[u/mrichter/AliRoot.git] / MUON / AliMUONRawCluster.h

#ifndef ALIMUONRAWCLUSTER_H
#define ALIMUONRAWCLUSTER_H

/* Copyright(c) 1998-1999, ALICE Experiment at CERN, All rights reserved. *
 * See cxx source for full Copyright notice                               */

/* $Id$ */
// Revision of includes 07/05/2004

/// \ingroup base
/// \class AliMUONRawCluster
/// \brief MUON raw cluster
///
/// Class for the MUON RecPoint
/// It contains the propeorties of the physics cluters found in the tracking chambers
/// RawCluster contains also the information from the both cathode of the chambers.


#include <TObject.h>
#include <TMath.h> // because of inline funtion GetRadius
#include <TArrayF.h>
class AliMUONRawCluster : public TObject {

public:
   AliMUONRawCluster();
   virtual ~AliMUONRawCluster() { }
   Float_t      GetRadius(Int_t i) {return TMath::Sqrt(fX[i]*fX[i]+fY[i]*fY[i]);}
   Bool_t       IsSortable() const {return kTRUE;}
   Int_t        Compare(const TObject *obj) const;
   Int_t        PhysicsContribution() const;
   static Int_t BinarySearch(Float_t r, TArrayF ccord, Int_t from, Int_t upto);
   static void  SortMin(Int_t *idx,Float_t *xdarray, Float_t *xarray, Float_t *yarray, Float_t *qarray,Int_t ntr);
   void         DumpIndex();

   Int_t        AddCharge(Int_t i, Int_t Q);
   Int_t        AddX(Int_t i, Float_t X);
   Int_t        AddY(Int_t i, Float_t Y);
   Int_t        AddZ(Int_t i, Float_t Z);

   Int_t        GetCharge(Int_t i) const;
   Float_t      GetX(Int_t i) const;
   Float_t      GetY(Int_t i) const;
   Float_t      GetZ(Int_t i) const;
   Int_t        GetTrack(Int_t i) const;
   Int_t        GetPeakSignal(Int_t i) const;
   Int_t        GetMultiplicity(Int_t i) const;
   Int_t        GetClusterType() const;
   Int_t        GetGhost() const;
   Int_t        GetNcluster(Int_t i) const;
   Float_t      GetChi2(Int_t i) const;
   Int_t        GetIndex(Int_t i, Int_t j) const;
   Int_t        GetOffset(Int_t i, Int_t j) const;
   Float_t      GetContrib(Int_t i, Int_t j) const;
   Int_t        GetPhysics(Int_t i) const;
   Int_t        GetDetElemId() const ; 

   Int_t        SetCharge(Int_t i,Int_t Q);
   Int_t        SetX(Int_t i, Float_t X);
   Int_t        SetY(Int_t i, Float_t Y);
   Int_t        SetZ(Int_t i, Float_t Z);
   void         SetDetElemId(Int_t Id); 
   Int_t        SetTrack(Int_t i, Int_t track);
   Int_t        SetPeakSignal(Int_t i, Int_t peaksignal);
   Int_t        SetMultiplicity(Int_t i, Int_t mul);
   Int_t        SetClusterType(Int_t type);
   Int_t        SetGhost(Int_t ghost);
   Int_t        SetNcluster(Int_t i, Int_t ncluster);
   Int_t        SetChi2(Int_t i, Float_t chi2);
   void         SetIndex(Int_t i, Int_t j, Int_t index);
   void         SetOffset(Int_t i, Int_t j, Int_t offset);
   void         SetContrib(Int_t i, Int_t j, Float_t contrib);
   void         SetPhysics(Int_t i, Int_t physics);

private:
   Int_t       fIndexMap[50][2];  // indeces of digits
   Int_t       fOffsetMap[50][2]; // Emmanuel special
   Float_t     fContMap[50][2];   // Contribution from digit
   Int_t       fPhysicsMap[50];   // Distinguish signal and background contr.
  
   Int_t       fQ[2]  ;           // Q of cluster (in ADC counts)     
   Float_t     fX[2]  ;           // X of cluster
   Float_t     fY[2]  ;           // Y of cluster
   Float_t     fZ[2]  ;           // Z of cluster
   Int_t       fTracks[3];        //labels of overlapped tracks
   Int_t       fPeakSignal[2];    // Peak signal 
   Int_t       fMultiplicity[2];  // Cluster multiplicity
   Int_t       fClusterType;      // Cluster type
   Int_t       fGhost;            // 0 if not a ghost or ghost problem solved
                                  // >0 if ghost problem remains because
                                  // 1 both (true and ghost) satify 
                                  //   charge chi2 compatibility
                                  // 2 none give satisfactory chi2
   Int_t       fNcluster[2];      // Number of clusters
   Float_t     fChi2[2];          // Chi**2 of fit
   Int_t       fDetElemId;        // ID number of the detection element (slat) on which the cluster is found. 
   ClassDef(AliMUONRawCluster,1)  //Cluster class for MUON
};

// inline functions

inline  Int_t  AliMUONRawCluster::GetIndex(Int_t i, Int_t j) const
{ return fIndexMap[i][j]; }

inline  Int_t  AliMUONRawCluster::GetOffset(Int_t i, Int_t j) const
{ return fOffsetMap[i][j]; }

inline  Float_t  AliMUONRawCluster::GetContrib(Int_t i, Int_t j) const
{ return fContMap[i][j]; }

inline  Int_t  AliMUONRawCluster::GetPhysics(Int_t i) const
{ return fPhysicsMap[i]; }

inline  void  AliMUONRawCluster::SetIndex(Int_t i, Int_t j, Int_t index)
{ fIndexMap[i][j] = index; }

inline  void  AliMUONRawCluster::SetOffset(Int_t i, Int_t j, Int_t offset)
{ fOffsetMap[i][j] = offset; }

inline  void  AliMUONRawCluster::SetContrib(Int_t i, Int_t j, Float_t contrib)
{ fContMap[i][j] = contrib; }

inline  void  AliMUONRawCluster::SetPhysics(Int_t i, Int_t physics)
{ fPhysicsMap[i] = physics; }

inline void AliMUONRawCluster::SetDetElemId(Int_t Id)
{ fDetElemId = Id; }

inline Int_t AliMUONRawCluster::GetDetElemId() const
{ return fDetElemId;}
#endif
Commit	Line	Data
	1	#ifndef ALIMUONRAWCLUSTER_H
	2	#define ALIMUONRAWCLUSTER_H
	3
	4	/* Copyright(c) 1998-1999, ALICE Experiment at CERN, All rights reserved. *
	5	* See cxx source for full Copyright notice */
	6
	7	/* $Id$ */
	8	// Revision of includes 07/05/2004
	9
	10	/// \ingroup base
	11	/// \class AliMUONRawCluster
	12	/// \brief MUON raw cluster
	13	///
	14	/// Class for the MUON RecPoint
	15	/// It contains the propeorties of the physics cluters found in the tracking chambers
	16	/// RawCluster contains also the information from the both cathode of the chambers.
	17
	18
	19	#include <TObject.h>
	20	#include <TMath.h> // because of inline funtion GetRadius
	21	#include <TArrayF.h>
	22	class AliMUONRawCluster : public TObject {
	23
	24	public:
	25	AliMUONRawCluster();
	26	virtual ~AliMUONRawCluster() { }
	27	Float_t GetRadius(Int_t i) {return TMath::Sqrt(fX[i]fX[i]+fY[i]fY[i]);}
	28	Bool_t IsSortable() const {return kTRUE;}
	29	Int_t Compare(const TObject *obj) const;
	30	Int_t PhysicsContribution() const;
	31	static Int_t BinarySearch(Float_t r, TArrayF ccord, Int_t from, Int_t upto);
	32	static void SortMin(Int_t idx,Float_t xdarray, Float_t xarray, Float_t yarray, Float_t *qarray,Int_t ntr);
	33	void DumpIndex();
	34
	35	Int_t AddCharge(Int_t i, Int_t Q);
	36	Int_t AddX(Int_t i, Float_t X);
	37	Int_t AddY(Int_t i, Float_t Y);
	38	Int_t AddZ(Int_t i, Float_t Z);
	39
	40	Int_t GetCharge(Int_t i) const;
	41	Float_t GetX(Int_t i) const;
	42	Float_t GetY(Int_t i) const;
	43	Float_t GetZ(Int_t i) const;
	44	Int_t GetTrack(Int_t i) const;
	45	Int_t GetPeakSignal(Int_t i) const;
	46	Int_t GetMultiplicity(Int_t i) const;
	47	Int_t GetClusterType() const;
	48	Int_t GetGhost() const;
	49	Int_t GetNcluster(Int_t i) const;
	50	Float_t GetChi2(Int_t i) const;
	51	Int_t GetIndex(Int_t i, Int_t j) const;
	52	Int_t GetOffset(Int_t i, Int_t j) const;
	53	Float_t GetContrib(Int_t i, Int_t j) const;
	54	Int_t GetPhysics(Int_t i) const;
	55	Int_t GetDetElemId() const ;
	56
	57	Int_t SetCharge(Int_t i,Int_t Q);
	58	Int_t SetX(Int_t i, Float_t X);
	59	Int_t SetY(Int_t i, Float_t Y);
	60	Int_t SetZ(Int_t i, Float_t Z);
	61	void SetDetElemId(Int_t Id);
	62	Int_t SetTrack(Int_t i, Int_t track);
	63	Int_t SetPeakSignal(Int_t i, Int_t peaksignal);
	64	Int_t SetMultiplicity(Int_t i, Int_t mul);
	65	Int_t SetClusterType(Int_t type);
	66	Int_t SetGhost(Int_t ghost);
	67	Int_t SetNcluster(Int_t i, Int_t ncluster);
	68	Int_t SetChi2(Int_t i, Float_t chi2);
	69	void SetIndex(Int_t i, Int_t j, Int_t index);
	70	void SetOffset(Int_t i, Int_t j, Int_t offset);
	71	void SetContrib(Int_t i, Int_t j, Float_t contrib);
	72	void SetPhysics(Int_t i, Int_t physics);
	73
	74	private:
	75	Int_t fIndexMap[50][2]; // indeces of digits
	76	Int_t fOffsetMap[50][2]; // Emmanuel special
	77	Float_t fContMap[50][2]; // Contribution from digit
	78	Int_t fPhysicsMap[50]; // Distinguish signal and background contr.
	79
	80	Int_t fQ[2] ; // Q of cluster (in ADC counts)
	81	Float_t fX[2] ; // X of cluster
	82	Float_t fY[2] ; // Y of cluster
	83	Float_t fZ[2] ; // Z of cluster
	84	Int_t fTracks[3]; //labels of overlapped tracks
	85	Int_t fPeakSignal[2]; // Peak signal
	86	Int_t fMultiplicity[2]; // Cluster multiplicity
	87	Int_t fClusterType; // Cluster type
	88	Int_t fGhost; // 0 if not a ghost or ghost problem solved
	89	// >0 if ghost problem remains because
	90	// 1 both (true and ghost) satify
	91	// charge chi2 compatibility
	92	// 2 none give satisfactory chi2
	93	Int_t fNcluster[2]; // Number of clusters
	94	Float_t fChi2[2]; // Chi**2 of fit
	95	Int_t fDetElemId; // ID number of the detection element (slat) on which the cluster is found.
	96	ClassDef(AliMUONRawCluster,1) //Cluster class for MUON
	97	};
	98
	99	// inline functions
	100
	101	inline Int_t AliMUONRawCluster::GetIndex(Int_t i, Int_t j) const
	102	{ return fIndexMap[i][j]; }
	103
	104	inline Int_t AliMUONRawCluster::GetOffset(Int_t i, Int_t j) const
	105	{ return fOffsetMap[i][j]; }
	106
	107	inline Float_t AliMUONRawCluster::GetContrib(Int_t i, Int_t j) const
	108	{ return fContMap[i][j]; }
	109
	110	inline Int_t AliMUONRawCluster::GetPhysics(Int_t i) const
	111	{ return fPhysicsMap[i]; }
	112
	113	inline void AliMUONRawCluster::SetIndex(Int_t i, Int_t j, Int_t index)
	114	{ fIndexMap[i][j] = index; }
	115
	116	inline void AliMUONRawCluster::SetOffset(Int_t i, Int_t j, Int_t offset)
	117	{ fOffsetMap[i][j] = offset; }
	118
	119	inline void AliMUONRawCluster::SetContrib(Int_t i, Int_t j, Float_t contrib)
	120	{ fContMap[i][j] = contrib; }
	121
	122	inline void AliMUONRawCluster::SetPhysics(Int_t i, Int_t physics)
	123	{ fPhysicsMap[i] = physics; }
	124
	125	inline void AliMUONRawCluster::SetDetElemId(Int_t Id)
	126	{ fDetElemId = Id; }
	127
	128	inline Int_t AliMUONRawCluster::GetDetElemId() const
	129	{ return fDetElemId;}
	130	#endif
	131
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