#ifndef ALICALOTRACKREADER_H #define ALICALOTRACKREADER_H /* Copyright(c) 1998-1999, ALICE Experiment at CERN, All rights reserved. * * See cxx source for full Copyright notice */ //_________________________________________________________________________ // Base class for reading data: MonteCarlo, ESD or AOD, of PHOS EMCAL and // Central Barrel Tracking detectors. // Not all MC particles/tracks/clusters are kept, some kinematical restrictions are done. // Mother class of : AliCaloTrackESDReader: Fills ESD data in 3 TObjArrays (PHOS, EMCAL, CTS) // : AliCaloTrackMCReader : Fills Kinematics data in 3 TObjArrays (PHOS, EMCAL, CTS) // : AliCaloTrackAODReader: Fills AOD data in 3 TObjArrays (PHOS, EMCAL, CTS) // -- Author: Gustavo Conesa (INFN-LNF) ////////////////////////////////////////////////////////////////////////////// // --- ROOT system --- #include #include class TObjArray ; class TTree ; class TArrayI ; //--- ANALYSIS system --- #include "AliVEvent.h" class AliVCaloCells; class AliStack; class AliHeader; class AliGenEventHeader; class AliAODEvent; class AliMCEvent; class AliMixedEvent; class AliAODMCHeader; class AliESDtrackCuts; class AliCentrality; class AliTriggerAnalysis; class AliEventplane; class AliVCluster; // --- CaloTrackCorr / EMCAL --- #include "AliFiducialCut.h" class AliEMCALRecoUtils; class AliCalorimeterUtils; class AliCaloTrackReader : public TObject { public: AliCaloTrackReader() ; // ctor virtual ~AliCaloTrackReader() ; // virtual dtor //-------------------------------- // General methods //-------------------------------- virtual void Init(); virtual void InitParameters(); virtual void Print(const Option_t * opt) const; virtual void ResetLists(); virtual Int_t GetDebug() const { return fDebug ; } virtual void SetDebug(Int_t d) { fDebug = d ; } enum inputDataType {kESD, kAOD, kMC}; virtual Int_t GetDataType() const { return fDataType ; } virtual void SetDataType(Int_t data ) { fDataType = data ; } virtual Int_t GetEventNumber() const { return fEventNumber ; } TString GetTaskName() const { return fTaskName ; } void SetTaskName(TString name) { fTaskName = name ; } //--------------------------------------- // Input/output event setters and getters //--------------------------------------- virtual void SetInputEvent(AliVEvent* const input) ; virtual void SetOutputEvent(AliAODEvent* const aod) { fOutputEvent = aod ; } virtual void SetMC(AliMCEvent* const mc) { fMC = mc ; } virtual void SetInputOutputMCEvent(AliVEvent* /*esd*/, AliAODEvent* /*aod*/, AliMCEvent* /*mc*/) { ; } // Delta AODs virtual TList * GetAODBranchList() const { return fAODBranchList ; } void SetDeltaAODFileName(TString name ) { fDeltaAODFileName = name ; } TString GetDeltaAODFileName() const { return fDeltaAODFileName ; } void SwitchOnWriteDeltaAOD() { fWriteOutputDeltaAOD = kTRUE ; } void SwitchOffWriteDeltaAOD() { fWriteOutputDeltaAOD = kFALSE ; } Bool_t WriteDeltaAODToFile() const { return fWriteOutputDeltaAOD ; } //------------------------------------------------------------ // Clusters/Tracks arrays filtering/filling methods and switchs //------------------------------------------------------------ // Minimum pt setters and getters Float_t GetEMCALPtMin() const { return fEMCALPtMin ; } Float_t GetPHOSPtMin() const { return fPHOSPtMin ; } Float_t GetCTSPtMin() const { return fCTSPtMin ; } Float_t GetEMCALPtMax() const { return fEMCALPtMax ; } Float_t GetPHOSPtMax() const { return fPHOSPtMax ; } Float_t GetCTSPtMax() const { return fCTSPtMax ; } void SetEMCALPtMin(Float_t pt) { fEMCALPtMin = pt ; } void SetPHOSPtMin (Float_t pt) { fPHOSPtMin = pt ; } void SetCTSPtMin (Float_t pt) { fCTSPtMin = pt ; } void SetEMCALPtMax(Float_t pt) { fEMCALPtMax = pt ; } void SetPHOSPtMax (Float_t pt) { fPHOSPtMax = pt ; } void SetCTSPtMax (Float_t pt) { fCTSPtMax = pt ; } Float_t GetEMCALEMin() const { return GetEMCALPtMin() ; } Float_t GetPHOSEMin() const { return GetPHOSPtMin() ; } Float_t GetEMCALEMax() const { return GetEMCALPtMax() ; } Float_t GetPHOSEMax() const { return GetPHOSPtMax() ; } void SetEMCALEMin (Float_t e) { SetEMCALPtMin(e) ; } void SetPHOSEMin (Float_t e) { SetPHOSPtMin (e) ; } void SetEMCALEMax (Float_t e) { SetEMCALPtMax(e) ; } void SetPHOSEMax (Float_t e) { SetPHOSPtMax (e) ; } // Track DCA cut Bool_t AcceptDCA(const Float_t pt, const Float_t dca); Double_t GetTrackDCACut(Int_t i) const { if(i >= 0 && i < 3 ) return fTrackDCACut[i] ; else return -999 ; } void SetTrackDCACut(Int_t i, Float_t cut) { if(i >= 0 && i < 3 ) fTrackDCACut[i] = cut ; } void SwitchOnUseTrackDCACut() { fUseTrackDCACut = kTRUE ; } void SwitchOffUseTrackDCACut() { fUseTrackDCACut = kFALSE ; } Bool_t IsDCACutOn() const { return fUseTrackDCACut ; } // Time cut Double_t GetTrackTimeCutMin() const { return fTrackTimeCutMin ; } Double_t GetTrackTimeCutMax() const { return fTrackTimeCutMax ; } void SetTrackTimeCut(Double_t a, Double_t b) { fTrackTimeCutMin = a ; fTrackTimeCutMax = b ; } // ns void SwitchOnUseTrackTimeCut() { fUseTrackTimeCut = kTRUE ; } void SwitchOffUseTrackTimeCut() { fUseTrackTimeCut = kFALSE ; } Double_t GetEMCALTimeCutMin() const { return fEMCALTimeCutMin ; } Double_t GetEMCALTimeCutMax() const { return fEMCALTimeCutMax ; } Bool_t IsInTimeWindow(const Double_t tof, const Float_t energy) const ; void SetEMCALTimeCut(Double_t a, Double_t b) { fEMCALTimeCutMin = a ; fEMCALTimeCutMax = b ; } // ns void SetEMCALParametrizedMinTimeCut(Int_t i, Float_t par) { fEMCALParamTimeCutMin[i] = par ; } void SetEMCALParametrizedMaxTimeCut(Int_t i, Float_t par) { fEMCALParamTimeCutMax[i] = par ; } void SwitchOnUseEMCALTimeCut() { fUseEMCALTimeCut = kTRUE ; } void SwitchOffUseEMCALTimeCut() { fUseEMCALTimeCut = kFALSE ; } void SwitchOnUseParametrizedTimeCut() { fUseParamTimeCut = kTRUE ; } void SwitchOffUseParametrizedTimeCut() { fUseParamTimeCut = kFALSE ; } // Fidutial cuts virtual AliFiducialCut * GetFiducialCut() { if(!fFiducialCut) fFiducialCut = new AliFiducialCut(); return fFiducialCut ; } virtual void SetFiducialCut(AliFiducialCut * const fc) { fFiducialCut = fc ; } virtual Bool_t IsFiducialCutOn() const { return fCheckFidCut ; } virtual void SwitchOnFiducialCut() { fCheckFidCut = kTRUE ; fFiducialCut = new AliFiducialCut() ; } virtual void SwitchOffFiducialCut() { fCheckFidCut = kFALSE ; } // Cluster origin Bool_t IsEMCALCluster(AliVCluster *clus) const; Bool_t IsPHOSCluster (AliVCluster *clus) const; // Patch for cluster origin for Old AODs implementation void SwitchOnOldAODs() { fOldAOD = kTRUE ; } void SwitchOffOldAODs() { fOldAOD = kFALSE ; } // Cluster/track/cells switchs Bool_t IsCTSSwitchedOn() const { return fFillCTS ; } void SwitchOnCTS() { fFillCTS = kTRUE ; } void SwitchOffCTS() { fFillCTS = kFALSE ; } Bool_t IsEMCALSwitchedOn() const { return fFillEMCAL ; } void SwitchOnEMCAL() { fFillEMCAL = kTRUE ; } void SwitchOffEMCAL() { fFillEMCAL = kFALSE ; } Bool_t IsPHOSSwitchedOn() const { return fFillPHOS ; } void SwitchOnPHOS() { fFillPHOS = kTRUE ; } void SwitchOffPHOS() { fFillPHOS = kFALSE ; } Bool_t IsEMCALCellsSwitchedOn() const { return fFillEMCALCells ; } void SwitchOnEMCALCells() { fFillEMCALCells = kTRUE ; } void SwitchOffEMCALCells() { fFillEMCALCells = kFALSE ; } Bool_t IsPHOSCellsSwitchedOn() const { return fFillPHOSCells ; } void SwitchOnPHOSCells() { fFillPHOSCells = kTRUE ; } void SwitchOffPHOSCells() { fFillPHOSCells = kFALSE ; } Bool_t AreClustersRecalculated() const { return fRecalculateClusters ; } void SwitchOnClusterRecalculation() { fRecalculateClusters = kTRUE ; } void SwitchOffClusterRecalculation() { fRecalculateClusters = kFALSE ; } Bool_t IsEmbeddedClusterSelectionOn() const { return fSelectEmbeddedClusters ; } void SwitchOnEmbeddedClustersSelection() { fSelectEmbeddedClusters = kTRUE ; } void SwitchOffEmbeddedClustersSelection() { fSelectEmbeddedClusters = kFALSE ; } // Filling/ filtering / detector information access methods virtual Bool_t FillInputEvent(const Int_t iEntry, const char *currentFileName) ; virtual void FillInputCTS() ; virtual void FillInputEMCAL() ; virtual void FillInputEMCALAlgorithm(AliVCluster * clus, const Int_t iclus) ; virtual void FillInputPHOS() ; virtual void FillInputEMCALCells() ; virtual void FillInputPHOSCells() ; virtual void FillInputVZERO() ; Int_t GetV0Signal(Int_t i) const { return fV0ADC[i] ; } Int_t GetV0Multiplicity(Int_t i) const { return fV0Mul[i] ; } void SetEMCALClusterListName(TString &name) { fEMCALClustersListName = name ; } TString GetEMCALClusterListName() const { return fEMCALClustersListName ; } // Arrays with clusters/track/cells access method virtual TObjArray* GetCTSTracks() const { return fCTSTracks ; } virtual TObjArray* GetEMCALClusters() const { return fEMCALClusters ; } virtual TObjArray* GetPHOSClusters() const { return fPHOSClusters ; } virtual AliVCaloCells* GetEMCALCells() const { return fEMCALCells ; } virtual AliVCaloCells* GetPHOSCells() const { return fPHOSCells ; } //------------------------------------- // Event/track selection methods //------------------------------------- void AcceptFastClusterEvents() { fAcceptFastCluster = kTRUE ; } void RejectFastClusterEvents() { fAcceptFastCluster = kFALSE ; } Bool_t IsFastClusterAccepted() const { return fAcceptFastCluster ; } void SwitchOnLEDEventsRemoval() { fRemoveLEDEvents = kTRUE ; } void SwitchOffLEDEventsRemoval() { fRemoveLEDEvents = kFALSE ; } Bool_t IsLEDEventRemoved() const { return fRemoveLEDEvents ; } Bool_t RejectLEDEvents(); void SetFiredTriggerClassName(TString name ) { fFiredTriggerClassName = name ; } TString GetFiredTriggerClassName() const { return fFiredTriggerClassName ; } TString GetFiredTriggerClasses() const { return GetInputEvent()->GetFiredTriggerClasses() ; } UInt_t GetEventTriggerMask() const { return fEventTriggerMask ; } void SetEventTriggerMask(UInt_t evtTrig = AliVEvent::kAny) { fEventTriggerMask = evtTrig ; } Bool_t IsEventTriggerAtSEOn() const { return fEventTriggerAtSE ; } void SwitchOnEventTriggerAtSE() { fEventTriggerAtSE = kTRUE ; } void SwitchOffEventTriggerAtSE() { fEventTriggerAtSE = kFALSE ; } TArrayI GetTriggerPatches(Int_t tmin, Int_t tmax); void MatchTriggerCluster(TArrayI patches); Bool_t IsExoticEvent() { return fIsExoticEvent ; } Bool_t IsBadCellTriggerEvent() { return fIsBadCellEvent ; } Bool_t IsBadMaxCellTriggerEvent() { return fIsBadMaxCellEvent ; } Bool_t IsTriggerMatched() { return fIsTriggerMatch ; } Bool_t IsTriggerMatchedOpenCuts(Int_t i) { return fIsTriggerMatchOpenCut[i]; } Int_t GetTriggerClusterBC() { return fTriggerClusterBC ; } Int_t GetTriggerClusterIndex() { return fTriggerClusterIndex ; } Int_t GetTriggerClusterId() { return fTriggerClusterId ; } Float_t GetEventTriggerThreshold() { return fTriggerEventThreshold ; } void SetEventTriggerThreshold(Float_t tr) { fTriggerEventThreshold = tr ; } void SetTriggerPatchTimeWindow(Int_t min, Int_t max) { fTriggerPatchTimeWindow[0] = min ; fTriggerPatchTimeWindow[1] = max ; } void SwitchOffBadTriggerEventsRemoval() { fRemoveBadTriggerEvents = kFALSE ; } void SwitchOnBadTriggerEventsRemoval() { fRemoveBadTriggerEvents = kTRUE ; } void SwitchOffTriggerPatchMatching() { fTriggerPatchClusterMatch = kFALSE ; } void SwitchOnTriggerPatchMatching() { fTriggerPatchClusterMatch = kTRUE ; } UInt_t GetMixEventTriggerMask() const { return fMixEventTriggerMask ; } void SetMixEventTriggerMask(UInt_t evtTrig = AliVEvent::kAnyINT) { fMixEventTriggerMask = evtTrig ; } void SetEventTriggerBit(); Bool_t IsEventMinimumBias() const { return fEventTrigMinBias ; } Bool_t IsEventCentral() const { return fEventTrigCentral ; } Bool_t IsEventSemiCentral() const { return fEventTrigSemiCentral ; } Bool_t IsEventEMCALL0() const { return fEventTrigEMCALL0 ; } Bool_t IsEventEMCALL1Gamma1() const { return fEventTrigEMCALL1Gamma1 ; } Bool_t IsEventEMCALL1Gamma2() const { return fEventTrigEMCALL1Gamma2 ; } Bool_t IsEventEMCALL1Jet1() const { return fEventTrigEMCALL1Jet1 ; } Bool_t IsEventEMCALL1Jet2() const { return fEventTrigEMCALL1Jet2 ; } Bool_t IsEventEMCALL1Gamma() const { return (fEventTrigEMCALL1Gamma1 || fEventTrigEMCALL1Gamma2) ; } Bool_t IsEventEMCALL1Jet() const { return (fEventTrigEMCALL1Jet1 || fEventTrigEMCALL1Jet2 ) ; } Bool_t IsEventEMCALL1() const { return (IsEventEMCALL1Gamma() || IsEventEMCALL1Jet() ) ; } void SwitchOnEventSelection() { fDoEventSelection = kTRUE ; } void SwitchOffEventSelection() { fDoEventSelection = kFALSE ; } Bool_t IsEventSelectionDone() const { return fDoEventSelection ; } void SwitchOnV0ANDSelection() { fDoV0ANDEventSelection = kTRUE ; } void SwitchOffV0ANDSelection() { fDoV0ANDEventSelection = kFALSE ; } Bool_t IsV0ANDEventSelectionDone() const { return fDoV0ANDEventSelection ; } void SwitchOnVertexBCEventSelection() { fDoVertexBCEventSelection = kTRUE ; } void SwitchOffVertexBCEventSelection() { fDoVertexBCEventSelection = kFALSE ; } Bool_t IsVertexBCEventSelectionDone() const { return fDoVertexBCEventSelection ; } void SwitchOnPrimaryVertexSelection() { fUseEventsWithPrimaryVertex = kTRUE ; } void SwitchOffPrimaryVertexSelection() { fUseEventsWithPrimaryVertex = kFALSE ; } Bool_t IsPrimaryVertexSelectionDone() const { return fUseEventsWithPrimaryVertex ; } void SwitchOnRejectNoTrackEvents() { fDoRejectNoTrackEvents = kTRUE ; } void SwitchOffRejectNoTrackEvents() { fDoRejectNoTrackEvents = kFALSE ; } Bool_t IsEventWithNoTrackRejectionDone() const { return fDoRejectNoTrackEvents ; } // Time Stamp Double_t GetRunTimeStampMin() const { return fTimeStampRunMin ; } Double_t GetRunTimeStampMax() const { return fTimeStampRunMax ; } void SetRunTimeStamp(Double_t a, Double_t b) { fTimeStampRunMin = a ; fTimeStampRunMax = b ; } // seconds Float_t GetEventTimeStampFractionMin() const { return fTimeStampEventFracMin ; } Float_t GetEventTimeStampFractionMax() const { return fTimeStampEventFracMax ; } void SetEventTimeStampFraction(Float_t a, Float_t b) { fTimeStampEventFracMin = a ; fTimeStampEventFracMax = b ; } void SwitchOnSelectEventTimeStamp() { fTimeStampEventSelect = kTRUE ; } void SwitchOffSelectEventTimeStamp() { fTimeStampEventSelect = kFALSE ; } Bool_t IsSelectEventTimeStampOn() {return fTimeStampEventSelect ; } Bool_t IsPileUpFromSPD() const ; Bool_t IsPileUpFromEMCal() const ; Bool_t IsPileUpFromSPDAndEMCal() const ; Bool_t IsPileUpFromSPDOrEMCal() const ; Bool_t IsPileUpFromSPDAndNotEMCal() const ; Bool_t IsPileUpFromEMCalAndNotSPD() const ; Bool_t IsPileUpFromNotSPDAndNotEMCal() const ; void SetPileUpParamForSPD (Int_t i, Double_t param) { fPileUpParamSPD[i] = param ; } void SetPileUpParamForEMCal(Int_t param) { fNPileUpClustersCut = param ; } Int_t GetNPileUpClusters() { return fNPileUpClusters ; } Int_t GetNNonPileUpClusters() { return fNNonPileUpClusters ; } Int_t GetEMCalEventBC(Int_t bc) const { if(bc >=0 && bc < 19) return fEMCalBCEvent [bc] ; else return 0 ; } Int_t GetTrackEventBC(Int_t bc) const { if(bc >=0 && bc < 19) return fTrackBCEvent [bc] ; else return 0 ; } Int_t GetEMCalEventBCcut(Int_t bc) const { if(bc >=0 && bc < 19) return fEMCalBCEventCut[bc] ; else return 0 ; } Int_t GetTrackEventBCcut(Int_t bc) const { if(bc >=0 && bc < 19) return fTrackBCEventCut[bc] ; else return 0 ; } void SetEMCalEventBC(Int_t bc) { if(bc >=0 && bc < 19) fEMCalBCEvent [bc] = 1 ; } void SetTrackEventBC(Int_t bc) { if(bc >=0 && bc < 19) fTrackBCEvent [bc] = 1 ; } void SetEMCalEventBCcut(Int_t bc) { if(bc >=0 && bc < 19) fEMCalBCEventCut[bc] = 1 ; } void SetTrackEventBCcut(Int_t bc) { if(bc >=0 && bc < 19) fTrackBCEventCut[bc] = 1 ; } Int_t GetVertexBC(const AliVVertex * vtx); Int_t GetVertexBC() const { return fVertexBC ; } void SwitchOnRecalculateVertexBC() { fRecalculateVertexBC = kTRUE ; } void SwitchOffRecalculateVertexBC() { fRecalculateVertexBC = kFALSE ; } // Track selection ULong_t GetTrackStatus() const { return fTrackStatus ; } void SetTrackStatus(ULong_t bit) { fTrackStatus = bit ; } ULong_t GetTrackFilterMask() const {return fTrackFilterMask ; } void SetTrackFilterMask(ULong_t bit) { fTrackFilterMask = bit ; } AliESDtrackCuts* GetTrackCuts() const { return fESDtrackCuts ; } void SetTrackCuts(AliESDtrackCuts * cuts) ; AliESDtrackCuts* GetTrackComplementaryCuts() const { return fESDtrackComplementaryCuts ; } void SetTrackComplementaryCuts(AliESDtrackCuts * cuts) ; void SwitchOnConstrainTrackToVertex() { fConstrainTrack = kTRUE ; } void SwitchOffConstrainTrackToVertex() { fConstrainTrack = kFALSE ; } void SwitchOnAODHybridTrackSelection() { fSelectHybridTracks = kTRUE ; } void SwitchOffAODHybridTrackSelection() { fSelectHybridTracks = kFALSE ; } void SwitchOnTrackHitSPDSelection() { fSelectSPDHitTracks = kTRUE ; } void SwitchOffTrackHitSPDSelection() { fSelectSPDHitTracks = kFALSE ; } Int_t GetTrackMultiplicity() const { return fTrackMult ; } Float_t GetTrackMultiplicityEtaCut() const { return fTrackMultEtaCut ; } void SetTrackMultiplicityEtaCut(Float_t eta) { fTrackMultEtaCut = eta ; } // Calorimeter specific and patches void AnalyzeOnlyLED() { fAnaLED = kTRUE ; } void AnalyzeOnlyPhysics() { fAnaLED = kFALSE ; } //------------------------------- // Vertex methods //------------------------------- virtual void GetVertex(Double_t v[3]) const ; virtual Double_t* GetVertex(const Int_t evtIndex) const { return fVertex[evtIndex] ; } virtual void GetVertex(Double_t vertex[3], const Int_t evtIndex) const ; virtual void FillVertexArray(); virtual Bool_t CheckForPrimaryVertex(); virtual Float_t GetZvertexCut() const { return fZvtxCut ; } //cut on vertex position virtual void SetZvertexCut(Float_t zcut=10.) { fZvtxCut=zcut ; } //cut on vertex position //-------------------------- // Centrality / Event Plane //-------------------------- virtual AliCentrality* GetCentrality() const { if(fDataType!=kMC) return fInputEvent->GetCentrality() ; else return 0x0 ; } virtual void SetCentralityClass(TString name) { fCentralityClass = name ; } virtual void SetCentralityOpt(Int_t opt) { fCentralityOpt = opt ; } virtual TString GetCentralityClass() const { return fCentralityClass ; } virtual Int_t GetCentralityOpt() const { return fCentralityOpt ; } virtual Int_t GetEventCentrality() const ; virtual void SetCentralityBin(Int_t min, Int_t max) //Set the centrality bin to select the event. If used, then need to get percentile { fCentralityBin[0]=min; fCentralityBin[1]=max; if(min>=0 && max > 0) fCentralityOpt = 100 ; } virtual Float_t GetCentralityBin(Int_t i) const { if(i < 0 || i > 1) return 0 ; else return fCentralityBin[i] ; } virtual AliEventplane* GetEventPlane() const { if(fDataType!=kMC) return fInputEvent->GetEventplane() ; else return 0x0 ; } virtual Double_t GetEventPlaneAngle() const ; virtual void SetEventPlaneMethod(TString m) { fEventPlaneMethod = m ; } virtual TString GetEventPlaneMethod() const { return fEventPlaneMethod ; } //-------------------- // Mixing //-------------------- Int_t GetLastCaloMixedEvent() const { return fLastMixedCaloEvent ; } Int_t GetLastTracksMixedEvent () const { return fLastMixedTracksEvent ; } TList * GetListWithMixedEventsForCalo (Int_t bi) const { if(fListMixedCaloEvents) return fListMixedCaloEvents[bi] ; else return 0 ; } TList * GetListWithMixedEventsForTracks(Int_t bi) const { if(fListMixedTracksEvents) return fListMixedTracksEvents [bi] ; else return 0 ; } Bool_t ListWithMixedEventsForCaloExists() const { if(fListMixedCaloEvents) return kTRUE ; else return kFALSE ; } Bool_t ListWithMixedEventsForTracksExists() const { if(fListMixedTracksEvents) return kTRUE ; else return kFALSE ; } void SetLastCaloMixedEvent (Int_t e) { fLastMixedCaloEvent = e ; } void SetLastTracksMixedEvent(Int_t e) { fLastMixedTracksEvent = e ; } void SetListWithMixedEventsForCalo (TList ** l) { if(fListMixedCaloEvents) printf("AliCaloTrackReader::SetListWithMixedEventsForCalo() - Track Mixing event list already set, nothing done\n"); else fListMixedCaloEvents = l ; } void SetListWithMixedEventsForTracks(TList ** l) { if(fListMixedTracksEvents) printf("AliCaloTrackReader::SetListWithMixedEventsForTracks() - Calorimeter Mixing event list already set, nothing done\n"); else fListMixedTracksEvents = l ; } //------------------------------------- // Other methods //------------------------------------- AliCalorimeterUtils * GetCaloUtils() const { return fCaloUtils ; } void SetCaloUtils(AliCalorimeterUtils * caloutils) { fCaloUtils = caloutils ; } virtual Double_t GetBField() const { return fInputEvent->GetMagneticField() ; } void SetImportGeometryFromFile(Bool_t import, TString path = "") { fImportGeometryFromFile = import ; fImportGeometryFilePath = path ; } //------------------------------------------------ // MC analysis specific methods //------------------------------------------------- // Kinematics and galice.root available virtual AliStack* GetStack() const ; virtual AliHeader* GetHeader() const ; virtual AliGenEventHeader* GetGenEventHeader() const ; // Filtered kinematics in AOD virtual TClonesArray* GetAODMCParticles() const ; virtual AliAODMCHeader* GetAODMCHeader () const ; virtual AliVEvent* GetInputEvent() const { return fInputEvent ; } virtual AliVEvent* GetOriginalInputEvent() const { return 0x0 ; } virtual AliAODEvent* GetOutputEvent() const { return fOutputEvent ; } virtual AliMCEvent* GetMC() const { return fMC ; } virtual AliMixedEvent* GetMixedEvent() const { return fMixedEvent ; } virtual Int_t GetNMixedEvent() const { return fNMixedEvent ; } void SwitchOnStack() { fReadStack = kTRUE ; } void SwitchOffStack() { fReadStack = kFALSE ; } void SwitchOnAODMCParticles() { fReadAODMCParticles = kTRUE ; } void SwitchOffAODMCParticles() { fReadAODMCParticles = kFALSE ; } Bool_t ReadStack() const { return fReadStack ; } Bool_t ReadAODMCParticles() const { return fReadAODMCParticles ; } void RemapMCLabelForAODs(Int_t &label); // Select generated events, depending on comparison of pT hard and jets virtual Bool_t ComparePtHardAndJetPt() ; virtual Bool_t IsPtHardAndJetPtComparisonSet() const { return fComparePtHardAndJetPt ; } virtual void SetPtHardAndJetPtComparison(Bool_t compare) { fComparePtHardAndJetPt = compare ; } virtual Float_t GetPtHardAndJetFactor() const { return fPtHardAndJetPtFactor ; } virtual void SetPtHardAndJetPtFactor(Float_t factor) { fPtHardAndJetPtFactor = factor ; } virtual Bool_t ComparePtHardAndClusterPt() ; virtual Bool_t IsPtHardAndClusterPtComparisonSet() const { return fComparePtHardAndClusterPt ; } virtual void SetPtHardAndClusterPtComparison(Bool_t compare) { fComparePtHardAndClusterPt = compare ; } virtual Float_t GetPtHardAndClusterFactor() const { return fPtHardAndClusterPtFactor ; } virtual void SetPtHardAndClusterPtFactor(Float_t factor) { fPtHardAndClusterPtFactor = factor ; } virtual Bool_t IsHIJINGLabel(const Int_t label); void SetGeneratorMinMaxParticles(); void SwitchOnAcceptOnlyHIJINGLabels() { fAcceptOnlyHIJINGLabels = kTRUE ; } void SwitchOffAcceptOnlyHIJINGLabels() { fAcceptOnlyHIJINGLabels = kFALSE ; } Bool_t AcceptOnlyHIJINGLabels() const { return fAcceptOnlyHIJINGLabels ; } // MC reader methods, declared there to allow compilation, they are only used in the MC reader virtual void AddNeutralParticlesArray(TArrayI & /*array*/) { ; } virtual void AddChargedParticlesArray(TArrayI & /*array*/) { ; } virtual void AddStatusArray(TArrayI & /*array*/) { ; } virtual void SwitchOnPi0Decay() { ; } virtual void SwitchOffPi0Decay() { ; } virtual void SwitchOnStatusSelection() { ; } virtual void SwitchOffStatusSelection() { ; } virtual void SwitchOnOverlapCheck() { ; } virtual void SwitchOffOverlapCheck() { ; } virtual void SwitchOnOnlyGeneratorParticles() { ; } virtual void SwitchOffOnlyGeneratorParticles() { ; } virtual void SetEMCALOverlapAngle(Float_t /*angle*/) { ; } virtual void SetPHOSOverlapAngle(Float_t /*angle*/) { ; } //------------- // Jets //------------- Bool_t IsNonStandardJetsSwitchedOn() const { return fFillInputNonStandardJetBranch ; } void SwitchOnNonStandardJets() { fFillInputNonStandardJetBranch = kTRUE ; } void SwitchOffNonStandardJets() { fFillInputNonStandardJetBranch = kFALSE ; } virtual void FillInputNonStandardJets() ; virtual TClonesArray* GetNonStandardJets() const { return fNonStandardJets ; } virtual void SetInputNonStandardJetBranchName(TString name) { fInputNonStandardJetBranchName = name ; } virtual TString GetInputNonStandardJetBranchName() { return fInputNonStandardJetBranchName ; } protected: Int_t fEventNumber; // Event number Int_t fDataType ; // Select MC:Kinematics, Data:ESD/AOD, MCData:Both Int_t fDebug; // Debugging level AliFiducialCut * fFiducialCut; // Acceptance cuts Bool_t fCheckFidCut ; // Do analysis for clusters in defined region Bool_t fComparePtHardAndJetPt; // In MonteCarlo, jet events, reject fake events with wrong jet energy. Float_t fPtHardAndJetPtFactor; // Factor between ptHard and jet pT to reject/accept event. Bool_t fComparePtHardAndClusterPt; // In MonteCarlo, jet events, reject events with too large cluster energy Float_t fPtHardAndClusterPtFactor; // Factor between ptHard and cluster pT to reject/accept event. Float_t fCTSPtMin; // pT Threshold on charged particles Float_t fEMCALPtMin; // pT Threshold on emcal clusters Float_t fPHOSPtMin; // pT Threshold on phos clusters Float_t fCTSPtMax; // pT Threshold on charged particles Float_t fEMCALPtMax; // pT Threshold on emcal clusters Float_t fPHOSPtMax; // pT Threshold on phos clusters Bool_t fUseEMCALTimeCut; // Do time cut selection Bool_t fUseParamTimeCut; // Use simple or parametrized time cut Bool_t fUseTrackTimeCut; // Do time cut selection Double_t fEMCALTimeCutMin; // Remove clusters/cells with time smaller than this value, in ns Double_t fEMCALTimeCutMax; // Remove clusters/cells with time larger than this value, in ns Float_t fEMCALParamTimeCutMin[4]; // Remove clusters/cells with time smaller than parametrized value, in ns Double_t fEMCALParamTimeCutMax[4]; // Remove clusters/cells with time larger than parametrized value, in ns Double_t fTrackTimeCutMin; // Remove tracks with time smaller than this value, in ns Double_t fTrackTimeCutMax; // Remove tracks with time larger than this value, in ns Bool_t fUseTrackDCACut; // Do DCA selection Double_t fTrackDCACut[3]; // Remove tracks with DCA larger than cut, parameters of function stored here TList * fAODBranchList ; //-> List with AOD branches created and needed in analysis TObjArray * fCTSTracks ; //-> temporal array with tracks TObjArray * fEMCALClusters ; //-> temporal array with EMCAL CaloClusters TObjArray * fPHOSClusters ; //-> temporal array with PHOS CaloClusters AliVCaloCells * fEMCALCells ; //! temporal array with EMCAL CaloCells AliVCaloCells * fPHOSCells ; //! temporal array with PHOS CaloCells AliVEvent * fInputEvent; //! pointer to esd or aod input AliAODEvent * fOutputEvent; //! pointer to aod output AliMCEvent * fMC; //! Monte Carlo Event Handler Bool_t fFillCTS; // use data from CTS Bool_t fFillEMCAL; // use data from EMCAL Bool_t fFillPHOS; // use data from PHOS Bool_t fFillEMCALCells; // use data from EMCAL Bool_t fFillPHOSCells; // use data from PHOS Bool_t fRecalculateClusters; // Correct clusters, recalculate them if recalibration parameters is given Bool_t fSelectEmbeddedClusters; // Use only simulated clusters that come from embedding. ULong_t fTrackStatus ; // Track selection bit, select tracks refitted in TPC, ITS ... ULong_t fTrackFilterMask ; // Track selection bit, for AODs (any difference with track status?) AliESDtrackCuts *fESDtrackCuts ; // Track cut AliESDtrackCuts *fESDtrackComplementaryCuts; // Track cut, complementary cuts for hybrids Bool_t fConstrainTrack ; // Constrain Track to vertex Bool_t fSelectHybridTracks ; // Select CTS tracks of type hybrid (only for AODs) Bool_t fSelectSPDHitTracks ; // Ensure that track hits SPD layers Int_t fTrackMult ; // Track multiplicity Float_t fTrackMultEtaCut ; // Track multiplicity eta cut Bool_t fReadStack ; // Access kine information from stack Bool_t fReadAODMCParticles ; // Access kine information from filtered AOD MC particles TString fDeltaAODFileName ; // Delta AOD file name TString fFiredTriggerClassName; // Name of trigger event type used to do the analysis // Trigger bit UInt_t fEventTriggerMask ; // select this triggerered event UInt_t fMixEventTriggerMask ; // select this triggerered event for mixing, tipically kMB or kAnyINT Bool_t fEventTriggerAtSE; // select triggered event at SE base task or here Bool_t fEventTrigMinBias ; // Event is min bias on its name, it should correspond to AliVEvent::kMB, AliVEvent::kAnyInt Bool_t fEventTrigCentral ; // Event is AliVEvent::kCentral on its name, it should correspond to PbPb Bool_t fEventTrigSemiCentral ; // Event is AliVEvent::kSemiCentral on its name, it should correspond to PbPb Bool_t fEventTrigEMCALL0 ; // Event is EMCal L0 on its name, it should correspond to AliVEvent::kEMC7, AliVEvent::kEMC1 Bool_t fEventTrigEMCALL1Gamma1 ; // Event is L1-Gamma, threshold 1 on its name, it should correspond kEMCEGA Bool_t fEventTrigEMCALL1Gamma2 ; // Event is L1-Gamma, threshold 2 on its name, it should correspond kEMCEGA Bool_t fEventTrigEMCALL1Jet1 ; // Event is L1-Gamma, threshold 1 on its name, it should correspond kEMCEGA Bool_t fEventTrigEMCALL1Jet2 ; // Event is L1-Gamma, threshold 2 on its name, it should correspond kEMCEGA Int_t fBitEGA; // Trigger bit on VCaloTrigger for EGA Int_t fBitEJE; // Trigger bit on VCaloTrigger for EJE Bool_t fAnaLED; // Analyze LED data only. TString fTaskName; // Name of task that executes the analysis AliCalorimeterUtils * fCaloUtils ; // Pointer to CalorimeterUtils AliMixedEvent * fMixedEvent ; //! mixed event object. This class is not the owner Int_t fNMixedEvent ; // number of events in mixed event buffer Double_t ** fVertex ; //! vertex array 3 dim for each mixed event buffer TList ** fListMixedTracksEvents ; //! Container for tracks stored for different events, used in case of own mixing, set in analysis class TList ** fListMixedCaloEvents; //! Container for photon stored for different events, used in case of own mixing, set in analysis class Int_t fLastMixedTracksEvent ; // Temporary container with the last event added to the mixing list for tracks Int_t fLastMixedCaloEvent ; // Temporary container with the last event added to the mixing list for photons Bool_t fWriteOutputDeltaAOD; // Write the created delta AOD objects into file Bool_t fOldAOD; // Old AODs, before revision 4.20 Int_t fV0ADC[2] ; // Integrated V0 signal Int_t fV0Mul[2] ; // Integrated V0 Multiplicity TString fEMCALClustersListName; // Alternative list of clusters produced elsewhere and not from InputEvent // Event selection Float_t fZvtxCut ; // Cut on vertex position Bool_t fAcceptFastCluster; // Accept events from fast cluster, exclude these events for LHC11a Bool_t fRemoveLEDEvents; // Remove events where LED was wrongly firing - EMCAL LHC11a Bool_t fRemoveBadTriggerEvents; // Remove triggered events because trigger was exotic, bad, or out of BC Bool_t fTriggerPatchClusterMatch; // Search for the trigger patch and check if associated cluster was the trigger Int_t fTriggerPatchTimeWindow[2]; // Trigger patch selection window Float_t fTriggerEventThreshold; // Threshold to look for triggered events Int_t fTriggerClusterBC; // Event triggered by a cluster in BC -5 0 to 5 Int_t fTriggerClusterIndex; // Index in clusters array of trigger cluster Int_t fTriggerClusterId; // Id of trigger cluster (cluster->GetID()) Bool_t fIsExoticEvent; // Exotic trigger event flag Bool_t fIsBadCellEvent; // Bad cell triggered event flag, any cell in cluster is bad Bool_t fIsBadMaxCellEvent; // Bad cell triggered event flag, only max energy cell is bad Bool_t fIsTriggerMatch; // Could match the event to a trigger patch? Bool_t fIsTriggerMatchOpenCut[3]; // Could not match the event to a trigger patch?, retry opening cuts Bool_t fDoEventSelection; // Select events depending on V0, pileup, vertex well reconstructed, at least 1 track ... Bool_t fDoV0ANDEventSelection; // Select events depending on V0, fDoEventSelection should be on Bool_t fDoVertexBCEventSelection; // Select events with vertex on BC=0 or -100 Bool_t fDoRejectNoTrackEvents; // Reject events with no selected tracks in event Bool_t fUseEventsWithPrimaryVertex ; // Select events with primary vertex AliTriggerAnalysis* fTriggerAnalysis; // Access to trigger selection algorithm for V0AND calculation Bool_t fTimeStampEventSelect; // Select events within a fraction of data taking time Float_t fTimeStampEventFracMin; // Minimum value of time stamp fraction event Float_t fTimeStampEventFracMax; // Maximum value of time stamp fraction event Double_t fTimeStampRunMin; // Minimum value of time stamp in run Double_t fTimeStampRunMax; // Maximum value of time stamp in run Double_t fPileUpParamSPD[5]; // Parameters to pass to method IsPileupFromSPD: Int_t minContributors, // Double_t minZdist, // Double_t nSigmaZdist, // Double_t nSigmaDiamXY, // Double_t nSigmaDiamZ) // Pile-up in EMCal Int_t fNPileUpClusters; // Number of clusters with time avobe 20 ns Int_t fNNonPileUpClusters; // Number of clusters with time below 20 ns Int_t fNPileUpClustersCut; // Cut to select event as pile-up Int_t fEMCalBCEvent[19]; // Fill one entry per event if there is a cluster in a given BC Int_t fEMCalBCEventCut[19]; // Fill one entry per event if there is a cluster in a given BC, depend on cluster E, acceptance cut Int_t fTrackBCEvent[19]; // Fill one entry per event if there is a track in a given BC Int_t fTrackBCEventCut[19]; // Fill one entry per event if there is a track in a given BC, depend on track pT, acceptance cut Int_t fVertexBC; // Vertex BC Bool_t fRecalculateVertexBC; // Recalculate vertex BC from tracks pointing to vertex //Centrality/Event plane TString fCentralityClass; // Name of selected centrality class Int_t fCentralityOpt; // Option for the returned value of the centrality, possible options 5, 10, 100 Int_t fCentralityBin[2]; // Minimum and maximum value of the centrality for the analysis TString fEventPlaneMethod; // Name of event plane method, by default "Q" Bool_t fImportGeometryFromFile; // Import geometry settings in geometry.root file TString fImportGeometryFilePath; // path fo geometry.root file Bool_t fAcceptOnlyHIJINGLabels; // Select clusters or tracks that where generated by HIJING, reject other generators in case of cocktail Int_t fNMCProducedMin; // In case of cocktail, select particles in the list with label from this value Int_t fNMCProducedMax; // In case of cocktail, select particles in the list with label up to this value // jets Bool_t fFillInputNonStandardJetBranch; // Flag to use data from non standard jets TClonesArray * fNonStandardJets; //! temporal array with jets TString fInputNonStandardJetBranchName; // Name of non standard jet branch AliCaloTrackReader( const AliCaloTrackReader & r) ; // cpy ctor AliCaloTrackReader & operator = (const AliCaloTrackReader & r) ; // cpy assignment ClassDef(AliCaloTrackReader,59) } ; #endif //ALICALOTRACKREADER_H