DataTree/interface/SuperCluster.h

//--------------------------------------------------------------------------------------------------
// $Id: SuperCluster.h,v 1.18 2010/06/25 15:12:58 bendavid Exp $
//
// SuperCluster
//
// This class holds the super cluster information.
//
// Authors: S.Xie
//--------------------------------------------------------------------------------------------------

#ifndef MITANA_DATATREE_SUPERCLUSTER_H
#define MITANA_DATATREE_SUPERCLUSTER_H
 
#include <TMath.h>
#include "MitCommon/DataFormats/interface/Vect3C.h"
#include "MitAna/DataTree/interface/DataObject.h"
#include "MitAna/DataTree/interface/BasicCluster.h"
#include "MitAna/DataTree/interface/CaloTower.h"
#include "MitAna/DataCont/interface/RefArray.h"
#include "MitAna/DataCont/interface/Ref.h"

namespace mithep 
{
  class SuperCluster : public DataObject
  {
    public:
      SuperCluster() : fEnergy(0), fEtaWidth(0), fPreshowerEnergy(0), 
                       fPhiWidth(0), fRawEnergy(0) {}     
 
      void                   AddCluster(const BasicCluster *c)          { fClusters.Add(c);        }
      void                   AddTower(const CaloTower *t)               { fCaloTowers.Add(t);      }
      const BasicCluster    *Cluster(UInt_t i)       const { return fClusters.At(i);               }
      UInt_t                 ClusterSize()           const { return fClusters.Entries();           }
      Int_t                  Compare(const TObject *o) const;   
      Double_t               Energy()                const { return fEnergy;                       }
      Double_t               Et()                    const;
      Double_t               Eta()                   const { return fPoint.Eta();                  }
      Double_t               EtaWidth()              const { return fEtaWidth;                     }
      Bool_t                 HasTower(const CaloTower *t) const { return fCaloTowers.HasObject(t); }
      Double_t               HcalDepth1Energy()      const { return fHcalDepth1Energy;             }
      Double_t               HcalDepth2Energy()      const { return fHcalDepth2Energy;             }
      Double_t               HadDepth1OverEm()       const { return fHcalDepth1Energy/fEnergy;     }
      Double_t               HadDepth2OverEm()       const { return fHcalDepth2Energy/fEnergy;     }
      Double_t               HadOverEm()             const { return (fHcalDepth1Energy+
                                                                     fHcalDepth2Energy)/fEnergy;   }
      Bool_t                 IsSortable()            const { return kTRUE;                         }
      EObjType               ObjType()               const { return kSuperCluster;                 }
      UInt_t                 NTowers()               const { return fCaloTowers.Entries();         }
      Double_t               Phi()                   const { return fPoint.Phi();                  }
      Double_t               PhiWidth()              const { return fPhiWidth;                     }
      ThreeVectorC           Point()                 const { return fPoint.V();                    }
      void                   Print(Option_t *opt="") const;
      Double_t               PreshowerEnergy()       const { return fPreshowerEnergy;              }
      Double_t               RawEnergy()             const { return fRawEnergy;                    }
      Double_t               Rho()                   const { return fPoint.Rho();                  }
      const BasicCluster    *Seed()                  const { return fSeedRef.Obj();                }
      const CaloTower       *Tower(UInt_t i)         const { return fCaloTowers.At(i);             }
      void                   SetEnergy(Double_t energy)                 { fEnergy = energy;        }
      void                   SetEtaWidth(Double_t etaWidth)             { fEtaWidth = etaWidth;    }
      void                   SetPhiWidth(Double_t phiWidth)             { fPhiWidth = phiWidth;    }
      void                   SetPreshowerEnergy(Double_t e)             { fPreshowerEnergy = e;    }
      void                   SetRawEnergy(Double_t rawEnergy)           { fRawEnergy = rawEnergy;  }
      void                   SetHcalDepth1Energy(Double_t x)            { fHcalDepth1Energy = x;   }
      void                   SetHcalDepth2Energy(Double_t x)            { fHcalDepth2Energy = x;   }
      void                   SetSeed(const BasicCluster *s)             { fSeedRef = s;            }
      void                   SetXYZ(Double_t x, Double_t y, Double_t z) { fPoint.SetXYZ(x,y,z);    }
      
    protected:
      Vect3C                  fPoint;               //centroid Position
      Double32_t              fEnergy;              //[0,0,14]super cluster energy     
      Double32_t              fEtaWidth;            //[0,0,14]width in Phi
      Double32_t              fPreshowerEnergy;     //[0,0,14]energy in the preshower
      Double32_t              fPhiWidth;            //[0,0,14]width in Phi
      Double32_t              fRawEnergy;           //[0,0,14]super cluster raw energy
      Double32_t              fHcalDepth1Energy;    //[0,0,14] hcal depth1 over ECAL energy
      Double32_t              fHcalDepth2Energy;    //[0,0,14] hcal depth2 over ECAL energy
      RefArray<BasicCluster>  fClusters;            //assigned basic clusters
      Ref<BasicCluster>       fSeedRef;             //seed cluster
      RefArray<CaloTower>     fCaloTowers;          //calo towers (matched by detid)

    ClassDef(SuperCluster, 3) // Super cluster class
  };
}

//--------------------------------------------------------------------------------------------------
inline Double_t mithep::SuperCluster::Et() const
{
  // Return transverse energy.

  return fEnergy*fPoint.Rho()/fPoint.V().R();
}

//--------------------------------------------------------------------------------------------------
inline Int_t mithep::SuperCluster::Compare(const TObject *o) const
{
  // Default compare function for sorting according to transverse momentum. 
  // Returns -1 if this object is smaller than given object, 0 if objects are 
  // equal and 1 if this is larger than given object.

  const mithep::SuperCluster *s = dynamic_cast<const mithep::SuperCluster *>(o);
  if (!s)
    return 1;

  Double_t mye = Energy();
  Double_t e   = s->Energy();
  if (mye>e)
    return -1;
  else if (e>mye)
    return +1;
  return 0;
}
#endif
Revision:	1.19
Committed:	Wed Aug 18 01:36:48 2010 UTC (14 years, 8 months ago) by bendavid
Content type:	text/plain
Branch:	MAIN
CVS Tags:	Mit_014d
Changes since 1.18:	+2 -1 lines
Log Message:	add HasTower method to supercluster
#	User	Rev	Content
1	sixie	1.1	//--------------------------------------------------------------------------------------------------
2	bendavid	1.19	// $Id: SuperCluster.h,v 1.18 2010/06/25 15:12:58 bendavid Exp $
3	sixie	1.1	//
4			// SuperCluster
5			//
6	loizides	1.7	// This class holds the super cluster information.
7	sixie	1.1	//
8			// Authors: S.Xie
9			//--------------------------------------------------------------------------------------------------
10
11	loizides	1.3	#ifndef MITANA_DATATREE_SUPERCLUSTER_H
12			#define MITANA_DATATREE_SUPERCLUSTER_H
13	sixie	1.1
14			#include <TMath.h>
15	loizides	1.11	#include "MitCommon/DataFormats/interface/Vect3C.h"
16	sixie	1.1	#include "MitAna/DataTree/interface/DataObject.h"
17			#include "MitAna/DataTree/interface/BasicCluster.h"
18	bendavid	1.18	#include "MitAna/DataTree/interface/CaloTower.h"
19	sixie	1.1	#include "MitAna/DataCont/interface/RefArray.h"
20	bendavid	1.8	#include "MitAna/DataCont/interface/Ref.h"
21	sixie	1.1
22			namespace mithep
23			{
24			class SuperCluster : public DataObject
25			{
26			public:
27	loizides	1.7	SuperCluster() : fEnergy(0), fEtaWidth(0), fPreshowerEnergy(0),
28			fPhiWidth(0), fRawEnergy(0) {}
29	sixie	1.1
30	sixie	1.16	void AddCluster(const BasicCluster *c) { fClusters.Add(c); }
31	bendavid	1.18	void AddTower(const CaloTower *t) { fCaloTowers.Add(t); }
32	sixie	1.16	const BasicCluster *Cluster(UInt_t i) const { return fClusters.At(i); }
33			UInt_t ClusterSize() const { return fClusters.Entries(); }
34			Int_t Compare(const TObject *o) const;
35			Double_t Energy() const { return fEnergy; }
36			Double_t Et() const;
37			Double_t Eta() const { return fPoint.Eta(); }
38			Double_t EtaWidth() const { return fEtaWidth; }
39	bendavid	1.19	Bool_t HasTower(const CaloTower *t) const { return fCaloTowers.HasObject(t); }
40	sixie	1.16	Double_t HcalDepth1Energy() const { return fHcalDepth1Energy; }
41			Double_t HcalDepth2Energy() const { return fHcalDepth2Energy; }
42			Double_t HadDepth1OverEm() const { return fHcalDepth1Energy/fEnergy; }
43			Double_t HadDepth2OverEm() const { return fHcalDepth2Energy/fEnergy; }
44			Double_t HadOverEm() const { return (fHcalDepth1Energy+
45			fHcalDepth2Energy)/fEnergy; }
46			Bool_t IsSortable() const { return kTRUE; }
47			EObjType ObjType() const { return kSuperCluster; }
48	bendavid	1.18	UInt_t NTowers() const { return fCaloTowers.Entries(); }
49	sixie	1.16	Double_t Phi() const { return fPoint.Phi(); }
50			Double_t PhiWidth() const { return fPhiWidth; }
51			ThreeVectorC Point() const { return fPoint.V(); }
52			void Print(Option_t *opt="") const;
53			Double_t PreshowerEnergy() const { return fPreshowerEnergy; }
54			Double_t RawEnergy() const { return fRawEnergy; }
55			Double_t Rho() const { return fPoint.Rho(); }
56			const BasicCluster *Seed() const { return fSeedRef.Obj(); }
57	bendavid	1.18	const CaloTower *Tower(UInt_t i) const { return fCaloTowers.At(i); }
58	sixie	1.16	void SetEnergy(Double_t energy) { fEnergy = energy; }
59			void SetEtaWidth(Double_t etaWidth) { fEtaWidth = etaWidth; }
60			void SetPhiWidth(Double_t phiWidth) { fPhiWidth = phiWidth; }
61			void SetPreshowerEnergy(Double_t e) { fPreshowerEnergy = e; }
62			void SetRawEnergy(Double_t rawEnergy) { fRawEnergy = rawEnergy; }
63			void SetHcalDepth1Energy(Double_t x) { fHcalDepth1Energy = x; }
64			void SetHcalDepth2Energy(Double_t x) { fHcalDepth2Energy = x; }
65			void SetSeed(const BasicCluster *s) { fSeedRef = s; }
66			void SetXYZ(Double_t x, Double_t y, Double_t z) { fPoint.SetXYZ(x,y,z); }
67	sixie	1.1
68			protected:
69	sixie	1.16	Vect3C fPoint; //centroid Position
70			Double32_t fEnergy; //[0,0,14]super cluster energy
71			Double32_t fEtaWidth; //[0,0,14]width in Phi
72			Double32_t fPreshowerEnergy; //[0,0,14]energy in the preshower
73			Double32_t fPhiWidth; //[0,0,14]width in Phi
74			Double32_t fRawEnergy; //[0,0,14]super cluster raw energy
75			Double32_t fHcalDepth1Energy; //[0,0,14] hcal depth1 over ECAL energy
76			Double32_t fHcalDepth2Energy; //[0,0,14] hcal depth2 over ECAL energy
77			RefArray<BasicCluster> fClusters; //assigned basic clusters
78			Ref<BasicCluster> fSeedRef; //seed cluster
79	bendavid	1.18	RefArray<CaloTower> fCaloTowers; //calo towers (matched by detid)
80	sixie	1.1
81	bendavid	1.18	ClassDef(SuperCluster, 3) // Super cluster class
82	sixie	1.1	};
83			}
84	loizides	1.13
85			//--------------------------------------------------------------------------------------------------
86	sixie	1.14	inline Double_t mithep::SuperCluster::Et() const
87			{
88	loizides	1.15	// Return transverse energy.
89
90	sixie	1.14	return fEnergy*fPoint.Rho()/fPoint.V().R();
91			}
92
93			//--------------------------------------------------------------------------------------------------
94	loizides	1.13	inline Int_t mithep::SuperCluster::Compare(const TObject *o) const
95			{
96			// Default compare function for sorting according to transverse momentum.
97			// Returns -1 if this object is smaller than given object, 0 if objects are
98			// equal and 1 if this is larger than given object.
99
100			const mithep::SuperCluster s = dynamic_cast<const mithep::SuperCluster >(o);
101			if (!s)
102			return 1;
103
104			Double_t mye = Energy();
105			Double_t e = s->Energy();
106			if (mye>e)
107			return -1;
108			else if (e>mye)
109			return +1;
110			return 0;
111			}
112	sixie	1.1	#endif