CaloDoubleShower/src/CaloDoubleShower.cpp

/**
 * \file CaloDoubleShower.cpp
 * \author Emiliano Mocchiutti (2007/08/10)
 */
//
// headers
//
#include <CaloDoubleShower.h>
//--------------------------------------
/**
 * Default constructor 
 */
CaloDoubleShower::CaloDoubleShower(){
  Clear();
};

CaloDoubleShower::CaloDoubleShower(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
  //
  extern struct Calo2sh sdouble_;
  c2s = &sdouble_;
  event = new CaloLevel0();
  cstrip = new CaloStrip(false);
  debug = false;
  simulation = false;
  usepl18x = false;
  //
  Clear();
  //
};

void CaloDoubleShower::LoadMagneticField(){
  //
  // 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 CaloDoubleShower::Clear(){
  //
  dbls = 0;
  qdbls = 0.;
  //
};

void CaloDoubleShower::Print(){
  Print(0);
};

void CaloDoubleShower::Print(UInt_t nt){
  //
  Process(nt);
  //
  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(" dbls         [double shower flag]:.. %i\n",dbls);
  printf(" qdbls      [double shower energy]:.. %f\n",qdbls);
  printf("========================================================================\n");
  //
};

void CaloDoubleShower::Delete(){
  Clear();
};


void CaloDoubleShower::Process(){
  Process(0);
};

void CaloDoubleShower::Process(UInt_t ntr){
  //  
  if ( !L2 ){
    printf(" ERROR: cannot find PamLevel2 object, use the correct constructor or check your program!\n");
    printf(" ERROR: CaloDoubleShower 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  || ntr != sntr){
      newentry = true;
      OBT = L2->GetOrbitalInfo()->OBT;
      PKT = L2->GetOrbitalInfo()->pkt_num;
      atime = L2->GetOrbitalInfo()->absTime;
      sntr = ntr;
   };
  } else {
    newentry = true;
  };
  //
  if ( !newentry ) return;
  //
  // check track
  //
  PamTrack *ptrack = 0;
  if ( ntr >= 0 ){
    ptrack = L2->GetTrack(ntr);
  };
  //
  if ( !ptrack ){
    printf(" ERROR: cannot find requested track!\n");
    printf(" ERROR: CaloDoubleShower variables _NOT_ filled \n");    
    return;
  };
  //
  tr = ntr;
  //
  if ( debug ) printf(" Processing event at OBT %u PKT %u time %u \n",OBT,PKT,atime);
  //
  this->Clear();
  //
  // Some variables
  //

  //
  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);
    //
    if ( !usepl18x && view==0 && plane==18 ) mip = 0.;
    //
    event->clevel1->estrip[strip][plane][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;
  event->clevel1->npla = 22;
  event->clevel1->reverse = 0; // if the number of planes is even we have taken away a full module no need to do anything strange...
  //
  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);
  //
  // let's go
  //
  TrkTrack *ptt = ptrack->GetTrkTrack(); 
  //
  // 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];
  };      
  //
  Float_t m = (ptrack->GetToFTrack()->xtr_tof[0] - ptrack->GetToFTrack()->xtr_tof[3])/(ZTOF11-ZTOF21);
  Float_t q = ptrack->GetToFTrack()->xtr_tof[3] - m * ZTOF21;
  //
  c2s->pos = (m * (event->clevel1->zalig/10.) + q)*10. + event->clevel1->xalig;
  c2s->angol = m;
  //
  // call fortran routine
  //
  getdblsh();
  //
  // retrieve calculated variables;
  //
  dbls = (Int_t)c2s->dbls;
  qdbls = c2s->dblsq;
  //
  if ( debug ) this->Print();
  if ( debug ) printf(" exit \n");
  //
};
1	/**
2	* \file CaloDoubleShower.cpp
3	* \author Emiliano Mocchiutti (2007/08/10)
4	*/
5	//
6	// headers
7	//
8	#include <CaloDoubleShower.h>
9	//--------------------------------------
10	/**
11	* Default constructor
12	*/
13	CaloDoubleShower::CaloDoubleShower(){
14	Clear();
15	};
16
17	CaloDoubleShower::CaloDoubleShower(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	extern struct Calo2sh sdouble_;
30	c2s = &sdouble_;
31	event = new CaloLevel0();
32	cstrip = new CaloStrip(false);
33	debug = false;
34	simulation = false;
35	usepl18x = false;
36	//
37	Clear();
38	//
39	};
40
41	void CaloDoubleShower::LoadMagneticField(){
42	//
43	// loading magnetic field...
44	//
45	TrkLevel2 *trk = new TrkLevel2();
46	GL_PARAM *q4 = new GL_PARAM();
47	TSQLServer *dbc = 0;
48	TString host = "mysql://localhost/pamelaprod";
49	TString user = "anonymous";
50	TString psw = "";
51	const char *pamdbhost=gSystem->Getenv("PAM_DBHOST");
52	const char *pamdbuser=gSystem->Getenv("PAM_DBUSER");
53	const char *pamdbpsw=gSystem->Getenv("PAM_DBPSW");
54	if ( !pamdbhost ) pamdbhost = "";
55	if ( !pamdbuser ) pamdbuser = "";
56	if ( !pamdbpsw ) pamdbpsw = "";
57	if ( strcmp(pamdbhost,"") ) host = pamdbhost;
58	if ( strcmp(pamdbuser,"") ) user = pamdbuser;
59	if ( strcmp(pamdbpsw,"") ) psw = pamdbpsw;
60	dbc = TSQLServer::Connect(host.Data(),user.Data(),psw.Data());
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 CaloDoubleShower::Clear(){
68	//
69	dbls = 0;
70	qdbls = 0.;
71	//
72	};
73
74	void CaloDoubleShower::Print(){
75	Print(0);
76	};
77
78	void CaloDoubleShower::Print(UInt_t nt){
79	//
80	Process(nt);
81	//
82	printf("========================================================================\n");
83	printf(" OBT: %u PKT: %u ATIME: %u \n",OBT,PKT,atime);
84	printf(" debug [debug flag]:.. %i\n",debug);
85	printf(" simulation [simulation flag]:.. %i\n",simulation);
86	printf(" dbls [double shower flag]:.. %i\n",dbls);
87	printf(" qdbls [double shower energy]:.. %f\n",qdbls);
88	printf("========================================================================\n");
89	//
90	};
91
92	void CaloDoubleShower::Delete(){
93	Clear();
94	};
95
96
97	void CaloDoubleShower::Process(){
98	Process(0);
99	};
100
101	void CaloDoubleShower::Process(UInt_t ntr){
102	//
103	if ( !L2 ){
104	printf(" ERROR: cannot find PamLevel2 object, use the correct constructor or check your program!\n");
105	printf(" ERROR: CaloDoubleShower variables _NOT_ filled \n");
106	return;
107	};
108	//
109	Bool_t newentry = false;
110	//
111	if ( L2->IsORB() ){
112	if ( L2->GetOrbitalInfo()->pkt_num != PKT \|\| L2->GetOrbitalInfo()->OBT != OBT \|\| L2->GetOrbitalInfo()->absTime != atime \|\| ntr != sntr){
113	newentry = true;
114	OBT = L2->GetOrbitalInfo()->OBT;
115	PKT = L2->GetOrbitalInfo()->pkt_num;
116	atime = L2->GetOrbitalInfo()->absTime;
117	sntr = ntr;
118	};
119	} else {
120	newentry = true;
121	};
122	//
123	if ( !newentry ) return;
124	//
125	// check track
126	//
127	PamTrack *ptrack = 0;
128	if ( ntr >= 0 ){
129	ptrack = L2->GetTrack(ntr);
130	};
131	//
132	if ( !ptrack ){
133	printf(" ERROR: cannot find requested track!\n");
134	printf(" ERROR: CaloDoubleShower variables _NOT_ filled \n");
135	return;
136	};
137	//
138	tr = ntr;
139	//
140	if ( debug ) printf(" Processing event at OBT %u PKT %u time %u \n",OBT,PKT,atime);
141	//
142	this->Clear();
143	//
144	// Some variables
145	//
146
147	//
148	if ( debug ) printf(" Fill estrip matrix needed to calculate variables \n");
149	//
150	// Fill the estrip matrix
151	//
152	memset(event->clevel1->estrip, 0, 22296*sizeof(Float_t));
153	Int_t view = 0;
154	Int_t plane = 0;
155	Int_t strip = 0;
156	Float_t mip = 0.;
157	for ( Int_t i=0; i<L2->GetCaloLevel1()->istrip; i++ ){
158	//
159	mip = L2->GetCaloLevel1()->DecodeEstrip(i,view,plane,strip);
160	//
161	if ( !usepl18x && view==0 && plane==18 ) mip = 0.;
162	//
163	event->clevel1->estrip[strip][plane][view] = mip;
164	//
165	};
166	//
167	// if data comes from the simulation we must use mechanical alignment parameters (default is flight parameters)
168	//
169	if ( simulation ){
170	cstrip->UseMechanicalAlig();
171	};
172	//
173	// Set alignment parameter
174	//
175	event->clevel1->xalig = cstrip->GetXalig();
176	event->clevel1->yalig = cstrip->GetYalig();
177	event->clevel1->zalig = cstrip->GetZalig();
178	//
179	event->clevel1->emin = 0.7;
180	event->clevel1->npla = 22;
181	event->clevel1->reverse = 0; // if the number of planes is even we have taken away a full module no need to do anything strange...
182	//
183	if ( debug ) printf(" xalig = %f \n",event->clevel1->xalig);
184	if ( debug ) printf(" yalig = %f \n",event->clevel1->yalig);
185	if ( debug ) printf(" zalig = %f \n",event->clevel1->zalig);
186	//
187	// let's go
188	//
189	TrkTrack *ptt = ptrack->GetTrkTrack();
190	//
191	// Copy the alpha vector in the input structure
192	//
193	for (Int_t e = 0; e < 5 ; e++){
194	event->clevel1->al_p[e][0] = ptt->al[e];
195	};
196	//
197	Float_t m = (ptrack->GetToFTrack()->xtr_tof[0] - ptrack->GetToFTrack()->xtr_tof[3])/(ZTOF11-ZTOF21);
198	Float_t q = ptrack->GetToFTrack()->xtr_tof[3] - m * ZTOF21;
199	//
200	c2s->pos = (m * (event->clevel1->zalig/10.) + q)*10. + event->clevel1->xalig;
201	c2s->angol = m;
202	//
203	// call fortran routine
204	//
205	getdblsh();
206	//
207	// retrieve calculated variables;
208	//
209	dbls = (Int_t)c2s->dbls;
210	qdbls = c2s->dblsq;
211	//
212	if ( debug ) this->Print();
213	if ( debug ) printf(" exit \n");
214	//
215	};