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b9d0a01d | 1 | #define METHODDEBUG |
2 | ||
3 | // Fortran | |
4 | #include "TCallf77.h" | |
5 | ||
6 | // Fluka commons | |
7 | #include "Fdblprc.h" //(DBLPRC) fluka common | |
8 | #include "Fdimpar.h" //(DIMPAR) fluka parameters | |
9 | #include "Fepisor.h" //(EPISOR) fluka common | |
10 | #include "Fstack.h" //(STACK) fluka common | |
11 | #include "Fstars.h" //(STARS) fluka common | |
12 | #include "Fbeam.h" //(BEAM) fluka common | |
13 | #include "Fpaprop.h" //(PAPROP) fluka common | |
14 | #include "Fltclcm.h" //(LTCLCM) fluka common | |
15 | //#include "Fcaslim.h" //(CASLIM) fluka common | |
16 | ||
17 | //Virutal MC | |
18 | #include "TFluka.h" | |
19 | #include "TVirtualMCStack.h" | |
45dc600a | 20 | #include "TVirtualMCApplication.h" |
b9d0a01d | 21 | #include "TParticle.h" |
22 | #include "TVector3.h" | |
23 | ||
24 | //Other | |
eae0fe66 | 25 | #include <Riostream.h> |
b9d0a01d | 26 | |
27 | #ifndef WIN32 | |
28 | # define source source_ | |
29 | # define geocrs geocrs_ | |
30 | # define georeg georeg_ | |
31 | # define geohsm geohsm_ | |
32 | # define soevsv soevsv_ | |
33 | #else | |
34 | # define source SOURCE | |
35 | # define geocrs GEOCRS | |
36 | # define georeg GEOREG | |
37 | # define geohsm GEOHSM | |
38 | # define soevsv SOEVSV | |
39 | #endif | |
40 | ||
b9d0a01d | 41 | extern "C" { |
42 | // | |
43 | // Prototypes for FLUKA functions | |
44 | // | |
45 | void type_of_call geocrs(Double_t &, Double_t &, Double_t &); | |
46 | void type_of_call georeg(Double_t &, Double_t &, Double_t &, | |
47 | Int_t &, Int_t &); | |
48 | void type_of_call geohsm(Int_t &, Int_t &, Int_t &, Int_t &); | |
49 | void type_of_call soevsv(); | |
50 | /* | |
51 | *----------------------------------------------------------------------* | |
52 | * * | |
53 | * Created on 07 january 1990 by Alfredo Ferrari & Paola Sala * | |
54 | * Infn - Milan * | |
55 | * * | |
56 | * Last change on 21-jun-98 by Alfredo Ferrari * | |
57 | * * | |
58 | * C++ version on 27-sep-02 by Isidro Gonzalez * | |
59 | * * | |
60 | * This is just an example of a possible user written source routine. * | |
61 | * note that the beam card still has some meaning - in the scoring the * | |
62 | * maximum momentum used in deciding the binning is taken from the * | |
63 | * beam momentum. Other beam card parameters are obsolete. * | |
64 | * * | |
65 | *----------------------------------------------------------------------*/ | |
66 | ||
67 | void source(Int_t& nomore) { | |
68 | #ifdef METHODDEBUG | |
ce60a136 | 69 | cout << "==> source(" << nomore << ")" << endl; |
b9d0a01d | 70 | #endif |
71 | ||
ce60a136 | 72 | cout << "\t* EPISOR.lsouit = " << (EPISOR.lsouit?'T':'F') << endl; |
b9d0a01d | 73 | |
ce60a136 | 74 | static Bool_t lfirst = true; |
75 | static Bool_t particleIsPrimary = true; | |
76 | static Bool_t lastParticleWasPrimary = true; | |
77 | ||
78 | /* +-------------------------------------------------------------------* | |
79 | * First call initializations for FLUKA: */ | |
b9d0a01d | 80 | |
b9d0a01d | 81 | |
ce60a136 | 82 | nomore = 0; |
b9d0a01d | 83 | // Get the pointer to the VMC |
84 | TVirtualMC* fluka = TFluka::GetMC(); | |
ce60a136 | 85 | // Get the stack |
b9d0a01d | 86 | TVirtualMCStack* cppstack = fluka->GetStack(); |
ce60a136 | 87 | TParticle* particle; |
b9d0a01d | 88 | Int_t itrack = -1; |
ce60a136 | 89 | Int_t nprim = cppstack->GetNprimary(); |
90 | // Get the next particle from the stack | |
91 | particle = cppstack->PopNextTrack(itrack); | |
92 | ||
93 | // Is this a secondary not handled by Fluka, i.e. a particle added by user action ? | |
94 | lastParticleWasPrimary = particleIsPrimary; | |
95 | ||
96 | if (itrack >= nprim) { | |
97 | particleIsPrimary = kFALSE; | |
98 | } else { | |
99 | particleIsPrimary = kTRUE; | |
100 | } | |
101 | ||
102 | // printf("--->Got Particle %d %d %d\n", itrack, particleIsPrimary, lastParticleWasPrimary); | |
103 | ||
104 | if (lfirst) { | |
105 | EPISOR.tkesum = zerzer; | |
106 | lfirst = false; | |
107 | EPISOR.lussrc = true; | |
108 | } else { | |
109 | // | |
110 | // Post-track actions for primary track | |
111 | // | |
112 | if (particleIsPrimary) { | |
113 | TVirtualMCApplication::Instance()->PostTrack(); | |
114 | TVirtualMCApplication::Instance()->FinishPrimary(); | |
115 | } | |
116 | } | |
b9d0a01d | 117 | |
118 | //Exit if itrack is negative (-1). Set lsouit to false to mark last track for | |
119 | //this event | |
ce60a136 | 120 | |
b9d0a01d | 121 | if (itrack<0) { |
122 | nomore = 1; | |
123 | EPISOR.lsouit = false; | |
124 | cout << "\t* EPISOR.lsouit = " << (EPISOR.lsouit?'T':'F') << endl; | |
125 | cout << "\t* No more particles. Exiting..." << endl; | |
126 | #ifdef METHODDEBUG | |
127 | cout << "<== source(" << nomore << ")" << endl; | |
128 | #endif | |
129 | return; | |
130 | } | |
ce60a136 | 131 | |
b9d0a01d | 132 | //Get some info about the particle and print it |
ce60a136 | 133 | // |
134 | //pdg code | |
135 | Int_t pdg = particle->GetPdgCode(); | |
136 | ||
b9d0a01d | 137 | TVector3 polarisation; |
138 | particle->GetPolarisation(polarisation); | |
139 | cout << "\t* Particle " << itrack << " retrieved..." << endl; | |
140 | cout << "\t\t+ Name = " << particle->GetName() << endl; | |
ce60a136 | 141 | cout << "\t\t+ PDG/Fluka code = " << pdg |
142 | << " / " << fluka->IdFromPDG(pdg) << endl; | |
b9d0a01d | 143 | cout << "\t\t+ P = (" |
144 | << particle->Px() << " , " | |
145 | << particle->Py() << " , " | |
146 | << particle->Pz() << " ) --> " | |
147 | << particle->P() << " GeV" << endl; | |
b9d0a01d | 148 | /* Lstack is the stack counter: of course any time source is called it |
149 | * must be =0 | |
150 | */ | |
45dc600a | 151 | |
b9d0a01d | 152 | STACK.lstack++; |
ce60a136 | 153 | |
b9d0a01d | 154 | /* Wt is the weight of the particle*/ |
155 | STACK.wt[STACK.lstack] = oneone; | |
156 | STARS.weipri += STACK.wt[STACK.lstack]; | |
ce60a136 | 157 | |
b9d0a01d | 158 | /* Particle type (1=proton.....). Ijbeam is the type set by the BEAM |
159 | * card | |
160 | */ | |
ce60a136 | 161 | |
b9d0a01d | 162 | //STACK.ilo[STACK.lstack] = BEAM.ijbeam; |
ce60a136 | 163 | if (pdg == 50000050 || pdg == 50000051) { |
164 | STACK.ilo[STACK.lstack] = fluka-> IdFromPDG(22); | |
165 | } else { | |
166 | STACK.ilo[STACK.lstack] = fluka-> IdFromPDG(pdg); | |
167 | } | |
168 | ||
169 | ||
170 | ||
171 | ||
b9d0a01d | 172 | /* From this point ..... |
173 | * Particle generation (1 for primaries) | |
ce60a136 | 174 | */ |
b9d0a01d | 175 | STACK.lo[STACK.lstack] = 1; |
ce60a136 | 176 | |
b9d0a01d | 177 | /* User dependent flag:*/ |
178 | STACK.louse[STACK.lstack] = 0; | |
ce60a136 | 179 | |
b9d0a01d | 180 | /* User dependent spare variables:*/ |
148ba0b4 | 181 | Int_t ispr = 0; |
182 | for (ispr = 0; ispr < mkbmx1; ispr++) | |
b9d0a01d | 183 | STACK.sparek[STACK.lstack][ispr] = zerzer; |
ce60a136 | 184 | |
b9d0a01d | 185 | /* User dependent spare flags:*/ |
148ba0b4 | 186 | for (ispr = 0; ispr < mkbmx2; ispr++) |
b9d0a01d | 187 | STACK.ispark[STACK.lstack][ispr] = 0; |
ce60a136 | 188 | |
b9d0a01d | 189 | /* Save the track number of the stack particle:*/ |
5d298556 | 190 | STACK.ispark[STACK.lstack][mkbmx2-1] = itrack; |
b9d0a01d | 191 | STACK.nparma++; |
192 | STACK.numpar[STACK.lstack] = STACK.nparma; | |
193 | STACK.nevent[STACK.lstack] = 0; | |
194 | STACK.dfnear[STACK.lstack] = +zerzer; | |
ce60a136 | 195 | |
196 | /* Particle age (s)*/ | |
b9d0a01d | 197 | STACK.agestk[STACK.lstack] = +zerzer; |
198 | STACK.aknshr[STACK.lstack] = -twotwo; | |
ce60a136 | 199 | |
b9d0a01d | 200 | /* Group number for "low" energy neutrons, set to 0 anyway*/ |
201 | STACK.igroup[STACK.lstack] = 0; | |
ce60a136 | 202 | |
203 | /* Kinetic energy */ | |
204 | if (pdg == 50000050 || pdg == 50000051) { | |
205 | // | |
206 | // Special case for optical photons | |
207 | STACK.tke[STACK.lstack] = particle->Energy(); | |
208 | } else { | |
209 | STACK.tke[STACK.lstack] = particle->Energy() - particle->GetMass(); | |
210 | } | |
211 | ||
b9d0a01d | 212 | |
213 | /* Particle momentum*/ | |
b9d0a01d | 214 | STACK.pmom [STACK.lstack] = particle->P(); |
215 | ||
ce60a136 | 216 | /* Cosines (tx,ty,tz)*/ |
b9d0a01d | 217 | Double_t cosx = particle->Px()/particle->P(); |
218 | Double_t cosy = particle->Py()/particle->P(); | |
57dd4539 | 219 | Double_t cosz = TMath::Sqrt(oneone - cosx*cosx - cosy*cosy); |
220 | if (particle->Pz() < 0.) cosz = -cosz; | |
b9d0a01d | 221 | STACK.tx [STACK.lstack] = cosx; |
222 | STACK.ty [STACK.lstack] = cosy; | |
223 | STACK.tz [STACK.lstack] = cosz; | |
224 | ||
ce60a136 | 225 | /* Polarization cosines:*/ |
b9d0a01d | 226 | if (polarisation.Mag()) { |
ce60a136 | 227 | Double_t cospolx = polarisation.Px()/polarisation.Mag(); |
228 | Double_t cospoly = polarisation.Py()/polarisation.Mag(); | |
229 | Double_t cospolz = sqrt(oneone - cospolx*cospolx - cospoly*cospoly); | |
230 | STACK.tx [STACK.lstack] = cospolx; | |
231 | STACK.ty [STACK.lstack] = cospoly; | |
232 | STACK.tz [STACK.lstack] = cospolz; | |
b9d0a01d | 233 | } |
234 | else { | |
ce60a136 | 235 | STACK.txpol [STACK.lstack] = -twotwo; |
236 | STACK.typol [STACK.lstack] = +zerzer; | |
237 | STACK.tzpol [STACK.lstack] = +zerzer; | |
b9d0a01d | 238 | } |
239 | ||
240 | /* Particle coordinates*/ | |
ce60a136 | 241 | // Vertext coordinates; |
b9d0a01d | 242 | STACK.xa [STACK.lstack] = particle->Vx(); |
243 | STACK.ya [STACK.lstack] = particle->Vy(); | |
244 | STACK.za [STACK.lstack] = particle->Vz(); | |
245 | ||
b9d0a01d | 246 | /* Calculate the total kinetic energy of the primaries: don't change*/ |
247 | Int_t st_ilo = STACK.ilo[STACK.lstack]; | |
248 | if ( st_ilo != 0 ) | |
ce60a136 | 249 | EPISOR.tkesum += |
250 | ((STACK.tke[STACK.lstack] + PAPROP.amdisc[st_ilo+6]) | |
251 | * STACK.wt[STACK.lstack]); | |
b9d0a01d | 252 | else |
ce60a136 | 253 | EPISOR.tkesum += (STACK.tke[STACK.lstack] * STACK.wt[STACK.lstack]); |
b9d0a01d | 254 | |
255 | /* Here we ask for the region number of the hitting point. | |
256 | * NREG (LSTACK) = ... | |
257 | * The following line makes the starting region search much more | |
258 | * robust if particles are starting very close to a boundary: | |
259 | */ | |
260 | geocrs( STACK.tx[STACK.lstack], | |
261 | STACK.ty[STACK.lstack], | |
262 | STACK.tz[STACK.lstack] ); | |
ce60a136 | 263 | |
b9d0a01d | 264 | Int_t idisc; |
ce60a136 | 265 | |
b9d0a01d | 266 | georeg ( STACK.xa[STACK.lstack], |
267 | STACK.ya[STACK.lstack], | |
268 | STACK.za[STACK.lstack], | |
269 | STACK.nreg[STACK.lstack], | |
270 | idisc);//<-- dummy return variable not used | |
b9d0a01d | 271 | /* Do not change these cards:*/ |
272 | Int_t igeohsm1 = 1; | |
273 | Int_t igeohsm2 = -11; | |
274 | geohsm ( STACK.nhspnt[STACK.lstack], igeohsm1, igeohsm2, LTCLCM.mlattc ); | |
275 | STACK.nlattc[STACK.lstack] = LTCLCM.mlattc; | |
276 | soevsv(); | |
ce60a136 | 277 | // |
278 | // Pre-track actions at for primary tracks | |
279 | // | |
280 | if (particleIsPrimary) { | |
281 | TVirtualMCApplication::Instance()->BeginPrimary(); | |
282 | TVirtualMCApplication::Instance()->PreTrack(); | |
283 | } | |
284 | ||
285 | // | |
286 | ||
b9d0a01d | 287 | #ifdef METHODDEBUG |
288 | cout << "<== source(" << nomore << ")" << endl; | |
289 | #endif | |
290 | } | |
291 | } |