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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 // G4Region << 26 // >> 27 // $Id: G4Region.hh 99379 2016-09-20 09:45:19Z gcosmo $ >> 28 // >> 29 // class G4Region 27 // 30 // 28 // Class description: 31 // Class description: 29 // 32 // 30 // Defines a region or a group of regions in t 33 // Defines a region or a group of regions in the detector geometry 31 // setup, sharing properties associated to mat 34 // setup, sharing properties associated to materials or production 32 // cuts which may affect or bias specific phys 35 // cuts which may affect or bias specific physics processes. 33 36 34 // 18.09.02, G.Cosmo - Initial version << 37 // History: >> 38 // 18.09.02 G.Cosmo Initial version 35 // ------------------------------------------- 39 // -------------------------------------------------------------------- 36 #ifndef G4REGION_HH 40 #ifndef G4REGION_HH 37 #define G4REGION_HH 1 << 41 #define G4REGION_HH 38 42 39 #include <vector> 43 #include <vector> 40 #include <map> 44 #include <map> 41 #include <algorithm> 45 #include <algorithm> 42 46 43 #include "G4Types.hh" 47 #include "G4Types.hh" 44 #include "G4String.hh" 48 #include "G4String.hh" 45 #include "G4GeomSplitter.hh" 49 #include "G4GeomSplitter.hh" 46 50 47 class G4ProductionCuts; 51 class G4ProductionCuts; 48 class G4LogicalVolume; 52 class G4LogicalVolume; 49 class G4Material; 53 class G4Material; 50 class G4VUserRegionInformation; 54 class G4VUserRegionInformation; 51 class G4MaterialCutsCouple; 55 class G4MaterialCutsCouple; 52 class G4UserLimits; 56 class G4UserLimits; 53 class G4FieldManager; 57 class G4FieldManager; 54 class G4FastSimulationManager; 58 class G4FastSimulationManager; 55 class G4VPhysicalVolume; 59 class G4VPhysicalVolume; 56 class G4UserSteppingAction; 60 class G4UserSteppingAction; 57 61 58 class G4RegionData 62 class G4RegionData 59 { 63 { 60 // Encapsulates the fields associated to the 64 // Encapsulates the fields associated to the class 61 // G4Region that may not be read-only. 65 // G4Region that may not be read-only. 62 66 63 public: 67 public: 64 68 65 void initialize() 69 void initialize() 66 { 70 { 67 fFastSimulationManager = nullptr; << 71 fFastSimulationManager = 0; 68 fRegionalSteppingAction = nullptr; << 72 fRegionalSteppingAction = 0; 69 } 73 } 70 74 71 G4FastSimulationManager* fFastSimulationMa 75 G4FastSimulationManager* fFastSimulationManager; 72 G4UserSteppingAction* fRegionalSteppingAct 76 G4UserSteppingAction* fRegionalSteppingAction; 73 }; 77 }; 74 78 75 // The type G4RegionManager is introduced to e 79 // The type G4RegionManager is introduced to encapsulate the methods used by 76 // both the master thread and worker threads t 80 // both the master thread and worker threads to allocate memory space for 77 // the fields encapsulated by the class G4Regi 81 // the fields encapsulated by the class G4RegionData. When each thread 78 // initializes the value for these fields, it 82 // initializes the value for these fields, it refers to them using a macro 79 // definition defined below. For every G4Regio 83 // definition defined below. For every G4Region instance, there is a 80 // corresponding G4RegionData instance. All G4 84 // corresponding G4RegionData instance. All G4RegionData instances are 81 // organized by the class G4RegionManager as a 85 // organized by the class G4RegionManager as an array. 82 // The field "int instanceID" is added to the 86 // The field "int instanceID" is added to the class G4Region. 83 // The value of this field in each G4Region in 87 // The value of this field in each G4Region instance is the subscript 84 // of the corresponding G4RegionData instance. 88 // of the corresponding G4RegionData instance. 85 // In order to use the class G4RegionManager, 89 // In order to use the class G4RegionManager, we add a static member in 86 // the class G4Region as follows: "static G4Re 90 // the class G4Region as follows: "static G4RegionManager subInstanceManager". 87 // For the master thread, the array for G4Regi 91 // For the master thread, the array for G4RegionData instances grows 88 // dynamically along with G4Region instances a 92 // dynamically along with G4Region instances are created. For each worker 89 // thread, it copies the array of G4RegionData 93 // thread, it copies the array of G4RegionData instances from the master thread. 90 // In addition, it invokes a method similiar t 94 // In addition, it invokes a method similiar to the constructor explicitly 91 // to achieve the partial effect for each inst 95 // to achieve the partial effect for each instance in the array. 92 // 96 // 93 using G4RegionManager = G4GeomSplitter<G4Regio << 97 typedef G4GeomSplitter<G4RegionData> G4RegionManager; 94 98 95 class G4Region 99 class G4Region 96 { 100 { 97 public: << 101 typedef std::vector<G4LogicalVolume*> G4RootLVList; >> 102 typedef std::vector<G4Material*> G4MaterialList; >> 103 typedef std::pair<G4Material*,G4MaterialCutsCouple*> G4MaterialCouplePair; >> 104 typedef std::map<G4Material*,G4MaterialCutsCouple*> G4MaterialCoupleMap; >> 105 >> 106 public: // with description 98 107 99 G4Region(const G4String& name); 108 G4Region(const G4String& name); 100 virtual ~G4Region(); 109 virtual ~G4Region(); 101 110 102 G4Region(const G4Region&) = delete; << 103 G4Region& operator=(const G4Region&) = del << 104 // Copy constructor and assignment opera << 105 << 106 inline G4bool operator==(const G4Region& r 111 inline G4bool operator==(const G4Region& rg) const; 107 // Equality defined by address only. 112 // Equality defined by address only. 108 113 109 void AddRootLogicalVolume(G4LogicalVolume* << 114 void AddRootLogicalVolume(G4LogicalVolume* lv); 110 void RemoveRootLogicalVolume(G4LogicalVolu 115 void RemoveRootLogicalVolume(G4LogicalVolume* lv, G4bool scan=true); 111 // Add/remove root logical volumes and s 116 // Add/remove root logical volumes and set/reset their 112 // daughters flags as regions. They also 117 // daughters flags as regions. They also recompute the 113 // materials list for the region. Flag f << 118 // materials list for the region. 114 // always enabled by default. Search in << 115 // when adding, assuming the user guaran << 116 // NOT already inserted, in which case s << 117 // achieved in very complex flat geometr << 118 119 119 void SetName(const G4String& name); << 120 inline void SetName(const G4String& name); 120 inline const G4String& GetName() const; 121 inline const G4String& GetName() const; 121 // Set/get region's name. 122 // Set/get region's name. 122 123 123 inline void RegionModified(G4bool flag); 124 inline void RegionModified(G4bool flag); 124 inline G4bool IsModified() const; 125 inline G4bool IsModified() const; 125 // Accessors to flag identifying if a re 126 // Accessors to flag identifying if a region has been modified 126 // (and still cuts needs to be computed) 127 // (and still cuts needs to be computed) or not. 127 128 128 inline void SetProductionCuts(G4Production 129 inline void SetProductionCuts(G4ProductionCuts* cut); 129 inline G4ProductionCuts* GetProductionCuts 130 inline G4ProductionCuts* GetProductionCuts() const; 130 131 131 inline std::vector<G4LogicalVolume*>::iter 132 inline std::vector<G4LogicalVolume*>::iterator 132 GetRootLogicalVolumeIterator(); 133 GetRootLogicalVolumeIterator(); 133 inline std::vector<G4Material*>::const_ite 134 inline std::vector<G4Material*>::const_iterator 134 GetMaterialIterator() const; 135 GetMaterialIterator() const; 135 // Return iterators to lists of root log 136 // Return iterators to lists of root logical volumes and materials. 136 137 137 inline std::size_t GetNumberOfMaterials() << 138 inline size_t GetNumberOfMaterials() const; 138 inline std::size_t GetNumberOfRootVolumes( << 139 inline size_t GetNumberOfRootVolumes() const; 139 // Return the number of elements in the 140 // Return the number of elements in the lists of materials and 140 // root logical volumes. 141 // root logical volumes. 141 142 142 void UpdateMaterialList(); 143 void UpdateMaterialList(); 143 // Clears material list and recomputes i 144 // Clears material list and recomputes it looping through 144 // each root logical volume in the regio 145 // each root logical volume in the region. 145 146 146 void ClearMaterialList(); 147 void ClearMaterialList(); 147 // Clears the material list. 148 // Clears the material list. 148 149 149 void ScanVolumeTree(G4LogicalVolume* lv, G 150 void ScanVolumeTree(G4LogicalVolume* lv, G4bool region); 150 // Scans recursively the 'lv' logical vo 151 // Scans recursively the 'lv' logical volume tree, retrieves 151 // and places all materials in the list 152 // and places all materials in the list if becoming a region. 152 153 153 inline void SetUserInformation(G4VUserRegi 154 inline void SetUserInformation(G4VUserRegionInformation* ui); 154 inline G4VUserRegionInformation* GetUserIn 155 inline G4VUserRegionInformation* GetUserInformation() const; 155 // Set and Get methods for user informat 156 // Set and Get methods for user information. 156 157 157 inline void SetUserLimits(G4UserLimits* ul 158 inline void SetUserLimits(G4UserLimits* ul); 158 inline G4UserLimits* GetUserLimits() const 159 inline G4UserLimits* GetUserLimits() const; 159 // Set and Get methods for userL-limits 160 // Set and Get methods for userL-limits associated to a region. 160 // Once user-limits are set, it will pro 161 // Once user-limits are set, it will propagate to daughter volumes. 161 162 162 inline void ClearMap(); 163 inline void ClearMap(); 163 // Reset G4MaterialCoupleMap 164 // Reset G4MaterialCoupleMap 164 165 165 inline void RegisterMaterialCouplePair(G4M 166 inline void RegisterMaterialCouplePair(G4Material* mat, 166 G4M 167 G4MaterialCutsCouple* couple); 167 // Method invoked by G4ProductionCutsTab 168 // Method invoked by G4ProductionCutsTable to register the pair. 168 169 169 inline G4MaterialCutsCouple* FindCouple(G4 170 inline G4MaterialCutsCouple* FindCouple(G4Material* mat); 170 // Find a G4MaterialCutsCouple which cor 171 // Find a G4MaterialCutsCouple which corresponds to the material 171 // in this region. 172 // in this region. 172 173 173 void SetFastSimulationManager(G4FastSimula 174 void SetFastSimulationManager(G4FastSimulationManager* fsm); 174 G4FastSimulationManager* GetFastSimulation 175 G4FastSimulationManager* GetFastSimulationManager() const; 175 // Set and Get methods for G4FastSimulat 176 // Set and Get methods for G4FastSimulationManager. 176 // The root logical volume that has the 177 // The root logical volume that has the region with G4FastSimulationManager 177 // becomes an envelope of fast simulatio 178 // becomes an envelope of fast simulation. 178 179 179 void ClearFastSimulationManager(); 180 void ClearFastSimulationManager(); 180 // Set G4FastSimulationManager pointer t 181 // Set G4FastSimulationManager pointer to the one for the parent region 181 // if it exists. Otherwise set to null. 182 // if it exists. Otherwise set to null. 182 183 183 inline void SetFieldManager(G4FieldManager 184 inline void SetFieldManager(G4FieldManager* fm); 184 inline G4FieldManager* GetFieldManager() c 185 inline G4FieldManager* GetFieldManager() const; 185 // Set and Get methods for G4FieldManage 186 // Set and Get methods for G4FieldManager. 186 // The region with assigned field-manage 187 // The region with assigned field-manager sets the field to the 187 // geometrical area associated with it; 188 // geometrical area associated with it; priority is anyhow given 188 // to local fields eventually set to log 189 // to local fields eventually set to logical volumes. 189 190 190 inline G4VPhysicalVolume* GetWorldPhysical 191 inline G4VPhysicalVolume* GetWorldPhysical() const; 191 // Get method for the world physical vol 192 // Get method for the world physical volume which this region 192 // belongs to. A valid pointer will be a 193 // belongs to. A valid pointer will be assigned by G4RunManagerKernel 193 // through G4RegionStore when the geomet 194 // through G4RegionStore when the geometry is to be closed. Thus, this 194 // pointer may be incorrect at PreInit a 195 // pointer may be incorrect at PreInit and Idle state. If the pointer 195 // is null at the proper state, this par 196 // is null at the proper state, this particular region does not belong 196 // to any world (maybe not assigned to a 197 // to any world (maybe not assigned to any volume, etc.). 197 198 198 void SetWorld(G4VPhysicalVolume* wp); 199 void SetWorld(G4VPhysicalVolume* wp); 199 // Set the world physical volume if this 200 // Set the world physical volume if this region belongs to this world. 200 // If wp is null, reset the pointer. 201 // If wp is null, reset the pointer. 201 202 202 G4bool BelongsTo(G4VPhysicalVolume* thePhy 203 G4bool BelongsTo(G4VPhysicalVolume* thePhys) const; 203 // Returns whether this region belongs t 204 // Returns whether this region belongs to the given physical volume 204 // (recursively scanned to the bottom of 205 // (recursively scanned to the bottom of the hierarchy). 205 206 206 G4Region* GetParentRegion(G4bool& unique) 207 G4Region* GetParentRegion(G4bool& unique) const; 207 // Returns a region that contains this r 208 // Returns a region that contains this region. Otherwise null returned. 208 // Flag 'unique' is true if there is onl 209 // Flag 'unique' is true if there is only one parent region containing 209 // the current region. 210 // the current region. 210 211 211 void SetRegionalSteppingAction(G4UserStepp 212 void SetRegionalSteppingAction(G4UserSteppingAction* rusa); 212 G4UserSteppingAction* GetRegionalSteppingA 213 G4UserSteppingAction* GetRegionalSteppingAction() const; 213 // Set/Get method of the regional user s 214 // Set/Get method of the regional user stepping action 214 215 215 public: << 216 public: // without description 216 217 217 G4Region(__void__&); 218 G4Region(__void__&); 218 // Fake default constructor for usage re 219 // Fake default constructor for usage restricted to direct object 219 // persistency for clients requiring pre 220 // persistency for clients requiring preallocation of memory for 220 // persistifiable objects. 221 // persistifiable objects. 221 222 222 inline G4int GetInstanceID() const; 223 inline G4int GetInstanceID() const; 223 // Returns the instance ID. 224 // Returns the instance ID. 224 225 225 static const G4RegionManager& GetSubInstan 226 static const G4RegionManager& GetSubInstanceManager(); 226 // Returns the private data instance man 227 // Returns the private data instance manager. 227 228 228 static void Clean(); << 229 inline void UsedInMassGeometry(G4bool val=true); 229 // Clear memory allocated by sub-instanc << 230 inline void UsedInParallelGeometry(G4bool val=true); 230 << 231 inline void UsedInMassGeometry(G4bool val << 232 inline void UsedInParallelGeometry(G4bool << 233 inline G4bool IsInMassGeometry() const; 231 inline G4bool IsInMassGeometry() const; 234 inline G4bool IsInParallelGeometry() const 232 inline G4bool IsInParallelGeometry() const; 235 // Utility methods to identify if region 233 // Utility methods to identify if region is part of the main mass 236 // geometry for tracking or a parallel g 234 // geometry for tracking or a parallel geometry. 237 235 238 private: 236 private: 239 237 >> 238 G4Region(const G4Region&); >> 239 G4Region& operator=(const G4Region&); >> 240 // Private copy constructor and assignment operator. >> 241 240 inline void AddMaterial (G4Material* aMate 242 inline void AddMaterial (G4Material* aMaterial); 241 // Searchs the specified material in the 243 // Searchs the specified material in the material table and 242 // if not present adds it. 244 // if not present adds it. 243 245 244 private: 246 private: 245 247 246 using G4RootLVList = std::vector<G4Logical << 247 using G4MaterialList = std::vector<G4Mater << 248 using G4MaterialCouplePair = std::pair<G4M << 249 using G4MaterialCoupleMap = std::map<G4Mat << 250 << 251 G4String fName; 248 G4String fName; 252 249 253 G4RootLVList fRootVolumes; 250 G4RootLVList fRootVolumes; 254 G4MaterialList fMaterials; 251 G4MaterialList fMaterials; 255 G4MaterialCoupleMap fMaterialCoupleMap; 252 G4MaterialCoupleMap fMaterialCoupleMap; 256 253 257 G4bool fRegionMod = true; << 254 G4bool fRegionMod; 258 G4ProductionCuts* fCut = nullptr; << 255 G4ProductionCuts* fCut; 259 256 260 G4VUserRegionInformation* fUserInfo = null << 257 G4VUserRegionInformation* fUserInfo; 261 G4UserLimits* fUserLimits = nullptr; << 258 G4UserLimits* fUserLimits; 262 G4FieldManager* fFieldManager = nullptr; << 259 G4FieldManager* fFieldManager; 263 260 264 G4VPhysicalVolume* fWorldPhys = nullptr; << 261 G4VPhysicalVolume* fWorldPhys; 265 262 266 G4bool fInMassGeometry = false; << 263 G4bool fInMassGeometry; 267 G4bool fInParallelGeometry = false; << 264 G4bool fInParallelGeometry; 268 265 269 G4int instanceID; 266 G4int instanceID; 270 // This field is used as instance ID. 267 // This field is used as instance ID. 271 G4GEOM_DLL static G4RegionManager subInsta 268 G4GEOM_DLL static G4RegionManager subInstanceManager; 272 // This field helps to use the class G4R 269 // This field helps to use the class G4RegionManager introduced above. 273 }; 270 }; 274 271 275 #include "G4Region.icc" 272 #include "G4Region.icc" 276 273 277 #endif 274 #endif 278 275