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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 // $Id: G4Transportation.hh,v 1.12 2006/06/29 21:10:32 gunter Exp $ >> 28 // GEANT4 tag $Name: geant4-08-02 $ 27 // 29 // 28 // 30 // 29 // ------------------------------------------- 31 // ------------------------------------------------------------ 30 // GEANT 4 include file implementation 32 // GEANT 4 include file implementation 31 // ------------------------------------------- 33 // ------------------------------------------------------------ 32 // 34 // 33 // Class description: 35 // Class description: 34 // 36 // 35 // G4Transportation is a process responsible f 37 // G4Transportation is a process responsible for the transportation of 36 // a particle, i.e. the geometrical propagatio 38 // a particle, i.e. the geometrical propagation encountering the 37 // geometrical sub-volumes of the detectors. 39 // geometrical sub-volumes of the detectors. 38 // It is also tasked with part of updating the 40 // It is also tasked with part of updating the "safety". 39 41 40 // =========================================== 42 // ======================================================================= 41 // Created: 19 March 1997, J. Apostolakis 43 // Created: 19 March 1997, J. Apostolakis 42 // =========================================== 44 // ======================================================================= 43 #ifndef G4Transportation_hh 45 #ifndef G4Transportation_hh 44 #define G4Transportation_hh 1 46 #define G4Transportation_hh 1 45 47 46 #include "G4VProcess.hh" 48 #include "G4VProcess.hh" >> 49 #include "G4FieldManager.hh" 47 50 >> 51 #include "G4Navigator.hh" >> 52 #include "G4TransportationManager.hh" >> 53 #include "G4PropagatorInField.hh" 48 #include "G4Track.hh" 54 #include "G4Track.hh" 49 #include "G4Step.hh" 55 #include "G4Step.hh" 50 #include "G4ParticleChangeForTransport.hh" 56 #include "G4ParticleChangeForTransport.hh" 51 57 52 class G4Navigator; << 53 class G4PropagatorInField; << 54 class G4SafetyHelper; << 55 class G4TransportationLogger; << 56 << 57 class G4Transportation : public G4VProcess 58 class G4Transportation : public G4VProcess 58 { 59 { 59 // Concrete class that does the geometrical 60 // Concrete class that does the geometrical transport 60 61 61 public: // with description 62 public: // with description 62 63 63 G4Transportation( G4int verbosityLevel= 1 << 64 G4Transportation( G4int verbosityLevel= 1); 64 ~G4Transportation(); 65 ~G4Transportation(); 65 66 66 G4double AlongStepGetPhysicalInterac 67 G4double AlongStepGetPhysicalInteractionLength( 67 const G4Track& tr 68 const G4Track& track, 68 G4double p 69 G4double previousStepSize, 69 G4double c 70 G4double currentMinimumStep, 70 G4double& c 71 G4double& currentSafety, 71 G4GPILSelec 72 G4GPILSelection* selection 72 ); // override; << 73 ); 73 74 74 G4VParticleChange* AlongStepDoIt( 75 G4VParticleChange* AlongStepDoIt( 75 const G4Track& tr 76 const G4Track& track, 76 const G4Step& ste 77 const G4Step& stepData 77 ); // override; << 78 ); 78 79 79 G4VParticleChange* PostStepDoIt( 80 G4VParticleChange* PostStepDoIt( 80 const G4Track& tr 81 const G4Track& track, 81 const G4Step& st 82 const G4Step& stepData 82 ); // override; << 83 ); 83 // Responsible for the relocation << 84 // Responsible for the relocation. 84 85 85 G4double PostStepGetPhysicalInteractionLe 86 G4double PostStepGetPhysicalInteractionLength( 86 const G4Track& , 87 const G4Track& , 87 G4double previo 88 G4double previousStepSize, 88 G4ForceCondition* 89 G4ForceCondition* pForceCond 89 ); // override; << 90 ); 90 // Forces the PostStepDoIt action to be 91 // Forces the PostStepDoIt action to be called, 91 // but does not limit the step << 92 // but does not limit the step. 92 93 93 inline G4bool FieldExertedForce() { retur << 94 << 95 G4PropagatorInField* GetPropagatorInField 94 G4PropagatorInField* GetPropagatorInField(); 96 void SetPropagatorInField( G4PropagatorIn 95 void SetPropagatorInField( G4PropagatorInField* pFieldPropagator); 97 // Access/set the assistant class that << 96 // Access/set the assistant class that Propagate in a Field. >> 97 >> 98 inline void SetVerboseLevel( G4int verboseLevel ); >> 99 inline G4int GetVerboseLevel() const; >> 100 // Level of warnings regarding eg energy conservation >> 101 // in field integration. 98 102 99 inline G4double GetThresholdWarningEnergy 103 inline G4double GetThresholdWarningEnergy() const; 100 inline G4double GetThresholdImportantEner 104 inline G4double GetThresholdImportantEnergy() const; 101 inline G4int GetThresholdTrials() const; 105 inline G4int GetThresholdTrials() const; 102 106 103 inline void SetThresholdWarningEnergy( G4 107 inline void SetThresholdWarningEnergy( G4double newEnWarn ); 104 inline void SetThresholdImportantEnergy( 108 inline void SetThresholdImportantEnergy( G4double newEnImp ); 105 inline void SetThresholdTrials(G4int newM 109 inline void SetThresholdTrials(G4int newMaxTrials ); >> 110 106 // Get/Set parameters for killing loopers 111 // Get/Set parameters for killing loopers: 107 // Above 'important' energy a 'looping' 112 // Above 'important' energy a 'looping' particle in field will 108 // *NOT* be abandoned, except after fTh 113 // *NOT* be abandoned, except after fThresholdTrials attempts. 109 // Below Warning energy, no verbosity for 114 // Below Warning energy, no verbosity for looping particles is issued 110 115 111 void SetHighLooperThresholds(); // Shortc << 112 void SetLowLooperThresholds(); // Set low << 113 void PushThresholdsToLogger(); // Inform << 114 void ReportLooperThresholds(); // Print v << 115 << 116 inline G4double GetMaxEnergyKilled() cons 116 inline G4double GetMaxEnergyKilled() const; 117 inline G4double GetSumEnergyKilled() cons 117 inline G4double GetSumEnergyKilled() const; 118 inline void ResetKilledStatistics( G4int 118 inline void ResetKilledStatistics( G4int report = 1); 119 // Statistics for tracks killed (currentl 119 // Statistics for tracks killed (currently due to looping in field) 120 120 121 inline void EnableShortStepOptimisation(G << 122 // Whether short steps < safety will avoi << 123 << 124 static G4bool EnableMagneticMoment(G4bool << 125 // Whether to enable particles to be defl << 126 << 127 static G4bool EnableGravity(G4bool useGra << 128 // Whether to enable particles to be defl << 129 << 130 static void SetSilenceLooperWarnings( G << 131 // Do not warn (or throw exception) about << 132 static G4bool GetSilenceLooperWarnings(); << 133 << 134 public: // without description << 135 static G4bool EnableUseMagneticMoment(G4b << 136 { return EnableMagneticMoment(useMoment); << 137 << 138 public: // without description 121 public: // without description 139 122 140 G4double AtRestGetPhysicalInteractionLeng << 123 G4double AtRestGetPhysicalInteractionLength( 141 << 124 const G4Track& , 142 { return -1.0; } // No operation in At << 125 G4ForceCondition* >> 126 ) { return -1.0; }; >> 127 // No operation in AtRestDoIt. 143 128 144 G4VParticleChange* AtRestDoIt( const G4Tr << 129 G4VParticleChange* AtRestDoIt( 145 { return 0; } // No operation in At << 130 const G4Track& , >> 131 const G4Step& >> 132 ) {return 0;}; >> 133 // No operation in AtRestDoIt. 146 134 147 void StartTracking(G4Track* aTrack); << 135 void StartTracking(G4Track* aTrack); 148 // Reset state for new (potentially res 136 // Reset state for new (potentially resumed) track 149 137 150 virtual void ProcessDescription(std::ostr << 151 void PrintStatistics( std::ostream& outSt << 152 << 153 protected: 138 protected: 154 139 155 void SetTouchableInformation(const G4Touc << 140 G4bool DoesGlobalFieldExist(); >> 141 // Checks whether a field exists for the "global" field manager. 156 142 157 void ReportMissingLogger(const char * met << 143 private: 158 << 159 protected: << 160 144 161 G4Navigator* fLinearNavigator; << 145 G4Navigator* fLinearNavigator; 162 // The navigator for the 'mass' geometr << 163 // (the real one, that physics occurs i << 164 G4PropagatorInField* fFieldPropagator; 146 G4PropagatorInField* fFieldPropagator; 165 // The Propagators used to transport th 147 // The Propagators used to transport the particle 166 148 167 G4ThreeVector fTransportEndPosition= << 149 // G4FieldManager* fGlobalFieldMgr; // Used MagneticField CC 168 G4ThreeVector fTransportEndMomentumDir= << 150 // Field Manager for the whole Detector 169 G4double fTransportEndKineticEnergy= << 170 G4ThreeVector fTransportEndSpin= G4Three << 171 G4bool fMomentumChanged= true; << 172 G4bool fEndGlobalTimeComputed= fal << 173 G4double fCandidateEndGlobalTime= 0. << 174 // The particle's state after this Step << 175 151 176 G4bool fAnyFieldExists= false; << 152 G4ThreeVector fTransportEndPosition; 177 << 153 G4ThreeVector fTransportEndMomentumDir; 178 G4bool fParticleIsLooping = false; << 154 G4double fTransportEndKineticEnergy; 179 G4bool fNewTrack= true; // Flag << 155 G4ThreeVector fTransportEndSpin; 180 G4bool fFirstStepInVolume= true; << 156 G4bool fMomentumChanged; 181 G4bool fLastStepInVolume= false; // Last << 157 G4bool fEnergyChanged; 182 // (temporary << 158 G4bool fEndGlobalTimeComputed; 183 G4bool fGeometryLimitedStep= true; << 159 G4double fCandidateEndGlobalTime; 184 // Flag to determine whether a boundary << 160 // The particle's state after this Step, Store for DoIt 185 161 186 G4bool fFieldExertedForce= false; // Duri << 162 G4bool fParticleIsLooping; 187 163 188 G4TouchableHandle fCurrentTouchableHandle << 164 G4TouchableHandle fCurrentTouchableHandle; 189 165 190 G4ThreeVector fPreviousSftOrigin; << 166 // G4bool fFieldExists; 191 G4double fPreviousSafety; << 167 // Whether a magnetic field exists ... >> 168 // A data member for this is problematic: it is useful only if it >> 169 // can be initialised and updated -- and a scheme is not yet possible. >> 170 >> 171 G4bool fGeometryLimitedStep; >> 172 // Flag to determine whether a boundary was reached. >> 173 >> 174 G4ThreeVector fPreviousSftOrigin; >> 175 G4double fPreviousSafety; 192 // Remember last safety origin & value. 176 // Remember last safety origin & value. 193 177 194 G4ParticleChangeForTransport fParticleCha 178 G4ParticleChangeForTransport fParticleChange; 195 // New ParticleChange 179 // New ParticleChange 196 180 197 G4double fEndPointDistance; << 181 G4double endpointDistance; 198 182 199 // Thresholds for looping particles: << 183 // Thresholds for looping particles: 200 // << 184 // 201 G4double fThreshold_Warning_Energy = 1. << 185 G4double fThreshold_Warning_Energy; // Warn above this energy 202 G4double fThreshold_Important_Energy = 1. << 186 G4double fThreshold_Important_Energy; // Hesitate above this 203 G4int fThresholdTrials = 10; // << 187 G4int fThresholdTrials; // for this no of trials 204 // Above 'important' energy a 'looping' 188 // Above 'important' energy a 'looping' particle in field will 205 // *NOT* be abandoned, except after fTh << 189 // *NOT* be abandoned, except after fThresholdTrials attempts. 206 G4int fAbandonUnstableTrials = 0; // << 190 G4double fUnimportant_Energy; 207 // << 191 // Below this energy, no verbosity for looping particles is issued 208 // Counter for steps in which particle re << 192 209 // ( Used if it is above 'Important' Ene << 193 // Counter for steps in which particle reports 'looping', 210 G4int fNoLooperTrials= 0; << 194 // if it is above 'Important' Energy 211 << 195 G4int fNoLooperTrials; 212 // Statistics for tracks abandoned due to << 196 // Statistics for tracks abandoned 213 // << 197 G4double fSumEnergyKilled; 214 G4double fSumEnergyKilled= 0.0; << 198 G4double fMaxEnergyKilled; 215 G4double fSumEnerSqKilled= 0.0; << 199 216 G4double fMaxEnergyKilled= -1.0; << 200 217 G4int fMaxEnergyKilledPDG= 0; << 201 // Verbosity 218 unsigned long fNumLoopersKilled= 0; << 202 G4int fVerboseLevel; 219 G4double fSumEnergyKilled_NonElectron= 0. << 203 // Verbosity level for warnings 220 G4double fSumEnerSqKilled_NonElectron= 0. << 204 // eg about energy non-conservation in magnetic field. 221 G4double fMaxEnergyKilled_NonElectron= -1 << 222 G4int fMaxEnergyKilled_NonElecPDG= 0; << 223 unsigned long fNumLoopersKilled_NonElectr << 224 G4double fSumEnergySaved= 0.0; << 225 G4double fMaxEnergySaved= -1.0; << 226 G4double fSumEnergyUnstableSaved = 0.0; << 227 // Whether to avoid calling G4Navigator f << 228 // If using it, the safety estimate for e << 229 // << 230 G4bool fShortStepOptimisation; << 231 << 232 G4SafetyHelper* fpSafetyHelper; // To << 233 G4TransportationLogger* fpLogger; // Rep << 234 << 235 protected: << 236 << 237 static G4bool fUseMagneticMoment; << 238 static G4bool fUseGravity; << 239 static G4bool fSilenceLooperWarnings; // << 240 << 241 }; 205 }; 242 206 243 #include "G4Transportation.icc" 207 #include "G4Transportation.icc" 244 208 245 #endif 209 #endif 246 210