Geant4 Cross Reference

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Geant4/digits_hits/scorer/src/G4PSCylinderSurfaceFlux.cc

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Differences between /digits_hits/scorer/src/G4PSCylinderSurfaceFlux.cc (Version 11.3.0) and /digits_hits/scorer/src/G4PSCylinderSurfaceFlux.cc (Version 9.4.p2)


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 26 //                                                 26 //
                                                   >>  27 // $Id: G4PSCylinderSurfaceFlux.cc,v 1.8 2010-07-23 04:35:38 taso Exp $
                                                   >>  28 // GEANT4 tag $Name: geant4-09-04-patch-02 $
 27 //                                                 29 //
 28 // // G4PSCylinderSurfaceFlux                      30 // // G4PSCylinderSurfaceFlux
 29 #include "G4PSCylinderSurfaceFlux.hh"              31 #include "G4PSCylinderSurfaceFlux.hh"
 30                                                << 
 31 #include "G4SystemOfUnits.hh"                  << 
 32 #include "G4StepStatus.hh"                         32 #include "G4StepStatus.hh"
 33 #include "G4Track.hh"                              33 #include "G4Track.hh"
 34 #include "G4VSolid.hh"                             34 #include "G4VSolid.hh"
 35 #include "G4VPhysicalVolume.hh"                    35 #include "G4VPhysicalVolume.hh"
 36 #include "G4VPVParameterisation.hh"                36 #include "G4VPVParameterisation.hh"
 37 #include "G4UnitsTable.hh"                         37 #include "G4UnitsTable.hh"
 38 #include "G4GeometryTolerance.hh"                  38 #include "G4GeometryTolerance.hh"
 39 #include "G4VScoreHistFiller.hh"               << 
 40                                                << 
 41 // ///////////////////////////////////////////     39 // ////////////////////////////////////////////////////////////////////////////////
 42 // (Description)                                   40 // (Description)
 43 //   This is a primitive scorer class for scor     41 //   This is a primitive scorer class for scoring Surface Flux.
 44 //  Current version assumes only for G4Tubs sh     42 //  Current version assumes only for G4Tubs shape, and the surface
 45 //  is fixed on inner plane of the tube.           43 //  is fixed on inner plane of the tube.
 46 //                                                 44 //
 47 // Surface is defined at the innner surface of     45 // Surface is defined at the innner surface of the tube.
 48 // Direction                   R    R+dR           46 // Direction                   R    R+dR
 49 //   0  IN || OUT            ->|<-  |              47 //   0  IN || OUT            ->|<-  |
 50 //   1  IN                   ->|    |              48 //   1  IN                   ->|    |
 51 //   2  OUT                    |<-  |              49 //   2  OUT                    |<-  |
 52 //                                                 50 //
 53 // Created: 2007-03-29  Tsukasa ASO                51 // Created: 2007-03-29  Tsukasa ASO
 54 // 2010-07-22   Introduce Unit specification.      52 // 2010-07-22   Introduce Unit specification.
 55 // 2010-07-22   Add weighted and divideByArea      53 // 2010-07-22   Add weighted and divideByArea options
 56 // 2011-02-21   Get correct momentum direction     54 // 2011-02-21   Get correct momentum direction in Flux_Out.
 57 // 2020-10-06   Use G4VPrimitivePlotter and fi << 
 58 //              vs. surface flux * track weigh << 
 59 //                                             << 
 60 //////////////////////////////////////////////     55 ///////////////////////////////////////////////////////////////////////////////
 61                                                    56 
 62 G4PSCylinderSurfaceFlux::G4PSCylinderSurfaceFl <<  57 G4PSCylinderSurfaceFlux::G4PSCylinderSurfaceFlux(G4String name, 
 63                                                <<  58              G4int direction, G4int depth)
 64   : G4PSCylinderSurfaceFlux(name, direction, " <<  59     :G4VPrimitiveScorer(name,depth),HCID(-1),fDirection(direction),
 65 {}                                             <<  60      weighted(true),divideByArea(true)
 66                                                <<  61 {
 67 G4PSCylinderSurfaceFlux::G4PSCylinderSurfaceFl <<  62     DefineUnitAndCategory();
 68                                                <<  63     SetUnit("percm2");
 69                                                <<  64 }
 70   : G4VPrimitivePlotter(name, depth)           <<  65 
 71   , HCID(-1)                                   <<  66 G4PSCylinderSurfaceFlux::G4PSCylinderSurfaceFlux(G4String name, 
 72   , fDirection(direction)                      <<  67              G4int direction, 
 73   , EvtMap(nullptr)                            <<  68              const G4String& unit, 
 74   , weighted(true)                             <<  69              G4int depth)
 75   , divideByArea(true)                         <<  70   :G4VPrimitiveScorer(name,depth),HCID(-1),fDirection(direction)
 76 {                                                  71 {
 77   DefineUnitAndCategory();                     <<  72     DefineUnitAndCategory();
 78   SetUnit(unit);                               <<  73     SetUnit(unit);
 79 }                                                  74 }
 80                                                    75 
 81 G4bool G4PSCylinderSurfaceFlux::ProcessHits(G4 <<  76 G4PSCylinderSurfaceFlux::~G4PSCylinderSurfaceFlux()
                                                   >>  77 {;}
                                                   >>  78 
                                                   >>  79 G4bool G4PSCylinderSurfaceFlux::ProcessHits(G4Step* aStep,G4TouchableHistory*)
 82 {                                                  80 {
 83   G4StepPoint* preStep = aStep->GetPreStepPoin     81   G4StepPoint* preStep = aStep->GetPreStepPoint();
 84   G4VSolid* solid      = ComputeCurrentSolid(a << 
 85   assert(dynamic_cast<G4Tubs*>(solid));        << 
 86                                                    82 
 87   auto  tubsSolid = static_cast<G4Tubs*>(solid <<  83   G4VPhysicalVolume* physVol = preStep->GetPhysicalVolume();
                                                   >>  84   G4VPVParameterisation* physParam = physVol->GetParameterisation();
                                                   >>  85   G4VSolid * solid = 0;
                                                   >>  86   if(physParam)
                                                   >>  87   { // for parameterized volume
                                                   >>  88     G4int idx = ((G4TouchableHistory*)(aStep->GetPreStepPoint()->GetTouchable()))
                                                   >>  89                 ->GetReplicaNumber(indexDepth);
                                                   >>  90     solid = physParam->ComputeSolid(idx, physVol);
                                                   >>  91     solid->ComputeDimensions(physParam,idx,physVol);
                                                   >>  92   }
                                                   >>  93   else
                                                   >>  94   { // for ordinary volume
                                                   >>  95     solid = physVol->GetLogicalVolume()->GetSolid();
                                                   >>  96   }
 88                                                    97 
 89   G4int dirFlag = IsSelectedSurface(aStep, tub <<  98   G4Tubs* tubsSolid = (G4Tubs*)(solid);
                                                   >>  99   
                                                   >> 100   G4int dirFlag =IsSelectedSurface(aStep,tubsSolid);
                                                   >> 101   
                                                   >> 102   if ( dirFlag > 0 ){
                                                   >> 103     if (fDirection == fFlux_InOut || dirFlag == fDirection ){
 90                                                   104 
 91   if(dirFlag > 0)                              << 105       G4StepPoint* thisStep=0;
 92   {                                            << 106       if ( dirFlag == fFlux_In ){
 93     if(fDirection == fFlux_InOut || dirFlag == << 107   thisStep = preStep;
 94     {                                          << 108       }else if ( dirFlag == fFlux_Out ){
 95       G4StepPoint* thisStep = nullptr;         << 109   thisStep = aStep->GetPostStepPoint();
 96       if(dirFlag == fFlux_In)                  << 110       }else{
 97       {                                        << 111   return FALSE;
 98         thisStep = preStep;                    << 
 99       }                                        << 
100       else if(dirFlag == fFlux_Out)            << 
101       {                                        << 
102         thisStep = aStep->GetPostStepPoint();  << 
103       }                                           112       }
104       else                                     << 113   
105       {                                        << 
106         return false;                          << 
107       }                                        << 
108                                                << 
109       G4TouchableHandle theTouchable = thisSte    114       G4TouchableHandle theTouchable = thisStep->GetTouchableHandle();
110       G4ThreeVector pdirection       = thisSte << 115       G4ThreeVector pdirection = thisStep->GetMomentumDirection();
111       G4ThreeVector localdir =                 << 116       G4ThreeVector localdir  = 
112         theTouchable->GetHistory()->GetTopTran << 117   theTouchable->GetHistory()->GetTopTransform().TransformAxis(pdirection);
113       G4ThreeVector position = thisStep->GetPo    118       G4ThreeVector position = thisStep->GetPosition();
114       G4ThreeVector localpos =                 << 119       G4ThreeVector localpos  =
115         theTouchable->GetHistory()->GetTopTran << 120   theTouchable->GetHistory()->GetTopTransform().TransformAxis(position);
116       G4double angleFactor =                   << 121       G4double angleFactor = (localdir.x()*localpos.x()+localdir.y()*localpos.y())
117         (localdir.x() * localpos.x() + localdi << 122   /std::sqrt(localdir.x()*localdir.x()
118         std::sqrt(localdir.x() * localdir.x()  << 123        +localdir.y()*localdir.y()+localdir.z()*localdir.z())
119                   localdir.z() * localdir.z()) << 124   /std::sqrt(localpos.x()*localpos.x()+localpos.y()*localpos.y());
120         std::sqrt(localpos.x() * localpos.x()  << 125     
121                                                << 126       if ( angleFactor < 0 ) angleFactor *= -1.;
122       if(angleFactor < 0)                      << 127       G4double square = 2.*tubsSolid->GetZHalfLength()
123         angleFactor *= -1.;                    << 128   *tubsSolid->GetInnerRadius()* tubsSolid->GetDeltaPhiAngle()/radian;
124       G4double square = 2. * tubsSolid->GetZHa << 129     
125                         tubsSolid->GetInnerRad << 
126                         tubsSolid->GetDeltaPhi << 
127                                                << 
128       G4double flux = 1.0;                        130       G4double flux = 1.0;
129       if(weighted)                             << 131       if ( weighted ) flux *=preStep->GetWeight();  
130         flux *= preStep->GetWeight();          << 
131       // Current (Particle Weight)                132       // Current (Particle Weight)
132                                                   133 
133       flux = flux / angleFactor;               << 134       flux = flux/angleFactor;   
134       if(divideByArea)                         << 135       if ( divideByArea ) flux /= square;
135         flux /= square;                        << 136       //Flux with angle.
136       // Flux with angle.                      << 
137       G4int index = GetIndex(aStep);              137       G4int index = GetIndex(aStep);
138       EvtMap->add(index, flux);                << 138       EvtMap->add(index,flux);
139                                                << 139       return TRUE;
140       if(!hitIDMap.empty() && hitIDMap.find(in << 140     }else{
141       {                                        << 141       return FALSE;
142         auto filler = G4VScoreHistFiller::Inst << 
143         if(filler == nullptr)                  << 
144         {                                      << 
145           G4Exception("G4PSCylinderSurfaceFlux << 
146                       JustWarning,             << 
147                       "G4TScoreHistFiller is n << 
148                       "not filled.");          << 
149         }                                      << 
150         else                                   << 
151         {                                      << 
152           filler->FillH1(hitIDMap[index], this << 
153         }                                      << 
154       }                                        << 
155                                                << 
156       return true;                             << 
157     }                                             142     }
158                                                << 143   }else{
159     return false;                              << 144       return FALSE;
160   }                                               145   }
161                                                << 
162   return false;                                << 
163 }                                                 146 }
164                                                   147 
165 G4int G4PSCylinderSurfaceFlux::IsSelectedSurfa << 148 G4int G4PSCylinderSurfaceFlux::IsSelectedSurface(G4Step* aStep, G4Tubs* tubsSolid){
166                                                << 149 
167 {                                              << 150   G4TouchableHandle theTouchable = 
168   G4TouchableHandle theTouchable =             << 
169     aStep->GetPreStepPoint()->GetTouchableHand    151     aStep->GetPreStepPoint()->GetTouchableHandle();
170   G4double kCarTolerance =                     << 152   G4double kCarTolerance = G4GeometryTolerance::GetInstance()->GetSurfaceTolerance();  
171     G4GeometryTolerance::GetInstance()->GetSur << 
172                                                   153 
173   if(aStep->GetPreStepPoint()->GetStepStatus() << 154   if (aStep->GetPreStepPoint()->GetStepStatus() == fGeomBoundary ){
174   {                                            << 
175     // Entering Geometry                          155     // Entering Geometry
176     G4ThreeVector stppos1 = aStep->GetPreStepP << 156     G4ThreeVector stppos1= aStep->GetPreStepPoint()->GetPosition();
177     G4ThreeVector localpos1 =                  << 157     G4ThreeVector localpos1 = 
178       theTouchable->GetHistory()->GetTopTransf    158       theTouchable->GetHistory()->GetTopTransform().TransformPoint(stppos1);
179     if(std::fabs(localpos1.z()) > tubsSolid->G << 159     if ( std::fabs(localpos1.z()) > tubsSolid->GetZHalfLength() ) return -1;
180       return -1;                               << 160     //if(std::fabs( localpos1.x()*localpos1.x()+localpos1.y()*localpos1.y()  
181     // if(std::fabs( localpos1.x()*localpos1.x << 
182     //   - (tubsSolid->GetInnerRadius()*tubsSo    161     //   - (tubsSolid->GetInnerRadius()*tubsSolid->GetInnerRadius()))
183     //   <kCarTolerance ){                        162     //   <kCarTolerance ){
184     G4double localR2 =                         << 163     G4double localR2 = localpos1.x()*localpos1.x()+localpos1.y()*localpos1.y();
185       localpos1.x() * localpos1.x() + localpos << 
186     G4double InsideRadius = tubsSolid->GetInne    164     G4double InsideRadius = tubsSolid->GetInnerRadius();
187     if(localR2 >                               << 165     if (localR2 > (InsideRadius-kCarTolerance)*(InsideRadius-kCarTolerance)
188          (InsideRadius - kCarTolerance) * (Ins << 166   &&localR2 < (InsideRadius+kCarTolerance)*(InsideRadius+kCarTolerance)){
189        localR2 <                               << 
190          (InsideRadius + kCarTolerance) * (Ins << 
191     {                                          << 
192       return fFlux_In;                            167       return fFlux_In;
193     }                                             168     }
194   }                                               169   }
195                                                   170 
196   if(aStep->GetPostStepPoint()->GetStepStatus( << 171   if (aStep->GetPostStepPoint()->GetStepStatus() == fGeomBoundary ){
197   {                                            << 
198     // Exiting Geometry                           172     // Exiting Geometry
199     G4ThreeVector stppos2 = aStep->GetPostStep << 173     G4ThreeVector stppos2= aStep->GetPostStepPoint()->GetPosition();
200     G4ThreeVector localpos2 =                  << 174     G4ThreeVector localpos2 = 
201       theTouchable->GetHistory()->GetTopTransf    175       theTouchable->GetHistory()->GetTopTransform().TransformPoint(stppos2);
202     if(std::fabs(localpos2.z()) > tubsSolid->G << 176     if ( std::fabs(localpos2.z()) > tubsSolid->GetZHalfLength() ) return -1;
203       return -1;                               << 177     //if(std::fabs( localpos2.x()*localpos2.x()+localpos2.y()*localpos2.y()  
204     // if(std::fabs( localpos2.x()*localpos2.x << 178     //   - (tubsSolid->GetInnerRadius()*tubsSolid->GetInnerRadius())) 
205     //   - (tubsSolid->GetInnerRadius()*tubsSo << 
206     // <kCarTolerance ){                          179     // <kCarTolerance ){
207     G4double localR2 =                         << 180     G4double localR2 = localpos2.x()*localpos2.x()+localpos2.y()*localpos2.y();
208       localpos2.x() * localpos2.x() + localpos << 
209     G4double InsideRadius = tubsSolid->GetInne    181     G4double InsideRadius = tubsSolid->GetInnerRadius();
210     if(localR2 >                               << 182     if (localR2 > (InsideRadius-kCarTolerance)*(InsideRadius-kCarTolerance)
211          (InsideRadius - kCarTolerance) * (Ins << 183   &&localR2 < (InsideRadius+kCarTolerance)*(InsideRadius+kCarTolerance)){
212        localR2 <                               << 
213          (InsideRadius + kCarTolerance) * (Ins << 
214     {                                          << 
215       return fFlux_Out;                           184       return fFlux_Out;
216     }                                             185     }
217   }                                               186   }
218                                                   187 
219   return -1;                                      188   return -1;
220 }                                                 189 }
221                                                   190 
222 void G4PSCylinderSurfaceFlux::Initialize(G4HCo    191 void G4PSCylinderSurfaceFlux::Initialize(G4HCofThisEvent* HCE)
223 {                                                 192 {
224   EvtMap = new G4THitsMap<G4double>(GetMultiFu    193   EvtMap = new G4THitsMap<G4double>(GetMultiFunctionalDetector()->GetName(),
225                                     GetName()) << 194             GetName());
226   if(HCID < 0)                                 << 195   if ( HCID < 0 ) HCID = GetCollectionID(0);
227     HCID = GetCollectionID(0);                 << 196   HCE->AddHitsCollection(HCID, (G4VHitsCollection*)EvtMap);
228   HCE->AddHitsCollection(HCID, (G4VHitsCollect << 197 }
                                                   >> 198 
                                                   >> 199 void G4PSCylinderSurfaceFlux::EndOfEvent(G4HCofThisEvent*)
                                                   >> 200 {;}
                                                   >> 201 
                                                   >> 202 void G4PSCylinderSurfaceFlux::clear(){
                                                   >> 203   EvtMap->clear();
229 }                                                 204 }
230                                                   205 
231 void G4PSCylinderSurfaceFlux::clear() { EvtMap << 206 void G4PSCylinderSurfaceFlux::DrawAll()
                                                   >> 207 {;}
232                                                   208 
233 void G4PSCylinderSurfaceFlux::PrintAll()          209 void G4PSCylinderSurfaceFlux::PrintAll()
234 {                                                 210 {
235   G4cout << " MultiFunctionalDet  " << detecto    211   G4cout << " MultiFunctionalDet  " << detector->GetName() << G4endl;
236   G4cout << " PrimitiveScorer" << GetName() << << 212   G4cout << " PrimitiveScorer" << GetName() <<G4endl; 
237   G4cout << " Number of entries " << EvtMap->e    213   G4cout << " Number of entries " << EvtMap->entries() << G4endl;
238   for(const auto& [copy, flux] : *(EvtMap->Get << 214   std::map<G4int,G4double*>::iterator itr = EvtMap->GetMap()->begin();
239   {                                            << 215   for(; itr != EvtMap->GetMap()->end(); itr++) {
240     G4cout << "  copy no.: " << copy           << 216     G4cout << "  copy no.: " << itr->first
241            << "  flux  : " << *(flux) / GetUni << 217      << "  flux  : " << *(itr->second)/GetUnitValue()
242            << GetUnit() << "]" << G4endl;      << 218      << " ["<<GetUnit()<<"]"
                                                   >> 219      << G4endl;
243   }                                               220   }
244 }                                                 221 }
245                                                   222 
246 void G4PSCylinderSurfaceFlux::SetUnit(const G4    223 void G4PSCylinderSurfaceFlux::SetUnit(const G4String& unit)
247 {                                                 224 {
248   if(divideByArea)                             << 225     if ( divideByArea ) {
249   {                                            << 226   CheckAndSetUnit(unit,"Per Unit Surface");
250     CheckAndSetUnit(unit, "Per Unit Surface"); << 227     } else {
251   }                                            << 228   if (unit == "" ){
252   else                                         << 229       unitName = unit;
253   {                                            << 230       unitValue = 1.0;
254     if(unit.empty())                           << 231   }else{
255     {                                          << 232       G4String msg = "Invalid unit ["+unit+"] (Current  unit is [" +GetUnit()+"] )";
256       unitName  = unit;                        << 233       G4Exception(GetName(),"DetScorer0000",JustWarning,msg);
257       unitValue = 1.0;                         << 234   }
258     }                                          << 
259     else                                       << 
260     {                                          << 
261       G4String msg = "Invalid unit [" + unit + << 
262                      GetUnit() + "] ) for " +  << 
263       G4Exception("G4PSCylinderSurfaceFlux::Se << 
264                   msg);                        << 
265     }                                             235     }
266   }                                            << 
267 }                                                 236 }
268                                                   237 
269 void G4PSCylinderSurfaceFlux::DefineUnitAndCat << 238 void G4PSCylinderSurfaceFlux::DefineUnitAndCategory(){
270 {                                              << 239    // Per Unit Surface
271   // Per Unit Surface                          << 240    new G4UnitDefinition("percentimeter2","percm2","Per Unit Surface",(1./cm2));
272   new G4UnitDefinition("percentimeter2", "perc << 241    new G4UnitDefinition("permillimeter2","permm2","Per Unit Surface",(1./mm2));
273                        (1. / cm2));            << 242    new G4UnitDefinition("permeter2","perm2","Per Unit Surface",(1./m2));
274   new G4UnitDefinition("permillimeter2", "perm << 
275                        (1. / mm2));            << 
276   new G4UnitDefinition("permeter2", "perm2", " << 
277 }                                                 243 }
                                                   >> 244 
                                                   >> 245 
278                                                   246