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In this manner 39 // a zero or constant field can override a glo 44 // a zero or constant field can override a global field, a more or 40 // less exact version can override the externa 45 // less exact version can override the external approximation, lower 41 // or higher precision for tracking can be spe 46 // or higher precision for tracking can be specified, a different 42 // stepper can be chosen for different volumes 47 // stepper can be chosen for different volumes, ... 43 // 48 // 44 // It also stores a pointer to the ChordFinder 49 // It also stores a pointer to the ChordFinder object that can do the 45 // propagation in this field. All geometrical 50 // propagation in this field. All geometrical track "advancement" 46 // in the field is handled by this ChordFinder 51 // in the field is handled by this ChordFinder object. 47 // 52 // 48 // G4FieldManager allows the other classes/obj 53 // G4FieldManager allows the other classes/object (of the MagneticField 49 // & other class categories) to find out wheth 54 // & other class categories) to find out whether a detector field object 50 // exists and what that object is. 55 // exists and what that object is. 51 // 56 // 52 // The Chord Finder must be created either by 57 // The Chord Finder must be created either by calling CreateChordFinder 53 // for a Magnetic Field or by the user creatin 58 // for a Magnetic Field or by the user creating a a Chord Finder object 54 // "manually" and setting this pointer. 59 // "manually" and setting this pointer. 55 // 60 // 56 // A default FieldManager is created by the si 61 // A default FieldManager is created by the singleton class 57 // G4NavigatorForTracking and exists before ma 62 // G4NavigatorForTracking and exists before main is called. 58 // However a new one can be created and given 63 // However a new one can be created and given to G4NavigatorForTracking. 59 // 64 // 60 // Our current design envisions that one Field 65 // Our current design envisions that one Field manager is 61 // valid for each region detector. 66 // valid for each region detector. 62 // << 63 // It is expected that a particular geometrica << 64 // By default a Field Manager is created for t << 65 // will be utilised for all volumes unless it << 66 // field manager. << 67 // Note also that a region with both electric << 68 // have these treated as one field. << 69 // Similarly it could be extended to treat oth << 70 // components of a single field type. << 71 67 72 // Author: John Apostolakis, 10.03.97 - design << 68 // History: >> 69 // - 05.11.03 John Apostolakis, Added Min/MaximumEpsilonStep >> 70 // - 20.06.03 John Apostolakis, Abstract & ability to ConfigureForTrack >> 71 // - 10.03.97 John Apostolakis, design and implementation. 73 // ------------------------------------------- 72 // ------------------------------------------------------------------- >> 73 74 #ifndef G4FIELDMANAGER_HH 74 #ifndef G4FIELDMANAGER_HH 75 #define G4FIELDMANAGER_HH 1 75 #define G4FIELDMANAGER_HH 1 76 76 77 #include "globals.hh" 77 #include "globals.hh" 78 78 79 class G4Field; 79 class G4Field; 80 class G4MagneticField; 80 class G4MagneticField; 81 class G4ChordFinder; 81 class G4ChordFinder; 82 class G4Track; // Forward reference for param 82 class G4Track; // Forward reference for parameter configuration 83 83 84 class G4FieldManager 84 class G4FieldManager 85 { 85 { 86 public: // with description 86 public: // with description 87 G4FieldManager(G4Field* detectorField = nu << 87 G4FieldManager(G4Field *detectorField=0, 88 G4ChordFinder* pChordFinder << 88 G4ChordFinder *pChordFinder=0, 89 G4bool b = true ); // field << 89 G4bool b=true ); // fieldChangesEnergy is taken from field 90 // General constructor for any field. << 90 // General constructor for any field. 91 // -> Must be set with field and chordfi << 91 // -> Must be set with field and chordfinder for use. 92 G4FieldManager(G4MagneticField* detectorMa << 92 G4FieldManager(G4MagneticField *detectorMagneticField); 93 // Creates ChordFinder << 93 // Creates ChordFinder 94 // -> Assumes pure magnetic field (so en << 94 // - assumes pure magnetic field (so Energy constant) 95 << 95 virtual ~G4FieldManager(); 96 virtual ~G4FieldManager(); << 96 97 << 97 G4bool SetDetectorField(G4Field *detectorField); 98 G4FieldManager(const G4FieldManager&) = de << 98 inline const G4Field* GetDetectorField() const; 99 G4FieldManager& operator=(const G4FieldMan << 99 inline G4bool DoesFieldExist() const; 100 << 100 // Set, get and check the field object 101 G4bool SetDetectorField(G4Field* detectorF << 101 102 // Pushes the field to the equation. << 102 void CreateChordFinder(G4MagneticField *detectorMagField); 103 // Failure to push the field (due to abs << 103 inline void SetChordFinder(G4ChordFinder *aChordFinder); 104 // stepper or equation) is << 104 inline G4ChordFinder* GetChordFinder(); 105 // - '0' = quiet : Do not comp << 105 inline const G4ChordFinder* GetChordFinder() const; 106 // (It will s << 106 // Create, set or get the associated Chord Finder 107 // - '1' = warn : a warning i << 107 108 // - '2'/else = FATAL : a fatal err << 108 virtual void ConfigureForTrack( const G4Track * ); 109 // Returns success (true) or failure (fa << 109 // Setup the choice of the configurable parameters 110 << 110 // relying on the current track's energy, particle identity, .. 111 inline void ProposeDetectorField(G4Field* << 111 // Note: In addition to the values of member variables, 112 // Pushes the field to this class only - << 112 // a user can use this to change the ChordFinder, the field, ... 113 // Should be used to initialise this fi << 114 // the chord finder and its dependent cl << 115 // User is then responsible to ensure th << 116 // i) an equation, stepper, driver a << 117 // ii) this field is used by the equa << 118 << 119 inline void ChangeDetectorField(G4Field* << 120 // Pushes the field to the equation ( & << 121 // Can be used only once the equation, s << 122 // have all been created. Else it is an << 123 << 124 inline const G4Field* GetDetectorField() << 125 inline G4bool DoesFieldExist() co << 126 // Set, get and check the field object << 127 << 128 void CreateChordFinder(G4MagneticField* de << 129 inline void SetChordFinder(G4ChordFinder* << 130 inline G4ChordFinder* GetChordFinder(); << 131 inline const G4ChordFinder* GetChordFinder << 132 // Create, set or get the associated Cho << 133 << 134 virtual void ConfigureForTrack( const G4 << 135 // Setup the choice of the configurable << 136 // relying on the current track's energy << 137 // Note: in addition to the values of me << 138 // a user can use this to change t << 139 << 140 // static functions to handle global field << 141 static void SetGlobalFieldManager(G4FieldM << 142 static G4FieldManager* GetGlobalFieldManag << 143 113 144 public: // with description 114 public: // with description 145 115 146 inline G4double GetDeltaIntersection() con << 116 inline G4double GetDeltaIntersection() const; // virtual ? 147 // Accuracy for boundary intersection. << 117 // Accuracy for boundary intersection. 148 118 149 inline G4double GetDeltaOneStep() const; << 119 inline G4double GetDeltaOneStep() const; // virtual ? 150 // Accuracy for one tracking/physics ste << 120 // Accuracy for one tracking/physics step. 151 121 152 inline void SetAccuraciesWithDeltaOneStep( << 122 inline void SetAccuraciesWithDeltaOneStep(G4double valDeltaOneStep); 153 // Sets both accuracies, maintaining a f << 123 // Sets both accuracies, maintaining a fixed ratio for accuracties 154 // of volume Intersection and Integratio << 124 // of volume Intersection and Integration (in One Step) 155 125 156 inline void SetDeltaOneStep(G4double v << 126 inline void SetDeltaOneStep(G4double valueD1step); 157 // Set accuracy for integration of one s 127 // Set accuracy for integration of one step. (only) 158 inline void SetDeltaIntersection(G4dou << 128 inline void SetDeltaIntersection(G4double valueDintersection); 159 // Set accuracy of intersection of a vo 129 // Set accuracy of intersection of a volume. (only) 160 130 161 inline G4double GetMinimumEpsilonStep() c << 131 inline G4double GetMinimumEpsilonStep() const; 162 G4bool SetMinimumEpsilonStep( G4 << 132 inline void SetMinimumEpsilonStep( G4double newEpsMin ); 163 // Minimum for Relative accuracy of a St << 133 // Minimum for Relative accuracy of a Step 164 << 134 165 inline G4double GetMaximumEpsilonStep() c << 135 inline G4double GetMaximumEpsilonStep() const; 166 G4bool SetMaximumEpsilonStep( G4 << 136 inline void SetMaximumEpsilonStep( G4double newEpsMax ); 167 // Maximum for Relative accuracy of a St << 137 // Maximum for Relative accuracy of a Step 168 138 169 inline G4bool DoesFieldChangeEnergy() co << 139 inline G4bool DoesFieldChangeEnergy() const; 170 inline void SetFieldChangesEnergy(G4bo << 140 inline void SetFieldChangesEnergy(G4bool value); 171 // For electric field this should be tru << 141 // For electric field this should be true 172 // For magnetic field this should be fal << 142 // For magnetic field this should be false 173 << 174 virtual G4FieldManager* Clone() const; << 175 // Needed for multi-threading, create a << 176 << 177 public: << 178 static G4double GetMaxAcceptedEpsilon(); << 179 static G4bool SetMaxAcceptedEpsilon(G4do << 180 // Set value -- within limits. << 181 // If it fails, with softFail=true it giv << 182 << 183 protected: << 184 static G4double fMaxAcceptedEpsilon; << 185 static constexpr G4double fMinAcceptedEpsi << 186 // Epsilon_min/max values must be smalle << 187 << 188 static constexpr G4double fMaxWarningEpsil << 189 static constexpr G4double fMaxFinalEpsilon << 190 << 191 static G4bool fVerboseConstruc << 192 // Control verbosity of constructors << 193 143 194 private: 144 private: 195 145 196 void InitialiseFieldChangesEnergy(); << 146 G4FieldManager(const G4FieldManager&); 197 // Check whether field/equation change t << 147 G4FieldManager& operator=(const G4FieldManager&); 198 // and sets the data member accordingly << 148 // Private copy constructor and assignment operator. 199 // Note: does not handle special cases - << 149 200 // separately (e.g. magnetic monopole i << 201 << 202 protected: << 203 void ReportBadEpsilonValue(G4ExceptionDes << 204 G4String& name << 205 << 206 private: 150 private: 207 G4Field* fDetectorField = nullptr; << 151 208 G4ChordFinder* fChordFinder = nullptr; << 152 G4Field* fDetectorField; 209 // Dependent objects -- with state that << 153 G4ChordFinder* fChordFinder; 210 << 154 211 G4bool fAllocatedChordFinder = false; // D << 155 G4bool fAllocatedChordFinder; // Did we used "new" to 212 // c << 156 // create fChordFinder ? 213 // INVARIANTS of tracking --------------- << 157 G4bool fFieldChangesEnergy; 214 // << 158 215 // 1. 'CONSTANTS' - default values for ac << 159 // Values for the required accuracies 216 // << 160 // 217 const G4double fEpsilonMinDefault= 5.0e-5; << 161 G4double fDelta_One_Step_Value; // for one tracking/physics step 218 const G4double fEpsilonMaxDefault= 1.0e-3; << 162 G4double fDelta_Intersection_Val; // for boundary intersection 219 << 163 220 static G4double fDefault_Delta_One_Step_Va << 164 G4double fDefault_Delta_One_Step_Value; // = 0.25 * mm; 221 static G4double fDefault_Delta_Intersectio << 165 G4double fDefault_Delta_Intersection_Val; // = 0.1 * mm; 222 // Default values for accuracy parameter << 166 223 << 167 // Values for the small possible relative accuracy of a step 224 // 2. CHARACTERISTIC of field << 168 // (corresponding to the greatest possible integration accuracy) 225 // << 169 226 G4bool fFieldChangesEnergy = false; << 170 G4double fEpsilonMinDefault; // Can be 1.0e-5 to 1.0e-10 ... 227 << 171 G4double fEpsilonMaxDefault; // Can be 1.0e-3 to 1.0e-8 ... 228 // 3. PARAMETERS that determine the accur << 172 G4double fEpsilonMin; 229 // << 173 G4double fEpsilonMax; 230 G4double fDelta_One_Step_Value; // f << 231 G4double fDelta_Intersection_Val; // f << 232 // Values for the required accuracies << 233 << 234 G4double fEpsilonMin; << 235 G4double fEpsilonMax; << 236 // Values for the small possible relativ << 237 // (corresponding to the greatest possib << 238 << 239 static G4ThreadLocal G4FieldManager* fGlob << 240 // Global field manager set by G4Transpo << 241 // to allow accessing the global field w << 242 // on navigation << 243 }; 174 }; 244 175 >> 176 // Our current design and implementation expect that a particular >> 177 // geometrical region has a Field manager. >> 178 // By default a Field Manager is created for the world volume, and >> 179 // will be utilised for all volumes unless it is overridden by a 'local' >> 180 // field manager. >> 181 >> 182 // Note also that a region with both electric E and magnetic B field will >> 183 // have these treated as one field. >> 184 // Similarly it could be extended to treat other fields as additional components >> 185 // of a single field type. >> 186 >> 187 245 // Implementation of inline functions 188 // Implementation of inline functions 246 189 247 #include "G4FieldManager.icc" 190 #include "G4FieldManager.icc" 248 191 249 #endif << 192 #endif /* G4FIELDMANAGER_HH */ 250 193