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>> 1 // This code implementation is the intellectual property of >> 2 // the GEANT4 collaboration. 1 // 3 // 2 // ******************************************* << 4 // By copying, distributing or modifying the Program (or any work 3 // * License and Disclaimer << 5 // based on the Program) you indicate your acceptance of this statement, 4 // * << 6 // and all its terms. 5 // * The Geant4 software is copyright of th << 7 // 6 // * the Geant4 Collaboration. It is provided << 8 // $Id: G4ParticleChangeForDecay.hh,v 1.4 1999/11/07 16:31:59 kurasige Exp $ 7 // * conditions of the Geant4 Software License << 9 // GEANT4 tag $Name: geant4-02-00 $ 8 // * LICENSE and available at http://cern.ch/ << 10 // 9 // * include a list of copyright holders. << 11 // 10 // * << 12 // ------------------------------------------------------------ 11 // * Neither the authors of this software syst << 13 // GEANT 4 class header file 12 // * institutes,nor the agencies providing fin << 14 // 13 // * work make any representation or warran << 15 // For information related to this code contact: 14 // * regarding this software system or assum << 16 // CERN, CN Division, ASD group 15 // * use. Please see the license in the file << 17 // 16 // * for the full disclaimer and the limitatio << 18 // ------------------------------------------------------------ 17 // * << 19 // Implemented for the new scheme 23 Mar. 1998 H.Kurahige 18 // * This code implementation is the result << 20 // 19 // * technical work of the GEANT4 collaboratio << 21 // Class Description 20 // * By using, copying, modifying or distri << 22 // This class is a concrete class for ParticleChange which 21 // * any work based on the software) you ag << 23 // has functionality for G4Decay. 22 // * use in resulting scientific publicati << 24 // 23 // * acceptance of all terms of the Geant4 Sof << 25 // This class contains the results after invocation of the decay process. 24 // ******************************************* << 26 // This includes secondary particles generated by the interaction. 25 // << 27 // ------------------------------------------------------------ 26 // G4ParticleChangeForDecay << 28 #ifndef G4ParticleChangeForDecay_h 27 // << 29 #define G4ParticleChangeForDecay_h 1 28 // Class description: << 29 // << 30 // Concrete class for ParticleChange which has << 31 // << 32 // This class contains the results after invoc << 33 // This includes secondary particles generated << 34 << 35 // Author: Hisaya Kurashige, 23 March 1998 << 36 // ------------------------------------------- << 37 #ifndef G4ParticleChangeForDecay_hh << 38 #define G4ParticleChangeForDecay_hh 1 << 39 30 40 #include "globals.hh" 31 #include "globals.hh" 41 #include "G4ios.hh" 32 #include "G4ios.hh" 42 #include "G4ThreeVector.hh" 33 #include "G4ThreeVector.hh" 43 #include "G4VParticleChange.hh" << 44 << 45 class G4DynamicParticle; 34 class G4DynamicParticle; >> 35 #include "G4VParticleChange.hh" 46 36 47 class G4ParticleChangeForDecay final : public << 37 class G4ParticleChangeForDecay: public G4VParticleChange 48 { 38 { 49 public: << 39 public: 50 << 40 // default constructor 51 G4ParticleChangeForDecay(); 41 G4ParticleChangeForDecay(); 52 42 53 ~G4ParticleChangeForDecay() override = def << 43 // destructor >> 44 virtual ~G4ParticleChangeForDecay(); 54 45 55 G4ParticleChangeForDecay(const G4ParticleC << 46 protected: 56 G4ParticleChangeForDecay& operator=(const << 47 // hide copy constructor and assignment operaor as protected >> 48 G4ParticleChangeForDecay(const G4ParticleChangeForDecay &right); >> 49 G4ParticleChangeForDecay & operator=(const G4ParticleChangeForDecay &right); 57 50 58 // --- the following methods are for updatin << 51 public: 59 // Return the pointer to the G4Step after up << 52 // equal/unequal operator 60 // by using final state information of the t << 53 G4bool operator==(const G4ParticleChangeForDecay &right) const; 61 // !!! No effect for AlongSteyp << 54 G4bool operator!=(const G4ParticleChangeForDecay &right) const; >> 55 >> 56 public: // with description >> 57 // ---------------------------------------------------- >> 58 // --- the following methods are for updating G4Step ----- >> 59 // Return the pointer to the G4Step after updating the Step information >> 60 // by using final state information of the track given by a physics >> 61 // process >> 62 >> 63 // !!! No effect for AlongSteyp >> 64 // virtual G4Step* UpdateStepForAlongStep(G4Step* Step); >> 65 >> 66 virtual G4Step* UpdateStepForAtRest(G4Step* Step); >> 67 virtual G4Step* UpdateStepForPostStep(G4Step* Step); >> 68 >> 69 virtual void Initialize(const G4Track&); >> 70 // Initialize all propoerties by using G4Track information >> 71 >> 72 G4double GetTimeChange() const; >> 73 void SetTimeChange(G4double t); >> 74 // Get/Set theTimeChange vector. 62 75 63 G4Step* UpdateStepForAtRest(G4Step* Step) << 76 public: 64 G4Step* UpdateStepForPostStep(G4Step* Step << 77 virtual void DumpInfo() const; 65 78 66 void Initialize(const G4Track&) final; << 79 protected: 67 // Initialize all properties by using G4 << 80 G4double theTimeChange; >> 81 // The change of global time of a given particle. >> 82 >> 83 public: >> 84 // for Debug >> 85 virtual G4bool CheckIt(const G4Track&); >> 86 }; 68 87 69 void ProposeGlobalTime(G4double t); << 88 inline 70 void ProposeLocalTime(G4double t); << 89 G4double G4ParticleChangeForDecay::GetTimeChange() const 71 // Get/Propose the final global/local ti << 90 { 72 // NOTE: DO NOT INVOKE both methods in a << 91 return theTimeChange; 73 // Each method affects both local << 92 } 74 93 75 G4double GetGlobalTime(G4double timeDelay << 94 inline 76 G4double GetLocalTime(G4double timeDelay = << 95 void G4ParticleChangeForDecay::SetTimeChange(G4double t) 77 // Convert the time delay to the glocbal << 96 { 78 // Can get the final global/local time << 97 theTimeChange = t; >> 98 } 79 99 80 const G4ThreeVector* GetPolarization() con << 81 void ProposePolarization(G4double Px, G4do << 82 void ProposePolarization(const G4ThreeVect << 83 // Get/Propose the final Polarization ve << 84 100 85 // --- Dump and debug methods --- << 101 #endif >> 102 86 103 87 void DumpInfo() const final; << 88 104 89 G4bool CheckIt(const G4Track&) final; << 90 105 91 private: << 92 106 93 G4double theGlobalTime0 = 0.0; << 94 // The global time at Initial << 95 G4double theLocalTime0 = 0.0; << 96 // The local time at Initial << 97 107 98 G4double theTimeChange = 0.0; << 99 // The change of local time of a given p << 100 108 101 G4ThreeVector thePolarizationChange; << 102 // The changed (final) polarization of a << 103 }; << 104 109 105 // ---------------------- << 106 // Inline methods << 107 // ---------------------- << 108 110 109 inline << 110 void G4ParticleChangeForDecay::ProposeGlobalTi << 111 { << 112 theTimeChange = (t - theGlobalTime0) + theLo << 113 } << 114 111 115 inline << 116 G4double G4ParticleChangeForDecay::GetGlobalTi << 117 { << 118 // Convert the time delay to the global tim << 119 return theGlobalTime0 + (theTimeChange - the << 120 } << 121 112 122 inline << 123 void G4ParticleChangeForDecay::ProposeLocalTim << 124 { << 125 theTimeChange = t; << 126 } << 127 113 128 inline << 129 G4double G4ParticleChangeForDecay::GetLocalTim << 130 { << 131 // Convert the time delay to the local time << 132 return theTimeChange + timeDelay; << 133 } << 134 114 135 inline << 136 const G4ThreeVector* G4ParticleChangeForDecay: << 137 { << 138 return &thePolarizationChange; << 139 } << 140 115 141 inline << 142 void G4ParticleChangeForDecay::ProposePolariza << 143 const G4ThreeVector& finalPoralization) << 144 { << 145 thePolarizationChange = finalPoralization; << 146 } << 147 116 148 inline << 149 void G4ParticleChangeForDecay::ProposePolariza << 150 << 151 << 152 { << 153 thePolarizationChange.setX(Px); << 154 thePolarizationChange.setY(Py); << 155 thePolarizationChange.setZ(Pz); << 156 } << 157 117 158 #endif << 159 118