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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 // G4ProductionCutsTable << 27 // 26 // 28 // Class description: << 27 // $Id: G4ProductionCutsTable.hh,v 1.7 2006/06/29 19:29:50 gunter Exp $ >> 28 // GEANT4 tag $Name: geant4-08-01-patch-01 $ 29 // 29 // 30 // G4ProductionCutsTable is a singleton class << 30 // 31 // G4ProductionCuts objects. This class manage << 31 // ------------------------------------------------------------ 32 // cuts and energy cuts for each particle type << 32 // GEANT 4 class header file 33 << 33 // 34 // Author: M.Asai, 5 October 2002 - First impl << 34 // Class Description 35 // Modifications: H.Kurashige, 2004-2008 << 35 // G4ProductionCutsTable is a static singleton class of a table of 36 // ------------------------------------------- << 36 // G4ProductionCuts objects. This class also manages tables of 37 #ifndef G4ProductionCutsTable_hh << 37 // production cut and energy cut for each particle type. 38 #define G4ProductionCutsTable_hh 1 << 38 // >> 39 // ------------------------------------------------------------ >> 40 // First Implementation 05 Oct. 2002 M.Asai >> 41 // >> 42 // Modified 03 Feb 2004 H.Kurashige >> 43 // Modify RetrieveCutsTable to allow ordering of materials and >> 44 // couples can be different from one in file (i.e. at storing) >> 45 // Modified 20 Aug. 2004 H.Kurashige >> 46 // Modify RetrieveCutsTable to allow materials and >> 47 // couples can be different from one in file (i.e. at storing) >> 48 // >> 49 // ------------------------------------------------------------ 39 50 40 #include <cmath> << 51 #ifndef G4ProductionCutsTable_h 41 #include <vector> << 52 #define G4ProductionCutsTable_h 1 >> 53 >> 54 class G4RegionStore; >> 55 class G4VRangeToEnergyConverter; >> 56 class G4LogicalVolume; >> 57 class G4VPhysicalVolume; >> 58 class G4ProductionCuts; 42 59 43 #include "globals.hh" 60 #include "globals.hh" >> 61 #include <cmath> 44 #include "G4ios.hh" 62 #include "G4ios.hh" >> 63 #include <vector> 45 #include "G4MaterialCutsCouple.hh" 64 #include "G4MaterialCutsCouple.hh" 46 #include "G4MCCIndexConversionTable.hh" 65 #include "G4MCCIndexConversionTable.hh" 47 #include "G4Region.hh" 66 #include "G4Region.hh" 48 67 49 class G4RegionStore; << 50 class G4VRangeToEnergyConverter; << 51 class G4LogicalVolume; << 52 class G4VPhysicalVolume; << 53 class G4ProductionCuts; << 54 class G4ProductionCutsTableMessenger; << 55 68 56 class G4ProductionCutsTable 69 class G4ProductionCutsTable 57 { 70 { 58 public: << 71 public: // with description 59 << 60 static G4ProductionCutsTable* GetProductio 72 static G4ProductionCutsTable* GetProductionCutsTable(); 61 // This static method returns the single << 73 // This static method returns the singleton pointer of this class object. 62 // At first invocation, the singleton ob << 74 // At the first invokation of this method, the singleton object is instantiated. 63 75 64 G4ProductionCutsTable(const G4ProductionCu << 76 protected: 65 G4ProductionCutsTable& operator=(const G4P << 77 G4ProductionCutsTable(); >> 78 private: >> 79 G4ProductionCutsTable(const G4ProductionCutsTable& right); 66 80 >> 81 public: 67 virtual ~G4ProductionCutsTable(); 82 virtual ~G4ProductionCutsTable(); 68 83 69 void CreateCoupleTables(); << 84 public: // with description 70 // Creates material cuts couples table a << 71 << 72 void UpdateCoupleTable(G4VPhysicalVolume* 85 void UpdateCoupleTable(G4VPhysicalVolume* currentWorld); 73 // Triggers an update of the table of G4 << 86 // This method triggers an update of the table of G4ProductionCuts objects. 74 87 75 void SetEnergyRange(G4double lowedge, G4do 88 void SetEnergyRange(G4double lowedge, G4double highedge); 76 // Sets the limits of energy cuts for al << 89 // This method sets the limits of energy cuts for all particles. 77 90 78 G4double GetLowEdgeEnergy() const; 91 G4double GetLowEdgeEnergy() const; 79 G4double GetHighEdgeEnergy() const; 92 G4double GetHighEdgeEnergy() const; 80 // Get the limits of energy cuts for all << 93 // These methods get the limits of energy cuts for all particles. 81 << 82 G4double GetMaxEnergyCut(); << 83 void SetMaxEnergyCut(G4double value); << 84 // Get/set max cut energy of RangeToEner << 85 // for all particle types << 86 94 87 void DumpCouples() const; 95 void DumpCouples() const; 88 // Displays a list of registered couples << 96 // Display a list of registored couples 89 97 90 const G4MCCIndexConversionTable* GetMCCInd 98 const G4MCCIndexConversionTable* GetMCCIndexConversionTable() const; 91 // Gives the pointer to the MCCIndexConv << 99 // gives the pointer to the MCCIndexConversionTable 92 100 93 const std::vector<G4double>* GetRangeCutsV << 101 private: 94 const std::vector<G4double>* GetEnergyCuts << 95 << 96 std::size_t GetTableSize() const; << 97 // Returns the size of the couple table << 98 << 99 const G4MaterialCutsCouple* GetMaterialCut << 100 // Returns the pointer to the couple << 101 102 102 const G4MaterialCutsCouple* GetMaterialCut << 103 static G4ProductionCutsTable* fG4ProductionCutsTable; 103 co << 104 // Returns the pointer to the couple << 105 << 106 G4int GetCoupleIndex(const G4MaterialCutsC << 107 G4int GetCoupleIndex(const G4Material* aMa << 108 const G4ProductionCut << 109 // Return the index of the couple. << 110 // -1 is returned if index is not found << 111 104 112 G4bool IsModified() const; << 105 typedef std::vector<G4MaterialCutsCouple*> G4CoupleTable; 113 // Returns TRUE if at least one producti << 106 typedef std::vector<G4MaterialCutsCouple*>::const_iterator CoupleTableIterator; >> 107 typedef std::vector<G4double> G4CutVectorForAParticle; >> 108 typedef std::vector<G4CutVectorForAParticle*> G4CutTable; >> 109 G4CoupleTable coupleTable; >> 110 G4CutTable rangeCutTable; >> 111 G4CutTable energyCutTable; >> 112 >> 113 G4RegionStore* fG4RegionStore; >> 114 G4VRangeToEnergyConverter* converters[NumberOfG4CutIndex]; >> 115 >> 116 G4ProductionCuts* defaultProductionCuts; >> 117 >> 118 G4MCCIndexConversionTable mccConversionTable; >> 119 >> 120 // These two vectors are for the backward comparibility >> 121 G4double* rangeDoubleVector[NumberOfG4CutIndex]; >> 122 G4double* energyDoubleVector[NumberOfG4CutIndex]; >> 123 >> 124 public: >> 125 const std::vector<G4double>* GetRangeCutsVector(size_t pcIdx) const; >> 126 const std::vector<G4double>* GetEnergyCutsVector(size_t pcIdx) const; >> 127 >> 128 // These two vectors are for the backward comparibility >> 129 G4double* GetRangeCutsDoubleVector(size_t pcIdx) const; >> 130 G4double* GetEnergyCutsDoubleVector(size_t pcIdx) const; 114 131 115 void PhysicsTableUpdated(); << 132 public: // with description 116 // Resets the status of IsModified(). Th << 133 size_t GetTableSize() const; 117 // used by the RunManager when physics t << 134 // This method returns the size of the couple table. 118 << 135 119 G4ProductionCuts* GetDefaultProductionCuts << 136 const G4MaterialCutsCouple* GetMaterialCutsCouple(G4int i) const; 120 // Returns the default production cuts << 137 // This method returns the pointer to the couple. 121 << 138 122 G4double ConvertRangeToEnergy(const G4Part << 139 const G4MaterialCutsCouple* 123 const G4Mate << 140 GetMaterialCutsCouple(const G4Material* aMat, 124 G4doub << 141 const G4ProductionCuts* aCut) const; 125 // Gives energy corresponding to range v << 142 // This method returns the pointer to the couple. 126 // -1 is returned if particle or materia << 143 127 << 144 G4int GetCoupleIndex(const G4MaterialCutsCouple* aCouple) const; 128 void ResetConverters(); << 145 G4int GetCoupleIndex(const G4Material* aMat, 129 // Resets all range to energy converters << 146 const G4ProductionCuts* aCut) const; 130 << 147 // These methods return the index of the couple. 131 G4bool StoreCutsTable(const G4String& dire << 148 // -1 is returned if index is not found. 132 G4bool ascii = false << 133 // Stores cuts and material information << 134 // the specified directory << 135 << 136 G4bool RetrieveCutsTable(const G4String& d << 137 G4bool ascii = fa << 138 // Retrieve material cut couple informat << 139 // in files under the specified director << 140 << 141 G4bool CheckForRetrieveCutsTable(const G4S << 142 G4bool as << 143 // Checks stored material and cut values << 144 // with the current detector setup << 145 << 146 G4double* GetRangeCutsDoubleVector(std::si << 147 G4double* GetEnergyCutsDoubleVector(std::s << 148 // Methods for backward compatibility << 149 << 150 void SetEnergyCutVector(const std::vector< << 151 // User defined cut vectors (idx < 4) ra << 152 // to avoid inconsistency in physics << 153 << 154 void SetVerboseLevel(G4int value); << 155 G4int GetVerboseLevel() const; << 156 // Control flag for output message << 157 // 0: Silent << 158 // 1: Warning message << 159 // 2: More << 160 << 161 protected: << 162 << 163 G4ProductionCutsTable(); << 164 << 165 virtual G4bool StoreMaterialInfo(const G4S << 166 G4bool as << 167 // Stores material information in files << 168 << 169 virtual G4bool CheckMaterialInfo(const G4S << 170 G4bool as << 171 // Checks stored material is consistent << 172 << 173 virtual G4bool StoreMaterialCutsCoupleInfo << 174 << 175 // Stores materialCutsCouple information << 176 // specified directory << 177 << 178 virtual G4bool CheckMaterialCutsCoupleInfo << 179 << 180 // Checks stored materialCutsCouple is c << 181 // the current detector setup << 182 << 183 virtual G4bool StoreCutsInfo(const G4Strin << 184 G4bool ascii << 185 // Stores cut values information in file << 186 << 187 virtual G4bool RetrieveCutsInfo(const G4S << 188 G4bool as << 189 // Retrieves cut values information in f << 190 // specified directory << 191 149 >> 150 G4bool IsModified() const; >> 151 // This method returns TRUE if at least one production cut value is modified. >> 152 >> 153 void PhysicsTableUpdated(); >> 154 // This method resets the status of IsModified(). This method must >> 155 // be exclusively used by RunManager when physics tables are built. >> 156 >> 157 G4ProductionCuts* GetDefaultProductionCuts() const; >> 158 // This method returns the default production cuts. >> 159 192 private: 160 private: 193 << 194 void ScanAndSetCouple(G4LogicalVolume* aLV 161 void ScanAndSetCouple(G4LogicalVolume* aLV, 195 G4MaterialCutsCouple << 162 G4MaterialCutsCouple* aCouple, 196 G4Region* aRegion); << 163 G4Region* aRegion); 197 << 198 G4bool IsCoupleUsedInTheRegion(const G4Mat << 199 const G4Reg << 200 << 201 << 202 private: << 203 164 204 static G4ProductionCutsTable* fProductionC << 165 bool IsCoupleUsedInTheRegion(const G4MaterialCutsCouple* aCouple, >> 166 const G4Region* aRegion) const; 205 167 206 std::vector<G4MaterialCutsCouple*> coupleT << 168 public: // with description 207 std::vector<std::vector<G4double>*> rangeC << 169 // Store cuts and material information in files under the specified directory. 208 std::vector<std::vector<G4double>*> energy << 170 G4bool StoreCutsTable(const G4String& directory, 209 << 171 G4bool ascii = false); 210 std::vector<G4double>* userEnergyCuts[4] = << 172 >> 173 // Retrieve material cut couple information >> 174 // in files under the specified directory. >> 175 G4bool RetrieveCutsTable(const G4String& directory, >> 176 G4bool ascii = false); >> 177 >> 178 // check stored material and cut values are consistent with the current detector setup. >> 179 G4bool CheckForRetrieveCutsTable(const G4String& directory, >> 180 G4bool ascii = false); 211 181 212 G4RegionStore* fG4RegionStore = nullptr; << 182 protected: 213 G4VRangeToEnergyConverter* converters[Numb << 214 183 215 G4ProductionCuts* defaultProductionCuts = << 184 // Store material information in files under the specified directory. >> 185 virtual G4bool StoreMaterialInfo(const G4String& directory, >> 186 G4bool ascii = false); >> 187 >> 188 // check stored material is consistent with the current detector setup. >> 189 virtual G4bool CheckMaterialInfo(const G4String& directory, >> 190 G4bool ascii = false); >> 191 >> 192 // Store materialCutsCouple information in files under the specified directory. >> 193 virtual G4bool StoreMaterialCutsCoupleInfo(const G4String& directory, >> 194 G4bool ascii = false); >> 195 >> 196 // check stored materialCutsCouple is consistent with the current detector setup. >> 197 virtual G4bool CheckMaterialCutsCoupleInfo(const G4String& directory, >> 198 G4bool ascii = false); >> 199 >> 200 // Store cut values information in files under the specified directory. >> 201 virtual G4bool StoreCutsInfo(const G4String& directory, >> 202 G4bool ascii = false); >> 203 >> 204 // Retrieve cut values information in files under the specified directory. >> 205 virtual G4bool RetrieveCutsInfo(const G4String& directory, >> 206 G4bool ascii = false); 216 207 217 G4MCCIndexConversionTable mccConversionTab << 208 private: >> 209 G4bool firstUse; >> 210 enum { FixedStringLengthForStore = 32 }; 218 211 219 // These two vectors are for backward comp << 212 public: // with description 220 G4double* rangeDoubleVector[NumberOfG4CutI << 213 void SetVerboseLevel(G4int value); 221 G4double* energyDoubleVector[NumberOfG4Cut << 214 G4int GetVerboseLevel() const; >> 215 // controle flag for output message >> 216 // 0: Silent >> 217 // 1: Warning message >> 218 // 2: More 222 219 223 enum { FixedStringLengthForStore = 32 }; << 220 private: >> 221 G4int verboseLevel; 224 222 225 G4ProductionCutsTableMessenger* fMessenger << 226 G4int verboseLevel = 1; << 227 G4bool firstUse = true; << 228 }; 223 }; 229 224 230 // ------------------ << 231 // Inline methods << 232 // ------------------ << 233 << 234 inline 225 inline 235 const std::vector<G4double>* << 226 const std::vector<G4double>* G4ProductionCutsTable::GetRangeCutsVector(size_t pcIdx) const 236 G4ProductionCutsTable::GetRangeCutsVector(std: << 237 { 227 { 238 return rangeCutTable[pcIdx]; 228 return rangeCutTable[pcIdx]; 239 } 229 } 240 230 241 inline 231 inline 242 const std::vector<G4double>* << 232 const std::vector<G4double>* G4ProductionCutsTable::GetEnergyCutsVector(size_t pcIdx) const 243 G4ProductionCutsTable::GetEnergyCutsVector(std << 244 { 233 { 245 return energyCutTable[pcIdx]; << 234 return energyCutTable[pcIdx]; 246 } 235 } 247 236 248 inline 237 inline 249 std::size_t G4ProductionCutsTable::GetTableSiz << 238 size_t G4ProductionCutsTable::GetTableSize() const 250 { 239 { 251 return coupleTable.size(); 240 return coupleTable.size(); 252 } 241 } 253 242 254 inline 243 inline 255 const G4MaterialCutsCouple* << 244 const G4MaterialCutsCouple* G4ProductionCutsTable::GetMaterialCutsCouple(G4int i) const 256 G4ProductionCutsTable::GetMaterialCutsCouple(G << 257 { 245 { 258 return coupleTable[std::size_t(i)]; << 246 return coupleTable[size_t(i)]; 259 } 247 } 260 248 261 inline 249 inline 262 G4bool G4ProductionCutsTable::IsModified() con << 250 G4bool G4ProductionCutsTable::IsModified() const 263 { 251 { 264 if(firstUse) return true; 252 if(firstUse) return true; 265 for(auto itr=coupleTable.cbegin(); itr!=coup << 253 for(G4ProductionCutsTable::CoupleTableIterator itr=coupleTable.begin(); 266 { << 254 itr!=coupleTable.end();itr++){ 267 if((*itr)->IsRecalcNeeded()) 255 if((*itr)->IsRecalcNeeded()) 268 { 256 { 269 return true; 257 return true; 270 } 258 } 271 } 259 } 272 return false; 260 return false; 273 } 261 } 274 262 275 inline 263 inline 276 void G4ProductionCutsTable::PhysicsTableUpdate << 264 void G4ProductionCutsTable::PhysicsTableUpdated() 277 { 265 { 278 for(auto itr=coupleTable.cbegin(); itr!=coup << 266 for(G4ProductionCutsTable::CoupleTableIterator itr=coupleTable.begin();itr!=coupleTable.end();itr++){ 279 { << 280 (*itr)->PhysicsTableUpdated(); 267 (*itr)->PhysicsTableUpdated(); 281 } 268 } 282 } 269 } 283 270 284 inline 271 inline 285 G4double* << 272 G4double* G4ProductionCutsTable::GetRangeCutsDoubleVector(size_t pcIdx) const 286 G4ProductionCutsTable::GetRangeCutsDoubleVecto << 273 { return rangeDoubleVector[pcIdx]; } 287 { << 288 return rangeDoubleVector[pcIdx]; << 289 } << 290 274 291 inline 275 inline 292 G4double* << 276 G4double* G4ProductionCutsTable::GetEnergyCutsDoubleVector(size_t pcIdx) const 293 G4ProductionCutsTable::GetEnergyCutsDoubleVect << 277 { return energyDoubleVector[pcIdx]; } 294 { << 295 return energyDoubleVector[pcIdx]; << 296 } << 297 278 298 inline 279 inline 299 G4ProductionCuts* G4ProductionCutsTable::GetDe << 280 G4ProductionCuts* G4ProductionCutsTable::GetDefaultProductionCuts() const 300 { << 281 { return defaultProductionCuts; } 301 return defaultProductionCuts; << 302 } << 303 282 304 inline 283 inline 305 G4bool G4ProductionCutsTable::IsCoupleUsedInTh << 284 bool G4ProductionCutsTable::IsCoupleUsedInTheRegion( 306 const G4Mater 285 const G4MaterialCutsCouple* aCouple, 307 const G4Regio 286 const G4Region* aRegion) const 308 { 287 { 309 G4ProductionCuts* fProductionCut = aRegion-> 288 G4ProductionCuts* fProductionCut = aRegion->GetProductionCuts(); 310 auto mItr = aRegion->GetMaterialIterator(); << 289 std::vector<G4Material*>::const_iterator mItr = aRegion->GetMaterialIterator(); 311 std::size_t nMaterial = aRegion->GetNumberOf << 290 size_t nMaterial = aRegion->GetNumberOfMaterials(); 312 for(std::size_t iMate=0;iMate<nMaterial; ++i << 291 for(size_t iMate=0;iMate<nMaterial;iMate++, mItr++){ 313 { << 314 if(aCouple->GetMaterial()==(*mItr) && 292 if(aCouple->GetMaterial()==(*mItr) && 315 aCouple->GetProductionCuts()==fProducti << 293 aCouple->GetProductionCuts()==fProductionCut){ 316 { << 317 return true; 294 return true; 318 } 295 } 319 } 296 } 320 return false; 297 return false; 321 } 298 } 322 299 323 inline 300 inline 324 const G4MaterialCutsCouple* 301 const G4MaterialCutsCouple* 325 G4ProductionCutsTable::GetMaterialCutsCouple(c << 302 G4ProductionCutsTable::GetMaterialCutsCouple(const G4Material* aMat, 326 c << 303 const G4ProductionCuts* aCut) const 327 { << 304 { 328 for(auto cItr=coupleTable.cbegin(); cItr!=co << 305 for(CoupleTableIterator cItr=coupleTable.begin();cItr!=coupleTable.end();cItr++) 329 { 306 { 330 if((*cItr)->GetMaterial()!=aMat) continue; 307 if((*cItr)->GetMaterial()!=aMat) continue; 331 if((*cItr)->GetProductionCuts()==aCut) ret 308 if((*cItr)->GetProductionCuts()==aCut) return (*cItr); 332 } 309 } 333 return nullptr; << 310 return 0; 334 } 311 } 335 312 336 inline 313 inline 337 G4int << 314 G4int G4ProductionCutsTable::GetCoupleIndex(const G4MaterialCutsCouple* aCouple) const 338 G4ProductionCutsTable::GetCoupleIndex(const G4 << 339 { 315 { 340 G4int idx = 0; 316 G4int idx = 0; 341 for(auto cItr=coupleTable.cbegin(); cItr!=co << 317 for(CoupleTableIterator cItr=coupleTable.begin();cItr!=coupleTable.end();cItr++) 342 { 318 { 343 if((*cItr)==aCouple) return idx; 319 if((*cItr)==aCouple) return idx; 344 ++idx; << 320 idx++; 345 } 321 } 346 return -1; 322 return -1; 347 } 323 } 348 324 349 inline 325 inline 350 G4int G4ProductionCutsTable::GetCoupleIndex(co << 326 G4int G4ProductionCutsTable:: GetCoupleIndex(const G4Material* aMat, 351 co << 327 const G4ProductionCuts* aCut) const 352 { 328 { 353 const G4MaterialCutsCouple* aCouple = GetMat 329 const G4MaterialCutsCouple* aCouple = GetMaterialCutsCouple(aMat,aCut); 354 return GetCoupleIndex(aCouple); 330 return GetCoupleIndex(aCouple); 355 } 331 } 356 332 357 inline 333 inline 358 G4int G4ProductionCutsTable::GetVerboseLevel() << 334 void G4ProductionCutsTable::SetVerboseLevel(G4int value) 359 { 335 { 360 return verboseLevel; << 336 verboseLevel = value; >> 337 } >> 338 >> 339 inline >> 340 G4int G4ProductionCutsTable::GetVerboseLevel() const >> 341 { >> 342 return verboseLevel; 361 } 343 } 362 344 363 inline 345 inline 364 const G4MCCIndexConversionTable* << 346 const G4MCCIndexConversionTable* 365 G4ProductionCutsTable::GetMCCIndexConversionTa << 347 G4ProductionCutsTable::GetMCCIndexConversionTable() const 366 { 348 { 367 return &mccConversionTable; 349 return &mccConversionTable; 368 } 350 } 369 351 370 #endif 352 #endif >> 353 >> 354 >> 355 >> 356 >> 357 >> 358 371 359