DataTree/interface/CaloJet.h

//--------------------------------------------------------------------------------------------------
// $Id: CaloJet.h,v 1.7 2012/03/28 12:15:34 paus Exp $
//
// CaloJet
//
// This class holds information about reconstructed jet based on calorimeter towers.
//
// Authors: S.Xie, C.Loizides, J.Bendavid, C.Paus
//--------------------------------------------------------------------------------------------------

#ifndef MITANA_DATATREE_CALOJET_H
#define MITANA_DATATREE_CALOJET_H
 
#include "MitAna/DataTree/interface/Jet.h"
#include "MitAna/DataCont/interface/RefArray.h"
#include "MitAna/DataTree/interface/CaloTower.h"

namespace mithep 
{
  class CaloJet : public Jet
  {
    public:
      CaloJet() : fMaxEInEmTowers(0), fMaxEInHadTowers(0), fEnergyFractionH(0),
                  fEnergyFractionEm(0), fHadEnergyInHB(0), fHadEnergyInHO(0), fHadEnergyInHE(0),
                  fHadEnergyInHF(0), fEmEnergyInEB(0), fEmEnergyInEE(0), fEmEnergyInHF(0),
                  fTowersArea(0), fHPD(0), fRBX(0), fN90Hits(0), fSubDetector1(0), fSubDetector2(0),
                  fSubDetector3(0), fSubDetector4(0), fRestrictedEMF(0), fNHCalTowers(0),
                  fNECalTowers(0), fApproximatefHPD(0), fApproximatefRBX(0), fHitsInN90(0),
                  fNHits2RPC(0), fNHits3RPC(0), fNHitsRPC(0) {}
      CaloJet(Double_t px, Double_t py, Double_t pz, Double_t e) : 
                  Jet(px,py,pz,e),
                  fMaxEInEmTowers(0), fMaxEInHadTowers(0), fEnergyFractionH(0),
                  fEnergyFractionEm(0), fHadEnergyInHB(0), fHadEnergyInHO(0), fHadEnergyInHE(0),
                  fHadEnergyInHF(0), fEmEnergyInEB(0), fEmEnergyInEE(0), fEmEnergyInHF(0),
                  fTowersArea(0), fHPD(0), fRBX(0), fN90Hits(0), fSubDetector1(0), fSubDetector2(0),
                  fSubDetector3(0), fSubDetector4(0), fRestrictedEMF(0), fNHCalTowers(0),
                  fNECalTowers(0), fApproximatefHPD(0), fApproximatefRBX(0), fHitsInN90(0),
                  fNHits2RPC(0), fNHits3RPC(0), fNHitsRPC(0) {}

      void                AddTower(const CaloTower *t)        { fTowers.Add(t);                  }
      Bool_t              HasTower(const CaloTower *t)  const { return fTowers.HasObject(t);     }
      UInt_t              NTowers()                     const { return fTowers.Entries();        }
      const CaloTower    *Tower(UInt_t i)               const { return fTowers.At(i);            }
      UInt_t              NConstituents()               const { return NTowers();                }
      EObjType            ObjType()                     const { return kCaloJet;                 }  
      Double_t            EmEnergyInEB()                const { return fEmEnergyInEB;            } 
      Double_t            EmEnergyInEE()                const { return fEmEnergyInEE;            } 
      Double_t            EmEnergyInHF()                const { return fEmEnergyInHF;            } 
      Double_t            EnergyFractionH()             const { return fEnergyFractionH;         }
      Double_t            EnergyFractionEm()            const { return fEnergyFractionEm;        }
      Double_t            HadEnergyInHO()               const { return fHadEnergyInHO;           } 
      Double_t            HadEnergyInHB()               const { return fHadEnergyInHB;           } 
      Double_t            HadEnergyInHF()               const { return fHadEnergyInHF;           } 
      Double_t            HadEnergyInHE()               const { return fHadEnergyInHE;           }
      Jet                *MakeCopy()                    const { return new CaloJet(*this);       }
      Double_t            MaxEInEmTowers()              const { return fMaxEInEmTowers;          }
      Double_t            MaxEInHadTowers()             const { return fMaxEInHadTowers;         }
      void                SetEmEnergyInEB(Double_t val)       { fEmEnergyInEB     = val;         } 
      void                SetEmEnergyInEE(Double_t val)       { fEmEnergyInEE     = val;         } 
      void                SetEmEnergyInHF(Double_t val)       { fEmEnergyInHF     = val;         } 
      void                SetEnergyFractionH(Double_t val)    { fEnergyFractionH  = val;         }
      void                SetEnergyFractionEm(Double_t val)   { fEnergyFractionEm = val;         }
      void                SetHadEnergyInHO(Double_t val)      { fHadEnergyInHO    = val;         } 
      void                SetHadEnergyInHB(Double_t val)      { fHadEnergyInHB    = val;         } 
      void                SetHadEnergyInHF(Double_t val)      { fHadEnergyInHF    = val;         } 
      void                SetHadEnergyInHE(Double_t val)      { fHadEnergyInHE    = val;         } 
      void                SetMaxEInEmTowers(Double_t val)     { fMaxEInEmTowers   = val;         }
      void                SetMaxEInHadTowers(Double_t val)    { fMaxEInHadTowers  = val;         }
      void                SetTowersArea(Double_t val)         { fTowersArea       = val;         }
      void                SetFHPD(Double_t val)               { fHPD = val;                      }
      void                SetFRBX(Double_t val)               { fRBX = val;                      }
      void                SetN90Hits(Int_t val)               { fN90Hits = val;                  }
      void                SetFSubDetector1(Double_t val)      { fSubDetector1 = val;             }
      void                SetFSubDetector2(Double_t val)      { fSubDetector2 = val;             }
      void                SetFSubDetector3(Double_t val)      { fSubDetector3 = val;             }
      void                SetFSubDetector4(Double_t val)      { fSubDetector4 = val;             }
      void                SetRestrictedEMF(Double_t val)      { fRestrictedEMF = val;            }
      void                SetNHCalTowers(Int_t val)           { fNHCalTowers = val;              }
      void                SetNECalTowers(Int_t val)           { fNECalTowers = val;              }
      void                SetApproximatefHPD(Double_t val)    { fApproximatefHPD = val;          }
      void                SetApproximatefRBX(Double_t val)    { fApproximatefRBX = val;          }
      void                SetHitsInN90(Int_t val)             { fHitsInN90 = val;                }
      void                SetNHits2RPC(Int_t val)             { fNHits2RPC = val;                }
      void                SetNHits3RPC(Int_t val)             { fNHits3RPC = val;                }
      void                SetNHitsRPC(Int_t val)              { fNHitsRPC = val;                 }
      Double_t            TowersArea()                  const { return fTowersArea;              }
      Double_t            FHPD()                        const { return fHPD;                     }
      Double_t            FRBX()                        const { return fRBX;                     }
      UInt_t              N90Hits()                     const { return fN90Hits;                 }
      Double_t            FSubDetector1()               const { return fSubDetector1;            }
      Double_t            FSubDetector2()               const { return fSubDetector2;            }
      Double_t            FSubDetector3()               const { return fSubDetector3;            }
      Double_t            FSubDetector4()               const { return fSubDetector4;            }
      Double_t            RestrictedEMF()               const { return fRestrictedEMF;           }
      UInt_t              NHCalTowers()                 const { return fNHCalTowers;             }
      UInt_t              NECalTowers()                 const { return fNECalTowers;             }
      Double_t            ApproximatefHPD()             const { return fApproximatefHPD;         }
      Double_t            ApproximatefRBX()             const { return fApproximatefRBX;         }
      UInt_t              HitsInN90()                   const { return fHitsInN90;               }
      UInt_t              NHits2RPC()                   const { return fNHits2RPC;               }
      UInt_t              NHits3RPC()                   const { return fNHits3RPC;               }
      UInt_t              NHitsRPC()                    const { return fNHitsRPC;                }

      // Some structural tools
      void                Mark(UInt_t i = 1)            const;

    protected:

      Double32_t          fMaxEInEmTowers;    //[0,0,14]maximum energy in EM towers
      Double32_t          fMaxEInHadTowers;   //[0,0,14]maximum energy in HCAL towers
      Double32_t          fEnergyFractionH;   //[0,0,14]hadronic energy fraction
      Double32_t          fEnergyFractionEm;  //[0,0,14]electromagnetic energy fraction
      Double32_t          fHadEnergyInHB;     //[0,0,14]hadronic energy in HB
      Double32_t          fHadEnergyInHO;     //[0,0,14]hadronic energy in HO
      Double32_t          fHadEnergyInHE;     //[0,0,14]hadronic energy in HE
      Double32_t          fHadEnergyInHF;     //[0,0,14]hadronic energy in HF
      Double32_t          fEmEnergyInEB;      //[0,0,14]electromagnetic energy in EB
      Double32_t          fEmEnergyInEE;      //[0,0,14]electromagnetic energy in EE
      Double32_t          fEmEnergyInHF;      //[0,0,14]electromagnetic energy extracted from HF
      Double32_t          fTowersArea;        //[0,0,14]area of contributing towers
      Double32_t          fHPD;               //[0,0,14]energy from hottest hpd
      Double32_t          fRBX;               //[0,0,14]energy fraction from hottest rbx
      Int_t               fN90Hits;           //number of hits comprising 90 percent of the energy
      Double32_t          fSubDetector1;      //[0,0,14]
      Double32_t          fSubDetector2;      //[0,0,14]
      Double32_t          fSubDetector3;      //[0,0,14]
      Double32_t          fSubDetector4;      //[0,0,14]
      Double32_t          fRestrictedEMF;     //[0,0,14]
      Int_t               fNHCalTowers;
      Int_t               fNECalTowers;
      Double32_t          fApproximatefHPD;   //[0,0,14]
      Double32_t          fApproximatefRBX;   //[0,0,14]
      Int_t               fHitsInN90;
      Int_t               fNHits2RPC;
      Int_t               fNHits3RPC;
      Int_t               fNHitsRPC;
      RefArray<CaloTower> fTowers;            //calotowers in jet

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

//--------------------------------------------------------------------------------------------------
inline void mithep::CaloJet::Mark(UInt_t i) const
{
  // mark myself
  mithep::DataObject::Mark(i);
  // mark my dependencies if they are there
  fTowers.Mark(i);
}

#endif
Revision:	1.8
Committed:	Thu Mar 29 23:41:54 2012 UTC (13 years, 1 month ago) by paus
Content type:	text/plain
Branch:	MAIN
CVS Tags:	Mit_032, Mit_031, Mit_030, Mit_029c, Mit_029b, Mit_030_pre1, Mit_029a, Mit_029, Mit_029_pre1, Mit_028a, Mit_028, Mit_027a, Mit_027, Mit_026, Mit_025e, HEAD
Changes since 1.7:	+5 -6 lines
Log Message:	Version with working skimming and last 4.4 tag.
#	User	Rev	Content
1	bendavid	1.1	//--------------------------------------------------------------------------------------------------
2	paus	1.8	// $Id: CaloJet.h,v 1.7 2012/03/28 12:15:34 paus Exp $
3	bendavid	1.1	//
4			// CaloJet
5			//
6	loizides	1.3	// This class holds information about reconstructed jet based on calorimeter towers.
7	bendavid	1.1	//
8	paus	1.7	// Authors: S.Xie, C.Loizides, J.Bendavid, C.Paus
9	bendavid	1.1	//--------------------------------------------------------------------------------------------------
10
11			#ifndef MITANA_DATATREE_CALOJET_H
12			#define MITANA_DATATREE_CALOJET_H
13
14			#include "MitAna/DataTree/interface/Jet.h"
15			#include "MitAna/DataCont/interface/RefArray.h"
16			#include "MitAna/DataTree/interface/CaloTower.h"
17
18			namespace mithep
19			{
20			class CaloJet : public Jet
21			{
22			public:
23			CaloJet() : fMaxEInEmTowers(0), fMaxEInHadTowers(0), fEnergyFractionH(0),
24			fEnergyFractionEm(0), fHadEnergyInHB(0), fHadEnergyInHO(0), fHadEnergyInHE(0),
25			fHadEnergyInHF(0), fEmEnergyInEB(0), fEmEnergyInEE(0), fEmEnergyInHF(0),
26	bendavid	1.6	fTowersArea(0), fHPD(0), fRBX(0), fN90Hits(0), fSubDetector1(0), fSubDetector2(0),
27			fSubDetector3(0), fSubDetector4(0), fRestrictedEMF(0), fNHCalTowers(0),
28			fNECalTowers(0), fApproximatefHPD(0), fApproximatefRBX(0), fHitsInN90(0),
29			fNHits2RPC(0), fNHits3RPC(0), fNHitsRPC(0) {}
30	bendavid	1.1	CaloJet(Double_t px, Double_t py, Double_t pz, Double_t e) :
31			Jet(px,py,pz,e),
32			fMaxEInEmTowers(0), fMaxEInHadTowers(0), fEnergyFractionH(0),
33			fEnergyFractionEm(0), fHadEnergyInHB(0), fHadEnergyInHO(0), fHadEnergyInHE(0),
34			fHadEnergyInHF(0), fEmEnergyInEB(0), fEmEnergyInEE(0), fEmEnergyInHF(0),
35	bendavid	1.6	fTowersArea(0), fHPD(0), fRBX(0), fN90Hits(0), fSubDetector1(0), fSubDetector2(0),
36			fSubDetector3(0), fSubDetector4(0), fRestrictedEMF(0), fNHCalTowers(0),
37			fNECalTowers(0), fApproximatefHPD(0), fApproximatefRBX(0), fHitsInN90(0),
38			fNHits2RPC(0), fNHits3RPC(0), fNHitsRPC(0) {}
39	bendavid	1.1
40	loizides	1.3	void AddTower(const CaloTower *t) { fTowers.Add(t); }
41			Bool_t HasTower(const CaloTower *t) const { return fTowers.HasObject(t); }
42	loizides	1.4	UInt_t NTowers() const { return fTowers.Entries(); }
43	loizides	1.3	const CaloTower *Tower(UInt_t i) const { return fTowers.At(i); }
44			UInt_t NConstituents() const { return NTowers(); }
45			EObjType ObjType() const { return kCaloJet; }
46			Double_t EmEnergyInEB() const { return fEmEnergyInEB; }
47			Double_t EmEnergyInEE() const { return fEmEnergyInEE; }
48			Double_t EmEnergyInHF() const { return fEmEnergyInHF; }
49			Double_t EnergyFractionH() const { return fEnergyFractionH; }
50			Double_t EnergyFractionEm() const { return fEnergyFractionEm; }
51			Double_t HadEnergyInHO() const { return fHadEnergyInHO; }
52			Double_t HadEnergyInHB() const { return fHadEnergyInHB; }
53			Double_t HadEnergyInHF() const { return fHadEnergyInHF; }
54			Double_t HadEnergyInHE() const { return fHadEnergyInHE; }
55	bendavid	1.5	Jet MakeCopy() const { return new CaloJet(this); }
56	loizides	1.3	Double_t MaxEInEmTowers() const { return fMaxEInEmTowers; }
57			Double_t MaxEInHadTowers() const { return fMaxEInHadTowers; }
58			void SetEmEnergyInEB(Double_t val) { fEmEnergyInEB = val; }
59			void SetEmEnergyInEE(Double_t val) { fEmEnergyInEE = val; }
60			void SetEmEnergyInHF(Double_t val) { fEmEnergyInHF = val; }
61			void SetEnergyFractionH(Double_t val) { fEnergyFractionH = val; }
62			void SetEnergyFractionEm(Double_t val) { fEnergyFractionEm = val; }
63			void SetHadEnergyInHO(Double_t val) { fHadEnergyInHO = val; }
64			void SetHadEnergyInHB(Double_t val) { fHadEnergyInHB = val; }
65			void SetHadEnergyInHF(Double_t val) { fHadEnergyInHF = val; }
66			void SetHadEnergyInHE(Double_t val) { fHadEnergyInHE = val; }
67			void SetMaxEInEmTowers(Double_t val) { fMaxEInEmTowers = val; }
68			void SetMaxEInHadTowers(Double_t val) { fMaxEInHadTowers = val; }
69			void SetTowersArea(Double_t val) { fTowersArea = val; }
70	bendavid	1.6	void SetFHPD(Double_t val) { fHPD = val; }
71			void SetFRBX(Double_t val) { fRBX = val; }
72			void SetN90Hits(Int_t val) { fN90Hits = val; }
73			void SetFSubDetector1(Double_t val) { fSubDetector1 = val; }
74			void SetFSubDetector2(Double_t val) { fSubDetector2 = val; }
75			void SetFSubDetector3(Double_t val) { fSubDetector3 = val; }
76			void SetFSubDetector4(Double_t val) { fSubDetector4 = val; }
77			void SetRestrictedEMF(Double_t val) { fRestrictedEMF = val; }
78			void SetNHCalTowers(Int_t val) { fNHCalTowers = val; }
79			void SetNECalTowers(Int_t val) { fNECalTowers = val; }
80			void SetApproximatefHPD(Double_t val) { fApproximatefHPD = val; }
81			void SetApproximatefRBX(Double_t val) { fApproximatefRBX = val; }
82			void SetHitsInN90(Int_t val) { fHitsInN90 = val; }
83			void SetNHits2RPC(Int_t val) { fNHits2RPC = val; }
84			void SetNHits3RPC(Int_t val) { fNHits3RPC = val; }
85			void SetNHitsRPC(Int_t val) { fNHitsRPC = val; }
86	loizides	1.3	Double_t TowersArea() const { return fTowersArea; }
87	bendavid	1.6	Double_t FHPD() const { return fHPD; }
88			Double_t FRBX() const { return fRBX; }
89			UInt_t N90Hits() const { return fN90Hits; }
90			Double_t FSubDetector1() const { return fSubDetector1; }
91			Double_t FSubDetector2() const { return fSubDetector2; }
92			Double_t FSubDetector3() const { return fSubDetector3; }
93			Double_t FSubDetector4() const { return fSubDetector4; }
94			Double_t RestrictedEMF() const { return fRestrictedEMF; }
95			UInt_t NHCalTowers() const { return fNHCalTowers; }
96			UInt_t NECalTowers() const { return fNECalTowers; }
97			Double_t ApproximatefHPD() const { return fApproximatefHPD; }
98			Double_t ApproximatefRBX() const { return fApproximatefRBX; }
99			UInt_t HitsInN90() const { return fHitsInN90; }
100			UInt_t NHits2RPC() const { return fNHits2RPC; }
101			UInt_t NHits3RPC() const { return fNHits3RPC; }
102			UInt_t NHitsRPC() const { return fNHitsRPC; }
103
104	paus	1.7	// Some structural tools
105	paus	1.8	void Mark(UInt_t i = 1) const;
106	bendavid	1.1
107			protected:
108
109	loizides	1.3	Double32_t fMaxEInEmTowers; //[0,0,14]maximum energy in EM towers
110			Double32_t fMaxEInHadTowers; //[0,0,14]maximum energy in HCAL towers
111			Double32_t fEnergyFractionH; //[0,0,14]hadronic energy fraction
112			Double32_t fEnergyFractionEm; //[0,0,14]electromagnetic energy fraction
113			Double32_t fHadEnergyInHB; //[0,0,14]hadronic energy in HB
114			Double32_t fHadEnergyInHO; //[0,0,14]hadronic energy in HO
115			Double32_t fHadEnergyInHE; //[0,0,14]hadronic energy in HE
116			Double32_t fHadEnergyInHF; //[0,0,14]hadronic energy in HF
117			Double32_t fEmEnergyInEB; //[0,0,14]electromagnetic energy in EB
118			Double32_t fEmEnergyInEE; //[0,0,14]electromagnetic energy in EE
119			Double32_t fEmEnergyInHF; //[0,0,14]electromagnetic energy extracted from HF
120			Double32_t fTowersArea; //[0,0,14]area of contributing towers
121	bendavid	1.6	Double32_t fHPD; //[0,0,14]energy from hottest hpd
122			Double32_t fRBX; //[0,0,14]energy fraction from hottest rbx
123			Int_t fN90Hits; //number of hits comprising 90 percent of the energy
124			Double32_t fSubDetector1; //[0,0,14]
125			Double32_t fSubDetector2; //[0,0,14]
126			Double32_t fSubDetector3; //[0,0,14]
127			Double32_t fSubDetector4; //[0,0,14]
128			Double32_t fRestrictedEMF; //[0,0,14]
129			Int_t fNHCalTowers;
130			Int_t fNECalTowers;
131			Double32_t fApproximatefHPD; //[0,0,14]
132			Double32_t fApproximatefRBX; //[0,0,14]
133			Int_t fHitsInN90;
134			Int_t fNHits2RPC;
135			Int_t fNHits3RPC;
136			Int_t fNHitsRPC;
137	loizides	1.3	RefArray<CaloTower> fTowers; //calotowers in jet
138	bendavid	1.1
139	bendavid	1.6	ClassDef(CaloJet, 2) // CaloJet class
140	bendavid	1.1	};
141			}
142	paus	1.7
143			//--------------------------------------------------------------------------------------------------
144	paus	1.8	inline void mithep::CaloJet::Mark(UInt_t i) const
145	paus	1.7	{
146			// mark myself
147	paus	1.8	mithep::DataObject::Mark(i);
148	paus	1.7	// mark my dependencies if they are there
149	paus	1.8	fTowers.Mark(i);
150	paus	1.7	}
151
152	bendavid	1.1	#endif