Geant4 Cross Reference

Cross-Referencing   Geant4
Geant4/g3tog4/src/G3Division.cc

Version: [ ReleaseNotes ] [ 1.0 ] [ 1.1 ] [ 2.0 ] [ 3.0 ] [ 3.1 ] [ 3.2 ] [ 4.0 ] [ 4.0.p1 ] [ 4.0.p2 ] [ 4.1 ] [ 4.1.p1 ] [ 5.0 ] [ 5.0.p1 ] [ 5.1 ] [ 5.1.p1 ] [ 5.2 ] [ 5.2.p1 ] [ 5.2.p2 ] [ 6.0 ] [ 6.0.p1 ] [ 6.1 ] [ 6.2 ] [ 6.2.p1 ] [ 6.2.p2 ] [ 7.0 ] [ 7.0.p1 ] [ 7.1 ] [ 7.1.p1 ] [ 8.0 ] [ 8.0.p1 ] [ 8.1 ] [ 8.1.p1 ] [ 8.1.p2 ] [ 8.2 ] [ 8.2.p1 ] [ 8.3 ] [ 8.3.p1 ] [ 8.3.p2 ] [ 9.0 ] [ 9.0.p1 ] [ 9.0.p2 ] [ 9.1 ] [ 9.1.p1 ] [ 9.1.p2 ] [ 9.1.p3 ] [ 9.2 ] [ 9.2.p1 ] [ 9.2.p2 ] [ 9.2.p3 ] [ 9.2.p4 ] [ 9.3 ] [ 9.3.p1 ] [ 9.3.p2 ] [ 9.4 ] [ 9.4.p1 ] [ 9.4.p2 ] [ 9.4.p3 ] [ 9.4.p4 ] [ 9.5 ] [ 9.5.p1 ] [ 9.5.p2 ] [ 9.6 ] [ 9.6.p1 ] [ 9.6.p2 ] [ 9.6.p3 ] [ 9.6.p4 ] [ 10.0 ] [ 10.0.p1 ] [ 10.0.p2 ] [ 10.0.p3 ] [ 10.0.p4 ] [ 10.1 ] [ 10.1.p1 ] [ 10.1.p2 ] [ 10.1.p3 ] [ 10.2 ] [ 10.2.p1 ] [ 10.2.p2 ] [ 10.2.p3 ] [ 10.3 ] [ 10.3.p1 ] [ 10.3.p2 ] [ 10.3.p3 ] [ 10.4 ] [ 10.4.p1 ] [ 10.4.p2 ] [ 10.4.p3 ] [ 10.5 ] [ 10.5.p1 ] [ 10.6 ] [ 10.6.p1 ] [ 10.6.p2 ] [ 10.6.p3 ] [ 10.7 ] [ 10.7.p1 ] [ 10.7.p2 ] [ 10.7.p3 ] [ 10.7.p4 ] [ 11.0 ] [ 11.0.p1 ] [ 11.0.p2 ] [ 11.0.p3, ] [ 11.0.p4 ] [ 11.1 ] [ 11.1.1 ] [ 11.1.2 ] [ 11.1.3 ] [ 11.2 ] [ 11.2.1 ] [ 11.2.2 ] [ 11.3.0 ]

Diff markup

Differences between /g3tog4/src/G3Division.cc (Version 11.3.0) and /g3tog4/src/G3Division.cc (Version 11.2)


  1 //                                                  1 //
  2 // *******************************************      2 // ********************************************************************
  3 // * License and Disclaimer                         3 // * License and Disclaimer                                           *
  4 // *                                                4 // *                                                                  *
  5 // * The  Geant4 software  is  copyright of th      5 // * The  Geant4 software  is  copyright of the Copyright Holders  of *
  6 // * the Geant4 Collaboration.  It is provided      6 // * the Geant4 Collaboration.  It is provided  under  the terms  and *
  7 // * conditions of the Geant4 Software License      7 // * conditions of the Geant4 Software License,  included in the file *
  8 // * LICENSE and available at  http://cern.ch/      8 // * LICENSE and available at  http://cern.ch/geant4/license .  These *
  9 // * include a list of copyright holders.           9 // * include a list of copyright holders.                             *
 10 // *                                               10 // *                                                                  *
 11 // * Neither the authors of this software syst     11 // * Neither the authors of this software system, nor their employing *
 12 // * institutes,nor the agencies providing fin     12 // * institutes,nor the agencies providing financial support for this *
 13 // * work  make  any representation or  warran     13 // * work  make  any representation or  warranty, express or implied, *
 14 // * regarding  this  software system or assum     14 // * regarding  this  software system or assume any liability for its *
 15 // * use.  Please see the license in the file      15 // * use.  Please see the license in the file  LICENSE  and URL above *
 16 // * for the full disclaimer and the limitatio     16 // * for the full disclaimer and the limitation of liability.         *
 17 // *                                               17 // *                                                                  *
 18 // * This  code  implementation is the result      18 // * This  code  implementation is the result of  the  scientific and *
 19 // * technical work of the GEANT4 collaboratio     19 // * technical work of the GEANT4 collaboration.                      *
 20 // * By using,  copying,  modifying or  distri     20 // * By using,  copying,  modifying or  distributing the software (or *
 21 // * any work based  on the software)  you  ag     21 // * any work based  on the software)  you  agree  to acknowledge its *
 22 // * use  in  resulting  scientific  publicati     22 // * use  in  resulting  scientific  publications,  and indicate your *
 23 // * acceptance of all terms of the Geant4 Sof     23 // * acceptance of all terms of the Geant4 Software license.          *
 24 // *******************************************     24 // ********************************************************************
 25 //                                                 25 //
 26 //                                                 26 //
 27 //                                                 27 //
 28 // by I.Hrivnacova, V.Berejnoi 13.10.99            28 // by I.Hrivnacova, V.Berejnoi 13.10.99
 29                                                    29 
 30 #include <assert.h>                                30 #include <assert.h>
 31                                                    31 
 32 #include "G3Division.hh"                           32 #include "G3Division.hh"
 33 #include "G3VolTableEntry.hh"                      33 #include "G3VolTableEntry.hh"
 34 #include "G3toG4MakeSolid.hh"                      34 #include "G3toG4MakeSolid.hh"
 35 #include "G4Para.hh"                               35 #include "G4Para.hh"
 36 #include "G3Pos.hh"                                36 #include "G3Pos.hh"
 37 #include "G4SystemOfUnits.hh"                      37 #include "G4SystemOfUnits.hh"
 38 #include "G4LogicalVolume.hh"                      38 #include "G4LogicalVolume.hh"
 39 #include "G4VPhysicalVolume.hh"                    39 #include "G4VPhysicalVolume.hh"
 40 #include "G4PVPlacement.hh"                        40 #include "G4PVPlacement.hh"
 41 #include "G4PVReplica.hh"                          41 #include "G4PVReplica.hh"
 42 #ifndef G3G4_NO_REFLECTION                         42 #ifndef G3G4_NO_REFLECTION
 43 #include "G4ReflectionFactory.hh"                  43 #include "G4ReflectionFactory.hh"
 44 #endif                                             44 #endif
 45                                                    45 
 46 G3VolTableEntry* G4CreateVTE(G4String vname, G     46 G3VolTableEntry* G4CreateVTE(G4String vname, G4String shape, G4int nmed,
 47                                G4double Rpar[]     47                                G4double Rpar[], G4int npar);
 48                                                    48 
 49 G3Division::G3Division(G3DivType type, G3VolTa     49 G3Division::G3Division(G3DivType type, G3VolTableEntry* vte, 
 50                 G3VolTableEntry* mvte, G4int n     50                 G3VolTableEntry* mvte, G4int nofDivisions, 
 51     G4int iaxis, G4int nmed, G4double c0, G4do     51     G4int iaxis, G4int nmed, G4double c0, G4double step)
 52   : fType(type),                                   52   : fType(type),
 53     fVTE(vte),                                     53     fVTE(vte),
 54     fMVTE(mvte),                                   54     fMVTE(mvte),
 55     fNofDivisions(nofDivisions),                   55     fNofDivisions(nofDivisions),
 56     fIAxis(iaxis),                                 56     fIAxis(iaxis),
 57     fNmed(nmed),                                   57     fNmed(nmed),
 58     fC0(c0),                                       58     fC0(c0),
 59     fStep(step),                                   59     fStep(step),
 60     fLowRange(0.),                                 60     fLowRange(0.),
 61     fHighRange(0.),                                61     fHighRange(0.),
 62     fWidth(0.),                                    62     fWidth(0.),
 63     fOffset(0.),                                   63     fOffset(0.),
 64     fAxis(kXAxis)                                  64     fAxis(kXAxis)
 65 {                                                  65 {
 66   fVTE->SetHasNegPars(true);                       66   fVTE->SetHasNegPars(true);
 67 }                                                  67 }
 68                                                    68 
 69 G3Division::G3Division(G3VolTableEntry* vte, G     69 G3Division::G3Division(G3VolTableEntry* vte, G3VolTableEntry* mvte,
 70                        const G3Division& divis     70                        const G3Division& division)
 71   : fVTE(vte),                                     71   : fVTE(vte),
 72     fMVTE(mvte)                                    72     fMVTE(mvte)
 73 {                                                  73 {
 74   // only "input" parameters are copied from d     74   // only "input" parameters are copied from division
 75   fType = division.fType;                          75   fType = division.fType;
 76   fNofDivisions = division.fNofDivisions;          76   fNofDivisions = division.fNofDivisions;
 77   fIAxis = division.fIAxis;                        77   fIAxis = division.fIAxis;
 78   fNmed = division.fNmed;                          78   fNmed = division.fNmed;
 79   fC0 = division.fC0;                              79   fC0 = division.fC0;
 80   fStep = division.fStep;                          80   fStep = division.fStep;
 81                                                    81 
 82   // other parameters are set as in standard c     82   // other parameters are set as in standard constructor
 83   fLowRange = 0.;                                  83   fLowRange = 0.;
 84   fHighRange = 0.;                                 84   fHighRange = 0.;
 85   fWidth = 0.;                                     85   fWidth = 0.;
 86   fOffset = 0.;                                    86   fOffset = 0.;
 87   fAxis = kXAxis;                                  87   fAxis = kXAxis;
 88   fVTE->SetHasNegPars(true);                       88   fVTE->SetHasNegPars(true);
 89 }                                                  89 }
 90                                                    90 
 91 G3Division::~G3Division()                          91 G3Division::~G3Division()
 92 {}                                                 92 {}
 93                                                    93 
 94 // public methods                                  94 // public methods
 95                                                    95 
 96 void G3Division::UpdateVTE()                       96 void G3Division::UpdateVTE()
 97 {                                                  97 {
 98   if (fVTE->HasNegPars() && !(fMVTE->HasNegPar     98   if (fVTE->HasNegPars() && !(fMVTE->HasNegPars())) {
 99                                                    99 
100     // set nmed from mother                       100     // set nmed from mother 
101     if (fNmed == 0) fNmed = fMVTE->GetNmed();     101     if (fNmed == 0) fNmed = fMVTE->GetNmed();
102     fVTE->SetNmed(fNmed);                         102     fVTE->SetNmed(fNmed);
103                                                   103    
104     SetRangeAndAxis();                            104     SetRangeAndAxis();
105                                                   105     
106     // create envelope (if necessary)             106     // create envelope (if necessary)
107     // and solid                                  107     // and solid    
108     G3VolTableEntry* envVTE = 0;                  108     G3VolTableEntry* envVTE = 0;
109     if      (fType == kDvn)  envVTE = Dvn();      109     if      (fType == kDvn)  envVTE = Dvn(); 
110     else if (fType == kDvn2) envVTE = Dvn2();     110     else if (fType == kDvn2) envVTE = Dvn2(); 
111     else if (fType == kDvt)  envVTE = Dvt();      111     else if (fType == kDvt)  envVTE = Dvt(); 
112     else if (fType == kDvt2) envVTE = Dvt2();     112     else if (fType == kDvt2) envVTE = Dvt2();
113                                                   113     
114     if (envVTE) {                                 114     if (envVTE) {
115       // reset mother <-> daughter                115       // reset mother <-> daughter
116       fMVTE->ReplaceDaughter(fVTE, envVTE);       116       fMVTE->ReplaceDaughter(fVTE, envVTE);
117       fVTE->ReplaceMother(fMVTE, envVTE);         117       fVTE->ReplaceMother(fMVTE, envVTE);
118       envVTE->AddDaughter(fVTE);                  118       envVTE->AddDaughter(fVTE);
119       envVTE->AddMother(fMVTE);                   119       envVTE->AddMother(fMVTE);
120                                                   120 
121       // replace mother with envelope             121       // replace mother with envelope
122       fMVTE = envVTE;                             122       fMVTE = envVTE;
123     }                                             123     }
124   }                                               124   }  
125 }                                                 125 }
126                                                   126 
127 void G3Division::CreatePVReplica()                127 void G3Division::CreatePVReplica()
128 {                                                 128 {
129   G4String name = fVTE->GetName();                129   G4String name = fVTE->GetName();
130   G4LogicalVolume* lv =  fVTE->GetLV();           130   G4LogicalVolume* lv =  fVTE->GetLV();
131   G4LogicalVolume* mlv = fMVTE->GetLV();          131   G4LogicalVolume* mlv = fMVTE->GetLV();
132                                                   132   
133   G4String shape = fMVTE->GetShape();             133   G4String shape = fMVTE->GetShape();
134   if (shape == "PARA") {                          134   if (shape == "PARA") {
135     // The para volume cannot be replicated us    135     // The para volume cannot be replicated using G4PVReplica.
136     // (Replicating a volume along a cartesian    136     // (Replicating a volume along a cartesian axis means "slicing" it
137     // with slices -perpendicular- to that axi    137     // with slices -perpendicular- to that axis.)
138                                                   138     
139     // position the replicated elements           139     // position the replicated elements    
140     for (G4int i=0; i<fNofDivisions; i++) {       140     for (G4int i=0; i<fNofDivisions; i++) {
141        G4ThreeVector position = G4ThreeVector(    141        G4ThreeVector position = G4ThreeVector(); 
142        position[fIAxis-1] = fLowRange + fWidth    142        position[fIAxis-1] = fLowRange + fWidth/2. + i*fWidth;
143        if (position.y()!=0.)                      143        if (position.y()!=0.) 
144          position.setX(position.y()*((G4Para*)    144          position.setX(position.y()*((G4Para*)lv->GetSolid())->GetTanAlpha());
145                                                   145 
146        #ifndef G3G4_NO_REFLECTION                 146        #ifndef G3G4_NO_REFLECTION
147        G4ReflectionFactory::Instance()            147        G4ReflectionFactory::Instance()
148          ->Place(G4Translate3D(position), name    148          ->Place(G4Translate3D(position), name, lv, mlv, 0, i);
149                                                   149 
150        #else                                      150        #else  
151        new G4PVPlacement(0, position, lv, name    151        new G4PVPlacement(0, position, lv, name, mlv, 0, i);
152                                                   152 
153        #endif                                     153        #endif
154     }                                             154     }
155                                                   155     
156     // G4PVReplica cannot be created              156     // G4PVReplica cannot be created
157     return;                                       157     return;   
158   }                                               158   }     
159                                                   159   
160   #ifdef G3G4DEBUG                                160   #ifdef G3G4DEBUG
161     G4cout << "Create G4PVReplica name " << na    161     G4cout << "Create G4PVReplica name " << name << " logical volume name " 
162      << lv->GetName() << " mother logical volm    162      << lv->GetName() << " mother logical volme name "
163      << mlv->GetName() << " axis " << fAxis <<    163      << mlv->GetName() << " axis " << fAxis << " ndivisions " 
164      << fNofDivisions << " width " << fWidth <    164      << fNofDivisions << " width " << fWidth << " Offset "
165      << fOffset << G4endl;                        165      << fOffset << G4endl;
166   #endif                                          166   #endif
167                                                   167 
168   #ifndef G3G4_NO_REFLECTION                      168   #ifndef G3G4_NO_REFLECTION
169   G4ReflectionFactory::Instance()                 169   G4ReflectionFactory::Instance()
170     ->Replicate(name, lv, mlv, fAxis, fNofDivi    170     ->Replicate(name, lv, mlv, fAxis, fNofDivisions, fWidth, fOffset);
171                                                   171 
172   #else                                           172   #else    
173   new G4PVReplica(name, lv, mlv, fAxis, fNofDi    173   new G4PVReplica(name, lv, mlv, fAxis, fNofDivisions, fWidth, fOffset);
174                                                   174 
175   #endif                                          175   #endif
176 }                                                 176 }
177                                                   177 
178 // private methods                                178 // private methods
179                                                   179 
180 void G3Division::Exception(G4String where, G4S    180 void G3Division::Exception(G4String where, G4String what)
181 {                                                 181 {
182   G4String err_message = "G3Division::" + wher    182   G4String err_message = "G3Division::" + where + " for "
183                        + what + " is not imple    183                        + what + " is not implemented";
184   G4Exception("G3Division::Exception()", "G3to    184   G4Exception("G3Division::Exception()", "G3toG40004",
185               FatalException, err_message);       185               FatalException, err_message);
186   return;                                         186   return;
187 }                                                 187 }  
188                                                   188 
189 void G3Division::SetRangeAndAxis()                189 void G3Division::SetRangeAndAxis()
190 // set fHighRange, fLowRange, fAxis               190 // set fHighRange, fLowRange, fAxis
191 {                                                 191 {
192     G4String shape = fMVTE->GetShape();           192     G4String shape = fMVTE->GetShape();
193     G4double *Rpar = fMVTE->GetRpar();            193     G4double *Rpar = fMVTE->GetRpar();
194                                                   194     
195     switch (fIAxis) {                             195     switch (fIAxis) {
196       case 1: fAxis = kXAxis;                     196       case 1: fAxis = kXAxis;
197               break;                              197               break;
198       case 2: fAxis = kYAxis;                     198       case 2: fAxis = kYAxis;
199               break;                              199               break;
200       case 3: fAxis = kZAxis;                     200       case 3: fAxis = kZAxis;
201               break;                              201               break;
202       default: G4Exception("G3Division::SetRan    202       default: G4Exception("G3Division::SetRangeAndAxis()", "G3toG40005",
203                             FatalException, "W    203                             FatalException, "Wrong axis index definition!");
204     }                                             204     }
205                                                   205 
206     if ( shape == "BOX" ) {                       206     if ( shape == "BOX" ) {
207       fHighRange = Rpar[fIAxis-1]*cm;             207       fHighRange = Rpar[fIAxis-1]*cm;
208       fLowRange = -fHighRange;                    208       fLowRange = -fHighRange;
209     }                                             209     }
210     else if ( shape == "TRD1" ) {                 210     else if ( shape == "TRD1" ) {
211       if (fIAxis == 1){                           211       if (fIAxis == 1){
212         fHighRange = std::max(Rpar[0]*cm, Rpar    212         fHighRange = std::max(Rpar[0]*cm, Rpar[1]*cm);
213       }                                           213       }
214       else if( fIAxis == 2) {                     214       else if( fIAxis == 2) {
215        fHighRange = Rpar[2]*cm;                   215        fHighRange = Rpar[2]*cm;
216       }                                           216       }
217       else if( fIAxis == 3) {                     217       else if( fIAxis == 3) {
218        fHighRange = Rpar[3]*cm;                   218        fHighRange = Rpar[3]*cm;
219       }                                           219       }
220       fLowRange = - fHighRange;                   220       fLowRange = - fHighRange;
221     }                                             221     }
222     else if ( shape == "TRD2" ) {                 222     else if ( shape == "TRD2" ) {
223       if (fIAxis == 1){                           223       if (fIAxis == 1){
224         fHighRange = std::max(Rpar[0]*cm, Rpar    224         fHighRange = std::max(Rpar[0]*cm, Rpar[1]*cm);
225       }                                           225       }
226       else if( fIAxis == 2) {                     226       else if( fIAxis == 2) {
227         fHighRange = std::max(Rpar[2]*cm, Rpar    227         fHighRange = std::max(Rpar[2]*cm, Rpar[3]*cm);
228       }                                           228       }
229       else if( fIAxis == 3) {                     229       else if( fIAxis == 3) {
230        fHighRange = Rpar[4]*cm;                   230        fHighRange = Rpar[4]*cm;
231       }                                           231       }
232     }                                             232     }
233     else if ( shape == "TRAP" ) {                 233     else if ( shape == "TRAP" ) {
234       if ( fIAxis == 3 ) fHighRange = Rpar[0]*    234       if ( fIAxis == 3 ) fHighRange = Rpar[0]*cm;
235       else               fHighRange = 0.;         235       else               fHighRange = 0.;
236       fLowRange = -fHighRange;                    236       fLowRange = -fHighRange;
237     }                                             237     }
238     else if ( shape == "TUBE" ) {                 238     else if ( shape == "TUBE" ) {
239       if (fIAxis == 1){                           239       if (fIAxis == 1){
240         fHighRange = Rpar[1]*cm;                  240         fHighRange = Rpar[1]*cm;
241         fLowRange = Rpar[0]*cm;                   241         fLowRange = Rpar[0]*cm;
242         fAxis = kRho;                             242         fAxis = kRho;
243       }                                           243       }
244       else if( fIAxis == 2) {                     244       else if( fIAxis == 2) {
245         fHighRange = 360.*deg;                    245         fHighRange = 360.*deg;
246         fLowRange = 0.;                           246         fLowRange = 0.;
247         fAxis = kPhi;                             247         fAxis = kPhi;
248       }                                           248       }
249       else if( fIAxis == 3) {                     249       else if( fIAxis == 3) {
250        fHighRange = Rpar[2]*cm;                   250        fHighRange = Rpar[2]*cm;
251        fLowRange = -fHighRange;                   251        fLowRange = -fHighRange;
252       }                                           252       }
253     }                                             253     }
254     else if ( shape == "TUBS" ) {                 254     else if ( shape == "TUBS" ) {
255       if (fIAxis == 1){                           255       if (fIAxis == 1){
256         fHighRange = Rpar[1]*cm;                  256         fHighRange = Rpar[1]*cm;
257         fLowRange = Rpar[0]*cm;                   257         fLowRange = Rpar[0]*cm;
258         fAxis = kRho;                             258         fAxis = kRho;
259       }                                           259       }
260       else if( fIAxis == 2) {                     260       else if( fIAxis == 2) {
261                                                   261 
262        fLowRange = Rpar[3]*deg;                   262        fLowRange = Rpar[3]*deg;
263        fHighRange = Rpar[4]*deg - fLowRange;      263        fHighRange = Rpar[4]*deg - fLowRange;
264        if ( Rpar[4]*deg <= fLowRange )fHighRan    264        if ( Rpar[4]*deg <= fLowRange )fHighRange = fHighRange + 360.*deg;
265        fHighRange = fHighRange + fLowRange;       265        fHighRange = fHighRange + fLowRange;
266        fAxis = kPhi;                              266        fAxis = kPhi;
267       }                                           267       }
268       else if( fIAxis == 3) {                     268       else if( fIAxis == 3) {
269        fHighRange = Rpar[2]*cm;                   269        fHighRange = Rpar[2]*cm;
270        fLowRange = -fHighRange;                   270        fLowRange = -fHighRange;
271       }                                           271       }
272     }                                             272     }
273     else if ( shape == "CONE" ) {                 273     else if ( shape == "CONE" ) {
274       if (fIAxis == 1){                           274       if (fIAxis == 1){
275         fHighRange = std::max(Rpar[2]*cm,Rpar[    275         fHighRange = std::max(Rpar[2]*cm,Rpar[4]*cm);
276         fLowRange = std::max(Rpar[1]*cm,Rpar[3    276         fLowRange = std::max(Rpar[1]*cm,Rpar[3]*cm);
277         fAxis = kRho;                             277         fAxis = kRho;
278       }                                           278       }
279       else if( fIAxis == 2) {                     279       else if( fIAxis == 2) {
280                                                   280 
281        fLowRange = 0.;                            281        fLowRange = 0.;
282        fHighRange = 360.*deg;                     282        fHighRange = 360.*deg;
283        fAxis = kPhi;                              283        fAxis = kPhi;
284       }                                           284       }
285       else if( fIAxis == 3) {                     285       else if( fIAxis == 3) {
286        fHighRange = Rpar[0]*cm;                   286        fHighRange = Rpar[0]*cm;
287        fLowRange = -fHighRange;                   287        fLowRange = -fHighRange;
288       }                                           288       }
289     }                                             289     }
290     else if ( shape == "CONS" ) {                 290     else if ( shape == "CONS" ) {
291       if (fIAxis == 1){                           291       if (fIAxis == 1){
292         fHighRange = std::max(Rpar[2]*cm,Rpar[    292         fHighRange = std::max(Rpar[2]*cm,Rpar[4]*cm);
293         fLowRange = std::max(Rpar[1]*cm,Rpar[3    293         fLowRange = std::max(Rpar[1]*cm,Rpar[3]*cm);
294         fAxis = kRho;                             294         fAxis = kRho;
295       }                                           295       }
296       else if( fIAxis == 2) {                     296       else if( fIAxis == 2) {
297                                                   297 
298        fLowRange = Rpar[5]*deg;                   298        fLowRange = Rpar[5]*deg;
299        fHighRange = Rpar[6]*deg - fLowRange;      299        fHighRange = Rpar[6]*deg - fLowRange;
300        if ( Rpar[6]*deg <= fLowRange )fHighRan    300        if ( Rpar[6]*deg <= fLowRange )fHighRange = fHighRange + 360.*deg;
301        fHighRange = fHighRange + fLowRange;       301        fHighRange = fHighRange + fLowRange;
302        fAxis = kPhi;                              302        fAxis = kPhi;
303       }                                           303       }
304       else if( fIAxis == 3) {                     304       else if( fIAxis == 3) {
305        fHighRange = Rpar[2]*cm;                   305        fHighRange = Rpar[2]*cm;
306        fLowRange = -fHighRange;                   306        fLowRange = -fHighRange;
307       }                                           307       }
308     }                                             308     }
309     else if ( shape == "SPHE" ) {                 309     else if ( shape == "SPHE" ) {
310       if (fIAxis == 1){                           310       if (fIAxis == 1){
311         fHighRange = Rpar[1]*cm;                  311         fHighRange = Rpar[1]*cm;
312         fLowRange = Rpar[0]*cm;                   312         fLowRange = Rpar[0]*cm;
313         fAxis = kRho;                             313         fAxis = kRho;
314       }                                           314       }
315       else if( fIAxis == 2) {                     315       else if( fIAxis == 2) {
316        fLowRange = std::min(Rpar[2]*deg,Rpar[3    316        fLowRange = std::min(Rpar[2]*deg,Rpar[3]*deg);
317        fHighRange = std::max(Rpar[2]*deg,Rpar[    317        fHighRange = std::max(Rpar[2]*deg,Rpar[3]*deg);
318        fAxis = kPhi;                              318        fAxis = kPhi;
319       }                                           319       }
320       else if( fIAxis == 3) {                     320       else if( fIAxis == 3) {
321        fLowRange = std::min(Rpar[4]*deg,Rpar[5    321        fLowRange = std::min(Rpar[4]*deg,Rpar[5]*deg);
322        fHighRange = std::max(Rpar[4]*deg,Rpar[    322        fHighRange = std::max(Rpar[4]*deg,Rpar[5]*deg);
323        fAxis = kPhi; // ??????                    323        fAxis = kPhi; // ?????? 
324       }                                           324       }
325     }                                             325     }
326     else if ( shape == "PARA" ) {                 326     else if ( shape == "PARA" ) {
327       fHighRange = Rpar[fIAxis-1]*cm;             327       fHighRange = Rpar[fIAxis-1]*cm;
328       fLowRange = -fHighRange;                    328       fLowRange = -fHighRange;
329     }                                             329     }
330     else if ( shape == "PGON" ) {                 330     else if ( shape == "PGON" ) {
331         G4int i;                                  331         G4int i;
332         G4int nz = G4int(Rpar[3]);                332         G4int nz = G4int(Rpar[3]);
333                                                   333 
334         G4double pPhi1 = Rpar[0]*deg;             334         G4double pPhi1 = Rpar[0]*deg;
335         G4double dPhi  = Rpar[1]*deg;             335         G4double dPhi  = Rpar[1]*deg;
336                                                   336     
337         G4double *DzArray = new G4double[nz];     337         G4double *DzArray = new G4double[nz];
338         G4double *Rmax    = new G4double[nz];     338         G4double *Rmax    = new G4double[nz];
339         G4double *Rmin    = new G4double[nz];     339         G4double *Rmin    = new G4double[nz];
340         G4double rangehi[3], rangelo[3];          340         G4double rangehi[3], rangelo[3];
341         rangehi[0] = -kInfinity  ;                341         rangehi[0] = -kInfinity  ;
342         rangelo[0] =  kInfinity ;                 342         rangelo[0] =  kInfinity ;
343         rangehi[2] = -kInfinity ;                 343         rangehi[2] = -kInfinity ;
344         rangelo[2] =  kInfinity ;                 344         rangelo[2] =  kInfinity ;
345                                                   345 
346         for(i=0; i<nz; i++)                       346         for(i=0; i<nz; i++) 
347         {                                         347         {
348             G4int i4=3*i+4;                       348             G4int i4=3*i+4;
349             G4int i5=i4+1;                        349             G4int i5=i4+1;
350             G4int i6=i4+2;                        350             G4int i6=i4+2;
351                                                   351             
352             DzArray[i] = Rpar[i4]*cm;             352             DzArray[i] = Rpar[i4]*cm;
353             Rmin[i] = Rpar[i5]*cm;                353             Rmin[i] = Rpar[i5]*cm;
354             Rmax[i] = Rpar[i6]*cm;                354             Rmax[i] = Rpar[i6]*cm;
355             rangelo[0] = std::min(rangelo[0],     355             rangelo[0] = std::min(rangelo[0], Rmin[i]);
356             rangehi[0] = std::max(rangehi[0],     356             rangehi[0] = std::max(rangehi[0], Rmax[i]);
357             rangelo[2] = std::min(rangelo[2],     357             rangelo[2] = std::min(rangelo[2], DzArray[i]);
358             rangehi[2] = std::max(rangehi[2],     358             rangehi[2] = std::max(rangehi[2], DzArray[i]);
359         }                                         359         }
360         for (i=0;i<nz;i++){                       360         for (i=0;i<nz;i++){
361             assert(Rmin[i]>=0 && Rmax[i]>=Rmin    361             assert(Rmin[i]>=0 && Rmax[i]>=Rmin[i]);
362         }                                         362         }
363         rangehi[1] = pPhi1 + dPhi;                363         rangehi[1] = pPhi1 + dPhi;
364         rangelo[1] = pPhi1;                       364         rangelo[1] = pPhi1;
365         fHighRange = rangehi[fIAxis-1];           365         fHighRange = rangehi[fIAxis-1];
366         fLowRange = rangelo[fIAxis-1];            366         fLowRange = rangelo[fIAxis-1];
367         if      (fIAxis == 1)fAxis = kRho;        367         if      (fIAxis == 1)fAxis = kRho;
368         else if (fIAxis == 2)fAxis = kPhi;        368         else if (fIAxis == 2)fAxis = kPhi;
369         else if (fIAxis == 3)fAxis = kZAxis;      369         else if (fIAxis == 3)fAxis = kZAxis;
370                                                   370 
371         delete [] DzArray;                        371         delete [] DzArray;
372         delete [] Rmin;                           372         delete [] Rmin;
373         delete [] Rmax;                           373         delete [] Rmax;
374                                                   374 
375     }                                             375     }
376     else if ( shape == "PCON" ) {                 376     else if ( shape == "PCON" ) {
377                                                   377 
378         G4int i;                                  378         G4int i;
379         G4double pPhi1 = Rpar[0]*deg;             379         G4double pPhi1 = Rpar[0]*deg;
380         G4double dPhi  = Rpar[1]*deg;             380         G4double dPhi  = Rpar[1]*deg;    
381         G4int nz = G4int(Rpar[2]);                381         G4int nz = G4int(Rpar[2]);
382                                                   382     
383         G4double *DzArray = new G4double[nz];     383         G4double *DzArray = new G4double[nz];
384         G4double *Rmax    = new G4double[nz];     384         G4double *Rmax    = new G4double[nz];
385         G4double *Rmin    = new G4double[nz];     385         G4double *Rmin    = new G4double[nz];
386         G4double rangehi[3],rangelo[3];           386         G4double rangehi[3],rangelo[3];
387                                                   387 
388         rangehi[0] = -kInfinity  ;                388         rangehi[0] = -kInfinity  ;
389         rangelo[0] =  kInfinity ;                 389         rangelo[0] =  kInfinity ;
390         rangehi[2] = -kInfinity ;                 390         rangehi[2] = -kInfinity ;
391         rangelo[2] =  kInfinity ;                 391         rangelo[2] =  kInfinity ;
392                                                   392         
393         for(i=0; i<nz; i++){                      393         for(i=0; i<nz; i++){
394             G4int i4=3*i+3;                       394             G4int i4=3*i+3;
395             G4int i5=i4+1;                        395             G4int i5=i4+1;
396             G4int i6=i4+2;                        396             G4int i6=i4+2;
397                                                   397             
398             DzArray[i] = Rpar[i4]*cm;             398             DzArray[i] = Rpar[i4]*cm;
399             Rmin[i] = Rpar[i5]*cm;                399             Rmin[i] = Rpar[i5]*cm;
400             Rmax[i] = Rpar[i6]*cm;                400             Rmax[i] = Rpar[i6]*cm;
401             rangelo[0] = std::min(rangelo[0],     401             rangelo[0] = std::min(rangelo[0], Rmin[i]);
402             rangehi[0] = std::max(rangehi[0],     402             rangehi[0] = std::max(rangehi[0], Rmax[i]);
403             rangelo[2] = std::min(rangelo[2],     403             rangelo[2] = std::min(rangelo[2], DzArray[i]);
404             rangehi[2] = std::max(rangehi[2],     404             rangehi[2] = std::max(rangehi[2], DzArray[i]);
405         }                                         405         }
406         for (i=0;i<nz;i++){                       406         for (i=0;i<nz;i++){
407             assert(Rmin[i]>=0 && Rmax[i]>=Rmin    407             assert(Rmin[i]>=0 && Rmax[i]>=Rmin[i]);
408         }                                         408         }
409         rangehi[1] = pPhi1 + dPhi;                409         rangehi[1] = pPhi1 + dPhi;
410         rangelo[1] = pPhi1;                       410         rangelo[1] = pPhi1;
411         fHighRange = rangehi[fIAxis-1];           411         fHighRange = rangehi[fIAxis-1];
412         fLowRange = rangelo[fIAxis-1];            412         fLowRange = rangelo[fIAxis-1];
413         if      (fIAxis == 1)fAxis = kRho;        413         if      (fIAxis == 1)fAxis = kRho;
414         else if (fIAxis == 2)fAxis = kPhi;        414         else if (fIAxis == 2)fAxis = kPhi;
415         else if (fIAxis == 3)fAxis = kZAxis;      415         else if (fIAxis == 3)fAxis = kZAxis;
416                                                   416 
417                                                   417 
418         delete [] DzArray;                        418         delete [] DzArray;
419         delete [] Rmin;                           419         delete [] Rmin;
420         delete [] Rmax;                           420         delete [] Rmax;
421     }                                             421     }
422     else if ( shape == "ELTU" ||  shape == "HY    422     else if ( shape == "ELTU" ||  shape == "HYPE" || shape == "GTRA" ||
423          shape == "CTUB") {                       423          shape == "CTUB") {
424        Exception("SetRangeAndAxis", shape);       424        Exception("SetRangeAndAxis", shape);
425     }                                             425     }
426     else {                                        426     else {
427        Exception("SetRangeAndAxis", "Unknown s    427        Exception("SetRangeAndAxis", "Unknown shape" + shape);
428     }                                             428     }  
429                                                   429 
430     // verbose                                    430     // verbose
431     #ifdef G3G4DEBUG                              431     #ifdef G3G4DEBUG
432       G4cout << "Shape " << shape << " SetRang    432       G4cout << "Shape " << shape << " SetRangeAndAxis: " 
433        << fLowRange << " " << fHighRange << "     433        << fLowRange << " " << fHighRange << " " << fAxis << G4endl;
434     #endif                                        434     #endif
435 }                                                 435 }
436                                                   436 
437 G3VolTableEntry* G3Division::CreateEnvelope(G4    437 G3VolTableEntry* G3Division::CreateEnvelope(G4String shape, G4double hi, 
438                                G4double lo, G4    438                                G4double lo, G4double par[], G4int npar)
439 // create new VTE with G3Pos corresponding to     439 // create new VTE with G3Pos corresponding to the
440 // envelope of divided volume                     440 // envelope of divided volume
441 {                                                 441 {
442     // verbose                                    442     // verbose
443     // G4cout << "  G3Division::CreateEnvelope    443     // G4cout << "  G3Division::CreateEnvelope " << "fIAaxis= " << fIAxis
444     //        << " hi= " << hi                    444     //        << " hi= " << hi
445     //        << " lo= " << lo                    445     //        << " lo= " << lo
446     //        << G4endl;                          446     //        << G4endl;
447                                                   447 
448     G4double *Rpar = new G4double[npar+2];        448     G4double *Rpar = new G4double[npar+2];
449     for (G4int i=0; i<npar; ++i){ Rpar[i] = pa    449     for (G4int i=0; i<npar; ++i){ Rpar[i] = par[i];}
450     G4double pos[3] = {0.,0.,0.};                 450     G4double pos[3] = {0.,0.,0.};
451                                                   451   
452     if ( shape == "BOX" ) {                       452     if ( shape == "BOX" ) {
453       Rpar[fIAxis-1] = (hi - lo)/2./cm;           453       Rpar[fIAxis-1] = (hi - lo)/2./cm;
454       pos [fIAxis-1] = (hi + lo)/2.;              454       pos [fIAxis-1] = (hi + lo)/2.;
455     }                                             455     }
456     else if ( shape == "TRD1" ) {                 456     else if ( shape == "TRD1" ) {
457       if ( fIAxis == 1 || fIAxis == 2  ) {        457       if ( fIAxis == 1 || fIAxis == 2  ) {
458         Exception("CreateEnvelope","TRD1-x,y")    458         Exception("CreateEnvelope","TRD1-x,y");
459       }                                           459       }
460       else if ( fIAxis == 3 ) {                   460       else if ( fIAxis == 3 ) {
461   // x = x1 + (c-z1)(x2 -x1)/(z2-z1)              461   // x = x1 + (c-z1)(x2 -x1)/(z2-z1)
462   G4double tn, x1, z1;                            462   G4double tn, x1, z1;
463         tn = (Rpar[1] - Rpar[0])/(2.* Rpar[3])    463         tn = (Rpar[1] - Rpar[0])/(2.* Rpar[3]); 
464         x1 = Rpar[0]; z1 = -Rpar[3];              464         x1 = Rpar[0]; z1 = -Rpar[3];
465         Rpar[0] = x1 + tn * (lo/cm - z1);         465         Rpar[0] = x1 + tn * (lo/cm - z1);
466         Rpar[1] = x1 + tn * (hi/cm - z1);         466         Rpar[1] = x1 + tn * (hi/cm - z1);
467         Rpar[3] = (hi - lo)/2./cm;                467         Rpar[3] = (hi - lo)/2./cm;
468         pos[2]  = (hi + lo)/2.;                   468         pos[2]  = (hi + lo)/2.;
469       }                                           469       }
470     }                                             470     }
471     else if ( shape == "TRD2" ) {                 471     else if ( shape == "TRD2" ) {
472       if ( fIAxis == 1 || fIAxis == 2) {          472       if ( fIAxis == 1 || fIAxis == 2) {
473         Exception("CreateEnvelope","TRD2-x,y")    473         Exception("CreateEnvelope","TRD2-x,y");
474       }                                           474       }
475       else if ( fIAxis == 3 ) {                   475       else if ( fIAxis == 3 ) {
476   // x = x1 + (c-z1)(x2 -x1)/(z2-z1)              476   // x = x1 + (c-z1)(x2 -x1)/(z2-z1)
477   // y = y1 + (c-z1)(y2 -y1)/(z2-z1)              477   // y = y1 + (c-z1)(y2 -y1)/(z2-z1)
478   G4double tn1, tn2, x1, y1, z1;                  478   G4double tn1, tn2, x1, y1, z1;
479         tn1 = (Rpar[1] - Rpar[0])/(2.* Rpar[4]    479         tn1 = (Rpar[1] - Rpar[0])/(2.* Rpar[4]); 
480         tn2 = (Rpar[3] - Rpar[2])/(2.* Rpar[4]    480         tn2 = (Rpar[3] - Rpar[2])/(2.* Rpar[4]); 
481         x1 = Rpar[0]; y1 = Rpar[2]; z1 = -Rpar    481         x1 = Rpar[0]; y1 = Rpar[2]; z1 = -Rpar[3];
482         Rpar[0] = x1 + tn1 * (lo/cm - z1);        482         Rpar[0] = x1 + tn1 * (lo/cm - z1);
483         Rpar[1] = x1 + tn1 * (hi/cm - z1);        483         Rpar[1] = x1 + tn1 * (hi/cm - z1);
484         Rpar[2] = y1 + tn2 * (lo/cm - z1);        484         Rpar[2] = y1 + tn2 * (lo/cm - z1);
485         Rpar[3] = y1 + tn2 * (hi/cm - z1);        485         Rpar[3] = y1 + tn2 * (hi/cm - z1);
486         Rpar[4] = (hi - lo)/2./cm;                486         Rpar[4] = (hi - lo)/2./cm;
487         pos[2]  = (hi + lo)/2.;                   487         pos[2]  = (hi + lo)/2.;
488       }                                           488       }
489     }                                             489     }
490     else if ( shape == "TRAP" ) {                 490     else if ( shape == "TRAP" ) {
491       Exception("CreateEnvelope","TRAP-x,y,z")    491       Exception("CreateEnvelope","TRAP-x,y,z");
492     }                                             492     }
493     else if ( shape == "TUBE" ) {                 493     else if ( shape == "TUBE" ) {
494       if ( fIAxis == 1 ) {                        494       if ( fIAxis == 1 ) {
495         Rpar[0] = lo/cm;                          495         Rpar[0] = lo/cm;
496         Rpar[1] = hi/cm;                          496         Rpar[1] = hi/cm;
497       }                                           497       }
498       else if ( fIAxis == 2 ) {                   498       else if ( fIAxis == 2 ) {
499         Rpar[3] = lo/deg;                         499         Rpar[3] = lo/deg;
500         Rpar[4] = hi/deg;                         500         Rpar[4] = hi/deg;
501         npar = npar + 2;                          501         npar = npar + 2;
502         shape = "TUBS";                           502         shape = "TUBS";
503       }                                           503       }
504       else if ( fIAxis == 3 ) {                   504       else if ( fIAxis == 3 ) {
505         Rpar[2] = (hi - lo)/2./cm;                505         Rpar[2] = (hi - lo)/2./cm;
506         pos [2] = (hi + lo)/2.;                   506         pos [2] = (hi + lo)/2.;
507       }                                           507       }
508     }                                             508     }
509     else if ( shape == "TUBS" ) {                 509     else if ( shape == "TUBS" ) {
510       if ( fIAxis == 1 ) {                        510       if ( fIAxis == 1 ) {
511         Rpar[0] = lo/cm;                          511         Rpar[0] = lo/cm;
512         Rpar[1] = hi/cm;                          512         Rpar[1] = hi/cm;
513       }                                           513       }
514       else if ( fIAxis == 2 ) {                   514       else if ( fIAxis == 2 ) {
515         Rpar[3] = lo/deg;                         515         Rpar[3] = lo/deg;
516         Rpar[4] = hi/deg;                         516         Rpar[4] = hi/deg;
517       }                                           517       }
518       else if ( fIAxis == 3 ) {                   518       else if ( fIAxis == 3 ) {
519         Rpar[2] = (hi - lo)/2./cm;                519         Rpar[2] = (hi - lo)/2./cm;
520         pos [2] = (hi + lo)/2.;                   520         pos [2] = (hi + lo)/2.;
521       }                                           521       }
522     }                                             522     }
523     else if ( shape == "CONE" ) {                 523     else if ( shape == "CONE" ) {
524       if ( fIAxis == 1) {                         524       if ( fIAxis == 1) {
525         Exception("CreateEnvelope","CONE-x,z")    525         Exception("CreateEnvelope","CONE-x,z");
526       }                                           526       }
527       else if ( fIAxis == 2 ) {                   527       else if ( fIAxis == 2 ) {
528         Rpar[5] = lo/deg;                         528         Rpar[5] = lo/deg;
529         Rpar[6] = hi/deg;                         529         Rpar[6] = hi/deg;
530         npar = npar + 2;                          530         npar = npar + 2;
531         shape = "CONS";                           531         shape = "CONS";
532       }                                           532       }
533       else if ( fIAxis == 3 ) {                   533       else if ( fIAxis == 3 ) {
534         G4double tn1, tn2, rmin, rmax, z1;        534         G4double tn1, tn2, rmin, rmax, z1;
535         tn1 = (Rpar[3] - Rpar[1])/(2.* Rpar[0]    535         tn1 = (Rpar[3] - Rpar[1])/(2.* Rpar[0]); 
536         tn2 = (Rpar[4] - Rpar[2])/(2.* Rpar[0]    536         tn2 = (Rpar[4] - Rpar[2])/(2.* Rpar[0]); 
537         rmin = Rpar[1]; rmax = Rpar[2]; z1 = -    537         rmin = Rpar[1]; rmax = Rpar[2]; z1 = -Rpar[0];
538         Rpar[1] = rmin + tn1 * (lo/cm - z1);      538         Rpar[1] = rmin + tn1 * (lo/cm - z1);
539         Rpar[3] = rmin + tn1 * (hi/cm - z1);      539         Rpar[3] = rmin + tn1 * (hi/cm - z1);
540         Rpar[2] = rmax + tn2 * (lo/cm - z1);      540         Rpar[2] = rmax + tn2 * (lo/cm - z1);
541         Rpar[4] = rmax + tn2 * (hi/cm - z1);      541         Rpar[4] = rmax + tn2 * (hi/cm - z1);
542         Rpar[0] = (hi - lo)/2./cm;                542         Rpar[0] = (hi - lo)/2./cm;
543         pos[2]  = (hi + lo)/2.;                   543         pos[2]  = (hi + lo)/2.;
544       }                                           544       }
545     }                                             545     }
546     else if ( shape == "CONS" ) {                 546     else if ( shape == "CONS" ) {
547       if ( fIAxis == 1 ) {                        547       if ( fIAxis == 1 ) {
548         Exception("CreateEnvelope","CONS-x");     548         Exception("CreateEnvelope","CONS-x");
549       }                                           549       }
550       else if ( fIAxis == 2 ) {                   550       else if ( fIAxis == 2 ) {
551         Rpar[5] = lo/deg;                         551         Rpar[5] = lo/deg;
552         Rpar[6] = hi/deg;                         552         Rpar[6] = hi/deg;
553       }                                           553       }
554       else if ( fIAxis == 3 ) {                   554       else if ( fIAxis == 3 ) {
555         G4double tn1, tn2, rmin, rmax, z1;        555         G4double tn1, tn2, rmin, rmax, z1;
556         tn1 = (Rpar[3] - Rpar[1])/(2.* Rpar[0]    556         tn1 = (Rpar[3] - Rpar[1])/(2.* Rpar[0]); 
557         tn2 = (Rpar[4] - Rpar[2])/(2.* Rpar[0]    557         tn2 = (Rpar[4] - Rpar[2])/(2.* Rpar[0]); 
558         rmin = Rpar[1]; rmax = Rpar[2]; z1 = -    558         rmin = Rpar[1]; rmax = Rpar[2]; z1 = -Rpar[0];
559         Rpar[1] = rmin + tn1 * (lo/cm - z1);      559         Rpar[1] = rmin + tn1 * (lo/cm - z1);
560         Rpar[3] = rmin + tn1 * (hi/cm - z1);      560         Rpar[3] = rmin + tn1 * (hi/cm - z1);
561         Rpar[2] = rmax + tn2 * (lo/cm - z1);      561         Rpar[2] = rmax + tn2 * (lo/cm - z1);
562         Rpar[4] = rmax + tn2 * (hi/cm - z1);      562         Rpar[4] = rmax + tn2 * (hi/cm - z1);
563         Rpar[0] = (hi - lo)/2./cm;                563         Rpar[0] = (hi - lo)/2./cm;
564         pos[2]  = (hi + lo)/2.;                   564         pos[2]  = (hi + lo)/2.;
565       }                                           565       }
566     }                                             566     }
567     else if ( shape == "SPHE" ) {                 567     else if ( shape == "SPHE" ) {
568       Exception("CreateEnvelope","SPHE-x,y,z")    568       Exception("CreateEnvelope","SPHE-x,y,z");                
569     }                                             569     }
570     else if ( shape == "PARA" ) {                 570     else if ( shape == "PARA" ) {
571       Exception("CreateEnvelope","PARA-x,y,z")    571       Exception("CreateEnvelope","PARA-x,y,z");
572     }                                             572     }
573     else if ( shape == "PGON" ) {                 573     else if ( shape == "PGON" ) {
574       if ( fIAxis == 2) {                         574       if ( fIAxis == 2) {
575   Rpar[0] = lo/deg;                               575   Rpar[0] = lo/deg;
576   Rpar[1] = hi/deg;                               576   Rpar[1] = hi/deg;
577   // rotm = ???                                   577   // rotm = ???
578       }                                           578       }
579       else {                                      579       else {
580         Exception("CreateEnvelope","PGON-x,z")    580         Exception("CreateEnvelope","PGON-x,z");
581       }                                           581       }
582     }                                             582     }
583     else if ( shape == "PCON" ) {                 583     else if ( shape == "PCON" ) {
584       if ( fIAxis == 2) {                         584       if ( fIAxis == 2) {
585   Rpar[0] = lo/deg;                               585   Rpar[0] = lo/deg;
586   Rpar[1] = hi/deg;                               586   Rpar[1] = hi/deg;
587   // rotm = ???                                   587   // rotm = ???
588       }                                           588       }
589       else {                                      589       else {
590         Exception("CreateEnvelope","PCON-x,z")    590         Exception("CreateEnvelope","PCON-x,z");
591       }                                           591       }
592     }                                             592     }
593     else {                                        593     else {
594        Exception("CreateEnvelope", "Unknown sh    594        Exception("CreateEnvelope", "Unknown shape" + shape);
595     }                                             595     }  
596                                                   596 
597     // create new VTE corresponding to envelop    597     // create new VTE corresponding to envelope
598     G4String envName = fVTE->GetName() + "_ENV    598     G4String envName = fVTE->GetName() + "_ENV"; 
599     G3VolTableEntry* envVTE                       599     G3VolTableEntry* envVTE 
600       = G4CreateVTE(envName, shape, fNmed, Rpa    600       = G4CreateVTE(envName, shape, fNmed, Rpar, npar);
601                                                   601 
602     // create a G3Pos object and add it to env    602     // create a G3Pos object and add it to envVTE
603     G4String motherName = fMVTE->GetMasterClon    603     G4String motherName = fMVTE->GetMasterClone()->GetName();
604     G4ThreeVector* offset = new G4ThreeVector(    604     G4ThreeVector* offset = new G4ThreeVector(pos[0],pos[1],pos[2]);    
605     G4String only = "ONLY";                       605     G4String only = "ONLY";
606     G3Pos* aG3Pos = new G3Pos(motherName, 1, o    606     G3Pos* aG3Pos = new G3Pos(motherName, 1, offset, 0, only);              
607     envVTE->AddG3Pos(aG3Pos);                     607     envVTE->AddG3Pos(aG3Pos);
608                                                   608 
609     delete [] Rpar;                               609     delete [] Rpar; 
610                                                   610 
611     return envVTE;                                611     return envVTE;
612 }                                                 612 }
613                                                   613 
614 void G3Division::CreateSolid(G4String shape, G    614 void G3Division::CreateSolid(G4String shape, G4double par[], G4int npar)
615 // create the solid corresponding to divided v    615 // create the solid corresponding to divided volume
616 // and set the fOffset for replica                616 // and set the fOffset for replica
617 {                                                 617 {
618     G4double *Rpar = new G4double[npar+2];        618     G4double *Rpar = new G4double[npar+2];
619     for (G4int i=0; i<npar; ++i){ Rpar[i] = pa    619     for (G4int i=0; i<npar; ++i){ Rpar[i] = par[i];}
620                                                   620 
621     // verbose                                    621     // verbose
622     // G4cout << "G3Division::CreateSolid volu    622     // G4cout << "G3Division::CreateSolid volume before: " 
623     //        << fVTE->GetName() << " " << sha    623     //        << fVTE->GetName() << " " << shape << G4endl;    
624     // G4cout << " npar,Rpar: " << npar;          624     // G4cout << " npar,Rpar: " << npar;
625     // for (G4int ii = 0; ii < npar; ++ii) G4c    625     // for (G4int ii = 0; ii < npar; ++ii) G4cout << " " << Rpar[ii];
626     // G4cout << G4endl;                          626     // G4cout << G4endl;
627                                                   627   
628     if ( shape == "BOX" ) {                       628     if ( shape == "BOX" ) {
629       if      ( fIAxis == 1 ) Rpar[0] = fWidth    629       if      ( fIAxis == 1 ) Rpar[0] = fWidth/2./cm;
630       else if ( fIAxis == 2 ) Rpar[1] = fWidth    630       else if ( fIAxis == 2 ) Rpar[1] = fWidth/2./cm; 
631       else if ( fIAxis == 3 ) Rpar[2] = fWidth    631       else if ( fIAxis == 3 ) Rpar[2] = fWidth/2./cm; 
632     }                                             632     }
633     else if ( shape == "TRD1" ) {                 633     else if ( shape == "TRD1" ) {
634       if ( fIAxis == 1 || fIAxis == 2 ) {         634       if ( fIAxis == 1 || fIAxis == 2 ) {
635         Exception("CreateSolid", "TRD1-x,y");     635         Exception("CreateSolid", "TRD1-x,y");
636       }                                           636       }
637       else if ( fIAxis == 3 ) {                   637       else if ( fIAxis == 3 ) {
638          Rpar[3] = fWidth/2./cm;                  638          Rpar[3] = fWidth/2./cm; 
639       }                                           639       }
640     }                                             640     }
641     else if ( shape == "TRD2" ) {                 641     else if ( shape == "TRD2" ) {
642       if ( fIAxis == 1 || fIAxis == 2 ) {         642       if ( fIAxis == 1 || fIAxis == 2 ) {
643         Exception("CreateSolid", "TRD2-x,y");     643         Exception("CreateSolid", "TRD2-x,y");
644       }                                           644       }
645       else if ( fIAxis == 3 ) {                   645       else if ( fIAxis == 3 ) {
646          Rpar[4] =  fWidth/2./cm;                 646          Rpar[4] =  fWidth/2./cm; 
647       }                                           647       }
648     }                                             648     }
649     else if ( shape == "TRAP" ) {                 649     else if ( shape == "TRAP" ) {
650       if ( fIAxis == 1 || fIAxis == 2) {          650       if ( fIAxis == 1 || fIAxis == 2) {
651         Exception("CreateSolid", "TRAP-x,y");     651         Exception("CreateSolid", "TRAP-x,y");
652       }                                           652       }
653       else if ( fIAxis == 3 ) {                   653       else if ( fIAxis == 3 ) {
654          Rpar[0] =  fWidth/2./cm;                 654          Rpar[0] =  fWidth/2./cm; 
655       }                                           655       }
656     }                                             656     }
657     else if ( shape == "TUBE" ) {                 657     else if ( shape == "TUBE" ) {
658       if ( fIAxis == 1 ) {                        658       if ( fIAxis == 1 ) {
659          Rpar[1] = Rpar[0] + fWidth/cm;           659          Rpar[1] = Rpar[0] + fWidth/cm;
660          fOffset = Rpar[0]*cm;                    660          fOffset = Rpar[0]*cm;
661       }                                           661       }
662       else if ( fIAxis == 2 ) {                   662       else if ( fIAxis == 2 ) {
663          Rpar[3] = 0.;                            663          Rpar[3] = 0.; 
664          Rpar[4] = fWidth/deg;                    664          Rpar[4] = fWidth/deg; 
665          shape = "TUBS";                          665          shape = "TUBS";
666          npar = npar + 2;                         666          npar = npar + 2;
667       }                                           667       }
668       else if ( fIAxis == 3 ) {                   668       else if ( fIAxis == 3 ) {
669          Rpar[2] = fWidth/2./cm;                  669          Rpar[2] = fWidth/2./cm; 
670       }                                           670       }
671     }                                             671     }
672     else if ( shape == "TUBS" ) {                 672     else if ( shape == "TUBS" ) {
673       if ( fIAxis == 1 ) {                        673       if ( fIAxis == 1 ) {
674         Rpar[1] = Rpar[0] + fWidth/cm;            674         Rpar[1] = Rpar[0] + fWidth/cm;
675         fOffset = Rpar[0]*cm;                     675         fOffset = Rpar[0]*cm;
676       }                                           676       }
677       else if ( fIAxis == 2 ) {                   677       else if ( fIAxis == 2 ) {
678          fOffset = Rpar[3]*deg;                   678          fOffset = Rpar[3]*deg; 
679          Rpar[3] = 0.;                            679          Rpar[3] = 0.;
680          Rpar[4] =  fWidth/deg;                   680          Rpar[4] =  fWidth/deg;
681       }                                           681       }
682       else if ( fIAxis == 3 ) {                   682       else if ( fIAxis == 3 ) {
683          Rpar[2] = fWidth/2./cm;                  683          Rpar[2] = fWidth/2./cm; 
684       }                                           684       }
685     }                                             685     }
686     else if ( shape == "CONE" ) {                 686     else if ( shape == "CONE" ) {
687       if ( fIAxis == 1 ) {                        687       if ( fIAxis == 1 ) {
688         Exception("CreateSolid", "CONE-x");       688         Exception("CreateSolid", "CONE-x"); 
689       }                                           689       }
690       else if ( fIAxis == 2 ) {                   690       else if ( fIAxis == 2 ) {
691          Rpar[5] = 0.;                            691          Rpar[5] = 0.;
692          Rpar[6] = fWidth/deg;                    692          Rpar[6] = fWidth/deg;
693          shape = "CONS";                          693          shape = "CONS";
694          npar = npar + 2;                         694          npar = npar + 2;
695       }                                           695       }
696       else if ( fIAxis == 3 ) {                   696       else if ( fIAxis == 3 ) {
697          Rpar[0] = fWidth/2./cm;                  697          Rpar[0] = fWidth/2./cm; 
698       }                                           698       }
699     }                                             699     }
700     else if ( shape == "CONS" ) {                 700     else if ( shape == "CONS" ) {
701       if ( fIAxis == 1 ) {                        701       if ( fIAxis == 1 ) {
702         Exception("CreateSolid", "CONS-x");       702         Exception("CreateSolid", "CONS-x"); 
703       }                                           703       }
704       else if ( fIAxis == 2 ) {                   704       else if ( fIAxis == 2 ) {
705          fOffset = Rpar[5]*deg;                   705          fOffset = Rpar[5]*deg;
706          Rpar[5] = 0.;                            706          Rpar[5] = 0.;
707          Rpar[6] = fWidth/deg;                    707          Rpar[6] = fWidth/deg;
708       }                                           708       }
709       else if ( fIAxis == 3 ) {                   709       else if ( fIAxis == 3 ) {
710          Rpar[0] = fWidth/2./cm;                  710          Rpar[0] = fWidth/2./cm; 
711       }                                           711       }
712     }                                             712     }
713     else if (shape == "PARA") {                   713     else if (shape == "PARA") {
714       if      ( fIAxis == 1 ) {                   714       if      ( fIAxis == 1 ) {
715          Rpar[0] = fWidth/2./cm;                  715          Rpar[0] = fWidth/2./cm;
716       }                                           716       }  
717       else if ( Rpar[4] == 0. && Rpar[5] == 0.    717       else if ( Rpar[4] == 0. && Rpar[5] == 0. ) {
718          // only special case for axis 2,3 is     718          // only special case for axis 2,3 is supported
719         if ( fIAxis == 2 ) {                      719         if ( fIAxis == 2 ) {
720           Rpar[1] = fWidth/2./cm;                 720           Rpar[1] = fWidth/2./cm;
721   }                                               721   }  
722     else if ( fIAxis == 3) {                      722     else if ( fIAxis == 3) {
723           Rpar[2] = fWidth/2./cm;                 723           Rpar[2] = fWidth/2./cm;
724   }                                               724   }
725       }                                           725       }   
726       else                                        726       else    
727          Exception("CreateSolid", shape);         727          Exception("CreateSolid", shape);
728     }                                             728     }  
729     else if (shape == "SPHE") {                   729     else if (shape == "SPHE") {
730       Exception("CreateSolid", shape);            730       Exception("CreateSolid", shape);
731     }                                             731     }
732     else if ( shape == "PGON" ) {                 732     else if ( shape == "PGON" ) {
733       if ( fIAxis == 2 ) {                        733       if ( fIAxis == 2 ) {
734          fOffset = Rpar[0]*deg;                   734          fOffset = Rpar[0]*deg;
735          Rpar[0] = 0.;                            735          Rpar[0] = 0.;
736          Rpar[1] = fWidth/deg;                    736          Rpar[1] = fWidth/deg;
737          Rpar[2] = 1.;                            737          Rpar[2] = 1.;
738       }                                           738       }
739       else                                        739       else
740        Exception("CreateSolid", shape);           740        Exception("CreateSolid", shape);
741     }                                             741     }
742     else if ( shape == "PCON" ) {                 742     else if ( shape == "PCON" ) {
743       if ( fIAxis == 2 ) {                        743       if ( fIAxis == 2 ) {
744          fOffset = Rpar[0]*deg;                   744          fOffset = Rpar[0]*deg;
745          Rpar[0] = 0.;                            745          Rpar[0] = 0.;
746          Rpar[1] = fWidth/deg;                    746          Rpar[1] = fWidth/deg;
747       }                                           747       }
748       else {                                      748       else {
749         Exception("CreateSolid", shape);          749         Exception("CreateSolid", shape);
750       }                                           750       } 
751     }                                             751     }
752     else {                                        752     else {
753        Exception("CreateSolid", "Unknown shape    753        Exception("CreateSolid", "Unknown shape" + shape);
754     }                                             754     }  
755                                                   755 
756     // create solid and set it to fVTE            756     // create solid and set it to fVTE
757     G4bool hasNegPars;                            757     G4bool hasNegPars;
758     G4bool deferred;                              758     G4bool deferred;   
759     G4bool okAxis[3];                             759     G4bool okAxis[3];
760     G4VSolid* solid                               760     G4VSolid* solid
761     = G3toG4MakeSolid(fVTE->GetName(), shape,     761     = G3toG4MakeSolid(fVTE->GetName(), shape, Rpar, npar, hasNegPars, deferred, okAxis);  
762                                                   762 
763     if (hasNegPars) {                             763     if (hasNegPars) {
764        G4String err_message = "CreateSolid VTE    764        G4String err_message = "CreateSolid VTE " + fVTE->GetName()
765                             + " has negative p    765                             + " has negative parameters.";
766        G4Exception("G3Division::CreateSolid()"    766        G4Exception("G3Division::CreateSolid()", "G3toG40006",
767                    FatalException, err_message    767                    FatalException, err_message);
768        return;                                    768        return;
769     }                                             769     }   
770                                                   770     
771     // update vte                                 771     // update vte
772     fVTE->SetSolid(solid);                        772     fVTE->SetSolid(solid);
773     fVTE->SetNRpar(npar, Rpar);                   773     fVTE->SetNRpar(npar, Rpar); 
774     fVTE->SetHasNegPars(hasNegPars);              774     fVTE->SetHasNegPars(hasNegPars);
775                                                   775 
776     // verbose                                    776     // verbose
777     // G4cout << "G3Division::CreateSolid volu    777     // G4cout << "G3Division::CreateSolid volume after: " 
778     //        << fVTE->GetName() << " " << sha    778     //        << fVTE->GetName() << " " << shape << G4endl;    
779     // G4cout << " npar,Rpar: " << npar;          779     // G4cout << " npar,Rpar: " << npar;
780     // for (G4int iii = 0; iii < npar; ++iii)     780     // for (G4int iii = 0; iii < npar; ++iii) G4cout << " " << Rpar[iii];
781     // G4cout << G4endl;                          781     // G4cout << G4endl;
782     delete [] Rpar;                               782     delete [] Rpar;
783 }                                                 783 }
784                                                   784 
785                                                   785 
786 G3VolTableEntry* G3Division::Dvn()                786 G3VolTableEntry* G3Division::Dvn()
787 {                                                 787 {   
788   // no envelope need to be created               788   // no envelope need to be created 
789                                                   789 
790   // get parameters from mother                   790   // get parameters from mother
791   G4String shape = fMVTE->GetShape();             791   G4String shape = fMVTE->GetShape(); 
792   G4double* Rpar = fMVTE->GetRpar();              792   G4double* Rpar = fMVTE->GetRpar();
793   G4int     npar = fMVTE->GetNpar();              793   G4int     npar = fMVTE->GetNpar();
794                                                   794 
795   // set width for replica and create solid       795   // set width for replica and create solid
796   fWidth = (fHighRange - fLowRange)/fNofDivisi    796   fWidth = (fHighRange - fLowRange)/fNofDivisions;
797   CreateSolid(shape, Rpar, npar);                 797   CreateSolid(shape, Rpar, npar);
798                                                   798 
799   return 0;                                       799   return 0;       
800 }                                                 800 }
801                                                   801 
802 G3VolTableEntry* G3Division::Dvn2()               802 G3VolTableEntry* G3Division::Dvn2()
803 {                                                 803 {
804   // to be defined as const of this class         804   // to be defined as const of this class
805   G4double Rmin = 0.0001*cm;                      805   G4double Rmin = 0.0001*cm;
806                                                   806 
807   G4String shape = fMVTE->GetShape();             807   G4String shape = fMVTE->GetShape();
808   G4double* Rpar = fMVTE->GetRpar();              808   G4double* Rpar = fMVTE->GetRpar();
809   G4int     npar = fMVTE->GetNpar();              809   G4int     npar = fMVTE->GetNpar();
810                                                   810 
811   G4double c0 = fC0;                              811   G4double c0 = fC0;
812   if (fAxis == kPhi)  c0 = c0*deg;                812   if (fAxis == kPhi)  c0 = c0*deg;
813   else                c0 = c0*cm;                 813   else                c0 = c0*cm;
814                                                   814           
815   // create envelope (if needed)                  815   // create envelope (if needed)
816   G3VolTableEntry* envVTE = 0;                    816   G3VolTableEntry* envVTE = 0;
817   if( std::abs(c0 - fLowRange) > Rmin) {          817   if( std::abs(c0 - fLowRange) > Rmin) {
818     envVTE = CreateEnvelope(shape, fHighRange,    818     envVTE = CreateEnvelope(shape, fHighRange, c0, Rpar, npar);
819     Rpar = envVTE->GetRpar();                     819     Rpar = envVTE->GetRpar();
820     npar = envVTE->GetNpar();                     820     npar = envVTE->GetNpar();
821   }                                               821   }  
822                                                   822 
823   // set width for replica and create solid       823   // set width for replica and create solid
824   fWidth = (fHighRange - c0)/fNofDivisions;       824   fWidth = (fHighRange - c0)/fNofDivisions;
825   CreateSolid(shape, Rpar, npar);                 825   CreateSolid(shape, Rpar, npar);
826                                                   826 
827   return envVTE;                                  827   return envVTE;
828 }                                                 828 }
829                                                   829 
830 G3VolTableEntry* G3Division::Dvt()                830 G3VolTableEntry* G3Division::Dvt()
831 {                                                 831 {
832   // to be defined as const of this class         832   // to be defined as const of this class
833   G4double Rmin = 0.0001*cm;                      833   G4double Rmin = 0.0001*cm;
834                                                   834 
835   // get parameters from mother                   835   // get parameters from mother
836   G4String shape = fMVTE->GetShape();             836   G4String shape = fMVTE->GetShape();
837   G4double* Rpar = fMVTE->GetRpar();              837   G4double* Rpar = fMVTE->GetRpar();
838   G4int     npar = fMVTE->GetNpar();              838   G4int     npar = fMVTE->GetNpar();
839                                                   839 
840   // calculate the number of divisions            840   // calculate the number of divisions    
841   G4int ndvmx = fNofDivisions;                    841   G4int ndvmx = fNofDivisions;
842   G4double step = fStep;                          842   G4double step = fStep;
843                                                   843   
844   if (fAxis == kPhi)  step = step*deg;            844   if (fAxis == kPhi)  step = step*deg;
845   else                step = step*cm;             845   else                step = step*cm;
846                                                   846 
847   G4int ndiv = G4int((fHighRange - fLowRange +    847   G4int ndiv = G4int((fHighRange - fLowRange + Rmin)/step);
848   // to be added warning                          848   // to be added warning
849   if (ndvmx > 255) ndvmx = 255;                   849   if (ndvmx > 255) ndvmx = 255;
850   if (ndiv > ndvmx && ndvmx > 0 ) ndiv = ndvmx    850   if (ndiv > ndvmx && ndvmx > 0 ) ndiv = ndvmx;
851                                                   851 
852   // create envVTE (if needed)                    852   // create envVTE (if needed)
853   G3VolTableEntry* envVTE = 0;                    853   G3VolTableEntry* envVTE = 0;
854   G4double delta = std::abs((fHighRange - fLow    854   G4double delta = std::abs((fHighRange - fLowRange) - ndiv*step);
855   if (delta > Rmin) {                             855   if (delta > Rmin) {
856     envVTE                                        856     envVTE 
857        = CreateEnvelope(shape, fHighRange-delt    857        = CreateEnvelope(shape, fHighRange-delta/2., fLowRange+delta/2., 
858                         Rpar, npar);              858                         Rpar, npar);
859     Rpar = envVTE->GetRpar();                     859     Rpar = envVTE->GetRpar();
860     npar = envVTE->GetNpar();                     860     npar = envVTE->GetNpar();
861   }                                               861   }
862                                                   862 
863   // set width for replica and create solid       863   // set width for replica and create solid
864   fWidth = step;                                  864   fWidth = step;
865   fNofDivisions = ndiv;                           865   fNofDivisions = ndiv;
866   CreateSolid(shape, Rpar, npar);                 866   CreateSolid(shape, Rpar, npar);
867                                                   867 
868   return envVTE;                                  868   return envVTE;
869 }                                                 869 }
870                                                   870 
871 G3VolTableEntry* G3Division::Dvt2()               871 G3VolTableEntry* G3Division::Dvt2()
872 {                                                 872 {
873   // to be defined as const of this class         873   // to be defined as const of this class
874   G4double Rmin = 0.0001*cm;                      874   G4double Rmin = 0.0001*cm;
875                                                   875 
876   // get parameters from mother                   876   // get parameters from mother
877   G4String shape = fMVTE->GetShape();             877   G4String shape = fMVTE->GetShape();
878   G4double* Rpar = fMVTE->GetRpar();              878   G4double* Rpar = fMVTE->GetRpar();
879   G4int     npar = fMVTE->GetNpar();              879   G4int     npar = fMVTE->GetNpar();
880                                                   880 
881   // calculate the number of divisions            881   // calculate the number of divisions   
882   G4int ndvmx = fNofDivisions;                    882   G4int ndvmx = fNofDivisions;
883   G4double step = fStep;                          883   G4double step = fStep;
884   G4double c0 = fC0;                              884   G4double c0 = fC0;
885                                                   885 
886   if(fAxis == kPhi){                              886   if(fAxis == kPhi){
887     step = step*deg;                              887     step = step*deg;
888     c0 = c0*deg;                                  888     c0 = c0*deg;
889   }                                               889   } 
890   else {                                          890   else {
891     step = step*cm;                               891     step = step*cm;
892     c0 = c0*cm;                                   892     c0 = c0*cm;
893   }                                               893   }  
894                                                   894 
895   G4int ndiv = G4int((fHighRange - c0 + Rmin)/    895   G4int ndiv = G4int((fHighRange - c0 + Rmin)/step);
896   // to be added warning                          896   // to be added warning
897   if (ndvmx > 255) ndvmx = 255;                   897   if (ndvmx > 255) ndvmx = 255;
898   if (ndiv > ndvmx && ndvmx > 0 ) ndiv = ndvmx    898   if (ndiv > ndvmx && ndvmx > 0 ) ndiv = ndvmx;
899                                                   899 
900   // create envelope (if needed)                  900   // create envelope (if needed)
901   G3VolTableEntry* envVTE = 0;                    901   G3VolTableEntry* envVTE = 0;
902   G4double delta = std::abs((fHighRange - c0)     902   G4double delta = std::abs((fHighRange - c0) - ndiv*step);
903   if (std::abs(c0 - fLowRange) > Rmin) {          903   if (std::abs(c0 - fLowRange) > Rmin) {
904     envVTE                                        904     envVTE 
905       = CreateEnvelope(shape, fHighRange-delta    905       = CreateEnvelope(shape, fHighRange-delta/2., c0+delta/2., Rpar, npar);
906     Rpar = envVTE->GetRpar();                     906     Rpar = envVTE->GetRpar();
907     npar = envVTE->GetNpar();                     907     npar = envVTE->GetNpar();
908   }                                               908   }
909                                                   909 
910   // set with for replica and create solid        910   // set with for replica and create solid
911   fWidth = step;                                  911   fWidth = step;
912   fNofDivisions = ndiv;                           912   fNofDivisions = ndiv;
913   CreateSolid(shape, Rpar, npar);                 913   CreateSolid(shape, Rpar, npar);
914                                                   914 
915   return envVTE;                                  915   return envVTE;   
916 }                                                 916 }
917                                                   917