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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 // 26 // 27 // 27 // 28 // G4PSSphereSurfaceFlux 28 // G4PSSphereSurfaceFlux 29 #include "G4PSSphereSurfaceFlux.hh" 29 #include "G4PSSphereSurfaceFlux.hh" 30 30 31 #include "G4SystemOfUnits.hh" 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 ////////////////////////////////////////////// 39 //////////////////////////////////////////////////////////////////////////////// 40 // (Description) 40 // (Description) 41 // This is a primitive scorer class for scor 41 // This is a primitive scorer class for scoring only Surface Flux. 42 // Flux version assumes only for G4Sphere sha << 42 // Flux version assumes only for G4Sphere shape. 43 // 43 // 44 // Surface is defined at the inside of sphere 44 // Surface is defined at the inside of sphere. 45 // Direction -Rmin +Rmax 45 // Direction -Rmin +Rmax 46 // 0 IN || OUT ->|<- | 46 // 0 IN || OUT ->|<- | 47 // 1 IN ->| | 47 // 1 IN ->| | 48 // 2 OUT |<- | 48 // 2 OUT |<- | 49 // 49 // 50 // Created: 2005-11-14 Tsukasa ASO, Akinori K 50 // Created: 2005-11-14 Tsukasa ASO, Akinori Kimura. 51 // 29-Mar-2007 T.Aso, Bug fix for momentum d 51 // 29-Mar-2007 T.Aso, Bug fix for momentum direction at outgoing flux. 52 // 2010-07-22 Introduce Unit specification. 52 // 2010-07-22 Introduce Unit specification. 53 // 2010-07-22 Add weighted and divideByAre o 53 // 2010-07-22 Add weighted and divideByAre options 54 // 2011-02-21 Get correct momentum direction << 54 // 2011-02-21 Get correct momentum direction in Flux_Out. 55 // 2011-09-09 Modify comment in PrintAll(). 55 // 2011-09-09 Modify comment in PrintAll(). 56 // 2014-03-03 T.Aso, To use always positive 56 // 2014-03-03 T.Aso, To use always positive value for anglefactor. 57 ////////////////////////////////////////////// 57 /////////////////////////////////////////////////////////////////////////////// 58 58 59 G4PSSphereSurfaceFlux::G4PSSphereSurfaceFlux(c << 59 G4PSSphereSurfaceFlux::G4PSSphereSurfaceFlux(G4String name, 60 G << 60 G4int direction, G4int depth) 61 : G4PSSphereSurfaceFlux(name, direction, "pe << 61 : G4VPrimitiveScorer(name,depth),HCID(-1),fDirection(direction), 62 {} << 62 EvtMap(0),weighted(true),divideByArea(true) >> 63 { >> 64 DefineUnitAndCategory(); >> 65 SetUnit("percm2"); >> 66 } 63 67 64 G4PSSphereSurfaceFlux::G4PSSphereSurfaceFlux(c << 68 G4PSSphereSurfaceFlux::G4PSSphereSurfaceFlux(G4String name, 65 c << 69 G4int direction, 66 : G4VPrimitiveScorer(name, depth) << 70 const G4String& unit, 67 , HCID(-1) << 71 G4int depth) 68 , fDirection(direction) << 72 : G4VPrimitiveScorer(name,depth),HCID(-1),fDirection(direction), 69 , EvtMap(nullptr) << 73 EvtMap(0),weighted(true),divideByArea(true) 70 , weighted(true) << 71 , divideByArea(true) << 72 { 74 { 73 DefineUnitAndCategory(); << 75 DefineUnitAndCategory(); 74 SetUnit(unit); << 76 SetUnit(unit); 75 } 77 } 76 78 77 G4bool G4PSSphereSurfaceFlux::ProcessHits(G4St << 79 G4PSSphereSurfaceFlux::~G4PSSphereSurfaceFlux() >> 80 {;} >> 81 >> 82 G4bool G4PSSphereSurfaceFlux::ProcessHits(G4Step* aStep,G4TouchableHistory*) 78 { 83 { 79 G4StepPoint* preStep = aStep->GetPreStepPoin 84 G4StepPoint* preStep = aStep->GetPreStepPoint(); 80 85 81 G4VPhysicalVolume* physVol = preStep-> << 86 G4VPhysicalVolume* physVol = preStep->GetPhysicalVolume(); 82 G4VPVParameterisation* physParam = physVol-> 87 G4VPVParameterisation* physParam = physVol->GetParameterisation(); 83 G4VSolid* solid = nullptr; << 88 G4VSolid * solid = 0; 84 if(physParam != nullptr) << 89 if(physParam) 85 { // for parameterized volume << 90 { // for parameterized volume 86 G4int idx = << 91 G4int idx = ((G4TouchableHistory*)(aStep->GetPreStepPoint()->GetTouchable())) 87 ((G4TouchableHistory*) (aStep->GetPreSte << 92 ->GetReplicaNumber(indexDepth); 88 ->GetReplicaNumber(indexDepth); << 89 solid = physParam->ComputeSolid(idx, physV 93 solid = physParam->ComputeSolid(idx, physVol); 90 solid->ComputeDimensions(physParam, idx, p << 94 solid->ComputeDimensions(physParam,idx,physVol); 91 } 95 } 92 else 96 else 93 { // for ordinary volume << 97 { // for ordinary volume 94 solid = physVol->GetLogicalVolume()->GetSo 98 solid = physVol->GetLogicalVolume()->GetSolid(); 95 } 99 } 96 100 97 auto sphereSolid = (G4Sphere*) (solid); << 101 G4Sphere* sphereSolid = (G4Sphere*)(solid); 98 102 99 G4int dirFlag = IsSelectedSurface(aStep, sph << 103 G4int dirFlag =IsSelectedSurface(aStep,sphereSolid); 100 if(dirFlag > 0) << 104 if ( dirFlag > 0 ) { 101 { << 105 if ( fDirection == fFlux_InOut || fDirection == dirFlag ){ 102 if(fDirection == fFlux_InOut || fDirection << 106 103 { << 107 G4StepPoint* thisStep=0; 104 G4StepPoint* thisStep = nullptr; << 108 if ( dirFlag == fFlux_In ){ 105 if(dirFlag == fFlux_In) << 106 { << 107 thisStep = preStep; 109 thisStep = preStep; 108 } << 110 }else if ( dirFlag == fFlux_Out ){ 109 else if(dirFlag == fFlux_Out) << 110 { << 111 thisStep = aStep->GetPostStepPoint(); 111 thisStep = aStep->GetPostStepPoint(); 112 } << 112 }else{ 113 else << 113 return FALSE; 114 { << 115 return false; << 116 } 114 } 117 115 118 G4TouchableHandle theTouchable = thisSte 116 G4TouchableHandle theTouchable = thisStep->GetTouchableHandle(); 119 G4ThreeVector pdirection = thisSte << 117 G4ThreeVector pdirection = thisStep->GetMomentumDirection(); 120 G4ThreeVector localdir = << 118 G4ThreeVector localdir = 121 theTouchable->GetHistory()->GetTopTran 119 theTouchable->GetHistory()->GetTopTransform().TransformAxis(pdirection); 122 G4double localdirL2 = localdir.x() * loc << 120 G4double localdirL2 = localdir.x()*localdir.x() 123 localdir.y() * loc << 121 +localdir.y()*localdir.y() 124 localdir.z() * loc << 122 +localdir.z()*localdir.z(); 125 G4ThreeVector stppos1 = aStep->GetPreSte << 123 G4ThreeVector stppos1= aStep->GetPreStepPoint()->GetPosition(); 126 G4ThreeVector localpos1 = << 124 G4ThreeVector localpos1 = 127 theTouchable->GetHistory()->GetTopTran 125 theTouchable->GetHistory()->GetTopTransform().TransformPoint(stppos1); 128 G4double localR2 = localpos1.x() * local << 126 G4double localR2 = localpos1.x()*localpos1.x() 129 localpos1.y() * local << 127 +localpos1.y()*localpos1.y() 130 localpos1.z() * local << 128 +localpos1.z()*localpos1.z(); 131 G4double anglefactor = << 129 G4double anglefactor = (localdir.x()*localpos1.x() 132 (localdir.x() * localpos1.x() + locald << 130 +localdir.y()*localpos1.y() 133 localdir.z() * localpos1.z()) / << 131 +localdir.z()*localpos1.z()) 134 std::sqrt(localdirL2) / std::sqrt(loca << 132 /std::sqrt(localdirL2)/std::sqrt(localR2); 135 if(anglefactor < 0.0) << 133 if ( anglefactor < 0.0 ) anglefactor *= -1.0; 136 anglefactor *= -1.0; << 137 134 138 G4double current = 1.0 / anglefactor; 135 G4double current = 1.0 / anglefactor; 139 if(weighted) << 136 if ( weighted ) current *= thisStep->GetWeight(); // Flux (Particle Weight) 140 current *= thisStep->GetWeight(); // << 137 if ( divideByArea ) // Flux with angle. 141 if(divideByArea) // << 142 { 138 { 143 G4double radi = sphereSolid->GetInnerR << 139 G4double radi = sphereSolid->GetInnerRadius(); 144 G4double dph = sphereSolid->GetDeltaP << 140 G4double dph = sphereSolid->GetDeltaPhiAngle()/radian; 145 G4double stth = sphereSolid->GetStartT << 141 G4double stth = sphereSolid->GetStartThetaAngle()/radian; 146 G4double enth = stth + sphereSolid->Ge << 142 G4double enth = stth+sphereSolid->GetDeltaThetaAngle()/radian; 147 current /= radi * radi * dph * (-std:: << 143 current /= radi*radi*dph*( -std::cos(enth) + std::cos(stth) ); 148 } 144 } 149 145 150 G4int index = GetIndex(aStep); 146 G4int index = GetIndex(aStep); 151 EvtMap->add(index, current); << 147 EvtMap->add(index,current); 152 } 148 } 153 } 149 } 154 150 155 return true; << 151 return TRUE; 156 } 152 } 157 153 158 G4int G4PSSphereSurfaceFlux::IsSelectedSurface << 154 G4int G4PSSphereSurfaceFlux::IsSelectedSurface(G4Step* aStep, G4Sphere* sphereSolid){ 159 << 160 { << 161 G4TouchableHandle theTouchable = << 162 aStep->GetPreStepPoint()->GetTouchableHand << 163 G4double kCarTolerance = << 164 G4GeometryTolerance::GetInstance()->GetSur << 165 155 166 if(aStep->GetPreStepPoint()->GetStepStatus() << 156 G4TouchableHandle theTouchable = 167 { << 157 aStep->GetPreStepPoint()->GetTouchableHandle(); >> 158 G4double kCarTolerance = G4GeometryTolerance::GetInstance()->GetSurfaceTolerance(); >> 159 >> 160 if (aStep->GetPreStepPoint()->GetStepStatus() == fGeomBoundary ){ 168 // Entering Geometry 161 // Entering Geometry 169 G4ThreeVector stppos1 = aStep->GetPreStepP << 162 G4ThreeVector stppos1= aStep->GetPreStepPoint()->GetPosition(); 170 G4ThreeVector localpos1 = << 163 G4ThreeVector localpos1 = 171 theTouchable->GetHistory()->GetTopTransf 164 theTouchable->GetHistory()->GetTopTransform().TransformPoint(stppos1); 172 G4double localR2 = localpos1.x() * localpo << 165 G4double localR2 = localpos1.x()*localpos1.x() 173 localpos1.y() * localpo << 166 +localpos1.y()*localpos1.y() 174 localpos1.z() * localpo << 167 +localpos1.z()*localpos1.z(); 175 // G4double InsideRadius2 = << 168 //G4double InsideRadius2 = 176 // sphereSolid->GetInsideRadius()*sphereS 169 // sphereSolid->GetInsideRadius()*sphereSolid->GetInsideRadius(); 177 // if(std::fabs( localR2 - InsideRadius2 ) << 170 //if(std::fabs( localR2 - InsideRadius2 ) < kCarTolerance ){ 178 G4double InsideRadius = sphereSolid->GetIn 171 G4double InsideRadius = sphereSolid->GetInnerRadius(); 179 if(localR2 > << 172 if ( localR2 > (InsideRadius-kCarTolerance)*(InsideRadius-kCarTolerance) 180 (InsideRadius - kCarTolerance) * (Ins << 173 &&localR2 < (InsideRadius+kCarTolerance)*(InsideRadius+kCarTolerance)){ 181 localR2 < << 182 (InsideRadius + kCarTolerance) * (Ins << 183 { << 184 return fFlux_In; 174 return fFlux_In; 185 } 175 } 186 } 176 } 187 177 188 if(aStep->GetPostStepPoint()->GetStepStatus( << 178 if (aStep->GetPostStepPoint()->GetStepStatus() == fGeomBoundary ){ 189 { << 190 // Exiting Geometry 179 // Exiting Geometry 191 G4ThreeVector stppos2 = aStep->GetPostStep << 180 G4ThreeVector stppos2= aStep->GetPostStepPoint()->GetPosition(); 192 G4ThreeVector localpos2 = << 181 G4ThreeVector localpos2 = 193 theTouchable->GetHistory()->GetTopTransf 182 theTouchable->GetHistory()->GetTopTransform().TransformPoint(stppos2); 194 G4double localR2 = localpos2.x() * localpo << 183 G4double localR2 = localpos2.x()*localpos2.x() 195 localpos2.y() * localpo << 184 +localpos2.y()*localpos2.y() 196 localpos2.z() * localpo << 185 +localpos2.z()*localpos2.z(); 197 // G4double InsideRadius2 = << 186 //G4double InsideRadius2 = 198 // sphereSolid->GetInsideRadius()*sphereS 187 // sphereSolid->GetInsideRadius()*sphereSolid->GetInsideRadius(); 199 // if(std::facb(localR2 - InsideRadius2) ) << 188 //if(std::facb(localR2 - InsideRadius2) ) < kCarTolerance ){ 200 G4double InsideRadius = sphereSolid->GetIn 189 G4double InsideRadius = sphereSolid->GetInnerRadius(); 201 if(localR2 > << 190 if ( localR2 > (InsideRadius-kCarTolerance)*(InsideRadius-kCarTolerance) 202 (InsideRadius - kCarTolerance) * (Ins << 191 &&localR2 < (InsideRadius+kCarTolerance)*(InsideRadius+kCarTolerance)){ 203 localR2 < << 204 (InsideRadius + kCarTolerance) * (Ins << 205 { << 206 return fFlux_Out; 192 return fFlux_Out; 207 } 193 } 208 } 194 } 209 195 210 return -1; 196 return -1; 211 } 197 } 212 198 213 void G4PSSphereSurfaceFlux::Initialize(G4HCofT 199 void G4PSSphereSurfaceFlux::Initialize(G4HCofThisEvent* HCE) 214 { 200 { 215 EvtMap = new G4THitsMap<G4double>(detector-> 201 EvtMap = new G4THitsMap<G4double>(detector->GetName(), GetName()); 216 if(HCID < 0) << 202 if ( HCID < 0 ) HCID = GetCollectionID(0); 217 HCID = GetCollectionID(0); << 203 HCE->AddHitsCollection(HCID, (G4VHitsCollection*)EvtMap); 218 HCE->AddHitsCollection(HCID, (G4VHitsCollect << 204 } >> 205 >> 206 void G4PSSphereSurfaceFlux::EndOfEvent(G4HCofThisEvent*) >> 207 {;} >> 208 >> 209 void G4PSSphereSurfaceFlux::clear(){ >> 210 EvtMap->clear(); 219 } 211 } 220 212 221 void G4PSSphereSurfaceFlux::clear() { EvtMap-> << 213 void G4PSSphereSurfaceFlux::DrawAll() >> 214 {;} 222 215 223 void G4PSSphereSurfaceFlux::PrintAll() 216 void G4PSSphereSurfaceFlux::PrintAll() 224 { 217 { 225 G4cout << " MultiFunctionalDet " << detecto 218 G4cout << " MultiFunctionalDet " << detector->GetName() << G4endl; 226 G4cout << " PrimitiveScorer " << GetName() < << 219 G4cout << " PrimitiveScorer " << GetName() <<G4endl; 227 G4cout << " Number of entries " << EvtMap->e 220 G4cout << " Number of entries " << EvtMap->entries() << G4endl; 228 for(const auto& [copy, flux] : *(EvtMap->Get << 221 std::map<G4int,G4double*>::iterator itr = EvtMap->GetMap()->begin(); 229 { << 222 for(; itr != EvtMap->GetMap()->end(); itr++) { 230 G4cout << " copy no.: " << copy << 223 G4cout << " copy no.: " << itr->first 231 << " Flux : " << *(flux) / GetUni << 224 << " Flux : " << *(itr->second)/GetUnitValue() 232 << GetUnit() << "]" << G4endl; << 225 << " ["<<GetUnit()<<"]" >> 226 << G4endl; 233 } 227 } 234 } 228 } 235 229 236 void G4PSSphereSurfaceFlux::SetUnit(const G4St 230 void G4PSSphereSurfaceFlux::SetUnit(const G4String& unit) 237 { 231 { 238 if(divideByArea) << 232 if ( divideByArea ) { 239 { << 233 CheckAndSetUnit(unit,"Per Unit Surface"); 240 CheckAndSetUnit(unit, "Per Unit Surface"); << 234 } else { 241 } << 235 if (unit == "" ){ 242 else << 236 unitName = unit; 243 { << 237 unitValue = 1.0; 244 if(unit.empty()) << 238 }else{ 245 { << 239 G4String msg = "Invalid unit ["+unit+"] (Current unit is [" +GetUnit()+"] ) for " + GetName(); 246 unitName = unit; << 240 G4Exception("G4PSSphereSurfaceFlux::SetUnit","DetPS0016",JustWarning,msg); 247 unitValue = 1.0; << 241 } 248 } << 249 else << 250 { << 251 G4String msg = "Invalid unit [" + unit + << 252 GetUnit() + "] ) for " + << 253 G4Exception("G4PSSphereSurfaceFlux::SetU << 254 msg); << 255 } 242 } 256 } << 257 } 243 } 258 244 259 void G4PSSphereSurfaceFlux::DefineUnitAndCateg << 245 void G4PSSphereSurfaceFlux::DefineUnitAndCategory(){ 260 { << 246 // Per Unit Surface 261 // Per Unit Surface << 247 new G4UnitDefinition("percentimeter2","percm2","Per Unit Surface",(1./cm2)); 262 new G4UnitDefinition("percentimeter2", "perc << 248 new G4UnitDefinition("permillimeter2","permm2","Per Unit Surface",(1./mm2)); 263 (1. / cm2)); << 249 new G4UnitDefinition("permeter2","perm2","Per Unit Surface",(1./m2)); 264 new G4UnitDefinition("permillimeter2", "perm << 265 (1. / mm2)); << 266 new G4UnitDefinition("permeter2", "perm2", " << 267 } 250 } >> 251 268 252