruction status flags
+ Int_t fID; // Unique ID of the track
+ Int_t fLabel; // Track label
+ Int_t fITSLabel; // label according TPC
+ Int_t fTPCLabel; // label according TPC
+ Int_t fTRDLabel; // label according TRD
+ Int_t fTOFLabel[3]; // TOF label
+ Int_t fTOFCalChannel; // Channel Index of the TOF Signal
+ Int_t fTOFindex; // index of the assigned TOF cluster
+ Int_t fHMPIDqn; // 1000000*QDC + number of photon clusters
+ Int_t fHMPIDcluIdx; // 1000000*chamber id + cluster idx of the assigned MIP cluster
+ Int_t fEMCALindex; // index of associated EMCAL cluster (AliESDCaloCluster)
- AliExternalTrackParam *fIp; // Track parameters at the first measured point (TPC)
- AliExternalTrackParam *fTPCInner; // Track parameters at the first measured point (TPC) - first itteration
+ Int_t fKinkIndexes[3]; // array of indexes of posible kink candidates
+ Int_t fV0Indexes[3]; // array of indexes of posible kink candidates
- AliExternalTrackParam *fOp; // Track parameters at the last measured point (TPC or TRD)
+ Double32_t fR[AliPID::kSPECIES]; //[0.,1.,8] combined "detector response probability"
+ Double32_t fITSr[AliPID::kSPECIES]; //[0.,1.,8] "detector response probabilities" (for the PID)
+ Double32_t fTPCr[AliPID::kSPECIES]; //[0.,1.,8] "detector response probabilities" (for the PID)
+ Double32_t fTRDr[AliPID::kSPECIES]; //[0.,1.,8] "detector response probabilities" (for the PID)
+ Double32_t fTOFr[AliPID::kSPECIES]; //[0.,1.,8] "detector response probabilities" (for the PID)
+ Double32_t fHMPIDr[AliPID::kSPECIES];//[0.,1.,8] "detector response probabilities" (for the PID)
+
+ Double32_t fHMPIDtrkTheta;//[-2*pi,2*pi,16] theta of the track extrapolated to the HMPID, LORS
+ // how much of this is needed?
+ Double32_t fHMPIDtrkPhi; //[-2*pi,2*pi,16] phi of the track extrapolated to the HMPID, LORS
+ Double32_t fHMPIDsignal; // HMPID PID signal (Theta ckov, rad)
+
+ Double32_t fTrackTime[AliPID::kSPECIES]; // TOFs estimated by the tracking
+ Double32_t fTrackLength; // Track length
+ Double32_t fD; // Impact parameter in XY plane
+ Double32_t fZ; // Impact parameter in Z
+ Double32_t fCdd,fCdz,fCzz; // Covariance matrix of the impact parameters
+
+ Double32_t fCchi2; // chi2 at the primary vertex
+ Double32_t fITSchi2; // chi2 in the ITS
+ Double32_t fTPCchi2; // chi2 in the TPC
+ Double32_t fTRDchi2; // chi2 in the TRD
+ Double32_t fTOFchi2; // chi2 in the TOF
+ Double32_t fHMPIDchi2; // chi2 in the HMPID
- // ITS related track information
- Float_t fITSchi2; // chi2 in the ITS
- Int_t fITSncls; // number of clusters assigned in the ITS
- UChar_t fITSClusterMap; // map of clusters, one bit per a layer
- Float_t fITSsignal; // detector's PID signal
- Float_t fITSr[AliPID::kSPECIES]; // "detector response probabilities" (for the PID)
- Int_t fITSLabel; // label according TPC
- // TPC related track information
- Float_t fTPCchi2; // chi2 in the TPC
- Int_t fTPCncls; // number of clusters assigned in the TPC
+ Double32_t fITSsignal; // detector's PID signal
+ Double32_t fTPCsignal; // detector's PID signal
+ Double32_t fTPCsignalS; // RMS of dEdx measurement
+ Double32_t fTPCPoints[4]; // TPC points -first, max. dens, last and max density
+
+ Double32_t fTRDsignal; // detector's PID signal
+ Double32_t fTRDsignals[kNPlane][kNSlice]; // TRD signals from all six planes in 3 slices each
+ Double32_t fTRDQuality; // trd quality factor for TOF
+ Double32_t fTRDBudget; // trd material budget
+
+ Double32_t fTOFsignal; // detector's PID signal
+ Double32_t fTOFsignalToT; // detector's ToT signal
+ Double32_t fTOFsignalRaw; // detector's uncorrected time signal
+ Double32_t fTOFsignalDz; // local z of track's impact on the TOF pad
+ Double32_t fTOFInfo[10]; //! TOF informations
+
+ Double32_t fHMPIDtrkX; // x of the track impact, LORS
+ Double32_t fHMPIDtrkY; // y of the track impact, LORS
+ Double32_t fHMPIDmipX; // x of the MIP in LORS
+ Double32_t fHMPIDmipY; // y of the MIP in LORS
+
+
+
+
+ UShort_t fTPCncls; // number of clusters assigned in the TPC
UShort_t fTPCnclsF; // number of findable clusters in the TPC
- 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
- Float_t fTPCsignal; // detector's PID signal
UShort_t fTPCsignalN; // number of points used for dEdx
- Float_t fTPCsignalS; // RMS of dEdx measurement
- Float_t fTPCr[AliPID::kSPECIES]; // "detector response probabilities" (for the PID)
- Int_t fTPCLabel; // label according TPC
- Float_t fTPCPoints[4]; // TPC points -first, max. dens, last and max density
- Int_t fKinkIndexes[3];// array of indexes of posible kink candidates
- Int_t fV0Indexes[3]; // array of indexes of posible kink candidates
-
- // TRD related track information
- Float_t fTRDchi2; // chi2 in the TRD
+
+ Char_t fITSncls; // number of clusters assigned in the ITS
+ UChar_t fITSClusterMap; // map of clusters, one bit per a layer
UChar_t fTRDncls; // number of clusters assigned in the TRD
UChar_t fTRDncls0; // number of clusters assigned in the TRD before first material cross
- Float_t fTRDsignal; // detector's PID signal
- Float_t fTRDsignals[kNPlane][kNSlice]; // TRD signals from all six planes in 3 slices each
- Int_t fTRDTimBin[kNPlane]; // Time bin of Max cluster from all six planes
- Float_t fTRDr[AliPID::kSPECIES]; // "detector response probabilities" (for the PID)
- // A.Bercuci
- UChar_t fTRDpidQuality; // TRD PID quality according to number of planes. 6 is the best
- Int_t fTRDLabel; // label according TRD
- Float_t fTRDQuality; // trd quality factor for TOF
- Float_t fTRDBudget; // trd material budget
-
-
- // TOF related track information
- Float_t fTOFchi2; // chi2 in the TOF
- Int_t fTOFindex; // index of the assigned TOF cluster
- Int_t fTOFCalChannel; // Channel Index of the TOF Signal
- Float_t fTOFsignal; // detector's PID signal
- Float_t fTOFsignalToT; // detector's ToT signal
- Float_t fTOFsignalRaw; // detector's uncorrected time signal
- Float_t fTOFsignalDz; // local z of track's impact on the TOF pad
- Float_t fTOFr[AliPID::kSPECIES]; // "detector response probabilities" (for the PID)
- Int_t fTOFLabel[3]; // TOF label
- Float_t fTOFInfo[10]; //! TOF informations
-
- // HMPID related track information (kir)
- Float_t fHMPIDchi2; // chi2 in the HMPID
- Int_t fHMPIDqn; // 1000000*QDC + number of photon clusters
- Int_t fHMPIDcluIdx; // 1000000*chamber id + cluster idx of the assigned MIP cluster
- Float_t fHMPIDsignal; // HMPID PID signal (Theta ckov, rad)
- Float_t fHMPIDr[AliPID::kSPECIES];// "detector response probabilities" (for the PID)
- Float_t fHMPIDtrkTheta; // theta of the track extrapolated to the HMPID, LORS
- Float_t fHMPIDtrkPhi; // phi of the track extrapolated to the HMPID, LORS
- Float_t fHMPIDtrkX; // x of the track impact, LORS
- Float_t fHMPIDtrkY; // y of the track impact, LORS
- Float_t fHMPIDmipX; // x of the MIP in LORS
- Float_t fHMPIDmipY; // y of the MIP in LORS
-
- // EMCAL related track information
- Int_t fEMCALindex; // index of associated EMCAL cluster (AliESDCaloCluster)
-
- AliESDfriendTrack *fFriendTrack; //! All the complementary information
+ UChar_t fTRDpidQuality; // TRD PID quality according to number of planes. 6 is the best
+ Char_t fTRDTimBin[kNPlane]; // Time bin of Max cluster from all six planes
private:
AliESDtrack & operator=(const AliESDtrack & ) {return *this;}
- ClassDef(AliESDtrack,39) //ESDtrack
+ ClassDef(AliESDtrack,40) //ESDtrack
};
#endif