Geant4 Cross Reference

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Geant4/examples/extended/parameterisations/Par04/src/Par04EventAction.cc

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Differences between /examples/extended/parameterisations/Par04/src/Par04EventAction.cc (Version 11.3.0) and /examples/extended/parameterisations/Par04/src/Par04EventAction.cc (Version 7.0.p1)


  1 //                                                  1 
  2 // *******************************************    
  3 // * License and Disclaimer                       
  4 // *                                              
  5 // * The  Geant4 software  is  copyright of th    
  6 // * the Geant4 Collaboration.  It is provided    
  7 // * conditions of the Geant4 Software License    
  8 // * LICENSE and available at  http://cern.ch/    
  9 // * include a list of copyright holders.         
 10 // *                                              
 11 // * Neither the authors of this software syst    
 12 // * institutes,nor the agencies providing fin    
 13 // * work  make  any representation or  warran    
 14 // * regarding  this  software system or assum    
 15 // * use.  Please see the license in the file     
 16 // * for the full disclaimer and the limitatio    
 17 // *                                              
 18 // * This  code  implementation is the result     
 19 // * technical work of the GEANT4 collaboratio    
 20 // * By using,  copying,  modifying or  distri    
 21 // * any work based  on the software)  you  ag    
 22 // * use  in  resulting  scientific  publicati    
 23 // * acceptance of all terms of the Geant4 Sof    
 24 // *******************************************    
 25 //                                                
 26 #include "Par04EventAction.hh"                    
 27                                                   
 28 #include "Par04DetectorConstruction.hh"  // fo    
 29 #include "Par04Hit.hh"  // for Par04Hit, Par04    
 30 #include "Par04ParallelFullWorld.hh"              
 31                                                   
 32 #include "G4AnalysisManager.hh"  // for G4Anal    
 33 #include "G4Event.hh"  // for G4Event             
 34 #include "G4EventManager.hh"  // for G4EventMa    
 35 #include "G4Exception.hh"  // for G4Exception,    
 36 #include "G4ExceptionSeverity.hh"  // for Fata    
 37 #include "G4GenericAnalysisManager.hh"  // for    
 38 #include "G4HCofThisEvent.hh"  // for G4HCofTh    
 39 #include "G4PrimaryParticle.hh"  // for G4Prim    
 40 #include "G4PrimaryVertex.hh"  // for G4Primar    
 41 #include "G4SDManager.hh"  // for G4SDManager     
 42 #include "G4SystemOfUnits.hh"  // for GeV         
 43 #include "G4THitsCollection.hh"  // for G4THit    
 44 #include "G4ThreeVector.hh"  // for G4ThreeVec    
 45 #include "G4Timer.hh"  // for G4Timer             
 46 #include "G4UserEventAction.hh"  // for G4User    
 47                                                   
 48 #include <CLHEP/Units/SystemOfUnits.h>  // for    
 49 #include <CLHEP/Vector/ThreeVector.h>  // for     
 50 #include <algorithm>  // for max                  
 51 #include <cmath>  // for log10                    
 52 #include <cstddef>  // for size_t                 
 53 #include <ostream>  // for basic_ostream::oper    
 54                                                   
 55 //....oooOO0OOooo........oooOO0OOooo........oo    
 56                                                   
 57 Par04EventAction::Par04EventAction(Par04Detect    
 58                                    Par04Parall    
 59   : G4UserEventAction(),                          
 60     fHitCollectionID(-1),                         
 61     fPhysicalFullHitCollectionID(-1),             
 62     fPhysicalFastHitCollectionID(-1),             
 63     fTimer(),                                     
 64     fDetector(aDetector),                         
 65     fParallel(aParallel)                          
 66 {                                                 
 67   fCellNbRho = aDetector->GetMeshNbOfCells().x    
 68   fCellNbPhi = aDetector->GetMeshNbOfCells().y    
 69   fCellNbZ = aDetector->GetMeshNbOfCells().z()    
 70   fCalEdep.reserve(fCellNbRho * fCellNbPhi * f    
 71   fCalRho.reserve(fCellNbRho * fCellNbPhi * fC    
 72   fCalPhi.reserve(fCellNbRho * fCellNbPhi * fC    
 73   fCalZ.reserve(fCellNbRho * fCellNbPhi * fCel    
 74   fCalPhysicalEdep.reserve(fPhysicalNbLayers *    
 75   fCalPhysicalLayer.reserve(fPhysicalNbLayers     
 76   fCalPhysicalSlice.reserve(fPhysicalNbLayers     
 77   fCalPhysicalRow.reserve(fPhysicalNbLayers *     
 78 }                                                 
 79                                                   
 80 //....oooOO0OOooo........oooOO0OOooo........oo    
 81                                                   
 82 Par04EventAction::~Par04EventAction() = defaul    
 83                                                   
 84 //....oooOO0OOooo........oooOO0OOooo........oo    
 85                                                   
 86 void Par04EventAction::BeginOfEventAction(cons    
 87 {                                                 
 88   StartTimer();                                   
 89 }                                                 
 90                                                   
 91 //....oooOO0OOooo........oooOO0OOooo........oo    
 92                                                   
 93 void Par04EventAction::StartTimer()               
 94 {                                                 
 95   fTimer.Start();                                 
 96 }                                                 
 97                                                   
 98 //....oooOO0OOooo........oooOO0OOooo........oo    
 99                                                   
100 void Par04EventAction::StopTimer()                
101 {                                                 
102   fTimer.Stop();                                  
103 }                                                 
104                                                   
105 //....oooOO0OOooo........oooOO0OOooo........oo    
106                                                   
107 void Par04EventAction::EndOfEventAction(const     
108 {                                                 
109   G4SDManager::GetSDMpointer()->GetHCtable();     
110   StopTimer();                                    
111                                                   
112   // Get hits collection ID (only once)           
113   if (fHitCollectionID == -1) {                   
114     fHitCollectionID = G4SDManager::GetSDMpoin    
115   }                                               
116   if (fPhysicalFullHitCollectionID == -1) {       
117     fPhysicalFullHitCollectionID =                
118       G4SDManager::GetSDMpointer()->GetCollect    
119   }                                               
120   if (fPhysicalFastHitCollectionID == -1) {       
121     fPhysicalFastHitCollectionID =                
122       G4SDManager::GetSDMpointer()->GetCollect    
123   }                                               
124   // Get hits collection                          
125   auto hitsCollection =                           
126     static_cast<Par04HitsCollection*>(aEvent->    
127   auto physicalFullHitsCollection = static_cas    
128     aEvent->GetHCofThisEvent()->GetHC(fPhysica    
129   auto physicalFastHitsCollection = static_cas    
130     aEvent->GetHCofThisEvent()->GetHC(fPhysica    
131                                                   
132   if (hitsCollection == nullptr) {                
133     G4ExceptionDescription msg;                   
134     msg << "Cannot access hitsCollection ID "     
135     G4Exception("Par04EventAction::GetHitsColl    
136   }                                               
137   if (physicalFullHitsCollection == nullptr) {    
138     G4ExceptionDescription msg;                   
139     msg << "Cannot access physical full sim hi    
140     G4Exception("Par04EventAction::GetHitsColl    
141   }                                               
142   if (physicalFastHitsCollection == nullptr) {    
143     G4ExceptionDescription msg;                   
144     msg << "Cannot access physical fast sim hi    
145     G4Exception("Par04EventAction::GetHitsColl    
146   }                                               
147   // Get analysis manager                         
148   auto analysisManager = G4AnalysisManager::In    
149   // Retrieve only once detector dimensions       
150   if (fCellSizeZ == 0) {                          
151     fCellSizeZ = fDetector->GetMeshSizeOfCells    
152     fCellSizePhi = fDetector->GetMeshSizeOfCel    
153     fCellSizeRho = fDetector->GetMeshSizeOfCel    
154     fCellNbRho = fDetector->GetMeshNbOfCells()    
155     fCellNbPhi = fDetector->GetMeshNbOfCells()    
156     fCellNbZ = fDetector->GetMeshNbOfCells().z    
157   }                                               
158   if (fPhysicalNbLayers == 0) {                   
159     fPhysicalNbLayers = fParallel->GetNbOfLaye    
160     fPhysicalNbSlices = fParallel->GetNbOfSlic    
161     fPhysicalNbRows = fParallel->GetNbOfRows()    
162   }                                               
163                                                   
164   // Retrieve information from primary vertex     
165   // To calculate shower axis and entry point     
166   auto primaryVertex =                            
167     G4EventManager::GetEventManager()->GetCons    
168   auto primaryParticle = primaryVertex->GetPri    
169   G4double primaryEnergy = primaryParticle->Ge    
170   // Estimate from vertex and particle directi    
171   // Calculate entrance point to the detector     
172   auto primaryDirection = primaryParticle->Get    
173   auto primaryEntrance =                          
174     primaryVertex->GetPosition() - primaryVert    
175                                                   
176   // Resize back to initial mesh size             
177   fCalEdep.resize(fCellNbRho * fCellNbPhi * fC    
178   fCalRho.resize(fCellNbRho * fCellNbPhi * fCe    
179   fCalPhi.resize(fCellNbRho * fCellNbPhi * fCe    
180   fCalZ.resize(fCellNbRho * fCellNbPhi * fCell    
181   fCalPhysicalEdep.resize(fPhysicalNbLayers *     
182   fCalPhysicalLayer.resize(fPhysicalNbLayers *    
183   fCalPhysicalSlice.resize(fPhysicalNbLayers *    
184   fCalPhysicalRow.resize(fPhysicalNbLayers * f    
185                                                   
186   // Fill histograms                              
187   Par04Hit* hit = nullptr;                        
188   G4double hitEn = 0;                             
189   G4double totalEnergy = 0;                       
190   G4int hitNum = 0;                               
191   G4int totalNum = 0;                             
192   G4int hitZ = -1;                                
193   G4int hitRho = -1;                              
194   G4int hitPhi = -1;                              
195   G4int hitType = -1;                             
196   G4int numNonZeroThresholdCells = 0;             
197   G4double tDistance = 0., rDistance = 0., phi    
198   G4double tFirstMoment = 0., tSecondMoment =     
199   G4double rFirstMoment = 0., rSecondMoment =     
200   G4double phiMean = 0.;                          
201   for (size_t iHit = 0; iHit < hitsCollection-    
202     hit = static_cast<Par04Hit*>(hitsCollectio    
203     hitZ = hit->GetZid();                         
204     hitRho = hit->GetRhoId();                     
205     hitPhi = hit->GetPhiId();                     
206     hitEn = hit->GetEdep();                       
207     hitNum = hit->GetNdep();                      
208     hitType = hit->GetType();                     
209     if (hitEn > 0) {                              
210       totalEnergy += hitEn;                       
211       totalNum += hitNum;                         
212       tDistance = hitZ * fCellSizeZ;              
213       rDistance = hitRho * fCellSizeRho;          
214       phiDistance = hitPhi * fCellSizePhi;        
215       tFirstMoment += hitEn * tDistance;          
216       rFirstMoment += hitEn * rDistance;          
217       phiMean += hitEn * phiDistance;             
218       analysisManager->FillH1(4, tDistance, hi    
219       analysisManager->FillH1(5, rDistance, hi    
220       analysisManager->FillH1(10, hitType);       
221       if (hitEn > 0.0005) {  // e > 0.5 keV       
222         fCalEdep[numNonZeroThresholdCells] = h    
223         fCalRho[numNonZeroThresholdCells] = hi    
224         fCalPhi[numNonZeroThresholdCells] = hi    
225         fCalZ[numNonZeroThresholdCells] = hitZ    
226         numNonZeroThresholdCells++;               
227         analysisManager->FillH1(13, std::log10    
228         analysisManager->FillH1(15, hitNum);      
229       }                                           
230     }                                             
231   }                                               
232   tFirstMoment /= totalEnergy;                    
233   rFirstMoment /= totalEnergy;                    
234   phiMean /= totalEnergy;                         
235   analysisManager->FillH1(0, primaryEnergy / G    
236   analysisManager->FillH1(1, totalEnergy / GeV    
237   analysisManager->FillH1(2, totalEnergy / pri    
238   analysisManager->FillH1(3, fTimer.GetRealEla    
239   analysisManager->FillH1(6, tFirstMoment);       
240   analysisManager->FillH1(7, rFirstMoment);       
241   analysisManager->FillH1(12, numNonZeroThresh    
242   analysisManager->FillH1(14, totalNum);          
243   // Resize to store only energy hits above th    
244   fCalEdep.resize(numNonZeroThresholdCells);      
245   fCalRho.resize(numNonZeroThresholdCells);       
246   fCalPhi.resize(numNonZeroThresholdCells);       
247   fCalZ.resize(numNonZeroThresholdCells);         
248   analysisManager->FillNtupleDColumn(0, 0, pri    
249   analysisManager->FillNtupleDColumn(0, 1, fTi    
250   // Second loop over hits to calculate second    
251   for (size_t iHit = 0; iHit < hitsCollection-    
252     hit = static_cast<Par04Hit*>(hitsCollectio    
253     hitEn = hit->GetEdep();                       
254     hitZ = hit->GetZid();                         
255     hitRho = hit->GetRhoId();                     
256     hitPhi = hit->GetPhiId();                     
257     if (hitEn > 0) {                              
258       tDistance = hitZ * fCellSizeZ;              
259       rDistance = hitRho * fCellSizeRho;          
260       phiDistance = hitPhi * fCellSizePhi;        
261       tSecondMoment += hitEn * std::pow(tDista    
262       rSecondMoment += hitEn * std::pow(rDista    
263       analysisManager->FillH1(11, phiDistance     
264     }                                             
265   }                                               
266   tSecondMoment /= totalEnergy;                   
267   rSecondMoment /= totalEnergy;                   
268   analysisManager->FillH1(8, tSecondMoment);      
269   analysisManager->FillH1(9, rSecondMoment);      
270                                                   
271   // Fill ntuple with physical readout data       
272   G4double totalPhysicalEnergy = 0;               
273   totalNum = 0;                                   
274   hitEn = 0;                                      
275   hitNum = 0;                                     
276   G4int hitLayer = -1;                            
277   G4int hitRow = -1;                              
278   G4int hitSlice = -1;                            
279   numNonZeroThresholdCells = 0;                   
280   for (size_t iHit = 0; iHit < physicalFullHit    
281     hit = static_cast<Par04Hit*>(physicalFullH    
282     hitLayer = hit->GetRhoId();                   
283     hitRow = hit->GetZid();                       
284     hitSlice = hit->GetPhiId();                   
285     hitEn = hit->GetEdep();                       
286     hitNum = hit->GetNdep();                      
287     if (hitEn > 0) {                              
288       totalPhysicalEnergy += hitEn;               
289       totalNum += hitNum;                         
290       if (hitEn > 0.0005) {  // e > 0.5 keV       
291         fCalPhysicalEdep[numNonZeroThresholdCe    
292         fCalPhysicalLayer[numNonZeroThresholdC    
293         fCalPhysicalRow[numNonZeroThresholdCel    
294         fCalPhysicalSlice[numNonZeroThresholdC    
295         numNonZeroThresholdCells++;               
296         analysisManager->FillH1(19, std::log10    
297         analysisManager->FillH1(21, hitNum);      
298       }                                           
299     }                                             
300   }                                               
301   for (size_t iHit = 0; iHit < physicalFastHit    
302     hit = static_cast<Par04Hit*>(physicalFastH    
303     hitLayer = hit->GetRhoId();                   
304     hitRow = hit->GetZid();                       
305     hitSlice = hit->GetPhiId();                   
306     hitEn = hit->GetEdep();                       
307     hitNum = hit->GetNdep();                      
308     if (hitEn > 0) {                              
309       totalPhysicalEnergy += hitEn;               
310       totalNum += hitNum;                         
311       if (hitEn > 0.0005) {  // e > 0.5 keV       
312         fCalPhysicalEdep[numNonZeroThresholdCe    
313         fCalPhysicalLayer[numNonZeroThresholdC    
314         fCalPhysicalRow[numNonZeroThresholdCel    
315         fCalPhysicalSlice[numNonZeroThresholdC    
316         numNonZeroThresholdCells++;               
317         analysisManager->FillH1(19, std::log10    
318         analysisManager->FillH1(21, hitNum);      
319       }                                           
320     }                                             
321   }                                               
322   analysisManager->FillH1(16, totalPhysicalEne    
323   analysisManager->FillH1(17, totalPhysicalEne    
324   analysisManager->FillH1(18, numNonZeroThresh    
325   analysisManager->FillH1(20, totalNum);          
326   fCalPhysicalEdep.resize(numNonZeroThresholdC    
327   fCalPhysicalLayer.resize(numNonZeroThreshold    
328   fCalPhysicalSlice.resize(numNonZeroThreshold    
329   fCalPhysicalRow.resize(numNonZeroThresholdCe    
330   analysisManager->AddNtupleRow(0);               
331   analysisManager->AddNtupleRow(1);               
332   analysisManager->AddNtupleRow(2);               
333 }                                                 
334