//Virtual MC
#include "TFluka.h"
+#include "TFlukaCodes.h"
#include "TVirtualMCStack.h"
#include "TVirtualMCApplication.h"
#include "TParticle.h"
//* SeT User PRoperties for Emf particles *
//* *
//*----------------------------------------------------------------------*
- static Double_t emassmev = PAPROP.am[9] * 1000.;
+// Get the pointer to the VMC
+ TFluka* fluka = (TFluka*) gMC;
+ static Double_t emassmev = PAPROP.am[kFLUKAelectron + 6] * 1000.;
Int_t lbhabh = 0;
if (EVTFLG.ldltry == 1) {
if (EMFSTK.ichemf[EMFSTK.npemf-1] * EMFSTK.ichemf[EMFSTK.npemf-2] < 0) lbhabh = 1;
}
-
+
// mkbmx1 = dimension for kwb real spare array in fluka stack in DIMPAR
// mkbmx2 = dimension for kwb int. spare array in fluka stack in DIMPAR
// EMFSTK.espark = spare real variables available for
Int_t npnw, ispr;
for (npnw = EMFSTK.npstrt-1; npnw <= EMFSTK.npemf-1; npnw++) {
-
- for (ispr = 0; ispr <= mkbmx1-1; ispr++)
- EMFSTK.espark[npnw][ispr] = TRACKR.spausr[ispr];
+
+ for (ispr = 0; ispr <= mkbmx1-1; ispr++)
+ EMFSTK.espark[npnw][ispr] = TRACKR.spausr[ispr];
+
+ for (ispr = 0; ispr <= mkbmx2-1; ispr++)
+ EMFSTK.iespak[npnw][ispr] = TRACKR.ispusr[ispr];
- for (ispr = 0; ispr <= mkbmx2-1; ispr++)
- EMFSTK.iespak[npnw][ispr] = TRACKR.ispusr[ispr];
-
- EMFSTK.louemf[npnw] = TRACKR.llouse;
+ EMFSTK.louemf[npnw] = TRACKR.llouse;
}
-// Get the pointer to the VMC
- TFluka* fluka = (TFluka*) gMC;
+
Int_t verbosityLevel = fluka->GetVerbosityLevel();
Bool_t debug = (verbosityLevel>=3)?kTRUE:kFALSE;
fluka->SetTrackIsNew(kTRUE);
for (kp = EMFSTK.npstrt - 1; kp <= EMFSTK.npemf - 1; kp++) {
// Ckeck transport cut first
- Int_t ireg = EMFSTK.iremf[kp];
- Double_t cut = (TMath::Abs(EMFSTK.ichemf[kp]) == 1) ? EFMRGN.elethr[ireg-1] : EFMRGN.phothr[ireg-1];
+ Int_t ireg = EMFSTK.iremf[kp];
+ Double_t cut = (TMath::Abs(EMFSTK.ichemf[kp]) == 1) ? EMFRGN.elethr[ireg-1] : EMFRGN.phothr[ireg-1];
Double_t e = EMFSTK.etemf[kp];
+
if ((e < cut)
&& (
(EMFSTK.ichemf[kp] == 0) ||
(EMFSTK.ichemf[kp] == -1) ||
- (EMFSTK.ichemf[kp] == 1 && EFMRGN.phothr[ireg-1] > emassmev)
+ (EMFSTK.ichemf[kp] == 1 && EMFRGN.phothr[ireg-1] > emassmev)
)
)
{
- EMFSTK.iespak[kp][mkbmx2-1] = -1;
+ EMFSTK.iespak[kp][mkbmx2-1] = TRACKR.ispusr[mkbmx2-1];
EMFSTK.iespak[kp][mkbmx2-2] = 0;
continue;
}
-//* save the parent track number and reset it at each loop
+// Save the parent track number and reset it at each loop
Int_t done = 0;
Int_t parent = TRACKR.ispusr[mkbmx2-1];
Int_t flukaid = 0;
// Identify particle type
- if (EMFSTK.ichemf[kp] == -1) flukaid = 3;
- else if (EMFSTK.ichemf[kp] == 0) flukaid = 7;
- else if (EMFSTK.ichemf[kp] == 1) flukaid = 4;
+ if (EMFSTK.ichemf[kp] == -1) flukaid = kFLUKAelectron;
+ else if (EMFSTK.ichemf[kp] == 0) flukaid = kFLUKAphoton;
+ else if (EMFSTK.ichemf[kp] == 1) flukaid = kFLUKApositron;
- e *= emvgev;
+ e *= emvgev;
Int_t pdg = fluka->PDGFromId(flukaid);
Double_t p = sqrt(e * e - PAPROP.am[flukaid+6] * PAPROP.am[flukaid+6]);
Double_t px = p * EMFSTK.uemf[kp];
- Double_t pz = p * EMFSTK.vemf[kp];
- Double_t py = p * EMFSTK.wemf[kp];
+ Double_t py = p * EMFSTK.vemf[kp];
+ Double_t pz = p * EMFSTK.wemf[kp];
Double_t tof = EMFSTK.agemf[kp];
Double_t polx = EMFSTK.upol[kp];
Double_t poly = EMFSTK.vpol[kp];