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Geant4/examples/extended/electromagnetic/TestEm18/src/RunAction.cc

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Differences between /examples/extended/electromagnetic/TestEm18/src/RunAction.cc (Version 11.3.0) and /examples/extended/electromagnetic/TestEm18/src/RunAction.cc (Version 10.2.p1)


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 26 /// \file electromagnetic/TestEm18/src/RunActi     26 /// \file electromagnetic/TestEm18/src/RunAction.cc
 27 /// \brief Implementation of the RunAction cla     27 /// \brief Implementation of the RunAction class
 28 //                                                 28 //
                                                   >>  29 // $Id: RunAction.cc 82401 2014-06-18 14:43:54Z gcosmo $
 29 //                                                 30 //
 30 //....oooOO0OOooo........oooOO0OOooo........oo     31 //....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo......
 31 //....oooOO0OOooo........oooOO0OOooo........oo     32 //....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo......
 32                                                    33 
 33 #include "RunAction.hh"                            34 #include "RunAction.hh"
 34                                                << 
 35 #include "DetectorConstruction.hh"                 35 #include "DetectorConstruction.hh"
 36 #include "HistoManager.hh"                     << 
 37 #include "PrimaryGeneratorAction.hh"               36 #include "PrimaryGeneratorAction.hh"
                                                   >>  37 #include "HistoManager.hh"
 38                                                    38 
 39 #include "G4EmCalculator.hh"                   << 
 40 #include "G4Run.hh"                                39 #include "G4Run.hh"
                                                   >>  40 #include "G4RunManager.hh"
 41 #include "G4UnitsTable.hh"                         41 #include "G4UnitsTable.hh"
 42 #include "Randomize.hh"                        <<  42 #include "G4EmCalculator.hh"
 43                                                    43 
                                                   >>  44 #include "Randomize.hh"
 44 #include <iomanip>                                 45 #include <iomanip>
 45                                                    46 
 46 //....oooOO0OOooo........oooOO0OOooo........oo     47 //....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo......
 47                                                    48 
 48 RunAction::RunAction(DetectorConstruction* det     49 RunAction::RunAction(DetectorConstruction* det, PrimaryGeneratorAction* kin)
 49   : fDetector(det), fPrimary(kin)              <<  50 :G4UserRunAction(),fDetector(det), fPrimary(kin), fHistoManager(0)
 50 {                                              <<  51 { 
 51   fHistoManager = new HistoManager();          <<  52   fHistoManager = new HistoManager(); 
 52 }                                                  53 }
 53                                                    54 
 54 //....oooOO0OOooo........oooOO0OOooo........oo     55 //....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo......
 55                                                    56 
 56 RunAction::~RunAction()                            57 RunAction::~RunAction()
 57 {                                              <<  58 { 
 58   delete fHistoManager;                        <<  59   delete fHistoManager; 
 59 }                                                  60 }
 60                                                    61 
 61 //....oooOO0OOooo........oooOO0OOooo........oo     62 //....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo......
 62                                                    63 
 63 void RunAction::BeginOfRunAction(const G4Run*)     64 void RunAction::BeginOfRunAction(const G4Run*)
 64 {                                                  65 {
 65   // initialisation                            <<  66   //initialisation
 66   //                                               67   //
                                                   >>  68   fEnergyDeposit = 0.;
                                                   >>  69   
                                                   >>  70   fNbCharged = fNbNeutral = 0;
                                                   >>  71   fEnergyCharged = fEnergyNeutral = 0.;  
                                                   >>  72   fEmin[0] = fEmin[1] = DBL_MAX;
                                                   >>  73   fEmax[0] = fEmax[1] = 0.;    
                                                   >>  74     
 67   fNbSteps = 0;                                    75   fNbSteps = 0;
 68   fTrackLength = 0.;                               76   fTrackLength = 0.;
 69   fStepMin = DBL_MAX;                          <<  77    
 70   fStepMax = 0.;                               <<  78   //histograms
 71                                                << 
 72   fEdepPrimary = fEdepSecondary = fEdepTotal = << 
 73   fEdepPrimMin = fEdepSecMin = fEdepTotMin = D << 
 74   fEdepPrimMax = fEdepSecMax = fEdepTotMax = 0 << 
 75                                                << 
 76   fEnergyTransfered = 0.;                      << 
 77   fEtransfMin = DBL_MAX;                       << 
 78   fEtransfMax = 0.;                            << 
 79                                                << 
 80   fEnergyLost = 0.;                            << 
 81   fElostMin = DBL_MAX;                         << 
 82   fElostMax = 0.;                              << 
 83                                                << 
 84   fEnergyBalance = 0.;                         << 
 85   fEbalMin = DBL_MAX;                          << 
 86   fEbalMax = 0.;                               << 
 87                                                << 
 88   // histograms                                << 
 89   //                                               79   //
 90   G4AnalysisManager* analysisManager = G4Analy     80   G4AnalysisManager* analysisManager = G4AnalysisManager::Instance();
 91   if (analysisManager->IsActive()) {           <<  81   if ( analysisManager->IsActive() ) {
 92     analysisManager->OpenFile();                   82     analysisManager->OpenFile();
 93   }                                            <<  83   }       
 94                                                    84 
 95   // show Rndm status                          <<  85   // do not save Rndm status
                                                   >>  86   G4RunManager::GetRunManager()->SetRandomNumberStore(false);
 96   CLHEP::HepRandom::showEngineStatus();            87   CLHEP::HepRandom::showEngineStatus();
 97 }                                                  88 }
 98                                                    89 
 99 //....oooOO0OOooo........oooOO0OOooo........oo     90 //....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo......
100                                                    91 
101 void RunAction::CountProcesses(G4String procNa << 
102 {                                              << 
103   std::map<G4String, G4int>::iterator it = fPr << 
104   if (it == fProcCounter.end()) {              << 
105     fProcCounter[procName] = 1;                << 
106   }                                            << 
107   else {                                       << 
108     fProcCounter[procName]++;                  << 
109   }                                            << 
110 }                                              << 
111                                                << 
112 //....oooOO0OOooo........oooOO0OOooo........oo << 
113                                                << 
114 void RunAction::TrackLength(G4double step)     << 
115 {                                              << 
116   fTrackLength += step;                        << 
117   fNbSteps++;                                  << 
118   if (step < fStepMin) fStepMin = step;        << 
119   if (step > fStepMax) fStepMax = step;        << 
120 }                                              << 
121                                                << 
122 //....oooOO0OOooo........oooOO0OOooo........oo << 
123                                                << 
124 void RunAction::EnergyDeposited(G4double edepP << 
125 {                                              << 
126   fEdepPrimary += edepPrim;                    << 
127   if (edepPrim < fEdepPrimMin) fEdepPrimMin =  << 
128   if (edepPrim > fEdepPrimMax) fEdepPrimMax =  << 
129                                                << 
130   fEdepSecondary += edepSecond;                << 
131   if (edepSecond < fEdepSecMin) fEdepSecMin =  << 
132   if (edepSecond > fEdepSecMax) fEdepSecMax =  << 
133 }                                              << 
134                                                << 
135 //....oooOO0OOooo........oooOO0OOooo........oo << 
136                                                << 
137 void RunAction::EnergyTransferedByProcess(G4St << 
138 {                                              << 
139   std::map<G4String, MinMaxData>::iterator it  << 
140   if (it == fEtransfByProcess.end()) {         << 
141     fEtransfByProcess[process] = MinMaxData(1, << 
142   }                                            << 
143   else {                                       << 
144     MinMaxData& data = it->second;             << 
145     data.fCount++;                             << 
146     data.fVsum += energy;                      << 
147     // update min max                          << 
148     G4double emin = data.fVmin;                << 
149     if (energy < emin) data.fVmin = energy;    << 
150     G4double emax = data.fVmax;                << 
151     if (energy > emax) data.fVmax = energy;    << 
152   }                                            << 
153 }                                              << 
154                                                << 
155 //....oooOO0OOooo........oooOO0OOooo........oo << 
156                                                << 
157 void RunAction::EnergyTransfered(G4double ener << 
158 {                                              << 
159   fEnergyTransfered += energy;                 << 
160   if (energy < fEtransfMin) fEtransfMin = ener << 
161   if (energy > fEtransfMax) fEtransfMax = ener << 
162 }                                              << 
163                                                << 
164 //....oooOO0OOooo........oooOO0OOooo........oo << 
165                                                << 
166 void RunAction::TotalEnergyLost(G4double energ << 
167 {                                              << 
168   fEnergyLost += energy;                       << 
169   if (energy < fElostMin) fElostMin = energy;  << 
170   if (energy > fElostMax) fElostMax = energy;  << 
171 }                                              << 
172                                                << 
173 //....oooOO0OOooo........oooOO0OOooo........oo << 
174                                                << 
175 void RunAction::EnergyBalance(G4double energy) << 
176 {                                              << 
177   fEnergyBalance += energy;                    << 
178   if (energy < fEbalMin) fEbalMin = energy;    << 
179   if (energy > fEbalMax) fEbalMax = energy;    << 
180 }                                              << 
181                                                << 
182 //....oooOO0OOooo........oooOO0OOooo........oo << 
183                                                << 
184 void RunAction::TotalEnergyDeposit(G4double en << 
185 {                                              << 
186   fEdepTotal += energy;                        << 
187   if (energy < fEdepTotMin) fEdepTotMin = ener << 
188   if (energy > fEdepTotMax) fEdepTotMax = ener << 
189 }                                              << 
190                                                << 
191 //....oooOO0OOooo........oooOO0OOooo........oo << 
192                                                << 
193 void RunAction::EnergySpectrumOfSecondaries(G4 << 
194 {                                              << 
195   std::map<G4String, MinMaxData>::iterator it  << 
196   if (it == fEkinOfSecondaries.end()) {        << 
197     fEkinOfSecondaries[particle] = MinMaxData( << 
198   }                                            << 
199   else {                                       << 
200     MinMaxData& data = it->second;             << 
201     data.fCount++;                             << 
202     data.fVsum += energy;                      << 
203     // update min max                          << 
204     G4double emin = data.fVmin;                << 
205     if (energy < emin) data.fVmin = energy;    << 
206     G4double emax = data.fVmax;                << 
207     if (energy > emax) data.fVmax = energy;    << 
208   }                                            << 
209 }                                              << 
210                                                << 
211 //....oooOO0OOooo........oooOO0OOooo........oo << 
212                                                << 
213 void RunAction::EndOfRunAction(const G4Run* aR     92 void RunAction::EndOfRunAction(const G4Run* aRun)
214 {                                                  93 {
215   G4int nbEvents = aRun->GetNumberOfEvent();       94   G4int nbEvents = aRun->GetNumberOfEvent();
216   if (nbEvents == 0) return;                       95   if (nbEvents == 0) return;
217                                                <<  96   
218   G4Material* material = fDetector->GetMateria     97   G4Material* material = fDetector->GetMaterial();
219   G4double length = fDetector->GetSize();      <<  98   G4double length  = fDetector->GetSize();
220   G4double density = material->GetDensity();       99   G4double density = material->GetDensity();
221                                                << 100    
222   G4ParticleDefinition* particle = fPrimary->G << 101   G4ParticleDefinition* particle = fPrimary->GetParticleGun()
                                                   >> 102                                           ->GetParticleDefinition();
223   G4String partName = particle->GetParticleNam    103   G4String partName = particle->GetParticleName();
224   G4double ePrimary = fPrimary->GetParticleGun    104   G4double ePrimary = fPrimary->GetParticleGun()->GetParticleEnergy();
225                                                << 105   
226   G4int prec = G4cout.precision(3);               106   G4int prec = G4cout.precision(3);
227   G4cout << "\n ======================== run s    107   G4cout << "\n ======================== run summary ======================\n";
228   G4cout << "\n The run was " << nbEvents << "    108   G4cout << "\n The run was " << nbEvents << " " << partName << " of "
229          << G4BestUnit(ePrimary, "Energy") <<  << 109          << G4BestUnit(ePrimary,"Energy") << " through " 
230          << material->GetName() << " (density: << 110          << G4BestUnit(length,"Length") << " of "
                                                   >> 111          << material->GetName() << " (density: " 
                                                   >> 112          << G4BestUnit(density,"Volumic Mass") << ")";
                                                   >> 113   G4cout << "\n ===========================================================\n";
231   G4cout << G4endl;                               114   G4cout << G4endl;
232                                                << 115   
                                                   >> 116   //save histograms      
                                                   >> 117   G4AnalysisManager* analysisManager = G4AnalysisManager::Instance();  
                                                   >> 118   if ( analysisManager->IsActive() ) {
                                                   >> 119     analysisManager->Write();
                                                   >> 120     analysisManager->CloseFile();
                                                   >> 121   }      
                                                   >> 122     
233   if (particle->GetPDGCharge() == 0.) return;     123   if (particle->GetPDGCharge() == 0.) return;
                                                   >> 124    
                                                   >> 125   G4cout.precision(5);
                                                   >> 126   
                                                   >> 127   //track length
                                                   >> 128   //
                                                   >> 129   G4double trackLPerEvent = fTrackLength/nbEvents;
                                                   >> 130   G4double nbStepPerEvent = double(fNbSteps)/nbEvents;
                                                   >> 131   G4double stepSize = fTrackLength/fNbSteps;
                                                   >> 132   
                                                   >> 133   G4cout 
                                                   >> 134     << "\n TrackLength= " 
                                                   >> 135     << G4BestUnit(trackLPerEvent, "Length")
                                                   >> 136     << "\t nb of steps= " << nbStepPerEvent
                                                   >> 137     << "  stepSize= " << G4BestUnit(stepSize, "Length")
                                                   >> 138     << G4endl;
                                                   >> 139       
                                                   >> 140   //charged secondaries (ionization, direct pair production)
                                                   >> 141   //
                                                   >> 142   G4double energyPerEvent = fEnergyCharged/nbEvents;
                                                   >> 143   G4double nbPerEvent = double(fNbCharged)/nbEvents;
                                                   >> 144   G4double meanEkin = 0.;
                                                   >> 145   if (fNbCharged) meanEkin = fEnergyCharged/fNbCharged;
                                                   >> 146   
                                                   >> 147   G4cout 
                                                   >> 148     << "\n d-rays  : eLoss/primary= " 
                                                   >> 149     << G4BestUnit(energyPerEvent, "Energy")
                                                   >> 150     << "\t  nb of d-rays= " << nbPerEvent
                                                   >> 151     << "  <Tkin>= " << G4BestUnit(meanEkin, "Energy")
                                                   >> 152     << "  Tmin= "   << G4BestUnit(fEmin[0], "Energy")
                                                   >> 153     << "  Tmax= "   << G4BestUnit(fEmax[0], "Energy")
                                                   >> 154     << G4endl;
                                                   >> 155          
                                                   >> 156   //neutral secondaries (bremsstrahlung, pixe)
                                                   >> 157   //
                                                   >> 158   energyPerEvent = fEnergyNeutral/nbEvents;
                                                   >> 159   nbPerEvent = double(fNbNeutral)/nbEvents;
                                                   >> 160   meanEkin = 0.;
                                                   >> 161   if (fNbNeutral) meanEkin = fEnergyNeutral/fNbNeutral;
                                                   >> 162   
                                                   >> 163   G4cout 
                                                   >> 164     << "\n gamma   : eLoss/primary= " 
                                                   >> 165     << G4BestUnit(energyPerEvent, "Energy")
                                                   >> 166     << "\t  nb of gammas= " << nbPerEvent
                                                   >> 167     << "  <Tkin>= " << G4BestUnit(meanEkin, "Energy")
                                                   >> 168     << "  Tmin= "   << G4BestUnit(fEmin[1],  "Energy")
                                                   >> 169     << "  Tmax= "   << G4BestUnit(fEmax[1],  "Energy")
                                                   >> 170     << G4endl;
                                                   >> 171     
234                                                   172 
235   G4cout.precision(4);                         << 173   G4EmCalculator emCal;
236                                                << 174   
237   // frequency of processes                    << 175   //local energy deposit
238   //                                           << 
239   G4cout << "\n Process defining step :" << G4 << 
240   G4int index = 0;                             << 
241   for (const auto& procCounter : fProcCounter) << 
242     G4String procName = procCounter.first;     << 
243     G4int count = procCounter.second;          << 
244     G4String space = " ";                      << 
245     if (++index % 4 == 0) space = "\n";        << 
246     G4cout << " " << std::setw(15) << procName << 
247   }                                            << 
248   G4cout << G4endl;                            << 
249                                                << 
250   // track length                              << 
251   //                                              176   //
252   G4double trackLPerEvent = fTrackLength / nbE << 177   energyPerEvent = fEnergyDeposit/nbEvents;
253   G4double nbStepPerEvent = double(fNbSteps) / << 
254   G4double stepSize = fTrackLength / fNbSteps; << 
255                                                << 
256   G4cout << "\n TrackLength = " << G4BestUnit( << 
257          << "  nb of steps = " << nbStepPerEve << 
258          << "  stepSize = " << G4BestUnit(step << 
259          << G4BestUnit(fStepMin, "Length") <<  << 
260          << G4endl;                            << 
261                                                << 
262   // continuous energy deposited by primary tr << 
263   //                                              178   //
264   G4double energyPerEvent = fEdepPrimary / nbE << 179   G4double r0  = emCal.GetRangeFromRestricteDEDX(ePrimary,particle,material);  
265                                                << 
266   G4cout << "\n Energy continuously deposited  << 
267          << " (restricted dE/dx)  dE1 = " << G << 
268          << G4BestUnit(fEdepPrimMin, "Energy") << 
269          << ")" << G4endl;                     << 
270                                                << 
271   // eveluation of dE1 from reading restricted << 
272   //                                           << 
273   G4EmCalculator emCal;                        << 
274                                                << 
275   G4double r0 = emCal.GetRangeFromRestricteDED << 
276   G4double r1 = r0 - trackLPerEvent;              180   G4double r1 = r0 - trackLPerEvent;
277   G4double etry = ePrimary - energyPerEvent;   << 181   G4double etry = ePrimary - energyPerEvent;  
278   G4double efinal = 0.;                           182   G4double efinal = 0.;
279   if (r1 > 0.) efinal = GetEnergyFromRestricte << 183   if (r1 > 0.) efinal = GetEnergyFromRestrictedRange(r1,particle,material,etry);
280   G4double dEtable = ePrimary - efinal;           184   G4double dEtable = ePrimary - efinal;
281   G4double ratio = 0.;                            185   G4double ratio = 0.;
282   if (dEtable > 0.) ratio = energyPerEvent / d << 186   if (dEtable > 0.) ratio = energyPerEvent/dEtable;
283                                                << 187     
284   G4cout << "\n Evaluation of dE1 from reading << 188   G4cout 
285          << G4BestUnit(dEtable, "Energy") << " << 189     << "\n deposit : eLoss/primary= " 
286                                                << 190     << G4BestUnit(energyPerEvent, "Energy")
287   // energy transfered to secondary particles  << 191     << "\t <dEcut > table= " 
288   //                                           << 192     << G4BestUnit(dEtable, "Energy")
289   G4cout << "\n Energy transfered to secondary << 193     << "   ---> simul/reference= " << ratio           
290   std::map<G4String, MinMaxData>::iterator it1 << 194     << G4endl;
291   for (it1 = fEtransfByProcess.begin(); it1 != << 195     
292     G4String name = it1->first;                << 196   //total energy transferred
293     MinMaxData data = it1->second;             << 
294     energyPerEvent = data.fVsum / nbEvents;    << 
295     G4double eMin = data.fVmin;                << 
296     G4double eMax = data.fVmax;                << 
297                                                << 
298     G4cout << "  " << std::setw(17) << "due to << 
299            << G4BestUnit(energyPerEvent, "Ener << 
300            << G4BestUnit(eMax, "Energy") << ") << 
301   }                                            << 
302                                                << 
303   // total energy tranfered : dE3 = sum of dE2 << 
304   //                                           << 
305   energyPerEvent = fEnergyTransfered / nbEvent << 
306                                                << 
307   G4cout << "\n Total energy transfered to sec << 
308          << G4BestUnit(energyPerEvent, "Energy << 
309          << " --> " << G4BestUnit(fEtransfMax, << 
310                                                << 
311   // total energy lost by incident particle :  << 
312   //                                           << 
313   energyPerEvent = fEnergyLost / nbEvents;     << 
314                                                << 
315   G4cout << "\n Total energy lost by incident  << 
316          << G4BestUnit(energyPerEvent, "Energy << 
317          << " --> " << G4BestUnit(fElostMax, " << 
318                                                << 
319   // calcul of energy lost from energy balance << 
320   //                                              197   //
321   energyPerEvent = fEnergyBalance / nbEvents;  << 198   G4double energyTotal = fEnergyDeposit + fEnergyCharged + fEnergyNeutral;
322                                                << 199   energyPerEvent = energyTotal/nbEvents;
323   G4cout << "\n calcul of dE4 from energy bala << 
324          << G4BestUnit(energyPerEvent, "Energy << 
325          << " --> " << G4BestUnit(fEbalMax, "E << 
326                                                << 
327   // eveluation of dE4 from reading full Range << 
328   //                                              200   //
329   r0 = emCal.GetCSDARange(ePrimary, particle,  << 201   r0  = emCal.GetCSDARange(ePrimary,particle,material);  
330   r1 = r0 - trackLPerEvent;                       202   r1 = r0 - trackLPerEvent;
331   etry = ePrimary - energyPerEvent;               203   etry = ePrimary - energyPerEvent;
332   efinal = 0.;                                    204   efinal = 0.;
333   if (r1 > 0.) efinal = GetEnergyFromCSDARange << 205   if (r1 > 0.) efinal = GetEnergyFromCSDARange(r1,particle,material,etry);
334   dEtable = ePrimary - efinal;                    206   dEtable = ePrimary - efinal;
335   ratio = 0.;                                     207   ratio = 0.;
336   if (dEtable > 0.) ratio = energyPerEvent / d << 208   if (dEtable > 0.) ratio = energyPerEvent/dEtable;
337                                                << 209     
338   G4cout << "\n Evaluation of dE4 from reading << 210   G4cout 
339          << G4BestUnit(dEtable, "Energy") << " << 211     << "\n total   : eLoss/primary= " 
340                                                << 212     << G4BestUnit(energyPerEvent, "Energy")
341   // energy spectrum of secondary particles    << 213     << "\t <dEfull> table= " 
342   //                                           << 214     << G4BestUnit(dEtable, "Energy")
343   G4cout << "\n Energy spectrum of secondary p << 215     << "   ---> simul/reference= " << ratio           
344   std::map<G4String, MinMaxData>::iterator it2 << 216     << G4endl; 
345   for (it2 = fEkinOfSecondaries.begin(); it2 ! << 
346     G4String name = it2->first;                << 
347     MinMaxData data = it2->second;             << 
348     G4int count = data.fCount;                 << 
349     G4double eMean = data.fVsum / count;       << 
350     G4double eMin = data.fVmin;                << 
351     G4double eMax = data.fVmax;                << 
352                                                << 
353     G4cout << "  " << std::setw(13) << name << << 
354            << "  Emean = " << std::setw(6) <<  << 
355            << G4BestUnit(eMin, "Energy") << "  << 
356   }                                            << 
357   G4cout << G4endl;                            << 
358                                                << 
359   // continuous energy deposited by secondary  << 
360   //  (only if secondary particles are tracked << 
361   //                                           << 
362   if (fEdepSecondary > 0.) {                   << 
363     energyPerEvent = fEdepSecondary / nbEvents << 
364                                                << 
365     G4cout << "\n Energy continuously deposite << 
366            << " (restricted dE/dx)  dE5 = " << << 
367            << G4BestUnit(fEdepSecMin, "Energy" << 
368            << ")" << G4endl;                   << 
369                                                << 
370     // total energy deposited : dE6 = dE1 + dE << 
371     //                                         << 
372     energyPerEvent = fEdepTotal / nbEvents;    << 
373                                                << 
374     G4cout << "\n Total energy deposited : dE6 << 
375            << G4BestUnit(energyPerEvent, "Ener << 
376            << " --> " << G4BestUnit(fEdepTotMa << 
377            << G4endl;                          << 
378   }                                            << 
379                                                   217 
380   G4cout.precision(prec);                         218   G4cout.precision(prec);
381                                                   219 
382   // clear maps                                << 
383   //                                           << 
384   fProcCounter.clear();                        << 
385   fEtransfByProcess.clear();                   << 
386   fEkinOfSecondaries.clear();                  << 
387                                                << 
388   // save histograms                           << 
389   G4AnalysisManager* analysisManager = G4Analy << 
390   if (analysisManager->IsActive()) {           << 
391     analysisManager->Write();                  << 
392     analysisManager->CloseFile();              << 
393   }                                            << 
394                                                << 
395   // show Rndm status                             220   // show Rndm status
396   CLHEP::HepRandom::showEngineStatus();           221   CLHEP::HepRandom::showEngineStatus();
397 }                                                 222 }
398                                                   223 
399 //....oooOO0OOooo........oooOO0OOooo........oo    224 //....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo......
400                                                   225 
401 G4double RunAction::GetEnergyFromRestrictedRan << 226 G4double RunAction::GetEnergyFromRestrictedRange(G4double range,
402                                                << 227             G4ParticleDefinition* particle, G4Material* material, G4double Etry)
403 {                                                 228 {
404   G4EmCalculator emCal;                           229   G4EmCalculator emCal;
405                                                << 230     
406   G4double Energy = Etry, dE = 0., dEdx;          231   G4double Energy = Etry, dE = 0., dEdx;
407   G4double r, dr;                                 232   G4double r, dr;
408   G4double err = 1., errmax = 0.00001;         << 233   G4double err  = 1., errmax = 0.00001;
409   G4int iter = 0, itermax = 10;                << 234   G4int    iter = 0 , itermax = 10;  
410   while (err > errmax && iter < itermax) {        235   while (err > errmax && iter < itermax) {
411     iter++;                                       236     iter++;
412     Energy -= dE;                                 237     Energy -= dE;
413     r = emCal.GetRangeFromRestricteDEDX(Energy << 238     r = emCal.GetRangeFromRestricteDEDX(Energy,particle,material);
414     dr = r - range;                            << 239     dr = r - range;          
415     dEdx = emCal.GetDEDX(Energy, particle, mat << 240     dEdx = emCal.GetDEDX(Energy,particle,material);
416     dE = dEdx * dr;                            << 241     dE = dEdx*dr;
417     err = std::abs(dE) / Energy;               << 242     err = std::abs(dE)/Energy;    
418   }                                               243   }
419   if (iter == itermax) {                          244   if (iter == itermax) {
420     G4cout << "\n  ---> warning: RunAction::Ge << 245     G4cout 
421            << "   Etry = " << G4BestUnit(Etry, << 246     << "\n  ---> warning: RunAction::GetEnergyFromRestRange() did not converge"
422            << "   Energy = " << G4BestUnit(Ene << 247     << "   Etry = " << G4BestUnit(Etry,"Energy")
423            << "   iter = " << iter << G4endl;  << 248     << "   Energy = " << G4BestUnit(Energy,"Energy")
424   }                                            << 249     << "   err = " << err
425                                                << 250     << "   iter = " << iter << G4endl;
426   return Energy;                               << 251   }         
                                                   >> 252          
                                                   >> 253   return Energy;         
427 }                                                 254 }
428                                                   255 
429 //....oooOO0OOooo........oooOO0OOooo........oo    256 //....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo......
430                                                   257 
431 G4double RunAction::GetEnergyFromCSDARange(G4d << 258 G4double RunAction::GetEnergyFromCSDARange(G4double range,
432                                            G4M << 259             G4ParticleDefinition* particle, G4Material* material, G4double Etry)
433 {                                                 260 {
434   G4EmCalculator emCal;                           261   G4EmCalculator emCal;
435                                                << 262     
436   G4double Energy = Etry, dE = 0., dEdx;          263   G4double Energy = Etry, dE = 0., dEdx;
437   G4double r, dr;                                 264   G4double r, dr;
438   G4double err = 1., errmax = 0.00001;         << 265   G4double err  = 1., errmax = 0.00001;
439   G4int iter = 0, itermax = 10;                << 266   G4int    iter = 0 , itermax = 10;  
440   while (err > errmax && iter < itermax) {        267   while (err > errmax && iter < itermax) {
441     iter++;                                       268     iter++;
442     Energy -= dE;                                 269     Energy -= dE;
443     r = emCal.GetCSDARange(Energy, particle, m << 270     r = emCal.GetCSDARange(Energy,particle,material);
444     dr = r - range;                            << 271     dr = r - range;          
445     dEdx = emCal.ComputeTotalDEDX(Energy, part << 272     dEdx = emCal.ComputeTotalDEDX(Energy,particle,material);
446     dE = dEdx * dr;                            << 273     dE = dEdx*dr;
447     err = std::abs(dE) / Energy;               << 274     err = std::abs(dE)/Energy;
448   }                                               275   }
449   if (iter == itermax) {                          276   if (iter == itermax) {
450     G4cout << "\n  ---> warning: RunAction::Ge << 277     G4cout 
451            << "   Etry = " << G4BestUnit(Etry, << 278     << "\n  ---> warning: RunAction::GetEnergyFromCSDARange() did not converge"
452            << "   Energy = " << G4BestUnit(Ene << 279     << "   Etry = " << G4BestUnit(Etry,"Energy")
453            << "   iter = " << iter << G4endl;  << 280     << "   Energy = " << G4BestUnit(Energy,"Energy")
454   }                                            << 281     << "   err = " << err
455                                                << 282     << "   iter = " << iter << G4endl;
456   return Energy;                               << 283   }         
                                                   >> 284          
                                                   >> 285   return Energy;         
457 }                                                 286 }
458                                                   287 
459 //....oooOO0OOooo........oooOO0OOooo........oo    288 //....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo......
460                                                   289