TrackerLevel2/inc/TrkLevel2.h

/**
 * \file TrkLevel2.h
 * \author Elena Vannuccini
 */
#ifndef trklevel2_h
#define trklevel2_h

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

#include <TrkParams.h>
#include <TrkLevel1.h>

// z-coordinate of track state-vector reference-plane
#define ZINI 23.5   
// (mechanical) z-coordinate of the tracker planes
#define ZTRK6 -22.22
#define ZTRK5 -13.31
#define ZTRK4 -4.41
#define ZTRK3 4.49
#define ZTRK2 13.39
#define ZTRK1 22.29
// magnet cavity dimensions
#define ZMAGNHIGH 21.83
#define ZMAGNLOW -21.83
#define XMAGNHIGH 8.07 
#define XMAGNLOW -8.07 
#define YMAGNHIGH 6.57 
#define YMAGNLOW -6.57 
// tof planes 
#define ZS11  53.74
#define ZS12  53.04
#define ZS21  23.94
#define ZS22  23.44
#define ZS31 -23.49
#define ZS32 -24.34

// (mechanical) x/y-coordinates of magnet cavity
/* #define XTRKL -8.1 */
/* #define XTRKR  8.1 */
/* #define YTRKL -6.6 */
/* #define YTRKR  6.6 */

/**
 * \brief Class to describe, by points, a particle trajectory in the apparatus. 
 *
 * The idea is to create it by integrating the equations of motion, given the 
 * track state vector and the z coordinates where to evaluate track position.
 */
// ==================================================================
class Trajectory : public TObject{
 private:

 public:

    int npoint; ///< number of evaluated points along the trajectory
    float* x;   //[npoint]
    float* y;   //[npoint]
    float* z;   //[npoint]
    float* thx; //[npoint]
    float* thy; //[npoint]
    float* tl;  //[npoint]

    Trajectory();
    Trajectory(int n);
    Trajectory(int n, float* pz);
    ~Trajectory(){Delete();};
    void Dump();
    void Delete();

    int DoTrack(float* al, float zini);
    int DoTrack(float* al){ return DoTrack(al,23.5); };

    int DoTrack2(float* al, float zini);
    int DoTrack2(float* al){ return DoTrack2(al,23.5); };

    float GetLength(){float l=0; for(int i=0; i<npoint;i++)l=l+tl[i]; return l;};
    float GetLength(int,int);

    ClassDef(Trajectory,3);

};
/**
 * \brief Class to describe fitted tracks. 
 *
 * A track is defined by the measured coordinates associated to it, the 
 * track status vector, plus other quantities.
 * A track may have an "image", due to the ambiguity in the y view.
 *
 * Cluster flags: xgood[6], ygood[6]
 * 
 * xgood/ygood = +/- 0lsccccccc
 * ccccccc ID (1-7483647) of the included cluster  
 * s       sensor number (1,2   - increasing y)
 * l       ladder number (1,2,3 - increasing x)
 * +/-     does-not/does include bad strips
 *
 */
// ==================================================================
class TrkTrack : public TObject {

private:

public:

    int   seqno;           ///<stored track sequential number
    int   image;           ///<sequential number of track-image
        
    float al[5];           ///<TRACK STATE VECTOR 
    float coval[5][5];     ///<covariance matrix 
    int   xgood[6];        ///<cluster id for x-view (0 = view not included in the fit) 
    int   ygood[6];        ///<cluster id for y-view (0 = view not included in the fit) 
    float xm[6];           ///<measured x coordinates
    float ym[6];           ///<measured y coordinates 
    float zm[6];           ///<measured z coordinates 
    float resx[6];         ///<spatial resolution on X view
    float resy[6];         ///<spatial resolution on y view
    float tailx[6];        ///<spatial resolution tail on X view
    float taily[6];        ///<spatial resolution tail on y view
    float chi2;            ///<chi2
    int   nstep;           ///<n.step
    float xv[6];           ///<calculated x coordinates
    float yv[6];           ///<calculated y coordinates
    float zv[6];           ///<calculated z coordinates
    float axv[6];          ///<calculated angles (deg) on x view
    float ayv[6];          ///<calculated angles (deg) on y view
    float dedx_x[6];       ///<dE/dx in MIP (<0 if saturated)
    float dedx_y[6];       ///<dE/dx in MIP (<0 if saturated) 
    int   multmaxx[6];     ///<cluster multiplicity and strip of maximum on x view
    int   multmaxy[6];     ///<cluster multiplicity and strip of maximum on y view
    float seedx[6];        ///< seed of the cluster x
    float seedy[6];        ///< seed of the cluster y
    float xpu[6];          ///< x coordinate in pitch units
    float ypu[6];          ///< y coordinate in pitch units

    float xGF[14];         ///<calculated x coordinates on GF reference planes
    float yGF[14];         ///<calculated y coordinates on GF reference planes

    TrkTrack();
    TrkTrack(const TrkTrack&);

    ~TrkTrack(){ Delete(); };
        
    void Dump();
    void Clear();
    void Clear(Option_t *option){Clear();};
    void Delete();
    void Copy(TrkTrack&);
//    void Set();

    Int_t  GetSeqNo(){return seqno;}        ///< Returns the track sequential number
    Int_t  GetImageSeqNo(){return image;}   ///< Returns the track image sequential number
    Bool_t HasImage(){return !(image==-1);} ///< Returns true if the track has an image
    int DoTrack(Trajectory* t);             ///< Evaluates the trajectory in the apparatus.
    int DoTrack2(Trajectory* t);            ///< Evaluates the trajectory in the apparatus.
    float BdL(){return 0;};                 ///< Evaluates the integral of B*dL along the track.
    Int_t GetNX(){Int_t n=0; for(Int_t i=0; i<6; i++)n+=(Int_t)XGood(i); return n;}; 
    Int_t GetNY(){Int_t n=0; for(Int_t i=0; i<6; i++)n+=(Int_t)YGood(i); return n;};
    Int_t GetNXY(){Int_t n=0; for(Int_t i=0; i<6; i++)n+=(Int_t)YGood(i)*XGood(i); return n;};
    Int_t GetNtot(){return GetNX()+GetNY();};
    Float_t GetRigidity();
    Float_t GetDeflection();
    Bool_t IsSaturated(int,int);
    Bool_t IsSaturated(int);
    Bool_t IsSaturated();
    Bool_t IsBad(int,int);
    Float_t GetDEDX();
    Float_t GetDEDX(int ip);
    Float_t GetDEDX(int ip,int iv);
    Int_t GetLeverArmXY();
    Int_t GetLeverArmX();
    Int_t GetLeverArmY();
    Float_t GetChi2X();
    Float_t GetChi2Y();
    Float_t GetLnLX();
    Float_t GetLnLY();

    Float_t GetEffectiveAngle(int ip, int iv);
    
    void SetMeasure(double *xmeas, double *ymeas, double *zmeas);
    void SetResolution(double *rx, double *ry);
    void SetTail(double *tx, double *ty, double factor);
    void SetStudentParam(int flag);
    void SetGood(int *xg, int *yg);
    void LoadField(TString s);
    void Fit(double pfixed, int& fail, int iprint, int froml1);
    void Fit(double pfixed, int& fail, int iprint){ Fit(pfixed,fail,iprint,0); };
    void FitReset();
    void SetTrackingMode(int trackmode);
    void SetPrecisionFactor(double fact);
    void SetStepMin(int istepmin);
    void SetDeltaB(int id, double db);

    Bool_t IsInsideCavity(float);
    Bool_t IsInsideCavity(){ return IsInsideCavity(0.); };
    Bool_t IsInsideAcceptance(float);
    Bool_t IsInsideAcceptance(){ return IsInsideAcceptance(0.); };
    Bool_t IsInsideGFSurface(const char*,float);
    Bool_t IsInsideGFSurface(const char* surf){ return IsInsideGFSurface(surf,0.); };

    Bool_t EvaluateClusterPositions();

    void FillMiniStruct(cMini2track&);
    void SetFromMiniStruct(cMini2track*);
    
    Int_t GetClusterX_ID(int ip);
    Int_t GetClusterY_ID(int ip);
    Int_t GetLadder(int ip);
    Int_t GetSensor(int ip);
    Bool_t XGood(int ip){ return GetClusterX_ID(ip)!=-1; };
    Bool_t YGood(int ip){ return GetClusterY_ID(ip)!=-1; };
    void ResetXGood(int ip){ xgood[ip]=0; };
    void ResetYGood(int ip){ ygood[ip]=0; };
/*     void SetXGood(int ip, int clid, int is); */
/*     void SetYGood(int ip, int clid, int is); */
    void SetXGood(int ip, int clid, int il, int is, bool bad);
    void SetYGood(int ip, int clid, int il, int is, bool bad);
    void SetXGood(int ip, int clid, int il, int is){ SetXGood(ip,clid,il,is,false); };
    void SetYGood(int ip, int clid, int il, int is){ SetYGood(ip,clid,il,is,false); };


    Bool_t BadClusterX(int ip){ return IsBad(ip,0); };
    Bool_t BadClusterY(int ip){ return IsBad(ip,1); };

    Bool_t SaturatedClusterX(int ip){ return IsSaturated(ip,0); };
    Bool_t SaturatedClusterY(int ip){ return IsSaturated(ip,1); };

    Int_t GetClusterX_Multiplicity(int ip){ return (Int_t)(multmaxx[ip]/10000); };
    Int_t GetClusterY_Multiplicity(int ip){ return (Int_t)(multmaxy[ip]/10000); };
    Int_t GetClusterX_MaxStrip(int ip){ return (Int_t)(multmaxx[ip]%10000); };
    Int_t GetClusterY_MaxStrip(int ip){ return (Int_t)(multmaxy[ip]%10000); };
    Float_t GetClusterX_Seed(int ip){ return seedx[ip]; };
    Float_t GetClusterY_Seed(int ip){ return seedy[ip]; };
/*     Float_t GetClusterX_oordinatePU(int ip); */
/*     Float_t GetClusterY_CoordinatePU(int ip); */
    
    Float_t GetYav();
    Float_t GetXav();
    Float_t GetZav();

    Int_t GetNColumns();

    Float_t GetDEDX_max(int ip, int iv);
    Float_t GetDEDX_max(int iv){ return GetDEDX_max(-1,iv); };
    Float_t GetDEDX_max(){ return GetDEDX_max(-1,-1); };
    Float_t GetDEDX_min(int ip, int iv);
    Float_t GetDEDX_min(int iv){ return GetDEDX_min(-1,iv); };
    Float_t GetDEDX_min(){ return GetDEDX_min(-1,-1); };

    Float_t GetResidual_max(int ip, int iv);
    Float_t GetResidual_max(int iv){ return GetResidual_max(-1,iv); };
    Float_t GetResidual_max(){ return GetResidual_max(-1,-1); };
    Float_t GetResidual_av(int ip, int iv);
    Float_t GetResidual_av(int iv){ return GetResidual_av(-1,iv); };
    Float_t GetResidual_av(){ return GetResidual_av(-1,-1); };

    Int_t GetClusterX_Multiplicity_max();
    Int_t GetClusterX_Multiplicity_min();
    Int_t GetClusterY_Multiplicity_max();
    Int_t GetClusterY_Multiplicity_min();

    Float_t GetClusterX_Seed_min();
    Float_t GetClusterY_Seed_min();

    TrkTrack* GetTrkTrack(){return this;};

    friend class TrkLevel2;

    ClassDef(TrkTrack,5);

};
/**
 * \brief Class to describe single clusters ("singlets"). 
 *
 * Single clusters are clusters not associated to any track.
 */
class TrkSinglet : public TObject {

private:
        

public:
        
    int plane;       ///<plane 
    float coord[2];  ///<coordinate (on sensor 1 and 2)
    float sgnl;      ///<cluster signal in MIP (<0 if saturated)
    int multmax;     ///<cluster multiplicity and strip of maximum

    TrkSinglet();
    TrkSinglet(const TrkSinglet&);
    ~TrkSinglet(){Delete();};

    void Dump();
    void Clear();
    void Clear(Option_t *option){Clear();};
    void Delete(){Clear();};
    Float_t GetSignal(){return fabs(sgnl);}
    Bool_t IsSaturated(){return (sgnl<0); };

    Bool_t IsBad()                 { return multmax<=0; };
    Int_t GetCluster_Multiplicity(){ return (Int_t)(abs(multmax)/10000); };
    Int_t GetCluster_MaxStrip()    { return (Int_t)(abs(multmax)%10000); };


    friend class TrkLevel2;

    ClassDef(TrkSinglet,4);

};

/**
 * \brief Class to describe tracker LEVEL2 data.
 *
 * A tracker events is defined by some general variables, plus the collection of all the fitted tracks and all 
 * single clusters on X and Y views. 
 * Tracks and single clusters ("singlets") are described by the classes TrkTrack and TrkSinglet respectivelly.
 * 
 * Each track may have an "image", due to the ambiguity on the Y view, which is stored also. 
 * Thus, the number of stored tracks ( ntrk() ) differs from the number of "physical" tracks ( GetNTracks() ). 
 * Proper methods allow to sort tracks and select the physical ones ( GetTracks() ).
 *
 * The event status indicates the processing status of data from each DSP, according to the following
 * notation:
 *
 * LSB --> 0 missing packet
 *         1 CRC error
 *         2 on-line software alarm (latch-up, timeout ecc...)
 *         3 jump in the trigger counter
 *         4 decode error
 *         5 n.clusters > maximum number (level1 processing)
 *         6 
 *         7 
 *         8 n.clusters > maximum value (level2 processing)
 *         9 n.couples per plane > maximum values (vector dimention)
 *         10 n.doublets > maximum values
 *         11 n.triplets > maximum values
 *         12 n.yz-clouds > maximum values
 *         13 n.xz-clouds > maximum values 
 *         14 n.candidate-tracks > maximum values
 *         15 n.couples per plane > maximum values (for Hough transform)
 * MSB --> 16 
 *         
 *
 * For all data processed before June 2007 the event status was coded according to
 * a different rule:
 *
 * Status of level1 processing
 *  0 -- OK  
 *  1 -- missing packet
 *  2 -- 1  CRC error
 *  3 -- 2 on-line software alarm (latch-up flags asserted or n.transmitted-words = 0)
 *  4 -- 3 jump in the trigger counter
 * 10 -- 4 decode error
 * 11 -- 5  n.clusters > maximum number (for level1 processing)
 * Status of level2 processing
 * 21 -- 0 n.clusters > maximum value (for level2 processing)
 * 22 -- 1 n.couples per plane > maximum values (vector dimention)
 * 23 -- 2 n.doublets > maximum values 
 * 24 -- 3 n.triplets > maximum values 
 * 25 -- 4 n.yz-clouds > maximum values 
 * 26 -- 5 n.xz-clouds > maximum values 
 * 27 -- 6 n.candidate-tracks > maximum values 
 * 28 -- 7 n.couples per plane > maximum values (for Hough transform)
 *  
 * 
 */
class TrkLevel2 : public TObject {

 private:
 
 public:

    Int_t         good[12];       ///< event status
    UInt_t        VKmask[12];     ///< Viking-chip mask
    UInt_t        VKflag[12];     ///< Viking-chip flag

    TClonesArray *Track;        ///< fitted tracks
    TClonesArray *SingletX;     ///< x singlets
    TClonesArray *SingletY;     ///< y singlets

    TrkLevel2();
//    TrkLevel2(cTrkLevel2 *);
    ~TrkLevel2(){Delete();};
        
    void Clear();
    void Clear(Option_t *option){Clear();};
    void Delete();
    void Set();
    int UnpackError(){ for(int i=0; i<12; i++)if(!StatusCheck(i,0x12))return 1; return 0;};
    
    int ntrk() {return Track->GetEntries();}    ///< number of stored track
    int nclsx(){return SingletX->GetEntries();} ///< number of x singlets 
    int nclsy(){return SingletY->GetEntries();} ///< number of y singlets 

    void Dump();
    void SetFromLevel2Struct(cTrkLevel2 *, TrkLevel1 *);
    void SetFromLevel2Struct(cTrkLevel2 *s2){ SetFromLevel2Struct(s2, NULL);          };
    void SetFromLevel2Struct(TrkLevel1 *l1) { SetFromLevel2Struct(&level2event_, l1); };    
    void SetFromLevel2Struct()              { SetFromLevel2Struct(&level2event_);     };    
    void GetLevel2Struct(cTrkLevel2 *) const;
    void LoadField(TString);
    float GetBX(float* v){return TrkParams::GetBX(v);};///< Bx (kGauss)
    float GetBY(float* v){return TrkParams::GetBY(v);};///< By (kGauss)
    float GetBZ(float* v){return TrkParams::GetBZ(v);};///< Bz (kGauss)
    Float_t GetZTrk(Int_t);
    Float_t GetXTrkLeft(){return XMAGNLOW;};
    Float_t GetXTrkRight(){return XMAGNHIGH;};
    Float_t GetYTrkLeft(){return YMAGNLOW;};
    Float_t GetYTrkRight(){return YMAGNHIGH;};
    
    Bool_t IsMaskedVK(int,int);
    Bool_t GetVKMask(int,int);
    Bool_t GetVKFlag(int,int);

    TrkSinglet   *GetSingletX(int);
    TrkSinglet   *GetSingletY(int);
    
    TrkTrack     *GetStoredTrack(int i);
    Int_t         GetSeqNo(Int_t i)  {return (((TrkTrack *)Track->At(i))->seqno);}; ///< Returns track sequential number

    TRefArray *GetTracks_NFitSorted();
    TRefArray *GetTracks(){return this->GetTracks_NFitSorted();};
    
    Int_t     GetNTracks();
    TrkTrack* GetTrack(int i);
    TrkTrack* GetTrackImage(int i);
    
    TrkLevel2*    GetTrkLevel2(){return this;}
    TClonesArray* GetTrackArray(){return Track;};///< returns pointer to the track array
    
    void   StatusDump(int view);
    Bool_t StatusCheck(int view, int flagmask);

    ClassDef(TrkLevel2,3);

};

#endif
1	mocchiut	1.1	/**
2			* \file TrkLevel2.h
3			* \author Elena Vannuccini
4			*/
5			#ifndef trklevel2_h
6			#define trklevel2_h
7
8			#include <TObject.h>
9			#include <TObjArray.h>
10			#include <TClonesArray.h>
11	pam-fi	1.7	#include <TRefArray.h>
12	pam-fi	1.8	#include <TRef.h>
13	pam-fi	1.3
14	pam-fi	1.18	#include <TrkParams.h>
15	pam-fi	1.8	#include <TrkLevel1.h>
16	mocchiut	1.1
17	pam-fi	1.2	// z-coordinate of track state-vector reference-plane
18			#define ZINI 23.5
19	pam-fi	1.5	// (mechanical) z-coordinate of the tracker planes
20	pam-fi	1.27	#define ZTRK6 -22.22
21			#define ZTRK5 -13.31
22			#define ZTRK4 -4.41
23			#define ZTRK3 4.49
24			#define ZTRK2 13.39
25			#define ZTRK1 22.29
26			// magnet cavity dimensions
27			#define ZMAGNHIGH 21.83
28			#define ZMAGNLOW -21.83
29			#define XMAGNHIGH 8.07
30			#define XMAGNLOW -8.07
31			#define YMAGNHIGH 6.57
32			#define YMAGNLOW -6.57
33	pam-fi	1.35	// tof planes
34			#define ZS11 53.74
35			#define ZS12 53.04
36			#define ZS21 23.94
37			#define ZS22 23.44
38			#define ZS31 -23.49
39			#define ZS32 -24.34
40
41	pam-fi	1.5	// (mechanical) x/y-coordinates of magnet cavity
42	pam-fi	1.34	/* #define XTRKL -8.1 */
43			/* #define XTRKR 8.1 */
44			/* #define YTRKL -6.6 */
45			/* #define YTRKR 6.6 */
46	pam-fi	1.2
47	mocchiut	1.1	/**
48			* \brief Class to describe, by points, a particle trajectory in the apparatus.
49			*
50			* The idea is to create it by integrating the equations of motion, given the
51			* track state vector and the z coordinates where to evaluate track position.
52			*/
53			// ==================================================================
54			class Trajectory : public TObject{
55			private:
56
57			public:
58
59			int npoint; ///< number of evaluated points along the trajectory
60	pam-fi	1.35	float* x; //[npoint]
61			float* y; //[npoint]
62			float* z; //[npoint]
63			float* thx; //[npoint]
64			float* thy; //[npoint]
65			float* tl; //[npoint]
66	mocchiut	1.1
67	pam-fi	1.2	Trajectory();
68	mocchiut	1.1	Trajectory(int n);
69			Trajectory(int n, float* pz);
70	pam-fi	1.15	~Trajectory(){Delete();};
71	mocchiut	1.1	void Dump();
72	pam-fi	1.15	void Delete();
73	mocchiut	1.1
74	pam-fi	1.41	int DoTrack(float* al, float zini);
75			int DoTrack(float* al){ return DoTrack(al,23.5); };
76
77			int DoTrack2(float* al, float zini);
78			int DoTrack2(float* al){ return DoTrack2(al,23.5); };
79
80	pam-fi	1.2	float GetLength(){float l=0; for(int i=0; i<npoint;i++)l=l+tl[i]; return l;};
81			float GetLength(int,int);
82
83	pam-fi	1.35	ClassDef(Trajectory,3);
84	mocchiut	1.1
85			};
86			/**
87			* \brief Class to describe fitted tracks.
88			*
89			* A track is defined by the measured coordinates associated to it, the
90			* track status vector, plus other quantities.
91			* A track may have an "image", due to the ambiguity in the y view.
92	pam-fi	1.24	*
93			* Cluster flags: xgood[6], ygood[6]
94			*
95			* xgood/ygood = +/- 0lsccccccc
96	pam-fi	1.35	* ccccccc ID (1-7483647) of the included cluster
97			* s sensor number (1,2 - increasing y)
98			* l ladder number (1,2,3 - increasing x)
99			* +/- does-not/does include bad strips
100			*
101	mocchiut	1.1	*/
102			// ==================================================================
103			class TrkTrack : public TObject {
104
105			private:
106
107	pam-fi	1.32	public:
108
109	pam-fi	1.3	int seqno; ///<stored track sequential number
110			int image; ///<sequential number of track-image
111	pam-fi	1.8
112	pam-fi	1.22	float al[5]; ///<TRACK STATE VECTOR
113	mocchiut	1.1	float coval[5][5]; ///<covariance matrix
114	pam-fi	1.31	int xgood[6]; ///<cluster id for x-view (0 = view not included in the fit)
115			int ygood[6]; ///<cluster id for y-view (0 = view not included in the fit)
116	mocchiut	1.1	float xm[6]; ///<measured x coordinates
117			float ym[6]; ///<measured y coordinates
118			float zm[6]; ///<measured z coordinates
119			float resx[6]; ///<spatial resolution on X view
120			float resy[6]; ///<spatial resolution on y view
121	pam-fi	1.24	float tailx[6]; ///<spatial resolution tail on X view
122			float taily[6]; ///<spatial resolution tail on y view
123	mocchiut	1.1	float chi2; ///<chi2
124	pam-fi	1.31	int nstep; ///<n.step
125	pam-fi	1.12	float xv[6]; ///<calculated x coordinates
126	mocchiut	1.1	float yv[6]; ///<calculated y coordinates
127			float zv[6]; ///<calculated z coordinates
128			float axv[6]; ///<calculated angles (deg) on x view
129			float ayv[6]; ///<calculated angles (deg) on y view
130	pam-fi	1.24	float dedx_x[6]; ///<dE/dx in MIP (<0 if saturated)
131			float dedx_y[6]; ///<dE/dx in MIP (<0 if saturated)
132	pam-fi	1.31	int multmaxx[6]; ///<cluster multiplicity and strip of maximum on x view
133			int multmaxy[6]; ///<cluster multiplicity and strip of maximum on y view
134			float seedx[6]; ///< seed of the cluster x
135			float seedy[6]; ///< seed of the cluster y
136			float xpu[6]; ///< x coordinate in pitch units
137			float ypu[6]; ///< y coordinate in pitch units
138	pam-fi	1.3
139	pam-fi	1.35	float xGF[14]; ///<calculated x coordinates on GF reference planes
140			float yGF[14]; ///<calculated y coordinates on GF reference planes
141
142	mocchiut	1.1	TrkTrack();
143			TrkTrack(const TrkTrack&);
144
145	pam-fi	1.15	~TrkTrack(){ Delete(); };
146	pam-fi	1.10
147	mocchiut	1.1	void Dump();
148	pam-fi	1.12	void Clear();
149	pam-fi	1.15	void Clear(Option_t *option){Clear();};
150	pam-fi	1.12	void Delete();
151	pam-fi	1.15	void Copy(TrkTrack&);
152	pam-fi	1.16	// void Set();
153
154	pam-fi	1.3	Int_t GetSeqNo(){return seqno;} ///< Returns the track sequential number
155			Int_t GetImageSeqNo(){return image;} ///< Returns the track image sequential number
156	mocchiut	1.1	Bool_t HasImage(){return !(image==-1);} ///< Returns true if the track has an image
157	pam-fi	1.35	int DoTrack(Trajectory* t); ///< Evaluates the trajectory in the apparatus.
158			int DoTrack2(Trajectory* t); ///< Evaluates the trajectory in the apparatus.
159			float BdL(){return 0;}; ///< Evaluates the integral of B*dL along the track.
160	pam-fi	1.24	Int_t GetNX(){Int_t n=0; for(Int_t i=0; i<6; i++)n+=(Int_t)XGood(i); return n;};
161			Int_t GetNY(){Int_t n=0; for(Int_t i=0; i<6; i++)n+=(Int_t)YGood(i); return n;};
162	pam-fi	1.39	Int_t GetNXY(){Int_t n=0; for(Int_t i=0; i<6; i++)n+=(Int_t)YGood(i)*XGood(i); return n;};
163	pam-fi	1.3	Int_t GetNtot(){return GetNX()+GetNY();};
164	mocchiut	1.1	Float_t GetRigidity();
165			Float_t GetDeflection();
166	pam-fi	1.24	Bool_t IsSaturated(int,int);
167			Bool_t IsSaturated(int);
168			Bool_t IsSaturated();
169			Bool_t IsBad(int,int);
170	mocchiut	1.1	Float_t GetDEDX();
171	pam-fi	1.28	Float_t GetDEDX(int ip);
172			Float_t GetDEDX(int ip,int iv);
173	pam-fi	1.39	Int_t GetLeverArmXY();
174	pam-fi	1.24	Int_t GetLeverArmX();
175			Int_t GetLeverArmY();
176	pam-fi	1.29	Float_t GetChi2X();
177			Float_t GetChi2Y();
178			Float_t GetLnLX();
179			Float_t GetLnLY();
180	pam-fi	1.12
181	pam-fi	1.30	Float_t GetEffectiveAngle(int ip, int iv);
182
183	pam-fi	1.12	void SetMeasure(double xmeas, double ymeas, double *zmeas);
184			void SetResolution(double rx, double ry);
185	pam-fi	1.26	void SetTail(double tx, double ty, double factor);
186			void SetStudentParam(int flag);
187	pam-fi	1.12	void SetGood(int xg, int yg);
188			void LoadField(TString s);
189	pam-fi	1.25	void Fit(double pfixed, int& fail, int iprint, int froml1);
190			void Fit(double pfixed, int& fail, int iprint){ Fit(pfixed,fail,iprint,0); };
191	pam-fi	1.12	void FitReset();
192	pam-fi	1.19	void SetTrackingMode(int trackmode);
193	pam-fi	1.21	void SetPrecisionFactor(double fact);
194			void SetStepMin(int istepmin);
195	pam-fi	1.33	void SetDeltaB(int id, double db);
196
197	pam-fi	1.35	Bool_t IsInsideCavity(float);
198			Bool_t IsInsideCavity(){ return IsInsideCavity(0.); };
199	pam-fi	1.42	Bool_t IsInsideAcceptance(float);
200			Bool_t IsInsideAcceptance(){ return IsInsideAcceptance(0.); };
201			Bool_t IsInsideGFSurface(const char*,float);
202			Bool_t IsInsideGFSurface(const char* surf){ return IsInsideGFSurface(surf,0.); };
203	pam-fi	1.14
204	pam-fi	1.28	Bool_t EvaluateClusterPositions();
205	pam-fi	1.25
206	pam-fi	1.14	void FillMiniStruct(cMini2track&);
207			void SetFromMiniStruct(cMini2track*);
208	pam-fi	1.12
209	pam-fi	1.24	Int_t GetClusterX_ID(int ip);
210			Int_t GetClusterY_ID(int ip);
211			Int_t GetLadder(int ip);
212			Int_t GetSensor(int ip);
213			Bool_t XGood(int ip){ return GetClusterX_ID(ip)!=-1; };
214			Bool_t YGood(int ip){ return GetClusterY_ID(ip)!=-1; };
215	pam-fi	1.39	void ResetXGood(int ip){ xgood[ip]=0; };
216	pam-fi	1.25	void ResetYGood(int ip){ ygood[ip]=0; };
217	pam-fi	1.36	/* void SetXGood(int ip, int clid, int is); */
218			/* void SetYGood(int ip, int clid, int is); */
219			void SetXGood(int ip, int clid, int il, int is, bool bad);
220			void SetYGood(int ip, int clid, int il, int is, bool bad);
221			void SetXGood(int ip, int clid, int il, int is){ SetXGood(ip,clid,il,is,false); };
222			void SetYGood(int ip, int clid, int il, int is){ SetYGood(ip,clid,il,is,false); };
223
224	pam-fi	1.24
225			Bool_t BadClusterX(int ip){ return IsBad(ip,0); };
226			Bool_t BadClusterY(int ip){ return IsBad(ip,1); };
227
228			Bool_t SaturatedClusterX(int ip){ return IsSaturated(ip,0); };
229			Bool_t SaturatedClusterY(int ip){ return IsSaturated(ip,1); };
230	pam-fi	1.20
231	pam-fi	1.31	Int_t GetClusterX_Multiplicity(int ip){ return (Int_t)(multmaxx[ip]/10000); };
232			Int_t GetClusterY_Multiplicity(int ip){ return (Int_t)(multmaxy[ip]/10000); };
233			Int_t GetClusterX_MaxStrip(int ip){ return (Int_t)(multmaxx[ip]%10000); };
234			Int_t GetClusterY_MaxStrip(int ip){ return (Int_t)(multmaxy[ip]%10000); };
235			Float_t GetClusterX_Seed(int ip){ return seedx[ip]; };
236			Float_t GetClusterY_Seed(int ip){ return seedy[ip]; };
237	pam-fi	1.36	/* Float_t GetClusterX_oordinatePU(int ip); */
238	pam-fi	1.31	/* Float_t GetClusterY_CoordinatePU(int ip); */
239
240	pam-fi	1.34	Float_t GetYav();
241			Float_t GetXav();
242			Float_t GetZav();
243
244			Int_t GetNColumns();
245
246			Float_t GetDEDX_max(int ip, int iv);
247			Float_t GetDEDX_max(int iv){ return GetDEDX_max(-1,iv); };
248			Float_t GetDEDX_max(){ return GetDEDX_max(-1,-1); };
249			Float_t GetDEDX_min(int ip, int iv);
250			Float_t GetDEDX_min(int iv){ return GetDEDX_min(-1,iv); };
251			Float_t GetDEDX_min(){ return GetDEDX_min(-1,-1); };
252
253			Float_t GetResidual_max(int ip, int iv);
254			Float_t GetResidual_max(int iv){ return GetResidual_max(-1,iv); };
255			Float_t GetResidual_max(){ return GetResidual_max(-1,-1); };
256	pam-fi	1.37	Float_t GetResidual_av(int ip, int iv);
257			Float_t GetResidual_av(int iv){ return GetResidual_av(-1,iv); };
258			Float_t GetResidual_av(){ return GetResidual_av(-1,-1); };
259	pam-fi	1.34
260			Int_t GetClusterX_Multiplicity_max();
261			Int_t GetClusterX_Multiplicity_min();
262			Int_t GetClusterY_Multiplicity_max();
263			Int_t GetClusterY_Multiplicity_min();
264
265			Float_t GetClusterX_Seed_min();
266			Float_t GetClusterY_Seed_min();
267	pam-fi	1.31
268	mocchiut	1.1	TrkTrack* GetTrkTrack(){return this;};
269
270	pam-fi	1.3	friend class TrkLevel2;
271
272	pam-fi	1.35	ClassDef(TrkTrack,5);
273	mocchiut	1.1
274			};
275			/**
276			* \brief Class to describe single clusters ("singlets").
277			*
278			* Single clusters are clusters not associated to any track.
279			*/
280			class TrkSinglet : public TObject {
281
282			private:
283	pam-fi	1.8
284	mocchiut	1.1
285			public:
286	pam-fi	1.8
287	mocchiut	1.1	int plane; ///<plane
288			float coord[2]; ///<coordinate (on sensor 1 and 2)
289	pam-fi	1.24	float sgnl; ///<cluster signal in MIP (<0 if saturated)
290	pam-fi	1.35	int multmax; ///<cluster multiplicity and strip of maximum
291	mocchiut	1.1
292			TrkSinglet();
293			TrkSinglet(const TrkSinglet&);
294	pam-fi	1.15	~TrkSinglet(){Delete();};
295	mocchiut	1.1
296			void Dump();
297	pam-fi	1.15	void Clear();
298			void Clear(Option_t *option){Clear();};
299			void Delete(){Clear();};
300	pam-fi	1.24	Float_t GetSignal(){return fabs(sgnl);}
301			Bool_t IsSaturated(){return (sgnl<0); };
302	pam-fi	1.35
303			Bool_t IsBad() { return multmax<=0; };
304			Int_t GetCluster_Multiplicity(){ return (Int_t)(abs(multmax)/10000); };
305			Int_t GetCluster_MaxStrip() { return (Int_t)(abs(multmax)%10000); };
306
307
308	pam-fi	1.3	friend class TrkLevel2;
309
310	pam-fi	1.35	ClassDef(TrkSinglet,4);
311	mocchiut	1.1
312			};
313
314			/**
315			* \brief Class to describe tracker LEVEL2 data.
316			*
317			* A tracker events is defined by some general variables, plus the collection of all the fitted tracks and all
318			* single clusters on X and Y views.
319			* Tracks and single clusters ("singlets") are described by the classes TrkTrack and TrkSinglet respectivelly.
320			*
321			* Each track may have an "image", due to the ambiguity on the Y view, which is stored also.
322			* Thus, the number of stored tracks ( ntrk() ) differs from the number of "physical" tracks ( GetNTracks() ).
323			* Proper methods allow to sort tracks and select the physical ones ( GetTracks() ).
324	pam-fi	1.28	*
325			* The event status indicates the processing status of data from each DSP, according to the following
326			* notation:
327			*
328	pam-fi	1.35	* LSB --> 0 missing packet
329			* 1 CRC error
330			* 2 on-line software alarm (latch-up, timeout ecc...)
331			* 3 jump in the trigger counter
332			* 4 decode error
333			* 5 n.clusters > maximum number (level1 processing)
334			* 6
335			* 7
336			* 8 n.clusters > maximum value (level2 processing)
337			* 9 n.couples per plane > maximum values (vector dimention)
338			* 10 n.doublets > maximum values
339			* 11 n.triplets > maximum values
340			* 12 n.yz-clouds > maximum values
341			* 13 n.xz-clouds > maximum values
342			* 14 n.candidate-tracks > maximum values
343			* 15 n.couples per plane > maximum values (for Hough transform)
344			* MSB --> 16
345	pam-fi	1.28	*
346			*
347	pam-fi	1.39	* For all data processed before June 2007 the event status was coded according to
348			* a different rule:
349			*
350			* Status of level1 processing
351			* 0 -- OK
352			* 1 -- missing packet
353			* 2 -- 1 CRC error
354			* 3 -- 2 on-line software alarm (latch-up flags asserted or n.transmitted-words = 0)
355			* 4 -- 3 jump in the trigger counter
356			* 10 -- 4 decode error
357			* 11 -- 5 n.clusters > maximum number (for level1 processing)
358			* Status of level2 processing
359			* 21 -- 0 n.clusters > maximum value (for level2 processing)
360			* 22 -- 1 n.couples per plane > maximum values (vector dimention)
361			* 23 -- 2 n.doublets > maximum values
362			* 24 -- 3 n.triplets > maximum values
363			* 25 -- 4 n.yz-clouds > maximum values
364			* 26 -- 5 n.xz-clouds > maximum values
365			* 27 -- 6 n.candidate-tracks > maximum values
366			* 28 -- 7 n.couples per plane > maximum values (for Hough transform)
367	pam-fi	1.28	*
368			*
369	mocchiut	1.1	*/
370			class TrkLevel2 : public TObject {
371
372			private:
373	pam-fi	1.15
374	mocchiut	1.1	public:
375
376	pam-fi	1.15	Int_t good[12]; ///< event status
377	pam-fi	1.24	UInt_t VKmask[12]; ///< Viking-chip mask
378			UInt_t VKflag[12]; ///< Viking-chip flag
379	mocchiut	1.1
380			TClonesArray *Track; ///< fitted tracks
381			TClonesArray *SingletX; ///< x singlets
382			TClonesArray *SingletY; ///< y singlets
383
384			TrkLevel2();
385			// TrkLevel2(cTrkLevel2 *);
386	pam-fi	1.11	~TrkLevel2(){Delete();};
387	pam-fi	1.10
388	pam-fi	1.11	void Clear();
389	pam-fi	1.15	void Clear(Option_t *option){Clear();};
390	pam-fi	1.11	void Delete();
391	pam-fi	1.16	void Set();
392	pam-fi	1.40	int UnpackError(){ for(int i=0; i<12; i++)if(!StatusCheck(i,0x12))return 1; return 0;};
393	pam-fi	1.11
394			int ntrk() {return Track->GetEntries();} ///< number of stored track
395	mocchiut	1.1	int nclsx(){return SingletX->GetEntries();} ///< number of x singlets
396			int nclsy(){return SingletY->GetEntries();} ///< number of y singlets
397
398			void Dump();
399	pam-fi	1.11	void SetFromLevel2Struct(cTrkLevel2 , TrkLevel1 );
400	pam-fi	1.18	void SetFromLevel2Struct(cTrkLevel2 *s2){ SetFromLevel2Struct(s2, NULL); };
401			void SetFromLevel2Struct(TrkLevel1 *l1) { SetFromLevel2Struct(&level2event_, l1); };
402			void SetFromLevel2Struct() { SetFromLevel2Struct(&level2event_); };
403	pam-fi	1.11	void GetLevel2Struct(cTrkLevel2 *) const;
404	pam-fi	1.3	void LoadField(TString);
405	pam-fi	1.25	float GetBX(float* v){return TrkParams::GetBX(v);};///< Bx (kGauss)
406			float GetBY(float* v){return TrkParams::GetBY(v);};///< By (kGauss)
407			float GetBZ(float* v){return TrkParams::GetBZ(v);};///< Bz (kGauss)
408	pam-fi	1.6	Float_t GetZTrk(Int_t);
409	pam-fi	1.34	Float_t GetXTrkLeft(){return XMAGNLOW;};
410			Float_t GetXTrkRight(){return XMAGNHIGH;};
411			Float_t GetYTrkLeft(){return YMAGNLOW;};
412			Float_t GetYTrkRight(){return YMAGNHIGH;};
413	pam-fi	1.6
414	pam-fi	1.24	Bool_t IsMaskedVK(int,int);
415			Bool_t GetVKMask(int,int);
416			Bool_t GetVKFlag(int,int);
417
418	pam-fi	1.6	TrkSinglet *GetSingletX(int);
419			TrkSinglet *GetSingletY(int);
420
421			TrkTrack *GetStoredTrack(int i);
422	pam-fi	1.3	Int_t GetSeqNo(Int_t i) {return (((TrkTrack *)Track->At(i))->seqno);}; ///< Returns track sequential number
423	pam-fi	1.24
424	pam-fi	1.11	TRefArray *GetTracks_NFitSorted();
425			TRefArray *GetTracks(){return this->GetTracks_NFitSorted();};
426
427			Int_t GetNTracks();
428			TrkTrack* GetTrack(int i);
429	mocchiut	1.1	TrkTrack* GetTrackImage(int i);
430	pam-fi	1.11
431	pam-fi	1.3	TrkLevel2* GetTrkLevel2(){return this;}
432			TClonesArray* GetTrackArray(){return Track;};///< returns pointer to the track array
433
434	pam-fi	1.28	void StatusDump(int view);
435			Bool_t StatusCheck(int view, int flagmask);
436
437	pam-fi	1.24	ClassDef(TrkLevel2,3);
438	mocchiut	1.1
439			};
440
441			#endif