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60 class G4ParticleDefinition; 61 class G4DynamicParticle; 61 class G4DynamicParticle; 62 class G4MaterialCutsCouple; 62 class G4MaterialCutsCouple; 63 63 64 class G4VAtomDeexcitation { 64 class G4VAtomDeexcitation { 65 public: 65 public: 66 66 67 explicit G4VAtomDeexcitation(const G4String& << 67 G4VAtomDeexcitation(const G4String& modname = "Deexcitation"); 68 68 69 virtual ~G4VAtomDeexcitation(); 69 virtual ~G4VAtomDeexcitation(); 70 70 71 //========== initialization ========== 71 //========== initialization ========== 72 72 73 // Overall initialisation before new run 73 // Overall initialisation before new run 74 void InitialiseAtomicDeexcitation(); 74 void InitialiseAtomicDeexcitation(); 75 75 76 // Initialisation of deexcitation at the beg 76 // Initialisation of deexcitation at the beginning of run 77 virtual void InitialiseForNewRun() = 0; 77 virtual void InitialiseForNewRun() = 0; 78 78 79 // Initialisation for a concrete atom 79 // Initialisation for a concrete atom 80 // May be called at run time 80 // May be called at run time 81 virtual void InitialiseForExtraAtom(G4int Z) 81 virtual void InitialiseForExtraAtom(G4int Z) = 0; 82 82 83 void SetDeexcitationActiveRegion(const G4Str 83 void SetDeexcitationActiveRegion(const G4String& rname, 84 G4bool valD 84 G4bool valDeexcitation, 85 G4bool valA 85 G4bool valAuger, 86 G4bool valP 86 G4bool valPIXE); 87 << 87 88 // Activation of deexcitation 88 // Activation of deexcitation 89 inline void SetFluo(G4bool); 89 inline void SetFluo(G4bool); 90 inline G4bool IsFluoActive() const; 90 inline G4bool IsFluoActive() const; 91 91 92 // Activation of Auger electron production 92 // Activation of Auger electron production 93 inline void SetAuger(G4bool); 93 inline void SetAuger(G4bool); 94 inline G4bool IsAugerActive() const; 94 inline G4bool IsAugerActive() const; 95 95 96 // Activation of Auger cascade 96 // Activation of Auger cascade 97 inline void SetAugerCascade(G4bool); 97 inline void SetAugerCascade(G4bool); 98 inline G4bool IsAugerCascadeActive() const; 98 inline G4bool IsAugerCascadeActive() const; 99 99 100 // Activation of PIXE simulation 100 // Activation of PIXE simulation 101 inline void SetPIXE(G4bool); 101 inline void SetPIXE(G4bool); 102 inline G4bool IsPIXEActive() const; 102 inline G4bool IsPIXEActive() const; 103 103 104 // Deexcitation model name 104 // Deexcitation model name 105 inline const G4String& GetName() const; 105 inline const G4String& GetName() const; 106 106 107 // Access to the list of atoms active for de 107 // Access to the list of atoms active for deexcitation 108 inline const std::vector<G4bool>& GetListOfA 108 inline const std::vector<G4bool>& GetListOfActiveAtoms() const; 109 109 110 // Verbosity level 110 // Verbosity level 111 inline void SetVerboseLevel(G4int); 111 inline void SetVerboseLevel(G4int); 112 inline G4int GetVerboseLevel() const; 112 inline G4int GetVerboseLevel() const; 113 113 114 //========== Run time methods ========== 114 //========== Run time methods ========== 115 115 116 // Check if deexcitation is active for a giv 116 // Check if deexcitation is active for a given geometry volume 117 inline G4bool CheckDeexcitationActiveRegion( 117 inline G4bool CheckDeexcitationActiveRegion(G4int coupleIndex); 118 inline G4bool CheckAugerActiveRegion(G4int c 118 inline G4bool CheckAugerActiveRegion(G4int coupleIndex); 119 119 120 // Get atomic shell by shell index, used by 120 // Get atomic shell by shell index, used by discrete processes 121 // (for example, photoelectric), when shell 121 // (for example, photoelectric), when shell vacancy sampled by the model 122 virtual 122 virtual 123 const G4AtomicShell* GetAtomicShell(G4int Z, 123 const G4AtomicShell* GetAtomicShell(G4int Z, 124 G4Atomic 124 G4AtomicShellEnumerator shell) = 0; 125 125 126 // generation of deexcitation for given atom 126 // generation of deexcitation for given atom and shell vacancy 127 // and material cut couple, which defines cu << 127 inline void GenerateParticles(std::vector<G4DynamicParticle*>* secVect, 128 void GenerateParticles(std::vector<G4Dynamic << 128 const G4AtomicShell*, 129 const G4AtomicShell*, << 129 G4int Z, 130 G4int Z, G4int couple << 130 G4int coupleIndex); 131 131 132 // generation of deexcitation for given atom 132 // generation of deexcitation for given atom and shell vacancy 133 virtual void GenerateParticles(std::vector<G 133 virtual void GenerateParticles(std::vector<G4DynamicParticle*>* secVect, 134 const G4Atomi 134 const G4AtomicShell*, 135 G4int Z, G4do << 135 G4int Z, >> 136 G4double gammaCut, >> 137 G4double eCut) = 0; 136 138 137 // access or compute PIXE cross section 139 // access or compute PIXE cross section 138 virtual G4double 140 virtual G4double 139 GetShellIonisationCrossSectionPerAtom(const 141 GetShellIonisationCrossSectionPerAtom(const G4ParticleDefinition*, 140 G4int 142 G4int Z, 141 G4Atom 143 G4AtomicShellEnumerator shell, 142 G4doub 144 G4double kinE, 143 const << 145 const G4Material* mat = 0) = 0; 144 146 145 // access or compute PIXE cross section 147 // access or compute PIXE cross section 146 virtual G4double 148 virtual G4double 147 ComputeShellIonisationCrossSectionPerAtom( << 149 ComputeShellIonisationCrossSectionPerAtom(const G4ParticleDefinition*, 148 const << 150 G4int Z, 149 G4int << 151 G4AtomicShellEnumerator shell, 150 G4Atom << 152 G4double kinE, 151 G4doub << 153 const G4Material* mat = 0) = 0; 152 const << 153 154 154 // Sampling of PIXE for ionisation processes 155 // Sampling of PIXE for ionisation processes 155 void AlongStepDeexcitation(std::vector<G4Tra 156 void AlongStepDeexcitation(std::vector<G4Track*>& tracks, 156 const G4Step& ste 157 const G4Step& step, 157 G4double& eLoss, 158 G4double& eLoss, 158 G4int coupleIndex 159 G4int coupleIndex); 159 160 160 // copy constructor and hide assignment oper << 161 G4VAtomDeexcitation(G4VAtomDeexcitation &) = << 162 G4VAtomDeexcitation & operator=(const G4VAto << 163 << 164 private: 161 private: 165 162 166 const G4ParticleDefinition* gamma; << 163 // copy constructor and hide assignment operator 167 const G4ProductionCutsTable* theCoupleTable << 164 G4VAtomDeexcitation(G4VAtomDeexcitation &); 168 << 165 G4VAtomDeexcitation & operator=(const G4VAtomDeexcitation &right); 169 G4int nCouples = 0; << 170 G4int verbose = 1; << 171 166 172 G4bool isActive = false; << 167 G4EmParameters* theParameters; 173 G4bool flagAuger = false; << 168 const G4ParticleDefinition* gamma; 174 G4bool flagPIXE = false; << 175 G4bool ignoreCuts = false; << 176 << 177 G4bool isActiveLocked = false; << 178 G4bool isAugerLocked = false; << 179 G4bool isPIXELocked = false; << 180 169 >> 170 G4ProductionCutsTable* theCoupleTable; >> 171 G4int verbose; >> 172 G4String name; >> 173 G4bool isActive; >> 174 G4bool flagAuger; >> 175 G4bool flagAugerCascade; >> 176 G4bool flagPIXE; >> 177 G4bool ignoreCuts; 181 std::vector<G4bool> activeZ; 178 std::vector<G4bool> activeZ; 182 std::vector<G4bool> activeDeexcitationMedi 179 std::vector<G4bool> activeDeexcitationMedia; 183 std::vector<G4bool> activeAugerMedia; 180 std::vector<G4bool> activeAugerMedia; 184 std::vector<G4bool> activePIXEMedia; 181 std::vector<G4bool> activePIXEMedia; >> 182 std::vector<G4String> activeRegions; 185 std::vector<G4bool> deRegions; 183 std::vector<G4bool> deRegions; 186 std::vector<G4bool> AugerRegions; 184 std::vector<G4bool> AugerRegions; 187 std::vector<G4bool> PIXERegions; 185 std::vector<G4bool> PIXERegions; 188 std::vector<G4DynamicParticle*> vdyn; 186 std::vector<G4DynamicParticle*> vdyn; 189 std::vector<G4String> activeRegions; << 190 << 191 G4String name; << 192 187 193 #ifdef G4MULTITHREADED << 188 static G4int pixeIDg; 194 static G4Mutex atomDeexcitationMutex; << 189 static G4int pixeIDe; 195 #endif << 196 }; 190 }; 197 191 198 inline void G4VAtomDeexcitation::SetFluo(G4boo 192 inline void G4VAtomDeexcitation::SetFluo(G4bool val) 199 { 193 { 200 if(!isActiveLocked) { isActive = val; isActi << 194 isActive = val; >> 195 theParameters->SetFluo(val); 201 } 196 } 202 197 203 inline G4bool G4VAtomDeexcitation::IsFluoActiv 198 inline G4bool G4VAtomDeexcitation::IsFluoActive() const 204 { 199 { 205 return isActive; 200 return isActive; 206 } 201 } 207 202 208 inline void G4VAtomDeexcitation::SetAuger(G4bo 203 inline void G4VAtomDeexcitation::SetAuger(G4bool val) 209 { 204 { 210 if(!isAugerLocked) { flagAuger = val; isAuge << 205 flagAuger = val; >> 206 if(val) { isActive = true; } >> 207 theParameters->SetAuger(val); 211 } 208 } 212 209 213 inline G4bool G4VAtomDeexcitation::IsAugerActi 210 inline G4bool G4VAtomDeexcitation::IsAugerActive() const 214 { 211 { 215 return flagAuger; 212 return flagAuger; 216 } 213 } 217 214 218 inline void G4VAtomDeexcitation::SetAugerCasca 215 inline void G4VAtomDeexcitation::SetAugerCascade(G4bool val) 219 { 216 { 220 SetAuger(val); << 217 flagAugerCascade = val; >> 218 if(val) { isActive = true; } >> 219 theParameters->SetAugerCascade(val); 221 } 220 } 222 221 223 inline G4bool G4VAtomDeexcitation::IsAugerCasc 222 inline G4bool G4VAtomDeexcitation::IsAugerCascadeActive() const 224 { 223 { 225 return flagAuger; << 224 return flagAugerCascade; 226 } 225 } 227 226 228 inline void G4VAtomDeexcitation::SetPIXE(G4boo 227 inline void G4VAtomDeexcitation::SetPIXE(G4bool val) 229 { 228 { 230 if(!isPIXELocked) { flagPIXE = val; isPIXEL << 229 flagPIXE = val; >> 230 if(val) { isActive = true; } >> 231 theParameters->SetPixe(val); 231 } 232 } 232 233 233 inline G4bool G4VAtomDeexcitation::IsPIXEActiv 234 inline G4bool G4VAtomDeexcitation::IsPIXEActive() const 234 { 235 { 235 return flagPIXE; 236 return flagPIXE; 236 } 237 } 237 238 238 inline const G4String& G4VAtomDeexcitation::Ge 239 inline const G4String& G4VAtomDeexcitation::GetName() const 239 { 240 { 240 return name; 241 return name; 241 } 242 } 242 243 243 inline const std::vector<G4bool>& 244 inline const std::vector<G4bool>& 244 G4VAtomDeexcitation::GetListOfActiveAtoms() co 245 G4VAtomDeexcitation::GetListOfActiveAtoms() const 245 { 246 { 246 return activeZ; 247 return activeZ; 247 } 248 } 248 249 249 inline void G4VAtomDeexcitation::SetVerboseLev 250 inline void G4VAtomDeexcitation::SetVerboseLevel(G4int val) 250 { 251 { 251 verbose = val; 252 verbose = val; 252 } 253 } 253 254 254 inline G4int G4VAtomDeexcitation::GetVerboseLe 255 inline G4int G4VAtomDeexcitation::GetVerboseLevel() const 255 { 256 { 256 return verbose; 257 return verbose; 257 } 258 } 258 259 259 inline G4bool 260 inline G4bool 260 G4VAtomDeexcitation::CheckDeexcitationActiveRe << 261 G4VAtomDeexcitation::CheckDeexcitationActiveRegion(G4int coupleIndex) 261 { 262 { 262 return (idx < nCouples) ? activeDeexcitation << 263 return (isActive || activeDeexcitationMedia[coupleIndex]); 263 } 264 } 264 265 265 inline G4bool 266 inline G4bool 266 G4VAtomDeexcitation::CheckAugerActiveRegion(G4 << 267 G4VAtomDeexcitation::CheckAugerActiveRegion(G4int coupleIndex) 267 { 268 { 268 return (idx < nCouples) ? activeAugerMedia[i << 269 >> 270 return (flagAuger || activeAugerMedia[coupleIndex]); >> 271 } >> 272 >> 273 inline void >> 274 G4VAtomDeexcitation::GenerateParticles(std::vector<G4DynamicParticle*>* v, >> 275 const G4AtomicShell* as, >> 276 G4int Z, >> 277 G4int idx) >> 278 { >> 279 G4double gCut = DBL_MAX; >> 280 if(ignoreCuts) { >> 281 gCut = 0.0; >> 282 } else if (theCoupleTable) { >> 283 gCut = (*(theCoupleTable->GetEnergyCutsVector(0)))[idx]; >> 284 } >> 285 if(gCut < as->BindingEnergy()) { >> 286 G4double eCut = DBL_MAX; >> 287 if(CheckAugerActiveRegion(idx)) { >> 288 if(ignoreCuts) { >> 289 eCut = 0.0; >> 290 } else if (theCoupleTable) { >> 291 eCut = (*(theCoupleTable->GetEnergyCutsVector(1)))[idx]; >> 292 } >> 293 } >> 294 GenerateParticles(v, as, Z, gCut, eCut); >> 295 } 269 } 296 } 270 297 271 #endif 298 #endif 272 299 273 300