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Geant4/processes/electromagnetic/utils/src/G4EmBiasingManager.cc

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Diff markup

Differences between /processes/electromagnetic/utils/src/G4EmBiasingManager.cc (Version 11.3.0) and /processes/electromagnetic/utils/src/G4EmBiasingManager.cc (Version 11.0.p2)


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 25 //                                                 25 //
 26 //                                                 26 //
 27 // -------------------------------------------     27 // -------------------------------------------------------------------
 28 //                                                 28 //
 29 // GEANT4 Class file                               29 // GEANT4 Class file
 30 //                                                 30 //
 31 //                                                 31 //
 32 // File name:     G4EmBiasingManager               32 // File name:     G4EmBiasingManager
 33 //                                                 33 //
 34 // Author:        Vladimir Ivanchenko              34 // Author:        Vladimir Ivanchenko 
 35 //                                                 35 //
 36 // Creation date: 28.07.2011                       36 // Creation date: 28.07.2011
 37 //                                                 37 //
 38 // Modifications:                                  38 // Modifications:
 39 //                                                 39 //
 40 // 31-05-12 D. Sawkey put back in high energy      40 // 31-05-12 D. Sawkey put back in high energy limit for brem, russian roulette 
 41 // 30-05-12 D. Sawkey  brem split gammas are u     41 // 30-05-12 D. Sawkey  brem split gammas are unique; do weight tests for 
 42 //          brem, russian roulette                 42 //          brem, russian roulette
 43 // -------------------------------------------     43 // -------------------------------------------------------------------
 44 //                                                 44 //
 45 //....oooOO0OOooo........oooOO0OOooo........oo     45 //....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo....
 46 //....oooOO0OOooo........oooOO0OOooo........oo     46 //....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo....
 47                                                    47 
 48 #include "G4EmBiasingManager.hh"                   48 #include "G4EmBiasingManager.hh"
 49 #include "G4SystemOfUnits.hh"                      49 #include "G4SystemOfUnits.hh"
 50 #include "G4PhysicalConstants.hh"                  50 #include "G4PhysicalConstants.hh"
 51 #include "G4MaterialCutsCouple.hh"                 51 #include "G4MaterialCutsCouple.hh"
 52 #include "G4ProductionCutsTable.hh"                52 #include "G4ProductionCutsTable.hh"
 53 #include "G4ProductionCuts.hh"                     53 #include "G4ProductionCuts.hh"
 54 #include "G4Region.hh"                             54 #include "G4Region.hh"
 55 #include "G4RegionStore.hh"                        55 #include "G4RegionStore.hh"
 56 #include "G4Track.hh"                              56 #include "G4Track.hh"
 57 #include "G4Electron.hh"                           57 #include "G4Electron.hh"
 58 #include "G4Gamma.hh"                              58 #include "G4Gamma.hh"
 59 #include "G4VEmModel.hh"                           59 #include "G4VEmModel.hh"
 60 #include "G4LossTableManager.hh"                   60 #include "G4LossTableManager.hh"
 61 #include "G4ParticleChangeForLoss.hh"              61 #include "G4ParticleChangeForLoss.hh"
 62 #include "G4ParticleChangeForGamma.hh"             62 #include "G4ParticleChangeForGamma.hh"
 63 #include "G4EmParameters.hh"                       63 #include "G4EmParameters.hh"
 64                                                    64 
 65 //....oooOO0OOooo........oooOO0OOooo........oo     65 //....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo....
 66                                                    66 
 67 G4EmBiasingManager::G4EmBiasingManager()           67 G4EmBiasingManager::G4EmBiasingManager()
 68   : fDirectionalSplittingTarget(0.0,0.0,0.0)       68   : fDirectionalSplittingTarget(0.0,0.0,0.0)
 69 {                                                  69 {
 70   fSafetyMin = 1.e-6*mm;                           70   fSafetyMin = 1.e-6*mm;
 71   theElectron = G4Electron::Electron();            71   theElectron = G4Electron::Electron();
 72   theGamma    = G4Gamma::Gamma();                  72   theGamma    = G4Gamma::Gamma();
 73 }                                                  73 }
 74                                                    74 
 75 //....oooOO0OOooo........oooOO0OOooo........oo     75 //....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo....
 76                                                    76 
 77 G4EmBiasingManager::~G4EmBiasingManager() = de <<  77 G4EmBiasingManager::~G4EmBiasingManager()
                                                   >>  78 {}
 78                                                    79 
 79 //....oooOO0OOooo........oooOO0OOooo........oo     80 //....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo....
 80                                                    81 
 81 void G4EmBiasingManager::Initialise(const G4Pa     82 void G4EmBiasingManager::Initialise(const G4ParticleDefinition& part,
 82                                     const G4St     83                                     const G4String& procName, G4int verbose)
 83 {                                                  84 {
 84   //G4cout << "G4EmBiasingManager::Initialise      85   //G4cout << "G4EmBiasingManager::Initialise for "
 85   //         << part.GetParticleName()             86   //         << part.GetParticleName()
 86   //         << " and " << procName << G4endl;     87   //         << " and " << procName << G4endl;
 87   const G4ProductionCutsTable* theCoupleTable=     88   const G4ProductionCutsTable* theCoupleTable=
 88     G4ProductionCutsTable::GetProductionCutsTa     89     G4ProductionCutsTable::GetProductionCutsTable();
 89   G4int numOfCouples = (G4int)theCoupleTable-> <<  90   size_t numOfCouples = theCoupleTable->GetTableSize();
 90                                                    91 
 91   if(0 < nForcedRegions) { idxForcedCouple.res     92   if(0 < nForcedRegions) { idxForcedCouple.resize(numOfCouples, -1); }
 92   if(0 < nSecBiasedRegions) { idxSecBiasedCoup     93   if(0 < nSecBiasedRegions) { idxSecBiasedCouple.resize(numOfCouples, -1); }
 93                                                    94 
 94   // Deexcitation                                  95   // Deexcitation
 95   for (G4int j=0; j<numOfCouples; ++j) {       <<  96   for (size_t j=0; j<numOfCouples; ++j) {
 96     const G4MaterialCutsCouple* couple =           97     const G4MaterialCutsCouple* couple =
 97       theCoupleTable->GetMaterialCutsCouple(j)     98       theCoupleTable->GetMaterialCutsCouple(j);
 98     const G4ProductionCuts* pcuts = couple->Ge     99     const G4ProductionCuts* pcuts = couple->GetProductionCuts();
 99     if(0 <  nForcedRegions) {                     100     if(0 <  nForcedRegions) {
100       for(G4int i=0; i<nForcedRegions; ++i) {     101       for(G4int i=0; i<nForcedRegions; ++i) {
101         if(forcedRegions[i]) {                    102         if(forcedRegions[i]) {
102           if(pcuts == forcedRegions[i]->GetPro    103           if(pcuts == forcedRegions[i]->GetProductionCuts()) { 
103             idxForcedCouple[j] = i;               104             idxForcedCouple[j] = i;
104             break;                                105             break; 
105           }                                       106           }
106         }                                         107         }
107       }                                           108       }
108     }                                             109     }
109     if(0 < nSecBiasedRegions) {                   110     if(0 < nSecBiasedRegions) { 
110       for(G4int i=0; i<nSecBiasedRegions; ++i)    111       for(G4int i=0; i<nSecBiasedRegions; ++i) {
111         if(secBiasedRegions[i]) {                 112         if(secBiasedRegions[i]) {
112           if(pcuts == secBiasedRegions[i]->Get    113           if(pcuts == secBiasedRegions[i]->GetProductionCuts()) { 
113             idxSecBiasedCouple[j] = i;            114             idxSecBiasedCouple[j] = i;
114             break;                                115             break; 
115           }                                       116           }
116         }                                         117         }
117       }                                           118       }
118     }                                             119     }
119   }                                               120   }
120                                                   121 
121   G4EmParameters* param = G4EmParameters::Inst    122   G4EmParameters* param = G4EmParameters::Instance();
122   SetDirectionalSplitting(param->GetDirectiona    123   SetDirectionalSplitting(param->GetDirectionalSplitting());
123   if (fDirectionalSplitting) {                    124   if (fDirectionalSplitting) {
124     SetDirectionalSplittingTarget(param->GetDi    125     SetDirectionalSplittingTarget(param->GetDirectionalSplittingTarget());
125     SetDirectionalSplittingRadius(param->GetDi    126     SetDirectionalSplittingRadius(param->GetDirectionalSplittingRadius());
126   }                                               127   }
127                                                   128 
128   if (nForcedRegions > 0 && 0 < verbose) {        129   if (nForcedRegions > 0 && 0 < verbose) {
129     G4cout << " Forced Interaction is activate    130     G4cout << " Forced Interaction is activated for "
130            << part.GetParticleName() << " and     131            << part.GetParticleName() << " and " 
131            << procName                            132            << procName 
132            << " inside G4Regions: " << G4endl;    133            << " inside G4Regions: " << G4endl;
133     for (G4int i=0; i<nForcedRegions; ++i) {      134     for (G4int i=0; i<nForcedRegions; ++i) {
134       const G4Region* r = forcedRegions[i];       135       const G4Region* r = forcedRegions[i];
135       if(r) { G4cout << "           " << r->Ge    136       if(r) { G4cout << "           " << r->GetName() << G4endl; }
136     }                                             137     }
137   }                                               138   }
138   if (nSecBiasedRegions > 0 && 0 < verbose) {     139   if (nSecBiasedRegions > 0 && 0 < verbose) {
139     G4cout << " Secondary biasing is activated    140     G4cout << " Secondary biasing is activated for " 
140            << part.GetParticleName() << " and     141            << part.GetParticleName() << " and " 
141            << procName                            142            << procName 
142            << " inside G4Regions: " << G4endl;    143            << " inside G4Regions: " << G4endl;
143     for (G4int i=0; i<nSecBiasedRegions; ++i)     144     for (G4int i=0; i<nSecBiasedRegions; ++i) {
144       const G4Region* r = secBiasedRegions[i];    145       const G4Region* r = secBiasedRegions[i];
145       if(r) {                                     146       if(r) { 
146         G4cout << "           " << r->GetName(    147         G4cout << "           " << r->GetName() 
147                << "  BiasingWeight= " << secBi    148                << "  BiasingWeight= " << secBiasedWeight[i] << G4endl; 
148       }                                           149       }
149     }                                             150     }
150     if (fDirectionalSplitting) {                  151     if (fDirectionalSplitting) {
151       G4cout << "     Directional splitting ac    152       G4cout << "     Directional splitting activated, with target position: "
152              << fDirectionalSplittingTarget/cm    153              << fDirectionalSplittingTarget/cm
153              << " cm; radius: "                   154              << " cm; radius: "
154              << fDirectionalSplittingRadius/cm    155              << fDirectionalSplittingRadius/cm
155              << "cm." << G4endl;                  156              << "cm." << G4endl;
156     }                                             157     }
157   }                                               158   }
158 }                                                 159 }
159                                                   160 
160 //....oooOO0OOooo........oooOO0OOooo........oo    161 //....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo....
161                                                   162 
162 void G4EmBiasingManager::ActivateForcedInterac    163 void G4EmBiasingManager::ActivateForcedInteraction(G4double val, 
163                                                   164                                                    const G4String& rname)
164 {                                                 165 {
165   G4RegionStore* regionStore = G4RegionStore::    166   G4RegionStore* regionStore = G4RegionStore::GetInstance();
166   G4String name = rname;                          167   G4String name = rname;
167   if(name == "" || name == "world" || name ==     168   if(name == "" || name == "world" || name == "World") {
168     name = "DefaultRegionForTheWorld";            169     name = "DefaultRegionForTheWorld";
169   }                                               170   }
170   const G4Region* reg = regionStore->GetRegion    171   const G4Region* reg = regionStore->GetRegion(name, false);
171   if(!reg) {                                      172   if(!reg) { 
172     G4cout << "### G4EmBiasingManager::ForcedI    173     G4cout << "### G4EmBiasingManager::ForcedInteraction WARNING: "
173            << " G4Region <"                       174            << " G4Region <"
174            << rname << "> is unknown" << G4end    175            << rname << "> is unknown" << G4endl;
175     return;                                       176     return; 
176   }                                               177   }
177                                                   178 
178   // the region is in the list                    179   // the region is in the list
179   if (0 < nForcedRegions) {                       180   if (0 < nForcedRegions) {
180     for (G4int i=0; i<nForcedRegions; ++i) {      181     for (G4int i=0; i<nForcedRegions; ++i) {
181       if (reg == forcedRegions[i]) {              182       if (reg == forcedRegions[i]) {
182         lengthForRegion[i] = val;                 183         lengthForRegion[i] = val; 
183         return;                                   184         return;
184       }                                           185       }
185     }                                             186     }
186   }                                               187   }
187   if(val < 0.0) {                                 188   if(val < 0.0) { 
188     G4cout << "### G4EmBiasingManager::ForcedI    189     G4cout << "### G4EmBiasingManager::ForcedInteraction WARNING: "
189            << val << " < 0.0, so no activation    190            << val << " < 0.0, so no activation for the G4Region <"
190            << rname << ">" << G4endl;             191            << rname << ">" << G4endl;
191     return;                                       192     return; 
192   }                                               193   }
193                                                   194 
194   // new region                                   195   // new region 
195   forcedRegions.push_back(reg);                   196   forcedRegions.push_back(reg);
196   lengthForRegion.push_back(val);                 197   lengthForRegion.push_back(val);
197   ++nForcedRegions;                               198   ++nForcedRegions;
198 }                                                 199 }
199                                                   200 
200 //....oooOO0OOooo........oooOO0OOooo........oo    201 //....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo....
201                                                   202 
202 void                                              203 void 
203 G4EmBiasingManager::ActivateSecondaryBiasing(c    204 G4EmBiasingManager::ActivateSecondaryBiasing(const G4String& rname, 
204                                              G    205                                              G4double factor,
205                                              G    206                                              G4double energyLimit)
206 {                                                 207 {
207   //G4cout << "G4EmBiasingManager::ActivateSec    208   //G4cout << "G4EmBiasingManager::ActivateSecondaryBiasing: "
208   //         << rname << " F= " << factor << "    209   //         << rname << " F= " << factor << " E(MeV)= " << energyLimit/MeV
209   //         << G4endl;                           210   //         << G4endl; 
210   G4RegionStore* regionStore = G4RegionStore::    211   G4RegionStore* regionStore = G4RegionStore::GetInstance();
211   G4String name = rname;                          212   G4String name = rname;
212   if(name == "" || name == "world" || name ==     213   if(name == "" || name == "world" || name == "World") {
213     name = "DefaultRegionForTheWorld";            214     name = "DefaultRegionForTheWorld";
214   }                                               215   }
215   const G4Region* reg = regionStore->GetRegion    216   const G4Region* reg = regionStore->GetRegion(name, false);
216   if(!reg) {                                      217   if(!reg) { 
217     G4cout << "### G4EmBiasingManager::Activat    218     G4cout << "### G4EmBiasingManager::ActivateBremsstrahlungSplitting "
218            << "WARNING: G4Region <"               219            << "WARNING: G4Region <"
219            << rname << "> is unknown" << G4end    220            << rname << "> is unknown" << G4endl;
220     return;                                       221     return; 
221   }                                               222   }
222                                                   223 
223   // Range cut                                    224   // Range cut
224   G4int nsplit = 0;                               225   G4int nsplit = 0;
225   G4double w = factor;                            226   G4double w = factor;
226                                                   227 
227   // splitting                                    228   // splitting
228   if(factor >= 1.0) {                             229   if(factor >= 1.0) {
229     nsplit = G4lrint(factor);                     230     nsplit = G4lrint(factor);
230     w = 1.0/G4double(nsplit);                     231     w = 1.0/G4double(nsplit);
231                                                   232 
232     // Russian roulette                           233     // Russian roulette 
233   } else if(0.0 < factor) {                       234   } else if(0.0 < factor) { 
234     nsplit = 1;                                   235     nsplit = 1;
235     w = 1.0/factor;                               236     w = 1.0/factor;
236   }                                               237   }
237                                                   238 
238   // the region is in the list - overwrite par    239   // the region is in the list - overwrite parameters
239   if (0 < nSecBiasedRegions) {                    240   if (0 < nSecBiasedRegions) {
240     for (G4int i=0; i<nSecBiasedRegions; ++i)     241     for (G4int i=0; i<nSecBiasedRegions; ++i) {
241       if (reg == secBiasedRegions[i]) {           242       if (reg == secBiasedRegions[i]) {
242         secBiasedWeight[i] = w;                   243         secBiasedWeight[i] = w;
243         nBremSplitting[i]  = nsplit;              244         nBremSplitting[i]  = nsplit; 
244         secBiasedEnegryLimit[i] = energyLimit;    245         secBiasedEnegryLimit[i] = energyLimit;
245         return;                                   246         return;
246       }                                           247       }
247     }                                             248     }
248   }                                               249   }
249   /*                                              250   /*
250     G4cout << "### G4EmBiasingManager::Activat    251     G4cout << "### G4EmBiasingManager::ActivateSecondaryBiasing: "
251            << " nsplit= " << nsplit << " for t    252            << " nsplit= " << nsplit << " for the G4Region <"
252            << rname << ">" << G4endl;             253            << rname << ">" << G4endl; 
253   */                                              254   */
254                                                   255 
255   // new region                                   256   // new region 
256   secBiasedRegions.push_back(reg);                257   secBiasedRegions.push_back(reg);
257   secBiasedWeight.push_back(w);                   258   secBiasedWeight.push_back(w);
258   nBremSplitting.push_back(nsplit);               259   nBremSplitting.push_back(nsplit);
259   secBiasedEnegryLimit.push_back(energyLimit);    260   secBiasedEnegryLimit.push_back(energyLimit);
260   ++nSecBiasedRegions;                            261   ++nSecBiasedRegions;
261   //G4cout << "nSecBiasedRegions= " << nSecBia    262   //G4cout << "nSecBiasedRegions= " << nSecBiasedRegions << G4endl;
262 }                                                 263 }
263                                                   264 
264 //....oooOO0OOooo........oooOO0OOooo........oo    265 //....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo....
265                                                   266 
266 G4double G4EmBiasingManager::GetStepLimit(G4in    267 G4double G4EmBiasingManager::GetStepLimit(G4int coupleIdx, 
267                                           G4do    268                                           G4double previousStep)
268 {                                                 269 {
269   if(startTracking) {                             270   if(startTracking) {
270     startTracking = false;                        271     startTracking = false;
271     G4int i = idxForcedCouple[coupleIdx];         272     G4int i = idxForcedCouple[coupleIdx];
272     if(i < 0) {                                   273     if(i < 0) {
273       currentStepLimit = DBL_MAX;                 274       currentStepLimit = DBL_MAX;
274     } else {                                      275     } else {
275       currentStepLimit = lengthForRegion[i];      276       currentStepLimit = lengthForRegion[i];
276       if(currentStepLimit > 0.0) { currentStep    277       if(currentStepLimit > 0.0) { currentStepLimit *= G4UniformRand(); }
277     }                                             278     }
278   } else {                                        279   } else {
279     currentStepLimit -= previousStep;             280     currentStepLimit -= previousStep;
280   }                                               281   }
281   if(currentStepLimit < 0.0) { currentStepLimi    282   if(currentStepLimit < 0.0) { currentStepLimit = 0.0; }
282   return currentStepLimit;                        283   return currentStepLimit;
283 }                                                 284 }
284                                                   285 
285 //....oooOO0OOooo........oooOO0OOooo........oo    286 //....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo....
286                                                   287 
287 G4double                                          288 G4double 
288 G4EmBiasingManager::ApplySecondaryBiasing(        289 G4EmBiasingManager::ApplySecondaryBiasing(
289                     std::vector<G4DynamicParti    290                     std::vector<G4DynamicParticle*>& vd,
290                     const G4Track& track,         291                     const G4Track& track,
291                     G4VEmModel* currentModel,     292                     G4VEmModel* currentModel,
292                     G4ParticleChangeForLoss* p    293                     G4ParticleChangeForLoss* pPartChange,
293                     G4double& eloss,              294                     G4double& eloss,  
294                     G4int coupleIdx,              295                     G4int coupleIdx,
295                     G4double tcut,                296                     G4double tcut, 
296                     G4double safety)              297                     G4double safety)
297 {                                                 298 {
298   G4int index = idxSecBiasedCouple[coupleIdx];    299   G4int index = idxSecBiasedCouple[coupleIdx];
299   G4double weight = 1.;                           300   G4double weight = 1.;
300   if(0 <= index) {                                301   if(0 <= index) {
301     std::size_t n = vd.size();                 << 302     size_t n = vd.size();
302                                                   303 
303     // the check cannot be applied per seconda    304     // the check cannot be applied per secondary particle
304     // because weight correction is common, so    305     // because weight correction is common, so the first
305     // secondary is checked                       306     // secondary is checked
306     if((0 < n && vd[0]->GetKineticEnergy() < s    307     if((0 < n && vd[0]->GetKineticEnergy() < secBiasedEnegryLimit[index])
307           || fDirectionalSplitting) {             308           || fDirectionalSplitting) {
308                                                   309 
309       G4int nsplit = nBremSplitting[index];       310       G4int nsplit = nBremSplitting[index];
310                                                   311 
311       // Range cut                                312       // Range cut
312       if(0 == nsplit) {                           313       if(0 == nsplit) { 
313         if(safety > fSafetyMin) { ApplyRangeCu    314         if(safety > fSafetyMin) { ApplyRangeCut(vd, track, eloss, safety); }
314                                                   315 
315         // Russian Roulette                       316         // Russian Roulette
316       } else if(1 == nsplit) {                    317       } else if(1 == nsplit) { 
317         weight = ApplyRussianRoulette(vd, inde    318         weight = ApplyRussianRoulette(vd, index);
318                                                   319 
319         // Splitting                              320         // Splitting
320       } else {                                    321       } else {
321         if (fDirectionalSplitting) {              322         if (fDirectionalSplitting) {
322           weight = ApplyDirectionalSplitting(v    323           weight = ApplyDirectionalSplitting(vd, track, currentModel, index, tcut);
323         } else {                                  324         } else {
324           G4double tmpEnergy = pPartChange->Ge    325           G4double tmpEnergy = pPartChange->GetProposedKineticEnergy();
325           G4ThreeVector tmpMomDir = pPartChang    326           G4ThreeVector tmpMomDir = pPartChange->GetProposedMomentumDirection();
326                                                   327 
327           weight = ApplySplitting(vd, track, c    328           weight = ApplySplitting(vd, track, currentModel, index, tcut);
328                                                   329 
329           pPartChange->SetProposedKineticEnerg    330           pPartChange->SetProposedKineticEnergy(tmpEnergy);
330           pPartChange->ProposeMomentumDirectio    331           pPartChange->ProposeMomentumDirection(tmpMomDir);
331         }                                         332         }
332       }                                           333       }
333     }                                             334     }
334   }                                               335   }
335   return weight;                                  336   return weight;
336 }                                                 337 }
337                                                   338 
338 //....oooOO0OOooo........oooOO0OOooo........oo    339 //....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo....
339                                                   340 
340 G4double                                          341 G4double 
341 G4EmBiasingManager::ApplySecondaryBiasing(        342 G4EmBiasingManager::ApplySecondaryBiasing(
342                   std::vector<G4DynamicParticl    343                   std::vector<G4DynamicParticle*>& vd,
343                   const G4Track& track,           344                   const G4Track& track,
344                   G4VEmModel* currentModel,       345                   G4VEmModel* currentModel, 
345                   G4ParticleChangeForGamma* pP    346                   G4ParticleChangeForGamma* pPartChange,
346                   G4double& eloss,                347                   G4double& eloss,  
347                   G4int coupleIdx,                348                   G4int coupleIdx,
348                   G4double tcut,                  349                   G4double tcut, 
349                   G4double safety)                350                   G4double safety)
350 {                                                 351 {
351   G4int index = idxSecBiasedCouple[coupleIdx];    352   G4int index = idxSecBiasedCouple[coupleIdx];
352   G4double weight = 1.;                           353   G4double weight = 1.;
353   if(0 <= index) {                                354   if(0 <= index) {
354     std::size_t n = vd.size();                 << 355     size_t n = vd.size();
355                                                   356 
356     // the check cannot be applied per seconda    357     // the check cannot be applied per secondary particle
357     // because weight correction is common, so    358     // because weight correction is common, so the first
358     // secondary is checked                       359     // secondary is checked
359     if((0 < n && vd[0]->GetKineticEnergy() < s    360     if((0 < n && vd[0]->GetKineticEnergy() < secBiasedEnegryLimit[index])
360           || fDirectionalSplitting) {             361           || fDirectionalSplitting) {
361                                                   362 
362       G4int nsplit = nBremSplitting[index];       363       G4int nsplit = nBremSplitting[index];
363                                                   364 
364       // Range cut                                365       // Range cut
365       if(0 == nsplit) {                           366       if(0 == nsplit) { 
366         if(safety > fSafetyMin) { ApplyRangeCu    367         if(safety > fSafetyMin) { ApplyRangeCut(vd, track, eloss, safety); }
367                                                   368 
368         // Russian Roulette                       369         // Russian Roulette
369       } else if(1 == nsplit) {                    370       } else if(1 == nsplit) { 
370         weight = ApplyRussianRoulette(vd, inde    371         weight = ApplyRussianRoulette(vd, index);
371                                                   372 
372         // Splitting                              373         // Splitting
373       } else {                                    374       } else {
374         if (fDirectionalSplitting) {              375         if (fDirectionalSplitting) {
375           weight = ApplyDirectionalSplitting(v    376           weight = ApplyDirectionalSplitting(vd, track, currentModel,
376                                     index, tcu    377                                     index, tcut, pPartChange);
377         } else {                                  378         } else {
378           G4double tmpEnergy = pPartChange->Ge    379           G4double tmpEnergy = pPartChange->GetProposedKineticEnergy();
379           G4ThreeVector tmpMomDir = pPartChang    380           G4ThreeVector tmpMomDir = pPartChange->GetProposedMomentumDirection();
380                                                   381 
381           weight = ApplySplitting(vd, track, c    382           weight = ApplySplitting(vd, track, currentModel, index, tcut);
382                                                   383 
383           pPartChange->SetProposedKineticEnerg    384           pPartChange->SetProposedKineticEnergy(tmpEnergy);
384           pPartChange->ProposeMomentumDirectio    385           pPartChange->ProposeMomentumDirection(tmpMomDir);
385         }                                         386         }
386       }                                           387       }
387     }                                             388     }
388   }                                               389   }
389   return weight;                                  390   return weight;
390 }                                                 391 }
391                                                   392 
392 //....oooOO0OOooo........oooOO0OOooo........oo    393 //....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo....
393                                                   394 
394 G4double                                          395 G4double 
395 G4EmBiasingManager::ApplySecondaryBiasing(std:    396 G4EmBiasingManager::ApplySecondaryBiasing(std::vector<G4Track*>& track,
396                                           G4in    397                                           G4int coupleIdx)
397 {                                                 398 {
398   G4int index = idxSecBiasedCouple[coupleIdx];    399   G4int index = idxSecBiasedCouple[coupleIdx];
399   G4double weight = 1.;                           400   G4double weight = 1.;
400   if(0 <= index) {                                401   if(0 <= index) {
401     std::size_t n = track.size();              << 402     size_t n = track.size();
402                                                   403 
403     // the check cannot be applied per seconda    404     // the check cannot be applied per secondary particle
404     // because weight correction is common, so    405     // because weight correction is common, so the first
405     // secondary is checked                       406     // secondary is checked
406     if(0 < n && track[0]->GetKineticEnergy() <    407     if(0 < n && track[0]->GetKineticEnergy() < secBiasedEnegryLimit[index]) {
407                                                   408 
408       G4int nsplit = nBremSplitting[index];       409       G4int nsplit = nBremSplitting[index];
409                                                   410 
410         // Russian Roulette only                  411         // Russian Roulette only
411       if(1 == nsplit) {                           412       if(1 == nsplit) { 
412         weight = secBiasedWeight[index];          413         weight = secBiasedWeight[index];
413         for(std::size_t k=0; k<n; ++k) {       << 414         for(size_t k=0; k<n; ++k) {
414           if(G4UniformRand()*weight > 1.0) {      415           if(G4UniformRand()*weight > 1.0) {
415             const G4Track* t = track[k];          416             const G4Track* t = track[k];
416             delete t;                             417             delete t;
417             track[k] = nullptr;                << 418             track[k] = 0;
418           }                                       419           }
419         }                                         420         }
420       }                                           421       }
421     }                                             422     }
422   }                                               423   }
423   return weight;                                  424   return weight;
424 }                                                 425 }
425                                                   426 
426 //....oooOO0OOooo........oooOO0OOooo........oo    427 //....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo....
427                                                   428 
428 void                                              429 void
429 G4EmBiasingManager::ApplyRangeCut(std::vector<    430 G4EmBiasingManager::ApplyRangeCut(std::vector<G4DynamicParticle*>& vd,
430                                   const G4Trac    431                                   const G4Track& track,
431                                   G4double& el    432                                   G4double& eloss, G4double safety)
432 {                                                 433 {
433   std::size_t n = vd.size();                   << 434   size_t n = vd.size();
434   if(!eIonisation) {                              435   if(!eIonisation) { 
435     eIonisation =                                 436     eIonisation = 
436       G4LossTableManager::Instance()->GetEnerg    437       G4LossTableManager::Instance()->GetEnergyLossProcess(theElectron);
437   }                                               438   }
438   if(eIonisation) {                               439   if(eIonisation) { 
439     for(std::size_t k=0; k<n; ++k) {           << 440     for(size_t k=0; k<n; ++k) {
440       const G4DynamicParticle* dp = vd[k];        441       const G4DynamicParticle* dp = vd[k];
441       if(dp->GetDefinition() == theElectron) {    442       if(dp->GetDefinition() == theElectron) {
442         G4double e = dp->GetKineticEnergy();      443         G4double e = dp->GetKineticEnergy();
443         if(eIonisation->GetRange(e, track.GetM    444         if(eIonisation->GetRange(e, track.GetMaterialCutsCouple()) < safety) {
444           eloss += e;                             445           eloss += e;
445           delete dp;                              446           delete dp;
446           vd[k] = nullptr;                     << 447           vd[k] = 0;
447         }                                         448         }
448       }                                           449       }
449     }                                             450     }
450   }                                               451   }
451 }                                                 452 }
452                                                   453 
453 //....oooOO0OOooo........oooOO0OOooo........oo    454 //....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo....
454                                                   455 
455 G4bool G4EmBiasingManager::CheckDirection(G4Th    456 G4bool G4EmBiasingManager::CheckDirection(G4ThreeVector pos,
456                                           G4Th    457                                           G4ThreeVector momdir) const
457 {                                                 458 {
458   G4ThreeVector delta = fDirectionalSplittingT    459   G4ThreeVector delta = fDirectionalSplittingTarget - pos;
459   G4double angle = momdir.angle(delta);           460   G4double angle = momdir.angle(delta);
460   G4double dist = delta.cross(momdir).mag();      461   G4double dist = delta.cross(momdir).mag();
461   if (dist <= fDirectionalSplittingRadius && a    462   if (dist <= fDirectionalSplittingRadius && angle < halfpi) {
462     return true;                                  463     return true;
463   }                                               464   }
464   return false;                                   465   return false;
465 }                                                 466 }
466                                                   467 
467 //....oooOO0OOooo........oooOO0OOooo........oo    468 //....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo....
468                                                   469 
469 G4double                                          470 G4double
470 G4EmBiasingManager::ApplySplitting(std::vector    471 G4EmBiasingManager::ApplySplitting(std::vector<G4DynamicParticle*>& vd,
471                                    const G4Tra    472                                    const G4Track& track,
472                                    G4VEmModel*    473                                    G4VEmModel* currentModel, 
473                                    G4int index    474                                    G4int index,
474                                    G4double tc    475                                    G4double tcut)
475 {                                                 476 {
476   // method is applied only if 1 secondary cre    477   // method is applied only if 1 secondary created PostStep 
477   // in the case of many secondaries there is     478   // in the case of many secondaries there is a contradiction
478   G4double weight = 1.;                           479   G4double weight = 1.;
479   std::size_t n = vd.size();                   << 480   size_t n = vd.size();
480   G4double w = secBiasedWeight[index];            481   G4double w = secBiasedWeight[index];
481                                                   482 
482   if(1 != n || 1.0 <= w) { return weight; }       483   if(1 != n || 1.0 <= w) { return weight; }
483                                                   484 
484   G4double trackWeight = track.GetWeight();       485   G4double trackWeight = track.GetWeight();
485   const G4DynamicParticle* dynParticle = track    486   const G4DynamicParticle* dynParticle = track.GetDynamicParticle();
486                                                   487 
487   G4int nsplit = nBremSplitting[index];           488   G4int nsplit = nBremSplitting[index];
488                                                   489 
489   // double splitting is suppressed               490   // double splitting is suppressed 
490   if(1 < nsplit && trackWeight>w) {               491   if(1 < nsplit && trackWeight>w) {
491                                                   492 
492     weight = w;                                   493     weight = w;
493     if(nsplit > (G4int)tmpSecondaries.size())     494     if(nsplit > (G4int)tmpSecondaries.size()) { 
494       tmpSecondaries.reserve(nsplit);             495       tmpSecondaries.reserve(nsplit);
495     }                                             496     }
496     const G4MaterialCutsCouple* couple = track    497     const G4MaterialCutsCouple* couple = track.GetMaterialCutsCouple();
497     // start from 1, because already one secon    498     // start from 1, because already one secondary created
498     for(G4int k=1; k<nsplit; ++k) {               499     for(G4int k=1; k<nsplit; ++k) {
499       tmpSecondaries.clear();                     500       tmpSecondaries.clear();
500       currentModel->SampleSecondaries(&tmpSeco    501       currentModel->SampleSecondaries(&tmpSecondaries, couple, dynParticle, 
501                                       tcut);      502                                       tcut);
502       for (std::size_t kk=0; kk<tmpSecondaries << 503       for (size_t kk=0; kk<tmpSecondaries.size(); ++kk) {
503         vd.push_back(tmpSecondaries[kk]);         504         vd.push_back(tmpSecondaries[kk]);
504       }                                           505       }
505     }                                             506     }
506   }                                               507   }
507   return weight;                                  508   return weight;
508 }                                                 509 }
509                                                   510 
510 //....oooOO0OOooo........oooOO0OOooo........oo    511 //....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo....
511                                                   512 
512 G4double                                          513 G4double
513 G4EmBiasingManager::ApplyDirectionalSplitting(    514 G4EmBiasingManager::ApplyDirectionalSplitting(
514                                    std::vector    515                                    std::vector<G4DynamicParticle*>& vd,
515                                    const G4Tra    516                                    const G4Track& track,
516                                    G4VEmModel*    517                                    G4VEmModel* currentModel,
517                                    G4int index    518                                    G4int index,
518                                    G4double tc    519                                    G4double tcut,
519                                    G4ParticleC    520                                    G4ParticleChangeForGamma* partChange)
520 {                                                 521 {
521   // primary is gamma. do splitting/RR as appr    522   // primary is gamma. do splitting/RR as appropriate
522   // method applied for any number of secondar    523   // method applied for any number of secondaries
523                                                   524 
524   G4double weight = 1.0;                          525   G4double weight = 1.0;
525   G4double w = secBiasedWeight[index];            526   G4double w = secBiasedWeight[index];
526                                                   527 
527   fDirectionalSplittingWeights.clear();           528   fDirectionalSplittingWeights.clear();
528   if(1.0 <= w) {                                  529   if(1.0 <= w) {
529     fDirectionalSplittingWeights.push_back(wei    530     fDirectionalSplittingWeights.push_back(weight);
530     return weight;                                531     return weight;
531   }                                               532   }
532                                                   533 
533   G4double trackWeight = track.GetWeight();       534   G4double trackWeight = track.GetWeight();
534   G4int nsplit = nBremSplitting[index];           535   G4int nsplit = nBremSplitting[index];
535                                                   536 
536   // double splitting is suppressed               537   // double splitting is suppressed
537   if(1 < nsplit && trackWeight>w) {               538   if(1 < nsplit && trackWeight>w) {
538                                                   539 
539     weight = w;                                   540     weight = w;
540     const G4ThreeVector pos = track.GetPositio    541     const G4ThreeVector pos = track.GetPosition();
541                                                   542 
542     G4bool foundPrimaryParticle = false;          543     G4bool foundPrimaryParticle = false;
543     G4double primaryEnergy = 0.;                  544     G4double primaryEnergy = 0.;
544     G4ThreeVector primaryMomdir(0.,0.,0.);        545     G4ThreeVector primaryMomdir(0.,0.,0.);
545     G4double primaryWeight = trackWeight;         546     G4double primaryWeight = trackWeight;
546                                                   547 
547     tmpSecondaries = vd;                          548     tmpSecondaries = vd;
548     vd.clear();                                   549     vd.clear();
549     vd.reserve(nsplit);                           550     vd.reserve(nsplit);
550     for (G4int k=0; k<nsplit; ++k) {              551     for (G4int k=0; k<nsplit; ++k) {
551       if (k>0) {  // for k==0, SampleSecondari    552       if (k>0) {  // for k==0, SampleSecondaries has already been called
552         tmpSecondaries.clear();                   553         tmpSecondaries.clear();
553         // SampleSecondaries modifies primary     554         // SampleSecondaries modifies primary info stored in partChange
554         currentModel->SampleSecondaries(&tmpSe    555         currentModel->SampleSecondaries(&tmpSecondaries,
555                                         track.    556                                         track.GetMaterialCutsCouple(),
556                                         track.    557                                         track.GetDynamicParticle(), tcut);
557       }                                           558       }
558       for (std::size_t kk=0; kk<tmpSecondaries << 559       for (size_t kk=0; kk<tmpSecondaries.size(); ++kk) {
559         if (tmpSecondaries[kk]->GetParticleDef    560         if (tmpSecondaries[kk]->GetParticleDefinition() == theGamma) {
560           if (CheckDirection(pos, tmpSecondari    561           if (CheckDirection(pos, tmpSecondaries[kk]->GetMomentumDirection())){
561             vd.push_back(tmpSecondaries[kk]);     562             vd.push_back(tmpSecondaries[kk]);
562             fDirectionalSplittingWeights.push_    563             fDirectionalSplittingWeights.push_back(1.);
563           } else if (G4UniformRand() < w) {       564           } else if (G4UniformRand() < w) {
564             vd.push_back(tmpSecondaries[kk]);     565             vd.push_back(tmpSecondaries[kk]);
565             fDirectionalSplittingWeights.push_    566             fDirectionalSplittingWeights.push_back(1./weight);
566           } else {                                567           } else {
567             delete tmpSecondaries[kk];            568             delete tmpSecondaries[kk];
568             tmpSecondaries[kk] = nullptr;         569             tmpSecondaries[kk] = nullptr;
569           }                                       570           }
570         } else if (k==0) { // keep charged 2ry    571         } else if (k==0) { // keep charged 2ry from first splitting
571           vd.push_back(tmpSecondaries[kk]);       572           vd.push_back(tmpSecondaries[kk]);
572           fDirectionalSplittingWeights.push_ba    573           fDirectionalSplittingWeights.push_back(1./weight);
573         } else {                                  574         } else {
574           delete tmpSecondaries[kk];              575           delete tmpSecondaries[kk];
575           tmpSecondaries[kk] = nullptr;           576           tmpSecondaries[kk] = nullptr;
576         }                                         577         }
577       }                                           578       }
578                                                   579 
579       // primary                                  580       // primary
580       G4double en = partChange->GetProposedKin    581       G4double en = partChange->GetProposedKineticEnergy();
581       if (en>0.) { // don't add if kinetic ene    582       if (en>0.) { // don't add if kinetic energy = 0
582         G4ThreeVector momdir = partChange->Get    583         G4ThreeVector momdir = partChange->GetProposedMomentumDirection();
583         if (CheckDirection(pos,momdir)) {         584         if (CheckDirection(pos,momdir)) {
584           // keep only one primary; others are    585           // keep only one primary; others are secondaries
585           if (!foundPrimaryParticle) {            586           if (!foundPrimaryParticle) {
586             primaryEnergy = en;                   587             primaryEnergy = en;
587             primaryMomdir = momdir;               588             primaryMomdir = momdir;
588             foundPrimaryParticle = true;          589             foundPrimaryParticle = true;
589             primaryWeight = weight;               590             primaryWeight = weight;
590           } else {                                591           } else {
591             auto dp = new G4DynamicParticle(th << 592             G4DynamicParticle* dp = new G4DynamicParticle(theGamma,
592                           partChange->GetPropo << 593                                     partChange->GetProposedMomentumDirection(),
593                           partChange->GetPropo << 594                                     partChange->GetProposedKineticEnergy());
594             vd.push_back(dp);                     595             vd.push_back(dp);
595             fDirectionalSplittingWeights.push_    596             fDirectionalSplittingWeights.push_back(1.);
596           }                                       597           }
597         } else if (G4UniformRand()<w) { // not    598         } else if (G4UniformRand()<w) { // not going to target. play RR.
598           if (!foundPrimaryParticle) {            599           if (!foundPrimaryParticle) {
599             foundPrimaryParticle = true;          600             foundPrimaryParticle = true;
600             primaryEnergy = en;                   601             primaryEnergy = en;
601             primaryMomdir = momdir;               602             primaryMomdir = momdir;
602             primaryWeight = 1.;                   603             primaryWeight = 1.;
603           } else {                                604           } else {
604             auto dp = new G4DynamicParticle(th << 605             G4DynamicParticle* dp = new G4DynamicParticle(theGamma,
605                           partChange->GetPropo << 606                                     partChange->GetProposedMomentumDirection(),
606                           partChange->GetPropo << 607                                     partChange->GetProposedKineticEnergy());
607             vd.push_back(dp);                     608             vd.push_back(dp);
608             fDirectionalSplittingWeights.push_    609             fDirectionalSplittingWeights.push_back(1./weight);
609           }                                       610           }
610         }                                         611         }
611       }                                           612       }
612     }  // end of loop over nsplit                 613     }  // end of loop over nsplit
613                                                   614 
614     partChange->ProposeWeight(primaryWeight);     615     partChange->ProposeWeight(primaryWeight);
615     partChange->SetProposedKineticEnergy(prima    616     partChange->SetProposedKineticEnergy(primaryEnergy);
616     partChange->ProposeMomentumDirection(prima    617     partChange->ProposeMomentumDirection(primaryMomdir);
617   } else {                                        618   } else {
618     for (std::size_t i = 0; i < vd.size(); ++i << 619     for (size_t i = 0; i < vd.size(); ++i) {
619       fDirectionalSplittingWeights.push_back(1    620       fDirectionalSplittingWeights.push_back(1.);
620     }                                             621     }
621   }                                               622   }
622                                                   623 
623   return weight;                                  624   return weight;
624 }                                                 625 }
625                                                   626 
626 //....oooOO0OOooo........oooOO0OOooo........oo    627 //....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo....
627                                                   628 
628 G4double G4EmBiasingManager::GetWeight(G4int i    629 G4double G4EmBiasingManager::GetWeight(G4int i)
629 {                                                 630 {
630   // normally return 1. If a directionally spl    631   // normally return 1. If a directionally split particle survives RR,
631   //  return 1./(splitting factor)                632   //  return 1./(splitting factor)
632   if (fDirectionalSplittingWeights.size() >= (    633   if (fDirectionalSplittingWeights.size() >= (unsigned int)(i+1) ) {
633     G4double w = fDirectionalSplittingWeights[    634     G4double w = fDirectionalSplittingWeights[i];
634     fDirectionalSplittingWeights[i] = 1.; // e    635     fDirectionalSplittingWeights[i] = 1.; // ensure it's not used again
635     return w;                                     636     return w;
636   } else {                                        637   } else {
637     return 1.;                                    638     return 1.;
638   }                                               639   }
639 }                                                 640 }
640                                                   641 
641 G4double                                          642 G4double
642 G4EmBiasingManager::ApplyDirectionalSplitting(    643 G4EmBiasingManager::ApplyDirectionalSplitting(
643                                   std::vector<    644                                   std::vector<G4DynamicParticle*>& vd,
644                                   const G4Trac    645                                   const G4Track& track,
645                                   G4VEmModel*     646                                   G4VEmModel* currentModel,
646                                   G4int index,    647                                   G4int index,
647                                   G4double tcu    648                                   G4double tcut)
648 {                                                 649 {
649   // primary is not a gamma. Do nothing with p    650   // primary is not a gamma. Do nothing with primary
650                                                   651 
651   G4double weight = 1.0;                          652   G4double weight = 1.0;
652   G4double w = secBiasedWeight[index];            653   G4double w = secBiasedWeight[index];
653                                                   654 
654   fDirectionalSplittingWeights.clear();           655   fDirectionalSplittingWeights.clear();
655   if(1.0 <= w) {                                  656   if(1.0 <= w) {
656     fDirectionalSplittingWeights.push_back(wei    657     fDirectionalSplittingWeights.push_back(weight);
657     return weight;                                658     return weight;
658   }                                               659   }
659                                                   660 
660   G4double trackWeight = track.GetWeight();       661   G4double trackWeight = track.GetWeight();
661   G4int nsplit = nBremSplitting[index];           662   G4int nsplit = nBremSplitting[index];
662                                                   663 
663   // double splitting is suppressed               664   // double splitting is suppressed
664   if(1 < nsplit && trackWeight>w) {               665   if(1 < nsplit && trackWeight>w) {
665                                                   666 
666     weight = w;                                   667     weight = w;
667     const G4ThreeVector pos = track.GetPositio    668     const G4ThreeVector pos = track.GetPosition();
668                                                   669 
669     tmpSecondaries = vd;                          670     tmpSecondaries = vd;
670     vd.clear();                                   671     vd.clear();
671     vd.reserve(nsplit);                           672     vd.reserve(nsplit);
672     for (G4int k=0; k<nsplit; ++k) {              673     for (G4int k=0; k<nsplit; ++k) {
673       if (k>0) {                                  674       if (k>0) {
674         tmpSecondaries.clear();                   675         tmpSecondaries.clear();
675         currentModel->SampleSecondaries(&tmpSe    676         currentModel->SampleSecondaries(&tmpSecondaries,
676                                         track.    677                                         track.GetMaterialCutsCouple(),
677                                         track.    678                                         track.GetDynamicParticle(), tcut);
678       }                                           679       }
679       //for (auto sec : tmpSecondaries) {         680       //for (auto sec : tmpSecondaries) {
680       for (std::size_t kk=0; kk < tmpSecondari << 681       for (size_t kk=0; kk < tmpSecondaries.size(); ++kk) {
681         if (CheckDirection(pos, tmpSecondaries    682         if (CheckDirection(pos, tmpSecondaries[kk]->GetMomentumDirection())) {
682           vd.push_back(tmpSecondaries[kk]);       683           vd.push_back(tmpSecondaries[kk]);
683           fDirectionalSplittingWeights.push_ba    684           fDirectionalSplittingWeights.push_back(1.);
684         } else if (G4UniformRand()<w) {           685         } else if (G4UniformRand()<w) {
685           vd.push_back(tmpSecondaries[kk]);       686           vd.push_back(tmpSecondaries[kk]);
686           fDirectionalSplittingWeights.push_ba    687           fDirectionalSplittingWeights.push_back(1./weight);
687         } else {                                  688         } else {
688           delete tmpSecondaries[kk];              689           delete tmpSecondaries[kk];
689           tmpSecondaries[kk] = nullptr;           690           tmpSecondaries[kk] = nullptr;
690         }                                         691         }
691       }                                           692       }
692     }  // end of loop over nsplit                 693     }  // end of loop over nsplit
693   } else { // no splitting was done; still nee    694   } else { // no splitting was done; still need weights
694     for (std::size_t i = 0; i < vd.size(); ++i << 695     for (size_t i = 0; i < vd.size(); ++i) {
695       fDirectionalSplittingWeights.push_back(1    696       fDirectionalSplittingWeights.push_back(1.0);
696     }                                             697     }
697   }                                               698   }
698   return weight;                                  699   return weight;
699 }                                                 700 }
700                                                   701