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Geant4/examples/extended/medical/dna/svalue/src/Run.cc

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Differences between /examples/extended/medical/dna/svalue/src/Run.cc (Version 11.3.0) and /examples/extended/medical/dna/svalue/src/Run.cc (Version 11.1.2)


  1 //                                                  1 //
  2 // *******************************************      2 // ********************************************************************
  3 // * License and Disclaimer                         3 // * License and Disclaimer                                           *
  4 // *                                                4 // *                                                                  *
  5 // * The  Geant4 software  is  copyright of th      5 // * The  Geant4 software  is  copyright of the Copyright Holders  of *
  6 // * the Geant4 Collaboration.  It is provided      6 // * the Geant4 Collaboration.  It is provided  under  the terms  and *
  7 // * conditions of the Geant4 Software License      7 // * conditions of the Geant4 Software License,  included in the file *
  8 // * LICENSE and available at  http://cern.ch/      8 // * LICENSE and available at  http://cern.ch/geant4/license .  These *
  9 // * include a list of copyright holders.           9 // * include a list of copyright holders.                             *
 10 // *                                               10 // *                                                                  *
 11 // * Neither the authors of this software syst     11 // * Neither the authors of this software system, nor their employing *
 12 // * institutes,nor the agencies providing fin     12 // * institutes,nor the agencies providing financial support for this *
 13 // * work  make  any representation or  warran     13 // * work  make  any representation or  warranty, express or implied, *
 14 // * regarding  this  software system or assum     14 // * regarding  this  software system or assume any liability for its *
 15 // * use.  Please see the license in the file      15 // * use.  Please see the license in the file  LICENSE  and URL above *
 16 // * for the full disclaimer and the limitatio     16 // * for the full disclaimer and the limitation of liability.         *
 17 // *                                               17 // *                                                                  *
 18 // * This  code  implementation is the result      18 // * This  code  implementation is the result of  the  scientific and *
 19 // * technical work of the GEANT4 collaboratio     19 // * technical work of the GEANT4 collaboration.                      *
 20 // * By using,  copying,  modifying or  distri     20 // * By using,  copying,  modifying or  distributing the software (or *
 21 // * any work based  on the software)  you  ag     21 // * any work based  on the software)  you  agree  to acknowledge its *
 22 // * use  in  resulting  scientific  publicati     22 // * use  in  resulting  scientific  publications,  and indicate your *
 23 // * acceptance of all terms of the Geant4 Sof     23 // * acceptance of all terms of the Geant4 Software license.          *
 24 // *******************************************     24 // ********************************************************************
 25 //                                                 25 //
 26 // This example is provided by the Geant4-DNA      26 // This example is provided by the Geant4-DNA collaboration
 27 // Any report or published results obtained us <<  27 // Any report or published results obtained using the Geant4-DNA software 
 28 // shall cite the following Geant4-DNA collabo     28 // shall cite the following Geant4-DNA collaboration publications:
 29 // Med. Phys. 45 (2018) e722-e739              << 
 30 // Phys. Med. 31 (2015) 861-874                << 
 31 // Med. Phys. 37 (2010) 4692-4708                  29 // Med. Phys. 37 (2010) 4692-4708
 32 // Int. J. Model. Simul. Sci. Comput. 1 (2010) <<  30 // Phys. Med. 31 (2015) 861-874
 33 //                                             << 
 34 // The Geant4-DNA web site is available at htt     31 // The Geant4-DNA web site is available at http://geant4-dna.org
 35 //                                                 32 //
 36 /// \file medical/dna/svalue/src/Run.cc            33 /// \file medical/dna/svalue/src/Run.cc
 37 /// \brief Implementation of the Run class         34 /// \brief Implementation of the Run class
 38                                                    35 
 39 #include "Run.hh"                                  36 #include "Run.hh"
 40                                                <<  37 #include "DetectorConstruction.hh"
 41 #include "HistoManager.hh"                         38 #include "HistoManager.hh"
 42 #include "MyFile.hh"                               39 #include "MyFile.hh"
 43                                                    40 
 44 #ifdef MYFILE                                      41 #ifdef MYFILE
 45 #  include "MyPrimaryGeneratorActionFromFile.h <<  42  #include "MyPrimaryGeneratorActionFromFile.hh"
 46 #else                                              43 #else
 47 #  include "PrimaryGeneratorAction.hh"         <<  44  #include "PrimaryGeneratorAction.hh"
 48 #endif                                             45 #endif
 49                                                    46 
                                                   >>  47 #include "G4Material.hh"
 50 #include "G4SystemOfUnits.hh"                      48 #include "G4SystemOfUnits.hh"
 51 #include "G4UnitsTable.hh"                         49 #include "G4UnitsTable.hh"
 52                                                    50 
 53 //....oooOO0OOooo........oooOO0OOooo........oo     51 //....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo......
 54                                                    52 
 55 Run::Run(const DetectorConstruction* detector)     53 Run::Run(const DetectorConstruction* detector)
 56   : G4Run(),                                   <<  54 : G4Run(),
 57     fDetector(detector),                       <<  55   fDetector(detector),
 58     fParticle(0),                              <<  56   fParticle(0), fEkin(0.),  
 59     fEkin(0.),                                 <<  57   fCytoEdeposit(0.),  fCytoEdeposit2(0.),
 60     fCytoEdeposit(0.),                         <<  58   fNuclEdeposit(0.),  fNuclEdeposit2(0.),
 61     fCytoEdeposit2(0.),                        <<  59   fTrackLen(0.),  fTrackLen2(0.),
 62     fNuclEdeposit(0.),                         <<  60   fProjRange(0.), fProjRange2(0.),
 63     fNuclEdeposit2(0.),                        <<  61   fNbOfSteps(0), fNbOfSteps2(0),
 64     fTrackLen(0.),                             <<  62   fStepSize(0.),  fStepSize2(0.)
 65     fTrackLen2(0.),                            << 
 66     fProjRange(0.),                            << 
 67     fProjRange2(0.),                           << 
 68     fNbOfSteps(0),                             << 
 69     fNbOfSteps2(0),                            << 
 70     fStepSize(0.),                             << 
 71     fStepSize2(0.)                             << 
 72 {}                                                 63 {}
 73                                                    64 
 74 //....oooOO0OOooo........oooOO0OOooo........oo     65 //....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo......
 75                                                    66 
 76 Run::~Run() {}                                 <<  67 Run::~Run()
                                                   >>  68 {}
 77                                                    69 
 78 //....oooOO0OOooo........oooOO0OOooo........oo     70 //....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo......
 79                                                    71 
 80 void Run::SetPrimary(G4ParticleDefinition* par <<  72 void Run::SetPrimary (G4ParticleDefinition* particle, G4double energy)
 81 {                                              <<  73 { 
 82   fParticle = particle;                            74   fParticle = particle;
 83   fEkin = energy;                              <<  75   fEkin     = energy;
 84 }                                                  76 }
 85                                                    77 
 86 //....oooOO0OOooo........oooOO0OOooo........oo     78 //....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo......
 87                                                    79 
 88 void Run::AddCytoEdep(G4double e)              <<  80 void Run::AddCytoEdep (G4double e)        
 89 {                                                  81 {
 90   fCytoEdeposit += e;                          <<  82   fCytoEdeposit  += e;
 91   fCytoEdeposit2 += e * e;                     <<  83   fCytoEdeposit2 += e*e;
 92 }                                                  84 }
 93                                                    85 
 94 //....oooOO0OOooo........oooOO0OOooo........oo     86 //....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo......
 95                                                    87 
 96 void Run::AddNuclEdep(G4double e)              <<  88 void Run::AddNuclEdep (G4double e)        
 97 {                                                  89 {
 98   fNuclEdeposit += e;                          <<  90   fNuclEdeposit  += e;
 99   fNuclEdeposit2 += e * e;                     <<  91   fNuclEdeposit2 += e*e;
100 }                                                  92 }
101                                                    93 
102 //....oooOO0OOooo........oooOO0OOooo........oo     94 //....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo......
103                                                <<  95     
104 void Run::AddTrackLength(G4double t)           <<  96 void Run::AddTrackLength (G4double t) 
105 {                                                  97 {
106   fTrackLen += t;                              <<  98   fTrackLen  += t;
107   fTrackLen2 += t * t;                         <<  99   fTrackLen2 += t*t;
108 }                                                 100 }
109                                                   101 
110 //....oooOO0OOooo........oooOO0OOooo........oo    102 //....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo......
111                                                << 103     
112 void Run::AddProjRange(G4double x)             << 104 void Run::AddProjRange (G4double x) 
113 {                                                 105 {
114   fProjRange += x;                             << 106   fProjRange  += x;
115   fProjRange2 += x * x;                        << 107   fProjRange2 += x*x;
116 }                                                 108 }
117                                                   109 
118 //....oooOO0OOooo........oooOO0OOooo........oo    110 //....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo......
119                                                << 111     
120 void Run::AddStepSize(G4int nb, G4double st)   << 112 void Run::AddStepSize (G4int nb, G4double st)
121 {                                                 113 {
122   fNbOfSteps += nb;                            << 114   fNbOfSteps  += nb; 
123   fNbOfSteps2 += nb * nb;                      << 115   fNbOfSteps2 += nb*nb;
124   fStepSize += st;                             << 116   fStepSize   += st ; 
125   fStepSize2 += st * st;                       << 117   fStepSize2  += st*st;  
126 }                                                 118 }
127                                                   119 
128 //....oooOO0OOooo........oooOO0OOooo........oo    120 //....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo......
129                                                   121 
130 void Run::Merge(const G4Run* run)                 122 void Run::Merge(const G4Run* run)
131 {                                                 123 {
132   const Run* localRun = static_cast<const Run*    124   const Run* localRun = static_cast<const Run*>(run);
133                                                << 125   
134   // Pass information about primary particle   << 126   // pass information about primary particle
135                                                << 
136   fParticle = localRun->fParticle;                127   fParticle = localRun->fParticle;
137   fEkin = localRun->fEkin;                     << 128   fEkin     = localRun->fEkin;
138                                                << 
139   // Accumulate sums                           << 
140                                                   129 
141   fCytoEdeposit += localRun->fCytoEdeposit;    << 130   // accumulate sums
142   fCytoEdeposit2 += localRun->fCytoEdeposit2;  << 131   
143   fNuclEdeposit += localRun->fNuclEdeposit;    << 132   fCytoEdeposit   += localRun->fCytoEdeposit;
144   fNuclEdeposit2 += localRun->fNuclEdeposit2;  << 133   fCytoEdeposit2  += localRun->fCytoEdeposit2;
145                                                << 134   fNuclEdeposit   += localRun->fNuclEdeposit;
146   fTrackLen += localRun->fTrackLen;            << 135   fNuclEdeposit2  += localRun->fNuclEdeposit2;
147   fTrackLen2 += localRun->fTrackLen2;          << 136   
148   fProjRange += localRun->fProjRange;          << 137   fTrackLen   += localRun->fTrackLen;  
                                                   >> 138   fTrackLen2  += localRun->fTrackLen2;
                                                   >> 139   fProjRange  += localRun->fProjRange; 
149   fProjRange2 += localRun->fProjRange2;           140   fProjRange2 += localRun->fProjRange2;
150   fNbOfSteps += localRun->fNbOfSteps;          << 141   fNbOfSteps  += localRun->fNbOfSteps ;
151   fNbOfSteps2 += localRun->fNbOfSteps2;           142   fNbOfSteps2 += localRun->fNbOfSteps2;
152   fStepSize += localRun->fStepSize;            << 143   fStepSize   += localRun->fStepSize;  
153   fStepSize2 += localRun->fStepSize2;          << 144   fStepSize2  += localRun->fStepSize2;
154                                                   145 
155   G4Run::Merge(run);                           << 146   G4Run::Merge(run); 
156 }                                              << 147 } 
157                                                   148 
158 //....oooOO0OOooo........oooOO0OOooo........oo    149 //....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo......
159                                                   150 
160 void Run::EndOfRun()                           << 151 void Run::EndOfRun() 
161 {                                                 152 {
162   std::ios::fmtflags mode = G4cout.flags();       153   std::ios::fmtflags mode = G4cout.flags();
163   G4cout.setf(std::ios::fixed, std::ios::float << 154   G4cout.setf(std::ios::fixed,std::ios::floatfield);
164   G4int prec = G4cout.precision(2);               155   G4int prec = G4cout.precision(2);
165                                                << 156   
166   // Run conditions                            << 157   //run conditions  
167                                                << 158   //
168   G4String partName = fParticle->GetParticleNa    159   G4String partName = fParticle->GetParticleName();
169                                                << 160   
170   G4cout << "\n ======================== run s << 161   G4cout << "\n ======================== run summary =====================\n";  
171   G4cout << "\n The run is " << numberOfEvent  << 162   G4cout 
172          << G4BestUnit(fEkin, "Energy") << G4e << 163     << "\n The run is " << numberOfEvent << " "<< partName << " of "
                                                   >> 164     << G4BestUnit(fEkin,"Energy") << G4endl;    
173                                                   165 
174   if (numberOfEvent == 0) {                       166   if (numberOfEvent == 0) {
175     G4cout.setf(mode, std::ios::floatfield);   << 167     G4cout.setf(mode,std::ios::floatfield);
176     G4cout.precision(prec);                    << 168     G4cout.precision(prec);  
177     return;                                       169     return;
178   }                                               170   }
179                                                << 171       
180   // Compute S-value for cytoplasm (C<-C)      << 172   //
181                                                << 173   
182   fCytoEdeposit /= numberOfEvent;              << 174   fCytoEdeposit /= numberOfEvent; fCytoEdeposit2 /= numberOfEvent;
183   fCytoEdeposit2 /= numberOfEvent;             << 175   G4double rmsCyto = fCytoEdeposit2 - fCytoEdeposit*fCytoEdeposit;        
184   G4double rmsCyto = fCytoEdeposit2 - fCytoEde << 176   if (rmsCyto>0.) rmsCyto = std::sqrt(rmsCyto); else rmsCyto = 0.;
185   if (rmsCyto > 0.)                            << 177 
186     rmsCyto = std::sqrt(rmsCyto);              << 178   G4cout.precision(3);       
187   else                                         << 179   G4cout 
188     rmsCyto = 0.;                              << 180     << "\n Total Energy deposited in cytoplasm = " << G4BestUnit(fCytoEdeposit,"Energy")
189                                                << 181     << " +- "                                << G4BestUnit( rmsCyto,"Energy")
190   G4cout.precision(3);                         << 182     << G4endl;
191   G4cout << "\n Total Energy deposited in cyto << 183                     
192          << " +- " << G4BestUnit(rmsCyto, "Ene << 184   G4double sValueCyto=fCytoEdeposit/fDetector->GetCytoMass();
193                                                << 185   G4double rmsSValueCyto=rmsCyto/fDetector->GetCytoMass();
194   G4double sValueCyto = fCytoEdeposit / fDetec << 186   
195   G4double rmsSValueCyto = rmsCyto / fDetector << 187   G4cout.precision(3);       
196                                                << 188   G4cout 
197   G4cout.precision(3);                         << 189     << "\n S value for cytoplasm (C<-C) = " << sValueCyto/gray << " Gy/Bq.s "
198   G4cout << "\n S value for cytoplasm (C<-C) = << 190     << " +- "                                << rmsSValueCyto/gray 
199          << " +- " << rmsSValueCyto / gray <<  << 191     <<  " Gy/Bq.s "
200                                                << 192     << G4endl;
201   // Compute S-value for nucleus (N<-C)        << 193               
202                                                << 194   //
203   fNuclEdeposit /= numberOfEvent;              << 195   
204   fNuclEdeposit2 /= numberOfEvent;             << 196   fNuclEdeposit /= numberOfEvent; fNuclEdeposit2 /= numberOfEvent;
205   G4double rmsNucl = fNuclEdeposit2 - fNuclEde << 197   G4double rmsNucl = fNuclEdeposit2 - fNuclEdeposit*fNuclEdeposit;        
206   if (rmsNucl > 0.)                            << 198   if (rmsNucl>0.) rmsNucl = std::sqrt(rmsNucl); else rmsNucl = 0.;
207     rmsNucl = std::sqrt(rmsNucl);              << 199 
208   else                                         << 200   G4cout.precision(3);       
209     rmsNucl = 0.;                              << 201   G4cout 
210                                                << 202     << "\n Total Energy deposited in nucleus = " << G4BestUnit(fNuclEdeposit,"Energy")
211   G4cout.precision(3);                         << 203     << " +- "                                << G4BestUnit( rmsNucl,"Energy")
212   G4cout << "\n Total Energy deposited in nucl << 204     << G4endl;
213          << " +- " << G4BestUnit(rmsNucl, "Ene << 205                     
214                                                << 206   G4double sValueNucl=fNuclEdeposit/fDetector->GetNuclMass();
215   G4double sValueNucl = fNuclEdeposit / fDetec << 207   G4double rmsSValueNucl=rmsNucl/fDetector->GetNuclMass();
216   G4double rmsSValueNucl = rmsNucl / fDetector << 208   
217                                                << 209   G4cout.precision(3);       
218   G4cout.precision(3);                         << 210   G4cout 
219   G4cout << "\n S value for nucleus (N<-C) = " << 211     << "\n S value for nucleus (N<-C) = " << sValueNucl/gray << " Gy/Bq.s "
220          << " +- " << rmsSValueNucl / gray <<  << 212     << " +- "                                << rmsSValueNucl/gray 
221                                                << 213     <<  " Gy/Bq.s "
222   // Compute track length of primary track     << 214     << G4endl;
223                                                << 215 
224   fTrackLen /= numberOfEvent;                  << 216   //compute track length of primary track
225   fTrackLen2 /= numberOfEvent;                 << 217   //
226   G4double rms = fTrackLen2 - fTrackLen * fTra << 218   fTrackLen /= numberOfEvent; fTrackLen2 /= numberOfEvent;
227   if (rms > 0.)                                << 219   G4double rms = fTrackLen2 - fTrackLen*fTrackLen;        
228     rms = std::sqrt(rms);                      << 220   if (rms>0.) rms = std::sqrt(rms); else rms = 0.;
229   else                                         << 221 
230     rms = 0.;                                  << 222   G4cout.precision(3);       
231                                                << 223   G4cout 
232   G4cout.precision(3);                         << 224     << "\n Track length of primary track = " << G4BestUnit(fTrackLen,"Length")
233   G4cout << "\n Track length of primary track  << 225     << " +- "                                << G4BestUnit( rms,"Length");
234          << G4BestUnit(rms, "Length");         << 226     
235                                                << 227   //compute projected range of primary track
236   // Compute projected range of primary track  << 228   //
237                                                << 229   fProjRange /= numberOfEvent; fProjRange2 /= numberOfEvent;
238   fProjRange /= numberOfEvent;                 << 230   rms = fProjRange2 - fProjRange*fProjRange;        
239   fProjRange2 /= numberOfEvent;                << 231   if (rms>0.) rms = std::sqrt(rms); else rms = 0.;
240   rms = fProjRange2 - fProjRange * fProjRange; << 232    
241   if (rms > 0.)                                << 233   G4cout 
242     rms = std::sqrt(rms);                      << 234     << "\n Projected range               = " << G4BestUnit(fProjRange,"Length")
243   else                                         << 235     << " +- "                                << G4BestUnit( rms,"Length")    
244     rms = 0.;                                  << 236     << G4endl;
245                                                << 237     
246   G4cout << "\n Projected range                << 238   //nb of steps and step size of primary track
247          << G4BestUnit(rms, "Length") << G4end << 239   //
248                                                << 
249   // Nb of steps and step size of primary trac << 
250                                                << 
251   G4double dNofEvents = double(numberOfEvent);    240   G4double dNofEvents = double(numberOfEvent);
252   G4double fNbSteps = fNbOfSteps / dNofEvents, << 241   G4double fNbSteps  = fNbOfSteps/dNofEvents, 
253   rms = fNbSteps2 - fNbSteps * fNbSteps;       << 242            fNbSteps2 = fNbOfSteps2/dNofEvents;
254   if (rms > 0.)                                << 243   rms = fNbSteps2 - fNbSteps*fNbSteps;       
255     rms = std::sqrt(rms);                      << 244   if (rms>0.) rms = std::sqrt(rms); else rms = 0.;
256   else                                         << 245 
257     rms = 0.;                                  << 246   G4cout.precision(2);       
258                                                << 247   G4cout << "\n Nb of steps of primary track  = " << fNbSteps << " +- " << rms
259   G4cout.precision(2);                         << 248   << G4endl;
260   G4cout << "\n Nb of steps of primary track   << 249     
261                                                << 250   fStepSize /= numberOfEvent; fStepSize2 /= numberOfEvent;
262   fStepSize /= numberOfEvent;                  << 251   rms = fStepSize2 - fStepSize*fStepSize;        
263   fStepSize2 /= numberOfEvent;                 << 252   if (rms>0.) rms = std::sqrt(rms); else rms = 0.;
264   rms = fStepSize2 - fStepSize * fStepSize;    << 253 
265   if (rms > 0.)                                << 254   G4cout.precision(3);       
266     rms = std::sqrt(rms);                      << 255   G4cout 
267   else                                         << 256     << "\n Step size                     = " << G4BestUnit(fStepSize,"Length")
268     rms = 0.;                                  << 257     << " +- "           << G4BestUnit( rms,"Length")
269                                                << 258     << G4endl;
270   G4cout.precision(3);                         << 
271   G4cout << "\n Step size                      << 
272          << G4BestUnit(rms, "Length") << G4end << 
273                                                << 
274   // Normalize histograms of longitudinal ener << 
275                                                   259 
                                                   >> 260   // normalize histograms of longitudinal energy profile
                                                   >> 261   //
276   G4AnalysisManager* analysisManager = G4Analy    262   G4AnalysisManager* analysisManager = G4AnalysisManager::Instance();
277   G4int ih = 1;                                   263   G4int ih = 1;
278   G4double binWidth = analysisManager->GetH1Wi    264   G4double binWidth = analysisManager->GetH1Width(ih);
279   G4double fac = (1. / (numberOfEvent * binWid << 265   G4double fac = (1./(numberOfEvent*binWidth))*(mm/MeV);
280   analysisManager->ScaleH1(ih, fac);           << 266   analysisManager->ScaleH1(ih,fac);
281                                                << 267     
282   // Reset default formats                     << 268   // reset default formats
283                                                << 269   G4cout.setf(mode,std::ios::floatfield);
284   G4cout.setf(mode, std::ios::floatfield);     << 
285   G4cout.precision(prec);                         270   G4cout.precision(prec);
286                                                << 271   
287   // Output file                               << 272   //output file
288                                                << 273   FILE *myFile;
289   FILE* myFile;                                << 274   myFile = fopen ("s.txt","a");
290   myFile = fopen("s.txt", "a");                << 275   fprintf (myFile, "%e %e %e %e %e %e %e \n", 
291   fprintf(myFile, "%e %e %e %e %e %e %e \n", f << 276     fDetector->GetNuclRadius()/nm,
292           fDetector->GetCytoThickness() / nm,  << 277     fDetector->GetCytoThickness()/nm,
293           sValueNucl / gray, rmsSValueNucl / g << 278     fEkin/eV,
294   fclose(myFile);                              << 279     sValueCyto/gray,
                                                   >> 280     rmsSValueCyto/gray,
                                                   >> 281     sValueNucl/gray,
                                                   >> 282     rmsSValueNucl/gray
                                                   >> 283     );
                                                   >> 284   fclose (myFile);
                                                   >> 285   
295 }                                                 286 }
296                                                   287