CaloPreSampler/src/CaloPreSampler.cpp

/**
 * \file CaloPreSampler.cpp
 * \author Emiliano Mocchiutti (2007/07/18)
 */
//
// headers
//
#include <CaloPreSampler.h>
//--------------------------------------
/**
 * Default constructor 
 */
CaloPreSampler::CaloPreSampler(){
  Clear();
};

CaloPreSampler::CaloPreSampler(PamLevel2 *l2p){  
  //
  L2 = l2p;
  //
  if ( !L2->IsORB() ) printf(" WARNING: OrbitalInfo Tree is needed, the plugin could not work properly without it \n");
  //
  OBT = 0;
  PKT = 0;
  atime = 0;
  //
  // Default variables
  //
  event = new CaloLevel0();
  cstrip = new CaloStrip(false);
  //  c1 = new CaloLevel1();
  pcalo = new CaloLevel2();
  N = 3;
  debug = false;
  sel = true;
  cont = false;
  emulate18 = true;
  simulation = false;
  //
  Clear();
  //
  // loading magnetic field...
  //
  TrkLevel2 *trk = new TrkLevel2();
  GL_PARAM *q4 = new GL_PARAM();
  TSQLServer *dbc = 0;
  TString host = "mysql://localhost/pamelaprod";
  TString user = "anonymous";
  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;
  dbc = TSQLServer::Connect(host.Data(),user.Data(),psw.Data());
  //
  q4->Query_GL_PARAM(1,1,dbc);
  printf(" Reading magnetic field maps at %s\n",(q4->PATH+q4->NAME).Data());
  trk->LoadField(q4->PATH+q4->NAME);
  //
};

void CaloPreSampler::Clear(){
  //
  pcalo->Clear();
  //
};

void CaloPreSampler::Print(){
  //
  Process();
  //
  printf("========================================================================\n");
  printf(" OBT: %u PKT: %u ATIME: %u \n",OBT,PKT,atime);
  printf(" debug                [debug flag]:.. %i\n",debug);
  printf(" simulation      [simulation flag]:.. %i\n",simulation);
  printf(" emulate18 [emulate dead plane 18]:.. %i\n",emulate18);
  printf(" selection mode                   :.. %i\n",sel);
  printf(" contamination mode               :.. %i\n",cont);
  printf(" pre-sampler planes               :.. %i\n",N);
  printf(" pcalo->qtot                      :.. %f\n",pcalo->qtot);
  printf(" pcalo->nstrip                    :.. %i\n",pcalo->nstrip);  
  printf(" pcalo->track0->qtrack            :.. %f\n",pcalo->GetCaloTrkVar(0)->qtrack);  
  printf(" pcalo->track0->dX0l              :.. %f\n",pcalo->GetCaloTrkVar(0)->dX0l);  
  printf("========================================================================\n");
  //
};

void CaloPreSampler::Delete(){
  Clear();
  delete pcalo;
  //delete this;
};


void CaloPreSampler::Process(){
  //  
  if ( !L2 ){
    printf(" ERROR: cannot find PamLevel2 object, use the correct constructor or check your program!\n");
    printf(" ERROR: CaloPreSampler variables _NOT_ filled \n");
    return;
  };
  //
  Bool_t newentry = false;
  //
  if ( L2->IsORB() ){
    if ( L2->GetOrbitalInfo()->pkt_num != PKT || L2->GetOrbitalInfo()->OBT != OBT || L2->GetOrbitalInfo()->absTime != atime || sel != ssel ){
      newentry = true;
      OBT = L2->GetOrbitalInfo()->OBT;
      PKT = L2->GetOrbitalInfo()->pkt_num;
      atime = L2->GetOrbitalInfo()->absTime;
      ssel = sel;
    };
  } else {
    newentry = true;
  };
  //
  if ( !newentry ) return;
  //
  // Some variables
  //
  Int_t S3 = 0;
  Int_t S2 = 0;
  Int_t S12 = 0;
  Int_t S11 = 0;
  Float_t tmptrigty = -1.; 
  Bool_t trackanyway = true;
  Float_t rigdefault = 50.;
  Bool_t hZn = true;
  Bool_t withtrk = true;
  Bool_t st = true;
  Int_t ntrkentry = 0;
  TrkLevel2 *trk = L2->GetTrkLevel2();
  Bool_t filled = false;
  //
  if ( debug ) printf(" Processing event at OBT %u PKT %u time %u \n",OBT,PKT,atime);
  //
  this->Clear();
  //
  // find out if we have trkseqno = -1, -2 or -3
  //
  Bool_t m1 = false;
  Bool_t m2 = false;
  Bool_t m3 = false;
  for (Int_t mm=0; mm < L2->GetCaloLevel2()->ntrk(); mm++ ){
    if ( L2->GetCaloLevel2()->GetCaloTrkVar(mm)->trkseqno == -1 ) m1 = true;
    if ( L2->GetCaloLevel2()->GetCaloTrkVar(mm)->trkseqno == -2 ) m2 = true;
    if ( L2->GetCaloLevel2()->GetCaloTrkVar(mm)->trkseqno == -3 ) m3 = true;
  };
  //
  if ( debug ) printf(" Fill estrip matrix needed to calculate variables \n");
  //
  // Fill the estrip matrix
  //
  memset(event->clevel1->estrip, 0, 2*22*96*sizeof(Float_t));
  Int_t view = 0;
  Int_t plane = 0;
  Int_t strip = 0;
  Float_t mip = 0.;
  for ( Int_t i=0; i<L2->GetCaloLevel1()->istrip; i++ ){
    //
    mip = L2->GetCaloLevel1()->DecodeEstrip(i,view,plane,strip);
    //
    // Selection mode: fill the matrix only for plane < (22 - N) REMEMBER N = number of W planes to be used as presampler, ie if N = 2 then we want to use planes from 0 to 19
    //                 included so plane < (22 - 2)
    //
    if ( sel ){
      if ( plane < (22 - N) ){
        //
        if ( emulate18 && plane == (18 - N) ) mip = 0.;
        event->clevel1->estrip[strip][plane][view] = mip;
        //
      };
    };
    //
    // Contamination mode: fill the matrix only for planes from N to 22 but shift all planes up to the first one
    //
    if ( cont ){
      if ( plane >= N ){
        //
        if ( emulate18 && plane == (18 + N) ) mip = 0.;
        event->clevel1->estrip[strip][(plane-N)][view] = mip;
        //
      };
    };    
    //
  };
  //
  // if data comes from the simulation we must use mechanical alignment parameters (default is flight parameters)
  //
  if ( simulation ){
    cstrip->UseMechanicalAlig();
  };
  //
  // Set alignment parameter 
  //
  event->clevel1->xalig = cstrip->GetXalig();
  event->clevel1->yalig = cstrip->GetYalig();
  event->clevel1->zalig = cstrip->GetZalig();
  //
  event->clevel1->emin = 0.7;
  //
  // in case of the contamination mode we must play with the Z alignment in order to have the correct track in the calo since we have moved the planes up...
  //
  if ( cont ){
    if ( !(N%2) ){
      event->clevel1->reverse = 0; // if the number of planes is even we have taken away a full module no need to do anything strange...
      event->clevel1->zalig -= (N/2) * (8.09 + 10.09);
    } else {
      event->clevel1->reverse = 1; // if the number of planes is odd we have taken away half a module, we need to reverse silicon planes shifting
      event->clevel1->zalig -= ((N+1)/2) * 8.09 + ((N-1)/2) * 10.09;
    };
  };
  if ( debug ) printf(" xalig = %f \n",event->clevel1->xalig);
  if ( debug ) printf(" yalig = %f \n",event->clevel1->yalig);
  if ( debug ) printf(" zalig = %f \n",event->clevel1->zalig);
  //
  if ( debug ) printf(" Calculate variables as done in CaloCore, N = %i \n",N);
  //
  // Calculate variables
  //
  //
  // use only N W planes
  //
  event->clevel1->npla = 22-N;
  //
  S3 = 0;
  S2 = 0;
  S12 = 0;
  S11 = 0;
  S3 = L2->GetTrigLevel2()->patterntrig[2];
  S2 = L2->GetTrigLevel2()->patterntrig[3];
  S12 = L2->GetTrigLevel2()->patterntrig[4];
  S11 = L2->GetTrigLevel2()->patterntrig[5];
  if ( L2->GetTrigLevel2()->patterntrig[1] & (1<<0) ) tmptrigty = 1.;
  if ( L2->GetTrigLevel2()->patterntrig[0] ) tmptrigty = 2.;
  if ( S3 || S2 || S12 || S11 )  tmptrigty = 0.;    
  if ( !(L2->GetTrigLevel2()->patterntrig[1] & (1<<0)) && !L2->GetTrigLevel2()->patterntrig[0] && !S3 && !S2 && !S12 && !S11 ) tmptrigty = 1.;
  event->clevel2->trigty = tmptrigty;
  //
  // do we have at least one track from the tracker? this check has been disabled
  //
  event->clevel1->good2 = 1;
  //
  // Calculate variables common to all tracks (qtot, nstrip, etc.)
  //
  if ( debug ) printf("1 Call GetCommonVar() \n");
  event->GetCommonVar();
  //
  // Fill common variables
  //
  if ( debug ) printf("1 Call FillCommonVar() \n");
  event->FillCommonVar(NULL,pcalo);
  //
  // Calculate variables related to tracks only if we have at least one track (from selftrigger and/or tracker)
  //
  ntrkentry = 0;
  //
  filled = false;
  //
  // Run over tracks (tracker or calorimeter )
  //
  if ( withtrk ){
    //
    for (Int_t nt=0; nt < trk->ntrk(); nt++){  
      //
      event->clevel1->good2 = 1;
      //
      TrkTrack *ptt = trk->GetStoredTrack(nt); 
      //
      event->clevel1->trkchi2 = 0;
      //
      // Copy the alpha vector in the input structure
      //
      for (Int_t e = 0; e < 5 ; e++){
        event->clevel1->al_p[e][0] = ptt->al[e];
      };          
      //
      // Get tracker related variables for this track
      //
      if ( debug ) printf("track %i Call GetTrkVar() \n",nt);
      event->GetTrkVar();
      if ( debug ) printf(" event->clevel2->dX0l %f \n",event->clevel2->dX0l);
      //
      // Save tracker track sequence number
      //        
      event->trkseqno = nt;
      //
      // Copy values in the class ca from the structure clevel2
      //
      if ( debug ) printf("track %i Call FillTrkVar() \n",nt);
      event->FillTrkVar(pcalo,ntrkentry);


      ntrkentry++;      
      filled = true;
      //
    }; // loop on all the tracks
  };
  // 
  // if no tracks found but there is the possibility to have a good track we should try to calculate anyway the track related variables using the calorimeter 
  // fit of the track (to be used for example when TRK is off due to any reason like IPM3/5 off).
  // here we make an event selection so it must be done very carefully...
  //
  // conditions are: 0) no track from the tracker 1) we have a track fit both in x and y 2) no problems with calo for this event 3) no selftrigger event
  //
  //  if ( trackanyway && !filled && event->clevel2->npcfit[0] >= 2 && event->clevel2->npcfit[1] >= 2 && event->clevel2->good != 0 && event->clevel2->trigty < 2. ){
  if ( trackanyway && m3 ){
    if ( debug ) printf(" Event with a track not fitted by the tracker \n");
    //
    // Disable "track mode" in the fortran routine
    //
    event->clevel1->good2 = 0;
    event->clevel1->riginput = rigdefault;
    if ( debug ) printf(" Using as default rigidity: %f \n",event->clevel1->riginput);
    //
    // We have a selftrigger event to analyze.
    //
    for (Int_t e = 0; e < 5 ; e++){
      event->clevel1->al_p[e][0] = 0.;
      event->clevel1->al_p[e][1] = 0.;
    };
    event->clevel1->trkchi2 = 0;
    //
    if ( debug ) printf("-3 a Call GetTrkVar() \n");
    event->GetTrkVar();
    //
    // if we had no problem (clevel1->good2 = 0, NOTICE zero, not one in this mode!), fill and go on
    //
    if ( event->clevel1->good2 == 0 ) {
      //
      // In selftrigger mode the trkentry variable is set to -1
      //
      event->trkseqno = -3;
      //
      // Copy values in the class ca from the structure clevel2
      //
      if ( debug ) printf("-3 a Call FillTrkVar() \n");
      event->FillTrkVar(pcalo,ntrkentry);
      ntrkentry++;
      filled = true;
      //
    } else {
      if ( debug ) printf(" Selftrigger: problems with event \n");
    };
    //
  };
  //
  // Call high energy nuclei routine
  //
  //  if ( hZn && event->clevel2->trigty >= 2. ){
  if ( hZn && m2 ){
    if ( debug ) printf(" Calling selftrigger high energy nuclei routine \n");
    //
    // Disable "track mode" in the fortran routine
    //
    event->clevel1->good2 = 0;
    //
    // Set high energy nuclei flag to one
    // 
    event->clevel1->hzn = 1; 
    event->clevel1->riginput = rigdefault;
    //
    // We have a selftrigger event to analyze.
    //
    for (Int_t e = 0; e < 5 ; e++){
      event->clevel1->al_p[e][0] = 0.;
      event->clevel1->al_p[e][1] = 0.;
    };
    event->clevel1->trkchi2 = 0;
    //
    if ( debug ) printf("-2 a Call GetTrkVar() \n");
    event->GetTrkVar();
    //
    // if we had no problem (clevel1->good2 = 0, NOTICE zero, not one in this mode!), fill and go on
    //
    if ( event->clevel1->good2 == 0 ) {
      //
      // In selftrigger mode the trkentry variable is set to -1
      //
      event->trkseqno = -2;
      //
      // Copy values in the class ca from the structure clevel2
      //
      if ( debug ) printf("-2 a Call FillTrkVar() \n");
      event->FillTrkVar(pcalo,ntrkentry);
      ntrkentry++;
      filled = true;
      //
    } else {
      if ( debug ) printf(" Selftrigger: problems with event \n");
    };
    //
  };
  //
  // self trigger event
  //
  //  if ( st && event->clevel2->trigty >= 2. ){
  if ( st && m1 ){
    if ( debug ) printf(" Selftrigger event  \n");
    //
    // Disable "track mode" in the fortran routine
    //
    event->clevel1->good2 = 0;
    //
    // disable high enery nuclei flag;
    //
    event->clevel1->hzn = 0; 
    //
    // We have a selftrigger event to analyze.
    //
    for (Int_t e = 0; e < 5 ; e++){
      event->clevel1->al_p[e][0] = 0.;
      event->clevel1->al_p[e][1] = 0.;
    };
    event->clevel1->trkchi2 = 0;
    //
    if ( debug ) printf("-1 a Call GetTrkVar() \n");
    event->GetTrkVar();
    //
    // if we had no problem (clevel2->good = 0, NOTICE zero, not one in selftrigger mode!), fill and go on
    //
    if ( event->clevel1->good2 == 0 ) {
      //
      // In selftrigger mode the trkentry variable is set to -1
      //
      event->trkseqno = -1;
      //
      // Copy values in the class ca from the structure clevel2
      //
      if ( debug ) printf("-1 a Call FillTrkVar() \n");
      event->FillTrkVar(pcalo,ntrkentry);
      ntrkentry++;
      filled = true;
      //
    } else {
      if ( debug ) printf(" Selftrigger: problems with event \n");
    };
  };
  //
  // Clear structures used to communicate with fortran
  //
  event->ClearStructs();
  //
  //
  //
  if ( debug ) this->Print();
  if ( debug ) printf(" exit \n");
  //
};
1	mocchiut	1.1	/**
2			* \file CaloPreSampler.cpp
3			* \author Emiliano Mocchiutti (2007/07/18)
4			*/
5			//
6			// headers
7			//
8			#include <CaloPreSampler.h>
9			//--------------------------------------
10			/**
11			* Default constructor
12			*/
13			CaloPreSampler::CaloPreSampler(){
14			Clear();
15			};
16
17			CaloPreSampler::CaloPreSampler(PamLevel2 *l2p){
18			//
19			L2 = l2p;
20			//
21			if ( !L2->IsORB() ) printf(" WARNING: OrbitalInfo Tree is needed, the plugin could not work properly without it \n");
22			//
23			OBT = 0;
24			PKT = 0;
25			atime = 0;
26			//
27			// Default variables
28			//
29			event = new CaloLevel0();
30			cstrip = new CaloStrip(false);
31			// c1 = new CaloLevel1();
32			pcalo = new CaloLevel2();
33			N = 3;
34			debug = false;
35			sel = true;
36			cont = false;
37			emulate18 = true;
38			simulation = false;
39			//
40			Clear();
41			//
42			// loading magnetic field...
43			//
44			TrkLevel2 *trk = new TrkLevel2();
45			GL_PARAM *q4 = new GL_PARAM();
46			TSQLServer *dbc = 0;
47			TString host = "mysql://localhost/pamelaprod";
48			TString user = "anonymous";
49			TString psw = "";
50			const char *pamdbhost=gSystem->Getenv("PAM_DBHOST");
51			const char *pamdbuser=gSystem->Getenv("PAM_DBUSER");
52			const char *pamdbpsw=gSystem->Getenv("PAM_DBPSW");
53			if ( !pamdbhost ) pamdbhost = "";
54			if ( !pamdbuser ) pamdbuser = "";
55			if ( !pamdbpsw ) pamdbpsw = "";
56			if ( strcmp(pamdbhost,"") ) host = pamdbhost;
57			if ( strcmp(pamdbuser,"") ) user = pamdbuser;
58			if ( strcmp(pamdbpsw,"") ) psw = pamdbpsw;
59			dbc = TSQLServer::Connect(host.Data(),user.Data(),psw.Data());
60			//
61			q4->Query_GL_PARAM(1,1,dbc);
62			printf(" Reading magnetic field maps at %s\n",(q4->PATH+q4->NAME).Data());
63			trk->LoadField(q4->PATH+q4->NAME);
64			//
65			};
66
67			void CaloPreSampler::Clear(){
68			//
69			pcalo->Clear();
70			//
71			};
72
73			void CaloPreSampler::Print(){
74			//
75			Process();
76			//
77			printf("========================================================================\n");
78			printf(" OBT: %u PKT: %u ATIME: %u \n",OBT,PKT,atime);
79			printf(" debug [debug flag]:.. %i\n",debug);
80			printf(" simulation [simulation flag]:.. %i\n",simulation);
81			printf(" emulate18 [emulate dead plane 18]:.. %i\n",emulate18);
82			printf(" selection mode :.. %i\n",sel);
83			printf(" contamination mode :.. %i\n",cont);
84			printf(" pre-sampler planes :.. %i\n",N);
85			printf(" pcalo->qtot :.. %f\n",pcalo->qtot);
86			printf(" pcalo->nstrip :.. %i\n",pcalo->nstrip);
87			printf(" pcalo->track0->qtrack :.. %f\n",pcalo->GetCaloTrkVar(0)->qtrack);
88			printf(" pcalo->track0->dX0l :.. %f\n",pcalo->GetCaloTrkVar(0)->dX0l);
89			printf("========================================================================\n");
90			//
91			};
92
93			void CaloPreSampler::Delete(){
94			Clear();
95			delete pcalo;
96			//delete this;
97			};
98
99
100			void CaloPreSampler::Process(){
101			//
102			if ( !L2 ){
103			printf(" ERROR: cannot find PamLevel2 object, use the correct constructor or check your program!\n");
104			printf(" ERROR: CaloPreSampler variables _NOT_ filled \n");
105			return;
106			};
107			//
108			Bool_t newentry = false;
109			//
110			if ( L2->IsORB() ){
111			if ( L2->GetOrbitalInfo()->pkt_num != PKT \|\| L2->GetOrbitalInfo()->OBT != OBT \|\| L2->GetOrbitalInfo()->absTime != atime \|\| sel != ssel ){
112			newentry = true;
113			OBT = L2->GetOrbitalInfo()->OBT;
114			PKT = L2->GetOrbitalInfo()->pkt_num;
115			atime = L2->GetOrbitalInfo()->absTime;
116			ssel = sel;
117			};
118			} else {
119			newentry = true;
120			};
121			//
122			if ( !newentry ) return;
123			//
124			// Some variables
125			//
126			Int_t S3 = 0;
127			Int_t S2 = 0;
128			Int_t S12 = 0;
129			Int_t S11 = 0;
130			Float_t tmptrigty = -1.;
131			Bool_t trackanyway = true;
132			Float_t rigdefault = 50.;
133			Bool_t hZn = true;
134			Bool_t withtrk = true;
135			Bool_t st = true;
136			Int_t ntrkentry = 0;
137			TrkLevel2 *trk = L2->GetTrkLevel2();
138			Bool_t filled = false;
139			//
140			if ( debug ) printf(" Processing event at OBT %u PKT %u time %u \n",OBT,PKT,atime);
141			//
142			this->Clear();
143			//
144			// find out if we have trkseqno = -1, -2 or -3
145			//
146			Bool_t m1 = false;
147			Bool_t m2 = false;
148			Bool_t m3 = false;
149			for (Int_t mm=0; mm < L2->GetCaloLevel2()->ntrk(); mm++ ){
150			if ( L2->GetCaloLevel2()->GetCaloTrkVar(mm)->trkseqno == -1 ) m1 = true;
151			if ( L2->GetCaloLevel2()->GetCaloTrkVar(mm)->trkseqno == -2 ) m2 = true;
152			if ( L2->GetCaloLevel2()->GetCaloTrkVar(mm)->trkseqno == -3 ) m3 = true;
153			};
154			//
155			if ( debug ) printf(" Fill estrip matrix needed to calculate variables \n");
156			//
157			// Fill the estrip matrix
158			//
159			memset(event->clevel1->estrip, 0, 22296*sizeof(Float_t));
160			Int_t view = 0;
161			Int_t plane = 0;
162			Int_t strip = 0;
163			Float_t mip = 0.;
164			for ( Int_t i=0; i<L2->GetCaloLevel1()->istrip; i++ ){
165			//
166			mip = L2->GetCaloLevel1()->DecodeEstrip(i,view,plane,strip);
167			//
168			// Selection mode: fill the matrix only for plane < (22 - N) REMEMBER N = number of W planes to be used as presampler, ie if N = 2 then we want to use planes from 0 to 19
169			// included so plane < (22 - 2)
170			//
171			if ( sel ){
172			if ( plane < (22 - N) ){
173			//
174			if ( emulate18 && plane == (18 - N) ) mip = 0.;
175			event->clevel1->estrip[strip][plane][view] = mip;
176			//
177			};
178			};
179			//
180			// Contamination mode: fill the matrix only for planes from N to 22 but shift all planes up to the first one
181			//
182			if ( cont ){
183			if ( plane >= N ){
184			//
185			if ( emulate18 && plane == (18 + N) ) mip = 0.;
186			event->clevel1->estrip[strip][(plane-N)][view] = mip;
187			//
188			};
189			};
190			//
191			};
192			//
193			// if data comes from the simulation we must use mechanical alignment parameters (default is flight parameters)
194			//
195			if ( simulation ){
196			cstrip->UseMechanicalAlig();
197			};
198			//
199			// Set alignment parameter
200			//
201			event->clevel1->xalig = cstrip->GetXalig();
202			event->clevel1->yalig = cstrip->GetYalig();
203			event->clevel1->zalig = cstrip->GetZalig();
204			//
205			event->clevel1->emin = 0.7;
206			//
207			// in case of the contamination mode we must play with the Z alignment in order to have the correct track in the calo since we have moved the planes up...
208			//
209			if ( cont ){
210			if ( !(N%2) ){
211			event->clevel1->reverse = 0; // if the number of planes is even we have taken away a full module no need to do anything strange...
212			event->clevel1->zalig -= (N/2) * (8.09 + 10.09);
213			} else {
214			event->clevel1->reverse = 1; // if the number of planes is odd we have taken away half a module, we need to reverse silicon planes shifting
215			event->clevel1->zalig -= ((N+1)/2) * 8.09 + ((N-1)/2) * 10.09;
216			};
217			};
218			if ( debug ) printf(" xalig = %f \n",event->clevel1->xalig);
219			if ( debug ) printf(" yalig = %f \n",event->clevel1->yalig);
220			if ( debug ) printf(" zalig = %f \n",event->clevel1->zalig);
221			//
222			if ( debug ) printf(" Calculate variables as done in CaloCore, N = %i \n",N);
223			//
224			// Calculate variables
225			//
226			//
227			// use only N W planes
228			//
229			event->clevel1->npla = 22-N;
230			//
231			S3 = 0;
232			S2 = 0;
233			S12 = 0;
234			S11 = 0;
235			S3 = L2->GetTrigLevel2()->patterntrig[2];
236			S2 = L2->GetTrigLevel2()->patterntrig[3];
237			S12 = L2->GetTrigLevel2()->patterntrig[4];
238			S11 = L2->GetTrigLevel2()->patterntrig[5];
239			if ( L2->GetTrigLevel2()->patterntrig[1] & (1<<0) ) tmptrigty = 1.;
240			if ( L2->GetTrigLevel2()->patterntrig[0] ) tmptrigty = 2.;
241			if ( S3 \|\| S2 \|\| S12 \|\| S11 ) tmptrigty = 0.;
242			if ( !(L2->GetTrigLevel2()->patterntrig[1] & (1<<0)) && !L2->GetTrigLevel2()->patterntrig[0] && !S3 && !S2 && !S12 && !S11 ) tmptrigty = 1.;
243			event->clevel2->trigty = tmptrigty;
244			//
245			// do we have at least one track from the tracker? this check has been disabled
246			//
247			event->clevel1->good2 = 1;
248			//
249			// Calculate variables common to all tracks (qtot, nstrip, etc.)
250			//
251			if ( debug ) printf("1 Call GetCommonVar() \n");
252			event->GetCommonVar();
253			//
254			// Fill common variables
255			//
256			if ( debug ) printf("1 Call FillCommonVar() \n");
257			event->FillCommonVar(NULL,pcalo);
258			//
259			// Calculate variables related to tracks only if we have at least one track (from selftrigger and/or tracker)
260			//
261			ntrkentry = 0;
262			//
263			filled = false;
264			//
265			// Run over tracks (tracker or calorimeter )
266			//
267			if ( withtrk ){
268			//
269			for (Int_t nt=0; nt < trk->ntrk(); nt++){
270			//
271			event->clevel1->good2 = 1;
272			//
273			TrkTrack *ptt = trk->GetStoredTrack(nt);
274			//
275			event->clevel1->trkchi2 = 0;
276			//
277			// Copy the alpha vector in the input structure
278			//
279			for (Int_t e = 0; e < 5 ; e++){
280			event->clevel1->al_p[e][0] = ptt->al[e];
281			};
282			//
283			// Get tracker related variables for this track
284			//
285			if ( debug ) printf("track %i Call GetTrkVar() \n",nt);
286			event->GetTrkVar();
287			if ( debug ) printf(" event->clevel2->dX0l %f \n",event->clevel2->dX0l);
288			//
289			// Save tracker track sequence number
290			//
291			event->trkseqno = nt;
292			//
293			// Copy values in the class ca from the structure clevel2
294			//
295			if ( debug ) printf("track %i Call FillTrkVar() \n",nt);
296			event->FillTrkVar(pcalo,ntrkentry);
297
298
299			ntrkentry++;
300			filled = true;
301			//
302			}; // loop on all the tracks
303			};
304			//
305			// if no tracks found but there is the possibility to have a good track we should try to calculate anyway the track related variables using the calorimeter
306			// fit of the track (to be used for example when TRK is off due to any reason like IPM3/5 off).
307			// here we make an event selection so it must be done very carefully...
308			//
309			// conditions are: 0) no track from the tracker 1) we have a track fit both in x and y 2) no problems with calo for this event 3) no selftrigger event
310			//
311			// if ( trackanyway && !filled && event->clevel2->npcfit[0] >= 2 && event->clevel2->npcfit[1] >= 2 && event->clevel2->good != 0 && event->clevel2->trigty < 2. ){
312			if ( trackanyway && m3 ){
313			if ( debug ) printf(" Event with a track not fitted by the tracker \n");
314			//
315			// Disable "track mode" in the fortran routine
316			//
317			event->clevel1->good2 = 0;
318			event->clevel1->riginput = rigdefault;
319			if ( debug ) printf(" Using as default rigidity: %f \n",event->clevel1->riginput);
320			//
321			// We have a selftrigger event to analyze.
322			//
323			for (Int_t e = 0; e < 5 ; e++){
324			event->clevel1->al_p[e][0] = 0.;
325			event->clevel1->al_p[e][1] = 0.;
326			};
327			event->clevel1->trkchi2 = 0;
328			//
329			if ( debug ) printf("-3 a Call GetTrkVar() \n");
330			event->GetTrkVar();
331			//
332			// if we had no problem (clevel1->good2 = 0, NOTICE zero, not one in this mode!), fill and go on
333			//
334			if ( event->clevel1->good2 == 0 ) {
335			//
336			// In selftrigger mode the trkentry variable is set to -1
337			//
338			event->trkseqno = -3;
339			//
340			// Copy values in the class ca from the structure clevel2
341			//
342			if ( debug ) printf("-3 a Call FillTrkVar() \n");
343			event->FillTrkVar(pcalo,ntrkentry);
344			ntrkentry++;
345			filled = true;
346			//
347			} else {
348			if ( debug ) printf(" Selftrigger: problems with event \n");
349			};
350			//
351			};
352			//
353			// Call high energy nuclei routine
354			//
355			// if ( hZn && event->clevel2->trigty >= 2. ){
356			if ( hZn && m2 ){
357			if ( debug ) printf(" Calling selftrigger high energy nuclei routine \n");
358			//
359			// Disable "track mode" in the fortran routine
360			//
361			event->clevel1->good2 = 0;
362			//
363			// Set high energy nuclei flag to one
364			//
365			event->clevel1->hzn = 1;
366			event->clevel1->riginput = rigdefault;
367			//
368			// We have a selftrigger event to analyze.
369			//
370			for (Int_t e = 0; e < 5 ; e++){
371			event->clevel1->al_p[e][0] = 0.;
372			event->clevel1->al_p[e][1] = 0.;
373			};
374			event->clevel1->trkchi2 = 0;
375			//
376			if ( debug ) printf("-2 a Call GetTrkVar() \n");
377			event->GetTrkVar();
378			//
379			// if we had no problem (clevel1->good2 = 0, NOTICE zero, not one in this mode!), fill and go on
380			//
381			if ( event->clevel1->good2 == 0 ) {
382			//
383			// In selftrigger mode the trkentry variable is set to -1
384			//
385			event->trkseqno = -2;
386			//
387			// Copy values in the class ca from the structure clevel2
388			//
389			if ( debug ) printf("-2 a Call FillTrkVar() \n");
390			event->FillTrkVar(pcalo,ntrkentry);
391			ntrkentry++;
392			filled = true;
393			//
394			} else {
395			if ( debug ) printf(" Selftrigger: problems with event \n");
396			};
397			//
398			};
399			//
400			// self trigger event
401			//
402			// if ( st && event->clevel2->trigty >= 2. ){
403			if ( st && m1 ){
404			if ( debug ) printf(" Selftrigger event \n");
405			//
406			// Disable "track mode" in the fortran routine
407			//
408			event->clevel1->good2 = 0;
409			//
410			// disable high enery nuclei flag;
411			//
412			event->clevel1->hzn = 0;
413			//
414			// We have a selftrigger event to analyze.
415			//
416			for (Int_t e = 0; e < 5 ; e++){
417			event->clevel1->al_p[e][0] = 0.;
418			event->clevel1->al_p[e][1] = 0.;
419			};
420			event->clevel1->trkchi2 = 0;
421			//
422			if ( debug ) printf("-1 a Call GetTrkVar() \n");
423			event->GetTrkVar();
424			//
425			// if we had no problem (clevel2->good = 0, NOTICE zero, not one in selftrigger mode!), fill and go on
426			//
427			if ( event->clevel1->good2 == 0 ) {
428			//
429			// In selftrigger mode the trkentry variable is set to -1
430			//
431			event->trkseqno = -1;
432			//
433			// Copy values in the class ca from the structure clevel2
434			//
435			if ( debug ) printf("-1 a Call FillTrkVar() \n");
436			event->FillTrkVar(pcalo,ntrkentry);
437			ntrkentry++;
438			filled = true;
439			//
440			} else {
441			if ( debug ) printf(" Selftrigger: problems with event \n");
442			};
443			};
444			//
445			// Clear structures used to communicate with fortran
446			//
447			event->ClearStructs();
448			//
449			//
450			//
451			if ( debug ) this->Print();
452			if ( debug ) printf(" exit \n");
453			//
454			};