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Geant4/processes/electromagnetic/utils/src/G4TransportationWithMsc.cc

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Differences between /processes/electromagnetic/utils/src/G4TransportationWithMsc.cc (Version 11.3.0) and /processes/electromagnetic/utils/src/G4TransportationWithMsc.cc (Version 6.0.p1)


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 25 //                                                
 26 // G4TransportationWithMsc                        
 27 //                                                
 28 // Class Description:                             
 29 //                                                
 30 // It is a generic process of transportation w    
 31 // in the step limitation and propagation.        
 32 //                                                
 33 // Original author: Jonas Hahnfeld, 2022          
 34                                                   
 35 // -------------------------------------------    
 36 //                                                
 37 //....oooOO0OOooo........oooOO0OOooo........oo    
 38 //....oooOO0OOooo........oooOO0OOooo........oo    
 39                                                   
 40 #include "G4TransportationWithMsc.hh"             
 41                                                   
 42 #include "G4DynamicParticle.hh"                   
 43 #include "G4Electron.hh"                          
 44 #include "G4EmConfigurator.hh"                    
 45 #include "G4EmDataHandler.hh"                     
 46 #include "G4LossTableBuilder.hh"                  
 47 #include "G4LossTableManager.hh"                  
 48 #include "G4ParticleChangeForGamma.hh"            
 49 #include "G4ParticleChangeForMSC.hh"              
 50 #include "G4PhysicalConstants.hh"                 
 51 #include "G4PhysicsTableHelper.hh"                
 52 #include "G4PhysicsVector.hh"                     
 53 #include "G4ProductionCutsTable.hh"               
 54 #include "G4Step.hh"                              
 55 #include "G4StepPoint.hh"                         
 56 #include "G4StepStatus.hh"                        
 57 #include "G4Track.hh"                             
 58 #include "G4TransportationProcessType.hh"         
 59 #include "G4VMscModel.hh"                         
 60                                                   
 61 //....oooOO0OOooo........oooOO0OOooo........oo    
 62                                                   
 63 static constexpr G4double kLowestKinEnergy = 1    
 64 static constexpr G4double kGeomMin = 0.05 * CL    
 65 static constexpr G4double kMinDisplacement2 =     
 66                                                   
 67 //....oooOO0OOooo........oooOO0OOooo........oo    
 68                                                   
 69 G4TransportationWithMsc::G4TransportationWithM    
 70   : G4Transportation(verbosity, "Transportatio    
 71 {                                                 
 72   SetProcessSubType(static_cast<G4int>(TRANSPO    
 73   SetVerboseLevel(1);                             
 74                                                   
 75   fEmManager = G4LossTableManager::Instance();    
 76   fModelManager = new G4EmModelManager;           
 77                                                   
 78   if (type == ScatteringType::MultipleScatteri    
 79     fParticleChangeForMSC = new G4ParticleChan    
 80   }                                               
 81   else if (type == ScatteringType::SingleScatt    
 82     fParticleChangeForSS = new G4ParticleChang    
 83     fSecondariesSS = new std::vector<G4Dynamic    
 84   }                                               
 85                                                   
 86   G4ThreeVector zero;                             
 87   fSubStepDynamicParticle = new G4DynamicParti    
 88   fSubStepTrack = new G4Track(fSubStepDynamicP    
 89   fSubStep = new G4Step;                          
 90   fSubStepTrack->SetStep(fSubStep);               
 91 }                                                 
 92                                                   
 93 //....oooOO0OOooo........oooOO0OOooo........oo    
 94                                                   
 95 G4TransportationWithMsc::~G4TransportationWith    
 96 {                                                 
 97   delete fModelManager;                           
 98   delete fParticleChangeForMSC;                   
 99   delete fEmData;                                 
100   delete fParticleChangeForSS;                    
101   delete fSecondariesSS;                          
102                                                   
103   // fSubStepDynamicParticle is owned and also    
104   delete fSubStepTrack;                           
105   delete fSubStep;                                
106 }                                                 
107                                                   
108 //....oooOO0OOooo........oooOO0OOooo........oo    
109                                                   
110 void G4TransportationWithMsc::AddMscModel(G4VM    
111                                           cons    
112 {                                                 
113   if (fType != ScatteringType::MultipleScatter    
114     G4Exception("G4TransportationWithMsc::AddM    
115                 "not allowed unless type == Mu    
116   }                                               
117                                                   
118   fModelManager->AddEmModel(order, mscModel, n    
119   mscModel->SetParticleChange(fParticleChangeF    
120 }                                                 
121                                                   
122 //....oooOO0OOooo........oooOO0OOooo........oo    
123                                                   
124 void G4TransportationWithMsc::AddSSModel(G4VEm    
125 {                                                 
126   if (fType != ScatteringType::SingleScatterin    
127     G4Exception("G4TransportationWithMsc::AddS    
128                 "not allowed unless type == Si    
129   }                                               
130                                                   
131   fModelManager->AddEmModel(order, model, null    
132   model->SetPolarAngleLimit(0.0);                 
133   model->SetParticleChange(fParticleChangeForS    
134 }                                                 
135                                                   
136 //....oooOO0OOooo........oooOO0OOooo........oo    
137                                                   
138 void G4TransportationWithMsc::PreparePhysicsTa    
139 {                                                 
140   if (nullptr == fFirstParticle) {                
141     fFirstParticle = &part;                       
142     G4VMultipleScattering* ptr = nullptr;         
143     auto emConfigurator = fEmManager->EmConfig    
144     emConfigurator->PrepareModels(&part, ptr,     
145   }                                               
146                                                   
147   if (fFirstParticle == &part) {                  
148     G4bool master = fEmManager->IsMaster();       
149     G4LossTableBuilder* bld = fEmManager->GetT    
150     G4bool baseMat = bld->GetBaseMaterialFlag(    
151     const auto* theParameters = G4EmParameters    
152                                                   
153     if (master) {                                 
154       SetVerboseLevel(theParameters->Verbose()    
155     }                                             
156     else {                                        
157       SetVerboseLevel(theParameters->WorkerVer    
158     }                                             
159                                                   
160     const G4int numberOfModels = fModelManager    
161     if (fType == ScatteringType::MultipleScatt    
162       for (G4int i = 0; i < numberOfModels; ++    
163         auto msc = static_cast<G4VMscModel*>(f    
164         msc->SetPolarAngleLimit(theParameters-    
165         G4double emax = std::min(msc->HighEner    
166         msc->SetHighEnergyLimit(emax);            
167         msc->SetUseBaseMaterials(baseMat);        
168       }                                           
169     }                                             
170     else if (fType == ScatteringType::SingleSc    
171       if (master) {                               
172         if (fEmData == nullptr) {                 
173           fEmData = new G4EmDataHandler(2);       
174         }                                         
175                                                   
176         fLambdaTable = fEmData->MakeTable(0);     
177         bld->InitialiseBaseMaterials(fLambdaTa    
178       }                                           
179     }                                             
180                                                   
181     fCuts = fModelManager->Initialise(fFirstPa    
182   }                                               
183 }                                                 
184                                                   
185 //....oooOO0OOooo........oooOO0OOooo........oo    
186                                                   
187 void G4TransportationWithMsc::BuildPhysicsTabl    
188 {                                                 
189   if (fFirstParticle == &part) {                  
190     fEmManager->BuildPhysicsTable(fFirstPartic    
191                                                   
192     if (fEmManager->IsMaster()) {                 
193       if (fType == ScatteringType::SingleScatt    
194         const auto* theParameters = G4EmParame    
195         G4LossTableBuilder* bld = fEmManager->    
196         const G4ProductionCutsTable* theCouple    
197           G4ProductionCutsTable::GetProduction    
198         std::size_t numOfCouples = theCoupleTa    
199                                                   
200         G4double emin = theParameters->MinKinE    
201         G4double emax = theParameters->MaxKinE    
202                                                   
203         G4double scale = emax / emin;             
204         G4int nbin = theParameters->NumberOfBi    
205         scale = nbin / G4Log(scale);              
206                                                   
207         G4int bin = G4lrint(scale * G4Log(emax    
208         bin = std::max(bin, 5);                   
209                                                   
210         for (std::size_t i = 0; i < numOfCoupl    
211           if (!bld->GetFlag(i)) continue;         
212                                                   
213           // Create physics vector and fill it    
214           const G4MaterialCutsCouple* couple =    
215                                                   
216           auto* aVector = new G4PhysicsLogVect    
217           fModelManager->FillLambdaVector(aVec    
218           aVector->FillSecondDerivatives();       
219           G4PhysicsTableHelper::SetPhysicsVect    
220         }                                         
221       }                                           
222     }                                             
223     else {                                        
224       const auto masterProcess = static_cast<c    
225                                                   
226       // Initialisation of models.                
227       const G4int numberOfModels = fModelManag    
228       if (fType == ScatteringType::MultipleSca    
229         for (G4int i = 0; i < numberOfModels;     
230           auto msc = static_cast<G4VMscModel*>    
231           auto msc0 = static_cast<G4VMscModel*    
232           msc->SetCrossSectionTable(msc0->GetC    
233           msc->InitialiseLocal(fFirstParticle,    
234         }                                         
235       }                                           
236       else if (fType == ScatteringType::Single    
237         this->fLambdaTable = masterProcess->fL    
238       }                                           
239     }                                             
240   }                                               
241                                                   
242   if (!G4EmParameters::Instance()->IsPrintLock    
243     G4cout << G4endl;                             
244     G4cout << GetProcessName() << ": for " <<     
245     if (fMultipleSteps) {                         
246       G4cout << " (multipleSteps: 1)";            
247     }                                             
248     G4cout << G4endl;                             
249     fModelManager->DumpModelList(G4cout, verbo    
250   }                                               
251 }                                                 
252                                                   
253 //....oooOO0OOooo........oooOO0OOooo........oo    
254                                                   
255 void G4TransportationWithMsc::StartTracking(G4    
256 {                                                 
257   auto* currParticle = track->GetParticleDefin    
258   fIonisation = fEmManager->GetEnergyLossProce    
259                                                   
260   fSubStepDynamicParticle->SetDefinition(currP    
261                                                   
262   const G4int numberOfModels = fModelManager->    
263   if (fType == ScatteringType::MultipleScatter    
264     for (G4int i = 0; i < numberOfModels; ++i)    
265       auto msc = static_cast<G4VMscModel*>(fMo    
266       msc->StartTracking(track);                  
267       msc->SetIonisation(fIonisation, currPart    
268     }                                             
269   }                                               
270                                                   
271   // Ensure that field propagation state is al    
272   G4Transportation::StartTracking(track);         
273 }                                                 
274                                                   
275 //....oooOO0OOooo........oooOO0OOooo........oo    
276                                                   
277 G4double G4TransportationWithMsc::AlongStepGet    
278                                                   
279                                                   
280                                                   
281                                                   
282 {                                                 
283   *selection = NotCandidateForSelection;          
284                                                   
285   const G4double physStepLimit = currentMinimu    
286                                                   
287   switch (fType) {                                
288     case ScatteringType::MultipleScattering: {    
289       // Select the MSC model for the current     
290       G4VMscModel* mscModel = nullptr;            
291       const G4double ekin = track.GetKineticEn    
292       const auto* couple = track.GetMaterialCu    
293       const auto* particleDefinition = track.G    
294       if (physStepLimit > kGeomMin) {             
295         G4double ekinForSelection = ekin;         
296         G4double pdgMass = particleDefinition-    
297         if (pdgMass > CLHEP::GeV) {               
298           ekinForSelection *= proton_mass_c2 /    
299         }                                         
300                                                   
301         if (ekinForSelection >= kLowestKinEner    
302           mscModel = static_cast<G4VMscModel*>    
303             fModelManager->SelectModel(ekinFor    
304           if (mscModel == nullptr) {              
305             G4Exception("G4TransportationWithM    
306                         "no MSC model found");    
307           }                                       
308           if (!mscModel->IsActive(ekinForSelec    
309             mscModel = nullptr;                   
310           }                                       
311         }                                         
312       }                                           
313                                                   
314       // Call the MSC model to potentially lim    
315       // geometric path length.                   
316       if (mscModel != nullptr) {                  
317         mscModel->SetCurrentCouple(couple);       
318                                                   
319         // Use the provided track for the firs    
320         const G4Track* currentTrackPtr = &trac    
321                                                   
322         G4double currentSafety = proposedSafet    
323         G4double currentEnergy = ekin;            
324                                                   
325         G4double stepLimitLeft = physStepLimit    
326         G4double totalGeometryStepLength = 0,     
327         G4bool firstStep = true, continueStepp    
328                                                   
329         do {                                      
330           G4double gPathLength = stepLimitLeft    
331           G4double tPathLength =                  
332             mscModel->ComputeTruePathLengthLim    
333           G4bool mscLimitsStep = (tPathLength     
334           if (!fMultipleSteps && mscLimitsStep    
335             // MSC limits the step.               
336             *selection = CandidateForSelection    
337           }                                       
338                                                   
339           if (!firstStep) {                       
340             // Move the navigator to where the    
341             fLinearNavigator->LocateGlobalPoin    
342           }                                       
343                                                   
344           G4GPILSelection transportSelection;     
345           G4double geometryStepLength = G4Tran    
346             *currentTrackPtr, previousStepSize    
347           if (geometryStepLength < gPathLength    
348             // Transportation limits the step,    
349             *selection = CandidateForSelection    
350             continueStepping = false;             
351           }                                       
352           if (fTransportEndKineticEnergy != cu    
353             // Field propagation changed the e    
354             // estimate the continuous energy     
355             continueStepping = false;             
356           }                                       
357                                                   
358           if (firstStep) {                        
359             proposedSafety = currentSafety;       
360           }                                       
361           totalGeometryStepLength += geometryS    
362                                                   
363           // Sample MSC direction change and d    
364           const G4double range = mscModel->Get    
365                                                   
366           tPathLength = mscModel->ComputeTrueS    
367                                                   
368           // Protect against wrong t->g->t con    
369           tPathLength = std::min(tPathLength,     
370                                                   
371           totalTruePathLength += tPathLength;     
372           if (*selection != CandidateForSelect    
373             // If neither MSC nor transportati    
374             // distance we want - make sure we    
375             continueStepping = false;             
376           }                                       
377           else if (tPathLength >= range) {        
378             // The particle will stop, exit th    
379             continueStepping = false;             
380           }                                       
381           else {                                  
382             stepLimitLeft -= tPathLength;         
383           }                                       
384                                                   
385           // Do not sample scattering at the l    
386           if (tPathLength < range && tPathLeng    
387             static constexpr G4double minSafet    
388             static constexpr G4double sFact =     
389                                                   
390             // The call to SampleScattering()     
391             // direction into fParticleChangeF    
392             // 1) Make sure the momentum direc    
393             fParticleChangeForMSC->ProposeMome    
394             // 2) Call SampleScattering(), whi    
395             const G4ThreeVector displacement =    
396               mscModel->SampleScattering(fTran    
397             // 3) Get the changed direction.      
398             fTransportEndMomentumDir = *fParti    
399                                                   
400             const G4double r2 = displacement.m    
401             if (r2 > kMinDisplacement2) {         
402               G4bool positionChanged = true;      
403               G4double dispR = std::sqrt(r2);     
404               G4double postSafety =               
405                 sFact * fpSafetyHelper->Comput    
406                                                   
407               // Far away from geometry bounda    
408               if (postSafety > 0.0 && dispR <=    
409                 fTransportEndPosition += displ    
410                                                   
411                 // Near the boundary              
412               }                                   
413               else {                              
414                 // displaced point is definite    
415                 if (dispR < postSafety) {         
416                   fTransportEndPosition += dis    
417                                                   
418                   // reduced displacement         
419                 }                                 
420                 else if (postSafety > kGeomMin    
421                   fTransportEndPosition += dis    
422                                                   
423                   // very small postSafety        
424                 }                                 
425                 else {                            
426                   positionChanged = false;        
427                 }                                 
428               }                                   
429               if (positionChanged) {              
430                 fpSafetyHelper->ReLocateWithin    
431               }                                   
432             }                                     
433           }                                       
434                                                   
435           if (continueStepping) {                 
436             // Update safety according to the     
437             if (currentSafety < fEndPointDista    
438               currentSafety = 0;                  
439             }                                     
440             else {                                
441               currentSafety -= fEndPointDistan    
442             }                                     
443                                                   
444             // Update the kinetic energy accor    
445             currentEnergy = mscModel->GetEnerg    
446                                                   
447             // From now on, use the track that    
448             currentTrackPtr = fSubStepTrack;      
449                                                   
450             fSubStepDynamicParticle->SetKineti    
451             fSubStepDynamicParticle->SetMoment    
452             fSubStepTrack->SetPosition(fTransp    
453                                                   
454             G4StepPoint& subPreStepPoint = *fS    
455             subPreStepPoint.SetMaterialCutsCou    
456             subPreStepPoint.SetPosition(fTrans    
457             subPreStepPoint.SetSafety(currentS    
458             subPreStepPoint.SetStepStatus(fAlo    
459           }                                       
460           firstStep = false;                      
461         } while (continueStepping);               
462                                                   
463         // Note: currentEnergy is only updated    
464         // In case field propagation changed t    
465         // immediately set to false and curren    
466         // initial kinetic energy stored in ek    
467         if (currentEnergy != ekin) {              
468           // If field propagation didn't chang    
469           // did multiple steps, reset the ene    
470           // propose to not subtract the energ    
471           fTransportEndKineticEnergy = ekin;      
472           // Also ask for the range again with    
473           // correctly cached in the G4VEnergy    
474           // FIXME: Asking for a range should     
475           (void)mscModel->GetRange(particleDef    
476         }                                         
477                                                   
478         fParticleChange.ProposeTrueStepLength(    
479                                                   
480         // Inform G4Transportation that the mo    
481         // to scattering. We do this unconditi    
482         // where the last step is done without    
483         // the flag, for example when running     
484         fMomentumChanged = true;                  
485                                                   
486         return totalGeometryStepLength;           
487       }                                           
488       break;                                      
489     }                                             
490                                                   
491     case ScatteringType::SingleScattering: {      
492       // Select the model for the current kine    
493       const G4double ekin = track.GetKineticEn    
494       const auto* couple = track.GetMaterialCu    
495       const auto* particleDefinition = track.G    
496                                                   
497       G4double ekinForSelection = ekin;           
498       G4double pdgMass = particleDefinition->G    
499       if (pdgMass > CLHEP::GeV) {                 
500         ekinForSelection *= proton_mass_c2 / p    
501       }                                           
502                                                   
503       G4VEmModel* currentModel = fModelManager    
504       if (currentModel == nullptr) {              
505         G4Exception("G4TransportationWithMsc::    
506                     "no scattering model found    
507       }                                           
508       if (!currentModel->IsActive(ekinForSelec    
509         currentModel = nullptr;                   
510       }                                           
511                                                   
512       if (currentModel != nullptr) {              
513         currentModel->SetCurrentCouple(couple)    
514         G4int coupleIndex = couple->GetIndex()    
515                                                   
516         // Compute mean free path.                
517         G4double logEkin = track.GetDynamicPar    
518         G4double lambda = ((*fLambdaTable)[cou    
519         if (lambda > 0.0) {                       
520           // Assume that the mean free path an    
521           // step, which is a valid approximat    
522           G4double meanFreePath = 1.0 / lambda    
523           G4double dedx = fIonisation->GetDEDX    
524                                                   
525           G4double currentSafety = proposedSaf    
526           G4double currentEnergy = ekin;          
527                                                   
528           // Use the provided track for the fi    
529           const G4Track* currentTrackPtr = &tr    
530                                                   
531           G4double stepLimitLeft = physStepLim    
532           G4double totalStepLength = 0;           
533           G4bool firstStep = true, continueSte    
534                                                   
535           do {                                    
536             G4double interactionLength = meanF    
537                                                   
538             G4bool ssLimitsStep = (interaction    
539             G4double gPathLength = stepLimitLe    
540             if (ssLimitsStep) {                   
541               if (!fMultipleSteps) {              
542                 // Scattering limits the step.    
543                 *selection = CandidateForSelec    
544               }                                   
545               gPathLength = interactionLength;    
546             }                                     
547                                                   
548             if (!firstStep) {                     
549               // Move the navigator to where t    
550               fLinearNavigator->LocateGlobalPo    
551             }                                     
552                                                   
553             G4GPILSelection transportSelection    
554             G4double geometryStepLength = G4Tr    
555               *currentTrackPtr, previousStepSi    
556             if (geometryStepLength < gPathLeng    
557               // Transportation limits the ste    
558               *selection = CandidateForSelecti    
559               ssLimitsStep = false;               
560               continueStepping = false;           
561             }                                     
562             if (fTransportEndKineticEnergy !=     
563               // Field propagation changed the    
564               // estimate the continuous energ    
565               continueStepping = false;           
566             }                                     
567                                                   
568             if (firstStep) {                      
569               proposedSafety = currentSafety;     
570             }                                     
571             totalStepLength += geometryStepLen    
572                                                   
573             if (*selection != CandidateForSele    
574               // If neither scattering nor tra    
575               // got the distance we want - ma    
576               continueStepping = false;           
577             }                                     
578             else {                                
579               stepLimitLeft -= geometryStepLen    
580             }                                     
581                                                   
582             // Update the kinetic energy accor    
583             G4double energyAfterLinearLoss =      
584               fTransportEndKineticEnergy - geo    
585                                                   
586             if (ssLimitsStep) {                   
587               fSubStepDynamicParticle->SetKine    
588                                                   
589               // The call to SampleSecondaries    
590               // direction into fParticleChang    
591               // 1) Set the momentum direction    
592               fSubStepDynamicParticle->SetMome    
593               // 2) Call SampleSecondaries(),     
594               currentModel->SampleSecondaries(    
595                                                   
596               // 3) Get the changed direction.    
597               fTransportEndMomentumDir = fPart    
598                                                   
599               // Check that the model neither     
600               // a local energy deposit becaus    
601               // to handle these cases.           
602               if (fSecondariesSS->size() > 0)     
603                 G4Exception("G4TransportationW    
604                             "scattering model     
605               }                                   
606               if (fParticleChangeForSS->GetLoc    
607                 G4Exception("G4TransportationW    
608                             "scattering model     
609               }                                   
610             }                                     
611                                                   
612             if (continueStepping) {               
613               // Update safety according to th    
614               if (currentSafety < fEndPointDis    
615                 currentSafety = 0;                
616               }                                   
617               else {                              
618                 currentSafety -= fEndPointDist    
619               }                                   
620                                                   
621               // Update the energy taking cont    
622               currentEnergy = energyAfterLinea    
623                                                   
624               // From now on, use the track th    
625               currentTrackPtr = fSubStepTrack;    
626                                                   
627               fSubStepDynamicParticle->SetKine    
628               fSubStepDynamicParticle->SetMome    
629               fSubStepTrack->SetPosition(fTran    
630                                                   
631               G4StepPoint& subPreStepPoint = *    
632               subPreStepPoint.SetMaterialCutsC    
633               subPreStepPoint.SetPosition(fTra    
634               subPreStepPoint.SetSafety(curren    
635               subPreStepPoint.SetStepStatus(fA    
636             }                                     
637             firstStep = false;                    
638           } while (continueStepping);             
639                                                   
640           // Note: currentEnergy is only updat    
641           // In case field propagation changed    
642           // immediately set to false and curr    
643           // initial kinetic energy stored in     
644           if (currentEnergy != ekin) {            
645             // If field propagation didn't cha    
646             // did multiple steps, reset the e    
647             // propose to not subtract the ene    
648             fTransportEndKineticEnergy = ekin;    
649           }                                       
650                                                   
651           fParticleChange.ProposeTrueStepLengt    
652                                                   
653           // Inform G4Transportation that the     
654           // to scattering, even if there is n    
655           fMomentumChanged = true;                
656                                                   
657           return totalStepLength;                 
658         }                                         
659       }                                           
660       break;                                      
661     }                                             
662   }                                               
663                                                   
664   // If we get here, no scattering has happene    
665   return G4Transportation::AlongStepGetPhysica    
666     track, previousStepSize, currentMinimumSte    
667 }                                                 
668                                                   
669 //....oooOO0OOooo........oooOO0OOooo........oo    
670