DataTree/interface/Electron.h

//--------------------------------------------------------------------------------------------------
// $Id: Electron.h,v 1.33 2009/07/07 08:31:45 bendavid Exp $
//
// Electron
//
// This class holds information about reconstructed electrons from CMSSW.
//
// Authors: C.Loizides, J.Bendavid, S.Xie
//--------------------------------------------------------------------------------------------------

#ifndef MITANA_DATATREE_ELECTRON_H
#define MITANA_DATATREE_ELECTRON_H
 
#include "MitAna/DataTree/interface/SuperCluster.h"
#include "MitAna/DataTree/interface/ChargedParticle.h"
#include "MitAna/DataCont/interface/Ref.h"

namespace mithep 
{
  class Electron : public ChargedParticle
  {
    public:
      Electron() : 
        fESuperClusterOverP(0), fESeedClusterOverPout(0), fDeltaEtaSuperClTrkAtVtx(0),
        fDeltaEtaSeedClTrkAtCalo(0), fDeltaPhiSuperClTrkAtVtx(0), 
        fDeltaPhiSeedClTrkAtCalo(0), fFBrem(0), fHadronicOverEm(0), fHcalDepth1OverEcal(0),
        fHcalDepth2OverEcal(0), fNumberOfClusters(0), fE15(0), fE25Max(0), fE33(0),
        fE55(0), fCovEtaEta(0), fCoviEtaiEta(0), fCovEtaPhi(0), fCovPhiPhi(0),
        fCaloIsolation(0), fHcalJurassicIsolation(0),
        fHcalDepth1TowerSumEtDr04(0), fHcalDepth2TowerSumEtDr04(0),
        fEcalJurassicIsolation(0), fTrackIsolationDr04(0), fCaloTowerIsolation(0),
        fHcalDepth1TowerSumEtDr03(0), fHcalDepth2TowerSumEtDr03(0),
        fEcalRecHitSumEtDr03(0), fTrackIsolation(0), fPassLooseID(0),
        fPassTightID(0), fIDLikelihood(0), fPIn(0), fPOut(0), fFracSharedHits(0),
        fMva(0), fIsEnergyScaleCorrected(0), fIsMomentumCorrected(0),
        fClassification(0), fIsEB(), fIsEE(0), fIsEBEEGap(0), fIsEBEtaGap(0),
        fIsEBPhiGap(0), fIsEEDeeGap(0), fIsEERingGap(0),
        fIsEcalDriven(0), fIsTrackerDriven(0) {}

      const Track         *BestTrk()                const;
      Double_t             CaloIsolation()          const { return fCaloIsolation;       } //*DEPRECATED*
      Double_t             CaloTowerIsolation()     const { return HcalTowerSumEtDr03(); } //*DEPRECATED*
      Int_t                Classification()         const { return fClassification;      }
      Double_t             CovEtaEta()              const { return fCovEtaEta;           }
      Double_t             CovEtaPhi()              const { return fCovEtaPhi;           } //*DEPRECATED*
      Double_t             CovPhiPhi()              const { return fCovPhiPhi;           } //*DEPRECATED*
      Double_t             CoviEtaiEta()            const { return fCoviEtaiEta;         }
      Double_t             DeltaEtaSuperClusterTrackAtVtx() const 
                             { return fDeltaEtaSuperClTrkAtVtx; }
      Double_t             DeltaEtaSeedClusterTrackAtCalo() const 
                             { return fDeltaEtaSeedClTrkAtCalo; }
      Double_t             DeltaPhiSuperClusterTrackAtVtx() const 
                             { return fDeltaPhiSuperClTrkAtVtx; }
      Double_t             DeltaPhiSeedClusterTrackAtCalo() const 
                             { return fDeltaPhiSeedClTrkAtCalo; }
      Double_t             E15()                    const { return fE15;                }
      Double_t             E25Max()                 const { return fE25Max;             }
      Double_t             E33()                    const { return fE33;                } //*DEPRECATED*
      Double_t             E55()                    const { return fE55;                }
      Double_t             EcalJurassicIsolation()  const { return EcalRecHitIsoDr04(); } //*DEPRECATED*
      Double_t             ESuperClusterOverP()     const { return fESuperClusterOverP;            }
      Double_t             ESeedClusterOverPout()   const { return fESeedClusterOverPout;          }
      Double_t             ESeedClusterOverPIn()    const;
      Double_t             FBrem()                  const { return fFBrem;                         }
      Double_t             FBremOld()               const { return (PIn() - POut())/PIn();         }
      Double_t             FracSharedHits()         const { return fFracSharedHits;                }
      const Track         *GsfTrk()                 const { return fGsfTrackRef.Obj();             }
      Double_t             HadronicOverEm()         const { return fHadronicOverEm;                }
      Double_t             HcalDepth1OverEcal()     const { return fHcalDepth1OverEcal;            }
      Double_t             HcalDepth2OverEcal()     const { return fHcalDepth2OverEcal;            }
      Bool_t               HasGsfTrk()              const { return fGsfTrackRef.IsValid();         }
      Bool_t               HasTrackerTrk()          const { return fTrackerTrackRef.IsValid();     }
      Bool_t               HasSuperCluster()        const { return fSuperClusterRef.IsValid();     }
      Double_t             HcalIsolation()          const { return fHcalJurassicIsolation;         } //*DEPRECATED*
      Double_t             IDLikelihood()           const { return fIDLikelihood;                  }
      Bool_t               IsEnergyScaleCorrected() const { return fIsEnergyScaleCorrected;        }
      Bool_t               IsMomentumCorrected()    const { return fIsMomentumCorrected;           }
      Bool_t               IsEB()                   const { return fIsEB;                          }
      Bool_t               IsEE()                   const { return fIsEE;                          }
      Bool_t               IsEBEEGap()              const { return fIsEBEEGap;                     }
      Bool_t               IsEBEtaGap()             const { return fIsEBEtaGap;                    }
      Bool_t               IsEBPhiGap()             const { return fIsEBPhiGap;                    }
      Bool_t               IsEEDeeGap()             const { return fIsEEDeeGap;                    }
      Bool_t               IsEERingGap()            const { return fIsEERingGap;                   }
      Bool_t               IsEcalDriven()           const { return fIsEcalDriven;                  }
      Bool_t               IsTrackerDriven()        const { return fIsTrackerDriven;               }
      Double_t             Mva()                    const { return fMva;                           }
      Double_t             NumberOfClusters()       const { return fNumberOfClusters;              }
      EObjType             ObjType()                const { return kElectron;                      }
      Double_t             PassLooseID()            const { return fPassLooseID;                   }
      Double_t             PassTightID()            const { return fPassTightID;                   }
      Double_t             PIn()                    const { return fPIn;                           }
      Double_t             POut()                   const { return fPOut;                          }
      const SuperCluster  *SCluster()               const { return fSuperClusterRef.Obj();         }
      
      Double_t             EcalRecHitIsoDr04()      const { return fEcalJurassicIsolation;         }
      Double_t             HcalTowerSumEtDr04()     const { return HcalDepth1TowerSumEtDr04() +
                                                                   HcalDepth2TowerSumEtDr04();     }
      Double_t             HcalDepth1TowerSumEtDr04() const { return fHcalDepth1TowerSumEtDr04;    }
      Double_t             HcalDepth2TowerSumEtDr04() const { return fHcalDepth2TowerSumEtDr04;    }
      Double_t             TrackIsolationDr04()     const { return fTrackIsolationDr04;            }
      Double_t             EcalRecHitIsoDr03()      const { return fEcalRecHitSumEtDr03;           }
      Double_t             HcalTowerSumEtDr03()     const { return fCaloTowerIsolation;            }
      Double_t             HcalDepth1TowerSumEtDr03() const { return fHcalDepth1TowerSumEtDr03;    }
      Double_t             HcalDepth2TowerSumEtDr03() const { return fHcalDepth2TowerSumEtDr03;    }
      Double_t             TrackIsolationDr03()     const { return fTrackIsolation;                }
      
      
      void                 SetClassification(Int_t x)             { fClassification = x;           }
      void                 SetCovEtaEta(Double_t CovEtaEta)       { fCovEtaEta = CovEtaEta;        }
      void                 SetCoviEtaiEta(Double_t CoviEtaiEta)   { fCoviEtaiEta = CoviEtaiEta;    }
      void                 SetDeltaEtaSuperClusterTrackAtVtx(Double_t x)  
                             { fDeltaEtaSuperClTrkAtVtx = x;   }
      void                 SetDeltaEtaSeedClusterTrackAtCalo(Double_t x)  
                             { fDeltaEtaSeedClTrkAtCalo = x;   }
      void                 SetDeltaPhiSuperClusterTrackAtVtx(Double_t x)  
                             { fDeltaPhiSuperClTrkAtVtx = x;   }
      void                 SetDeltaPhiSeedClusterTrackAtCalo(Double_t x)  
                             { fDeltaPhiSeedClTrkAtCalo = x;   }
      void                 SetE15(Double_t x)                     { fE15 = x;                      }
      void                 SetE25Max(Double_t x)                  { fE25Max = x;                   }
      void                 SetE55(Double_t x)                     { fE55 = x;                      }
      void                 SetESeedClusterOverPout(Double_t x)    { fESeedClusterOverPout = x;     }
      void                 SetESuperClusterOverP(Double_t x)      { fESuperClusterOverP = x;       }
      void                 SetFBrem(Double_t x)                   { fFBrem = x;                    }
      void                 SetFracSharedHits(Double_t x)          { fFracSharedHits = x;           }
      void                 SetGsfTrk(const Track* t)                     
                             { fGsfTrackRef = t; ClearCharge(); }
      void                 SetHadronicOverEm(Double_t x)          { fHadronicOverEm = x;           }
      void                 SetHcalDepth1OverEcal(Double_t x)      { fHcalDepth1OverEcal = x;       }
      void                 SetHcalDepth2OverEcal(Double_t x)      { fHcalDepth2OverEcal = x;       }
      void                 SetIDLikelihood(Double_t likelihood)   { fIDLikelihood = likelihood;    }
      void                 SetIsEnergyScaleCorrected(Bool_t x)    { fIsEnergyScaleCorrected = x;   }
      void                 SetIsMomentumCorrected(Bool_t x)       { fIsMomentumCorrected = x;      }
      void                 SetNumberOfClusters(Double_t x)        { fNumberOfClusters = x;         }
      void                 SetPIn(Double_t PIn)                   { fPIn = PIn;                    }
      void                 SetPOut(Double_t POut)                 { fPOut = POut;                  }
      void                 SetPassLooseID(Double_t passLooseID)   { fPassLooseID = passLooseID;    }
      void                 SetPassTightID(Double_t passTightID)   { fPassTightID = passTightID;    }
      void                 SetPtEtaPhi(Double_t pt, Double_t eta, Double_t phi);
      void                 SetSuperCluster(const SuperCluster* sc) 
                             { fSuperClusterRef = sc; }
      void                 SetTrackerTrk(const Track* t)                 
                             { fTrackerTrackRef = t; ClearCharge(); }
      void                 SetEcalRecHitIsoDr04(Double_t x)        { fEcalJurassicIsolation = x;    }
      void                 SetHcalDepth1TowerSumEtDr04(Double_t x) { fHcalDepth1TowerSumEtDr04 = x; }
      void                 SetHcalDepth2TowerSumEtDr04(Double_t x) { fHcalDepth2TowerSumEtDr04 = x; }
      void                 SetTrackIsolationDr04(Double_t x)       { fTrackIsolationDr04 = x;       }
      void                 SetEcalRecHitIsoDr03(Double_t x)        { fEcalRecHitSumEtDr03 = x;      }
      void                 SetHcalTowerSumEtDr03(Double_t x)       { fCaloTowerIsolation = x;       }
      void                 SetHcalDepth1TowerSumEtDr03(Double_t x) { fHcalDepth1TowerSumEtDr03 = x; }
      void                 SetHcalDepth2TowerSumEtDr03(Double_t x) { fHcalDepth2TowerSumEtDr03 = x; }
      void                 SetTrackIsolationDr03(Double_t x)       { fTrackIsolation = x;   }
      void                 SetMva(Double_t x)                      { fMva = x;              }
      void                 SetIsEB(Bool_t b)                       { fIsEB = b;             }
      void                 SetIsEE(Bool_t b)                       { fIsEE = b;             }
      void                 SetIsEBEEGap(Bool_t b)                  { fIsEBEEGap = b;        }
      void                 SetIsEBEtaGap(Bool_t b)                 { fIsEBEtaGap = b;       }
      void                 SetIsEBPhiGap(Bool_t b)                 { fIsEBPhiGap = b;       }
      void                 SetIsEEDeeGap(Bool_t b)                 { fIsEEDeeGap = b;       }
      void                 SetIsEERingGap(Bool_t b)                { fIsEERingGap = b;      }
      void                 SetIsEcalDriven(Bool_t b)               { fIsEcalDriven = b;     }
      void                 SetIsTrackerDriven(Bool_t b)            { fIsTrackerDriven = b;  }
      
     
      const Track         *TrackerTrk()            const { return fTrackerTrackRef.Obj();   }
      Double_t             TrackIsolation()        const { return TrackIsolationDr03();     } //*DEPRECATED*
      const Track         *Trk()                   const { return BestTrk();                }

    protected:
      Double_t             GetMass()               const { return 0.51099892e-3;            }
      void                 GetMom()                const;

      Vect3C               fMom;                       //stored three-momentum
      Ref<Track>           fGsfTrackRef;               //gsf track reference
      Ref<Track>           fTrackerTrackRef;           //tracker track reference
      Ref<SuperCluster>    fSuperClusterRef;           //reference to SuperCluster
      Double32_t           fESuperClusterOverP;        //[0,0,14]super cluster e over p ratio
      Double32_t           fESeedClusterOverPout;      //[0,0,14]seed cluster e over p mom
      Double32_t           fDeltaEtaSuperClTrkAtVtx;   //[0,0,14]delta eta of super cluster with trk
      Double32_t           fDeltaEtaSeedClTrkAtCalo;   //[0,0,14]delta eta of seeed cluster with trk
      Double32_t           fDeltaPhiSuperClTrkAtVtx;   //[0,0,14]delta phi of super cluster with trk
      Double32_t           fDeltaPhiSeedClTrkAtCalo;   //[0,0,14]delta phi of seeed cluster with trk
      Double32_t           fFBrem;                     //[0,0,14]brem fraction
      Double32_t           fHadronicOverEm;            //[0,0,14]hadronic over em fraction *DEPRECATED*
      Double32_t           fHcalDepth1OverEcal;        //[0,0,14]hadronic over em fraction depth1
      Double32_t           fHcalDepth2OverEcal;        //[0,0,14]hadronic over em fraction depth2
      Double32_t           fNumberOfClusters;          //[0,0,14]number of associated clusters
      Double32_t           fE15;                       //[0,0,14]1x5 crystal energy
      Double32_t           fE25Max;                    //[0,0,14]2x5 crystal energy (max of two possible sums)
      Double32_t           fE33;                       //[0,0,14]3x3 crystal energy *DEPRECATED*
      Double32_t           fE55;                       //[0,0,14]5x5 crystal energy
      Double32_t           fCovEtaEta;                 //[0,0,14]variance eta-eta
      Double32_t           fCoviEtaiEta;               //[0,0,14]covariance eta-eta (in crystals)
      Double32_t           fCovEtaPhi;                 //[0,0,14]covariance eta-phi *DEPRECATED*
      Double32_t           fCovPhiPhi;                 //[0,0,14]covariance phi-phi *DEPRECATED*
      Double32_t           fCaloIsolation;             //[0,0,14](non-jura) ecal isolation based on rechits dR 0.3 *DEPRECATED*
      Double32_t           fHcalJurassicIsolation;     //[0,0,14]hcal jura iso dR 0.4 *DEPRECATED*
      Double32_t           fHcalDepth1TowerSumEtDr04;  //[0,0,14]hcal depth1 tower based isolation dR 0.4
      Double32_t           fHcalDepth2TowerSumEtDr04;  //[0,0,14]hcal depth2 tower based isolation dR 0.4
      Double32_t           fEcalJurassicIsolation;     //[0,0,14]ecal jura iso dR 0.4 *RENAMING*
      Double32_t           fTrackIsolationDr04;        //[0,0,14]isolation based on tracks dR 0.4
      Double32_t           fCaloTowerIsolation;        //[0,0,14]hcal tower based isolation dR 0.3 *DEPRECATED*
      Double32_t           fHcalDepth1TowerSumEtDr03;  //[0,0,14]hcal depth1 tower based isolation dR 0.3
      Double32_t           fHcalDepth2TowerSumEtDr03;  //[0,0,14]hcal depth2 tower based isolation dR 0.3
      Double32_t           fEcalRecHitSumEtDr03;       //[0,0,14]ecal jura iso dR 0.3
      Double32_t           fTrackIsolation;            //[0,0,14]isolation based on tracks dR 0.3 *RENAMING*
      Double32_t           fPassLooseID;               //[0,0,14]pass loose id
      Double32_t           fPassTightID;               //[0,0,14]pass tight id
      Double32_t           fIDLikelihood;              //[0,0,14]likelihood value
      Double32_t           fPIn;                       //[0,0,14]momentum at vtx
      Double32_t           fPOut;                      //[0,0,14]momentum at ecal surface
      Double32_t           fFracSharedHits;            //[0,0,14]fraction of shared hits btw gsf and std. track
      Double32_t           fMva;                       //[0,0,14] pflow mva output
      Bool_t               fIsEnergyScaleCorrected;    //class dependent escale correction
      Bool_t               fIsMomentumCorrected;       //class dependent E-p combination 
      Int_t                fClassification;            //classification (see GsfElectron.h)
      Bool_t               fIsEB;                      //is ECAL barrel
      Bool_t               fIsEE;                      //is ECAL Endcap
      Bool_t               fIsEBEEGap;                 //is in barrel-endcap gap
      Bool_t               fIsEBEtaGap;                //is in EB eta module gap
      Bool_t               fIsEBPhiGap;                //is in EB phi module gap
      Bool_t               fIsEEDeeGap;                //is in EE dee gap
      Bool_t               fIsEERingGap;               //is in EE ring gap
      Bool_t               fIsEcalDriven;              //is std. egamma electron
      Bool_t               fIsTrackerDriven;           //is pflow track-seeded electron

    ClassDef(Electron, 2) // Electron class
  };
}

//--------------------------------------------------------------------------------------------------
inline const mithep::Track *mithep::Electron::BestTrk() const
{
  // Return "best" track.

  if (HasGsfTrk())
    return GsfTrk();
  else if (HasTrackerTrk())
    return TrackerTrk();

  return 0;
}

//--------------------------------------------------------------------------------------------------
inline void mithep::Electron::GetMom() const
{
  // Get momentum of the electron. We use an explicitly stored three vector, with the pdg mass,
  // since the momentum vector may be computed non-trivially in cmssw

  fCachedMom.SetCoordinates(fMom.Rho(),fMom.Eta(),fMom.Phi(),GetMass());
}

//-------------------------------------------------------------------------------------------------
inline Double_t mithep::Electron::ESeedClusterOverPIn() const
{
  // Return energy of the SuperCluster seed divided by the magnitude 
  // of the track momentum at the vertex.
  
  return SCluster()->Seed()->Energy() / PIn();
}

//-------------------------------------------------------------------------------------------------
inline void mithep::Electron::SetPtEtaPhi(Double_t pt, Double_t eta, Double_t phi)
{
  // Set three-vector
  
  fMom.Set(pt,eta,phi);
  ClearMom();
}
#endif
Revision:	1.34
Committed:	Mon Jul 20 04:57:27 2009 UTC (15 years, 9 months ago) by loizides
Content type:	text/plain
Branch:	MAIN
Changes since 1.33:	+41 -40 lines
Log Message:	Cleanup
#	Content
1	//--------------------------------------------------------------------------------------------------
2	// $Id: Electron.h,v 1.33 2009/07/07 08:31:45 bendavid Exp $
3	//
4	// Electron
5	//
6	// This class holds information about reconstructed electrons from CMSSW.
7	//
8	// Authors: C.Loizides, J.Bendavid, S.Xie
9	//--------------------------------------------------------------------------------------------------
10
11	#ifndef MITANA_DATATREE_ELECTRON_H
12	#define MITANA_DATATREE_ELECTRON_H
13
14	#include "MitAna/DataTree/interface/SuperCluster.h"
15	#include "MitAna/DataTree/interface/ChargedParticle.h"
16	#include "MitAna/DataCont/interface/Ref.h"
17
18	namespace mithep
19	{
20	class Electron : public ChargedParticle
21	{
22	public:
23	Electron() :
24	fESuperClusterOverP(0), fESeedClusterOverPout(0), fDeltaEtaSuperClTrkAtVtx(0),
25	fDeltaEtaSeedClTrkAtCalo(0), fDeltaPhiSuperClTrkAtVtx(0),
26	fDeltaPhiSeedClTrkAtCalo(0), fFBrem(0), fHadronicOverEm(0), fHcalDepth1OverEcal(0),
27	fHcalDepth2OverEcal(0), fNumberOfClusters(0), fE15(0), fE25Max(0), fE33(0),
28	fE55(0), fCovEtaEta(0), fCoviEtaiEta(0), fCovEtaPhi(0), fCovPhiPhi(0),
29	fCaloIsolation(0), fHcalJurassicIsolation(0),
30	fHcalDepth1TowerSumEtDr04(0), fHcalDepth2TowerSumEtDr04(0),
31	fEcalJurassicIsolation(0), fTrackIsolationDr04(0), fCaloTowerIsolation(0),
32	fHcalDepth1TowerSumEtDr03(0), fHcalDepth2TowerSumEtDr03(0),
33	fEcalRecHitSumEtDr03(0), fTrackIsolation(0), fPassLooseID(0),
34	fPassTightID(0), fIDLikelihood(0), fPIn(0), fPOut(0), fFracSharedHits(0),
35	fMva(0), fIsEnergyScaleCorrected(0), fIsMomentumCorrected(0),
36	fClassification(0), fIsEB(), fIsEE(0), fIsEBEEGap(0), fIsEBEtaGap(0),
37	fIsEBPhiGap(0), fIsEEDeeGap(0), fIsEERingGap(0),
38	fIsEcalDriven(0), fIsTrackerDriven(0) {}
39
40	const Track *BestTrk() const;
41	Double_t CaloIsolation() const { return fCaloIsolation; } //DEPRECATED
42	Double_t CaloTowerIsolation() const { return HcalTowerSumEtDr03(); } //DEPRECATED
43	Int_t Classification() const { return fClassification; }
44	Double_t CovEtaEta() const { return fCovEtaEta; }
45	Double_t CovEtaPhi() const { return fCovEtaPhi; } //DEPRECATED
46	Double_t CovPhiPhi() const { return fCovPhiPhi; } //DEPRECATED
47	Double_t CoviEtaiEta() const { return fCoviEtaiEta; }
48	Double_t DeltaEtaSuperClusterTrackAtVtx() const
49	{ return fDeltaEtaSuperClTrkAtVtx; }
50	Double_t DeltaEtaSeedClusterTrackAtCalo() const
51	{ return fDeltaEtaSeedClTrkAtCalo; }
52	Double_t DeltaPhiSuperClusterTrackAtVtx() const
53	{ return fDeltaPhiSuperClTrkAtVtx; }
54	Double_t DeltaPhiSeedClusterTrackAtCalo() const
55	{ return fDeltaPhiSeedClTrkAtCalo; }
56	Double_t E15() const { return fE15; }
57	Double_t E25Max() const { return fE25Max; }
58	Double_t E33() const { return fE33; } //DEPRECATED
59	Double_t E55() const { return fE55; }
60	Double_t EcalJurassicIsolation() const { return EcalRecHitIsoDr04(); } //DEPRECATED
61	Double_t ESuperClusterOverP() const { return fESuperClusterOverP; }
62	Double_t ESeedClusterOverPout() const { return fESeedClusterOverPout; }
63	Double_t ESeedClusterOverPIn() const;
64	Double_t FBrem() const { return fFBrem; }
65	Double_t FBremOld() const { return (PIn() - POut())/PIn(); }
66	Double_t FracSharedHits() const { return fFracSharedHits; }
67	const Track *GsfTrk() const { return fGsfTrackRef.Obj(); }
68	Double_t HadronicOverEm() const { return fHadronicOverEm; }
69	Double_t HcalDepth1OverEcal() const { return fHcalDepth1OverEcal; }
70	Double_t HcalDepth2OverEcal() const { return fHcalDepth2OverEcal; }
71	Bool_t HasGsfTrk() const { return fGsfTrackRef.IsValid(); }
72	Bool_t HasTrackerTrk() const { return fTrackerTrackRef.IsValid(); }
73	Bool_t HasSuperCluster() const { return fSuperClusterRef.IsValid(); }
74	Double_t HcalIsolation() const { return fHcalJurassicIsolation; } //DEPRECATED
75	Double_t IDLikelihood() const { return fIDLikelihood; }
76	Bool_t IsEnergyScaleCorrected() const { return fIsEnergyScaleCorrected; }
77	Bool_t IsMomentumCorrected() const { return fIsMomentumCorrected; }
78	Bool_t IsEB() const { return fIsEB; }
79	Bool_t IsEE() const { return fIsEE; }
80	Bool_t IsEBEEGap() const { return fIsEBEEGap; }
81	Bool_t IsEBEtaGap() const { return fIsEBEtaGap; }
82	Bool_t IsEBPhiGap() const { return fIsEBPhiGap; }
83	Bool_t IsEEDeeGap() const { return fIsEEDeeGap; }
84	Bool_t IsEERingGap() const { return fIsEERingGap; }
85	Bool_t IsEcalDriven() const { return fIsEcalDriven; }
86	Bool_t IsTrackerDriven() const { return fIsTrackerDriven; }
87	Double_t Mva() const { return fMva; }
88	Double_t NumberOfClusters() const { return fNumberOfClusters; }
89	EObjType ObjType() const { return kElectron; }
90	Double_t PassLooseID() const { return fPassLooseID; }
91	Double_t PassTightID() const { return fPassTightID; }
92	Double_t PIn() const { return fPIn; }
93	Double_t POut() const { return fPOut; }
94	const SuperCluster *SCluster() const { return fSuperClusterRef.Obj(); }
95
96	Double_t EcalRecHitIsoDr04() const { return fEcalJurassicIsolation; }
97	Double_t HcalTowerSumEtDr04() const { return HcalDepth1TowerSumEtDr04() +
98	HcalDepth2TowerSumEtDr04(); }
99	Double_t HcalDepth1TowerSumEtDr04() const { return fHcalDepth1TowerSumEtDr04; }
100	Double_t HcalDepth2TowerSumEtDr04() const { return fHcalDepth2TowerSumEtDr04; }
101	Double_t TrackIsolationDr04() const { return fTrackIsolationDr04; }
102	Double_t EcalRecHitIsoDr03() const { return fEcalRecHitSumEtDr03; }
103	Double_t HcalTowerSumEtDr03() const { return fCaloTowerIsolation; }
104	Double_t HcalDepth1TowerSumEtDr03() const { return fHcalDepth1TowerSumEtDr03; }
105	Double_t HcalDepth2TowerSumEtDr03() const { return fHcalDepth2TowerSumEtDr03; }
106	Double_t TrackIsolationDr03() const { return fTrackIsolation; }
107
108
109	void SetClassification(Int_t x) { fClassification = x; }
110	void SetCovEtaEta(Double_t CovEtaEta) { fCovEtaEta = CovEtaEta; }
111	void SetCoviEtaiEta(Double_t CoviEtaiEta) { fCoviEtaiEta = CoviEtaiEta; }
112	void SetDeltaEtaSuperClusterTrackAtVtx(Double_t x)
113	{ fDeltaEtaSuperClTrkAtVtx = x; }
114	void SetDeltaEtaSeedClusterTrackAtCalo(Double_t x)
115	{ fDeltaEtaSeedClTrkAtCalo = x; }
116	void SetDeltaPhiSuperClusterTrackAtVtx(Double_t x)
117	{ fDeltaPhiSuperClTrkAtVtx = x; }
118	void SetDeltaPhiSeedClusterTrackAtCalo(Double_t x)
119	{ fDeltaPhiSeedClTrkAtCalo = x; }
120	void SetE15(Double_t x) { fE15 = x; }
121	void SetE25Max(Double_t x) { fE25Max = x; }
122	void SetE55(Double_t x) { fE55 = x; }
123	void SetESeedClusterOverPout(Double_t x) { fESeedClusterOverPout = x; }
124	void SetESuperClusterOverP(Double_t x) { fESuperClusterOverP = x; }
125	void SetFBrem(Double_t x) { fFBrem = x; }
126	void SetFracSharedHits(Double_t x) { fFracSharedHits = x; }
127	void SetGsfTrk(const Track* t)
128	{ fGsfTrackRef = t; ClearCharge(); }
129	void SetHadronicOverEm(Double_t x) { fHadronicOverEm = x; }
130	void SetHcalDepth1OverEcal(Double_t x) { fHcalDepth1OverEcal = x; }
131	void SetHcalDepth2OverEcal(Double_t x) { fHcalDepth2OverEcal = x; }
132	void SetIDLikelihood(Double_t likelihood) { fIDLikelihood = likelihood; }
133	void SetIsEnergyScaleCorrected(Bool_t x) { fIsEnergyScaleCorrected = x; }
134	void SetIsMomentumCorrected(Bool_t x) { fIsMomentumCorrected = x; }
135	void SetNumberOfClusters(Double_t x) { fNumberOfClusters = x; }
136	void SetPIn(Double_t PIn) { fPIn = PIn; }
137	void SetPOut(Double_t POut) { fPOut = POut; }
138	void SetPassLooseID(Double_t passLooseID) { fPassLooseID = passLooseID; }
139	void SetPassTightID(Double_t passTightID) { fPassTightID = passTightID; }
140	void SetPtEtaPhi(Double_t pt, Double_t eta, Double_t phi);
141	void SetSuperCluster(const SuperCluster* sc)
142	{ fSuperClusterRef = sc; }
143	void SetTrackerTrk(const Track* t)
144	{ fTrackerTrackRef = t; ClearCharge(); }
145	void SetEcalRecHitIsoDr04(Double_t x) { fEcalJurassicIsolation = x; }
146	void SetHcalDepth1TowerSumEtDr04(Double_t x) { fHcalDepth1TowerSumEtDr04 = x; }
147	void SetHcalDepth2TowerSumEtDr04(Double_t x) { fHcalDepth2TowerSumEtDr04 = x; }
148	void SetTrackIsolationDr04(Double_t x) { fTrackIsolationDr04 = x; }
149	void SetEcalRecHitIsoDr03(Double_t x) { fEcalRecHitSumEtDr03 = x; }
150	void SetHcalTowerSumEtDr03(Double_t x) { fCaloTowerIsolation = x; }
151	void SetHcalDepth1TowerSumEtDr03(Double_t x) { fHcalDepth1TowerSumEtDr03 = x; }
152	void SetHcalDepth2TowerSumEtDr03(Double_t x) { fHcalDepth2TowerSumEtDr03 = x; }
153	void SetTrackIsolationDr03(Double_t x) { fTrackIsolation = x; }
154	void SetMva(Double_t x) { fMva = x; }
155	void SetIsEB(Bool_t b) { fIsEB = b; }
156	void SetIsEE(Bool_t b) { fIsEE = b; }
157	void SetIsEBEEGap(Bool_t b) { fIsEBEEGap = b; }
158	void SetIsEBEtaGap(Bool_t b) { fIsEBEtaGap = b; }
159	void SetIsEBPhiGap(Bool_t b) { fIsEBPhiGap = b; }
160	void SetIsEEDeeGap(Bool_t b) { fIsEEDeeGap = b; }
161	void SetIsEERingGap(Bool_t b) { fIsEERingGap = b; }
162	void SetIsEcalDriven(Bool_t b) { fIsEcalDriven = b; }
163	void SetIsTrackerDriven(Bool_t b) { fIsTrackerDriven = b; }
164
165
166	const Track *TrackerTrk() const { return fTrackerTrackRef.Obj(); }
167	Double_t TrackIsolation() const { return TrackIsolationDr03(); } //DEPRECATED
168	const Track *Trk() const { return BestTrk(); }
169
170	protected:
171	Double_t GetMass() const { return 0.51099892e-3; }
172	void GetMom() const;
173
174	Vect3C fMom; //stored three-momentum
175	Ref<Track> fGsfTrackRef; //gsf track reference
176	Ref<Track> fTrackerTrackRef; //tracker track reference
177	Ref<SuperCluster> fSuperClusterRef; //reference to SuperCluster
178	Double32_t fESuperClusterOverP; //[0,0,14]super cluster e over p ratio
179	Double32_t fESeedClusterOverPout; //[0,0,14]seed cluster e over p mom
180	Double32_t fDeltaEtaSuperClTrkAtVtx; //[0,0,14]delta eta of super cluster with trk
181	Double32_t fDeltaEtaSeedClTrkAtCalo; //[0,0,14]delta eta of seeed cluster with trk
182	Double32_t fDeltaPhiSuperClTrkAtVtx; //[0,0,14]delta phi of super cluster with trk
183	Double32_t fDeltaPhiSeedClTrkAtCalo; //[0,0,14]delta phi of seeed cluster with trk
184	Double32_t fFBrem; //[0,0,14]brem fraction
185	Double32_t fHadronicOverEm; //[0,0,14]hadronic over em fraction DEPRECATED
186	Double32_t fHcalDepth1OverEcal; //[0,0,14]hadronic over em fraction depth1
187	Double32_t fHcalDepth2OverEcal; //[0,0,14]hadronic over em fraction depth2
188	Double32_t fNumberOfClusters; //[0,0,14]number of associated clusters
189	Double32_t fE15; //[0,0,14]1x5 crystal energy
190	Double32_t fE25Max; //[0,0,14]2x5 crystal energy (max of two possible sums)
191	Double32_t fE33; //[0,0,14]3x3 crystal energy DEPRECATED
192	Double32_t fE55; //[0,0,14]5x5 crystal energy
193	Double32_t fCovEtaEta; //[0,0,14]variance eta-eta
194	Double32_t fCoviEtaiEta; //[0,0,14]covariance eta-eta (in crystals)
195	Double32_t fCovEtaPhi; //[0,0,14]covariance eta-phi DEPRECATED
196	Double32_t fCovPhiPhi; //[0,0,14]covariance phi-phi DEPRECATED
197	Double32_t fCaloIsolation; //[0,0,14](non-jura) ecal isolation based on rechits dR 0.3 DEPRECATED
198	Double32_t fHcalJurassicIsolation; //[0,0,14]hcal jura iso dR 0.4 DEPRECATED
199	Double32_t fHcalDepth1TowerSumEtDr04; //[0,0,14]hcal depth1 tower based isolation dR 0.4
200	Double32_t fHcalDepth2TowerSumEtDr04; //[0,0,14]hcal depth2 tower based isolation dR 0.4
201	Double32_t fEcalJurassicIsolation; //[0,0,14]ecal jura iso dR 0.4 RENAMING
202	Double32_t fTrackIsolationDr04; //[0,0,14]isolation based on tracks dR 0.4
203	Double32_t fCaloTowerIsolation; //[0,0,14]hcal tower based isolation dR 0.3 DEPRECATED
204	Double32_t fHcalDepth1TowerSumEtDr03; //[0,0,14]hcal depth1 tower based isolation dR 0.3
205	Double32_t fHcalDepth2TowerSumEtDr03; //[0,0,14]hcal depth2 tower based isolation dR 0.3
206	Double32_t fEcalRecHitSumEtDr03; //[0,0,14]ecal jura iso dR 0.3
207	Double32_t fTrackIsolation; //[0,0,14]isolation based on tracks dR 0.3 RENAMING
208	Double32_t fPassLooseID; //[0,0,14]pass loose id
209	Double32_t fPassTightID; //[0,0,14]pass tight id
210	Double32_t fIDLikelihood; //[0,0,14]likelihood value
211	Double32_t fPIn; //[0,0,14]momentum at vtx
212	Double32_t fPOut; //[0,0,14]momentum at ecal surface
213	Double32_t fFracSharedHits; //[0,0,14]fraction of shared hits btw gsf and std. track
214	Double32_t fMva; //[0,0,14] pflow mva output
215	Bool_t fIsEnergyScaleCorrected; //class dependent escale correction
216	Bool_t fIsMomentumCorrected; //class dependent E-p combination
217	Int_t fClassification; //classification (see GsfElectron.h)
218	Bool_t fIsEB; //is ECAL barrel
219	Bool_t fIsEE; //is ECAL Endcap
220	Bool_t fIsEBEEGap; //is in barrel-endcap gap
221	Bool_t fIsEBEtaGap; //is in EB eta module gap
222	Bool_t fIsEBPhiGap; //is in EB phi module gap
223	Bool_t fIsEEDeeGap; //is in EE dee gap
224	Bool_t fIsEERingGap; //is in EE ring gap
225	Bool_t fIsEcalDriven; //is std. egamma electron
226	Bool_t fIsTrackerDriven; //is pflow track-seeded electron
227
228	ClassDef(Electron, 2) // Electron class
229	};
230	}
231
232	//--------------------------------------------------------------------------------------------------
233	inline const mithep::Track *mithep::Electron::BestTrk() const
234	{
235	// Return "best" track.
236
237	if (HasGsfTrk())
238	return GsfTrk();
239	else if (HasTrackerTrk())
240	return TrackerTrk();
241
242	return 0;
243	}
244
245	//--------------------------------------------------------------------------------------------------
246	inline void mithep::Electron::GetMom() const
247	{
248	// Get momentum of the electron. We use an explicitly stored three vector, with the pdg mass,
249	// since the momentum vector may be computed non-trivially in cmssw
250
251	fCachedMom.SetCoordinates(fMom.Rho(),fMom.Eta(),fMom.Phi(),GetMass());
252	}
253
254	//-------------------------------------------------------------------------------------------------
255	inline Double_t mithep::Electron::ESeedClusterOverPIn() const
256	{
257	// Return energy of the SuperCluster seed divided by the magnitude
258	// of the track momentum at the vertex.
259
260	return SCluster()->Seed()->Energy() / PIn();
261	}
262
263	//-------------------------------------------------------------------------------------------------
264	inline void mithep::Electron::SetPtEtaPhi(Double_t pt, Double_t eta, Double_t phi)
265	{
266	// Set three-vector
267
268	fMom.Set(pt,eta,phi);
269	ClearMom();
270	}
271	#endif