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Geant4/event/src/G4AdjointPosOnPhysVolGenerator.cc

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Diff markup

Differences between /event/src/G4AdjointPosOnPhysVolGenerator.cc (Version 11.3.0) and /event/src/G4AdjointPosOnPhysVolGenerator.cc (Version 6.1)


  1 //                                                  1 
  2 // *******************************************    
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  5 // * The  Geant4 software  is  copyright of th    
  6 // * the Geant4 Collaboration.  It is provided    
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 11 // * Neither the authors of this software syst    
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 14 // * regarding  this  software system or assum    
 15 // * use.  Please see the license in the file     
 16 // * for the full disclaimer and the limitatio    
 17 // *                                              
 18 // * This  code  implementation is the result     
 19 // * technical work of the GEANT4 collaboratio    
 20 // * By using,  copying,  modifying or  distri    
 21 // * any work based  on the software)  you  ag    
 22 // * use  in  resulting  scientific  publicati    
 23 // * acceptance of all terms of the Geant4 Sof    
 24 // *******************************************    
 25 //                                                
 26 // G4AdjointPosOnPhysVolGenerator class implem    
 27 //                                                
 28 // Author: L. Desorgher, SpaceIT GmbH - 01.06.    
 29 // Contract: ESA contract 21435/08/NL/AT          
 30 // Customer: ESA/ESTEC                            
 31 // -------------------------------------------    
 32                                                   
 33 #include "G4AdjointPosOnPhysVolGenerator.hh"      
 34 #include "G4VSolid.hh"                            
 35 #include "G4VoxelLimits.hh"                       
 36 #include "G4AffineTransform.hh"                   
 37 #include "Randomize.hh"                           
 38 #include "G4VPhysicalVolume.hh"                   
 39 #include "G4PhysicalVolumeStore.hh"               
 40 #include "G4LogicalVolumeStore.hh"                
 41                                                   
 42 G4ThreadLocal G4AdjointPosOnPhysVolGenerator*     
 43 G4AdjointPosOnPhysVolGenerator::theInstance =     
 44                                                   
 45 // -------------------------------------------    
 46 //                                                
 47 G4AdjointPosOnPhysVolGenerator* G4AdjointPosOn    
 48 {                                                 
 49   if(theInstance == nullptr)                      
 50   {                                               
 51     theInstance = new G4AdjointPosOnPhysVolGen    
 52   }                                               
 53   return theInstance;                             
 54 }                                                 
 55                                                   
 56 // -------------------------------------------    
 57 //                                                
 58 G4VPhysicalVolume*                                
 59 G4AdjointPosOnPhysVolGenerator::DefinePhysical    
 60 {                                                 
 61   thePhysicalVolume = nullptr;                    
 62   theSolid = nullptr;                             
 63   G4PhysicalVolumeStore* thePhysVolStore = G4P    
 64   for ( unsigned int i=0; i< thePhysVolStore->    
 65   {                                               
 66     G4String vol_name =(*thePhysVolStore)[i]->    
 67     if (vol_name.empty())                         
 68     {                                             
 69       vol_name = (*thePhysVolStore)[i]->GetLog    
 70     }                                             
 71     if (vol_name == aName)                        
 72     {                                             
 73       thePhysicalVolume = (*thePhysVolStore)[i    
 74     }                                             
 75   }                                               
 76   if (thePhysicalVolume != nullptr)               
 77   {                                               
 78     theSolid = thePhysicalVolume->GetLogicalVo    
 79     ComputeTransformationFromPhysVolToWorld();    
 80   }                                               
 81   else                                            
 82   {                                               
 83     G4cout << "The physical volume with name "    
 84            << " does not exist!!" << G4endl;      
 85     G4cout << "Before generating a source on a    
 86            << "of a volume you should select a    
 87            << G4endl;                             
 88   }                                               
 89   return thePhysicalVolume;                       
 90 }                                                 
 91                                                   
 92 // -------------------------------------------    
 93 //                                                
 94 void                                              
 95 G4AdjointPosOnPhysVolGenerator::DefinePhysical    
 96 {                                                 
 97   thePhysicalVolume = DefinePhysicalVolume(aNa    
 98 }                                                 
 99                                                   
100 // -------------------------------------------    
101 //                                                
102 G4double G4AdjointPosOnPhysVolGenerator::Compu    
103 {                                                 
104   return ComputeAreaOfExtSurface(theSolid);       
105 }                                                 
106                                                   
107 // -------------------------------------------    
108 //                                                
109 G4double G4AdjointPosOnPhysVolGenerator::Compu    
110 {                                                 
111   return ComputeAreaOfExtSurface(theSolid,NSta    
112 }                                                 
113                                                   
114 // -------------------------------------------    
115 //                                                
116 G4double G4AdjointPosOnPhysVolGenerator::Compu    
117 {                                                 
118   return ComputeAreaOfExtSurface(theSolid,eps)    
119 }                                                 
120                                                   
121 // -------------------------------------------    
122 //                                                
123 G4double                                          
124 G4AdjointPosOnPhysVolGenerator::ComputeAreaOfE    
125 {                                                 
126   return ComputeAreaOfExtSurface(aSolid,1.e-3)    
127 }                                                 
128                                                   
129 // -------------------------------------------    
130 //                                                
131 G4double                                          
132 G4AdjointPosOnPhysVolGenerator::ComputeAreaOfE    
133                                                   
134 {                                                 
135   if (ModelOfSurfaceSource == "OnSolid")          
136   {                                               
137     if (UseSphere)                                
138     {                                             
139       return ComputeAreaOfExtSurfaceStartingFr    
140     }                                             
141                                                   
142     return ComputeAreaOfExtSurfaceStartingFrom    
143   }                                               
144                                                   
145   G4ThreeVector p, dir;                           
146   if (ModelOfSurfaceSource == "ExternalSphere"    
147   {                                               
148     return GenerateAPositionOnASphereBoundary(    
149   }                                               
150                                                   
151   return GenerateAPositionOnABoxBoundary(aSoli    
152 }                                                 
153                                                   
154 // -------------------------------------------    
155 //                                                
156 G4double                                          
157 G4AdjointPosOnPhysVolGenerator::ComputeAreaOfE    
158                                                   
159 {                                                 
160   auto  Nstats = G4int(1./(eps*eps));             
161   return ComputeAreaOfExtSurface(aSolid,Nstats    
162 }                                                 
163                                                   
164 // -------------------------------------------    
165 //                                                
166 void G4AdjointPosOnPhysVolGenerator::             
167 GenerateAPositionOnTheExtSurfaceOfASolid(G4VSo    
168                                          G4Thr    
169 {                                                 
170   if (ModelOfSurfaceSource == "OnSolid")          
171   {                                               
172     GenerateAPositionOnASolidBoundary(aSolid,     
173     return;                                       
174   }                                               
175   if (ModelOfSurfaceSource == "ExternalSphere"    
176   {                                               
177     GenerateAPositionOnASphereBoundary(aSolid,    
178     return;                                       
179   }                                               
180   GenerateAPositionOnABoxBoundary(aSolid, p, d    
181   return;                                         
182 }                                                 
183                                                   
184 // -------------------------------------------    
185 //                                                
186 void G4AdjointPosOnPhysVolGenerator::             
187 GenerateAPositionOnTheExtSurfaceOfTheSolid(G4T    
188                                            G4T    
189 {                                                 
190   GenerateAPositionOnTheExtSurfaceOfASolid(the    
191 }                                                 
192                                                   
193 // -------------------------------------------    
194 //                                                
195 G4double G4AdjointPosOnPhysVolGenerator::         
196 ComputeAreaOfExtSurfaceStartingFromBox(G4VSoli    
197 {                                                 
198   if ( Nstat <= 0 ) { return 0.; }                
199   G4double area=1.;                               
200   G4int i=0, j=0;                                 
201   while (i<Nstat)                                 
202   {                                               
203     G4ThreeVector p, direction;                   
204     area = GenerateAPositionOnABoxBoundary( aS    
205     G4double dist_to_in = aSolid->DistanceToIn    
206     if (dist_to_in<kInfinity/2.) { ++i; }         
207     ++j;                                          
208   }                                               
209   area=area*G4double(i)/G4double(j);              
210   return area;                                    
211 }                                                 
212                                                   
213 // -------------------------------------------    
214 //                                                
215 G4double G4AdjointPosOnPhysVolGenerator::         
216 ComputeAreaOfExtSurfaceStartingFromSphere(G4VS    
217 {                                                 
218   if ( Nstat <= 0 ) { return 0.; }                
219   G4double area=1.;                               
220   G4int i=0, j=0;                                 
221   while (i<Nstat)                                 
222   {                                               
223     G4ThreeVector p, direction;                   
224     area = GenerateAPositionOnASphereBoundary(    
225     G4double dist_to_in = aSolid->DistanceToIn    
226     if (dist_to_in<kInfinity/2.)  { ++i; }        
227     ++j;                                          
228   }                                               
229   area=area*G4double(i)/G4double(j);              
230   return area;                                    
231 }                                                 
232                                                   
233 // -------------------------------------------    
234 //                                                
235 void G4AdjointPosOnPhysVolGenerator::             
236 GenerateAPositionOnASolidBoundary(G4VSolid* aS    
237                                   G4ThreeVecto    
238 {                                                 
239   G4bool find_pos = false;                        
240   while (!find_pos)                               
241   {                                               
242     if (UseSphere)                                
243     {                                             
244       GenerateAPositionOnASphereBoundary( aSol    
245     }                                             
246     else                                          
247     {                                             
248       GenerateAPositionOnABoxBoundary( aSolid,    
249     }                                             
250     G4double dist_to_in = aSolid->DistanceToIn    
251     if (dist_to_in<kInfinity/2.)                  
252     {                                             
253       find_pos = true;                            
254       p += 0.999999*direction*dist_to_in;         
255     }                                             
256   }                                               
257 }                                                 
258                                                   
259 // -------------------------------------------    
260 //                                                
261 G4double G4AdjointPosOnPhysVolGenerator::         
262 GenerateAPositionOnASphereBoundary(G4VSolid* a    
263                                    G4ThreeVect    
264 {                                                 
265   G4double minX,maxX,minY,maxY,minZ,maxZ;         
266                                                   
267   // values needed for CalculateExtent signatu    
268                                                   
269   G4VoxelLimits limit;                // Unlim    
270   G4AffineTransform origin;                       
271                                                   
272   // min max extents of pSolid along X,Y,Z        
273                                                   
274   aSolid->CalculateExtent(kXAxis,limit,origin,    
275   aSolid->CalculateExtent(kYAxis,limit,origin,    
276   aSolid->CalculateExtent(kZAxis,limit,origin,    
277                                                   
278   G4ThreeVector center = G4ThreeVector((minX+m    
279                                        (minY+m    
280                                        (minZ+m    
281   G4double dX=(maxX-minX)/2.;                     
282   G4double dY=(maxY-minY)/2.;                     
283   G4double dZ=(maxZ-minZ)/2.;                     
284   G4double scale=1.01;                            
285   G4double r=scale*std::sqrt(dX*dX+dY*dY+dZ*dZ    
286                                                   
287   G4double cos_th2 = G4UniformRand();             
288   G4double theta = std::acos(std::sqrt(cos_th2    
289   G4double phi=G4UniformRand()*CLHEP::twopi;      
290   direction.setRThetaPhi(1.,theta,phi);           
291   direction=-direction;                           
292   G4double cos_th = (1.-2.*G4UniformRand());      
293   theta = std::acos(cos_th);                      
294   if (G4UniformRand() < 0.5)  { theta=CLHEP::p    
295   phi=G4UniformRand()*CLHEP::twopi;               
296   p.setRThetaPhi(r,theta,phi);                    
297   p+=center;                                      
298   direction.rotateY(theta);                       
299   direction.rotateZ(phi);                         
300   return 4.*CLHEP::pi*r*r;;                       
301 }                                                 
302                                                   
303 // -------------------------------------------    
304 //                                                
305 G4double G4AdjointPosOnPhysVolGenerator::         
306 GenerateAPositionOnABoxBoundary(G4VSolid* aSol    
307                                 G4ThreeVector&    
308 {                                                 
309                                                   
310   G4double ran_var,px,py,pz,minX,maxX,minY,max    
311                                                   
312   // values needed for CalculateExtent signatu    
313                                                   
314   G4VoxelLimits limit;                // Unlim    
315   G4AffineTransform origin;                       
316                                                   
317   // min max extents of pSolid along X,Y,Z        
318                                                   
319   aSolid->CalculateExtent(kXAxis,limit,origin,    
320   aSolid->CalculateExtent(kYAxis,limit,origin,    
321   aSolid->CalculateExtent(kZAxis,limit,origin,    
322                                                   
323   G4double scale=.1;                              
324   minX-=scale*std::abs(minX);                     
325   minY-=scale*std::abs(minY);                     
326   minZ-=scale*std::abs(minZ);                     
327   maxX+=scale*std::abs(maxX);                     
328   maxY+=scale*std::abs(maxY);                     
329   maxZ+=scale*std::abs(maxZ);                     
330                                                   
331   G4double dX=(maxX-minX);                        
332   G4double dY=(maxY-minY);                        
333   G4double dZ=(maxZ-minZ);                        
334                                                   
335   G4double XY_prob=2.*dX*dY;                      
336   G4double YZ_prob=2.*dY*dZ;                      
337   G4double ZX_prob=2.*dZ*dX;                      
338   G4double area=XY_prob+YZ_prob+ZX_prob;          
339   XY_prob/=area;                                  
340   YZ_prob/=area;                                  
341   ZX_prob/=area;                                  
342                                                   
343   ran_var=G4UniformRand();                        
344   G4double cos_th2 = G4UniformRand();             
345   G4double sth = std::sqrt(1.-cos_th2);           
346   G4double cth = std::sqrt(cos_th2);              
347   G4double phi = G4UniformRand()*CLHEP::twopi;    
348   G4double dirX = sth*std::cos(phi);              
349   G4double dirY = sth*std::sin(phi);              
350   G4double dirZ = cth;                            
351   if (ran_var <=XY_prob)  // on the XY faces      
352   {                                               
353     G4double ran_var1=ran_var/XY_prob;            
354     G4double ranX=ran_var1;                       
355     if (ran_var1<=0.5)                            
356     {                                             
357       pz=minZ;                                    
358       direction=G4ThreeVector(dirX,dirY,dirZ);    
359       ranX=ran_var1*2.;                           
360     }                                             
361     else                                          
362     {                                             
363       pz=maxZ;                                    
364       direction=-G4ThreeVector(dirX,dirY,dirZ)    
365       ranX=(ran_var1-0.5)*2.;                     
366     }                                             
367     G4double ranY=G4UniformRand();                
368     px=minX+(maxX-minX)*ranX;                     
369     py=minY+(maxY-minY)*ranY;                     
370   }                                               
371   else if (ran_var <=(XY_prob+YZ_prob))  // on    
372   {                                               
373     G4double ran_var1=(ran_var-XY_prob)/YZ_pro    
374     G4double ranY=ran_var1;                       
375     if (ran_var1<=0.5)                            
376     {                                             
377       px=minX;                                    
378       direction=G4ThreeVector(dirZ,dirX,dirY);    
379       ranY=ran_var1*2.;                           
380     }                                             
381     else                                          
382     {                                             
383       px=maxX;                                    
384       direction=-G4ThreeVector(dirZ,dirX,dirY)    
385       ranY=(ran_var1-0.5)*2.;                     
386     }                                             
387     G4double ranZ=G4UniformRand();                
388     py=minY+(maxY-minY)*ranY;                     
389     pz=minZ+(maxZ-minZ)*ranZ;                     
390   }                                               
391   else  // on the ZX faces                        
392   {                                               
393     G4double ran_var1=(ran_var-XY_prob-YZ_prob    
394     G4double ranZ=ran_var1;                       
395     if (ran_var1<=0.5)                            
396     {                                             
397       py=minY;                                    
398       direction=G4ThreeVector(dirY,dirZ,dirX);    
399       ranZ=ran_var1*2.;                           
400     }                                             
401     else                                          
402     {                                             
403       py=maxY;                                    
404       direction=-G4ThreeVector(dirY,dirZ,dirX)    
405       ranZ=(ran_var1-0.5)*2.;                     
406     }                                             
407     G4double ranX=G4UniformRand();                
408     px=minX+(maxX-minX)*ranX;                     
409     pz=minZ+(maxZ-minZ)*ranZ;                     
410   }                                               
411                                                   
412   p=G4ThreeVector(px,py,pz);                      
413   return area;                                    
414 }                                                 
415                                                   
416 // -------------------------------------------    
417 //                                                
418 void G4AdjointPosOnPhysVolGenerator::             
419 GenerateAPositionOnTheExtSurfaceOfThePhysicalV    
420                                                   
421 {                                                 
422   if (thePhysicalVolume == nullptr)               
423   {                                               
424     G4cout << "Before generating a source on a    
425            << "of volume you should select a p    
426     return;                                       
427   }                                               
428   GenerateAPositionOnTheExtSurfaceOfTheSolid(p    
429   p = theTransformationFromPhysVolToWorld.Tran    
430   direction = theTransformationFromPhysVolToWo    
431 }                                                 
432                                                   
433 // -------------------------------------------    
434 //                                                
435 void G4AdjointPosOnPhysVolGenerator::             
436 GenerateAPositionOnTheExtSurfaceOfThePhysicalV    
437                                                   
438                                                   
439 {                                                 
440   GenerateAPositionOnTheExtSurfaceOfThePhysica    
441   costh_to_normal = CosThDirComparedToNormal;     
442 }                                                 
443                                                   
444 // -------------------------------------------    
445 //                                                
446 void G4AdjointPosOnPhysVolGenerator::ComputeTr    
447 {                                                 
448   G4VPhysicalVolume* daughter = thePhysicalVol    
449   G4LogicalVolume* mother = thePhysicalVolume-    
450   theTransformationFromPhysVolToWorld = G4Affi    
451   G4PhysicalVolumeStore* thePhysVolStore = G4P    
452   while (mother != nullptr)                       
453   {                                               
454     theTransformationFromPhysVolToWorld *=        
455       G4AffineTransform(daughter->GetFrameRota    
456                         daughter->GetObjectTra    
457     for ( unsigned int i=0; i<thePhysVolStore-    
458     {                                             
459       if ((*thePhysVolStore)[i]->GetLogicalVol    
460       {                                           
461         daughter = (*thePhysVolStore)[i];         
462         mother = daughter->GetMotherLogical();    
463         break;                                    
464       }                                           
465     }                                             
466   }                                               
467 }                                                 
468