/[PAMELA software]/DarthVader/ToFLevel2/src/ToFLevel2.cpp

Diff of /DarthVader/ToFLevel2/src/ToFLevel2.cpp

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-revision 1.17 by mocchiut,
Wed Oct 10 16:01:33 2007 UTC
+revision 1.21 by mocchiut,
Fri Apr 18 18:55:53 2008 UTC
 Line 3
   * \author Gianfranca DeRosa, Wolfgang Menn
   */
- #include <TObject.h>
  #include <ToFLevel2.h>
- #include <iostream>
  using namespace std;
  ClassImp(ToFPMT);
  ClassImp(ToFTrkVar);
  ClassImp(ToFLevel2);
 Line 25 
 ToFPMT::ToFPMT(const ToFPMT &t){
    tdc = t.tdc;
  }
- void ToFPMT::Clear(){
+ void ToFPMT::Clear(Option_t *t){
    pmt_id = 0;
    adc = 0.;
    tdc_tw = 0.;
 Line 53 
 ToFTrkVar::ToFTrkVar() {
    //
  };
- void ToFTrkVar::Clear() {
+ void ToFTrkVar::Clear(Option_t *t) {
    trkseqno = 0;
    npmttdc = 0;
    npmtadc = 0;
 Line 107 
 void ToFLevel2::Set(){//ELENA
      if(!ToFTrk)ToFTrk = new TClonesArray("ToFTrkVar",2); //ELENA
  }//ELENA
- void ToFLevel2::Clear(){
+ void ToFLevel2::Clear(Option_t *t){
    //
    if(ToFTrk)ToFTrk->Delete(); //ELENA
    if(PMT)PMT->Delete(); //ELENA
 Line 116 
 void ToFLevel2::Clear(){
    //
  };
- void ToFLevel2::Delete(){ //ELENA
+ void ToFLevel2::Delete(Option_t *t){ //ELENA
    //
    if(ToFTrk){
        ToFTrk->Delete(); //ELENA
 Line 696 
 void ToFLevel2::GetPMTPaddle(Int_t pmt_i
  // gf Apr 07
  void ToFLevel2::GetPaddlePMT(Int_t paddle, Int_t &pmtleft, Int_t &pmtright){
+   pmtleft=paddle*2;
-   if(paddle==0){
+   pmtright= pmtleft+1;
-     pmtleft=0;
-     pmtright=1;
-   }
-   if(paddle==1){
-     pmtleft=2;
-     pmtright=3;
-   }
-   if(paddle==2){
-     pmtleft=4;
-     pmtright=5;
-   }
-   if(paddle==3){
-     pmtleft=6;
-     pmtright=7;
-   }
-   if(paddle==4){
-     pmtleft=8;
-     pmtright=9;
-   }
-   if(paddle==5){
-     pmtleft=10;
-     pmtright=11;
-   }
-   if(paddle==6){
-     pmtleft=12;
-     pmtright=13;
-   }
-   if(paddle==7){
-     pmtleft=14;
-     pmtright=15;
-   }
-   if(paddle==8){
-     pmtleft=16;
-     pmtright=17;
-   }
-   if(paddle==9){
-     pmtleft=18;
-     pmtright=19;
-   }
-   if(paddle==10){
-     pmtleft=20;
-     pmtright=21;
-   }
-   if(paddle==11){
-     pmtleft=22;
-     pmtright=23;
-   }
-   if(paddle==12){
-     pmtleft=24;
-     pmtright=25;
-   }
-   if(paddle==13){
-     pmtleft=26;
-     pmtright=27;
-   }
-   if(paddle==14){
-     pmtleft=28;
-     pmtright=29;
-   }
-   if(paddle==15){
-     pmtleft=30;
-     pmtright=31;
-   }
-   if(paddle==16){
-     pmtleft=32;
-     pmtright=33;
-   }
-   if(paddle==17){
-     pmtleft=34;
-     pmtright=35;
-   }
-   if(paddle==18){
-     pmtleft=36;
-     pmtright=37;
-   }
-   if(paddle==19){
-     pmtleft=38;
-     pmtright=39;
-   }
-   if(paddle==20){
-     pmtleft=40;
-     pmtright=41;
-   }
-   if(paddle==21){
-     pmtleft=42;
-     pmtright=43;
-   }
-   if(paddle==22){
-     pmtleft=44;
-     pmtright=45;
-   }
-   if(paddle==23){
-     pmtleft=46;
-     pmtright=47;
-   }
    return;
  }
-Line 930 
 void ToFLevel2::GetPaddleGeometry(Int_t
+Line 811 
 void ToFLevel2::GetPaddleGeometry(Int_t
   */
  Int_t ToFLevel2::GetPaddleid(Int_t plane, Int_t paddle)
  {
    Int_t padid=-1;
-   Int_t pads11=8;
+   Int_t pads[6]={8,6,2,2,3,3};
-   Int_t pads12=6;
-   Int_t pads21=2;
-   Int_t pads22=2;
-   Int_t pads31=3;
-   //  Int_t pads32=3;
-   if(plane == 0){
+   int somma=0;
-     padid=paddle;
+   int np=plane;
-   }
+   for(Int_t j=0; j<np; j++){
+     somma+=pads[j];
-   if(plane == 1){
-     padid=pads11+paddle;
    }
+   padid=paddle+somma;
-   if(plane == 2){
-     padid=pads11+pads12+paddle;
-   }
-   if(plane == 3){
-     padid=pads11+pads12+pads21+paddle;
-   }
-   if(plane == 4){
-     padid=pads11+pads12+pads21+pads22+paddle;
-   }
-   if(plane == 5){
-     padid=pads11+pads12+pads21+pads22+pads31+paddle;
-   }
    return padid;
  }
-Line 1049 
 Int_t ToFLevel2::GetNPaddle(Int_t plane)
+Line 904 
 Int_t ToFLevel2::GetNPaddle(Int_t plane)
  }
+ /// wm feb 08
+ /**
+  * Method to calculate Beta from the 12 single measurements
+  * we check the individual weights for artificial TDC values, then calculate
+  * am mean beta for the first time. In a second step we loop again through
+  * the single measurements, checking for the residual from the mean
+  * The cut on the residual reject measurements > "x"-sigma. A chi2 value is
+  * calculated, furthermore a "quality" value by adding the weights which
+  * are finally used. If all measurements are taken, "quality" will be = 22.47.
+  * A chi2 cut around 3-4 and a quality-cut > 20 is needed for clean beta
+  * measurements like antiprotons etc.
+  * The Level2 output is derived in the fortran routines using: 10.,10.,20.
+  * @param notrack Track Number
+  * @param cut on residual: difference between single measurement and mean
+  * @param cut on "quality"
+  * @param cut on chi2
+  */
+ Float_t ToFLevel2::CalcBeta(Int_t notrack, Float_t resmax, Float_t qualitycut, Float_t chi2cut){
+ //  cout<<" in CalcBeta "<<resmax<<" "<<chi2cut<<" "<<qualitycut<<endl;
+   Float_t bxx = 100.;
+   //
+   ToFTrkVar *trk = GetToFTrkVar(notrack);
+   if(!trk) return 0; //ELENA
+   Float_t chi2,xhelp,beta_mean;
+   Float_t w_i[12],quality,sw,sxw,res,betachi,beta_mean_inv;
+   Float_t b[12],tdcfl;
+   Int_t  pmt_id,pmt_plane;
+   for (Int_t i=0; i<12; i++){
+     b[i] = trk->beta[i];
+                               }
+ //========================================================================
+ //---  Find out ToF layers with artificial TDC values & fill vector    ---
+ //========================================================================
+ Float_t  w_il[6];
+      for (Int_t jj=0; jj<6;jj++) {
+          w_il[jj] = 1000.;
+                                  }
+   for (Int_t i=0; i<trk->npmttdc; i++){
+     //
+     pmt_id = (trk->pmttdc).At(i);
+     pmt_plane = GetPlaneIndex(pmt_id);
+     tdcfl = (trk->tdcflag).At(i);
+     if (w_il[pmt_plane] != 1.) w_il[pmt_plane] = tdcfl; //tdcflag
+                                      };
+ //========================================================================
+ //---  Set weights for the 12 measurements using information for top and bottom:
+ //---  if no measurements: weight = set to very high value=> not used
+ //---  top or bottom artificial: weight*sqrt(2)
+ //---  top and bottom artificial: weight*sqrt(2)*sqrt(2)
+ //========================================================================
+ Int_t itop[12] = {0,0,1,1,2,2,3,3,0,0,1,1};
+ Int_t ibot[12] = {4,5,4,5,4,5,4,5,2,3,2,3};
+      xhelp= 1E09;
+      for (Int_t jj=0; jj<12;jj++) {
+      if (jj<4)           xhelp = 0.11;    // S1-S3
+      if ((jj>3)&&(jj<8)) xhelp = 0.18;    // S2-S3
+      if (jj>7)           xhelp = 0.28;    // S1-S2
+      if ((w_il[itop[jj]] == 1000.) && (w_il[ibot[jj]] == 1000.)) xhelp = 1E09;
+      if ((w_il[itop[jj]] == 1) || (w_il[ibot[jj]] == 1.)) xhelp = xhelp*1.414 ;
+      if ((w_il[itop[jj]] == 1) && (w_il[ibot[jj]] == 1.)) xhelp = xhelp*2. ;
+      w_i[jj] = 1./xhelp;
+                                   }
+ //========================================================================
+ //--- Calculate mean beta for the first time -----------------------------
+ //--- We are using "1/beta" since its error is gaussian ------------------
+ //========================================================================
+       Int_t icount=0;
+       sw=0.;
+       sxw=0.;
+       beta_mean=100.;
+           for (Int_t jj=0; jj<12;jj++){
+         if ((fabs(1./b[jj])>0.1)&&(fabs(1./b[jj])<15.))
+          {
+             icount= icount+1;
+             sxw=sxw + (1./b[jj])*w_i[jj]*w_i[jj] ;
+             sw =sw + w_i[jj]*w_i[jj] ;
+          }
+          }
+       if (icount>0) beta_mean=1./(sxw/sw);
+       beta_mean_inv = 1./beta_mean;
+ //========================================================================
+ //--- Calculate beta for the second time, use residuals of the single
+ //--- measurements to get a chi2 value
+ //========================================================================
+       icount=0;
+       sw=0.;
+       sxw=0.;
+       betachi = 100.;
+       chi2 = 0.;
+       quality=0.;
+           for (Int_t jj=0; jj<12;jj++){
+        if ((fabs(1./b[jj])>0.1)&&(fabs(1./b[jj])<15.)&&(w_i[jj]>0.01)) {
+             res = beta_mean_inv - (1./b[jj]) ;
+             if (fabs(res*w_i[jj])<resmax)          {;
+             chi2 = chi2 + pow((res*w_i[jj]),2) ;
+             icount= icount+1;
+             sxw=sxw + (1./b[jj])*w_i[jj]*w_i[jj] ;
+             sw =sw + w_i[jj]*w_i[jj] ;
+                                                }
+                                                                         }
+                                       }
+       quality = sqrt(sw) ;
+       if (icount==0) chi2 = 1000.;
+       if (icount>0) chi2 = chi2/(icount) ;
+       if (icount>0) betachi=1./(sxw/sw);
+    bxx = 100.;
+    if ((chi2 < chi2cut)&&(quality>qualitycut)) bxx = betachi;
+   //
+   return(bxx);
+ };
+ ////////////////////////////////////////////////////
  ////////////////////////////////////////////////////
-Line 1099 
 void ToFLevel2::GetLevel2Struct(cToFLeve
+Line 1097 
 void ToFLevel2::GetLevel2Struct(cToFLeve
        }
    } //ELENA
  }
+ //
+ // Reprocessing tool // Emiliano 08/04/07
+ //
+ Int_t ToFLevel2::Process(TrkLevel2 *trk, TrigLevel2 *trg, GL_RUN *run, OrbitalInfo *orb, Bool_t force){
+   //
+   // Copiare qui qualcosa di simile a calonuclei per evitare di riprocessare sempre tutto
+   //
+   //
+   // structures to communicate with F77
+   //
+   extern struct ToFInput  tofinput_;
+   extern struct ToFOutput tofoutput_;
+   //
+   // DB connection
+   //
+   TString host;
+   TString user;
+   TString psw;
+   const char *pamdbhost=gSystem->Getenv("PAM_DBHOST");
+   const char *pamdbuser=gSystem->Getenv("PAM_DBUSER");
+   const char *pamdbpsw=gSystem->Getenv("PAM_DBPSW");
+   if ( !pamdbhost ) pamdbhost = "";
+   if ( !pamdbuser ) pamdbuser = "";
+   if ( !pamdbpsw ) pamdbpsw = "";
+   if ( strcmp(pamdbhost,"") ) host = pamdbhost;
+   if ( strcmp(pamdbuser,"") ) user = pamdbuser;
+   if ( strcmp(pamdbpsw,"") ) psw = pamdbpsw;
+   //
+   //
+   TSQLServer *dbc = TSQLServer::Connect(host.Data(),user.Data(),psw.Data());
+   if ( !dbc->IsConnected() ) return 1;
+   stringstream myquery;
+   myquery.str("");
+   myquery << "SET time_zone='+0:00'";
+   dbc->Query(myquery.str().c_str());
+   GL_PARAM *glparam = new GL_PARAM();
+   glparam->Query_GL_PARAM(1,1,dbc); // parameters stored in DB in GL_PRAM table
+   trk->LoadField(glparam->PATH+glparam->NAME);
+   //
+   Bool_t defcal = true;
+   Int_t error=glparam->Query_GL_PARAM(run->RUNHEADER_TIME,201,dbc); // parameters stored in DB in GL_PRAM table
+   if ( error<0 ) {
+     return(1);
+   };
+   printf(" Reading ToF parameter file: %s \n",(glparam->PATH+glparam->NAME).Data());
+   if ( (UInt_t)glparam->TO_TIME != (UInt_t)4294967295UL ) defcal = false;
+   //
+   Int_t nlen = (Int_t)(glparam->PATH+glparam->NAME).Length();
+   rdtofcal((char *)(glparam->PATH+glparam->NAME).Data(),&nlen);
+   //
+   Int_t adc[4][12];
+   Int_t tdc[4][12];
+   Float_t tdcc[4][12];
+   //
+   // process tof data
+   //
+   for (Int_t hh=0; hh<12;hh++){
+     for (Int_t kk=0; kk<4;kk++){
+            adc[kk][hh] = 4095;
+            tdc[kk][hh] = 4095;
+            tdcc[kk][hh] = 4095.;
+            tofinput_.adc[hh][kk] = 4095;
+            tofinput_.tdc[hh][kk] = 4095;
+     };
+   };
+   Int_t ntrkentry = 0;
+   Int_t npmtentry = 0;
+   Int_t gg = 0;
+   Int_t hh = 0;
+   Int_t adcf[48];
+   memset(adcf, 0, 48*sizeof(Int_t));
+   Int_t tdcf[48];
+   memset(tdcf, 0, 48*sizeof(Int_t));
+   for (Int_t pm=0; pm < this->ntrk() ; pm++){
+      ToFTrkVar *ttf = this->GetToFTrkVar(pm);
+      for ( Int_t nc=0; nc < ttf->npmttdc; nc++){
+             if ( (ttf->tdcflag).At(nc) != 0 ) tdcf[(ttf->pmttdc).At(nc)] = 1;
+      };
+      for ( Int_t nc=0; nc < ttf->npmtadc; nc++){
+             if ( (ttf->adcflag).At(nc) != 0 ) adcf[(ttf->pmtadc).At(nc)] = 1;
+      };
+   };
+   //
+   for (Int_t pm=0; pm < this->npmt() ; pm++){
+      ToFPMT *pmt = this->GetToFPMT(pm);
+      this->GetPMTIndex(pmt->pmt_id, gg, hh);
+      if ( adcf[pmt->pmt_id] == 0 ){
+              tofinput_.adc[gg][hh] = (int)pmt->adc;
+              adc[hh][gg] = (int)pmt->adc;
+      };
+      if ( tdcf[pmt->pmt_id] == 0 ){
+              tofinput_.tdc[gg][hh] = (int)pmt->tdc;
+              tdc[hh][gg] = (int)pmt->tdc;
+      };
+      tdcc[hh][gg] = (float)pmt->tdc_tw;
+      // Int_t pppid = this->GetPMTid(hh,gg);
+      //      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);
+   };
+   //
+   Int_t unpackError = this->unpackError;
+   //
+   for (Int_t hh=0; hh<5;hh++){
+      tofinput_.patterntrig[hh]=trg->patterntrig[hh];
+   };
+   //
+   this->Clear();
+   //
+       Int_t pmt_id = 0;
+       ToFPMT *t_pmt = new ToFPMT();
+       if(!(this->PMT)) this->PMT = new TClonesArray("ToFPMT",12); //ELENA
+       TClonesArray &tpmt = *this->PMT;
+       ToFTrkVar *t_tof = new ToFTrkVar();
+       if(!(this->ToFTrk)) this->ToFTrk = new TClonesArray("ToFTrkVar",2); //ELENA
+       TClonesArray &t = *this->ToFTrk;
+       //
+       //
+       // Here we have calibrated data, ready to be passed to the FORTRAN routine which will extract common and track-related  variables.
+       //
+       npmtentry = 0;
+       //
+       ntrkentry = 0;
+       //
+       // Calculate tracks informations from ToF alone
+       //
+       tofl2com();
+       //
+       memcpy(this->tof_j_flag,tofoutput_.tof_j_flag,6*sizeof(Int_t));
+       //
+       t_tof->trkseqno = -1;
+       //
+       // and now we must copy from the output structure to the level2 class:
+       //
+       t_tof->npmttdc = 0;
+       //
+       for (Int_t hh=0; hh<12;hh++){
+         for (Int_t kk=0; kk<4;kk++){
+           if ( tofoutput_.tofmask[hh][kk] != 0 ){
+             pmt_id = this->GetPMTid(kk,hh);
+             t_tof->pmttdc.AddAt(pmt_id,t_tof->npmttdc);
+             t_tof->tdcflag.AddAt(tofoutput_.tdcflagtof[hh][kk],t_tof->npmttdc); // gf: Jan 09/07
+             t_tof->npmttdc++;
+           };
+         };
+       };
+       for (Int_t kk=0; kk<13;kk++){
+         t_tof->beta[kk] = tofoutput_.betatof_a[kk];
+       }
+       //
+       t_tof->npmtadc = 0;
+       for (Int_t hh=0; hh<12;hh++){
+         for (Int_t kk=0; kk<4;kk++){
+           if ( tofoutput_.adctof_c[hh][kk] < 1000 ){
+             t_tof->dedx.AddAt(tofoutput_.adctof_c[hh][kk],t_tof->npmtadc);
+             pmt_id = this->GetPMTid(kk,hh);
+             t_tof->pmtadc.AddAt(pmt_id,t_tof->npmtadc);
+             t_tof->adcflag.AddAt(tofoutput_.adcflagtof[hh][kk],t_tof->npmtadc); // gf: Jan 09/07
+             t_tof->npmtadc++;
+           };
+         };
+       };
+       //
+       memcpy(t_tof->xtofpos,tofoutput_.xtofpos,sizeof(t_tof->xtofpos));
+       memcpy(t_tof->ytofpos,tofoutput_.ytofpos,sizeof(t_tof->ytofpos));
+       memcpy(t_tof->xtr_tof,tofoutput_.xtr_tof,sizeof(t_tof->xtr_tof));
+       memcpy(t_tof->ytr_tof,tofoutput_.ytr_tof,sizeof(t_tof->ytr_tof));
+       //
+       new(t[ntrkentry]) ToFTrkVar(*t_tof);
+       ntrkentry++;
+       t_tof->Clear();
+       //
+       //
+       //
+       t_pmt->Clear();
+       //
+       for (Int_t hh=0; hh<12;hh++){
+         for (Int_t kk=0; kk<4;kk++){
+          // new WM
+           if ( tofoutput_.tdc_c[hh][kk] < 4095 || adc[kk][hh] < 4095  || tdc[kk][hh] < 4095 ){
+ //          if ( tdcc[kk][hh] < 4095. || adc[kk][hh] < 4095  || tdc[kk][hh] < 4095 ){
+             //
+             t_pmt->pmt_id = this->GetPMTid(kk,hh);
+             t_pmt->tdc_tw = tofoutput_.tdc_c[hh][kk];
+             t_pmt->adc = (Float_t)adc[kk][hh];
+             t_pmt->tdc = (Float_t)tdc[kk][hh];
+             //
+             new(tpmt[npmtentry]) ToFPMT(*t_pmt);
+             npmtentry++;
+             t_pmt->Clear();
+           };
+         };
+       };
+       //
+       // Calculate track-related variables
+       //
+       if ( trk->ntrk() > 0 ){
+         //
+         // We have at least one track
+         //
+         //
+         // Run over tracks
+         //
+         for(Int_t nt=0; nt < trk->ntrk(); nt++){
+           //
+           TrkTrack *ptt = trk->GetStoredTrack(nt);
+           //
+           // Copy the alpha vector in the input structure
+           //
+           for (Int_t e = 0; e < 5 ; e++){
+             tofinput_.al_pp[e] = ptt->al[e];
+           };
+           //
+           // Get tracker related variables for this track
+           //
+           toftrk();
+           //
+           // Copy values in the class from the structure (we need to use a temporary class to store variables).
+           //
+           t_tof->npmttdc = 0;
+           for (Int_t hh=0; hh<12;hh++){
+             for (Int_t kk=0; kk<4;kk++){
+               if ( tofoutput_.tofmask[hh][kk] != 0 ){
+                 pmt_id = this->GetPMTid(kk,hh);
+                 t_tof->pmttdc.AddAt(pmt_id,t_tof->npmttdc);
+                 t_tof->tdcflag.AddAt(tofoutput_.tdcflag[hh][kk],t_tof->npmttdc); // gf: Jan 09/07
+                 t_tof->npmttdc++;
+               };
+             };
+           };
+           for (Int_t kk=0; kk<13;kk++){
+             t_tof->beta[kk] = tofoutput_.beta_a[kk];
+           };
+           //
+           t_tof->npmtadc = 0;
+           for (Int_t hh=0; hh<12;hh++){
+             for (Int_t kk=0; kk<4;kk++){
+               if ( tofoutput_.adc_c[hh][kk] < 1000 ){
+                 t_tof->dedx.AddAt(tofoutput_.adc_c[hh][kk],t_tof->npmtadc);
+                 pmt_id = this->GetPMTid(kk,hh);
+                 t_tof->pmtadc.AddAt(pmt_id,t_tof->npmtadc);
+                 t_tof->adcflag.AddAt(tofoutput_.adcflag[hh][kk],t_tof->npmtadc); // gf: Jan 09/07
+                 t_tof->npmtadc++;
+               };
+             };
+           };
+           //
+           memcpy(t_tof->xtofpos,tofoutput_.xtofpos,sizeof(t_tof->xtofpos));
+           memcpy(t_tof->ytofpos,tofoutput_.ytofpos,sizeof(t_tof->ytofpos));
+           memcpy(t_tof->xtr_tof,tofoutput_.xtr_tof,sizeof(t_tof->xtr_tof));
+           memcpy(t_tof->ytr_tof,tofoutput_.ytr_tof,sizeof(t_tof->ytr_tof));
+           //
+           // Store the tracker track number in order to be sure to have shyncronized data during analysis
+           //
+           t_tof->trkseqno = nt;
+           //
+           // create a new object for this event with track-related variables
+           //
+           new(t[ntrkentry]) ToFTrkVar(*t_tof);
+           ntrkentry++;
+           t_tof->Clear();
+           //
+         }; // loop on all the tracks
+       //
+       this->unpackError = unpackError;
+       if ( defcal ){
+         this->default_calib = 1;
+       } else {
+         this->default_calib = 0;
+       };
+  };
+   return(0);
+ }

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