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03ca248b | 1 | /************************************************************************** |
2 | * Copyright(c) 1998-1999, ALICE Experiment at CERN, All rights reserved. * | |
3 | * * | |
4 | * Author: The ALICE Off-line Project. * | |
5 | * Contributors are mentioned in the code where appropriate. * | |
6 | * * | |
7 | * Permission to use, copy, modify and distribute this software and its * | |
8 | * documentation strictly for non-commercial purposes is hereby granted * | |
9 | * without fee, provided that the above copyright notice appears in all * | |
10 | * copies and that both the copyright notice and this permission notice * | |
11 | * appear in the supporting documentation. The authors make no claims * | |
12 | * about the suitability of this software for any purpose. It is * | |
13 | * provided "as is" without express or implied warranty. * | |
14 | **************************************************************************/ | |
15 | ||
803d1ab0 | 16 | /* $Id$ */ |
03ca248b | 17 | |
eae0fe66 | 18 | #include <Riostream.h> |
b9d0a01d | 19 | |
6d4d27f2 | 20 | #include "TClonesArray.h" |
03ca248b | 21 | #include "TFluka.h" |
b9d0a01d | 22 | #include "TCallf77.h" //For the fortran calls |
23 | #include "Fdblprc.h" //(DBLPRC) fluka common | |
b9d0a01d | 24 | #include "Fepisor.h" //(EPISOR) fluka common |
fa3d1cc7 | 25 | #include "Ffinuc.h" //(FINUC) fluka common |
26 | #include "Fiounit.h" //(IOUNIT) fluka common | |
27 | #include "Fpaprop.h" //(PAPROP) fluka common | |
f9cb2fec | 28 | #include "Fpart.h" //(PART) fluka common |
fa3d1cc7 | 29 | #include "Ftrackr.h" //(TRACKR) fluka common |
6d4d27f2 | 30 | #include "Fpaprop.h" //(PAPROP) fluka common |
fa3d1cc7 | 31 | #include "Ffheavy.h" //(FHEAVY) fluka common |
b9d0a01d | 32 | |
fa3d1cc7 | 33 | #include "TVirtualMC.h" |
bf3aa28e | 34 | #include "TG4GeometryManager.h" //For the geometry management |
35 | #include "TG4DetConstruction.h" //For the detector construction | |
36 | ||
37 | #include "FGeometryInit.hh" | |
fa3d1cc7 | 38 | #include "TLorentzVector.h" |
6d4d27f2 | 39 | #include "FlukaVolume.h" |
bf3aa28e | 40 | |
b9d0a01d | 41 | // Fluka methods that may be needed. |
42 | #ifndef WIN32 | |
43 | # define flukam flukam_ | |
44 | # define fluka_openinp fluka_openinp_ | |
45 | # define fluka_closeinp fluka_closeinp_ | |
f9cb2fec | 46 | # define mcihad mcihad_ |
47 | # define mpdgha mpdgha_ | |
b9d0a01d | 48 | #else |
49 | # define flukam FLUKAM | |
50 | # define fluka_openinp FLUKA_OPENINP | |
51 | # define fluka_closeinp FLUKA_CLOSEINP | |
f9cb2fec | 52 | # define mcihad MCIHAD |
53 | # define mpdgha MPDGHA | |
b9d0a01d | 54 | #endif |
55 | ||
56 | extern "C" | |
57 | { | |
58 | // | |
59 | // Prototypes for FLUKA functions | |
60 | // | |
61 | void type_of_call flukam(const int&); | |
62 | void type_of_call fluka_openinp(const int&, DEFCHARA); | |
63 | void type_of_call fluka_closeinp(const int&); | |
f9cb2fec | 64 | int type_of_call mcihad(const int&); |
65 | int type_of_call mpdgha(const int&); | |
b9d0a01d | 66 | } |
67 | ||
68 | // | |
69 | // Class implementation for ROOT | |
70 | // | |
03ca248b | 71 | ClassImp(TFluka) |
b9d0a01d | 72 | |
73 | // | |
bf3aa28e | 74 | //---------------------------------------------------------------------------- |
75 | // TFluka constructors and destructors. | |
b9d0a01d | 76 | //____________________________________________________________________________ |
77 | TFluka::TFluka() | |
78 | :TVirtualMC(), | |
79 | fVerbosityLevel(0), | |
1de0a072 | 80 | sInputFileName(""), |
27b2f7fe | 81 | fDetector(0), |
82 | fCurrentFlukaRegion(-1) | |
b9d0a01d | 83 | { |
84 | // | |
85 | // Default constructor | |
86 | // | |
87 | } | |
88 | ||
22229ba5 | 89 | TFluka::TFluka(const char *title, Int_t verbosity, Bool_t isRootGeometrySupported) |
90 | :TVirtualMC("TFluka",title, isRootGeometrySupported), | |
b9d0a01d | 91 | fVerbosityLevel(verbosity), |
1de0a072 | 92 | sInputFileName(""), |
24969d13 | 93 | fTrackIsEntering(0), |
94 | fTrackIsExiting(0), | |
fbf08100 | 95 | fTrackIsNew(0), |
27b2f7fe | 96 | fDetector(0), |
97 | fCurrentFlukaRegion(-1) | |
b9d0a01d | 98 | { |
99 | if (fVerbosityLevel >=3) | |
100 | cout << "==> TFluka::TFluka(" << title << ") constructor called." << endl; | |
101 | ||
bf3aa28e | 102 | |
103 | // create geometry manager | |
104 | if (fVerbosityLevel >=2) | |
105 | cout << "\t* Creating G4 Geometry manager..." << endl; | |
106 | fGeometryManager = new TG4GeometryManager(); | |
107 | if (fVerbosityLevel >=2) | |
108 | cout << "\t* Creating G4 Detector..." << endl; | |
109 | fDetector = new TG4DetConstruction(); | |
110 | FGeometryInit* geominit = FGeometryInit::GetInstance(); | |
111 | if (geominit) | |
112 | geominit->setDetConstruction(fDetector); | |
113 | else { | |
114 | cerr << "ERROR: Could not create FGeometryInit!" << endl; | |
115 | cerr << " Exiting!!!" << endl; | |
116 | abort(); | |
117 | } | |
118 | ||
b9d0a01d | 119 | if (fVerbosityLevel >=3) |
120 | cout << "<== TFluka::TFluka(" << title << ") constructor called." << endl; | |
6d4d27f2 | 121 | |
122 | fVolumeMediaMap = new TClonesArray("FlukaVolume",1000); | |
123 | fNVolumes = 0; | |
124 | fMediaByRegion = 0; | |
b9d0a01d | 125 | } |
126 | ||
bf3aa28e | 127 | TFluka::~TFluka() { |
128 | if (fVerbosityLevel >=3) | |
129 | cout << "==> TFluka::~TFluka() destructor called." << endl; | |
130 | ||
131 | delete fGeometryManager; | |
6d4d27f2 | 132 | fVolumeMediaMap->Delete(); |
133 | delete fVolumeMediaMap; | |
134 | ||
bf3aa28e | 135 | |
136 | if (fVerbosityLevel >=3) | |
137 | cout << "<== TFluka::~TFluka() destructor called." << endl; | |
138 | } | |
139 | ||
140 | // | |
141 | //_____________________________________________________________________________ | |
142 | // TFluka control methods | |
b9d0a01d | 143 | //____________________________________________________________________________ |
144 | void TFluka::Init() { | |
1de0a072 | 145 | |
6364fb0a | 146 | FGeometryInit* geominit = FGeometryInit::GetInstance(); |
b9d0a01d | 147 | if (fVerbosityLevel >=3) |
148 | cout << "==> TFluka::Init() called." << endl; | |
149 | ||
6364fb0a | 150 | cout << "\t* InitPhysics() - Prepare input file to be called" << endl; |
151 | geominit->Init(); | |
152 | // now we have G4 geometry created and we have to patch alice.inp | |
153 | // with the material mapping file FlukaMat.inp | |
154 | InitPhysics(); // prepare input file with the current physics settings | |
5929ad29 | 155 | cout << "\t* InitPhysics() - Prepare input file was called" << endl; |
1de0a072 | 156 | |
b9d0a01d | 157 | if (fVerbosityLevel >=2) |
158 | cout << "\t* Changing lfdrtr = (" << (GLOBAL.lfdrtr?'T':'F') | |
159 | << ") in fluka..." << endl; | |
160 | GLOBAL.lfdrtr = true; | |
161 | ||
162 | if (fVerbosityLevel >=2) | |
1de0a072 | 163 | cout << "\t* Opening file " << sInputFileName << endl; |
164 | const char* fname = sInputFileName; | |
b9d0a01d | 165 | fluka_openinp(lunin, PASSCHARA(fname)); |
166 | ||
167 | if (fVerbosityLevel >=2) | |
168 | cout << "\t* Calling flukam..." << endl; | |
bf3aa28e | 169 | flukam(1); |
b9d0a01d | 170 | |
171 | if (fVerbosityLevel >=2) | |
1de0a072 | 172 | cout << "\t* Closing file " << sInputFileName << endl; |
b9d0a01d | 173 | fluka_closeinp(lunin); |
174 | ||
1de0a072 | 175 | FinishGeometry(); |
176 | ||
b9d0a01d | 177 | if (fVerbosityLevel >=3) |
178 | cout << "<== TFluka::Init() called." << endl; | |
fa3d1cc7 | 179 | |
b9d0a01d | 180 | } |
181 | ||
bf3aa28e | 182 | void TFluka::FinishGeometry() { |
6d4d27f2 | 183 | // |
184 | // Build-up table with region to medium correspondance | |
185 | // | |
186 | char tmp[5]; | |
187 | ||
bf3aa28e | 188 | if (fVerbosityLevel >=3) |
189 | cout << "==> TFluka::FinishGeometry() called." << endl; | |
190 | ||
6d4d27f2 | 191 | // fGeometryManager->Ggclos(); |
bf3aa28e | 192 | |
6d4d27f2 | 193 | FGeometryInit* flugg = FGeometryInit::GetInstance(); |
194 | ||
195 | fMediaByRegion = new Int_t[fNVolumes+2]; | |
196 | for (Int_t i = 0; i < fNVolumes; i++) | |
197 | { | |
198 | FlukaVolume* vol = dynamic_cast<FlukaVolume*>((*fVolumeMediaMap)[i]); | |
199 | TString volName = vol->GetName(); | |
200 | Int_t media = vol->GetMedium(); | |
fee5ea25 | 201 | if (fVerbosityLevel >= 3) |
6d4d27f2 | 202 | printf("Finish Geometry: volName, media %d %s %d \n", i, volName.Data(), media); |
203 | strcpy(tmp, volName.Data()); | |
204 | tmp[4] = '\0'; | |
b0d8df96 | 205 | flugg->SetMediumFromName(tmp, media, i+1); |
206 | fMediaByRegion[i] = media; | |
27b2f7fe | 207 | } |
6d4d27f2 | 208 | |
209 | flugg->BuildMediaMap(); | |
27b2f7fe | 210 | |
bf3aa28e | 211 | if (fVerbosityLevel >=3) |
212 | cout << "<== TFluka::FinishGeometry() called." << endl; | |
213 | } | |
214 | ||
215 | void TFluka::BuildPhysics() { | |
216 | if (fVerbosityLevel >=3) | |
217 | cout << "==> TFluka::BuildPhysics() called." << endl; | |
218 | ||
219 | ||
220 | if (fVerbosityLevel >=3) | |
221 | cout << "<== TFluka::BuildPhysics() called." << endl; | |
222 | } | |
223 | ||
b9d0a01d | 224 | void TFluka::ProcessEvent() { |
225 | if (fVerbosityLevel >=3) | |
226 | cout << "==> TFluka::ProcessEvent() called." << endl; | |
b0d8df96 | 227 | fApplication->GeneratePrimaries(); |
228 | EPISOR.lsouit = true; | |
229 | flukam(1); | |
b9d0a01d | 230 | if (fVerbosityLevel >=3) |
231 | cout << "<== TFluka::ProcessEvent() called." << endl; | |
232 | } | |
233 | ||
bf3aa28e | 234 | |
b9d0a01d | 235 | void TFluka::ProcessRun(Int_t nevent) { |
236 | if (fVerbosityLevel >=3) | |
237 | cout << "==> TFluka::ProcessRun(" << nevent << ") called." | |
238 | << endl; | |
239 | ||
240 | if (fVerbosityLevel >=2) { | |
241 | cout << "\t* GLOBAL.fdrtr = " << (GLOBAL.lfdrtr?'T':'F') << endl; | |
242 | cout << "\t* Calling flukam again..." << endl; | |
243 | } | |
b0d8df96 | 244 | fApplication->InitGeometry(); |
245 | fApplication->BeginEvent(); | |
246 | ProcessEvent(); | |
247 | fApplication->FinishEvent(); | |
b9d0a01d | 248 | if (fVerbosityLevel >=3) |
249 | cout << "<== TFluka::ProcessRun(" << nevent << ") called." | |
250 | << endl; | |
b0d8df96 | 251 | |
b9d0a01d | 252 | } |
253 | ||
bf3aa28e | 254 | //_____________________________________________________________________________ |
255 | // methods for building/management of geometry | |
256 | //____________________________________________________________________________ | |
257 | // functions from GCONS | |
258 | void TFluka::Gfmate(Int_t imat, char *name, Float_t &a, Float_t &z, | |
259 | Float_t &dens, Float_t &radl, Float_t &absl, | |
260 | Float_t* ubuf, Int_t& nbuf) { | |
261 | // | |
262 | fGeometryManager->Gfmate(imat, name, a, z, dens, radl, absl, ubuf, nbuf); | |
263 | } | |
264 | ||
265 | void TFluka::Gfmate(Int_t imat, char *name, Double_t &a, Double_t &z, | |
266 | Double_t &dens, Double_t &radl, Double_t &absl, | |
267 | Double_t* ubuf, Int_t& nbuf) { | |
268 | // | |
269 | fGeometryManager->Gfmate(imat, name, a, z, dens, radl, absl, ubuf, nbuf); | |
270 | } | |
271 | ||
272 | // detector composition | |
273 | void TFluka::Material(Int_t& kmat, const char* name, Double_t a, | |
274 | Double_t z, Double_t dens, Double_t radl, Double_t absl, | |
275 | Float_t* buf, Int_t nwbuf) { | |
276 | // | |
277 | fGeometryManager | |
278 | ->Material(kmat, name, a, z, dens, radl, absl, buf, nwbuf); | |
279 | } | |
280 | void TFluka::Material(Int_t& kmat, const char* name, Double_t a, | |
281 | Double_t z, Double_t dens, Double_t radl, Double_t absl, | |
282 | Double_t* buf, Int_t nwbuf) { | |
283 | // | |
284 | fGeometryManager | |
285 | ->Material(kmat, name, a, z, dens, radl, absl, buf, nwbuf); | |
286 | } | |
287 | ||
288 | void TFluka::Mixture(Int_t& kmat, const char *name, Float_t *a, | |
289 | Float_t *z, Double_t dens, Int_t nlmat, Float_t *wmat) { | |
290 | // | |
291 | fGeometryManager | |
292 | ->Mixture(kmat, name, a, z, dens, nlmat, wmat); | |
293 | } | |
294 | void TFluka::Mixture(Int_t& kmat, const char *name, Double_t *a, | |
295 | Double_t *z, Double_t dens, Int_t nlmat, Double_t *wmat) { | |
296 | // | |
297 | fGeometryManager | |
298 | ->Mixture(kmat, name, a, z, dens, nlmat, wmat); | |
299 | } | |
300 | ||
301 | void TFluka::Medium(Int_t& kmed, const char *name, Int_t nmat, | |
302 | Int_t isvol, Int_t ifield, Double_t fieldm, Double_t tmaxfd, | |
303 | Double_t stemax, Double_t deemax, Double_t epsil, | |
304 | Double_t stmin, Float_t* ubuf, Int_t nbuf) { | |
305 | // | |
306 | fGeometryManager | |
307 | ->Medium(kmed, name, nmat, isvol, ifield, fieldm, tmaxfd, stemax, deemax, | |
308 | epsil, stmin, ubuf, nbuf); | |
309 | } | |
310 | void TFluka::Medium(Int_t& kmed, const char *name, Int_t nmat, | |
311 | Int_t isvol, Int_t ifield, Double_t fieldm, Double_t tmaxfd, | |
312 | Double_t stemax, Double_t deemax, Double_t epsil, | |
313 | Double_t stmin, Double_t* ubuf, Int_t nbuf) { | |
314 | // | |
315 | fGeometryManager | |
316 | ->Medium(kmed, name, nmat, isvol, ifield, fieldm, tmaxfd, stemax, deemax, | |
317 | epsil, stmin, ubuf, nbuf); | |
318 | } | |
319 | ||
320 | void TFluka::Matrix(Int_t& krot, Double_t thetaX, Double_t phiX, | |
321 | Double_t thetaY, Double_t phiY, Double_t thetaZ, | |
322 | Double_t phiZ) { | |
323 | // | |
324 | fGeometryManager | |
325 | ->Matrix(krot, thetaX, phiX, thetaY, phiY, thetaZ, phiZ); | |
326 | } | |
327 | ||
328 | void TFluka::Gstpar(Int_t itmed, const char *param, Double_t parval) { | |
329 | // | |
330 | fGeometryManager->Gstpar(itmed, param, parval); | |
331 | } | |
332 | ||
333 | // functions from GGEOM | |
334 | Int_t TFluka::Gsvolu(const char *name, const char *shape, Int_t nmed, | |
335 | Float_t *upar, Int_t np) { | |
336 | // | |
6d4d27f2 | 337 | // fVolumeMediaMap[TString(name)] = nmed; |
fee5ea25 | 338 | if (fVerbosityLevel >= 3) |
b0d8df96 | 339 | printf("TFluka::Gsvolu() name = %s, nmed = %d\n", name, nmed); |
340 | ||
6d4d27f2 | 341 | TClonesArray &lvols = *fVolumeMediaMap; |
342 | new(lvols[fNVolumes++]) | |
343 | FlukaVolume(name, nmed); | |
344 | return fGeometryManager->Gsvolu(name, shape, nmed, upar, np); | |
bf3aa28e | 345 | } |
346 | Int_t TFluka::Gsvolu(const char *name, const char *shape, Int_t nmed, | |
347 | Double_t *upar, Int_t np) { | |
348 | // | |
6d4d27f2 | 349 | TClonesArray &lvols = *fVolumeMediaMap; |
350 | new(lvols[fNVolumes++]) | |
351 | FlukaVolume(name, nmed); | |
352 | ||
353 | return fGeometryManager->Gsvolu(name, shape, nmed, upar, np); | |
bf3aa28e | 354 | } |
355 | ||
356 | void TFluka::Gsdvn(const char *name, const char *mother, Int_t ndiv, | |
357 | Int_t iaxis) { | |
358 | // | |
b0d8df96 | 359 | // The medium of the daughter is the one of the mother |
360 | Int_t volid = TFluka::VolId(mother); | |
361 | Int_t med = TFluka::VolId2Mate(volid); | |
362 | TClonesArray &lvols = *fVolumeMediaMap; | |
363 | new(lvols[fNVolumes++]) | |
364 | FlukaVolume(name, med); | |
6d4d27f2 | 365 | fGeometryManager->Gsdvn(name, mother, ndiv, iaxis); |
bf3aa28e | 366 | } |
367 | ||
368 | void TFluka::Gsdvn2(const char *name, const char *mother, Int_t ndiv, | |
369 | Int_t iaxis, Double_t c0i, Int_t numed) { | |
370 | // | |
6d4d27f2 | 371 | TClonesArray &lvols = *fVolumeMediaMap; |
372 | new(lvols[fNVolumes++]) | |
373 | FlukaVolume(name, numed); | |
374 | fGeometryManager->Gsdvn2(name, mother, ndiv, iaxis, c0i, numed); | |
bf3aa28e | 375 | } |
376 | ||
377 | void TFluka::Gsdvt(const char *name, const char *mother, Double_t step, | |
378 | Int_t iaxis, Int_t numed, Int_t ndvmx) { | |
6d4d27f2 | 379 | // |
380 | TClonesArray &lvols = *fVolumeMediaMap; | |
381 | new(lvols[fNVolumes++]) | |
382 | FlukaVolume(name, numed); | |
383 | fGeometryManager->Gsdvt(name, mother, step, iaxis, numed, ndvmx); | |
bf3aa28e | 384 | } |
385 | ||
386 | void TFluka::Gsdvt2(const char *name, const char *mother, Double_t step, | |
387 | Int_t iaxis, Double_t c0, Int_t numed, Int_t ndvmx) { | |
388 | // | |
6d4d27f2 | 389 | TClonesArray &lvols = *fVolumeMediaMap; |
390 | new(lvols[fNVolumes++]) | |
391 | FlukaVolume(name, numed); | |
392 | fGeometryManager->Gsdvt2(name, mother, step, iaxis, c0, numed, ndvmx); | |
bf3aa28e | 393 | } |
394 | ||
395 | void TFluka::Gsord(const char *name, Int_t iax) { | |
396 | // | |
397 | fGeometryManager->Gsord(name, iax); | |
398 | } | |
399 | ||
400 | void TFluka::Gspos(const char *name, Int_t nr, const char *mother, | |
401 | Double_t x, Double_t y, Double_t z, Int_t irot, | |
402 | const char *konly) { | |
403 | // | |
404 | fGeometryManager->Gspos(name, nr, mother, x, y, z, irot, konly); | |
405 | } | |
406 | ||
407 | void TFluka::Gsposp(const char *name, Int_t nr, const char *mother, | |
408 | Double_t x, Double_t y, Double_t z, Int_t irot, | |
409 | const char *konly, Float_t *upar, Int_t np) { | |
410 | // | |
411 | fGeometryManager->Gsposp(name, nr, mother, x, y, z, irot, konly, upar, np); | |
412 | } | |
413 | void TFluka::Gsposp(const char *name, Int_t nr, const char *mother, | |
414 | Double_t x, Double_t y, Double_t z, Int_t irot, | |
415 | const char *konly, Double_t *upar, Int_t np) { | |
416 | // | |
417 | fGeometryManager->Gsposp(name, nr, mother, x, y, z, irot, konly, upar, np); | |
418 | } | |
419 | ||
420 | void TFluka::Gsbool(const char* onlyVolName, const char* manyVolName) { | |
421 | // | |
422 | fGeometryManager->Gsbool(onlyVolName, manyVolName); | |
423 | } | |
424 | ||
425 | void TFluka::SetCerenkov(Int_t itmed, Int_t npckov, Float_t *ppckov, | |
426 | Float_t *absco, Float_t *effic, Float_t *rindex) { | |
427 | // | |
428 | fGeometryManager->SetCerenkov(itmed, npckov, ppckov, absco, effic, rindex); | |
429 | } | |
430 | void TFluka::SetCerenkov(Int_t itmed, Int_t npckov, Double_t *ppckov, | |
431 | Double_t *absco, Double_t *effic, Double_t *rindex) { | |
432 | // | |
433 | fGeometryManager->SetCerenkov(itmed, npckov, ppckov, absco, effic, rindex); | |
434 | } | |
435 | ||
436 | // Euclid | |
437 | void TFluka::WriteEuclid(const char* fileName, const char* topVol, | |
438 | Int_t number, Int_t nlevel) { | |
439 | // | |
440 | fGeometryManager->WriteEuclid(fileName, topVol, number, nlevel); | |
441 | } | |
442 | ||
443 | ||
444 | ||
27b2f7fe | 445 | //_____________________________________________________________________________ |
446 | // methods needed by the stepping | |
447 | //____________________________________________________________________________ | |
6d4d27f2 | 448 | |
27b2f7fe | 449 | Int_t TFluka::GetMedium() const { |
b0d8df96 | 450 | // |
451 | // Get the medium number for the current fluka region | |
452 | // | |
6d4d27f2 | 453 | FGeometryInit* flugg = FGeometryInit::GetInstance(); |
454 | return flugg->GetMedium(fCurrentFlukaRegion); | |
27b2f7fe | 455 | } |
bf3aa28e | 456 | |
457 | ||
458 | ||
459 | //____________________________________________________________________________ | |
1de0a072 | 460 | // particle table usage |
bf3aa28e | 461 | // ID <--> PDG transformations |
b9d0a01d | 462 | //_____________________________________________________________________________ |
463 | Int_t TFluka::IdFromPDG(Int_t pdg) const | |
464 | { | |
72f84f29 | 465 | // |
466 | // Return Fluka code from PDG and pseudo ENDF code | |
467 | ||
468 | // Catch the feedback photons | |
469 | if (pdg == 50000051) return (-1); | |
470 | // MCIHAD() goes from pdg to fluka internal. | |
471 | Int_t intfluka = mcihad(pdg); | |
472 | // KPTOIP array goes from internal to official | |
473 | return GetFlukaKPTOIP(intfluka); | |
b9d0a01d | 474 | } |
475 | ||
b9d0a01d | 476 | Int_t TFluka::PDGFromId(Int_t id) const |
477 | { | |
478 | // | |
f9cb2fec | 479 | // Return PDG code and pseudo ENDF code from Fluka code |
c230803a | 480 | |
5929ad29 | 481 | // IPTOKP array goes from official to internal |
f906eae0 | 482 | |
483 | if (id == -1) { | |
484 | // Cerenkov photon | |
485 | if (fVerbosityLevel >= 1) | |
486 | printf("\n PDGFromId: Cerenkov Photon \n"); | |
487 | return 50000050; | |
488 | } | |
5929ad29 | 489 | // Error id |
b0d8df96 | 490 | if (id == 0) { |
f906eae0 | 491 | if (fVerbosityLevel >= 1) |
492 | printf("PDGFromId: Error id = 0\n"); | |
b0d8df96 | 493 | return -1; |
494 | } | |
5929ad29 | 495 | // Good id |
f906eae0 | 496 | Int_t intfluka = GetFlukaIPTOKP(id); |
b0d8df96 | 497 | if (intfluka == 0) { |
f906eae0 | 498 | if (fVerbosityLevel >= 1) |
499 | printf("PDGFromId: Error intfluka = 0: %d\n", id); | |
b0d8df96 | 500 | return -1; |
6015a930 | 501 | } else if (intfluka < 0) { |
f906eae0 | 502 | if (fVerbosityLevel >= 1) |
503 | printf("PDGFromId: Error intfluka < 0: %d\n", id); | |
6015a930 | 504 | return -1; |
b0d8df96 | 505 | } |
fee5ea25 | 506 | if (fVerbosityLevel >= 3) |
f906eae0 | 507 | printf("mpdgha called with %d %d \n", id, intfluka); |
5929ad29 | 508 | // MPDGHA() goes from fluka internal to pdg. |
f906eae0 | 509 | return mpdgha(intfluka); |
6d4d27f2 | 510 | } |
511 | ||
1de0a072 | 512 | //_____________________________________________________________________________ |
513 | // methods for physics management | |
514 | //____________________________________________________________________________ | |
515 | // | |
516 | // set methods | |
517 | // | |
518 | ||
519 | void TFluka::SetProcess(const char* flagName, Int_t flagValue) | |
520 | { | |
521 | Int_t i; | |
522 | if (iNbOfProc < 100) { | |
523 | for (i=0; i<iNbOfProc; i++) { | |
524 | if (strcmp(&sProcessFlag[i][0],flagName) == 0) { | |
525 | iProcessValue[iNbOfProc] = flagValue; | |
526 | goto fin; | |
527 | } | |
528 | } | |
529 | strcpy(&sProcessFlag[iNbOfProc][0],flagName); | |
530 | iProcessValue[iNbOfProc++] = flagValue; | |
531 | } | |
532 | else | |
533 | cout << "Nb of SetProcess calls exceeds 100 - ignored" << endl; | |
534 | fin: | |
535 | iNbOfProc = iNbOfProc; | |
536 | } | |
537 | ||
538 | void TFluka::SetCut(const char* cutName, Double_t cutValue) | |
539 | { | |
540 | Int_t i; | |
541 | if (iNbOfCut < 100) { | |
542 | for (i=0; i<iNbOfCut; i++) { | |
543 | if (strcmp(&sCutFlag[i][0],cutName) == 0) { | |
544 | fCutValue[iNbOfCut] = cutValue; | |
545 | goto fin; | |
546 | } | |
547 | } | |
548 | strcpy(&sCutFlag[iNbOfCut][0],cutName); | |
549 | fCutValue[iNbOfCut++] = cutValue; | |
550 | } | |
551 | else | |
552 | cout << "Nb of SetCut calls exceeds 100 - ignored" << endl; | |
553 | fin: | |
554 | iNbOfCut = iNbOfCut; | |
555 | } | |
556 | ||
557 | Double_t TFluka::Xsec(char*, Double_t, Int_t, Int_t) | |
558 | { | |
559 | printf("WARNING: Xsec not yet implemented !\n"); return -1.; | |
560 | } | |
561 | ||
562 | ||
563 | void TFluka::InitPhysics() | |
564 | { | |
cbc3a17e | 565 | Int_t i, j, k; |
566 | Double_t fCut; | |
861d858d | 567 | Double_t zero, one, two, three; |
568 | FILE *pAliceCoreInp, *pAliceFlukaMat, *pAliceInp; | |
569 | ||
570 | zero = 0.0; | |
571 | one = 1.0; | |
572 | two = 2.0; | |
573 | three = 3.0; | |
574 | ||
754972a2 | 575 | FGeometryInit* geominit = FGeometryInit::GetInstance(); |
576 | Float_t fLastMaterial = geominit->GetLastMaterialIndex(); | |
577 | printf(" last FLUKA material is %g\n", fLastMaterial); | |
cbc3a17e | 578 | |
1de0a072 | 579 | // construct file names |
0c160c74 | 580 | TString sAliceCoreInp = getenv("ALICE_ROOT"); |
581 | sAliceCoreInp +="/TFluka/input/"; | |
754972a2 | 582 | TString sAliceTmp = "flukaMat.inp"; |
0c160c74 | 583 | TString sAliceInp = GetInputFileName(); |
1de0a072 | 584 | sAliceCoreInp += GetCoreInputFileName(); |
861d858d | 585 | /* open files */ |
e749c124 | 586 | if ((pAliceCoreInp = fopen(sAliceCoreInp.Data(),"r")) == NULL) { |
861d858d | 587 | printf("\nCannot open file %s\n",sAliceCoreInp.Data()); |
588 | exit(1); | |
589 | } | |
e749c124 | 590 | if ((pAliceFlukaMat = fopen(sAliceTmp.Data(),"r")) == NULL) { |
861d858d | 591 | printf("\nCannot open file %s\n",sAliceTmp.Data()); |
592 | exit(1); | |
593 | } | |
e749c124 | 594 | if ((pAliceInp = fopen(sAliceInp.Data(),"w")) == NULL) { |
861d858d | 595 | printf("\nCannot open file %s\n",sAliceInp.Data()); |
596 | exit(1); | |
597 | } | |
1de0a072 | 598 | |
6364fb0a | 599 | // copy core input file |
1de0a072 | 600 | Char_t sLine[255]; |
601 | Float_t fEventsPerRun; | |
6364fb0a | 602 | |
861d858d | 603 | while ((fgets(sLine,255,pAliceCoreInp)) != NULL) { |
6364fb0a | 604 | if (strncmp(sLine,"GEOEND",6) != 0) |
e749c124 | 605 | fprintf(pAliceInp,"%s",sLine); // copy until GEOEND card |
6364fb0a | 606 | else { |
861d858d | 607 | fprintf(pAliceInp,"GEOEND\n"); // add GEOEND card |
6364fb0a | 608 | goto flukamat; |
609 | } | |
610 | } // end of while until GEOEND card | |
611 | ||
612 | flukamat: | |
861d858d | 613 | while ((fgets(sLine,255,pAliceFlukaMat)) != NULL) { // copy flukaMat.inp file |
614 | fprintf(pAliceInp,"%s\n",sLine); | |
6364fb0a | 615 | } |
616 | ||
861d858d | 617 | while ((fgets(sLine,255,pAliceCoreInp)) != NULL) { |
1de0a072 | 618 | if (strncmp(sLine,"START",5) != 0) |
861d858d | 619 | fprintf(pAliceInp,"%s\n",sLine); |
1de0a072 | 620 | else { |
621 | sscanf(sLine+10,"%10f",&fEventsPerRun); | |
622 | goto fin; | |
623 | } | |
6364fb0a | 624 | } //end of while until START card |
1de0a072 | 625 | |
626 | fin: | |
627 | // in G3 the process control values meaning can be different for | |
628 | // different processes, but for most of them is: | |
629 | // 0 process is not activated | |
630 | // 1 process is activated WITH generation of secondaries | |
631 | // 2 process is activated WITHOUT generation of secondaries | |
632 | // if process does not generate secondaries => 1 same as 2 | |
633 | // | |
634 | // Exceptions: | |
635 | // MULS: also 3 | |
636 | // LOSS: also 3, 4 | |
637 | // RAYL: only 0,1 | |
638 | // HADR: may be > 2 | |
639 | // | |
640 | ||
641 | // Loop over number of SetProcess calls | |
861d858d | 642 | fprintf(pAliceInp,"*----------------------------------------------------------------------------- \n"); |
643 | fprintf(pAliceInp,"*----- The following data are generated from SetProcess and SetCut calls ----- \n"); | |
644 | fprintf(pAliceInp,"*----------------------------------------------------------------------------- \n"); | |
cbc3a17e | 645 | for (i=0; i<iNbOfProc; i++) { |
1de0a072 | 646 | |
647 | // annihilation | |
648 | // G3 default value: 1 | |
649 | // G4 processes: G4eplusAnnihilation/G4IeplusAnnihilation | |
650 | // Particles: e+ | |
651 | // Physics: EM | |
cbc3a17e | 652 | // flag = 0 no annihilation |
653 | // flag = 1 annihilation, decays processed | |
654 | // flag = 2 annihilation, no decay product stored | |
1de0a072 | 655 | // gMC ->SetProcess("ANNI",1); // EMFCUT -1. 0. 0. 3. lastmat 0. ANNH-THR |
cbc3a17e | 656 | if (strncmp(&sProcessFlag[i][0],"ANNI",4) == 0) { |
657 | if (iProcessValue[i] == 1 || iProcessValue[i] == 2) { | |
861d858d | 658 | fprintf(pAliceInp,"*\n*Kinetic energy threshold (GeV) for e+ annihilation - resets to default=0.\n"); |
659 | fprintf(pAliceInp,"*Generated from call: SetProcess('ANNI',1) or SetProcess('ANNI',2)\n"); | |
660 | // -one = kinetic energy threshold (GeV) for e+ annihilation (resets to default=0) | |
661 | // zero = not used | |
662 | // zero = not used | |
663 | // three = lower bound of the material indices in which the respective thresholds apply | |
664 | // fLastMaterial = upper bound of the material indices in which the respective thresholds apply | |
665 | // one = step length in assigning indices | |
666 | // "ANNH-THR"; | |
e749c124 | 667 | fprintf(pAliceInp,"EMFCUT %10.1f%10.1f%10.1f%10.1f%10.1f%10.1fANNH-THR\n",-one,zero,zero,three,fLastMaterial,one); |
cbc3a17e | 668 | } |
669 | else if (iProcessValue[i] == 0) { | |
861d858d | 670 | fprintf(pAliceInp,"*\n*No annihilation - no FLUKA card generated\n"); |
671 | fprintf(pAliceInp,"*Generated from call: SetProcess('ANNI',0)\n"); | |
cbc3a17e | 672 | } |
673 | else { | |
861d858d | 674 | fprintf(pAliceInp,"*\n*Illegal flag value in SetProcess('ANNI',?) call.\n"); |
675 | fprintf(pAliceInp,"*No FLUKA card generated\n"); | |
cbc3a17e | 676 | } |
1de0a072 | 677 | } |
678 | ||
cbc3a17e | 679 | // bremsstrahlung and pair production are both activated |
1de0a072 | 680 | // G3 default value: 1 |
681 | // G4 processes: G4eBremsstrahlung/G4IeBremsstrahlung, | |
682 | // G4MuBremsstrahlung/G4IMuBremsstrahlung, | |
683 | // G4LowEnergyBremstrahlung | |
684 | // Particles: e-/e+; mu+/mu- | |
685 | // Physics: EM | |
cbc3a17e | 686 | // flag = 0 no bremsstrahlung |
687 | // flag = 1 bremsstrahlung, photon processed | |
688 | // flag = 2 bremsstrahlung, no photon stored | |
1de0a072 | 689 | // gMC ->SetProcess("BREM",1); // PAIRBREM 2. 0. 0. 3. lastmat |
861d858d | 690 | // EMFCUT -1. 0. 0. 3. lastmat 0. ELPO-THR |
cbc3a17e | 691 | // G3 default value: 1 |
692 | // G4 processes: G4GammaConversion, | |
693 | // G4MuPairProduction/G4IMuPairProduction | |
694 | // G4LowEnergyGammaConversion | |
695 | // Particles: gamma, mu | |
696 | // Physics: EM | |
697 | // flag = 0 no delta rays | |
698 | // flag = 1 delta rays, secondaries processed | |
699 | // flag = 2 delta rays, no secondaries stored | |
700 | // gMC ->SetProcess("PAIR",1); // PAIRBREM 1. 0. 0. 3. lastmat | |
861d858d | 701 | // EMFCUT 0. 0. -1. 3. lastmat 0. PHOT-THR |
cbc3a17e | 702 | else if ((strncmp(&sProcessFlag[i][0],"PAIR",4) == 0) && (iProcessValue[i] == 1 || iProcessValue[i] == 2)) { |
703 | for (j=0; j<iNbOfProc; j++) { | |
704 | if ((strncmp(&sProcessFlag[j][0],"BREM",4) == 0) && (iProcessValue[j] == 1 || iProcessValue[j] == 2)) { | |
861d858d | 705 | fprintf(pAliceInp,"*\n*Bremsstrahlung and pair production by muons and charged hadrons both activated\n"); |
706 | fprintf(pAliceInp,"*Generated from call: SetProcess('BREM',1) and SetProcess('PAIR',1)\n"); | |
707 | fprintf(pAliceInp,"*Energy threshold set by call SetCut('BCUTM',cut) or set to 0.\n"); | |
708 | fprintf(pAliceInp,"*Energy threshold set by call SetCut('PPCUTM',cut) or set to 0.\n"); | |
709 | // three = bremsstrahlung and pair production by muons and charged hadrons both are activated | |
e749c124 | 710 | fprintf(pAliceInp,"PAIRBREM %10.1f",three); |
cbc3a17e | 711 | // direct pair production by muons |
712 | // G4 particles: "e-", "e+" | |
713 | // G3 default value: 0.01 GeV | |
714 | //gMC ->SetCut("PPCUTM",cut); // total energy cut for direct pair prod. by muons | |
715 | fCut = 0.0; | |
716 | for (k=0; k<iNbOfCut; k++) { | |
717 | if (strncmp(&sCutFlag[k][0],"PPCUTM",6) == 0) fCut = fCutValue[k]; | |
718 | } | |
e749c124 | 719 | fprintf(pAliceInp,"%10.4g",fCut); |
861d858d | 720 | // fCut; = e+, e- kinetic energy threshold (in GeV) for explicit pair production. |
cbc3a17e | 721 | // muon and hadron bremsstrahlung |
722 | // G4 particles: "gamma" | |
723 | // G3 default value: CUTGAM=0.001 GeV | |
724 | //gMC ->SetCut("BCUTM",cut); // cut for muon and hadron bremsstrahlung | |
725 | fCut = 0.0; | |
726 | for (k=0; k<iNbOfCut; k++) { | |
727 | if (strncmp(&sCutFlag[k][0],"BCUTM",5) == 0) fCut = fCutValue[k]; | |
728 | } | |
e749c124 | 729 | fprintf(pAliceInp,"%10.4g%10.1f%10.1f\n",fCut,three,fLastMaterial); |
861d858d | 730 | // fCut = photon energy threshold (GeV) for explicit bremsstrahlung production |
731 | // three = lower bound of the material indices in which the respective thresholds apply | |
732 | // fLastMaterial = upper bound of the material indices in which the respective thresholds apply | |
cbc3a17e | 733 | |
734 | // for e+ and e- | |
861d858d | 735 | fprintf(pAliceInp,"*\n*Kinetic energy threshold (GeV) for e+/e- bremsstrahlung - resets to default=0.\n"); |
736 | fprintf(pAliceInp,"*Generated from call: SetProcess('BREM',1);\n"); | |
cbc3a17e | 737 | fCut = -1.0; |
738 | for (k=0; k<iNbOfCut; k++) { | |
739 | if (strncmp(&sCutFlag[k][0],"BCUTE",5) == 0) fCut = fCutValue[k]; | |
740 | } | |
861d858d | 741 | //fCut = kinetic energy threshold (GeV) for e+/e- bremsstrahlung (resets to default=0) |
742 | // zero = not used | |
743 | // zero = not used | |
744 | // three = lower bound of the material indices in which the respective thresholds apply | |
745 | // fLastMaterial = upper bound of the material indices in which the respective thresholds apply | |
746 | // one = step length in assigning indices | |
747 | // "ELPO-THR"; | |
e749c124 | 748 | fprintf(pAliceInp,"EMFCUT %10.4g%10.1f%10.1f%10.1f%10.1f%10.1fELPO-THR\n",fCut,zero,zero,three,fLastMaterial,one); |
cbc3a17e | 749 | |
750 | // for e+ and e- | |
861d858d | 751 | fprintf(pAliceInp,"*\n*Pair production by electrons is activated\n"); |
752 | fprintf(pAliceInp,"*Generated from call: SetProcess('PAIR',1);\n"); | |
cbc3a17e | 753 | fCut = -1.0; |
754 | for (j=0; j<iNbOfCut; j++) { | |
755 | if (strncmp(&sCutFlag[j][0],"CUTGAM",6) == 0) fCut = fCutValue[j]; | |
756 | } | |
861d858d | 757 | // fCut = energy threshold (GeV) for gamma pair production (< 0.0 : resets to default, = 0.0 : ignored) |
758 | // three = lower bound of the material indices in which the respective thresholds apply | |
759 | // fLastMaterial = upper bound of the material indices in which the respective thresholds apply | |
760 | // one = step length in assigning indices | |
e749c124 | 761 | fprintf(pAliceInp,"EMFCUT %10.1f%10.1f%10.4g%10.1f%10.1f%10.1fPHOT-THR\n",zero,zero,fCut,three,fLastMaterial,one); |
cbc3a17e | 762 | goto BOTH; |
763 | } // end of if for BREM | |
764 | } // end of loop for BREM | |
765 | ||
766 | // only pair production by muons and charged hadrons is activated | |
861d858d | 767 | fprintf(pAliceInp,"*\n*Pair production by muons and charged hadrons is activated\n"); |
768 | fprintf(pAliceInp,"*Generated from call: SetProcess('PAIR',1) or SetProcess('PAIR',2)\n"); | |
769 | fprintf(pAliceInp,"*Energy threshold set by call SetCut('PPCUTM',cut) or set to 0.\n"); | |
cbc3a17e | 770 | // direct pair production by muons |
771 | // G4 particles: "e-", "e+" | |
772 | // G3 default value: 0.01 GeV | |
773 | //gMC ->SetCut("PPCUTM",cut); // total energy cut for direct pair prod. by muons | |
861d858d | 774 | // one = pair production by muons and charged hadrons is activated |
775 | // zero = e+, e- kinetic energy threshold (in GeV) for explicit pair production. | |
776 | // zero = no explicit bremsstrahlung production is simulated | |
777 | // three = lower bound of the material indices in which the respective thresholds apply | |
778 | // fLastMaterial = upper bound of the material indices in which the respective thresholds apply | |
e749c124 | 779 | fprintf(pAliceInp,"PAIRBREM %10.1f%10.1f%10.1f%10.1f%10.1f\n",one,zero,zero,three,fLastMaterial); |
cbc3a17e | 780 | |
1de0a072 | 781 | // for e+ and e- |
861d858d | 782 | fprintf(pAliceInp,"*\n*Pair production by electrons is activated\n"); |
783 | fprintf(pAliceInp,"*Generated from call: SetProcess('PAIR',1) or SetProcess('PAIR',2)\n"); | |
cbc3a17e | 784 | fCut = -1.0; |
785 | for (j=0; j<iNbOfCut; j++) { | |
786 | if (strncmp(&sCutFlag[j][0],"CUTGAM",6) == 0) fCut = fCutValue[j]; | |
787 | } | |
861d858d | 788 | // zero = energy threshold (GeV) for Compton scattering (= 0.0 : ignored) |
789 | // zero = energy threshold (GeV) for Photoelectric (= 0.0 : ignored) | |
790 | // fCut = energy threshold (GeV) for gamma pair production (< 0.0 : resets to default, = 0.0 : ignored) | |
791 | // three = lower bound of the material indices in which the respective thresholds apply | |
792 | // fLastMaterial = upper bound of the material indices in which the respective thresholds apply | |
793 | // one = step length in assigning indices | |
e749c124 | 794 | fprintf(pAliceInp,"EMFCUT %10.1f%10.1f%10.4g%10.1f%10.1f%10.1fPHOT-THR\n",zero,zero,fCut,three,fLastMaterial,one); |
cbc3a17e | 795 | |
796 | BOTH: | |
797 | k = 0; | |
798 | } // end of if for PAIR | |
799 | ||
800 | ||
801 | ||
802 | // bremsstrahlung | |
803 | // G3 default value: 1 | |
804 | // G4 processes: G4eBremsstrahlung/G4IeBremsstrahlung, | |
805 | // G4MuBremsstrahlung/G4IMuBremsstrahlung, | |
806 | // G4LowEnergyBremstrahlung | |
807 | // Particles: e-/e+; mu+/mu- | |
808 | // Physics: EM | |
809 | // flag = 0 no bremsstrahlung | |
810 | // flag = 1 bremsstrahlung, photon processed | |
811 | // flag = 2 bremsstrahlung, no photon stored | |
812 | // gMC ->SetProcess("BREM",1); // PAIRBREM 2. 0. 0. 3. lastmat | |
813 | // EMFCUT -1. 0. 0. 3. lastmat 0. ELPO-THR | |
814 | else if (strncmp(&sProcessFlag[i][0],"BREM",4) == 0) { | |
815 | for (j=0; j<iNbOfProc; j++) { | |
816 | if ((strncmp(&sProcessFlag[j][0],"PAIR",4) == 0) && iProcessValue[j] == 1) goto NOBREM; | |
817 | } | |
818 | if (iProcessValue[i] == 1 || iProcessValue[i] == 2) { | |
861d858d | 819 | fprintf(pAliceInp,"*\n*Bremsstrahlung by muons and charged hadrons is activated\n"); |
820 | fprintf(pAliceInp,"*Generated from call: SetProcess('BREM',1) or SetProcess('BREM',2)\n"); | |
821 | fprintf(pAliceInp,"*Energy threshold set by call SetCut('BCUTM',cut) or set to 0.\n"); | |
822 | // two = bremsstrahlung by muons and charged hadrons is activated | |
823 | // zero = no meaning | |
cbc3a17e | 824 | // muon and hadron bremsstrahlung |
825 | // G4 particles: "gamma" | |
826 | // G3 default value: CUTGAM=0.001 GeV | |
827 | //gMC ->SetCut("BCUTM",cut); // cut for muon and hadron bremsstrahlung | |
828 | fCut = 0.0; | |
829 | for (j=0; j<iNbOfCut; j++) { | |
830 | if (strncmp(&sCutFlag[j][0],"BCUTM",5) == 0) fCut = fCutValue[j]; | |
831 | } | |
861d858d | 832 | // fCut = photon energy threshold (GeV) for explicit bremsstrahlung production |
833 | // three = lower bound of the material indices in which the respective thresholds apply | |
834 | // fLastMaterial = upper bound of the material indices in which the respective thresholds apply | |
e749c124 | 835 | fprintf(pAliceInp,"PAIRBREM %10.1f%10.1f%10.4g%10.1f%10.1f\n",two,zero,fCut,three,fLastMaterial); |
cbc3a17e | 836 | |
837 | // for e+ and e- | |
861d858d | 838 | fprintf(pAliceInp,"*\n*Kinetic energy threshold (GeV) for e+/e- bremsstrahlung - resets to default=0.\n"); |
839 | fprintf(pAliceInp,"*Generated from call: SetProcess('BREM',1);"); | |
840 | // - one = kinetic energy threshold (GeV) for e+/e- bremsstrahlung (resets to default=0) | |
841 | // zero = not used | |
842 | // zero = not used | |
843 | // three = lower bound of the material indices in which the respective thresholds apply | |
844 | // fLastMaterial = upper bound of the material indices in which the respective thresholds apply | |
845 | // one = step length in assigning indices | |
846 | //"ELPO-THR"; | |
e749c124 | 847 | fprintf(pAliceInp,"EMFCUT %10.1f%10.1f%10.1f%10.1f%10.1f%10.1fELPO-THR\n",-one,zero,zero,three,fLastMaterial,one); |
cbc3a17e | 848 | } |
849 | else if (iProcessValue[i] == 0) { | |
861d858d | 850 | fprintf(pAliceInp,"*\n*No bremsstrahlung - no FLUKA card generated\n"); |
851 | fprintf(pAliceInp,"*Generated from call: SetProcess('BREM',0)\n"); | |
cbc3a17e | 852 | } |
853 | else { | |
861d858d | 854 | fprintf(pAliceInp,"*\n*Illegal flag value in SetProcess('BREM',?) call.\n"); |
855 | fprintf(pAliceInp,"*No FLUKA card generated\n"); | |
cbc3a17e | 856 | } |
857 | NOBREM: | |
858 | j = 0; | |
859 | } // end of else if (strncmp(&sProcessFlag[i][0],"BREM",4) == 0) | |
860 | ||
1de0a072 | 861 | |
cbc3a17e | 862 | // Cerenkov photon generation |
863 | // G3 default value: 0 | |
864 | // G4 process: G4Cerenkov | |
865 | // | |
866 | // Particles: charged | |
867 | // Physics: Optical | |
868 | // flag = 0 no Cerenkov photon generation | |
869 | // flag = 1 Cerenkov photon generation | |
870 | // flag = 2 Cerenkov photon generation with primary stopped at each step | |
871 | //xx gMC ->SetProcess("CKOV",1); // ??? Cerenkov photon generation | |
872 | else if (strncmp(&sProcessFlag[i][0],"CKOV",4) == 0) { | |
873 | if (iProcessValue[i] == 1 || iProcessValue[i] == 2) { | |
861d858d | 874 | fprintf(pAliceInp,"*\n*Cerenkov photon generation\n"); |
875 | fprintf(pAliceInp,"*Generated from call: SetProcess('CKOV',1) or SetProcess('CKOV',2)\n"); | |
876 | Double_t emin = 2.07e-9; // minimum Cerenkov photon emission energy (in GeV!). Default: 2.07E-9 GeV (corresponding to 600 nm) | |
877 | Double_t emax = 4.96e-9; // maximum Cerenkov photon emission energy (in GeV!). Default: 4.96E-9 GeV (corresponding to 250 nm) | |
e749c124 | 878 | fprintf(pAliceInp,"OPT-PROD %10.4g%10.4g%10.1f%10.1f%10.1f%10.1fCERENKOV\n",emin,emax,zero,three,fLastMaterial,one); |
cbc3a17e | 879 | } |
880 | else if (iProcessValue[i] == 0) { | |
861d858d | 881 | fprintf(pAliceInp,"*\n*No Cerenkov photon generation\n"); |
882 | fprintf(pAliceInp,"*Generated from call: SetProcess('CKOV',0)\n"); | |
883 | // zero = not used | |
884 | // zero = not used | |
885 | // zero = not used | |
886 | // three = lower bound of the material indices in which the respective thresholds apply | |
887 | // fLastMaterial = upper bound of the material indices in which the respective thresholds apply | |
888 | // one = step length in assigning indices | |
889 | //"CERE-OFF"; | |
e749c124 | 890 | fprintf(pAliceInp,"OPT-PROD %10.1f%10.1f%10.1f%10.1f%10.1f%10.1fCERE-OFF\n",zero,zero,zero,three,fLastMaterial,one); |
cbc3a17e | 891 | } |
892 | else { | |
861d858d | 893 | fprintf(pAliceInp,"*\n*Illegal flag value in SetProcess('CKOV',?) call.\n"); |
894 | fprintf(pAliceInp,"*No FLUKA card generated\n"); | |
cbc3a17e | 895 | } |
896 | } // end of else if (strncmp(&sProcessFlag[i][0],"CKOV",4) == 0) | |
897 | ||
898 | ||
1de0a072 | 899 | // Compton scattering |
900 | // G3 default value: 1 | |
901 | // G4 processes: G4ComptonScattering, | |
902 | // G4LowEnergyCompton, | |
903 | // G4PolarizedComptonScattering | |
904 | // Particles: gamma | |
cbc3a17e | 905 | // Physics: EM |
906 | // flag = 0 no Compton scattering | |
907 | // flag = 1 Compton scattering, electron processed | |
908 | // flag = 2 Compton scattering, no electron stored | |
1de0a072 | 909 | // gMC ->SetProcess("COMP",1); // EMFCUT -1. 0. 0. 3. lastmat 0. PHOT-THR |
cbc3a17e | 910 | else if (strncmp(&sProcessFlag[i][0],"COMP",4) == 0) { |
911 | if (iProcessValue[i] == 1 || iProcessValue[i] == 2) { | |
861d858d | 912 | fprintf(pAliceInp,"*\n*Energy threshold (GeV) for Compton scattering - resets to default=0.\n"); |
913 | fprintf(pAliceInp,"*Generated from call: SetProcess('COMP',1);\n"); | |
914 | // - one = energy threshold (GeV) for Compton scattering - resets to default=0. | |
915 | // zero = not used | |
916 | // zero = not used | |
917 | // three = lower bound of the material indices in which the respective thresholds apply | |
918 | // fLastMaterial = upper bound of the material indices in which the respective thresholds apply | |
919 | // one = step length in assigning indices | |
920 | //"PHOT-THR"; | |
e749c124 | 921 | fprintf(pAliceInp,"EMFCUT %10.1f%10.1f%10.1f%10.1f%10.1f%10.1fPHOT-THR\n",-one,zero,zero,three,fLastMaterial,one); |
cbc3a17e | 922 | } |
923 | else if (iProcessValue[i] == 0) { | |
861d858d | 924 | fprintf(pAliceInp,"*\n*No Compton scattering - no FLUKA card generated\n"); |
925 | fprintf(pAliceInp,"*Generated from call: SetProcess('COMP',0)\n"); | |
cbc3a17e | 926 | } |
927 | else { | |
861d858d | 928 | fprintf(pAliceInp,"*\n*Illegal flag value in SetProcess('COMP',?) call.\n"); |
929 | fprintf(pAliceInp,"*No FLUKA card generated\n"); | |
cbc3a17e | 930 | } |
931 | } // end of else if (strncmp(&sProcessFlag[i][0],"COMP",4) == 0) | |
1de0a072 | 932 | |
933 | // decay | |
934 | // G3 default value: 1 | |
935 | // G4 process: G4Decay | |
936 | // | |
937 | // Particles: all which decay is applicable for | |
938 | // Physics: General | |
cbc3a17e | 939 | // flag = 0 no decays |
940 | // flag = 1 decays, secondaries processed | |
941 | // flag = 2 decays, no secondaries stored | |
1de0a072 | 942 | //gMC ->SetProcess("DCAY",1); // not available |
943 | else if ((strncmp(&sProcessFlag[i][0],"DCAY",4) == 0) && iProcessValue[i] == 1) | |
944 | cout << "SetProcess for flag=" << &sProcessFlag[i][0] << " value=" << iProcessValue[i] << " not avaliable!" << endl; | |
945 | ||
946 | // delta-ray | |
947 | // G3 default value: 2 | |
948 | // !! G4 treats delta rays in different way | |
949 | // G4 processes: G4eIonisation/G4IeIonization, | |
950 | // G4MuIonisation/G4IMuIonization, | |
951 | // G4hIonisation/G4IhIonisation | |
cbc3a17e | 952 | // Particles: charged |
1de0a072 | 953 | // Physics: EM |
cbc3a17e | 954 | // flag = 0 no energy loss |
955 | // flag = 1 restricted energy loss fluctuations | |
956 | // flag = 2 complete energy loss fluctuations | |
957 | // flag = 3 same as 1 | |
958 | // flag = 4 no energy loss fluctuations | |
1de0a072 | 959 | // gMC ->SetProcess("DRAY",0); // DELTARAY 1.E+6 0. 0. 3. lastmat 0. |
cbc3a17e | 960 | else if (strncmp(&sProcessFlag[i][0],"DRAY",4) == 0) { |
961 | if (iProcessValue[i] == 0 || iProcessValue[i] == 4) { | |
861d858d | 962 | fprintf(pAliceInp,"*\n*Kinetic energy threshold (GeV) for delta ray production\n"); |
963 | fprintf(pAliceInp,"*Generated from call: SetProcess('DRAY',0) or SetProcess('DRAY',4)\n"); | |
964 | fprintf(pAliceInp,"*No delta ray production by muons - threshold set artificially high\n"); | |
965 | Double_t emin = 1.0e+6; // kinetic energy threshold (GeV) for delta ray production (discrete energy transfer) | |
966 | // zero = ignored | |
967 | // zero = ignored | |
968 | // three = lower bound of the material indices in which the respective thresholds apply | |
969 | // fLastMaterial = upper bound of the material indices in which the respective thresholds apply | |
970 | // one = step length in assigning indices | |
e749c124 | 971 | fprintf(pAliceInp,"DELTARAY %10.4g%10.1f%10.1f%10.1f%10.1f%10.1f\n",emin,zero,zero,three,fLastMaterial,one); |
cbc3a17e | 972 | } |
973 | else if (iProcessValue[i] == 1 || iProcessValue[i] == 2 || iProcessValue[i] == 3) { | |
861d858d | 974 | fprintf(pAliceInp,"*\n*Kinetic energy threshold (GeV) for delta ray production\n"); |
975 | fprintf(pAliceInp,"*Generated from call: SetProcess('DRAY',flag), flag=1,2,3\n"); | |
976 | fprintf(pAliceInp,"*Delta ray production by muons switched on\n"); | |
977 | fprintf(pAliceInp,"*Energy threshold set by call SetCut('DCUTM',cut) or set to 1.0e+6.\n"); | |
cbc3a17e | 978 | fCut = 1.0e+6; |
979 | for (j=0; j<iNbOfCut; j++) { | |
980 | if (strncmp(&sCutFlag[j][0],"DCUTM",5) == 0) fCut = fCutValue[j]; | |
981 | } | |
861d858d | 982 | // fCut = kinetic energy threshold (GeV) for delta ray production (discrete energy transfer) |
983 | // zero = ignored | |
984 | // zero = ignored | |
985 | // three = lower bound of the material indices in which the respective thresholds apply | |
986 | // fLastMaterial = upper bound of the material indices in which the respective thresholds apply | |
987 | // one = step length in assigning indices | |
e749c124 | 988 | fprintf(pAliceInp,"DELTARAY %10.4g%10.1f%10.1f%10.1f%10.1f%10.1f\n",fCut,zero,zero,three,fLastMaterial,one); |
cbc3a17e | 989 | } |
990 | else { | |
861d858d | 991 | fprintf(pAliceInp,"*\n*Illegal flag value in SetProcess('DRAY',?) call.\n"); |
992 | fprintf(pAliceInp,"*No FLUKA card generated\n"); | |
cbc3a17e | 993 | } |
994 | } // end of else if (strncmp(&sProcessFlag[i][0],"DRAY",4) == 0) | |
1de0a072 | 995 | |
cbc3a17e | 996 | // hadronic process |
997 | // G3 default value: 1 | |
998 | // G4 processes: all defined by TG4PhysicsConstructorHadron | |
999 | // | |
1000 | // Particles: hadrons | |
1001 | // Physics: Hadron | |
1002 | // flag = 0 no multiple scattering | |
1003 | // flag = 1 hadronic interactions, secondaries processed | |
1004 | // flag = 2 hadronic interactions, no secondaries stored | |
1005 | // gMC ->SetProcess("HADR",1); // ??? hadronic process | |
1006 | //Select pure GEANH (HADR 1) or GEANH/NUCRIN (HADR 3) ????? | |
1007 | else if (strncmp(&sProcessFlag[i][0],"HADR",4) == 0) { | |
1008 | if (iProcessValue[i] == 1 || iProcessValue[i] == 2) { | |
861d858d | 1009 | fprintf(pAliceInp,"*\n*Hadronic interaction is ON by default in FLUKA\n"); |
1010 | fprintf(pAliceInp,"*No FLUKA card generated\n"); | |
cbc3a17e | 1011 | } |
1012 | else if (iProcessValue[i] == 0) { | |
861d858d | 1013 | fprintf(pAliceInp,"*\n*Hadronic interaction is set OFF\n"); |
1014 | fprintf(pAliceInp,"*Generated from call: SetProcess('HADR',0);\n"); | |
1015 | // zero = ignored | |
1016 | // three = multiple scattering for hadrons and muons is completely suppressed | |
1017 | // zero = no spin-relativistic corrections | |
1018 | // three = lower bound of the material indices in which the respective thresholds apply | |
1019 | // fLastMaterial = upper bound of the material indices in which the respective thresholds apply | |
e749c124 | 1020 | fprintf(pAliceInp,"MULSOPT %10.1f%10.1f%10.1f%10.1f%10.1f\n",zero,three,zero,three,fLastMaterial); |
cbc3a17e | 1021 | |
1022 | } | |
1023 | else { | |
861d858d | 1024 | fprintf(pAliceInp,"*\n*Illegal flag value in SetProcess('HADR',?) call.\n"); |
1025 | fprintf(pAliceInp,"*No FLUKA card generated\n"); | |
cbc3a17e | 1026 | } |
1027 | } // end of else if (strncmp(&sProcessFlag[i][0],"HADR",4) == 0) | |
1028 | ||
1029 | ||
1030 | // energy loss | |
1031 | // G3 default value: 2 | |
1032 | // G4 processes: G4eIonisation/G4IeIonization, | |
1033 | // G4MuIonisation/G4IMuIonization, | |
1034 | // G4hIonisation/G4IhIonisation | |
1de0a072 | 1035 | // |
cbc3a17e | 1036 | // Particles: charged |
1037 | // Physics: EM | |
1038 | // flag=0 no energy loss | |
1039 | // flag=1 restricted energy loss fluctuations | |
1040 | // flag=2 complete energy loss fluctuations | |
1041 | // flag=3 same as 1 | |
1042 | // flag=4 no energy loss fluctuations | |
1043 | // If the value ILOSS is changed, then (in G3) cross-sections and energy | |
1044 | // loss tables must be recomputed via the command 'PHYSI' | |
1045 | // gMC ->SetProcess("LOSS",2); // ??? IONFLUCT ? energy loss | |
1046 | else if (strncmp(&sProcessFlag[i][0],"LOSS",4) == 0) { | |
1047 | if (iProcessValue[i] == 2) { // complete energy loss fluctuations | |
861d858d | 1048 | fprintf(pAliceInp,"*\n*Complete energy loss fluctuations do not exist in FLUKA\n"); |
1049 | fprintf(pAliceInp,"*Generated from call: SetProcess('LOSS',2);\n"); | |
1050 | fprintf(pAliceInp,"*flag=2=complete energy loss fluctuations\n"); | |
1051 | fprintf(pAliceInp,"*No FLUKA card generated\n"); | |
cbc3a17e | 1052 | } |
1053 | else if (iProcessValue[i] == 1 || iProcessValue[i] == 3) { // restricted energy loss fluctuations | |
861d858d | 1054 | fprintf(pAliceInp,"*\n*Restricted energy loss fluctuations\n"); |
1055 | fprintf(pAliceInp,"*Generated from call: SetProcess('LOSS',1) or SetProcess('LOSS',3)\n"); | |
1056 | // one = restricted energy loss fluctuations (for hadrons and muons) switched on | |
1057 | // one = restricted energy loss fluctuations (for e+ and e-) switched on | |
1058 | // one = minimal accuracy | |
1059 | // three = lower bound of the material indices in which the respective thresholds apply | |
1060 | // upper bound of the material indices in which the respective thresholds apply | |
e749c124 | 1061 | fprintf(pAliceInp,"IONFLUCT %10.1f%10.1f%10.1f%10.1f%10.1f\n",one,one,one,three,fLastMaterial); |
cbc3a17e | 1062 | } |
1063 | else if (iProcessValue[i] == 4) { // no energy loss fluctuations | |
861d858d | 1064 | fprintf(pAliceInp,"*\n*No energy loss fluctuations\n"); |
1065 | fprintf(pAliceInp,"*\n*Generated from call: SetProcess('LOSS',4)\n"); | |
1066 | // - one = restricted energy loss fluctuations (for hadrons and muons) switched off | |
1067 | // - one = restricted energy loss fluctuations (for e+ and e-) switched off | |
1068 | // one = minimal accuracy | |
1069 | // three = lower bound of the material indices in which the respective thresholds apply | |
1070 | // fLastMaterial = upper bound of the material indices in which the respective thresholds apply | |
e749c124 | 1071 | fprintf(pAliceInp,"IONFLUCT %10.1f%10.1f%10.1f%10.1f%10.1f\n",-one,-one,one,three,fLastMaterial); |
cbc3a17e | 1072 | } |
1073 | else { | |
861d858d | 1074 | fprintf(pAliceInp,"*\n*Illegal flag value in SetProcess('LOSS',?) call.\n"); |
1075 | fprintf(pAliceInp,"*No FLUKA card generated\n"); | |
cbc3a17e | 1076 | } |
1077 | } // end of else if (strncmp(&sProcessFlag[i][0],"LOSS",4) == 0) | |
1078 | ||
1079 | ||
1080 | // multiple scattering | |
1081 | // G3 default value: 1 | |
1082 | // G4 process: G4MultipleScattering/G4IMultipleScattering | |
1083 | // | |
1084 | // Particles: charged | |
1085 | // Physics: EM | |
1086 | // flag = 0 no multiple scattering | |
1087 | // flag = 1 Moliere or Coulomb scattering | |
1088 | // flag = 2 Moliere or Coulomb scattering | |
1089 | // flag = 3 Gaussian scattering | |
1090 | // gMC ->SetProcess("MULS",1); // MULSOPT multiple scattering | |
1091 | else if (strncmp(&sProcessFlag[i][0],"MULS",4) == 0) { | |
1092 | if (iProcessValue[i] == 1 || iProcessValue[i] == 2 || iProcessValue[i] == 3) { | |
861d858d | 1093 | fprintf(pAliceInp,"*\n*Multiple scattering is ON by default for e+e- and for hadrons/muons\n"); |
1094 | fprintf(pAliceInp,"*No FLUKA card generated\n"); | |
cbc3a17e | 1095 | } |
1096 | else if (iProcessValue[i] == 0) { | |
861d858d | 1097 | fprintf(pAliceInp,"*\n*Multiple scattering is set OFF\n"); |
1098 | fprintf(pAliceInp,"*Generated from call: SetProcess('MULS',0);\n"); | |
1099 | // zero = ignored | |
1100 | // three = multiple scattering for hadrons and muons is completely suppressed | |
1101 | // three = multiple scattering for e+ and e- is completely suppressed | |
1102 | // three = lower bound of the material indices in which the respective thresholds apply | |
1103 | // fLastMaterial = upper bound of the material indices in which the respective thresholds apply | |
e749c124 | 1104 | fprintf(pAliceInp,"MULSOPT %10.1f%10.1f%10.1f%10.1f%10.1f\n",zero,three,three,three,fLastMaterial); |
cbc3a17e | 1105 | } |
1106 | else { | |
861d858d | 1107 | fprintf(pAliceInp,"*\n*Illegal flag value in SetProcess('MULS',?) call.\n"); |
1108 | fprintf(pAliceInp,"*No FLUKA card generated\n"); | |
cbc3a17e | 1109 | } |
1110 | } // end of else if (strncmp(&sProcessFlag[i][0],"MULS",4) == 0) | |
1111 | ||
1de0a072 | 1112 | |
1113 | // muon nuclear interaction | |
1114 | // G3 default value: 0 | |
1115 | // G4 processes: G4MuNuclearInteraction, | |
1116 | // G4MuonMinusCaptureAtRest | |
1117 | // | |
1118 | // Particles: mu | |
1119 | // Physics: Not set | |
cbc3a17e | 1120 | // flag = 0 no muon-nuclear interaction |
1121 | // flag = 1 nuclear interaction, secondaries processed | |
1122 | // flag = 2 nuclear interaction, secondaries not processed | |
1de0a072 | 1123 | // gMC ->SetProcess("MUNU",1); // MUPHOTON 1. 0. 0. 3. lastmat |
cbc3a17e | 1124 | else if (strncmp(&sProcessFlag[i][0],"MUNU",4) == 0) { |
1125 | if (iProcessValue[i] == 1) { | |
861d858d | 1126 | fprintf(pAliceInp,"*\n*Muon nuclear interactions with production of secondary hadrons\n"); |
e749c124 | 1127 | fprintf(pAliceInp,"*Generated from call: SetProcess('MUNU',1);\n"); |
861d858d | 1128 | // one = full simulation of muon nuclear interactions and production of secondary hadrons |
1129 | // zero = ratio of longitudinal to transverse virtual photon cross-section - Default = 0.25. | |
1130 | // zero = fraction of rho-like interactions ( must be < 1) - Default = 0.75. | |
1131 | // three = lower bound of the material indices in which the respective thresholds apply | |
1132 | // fLastMaterial = upper bound of the material indices in which the respective thresholds apply | |
e749c124 | 1133 | fprintf(pAliceInp,"MUPHOTON %10.1f%10.1f%10.1f%10.1f%10.1f\n",one,zero,zero,three,fLastMaterial); |
cbc3a17e | 1134 | } |
1135 | else if (iProcessValue[i] == 2) { | |
861d858d | 1136 | fprintf(pAliceInp,"*\n*Muon nuclear interactions without production of secondary hadrons\n"); |
1137 | fprintf(pAliceInp,"*Generated from call: SetProcess('MUNU',2);\n"); | |
1138 | // two = full simulation of muon nuclear interactions and production of secondary hadrons | |
1139 | // zero = ratio of longitudinal to transverse virtual photon cross-section - Default = 0.25. | |
1140 | // zero = fraction of rho-like interactions ( must be < 1) - Default = 0.75. | |
1141 | // three = lower bound of the material indices in which the respective thresholds apply | |
1142 | // fLastMaterial = upper bound of the material indices in which the respective thresholds apply | |
e749c124 | 1143 | fprintf(pAliceInp,"MUPHOTON %10.1f%10.1f%10.1f%10.1f%10.1f\n",two,zero,zero,three,fLastMaterial); |
cbc3a17e | 1144 | } |
1145 | else if (iProcessValue[i] == 0) { | |
861d858d | 1146 | fprintf(pAliceInp,"*\n*No muon nuclear interaction - no FLUKA card generated\n"); |
1147 | fprintf(pAliceInp,"*Generated from call: SetProcess('MUNU',0)\n"); | |
cbc3a17e | 1148 | } |
1149 | else { | |
861d858d | 1150 | fprintf(pAliceInp,"*\n*Illegal flag value in SetProcess('MUNU',?) call.\n"); |
1151 | fprintf(pAliceInp,"*No FLUKA card generated\n"); | |
cbc3a17e | 1152 | } |
1153 | } // end of else if (strncmp(&sProcessFlag[i][0],"MUNU",4) == 0) | |
1de0a072 | 1154 | |
1de0a072 | 1155 | |
1156 | // photofission | |
1157 | // G3 default value: 0 | |
1158 | // G4 process: ?? | |
1159 | // | |
1160 | // Particles: gamma | |
1161 | // Physics: ?? | |
1162 | // gMC ->SetProcess("PFIS",0); // PHOTONUC -1. 0. 0. 3. lastmat 0. | |
cbc3a17e | 1163 | // flag = 0 no photon fission |
1164 | // flag = 1 photon fission, secondaries processed | |
1165 | // flag = 2 photon fission, no secondaries stored | |
1166 | else if (strncmp(&sProcessFlag[i][0],"PFIS",4) == 0) { | |
1167 | if (iProcessValue[i] == 0) { | |
861d858d | 1168 | fprintf(pAliceInp,"*\n*No photonuclear interactions\n"); |
1169 | fprintf(pAliceInp,"*Generated from call: SetProcess('PFIS',0);\n"); | |
1170 | // - one = no photonuclear interactions | |
1171 | // zero = not used | |
1172 | // zero = not used | |
1173 | // three = lower bound of the material indices in which the respective thresholds apply | |
1174 | // fLastMaterial = upper bound of the material indices in which the respective thresholds apply | |
e749c124 | 1175 | fprintf(pAliceInp,"PHOTONUC %10.1f%10.1f%10.1f%10.1f%10.1f\n",-one,zero,zero,three,fLastMaterial); |
cbc3a17e | 1176 | } |
1177 | else if (iProcessValue[i] == 1) { | |
861d858d | 1178 | fprintf(pAliceInp,"*\n*Photon nuclear interactions are activated at all energies\n"); |
1179 | fprintf(pAliceInp,"*Generated from call: SetProcess('PFIS',1);\n"); | |
1180 | // one = photonuclear interactions are activated at all energies | |
1181 | // zero = not used | |
1182 | // zero = not used | |
1183 | // three = lower bound of the material indices in which the respective thresholds apply | |
1184 | // fLastMaterial = upper bound of the material indices in which the respective thresholds apply | |
e749c124 | 1185 | fprintf(pAliceInp,"PHOTONUC %10.1f%10.1f%10.1f%10.1f%10.1f\n",one,zero,zero,three,fLastMaterial); |
cbc3a17e | 1186 | } |
1187 | else if (iProcessValue[i] == 0) { | |
861d858d | 1188 | fprintf(pAliceInp,"*\n*No photofission - no FLUKA card generated\n"); |
1189 | fprintf(pAliceInp,"*Generated from call: SetProcess('PFIS',0)\n"); | |
cbc3a17e | 1190 | } |
1191 | else { | |
861d858d | 1192 | fprintf(pAliceInp,"*\n*Illegal flag value in SetProcess('PFIS',?) call.\n"); |
1193 | fprintf(pAliceInp,"*No FLUKA card generated\n"); | |
cbc3a17e | 1194 | } |
1de0a072 | 1195 | } |
1196 | ||
cbc3a17e | 1197 | |
1de0a072 | 1198 | // photo electric effect |
1199 | // G3 default value: 1 | |
1200 | // G4 processes: G4PhotoElectricEffect | |
1201 | // G4LowEnergyPhotoElectric | |
1202 | // Particles: gamma | |
1203 | // Physics: EM | |
cbc3a17e | 1204 | // flag = 0 no photo electric effect |
1205 | // flag = 1 photo electric effect, electron processed | |
1206 | // flag = 2 photo electric effect, no electron stored | |
1de0a072 | 1207 | // gMC ->SetProcess("PHOT",1); // EMFCUT 0. -1. 0. 3. lastmat 0. PHOT-THR |
cbc3a17e | 1208 | else if (strncmp(&sProcessFlag[i][0],"PHOT",4) == 0) { |
1209 | if (iProcessValue[i] == 1 || iProcessValue[i] == 2) { | |
861d858d | 1210 | fprintf(pAliceInp,"*\n*Photo electric effect is activated\n"); |
1211 | fprintf(pAliceInp,"*Generated from call: SetProcess('PHOT',1);\n"); | |
1212 | // zero = ignored | |
1213 | // - one = resets to default=0. | |
1214 | // zero = ignored | |
1215 | // three = lower bound of the material indices in which the respective thresholds apply | |
1216 | // fLastMaterial = upper bound of the material indices in which the respective thresholds apply | |
1217 | // one = step length in assigning indices | |
1218 | //"PHOT-THR"; | |
e749c124 | 1219 | fprintf(pAliceInp,"EMFCUT %10.1f%10.1f%10.1f%10.1f%10.1f%10.1fPHOT-THR\n",zero,-one,zero,three,fLastMaterial,one); |
cbc3a17e | 1220 | } |
1221 | else if (iProcessValue[i] == 0) { | |
861d858d | 1222 | fprintf(pAliceInp,"*\n*No photo electric effect - no FLUKA card generated\n"); |
1223 | fprintf(pAliceInp,"*Generated from call: SetProcess('PHOT',0)\n"); | |
cbc3a17e | 1224 | } |
1225 | else { | |
861d858d | 1226 | fprintf(pAliceInp,"*\n*Illegal flag value in SetProcess('PHOT',?) call.\n"); |
1227 | fprintf(pAliceInp,"*No FLUKA card generated\n"); | |
cbc3a17e | 1228 | } |
1229 | } // else if (strncmp(&sProcessFlag[i][0],"PHOT",4) == 0) | |
1de0a072 | 1230 | |
5929ad29 | 1231 | |
cbc3a17e | 1232 | // Rayleigh scattering |
1de0a072 | 1233 | // G3 default value: 0 |
cbc3a17e | 1234 | // G4 process: G4OpRayleigh |
1de0a072 | 1235 | // |
cbc3a17e | 1236 | // Particles: optical photon |
1de0a072 | 1237 | // Physics: Optical |
cbc3a17e | 1238 | // flag = 0 Rayleigh scattering off |
1239 | // flag = 1 Rayleigh scattering on | |
1240 | //xx gMC ->SetProcess("RAYL",1); | |
1241 | else if (strncmp(&sProcessFlag[i][0],"RAYL",4) == 0) { | |
1242 | if (iProcessValue[i] == 1) { | |
861d858d | 1243 | fprintf(pAliceInp,"*\n*Rayleigh scattering is ON by default in FLUKA\n"); |
1244 | fprintf(pAliceInp,"*No FLUKA card generated\n"); | |
cbc3a17e | 1245 | } |
1246 | else if (iProcessValue[i] == 0) { | |
861d858d | 1247 | fprintf(pAliceInp,"*\n*Rayleigh scattering is set OFF\n"); |
1248 | fprintf(pAliceInp,"*Generated from call: SetProcess('RAYL',0);\n"); | |
1249 | // - one = no Rayleigh scattering and no binding corrections for Compton | |
1250 | // three = lower bound of the material indices in which the respective thresholds apply | |
1251 | // fLastMaterial = upper bound of the material indices in which the respective thresholds apply | |
e749c124 | 1252 | fprintf(pAliceInp,"EMFRAY %10.1f%10.1f%10.1f%10.1f\n",-one,three,three,fLastMaterial); |
cbc3a17e | 1253 | } |
1254 | else { | |
861d858d | 1255 | fprintf(pAliceInp,"*\n*Illegal flag value in SetProcess('RAYL',?) call.\n"); |
1256 | fprintf(pAliceInp,"*No FLUKA card generated\n"); | |
cbc3a17e | 1257 | } |
1258 | } // end of else if (strncmp(&sProcessFlag[i][0],"RAYL",4) == 0) | |
1de0a072 | 1259 | |
5929ad29 | 1260 | |
1261 | // synchrotron radiation in magnetic field | |
1262 | // G3 default value: 0 | |
1263 | // G4 process: G4SynchrotronRadiation | |
1264 | // | |
1265 | // Particles: ?? | |
1266 | // Physics: Not set | |
1267 | // flag = 0 no synchrotron radiation | |
1268 | // flag = 1 synchrotron radiation | |
1269 | //xx gMC ->SetProcess("SYNC",1); // synchrotron radiation generation | |
1270 | else if (strncmp(&sProcessFlag[i][0],"SYNC",4) == 0) { | |
861d858d | 1271 | fprintf(pAliceInp,"*\n*Synchrotron radiation generation is NOT implemented in FLUKA\n"); |
1272 | fprintf(pAliceInp,"*No FLUKA card generated\n"); | |
5929ad29 | 1273 | } |
1274 | ||
cbc3a17e | 1275 | |
1276 | // Automatic calculation of tracking medium parameters | |
1277 | // flag = 0 no automatic calculation | |
1278 | // flag = 1 automatic calculation | |
1279 | //xx gMC ->SetProcess("AUTO",1); // ??? automatic computation of the tracking medium parameters | |
5929ad29 | 1280 | else if (strncmp(&sProcessFlag[i][0],"AUTO",4) == 0) { |
861d858d | 1281 | fprintf(pAliceInp,"*\n*Automatic calculation of tracking medium parameters is always ON in FLUKA\n"); |
1282 | fprintf(pAliceInp,"*No FLUKA card generated\n"); | |
5929ad29 | 1283 | } |
1284 | ||
1285 | ||
1286 | // To control energy loss fluctuation model | |
1287 | // flag = 0 Urban model | |
1288 | // flag = 1 PAI model | |
1289 | // flag = 2 PAI+ASHO model (not active at the moment) | |
1290 | //xx gMC ->SetProcess("STRA",1); // ??? energy fluctuation model | |
1291 | else if (strncmp(&sProcessFlag[i][0],"STRA",4) == 0) { | |
1292 | if (iProcessValue[i] == 0 || iProcessValue[i] == 2 || iProcessValue[i] == 3) { | |
861d858d | 1293 | fprintf(pAliceInp,"*\n*Ionization energy losses calculation is activated\n"); |
1294 | fprintf(pAliceInp,"*Generated from call: SetProcess('STRA',n);, n=0,1,2\n"); | |
1295 | // one = restricted energy loss fluctuations (for hadrons and muons) switched on | |
1296 | // one = restricted energy loss fluctuations (for e+ and e-) switched on | |
1297 | // one = minimal accuracy | |
1298 | // three = lower bound of the material indices in which the respective thresholds apply | |
1299 | // fLastMaterial = upper bound of the material indices in which the respective thresholds apply | |
e749c124 | 1300 | fprintf(pAliceInp,"IONFLUCT %10.1f%10.1f%10.1f%10.1f%10.1f\n",one,one,one,three,fLastMaterial); |
5929ad29 | 1301 | } |
1302 | else { | |
861d858d | 1303 | fprintf(pAliceInp,"*\n*Illegal flag value in SetProcess('STRA',?) call.\n"); |
1304 | fprintf(pAliceInp,"*No FLUKA card generated\n"); | |
5929ad29 | 1305 | } |
1306 | } // else if (strncmp(&sProcessFlag[i][0],"STRA",4) == 0) | |
1307 | ||
1308 | ||
1309 | ||
1310 | ||
1311 | else { // processes not yet treated | |
1de0a072 | 1312 | |
cbc3a17e | 1313 | // light photon absorption (Cerenkov photons) |
1de0a072 | 1314 | // it is turned on when Cerenkov process is turned on |
1315 | // G3 default value: 0 | |
1316 | // G4 process: G4OpAbsorption, G4OpBoundaryProcess | |
1317 | // | |
1318 | // Particles: optical photon | |
1319 | // Physics: Optical | |
cbc3a17e | 1320 | // flag = 0 no absorption of Cerenkov photons |
1321 | // flag = 1 absorption of Cerenkov photons | |
1de0a072 | 1322 | // gMC ->SetProcess("LABS",2); // ??? Cerenkov light absorption |
1323 | ||
1de0a072 | 1324 | |
1de0a072 | 1325 | |
1326 | cout << "SetProcess for flag=" << &sProcessFlag[i][0] << " value=" << iProcessValue[i] << " not yet implemented!" << endl; | |
1327 | } | |
1328 | } //end of loop number of SetProcess calls | |
1329 | ||
1330 | ||
1331 | // Loop over number of SetCut calls | |
1332 | for (Int_t i=0; i<iNbOfCut; i++) { | |
1333 | ||
cbc3a17e | 1334 | // cuts used in SetProcess calls |
1335 | if (strncmp(&sCutFlag[i][0],"BCUTM",5) == 0) continue; | |
1336 | else if (strncmp(&sCutFlag[i][0],"BCUTE",5) == 0) continue; | |
1337 | else if (strncmp(&sCutFlag[i][0],"DCUTM",5) == 0) continue; | |
1338 | else if (strncmp(&sCutFlag[i][0],"PPCUTM",6) == 0) continue; | |
1339 | ||
1de0a072 | 1340 | // gammas |
1341 | // G4 particles: "gamma" | |
1342 | // G3 default value: 0.001 GeV | |
1343 | //gMC ->SetCut("CUTGAM",cut); // cut for gammas | |
cbc3a17e | 1344 | else if (strncmp(&sCutFlag[i][0],"CUTGAM",6) == 0) { |
861d858d | 1345 | fprintf(pAliceInp,"*\n*Cut for gamma\n"); |
1346 | fprintf(pAliceInp,"*Generated from call: SetCut('CUTGAM',cut);\n"); | |
1347 | // -fCutValue[i]; | |
1348 | // 7.0 = lower bound of the particle id-numbers to which the cut-off | |
e749c124 | 1349 | fprintf(pAliceInp,"PART-THR %10.4g%10.1f\n",-fCutValue[i],7.0); |
1de0a072 | 1350 | } |
1351 | ||
1352 | // electrons | |
1353 | // G4 particles: "e-" | |
1354 | // ?? positrons | |
1355 | // G3 default value: 0.001 GeV | |
1356 | //gMC ->SetCut("CUTELE",cut); // cut for e+,e- | |
1357 | else if (strncmp(&sCutFlag[i][0],"CUTELE",6) == 0) { | |
861d858d | 1358 | fprintf(pAliceInp,"*\n*Cut for electrons\n"); |
1359 | fprintf(pAliceInp,"*Generated from call: SetCut('CUTELE',cut);\n"); | |
1360 | // -fCutValue[i]; | |
1361 | // three = lower bound of the particle id-numbers to which the cut-off | |
1362 | // 4.0 = upper bound of the particle id-numbers to which the cut-off | |
1363 | // one = step length in assigning numbers | |
e749c124 | 1364 | fprintf(pAliceInp,"PART-THR %10.4g%10.1f%10.1f%10.1f\n",-fCutValue[i],three,4.0,one); |
1de0a072 | 1365 | } |
1366 | ||
1367 | // neutral hadrons | |
1368 | // G4 particles: of type "baryon", "meson", "nucleus" with zero charge | |
1369 | // G3 default value: 0.01 GeV | |
1370 | //gMC ->SetCut("CUTNEU",cut); // cut for neutral hadrons | |
1371 | else if (strncmp(&sCutFlag[i][0],"CUTNEU",6) == 0) { | |
861d858d | 1372 | fprintf(pAliceInp,"*\n*Cut for neutral hadrons\n"); |
1373 | fprintf(pAliceInp,"*Generated from call: SetCut('CUTNEU',cut);\n"); | |
1374 | ||
1375 | // 8.0 = Neutron | |
1376 | // 9.0 = Antineutron | |
e749c124 | 1377 | fprintf(pAliceInp,"PART-THR %10.4g%10.1f%10.1f\n",-fCutValue[i],8.0,9.0); |
861d858d | 1378 | |
1379 | // 12.0 = Kaon zero long | |
1380 | // 12.0 = Kaon zero long | |
e749c124 | 1381 | fprintf(pAliceInp,"PART-THR %10.4g%10.1f%10.1f\n",-fCutValue[i],12.0,12.0); |
861d858d | 1382 | |
1383 | // 17.0 = Lambda, 18.0 = Antilambda | |
1384 | // 19.0 = Kaon zero short | |
e749c124 | 1385 | fprintf(pAliceInp,"PART-THR %10.4g%10.1f%10.1f\n",-fCutValue[i],17.0,19.0); |
861d858d | 1386 | |
1387 | // 22.0 = Sigma zero, Pion zero, Kaon zero | |
1388 | // 25.0 = Antikaon zero | |
e749c124 | 1389 | fprintf(pAliceInp,"PART-THR %10.4g%10.1f%10.1f\n",-fCutValue[i],22.0,25.0); |
861d858d | 1390 | |
1391 | // 32.0 = Antisigma zero | |
1392 | // 32.0 = Antisigma zero | |
e749c124 | 1393 | fprintf(pAliceInp,"PART-THR %10.4g%10.1f%10.1f\n",-fCutValue[i],32.0,32.0); |
861d858d | 1394 | |
1395 | // 34.0 = Xi zero | |
1396 | // 35.0 = AntiXi zero | |
e749c124 | 1397 | fprintf(pAliceInp,"PART-THR %10.4g%10.1f%10.1f\n",-fCutValue[i],34.0,35.0); |
861d858d | 1398 | |
1399 | // 47.0 = D zero | |
1400 | // 48.0 = AntiD zero | |
e749c124 | 1401 | fprintf(pAliceInp,"PART-THR %10.4g%10.1f%10.1f\n",-fCutValue[i],47.0,48.0); |
861d858d | 1402 | |
1403 | // 53.0 = Xi_c zero | |
1404 | // 53.0 = Xi_c zero | |
e749c124 | 1405 | fprintf(pAliceInp,"PART-THR %10.4g%10.1f%10.1f\n",-fCutValue[i],53.0,53.0); |
861d858d | 1406 | |
1407 | // 55.0 = Xi'_c zero | |
1408 | // 56.0 = Omega_c zero | |
e749c124 | 1409 | fprintf(pAliceInp,"PART-THR %10.4g%10.1f%10.1f\n",-fCutValue[i],55.0,56.0); |
861d858d | 1410 | |
1411 | // 59.0 = AntiXi_c zero | |
1412 | // 59.0 = AntiXi_c zero | |
e749c124 | 1413 | fprintf(pAliceInp,"PART-THR %10.4g%10.1f%10.1f\n",-fCutValue[i],59.0,59.0); |
861d858d | 1414 | |
1415 | // 61.0 = AntiXi'_c zero | |
1416 | // 62.0 = AntiOmega_c zero | |
e749c124 | 1417 | fprintf(pAliceInp,"PART-THR %10.4g%10.1f%10.1f\n",-fCutValue[i],61.0,62.0); |
1de0a072 | 1418 | } |
1419 | ||
1420 | // charged hadrons | |
1421 | // G4 particles: of type "baryon", "meson", "nucleus" with non-zero charge | |
1422 | // G3 default value: 0.01 GeV | |
1423 | //gMC ->SetCut("CUTHAD",cut); // cut for charged hadrons | |
1424 | else if (strncmp(&sCutFlag[i][0],"CUTHAD",6) == 0) { | |
861d858d | 1425 | fprintf(pAliceInp,"*\n*Cut for charged hadrons\n"); |
1426 | fprintf(pAliceInp,"*Generated from call: SetCut('CUTHAD',cut);\n"); | |
1427 | ||
1428 | // 1.0 = Proton | |
1429 | // 2.0 = Antiproton | |
e749c124 | 1430 | fprintf(pAliceInp,"PART-THR %10.4g%10.1f%10.1f\n",-fCutValue[i],1.0,2.0); |
861d858d | 1431 | |
1432 | // 13.0 = Positive Pion, Negative Pion, Positive Kaon | |
1433 | // 16.0 = Negative Kaon | |
e749c124 | 1434 | fprintf(pAliceInp,"PART-THR %10.4g%10.1f%10.1f\n",-fCutValue[i],13.0,16.0); |
861d858d | 1435 | |
1436 | // 20.0 = Negative Sigma | |
1437 | // 21.0 = Positive Sigma | |
e749c124 | 1438 | fprintf(pAliceInp,"PART-THR %10.4g%10.1f%10.1f\n",-fCutValue[i],20.0,21.0); |
861d858d | 1439 | |
1440 | // 31.0 = Antisigma minus | |
1441 | // 33.0 = Antisigma plus | |
1442 | // 2.0 = step length | |
e749c124 | 1443 | fprintf(pAliceInp,"PART-THR %10.4g%10.1f%10.1f%10.1f\n",-fCutValue[i],31.0,33.0,2.0); |
861d858d | 1444 | |
1445 | // 36.0 = Negative Xi, Positive Xi, Omega minus | |
1446 | // 39.0 = Antiomega | |
e749c124 | 1447 | fprintf(pAliceInp,"PART-THR %10.4g%10.1f%10.1f\n",-fCutValue[i],36.0,39.0); |
861d858d | 1448 | |
1449 | // 45.0 = D plus | |
1450 | // 46.0 = D minus | |
e749c124 | 1451 | fprintf(pAliceInp,"PART-THR %10.4g%10.1f%10.1f\n",-fCutValue[i],45.0,46.0); |
861d858d | 1452 | |
1453 | // 49.0 = D_s plus, D_s minus, Lambda_c plus | |
1454 | // 52.0 = Xi_c plus | |
e749c124 | 1455 | fprintf(pAliceInp,"PART-THR %10.4g%10.1f%10.1f\n",-fCutValue[i],49.0,52.0); |
861d858d | 1456 | |
1457 | // 54.0 = Xi'_c plus | |
1458 | // 60.0 = AntiXi'_c minus | |
1459 | // 6.0 = step length | |
e749c124 | 1460 | fprintf(pAliceInp,"PART-THR %10.4g%10.1f%10.1f%10.1f\n",-fCutValue[i],54.0,60.0,6.0); |
861d858d | 1461 | |
1462 | // 57.0 = Antilambda_c minus | |
1463 | // 58.0 = AntiXi_c minus | |
e749c124 | 1464 | fprintf(pAliceInp,"PART-THR %10.4g%10.1f%10.1f\n",-fCutValue[i],57.0,58.0); |
1de0a072 | 1465 | } |
1466 | ||
1467 | // muons | |
1468 | // G4 particles: "mu+", "mu-" | |
1469 | // G3 default value: 0.01 GeV | |
1470 | //gMC ->SetCut("CUTMUO",cut); // cut for mu+, mu- | |
1471 | else if (strncmp(&sCutFlag[i][0],"CUTMUO",6) == 0) { | |
861d858d | 1472 | fprintf(pAliceInp,"*\n*Cut for muons\n"); |
1473 | fprintf(pAliceInp,"*Generated from call: SetCut('CUTMUO',cut);\n"); | |
1474 | // 10.0 = Muon+ | |
1475 | // 11.0 = Muon- | |
e749c124 | 1476 | fprintf(pAliceInp,"PART-THR %10.4g%10.1f%10.1f\n",-fCutValue[i],10.0,11.0); |
1de0a072 | 1477 | } |
861d858d | 1478 | |
1de0a072 | 1479 | // delta-rays by electrons |
1480 | // G4 particles: "e-" | |
1481 | // G3 default value: 10**4 GeV | |
cbc3a17e | 1482 | // gMC ->SetCut("DCUTE",cut); // cut for deltarays by electrons ??????????????? |
1de0a072 | 1483 | else if (strncmp(&sCutFlag[i][0],"DCUTE",5) == 0) { |
861d858d | 1484 | fprintf(pAliceInp,"*\n*Cut for delta rays by electrons ????????????\n"); |
1485 | fprintf(pAliceInp,"*Generated from call: SetCut('DCUTE',cut);\n"); | |
1486 | // -fCutValue[i]; | |
1487 | // zero = ignored | |
1488 | // zero = ignored | |
1489 | // three = lower bound of the material indices in which the respective thresholds apply | |
1490 | // fLastMaterial = upper bound of the material indices in which the respective thresholds apply | |
e749c124 | 1491 | fprintf(pAliceInp,"EMFCUT %10.4g%10.1f%10.1f%10.1f%10.1f\n",-fCutValue[i],zero,zero,three,fLastMaterial); |
1de0a072 | 1492 | } |
1493 | ||
cbc3a17e | 1494 | // |
1de0a072 | 1495 | // time of flight cut in seconds |
1496 | // G4 particles: all | |
1497 | // G3 default value: 0.01 GeV | |
1498 | //gMC ->SetCut("TOFMAX",tofmax); // time of flight cuts in seconds | |
1499 | else if (strncmp(&sCutFlag[i][0],"TOFMAX",6) == 0) { | |
861d858d | 1500 | fprintf(pAliceInp,"*\n*Time of flight cuts in seconds\n"); |
1501 | fprintf(pAliceInp,"*Generated from call: SetCut('TOFMAX',tofmax);\n"); | |
1502 | // zero = ignored | |
1503 | // zero = ignored | |
1504 | // -6.0 = lower bound of the particle numbers for which the transport time cut-off and/or the start signal is to be applied | |
1505 | // 64.0 = upper bound of the particle numbers for which the transport time cut-off and/or the start signal is to be applied | |
e749c124 | 1506 | fprintf(pAliceInp,"TIME-CUT %10.4g%10.1f%10.1f%10.1f%10.1f\n",fCutValue[i]*1.e9,zero,zero,-6.0,64.0); |
1de0a072 | 1507 | } |
1508 | ||
1509 | else { | |
1510 | cout << "SetCut for flag=" << &sCutFlag[i][0] << " value=" << fCutValue[i] << " not yet implemented!" << endl; | |
1511 | } | |
e749c124 | 1512 | } //end of loop over SetCut calls |
1de0a072 | 1513 | |
1514 | // Add START and STOP card | |
e749c124 | 1515 | fprintf(pAliceInp,"START %10.1f\n",fEventsPerRun); |
861d858d | 1516 | fprintf(pAliceInp,"STOP \n"); |
1de0a072 | 1517 | |
6364fb0a | 1518 | } // end of InitPhysics |
1de0a072 | 1519 | |
cbc3a17e | 1520 | |
bc021b12 | 1521 | void TFluka::SetMaxStep(Double_t) |
1522 | { | |
1523 | // SetMaxStep is dummy procedure in TFluka ! | |
fee5ea25 | 1524 | if (fVerbosityLevel >=3) |
bc021b12 | 1525 | cout << "SetMaxStep is dummy procedure in TFluka !" << endl; |
1526 | } | |
1527 | ||
1528 | void TFluka::SetMaxNStep(Int_t) | |
1529 | { | |
1530 | // SetMaxNStep is dummy procedure in TFluka ! | |
fee5ea25 | 1531 | if (fVerbosityLevel >=3) |
bc021b12 | 1532 | cout << "SetMaxNStep is dummy procedure in TFluka !" << endl; |
1533 | } | |
1534 | ||
1535 | void TFluka::SetUserDecay(Int_t) | |
1536 | { | |
1537 | // SetUserDecay is dummy procedure in TFluka ! | |
fee5ea25 | 1538 | if (fVerbosityLevel >=3) |
bc021b12 | 1539 | cout << "SetUserDecay is dummy procedure in TFluka !" << endl; |
1540 | } | |
1541 | ||
fa3d1cc7 | 1542 | // |
1543 | // dynamic properties | |
1544 | // | |
1545 | void TFluka::TrackPosition(TLorentzVector& position) const | |
1546 | { | |
1547 | // Return the current position in the master reference frame of the | |
1548 | // track being transported | |
1549 | // TRACKR.atrack = age of the particle | |
1550 | // TRACKR.xtrack = x-position of the last point | |
1551 | // TRACKR.ytrack = y-position of the last point | |
1552 | // TRACKR.ztrack = z-position of the last point | |
1de0a072 | 1553 | Int_t caller = GetCaller(); |
fbf08100 | 1554 | if (caller == 3 || caller == 6 || caller == 11 || caller == 12) { //bxdraw,endraw,usdraw |
1de0a072 | 1555 | position.SetX(GetXsco()); |
1556 | position.SetY(GetYsco()); | |
1557 | position.SetZ(GetZsco()); | |
1558 | position.SetT(TRACKR.atrack); | |
1559 | } | |
1560 | else if (caller == 4) { // mgdraw | |
1561 | position.SetX(TRACKR.xtrack[TRACKR.ntrack]); | |
1562 | position.SetY(TRACKR.ytrack[TRACKR.ntrack]); | |
1563 | position.SetZ(TRACKR.ztrack[TRACKR.ntrack]); | |
1564 | position.SetT(TRACKR.atrack); | |
1565 | } | |
1566 | else if (caller == 5) { // sodraw | |
1567 | position.SetX(TRACKR.xtrack[TRACKR.ntrack]); | |
1568 | position.SetY(TRACKR.ytrack[TRACKR.ntrack]); | |
1569 | position.SetZ(TRACKR.ztrack[TRACKR.ntrack]); | |
1570 | position.SetT(0); | |
1571 | } | |
1572 | else | |
1573 | Warning("TrackPosition","position not available"); | |
1574 | } | |
24969d13 | 1575 | |
1de0a072 | 1576 | // |
1577 | void TFluka::TrackPosition(Double_t& x, Double_t& y, Double_t& z) const | |
1578 | { | |
1579 | // Return the current position in the master reference frame of the | |
1580 | // track being transported | |
1581 | // TRACKR.atrack = age of the particle | |
1582 | // TRACKR.xtrack = x-position of the last point | |
1583 | // TRACKR.ytrack = y-position of the last point | |
1584 | // TRACKR.ztrack = z-position of the last point | |
1585 | Int_t caller = GetCaller(); | |
fbf08100 | 1586 | if (caller == 3 || caller == 6 || caller == 11 || caller == 12) { //bxdraw,endraw,usdraw |
1de0a072 | 1587 | x = GetXsco(); |
1588 | y = GetYsco(); | |
1589 | z = GetZsco(); | |
1590 | } | |
e8f0734b | 1591 | else if (caller == 4 || caller == 5) { // mgdraw, sodraw |
1de0a072 | 1592 | x = TRACKR.xtrack[TRACKR.ntrack]; |
1593 | y = TRACKR.ytrack[TRACKR.ntrack]; | |
1594 | z = TRACKR.ztrack[TRACKR.ntrack]; | |
1595 | } | |
1596 | else | |
1597 | Warning("TrackPosition","position not available"); | |
fa3d1cc7 | 1598 | } |
1599 | ||
1600 | void TFluka::TrackMomentum(TLorentzVector& momentum) const | |
1601 | { | |
1602 | // Return the direction and the momentum (GeV/c) of the track | |
1603 | // currently being transported | |
1604 | // TRACKR.ptrack = momentum of the particle (not always defined, if | |
1605 | // < 0 must be obtained from etrack) | |
1606 | // TRACKR.cx,y,ztrck = direction cosines of the current particle | |
1607 | // TRACKR.etrack = total energy of the particle | |
1608 | // TRACKR.jtrack = identity number of the particle | |
1609 | // PAPROP.am[TRACKR.jtrack] = particle mass in gev | |
1de0a072 | 1610 | Int_t caller = GetCaller(); |
1611 | if (caller != 2) { // not eedraw | |
1612 | if (TRACKR.ptrack >= 0) { | |
1613 | momentum.SetPx(TRACKR.ptrack*TRACKR.cxtrck); | |
1614 | momentum.SetPy(TRACKR.ptrack*TRACKR.cytrck); | |
1615 | momentum.SetPz(TRACKR.ptrack*TRACKR.cztrck); | |
1616 | momentum.SetE(TRACKR.etrack); | |
1617 | return; | |
1618 | } | |
1619 | else { | |
1620 | Double_t p = sqrt(TRACKR.etrack*TRACKR.etrack - PAPROP.am[TRACKR.jtrack+6]*PAPROP.am[TRACKR.jtrack+6]); | |
1621 | momentum.SetPx(p*TRACKR.cxtrck); | |
1622 | momentum.SetPy(p*TRACKR.cytrck); | |
1623 | momentum.SetPz(p*TRACKR.cztrck); | |
1624 | momentum.SetE(TRACKR.etrack); | |
1625 | return; | |
1626 | } | |
fa3d1cc7 | 1627 | } |
1de0a072 | 1628 | else |
1629 | Warning("TrackMomentum","momentum not available"); | |
1630 | } | |
1631 | ||
1632 | void TFluka::TrackMomentum(Double_t& px, Double_t& py, Double_t& pz, Double_t& e) const | |
1633 | { | |
1634 | // Return the direction and the momentum (GeV/c) of the track | |
1635 | // currently being transported | |
1636 | // TRACKR.ptrack = momentum of the particle (not always defined, if | |
1637 | // < 0 must be obtained from etrack) | |
1638 | // TRACKR.cx,y,ztrck = direction cosines of the current particle | |
1639 | // TRACKR.etrack = total energy of the particle | |
1640 | // TRACKR.jtrack = identity number of the particle | |
1641 | // PAPROP.am[TRACKR.jtrack] = particle mass in gev | |
1642 | Int_t caller = GetCaller(); | |
1643 | if (caller != 2) { // not eedraw | |
1644 | if (TRACKR.ptrack >= 0) { | |
1645 | px = TRACKR.ptrack*TRACKR.cxtrck; | |
1646 | py = TRACKR.ptrack*TRACKR.cytrck; | |
1647 | pz = TRACKR.ptrack*TRACKR.cztrck; | |
1648 | e = TRACKR.etrack; | |
1649 | return; | |
1650 | } | |
1651 | else { | |
1652 | Double_t p = sqrt(TRACKR.etrack*TRACKR.etrack - PAPROP.am[TRACKR.jtrack+6]*PAPROP.am[TRACKR.jtrack+6]); | |
1653 | px = p*TRACKR.cxtrck; | |
1654 | py = p*TRACKR.cytrck; | |
1655 | pz = p*TRACKR.cztrck; | |
1656 | e = TRACKR.etrack; | |
1657 | return; | |
1658 | } | |
fa3d1cc7 | 1659 | } |
1de0a072 | 1660 | else |
1661 | Warning("TrackMomentum","momentum not available"); | |
fa3d1cc7 | 1662 | } |
1663 | ||
1664 | Double_t TFluka::TrackStep() const | |
1665 | { | |
1666 | // Return the length in centimeters of the current step | |
1667 | // TRACKR.ctrack = total curved path | |
1de0a072 | 1668 | Int_t caller = GetCaller(); |
fbf08100 | 1669 | if (caller == 11 || caller==12 || caller == 3 || caller == 6) //bxdraw,endraw,usdraw |
1de0a072 | 1670 | return 0.0; |
1671 | else if (caller == 4) //mgdraw | |
fa3d1cc7 | 1672 | return TRACKR.ctrack; |
1de0a072 | 1673 | else |
1674 | return -1.0; | |
fa3d1cc7 | 1675 | } |
1676 | ||
1677 | Double_t TFluka::TrackLength() const | |
1678 | { | |
5929ad29 | 1679 | // TRACKR.cmtrck = cumulative curved path since particle birth |
1de0a072 | 1680 | Int_t caller = GetCaller(); |
e8f0734b | 1681 | if (caller == 11 || caller==12 || caller == 3 || caller == 4 || caller == 6) //bxdraw,endraw,mgdraw,usdraw |
5929ad29 | 1682 | return TRACKR.cmtrck; |
1de0a072 | 1683 | else |
1684 | return -1.0; | |
fa3d1cc7 | 1685 | } |
1686 | ||
1687 | Double_t TFluka::TrackTime() const | |
1688 | { | |
1689 | // Return the current time of flight of the track being transported | |
1690 | // TRACKR.atrack = age of the particle | |
1de0a072 | 1691 | Int_t caller = GetCaller(); |
fbf08100 | 1692 | if (caller == 11 || caller==12 || caller == 3 || caller == 4 || caller == 6) //bxdraw,endraw,mgdraw,usdraw |
1de0a072 | 1693 | return TRACKR.atrack; |
1694 | else | |
1695 | return -1; | |
fa3d1cc7 | 1696 | } |
1697 | ||
1698 | Double_t TFluka::Edep() const | |
1699 | { | |
1700 | // Energy deposition | |
1701 | // if TRACKR.ntrack = 0, TRACKR.mtrack = 0: | |
1702 | // -->local energy deposition (the value and the point are not recorded in TRACKR) | |
1703 | // but in the variable "rull" of the procedure "endraw.cxx" | |
1704 | // if TRACKR.ntrack > 0, TRACKR.mtrack = 0: | |
1705 | // -->no energy loss along the track | |
1706 | // if TRACKR.ntrack > 0, TRACKR.mtrack > 0: | |
1707 | // -->energy loss distributed along the track | |
1708 | // TRACKR.dtrack = energy deposition of the jth deposition even | |
fbf08100 | 1709 | |
1710 | // If coming from bxdraw we have 2 steps of 0 length and 0 edep | |
1711 | Int_t caller = GetCaller(); | |
1712 | if (caller == 11 || caller==12) return 0.0; | |
1de0a072 | 1713 | Double_t sum = 0; |
1714 | for ( Int_t j=0;j<TRACKR.mtrack;j++) { | |
1715 | sum +=TRACKR.dtrack[j]; | |
1716 | } | |
fa3d1cc7 | 1717 | if (TRACKR.ntrack == 0 && TRACKR.mtrack == 0) |
1de0a072 | 1718 | return fRull + sum; |
fa3d1cc7 | 1719 | else { |
fa3d1cc7 | 1720 | return sum; |
1721 | } | |
1722 | } | |
1723 | ||
1724 | Int_t TFluka::TrackPid() const | |
1725 | { | |
1726 | // Return the id of the particle transported | |
1727 | // TRACKR.jtrack = identity number of the particle | |
1de0a072 | 1728 | Int_t caller = GetCaller(); |
1729 | if (caller != 2) // not eedraw | |
1730 | return PDGFromId(TRACKR.jtrack); | |
1731 | else | |
1732 | return -1000; | |
fa3d1cc7 | 1733 | } |
1734 | ||
1735 | Double_t TFluka::TrackCharge() const | |
1736 | { | |
1737 | // Return charge of the track currently transported | |
1738 | // PAPROP.ichrge = electric charge of the particle | |
bc021b12 | 1739 | // TRACKR.jtrack = identity number of the particle |
1de0a072 | 1740 | Int_t caller = GetCaller(); |
1741 | if (caller != 2) // not eedraw | |
1742 | return PAPROP.ichrge[TRACKR.jtrack+6]; | |
1743 | else | |
1744 | return -1000.0; | |
fa3d1cc7 | 1745 | } |
1746 | ||
1747 | Double_t TFluka::TrackMass() const | |
1748 | { | |
1749 | // PAPROP.am = particle mass in GeV | |
bc021b12 | 1750 | // TRACKR.jtrack = identity number of the particle |
1de0a072 | 1751 | Int_t caller = GetCaller(); |
0c160c74 | 1752 | if (caller != 2) { // not eedraw |
1753 | // cout << "JTRACK=" << TRACKR.jtrack << " mass=" << PAPROP.am[TRACKR.jtrack+6] << endl; | |
1de0a072 | 1754 | return PAPROP.am[TRACKR.jtrack+6]; |
0c160c74 | 1755 | } |
1de0a072 | 1756 | else |
1757 | return -1000.0; | |
fa3d1cc7 | 1758 | } |
1759 | ||
1760 | Double_t TFluka::Etot() const | |
1761 | { | |
1762 | // TRACKR.etrack = total energy of the particle | |
1de0a072 | 1763 | Int_t caller = GetCaller(); |
1764 | if (caller != 2) // not eedraw | |
1765 | return TRACKR.etrack; | |
1766 | else | |
1767 | return -1000.0; | |
fa3d1cc7 | 1768 | } |
1769 | ||
1770 | // | |
1771 | // track status | |
1772 | // | |
1773 | Bool_t TFluka::IsNewTrack() const | |
1774 | { | |
fbf08100 | 1775 | // Return true for the first call of Stepping() |
fbf08100 | 1776 | return fTrackIsNew; |
fa3d1cc7 | 1777 | } |
1778 | ||
1779 | Bool_t TFluka::IsTrackInside() const | |
1780 | { | |
1781 | // True if the track is not at the boundary of the current volume | |
1782 | // In Fluka a step is always inside one kind of material | |
1783 | // If the step would go behind the region of one material, | |
1784 | // it will be shortened to reach only the boundary. | |
1785 | // Therefore IsTrackInside() is always true. | |
1de0a072 | 1786 | Int_t caller = GetCaller(); |
fbf08100 | 1787 | if (caller == 11 || caller==12) // bxdraw |
1de0a072 | 1788 | return 0; |
1789 | else | |
1790 | return 1; | |
fa3d1cc7 | 1791 | } |
1792 | ||
1793 | Bool_t TFluka::IsTrackEntering() const | |
1794 | { | |
1795 | // True if this is the first step of the track in the current volume | |
cbc3a17e | 1796 | |
1de0a072 | 1797 | Int_t caller = GetCaller(); |
12d57e74 | 1798 | if (caller == 11) // bxdraw entering |
1de0a072 | 1799 | return 1; |
fa3d1cc7 | 1800 | else return 0; |
1801 | } | |
1802 | ||
1803 | Bool_t TFluka::IsTrackExiting() const | |
1804 | { | |
1de0a072 | 1805 | Int_t caller = GetCaller(); |
1806 | if (caller == 12) // bxdraw exiting | |
1807 | return 1; | |
fa3d1cc7 | 1808 | else return 0; |
1809 | } | |
1810 | ||
1811 | Bool_t TFluka::IsTrackOut() const | |
1812 | { | |
1813 | // True if the track is out of the setup | |
1814 | // means escape | |
1815 | // Icode = 14: escape - call from Kaskad | |
1816 | // Icode = 23: escape - call from Emfsco | |
1817 | // Icode = 32: escape - call from Kasneu | |
1818 | // Icode = 40: escape - call from Kashea | |
1819 | // Icode = 51: escape - call from Kasoph | |
70541a80 | 1820 | if (fIcode == 14 || |
1821 | fIcode == 23 || | |
1822 | fIcode == 32 || | |
1823 | fIcode == 40 || | |
1824 | fIcode == 51) return 1; | |
fa3d1cc7 | 1825 | else return 0; |
1826 | } | |
1827 | ||
1828 | Bool_t TFluka::IsTrackDisappeared() const | |
1829 | { | |
1830 | // means all inelastic interactions and decays | |
70541a80 | 1831 | // fIcode from usdraw |
1832 | if (fIcode == 101 || // inelastic interaction | |
1833 | fIcode == 102 || // particle decay | |
1834 | fIcode == 214 || // in-flight annihilation | |
1835 | fIcode == 215 || // annihilation at rest | |
1836 | fIcode == 217 || // pair production | |
1837 | fIcode == 221) return 1; | |
fa3d1cc7 | 1838 | else return 0; |
1839 | } | |
1840 | ||
1841 | Bool_t TFluka::IsTrackStop() const | |
1842 | { | |
1843 | // True if the track energy has fallen below the threshold | |
1844 | // means stopped by signal or below energy threshold | |
1845 | // Icode = 12: stopping particle - call from Kaskad | |
1846 | // Icode = 15: time kill - call from Kaskad | |
1847 | // Icode = 21: below threshold, iarg=1 - call from Emfsco | |
1848 | // Icode = 22: below threshold, iarg=2 - call from Emfsco | |
1849 | // Icode = 24: time kill - call from Emfsco | |
1850 | // Icode = 31: below threshold - call from Kasneu | |
1851 | // Icode = 33: time kill - call from Kasneu | |
1852 | // Icode = 41: time kill - call from Kashea | |
1853 | // Icode = 52: time kill - call from Kasoph | |
70541a80 | 1854 | if (fIcode == 12 || |
1855 | fIcode == 15 || | |
1856 | fIcode == 21 || | |
1857 | fIcode == 22 || | |
1858 | fIcode == 24 || | |
1859 | fIcode == 31 || | |
1860 | fIcode == 33 || | |
1861 | fIcode == 41 || | |
1862 | fIcode == 52) return 1; | |
fa3d1cc7 | 1863 | else return 0; |
1864 | } | |
1865 | ||
1866 | Bool_t TFluka::IsTrackAlive() const | |
1867 | { | |
1868 | // means not disappeared or not out | |
1869 | if (IsTrackDisappeared() || IsTrackOut() ) return 0; | |
1870 | else return 1; | |
1871 | } | |
1872 | ||
1873 | // | |
1874 | // secondaries | |
1875 | // | |
1876 | ||
1877 | Int_t TFluka::NSecondaries() const | |
1878 | // Number of secondary particles generated in the current step | |
bc021b12 | 1879 | // FINUC.np = number of secondaries except light and heavy ions |
b8b430a9 | 1880 | // FHEAVY.npheav = number of secondaries for light and heavy secondary ions |
fa3d1cc7 | 1881 | { |
1de0a072 | 1882 | Int_t caller = GetCaller(); |
1883 | if (caller == 6) // valid only after usdraw | |
1884 | return FINUC.np + FHEAVY.npheav; | |
1885 | else | |
1886 | return 0; | |
1887 | } // end of NSecondaries | |
fa3d1cc7 | 1888 | |
1889 | void TFluka::GetSecondary(Int_t isec, Int_t& particleId, | |
1890 | TLorentzVector& position, TLorentzVector& momentum) | |
fa3d1cc7 | 1891 | { |
1de0a072 | 1892 | Int_t caller = GetCaller(); |
1893 | if (caller == 6) { // valid only after usdraw | |
1894 | if (isec >= 0 && isec < FINUC.np) { | |
1895 | particleId = PDGFromId(FINUC.kpart[isec]); | |
1896 | position.SetX(fXsco); | |
1897 | position.SetY(fYsco); | |
1898 | position.SetZ(fZsco); | |
1899 | position.SetT(TRACKR.atrack); | |
1de0a072 | 1900 | momentum.SetPx(FINUC.plr[isec]*FINUC.cxr[isec]); |
1901 | momentum.SetPy(FINUC.plr[isec]*FINUC.cyr[isec]); | |
1902 | momentum.SetPz(FINUC.plr[isec]*FINUC.czr[isec]); | |
1903 | momentum.SetE(FINUC.tki[isec] + PAPROP.am[FINUC.kpart[isec]+6]); | |
bc021b12 | 1904 | } |
1de0a072 | 1905 | else if (isec >= FINUC.np && isec < FINUC.np + FHEAVY.npheav) { |
1906 | Int_t jsec = isec - FINUC.np; | |
1907 | particleId = FHEAVY.kheavy[jsec]; // this is Fluka id !!! | |
1908 | position.SetX(fXsco); | |
1909 | position.SetY(fYsco); | |
1910 | position.SetZ(fZsco); | |
1911 | position.SetT(TRACKR.atrack); | |
1de0a072 | 1912 | momentum.SetPx(FHEAVY.pheavy[jsec]*FHEAVY.cxheav[jsec]); |
1913 | momentum.SetPy(FHEAVY.pheavy[jsec]*FHEAVY.cyheav[jsec]); | |
1914 | momentum.SetPz(FHEAVY.pheavy[jsec]*FHEAVY.czheav[jsec]); | |
1915 | if (FHEAVY.tkheav[jsec] >= 3 && FHEAVY.tkheav[jsec] <= 6) | |
1916 | momentum.SetE(FHEAVY.tkheav[jsec] + PAPROP.am[jsec+6]); | |
1917 | else if (FHEAVY.tkheav[jsec] > 6) | |
1918 | momentum.SetE(FHEAVY.tkheav[jsec] + FHEAVY.amnhea[jsec]); // to be checked !!! | |
1919 | } | |
1920 | else | |
1921 | Warning("GetSecondary","isec out of range"); | |
1922 | } | |
1923 | else | |
1924 | Warning("GetSecondary","no secondaries available"); | |
1925 | } // end of GetSecondary | |
fa3d1cc7 | 1926 | |
adbc5ae1 | 1927 | TMCProcess TFluka::ProdProcess(Int_t) const |
fa3d1cc7 | 1928 | // Name of the process that has produced the secondary particles |
1929 | // in the current step | |
bc021b12 | 1930 | { |
1de0a072 | 1931 | const TMCProcess kIpNoProc = kPNoProcess; |
1932 | const TMCProcess kIpPDecay = kPDecay; | |
1933 | const TMCProcess kIpPPair = kPPair; | |
1934 | // const TMCProcess kIpPPairFromPhoton = kPPairFromPhoton; | |
1935 | // const TMCProcess kIpPPairFromVirtualPhoton = kPPairFromVirtualPhoton; | |
1936 | const TMCProcess kIpPCompton = kPCompton; | |
1937 | const TMCProcess kIpPPhotoelectric = kPPhotoelectric; | |
1938 | const TMCProcess kIpPBrem = kPBrem; | |
1939 | // const TMCProcess kIpPBremFromHeavy = kPBremFromHeavy; | |
1940 | // const TMCProcess kIpPBremFromElectronOrPositron = kPBremFromElectronOrPositron; | |
1941 | const TMCProcess kIpPDeltaRay = kPDeltaRay; | |
1942 | // const TMCProcess kIpPMoller = kPMoller; | |
1943 | // const TMCProcess kIpPBhabha = kPBhabha; | |
1944 | const TMCProcess kIpPAnnihilation = kPAnnihilation; | |
1945 | // const TMCProcess kIpPAnnihilInFlight = kPAnnihilInFlight; | |
1946 | // const TMCProcess kIpPAnnihilAtRest = kPAnnihilAtRest; | |
1947 | const TMCProcess kIpPHadronic = kPHadronic; | |
1948 | const TMCProcess kIpPMuonNuclear = kPMuonNuclear; | |
1949 | const TMCProcess kIpPPhotoFission = kPPhotoFission; | |
1950 | const TMCProcess kIpPRayleigh = kPRayleigh; | |
b0d8df96 | 1951 | // const TMCProcess kIpPCerenkov = kPCerenkov; |
1952 | // const TMCProcess kIpPSynchrotron = kPSynchrotron; | |
bc021b12 | 1953 | |
1de0a072 | 1954 | Int_t mugamma = TRACKR.jtrack == 7 || TRACKR.jtrack == 10 || TRACKR.jtrack == 11; |
70541a80 | 1955 | if (fIcode == 102) return kIpPDecay; |
1956 | else if (fIcode == 104 || fIcode == 217) return kIpPPair; | |
1957 | // else if (fIcode == 104) return kIpPairFromPhoton; | |
1958 | // else if (fIcode == 217) return kIpPPairFromVirtualPhoton; | |
1959 | else if (fIcode == 219) return kIpPCompton; | |
1960 | else if (fIcode == 221) return kIpPPhotoelectric; | |
1961 | else if (fIcode == 105 || fIcode == 208) return kIpPBrem; | |
1962 | // else if (fIcode == 105) return kIpPBremFromHeavy; | |
1963 | // else if (fIcode == 208) return kPBremFromElectronOrPositron; | |
1964 | else if (fIcode == 103 || fIcode == 400) return kIpPDeltaRay; | |
1965 | else if (fIcode == 210 || fIcode == 212) return kIpPDeltaRay; | |
1966 | // else if (fIcode == 210) return kIpPMoller; | |
1967 | // else if (fIcode == 212) return kIpPBhabha; | |
1968 | else if (fIcode == 214 || fIcode == 215) return kIpPAnnihilation; | |
1969 | // else if (fIcode == 214) return kIpPAnnihilInFlight; | |
1970 | // else if (fIcode == 215) return kIpPAnnihilAtRest; | |
1971 | else if (fIcode == 101) return kIpPHadronic; | |
1972 | else if (fIcode == 101) { | |
1de0a072 | 1973 | if (!mugamma) return kIpPHadronic; |
1974 | else if (TRACKR.jtrack == 7) return kIpPPhotoFission; | |
1975 | else return kIpPMuonNuclear; | |
1976 | } | |
70541a80 | 1977 | else if (fIcode == 225) return kIpPRayleigh; |
bc021b12 | 1978 | // Fluka codes 100, 300 and 400 still to be investigasted |
1de0a072 | 1979 | else return kIpNoProc; |
bc021b12 | 1980 | } |
fa3d1cc7 | 1981 | |
1982 | //Int_t StepProcesses(TArrayI &proc) const | |
1983 | // Return processes active in the current step | |
1984 | //{ | |
1985 | //ck = total energy of the particl ???????????????? | |
1986 | //} | |
1987 | ||
1988 | ||
b0d8df96 | 1989 | Int_t TFluka::VolId2Mate(Int_t id) const |
1990 | { | |
1991 | // | |
1992 | // Returns the material number for a given volume ID | |
1993 | // | |
fee5ea25 | 1994 | if (fVerbosityLevel >= 3) |
12d57e74 | 1995 | printf("VolId2Mate %d %d\n", id, fMediaByRegion[id-1]); |
b0d8df96 | 1996 | return fMediaByRegion[id-1]; |
1997 | } | |
1998 | ||
1999 | const char* TFluka::VolName(Int_t id) const | |
2000 | { | |
2001 | // | |
2002 | // Returns the volume name for a given volume ID | |
2003 | // | |
2004 | FlukaVolume* vol = dynamic_cast<FlukaVolume*>((*fVolumeMediaMap)[id-1]); | |
2005 | const char* name = vol->GetName(); | |
fee5ea25 | 2006 | if (fVerbosityLevel >= 3) |
b0d8df96 | 2007 | printf("VolName %d %s \n", id, name); |
2008 | return name; | |
2009 | } | |
2010 | ||
2011 | Int_t TFluka::VolId(const Text_t* volName) const | |
2012 | { | |
2013 | // | |
2014 | // Converts from volume name to volume ID. | |
2015 | // Time consuming. (Only used during set-up) | |
2016 | // Could be replaced by hash-table | |
2017 | // | |
2018 | char tmp[5]; | |
2019 | Int_t i =0; | |
2020 | for (i = 0; i < fNVolumes; i++) | |
2021 | { | |
2022 | FlukaVolume* vol = dynamic_cast<FlukaVolume*>((*fVolumeMediaMap)[i]); | |
2023 | TString name = vol->GetName(); | |
2024 | strcpy(tmp, name.Data()); | |
2025 | tmp[4] = '\0'; | |
2026 | if (!strcmp(tmp, volName)) break; | |
2027 | } | |
2028 | i++; | |
2029 | ||
2030 | return i; | |
2031 | } | |
2032 | ||
2033 | ||
2034 | Int_t TFluka::CurrentVolID(Int_t& copyNo) const | |
2035 | { | |
2036 | // | |
2037 | // Return the logical id and copy number corresponding to the current fluka region | |
2038 | // | |
2039 | int ir = fCurrentFlukaRegion; | |
2040 | int id = (FGeometryInit::GetInstance())->CurrentVolID(ir, copyNo); | |
12d57e74 | 2041 | copyNo++; |
fee5ea25 | 2042 | if (fVerbosityLevel >= 3) |
b0d8df96 | 2043 | printf("CurrentVolID: %d %d %d \n", ir, id, copyNo); |
2044 | return id; | |
b0d8df96 | 2045 | } |
2046 | ||
2047 | Int_t TFluka::CurrentVolOffID(Int_t off, Int_t& copyNo) const | |
2048 | { | |
2049 | // | |
2050 | // Return the logical id and copy number of off'th mother | |
2051 | // corresponding to the current fluka region | |
2052 | // | |
2053 | if (off == 0) | |
2054 | return CurrentVolID(copyNo); | |
2055 | ||
2056 | int ir = fCurrentFlukaRegion; | |
2057 | int id = (FGeometryInit::GetInstance())->CurrentVolOffID(ir, off, copyNo); | |
12d57e74 | 2058 | copyNo++; |
fee5ea25 | 2059 | if (fVerbosityLevel >= 3) |
b0d8df96 | 2060 | printf("CurrentVolOffID: %d %d %d \n", ir, id, copyNo); |
2061 | if (id == -1) | |
fee5ea25 | 2062 | if (fVerbosityLevel >= 0) |
b0d8df96 | 2063 | printf("CurrentVolOffID: Warning Mother not found !!!\n"); |
2064 | return id; | |
2065 | } | |
2066 | ||
2067 | ||
2068 | const char* TFluka::CurrentVolName() const | |
2069 | { | |
2070 | // | |
2071 | // Return the current volume name | |
2072 | // | |
2073 | Int_t copy; | |
2074 | Int_t id = TFluka::CurrentVolID(copy); | |
2075 | const char* name = TFluka::VolName(id); | |
fee5ea25 | 2076 | if (fVerbosityLevel >= 3) |
b0d8df96 | 2077 | printf("CurrentVolumeName: %d %s \n", fCurrentFlukaRegion, name); |
2078 | return name; | |
2079 | } | |
2080 | ||
2081 | const char* TFluka::CurrentVolOffName(Int_t off) const | |
2082 | { | |
2083 | // | |
2084 | // Return the volume name of the off'th mother of the current volume | |
2085 | // | |
2086 | Int_t copy; | |
2087 | Int_t id = TFluka::CurrentVolOffID(off, copy); | |
2088 | const char* name = TFluka::VolName(id); | |
fee5ea25 | 2089 | if (fVerbosityLevel >= 3) |
b0d8df96 | 2090 | printf("CurrentVolumeOffName: %d %s \n", fCurrentFlukaRegion, name); |
2091 | return name; | |
2092 | } | |
2093 | ||
0c160c74 | 2094 | Int_t TFluka::CurrentMaterial(Float_t & /*a*/, Float_t & /*z*/, |
2095 | Float_t & /*dens*/, Float_t & /*radl*/, Float_t & /*absl*/) const | |
b0d8df96 | 2096 | { |
2097 | // | |
2098 | // Return the current medium number | |
2099 | // | |
2100 | Int_t copy; | |
2101 | Int_t id = TFluka::CurrentVolID(copy); | |
2102 | Int_t med = TFluka::VolId2Mate(id); | |
fee5ea25 | 2103 | if (fVerbosityLevel >= 3) |
b0d8df96 | 2104 | printf("CurrentMaterial: %d %d \n", fCurrentFlukaRegion, med); |
2105 | return med; | |
2106 | } | |
2107 | ||
dc37cac6 | 2108 | void TFluka::Gmtod(Float_t* xm, Float_t* xd, Int_t iflag) |
2109 | { | |
2110 | // Transforms a position from the world reference frame | |
2111 | // to the current volume reference frame. | |
2112 | // | |
2113 | // Geant3 desription: | |
2114 | // ================== | |
2115 | // Computes coordinates XD (in DRS) | |
2116 | // from known coordinates XM in MRS | |
2117 | // The local reference system can be initialized by | |
2118 | // - the tracking routines and GMTOD used in GUSTEP | |
2119 | // - a call to GMEDIA(XM,NUMED) | |
2120 | // - a call to GLVOLU(NLEVEL,NAMES,NUMBER,IER) | |
2121 | // (inverse routine is GDTOM) | |
2122 | // | |
2123 | // If IFLAG=1 convert coordinates | |
2124 | // IFLAG=2 convert direction cosinus | |
2125 | // | |
2126 | // --- | |
2127 | Double_t xmD[3], xdD[3]; | |
2128 | xmD[0] = xm[0]; xmD[1] = xm[1]; xmD[2] = xm[2]; | |
2129 | (FGeometryInit::GetInstance())->Gmtod(xmD, xdD, iflag); | |
2130 | xd[0] = xdD[0]; xd[1] = xdD[1]; xd[2] = xdD[2]; | |
2131 | } | |
2132 | ||
2133 | ||
2134 | void TFluka::Gmtod(Double_t* xm, Double_t* xd, Int_t iflag) | |
2135 | { | |
2136 | // Transforms a position from the world reference frame | |
2137 | // to the current volume reference frame. | |
2138 | // | |
2139 | // Geant3 desription: | |
2140 | // ================== | |
2141 | // Computes coordinates XD (in DRS) | |
2142 | // from known coordinates XM in MRS | |
2143 | // The local reference system can be initialized by | |
2144 | // - the tracking routines and GMTOD used in GUSTEP | |
2145 | // - a call to GMEDIA(XM,NUMED) | |
2146 | // - a call to GLVOLU(NLEVEL,NAMES,NUMBER,IER) | |
2147 | // (inverse routine is GDTOM) | |
2148 | // | |
2149 | // If IFLAG=1 convert coordinates | |
2150 | // IFLAG=2 convert direction cosinus | |
2151 | // | |
2152 | // --- | |
72f84f29 | 2153 | (FGeometryInit::GetInstance())->Gmtod(xm, xd, iflag); |
dc37cac6 | 2154 | } |
2155 | ||
2156 | void TFluka::Gdtom(Float_t* xd, Float_t* xm, Int_t iflag) | |
2157 | { | |
2158 | // Transforms a position from the current volume reference frame | |
2159 | // to the world reference frame. | |
2160 | // | |
2161 | // Geant3 desription: | |
2162 | // ================== | |
2163 | // Computes coordinates XM (Master Reference System | |
2164 | // knowing the coordinates XD (Detector Ref System) | |
2165 | // The local reference system can be initialized by | |
2166 | // - the tracking routines and GDTOM used in GUSTEP | |
2167 | // - a call to GSCMED(NLEVEL,NAMES,NUMBER) | |
2168 | // (inverse routine is GMTOD) | |
2169 | // | |
2170 | // If IFLAG=1 convert coordinates | |
2171 | // IFLAG=2 convert direction cosinus | |
2172 | // | |
2173 | // --- | |
72f84f29 | 2174 | Double_t xmD[3], xdD[3]; |
2175 | xdD[0] = xd[0]; xdD[1] = xd[1]; xdD[2] = xd[2]; | |
2176 | (FGeometryInit::GetInstance())->Gdtom(xdD, xmD, iflag); | |
2177 | xm[0] = xmD[0]; xm[1] = xmD[1]; xm[2] = xmD[2]; | |
dc37cac6 | 2178 | } |
2179 | void TFluka::Gdtom(Double_t* xd, Double_t* xm, Int_t iflag) | |
2180 | { | |
2181 | // Transforms a position from the current volume reference frame | |
2182 | // to the world reference frame. | |
2183 | // | |
2184 | // Geant3 desription: | |
2185 | // ================== | |
2186 | // Computes coordinates XM (Master Reference System | |
2187 | // knowing the coordinates XD (Detector Ref System) | |
2188 | // The local reference system can be initialized by | |
2189 | // - the tracking routines and GDTOM used in GUSTEP | |
2190 | // - a call to GSCMED(NLEVEL,NAMES,NUMBER) | |
2191 | // (inverse routine is GMTOD) | |
2192 | // | |
2193 | // If IFLAG=1 convert coordinates | |
2194 | // IFLAG=2 convert direction cosinus | |
2195 | // | |
2196 | // --- | |
2197 | ||
72f84f29 | 2198 | (FGeometryInit::GetInstance())->Gdtom(xd, xm, iflag); |
dc37cac6 | 2199 | } |
b0d8df96 | 2200 | |
fa3d1cc7 | 2201 | // =============================================================== |