Geant4 Cross Reference

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Geant4/persistency/ascii/src/G4tgbVolume.cc

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Differences between /persistency/ascii/src/G4tgbVolume.cc (Version 11.3.0) and /persistency/ascii/src/G4tgbVolume.cc (Version 10.4.p2)


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 25 //                                                 25 //
 26 // G4tgbVolume implementation                  << 
 27 //                                                 26 //
 28 // Author: P.Arce, CIEMAT (November 2007)      <<  27 // $Id: G4tgbVolume.cc 77356 2013-11-22 17:10:29Z gcosmo $
 29 // ------------------------------------------- <<  28 //
                                                   >>  29 //
                                                   >>  30 // class G4tgbVolume
                                                   >>  31 
                                                   >>  32 // History:
                                                   >>  33 // - Created.                                 P.Arce, CIEMAT (November 2007)
                                                   >>  34 // -------------------------------------------------------------------------
 30                                                    35 
 31 #include "G4tgbVolume.hh"                          36 #include "G4tgbVolume.hh"
 32                                                    37 
                                                   >>  38 #include "G4PhysicalConstants.hh"
                                                   >>  39 #include "G4SystemOfUnits.hh"
 33 #include "G4tgbVolumeMgr.hh"                       40 #include "G4tgbVolumeMgr.hh"
 34 #include "G4tgbMaterialMgr.hh"                     41 #include "G4tgbMaterialMgr.hh"
 35 #include "G4tgbRotationMatrixMgr.hh"               42 #include "G4tgbRotationMatrixMgr.hh"
 36 #include "G4tgbPlaceParamLinear.hh"                43 #include "G4tgbPlaceParamLinear.hh"
 37 #include "G4tgbPlaceParamSquare.hh"                44 #include "G4tgbPlaceParamSquare.hh"
 38 #include "G4tgbPlaceParamCircle.hh"                45 #include "G4tgbPlaceParamCircle.hh"
 39                                                    46 
 40 #include "G4tgrSolid.hh"                           47 #include "G4tgrSolid.hh"
 41 #include "G4tgrSolidBoolean.hh"                    48 #include "G4tgrSolidBoolean.hh"
 42 #include "G4tgrSolidMultiUnion.hh"             << 
 43 #include "G4tgrSolidScaled.hh"                 << 
 44 #include "G4tgrVolume.hh"                          49 #include "G4tgrVolume.hh"
 45 #include "G4tgrVolumeDivision.hh"                  50 #include "G4tgrVolumeDivision.hh"
 46 #include "G4tgrVolumeAssembly.hh"                  51 #include "G4tgrVolumeAssembly.hh"
 47 #include "G4tgrVolumeMgr.hh"                       52 #include "G4tgrVolumeMgr.hh"
 48 #include "G4tgrPlace.hh"                           53 #include "G4tgrPlace.hh"
 49 #include "G4tgrPlaceSimple.hh"                     54 #include "G4tgrPlaceSimple.hh"
 50 #include "G4tgrPlaceDivRep.hh"                     55 #include "G4tgrPlaceDivRep.hh"
 51 #include "G4tgrPlaceParameterisation.hh"           56 #include "G4tgrPlaceParameterisation.hh"
 52 #include "G4tgrUtils.hh"                           57 #include "G4tgrUtils.hh"
 53                                                    58 
 54 #include "G4VSolid.hh"                             59 #include "G4VSolid.hh"
 55 #include "G4UnionSolid.hh"                         60 #include "G4UnionSolid.hh"
 56 #include "G4SubtractionSolid.hh"                   61 #include "G4SubtractionSolid.hh"
 57 #include "G4IntersectionSolid.hh"                  62 #include "G4IntersectionSolid.hh"
 58 #include "G4MultiUnion.hh"                     << 
 59 #include "G4ScaledSolid.hh"                    << 
 60 #include "G4LogicalVolume.hh"                      63 #include "G4LogicalVolume.hh"
 61 #include "G4VPhysicalVolume.hh"                    64 #include "G4VPhysicalVolume.hh"
 62 #include "G4PVPlacement.hh"                        65 #include "G4PVPlacement.hh"
 63 #include "G4PVDivision.hh"                         66 #include "G4PVDivision.hh"
 64 #include "G4PVReplica.hh"                          67 #include "G4PVReplica.hh"
 65 #include "G4PVParameterised.hh"                    68 #include "G4PVParameterised.hh"
 66 #include "G4Box.hh"                                69 #include "G4Box.hh"
 67 #include "G4Tubs.hh"                               70 #include "G4Tubs.hh"
 68 #include "G4Cons.hh"                               71 #include "G4Cons.hh"
 69 #include "G4Trap.hh"                               72 #include "G4Trap.hh"
 70 #include "G4Sphere.hh"                             73 #include "G4Sphere.hh"
 71 #include "G4Orb.hh"                                74 #include "G4Orb.hh"
 72 #include "G4Trd.hh"                                75 #include "G4Trd.hh"
 73 #include "G4Para.hh"                               76 #include "G4Para.hh"
 74 #include "G4Torus.hh"                              77 #include "G4Torus.hh"
 75 #include "G4Hype.hh"                               78 #include "G4Hype.hh"
 76 #include "G4Polycone.hh"                           79 #include "G4Polycone.hh"
 77 #include "G4GenericPolycone.hh"                    80 #include "G4GenericPolycone.hh"
 78 #include "G4Polyhedra.hh"                          81 #include "G4Polyhedra.hh"
 79 #include "G4EllipticalTube.hh"                     82 #include "G4EllipticalTube.hh"
 80 #include "G4Ellipsoid.hh"                          83 #include "G4Ellipsoid.hh"
 81 #include "G4EllipticalCone.hh"                     84 #include "G4EllipticalCone.hh"
 82 #include "G4Hype.hh"                               85 #include "G4Hype.hh"
 83 #include "G4Tet.hh"                                86 #include "G4Tet.hh"
 84 #include "G4TwistedBox.hh"                         87 #include "G4TwistedBox.hh"
 85 #include "G4TwistedTrap.hh"                        88 #include "G4TwistedTrap.hh"
 86 #include "G4TwistedTrd.hh"                         89 #include "G4TwistedTrd.hh"
 87 #include "G4TwistedTubs.hh"                        90 #include "G4TwistedTubs.hh"
 88 #include "G4AssemblyVolume.hh"                     91 #include "G4AssemblyVolume.hh"
 89 #include "G4TessellatedSolid.hh"                   92 #include "G4TessellatedSolid.hh"
 90 #include "G4TriangularFacet.hh"                    93 #include "G4TriangularFacet.hh"
 91 #include "G4QuadrangularFacet.hh"                  94 #include "G4QuadrangularFacet.hh"
 92 #include "G4ExtrudedSolid.hh"                      95 #include "G4ExtrudedSolid.hh"
 93                                                    96 
 94 #include "G4VisExtent.hh"                          97 #include "G4VisExtent.hh"
 95 #include "G4Material.hh"                           98 #include "G4Material.hh"
 96 #include "G4RotationMatrix.hh"                     99 #include "G4RotationMatrix.hh"
 97 #include "G4ReflectionFactory.hh"                 100 #include "G4ReflectionFactory.hh"
 98                                                   101 
 99 #include "G4VisAttributes.hh"                     102 #include "G4VisAttributes.hh"
100 #include "G4RegionStore.hh"                       103 #include "G4RegionStore.hh"
101 #include "G4tgrMessenger.hh"                      104 #include "G4tgrMessenger.hh"
102 #include "G4UIcommand.hh"                         105 #include "G4UIcommand.hh"
103 #include "G4GeometryTolerance.hh"                 106 #include "G4GeometryTolerance.hh"
104                                                   107 
105 #include "G4PhysicalConstants.hh"              << 108 //-------------------------------------------------------------------
106 #include "G4SystemOfUnits.hh"                  << 
107                                                << 
108 // ------------------------------------------- << 
109 G4tgbVolume::G4tgbVolume()                        109 G4tgbVolume::G4tgbVolume()
                                                   >> 110   : theTgrVolume(0), theG4AssemblyVolume(0)
110 {                                                 111 {
111 }                                                 112 }
112                                                   113 
113 // ------------------------------------------- << 114 
                                                   >> 115 //-------------------------------------------------------------------
114 G4tgbVolume::~G4tgbVolume()                       116 G4tgbVolume::~G4tgbVolume()
115 {                                                 117 {
116 }                                                 118 }
117                                                   119 
118 // ------------------------------------------- << 120 
119 G4tgbVolume::G4tgbVolume(G4tgrVolume* vol)     << 121 //-------------------------------------------------------------------
                                                   >> 122 G4tgbVolume::G4tgbVolume( G4tgrVolume* vol)
120 {                                                 123 {
121   theTgrVolume = vol;                             124   theTgrVolume = vol;
                                                   >> 125   theG4AssemblyVolume = 0;
122 }                                                 126 }
123                                                   127 
124 // ------------------------------------------- << 128 
125 void G4tgbVolume::ConstructG4Volumes(const G4t << 129 //-------------------------------------------------------------------
126                                      const G4L << 130 void G4tgbVolume::ConstructG4Volumes( const G4tgrPlace* place,
                                                   >> 131                                       const G4LogicalVolume* parentLV )
127 {                                                 132 {
128 #ifdef G4VERBOSE                                  133 #ifdef G4VERBOSE
129   if(G4tgrMessenger::GetVerboseLevel() >= 2)   << 134   if( G4tgrMessenger::GetVerboseLevel() >= 2 )
130   {                                               135   {
131     G4cout << G4endl << "@@@ G4tgbVolume::Cons << 136     G4cout << G4endl <<  "@@@ G4tgbVolume::ConstructG4Volumes - " << GetName() << G4endl;
132            << G4endl;                          << 137     if( place && parentLV ) G4cout << "   place in LV " << parentLV->GetName() << G4endl;
133     if(place && parentLV)                      << 
134       G4cout << "   place in LV " << parentLV- << 
135   }                                               138   }
136 #endif                                            139 #endif
137   G4tgbVolumeMgr* g4vmgr     = G4tgbVolumeMgr: << 140   G4tgbVolumeMgr* g4vmgr = G4tgbVolumeMgr::GetInstance();
138   G4LogicalVolume* logvol    = g4vmgr->FindG4L << 141   G4LogicalVolume* logvol = g4vmgr->FindG4LogVol( GetName() );
139   G4bool bFirstCopy          = false;          << 142   G4bool bFirstCopy = false;
140   G4VPhysicalVolume* physvol = nullptr;        << 143   if( logvol == 0 ) 
141   if(logvol == nullptr)                        << 
142   {                                               144   {
143     bFirstCopy = true;                            145     bFirstCopy = true;
144     if(theTgrVolume->GetType() != "VOLDivision << 146     if( theTgrVolume->GetType() != "VOLDivision" )
145     {                                             147     {
146       //--- If first time build solid and LogV    148       //--- If first time build solid and LogVol
147       G4VSolid* solid = FindOrConstructG4Solid << 149       G4VSolid* solid = FindOrConstructG4Solid( theTgrVolume->GetSolid() ); 
148       if(solid != nullptr)  // for G4AssemblyV << 150       if( solid != 0 )   // for G4AssemblyVolume it is 0
149       {                                           151       {
150         g4vmgr->RegisterMe(solid);             << 152   g4vmgr->RegisterMe( solid );
151         logvol = ConstructG4LogVol(solid);     << 153   logvol = ConstructG4LogVol( solid );
152         g4vmgr->RegisterMe(logvol);            << 154   g4vmgr->RegisterMe( logvol );
153         g4vmgr->RegisterChildParentLVs(logvol, << 155   g4vmgr->RegisterChildParentLVs( logvol, parentLV ); 
154       }                                           156       }
155     }                                             157     }
156     else                                          158     else
157     {                                             159     {
158       return;                                     160       return;
159     }                                             161     }
160   }                                            << 162   } 
161   //--- Construct PhysVol                         163   //--- Construct PhysVol
162   physvol = ConstructG4PhysVol(place, logvol,  << 164   G4VPhysicalVolume* physvol = ConstructG4PhysVol( place, logvol, parentLV );
163                                                << 165   if( physvol != 0 )  // 0 for G4AssemblyVolumes
164   if(physvol != nullptr)  // nullptr for G4Ass << 
165   {                                               166   {
166     g4vmgr->RegisterMe(physvol);               << 167     g4vmgr->RegisterMe( physvol );
167                                                   168 
168     if(logvol == nullptr)  // case of division << 169     if( logvol == 0 ) // case of divisions
169     {                                             170     {
170       logvol = physvol->GetLogicalVolume();       171       logvol = physvol->GetLogicalVolume();
171     }                                             172     }
172   }                                               173   }
173   else                                         << 174   else 
174   {                                               175   {
175     return;                                       176     return;
176   }                                               177   }
177                                                   178 
178   //--- If first copy build children placement    179   //--- If first copy build children placements in this LogVol
179   if(bFirstCopy)                                  180   if(bFirstCopy)
180   {                                               181   {
181     std::pair<G4mmapspl::iterator, G4mmapspl:: << 182     std::pair<G4mmapspl::iterator, G4mmapspl::iterator> children
182       G4tgrVolumeMgr::GetInstance()->GetChildr << 183       = G4tgrVolumeMgr::GetInstance()->GetChildren( GetName() );
183     for(auto cite = children.first; cite != ch << 184     G4mmapspl::iterator cite; 
                                                   >> 185     for( cite = children.first; cite != children.second; cite++ )
184     {                                             186     {
185       //----- Call G4tgrPlace ->constructG4Vol << 187       //----- Call G4tgrPlace ->constructG4Volumes 
186       //---- find G4tgbVolume corresponding to    188       //---- find G4tgbVolume corresponding to the G4tgrVolume
187       //     pointed by G4tgrPlace                189       //     pointed by G4tgrPlace
188       G4tgrPlace* pl    = const_cast<G4tgrPlac << 190       G4tgrPlace* pl = const_cast<G4tgrPlace*>((*cite).second);
189       G4tgbVolume* svol = g4vmgr->FindVolume(p << 191       G4tgbVolume* svol = g4vmgr->FindVolume( pl->GetVolume()->GetName() );
190       //--- find copyNo                           192       //--- find copyNo
191 #ifdef G4VERBOSE                                  193 #ifdef G4VERBOSE
192       if(G4tgrMessenger::GetVerboseLevel() >=  << 194       if( G4tgrMessenger::GetVerboseLevel() >= 2 )
193       {                                           195       {
194         G4cout << " G4tgbVolume::ConstructG4Vo << 196   G4cout << " G4tgbVolume::ConstructG4Volumes - construct daughter " <<  pl->GetVolume()->GetName() << " # " << pl->GetCopyNo() << G4endl;
195                << pl->GetVolume()->GetName() < << 
196                << G4endl;                      << 
197       }                                           197       }
198 #endif                                            198 #endif
199       svol->ConstructG4Volumes(pl, logvol);    << 199       svol->ConstructG4Volumes( pl, logvol );
200     }                                             200     }
201   }                                               201   }
                                                   >> 202 
202 }                                                 203 }
203                                                   204 
204 // ------------------------------------------- << 205 
205 G4VSolid* G4tgbVolume::FindOrConstructG4Solid( << 206 
                                                   >> 207 //-------------------------------------------------------------------
                                                   >> 208 G4VSolid* G4tgbVolume::FindOrConstructG4Solid( const G4tgrSolid* sol ) 
206 {                                                 209 {
207   G4double angularTolerance =                  << 210   G4double angularTolerance = G4GeometryTolerance::GetInstance()
208     G4GeometryTolerance::GetInstance()->GetAng << 211                             ->GetAngularTolerance();
209                                                   212 
210   if(sol == nullptr)                           << 213   if( sol == 0 ) { return 0; }
211   {                                            << 
212     return nullptr;                            << 
213   }                                            << 
214                                                   214 
215 #ifdef G4VERBOSE                                  215 #ifdef G4VERBOSE
216   if(G4tgrMessenger::GetVerboseLevel() >= 2)   << 216   if( G4tgrMessenger::GetVerboseLevel() >= 2 )
217   {                                               217   {
218     G4cout << " G4tgbVolume::FindOrConstructG4    218     G4cout << " G4tgbVolume::FindOrConstructG4Solid():" << G4endl
219            << "   SOLID = " << sol << G4endl < << 219            << "   SOLID = " << sol << G4endl
220            << " of type " << sol->GetType() << << 220            << "   " << sol->GetName() << " of type " << sol->GetType()
                                                   >> 221            << G4endl;
221   }                                               222   }
222 #endif                                         << 223 #endif 
223                                                   224 
224   //----- Check if solid exists already           225   //----- Check if solid exists already
225   G4VSolid* solid = G4tgbVolumeMgr::GetInstanc << 226   G4VSolid* solid = G4tgbVolumeMgr::GetInstance()
226   if(solid != nullptr)                         << 227                     ->FindG4Solid( sol->GetName() );
227   {                                            << 228   if( solid ) { return solid; }
228     return solid;                              << 
229   }                                            << 
230                                                   229 
231   // Give 'sol' as Boolean solids needs to cal    230   // Give 'sol' as Boolean solids needs to call this method twice
232                                                   231 
233 #ifdef G4VERBOSE                                  232 #ifdef G4VERBOSE
234   if(G4tgrMessenger::GetVerboseLevel() >= 2)   << 233   if( G4tgrMessenger::GetVerboseLevel() >= 2 )
235   {                                               234   {
236     G4cout << " G4tgbVolume::FindOrConstructG4    235     G4cout << " G4tgbVolume::FindOrConstructG4Solid() - "
237            << sol->GetSolidParams().size() <<     236            << sol->GetSolidParams().size() << G4endl;
238   }                                               237   }
239 #endif                                            238 #endif
240                                                << 239   
241   std::vector<G4double> solParam;                 240   std::vector<G4double> solParam;
242                                                   241 
243   // In case of BOOLEAN solids, solidParams ar    242   // In case of BOOLEAN solids, solidParams are taken from components
244                                                   243 
245   if(sol->GetSolidParams().size() == 1)        << 244   if( sol->GetSolidParams().size() == 1)
246   {                                            << 245   { 
247     solParam = *sol->GetSolidParams()[0];      << 246     solParam = * sol->GetSolidParams()[ 0 ];
248   }                                               247   }
249                                                   248 
250   //----------- instantiate the appropiate G4V    249   //----------- instantiate the appropiate G4VSolid type
251   G4String stype = sol->GetType();                250   G4String stype = sol->GetType();
252   G4String sname = sol->GetName();                251   G4String sname = sol->GetName();
253                                                   252 
254   if(stype == "BOX")                           << 253   if( stype == "BOX" )
255   {                                               254   {
256     CheckNoSolidParams(stype, 3, (G4int)solPar << 255     CheckNoSolidParams( stype, 3, solParam.size() );
257     solid = new G4Box(sname, solParam[0], solP << 256     solid = new G4Box( sname, solParam[0], solParam[1], solParam[2] ); 
                                                   >> 257 
258   }                                               258   }
259   else if(stype == "TUBE")                     << 259   else if( stype == "TUBE" )
260   {                                               260   {
261     CheckNoSolidParams(stype, 3, (G4int)solPar << 261     CheckNoSolidParams( stype, 3, solParam.size() );
262     solid = new G4Tubs(sname, solParam[0], sol << 262     solid = new G4Tubs( sname, solParam[0], solParam[1], solParam[2],
263                        360. * deg);            << 263                         0.*deg, 360.*deg );
264   }                                               264   }
265   else if(stype == "TUBS")                     << 265   else if( stype == "TUBS" )
266   {                                               266   {
267     CheckNoSolidParams(stype, 5, (G4int)solPar << 267     CheckNoSolidParams( stype, 5, solParam.size() );
268     G4double phiDelta = solParam[4];              268     G4double phiDelta = solParam[4];
269     if(std::fabs(phiDelta - twopi) < angularTo << 269     if( std::fabs(phiDelta - twopi) < angularTolerance ) { phiDelta = twopi; }
270     {                                          << 270     solid = new G4Tubs( sname, solParam[0], solParam[1], solParam[2],
271       phiDelta = twopi;                        << 271                         solParam[3], phiDelta );
272     }                                          << 
273     solid = new G4Tubs(sname, solParam[0], sol << 
274                        solParam[3], phiDelta); << 
275   }                                               272   }
276   else if(stype == "TRAP")                     << 273   else if( stype == "TRAP" )
277   {                                               274   {
278     if(solParam.size() == 11)                  << 275     if( solParam.size() == 11 )
279     {                                             276     {
280       solid = new G4Trap(sname, solParam[0], s << 277       solid = new G4Trap( sname, solParam[0], solParam[1], solParam[2],
281                          solParam[3], solParam << 278                           solParam[3], solParam[4], solParam[5], solParam[6],
282                          solParam[7], solParam << 279                           solParam[7], solParam[8], solParam[9], solParam[10] );
283     }                                             280     }
284     else if(solParam.size() == 4)              << 281     else if( solParam.size() == 4 )
285     {                                             282     {
286       solid = new G4Trap(sname, solParam[0], s << 283       solid = new G4Trap( sname, solParam[0], solParam[1]/deg,
287                          solParam[2] / deg, so << 284                           solParam[2]/deg, solParam[3]);
288     }                                             285     }
289     else                                          286     else
290     {                                             287     {
291       G4String ErrMessage1 = "Solid type " + s    288       G4String ErrMessage1 = "Solid type " + stype;
292       G4String ErrMessage2 = " should have 11     289       G4String ErrMessage2 = " should have 11 or 4 parameters,\n";
293       G4String ErrMessage3 =                   << 290       G4String ErrMessage3 = "and it has "
294         "and it has " + G4UIcommand::ConvertTo << 291                          + G4UIcommand::ConvertToString(G4int(solParam.size()));
295       G4String ErrMessage = ErrMessage1 + ErrM    292       G4String ErrMessage = ErrMessage1 + ErrMessage2 + ErrMessage3 + " !";
296       G4Exception("G4tgbVolume::FindOrConstruc << 293       G4Exception("G4tgbVolume::FindOrConstructG4Solid()",
297                   FatalException, ErrMessage); << 294                   "InvalidSetup", FatalException, ErrMessage);
298       return 0;                                   295       return 0;
299     }                                             296     }
                                                   >> 297     
300   }                                               298   }
301   else if(stype == "TRD")                      << 299   else if( stype == "TRD" )
302   {                                               300   {
303     CheckNoSolidParams(stype, 5, (G4int)solPar << 301     CheckNoSolidParams( stype, 5, solParam.size() );
304     solid = new G4Trd(sname, solParam[0], solP << 302     solid = new G4Trd( sname, solParam[0], solParam[1], solParam[2],
305                       solParam[4]);            << 303                        solParam[3], solParam[4] );
306   }                                               304   }
307   else if(stype == "PARA")                     << 305   else if( stype == "PARA" )
308   {                                               306   {
309     CheckNoSolidParams(stype, 6, (G4int)solPar << 307     CheckNoSolidParams( stype, 6, solParam.size() );
310     solid = new G4Para(sname, solParam[0], sol << 308     solid = new G4Para( sname, solParam[0], solParam[1], solParam[2],
311                        solParam[3], solParam[4 << 309                         solParam[3], solParam[4], solParam[5] );
312   }                                               310   }
313   else if(stype == "CONE")                     << 311   else if( stype == "CONE" )
314   {                                               312   {
315     CheckNoSolidParams(stype, 5, (G4int)solPar << 313     CheckNoSolidParams( stype, 5, solParam.size() );
316     solid = new G4Cons(sname, solParam[0], sol << 314     solid = new G4Cons( sname, solParam[0], solParam[1], solParam[2],
317                        solParam[3], solParam[4 << 315                         solParam[3], solParam[4], 0., 360.*deg);
318   }                                               316   }
319   else if(stype == "CONS")                     << 317   else if( stype == "CONS" )
320   {                                               318   {
321     CheckNoSolidParams(stype, 7, (G4int)solPar << 319     CheckNoSolidParams( stype, 7, solParam.size() );
322     G4double phiDelta = solParam[6];              320     G4double phiDelta = solParam[6];
323     if(std::fabs(phiDelta - twopi) < angularTo << 321     if( std::fabs(phiDelta - twopi) < angularTolerance ) { phiDelta = twopi; }
324     {                                          << 322     solid = new G4Cons( sname, solParam[0], solParam[1], solParam[2],
325       phiDelta = twopi;                        << 323                         solParam[3], solParam[4], solParam[5], phiDelta);
326     }                                          << 
327     solid = new G4Cons(sname, solParam[0], sol << 
328                        solParam[3], solParam[4 << 
329   }                                               324   }
330   else if(stype == "SPHERE")                   << 325   else if( stype == "SPHERE" )
331   {                                               326   {
332     CheckNoSolidParams(stype, 6, (G4int)solPar << 327     CheckNoSolidParams( stype, 6, solParam.size() );
333     G4double phiDelta = solParam[3];              328     G4double phiDelta = solParam[3];
334     if(std::fabs(phiDelta - twopi) < angularTo << 329     if( std::fabs(phiDelta - twopi) < angularTolerance ) { phiDelta = twopi; }
335     {                                          << 
336       phiDelta = twopi;                        << 
337     }                                          << 
338     G4double thetaDelta = solParam[5];            330     G4double thetaDelta = solParam[5];
339     if(std::fabs(thetaDelta - pi) < angularTol << 331     if( std::fabs(thetaDelta - pi) < angularTolerance ) { thetaDelta = pi; }
340     {                                          << 332     solid = new G4Sphere( sname, solParam[0], solParam[1], solParam[2],
341       thetaDelta = pi;                         << 333                           phiDelta, solParam[4], thetaDelta);
342     }                                          << 
343     solid = new G4Sphere(sname, solParam[0], s << 
344                          solParam[4], thetaDel << 
345   }                                               334   }
346   else if(stype == "ORB")                      << 335   else if( stype == "ORB" )
347   {                                               336   {
348     CheckNoSolidParams(stype, 1, (G4int)solPar << 337     CheckNoSolidParams( stype, 1, solParam.size() );
349     solid = new G4Orb(sname, solParam[0]);     << 338     solid = new G4Orb( sname, solParam[0] );
350   }                                               339   }
351   else if(stype == "TORUS")                    << 340   else if( stype == "TORUS" )
352   {                                               341   {
353     CheckNoSolidParams(stype, 5, (G4int)solPar << 342     CheckNoSolidParams( stype, 5, solParam.size() );
354     G4double phiDelta = solParam[4];              343     G4double phiDelta = solParam[4];
355     if(std::fabs(phiDelta - twopi) < angularTo << 344     if( std::fabs(phiDelta - twopi) < angularTolerance ) { phiDelta = twopi; }
356     {                                          << 345     solid = new G4Torus( sname, solParam[0], solParam[1], solParam[2],
357       phiDelta = twopi;                        << 346                          solParam[3], phiDelta );
358     }                                          << 
359     solid = new G4Torus(sname, solParam[0], so << 
360                         solParam[3], phiDelta) << 
361   }                                               347   }
362   else if(stype == "POLYCONE"                  << 348   else if( stype == "POLYCONE" )
363     || stype == "GENERICPOLYCONE")             << 
364   {                                               349   {
365     std::size_t nplanes = std::size_t(solParam << 350     size_t nplanes = size_t(solParam[2]);
366     G4bool genericPoly = false;                   351     G4bool genericPoly = false;
367     if(solParam.size() == 3 + nplanes * 3)     << 352     if( solParam.size() == 3+nplanes*3 )
368     {                                          << 353     { 
369       genericPoly = false;                        354       genericPoly = false;
370     }                                             355     }
371     else if(solParam.size() == 3 + nplanes * 2 << 356     else if( solParam.size() == 3+nplanes*2 )
372     {                                          << 357     { 
373       genericPoly = true;                         358       genericPoly = true;
374     }                                             359     }
375     else                                          360     else
376     {                                             361     {
377       G4String Err1 = "Solid type " + stype +     362       G4String Err1 = "Solid type " + stype + " should have ";
378       G4String Err2 = G4UIcommand::ConvertToSt << 363       G4String Err2 = G4UIcommand::ConvertToString(G4int(3+nplanes*3))
379                       " (Z,Rmin,Rmax)\n";      << 364                     + " (Z,Rmin,Rmax)\n";
380       G4String Err3 =                          << 365       G4String Err3 = "or " + G4UIcommand::ConvertToString(G4int(3+nplanes*2));
381         "or " + G4UIcommand::ConvertToString(G << 
382       G4String Err4 = " (RZ corners) parameter    366       G4String Err4 = " (RZ corners) parameters,\n";
383       G4String Err5 =                          << 367       G4String Err5 = "and it has "
384         "and it has " + G4UIcommand::ConvertTo << 368                     +  G4UIcommand::ConvertToString(G4int(solParam.size()));
385       G4String ErrMessage = Err1 + Err2 + Err3    369       G4String ErrMessage = Err1 + Err2 + Err3 + Err4 + Err5 + " !";
386       G4Exception("G4tgbVolume::FindOrConstruc << 370       G4Exception("G4tgbVolume::FindOrConstructG4Solid()",
387                   FatalException, ErrMessage); << 371                   "InvalidSetup", FatalException, ErrMessage);
388       return nullptr;                          << 372       return 0;
389     }                                             373     }
390                                                   374 
391     if(!genericPoly)                           << 375     if( !genericPoly )
392     {                                             376     {
393       std::vector<G4double>* z_p    = new std: << 377       std::vector<G4double>* z_p = new std::vector<G4double>;
394       std::vector<G4double>* rmin_p = new std:    378       std::vector<G4double>* rmin_p = new std::vector<G4double>;
395       std::vector<G4double>* rmax_p = new std:    379       std::vector<G4double>* rmax_p = new std::vector<G4double>;
396       for(std::size_t ii = 0; ii < nplanes; ++ << 380       for( size_t ii = 0; ii < nplanes; ii++ )
397       {                                           381       {
398         (*z_p).push_back(solParam[3 + 3 * ii]) << 382         (*z_p).push_back( solParam[3+3*ii] );
399         (*rmin_p).push_back(solParam[3 + 3 * i << 383         (*rmin_p).push_back( solParam[3+3*ii+1] );
400         (*rmax_p).push_back(solParam[3 + 3 * i << 384         (*rmax_p).push_back(  solParam[3+3*ii+2] );
401       }                                           385       }
402       G4double phiTotal = solParam[1];            386       G4double phiTotal = solParam[1];
403       if(std::fabs(phiTotal - twopi) < angular << 387       if( std::fabs(phiTotal - twopi) < angularTolerance ) { phiTotal = twopi; }
404       {                                        << 388       solid = new G4Polycone( sname, solParam[0], phiTotal, // start,delta-phi
405         phiTotal = twopi;                      << 389                               nplanes, // sections
406       }                                        << 390                               &((*z_p)[0]), &((*rmin_p)[0]), &((*rmax_p)[0]));
407       solid = new G4Polycone(sname, solParam[0 << 
408                              (G4int)nplanes,   << 
409                              &((*z_p)[0]), &(( << 
410     }                                             391     }
411     else                                          392     else
412     {                                             393     {
413       std::vector<G4double>* R_c = new std::ve    394       std::vector<G4double>* R_c = new std::vector<G4double>;
414       std::vector<G4double>* Z_c = new std::ve    395       std::vector<G4double>* Z_c = new std::vector<G4double>;
415       for(size_t ii = 0; ii < nplanes; ii++)   << 396       for( size_t ii = 0; ii < nplanes; ii++ )
416       {                                           397       {
417         (*R_c).push_back(solParam[3 + 2 * ii]) << 398         (*R_c).push_back( solParam[3+2*ii] );
418         (*Z_c).push_back(solParam[3 + 2 * ii + << 399         (*Z_c).push_back( solParam[3+2*ii+1] );
419       }                                           400       }
420       G4double phiTotal = solParam[1];            401       G4double phiTotal = solParam[1];
421       if(std::fabs(phiTotal - twopi) < angular << 402       if( std::fabs(phiTotal - twopi) < angularTolerance ) { phiTotal = twopi; }
422       {                                        << 403       solid = new G4GenericPolycone( sname,
423         phiTotal = twopi;                      << 404                               solParam[0], phiTotal, // start,delta-phi
424       }                                        << 405                               nplanes, // sections
425       solid =                                  << 
426         new G4GenericPolycone(sname, solParam[ << 
427                               (G4int)nplanes,  << 
428                               &((*R_c)[0]), &(    406                               &((*R_c)[0]), &((*Z_c)[0]));
429     }                                             407     }
                                                   >> 408 
430   }                                               409   }
431   else if(stype == "POLYHEDRA")                << 410   else if( stype == "POLYHEDRA" )
432   {                                               411   {
433     std::size_t nplanes = std::size_t(solParam << 412     size_t nplanes = size_t(solParam[3]);
434     G4bool genericPoly = false;                   413     G4bool genericPoly = false;
435     if(solParam.size() == 4 + nplanes * 3)     << 414     if( solParam.size() == 4+nplanes*3 )
436     {                                          << 415     { 
437       genericPoly = false;                     << 
438     }                                          << 
439     else if(solParam.size() == 4 + nplanes * 2 << 
440     {                                          << 
441       genericPoly = true;                         416       genericPoly = true;
442     }                                             417     }
                                                   >> 418     else if( solParam.size() == 4+nplanes*2 )
                                                   >> 419     { 
                                                   >> 420       genericPoly = false;
                                                   >> 421     }
443     else                                          422     else
444     {                                             423     {
445       G4String Err1 = "Solid type " + stype +     424       G4String Err1 = "Solid type " + stype + " should have ";
446       G4String Err2 = G4UIcommand::ConvertToSt << 425       G4String Err2 = G4UIcommand::ConvertToString(G4int(4+nplanes*3))
447                       " (Z,Rmin,Rmax)\n";      << 426                     + " (Z,Rmin,Rmax)\n";
448       G4String Err3 =                          << 427       G4String Err3 = "or " + G4UIcommand::ConvertToString(G4int(4+nplanes*2));
449         "or " + G4UIcommand::ConvertToString(G << 
450       G4String Err4 = " (RZ corners) parameter    428       G4String Err4 = " (RZ corners) parameters,\n";
451       G4String Err5 =                          << 429       G4String Err5 = "and it has "
452         "and it has " + G4UIcommand::ConvertTo << 430                     + G4UIcommand::ConvertToString(G4int(solParam.size()));
453       G4String ErrMessage = Err1 + Err2 + Err3    431       G4String ErrMessage = Err1 + Err2 + Err3 + Err4 + Err5 + " !";
454       G4Exception("G4tgbVolume::FindOrConstruc << 432       G4Exception("G4tgbVolume::FindOrConstructG4Solid()",
455                   FatalException, ErrMessage); << 433                   "InvalidSetup", FatalException, ErrMessage);
456       return nullptr;                          << 434       return 0;
457     }                                             435     }
458                                                << 436     
459     if(!genericPoly)                           << 437     if( !genericPoly )
460     {                                             438     {
461       std::vector<G4double>* z_p    = new std: << 439       std::vector<G4double>* z_p = new std::vector<G4double>;
462       std::vector<G4double>* rmin_p = new std:    440       std::vector<G4double>* rmin_p = new std::vector<G4double>;
463       std::vector<G4double>* rmax_p = new std:    441       std::vector<G4double>* rmax_p = new std::vector<G4double>;
464       for(std::size_t ii = 0; ii < nplanes; ++ << 442       for( size_t ii = 0; ii < nplanes; ii++ )
465       {                                           443       {
466         (*z_p).push_back(solParam[4 + 3 * ii]) << 444         (*z_p).push_back( solParam[4+3*ii] );
467         (*rmin_p).push_back(solParam[4 + 3 * i << 445         (*rmin_p).push_back( solParam[4+3*ii+1] );
468         (*rmax_p).push_back(solParam[4 + 3 * i << 446         (*rmax_p).push_back(  solParam[4+3*ii+2] );
469       }                                           447       }
470       G4double phiTotal = solParam[1];            448       G4double phiTotal = solParam[1];
471       if(std::fabs(phiTotal - twopi) < angular << 449       if( std::fabs(phiTotal - twopi) < angularTolerance ) { phiTotal = twopi; }
472       {                                        << 450       solid = new G4Polyhedra( sname, solParam[0], phiTotal,
473         phiTotal = twopi;                      << 451                                G4int(solParam[2]), nplanes,
474       }                                        << 452                                &((*z_p)[0]), &((*rmin_p)[0]), &((*rmax_p)[0]));
475       solid = new G4Polyhedra(sname, solParam[ << 
476                               (G4int)nplanes,  << 
477                               &((*rmax_p)[0])) << 
478     }                                             453     }
479     else                                          454     else
480     {                                             455     {
481       std::vector<G4double>* R_c = new std::ve    456       std::vector<G4double>* R_c = new std::vector<G4double>;
482       std::vector<G4double>* Z_c = new std::ve    457       std::vector<G4double>* Z_c = new std::vector<G4double>;
483       for(std::size_t ii = 0; ii < nplanes; ++ << 458       for( size_t ii = 0; ii < nplanes; ii++ )
484       {                                           459       {
485         (*R_c).push_back(solParam[4 + 2 * ii]) << 460         (*R_c).push_back( solParam[4+2*ii] );
486         (*Z_c).push_back(solParam[4 + 2 * ii + << 461         (*Z_c).push_back( solParam[4+2*ii+1] );
487       }                                           462       }
488       G4double phiTotal = solParam[1];            463       G4double phiTotal = solParam[1];
489       if(std::fabs(phiTotal - twopi) < angular << 464       if( std::fabs(phiTotal - twopi) < angularTolerance ) { phiTotal = twopi; }
490       {                                        << 465       solid = new G4Polyhedra( sname, solParam[0], phiTotal,
491         phiTotal = twopi;                      << 466                                G4int(solParam[2]), nplanes,
492       }                                        << 467                                &((*R_c)[0]), &((*Z_c)[0]));
493       solid = new G4Polyhedra(sname, solParam[ << 
494                               (G4int)nplanes,  << 
495     }                                             468     }
496   }                                               469   }
497   else if(stype == "ELLIPTICALTUBE")           << 470   else if( stype == "ELLIPTICALTUBE" )
498   {                                               471   {
499     CheckNoSolidParams(stype, 3, (G4int)solPar << 472     CheckNoSolidParams( stype, 3, solParam.size() );
500     solid = new G4EllipticalTube(sname, solPar << 473     solid = new G4EllipticalTube( sname, solParam[0], solParam[1], solParam[2]);
501   }                                               474   }
502   else if(stype == "ELLIPSOID")                << 475   else if( stype == "ELLIPSOID" )
503   {                                               476   {
504     CheckNoSolidParams(stype, 5, (G4int)solPar << 477     CheckNoSolidParams( stype, 5, solParam.size() );
505     solid = new G4Ellipsoid(sname, solParam[0] << 478     solid = new G4Ellipsoid( sname, solParam[0], solParam[1], solParam[2],
506                             solParam[3], solPa << 479                              solParam[3], solParam[4] );
507   }                                               480   }
508   else if(stype == "ELLIPTICALCONE")           << 481   else if( stype == "ELLIPTICALCONE" )
509   {                                               482   {
510     CheckNoSolidParams(stype, 4, (G4int)solPar << 483     CheckNoSolidParams( stype, 4, solParam.size() );
511     solid = new G4EllipticalCone(sname, solPar << 484     solid = new G4EllipticalCone( sname, solParam[0], solParam[1],
512                                  solParam[3]); << 485                                   solParam[2], solParam[3] );
513   }                                               486   }
514   else if(stype == "HYPE")                     << 487   else if( stype == "HYPE" )
515   {                                               488   {
516     CheckNoSolidParams(stype, 5, (G4int)solPar << 489     CheckNoSolidParams( stype, 5, solParam.size() );
517     solid = new G4Hype(sname, solParam[0], sol << 490     solid = new G4Hype( sname, solParam[0], solParam[1], solParam[2],
518                        solParam[3], solParam[4 << 491                         solParam[3], solParam[4] );
519   }                                               492   }
520   else if(stype == "TET")                      << 493   else if( stype == "TET" )
521   {                                               494   {
522     CheckNoSolidParams(stype, 12, (G4int)solPa << 495     CheckNoSolidParams( stype, 12, solParam.size() );
523     G4ThreeVector anchor(solParam[0], solParam    496     G4ThreeVector anchor(solParam[0], solParam[1], solParam[2]);
524     G4ThreeVector p2(solParam[3], solParam[4],    497     G4ThreeVector p2(solParam[3], solParam[4], solParam[5]);
525     G4ThreeVector p3(solParam[6], solParam[7],    498     G4ThreeVector p3(solParam[6], solParam[7], solParam[8]);
526     G4ThreeVector p4(solParam[9], solParam[10]    499     G4ThreeVector p4(solParam[9], solParam[10], solParam[11]);
527     solid = new G4Tet(sname, anchor, p2, p3, p << 500     solid = new G4Tet( sname, anchor, p2, p3, p4 );
528   }                                               501   }
529   else if(stype == "TWISTEDBOX")               << 502   else if( stype == "TWISTEDBOX" )
530   {                                               503   {
531     CheckNoSolidParams(stype, 4, (G4int)solPar << 504     CheckNoSolidParams( stype, 4, solParam.size() );
532     solid = new G4TwistedBox(sname, solParam[0 << 505     solid = new G4TwistedBox( sname, solParam[0], solParam[1],
533                              solParam[3]);     << 506                               solParam[2], solParam[3]);
534   }                                               507   }
535   else if(stype == "TWISTEDTRAP")              << 508   else if( stype == "TWISTEDTRAP" )
536   {                                               509   {
537     CheckNoSolidParams(stype, 11, (G4int)solPa << 510     CheckNoSolidParams( stype, 11, solParam.size() );
538     solid =                                    << 511     solid = new G4TwistedTrap( sname, solParam[0], solParam[1], solParam[2],
539       new G4TwistedTrap(sname, solParam[0], so << 
540                         solParam[3], solParam[    512                         solParam[3], solParam[4], solParam[5], solParam[6],
541                         solParam[7], solParam[ << 513                         solParam[7], solParam[8], solParam[9], solParam[10] );
542   }                                            << 
543   else if(stype == "TWISTEDTRD")               << 
544   {                                            << 
545     CheckNoSolidParams(stype, 6, (G4int)solPar << 
546     solid = new G4TwistedTrd(sname, solParam[0 << 
547                              solParam[3], solP << 
548   }                                               514   }
549     else if(stype == "SCALED")                 << 515   else if( stype == "TWISTEDTRD" )
550   {                                               516   {
551     const G4tgrSolidScaled* tgrSol = dynamic_c << 517     CheckNoSolidParams( stype, 6, solParam.size() );
552     if(tgrSol == nullptr)                      << 518     solid = new G4TwistedTrd( sname, solParam[0], solParam[1], solParam[2],
553     {                                          << 519                               solParam[3], solParam[4], solParam[5]);
554       G4Exception("G4tgbVolume::FindOrConstruc << 
555                   FatalException, "Invalid Sol << 
556       return nullptr;                          << 
557     }                                          << 
558     G4VSolid* sol0   = FindOrConstructG4Solid( << 
559     G4Scale3D scale  = tgrSol->GetScale3d();   << 
560     solid  = new G4ScaledSolid(sname, sol0, sc << 
561   }                                               520   }
562   else if(stype == "TWISTEDTUBS")              << 521   else if( stype == "TWISTEDTUBS" )
563   {                                               522   {
564     CheckNoSolidParams(stype, 5, (G4int)solPar << 523     CheckNoSolidParams( stype, 5, solParam.size() );
565     G4double phiTotal = solParam[4];              524     G4double phiTotal = solParam[4];
566     if(std::fabs(phiTotal - twopi) < angularTo << 525     if( std::fabs(phiTotal - twopi) < angularTolerance ) { phiTotal = twopi; }
567     {                                          << 526     solid = new G4TwistedTubs( sname, solParam[0], solParam[1], solParam[2],
568       phiTotal = twopi;                        << 527                                solParam[3], phiTotal);
569     }                                          << 528   }
570     solid = new G4TwistedTubs(sname, solParam[ << 529   else if( stype == "TESSELLATED" )
571                               solParam[3], phi << 530   {
572   }                                            << 531     G4int nFacets = G4int(solParam[0]);
573   else if(stype == "TESSELLATED")              << 532     G4int jj = 0;
574   {                                            << 533     solid = new G4TessellatedSolid(sname);
575     G4int nFacets               = G4int(solPar << 534     G4TessellatedSolid* solidTS = (G4TessellatedSolid*)(solid);
576     G4int jj                    = 0;           << 535     G4VFacet* facet=0;
577     solid                       = new G4Tessel << 536     
578     G4TessellatedSolid* solidTS = (G4Tessellat << 537     for( G4int ii = 0; ii < nFacets; ii++){
579     G4VFacet* facet             = nullptr;     << 538       G4int nPoints = G4int(solParam[jj+1]);
580                                                << 539       if( G4int(solParam.size()) < jj + nPoints*3 + 2 ) {
581     for(G4int ii = 0; ii < nFacets; ++ii)      << 540   G4String Err1 = "Too small number of parameters in tesselated solid, it should be at least "  + G4UIcommand::ConvertToString(jj + nPoints*3 + 2 );
582     {                                          << 541   G4String Err2 = " facet number " + G4UIcommand::ConvertToString(ii);
583       G4int nPoints = G4int(solParam[jj + 1]); << 542   G4String Err3 = " number of parameters is " + G4UIcommand::ConvertToString(G4int(solParam.size()));
584       if(G4int(solParam.size()) < jj + nPoints << 543   G4String ErrMessage = Err1 + Err2 + Err3 + " !";
585       {                                        << 544   G4Exception("G4tgbVolume::FindOrConstructG4Solid()",
586         G4String Err1 = "Too small number of p << 545         "InvalidSetup", FatalException, ErrMessage);
587                         "it should be at least << 546         return 0;
588                         G4UIcommand::ConvertTo << 547       }
589         G4String Err2 = " facet number " + G4U << 548       
590         G4String Err3 = " number of parameters << 549       if( nPoints == 3 ) 
591                         G4UIcommand::ConvertTo << 550       {
592         G4String ErrMessage = Err1 + Err2 + Er << 551   G4ThreeVector pt0(solParam[jj+2],solParam[jj+3],solParam[jj+4]);
593         G4Exception("G4tgbVolume::FindOrConstr << 552   G4ThreeVector vt1(solParam[jj+5],solParam[jj+6],solParam[jj+7]);
594                     FatalException, ErrMessage << 553   G4ThreeVector vt2(solParam[jj+8],solParam[jj+9],solParam[jj+10]);
595         return nullptr;                        << 554   G4FacetVertexType vertexType = ABSOLUTE;
596       }                                        << 555   if( solParam[jj+11] == 0 ) 
597                                                << 556   {
598       if(nPoints == 3)                         << 557     vertexType = ABSOLUTE;
599       {                                        << 558   } 
600         G4ThreeVector pt0(solParam[jj + 2], so << 559   else if( solParam[jj+11] == 1 )  
601         G4ThreeVector vt1(solParam[jj + 5], so << 560   {
602         G4ThreeVector vt2(solParam[jj + 8], so << 561     vertexType = RELATIVE;
603                           solParam[jj + 10]);  << 562   } 
604         G4FacetVertexType vertexType = ABSOLUT << 563   else 
605         if(solParam[jj + 11] == 0)             << 564   {
606         {                                      << 565     G4String Err1 = "Wrong number of vertex type in tesselated solid, it should be 0 =ABSOLUTE) or 1 (=RELATIVE)";
607           vertexType = ABSOLUTE;               << 566     G4String Err2 = " facet number " + G4UIcommand::ConvertToString(G4int(ii));
608         }                                      << 567     G4String Err3 = " vertex type is " + G4UIcommand::ConvertToString(solParam[jj+11]);
609         else if(solParam[jj + 11] == 1)        << 568     G4String ErrMessage = Err1 + Err2 + Err3 + " !";
610         {                                      << 569     G4Exception("G4tgbVolume::FindOrConstructG4Solid()",
611           vertexType = RELATIVE;               << 570           "InvalidSetup", FatalException, ErrMessage);
612         }                                      << 571           return 0;
613         else                                   << 572   }
614         {                                      << 573   facet = new G4TriangularFacet( pt0, vt1, vt2, vertexType );
615           G4String Err1 = "Wrong number of ver << 574       } 
616                           "should be 0 =ABSOLU << 575       else if( nPoints == 4 ) 
617           G4String Err2 =                      << 576       {
618             " facet number " + G4UIcommand::Co << 577   G4ThreeVector pt0(solParam[jj+2],solParam[jj+3],solParam[jj+4]);
619           G4String Err3 = " vertex type is " + << 578   G4ThreeVector vt1(solParam[jj+5],solParam[jj+6],solParam[jj+7]);
620                           G4UIcommand::Convert << 579   G4ThreeVector vt2(solParam[jj+8],solParam[jj+9],solParam[jj+10]);
621           G4String ErrMessage = Err1 + Err2 +  << 580   G4ThreeVector vt3(solParam[jj+11],solParam[jj+12],solParam[jj+13]);
622           G4Exception("G4tgbVolume::FindOrCons << 581   G4FacetVertexType vertexType = ABSOLUTE;
623                       FatalException, ErrMessa << 582   if( solParam[jj+14] == 0 ) 
624           return nullptr;                      << 583   {
625         }                                      << 584     vertexType = ABSOLUTE;
626         facet = new G4TriangularFacet(pt0, vt1 << 585   }
627       }                                        << 586   else if( solParam[jj+14] == 1 )
628       else if(nPoints == 4)                    << 587   {
629       {                                        << 588     vertexType = RELATIVE;
630         G4ThreeVector pt0(solParam[jj + 2], so << 589   } 
631         G4ThreeVector vt1(solParam[jj + 5], so << 590   else 
632         G4ThreeVector vt2(solParam[jj + 8], so << 591   {
633                           solParam[jj + 10]);  << 592     G4String Err1 = "Wrong number of vertex type in tesselated solid, it should be 0 =ABSOLUTE) or 1 (=RELATIVE)";
634         G4ThreeVector vt3(solParam[jj + 11], s << 593     G4String Err2 = " facet number " + G4UIcommand::ConvertToString(G4int(ii));
635                           solParam[jj + 13]);  << 594     G4String Err3 = " vertex type is " + G4UIcommand::ConvertToString(solParam[jj+14]);
636         G4FacetVertexType vertexType = ABSOLUT << 595     G4String ErrMessage = Err1 + Err2 + Err3 + " !";
637         if(solParam[jj + 14] == 0)             << 596     G4Exception("G4tgbVolume::FindOrConstructG4Solid()",
638         {                                      << 597           "InvalidSetup", FatalException, ErrMessage);
639           vertexType = ABSOLUTE;               << 598           return 0;
640         }                                      << 599   }
641         else if(solParam[jj + 14] == 1)        << 600   facet = new G4QuadrangularFacet( pt0, vt1, vt2, vt3, vertexType );
642         {                                      << 601       } 
643           vertexType = RELATIVE;               << 602       else 
644         }                                      << 603       {
645         else                                   << 604   G4String Err1 = "Wrong number of points in tesselated solid, it should be 3 or 4";
646         {                                      << 605   G4String Err2 = " facet number " + G4UIcommand::ConvertToString(G4int(ii));
647           G4String Err1 = "Wrong number of ver << 606   G4String Err3 = " number of points is " + G4UIcommand::ConvertToString(G4int(nPoints));
648                           "should be 0 =ABSOLU << 607   G4String ErrMessage = Err1 + Err2 + Err3 + " !";
649           G4String Err2 =                      << 608   G4Exception("G4tgbVolume::FindOrConstructG4Solid()",
650             " facet number " + G4UIcommand::Co << 609         "InvalidSetup", FatalException, ErrMessage);
651           G4String Err3 = " vertex type is " + << 610         return 0;
652                           G4UIcommand::Convert << 611       }
653           G4String ErrMessage = Err1 + Err2 +  << 612       
654           G4Exception("G4tgbVolume::FindOrCons << 613       solidTS->AddFacet( facet );
655                       FatalException, ErrMessa << 614       jj += nPoints*3 + 2;
656           return nullptr;                      << 615     }
657         }                                      << 616     
658         facet = new G4QuadrangularFacet(pt0, v << 617   }  
659       }                                        << 618   else if( stype == "EXTRUDED" ) 
660       else                                     << 
661       {                                        << 
662         G4String Err1 =                        << 
663           "Wrong number of points in tesselate << 
664         G4String Err2 =                        << 
665           " facet number " + G4UIcommand::Conv << 
666         G4String Err3 = " number of points is  << 
667                         G4UIcommand::ConvertTo << 
668         G4String ErrMessage = Err1 + Err2 + Er << 
669         G4Exception("G4tgbVolume::FindOrConstr << 
670                     FatalException, ErrMessage << 
671         return nullptr;                        << 
672       }                                        << 
673                                                << 
674       solidTS->AddFacet(facet);                << 
675       jj += nPoints * 3 + 2;                   << 
676     }                                          << 
677   }                                            << 
678   else if(stype == "EXTRUDED")                 << 
679   {                                               619   {
680     std::vector<G4TwoVector> polygonList;         620     std::vector<G4TwoVector> polygonList;
681     std::vector<G4ExtrudedSolid::ZSection> zse    621     std::vector<G4ExtrudedSolid::ZSection> zsectionList;
682     G4int nPolygons = G4int(solParam[0]);         622     G4int nPolygons = G4int(solParam[0]);
683     G4int ii        = 1;                       << 623     G4int ii = 1;
684     G4int nMax      = nPolygons * 2 + 1;       << 624     G4int nMax = nPolygons*2+1;
685     for(; ii < nMax; ii += 2)                  << 625     for( ;ii < nMax; ii+=2 )
686     {                                             626     {
687       polygonList.push_back(G4TwoVector(solPar << 627       polygonList.push_back( G4TwoVector(solParam[ii],solParam[ii+1]) );
688     }                                             628     }
689     G4int nZSections = G4int(solParam[ii]);       629     G4int nZSections = G4int(solParam[ii]);
690     nMax             = nPolygons * 2 + nZSecti << 630     nMax = nPolygons*2 + nZSections*4 + 2; 
691     ++ii;                                      << 631     ii++;
692     for(; ii < nMax; ii += 4)                  << 632     for( ; ii < nMax; ii+=4 )
693     {                                             633     {
694       G4TwoVector offset(solParam[ii + 1], sol << 634       G4TwoVector offset(solParam[ii+1],solParam[ii+2]);
695       zsectionList.push_back(                  << 635       zsectionList.push_back( G4ExtrudedSolid::ZSection(solParam[ii],offset,solParam[ii+3]) );
696         G4ExtrudedSolid::ZSection(solParam[ii] << 
697     }                                             636     }
698     solid = new G4ExtrudedSolid(sname, polygon << 637     solid = new G4ExtrudedSolid( sname, polygonList, zsectionList );
                                                   >> 638     
699   }                                               639   }
700   else if(stype.substr(0, 7) == "Boolean")     << 640   else if( stype.substr(0,7) == "Boolean" )
701   {                                               641   {
702     const G4tgrSolidBoolean* solb = dynamic_ca    642     const G4tgrSolidBoolean* solb = dynamic_cast<const G4tgrSolidBoolean*>(sol);
703     if(solb == nullptr)                        << 643     if (!solb)
704     {                                             644     {
705       G4Exception("G4tgbVolume::FindOrConstruc << 645       G4Exception("G4tgbVolume::FindOrConstructG4Solid()",
706                   FatalException, "Invalid Sol << 646                   "InvalidSetup", FatalException, "Invalid Solid pointer");
707       return nullptr;                          << 647       return 0;
708     }                                          << 648     }
709     G4VSolid* sol1 = FindOrConstructG4Solid(so << 649     G4VSolid* sol1 = FindOrConstructG4Solid( solb->GetSolid(0));
710     G4VSolid* sol2 = FindOrConstructG4Solid(so << 650     G4VSolid* sol2 = FindOrConstructG4Solid( solb->GetSolid(1));
711     G4RotationMatrix* relRotMat =              << 651     G4RotationMatrix* relRotMat = G4tgbRotationMatrixMgr::GetInstance()
712       G4tgbRotationMatrixMgr::GetInstance()->F << 652       ->FindOrBuildG4RotMatrix( sol->GetRelativeRotMatName() );
713         sol->GetRelativeRotMatName());         << 
714     G4ThreeVector relPlace = solb->GetRelative    653     G4ThreeVector relPlace = solb->GetRelativePlace();
715                                                   654 
716     if(stype == "Boolean_UNION")               << 655     if( stype == "Boolean_UNION" )
717     {                                             656     {
718       solid = new G4UnionSolid(sname, sol1, so << 657       solid = new G4UnionSolid( sname, sol1, sol2, relRotMat, relPlace );
719     }                                             658     }
720     else if(stype == "Boolean_SUBTRACTION")    << 659     else if( stype == "Boolean_SUBTRACTION" )
721     {                                             660     {
722       solid = new G4SubtractionSolid(sname, so << 661       solid = new G4SubtractionSolid( sname, sol1, sol2, relRotMat, relPlace );
723     }                                             662     }
724     else if(stype == "Boolean_INTERSECTION")   << 663     else if( stype == "Boolean_INTERSECTION" )
725     {                                             664     {
726       solid = new G4IntersectionSolid(sname, s << 665       solid = new G4IntersectionSolid( sname, sol1, sol2, relRotMat, relPlace );
727     }                                             666     }
728     else                                          667     else
729     {                                             668     {
730       G4String ErrMessage = "Unknown Boolean t    669       G4String ErrMessage = "Unknown Boolean type " + stype;
731       G4Exception("G4tgbVolume::FindOrConstruc << 670       G4Exception("G4tgbVolume::FindOrConstructG4Solid()",
732                   FatalException, ErrMessage); << 671                   "InvalidSetup", FatalException, ErrMessage);
733       return nullptr;                          << 672       return 0;
734     }                                          << 
735   }                                            << 
736   else if(stype == "MULTIUNION")               << 
737   {                                            << 
738     const G4tgrSolidMultiUnion* tgrSol = dynam << 
739     if(tgrSol == nullptr)                      << 
740     {                                          << 
741       G4Exception("G4tgbVolume::FindOrConstruc << 
742                   FatalException, "Invalid Sol << 
743       return nullptr;                          << 
744     }                                          << 
745                                                << 
746     G4int nsol =  tgrSol->GetNSolid();         << 
747     G4VSolid*     soli;                        << 
748     G4Transform3D tri;                         << 
749     G4MultiUnion* solidu = new G4MultiUnion(sn << 
750                                                << 
751     for (G4int i=0; i<nsol; ++i)               << 
752     {                                          << 
753       soli = FindOrConstructG4Solid(tgrSol->Ge << 
754       tri  = tgrSol->GetTransformation(i);     << 
755       solidu->AddNode(*soli, tri);             << 
756     }                                             673     }
757     solidu->Voxelize();                        << 
758     solid = dynamic_cast<G4VSolid*>(solidu);   << 
759   }                                               674   }
760   else                                            675   else
761   {                                               676   {
762     G4String ErrMessage =                      << 677     G4String ErrMessage = "Solids of type " + stype
763       "Solids of type " + stype + " not implem << 678                         + " not implemented yet, sorry...";
764     G4Exception("G4tgbVolume::FindOrConstructG    679     G4Exception("G4tgbVolume::FindOrConstructG4Solid()", "NotImplemented",
765                 FatalException, ErrMessage);      680                 FatalException, ErrMessage);
766     return nullptr;                            << 681     return 0;
767   }                                            << 682   } 
768                                                << 683   
769 #ifdef G4VERBOSE                                  684 #ifdef G4VERBOSE
770   if(G4tgrMessenger::GetVerboseLevel() >= 2)   << 685   if( G4tgrMessenger::GetVerboseLevel() >= 2 )
771   {                                               686   {
772     G4cout << " G4tgbVolume::FindOrConstructG4    687     G4cout << " G4tgbVolume::FindOrConstructG4Solid()" << G4endl
773            << "   Created solid " << sname <<  << 688            << "   Created solid " << sname
774            << solid->GetEntityType() << G4endl << 689            << " of type " << solid->GetEntityType() << G4endl; 
775   }                                               690   }
776 #endif                                            691 #endif
777                                                   692 
778 #ifdef G4VERBOSE                                  693 #ifdef G4VERBOSE
779   if(G4tgrMessenger::GetVerboseLevel() >= 1)   << 694     if( G4tgrMessenger::GetVerboseLevel() >= 1 )
780   {                                            << 695     {
781     G4cout << " Constructing new G4Solid: " << << 696       G4cout << " Constructing new G4Solid: " 
782   }                                            << 697              << *solid << G4endl;
                                                   >> 698     }
783 #endif                                            699 #endif
784                                                << 700  
785   return solid;                                   701   return solid;
786 }                                                 702 }
787                                                   703 
788 // ------------------------------------------- << 704 //-------------------------------------------------------------------
789 void G4tgbVolume::CheckNoSolidParams(const G4S << 705 void G4tgbVolume::CheckNoSolidParams( const G4String& solidType,
790                                      const uns << 706                                       const unsigned int NoParamExpected,
791                                      const uns << 707                                       const unsigned int NoParam )
792 {                                                 708 {
793   if(NoParamExpected != NoParam)               << 709   if( NoParamExpected != NoParam )
794   {                                               710   {
795     G4String Err1 = "Solid type " + solidType     711     G4String Err1 = "Solid type " + solidType + " should have ";
796     G4String Err2 =                            << 712     G4String Err2 = G4UIcommand::ConvertToString(G4int(NoParamExpected))
797       G4UIcommand::ConvertToString(G4int(NoPar << 713                   + " parameters,\n";
798     G4String Err3 =                            << 714     G4String Err3 = "and it has "
799       "and it has " + G4UIcommand::ConvertToSt << 715                   + G4UIcommand::ConvertToString(G4int(NoParam));
800     G4String ErrMessage = Err1 + Err2 + Err3 +    716     G4String ErrMessage = Err1 + Err2 + Err3 + " !";
801     G4Exception("G4tgbVolume::CheckNoSolidPara    717     G4Exception("G4tgbVolume::CheckNoSolidParams()", "InvalidSetup",
802                 FatalException, ErrMessage);      718                 FatalException, ErrMessage);
803   }                                               719   }
804 }                                                 720 }
805                                                   721 
806 // ------------------------------------------- << 722 
807 G4LogicalVolume* G4tgbVolume::ConstructG4LogVo << 723 //-------------------------------------------------------------------
                                                   >> 724 G4LogicalVolume* G4tgbVolume::ConstructG4LogVol( const G4VSolid* solid )
808 {                                                 725 {
809   G4LogicalVolume* logvol;                        726   G4LogicalVolume* logvol;
810                                                   727 
811 #ifdef G4VERBOSE                                  728 #ifdef G4VERBOSE
812   if(G4tgrMessenger::GetVerboseLevel() >= 2)   << 729   if( G4tgrMessenger::GetVerboseLevel() >= 2 )
813   {                                               730   {
814     G4cout << " G4tgbVolume::ConstructG4LogVol    731     G4cout << " G4tgbVolume::ConstructG4LogVol() - " << GetName() << G4endl;
815   }                                               732   }
816 #endif                                            733 #endif
817                                                   734 
818   //----------- Get the material first            735   //----------- Get the material first
819   G4Material* mate = G4tgbMaterialMgr::GetInst << 736   G4Material* mate = G4tgbMaterialMgr::GetInstance()
820     theTgrVolume->GetMaterialName());          << 737               ->FindOrBuildG4Material( theTgrVolume->GetMaterialName() );
821   if(mate == nullptr)                          << 738   if( mate == 0 )
822   {                                            << 739   {
823     G4String ErrMessage = "Material not found  << 740     G4String ErrMessage = "Material not found "
824                           theTgrVolume->GetMat << 741                         + theTgrVolume->GetMaterialName()
825                           GetName() + ".";     << 742                         + " for volume " + GetName() + ".";
826     G4Exception("G4tgbVolume::ConstructG4LogVo    743     G4Exception("G4tgbVolume::ConstructG4LogVol()", "InvalidSetup",
827                 FatalException, ErrMessage);      744                 FatalException, ErrMessage);
828   }                                               745   }
829 #ifdef G4VERBOSE                                  746 #ifdef G4VERBOSE
830   if(G4tgrMessenger::GetVerboseLevel() >= 2)   << 747   if( G4tgrMessenger::GetVerboseLevel() >= 2 )
831   {                                               748   {
832     G4cout << " G4tgbVolume::ConstructG4LogVol    749     G4cout << " G4tgbVolume::ConstructG4LogVol() -"
833            << " Material constructed: " << mat << 750            << " Material constructed: " << mate->GetName() << G4endl; 
834   }                                               751   }
835 #endif                                            752 #endif
836                                                << 753  
837   //---------- Construct the LV                   754   //---------- Construct the LV
838   logvol = new G4LogicalVolume(const_cast<G4VS << 755   logvol = new G4LogicalVolume( const_cast<G4VSolid*>(solid),
839                                const_cast<G4Ma << 756                                 const_cast<G4Material*>(mate), GetName() );
840                                                   757 
841 #ifdef G4VERBOSE                                  758 #ifdef G4VERBOSE
842   if(G4tgrMessenger::GetVerboseLevel() >= 1)   << 759     if( G4tgrMessenger::GetVerboseLevel() >= 1 )
843   {                                            << 760     {
844     G4cout << " Constructing new G4LogicalVolu << 761       G4cout << " Constructing new G4LogicalVolume: " 
845            << " mate " << mate->GetName() << G << 762              << logvol->GetName() << " mate " << mate->GetName() << G4endl;
846   }                                            << 763     }
847 #endif                                            764 #endif
848                                                << 765  
849   //---------- Set visibility and colour          766   //---------- Set visibility and colour
850   if(!GetVisibility() || GetColour()[0] != -1) << 767   if( !GetVisibility() || GetColour()[0] != -1 )
851   {                                               768   {
852     G4VisAttributes* visAtt = new G4VisAttribu    769     G4VisAttributes* visAtt = new G4VisAttributes();
853 #ifdef G4VERBOSE                                  770 #ifdef G4VERBOSE
854     if(G4tgrMessenger::GetVerboseLevel() >= 1) << 771     if( G4tgrMessenger::GetVerboseLevel() >= 1 )
855     {                                             772     {
856       G4cout << " Constructing new G4VisAttrib << 773       G4cout << " Constructing new G4VisAttributes: " 
                                                   >> 774              << *visAtt << G4endl;
857     }                                             775     }
858 #endif                                            776 #endif
859                                                << 777  
860     if(!GetVisibility())                       << 778     if( !GetVisibility() )
861     {                                             779     {
862       visAtt->SetVisibility(GetVisibility());  << 780       visAtt->SetVisibility( GetVisibility() );
863     }                                             781     }
864     else if(GetColour()[0] != -1)              << 782     else if( GetColour()[0] != -1 )
865     {                                             783     {
866       // this else should not be necessary, be    784       // this else should not be necessary, because if the visibility
867       // is set to off, colour should have no     785       // is set to off, colour should have no effect. But it does not
868       // work: if you set colour and vis off,     786       // work: if you set colour and vis off, it is visualized!?!?!?
869                                                   787 
870       const G4double* col = GetColour();          788       const G4double* col = GetColour();
871       if(col[3] == -1.)                        << 789       if( col[3] == -1. )
872       {                                           790       {
873         visAtt->SetColour(G4Colour(col[0], col << 791         visAtt->SetColour( G4Colour(col[0],col[1],col[2]));
874       }                                           792       }
875       else                                        793       else
876       {                                           794       {
877         visAtt->SetColour(G4Colour(col[0], col << 795         visAtt->SetColour( G4Colour(col[0],col[1],col[2],col[3]));
878       }                                           796       }
879     }                                             797     }
880     logvol->SetVisAttributes(visAtt);             798     logvol->SetVisAttributes(visAtt);
881   }                                               799   }
882                                                   800 
883 #ifdef G4VERBOSE                                  801 #ifdef G4VERBOSE
884   if(G4tgrMessenger::GetVerboseLevel() >= 2)   << 802   if( G4tgrMessenger::GetVerboseLevel() >= 2 )
885   {                                               803   {
886     G4cout << " G4tgbVolume::ConstructG4LogVol    804     G4cout << " G4tgbVolume::ConstructG4LogVol() -"
887            << " Created logical volume: " << G    805            << " Created logical volume: " << GetName() << G4endl;
888   }                                               806   }
889 #endif                                            807 #endif
890                                                   808 
891   return logvol;                                  809   return logvol;
892 }                                                 810 }
893                                                   811 
894 // ------------------------------------------- << 812 
                                                   >> 813 //-------------------------------------------------------------------
895 G4VPhysicalVolume*                                814 G4VPhysicalVolume*
896 G4tgbVolume::ConstructG4PhysVol(const G4tgrPla << 815 G4tgbVolume::ConstructG4PhysVol( const G4tgrPlace* place,
897                                 const G4Logica << 816                                  const G4LogicalVolume* currentLV,
898                                 const G4Logica << 817                                  const G4LogicalVolume* parentLV )
899 {                                                 818 {
900   G4VPhysicalVolume* physvol = nullptr;        << 819   G4VPhysicalVolume* physvol = 0;
901   G4int copyNo;                                   820   G4int copyNo;
902                                                << 821   
903   //----- Case of placement of top volume         822   //----- Case of placement of top volume
904   if(place == nullptr)                         << 823   if( place == 0 )
905   {                                               824   {
906 #ifdef G4VERBOSE                                  825 #ifdef G4VERBOSE
907     if(G4tgrMessenger::GetVerboseLevel() >= 2) << 826     if( G4tgrMessenger::GetVerboseLevel() >= 2 )
908     {                                             827     {
909       G4cout << " G4tgbVolume::ConstructG4Phys << 828       G4cout << " G4tgbVolume::ConstructG4PhysVol() - World: "
910              << G4endl;                        << 829              << GetName() << G4endl;
911     }                                             830     }
912 #endif                                            831 #endif
913     physvol = new G4PVPlacement(               << 832     physvol = new G4PVPlacement(0, G4ThreeVector(),
914       nullptr, G4ThreeVector(), const_cast<G4L << 833                                 const_cast<G4LogicalVolume*>(currentLV),
915       GetName(), 0, false, 0, theTgrVolume->Ge << 834                                 GetName(), 0, false, 0, 
                                                   >> 835         theTgrVolume->GetCheckOverlaps());
916 #ifdef G4VERBOSE                                  836 #ifdef G4VERBOSE
917     if(G4tgrMessenger::GetVerboseLevel() >= 1) << 837     if( G4tgrMessenger::GetVerboseLevel() >= 1 )
918     {                                             838     {
919       G4cout << " Constructing new : G4PVPlace << 839       G4cout << " Constructing new : G4PVPlacement " 
920              << G4endl;                        << 840              << physvol->GetName() << G4endl;
921     }                                             841     }
922 #endif                                            842 #endif
923   }                                               843   }
924   else                                            844   else
925   {                                            << 845   { 
926     copyNo = place->GetCopyNo();                  846     copyNo = place->GetCopyNo();
927                                                   847 
928 #ifdef G4VERBOSE                                  848 #ifdef G4VERBOSE
929     if(G4tgrMessenger::GetVerboseLevel() >= 2) << 849     if( G4tgrMessenger::GetVerboseLevel() >= 2 )
930     {                                             850     {
931       G4cout << " G4tgbVolume::ConstructG4Phys    851       G4cout << " G4tgbVolume::ConstructG4PhysVol() - " << GetName() << G4endl
932              << "   inside " << parentLV->GetN    852              << "   inside " << parentLV->GetName() << " copy No: " << copyNo
933              << " of type= " << theTgrVolume->    853              << " of type= " << theTgrVolume->GetType() << G4endl
934              << "   placement type= " << place    854              << "   placement type= " << place->GetType() << G4endl;
935     }                                             855     }
936 #endif                                            856 #endif
937                                                << 857     
938     if(theTgrVolume->GetType() == "VOLSimple") << 858     if( theTgrVolume->GetType() == "VOLSimple" )
939     {                                             859     {
940       //----- Get placement                       860       //----- Get placement
941 #ifdef G4VERBOSE                                  861 #ifdef G4VERBOSE
942       if(G4tgrMessenger::GetVerboseLevel() >=  << 862       if( G4tgrMessenger::GetVerboseLevel() >= 2 )
943       {                                           863       {
944         G4cout << " G4tgbVolume::ConstructG4Ph    864         G4cout << " G4tgbVolume::ConstructG4PhysVol() - Placement type = "
945                << place->GetType() << G4endl;     865                << place->GetType() << G4endl;
946       }                                           866       }
947 #endif                                            867 #endif
948                                                << 868       
949       //--------------- If it is  G4tgrPlaceSi    869       //--------------- If it is  G4tgrPlaceSimple
950       if(place->GetType() == "PlaceSimple")    << 870       if( place->GetType() == "PlaceSimple" )
951       {                                           871       {
952         //----- Get rotation matrix               872         //----- Get rotation matrix
953         G4tgrPlaceSimple* placeSimple = (G4tgr << 873         G4tgrPlaceSimple* placeSimple = (G4tgrPlaceSimple*)place; 
954         G4String rmName               = placeS << 874   G4String rmName = placeSimple->GetRotMatName();
955                                                   875 
956         G4RotationMatrix* rotmat =             << 876         G4RotationMatrix* rotmat = G4tgbRotationMatrixMgr::GetInstance()
957           G4tgbRotationMatrixMgr::GetInstance( << 877                                  ->FindOrBuildG4RotMatrix( rmName );
958         //----- Place volume in mother            878         //----- Place volume in mother
959         G4double check =                       << 879         G4double check = (rotmat->colX().cross(rotmat->colY()))*rotmat->colZ();
960           (rotmat->colX().cross(rotmat->colY() << 
961         G4double tol = 1.0e-3;                    880         G4double tol = 1.0e-3;
962         //---- Check that matrix is ortogonal     881         //---- Check that matrix is ortogonal
963         if(1 - std::abs(check) > tol)          << 882         if (1-std::abs(check)>tol)
964         {                                         883         {
965           G4cerr << " Matrix : " << rmName <<  << 884           G4cerr << " Matrix : " << rmName << " " << rotmat->colX()
966                  << rotmat->colY() << " " << r << 885                  << " " << rotmat->colY() << " " << rotmat->colZ() << G4endl
967                  << " product x X y * z = " <<    886                  << " product x X y * z = " << check << " x X y "
968                  << rotmat->colX().cross(rotma    887                  << rotmat->colX().cross(rotmat->colY()) << G4endl;
969           G4String ErrMessage = "Rotation is n    888           G4String ErrMessage = "Rotation is not ortogonal " + rmName + " !";
970           G4Exception("G4tgbVolume::ConstructG << 889           G4Exception("G4tgbVolume::ConstructG4PhysVol()",
971                       FatalException, ErrMessa << 890                       "InvalidSetup", FatalException, ErrMessage);
972           //---- Check if it is reflection        891           //---- Check if it is reflection
973         }                                         892         }
974         else if(1 + check <= tol)              << 893         else if (1+check<=tol)
975         {                                         894         {
976           G4Translate3D transl = place->GetPla    895           G4Translate3D transl = place->GetPlacement();
977           G4Transform3D trfrm  = transl * G4Ro    896           G4Transform3D trfrm  = transl * G4Rotate3D(*rotmat);
978           physvol =                            << 897           physvol = (G4ReflectionFactory::Instance()->Place(trfrm, GetName(),
979             (G4ReflectionFactory::Instance()-> << 898                      const_cast<G4LogicalVolume*>(currentLV),
980                trfrm, GetName(), const_cast<G4 << 899                      const_cast<G4LogicalVolume*>(parentLV),
981                const_cast<G4LogicalVolume*>(pa << 900                      false, copyNo, false )).first;
982               .first;                          << 
983         }                                         901         }
984         else                                      902         else
985         {                                         903         {
986 #ifdef G4VERBOSE                                  904 #ifdef G4VERBOSE
987           if(G4tgrMessenger::GetVerboseLevel() << 905           if( G4tgrMessenger::GetVerboseLevel() >= 1 )
988           {                                       906           {
989             G4cout << "Construction new G4VPhy    907             G4cout << "Construction new G4VPhysicalVolume"
990                    << " through G4ReflectionFa << 908        << " through G4ReflectionFactory " << GetName() 
991                    << " in volume " << parentL << 909        << " in volume " << parentLV->GetName() 
992                    << copyNo << " position " < << 910        << " copyNo " << copyNo 
993                    << rotmat->colX() << " " << << 911        << " position " << place->GetPlacement() 
994                    << rotmat->colZ() << G4endl << 912                    << " ROT " << rotmat->colX() 
                                                   >> 913                    << " " << rotmat->colY() 
                                                   >> 914                    << " " << rotmat->colZ() << G4endl;
995           }                                       915           }
996 #endif                                            916 #endif
997           physvol =                            << 917           physvol = new G4PVPlacement( rotmat, place->GetPlacement(),
998             new G4PVPlacement(rotmat, place->G << 918                                        const_cast<G4LogicalVolume*>(currentLV),
999                               const_cast<G4Log << 919                                        GetName(),
1000                               GetName(), cons << 920                                        const_cast<G4LogicalVolume*>(parentLV),
1001                               false, copyNo,  << 921                                        false, copyNo, 
                                                   >> 922                theTgrVolume->GetCheckOverlaps());
1002         }                                        923         }
1003                                               << 924         
1004         //--------------- If it is G4tgrPlace    925         //--------------- If it is G4tgrPlaceParam
1005       }                                          926       }
1006       else if(place->GetType() == "PlaceParam << 927       else if( place->GetType() == "PlaceParam" )
1007       {                                          928       {
1008         G4tgrPlaceParameterisation* dp = (G4t << 929   G4tgrPlaceParameterisation* dp = (G4tgrPlaceParameterisation*)(place);
1009                                                  930 
1010         //----- See what parameterisation typ    931         //----- See what parameterisation type
1011 #ifdef G4VERBOSE                                 932 #ifdef G4VERBOSE
1012         if(G4tgrMessenger::GetVerboseLevel()  << 933         if( G4tgrMessenger::GetVerboseLevel() >= 2 )
1013         {                                        934         {
1014           G4cout << " G4tgbVolume::ConstructG    935           G4cout << " G4tgbVolume::ConstructG4PhysVol() -" << G4endl
1015                  << "   param: " << GetName() << 936                  << "   param: " << GetName() << " in " <<  parentLV->GetName()
1016                  << " param type= " << dp->Ge    937                  << " param type= " << dp->GetParamType() << G4endl;
1017         }                                        938         }
1018 #endif                                           939 #endif
1019                                               << 940         
1020         G4tgbPlaceParameterisation* param = n << 941         G4tgbPlaceParameterisation * param=0;
1021                                               << 942         
1022         if((dp->GetParamType() == "CIRCLE") | << 943         if( (dp->GetParamType() == "CIRCLE")
1023            (dp->GetParamType() == "CIRCLE_XY" << 944          || (dp->GetParamType() == "CIRCLE_XY")
1024            (dp->GetParamType() == "CIRCLE_XZ" << 945          || (dp->GetParamType() == "CIRCLE_XZ")
1025            (dp->GetParamType() == "CIRCLE_YZ" << 946          || (dp->GetParamType() == "CIRCLE_YZ") )
1026         {                                     << 947         { 
1027           param = new G4tgbPlaceParamCircle(d    948           param = new G4tgbPlaceParamCircle(dp);
1028         }                                     << 949           
1029         else if((dp->GetParamType() == "LINEA << 950         } 
1030                 (dp->GetParamType() == "LINEA << 951   else if( (dp->GetParamType() == "LINEAR")
1031                 (dp->GetParamType() == "LINEA << 952                 || (dp->GetParamType() == "LINEAR_X")
1032                 (dp->GetParamType() == "LINEA << 953                 || (dp->GetParamType() == "LINEAR_Y")
1033         {                                     << 954                 || (dp->GetParamType() == "LINEAR_Z") )
                                                   >> 955         {   
1034           param = new G4tgbPlaceParamLinear(d    956           param = new G4tgbPlaceParamLinear(dp);
1035         }                                     << 957           
1036         else if((dp->GetParamType() == "SQUAR << 958         } 
1037                 (dp->GetParamType() == "SQUAR << 959   else if( (dp->GetParamType() == "SQUARE")
1038                 (dp->GetParamType() == "SQUAR << 960                 || (dp->GetParamType() == "SQUARE_XY")
1039                 (dp->GetParamType() == "SQUAR << 961                 || (dp->GetParamType() == "SQUARE_XZ")
                                                   >> 962                 || (dp->GetParamType() == "SQUARE_YZ") )
1040         {                                        963         {
1041           param = new G4tgbPlaceParamSquare(d    964           param = new G4tgbPlaceParamSquare(dp);
1042         }                                        965         }
1043         else                                     966         else
1044         {                                        967         {
1045           G4String ErrMessage = "Parameterisa << 968           G4String ErrMessage = "Parameterisation has wrong type, TYPE: "
1046                                 G4String(dp-> << 969                               + G4String(dp->GetParamType()) + " !";
1047           G4Exception("G4tgbVolume::Construct    970           G4Exception("G4tgbVolume::ConstructG4PhysVol", "WrongArgument",
1048                       FatalException, ErrMess    971                       FatalException, ErrMessage);
1049           return nullptr;                     << 972           return 0;
1050         }                                        973         }
1051 #ifdef G4VERBOSE                                 974 #ifdef G4VERBOSE
1052         if(G4tgrMessenger::GetVerboseLevel()  << 975         if( G4tgrMessenger::GetVerboseLevel() >= 1 )
1053         {                                        976         {
1054           G4cout << " G4tgbVolume::ConstructG    977           G4cout << " G4tgbVolume::ConstructG4PhysVol() -" << G4endl
1055                  << "   New G4PVParameterised    978                  << "   New G4PVParameterised: " << GetName() << " vol "
1056                  << currentLV->GetName() << "    979                  << currentLV->GetName() << " in vol " << parentLV->GetName()
1057                  << " axis " << param->GetAxi    980                  << " axis " << param->GetAxis() << " nCopies "
1058                  << param->GetNCopies() << G4    981                  << param->GetNCopies() << G4endl;
1059         }                                        982         }
1060 #endif                                           983 #endif
1061         physvol = new G4PVParameterised(      << 984         physvol = new G4PVParameterised(GetName(),
1062           GetName(), const_cast<G4LogicalVolu << 985                                         const_cast<G4LogicalVolume*>(currentLV),
1063           const_cast<G4LogicalVolume*>(parent << 986                                         const_cast<G4LogicalVolume*>(parentLV),
1064           param->GetNCopies(), param);        << 987                                         EAxis(param->GetAxis()),
                                                   >> 988                                         param->GetNCopies(), param);
1065 #ifdef G4VERBOSE                                 989 #ifdef G4VERBOSE
1066         if(G4tgrMessenger::GetVerboseLevel()  << 990     if( G4tgrMessenger::GetVerboseLevel() >= 1 )
1067         {                                     << 991     {
1068           G4cout << " Constructing new G4PVPa << 992       G4cout << " Constructing new G4PVParameterised: " 
1069                  << physvol->GetName() << " i << 993              << physvol->GetName() << " in volume " << parentLV->GetName() 
1070                  << " N copies " << param->Ge << 994        << " N copies " << param->GetNCopies() 
1071                  << param->GetAxis() << G4end << 995        << " axis " << param->GetAxis() << G4endl;
1072         }                                     << 996     }
1073 #endif                                           997 #endif
                                                   >> 998 
1074       }                                          999       }
1075       else if(place->GetType() == "PlaceRepli << 1000       else if( place->GetType() == "PlaceReplica" )
1076       {                                          1001       {
1077         //--------------- If it is  PlaceRepl << 1002   //--------------- If it is  PlaceReplica
1078         G4tgrPlaceDivRep* dpr = (G4tgrPlaceDi << 1003   G4tgrPlaceDivRep* dpr = (G4tgrPlaceDivRep*)place;
1079                                                  1004 
1080 #ifdef G4VERBOSE                                 1005 #ifdef G4VERBOSE
1081         if(G4tgrMessenger::GetVerboseLevel()  << 1006   if( G4tgrMessenger::GetVerboseLevel() >= 2 )
1082         {                                        1007         {
1083           G4cout << " G4tgbVolume::ConstructG << 1008     G4cout << " G4tgbVolume::ConstructG4PhysVol() -" << G4endl
1084                  << "   replica"              << 1009      << "   replica" << " " << currentLV->GetName()
1085                  << " " << currentLV->GetName << 1010      << " in " <<  parentLV->GetName() 
1086                  << " NDiv " << dpr->GetNDiv( << 1011      << " NDiv " << dpr->GetNDiv() << " Width " << dpr->GetWidth()
1087                  << " offset " << dpr->GetOff << 1012      << " offset " << dpr->GetOffset() << G4endl;
1088         }                                     << 1013   }
1089 #endif                                           1014 #endif
1090         physvol = new G4PVReplica(            << 1015   physvol = new G4PVReplica(GetName(),
1091           GetName(), const_cast<G4LogicalVolu << 1016           const_cast<G4LogicalVolume*>(currentLV),
1092           const_cast<G4LogicalVolume*>(parent << 1017           const_cast<G4LogicalVolume*>(parentLV),
1093           dpr->GetNDiv(), dpr->GetWidth(), dp << 1018           EAxis(dpr->GetAxis()), dpr->GetNDiv(),
                                                   >> 1019           dpr->GetWidth(), dpr->GetOffset());
1094 #ifdef G4VERBOSE                                 1020 #ifdef G4VERBOSE
1095         if(G4tgrMessenger::GetVerboseLevel()  << 1021     if( G4tgrMessenger::GetVerboseLevel() >= 1 )
1096         {                                     << 1022     {
1097           G4cout << " Constructing new G4PVRe << 1023       G4cout << " Constructing new G4PVReplica: " 
1098                  << " in " << parentLV->GetNa << 1024        << currentLV->GetName()
1099                  << " Width " << dpr->GetWidt << 1025        << " in " <<  parentLV->GetName() 
1100                  << dpr->GetOffset() << G4end << 1026        << " NDiv " << dpr->GetNDiv() << " Width " << dpr->GetWidth()
1101         }                                     << 1027        << " offset " << dpr->GetOffset() << G4endl;
                                                   >> 1028     }
1102 #endif                                           1029 #endif
1103       }                                          1030       }
1104     }                                            1031     }
1105     else if(theTgrVolume->GetType() == "VOLDi << 1032     else if( theTgrVolume->GetType() == "VOLDivision" )
1106     {                                            1033     {
1107       G4tgrVolumeDivision* volr  = (G4tgrVolu << 1034       G4tgrVolumeDivision* volr = (G4tgrVolumeDivision*)theTgrVolume;
1108       G4tgrPlaceDivRep* placeDiv = volr->GetP << 1035       G4tgrPlaceDivRep* placeDiv = volr->GetPlaceDivision() ;
1109       G4VSolid* solid =                       << 1036       G4VSolid* solid = BuildSolidForDivision( parentLV->GetSolid(), placeDiv->GetAxis() );
1110         BuildSolidForDivision(parentLV->GetSo << 1037       G4Material* mate = G4tgbMaterialMgr::GetInstance()
1111       G4Material* mate = G4tgbMaterialMgr::Ge << 1038                   ->FindOrBuildG4Material( theTgrVolume->GetMaterialName() );
1112         theTgrVolume->GetMaterialName());     << 1039       G4LogicalVolume* divLV = new G4LogicalVolume(solid,
1113       G4LogicalVolume* divLV =                << 1040                                                   const_cast<G4Material*>(mate),
1114         new G4LogicalVolume(solid, const_cast << 1041                GetName() );
1115 #ifdef G4VERBOSE                                 1042 #ifdef G4VERBOSE
1116       if(G4tgrMessenger::GetVerboseLevel() >= << 1043       if( G4tgrMessenger::GetVerboseLevel() >= 1 )
1117       {                                          1044       {
1118         G4cout << " Constructed new G4Logical << 1045   G4cout << " Constructed new G4LogicalVolume for division: " 
1119                << divLV->GetName() << " mate  << 1046          << divLV->GetName() << " mate " << mate->GetName() << G4endl;
1120       }                                          1047       }
1121 #endif                                           1048 #endif
1122                                               << 1049  
1123       G4DivType divType = placeDiv->GetDivTyp    1050       G4DivType divType = placeDiv->GetDivType();
1124       switch(divType)                         << 1051       switch (divType)
1125       {                                          1052       {
1126         case DivByNdiv:                       << 1053       case DivByNdiv:
1127           physvol = new G4PVDivision(GetName( << 1054   physvol = new G4PVDivision(GetName(), (G4LogicalVolume*)divLV,
1128                                      const_ca << 1055            const_cast<G4LogicalVolume*>(parentLV),
1129                                      placeDiv << 1056            placeDiv->GetAxis(), placeDiv->GetNDiv(),
1130                                      placeDiv << 1057            placeDiv->GetOffset());
1131 #ifdef G4VERBOSE                                 1058 #ifdef G4VERBOSE
1132           if(G4tgrMessenger::GetVerboseLevel( << 1059   if( G4tgrMessenger::GetVerboseLevel() >= 1 )
1133           {                                   << 1060         {
1134             G4cout << " Constructing new G4PV << 1061     G4cout << " Constructing new G4PVDivision by number of divisions: " 
1135                    << GetName() << " in " <<  << 1062      << GetName() << " in " <<  parentLV->GetName() 
1136                    << placeDiv->GetAxis() <<  << 1063      << " axis " << placeDiv->GetAxis()  
1137                    << " offset " << placeDiv- << 1064      << " Ndiv " << placeDiv->GetNDiv()
1138           }                                   << 1065      << " offset " << placeDiv->GetOffset() << G4endl;
1139 #endif                                        << 1066   }
1140           break;                              << 1067 #endif
1141         case DivByWidth:                      << 1068   break;
1142           physvol = new G4PVDivision(GetName( << 1069       case DivByWidth:
1143                                      const_ca << 1070   physvol = new G4PVDivision(GetName(), (G4LogicalVolume*)divLV,
1144                                      placeDiv << 1071            const_cast<G4LogicalVolume*>(parentLV),
1145                                      placeDiv << 1072            placeDiv->GetAxis(), placeDiv->GetWidth(),
1146 #ifdef G4VERBOSE                              << 1073            placeDiv->GetOffset());
1147           if(G4tgrMessenger::GetVerboseLevel( << 1074 #ifdef G4VERBOSE
1148           {                                   << 1075   if( G4tgrMessenger::GetVerboseLevel() >= 1 )
1149             G4cout << " Constructing new G4PV << 1076   {
1150                    << " in " << parentLV->Get << 1077     G4cout << " Constructing new G4PVDivision by width: " 
1151                    << placeDiv->GetAxis() <<  << 1078      << GetName() << " in " <<  parentLV->GetName() 
1152                    << " offset " << placeDiv- << 1079      << " axis " << placeDiv->GetAxis()  
1153           }                                   << 1080      << " width " << placeDiv->GetWidth()
1154 #endif                                        << 1081      << " offset " << placeDiv->GetOffset() << G4endl;
1155           break;                              << 1082   }
1156         case DivByNdivAndWidth:               << 1083 #endif
1157           physvol = new G4PVDivision(         << 1084   break;
1158             GetName(), (G4LogicalVolume*) div << 1085       case DivByNdivAndWidth:
1159             const_cast<G4LogicalVolume*>(pare << 1086   physvol = new G4PVDivision(GetName(), (G4LogicalVolume*)divLV,
1160             placeDiv->GetNDiv(), placeDiv->Ge << 1087            const_cast<G4LogicalVolume*>(parentLV),
1161 #ifdef G4VERBOSE                              << 1088            placeDiv->GetAxis(), placeDiv->GetNDiv(),
1162           if(G4tgrMessenger::GetVerboseLevel( << 1089            placeDiv->GetWidth(),
1163           {                                   << 1090            placeDiv->GetOffset());
1164             G4cout << " Constructing new G4PV << 1091 #ifdef G4VERBOSE
1165                    << " and number of divisio << 1092   if( G4tgrMessenger::GetVerboseLevel() >= 1 )
1166                    << parentLV->GetName() <<  << 1093   {
1167                    << " Ndiv " << placeDiv->G << 1094     G4cout << " Constructing new G4PVDivision by width"
1168                    << placeDiv->GetWidth() << << 1095      << " and number of divisions: " 
1169                    << placeDiv->GetOffset() < << 1096      << GetName() << " in " <<  parentLV->GetName() 
1170           }                                   << 1097      << " axis " << placeDiv->GetAxis()  
                                                   >> 1098      << " Ndiv " << placeDiv->GetNDiv()
                                                   >> 1099      << " width " << placeDiv->GetWidth()
                                                   >> 1100      << " offset " << placeDiv->GetOffset() << G4endl;
                                                   >> 1101   }
1171 #endif                                           1102 #endif
1172           break;                              << 1103   break;
1173       }                                          1104       }
1174     }                                            1105     }
1175     else if(theTgrVolume->GetType() == "VOLAs << 1106     else if( theTgrVolume->GetType() == "VOLAssembly" )
1176     {                                            1107     {
1177       // Define one layer as one assembly vol    1108       // Define one layer as one assembly volume
1178       G4tgrVolumeAssembly* tgrAssembly = (G4t << 1109       G4tgrVolumeAssembly * tgrAssembly = (G4tgrVolumeAssembly *)theTgrVolume;
1179                                                  1110 
1180       if(!theG4AssemblyVolume)                << 1111       if( !theG4AssemblyVolume )
1181       {                                          1112       {
1182         theG4AssemblyVolume = new G4AssemblyV    1113         theG4AssemblyVolume = new G4AssemblyVolume;
1183 #ifdef G4VERBOSE                                 1114 #ifdef G4VERBOSE
1184         if(G4tgrMessenger::GetVerboseLevel()  << 1115   if( G4tgrMessenger::GetVerboseLevel() >= 1 )
1185         {                                     << 1116     {
1186           G4cout << " Constructing new G4Asse << 1117       G4cout << " Constructing new G4AssemblyVolume: " 
1187                  << " number of assembly comp << 1118        << " number of assembly components " 
1188                  << tgrAssembly->GetNoCompone << 1119        <<  tgrAssembly->GetNoComponents() << G4endl;
1189         }                                     << 1120     }
1190 #endif                                        << 1121 #endif        
1191         G4tgbVolumeMgr* g4vmgr = G4tgbVolumeM    1122         G4tgbVolumeMgr* g4vmgr = G4tgbVolumeMgr::GetInstance();
1192         for(G4int ii = 0; ii < tgrAssembly->G << 1123         for( G4int ii = 0; ii < tgrAssembly->GetNoComponents(); ii++ )
1193         {                                        1124         {
1194           // Rotation and translation of a pl    1125           // Rotation and translation of a plate inside the assembly
1195                                                  1126 
1196           G4ThreeVector transl = tgrAssembly- << 1127           G4ThreeVector transl =  tgrAssembly->GetComponentPos(ii);
1197           G4String rmName      = tgrAssembly- << 1128           G4String rmName = tgrAssembly->GetComponentRM(ii);
1198           G4RotationMatrix* rotmat =          << 1129           G4RotationMatrix* rotmat = G4tgbRotationMatrixMgr::GetInstance()
1199             G4tgbRotationMatrixMgr::GetInstan << 1130                                    ->FindOrBuildG4RotMatrix( rmName );
1200               rmName);                        << 1131           
1201                                               << 
1202           //----- Get G4LogicalVolume of comp    1132           //----- Get G4LogicalVolume of component
1203           G4String lvname         = tgrAssemb << 1133           G4String lvname = tgrAssembly->GetComponentName(ii);
1204           G4LogicalVolume* logvol = g4vmgr->F << 1134           G4LogicalVolume* logvol = g4vmgr->FindG4LogVol( lvname);
1205           if(logvol == nullptr)               << 1135           if( logvol == 0 )
1206           {                                      1136           {
1207             g4vmgr->FindVolume(lvname)->Const << 1137             g4vmgr->FindVolume( lvname )->ConstructG4Volumes( 0, 0);
1208             logvol = g4vmgr->FindG4LogVol(lvn << 1138             logvol = g4vmgr->FindG4LogVol( lvname, true );
1209           }                                      1139           }
1210           // Fill the assembly by the plates     1140           // Fill the assembly by the plates
1211           theG4AssemblyVolume->AddPlacedVolum << 1141           theG4AssemblyVolume->AddPlacedVolume( logvol, transl, rotmat );
1212 #ifdef G4VERBOSE                                 1142 #ifdef G4VERBOSE
1213           if(G4tgrMessenger::GetVerboseLevel( << 1143     if( G4tgrMessenger::GetVerboseLevel() >= 1 )
1214           {                                   << 1144     {
1215             G4cout << " G4AssemblyVolume->Add << 1145       G4cout << " G4AssemblyVolume->AddPlacedVolume " << ii  
1216                    << logvol->GetName() << "  << 1146        << " " << logvol->GetName()
1217                    << " rotmat " << rotmat->c << 1147        << " translation " << transl  
1218                    << " " << rotmat->colZ() < << 1148        << " rotmat " << rotmat->colX() 
1219           }                                   << 1149        << " " << rotmat->colY() 
                                                   >> 1150        << " " << rotmat->colZ() << G4endl;
                                                   >> 1151     }
1220 #endif                                           1152 #endif
1221         }                                        1153         }
1222       }                                          1154       }
1223                                                  1155 
1224       // Rotation and Translation of the asse    1156       // Rotation and Translation of the assembly inside the world
1225                                                  1157 
1226       G4tgrPlaceSimple* placeSimple = (G4tgrP << 1158       G4tgrPlaceSimple* placeSimple = (G4tgrPlaceSimple*)place; 
1227       G4String rmName               = placeSi << 1159       G4String rmName = placeSimple->GetRotMatName();
1228       G4RotationMatrix* rotmat =              << 1160       G4RotationMatrix* rotmat = G4tgbRotationMatrixMgr::GetInstance()
1229         G4tgbRotationMatrixMgr::GetInstance() << 1161                                ->FindOrBuildG4RotMatrix( rmName );
1230       G4ThreeVector transl = place->GetPlacem    1162       G4ThreeVector transl = place->GetPlacement();
1231                                                  1163 
1232       G4LogicalVolume* parentLV_nonconst =       1164       G4LogicalVolume* parentLV_nonconst =
1233         const_cast<G4LogicalVolume*>(parentLV << 1165                        const_cast<G4LogicalVolume*>(parentLV);
1234       theG4AssemblyVolume->MakeImprint(parent << 1166       theG4AssemblyVolume->MakeImprint( parentLV_nonconst, transl, rotmat );
                                                   >> 1167  
1235     }                                            1168     }
1236     else  // If it is G4tgrVolumeAssembly     << 1169     else   // If it is G4tgrVolumeAssembly
1237     {                                            1170     {
1238       G4String ErrMessage =                   << 1171       G4String ErrMessage = "Volume type not supported: "
1239         "Volume type not supported: " + theTg << 1172                           + theTgrVolume->GetType() + ", sorry...";
1240       G4Exception("G4tgbVolume::ConstructG4Ph    1173       G4Exception("G4tgbVolume::ConstructG4PhysVol()", "NotImplemented",
1241                   FatalException, ErrMessage)    1174                   FatalException, ErrMessage);
1242     }                                         << 1175     }    
1243   }                                           << 1176   } 
1244                                                  1177 
1245   return physvol;                                1178   return physvol;
1246 }                                                1179 }
1247                                                  1180 
1248 // ------------------------------------------ << 1181 
1249 G4VSolid* G4tgbVolume::BuildSolidForDivision( << 1182 //-------------------------------------------------------------------
                                                   >> 1183 G4VSolid* G4tgbVolume::BuildSolidForDivision( G4VSolid* parentSolid, EAxis axis  )
1250 {                                                1184 {
1251   G4VSolid* solid = nullptr;                  << 1185   G4VSolid* solid=0;
1252   G4double redf =                             << 1186   G4double redf = (parentSolid->GetExtent().GetXmax()-parentSolid->GetExtent().GetXmin());
1253     (parentSolid->GetExtent().GetXmax() - par << 1187   redf = std::min(redf,parentSolid->GetExtent().GetYmax()-parentSolid->GetExtent().GetYmin());
1254   redf = std::min(redf, parentSolid->GetExten << 1188   redf = std::min(redf,parentSolid->GetExtent().GetZmax()-parentSolid->GetExtent().GetZmin());
1255                           parentSolid->GetExt << 1189   redf *= 0.001; //make daugther much smaller, to fit in parent
1256   redf = std::min(redf, parentSolid->GetExten << 1190 
1257                           parentSolid->GetExt << 1191   if( parentSolid->GetEntityType() == "G4Box" )
1258   redf *= 0.001;  // make daugther much small << 1192   {
1259                                               << 1193     G4Box* psolid = (G4Box*)(parentSolid);
1260   if(parentSolid->GetEntityType() == "G4Box") << 1194     solid = new G4Box(GetName(), psolid->GetXHalfLength()*redf,
1261   {                                           << 1195                                  psolid->GetZHalfLength()*redf,
1262     G4Box* psolid = (G4Box*) (parentSolid);   << 1196                                  psolid->GetZHalfLength()*redf);
1263     solid         = new G4Box(GetName(), psol << 1197   } 
1264                       psolid->GetZHalfLength( << 1198   else if ( parentSolid->GetEntityType() == "G4Tubs" )
1265                       psolid->GetZHalfLength( << 1199   {
1266   }                                           << 1200     G4Tubs* psolid = (G4Tubs*)(parentSolid);
1267   else if(parentSolid->GetEntityType() == "G4 << 1201     solid = new G4Tubs( GetName(), psolid->GetInnerRadius()*redf,
1268   {                                           << 1202                                    psolid->GetOuterRadius()*redf,
1269     G4Tubs* psolid = (G4Tubs*) (parentSolid); << 1203                                    psolid->GetZHalfLength()*redf,
1270     solid          = new G4Tubs(GetName(), ps << 1204                                    psolid->GetStartPhiAngle(),
1271                        psolid->GetOuterRadius << 1205                                    psolid->GetDeltaPhiAngle());
1272                        psolid->GetZHalfLength << 1206   } 
1273                        psolid->GetStartPhiAng << 1207   else if ( parentSolid->GetEntityType() == "G4Cons" )
1274   }                                           << 1208   {
1275   else if(parentSolid->GetEntityType() == "G4 << 1209     G4Cons* psolid = (G4Cons*)(parentSolid);
1276   {                                           << 1210     solid = new G4Cons( GetName(), psolid->GetInnerRadiusMinusZ()*redf,
1277     G4Cons* psolid = (G4Cons*) (parentSolid); << 1211                                    psolid->GetOuterRadiusMinusZ()*redf,
1278     solid = new G4Cons(GetName(), psolid->Get << 1212                                    psolid->GetInnerRadiusPlusZ()*redf,
1279                        psolid->GetOuterRadius << 1213                                    psolid->GetOuterRadiusPlusZ()*redf,
1280                        psolid->GetInnerRadius << 1214                                    psolid->GetZHalfLength()*redf,
1281                        psolid->GetOuterRadius << 1215                                    psolid->GetStartPhiAngle(),
1282                        psolid->GetZHalfLength << 1216                                    psolid->GetDeltaPhiAngle());
1283                        psolid->GetStartPhiAng << 1217   } 
1284   }                                           << 1218   else if ( parentSolid->GetEntityType() == "G4Trd" )
1285   else if(parentSolid->GetEntityType() == "G4 << 
1286   {                                              1219   {
1287     G4Trd* psolid  = (G4Trd*) (parentSolid);  << 1220     G4Trd* psolid = (G4Trd*)(parentSolid);
1288     G4double mpDx1 = psolid->GetXHalfLength1(    1221     G4double mpDx1 = psolid->GetXHalfLength1();
1289     G4double mpDx2 = psolid->GetXHalfLength2(    1222     G4double mpDx2 = psolid->GetXHalfLength2();
1290                                                  1223 
1291     if(axis == kXAxis &&                      << 1224     if( axis == kXAxis && std::fabs(mpDx1 - mpDx2) > G4GeometryTolerance::GetInstance()->GetSurfaceTolerance() )
1292        std::fabs(mpDx1 - mpDx2) >             << 1225     {
1293          G4GeometryTolerance::GetInstance()-> << 1226       solid = new G4Trap( GetName(), psolid->GetZHalfLength()*redf, 
1294     {                                         << 1227         psolid->GetYHalfLength1()*redf, 
1295       solid = new G4Trap(GetName(), psolid->G << 1228         psolid->GetXHalfLength2()*redf, 
1296                          psolid->GetYHalfLeng << 1229         psolid->GetXHalfLength1()*redf );
1297                          psolid->GetXHalfLeng << 1230     } 
1298                          psolid->GetXHalfLeng << 
1299     }                                         << 
1300     else                                         1231     else
1301     {                                            1232     {
1302       solid = new G4Trd(                      << 1233       solid = new G4Trd( GetName(), psolid->GetXHalfLength1()*redf,
1303         GetName(), psolid->GetXHalfLength1()  << 1234        psolid->GetXHalfLength2()*redf,
1304         psolid->GetXHalfLength2() * redf, pso << 1235        psolid->GetYHalfLength1()*redf,
1305         psolid->GetYHalfLength2() * redf, pso << 1236        psolid->GetYHalfLength2()*redf,
1306     }                                         << 1237        psolid->GetZHalfLength()*redf);
1307   }                                           << 1238     }
1308   else if(parentSolid->GetEntityType() == "G4 << 1239     
1309   {                                           << 1240   } 
1310     G4Para* psolid = (G4Para*) (parentSolid); << 1241   else if ( parentSolid->GetEntityType() == "G4Para" )
1311     solid          = new G4Para(              << 1242   {
1312       GetName(), psolid->GetXHalfLength() * r << 1243     G4Para* psolid = (G4Para*)(parentSolid);
1313       psolid->GetYHalfLength() * redf, psolid << 1244     solid = new G4Para( GetName(), psolid->GetXHalfLength()*redf,
1314       std::atan(psolid->GetTanAlpha()), psoli << 1245                                    psolid->GetYHalfLength()*redf,
1315       psolid->GetSymAxis().phi());            << 1246                                    psolid->GetZHalfLength()*redf,
1316   }                                           << 1247                                    std::atan(psolid->GetTanAlpha()),
1317   else if(parentSolid->GetEntityType() == "G4 << 1248                                    psolid->GetSymAxis().theta(),
                                                   >> 1249                                    psolid->GetSymAxis().phi() ); 
                                                   >> 1250   } 
                                                   >> 1251   else if ( parentSolid->GetEntityType() == "G4Polycone" )
1318   {                                              1252   {
1319     G4Polycone* psolid             = (G4Polyc << 1253     G4Polycone* psolid = (G4Polycone*)(parentSolid);
1320     G4PolyconeHistorical origParam = *(psolid    1254     G4PolyconeHistorical origParam = *(psolid->GetOriginalParameters());
1321     for(G4int ii = 0; ii < origParam.Num_z_pl << 1255     for( G4int ii = 0; ii < origParam.Num_z_planes; ii++ )
1322     {                                            1256     {
1323       origParam.Rmin[ii] = origParam.Rmin[ii] << 1257       origParam.Rmin[ii] = origParam.Rmin[ii]*redf;
1324       origParam.Rmax[ii] = origParam.Rmax[ii] << 1258       origParam.Rmax[ii] = origParam.Rmax[ii]*redf;
1325     }                                            1259     }
1326     solid = new G4Polycone(GetName(), psolid- << 1260     solid = new G4Polycone( GetName(), psolid->GetStartPhi(),
1327                            psolid->GetEndPhi( << 1261                                        psolid->GetEndPhi(),
1328                            origParam.Z_values << 1262                             origParam.Num_z_planes, origParam.Z_values,
1329   }                                           << 1263                             origParam.Rmin, origParam.Rmax);
1330   else if(parentSolid->GetEntityType() == "G4 << 1264 
1331   {                                           << 1265   } 
1332     G4GenericPolycone* psolid = (G4GenericPol << 1266   else if ( parentSolid->GetEntityType() == "G4GenericPolycone" )
1333     const G4int numRZ         = psolid->GetNu << 1267   {
1334     G4double* r               = new G4double[ << 1268     G4GenericPolycone* psolid = (G4GenericPolycone*)(parentSolid);
1335     G4double* z               = new G4double[ << 1269     const G4int numRZ = psolid->GetNumRZCorner();
1336     for(G4int ii = 0; ii < numRZ; ++ii)       << 1270     G4double* r = new G4double[numRZ];
                                                   >> 1271     G4double* z = new G4double[numRZ];
                                                   >> 1272     for( G4int ii = 0; ii < numRZ; ii++ )
1337     {                                            1273     {
1338       r[ii] = psolid->GetCorner(ii).r;           1274       r[ii] = psolid->GetCorner(ii).r;
1339       z[ii] = psolid->GetCorner(ii).z;           1275       z[ii] = psolid->GetCorner(ii).z;
1340     }                                            1276     }
1341     solid = new G4GenericPolycone(GetName(),  << 1277     solid = new G4GenericPolycone( GetName(), psolid->GetStartPhi(),
1342                                   psolid->Get << 1278                                    psolid->GetEndPhi() - psolid->GetStartPhi(),
1343                                   numRZ, r, z << 1279                                    numRZ, r, z);
1344     delete[] r;                               << 1280     delete [] r; delete [] z;
1345     delete[] z;                               << 1281 
1346   }                                           << 1282   } 
1347   else if(parentSolid->GetEntityType() == "G4 << 1283   else if ( parentSolid->GetEntityType() == "G4Polyhedra" )
1348   {                                              1284   {
1349     G4Polyhedra* psolid             = (G4Poly << 1285     G4Polyhedra* psolid = (G4Polyhedra*)(parentSolid);
1350     G4PolyhedraHistorical origParam = *(psoli    1286     G4PolyhedraHistorical origParam = *(psolid->GetOriginalParameters());
1351     for(G4int ii = 0; ii < origParam.Num_z_pl << 1287     for( G4int ii = 0; ii < origParam.Num_z_planes; ii++ )
1352     {                                            1288     {
1353       origParam.Rmin[ii] = origParam.Rmin[ii] << 1289       origParam.Rmin[ii] = origParam.Rmin[ii]*redf;
1354       origParam.Rmax[ii] = origParam.Rmax[ii] << 1290       origParam.Rmax[ii] = origParam.Rmax[ii]*redf;
1355     }                                            1291     }
1356     solid =                                   << 1292     solid = new G4Polyhedra( GetName(), psolid->GetStartPhi(),
1357       new G4Polyhedra(GetName(), psolid->GetS << 1293                                         psolid->GetEndPhi(),
1358                       psolid->GetNumSide(), o << 1294                                         psolid->GetNumSide(),
1359                       origParam.Z_values, ori << 1295                              origParam.Num_z_planes, origParam.Z_values,
                                                   >> 1296                              origParam.Rmin, origParam.Rmax);
1360   }                                              1297   }
1361   else                                           1298   else
1362   {                                           << 1299   { 
1363     G4String ErrMessage = "Solid type not sup << 1300     G4String ErrMessage = "Solid type not supported. VOLUME= " + GetName()
1364                           " Solid type= " + p << 1301                         + " Solid type= " + parentSolid->GetEntityType() + "\n"
1365                           "\n" +              << 1302                         + "Only supported types are: G4Box, G4Tubs, G4Cons,"
1366                           "Only supported typ << 1303                         + " G4Trd, G4Para, G4Polycone, G4Polyhedra.";
1367                           " G4Trd, G4Para, G4 << 
1368     G4Exception("G4tgbVolume::BuildSolidForDi    1304     G4Exception("G4tgbVolume::BuildSolidForDivision()", "NotImplemented",
1369                 FatalException, ErrMessage);     1305                 FatalException, ErrMessage);
1370     return nullptr;                           << 1306     return 0;
1371   }                                              1307   }
1372                                                  1308 
1373 #ifdef G4VERBOSE                                 1309 #ifdef G4VERBOSE
1374   if(G4tgrMessenger::GetVerboseLevel() >= 1)  << 1310     if( G4tgrMessenger::GetVerboseLevel() >= 1 )
1375   {                                           << 1311     {
1376     G4cout << " Constructing new G4Solid for  << 1312       G4cout << " Constructing new G4Solid for division: " 
1377   }                                           << 1313              << *solid << G4endl;
                                                   >> 1314     }
1378 #endif                                           1315 #endif
1379   return solid;                                  1316   return solid;
1380 }                                                1317 }
                                                   >> 1318  
1381                                                  1319