TrackerLevel2/inc/TrkLevel1.h

/**
 * \file TrkLevel1.h
 * \author Elena Vannuccini
 */
#ifndef trklevel1_h
#define trklevel1_h

#include <TObject.h>
#include <TClonesArray.h>
#include <TRef.h>

#include <TrkStruct.h>

#define INC_CUT 4.
/**
 * \brief Class to describe tracker clusters. 
 *
 * A cluster is defined as a group of adjacent strips whose signals exceed noise by INC_CUT sigma, and at least one strip has signal/noise > SEED_CUT. Tipical values are SEED_CUT = 7 and INC_CUT = 4.
 * 
 */
// ==================================================================
class TrkCluster : public TObject {

private:


public:
        
    int view; ///< view
    int maxs; ///< strip number (1-3072) of cluster center
    int indmax; 
    
    Int_t         CLlength; ///< number of stored strip info (signal+sigma+adc+bad)
    Float_t      *clsignal; //[CLlength] 
    Float_t      *clsigma;  //[CLlength]
    Int_t        *cladc;    //[CLlength]
    Bool_t       *clbad;    //[CLlength]
    
    TrkCluster();
    ~TrkCluster(){Clear();};
    TrkCluster(const TrkCluster&);

    void Dump();
    void Clear();
    void Clear(Option_t *option){Clear();};
    void Delete(){Clear();};
        
    Float_t GetSignal(Int_t, Float_t);    ///< cluster signal
    Float_t GetSignal(Float_t cut)  { return GetSignal( (Int_t)0, cut); };
    Float_t GetSignal(Int_t nstrip) { return GetSignal( nstrip, (Float_t)(-1000) ); };
    Float_t GetSignal()             { return GetSignal( (Int_t)0,(Float_t)INC_CUT); };
    
    Float_t GetSignalToNoise(Int_t,Float_t);  ///< cluster signal/noise
    Float_t GetSignalToNoise(Float_t cut)  { return GetSignalToNoise( (Int_t)0, cut); };
    Float_t GetSignalToNoise(Int_t nstrip) { return GetSignalToNoise( nstrip, (Float_t)(-1000) ); };
    Float_t GetSignalToNoise()             { return GetSignalToNoise( (Int_t)0, (Float_t)INC_CUT); };


    Int_t   GetMultiplicity(Float_t);         ///< cluster multiplicity 
    Int_t   GetMultiplicity()  { return GetMultiplicity(INC_CUT);  };
    
    cTrkLevel1* GetLevel1Struct();
    
    Float_t GetCOG(Int_t);
    Float_t GetCOG(Float_t angle);
    Float_t GetCOG(){ return GetCOG(0); };
    Float_t GetETA(Int_t,float);
    Float_t GetETA(float angle){ return GetETA(0,angle); };
    
    Bool_t IsBad(Int_t);                ///< bad-cluster flag
    Bool_t IsSaturated(Int_t);          ///< saturated-cluster flag

    Int_t GetPlane() { return (Int_t)((view+1)/2);};         ///< plane number (1-6)
    Int_t GetLadder(){ return 1+(Int_t)((maxs-1)/1024);  };  ///< ladder number (1-3)
    Bool_t IsY(){ return (Bool_t)view%2; };
    Bool_t IsX(){ return !((Bool_t)view%2); };
        
    TrkCluster* GetTrkCluster(){ return this; };

    friend class TrkLevel1;

    ClassDef(TrkCluster,2);

};

/**
 * \brief Class to describe tracker LEVEL1 data.
 *
 * A Level1 tracker event is defined as a collection of clusters ( TrkCluster objects ).
 * The result of common-noise computation for each viking is also stored ( cnev[24][12] ).
 * A general flag summarize the event status (missing sections, crc failures, decoding errors ans so on...).
 */
class TrkLevel1 : public TObject {

 private:
    
 public:

    Int_t         good[12];       ///< event status
    Float_t       cn[24][12];     ///< CN
//    Float_t       cnrms[24][12];  ///< CN RMS
    Int_t         cnn[24][12];    ///< number of strips for CN computation

        
    TClonesArray *Cluster;        ///< clusters
        
    TrkLevel1();
    ~TrkLevel1(){Delete();};
    
    int nclstr() {return Cluster->GetEntries();}    ///< number of stored clusters
    
    void Dump();
    void SetFromLevel1Struct(cTrkLevel1 *, Bool_t);
//      void GetLevel1Struct(cTrkLevel1 *) const;
    cTrkLevel1* GetLevel1Struct();
    void Clear();
    void Delete();
    void Set();
    
    TrkCluster*   GetCluster(int);
    
    TrkLevel1*    GetTrkLevel1(){return this;}
    TClonesArray* GetClusters(){return Cluster;};   ///< returns pointer to the cluster array
    
    int LoadPfaParam(TString);
    int GetPfaNbinsAngle(){return pfa_.nangbin;};
    int GetPfaNbinsETA(){return pfa_.netaval;};
    int GetPfaNbinsCharge(){return 0;};
    float* GetPfaCoord(TString pfa, int nview, int nladder, int nang);
    float* GetPfaAbs(TString pfa, int nang);

    ClassDef(TrkLevel1,2);

};


#endif
1	pam-fi	1.1	/**
2			* \file TrkLevel1.h
3			* \author Elena Vannuccini
4			*/
5			#ifndef trklevel1_h
6			#define trklevel1_h
7
8			#include <TObject.h>
9			#include <TClonesArray.h>
10			#include <TRef.h>
11
12			#include <TrkStruct.h>
13
14	pam-fi	1.2	#define INC_CUT 4.
15	pam-fi	1.1	/**
16			* \brief Class to describe tracker clusters.
17			*
18	pam-fi	1.2	* A cluster is defined as a group of adjacent strips whose signals exceed noise by INC_CUT sigma, and at least one strip has signal/noise > SEED_CUT. Tipical values are SEED_CUT = 7 and INC_CUT = 4.
19			*
20	pam-fi	1.1	*/
21			// ==================================================================
22			class TrkCluster : public TObject {
23
24			private:
25
26
27			public:
28
29	pam-fi	1.5	int view; ///< view
30			int maxs; ///< strip number (1-3072) of cluster center
31			int indmax;
32
33			Int_t CLlength; ///< number of stored strip info (signal+sigma+adc+bad)
34			Float_t *clsignal; //[CLlength]
35			Float_t *clsigma; //[CLlength]
36			Int_t *cladc; //[CLlength]
37			Bool_t *clbad; //[CLlength]
38
39	pam-fi	1.1	TrkCluster();
40	pam-fi	1.8	~TrkCluster(){Clear();};
41	pam-fi	1.1	TrkCluster(const TrkCluster&);
42
43			void Dump();
44	pam-fi	1.7	void Clear();
45	pam-fi	1.8	void Clear(Option_t *option){Clear();};
46			void Delete(){Clear();};
47	pam-fi	1.3
48	pam-fi	1.4	Float_t GetSignal(Int_t, Float_t); ///< cluster signal
49			Float_t GetSignal(Float_t cut) { return GetSignal( (Int_t)0, cut); };
50			Float_t GetSignal(Int_t nstrip) { return GetSignal( nstrip, (Float_t)(-1000) ); };
51			Float_t GetSignal() { return GetSignal( (Int_t)0,(Float_t)INC_CUT); };
52
53			Float_t GetSignalToNoise(Int_t,Float_t); ///< cluster signal/noise
54			Float_t GetSignalToNoise(Float_t cut) { return GetSignalToNoise( (Int_t)0, cut); };
55			Float_t GetSignalToNoise(Int_t nstrip) { return GetSignalToNoise( nstrip, (Float_t)(-1000) ); };
56			Float_t GetSignalToNoise() { return GetSignalToNoise( (Int_t)0, (Float_t)INC_CUT); };
57
58
59			Int_t GetMultiplicity(Float_t); ///< cluster multiplicity
60			Int_t GetMultiplicity() { return GetMultiplicity(INC_CUT); };
61
62			cTrkLevel1* GetLevel1Struct();
63
64			Float_t GetCOG(Int_t);
65	pam-fi	1.5	Float_t GetCOG(Float_t angle);
66	pam-fi	1.4	Float_t GetCOG(){ return GetCOG(0); };
67			Float_t GetETA(Int_t,float);
68			Float_t GetETA(float angle){ return GetETA(0,angle); };
69
70			Bool_t IsBad(Int_t); ///< bad-cluster flag
71	pam-fi	1.8	Bool_t IsSaturated(Int_t); ///< saturated-cluster flag
72	pam-fi	1.6
73			Int_t GetPlane() { return (Int_t)((view+1)/2);}; ///< plane number (1-6)
74			Int_t GetLadder(){ return 1+(Int_t)((maxs-1)/1024); }; ///< ladder number (1-3)
75			Bool_t IsY(){ return (Bool_t)view%2; };
76			Bool_t IsX(){ return !((Bool_t)view%2); };
77	pam-fi	1.2
78			TrkCluster* GetTrkCluster(){ return this; };
79	pam-fi	1.1
80			friend class TrkLevel1;
81
82	pam-fi	1.2	ClassDef(TrkCluster,2);
83	pam-fi	1.1
84			};
85
86			/**
87			* \brief Class to describe tracker LEVEL1 data.
88			*
89	pam-fi	1.2	* A Level1 tracker event is defined as a collection of clusters ( TrkCluster objects ).
90			* The result of common-noise computation for each viking is also stored ( cnev[24][12] ).
91			* A general flag summarize the event status (missing sections, crc failures, decoding errors ans so on...).
92	pam-fi	1.1	*/
93			class TrkLevel1 : public TObject {
94
95			private:
96	pam-fi	1.5
97	pam-fi	1.1	public:
98
99	pam-fi	1.5	Int_t good[12]; ///< event status
100			Float_t cn[24][12]; ///< CN
101			// Float_t cnrms[24][12]; ///< CN RMS
102			Int_t cnn[24][12]; ///< number of strips for CN computation
103	pam-fi	1.7
104	pam-fi	1.2
105	pam-fi	1.1	TClonesArray *Cluster; ///< clusters
106	pam-fi	1.7
107	pam-fi	1.1	TrkLevel1();
108	pam-fi	1.5	~TrkLevel1(){Delete();};
109
110			int nclstr() {return Cluster->GetEntries();} ///< number of stored clusters
111
112	pam-fi	1.1	void Dump();
113	pam-fi	1.7	void SetFromLevel1Struct(cTrkLevel1 *, Bool_t);
114	pam-fi	1.3	// void GetLevel1Struct(cTrkLevel1 *) const;
115	pam-fi	1.5	cTrkLevel1* GetLevel1Struct();
116			void Clear();
117			void Delete();
118	pam-fi	1.9	void Set();
119	pam-fi	1.5
120	pam-fi	1.1	TrkCluster* GetCluster(int);
121
122			TrkLevel1* GetTrkLevel1(){return this;}
123	pam-fi	1.3	TClonesArray* GetClusters(){return Cluster;}; ///< returns pointer to the cluster array
124	pam-fi	1.1
125	pam-fi	1.10	int LoadPfaParam(TString);
126			int GetPfaNbinsAngle(){return pfa_.nangbin;};
127			int GetPfaNbinsETA(){return pfa_.netaval;};
128			int GetPfaNbinsCharge(){return 0;};
129			float* GetPfaCoord(TString pfa, int nview, int nladder, int nang);
130			float* GetPfaAbs(TString pfa, int nang);
131
132	pam-fi	1.5	ClassDef(TrkLevel1,2);
133	pam-fi	1.1
134			};
135
136
137			#endif