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<< 62 DefineUnitAndCategory(); 77 SetUnit(unit); << 63 SetUnit("percm2"); 78 } 64 } 79 65 80 G4bool G4PSCylinderSurfaceCurrent::ProcessHits << 66 G4PSCylinderSurfaceCurrent::G4PSCylinderSurfaceCurrent(G4String name, 81 << 67 G4int direction, >> 68 const G4String& unit, >> 69 G4int depth) >> 70 :G4VPrimitiveScorer(name,depth),HCID(-1),fDirection(direction),EvtMap(0), >> 71 weighted(true),divideByArea(true) >> 72 { >> 73 DefineUnitAndCategory(); >> 74 SetUnit(unit); >> 75 } >> 76 >> 77 G4PSCylinderSurfaceCurrent::~G4PSCylinderSurfaceCurrent() >> 78 {;} >> 79 >> 80 G4bool G4PSCylinderSurfaceCurrent::ProcessHits(G4Step* aStep,G4TouchableHistory*) 82 { 81 { 83 G4StepPoint* preStep = aStep->GetPreStepPoin 82 G4StepPoint* preStep = aStep->GetPreStepPoint(); 84 G4VSolid* solid = ComputeCurrentSolid(a << 83 G4VPhysicalVolume* physVol = preStep->GetPhysicalVolume(); 85 auto tubsSolid = static_cast<G4Tubs*>(so << 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 } 86 97 87 G4int dirFlag = IsSelectedSurface(aStep, tub << 98 G4Tubs* tubsSolid = (G4Tubs*)(solid); >> 99 >> 100 G4int dirFlag =IsSelectedSurface(aStep,tubsSolid); 88 // G4cout << " pos " << preStep->GetPosition 101 // G4cout << " pos " << preStep->GetPosition() <<" dirFlag " << G4endl; 89 if(dirFlag > 0) << 102 if ( dirFlag > 0 ) { 90 { << 103 if ( fDirection == fCurrent_InOut || fDirection == dirFlag ){ 91 if(fDirection == fCurrent_InOut || fDirect << 92 { << 93 G4TouchableHandle theTouchable = preStep 104 G4TouchableHandle theTouchable = preStep->GetTouchableHandle(); 94 // 105 // 95 G4double current = 1.0; 106 G4double current = 1.0; 96 if(weighted) << 107 if ( weighted ) current = preStep->GetWeight(); // Current (Particle Weight) 97 current = preStep->GetWeight(); // Cu << 98 // 108 // 99 if(divideByArea) << 109 if ( divideByArea ){ 100 { << 110 G4double square = 2.*tubsSolid->GetZHalfLength() 101 G4double square = 2. * tubsSolid->GetZ << 111 *tubsSolid->GetInnerRadius()* tubsSolid->GetDeltaPhiAngle()/radian; 102 tubsSolid->GetInnerR << 112 current = current/square; // Current normalized by Area 103 tubsSolid->GetDeltaP << 104 current = current / square; // Curren << 105 } 113 } 106 114 107 G4int index = GetIndex(aStep); 115 G4int index = GetIndex(aStep); 108 EvtMap->add(index, current); << 116 EvtMap->add(index,current); 109 << 110 if(!hitIDMap.empty() && hitIDMap.find(in << 111 { << 112 auto filler = G4VScoreHistFiller::Inst << 113 if(filler == nullptr) << 114 { << 115 G4Exception("G4PSCylinderSurfaceCurr << 116 JustWarning, << 117 "G4TScoreHistFiller is n << 118 "not filled."); << 119 } << 120 else << 121 { << 122 filler->FillH1(hitIDMap[index], preS << 123 } << 124 } << 125 } 117 } >> 118 126 } 119 } 127 120 128 return true; << 121 return TRUE; 129 } 122 } 130 123 131 G4int G4PSCylinderSurfaceCurrent::IsSelectedSu << 124 G4int G4PSCylinderSurfaceCurrent::IsSelectedSurface(G4Step* aStep, G4Tubs* tubsSolid){ 132 << 125 133 { << 126 G4TouchableHandle theTouchable = 134 G4TouchableHandle theTouchable = << 135 aStep->GetPreStepPoint()->GetTouchableHand 127 aStep->GetPreStepPoint()->GetTouchableHandle(); 136 G4double kCarTolerance = << 128 G4double kCarTolerance = G4GeometryTolerance::GetInstance()->GetSurfaceTolerance(); 137 G4GeometryTolerance::GetInstance()->GetSur << 138 129 139 if(aStep->GetPreStepPoint()->GetStepStatus() << 130 if (aStep->GetPreStepPoint()->GetStepStatus() == fGeomBoundary ){ 140 { << 141 // Entering Geometry 131 // Entering Geometry 142 G4ThreeVector stppos1 = aStep->GetPreStepP << 132 G4ThreeVector stppos1= aStep->GetPreStepPoint()->GetPosition(); 143 G4ThreeVector localpos1 = << 133 G4ThreeVector localpos1 = 144 theTouchable->GetHistory()->GetTopTransf 134 theTouchable->GetHistory()->GetTopTransform().TransformPoint(stppos1); 145 if(std::fabs(localpos1.z()) > tubsSolid->G << 135 if ( std::fabs(localpos1.z()) > tubsSolid->GetZHalfLength() ) return -1; 146 return -1; << 136 G4double localR2 = localpos1.x()*localpos1.x()+localpos1.y()*localpos1.y(); 147 G4double localR2 = << 148 localpos1.x() * localpos1.x() + localpos << 149 G4double InsideRadius = tubsSolid->GetInne 137 G4double InsideRadius = tubsSolid->GetInnerRadius(); 150 if(localR2 > << 138 if (localR2 > (InsideRadius-kCarTolerance)*(InsideRadius-kCarTolerance) 151 (InsideRadius - kCarTolerance) * (Ins << 139 &&localR2 < (InsideRadius+kCarTolerance)*(InsideRadius+kCarTolerance)){ 152 localR2 < << 153 (InsideRadius + kCarTolerance) * (Ins << 154 { << 155 return fCurrent_In; 140 return fCurrent_In; 156 } 141 } 157 } 142 } 158 143 159 if(aStep->GetPostStepPoint()->GetStepStatus( << 144 if (aStep->GetPostStepPoint()->GetStepStatus() == fGeomBoundary ){ 160 { << 161 // Exiting Geometry 145 // Exiting Geometry 162 G4ThreeVector stppos2 = aStep->GetPostStep << 146 G4ThreeVector stppos2= aStep->GetPostStepPoint()->GetPosition(); 163 G4ThreeVector localpos2 = << 147 G4ThreeVector localpos2 = 164 theTouchable->GetHistory()->GetTopTransf 148 theTouchable->GetHistory()->GetTopTransform().TransformPoint(stppos2); 165 if(std::fabs(localpos2.z()) > tubsSolid->G << 149 if ( std::fabs(localpos2.z()) > tubsSolid->GetZHalfLength() ) return -1; 166 return -1; << 150 G4double localR2 = localpos2.x()*localpos2.x()+localpos2.y()*localpos2.y(); 167 G4double localR2 = << 168 localpos2.x() * localpos2.x() + localpos << 169 G4double InsideRadius = tubsSolid->GetInne 151 G4double InsideRadius = tubsSolid->GetInnerRadius(); 170 if(localR2 > << 152 if (localR2 > (InsideRadius-kCarTolerance)*(InsideRadius-kCarTolerance) 171 (InsideRadius - kCarTolerance) * (Ins << 153 &&localR2 < (InsideRadius+kCarTolerance)*(InsideRadius+kCarTolerance)){ 172 localR2 < << 173 (InsideRadius + kCarTolerance) * (Ins << 174 { << 175 return fCurrent_Out; 154 return fCurrent_Out; 176 } 155 } 177 } 156 } 178 157 179 return -1; 158 return -1; 180 } 159 } 181 160 182 void G4PSCylinderSurfaceCurrent::Initialize(G4 161 void G4PSCylinderSurfaceCurrent::Initialize(G4HCofThisEvent* HCE) 183 { 162 { 184 EvtMap = new G4THitsMap<G4double>(detector-> 163 EvtMap = new G4THitsMap<G4double>(detector->GetName(), GetName()); 185 if(HCID < 0) << 164 if ( HCID < 0 ) HCID = GetCollectionID(0); 186 HCID = GetCollectionID(0); << 165 HCE->AddHitsCollection(HCID, (G4VHitsCollection*)EvtMap); 187 HCE->AddHitsCollection(HCID, (G4VHitsCollect << 188 } 166 } 189 167 190 void G4PSCylinderSurfaceCurrent::clear() { Evt << 168 void G4PSCylinderSurfaceCurrent::EndOfEvent(G4HCofThisEvent*) >> 169 {;} >> 170 >> 171 void G4PSCylinderSurfaceCurrent::clear(){ >> 172 EvtMap->clear(); >> 173 } >> 174 >> 175 void G4PSCylinderSurfaceCurrent::DrawAll() >> 176 {;} 191 177 192 void G4PSCylinderSurfaceCurrent::PrintAll() 178 void G4PSCylinderSurfaceCurrent::PrintAll() 193 { 179 { 194 G4cout << " MultiFunctionalDet " << detecto 180 G4cout << " MultiFunctionalDet " << detector->GetName() << G4endl; 195 G4cout << " PrimitiveScorer " << GetName() < << 181 G4cout << " PrimitiveScorer " << GetName() <<G4endl; 196 G4cout << " Number of entries " << EvtMap->e 182 G4cout << " Number of entries " << EvtMap->entries() << G4endl; 197 for(const auto& [copy, current] : *(EvtMap-> << 183 std::map<G4int,G4double*>::iterator itr = EvtMap->GetMap()->begin(); 198 { << 184 for(; itr != EvtMap->GetMap()->end(); itr++) { 199 G4cout << " copy no.: " << copy << " cur << 185 G4cout << " copy no.: " << itr->first 200 if(divideByArea) << 186 << " current : " ; 201 { << 187 if ( divideByArea ) { 202 G4cout << *(current) / GetUnitValue() << << 188 G4cout << *(itr->second)/GetUnitValue() 203 } << 189 << " ["<<GetUnit()<<"]"; 204 else << 190 } else { 205 { << 191 G4cout << *(itr->second) << " [tracks]"; 206 G4cout << *(current) << " [tracks]"; << 207 } 192 } 208 G4cout << G4endl; 193 G4cout << G4endl; 209 } 194 } 210 } 195 } 211 196 212 void G4PSCylinderSurfaceCurrent::SetUnit(const 197 void G4PSCylinderSurfaceCurrent::SetUnit(const G4String& unit) 213 { 198 { 214 if(divideByArea) << 199 if ( divideByArea ) { 215 { << 200 CheckAndSetUnit(unit,"Per Unit Surface"); 216 CheckAndSetUnit(unit, "Per Unit Surface"); << 201 } else { 217 } << 202 if (unit == "" ){ 218 else << 203 unitName = unit; 219 { << 204 unitValue = 1.0; 220 if(unit.empty()) << 205 }else{ 221 { << 206 G4String msg = "Invalid unit ["+unit+"] (Current unit is [" +GetUnit()+"] ) for " + GetName(); 222 unitName = unit; << 207 G4Exception("G4PSCylinderSurfaceCurrent::SetUnit","DetPS0002", 223 unitValue = 1.0; << 208 JustWarning,msg); 224 } << 209 } 225 else << 226 { << 227 G4String msg = "Invalid unit [" + unit + << 228 GetUnit() + "] ) for " + << 229 G4Exception("G4PSCylinderSurfaceCurrent: << 230 JustWarning, msg); << 231 } 210 } 232 } << 233 } 211 } 234 212 235 void G4PSCylinderSurfaceCurrent::DefineUnitAnd << 213 void G4PSCylinderSurfaceCurrent::DefineUnitAndCategory(){ 236 { << 214 // Per Unit Surface 237 // Per Unit Surface << 215 new G4UnitDefinition("percentimeter2","percm2","Per Unit Surface",(1./cm2)); 238 new G4UnitDefinition("percentimeter2", "perc << 216 new G4UnitDefinition("permillimeter2","permm2","Per Unit Surface",(1./mm2)); 239 (1. / cm2)); << 217 new G4UnitDefinition("permeter2","perm2","Per Unit Surface",(1./m2)); 240 new G4UnitDefinition("permillimeter2", "perm << 241 (1. / mm2)); << 242 new G4UnitDefinition("permeter2", "perm2", " << 243 } 218 } >> 219 244 220