+// -*- mode: C++ -*-
#ifndef ALIESD_H
#define ALIESD_H
/* Copyright(c) 1998-1999, ALICE Experiment at CERN, All rights reserved. *
* See cxx source for full Copyright notice */
-/* $Id$ */
-
-///////////////////////////////////////////////////////////////////////////////
-// //
-// Alice ESD object //
-// //
-///////////////////////////////////////////////////////////////////////////////
-
-#include "TObject.h"
-#include "TObjArray.h"
-#include "TArrayI.h"
-#include "TArrayF.h"
-#include "TArrayD.h"
-
-class AliESDTrack : public TObject
-{
-public:
- AliESDTrack();
- virtual ~AliESDTrack() {}
-
-protected:
- Int_t fTrackID; // Track number
- // Track parameters at Vertex
- TArrayD fPVertex; // (5) Track parameters
- TArrayD fPEVertex; // (15) Track parameter errors
-
- // Track parameters at first measured point
- TArrayD fPFMeasPoint; // (6) Track parameters
- TArrayD fPFMeasPointErr; // (15) Track parameter error
-
- // Track parameters at last measured point
- TArrayD fPLMeasPoint; // (6) Track parameters
- TArrayD fPLMeasPointErr; // (15) Track parameter error
-
- Float_t fTrackLength; // Track length
- Float_t fTrackLengthErr; // Track length error
- Int_t fStopVertex; // Index of stop vertex
-
- Int_t fNPointsITS; // Number of points in ITS
- Int_t fNPointsTPC; // Number of points in TPC
- Int_t fNPointsTRD; // Number of points in TRD
- Float_t fMeanResITS; // Mean residual in ITS
- Float_t fMeanResTPC; // Mean residual in TPC
- Float_t fMeanResTRD; // Mean residual in TRD
- Float_t fGlobalChi2; // Global chi square
- Int_t fParticleType; // PDG code
-
- Float_t fPIDprobPi; // PID probability for pi
- Float_t fPIDprobK; // PID probability for K
- Float_t fPIDprobP; // PID probability for p
- Float_t fPIDprobE; // PID probability for e
-
-private:
- AliESDTrack(const AliESDTrack & esdt);
- AliESDTrack & operator=(const AliESDTrack &) {return (*this);}
-
- ClassDef(AliESDTrack,1) //ESDTrack
-};
-
-
-class AliESDVertex : public TObject
-{
-public:
- AliESDVertex();
- virtual ~AliESDVertex() {}
-
-protected:
- Int_t fNPrimary; // Number of primary tracks
- TArrayF fCoordinates; // (3) Vertex coordinates
- TArrayF fErrorMatrix; // (6) Error Matrix
- TObjArray fPrimaryTracks; // List of primary tracks
- Float_t fEffectiveMass; // Effective Mass
- Float_t fEffectiveMassError; // Effective Mass Error
-private:
- AliESDVertex(const AliESDVertex & esdv);
- AliESDVertex & operator=(const AliESDVertex &) {return (*this);}
-
- ClassDef(AliESDVertex,1) //ESDVertex
-};
+/* $Id$ */
-class AliESD : public TObject
-{
+//-------------------------------------------------------------------------
+// Class AliESD
+// This is the class to deal with during the physical analysis of data
+//
+// Origin: Iouri Belikov, CERN, Jouri.Belikov@cern.ch
+//-------------------------------------------------------------------------
+
+#include <TClonesArray.h>
+#include <TObject.h>
+
+#include "AliESDMuonTrack.h"
+#include "AliESDPmdTrack.h"
+#include "AliESDTrdTrack.h"
+#include "AliESDVertex.h"
+#include "AliESDcascade.h"
+#include "AliESDkink.h"
+#include "AliESDtrack.h"
+#include "AliESDHLTtrack.h"
+#include "AliESDCaloCluster.h"
+#include "AliESDv0.h"
+#include "AliESDV0MI.h"
+#include "AliESDFMD.h"
+
+class AliESDfriend;
+
+class AliESD : public TObject {
public:
AliESD();
- virtual ~AliESD() {}
+ virtual ~AliESD();
- Int_t EventNumber() const {return fEventNumber;}
- Int_t RunNumber() const {return fRunNumber;}
- Long_t Trigger() const {return fTrigger;}
-
- Int_t BitDDL() const {return fBitDDL;}
- Int_t NSecVertex() const {return fNSecVertex;}
- Float_t NParticipants() const {return fNParticipants;}
+ void SetESDfriend(const AliESDfriend *f);
+ void GetESDfriend(AliESDfriend *f) const;
+
+ void SetEventNumber(Int_t n) {fEventNumber=n;}
+ void SetRunNumber(Int_t n) {fRunNumber=n;}
+ void SetTriggerMask(ULong64_t n) {fTriggerMask=n;}
+ void SetTriggerCluster(UChar_t n) {fTriggerCluster = n;}
+ void SetMagneticField(Float_t mf){fMagneticField = mf;}
+ Float_t GetMagneticField() const {return fMagneticField;}
+ AliESDtrack *GetTrack(Int_t i) const {
+ return (AliESDtrack *)fTracks.UncheckedAt(i);
+ }
+ AliESDHLTtrack *GetHLTConfMapTrack(Int_t i) const {
+ return (AliESDHLTtrack *)fHLTConfMapTracks.UncheckedAt(i);
+ }
+ AliESDHLTtrack *GetHLTHoughTrack(Int_t i) const {
+ return (AliESDHLTtrack *)fHLTHoughTracks.UncheckedAt(i);
+ }
+ AliESDMuonTrack *GetMuonTrack(Int_t i) const {
+ return (AliESDMuonTrack *)fMuonTracks.UncheckedAt(i);
+ }
+ AliESDPmdTrack *GetPmdTrack(Int_t i) const {
+ return (AliESDPmdTrack *)fPmdTracks.UncheckedAt(i);
+ }
+ AliESDTrdTrack *GetTrdTrack(Int_t i) const {
+ return (AliESDTrdTrack *)fTrdTracks.UncheckedAt(i);
+ }
+
+ Int_t AddTrack(const AliESDtrack *t) {
+ AliESDtrack * track = new(fTracks[fTracks.GetEntriesFast()]) AliESDtrack(*t);
+ track->SetID(fTracks.GetEntriesFast()-1);
+ return track->GetID();
+
+ }
+ void AddHLTConfMapTrack(const AliESDHLTtrack *t) {
+ new(fHLTConfMapTracks[fHLTConfMapTracks.GetEntriesFast()]) AliESDHLTtrack(*t);
+ }
+ void AddHLTHoughTrack(const AliESDHLTtrack *t) {
+ new(fHLTHoughTracks[fHLTHoughTracks.GetEntriesFast()]) AliESDHLTtrack(*t);
+ }
+ void AddMuonTrack(const AliESDMuonTrack *t) {
+ new(fMuonTracks[fMuonTracks.GetEntriesFast()]) AliESDMuonTrack(*t);
+ }
+ void AddPmdTrack(const AliESDPmdTrack *t) {
+ new(fPmdTracks[fPmdTracks.GetEntriesFast()]) AliESDPmdTrack(*t);
+ }
+ void AddTrdTrack(const AliESDTrdTrack *t) {
+ new(fTrdTracks[fTrdTracks.GetEntriesFast()]) AliESDTrdTrack(*t);
+ }
+
+ AliESDv0 *GetV0(Int_t i) const {
+ return (AliESDv0 *)fV0s.UncheckedAt(i);
+ }
+ void AddV0(const AliESDv0 *v) {
+ new(fV0s[fV0s.GetEntriesFast()]) AliESDv0(*v);
+ }
+ void UpdateV0PIDs();
+
+ AliESDcascade *GetCascade(Int_t i) const {
+ return (AliESDcascade *)fCascades.UncheckedAt(i);
+ }
+ void AddCascade(const AliESDcascade *c) {
+ new(fCascades[fCascades.GetEntriesFast()]) AliESDcascade(*c);
+ }
+
+ AliESDkink *GetKink(Int_t i) const {
+ return (AliESDkink *)fKinks.UncheckedAt(i);
+ }
+ Int_t AddKink(const AliESDkink *c) {
+ AliESDkink * kink = new(fKinks[fKinks.GetEntriesFast()]) AliESDkink(*c);
+ kink->SetID(fKinks.GetEntriesFast());
+ return fKinks.GetEntriesFast()-1;
+ }
+
+ AliESDV0MI *GetV0MI(Int_t i) const {
+ return (AliESDV0MI *)fV0MIs.UncheckedAt(i);
+ }
+ Int_t AddV0MI(const AliESDV0MI *c) {
+ AliESDV0MI * v0 = new(fV0MIs[fV0MIs.GetEntriesFast()]) AliESDV0MI(*c);
+ v0->SetID(fV0MIs.GetEntriesFast()-1);
+ return fV0MIs.GetEntriesFast()-1;
+ }
+
+ AliESDCaloCluster *GetCaloCluster(Int_t i) const {
+ return (AliESDCaloCluster *)fCaloClusters.UncheckedAt(i);
+ }
+ Int_t AddCaloCluster(const AliESDCaloCluster *c) {
+ AliESDCaloCluster *clus = new(fCaloClusters[fCaloClusters.GetEntriesFast()]) AliESDCaloCluster(*c);
+ clus->SetID(fCaloClusters.GetEntriesFast()-1);
+ return fCaloClusters.GetEntriesFast()-1;
+ }
+
+ void SetVertex(const AliESDVertex* vertex) {
+ fSPDVertex=new AliESDVertex(*vertex);
+ }
+ const AliESDVertex* GetVertex() const {return fSPDVertex;};
+
+ void SetPrimaryVertex(const AliESDVertex* vertex) {
+ fPrimaryVertex=new AliESDVertex(*vertex);
+ }
+ const AliESDVertex* GetPrimaryVertex() const {return fPrimaryVertex;};
+
+ Int_t GetEventNumber() const {return fEventNumber;}
+ Int_t GetRunNumber() const {return fRunNumber;}
+ ULong64_t GetTriggerMask() const {return fTriggerMask;}
+ UChar_t GetTriggerCluster() const {return fTriggerCluster;}
+ Int_t GetNumberOfTracks() const {return fTracks.GetEntriesFast();}
+ Int_t GetNumberOfHLTConfMapTracks() const {return fHLTConfMapTracks.GetEntriesFast();}
+ Int_t GetNumberOfHLTHoughTracks() const {return fHLTHoughTracks.GetEntriesFast();}
+ Int_t GetNumberOfMuonTracks() const {return fMuonTracks.GetEntriesFast();}
+ Int_t GetNumberOfPmdTracks() const {return fPmdTracks.GetEntriesFast();}
+ Int_t GetNumberOfTrdTracks() const {return fTrdTracks.GetEntriesFast();}
+ Int_t GetNumberOfV0s() const {return fV0s.GetEntriesFast();}
+ Int_t GetNumberOfCascades() const {return fCascades.GetEntriesFast();}
+ Int_t GetNumberOfKinks() const {return fKinks.GetEntriesFast();}
+ Int_t GetNumberOfV0MIs() const {return fV0MIs.GetEntriesFast();}
+ Int_t GetNumberOfCaloClusters() const {return fCaloClusters.GetEntriesFast();}
+
+ Int_t GetNumberOfEMCALClusters() const {return fEMCALClusters;}
+ void SetNumberOfEMCALClusters(Int_t clus) {fEMCALClusters = clus;}
+ Int_t GetFirstEMCALCluster() const {return fFirstEMCALCluster;}
+ void SetFirstEMCALCluster(Int_t index) {fFirstEMCALCluster = index;}
+
+ Int_t GetNumberOfPHOSClusters() const {return fPHOSClusters;}
+ void SetNumberOfPHOSClusters(Int_t part) { fPHOSClusters = part ; }
+ void SetFirstPHOSCluster(Int_t index) { fFirstPHOSCluster = index ; }
+ Int_t GetFirstPHOSCluster() const { return fFirstPHOSCluster ; }
+
+ Float_t GetT0zVertex() const {return fT0zVertex;}
+ void SetT0zVertex(Float_t z) {fT0zVertex=z;}
+ Float_t GetT0() const {return fT0timeStart;}
+ void SetT0(Float_t timeStart) {fT0timeStart = timeStart;}
+ const Float_t * GetT0time() const {return fT0time;}
+ void SetT0time(Float_t time[24]) {
+ for (Int_t i=0; i<24; i++) fT0time[i] = time[i];
+ }
+ const Float_t * GetT0amplitude() const {return fT0amplitude;}
+ void SetT0amplitude(Float_t amp[24]) {
+ for (Int_t i=0; i<24; i++) fT0amplitude[i] = amp[i];
+ }
+
+ Float_t GetZDCN1Energy() const {return fZDCN1Energy;}
+ Float_t GetZDCP1Energy() const {return fZDCP1Energy;}
+ Float_t GetZDCN2Energy() const {return fZDCN2Energy;}
+ Float_t GetZDCP2Energy() const {return fZDCP2Energy;}
+ Float_t GetZDCEMEnergy() const {return fZDCEMEnergy;}
+ Int_t GetZDCParticipants() const {return fZDCParticipants;}
+ void SetZDC(Float_t n1Energy, Float_t p1Energy, Float_t emEnergy,
+ Float_t n2Energy, Float_t p2Energy, Int_t participants)
+ {fZDCN1Energy=n1Energy; fZDCP1Energy=p1Energy; fZDCEMEnergy=emEnergy;
+ fZDCN2Energy=n2Energy; fZDCP2Energy=p2Energy; fZDCParticipants=participants;}
+
+ void ResetV0s() { fV0s.Clear(); }
+ void ResetCascades() { fCascades.Clear(); }
+ void Reset();
+
+ void Print(Option_t *option="") const;
+
+ void SetFMDData(AliESDFMD * obj) {
+ fESDFMD = new AliESDFMD(*obj);
+ }
+
+ AliESDFMD * GetFMDData(){ return fESDFMD;}
+
protected:
// Event Identification
- Int_t fEventNumber; // Event Number
- Int_t fRunNumber; // Run Number
- Long_t fTrigger; // Trigger Type (cfg Transverse Energy&Max trans ch mom)
- Int_t fRecoVersion; // Version of reconstruction
-
- // Summary Information
- Int_t fBitDDL; // Bitmap of active DDL
- Int_t fNSecVertex; // Number of Secondary Vertexes
- Float_t fNParticipants; // Estimated Number of participants
- Float_t fNPartError; // N of participant error
- Int_t fNElectron; // N of electrons
- Int_t fNMuons; // N of muons
- Int_t fNPions; // N of pions
- Int_t fNKaons; // N of kaons
- Int_t fNProtons; // N of protons
- Int_t fNPHOSPhotons; // N of photons in PHOS
- Int_t fNPHOSNeutrons; // N of neutrons in PHOS
- Int_t fNPHOSCCluster; // N of charged clusters in PHOS
- Int_t fNEMCALCluster; // N of clusters in EMCAL
- Int_t fNPMDCluster; // N of clusters in PMD
- Float_t fTMaxClusterEnergy; // Transverse energy of biggest cluster
- Float_t fTMaxPCharged; // Biggest transverse momentum of charged particles
- TArrayI fNCharged; // Charged Multiplicity
- Float_t fTotTranEnergy; // Total transverse energy
-
- // Primary Vertex Object
- AliESDVertex fESDVertex; // Primary Vertex Object
- TObjArray fSecVertex; // List secondary vertexes
- TObjArray fNonAssTrack; // List of non assigned tracks
- TObjArray fPhoton; // List of photons
- TObjArray fNeutron; // List of neutrons
- TObjArray fEMCALCluster; // List of EMCAL clusters
- TObjArray fPMDCluster; // List of PMD clusters
-
-private:
- AliESD(const AliESD &);
- AliESD & operator=(const AliESD &) {return (*this);}
-
- ClassDef(AliESD,1) //ESD
+ Int_t fEventNumber; // Event Number
+ Int_t fRunNumber; // Run Number
+ ULong64_t fTriggerMask; // Trigger Type (mask)
+ UChar_t fTriggerCluster; // Trigger cluster (mask)
+ Int_t fRecoVersion; // Version of reconstruction
+ Float_t fMagneticField; // Solenoid Magnetic Field in kG : for compatibility with AliMagF
+
+ Float_t fZDCN1Energy; // reconstructed energy in the neutron ZDC
+ Float_t fZDCP1Energy; // reconstructed energy in the proton ZDC
+ Float_t fZDCN2Energy; // reconstructed energy in the neutron ZDC
+ Float_t fZDCP2Energy; // reconstructed energy in the proton ZDC
+ Float_t fZDCEMEnergy; // reconstructed energy in the electromagnetic ZDC
+ Int_t fZDCParticipants; // number of participants estimated by the ZDC
+
+ Float_t fT0zVertex; // vertex z position estimated by the START
+ AliESDVertex *fSPDVertex; // Primary vertex estimated by the SPD
+ AliESDVertex *fPrimaryVertex; // Primary vertex estimated using ESD tracks
+
+ Float_t fT0timeStart; // interaction time estimated by the START
+ Float_t fT0time[24]; // best TOF on each START PMT
+ Float_t fT0amplitude[24]; // number of particles(MIPs) on each START PMT
+
+ TClonesArray fTracks; // ESD tracks
+ TClonesArray fHLTConfMapTracks;// HLT ESD tracks from Conformal Mapper method
+ TClonesArray fHLTHoughTracks; // HLT ESD tracks from Hough Transform method
+ TClonesArray fMuonTracks; // MUON ESD tracks
+ TClonesArray fPmdTracks; // PMD ESD tracks
+ TClonesArray fTrdTracks; // TRD ESD tracks (triggered)
+ TClonesArray fV0s; // V0 vertices
+ TClonesArray fCascades; // Cascade vertices
+ TClonesArray fKinks; // Kinks
+ TClonesArray fV0MIs; // V0MI
+ TClonesArray fCaloClusters; // Calorimeter clusters for PHOS/EMCAL
+ Int_t fEMCALClusters; // Number of EMCAL clusters (subset of caloclusters)
+ Int_t fFirstEMCALCluster; // First EMCAL cluster in the fCaloClusters list
+
+ Int_t fPHOSClusters; // Number of PHOS clusters (subset of caloclusters)
+ Int_t fFirstPHOSCluster; // First PHOS cluster in the fCaloClusters list
+
+ AliESDFMD * fESDFMD; // FMD object containing rough multiplicity
+
+ ClassDef(AliESD,11) //ESD class
};
-
#endif