ToFLevel2/inc/ToFLevel2.h

/**
 * \file ToFLevel2.h
 * \author Gianfranca DeRosa / Wolfgang Menn / Rita Carbone with E. M. supervision
 */

#ifndef ToFLevel2_h
#define ToFLevel2_h
//
#include <TObject.h>
#include <TArrayI.h>
#include <TArrayF.h>
#include <TClonesArray.h>

#include <math.h> // EMILIANO
#include <iostream> // from ToFLevel2.cpp
#include <fstream> // Emiliano
#include <sstream> // Emiliano 
#include <string> // Emiliano


#include <ToFStruct.h>

#include <TrkLevel2.h> // Emiliano
#include <TrigLevel2.h> // Emiliano 
#include <GLTables.h> // Emiliano
#include <OrbitalInfo.h> // Emiliano
#include <ToFCore.h> // Emiliano
#include <physics/tof/TofEvent.h>

//
// Declaration of the core fortran routines
//
#define tofl2com tofl2com_
extern "C" int tofl2com();
#define toftrk toftrk_
extern "C" int toftrk();
#define rdtofcal rdtofcal_
extern "C" int rdtofcal(char [], int *);

//
// class which contains track related variables
//
#define ZTOF11 53.74
#define ZTOF12 53.04
#define ZTOF21 23.94
#define ZTOF22 23.44
#define ZTOF31 -23.49
#define ZTOF32 -24.34


class ToFGeom : public TObject {

private:
  TArrayI  ePlane, eXY;

public:
  ToFGeom() {
    int plane[24] = { 
      0, 0, 0, 0, 0, 0, 0, 0,
      1, 1, 1, 1, 1, 1, 
      2, 2,             
      3, 3,             
      4, 4, 4,
      5, 5, 5
    };
    int plXY[6]= {  2,  1,  1,  2,  2,  1 }; // X==1, Y==2 */
    ePlane.Set(24,plane);
    eXY.Set(6,plXY);
  }

  int GetPad(   int idpmt)  { return (int)((idpmt+0.5)/2.); }
  int GetPlane( int idpmt)  { return ePlane[ GetPad(idpmt) ];  }
  int GetXY(    int idpmt)  { return eXY[ GetPlane(idpmt) ]; }

   ClassDef(ToFGeom,1);

};


/**
 * \brief  Class which contains the PMT data
 *
 * If there is a valid ADC or a TDC value (value<4095) for a PMT, both ADC and TDC data
 * are stored in the PMT class.
 * Look in the ToFLevel2Ex.cxx example in the repository how to read the PMT class. 
 */
class ToFPMT : public TObject {

 private:

 public:
    Int_t pmt_id;     ///<the identification number of the PMT from 0 to 47
    Float_t adc;      ///<raw ADC value for this PMT
    Float_t tdc;      ///<raw TDC value for this PMT
    Float_t tdc_tw;   ///<time-walk corrected TDC value for this PMT
    //
    ToFPMT();
    ToFPMT(const ToFPMT&);
    //
    ToFPMT* GetToFPMT(){return this;};
    void Clear(Option_t *t="");

    ClassDef(ToFPMT,2);
};

/**
 * \brief  Class used to calibrate adc to dEdx for each PMT
 *
 * Class used to calibrate adc to dEdx for each PMT
 */
class ToFdEdx : public TObject {

 private:
    //
    ToFGeom  eGeom;  // ToF geometry
    //
    Float_t  adc_he;
    TArrayF eDEDXpmt;  // 0-47  pmt dEdx
    // parameters:
    TArrayF PMTsat;  // 0-47  saturation parameters
    Float_t adc[48];
    //

    TArrayF parAtt[48];      // 48 x 6
    TArrayF parPos[48];      // 48 x 4
    TArrayF parDesatBB[48];  // 48 x 3
    TArrayF parBBneg[48];    // 48 x 3
    TArrayF  parBBpos;    // 48 x 1
 
    double f_adcPC( float x );
    double f_BB( TArrayF &p, float x );
    double f_BB5B( float x );
    double f_att( TArrayF &p, float x ) ;
    double f_att5B( float x );
    double f_desatBB( TArrayF &p, float x );  
    double f_desatBB5B( float x );
    double f_pos( TArrayF &p, float x );
    double f_pos5B( float x );
    float Get_adc_he( int id, float pl_x[6], float pl_y[6]);

    Bool_t conn[12]; 

    UInt_t ts[12];
    UInt_t te[12];    
   
    
 public:
    ToFdEdx();   // class constructor
    ~ToFdEdx(){ Delete(); };  // class distructor
    //
    void Clear(Option_t *option="");
    void Delete(Option_t *option="") { Clear(); }

    void Init(pamela::tof::TofEvent *tofl0 );  // init parameters
    void Init(Int_t i, Int_t j, Float_t adce);
    void Define_PMTsat();

    void ReadParAtt(            const char *fname  );
    void ReadParPos(            const char *fname  );
    void ReadParBBneg(          const char *fname  );
    void ReadParBBpos(          const char *fname  );
    void ReadParDesatBB(        const char *fname  );

    void CheckConnectors(UInt_t atime, GL_PARAM *glparam, TSQLServer *dbc);

    void Process( UInt_t atime, Float_t betamean, Float_t *xtr_tof, Float_t *ytr_tof); //
    void Print(Option_t *option="");

    Float_t GetdEdx_pmt(Int_t ipmt) { return eDEDXpmt[ipmt]; }  // 0-47 dEdx for each PMT for tracked events
    //
    ToFdEdx* GetToFdEdx(){return this;};
    ClassDef(ToFdEdx,2);
};


/**
 * \brief Class which contains the tracker related variables
 *
 * We can use the ToF standalone to find hitted paddles, calculate beta, etc..
 * These results are then stored with the "trkseqno" = -1.
 * If we use the track from the tracker, then the penetration points in the
 * scintillators are calculated, which defines the hitted paddles. For these paddles
 * we calculate then all the output.
 * Note: The artificial ADC values are stored as dEdx in the output, the dEdx will be
 * by definition = 1. However, the artificial TDC values are just used internally
 * and not stored in the output. But one can see in both cases which PMT has artificial
 * values using "adcflag" and "tdcflag".
 * Look in the ToFLevel2Ex.cxx example in the repository how to read the tracker related
 * variables. 
 */
class ToFTrkVar : public TObject {

 private:

 public:
  //
  Int_t trkseqno; ///< tracker sequ. number: -1=ToF standalone, 0=first Tracker track, ...
  //
  Int_t npmttdc;  ///<number of the TDC measurements used to evaluate beta
  TArrayI pmttdc;  ///<contains the ID (0..47) for the PMT used to evaluate beta
  TArrayI tdcflag; ///<flag for artificial TDC, "0" if normal TDC value

/**
 * \brief beta, 12 measurements for the 12  combinations, beta[13] is modified weighted mean
 *
 * The 12 measurements are S11-S31, S11-S32, S12-S31, S12-S32, and then analogue for
 * S2-S3 and S1-S2. 
 * The calculation of beta[13] is now modified:
 * We check the individual weights for artificial TDC values, then calculate
 * am mean beta for the first time. In a second step we loop again through
 * the single measurements, checking for the residual from the mean
 * The cut on the residual reject measurements > "x"-sigma. A chi2 value is
 * calculated, furthermore a "quality" value by adding the weights which
 * are finally used. If all measurements are taken, "quality" will be = 505.
 * A chi2 cut around 3-4 and a quality-cut > 400 is needed for clean beta
 * The Level2 beta[12] which is derived in the fortran routines uses: 10.,200.,20.
 * This is not a very high quality measurement. One can re-calculate a new beta[13]
 * using the L2-method "CalcBeta"
 */
  Float_t beta[13]; 
  //
  Int_t npmtadc;  ///<number of the ADC measurements used for dEdx evaluation
  TArrayI pmtadc; ///<contains the ID (0..47) for the PMT used to evaluate dEdx
  TArrayI adcflag; ///<flag for artificial ADCs, "0" if normal ADC value
  TArrayF dedx;    ///<energy loss for this PMT in mip
  //
  Float_t xtofpos[3];  ///<x-measurement using the TDC values and the calibration from S12, S21, S32
  Float_t ytofpos[3];  ///<x-measurement using the TDC values and the calibration from S11, S22, S31
  //
  Float_t xtr_tof[6];  ///<x-measurement in the ToF layers from tracker
  Float_t ytr_tof[6];  ///<x-measurement in the ToF layers from tracker
  //
  ToFTrkVar();
  ToFTrkVar(const ToFTrkVar&);

  ToFTrkVar* GetToFTrkVar(){return this;};
  void Clear(Option_t *t="");

  ClassDef(ToFTrkVar,1);
  //
};

/**
 * \brief  Class to describe ToF LEVEL2 data
 *
 */

class ToFLevel2 : public TObject {
 private:

 public:
  //
  TClonesArray *PMT; ///<class needed to store PMT hit informations
  TClonesArray *ToFTrk; ///<track related variable class
  Int_t tof_j_flag[6];  ///<number of hitted paddle(s) for each ToF layer: flag = flag + 2**(paddlenumber-1)
  //
  Int_t unpackError;///< zero if no error presente
  Int_t default_calib; ///< one if the default calibration has been used to process the data, zero otherwise
  //
  Float_t GetdEdx(Int_t notrack, Int_t plane, Int_t adcfl); // gf Apr 07

  Float_t CalcBeta(Int_t notrack, Float_t resmax, Float_t qualitycut, Float_t chi2cut);  //  wm feb 08

  //
//  Float_t CalcBeta(Int_t notrack, Float_t resmax, Float_t chi2cut, Float_t qualitycut);   // wm feb 08
  //
  // methods to make life simplier during the analysis, returns a pointer to the ToFTrkVar class containing track related variables
  //
  Int_t ntrk(){return ToFTrk->GetEntries();};
  Int_t npmt(){return PMT->GetEntries();};

  //
  void GetLevel2Struct(cToFLevel2 *) const;
  //
  ToFTrkVar *GetToFTrkVar(Int_t notrack);
  ToFPMT *GetToFPMT(Int_t nohit);
  Int_t GetPMTid(Int_t gg, Int_t hh);
  TString GetPMTName(Int_t ind);
  
  Int_t GetPlaneIndex(Int_t pmt_id);
  void GetMatrix(Int_t notrack, Float_t adc[4][12], Float_t tdc[4][12]);
  void GetPMTIndex(Int_t pmt_id, Int_t &gg, Int_t &hh);

  // gf Apr 07
  void GetdEdxPaddle(Int_t notrack, Int_t paddleid, Int_t adcfl, Float_t &PadEdx, Int_t &SatWarning); // gf Apr 07
  TString GetPMTName(Int_t ind, Int_t &iplane, Int_t &ipaddle,Int_t &ipmt);
  Int_t GetPaddleIdOfTrack(Float_t xtr, Float_t ytr, Int_t plane); // gf Apr 07
  Int_t GetPaddleIdOfTrack(Float_t xtr, Float_t ytr, Int_t plane, Float_t margin); // wm jun 2008
  void GetPMTPaddle(Int_t pmt_id, Int_t &plane, Int_t &paddle); // gf Apr 07
  void GetPaddlePMT(Int_t paddle, Int_t &pmtleft, Int_t &pmtright); // gf Apr 07
  void GetPaddleGeometry(Int_t plane, Int_t paddle, Float_t &xleft, Float_t &xright, Float_t &yleft, Float_t &yright); // gf Apr 07
  Int_t GetPaddleid(Int_t plane, Int_t paddle);
  void GetPaddlePlane(Int_t padid, Int_t &plane, Int_t &paddle);
  Int_t GetNPaddle(Int_t plane);
  //
  //
  //
  Int_t Process(TrkLevel2 *trk, TrigLevel2 *trg, GL_RUN *run, OrbitalInfo *orb, Bool_t force); // Emiliano
  
  //
  // constructor
  //
  ToFLevel2();
  ~ToFLevel2(){Delete();}; //ELENA
  void Delete(Option_t *t=""); //ELENA
  void Set();//ELENA
  //
  //
  ToFLevel2*   GetToFLevel2(){return this;};

/**
 * Method to get the z-position of the 6 TOF layers from the plane ID
 * @param plane_id Plane ID (11 12 21 22 31 32)
 */
  Float_t      GetZTOF(Int_t plane_id){
      switch(plane_id){
      case 11: return ZTOF11;
      case 12: return ZTOF12;
      case 21: return ZTOF21;
      case 22: return ZTOF22;
      case 31: return ZTOF31;
      case 32: return ZTOF32;
      default: return 0.;
      };
  };

    //
    // Paddles position
    //
    /*
      S11 8 paddles  33.0 x 5.1 cm
      S12 6 paddles  40.8 x 5.5 cm
      S21 2 paddles  18.0 x 7.5 cm
      S22 2 paddles  15.0 x 9.0 cm
      S31 3 paddles  15.0 x 6.0 cm
      S32 3 paddles  18.0 x 5.0 cm
    */

    Int_t  GetToFPlaneID(Int_t ip);
    Int_t  GetToFPlaneIndex(Int_t plane_id);
    Bool_t HitPaddle(Int_t ,Int_t);
    Int_t  GetNHitPaddles(Int_t plane);
    void Clear(Option_t *t="");
    //
    ClassDef(ToFLevel2,4);
};

#endif

1	/**
2	* \file ToFLevel2.h
3	* \author Gianfranca DeRosa / Wolfgang Menn / Rita Carbone with E. M. supervision
4	*/
5
6	#ifndef ToFLevel2_h
7	#define ToFLevel2_h
8	//
9	#include <TObject.h>
10	#include <TArrayI.h>
11	#include <TArrayF.h>
12	#include <TClonesArray.h>
13
14	#include <math.h> // EMILIANO
15	#include <iostream> // from ToFLevel2.cpp
16	#include <fstream> // Emiliano
17	#include <sstream> // Emiliano
18	#include <string> // Emiliano
19
20
21	#include <ToFStruct.h>
22
23	#include <TrkLevel2.h> // Emiliano
24	#include <TrigLevel2.h> // Emiliano
25	#include <GLTables.h> // Emiliano
26	#include <OrbitalInfo.h> // Emiliano
27	#include <ToFCore.h> // Emiliano
28	#include <physics/tof/TofEvent.h>
29
30	//
31	// Declaration of the core fortran routines
32	//
33	#define tofl2com tofl2com_
34	extern "C" int tofl2com();
35	#define toftrk toftrk_
36	extern "C" int toftrk();
37	#define rdtofcal rdtofcal_
38	extern "C" int rdtofcal(char [], int *);
39
40	//
41	// class which contains track related variables
42	//
43	#define ZTOF11 53.74
44	#define ZTOF12 53.04
45	#define ZTOF21 23.94
46	#define ZTOF22 23.44
47	#define ZTOF31 -23.49
48	#define ZTOF32 -24.34
49
50
51	class ToFGeom : public TObject {
52
53	private:
54	TArrayI ePlane, eXY;
55
56	public:
57	ToFGeom() {
58	int plane[24] = {
59	0, 0, 0, 0, 0, 0, 0, 0,
60	1, 1, 1, 1, 1, 1,
61	2, 2,
62	3, 3,
63	4, 4, 4,
64	5, 5, 5
65	};
66	int plXY[6]= { 2, 1, 1, 2, 2, 1 }; // X==1, Y==2 */
67	ePlane.Set(24,plane);
68	eXY.Set(6,plXY);
69	}
70
71	int GetPad( int idpmt) { return (int)((idpmt+0.5)/2.); }
72	int GetPlane( int idpmt) { return ePlane[ GetPad(idpmt) ]; }
73	int GetXY( int idpmt) { return eXY[ GetPlane(idpmt) ]; }
74
75	ClassDef(ToFGeom,1);
76
77	};
78
79
80	/**
81	* \brief Class which contains the PMT data
82	*
83	* If there is a valid ADC or a TDC value (value<4095) for a PMT, both ADC and TDC data
84	* are stored in the PMT class.
85	* Look in the ToFLevel2Ex.cxx example in the repository how to read the PMT class.
86	*/
87	class ToFPMT : public TObject {
88
89	private:
90
91	public:
92	Int_t pmt_id; ///<the identification number of the PMT from 0 to 47
93	Float_t adc; ///<raw ADC value for this PMT
94	Float_t tdc; ///<raw TDC value for this PMT
95	Float_t tdc_tw; ///<time-walk corrected TDC value for this PMT
96	//
97	ToFPMT();
98	ToFPMT(const ToFPMT&);
99	//
100	ToFPMT* GetToFPMT(){return this;};
101	void Clear(Option_t *t="");
102
103	ClassDef(ToFPMT,2);
104	};
105
106	/**
107	* \brief Class used to calibrate adc to dEdx for each PMT
108	*
109	* Class used to calibrate adc to dEdx for each PMT
110	*/
111	class ToFdEdx : public TObject {
112
113	private:
114	//
115	ToFGeom eGeom; // ToF geometry
116	//
117	Float_t adc_he;
118	TArrayF eDEDXpmt; // 0-47 pmt dEdx
119	// parameters:
120	TArrayF PMTsat; // 0-47 saturation parameters
121	Float_t adc[48];
122	//
123
124	TArrayF parAtt[48]; // 48 x 6
125	TArrayF parPos[48]; // 48 x 4
126	TArrayF parDesatBB[48]; // 48 x 3
127	TArrayF parBBneg[48]; // 48 x 3
128	TArrayF parBBpos; // 48 x 1
129
130	double f_adcPC( float x );
131	double f_BB( TArrayF &p, float x );
132	double f_BB5B( float x );
133	double f_att( TArrayF &p, float x ) ;
134	double f_att5B( float x );
135	double f_desatBB( TArrayF &p, float x );
136	double f_desatBB5B( float x );
137	double f_pos( TArrayF &p, float x );
138	double f_pos5B( float x );
139	float Get_adc_he( int id, float pl_x[6], float pl_y[6]);
140
141	Bool_t conn[12];
142
143	UInt_t ts[12];
144	UInt_t te[12];
145
146
147	public:
148	ToFdEdx(); // class constructor
149	~ToFdEdx(){ Delete(); }; // class distructor
150	//
151	void Clear(Option_t *option="");
152	void Delete(Option_t *option="") { Clear(); }
153
154	void Init(pamela::tof::TofEvent *tofl0 ); // init parameters
155	void Init(Int_t i, Int_t j, Float_t adce);
156	void Define_PMTsat();
157
158	void ReadParAtt( const char *fname );
159	void ReadParPos( const char *fname );
160	void ReadParBBneg( const char *fname );
161	void ReadParBBpos( const char *fname );
162	void ReadParDesatBB( const char *fname );
163
164	void CheckConnectors(UInt_t atime, GL_PARAM glparam, TSQLServer dbc);
165
166	void Process( UInt_t atime, Float_t betamean, Float_t xtr_tof, Float_t ytr_tof); //
167	void Print(Option_t *option="");
168
169	Float_t GetdEdx_pmt(Int_t ipmt) { return eDEDXpmt[ipmt]; } // 0-47 dEdx for each PMT for tracked events
170	//
171	ToFdEdx* GetToFdEdx(){return this;};
172	ClassDef(ToFdEdx,2);
173	};
174
175
176	/**
177	* \brief Class which contains the tracker related variables
178	*
179	* We can use the ToF standalone to find hitted paddles, calculate beta, etc..
180	* These results are then stored with the "trkseqno" = -1.
181	* If we use the track from the tracker, then the penetration points in the
182	* scintillators are calculated, which defines the hitted paddles. For these paddles
183	* we calculate then all the output.
184	* Note: The artificial ADC values are stored as dEdx in the output, the dEdx will be
185	* by definition = 1. However, the artificial TDC values are just used internally
186	* and not stored in the output. But one can see in both cases which PMT has artificial
187	* values using "adcflag" and "tdcflag".
188	* Look in the ToFLevel2Ex.cxx example in the repository how to read the tracker related
189	* variables.
190	*/
191	class ToFTrkVar : public TObject {
192
193	private:
194
195	public:
196	//
197	Int_t trkseqno; ///< tracker sequ. number: -1=ToF standalone, 0=first Tracker track, ...
198	//
199	Int_t npmttdc; ///<number of the TDC measurements used to evaluate beta
200	TArrayI pmttdc; ///<contains the ID (0..47) for the PMT used to evaluate beta
201	TArrayI tdcflag; ///<flag for artificial TDC, "0" if normal TDC value
202
203	/**
204	* \brief beta, 12 measurements for the 12 combinations, beta[13] is modified weighted mean
205	*
206	* The 12 measurements are S11-S31, S11-S32, S12-S31, S12-S32, and then analogue for
207	* S2-S3 and S1-S2.
208	* The calculation of beta[13] is now modified:
209	* We check the individual weights for artificial TDC values, then calculate
210	* am mean beta for the first time. In a second step we loop again through
211	* the single measurements, checking for the residual from the mean
212	* The cut on the residual reject measurements > "x"-sigma. A chi2 value is
213	* calculated, furthermore a "quality" value by adding the weights which
214	* are finally used. If all measurements are taken, "quality" will be = 505.
215	* A chi2 cut around 3-4 and a quality-cut > 400 is needed for clean beta
216	* The Level2 beta[12] which is derived in the fortran routines uses: 10.,200.,20.
217	* This is not a very high quality measurement. One can re-calculate a new beta[13]
218	* using the L2-method "CalcBeta"
219	*/
220	Float_t beta[13];
221	//
222	Int_t npmtadc; ///<number of the ADC measurements used for dEdx evaluation
223	TArrayI pmtadc; ///<contains the ID (0..47) for the PMT used to evaluate dEdx
224	TArrayI adcflag; ///<flag for artificial ADCs, "0" if normal ADC value
225	TArrayF dedx; ///<energy loss for this PMT in mip
226	//
227	Float_t xtofpos[3]; ///<x-measurement using the TDC values and the calibration from S12, S21, S32
228	Float_t ytofpos[3]; ///<x-measurement using the TDC values and the calibration from S11, S22, S31
229	//
230	Float_t xtr_tof[6]; ///<x-measurement in the ToF layers from tracker
231	Float_t ytr_tof[6]; ///<x-measurement in the ToF layers from tracker
232	//
233	ToFTrkVar();
234	ToFTrkVar(const ToFTrkVar&);
235
236	ToFTrkVar* GetToFTrkVar(){return this;};
237	void Clear(Option_t *t="");
238
239	ClassDef(ToFTrkVar,1);
240	//
241	};
242
243	/**
244	* \brief Class to describe ToF LEVEL2 data
245	*
246	*/
247
248	class ToFLevel2 : public TObject {
249	private:
250
251	public:
252	//
253	TClonesArray *PMT; ///<class needed to store PMT hit informations
254	TClonesArray *ToFTrk; ///<track related variable class
255	Int_t tof_j_flag[6]; ///<number of hitted paddle(s) for each ToF layer: flag = flag + 2**(paddlenumber-1)
256	//
257	Int_t unpackError;///< zero if no error presente
258	Int_t default_calib; ///< one if the default calibration has been used to process the data, zero otherwise
259	//
260	Float_t GetdEdx(Int_t notrack, Int_t plane, Int_t adcfl); // gf Apr 07
261
262	Float_t CalcBeta(Int_t notrack, Float_t resmax, Float_t qualitycut, Float_t chi2cut); // wm feb 08
263
264	//
265	// Float_t CalcBeta(Int_t notrack, Float_t resmax, Float_t chi2cut, Float_t qualitycut); // wm feb 08
266	//
267	// methods to make life simplier during the analysis, returns a pointer to the ToFTrkVar class containing track related variables
268	//
269	Int_t ntrk(){return ToFTrk->GetEntries();};
270	Int_t npmt(){return PMT->GetEntries();};
271
272	//
273	void GetLevel2Struct(cToFLevel2 *) const;
274	//
275	ToFTrkVar *GetToFTrkVar(Int_t notrack);
276	ToFPMT *GetToFPMT(Int_t nohit);
277	Int_t GetPMTid(Int_t gg, Int_t hh);
278	TString GetPMTName(Int_t ind);
279
280	Int_t GetPlaneIndex(Int_t pmt_id);
281	void GetMatrix(Int_t notrack, Float_t adc[4][12], Float_t tdc[4][12]);
282	void GetPMTIndex(Int_t pmt_id, Int_t &gg, Int_t &hh);
283
284	// gf Apr 07
285	void GetdEdxPaddle(Int_t notrack, Int_t paddleid, Int_t adcfl, Float_t &PadEdx, Int_t &SatWarning); // gf Apr 07
286	TString GetPMTName(Int_t ind, Int_t &iplane, Int_t &ipaddle,Int_t &ipmt);
287	Int_t GetPaddleIdOfTrack(Float_t xtr, Float_t ytr, Int_t plane); // gf Apr 07
288	Int_t GetPaddleIdOfTrack(Float_t xtr, Float_t ytr, Int_t plane, Float_t margin); // wm jun 2008
289	void GetPMTPaddle(Int_t pmt_id, Int_t &plane, Int_t &paddle); // gf Apr 07
290	void GetPaddlePMT(Int_t paddle, Int_t &pmtleft, Int_t &pmtright); // gf Apr 07
291	void GetPaddleGeometry(Int_t plane, Int_t paddle, Float_t &xleft, Float_t &xright, Float_t &yleft, Float_t &yright); // gf Apr 07
292	Int_t GetPaddleid(Int_t plane, Int_t paddle);
293	void GetPaddlePlane(Int_t padid, Int_t &plane, Int_t &paddle);
294	Int_t GetNPaddle(Int_t plane);
295	//
296	//
297	//
298	Int_t Process(TrkLevel2 trk, TrigLevel2 trg, GL_RUN run, OrbitalInfo orb, Bool_t force); // Emiliano
299
300	//
301	// constructor
302	//
303	ToFLevel2();
304	~ToFLevel2(){Delete();}; //ELENA
305	void Delete(Option_t *t=""); //ELENA
306	void Set();//ELENA
307	//
308	//
309	ToFLevel2* GetToFLevel2(){return this;};
310
311	/**
312	* Method to get the z-position of the 6 TOF layers from the plane ID
313	* @param plane_id Plane ID (11 12 21 22 31 32)
314	*/
315	Float_t GetZTOF(Int_t plane_id){
316	switch(plane_id){
317	case 11: return ZTOF11;
318	case 12: return ZTOF12;
319	case 21: return ZTOF21;
320	case 22: return ZTOF22;
321	case 31: return ZTOF31;
322	case 32: return ZTOF32;
323	default: return 0.;
324	};
325	};
326
327	//
328	// Paddles position
329	//
330	/*
331	S11 8 paddles 33.0 x 5.1 cm
332	S12 6 paddles 40.8 x 5.5 cm
333	S21 2 paddles 18.0 x 7.5 cm
334	S22 2 paddles 15.0 x 9.0 cm
335	S31 3 paddles 15.0 x 6.0 cm
336	S32 3 paddles 18.0 x 5.0 cm
337	*/
338
339	Int_t GetToFPlaneID(Int_t ip);
340	Int_t GetToFPlaneIndex(Int_t plane_id);
341	Bool_t HitPaddle(Int_t ,Int_t);
342	Int_t GetNHitPaddles(Int_t plane);
343	void Clear(Option_t *t="");
344	//
345	ClassDef(ToFLevel2,4);
346	};
347
348	#endif
349