| Geant4 Cross Reference |
1 // 1 //
2 // ******************************************* 2 // ********************************************************************
3 // * License and Disclaimer 3 // * License and Disclaimer *
4 // * 4 // * *
5 // * The Geant4 software is copyright of th 5 // * The Geant4 software is copyright of the Copyright Holders of *
6 // * the Geant4 Collaboration. It is provided 6 // * the Geant4 Collaboration. It is provided under the terms and *
7 // * conditions of the Geant4 Software License 7 // * conditions of the Geant4 Software License, included in the file *
8 // * LICENSE and available at http://cern.ch/ 8 // * LICENSE and available at http://cern.ch/geant4/license . These *
9 // * include a list of copyright holders. 9 // * include a list of copyright holders. *
10 // * 10 // * *
11 // * Neither the authors of this software syst 11 // * Neither the authors of this software system, nor their employing *
12 // * institutes,nor the agencies providing fin 12 // * institutes,nor the agencies providing financial support for this *
13 // * work make any representation or warran 13 // * work make any representation or warranty, express or implied, *
14 // * regarding this software system or assum 14 // * regarding this software system or assume any liability for its *
15 // * use. Please see the license in the file 15 // * use. 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 // G4ParticleDefinition inline methods impleme <<
27 // 26 //
28 // Authors: G.Cosmo, 2 December 1995 - Design, << 27 // $Id$
29 // M.Asai, 29 January 1996 - First im << 28 //
30 // ------------------------------------------- <<
31 <<
32 inline G4int G4ParticleDefinition::GetInstance <<
33 { <<
34 return g4particleDefinitionInstanceID; <<
35 } <<
36 <<
37 inline G4bool G4ParticleDefinition::GetPDGStab <<
38 { <<
39 if (IsGeneralIon()) { <<
40 return (GetIonLifeTime() < 0.); <<
41 } <<
42 <<
43 return thePDGStable; <<
44 } <<
45 <<
46 inline G4double G4ParticleDefinition::GetPDGLi <<
47 { <<
48 return thePDGLifeTime; <<
49 } <<
50 <<
51 inline G4double G4ParticleDefinition::GetIonLi <<
52 { <<
53 //-- No longer needed to access to G4IonTabl <<
54 //-- Method GetIonLifeTime() itself is kept <<
55 29
56 return thePDGLifeTime; << 30 inline
>> 31 G4ParticleTable* G4ParticleDefinition::GetParticleTable() const
>> 32 {
>> 33 return theParticleTable;
57 } 34 }
58 35
59 inline G4ParticleTable* G4ParticleDefinition:: << 36 inline
60 { << 37 G4DecayTable* G4ParticleDefinition::GetDecayTable() const
61 return theParticleTable; << 38 {
>> 39 return theDecayTable;
62 } 40 }
63 41
64 inline G4DecayTable* G4ParticleDefinition::Get << 42 inline
65 { << 43 void G4ParticleDefinition::SetDecayTable(G4DecayTable* aDecayTable)
66 return theDecayTable; << 44 {
>> 45 theDecayTable = aDecayTable;
67 } 46 }
68 47
69 inline void G4ParticleDefinition::SetDecayTabl <<
70 { <<
71 theDecayTable = aDecayTable; <<
72 } <<
73 48
74 inline void G4ParticleDefinition::SetVerboseLe << 49 inline
>> 50 void G4ParticleDefinition::SetVerboseLevel(G4int value)
75 { 51 {
76 verboseLevel = value; << 52 verboseLevel = value;
77 } 53 }
78 54
79 inline G4int G4ParticleDefinition::GetVerboseL << 55 inline
>> 56 G4int G4ParticleDefinition::GetVerboseLevel() const
80 { 57 {
81 return verboseLevel; << 58 return verboseLevel;
82 } 59 }
83 60
84 inline G4ProcessManager* G4ParticleDefinition: << 61 inline
>> 62 G4ProcessManager* G4ParticleDefinition::GetProcessManager() const
85 { 63 {
86 return theProcessManagerShadow; << 64 return theProcessManager;
87 } 65 }
88 66
89 inline void G4ParticleDefinition::SetMasterPro << 67 inline
>> 68 void G4ParticleDefinition::SetProcessManager(G4ProcessManager *aProcessManager)
90 { 69 {
91 theProcessManagerShadow = aNewPM; << 70 theProcessManager = aProcessManager;
92 } 71 }
93 72
94 inline G4int G4ParticleDefinition::GetQuarkCon << 73 inline
>> 74 G4int G4ParticleDefinition::GetQuarkContent(G4int flavor) const
95 { 75 {
96 G4int content = 0; << 76 G4int content = 0;
97 if ((flavor > 0) && (flavor <= NumberOfQuark << 77 if ((flavor>0) && (flavor<=NumberOfQuarkFlavor)){
98 content = theQuarkContent[flavor - 1]; << 78 content = theQuarkContent[flavor-1];
99 } << 79 }else {
100 else { <<
101 #ifdef G4VERBOSE 80 #ifdef G4VERBOSE
102 if (verboseLevel > 0) { << 81 if (verboseLevel >0) {
103 std::ostringstream message; << 82 G4cout << "Invalid Quark Flavor for G4ParticleDefinition::GetQuarkContent";
104 message << "Invalid Quark Flavor: " << f << 83 G4cout << ": flavor=" << flavor <<G4endl;
105 G4Exception("G4ParticleDefinition::GetQu << 84 }
106 } << 85 #endif
107 #endif <<
108 } 86 }
109 return content; << 87 return content;
110 } 88 }
111 89
112 inline G4int G4ParticleDefinition::GetAntiQuar << 90 inline
>> 91 G4int G4ParticleDefinition::GetAntiQuarkContent(G4int flavor) const
113 { 92 {
114 G4int content = 0; 93 G4int content = 0;
115 if ((flavor > 0) && (flavor <= NumberOfQuark << 94 if ((flavor>0) && (flavor<=NumberOfQuarkFlavor)){
116 content = theAntiQuarkContent[flavor - 1]; << 95 content = theAntiQuarkContent[flavor-1];
117 } << 96 }else {
118 else { <<
119 #ifdef G4VERBOSE 97 #ifdef G4VERBOSE
120 if (verboseLevel > 0) { << 98 if (verboseLevel >0) {
121 std::ostringstream message; << 99 G4cout <<"Invalid Quark Flavor for G4ParticleDefinition::GetAntiQuarkContent";
122 message << "Invalid Quark Flavor: " << f << 100 G4cout << ": flavor=" << flavor <<G4endl;
123 G4Exception("G4ParticleDefinition::GetAn <<
124 message); <<
125 } 101 }
126 #endif 102 #endif
127 } << 103 }
128 return content; 104 return content;
129 } 105 }
130 106
131 inline void G4ParticleDefinition::SetParticleS << 107
>> 108 inline
>> 109 void G4ParticleDefinition::SetParticleSubType(const G4String& subtype)
132 { 110 {
133 theParticleSubType = subtype; 111 theParticleSubType = subtype;
134 } 112 }
135 << 113
136 inline void G4ParticleDefinition::SetAntiPDGEn << 114 inline
137 { << 115 void G4ParticleDefinition::SetAntiPDGEncoding(G4int aEncoding)
138 theAntiPDGEncoding = aEncoding; << 116 {
>> 117 theAntiPDGEncoding = aEncoding;
139 } 118 }
140 119
141 inline G4bool G4ParticleDefinition::GetApplyCu << 120 inline
>> 121 G4bool G4ParticleDefinition::GetApplyCutsFlag() const
142 { 122 {
143 return fApplyCutsFlag; 123 return fApplyCutsFlag;
144 } 124 }
145 125
146 inline void G4ParticleDefinition::SetAtomicNum << 126 inline
>> 127 void G4ParticleDefinition::SetAtomicNumber(G4int i)
147 { 128 {
148 theAtomicNumber = i; 129 theAtomicNumber = i;
149 } 130 }
150 131
151 inline G4int G4ParticleDefinition::GetAtomicNu << 132 inline
>> 133 G4int G4ParticleDefinition::GetAtomicNumber() const
152 { 134 {
153 return theAtomicNumber; 135 return theAtomicNumber;
154 } 136 }
155 137
156 inline void G4ParticleDefinition::SetAtomicMas << 138 inline
>> 139 void G4ParticleDefinition::SetAtomicMass(G4int i)
157 { 140 {
158 theAtomicMass = i; 141 theAtomicMass = i;
159 } 142 }
160 143
161 inline G4int G4ParticleDefinition::GetAtomicMa << 144 inline
>> 145 G4int G4ParticleDefinition::GetAtomicMass() const
162 { 146 {
163 return theAtomicMass; 147 return theAtomicMass;
164 } 148 }
165 149
166 inline void G4ParticleDefinition::SetPDGMagnet << 150 inline
167 { << 151 void G4ParticleDefinition::SetPDGMagneticMoment(G4double magneticMoment)
168 thePDGMagneticMoment = magneticMoment; <<
169 } <<
170 <<
171 inline G4bool G4ParticleDefinition::IsGeneralI <<
172 { <<
173 return isGeneralIon; <<
174 } <<
175 <<
176 inline G4bool G4ParticleDefinition::IsMuonicAt <<
177 { <<
178 return isMuonicAtom; <<
179 } <<
180 <<
181 inline G4int G4ParticleDefinition::GetParticle <<
182 { <<
183 return g4particleDefinitionInstanceID; <<
184 } <<
185 <<
186 inline G4bool G4ParticleDefinition::IsHypernuc <<
187 { <<
188 return GetNumberOfLambdasInHypernucleus() > <<
189 } <<
190 <<
191 inline G4int G4ParticleDefinition::GetNumberOf <<
192 { <<
193 G4int numberOfLambdas = 0; <<
194 // PDG code of hypernuclei: 10LZZZAAAI <<
195 if (thePDGEncoding > 0 && thePDGEncoding / 1 <<
196 numberOfLambdas = (thePDGEncoding / 100000 <<
197 } <<
198 return numberOfLambdas; <<
199 } <<
200 <<
201 inline G4bool G4ParticleDefinition::IsAntiHype <<
202 { 152 {
203 return GetNumberOfAntiLambdasInAntiHypernucl << 153 thePDGMagneticMoment = magneticMoment;
204 } 154 }
205 155
206 inline G4int G4ParticleDefinition::GetNumberOf << 156 inline
>> 157 G4double G4ParticleDefinition::CalculateAnomaly() const
207 { 158 {
208 G4int numberOfAntiLambdas = 0; << 159 // gives the anomaly of magnetic moment for spin 1/2 particles
209 // PDG code of anti-hypernuclei: -10LZZZAAAI << 160 if (thePDGiSpin==1) {
210 if (thePDGEncoding < 0 && thePDGEncoding / 1 << 161 G4double muB = 0.5*CLHEP::eplus*CLHEP::hbar_Planck/(thePDGMass/CLHEP::c_squared);
211 numberOfAntiLambdas = (std::abs(thePDGEnco << 162 return 0.5*std::fabs(thePDGMagneticMoment/muB - 2.*thePDGCharge/CLHEP::eplus);
212 } << 163 } else {
213 return numberOfAntiLambdas; << 164 return 0.0;
>> 165 }
214 } 166 }
215 167