TrackerLevel2/src/TrkLevel1.cpp

/**
 * \file TrkLevel1.cpp
 * \author Elena Vannuccini
 */
#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*);
        
}
//--------------------------------------
//
//
//--------------------------------------
TrkCluster::TrkCluster(){
        
        view     = 0;
        maxs     = 0;
        indmax   = 0;
        
        CLlength = 0;
        clsignal = 0; 
        clsigma  = 0; 
        cladc    = 0; 
        clbad    = 0; 

};
//--------------------------------------
//
//
//--------------------------------------
TrkCluster::~TrkCluster(){
        
        delete [] clsignal; 
        delete [] clsigma; 
        delete [] cladc; 
        delete [] clbad; 
};
//--------------------------------------
//
//
//--------------------------------------
TrkCluster::TrkCluster(const TrkCluster& t){
        
        view     = t.view;
        maxs     = t.maxs;
        indmax   = t.indmax;
        
        CLlength = t.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]; 
                clsigma[i]  = t.clsigma[i]; 
                cladc[i]    = t.cladc[i]; 
                clbad[i]    = t.clbad[i]; 
        };

};
//--------------------------------------
//
//
//--------------------------------------
/**
 * Evaluate the cluster signal including all adjacent strip with a significant signal ( s > cut*sigma ).
 * @param cut Inclusion cut.
 */
Float_t TrkCluster::GetSignal(Float_t cut){
        Float_t s = 0;
        for(Int_t is = 0; is < CLlength; is++){
                Float_t scut = cut*clsigma[is];
                if(clsignal[is] > scut) s += clsignal[is];
        };
        return s;
};
/**
 * Evaluate the cluster signal including a ( maximum ) fixed number of adjacent strips (with s>0) around the maxs. 
 * @param nstrip Number of strips.
 */
Float_t TrkCluster::GetSignal(Int_t nstrip){
        
        Float_t s = 0;
        Int_t il = indmax;
        Int_t ir = indmax;
        Int_t inc = 0;
        
        while ( inc<nstrip ){
                Float_t sl = 0;
                Float_t sr = 0;
                if( il >= 0       ) sl = clsignal[il];
                if( ir < CLlength ) sr = clsignal[ir];
                if( sl == sr && inc == 0 ){
                        s += clsignal[il]; 
                        il--; 
                        ir++;
                }else if ( sl >= sr && sl>0 && inc !=0){
                        s += sl;
                        il--; 
                }else if ( sl < sr && sr>0 ){
                        s += sr;
                        ir++;
                }else break;
                
                inc++;
        }
        return s;
};
/**
 * Evaluate the cluster signal-to-noise, as defined by Turchetta, including all adjacent strip with a significant signal ( s > cut*sigma ).
 * @param cut Inclusion cut.
 */
Float_t TrkCluster::GetSignalToNoise(Float_t cut){
        Float_t sn = 0;
        for(Int_t is = 0; is < CLlength; is++){
                Float_t scut = cut*clsigma[is];
                if(clsignal[is] > scut) sn += clsignal[is]/clsigma[is];
        };
        return sn;
};
/**
 * Evaluate the cluster signal-to-noise, as defined by Turchetta, including a ( maximum ) fixed number of adjacent strips (with s>0) around the maxs. 
 * @param nstrip Number of strips.
 */
Float_t TrkCluster::GetSignalToNoise(Int_t nstrip){
        
        Float_t sn = 0;
        Int_t il = indmax;
        Int_t ir = indmax;
        Int_t inc = 0;
        
        while ( inc<nstrip ){
                Float_t sl = 0;
                Float_t sr = 0;
                if( il >= 0       ) sl = clsignal[il];
                if( ir < CLlength ) sr = clsignal[ir];
                if( sl == sr && inc == 0 ){
                        sn += clsignal[il]/clsigma[is]; 
                        il--; 
                        ir++;
                }else if ( sl >= sr && sl>0 && inc !=0){
                        sn += sl/clsigma[il];
                        il--; 
                }else if ( sl < sr && sr>0 ){
                        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++){
                Float_t scut = cut*clsigma[is];
                if(clsignal[is] > scut) m++;
        };
        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;        
        Int_t  imax = 0;        
        for(Int_t is = 0; is < CLlength; is++){
                if(clsignal[is] > max){
                        max = clsignal[is];
                        imax = is;
                };
        };
        
        Int_t il,ir;
        il = imax;
        ir = imax;*/
        
        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];
        
        return ( isbad != nbad );
};
//--------------------------------------
//
//
//--------------------------------------
void TrkCluster::Dump(){

        cout << "----- Cluster" << endl;
        cout << "View "<<view << " - Ladder "<<GetLadder()<<endl;
        cout << "Position of maximun "<< maxs <<endl;
        cout << "Multiplicity        "<< GetMultiplicity() <<endl;
        cout << "Tot signal          "<< GetSignal() << " (ADC channels)"<<endl ;
        cout << "Signal/Noise        "<< GetSignalToNoise();
        cout <<endl<< "Strip signals       ";
        for(Int_t i =0; i<CLlength; i++)cout << " " <<clsignal[i];
        cout <<endl<< "Strip sigmas        ";
        for(Int_t i =0; i<CLlength; i++)cout << " " <<clsigma[i];
        cout <<endl<< "Strip ADC           ";
        for(Int_t i =0; i<CLlength; i++)cout << " " <<cladc[i];
        cout <<endl<< "Strip BAD           ";
        for(Int_t i =0; i<CLlength; i++){
                if(i==indmax)cout << "  *" <<clbad[i]<<"*";
                else cout << " " <<clbad[i];
        }
        cout << endl;
        
}
//--------------------------------------
//
//
//--------------------------------------
/**
 * Method to fill a level1 struct with only one cluster (done to use F77 p.f.a. routines on a cluster basis). 
 */
cTrkLevel1* TrkCluster::GetLevel1Struct(){
                
        cTrkLevel1* l1 = new cTrkLevel1;
        
        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];
        };
        
        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){
        
        int ic = 1;
        level1event_ = *GetLevel1Struct();
        return cog_(&ncog,&ic);
        
};
//--------------------------------------
//
//
//--------------------------------------
/**
 * Evaluates the cluster position, in strips, relative to the strip with the maximum signal (TrkCluster::maxs), by applying the non-linear ETA-algorythm. 
 *  @param neta  Number of strips to evaluate ETA.
 *  @param angle Projected angle between particle track and detector plane.
 * 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){
        
//      LoadPfaParam();
        int ic = 1;
        level1event_ = *GetLevel1Struct();
        if(neta == 0)      return pfaeta_(&ic,&angle);
        else if(neta == 2) return pfaeta2_(&ic,&angle);
        else if(neta == 3) return pfaeta3_(&ic,&angle);
        else if(neta == 4) return pfaeta4_(&ic,&angle);
        else cout << "ETA"<<neta<<" not implemented\n";
        return 0;
        
};
 
//--------------------------------------
//
//
//--------------------------------------
TrkLevel1::TrkLevel1(){
    
//      good1 = -1;
        
        Cluster = new TClonesArray("TrkCluster");
        
        for(Int_t i=0; i<12 ; i++){
//              crc[i] = -1;
                good[i] = -1;
                for(Int_t j=0; j<24 ; j++){
                        cnev[j][i]=0;
                        cnnev[j][i]=0;
                };
//              fshower[i]=0;
        };
}
//--------------------------------------
//
//
//--------------------------------------
void TrkLevel1::Dump(){
    
        cout<<"DSP status: ";
        for(Int_t i=0; i<12 ; i++)cout<<good[i]<<" ";
        cout<<endl;
        
        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).
 */
void TrkLevel1::SetFromLevel1Struct(cTrkLevel1 *l1){

        //  *** CLUSTER ***
        TrkCluster* t_cl = new TrkCluster();
        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 struct cTrkLevel1 with values from a TrkLevel1 object (to put data into a F77 common).
 */

cTrkLevel1* TrkLevel1::GetLevel1Struct() {
        
        cTrkLevel1 *l1=0;
        //
        for(Int_t i=0; i<12 ; i++){
                l1->good[i] = good[i];
                for(Int_t j=0; j<24 ; j++){
                        l1->cnev[j][i]  = cnev[j][i];
                        l1->cnnev[j][i] = cnnev[j][i];
                };
        };
        
//  *** CLUSTERS ***
    l1->nclstr1 =  Cluster->GetEntries();
        for(Int_t i=0;i<l1->nclstr1;i++){

                l1->view[i]     = ((TrkCluster *)Cluster->At(i))->view;
                l1->maxs[i]     = ((TrkCluster *)Cluster->At(i))->maxs;
                // COMPLETARE //
                // COMPLETARE //
                // COMPLETARE //
                // COMPLETARE //
                // COMPLETARE //
                // COMPLETARE //
                
        }
        // COMPLETARE //
        // COMPLETARE //
        // COMPLETARE //
        // COMPLETARE //
        // COMPLETARE //
        // COMPLETARE //
        return l1;
}
//--------------------------------------
//
//
//--------------------------------------
void TrkLevel1::Clear(){
        
        for(Int_t i=0; i<12 ; i++){
                good[i] = -1;
                for(Int_t j=0; j<24 ; j++){
                        cnev[j][i]     = 0;
                        cnnev[j][i] = 0;
                };
        };
        //
        Cluster->Clear();

}
//--------------------------------------
//
//
//--------------------------------------
void TrkLevel1::Delete(){
        
        for(Int_t i=0; i<12 ; i++){
                good[i] = -1;
                for(Int_t j=0; j<24 ; j++){
                        cnev[j][i]     = 0;
                        cnnev[j][i] = 0;
                };
        };
        //
        Cluster->Delete();

}

//--------------------------------------
//
//
//--------------------------------------
TrkCluster *TrkLevel1::GetCluster(int is){

        if(is >= this->nclstr()){
                cout << "** TrkLevel1::GetCluster(int) ** Cluster "<< is << " does not exits! " << endl; 
                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( strcmp(path_.path,path.Data()) ){
                cout <<"Loading p.f.a. parameters\n";
                strcpy(path_.path,path.Data());
                path_.pathlen = path.Length();
                path_.error   = 0;
                return readetaparam_();
        }       
        return 0;
}


ClassImp(TrkLevel1);
ClassImp(TrkCluster);
1	/**
2	* \file TrkLevel1.cpp
3	* \author Elena Vannuccini
4	*/
5	#include <TrkLevel1.h>
6	#include <iostream>
7	using namespace std;
8	//......................................
9	// F77 routines
10	//......................................
11	extern "C" {
12
13	// int readetaparam_();
14	float cog_(int,int);
15	float pfaeta_(int,float);
16	float pfaeta2_(int,float);
17	float pfaeta3_(int,float);
18	float pfaeta4_(int,float);
19
20	}
21	//--------------------------------------
22	//
23	//
24	//--------------------------------------
25	TrkCluster::TrkCluster(){
26
27	view = 0;
28	maxs = 0;
29	indmax = 0;
30
31	CLlength = 0;
32	clsignal = 0;
33	clsigma = 0;
34	cladc = 0;
35	clbad = 0;
36
37	};
38	//--------------------------------------
39	//
40	//
41	//--------------------------------------
42	TrkCluster::~TrkCluster(){
43
44	delete [] clsignal;
45	delete [] clsigma;
46	delete [] cladc;
47	delete [] clbad;
48	};
49	//--------------------------------------
50	//
51	//
52	//--------------------------------------
53	TrkCluster::TrkCluster(const TrkCluster& t){
54
55	view = t.view;
56	maxs = t.maxs;
57	indmax = t.indmax;
58
59	CLlength = t.CLlength;
60	clsignal = new Float_t[CLlength];
61	clsigma = new Float_t[CLlength];
62	cladc = new Int_t[CLlength];
63	clbad = new Bool_t[CLlength];
64	for(Int_t i=0; i<CLlength;i++){
65	clsignal[i] = t.clsignal[i];
66	clsigma[i] = t.clsigma[i];
67	cladc[i] = t.cladc[i];
68	clbad[i] = t.clbad[i];
69	};
70
71	};
72	//--------------------------------------
73	//
74	//
75	//--------------------------------------
76	/**
77	* Evaluate the cluster signal including all adjacent strip with a significant signal ( s > cut*sigma ).
78	* @param cut Inclusion cut.
79	*/
80	Float_t TrkCluster::GetSignal(Float_t cut){
81	Float_t s = 0;
82	for(Int_t is = 0; is < CLlength; is++){
83	Float_t scut = cut*clsigma[is];
84	if(clsignal[is] > scut) s += clsignal[is];
85	};
86	return s;
87	};
88	/**
89	* Evaluate the cluster signal including a ( maximum ) fixed number of adjacent strips (with s>0) around the maxs.
90	* @param nstrip Number of strips.
91	*/
92	Float_t TrkCluster::GetSignal(Int_t nstrip){
93
94	Float_t s = 0;
95	Int_t il = indmax;
96	Int_t ir = indmax;
97	Int_t inc = 0;
98
99	while ( inc<nstrip ){
100	Float_t sl = 0;
101	Float_t sr = 0;
102	if( il >= 0 ) sl = clsignal[il];
103	if( ir < CLlength ) sr = clsignal[ir];
104	if( sl == sr && inc == 0 ){
105	s += clsignal[il];
106	il--;
107	ir++;
108	}else if ( sl >= sr && sl>0 && inc !=0){
109	s += sl;
110	il--;
111	}else if ( sl < sr && sr>0 ){
112	s += sr;
113	ir++;
114	}else break;
115
116	inc++;
117	}
118	return s;
119	};
120	/**
121	* Evaluate the cluster signal-to-noise, as defined by Turchetta, including all adjacent strip with a significant signal ( s > cut*sigma ).
122	* @param cut Inclusion cut.
123	*/
124	Float_t TrkCluster::GetSignalToNoise(Float_t cut){
125	Float_t sn = 0;
126	for(Int_t is = 0; is < CLlength; is++){
127	Float_t scut = cut*clsigma[is];
128	if(clsignal[is] > scut) sn += clsignal[is]/clsigma[is];
129	};
130	return sn;
131	};
132	/**
133	* Evaluate the cluster signal-to-noise, as defined by Turchetta, including a ( maximum ) fixed number of adjacent strips (with s>0) around the maxs.
134	* @param nstrip Number of strips.
135	*/
136	Float_t TrkCluster::GetSignalToNoise(Int_t nstrip){
137
138	Float_t sn = 0;
139	Int_t il = indmax;
140	Int_t ir = indmax;
141	Int_t inc = 0;
142
143	while ( inc<nstrip ){
144	Float_t sl = 0;
145	Float_t sr = 0;
146	if( il >= 0 ) sl = clsignal[il];
147	if( ir < CLlength ) sr = clsignal[ir];
148	if( sl == sr && inc == 0 ){
149	sn += clsignal[il]/clsigma[is];
150	il--;
151	ir++;
152	}else if ( sl >= sr && sl>0 && inc !=0){
153	sn += sl/clsigma[il];
154	il--;
155	}else if ( sl < sr && sr>0 ){
156	sn += sr/clsigma[ir];
157	ir++;
158	}else break;
159
160	inc++;
161	}
162	return sn;
163	};
164	/**
165	* Evaluate the cluster multiplicity.
166	* @param cut Inclusion cut.
167	*/
168	Int_t TrkCluster::GetMultiplicity(Float_t cut){
169	Int_t m = 0;
170	for(Int_t is = 0; is < CLlength; is++){
171	Float_t scut = cut*clsigma[is];
172	if(clsignal[is] > scut) m++;
173	};
174	return m;
175	};
176	/**
177	* True if the cluster contains bad strips.
178	* @param nbad Number of strips around the maximum.
179	*/
180	Bool_t TrkCluster::IsBad(Int_t nbad){
181
182	/* Float_t max = 0;
183	Int_t imax = 0;
184	for(Int_t is = 0; is < CLlength; is++){
185	if(clsignal[is] > max){
186	max = clsignal[is];
187	imax = is;
188	};
189	};
190
191	Int_t il,ir;
192	il = imax;
193	ir = imax;*/
194
195	Int_t il,ir;
196	il = indmax;
197	ir = indmax;
198	for(Int_t i=1; i<nbad; i++){
199	if (ir == CLlength && il == 0)break;
200	else if (ir == CLlength && il != 0)il--;
201	else if (ir != CLlength && il == 0)ir++;
202	else{
203	if(clsignal[il-1] > clsignal[ir+1])il--;
204	else ir++;
205	}
206	}
207	Int_t isbad = 0;
208	for(Int_t i=il; i<=ir; i++)isbad += clbad[i];
209
210	return ( isbad != nbad );
211	};
212	//--------------------------------------
213	//
214	//
215	//--------------------------------------
216	void TrkCluster::Dump(){
217
218	cout << "----- Cluster" << endl;
219	cout << "View "<<view << " - Ladder "<<GetLadder()<<endl;
220	cout << "Position of maximun "<< maxs <<endl;
221	cout << "Multiplicity "<< GetMultiplicity() <<endl;
222	cout << "Tot signal "<< GetSignal() << " (ADC channels)"<<endl ;
223	cout << "Signal/Noise "<< GetSignalToNoise();
224	cout <<endl<< "Strip signals ";
225	for(Int_t i =0; i<CLlength; i++)cout << " " <<clsignal[i];
226	cout <<endl<< "Strip sigmas ";
227	for(Int_t i =0; i<CLlength; i++)cout << " " <<clsigma[i];
228	cout <<endl<< "Strip ADC ";
229	for(Int_t i =0; i<CLlength; i++)cout << " " <<cladc[i];
230	cout <<endl<< "Strip BAD ";
231	for(Int_t i =0; i<CLlength; i++){
232	if(i==indmax)cout << " " <<clbad[i]<<"";
233	else cout << " " <<clbad[i];
234	}
235	cout << endl;
236
237	}
238	//--------------------------------------
239	//
240	//
241	//--------------------------------------
242	/**
243	* Method to fill a level1 struct with only one cluster (done to use F77 p.f.a. routines on a cluster basis).
244	*/
245	cTrkLevel1* TrkCluster::GetLevel1Struct(){
246
247	cTrkLevel1* l1 = new cTrkLevel1;
248
249	l1->nclstr1 = 1;
250	l1->view[0] = view;
251	l1->ladder[0] = GetLadder();
252	l1->maxs[0] = maxs;
253	l1->mult[0] = GetMultiplicity();
254	l1->dedx[0] = GetSignal();
255	l1->indstart[0] = 1;
256	l1->indmax[0] = indmax+1;
257	l1->totCLlength = CLlength;
258	for(Int_t i=0; i<CLlength; i++){
259	l1->clsignal[i] = clsignal[i];
260	l1->clsigma[i] = clsigma[i];
261	l1->cladc[i] = cladc[i];
262	l1->clbad[i] = clbad[i];
263	};
264
265	return l1;
266	};
267	//--------------------------------------
268	//
269	//
270	//--------------------------------------
271	/**
272	* Evaluates the Center-Of-Gravity (COG) of the cluster, in strips, relative to the strip with the maximum signal (TrkCluster::maxs).
273	* @param ncog Number of strips to evaluate COG.
274	* If ncog=0, the COG of the cluster is evaluated according to the cluster multiplicity (defined by the inclusion cut).
275	* If ncog>0, the COG is evaluated using ncog strips, even if they have a negative signal (according to G.Landi)
276	*/
277	Float_t TrkCluster::GetCOG(Int_t ncog){
278
279	int ic = 1;
280	level1event_ = *GetLevel1Struct();
281	return cog_(&ncog,&ic);
282
283	};
284	//--------------------------------------
285	//
286	//
287	//--------------------------------------
288	/**
289	* Evaluates the cluster position, in strips, relative to the strip with the maximum signal (TrkCluster::maxs), by applying the non-linear ETA-algorythm.
290	* @param neta Number of strips to evaluate ETA.
291	* @param angle Projected angle between particle track and detector plane.
292	* Implemented values of neta are 2,3,4. If neta=0, ETA2, ETA3 and ETA4 are applied according to the angle.
293	*/
294	Float_t TrkCluster::GetETA(Int_t neta, float angle){
295
296	// LoadPfaParam();
297	int ic = 1;
298	level1event_ = *GetLevel1Struct();
299	if(neta == 0) return pfaeta_(&ic,&angle);
300	else if(neta == 2) return pfaeta2_(&ic,&angle);
301	else if(neta == 3) return pfaeta3_(&ic,&angle);
302	else if(neta == 4) return pfaeta4_(&ic,&angle);
303	else cout << "ETA"<<neta<<" not implemented\n";
304	return 0;
305
306	};
307
308	//--------------------------------------
309	//
310	//
311	//--------------------------------------
312	TrkLevel1::TrkLevel1(){
313
314	// good1 = -1;
315
316	Cluster = new TClonesArray("TrkCluster");
317
318	for(Int_t i=0; i<12 ; i++){
319	// crc[i] = -1;
320	good[i] = -1;
321	for(Int_t j=0; j<24 ; j++){
322	cnev[j][i]=0;
323	cnnev[j][i]=0;
324	};
325	// fshower[i]=0;
326	};
327	}
328	//--------------------------------------
329	//
330	//
331	//--------------------------------------
332	void TrkLevel1::Dump(){
333
334	cout<<"DSP status: ";
335	for(Int_t i=0; i<12 ; i++)cout<<good[i]<<" ";
336	cout<<endl;
337
338	TClonesArray &t = *Cluster;
339	for(int i=0; i<this->nclstr(); i++) ((TrkCluster *)t[i])->Dump();
340
341	}
342	//--------------------------------------
343	//
344	//
345	//--------------------------------------
346	/**
347	* Fills a TrkLevel1 object with values from a struct cTrkLevel1 (to get data from F77 common).
348	*/
349	void TrkLevel1::SetFromLevel1Struct(cTrkLevel1 *l1){
350
351	// * CLUSTER *
352	TrkCluster* t_cl = new TrkCluster();
353	TClonesArray &t = *Cluster;
354	for(int i=0; i<l1->nclstr1; i++){
355
356	t_cl->view = l1->view[i];
357	t_cl->maxs = l1->maxs[i];
358	t_cl->indmax = l1->indmax[i] - l1->indstart[i];
359
360	Int_t from = l1->indstart[i] -1;
361	Int_t to = l1->totCLlength ;
362	if(i != l1->nclstr1-1)to = l1->indstart[i+1] -1 ;
363	t_cl->CLlength = to - from ;
364
365	t_cl->clsignal = new Float_t[t_cl->CLlength];
366	t_cl->clsigma = new Float_t[t_cl->CLlength];
367	t_cl->cladc = new Int_t[t_cl->CLlength];
368	t_cl->clbad = new Bool_t[t_cl->CLlength];
369	Int_t index = 0;
370	for(Int_t is = from; is < to; is++ ){
371	t_cl->clsignal[index] = (Float_t) l1->clsignal[is];
372	t_cl->clsigma[index] = (Float_t) l1->clsigma[is];
373	t_cl->cladc[index] = (Int_t) l1->cladc[is];
374	t_cl->clbad[index] = (Bool_t) l1->clbad[is];
375	index++;
376	};
377
378	new(t[i]) TrkCluster(*t_cl);
379	};
380
381	delete t_cl;
382
383	// **general variables**
384
385	for(Int_t i=0; i<12 ; i++){
386	good[i] = -1;
387	for(Int_t j=0; j<24 ; j++){
388	cnev[j][i] = l1->cnev[j][i];
389	cnnev[j][i] = l1->cnnev[j][i];
390	};
391	};
392
393	}
394	/**
395	* Fills a struct cTrkLevel1 with values from a TrkLevel1 object (to put data into a F77 common).
396	*/
397
398	cTrkLevel1* TrkLevel1::GetLevel1Struct() {
399
400	cTrkLevel1 *l1=0;
401	//
402	for(Int_t i=0; i<12 ; i++){
403	l1->good[i] = good[i];
404	for(Int_t j=0; j<24 ; j++){
405	l1->cnev[j][i] = cnev[j][i];
406	l1->cnnev[j][i] = cnnev[j][i];
407	};
408	};
409
410	// * CLUSTERS *
411	l1->nclstr1 = Cluster->GetEntries();
412	for(Int_t i=0;i<l1->nclstr1;i++){
413
414	l1->view[i] = ((TrkCluster *)Cluster->At(i))->view;
415	l1->maxs[i] = ((TrkCluster *)Cluster->At(i))->maxs;
416	// COMPLETARE //
417	// COMPLETARE //
418	// COMPLETARE //
419	// COMPLETARE //
420	// COMPLETARE //
421	// COMPLETARE //
422
423	}
424	// COMPLETARE //
425	// COMPLETARE //
426	// COMPLETARE //
427	// COMPLETARE //
428	// COMPLETARE //
429	// COMPLETARE //
430	return l1;
431	}
432	//--------------------------------------
433	//
434	//
435	//--------------------------------------
436	void TrkLevel1::Clear(){
437
438	for(Int_t i=0; i<12 ; i++){
439	good[i] = -1;
440	for(Int_t j=0; j<24 ; j++){
441	cnev[j][i] = 0;
442	cnnev[j][i] = 0;
443	};
444	};
445	//
446	Cluster->Clear();
447
448	}
449	//--------------------------------------
450	//
451	//
452	//--------------------------------------
453	void TrkLevel1::Delete(){
454
455	for(Int_t i=0; i<12 ; i++){
456	good[i] = -1;
457	for(Int_t j=0; j<24 ; j++){
458	cnev[j][i] = 0;
459	cnnev[j][i] = 0;
460	};
461	};
462	//
463	Cluster->Delete();
464
465	}
466
467	//--------------------------------------
468	//
469	//
470	//--------------------------------------
471	TrkCluster *TrkLevel1::GetCluster(int is){
472
473	if(is >= this->nclstr()){
474	cout << " TrkLevel1::GetCluster(int) Cluster "<< is << " does not exits! " << endl;
475	cout << "( Stored clusters nclstr() = "<< this->nclstr()<<" )" << endl;
476	return 0;
477	}
478	TClonesArray &t = *(Cluster);
479	TrkCluster cluster = (TrkCluster)t[is];
480	return cluster;
481	}
482	//--------------------------------------
483	//
484	//
485	//--------------------------------------
486	/**
487	* Load Position-Finding-Algorythm parameters (call the F77 routine).
488	*
489	*/
490	int TrkLevel1::LoadPfaParam(TString path){
491
492	if( strcmp(path_.path,path.Data()) ){
493	cout <<"Loading p.f.a. parameters\n";
494	strcpy(path_.path,path.Data());
495	path_.pathlen = path.Length();
496	path_.error = 0;
497	return readetaparam_();
498	}
499	return 0;
500	}
501
502
503	ClassImp(TrkLevel1);
504	ClassImp(TrkCluster);