[u/mrichter/AliRoot.git] / STEER / AOD / AliAODHeader.h

#ifndef ALIAODHEADER_H
#define ALIAODHEADER_H
/* Copyright(c) 1998-2007, ALICE Experiment at CERN, All rights reserved. *
 * See cxx source for full Copyright notice                               */

/* $Id$ */

//-------------------------------------------------------------------------
//     AOD event header class
//     Author: Markus Oldenburg, CERN
//-------------------------------------------------------------------------

#include <TVector2.h>

#include "AliVHeader.h"
#include "AliAODVertex.h"
#include <TString.h>
#include <TBits.h>
#include "AliCentrality.h"
#include "AliEventplane.h"

class TGeoHMatrix;
class TString;


class AliAODHeader : public AliVHeader {

 public :
  AliAODHeader();
 
  AliAODHeader(Int_t nRun, UShort_t nBunchX, UInt_t nOrbit, UInt_t nPeriod, const Char_t *title="");
  AliAODHeader(Int_t nRun, 
	       UShort_t nBunchX,
	       UInt_t nOrbit,
	       UInt_t nPeriod,
	       Int_t refMult,
	       Int_t refMultPos,
	       Int_t refMultNeg,
	       Int_t refMultComb05,
	       Int_t refMultComb08,
	       Double_t magField,
	       Double_t muonMagFieldScale,
	       Double_t cent,
	       Double_t eventplane,
	       Double_t n1Energy,
	       Double_t p1Energy,
	       Double_t n2Energy,
	       Double_t p2Energy,
	       Double_t *emEnergy,
	       ULong64_t fTriggerMask,
	       UChar_t   fTriggerCluster,
	       UInt_t    fEventType,
	       const Float_t *vzeroEqFactors,
	       const Char_t *title="",
	       Int_t nMuons=0,
	       Int_t nDimuons=0,
	       Int_t nGlobalMuons=0,             // AU
	       Int_t nGlobalDimuons=0);          // AU
  
  virtual ~AliAODHeader();
  AliAODHeader(const AliAODHeader& evt); 
  AliAODHeader& operator=(const AliAODHeader& evt);
  Bool_t    InitMagneticField() const;

  Int_t     GetRunNumber()          const { return fRunNumber;}
  Int_t     GetEventNumberESDFile() const { return fEventNumberESDFile;}
  Int_t     GetNumberOfESDTracks()    const { return fNumberESDTracks;}
  UShort_t  GetBunchCrossNumber()   const { return fBunchCrossNumber; }
  UInt_t    GetOrbitNumber()        const { return fOrbitNumber; }
  UInt_t    GetPeriodNumber()       const { return fPeriodNumber; }
  ULong64_t GetTriggerMask()        const { return fTriggerMask; }
  UChar_t   GetTriggerCluster()     const { return fTriggerCluster; }
  TString   GetFiredTriggerClasses()const { return fFiredTriggers;}
  UInt_t    GetEventType()          const { return fEventType; }
  Double_t  GetMagneticField()      const { return fMagneticField; }
  Double_t  GetMuonMagFieldScale()  const { return fMuonMagFieldScale; }
  
  Double_t  GetCentrality()         const { return fCentrality; }
  Double_t  GetEventplane()         const { return fEventplane; }
  Double_t  GetEventplaneMag()      const { return fEventplaneMag; }
  Double_t  GetEventplaneQx()       const { return fEventplaneQx; }
  Double_t  GetEventplaneQy()       const { return fEventplaneQy; }
  Double_t  GetZDCN1Energy()        const { return fZDCN1Energy; }
  Double_t  GetZDCP1Energy()        const { return fZDCP1Energy; }
  Double_t  GetZDCN2Energy()        const { return fZDCN2Energy; }
  Double_t  GetZDCP2Energy()        const { return fZDCP2Energy; }
  Double_t  GetZDCEMEnergy(Int_t i) const { return fZDCEMEnergy[i]; }
  Int_t     GetRefMultiplicity()    const { return fRefMult; }
  Int_t     GetRefMultiplicityPos() const { return fRefMultPos; }
  Int_t     GetRefMultiplicityNeg() const { return fRefMultNeg; }
  Int_t     GetNumberOfMuons()      const { return fNMuons; }
  Int_t     GetNumberOfDimuons()    const { return fNDimuons; }
  Int_t     GetNumberOfGlobalMuons()   const { return fNGlobalMuons; }      // AU
  Int_t     GetNumberOfGlobalDimuons() const { return fNGlobalDimuons; }    // AU
  Int_t     GetRefMultiplicityComb05() const { return fRefMultComb05; }
  Int_t     GetRefMultiplicityComb08() const { return fRefMultComb08; }

  Double_t  GetQTheta(UInt_t i) const;
  UInt_t    GetNQTheta() const { return (UInt_t)fNQTheta; }

  Double_t GetDiamondX() const {return fDiamondXY[0];}
  Double_t GetDiamondY() const {return fDiamondXY[1];}
  Double_t GetDiamondZ() const {return fDiamondZ;}
  Double_t GetSigma2DiamondX() const {return fDiamondCovXY[0];}
  Double_t GetSigma2DiamondY() const {return fDiamondCovXY[2];}
  Double_t GetSigma2DiamondZ() const {return fDiamondSig2Z;}
  void GetDiamondCovXY(Float_t cov[3]) const {
    for(Int_t i=0;i<3;i++) cov[i]=fDiamondCovXY[i]; return;
  }
  UInt_t   GetL0TriggerInputs() const {return fL0TriggerInputs;}  
  UInt_t   GetL1TriggerInputs() const {return fL1TriggerInputs;} 
  UShort_t GetL2TriggerInputs() const {return fL2TriggerInputs;} 
  AliCentrality* GetCentralityP()  const { return fCentralityP; }
  AliEventplane* GetEventplaneP()  const { return fEventplaneP; }

  
  void SetRunNumber(Int_t nRun)                { fRunNumber = nRun; }
  void SetEventNumberESDFile(Int_t n)          { fEventNumberESDFile=n; }
  void SetNumberOfESDTracks(Int_t n)           { fNumberESDTracks=n; }
  void SetBunchCrossNumber(UShort_t nBx)       { fBunchCrossNumber = nBx; }
  void SetOrbitNumber(UInt_t nOr)              { fOrbitNumber = nOr; }
  void SetPeriodNumber(UInt_t nPer)            { fPeriodNumber = nPer; }
  void SetTriggerMask(ULong64_t trigMsk)       { fTriggerMask = trigMsk; }
  void SetFiredTriggerClasses(TString trig)    { fFiredTriggers = trig;}
  void SetTriggerCluster(UChar_t trigClus)     { fTriggerCluster = trigClus; }
  void SetEventType(UInt_t evttype)            { fEventType = evttype; }
  void SetMagneticField(Double_t magFld)       { fMagneticField = magFld; }
  void SetMuonMagFieldScale(Double_t magFldScl){ fMuonMagFieldScale = magFldScl; }
  void SetCentrality(const AliCentrality* cent);
  void SetEventplane(AliEventplane* eventplane);
  void SetZDCN1Energy(Double_t n1Energy)       { fZDCN1Energy = n1Energy; }
  void SetZDCP1Energy(Double_t p1Energy)       { fZDCP1Energy = p1Energy; }
  void SetZDCN2Energy(Double_t n2Energy)       { fZDCN2Energy = n2Energy; }
  void SetZDCP2Energy(Double_t p2Energy)       { fZDCP2Energy = p2Energy; }
  void SetZDCEMEnergy(Double_t emEnergy1, Double_t emEnergy2)      
  	{ fZDCEMEnergy[0] = emEnergy1; fZDCEMEnergy[1] = emEnergy2;}
  void SetRefMultiplicity(Int_t refMult)       { fRefMult = refMult; }
  void SetRefMultiplicityPos(Int_t refMultPos) { fRefMultPos = refMultPos; }
  void SetRefMultiplicityNeg(Int_t refMultNeg) { fRefMultNeg = refMultNeg; }
  void SetNumberOfMuons(Int_t nMuons) { fNMuons = nMuons; }
  void SetNumberOfDimuons(Int_t nDimuons) { fNDimuons = nDimuons; }
  void SetNumberOfGlobalMuons(Int_t nGlobalMuons) { fNGlobalMuons = nGlobalMuons; }            // AU
  void SetNumberOfGlobalDimuons(Int_t nGlobalDimuons) { fNGlobalDimuons = nGlobalDimuons; }    // AU
  void SetRefMultiplicityComb05(Int_t refMult)   { fRefMultComb05 = refMult; }
  void SetRefMultiplicityComb08(Int_t refMult)   { fRefMultComb08 = refMult; }  

  void SetQTheta(Double_t *QTheta, UInt_t size = 5);  
  void RemoveQTheta();

  void ResetEventplanePointer();
  
  void SetDiamond(Float_t xy[2],Float_t cov[3]) { 
    for(Int_t i=0;i<3;i++) {fDiamondCovXY[i] = cov[i];}
    for(Int_t i=0;i<2;i++) {fDiamondXY[i]    = xy[i] ;}
  }
  void SetDiamondZ(Float_t z, Float_t sig2z){
    fDiamondZ=z; fDiamondSig2Z=sig2z;
  }
  void SetL0TriggerInputs(UInt_t n)   {fL0TriggerInputs=n;}
  void SetL1TriggerInputs(UInt_t n)   {fL1TriggerInputs=n;}
  void SetL2TriggerInputs(UShort_t n) {fL2TriggerInputs=n;}
  void SetESDFileName(TString name)   {fESDFileName = name;}
  void Print(Option_t* option = "") const;

  void    SetPHOSMatrix(TGeoHMatrix*matrix, Int_t i) {
      if ((i >= 0) && (i < kNPHOSMatrix)) fPHOSMatrix[i] = matrix;
  }
  const TGeoHMatrix* GetPHOSMatrix(Int_t i) const {
      return ((i >= 0) && (i < kNPHOSMatrix)) ? fPHOSMatrix[i] : NULL;
  }
  
  void    SetEMCALMatrix(TGeoHMatrix*matrix, Int_t i) {
      if ((i >= 0) && (i < kNEMCALMatrix)) fEMCALMatrix[i] = matrix;
  }
  const TGeoHMatrix* GetEMCALMatrix(Int_t i) const {
      return ((i >= 0) && (i < kNEMCALMatrix)) ? fEMCALMatrix[i] : NULL;
  }
  
  UInt_t GetOfflineTrigger() { return fOfflineTrigger; }
  void   SetOfflineTrigger(UInt_t trigger) { fOfflineTrigger = trigger; }
  UInt_t GetNumberOfITSClusters(Int_t ilay) const {return fITSClusters[ilay];}
  void   SetITSClusters(Int_t ilay, UInt_t nclus);
  Int_t  GetTPConlyRefMultiplicity() const {return fTPConlyRefMult;}
  void   SetTPConlyRefMultiplicity(Int_t mult) {fTPConlyRefMult = mult;} 
  
  TString GetESDFileName() const  {return fESDFileName;}
  void Clear(Option_t* = "");
  enum {kNPHOSMatrix = 5};
  enum {kNEMCALMatrix = 22}; 
  enum {kT0SpreadSize = 4};

  void           SetVZEROEqFactors(const Float_t* factors) {
    if (factors)
      for (Int_t i = 0; i < 64; ++i) fVZEROEqFactors[i] = factors[i];}
  const Float_t* GetVZEROEqFactors() const {return fVZEROEqFactors;}
  Float_t        GetVZEROEqFactors(Int_t i) const {return fVZEROEqFactors[i];}
  Float_t    GetT0spread(Int_t i) const {
    return ((i >= 0)  && (i<kT0SpreadSize)) ? fT0spread[i] : 0;}
  void       SetT0spread(Int_t i, Float_t t) {
    if ((i>=0)&&(i<kT0SpreadSize)) fT0spread[i]=t;}

  Int_t  FindIRIntInteractionsBXMap(Int_t difference) const;
  void   SetIRInt2InteractionMap(TBits bits) { fIRInt2InteractionsMap = bits; }
  void   SetIRInt1InteractionMap(TBits bits) { fIRInt1InteractionsMap = bits; }
  TBits  GetIRInt2InteractionMap() const { return fIRInt2InteractionsMap; }
  TBits  GetIRInt1InteractionMap() const { return fIRInt1InteractionsMap; }
  Int_t  GetIRInt2ClosestInteractionMap() const;
  Int_t  GetIRInt1ClosestInteractionMap(Int_t gap = 3) const;
  Int_t  GetIRInt2LastInteractionMap() const;
  
 private :
  
  Double32_t  fMagneticField;       // Solenoid Magnetic Field in kG
  Double32_t  fMuonMagFieldScale;   // magnetic field scale of muon arm magnet
  Double32_t  fCentrality;          // Centrality
  Double32_t  fEventplane;          // Event plane angle
  Double32_t  fEventplaneMag;       // Length of Q vector from TPC event plance
  Double32_t  fEventplaneQx;        // Q vector component x from TPC event plance
  Double32_t  fEventplaneQy;        // Q vector component y from TPC event plance
  Double32_t  fZDCN1Energy;         // reconstructed energy in the neutron1 ZDC
  Double32_t  fZDCP1Energy;         // reconstructed energy in the proton1 ZDC
  Double32_t  fZDCN2Energy;         // reconstructed energy in the neutron2 ZDC
  Double32_t  fZDCP2Energy;         // reconstructed energy in the proton2 ZDC
  Double32_t  fZDCEMEnergy[2];      // reconstructed energy in the electromagnetic ZDCs
  Int_t       fNQTheta;             // number of QTheta elements
  Double32_t *fQTheta;              // [fNQTheta] values to store Lee-Yang-Zeros
  ULong64_t   fTriggerMask;         // Trigger Type (mask)
  TString     fFiredTriggers;       // String with fired triggers
  Int_t       fRunNumber;           // Run Number
  Int_t       fRefMult;             // reference multiplicity
  Int_t       fRefMultPos;          // reference multiplicity of positive particles
  Int_t       fRefMultNeg;          // reference multiplicity of negative particles
  Int_t       fNMuons;              // number of muons in the forward spectrometer
  Int_t       fNDimuons;            // number of dimuons in the forward spectrometer
  Int_t       fNGlobalMuons;        // number of muons in the forward spectrometer + MFT       // AU
  Int_t       fNGlobalDimuons;      // number of dimuons in the forward spectrometer + MFT     // AU
  UInt_t      fEventType;           // Type of Event
  UInt_t      fOrbitNumber;         // Orbit Number
  UInt_t      fPeriodNumber;        // Period Number
  UShort_t    fBunchCrossNumber;    // BunchCrossingNumber
  Short_t     fRefMultComb05;       // combined reference multiplicity (tracklets + ITSTPC) in |eta|<0.5
  Short_t     fRefMultComb08;       // combined reference multiplicity (tracklets + ITSTPC) in |eta|<0.8
  UChar_t     fTriggerCluster;      // Trigger cluster (mask)
  Double32_t      fDiamondXY[2];    // Interaction diamond (x,y) in RUN
  Double32_t      fDiamondCovXY[3]; // Interaction diamond covariance (x,y) in RUN
  Double32_t      fDiamondZ;        // Interaction diamond (z) in RUN
  Double32_t      fDiamondSig2Z;    // Interaction diamond sigma^2 (z) in RUN
  TGeoHMatrix*    fPHOSMatrix[kNPHOSMatrix];   //PHOS module position and orientation matrices
  TGeoHMatrix*    fEMCALMatrix[kNEMCALMatrix]; //EMCAL supermodule position and orientation matrices
  UInt_t      fOfflineTrigger;      // fired offline triggers for this event
  TString     fESDFileName;         // ESD file name to which this event belongs
  Int_t       fEventNumberESDFile;  // Event number in ESD file
  Int_t       fNumberESDTracks;     // Number of tracks in origingal ESD event
  UInt_t      fL0TriggerInputs;     // L0 Trigger Inputs (mask)
  UInt_t      fL1TriggerInputs;     // L1 Trigger Inputs (mask)
  UShort_t    fL2TriggerInputs;     // L2 Trigger Inputs (mask)
  UInt_t      fITSClusters[6];      // Number of ITS cluster per layer
  Int_t       fTPConlyRefMult;      // Reference multiplicty for standard TPC only tracks
  AliCentrality* fCentralityP;      // Pointer to full centrality information
  AliEventplane* fEventplaneP;	    // Pointer to full event plane information
  Float_t     fVZEROEqFactors[64];  // V0 channel equalization factors for event-plane reconstruction
  Float_t     fT0spread[kT0SpreadSize]; // spread of time distributions: (TOA+T0C/2), T0A, T0C, (T0A-T0C)/2
  TBits   fIRInt2InteractionsMap;  // map of the Int2 events (normally 0TVX) near the event, that's Int2Id-EventId in a -90 to 90 window
  TBits   fIRInt1InteractionsMap;  // map of the Int1 events (normally V0A&V0C) near the event, that's Int1Id-EventId in a -90 to 90 window
  ClassDef(AliAODHeader, 24);
};
inline
void AliAODHeader::SetCentrality(const AliCentrality* cent)      { 
    if(cent){
	if(fCentralityP)*fCentralityP = *cent;
	else fCentralityP = new AliCentrality(*cent);
	fCentrality = cent->GetCentralityPercentile("V0M");
    }
    else{
	fCentrality = -999;
    }
}
inline
void AliAODHeader::SetEventplane(AliEventplane* eventplane)      { 
    if(eventplane){
	if(fEventplaneP)*fEventplaneP = *eventplane;
	else fEventplaneP = new AliEventplane(*eventplane);
	fEventplane = eventplane->GetEventplane("Q");
        const TVector2* qvect=eventplane->GetQVector();
        fEventplaneMag = -999;
	fEventplaneQx = -999;
	fEventplaneQy = -999;
        if (qvect) {
	  fEventplaneMag=qvect->Mod();
	  fEventplaneQx=qvect->X();
	  fEventplaneQy=qvect->Y();
	}
    }
    else{
	fEventplane = -999;
        fEventplaneMag = -999;
	fEventplaneQx = -999;
	fEventplaneQy = -999;
    }
}
inline
void AliAODHeader::ResetEventplanePointer()      {
  delete fEventplaneP;
  fEventplaneP = 0x0;
}

inline
void AliAODHeader::SetITSClusters(Int_t ilay, UInt_t nclus)
{
    if (ilay >= 0 && ilay < 6) fITSClusters[ilay] = nclus;
}


#endif
Commit	Line	Data
77f43bb7	1	#ifndef ALIAODHEADER_H
77f43bb7	2	#define ALIAODHEADER_H
df9db588	3	/* Copyright(c) 1998-2007, ALICE Experiment at CERN, All rights reserved. *
	4	* See cxx source for full Copyright notice */
	5
	6	/* $Id$ */
	7
	8	//-------------------------------------------------------------------------
9ae2e5e6	9	// AOD event header class
df9db588	10	// Author: Markus Oldenburg, CERN
	11	//-------------------------------------------------------------------------
	12
c7d82ff7	13	#include <TVector2.h>
c7d82ff7	14
9ae2e5e6	15	#include "AliVHeader.h"
df9db588	16	#include "AliAODVertex.h"
a5f7aba4	17	#include <TString.h>
4ccebdba	18	#include <TBits.h>
f1c1d7c6	19	#include "AliCentrality.h"
ce7adfe9	20	#include "AliEventplane.h"
df9db588	21
1aa76f71	22	class TGeoHMatrix;
27346f69	23	class TString;
1aa76f71	24
f1c1d7c6	25
9ae2e5e6	26	class AliAODHeader : public AliVHeader {
df9db588	27
df9db588	28	public :
31fd97b2	29	AliAODHeader();
df9db588	30
abfce367	31	AliAODHeader(Int_t nRun, UShort_t nBunchX, UInt_t nOrbit, UInt_t nPeriod, const Char_t *title="");
31fd97b2	32	AliAODHeader(Int_t nRun,
	33	UShort_t nBunchX,
	34	UInt_t nOrbit,
89cf15db	35	UInt_t nPeriod,
31fd97b2	36	Int_t refMult,
	37	Int_t refMultPos,
	38	Int_t refMultNeg,
e9f4e33d	39	Int_t refMultComb05,
e9f4e33d	40	Int_t refMultComb08,
31fd97b2	41	Double_t magField,
6b6f8d32	42	Double_t muonMagFieldScale,
6b6f8d32	43	Double_t cent,
ce7adfe9	44	Double_t eventplane,
6b6f8d32	45	Double_t n1Energy,
	46	Double_t p1Energy,
	47	Double_t n2Energy,
	48	Double_t p2Energy,
a85132e7	49	Double_t *emEnergy,
31fd97b2	50	ULong64_t fTriggerMask,
	51	UChar_t fTriggerCluster,
	52	UInt_t fEventType,
5e14e698	53	const Float_t *vzeroEqFactors,
fa8b0e56	54	const Char_t *title="",
fa8b0e56	55	Int_t nMuons=0,
f7cc8591	56	Int_t nDimuons=0,
	57	Int_t nGlobalMuons=0, // AU
	58	Int_t nGlobalDimuons=0); // AU
31fd97b2	59
df9db588	60	virtual ~AliAODHeader();
	61	AliAODHeader(const AliAODHeader& evt);
	62	AliAODHeader& operator=(const AliAODHeader& evt);
127be208	63	Bool_t InitMagneticField() const;
a5f7aba4	64
	65	Int_t GetRunNumber() const { return fRunNumber;}
	66	Int_t GetEventNumberESDFile() const { return fEventNumberESDFile;}
ef7661fd	67	Int_t GetNumberOfESDTracks() const { return fNumberESDTracks;}
31fd97b2	68	UShort_t GetBunchCrossNumber() const { return fBunchCrossNumber; }
31fd97b2	69	UInt_t GetOrbitNumber() const { return fOrbitNumber; }
89cf15db	70	UInt_t GetPeriodNumber() const { return fPeriodNumber; }
df9db588	71	ULong64_t GetTriggerMask() const { return fTriggerMask; }
df9db588	72	UChar_t GetTriggerCluster() const { return fTriggerCluster; }
27346f69	73	TString GetFiredTriggerClasses()const { return fFiredTriggers;}
df9db588	74	UInt_t GetEventType() const { return fEventType; }
df9db588	75	Double_t GetMagneticField() const { return fMagneticField; }
6b6f8d32	76	Double_t GetMuonMagFieldScale() const { return fMuonMagFieldScale; }
6b6f8d32	77
df9db588	78	Double_t GetCentrality() const { return fCentrality; }
ce7adfe9	79	Double_t GetEventplane() const { return fEventplane; }
a52246de	80	Double_t GetEventplaneMag() const { return fEventplaneMag; }
5a3b31b5	81	Double_t GetEventplaneQx() const { return fEventplaneQx; }
5a3b31b5	82	Double_t GetEventplaneQy() const { return fEventplaneQy; }
6b6f8d32	83	Double_t GetZDCN1Energy() const { return fZDCN1Energy; }
	84	Double_t GetZDCP1Energy() const { return fZDCP1Energy; }
	85	Double_t GetZDCN2Energy() const { return fZDCN2Energy; }
	86	Double_t GetZDCP2Energy() const { return fZDCP2Energy; }
a85132e7	87	Double_t GetZDCEMEnergy(Int_t i) const { return fZDCEMEnergy[i]; }
df9db588	88	Int_t GetRefMultiplicity() const { return fRefMult; }
	89	Int_t GetRefMultiplicityPos() const { return fRefMultPos; }
	90	Int_t GetRefMultiplicityNeg() const { return fRefMultNeg; }
fa8b0e56	91	Int_t GetNumberOfMuons() const { return fNMuons; }
fa8b0e56	92	Int_t GetNumberOfDimuons() const { return fNDimuons; }
f7cc8591	93	Int_t GetNumberOfGlobalMuons() const { return fNGlobalMuons; } // AU
f7cc8591	94	Int_t GetNumberOfGlobalDimuons() const { return fNGlobalDimuons; } // AU
e9f4e33d	95	Int_t GetRefMultiplicityComb05() const { return fRefMultComb05; }
e9f4e33d	96	Int_t GetRefMultiplicityComb08() const { return fRefMultComb08; }
ff254193	97
	98	Double_t GetQTheta(UInt_t i) const;
	99	UInt_t GetNQTheta() const { return (UInt_t)fNQTheta; }
613fc341	100
	101	Double_t GetDiamondX() const {return fDiamondXY[0];}
	102	Double_t GetDiamondY() const {return fDiamondXY[1];}
49fc2e2c	103	Double_t GetDiamondZ() const {return fDiamondZ;}
613fc341	104	Double_t GetSigma2DiamondX() const {return fDiamondCovXY[0];}
613fc341	105	Double_t GetSigma2DiamondY() const {return fDiamondCovXY[2];}
49fc2e2c	106	Double_t GetSigma2DiamondZ() const {return fDiamondSig2Z;}
613fc341	107	void GetDiamondCovXY(Float_t cov[3]) const {
	108	for(Int_t i=0;i<3;i++) cov[i]=fDiamondCovXY[i]; return;
	109	}
a5f7aba4	110	UInt_t GetL0TriggerInputs() const {return fL0TriggerInputs;}
	111	UInt_t GetL1TriggerInputs() const {return fL1TriggerInputs;}
	112	UShort_t GetL2TriggerInputs() const {return fL2TriggerInputs;}
f1c1d7c6	113	AliCentrality* GetCentralityP() const { return fCentralityP; }
ce7adfe9	114	AliEventplane* GetEventplaneP() const { return fEventplaneP; }
a5f7aba4	115
6b6f8d32	116
df9db588	117	void SetRunNumber(Int_t nRun) { fRunNumber = nRun; }
a5f7aba4	118	void SetEventNumberESDFile(Int_t n) { fEventNumberESDFile=n; }
ef7661fd	119	void SetNumberOfESDTracks(Int_t n) { fNumberESDTracks=n; }
31fd97b2	120	void SetBunchCrossNumber(UShort_t nBx) { fBunchCrossNumber = nBx; }
9ae2e5e6	121	void SetOrbitNumber(UInt_t nOr) { fOrbitNumber = nOr; }
9ae2e5e6	122	void SetPeriodNumber(UInt_t nPer) { fPeriodNumber = nPer; }
df9db588	123	void SetTriggerMask(ULong64_t trigMsk) { fTriggerMask = trigMsk; }
27346f69	124	void SetFiredTriggerClasses(TString trig) { fFiredTriggers = trig;}
df9db588	125	void SetTriggerCluster(UChar_t trigClus) { fTriggerCluster = trigClus; }
	126	void SetEventType(UInt_t evttype) { fEventType = evttype; }
	127	void SetMagneticField(Double_t magFld) { fMagneticField = magFld; }
6b6f8d32	128	void SetMuonMagFieldScale(Double_t magFldScl){ fMuonMagFieldScale = magFldScl; }
77f43bb7	129	void SetCentrality(const AliCentrality* cent);
ce7adfe9	130	void SetEventplane(AliEventplane* eventplane);
6b6f8d32	131	void SetZDCN1Energy(Double_t n1Energy) { fZDCN1Energy = n1Energy; }
	132	void SetZDCP1Energy(Double_t p1Energy) { fZDCP1Energy = p1Energy; }
	133	void SetZDCN2Energy(Double_t n2Energy) { fZDCN2Energy = n2Energy; }
	134	void SetZDCP2Energy(Double_t p2Energy) { fZDCP2Energy = p2Energy; }
a85132e7	135	void SetZDCEMEnergy(Double_t emEnergy1, Double_t emEnergy2)
a85132e7	136	{ fZDCEMEnergy[0] = emEnergy1; fZDCEMEnergy[1] = emEnergy2;}
df9db588	137	void SetRefMultiplicity(Int_t refMult) { fRefMult = refMult; }
	138	void SetRefMultiplicityPos(Int_t refMultPos) { fRefMultPos = refMultPos; }
	139	void SetRefMultiplicityNeg(Int_t refMultNeg) { fRefMultNeg = refMultNeg; }
fa8b0e56	140	void SetNumberOfMuons(Int_t nMuons) { fNMuons = nMuons; }
fa8b0e56	141	void SetNumberOfDimuons(Int_t nDimuons) { fNDimuons = nDimuons; }
f7cc8591	142	void SetNumberOfGlobalMuons(Int_t nGlobalMuons) { fNGlobalMuons = nGlobalMuons; } // AU
f7cc8591	143	void SetNumberOfGlobalDimuons(Int_t nGlobalDimuons) { fNGlobalDimuons = nGlobalDimuons; } // AU
e9f4e33d	144	void SetRefMultiplicityComb05(Int_t refMult) { fRefMultComb05 = refMult; }
	145	void SetRefMultiplicityComb08(Int_t refMult) { fRefMultComb08 = refMult; }
	146
ff254193	147	void SetQTheta(Double_t *QTheta, UInt_t size = 5);
	148	void RemoveQTheta();
	149
c7d82ff7	150	void ResetEventplanePointer();
c7d82ff7	151
613fc341	152	void SetDiamond(Float_t xy[2],Float_t cov[3]) {
11becff8	153	for(Int_t i=0;i<3;i++) {fDiamondCovXY[i] = cov[i];}
11becff8	154	for(Int_t i=0;i<2;i++) {fDiamondXY[i] = xy[i] ;}
613fc341	155	}
49fc2e2c	156	void SetDiamondZ(Float_t z, Float_t sig2z){
	157	fDiamondZ=z; fDiamondSig2Z=sig2z;
	158	}
a5f7aba4	159	void SetL0TriggerInputs(UInt_t n) {fL0TriggerInputs=n;}
	160	void SetL1TriggerInputs(UInt_t n) {fL1TriggerInputs=n;}
	161	void SetL2TriggerInputs(UShort_t n) {fL2TriggerInputs=n;}
	162	void SetESDFileName(TString name) {fESDFileName = name;}
df9db588	163	void Print(Option_t* option = "") const;
1aa76f71	164
	165	void SetPHOSMatrix(TGeoHMatrix*matrix, Int_t i) {
	166	if ((i >= 0) && (i < kNPHOSMatrix)) fPHOSMatrix[i] = matrix;
	167	}
	168	const TGeoHMatrix* GetPHOSMatrix(Int_t i) const {
	169	return ((i >= 0) && (i < kNPHOSMatrix)) ? fPHOSMatrix[i] : NULL;
	170	}
6b6f8d32	171
1aa76f71	172	void SetEMCALMatrix(TGeoHMatrix*matrix, Int_t i) {
	173	if ((i >= 0) && (i < kNEMCALMatrix)) fEMCALMatrix[i] = matrix;
	174	}
	175	const TGeoHMatrix* GetEMCALMatrix(Int_t i) const {
	176	return ((i >= 0) && (i < kNEMCALMatrix)) ? fEMCALMatrix[i] : NULL;
	177	}
	178
0c6c629b	179	UInt_t GetOfflineTrigger() { return fOfflineTrigger; }
f7ce7a37	180	void SetOfflineTrigger(UInt_t trigger) { fOfflineTrigger = trigger; }
	181	UInt_t GetNumberOfITSClusters(Int_t ilay) const {return fITSClusters[ilay];}
	182	void SetITSClusters(Int_t ilay, UInt_t nclus);
	183	Int_t GetTPConlyRefMultiplicity() const {return fTPConlyRefMult;}
	184	void SetTPConlyRefMultiplicity(Int_t mult) {fTPConlyRefMult = mult;}
	185
5e6a3170	186	TString GetESDFileName() const {return fESDFileName;}
99dbf027	187	void Clear(Option_t* = "");
1aa76f71	188	enum {kNPHOSMatrix = 5};
8cc543cb	189	enum {kNEMCALMatrix = 22};
949be341	190	enum {kT0SpreadSize = 4};
5e14e698	191
	192	void SetVZEROEqFactors(const Float_t* factors) {
	193	if (factors)
	194	for (Int_t i = 0; i < 64; ++i) fVZEROEqFactors[i] = factors[i];}
	195	const Float_t* GetVZEROEqFactors() const {return fVZEROEqFactors;}
	196	Float_t GetVZEROEqFactors(Int_t i) const {return fVZEROEqFactors[i];}
949be341	197	Float_t GetT0spread(Int_t i) const {
	198	return ((i >= 0) && (i<kT0SpreadSize)) ? fT0spread[i] : 0;}
	199	void SetT0spread(Int_t i, Float_t t) {
	200	if ((i>=0)&&(i<kT0SpreadSize)) fT0spread[i]=t;}
	201
299994c6	202	Int_t FindIRIntInteractionsBXMap(Int_t difference) const;
4ccebdba	203	void SetIRInt2InteractionMap(TBits bits) { fIRInt2InteractionsMap = bits; }
4ccebdba	204	void SetIRInt1InteractionMap(TBits bits) { fIRInt1InteractionsMap = bits; }
299994c6	205	TBits GetIRInt2InteractionMap() const { return fIRInt2InteractionsMap; }
	206	TBits GetIRInt1InteractionMap() const { return fIRInt1InteractionsMap; }
	207	Int_t GetIRInt2ClosestInteractionMap() const;
	208	Int_t GetIRInt1ClosestInteractionMap(Int_t gap = 3) const;
	209	Int_t GetIRInt2LastInteractionMap() const;
6b6f8d32	210
df9db588	211	private :
6b6f8d32	212
	213	Double32_t fMagneticField; // Solenoid Magnetic Field in kG
	214	Double32_t fMuonMagFieldScale; // magnetic field scale of muon arm magnet
	215	Double32_t fCentrality; // Centrality
ce7adfe9	216	Double32_t fEventplane; // Event plane angle
c7d82ff7	217	Double32_t fEventplaneMag; // Length of Q vector from TPC event plance
5a3b31b5	218	Double32_t fEventplaneQx; // Q vector component x from TPC event plance
5a3b31b5	219	Double32_t fEventplaneQy; // Q vector component y from TPC event plance
6b6f8d32	220	Double32_t fZDCN1Energy; // reconstructed energy in the neutron1 ZDC
	221	Double32_t fZDCP1Energy; // reconstructed energy in the proton1 ZDC
	222	Double32_t fZDCN2Energy; // reconstructed energy in the neutron2 ZDC
	223	Double32_t fZDCP2Energy; // reconstructed energy in the proton2 ZDC
a85132e7	224	Double32_t fZDCEMEnergy[2]; // reconstructed energy in the electromagnetic ZDCs
ff254193	225	Int_t fNQTheta; // number of QTheta elements
ff254193	226	Double32_t *fQTheta; // [fNQTheta] values to store Lee-Yang-Zeros
6b6f8d32	227	ULong64_t fTriggerMask; // Trigger Type (mask)
27346f69	228	TString fFiredTriggers; // String with fired triggers
6b6f8d32	229	Int_t fRunNumber; // Run Number
	230	Int_t fRefMult; // reference multiplicity
	231	Int_t fRefMultPos; // reference multiplicity of positive particles
	232	Int_t fRefMultNeg; // reference multiplicity of negative particles
fa8b0e56	233	Int_t fNMuons; // number of muons in the forward spectrometer
fa8b0e56	234	Int_t fNDimuons; // number of dimuons in the forward spectrometer
f7cc8591	235	Int_t fNGlobalMuons; // number of muons in the forward spectrometer + MFT // AU
f7cc8591	236	Int_t fNGlobalDimuons; // number of dimuons in the forward spectrometer + MFT // AU
9333290e	237	UInt_t fEventType; // Type of Event
	238	UInt_t fOrbitNumber; // Orbit Number
	239	UInt_t fPeriodNumber; // Period Number
	240	UShort_t fBunchCrossNumber; // BunchCrossingNumber
e9f4e33d	241	Short_t fRefMultComb05; // combined reference multiplicity (tracklets + ITSTPC) in \|eta\|<0.5
e9f4e33d	242	Short_t fRefMultComb08; // combined reference multiplicity (tracklets + ITSTPC) in \|eta\|<0.8
6b6f8d32	243	UChar_t fTriggerCluster; // Trigger cluster (mask)
613fc341	244	Double32_t fDiamondXY[2]; // Interaction diamond (x,y) in RUN
613fc341	245	Double32_t fDiamondCovXY[3]; // Interaction diamond covariance (x,y) in RUN
49fc2e2c	246	Double32_t fDiamondZ; // Interaction diamond (z) in RUN
49fc2e2c	247	Double32_t fDiamondSig2Z; // Interaction diamond sigma^2 (z) in RUN
1aa76f71	248	TGeoHMatrix* fPHOSMatrix[kNPHOSMatrix]; //PHOS module position and orientation matrices
1aa76f71	249	TGeoHMatrix* fEMCALMatrix[kNEMCALMatrix]; //EMCAL supermodule position and orientation matrices
0c6c629b	250	UInt_t fOfflineTrigger; // fired offline triggers for this event
a5f7aba4	251	TString fESDFileName; // ESD file name to which this event belongs
a5f7aba4	252	Int_t fEventNumberESDFile; // Event number in ESD file
ef7661fd	253	Int_t fNumberESDTracks; // Number of tracks in origingal ESD event
a5f7aba4	254	UInt_t fL0TriggerInputs; // L0 Trigger Inputs (mask)
	255	UInt_t fL1TriggerInputs; // L1 Trigger Inputs (mask)
	256	UShort_t fL2TriggerInputs; // L2 Trigger Inputs (mask)
f7ce7a37	257	UInt_t fITSClusters[6]; // Number of ITS cluster per layer
f7ce7a37	258	Int_t fTPConlyRefMult; // Reference multiplicty for standard TPC only tracks
f1c1d7c6	259	AliCentrality* fCentralityP; // Pointer to full centrality information
ce7adfe9	260	AliEventplane* fEventplaneP; // Pointer to full event plane information
5e14e698	261	Float_t fVZEROEqFactors[64]; // V0 channel equalization factors for event-plane reconstruction
949be341	262	Float_t fT0spread[kT0SpreadSize]; // spread of time distributions: (TOA+T0C/2), T0A, T0C, (T0A-T0C)/2
4ccebdba	263	TBits fIRInt2InteractionsMap; // map of the Int2 events (normally 0TVX) near the event, that's Int2Id-EventId in a -90 to 90 window
4ccebdba	264	TBits fIRInt1InteractionsMap; // map of the Int1 events (normally V0A&V0C) near the event, that's Int1Id-EventId in a -90 to 90 window
f7cc8591	265	ClassDef(AliAODHeader, 24);
df9db588	266	};
5e6a3170	267	inline
77f43bb7	268	void AliAODHeader::SetCentrality(const AliCentrality* cent) {
5e6a3170	269	if(cent){
	270	if(fCentralityP)fCentralityP = cent;
	271	else fCentralityP = new AliCentrality(*cent);
	272	fCentrality = cent->GetCentralityPercentile("V0M");
	273	}
	274	else{
	275	fCentrality = -999;
	276	}
	277	}
ce7adfe9	278	inline
	279	void AliAODHeader::SetEventplane(AliEventplane* eventplane) {
	280	if(eventplane){
	281	if(fEventplaneP)fEventplaneP = eventplane;
	282	else fEventplaneP = new AliEventplane(*eventplane);
	283	fEventplane = eventplane->GetEventplane("Q");
c7d82ff7	284	const TVector2* qvect=eventplane->GetQVector();
c7d82ff7	285	fEventplaneMag = -999;
5a3b31b5	286	fEventplaneQx = -999;
	287	fEventplaneQy = -999;
	288	if (qvect) {
	289	fEventplaneMag=qvect->Mod();
	290	fEventplaneQx=qvect->X();
	291	fEventplaneQy=qvect->Y();
	292	}
ce7adfe9	293	}
	294	else{
	295	fEventplane = -999;
c7d82ff7	296	fEventplaneMag = -999;
5a3b31b5	297	fEventplaneQx = -999;
5a3b31b5	298	fEventplaneQy = -999;
ce7adfe9	299	}
ce7adfe9	300	}
c7d82ff7	301	inline
	302	void AliAODHeader::ResetEventplanePointer() {
	303	delete fEventplaneP;
	304	fEventplaneP = 0x0;
	305	}
f7ce7a37	306
	307	inline
	308	void AliAODHeader::SetITSClusters(Int_t ilay, UInt_t nclus)
	309	{
	310	if (ilay >= 0 && ilay < 6) fITSClusters[ilay] = nclus;
	311	}
	312
	313
df9db588	314	#endif