Geant4 Cross Reference

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Geant4/processes/electromagnetic/utils/src/G4VEmProcess.cc

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Diff markup

Differences between /processes/electromagnetic/utils/src/G4VEmProcess.cc (Version 11.3.0) and /processes/electromagnetic/utils/src/G4VEmProcess.cc (Version 6.1)


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 25 //                                                 22 //
                                                   >>  23 // $Id: G4VEmProcess.cc,v 1.4 2004/03/01 13:06:26 vnivanch Exp $
                                                   >>  24 // GEANT4 tag $Name: geant4-06-01 $
                                                   >>  25 //
 26 // -------------------------------------------     26 // -------------------------------------------------------------------
 27 //                                                 27 //
 28 // GEANT4 Class file                               28 // GEANT4 Class file
 29 //                                                 29 //
 30 //                                                 30 //
 31 // File name:     G4VEmProcess                     31 // File name:     G4VEmProcess
 32 //                                                 32 //
 33 // Author:        Vladimir Ivanchenko on base      33 // Author:        Vladimir Ivanchenko on base of Laszlo Urban code
 34 //                                                 34 //
 35 // Creation date: 01.10.2003                       35 // Creation date: 01.10.2003
 36 //                                                 36 //
 37 // Modifications: by V.Ivanchenko              <<  37 // Modifications:
                                                   >>  38 //
 38 //                                                 39 //
 39 // Class Description: based class for discrete <<  40 // Class Description:
 40 //                                                 41 //
                                                   >>  42 // It is the unified process for e+ annililation at rest and in fly.
 41                                                    43 
 42 // -------------------------------------------     44 // -------------------------------------------------------------------
 43 //                                                 45 //
 44 //....oooOO0OOooo........oooOO0OOooo........oo     46 //....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo....
 45 //....oooOO0OOooo........oooOO0OOooo........oo     47 //....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo....
 46                                                    48 
 47 #include "G4VEmProcess.hh"                         49 #include "G4VEmProcess.hh"
 48 #include "G4PhysicalConstants.hh"              << 
 49 #include "G4SystemOfUnits.hh"                  << 
 50 #include "G4ProcessManager.hh"                 << 
 51 #include "G4LossTableManager.hh"                   50 #include "G4LossTableManager.hh"
 52 #include "G4LossTableBuilder.hh"               << 
 53 #include "G4Step.hh"                               51 #include "G4Step.hh"
 54 #include "G4ParticleDefinition.hh"                 52 #include "G4ParticleDefinition.hh"
 55 #include "G4VEmModel.hh"                           53 #include "G4VEmModel.hh"
                                                   >>  54 #include "G4VEmFluctuationModel.hh"
 56 #include "G4DataVector.hh"                         55 #include "G4DataVector.hh"
 57 #include "G4PhysicsTable.hh"                       56 #include "G4PhysicsTable.hh"
 58 #include "G4EmDataHandler.hh"                  <<  57 #include "G4PhysicsVector.hh"
 59 #include "G4PhysicsLogVector.hh"                   58 #include "G4PhysicsLogVector.hh"
 60 #include "G4VParticleChange.hh"                    59 #include "G4VParticleChange.hh"
 61 #include "G4ProductionCutsTable.hh"            << 
 62 #include "G4Region.hh"                         << 
 63 #include "G4Gamma.hh"                              60 #include "G4Gamma.hh"
 64 #include "G4Electron.hh"                           61 #include "G4Electron.hh"
 65 #include "G4Positron.hh"                           62 #include "G4Positron.hh"
 66 #include "G4PhysicsTableHelper.hh"             <<  63 #include "G4ProcessManager.hh"
 67 #include "G4EmBiasingManager.hh"               <<  64 #include "G4UnitsTable.hh"
 68 #include "G4EmParameters.hh"                   <<  65 #include "G4ProductionCutsTable.hh"
 69 #include "G4EmProcessSubType.hh"               <<  66 #include "G4Region.hh"
 70 #include "G4EmTableUtil.hh"                    <<  67 #include "G4RegionStore.hh"
 71 #include "G4EmUtility.hh"                      << 
 72 #include "G4DNAModelSubType.hh"                << 
 73 #include "G4GenericIon.hh"                     << 
 74 #include "G4Log.hh"                            << 
 75 #include <iostream>                            << 
 76                                                    68 
 77 //....oooOO0OOooo........oooOO0OOooo........oo     69 //....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo....
 78                                                    70 
 79 G4VEmProcess::G4VEmProcess(const G4String& nam     71 G4VEmProcess::G4VEmProcess(const G4String& name, G4ProcessType type):
 80   G4VDiscreteProcess(name, type)               <<  72                       G4VRestDiscreteProcess(name, type),
                                                   >>  73   theLambdaTable(0),
                                                   >>  74   particle(0),
                                                   >>  75   secondaryParticle(0),
                                                   >>  76   currentCouple(0),
                                                   >>  77   nLambdaBins(90),
                                                   >>  78   integral(true),
                                                   >>  79   meanFreePath(true)
 81 {                                                  80 {
 82   theParameters = G4EmParameters::Instance();  << 
 83   SetVerboseLevel(1);                          << 
 84                                                    81 
 85   // Size of tables                            <<  82   minKinEnergy         = 0.1*keV;
 86   minKinEnergy = 0.1*CLHEP::keV;               <<  83   maxKinEnergy         = 100.0*GeV;
 87   maxKinEnergy = 100.0*CLHEP::TeV;             << 
 88                                                << 
 89   // default lambda factor                     << 
 90   invLambdaFactor = 1.0/lambdaFactor;          << 
 91                                                << 
 92   // particle types                            << 
 93   theGamma = G4Gamma::Gamma();                 << 
 94   theElectron = G4Electron::Electron();        << 
 95   thePositron = G4Positron::Positron();        << 
 96                                                << 
 97   pParticleChange = &fParticleChange;          << 
 98   fParticleChange.SetSecondaryWeightByProcess( << 
 99   secParticles.reserve(5);                     << 
100                                                    84 
101   modelManager = new G4EmModelManager();           85   modelManager = new G4EmModelManager();
102   lManager = G4LossTableManager::Instance();   <<  86   (G4LossTableManager::Instance())->Register(this);
103   lManager->Register(this);                    << 
104   isTheMaster = lManager->IsMaster();          << 
105   G4LossTableBuilder* bld = lManager->GetTable << 
106   theDensityFactor = bld->GetDensityFactors(); << 
107   theDensityIdx = bld->GetCoupleIndexes();     << 
108 }                                                  87 }
109                                                    88 
110 //....oooOO0OOooo........oooOO0OOooo........oo     89 //....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo....
111                                                    90 
112 G4VEmProcess::~G4VEmProcess()                      91 G4VEmProcess::~G4VEmProcess()
113 {                                                  92 {
114   if(isTheMaster) {                            <<  93   if(theLambdaTable) theLambdaTable->clearAndDestroy();
115     delete theData;                            <<  94   theLambdaTable = 0;
116     delete theEnergyOfCrossSectionMax;         <<  95   modelManager->Clear();
117   }                                            << 
118   delete modelManager;                             96   delete modelManager;
119   delete biasManager;                          <<  97   (G4LossTableManager::Instance())->DeRegister(this);
120   lManager->DeRegister(this);                  << 
121 }                                                  98 }
122                                                    99 
123 //....oooOO0OOooo........oooOO0OOooo........oo    100 //....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo....
124                                                   101 
125 void G4VEmProcess::AddEmModel(G4int order, G4V << 102 void G4VEmProcess::Initialise()
126                               const G4Region*  << 
127 {                                                 103 {
128   if(nullptr == ptr) { return; }               << 104   if(theLambdaTable) theLambdaTable->clearAndDestroy();
129   G4VEmFluctuationModel* fm = nullptr;         << 105   theLambdaTable = 0;
130   modelManager->AddEmModel(order, ptr, fm, reg << 106   modelManager->Clear();
131   ptr->SetParticleChange(pParticleChange);     << 107   theCuts = modelManager->Initialise(particle,secondaryParticle,2.,verboseLevel);
132 }                                                 108 }
133                                                   109 
134 //....oooOO0OOooo........oooOO0OOooo........oo    110 //....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo....
135                                                   111 
136 void G4VEmProcess::SetEmModel(G4VEmModel* ptr, << 112 void G4VEmProcess::BuildPhysicsTable(const G4ParticleDefinition& part)
137 {                                                 113 {
138   if(nullptr == ptr) { return; }               << 114   if( !particle ) particle = &part;
139   if(!emModels.empty()) {                      << 115   currentCouple = 0;
140     for(auto & em : emModels) { if(em == ptr)  << 116   preStepLambda = 0.0;
                                                   >> 117   if(0 < verboseLevel) {
                                                   >> 118     G4cout << "G4VEmProcess::BuildPhysicsTable() for "
                                                   >> 119            << GetProcessName()
                                                   >> 120            << " and particle " << part.GetParticleName()
                                                   >> 121            << G4endl;
                                                   >> 122   }
                                                   >> 123 
                                                   >> 124   G4bool cutsWasModified = false;
                                                   >> 125   const G4ProductionCutsTable* theCoupleTable=
                                                   >> 126         G4ProductionCutsTable::GetProductionCutsTable();
                                                   >> 127   size_t numOfCouples = theCoupleTable->GetTableSize();
                                                   >> 128   for (size_t j=0; j<numOfCouples; j++){
                                                   >> 129     if (theCoupleTable->GetMaterialCutsCouple(j)->IsRecalcNeeded()) {
                                                   >> 130       cutsWasModified = true;
                                                   >> 131       break;
                                                   >> 132     }
                                                   >> 133   }
                                                   >> 134   if( !cutsWasModified ) return;
                                                   >> 135 
                                                   >> 136   Initialise();
                                                   >> 137   theLambdaTable = BuildLambdaTable();
                                                   >> 138   PrintInfoDefinition();
                                                   >> 139 
                                                   >> 140   if(0 < verboseLevel && theCuts) {
                                                   >> 141     G4cout << "G4VEmProcess::BuildPhysicsTable() done for "
                                                   >> 142            << GetProcessName()
                                                   >> 143            << " and particle " << part.GetParticleName()
                                                   >> 144            << G4endl;
141   }                                               145   }
142   emModels.push_back(ptr);                     << 
143 }                                                 146 }
144                                                   147 
145 //....oooOO0OOooo........oooOO0OOooo........oo    148 //....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo....
146                                                   149 
147 void G4VEmProcess::PreparePhysicsTable(const G << 150 G4PhysicsTable* G4VEmProcess::BuildLambdaTable()
148 {                                                 151 {
149   if(nullptr == particle) { SetParticle(&part) << 
150                                                   152 
151   if(part.GetParticleType() == "nucleus" &&    << 153   if(0 < verboseLevel) {
152      part.GetParticleSubType() == "generic") { << 154     G4cout << "G4VEnergyLossSTD::BuildLambdaTable() for process "
                                                   >> 155            << GetProcessName() << " and particle "
                                                   >> 156            << particle->GetParticleName()
                                                   >> 157            << G4endl;
                                                   >> 158   }
153                                                   159 
154     G4String pname = part.GetParticleName();   << 160   // Access to materials
155     if(pname != "deuteron" && pname != "triton << 161   const G4ProductionCutsTable* theCoupleTable=
156        pname != "He3" && pname != "alpha" && p << 162         G4ProductionCutsTable::GetProductionCutsTable();
157        pname != "helium" && pname != "hydrogen << 163   size_t numOfCouples = theCoupleTable->GetTableSize();
158                                                   164 
159       particle = G4GenericIon::GenericIon();   << 165   G4PhysicsTable* theTable = new G4PhysicsTable(numOfCouples);
160       isIon = true;                            << 
161     }                                          << 
162   }                                            << 
163   if(particle != &part) { return; }            << 
164                                                   166 
165   lManager->PreparePhysicsTable(&part, this);  << 167   for(size_t i=0; i<numOfCouples; i++) {
166                                                   168 
167   // for new run                               << 169     // create physics vector and fill it
168   currentCouple = nullptr;                     << 170     const G4MaterialCutsCouple* couple = theCoupleTable->GetMaterialCutsCouple(i);
169   preStepLambda = 0.0;                         << 171     G4PhysicsVector* aVector = LambdaPhysicsVector(couple);
170   fLambdaEnergy = 0.0;                         << 172     modelManager->FillLambdaVector(aVector, couple);
171                                                   173 
172   InitialiseProcess(particle);                 << 174     // Insert vector for this material into the table
                                                   >> 175     theTable->insert(aVector) ;
                                                   >> 176   }
173                                                   177 
174   G4LossTableBuilder* bld = lManager->GetTable << 178   if(0 < verboseLevel) {
175   const G4ProductionCutsTable* theCoupleTable= << 179     G4cout << "Lambda table is built for "
176     G4ProductionCutsTable::GetProductionCutsTa << 180            << particle->GetParticleName()
177   theCutsGamma    = theCoupleTable->GetEnergyC << 181            << G4endl;
178   theCutsElectron = theCoupleTable->GetEnergyC << 182     if(2 < verboseLevel) {
179   theCutsPositron = theCoupleTable->GetEnergyC << 183       G4cout << *theTable << G4endl;
180                                                << 
181   // initialisation of the process             << 
182   if(!actMinKinEnergy) { minKinEnergy = thePar << 
183   if(!actMaxKinEnergy) { maxKinEnergy = thePar << 
184                                                << 
185   applyCuts       = theParameters->ApplyCuts() << 
186   lambdaFactor    = theParameters->LambdaFacto << 
187   invLambdaFactor = 1.0/lambdaFactor;          << 
188   theParameters->DefineRegParamForEM(this);    << 
189                                                << 
190   // integral option may be disabled           << 
191   if(!theParameters->Integral()) { fXSType = f << 
192                                                << 
193   // prepare tables                            << 
194   if(isTheMaster) {                            << 
195     if(nullptr == theData) { theData = new G4E << 
196                                                << 
197     if(buildLambdaTable) {                     << 
198       theLambdaTable = theData->MakeTable(0);  << 
199       bld->InitialiseBaseMaterials(theLambdaTa << 
200     }                                          << 
201     // high energy table                       << 
202     if(minKinEnergyPrim < maxKinEnergy) {      << 
203       theLambdaTablePrim = theData->MakeTable( << 
204       bld->InitialiseBaseMaterials(theLambdaTa << 
205     }                                             184     }
206   }                                               185   }
207   // models                                    << 186 
208   baseMat = bld->GetBaseMaterialFlag();        << 187   return theTable;
209   numberOfModels = modelManager->NumberOfModel << 
210   currentModel = modelManager->GetModel(0);    << 
211   if(nullptr != lManager->AtomDeexcitation())  << 
212     modelManager->SetFluoFlag(true);           << 
213   }                                            << 
214   // forced biasing                            << 
215   if(nullptr != biasManager) {                 << 
216     biasManager->Initialise(part, GetProcessNa << 
217     biasFlag = false;                          << 
218   }                                            << 
219                                                << 
220   theCuts =                                    << 
221     G4EmTableUtil::PrepareEmProcess(this, part << 
222                                     modelManag << 
223                                     secID, tri << 
224                                     verboseLev << 
225 }                                                 188 }
226                                                   189 
227 //....oooOO0OOooo........oooOO0OOooo........oo    190 //....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo....
228                                                   191 
229 void G4VEmProcess::BuildPhysicsTable(const G4P << 192 void G4VEmProcess::SetParticle(const G4ParticleDefinition* p)
230 {                                                 193 {
231   if(nullptr == masterProc) {                  << 194   particle = p;
232     if(isTheMaster) { masterProc = this; }     << 
233     else { masterProc = static_cast<const G4VE << 
234   }                                            << 
235   G4int nModels = modelManager->NumberOfModels << 
236   G4bool isLocked = theParameters->IsPrintLock << 
237   G4bool toBuild = (buildLambdaTable || minKin << 
238                                                << 
239   G4EmTableUtil::BuildEmProcess(this, masterPr << 
240                                 nModels, verbo << 
241                                 isLocked, toBu << 
242 }                                              << 
243                                                << 
244 //....oooOO0OOooo........oooOO0OOooo........oo << 
245                                                << 
246 void G4VEmProcess::BuildLambdaTable()          << 
247 {                                              << 
248   G4double scale = theParameters->MaxKinEnergy << 
249   G4int nbin =                                 << 
250     theParameters->NumberOfBinsPerDecade()*G4l << 
251   if(actBinning) { nbin = std::max(nbin, nLamb << 
252   scale = nbin/G4Log(scale);                   << 
253                                                << 
254   G4LossTableBuilder* bld = lManager->GetTable << 
255   G4EmTableUtil::BuildLambdaTable(this, partic << 
256                                   bld, theLamb << 
257                                   minKinEnergy << 
258                                   maxKinEnergy << 
259                                   startFromNul << 
260 }                                              << 
261                                                << 
262 //....oooOO0OOooo........oooOO0OOooo........oo << 
263                                                << 
264 void G4VEmProcess::StreamInfo(std::ostream& ou << 
265                   const G4ParticleDefinition&  << 
266 {                                              << 
267   G4String indent = (rst ? "  " : "");         << 
268   out << std::setprecision(6);                 << 
269   out << G4endl << indent << GetProcessName()  << 
270   if (!rst) {                                  << 
271     out << " for " << part.GetParticleName();  << 
272   }                                            << 
273   if(fXSType != fEmNoIntegral)  { out << " XSt << 
274   if(applyCuts) { out << " applyCuts:1 "; }    << 
275   G4int subtype = GetProcessSubType();         << 
276   out << " SubType=" << subtype;               << 
277   if (subtype == fAnnihilation) {              << 
278     G4int mod = theParameters->PositronAtRestM << 
279     const G4String namp[2] = {"Simple", "Allis << 
280     out << " AtRestModel:" << namp[mod];       << 
281   }                                            << 
282   if(biasFactor != 1.0) { out << "  BiasingFac << 
283   out << " BuildTable=" << buildLambdaTable << << 
284   if(buildLambdaTable) {                       << 
285     if(particle == &part) {                    << 
286       for(auto & v : *theLambdaTable) {        << 
287         if(nullptr != v) {                     << 
288           out << "      Lambda table from ";   << 
289           G4double emin = v->Energy(0);        << 
290           G4double emax = v->GetMaxEnergy();   << 
291           G4int nbin = G4int(v->GetVectorLengt << 
292           if(emin > minKinEnergy) { out << "th << 
293           else { out << G4BestUnit(emin,"Energ << 
294           out << " to "                        << 
295               << G4BestUnit(emax,"Energy")     << 
296               << ", " << G4lrint(nbin/std::log << 
297               << " bins/decade, spline: "      << 
298               << splineFlag << G4endl;         << 
299           break;                               << 
300         }                                      << 
301       }                                        << 
302     } else {                                   << 
303       out << "      Used Lambda table of "     << 
304       << particle->GetParticleName() << G4endl << 
305     }                                          << 
306   }                                            << 
307   if(minKinEnergyPrim < maxKinEnergy) {        << 
308     if(particle == &part) {                    << 
309       for(auto & v : *theLambdaTablePrim) {    << 
310         if(nullptr != v) {                     << 
311           out << "      LambdaPrime table from << 
312               << G4BestUnit(v->Energy(0),"Ener << 
313               << " to "                        << 
314               << G4BestUnit(v->GetMaxEnergy(), << 
315               << " in " << v->GetVectorLength( << 
316               << " bins " << G4endl;           << 
317           break;                               << 
318         }                                      << 
319       }                                        << 
320     } else {                                   << 
321       out << "      Used LambdaPrime table of  << 
322                << particle->GetParticleName()  << 
323     }                                          << 
324   }                                            << 
325   StreamProcessInfo(out);                      << 
326   modelManager->DumpModelList(out, verboseLeve << 
327                                                << 
328   if(verboseLevel > 2 && buildLambdaTable) {   << 
329     out << "      LambdaTable address= " << th << 
330     if(theLambdaTable && particle == &part) {  << 
331       out << (*theLambdaTable) << G4endl;      << 
332     }                                          << 
333   }                                            << 
334 }                                                 195 }
335                                                   196 
336 //....oooOO0OOooo........oooOO0OOooo........oo    197 //....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo....
337                                                   198 
338 void G4VEmProcess::StartTracking(G4Track* trac << 199 void G4VEmProcess::SetSecondaryParticle(const G4ParticleDefinition* p)
339 {                                                 200 {
340   // reset parameters for the new track        << 201   secondaryParticle = p;
341   currentParticle = track->GetParticleDefiniti << 
342   theNumberOfInteractionLengthLeft = -1.0;     << 
343   mfpKinEnergy = DBL_MAX;                      << 
344   preStepLambda = 0.0;                         << 
345                                                << 
346   if(isIon) { massRatio = proton_mass_c2/curre << 
347                                                << 
348   // forced biasing only for primary particles << 
349   if(biasManager) {                            << 
350     if(0 == track->GetParentID()) {            << 
351       // primary particle                      << 
352       biasFlag = true;                         << 
353       biasManager->ResetForcedInteraction();   << 
354     }                                          << 
355   }                                            << 
356 }                                                 202 }
357                                                   203 
358 //....oooOO0OOooo........oooOO0OOooo........oo    204 //....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo....
359                                                   205 
360 G4double G4VEmProcess::PostStepGetPhysicalInte << 206 void G4VEmProcess::AddEmModel(G4int order, G4VEmModel* p,
361                              const G4Track& tr << 207                                       G4VEmFluctuationModel*,
362                              G4double   previo << 208                                 const G4Region* region)
363                              G4ForceCondition* << 209 {
364 {                                              << 210   modelManager->AddEmModel(order, p, 0, region);
365   *condition = NotForced;                      << 
366   G4double x = DBL_MAX;                        << 
367                                                << 
368   DefineMaterial(track.GetMaterialCutsCouple() << 
369   preStepKinEnergy = track.GetKineticEnergy(); << 
370   const G4double scaledEnergy = preStepKinEner << 
371   SelectModel(scaledEnergy, currentCoupleIndex << 
372   /*                                           << 
373   G4cout << "PostStepGetPhysicalInteractionLen << 
374          << "  couple: " << currentCouple << G << 
375   */                                           << 
376   if(!currentModel->IsActive(scaledEnergy)) {  << 
377     theNumberOfInteractionLengthLeft = -1.0;   << 
378     currentInteractionLength = DBL_MAX;        << 
379     mfpKinEnergy = DBL_MAX;                    << 
380     preStepLambda = 0.0;                       << 
381     return x;                                  << 
382   }                                            << 
383                                                << 
384   // forced biasing only for primary particles << 
385   if(biasManager) {                            << 
386     if(0 == track.GetParentID()) {             << 
387       if(biasFlag &&                           << 
388          biasManager->ForcedInteractionRegion( << 
389         return biasManager->GetStepLimit((G4in << 
390       }                                        << 
391     }                                          << 
392   }                                            << 
393                                                << 
394   // compute mean free path                    << 
395                                                << 
396   ComputeIntegralLambda(preStepKinEnergy, trac << 
397                                                << 
398   // zero cross section                        << 
399   if(preStepLambda <= 0.0) {                   << 
400     theNumberOfInteractionLengthLeft = -1.0;   << 
401     currentInteractionLength = DBL_MAX;        << 
402                                                << 
403   } else {                                     << 
404                                                << 
405     // non-zero cross section                  << 
406     if (theNumberOfInteractionLengthLeft < 0.0 << 
407                                                << 
408       // beggining of tracking (or just after  << 
409       theNumberOfInteractionLengthLeft = -G4Lo << 
410       theInitialNumberOfInteractionLength = th << 
411                                                << 
412     } else {                                   << 
413                                                << 
414       theNumberOfInteractionLengthLeft -=      << 
415         previousStepSize/currentInteractionLen << 
416       theNumberOfInteractionLengthLeft =       << 
417         std::max(theNumberOfInteractionLengthL << 
418     }                                          << 
419                                                << 
420     // new mean free path and step limit for t << 
421     currentInteractionLength = 1.0/preStepLamb << 
422     x = theNumberOfInteractionLengthLeft * cur << 
423   }                                            << 
424   return x;                                    << 
425 }                                                 211 }
426                                                   212 
427 //....oooOO0OOooo........oooOO0OOooo........oo    213 //....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo....
428                                                   214 
429 void G4VEmProcess::ComputeIntegralLambda(G4dou << 215 void G4VEmProcess::UpdateEmModel(const G4String& nam, G4double emin,
                                                   >> 216                                                               G4double emax)
430 {                                                 217 {
431   if (fXSType == fEmNoIntegral) {              << 218   modelManager->UpdateEmModel(nam, emin, emax);
432     preStepLambda = GetCurrentLambda(e, LogEki << 
433                                                << 
434   } else if (fXSType == fEmIncreasing) {       << 
435     if(e*invLambdaFactor < mfpKinEnergy) {     << 
436       preStepLambda = GetCurrentLambda(e, LogE << 
437       mfpKinEnergy = (preStepLambda > 0.0) ? e << 
438     }                                          << 
439                                                << 
440   } else if(fXSType == fEmDecreasing) {        << 
441     if(e < mfpKinEnergy) {                     << 
442       const G4double e1 = e*lambdaFactor;      << 
443       preStepLambda = GetCurrentLambda(e1);    << 
444       mfpKinEnergy = e1;                       << 
445     }                                          << 
446                                                << 
447   } else if(fXSType == fEmOnePeak) {           << 
448     const G4double epeak = (*theEnergyOfCrossS << 
449     if(e <= epeak) {                           << 
450       if(e*invLambdaFactor < mfpKinEnergy) {   << 
451         preStepLambda = GetCurrentLambda(e, Lo << 
452         mfpKinEnergy = (preStepLambda > 0.0) ? << 
453       }                                        << 
454     } else if(e < mfpKinEnergy) {              << 
455       const G4double e1 = std::max(epeak, e*la << 
456       preStepLambda = GetCurrentLambda(e1);    << 
457       mfpKinEnergy = e1;                       << 
458     }                                          << 
459   } else {                                     << 
460     preStepLambda = GetCurrentLambda(e, LogEki << 
461   }                                            << 
462 }                                                 219 }
463                                                   220 
464 //....oooOO0OOooo........oooOO0OOooo........oo    221 //....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo....
465                                                   222 
466 G4VParticleChange* G4VEmProcess::PostStepDoIt(    223 G4VParticleChange* G4VEmProcess::PostStepDoIt(const G4Track& track,
467                                                   224                                               const G4Step& step)
468 {                                                 225 {
469   // clear number of interaction lengths in an << 226   aParticleChange.Initialize(track);
470   theNumberOfInteractionLengthLeft = -1.0;     << 227   G4double finalT = track.GetKineticEnergy();
471   mfpKinEnergy = DBL_MAX;                      << 
472                                                << 
473   fParticleChange.InitializeForPostStep(track) << 
474                                                << 
475   // Do not make anything if particle is stopp << 
476   // should be performed by the AtRestDoIt!    << 
477   if (track.GetTrackStatus() == fStopButAlive) << 
478                                                << 
479   const G4double finalT = track.GetKineticEner << 
480                                                << 
481   // forced process - should happen only once  << 
482   if(biasFlag) {                               << 
483     if(biasManager->ForcedInteractionRegion((G << 
484       biasFlag = false;                        << 
485     }                                          << 
486   }                                            << 
487                                                << 
488   // check active and select model             << 
489   const G4double scaledEnergy = finalT*massRat << 
490   SelectModel(scaledEnergy, currentCoupleIndex << 
491   if(!currentModel->IsActive(scaledEnergy)) {  << 
492                                                   228 
493   // Integral approach                            229   // Integral approach
494   if (fXSType != fEmNoIntegral) {              << 230   if (integral) {
495     const G4double logFinalT =                 << 231     G4bool b;
496       track.GetDynamicParticle()->GetLogKineti << 232     G4double postStepLambda =
497     const G4double lx = std::max(GetCurrentLam << 233              (((*theLambdaTable)[currentMaterialIndex])->GetValue(finalT,b));
498 #ifdef G4VERBOSE                               << 234 
499     if(preStepLambda < lx && 1 < verboseLevel) << 235     if(preStepLambda*G4UniformRand() > postStepLambda)
500       G4cout << "WARNING: for " << currentPart << 236       return G4VRestDiscreteProcess::PostStepDoIt(track,step);
501              << " and " << GetProcessName() << << 
502              << " preLambda= " << preStepLambd << 
503              << " < " << lx << " (postLambda)  << 
504     }                                          << 
505 #endif                                         << 
506     // if false interaction then use new cross << 
507     // if both values are zero - no interactio << 
508     if(preStepLambda*G4UniformRand() >= lx) {  << 
509       return &fParticleChange;                 << 
510     }                                          << 
511   }                                               237   }
512                                                   238 
513   // define new weight for primary and seconda << 239   G4VEmModel* currentModel = SelectModel(finalT);
514   G4double weight = fParticleChange.GetParentW << 240   G4double tcut = (*theCuts)[currentMaterialIndex];
515   if(weightFlag) {                             << 241   const G4DynamicParticle* dynParticle = track.GetDynamicParticle();
516     weight /= biasFactor;                      << 242 
517     fParticleChange.ProposeWeight(weight);     << 243   /*
518   }                                            << 244   if(0 < verboseLevel) {
519                                                << 245     const G4ParticleDefinition* pd = dynParticle->GetDefinition();
520 #ifdef G4VERBOSE                               << 
521   if(1 < verboseLevel) {                       << 
522     G4cout << "G4VEmProcess::PostStepDoIt: Sam    246     G4cout << "G4VEmProcess::PostStepDoIt: Sample secondary; E= "
523            << finalT/MeV                          247            << finalT/MeV
524            << " MeV; model= (" << currentModel << 248            << " MeV; model= (" << currentModel->LowEnergyLimit(pd)
525            << ", " <<  currentModel->HighEnerg << 249            << ", " <<  currentModel->HighEnergyLimit(pd) << ")"
526            << G4endl;                             250            << G4endl;
527   }                                               251   }
528 #endif                                         << 252   */
529                                                << 
530   // sample secondaries                        << 
531   secParticles.clear();                        << 
532   currentModel->SampleSecondaries(&secParticle << 
533                                   currentCoupl << 
534                                   track.GetDyn << 
535                                   (*theCuts)[c << 
536                                                << 
537   G4int num0 = (G4int)secParticles.size();     << 
538                                                << 
539   // splitting or Russian roulette             << 
540   if(biasManager) {                            << 
541     if(biasManager->SecondaryBiasingRegion((G4 << 
542       G4double eloss = 0.0;                    << 
543       weight *= biasManager->ApplySecondaryBia << 
544         secParticles, track, currentModel, &fP << 
545         (G4int)currentCoupleIndex, (*theCuts)[ << 
546         step.GetPostStepPoint()->GetSafety()); << 
547       if(eloss > 0.0) {                        << 
548         eloss += fParticleChange.GetLocalEnerg << 
549         fParticleChange.ProposeLocalEnergyDepo << 
550       }                                        << 
551     }                                          << 
552   }                                            << 
553                                                << 
554   // save secondaries                          << 
555   G4int num = (G4int)secParticles.size();      << 
556   if(num > 0) {                                << 
557                                                << 
558     fParticleChange.SetNumberOfSecondaries(num << 
559     G4double edep = fParticleChange.GetLocalEn << 
560     G4double time = track.GetGlobalTime();     << 
561                                                << 
562     G4int n1(0), n2(0);                        << 
563     if(num0 > mainSecondaries) {               << 
564       currentModel->FillNumberOfSecondaries(n1 << 
565     }                                          << 
566                                                << 
567     for (G4int i=0; i<num; ++i) {              << 
568       G4DynamicParticle* dp = secParticles[i]; << 
569       if (nullptr != dp) {                     << 
570         const G4ParticleDefinition* p = dp->Ge << 
571         G4double e = dp->GetKineticEnergy();   << 
572         G4bool good = true;                    << 
573         if(applyCuts) {                        << 
574           if (p == theGamma) {                 << 
575             if (e < (*theCutsGamma)[currentCou << 
576                                                << 
577           } else if (p == theElectron) {       << 
578             if (e < (*theCutsElectron)[current << 
579                                                << 
580           } else if (p == thePositron) {       << 
581             if (electron_mass_c2 < (*theCutsGa << 
582                 e < (*theCutsPositron)[current << 
583               good = false;                    << 
584               e += 2.0*electron_mass_c2;       << 
585             }                                  << 
586           }                                    << 
587           // added secondary if it is good     << 
588         }                                      << 
589         if (good) {                            << 
590           G4Track* t = new G4Track(dp, time, t << 
591           t->SetTouchableHandle(track.GetTouch << 
592           if (biasManager) {                   << 
593             t->SetWeight(weight * biasManager- << 
594           } else {                             << 
595             t->SetWeight(weight);              << 
596           }                                    << 
597           pParticleChange->AddSecondary(t);    << 
598                                                << 
599           // define type of secondary          << 
600           if(i < mainSecondaries) {            << 
601             t->SetCreatorModelID(secID);       << 
602             if(GetProcessSubType() == fCompton << 
603               t->SetCreatorModelID(_ComptonGam << 
604             }                                  << 
605           } else if(i < mainSecondaries + n1)  << 
606             t->SetCreatorModelID(tripletID);   << 
607           } else if(i < mainSecondaries + n1 + << 
608             t->SetCreatorModelID(_IonRecoil);  << 
609           } else {                             << 
610             if(i < num0) {                     << 
611               if(p == theGamma) {              << 
612                 t->SetCreatorModelID(fluoID);  << 
613               } else {                         << 
614                 t->SetCreatorModelID(augerID); << 
615               }                                << 
616             } else {                           << 
617               t->SetCreatorModelID(biasID);    << 
618             }                                  << 
619           }                                    << 
620           /*                                   << 
621           G4cout << "Secondary(post step) has  << 
622                  << ", Ekin= " << t->GetKineti << 
623                  << GetProcessName() << " fluo << 
624                  << " augerID= " << augerID << << 
625           */                                   << 
626         } else {                               << 
627           delete dp;                           << 
628           edep += e;                           << 
629         }                                      << 
630       }                                        << 
631     }                                          << 
632     fParticleChange.ProposeLocalEnergyDeposit( << 
633   }                                            << 
634                                                << 
635   if(0.0 == fParticleChange.GetProposedKinetic << 
636      fAlive == fParticleChange.GetTrackStatus( << 
637     if(particle->GetProcessManager()->GetAtRes << 
638          { fParticleChange.ProposeTrackStatus( << 
639     else { fParticleChange.ProposeTrackStatus( << 
640   }                                            << 
641                                                   253 
642   return &fParticleChange;                     << 254   SecondariesPostStep(currentModel,currentCouple,dynParticle,tcut,finalT);
                                                   >> 255   return &aParticleChange;
643 }                                                 256 }
644                                                   257 
645 //....oooOO0OOooo........oooOO0OOooo........oo    258 //....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo....
646                                                   259 
647 G4bool G4VEmProcess::StorePhysicsTable(const G << 260 void G4VEmProcess::PrintInfoDefinition()
648                                        const G << 
649                                        G4bool  << 
650 {                                                 261 {
651   if(!isTheMaster || part != particle) { retur << 262   G4cout << G4endl << GetProcessName() << ":  " << G4endl
652   if(G4EmTableUtil::StoreTable(this, part, the << 263          << "      Lambda tables from threshold to "
653              directory, "Lambda",              << 264          << G4BestUnit(maxKinEnergy,"Energy")
654                                verboseLevel, a << 265          << " in " << nLambdaBins << " bins."
655      G4EmTableUtil::StoreTable(this, part, the << 266          << G4endl;
656              directory, "LambdaPrim",          << 267   /*
657                                verboseLevel, a << 268       G4cout << "DEDXTable address= " << theDEDXTable << G4endl;
658      return true;                              << 269       if(theDEDXTable) G4cout << (*theDEDXTable) << G4endl;
659   }                                            << 270       G4cout << "RangeTable address= " << theRangeTable << G4endl;
660   return false;                                << 271       if(theRangeTable) G4cout << (*theRangeTable) << G4endl;
661 }                                              << 272       G4cout << "InverseRangeTable address= " << theInverseRangeTable << G4endl;
662                                                << 273       if(theInverseRangeTable) G4cout << (*theInverseRangeTable) << G4endl;
663 //....oooOO0OOooo........oooOO0OOooo........oo << 274   */
                                                   >> 275   if(0 < verboseLevel) {
                                                   >> 276     G4cout << "Tables are built for " << particle->GetParticleName()
                                                   >> 277            << " IntegralFlag= " <<  integral
                                                   >> 278            << G4endl;
664                                                   279 
665 G4bool G4VEmProcess::RetrievePhysicsTable(cons << 280     if(2 < verboseLevel) {
666                                           cons << 281       G4cout << "LambdaTable address= " << theLambdaTable << G4endl;
667                                           G4bo << 282       if(theLambdaTable) G4cout << (*theLambdaTable) << G4endl;
668 {                                              << 283     }
669   if(!isTheMaster || part != particle) { retur << 
670   G4bool yes = true;                           << 
671   if(buildLambdaTable) {                       << 
672     yes = G4EmTableUtil::RetrieveTable(this, p << 
673                                        "Lambda << 
674                                        ascii,  << 
675   }                                            << 
676   if(yes && minKinEnergyPrim < maxKinEnergy) { << 
677     yes = G4EmTableUtil::RetrieveTable(this, p << 
678                                        "Lambda << 
679                                        ascii,  << 
680   }                                               284   }
681   return yes;                                  << 
682 }                                                 285 }
683                                                   286 
684 //....oooOO0OOooo........oooOO0OOooo........oo    287 //....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo....
685                                                   288 
686 G4double G4VEmProcess::GetCrossSection(G4doubl << 289 G4PhysicsVector* G4VEmProcess::LambdaPhysicsVector(const G4MaterialCutsCouple* couple)
687                                        const G << 
688 {                                                 290 {
689   CurrentSetup(couple, kinEnergy);             << 291   G4double cut  = (*theCuts)[couple->GetIndex()];
690   return GetCurrentLambda(kinEnergy, G4Log(kin << 292   G4double tmin = std::max(MinPrimaryEnergy(particle, couple->GetMaterial(), cut),
                                                   >> 293                                minKinEnergy);
                                                   >> 294   if(tmin >= maxKinEnergy) tmin = 0.5*maxKinEnergy;
                                                   >> 295   G4PhysicsVector* v = new G4PhysicsLogVector(tmin, maxKinEnergy, nLambdaBins);
                                                   >> 296   return v;
691 }                                                 297 }
692                                                   298 
693 //....oooOO0OOooo........oooOO0OOooo........oo    299 //....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo....
694                                                   300 
695 G4double G4VEmProcess::GetMeanFreePath(const G << 301 G4double G4VEmProcess::MicroscopicCrossSection(G4double kineticEnergy,
696                                        G4doubl << 302                                          const G4MaterialCutsCouple* couple)
697                                        G4Force << 
698 {                                              << 
699   *condition = NotForced;                      << 
700   return G4VEmProcess::MeanFreePath(track);    << 
701 }                                              << 
702                                                << 
703 //....oooOO0OOooo........oooOO0OOooo........oo << 
704                                                << 
705 G4double                                       << 
706 G4VEmProcess::ComputeCrossSectionPerAtom(G4dou << 
707                                          G4dou << 
708 {                                              << 
709   SelectModel(kinEnergy, currentCoupleIndex);  << 
710   return (currentModel) ?                      << 
711     currentModel->ComputeCrossSectionPerAtom(c << 
712                                              Z << 
713 }                                              << 
714                                                << 
715 //....oooOO0OOooo........oooOO0OOooo........oo << 
716                                                << 
717 G4PhysicsVector*                               << 
718 G4VEmProcess::LambdaPhysicsVector(const G4Mate << 
719 {                                                 303 {
                                                   >> 304   // Cross section per atom is calculated
720   DefineMaterial(couple);                         305   DefineMaterial(couple);
721   G4PhysicsVector* newv = new G4PhysicsLogVect << 306   G4double cross = 0.0;
722                                                << 307   G4bool b;
723   return newv;                                 << 308   if(theLambdaTable) {
724 }                                              << 309     cross = (((*theLambdaTable)[currentMaterialIndex])->
                                                   >> 310                            GetValue(kineticEnergy, b));
725                                                   311 
726 //....oooOO0OOooo........oooOO0OOooo........oo << 312     cross /= currentMaterial->GetTotNbOfAtomsPerVolume();
                                                   >> 313   }
727                                                   314 
728 const G4Element* G4VEmProcess::GetCurrentEleme << 315   return cross;
729 {                                              << 
730   return (nullptr != currentModel) ?           << 
731     currentModel->GetCurrentElement(currentMat << 
732 }                                                 316 }
733                                                   317 
734 //....oooOO0OOooo........oooOO0OOooo........oo    318 //....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo....
735                                                   319 
736 const G4Element* G4VEmProcess::GetTargetElemen << 320 G4double G4VEmProcess::MeanFreePath(const G4Track& track,
                                                   >> 321                                           G4double s,
                                                   >> 322                                           G4ForceCondition* cond)
737 {                                                 323 {
738   return (nullptr != currentModel) ?           << 324   return GetMeanFreePath(track, s, cond);
739     currentModel->GetCurrentElement(currentMat << 
740 }                                                 325 }
741                                                   326 
742 //....oooOO0OOooo........oooOO0OOooo........oo    327 //....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo....
743                                                   328 
744 const G4Isotope* G4VEmProcess::GetTargetIsotop << 329 G4bool G4VEmProcess::StorePhysicsTable(G4ParticleDefinition* part,
                                                   >> 330              const G4String& directory,
                                                   >> 331                    G4bool ascii)
745 {                                                 332 {
746   return (nullptr != currentModel) ?           << 333   G4bool yes = true;
747     currentModel->GetCurrentIsotope(GetCurrent << 
748 }                                              << 
749                                                << 
750 //....oooOO0OOooo........oooOO0OOooo........oo << 
751                                                   334 
752 void G4VEmProcess::SetCrossSectionBiasingFacto << 335   if ( theLambdaTable ) {
753 {                                              << 336     const G4String name = GetPhysicsTableFileName(part,directory,"Lambda",ascii);
754   if(f > 0.0) {                                << 337     yes = theLambdaTable->StorePhysicsTable(name,ascii);
755     biasFactor = f;                            << 
756     weightFlag = flag;                         << 
757     if(1 < verboseLevel) {                     << 
758       G4cout << "### SetCrossSectionBiasingFac << 
759              << particle->GetParticleName()    << 
760              << " and process " << GetProcessN << 
761              << " biasFactor= " << f << " weig << 
762              << G4endl;                        << 
763     }                                          << 
764   }                                               338   }
765 }                                              << 
766                                                   339 
767 //....oooOO0OOooo........oooOO0OOooo........oo << 340   if ( yes ) {
768                                                << 341     G4cout << "Physics tables are stored for " << particle->GetParticleName()
769 void                                           << 342            << " and process " << GetProcessName()
770 G4VEmProcess::ActivateForcedInteraction(G4doub << 343      << " in the directory <" << directory
771                                         G4bool << 344      << "> " << G4endl;
772 {                                              << 345   } else {
773   if(nullptr == biasManager) { biasManager = n << 346     G4cout << "Fail to store Physics Tables for " << particle->GetParticleName()
774   if(1 < verboseLevel) {                       << 
775     G4cout << "### ActivateForcedInteraction:  << 
776            << particle->GetParticleName()      << 
777            << " and process " << GetProcessNam    347            << " and process " << GetProcessName()
778            << " length(mm)= " << length/mm     << 348      << " in the directory <" << directory
779            << " in G4Region <" << r            << 349      << "> " << G4endl;
780            << "> weightFlag= " << flag         << 
781            << G4endl;                          << 
782   }                                               350   }
783   weightFlag = flag;                           << 351   return yes;
784   biasManager->ActivateForcedInteraction(lengt << 
785 }                                                 352 }
786                                                   353 
787 //....oooOO0OOooo........oooOO0OOooo........oo << 354 //....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo......
788                                                   355 
789 void                                           << 356 G4bool G4VEmProcess::RetrievePhysicsTable(G4ParticleDefinition* part,
790 G4VEmProcess::ActivateSecondaryBiasing(const G << 357                   const G4String& directory,
791                  G4double factor,              << 358                         G4bool ascii)
792                  G4double energyLimit)         << 
793 {                                                 359 {
794   if (0.0 <= factor) {                         << 360   currentCouple = 0;
795                                                << 361   preStepLambda = 0.0;
796     // Range cut can be applied only for e-    << 362   if(0 < verboseLevel) {
797     if(0.0 == factor && secondaryParticle != G << 363     G4cout << "G4VEmProcess::RetrievePhysicsTable() for "
798       { return; }                              << 364            << part->GetParticleName() << " and process "
799                                                << 365      << GetProcessName() << G4endl;
800     if(!biasManager) { biasManager = new G4EmB << 
801     biasManager->ActivateSecondaryBiasing(regi << 
802     if(1 < verboseLevel) {                     << 
803       G4cout << "### ActivateSecondaryBiasing: << 
804        << " process " << GetProcessName()      << 
805        << " factor= " << factor                << 
806        << " in G4Region <" << region           << 
807        << "> energyLimit(MeV)= " << energyLimi << 
808        << G4endl;                              << 
809     }                                          << 
810   }                                               366   }
811 }                                              << 367   G4bool yes = true;
812                                                << 
813 //....oooOO0OOooo........oooOO0OOooo........oo << 
814                                                << 
815 void G4VEmProcess::SetLambdaBinning(G4int n)   << 
816 {                                              << 
817   if(5 < n && n < 10000000) {                  << 
818     nLambdaBins = n;                           << 
819     actBinning = true;                         << 
820   } else {                                     << 
821     G4double e = (G4double)n;                  << 
822     PrintWarning("SetLambdaBinning", e);       << 
823   }                                            << 
824 }                                              << 
825                                                << 
826 //....oooOO0OOooo........oooOO0OOooo........oo << 
827                                                << 
828 void G4VEmProcess::SetMinKinEnergy(G4double e) << 
829 {                                              << 
830   if(1.e-3*eV < e && e < maxKinEnergy) {       << 
831     nLambdaBins = G4lrint(nLambdaBins*G4Log(ma << 
832                           /G4Log(maxKinEnergy/ << 
833     minKinEnergy = e;                          << 
834     actMinKinEnergy = true;                    << 
835   } else { PrintWarning("SetMinKinEnergy", e); << 
836 }                                              << 
837                                                << 
838 //....oooOO0OOooo........oooOO0OOooo........oo << 
839                                                << 
840 void G4VEmProcess::SetMaxKinEnergy(G4double e) << 
841 {                                              << 
842   if(minKinEnergy < e && e < 1.e+6*TeV) {      << 
843     nLambdaBins = G4lrint(nLambdaBins*G4Log(e/ << 
844                           /G4Log(maxKinEnergy/ << 
845     maxKinEnergy = e;                          << 
846     actMaxKinEnergy = true;                    << 
847   } else { PrintWarning("SetMaxKinEnergy", e); << 
848 }                                              << 
849                                                << 
850 //....oooOO0OOooo........oooOO0OOooo........oo << 
851                                                << 
852 void G4VEmProcess::SetMinKinEnergyPrim(G4doubl << 
853 {                                              << 
854   if(theParameters->MinKinEnergy() <= e &&     << 
855      e <= theParameters->MaxKinEnergy()) { min << 
856   else { PrintWarning("SetMinKinEnergyPrim", e << 
857 }                                              << 
858                                                << 
859 //....oooOO0OOooo........oooOO0OOooo........oo << 
860                                                << 
861 G4VEmProcess* G4VEmProcess::GetEmProcess(const << 
862 {                                              << 
863   return (nam == GetProcessName()) ? this : nu << 
864 }                                              << 
865                                                << 
866 //....oooOO0OOooo........oooOO0OOooo........oo << 
867                                                   368 
868 G4double G4VEmProcess::PolarAngleLimit() const << 369   const G4String particleName = part->GetParticleName();
869 {                                              << 370   if( !particle ) particle = part;
870   return theParameters->MscThetaLimit();       << 
871 }                                              << 
872                                                   371 
873 //....oooOO0OOooo........oooOO0OOooo........oo << 372   Initialise();
874                                                   373 
875 void G4VEmProcess::PrintWarning(G4String tit,  << 374   G4String filename;
876 {                                              << 375   const G4ProductionCutsTable* theCoupleTable=
877   G4String ss = "G4VEmProcess::" + tit;        << 376            G4ProductionCutsTable::GetProductionCutsTable();
878   G4ExceptionDescription ed;                   << 377   size_t numOfCouples = theCoupleTable->GetTableSize();
879   ed << "Parameter is out of range: " << val   << 
880      << " it will have no effect!\n" << "  Pro << 
881      << GetProcessName() << "  nbins= " << the << 
882      << " Emin(keV)= " << theParameters->MinKi << 
883      << " Emax(GeV)= " << theParameters->MaxKi << 
884   G4Exception(ss, "em0044", JustWarning, ed);  << 
885 }                                              << 
886                                                << 
887 //....oooOO0OOooo........oooOO0OOooo........oo << 
888                                                   378 
889 void G4VEmProcess::ProcessDescription(std::ost << 379   filename = GetPhysicsTableFileName(part,directory,"Lambda",ascii);
890 {                                              << 380   theLambdaTable = new G4PhysicsTable(numOfCouples);
891   if(nullptr != particle) {                    << 381   yes = theLambdaTable->RetrievePhysicsTable(filename,ascii);
892     StreamInfo(out, *particle, true);          << 382   if ( yes ) {
                                                   >> 383       if (-1 < verboseLevel) {
                                                   >> 384         G4cout << "Lambda table for " << particleName << " is retrieved from <"
                                                   >> 385                << filename << ">"
                                                   >> 386                << G4endl;
                                                   >> 387       }
                                                   >> 388       PrintInfoDefinition();
                                                   >> 389   } else {
                                                   >> 390       theLambdaTable->clearAndDestroy();
                                                   >> 391       theLambdaTable = 0;
                                                   >> 392       if (-1 < verboseLevel) {
                                                   >> 393         G4cout << "Lambda table for " << particleName << " in file <"
                                                   >> 394                << filename << "> is not exist"
                                                   >> 395                << G4endl;
                                                   >> 396       }
893   }                                               397   }
                                                   >> 398 
                                                   >> 399   return yes;
894 }                                                 400 }
895                                                   401 
896 //....oooOO0OOooo........oooOO0OOooo........oo    402 //....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo....
897                                                   403