/[PAMELA software]/DarthVader/ToFLevel2/src/ToFLevel2.cpp
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revision 1.9 by mocchiut, Thu Nov 30 15:44:55 2006 UTC revision 1.44 by mocchiut, Thu Feb 26 14:35:01 2015 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 40  ToFTrkVar::ToFTrkVar() { Line 55  ToFTrkVar::ToFTrkVar() {
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;
# Line 56  void ToFTrkVar::Clear() { Line 73  void ToFTrkVar::Clear() {
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 74  ToFTrkVar::ToFTrkVar(const ToFTrkVar &t) Line 93  ToFTrkVar::ToFTrkVar(const ToFTrkVar &t)
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    //
118    //
119    //--------------------------------------
120    void ToFLevel2::SetTrackArray(TClonesArray *track){//ELENA
121        if(track && strcmp(track->GetClass()->GetName(),"ToFTrkVar")==0){
122            if(ToFTrk)ToFTrk->Clear("C");
123            ToFTrk = track;
124        }
125    }
126    
127    void ToFLevel2::Clear(Option_t *t){
128    //    //
129    ToFTrk->Clear();    if(ToFTrk)ToFTrk->Delete(); //ELENA
130    PMT->Clear();    if(PMT)PMT->Delete(); //ELENA
131    memset(tof_j_flag, 0, 6*sizeof(Int_t));    memset(tof_j_flag, 0, 6*sizeof(Int_t));
132    unpackError = 0;    unpackError = 0;
133      unpackWarning = 0;
134    //    //
135  };  };
136    
137    void ToFLevel2::Delete(Option_t *t){ //ELENA
138      //
139      if(ToFTrk){
140          ToFTrk->Delete(); //ELENA
141          delete ToFTrk;  //ELENA
142      }
143      if(PMT){
144          PMT->Delete(); //ELENA
145          delete PMT; //ELENA
146      } //ELENA
147      //
148    }; //ELENA
149    
150  ToFTrkVar *ToFLevel2::GetToFTrkVar(Int_t itrk){  ToFTrkVar *ToFLevel2::GetToFTrkVar(Int_t itrk){
151    //        //    
152    if(itrk >= ntrk()){    if(itrk >= ntrk()){
# Line 103  ToFTrkVar *ToFLevel2::GetToFTrkVar(Int_t Line 155  ToFTrkVar *ToFLevel2::GetToFTrkVar(Int_t
155      return(NULL);      return(NULL);
156    }      }  
157    //    //
158      if(!ToFTrk)return 0; //ELENA
159    TClonesArray &t = *(ToFTrk);    TClonesArray &t = *(ToFTrk);
160    ToFTrkVar *toftrack = (ToFTrkVar*)t[itrk];    ToFTrkVar *toftrack = (ToFTrkVar*)t[itrk];
161    return toftrack;    return toftrack;
162  }  }
163    
164    /**
165     * Retrieves the tof track matching the seqno-th tracker stored track.
166     *
167     */
168    ToFTrkVar *ToFLevel2::GetToFStoredTrack(int seqno){
169    
170      if( ntrk()==0 ){
171        printf("ToFLevel2::GetToFStoredTrack(int) : requested tracker SeqNo %i but no ToFrimeter tracks are stored\n",seqno);
172        return NULL;
173      };
174      
175      ToFTrkVar *c = 0;
176      Int_t it_tof=0;
177        
178      do {
179        c = GetToFTrkVar(it_tof);
180        it_tof++;
181      } while( c && seqno != c->trkseqno && it_tof < ntrk());      
182      
183      if(!c || seqno != c->trkseqno){
184        c = 0;
185        if(seqno!=-1 ) printf("ToFLevel2::GetToFStoredTrack(int) : requested tracker SeqNo %i does not match ToFrimeter stored tracks\n",seqno);
186      };
187      return c;
188        
189    }
190    
191    
192  ToFPMT *ToFLevel2::GetToFPMT(Int_t ihit){  ToFPMT *ToFLevel2::GetToFPMT(Int_t ihit){
193    //        //    
194    if(ihit >= npmt()){    if(ihit >= npmt()){
# Line 116  ToFPMT *ToFLevel2::GetToFPMT(Int_t ihit) Line 197  ToFPMT *ToFLevel2::GetToFPMT(Int_t ihit)
197      return(NULL);      return(NULL);
198    }      }  
199    //    //
200      if(!PMT)return 0; //ELENA
201    TClonesArray &t = *(PMT);    TClonesArray &t = *(PMT);
202    ToFPMT *tofpmt = (ToFPMT*)t[ihit];    ToFPMT *tofpmt = (ToFPMT*)t[ihit];
203    return tofpmt;    return tofpmt;
# Line 126  ToFPMT *ToFLevel2::GetToFPMT(Int_t ihit) Line 208  ToFPMT *ToFLevel2::GetToFPMT(Int_t ihit)
208  //--------------------------------------  //--------------------------------------
209  /**  /**
210   * 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)
211     * @param Plane index (0,1,2,3,4,5).
212   */   */
213    Int_t  ToFLevel2::GetToFPlaneID(Int_t ip){    Int_t  ToFLevel2::GetToFPlaneID(Int_t ip){
214        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 133  ToFPMT *ToFLevel2::GetToFPMT(Int_t ihit) Line 216  ToFPMT *ToFLevel2::GetToFPMT(Int_t ihit)
216    };    };
217  /**  /**
218   * 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)
219     * @param plane Plane ID (11, 12, 21, 22, 31, 32)
220   */   */
221    Int_t  ToFLevel2::GetToFPlaneIndex(Int_t plane_id){    Int_t  ToFLevel2::GetToFPlaneIndex(Int_t plane_id){
222        if(        if(
# Line 146  ToFPMT *ToFLevel2::GetToFPMT(Int_t ihit) Line 230  ToFPMT *ToFLevel2::GetToFPMT(Int_t ihit)
230        else return -1;        else return -1;
231    };    };
232  /**  /**
233   * 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
234     * from both PMTs. The method uses the "tof_j_flag" variable.
235   * @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).
236   * @param paddle_id Paddle ID.   * @param paddle_id Paddle ID.
237   * @return 1 if the paddle was hit.   * @return 1 if the paddle was hit.
# Line 167  ToFPMT *ToFLevel2::GetToFPMT(Int_t ihit) Line 252  ToFPMT *ToFLevel2::GetToFPMT(Int_t ihit)
252         false) return true;         false) return true;
253      else return false;      else return false;
254  };  };
255    
256  /**  /**
257   * Method to get the number of hit paddles on a ToF plane.   * Strict method to get the number of hit paddles on a ToF plane.
258     * The method uses "HitPaddle" which checks if there is a TDC signal
259     * from both PMTs.
260   * @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).
261   */   */
262  Int_t ToFLevel2::GetNHitPaddles(Int_t plane){  Int_t ToFLevel2::GetNHitPaddles(Int_t plane){
# Line 177  Int_t ToFLevel2::GetNHitPaddles(Int_t pl Line 265  Int_t ToFLevel2::GetNHitPaddles(Int_t pl
265      return npad;      return npad;
266  };  };
267    
268    /**
269     * Optional method to get the number of hit paddles on a ToF plane.
270     * The method does NOT check if there is a signal from both PMTs, it only
271     * checks if there is some PMT signal in a paddle
272     * @param plane Plane ID (11, 12, 21, 22, 31, 32) or Plane index (0,1,2,3,4,5).
273     */
274    Int_t ToFLevel2::GetTrueNHitPaddles(Int_t plane){
275        Int_t npad=0;
276        TClonesArray* Pmt = this->PMT;
277        int paddle[24];
278        memset(paddle,0, 24*sizeof(int));
279        for(int i=0; i<Pmt->GetEntries(); i++) {  //loop per vedere quale TOF è colpito
280          ToFPMT* pmthit = (ToFPMT*)Pmt->At(i);
281          int pplane = -1;
282          int ppaddle = -1;
283          GetPMTPaddle(pmthit->pmt_id,pplane,ppaddle);
284          if ( pplane == plane ) paddle[ppaddle]++;
285        }
286        for(int i=0;i<24;i++) if ( paddle[i]>0 ) npad++;
287    
288        return npad;
289    };
290    
291    //new, wm Feb 15
292    //wm Nov 08
293    //gf Apr 07
294    /**
295     * Method to get the mean dEdx from a ToF layer
296     * By definition there should be PMTs with dEdx values only in one paddle of a layer
297     * (the paddle hitted by the track), this method looks for the hitted paddle
298     * and gives the mean dEdx of that paddle as the output
299     * The method was modified for the "ToF-standalone" part in february 2015
300     * The "adcfl" option is not very useful (an artificial dEdx is per
301     * definition= 1 mip and not a real measurement), anyway left in the code
302     * @param notrack Track Number
303     * @param plane Plane index (0,1,2,3,4,5)
304     * @param adcflag in the plane (100<-> independent of the adcflag; !=0&&!=100 <-> at least one PMT with adcflag!=0; )
305     */
306    Float_t ToFLevel2::GetdEdx(Int_t notrack, Int_t plane, Int_t adcfl){
307      ToFTrkVar *trk = GetToFTrkVar(notrack);
308      return this->GetdEdx(trk, plane, adcfl);
309    }
310    
311  Float_t ToFLevel2::GetdEdx(Int_t notrack, Int_t plane){  //new, wm Feb 15
312    //wm Nov 08
313    //gf Apr 07
314    /**
315     * Method to get the mean dEdx from a ToF layer
316     * By definition there should be PMTs with dEdx values only in one paddle of a layer
317     * (the paddle hitted by the track), this method looks for the hitted paddle
318     * and gives the mean dEdx of that paddle as the output
319     * The method was modified for the "ToF-standalone" part in february 2015
320     * The "adcfl" option is not very useful (an artificial dEdx is per
321     * definition= 1 mip and not a real measurement), anyway left in the code
322     * @param trk Pointer to TofTrkVar class
323     * @param plane Plane index (0,1,2,3,4,5)
324     * @param adcflag in the plane (100<-> independent of the adcflag; !=0&&!=100 <-> at least one PMT with adcflag!=0; )
325     */
326    Float_t ToFLevel2::GetdEdx(ToFTrkVar *trk, Int_t plane, Int_t adcfl){
327      
328    Float_t dedx = 0.;    Float_t dedx = 0.;
329    Int_t ip = 0;    Float_t PadEdx =0.;
330    Int_t pmt_id = 0;    Int_t SatWarning;
331    Int_t pl = 0;    Int_t pad=-1;
   if ( plane >= 6 ){  
     ip = GetToFPlaneIndex(plane);  
   } else {  
     ip = plane;  
   };  
332    //    //
333    ToFTrkVar *trk = GetToFTrkVar(notrack);    if(!trk) return 0; //ELENA
334    //    //
335    for (Int_t i=0; i<trk->npmtadc; i++){    // ToF standalone part
     //  
     pmt_id = (trk->pmtadc).At(i);  
     //  
     pl = GetPlaneIndex(pmt_id);  
     //  
     if ( pl == ip ) dedx += (trk->dedx).At(i);    
     //  
   };  
336    //    //
337      if ( trk->trkseqno == -1 ){
338        
339        //    ToFTrkVar *t_tof = trk;
340        
341        // Find the hitted paddle  (two good TDC values) using the tof_j_flag (from tofl2com.for)
342        
343        Int_t Ipaddle=-1;
344        // if tof_j_flag == 0: no paddle was hitted. Otherwise decode tof_j_flag to get the paddle
345        if (this->tof_j_flag[plane] > 0)  Ipaddle = (Int_t)log2(this->tof_j_flag[plane]) ;
346        
347        Ipaddle =  (Int_t)log2(this->tof_j_flag[plane]) ;
348        
349        // Get the dEdx of this paddle using "GetdEdxPaddle"
350        if (Ipaddle>-1) {
351          Int_t pad = GetPaddleid(plane,Ipaddle);
352          GetdEdxPaddle(trk, pad, adcfl, PadEdx, SatWarning);
353          dedx = PadEdx;
354        }
355        
356        // If there was no correct hitted paddle, but there was one (and only one) paddle with some
357        // PMT entries in the PMT-class (found with "GetTrueNHitPaddles", use the dEdx of this paddle
358        
359        if ((Ipaddle<0) && (GetTrueNHitPaddles(plane)==1)) {
360          // find the paddle by looping over the paddles in each layer
361          // since GetTrueNHitPaddles==1 this is OK
362          for (Int_t ii=0; ii<GetNPaddle(plane); ii++){
363            Int_t paddleid=ii;
364            Int_t pad = GetPaddleid(plane,paddleid);
365            GetdEdxPaddle(trk, pad, adcfl, PadEdx, SatWarning);
366            dedx += PadEdx;
367          }
368        }
369      } else {
370        // track dependent dEdx: simple, there will be only one paddle hitted in    each layer
371        // so just loop over the paddles in each layer
372        for (Int_t ii=0; ii<GetNPaddle(plane); ii++){
373          Int_t paddleid=ii;
374          pad = GetPaddleid(plane,paddleid);
375          GetdEdxPaddle(trk, pad, adcfl, PadEdx, SatWarning);
376          dedx += PadEdx;
377        }
378      }
379      //
380    return(dedx);    return(dedx);
381  };  }
   
382    
383    /**
384     * Method to fill the ADC_C 4x12 matrix with the dEdx values and the TDC 4x12 matrix
385     * with the time-walk corrected TDC values.
386     * @param notrack Track Number
387     * @param adc  ADC_C matrix with dEdx values
388     * @param tdc  TDC matrix
389     */
390  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]){
391    //    //
392    for (Int_t aa=0; aa<4;aa++){    for (Int_t aa=0; aa<4;aa++){
# Line 219  void ToFLevel2::GetMatrix(Int_t notrack, Line 401  void ToFLevel2::GetMatrix(Int_t notrack,
401    Int_t kk = 0;    Int_t kk = 0;
402    //    //
403    ToFTrkVar *trk = GetToFTrkVar(notrack);    ToFTrkVar *trk = GetToFTrkVar(notrack);
404      if(!trk)return; //ELENA
405    //    //
406    for (Int_t i=0; i<trk->npmtadc; i++){    for (Int_t i=0; i<trk->npmtadc; i++){
407      //      //
# Line 232  void ToFLevel2::GetMatrix(Int_t notrack, Line 415  void ToFLevel2::GetMatrix(Int_t notrack,
415    for (Int_t i=0; i<npmt(); i++){    for (Int_t i=0; i<npmt(); i++){
416      //      //
417      ToFPMT *pmt = GetToFPMT(i);      ToFPMT *pmt = GetToFPMT(i);
418        if(!pmt)break; //ELENA
419      //      //
420      GetPMTIndex(pmt->pmt_id,hh,kk);      GetPMTIndex(pmt->pmt_id,hh,kk);
421      //      //
# Line 243  void ToFLevel2::GetMatrix(Int_t notrack, Line 427  void ToFLevel2::GetMatrix(Int_t notrack,
427  };  };
428    
429    
430    /**
431     * Method to get the plane index (0 - 5) for the PMT_ID as input
432     * @param pmt_id  PMT_ID (0 - 47)
433     */
434  Int_t ToFLevel2::GetPlaneIndex(Int_t pmt_id){  Int_t ToFLevel2::GetPlaneIndex(Int_t pmt_id){
435    TString pmtname = GetPMTName(pmt_id);    TString pmtname = GetPMTName(pmt_id);
436    pmtname.Resize(3);    pmtname.Resize(3);
# Line 257  Int_t ToFLevel2::GetPlaneIndex(Int_t pmt Line 444  Int_t ToFLevel2::GetPlaneIndex(Int_t pmt
444  };  };
445    
446    
447    /**
448     * Method to get the PMT_ID if the index (4,12) is given. We have 4 channels on
449     * each of the 12 half-boards, this method decodes which PMT is cables to which
450     * channel.
451     * @param hh Channel
452     * @param kk HalfBoard
453     */
454  Int_t ToFLevel2::GetPMTid(Int_t hh, Int_t kk){  Int_t ToFLevel2::GetPMTid(Int_t hh, Int_t kk){
455    //    //
456    short tof[4][24] = {    short tof[4][24] = {
# Line 285  Int_t ToFLevel2::GetPMTid(Int_t hh, Int_ Line 479  Int_t ToFLevel2::GetPMTid(Int_t hh, Int_
479    return ind;    return ind;
480  };  };
481    
 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;  
 };  
   
482    
483    /**
484     * Method to get the PMT index if the PMT ID is given. This method is the
485     * "reverse" of method "GetPMTid"
486     * @param ind  PMT_ID (0 - 47)
487     * @param hb   HalfBoard
488     * @param ch   Channel
489     */
490  void ToFLevel2::GetPMTIndex(Int_t ind, Int_t &hb, Int_t &ch){  void ToFLevel2::GetPMTIndex(Int_t ind, Int_t &hb, Int_t &ch){
491    //    //
492    short tof[4][24] = {    short tof[4][24] = {
# Line 332  void ToFLevel2::GetPMTIndex(Int_t ind, I Line 513  void ToFLevel2::GetPMTIndex(Int_t ind, I
513    return;    return;
514  };  };
515    
516    
517    
518    //  wm Nov 08 revision - saturation values included
519    /// gf Apr 07
520    /**
521     * Method to get the dEdx from a given ToF paddle.
522     * If two PMTs are good, the mean dEdx of both PMTs is taken, otherwise
523     * just the dEdx of the "good" PMT. If both PMTs are above saturation => dEdx=1000
524     * @param notrack Track Number
525     * @param Paddle index (0,1,...,23).
526     * @param adcflag in the paddle (100<-> independent of the adcflag; !=0&&!=100 <-> at least one PMT with adcflag!=0; )
527     * @param PadEdx dEdx from a given ToF paddle
528     * @param SatWarning 1 if the PMT ios near saturation region (adcraw ~3000)
529     */
530    void ToFLevel2::GetdEdxPaddle(Int_t notrack, Int_t paddleid, Int_t adcfl, Float_t &PadEdx, Int_t &SatWarning){
531    
532      ToFTrkVar *trk = GetToFTrkVar(notrack);
533      this->GetdEdxPaddle(trk, paddleid, adcfl, PadEdx, SatWarning);
534      
535    };
536    
537    //
538    //  wm Nov 08 revision - saturation values included
539    /// gf Apr 07
540    /**
541     * Method to get the dEdx from a given ToF paddle.
542     * If two PMTs are good, the mean dEdx of both PMTs is taken, otherwise
543     * just the dEdx of the "good" PMT. If both PMTs are above saturation => dEdx=1000
544     * @param notrack Track Number
545     * @param Paddle index (0,1,...,23).
546     * @param adcflag in the paddle (100<-> independent of the adcflag; !=0&&!=100 <-> at least one PMT with adcflag!=0; )
547     * @param PadEdx dEdx from a given ToF paddle
548     * @param SatWarning 1 if the PMT ios near saturation region (adcraw ~3000)
549     */
550    void ToFLevel2::GetdEdxPaddle(ToFTrkVar *trk, Int_t paddleid, Int_t adcfl, Float_t &PadEdx, Int_t &SatWarning){
551    
552      /*
553        Float_t  PMTsat[48] = {
554        3162.14, 3165.48, 3153.85, 3085.73, 3089.65, 3107.64, 3097.52, 3078.37,
555        3130.05, 3087.07, 3112.22, 3102.92, 3080.58, 3092.55, 3087.94, 3125.03,
556        3094.09, 3143.16, 3125.51, 3181.27, 3092.09, 3124.98, 3069.3, 3095.53,
557        3097.11, 3133.53, 3114.73, 3113.01, 3091.19, 3097.99, 3033.84, 3134.98,
558        3081.37, 3111.04, 3066.77, 3108.17, 3133, 3111.06, 3052.52, 3140.66,
559        3106.33, 3094.85, 3150.85, 3118.8, 3096.24, 3118.47,3111.36, 3117.11 } ;
560      */
561    
562      // new values from Napoli dec 2008
563      Float_t  PMTsat[48] = {
564        3176.35,3178.19,3167.38,3099.73,3117.00,3126.29,3111.44,3092.27,
565        3146.48,3094.41,3132.13,3115.37,3099.32,3110.97,3111.80,3143.14,
566        3106.72,3153.44,3136.00,3188.96,3104.73,3140.45,3073.18,3106.62,
567        3112.48,3146.92,3127.24,3136.52,3109.59,3112.89,3045.15,3147.26,
568        3095.92,3121.05,3083.25,3123.62,3150.92,3125.30,3067.60,3160.18,
569        3119.36,3108.92,3164.77,3133.64,3111.47,3131.98,3128.87,3135.56 };
570    
571      for (Int_t i=0; i<48;i++) PMTsat[i] = PMTsat[i] - 5.;  // safety margin
572    
573    
574      PadEdx = 0.;
575      //  SatWarning = 1000;
576      SatWarning = 0;   // 0=good, increase for each bad PMT
577    
578      Float_t dEdx[48] = {0};
579      Int_t pmt_id = -1;
580      Float_t adcraw[48];
581      //
582      if(!trk) return; //ELENA
583      //
584    
585      Int_t pmtleft=-1;
586      Int_t pmtright=-1;
587      GetPaddlePMT(paddleid, pmtleft, pmtright);
588    
589      adcraw[pmtleft] = 4095;
590      adcraw[pmtright] = 4095;
591    
592      
593      for (Int_t jj=0; jj<npmt(); jj++){
594        
595        ToFPMT *pmt = GetToFPMT(jj);
596        if(!pmt)break; //ELENA
597        
598        pmt_id = pmt->pmt_id;
599        if(pmt_id==pmtleft){
600          adcraw[pmtleft] = pmt->adc;
601        }
602        
603        if(pmt_id==pmtright){
604          adcraw[pmtright] = pmt->adc;
605        }
606      }
607    
608      
609      for (Int_t i=0; i<trk->npmtadc; i++){
610    
611        if((trk->adcflag).At(i)==0 || adcfl==100){
612          if((trk->pmtadc).At(i) == pmtleft)dEdx[pmtleft] = (trk->dedx).At(i);
613          if((trk->pmtadc).At(i) == pmtright)dEdx[pmtright] = (trk->dedx).At(i);
614        }else{
615          if((trk->pmtadc).At(i) == pmtleft)dEdx[pmtleft] = 0.;
616          if((trk->pmtadc).At(i) == pmtright)dEdx[pmtright] = 0.;
617        }
618      }
619    
620    
621      //  if( adcraw[pmtleft] >3000 || adcraw[pmtright] >3000)SatWarning=1;  //old version
622    
623      // Increase SatWarning Counter for each PMT>Sat
624      if( adcraw[pmtleft] > PMTsat[pmtleft])SatWarning++;  
625      if( adcraw[pmtright] > PMTsat[pmtright])SatWarning++;
626    
627      // if ADC  > sat set dEdx=1000
628      if( adcraw[pmtleft] > PMTsat[pmtleft]) dEdx[pmtleft] = 1000.;
629      if( adcraw[pmtright] > PMTsat[pmtright]) dEdx[pmtright] = 1000. ;
630    
631      // if two PMT are good, take mean dEdx, otherwise only the good dEdx
632      if(dEdx[pmtleft]<1000 && dEdx[pmtright]<1000) PadEdx = (dEdx[pmtleft]+dEdx[pmtright])*0.5;
633      if(dEdx[pmtleft]==1000 && dEdx[pmtright]<1000) PadEdx = dEdx[pmtright];  
634      if(dEdx[pmtleft]<1000 && dEdx[pmtright]==1000) PadEdx = dEdx[pmtleft];
635      
636    };
637    
638    // gf Apr 07
639    
640    /**
641     * Method to get the PMT name (like "S11_1A") if the PMT_ID is given.
642     * Indexes of corresponding  plane, paddle and  pmt are also given as output.
643     * @param ind  PMT_ID (0 - 47)
644     * @param iplane plane index (0 - 5)
645     * @param ipaddle paddle index (relative to the plane)
646     * @param ipmt pmt index (0(A), 1(B))
647     */
648    TString ToFLevel2::GetPMTName(Int_t ind, Int_t &iplane, Int_t &ipaddle,Int_t &ipmt){
649      
650      TString pmtname = " ";
651      
652      TString photoS[48] = {
653        "S11_1A", "S11_1B", "S11_2A", "S11_2B", "S11_3A", "S11_3B", "S11_4A",
654        "S11_4B",
655        "S11_5A", "S11_5B", "S11_6A", "S11_6B", "S11_7A", "S11_7B", "S11_8A",
656        "S11_8B",
657        "S12_1A", "S12_1B", "S12_2A", "S12_2B", "S12_3A", "S12_3B", "S12_4A",
658        "S12_4B", "S12_5A",  "S12_5B", "S12_6A", "S12_6B",
659        "S21_1A", "S21_1B", "S21_2A", "S21_2B",
660        "S22_1A", "S22_1B", "S22_2A", "S22_2B",
661        "S31_1A", "S31_1B", "S31_2A", "S31_2B", "S31_3A", "S31_3B",
662        "S32_1A", "S32_1B", "S32_2A", "S32_2B", "S32_3A", "S32_3B"
663      };
664      
665      
666      pmtname = photoS[ind].Data();
667      
668      TString ss = pmtname(1,2);
669      iplane  = (int)(atoi(ss.Data())/10)*2-3+atoi(ss.Data())%10;
670      ss = pmtname(4);
671      ipaddle = atoi(ss.Data())-1 ;
672      if( pmtname.Contains("A") )ipmt=0;
673      if( pmtname.Contains("B") )ipmt=1;
674      
675      return pmtname;
676    };
677    /**
678     * Method to get the PMT name (like "S11_1A") if the PMT_ID is given
679     * @param ind  PMT_ID (0 - 47)
680     */
681    TString ToFLevel2::GetPMTName(Int_t ind){
682    
683      Int_t iplane  = -1;
684      Int_t ipaddle = -1;
685      Int_t ipmt    = -1;
686      return GetPMTName(ind,iplane,ipaddle,ipmt);
687      
688    };
689    
690    // wm jun 08
691    Int_t ToFLevel2::GetPaddleIdOfTrack(Float_t xtr, Float_t ytr, Int_t plane){
692    return GetPaddleIdOfTrack(xtr ,ytr ,plane, 0.4);
693    }
694    
695    // gf Apr 07
696    Int_t ToFLevel2::GetPaddleIdOfTrack(Float_t xtr, Float_t ytr, Int_t plane, Float_t margin){
697      
698      Double_t xt,yt,xl,xh,yl,yh;
699      
700      Float_t tof11_x[8] = {-17.85,-12.75,-7.65,-2.55,2.55,7.65,12.75,17.85};
701      Float_t tof12_y[6] = { -13.75,-8.25,-2.75,2.75,8.25,13.75};
702      Float_t tof21_y[2] = { 3.75,-3.75};
703      Float_t tof22_x[2] = { -4.5,4.5};
704      Float_t tof31_x[3] = { -6.0,0.,6.0};
705      Float_t tof32_y[3] = { -5.0,0.0,5.0};
706      
707      //  S11 8 paddles  33.0 x 5.1 cm
708      //  S12 6 paddles  40.8 x 5.5 cm
709      //  S21 2 paddles  18.0 x 7.5 cm
710      //  S22 2 paddles  15.0 x 9.0 cm
711      //  S31 3 paddles  15.0 x 6.0 cm
712      //  S32 3 paddles  18.0 x 5.0 cm
713      
714      Int_t paddleidoftrack=-1;
715      //
716      
717      //--- S11 ------
718      
719      if(plane==0){
720        xt = xtr;
721        yt = ytr;
722        paddleidoftrack=-1;
723        yl = -33.0/2. ;
724        yh =  33.0/2. ;
725        if ((yt>yl)&&(yt<yh)) {
726          for (Int_t i1=0; i1<8;i1++){
727            xl = tof11_x[i1] - (5.1-margin)/2. ;
728            xh = tof11_x[i1] + (5.1-margin)/2. ;
729            if ((xt>xl)&&(xt<xh))  paddleidoftrack=i1;
730          }
731        }
732      }
733      //      cout<<"S11  "<<paddleidoftrack[0]<<"\n";
734      
735      //--- S12 -------
736      if(plane==1){
737        xt = xtr;
738        yt = ytr;
739        paddleidoftrack=-1;
740        xl = -40.8/2. ;
741        xh =  40.8/2. ;
742        
743        if ((xt>xl)&&(xt<xh)) {
744          for (Int_t i1=0; i1<6;i1++){
745            yl = tof12_y[i1] - (5.5-margin)/2. ;
746            yh = tof12_y[i1] + (5.5-margin)/2. ;
747            if ((yt>yl)&&(yt<yh))  paddleidoftrack=i1;
748          }
749        }
750      }
751      
752      //--- S21 ------
753    
754      if(plane==2){
755        xt = xtr;
756        yt = ytr;
757        paddleidoftrack=-1;
758        xl = -18./2. ;
759        xh =  18./2. ;
760        
761        if ((xt>xl)&&(xt<xh)) {
762          for (Int_t i1=0; i1<2;i1++){
763            yl = tof21_y[i1] - (7.5-margin)/2. ;
764            yh = tof21_y[i1] + (7.5-margin)/2. ;
765            if ((yt>yl)&&(yt<yh))  paddleidoftrack=i1;
766          }
767        }
768      }
769      
770      //--- S22 ------
771      if(plane==3){
772        xt = xtr;
773        yt = ytr;
774        paddleidoftrack=-1;
775        yl = -15./2. ;
776        yh =  15./2. ;
777        
778        if ((yt>yl)&&(yt<yh)) {
779          for (Int_t i1=0; i1<2;i1++){
780            xl = tof22_x[i1] - (9.0-margin)/2. ;
781            xh = tof22_x[i1] + (9.0-margin)/2. ;
782            if ((xt>xl)&&(xt<xh))  paddleidoftrack=i1;
783          }
784        }
785      }  
786      
787      //--- S31 ------
788      if(plane==4){
789        xt = xtr;
790        yt = ytr;
791        paddleidoftrack=-1;
792        yl = -15.0/2. ;
793        yh =  15.0/2. ;
794        
795        if ((yt>yl)&&(yt<yh)) {
796          for (Int_t i1=0; i1<3;i1++){
797            xl = tof31_x[i1] - (6.0-margin)/2. ;
798            xh = tof31_x[i1] + (6.0-margin)/2. ;
799            if ((xt>xl)&&(xt<xh))  paddleidoftrack=i1;
800          }
801        }
802      }  
803      
804      //---  S32 ------
805      if(plane==5){
806        xt = xtr;
807        yt = ytr;
808        paddleidoftrack=-1;
809        xl = -18.0/2. ;
810        xh =  18.0/2. ;
811        
812        if ((xt>xl)&&(xt<xh)) {
813          for (Int_t i1=0; i1<3;i1++){
814            yl = tof32_y[i1] - (5.0-margin)/2. ;
815            yh = tof32_y[i1] + (5.0-margin)/2. ;
816            if ((yt>yl)&&(yt<yh)) paddleidoftrack=i1;
817          }
818        }
819      }
820      
821      return paddleidoftrack;
822    
823    }  
824    
825    //
826    
827    // gf Apr 07
828    
829    void ToFLevel2::GetPMTPaddle(Int_t pmt_id, Int_t &plane, Int_t &paddle){
830      
831      plane = GetPlaneIndex(pmt_id);
832    
833      if(plane == 0){
834        if(pmt_id==0 || pmt_id==1)paddle=0;
835        if(pmt_id==2 || pmt_id==3)paddle=1;
836        if(pmt_id==4 || pmt_id==5)paddle=2;
837        if(pmt_id==6 || pmt_id==7)paddle=3;
838        if(pmt_id==8 || pmt_id==9)paddle=4;
839        if(pmt_id==10 || pmt_id==11)paddle=5;
840        if(pmt_id==12 || pmt_id==13)paddle=6;
841        if(pmt_id==14 || pmt_id==15)paddle=7;
842      }
843      
844      if(plane == 1){
845        if(pmt_id==16 || pmt_id==17)paddle=0;
846        if(pmt_id==18 || pmt_id==19)paddle=1;
847        if(pmt_id==20 || pmt_id==21)paddle=2;
848        if(pmt_id==22 || pmt_id==23)paddle=3;
849        if(pmt_id==24 || pmt_id==25)paddle=4;
850        if(pmt_id==26 || pmt_id==27)paddle=5;
851      }
852      
853      if(plane == 2){
854        if(pmt_id==28 || pmt_id==29)paddle=0;
855        if(pmt_id==30 || pmt_id==31)paddle=1;
856      }
857      
858      if(plane == 3){
859        if(pmt_id==32 || pmt_id==33)paddle=0;
860        if(pmt_id==34 || pmt_id==35)paddle=1;
861      }
862      
863      if(plane == 4){
864        if(pmt_id==36 || pmt_id==37)paddle=0;
865        if(pmt_id==38 || pmt_id==39)paddle=1;
866        if(pmt_id==40 || pmt_id==41)paddle=2;
867      }
868      
869      if(plane == 5){
870        if(pmt_id==42 || pmt_id==43)paddle=0;
871        if(pmt_id==44 || pmt_id==45)paddle=1;
872        if(pmt_id==46 || pmt_id==47)paddle=2;
873      }
874      return;
875    }
876    
877    //
878    
879    // gf Apr 07
880    
881    void ToFLevel2::GetPaddlePMT(Int_t paddle, Int_t &pmtleft, Int_t &pmtright){
882      pmtleft=paddle*2;
883      pmtright= pmtleft+1;  
884      return;
885    }
886    
887    //
888    
889    
890    
891    // // gf Apr 07
892    
893    void ToFLevel2::GetPaddleGeometry(Int_t plane, Int_t paddle, Float_t &xleft, Float_t &xright, Float_t &yleft, Float_t &yright){
894      
895      Int_t i1;
896    
897      Float_t tof11_x[8] = {-17.85,-12.75,-7.65,-2.55,2.55,7.65,12.75,17.85};
898      Float_t tof12_y[6] = { -13.75,-8.25,-2.75,2.75,8.25,13.75};
899      Float_t tof21_y[2] = { 3.75,-3.75};
900      Float_t tof22_x[2] = { -4.5,4.5};
901      Float_t tof31_x[3] = { -6.0,0.,6.0};
902      Float_t tof32_y[3] = { -5.0,0.0,5.0};
903            
904      //  S11 8 paddles  33.0 x 5.1 cm
905      //  S12 6 paddles  40.8 x 5.5 cm
906      //  S21 2 paddles  18.0 x 7.5 cm
907      //  S22 2 paddles  15.0 x 9.0 cm
908      //  S31 3 paddles  15.0 x 6.0 cm
909      //  S32 3 paddles  18.0 x 5.0 cm
910    
911      if(plane==0)
912        {
913          for (i1=0; i1<8;i1++){
914            if(i1 == paddle){
915              xleft = tof11_x[i1] - 5.1/2.;
916              xright = tof11_x[i1] + 5.1/2.;
917              yleft = -33.0/2.;
918              yright = 33.0/2.;
919            }
920          }
921        }
922      
923      if(plane==1)
924        {
925          for (i1=0; i1<6;i1++){
926            if(i1 == paddle){
927              xleft = -40.8/2.;
928              xright = 40.8/2.;
929              yleft = tof12_y[i1] - 5.5/2.;
930              yright = tof12_y[i1] + 5.5/2.;
931            }
932          }
933        }
934    
935      if(plane==2)
936        {
937          for (i1=0; i1<2;i1++){
938            if(i1 == paddle){
939              xleft =  -18./2.;
940              xright = 18./2.;
941              yleft = tof21_y[i1] - 7.5/2.;
942              yright = tof21_y[i1] + 7.5/2.;
943            }
944          }
945        }
946      
947      if(plane==3)
948        {
949          for (i1=0; i1<2;i1++){
950            if(i1 == paddle){
951              xleft = tof22_x[i1] - 9.0/2.;
952              xright = tof22_x[i1] + 9.0/2.;
953              yleft = -15./2.;
954              yright = 15./2.;
955            }
956          }
957        }
958    
959    
960      if(plane==4)
961        {
962          for (i1=0; i1<3;i1++){
963            if(i1 == paddle){
964              xleft = tof31_x[i1] - 6.0/2.;
965              xright = tof31_x[i1] + 6.0/2.;
966              yleft = -15./2.;
967              yright = 15./2.;
968            }
969          }
970        }
971    
972      if(plane==5)
973        {
974          for (i1=0; i1<3;i1++){
975            if(i1 == paddle){
976              xleft = -18.0/2.;
977              xright = 18.0/2.;
978              yleft = tof32_y[i1] - 5.0/2.;
979              yright = tof32_y[i1] + 5.0/2.;
980            }
981          }
982        }
983      return;
984    }
985    
986    // gf Apr 07
987    /**
988     * Method to get the paddle index (0,...23) if the plane ID and the paddle id in the plane is given.
989     * This method is the
990     * "reverse" of method "GetPaddlePlane"
991     * @param plane    (0 - 5)
992     * @param paddle   (plane=0, paddle = 0,...5)
993     * @param padid    (0 - 23)
994     */
995    Int_t ToFLevel2::GetPaddleid(Int_t plane, Int_t paddle)
996    {
997      Int_t padid=-1;
998      Int_t pads[6]={8,6,2,2,3,3};
999    
1000      int somma=0;
1001      int np=plane;
1002      for(Int_t j=0; j<np; j++){
1003        somma+=pads[j];
1004      }
1005      padid=paddle+somma;
1006      return padid;
1007    
1008    }
1009    
1010    
1011    // gf Apr 07
1012    /**
1013     * Method to get the plane ID and the paddle id in the plane if the paddle index (0,...23) is given.
1014     * This method is the
1015     * "reverse" of method "GetPaddleid"
1016     * @param pad      (0 - 23)
1017     * @param plane    (0 - 5)
1018     * @param paddle   (plane=0, paddle = 0,...5)
1019     */
1020    void ToFLevel2::GetPaddlePlane(Int_t pad, Int_t &plane, Int_t &paddle)
1021    {
1022    
1023      Int_t pads11=8;
1024      Int_t pads12=6;
1025      Int_t pads21=2;
1026      Int_t pads22=2;
1027      Int_t pads31=3;
1028      // Int_t pads32=3;
1029    
1030      if(pad<8){
1031        plane=0;
1032        paddle=pad;
1033        return;
1034      }
1035    
1036      if((7<pad)&&(pad<14)){
1037        plane=1;
1038        paddle=pad-pads11;
1039        return;
1040      }
1041      
1042      if((13<pad)&&(pad<16)){
1043        plane=2;
1044        paddle=pad-pads11-pads12;
1045        return;
1046      }
1047    
1048      if((15<pad)&&(pad<18)){
1049        plane=3;
1050        paddle=pad-pads11-pads12-pads21;
1051        return;
1052      }
1053    
1054      if((17<pad)&&(pad<21)){
1055        plane=4;
1056        paddle=pad-pads11-pads12-pads21-pads22;
1057        return;
1058      }
1059    
1060      if((20<pad)&&(pad<24)){
1061        plane=5;
1062        paddle=pad-pads11-pads12-pads21-pads22-pads31;
1063        return;
1064      }  
1065    
1066    }
1067    
1068    
1069    Int_t ToFLevel2::GetNPaddle(Int_t plane){
1070    
1071      Int_t npaddle=-1;
1072    
1073      Int_t pads11=8;
1074      Int_t pads12=6;
1075      Int_t pads21=2;
1076      Int_t pads22=2;
1077      Int_t pads31=3;
1078      Int_t pads32=3;
1079    
1080      if(plane==0)npaddle=pads11;
1081      if(plane==1)npaddle=pads12;
1082      if(plane==2)npaddle=pads21;
1083      if(plane==3)npaddle=pads22;
1084      if(plane==4)npaddle=pads31;
1085      if(plane==5)npaddle=pads32;
1086    
1087      return npaddle;
1088    
1089    }
1090    
1091    
1092    
1093    /// wm feb 08
1094    
1095    /**
1096     * Method to calculate Beta from the 12 single measurements
1097     * we check the individual weights for artificial TDC values, then calculate
1098     * am mean beta for the first time. In a second step we loop again through
1099     * the single measurements, checking for the residual from the mean
1100     * The cut on the residual reject measurements > "x"-sigma. A chi2 value is
1101     * calculated, furthermore a "quality" value by adding the weights which
1102     * are finally used. If all measurements are taken, "quality" will be = 22.47.
1103     * A chi2 cut around 3-4 and a quality-cut > 20 is needed for clean beta
1104     * measurements like antiprotons etc.
1105     * The Level2 output is derived in the fortran routines using: 10.,10.,20.
1106     * @param notrack Track Number
1107     * @param cut on residual: difference between single measurement and mean
1108     * @param cut on "quality"
1109     * @param cut on chi2
1110     */
1111    
1112    Float_t ToFLevel2::CalcBeta(Int_t notrack, Float_t resmax, Float_t qualitycut, Float_t chi2cut){
1113    
1114    //  cout<<" in CalcBeta "<<resmax<<" "<<chi2cut<<" "<<qualitycut<<endl;
1115    
1116      Float_t bxx = 100.;
1117      //
1118      ToFTrkVar *trk = GetToFTrkVar(notrack);
1119      if(!trk) return 0; //ELENA
1120    
1121    
1122      Float_t chi2,xhelp,beta_mean;
1123      Float_t w_i[12],quality,sw,sxw,res,betachi,beta_mean_inv;
1124      Float_t b[12],tdcfl;
1125      Int_t  pmt_id,pmt_plane;
1126    
1127      for (Int_t i=0; i<12; i++){
1128        b[i] = trk->beta[i];
1129                                  }
1130          
1131    
1132    //========================================================================
1133    //---  Find out ToF layers with artificial TDC values & fill vector    ---
1134    //========================================================================
1135    
1136    Float_t  w_il[6];
1137    
1138         for (Int_t jj=0; jj<6;jj++) {
1139             w_il[jj] = 1000.;
1140                                     }
1141    
1142    
1143      for (Int_t i=0; i<trk->npmttdc; i++){
1144        //
1145        pmt_id = (trk->pmttdc).At(i);
1146        pmt_plane = GetPlaneIndex(pmt_id);
1147        tdcfl = (trk->tdcflag).At(i);
1148        if (w_il[pmt_plane] != 1.) w_il[pmt_plane] = tdcfl; //tdcflag
1149                                         };
1150      
1151    //========================================================================
1152    //---  Set weights for the 12 measurements using information for top and bottom:
1153    //---  if no measurements: weight = set to very high value=> not used
1154    //---  top or bottom artificial: weight*sqrt(2)
1155    //---  top and bottom artificial: weight*sqrt(2)*sqrt(2)
1156    //========================================================================
1157    
1158    Int_t itop[12] = {0,0,1,1,2,2,3,3,0,0,1,1};
1159    Int_t ibot[12] = {4,5,4,5,4,5,4,5,2,3,2,3};
1160    
1161         xhelp= 1E09;
1162      
1163         for (Int_t jj=0; jj<12;jj++) {
1164         if (jj<4)           xhelp = 0.11;    // S1-S3
1165         if ((jj>3)&&(jj<8)) xhelp = 0.18;    // S2-S3
1166         if (jj>7)           xhelp = 0.28;    // S1-S2
1167         if ((w_il[itop[jj]] == 1000.) && (w_il[ibot[jj]] == 1000.)) xhelp = 1E09;
1168         if ((w_il[itop[jj]] == 1) || (w_il[ibot[jj]] == 1.)) xhelp = xhelp*1.414 ;
1169         if ((w_il[itop[jj]] == 1) && (w_il[ibot[jj]] == 1.)) xhelp = xhelp*2. ;
1170    
1171         w_i[jj] = 1./xhelp;
1172                                      }
1173    
1174    
1175    //========================================================================
1176    //--- Calculate mean beta for the first time -----------------------------
1177    //--- We are using "1/beta" since its error is gaussian ------------------
1178    //========================================================================
1179    
1180          Int_t icount=0;
1181          sw=0.;
1182          sxw=0.;
1183          beta_mean=100.;
1184    
1185              for (Int_t jj=0; jj<12;jj++){
1186            if ((fabs(1./b[jj])>0.1)&&(fabs(1./b[jj])<15.))
1187             {
1188                icount= icount+1;
1189                sxw=sxw + (1./b[jj])*w_i[jj]*w_i[jj] ;
1190                sw =sw + w_i[jj]*w_i[jj] ;
1191    
1192             }
1193             }
1194    
1195          if (icount>0) beta_mean=1./(sxw/sw);
1196          beta_mean_inv = 1./beta_mean;
1197    
1198    //========================================================================
1199    //--- Calculate beta for the second time, use residuals of the single
1200    //--- measurements to get a chi2 value
1201    //========================================================================
1202    
1203          icount=0;
1204          sw=0.;
1205          sxw=0.;
1206          betachi = 100.;
1207          chi2 = 0.;
1208          quality=0.;
1209    
1210    
1211              for (Int_t jj=0; jj<12;jj++){
1212           if ((fabs(1./b[jj])>0.1)&&(fabs(1./b[jj])<15.)&&(w_i[jj]>0.01)) {
1213                res = beta_mean_inv - (1./b[jj]) ;
1214                if (fabs(res*w_i[jj])<resmax)          {;
1215                chi2 = chi2 + pow((res*w_i[jj]),2) ;
1216                icount= icount+1;
1217                sxw=sxw + (1./b[jj])*w_i[jj]*w_i[jj] ;
1218                sw =sw + w_i[jj]*w_i[jj] ;
1219                                                   }
1220                                                                            }
1221                                          }
1222          quality = sqrt(sw) ;
1223    
1224          if (icount==0) chi2 = 1000.;
1225          if (icount>0) chi2 = chi2/(icount) ;
1226          if (icount>0) betachi=1./(sxw/sw);
1227    
1228       bxx = 100.;
1229       if ((chi2 < chi2cut)&&(quality>qualitycut)) bxx = betachi;
1230      //
1231      return(bxx);
1232    };
1233    
1234    
1235    ////////////////////////////////////////////////////
1236    ////////////////////////////////////////////////////
1237    
1238    
1239  /**  /**
1240   * 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).
1241   */   */
# Line 340  void ToFLevel2::GetLevel2Struct(cToFLeve Line 1244  void ToFLevel2::GetLevel2Struct(cToFLeve
1244    for(Int_t i=0;i<6;i++)    for(Int_t i=0;i<6;i++)
1245      l2->tof_j_flag[i]=tof_j_flag[i];      l2->tof_j_flag[i]=tof_j_flag[i];
1246    
1247    l2->ntoftrk = ToFTrk->GetEntries();    if(ToFTrk){ //ELENA
1248    for(Int_t j=0;j<l2->ntoftrk;j++){        l2->ntoftrk = ToFTrk->GetEntries();
1249      l2->toftrkseqno[j]= ((ToFTrkVar*)ToFTrk->At(j))->trkseqno;        for(Int_t j=0;j<l2->ntoftrk;j++){
1250      l2->npmttdc[j]= ((ToFTrkVar*)ToFTrk->At(j))->npmttdc;            l2->toftrkseqno[j]= ((ToFTrkVar*)ToFTrk->At(j))->trkseqno;
1251      for(Int_t i=0;i<l2->npmttdc[j];i++){            l2->npmttdc[j]= ((ToFTrkVar*)ToFTrk->At(j))->npmttdc;
1252        l2->pmttdc[i][j] = ((ToFTrkVar*)ToFTrk->At(j))->pmttdc.At(i);            for(Int_t i=0;i<l2->npmttdc[j];i++){
1253        l2->tdcflag[i][j] = ((ToFTrkVar*)ToFTrk->At(j))->tdcflag.At(i); // gf: 30 Nov 2006                l2->pmttdc[i][j] = ((ToFTrkVar*)ToFTrk->At(j))->pmttdc.At(i);
1254      }                l2->tdcflag[i][j] = ((ToFTrkVar*)ToFTrk->At(j))->tdcflag.At(i); // gf: 30 Nov 2006
1255      for(Int_t i=0;i<13;i++)            }
1256        l2->beta[i][j] = ((ToFTrkVar*)ToFTrk->At(j))->beta[i];            for(Int_t i=0;i<13;i++)
1257                      l2->beta[i][j] = ((ToFTrkVar*)ToFTrk->At(j))->beta[i];
1258      l2->npmtadc[j]= ((ToFTrkVar*)ToFTrk->At(j))->npmtadc;            
1259      for(Int_t i=0;i<l2->npmtadc[j];i++){            l2->npmtadc[j]= ((ToFTrkVar*)ToFTrk->At(j))->npmtadc;
1260        l2->pmtadc[i][j] = ((ToFTrkVar*)ToFTrk->At(j))->pmtadc.At(i);            for(Int_t i=0;i<l2->npmtadc[j];i++){
1261        l2->adcflag[i][j] = ((ToFTrkVar*)ToFTrk->At(j))->adcflag.At(i); // gf: 30 Nov 2006                l2->pmtadc[i][j] = ((ToFTrkVar*)ToFTrk->At(j))->pmtadc.At(i);
1262        l2->dedx[i][j] = ((ToFTrkVar*)ToFTrk->At(j))->dedx.At(i);                l2->adcflag[i][j] = ((ToFTrkVar*)ToFTrk->At(j))->adcflag.At(i); // gf: 30 Nov 2006
1263      }                l2->dedx[i][j] = ((ToFTrkVar*)ToFTrk->At(j))->dedx.At(i);
1264      for(Int_t i=0;i<3;i++){            }
1265        l2->xtofpos[i][j]=((ToFTrkVar*)ToFTrk->At(j))->xtofpos[i];            for(Int_t i=0;i<3;i++){
1266        l2->ytofpos[i][j]=((ToFTrkVar*)ToFTrk->At(j))->ytofpos[i];                l2->xtofpos[i][j]=((ToFTrkVar*)ToFTrk->At(j))->xtofpos[i];
1267                  l2->ytofpos[i][j]=((ToFTrkVar*)ToFTrk->At(j))->ytofpos[i];
1268              }
1269              for(Int_t i=0;i<6;i++){
1270                  l2->xtr_tof[i][j]=((ToFTrkVar*)ToFTrk->At(j))->xtr_tof[i];
1271                  l2->ytr_tof[i][j]=((ToFTrkVar*)ToFTrk->At(j))->ytr_tof[i];
1272              }
1273          }
1274      } //ELENA
1275        
1276      if(PMT){ //ELENA
1277          l2->npmt = PMT->GetEntries();
1278          for(Int_t j=0;j<l2->npmt;j++){
1279              l2->pmt_id[j] = ((ToFPMT*)PMT->At(j))->pmt_id;
1280              l2->adc[j] =((ToFPMT*)PMT->At(j))->adc;
1281              l2->tdc_tw[j] =((ToFPMT*)PMT->At(j))->tdc_tw;
1282          }
1283      } //ELENA
1284    }
1285    
1286    
1287    //
1288    // Reprocessing tool // Emiliano 08/04/07
1289    //
1290    Int_t ToFLevel2::Process(TrkLevel2 *trk, TrigLevel2 *trg, GL_RUN *run, OrbitalInfo *orb, Bool_t force){
1291      //
1292      // Copiare qui qualcosa di simile a calonuclei per evitare di riprocessare sempre tutto
1293      //
1294      printf("\n\n\n ERROR: NOT IMPLEMENTED ANYMORE, write Emiliano if you need this method (Emiliano.Mocchiutti@ts.infn.it) \n\n\n");
1295      return(-1);
1296      //   //
1297      //   // structures to communicate with F77
1298      //   //
1299      //   extern struct ToFInput  tofinput_;
1300    //   extern struct ToFOutput tofoutput_;
1301    //   //
1302    //   // DB connection
1303    //   //
1304    //   TString host;
1305    //   TString user;
1306    //   TString psw;
1307    //   const char *pamdbhost=gSystem->Getenv("PAM_DBHOST");
1308    //   const char *pamdbuser=gSystem->Getenv("PAM_DBUSER");
1309    //   const char *pamdbpsw=gSystem->Getenv("PAM_DBPSW");
1310    //   if ( !pamdbhost ) pamdbhost = "";
1311    //   if ( !pamdbuser ) pamdbuser = "";
1312    //   if ( !pamdbpsw ) pamdbpsw = "";
1313    //   if ( strcmp(pamdbhost,"") ) host = pamdbhost;
1314    //   if ( strcmp(pamdbuser,"") ) user = pamdbuser;
1315    //   if ( strcmp(pamdbpsw,"") ) psw = pamdbpsw;
1316    //   //
1317    //   //
1318    //   TSQLServer *dbc = TSQLServer::Connect(host.Data(),user.Data(),psw.Data());
1319    //   if ( !dbc->IsConnected() ) return 1;
1320    //   stringstream myquery;
1321    //   myquery.str("");
1322    //   myquery << "SET time_zone='+0:00';";
1323    //   dbc->Query(myquery.str().c_str());
1324    //   delete dbc->Query("SET sql_mode = 'NO_UNSIGNED_SUBTRACTION';");
1325    //   GL_PARAM *glparam = new GL_PARAM();
1326    //   glparam->Query_GL_PARAM(1,1,dbc); // parameters stored in DB in GL_PRAM table
1327    //   trk->LoadField(glparam->PATH+glparam->NAME);
1328    //   //
1329    //   Bool_t defcal = true;
1330    //   Int_t error=glparam->Query_GL_PARAM(run->RUNHEADER_TIME,201,dbc); // parameters stored in DB in GL_PRAM table
1331    //   if ( error<0 ) {
1332    //     return(1);
1333    //   };
1334    //   printf(" Reading ToF parameter file: %s \n",(glparam->PATH+glparam->NAME).Data());
1335    //   if ( (UInt_t)glparam->TO_TIME != (UInt_t)4294967295UL ) defcal = false;
1336    //   //
1337    //   Int_t nlen = (Int_t)(glparam->PATH+glparam->NAME).Length();
1338    //   rdtofcal((char *)(glparam->PATH+glparam->NAME).Data(),&nlen);
1339    //   //
1340    //   Int_t adc[4][12];
1341    //   Int_t tdc[4][12];
1342    //   Float_t tdcc[4][12];
1343    //   //
1344    //   // process tof data
1345    //   //
1346    //   for (Int_t hh=0; hh<12;hh++){
1347    //     for (Int_t kk=0; kk<4;kk++){
1348    //            adc[kk][hh] = 4095;
1349    //            tdc[kk][hh] = 4095;
1350    //            tdcc[kk][hh] = 4095.;
1351    //            tofinput_.adc[hh][kk] = 4095;
1352    //            tofinput_.tdc[hh][kk] = 4095;
1353    //     };
1354    //   };
1355    //   Int_t ntrkentry = 0;
1356    //   Int_t npmtentry = 0;
1357    //   Int_t gg = 0;
1358    //   Int_t hh = 0;
1359    //   Int_t adcf[48];
1360    //   memset(adcf, 0, 48*sizeof(Int_t));
1361    //   Int_t tdcf[48];
1362    //   memset(tdcf, 0, 48*sizeof(Int_t));
1363    //   for (Int_t pm=0; pm < this->ntrk() ; pm++){
1364    //      ToFTrkVar *ttf = this->GetToFTrkVar(pm);
1365    //      for ( Int_t nc=0; nc < ttf->npmttdc; nc++){
1366    //             if ( (ttf->tdcflag).At(nc) != 0 ) tdcf[(ttf->pmttdc).At(nc)] = 1;
1367    //      };
1368    //      for ( Int_t nc=0; nc < ttf->npmtadc; nc++){
1369    //             if ( (ttf->adcflag).At(nc) != 0 ) adcf[(ttf->pmtadc).At(nc)] = 1;
1370    //      };
1371    //   };
1372    //   //
1373    //   for (Int_t pm=0; pm < this->npmt() ; pm++){
1374    //      ToFPMT *pmt = this->GetToFPMT(pm);
1375    //      this->GetPMTIndex(pmt->pmt_id, gg, hh);
1376    //      if ( adcf[pmt->pmt_id] == 0 ){
1377    //              tofinput_.adc[gg][hh] = (int)pmt->adc;
1378    //              adc[hh][gg] = (int)pmt->adc;
1379    //      };
1380    //      if ( tdcf[pmt->pmt_id] == 0 ){
1381    //              tofinput_.tdc[gg][hh] = (int)pmt->tdc;
1382    //              tdc[hh][gg] = (int)pmt->tdc;
1383    //      };
1384    //      tdcc[hh][gg] = (float)pmt->tdc_tw;
1385    //      // Int_t pppid = this->GetPMTid(hh,gg);
1386    //      //      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);
1387    //   };
1388    //   //
1389    //   Int_t unpackError = this->unpackError;
1390    //   //
1391    //   for (Int_t hh=0; hh<5;hh++){
1392    //      tofinput_.patterntrig[hh]=trg->patterntrig[hh];
1393    //   };
1394    //   //
1395    //   this->Clear();
1396    //   //
1397    //       Int_t pmt_id = 0;
1398    //       ToFPMT *t_pmt = new ToFPMT();
1399    //       if(!(this->PMT)) this->PMT = new TClonesArray("ToFPMT",12); //ELENA
1400    //       TClonesArray &tpmt = *this->PMT;
1401    //       ToFTrkVar *t_tof = new ToFTrkVar();
1402    //       if(!(this->ToFTrk)) this->ToFTrk = new TClonesArray("ToFTrkVar",2); //ELENA
1403    //       TClonesArray &t = *this->ToFTrk;
1404    //       //
1405    //       //
1406    //       // Here we have calibrated data, ready to be passed to the FORTRAN routine which will extract common and track-related  variables.
1407    //       //
1408    //       npmtentry = 0;
1409    //       //
1410    //       ntrkentry = 0;
1411    //       //
1412    //       // Calculate tracks informations from ToF alone
1413    //       //
1414    //       tofl2com();
1415    //       //
1416    //       memcpy(this->tof_j_flag,tofoutput_.tof_j_flag,6*sizeof(Int_t));
1417    //       //
1418    //       t_tof->trkseqno = -1;
1419    //       //
1420    //       // and now we must copy from the output structure to the level2 class:
1421    //       //
1422    //       t_tof->npmttdc = 0;
1423    //       //
1424    //       for (Int_t hh=0; hh<12;hh++){
1425    //         for (Int_t kk=0; kk<4;kk++){
1426    //           if ( tofoutput_.tofmask[hh][kk] != 0 ){
1427    //             pmt_id = this->GetPMTid(kk,hh);
1428    //             t_tof->pmttdc.AddAt(pmt_id,t_tof->npmttdc);
1429    //             t_tof->tdcflag.AddAt(tofoutput_.tdcflagtof[hh][kk],t_tof->npmttdc); // gf: Jan 09/07
1430    //             t_tof->npmttdc++;
1431    //           };
1432    //         };
1433    //       };
1434    //       for (Int_t kk=0; kk<13;kk++){
1435    //         t_tof->beta[kk] = tofoutput_.betatof_a[kk];
1436    //       }
1437    //       //
1438    //       t_tof->npmtadc = 0;
1439    //       for (Int_t hh=0; hh<12;hh++){
1440    //         for (Int_t kk=0; kk<4;kk++){
1441    //           if ( tofoutput_.adctof_c[hh][kk] < 1000 ){
1442    //             t_tof->dedx.AddAt(tofoutput_.adctof_c[hh][kk],t_tof->npmtadc);
1443    //             pmt_id = this->GetPMTid(kk,hh);
1444    //             t_tof->pmtadc.AddAt(pmt_id,t_tof->npmtadc);
1445    //             t_tof->adcflag.AddAt(tofoutput_.adcflagtof[hh][kk],t_tof->npmtadc); // gf: Jan 09/07
1446    //             t_tof->npmtadc++;
1447    //           };
1448    //         };
1449    //       };
1450    //       //
1451    //       memcpy(t_tof->xtofpos,tofoutput_.xtofpos,sizeof(t_tof->xtofpos));
1452    //       memcpy(t_tof->ytofpos,tofoutput_.ytofpos,sizeof(t_tof->ytofpos));
1453    //       memcpy(t_tof->xtr_tof,tofoutput_.xtr_tof,sizeof(t_tof->xtr_tof));
1454    //       memcpy(t_tof->ytr_tof,tofoutput_.ytr_tof,sizeof(t_tof->ytr_tof));
1455    //       //
1456    //       new(t[ntrkentry]) ToFTrkVar(*t_tof);
1457    //       ntrkentry++;
1458    //       t_tof->Clear();
1459    //       //
1460    //       //
1461    //       //
1462    //       t_pmt->Clear();
1463    //       //
1464    //       for (Int_t hh=0; hh<12;hh++){
1465    //         for (Int_t kk=0; kk<4;kk++){
1466    //          // new WM
1467    //           if ( tofoutput_.tdc_c[hh][kk] < 4095 || adc[kk][hh] < 4095  || tdc[kk][hh] < 4095 ){
1468    // //          if ( tdcc[kk][hh] < 4095. || adc[kk][hh] < 4095  || tdc[kk][hh] < 4095 ){
1469    //             //
1470    //             t_pmt->pmt_id = this->GetPMTid(kk,hh);
1471    //             t_pmt->tdc_tw = tofoutput_.tdc_c[hh][kk];
1472    //             t_pmt->adc = (Float_t)adc[kk][hh];
1473    //             t_pmt->tdc = (Float_t)tdc[kk][hh];
1474    //             //
1475    //             new(tpmt[npmtentry]) ToFPMT(*t_pmt);
1476    //             npmtentry++;
1477    //             t_pmt->Clear();
1478    //           };
1479    //         };
1480    //       };
1481    //       //
1482    //       // Calculate track-related variables
1483    //       //
1484    //       if ( trk->ntrk() > 0 ){
1485    //         //
1486    //         // We have at least one track
1487    //         //
1488    //         //
1489    //         // Run over tracks
1490    //         //
1491    //         for(Int_t nt=0; nt < trk->ntrk(); nt++){
1492    //           //
1493    //           TrkTrack *ptt = trk->GetStoredTrack(nt);
1494    //           //
1495    //           // Copy the alpha vector in the input structure
1496    //           //
1497    //           for (Int_t e = 0; e < 5 ; e++){
1498    //             tofinput_.al_pp[e] = ptt->al[e];
1499    //           };
1500    //           //
1501    //           // Get tracker related variables for this track
1502    //           //
1503    //           toftrk();
1504    //           //
1505    //           // Copy values in the class from the structure (we need to use a temporary class to store variables).
1506    //           //
1507    //           t_tof->npmttdc = 0;
1508    //           for (Int_t hh=0; hh<12;hh++){
1509    //             for (Int_t kk=0; kk<4;kk++){
1510    //               if ( tofoutput_.tofmask[hh][kk] != 0 ){
1511    //                 pmt_id = this->GetPMTid(kk,hh);
1512    //                 t_tof->pmttdc.AddAt(pmt_id,t_tof->npmttdc);
1513    //                 t_tof->tdcflag.AddAt(tofoutput_.tdcflag[hh][kk],t_tof->npmttdc); // gf: Jan 09/07
1514    //                 t_tof->npmttdc++;
1515    //               };
1516    //             };
1517    //           };
1518    //           for (Int_t kk=0; kk<13;kk++){
1519    //             t_tof->beta[kk] = tofoutput_.beta_a[kk];
1520    //           };
1521    //           //
1522    //           t_tof->npmtadc = 0;
1523    //           for (Int_t hh=0; hh<12;hh++){
1524    //             for (Int_t kk=0; kk<4;kk++){
1525    //               if ( tofoutput_.adc_c[hh][kk] < 1000 ){
1526    //                 t_tof->dedx.AddAt(tofoutput_.adc_c[hh][kk],t_tof->npmtadc);
1527    //                 pmt_id = this->GetPMTid(kk,hh);
1528    //                 t_tof->pmtadc.AddAt(pmt_id,t_tof->npmtadc);
1529    //                 t_tof->adcflag.AddAt(tofoutput_.adcflag[hh][kk],t_tof->npmtadc); // gf: Jan 09/07
1530    //                 t_tof->npmtadc++;
1531    //               };
1532    //             };
1533    //           };
1534    //           //
1535    //           memcpy(t_tof->xtofpos,tofoutput_.xtofpos,sizeof(t_tof->xtofpos));
1536    //           memcpy(t_tof->ytofpos,tofoutput_.ytofpos,sizeof(t_tof->ytofpos));
1537    //           memcpy(t_tof->xtr_tof,tofoutput_.xtr_tof,sizeof(t_tof->xtr_tof));
1538    //           memcpy(t_tof->ytr_tof,tofoutput_.ytr_tof,sizeof(t_tof->ytr_tof));
1539    //           //
1540    //           // Store the tracker track number in order to be sure to have shyncronized data during analysis
1541    //           //
1542    //           t_tof->trkseqno = nt;
1543    //           //
1544    //           // create a new object for this event with track-related variables
1545    //           //
1546    //           new(t[ntrkentry]) ToFTrkVar(*t_tof);
1547    //           ntrkentry++;
1548    //           t_tof->Clear();
1549    //           //
1550    //         }; // loop on all the tracks
1551    //       //
1552    //       this->unpackError = unpackError;
1553    //       if ( defcal ){
1554    //         this->default_calib = 1;
1555    //       } else {
1556    //         this->default_calib = 0;
1557    //       };
1558    //};
1559    //  return(0);
1560    }
1561    
1562    bool ToFLevel2::bit(int decimal, char pos){
1563      return( (decimal>>pos)%2 );
1564    }
1565    
1566    bool ToFLevel2::checkPMT(TString givenpmt){
1567      TClonesArray* Pmt = this->PMT;
1568      //  printf(" ou %s entries %i \n",givenpmt.Data(),Pmt->GetEntries());
1569      for(int i=0; i<Pmt->GetEntries(); i++) {  
1570        ToFPMT* pmthit = (ToFPMT*)Pmt->At(i);
1571        TString pmtname = this->GetPMTName(pmthit->pmt_id);
1572        //    printf(" name %s \n",pmtname.Data());
1573        if ( !strcmp(pmtname.Data(),givenpmt.Data()) )
1574          return true;
1575      }
1576      //  printf(" PMT %s missing \n",givenpmt.Data());
1577      return false;
1578    }
1579    
1580    bool ToFLevel2::checkPMTpatternPMThit(TrigLevel2 *trg, int &pmtpattern, int &pmtnosignal){
1581      UInt_t *patterntrig = trg->patterntrig;
1582      pmtpattern = 0;
1583      pmtnosignal = 0;
1584      bool good = true;
1585      //S3
1586      if ( this->bit(patterntrig[2],0) ){ pmtpattern++;  if ( !this->checkPMT("S31_1A")){ pmtnosignal++; good = false;}}
1587      if ( this->bit(patterntrig[2],1) ){ pmtpattern++;  if ( !this->checkPMT("S31_2A")){ pmtnosignal++; good = false;}}
1588      if ( this->bit(patterntrig[2],2) ){ pmtpattern++;  if ( !this->checkPMT("S31_3A")){ pmtnosignal++; good = false;}}
1589      if ( this->bit(patterntrig[2],3) ){ pmtpattern++;  if ( !this->checkPMT("S31_1B")){ pmtnosignal++; good = false;}}
1590      if ( this->bit(patterntrig[2],4) ){ pmtpattern++;  if ( !this->checkPMT("S31_2B")){ pmtnosignal++; good = false;}}
1591      if ( this->bit(patterntrig[2],5) ){ pmtpattern++;  if ( !this->checkPMT("S31_3B")){ pmtnosignal++; good = false;}}      
1592      if ( this->bit(patterntrig[2],6) ){ pmtpattern++;  if ( !this->checkPMT("S32_1A")){ pmtnosignal++; good = false;}}
1593      if ( this->bit(patterntrig[2],7) ){ pmtpattern++;  if ( !this->checkPMT("S32_2A")){ pmtnosignal++; good = false;}}
1594      if ( this->bit(patterntrig[2],8) ){ pmtpattern++;  if ( !this->checkPMT("S32_3A")){ pmtnosignal++; good = false;}}
1595      if ( this->bit(patterntrig[2],9) ){ pmtpattern++;  if ( !this->checkPMT("S32_1B")){ pmtnosignal++; good = false;}}
1596      if ( this->bit(patterntrig[2],10) ){ pmtpattern++;  if ( !this->checkPMT("S32_2B")){ pmtnosignal++; good = false;}}
1597      if ( this->bit(patterntrig[2],11) ){ pmtpattern++;  if ( !this->checkPMT("S32_3B")){ pmtnosignal++; good = false;}}      
1598      //S2
1599      if ( this->bit(patterntrig[3],0) ){ pmtpattern++;  if ( !this->checkPMT("S21_1A")){ pmtnosignal++; good = false;}}
1600      if ( this->bit(patterntrig[3],1) ){ pmtpattern++;  if ( !this->checkPMT("S21_2A")){ pmtnosignal++; good = false;}}
1601      if ( this->bit(patterntrig[3],2) ){ pmtpattern++;  if ( !this->checkPMT("S21_1B")){ pmtnosignal++; good = false;}}
1602      if ( this->bit(patterntrig[3],3) ){ pmtpattern++;  if ( !this->checkPMT("S21_2B")){ pmtnosignal++; good = false;}}      
1603      if ( this->bit(patterntrig[3],4) ){ pmtpattern++;  if ( !this->checkPMT("S22_1A")){ pmtnosignal++; good = false;}}
1604      if ( this->bit(patterntrig[3],5) ){ pmtpattern++;  if ( !this->checkPMT("S22_2A")){ pmtnosignal++; good = false;}}
1605      if ( this->bit(patterntrig[3],6) ){ pmtpattern++;  if ( !this->checkPMT("S22_1B")){ pmtnosignal++; good = false;}}
1606      if ( this->bit(patterntrig[3],7) ){ pmtpattern++;  if ( !this->checkPMT("S22_2B")){ pmtnosignal++; good = false;}}      
1607      //S12
1608      if ( this->bit(patterntrig[4],0) ){ pmtpattern++;  if ( !this->checkPMT("S12_1A")){ pmtnosignal++; good = false;}}
1609      if ( this->bit(patterntrig[4],1) ){ pmtpattern++;  if ( !this->checkPMT("S12_2A")){ pmtnosignal++; good = false;}}
1610      if ( this->bit(patterntrig[4],2) ){ pmtpattern++;  if ( !this->checkPMT("S12_3A")){ pmtnosignal++; good = false;}}
1611      if ( this->bit(patterntrig[4],3) ){ pmtpattern++;  if ( !this->checkPMT("S12_4A")){ pmtnosignal++; good = false;}}
1612      if ( this->bit(patterntrig[4],4) ){ pmtpattern++;  if ( !this->checkPMT("S12_5A")){ pmtnosignal++; good = false;}}
1613      if ( this->bit(patterntrig[4],5) ){ pmtpattern++;  if ( !this->checkPMT("S12_6A")){ pmtnosignal++; good = false;}}      
1614      if ( this->bit(patterntrig[4],6) ){ pmtpattern++;  if ( !this->checkPMT("S12_1A")){ pmtnosignal++; good = false;}}
1615      if ( this->bit(patterntrig[4],7) ){ pmtpattern++;  if ( !this->checkPMT("S12_2A")){ pmtnosignal++; good = false;}}
1616      if ( this->bit(patterntrig[4],8) ){ pmtpattern++;  if ( !this->checkPMT("S12_3A")){ pmtnosignal++; good = false;}}
1617      if ( this->bit(patterntrig[4],9) ){ pmtpattern++;  if ( !this->checkPMT("S12_4B")){ pmtnosignal++; good = false;}}
1618      if ( this->bit(patterntrig[4],10) ){ pmtpattern++; if ( !this->checkPMT("S12_5B")){ pmtnosignal++; good = false;}}
1619      if ( this->bit(patterntrig[4],11) ){ pmtpattern++; if ( !this->checkPMT("S12_6B")){ pmtnosignal++; good = false;}}      
1620      //S11
1621      if ( this->bit(patterntrig[5],0) ){ pmtpattern++;  if ( !this->checkPMT("S11_1A")){ pmtnosignal++; good = false;}}
1622      if ( this->bit(patterntrig[5],1) ){ pmtpattern++;  if ( !this->checkPMT("S11_2A")){ pmtnosignal++; good = false;}}
1623      if ( this->bit(patterntrig[5],2) ){ pmtpattern++;  if ( !this->checkPMT("S11_3A")){ pmtnosignal++; good = false;}}
1624      if ( this->bit(patterntrig[5],3) ){ pmtpattern++;  if ( !this->checkPMT("S11_4A")){ pmtnosignal++; good = false;}}
1625      if ( this->bit(patterntrig[5],4) ){ pmtpattern++;  if ( !this->checkPMT("S11_5A")){ pmtnosignal++; good = false;}}
1626      if ( this->bit(patterntrig[5],5) ){ pmtpattern++;  if ( !this->checkPMT("S11_6A")){ pmtnosignal++; good = false;}}
1627      if ( this->bit(patterntrig[5],6) ){ pmtpattern++;  if ( !this->checkPMT("S11_7A")){ pmtnosignal++; good = false;}}
1628      if ( this->bit(patterntrig[5],7) ){ pmtpattern++;  if ( !this->checkPMT("S11_8A")){ pmtnosignal++; good = false;}}      
1629      if ( this->bit(patterntrig[5],8) ){ pmtpattern++;  if ( !this->checkPMT("S11_1B")){ pmtnosignal++; good = false;}}
1630      if ( this->bit(patterntrig[5],9) ){ pmtpattern++;  if ( !this->checkPMT("S11_2B")){ pmtnosignal++; good = false;}}
1631      if ( this->bit(patterntrig[5],10) ){ pmtpattern++; if ( !this->checkPMT("S11_3B")){ pmtnosignal++; good = false;}}
1632      if ( this->bit(patterntrig[5],11) ){ pmtpattern++; if ( !this->checkPMT("S11_4B")){ pmtnosignal++; good = false;}}
1633      if ( this->bit(patterntrig[5],12) ){ pmtpattern++; if ( !this->checkPMT("S11_5B")){ pmtnosignal++; good = false;}}
1634      if ( this->bit(patterntrig[5],13) ){ pmtpattern++; if ( !this->checkPMT("S11_6B")){ pmtnosignal++; good = false;}}
1635      if ( this->bit(patterntrig[5],14) ){ pmtpattern++; if ( !this->checkPMT("S11_7B")){ pmtnosignal++; good = false;}}
1636      if ( this->bit(patterntrig[5],15) ){ pmtpattern++; if ( !this->checkPMT("S11_8B")){ pmtnosignal++; good = false;}}
1637    
1638      return good;
1639    }
1640    
1641    bool ToFLevel2::checkPMTpmttrig(TrigLevel2 *trg){
1642      //  UInt_t *patterntrig = trg->patterntrig;
1643      int rS11 = 0;
1644      int rS12 = 0;
1645      int rS21 = 0;
1646      int rS22 = 0;
1647      int rS31 = 0;
1648      int rS32 = 0;
1649    
1650      // trigger configuration for the event from saved pmts
1651      TClonesArray* Pmt = this->PMT;
1652      for(int i=0; i<Pmt->GetEntries(); i++) {  
1653        ToFPMT* pmthit = (ToFPMT*)Pmt->At(i);
1654        TString pmtname = this->GetPMTName(pmthit->pmt_id);
1655        if ( pmtname.Contains("S11") ) rS11++;
1656        if ( pmtname.Contains("S12") ) rS12++;
1657        if ( pmtname.Contains("S21") ) rS21++;
1658        if ( pmtname.Contains("S22") ) rS22++;
1659        if ( pmtname.Contains("S31") ) rS31++;
1660        if ( pmtname.Contains("S32") ) rS32++;
1661      }
1662      int rTOF1 = (rS11 + rS12) * (rS21 + rS22) * (rS31 + rS32);
1663      int rTOF2 = (rS11 * rS12) * (rS21 * rS22) * (rS31 * rS32);
1664    
1665      int rTOF3 = (rS21 + rS22) * (rS31 + rS32);
1666      int rTOF4 = (rS21 * rS22) * (rS31 * rS32);
1667    
1668      int rTOF5 = rS12 * (rS21 * rS22);
1669    
1670      int rTOF6 = (rS11 + rS12) * (rS31 + rS32);
1671      int rTOF7 = (rS11 * rS12) * (rS31 * rS32);
1672    
1673    
1674      // trigger configuration of the run
1675      bool TCTOF1 = false;
1676      bool TCTOF2 = false;
1677      bool TCTOF3 = false;
1678      bool TCTOF4 = false;
1679      bool TCTOF5 = false;
1680      bool TCTOF6 = false;
1681      bool TCTOF7 = false;
1682      if ( trg->trigconf & (1<<0) ) TCTOF1 = true;
1683      if ( trg->trigconf & (1<<1) ) TCTOF2 = true;
1684      if ( trg->trigconf & (1<<2) ) TCTOF3 = true;
1685      if ( trg->trigconf & (1<<3) ) TCTOF4 = true;
1686      if ( trg->trigconf & (1<<4) ) TCTOF5 = true;
1687      if ( trg->trigconf & (1<<5) ) TCTOF6 = true;
1688      if ( trg->trigconf & (1<<6) ) TCTOF7 = true;
1689    
1690      // do patterntrig pmts match the trigger configuration?
1691      bool pmtsconf_trigconf_match = true;
1692      if ( rTOF1 == 0 && TCTOF1 ) pmtsconf_trigconf_match = false;
1693      if ( rTOF2 == 0 && TCTOF2 ) pmtsconf_trigconf_match = false;
1694      if ( rTOF3 == 0 && TCTOF3 ) pmtsconf_trigconf_match = false;
1695      if ( rTOF4 == 0 && TCTOF4 ) pmtsconf_trigconf_match = false;
1696      if ( rTOF5 == 0 && TCTOF5 ) pmtsconf_trigconf_match = false;
1697      if ( rTOF6 == 0 && TCTOF6 ) pmtsconf_trigconf_match = false;
1698      if ( rTOF7 == 0 && TCTOF7 ) pmtsconf_trigconf_match = false;
1699    
1700      return pmtsconf_trigconf_match;
1701    }
1702    
1703    void ToFLevel2::printPMT(){
1704      TClonesArray* Pmt = this->PMT;
1705      for(int i=0; i<Pmt->GetEntries(); i++) {  
1706        ToFPMT* pmthit = (ToFPMT*)Pmt->At(i);
1707        TString pmtname = this->GetPMTName(pmthit->pmt_id);
1708        printf(" PMT hit: %s \n",pmtname.Data());
1709      }
1710    }
1711    
1712    
1713    ToFdEdx::ToFdEdx()
1714    {
1715      memset(conn,0,12*sizeof(Bool_t));
1716      memset(ts,0,12*sizeof(UInt_t));
1717      memset(te,0,12*sizeof(UInt_t));
1718      eDEDXpmt = new TArrayF(48);
1719      Define_PMTsat();
1720      Clear();
1721    }
1722    
1723    ToFdEdx::~ToFdEdx(){
1724      Clear();
1725      Delete();
1726    }
1727    
1728    void ToFdEdx::Delete(Option_t *option){
1729      if ( eDEDXpmt ){
1730        eDEDXpmt->Set(0);
1731        if ( eDEDXpmt) delete eDEDXpmt;
1732      }
1733    }
1734    
1735    //------------------------------------------------------------------------
1736    void ToFdEdx::CheckConnectors(UInt_t atime, GL_PARAM *glparam, TSQLServer *dbc)
1737    {
1738      for(int i=0; i<12; i++){
1739        if(atime<=ts[i] || atime>te[i]){
1740          Int_t error=glparam->Query_GL_PARAM(atime,210+i,dbc); // parameters stored in DB in GL_PRAM table
1741          if ( error<0 ) {
1742            conn[i]=false;
1743            ts[i]=0;
1744            te[i]=numeric_limits<UInt_t>::max();
1745          };
1746          if ( !error ){
1747            conn[i]=true;
1748            ts[i]=glparam->FROM_TIME;
1749            te[i]=glparam->TO_TIME;
1750          }
1751          if ( error>0 ){
1752            conn[i]=false;
1753            ts[i]=glparam->TO_TIME;
1754            TSQLResult *pResult;
1755            TSQLRow *row;
1756            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);
1757            pResult=dbc->Query(query.Data());
1758            if(!pResult->GetRowCount()){
1759              te[i]=numeric_limits<UInt_t>::max();
1760            }else{
1761              row=pResult->Next();
1762              te[i]=(UInt_t)atoll(row->GetField(0));
1763            }
1764          }
1765          //
1766          
1767      }      }
1768    }    }
1769    
1770    }
1771    //------------------------------------------------------------------------
1772    void ToFdEdx::Clear(Option_t *option)
1773    {
1774      //
1775      // Set arrays and initialize structure
1776      //  eDEDXpmt.Set(48);    eDEDXpmt.Reset(-1);   // Set array size  and reset structure
1777      eDEDXpmt->Set(48);    eDEDXpmt->Reset(-1);   // Set array size  and reset structure
1778      //
1779    };
1780    
1781    //------------------------------------------------------------------------
1782    void ToFdEdx::Print(Option_t *option)
1783    {
1784      //
1785      printf("========================================================================\n");
1786    
1787    };
1788    
1789    //------------------------------------------------------------------------
1790    void ToFdEdx::Init(pamela::tof::TofEvent *tofl0)
1791    {
1792      //
1793      ToFLevel2 tf;
1794      for (Int_t gg=0; gg<4;gg++){
1795        for (Int_t hh=0; hh<12;hh++){
1796          //          tofinput_.tdc[hh][gg]=tofEvent->tdc[gg][hh];          
1797          int mm = tf.GetPMTid(gg,hh);        
1798          adc[mm]= (0xFFF & tofl0->adc[gg][hh]); // EM, exclude warning bits
1799        };      
1800      };
1801      
1802    };
1803    
1804    //------------------------------------------------------------------------
1805    void ToFdEdx::Init(Int_t gg, Int_t hh, Float_t adce)
1806    {
1807      //
1808      ToFLevel2 tf;
1809      //  for (Int_t gg=0; gg<4;gg++){
1810      //    for (Int_t hh=0; hh<12;hh++){
1811      int mm = tf.GetPMTid(gg,hh);    
1812      adc[mm]=adce;
1813      
1814    };
1815    //------------------------------------------------------------------------
1816    void ToFdEdx::Process(UInt_t atime, Float_t betamean, Float_t *xtr_tof, Float_t *ytr_tof, Int_t exitat)
1817    {
1818      bool debug = false;
1819      if ( debug ) printf(" INSIDE TOFDEDX PROCESS \n");
1820      // the parameters should be already initialised by InitPar()
1821      //  printf(" in process \n");
1822      Clear();
1823    
1824     // define angle:  
1825      double dx   = xtr_tof[1] - xtr_tof[5];
1826      double dy   = ytr_tof[0] - ytr_tof[4];
1827      double dr   = sqrt(dx*dx+dy*dy);
1828      double theta=atan(dr/76.81);
1829      //
1830      if ( xtr_tof[1] > 99. ||  xtr_tof[5] > 99. || ytr_tof[0] > 99. ||  ytr_tof[4] > 99. ) theta = 0.;
1831      for (Int_t ii=0; ii<6; ii++){
1832        if ( xtr_tof[ii] > 99. ) xtr_tof[ii] = 0.;
1833        if ( ytr_tof[ii] > 99. ) ytr_tof[ii] = 0.;
1834      };
1835      //
1836      if ( debug ) printf(" theta %f \n",theta);
1837      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]);
1838      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]);
1839      //--------------------- TABLE OF PERIODS WITH HV PROBLEMS ----------------------------
1840      
1841      int Aconn=conn[0];    // PMT 0,20,22,24
1842      int Bconn=conn[1];    // PMT 6,12,26,34
1843      int Cconn=conn[2];    // PMT 4,14,28,32
1844      int Dconn=conn[3];    // PMT 2,8,10,30
1845      int Econn=conn[4];    // PMT 42,43,44,47
1846      int Fconn=conn[5];    // PMT 7,19,23,27
1847      int Gconn=conn[6];    // PMT 3,11,25,33
1848      int Hconn=conn[7];    // PMT 1,9,13,21
1849      int Iconn=conn[8];    // PMT 5,29,31,35
1850      int Lconn=conn[9];    // PMT 37,40,45,46
1851      int Mconn=conn[10];    // PMT 15,16,17,18
1852      int Nconn=conn[11];    // PMT 36,38,39,41
1853      if( false ) cout << Gconn << Iconn << Lconn <<endl; // to avoid compilation warnings
1854        
1855      //  printf(" size %i \n",eDEDXpmt.GetSize());
1856      for( int ii=0; ii<48; ii++ ) {
1857        //
1858        //    eDEDXpmt.SetAt(-1.,ii);
1859        //    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]);
1860        if ( debug ) printf("II %i adc %f \n",ii,adc[ii]);
1861    
1862        if( adc[ii] >= 4095. ){
1863          //      eDEDXpmt[ii] = 0.;
1864          eDEDXpmt->AddAt(0.,ii);
1865          if ( debug ) printf(" %i adc>4095 \n",ii);
1866          continue; // EMILIANO
1867        };
1868    
1869        if( adc[ii] >= (PMTsat[ii]-5.) && adc[ii] < 4095. ){
1870          eDEDXpmt->AddAt(1000.,ii);
1871          if ( debug ) printf(" %i adc> pmtsat && adc<4095 \n",ii);
1872          continue; // EMILIANO
1873        };
1874    
1875        if( adc[ii] <= 0. ) {
1876          eDEDXpmt->AddAt(1500.,ii);
1877          if ( debug ) printf(" %i adc<=0 \n",ii);
1878          continue;
1879        };
1880        //
1881        double adcpC   = f_adcPC( adc[ii] );    // - adc conversion in pC
1882        if ( exitat == 0 ){
1883          eDEDXpmt->AddAt((Float_t)adcpC,ii);
1884          continue;
1885        }
1886        //    printf(" e qua? \n");
1887    
1888        double adccorr = adcpC*fabs(cos(theta));    
1889        if ( debug ) printf(" adccorr %f \n",adccorr);
1890        if(adccorr<=0.){
1891          if ( debug ) printf(" %i adccorr<=0 \n",ii);
1892          //      eDEDXpmt->AddAt((Float_t)adcpC,ii);//?
1893          continue;
1894        }
1895        if ( exitat == 1 ){
1896          eDEDXpmt->AddAt((Float_t)adccorr,ii);
1897          continue;
1898        }
1899        //    printf(" e quo? \n");
1900    
1901        //    int standard=0;
1902        int S115B_ok=0;
1903        int S115B_break=0;
1904    
1905        if(atime<1158720000)S115B_ok=1;
1906        else S115B_break=1;
1907    
1908    
1909        //------------------------------------------------------------------------
1910        //    printf(" e qui? \n");
1911        //---------------------------------------------------- Z reconstruction
1912    
1913        double adcHe, adcnorm, adclin, dEdx;//, Zeta; // EM GCC4.7
1914    
1915        adcHe=-2;
1916        adcnorm=-2;
1917        adclin=-2;
1918        dEdx=-2;
1919        //    Zeta=-2;//EM GCC4.7
1920        Double_t correction = 1.;
1921    
1922        if(Aconn==1 && (ii==0 || ii==20 || ii==22 || ii==24)){
1923          correction = 1.675;
1924        }
1925        else if(Bconn==1 && (ii==6 || ii==12 || ii==26 || ii==34)){
1926          correction = 2.482;
1927        }
1928        else if(Cconn==1 && (ii==4 || ii==14 || ii==28 || ii==32)){
1929          correction = 1.464;
1930        }
1931        else if(Dconn==1 && (ii==2 || ii==8 || ii==10 || ii==30)){
1932          correction = 1.995;
1933        }
1934        else if(Econn==1 && (ii==42 || ii==43 || ii==44 || ii==47)){
1935          correction = 1.273;
1936        }
1937        else if(Fconn==1 && (ii==7 || ii==19 || ii==23 || ii==27)){
1938          correction = 1.565;
1939        }
1940        else if(Mconn==1 && (ii==15 || ii==16 || ii==17 || ii==18)){
1941          correction = 1.565;
1942        }
1943        else if(Nconn==1 && (ii==36 || ii==38 || ii==39 || ii==41)){
1944          correction = 1.018;
1945        }
1946        else if(Hconn==1 && (ii==1 || ii==13 || ii==21 || (ii==9&&S115B_ok==1))){
1947          correction = 1.84;
1948        }
1949        else if(S115B_break==1 && ii==9 && Hconn==1){
1950          correction = 1.64;
1951        }
1952        else correction = 1.;
1953        
1954        if( ii==9 && S115B_break==1 ){
1955          adcHe   = f_att5B( ytr_tof[0] )/correction;
1956        } else {
1957          adcHe   = Get_adc_he(ii, xtr_tof, ytr_tof)/correction;
1958        };
1959        if(adcHe<=0){
1960          if ( debug ) printf(" %i adcHe<=0 \n",ii);
1961          //      eDEDXpmt->AddAt((Float_t)adccorr,ii); //?
1962          continue;
1963        }
1964        if ( exitat == 2 ){
1965          if(ii==9 && S115B_break==1)  eDEDXpmt->AddAt(36.*(Float_t)adccorr/adcHe,ii);
1966          else  adclin  = 4.*(Float_t)adccorr/adcHe;
1967          continue;
1968        }
1969    
1970        if(ii==9 && S115B_break==1)  adcnorm = f_pos5B(adccorr);
1971        else adcnorm = f_pos( (parPos[ii]), adccorr);
1972        if(adcnorm<=0){
1973          if ( debug ) printf(" %i adcnorm<=0 \n",ii);
1974          //      eDEDXpmt->AddAt((Float_t)adccorr,ii);//?
1975          continue;
1976        }
1977        if ( debug ) printf(" adcnorm %f \n",adcnorm);
1978    
1979        if(ii==9 && S115B_break==1)  adclin  = 36.*adcnorm/adcHe;
1980        else  adclin  = 4.*adcnorm/adcHe;
1981        if ( debug ) printf(" adclin %f \n",adclin);
1982        if(adclin<=0){
1983          if ( debug ) printf(" %i adclin<=0 \n",ii);
1984          //      eDEDXpmt->AddAt((Float_t)adccorr,ii);//?
1985          continue;
1986        }
1987        if ( exitat == 3 ){
1988          if(ii==9 && S115B_break==1)  eDEDXpmt->AddAt((Float_t)adclin,ii);
1989          else  eDEDXpmt->AddAt((Float_t)adclin,ii);
1990          continue;
1991        }
1992        //
1993        if ( betamean > 99. ){
1994          //      eDEDXpmt.AddAt((Float_t)adclin,ii);
1995          eDEDXpmt->AddAt((Float_t)adclin,ii);
1996          //      printf(" AAPMT IS %i dedx is %f vector is %f \n",ii,adclin,eDEDXpmt[ii]);
1997          if ( debug ) printf(" %i betamean > 99 \n",ii);
1998          continue;
1999        };
2000        //
2001        double dEdxHe=-2;
2002        if(ii==9 && S115B_break==1){
2003          if( betamean <1. ) dEdxHe = f_BB5B( betamean );
2004          else                       dEdxHe = 33;
2005        } else {
2006          if( betamean <1. ) dEdxHe = f_BB( (parBBneg[ii]), betamean );
2007          else                       dEdxHe = parBBpos[ii];
2008        }
2009        
2010        if ( debug ) printf(" dEdxHe %f \n",dEdxHe);
2011            
2012    l2->npmt = PMT->GetEntries();      if(dEdxHe<=0){
2013     for(Int_t j=0;j<l2->npmt;j++){        eDEDXpmt->AddAt((Float_t)adclin,ii);
2014       l2->pmt_id[j] = ((ToFPMT*)PMT->At(j))->pmt_id;        if ( debug ) printf(" %i dEdxHe<=0 \n",ii);
2015       l2->adc[j] =((ToFPMT*)PMT->At(j))->adc;        continue;
2016       l2->tdc_tw[j] =((ToFPMT*)PMT->At(j))->tdc_tw;      };
2017     }  
2018        if(ii==9 && S115B_break==1)  dEdx = f_desatBB5B( adclin );
2019        else  dEdx = f_desatBB((parDesatBB[ii]), adclin );
2020    
2021        if(dEdx<=0){
2022          eDEDXpmt->AddAt((Float_t)adclin,ii);
2023          if ( debug ) printf(" %i dEdx<=0 \n",ii);
2024          continue;
2025        };
2026    
2027        if ( debug ) printf(" dEdx %f \n",dEdx);
2028        eDEDXpmt->AddAt((Float_t)dEdx,ii);
2029        //    eDEDXpmt.AddAt((Float_t)dEdx,ii);
2030    
2031        //    printf(" PMT IS %i dedx is %f vector is %f \n",ii,dEdx,eDEDXpmt[ii]);
2032    
2033      }  //end loop on 48 PMT
2034    
2035    };
2036    
2037    
2038    //------------------------------------------------------------------------
2039    void ToFdEdx::Define_PMTsat()
2040    {
2041      Float_t  sat[48] = {
2042        3176.35,3178.19,3167.38,3099.73,3117.00,3126.29,3111.44,3092.27,
2043        3146.48,3094.41,3132.13,3115.37,3099.32,3110.97,3111.80,3143.14,
2044        3106.72,3153.44,3136.00,3188.96,3104.73,3140.45,3073.18,3106.62,
2045        3112.48,3146.92,3127.24,3136.52,3109.59,3112.89,3045.15,3147.26,
2046        3095.92,3121.05,3083.25,3123.62,3150.92,3125.30,3067.60,3160.18,
2047        3119.36,3108.92,3164.77,3133.64,3111.47,3131.98,3128.87,3135.56 };
2048      PMTsat.Set(48,sat);
2049    }
2050    
2051    //------------------------------------------------------------------------
2052    void ToFdEdx::ReadParBBpos( const char *fname )
2053    {
2054      //  printf("read %s\n",fname);
2055      parBBpos.Set(48);
2056      FILE *fattin = fopen( fname , "r" );
2057      for (int i=0; i<48; i++) {
2058        int   tid=0;
2059        float  tp;
2060        if(fscanf(fattin,"%d %f",
2061                  &tid, &tp )!=2) break;
2062        parBBpos[i]=tp;
2063      }
2064      fclose(fattin);
2065    }
2066    
2067    //------------------------------------------------------------------------
2068    void ToFdEdx::ReadParDesatBB( const char *fname )
2069    {
2070      //  printf("read %s\n",fname);
2071      FILE *fattin = fopen( fname , "r" );
2072      for (int i=0; i<48; i++) {
2073        int   tid=0;
2074        float  tp[3];
2075        if(fscanf(fattin,"%d %f %f %f",
2076                  &tid, &tp[0], &tp[1], &tp[2] )!=4) break;
2077        parDesatBB[i].Set(3,tp);
2078      }
2079      fclose(fattin);
2080    }
2081    
2082    
2083    //------------------------------------------------------------------------
2084    void ToFdEdx::ReadParBBneg( const char *fname )
2085    
2086    {
2087      //  printf("read %s\n",fname);
2088      FILE *fattin = fopen( fname , "r" );
2089      for (int i=0; i<48; i++) {
2090        int   tid=0;
2091        float  tp[3];
2092        if(fscanf(fattin,"%d %f %f %f",
2093                  &tid, &tp[0], &tp[1], &tp[2] )!=4) break;
2094        parBBneg[i].Set(3,tp);
2095      }
2096      fclose(fattin);
2097  }  }
2098    
2099    //------------------------------------------------------------------------
2100    void ToFdEdx::ReadParPos( const char *fname )
2101    {
2102      //  printf("read %s\n",fname);
2103      FILE *fattin = fopen( fname , "r" );
2104      for (int i=0; i<48; i++) {
2105        int   tid=0;
2106        float  tp[4];
2107        if(fscanf(fattin,"%d %f %f %f %f",
2108                  &tid, &tp[0], &tp[1], &tp[2], &tp[3])!=5) break;
2109        parPos[i].Set(4,tp);
2110      }
2111      fclose(fattin);
2112    }
2113    
2114    //------------------------------------------------------------------------
2115    void ToFdEdx::ReadParAtt( const char *fname )
2116    {
2117      //  printf("read %s\n",fname);
2118      FILE *fattin = fopen( fname , "r" );
2119      for (int i=0; i<48; i++) {
2120        int   tid=0;
2121        float  tp[6];
2122        if(fscanf(fattin,"%d %f %f %f %f %f %f",
2123                  &tid, &tp[0], &tp[1], &tp[2], &tp[3], &tp[4], &tp[5] )!=7) break;
2124        parAtt[i].Set(6,tp);
2125      }
2126      fclose(fattin);
2127    }
2128    
2129    
2130    
2131    
2132    
2133    
2134    double ToFdEdx::f_att( TArrayF &p, float x )
2135    {
2136      return
2137        p[0] +
2138        p[1]*x +
2139        p[2]*x*x +
2140        p[3]*x*x*x +
2141        p[4]*x*x*x*x +
2142        p[5]*x*x*x*x*x;
2143    }
2144    //------------------------------------------------------------------------
2145    double ToFdEdx::f_att5B( float x )
2146    {
2147      return
2148        101.9409 +
2149        6.643781*x +
2150        0.2765518*x*x +
2151        0.004617647*x*x*x +
2152        0.0006195132*x*x*x*x +
2153        0.00002813734*x*x*x*x*x;
2154    }
2155    
2156    
2157    double ToFdEdx::f_pos( TArrayF &p, float x )
2158    {
2159      return
2160        p[0] +
2161        p[1]*x +
2162        p[2]*x*x +
2163        p[3]*x*x*x;
2164    }
2165    
2166    double ToFdEdx::f_pos5B( float x )
2167    {
2168      return
2169        15.45132 +
2170        0.8369721*x +
2171        0.0005*x*x;
2172    }
2173    
2174    
2175    
2176    double ToFdEdx::f_adcPC( float x )
2177    {
2178      return 28.12+0.6312*x-5.647e-05*x*x+3.064e-08*x*x*x;
2179    }
2180    
2181    
2182    float ToFdEdx::Get_adc_he( int id, float pl_x[6], float pl_y[6])
2183    {
2184    
2185      //
2186      // input: id - pmt [0:47}
2187      //             pl_x - coord x of the tof plane
2188      //             pl_y - coord y
2189    
2190      adc_he = 0;
2191      if( eGeom.GetXY(id)==1 )  adc_he = f_att( (parAtt[id]), pl_x[eGeom.GetPlane(id)] );
2192      if( eGeom.GetXY(id)==2 )  adc_he = f_att( (parAtt[id]), pl_y[eGeom.GetPlane(id)] );
2193      return adc_he;
2194    }
2195    
2196    //------------------------------------------------------------------------
2197    double ToFdEdx::f_BB( TArrayF &p, float x )
2198    {
2199      return  p[0]/(x*x)*(log(x*x/(1-x*x)) - p[1]*x*x - p[2]);
2200    }
2201    
2202    //------------------------------------------------------------------------
2203    double ToFdEdx::f_BB5B( float x )
2204    {
2205      return  0.165797/(x*x)*(log(x*x/(1-x*x)) + 140.481*x*x + 52.9258);
2206    }
2207    //------------------------------------------------------------------------
2208    double ToFdEdx::f_desatBB( TArrayF &p, float x )
2209    {
2210      return
2211        p[0] +
2212        p[1]*x +
2213        p[2]*x*x;
2214    }
2215    
2216    //------------------------------------------------------------------------
2217    double ToFdEdx::f_desatBB5B( float x )
2218    {
2219      return
2220        -2.4 +
2221        0.75*x +
2222        0.009*x*x;
2223    }
2224    

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