**************************************************************************/
// $Id$
+
+// Class TFlukaMCGeometry
+// --------------------
+// Implementation of the TVirtualMCGeometry interface
+// for defining and using TGeo geometry with FLUKA.
+// This allows the FLUKA MonteCarlo to run with the TGeo
+// geometrical modeller
// Author: Andrei Gheata 10/07/2003
-#include "TObjString.h"
-#include "TFlukaGeo.h"
+#include "Riostream.h"
+#include "TList.h"
+#include "TCallf77.h"
+#include "TFluka.h"
#include "TFlukaMCGeometry.h"
+#include "TFlukaConfigOption.h"
#include "TGeoManager.h"
#include "TGeoVolume.h"
-
-#include "TCallf77.h"
+#include "TObjString.h"
+#include "Fsourcm.h"
+#include "Ftrackr.h"
+#include "Fstepsz.h" //(STEPSZ) fluka common
#ifndef WIN32
# define idnrwr idnrwr_
void type_of_call g1wr(Double_t & /*pSx*/, Double_t & /*pSy*/, Double_t & /*pSz*/,
Double_t * /*pV*/, Int_t & /*oldReg*/ , const Int_t & /*oldLttc*/, Double_t & /*propStep*/,
Int_t & /*nascFlag*/, Double_t & /*retStep*/, Int_t & /*newReg*/,
- Double_t & /*saf*/, Int_t & /*newLttc*/, Int_t & /*LttcFlag*/,
+ Double_t & /*saf*/, Int_t & /*newLttc*/, Int_t & /*LttcFlag*/,
Double_t *s /*Lt*/, Int_t * /*jrLt*/);
void type_of_call g1rtwr();
- void type_of_call conhwr(Int_t & /*intHist*/, Int_t * /*incrCount*/);
+ void type_of_call conhwr(Int_t & /*intHist*/, Int_t & /*incrCount*/);
void type_of_call inihwr(Int_t & /*intHist*/);
void type_of_call jomiwr(const Int_t & /*nge*/, const Int_t & /*lin*/, const Int_t & /*lou*/,
Int_t & /*flukaReg*/);
void type_of_call lkdbwr(Double_t & /*pSx*/, Double_t & /*pSy*/, Double_t & /*pSz*/,
Double_t * /*pV*/, const Int_t & /*oldReg*/, const Int_t & /*oldLttc*/,
- Int_t & /*newReg*/, Int_t & /*flagErr*/, Int_t & /*newLttc*/);
+ Int_t & /*flagErr*/, Int_t & /*newReg*/, Int_t & /*newLttc*/);
void type_of_call lkfxwr(Double_t & /*pSx*/, Double_t & /*pSy*/, Double_t & /*pSz*/,
Double_t * /*pV*/, const Int_t & /*oldReg*/, const Int_t & /*oldLttc*/,
- Int_t & /*newReg*/, Int_t & /*flagErr*/, Int_t & /*newLttc*/);
+ Int_t & /*flagErr*/, Int_t & /*newReg*/, Int_t & /*newLttc*/);
void type_of_call lkmgwr(Double_t & /*pSx*/, Double_t & /*pSy*/, Double_t & /*pSz*/,
Double_t * /*pV*/, const Int_t & /*oldReg*/, const Int_t & /*oldLttc*/,
- Int_t & /*flagErr*/, Int_t & /*newReg*/, Int_t & /*newLttc*/);
+ Int_t & /*flagErr*/, Int_t & /*newReg*/, Int_t & /*newLttc*/);
void type_of_call lkwr(Double_t & /*pSx*/, Double_t & /*pSy*/, Double_t & /*pSz*/,
Double_t * /*pV*/, const Int_t & /*oldReg*/, const Int_t & /*oldLttc*/,
- Int_t & /*newReg*/, Int_t & /*flagErr*/, Int_t & /*newLttc*/);
+ Int_t & /*flagErr*/, Int_t & /*newReg*/, Int_t & /*newLttc*/);
// void type_of_call magfld(const Double_t & /*pX*/, const Double_t & /*pY*/, const Double_t & /*pZ*/,
// Double_t & /*cosBx*/, Double_t & /*cosBy*/, Double_t & /*cosBz*/,
-// Double_t & /*Bmag*/, Int_t & /*reg*/, Int_t & /*idiscflag*/);
+// Double_t & /*Bmag*/, Int_t & /*reg*/, Int_t & /*idiscflag*/);
void type_of_call nrmlwr(Double_t & /*pSx*/, Double_t & /*pSy*/, Double_t & /*pSz*/,
Double_t & /*pVx*/, Double_t & /*pVy*/, Double_t & /*pVz*/,
- Double_t * /*norml*/, const Int_t & /*oldReg*/,
- const Int_t & /*newReg*/, Int_t & /*flagErr*/);
+ Double_t * /*norml*/, const Int_t & /*oldReg*/,
+ const Int_t & /*newReg*/, Int_t & /*flagErr*/);
void type_of_call rgrpwr(const Int_t & /*flukaReg*/, const Int_t & /*ptrLttc*/, Int_t & /*g4Reg*/,
Int_t * /*indMother*/, Int_t * /*repMother*/, Int_t & /*depthFluka*/);
Int_t type_of_call isvhwr(const Int_t & /*fCheck*/, const Int_t & /*intHist*/);
-};
+}
// TFluka global pointer
-TFluka *fluka = 0;
-TFlukaMCGeometry *mcgeom = 0;
-Int_t kNstep = 0;
+TFluka *gFluka = 0;
+TFlukaMCGeometry *gMCGeom = 0;
+Int_t gNstep = 0;
ClassImp(TFlukaMCGeometry)
-TFlukaMCGeometry* TFlukaMCGeometry::fgInstance=0;
+TFlukaMCGeometry* TFlukaMCGeometry::fgInstance= NULL;
//_____________________________________________________________________________
TFlukaMCGeometry::TFlukaMCGeometry(const char *name, const char *title)
- : TVirtualMCGeometry(name, title)
+ :TNamed(name, title),
+ fDebug(kFALSE),
+ fLastMaterial(0),
+ fDummyRegion(0),
+ fCurrentRegion(0),
+ fCurrentLattice(0),
+ fNextRegion(0),
+ fNextLattice(0),
+ fRegionList(0),
+ fIndmat(0),
+ fMatList(new TObjArray(256)),
+ fMatNames(new TObjArray(256))
{
//
// Standard constructor
//
- fDebug = kFALSE;
- fLastMaterial = 0;
- fNextRegion = 0;
- fNextLattice = 0;
- fRegionList = 0;
- fluka = (TFluka*)gMC;
- mcgeom = this;
- kNstep = 0;
+ gFluka = (TFluka*)gMC;
+ gMCGeom = this;
+ gNstep = 0;
}
//_____________________________________________________________________________
TFlukaMCGeometry::TFlukaMCGeometry()
- : TVirtualMCGeometry()
-{
+ :TNamed(),
+ fDebug(kFALSE),
+ fLastMaterial(0),
+ fDummyRegion(0),
+ fCurrentRegion(0),
+ fCurrentLattice(0),
+ fNextRegion(0),
+ fNextLattice(0),
+ fRegionList(0),
+ fIndmat(0),
+ fMatList(0),
+ fMatNames(0)
+
+{
//
// Default constructor
//
- fDebug = kFALSE;
- fLastMaterial = 0;
- fNextRegion = 0;
- fNextLattice = 0;
- fRegionList = 0;
- fluka = (TFluka*)gMC;
- mcgeom = this;
- kNstep = 0;
+ gFluka = (TFluka*)gMC;
+ gMCGeom = this;
+ gNstep = 0;
}
//_____________________________________________________________________________
//
fgInstance=0;
if (fRegionList) delete [] fRegionList;
+ if (fMatList) delete fMatList;
+ if (fMatNames) {fMatNames->Delete(); delete fMatNames;}
if (gGeoManager) delete gGeoManager;
}
//
// private methods
//
-//_____________________________________________________________________________
-TFlukaMCGeometry::TFlukaMCGeometry(const TFlukaMCGeometry &)
- : TVirtualMCGeometry()
-{
- //
- // Copy constructor
- //
-}
//_____________________________________________________________________________
Double_t* TFlukaMCGeometry::CreateDoubleArray(Float_t* array, Int_t size) const
}
//
// public methods
-//_____________________________________________________________________________
-void TFlukaMCGeometry::Gfmate(Int_t imat, char *name, Float_t &a, Float_t &z,
- Float_t &dens, Float_t &radl, Float_t &absl,
- Float_t* /*ubuf*/, Int_t& /*nbuf*/)
-{
- if (fDebug) printf("Gfmate %i\n", imat);
- TGeoMaterial *mat;
- TIter next (gGeoManager->GetListOfMaterials());
- while ((mat = (TGeoMaterial*)next())) {
- if (mat->GetUniqueID() == (UInt_t)imat) break;
- }
- if (!mat) {
- Error("Gfmate", "no material with index %i found", imat);
- return;
- }
- sprintf(name, "%s", mat->GetName());
- a = mat->GetA();
- z = mat->GetZ();
- dens = mat->GetDensity();
- radl = mat->GetRadLen();
- absl = mat->GetIntLen();
- if (fDebug) printf(" ->material found : %s a=%g, z=%g, dens=%g, radl=%g, absl=%g\n", name, a,z,dens,radl,absl);
-}
-//_____________________________________________________________________________
-void TFlukaMCGeometry::Gfmate(Int_t imat, char *name, Double_t &a, Double_t &z,
- Double_t &dens, Double_t &radl, Double_t &absl,
- Double_t* /*ubuf*/, Int_t& /*nbuf*/)
-{
- if (fDebug) printf("Gfmate %i\n", imat);
- TGeoMaterial *mat;
- TIter next (gGeoManager->GetListOfMaterials());
- while ((mat = (TGeoMaterial*)next())) {
- if (mat->GetUniqueID() == (UInt_t)imat) break;
- }
- if (!mat) {
- Error("Gfmate", "no material with index %i found", imat);
- return;
- }
- sprintf(name, "%s", mat->GetName());
- a = mat->GetA();
- z = mat->GetZ();
- dens = mat->GetDensity();
- radl = mat->GetRadLen();
- absl = mat->GetIntLen();
- if (fDebug) printf(" ->material found : %s a=%g, z=%g, dens=%g, radl=%g, absl=%g\n", name, a,z,dens,radl,absl);
-}
-//_____________________________________________________________________________
-void TFlukaMCGeometry::Material(Int_t& kmat, const char* name, Double_t a, Double_t z,
- Double_t dens, Double_t radl, Double_t absl, Float_t* buf,
- Int_t nwbuf)
-{
- //
- // Defines a Material
- //
- // kmat number assigned to the material
- // name material name
- // a atomic mass in au
- // z atomic number
- // dens density in g/cm3
- // absl absorbtion length in cm
- // if >=0 it is ignored and the program
- // calculates it, if <0. -absl is taken
- // radl radiation length in cm
- // if >=0 it is ignored and the program
- // calculates it, if <0. -radl is taken
- // buf pointer to an array of user words
- // nbuf number of user words
- //
-
- Double_t* dbuf = CreateDoubleArray(buf, nwbuf);
- Material(kmat, name, a, z, dens, radl, absl, dbuf, nwbuf);
- delete [] dbuf;
-}
-
-//_____________________________________________________________________________
-void TFlukaMCGeometry::Material(Int_t& kmat, const char* name, Double_t a, Double_t z,
- Double_t dens, Double_t radl, Double_t absl, Double_t* /*buf*/,
- Int_t /*nwbuf*/)
-{
- //
- // Defines a Material
- //
- // kmat number assigned to the material
- // name material name
- // a atomic mass in au
- // z atomic number
- // dens density in g/cm3
- // absl absorbtion length in cm
- // if >=0 it is ignored and the program
- // calculates it, if <0. -absl is taken
- // radl radiation length in cm
- // if >=0 it is ignored and the program
- // calculates it, if <0. -radl is taken
- // buf pointer to an array of user words
- // nbuf number of user words
- //
-
- kmat = gGeoManager->GetListOfMaterials()->GetSize();
- gGeoManager->Material(name, a, z, dens, kmat, radl, absl);
- if (fDebug) printf("Material %s: kmat=%i, a=%g, z=%g, dens=%g\n", name, kmat, a, z, dens);
-}
-
-//_____________________________________________________________________________
-void TFlukaMCGeometry::Mixture(Int_t& kmat, const char* name, Float_t* a, Float_t* z,
- Double_t dens, Int_t nlmat, Float_t* wmat)
-{
- //
- // Defines mixture OR COMPOUND IMAT as composed by
- // THE BASIC NLMAT materials defined by arrays A,Z and WMAT
- //
- // If NLMAT > 0 then wmat contains the proportion by
- // weights of each basic material in the mixture.
- //
- // If nlmat < 0 then WMAT contains the number of atoms
- // of a given kind into the molecule of the COMPOUND
- // In this case, WMAT in output is changed to relative
- // weigths.
- //
-
- Double_t* da = CreateDoubleArray(a, TMath::Abs(nlmat));
- Double_t* dz = CreateDoubleArray(z, TMath::Abs(nlmat));
- Double_t* dwmat = CreateDoubleArray(wmat, TMath::Abs(nlmat));
-
- Mixture(kmat, name, da, dz, dens, nlmat, dwmat);
- for (Int_t i=0; i<nlmat; i++) {
- a[i] = da[i]; z[i] = dz[i]; wmat[i] = dwmat[i];
- }
-
- delete [] da;
- delete [] dz;
- delete [] dwmat;
-}
-
-//_____________________________________________________________________________
-void TFlukaMCGeometry::Mixture(Int_t& kmat, const char* name, Double_t* a, Double_t* z,
- Double_t dens, Int_t nlmat, Double_t* wmat)
-{
- //
- // Defines mixture OR COMPOUND IMAT as composed by
- // THE BASIC NLMAT materials defined by arrays A,Z and WMAT
- //
- // If NLMAT > 0 then wmat contains the proportion by
- // weights of each basic material in the mixture.
- //
- // If nlmat < 0 then WMAT contains the number of atoms
- // of a given kind into the molecule of the COMPOUND
- // In this case, WMAT in output is changed to relative
- // weigths.
- //
-
- if (nlmat < 0) {
- nlmat = - nlmat;
- Double_t amol = 0;
- Int_t i;
- for (i=0;i<nlmat;i++) {
- amol += a[i]*wmat[i];
- }
- for (i=0;i<nlmat;i++) {
- wmat[i] *= a[i]/amol;
- }
- }
- kmat = gGeoManager->GetListOfMaterials()->GetSize();
- if (fDebug) {
- printf("Mixture %s with %i elem: kmat=%i, dens=%g\n", name, nlmat, kmat, dens);
- for (Int_t j=0; j<nlmat; j++) printf(" Elem %i: z=%g a=%g w=%g\n",j,z[j],a[j],wmat[j]);
- }
- gGeoManager->Mixture(name, a, z, dens, nlmat, wmat, kmat);
-}
//_____________________________________________________________________________
Int_t TFlukaMCGeometry::GetMedium() const
{
Int_t TFlukaMCGeometry::GetFlukaMaterial(Int_t imed) const
{
// Returns FLUKA material index for medium IMED
- TGeoMedium *med = (TGeoMedium*)gGeoManager->GetListOfMedia()->At(imed-1);
+ TGeoMedium *med = (TGeoMedium*)gGeoManager->GetListOfMedia()->At(imed-1);
if (!med) {
Error("GetFlukaMaterial", "MEDIUM %i nor found", imed);
return -1;
}
+ TGeoMaterial* mat = med->GetMaterial();
+ if (!mat->IsUsed()) return -1;
Int_t imatfl = med->GetMaterial()->GetIndex();
return imatfl;
}
TGeoVolume *vol;
Int_t imedium, ireg;
while ((vol = (TGeoVolume*)next())) {
- imedium = vol->GetMedium()->GetId();
- if (imedium == imed) {
- ireg = vol->GetNumber();
- fRegionList[nreg++] = ireg;
- }
+ TGeoMedium* med;
+ if ((med = vol->GetMedium()) == 0) continue;
+ imedium = med->GetId();
+ if (imedium == imed) {
+ ireg = vol->GetNumber();
+ fRegionList[nreg++] = ireg;
+ }
}
return fRegionList;
-}
+}
//_____________________________________________________________________________
Int_t *TFlukaMCGeometry::GetMaterialList(Int_t imat, Int_t &nreg)
TGeoVolume *vol;
Int_t imaterial, ireg;
while ((vol = (TGeoVolume*)next())) {
- imaterial = vol->GetMedium()->GetMaterial()->GetIndex();
- if (imaterial == imat) {
- ireg = vol->GetNumber();
- fRegionList[nreg++] = ireg;
- }
+ TGeoMedium* med;
+ if ((med = vol->GetMedium()) == 0) continue;
+ imaterial = med->GetMaterial()->GetIndex();
+ if (imaterial == imat) {
+ ireg = vol->GetNumber();
+ fRegionList[nreg++] = ireg;
+ }
}
return fRegionList;
-}
-//_____________________________________________________________________________
-void TFlukaMCGeometry::Medium(Int_t& kmed, const char* name, Int_t nmat, Int_t isvol,
- Int_t ifield, Double_t fieldm, Double_t tmaxfd,
- Double_t stemax, Double_t deemax, Double_t epsil,
- Double_t stmin, Float_t* ubuf, Int_t nbuf)
-{
- //
- // kmed tracking medium number assigned
- // name tracking medium name
- // nmat material number
- // isvol sensitive volume flag
- // ifield magnetic field
- // fieldm max. field value (kilogauss)
- // tmaxfd max. angle due to field (deg/step)
- // stemax max. step allowed
- // deemax max. fraction of energy lost in a step
- // epsil tracking precision (cm)
- // stmin min. step due to continuous processes (cm)
- //
- // ifield = 0 if no magnetic field; ifield = -1 if user decision in guswim;
- // ifield = 1 if tracking performed with g3rkuta; ifield = 2 if tracking
- // performed with g3helix; ifield = 3 if tracking performed with g3helx3.
- //
-
- //printf("Creating mediuma: %s, numed=%d, nmat=%d\n",name,kmed,nmat);
- Double_t* dubuf = CreateDoubleArray(ubuf, nbuf);
- Medium(kmed, name, nmat, isvol, ifield, fieldm, tmaxfd, stemax, deemax, epsil,
- stmin, dubuf, nbuf);
- delete [] dubuf;
-}
-
-//_____________________________________________________________________________
-void TFlukaMCGeometry::Medium(Int_t& kmed, const char* name, Int_t nmat, Int_t isvol,
- Int_t ifield, Double_t fieldm, Double_t tmaxfd,
- Double_t stemax, Double_t deemax, Double_t epsil,
- Double_t stmin, Double_t* /*ubuf*/, Int_t /*nbuf*/)
-{
- //
- // kmed tracking medium number assigned
- // name tracking medium name
- // nmat material number
- // isvol sensitive volume flag
- // ifield magnetic field
- // fieldm max. field value (kilogauss)
- // tmaxfd max. angle due to field (deg/step)
- // stemax max. step allowed
- // deemax max. fraction of energy lost in a step
- // epsil tracking precision (cm)
- // stmin min. step due to continuos processes (cm)
- //
- // ifield = 0 if no magnetic field; ifield = -1 if user decision in guswim;
- // ifield = 1 if tracking performed with g3rkuta; ifield = 2 if tracking
- // performed with g3helix; ifield = 3 if tracking performed with g3helx3.
- //
-
- kmed = gGeoManager->GetListOfMedia()->GetSize()+1;
- gGeoManager->Medium(name,kmed,nmat, isvol, ifield, fieldm, tmaxfd, stemax,deemax, epsil, stmin);
- if (fDebug) printf("Medium %s: kmed=%i, nmat=%i, isvol=%i\n", name, kmed, nmat,isvol);
-}
-
-//_____________________________________________________________________________
-void TFlukaMCGeometry::Matrix(Int_t& krot, Double_t thex, Double_t phix, Double_t they,
- Double_t phiy, Double_t thez, Double_t phiz)
-{
- //
- // krot rotation matrix number assigned
- // theta1 polar angle for axis i
- // phi1 azimuthal angle for axis i
- // theta2 polar angle for axis ii
- // phi2 azimuthal angle for axis ii
- // theta3 polar angle for axis iii
- // phi3 azimuthal angle for axis iii
- //
- // it defines the rotation matrix number irot.
- //
-
- krot = gGeoManager->GetListOfMatrices()->GetEntriesFast();
- gGeoManager->Matrix(krot, thex, phix, they, phiy, thez, phiz);
- if (fDebug) printf("Rotation %i defined\n", krot);
}
-
-//_____________________________________________________________________________
-Int_t TFlukaMCGeometry::Gsvolu(const char *name, const char *shape, Int_t nmed,
- Float_t *upar, Int_t npar)
-{
- //
- // NAME Volume name
- // SHAPE Volume type
- // NUMED Tracking medium number
- // NPAR Number of shape parameters
- // UPAR Vector containing shape parameters
- //
- // It creates a new volume in the JVOLUM data structure.
- //
-
- Double_t* dupar = CreateDoubleArray(upar, npar);
- Int_t id = Gsvolu(name, shape, nmed, dupar, npar);
- delete [] dupar;
- return id;
-}
-
-//_____________________________________________________________________________
-Int_t TFlukaMCGeometry::Gsvolu(const char *name, const char *shape, Int_t nmed,
- Double_t *upar, Int_t npar)
-{
- //
- // NAME Volume name
- // SHAPE Volume type
- // NUMED Tracking medium number
- // NPAR Number of shape parameters
- // UPAR Vector containing shape parameters
- //
- // It creates a new volume in the JVOLUM data structure.
- //
- char vname[5];
- Vname(name,vname);
- char vshape[5];
- Vname(shape,vshape);
-
- TGeoVolume* vol = gGeoManager->Volume(vname, shape, nmed, upar, npar);
- if (fDebug) printf("Volume %s: id=%i shape=%s, nmed=%i\n", vname, vol->GetNumber(), shape, nmed);
- return vol->GetNumber();
-}
-
-//_____________________________________________________________________________
-void TFlukaMCGeometry::Gsdvn(const char *name, const char *mother, Int_t ndiv,
- Int_t iaxis)
-{
- //
- // Create a new volume by dividing an existing one
- //
- // NAME Volume name
- // MOTHER Mother volume name
- // NDIV Number of divisions
- // IAXIS Axis value
- //
- // X,Y,Z of CAXIS will be translated to 1,2,3 for IAXIS.
- // It divides a previously defined volume.
- //
- char vname[5];
- Vname(name,vname);
- char vmother[5];
- Vname(mother,vmother);
-
- gGeoManager->Division(vname, vmother, iaxis, ndiv, 0, 0, 0, "n");
- if (fDebug) printf("Division %s: mother=%s iaxis=%i ndiv=%i\n", vname, vmother, iaxis, ndiv);
-}
-
-//_____________________________________________________________________________
-void TFlukaMCGeometry::Gsdvn2(const char *name, const char *mother, Int_t ndiv,
- Int_t iaxis, Double_t c0i, Int_t numed)
-{
- //
- // Create a new volume by dividing an existing one
- //
- // Divides mother into ndiv divisions called name
- // along axis iaxis starting at coordinate value c0.
- // the new volume created will be medium number numed.
- //
- char vname[5];
- Vname(name,vname);
- char vmother[5];
- Vname(mother,vmother);
-
- gGeoManager->Division(vname, vmother, iaxis, ndiv, c0i, 0, numed, "nx");
-}
-//_____________________________________________________________________________
-void TFlukaMCGeometry::Gsdvt(const char *name, const char *mother, Double_t step,
- Int_t iaxis, Int_t numed, Int_t /*ndvmx*/)
-{
- //
- // Create a new volume by dividing an existing one
- //
- // Divides MOTHER into divisions called NAME along
- // axis IAXIS in steps of STEP. If not exactly divisible
- // will make as many as possible and will centre them
- // with respect to the mother. Divisions will have medium
- // number NUMED. If NUMED is 0, NUMED of MOTHER is taken.
- // NDVMX is the expected maximum number of divisions
- // (If 0, no protection tests are performed)
- //
- char vname[5];
- Vname(name,vname);
- char vmother[5];
- Vname(mother,vmother);
-
- gGeoManager->Division(vname, vmother, iaxis, 0, 0, step, numed, "s");
-}
-
-//_____________________________________________________________________________
-void TFlukaMCGeometry::Gsdvt2(const char *name, const char *mother, Double_t step,
- Int_t iaxis, Double_t c0, Int_t numed, Int_t /*ndvmx*/)
-{
- //
- // Create a new volume by dividing an existing one
- //
- // Divides MOTHER into divisions called NAME along
- // axis IAXIS starting at coordinate value C0 with step
- // size STEP.
- // The new volume created will have medium number NUMED.
- // If NUMED is 0, NUMED of mother is taken.
- // NDVMX is the expected maximum number of divisions
- // (If 0, no protection tests are performed)
- //
- char vname[5];
- Vname(name,vname);
- char vmother[5];
- Vname(mother,vmother);
-
- gGeoManager->Division(vname, vmother, iaxis, 0, c0, step, numed, "sx");
-}
-
-//_____________________________________________________________________________
-void TFlukaMCGeometry::Gsord(const char * /*name*/, Int_t /*iax*/)
-{
- //
- // Flags volume CHNAME whose contents will have to be ordered
- // along axis IAX, by setting the search flag to -IAX
- // IAX = 1 X axis
- // IAX = 2 Y axis
- // IAX = 3 Z axis
- // IAX = 4 Rxy (static ordering only -> GTMEDI)
- // IAX = 14 Rxy (also dynamic ordering -> GTNEXT)
- // IAX = 5 Rxyz (static ordering only -> GTMEDI)
- // IAX = 15 Rxyz (also dynamic ordering -> GTNEXT)
- // IAX = 6 PHI (PHI=0 => X axis)
- // IAX = 7 THETA (THETA=0 => Z axis)
- //
-
- // TBC - keep this function
- // nothing to be done for TGeo //xx
-}
-
-//_____________________________________________________________________________
-void TFlukaMCGeometry::Gspos(const char *name, Int_t nr, const char *mother, Double_t x,
- Double_t y, Double_t z, Int_t irot, const char *konly)
-{
- //
- // Position a volume into an existing one
- //
- // NAME Volume name
- // NUMBER Copy number of the volume
- // MOTHER Mother volume name
- // X X coord. of the volume in mother ref. sys.
- // Y Y coord. of the volume in mother ref. sys.
- // Z Z coord. of the volume in mother ref. sys.
- // IROT Rotation matrix number w.r.t. mother ref. sys.
- // ONLY ONLY/MANY flag
- //
- // It positions a previously defined volume in the mother.
- //
-
- TString only = konly;
- only.ToLower();
- Bool_t isOnly = kFALSE;
- if (only.Contains("only")) isOnly = kTRUE;
- char vname[5];
- Vname(name,vname);
- char vmother[5];
- Vname(mother,vmother);
-
- Double_t *upar=0;
- gGeoManager->Node(vname, nr, vmother, x, y, z, irot, isOnly, upar);
- if (fDebug) printf("Adding daughter %s to %s: cpy=%i irot=%i only=%s\n", vname,vmother,nr,irot,only.Data());
-}
-
-//_____________________________________________________________________________
-void TFlukaMCGeometry::Gsposp(const char *name, Int_t nr, const char *mother,
- Double_t x, Double_t y, Double_t z, Int_t irot,
- const char *konly, Float_t *upar, Int_t np )
-{
- //
- // Place a copy of generic volume NAME with user number
- // NR inside MOTHER, with its parameters UPAR(1..NP)
- //
-
- Double_t* dupar = CreateDoubleArray(upar, np);
- Gsposp(name, nr, mother, x, y, z, irot, konly, dupar, np);
- delete [] dupar;
-}
-
-//_____________________________________________________________________________
-void TFlukaMCGeometry::Gsposp(const char *name, Int_t nr, const char *mother,
- Double_t x, Double_t y, Double_t z, Int_t irot,
- const char *konly, Double_t *upar, Int_t np )
-{
- //
- // Place a copy of generic volume NAME with user number
- // NR inside MOTHER, with its parameters UPAR(1..NP)
- //
-
- TString only = konly;
- only.ToLower();
- Bool_t isOnly = kFALSE;
- if (only.Contains("only")) isOnly = kTRUE;
- char vname[5];
- Vname(name,vname);
- char vmother[5];
- Vname(mother,vmother);
-
- gGeoManager->Node(vname,nr,vmother, x,y,z,irot,isOnly,upar,np);
- if (fDebug) printf("Adding daughter(s) %s to %s: cpy=%i irot=%i only=%s\n", vname,vmother,nr,irot,only.Data());
-}
-//_____________________________________________________________________________
-Int_t TFlukaMCGeometry::VolId(const Text_t *name) const
-{
- //
- // Return the unique numeric identifier for volume name
- //
-
- Int_t uid = gGeoManager->GetUID(name);
- if (uid<0) {
- printf("VolId: Volume %s not found\n",name);
- return 0;
- }
- if (fDebug) printf("VolId for %s: %i\n", name, uid);
- return uid;
-}
-
-//_____________________________________________________________________________
-const char* TFlukaMCGeometry::VolName(Int_t id) const
-{
- //
- // Return the volume name given the volume identifier
- //
- TGeoVolume *volume = gGeoManager->GetVolume(id);
- if (!volume) {
- Error("VolName","volume with id=%d does not exist",id);
- return "NULL";
- }
- if (fDebug) printf("VolName for id=%i: %s\n", id, volume->GetName());
- return volume->GetName();
-}
-
//_____________________________________________________________________________
Int_t TFlukaMCGeometry::NofVolumes() const
{
return gGeoManager->GetListOfUVolumes()->GetEntriesFast()-1;
}
-
-//_____________________________________________________________________________
-Int_t TFlukaMCGeometry::VolId2Mate(Int_t id) const
-{
- //
- // Return material number for a given volume id
- //
- TGeoVolume *volume = gGeoManager->GetVolume(id);
- if (!volume) {
- Error("VolId2Mate","volume with id=%d does not exist",id);
- return 0;
- }
- TGeoMedium *med = volume->GetMedium();
- if (!med) return 0;
- if (fDebug) printf("VolId2Mate id=%i: idmed=%i\n", id, med->GetId());
- return med->GetId();
-}
-
-//_____________________________________________________________________________
-Int_t TFlukaMCGeometry::CurrentVolID(Int_t& copyNo) const
-{
- // Returns the current volume ID and copy number
- if (gGeoManager->IsOutside()) return 0;
- TGeoNode *node = gGeoManager->GetCurrentNode();
- copyNo = node->GetNumber();
- Int_t id = node->GetVolume()->GetNumber();
- if (fDebug) printf("CurrentVolId(cpy=%i) = %i\n", copyNo, id);
- return id;
-}
-
-//_____________________________________________________________________________
-Int_t TFlukaMCGeometry::CurrentVolOffID(Int_t off, Int_t& copyNo) const
-{
- // Return the current volume "off" upward in the geometrical tree
- // ID and copy number
- if (off<0 || off>gGeoManager->GetLevel()) return 0;
- if (off==0) return CurrentVolID(copyNo);
- TGeoNode *node = gGeoManager->GetMother(off);
- if (!node) return 0;
- copyNo = node->GetNumber();
- if (fDebug) printf("CurrentVolOffId(off=%i,cpy=%i) = %i\n", off,copyNo,node->GetVolume()->GetNumber() );
- return node->GetVolume()->GetNumber();
-}
-// FLUKA specific
-
-//_____________________________________________________________________________
-const char* TFlukaMCGeometry::CurrentVolName() const
-{
- //
- // Returns the current volume name
- //
- if (gGeoManager->IsOutside()) return 0;
- if (fDebug) printf("CurrentVolName : %s\n", gGeoManager->GetCurrentVolume()->GetName());
- return gGeoManager->GetCurrentVolume()->GetName();
-}
-//_____________________________________________________________________________
-const char* TFlukaMCGeometry::CurrentVolOffName(Int_t off) const
-{
- //
- // Return the current volume "off" upward in the geometrical tree
- // ID, name and copy number
- // if name=0 no name is returned
- //
- if (off<0 || off>gGeoManager->GetLevel()) return 0;
- if (off==0) return CurrentVolName();
- TGeoNode *node = gGeoManager->GetMother(off);
- if (!node) return 0;
- if (fDebug) printf("CurrentVolOffName(off=%i) : %s\n", off,node->GetVolume()->GetName());
- return node->GetVolume()->GetName();
-}
//_____________________________________________________________________________
-void TFlukaMCGeometry::Gsatt(const char *name, const char *att, Int_t val)
-{
- //
- // NAME Volume name
- // IOPT Name of the attribute to be set
- // IVAL Value to which the attribute is to be set
- // see: TFluka::Gsatt
- char vname[5];
- Vname(name,vname);
- char vatt[5];
- Vname(att,vatt);
- gGeoManager->SetVolumeAttribute(vname, vatt, val);
-}
-
-//_____________________________________________________________________________
-void TFlukaMCGeometry::Gdtom(Float_t *xd, Float_t *xm, Int_t iflag)
-{
- //
- // Computes coordinates XM (Master Reference System
- // knowing the coordinates XD (Detector Ref System)
- // The local reference system can be initialized by
- // - the tracking routines and GDTOM used in GUSTEP
- // - a call to GSCMED(NLEVEL,NAMES,NUMBER)
- // (inverse routine is GMTOD)
- //
- // If IFLAG=1 convert coordinates
- // IFLAG=2 convert direction cosinus
- //
- Double_t xmL[3], xdL[3];
- Int_t i;
- for (i=0;i<3;i++) xdL[i] = xd[i];
- if (iflag == 1) gGeoManager->LocalToMaster(xdL,xmL);
- else gGeoManager->LocalToMasterVect(xdL,xmL);
- for (i=0;i<3;i++) xm[i]=xmL[i];
+TGeoMaterial * TFlukaMCGeometry::GetMakeWrongMaterial(Double_t z)
+{
+// Try to replace a wrongly-defined material
+ static Double_t kz[23] = {7.3, 17.8184, 7.2167, 10.856, 8.875, 8.9, 7.177,
+ 25.72, 6.2363, 7.1315, 47.7056, 10.6467, 7.8598, 2.10853, 10.6001, 9.1193,
+ 15.3383, 4.55, 9.6502, 6.4561, 21.7963, 29.8246, 15.4021};
+
+ Int_t ind;
+ Double_t dz;
+ for (ind=0; ind<23; ind++) {
+ dz = TMath::Abs(z-kz[ind]);
+ if (dz<1E-4) break;
+ }
+ if (ind>22) {
+ printf("Cannot patch material with Z=%g\n", z);
+ return 0;
+ }
+ TGeoMixture *mix = 0;
+ TGeoElement *element;
+ TGeoElementTable *table = gGeoManager->GetElementTable();
+ switch (ind) {
+ case 0: // AIR
+ mix = new TGeoMixture("TPC_AIR", 4, 0.001205);
+ element = table->GetElement(6); // C
+ mix->DefineElement(0, element, 0.000124);
+ element = table->GetElement(7); // N
+ mix->DefineElement(1, element, 0.755267);
+ element = table->GetElement(8); // O
+ mix->DefineElement(2, element, 0.231781);
+ element = table->GetElement(18); // AR
+ mix->DefineElement(3, element, 0.012827);
+ break;
+ case 1: //SDD SI CHIP
+ mix = new TGeoMixture("ITS_SDD_SI", 6, 2.4485);
+ element = table->GetElement(1);
+ mix->DefineElement(0, element, 0.004367771);
+ element = table->GetElement(6);
+ mix->DefineElement(1, element, 0.039730642);
+ element = table->GetElement(7);
+ mix->DefineElement(2, element, 0.001396798);
+ element = table->GetElement(8);
+ mix->DefineElement(3, element, 0.01169634);
+ element = table->GetElement(14);
+ mix->DefineElement(4, element, 0.844665);
+ element = table->GetElement(47);
+ mix->DefineElement(5, element, 0.09814344903);
+ break;
+ case 2: // WATER
+ mix = new TGeoMixture("ITS_WATER", 2, 1.0);
+ element = table->GetElement(1);
+ mix->DefineElement(0, element, 0.111898344);
+ element = table->GetElement(8);
+ mix->DefineElement(1, element, 0.888101656);
+ break;
+ case 3: // CERAMICS
+ mix = new TGeoMixture("ITS_CERAMICS", 5, 3.6);
+ element = table->GetElement(8);
+ mix->DefineElement(0, element, 0.59956);
+ element = table->GetElement(13);
+ mix->DefineElement(1, element, 0.3776);
+ element = table->GetElement(14);
+ mix->DefineElement(2, element, 0.00933);
+ element = table->GetElement(24);
+ mix->DefineElement(3, element, 0.002);
+ element = table->GetElement(25);
+ mix->DefineElement(4, element, 0.0115);
+ break;
+ case 4: // EPOXY
+ mix = new TGeoMixture("MUON_G10FR4", 4, 1.8);
+ element = table->GetElement(1);
+ mix->DefineElement(0, element, 0.19);
+ element = table->GetElement(6);
+ mix->DefineElement(1, element, 0.18);
+ element = table->GetElement(8);
+ mix->DefineElement(2, element, 0.35);
+ element = table->GetElement(14);
+ mix->DefineElement(3, element, 0.28);
+ break;
+ case 5: // EPOXY
+ mix = new TGeoMixture("G10FR4", 4, 1.8);
+ element = table->GetElement(1);
+ mix->DefineElement(0, element, 0.19);
+ element = table->GetElement(6);
+ mix->DefineElement(1, element, 0.18);
+ element = table->GetElement(8);
+ mix->DefineElement(2, element, 0.35);
+ element = table->GetElement(14);
+ mix->DefineElement(3, element, 0.28);
+ break;
+ case 6: // KAPTON
+ mix = new TGeoMixture("ITS_KAPTON", 4, 1.3);
+ element = table->GetElement(1);
+ mix->DefineElement(0, element, 0.026363415);
+ element = table->GetElement(6);
+ mix->DefineElement(1, element, 0.6911272);
+ element = table->GetElement(7);
+ mix->DefineElement(2, element, 0.073271325);
+ element = table->GetElement(8);
+ mix->DefineElement(3, element, 0.209238060);
+ break;
+ case 7: // INOX
+ mix = new TGeoMixture("ITS_INOX", 9, 7.9);
+ element = table->GetElement(6);
+ mix->DefineElement(0, element, 0.0003);
+ element = table->GetElement(14);
+ mix->DefineElement(1, element, 0.01);
+ element = table->GetElement(15);
+ mix->DefineElement(2, element, 0.00045);
+ element = table->GetElement(16);
+ mix->DefineElement(3, element, 0.0003);
+ element = table->GetElement(24);
+ mix->DefineElement(4, element, 0.17);
+ element = table->GetElement(25);
+ mix->DefineElement(5, element, 0.02);
+ element = table->GetElement(26);
+ mix->DefineElement(6, element, 0.654);
+ element = table->GetElement(28);
+ mix->DefineElement(7, element, 0.12);
+ element = table->GetElement(42);
+ mix->DefineElement(8, element, 0.025);
+ break;
+ case 8: // ROHACELL
+ mix = new TGeoMixture("ROHACELL", 4, 0.05);
+ element = table->GetElement(1);
+ mix->DefineElement(0, element, 0.07836617);
+ element = table->GetElement(6);
+ mix->DefineElement(1, element, 0.64648941);
+ element = table->GetElement(7);
+ mix->DefineElement(2, element, 0.08376983);
+ element = table->GetElement(8);
+ mix->DefineElement(3, element, 0.19137459);
+ break;
+ case 9: // SDD-C-AL
+ mix = new TGeoMixture("ITS_SDD-C-AL", 5, 1.9837);
+ element = table->GetElement(1);
+ mix->DefineElement(0, element, 0.022632);
+ element = table->GetElement(6);
+ mix->DefineElement(1, element, 0.8176579);
+ element = table->GetElement(7);
+ mix->DefineElement(2, element, 0.0093488);
+ element = table->GetElement(8);
+ mix->DefineElement(3, element, 0.0503618);
+ element = table->GetElement(13);
+ mix->DefineElement(4, element, 0.1);
+ break;
+ case 10: // X7R-CAP
+ mix = new TGeoMixture("ITS_X7R-CAP", 7, 6.72);
+ element = table->GetElement(8);
+ mix->DefineElement(0, element, 0.085975822);
+ element = table->GetElement(22);
+ mix->DefineElement(1, element, 0.084755042);
+ element = table->GetElement(28);
+ mix->DefineElement(2, element, 0.038244751);
+ element = table->GetElement(29);
+ mix->DefineElement(3, element, 0.009471271);
+ element = table->GetElement(50);
+ mix->DefineElement(4, element, 0.321736471);
+ element = table->GetElement(56);
+ mix->DefineElement(5, element, 0.251639432);
+ element = table->GetElement(82);
+ mix->DefineElement(6, element, 0.2081768);
+ break;
+ case 11: // SDD ruby sph. Al2O3
+ mix = new TGeoMixture("ITS_AL2O3", 2, 3.97);
+ element = table->GetElement(8);
+ mix->DefineElement(0, element, 0.5293);
+ element = table->GetElement(13);
+ mix->DefineElement(1, element, 0.4707);
+ break;
+ case 12: // SDD HV microcable
+ mix = new TGeoMixture("ITS_HV-CABLE", 5, 1.6087);
+ element = table->GetElement(1);
+ mix->DefineElement(0, element, 0.01983871336);
+ element = table->GetElement(6);
+ mix->DefineElement(1, element, 0.520088819984);
+ element = table->GetElement(7);
+ mix->DefineElement(2, element, 0.0551367996);
+ element = table->GetElement(8);
+ mix->DefineElement(3, element, 0.157399667056);
+ element = table->GetElement(13);
+ mix->DefineElement(4, element, 0.247536);
+ break;
+ case 13: //SDD LV+signal cable
+ mix = new TGeoMixture("ITS_LV-CABLE", 5, 2.1035);
+ element = table->GetElement(1);
+ mix->DefineElement(0, element, 0.0082859922);
+ element = table->GetElement(6);
+ mix->DefineElement(1, element, 0.21722436468);
+ element = table->GetElement(7);
+ mix->DefineElement(2, element, 0.023028867);
+ element = table->GetElement(8);
+ mix->DefineElement(3, element, 0.06574077612);
+ element = table->GetElement(13);
+ mix->DefineElement(4, element, 0.68572);
+ break;
+ case 14: //SDD hybrid microcab
+ mix = new TGeoMixture("ITS_HYB-CAB", 5, 2.0502);
+ element = table->GetElement(1);
+ mix->DefineElement(0, element, 0.00926228815);
+ element = table->GetElement(6);
+ mix->DefineElement(1, element, 0.24281879711);
+ element = table->GetElement(7);
+ mix->DefineElement(2, element, 0.02574224025);
+ element = table->GetElement(8);
+ mix->DefineElement(3, element, 0.07348667449);
+ element = table->GetElement(13);
+ mix->DefineElement(4, element, 0.64869);
+ break;
+ case 15: //SDD anode microcab
+ mix = new TGeoMixture("ITS_ANOD-CAB", 5, 1.7854);
+ element = table->GetElement(1);
+ mix->DefineElement(0, element, 0.0128595919215);
+ element = table->GetElement(6);
+ mix->DefineElement(1, element, 0.392653705471);
+ element = table->GetElement(7);
+ mix->DefineElement(2, element, 0.041626868025);
+ element = table->GetElement(8);
+ mix->DefineElement(3, element, 0.118832707289);
+ element = table->GetElement(13);
+ mix->DefineElement(4, element, 0.431909);
+ break;
+ case 16: // inox/alum
+ mix = new TGeoMixture("ITS_INOX-AL", 5, 3.0705);
+ element = table->GetElement(13);
+ mix->DefineElement(0, element, 0.816164);
+ element = table->GetElement(14);
+ mix->DefineElement(1, element, 0.000919182);
+ element = table->GetElement(24);
+ mix->DefineElement(2, element, 0.0330906);
+ element = table->GetElement(26);
+ mix->DefineElement(3, element, 0.131443);
+ element = table->GetElement(28);
+ mix->DefineElement(4, element, 0.0183836);
+ case 17: // MYLAR
+ mix = new TGeoMixture("TPC_MYLAR", 3, 1.39);
+ element = table->GetElement(1);
+ mix->DefineElement(0, element, 0.0416667);
+ element = table->GetElement(6);
+ mix->DefineElement(1, element, 0.625);
+ element = table->GetElement(8);
+ mix->DefineElement(2, element, 0.333333);
+ break;
+ case 18: // SPDBUS(AL+KPT+EPOX) - unknown composition
+ mix = new TGeoMixture("ITS_SPDBUS", 1, 1.906);
+ element = table->GetElement(9);
+ mix->DefineElement(0, element, 1.);
+ z = element->Z();
+ break;
+ case 19: // SDD/SSD rings - unknown composition
+ mix = new TGeoMixture("ITS_SDDRINGS", 1, 1.8097);
+ element = table->GetElement(6);
+ mix->DefineElement(0, element, 1.);
+ z = element->Z();
+ break;
+ case 20: // SPD end ladder - unknown composition
+ mix = new TGeoMixture("ITS_SPDEL", 1, 3.6374);
+ element = table->GetElement(22);
+ mix->DefineElement(0, element, 1.);
+ z = element->Z();
+ break;
+ case 21: // SDD end ladder - unknown composition
+ mix = new TGeoMixture("ITS_SDDEL", 1, 0.3824);
+ element = table->GetElement(30);
+ mix->DefineElement(0, element, 1.);
+ z = element->Z();
+ break;
+ case 22: // SSD end ladder - unknown composition
+ mix = new TGeoMixture("ITS_SSDEL", 1, 0.68);
+ element = table->GetElement(16);
+ mix->DefineElement(0, element, 1.);
+ z = element->Z();
+ break;
+ }
+ mix->SetZ(z);
+ printf("Patched with mixture %s\n", mix->GetName());
+ return mix;
}
-//_____________________________________________________________________________
-void TFlukaMCGeometry::Gdtom(Double_t *xd, Double_t *xm, Int_t iflag)
-{
- if (iflag == 1) gGeoManager->LocalToMaster(xd,xm);
- else gGeoManager->LocalToMasterVect(xd,xm);
-}
-
-//_____________________________________________________________________________
-void TFlukaMCGeometry::Gmtod(Float_t *xm, Float_t *xd, Int_t iflag)
-{
- //
- // Computes coordinates XD (in DRS)
- // from known coordinates XM in MRS
- // The local reference system can be initialized by
- // - the tracking routines and GMTOD used in GUSTEP
- // - a call to GMEDIA(XM,NUMED,CHECK)
- // - a call to GLVOLU(NLEVEL,NAMES,NUMBER,IER)
- // (inverse routine is GDTOM)
- //
- // If IFLAG=1 convert coordinates
- // IFLAG=2 convert direction cosinus
- //
- Double_t xmL[3], xdL[3];
- Int_t i;
- for (i=0;i<3;i++) xmL[i]=xm[i];
- if (iflag == 1) gGeoManager->MasterToLocal(xmL,xdL);
- else gGeoManager->MasterToLocalVect(xmL,xdL);
- for (i=0;i<3;i++) xd[i] = xdL[i];
-}
-
-//_____________________________________________________________________________
-void TFlukaMCGeometry::Gmtod(Double_t *xm, Double_t *xd, Int_t iflag)
-{
- if (iflag == 1) gGeoManager->MasterToLocal(xm,xd);
- else gGeoManager->MasterToLocalVect(xm,xd);
-}
-
//_____________________________________________________________________________
void TFlukaMCGeometry::CreateFlukaMatFile(const char *fname)
{
// program load the right cross sections, and equal to the names included in
// the .pemf. Otherwise the user must define the LOW-MAT CARDS, and make his
// own .pemf, in order to get the right cross sections loaded in memory.
-
- Int_t zelem[128];
- static char elNames[220] = {
- // 1 ============================= 5 ==================================== 10 ===================================== 15 ===
- 'H','_','H','E','L','I','B','E','B','_','C','_','N','_','O','_','F','_','N','E','N','A','M','G','A','L','S','I','P','_',
- 'S','_','C','L','A','R','K','_','C','A','S','C','T','I','V','_','C','R','M','N','F','E','C','O','N','I','C','U','Z','N',
- 'G','A','G','E','A','S','S','E','B','R','K','R','R','B','S','R','Y','_','Z','R','N','B','M','O','T','C','R','U','R','H',
- 'P','D','A','G','C','D','I','N','S','N','S','B','T','E','I','_','X','E','C','S','B','A','L','A','C','E','P','R','N','D',
- 'P','M','S','M','E','U','G','D','T','B','D','Y','H','O','E','R','T','M','Y','B','L','U','H','F','T','A','W','_','R','E',
- 'O','S','I','R','P','T','A','U','H','G','T','L','P','B','B','I','P','O','A','T','R','N','F','R','R','A','A','C','T','H',
- 'P','A','U','_','N','P','P','U','A','M','C','M','B','K','C','F','E','S','F','M','M','D','N','O','L','R','R','F','D','B',
- 'S','G','B','H','H','S','M','T','D','S'};
- memset(zelem, 0, 128*sizeof(Int_t));
+
+
TString sname;
gGeoManager->Export("flgeom.root");
if (fname) sname = fname;
}
PrintHeader(out, "MATERIALS AND COMPOUNDS");
PrintHeader(out, "MATERIALS");
+ Int_t i,j,idmat;
+ Int_t counttothree, nelem;
+ Double_t a,z,rho, w;
+ TGeoElementTable *table = gGeoManager->GetElementTable();
+ TGeoElement *element;
+ element = table->GetElement(13);
+ element->SetTitle("ALUMINUM"); // this is how FLUKA likes it ...
+ element = table->GetElement(15);
+ element->SetTitle("PHOSPHO"); // same story ...
+// element = table->GetElement(10);
+// element->SetTitle("ARGON"); // NEON not in neutron xsec table
+ Int_t nelements = table->GetNelements();
TList *matlist = gGeoManager->GetListOfMaterials();
+// TList *medlist = gGeoManager->GetListOfMedia();
+// Int_t nmed = medlist->GetSize();
TIter next(matlist);
Int_t nmater = matlist->GetSize();
Int_t nfmater = 0;
- TObjArray *listfluka = new TObjArray(nmater+50);
- TObjArray *listflukanames = new TObjArray(nmater+50);
- TGeoMaterial *mat, *matorig;
+ TGeoMaterial *mat;
TGeoMixture *mix = 0;
TString matname;
- TObjString *objstr, *objstrother;
- Int_t i,j,k,idmat;
- Bool_t done;
- Int_t nelem, nidmat;
- Double_t amat,zmat,rhomat;
- Double_t zel, ael, wel, rho;
- char elname[8] = {' ',' ','_', 'E','L','E','M','\0'};
- char digit[3];
- Bool_t found = kFALSE;
+ TObjString *objstr;
+ // Create all needed elements
+ for (Int_t i=1; i<nelements; i++) {
+ element = table->GetElement(i);
+ // skip elements which are not defined
+ if (!element->IsUsed() && !element->IsDefined()) continue;
+ matname = element->GetTitle();
+ ToFlukaString(matname);
+ rho = 0.999;
+
+ mat = new TGeoMaterial(matname, element->A(), element->Z(), rho);
+ mat->SetIndex(nfmater+3);
+ mat->SetUsed(kTRUE);
+ fMatList->Add(mat);
+ objstr = new TObjString(matname.Data());
+ fMatNames->Add(objstr);
+ nfmater++;
+ }
- if (fDebug) printf("Creating materials and compounds\n");
+ fIndmat = nfmater;
+// TGeoMedium *med;
+ // Adjust material names and add them to FLUKA list
for (i=0; i<nmater; i++) {
mat = (TGeoMaterial*)matlist->At(i);
- if (mat->GetZ()<1E-1) {
+ if (!mat->IsUsed()) continue;
+ z = mat->GetZ();
+ a = mat->GetA();
+ rho = mat->GetDensity();
+ if (mat->GetZ()<0.001) {
mat->SetIndex(2); // vacuum, built-in inside FLUKA
continue;
- }
-// printf("material: %s index=%i: Z=%f A=%f rho=%f\n", mat->GetName(), mat->GetIndex(),mat->GetZ(),mat->GetA(),mat->GetDensity());
- matorig = gGeoManager->FindDuplicateMaterial(mat);
- if (matorig) {
- idmat = matorig->GetIndex();
- mat->SetIndex(idmat);
-// printf(" -> found a duplicate: %s with index %i\n", matorig->GetName(), idmat);
- matorig = 0;
- } else {
-// printf(" Adding to temp list with index %i\n", nfmater+3);
- listfluka->Add(mat);
- mat->SetIndex(nfmater+3);
- matorig = mat;
- objstr = new TObjString(mat->GetName());
- listflukanames->Add(objstr);
- nfmater++;
- // look if name is existing
- nidmat = 0;
- matname = objstr->GetString();
- ToFlukaString(matname);
- objstr->SetString(matname.Data());
- done = kFALSE;
- while (!done) {
- if (nfmater == 1) break;
- for (j=0; j<nfmater-1; j++) {
- objstrother = (TObjString*)listflukanames->At(j);
- if (objstr->IsEqual(objstrother)) {
- // we have to change the name
- if (nidmat>98) {
- Error("CreateFlukaMatFile", "too many materials having same name");
- return;
- }
- nidmat++;
- k = matname.Index(" ");
- if (k<0 || k>6) k=6;
- if (nidmat>9) {
- sprintf(digit, "%d", nidmat);
- } else {
- digit[0] = '0';
- sprintf(&digit[1], "%d", nidmat);
- }
- matname.Insert(k,digit);
- matname.Remove(8);
- objstr->SetString(matname.Data());
- break;
- }
- if (j == nfmater-2) {
- done = kTRUE;
- break;
- }
- }
- }
-// printf(" newmat name: %s\n", matname.Data());
- }
- // now we have unique materials with unique names in the lists
-
- if (matorig && matorig->IsMixture()) {
- // create dummy materials for elements
- rho = 0.999;
- mix = (TGeoMixture*)matorig;
- nelem = mix->GetNelements();
-// printf(" material is a MIXTURE with %i elements:\n", nelem);
- for (j=0; j<nelem; j++) {
- found = kFALSE;
- zel = (mix->GetZmixt())[j];
- ael = (mix->GetAmixt())[j];
-// printf(" Zelem[%i] = %g\n",j,zel);
- if ((zel-Int_t(zel))>0.01) {
- TGeoMaterial *mat1;
- for (Int_t imat=0; imat<nfmater; imat++) {
- mat1 = (TGeoMaterial*)listfluka->At(imat);
- if (TMath::Abs(mat1->GetZ()-zel)>1E-4) continue;
- if (TMath::Abs(mat1->GetA()-ael)>1E-4) continue;
- found = kTRUE;
- break;
- }
- if (!found) Warning("CreateFlukaMatFile", "element with Z=%f\n", zel);
- }
- if (!zelem[Int_t(zel)] && !found) {
- // write fluka element
- memcpy(elname, &elNames[2*Int_t(zel-1)], 2);
- zelem[Int_t(zel)] = 1;
- mat = new TGeoMaterial(elname, ael, zel, rho);
- mat->SetIndex(nfmater+3);
-// printf(" element not in list: new material %s at index=%i, Z=%g, A=%g, dummyrho=%g\n",
-// elname,nfmater+3,zel,ael,rho);
- listfluka->Add(mat);
- objstr = new TObjString(elname);
- listflukanames->Add(objstr);
- nfmater++;
- }
- }
- }
- }
- // now dump materials in the file
-// printf("DUMPING %i materials\n", nfmater);
+ }
+ matname = mat->GetName();
+ FlukaMatName(matname);
+
+ mat->SetIndex(nfmater+3);
+ objstr = new TObjString(matname.Data());
+ fMatList->Add(mat);
+ fMatNames->Add(objstr);
+ nfmater++;
+ }
+
+ // Dump all elements with MATERIAL cards
for (i=0; i<nfmater; i++) {
- mat = (TGeoMaterial*)listfluka->At(i);
+ mat = (TGeoMaterial*)fMatList->At(i);
+// mat->SetUsed(kFALSE);
+ mix = 0;
out << setw(10) << "MATERIAL ";
out.setf(static_cast<std::ios::fmtflags>(0),std::ios::floatfield);
-// matname = mat->GetName();
- objstr = (TObjString*)listflukanames->At(i);
+ objstr = (TObjString*)fMatNames->At(i);
matname = objstr->GetString();
- ToFlukaString(matname);
- zmat = mat->GetZ();
- if (zmat-Int_t(zmat)>0.01) {
- if (zmat-Int_t(zmat)>0.5) zmat = Int_t(zmat)+1.;
- else zmat = Int_t(zmat);
- }
- amat = mat->GetA();
- rhomat = mat->GetDensity();
- // write material card
+ z = mat->GetZ();
+ a = mat->GetA();
+ rho = mat->GetDensity();
if (mat->IsMixture()) {
out << setw(10) << " ";
out << setw(10) << " ";
mix = (TGeoMixture*)mat;
} else {
- out << setw(10) << setiosflags(ios::fixed) << setprecision(1) << zmat;
- out << setw(10) << setprecision(3) << amat;
+ out << setw(10) << setiosflags(ios::fixed) << setprecision(1) << z;
+ out << setw(10) << setprecision(3) << a;
}
out.setf(static_cast<std::ios::fmtflags>(0),std::ios::floatfield);
- out << setw(10) << setiosflags(ios::scientific) << setprecision(3) << rhomat;
+ out << setw(10) << setiosflags(ios::scientific) << setprecision(3) << rho;
out.setf(static_cast<std::ios::fmtflags>(0),std::ios::floatfield);
- out << setw(10) << setiosflags(ios::fixed) << setprecision(1) << Double_t(i+3);
+ out << setw(10) << setiosflags(ios::fixed) << setprecision(1) << Double_t(mat->GetIndex());
out << setw(10) << " ";
out << setw(10) << " ";
out << setw(8) << matname.Data() << endl;
- // add LOW-MAT crd
- if (!mat->IsMixture()) {
- out << setw(10) << "LOW-MAT ";
- out.setf(static_cast<std::ios::fmtflags>(0),std::ios::floatfield);
- out << setw(10) << setiosflags(ios::fixed) << setprecision(1) << Double_t(i+3);
- out << setw(10) << " ";
- out << setw(10) << " ";
- out << setw(10) << " ";
- out << setw(10) << " ";
- out << setw(10) << " ";
- out << setw(8) << matname.Data() << endl;
+ if (!mix) {
+ // add LOW-MAT card for NEON to associate with ARGON neutron xsec
+ if (z==10) {
+ out << setw(10) << "LOW-MAT ";
+ out.setf(static_cast<std::ios::fmtflags>(0),std::ios::floatfield);
+ out << setw(10) << setiosflags(ios::fixed) << setprecision(1) << Double_t(mat->GetIndex());
+ out << setw(10) << setiosflags(ios::fixed) << setprecision(1) << 18.;
+ out << setw(10) << setiosflags(ios::fixed) << setprecision(1) << -2.;
+ out << setw(10) << setiosflags(ios::fixed) << setprecision(1) << 293.;
+ out << setw(10) << " ";
+ out << setw(10) << " ";
+// out << setw(8) << matname.Data() << endl;
+ out << setw(8) << " " << endl;
+ }
+ else {
+ element = table->GetElement((int)z);
+ TString elename = element->GetTitle();
+ ToFlukaString(elename);
+ if( matname.CompareTo( elename ) != 0 ) {
+ out << setw(10) << "LOW-MAT ";
+ out.setf(static_cast<std::ios::fmtflags>(0),std::ios::floatfield);
+ out << setw(10) << setiosflags(ios::fixed) << setprecision(1) << Double_t(mat->GetIndex());
+ out << setw(10) << setiosflags(ios::fixed) << setprecision(1) << z;
+ out << setw(10) << setiosflags(ios::fixed) << setprecision(1) << " ";
+ out << setw(10) << setiosflags(ios::fixed) << setprecision(1) << " ";
+ out << setw(10) << " ";
+ out << setw(10) << " ";
+ // missing material at Low Energy Cross Section Table
+ if( (int)z==10 || (int)z==21 || (int)z==34 || (int)z==37 || (int)z==39 || (int)z==44 ||
+ (int)z==45 || (int)z==46 || (int)z==52 || (int)z==57 || (int)z==59 || (int)z==60 ||
+ (int)z==61 || (int)z==65 || (int)z==66 || (int)z==67 || (int)z==68 || (int)z==69 ||
+ (int)z==70 || (int)z==71 || (int)z==72 || (int)z==76 || (int)z==77 || (int)z==78 ||
+ (int)z==81 || (int)z==84 || (int)z==85 || (int)z==86 || (int)z==87 || (int)z==88 ||
+ (int)z==89 || (int)z==91 )
+ out << setw(8) << "UNKNOWN " << endl;
+ else
+ out << setw(8) << elename.Data() << endl;
+ // out << setw(8) << " " << endl;
+ }
+ }
+ continue;
}
- }
- // write mixture header
- PrintHeader(out, "COMPOUNDS");
- Int_t counttothree;
- TGeoMaterial *element;
- for (i=0; i<nfmater; i++) {
- mat = (TGeoMaterial*)listfluka->At(i);
- if (!mat->IsMixture()) continue;
- mix = (TGeoMixture*)mat;
counttothree = 0;
out << setw(10) << "COMPOUND ";
nelem = mix->GetNelements();
- objstr = (TObjString*)listflukanames->At(i);
+ objstr = (TObjString*)fMatNames->At(i);
matname = objstr->GetString();
-// printf("MIXTURE %s with index %i having %i elements\n", matname.Data(), mat->GetIndex(),nelem);
for (j=0; j<nelem; j++) {
- // dump mixture cards
-// printf(" #elem %i: Z=%g, A=%g, W=%g\n", j, (mix->GetZmixt())[j],
-// (mix->GetAmixt())[j],(mix->GetWmixt())[j]);
- wel = (mix->GetWmixt())[j];
- zel = (mix->GetZmixt())[j];
- ael = (mix->GetAmixt())[j];
- if (zel-Int_t(zel)>0.01) {
- // loop the temporary list
- element = 0;
- TGeoMaterial *mat1;
- for (Int_t imat=0; imat<i; imat++) {
- mat1 = (TGeoMaterial*)listfluka->At(imat);
- if (TMath::Abs(mat1->GetZ()-zel)>1E-4) continue;
- if (TMath::Abs(mat1->GetA()-ael)>1E-4) continue;
- element = mat1;
- break;
- }
- } else {
- memcpy(elname, &elNames[2*Int_t(zel-1)], 2);
- element = (TGeoMaterial*)listfluka->FindObject(elname);
- }
- if (!element) {
- Error("CreateFlukaMatFile", "Element Z=%g %s not found", zel, elname);
- return;
- }
- idmat = element->GetIndex();
-// printf("element %s , index=%i\n", element->GetName(), idmat);
+ w = (mix->GetWmixt())[j];
+ if (w<0.00001) w=0.00001;
+ z = (mix->GetZmixt())[j];
+ a = (mix->GetAmixt())[j];
+ idmat = GetElementIndex(Int_t(z));
+ if (!idmat) Error("CreateFlukaMatFile", "element with Z=%f not found", z);
out.setf(static_cast<std::ios::fmtflags>(0),std::ios::floatfield);
- out << setw(10) << setiosflags(ios::fixed) << setprecision(6) << -wel;
+ out << setw(10) << setiosflags(ios::fixed) << setprecision(6) << -w;
out.setf(static_cast<std::ios::fmtflags>(0),std::ios::floatfield);
out << setw(10) << setiosflags(ios::fixed) << setprecision(1) << Double_t(idmat);
counttothree++;
out << endl;
if ( (j+1) != nelem) out << setw(10) << "COMPOUND ";
counttothree = 0;
- }
- }
- //Unless we have 3, 6, 9... submaterials we need to put some empty
- //space and the compound name
+ }
+ }
if (nelem%3) {
for (j=0; j<(3-(nelem%3)); j++)
out << setw(10) << " " << setw(10) << " ";
out << matname.Data();
out << endl;
- }
- }
-
- // Now print the list of regions (volumes in TGeo)
+ }
+ }
Int_t nvols = gGeoManager->GetListOfUVolumes()->GetEntriesFast()-1;
TGeoVolume *vol;
-/*
- PrintHeader(out, "TGEO VOLUMES");
- for (i=1; i<=nvols; i++) {
- vol = gGeoManager->GetVolume(i);
- out.setf(std::ios::left, std::ios::adjustfield);
- out << setw(10) << i;
- out << setw(20) << vol->GetName() << endl;
- }
-*/
// Now print the material assignments
Double_t flagfield = 0.;
printf("#############################################################\n");
- if (fluka->IsFieldEnabled()) {
+ if (gFluka->IsFieldEnabled()) {
flagfield = 1.;
printf("Magnetic field enabled\n");
} else printf("Magnetic field disabled\n");
PrintHeader(out, "TGEO MATERIAL ASSIGNMENTS");
for (i=1; i<=nvols; i++) {
+ TGeoMedium* med;
vol = gGeoManager->GetVolume(i);
- mat = vol->GetMedium()->GetMaterial();
+ if ((med = vol->GetMedium()) == 0) continue;
+ mat = med->GetMaterial();
idmat = mat->GetIndex();
+ for (Int_t j=0; j<nfmater; j++) {
+ mat = (TGeoMaterial*)fMatList->At(j);
+ if (mat->GetIndex() == idmat) mat->SetUsed(kTRUE);
+ }
+
+ Float_t hasfield = (vol->GetMedium()->GetParam(1) > 0) ? flagfield : 0.;
+ out << "* Assigning material: " << vol->GetMedium()->GetMaterial()->GetName() << " to Volume: " << vol->GetName();
+ out << endl;
+
out << setw(10) << "ASSIGNMAT ";
out.setf(static_cast<std::ios::fmtflags>(0),std::ios::floatfield);
out << setw(10) << setiosflags(ios::fixed) << Double_t(idmat);
out << setw(10) << setiosflags(ios::fixed) << Double_t(i);
out << setw(10) << "0.0";
out << setw(10) << "0.0";
- out << setw(10) << setiosflags(ios::fixed) << flagfield;
+ out << setw(10) << setiosflags(ios::fixed) << hasfield;
out << setw(10) << "0.0";
out << endl;
}
- delete listfluka;
- listflukanames->Delete();
- delete listflukanames;
+ // dummy region
+ idmat = 2; // vacuum
+ fDummyRegion = nvols+1;
+ out << "* Dummy region: " << endl;
+ out << setw(10) << "ASSIGNMAT ";
+ out.setf(static_cast<std::ios::fmtflags>(0),std::ios::floatfield);
+ out << setw(10) << setiosflags(ios::fixed) << idmat;
+ out << setw(10) << setiosflags(ios::fixed) << fDummyRegion;
+ out << setw(10) << "0.0";
+ out << setw(10) << "0.0";
+ out << setw(10) << "0.0";
+ out << setw(10) << "0.0" << endl;
out.close();
fLastMaterial = nfmater+2;
}
+void TFlukaMCGeometry::CreatePemfFile()
+{
+ //
+ // Steering routine to write and process peg files producing the pemf input
+ //
+ char number[20];
+ Int_t countMatOK = 0;
+ Int_t countElemError = 0;
+ Int_t countNoStern = 0;
+ Int_t countMixError = 0;
+ Int_t countGas = 0;
+ Int_t countPemfError = 0;
+ Int_t i;
+ TGeoMaterial* mat = 0x0;
+ TString sname;
+
+ for (i = fIndmat; i < fLastMaterial - 2; i++) {
+ printf("Write Peg Files %d\n", i);
+
+ mat = (TGeoMaterial*)fMatList->At(i);
+ if (!mat->IsUsed()) continue;
+ sname = "mat";
+ sprintf(number, "%d", i);
+ sname.Append(number);
+ cout << endl;
+ cout << endl;
+ cout << "******************************************************************************" << endl;
+ cout << "******************************************************************************" << endl;
+ cout << endl;
+ WritePegFile(i, &countNoStern, &countElemError, &countMixError, &countGas);
+ sname.Prepend("$FLUPRO/pemf/rpemf peg/");
+ gSystem->Exec(sname.Data());
+
+ // check if the pemf file was created
+ TString sname = Form("peg/mat%d.pemf", i);
+ ifstream in( sname.Data() );
+ if ( in ) {
+ countMatOK++;
+ in.close();
+ } else {
+ cout << "ERROR Fail to create the pemf file " << sname << endl;
+ countPemfError++;
+ }
+ }
+ cout << "Materials (pemf created) " << countMatOK << endl;
+ cout << "Not Sternheimer par. found " << countNoStern << endl;
+ cout << "Elements with error definitions (Z not integer) " << countElemError << endl;
+ cout << "Mixtures with error definitions (Z not integer) " << countMixError << endl;
+ cout << "Posible Gas (rho < 0.01) " << countGas << endl;
+ // cout << "Posible Gas (without pressure information) " << countGasError << endl;
+ cout << "Pemf files Error " << countPemfError << endl;
+ cout << endl << endl;
+
+ sname = "cat peg/*.pemf > peg/FlukaVmc.pemf";
+ gSystem->Exec(sname.Data());
+ sname = "mv peg/FlukaVmc.pemf FlukaVmc.pemf";
+ gSystem->Exec(sname.Data());
+}
+
+//_____________________________________________________________________________
+void TFlukaMCGeometry::WritePegFile(Int_t imat, Int_t *NoStern, Int_t *ElemError,
+ Int_t *MixError, Int_t *countGas) const
+{
+ // Write the .peg file for one material
+
+ TGeoMaterial *mat = (TGeoMaterial*)fMatList->At(imat);
+ TString name = ((TObjString*)fMatNames->At(imat))->GetString();
+ TString line;
+ char number[20];
+ TGeoElement *elem = mat->GetElement();
+ name = name.Strip();
+ TString sname = "mat";
+ sprintf(number, "%d", imat);
+ sname.Append(number);
+ sname.Append(".peg");
+ sname.Prepend("peg/");
+ ofstream out;
+ out.open(sname.Data(), ios::out);
+ if (!out.good()) return;
+ Double_t dens = mat->GetDensity();
+ TGeoMixture *mix = 0;
+ Int_t nel = 1;
+ Int_t i;
+ if (mat->IsMixture()) {
+ mix = (TGeoMixture*)mat;
+ nel = mix->GetNelements();
+ }
+
+ if (nel==1) {
+ cout << "( Element ) " << name << " Z=" << mat->GetZ() << " Rho " << mat->GetDensity() << endl;
+
+ Double_t zel = mat->GetZ();
+ if( (zel-Int_t(zel))>0.001 || zel < 1 ) {
+ cout << " ERROR: A Element with not integer Z=" << zel << endl;
+ cout << endl;
+ (*ElemError)++;
+ return;
+ }
+
+ out << "ELEM" << endl;
+ out << " &INP IRAYL=1, RHO=" << dens << ", " << endl;
+
+ // check for the Sternheimer parameters
+ Double_t *issb_parm = GetISSB( mat->GetDensity(), 1, &zel, 0 );
+ if( issb_parm[0] > 0 && issb_parm[1] > 0 ) {
+ cout << "Sternheimer parameters found" << endl;
+ out << ", ISSB=1, IEV=" << issb_parm[0] << ", CBAR=" << issb_parm[1]
+ << ", X0=" << issb_parm[2] << "," << endl;
+ out << "X1=" <<issb_parm[3] <<", AFACT="<<issb_parm[4] <<", SK="
+ << issb_parm[5] << ", DELTA0=" << issb_parm[6];
+ }
+ else {
+ cout << "WARNING: Strange element, Sternheimer parameters not found" << endl;
+ (*NoStern)++;
+ }
+
+ if (dens<0.01) {
+ (*countGas)++;
+ out << " GASP=1." << endl;
+ }
+
+ out << " &END" << endl;
+ out << name.Data() << endl;
+ out << elem->GetName() << endl;
+
+ }
+ else {
+
+ cout << "( Mixture ) " << name << " Rho " << dens << " nElem " << nel << endl;
+
+ Double_t *zt = new Double_t[nel];
+ Double_t *wt = new Double_t[nel];
+ for (int j=0; j<nel; j++) {
+ zt[j] = (mix->GetZmixt())[j];
+ wt[j] = (mix->GetWmixt())[j];
+ if( (zt[j]-Int_t(zt[j])) > 0.001 || zt[j] < 1 ) {
+ cout << "ERROR Mixture " << name << " with an element with not integer Z=" << zt[j] << endl;
+ cout << endl;
+ (*MixError)++;
+ // just continue since the mixtures are not patch,
+ // but the final release should include the return
+ // return;
+ }
+ }
+ Double_t *issb_parm = GetISSB( mat->GetDensity(), nel, zt, wt );
+ out << "MIXT" << endl;
+ out << " &INP IRAYL=1, NE=" << nel << ", RHOZ=" << wt[0] << ",";
+ line = Form(" &INP IRAYL=1, NE=%d RHOZ=%g", nel, wt[0]);
+ for(int j=1; j<nel; j++) {
+ out << " " << wt[j] << ",";
+ line += Form(" %g,", wt[j] );
+ if( line.Length() > 60 ) { out << endl; line = ""; }
+ }
+ out << " RHO=" << mat->GetDensity() << ", ";
+ line += Form(" RHO=%g, ", mat->GetDensity());
+ if( line.Length() > 60 ) { out << endl; line = ""; }
+
+ if( issb_parm[0] > 0 && issb_parm[1] > 0 ) {
+ cout << "Sternheimer parameters found" << endl;
+ out << " ISSB=1, IEV=" << issb_parm[0] << ",";
+ line += Form(" ISSB=1, IEV=%g,", issb_parm[0]);
+ if( line.Length() > 60 ) { out << endl; line = ""; }
+ out << " CBAR=" << issb_parm[1] << ",";
+ line += Form(" CBAR=%g,",issb_parm[1]);
+ if( line.Length() > 60 ) { out << endl; line = ""; }
+ out << " X0=" << issb_parm[2] << ",";
+ line += Form(" X0=%g,", issb_parm[2]);
+ if( line.Length() > 60 ) { out << endl; line = ""; }
+ out << " X1=" << issb_parm[3] << ",";
+ line += Form(" X1=%g,", issb_parm[3]);
+ if( line.Length() > 60 ) { out << endl; line = ""; }
+ out << " AFACT="<< issb_parm[4] << ",";
+ line += Form(" AFACT=%g,", issb_parm[4]);
+ if( line.Length() > 60 ) { out << endl; line = ""; }
+ out << " SK=" << issb_parm[5] << ",";
+ line += Form(" SK=%g,", issb_parm[5]);
+ if( line.Length() > 60 ) { out << endl; line = ""; }
+ }
+ else {
+ cout << "Sternheimer parameters not found" << endl;
+ (*NoStern)++;
+ }
+
+ if (dens<0.01){
+ (*countGas)++;
+ out << " GASP=1." << endl;
+ }
+
+ out << " &END" << endl;
+ out << name.Data() << endl;
+ for (i=0; i<nel; i++) {
+ elem = mix->GetElement(i);
+ line = elem->GetName();
+ if (line.Length()==1) line.Append(" ");
+ out << line.Data() << " ";
+ }
+ out << endl;
+
+ delete [] zt;
+ delete [] wt;
+ }
+
+ Double_t ue = 3000000.; // [MeV]
+ Double_t up = 3000000.; // [MeV]
+ Double_t ae = -1.;
+ Double_t ap = -1.;
+
+
+ TObjArray* cutList = ((TFluka*) gMC)->GetListOfUserConfigs();
+ TIter next(cutList);
+ TFlukaConfigOption* proc;
+
+ while((proc = (TFlukaConfigOption*)next()))
+ {
+ if (proc->Medium() == mat->GetIndex()) {
+ ap = proc->Cut(kCUTGAM);
+ ae = proc->Cut(kCUTELE);
+ if (ap == -1.) ap = TFlukaConfigOption::DefaultCut(kCUTGAM);
+ if (ae == -1.) ae = TFlukaConfigOption::DefaultCut(kCUTELE);
+ break;
+ }
+ }
+
+ if (ap == -1.) ap = TFlukaConfigOption::DefaultCut(kCUTGAM);
+ if (ae == -1.) ae = TFlukaConfigOption::DefaultCut(kCUTELE);
+
+ ap *= 1000.; // [MeV]
+ ae = (ae + 0.00051099906) * 1000.; // [MeV]
+
+ out << "ENER" << endl;
+ out << " $INP AE=" << ae << ", UE=" << ue <<", AP=" << ap << ", UP=" << up << " $END" << endl;
+ out << "PWLF" << endl;
+ out << " $INP NALE=300, NALG=400, NALR=100 $END" << endl;
+ out << "DECK" << endl;
+ out << " $INP $END" << endl;
+ out << "TEST" << endl;
+ out << " $INP $END" << endl;
+ out.close();
+}
+
+Double_t * TFlukaMCGeometry::GetISSB(Double_t rho, Int_t nElem, Double_t *zelem, Double_t *welem ) const
+{
+ // Read the density effect parameters
+ // from R.M. Sternheimer et al. Atomic Data
+ // and Nuclear Data Tables, Vol. 30 No. 2
+ //
+ // return the parameters if the element/mixture match with one of the list
+ // otherwise returns the parameters set to 0
+
+ struct sternheimerData {
+ TString longname; // element/mixture name
+ Int_t nelems; // number of constituents N
+ Int_t Z[20]; //[nelems] Z
+ Double_t wt[20]; //[nelems] weight fraction
+ Double_t density; // g/cm3
+ Double_t iev; // Average Ion potential (eV)
+ // **** Sternheimer parameters ****
+ Double_t cbar; // CBAR
+ Double_t x0; // X0
+ Double_t x1; // X1
+ Double_t afact; // AFACT
+ Double_t sk; // SK
+ Double_t delta0; // DELTA0
+
+ sternheimerData():
+ longname(""), nelems(0), density(0), iev(0), cbar(0),
+ x0(0), x1(0), afact(0), sk(0), delta0(0) {}
+ };
+
+ TString shortname;
+ TString formula;
+ Int_t num;
+ char state;
+
+ static Double_t parameters[7];
+ memset( parameters, 0, sizeof(Double_t) );
+
+ static sternheimerData sternDataArray[300];
+ static Bool_t isFileRead = kFALSE;
+
+ // Read the data file if is needed
+ if( isFileRead == kFALSE ) {
+ TString sSternheimerInp = getenv("ALICE_ROOT");
+ sSternheimerInp +="/TFluka/input/Sternheimer.data";
+
+ ifstream in(sSternheimerInp);
+ char line[100];
+ in.getline(line, 100);
+ in.getline(line, 100);
+ in.getline(line, 100);
+ in.getline(line, 100);
+ in.getline(line, 100);
+ in.getline(line, 100);
+
+
+ Int_t is = 0;
+ while( !in.eof() ) {
+ in >> shortname >> num >> sternDataArray[is].nelems
+ >> sternDataArray[is].longname >> formula >> state;
+ if( in.eof() ) break;
+ for(int i=0; i<sternDataArray[is].nelems; i++) {
+ in >> sternDataArray[is].Z[i] >> sternDataArray[is].wt[i];
+ }
+ in >> sternDataArray[is].density;
+ in >> sternDataArray[is].iev;
+ in >> sternDataArray[is].cbar;
+ in >> sternDataArray[is].x0;
+ in >> sternDataArray[is].x1;
+ in >> sternDataArray[is].afact;
+ in >> sternDataArray[is].sk;
+ if( sternDataArray[is].nelems == 1 ) in >> sternDataArray[is].delta0;
+ is++;
+ }
+ isFileRead = kTRUE;
+ in.close();
+ }
+
+ Int_t is = 0;
+ while( is < 280 ) {
+
+ // check for elements
+ if( sternDataArray[is].nelems == 1 && nElem == 1
+ && sternDataArray[is].Z[0] == Int_t(*zelem)
+ && TMath::Abs( (sternDataArray[is].density - rho)/sternDataArray[is].density ) < 0.1 ) {
+ cout << sternDataArray[is].longname << " #elems:" << sternDataArray[is].nelems << " Rho:"
+ << sternDataArray[is].density << endl;
+ cout << sternDataArray[is].iev << " "
+ << sternDataArray[is].cbar << " "
+ << sternDataArray[is].x0 << " "
+ << sternDataArray[is].x1 << " "
+ << sternDataArray[is].afact << " "
+ << sternDataArray[is].sk << " "
+ << sternDataArray[is].delta0 << endl;
+
+ parameters[0] = sternDataArray[is].iev;
+ parameters[1] = sternDataArray[is].cbar;
+ parameters[2] = sternDataArray[is].x0;
+ parameters[3] = sternDataArray[is].x1;
+ parameters[4] = sternDataArray[is].afact;
+ parameters[5] = sternDataArray[is].sk;
+ parameters[6] = sternDataArray[is].delta0;
+ return parameters;
+ }
+
+ // check for mixture
+ int nmatch = 0;
+ if( sternDataArray[is].nelems > 1 && sternDataArray[is].nelems == nElem ) {
+ for(int j=0; j<sternDataArray[is].nelems; j++) {
+ if( sternDataArray[is].Z[j] == Int_t(zelem[j]) &&
+ TMath::Abs( (sternDataArray[is].wt[j] - welem[j])/sternDataArray[is].wt[j] ) < 0.1 )
+ nmatch++;
+ }
+ }
+
+ if( sternDataArray[is].nelems > 1 &&
+ TMath::Abs( (sternDataArray[is].density - rho)/sternDataArray[is].density ) < 0.1
+ && nmatch == sternDataArray[is].nelems ) {
+ cout << sternDataArray[is].longname << " #elem:" << sternDataArray[is].nelems << " Rho:"
+ << sternDataArray[is].density << endl;
+ cout << sternDataArray[is].iev << " "
+ << sternDataArray[is].cbar << " "
+ << sternDataArray[is].x0 << " "
+ << sternDataArray[is].x1 << " "
+ << sternDataArray[is].afact << " "
+ << sternDataArray[is].sk << " "
+ << sternDataArray[is].delta0 << endl;
+
+ parameters[0] = sternDataArray[is].iev;
+ parameters[1] = sternDataArray[is].cbar;
+ parameters[2] = sternDataArray[is].x0;
+ parameters[3] = sternDataArray[is].x1;
+ parameters[4] = sternDataArray[is].afact;
+ parameters[5] = sternDataArray[is].sk;
+ parameters[6] = 0;
+ return parameters;
+ }
+ is++;
+ }
+ return parameters;
+}
+
//_____________________________________________________________________________
void TFlukaMCGeometry::PrintHeader(ofstream &out, const char *text) const
{
if (gGeoManager->IsOutside()) return 0;
return gGeoManager->GetCurrentNode()->GetUniqueID();
}
+
+//_____________________________________________________________________________
+Int_t TFlukaMCGeometry::GetElementIndex(Int_t z) const
+{
+// Get index of a material having a given Z element.
+ TIter next(fMatList);
+ TGeoMaterial *mat;
+ Int_t index = 0;
+ while ((mat=(TGeoMaterial*)next())) {
+ if (mat->IsMixture()) continue;
+ if (mat->GetElement()->Z() == z) return mat->GetIndex();
+ }
+ return index;
+}
+
//_____________________________________________________________________________
-void TFlukaMCGeometry::SetMreg(Int_t mreg)
+void TFlukaMCGeometry::SetMreg(Int_t mreg, Int_t lttc)
{
// Update if needed next history;
- if (fluka->GetDummyBoundary()==2) {
- gGeoManager->CdNode(fNextLattice-1);
- return;
- }
- Int_t curreg = (gGeoManager->IsOutside())?(mcgeom->NofVolumes()+1):gGeoManager->GetCurrentVolume()->GetNumber();
- if (mreg==curreg) return;
- if (mreg==fNextRegion) {
- if (fNextLattice!=999999999) gGeoManager->CdNode(fNextLattice-1);
+// if (gFluka->GetDummyBoundary()==2) {
+// gGeoManager->CdNode(fNextLattice-1);
+// return;
+// }
+ if (lttc == TFlukaMCGeometry::kLttcOutside) {
+ fCurrentRegion = NofVolumes()+2;
+ fCurrentLattice = lttc;
+ gGeoManager->CdTop();
+ gGeoManager->SetOutside(kTRUE);
+ }
+ if (lttc == TFlukaMCGeometry::kLttcVirtual) return;
+ if (lttc <=0) {
+ Error("TFlukaMCGeometry::SetMreg","Invalide lattice %i",lttc);
return;
- } else {
- if (mreg == fCurrentRegion) {
- if (fCurrentLattice!=999999999) gGeoManager->CdNode(fCurrentLattice-1);
- return;
- }
- }
- if (fDebug) printf("ERROR: mreg=%i neither current nor next region\n", mreg);
+ }
+ fCurrentRegion = mreg;
+ fCurrentLattice = lttc;
+
+ Int_t crtlttc = gGeoManager->GetCurrentNodeId()+1;
+ if (crtlttc == lttc) return;
+ gGeoManager->CdNode(lttc-1);
}
//_____________________________________________________________________________
if (str(pos)==' ') str.Replace(pos,1,"_",1);
return;
}
+
+//_____________________________________________________________________________
+void TFlukaMCGeometry::FlukaMatName(TString &str) const
+{
+// Strip the detector name
+
+ TObjArray * tokens = str.Tokenize("_");
+ Int_t ntok = tokens->GetEntries();
+ if (ntok > 0) {
+ TString head = ((TObjString*) tokens->At(0))->GetString();
+ Int_t nhead = head.Length();
+ str = str.Remove(0, nhead + 1);
+ }
+ tokens->Clear();
+ delete tokens;
+
+// Convert a name to upper case 8 chars.
+ ToFlukaString(str);
+ Int_t ilast;
+ for (ilast=7; ilast>0; ilast--) if (str(ilast)!=' ') break;
+ if (ilast>5) ilast = 5;
+ char number[3];
+ TIter next(fMatNames);
+ TObjString *objstr;
+ TString matname;
+ Int_t index = 0;
+ while ((objstr=(TObjString*)next())) {
+ matname = objstr->GetString();
+ if (matname == str) {
+ index++;
+ if (index<10) {
+ number[0] = '0';
+ sprintf(&number[1], "%d", index);
+ } else if (index<100) {
+ sprintf(number, "%d", index);
+ } else {
+ Error("FlukaMatName", "Too many materials %s", str.Data());
+ return;
+ }
+ str.Replace(ilast+1, 2, number);
+ str.Remove(8);
+ }
+ }
+}
+
//______________________________________________________________________________
void TFlukaMCGeometry::Vname(const char *name, char *vname) const
{
}
+//______________________________________________________________________________
+Int_t TFlukaMCGeometry::GetNstep()
+{
+ // return gNstep for debug propose
+ return gNstep;
+}
+
// FLUKA GEOMETRY WRAPPERS - to replace FLUGG wrappers
//_____________________________________________________________________________
// card in fluka input), returns 1 if user wants Fluka always to
// use DNEAR (in this case, be sure that GEANT4 DNEAR is unique,
// coming from all directions!!!)
- if (mcgeom->IsDebugging()) printf("========== Dummy IDNRWR\n");
+ if (gMCGeom->IsDebugging()) printf("========== Dummy IDNRWR\n");
return 0;
}
//_____________________________________________________________________________
void g1wr(Double_t &pSx, Double_t &pSy, Double_t &pSz,
Double_t *pV, Int_t &oldReg , const Int_t &oldLttc, Double_t &propStep,
- Int_t &nascFlag, Double_t &retStep, Int_t &newReg,
- Double_t &saf, Int_t &newLttc, Int_t <tcFlag,
+ Int_t &/*nascFlag*/, Double_t &retStep, Int_t &newReg,
+ Double_t &saf, Int_t &newLttc, Int_t <tcFlag,
Double_t *sLt, Int_t *jrLt)
{
// Initialize FLUKa point and direction;
- kNstep++;
-/*
- if (kNstep>0) {
- mcgeom->SetDebugMode(kTRUE);
- fluka->SetVerbosityLevel(3);
- }
- if (kNstep>6520) {
- mcgeom->SetDebugMode(kFALSE);
- fluka->SetVerbosityLevel(0);
- }
- if ((kNstep%10)==0) printf("step %i\n", kNstep);
-*/
+ static Int_t ierr = 0;
+ gNstep++;
+// gMCGeom->SetDebugMode(kTRUE);
+
+ NORLAT.xn[0] = pSx;
+ NORLAT.xn[1] = pSy;
+ NORLAT.xn[2] = pSz;
+
+ Int_t olttc = oldLttc;
+ if (oldLttc<=0) {
+ gGeoManager->FindNode(pSx,pSy,pSz);
+ olttc = gGeoManager->GetCurrentNodeId()+1;
+ oldReg = gGeoManager->GetCurrentVolume()->GetNumber();
+ }
- if (mcgeom->IsDebugging()) {
- printf("========== Inside G1WR\n");
- printf(" point/dir:(%14.9f, %14.9f, %14.9f, %g, %g, %g)\n", pSx,pSy,pSz,pV[0],pV[1],pV[2]);
- printf(" oldReg=%i oldLttc=%i pstep=%f\n",oldReg, oldLttc, propStep);
- }
- gGeoManager->SetCurrentPoint(pSx, pSy, pSz);
- gGeoManager->SetCurrentDirection(pV);
- mcgeom->SetCurrentRegion(oldReg, oldLttc);
+ if (gMCGeom->IsDebugging()) {
+ cout << "g1wr gNstep=" << gNstep << " oldReg="<< oldReg <<" olttc="<< olttc
+ << " track=" << TRACKR.ispusr[mkbmx2-1] << endl;
+ cout << " point: (" << pSx << ", " << pSy << ", " << pSz << ") dir: ("
+ << pV[0] << ", " << pV[1] << ", " << pV[2] << ")" << endl;
+ }
+
+
+ Int_t ccreg=0,cclat=0;
+ gMCGeom->GetCurrentRegion(ccreg,cclat);
+ Bool_t crossed = (ccreg==oldReg && cclat==olttc)?kFALSE:kTRUE;
+
+ gMCGeom->SetCurrentRegion(oldReg, olttc);
// Initialize default return values
lttcFlag = 0;
- jrLt[lttcFlag] = oldLttc;
+ jrLt[lttcFlag] = olttc;
sLt[lttcFlag] = propStep;
jrLt[lttcFlag+1] = -1;
sLt[lttcFlag+1] = 0.;
newReg = oldReg;
- newLttc = oldLttc;
- // check if dummy boundary flag is set
+ newLttc = olttc;
+ Bool_t crossedDummy = (oldReg == gFluka->GetDummyRegion())?kTRUE:kFALSE;
Int_t curLttc, curReg;
- if (fluka->IsDummyBoundary()) {
- // printf("Dummy boundary intercepted. Point is: %f, %f, %f\n", pSx, pSy, pSz);
- Bool_t crossedDummy = (oldLttc == TFlukaMCGeometry::kLttcVirtual)?kTRUE:kFALSE;
- if (crossedDummy) {
- // FLUKA crossed the dummy boundary - update new region/history
- retStep = 0.;
- saf = 0.;
- mcgeom->GetNextRegion(newReg, newLttc);
- mcgeom->SetMreg(newReg);
- if (mcgeom->IsDebugging()) printf(" virtual newReg=%i newLttc=%i\n", newReg, newLttc);
- sLt[lttcFlag] = 0.; // null step in current region
- lttcFlag++;
- jrLt[lttcFlag] = newLttc;
- sLt[lttcFlag] = 0.; // null step in next region
- jrLt[lttcFlag+1] = -1;
- sLt[lttcFlag+1] = 0.;
- fluka->SetDummyBoundary(0);
- return;
- }
- }
-
+ if (crossedDummy) {
+ // FLUKA crossed the dummy boundary - update new region/history
+ retStep = TGeoShape::Tolerance();
+ saf = 0.;
+ gMCGeom->GetNextRegion(newReg, newLttc);
+ gMCGeom->SetMreg(newReg, newLttc);
+ sLt[lttcFlag] = TGeoShape::Tolerance(); // null step in current region
+ lttcFlag++;
+ jrLt[lttcFlag] = newLttc;
+ sLt[lttcFlag] = TGeoShape::Tolerance(); // null step in next region
+ jrLt[lttcFlag+1] = -1;
+ sLt[lttcFlag+1] = 0.; // null step in next region;
+ if (gMCGeom->IsDebugging()) printf("=> crossed dummy!! newReg=%i newLttc=%i\n", newReg, newLttc);
+ return;
+ }
+
// Reset outside flag
- if (gGeoManager->IsOutside()) {
- gGeoManager->SetOutside(kFALSE);
- gGeoManager->CdTop();
- }
-
- // Reset dummy boundary flag
- fluka->SetDummyBoundary(0);
-
+ gGeoManager->SetOutside(kFALSE);
+
curLttc = gGeoManager->GetCurrentNodeId()+1;
curReg = gGeoManager->GetCurrentVolume()->GetNumber();
- if (oldLttc != curLttc) {
+ if (olttc != curLttc) {
// FLUKA crossed the boundary : we trust that the given point is really there,
// so we just update TGeo state
- gGeoManager->CdNode(oldLttc-1);
+ gGeoManager->CdNode(olttc-1);
curLttc = gGeoManager->GetCurrentNodeId()+1;
curReg = gGeoManager->GetCurrentVolume()->GetNumber();
- if (mcgeom->IsDebugging()) printf(" re-initialized point: curReg=%i curLttc=%i\n", curReg, curLttc);
- }
- // Now the current TGeo state reflects the FLUKA state
- if (mcgeom->IsDebugging()) printf(" current path: %s\n", gGeoManager->GetPath());
- Double_t extra = 1E-6;
- Double_t tmpStep = propStep + extra;
- gGeoManager->FindNextBoundary(-tmpStep);
- Double_t snext = gGeoManager->GetStep();
- // !!!!!
- if (snext<=0) {
- // FLUKA is in the wrong region, notify it
- if (mcgeom->IsDebugging()) printf("ERROR: snext=%f\n", snext);
-// newReg = -3;
-// return;
- snext = extra;
+ }
+ // Now the current TGeo state reflects the FLUKA state
+
+ gGeoManager->SetCurrentPoint(pSx, pSy, pSz);
+ gGeoManager->SetCurrentDirection(pV);
+ Double_t pt[3], local[3], ldir[3];
+ Int_t pid = TRACKR.jtrack;
+ pt[0] = pSx;
+ pt[1] = pSy;
+ pt[2] = pSz;
+ gGeoManager->MasterToLocal(pt,local);
+ gGeoManager->MasterToLocalVect(pV,ldir);
+/*
+ Bool_t valid = gGeoManager->GetCurrentVolume()->Contains(local);
+ if (!valid) {
+ printf("location not valid in %s pid=%i\n", gGeoManager->GetPath(),pid);
+ printf("local:(%f, %f, %f) ldir:(%f, %f, %f)\n", local[0],local[1],local[2],ldir[0],ldir[1],ldir[2]);
+// gGeoManager->FindNode();
+// printf(" -> actual location: %s\n", gGeoManager->GetPath());
}
- saf = gGeoManager->GetSafeDistance();
- Bool_t cross = kFALSE;
- Bool_t onBound = kFALSE;
- if (snext<tmpStep) {
- // We have some boundary in the way
- Double_t dd = snext-propStep;
- if (dd < 0) {
- cross = kTRUE;
- dd = -dd;
- }
- if (dd < 1E-8) onBound = kTRUE;
+*/
+ Double_t pstep = propStep;
+ Double_t snext = propStep;
+ const Double_t epsil = 0.9999999 * TGeoShape::Tolerance();
+ // This should never happen !!!
+ if (pstep<TGeoShape::Tolerance()) {
+ printf("Proposed step is 0 !!!\n");
+ pstep = 2.*TGeoShape::Tolerance();
+ }
+ if (crossed) {
+ gGeoManager->FindNextBoundaryAndStep(pstep);
+ snext = gGeoManager->GetStep();
+ saf = 0.;
+ if (snext <= TGeoShape::Tolerance()) {
+// printf("FLUKA crossed boundary but snext=%g\n", snext);
+ ierr++;
+ snext = epsil;
+ } else {
+ snext += TGeoShape::Tolerance();
+ ierr = 0;
+ }
+ } else {
+ gGeoManager->FindNextBoundaryAndStep(pstep, kTRUE);
+ snext = gGeoManager->GetStep();
+ saf = gGeoManager->GetSafeDistance();
+ if (snext <= TGeoShape::Tolerance()) {
+// printf("FLUKA put particle on bondary without crossing\n");
+ ierr++;
+ snext = epsil;
+ saf = 0.;
+ } else {
+ snext += TGeoShape::Tolerance();
+ ierr = 0;
+ }
+ if (saf<0) saf=0.;
+ saf -= saf*3.0e-09;
}
- snext += 1.E-8;
- if (mcgeom->IsDebugging()) {
- if (!cross) printf(" physical step approved: %f\n", propStep);
- else printf(" boundary crossing at: %f\n", snext);
- if (onBound) printf(" step on boundary limit ! NASC=%i\n", nascFlag);
+// if (ierr>1) {
+// printf("%d snext=%g\n", ierr, snext);
+// }
+ if (ierr == 10) {
+// printf("Too many null steps - sending error code -33...\n");
+ newReg = -33; // Error code
+ ierr = 0;
+ return;
}
- if (!cross) {
+
+ PAREM.dist = snext;
+ NORLAT.distn = snext;
+ NORLAT.xn[0] += snext*pV[0];
+ NORLAT.xn[1] += snext*pV[1];
+ NORLAT.xn[2] += snext*pV[2];
+ if (!gGeoManager->IsOnBoundary()) {
// Next boundary further than proposed step, which is approved
+ if (saf>propStep) saf = propStep;
retStep = propStep;
sLt[lttcFlag] = propStep;
return;
}
- // The next boundary is closer. We try to cross it.
- Double_t *point = gGeoManager->GetCurrentPoint();
- Double_t *dir = gGeoManager->GetCurrentDirection();
- Double_t pt[3];
- memcpy(pt, point, 3*sizeof(Double_t));
-
- Int_t i;
- for (i=0;i<3;i++) point[i] += snext*dir[i];
- gGeoManager->FindNode();
+ if (saf>snext) saf = snext; // Safety should be less than the proposed step if a boundary will be crossed
+ gGeoManager->SetCurrentPoint(pSx,pSy,pSz);
newLttc = (gGeoManager->IsOutside())?(TFlukaMCGeometry::kLttcOutside):gGeoManager->GetCurrentNodeId()+1;
- if (newLttc == oldLttc) {
- // brute force ...
- // Just try a fast extra small step
- snext += 1E-6;
- for (i=0;i<3;i++) point[i] = pt[i]+snext*dir[i];
- gGeoManager->FindNode();
- newLttc = (gGeoManager->IsOutside())?(TFlukaMCGeometry::kLttcOutside):gGeoManager->GetCurrentNodeId()+1;
- if (newLttc == oldLttc) {
- // check if state changes at the end of the proposed step
- for (i=0;i<3;i++) point[i] = pt[i]+propStep*dir[i];
- gGeoManager->FindNode();
- newLttc = (gGeoManager->IsOutside())?(TFlukaMCGeometry::kLttcOutside):gGeoManager->GetCurrentNodeId()+1;
- if (newLttc==oldLttc) {
- // approve step
- retStep = propStep;
- sLt[lttcFlag] = propStep;
- return;
- }
- // snext is underestimated - we will create a virtual one to overcome the error
-// printf("some boundary in the way...\n");
- }
- }
- gGeoManager->SetCurrentPoint(pt);
-// newLttc = (gGeoManager->IsOutside())?(TFlukaMCGeometry::kLttcOutside):gGeoManager->GetCurrentNodeId()+1;
- newReg = (gGeoManager->IsOutside())?(mcgeom->NofVolumes()+1):gGeoManager->GetCurrentVolume()->GetNumber();
- if (mcgeom->IsDebugging()) printf(" newReg=%i newLttc=%i\n", newReg, newLttc);
+ newReg = (gGeoManager->IsOutside())?(gMCGeom->NofVolumes()+2):gGeoManager->GetCurrentVolume()->GetNumber();
+ if (gMCGeom->IsDebugging()) printf("=> newReg=%i newLttc=%i\n", newReg, newLttc);
// We really crossed the boundary, but is it the same region ?
- mcgeom->SetNextRegion(newReg, newLttc);
- if (newReg == oldReg) {
+ gMCGeom->SetNextRegion(newReg, newLttc);
+
+ if ( ((newReg==oldReg && newLttc!=olttc) || (oldReg!=newReg && olttc==newLttc) ) && pid!=-1) {
// Virtual boundary between replicants
- if (mcgeom->IsDebugging()) printf(" DUMMY boundary\n");
- newReg = 1; // cheat FLUKA telling it it crossed the TOP region
+ newReg = gFluka->GetDummyRegion();
newLttc = TFlukaMCGeometry::kLttcVirtual;
- // mark that next boundary is virtual
- fluka->SetDummyBoundary(1);
- }
+ if (gMCGeom->IsDebugging()) printf("=> virtual boundary!! newReg=%i newLttc=%i\n", newReg, newLttc);
+ }
+
retStep = snext;
sLt[lttcFlag] = snext;
lttcFlag++;
jrLt[lttcFlag] = newLttc;
sLt[lttcFlag] = snext;
jrLt[lttcFlag+1] = -1;
- sLt[lttcFlag+1] = 0.;
- if (newLttc!=oldLttc) {
- if (gGeoManager->IsOutside()) {
- gGeoManager->SetOutside(kFALSE);
- gGeoManager->CdTop();
- }
- gGeoManager->CdTop();
- if (!gGeoManager->GetCurrentMatrix()->IsIdentity()) printf("ERROR at step %i\n", kNstep);
- gGeoManager->CdNode(oldLttc-1);
- }
- if (mcgeom->IsDebugging()) {
+ sLt[lttcFlag+1] = 0.;
+ gGeoManager->SetOutside(kFALSE);
+ gGeoManager->CdNode(olttc-1);
+ if (gMCGeom->IsDebugging()) {
printf("=> snext=%g safe=%g\n", snext, saf);
for (Int_t i=0; i<lttcFlag+1; i++) printf(" jrLt[%i]=%i sLt[%i]=%g\n", i,jrLt[i],i,sLt[i]);
- }
- if (mcgeom->IsDebugging()) printf("<= G1WR (in: %s)\n", gGeoManager->GetPath());
+ }
}
//_____________________________________________________________________________
void g1rtwr()
{
- if (mcgeom->IsDebugging()) printf("========== Dummy G1RTWR\n");
+
+ if (gMCGeom->IsDebugging()) printf("========== Dummy G1RTWR\n");
}
//_____________________________________________________________________________
-void conhwr(Int_t & /*intHist*/, Int_t * /*incrCount*/)
+void conhwr(Int_t & intHist, Int_t & incrCount)
{
- if (mcgeom->IsDebugging()) printf("========== Dummy CONHWR\n");
+ if (gMCGeom->IsDebugging()) printf("========== Dummy CONHWR intHist=%d incrCount=%d currentNodeId=%d\n",
+ intHist, incrCount, gGeoManager->GetCurrentNodeId()+1 );
+// if( incrCount != -1 ) {
+// if (intHist==0) gGeoManager->CdTop();
+// else gGeoManager->CdNode(intHist-1);
+// }
+// intHist = gGeoManager->GetCurrentNodeId()+1;
}
//_____________________________________________________________________________
void inihwr(Int_t &intHist)
{
- if (mcgeom->IsDebugging()) printf("========== Inside INIHWR -> reinitializing history: %i\n", intHist);
+ if (gMCGeom->IsDebugging())
+ printf("========== Inside INIHWR -> reinitializing history: %i \n", intHist);
if (gGeoManager->IsOutside()) gGeoManager->CdTop();
- if (intHist<=0) {
+ if (intHist<0) {
// printf("=== wrong history number\n");
return;
}
if (intHist==0) gGeoManager->CdTop();
else gGeoManager->CdNode(intHist-1);
- if (mcgeom->IsDebugging()) {
+ if (gMCGeom->IsDebugging()) {
printf(" --- current path: %s\n", gGeoManager->GetPath());
printf("<= INIHWR\n");
- }
+ }
}
//_____________________________________________________________________________
// Geometry initialization wrapper called by FLUKAM. Provides to FLUKA the
// number of regions (volumes in TGeo)
// build application geometry
- if (mcgeom->IsDebugging()) printf("========== Inside JOMIWR\n");
- flukaReg = gGeoManager->GetListOfUVolumes()->GetEntriesFast();
- if (mcgeom->IsDebugging()) printf("<= JOMIWR: last region=%i\n", flukaReg);
+ if (gMCGeom->IsDebugging()) printf("========== Inside JOMIWR\n");
+ flukaReg = gGeoManager->GetListOfUVolumes()->GetEntriesFast()+1;
+ if (gMCGeom->IsDebugging()) printf("<= JOMIWR: last region=%i\n", flukaReg);
}
//_____________________________________________________________________________
void lkdbwr(Double_t &pSx, Double_t &pSy, Double_t &pSz,
- Double_t * /*pV*/, const Int_t &oldReg, const Int_t &oldLttc,
- Int_t &newReg, Int_t &flagErr, Int_t &newLttc)
+ Double_t *pV, const Int_t &oldReg, const Int_t &oldLttc,
+ Int_t &flagErr, Int_t &newReg, Int_t &newLttc)
{
- if (mcgeom->IsDebugging()) {
+ if (gMCGeom->IsDebugging()) {
printf("========== Inside LKDBWR (%f, %f, %f)\n",pSx, pSy, pSz);
-// printf(" in: pV=(%f, %f, %f)\n", pV[0], pV[1], pV[2]);
+ printf(" in: pV=(%f, %f, %f)\n", pV[0], pV[1], pV[2]);
printf(" in: oldReg=%i oldLttc=%i\n", oldReg, oldLttc);
}
- TGeoNode *node = gGeoManager->FindNode(pSx, pSy, pSz);
- if (gGeoManager->IsOutside()) {
- newReg = mcgeom->NofVolumes()+1;
-// newLttc = gGeoManager->GetCurrentNodeId();
- newLttc = 999999999;
- if (mcgeom->IsDebugging()) {
- printf("OUTSIDE\n");
- printf(" out: newReg=%i newLttc=%i\n", newReg, newLttc);
- printf("<= LKMGWR\n");
- }
- flagErr = newReg;
- return;
- }
- newReg = node->GetVolume()->GetNumber();
- newLttc = gGeoManager->GetCurrentNodeId()+1;
- mcgeom->SetNextRegion(newReg, newLttc);
- flagErr = newReg;
- if (mcgeom->IsDebugging()) {
- printf(" out: newReg=%i newLttc=%i\n", newReg, newLttc);
- printf("<= LKDBWR\n");
- }
+ lkwr(pSx,pSy,pSz,pV,oldReg,oldLttc,flagErr,newReg,newLttc);
}
//_____________________________________________________________________________
void lkfxwr(Double_t &pSx, Double_t &pSy, Double_t &pSz,
- Double_t * /*pV*/, const Int_t &oldReg, const Int_t &oldLttc,
- Int_t &newReg, Int_t &flagErr, Int_t &newLttc)
+ Double_t *pV, const Int_t &oldReg, const Int_t &oldLttc,
+ Int_t &flagErr, Int_t &newReg, Int_t &newLttc)
{
- if (mcgeom->IsDebugging()) {
+ if (gMCGeom->IsDebugging()) {
printf("========== Inside LKFXWR (%f, %f, %f)\n",pSx, pSy, pSz);
-// printf(" in: pV=(%f, %f, %f)\n", pV[0], pV[1], pV[2]);
+ printf(" in: pV=(%f, %f, %f)\n", pV[0], pV[1], pV[2]);
printf(" in: oldReg=%i oldLttc=%i\n", oldReg, oldLttc);
}
- TGeoNode *node = gGeoManager->FindNode(pSx, pSy, pSz);
- if (gGeoManager->IsOutside()) {
- newReg = mcgeom->NofVolumes()+1;
-// newLttc = gGeoManager->GetCurrentNodeId();
- newLttc = 999999999;
- if (mcgeom->IsDebugging()) {
- printf("OUTSIDE\n");
- printf(" out: newReg=%i newLttc=%i\n", newReg, newLttc);
- printf("<= LKMGWR\n");
- }
- flagErr = newReg;
- return;
- }
- newReg = node->GetVolume()->GetNumber();
- newLttc = gGeoManager->GetCurrentNodeId()+1;
- mcgeom->SetNextRegion(newReg, newLttc);
- flagErr = newReg;
- if (mcgeom->IsDebugging()) {
- printf(" out: newReg=%i newLttc=%i\n", newReg, newLttc);
- printf("<= LKFXWR\n");
- }
+ lkwr(pSx,pSy,pSz,pV,oldReg,oldLttc,flagErr,newReg,newLttc);
}
//_____________________________________________________________________________
void lkmgwr(Double_t &pSx, Double_t &pSy, Double_t &pSz,
- Double_t * /*pV*/, const Int_t &oldReg, const Int_t &oldLttc,
- Int_t &flagErr, Int_t &newReg, Int_t &newLttc)
+ Double_t *pV, const Int_t &oldReg, const Int_t &oldLttc,
+ Int_t &flagErr, Int_t &newReg, Int_t &newLttc)
{
- if (mcgeom->IsDebugging()) {
+ if (gMCGeom->IsDebugging()) {
printf("========== Inside LKMGWR (%f, %f, %f)\n",pSx, pSy, pSz);
-// printf(" in: pV=(%f, %f, %f)\n", pV[0], pV[1], pV[2]);
+ printf(" in: pV=(%f, %f, %f)\n", pV[0], pV[1], pV[2]);
printf(" in: oldReg=%i oldLttc=%i\n", oldReg, oldLttc);
}
- TGeoNode *node = gGeoManager->FindNode(pSx, pSy, pSz);
- if (gGeoManager->IsOutside()) {
- newReg = mcgeom->NofVolumes()+1;
-// newLttc = gGeoManager->GetCurrentNodeId();
- newLttc = 999999999;
- if (mcgeom->IsDebugging()) {
- printf("OUTSIDE\n");
- printf(" out: newReg=%i newLttc=%i\n", newReg, newLttc);
- printf("<= LKMGWR\n");
- }
- flagErr = newReg;
- return;
- }
- newReg = node->GetVolume()->GetNumber();
- newLttc = gGeoManager->GetCurrentNodeId()+1;
- mcgeom->SetNextRegion(newReg, newLttc);
- flagErr = newReg;
- if (mcgeom->IsDebugging()) {
- printf(" out: newReg=%i newLttc=%i\n", newReg, newLttc);
- printf("<= LKMGWR\n");
- }
+ lkwr(pSx,pSy,pSz,pV,oldReg,oldLttc,flagErr,newReg,newLttc);
}
//_____________________________________________________________________________
void lkwr(Double_t &pSx, Double_t &pSy, Double_t &pSz,
- Double_t * /*pV*/, const Int_t &oldReg, const Int_t &oldLttc,
- Int_t &newReg, Int_t &flagErr, Int_t &newLttc)
+ Double_t *pV, const Int_t &oldReg, const Int_t &oldLttc,
+ Int_t &flagErr, Int_t &newReg, Int_t &newLttc)
{
- if (mcgeom->IsDebugging()) {
+ if (gMCGeom->IsDebugging()) {
printf("========== Inside LKWR (%f, %f, %f)\n",pSx, pSy, pSz);
-// printf(" in: pV=(%f, %f, %f)\n", pV[0], pV[1], pV[2]);
+ printf(" in: pV=(%f, %f, %f)\n", pV[0], pV[1], pV[2]);
printf(" in: oldReg=%i oldLttc=%i\n", oldReg, oldLttc);
}
- TGeoNode *node = gGeoManager->FindNode(pSx, pSy, pSz);
+ flagErr = 0;
+ Double_t epsil = 1000.*TGeoShape::Tolerance();
+ TGeoNode *node = gGeoManager->FindNode(pSx+epsil*pV[0], pSy+epsil*pV[1], pSz+epsil*pV[2]);
if (gGeoManager->IsOutside()) {
- newReg = mcgeom->NofVolumes()+1;
-// newLttc = gGeoManager->GetCurrentNodeId();
- newLttc = 999999999;
- if (mcgeom->IsDebugging()) {
- printf("OUTSIDE\n");
- printf(" out: newReg=%i newLttc=%i\n", newReg, newLttc);
- printf("<= LKMGWR\n");
- }
- flagErr = newReg;
+ newReg = gMCGeom->NofVolumes()+2;
+ newLttc = TFlukaMCGeometry::kLttcOutside;
+ gGeoManager->SetOutside(kFALSE);
+ if (oldLttc>0 && oldLttc<newLttc) gGeoManager->CdNode(oldLttc-1);
return;
}
+ gGeoManager->SetOutside(kFALSE);
newReg = node->GetVolume()->GetNumber();
newLttc = gGeoManager->GetCurrentNodeId()+1;
- mcgeom->SetNextRegion(newReg, newLttc);
- flagErr = newReg;
- if (mcgeom->IsDebugging()) {
- printf(" out: newReg=%i newLttc=%i in %s\n", newReg, newLttc, gGeoManager->GetPath());
- printf("<= LKWR\n");
+ if (oldLttc==TFlukaMCGeometry::kLttcOutside || oldLttc==0) return;
+
+ Int_t dummy = gFluka->GetDummyRegion();
+ if (oldReg==dummy) {
+ Int_t newreg1, newlttc1;
+ gMCGeom->GetNextRegion(newreg1, newlttc1);
+ if (newreg1==newReg && newlttc1==newLttc) {
+ newReg = dummy;
+ newLttc = TFlukaMCGeometry::kLttcVirtual;
+ flagErr = newReg;
+ if (gMCGeom->IsDebugging()) printf(" virtual boundary (oldReg==dummy) !! newReg=%i newLttc=%i\n", newReg, newLttc);
+ }
+ return;
+ }
+
+ if (oldReg==newReg && oldLttc!=newLttc) {
+ newReg = dummy;
+ newLttc = TFlukaMCGeometry::kLttcVirtual;
+ if (gMCGeom->IsDebugging()) printf(" virtual boundary!! newReg=%i newLttc=%i\n", newReg, newLttc);
+ }
+
+ if( oldReg!=newReg && oldLttc==newLttc ) {
+ // this should not happen!! ??? Ernesto
+// cout << " lkwr oldReg!=newReg ("<< oldReg <<"!="<< newReg
+// << ") && oldLttc==newLttc ("<< newLttc <<") !!!!!!!!!!!!!!!!!" << endl;
+ newReg = dummy;
+ newLttc = TFlukaMCGeometry::kLttcVirtual;
+ flagErr = newReg;
+ }
+
+ if (gMCGeom->IsDebugging()) {
+ printf(" LKWR: newReg=%i newLttc=%i\n", newReg, newLttc);
}
}
//_____________________________________________________________________________
void nrmlwr(Double_t &pSx, Double_t &pSy, Double_t &pSz,
Double_t &pVx, Double_t &pVy, Double_t &pVz,
- Double_t *norml, const Int_t &oldReg,
- const Int_t &newReg, Int_t &flagErr)
+ Double_t *norml, const Int_t &oldReg,
+ const Int_t &newReg, Int_t &flagErr)
{
- if (mcgeom->IsDebugging()) {
+ if (gMCGeom->IsDebugging()) {
printf("========== Inside NRMLWR (%g, %g, %g, %g, %g, %g)\n", pSx,pSy,pSz,pVx,pVy,pVz);
+ printf(" (%g, %g, %g)\n", NORLAT.xn[0], NORLAT.xn[1], NORLAT.xn[2]);
printf(" oldReg=%i, newReg=%i\n", oldReg,newReg);
}
-// Int_t curreg = (gGeoManager->IsOutside())?(mcgeom->NofVolumes()+1):gGeoManager->GetCurrentVolume()->GetNumber();
-// Int_t curLttc = gGeoManager->GetCurrentNodeId()+1;
-// if (mcgeom->IsDebugging()) printf(" curReg=%i, curLttc=%i in: %s\n", curreg, curLttc, gGeoManager->GetPath());
-// Bool_t regsame = (curreg==oldReg)?kTRUE:kFALSE;
- gGeoManager->SetCurrentPoint(pSx, pSy, pSz);
- gGeoManager->SetCurrentDirection(pVx,pVy,pVz);
-/*
- if (!regsame) {
- if (mcgeom->IsDebugging()) printf(" REGIONS DOEN NOT MATCH\n");
- gGeoManager->FindNode();
- curreg = (gGeoManager->IsOutside())?(mcgeom->NofVolumes()+1):gGeoManager->GetCurrentVolume()->GetNumber();
- curLttc = gGeoManager->GetCurrentNodeId()+1;
- if (mcgeom->IsDebugging()) printf(" re-initialized point: curReg=%i curLttc=%i curPath=%s\n", curreg, curLttc, gGeoManager->GetPath());
- }
-*/
+ gGeoManager->SetCurrentPoint(NORLAT.xn[0], NORLAT.xn[1], NORLAT.xn[2]);
+ gGeoManager->SetCurrentDirection(pVx, pVy, pVz);
Double_t *dnorm = gGeoManager->FindNormalFast();
flagErr = 0;
if (!dnorm) {
norml[0] = -pVx;
norml[1] = -pVy;
norml[2] = -pVz;
- }
- norml[0] = -dnorm[0];
- norml[1] = -dnorm[1];
- norml[2] = -dnorm[2];
- if (mcgeom->IsDebugging()) printf(" normal to boundary: (%g, %g, %g)\n", norml[0], norml[1], norml[2]);
-// curreg = (gGeoManager->IsOutside())?(mcgeom->NofVolumes()+1):gGeoManager->GetCurrentVolume()->GetNumber();
-// curLttc = gGeoManager->GetCurrentNodeId()+1;
- if (mcgeom->IsDebugging()) {
-// printf(" final location: curReg=%i, curLttc=%i in %s\n", curreg,curLttc,gGeoManager->GetPath());
+ } else {
+ norml[0] = -dnorm[0];
+ norml[1] = -dnorm[1];
+ norml[2] = -dnorm[2];
+ }
+
+ if (gMCGeom->IsDebugging()) {
+ printf(" normal to boundary: (%g, %g, %g)\n", norml[0], norml[1], norml[2]);
printf("<= NRMLWR\n");
- }
+ }
+
}
//_____________________________________________________________________________
void rgrpwr(const Int_t & /*flukaReg*/, const Int_t & /*ptrLttc*/, Int_t & /*g4Reg*/,
Int_t * /*indMother*/, Int_t * /*repMother*/, Int_t & /*depthFluka*/)
{
- if (mcgeom->IsDebugging()) printf("=> Dummy RGRPWR\n");
+ if (gMCGeom->IsDebugging()) printf("=> Dummy RGRPWR\n");
}
//_____________________________________________________________________________
// For TGeo, just return the current node ID. No copy need to be made.
- if (mcgeom->IsDebugging()) printf("=> Inside ISVHWR\n");
+ if (gMCGeom->IsDebugging()) printf("=> Inside ISVHWR check=%d intHist=%d\n", check, intHist);
if (check<0) return intHist;
Int_t histInt = gGeoManager->GetCurrentNodeId()+1;
- if (mcgeom->IsDebugging()) printf("<= ISVHWR: history is: %i in: %s\n", histInt, gGeoManager->GetPath());
+ if (gMCGeom->IsDebugging()) printf("<= ISVHWR: history is: %i in: %s\n", histInt, gGeoManager->GetPath());
return histInt;
}