Geant4-11
G4ParticleHPProduct.hh
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27// P. Arce, June-2014 Conversion neutron_hp to particle_hp
28//
29#ifndef G4ParticleHPProduct_h
30#define G4ParticleHPProduct_h 1
31
32#include "G4HadronicException.hh"
33#include "globals.hh"
34#include "G4ParticleHPVector.hh"
35#include "Randomize.hh"
36#include "G4ios.hh"
37#include <fstream>
38#include "globals.hh"
39#include "G4VParticleHPEnergyAngular.hh"
40#include "G4ReactionProductVector.hh"
41
42#include "G4ParticleHPContEnergyAngular.hh"
43#include "G4ParticleHPDiscreteTwoBody.hh"
44#include "G4ParticleHPIsotropic.hh"
45#include "G4ParticleHPNBodyPhaseSpace.hh"
46#include "G4ParticleHPLabAngularEnergy.hh"
47#include "G4Cache.hh"
48class G4ParticleDefinition;
49
50enum G4HPMultiMethod { G4HPMultiPoisson, G4HPMultiBetweenInts };
51
52class G4ParticleHPProduct
53{
54 struct toBeCached
55 {
56 G4ReactionProduct* theProjectileRP;
57 G4ReactionProduct* theTarget;
58 G4int theCurrentMultiplicity;
59 toBeCached()
60 : theProjectileRP(0), theTarget(0), theCurrentMultiplicity(-1) {}
61 };
62
63public:
64
65 G4ParticleHPProduct()
66 {
67 theDist = 0;
68 toBeCached val;
69 fCache.Put( val );
70
71 char * method = std::getenv( "G4PHP_MULTIPLICITY_METHOD" );
72 if( method )
73 {
74 if( G4String(method) == "Poisson" ) {
75 theMultiplicityMethod = G4HPMultiPoisson;
76 } else if( G4String(method) == "BetweenInts" ) {
77 theMultiplicityMethod = G4HPMultiBetweenInts;
78 } else {
79 throw G4HadronicException(__FILE__, __LINE__, ("multiplicity method unknown to G4ParticleHPProduct" + G4String(method)).c_str());
80 }
81 }
82 else
83 {
84 theMultiplicityMethod = G4HPMultiPoisson;
85 }
86 theMassCode = 0.0;
87 theMass = 0.0;
88 theIsomerFlag = 0;
89 theGroundStateQValue = 0.0;
90 theActualStateQValue = 0.0;
91 theDistLaw = -1;
92 }
93
94 ~G4ParticleHPProduct()
95 {
96 if(theDist != 0) delete theDist;
97 }
98
99 inline void Init(std::istream & aDataFile, G4ParticleDefinition* projectile)
100 {
101 aDataFile >> theMassCode>>theMass>>theIsomerFlag>>theDistLaw
102 >> theGroundStateQValue>>theActualStateQValue;
103 if( std::getenv("G4PHPTEST") )
104 G4cout << " G4ParticleHPProduct :: Init MassCode "
105 << theMassCode << " " << theMass << " theActualStateQValue "
106 << theActualStateQValue << G4endl;// GDEB
107 if( std::getenv("G4PHPTEST") )
108 G4cout << " G4ParticleHPProduct :: Init theActualStateQValue "
109 << theActualStateQValue << G4endl;// GDEB
110 theGroundStateQValue*= CLHEP::eV;
111 theActualStateQValue*= CLHEP::eV;
112 theYield.Init(aDataFile, CLHEP::eV);
113 theYield.Hash();
114 if(theDistLaw==0)
115 {
116 // distribution not known, use E-independent, isotropic
117 // angular distribution
118 theDist = new G4ParticleHPIsotropic;
119 }
120 else if(theDistLaw == 1)
121 {
122 // Continuum energy-angular distribution
123 theDist = new G4ParticleHPContEnergyAngular(projectile);
124 }
125 else if(theDistLaw == 2)
126 {
127 // Discrete 2-body scattering
128 theDist = new G4ParticleHPDiscreteTwoBody;
129 }
130 else if(theDistLaw == 3)
131 {
132 // Isotropic emission
133 theDist = new G4ParticleHPIsotropic;
134 }
135 else if(theDistLaw == 4)
136 {
137 // Discrete 2-body recoil modification
138 // not used for now. @@@@
139 theDist = new G4ParticleHPDiscreteTwoBody;
140 // the above is only temporary;
141 // recoils need to be addressed
142 // properly
143 delete theDist;
144 theDist = 0;
145 }
146 // else if(theDistLaw == 5)
147 // {
148 // charged particles only, to be used in a later stage. @@@@
149 // }
150 else if(theDistLaw == 6)
151 {
152 // N-Body phase space
153 theDist = new G4ParticleHPNBodyPhaseSpace;
154 }
155 else if(theDistLaw == 7)
156 {
157 // Laboratory angular energy paraetrisation
158 theDist = new G4ParticleHPLabAngularEnergy;
159 }
160 else
161 {
162 throw G4HadronicException(__FILE__, __LINE__, "distribution law unknown to G4ParticleHPProduct");
163 }
164 if(theDist!=0)
165 {
166 theDist->SetQValue(theActualStateQValue);
167 theDist->Init(aDataFile);
168 }
169 }
170
171 G4int GetMultiplicity(G4double anEnergy);
172 G4ReactionProductVector * Sample(G4double anEnergy, G4int nParticles);
173
174 G4double GetMeanYield(G4double anEnergy)
175 {
176 return theYield.GetY(anEnergy);
177 }
178
179 void SetProjectileRP(G4ReactionProduct * aIncidentPart)
180 {
181 fCache.Get().theProjectileRP = aIncidentPart;
182 }
183
184 void SetTarget(G4ReactionProduct * aTarget)
185 {
186 fCache.Get().theTarget = aTarget;
187 }
188
189 inline G4ReactionProduct * GetTarget()
190 {
191 return fCache.Get().theTarget;
192 }
193
194 inline G4ReactionProduct * GetProjectileRP()
195 {
196 return fCache.Get().theProjectileRP;
197 }
198
199 inline G4double MeanEnergyOfThisInteraction()
200 {
201 G4double result;
202 if(theDist == 0)
203 {
204 result = 0;
205 }
206 else
207 {
208 result=theDist->MeanEnergyOfThisInteraction();
209 result *= fCache.Get().theCurrentMultiplicity;
210 }
211 return result;
212 }
213
214 inline G4double GetQValue()
215 {
216 return theActualStateQValue;
217 }
218
219 //TK120515 For migration of frameFlag (MF6 LCT) = 3 in
220 //G4ParticleHPEnAngCorrelation
221 G4double GetMassCode() {return theMassCode;}
222 G4double GetMass() {return theMass;}
223
224private:
225
226 // data members
227
228 G4double theMassCode;
229 G4double theMass;
230 G4int theIsomerFlag;
231 G4double theGroundStateQValue;
232 G4double theActualStateQValue;
233 G4int theDistLaw; // redundant
234 G4ParticleHPVector theYield;
235 G4VParticleHPEnergyAngular * theDist;
236
237 // cashed values
238 //
239 G4Cache<toBeCached> fCache;
240
241 G4HPMultiMethod theMultiplicityMethod;
242};
243
244#endif
G4HPMultiMethod
G4HPMultiMethod
Definition: G4ParticleHPProduct.hh:50
G4HPMultiPoisson
@ G4HPMultiPoisson
Definition: G4ParticleHPProduct.hh:50
G4HPMultiBetweenInts
@ G4HPMultiBetweenInts
Definition: G4ParticleHPProduct.hh:50
G4ReactionProductVector
std::vector< G4ReactionProduct * > G4ReactionProductVector
Definition: G4ReactionProductVector.hh:43
G4double
double G4double
Definition: G4Types.hh:83
G4int
int G4int
Definition: G4Types.hh:85
G4endl
#define G4endl
Definition: G4ios.hh:57
G4cout
G4GLOB_DLL std::ostream G4cout
G4ParticleHPProduct::theMultiplicityMethod
G4HPMultiMethod theMultiplicityMethod
Definition: G4ParticleHPProduct.hh:241
G4ParticleHPProduct::Init
void Init(std::istream &aDataFile, G4ParticleDefinition *projectile)
Definition: G4ParticleHPProduct.hh:99
G4ParticleHPProduct::theYield
G4ParticleHPVector theYield
Definition: G4ParticleHPProduct.hh:234
G4ParticleHPProduct::GetProjectileRP
G4ReactionProduct * GetProjectileRP()
Definition: G4ParticleHPProduct.hh:194
G4ParticleHPProduct::Sample
G4ReactionProductVector * Sample(G4double anEnergy, G4int nParticles)
Definition: G4ParticleHPProduct.cc:112
G4ParticleHPProduct::MeanEnergyOfThisInteraction
G4double MeanEnergyOfThisInteraction()
Definition: G4ParticleHPProduct.hh:199
G4ParticleHPProduct::fCache
G4Cache< toBeCached > fCache
Definition: G4ParticleHPProduct.hh:239
G4ParticleHPProduct::GetTarget
G4ReactionProduct * GetTarget()
Definition: G4ParticleHPProduct.hh:189
G4ParticleHPProduct::GetMeanYield
G4double GetMeanYield(G4double anEnergy)
Definition: G4ParticleHPProduct.hh:174
G4ParticleHPProduct::SetTarget
void SetTarget(G4ReactionProduct *aTarget)
Definition: G4ParticleHPProduct.hh:184
G4ParticleHPProduct::SetProjectileRP
void SetProjectileRP(G4ReactionProduct *aIncidentPart)
Definition: G4ParticleHPProduct.hh:179
G4ParticleHPProduct::GetMultiplicity
G4int GetMultiplicity(G4double anEnergy)
Definition: G4ParticleHPProduct.cc:45
G4ParticleHPProduct::theDist
G4VParticleHPEnergyAngular * theDist
Definition: G4ParticleHPProduct.hh:235
G4ParticleHPVector::GetY
G4double GetY(G4double x)
Definition: G4ParticleHPVector.hh:198
G4ParticleHPVector::Init
void Init(std::istream &aDataFile, G4int total, G4double ux=1., G4double uy=1.)
Definition: G4ParticleHPVector.hh:221
G4VParticleHPEnergyAngular::MeanEnergyOfThisInteraction
virtual G4double MeanEnergyOfThisInteraction()=0
G4VParticleHPEnergyAngular::Init
virtual void Init(std::istream &aDataFile)=0
CLHEP::eV
static constexpr double eV
Definition: SystemOfUnits.h:182
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