/[PAMELA software]/DarthVader/TrackerLevel2/src/TrkLevel1.cpp

Diff of /DarthVader/TrackerLevel2/src/TrkLevel1.cpp

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-revision 1.2 by pam-fi,
Thu Sep 28 14:04:39 2006 UTC
+revision 1.21 by pam-fi,
Wed Aug 22 07:03:45 2007 UTC
 Line 5
  #include <TrkLevel1.h>
  #include <iostream>
  using namespace std;
+ //......................................
+ // F77 routines
+ //......................................
+ extern "C" {
+ //      int readetaparam_();
+     float cog_(int*,int*);
+     float pfaeta_(int*,float*);
+     float pfaeta2_(int*,float*);
+     float pfaeta3_(int*,float*);
+     float pfaeta4_(int*,float*);
+     float pfaetal_(int*,float*);
+ }
  //--------------------------------------
  //
  //
  //--------------------------------------
  TrkCluster::TrkCluster(){
-         view     = 0;
+ //    cout << "TrkCluster::TrkCluster()"<<endl;
-         maxs     = 0;
+     view     = -1;
-         indmax   = 0;
+     maxs     = -1;
+     indmax   = -1;
-         CLlength = 0;
-         clsignal = 0;
+     CLlength = 0;
-         clsigma  = 0;
+     clsignal = 0;
-         cladc    = 0;
+     clsigma  = 0;
-         clbad    = 0;
+     cladc    = 0;
+     clbad    = 0;
  };
  //--------------------------------------
  //
  //
  //--------------------------------------
- TrkCluster::~TrkCluster(){
-         delete [] clsignal;
-         delete [] clsigma;
-         delete [] cladc;
-         delete [] clbad;
- };
- //--------------------------------------
- //
- //
- //--------------------------------------
  TrkCluster::TrkCluster(const TrkCluster& t){
-         view     = t.view;
+     view     = t.view;
-         maxs     = t.maxs;
+     maxs     = t.maxs;
-         indmax   = t.indmax;
+     indmax   = t.indmax;
-         CLlength = t.CLlength;
+     CLlength = t.CLlength;
+     if(CLlength){
          clsignal = new Float_t[CLlength];
          clsigma  = new Float_t[CLlength];
          cladc    = new Int_t[CLlength];
          clbad    = new Bool_t[CLlength];
          for(Int_t i=0; i<CLlength;i++){
-                 clsignal[i] = t.clsignal[i];
+             clsignal[i] = t.clsignal[i];
-                 clsigma[i]  = t.clsigma[i];
+             clsigma[i]  = t.clsigma[i];
-                 cladc[i]    = t.cladc[i];
+             cladc[i]    = t.cladc[i];
-                 clbad[i]    = t.clbad[i];
+             clbad[i]    = t.clbad[i];
          };
+     };
+ };
+ //--------------------------------------
+ //
+ //
+ //--------------------------------------
+ void TrkCluster::Clear(){
+ //    cout << "void TrkCluster::Clear()"<<endl;
+     if(CLlength){
+         delete [] clsignal;
+         delete [] clsigma;
+         delete [] cladc;
+         delete [] clbad;
+     }
+     view     = 0;
+     maxs     = 0;
+     indmax   = 0;
+     CLlength = 0;
+     clsignal = 0;
+     clsigma  = 0;
+     cladc    = 0;
+     clbad    = 0;
  };
  //--------------------------------------
-Line 61 
 TrkCluster::TrkCluster(const TrkCluster&
+Line 91 
 TrkCluster::TrkCluster(const TrkCluster&
  //
  //--------------------------------------
  /**
-  * Evaluate the cluster signal.
+  * Evaluate the cluster signal including a maximum number of adjacent
-  * @param cut Inclusion cut.
+  * strips, around maxs, having a significant signal.
+  * @param nstrip   Maximum number of strips.
+  * @param cut      Inclusion cut ( s > cut*sigma ).
+  * If nstrip<=0 only the inclusion cut is used to determine the cluster size.
   */
- Float_t TrkCluster::GetSignal(Float_t cut){
+ Float_t TrkCluster::GetSignal(Int_t nstrip, Float_t cut){
-         Float_t s = 0;
-         for(Int_t is = 0; is < CLlength; is++){
+     if(CLlength<=0)return 0;
-                 Float_t scut = cut*clsigma[is];
-                 if(clsignal[is] > scut) s += clsignal[is];
+     Float_t s = 0;
+     if( nstrip<=0 ){
+ //          for(Int_t is = 0; is < CLlength; is++){
+ //              Float_t scut = cut*clsigma[is];
+ //              if(clsignal[is] > scut) s += clsignal[is];
+ //          };
+         for(Int_t is = indmax+1; is < CLlength; is++){
+             Float_t scut = cut*clsigma[is];
+             if(clsignal[is] > scut) s += clsignal[is];
+             else break;
+         };
+         for(Int_t is = indmax; is >=0; is--){
+             Float_t scut = cut*clsigma[is];
+             if(clsignal[is] > scut) s += clsignal[is];
+             else break;
          };
          return s;
+     };
+     Int_t il = indmax;
+     Int_t ir = indmax;
+     Int_t inc = 0;
+     if( clsignal[indmax] < cut*clsigma[indmax] ) return 0;
+     while ( inc < nstrip ){
+         Float_t sl = -100000;
+         Float_t sr = -100000;
+         if( il >= 0       ) sl = clsignal[il];
+         if( ir < CLlength ) sr = clsignal[ir];
+         if( sl == sr && inc == 0 ){
+             s += clsignal[il]; //cout << inc<<" - "<< clsignal[il]<<" "<<s<<endl;
+             il--;
+             ir++;
+         }else if ( sl >= sr && sl > cut*clsigma[il] && inc !=0 ){
+             s += sl;//cout << inc<<" - "<< clsignal[il]<<" "<<s<<endl;
+             il--;
+         }else if ( sl < sr && sr > cut*clsigma[ir] ){
+             s += sr;//cout << inc<<" - " << clsignal[ir]<<" "<<s<<endl;
+             ir++;
+         }else break;
+         inc++;
+     }
+     return s;
  };
  /**
-  * Evaluate the cluster signal-to-noise, as defined by Turchetta.
+  * Evaluate the cluster signal-to-noise, as defined by Turchetta, including a
-  * @param cut Inclusion cut.
+  * maximum number of adjacent strips, around maxs, having a significant signal.
+  * @param nstrip   Maximum number of strips.
+  * @param cut      Inclusion cut ( s > cut*sigma ).
+  * If nstrip<=0 only the inclusion cut is used to determine the cluster size.
   */
- Float_t TrkCluster::GetSignalToNoise(Float_t cut){
+ Float_t TrkCluster::GetSignalToNoise(Int_t nstrip, Float_t cut){
-         Float_t sn = 0;
-         for(Int_t is = 0; is < CLlength; is++){
+     if(CLlength<=0)return 0;
-                 Float_t scut = cut*clsigma[is];
-                 if(clsignal[is] > scut) sn += clsignal[is]/clsigma[is];
+     Float_t sn = 0;
+     if( nstrip<=0 ){
+         for(Int_t is = indmax+1; is < CLlength; is++){
+             Float_t scut = cut*clsigma[is];
+             if(clsignal[is] > scut) sn += clsignal[is]/clsigma[is];
+             else break;
+         };
+         for(Int_t is = indmax; is >=0; is--){
+             Float_t scut = cut*clsigma[is];
+             if(clsignal[is] > scut) sn += clsignal[is]/clsigma[is];
+             else break;
          };
          return sn;
+     };
+     Int_t il = indmax;
+     Int_t ir = indmax;
+     Int_t inc = 0;
+     if( clsignal[indmax] < cut*clsigma[indmax] ) return 0;
+     while ( inc < nstrip ){
+         Float_t sl = -100000;
+         Float_t sr = -100000;
+         if( il >= 0       ) sl = clsignal[il];
+         if( ir < CLlength ) sr = clsignal[ir];
+         if( sl == sr && inc == 0 ){
+             sn += clsignal[il]/clsigma[il];
+             il--;
+             ir++;
+         }else if ( sl >= sr && sl > cut*clsigma[il] && inc !=0 ){
+             sn += sl/clsigma[il];
+             il--;
+         }else if ( sl < sr && sr > cut*clsigma[ir] ){
+             sn += sr/clsigma[ir];
+             ir++;
+         }else break;
+         inc++;
+     }
+     return sn;
  };
  /**
   * Evaluate the cluster multiplicity.
   * @param cut Inclusion cut.
   */
  Int_t TrkCluster::GetMultiplicity(Float_t cut){
-         Int_t m = 0;
-         for(Int_t is = 0; is < CLlength; is++){
+     if(CLlength<=0)return 0;
-                 Float_t scut = cut*clsigma[is];
-                 if(clsignal[is] > scut) m++;
+     Int_t m = 0;
-         };
-         return m;
+     for(Int_t is = indmax+1; is < CLlength; is++){
+         Float_t scut = cut*clsigma[is];
+         if(clsignal[is] > scut) m++;
+         else break;
+     };
+     for(Int_t is = indmax; is >=0; is--){
+         Float_t scut = cut*clsigma[is];
+         if(clsignal[is] > scut) m++;
+         else break;
+     };
+     return m;
  };
  /**
   * True if the cluster contains bad strips.
   * @param nbad Number of strips around the maximum.
   */
  Bool_t TrkCluster::IsBad(Int_t nbad){
- /*      Float_t max = 0;
+     if(CLlength<=0)return 0;
-         Int_t  imax = 0;
-         for(Int_t is = 0; is < CLlength; is++){
+     Int_t il,ir;
-                 if(clsignal[is] > max){
+     il = indmax;
-                         max = clsignal[is];
+     ir = indmax;
-                         imax = is;
+     for(Int_t i=1; i<nbad; i++){
-                 };
+         if (ir == CLlength-1 && il == 0)break;
-         };
+         else if (ir == CLlength-1 && il != 0)il--;
+         else if (ir != CLlength-1 && il == 0)ir++;
-         Int_t il,ir;
+         else{
-         il = imax;
+             if(clsignal[il-1] > clsignal[ir+1])il--;
-         ir = imax;*/
+             else ir++;
-         Int_t il,ir;
-         il = indmax;
-         ir = indmax;
-         for(Int_t i=1; i<nbad; i++){
-                      if (ir == CLlength && il == 0)break;
-                 else if (ir == CLlength && il != 0)il--;
-                 else if (ir != CLlength && il == 0)ir++;
-                 else{
-                         if(clsignal[il-1] > clsignal[ir+1])il--;
-                         else ir++;
-                 }
          }
-         Int_t isbad = 0;
+     }
-         for(Int_t i=il; i<=ir; i++)isbad += clbad[i];
+     Int_t isbad = 0;
+     for(Int_t i=il; i<=ir; i++)isbad += clbad[i];
-         return ( isbad != nbad );
+     return ( isbad != nbad );
  };
+ /**
+  * True if the cluster contains saturated strips.
+  * @param nbad Number of strips around the maximum.
+  */
+ Bool_t TrkCluster::IsSaturated(Int_t nbad){
+     if(CLlength<=0)return 0;
+     Int_t il,ir;
+     il = indmax;
+     ir = indmax;
+     for(Int_t i=1; i<nbad; i++){
+         if (ir == CLlength-1 && il == 0)break;
+         else if (ir == CLlength-1 && il != 0)il--;
+         else if (ir != CLlength-1 && il == 0)ir++;
+         else{
+             if(clsignal[il-1] > clsignal[ir+1])il--;
+             else ir++;
+         }
+     }
+     Int_t isbad = 0;
+     for(Int_t i=il; i<=ir; i++){
+         if( IsX() && cladc[i] > 2980 )isbad++;
+         if( IsY() && cladc[i] <   80 )isbad++;
+     }
+     return ( isbad != 0 );
+ }
  //--------------------------------------
  //
  //
  //--------------------------------------
  void TrkCluster::Dump(){
-         cout << "----- Cluster" << endl;
+     cout << "----- Cluster" << endl;
-         cout << "View "<<view << " - Ladder "<<GetLadder()<<endl;
+     cout << "View "<<view << " - Ladder "<<GetLadder()<<endl;
-         cout << "Position of maximun "<< maxs <<endl;
+     cout << "Position of maximun "<< maxs <<endl;
-         cout << "Multiplicity        "<< GetMultiplicity() <<endl;
+     cout << "Multiplicity        "<< GetMultiplicity() <<endl;
-         cout << "Tot signal          "<< GetSignal() << " (ADC channels)"<<endl ;
+     cout << "Tot signal          "<< GetSignal() << " (ADC channels)"<<endl ;
-         cout << "Signal/Noise        "<< GetSignalToNoise();
+     cout << "Signal/Noise        "<< GetSignalToNoise()<<endl;
-         cout <<endl<< "Strip signals       ";
+     cout << "COG                 "<< GetCOG(0)<<endl;;
-         for(Int_t i =0; i<CLlength; i++)cout << " " <<clsignal[i];
+     cout << "Strip signals       ";
-         cout <<endl<< "Strip sigmas        ";
+     for(Int_t i =0; i<CLlength; i++)cout << " " <<clsignal[i];
-         for(Int_t i =0; i<CLlength; i++)cout << " " <<clsigma[i];
+     cout <<endl<< "Strip sigmas        ";
-         cout <<endl<< "Strip ADC           ";
+     for(Int_t i =0; i<CLlength; i++)cout << " " <<clsigma[i];
-         for(Int_t i =0; i<CLlength; i++)cout << " " <<cladc[i];
+     cout <<endl<< "Strip ADC           ";
-         cout <<endl<< "Strip BAD           ";
+     for(Int_t i =0; i<CLlength; i++)cout << " " <<cladc[i];
-         for(Int_t i =0; i<CLlength; i++){
+     cout <<endl<< "Strip BAD           ";
-                 if(i==indmax)cout << "  *" <<clbad[i]<<"*";
+     for(Int_t i =0; i<CLlength; i++){
-                 else cout << " " <<clbad[i];
+         if(i==indmax)cout << "  *" <<clbad[i]<<"*";
-         }
+         else cout << " " <<clbad[i];
-         cout << endl;
+     }
+     cout << endl;
  }
  //--------------------------------------
  //
  //
  //--------------------------------------
- TrkLevel1::TrkLevel1(){
+ /**
+  * Method to fill a level1 struct with only one cluster (done to use F77 p.f.a. routines on a cluster basis).
+  */
+ void TrkCluster::GetLevel1Struct(cTrkLevel1* l1){
+ //    cTrkLevel1* l1 = new cTrkLevel1;
+ //    cTrkLevel1* l1 = &level1event_ ;
+     l1->nclstr1 = 1;
+     l1->view[0] = view;
+     l1->ladder[0] = GetLadder();
+     l1->maxs[0] = maxs;
+     l1->mult[0] = GetMultiplicity();
+     l1->dedx[0] = GetSignal();
+     l1->indstart[0] = 1;
+     l1->indmax[0]   = indmax+1;
+     l1->totCLlength = CLlength;
+     for(Int_t i=0; i<CLlength; i++){
+         l1->clsignal[i] = clsignal[i];
+         l1->clsigma[i] = clsigma[i];
+         l1->cladc[i] = cladc[i];
+         l1->clbad[i] = clbad[i];
+     };
- //      good1 = -1;
+ //    return l1;
+ };
+ //--------------------------------------
+ //
+ //
+ //--------------------------------------
+ /**
+  * Evaluates the Center-Of-Gravity (COG) of the cluster, in strips, relative to the strip with the maximum signal (TrkCluster::maxs).
+  *      @param ncog Number of strips to evaluate COG.
+  * If ncog=0, the COG of the cluster is evaluated according to the cluster multiplicity (defined by the inclusion cut).
+  * If ncog>0, the COG is evaluated using ncog strips, even if they have a negative signal (according to G.Landi)
+  */
+ Float_t TrkCluster::GetCOG(Int_t ncog){
-         Cluster = new TClonesArray("TrkCluster");
+     int ic = 1;
+     GetLevel1Struct();
+     return cog_(&ncog,&ic);
-         for(Int_t i=0; i<12 ; i++){
+ };
- //              crc[i] = -1;
+ /**
-                 good[i] = -1;
+  * Evaluates the Center-Of-Gravity (COG) of the cluster, in strips, relative to the strip with the maximum signal (TrkCluster::maxs),
-                 for(Int_t j=0; j<24 ; j++){
+  * choosing the number of strips according to the angle, as implemented for the eta-algorythm .
-                         cnev[j][i]=0;
+  *      @param angle Projected angle in degree.
-                         cnnev[j][i]=0;
+  */
-                 };
+ Float_t TrkCluster::GetCOG(Float_t angle){
- //              fshower[i]=0;
+     Int_t neta  = 0;
+ //     Float_t eta = GetETA(0,angle);
+ //     for(neta=2; neta<10; neta++) if( eta == GetETA(neta,angle) ) break;
+ //    if(eta != GetETA(neta,angle) )cout << "Attenzione!! pasticcio "<<endl;
+     if( view%2 ){   //Y
+         neta=2;
+     }else{          //X
+         if( fabs(angle) <= 10. ){
+             neta = 2;
+         }else if( fabs(angle) > 10. && fabs(angle) <= 15. ){
+             neta = 3;
+         }else{
+             neta = 4;
          };
- }
+     };
+     return GetCOG(neta);
+ };
  //--------------------------------------
  //
  //
  //--------------------------------------
- void TrkLevel1::Dump(){
+ /**
+  * Evaluates the cluster position, in pitch units, relative to the strip with the maximum signal (TrkCluster::maxs), by applying the non-linear ETA-algorythm.
-         cout<<"DSP status: ";
+  *  @param neta  Number of strips to evaluate ETA.
-         for(Int_t i=0; i<12 ; i++)cout<<good[i]<<" ";
+  *  @param angle Projected (effective) angle between particle track and detector plane.
-         cout<<endl;
+  * Implemented values of neta are 2,3,4. If neta=0, ETA2, ETA3 and ETA4 are applied according to the angle.
+  */
+ Float_t TrkCluster::GetETA(Int_t neta, float angle, bool landi){
-         TClonesArray &t  = *Cluster;
+ //    cout << "GetETA(neta,angle) "<< neta << " "<< angle;
-         for(int i=0; i<this->nclstr(); i++)     ((TrkCluster *)t[i])->Dump();
+ //      LoadPfaParam();
+     TrkParams::Load(4);
+     if( !TrkParams::IsLoaded(4) ){
+         cout << "int Trajectory::DoTrack2(float* al) --- ERROR --- p.f.a. parameters  not loaded"<<endl;
+         return 0;
+     }
+     float ax = angle;
+     int ic = 1;
+     GetLevel1Struct();
+     if(     neta == 0 && !landi) return pfaeta_(&ic,&ax);
+     else if(neta == 0 && landi ) return pfaetal_(&ic,&ax);
+     else if(neta == 2          ) return pfaeta2_(&ic,&ax);
+     else if(neta == 3          ) return pfaeta3_(&ic,&ax);
+     else if(neta == 4          ) return pfaeta4_(&ic,&ax);
+     else cout << "ETA"<<neta<<" not implemented\n";
+     return 0;
+ };
+ /**
+  * Evaluates the cluster position, in pitch units, relative to the strip with
+  * the maximum signal (TrkCluster::maxs), by applying the PFA set as default (see TrkParams).
+  *  @param angle Projected (effective) angle between particle track and detector plane.
+  */
+ Float_t TrkCluster::GetPositionPU(float angle){
+     if( TrkParams::GetPFA() == 0  )return GetETA(0,angle,false);
+     if( TrkParams::GetPFA() == 1  )return 0.;
+     if( TrkParams::GetPFA() == 2  )return GetETA(2,angle,false);
+     if( TrkParams::GetPFA() == 3  )return GetETA(3,angle,false);
+     if( TrkParams::GetPFA() == 4  )return GetETA(4,angle,false);
+     if( TrkParams::GetPFA() == 5  )return GetETA(0,angle,true);
+     if( TrkParams::GetPFA() == 6  )return 0.;
+     if( TrkParams::GetPFA() == 7  )return 0.;
+     if( TrkParams::GetPFA() == 8  )return 0.;
+     if( TrkParams::GetPFA() == 9  )return 0.;
+     if( TrkParams::GetPFA() == 10 )return GetCOG(0);
+     if( TrkParams::GetPFA() == 11 )return GetCOG(1);
+     if( TrkParams::GetPFA() == 12 )return GetCOG(2);
+     if( TrkParams::GetPFA() == 13 )return GetCOG(3);
+     if( TrkParams::GetPFA() == 14 )return GetCOG(4);
+     return 0.;
+ }
+ //--------------------------------------
+ //
+ //
+ //--------------------------------------
+ TrkLevel1::TrkLevel1(){
+ //    cout << "TrkLevel1::TrkLevel1()"<<endl;
+ //    Cluster = new TClonesArray("TrkCluster");
+     Cluster = 0;
+     for(Int_t i=0; i<12 ; i++){
+         good[i] = -1;
+         for(Int_t j=0; j<24 ; j++){
+             cn[j][i]=0;
+             cnn[j][i]=0;
+         };
+     };
+     TrkParams::SetTrackingMode();
+     TrkParams::SetPrecisionFactor();
+     TrkParams::SetStepMin();
+     TrkParams::SetPFA();
+ }
+ //--------------------------------------
+ //
+ //
+ //--------------------------------------
+ void TrkLevel1::Set(){
+     if(!Cluster)Cluster = new TClonesArray("TrkCluster");
  }
  //--------------------------------------
  //
  //
  //--------------------------------------
+ void TrkLevel1::Dump(){
+     cout<<"DSP status: ";
+     for(Int_t i=0; i<12 ; i++)cout<<good[i]<<" ";
+     cout<<endl;
+     cout<<"VA1 mask : "<<endl;
+     for(Int_t i=0; i<12 ; i++){
+         for(Int_t ii=0; ii<24 ; ii++){
+             Int_t mask = cnn[ii][i];
+             if(mask>0)mask=1;
+             cout<<mask<<" ";
+         }
+         cout <<endl;
+     }
+     if(!Cluster)return;
+     TClonesArray &t  = *Cluster;
+     for(int i=0; i<this->nclstr(); i++)     ((TrkCluster *)t[i])->Dump();
+ }
  /**
-  * Fills a TrkLevel1 object with values from a struct cTrkLevel1 (to get data from F77 common).
+  * \brief Dump processing status
+  */
+ void TrkLevel1::StatusDump(int view){
+     cout << "DSP n. "<<view+1<<" (level1-)status: "<<hex<<showbase<<good[view]<<dec<<endl;
+ };
+ /**
+  * \brief Check event status
+  *
+  * Check the event status, according to a flag-mask given as input.
+  * Return true if the view passes the check.
+  *
+  * @param view View number (0-11)
+  * @param flagmask Mask of flags to check (eg. flagmask=0x111 no missing packet,
+  *  no crc error, no software alarm)
+  *
+  * @see TrkLevel2 class definition to know how the status flag is defined
+  *
   */
- void TrkLevel1::SetFromLevel1Struct(cTrkLevel1 *l1){
+ Bool_t TrkLevel1::StatusCheck(int view, int flagmask){
-         //  *** CLUSTER ***
+     if( view<0 || view >= 12)return false;
-         TrkCluster* t_cl = new TrkCluster();
+     return !(good[view]&flagmask);
-         TClonesArray &t = *Cluster;
-         for(int i=0; i<l1->nclstr1; i++){
+ };
-                 t_cl->view     = l1->view[i];
-                 t_cl->maxs     = l1->maxs[i];
-                 t_cl->indmax   = l1->indmax[i] - l1->indstart[i];
-                 Int_t from = l1->indstart[i] -1;
-                 Int_t to   = l1->totCLlength ;
-                 if(i != l1->nclstr1-1)to   = l1->indstart[i+1] -1 ;
-                 t_cl->CLlength = to - from ;
-                 t_cl->clsignal = new Float_t[t_cl->CLlength];
-                 t_cl->clsigma  = new Float_t[t_cl->CLlength];
-                 t_cl->cladc    = new Int_t[t_cl->CLlength];
-                 t_cl->clbad    = new Bool_t[t_cl->CLlength];
-                 Int_t index = 0;
-                 for(Int_t is = from; is < to; is++ ){
-                         t_cl->clsignal[index] = (Float_t) l1->clsignal[is];
-                         t_cl->clsigma[index]  = (Float_t) l1->clsigma[is];
-                         t_cl->cladc[index]    = (Int_t)   l1->cladc[is];
-                         t_cl->clbad[index]    = (Bool_t)  l1->clbad[is];
-                         index++;
-                 };
-                 new(t[i]) TrkCluster(*t_cl);
-         };
-         delete t_cl;
-         //  ****general variables****
-         for(Int_t i=0; i<12 ; i++){
+ //--------------------------------------
-                 good[i] = -1;
+ //
-                 for(Int_t j=0; j<24 ; j++){
+ //
-                         cnev[j][i]     = l1->cnev[j][i];
+ //--------------------------------------
-                         cnnev[j][i] = l1->cnnev[j][i];
+ /**
-                 };
+  * Fills a TrkLevel1 object with values from a struct cTrkLevel1 (to get data from F77 common).
+  */
+ void TrkLevel1::SetFromLevel1Struct(cTrkLevel1 *l1, Bool_t full){
+ //    cout << "void TrkLevel1::SetFromLevel1Struct(cTrkLevel1 *l1, Bool_t full)"<<endl;
+     Clear();
+     //  ---------------
+     //  *** CLUSTER ***
+     //  ---------------
+     TrkCluster* t_cl = new TrkCluster();
+     if(!Cluster)Cluster = new TClonesArray("TrkCluster");
+     TClonesArray &t = *Cluster;
+     for(int i=0; i<l1->nclstr1; i++){
+         t_cl->Clear();
+ //      if( full || (!full && l1->whichtrack[i]) ){
+         t_cl->view     = l1->view[i];
+         t_cl->maxs     = l1->maxs[i];
+         if( full || (!full && l1->whichtrack[i]) ){
+             t_cl->indmax   = l1->indmax[i] - l1->indstart[i];
+             Int_t from = l1->indstart[i] -1;
+             Int_t to   = l1->totCLlength ;
+             if(i != l1->nclstr1-1)to   = l1->indstart[i+1] -1 ;
+             t_cl->CLlength = to - from ;
+             t_cl->clsignal = new Float_t[t_cl->CLlength];
+             t_cl->clsigma  = new Float_t[t_cl->CLlength];
+             t_cl->cladc    = new Int_t[t_cl->CLlength];
+             t_cl->clbad    = new Bool_t[t_cl->CLlength];
+             Int_t index = 0;
+             for(Int_t is = from; is < to; is++ ){
+                 t_cl->clsignal[index] = (Float_t) l1->clsignal[is];
+                 t_cl->clsigma[index]  = (Float_t) l1->clsigma[is];
+                 t_cl->cladc[index]    = (Int_t)   l1->cladc[is];
+                 t_cl->clbad[index]    = (Bool_t)  l1->clbad[is];
+                 index++;
+             };
+         }
+         new(t[i]) TrkCluster(*t_cl); // <<< store cluster
+     };
+     delete t_cl;
+     //  -------------------------
+     //  ****general variables****
+     //  -------------------------
+     for(Int_t i=0; i<12 ; i++){
+         good[i] = l1->good[i];
+         for(Int_t j=0; j<24 ; j++){
+             cn[j][i]     = l1->cnev[j][i];
+ //          cnrms[j][i]  = l1->cnrmsev[j][i];
+             cnn[j][i]    = l1->cnnev[j][i];
          };
+     };
  }
  /**
   * Fills a struct cTrkLevel1 with values from a TrkLevel1 object (to put data into a F77 common).
   */
- void TrkLevel1::GetLevel1Struct(cTrkLevel1 *l1) const {
+ void TrkLevel1::GetLevel1Struct(cTrkLevel1* l1) {
-         // ********* completare ********* //
+ //    cTrkLevel1* l1 = &level1event_ ;
-         // ********* completare ********* //
-         // ********* completare ********* //
+     for(Int_t i=0; i<12 ; i++){
-         // ********* completare ********* //
+         l1->good[i] = good[i];
-         // ********* completare ********* //
+         for(Int_t j=0; j<24 ; j++){
-         // ********* completare ********* //
+             l1->cnev[j][i]    = cn[j][i]  ;
- //  general variables
+             l1->cnnev[j][i]   = cnn[j][i] ;
- //      l1->good1 = good1;
+             l1->cnrmsev[j][i] = 0. ;
-         for(Int_t i=0; i<12 ; i++){
- //              l1->crc[i] = crc[i];
-                 for(Int_t j=0; j<24 ; j++){
-                         l1->cnev[j][i]     = cnev[j][i];
-                         l1->cnnev[j][i] = cnnev[j][i];
-                 };
- //              l1->fshower[i] = fshower[i];
          };
+         l1->fshower[i] = 0;
- //  *** CLUSTERS ***
+     };
-     l1->nclstr1 =  Cluster->GetEntries();
-         for(Int_t i=0;i<l1->nclstr1;i++){
+     l1->nclstr1=0;
+     l1->totCLlength=0;
-                 l1->view[i]     = ((TrkCluster *)Cluster->At(i))->view;
+     Int_t index=0;
- //              l1->ladder[i]   = ((TrkCluster *)Cluster->At(i))->ladder;
+     if(Cluster){
-                 l1->maxs[i]     = ((TrkCluster *)Cluster->At(i))->maxs;
+         Int_t i=0;
- //              l1->mult[i]     = ((TrkCluster *)Cluster->At(i))->mult;
+         for(Int_t ii=0;ii<Cluster->GetEntries();ii++){
- //              l1->dedx[i]     = ((TrkCluster *)Cluster->At(i))->sgnl;
+             TrkCluster *clu = GetCluster(ii);
+             // ----------------------------------------
+             // attenzione!!
+             // se il cluster non e` salvato (view = 0)
+             // DEVE essere escluso dal common F77
+             // ----------------------------------------
+             if(clu->view != 0 ){
+                 l1->view[i]     = clu->view;
+                 l1->ladder[i]   = clu->GetLadder();
+                 l1->maxs[i]     = clu->maxs;
+                 l1->mult[i]     = clu->GetMultiplicity();
+                 l1->dedx[i]     = clu->GetSignal();
+                 l1->indstart[i] = index+1;
+                 l1->indmax[i]   = l1->indstart[i] + clu->indmax;
+                 l1->totCLlength += clu->CLlength;
+                 for(Int_t iw=0; iw < clu->CLlength; iw++){
+                     l1->clsignal[index] = clu->clsignal[iw];
+                     l1->clsigma[index]  = clu->clsigma[iw];
+                     l1->cladc[index]    = clu->cladc[iw];
+                     l1->clbad[index]    = clu->clbad[iw];
+                     index++;
+                 }
+                 i++;
+             }
          }
+         l1->nclstr1 =  i;
-         // ********* completare ********* //
+     }
+ //    return l1;
  }
  //--------------------------------------
  //
  //
  //--------------------------------------
  void TrkLevel1::Clear(){
-         for(Int_t i=0; i<12 ; i++){
+     for(Int_t i=0; i<12 ; i++){
-                 good[i] = -1;
+         good[i] = -1;
-                 for(Int_t j=0; j<24 ; j++){
+         for(Int_t j=0; j<24 ; j++){
-                         cnev[j][i]     = 0;
+             cn[j][i]    = 0;
-                         cnnev[j][i] = 0;
+             cnn[j][i]   = 0;
-                 };
          };
-         //
+     };
-         Cluster->Clear();
+ //    if(Cluster)Cluster->Clear("C");
+     if(Cluster)Cluster->Delete();
+ }
+ //--------------------------------------
+ //
+ //
+ //--------------------------------------
+ void TrkLevel1::Delete(){
+ //    Clear();
+     if(Cluster)Cluster->Delete();
+     if(Cluster)delete Cluster;
  }
  //--------------------------------------
  //
-Line 305 
 void TrkLevel1::Clear(){
+Line 677 
 void TrkLevel1::Clear(){
  //--------------------------------------
  TrkCluster *TrkLevel1::GetCluster(int is){
-         if(is >= this->nclstr()){
+     if(!Cluster)return 0;
-                 cout << "** TrkLevel1::GetCluster(int) ** Cluster "<< is << " does not exits! " << endl;
+     if(is >= nclstr()){
-                 cout << "( Stored clusters nclstr() = "<< this->nclstr()<<" )" << endl;
+         cout << "** TrkLevel1::GetCluster(int) ** Cluster "<< is << " does not exits! " << endl;
-                 return 0;
+         cout << "( Stored clusters nclstr() = "<< this->nclstr()<<" )" << endl;
+         return 0;
+     }
+     TClonesArray &t = *(Cluster);
+     TrkCluster *cluster = (TrkCluster*)t[is];
+     return cluster;
+ }
+ //--------------------------------------
+ //
+ //
+ //--------------------------------------
+ // /**
+ //  * Load Position-Finding-Algorythm parameters (call the F77 routine).
+ //  *
+ //  */
+ // int TrkLevel1::LoadPfaParam(TString path){
+ //     if( path.IsNull() ){
+ //      path = gSystem->Getenv("PAM_CALIB");
+ //      if(path.IsNull()){
+ //          cout << " TrkLevel1::LoadPfaParam() ==> No PAMELA environment variables defined "<<endl;
+ //          return 0;
+ //      }
+ //      path.Append("/trk-param/eta_param-0/");
+ //     }
+ //     strcpy(path_.path,path.Data());
+ //     path_.pathlen = path.Length();
+ //     path_.error   = 0;
+ //     cout <<"Loading p.f.a. parameters: "<<path<<endl;
+ //     return readetaparam_();
+ // }
+ // /**
+ //  * Load magnetic field parameters (call the F77 routine).
+ //  *
+ //  */
+ // int TrkLevel1::LoadFieldParam(TString path){
+ // //    if( strcmp(path_.path,path.Data()) ){
+ //     if( path.IsNull() ){
+ //      path = gSystem->Getenv("PAM_CALIB");
+ //      if(path.IsNull()){
+ //          cout << " TrkLevel1::LoadFieldParam() ==> No PAMELA environment variables defined "<<endl;
+ //          return 0;
+ //      }
+ //      path.Append("/trk-param/field_param-0/");
+ //     }
+ //     cout <<"Loading magnetic field "<<path<<endl;
+ //     strcpy(path_.path,path.Data());
+ //     path_.pathlen = path.Length();
+ //     path_.error   = 0;
+ //     return readb_();
+ // //    }
+ // //    return 0;
+ // }
+ // /**
+ //  * Load magnetic field parameters (call the F77 routine).
+ //  *
+ //  */
+ // int TrkLevel1::LoadChargeParam(TString path){
+ // //    if( strcmp(path_.path,path.Data()) ){
+ //     if( path.IsNull() ){
+ //      path = gSystem->Getenv("PAM_CALIB");
+ //      if(path.IsNull()){
+ //          cout << " TrkLevel1::LoadChargeParam() ==> No PAMELA environment variables defined "<<endl;
+ //          return 0;
+ //      }
+ //      path.Append("/trk-param/charge_param-1/");
+ //     }
+ //     cout <<"Loading charge-correlation parameters: "<<path<<endl;
+ //     strcpy(path_.path,path.Data());
+ //     path_.pathlen = path.Length();
+ //     path_.error   = 0;
+ //     return readchargeparam_();
+ // //    }
+ // //    return 0;
+ // }
+ // /**
+ //  * Load magnetic field parameters (call the F77 routine).
+ //  *
+ //  */
+ // int TrkLevel1::LoadAlignmentParam(TString path){
+ // //    if( strcmp(path_.path,path.Data()) ){
+ //     if( path.IsNull() ){
+ //      path = gSystem->Getenv("PAM_CALIB");
+ //      if(path.IsNull()){
+ //          cout << " TrkLevel1::LoadAlignmentParam() ==> No PAMELA environment variables defined "<<endl;
+ //          return 0;
+ //      }
+ //      path.Append("/trk-param/align_param-0/");
+ //     }
+ //     cout <<"Loading alignment parameters: "<<path<<endl;
+ //     strcpy(path_.path,path.Data());
+ //     path_.pathlen = path.Length();
+ //     path_.error   = 0;
+ //     return readalignparam_();
+ // //    }
+ // //    return 0;
+ // }
+ // /**
+ //  * Load magnetic field parameters (call the F77 routine).
+ //  *
+ //  */
+ // int TrkLevel1::LoadMipParam(TString path){
+ // //    if( strcmp(path_.path,path.Data()) ){
+ //     if( path.IsNull() ){
+ //      path = gSystem->Getenv("PAM_CALIB");
+ //      if(path.IsNull()){
+ //          cout << " TrkLevel1::LoadMipParam() ==> No PAMELA environment variables defined "<<endl;
+ //          return 0;
+ //      }
+ //      path.Append("/trk-param/mip_param-0/");
+ //     }
+ //     cout <<"Loading ADC-to-MIP conversion parameters: "<<path<<endl;
+ //     strcpy(path_.path,path.Data());
+ //     path_.pathlen = path.Length();
+ //     path_.error   = 0;
+ //     return readmipparam_();
+ // //    }
+ // //    return 0;
+ // }
+ // /**
+ //  * Load magnetic field parameters (call the F77 routine).
+ //  *
+ //  */
+ // int TrkLevel1::LoadVKMaskParam(TString path){
+ // //    if( strcmp(path_.path,path.Data()) ){
+ //     if( path.IsNull() ){
+ //      path = gSystem->Getenv("PAM_CALIB");
+ //      if(path.IsNull()){
+ //          cout << " TrkLevel1::LoadVKMaskParam() ==> No PAMELA environment variables defined "<<endl;
+ //          return 0;
+ //      }
+ //      path.Append("/trk-param/mask_param-1/");
+ //     }
+ //     cout <<"Loading VK-mask parameters: "<<path<<endl;
+ //     strcpy(path_.path,path.Data());
+ //     path_.pathlen = path.Length();
+ //     path_.error   = 0;
+ //     return readvkmask_();
+ // //    }
+ // //    return 0;
+ // }
+ // /**
+ //  * Load all (default) parameters. Environment variable must be defined.
+ //  *
+ //  */
+ // int TrkLevel1::LoadParams(){
+ //     int result=0;
+ //     result = result * LoadFieldParam();
+ //     result = result * LoadPfaParam();
+ //     result = result * LoadChargeParam();
+ //     result = result * LoadAlignmentParam();
+ //     result = result * LoadMipParam();
+ //     result = result * LoadVKMaskParam();
+ //     return result;
+ // }
+ int TrkLevel1::GetPfaNbinsAngle(){
+     TrkParams::Load(4);
+     if( !TrkParams::IsLoaded(4) ){
+         cout << "int TrkLevel1::GetPfaNbinsAngle() --- ERROR --- p.f.a. parameters  not loaded"<<endl;
+         return 0;
+     }
+     return pfa_.nangbin;
+ };
+ int TrkLevel1::GetPfaNbinsETA(){
+     TrkParams::Load(4);
+     if( !TrkParams::IsLoaded(4) ){
+         cout << "int TrkLevel1::GetPfaNbinsETA() --- ERROR --- p.f.a. parameters  not loaded"<<endl;
+         return 0;
+     }
+     return pfa_.netaval;
+ };
+ /**
+  *
+  *
+  */
+ float* TrkLevel1::GetPfaCoord(TString pfa, int nview, int nladder, int nang){
+     TrkParams::Load(4);
+     if( !TrkParams::IsLoaded(4) ){
+         cout << "float* TrkLevel1::GetPfaCoord(TString pfa, int nview, int nladder, int nang) --- ERROR --- p.f.a. parameters  not loaded"<<endl;
+         return 0;
+     }
+     int nbins = GetPfaNbinsETA();
+     if(!nbins)return 0;
+     float *fcorr = new float [nbins];
+     if(!pfa.CompareTo("ETA2",TString::kIgnoreCase)){
+         for(int ib=0; ib<nbins; ib++){
+             fcorr[ib] = pfa_.feta2[nang][nladder][nview][ib];
+             cout << pfa_.eta2[nang][ib] << " - " <<  pfa_.feta2[nang][nladder][nview][ib]<<endl;;
          }
-         TClonesArray &t = *(Cluster);
+     }else if (!pfa.CompareTo("ETA3",TString::kIgnoreCase)){
-         TrkCluster *cluster = (TrkCluster*)t[is];
+         for(int ib=0; ib<nbins; ib++)fcorr[ib] = pfa_.feta3[nang][nladder][nview][ib];
-         return cluster;
+     }else if (!pfa.CompareTo("ETA4",TString::kIgnoreCase)){
+         for(int ib=0; ib<nbins; ib++)fcorr[ib] = pfa_.feta4[nang][nladder][nview][ib];
+     }else{
+         cout << pfa<<" pfa parameters not implemented "<<endl;
+         return 0;
+     }
+     return fcorr;
+ };
+ float* TrkLevel1::GetPfaAbs(TString pfa, int nang){
+     TrkParams::Load(4);
+     if( !TrkParams::IsLoaded(4) ){
+         cout << "float* TrkLevel1::GetPfaAbs(TString pfa, int nang) --- ERROR --- p.f.a. parameters  not loaded"<<endl;
+         return 0;
+     }
+     int nbins = GetPfaNbinsETA();
+     if(!nbins)return 0;
+     float *fcorr = new float [nbins];
+     if(!pfa.CompareTo("ETA2",TString::kIgnoreCase)){
+         for(int ib=0; ib<nbins; ib++)fcorr[ib] = pfa_.eta2[nang][ib];
+     }else if (!pfa.CompareTo("ETA3",TString::kIgnoreCase)){
+         for(int ib=0; ib<nbins; ib++)fcorr[ib] = pfa_.eta3[nang][ib];
+     }else if (!pfa.CompareTo("ETA4",TString::kIgnoreCase)){
+         for(int ib=0; ib<nbins; ib++)fcorr[ib] = pfa_.eta4[nang][ib];
+     }else{
+         cout << pfa<<" pfa parameters not implemented "<<endl;
+         return 0;
+     }
+     return fcorr;
+ };
+ /**
+  * Method to call the F77 routine that performs level1->level2 processing.
+  * The level2 output is stored in a common block, which can be retrieved
+  * by mean of the method TrkLevel2::SetFromLevel2Struct().
+  * NB If the TrkLevel1 object is readout from a tree, and the
+  * TrkLevel1::ProcessEvent(int pfa) is used to reprocess the event, attention
+  * should be payed to the fact that single clusters (clusters not associated
+  * with any track) might not be stored. Full reprocessing should be done starting
+  * from level0 data.
+  */
+ //int TrkLevel1::ProcessEvent(int pfa){
+ int TrkLevel1::ProcessEvent(){
+ //    cout << "int TrkLevel1::ProcessEvent()" << endl;
+     TrkParams::Load( );
+     if( !TrkParams::IsLoaded() )return 0;
+     GetLevel1Struct();
+ //    analysisflight_(&pfa);
+ //    TrkParams::SetPFA(pfa);
+     analysisflight_();
+     return 1;
  }

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+Added in v.1.21

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