4 /* Copyright(c) 1998-1999, ALICE Experiment at CERN, All rights reserved. *
5 * See cxx source for full Copyright notice */
8 /* $Id: AliESD.h 52237 2011-10-20 19:26:08Z hristov $ */
10 //-------------------------------------------------------------------------
12 // This is the class to deal with during the physical analysis of data
14 // Origin: Iouri Belikov, CERN, Jouri.Belikov@cern.ch
15 //-------------------------------------------------------------------------
17 #include <TClonesArray.h>
21 #include "AliESDMuonTrack.h"
22 #include "AliESDPmdTrack.h"
23 #include "AliESDTrdTrack.h"
24 #include "AliESDVertex.h"
25 #include "AliESDcascade.h"
26 #include "AliESDkink.h"
27 #include "AliESDtrack.h"
28 #include "AliESDHLTtrack.h"
29 #include "AliESDCaloCluster.h"
31 #include "AliESDFMD.h"
32 #include "AliESDVZERO.h"
33 #include "AliMultiplicity.h"
34 #include "AliRawDataErrorLog.h"
35 #include "AliESDACORDE.h"
40 class AliESD : public TObject {
43 AliESD(const AliESD&);
46 void SetESDfriend(const AliESDfriend *f);
47 void GetESDfriend(AliESDfriend *f) const;
49 void SetEventNumberInFile(Int_t n) {fEventNumberInFile=n;}
50 void SetBunchCrossNumber(UShort_t n) {fBunchCrossNumber=n;}
51 void SetOrbitNumber(UInt_t n) {fOrbitNumber=n;}
52 void SetPeriodNumber(UInt_t n) {fPeriodNumber=n;}
53 void SetRunNumber(Int_t n) {fRunNumber=n;}
54 void SetTimeStamp(UInt_t timeStamp){fTimeStamp = timeStamp;}
55 void SetEventType(UInt_t eventType){fEventType = eventType;}
56 void SetTriggerMask(ULong64_t n) {fTriggerMask=n;}
57 void SetTriggerCluster(UChar_t n) {fTriggerCluster = n;}
58 void SetMagneticField(Float_t mf){fMagneticField = mf;}
59 Float_t GetMagneticField() const {return fMagneticField;}
61 AliESDtrack *GetTrack(Int_t i) const {
62 return (AliESDtrack *)fTracks.UncheckedAt(i);
64 AliESDHLTtrack *GetHLTConfMapTrack(Int_t i) const {
65 return (AliESDHLTtrack *)fHLTConfMapTracks.UncheckedAt(i);
67 AliESDHLTtrack *GetHLTHoughTrack(Int_t i) const {
68 return (AliESDHLTtrack *)fHLTHoughTracks.UncheckedAt(i);
70 AliESDMuonTrack *GetMuonTrack(Int_t i) const {
71 return (AliESDMuonTrack *)fMuonTracks.UncheckedAt(i);
73 AliESDPmdTrack *GetPmdTrack(Int_t i) const {
74 return (AliESDPmdTrack *)fPmdTracks.UncheckedAt(i);
76 AliESDTrdTrack *GetTrdTrack(Int_t i) const {
77 return (AliESDTrdTrack *)fTrdTracks.UncheckedAt(i);
80 Bool_t Clean(Float_t *cleanPars);
81 Bool_t RemoveKink(Int_t i);
82 Bool_t RemoveV0(Int_t i);
83 Bool_t RemoveTrack(Int_t i);
85 Int_t AddTrack(const AliESDtrack *t) {
86 AliESDtrack * track = new(fTracks[fTracks.GetEntriesFast()]) AliESDtrack(*t);track->SetID(fTracks.GetEntriesFast()-1);return track->GetID();
88 void AddHLTConfMapTrack(const AliESDHLTtrack *t) {
89 new(fHLTConfMapTracks[fHLTConfMapTracks.GetEntriesFast()]) AliESDHLTtrack(*t);
91 void AddHLTHoughTrack(const AliESDHLTtrack *t) {
92 new(fHLTHoughTracks[fHLTHoughTracks.GetEntriesFast()]) AliESDHLTtrack(*t);
94 void AddMuonTrack(const AliESDMuonTrack *t) {
95 new(fMuonTracks[fMuonTracks.GetEntriesFast()]) AliESDMuonTrack(*t);
97 void AddPmdTrack(const AliESDPmdTrack *t) {
98 new(fPmdTracks[fPmdTracks.GetEntriesFast()]) AliESDPmdTrack(*t);
100 void AddTrdTrack(const AliESDTrdTrack *t) {
101 new(fTrdTracks[fTrdTracks.GetEntriesFast()]) AliESDTrdTrack(*t);
104 AliESDv0 *GetV0(Int_t i) const {
105 return (AliESDv0 *)fV0s.UncheckedAt(i);
107 Int_t AddV0(const AliESDv0 *v);
109 AliESDcascade *GetCascade(Int_t i) const {
110 return (AliESDcascade *)fCascades.UncheckedAt(i);
112 void AddCascade(const AliESDcascade *c) {
113 new(fCascades[fCascades.GetEntriesFast()]) AliESDcascade(*c);
116 AliESDkink *GetKink(Int_t i) const {
117 return (AliESDkink *)fKinks.UncheckedAt(i);
119 Int_t AddKink(const AliESDkink *c) {
120 AliESDkink * kink = new(fKinks[fKinks.GetEntriesFast()]) AliESDkink(*c);
121 kink->SetID(fKinks.GetEntriesFast());
122 return fKinks.GetEntriesFast()-1;
125 AliESDCaloCluster *GetCaloCluster(Int_t i) const {
126 return (AliESDCaloCluster *)fCaloClusters.UncheckedAt(i);
128 Int_t AddCaloCluster(const AliESDCaloCluster *c) {
129 AliESDCaloCluster *clus = new(fCaloClusters[fCaloClusters.GetEntriesFast()]) AliESDCaloCluster(*c);
130 clus->SetID(fCaloClusters.GetEntriesFast()-1);
131 return fCaloClusters.GetEntriesFast()-1;
134 void AddPHOSTriggerPosition(TArrayF array) { fPHOSTriggerPosition = new TArrayF(array) ; }
135 void AddPHOSTriggerAmplitudes(TArrayF array) { fPHOSTriggerAmplitudes = new TArrayF(array) ; }
136 void AddEMCALTriggerPosition(TArrayF array) { fEMCALTriggerPosition = new TArrayF(array) ; }
137 void AddEMCALTriggerAmplitudes(TArrayF array){ fEMCALTriggerAmplitudes = new TArrayF(array) ; }
139 void SetVertex(const AliESDVertex *vertex) {
140 new (&fSPDVertex) AliESDVertex(*vertex);
142 const AliESDVertex *GetVertex() const {return &fSPDVertex;}
144 void SetMultiplicity(const AliMultiplicity *mul) {
145 new (&fSPDMult) AliMultiplicity(*mul);
147 const AliMultiplicity *GetMultiplicity() const {return &fSPDMult;}
149 void SetPrimaryVertex(const AliESDVertex *vertex) {
150 new (&fPrimaryVertex) AliESDVertex(*vertex);
152 const AliESDVertex *GetPrimaryVertex() const {return &fPrimaryVertex;}
154 void SetDiamond(const AliESDVertex *vertex);
155 Float_t GetDiamondX() const {return fDiamondXY[0];}
156 Float_t GetDiamondY() const {return fDiamondXY[1];}
157 Float_t GetSigma2DiamondX() const {return fDiamondCovXY[0];}
158 Float_t GetSigma2DiamondY() const {return fDiamondCovXY[2];}
159 void GetDiamondCovXY(Float_t cov[3]) const {
160 for(Int_t i=0;i<3;i++) cov[i]=fDiamondCovXY[i]; return;
163 Int_t GetEventNumberInFile() const {return fEventNumberInFile;}
164 UShort_t GetBunchCrossNumber() const {return fBunchCrossNumber;}
165 UInt_t GetOrbitNumber() const {return fOrbitNumber;}
166 UInt_t GetPeriodNumber() const {return fPeriodNumber;}
167 Int_t GetRunNumber() const {return fRunNumber;}
168 UInt_t GetTimeStamp() const { return fTimeStamp;}
169 UInt_t GetEventType() const { return fEventType;}
170 ULong64_t GetTriggerMask() const {return fTriggerMask;}
171 UChar_t GetTriggerCluster() const {return fTriggerCluster;}
173 Int_t GetNumberOfTracks() const {return fTracks.GetEntriesFast();}
174 Int_t GetNumberOfHLTConfMapTracks() const {return fHLTConfMapTracks.GetEntriesFast();}
175 Int_t GetNumberOfHLTHoughTracks() const {return fHLTHoughTracks.GetEntriesFast();}
176 Int_t GetNumberOfMuonTracks() const {return fMuonTracks.GetEntriesFast();}
177 Int_t GetNumberOfPmdTracks() const {return fPmdTracks.GetEntriesFast();}
178 Int_t GetNumberOfTrdTracks() const {return fTrdTracks.GetEntriesFast();}
179 Int_t GetNumberOfV0s() const {return fV0s.GetEntriesFast();}
180 Int_t GetNumberOfCascades() const {return fCascades.GetEntriesFast();}
181 Int_t GetNumberOfKinks() const {return fKinks.GetEntriesFast();}
182 Int_t GetNumberOfCaloClusters() const {return fCaloClusters.GetEntriesFast();}
184 Int_t GetNumberOfEMCALClusters() const {return fEMCALClusters;}
185 void SetNumberOfEMCALClusters(Int_t clus) {fEMCALClusters = clus;}
186 Int_t GetFirstEMCALCluster() const {return fFirstEMCALCluster;}
187 void SetFirstEMCALCluster(Int_t index) {fFirstEMCALCluster = index;}
188 TArrayF *GetEMCALTriggerPosition() const {return fEMCALTriggerPosition;}
189 TArrayF *GetEMCALTriggerAmplitudes() const {return fEMCALTriggerAmplitudes;}
191 Int_t GetNumberOfPHOSClusters() const {return fPHOSClusters;}
192 void SetNumberOfPHOSClusters(Int_t part) { fPHOSClusters = part ; }
193 void SetFirstPHOSCluster(Int_t index) { fFirstPHOSCluster = index ; }
194 Int_t GetFirstPHOSCluster() const { return fFirstPHOSCluster ; }
195 TArrayF *GetPHOSTriggerPosition() const {return fPHOSTriggerPosition;}
196 TArrayF *GetPHOSTriggerAmplitudes() const {return fPHOSTriggerAmplitudes;}
199 Double32_t GetT0zVertex() const {return fT0zVertex;}
200 void SetT0zVertex(Double32_t z) {fT0zVertex=z;}
201 Double32_t GetT0() const {return fT0timeStart;}
202 void SetT0(Double32_t timeStart) {fT0timeStart = timeStart;}
203 Float_t GetT0clock() const {return fT0clock;}
204 void SetT0clock(Float_t timeStart) {fT0clock = timeStart;}
205 Double32_t GetT0TOF(Int_t i) const {return fT0TOF[i];}
206 const Double32_t * GetT0TOF() const {return fT0TOF;}
207 void SetT0TOF(Int_t icase, Float_t time) { fT0TOF[icase] = time;}
208 Int_t GetT0Trig() const {return fT0trig;}
209 void SetT0Trig(Int_t tvdc) {fT0trig = tvdc;}
210 const Double32_t * GetT0time() const {return fT0time;}
211 void SetT0time(Double32_t time[24]) {
212 for (Int_t i=0; i<24; i++) fT0time[i] = time[i];
214 const Double32_t * GetT0amplitude() const {return fT0amplitude;}
215 void SetT0amplitude(Double32_t amp[24]) {
216 for (Int_t i=0; i<24; i++) fT0amplitude[i] = amp[i];
219 Float_t GetZDCN1Energy() const {return fZDCN1Energy;}
220 Float_t GetZDCP1Energy() const {return fZDCP1Energy;}
221 Float_t GetZDCN2Energy() const {return fZDCN2Energy;}
222 Float_t GetZDCP2Energy() const {return fZDCP2Energy;}
223 Float_t GetZDCEMEnergy() const {return fZDCEMEnergy;}
224 Int_t GetZDCParticipants() const {return fZDCParticipants;}
225 void SetZDC(Float_t n1Energy, Float_t p1Energy, Float_t emEnergy,
226 Float_t n2Energy, Float_t p2Energy, Int_t participants)
227 {fZDCN1Energy=n1Energy; fZDCP1Energy=p1Energy; fZDCEMEnergy=emEnergy;
228 fZDCN2Energy=n2Energy; fZDCP2Energy=p2Energy; fZDCParticipants=participants;}
230 void ResetV0s() { fV0s.Clear(); }
231 void ResetCascades() { fCascades.Clear(); }
234 void Print(Option_t *option="") const;
236 void SetFMDData(AliESDFMD * obj) { fESDFMD = new AliESDFMD(*obj); }
237 AliESDFMD *GetFMDData(){ return fESDFMD; }
239 void SetVZEROData(AliESDVZERO * obj) { fESDVZERO = new AliESDVZERO(*obj); }
240 AliESDVZERO *GetVZEROData(){ return fESDVZERO; }
241 void SetACORDEData(AliESDACORDE * obj){ fESDACORDE = new AliESDACORDE(*obj); }
242 AliESDACORDE *GetACORDEDAta(){ return fESDACORDE; }
243 void SetADData(AliESDAD * obj){ fESDAD = new AliESDAD(*obj); }
244 AliESDAD *GetADData(){ return fESDAD; }
248 AliRawDataErrorLog *GetErrorLog(Int_t i) const {
249 return (AliRawDataErrorLog *)fErrorLogs.UncheckedAt(i);
251 void AddRawDataErrorLog(const AliRawDataErrorLog *log) {
252 new(fErrorLogs[fErrorLogs.GetEntriesFast()]) AliRawDataErrorLog(*log);
254 Int_t GetNumberOfErrorLogs() const {return fErrorLogs.GetEntriesFast();}
257 AliESD &operator=(const AliESD& source);
259 // Event Identification
261 Int_t fEventNumberInFile;// running Event count in the file
262 UShort_t fBunchCrossNumber;// Bunch Crossing Number
263 UInt_t fOrbitNumber; // Orbit Number
264 UInt_t fPeriodNumber; // Period Number
265 Int_t fRunNumber; // Run Number
266 UInt_t fTimeStamp; // Time stamp
267 UInt_t fEventType; // Type of Event
268 ULong64_t fTriggerMask; // Trigger Type (mask)
269 UChar_t fTriggerCluster; // Trigger cluster (mask)
270 Int_t fRecoVersion; // Version of reconstruction
271 Float_t fMagneticField; // Solenoid Magnetic Field in kG : for compatibility with AliMagF
273 Float_t fZDCN1Energy; // reconstructed energy in the neutron ZDC
274 Float_t fZDCP1Energy; // reconstructed energy in the proton ZDC
275 Float_t fZDCN2Energy; // reconstructed energy in the neutron ZDC
276 Float_t fZDCP2Energy; // reconstructed energy in the proton ZDC
277 Float_t fZDCEMEnergy; // reconstructed energy in the electromagnetic ZDC
278 Int_t fZDCParticipants; // number of participants estimated by the ZDC
281 Double32_t fT0zVertex; // vertex z position estimated by the T0
282 AliESDVertex fSPDVertex; // Primary vertex estimated by the SPD
283 AliESDVertex fPrimaryVertex; // Primary vertex estimated using ESD tracks
284 Float_t fDiamondXY[2]; // Interaction diamond (x,y) in RUN
285 Float_t fDiamondCovXY[3]; // Interaction diamond covariance (x,y) in RUN
286 AliMultiplicity fSPDMult; // SPD tracklet multiplicity
288 Float_t fT0clock; // backward compatibility
289 Double32_t fT0TOF[3]; // interaction time in ns ( A&C, A, C)
290 Double32_t fT0timeStart; // interaction time estimated by the T0
291 Int_t fT0trig; // T0 trigger signals
292 Double32_t fT0time[24]; // best TOF on each T0 PMT
293 Double32_t fT0amplitude[24]; // number of particles(MIPs) on each T0 PMT
296 TClonesArray fTracks; // ESD tracks
297 TClonesArray fHLTConfMapTracks;// HLT ESD tracks from Conformal Mapper method
298 TClonesArray fHLTHoughTracks; // HLT ESD tracks from Hough Transform method
299 TClonesArray fMuonTracks; // MUON ESD tracks
300 TClonesArray fPmdTracks; // PMD ESD tracks
301 TClonesArray fTrdTracks; // TRD ESD tracks (triggered)
302 TClonesArray fV0s; // V0 vertices
303 TClonesArray fCascades; // Cascade vertices
304 TClonesArray fKinks; // Kinks
305 TClonesArray fCaloClusters; // Calorimeter clusters for PHOS/EMCAL
306 Int_t fEMCALClusters; // Number of EMCAL clusters (subset of caloclusters)
307 Int_t fFirstEMCALCluster; // First EMCAL cluster in the fCaloClusters list
308 TArrayF *fEMCALTriggerPosition; ///(x,y,z of 2x2 and x,y,z of nxn) not position of centroid but of patch corner
309 TArrayF *fEMCALTriggerAmplitudes; //(2x2 max ampl, 2x2 amp out of patch, nxn max ampl, nxn amp out of patch)
311 Int_t fPHOSClusters; // Number of PHOS clusters (subset of caloclusters)
312 Int_t fFirstPHOSCluster; // First PHOS cluster in the fCaloClusters list
313 TArrayF *fPHOSTriggerPosition; //(x,y,z of 2x2 and x,y,z of nxn), not position of centroid but of patch corner
314 TArrayF *fPHOSTriggerAmplitudes; //(2x2 max ampl, 2x2 amp out of patch, nxn max ampl, nxn amp out of patch)
316 AliESDFMD *fESDFMD; // FMD object containing rough multiplicity
317 AliESDVZERO *fESDVZERO; // VZERO object containing rough multiplicity
318 AliESDACORDE *fESDACORDE; // ACORDE ESD object containing bit pattern
319 AliESDAD *fESDAD; // AD ESD object containing bit pattern
320 TClonesArray fErrorLogs; // Raw-data reading error messages
322 ClassDef(AliESD,23) //ESD class