* provided "as is" without express or implied warranty. *
**************************************************************************/
-/*
-$Log$
-Revision 1.14 2003/02/18 12:47:59 morsch
-Gmtod and Gdtom added.
-
-Revision 1.13 2003/01/31 14:01:51 morsch
-Major update on
-- Getters related to geometry.
-- Communication with run manager (event steering)
-
-Revision 1.12 2003/01/31 12:18:53 morsch
-Corrected indices. (E. Futo)
-
-Revision 1.9 2002/12/06 12:41:29 morsch
-Mess from last merge cleaned up.
-
-Revision 1.8 2002/12/06 12:28:44 morsch
-Region to media mapping corrected and improved.
-
-Revision 1.7 2002/12/06 12:21:32 morsch
-User stepping methods added (E. Futo)
-
-Revision 1.6 2002/11/21 18:40:06 iglez2
-Media handling added
-
-Revision 1.5 2002/11/07 17:59:10 iglez2
-Included the geometry through geant4_vmc/FLUGG
-
-Revision 1.4 2002/11/04 16:00:46 iglez2
-The conversion between ID and PDG now uses Fluka routines and arrays which is more consistent.
-
-Revision 1.3 2002/10/22 15:12:14 alibrary
-Introducing Riostream.h
-
-Revision 1.2 2002/10/14 14:57:40 hristov
-Merging the VirtualMC branch to the main development branch (HEAD)
-
-Revision 1.1.2.8 2002/10/08 16:33:17 iglez2
-LSOUIT is set to true before the second call to flukam.
-
-Revision 1.1.2.7 2002/10/08 09:30:37 iglez2
-Solved stupid missing ;
-
-Revision 1.1.2.6 2002/10/07 13:40:22 iglez2
-First implementations of the PDG <--> Fluka Id conversion routines
-
-Revision 1.1.2.5 2002/09/26 16:26:03 iglez2
-Added verbosity
-Call to gAlice->Generator()->Generate()
-
-Revision 1.1.2.4 2002/09/26 13:22:23 iglez2
-Naive implementation of ProcessRun and ProcessEvent
-Opening/Closing of input file (fInputFileName) with FORTRAN unit 5 before/after the first call to flukam inside Init()
-
-Revision 1.1.2.3 2002/09/20 15:35:51 iglez2
-Modification of LFDRTR. Value is passed to FLUKA !!!
-
-Revision 1.1.2.2 2002/09/18 14:34:44 iglez2
-Revised version with all pure virtual methods implemented
-
-Revision 1.1.2.1 2002/07/24 08:49:41 alibrary
-Adding TFluka to VirtualMC
-
-Revision 1.1 2002/07/05 13:10:07 morsch
-First commit of Fluka interface.
-
-*/
+/* $Id$ */
#include <Riostream.h>
TFluka::TFluka()
:TVirtualMC(),
fVerbosityLevel(0),
- fInputFileName(""),
+ sInputFileName(""),
fDetector(0),
fCurrentFlukaRegion(-1)
{
//
}
-TFluka::TFluka(const char *title, Int_t verbosity)
- :TVirtualMC("TFluka",title),
+TFluka::TFluka(const char *title, Int_t verbosity, Bool_t isRootGeometrySupported)
+ :TVirtualMC("TFluka",title, isRootGeometrySupported),
fVerbosityLevel(verbosity),
- fInputFileName(""),
+ sInputFileName(""),
+ fTrackIsEntering(0),
+ fTrackIsExiting(0),
+ fTrackIsNew(0),
fDetector(0),
fCurrentFlukaRegion(-1)
{
// TFluka control methods
//____________________________________________________________________________
void TFluka::Init() {
+
+ FGeometryInit* geominit = FGeometryInit::GetInstance();
if (fVerbosityLevel >=3)
cout << "==> TFluka::Init() called." << endl;
+ cout << "\t* InitPhysics() - Prepare input file to be called" << endl;
+ geominit->Init();
+ // now we have G4 geometry created and we have to patch alice.inp
+ // with the material mapping file FlukaMat.inp
+ InitPhysics(); // prepare input file with the current physics settings
+ cout << "\t* InitPhysics() - Prepare input file was called" << endl;
+
if (fVerbosityLevel >=2)
cout << "\t* Changing lfdrtr = (" << (GLOBAL.lfdrtr?'T':'F')
<< ") in fluka..." << endl;
GLOBAL.lfdrtr = true;
if (fVerbosityLevel >=2)
- cout << "\t* Opening file " << fInputFileName << endl;
- const char* fname = fInputFileName;
+ cout << "\t* Opening file " << sInputFileName << endl;
+ const char* fname = sInputFileName;
fluka_openinp(lunin, PASSCHARA(fname));
if (fVerbosityLevel >=2)
flukam(1);
if (fVerbosityLevel >=2)
- cout << "\t* Closing file " << fInputFileName << endl;
+ cout << "\t* Closing file " << sInputFileName << endl;
fluka_closeinp(lunin);
+ FinishGeometry();
+
if (fVerbosityLevel >=3)
cout << "<== TFluka::Init() called." << endl;
- FinishGeometry();
-
}
void TFluka::FinishGeometry() {
FlukaVolume* vol = dynamic_cast<FlukaVolume*>((*fVolumeMediaMap)[i]);
TString volName = vol->GetName();
Int_t media = vol->GetMedium();
+ if (fVerbosityLevel >= 3)
printf("Finish Geometry: volName, media %d %s %d \n", i, volName.Data(), media);
strcpy(tmp, volName.Data());
tmp[4] = '\0';
Float_t *upar, Int_t np) {
//
// fVolumeMediaMap[TString(name)] = nmed;
+ if (fVerbosityLevel >= 3)
printf("TFluka::Gsvolu() name = %s, nmed = %d\n", name, nmed);
TClonesArray &lvols = *fVolumeMediaMap;
//____________________________________________________________________________
+// particle table usage
// ID <--> PDG transformations
//_____________________________________________________________________________
Int_t TFluka::IdFromPDG(Int_t pdg) const
{
- //
- // Return Fluka code from PDG and pseudo ENDF code
-
- // MCIHAD() goes from pdg to fluka internal.
- Int_t intfluka = mcihad(pdg);
- // KPTOIP array goes from internal to official
- return GetFlukaKPTOIP(intfluka);
+ //
+ // Return Fluka code from PDG and pseudo ENDF code
+
+ // Catch the feedback photons
+ if (pdg == 50000051) return (-1);
+ // MCIHAD() goes from pdg to fluka internal.
+ Int_t intfluka = mcihad(pdg);
+ // KPTOIP array goes from internal to official
+ return GetFlukaKPTOIP(intfluka);
}
Int_t TFluka::PDGFromId(Int_t id) const
//
// Return PDG code and pseudo ENDF code from Fluka code
- //IPTOKP array goes from official to internal
+ // IPTOKP array goes from official to internal
+
+ if (id == -1) {
+// Cerenkov photon
+ if (fVerbosityLevel >= 1)
+ printf("\n PDGFromId: Cerenkov Photon \n");
+ return 50000050;
+ }
+// Error id
if (id == 0) {
- printf("PDGFromId: Error id = 0");
+ if (fVerbosityLevel >= 1)
+ printf("PDGFromId: Error id = 0\n");
return -1;
}
-
- Int_t intfluka = GetFlukaIPTOKP(id);
+// Good id
+ Int_t intfluka = GetFlukaIPTOKP(id);
if (intfluka == 0) {
- printf("PDGFromId: Error intfluka = 0");
+ if (fVerbosityLevel >= 1)
+ printf("PDGFromId: Error intfluka = 0: %d\n", id);
return -1;
} else if (intfluka < 0) {
- printf("PDGFromId: Error intfluka < 0");
+ if (fVerbosityLevel >= 1)
+ printf("PDGFromId: Error intfluka < 0: %d\n", id);
return -1;
}
- printf("mpdgha called with %d %d \n", id, intfluka);
- return mpdgha(intfluka);
+ if (fVerbosityLevel >= 3)
+ printf("mpdgha called with %d %d \n", id, intfluka);
+ // MPDGHA() goes from fluka internal to pdg.
+ return mpdgha(intfluka);
}
//_____________________________________________________________________________
-// methods for step management
+// methods for physics management
//____________________________________________________________________________
//
// set methods
//
+
+void TFluka::SetProcess(const char* flagName, Int_t flagValue)
+{
+ Int_t i;
+ if (iNbOfProc < 100) {
+ for (i=0; i<iNbOfProc; i++) {
+ if (strcmp(&sProcessFlag[i][0],flagName) == 0) {
+ iProcessValue[iNbOfProc] = flagValue;
+ goto fin;
+ }
+ }
+ strcpy(&sProcessFlag[iNbOfProc][0],flagName);
+ iProcessValue[iNbOfProc++] = flagValue;
+ }
+ else
+ cout << "Nb of SetProcess calls exceeds 100 - ignored" << endl;
+fin:
+ iNbOfProc = iNbOfProc;
+}
+
+void TFluka::SetCut(const char* cutName, Double_t cutValue)
+{
+ Int_t i;
+ if (iNbOfCut < 100) {
+ for (i=0; i<iNbOfCut; i++) {
+ if (strcmp(&sCutFlag[i][0],cutName) == 0) {
+ fCutValue[iNbOfCut] = cutValue;
+ goto fin;
+ }
+ }
+ strcpy(&sCutFlag[iNbOfCut][0],cutName);
+ fCutValue[iNbOfCut++] = cutValue;
+ }
+ else
+ cout << "Nb of SetCut calls exceeds 100 - ignored" << endl;
+fin:
+ iNbOfCut = iNbOfCut;
+}
+
+Double_t TFluka::Xsec(char*, Double_t, Int_t, Int_t)
+{
+ printf("WARNING: Xsec not yet implemented !\n"); return -1.;
+}
+
+
+void TFluka::InitPhysics()
+{
+ Int_t i, j, k;
+ Double_t fCut;
+ Double_t zero, one, two, three;
+ FILE *pAliceCoreInp, *pAliceFlukaMat, *pAliceInp;
+
+ zero = 0.0;
+ one = 1.0;
+ two = 2.0;
+ three = 3.0;
+
+ FGeometryInit* geominit = FGeometryInit::GetInstance();
+ Float_t fLastMaterial = geominit->GetLastMaterialIndex();
+ printf(" last FLUKA material is %g\n", fLastMaterial);
+
+// construct file names
+ TString sAliceCoreInp = getenv("ALICE_ROOT");
+ sAliceCoreInp +="/TFluka/input/";
+ TString sAliceTmp = "flukaMat.inp";
+ TString sAliceInp = GetInputFileName();
+ sAliceCoreInp += GetCoreInputFileName();
+/* open files */
+ if ((pAliceCoreInp = fopen(sAliceCoreInp.Data(),"r")) == NULL) {
+ printf("\nCannot open file %s\n",sAliceCoreInp.Data());
+ exit(1);
+ }
+ if ((pAliceFlukaMat = fopen(sAliceTmp.Data(),"r")) == NULL) {
+ printf("\nCannot open file %s\n",sAliceTmp.Data());
+ exit(1);
+ }
+ if ((pAliceInp = fopen(sAliceInp.Data(),"w")) == NULL) {
+ printf("\nCannot open file %s\n",sAliceInp.Data());
+ exit(1);
+ }
+
+// copy core input file
+ Char_t sLine[255];
+ Float_t fEventsPerRun;
+
+ while ((fgets(sLine,255,pAliceCoreInp)) != NULL) {
+ if (strncmp(sLine,"GEOEND",6) != 0)
+ fprintf(pAliceInp,"%s",sLine); // copy until GEOEND card
+ else {
+ fprintf(pAliceInp,"GEOEND\n"); // add GEOEND card
+ goto flukamat;
+ }
+ } // end of while until GEOEND card
+
+flukamat:
+ while ((fgets(sLine,255,pAliceFlukaMat)) != NULL) { // copy flukaMat.inp file
+ fprintf(pAliceInp,"%s\n",sLine);
+ }
+
+ while ((fgets(sLine,255,pAliceCoreInp)) != NULL) {
+ if (strncmp(sLine,"START",5) != 0)
+ fprintf(pAliceInp,"%s\n",sLine);
+ else {
+ sscanf(sLine+10,"%10f",&fEventsPerRun);
+ goto fin;
+ }
+ } //end of while until START card
+
+fin:
+// in G3 the process control values meaning can be different for
+// different processes, but for most of them is:
+// 0 process is not activated
+// 1 process is activated WITH generation of secondaries
+// 2 process is activated WITHOUT generation of secondaries
+// if process does not generate secondaries => 1 same as 2
+//
+// Exceptions:
+// MULS: also 3
+// LOSS: also 3, 4
+// RAYL: only 0,1
+// HADR: may be > 2
+//
+
+// Loop over number of SetProcess calls
+ fprintf(pAliceInp,"*----------------------------------------------------------------------------- \n");
+ fprintf(pAliceInp,"*----- The following data are generated from SetProcess and SetCut calls ----- \n");
+ fprintf(pAliceInp,"*----------------------------------------------------------------------------- \n");
+ for (i=0; i<iNbOfProc; i++) {
+
+ // annihilation
+ // G3 default value: 1
+ // G4 processes: G4eplusAnnihilation/G4IeplusAnnihilation
+ // Particles: e+
+ // Physics: EM
+ // flag = 0 no annihilation
+ // flag = 1 annihilation, decays processed
+ // flag = 2 annihilation, no decay product stored
+ // gMC ->SetProcess("ANNI",1); // EMFCUT -1. 0. 0. 3. lastmat 0. ANNH-THR
+ if (strncmp(&sProcessFlag[i][0],"ANNI",4) == 0) {
+ if (iProcessValue[i] == 1 || iProcessValue[i] == 2) {
+ fprintf(pAliceInp,"*\n*Kinetic energy threshold (GeV) for e+ annihilation - resets to default=0.\n");
+ fprintf(pAliceInp,"*Generated from call: SetProcess('ANNI',1) or SetProcess('ANNI',2)\n");
+ // -one = kinetic energy threshold (GeV) for e+ annihilation (resets to default=0)
+ // zero = not used
+ // zero = not used
+ // three = lower bound of the material indices in which the respective thresholds apply
+ // fLastMaterial = upper bound of the material indices in which the respective thresholds apply
+ // one = step length in assigning indices
+ // "ANNH-THR";
+ fprintf(pAliceInp,"EMFCUT %10.1f%10.1f%10.1f%10.1f%10.1f%10.1fANNH-THR\n",-one,zero,zero,three,fLastMaterial,one);
+ }
+ else if (iProcessValue[i] == 0) {
+ fprintf(pAliceInp,"*\n*No annihilation - no FLUKA card generated\n");
+ fprintf(pAliceInp,"*Generated from call: SetProcess('ANNI',0)\n");
+ }
+ else {
+ fprintf(pAliceInp,"*\n*Illegal flag value in SetProcess('ANNI',?) call.\n");
+ fprintf(pAliceInp,"*No FLUKA card generated\n");
+ }
+ }
+
+ // bremsstrahlung and pair production are both activated
+ // G3 default value: 1
+ // G4 processes: G4eBremsstrahlung/G4IeBremsstrahlung,
+ // G4MuBremsstrahlung/G4IMuBremsstrahlung,
+ // G4LowEnergyBremstrahlung
+ // Particles: e-/e+; mu+/mu-
+ // Physics: EM
+ // flag = 0 no bremsstrahlung
+ // flag = 1 bremsstrahlung, photon processed
+ // flag = 2 bremsstrahlung, no photon stored
+ // gMC ->SetProcess("BREM",1); // PAIRBREM 2. 0. 0. 3. lastmat
+ // EMFCUT -1. 0. 0. 3. lastmat 0. ELPO-THR
+ // G3 default value: 1
+ // G4 processes: G4GammaConversion,
+ // G4MuPairProduction/G4IMuPairProduction
+ // G4LowEnergyGammaConversion
+ // Particles: gamma, mu
+ // Physics: EM
+ // flag = 0 no delta rays
+ // flag = 1 delta rays, secondaries processed
+ // flag = 2 delta rays, no secondaries stored
+ // gMC ->SetProcess("PAIR",1); // PAIRBREM 1. 0. 0. 3. lastmat
+ // EMFCUT 0. 0. -1. 3. lastmat 0. PHOT-THR
+ else if ((strncmp(&sProcessFlag[i][0],"PAIR",4) == 0) && (iProcessValue[i] == 1 || iProcessValue[i] == 2)) {
+ for (j=0; j<iNbOfProc; j++) {
+ if ((strncmp(&sProcessFlag[j][0],"BREM",4) == 0) && (iProcessValue[j] == 1 || iProcessValue[j] == 2)) {
+ fprintf(pAliceInp,"*\n*Bremsstrahlung and pair production by muons and charged hadrons both activated\n");
+ fprintf(pAliceInp,"*Generated from call: SetProcess('BREM',1) and SetProcess('PAIR',1)\n");
+ fprintf(pAliceInp,"*Energy threshold set by call SetCut('BCUTM',cut) or set to 0.\n");
+ fprintf(pAliceInp,"*Energy threshold set by call SetCut('PPCUTM',cut) or set to 0.\n");
+ // three = bremsstrahlung and pair production by muons and charged hadrons both are activated
+ fprintf(pAliceInp,"PAIRBREM %10.1f",three);
+ // direct pair production by muons
+ // G4 particles: "e-", "e+"
+ // G3 default value: 0.01 GeV
+ //gMC ->SetCut("PPCUTM",cut); // total energy cut for direct pair prod. by muons
+ fCut = 0.0;
+ for (k=0; k<iNbOfCut; k++) {
+ if (strncmp(&sCutFlag[k][0],"PPCUTM",6) == 0) fCut = fCutValue[k];
+ }
+ fprintf(pAliceInp,"%10.4g",fCut);
+ // fCut; = e+, e- kinetic energy threshold (in GeV) for explicit pair production.
+ // muon and hadron bremsstrahlung
+ // G4 particles: "gamma"
+ // G3 default value: CUTGAM=0.001 GeV
+ //gMC ->SetCut("BCUTM",cut); // cut for muon and hadron bremsstrahlung
+ fCut = 0.0;
+ for (k=0; k<iNbOfCut; k++) {
+ if (strncmp(&sCutFlag[k][0],"BCUTM",5) == 0) fCut = fCutValue[k];
+ }
+ fprintf(pAliceInp,"%10.4g%10.1f%10.1f\n",fCut,three,fLastMaterial);
+ // fCut = photon energy threshold (GeV) for explicit bremsstrahlung production
+ // three = lower bound of the material indices in which the respective thresholds apply
+ // fLastMaterial = upper bound of the material indices in which the respective thresholds apply
+
+ // for e+ and e-
+ fprintf(pAliceInp,"*\n*Kinetic energy threshold (GeV) for e+/e- bremsstrahlung - resets to default=0.\n");
+ fprintf(pAliceInp,"*Generated from call: SetProcess('BREM',1);\n");
+ fCut = -1.0;
+ for (k=0; k<iNbOfCut; k++) {
+ if (strncmp(&sCutFlag[k][0],"BCUTE",5) == 0) fCut = fCutValue[k];
+ }
+ //fCut = kinetic energy threshold (GeV) for e+/e- bremsstrahlung (resets to default=0)
+ // zero = not used
+ // zero = not used
+ // three = lower bound of the material indices in which the respective thresholds apply
+ // fLastMaterial = upper bound of the material indices in which the respective thresholds apply
+ // one = step length in assigning indices
+ // "ELPO-THR";
+ fprintf(pAliceInp,"EMFCUT %10.4g%10.1f%10.1f%10.1f%10.1f%10.1fELPO-THR\n",fCut,zero,zero,three,fLastMaterial,one);
+
+ // for e+ and e-
+ fprintf(pAliceInp,"*\n*Pair production by electrons is activated\n");
+ fprintf(pAliceInp,"*Generated from call: SetProcess('PAIR',1);\n");
+ fCut = -1.0;
+ for (j=0; j<iNbOfCut; j++) {
+ if (strncmp(&sCutFlag[j][0],"CUTGAM",6) == 0) fCut = fCutValue[j];
+ }
+ // fCut = energy threshold (GeV) for gamma pair production (< 0.0 : resets to default, = 0.0 : ignored)
+ // three = lower bound of the material indices in which the respective thresholds apply
+ // fLastMaterial = upper bound of the material indices in which the respective thresholds apply
+ // one = step length in assigning indices
+ fprintf(pAliceInp,"EMFCUT %10.1f%10.1f%10.4g%10.1f%10.1f%10.1fPHOT-THR\n",zero,zero,fCut,three,fLastMaterial,one);
+ goto BOTH;
+ } // end of if for BREM
+ } // end of loop for BREM
+
+ // only pair production by muons and charged hadrons is activated
+ fprintf(pAliceInp,"*\n*Pair production by muons and charged hadrons is activated\n");
+ fprintf(pAliceInp,"*Generated from call: SetProcess('PAIR',1) or SetProcess('PAIR',2)\n");
+ fprintf(pAliceInp,"*Energy threshold set by call SetCut('PPCUTM',cut) or set to 0.\n");
+ // direct pair production by muons
+ // G4 particles: "e-", "e+"
+ // G3 default value: 0.01 GeV
+ //gMC ->SetCut("PPCUTM",cut); // total energy cut for direct pair prod. by muons
+ // one = pair production by muons and charged hadrons is activated
+ // zero = e+, e- kinetic energy threshold (in GeV) for explicit pair production.
+ // zero = no explicit bremsstrahlung production is simulated
+ // three = lower bound of the material indices in which the respective thresholds apply
+ // fLastMaterial = upper bound of the material indices in which the respective thresholds apply
+ fprintf(pAliceInp,"PAIRBREM %10.1f%10.1f%10.1f%10.1f%10.1f\n",one,zero,zero,three,fLastMaterial);
+
+ // for e+ and e-
+ fprintf(pAliceInp,"*\n*Pair production by electrons is activated\n");
+ fprintf(pAliceInp,"*Generated from call: SetProcess('PAIR',1) or SetProcess('PAIR',2)\n");
+ fCut = -1.0;
+ for (j=0; j<iNbOfCut; j++) {
+ if (strncmp(&sCutFlag[j][0],"CUTGAM",6) == 0) fCut = fCutValue[j];
+ }
+ // zero = energy threshold (GeV) for Compton scattering (= 0.0 : ignored)
+ // zero = energy threshold (GeV) for Photoelectric (= 0.0 : ignored)
+ // fCut = energy threshold (GeV) for gamma pair production (< 0.0 : resets to default, = 0.0 : ignored)
+ // three = lower bound of the material indices in which the respective thresholds apply
+ // fLastMaterial = upper bound of the material indices in which the respective thresholds apply
+ // one = step length in assigning indices
+ fprintf(pAliceInp,"EMFCUT %10.1f%10.1f%10.4g%10.1f%10.1f%10.1fPHOT-THR\n",zero,zero,fCut,three,fLastMaterial,one);
+
+BOTH:
+ k = 0;
+ } // end of if for PAIR
+
+
+
+ // bremsstrahlung
+ // G3 default value: 1
+ // G4 processes: G4eBremsstrahlung/G4IeBremsstrahlung,
+ // G4MuBremsstrahlung/G4IMuBremsstrahlung,
+ // G4LowEnergyBremstrahlung
+ // Particles: e-/e+; mu+/mu-
+ // Physics: EM
+ // flag = 0 no bremsstrahlung
+ // flag = 1 bremsstrahlung, photon processed
+ // flag = 2 bremsstrahlung, no photon stored
+ // gMC ->SetProcess("BREM",1); // PAIRBREM 2. 0. 0. 3. lastmat
+ // EMFCUT -1. 0. 0. 3. lastmat 0. ELPO-THR
+ else if (strncmp(&sProcessFlag[i][0],"BREM",4) == 0) {
+ for (j=0; j<iNbOfProc; j++) {
+ if ((strncmp(&sProcessFlag[j][0],"PAIR",4) == 0) && iProcessValue[j] == 1) goto NOBREM;
+ }
+ if (iProcessValue[i] == 1 || iProcessValue[i] == 2) {
+ fprintf(pAliceInp,"*\n*Bremsstrahlung by muons and charged hadrons is activated\n");
+ fprintf(pAliceInp,"*Generated from call: SetProcess('BREM',1) or SetProcess('BREM',2)\n");
+ fprintf(pAliceInp,"*Energy threshold set by call SetCut('BCUTM',cut) or set to 0.\n");
+ // two = bremsstrahlung by muons and charged hadrons is activated
+ // zero = no meaning
+ // muon and hadron bremsstrahlung
+ // G4 particles: "gamma"
+ // G3 default value: CUTGAM=0.001 GeV
+ //gMC ->SetCut("BCUTM",cut); // cut for muon and hadron bremsstrahlung
+ fCut = 0.0;
+ for (j=0; j<iNbOfCut; j++) {
+ if (strncmp(&sCutFlag[j][0],"BCUTM",5) == 0) fCut = fCutValue[j];
+ }
+ // fCut = photon energy threshold (GeV) for explicit bremsstrahlung production
+ // three = lower bound of the material indices in which the respective thresholds apply
+ // fLastMaterial = upper bound of the material indices in which the respective thresholds apply
+ fprintf(pAliceInp,"PAIRBREM %10.1f%10.1f%10.4g%10.1f%10.1f\n",two,zero,fCut,three,fLastMaterial);
+
+ // for e+ and e-
+ fprintf(pAliceInp,"*\n*Kinetic energy threshold (GeV) for e+/e- bremsstrahlung - resets to default=0.\n");
+ fprintf(pAliceInp,"*Generated from call: SetProcess('BREM',1);");
+ // - one = kinetic energy threshold (GeV) for e+/e- bremsstrahlung (resets to default=0)
+ // zero = not used
+ // zero = not used
+ // three = lower bound of the material indices in which the respective thresholds apply
+ // fLastMaterial = upper bound of the material indices in which the respective thresholds apply
+ // one = step length in assigning indices
+ //"ELPO-THR";
+ fprintf(pAliceInp,"EMFCUT %10.1f%10.1f%10.1f%10.1f%10.1f%10.1fELPO-THR\n",-one,zero,zero,three,fLastMaterial,one);
+ }
+ else if (iProcessValue[i] == 0) {
+ fprintf(pAliceInp,"*\n*No bremsstrahlung - no FLUKA card generated\n");
+ fprintf(pAliceInp,"*Generated from call: SetProcess('BREM',0)\n");
+ }
+ else {
+ fprintf(pAliceInp,"*\n*Illegal flag value in SetProcess('BREM',?) call.\n");
+ fprintf(pAliceInp,"*No FLUKA card generated\n");
+ }
+NOBREM:
+ j = 0;
+ } // end of else if (strncmp(&sProcessFlag[i][0],"BREM",4) == 0)
+
+
+ // Cerenkov photon generation
+ // G3 default value: 0
+ // G4 process: G4Cerenkov
+ //
+ // Particles: charged
+ // Physics: Optical
+ // flag = 0 no Cerenkov photon generation
+ // flag = 1 Cerenkov photon generation
+ // flag = 2 Cerenkov photon generation with primary stopped at each step
+ //xx gMC ->SetProcess("CKOV",1); // ??? Cerenkov photon generation
+ else if (strncmp(&sProcessFlag[i][0],"CKOV",4) == 0) {
+ if (iProcessValue[i] == 1 || iProcessValue[i] == 2) {
+ fprintf(pAliceInp,"*\n*Cerenkov photon generation\n");
+ fprintf(pAliceInp,"*Generated from call: SetProcess('CKOV',1) or SetProcess('CKOV',2)\n");
+ Double_t emin = 2.07e-9; // minimum Cerenkov photon emission energy (in GeV!). Default: 2.07E-9 GeV (corresponding to 600 nm)
+ Double_t emax = 4.96e-9; // maximum Cerenkov photon emission energy (in GeV!). Default: 4.96E-9 GeV (corresponding to 250 nm)
+ fprintf(pAliceInp,"OPT-PROD %10.4g%10.4g%10.1f%10.1f%10.1f%10.1fCERENKOV\n",emin,emax,zero,three,fLastMaterial,one);
+ }
+ else if (iProcessValue[i] == 0) {
+ fprintf(pAliceInp,"*\n*No Cerenkov photon generation\n");
+ fprintf(pAliceInp,"*Generated from call: SetProcess('CKOV',0)\n");
+ // zero = not used
+ // zero = not used
+ // zero = not used
+ // three = lower bound of the material indices in which the respective thresholds apply
+ // fLastMaterial = upper bound of the material indices in which the respective thresholds apply
+ // one = step length in assigning indices
+ //"CERE-OFF";
+ fprintf(pAliceInp,"OPT-PROD %10.1f%10.1f%10.1f%10.1f%10.1f%10.1fCERE-OFF\n",zero,zero,zero,three,fLastMaterial,one);
+ }
+ else {
+ fprintf(pAliceInp,"*\n*Illegal flag value in SetProcess('CKOV',?) call.\n");
+ fprintf(pAliceInp,"*No FLUKA card generated\n");
+ }
+ } // end of else if (strncmp(&sProcessFlag[i][0],"CKOV",4) == 0)
+
+
+ // Compton scattering
+ // G3 default value: 1
+ // G4 processes: G4ComptonScattering,
+ // G4LowEnergyCompton,
+ // G4PolarizedComptonScattering
+ // Particles: gamma
+ // Physics: EM
+ // flag = 0 no Compton scattering
+ // flag = 1 Compton scattering, electron processed
+ // flag = 2 Compton scattering, no electron stored
+ // gMC ->SetProcess("COMP",1); // EMFCUT -1. 0. 0. 3. lastmat 0. PHOT-THR
+ else if (strncmp(&sProcessFlag[i][0],"COMP",4) == 0) {
+ if (iProcessValue[i] == 1 || iProcessValue[i] == 2) {
+ fprintf(pAliceInp,"*\n*Energy threshold (GeV) for Compton scattering - resets to default=0.\n");
+ fprintf(pAliceInp,"*Generated from call: SetProcess('COMP',1);\n");
+ // - one = energy threshold (GeV) for Compton scattering - resets to default=0.
+ // zero = not used
+ // zero = not used
+ // three = lower bound of the material indices in which the respective thresholds apply
+ // fLastMaterial = upper bound of the material indices in which the respective thresholds apply
+ // one = step length in assigning indices
+ //"PHOT-THR";
+ fprintf(pAliceInp,"EMFCUT %10.1f%10.1f%10.1f%10.1f%10.1f%10.1fPHOT-THR\n",-one,zero,zero,three,fLastMaterial,one);
+ }
+ else if (iProcessValue[i] == 0) {
+ fprintf(pAliceInp,"*\n*No Compton scattering - no FLUKA card generated\n");
+ fprintf(pAliceInp,"*Generated from call: SetProcess('COMP',0)\n");
+ }
+ else {
+ fprintf(pAliceInp,"*\n*Illegal flag value in SetProcess('COMP',?) call.\n");
+ fprintf(pAliceInp,"*No FLUKA card generated\n");
+ }
+ } // end of else if (strncmp(&sProcessFlag[i][0],"COMP",4) == 0)
+
+ // decay
+ // G3 default value: 1
+ // G4 process: G4Decay
+ //
+ // Particles: all which decay is applicable for
+ // Physics: General
+ // flag = 0 no decays
+ // flag = 1 decays, secondaries processed
+ // flag = 2 decays, no secondaries stored
+ //gMC ->SetProcess("DCAY",1); // not available
+ else if ((strncmp(&sProcessFlag[i][0],"DCAY",4) == 0) && iProcessValue[i] == 1)
+ cout << "SetProcess for flag=" << &sProcessFlag[i][0] << " value=" << iProcessValue[i] << " not avaliable!" << endl;
+
+ // delta-ray
+ // G3 default value: 2
+ // !! G4 treats delta rays in different way
+ // G4 processes: G4eIonisation/G4IeIonization,
+ // G4MuIonisation/G4IMuIonization,
+ // G4hIonisation/G4IhIonisation
+ // Particles: charged
+ // Physics: EM
+ // flag = 0 no energy loss
+ // flag = 1 restricted energy loss fluctuations
+ // flag = 2 complete energy loss fluctuations
+ // flag = 3 same as 1
+ // flag = 4 no energy loss fluctuations
+ // gMC ->SetProcess("DRAY",0); // DELTARAY 1.E+6 0. 0. 3. lastmat 0.
+ else if (strncmp(&sProcessFlag[i][0],"DRAY",4) == 0) {
+ if (iProcessValue[i] == 0 || iProcessValue[i] == 4) {
+ fprintf(pAliceInp,"*\n*Kinetic energy threshold (GeV) for delta ray production\n");
+ fprintf(pAliceInp,"*Generated from call: SetProcess('DRAY',0) or SetProcess('DRAY',4)\n");
+ fprintf(pAliceInp,"*No delta ray production by muons - threshold set artificially high\n");
+ Double_t emin = 1.0e+6; // kinetic energy threshold (GeV) for delta ray production (discrete energy transfer)
+ // zero = ignored
+ // zero = ignored
+ // three = lower bound of the material indices in which the respective thresholds apply
+ // fLastMaterial = upper bound of the material indices in which the respective thresholds apply
+ // one = step length in assigning indices
+ fprintf(pAliceInp,"DELTARAY %10.4g%10.1f%10.1f%10.1f%10.1f%10.1f\n",emin,zero,zero,three,fLastMaterial,one);
+ }
+ else if (iProcessValue[i] == 1 || iProcessValue[i] == 2 || iProcessValue[i] == 3) {
+ fprintf(pAliceInp,"*\n*Kinetic energy threshold (GeV) for delta ray production\n");
+ fprintf(pAliceInp,"*Generated from call: SetProcess('DRAY',flag), flag=1,2,3\n");
+ fprintf(pAliceInp,"*Delta ray production by muons switched on\n");
+ fprintf(pAliceInp,"*Energy threshold set by call SetCut('DCUTM',cut) or set to 1.0e+6.\n");
+ fCut = 1.0e+6;
+ for (j=0; j<iNbOfCut; j++) {
+ if (strncmp(&sCutFlag[j][0],"DCUTM",5) == 0) fCut = fCutValue[j];
+ }
+ // fCut = kinetic energy threshold (GeV) for delta ray production (discrete energy transfer)
+ // zero = ignored
+ // zero = ignored
+ // three = lower bound of the material indices in which the respective thresholds apply
+ // fLastMaterial = upper bound of the material indices in which the respective thresholds apply
+ // one = step length in assigning indices
+ fprintf(pAliceInp,"DELTARAY %10.4g%10.1f%10.1f%10.1f%10.1f%10.1f\n",fCut,zero,zero,three,fLastMaterial,one);
+ }
+ else {
+ fprintf(pAliceInp,"*\n*Illegal flag value in SetProcess('DRAY',?) call.\n");
+ fprintf(pAliceInp,"*No FLUKA card generated\n");
+ }
+ } // end of else if (strncmp(&sProcessFlag[i][0],"DRAY",4) == 0)
+
+ // hadronic process
+ // G3 default value: 1
+ // G4 processes: all defined by TG4PhysicsConstructorHadron
+ //
+ // Particles: hadrons
+ // Physics: Hadron
+ // flag = 0 no multiple scattering
+ // flag = 1 hadronic interactions, secondaries processed
+ // flag = 2 hadronic interactions, no secondaries stored
+ // gMC ->SetProcess("HADR",1); // ??? hadronic process
+ //Select pure GEANH (HADR 1) or GEANH/NUCRIN (HADR 3) ?????
+ else if (strncmp(&sProcessFlag[i][0],"HADR",4) == 0) {
+ if (iProcessValue[i] == 1 || iProcessValue[i] == 2) {
+ fprintf(pAliceInp,"*\n*Hadronic interaction is ON by default in FLUKA\n");
+ fprintf(pAliceInp,"*No FLUKA card generated\n");
+ }
+ else if (iProcessValue[i] == 0) {
+ fprintf(pAliceInp,"*\n*Hadronic interaction is set OFF\n");
+ fprintf(pAliceInp,"*Generated from call: SetProcess('HADR',0);\n");
+ // zero = ignored
+ // three = multiple scattering for hadrons and muons is completely suppressed
+ // zero = no spin-relativistic corrections
+ // three = lower bound of the material indices in which the respective thresholds apply
+ // fLastMaterial = upper bound of the material indices in which the respective thresholds apply
+ fprintf(pAliceInp,"MULSOPT %10.1f%10.1f%10.1f%10.1f%10.1f\n",zero,three,zero,three,fLastMaterial);
+
+ }
+ else {
+ fprintf(pAliceInp,"*\n*Illegal flag value in SetProcess('HADR',?) call.\n");
+ fprintf(pAliceInp,"*No FLUKA card generated\n");
+ }
+ } // end of else if (strncmp(&sProcessFlag[i][0],"HADR",4) == 0)
+
+
+ // energy loss
+ // G3 default value: 2
+ // G4 processes: G4eIonisation/G4IeIonization,
+ // G4MuIonisation/G4IMuIonization,
+ // G4hIonisation/G4IhIonisation
+ //
+ // Particles: charged
+ // Physics: EM
+ // flag=0 no energy loss
+ // flag=1 restricted energy loss fluctuations
+ // flag=2 complete energy loss fluctuations
+ // flag=3 same as 1
+ // flag=4 no energy loss fluctuations
+ // If the value ILOSS is changed, then (in G3) cross-sections and energy
+ // loss tables must be recomputed via the command 'PHYSI'
+ // gMC ->SetProcess("LOSS",2); // ??? IONFLUCT ? energy loss
+ else if (strncmp(&sProcessFlag[i][0],"LOSS",4) == 0) {
+ if (iProcessValue[i] == 2) { // complete energy loss fluctuations
+ fprintf(pAliceInp,"*\n*Complete energy loss fluctuations do not exist in FLUKA\n");
+ fprintf(pAliceInp,"*Generated from call: SetProcess('LOSS',2);\n");
+ fprintf(pAliceInp,"*flag=2=complete energy loss fluctuations\n");
+ fprintf(pAliceInp,"*No FLUKA card generated\n");
+ }
+ else if (iProcessValue[i] == 1 || iProcessValue[i] == 3) { // restricted energy loss fluctuations
+ fprintf(pAliceInp,"*\n*Restricted energy loss fluctuations\n");
+ fprintf(pAliceInp,"*Generated from call: SetProcess('LOSS',1) or SetProcess('LOSS',3)\n");
+ // one = restricted energy loss fluctuations (for hadrons and muons) switched on
+ // one = restricted energy loss fluctuations (for e+ and e-) switched on
+ // one = minimal accuracy
+ // three = lower bound of the material indices in which the respective thresholds apply
+ // upper bound of the material indices in which the respective thresholds apply
+ fprintf(pAliceInp,"IONFLUCT %10.1f%10.1f%10.1f%10.1f%10.1f\n",one,one,one,three,fLastMaterial);
+ }
+ else if (iProcessValue[i] == 4) { // no energy loss fluctuations
+ fprintf(pAliceInp,"*\n*No energy loss fluctuations\n");
+ fprintf(pAliceInp,"*\n*Generated from call: SetProcess('LOSS',4)\n");
+ // - one = restricted energy loss fluctuations (for hadrons and muons) switched off
+ // - one = restricted energy loss fluctuations (for e+ and e-) switched off
+ // one = minimal accuracy
+ // three = lower bound of the material indices in which the respective thresholds apply
+ // fLastMaterial = upper bound of the material indices in which the respective thresholds apply
+ fprintf(pAliceInp,"IONFLUCT %10.1f%10.1f%10.1f%10.1f%10.1f\n",-one,-one,one,three,fLastMaterial);
+ }
+ else {
+ fprintf(pAliceInp,"*\n*Illegal flag value in SetProcess('LOSS',?) call.\n");
+ fprintf(pAliceInp,"*No FLUKA card generated\n");
+ }
+ } // end of else if (strncmp(&sProcessFlag[i][0],"LOSS",4) == 0)
+
+
+ // multiple scattering
+ // G3 default value: 1
+ // G4 process: G4MultipleScattering/G4IMultipleScattering
+ //
+ // Particles: charged
+ // Physics: EM
+ // flag = 0 no multiple scattering
+ // flag = 1 Moliere or Coulomb scattering
+ // flag = 2 Moliere or Coulomb scattering
+ // flag = 3 Gaussian scattering
+ // gMC ->SetProcess("MULS",1); // MULSOPT multiple scattering
+ else if (strncmp(&sProcessFlag[i][0],"MULS",4) == 0) {
+ if (iProcessValue[i] == 1 || iProcessValue[i] == 2 || iProcessValue[i] == 3) {
+ fprintf(pAliceInp,"*\n*Multiple scattering is ON by default for e+e- and for hadrons/muons\n");
+ fprintf(pAliceInp,"*No FLUKA card generated\n");
+ }
+ else if (iProcessValue[i] == 0) {
+ fprintf(pAliceInp,"*\n*Multiple scattering is set OFF\n");
+ fprintf(pAliceInp,"*Generated from call: SetProcess('MULS',0);\n");
+ // zero = ignored
+ // three = multiple scattering for hadrons and muons is completely suppressed
+ // three = multiple scattering for e+ and e- is completely suppressed
+ // three = lower bound of the material indices in which the respective thresholds apply
+ // fLastMaterial = upper bound of the material indices in which the respective thresholds apply
+ fprintf(pAliceInp,"MULSOPT %10.1f%10.1f%10.1f%10.1f%10.1f\n",zero,three,three,three,fLastMaterial);
+ }
+ else {
+ fprintf(pAliceInp,"*\n*Illegal flag value in SetProcess('MULS',?) call.\n");
+ fprintf(pAliceInp,"*No FLUKA card generated\n");
+ }
+ } // end of else if (strncmp(&sProcessFlag[i][0],"MULS",4) == 0)
+
+
+ // muon nuclear interaction
+ // G3 default value: 0
+ // G4 processes: G4MuNuclearInteraction,
+ // G4MuonMinusCaptureAtRest
+ //
+ // Particles: mu
+ // Physics: Not set
+ // flag = 0 no muon-nuclear interaction
+ // flag = 1 nuclear interaction, secondaries processed
+ // flag = 2 nuclear interaction, secondaries not processed
+ // gMC ->SetProcess("MUNU",1); // MUPHOTON 1. 0. 0. 3. lastmat
+ else if (strncmp(&sProcessFlag[i][0],"MUNU",4) == 0) {
+ if (iProcessValue[i] == 1) {
+ fprintf(pAliceInp,"*\n*Muon nuclear interactions with production of secondary hadrons\n");
+ fprintf(pAliceInp,"*Generated from call: SetProcess('MUNU',1);\n");
+ // one = full simulation of muon nuclear interactions and production of secondary hadrons
+ // zero = ratio of longitudinal to transverse virtual photon cross-section - Default = 0.25.
+ // zero = fraction of rho-like interactions ( must be < 1) - Default = 0.75.
+ // three = lower bound of the material indices in which the respective thresholds apply
+ // fLastMaterial = upper bound of the material indices in which the respective thresholds apply
+ fprintf(pAliceInp,"MUPHOTON %10.1f%10.1f%10.1f%10.1f%10.1f\n",one,zero,zero,three,fLastMaterial);
+ }
+ else if (iProcessValue[i] == 2) {
+ fprintf(pAliceInp,"*\n*Muon nuclear interactions without production of secondary hadrons\n");
+ fprintf(pAliceInp,"*Generated from call: SetProcess('MUNU',2);\n");
+ // two = full simulation of muon nuclear interactions and production of secondary hadrons
+ // zero = ratio of longitudinal to transverse virtual photon cross-section - Default = 0.25.
+ // zero = fraction of rho-like interactions ( must be < 1) - Default = 0.75.
+ // three = lower bound of the material indices in which the respective thresholds apply
+ // fLastMaterial = upper bound of the material indices in which the respective thresholds apply
+ fprintf(pAliceInp,"MUPHOTON %10.1f%10.1f%10.1f%10.1f%10.1f\n",two,zero,zero,three,fLastMaterial);
+ }
+ else if (iProcessValue[i] == 0) {
+ fprintf(pAliceInp,"*\n*No muon nuclear interaction - no FLUKA card generated\n");
+ fprintf(pAliceInp,"*Generated from call: SetProcess('MUNU',0)\n");
+ }
+ else {
+ fprintf(pAliceInp,"*\n*Illegal flag value in SetProcess('MUNU',?) call.\n");
+ fprintf(pAliceInp,"*No FLUKA card generated\n");
+ }
+ } // end of else if (strncmp(&sProcessFlag[i][0],"MUNU",4) == 0)
+
+
+ // photofission
+ // G3 default value: 0
+ // G4 process: ??
+ //
+ // Particles: gamma
+ // Physics: ??
+ // gMC ->SetProcess("PFIS",0); // PHOTONUC -1. 0. 0. 3. lastmat 0.
+ // flag = 0 no photon fission
+ // flag = 1 photon fission, secondaries processed
+ // flag = 2 photon fission, no secondaries stored
+ else if (strncmp(&sProcessFlag[i][0],"PFIS",4) == 0) {
+ if (iProcessValue[i] == 0) {
+ fprintf(pAliceInp,"*\n*No photonuclear interactions\n");
+ fprintf(pAliceInp,"*Generated from call: SetProcess('PFIS',0);\n");
+ // - one = no photonuclear interactions
+ // zero = not used
+ // zero = not used
+ // three = lower bound of the material indices in which the respective thresholds apply
+ // fLastMaterial = upper bound of the material indices in which the respective thresholds apply
+ fprintf(pAliceInp,"PHOTONUC %10.1f%10.1f%10.1f%10.1f%10.1f\n",-one,zero,zero,three,fLastMaterial);
+ }
+ else if (iProcessValue[i] == 1) {
+ fprintf(pAliceInp,"*\n*Photon nuclear interactions are activated at all energies\n");
+ fprintf(pAliceInp,"*Generated from call: SetProcess('PFIS',1);\n");
+ // one = photonuclear interactions are activated at all energies
+ // zero = not used
+ // zero = not used
+ // three = lower bound of the material indices in which the respective thresholds apply
+ // fLastMaterial = upper bound of the material indices in which the respective thresholds apply
+ fprintf(pAliceInp,"PHOTONUC %10.1f%10.1f%10.1f%10.1f%10.1f\n",one,zero,zero,three,fLastMaterial);
+ }
+ else if (iProcessValue[i] == 0) {
+ fprintf(pAliceInp,"*\n*No photofission - no FLUKA card generated\n");
+ fprintf(pAliceInp,"*Generated from call: SetProcess('PFIS',0)\n");
+ }
+ else {
+ fprintf(pAliceInp,"*\n*Illegal flag value in SetProcess('PFIS',?) call.\n");
+ fprintf(pAliceInp,"*No FLUKA card generated\n");
+ }
+ }
+
+
+ // photo electric effect
+ // G3 default value: 1
+ // G4 processes: G4PhotoElectricEffect
+ // G4LowEnergyPhotoElectric
+ // Particles: gamma
+ // Physics: EM
+ // flag = 0 no photo electric effect
+ // flag = 1 photo electric effect, electron processed
+ // flag = 2 photo electric effect, no electron stored
+ // gMC ->SetProcess("PHOT",1); // EMFCUT 0. -1. 0. 3. lastmat 0. PHOT-THR
+ else if (strncmp(&sProcessFlag[i][0],"PHOT",4) == 0) {
+ if (iProcessValue[i] == 1 || iProcessValue[i] == 2) {
+ fprintf(pAliceInp,"*\n*Photo electric effect is activated\n");
+ fprintf(pAliceInp,"*Generated from call: SetProcess('PHOT',1);\n");
+ // zero = ignored
+ // - one = resets to default=0.
+ // zero = ignored
+ // three = lower bound of the material indices in which the respective thresholds apply
+ // fLastMaterial = upper bound of the material indices in which the respective thresholds apply
+ // one = step length in assigning indices
+ //"PHOT-THR";
+ fprintf(pAliceInp,"EMFCUT %10.1f%10.1f%10.1f%10.1f%10.1f%10.1fPHOT-THR\n",zero,-one,zero,three,fLastMaterial,one);
+ }
+ else if (iProcessValue[i] == 0) {
+ fprintf(pAliceInp,"*\n*No photo electric effect - no FLUKA card generated\n");
+ fprintf(pAliceInp,"*Generated from call: SetProcess('PHOT',0)\n");
+ }
+ else {
+ fprintf(pAliceInp,"*\n*Illegal flag value in SetProcess('PHOT',?) call.\n");
+ fprintf(pAliceInp,"*No FLUKA card generated\n");
+ }
+ } // else if (strncmp(&sProcessFlag[i][0],"PHOT",4) == 0)
+
+
+ // Rayleigh scattering
+ // G3 default value: 0
+ // G4 process: G4OpRayleigh
+ //
+ // Particles: optical photon
+ // Physics: Optical
+ // flag = 0 Rayleigh scattering off
+ // flag = 1 Rayleigh scattering on
+ //xx gMC ->SetProcess("RAYL",1);
+ else if (strncmp(&sProcessFlag[i][0],"RAYL",4) == 0) {
+ if (iProcessValue[i] == 1) {
+ fprintf(pAliceInp,"*\n*Rayleigh scattering is ON by default in FLUKA\n");
+ fprintf(pAliceInp,"*No FLUKA card generated\n");
+ }
+ else if (iProcessValue[i] == 0) {
+ fprintf(pAliceInp,"*\n*Rayleigh scattering is set OFF\n");
+ fprintf(pAliceInp,"*Generated from call: SetProcess('RAYL',0);\n");
+ // - one = no Rayleigh scattering and no binding corrections for Compton
+ // three = lower bound of the material indices in which the respective thresholds apply
+ // fLastMaterial = upper bound of the material indices in which the respective thresholds apply
+ fprintf(pAliceInp,"EMFRAY %10.1f%10.1f%10.1f%10.1f\n",-one,three,three,fLastMaterial);
+ }
+ else {
+ fprintf(pAliceInp,"*\n*Illegal flag value in SetProcess('RAYL',?) call.\n");
+ fprintf(pAliceInp,"*No FLUKA card generated\n");
+ }
+ } // end of else if (strncmp(&sProcessFlag[i][0],"RAYL",4) == 0)
+
+
+ // synchrotron radiation in magnetic field
+ // G3 default value: 0
+ // G4 process: G4SynchrotronRadiation
+ //
+ // Particles: ??
+ // Physics: Not set
+ // flag = 0 no synchrotron radiation
+ // flag = 1 synchrotron radiation
+ //xx gMC ->SetProcess("SYNC",1); // synchrotron radiation generation
+ else if (strncmp(&sProcessFlag[i][0],"SYNC",4) == 0) {
+ fprintf(pAliceInp,"*\n*Synchrotron radiation generation is NOT implemented in FLUKA\n");
+ fprintf(pAliceInp,"*No FLUKA card generated\n");
+ }
+
+
+ // Automatic calculation of tracking medium parameters
+ // flag = 0 no automatic calculation
+ // flag = 1 automatic calculation
+ //xx gMC ->SetProcess("AUTO",1); // ??? automatic computation of the tracking medium parameters
+ else if (strncmp(&sProcessFlag[i][0],"AUTO",4) == 0) {
+ fprintf(pAliceInp,"*\n*Automatic calculation of tracking medium parameters is always ON in FLUKA\n");
+ fprintf(pAliceInp,"*No FLUKA card generated\n");
+ }
+
+
+ // To control energy loss fluctuation model
+ // flag = 0 Urban model
+ // flag = 1 PAI model
+ // flag = 2 PAI+ASHO model (not active at the moment)
+ //xx gMC ->SetProcess("STRA",1); // ??? energy fluctuation model
+ else if (strncmp(&sProcessFlag[i][0],"STRA",4) == 0) {
+ if (iProcessValue[i] == 0 || iProcessValue[i] == 2 || iProcessValue[i] == 3) {
+ fprintf(pAliceInp,"*\n*Ionization energy losses calculation is activated\n");
+ fprintf(pAliceInp,"*Generated from call: SetProcess('STRA',n);, n=0,1,2\n");
+ // one = restricted energy loss fluctuations (for hadrons and muons) switched on
+ // one = restricted energy loss fluctuations (for e+ and e-) switched on
+ // one = minimal accuracy
+ // three = lower bound of the material indices in which the respective thresholds apply
+ // fLastMaterial = upper bound of the material indices in which the respective thresholds apply
+ fprintf(pAliceInp,"IONFLUCT %10.1f%10.1f%10.1f%10.1f%10.1f\n",one,one,one,three,fLastMaterial);
+ }
+ else {
+ fprintf(pAliceInp,"*\n*Illegal flag value in SetProcess('STRA',?) call.\n");
+ fprintf(pAliceInp,"*No FLUKA card generated\n");
+ }
+ } // else if (strncmp(&sProcessFlag[i][0],"STRA",4) == 0)
+
+
+
+
+ else { // processes not yet treated
+
+ // light photon absorption (Cerenkov photons)
+ // it is turned on when Cerenkov process is turned on
+ // G3 default value: 0
+ // G4 process: G4OpAbsorption, G4OpBoundaryProcess
+ //
+ // Particles: optical photon
+ // Physics: Optical
+ // flag = 0 no absorption of Cerenkov photons
+ // flag = 1 absorption of Cerenkov photons
+ // gMC ->SetProcess("LABS",2); // ??? Cerenkov light absorption
+
+
+
+ cout << "SetProcess for flag=" << &sProcessFlag[i][0] << " value=" << iProcessValue[i] << " not yet implemented!" << endl;
+ }
+ } //end of loop number of SetProcess calls
+
+
+// Loop over number of SetCut calls
+ for (Int_t i=0; i<iNbOfCut; i++) {
+
+ // cuts used in SetProcess calls
+ if (strncmp(&sCutFlag[i][0],"BCUTM",5) == 0) continue;
+ else if (strncmp(&sCutFlag[i][0],"BCUTE",5) == 0) continue;
+ else if (strncmp(&sCutFlag[i][0],"DCUTM",5) == 0) continue;
+ else if (strncmp(&sCutFlag[i][0],"PPCUTM",6) == 0) continue;
+
+ // gammas
+ // G4 particles: "gamma"
+ // G3 default value: 0.001 GeV
+ //gMC ->SetCut("CUTGAM",cut); // cut for gammas
+ else if (strncmp(&sCutFlag[i][0],"CUTGAM",6) == 0) {
+ fprintf(pAliceInp,"*\n*Cut for gamma\n");
+ fprintf(pAliceInp,"*Generated from call: SetCut('CUTGAM',cut);\n");
+ // -fCutValue[i];
+ // 7.0 = lower bound of the particle id-numbers to which the cut-off
+ fprintf(pAliceInp,"PART-THR %10.4g%10.1f\n",-fCutValue[i],7.0);
+ }
+
+ // electrons
+ // G4 particles: "e-"
+ // ?? positrons
+ // G3 default value: 0.001 GeV
+ //gMC ->SetCut("CUTELE",cut); // cut for e+,e-
+ else if (strncmp(&sCutFlag[i][0],"CUTELE",6) == 0) {
+ fprintf(pAliceInp,"*\n*Cut for electrons\n");
+ fprintf(pAliceInp,"*Generated from call: SetCut('CUTELE',cut);\n");
+ // -fCutValue[i];
+ // three = lower bound of the particle id-numbers to which the cut-off
+ // 4.0 = upper bound of the particle id-numbers to which the cut-off
+ // one = step length in assigning numbers
+ fprintf(pAliceInp,"PART-THR %10.4g%10.1f%10.1f%10.1f\n",-fCutValue[i],three,4.0,one);
+ }
+
+ // neutral hadrons
+ // G4 particles: of type "baryon", "meson", "nucleus" with zero charge
+ // G3 default value: 0.01 GeV
+ //gMC ->SetCut("CUTNEU",cut); // cut for neutral hadrons
+ else if (strncmp(&sCutFlag[i][0],"CUTNEU",6) == 0) {
+ fprintf(pAliceInp,"*\n*Cut for neutral hadrons\n");
+ fprintf(pAliceInp,"*Generated from call: SetCut('CUTNEU',cut);\n");
+
+ // 8.0 = Neutron
+ // 9.0 = Antineutron
+ fprintf(pAliceInp,"PART-THR %10.4g%10.1f%10.1f\n",-fCutValue[i],8.0,9.0);
+
+ // 12.0 = Kaon zero long
+ // 12.0 = Kaon zero long
+ fprintf(pAliceInp,"PART-THR %10.4g%10.1f%10.1f\n",-fCutValue[i],12.0,12.0);
+
+ // 17.0 = Lambda, 18.0 = Antilambda
+ // 19.0 = Kaon zero short
+ fprintf(pAliceInp,"PART-THR %10.4g%10.1f%10.1f\n",-fCutValue[i],17.0,19.0);
+
+ // 22.0 = Sigma zero, Pion zero, Kaon zero
+ // 25.0 = Antikaon zero
+ fprintf(pAliceInp,"PART-THR %10.4g%10.1f%10.1f\n",-fCutValue[i],22.0,25.0);
+
+ // 32.0 = Antisigma zero
+ // 32.0 = Antisigma zero
+ fprintf(pAliceInp,"PART-THR %10.4g%10.1f%10.1f\n",-fCutValue[i],32.0,32.0);
+
+ // 34.0 = Xi zero
+ // 35.0 = AntiXi zero
+ fprintf(pAliceInp,"PART-THR %10.4g%10.1f%10.1f\n",-fCutValue[i],34.0,35.0);
+
+ // 47.0 = D zero
+ // 48.0 = AntiD zero
+ fprintf(pAliceInp,"PART-THR %10.4g%10.1f%10.1f\n",-fCutValue[i],47.0,48.0);
+
+ // 53.0 = Xi_c zero
+ // 53.0 = Xi_c zero
+ fprintf(pAliceInp,"PART-THR %10.4g%10.1f%10.1f\n",-fCutValue[i],53.0,53.0);
+
+ // 55.0 = Xi'_c zero
+ // 56.0 = Omega_c zero
+ fprintf(pAliceInp,"PART-THR %10.4g%10.1f%10.1f\n",-fCutValue[i],55.0,56.0);
+
+ // 59.0 = AntiXi_c zero
+ // 59.0 = AntiXi_c zero
+ fprintf(pAliceInp,"PART-THR %10.4g%10.1f%10.1f\n",-fCutValue[i],59.0,59.0);
+
+ // 61.0 = AntiXi'_c zero
+ // 62.0 = AntiOmega_c zero
+ fprintf(pAliceInp,"PART-THR %10.4g%10.1f%10.1f\n",-fCutValue[i],61.0,62.0);
+ }
+
+ // charged hadrons
+ // G4 particles: of type "baryon", "meson", "nucleus" with non-zero charge
+ // G3 default value: 0.01 GeV
+ //gMC ->SetCut("CUTHAD",cut); // cut for charged hadrons
+ else if (strncmp(&sCutFlag[i][0],"CUTHAD",6) == 0) {
+ fprintf(pAliceInp,"*\n*Cut for charged hadrons\n");
+ fprintf(pAliceInp,"*Generated from call: SetCut('CUTHAD',cut);\n");
+
+ // 1.0 = Proton
+ // 2.0 = Antiproton
+ fprintf(pAliceInp,"PART-THR %10.4g%10.1f%10.1f\n",-fCutValue[i],1.0,2.0);
+
+ // 13.0 = Positive Pion, Negative Pion, Positive Kaon
+ // 16.0 = Negative Kaon
+ fprintf(pAliceInp,"PART-THR %10.4g%10.1f%10.1f\n",-fCutValue[i],13.0,16.0);
+
+ // 20.0 = Negative Sigma
+ // 21.0 = Positive Sigma
+ fprintf(pAliceInp,"PART-THR %10.4g%10.1f%10.1f\n",-fCutValue[i],20.0,21.0);
+
+ // 31.0 = Antisigma minus
+ // 33.0 = Antisigma plus
+ // 2.0 = step length
+ fprintf(pAliceInp,"PART-THR %10.4g%10.1f%10.1f%10.1f\n",-fCutValue[i],31.0,33.0,2.0);
+
+ // 36.0 = Negative Xi, Positive Xi, Omega minus
+ // 39.0 = Antiomega
+ fprintf(pAliceInp,"PART-THR %10.4g%10.1f%10.1f\n",-fCutValue[i],36.0,39.0);
+
+ // 45.0 = D plus
+ // 46.0 = D minus
+ fprintf(pAliceInp,"PART-THR %10.4g%10.1f%10.1f\n",-fCutValue[i],45.0,46.0);
+
+ // 49.0 = D_s plus, D_s minus, Lambda_c plus
+ // 52.0 = Xi_c plus
+ fprintf(pAliceInp,"PART-THR %10.4g%10.1f%10.1f\n",-fCutValue[i],49.0,52.0);
+
+ // 54.0 = Xi'_c plus
+ // 60.0 = AntiXi'_c minus
+ // 6.0 = step length
+ fprintf(pAliceInp,"PART-THR %10.4g%10.1f%10.1f%10.1f\n",-fCutValue[i],54.0,60.0,6.0);
+
+ // 57.0 = Antilambda_c minus
+ // 58.0 = AntiXi_c minus
+ fprintf(pAliceInp,"PART-THR %10.4g%10.1f%10.1f\n",-fCutValue[i],57.0,58.0);
+ }
+
+ // muons
+ // G4 particles: "mu+", "mu-"
+ // G3 default value: 0.01 GeV
+ //gMC ->SetCut("CUTMUO",cut); // cut for mu+, mu-
+ else if (strncmp(&sCutFlag[i][0],"CUTMUO",6) == 0) {
+ fprintf(pAliceInp,"*\n*Cut for muons\n");
+ fprintf(pAliceInp,"*Generated from call: SetCut('CUTMUO',cut);\n");
+ // 10.0 = Muon+
+ // 11.0 = Muon-
+ fprintf(pAliceInp,"PART-THR %10.4g%10.1f%10.1f\n",-fCutValue[i],10.0,11.0);
+ }
+
+ // delta-rays by electrons
+ // G4 particles: "e-"
+ // G3 default value: 10**4 GeV
+ // gMC ->SetCut("DCUTE",cut); // cut for deltarays by electrons ???????????????
+ else if (strncmp(&sCutFlag[i][0],"DCUTE",5) == 0) {
+ fprintf(pAliceInp,"*\n*Cut for delta rays by electrons ????????????\n");
+ fprintf(pAliceInp,"*Generated from call: SetCut('DCUTE',cut);\n");
+ // -fCutValue[i];
+ // zero = ignored
+ // zero = ignored
+ // three = lower bound of the material indices in which the respective thresholds apply
+ // fLastMaterial = upper bound of the material indices in which the respective thresholds apply
+ fprintf(pAliceInp,"EMFCUT %10.4g%10.1f%10.1f%10.1f%10.1f\n",-fCutValue[i],zero,zero,three,fLastMaterial);
+ }
+
+ //
+ // time of flight cut in seconds
+ // G4 particles: all
+ // G3 default value: 0.01 GeV
+ //gMC ->SetCut("TOFMAX",tofmax); // time of flight cuts in seconds
+ else if (strncmp(&sCutFlag[i][0],"TOFMAX",6) == 0) {
+ fprintf(pAliceInp,"*\n*Time of flight cuts in seconds\n");
+ fprintf(pAliceInp,"*Generated from call: SetCut('TOFMAX',tofmax);\n");
+ // zero = ignored
+ // zero = ignored
+ // -6.0 = lower bound of the particle numbers for which the transport time cut-off and/or the start signal is to be applied
+ // 64.0 = upper bound of the particle numbers for which the transport time cut-off and/or the start signal is to be applied
+ 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);
+ }
+
+ else {
+ cout << "SetCut for flag=" << &sCutFlag[i][0] << " value=" << fCutValue[i] << " not yet implemented!" << endl;
+ }
+ } //end of loop over SetCut calls
+
+// Add START and STOP card
+ fprintf(pAliceInp,"START %10.1f\n",fEventsPerRun);
+ fprintf(pAliceInp,"STOP \n");
+
+} // end of InitPhysics
+
+
void TFluka::SetMaxStep(Double_t)
{
// SetMaxStep is dummy procedure in TFluka !
+ if (fVerbosityLevel >=3)
cout << "SetMaxStep is dummy procedure in TFluka !" << endl;
}
void TFluka::SetMaxNStep(Int_t)
{
// SetMaxNStep is dummy procedure in TFluka !
+ if (fVerbosityLevel >=3)
cout << "SetMaxNStep is dummy procedure in TFluka !" << endl;
}
void TFluka::SetUserDecay(Int_t)
{
// SetUserDecay is dummy procedure in TFluka !
+ if (fVerbosityLevel >=3)
cout << "SetUserDecay is dummy procedure in TFluka !" << endl;
}
// TRACKR.xtrack = x-position of the last point
// TRACKR.ytrack = y-position of the last point
// TRACKR.ztrack = z-position of the last point
- position.SetX(TRACKR.xtrack[TRACKR.ntrack]);
- position.SetY(TRACKR.ytrack[TRACKR.ntrack]);
- position.SetZ(TRACKR.ztrack[TRACKR.ntrack]);
- position.SetT(TRACKR.atrack);
+ Int_t caller = GetCaller();
+ if (caller == 3 || caller == 6 || caller == 11 || caller == 12) { //bxdraw,endraw,usdraw
+ position.SetX(GetXsco());
+ position.SetY(GetYsco());
+ position.SetZ(GetZsco());
+ position.SetT(TRACKR.atrack);
+ }
+ else if (caller == 4) { // mgdraw
+ position.SetX(TRACKR.xtrack[TRACKR.ntrack]);
+ position.SetY(TRACKR.ytrack[TRACKR.ntrack]);
+ position.SetZ(TRACKR.ztrack[TRACKR.ntrack]);
+ position.SetT(TRACKR.atrack);
+ }
+ else if (caller == 5) { // sodraw
+ position.SetX(TRACKR.xtrack[TRACKR.ntrack]);
+ position.SetY(TRACKR.ytrack[TRACKR.ntrack]);
+ position.SetZ(TRACKR.ztrack[TRACKR.ntrack]);
+ position.SetT(0);
+ }
+ else
+ Warning("TrackPosition","position not available");
+}
+
+//
+void TFluka::TrackPosition(Double_t& x, Double_t& y, Double_t& z) const
+{
+// Return the current position in the master reference frame of the
+// track being transported
+// TRACKR.atrack = age of the particle
+// TRACKR.xtrack = x-position of the last point
+// TRACKR.ytrack = y-position of the last point
+// TRACKR.ztrack = z-position of the last point
+ Int_t caller = GetCaller();
+ if (caller == 3 || caller == 6 || caller == 11 || caller == 12) { //bxdraw,endraw,usdraw
+ x = GetXsco();
+ y = GetYsco();
+ z = GetZsco();
+ }
+ else if (caller == 4 || caller == 5) { // mgdraw, sodraw
+ x = TRACKR.xtrack[TRACKR.ntrack];
+ y = TRACKR.ytrack[TRACKR.ntrack];
+ z = TRACKR.ztrack[TRACKR.ntrack];
+ }
+ else
+ Warning("TrackPosition","position not available");
}
void TFluka::TrackMomentum(TLorentzVector& momentum) const
// TRACKR.etrack = total energy of the particle
// TRACKR.jtrack = identity number of the particle
// PAPROP.am[TRACKR.jtrack] = particle mass in gev
- if (TRACKR.ptrack >= 0) {
- momentum.SetPx(TRACKR.ptrack*TRACKR.cxtrck);
- momentum.SetPy(TRACKR.ptrack*TRACKR.cytrck);
- momentum.SetPz(TRACKR.ptrack*TRACKR.cztrck);
- momentum.SetE(TRACKR.etrack);
- return;
+ Int_t caller = GetCaller();
+ if (caller != 2) { // not eedraw
+ if (TRACKR.ptrack >= 0) {
+ momentum.SetPx(TRACKR.ptrack*TRACKR.cxtrck);
+ momentum.SetPy(TRACKR.ptrack*TRACKR.cytrck);
+ momentum.SetPz(TRACKR.ptrack*TRACKR.cztrck);
+ momentum.SetE(TRACKR.etrack);
+ return;
+ }
+ else {
+ Double_t p = sqrt(TRACKR.etrack*TRACKR.etrack - PAPROP.am[TRACKR.jtrack+6]*PAPROP.am[TRACKR.jtrack+6]);
+ momentum.SetPx(p*TRACKR.cxtrck);
+ momentum.SetPy(p*TRACKR.cytrck);
+ momentum.SetPz(p*TRACKR.cztrck);
+ momentum.SetE(TRACKR.etrack);
+ return;
+ }
}
- else {
- Double_t p = sqrt(TRACKR.etrack*TRACKR.etrack - PAPROP.am[TRACKR.jtrack+6]*PAPROP.am[TRACKR.jtrack+6]);
- momentum.SetPx(p*TRACKR.cxtrck);
- momentum.SetPy(p*TRACKR.cytrck);
- momentum.SetPz(p*TRACKR.cztrck);
- momentum.SetE(TRACKR.etrack);
- return;
+ else
+ Warning("TrackMomentum","momentum not available");
+}
+
+void TFluka::TrackMomentum(Double_t& px, Double_t& py, Double_t& pz, Double_t& e) const
+{
+// Return the direction and the momentum (GeV/c) of the track
+// currently being transported
+// TRACKR.ptrack = momentum of the particle (not always defined, if
+// < 0 must be obtained from etrack)
+// TRACKR.cx,y,ztrck = direction cosines of the current particle
+// TRACKR.etrack = total energy of the particle
+// TRACKR.jtrack = identity number of the particle
+// PAPROP.am[TRACKR.jtrack] = particle mass in gev
+ Int_t caller = GetCaller();
+ if (caller != 2) { // not eedraw
+ if (TRACKR.ptrack >= 0) {
+ px = TRACKR.ptrack*TRACKR.cxtrck;
+ py = TRACKR.ptrack*TRACKR.cytrck;
+ pz = TRACKR.ptrack*TRACKR.cztrck;
+ e = TRACKR.etrack;
+ return;
+ }
+ else {
+ Double_t p = sqrt(TRACKR.etrack*TRACKR.etrack - PAPROP.am[TRACKR.jtrack+6]*PAPROP.am[TRACKR.jtrack+6]);
+ px = p*TRACKR.cxtrck;
+ py = p*TRACKR.cytrck;
+ pz = p*TRACKR.cztrck;
+ e = TRACKR.etrack;
+ return;
+ }
}
+ else
+ Warning("TrackMomentum","momentum not available");
}
Double_t TFluka::TrackStep() const
{
// Return the length in centimeters of the current step
// TRACKR.ctrack = total curved path
+ Int_t caller = GetCaller();
+ if (caller == 11 || caller==12 || caller == 3 || caller == 6) //bxdraw,endraw,usdraw
+ return 0.0;
+ else if (caller == 4) //mgdraw
return TRACKR.ctrack;
+ else
+ return -1.0;
}
Double_t TFluka::TrackLength() const
{
-// Still wrong !!!
-// This is the sum of substeps !!!
-// TRACKR.ctrack = total curved path of the current step
-// Sum of the substeps is identical to TRACKR.ctrack if the is no mag. field
-// The sum of all step length starting from the beginning of the track
-// for the time being returns only the length in centimeters of the current step
- Double_t sum = 0;
- for ( Int_t j=0;j<TRACKR.ntrack;j++) {
- sum +=TRACKR.ttrack[j];
- }
- return sum;
+// TRACKR.cmtrck = cumulative curved path since particle birth
+ Int_t caller = GetCaller();
+ if (caller == 11 || caller==12 || caller == 3 || caller == 4 || caller == 6) //bxdraw,endraw,mgdraw,usdraw
+ return TRACKR.cmtrck;
+ else
+ return -1.0;
}
Double_t TFluka::TrackTime() const
{
// Return the current time of flight of the track being transported
// TRACKR.atrack = age of the particle
- return TRACKR.atrack;
+ Int_t caller = GetCaller();
+ if (caller == 11 || caller==12 || caller == 3 || caller == 4 || caller == 6) //bxdraw,endraw,mgdraw,usdraw
+ return TRACKR.atrack;
+ else
+ return -1;
}
Double_t TFluka::Edep() const
// if TRACKR.ntrack > 0, TRACKR.mtrack > 0:
// -->energy loss distributed along the track
// TRACKR.dtrack = energy deposition of the jth deposition even
+
+ // If coming from bxdraw we have 2 steps of 0 length and 0 edep
+ Int_t caller = GetCaller();
+ if (caller == 11 || caller==12) return 0.0;
+ Double_t sum = 0;
+ for ( Int_t j=0;j<TRACKR.mtrack;j++) {
+ sum +=TRACKR.dtrack[j];
+ }
if (TRACKR.ntrack == 0 && TRACKR.mtrack == 0)
- return fRull;
+ return fRull + sum;
else {
- Double_t sum = 0;
- for ( Int_t j=0;j<TRACKR.mtrack;j++) {
- sum +=TRACKR.dtrack[j];
- }
return sum;
}
}
{
// Return the id of the particle transported
// TRACKR.jtrack = identity number of the particle
- return PDGFromId(TRACKR.jtrack);
+ Int_t caller = GetCaller();
+ if (caller != 2) // not eedraw
+ return PDGFromId(TRACKR.jtrack);
+ else
+ return -1000;
}
Double_t TFluka::TrackCharge() const
// Return charge of the track currently transported
// PAPROP.ichrge = electric charge of the particle
// TRACKR.jtrack = identity number of the particle
- return PAPROP.ichrge[TRACKR.jtrack+6];
+ Int_t caller = GetCaller();
+ if (caller != 2) // not eedraw
+ return PAPROP.ichrge[TRACKR.jtrack+6];
+ else
+ return -1000.0;
}
Double_t TFluka::TrackMass() const
{
// PAPROP.am = particle mass in GeV
// TRACKR.jtrack = identity number of the particle
- return PAPROP.am[TRACKR.jtrack+6];
+ Int_t caller = GetCaller();
+ if (caller != 2) { // not eedraw
+// cout << "JTRACK=" << TRACKR.jtrack << " mass=" << PAPROP.am[TRACKR.jtrack+6] << endl;
+ return PAPROP.am[TRACKR.jtrack+6];
+ }
+ else
+ return -1000.0;
}
Double_t TFluka::Etot() const
{
// TRACKR.etrack = total energy of the particle
- return TRACKR.etrack;
+ Int_t caller = GetCaller();
+ if (caller != 2) // not eedraw
+ return TRACKR.etrack;
+ else
+ return -1000.0;
}
//
//
Bool_t TFluka::IsNewTrack() const
{
-// ???????????????,
-// True if the track is not at the boundary of the current volume
-// Not true in some cases in bxdraw - to be solved
- return 1;
+// Return true for the first call of Stepping()
+ return fTrackIsNew;
}
Bool_t TFluka::IsTrackInside() const
// If the step would go behind the region of one material,
// it will be shortened to reach only the boundary.
// Therefore IsTrackInside() is always true.
-// Not true in some cases in bxdraw - to be solved
- return 1;
+ Int_t caller = GetCaller();
+ if (caller == 11 || caller==12) // bxdraw
+ return 0;
+ else
+ return 1;
}
Bool_t TFluka::IsTrackEntering() const
{
// True if this is the first step of the track in the current volume
-// Boundary- (X) crossing
-// Icode = 19: boundary crossing - call from Kaskad
-// Icode = 29: boundary crossing - call from Emfsco
-// Icode = 39: boundary crossing - call from Kasneu
-// Icode = 49: boundary crossing - call from Kashea
-// Icode = 59: boundary crossing - call from Kasoph
- if (fIcode == 19 ||
- fIcode == 29 ||
- fIcode == 39 ||
- fIcode == 49 ||
- fIcode == 59) return 1;
+
+ Int_t caller = GetCaller();
+ if (caller == 11) // bxdraw entering
+ return 1;
else return 0;
}
Bool_t TFluka::IsTrackExiting() const
{
-// True if this is the last step of the track in the current volume
-// Boundary- (X) crossing
-// Icode = 19: boundary crossing - call from Kaskad
-// Icode = 29: boundary crossing - call from Emfsco
-// Icode = 39: boundary crossing - call from Kasneu
-// Icode = 49: boundary crossing - call from Kashea
-// Icode = 59: boundary crossing - call from Kasoph
- if (fIcode == 19 ||
- fIcode == 29 ||
- fIcode == 39 ||
- fIcode == 49 ||
- fIcode == 59) return 1;
+ Int_t caller = GetCaller();
+ if (caller == 12) // bxdraw exiting
+ return 1;
else return 0;
}
// FINUC.np = number of secondaries except light and heavy ions
// FHEAVY.npheav = number of secondaries for light and heavy secondary ions
{
- return FINUC.np + FHEAVY.npheav;
-}
+ Int_t caller = GetCaller();
+ if (caller == 6) // valid only after usdraw
+ return FINUC.np + FHEAVY.npheav;
+ else
+ return 0;
+} // end of NSecondaries
void TFluka::GetSecondary(Int_t isec, Int_t& particleId,
TLorentzVector& position, TLorentzVector& momentum)
{
- if (isec >= 0 && isec < FINUC.np) {
- // more fine condition depending on icode
- // icode = 100 ?
- // icode = 101 OK
- // icode = 102 OK
- // icode = 103 ?
- // icode = 104 ?
- // icode = 105 ?
- // icode = 208 ?
- // icode = 210 ?
- // icode = 212 ?
- // icode = 214 OK
- // icode = 215 OK
- // icode = 219 ?
- // icode = 221 OK
- // icode = 225 ?
- // icode = 300 ?
- // icode = 400 ?
-
- particleId = PDGFromId(FINUC.kpart[isec]);
- position.SetX(fXsco);
- position.SetY(fYsco);
- position.SetZ(fZsco);
- position.SetT(TRACKR.atrack);
-// position.SetT(TRACKR.atrack+FINUC.agesec[isec]); //not yet implem.
- momentum.SetPx(FINUC.plr[isec]*FINUC.cxr[isec]);
- momentum.SetPy(FINUC.plr[isec]*FINUC.cyr[isec]);
- momentum.SetPz(FINUC.plr[isec]*FINUC.czr[isec]);
- momentum.SetE(FINUC.tki[isec] + PAPROP.am[FINUC.kpart[isec]+6]);
- }
- if (isec >= FINUC.np && isec < FINUC.np + FHEAVY.npheav) {
- Int_t jsec = isec - FINUC.np;
- particleId = FHEAVY.kheavy[jsec]; // this is Fluka id !!!
- position.SetX(fXsco);
- position.SetY(fYsco);
- position.SetZ(fZsco);
- position.SetT(TRACKR.atrack);
-// position.SetT(TRACKR.atrack+FHEAVY.agheav[jsec]); //not yet implem.
- momentum.SetPx(FHEAVY.pheavy[jsec]*FHEAVY.cxheav[jsec]);
- momentum.SetPy(FHEAVY.pheavy[jsec]*FHEAVY.cyheav[jsec]);
- momentum.SetPz(FHEAVY.pheavy[jsec]*FHEAVY.czheav[jsec]);
- if (FHEAVY.tkheav[jsec] >= 3 && FHEAVY.tkheav[jsec] <= 6)
- momentum.SetE(FHEAVY.tkheav[jsec] + PAPROP.am[jsec+6]);
- else if (FHEAVY.tkheav[jsec] > 6)
- momentum.SetE(FHEAVY.tkheav[jsec] + FHEAVY.amnhea[jsec]); // to be checked !!!
+ Int_t caller = GetCaller();
+ if (caller == 6) { // valid only after usdraw
+ if (isec >= 0 && isec < FINUC.np) {
+ particleId = PDGFromId(FINUC.kpart[isec]);
+ position.SetX(fXsco);
+ position.SetY(fYsco);
+ position.SetZ(fZsco);
+ position.SetT(TRACKR.atrack);
+ momentum.SetPx(FINUC.plr[isec]*FINUC.cxr[isec]);
+ momentum.SetPy(FINUC.plr[isec]*FINUC.cyr[isec]);
+ momentum.SetPz(FINUC.plr[isec]*FINUC.czr[isec]);
+ momentum.SetE(FINUC.tki[isec] + PAPROP.am[FINUC.kpart[isec]+6]);
}
-}
+ else if (isec >= FINUC.np && isec < FINUC.np + FHEAVY.npheav) {
+ Int_t jsec = isec - FINUC.np;
+ particleId = FHEAVY.kheavy[jsec]; // this is Fluka id !!!
+ position.SetX(fXsco);
+ position.SetY(fYsco);
+ position.SetZ(fZsco);
+ position.SetT(TRACKR.atrack);
+ momentum.SetPx(FHEAVY.pheavy[jsec]*FHEAVY.cxheav[jsec]);
+ momentum.SetPy(FHEAVY.pheavy[jsec]*FHEAVY.cyheav[jsec]);
+ momentum.SetPz(FHEAVY.pheavy[jsec]*FHEAVY.czheav[jsec]);
+ if (FHEAVY.tkheav[jsec] >= 3 && FHEAVY.tkheav[jsec] <= 6)
+ momentum.SetE(FHEAVY.tkheav[jsec] + PAPROP.am[jsec+6]);
+ else if (FHEAVY.tkheav[jsec] > 6)
+ momentum.SetE(FHEAVY.tkheav[jsec] + FHEAVY.amnhea[jsec]); // to be checked !!!
+ }
+ else
+ Warning("GetSecondary","isec out of range");
+ }
+ else
+ Warning("GetSecondary","no secondaries available");
+} // end of GetSecondary
-TMCProcess TFluka::ProdProcess(Int_t isec) const
+TMCProcess TFluka::ProdProcess(Int_t) const
// Name of the process that has produced the secondary particles
// in the current step
{
- const TMCProcess kIpNoProc = kPNoProcess;
- const TMCProcess kIpPDecay = kPDecay;
- const TMCProcess kIpPPair = kPPair;
-//const TMCProcess kIpPPairFromPhoton = kPPairFromPhoton;
-//const TMCProcess kIpPPairFromVirtualPhoton = kPPairFromVirtualPhoton;
- const TMCProcess kIpPCompton = kPCompton;
- const TMCProcess kIpPPhotoelectric = kPPhotoelectric;
- const TMCProcess kIpPBrem = kPBrem;
-//const TMCProcess kIpPBremFromHeavy = kPBremFromHeavy;
-//const TMCProcess kIpPBremFromElectronOrPositron = kPBremFromElectronOrPositron;
- const TMCProcess kIpPDeltaRay = kPDeltaRay;
-//const TMCProcess kIpPMoller = kPMoller;
-//const TMCProcess kIpPBhabha = kPBhabha;
- const TMCProcess kIpPAnnihilation = kPAnnihilation;
-//const TMCProcess kIpPAnnihilInFlight = kPAnnihilInFlight;
-//const TMCProcess kIpPAnnihilAtRest = kPAnnihilAtRest;
- const TMCProcess kIpPHadronic = kPHadronic;
- const TMCProcess kIpPMuonNuclear = kPMuonNuclear;
- const TMCProcess kIpPPhotoFission = kPPhotoFission;
- const TMCProcess kIpPRayleigh = kPRayleigh;
+ const TMCProcess kIpNoProc = kPNoProcess;
+ const TMCProcess kIpPDecay = kPDecay;
+ const TMCProcess kIpPPair = kPPair;
+// const TMCProcess kIpPPairFromPhoton = kPPairFromPhoton;
+// const TMCProcess kIpPPairFromVirtualPhoton = kPPairFromVirtualPhoton;
+ const TMCProcess kIpPCompton = kPCompton;
+ const TMCProcess kIpPPhotoelectric = kPPhotoelectric;
+ const TMCProcess kIpPBrem = kPBrem;
+// const TMCProcess kIpPBremFromHeavy = kPBremFromHeavy;
+// const TMCProcess kIpPBremFromElectronOrPositron = kPBremFromElectronOrPositron;
+ const TMCProcess kIpPDeltaRay = kPDeltaRay;
+// const TMCProcess kIpPMoller = kPMoller;
+// const TMCProcess kIpPBhabha = kPBhabha;
+ const TMCProcess kIpPAnnihilation = kPAnnihilation;
+// const TMCProcess kIpPAnnihilInFlight = kPAnnihilInFlight;
+// const TMCProcess kIpPAnnihilAtRest = kPAnnihilAtRest;
+ const TMCProcess kIpPHadronic = kPHadronic;
+ const TMCProcess kIpPMuonNuclear = kPMuonNuclear;
+ const TMCProcess kIpPPhotoFission = kPPhotoFission;
+ const TMCProcess kIpPRayleigh = kPRayleigh;
// const TMCProcess kIpPCerenkov = kPCerenkov;
// const TMCProcess kIpPSynchrotron = kPSynchrotron;
- Int_t mugamma = TRACKR.jtrack == 7 || TRACKR.jtrack == 10 || TRACKR.jtrack == 11;
- if (fIcode == 102) return kIpPDecay;
- else if (fIcode == 104 || fIcode == 217) return kIpPPair;
-//else if (fIcode == 104) return kIpPairFromPhoton;
-//else if (fIcode == 217) return kIpPPairFromVirtualPhoton;
- else if (fIcode == 219) return kIpPCompton;
- else if (fIcode == 221) return kIpPPhotoelectric;
- else if (fIcode == 105 || fIcode == 208) return kIpPBrem;
-//else if (fIcode == 105) return kIpPBremFromHeavy;
-//else if (fIcode == 208) return kPBremFromElectronOrPositron;
- else if (fIcode == 103 || fIcode == 400) return kIpPDeltaRay;
- else if (fIcode == 210 || fIcode == 212) return kIpPDeltaRay;
-//else if (fIcode == 210) return kIpPMoller;
-//else if (fIcode == 212) return kIpPBhabha;
- else if (fIcode == 214 || fIcode == 215) return kIpPAnnihilation;
-//else if (fIcode == 214) return kIpPAnnihilInFlight;
-//else if (fIcode == 215) return kIpPAnnihilAtRest;
- else if (fIcode == 101) return kIpPHadronic;
- else if (fIcode == 101) {
- if (!mugamma) return kIpPHadronic;
- else if (TRACKR.jtrack == 7) return kIpPPhotoFission;
- else return kIpPMuonNuclear;
- }
- else if (fIcode == 225) return kIpPRayleigh;
+ Int_t mugamma = TRACKR.jtrack == 7 || TRACKR.jtrack == 10 || TRACKR.jtrack == 11;
+ if (fIcode == 102) return kIpPDecay;
+ else if (fIcode == 104 || fIcode == 217) return kIpPPair;
+// else if (fIcode == 104) return kIpPairFromPhoton;
+// else if (fIcode == 217) return kIpPPairFromVirtualPhoton;
+ else if (fIcode == 219) return kIpPCompton;
+ else if (fIcode == 221) return kIpPPhotoelectric;
+ else if (fIcode == 105 || fIcode == 208) return kIpPBrem;
+// else if (fIcode == 105) return kIpPBremFromHeavy;
+// else if (fIcode == 208) return kPBremFromElectronOrPositron;
+ else if (fIcode == 103 || fIcode == 400) return kIpPDeltaRay;
+ else if (fIcode == 210 || fIcode == 212) return kIpPDeltaRay;
+// else if (fIcode == 210) return kIpPMoller;
+// else if (fIcode == 212) return kIpPBhabha;
+ else if (fIcode == 214 || fIcode == 215) return kIpPAnnihilation;
+// else if (fIcode == 214) return kIpPAnnihilInFlight;
+// else if (fIcode == 215) return kIpPAnnihilAtRest;
+ else if (fIcode == 101) return kIpPHadronic;
+ else if (fIcode == 101) {
+ if (!mugamma) return kIpPHadronic;
+ else if (TRACKR.jtrack == 7) return kIpPPhotoFission;
+ else return kIpPMuonNuclear;
+ }
+ else if (fIcode == 225) return kIpPRayleigh;
// Fluka codes 100, 300 and 400 still to be investigasted
- else return kIpNoProc;
+ else return kIpNoProc;
}
//Int_t StepProcesses(TArrayI &proc) const
//
// Returns the material number for a given volume ID
//
- printf("VolId2Mate %d %d\n", id, fMediaByRegion[id]);
+ if (fVerbosityLevel >= 3)
+ printf("VolId2Mate %d %d\n", id, fMediaByRegion[id-1]);
return fMediaByRegion[id-1];
}
//
FlukaVolume* vol = dynamic_cast<FlukaVolume*>((*fVolumeMediaMap)[id-1]);
const char* name = vol->GetName();
+ if (fVerbosityLevel >= 3)
printf("VolName %d %s \n", id, name);
return name;
}
//
int ir = fCurrentFlukaRegion;
int id = (FGeometryInit::GetInstance())->CurrentVolID(ir, copyNo);
+ copyNo++;
+ if (fVerbosityLevel >= 3)
printf("CurrentVolID: %d %d %d \n", ir, id, copyNo);
return id;
-
}
Int_t TFluka::CurrentVolOffID(Int_t off, Int_t& copyNo) const
int ir = fCurrentFlukaRegion;
int id = (FGeometryInit::GetInstance())->CurrentVolOffID(ir, off, copyNo);
-
+ copyNo++;
+ if (fVerbosityLevel >= 3)
printf("CurrentVolOffID: %d %d %d \n", ir, id, copyNo);
if (id == -1)
+ if (fVerbosityLevel >= 0)
printf("CurrentVolOffID: Warning Mother not found !!!\n");
return id;
}
Int_t copy;
Int_t id = TFluka::CurrentVolID(copy);
const char* name = TFluka::VolName(id);
+ if (fVerbosityLevel >= 3)
printf("CurrentVolumeName: %d %s \n", fCurrentFlukaRegion, name);
return name;
}
Int_t copy;
Int_t id = TFluka::CurrentVolOffID(off, copy);
const char* name = TFluka::VolName(id);
+ if (fVerbosityLevel >= 3)
printf("CurrentVolumeOffName: %d %s \n", fCurrentFlukaRegion, name);
return name;
}
-Int_t TFluka::CurrentMaterial(Float_t &a, Float_t &z,
- Float_t &dens, Float_t &radl, Float_t &absl) const
+Int_t TFluka::CurrentMaterial(Float_t & /*a*/, Float_t & /*z*/,
+ Float_t & /*dens*/, Float_t & /*radl*/, Float_t & /*absl*/) const
{
//
// Return the current medium number
Int_t copy;
Int_t id = TFluka::CurrentVolID(copy);
Int_t med = TFluka::VolId2Mate(id);
+ if (fVerbosityLevel >= 3)
printf("CurrentMaterial: %d %d \n", fCurrentFlukaRegion, med);
return med;
}
// IFLAG=2 convert direction cosinus
//
// ---
- Double_t xmD[3], xdD[3];
- xdD[0] = xd[0]; xdD[1] = xd[1]; xdD[2] = xd[2];
- (FGeometryInit::GetInstance())->Gdtom(xmD, xdD, iflag);
- xm[0] = xmD[0]; xm[1] = xmD[1]; xm[2] = xmD[2];
+ (FGeometryInit::GetInstance())->Gmtod(xm, xd, iflag);
}
void TFluka::Gdtom(Float_t* xd, Float_t* xm, Int_t iflag)
// IFLAG=2 convert direction cosinus
//
// ---
-
-
+ Double_t xmD[3], xdD[3];
+ xdD[0] = xd[0]; xdD[1] = xd[1]; xdD[2] = xd[2];
+ (FGeometryInit::GetInstance())->Gdtom(xdD, xmD, iflag);
+ xm[0] = xmD[0]; xm[1] = xmD[1]; xm[2] = xmD[2];
}
void TFluka::Gdtom(Double_t* xd, Double_t* xm, Int_t iflag)
{
//
// ---
- (FGeometryInit::GetInstance())->Gdtom(xm, xd, iflag);
+ (FGeometryInit::GetInstance())->Gdtom(xd, xm, iflag);
}
// ===============================================================
-void TFluka::FutoTest()
-{
- Int_t icode, mreg, newreg, particleId;
-// Int_t medium;
- Double_t rull, xsco, ysco, zsco;
- TLorentzVector position, momentum;
- icode = GetIcode();
- if (icode == 0) {
- cout << " icode=" << icode << endl;
- /*
- cout << "TLorentzVector positionX=" << position.X()
- << "positionY=" << position.Y()
- << "positionZ=" << position.Z()
- << "timeT=" << position.T() << endl;
- cout << "TLorentzVector momentumX=" << momentum.X()
- << "momentumY=" << momentum.Y()
- << "momentumZ=" << momentum.Z()
- << "energyE=" << momentum.E() << endl;
- cout << "TrackPid=" << TrackPid() << endl;
- */
- }
-
- else if (icode > 0 && icode <= 5) {
-// mgdraw
- mreg = GetMreg();
-// medium = GetMedium();
- cout << " icode=" << icode
- << " mreg=" << mreg
-// << " medium=" << medium
- << endl;
- TrackPosition(position);
- TrackMomentum(momentum);
- cout << "TLorentzVector positionX=" << position.X()
- << "positionY=" << position.Y()
- << "positionZ=" << position.Z()
- << "timeT=" << position.T() << endl;
- cout << "TLorentzVector momentumX=" << momentum.X()
- << "momentumY=" << momentum.Y()
- << "momentumZ=" << momentum.Z()
- << "energyE=" << momentum.E() << endl;
- cout << "TrackStep=" << TrackStep() << endl;
- cout << "TrackLength=" << TrackLength() << endl;
- cout << "TrackTime=" << TrackTime() << endl;
- cout << "Edep=" << Edep() << endl;
- cout << "TrackPid=" << TrackPid() << endl;
- cout << "TrackCharge=" << TrackCharge() << endl;
- cout << "TrackMass=" << TrackMass() << endl;
- cout << "Etot=" << Etot() << endl;
- cout << "IsNewTrack=" << IsNewTrack() << endl;
- cout << "IsTrackInside=" << IsTrackInside() << endl;
- cout << "IsTrackEntering=" << IsTrackEntering() << endl;
- cout << "IsTrackExiting=" << IsTrackExiting() << endl;
- cout << "IsTrackOut=" << IsTrackOut() << endl;
- cout << "IsTrackDisappeared=" << IsTrackDisappeared() << endl;
- cout << "IsTrackAlive=" << IsTrackAlive() << endl;
- }
-
- else if((icode >= 10 && icode <= 15) ||
- (icode >= 20 && icode <= 24) ||
- (icode >= 30 && icode <= 33) ||
- (icode >= 40 && icode <= 41) ||
- (icode >= 50 && icode <= 52)) {
-// endraw
- mreg = GetMreg();
-// medium = GetMedium();
- rull = GetRull();
- xsco = GetXsco();
- ysco = GetYsco();
- zsco = GetZsco();
- cout << " icode=" << icode
- << " mreg=" << mreg
-// << " medium=" << medium
- << " rull=" << rull
- << " xsco=" << xsco
- << " ysco=" << ysco
- << " zsco=" << zsco << endl;
- TrackPosition(position);
- TrackMomentum(momentum);
- cout << "Edep=" << Edep() << endl;
- cout << "Etot=" << Etot() << endl;
- cout << "TrackPid=" << TrackPid() << endl;
- cout << "TrackCharge=" << TrackCharge() << endl;
- cout << "TrackMass=" << TrackMass() << endl;
- cout << "IsTrackOut=" << IsTrackOut() << endl;
- cout << "IsTrackDisappeared=" << IsTrackDisappeared() << endl;
- cout << "IsTrackStop=" << IsTrackStop() << endl;
- cout << "IsTrackAlive=" << IsTrackAlive() << endl;
- }
-
- else if((icode >= 100 && icode <= 105) ||
- (icode == 208) ||
- (icode == 210) ||
- (icode == 212) ||
- (icode >= 214 && icode <= 215) ||
- (icode == 217) ||
- (icode == 219) ||
- (icode == 221) ||
- (icode == 225) ||
- (icode == 300) ||
- (icode == 400)) {
-// usdraw
- mreg = GetMreg();
-// medium = GetMedium();
- xsco = GetXsco();
- ysco = GetYsco();
- zsco = GetZsco();
- cout << " icode=" << icode
- << " mreg=" << mreg
-// << " medium=" << medium
- << " xsco=" << xsco
- << " ysco=" << ysco
- << " zsco=" << zsco << endl;
- cout << "TrackPid=" << TrackPid() << endl;
- cout << "NSecondaries=" << NSecondaries() << endl;
- for (Int_t isec=0; isec< NSecondaries(); isec++) {
- TFluka::GetSecondary(isec, particleId, position, momentum);
- cout << "TLorentzVector positionX=" << position.X()
- << "positionY=" << position.Y()
- << "positionZ=" << position.Z()
- << "timeT=" << position.T() << endl;
- cout << "TLorentzVector momentumX=" << momentum.X()
- << "momentumY=" << momentum.Y()
- << "momentumZ=" << momentum.Z()
- << "energyE=" << momentum.E() << endl;
- cout << "TrackPid=" << particleId << endl;
-
- }
- }
-
- else if((icode == 19) ||
- (icode == 29) ||
- (icode == 39) ||
- (icode == 49) ||
- (icode == 59)) {
- mreg = GetMreg();
-// medium = GetMedium();
- newreg = GetNewreg();
- xsco = GetXsco();
- ysco = GetYsco();
- zsco = GetZsco();
- cout << " icode=" << icode
- << " mreg=" << mreg
-// << " medium=" << medium
- << " newreg=" << newreg
- << " xsco=" << xsco
- << " ysco=" << ysco
- << " zsco=" << zsco << endl;
- }
-//
-// ====================================================================
-//
-
-
-
-} // end of FutoTest
-