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Geant4/geometry/solids/specific/src/G4GenericPolycone.cc

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Differences between /geometry/solids/specific/src/G4GenericPolycone.cc (Version 11.3.0) and /geometry/solids/specific/src/G4GenericPolycone.cc (Version 11.0)


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 25 //                                                 25 //
 26 // G4GenericPolycone implementation                26 // G4GenericPolycone implementation
 27 //                                                 27 //
 28 // Authors: T.Nikitina, G.Cosmo - CERN             28 // Authors: T.Nikitina, G.Cosmo - CERN
 29 // -------------------------------------------     29 // --------------------------------------------------------------------
 30                                                    30 
 31 #include "G4GenericPolycone.hh"                    31 #include "G4GenericPolycone.hh"
 32                                                    32 
 33 #if !defined(G4GEOM_USE_UGENERICPOLYCONE)          33 #if !defined(G4GEOM_USE_UGENERICPOLYCONE)
 34                                                    34 
 35 #include "G4PolyconeSide.hh"                       35 #include "G4PolyconeSide.hh"
 36 #include "G4PolyPhiFace.hh"                        36 #include "G4PolyPhiFace.hh"
 37                                                    37 
 38 #include "G4GeomTools.hh"                          38 #include "G4GeomTools.hh"
 39 #include "G4VoxelLimits.hh"                        39 #include "G4VoxelLimits.hh"
 40 #include "G4AffineTransform.hh"                    40 #include "G4AffineTransform.hh"
 41 #include "G4BoundingEnvelope.hh"                   41 #include "G4BoundingEnvelope.hh"
 42                                                    42 
 43 #include "G4QuickRand.hh"                          43 #include "G4QuickRand.hh"
 44                                                    44 
 45 #include "G4Polyhedron.hh"                         45 #include "G4Polyhedron.hh"
 46 #include "G4EnclosingCylinder.hh"                  46 #include "G4EnclosingCylinder.hh"
 47 #include "G4ReduciblePolygon.hh"                   47 #include "G4ReduciblePolygon.hh"
 48 #include "G4VPVParameterisation.hh"                48 #include "G4VPVParameterisation.hh"
 49                                                    49 
 50 namespace                                          50 namespace
 51 {                                                  51 {
 52   G4Mutex surface_elementsMutex = G4MUTEX_INIT     52   G4Mutex surface_elementsMutex = G4MUTEX_INITIALIZER;
 53 }                                                  53 }
 54                                                    54 
 55 using namespace CLHEP;                             55 using namespace CLHEP;
 56                                                    56 
 57 // Constructor (generic parameters)                57 // Constructor (generic parameters)
 58 //                                                 58 //
 59 G4GenericPolycone::G4GenericPolycone( const G4     59 G4GenericPolycone::G4GenericPolycone( const G4String& name,
 60                               G4double phiStar     60                               G4double phiStart,
 61                               G4double phiTota     61                               G4double phiTotal,
 62                               G4int    numRZ,      62                               G4int    numRZ,
 63                         const G4double r[],        63                         const G4double r[],
 64                         const G4double z[]   )     64                         const G4double z[]   )
 65   : G4VCSGfaceted( name )                          65   : G4VCSGfaceted( name )
 66 {                                                  66 {
 67                                                    67 
 68   auto rz = new G4ReduciblePolygon( r, z, numR <<  68   G4ReduciblePolygon *rz = new G4ReduciblePolygon( r, z, numRZ );
 69                                                    69 
 70   Create( phiStart, phiTotal, rz );                70   Create( phiStart, phiTotal, rz );
 71                                                    71 
 72   // Set original_parameters struct for consis     72   // Set original_parameters struct for consistency
 73   //                                               73   //
 74   //SetOriginalParameters(rz);                     74   //SetOriginalParameters(rz);
 75                                                    75 
 76   delete rz;                                       76   delete rz;
 77 }                                                  77 }
 78                                                    78 
 79 // Create                                          79 // Create
 80 //                                                 80 //
 81 // Generic create routine, called by each cons     81 // Generic create routine, called by each constructor after
 82 // conversion of arguments                         82 // conversion of arguments
 83 //                                                 83 //
 84 void G4GenericPolycone::Create( G4double phiSt     84 void G4GenericPolycone::Create( G4double phiStart,
 85                                 G4double phiTo <<  85                          G4double phiTotal,
 86                                 G4ReduciblePol <<  86                          G4ReduciblePolygon *rz    )
 87 {                                                  87 {
 88   //                                               88   //
 89   // Perform checks of rz values                   89   // Perform checks of rz values
 90   //                                               90   //
 91   if (rz->Amin() < 0.0)                            91   if (rz->Amin() < 0.0)
 92   {                                                92   {
 93     std::ostringstream message;                    93     std::ostringstream message;
 94     message << "Illegal input parameters - " <     94     message << "Illegal input parameters - " << GetName() << G4endl
 95             << "        All R values must be >     95             << "        All R values must be >= 0 !";
 96     G4Exception("G4GenericPolycone::Create()",     96     G4Exception("G4GenericPolycone::Create()", "GeomSolids0002",
 97                 FatalErrorInArgument, message)     97                 FatalErrorInArgument, message);
 98   }                                                98   }
 99                                                    99 
100   G4double rzArea = rz->Area();                   100   G4double rzArea = rz->Area();
101   if (rzArea < -kCarTolerance)                    101   if (rzArea < -kCarTolerance)
102   {                                               102   {
103     rz->ReverseOrder();                           103     rz->ReverseOrder();
104   }                                               104   }
105   else if (rzArea < kCarTolerance)                105   else if (rzArea < kCarTolerance)
106   {                                               106   {
107     std::ostringstream message;                   107     std::ostringstream message;
108     message << "Illegal input parameters - " <    108     message << "Illegal input parameters - " << GetName() << G4endl
109             << "        R/Z cross section is z    109             << "        R/Z cross section is zero or near zero: " << rzArea;
110     G4Exception("G4GenericPolycone::Create()",    110     G4Exception("G4GenericPolycone::Create()", "GeomSolids0002",
111                 FatalErrorInArgument, message)    111                 FatalErrorInArgument, message);
112   }                                               112   }
113                                                   113 
114   if ( (!rz->RemoveDuplicateVertices( kCarTole    114   if ( (!rz->RemoveDuplicateVertices( kCarTolerance ))
115     || (!rz->RemoveRedundantVertices( kCarTole    115     || (!rz->RemoveRedundantVertices( kCarTolerance ))     )
116   {                                               116   {
117     std::ostringstream message;                   117     std::ostringstream message;
118     message << "Illegal input parameters - " <    118     message << "Illegal input parameters - " << GetName() << G4endl
119             << "        Too few unique R/Z val    119             << "        Too few unique R/Z values !";
120     G4Exception("G4GenericPolycone::Create()",    120     G4Exception("G4GenericPolycone::Create()", "GeomSolids0002",
121                 FatalErrorInArgument, message)    121                 FatalErrorInArgument, message);
122   }                                               122   }
123                                                   123 
124   if (rz->CrossesItself(1/kInfinity))             124   if (rz->CrossesItself(1/kInfinity))
125   {                                               125   {
126     std::ostringstream message;                   126     std::ostringstream message;
127     message << "Illegal input parameters - " <    127     message << "Illegal input parameters - " << GetName() << G4endl
128             << "        R/Z segments cross !";    128             << "        R/Z segments cross !";
129     G4Exception("G4GenericPolycone::Create()",    129     G4Exception("G4GenericPolycone::Create()", "GeomSolids0002",
130                 FatalErrorInArgument, message)    130                 FatalErrorInArgument, message);
131   }                                               131   }
132                                                   132 
133   numCorner = rz->NumVertices();                  133   numCorner = rz->NumVertices();
134                                                   134 
135   //                                              135   //
136   // Phi opening? Account for some possible ro    136   // Phi opening? Account for some possible roundoff, and interpret
137   // nonsense value as representing no phi ope    137   // nonsense value as representing no phi opening
138   //                                              138   //
139   if (phiTotal <= 0 || phiTotal > twopi-1E-10)    139   if (phiTotal <= 0 || phiTotal > twopi-1E-10)
140   {                                               140   {
141     phiIsOpen = false;                            141     phiIsOpen = false;
142     startPhi = 0;                                 142     startPhi = 0;
143     endPhi = twopi;                               143     endPhi = twopi;
144   }                                               144   }
145   else                                            145   else
146   {                                               146   {
147     phiIsOpen = true;                             147     phiIsOpen = true;
148                                                   148 
149     //                                            149     //
150     // Convert phi into our convention            150     // Convert phi into our convention
151     //                                            151     //
152     startPhi = phiStart;                          152     startPhi = phiStart;
153     while( startPhi < 0 )    // Loop checking,    153     while( startPhi < 0 )    // Loop checking, 13.08.2015, G.Cosmo
154       startPhi += twopi;                          154       startPhi += twopi;
155                                                   155 
156     endPhi = phiStart+phiTotal;                   156     endPhi = phiStart+phiTotal;
157     while( endPhi < startPhi )    // Loop chec    157     while( endPhi < startPhi )    // Loop checking, 13.08.2015, G.Cosmo
158       endPhi += twopi;                            158       endPhi += twopi;
159   }                                               159   }
160                                                   160 
161   //                                              161   //
162   // Allocate corner array.                       162   // Allocate corner array.
163   //                                              163   //
164   corners = new G4PolyconeSideRZ[numCorner];      164   corners = new G4PolyconeSideRZ[numCorner];
165                                                   165 
166   //                                              166   //
167   // Copy corners                                 167   // Copy corners
168   //                                              168   //
169   G4ReduciblePolygonIterator iterRZ(rz);          169   G4ReduciblePolygonIterator iterRZ(rz);
170                                                   170 
171   G4PolyconeSideRZ* next = corners;               171   G4PolyconeSideRZ* next = corners;
172   iterRZ.Begin();                                 172   iterRZ.Begin();
173   do    // Loop checking, 13.08.2015, G.Cosmo     173   do    // Loop checking, 13.08.2015, G.Cosmo
174   {                                               174   {
175     next->r = iterRZ.GetA();                      175     next->r = iterRZ.GetA();
176     next->z = iterRZ.GetB();                      176     next->z = iterRZ.GetB();
177   } while( ++next, iterRZ.Next() );               177   } while( ++next, iterRZ.Next() );
178                                                   178 
179   //                                              179   //
180   // Allocate face pointer array                  180   // Allocate face pointer array
181   //                                              181   //
182   numFace = phiIsOpen ? numCorner+2 : numCorne    182   numFace = phiIsOpen ? numCorner+2 : numCorner;
183   faces = new G4VCSGface*[numFace];               183   faces = new G4VCSGface*[numFace];
184                                                   184 
185   //                                              185   //
186   // Construct conical faces                      186   // Construct conical faces
187   //                                              187   //
188   // But! Don't construct a face if both point    188   // But! Don't construct a face if both points are at zero radius!
189   //                                              189   //
190   G4PolyconeSideRZ *corner = corners,             190   G4PolyconeSideRZ *corner = corners,
191                    *prev = corners + numCorner    191                    *prev = corners + numCorner-1,
192                    *nextNext;                     192                    *nextNext;
193   G4VCSGface** face = faces;                      193   G4VCSGface** face = faces;
194   do    // Loop checking, 13.08.2015, G.Cosmo     194   do    // Loop checking, 13.08.2015, G.Cosmo
195   {                                               195   {
196     next = corner+1;                              196     next = corner+1;
197     if (next >= corners+numCorner) next = corn    197     if (next >= corners+numCorner) next = corners;
198     nextNext = next+1;                            198     nextNext = next+1;
199     if (nextNext >= corners+numCorner) nextNex    199     if (nextNext >= corners+numCorner) nextNext = corners;
200                                                   200 
201     if (corner->r < 1/kInfinity && next->r < 1    201     if (corner->r < 1/kInfinity && next->r < 1/kInfinity) continue;
202                                                   202 
203     //                                            203     //
204     // We must decide here if we can dare decl    204     // We must decide here if we can dare declare one of our faces
205     // as having a "valid" normal (i.e. allBeh    205     // as having a "valid" normal (i.e. allBehind = true). This
206     // is never possible if the face faces "in    206     // is never possible if the face faces "inward" in r.
207     //                                            207     //
208     G4bool allBehind;                             208     G4bool allBehind;
209     if (corner->z > next->z)                      209     if (corner->z > next->z)
210     {                                             210     {
211       allBehind = false;                          211       allBehind = false;
212     }                                             212     }
213     else                                          213     else
214     {                                             214     {
215       //                                          215       //
216       // Otherwise, it is only true if the lin    216       // Otherwise, it is only true if the line passing
217       // through the two points of the segment    217       // through the two points of the segment do not
218       // split the r/z cross section              218       // split the r/z cross section
219       //                                          219       //
220       allBehind = !rz->BisectedBy( corner->r,     220       allBehind = !rz->BisectedBy( corner->r, corner->z,
221                  next->r, next->z, kCarToleran    221                  next->r, next->z, kCarTolerance );
222     }                                             222     }
223                                                   223 
224     *face++ = new G4PolyconeSide( prev, corner    224     *face++ = new G4PolyconeSide( prev, corner, next, nextNext,
225                 startPhi, endPhi-startPhi, phi    225                 startPhi, endPhi-startPhi, phiIsOpen, allBehind );
226   } while( prev=corner, corner=next, corner >     226   } while( prev=corner, corner=next, corner > corners );
227                                                   227 
228   if (phiIsOpen)                                  228   if (phiIsOpen)
229   {                                               229   {
230     //                                            230     //
231     // Construct phi open edges                   231     // Construct phi open edges
232     //                                            232     //
233     *face++ = new G4PolyPhiFace( rz, startPhi,    233     *face++ = new G4PolyPhiFace( rz, startPhi, 0, endPhi  );
234     *face++ = new G4PolyPhiFace( rz, endPhi,      234     *face++ = new G4PolyPhiFace( rz, endPhi,   0, startPhi );
235   }                                               235   }
236                                                   236 
237   //                                              237   //
238   // We might have dropped a face or two: reca    238   // We might have dropped a face or two: recalculate numFace
239   //                                              239   //
240   numFace = (G4int)(face-faces);               << 240   numFace = face-faces;
241                                                   241 
242   //                                              242   //
243   // Make enclosingCylinder                       243   // Make enclosingCylinder
244   //                                              244   //
245   enclosingCylinder =                             245   enclosingCylinder =
246     new G4EnclosingCylinder( rz, phiIsOpen, ph    246     new G4EnclosingCylinder( rz, phiIsOpen, phiStart, phiTotal );
247 }                                                 247 }
248                                                   248 
249 // Fake default constructor - sets only member    249 // Fake default constructor - sets only member data and allocates memory
250 //                            for usage restri    250 //                            for usage restricted to object persistency.
251 //                                                251 //
252 G4GenericPolycone::G4GenericPolycone( __void__    252 G4GenericPolycone::G4GenericPolycone( __void__& a )
253   : G4VCSGfaceted(a), startPhi(0.), endPhi(0.)    253   : G4VCSGfaceted(a), startPhi(0.), endPhi(0.), numCorner(0)
254 {                                                 254 {
255 }                                                 255 }
256                                                   256 
257 // Destructor                                     257 // Destructor
258 //                                                258 //
259 G4GenericPolycone::~G4GenericPolycone()           259 G4GenericPolycone::~G4GenericPolycone()
260 {                                                 260 {
261   delete [] corners;                              261   delete [] corners;
262   delete enclosingCylinder;                       262   delete enclosingCylinder;
263   delete fElements;                               263   delete fElements;
264   delete fpPolyhedron;                            264   delete fpPolyhedron;
265   corners = nullptr;                              265   corners = nullptr;
266   enclosingCylinder = nullptr;                    266   enclosingCylinder = nullptr;
267   fElements = nullptr;                            267   fElements = nullptr;
268   fpPolyhedron = nullptr;                         268   fpPolyhedron = nullptr;
269 }                                                 269 }
270                                                   270 
271 // Copy constructor                               271 // Copy constructor
272 //                                                272 //
273 G4GenericPolycone::G4GenericPolycone( const G4    273 G4GenericPolycone::G4GenericPolycone( const G4GenericPolycone& source )
274   : G4VCSGfaceted( source )                       274   : G4VCSGfaceted( source )
275 {                                                 275 {
276   CopyStuff( source );                            276   CopyStuff( source );
277 }                                                 277 }
278                                                   278 
279 // Assignment operator                            279 // Assignment operator
280 //                                                280 //
281 G4GenericPolycone&                                281 G4GenericPolycone&
282 G4GenericPolycone::operator=( const G4GenericP    282 G4GenericPolycone::operator=( const G4GenericPolycone& source )
283 {                                                 283 {
284   if (this == &source) return *this;              284   if (this == &source) return *this;
285                                                   285 
286   G4VCSGfaceted::operator=( source );             286   G4VCSGfaceted::operator=( source );
287                                                   287 
288   delete [] corners;                              288   delete [] corners;
289   // if (original_parameters) delete original_    289   // if (original_parameters) delete original_parameters;
290                                                   290 
291   delete enclosingCylinder;                       291   delete enclosingCylinder;
292                                                   292 
293   CopyStuff( source );                            293   CopyStuff( source );
294                                                   294 
295   return *this;                                   295   return *this;
296 }                                                 296 }
297                                                   297 
298 // CopyStuff                                      298 // CopyStuff
299 //                                                299 //
300 void G4GenericPolycone::CopyStuff( const G4Gen    300 void G4GenericPolycone::CopyStuff( const G4GenericPolycone& source )
301 {                                                 301 {
302   //                                              302   //
303   // Simple stuff                                 303   // Simple stuff
304   //                                              304   //
305   startPhi  = source.startPhi;                    305   startPhi  = source.startPhi;
306   endPhi    = source.endPhi;                      306   endPhi    = source.endPhi;
307   phiIsOpen = source.phiIsOpen;                   307   phiIsOpen = source.phiIsOpen;
308   numCorner = source.numCorner;                   308   numCorner = source.numCorner;
309                                                   309 
310   //                                              310   //
311   // The corner array                             311   // The corner array
312   //                                              312   //
313   corners = new G4PolyconeSideRZ[numCorner];      313   corners = new G4PolyconeSideRZ[numCorner];
314                                                   314 
315   G4PolyconeSideRZ  *corn = corners,              315   G4PolyconeSideRZ  *corn = corners,
316         *sourceCorn = source.corners;             316         *sourceCorn = source.corners;
317   do    // Loop checking, 13.08.2015, G.Cosmo     317   do    // Loop checking, 13.08.2015, G.Cosmo
318   {                                               318   {
319     *corn = *sourceCorn;                          319     *corn = *sourceCorn;
320   } while( ++sourceCorn, ++corn < corners+numC    320   } while( ++sourceCorn, ++corn < corners+numCorner );
321                                                   321 
322   //                                              322   //
323   // Enclosing cylinder                           323   // Enclosing cylinder
324   //                                              324   //
325   enclosingCylinder = new G4EnclosingCylinder(    325   enclosingCylinder = new G4EnclosingCylinder( *source.enclosingCylinder );
326                                                   326 
327   //                                              327   //
328   // Surface elements                             328   // Surface elements
329   //                                              329   //
330   delete fElements;                               330   delete fElements;
331   fElements = nullptr;                            331   fElements = nullptr;
332                                                   332 
333   // Polyhedron                                   333   // Polyhedron
334   //                                              334   //
335   fRebuildPolyhedron = false;                     335   fRebuildPolyhedron = false;
336   delete fpPolyhedron;                            336   delete fpPolyhedron;
337   fpPolyhedron = nullptr;                         337   fpPolyhedron = nullptr;
338 }                                                 338 }
339                                                   339 
340 // Reset                                          340 // Reset
341 //                                                341 //
342 G4bool G4GenericPolycone::Reset()                 342 G4bool G4GenericPolycone::Reset()
343 {                                                 343 {
344   std::ostringstream message;                     344   std::ostringstream message;
345   message << "Solid " << GetName() << " built     345   message << "Solid " << GetName() << " built using generic construct."
346           << G4endl << "Not applicable to the     346           << G4endl << "Not applicable to the generic construct !";
347   G4Exception("G4GenericPolycone::Reset()", "G    347   G4Exception("G4GenericPolycone::Reset()", "GeomSolids1001",
348               JustWarning, message, "Parameter    348               JustWarning, message, "Parameters NOT resetted.");
349   return true;                                    349   return true;
350 }                                                 350 }
351                                                   351 
352 // Inside                                         352 // Inside
353 //                                                353 //
354 // This is an override of G4VCSGfaceted::Insid    354 // This is an override of G4VCSGfaceted::Inside, created in order
355 // to speed things up by first checking with G    355 // to speed things up by first checking with G4EnclosingCylinder.
356 //                                                356 //
357 EInside G4GenericPolycone::Inside( const G4Thr    357 EInside G4GenericPolycone::Inside( const G4ThreeVector& p ) const
358 {                                                 358 {
359   //                                              359   //
360   // Quick test                                   360   // Quick test
361   //                                              361   //
362   if (enclosingCylinder->MustBeOutside(p)) ret    362   if (enclosingCylinder->MustBeOutside(p)) return kOutside;
363                                                   363 
364   //                                              364   //
365   // Long answer                                  365   // Long answer
366   //                                              366   //
367   return G4VCSGfaceted::Inside(p);                367   return G4VCSGfaceted::Inside(p);
368 }                                                 368 }
369                                                   369 
370 // DistanceToIn                                   370 // DistanceToIn
371 //                                                371 //
372 // This is an override of G4VCSGfaceted::Insid    372 // This is an override of G4VCSGfaceted::Inside, created in order
373 // to speed things up by first checking with G    373 // to speed things up by first checking with G4EnclosingCylinder.
374 //                                                374 //
375 G4double G4GenericPolycone::DistanceToIn( cons    375 G4double G4GenericPolycone::DistanceToIn( const G4ThreeVector& p,
376                                           cons    376                                           const G4ThreeVector& v ) const
377 {                                                 377 {
378   //                                              378   //
379   // Quick test                                   379   // Quick test
380   //                                              380   //
381   if (enclosingCylinder->ShouldMiss(p,v))         381   if (enclosingCylinder->ShouldMiss(p,v))
382     return kInfinity;                             382     return kInfinity;
383                                                   383 
384   //                                              384   //
385   // Long answer                                  385   // Long answer
386   //                                              386   //
387   return G4VCSGfaceted::DistanceToIn( p, v );     387   return G4VCSGfaceted::DistanceToIn( p, v );
388 }                                                 388 }
389                                                   389 
390 // DistanceToIn                                   390 // DistanceToIn
391 //                                                391 //
392 G4double G4GenericPolycone::DistanceToIn( cons    392 G4double G4GenericPolycone::DistanceToIn( const G4ThreeVector& p ) const
393 {                                                 393 {
394   return G4VCSGfaceted::DistanceToIn(p);          394   return G4VCSGfaceted::DistanceToIn(p);
395 }                                                 395 }
396                                                   396 
397 // BoundingLimits                                 397 // BoundingLimits
398 //                                                398 //
399 // Get bounding box                               399 // Get bounding box
400 //                                                400 //
401 void                                              401 void
402 G4GenericPolycone::BoundingLimits(G4ThreeVecto    402 G4GenericPolycone::BoundingLimits(G4ThreeVector& pMin,
403                                   G4ThreeVecto    403                                   G4ThreeVector& pMax) const
404 {                                                 404 {
405   G4double rmin = kInfinity, rmax = -kInfinity    405   G4double rmin = kInfinity, rmax = -kInfinity;
406   G4double zmin = kInfinity, zmax = -kInfinity    406   G4double zmin = kInfinity, zmax = -kInfinity;
407                                                   407 
408   for (G4int i=0; i<GetNumRZCorner(); ++i)        408   for (G4int i=0; i<GetNumRZCorner(); ++i)
409   {                                               409   {
410     G4PolyconeSideRZ corner = GetCorner(i);       410     G4PolyconeSideRZ corner = GetCorner(i);
411     if (corner.r < rmin) rmin = corner.r;         411     if (corner.r < rmin) rmin = corner.r;
412     if (corner.r > rmax) rmax = corner.r;         412     if (corner.r > rmax) rmax = corner.r;
413     if (corner.z < zmin) zmin = corner.z;         413     if (corner.z < zmin) zmin = corner.z;
414     if (corner.z > zmax) zmax = corner.z;         414     if (corner.z > zmax) zmax = corner.z;
415   }                                               415   }
416                                                   416 
417   if (IsOpen())                                   417   if (IsOpen())
418   {                                               418   {
419     G4TwoVector vmin,vmax;                        419     G4TwoVector vmin,vmax;
420     G4GeomTools::DiskExtent(rmin,rmax,            420     G4GeomTools::DiskExtent(rmin,rmax,
421                             GetSinStartPhi(),G    421                             GetSinStartPhi(),GetCosStartPhi(),
422                             GetSinEndPhi(),Get    422                             GetSinEndPhi(),GetCosEndPhi(),
423                             vmin,vmax);           423                             vmin,vmax);
424     pMin.set(vmin.x(),vmin.y(),zmin);             424     pMin.set(vmin.x(),vmin.y(),zmin);
425     pMax.set(vmax.x(),vmax.y(),zmax);             425     pMax.set(vmax.x(),vmax.y(),zmax);
426   }                                               426   }
427   else                                            427   else
428   {                                               428   {
429     pMin.set(-rmax,-rmax, zmin);                  429     pMin.set(-rmax,-rmax, zmin);
430     pMax.set( rmax, rmax, zmax);                  430     pMax.set( rmax, rmax, zmax);
431   }                                               431   }
432                                                   432 
433   // Check correctness of the bounding box        433   // Check correctness of the bounding box
434   //                                              434   //
435   if (pMin.x() >= pMax.x() || pMin.y() >= pMax    435   if (pMin.x() >= pMax.x() || pMin.y() >= pMax.y() || pMin.z() >= pMax.z())
436   {                                               436   {
437     std::ostringstream message;                   437     std::ostringstream message;
438     message << "Bad bounding box (min >= max)     438     message << "Bad bounding box (min >= max) for solid: "
439             << GetName() << " !"                  439             << GetName() << " !"
440             << "\npMin = " << pMin                440             << "\npMin = " << pMin
441             << "\npMax = " << pMax;               441             << "\npMax = " << pMax;
442     G4Exception("GenericG4Polycone::BoundingLi    442     G4Exception("GenericG4Polycone::BoundingLimits()", "GeomMgt0001",
443                 JustWarning, message);            443                 JustWarning, message);
444     DumpInfo();                                   444     DumpInfo();
445   }                                               445   }
446 }                                                 446 }
447                                                   447 
448 // CalculateExtent                                448 // CalculateExtent
449 //                                                449 //
450 // Calculate extent under transform and specif    450 // Calculate extent under transform and specified limit
451 //                                                451 //
452 G4bool                                            452 G4bool
453 G4GenericPolycone::CalculateExtent(const EAxis    453 G4GenericPolycone::CalculateExtent(const EAxis pAxis,
454                                    const G4Vox    454                                    const G4VoxelLimits& pVoxelLimit,
455                                    const G4Aff    455                                    const G4AffineTransform& pTransform,
456                                          G4dou    456                                          G4double& pMin, G4double& pMax) const
457 {                                                 457 {
458   G4ThreeVector bmin, bmax;                       458   G4ThreeVector bmin, bmax;
459   G4bool exist;                                   459   G4bool exist;
460                                                   460 
461   // Check bounding box (bbox)                    461   // Check bounding box (bbox)
462   //                                              462   //
463   BoundingLimits(bmin,bmax);                      463   BoundingLimits(bmin,bmax);
464   G4BoundingEnvelope bbox(bmin,bmax);             464   G4BoundingEnvelope bbox(bmin,bmax);
465 #ifdef G4BBOX_EXTENT                              465 #ifdef G4BBOX_EXTENT
466   return bbox.CalculateExtent(pAxis,pVoxelLimi    466   return bbox.CalculateExtent(pAxis,pVoxelLimit,pTransform,pMin,pMax);
467 #endif                                            467 #endif
468   if (bbox.BoundingBoxVsVoxelLimits(pAxis,pVox    468   if (bbox.BoundingBoxVsVoxelLimits(pAxis,pVoxelLimit,pTransform,pMin,pMax))
469   {                                               469   {
470     return exist = pMin < pMax;                << 470     return exist = (pMin < pMax) ? true : false;
471   }                                               471   }
472                                                   472 
473   // To find the extent, RZ contour of the pol    473   // To find the extent, RZ contour of the polycone is subdivided
474   // in triangles. The extent is calculated as    474   // in triangles. The extent is calculated as cumulative extent of
475   // all sub-polycones formed by rotation of t    475   // all sub-polycones formed by rotation of triangles around Z
476   //                                              476   //
477   G4TwoVectorList contourRZ;                      477   G4TwoVectorList contourRZ;
478   G4TwoVectorList triangles;                      478   G4TwoVectorList triangles;
479   G4double eminlim = pVoxelLimit.GetMinExtent(    479   G4double eminlim = pVoxelLimit.GetMinExtent(pAxis);
480   G4double emaxlim = pVoxelLimit.GetMaxExtent(    480   G4double emaxlim = pVoxelLimit.GetMaxExtent(pAxis);
481                                                   481 
482   // get RZ contour, ensure anticlockwise orde    482   // get RZ contour, ensure anticlockwise order of corners
483   for (G4int i=0; i<GetNumRZCorner(); ++i)        483   for (G4int i=0; i<GetNumRZCorner(); ++i)
484   {                                               484   {
485     G4PolyconeSideRZ corner = GetCorner(i);       485     G4PolyconeSideRZ corner = GetCorner(i);
486     contourRZ.emplace_back(corner.r,corner.z); << 486     contourRZ.push_back(G4TwoVector(corner.r,corner.z));
487   }                                               487   }
488   G4double area = G4GeomTools::PolygonArea(con    488   G4double area = G4GeomTools::PolygonArea(contourRZ);
489   if (area < 0.) std::reverse(contourRZ.begin(    489   if (area < 0.) std::reverse(contourRZ.begin(),contourRZ.end());
490                                                   490 
491   // triangulate RZ countour                      491   // triangulate RZ countour
492   if (!G4GeomTools::TriangulatePolygon(contour    492   if (!G4GeomTools::TriangulatePolygon(contourRZ,triangles))
493   {                                               493   {
494     std::ostringstream message;                   494     std::ostringstream message;
495     message << "Triangulation of RZ contour ha    495     message << "Triangulation of RZ contour has failed for solid: "
496             << GetName() << " !"                  496             << GetName() << " !"
497             << "\nExtent has been calculated u    497             << "\nExtent has been calculated using boundary box";
498     G4Exception("G4GenericPolycone::CalculateE    498     G4Exception("G4GenericPolycone::CalculateExtent()",
499                 "GeomMgt1002", JustWarning, me    499                 "GeomMgt1002", JustWarning, message);
500     return bbox.CalculateExtent(pAxis,pVoxelLi    500     return bbox.CalculateExtent(pAxis,pVoxelLimit,pTransform,pMin,pMax);
501   }                                               501   }
502                                                   502 
503   // set trigonometric values                     503   // set trigonometric values
504   const G4int NSTEPS = 24;            // numbe    504   const G4int NSTEPS = 24;            // number of steps for whole circle
505   G4double astep  = twopi/NSTEPS;     // max a    505   G4double astep  = twopi/NSTEPS;     // max angle for one step
506                                                   506 
507   G4double sphi   = GetStartPhi();                507   G4double sphi   = GetStartPhi();
508   G4double ephi   = GetEndPhi();                  508   G4double ephi   = GetEndPhi();
509   G4double dphi   = IsOpen() ? ephi-sphi : two    509   G4double dphi   = IsOpen() ? ephi-sphi : twopi;
510   G4int    ksteps = (dphi <= astep) ? 1 : (G4i    510   G4int    ksteps = (dphi <= astep) ? 1 : (G4int)((dphi-deg)/astep) + 1;
511   G4double ang    = dphi/ksteps;                  511   G4double ang    = dphi/ksteps;
512                                                   512 
513   G4double sinHalf = std::sin(0.5*ang);           513   G4double sinHalf = std::sin(0.5*ang);
514   G4double cosHalf = std::cos(0.5*ang);           514   G4double cosHalf = std::cos(0.5*ang);
515   G4double sinStep = 2.*sinHalf*cosHalf;          515   G4double sinStep = 2.*sinHalf*cosHalf;
516   G4double cosStep = 1. - 2.*sinHalf*sinHalf;     516   G4double cosStep = 1. - 2.*sinHalf*sinHalf;
517                                                   517 
518   G4double sinStart = GetSinStartPhi();           518   G4double sinStart = GetSinStartPhi();
519   G4double cosStart = GetCosStartPhi();           519   G4double cosStart = GetCosStartPhi();
520   G4double sinEnd   = GetSinEndPhi();             520   G4double sinEnd   = GetSinEndPhi();
521   G4double cosEnd   = GetCosEndPhi();             521   G4double cosEnd   = GetCosEndPhi();
522                                                   522 
523   // define vectors and arrays                    523   // define vectors and arrays
524   std::vector<const G4ThreeVectorList *> polyg    524   std::vector<const G4ThreeVectorList *> polygons;
525   polygons.resize(ksteps+2);                      525   polygons.resize(ksteps+2);
526   G4ThreeVectorList pols[NSTEPS+2];               526   G4ThreeVectorList pols[NSTEPS+2];
527   for (G4int k=0; k<ksteps+2; ++k) pols[k].res    527   for (G4int k=0; k<ksteps+2; ++k) pols[k].resize(6);
528   for (G4int k=0; k<ksteps+2; ++k) polygons[k]    528   for (G4int k=0; k<ksteps+2; ++k) polygons[k] = &pols[k];
529   G4double r0[6],z0[6]; // contour with origin    529   G4double r0[6],z0[6]; // contour with original edges of triangle
530   G4double r1[6];       // shifted radii of ex    530   G4double r1[6];       // shifted radii of external edges of triangle
531                                                   531 
532   // main loop along triangles                    532   // main loop along triangles
533   pMin = kInfinity;                               533   pMin = kInfinity;
534   pMax =-kInfinity;                               534   pMax =-kInfinity;
535   G4int ntria = (G4int)triangles.size()/3;     << 535   G4int ntria = triangles.size()/3;
536   for (G4int i=0; i<ntria; ++i)                   536   for (G4int i=0; i<ntria; ++i)
537   {                                               537   {
538     G4int i3 = i*3;                               538     G4int i3 = i*3;
539     for (G4int k=0; k<3; ++k)                     539     for (G4int k=0; k<3; ++k)
540     {                                             540     {
541       G4int e0 = i3+k, e1 = (k<2) ? e0+1 : i3;    541       G4int e0 = i3+k, e1 = (k<2) ? e0+1 : i3;
542       G4int k2 = k*2;                             542       G4int k2 = k*2;
543       // set contour with original edges of tr    543       // set contour with original edges of triangle
544       r0[k2+0] = triangles[e0].x(); z0[k2+0] =    544       r0[k2+0] = triangles[e0].x(); z0[k2+0] = triangles[e0].y();
545       r0[k2+1] = triangles[e1].x(); z0[k2+1] =    545       r0[k2+1] = triangles[e1].x(); z0[k2+1] = triangles[e1].y();
546       // set shifted radii                        546       // set shifted radii
547       r1[k2+0] = r0[k2+0];                        547       r1[k2+0] = r0[k2+0];
548       r1[k2+1] = r0[k2+1];                        548       r1[k2+1] = r0[k2+1];
549       if (z0[k2+1] - z0[k2+0] <= 0) continue;     549       if (z0[k2+1] - z0[k2+0] <= 0) continue;
550       r1[k2+0] /= cosHalf;                        550       r1[k2+0] /= cosHalf;
551       r1[k2+1] /= cosHalf;                        551       r1[k2+1] /= cosHalf;
552     }                                             552     }
553                                                   553 
554     // rotate countour, set sequence of 6-side    554     // rotate countour, set sequence of 6-sided polygons
555     G4double sinCur = sinStart*cosHalf + cosSt    555     G4double sinCur = sinStart*cosHalf + cosStart*sinHalf;
556     G4double cosCur = cosStart*cosHalf - sinSt    556     G4double cosCur = cosStart*cosHalf - sinStart*sinHalf;
557     for (G4int j=0; j<6; ++j)                     557     for (G4int j=0; j<6; ++j)
558     {                                             558     {
559       pols[0][j].set(r0[j]*cosStart,r0[j]*sinS    559       pols[0][j].set(r0[j]*cosStart,r0[j]*sinStart,z0[j]);
560     }                                             560     }
561     for (G4int k=1; k<ksteps+1; ++k)              561     for (G4int k=1; k<ksteps+1; ++k)
562     {                                             562     {
563       for (G4int j=0; j<6; ++j)                   563       for (G4int j=0; j<6; ++j)
564       {                                           564       {
565         pols[k][j].set(r1[j]*cosCur,r1[j]*sinC    565         pols[k][j].set(r1[j]*cosCur,r1[j]*sinCur,z0[j]);
566       }                                           566       }
567       G4double sinTmp = sinCur;                   567       G4double sinTmp = sinCur;
568       sinCur = sinCur*cosStep + cosCur*sinStep    568       sinCur = sinCur*cosStep + cosCur*sinStep;
569       cosCur = cosCur*cosStep - sinTmp*sinStep    569       cosCur = cosCur*cosStep - sinTmp*sinStep;
570     }                                             570     }
571     for (G4int j=0; j<6; ++j)                     571     for (G4int j=0; j<6; ++j)
572     {                                             572     {
573       pols[ksteps+1][j].set(r0[j]*cosEnd,r0[j]    573       pols[ksteps+1][j].set(r0[j]*cosEnd,r0[j]*sinEnd,z0[j]);
574     }                                             574     }
575                                                   575 
576     // set sub-envelope and adjust extent         576     // set sub-envelope and adjust extent
577     G4double emin,emax;                           577     G4double emin,emax;
578     G4BoundingEnvelope benv(polygons);            578     G4BoundingEnvelope benv(polygons);
579     if (!benv.CalculateExtent(pAxis,pVoxelLimi    579     if (!benv.CalculateExtent(pAxis,pVoxelLimit,pTransform,emin,emax)) continue;
580     if (emin < pMin) pMin = emin;                 580     if (emin < pMin) pMin = emin;
581     if (emax > pMax) pMax = emax;                 581     if (emax > pMax) pMax = emax;
582     if (eminlim > pMin && emaxlim < pMax) retu    582     if (eminlim > pMin && emaxlim < pMax) return true; // max possible extent
583   }                                               583   }
584   return (pMin < pMax);                           584   return (pMin < pMax);
585 }                                                 585 }
586                                                   586 
587 // GetEntityType                                  587 // GetEntityType
588 //                                                588 //
589 G4GeometryType  G4GenericPolycone::GetEntityTy    589 G4GeometryType  G4GenericPolycone::GetEntityType() const
590 {                                                 590 {
591   return {"G4GenericPolycone"};                << 591   return G4String("G4GenericPolycone");
592 }                                                 592 }
593                                                   593 
594 // Clone                                          594 // Clone
595 //                                                595 //
596 // Make a clone of the object                     596 // Make a clone of the object
597 //                                                597 //
598 G4VSolid* G4GenericPolycone::Clone() const        598 G4VSolid* G4GenericPolycone::Clone() const
599 {                                                 599 {
600   return new G4GenericPolycone(*this);            600   return new G4GenericPolycone(*this);
601 }                                                 601 }
602                                                   602 
603 // StreamInfo                                     603 // StreamInfo
604 //                                                604 //
605 // Stream object contents to an output stream     605 // Stream object contents to an output stream
606 //                                                606 //
607 std::ostream& G4GenericPolycone::StreamInfo( s    607 std::ostream& G4GenericPolycone::StreamInfo( std::ostream& os ) const
608 {                                                 608 {
609   G4long oldprc = os.precision(16);            << 609   G4int oldprc = os.precision(16);
610   os << "-------------------------------------    610   os << "-----------------------------------------------------------\n"
611      << "    *** Dump for solid - " << GetName    611      << "    *** Dump for solid - " << GetName() << " ***\n"
612      << "    =================================    612      << "    ===================================================\n"
613      << " Solid type: G4GenericPolycone\n"        613      << " Solid type: G4GenericPolycone\n"
614      << " Parameters: \n"                         614      << " Parameters: \n"
615      << "    starting phi angle : " << startPh    615      << "    starting phi angle : " << startPhi/degree << " degrees \n"
616      << "    ending phi angle   : " << endPhi/    616      << "    ending phi angle   : " << endPhi/degree << " degrees \n";
617   G4int i=0;                                      617   G4int i=0;
618                                                   618 
619   os << "    number of RZ points: " << numCorn    619   os << "    number of RZ points: " << numCorner << "\n"
620      << "              RZ values (corners): \n    620      << "              RZ values (corners): \n";
621      for (i=0; i<numCorner; i++)                  621      for (i=0; i<numCorner; i++)
622      {                                            622      {
623        os << "                         "          623        os << "                         "
624           << corners[i].r << ", " << corners[i    624           << corners[i].r << ", " << corners[i].z << "\n";
625      }                                            625      }
626   os << "-------------------------------------    626   os << "-----------------------------------------------------------\n";
627   os.precision(oldprc);                           627   os.precision(oldprc);
628                                                   628 
629   return os;                                      629   return os;
630 }                                                 630 }
631                                                   631 
632 //////////////////////////////////////////////    632 //////////////////////////////////////////////////////////////////////////
633 //                                                633 //
634 // Return volume                                  634 // Return volume
635                                                   635 
636 G4double G4GenericPolycone::GetCubicVolume()      636 G4double G4GenericPolycone::GetCubicVolume()
637 {                                                 637 {
638   if (fCubicVolume == 0.)                         638   if (fCubicVolume == 0.)
639   {                                               639   {
640     G4double total = 0.;                          640     G4double total = 0.;
641     G4int nrz = GetNumRZCorner();                 641     G4int nrz = GetNumRZCorner();
642     G4PolyconeSideRZ a = GetCorner(nrz - 1);      642     G4PolyconeSideRZ a = GetCorner(nrz - 1);
643     for (G4int i=0; i<nrz; ++i)                   643     for (G4int i=0; i<nrz; ++i)
644     {                                             644     {
645       G4PolyconeSideRZ b = GetCorner(i);          645       G4PolyconeSideRZ b = GetCorner(i);
646       total += (b.r*b.r + b.r*a.r + a.r*a.r)*(    646       total += (b.r*b.r + b.r*a.r + a.r*a.r)*(b.z - a.z);
647       a = b;                                      647       a = b;
648     }                                             648     }
649     fCubicVolume = std::abs(total)*(GetEndPhi(    649     fCubicVolume = std::abs(total)*(GetEndPhi() - GetStartPhi())/6.;
650   }                                               650   }
651   return fCubicVolume;                            651   return fCubicVolume;
652 }                                                 652 }
653                                                   653 
654 //////////////////////////////////////////////    654 //////////////////////////////////////////////////////////////////////////
655 //                                                655 //
656 // Return surface area                            656 // Return surface area
657                                                   657 
658 G4double G4GenericPolycone::GetSurfaceArea()      658 G4double G4GenericPolycone::GetSurfaceArea()
659 {                                                 659 {
660   if (fSurfaceArea == 0.)                         660   if (fSurfaceArea == 0.)
661   {                                               661   {
662     // phi cut area                               662     // phi cut area
663     G4int nrz = GetNumRZCorner();                 663     G4int nrz = GetNumRZCorner();
664     G4double scut = 0.;                           664     G4double scut = 0.;
665     if (IsOpen())                                 665     if (IsOpen())
666     {                                             666     {
667       G4PolyconeSideRZ a = GetCorner(nrz - 1);    667       G4PolyconeSideRZ a = GetCorner(nrz - 1);
668       for (G4int i=0; i<nrz; ++i)                 668       for (G4int i=0; i<nrz; ++i)
669       {                                           669       {
670         G4PolyconeSideRZ b = GetCorner(i);        670         G4PolyconeSideRZ b = GetCorner(i);
671         scut += a.r*b.z - a.z*b.r;                671         scut += a.r*b.z - a.z*b.r;
672         a = b;                                    672         a = b;
673       }                                           673       }
674       scut = std::abs(scut);                      674       scut = std::abs(scut);
675     }                                             675     }
676     // lateral surface area                       676     // lateral surface area
677     G4double slat = 0;                            677     G4double slat = 0;
678     G4PolyconeSideRZ a = GetCorner(nrz - 1);      678     G4PolyconeSideRZ a = GetCorner(nrz - 1);
679     for (G4int i=0; i<nrz; ++i)                   679     for (G4int i=0; i<nrz; ++i)
680     {                                             680     {
681       G4PolyconeSideRZ b = GetCorner(i);          681       G4PolyconeSideRZ b = GetCorner(i);
682       G4double h = std::sqrt((b.r - a.r)*(b.r     682       G4double h = std::sqrt((b.r - a.r)*(b.r - a.r) + (b.z - a.z)*(b.z - a.z));
683       slat += (b.r + a.r)*h;                      683       slat += (b.r + a.r)*h;
684       a = b;                                      684       a = b;
685     }                                             685     }
686     slat *= (GetEndPhi() - GetStartPhi())/2.;     686     slat *= (GetEndPhi() - GetStartPhi())/2.;
687     fSurfaceArea = scut + slat;                   687     fSurfaceArea = scut + slat;
688   }                                               688   }
689   return fSurfaceArea;                            689   return fSurfaceArea;
690 }                                                 690 }
691                                                   691 
692 //////////////////////////////////////////////    692 //////////////////////////////////////////////////////////////////////////
693 //                                                693 //
694 // Set vector of surface elements, auxiliary m    694 // Set vector of surface elements, auxiliary method for sampling
695 // random points on surface                       695 // random points on surface
696                                                   696 
697 void G4GenericPolycone::SetSurfaceElements() c    697 void G4GenericPolycone::SetSurfaceElements() const
698 {                                                 698 {
699   fElements = new std::vector<G4GenericPolycon    699   fElements = new std::vector<G4GenericPolycone::surface_element>;
700   G4double sarea = 0.;                            700   G4double sarea = 0.;
701   G4int nrz = GetNumRZCorner();                   701   G4int nrz = GetNumRZCorner();
702                                                   702 
703   // set lateral surface elements                 703   // set lateral surface elements
704   G4double dphi = GetEndPhi() - GetStartPhi();    704   G4double dphi = GetEndPhi() - GetStartPhi();
705   G4int ia = nrz - 1;                             705   G4int ia = nrz - 1;
706   for (G4int ib=0; ib<nrz; ++ib)                  706   for (G4int ib=0; ib<nrz; ++ib)
707   {                                               707   {
708     G4PolyconeSideRZ a = GetCorner(ia);           708     G4PolyconeSideRZ a = GetCorner(ia);
709     G4PolyconeSideRZ b = GetCorner(ib);           709     G4PolyconeSideRZ b = GetCorner(ib);
710     G4GenericPolycone::surface_element selem;     710     G4GenericPolycone::surface_element selem;
711     selem.i0 = ia;                                711     selem.i0 = ia;
712     selem.i1 = ib;                                712     selem.i1 = ib;
713     selem.i2 = -1;                                713     selem.i2 = -1;
714     ia = ib;                                      714     ia = ib;
715     if (a.r == 0. && b.r == 0.) continue;         715     if (a.r == 0. && b.r == 0.) continue;
716     G4double h = std::sqrt((b.r - a.r)*(b.r -     716     G4double h = std::sqrt((b.r - a.r)*(b.r - a.r) + (b.z - a.z)*(b.z - a.z));
717     sarea += 0.5*dphi*(b.r + a.r)*h;              717     sarea += 0.5*dphi*(b.r + a.r)*h;
718     selem.area = sarea;                           718     selem.area = sarea;
719     fElements->push_back(selem);                  719     fElements->push_back(selem);
720   }                                               720   }
721                                                   721 
722   // set elements for phi cuts                    722   // set elements for phi cuts
723   if (IsOpen())                                   723   if (IsOpen())
724   {                                               724   {
725     G4TwoVectorList contourRZ;                    725     G4TwoVectorList contourRZ;
726     std::vector<G4int> triangles;                 726     std::vector<G4int> triangles;
727     for (G4int i=0; i<nrz; ++i)                   727     for (G4int i=0; i<nrz; ++i)
728     {                                             728     {
729       G4PolyconeSideRZ corner = GetCorner(i);     729       G4PolyconeSideRZ corner = GetCorner(i);
730       contourRZ.emplace_back(corner.r, corner. << 730       contourRZ.push_back(G4TwoVector(corner.r, corner.z));
731     }                                             731     }
732     G4GeomTools::TriangulatePolygon(contourRZ,    732     G4GeomTools::TriangulatePolygon(contourRZ, triangles);
733     auto  ntria = (G4int)triangles.size();     << 733     G4int ntria = triangles.size();
734     for (G4int i=0; i<ntria; i+=3)                734     for (G4int i=0; i<ntria; i+=3)
735     {                                             735     {
736       G4GenericPolycone::surface_element selem    736       G4GenericPolycone::surface_element selem;
737       selem.i0 = triangles[i];                    737       selem.i0 = triangles[i];
738       selem.i1 = triangles[i+1];                  738       selem.i1 = triangles[i+1];
739       selem.i2 = triangles[i+2];                  739       selem.i2 = triangles[i+2];
740       G4PolyconeSideRZ a = GetCorner(selem.i0)    740       G4PolyconeSideRZ a = GetCorner(selem.i0);
741       G4PolyconeSideRZ b = GetCorner(selem.i1)    741       G4PolyconeSideRZ b = GetCorner(selem.i1);
742       G4PolyconeSideRZ c = GetCorner(selem.i2)    742       G4PolyconeSideRZ c = GetCorner(selem.i2);
743       G4double stria =                            743       G4double stria =
744         std::abs(G4GeomTools::TriangleArea(a.r    744         std::abs(G4GeomTools::TriangleArea(a.r, a.z, b.r, b.z, c.r, c.z));
745       sarea += stria;                             745       sarea += stria;
746       selem.area = sarea;                         746       selem.area = sarea;
747       fElements->push_back(selem); // start ph    747       fElements->push_back(selem); // start phi
748       sarea += stria;                             748       sarea += stria;
749       selem.area = sarea;                         749       selem.area = sarea;
750       selem.i0 += nrz;                            750       selem.i0 += nrz;
751       fElements->push_back(selem); // end phi     751       fElements->push_back(selem); // end phi
752     }                                             752     }
753   }                                               753   }
754 }                                                 754 }
755                                                   755 
756 //////////////////////////////////////////////    756 //////////////////////////////////////////////////////////////////////////
757 //                                                757 //
758 // Generate random point on surface               758 // Generate random point on surface
759                                                   759 
760 G4ThreeVector G4GenericPolycone::GetPointOnSur    760 G4ThreeVector G4GenericPolycone::GetPointOnSurface() const
761 {                                                 761 {
762   // Set surface elements                         762   // Set surface elements
763   if (fElements == nullptr)                    << 763   if (!fElements)
764   {                                               764   {
765     G4AutoLock l(&surface_elementsMutex);         765     G4AutoLock l(&surface_elementsMutex);
766     SetSurfaceElements();                         766     SetSurfaceElements();
767     l.unlock();                                   767     l.unlock();
768   }                                               768   }
769                                                   769 
770   // Select surface element                       770   // Select surface element
771   G4GenericPolycone::surface_element selem;       771   G4GenericPolycone::surface_element selem;
772   selem = fElements->back();                      772   selem = fElements->back();
773   G4double select = selem.area*G4QuickRand();     773   G4double select = selem.area*G4QuickRand();
774   auto it = std::lower_bound(fElements->begin(    774   auto it = std::lower_bound(fElements->begin(), fElements->end(), select,
775                              [](const G4Generi    775                              [](const G4GenericPolycone::surface_element& x, G4double val)
776                              -> G4bool { retur    776                              -> G4bool { return x.area < val; });
777                                                   777 
778   // Generate random point                        778   // Generate random point
779   G4double r = 0, z = 0, phi = 0;                 779   G4double r = 0, z = 0, phi = 0;
780   G4double u = G4QuickRand();                     780   G4double u = G4QuickRand();
781   G4double v = G4QuickRand();                     781   G4double v = G4QuickRand();
782   G4int i0 = (*it).i0;                            782   G4int i0 = (*it).i0;
783   G4int i1 = (*it).i1;                            783   G4int i1 = (*it).i1;
784   G4int i2 = (*it).i2;                            784   G4int i2 = (*it).i2;
785   if (i2 < 0) // lateral surface                  785   if (i2 < 0) // lateral surface
786   {                                               786   {
787     G4PolyconeSideRZ p0 = GetCorner(i0);          787     G4PolyconeSideRZ p0 = GetCorner(i0);
788     G4PolyconeSideRZ p1 = GetCorner(i1);          788     G4PolyconeSideRZ p1 = GetCorner(i1);
789     if (p1.r < p0.r)                              789     if (p1.r < p0.r)
790     {                                             790     {
791       p0 = GetCorner(i1);                         791       p0 = GetCorner(i1);
792       p1 = GetCorner(i0);                         792       p1 = GetCorner(i0);
793     }                                             793     }
794     if (p1.r - p0.r < kCarTolerance) // cylind    794     if (p1.r - p0.r < kCarTolerance) // cylindrical surface
795     {                                             795     {
796       r = (p1.r - p0.r)*u + p0.r;                 796       r = (p1.r - p0.r)*u + p0.r;
797       z = (p1.z - p0.z)*u + p0.z;                 797       z = (p1.z - p0.z)*u + p0.z;
798     }                                             798     }
799     else // conical surface                       799     else // conical surface
800     {                                             800     {
801       r = std::sqrt(p1.r*p1.r*u + p0.r*p0.r*(1    801       r = std::sqrt(p1.r*p1.r*u + p0.r*p0.r*(1. - u));
802       z = p0.z + (p1.z - p0.z)*(r - p0.r)/(p1.    802       z = p0.z + (p1.z - p0.z)*(r - p0.r)/(p1.r - p0.r);
803     }                                             803     }
804     phi = (GetEndPhi() - GetStartPhi())*v + Ge    804     phi = (GetEndPhi() - GetStartPhi())*v + GetStartPhi();
805   }                                               805   }
806   else // phi cut                                 806   else // phi cut
807   {                                               807   {
808     G4int nrz = GetNumRZCorner();                 808     G4int nrz = GetNumRZCorner();
809     phi = (i0 < nrz) ? GetStartPhi() : GetEndP    809     phi = (i0 < nrz) ? GetStartPhi() : GetEndPhi();
810     if (i0 >= nrz) { i0 -= nrz; }                 810     if (i0 >= nrz) { i0 -= nrz; }
811     G4PolyconeSideRZ p0 = GetCorner(i0);          811     G4PolyconeSideRZ p0 = GetCorner(i0);
812     G4PolyconeSideRZ p1 = GetCorner(i1);          812     G4PolyconeSideRZ p1 = GetCorner(i1);
813     G4PolyconeSideRZ p2 = GetCorner(i2);          813     G4PolyconeSideRZ p2 = GetCorner(i2);
814     if (u + v > 1.) { u = 1. - u; v = 1. - v;     814     if (u + v > 1.) { u = 1. - u; v = 1. - v; }
815     r = (p1.r - p0.r)*u +  (p2.r - p0.r)*v + p    815     r = (p1.r - p0.r)*u +  (p2.r - p0.r)*v + p0.r;
816     z = (p1.z - p0.z)*u +  (p2.z - p0.z)*v + p    816     z = (p1.z - p0.z)*u +  (p2.z - p0.z)*v + p0.z;
817   }                                               817   }
818   return {r*std::cos(phi), r*std::sin(phi), z} << 818   return G4ThreeVector(r*std::cos(phi), r*std::sin(phi), z);
819 }                                                 819 }
820                                                   820 
821 //////////////////////////////////////////////    821 //////////////////////////////////////////////////////////////////////////
822 //                                                822 //
823 // CreatePolyhedron                               823 // CreatePolyhedron
824                                                   824 
825 G4Polyhedron* G4GenericPolycone::CreatePolyhed    825 G4Polyhedron* G4GenericPolycone::CreatePolyhedron() const
826 {                                                 826 {
827   std::vector<G4TwoVector> rz(numCorner);         827   std::vector<G4TwoVector> rz(numCorner);
828   for (G4int i = 0; i < numCorner; ++i)           828   for (G4int i = 0; i < numCorner; ++i)
829     rz[i].set(corners[i].r, corners[i].z);        829     rz[i].set(corners[i].r, corners[i].z);
830   return new G4PolyhedronPcon(startPhi, endPhi    830   return new G4PolyhedronPcon(startPhi, endPhi - startPhi, rz);
831 }                                                 831 }
832                                                   832 
833 #endif                                            833 #endif
834                                                   834