/[PAMELA software]/DarthVader/ToFLevel2/src/ToFLevel2.cpp
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revision 1.8 by mocchiut, Thu Nov 9 17:05:48 2006 UTC revision 1.41 by mocchiut, Tue Oct 14 14:07:36 2014 UTC
# Line 1  Line 1 
1  #include <TObject.h>  /**
2     * \file ToFLevel2.cpp
3     * \author Gianfranca DeRosa, Wolfgang Menn
4     *
5     * WM dec 2008: Description of "GetdEdx" changed
6     * WM dec 2008: "GetdEdxPaddle" modified: Now includes saturation limit
7     *              PMTs higher than the saturation limit are not used for dEdx
8     * WM apr 2009: bug found by Nicola in method "GetPaddlePlane"
9     */
10    
11  #include <ToFLevel2.h>  #include <ToFLevel2.h>
 #include <iostream>  
12  using namespace std;  using namespace std;
13  ClassImp(ToFPMT);  ClassImp(ToFPMT);
14    ClassImp(ToFdEdx);
15    ClassImp(ToFGeom);
16  ClassImp(ToFTrkVar);  ClassImp(ToFTrkVar);
17  ClassImp(ToFLevel2);  ClassImp(ToFLevel2);
18    
# Line 10  ToFPMT::ToFPMT(){ Line 20  ToFPMT::ToFPMT(){
20    pmt_id = 0;    pmt_id = 0;
21    adc = 0.;    adc = 0.;
22    tdc_tw = 0.;    tdc_tw = 0.;
23      tdc = 0.;
24      l0flag_adc = 0.;
25      l0flag_tdc = 0.;
26  }  }
27    
28  ToFPMT::ToFPMT(const ToFPMT &t){  ToFPMT::ToFPMT(const ToFPMT &t){
29    pmt_id = t.pmt_id;    pmt_id = t.pmt_id;
30    adc = t.adc;    adc = t.adc;
31    tdc_tw = t.tdc_tw;    tdc_tw = t.tdc_tw;
32      tdc = t.tdc;
33  }  }
34    
35  void ToFPMT::Clear(){  void ToFPMT::Clear(Option_t *t){
36    pmt_id = 0;    pmt_id = 0;
37    adc = 0.;    adc = 0.;
38    tdc_tw = 0.;    tdc_tw = 0.;
39      tdc = 0.;
40  }  }
41    
42    
# Line 32  ToFTrkVar::ToFTrkVar() { Line 47  ToFTrkVar::ToFTrkVar() {
47    npmtadc = 0;    npmtadc = 0;
48    pmttdc = TArrayI(48);    pmttdc = TArrayI(48);
49    pmtadc = TArrayI(48);    pmtadc = TArrayI(48);
50      tdcflag = TArrayI(48); // gf: 30 Nov 2006
51      adcflag = TArrayI(48); // gf: 30 Nov 2006
52    dedx = TArrayF(48);    dedx = TArrayF(48);
53    //    //
54    //    //
55    memset(beta,  0, 13*sizeof(Float_t));    memset(beta,  0, 13*sizeof(Float_t));
56    memset(xtofpos,  0, 3*sizeof(Float_t));    memset(xtofpos,  0, 3*sizeof(Float_t));
57    memset(ytofpos,  0, 3*sizeof(Float_t));    memset(ytofpos,  0, 3*sizeof(Float_t));
58      memset(xtr_tof,  0, 6*sizeof(Float_t));
59      memset(ytr_tof,  0, 6*sizeof(Float_t));
60    //    //
61  };  };
62    
63  void ToFTrkVar::Clear() {  void ToFTrkVar::Clear(Option_t *t) {
64    trkseqno = 0;    trkseqno = 0;
65    npmttdc = 0;    npmttdc = 0;
66    npmtadc = 0;    npmtadc = 0;
67    pmttdc.Reset();    pmttdc.Reset();
68    pmtadc.Reset();    pmtadc.Reset();
69      tdcflag.Reset(); // gf: 30 Nov 2006
70      adcflag.Reset(); // gf: 30 Nov 2006
71    dedx.Reset();    dedx.Reset();
72    //    //
73    memset(beta,  0, 13*sizeof(Float_t));    memset(beta,  0, 13*sizeof(Float_t));
74    memset(xtofpos,  0, 3*sizeof(Float_t));    memset(xtofpos,  0, 3*sizeof(Float_t));
75    memset(ytofpos,  0, 3*sizeof(Float_t));    memset(ytofpos,  0, 3*sizeof(Float_t));
76      memset(xtr_tof,  0, 6*sizeof(Float_t));
77      memset(ytr_tof,  0, 6*sizeof(Float_t));
78    //    //
79  };  };
80    
# Line 63  ToFTrkVar::ToFTrkVar(const ToFTrkVar &t) Line 86  ToFTrkVar::ToFTrkVar(const ToFTrkVar &t)
86    npmtadc = t.npmtadc;    npmtadc = t.npmtadc;
87    (t.pmttdc).Copy(pmttdc);    (t.pmttdc).Copy(pmttdc);
88    (t.pmtadc).Copy(pmtadc);    (t.pmtadc).Copy(pmtadc);
89      (t.tdcflag).Copy(tdcflag); // gf: 30 Nov 2006
90      (t.adcflag).Copy(adcflag); // gf: 30 Nov 2006
91    (t.dedx).Copy(dedx);    (t.dedx).Copy(dedx);
92    //    //
93    memcpy(beta,t.beta,sizeof(beta));    memcpy(beta,t.beta,sizeof(beta));
94    memcpy(xtofpos,t.xtofpos,sizeof(xtofpos));    memcpy(xtofpos,t.xtofpos,sizeof(xtofpos));
95    memcpy(ytofpos,t.ytofpos,sizeof(ytofpos));    memcpy(ytofpos,t.ytofpos,sizeof(ytofpos));
96      memcpy(xtr_tof,t.xtr_tof,sizeof(xtr_tof));
97      memcpy(ytr_tof,t.ytr_tof,sizeof(ytr_tof));
98    //    //
99  };  };
100    
101  ToFLevel2::ToFLevel2() {      ToFLevel2::ToFLevel2() {    
102    //    //
103    PMT = new TClonesArray("ToFPMT",12);  //  PMT = new TClonesArray("ToFPMT",12); //ELENA
104    ToFTrk = new TClonesArray("ToFTrkVar",2);  //  ToFTrk = new TClonesArray("ToFTrkVar",2); //ELENA
105      PMT = 0; //ELENA
106      ToFTrk = 0; //ELENA
107    //    //
108    this->Clear();    this->Clear();
109    //    //
110  };  };
111    
112  void ToFLevel2::Clear(){  void ToFLevel2::Set(){//ELENA
113        if(!PMT)PMT = new TClonesArray("ToFPMT",12); //ELENA
114        if(!ToFTrk)ToFTrk = new TClonesArray("ToFTrkVar",2); //ELENA
115    }//ELENA
116    
117    void ToFLevel2::Clear(Option_t *t){
118    //    //
119    ToFTrk->Clear();    if(ToFTrk)ToFTrk->Delete(); //ELENA
120    PMT->Clear();    if(PMT)PMT->Delete(); //ELENA
121    memset(tof_j_flag, 0, 6*sizeof(Int_t));    memset(tof_j_flag, 0, 6*sizeof(Int_t));
122    unpackError = 0;    unpackError = 0;
123      unpackWarning = 0;
124    //    //
125  };  };
126    
127    void ToFLevel2::Delete(Option_t *t){ //ELENA
128      //
129      if(ToFTrk){
130          ToFTrk->Delete(); //ELENA
131          delete ToFTrk;  //ELENA
132      }
133      if(PMT){
134          PMT->Delete(); //ELENA
135          delete PMT; //ELENA
136      } //ELENA
137      //
138    }; //ELENA
139    
140  ToFTrkVar *ToFLevel2::GetToFTrkVar(Int_t itrk){  ToFTrkVar *ToFLevel2::GetToFTrkVar(Int_t itrk){
141    //        //    
142    if(itrk >= ntrk()){    if(itrk >= ntrk()){
# Line 97  ToFTrkVar *ToFLevel2::GetToFTrkVar(Int_t Line 145  ToFTrkVar *ToFLevel2::GetToFTrkVar(Int_t
145      return(NULL);      return(NULL);
146    }      }  
147    //    //
148      if(!ToFTrk)return 0; //ELENA
149    TClonesArray &t = *(ToFTrk);    TClonesArray &t = *(ToFTrk);
150    ToFTrkVar *toftrack = (ToFTrkVar*)t[itrk];    ToFTrkVar *toftrack = (ToFTrkVar*)t[itrk];
151    return toftrack;    return toftrack;
# Line 110  ToFPMT *ToFLevel2::GetToFPMT(Int_t ihit) Line 159  ToFPMT *ToFLevel2::GetToFPMT(Int_t ihit)
159      return(NULL);      return(NULL);
160    }      }  
161    //    //
162      if(!PMT)return 0; //ELENA
163    TClonesArray &t = *(PMT);    TClonesArray &t = *(PMT);
164    ToFPMT *tofpmt = (ToFPMT*)t[ihit];    ToFPMT *tofpmt = (ToFPMT*)t[ihit];
165    return tofpmt;    return tofpmt;
# Line 120  ToFPMT *ToFLevel2::GetToFPMT(Int_t ihit) Line 170  ToFPMT *ToFLevel2::GetToFPMT(Int_t ihit)
170  //--------------------------------------  //--------------------------------------
171  /**  /**
172   * Method to get the plane ID (11 12 21 22 31 32) from the plane index (0 1 2 3 4 5)   * Method to get the plane ID (11 12 21 22 31 32) from the plane index (0 1 2 3 4 5)
173     * @param Plane index (0,1,2,3,4,5).
174   */   */
175    Int_t  ToFLevel2::GetToFPlaneID(Int_t ip){    Int_t  ToFLevel2::GetToFPlaneID(Int_t ip){
176        if(ip>=0 && ip<6)return 10*((int)(ip/2+1.1))+(ip%2)+1;        if(ip>=0 && ip<6)return 10*((int)(ip/2+1.1))+(ip%2)+1;
# Line 127  ToFPMT *ToFLevel2::GetToFPMT(Int_t ihit) Line 178  ToFPMT *ToFLevel2::GetToFPMT(Int_t ihit)
178    };    };
179  /**  /**
180   * Method to get the plane index (0 1 2 3 4 5) from the plane ID (11 12 21 22 31 32)   * Method to get the plane index (0 1 2 3 4 5) from the plane ID (11 12 21 22 31 32)
181     * @param plane Plane ID (11, 12, 21, 22, 31, 32)
182   */   */
183    Int_t  ToFLevel2::GetToFPlaneIndex(Int_t plane_id){    Int_t  ToFLevel2::GetToFPlaneIndex(Int_t plane_id){
184        if(        if(
# Line 140  ToFPMT *ToFLevel2::GetToFPMT(Int_t ihit) Line 192  ToFPMT *ToFLevel2::GetToFPMT(Int_t ihit)
192        else return -1;        else return -1;
193    };    };
194  /**  /**
195   * Method to know if a given ToF paddle was hit, that is there is a TDC signal from both PMTs   * Method to know if a given ToF paddle was hit, that is there is a TDC signal
196     * from both PMTs. The method uses the "tof_j_flag" variable.
197   * @param plane Plane ID (11, 12, 21, 22, 31, 32) or Plane index (0,1,2,3,4,5).   * @param plane Plane ID (11, 12, 21, 22, 31, 32) or Plane index (0,1,2,3,4,5).
198   * @param paddle_id Paddle ID.   * @param paddle_id Paddle ID.
199   * @return 1 if the paddle was hit.   * @return 1 if the paddle was hit.
# Line 171  Int_t ToFLevel2::GetNHitPaddles(Int_t pl Line 224  Int_t ToFLevel2::GetNHitPaddles(Int_t pl
224      return npad;      return npad;
225  };  };
226    
227    /**
228     * Method to get the number of hit paddles on a ToF plane.
229     * @param plane Plane ID (11, 12, 21, 22, 31, 32) or Plane index (0,1,2,3,4,5).
230     */
231    Int_t ToFLevel2::GetTrueNHitPaddles(Int_t plane){
232        Int_t npad=0;
233        TClonesArray* Pmt = this->PMT;
234        int paddle[24];
235        memset(paddle,0, 24*sizeof(int));
236        for(int i=0; i<Pmt->GetEntries(); i++) {  //loop per vedere quale TOF è colpito
237          ToFPMT* pmthit = (ToFPMT*)Pmt->At(i);
238          int pplane = -1;
239          int ppaddle = -1;
240          GetPMTPaddle(pmthit->pmt_id,pplane,ppaddle);
241          if ( pplane == plane ) paddle[ppaddle]++;
242        }
243        for(int i=0;i<24;i++) if ( paddle[i]>0 ) npad++;
244    
245  Float_t ToFLevel2::GetdEdx(Int_t notrack, Int_t plane){      return npad;
246    };
247    
248    //wm Nov 08
249    //gf Apr 07
250    /**
251     * Method to get the mean dEdx from a ToF layer - ATTENTION:
252     * It will sum up the dEdx of all the paddles, but since by definition
253     * only the paddle hitted by the track gets a dEdx value and the other
254     * paddles are set to zero, the output is just the dEdx of the hitted
255     * paddle in each layer!
256     * The "adcfl" option is not very useful (an artificial dEdx is per
257     * definition= 1 mip and not a real measurement), anyway left in the code
258     * @param notrack Track Number
259     * @param plane Plane index (0,1,2,3,4,5)
260     * @param adcflag in the plane (100<-> independent of the adcflag; !=0&&!=100 <-> at least one PMT with adcflag!=0; )
261     */
262    Float_t ToFLevel2::GetdEdx(ToFTrkVar *trk, Int_t plane, Int_t adcfl){
263      //  printf("fiffi\n");
264    Float_t dedx = 0.;    Float_t dedx = 0.;
265    Int_t ip = 0;    Float_t PadEdx =0.;
266    Int_t pmt_id = 0;    Int_t SatWarning;
267    Int_t pl = 0;    Int_t pad=-1;
268    if ( plane >= 6 ){    //
269      ip = GetToFPlaneIndex(plane);    if(!trk) return 0; //ELENA
270      //
271      if ( trk->trkseqno == -1 ){ //standalone, only paddles along the track, or about...
272        //    printf("ciccio\n");
273        Float_t xleft=0;
274        Float_t xright=0;
275        Float_t yleft=0;
276        Float_t yright=0;
277        Float_t xtof_temp[6]={100.,100.,100.,100.,100.,100.};
278        Float_t ytof_temp[6]={100.,100.,100.,100.,100.,100.};
279        ToFTrkVar *t_tof = trk;
280        
281        xtof_temp[0]=t_tof->xtofpos[0];
282        ytof_temp[0]=t_tof->ytofpos[0];
283        xtof_temp[1]=t_tof->xtofpos[0];
284        ytof_temp[1]=t_tof->ytofpos[0];
285    
286        xtof_temp[2]=t_tof->xtofpos[1];
287        ytof_temp[2]=t_tof->ytofpos[1];
288        xtof_temp[3]=t_tof->xtofpos[1];
289        ytof_temp[3]=t_tof->ytofpos[1];
290    
291        xtof_temp[4]=t_tof->xtofpos[2];
292        ytof_temp[4]=t_tof->ytofpos[2];
293        xtof_temp[5]=t_tof->xtofpos[2];
294        ytof_temp[5]=t_tof->ytofpos[2];
295    
296        if(t_tof->xtofpos[0]<100. && t_tof->ytofpos[0]<100.){
297          xtof_temp[1]=t_tof->xtofpos[0];
298          ytof_temp[0]=t_tof->ytofpos[0];
299        }else if(t_tof->xtofpos[0]>=100. && t_tof->ytofpos[0]<100.){
300          ytof_temp[0]=t_tof->ytofpos[0];
301          this->GetPaddleGeometry(0,(Int_t)log2(this->tof_j_flag[0]),xleft, xright, yleft, yright);
302          xtof_temp[1]=xleft+2.55;
303        }else if(t_tof->ytofpos[0]>=100. && t_tof->xtofpos[0]<100.){
304          xtof_temp[1]=t_tof->xtofpos[0];
305          this->GetPaddleGeometry(1,(Int_t)log2(this->tof_j_flag[1]),xleft, xright, yleft, yright);
306          ytof_temp[0]=yleft+2.75;
307        }
308        
309        if(t_tof->xtofpos[1]<100. && t_tof->ytofpos[1]<100.){
310          xtof_temp[2]=t_tof->xtofpos[1];
311          ytof_temp[3]=t_tof->ytofpos[1];
312        }else if(t_tof->xtofpos[1]>=100. && t_tof->ytofpos[1]<100.){
313          ytof_temp[3]=t_tof->ytofpos[1];
314          this->GetPaddleGeometry(3,(Int_t)log2(this->tof_j_flag[3]),xleft, xright, yleft, yright);
315          xtof_temp[2]=xleft+4.5;
316        }else if(t_tof->ytofpos[1]>=100. && t_tof->xtofpos[1]<100.){
317          xtof_temp[2]=t_tof->xtofpos[1];
318          this->GetPaddleGeometry(2,(Int_t)log2(this->tof_j_flag[2]),xleft, xright, yleft, yright);
319          ytof_temp[3]=yleft+3.75;
320        }
321        
322        if(t_tof->xtofpos[2]<100. && t_tof->ytofpos[2]<100.){
323          xtof_temp[5]=t_tof->xtofpos[2];
324          ytof_temp[4]=t_tof->ytofpos[2];
325        }else if(t_tof->xtofpos[2]>=100. && t_tof->ytofpos[2]<100.){
326          ytof_temp[4]=t_tof->ytofpos[2];
327          this->GetPaddleGeometry(4,(Int_t)log2(this->tof_j_flag[4]),xleft, xright, yleft, yright);
328          xtof_temp[5]=xleft+3;
329        }else if(t_tof->ytofpos[2]>=100. && t_tof->xtofpos[2]<100.){
330          xtof_temp[5]=t_tof->xtofpos[2];
331          this->GetPaddleGeometry(5,(Int_t)log2(this->tof_j_flag[5]),xleft, xright, yleft, yright);
332          ytof_temp[4]=yleft+2.5;
333        }
334    
335        if ( (xtof_temp[0])> 17.85 && fabs(xtof_temp[0])<17.85+4. ) xtof_temp[0] =17.84;
336        if ( (xtof_temp[1])> 17.85 && fabs(xtof_temp[1])<17.85+4. ) xtof_temp[1] =17.84;
337        if ( (ytof_temp[0])> 13.75 && fabs(ytof_temp[0])<13.75+4. ) ytof_temp[0] =13.74;
338        if ( (ytof_temp[1])> 13.75 && fabs(ytof_temp[1])<13.75+4. ) ytof_temp[1] =13.74;
339        if ( (xtof_temp[0])< -17.85 && fabs(xtof_temp[0])>-(17.85+4.) ) xtof_temp[0] =-17.84;
340        if ( (xtof_temp[1])< -17.85 && fabs(xtof_temp[1])>-(17.85+4.) ) xtof_temp[1] =-17.84;
341        if ( (ytof_temp[0])< -13.75 && fabs(ytof_temp[0])>-(13.75+4.) ) ytof_temp[0] =-13.74;
342        if ( (ytof_temp[1])< -13.75 && fabs(ytof_temp[1])>-(13.75+4.) ) ytof_temp[1] =-13.74;
343    
344        if ( (xtof_temp[2])> 4.5 && (xtof_temp[2])<4.5+4. ) xtof_temp[2] =4.4;
345        if ( (xtof_temp[3])> 4.45 && (xtof_temp[3])<4.5+4. ) xtof_temp[3] =4.4;
346        if ( (ytof_temp[2])> 3.75 && (ytof_temp[2])<3.75+4. ) ytof_temp[2] =3.74;
347        if ( (ytof_temp[3])> 3.75 && (ytof_temp[3])<3.75+4. ) ytof_temp[3] =3.74;
348        if ( (xtof_temp[2])< -4.5 && (xtof_temp[2])>-(4.5+4.) ) xtof_temp[2] =-4.4;
349        if ( (xtof_temp[3])< -4.45 && (xtof_temp[3])>-(4.5+4.) ) xtof_temp[3] =-4.4;
350        if ( (ytof_temp[2])< -3.75 && (ytof_temp[2])>-(3.75+4.) ) ytof_temp[2] =-3.74;
351        if ( (ytof_temp[3])< -3.75 && (ytof_temp[3])>-(3.75+4.) ) ytof_temp[3] =-3.74;
352    
353        if ( (xtof_temp[4])> 6. && (xtof_temp[4])<6.+4. ) xtof_temp[2] =5.9;
354        if ( (xtof_temp[5])> 6. && (xtof_temp[5])<6.+4. ) xtof_temp[3] =5.9;
355        if ( (ytof_temp[4])> 5. && (ytof_temp[4])<5.+4. ) ytof_temp[2] =4.9;
356        if ( (ytof_temp[5])> 5. && (ytof_temp[5])<5.+4. ) ytof_temp[3] =4.9;
357        if ( (xtof_temp[4])< -6. && (xtof_temp[4])>-(6.+4.) ) xtof_temp[2] =-5.9;
358        if ( (xtof_temp[5])< -6. && (xtof_temp[5])>-(6.+4.) ) xtof_temp[3] =-5.9;
359        if ( (ytof_temp[4])< -5. && (ytof_temp[4])>-(5.+4.) ) ytof_temp[2] =-4.9;
360        if ( (ytof_temp[5])< -5. && (ytof_temp[5])>-(5.+4.) ) ytof_temp[3] =-4.9;
361    
362    
363        for (Int_t ii=0; ii<GetNPaddle(plane); ii++){
364          Int_t paddleid=ii;
365          pad = GetPaddleid(plane,paddleid);
366          Int_t IpaddleT=-1;
367          IpaddleT=this->GetPaddleIdOfTrack(xtof_temp[plane],ytof_temp[plane], plane,0.0);
368    //      printf("SSS %i %i %f %f  %f %f \n",IpaddleT,paddleid,xtof_temp[plane],ytof_temp[plane],t_tof->xtofpos[plane],t_tof->ytofpos[plane]);
369          //      if ( IpaddleT == paddleid || IpaddleT-1 == paddleid || IpaddleT+1 == paddleid ){
370          if ( IpaddleT == paddleid || GetTrueNHitPaddles(plane) == 1 ){
371            //IpaddleT-1 == paddleid || IpaddleT+1 == paddleid ){
372            GetdEdxPaddle(trk, pad, adcfl, PadEdx, SatWarning);
373            dedx += PadEdx;
374          }
375        };
376    } else {    } else {
377      ip = plane;      for (Int_t ii=0; ii<GetNPaddle(plane); ii++){
378    };        Int_t paddleid=ii;
379          pad = GetPaddleid(plane,paddleid);
380          GetdEdxPaddle(trk, pad, adcfl, PadEdx, SatWarning);
381          dedx += PadEdx;
382    //      printf("TTT %i %i %f\n",paddleid,plane,PadEdx);
383        };
384      }
385      //
386      return(dedx);
387    };
388    
389    
390    //wm Nov 08
391    //gf Apr 07
392    /**
393     * Method to get the mean dEdx from a ToF layer - ATTENTION:
394     * It will sum up the dEdx of all the paddles, but since by definition
395     * only the paddle hitted by the track gets a dEdx value and the other
396     * paddles are set to zero, the output is just the dEdx of the hitted
397     * paddle in each layer!
398     * The "adcfl" option is not very useful (an artificial dEdx is per
399     * definition= 1 mip and not a real measurement), anyway left in the code
400     * @param notrack Track Number
401     * @param plane Plane index (0,1,2,3,4,5)
402     * @param adcflag in the plane (100<-> independent of the adcflag; !=0&&!=100 <-> at least one PMT with adcflag!=0; )
403     */
404    Float_t ToFLevel2::GetdEdx(Int_t notrack, Int_t plane, Int_t adcfl){
405      //  printf("fiffi\n");
406      Float_t dedx = 0.;
407      Float_t PadEdx =0.;
408      Int_t SatWarning;
409      Int_t pad=-1;
410    //    //
411    ToFTrkVar *trk = GetToFTrkVar(notrack);    ToFTrkVar *trk = GetToFTrkVar(notrack);
412      if(!trk) return 0; //ELENA
413    //    //
414    for (Int_t i=0; i<trk->npmtadc; i++){    if ( trk->trkseqno == -1 ){ //standalone, only paddles along the track, or about...
415      //      //    printf("ciccio\n");
416      pmt_id = (trk->pmtadc).At(i);      Float_t xleft=0;
417      //      Float_t xright=0;
418      pl = GetPlaneIndex(pmt_id);      Float_t yleft=0;
419      //      Float_t yright=0;
420      if ( pl == ip ) dedx += (trk->dedx).At(i);        Float_t xtof_temp[6]={100.,100.,100.,100.,100.,100.};
421      //      Float_t ytof_temp[6]={100.,100.,100.,100.,100.,100.};
422    };      ToFTrkVar *t_tof = trk;
423        
424        xtof_temp[0]=t_tof->xtofpos[0];
425        ytof_temp[0]=t_tof->ytofpos[0];
426        xtof_temp[1]=t_tof->xtofpos[0];
427        ytof_temp[1]=t_tof->ytofpos[0];
428    
429        xtof_temp[2]=t_tof->xtofpos[1];
430        ytof_temp[2]=t_tof->ytofpos[1];
431        xtof_temp[3]=t_tof->xtofpos[1];
432        ytof_temp[3]=t_tof->ytofpos[1];
433    
434        xtof_temp[4]=t_tof->xtofpos[2];
435        ytof_temp[4]=t_tof->ytofpos[2];
436        xtof_temp[5]=t_tof->xtofpos[2];
437        ytof_temp[5]=t_tof->ytofpos[2];
438    
439        if(t_tof->xtofpos[0]<100. && t_tof->ytofpos[0]<100.){
440          xtof_temp[1]=t_tof->xtofpos[0];
441          ytof_temp[0]=t_tof->ytofpos[0];
442        }else if(t_tof->xtofpos[0]>=100. && t_tof->ytofpos[0]<100.){
443          ytof_temp[0]=t_tof->ytofpos[0];
444          this->GetPaddleGeometry(0,(Int_t)log2(this->tof_j_flag[0]),xleft, xright, yleft, yright);
445          xtof_temp[1]=xleft+2.55;
446        }else if(t_tof->ytofpos[0]>=100. && t_tof->xtofpos[0]<100.){
447          xtof_temp[1]=t_tof->xtofpos[0];
448          this->GetPaddleGeometry(1,(Int_t)log2(this->tof_j_flag[1]),xleft, xright, yleft, yright);
449          ytof_temp[0]=yleft+2.75;
450        }
451        
452        if(t_tof->xtofpos[1]<100. && t_tof->ytofpos[1]<100.){
453          xtof_temp[2]=t_tof->xtofpos[1];
454          ytof_temp[3]=t_tof->ytofpos[1];
455        }else if(t_tof->xtofpos[1]>=100. && t_tof->ytofpos[1]<100.){
456          ytof_temp[3]=t_tof->ytofpos[1];
457          this->GetPaddleGeometry(3,(Int_t)log2(this->tof_j_flag[3]),xleft, xright, yleft, yright);
458          xtof_temp[2]=xleft+4.5;
459        }else if(t_tof->ytofpos[1]>=100. && t_tof->xtofpos[1]<100.){
460          xtof_temp[2]=t_tof->xtofpos[1];
461          this->GetPaddleGeometry(2,(Int_t)log2(this->tof_j_flag[2]),xleft, xright, yleft, yright);
462          ytof_temp[3]=yleft+3.75;
463        }
464        
465        if(t_tof->xtofpos[2]<100. && t_tof->ytofpos[2]<100.){
466          xtof_temp[5]=t_tof->xtofpos[2];
467          ytof_temp[4]=t_tof->ytofpos[2];
468        }else if(t_tof->xtofpos[2]>=100. && t_tof->ytofpos[2]<100.){
469          ytof_temp[4]=t_tof->ytofpos[2];
470          this->GetPaddleGeometry(4,(Int_t)log2(this->tof_j_flag[4]),xleft, xright, yleft, yright);
471          xtof_temp[5]=xleft+3;
472        }else if(t_tof->ytofpos[2]>=100. && t_tof->xtofpos[2]<100.){
473          xtof_temp[5]=t_tof->xtofpos[2];
474          this->GetPaddleGeometry(5,(Int_t)log2(this->tof_j_flag[5]),xleft, xright, yleft, yright);
475          ytof_temp[4]=yleft+2.5;
476        }
477    
478        if ( (xtof_temp[0])> 17.85 && fabs(xtof_temp[0])<17.85+4. ) xtof_temp[0] =17.84;
479        if ( (xtof_temp[1])> 17.85 && fabs(xtof_temp[1])<17.85+4. ) xtof_temp[1] =17.84;
480        if ( (ytof_temp[0])> 13.75 && fabs(ytof_temp[0])<13.75+4. ) ytof_temp[0] =13.74;
481        if ( (ytof_temp[1])> 13.75 && fabs(ytof_temp[1])<13.75+4. ) ytof_temp[1] =13.74;
482        if ( (xtof_temp[0])< -17.85 && fabs(xtof_temp[0])>-(17.85+4.) ) xtof_temp[0] =-17.84;
483        if ( (xtof_temp[1])< -17.85 && fabs(xtof_temp[1])>-(17.85+4.) ) xtof_temp[1] =-17.84;
484        if ( (ytof_temp[0])< -13.75 && fabs(ytof_temp[0])>-(13.75+4.) ) ytof_temp[0] =-13.74;
485        if ( (ytof_temp[1])< -13.75 && fabs(ytof_temp[1])>-(13.75+4.) ) ytof_temp[1] =-13.74;
486    
487        if ( (xtof_temp[2])> 4.5 && (xtof_temp[2])<4.5+4. ) xtof_temp[2] =4.4;
488        if ( (xtof_temp[3])> 4.45 && (xtof_temp[3])<4.5+4. ) xtof_temp[3] =4.4;
489        if ( (ytof_temp[2])> 3.75 && (ytof_temp[2])<3.75+4. ) ytof_temp[2] =3.74;
490        if ( (ytof_temp[3])> 3.75 && (ytof_temp[3])<3.75+4. ) ytof_temp[3] =3.74;
491        if ( (xtof_temp[2])< -4.5 && (xtof_temp[2])>-(4.5+4.) ) xtof_temp[2] =-4.4;
492        if ( (xtof_temp[3])< -4.45 && (xtof_temp[3])>-(4.5+4.) ) xtof_temp[3] =-4.4;
493        if ( (ytof_temp[2])< -3.75 && (ytof_temp[2])>-(3.75+4.) ) ytof_temp[2] =-3.74;
494        if ( (ytof_temp[3])< -3.75 && (ytof_temp[3])>-(3.75+4.) ) ytof_temp[3] =-3.74;
495    
496        if ( (xtof_temp[4])> 6. && (xtof_temp[4])<6.+4. ) xtof_temp[2] =5.9;
497        if ( (xtof_temp[5])> 6. && (xtof_temp[5])<6.+4. ) xtof_temp[3] =5.9;
498        if ( (ytof_temp[4])> 5. && (ytof_temp[4])<5.+4. ) ytof_temp[2] =4.9;
499        if ( (ytof_temp[5])> 5. && (ytof_temp[5])<5.+4. ) ytof_temp[3] =4.9;
500        if ( (xtof_temp[4])< -6. && (xtof_temp[4])>-(6.+4.) ) xtof_temp[2] =-5.9;
501        if ( (xtof_temp[5])< -6. && (xtof_temp[5])>-(6.+4.) ) xtof_temp[3] =-5.9;
502        if ( (ytof_temp[4])< -5. && (ytof_temp[4])>-(5.+4.) ) ytof_temp[2] =-4.9;
503        if ( (ytof_temp[5])< -5. && (ytof_temp[5])>-(5.+4.) ) ytof_temp[3] =-4.9;
504    
505    
506        for (Int_t ii=0; ii<GetNPaddle(plane); ii++){
507          Int_t paddleid=ii;
508          pad = GetPaddleid(plane,paddleid);
509          Int_t IpaddleT=-1;
510          IpaddleT=this->GetPaddleIdOfTrack(xtof_temp[plane],ytof_temp[plane], plane,0.0);
511    //      printf("SSS %i %i %f %f  %f %f \n",IpaddleT,paddleid,xtof_temp[plane],ytof_temp[plane],t_tof->xtofpos[plane],t_tof->ytofpos[plane]);
512          //      if ( IpaddleT == paddleid || IpaddleT-1 == paddleid || IpaddleT+1 == paddleid ){
513          if ( IpaddleT == paddleid || GetTrueNHitPaddles(plane) == 1 ){
514            //IpaddleT-1 == paddleid || IpaddleT+1 == paddleid ){
515            GetdEdxPaddle(notrack, pad, adcfl, PadEdx, SatWarning);
516            dedx += PadEdx;
517          }
518        };
519      } else {
520        for (Int_t ii=0; ii<GetNPaddle(plane); ii++){
521          Int_t paddleid=ii;
522          pad = GetPaddleid(plane,paddleid);
523          GetdEdxPaddle(notrack, pad, adcfl, PadEdx, SatWarning);
524          dedx += PadEdx;
525    //      printf("TTT %i %i %f\n",paddleid,plane,PadEdx);
526        };
527      }
528    //    //
529    return(dedx);    return(dedx);
530  };  };
531    
532    /**
533     * Method to fill the ADC_C 4x12 matrix with the dEdx values and the TDC 4x12 matrix
534     * with the time-walk corrected TDC values.
535     * @param notrack Track Number
536     * @param adc  ADC_C matrix with dEdx values
537     * @param tdc  TDC matrix
538     */
539  void ToFLevel2::GetMatrix(Int_t notrack, Float_t adc[4][12], Float_t tdc[4][12]){  void ToFLevel2::GetMatrix(Int_t notrack, Float_t adc[4][12], Float_t tdc[4][12]){
540    //    //
541    for (Int_t aa=0; aa<4;aa++){    for (Int_t aa=0; aa<4;aa++){
# Line 213  void ToFLevel2::GetMatrix(Int_t notrack, Line 550  void ToFLevel2::GetMatrix(Int_t notrack,
550    Int_t kk = 0;    Int_t kk = 0;
551    //    //
552    ToFTrkVar *trk = GetToFTrkVar(notrack);    ToFTrkVar *trk = GetToFTrkVar(notrack);
553      if(!trk)return; //ELENA
554    //    //
555    for (Int_t i=0; i<trk->npmtadc; i++){    for (Int_t i=0; i<trk->npmtadc; i++){
556      //      //
# Line 226  void ToFLevel2::GetMatrix(Int_t notrack, Line 564  void ToFLevel2::GetMatrix(Int_t notrack,
564    for (Int_t i=0; i<npmt(); i++){    for (Int_t i=0; i<npmt(); i++){
565      //      //
566      ToFPMT *pmt = GetToFPMT(i);      ToFPMT *pmt = GetToFPMT(i);
567        if(!pmt)break; //ELENA
568      //      //
569      GetPMTIndex(pmt->pmt_id,hh,kk);      GetPMTIndex(pmt->pmt_id,hh,kk);
570      //      //
# Line 237  void ToFLevel2::GetMatrix(Int_t notrack, Line 576  void ToFLevel2::GetMatrix(Int_t notrack,
576  };  };
577    
578    
579    /**
580     * Method to get the plane index (0 - 5) for the PMT_ID as input
581     * @param pmt_id  PMT_ID (0 - 47)
582     */
583  Int_t ToFLevel2::GetPlaneIndex(Int_t pmt_id){  Int_t ToFLevel2::GetPlaneIndex(Int_t pmt_id){
584    TString pmtname = GetPMTName(pmt_id);    TString pmtname = GetPMTName(pmt_id);
585    pmtname.Resize(3);    pmtname.Resize(3);
# Line 251  Int_t ToFLevel2::GetPlaneIndex(Int_t pmt Line 593  Int_t ToFLevel2::GetPlaneIndex(Int_t pmt
593  };  };
594    
595    
596    /**
597     * Method to get the PMT_ID if the index (4,12) is given. We have 4 channels on
598     * each of the 12 half-boards, this method decodes which PMT is cables to which
599     * channel.
600     * @param hh Channel
601     * @param kk HalfBoard
602     */
603  Int_t ToFLevel2::GetPMTid(Int_t hh, Int_t kk){  Int_t ToFLevel2::GetPMTid(Int_t hh, Int_t kk){
604    //    //
605    short tof[4][24] = {    short tof[4][24] = {
# Line 279  Int_t ToFLevel2::GetPMTid(Int_t hh, Int_ Line 628  Int_t ToFLevel2::GetPMTid(Int_t hh, Int_
628    return ind;    return ind;
629  };  };
630    
 TString ToFLevel2::GetPMTName(Int_t ind){  
     
   TString pmtname = " ";  
     
   TString photoS[48] = {  
     "S11_1A", "S11_1B", "S11_2A", "S11_2B", "S11_3A", "S11_3B", "S11_4A", "S11_4B",  
     "S11_5A", "S11_5B", "S11_6A", "S11_6B", "S11_7A", "S11_7B", "S11_8A", "S11_8B",  
     "S12_1A", "S12_1B", "S12_2A", "S12_2B", "S12_3A", "S12_3B", "S12_4A", "S12_4B", "S12_5A",  "S12_5B", "S12_6A", "S12_6B",  
     "S21_1A", "S21_1B", "S21_2A", "S21_2B",  
     "S22_1A", "S22_1B", "S22_2A", "S22_2B",  
     "S31_1A", "S31_1B", "S31_2A", "S31_2B", "S31_3A", "S31_3B",  
     "S32_1A", "S32_1B", "S32_2A", "S32_2B", "S32_3A", "S32_3B"  
   };  
     
   
   pmtname = photoS[ind].Data();  
   
   return pmtname;  
 };  
   
631    
632    /**
633     * Method to get the PMT index if the PMT ID is given. This method is the
634     * "reverse" of method "GetPMTid"
635     * @param ind  PMT_ID (0 - 47)
636     * @param hb   HalfBoard
637     * @param ch   Channel
638     */
639  void ToFLevel2::GetPMTIndex(Int_t ind, Int_t &hb, Int_t &ch){  void ToFLevel2::GetPMTIndex(Int_t ind, Int_t &hb, Int_t &ch){
640    //    //
641    short tof[4][24] = {    short tof[4][24] = {
# Line 326  void ToFLevel2::GetPMTIndex(Int_t ind, I Line 662  void ToFLevel2::GetPMTIndex(Int_t ind, I
662    return;    return;
663  };  };
664    
665    
666    
667    //  wm Nov 08 revision - saturation values included
668    /// gf Apr 07
669    /**
670     * Method to get the dEdx from a given ToF paddle.
671     * If two PMTs are good, the mean dEdx of both PMTs is taken, otherwise
672     * just the dEdx of the "good" PMT. If both PMTs are above saturation => dEdx=1000
673     * @param notrack Track Number
674     * @param Paddle index (0,1,...,23).
675     * @param adcflag in the paddle (100<-> independent of the adcflag; !=0&&!=100 <-> at least one PMT with adcflag!=0; )
676     * @param PadEdx dEdx from a given ToF paddle
677     * @param SatWarning 1 if the PMT ios near saturation region (adcraw ~3000)
678     */
679    void ToFLevel2::GetdEdxPaddle(Int_t notrack, Int_t paddleid, Int_t adcfl, Float_t &PadEdx, Int_t &SatWarning){
680    
681      /*
682        Float_t  PMTsat[48] = {
683        3162.14, 3165.48, 3153.85, 3085.73, 3089.65, 3107.64, 3097.52, 3078.37,
684        3130.05, 3087.07, 3112.22, 3102.92, 3080.58, 3092.55, 3087.94, 3125.03,
685        3094.09, 3143.16, 3125.51, 3181.27, 3092.09, 3124.98, 3069.3, 3095.53,
686        3097.11, 3133.53, 3114.73, 3113.01, 3091.19, 3097.99, 3033.84, 3134.98,
687        3081.37, 3111.04, 3066.77, 3108.17, 3133, 3111.06, 3052.52, 3140.66,
688        3106.33, 3094.85, 3150.85, 3118.8, 3096.24, 3118.47,3111.36, 3117.11 } ;
689      */
690    
691      // new values from Napoli dec 2008
692      Float_t  PMTsat[48] = {
693        3176.35,3178.19,3167.38,3099.73,3117.00,3126.29,3111.44,3092.27,
694        3146.48,3094.41,3132.13,3115.37,3099.32,3110.97,3111.80,3143.14,
695        3106.72,3153.44,3136.00,3188.96,3104.73,3140.45,3073.18,3106.62,
696        3112.48,3146.92,3127.24,3136.52,3109.59,3112.89,3045.15,3147.26,
697        3095.92,3121.05,3083.25,3123.62,3150.92,3125.30,3067.60,3160.18,
698        3119.36,3108.92,3164.77,3133.64,3111.47,3131.98,3128.87,3135.56 };
699    
700      for (Int_t i=0; i<48;i++) PMTsat[i] = PMTsat[i] - 5.;  // safety margin
701    
702    
703      PadEdx = 0.;
704      //  SatWarning = 1000;
705      SatWarning = 0;   // 0=good, increase for each bad PMT
706    
707      Float_t dEdx[48] = {0};
708      Int_t pmt_id = -1;
709      Float_t adcraw[48];
710      //
711      ToFTrkVar *trk = GetToFTrkVar(notrack);
712      if(!trk) return; //ELENA
713      //
714    
715      Int_t pmtleft=-1;
716      Int_t pmtright=-1;
717      GetPaddlePMT(paddleid, pmtleft, pmtright);
718    
719      adcraw[pmtleft] = 4095;
720      adcraw[pmtright] = 4095;
721    
722      
723      for (Int_t jj=0; jj<npmt(); jj++){
724        
725        ToFPMT *pmt = GetToFPMT(jj);
726        if(!pmt)break; //ELENA
727        
728        pmt_id = pmt->pmt_id;
729        if(pmt_id==pmtleft){
730          adcraw[pmtleft] = pmt->adc;
731        }
732        
733        if(pmt_id==pmtright){
734          adcraw[pmtright] = pmt->adc;
735        }
736      }
737    
738      
739      for (Int_t i=0; i<trk->npmtadc; i++){
740    
741        if((trk->adcflag).At(i)==0 || adcfl==100){
742          if((trk->pmtadc).At(i) == pmtleft)dEdx[pmtleft] = (trk->dedx).At(i);
743          if((trk->pmtadc).At(i) == pmtright)dEdx[pmtright] = (trk->dedx).At(i);
744        }else{
745          if((trk->pmtadc).At(i) == pmtleft)dEdx[pmtleft] = 0.;
746          if((trk->pmtadc).At(i) == pmtright)dEdx[pmtright] = 0.;
747        }
748      }
749    
750    
751      //  if( adcraw[pmtleft] >3000 || adcraw[pmtright] >3000)SatWarning=1;  //old version
752    
753      // Increase SatWarning Counter for each PMT>Sat
754      if( adcraw[pmtleft] > PMTsat[pmtleft])SatWarning++;  
755      if( adcraw[pmtright] > PMTsat[pmtright])SatWarning++;
756    
757      // if ADC  > sat set dEdx=1000
758      if( adcraw[pmtleft] > PMTsat[pmtleft]) dEdx[pmtleft] = 1000.;
759      if( adcraw[pmtright] > PMTsat[pmtright]) dEdx[pmtright] = 1000. ;
760    
761      // if two PMT are good, take mean dEdx, otherwise only the good dEdx
762      if(dEdx[pmtleft]<1000 && dEdx[pmtright]<1000) PadEdx = (dEdx[pmtleft]+dEdx[pmtright])*0.5;
763      if(dEdx[pmtleft]==1000 && dEdx[pmtright]<1000) PadEdx = dEdx[pmtright];  
764      if(dEdx[pmtleft]<1000 && dEdx[pmtright]==1000) PadEdx = dEdx[pmtleft];
765      
766    };
767    
768    //
769    //  wm Nov 08 revision - saturation values included
770    /// gf Apr 07
771    /**
772     * Method to get the dEdx from a given ToF paddle.
773     * If two PMTs are good, the mean dEdx of both PMTs is taken, otherwise
774     * just the dEdx of the "good" PMT. If both PMTs are above saturation => dEdx=1000
775     * @param notrack Track Number
776     * @param Paddle index (0,1,...,23).
777     * @param adcflag in the paddle (100<-> independent of the adcflag; !=0&&!=100 <-> at least one PMT with adcflag!=0; )
778     * @param PadEdx dEdx from a given ToF paddle
779     * @param SatWarning 1 if the PMT ios near saturation region (adcraw ~3000)
780     */
781    void ToFLevel2::GetdEdxPaddle(ToFTrkVar *trk, Int_t paddleid, Int_t adcfl, Float_t &PadEdx, Int_t &SatWarning){
782    
783      /*
784        Float_t  PMTsat[48] = {
785        3162.14, 3165.48, 3153.85, 3085.73, 3089.65, 3107.64, 3097.52, 3078.37,
786        3130.05, 3087.07, 3112.22, 3102.92, 3080.58, 3092.55, 3087.94, 3125.03,
787        3094.09, 3143.16, 3125.51, 3181.27, 3092.09, 3124.98, 3069.3, 3095.53,
788        3097.11, 3133.53, 3114.73, 3113.01, 3091.19, 3097.99, 3033.84, 3134.98,
789        3081.37, 3111.04, 3066.77, 3108.17, 3133, 3111.06, 3052.52, 3140.66,
790        3106.33, 3094.85, 3150.85, 3118.8, 3096.24, 3118.47,3111.36, 3117.11 } ;
791      */
792    
793      // new values from Napoli dec 2008
794      Float_t  PMTsat[48] = {
795        3176.35,3178.19,3167.38,3099.73,3117.00,3126.29,3111.44,3092.27,
796        3146.48,3094.41,3132.13,3115.37,3099.32,3110.97,3111.80,3143.14,
797        3106.72,3153.44,3136.00,3188.96,3104.73,3140.45,3073.18,3106.62,
798        3112.48,3146.92,3127.24,3136.52,3109.59,3112.89,3045.15,3147.26,
799        3095.92,3121.05,3083.25,3123.62,3150.92,3125.30,3067.60,3160.18,
800        3119.36,3108.92,3164.77,3133.64,3111.47,3131.98,3128.87,3135.56 };
801    
802      for (Int_t i=0; i<48;i++) PMTsat[i] = PMTsat[i] - 5.;  // safety margin
803    
804    
805      PadEdx = 0.;
806      //  SatWarning = 1000;
807      SatWarning = 0;   // 0=good, increase for each bad PMT
808    
809      Float_t dEdx[48] = {0};
810      Int_t pmt_id = -1;
811      Float_t adcraw[48];
812      //
813      if(!trk) return; //ELENA
814      //
815    
816      Int_t pmtleft=-1;
817      Int_t pmtright=-1;
818      GetPaddlePMT(paddleid, pmtleft, pmtright);
819    
820      adcraw[pmtleft] = 4095;
821      adcraw[pmtright] = 4095;
822    
823      
824      for (Int_t jj=0; jj<npmt(); jj++){
825        
826        ToFPMT *pmt = GetToFPMT(jj);
827        if(!pmt)break; //ELENA
828        
829        pmt_id = pmt->pmt_id;
830        if(pmt_id==pmtleft){
831          adcraw[pmtleft] = pmt->adc;
832        }
833        
834        if(pmt_id==pmtright){
835          adcraw[pmtright] = pmt->adc;
836        }
837      }
838    
839      
840      for (Int_t i=0; i<trk->npmtadc; i++){
841    
842        if((trk->adcflag).At(i)==0 || adcfl==100){
843          if((trk->pmtadc).At(i) == pmtleft)dEdx[pmtleft] = (trk->dedx).At(i);
844          if((trk->pmtadc).At(i) == pmtright)dEdx[pmtright] = (trk->dedx).At(i);
845        }else{
846          if((trk->pmtadc).At(i) == pmtleft)dEdx[pmtleft] = 0.;
847          if((trk->pmtadc).At(i) == pmtright)dEdx[pmtright] = 0.;
848        }
849      }
850    
851    
852      //  if( adcraw[pmtleft] >3000 || adcraw[pmtright] >3000)SatWarning=1;  //old version
853    
854      // Increase SatWarning Counter for each PMT>Sat
855      if( adcraw[pmtleft] > PMTsat[pmtleft])SatWarning++;  
856      if( adcraw[pmtright] > PMTsat[pmtright])SatWarning++;
857    
858      // if ADC  > sat set dEdx=1000
859      if( adcraw[pmtleft] > PMTsat[pmtleft]) dEdx[pmtleft] = 1000.;
860      if( adcraw[pmtright] > PMTsat[pmtright]) dEdx[pmtright] = 1000. ;
861    
862      // if two PMT are good, take mean dEdx, otherwise only the good dEdx
863      if(dEdx[pmtleft]<1000 && dEdx[pmtright]<1000) PadEdx = (dEdx[pmtleft]+dEdx[pmtright])*0.5;
864      if(dEdx[pmtleft]==1000 && dEdx[pmtright]<1000) PadEdx = dEdx[pmtright];  
865      if(dEdx[pmtleft]<1000 && dEdx[pmtright]==1000) PadEdx = dEdx[pmtleft];
866      
867    };
868    
869    // gf Apr 07
870    
871    /**
872     * Method to get the PMT name (like "S11_1A") if the PMT_ID is given.
873     * Indexes of corresponding  plane, paddle and  pmt are also given as output.
874     * @param ind  PMT_ID (0 - 47)
875     * @param iplane plane index (0 - 5)
876     * @param ipaddle paddle index (relative to the plane)
877     * @param ipmt pmt index (0(A), 1(B))
878     */
879    TString ToFLevel2::GetPMTName(Int_t ind, Int_t &iplane, Int_t &ipaddle,Int_t &ipmt){
880      
881      TString pmtname = " ";
882      
883      TString photoS[48] = {
884        "S11_1A", "S11_1B", "S11_2A", "S11_2B", "S11_3A", "S11_3B", "S11_4A",
885        "S11_4B",
886        "S11_5A", "S11_5B", "S11_6A", "S11_6B", "S11_7A", "S11_7B", "S11_8A",
887        "S11_8B",
888        "S12_1A", "S12_1B", "S12_2A", "S12_2B", "S12_3A", "S12_3B", "S12_4A",
889        "S12_4B", "S12_5A",  "S12_5B", "S12_6A", "S12_6B",
890        "S21_1A", "S21_1B", "S21_2A", "S21_2B",
891        "S22_1A", "S22_1B", "S22_2A", "S22_2B",
892        "S31_1A", "S31_1B", "S31_2A", "S31_2B", "S31_3A", "S31_3B",
893        "S32_1A", "S32_1B", "S32_2A", "S32_2B", "S32_3A", "S32_3B"
894      };
895      
896      
897      pmtname = photoS[ind].Data();
898      
899      TString ss = pmtname(1,2);
900      iplane  = (int)(atoi(ss.Data())/10)*2-3+atoi(ss.Data())%10;
901      ss = pmtname(4);
902      ipaddle = atoi(ss.Data())-1 ;
903      if( pmtname.Contains("A") )ipmt=0;
904      if( pmtname.Contains("B") )ipmt=1;
905      
906      return pmtname;
907    };
908    /**
909     * Method to get the PMT name (like "S11_1A") if the PMT_ID is given
910     * @param ind  PMT_ID (0 - 47)
911     */
912    TString ToFLevel2::GetPMTName(Int_t ind){
913    
914      Int_t iplane  = -1;
915      Int_t ipaddle = -1;
916      Int_t ipmt    = -1;
917      return GetPMTName(ind,iplane,ipaddle,ipmt);
918      
919    };
920    
921    // wm jun 08
922    Int_t ToFLevel2::GetPaddleIdOfTrack(Float_t xtr, Float_t ytr, Int_t plane){
923    return GetPaddleIdOfTrack(xtr ,ytr ,plane, 0.4);
924    }
925    
926    // gf Apr 07
927    Int_t ToFLevel2::GetPaddleIdOfTrack(Float_t xtr, Float_t ytr, Int_t plane, Float_t margin){
928      
929      Double_t xt,yt,xl,xh,yl,yh;
930      
931      Float_t tof11_x[8] = {-17.85,-12.75,-7.65,-2.55,2.55,7.65,12.75,17.85};
932      Float_t tof12_y[6] = { -13.75,-8.25,-2.75,2.75,8.25,13.75};
933      Float_t tof21_y[2] = { 3.75,-3.75};
934      Float_t tof22_x[2] = { -4.5,4.5};
935      Float_t tof31_x[3] = { -6.0,0.,6.0};
936      Float_t tof32_y[3] = { -5.0,0.0,5.0};
937      
938      //  S11 8 paddles  33.0 x 5.1 cm
939      //  S12 6 paddles  40.8 x 5.5 cm
940      //  S21 2 paddles  18.0 x 7.5 cm
941      //  S22 2 paddles  15.0 x 9.0 cm
942      //  S31 3 paddles  15.0 x 6.0 cm
943      //  S32 3 paddles  18.0 x 5.0 cm
944      
945      Int_t paddleidoftrack=-1;
946      //
947      
948      //--- S11 ------
949      
950      if(plane==0){
951        xt = xtr;
952        yt = ytr;
953        paddleidoftrack=-1;
954        yl = -33.0/2. ;
955        yh =  33.0/2. ;
956        if ((yt>yl)&&(yt<yh)) {
957          for (Int_t i1=0; i1<8;i1++){
958            xl = tof11_x[i1] - (5.1-margin)/2. ;
959            xh = tof11_x[i1] + (5.1-margin)/2. ;
960            if ((xt>xl)&&(xt<xh))  paddleidoftrack=i1;
961          }
962        }
963      }
964      //      cout<<"S11  "<<paddleidoftrack[0]<<"\n";
965      
966      //--- S12 -------
967      if(plane==1){
968        xt = xtr;
969        yt = ytr;
970        paddleidoftrack=-1;
971        xl = -40.8/2. ;
972        xh =  40.8/2. ;
973        
974        if ((xt>xl)&&(xt<xh)) {
975          for (Int_t i1=0; i1<6;i1++){
976            yl = tof12_y[i1] - (5.5-margin)/2. ;
977            yh = tof12_y[i1] + (5.5-margin)/2. ;
978            if ((yt>yl)&&(yt<yh))  paddleidoftrack=i1;
979          }
980        }
981      }
982      
983      //--- S21 ------
984    
985      if(plane==2){
986        xt = xtr;
987        yt = ytr;
988        paddleidoftrack=-1;
989        xl = -18./2. ;
990        xh =  18./2. ;
991        
992        if ((xt>xl)&&(xt<xh)) {
993          for (Int_t i1=0; i1<2;i1++){
994            yl = tof21_y[i1] - (7.5-margin)/2. ;
995            yh = tof21_y[i1] + (7.5-margin)/2. ;
996            if ((yt>yl)&&(yt<yh))  paddleidoftrack=i1;
997          }
998        }
999      }
1000      
1001      //--- S22 ------
1002      if(plane==3){
1003        xt = xtr;
1004        yt = ytr;
1005        paddleidoftrack=-1;
1006        yl = -15./2. ;
1007        yh =  15./2. ;
1008        
1009        if ((yt>yl)&&(yt<yh)) {
1010          for (Int_t i1=0; i1<2;i1++){
1011            xl = tof22_x[i1] - (9.0-margin)/2. ;
1012            xh = tof22_x[i1] + (9.0-margin)/2. ;
1013            if ((xt>xl)&&(xt<xh))  paddleidoftrack=i1;
1014          }
1015        }
1016      }  
1017      
1018      //--- S31 ------
1019      if(plane==4){
1020        xt = xtr;
1021        yt = ytr;
1022        paddleidoftrack=-1;
1023        yl = -15.0/2. ;
1024        yh =  15.0/2. ;
1025        
1026        if ((yt>yl)&&(yt<yh)) {
1027          for (Int_t i1=0; i1<3;i1++){
1028            xl = tof31_x[i1] - (6.0-margin)/2. ;
1029            xh = tof31_x[i1] + (6.0-margin)/2. ;
1030            if ((xt>xl)&&(xt<xh))  paddleidoftrack=i1;
1031          }
1032        }
1033      }  
1034      
1035      //---  S32 ------
1036      if(plane==5){
1037        xt = xtr;
1038        yt = ytr;
1039        paddleidoftrack=-1;
1040        xl = -18.0/2. ;
1041        xh =  18.0/2. ;
1042        
1043        if ((xt>xl)&&(xt<xh)) {
1044          for (Int_t i1=0; i1<3;i1++){
1045            yl = tof32_y[i1] - (5.0-margin)/2. ;
1046            yh = tof32_y[i1] + (5.0-margin)/2. ;
1047            if ((yt>yl)&&(yt<yh)) paddleidoftrack=i1;
1048          }
1049        }
1050      }
1051      
1052      return paddleidoftrack;
1053    
1054    }  
1055    
1056    //
1057    
1058    // gf Apr 07
1059    
1060    void ToFLevel2::GetPMTPaddle(Int_t pmt_id, Int_t &plane, Int_t &paddle){
1061      
1062      plane = GetPlaneIndex(pmt_id);
1063    
1064      if(plane == 0){
1065        if(pmt_id==0 || pmt_id==1)paddle=0;
1066        if(pmt_id==2 || pmt_id==3)paddle=1;
1067        if(pmt_id==4 || pmt_id==5)paddle=2;
1068        if(pmt_id==6 || pmt_id==7)paddle=3;
1069        if(pmt_id==8 || pmt_id==9)paddle=4;
1070        if(pmt_id==10 || pmt_id==11)paddle=5;
1071        if(pmt_id==12 || pmt_id==13)paddle=6;
1072        if(pmt_id==14 || pmt_id==15)paddle=7;
1073      }
1074      
1075      if(plane == 1){
1076        if(pmt_id==16 || pmt_id==17)paddle=0;
1077        if(pmt_id==18 || pmt_id==19)paddle=1;
1078        if(pmt_id==20 || pmt_id==21)paddle=2;
1079        if(pmt_id==22 || pmt_id==23)paddle=3;
1080        if(pmt_id==24 || pmt_id==25)paddle=4;
1081        if(pmt_id==26 || pmt_id==27)paddle=5;
1082      }
1083      
1084      if(plane == 2){
1085        if(pmt_id==28 || pmt_id==29)paddle=0;
1086        if(pmt_id==30 || pmt_id==31)paddle=1;
1087      }
1088      
1089      if(plane == 3){
1090        if(pmt_id==32 || pmt_id==33)paddle=0;
1091        if(pmt_id==34 || pmt_id==35)paddle=1;
1092      }
1093      
1094      if(plane == 4){
1095        if(pmt_id==36 || pmt_id==37)paddle=0;
1096        if(pmt_id==38 || pmt_id==39)paddle=1;
1097        if(pmt_id==40 || pmt_id==41)paddle=2;
1098      }
1099      
1100      if(plane == 5){
1101        if(pmt_id==42 || pmt_id==43)paddle=0;
1102        if(pmt_id==44 || pmt_id==45)paddle=1;
1103        if(pmt_id==46 || pmt_id==47)paddle=2;
1104      }
1105      return;
1106    }
1107    
1108    //
1109    
1110    // gf Apr 07
1111    
1112    void ToFLevel2::GetPaddlePMT(Int_t paddle, Int_t &pmtleft, Int_t &pmtright){
1113      pmtleft=paddle*2;
1114      pmtright= pmtleft+1;  
1115      return;
1116    }
1117    
1118    //
1119    
1120    
1121    
1122    // // gf Apr 07
1123    
1124    void ToFLevel2::GetPaddleGeometry(Int_t plane, Int_t paddle, Float_t &xleft, Float_t &xright, Float_t &yleft, Float_t &yright){
1125      
1126      Int_t i1;
1127    
1128      Float_t tof11_x[8] = {-17.85,-12.75,-7.65,-2.55,2.55,7.65,12.75,17.85};
1129      Float_t tof12_y[6] = { -13.75,-8.25,-2.75,2.75,8.25,13.75};
1130      Float_t tof21_y[2] = { 3.75,-3.75};
1131      Float_t tof22_x[2] = { -4.5,4.5};
1132      Float_t tof31_x[3] = { -6.0,0.,6.0};
1133      Float_t tof32_y[3] = { -5.0,0.0,5.0};
1134            
1135      //  S11 8 paddles  33.0 x 5.1 cm
1136      //  S12 6 paddles  40.8 x 5.5 cm
1137      //  S21 2 paddles  18.0 x 7.5 cm
1138      //  S22 2 paddles  15.0 x 9.0 cm
1139      //  S31 3 paddles  15.0 x 6.0 cm
1140      //  S32 3 paddles  18.0 x 5.0 cm
1141    
1142      if(plane==0)
1143        {
1144          for (i1=0; i1<8;i1++){
1145            if(i1 == paddle){
1146              xleft = tof11_x[i1] - 5.1/2.;
1147              xright = tof11_x[i1] + 5.1/2.;
1148              yleft = -33.0/2.;
1149              yright = 33.0/2.;
1150            }
1151          }
1152        }
1153      
1154      if(plane==1)
1155        {
1156          for (i1=0; i1<6;i1++){
1157            if(i1 == paddle){
1158              xleft = -40.8/2.;
1159              xright = 40.8/2.;
1160              yleft = tof12_y[i1] - 5.5/2.;
1161              yright = tof12_y[i1] + 5.5/2.;
1162            }
1163          }
1164        }
1165    
1166      if(plane==2)
1167        {
1168          for (i1=0; i1<2;i1++){
1169            if(i1 == paddle){
1170              xleft =  -18./2.;
1171              xright = 18./2.;
1172              yleft = tof21_y[i1] - 7.5/2.;
1173              yright = tof21_y[i1] + 7.5/2.;
1174            }
1175          }
1176        }
1177      
1178      if(plane==3)
1179        {
1180          for (i1=0; i1<2;i1++){
1181            if(i1 == paddle){
1182              xleft = tof22_x[i1] - 9.0/2.;
1183              xright = tof22_x[i1] + 9.0/2.;
1184              yleft = -15./2.;
1185              yright = 15./2.;
1186            }
1187          }
1188        }
1189    
1190    
1191      if(plane==4)
1192        {
1193          for (i1=0; i1<3;i1++){
1194            if(i1 == paddle){
1195              xleft = tof31_x[i1] - 6.0/2.;
1196              xright = tof31_x[i1] + 6.0/2.;
1197              yleft = -15./2.;
1198              yright = 15./2.;
1199            }
1200          }
1201        }
1202    
1203      if(plane==5)
1204        {
1205          for (i1=0; i1<3;i1++){
1206            if(i1 == paddle){
1207              xleft = -18.0/2.;
1208              xright = 18.0/2.;
1209              yleft = tof32_y[i1] - 5.0/2.;
1210              yright = tof32_y[i1] + 5.0/2.;
1211            }
1212          }
1213        }
1214      return;
1215    }
1216    
1217    // gf Apr 07
1218    /**
1219     * Method to get the paddle index (0,...23) if the plane ID and the paddle id in the plane is given.
1220     * This method is the
1221     * "reverse" of method "GetPaddlePlane"
1222     * @param plane    (0 - 5)
1223     * @param paddle   (plane=0, paddle = 0,...5)
1224     * @param padid    (0 - 23)
1225     */
1226    Int_t ToFLevel2::GetPaddleid(Int_t plane, Int_t paddle)
1227    {
1228      Int_t padid=-1;
1229      Int_t pads[6]={8,6,2,2,3,3};
1230    
1231      int somma=0;
1232      int np=plane;
1233      for(Int_t j=0; j<np; j++){
1234        somma+=pads[j];
1235      }
1236      padid=paddle+somma;
1237      return padid;
1238    
1239    }
1240    
1241    
1242    // gf Apr 07
1243    /**
1244     * Method to get the plane ID and the paddle id in the plane if the paddle index (0,...23) is given.
1245     * This method is the
1246     * "reverse" of method "GetPaddleid"
1247     * @param pad      (0 - 23)
1248     * @param plane    (0 - 5)
1249     * @param paddle   (plane=0, paddle = 0,...5)
1250     */
1251    void ToFLevel2::GetPaddlePlane(Int_t pad, Int_t &plane, Int_t &paddle)
1252    {
1253    
1254      Int_t pads11=8;
1255      Int_t pads12=6;
1256      Int_t pads21=2;
1257      Int_t pads22=2;
1258      Int_t pads31=3;
1259      // Int_t pads32=3;
1260    
1261      if(pad<8){
1262        plane=0;
1263        paddle=pad;
1264        return;
1265      }
1266    
1267      if((7<pad)&&(pad<14)){
1268        plane=1;
1269        paddle=pad-pads11;
1270        return;
1271      }
1272      
1273      if((13<pad)&&(pad<16)){
1274        plane=2;
1275        paddle=pad-pads11-pads12;
1276        return;
1277      }
1278    
1279      if((15<pad)&&(pad<18)){
1280        plane=3;
1281        paddle=pad-pads11-pads12-pads21;
1282        return;
1283      }
1284    
1285      if((17<pad)&&(pad<21)){
1286        plane=4;
1287        paddle=pad-pads11-pads12-pads21-pads22;
1288        return;
1289      }
1290    
1291      if((20<pad)&&(pad<24)){
1292        plane=5;
1293        paddle=pad-pads11-pads12-pads21-pads22-pads31;
1294        return;
1295      }  
1296    
1297    }
1298    
1299    
1300    Int_t ToFLevel2::GetNPaddle(Int_t plane){
1301    
1302      Int_t npaddle=-1;
1303    
1304      Int_t pads11=8;
1305      Int_t pads12=6;
1306      Int_t pads21=2;
1307      Int_t pads22=2;
1308      Int_t pads31=3;
1309      Int_t pads32=3;
1310    
1311      if(plane==0)npaddle=pads11;
1312      if(plane==1)npaddle=pads12;
1313      if(plane==2)npaddle=pads21;
1314      if(plane==3)npaddle=pads22;
1315      if(plane==4)npaddle=pads31;
1316      if(plane==5)npaddle=pads32;
1317    
1318      return npaddle;
1319    
1320    }
1321    
1322    
1323    
1324    /// wm feb 08
1325    
1326    /**
1327     * Method to calculate Beta from the 12 single measurements
1328     * we check the individual weights for artificial TDC values, then calculate
1329     * am mean beta for the first time. In a second step we loop again through
1330     * the single measurements, checking for the residual from the mean
1331     * The cut on the residual reject measurements > "x"-sigma. A chi2 value is
1332     * calculated, furthermore a "quality" value by adding the weights which
1333     * are finally used. If all measurements are taken, "quality" will be = 22.47.
1334     * A chi2 cut around 3-4 and a quality-cut > 20 is needed for clean beta
1335     * measurements like antiprotons etc.
1336     * The Level2 output is derived in the fortran routines using: 10.,10.,20.
1337     * @param notrack Track Number
1338     * @param cut on residual: difference between single measurement and mean
1339     * @param cut on "quality"
1340     * @param cut on chi2
1341     */
1342    
1343    Float_t ToFLevel2::CalcBeta(Int_t notrack, Float_t resmax, Float_t qualitycut, Float_t chi2cut){
1344    
1345    //  cout<<" in CalcBeta "<<resmax<<" "<<chi2cut<<" "<<qualitycut<<endl;
1346    
1347      Float_t bxx = 100.;
1348      //
1349      ToFTrkVar *trk = GetToFTrkVar(notrack);
1350      if(!trk) return 0; //ELENA
1351    
1352    
1353      Float_t chi2,xhelp,beta_mean;
1354      Float_t w_i[12],quality,sw,sxw,res,betachi,beta_mean_inv;
1355      Float_t b[12],tdcfl;
1356      Int_t  pmt_id,pmt_plane;
1357    
1358      for (Int_t i=0; i<12; i++){
1359        b[i] = trk->beta[i];
1360                                  }
1361          
1362    
1363    //========================================================================
1364    //---  Find out ToF layers with artificial TDC values & fill vector    ---
1365    //========================================================================
1366    
1367    Float_t  w_il[6];
1368    
1369         for (Int_t jj=0; jj<6;jj++) {
1370             w_il[jj] = 1000.;
1371                                     }
1372    
1373    
1374      for (Int_t i=0; i<trk->npmttdc; i++){
1375        //
1376        pmt_id = (trk->pmttdc).At(i);
1377        pmt_plane = GetPlaneIndex(pmt_id);
1378        tdcfl = (trk->tdcflag).At(i);
1379        if (w_il[pmt_plane] != 1.) w_il[pmt_plane] = tdcfl; //tdcflag
1380                                         };
1381      
1382    //========================================================================
1383    //---  Set weights for the 12 measurements using information for top and bottom:
1384    //---  if no measurements: weight = set to very high value=> not used
1385    //---  top or bottom artificial: weight*sqrt(2)
1386    //---  top and bottom artificial: weight*sqrt(2)*sqrt(2)
1387    //========================================================================
1388    
1389    Int_t itop[12] = {0,0,1,1,2,2,3,3,0,0,1,1};
1390    Int_t ibot[12] = {4,5,4,5,4,5,4,5,2,3,2,3};
1391    
1392         xhelp= 1E09;
1393      
1394         for (Int_t jj=0; jj<12;jj++) {
1395         if (jj<4)           xhelp = 0.11;    // S1-S3
1396         if ((jj>3)&&(jj<8)) xhelp = 0.18;    // S2-S3
1397         if (jj>7)           xhelp = 0.28;    // S1-S2
1398         if ((w_il[itop[jj]] == 1000.) && (w_il[ibot[jj]] == 1000.)) xhelp = 1E09;
1399         if ((w_il[itop[jj]] == 1) || (w_il[ibot[jj]] == 1.)) xhelp = xhelp*1.414 ;
1400         if ((w_il[itop[jj]] == 1) && (w_il[ibot[jj]] == 1.)) xhelp = xhelp*2. ;
1401    
1402         w_i[jj] = 1./xhelp;
1403                                      }
1404    
1405    
1406    //========================================================================
1407    //--- Calculate mean beta for the first time -----------------------------
1408    //--- We are using "1/beta" since its error is gaussian ------------------
1409    //========================================================================
1410    
1411          Int_t icount=0;
1412          sw=0.;
1413          sxw=0.;
1414          beta_mean=100.;
1415    
1416              for (Int_t jj=0; jj<12;jj++){
1417            if ((fabs(1./b[jj])>0.1)&&(fabs(1./b[jj])<15.))
1418             {
1419                icount= icount+1;
1420                sxw=sxw + (1./b[jj])*w_i[jj]*w_i[jj] ;
1421                sw =sw + w_i[jj]*w_i[jj] ;
1422    
1423             }
1424             }
1425    
1426          if (icount>0) beta_mean=1./(sxw/sw);
1427          beta_mean_inv = 1./beta_mean;
1428    
1429    //========================================================================
1430    //--- Calculate beta for the second time, use residuals of the single
1431    //--- measurements to get a chi2 value
1432    //========================================================================
1433    
1434          icount=0;
1435          sw=0.;
1436          sxw=0.;
1437          betachi = 100.;
1438          chi2 = 0.;
1439          quality=0.;
1440    
1441    
1442              for (Int_t jj=0; jj<12;jj++){
1443           if ((fabs(1./b[jj])>0.1)&&(fabs(1./b[jj])<15.)&&(w_i[jj]>0.01)) {
1444                res = beta_mean_inv - (1./b[jj]) ;
1445                if (fabs(res*w_i[jj])<resmax)          {;
1446                chi2 = chi2 + pow((res*w_i[jj]),2) ;
1447                icount= icount+1;
1448                sxw=sxw + (1./b[jj])*w_i[jj]*w_i[jj] ;
1449                sw =sw + w_i[jj]*w_i[jj] ;
1450                                                   }
1451                                                                            }
1452                                          }
1453          quality = sqrt(sw) ;
1454    
1455          if (icount==0) chi2 = 1000.;
1456          if (icount>0) chi2 = chi2/(icount) ;
1457          if (icount>0) betachi=1./(sxw/sw);
1458    
1459       bxx = 100.;
1460       if ((chi2 < chi2cut)&&(quality>qualitycut)) bxx = betachi;
1461      //
1462      return(bxx);
1463    };
1464    
1465    
1466    ////////////////////////////////////////////////////
1467    ////////////////////////////////////////////////////
1468    
1469    
1470  /**  /**
1471   * Fills a struct cToFLevel2 with values from a ToFLevel2 object (to put data into a F77 common).   * Fills a struct cToFLevel2 with values from a ToFLevel2 object (to put data into a F77 common).
1472   */   */
# Line 334  void ToFLevel2::GetLevel2Struct(cToFLeve Line 1475  void ToFLevel2::GetLevel2Struct(cToFLeve
1475    for(Int_t i=0;i<6;i++)    for(Int_t i=0;i<6;i++)
1476      l2->tof_j_flag[i]=tof_j_flag[i];      l2->tof_j_flag[i]=tof_j_flag[i];
1477    
1478    l2->ntoftrk = ToFTrk->GetEntries();    if(ToFTrk){ //ELENA
1479    for(Int_t j=0;j<l2->ntoftrk;j++){        l2->ntoftrk = ToFTrk->GetEntries();
1480      l2->toftrkseqno[j]= ((ToFTrkVar*)ToFTrk->At(j))->trkseqno;        for(Int_t j=0;j<l2->ntoftrk;j++){
1481      l2->npmttdc[j]= ((ToFTrkVar*)ToFTrk->At(j))->npmttdc;            l2->toftrkseqno[j]= ((ToFTrkVar*)ToFTrk->At(j))->trkseqno;
1482      for(Int_t i=0;i<l2->npmttdc[j];i++)            l2->npmttdc[j]= ((ToFTrkVar*)ToFTrk->At(j))->npmttdc;
1483        l2->pmttdc[i][j] = ((ToFTrkVar*)ToFTrk->At(j))->pmttdc.At(i);            for(Int_t i=0;i<l2->npmttdc[j];i++){
1484      for(Int_t i=0;i<13;i++)                l2->pmttdc[i][j] = ((ToFTrkVar*)ToFTrk->At(j))->pmttdc.At(i);
1485        l2->beta[i][j] = ((ToFTrkVar*)ToFTrk->At(j))->beta[i];                l2->tdcflag[i][j] = ((ToFTrkVar*)ToFTrk->At(j))->tdcflag.At(i); // gf: 30 Nov 2006
1486              }
1487      l2->npmtadc[j]= ((ToFTrkVar*)ToFTrk->At(j))->npmtadc;            for(Int_t i=0;i<13;i++)
1488      for(Int_t i=0;i<l2->npmtadc[j];i++){                l2->beta[i][j] = ((ToFTrkVar*)ToFTrk->At(j))->beta[i];
1489        l2->pmtadc[i][j] = ((ToFTrkVar*)ToFTrk->At(j))->pmtadc.At(i);            
1490        l2->dedx[i][j] = ((ToFTrkVar*)ToFTrk->At(j))->dedx.At(i);            l2->npmtadc[j]= ((ToFTrkVar*)ToFTrk->At(j))->npmtadc;
1491      }            for(Int_t i=0;i<l2->npmtadc[j];i++){
1492      for(Int_t i=0;i<3;i++){                l2->pmtadc[i][j] = ((ToFTrkVar*)ToFTrk->At(j))->pmtadc.At(i);
1493        l2->xtofpos[i][j]=((ToFTrkVar*)ToFTrk->At(j))->xtofpos[i];                l2->adcflag[i][j] = ((ToFTrkVar*)ToFTrk->At(j))->adcflag.At(i); // gf: 30 Nov 2006
1494        l2->ytofpos[i][j]=((ToFTrkVar*)ToFTrk->At(j))->ytofpos[i];                l2->dedx[i][j] = ((ToFTrkVar*)ToFTrk->At(j))->dedx.At(i);
1495              }
1496              for(Int_t i=0;i<3;i++){
1497                  l2->xtofpos[i][j]=((ToFTrkVar*)ToFTrk->At(j))->xtofpos[i];
1498                  l2->ytofpos[i][j]=((ToFTrkVar*)ToFTrk->At(j))->ytofpos[i];
1499              }
1500              for(Int_t i=0;i<6;i++){
1501                  l2->xtr_tof[i][j]=((ToFTrkVar*)ToFTrk->At(j))->xtr_tof[i];
1502                  l2->ytr_tof[i][j]=((ToFTrkVar*)ToFTrk->At(j))->ytr_tof[i];
1503              }
1504          }
1505      } //ELENA
1506        
1507      if(PMT){ //ELENA
1508          l2->npmt = PMT->GetEntries();
1509          for(Int_t j=0;j<l2->npmt;j++){
1510              l2->pmt_id[j] = ((ToFPMT*)PMT->At(j))->pmt_id;
1511              l2->adc[j] =((ToFPMT*)PMT->At(j))->adc;
1512              l2->tdc_tw[j] =((ToFPMT*)PMT->At(j))->tdc_tw;
1513          }
1514      } //ELENA
1515    }
1516    
1517    
1518    //
1519    // Reprocessing tool // Emiliano 08/04/07
1520    //
1521    Int_t ToFLevel2::Process(TrkLevel2 *trk, TrigLevel2 *trg, GL_RUN *run, OrbitalInfo *orb, Bool_t force){
1522      //
1523      // Copiare qui qualcosa di simile a calonuclei per evitare di riprocessare sempre tutto
1524      //
1525      printf("\n\n\n ERROR: NOT IMPLEMENTED ANYMORE, write Emiliano if you need this method (Emiliano.Mocchiutti@ts.infn.it) \n\n\n");
1526      return(-1);
1527      //   //
1528      //   // structures to communicate with F77
1529      //   //
1530      //   extern struct ToFInput  tofinput_;
1531    //   extern struct ToFOutput tofoutput_;
1532    //   //
1533    //   // DB connection
1534    //   //
1535    //   TString host;
1536    //   TString user;
1537    //   TString psw;
1538    //   const char *pamdbhost=gSystem->Getenv("PAM_DBHOST");
1539    //   const char *pamdbuser=gSystem->Getenv("PAM_DBUSER");
1540    //   const char *pamdbpsw=gSystem->Getenv("PAM_DBPSW");
1541    //   if ( !pamdbhost ) pamdbhost = "";
1542    //   if ( !pamdbuser ) pamdbuser = "";
1543    //   if ( !pamdbpsw ) pamdbpsw = "";
1544    //   if ( strcmp(pamdbhost,"") ) host = pamdbhost;
1545    //   if ( strcmp(pamdbuser,"") ) user = pamdbuser;
1546    //   if ( strcmp(pamdbpsw,"") ) psw = pamdbpsw;
1547    //   //
1548    //   //
1549    //   TSQLServer *dbc = TSQLServer::Connect(host.Data(),user.Data(),psw.Data());
1550    //   if ( !dbc->IsConnected() ) return 1;
1551    //   stringstream myquery;
1552    //   myquery.str("");
1553    //   myquery << "SET time_zone='+0:00';";
1554    //   dbc->Query(myquery.str().c_str());
1555    //   delete dbc->Query("SET sql_mode = 'NO_UNSIGNED_SUBTRACTION';");
1556    //   GL_PARAM *glparam = new GL_PARAM();
1557    //   glparam->Query_GL_PARAM(1,1,dbc); // parameters stored in DB in GL_PRAM table
1558    //   trk->LoadField(glparam->PATH+glparam->NAME);
1559    //   //
1560    //   Bool_t defcal = true;
1561    //   Int_t error=glparam->Query_GL_PARAM(run->RUNHEADER_TIME,201,dbc); // parameters stored in DB in GL_PRAM table
1562    //   if ( error<0 ) {
1563    //     return(1);
1564    //   };
1565    //   printf(" Reading ToF parameter file: %s \n",(glparam->PATH+glparam->NAME).Data());
1566    //   if ( (UInt_t)glparam->TO_TIME != (UInt_t)4294967295UL ) defcal = false;
1567    //   //
1568    //   Int_t nlen = (Int_t)(glparam->PATH+glparam->NAME).Length();
1569    //   rdtofcal((char *)(glparam->PATH+glparam->NAME).Data(),&nlen);
1570    //   //
1571    //   Int_t adc[4][12];
1572    //   Int_t tdc[4][12];
1573    //   Float_t tdcc[4][12];
1574    //   //
1575    //   // process tof data
1576    //   //
1577    //   for (Int_t hh=0; hh<12;hh++){
1578    //     for (Int_t kk=0; kk<4;kk++){
1579    //            adc[kk][hh] = 4095;
1580    //            tdc[kk][hh] = 4095;
1581    //            tdcc[kk][hh] = 4095.;
1582    //            tofinput_.adc[hh][kk] = 4095;
1583    //            tofinput_.tdc[hh][kk] = 4095;
1584    //     };
1585    //   };
1586    //   Int_t ntrkentry = 0;
1587    //   Int_t npmtentry = 0;
1588    //   Int_t gg = 0;
1589    //   Int_t hh = 0;
1590    //   Int_t adcf[48];
1591    //   memset(adcf, 0, 48*sizeof(Int_t));
1592    //   Int_t tdcf[48];
1593    //   memset(tdcf, 0, 48*sizeof(Int_t));
1594    //   for (Int_t pm=0; pm < this->ntrk() ; pm++){
1595    //      ToFTrkVar *ttf = this->GetToFTrkVar(pm);
1596    //      for ( Int_t nc=0; nc < ttf->npmttdc; nc++){
1597    //             if ( (ttf->tdcflag).At(nc) != 0 ) tdcf[(ttf->pmttdc).At(nc)] = 1;
1598    //      };
1599    //      for ( Int_t nc=0; nc < ttf->npmtadc; nc++){
1600    //             if ( (ttf->adcflag).At(nc) != 0 ) adcf[(ttf->pmtadc).At(nc)] = 1;
1601    //      };
1602    //   };
1603    //   //
1604    //   for (Int_t pm=0; pm < this->npmt() ; pm++){
1605    //      ToFPMT *pmt = this->GetToFPMT(pm);
1606    //      this->GetPMTIndex(pmt->pmt_id, gg, hh);
1607    //      if ( adcf[pmt->pmt_id] == 0 ){
1608    //              tofinput_.adc[gg][hh] = (int)pmt->adc;
1609    //              adc[hh][gg] = (int)pmt->adc;
1610    //      };
1611    //      if ( tdcf[pmt->pmt_id] == 0 ){
1612    //              tofinput_.tdc[gg][hh] = (int)pmt->tdc;
1613    //              tdc[hh][gg] = (int)pmt->tdc;
1614    //      };
1615    //      tdcc[hh][gg] = (float)pmt->tdc_tw;
1616    //      // Int_t pppid = this->GetPMTid(hh,gg);
1617    //      //      printf(" pm %i pmt_id %i pppid %i hh %i gg %i tdcc %f tdc %f adc %f \n",pm,pmt->pmt_id,pppid,hh,gg,pmt->tdc_tw,pmt->tdc,pmt->adc);
1618    //   };
1619    //   //
1620    //   Int_t unpackError = this->unpackError;
1621    //   //
1622    //   for (Int_t hh=0; hh<5;hh++){
1623    //      tofinput_.patterntrig[hh]=trg->patterntrig[hh];
1624    //   };
1625    //   //
1626    //   this->Clear();
1627    //   //
1628    //       Int_t pmt_id = 0;
1629    //       ToFPMT *t_pmt = new ToFPMT();
1630    //       if(!(this->PMT)) this->PMT = new TClonesArray("ToFPMT",12); //ELENA
1631    //       TClonesArray &tpmt = *this->PMT;
1632    //       ToFTrkVar *t_tof = new ToFTrkVar();
1633    //       if(!(this->ToFTrk)) this->ToFTrk = new TClonesArray("ToFTrkVar",2); //ELENA
1634    //       TClonesArray &t = *this->ToFTrk;
1635    //       //
1636    //       //
1637    //       // Here we have calibrated data, ready to be passed to the FORTRAN routine which will extract common and track-related  variables.
1638    //       //
1639    //       npmtentry = 0;
1640    //       //
1641    //       ntrkentry = 0;
1642    //       //
1643    //       // Calculate tracks informations from ToF alone
1644    //       //
1645    //       tofl2com();
1646    //       //
1647    //       memcpy(this->tof_j_flag,tofoutput_.tof_j_flag,6*sizeof(Int_t));
1648    //       //
1649    //       t_tof->trkseqno = -1;
1650    //       //
1651    //       // and now we must copy from the output structure to the level2 class:
1652    //       //
1653    //       t_tof->npmttdc = 0;
1654    //       //
1655    //       for (Int_t hh=0; hh<12;hh++){
1656    //         for (Int_t kk=0; kk<4;kk++){
1657    //           if ( tofoutput_.tofmask[hh][kk] != 0 ){
1658    //             pmt_id = this->GetPMTid(kk,hh);
1659    //             t_tof->pmttdc.AddAt(pmt_id,t_tof->npmttdc);
1660    //             t_tof->tdcflag.AddAt(tofoutput_.tdcflagtof[hh][kk],t_tof->npmttdc); // gf: Jan 09/07
1661    //             t_tof->npmttdc++;
1662    //           };
1663    //         };
1664    //       };
1665    //       for (Int_t kk=0; kk<13;kk++){
1666    //         t_tof->beta[kk] = tofoutput_.betatof_a[kk];
1667    //       }
1668    //       //
1669    //       t_tof->npmtadc = 0;
1670    //       for (Int_t hh=0; hh<12;hh++){
1671    //         for (Int_t kk=0; kk<4;kk++){
1672    //           if ( tofoutput_.adctof_c[hh][kk] < 1000 ){
1673    //             t_tof->dedx.AddAt(tofoutput_.adctof_c[hh][kk],t_tof->npmtadc);
1674    //             pmt_id = this->GetPMTid(kk,hh);
1675    //             t_tof->pmtadc.AddAt(pmt_id,t_tof->npmtadc);
1676    //             t_tof->adcflag.AddAt(tofoutput_.adcflagtof[hh][kk],t_tof->npmtadc); // gf: Jan 09/07
1677    //             t_tof->npmtadc++;
1678    //           };
1679    //         };
1680    //       };
1681    //       //
1682    //       memcpy(t_tof->xtofpos,tofoutput_.xtofpos,sizeof(t_tof->xtofpos));
1683    //       memcpy(t_tof->ytofpos,tofoutput_.ytofpos,sizeof(t_tof->ytofpos));
1684    //       memcpy(t_tof->xtr_tof,tofoutput_.xtr_tof,sizeof(t_tof->xtr_tof));
1685    //       memcpy(t_tof->ytr_tof,tofoutput_.ytr_tof,sizeof(t_tof->ytr_tof));
1686    //       //
1687    //       new(t[ntrkentry]) ToFTrkVar(*t_tof);
1688    //       ntrkentry++;
1689    //       t_tof->Clear();
1690    //       //
1691    //       //
1692    //       //
1693    //       t_pmt->Clear();
1694    //       //
1695    //       for (Int_t hh=0; hh<12;hh++){
1696    //         for (Int_t kk=0; kk<4;kk++){
1697    //          // new WM
1698    //           if ( tofoutput_.tdc_c[hh][kk] < 4095 || adc[kk][hh] < 4095  || tdc[kk][hh] < 4095 ){
1699    // //          if ( tdcc[kk][hh] < 4095. || adc[kk][hh] < 4095  || tdc[kk][hh] < 4095 ){
1700    //             //
1701    //             t_pmt->pmt_id = this->GetPMTid(kk,hh);
1702    //             t_pmt->tdc_tw = tofoutput_.tdc_c[hh][kk];
1703    //             t_pmt->adc = (Float_t)adc[kk][hh];
1704    //             t_pmt->tdc = (Float_t)tdc[kk][hh];
1705    //             //
1706    //             new(tpmt[npmtentry]) ToFPMT(*t_pmt);
1707    //             npmtentry++;
1708    //             t_pmt->Clear();
1709    //           };
1710    //         };
1711    //       };
1712    //       //
1713    //       // Calculate track-related variables
1714    //       //
1715    //       if ( trk->ntrk() > 0 ){
1716    //         //
1717    //         // We have at least one track
1718    //         //
1719    //         //
1720    //         // Run over tracks
1721    //         //
1722    //         for(Int_t nt=0; nt < trk->ntrk(); nt++){
1723    //           //
1724    //           TrkTrack *ptt = trk->GetStoredTrack(nt);
1725    //           //
1726    //           // Copy the alpha vector in the input structure
1727    //           //
1728    //           for (Int_t e = 0; e < 5 ; e++){
1729    //             tofinput_.al_pp[e] = ptt->al[e];
1730    //           };
1731    //           //
1732    //           // Get tracker related variables for this track
1733    //           //
1734    //           toftrk();
1735    //           //
1736    //           // Copy values in the class from the structure (we need to use a temporary class to store variables).
1737    //           //
1738    //           t_tof->npmttdc = 0;
1739    //           for (Int_t hh=0; hh<12;hh++){
1740    //             for (Int_t kk=0; kk<4;kk++){
1741    //               if ( tofoutput_.tofmask[hh][kk] != 0 ){
1742    //                 pmt_id = this->GetPMTid(kk,hh);
1743    //                 t_tof->pmttdc.AddAt(pmt_id,t_tof->npmttdc);
1744    //                 t_tof->tdcflag.AddAt(tofoutput_.tdcflag[hh][kk],t_tof->npmttdc); // gf: Jan 09/07
1745    //                 t_tof->npmttdc++;
1746    //               };
1747    //             };
1748    //           };
1749    //           for (Int_t kk=0; kk<13;kk++){
1750    //             t_tof->beta[kk] = tofoutput_.beta_a[kk];
1751    //           };
1752    //           //
1753    //           t_tof->npmtadc = 0;
1754    //           for (Int_t hh=0; hh<12;hh++){
1755    //             for (Int_t kk=0; kk<4;kk++){
1756    //               if ( tofoutput_.adc_c[hh][kk] < 1000 ){
1757    //                 t_tof->dedx.AddAt(tofoutput_.adc_c[hh][kk],t_tof->npmtadc);
1758    //                 pmt_id = this->GetPMTid(kk,hh);
1759    //                 t_tof->pmtadc.AddAt(pmt_id,t_tof->npmtadc);
1760    //                 t_tof->adcflag.AddAt(tofoutput_.adcflag[hh][kk],t_tof->npmtadc); // gf: Jan 09/07
1761    //                 t_tof->npmtadc++;
1762    //               };
1763    //             };
1764    //           };
1765    //           //
1766    //           memcpy(t_tof->xtofpos,tofoutput_.xtofpos,sizeof(t_tof->xtofpos));
1767    //           memcpy(t_tof->ytofpos,tofoutput_.ytofpos,sizeof(t_tof->ytofpos));
1768    //           memcpy(t_tof->xtr_tof,tofoutput_.xtr_tof,sizeof(t_tof->xtr_tof));
1769    //           memcpy(t_tof->ytr_tof,tofoutput_.ytr_tof,sizeof(t_tof->ytr_tof));
1770    //           //
1771    //           // Store the tracker track number in order to be sure to have shyncronized data during analysis
1772    //           //
1773    //           t_tof->trkseqno = nt;
1774    //           //
1775    //           // create a new object for this event with track-related variables
1776    //           //
1777    //           new(t[ntrkentry]) ToFTrkVar(*t_tof);
1778    //           ntrkentry++;
1779    //           t_tof->Clear();
1780    //           //
1781    //         }; // loop on all the tracks
1782    //       //
1783    //       this->unpackError = unpackError;
1784    //       if ( defcal ){
1785    //         this->default_calib = 1;
1786    //       } else {
1787    //         this->default_calib = 0;
1788    //       };
1789    //};
1790    //  return(0);
1791    }
1792    
1793    bool ToFLevel2::bit(int decimal, char pos){
1794      return( (decimal>>pos)%2 );
1795    }
1796    
1797    bool ToFLevel2::checkPMT(TString givenpmt){
1798      TClonesArray* Pmt = this->PMT;
1799      //  printf(" ou %s entries %i \n",givenpmt.Data(),Pmt->GetEntries());
1800      for(int i=0; i<Pmt->GetEntries(); i++) {  
1801        ToFPMT* pmthit = (ToFPMT*)Pmt->At(i);
1802        TString pmtname = this->GetPMTName(pmthit->pmt_id);
1803        //    printf(" name %s \n",pmtname.Data());
1804        if ( !strcmp(pmtname.Data(),givenpmt.Data()) )
1805          return true;
1806      }
1807      //  printf(" PMT %s missing \n",givenpmt.Data());
1808      return false;
1809    }
1810    
1811    bool ToFLevel2::checkPMTpatternPMThit(TrigLevel2 *trg, int &pmtpattern, int &pmtnosignal){
1812      UInt_t *patterntrig = trg->patterntrig;
1813      pmtpattern = 0;
1814      pmtnosignal = 0;
1815      bool good = true;
1816      //S3
1817      if ( this->bit(patterntrig[2],0) ){ pmtpattern++;  if ( !this->checkPMT("S31_1A")){ pmtnosignal++; good = false;}}
1818      if ( this->bit(patterntrig[2],1) ){ pmtpattern++;  if ( !this->checkPMT("S31_2A")){ pmtnosignal++; good = false;}}
1819      if ( this->bit(patterntrig[2],2) ){ pmtpattern++;  if ( !this->checkPMT("S31_3A")){ pmtnosignal++; good = false;}}
1820      if ( this->bit(patterntrig[2],3) ){ pmtpattern++;  if ( !this->checkPMT("S31_1B")){ pmtnosignal++; good = false;}}
1821      if ( this->bit(patterntrig[2],4) ){ pmtpattern++;  if ( !this->checkPMT("S31_2B")){ pmtnosignal++; good = false;}}
1822      if ( this->bit(patterntrig[2],5) ){ pmtpattern++;  if ( !this->checkPMT("S31_3B")){ pmtnosignal++; good = false;}}      
1823      if ( this->bit(patterntrig[2],6) ){ pmtpattern++;  if ( !this->checkPMT("S32_1A")){ pmtnosignal++; good = false;}}
1824      if ( this->bit(patterntrig[2],7) ){ pmtpattern++;  if ( !this->checkPMT("S32_2A")){ pmtnosignal++; good = false;}}
1825      if ( this->bit(patterntrig[2],8) ){ pmtpattern++;  if ( !this->checkPMT("S32_3A")){ pmtnosignal++; good = false;}}
1826      if ( this->bit(patterntrig[2],9) ){ pmtpattern++;  if ( !this->checkPMT("S32_1B")){ pmtnosignal++; good = false;}}
1827      if ( this->bit(patterntrig[2],10) ){ pmtpattern++;  if ( !this->checkPMT("S32_2B")){ pmtnosignal++; good = false;}}
1828      if ( this->bit(patterntrig[2],11) ){ pmtpattern++;  if ( !this->checkPMT("S32_3B")){ pmtnosignal++; good = false;}}      
1829      //S2
1830      if ( this->bit(patterntrig[3],0) ){ pmtpattern++;  if ( !this->checkPMT("S21_1A")){ pmtnosignal++; good = false;}}
1831      if ( this->bit(patterntrig[3],1) ){ pmtpattern++;  if ( !this->checkPMT("S21_2A")){ pmtnosignal++; good = false;}}
1832      if ( this->bit(patterntrig[3],2) ){ pmtpattern++;  if ( !this->checkPMT("S21_1B")){ pmtnosignal++; good = false;}}
1833      if ( this->bit(patterntrig[3],3) ){ pmtpattern++;  if ( !this->checkPMT("S21_2B")){ pmtnosignal++; good = false;}}      
1834      if ( this->bit(patterntrig[3],4) ){ pmtpattern++;  if ( !this->checkPMT("S22_1A")){ pmtnosignal++; good = false;}}
1835      if ( this->bit(patterntrig[3],5) ){ pmtpattern++;  if ( !this->checkPMT("S22_2A")){ pmtnosignal++; good = false;}}
1836      if ( this->bit(patterntrig[3],6) ){ pmtpattern++;  if ( !this->checkPMT("S22_1B")){ pmtnosignal++; good = false;}}
1837      if ( this->bit(patterntrig[3],7) ){ pmtpattern++;  if ( !this->checkPMT("S22_2B")){ pmtnosignal++; good = false;}}      
1838      //S12
1839      if ( this->bit(patterntrig[4],0) ){ pmtpattern++;  if ( !this->checkPMT("S12_1A")){ pmtnosignal++; good = false;}}
1840      if ( this->bit(patterntrig[4],1) ){ pmtpattern++;  if ( !this->checkPMT("S12_2A")){ pmtnosignal++; good = false;}}
1841      if ( this->bit(patterntrig[4],2) ){ pmtpattern++;  if ( !this->checkPMT("S12_3A")){ pmtnosignal++; good = false;}}
1842      if ( this->bit(patterntrig[4],3) ){ pmtpattern++;  if ( !this->checkPMT("S12_4A")){ pmtnosignal++; good = false;}}
1843      if ( this->bit(patterntrig[4],4) ){ pmtpattern++;  if ( !this->checkPMT("S12_5A")){ pmtnosignal++; good = false;}}
1844      if ( this->bit(patterntrig[4],5) ){ pmtpattern++;  if ( !this->checkPMT("S12_6A")){ pmtnosignal++; good = false;}}      
1845      if ( this->bit(patterntrig[4],6) ){ pmtpattern++;  if ( !this->checkPMT("S12_1A")){ pmtnosignal++; good = false;}}
1846      if ( this->bit(patterntrig[4],7) ){ pmtpattern++;  if ( !this->checkPMT("S12_2A")){ pmtnosignal++; good = false;}}
1847      if ( this->bit(patterntrig[4],8) ){ pmtpattern++;  if ( !this->checkPMT("S12_3A")){ pmtnosignal++; good = false;}}
1848      if ( this->bit(patterntrig[4],9) ){ pmtpattern++;  if ( !this->checkPMT("S12_4B")){ pmtnosignal++; good = false;}}
1849      if ( this->bit(patterntrig[4],10) ){ pmtpattern++; if ( !this->checkPMT("S12_5B")){ pmtnosignal++; good = false;}}
1850      if ( this->bit(patterntrig[4],11) ){ pmtpattern++; if ( !this->checkPMT("S12_6B")){ pmtnosignal++; good = false;}}      
1851      //S11
1852      if ( this->bit(patterntrig[5],0) ){ pmtpattern++;  if ( !this->checkPMT("S11_1A")){ pmtnosignal++; good = false;}}
1853      if ( this->bit(patterntrig[5],1) ){ pmtpattern++;  if ( !this->checkPMT("S11_2A")){ pmtnosignal++; good = false;}}
1854      if ( this->bit(patterntrig[5],2) ){ pmtpattern++;  if ( !this->checkPMT("S11_3A")){ pmtnosignal++; good = false;}}
1855      if ( this->bit(patterntrig[5],3) ){ pmtpattern++;  if ( !this->checkPMT("S11_4A")){ pmtnosignal++; good = false;}}
1856      if ( this->bit(patterntrig[5],4) ){ pmtpattern++;  if ( !this->checkPMT("S11_5A")){ pmtnosignal++; good = false;}}
1857      if ( this->bit(patterntrig[5],5) ){ pmtpattern++;  if ( !this->checkPMT("S11_6A")){ pmtnosignal++; good = false;}}
1858      if ( this->bit(patterntrig[5],6) ){ pmtpattern++;  if ( !this->checkPMT("S11_7A")){ pmtnosignal++; good = false;}}
1859      if ( this->bit(patterntrig[5],7) ){ pmtpattern++;  if ( !this->checkPMT("S11_8A")){ pmtnosignal++; good = false;}}      
1860      if ( this->bit(patterntrig[5],8) ){ pmtpattern++;  if ( !this->checkPMT("S11_1B")){ pmtnosignal++; good = false;}}
1861      if ( this->bit(patterntrig[5],9) ){ pmtpattern++;  if ( !this->checkPMT("S11_2B")){ pmtnosignal++; good = false;}}
1862      if ( this->bit(patterntrig[5],10) ){ pmtpattern++; if ( !this->checkPMT("S11_3B")){ pmtnosignal++; good = false;}}
1863      if ( this->bit(patterntrig[5],11) ){ pmtpattern++; if ( !this->checkPMT("S11_4B")){ pmtnosignal++; good = false;}}
1864      if ( this->bit(patterntrig[5],12) ){ pmtpattern++; if ( !this->checkPMT("S11_5B")){ pmtnosignal++; good = false;}}
1865      if ( this->bit(patterntrig[5],13) ){ pmtpattern++; if ( !this->checkPMT("S11_6B")){ pmtnosignal++; good = false;}}
1866      if ( this->bit(patterntrig[5],14) ){ pmtpattern++; if ( !this->checkPMT("S11_7B")){ pmtnosignal++; good = false;}}
1867      if ( this->bit(patterntrig[5],15) ){ pmtpattern++; if ( !this->checkPMT("S11_8B")){ pmtnosignal++; good = false;}}
1868    
1869      return good;
1870    }
1871    
1872    bool ToFLevel2::checkPMTpmttrig(TrigLevel2 *trg){
1873      //  UInt_t *patterntrig = trg->patterntrig;
1874      int rS11 = 0;
1875      int rS12 = 0;
1876      int rS21 = 0;
1877      int rS22 = 0;
1878      int rS31 = 0;
1879      int rS32 = 0;
1880    
1881      // trigger configuration for the event from saved pmts
1882      TClonesArray* Pmt = this->PMT;
1883      for(int i=0; i<Pmt->GetEntries(); i++) {  
1884        ToFPMT* pmthit = (ToFPMT*)Pmt->At(i);
1885        TString pmtname = this->GetPMTName(pmthit->pmt_id);
1886        if ( pmtname.Contains("S11") ) rS11++;
1887        if ( pmtname.Contains("S12") ) rS12++;
1888        if ( pmtname.Contains("S21") ) rS21++;
1889        if ( pmtname.Contains("S22") ) rS22++;
1890        if ( pmtname.Contains("S31") ) rS31++;
1891        if ( pmtname.Contains("S32") ) rS32++;
1892      }
1893      int rTOF1 = (rS11 + rS12) * (rS21 + rS22) * (rS31 + rS32);
1894      int rTOF2 = (rS11 * rS12) * (rS21 * rS22) * (rS31 * rS32);
1895    
1896      int rTOF3 = (rS21 + rS22) * (rS31 + rS32);
1897      int rTOF4 = (rS21 * rS22) * (rS31 * rS32);
1898    
1899      int rTOF5 = rS12 * (rS21 * rS22);
1900    
1901      int rTOF6 = (rS11 + rS12) * (rS31 + rS32);
1902      int rTOF7 = (rS11 * rS12) * (rS31 * rS32);
1903    
1904    
1905      // trigger configuration of the run
1906      bool TCTOF1 = false;
1907      bool TCTOF2 = false;
1908      bool TCTOF3 = false;
1909      bool TCTOF4 = false;
1910      bool TCTOF5 = false;
1911      bool TCTOF6 = false;
1912      bool TCTOF7 = false;
1913      if ( trg->trigconf & (1<<0) ) TCTOF1 = true;
1914      if ( trg->trigconf & (1<<1) ) TCTOF2 = true;
1915      if ( trg->trigconf & (1<<2) ) TCTOF3 = true;
1916      if ( trg->trigconf & (1<<3) ) TCTOF4 = true;
1917      if ( trg->trigconf & (1<<4) ) TCTOF5 = true;
1918      if ( trg->trigconf & (1<<5) ) TCTOF6 = true;
1919      if ( trg->trigconf & (1<<6) ) TCTOF7 = true;
1920    
1921      // do patterntrig pmts match the trigger configuration?
1922      bool pmtsconf_trigconf_match = true;
1923      if ( rTOF1 == 0 && TCTOF1 ) pmtsconf_trigconf_match = false;
1924      if ( rTOF2 == 0 && TCTOF2 ) pmtsconf_trigconf_match = false;
1925      if ( rTOF3 == 0 && TCTOF3 ) pmtsconf_trigconf_match = false;
1926      if ( rTOF4 == 0 && TCTOF4 ) pmtsconf_trigconf_match = false;
1927      if ( rTOF5 == 0 && TCTOF5 ) pmtsconf_trigconf_match = false;
1928      if ( rTOF6 == 0 && TCTOF6 ) pmtsconf_trigconf_match = false;
1929      if ( rTOF7 == 0 && TCTOF7 ) pmtsconf_trigconf_match = false;
1930    
1931      return pmtsconf_trigconf_match;
1932    }
1933    
1934    void ToFLevel2::printPMT(){
1935      TClonesArray* Pmt = this->PMT;
1936      for(int i=0; i<Pmt->GetEntries(); i++) {  
1937        ToFPMT* pmthit = (ToFPMT*)Pmt->At(i);
1938        TString pmtname = this->GetPMTName(pmthit->pmt_id);
1939        printf(" PMT hit: %s \n",pmtname.Data());
1940      }
1941    }
1942    
1943    
1944    ToFdEdx::ToFdEdx()
1945    {
1946      memset(conn,0,12*sizeof(Bool_t));
1947      memset(ts,0,12*sizeof(UInt_t));
1948      memset(te,0,12*sizeof(UInt_t));
1949      eDEDXpmt = new TArrayF(48);
1950      Define_PMTsat();
1951      Clear();
1952    }
1953    
1954    ToFdEdx::~ToFdEdx(){
1955      Clear();
1956      Delete();
1957    }
1958    
1959    void ToFdEdx::Delete(Option_t *option){
1960      if ( eDEDXpmt ){
1961        eDEDXpmt->Set(0);
1962        if ( eDEDXpmt) delete eDEDXpmt;
1963      }
1964    }
1965    
1966    //------------------------------------------------------------------------
1967    void ToFdEdx::CheckConnectors(UInt_t atime, GL_PARAM *glparam, TSQLServer *dbc)
1968    {
1969      for(int i=0; i<12; i++){
1970        if(atime<=ts[i] || atime>te[i]){
1971          Int_t error=glparam->Query_GL_PARAM(atime,210+i,dbc); // parameters stored in DB in GL_PRAM table
1972          if ( error<0 ) {
1973            conn[i]=false;
1974            ts[i]=0;
1975            te[i]=numeric_limits<UInt_t>::max();
1976          };
1977          if ( !error ){
1978            conn[i]=true;
1979            ts[i]=glparam->FROM_TIME;
1980            te[i]=glparam->TO_TIME;
1981          }
1982          if ( error>0 ){
1983            conn[i]=false;
1984            ts[i]=glparam->TO_TIME;
1985            TSQLResult *pResult;
1986            TSQLRow *row;
1987            TString query= Form("SELECT FROM_TIME FROM GL_PARAM WHERE TYPE=%i AND FROM_TIME>=%i ORDER BY FROM_TIME ASC LIMIT 1;",210+i,atime);
1988            pResult=dbc->Query(query.Data());
1989            if(!pResult->GetRowCount()){
1990              te[i]=numeric_limits<UInt_t>::max();
1991            }else{
1992              row=pResult->Next();
1993              te[i]=(UInt_t)atoll(row->GetField(0));
1994            }
1995          }
1996          //
1997          
1998      }      }
1999    }    }
2000    
2001    }
2002    //------------------------------------------------------------------------
2003    void ToFdEdx::Clear(Option_t *option)
2004    {
2005      //
2006      // Set arrays and initialize structure
2007      //  eDEDXpmt.Set(48);    eDEDXpmt.Reset(-1);   // Set array size  and reset structure
2008      eDEDXpmt->Set(48);    eDEDXpmt->Reset(-1);   // Set array size  and reset structure
2009      //
2010    };
2011    
2012    //------------------------------------------------------------------------
2013    void ToFdEdx::Print(Option_t *option)
2014    {
2015      //
2016      printf("========================================================================\n");
2017    
2018    };
2019    
2020    //------------------------------------------------------------------------
2021    void ToFdEdx::Init(pamela::tof::TofEvent *tofl0)
2022    {
2023      //
2024      ToFLevel2 tf;
2025      for (Int_t gg=0; gg<4;gg++){
2026        for (Int_t hh=0; hh<12;hh++){
2027          //          tofinput_.tdc[hh][gg]=tofEvent->tdc[gg][hh];          
2028          int mm = tf.GetPMTid(gg,hh);        
2029          adc[mm]= (0xFFF & tofl0->adc[gg][hh]); // EM, exclude warning bits
2030        };      
2031      };
2032      
2033    };
2034    
2035    //------------------------------------------------------------------------
2036    void ToFdEdx::Init(Int_t gg, Int_t hh, Float_t adce)
2037    {
2038      //
2039      ToFLevel2 tf;
2040      //  for (Int_t gg=0; gg<4;gg++){
2041      //    for (Int_t hh=0; hh<12;hh++){
2042      int mm = tf.GetPMTid(gg,hh);    
2043      adc[mm]=adce;
2044      
2045    };
2046    //------------------------------------------------------------------------
2047    void ToFdEdx::Process(UInt_t atime, Float_t betamean, Float_t *xtr_tof, Float_t *ytr_tof, Int_t exitat)
2048    {
2049      bool debug = false;
2050      if ( debug ) printf(" INSIDE TOFDEDX PROCESS \n");
2051      // the parameters should be already initialised by InitPar()
2052      //  printf(" in process \n");
2053      Clear();
2054    
2055     // define angle:  
2056      double dx   = xtr_tof[1] - xtr_tof[5];
2057      double dy   = ytr_tof[0] - ytr_tof[4];
2058      double dr   = sqrt(dx*dx+dy*dy);
2059      double theta=atan(dr/76.81);
2060      //
2061      if ( xtr_tof[1] > 99. ||  xtr_tof[5] > 99. || ytr_tof[0] > 99. ||  ytr_tof[4] > 99. ) theta = 0.;
2062      for (Int_t ii=0; ii<6; ii++){
2063        if ( xtr_tof[ii] > 99. ) xtr_tof[ii] = 0.;
2064        if ( ytr_tof[ii] > 99. ) ytr_tof[ii] = 0.;
2065      };
2066      //
2067      if ( debug ) printf(" theta %f \n",theta);
2068      if ( debug ) printf(" xtr_tof %.1f %.1f %.1f %.1f %.1f %.1f \n",xtr_tof[0],xtr_tof[1],xtr_tof[2],xtr_tof[3],xtr_tof[4],xtr_tof[5]);
2069      if ( debug ) printf(" ytr_tof %.1f %.1f %.1f %.1f %.1f %.1f \n",ytr_tof[0],ytr_tof[1],ytr_tof[2],ytr_tof[3],ytr_tof[4],ytr_tof[5]);
2070      //--------------------- TABLE OF PERIODS WITH HV PROBLEMS ----------------------------
2071      
2072      int Aconn=conn[0];    // PMT 0,20,22,24
2073      int Bconn=conn[1];    // PMT 6,12,26,34
2074      int Cconn=conn[2];    // PMT 4,14,28,32
2075      int Dconn=conn[3];    // PMT 2,8,10,30
2076      int Econn=conn[4];    // PMT 42,43,44,47
2077      int Fconn=conn[5];    // PMT 7,19,23,27
2078      int Gconn=conn[6];    // PMT 3,11,25,33
2079      int Hconn=conn[7];    // PMT 1,9,13,21
2080      int Iconn=conn[8];    // PMT 5,29,31,35
2081      int Lconn=conn[9];    // PMT 37,40,45,46
2082      int Mconn=conn[10];    // PMT 15,16,17,18
2083      int Nconn=conn[11];    // PMT 36,38,39,41
2084      if( false ) cout << Gconn << Iconn << Lconn <<endl; // to avoid compilation warnings
2085        
2086      //  printf(" size %i \n",eDEDXpmt.GetSize());
2087      for( int ii=0; ii<48; ii++ ) {
2088        //
2089        //    eDEDXpmt.SetAt(-1.,ii);
2090        //    printf(" ii %i beta %f atime %u xtr 1 %f ytr 1 %f adc %f \n",ii,betamean,atime,xtr_tof[0],ytr_tof[0],adc[ii]);
2091        if ( debug ) printf("II %i adc %f \n",ii,adc[ii]);
2092    
2093        if( adc[ii] >= 4095. ){
2094          //      eDEDXpmt[ii] = 0.;
2095          eDEDXpmt->AddAt(0.,ii);
2096          if ( debug ) printf(" %i adc>4095 \n",ii);
2097          continue; // EMILIANO
2098        };
2099    
2100        if( adc[ii] >= (PMTsat[ii]-5.) && adc[ii] < 4095. ){
2101          eDEDXpmt->AddAt(1000.,ii);
2102          if ( debug ) printf(" %i adc> pmtsat && adc<4095 \n",ii);
2103          continue; // EMILIANO
2104        };
2105    
2106        if( adc[ii] <= 0. ) {
2107          eDEDXpmt->AddAt(1500.,ii);
2108          if ( debug ) printf(" %i adc<=0 \n",ii);
2109          continue;
2110        };
2111        //
2112        double adcpC   = f_adcPC( adc[ii] );    // - adc conversion in pC
2113        if ( exitat == 0 ){
2114          eDEDXpmt->AddAt((Float_t)adcpC,ii);
2115          continue;
2116        }
2117        //    printf(" e qua? \n");
2118    
2119        double adccorr = adcpC*fabs(cos(theta));    
2120        if ( debug ) printf(" adccorr %f \n",adccorr);
2121        if(adccorr<=0.){
2122          if ( debug ) printf(" %i adccorr<=0 \n",ii);
2123          //      eDEDXpmt->AddAt((Float_t)adcpC,ii);//?
2124          continue;
2125        }
2126        if ( exitat == 1 ){
2127          eDEDXpmt->AddAt((Float_t)adccorr,ii);
2128          continue;
2129        }
2130        //    printf(" e quo? \n");
2131    
2132        //    int standard=0;
2133        int S115B_ok=0;
2134        int S115B_break=0;
2135    
2136        if(atime<1158720000)S115B_ok=1;
2137        else S115B_break=1;
2138    
2139    
2140        //------------------------------------------------------------------------
2141        //    printf(" e qui? \n");
2142        //---------------------------------------------------- Z reconstruction
2143    
2144        double adcHe, adcnorm, adclin, dEdx;//, Zeta; // EM GCC4.7
2145    
2146        adcHe=-2;
2147        adcnorm=-2;
2148        adclin=-2;
2149        dEdx=-2;
2150        //    Zeta=-2;//EM GCC4.7
2151        Double_t correction = 1.;
2152    
2153        if(Aconn==1 && (ii==0 || ii==20 || ii==22 || ii==24)){
2154          correction = 1.675;
2155        }
2156        else if(Bconn==1 && (ii==6 || ii==12 || ii==26 || ii==34)){
2157          correction = 2.482;
2158        }
2159        else if(Cconn==1 && (ii==4 || ii==14 || ii==28 || ii==32)){
2160          correction = 1.464;
2161        }
2162        else if(Dconn==1 && (ii==2 || ii==8 || ii==10 || ii==30)){
2163          correction = 1.995;
2164        }
2165        else if(Econn==1 && (ii==42 || ii==43 || ii==44 || ii==47)){
2166          correction = 1.273;
2167        }
2168        else if(Fconn==1 && (ii==7 || ii==19 || ii==23 || ii==27)){
2169          correction = 1.565;
2170        }
2171        else if(Mconn==1 && (ii==15 || ii==16 || ii==17 || ii==18)){
2172          correction = 1.565;
2173        }
2174        else if(Nconn==1 && (ii==36 || ii==38 || ii==39 || ii==41)){
2175          correction = 1.018;
2176        }
2177        else if(Hconn==1 && (ii==1 || ii==13 || ii==21 || (ii==9&&S115B_ok==1))){
2178          correction = 1.84;
2179        }
2180        else if(S115B_break==1 && ii==9 && Hconn==1){
2181          correction = 1.64;
2182        }
2183        else correction = 1.;
2184        
2185        if( ii==9 && S115B_break==1 ){
2186          adcHe   = f_att5B( ytr_tof[0] )/correction;
2187        } else {
2188          adcHe   = Get_adc_he(ii, xtr_tof, ytr_tof)/correction;
2189        };
2190        if(adcHe<=0){
2191          if ( debug ) printf(" %i adcHe<=0 \n",ii);
2192          //      eDEDXpmt->AddAt((Float_t)adccorr,ii); //?
2193          continue;
2194        }
2195        if ( exitat == 2 ){
2196          if(ii==9 && S115B_break==1)  eDEDXpmt->AddAt(36.*(Float_t)adccorr/adcHe,ii);
2197          else  adclin  = 4.*(Float_t)adccorr/adcHe;
2198          continue;
2199        }
2200    
2201        if(ii==9 && S115B_break==1)  adcnorm = f_pos5B(adccorr);
2202        else adcnorm = f_pos( (parPos[ii]), adccorr);
2203        if(adcnorm<=0){
2204          if ( debug ) printf(" %i adcnorm<=0 \n",ii);
2205          //      eDEDXpmt->AddAt((Float_t)adccorr,ii);//?
2206          continue;
2207        }
2208        if ( debug ) printf(" adcnorm %f \n",adcnorm);
2209    
2210        if(ii==9 && S115B_break==1)  adclin  = 36.*adcnorm/adcHe;
2211        else  adclin  = 4.*adcnorm/adcHe;
2212        if ( debug ) printf(" adclin %f \n",adclin);
2213        if(adclin<=0){
2214          if ( debug ) printf(" %i adclin<=0 \n",ii);
2215          //      eDEDXpmt->AddAt((Float_t)adccorr,ii);//?
2216          continue;
2217        }
2218        if ( exitat == 3 ){
2219          if(ii==9 && S115B_break==1)  eDEDXpmt->AddAt((Float_t)adclin,ii);
2220          else  eDEDXpmt->AddAt((Float_t)adclin,ii);
2221          continue;
2222        }
2223        //
2224        if ( betamean > 99. ){
2225          //      eDEDXpmt.AddAt((Float_t)adclin,ii);
2226          eDEDXpmt->AddAt((Float_t)adclin,ii);
2227          //      printf(" AAPMT IS %i dedx is %f vector is %f \n",ii,adclin,eDEDXpmt[ii]);
2228          if ( debug ) printf(" %i betamean > 99 \n",ii);
2229          continue;
2230        };
2231        //
2232        double dEdxHe=-2;
2233        if(ii==9 && S115B_break==1){
2234          if( betamean <1. ) dEdxHe = f_BB5B( betamean );
2235          else                       dEdxHe = 33;
2236        } else {
2237          if( betamean <1. ) dEdxHe = f_BB( (parBBneg[ii]), betamean );
2238          else                       dEdxHe = parBBpos[ii];
2239        }
2240            
2241    l2->npmt = PMT->GetEntries();      if ( debug ) printf(" dEdxHe %f \n",dEdxHe);
2242     for(Int_t j=0;j<l2->npmt;j++){      
2243       l2->pmt_id[j] = ((ToFPMT*)PMT->At(j))->pmt_id;      if(dEdxHe<=0){
2244       l2->adc[j] =((ToFPMT*)PMT->At(j))->adc;        eDEDXpmt->AddAt((Float_t)adclin,ii);
2245       l2->tdc_tw[j] =((ToFPMT*)PMT->At(j))->tdc_tw;        if ( debug ) printf(" %i dEdxHe<=0 \n",ii);
2246     }        continue;
2247        };
2248    
2249        if(ii==9 && S115B_break==1)  dEdx = f_desatBB5B( adclin );
2250        else  dEdx = f_desatBB((parDesatBB[ii]), adclin );
2251    
2252        if(dEdx<=0){
2253          eDEDXpmt->AddAt((Float_t)adclin,ii);
2254          if ( debug ) printf(" %i dEdx<=0 \n",ii);
2255          continue;
2256        };
2257    
2258        if ( debug ) printf(" dEdx %f \n",dEdx);
2259        eDEDXpmt->AddAt((Float_t)dEdx,ii);
2260        //    eDEDXpmt.AddAt((Float_t)dEdx,ii);
2261    
2262        //    printf(" PMT IS %i dedx is %f vector is %f \n",ii,dEdx,eDEDXpmt[ii]);
2263    
2264      }  //end loop on 48 PMT
2265    
2266    };
2267    
2268    
2269    //------------------------------------------------------------------------
2270    void ToFdEdx::Define_PMTsat()
2271    {
2272      Float_t  sat[48] = {
2273        3176.35,3178.19,3167.38,3099.73,3117.00,3126.29,3111.44,3092.27,
2274        3146.48,3094.41,3132.13,3115.37,3099.32,3110.97,3111.80,3143.14,
2275        3106.72,3153.44,3136.00,3188.96,3104.73,3140.45,3073.18,3106.62,
2276        3112.48,3146.92,3127.24,3136.52,3109.59,3112.89,3045.15,3147.26,
2277        3095.92,3121.05,3083.25,3123.62,3150.92,3125.30,3067.60,3160.18,
2278        3119.36,3108.92,3164.77,3133.64,3111.47,3131.98,3128.87,3135.56 };
2279      PMTsat.Set(48,sat);
2280    }
2281    
2282    //------------------------------------------------------------------------
2283    void ToFdEdx::ReadParBBpos( const char *fname )
2284    {
2285      //  printf("read %s\n",fname);
2286      parBBpos.Set(48);
2287      FILE *fattin = fopen( fname , "r" );
2288      for (int i=0; i<48; i++) {
2289        int   tid=0;
2290        float  tp;
2291        if(fscanf(fattin,"%d %f",
2292                  &tid, &tp )!=2) break;
2293        parBBpos[i]=tp;
2294      }
2295      fclose(fattin);
2296    }
2297    
2298    //------------------------------------------------------------------------
2299    void ToFdEdx::ReadParDesatBB( const char *fname )
2300    {
2301      //  printf("read %s\n",fname);
2302      FILE *fattin = fopen( fname , "r" );
2303      for (int i=0; i<48; i++) {
2304        int   tid=0;
2305        float  tp[3];
2306        if(fscanf(fattin,"%d %f %f %f",
2307                  &tid, &tp[0], &tp[1], &tp[2] )!=4) break;
2308        parDesatBB[i].Set(3,tp);
2309      }
2310      fclose(fattin);
2311    }
2312    
2313    
2314    //------------------------------------------------------------------------
2315    void ToFdEdx::ReadParBBneg( const char *fname )
2316    
2317    {
2318      //  printf("read %s\n",fname);
2319      FILE *fattin = fopen( fname , "r" );
2320      for (int i=0; i<48; i++) {
2321        int   tid=0;
2322        float  tp[3];
2323        if(fscanf(fattin,"%d %f %f %f",
2324                  &tid, &tp[0], &tp[1], &tp[2] )!=4) break;
2325        parBBneg[i].Set(3,tp);
2326      }
2327      fclose(fattin);
2328    }
2329    
2330    //------------------------------------------------------------------------
2331    void ToFdEdx::ReadParPos( const char *fname )
2332    {
2333      //  printf("read %s\n",fname);
2334      FILE *fattin = fopen( fname , "r" );
2335      for (int i=0; i<48; i++) {
2336        int   tid=0;
2337        float  tp[4];
2338        if(fscanf(fattin,"%d %f %f %f %f",
2339                  &tid, &tp[0], &tp[1], &tp[2], &tp[3])!=5) break;
2340        parPos[i].Set(4,tp);
2341      }
2342      fclose(fattin);
2343  }  }
2344    
2345    //------------------------------------------------------------------------
2346    void ToFdEdx::ReadParAtt( const char *fname )
2347    {
2348      //  printf("read %s\n",fname);
2349      FILE *fattin = fopen( fname , "r" );
2350      for (int i=0; i<48; i++) {
2351        int   tid=0;
2352        float  tp[6];
2353        if(fscanf(fattin,"%d %f %f %f %f %f %f",
2354                  &tid, &tp[0], &tp[1], &tp[2], &tp[3], &tp[4], &tp[5] )!=7) break;
2355        parAtt[i].Set(6,tp);
2356      }
2357      fclose(fattin);
2358    }
2359    
2360    
2361    
2362    
2363    
2364    
2365    double ToFdEdx::f_att( TArrayF &p, float x )
2366    {
2367      return
2368        p[0] +
2369        p[1]*x +
2370        p[2]*x*x +
2371        p[3]*x*x*x +
2372        p[4]*x*x*x*x +
2373        p[5]*x*x*x*x*x;
2374    }
2375    //------------------------------------------------------------------------
2376    double ToFdEdx::f_att5B( float x )
2377    {
2378      return
2379        101.9409 +
2380        6.643781*x +
2381        0.2765518*x*x +
2382        0.004617647*x*x*x +
2383        0.0006195132*x*x*x*x +
2384        0.00002813734*x*x*x*x*x;
2385    }
2386    
2387    
2388    double ToFdEdx::f_pos( TArrayF &p, float x )
2389    {
2390      return
2391        p[0] +
2392        p[1]*x +
2393        p[2]*x*x +
2394        p[3]*x*x*x;
2395    }
2396    
2397    double ToFdEdx::f_pos5B( float x )
2398    {
2399      return
2400        15.45132 +
2401        0.8369721*x +
2402        0.0005*x*x;
2403    }
2404    
2405    
2406    
2407    double ToFdEdx::f_adcPC( float x )
2408    {
2409      return 28.12+0.6312*x-5.647e-05*x*x+3.064e-08*x*x*x;
2410    }
2411    
2412    
2413    float ToFdEdx::Get_adc_he( int id, float pl_x[6], float pl_y[6])
2414    {
2415    
2416      //
2417      // input: id - pmt [0:47}
2418      //             pl_x - coord x of the tof plane
2419      //             pl_y - coord y
2420    
2421      adc_he = 0;
2422      if( eGeom.GetXY(id)==1 )  adc_he = f_att( (parAtt[id]), pl_x[eGeom.GetPlane(id)] );
2423      if( eGeom.GetXY(id)==2 )  adc_he = f_att( (parAtt[id]), pl_y[eGeom.GetPlane(id)] );
2424      return adc_he;
2425    }
2426    
2427    //------------------------------------------------------------------------
2428    double ToFdEdx::f_BB( TArrayF &p, float x )
2429    {
2430      return  p[0]/(x*x)*(log(x*x/(1-x*x)) - p[1]*x*x - p[2]);
2431    }
2432    
2433    //------------------------------------------------------------------------
2434    double ToFdEdx::f_BB5B( float x )
2435    {
2436      return  0.165797/(x*x)*(log(x*x/(1-x*x)) + 140.481*x*x + 52.9258);
2437    }
2438    //------------------------------------------------------------------------
2439    double ToFdEdx::f_desatBB( TArrayF &p, float x )
2440    {
2441      return
2442        p[0] +
2443        p[1]*x +
2444        p[2]*x*x;
2445    }
2446    
2447    //------------------------------------------------------------------------
2448    double ToFdEdx::f_desatBB5B( float x )
2449    {
2450      return
2451        -2.4 +
2452        0.75*x +
2453        0.009*x*x;
2454    }
2455    

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