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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 /// \file biasing/ReverseMC01/src/G4AdjointPhy << 26 // $Id: G4AdjointPhysicsMessenger.cc,v 1.1 2009/11/19 22:41:18 ldesorgh Exp $ 27 /// \brief Implementation of the G4AdjointPhys << 27 // GEANT4 tag $Name: geant4-09-03 $ 28 // << 29 // 28 // 30 ////////////////////////////////////////////// 29 ////////////////////////////////////////////////////////////// 31 // Class Name: G4AdjointPhysicsMes << 30 // Class Name: G4AdjointPhysicsMessenger 32 // Author: L. Desorgher << 31 // Author: L. Desorgher 33 // Organisation: SpaceIT GmbH << 32 // Organisation: SpaceIT GmbH 34 // Contract: ESA contract 21435/ << 33 // Contract: ESA contract 21435/08/NL/AT 35 // Customer: ESA/ESTEC << 34 // Customer: ESA/ESTEC 36 ////////////////////////////////////////////// 35 ////////////////////////////////////////////////////////////// 37 << 38 //....oooOO0OOooo........oooOO0OOooo........oo << 39 //....oooOO0OOooo........oooOO0OOooo........oo << 40 << 41 #include "G4AdjointPhysicsMessenger.hh" 36 #include "G4AdjointPhysicsMessenger.hh" 42 << 37 #include "G4UIdirectory.hh" 43 #include "G4AdjointPhysicsList.hh" << 44 #include "G4UIcmdWith3VectorAndUnit.hh" << 45 #include "G4UIcmdWithABool.hh" 38 #include "G4UIcmdWithABool.hh" 46 #include "G4UIcmdWithADouble.hh" << 47 #include "G4UIcmdWithADoubleAndUnit.hh" << 48 #include "G4UIcmdWithAString.hh" << 49 #include "G4UIcmdWithAnInteger.hh" 39 #include "G4UIcmdWithAnInteger.hh" >> 40 #include "G4UIcmdWithADoubleAndUnit.hh" >> 41 #include "G4UIcmdWithADouble.hh" 50 #include "G4UIcmdWithoutParameter.hh" 42 #include "G4UIcmdWithoutParameter.hh" 51 #include "G4UIdirectory.hh" << 43 #include "G4UIcmdWithAString.hh" 52 #include "G4UnitsTable.hh" 44 #include "G4UnitsTable.hh" >> 45 #include "G4AdjointPhysicsList.hh" >> 46 #include "G4UIcmdWith3VectorAndUnit.hh" >> 47 /////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////// >> 48 // >> 49 G4AdjointPhysicsMessenger::G4AdjointPhysicsMessenger( >> 50 G4AdjointPhysicsList* pPhysicsList) >> 51 :thePhysicsList(pPhysicsList) >> 52 { >> 53 PhysicsDir = new G4UIdirectory("/adjoint_physics/"); >> 54 PhysicsDir->SetGuidance("Definition of physics processes to be used in the adjoint and forward simulation mode"); >> 55 >> 56 >> 57 >> 58 53 59 54 //....oooOO0OOooo........oooOO0OOooo........oo << 55 60 56 G4AdjointPhysicsMessenger::G4AdjointPhysicsMes << 61 //Physics 57 : G4UImessenger(), << 58 fPhysicsList(pPhysicsList), << 59 fPhysicsDir(0), << 60 fUsepIonisationCmd(0), << 61 fUseBremCmd(0), << 62 fUseComptonCmd(0), << 63 fUseMSCmd(0), << 64 fUsePEEffectCmd(0), << 65 fUseGammaConversionCmd(0), << 66 fUseEgainFluctuationCmd(0), << 67 fSetEminAdjModelsCmd(0), << 68 fSetEmaxAdjModelsCmd(0) << 69 { << 70 fPhysicsDir = new G4UIdirectory("/adjoint_ph << 71 << 72 fPhysicsDir->SetGuidance("Definition of adjo << 73 //------- 62 //------- 74 fUsepIonisationCmd = new G4UIcmdWithABool("/ << 63 75 fUsepIonisationCmd->SetGuidance("If true (fa << 64 /* UseIonisationCmd = new G4UIcmdWithABool("/adjoint_physics/UseElectronIonisation",this); 76 fUsepIonisationCmd->AvailableForStates(G4Sta << 65 UseIonisationCmd->SetGuidance("If true (false) the ionisation is (not) considered for both adjoint and forward simulations"); 77 << 66 UseIonisationCmd->AvailableForStates(G4State_PreInit); 78 fUseBremCmd = new G4UIcmdWithABool("/adjoint << 67 */ 79 fUseBremCmd->SetGuidance("If true (false) th << 68 80 fUseBremCmd->AvailableForStates(G4State_PreI << 69 UsepIonisationCmd = new G4UIcmdWithABool("/adjoint_physics/UseProtonIonisation",this); 81 << 70 UsepIonisationCmd->SetGuidance("If true (false) the proton ionisation is (not) considered for both adjoint and forward simulations"); 82 fUseComptonCmd = new G4UIcmdWithABool("/adjo << 71 UsepIonisationCmd->AvailableForStates(G4State_PreInit); 83 fUseComptonCmd->SetGuidance("If true (false) << 72 84 fUseComptonCmd->AvailableForStates(G4State_P << 73 UseBremCmd = new G4UIcmdWithABool("/adjoint_physics/UseBremsstrahlung",this); 85 << 74 UseBremCmd->SetGuidance("If true (false) the bremsstrahlung process is (not) considered for both adjoint and forward simulations"); 86 fUseMSCmd = new G4UIcmdWithABool("/adjoint_p << 75 UseBremCmd->AvailableForStates(G4State_PreInit); 87 fUseMSCmd->SetGuidance("If true (false) the << 76 88 fUseMSCmd->AvailableForStates(G4State_PreIni << 77 UseComptonCmd = new G4UIcmdWithABool("/adjoint_physics/UseCompton",this); 89 << 78 UseComptonCmd->SetGuidance("If true (false) the Compton scattering is (not) considered for both adjoint and forward simulations"); 90 fUseEgainFluctuationCmd = new G4UIcmdWithABo << 79 UseComptonCmd->AvailableForStates(G4State_PreInit); 91 fUseEgainFluctuationCmd->SetGuidance( << 80 92 "Switch on/off the fluctation for continuo << 81 UseMSCmd = new G4UIcmdWithABool("/adjoint_physics/UseMS",this); 93 fUseEgainFluctuationCmd->AvailableForStates( << 82 UseMSCmd->SetGuidance("If true (false) the continuous multiple scattering is (not) considered for both adjoint and forward simulations"); 94 << 83 UseMSCmd->AvailableForStates(G4State_PreInit); 95 fUsePEEffectCmd = new G4UIcmdWithABool("/adj << 84 96 fUsePEEffectCmd->AvailableForStates(G4State_ << 85 UseEgainFluctuationCmd = new G4UIcmdWithABool("/adjoint_physics/UseEgainElossFluctuation",this); 97 fUsePEEffectCmd->SetGuidance("If true (false << 86 UseEgainFluctuationCmd->SetGuidance("If true (false) the fluctation for continuous energy gain and loss is (not) considered for adjoint and forward simulations"); 98 << 87 UseEgainFluctuationCmd->AvailableForStates(G4State_PreInit); 99 fUseGammaConversionCmd = new G4UIcmdWithABoo << 88 100 fUseGammaConversionCmd->AvailableForStates(G << 89 UsePEEffectCmd = new G4UIcmdWithABool("/adjoint_physics/UsePEEffect",this); 101 fUseGammaConversionCmd->SetGuidance("If true << 90 UsePEEffectCmd->AvailableForStates(G4State_PreInit); 102 << 91 UsePEEffectCmd->SetGuidance("If true (false) the photo electric effect is (not) considered for the adjoint and forward simulations"); 103 fSetEminAdjModelsCmd = << 92 104 new G4UIcmdWithADoubleAndUnit("/adjoint_ph << 93 UseGammaConversionCmd = new G4UIcmdWithABool("/adjoint_physics/UseGammaConversion",this); 105 fSetEminAdjModelsCmd->SetGuidance("Set the m << 94 UseGammaConversionCmd->AvailableForStates(G4State_PreInit); 106 fSetEminAdjModelsCmd->SetParameterName("Emin << 95 UseGammaConversionCmd->SetGuidance("If true the gamma pair conversion is considered as weel as the e+ physics for the forward simulation"); 107 fSetEminAdjModelsCmd->SetUnitCategory("Energ << 96 108 fSetEminAdjModelsCmd->AvailableForStates(G4S << 97 SetEminAdjModelsCmd = new G4UIcmdWithADoubleAndUnit("/adjoint_physics/SetEminForAdjointModels",this); 109 << 98 SetEminAdjModelsCmd->SetGuidance("Set the minimum energy of the adjoint models"); 110 fSetEmaxAdjModelsCmd = << 99 SetEminAdjModelsCmd->SetParameterName("Emin",false); 111 new G4UIcmdWithADoubleAndUnit("/adjoint_ph << 100 SetEminAdjModelsCmd->SetUnitCategory("Energy"); 112 fSetEmaxAdjModelsCmd->SetGuidance("Set the m << 101 SetEminAdjModelsCmd->AvailableForStates(G4State_PreInit); 113 fSetEmaxAdjModelsCmd->SetParameterName("Emax << 102 114 fSetEmaxAdjModelsCmd->SetUnitCategory("Energ << 103 SetEmaxAdjModelsCmd = new G4UIcmdWithADoubleAndUnit("/adjoint_physics/SetEmaxForAdjointModels",this); 115 fSetEmaxAdjModelsCmd->AvailableForStates(G4S << 104 SetEmaxAdjModelsCmd->SetGuidance("Set the minimum energy of the adjoint models."); >> 105 SetEmaxAdjModelsCmd->SetParameterName("Emax",false); >> 106 SetEmaxAdjModelsCmd->SetUnitCategory("Energy"); >> 107 SetEmaxAdjModelsCmd->AvailableForStates(G4State_PreInit); >> 108 /* >> 109 #ifdef TEST_MODE >> 110 SetCSBiasingFactorComptonCmd = new G4UIcmdWithADouble("/adjoint_physics/SetCSBiasingFactorForCompton",this); >> 111 SetCSBiasingFactorComptonCmd->SetGuidance("Set the CS biading factor for the adjoint Compton Cross section"); >> 112 SetCSBiasingFactorComptonCmd->SetParameterName("biasing_factor",false); >> 113 SetCSBiasingFactorComptonCmd->AvailableForStates(G4State_PreInit); >> 114 >> 115 SetCSBiasingFactorBremCmd = new G4UIcmdWithADouble("/adjoint_physics/SetCSBiasingFactorForBrem",this); >> 116 SetCSBiasingFactorBremCmd->SetGuidance("Set the CS biading factor for the adjoint Brem Cross section"); >> 117 SetCSBiasingFactorBremCmd->SetParameterName("biasing_factor",false); >> 118 SetCSBiasingFactorBremCmd->AvailableForStates(G4State_PreInit); >> 119 >> 120 SetCSBiasingFactorIonisationCmd = new G4UIcmdWithADouble("/adjoint_physics/SetCSBiasingFactorForIonisation",this); >> 121 SetCSBiasingFactorIonisationCmd->SetGuidance("Set the CS biading factor for the adjoint Ionisation Cross section"); >> 122 SetCSBiasingFactorIonisationCmd->SetParameterName("biasing_factor",false); >> 123 SetCSBiasingFactorIonisationCmd->AvailableForStates(G4State_PreInit); >> 124 >> 125 SetCSBiasingFactorPEeffectCmd = new G4UIcmdWithADouble("/adjoint_physics/SetCSBiasingFactorForPEeffect",this); >> 126 SetCSBiasingFactorPEeffectCmd->SetGuidance("Set the CS biading factor for the adjoint PEeffect Cross section"); >> 127 SetCSBiasingFactorPEeffectCmd->SetParameterName("biasing_factor",false); >> 128 SetCSBiasingFactorPEeffectCmd->AvailableForStates(G4State_PreInit); >> 129 >> 130 >> 131 #endif >> 132 */ >> 133 >> 134 >> 135 >> 136 >> 137 116 } 138 } 117 139 118 //....oooOO0OOooo........oooOO0OOooo........oo << 140 /////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////// >> 141 // 119 142 120 G4AdjointPhysicsMessenger::~G4AdjointPhysicsMe 143 G4AdjointPhysicsMessenger::~G4AdjointPhysicsMessenger() 121 { 144 { 122 delete fUsepIonisationCmd; << 145 123 delete fUseBremCmd; << 146 124 delete fUseComptonCmd; << 147 125 delete fUseMSCmd; << 126 delete fUsePEEffectCmd; << 127 delete fUseGammaConversionCmd; << 128 delete fUseEgainFluctuationCmd; << 129 delete fSetEminAdjModelsCmd; << 130 delete fSetEmaxAdjModelsCmd; << 131 } 148 } 132 149 133 //....oooOO0OOooo........oooOO0OOooo........oo << 150 /////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////// >> 151 // 134 152 135 void G4AdjointPhysicsMessenger::SetNewValue(G4 << 153 void G4AdjointPhysicsMessenger::SetNewValue(G4UIcommand* command,G4String newValue) 136 { 154 { 137 if (command == fUsepIonisationCmd) { << 155 138 fPhysicsList->SetUseProtonIonisation(fUsep << 156 >> 157 >> 158 if ( command==UsepIonisationCmd){ >> 159 thePhysicsList->SetUseProtonIonisation(UsepIonisationCmd->GetNewBoolValue(newValue)); >> 160 139 } 161 } 140 else if (command == fUseBremCmd) { << 162 else if ( command==UseBremCmd){ 141 fPhysicsList->SetUseBrem(fUseBremCmd->GetN << 163 thePhysicsList->SetUseBrem(UseBremCmd->GetNewBoolValue(newValue)); 142 } 164 } 143 else if (command == fUseComptonCmd) { << 165 else if ( command==UseComptonCmd){ 144 fPhysicsList->SetUseCompton(fUseComptonCmd << 166 thePhysicsList->SetUseCompton(UseComptonCmd->GetNewBoolValue(newValue)); 145 } 167 } 146 else if (command == fUseMSCmd) { << 168 else if ( command==UseMSCmd){ 147 fPhysicsList->SetUseMS(fUseMSCmd->GetNewBo << 169 thePhysicsList->SetUseMS(UseMSCmd->GetNewBoolValue(newValue)); 148 } 170 } 149 else if (command == fUsePEEffectCmd) { << 171 else if ( command==UsePEEffectCmd){ 150 fPhysicsList->SetUsePEEffect(fUsePEEffectC << 172 thePhysicsList->SetUsePEEffect(UsePEEffectCmd->GetNewBoolValue(newValue)); 151 } 173 } 152 else if (command == fUseGammaConversionCmd) << 174 else if ( command==UseGammaConversionCmd){ 153 fPhysicsList->SetUseGammaConversion(fUseGa << 175 thePhysicsList->SetUseGammaConversion(UseGammaConversionCmd->GetNewBoolValue(newValue)); 154 } 176 } 155 else if (command == fUseEgainFluctuationCmd) << 177 else if ( command==UseEgainFluctuationCmd){ 156 fPhysicsList->SetUseEgainFluctuation(fUseE << 178 thePhysicsList->SetUseEgainFluctuation(UseEgainFluctuationCmd->GetNewBoolValue(newValue)); 157 } 179 } 158 180 159 else if (command == fSetEminAdjModelsCmd) { << 181 else if ( command== SetEminAdjModelsCmd){ 160 fPhysicsList->SetEminAdjModels(fSetEminAdj << 182 thePhysicsList->SetEminAdjModels(SetEminAdjModelsCmd->GetNewDoubleValue(newValue)); >> 183 } >> 184 else if ( command== SetEmaxAdjModelsCmd){ >> 185 thePhysicsList->SetEmaxAdjModels(SetEmaxAdjModelsCmd->GetNewDoubleValue(newValue)); >> 186 } >> 187 /* >> 188 #ifdef TEST_MODE >> 189 else if ( command== SetCSBiasingFactorComptonCmd){ >> 190 thePhysicsList->SetCSBiasingFactorCompton(SetCSBiasingFactorComptonCmd->GetNewDoubleValue(newValue)); 161 } 191 } 162 else if (command == fSetEmaxAdjModelsCmd) { << 192 else if ( command== SetCSBiasingFactorBremCmd){ 163 fPhysicsList->SetEmaxAdjModels(fSetEmaxAdj << 193 thePhysicsList->SetCSBiasingFactorBrem(SetCSBiasingFactorBremCmd->GetNewDoubleValue(newValue)); 164 } 194 } >> 195 else if ( command== SetCSBiasingFactorIonisationCmd){ >> 196 thePhysicsList->SetCSBiasingFactorIonisation(SetCSBiasingFactorIonisationCmd->GetNewDoubleValue(newValue)); >> 197 } >> 198 else if ( command== SetCSBiasingFactorPEeffectCmd){ >> 199 thePhysicsList->SetCSBiasingFactorPEeffect(SetCSBiasingFactorPEeffectCmd->GetNewDoubleValue(newValue)); >> 200 } >> 201 >> 202 >> 203 #endif >> 204 */ >> 205 165 } 206 } 166 207 167 //....oooOO0OOooo........oooOO0OOooo........oo << 168 208