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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 // << 27 // // 28 // GEANT4 Class source file << 28 // File: G4RadioactivationMessenger.cc // 29 // << 29 // Author: D.H. Wright (SLAC) // 30 // G4RadioactivationMessenger << 30 // Date: 29 August 2017 // 31 // << 31 // Description: messenger class for biased version of G4RadioactiveDecay. // 32 // Author: D.H. Wright (SLAC) << 32 // Based on the code of F. Lei and P.R. Truscott. // 33 // Date: 29 August 2017 << 33 // // 34 // << 35 // Based on the code of F. Lei and P.R. Trusc << 36 // << 37 ////////////////////////////////////////////// 34 //////////////////////////////////////////////////////////////////////////////// 38 35 39 #include "G4RadioactivationMessenger.hh" 36 #include "G4RadioactivationMessenger.hh" 40 #include "G4NuclearLevelData.hh" 37 #include "G4NuclearLevelData.hh" 41 #include "G4RadioactiveDecay.hh" << 42 << 43 #include <sstream> 38 #include <sstream> 44 #include "G4HadronicException.hh" << 45 39 46 40 47 G4RadioactivationMessenger::G4RadioactivationM << 41 G4RadioactivationMessenger::G4RadioactivationMessenger(G4Radioactivation* theRadioactivationContainer1) 48 :theRadDecay(ptr) << 42 :theRadioactivationContainer(theRadioactivationContainer1) 49 { 43 { 50 rdmDirectory = new G4UIdirectory("/process/h << 44 grdmDirectory = new G4UIdirectory("/grdm/"); 51 rdmDirectory->SetGuidance("Controls the bias << 45 grdmDirectory->SetGuidance("Controls the biased version of radioactive decay"); 52 46 53 // Command to turn on/off variance reduction 47 // Command to turn on/off variance reduction options 54 analoguemcCmd = new G4UIcmdWithABool("/proce << 48 analoguemcCmd = new G4UIcmdWithABool ("/grdm/analogueMC",this); 55 analoguemcCmd->SetGuidance("false: variance 49 analoguemcCmd->SetGuidance("false: variance reduction method; true: analogue method"); 56 analoguemcCmd->SetParameterName("AnalogueMC" 50 analoguemcCmd->SetParameterName("AnalogueMC",true); 57 analoguemcCmd->SetDefaultValue(true); 51 analoguemcCmd->SetDefaultValue(true); 58 << 52 59 // Command to use branching ratio biasing or 53 // Command to use branching ratio biasing or not 60 brbiasCmd = new G4UIcmdWithABool("/process/h << 54 brbiasCmd = new G4UIcmdWithABool ("/grdm/BRbias",this); 61 brbiasCmd->SetGuidance("false: no biasing; t 55 brbiasCmd->SetGuidance("false: no biasing; true: all branches are treated as equal"); 62 brbiasCmd->SetParameterName("BRBias",true); 56 brbiasCmd->SetParameterName("BRBias",true); 63 brbiasCmd->SetDefaultValue(true); 57 brbiasCmd->SetDefaultValue(true); 64 << 58 65 // Command to set the half-life thresold for 59 // Command to set the half-life thresold for isomer production 66 hlthCmd = new G4UIcmdWithADoubleAndUnit("/pr << 60 hlthCmd = new G4UIcmdWithADoubleAndUnit("/grdm/hlThreshold",this); 67 hlthCmd->SetGuidance("Set the h-l threshold 61 hlthCmd->SetGuidance("Set the h-l threshold for isomer production"); 68 hlthCmd->SetParameterName("hlThreshold",fals 62 hlthCmd->SetParameterName("hlThreshold",false); 69 hlthCmd->SetUnitCategory("Time"); 63 hlthCmd->SetUnitCategory("Time"); 70 << 64 71 // Command to define the incident particle s 65 // Command to define the incident particle source time profile 72 sourcetimeprofileCmd = new G4UIcmdWithAStrin << 66 sourcetimeprofileCmd = new G4UIcmdWithAString("/grdm/sourceTimeProfile",this); 73 sourcetimeprofileCmd->SetGuidance 67 sourcetimeprofileCmd->SetGuidance 74 ("Supply the name of the ascii file contai 68 ("Supply the name of the ascii file containing the source particle time profile"); 75 sourcetimeprofileCmd->SetParameterName("STim 69 sourcetimeprofileCmd->SetParameterName("STimeProfile",true); 76 sourcetimeprofileCmd->SetDefaultValue("sourc 70 sourcetimeprofileCmd->SetDefaultValue("source.data"); 77 << 71 78 // Command to define the incident particle s 72 // Command to define the incident particle source time profile 79 decaybiasprofileCmd = new G4UIcmdWithAString << 73 decaybiasprofileCmd = new G4UIcmdWithAString("/grdm/decayBiasProfile",this); 80 decaybiasprofileCmd->SetGuidance 74 decaybiasprofileCmd->SetGuidance 81 ("Supply the name of the ascii file contai 75 ("Supply the name of the ascii file containing the decay bias time profile"); 82 decaybiasprofileCmd->SetParameterName("DBias 76 decaybiasprofileCmd->SetParameterName("DBiasProfile",true); 83 decaybiasprofileCmd->SetDefaultValue("bias.d 77 decaybiasprofileCmd->SetDefaultValue("bias.data"); 84 << 78 85 // Command to set nuclei splitting parameter << 79 // Command to set nuclei spliting parameter 86 splitnucleiCmd = new G4UIcmdWithAnInteger("/ << 80 splitnucleiCmd = new G4UIcmdWithAnInteger("/grdm/splitNuclei",this); 87 splitnucleiCmd->SetGuidance("Set number of s << 81 splitnucleiCmd->SetGuidance("Set number of spliting for the isotopes."); 88 splitnucleiCmd->SetParameterName("NSplit",tr 82 splitnucleiCmd->SetParameterName("NSplit",true); 89 splitnucleiCmd->SetDefaultValue(1); 83 splitnucleiCmd->SetDefaultValue(1); 90 splitnucleiCmd->SetRange("NSplit>=1"); 84 splitnucleiCmd->SetRange("NSplit>=1"); 91 } 85 } 92 86 93 87 94 G4RadioactivationMessenger::~G4Radioactivation 88 G4RadioactivationMessenger::~G4RadioactivationMessenger() 95 { 89 { 96 delete rdmDirectory; << 90 delete grdmDirectory; 97 delete analoguemcCmd; 91 delete analoguemcCmd; 98 delete sourcetimeprofileCmd; 92 delete sourcetimeprofileCmd; 99 delete decaybiasprofileCmd; 93 delete decaybiasprofileCmd; 100 delete brbiasCmd; 94 delete brbiasCmd; 101 delete splitnucleiCmd; 95 delete splitnucleiCmd; 102 delete hlthCmd; 96 delete hlthCmd; 103 } 97 } 104 98 105 99 106 void G4RadioactivationMessenger::SetNewValue(G 100 void G4RadioactivationMessenger::SetNewValue(G4UIcommand* command, G4String newValues) 107 { 101 { 108 if ( command == analoguemcCmd ) { theRadDeca << 102 if (command==analoguemcCmd) {theRadioactivationContainer-> 109 SetAnalogueMonteCarlo( analoguemcCmd->GetN << 103 SetAnalogueMonteCarlo(analoguemcCmd->GetNewBoolValue(newValues)); 110 } else if ( command == brbiasCmd ) { theRadD << 104 111 SetBRBias( brbiasCmd->GetNewBoolValue( new << 105 } else if (command==brbiasCmd) {theRadioactivationContainer-> 112 } else if ( command == sourcetimeprofileCmd << 106 SetBRBias(brbiasCmd->GetNewBoolValue(newValues)); 113 SetSourceTimeProfile( newValues ); << 107 114 } else if ( command == decaybiasprofileCmd ) << 108 } else if (command==sourcetimeprofileCmd) {theRadioactivationContainer-> 115 SetDecayBias( newValues ); << 109 SetSourceTimeProfile(newValues); 116 } else if ( command == splitnucleiCmd ) { th << 110 117 SetSplitNuclei( splitnucleiCmd->GetNewIntV << 111 } else if (command==decaybiasprofileCmd) {theRadioactivationContainer-> 118 } else if ( command == hlthCmd ) { theRadDec << 112 SetDecayBias(newValues); 119 SetHLThreshold( hlthCmd->GetNewDoubleValue << 113 >> 114 } else if (command==splitnucleiCmd) {theRadioactivationContainer-> >> 115 SetSplitNuclei(splitnucleiCmd->GetNewIntValue(newValues)); >> 116 >> 117 } else if (command==hlthCmd ) {theRadioactivationContainer-> >> 118 SetHLThreshold(hlthCmd->GetNewDoubleValue(newValues)); 120 } 119 } 121 } 120 } 122 121 123 122