| Geant4 Cross Reference |
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25 // 25 //
26 // G4SPSEneDistribution 26 // G4SPSEneDistribution
27 // 27 //
28 // Class Description: 28 // Class Description:
29 // 29 //
30 // To generate the energy of a primary vertex 30 // To generate the energy of a primary vertex according to the
31 // defined distribution. This is a shared clas 31 // defined distribution. This is a shared class between threads.
32 // Only one thread should use the set-methods 32 // Only one thread should use the set-methods here.
33 // Note that this is exactly what is achieved 33 // Note that this is exactly what is achieved using UI commands.
34 // If you use the set methods to set defaults 34 // If you use the set methods to set defaults in your application take
35 // care that only one thread is executing them 35 // care that only one thread is executing them.
36 // In addition take care of calling these meth 36 // In addition take care of calling these methods before the run is
37 // started. Do not use the setters during the 37 // started. Do not use the setters during the event loop
38 38
39 // Author: Fan Lei, QinetiQ ltd. 39 // Author: Fan Lei, QinetiQ ltd.
40 // Customer: ESA/ESTEC 40 // Customer: ESA/ESTEC
41 // History: 41 // History:
42 // - 05/02/2004, Fan Lei - Created. 42 // - 05/02/2004, Fan Lei - Created.
43 // Based on the G4GeneralParticleSource cl 43 // Based on the G4GeneralParticleSource class.
44 // - 26/03/2014, Andrew Green. 44 // - 26/03/2014, Andrew Green.
45 // Modification to use STL vectors instead 45 // Modification to use STL vectors instead of C-style arrays.
46 // Also moved to dynamically allocated mem 46 // Also moved to dynamically allocated memory in the LinearInterpolation(),
47 // ExpInterpolation() and LogInterpolation 47 // ExpInterpolation() and LogInterpolation() functions.
48 // - 06/06/2014, Andrea Dotti. 48 // - 06/06/2014, Andrea Dotti.
49 // For thread safety: this is a shared obj 49 // For thread safety: this is a shared object.
50 // Added mutex to control access to shared 50 // Added mutex to control access to shared resources (data members).
51 // in Getters and Setters, mutex is NOT us 51 // in Getters and Setters, mutex is NOT used in GenerateOne() because it
52 // is assumed that properties are not chan 52 // is assumed that properties are not changed during event loop.
53 // - 24/11/2017, Fan Lei 53 // - 24/11/2017, Fan Lei
54 // Added cutoff power-law distribution opti 54 // Added cutoff power-law distribution option. Implementation is similar
55 // to that of the BlackBody one. 55 // to that of the BlackBody one.
56 // ------------------------------------------- 56 // --------------------------------------------------------------------
57 #ifndef G4SPSEneDistribution_hh 57 #ifndef G4SPSEneDistribution_hh
58 #define G4SPSEneDistribution_hh 1 58 #define G4SPSEneDistribution_hh 1
59 59
60 #include "G4PhysicsFreeVector.hh" << 60 #include "G4PhysicsOrderedFreeVector.hh"
61 #include "G4ParticleMomentum.hh" 61 #include "G4ParticleMomentum.hh"
62 #include "G4ParticleDefinition.hh" 62 #include "G4ParticleDefinition.hh"
63 #include "G4DataInterpolation.hh" 63 #include "G4DataInterpolation.hh"
64 #include "G4Threading.hh" 64 #include "G4Threading.hh"
65 #include "G4Cache.hh" 65 #include "G4Cache.hh"
66 #include <vector> 66 #include <vector>
67 67
68 #include "G4SPSRandomGenerator.hh" 68 #include "G4SPSRandomGenerator.hh"
69 69
70 class G4SPSEneDistribution 70 class G4SPSEneDistribution
71 { 71 {
72 public: 72 public:
73 73
74 G4SPSEneDistribution(); 74 G4SPSEneDistribution();
75 // Constructor: initializes variables 75 // Constructor: initializes variables
76 ~G4SPSEneDistribution(); 76 ~G4SPSEneDistribution();
77 // Destructor 77 // Destructor
78 78
79 void SetEnergyDisType(const G4String&); 79 void SetEnergyDisType(const G4String&);
80 // Allows the user to choose the energy 80 // Allows the user to choose the energy distribution type.
81 // The arguments are: Mono (mono-energet 81 // The arguments are: Mono (mono-energetic), Lin (linear),
82 // Pow (power-law), Exp (exponential), G 82 // Pow (power-law), Exp (exponential), Gauss (gaussian),
83 // Brem (bremsstrahlung), BBody (black-b 83 // Brem (bremsstrahlung), BBody (black-body),
84 // Cdg (cosmic diffuse gamma-ray), User 84 // Cdg (cosmic diffuse gamma-ray), User (user-defined),
85 // Arb (arbitrary point-wise), Epn (ener 85 // Arb (arbitrary point-wise), Epn (energy per nucleon)
86 86
87 const G4String& GetEnergyDisType(); 87 const G4String& GetEnergyDisType();
88 88
89 void SetEmin(G4double); 89 void SetEmin(G4double);
90 // Sets the minimum energy 90 // Sets the minimum energy
91 91
92 G4double GetEmin() const; 92 G4double GetEmin() const;
93 G4double GetArbEmin(); 93 G4double GetArbEmin();
94 94
95 void SetEmax(G4double); 95 void SetEmax(G4double);
96 // Sets the maximum energy 96 // Sets the maximum energy
97 97
98 G4double GetEmax() const; 98 G4double GetEmax() const;
99 G4double GetArbEmax(); 99 G4double GetArbEmax();
100 100
101 void SetMonoEnergy(G4double); 101 void SetMonoEnergy(G4double);
102 // Sets energy for mono-energetic distri 102 // Sets energy for mono-energetic distribution
103 103
104 void SetAlpha(G4double); 104 void SetAlpha(G4double);
105 // Sets alpha for a power-law distributi 105 // Sets alpha for a power-law distribution
106 106
107 void SetBiasAlpha(G4double); 107 void SetBiasAlpha(G4double);
108 108
109 void SetTemp(G4double); 109 void SetTemp(G4double);
110 // Sets Temperature for a Brem or BBody 110 // Sets Temperature for a Brem or BBody distributions
111 111
112 void SetBeamSigmaInE(G4double); 112 void SetBeamSigmaInE(G4double);
113 113
114 void SetEzero(G4double); 114 void SetEzero(G4double);
115 // Sets Ezero for an exponential distrib 115 // Sets Ezero for an exponential distribution
116 116
117 void SetGradient(G4double); 117 void SetGradient(G4double);
118 // Sets gradient for a linear distributi 118 // Sets gradient for a linear distribution
119 119
120 void SetInterCept(G4double); 120 void SetInterCept(G4double);
121 // Sets intercept for a linear distribut 121 // Sets intercept for a linear distribution
122 122
123 void UserEnergyHisto(const G4ThreeVector&) 123 void UserEnergyHisto(const G4ThreeVector&);
124 // Allows user to defined a histogram fo 124 // Allows user to defined a histogram for the energy distribution
125 125
126 void ArbEnergyHisto(const G4ThreeVector&); 126 void ArbEnergyHisto(const G4ThreeVector&);
127 // Allows the user to define an Arbitrar 127 // Allows the user to define an Arbitrary set of points for the
128 // energy distribution 128 // energy distribution
129 129
130 void ArbEnergyHistoFile(const G4String&); 130 void ArbEnergyHistoFile(const G4String&);
131 131
132 void EpnEnergyHisto(const G4ThreeVector&); 132 void EpnEnergyHisto(const G4ThreeVector&);
133 // Allows the user to define an Energy p 133 // Allows the user to define an Energy per nucleon histogram
134 134
135 void InputEnergySpectra(G4bool); 135 void InputEnergySpectra(G4bool);
136 // Allows the user to choose between mom 136 // Allows the user to choose between momentum and energy histograms
137 // for user-defined histograms and arbit 137 // for user-defined histograms and arbitrary point-wise spectra.
138 // The default is true (energy) 138 // The default is true (energy)
139 139
140 void InputDifferentialSpectra(G4bool); 140 void InputDifferentialSpectra(G4bool);
141 // Allows the user to choose between int 141 // Allows the user to choose between integral and differential
142 // distributions when using the arbitrar 142 // distributions when using the arbitrary point-wise option
143 143
144 void ArbInterpolate(const G4String&); 144 void ArbInterpolate(const G4String&);
145 // Allows the user to specify the type o 145 // Allows the user to specify the type of function to
146 // interpolate the Arbitrary points spec 146 // interpolate the Arbitrary points spectrum with
147 147
148 const G4String& GetIntType(); 148 const G4String& GetIntType();
149 149
150 void Calculate(); 150 void Calculate();
151 // Controls the calculation of Integral 151 // Controls the calculation of Integral PDF for the Cdg and BBody
152 // distributions 152 // distributions
153 153
154 void SetBiasRndm(G4SPSRandomGenerator* a); 154 void SetBiasRndm(G4SPSRandomGenerator* a);
155 // Sets the biased random number generat 155 // Sets the biased random number generator
156 156
157 void ReSetHist(const G4String&); 157 void ReSetHist(const G4String&);
158 // Resets the histogram for user defined 158 // Resets the histogram for user defined distribution
159 159
160 void SetVerbosity(G4int a); 160 void SetVerbosity(G4int a);
161 // Sets the verbosity level 161 // Sets the verbosity level
162 162
163 G4double GetWeight() const; 163 G4double GetWeight() const;
164 164
165 G4double GetMonoEnergy(); 165 G4double GetMonoEnergy();
166 // Mono-energetic energy 166 // Mono-energetic energy
167 167
168 G4double GetSE(); 168 G4double GetSE();
169 // Standard deviation for Gaussian distr 169 // Standard deviation for Gaussian distribution in energy
170 170
171 G4double Getalpha() const; 171 G4double Getalpha() const;
172 // Alpha (pow) 172 // Alpha (pow)
173 173
174 G4double GetEzero() const; 174 G4double GetEzero() const;
175 // E0 (exp) 175 // E0 (exp)
176 176
177 G4double GetTemp(); 177 G4double GetTemp();
178 // Temp (bbody,brem) 178 // Temp (bbody,brem)
179 179
180 G4double Getgrad() const; 180 G4double Getgrad() const;
181 // Gradient and intercept for linear spe 181 // Gradient and intercept for linear spectra
182 182
183 G4double Getcept() const; 183 G4double Getcept() const;
184 184
185 G4PhysicsFreeVector GetUserDefinedEnergyHi << 185 G4PhysicsOrderedFreeVector GetUserDefinedEnergyHisto();
186 186
187 G4PhysicsFreeVector GetArbEnergyHisto(); << 187 G4PhysicsOrderedFreeVector GetArbEnergyHisto();
188 188
189 G4double GenerateOne(G4ParticleDefinition* 189 G4double GenerateOne(G4ParticleDefinition*);
190 // Generate one random energy for the s 190 // Generate one random energy for the specified particle
191 191
192 G4double GetProbability (G4double); 192 G4double GetProbability (G4double);
193 193
194 G4double GetArbEneWeight(G4double); 194 G4double GetArbEneWeight(G4double);
195 195
196 inline void ApplyEnergyWeight(G4bool val) 196 inline void ApplyEnergyWeight(G4bool val) { applyEvergyWeight = val; }
197 inline G4bool IfApplyEnergyWeight() const 197 inline G4bool IfApplyEnergyWeight() const { return applyEvergyWeight; }
198 198
199 private: 199 private:
200 200
201 void LinearInterpolation(); 201 void LinearInterpolation();
202 void LogInterpolation(); 202 void LogInterpolation();
203 void ExpInterpolation(); 203 void ExpInterpolation();
204 void SplineInterpolation(); 204 void SplineInterpolation();
205 void CalculateCdgSpectrum(); 205 void CalculateCdgSpectrum();
206 void CalculateBbodySpectrum(); 206 void CalculateBbodySpectrum();
207 void CalculateCPowSpectrum(); 207 void CalculateCPowSpectrum();
208 208
209 // The following methods generate energies 209 // The following methods generate energies according
210 // to the spectral parameters defined abov 210 // to the spectral parameters defined above
211 211
212 void GenerateMonoEnergetic(); 212 void GenerateMonoEnergetic();
213 void GenerateBiasPowEnergies(); 213 void GenerateBiasPowEnergies();
214 void GenerateGaussEnergies(); 214 void GenerateGaussEnergies();
215 void GenerateBremEnergies(); 215 void GenerateBremEnergies();
216 void GenerateBbodyEnergies(); 216 void GenerateBbodyEnergies();
217 void GenerateCdgEnergies(); 217 void GenerateCdgEnergies();
218 void GenUserHistEnergies(); 218 void GenUserHistEnergies();
219 void GenEpnHistEnergies(); 219 void GenEpnHistEnergies();
220 void GenArbPointEnergies(); // NOTE: REQUI 220 void GenArbPointEnergies(); // NOTE: REQUIRES UPDATE OF DATA MEMBERS
221 void GenerateExpEnergies(G4bool); 221 void GenerateExpEnergies(G4bool);
222 void GenerateLinearEnergies(G4bool); 222 void GenerateLinearEnergies(G4bool);
223 void GeneratePowEnergies(G4bool); 223 void GeneratePowEnergies(G4bool);
224 void GenerateCPowEnergies(); 224 void GenerateCPowEnergies();
225 225
226 void ConvertEPNToEnergy(); 226 void ConvertEPNToEnergy();
227 // Converts energy per nucleon to energy 227 // Converts energy per nucleon to energy
228 228
229 void BBInitHists(); 229 void BBInitHists();
230 void CPInitHists(); 230 void CPInitHists();
231 231
232 private: // Non invariant data members beco 232 private: // Non invariant data members become G4Cache
233 233
234 G4String EnergyDisType; // energy dis type 234 G4String EnergyDisType; // energy dis type Variable - Mono,Lin,Exp,etc
235 G4double weight; // particle weight //// N 235 G4double weight; // particle weight //// NOT INVARIANT
236 G4double MonoEnergy; //Mono-energteic ener 236 G4double MonoEnergy; //Mono-energteic energy
237 G4double SE; // Standard deviation for Gau 237 G4double SE; // Standard deviation for Gaussian distribution in energy
238 238
239 G4double Emin, Emax; // emin and emax //// 239 G4double Emin, Emax; // emin and emax //// NOT INVARIANT
240 G4double alpha, Ezero;// alpha (pow), E0 ( 240 G4double alpha, Ezero;// alpha (pow), E0 (exp) //// NOT INVARIANT
241 G4double Temp; // Temp (bbody,brem) 241 G4double Temp; // Temp (bbody,brem)
242 G4double biasalpha; // biased power index 242 G4double biasalpha; // biased power index
243 G4double grad, cept; // gradient and inter 243 G4double grad, cept; // gradient and intercept for linear spectra //// NOT INVARIANT
244 G4double prob_norm; // normalisation facto 244 G4double prob_norm; // normalisation factor use in calculate the probability
245 G4bool Biased = false; // biased to power- 245 G4bool Biased = false; // biased to power-law
246 G4bool EnergySpec = true; // energy spectr 246 G4bool EnergySpec = true; // energy spectra, false - momentum spectra
247 G4bool DiffSpec = true; // differential sp 247 G4bool DiffSpec = true; // differential spec, false integral spec
248 248
249 G4PhysicsFreeVector UDefEnergyH; // energy << 249 G4PhysicsOrderedFreeVector UDefEnergyH; // energy hist data
250 G4PhysicsFreeVector IPDFEnergyH; << 250 G4PhysicsOrderedFreeVector IPDFEnergyH;
251 G4bool IPDFEnergyExist = false, IPDFArbExi 251 G4bool IPDFEnergyExist = false, IPDFArbExist = false, Epnflag = false;
252 G4PhysicsFreeVector ArbEnergyH; // Arb x,y << 252 G4PhysicsOrderedFreeVector ArbEnergyH; // Arb x,y histogram
253 G4PhysicsFreeVector IPDFArbEnergyH; // IPD << 253 G4PhysicsOrderedFreeVector IPDFArbEnergyH; // IPDF for Arb
254 G4PhysicsFreeVector EpnEnergyH; << 254 G4PhysicsOrderedFreeVector EpnEnergyH;
255 G4double CDGhist[3]; // cumulative histo f 255 G4double CDGhist[3]; // cumulative histo for cdg
256 256
257 std::vector<G4double>* BBHist = nullptr; 257 std::vector<G4double>* BBHist = nullptr;
258 std::vector<G4double>* Bbody_x = nullptr; 258 std::vector<G4double>* Bbody_x = nullptr;
259 G4bool BBhistInit = false; 259 G4bool BBhistInit = false;
260 G4bool BBhistCalcd = false; 260 G4bool BBhistCalcd = false;
261 261
262 // For cutoff power-law 262 // For cutoff power-law
263 // 263 //
264 std::vector<G4double>* CPHist = nullptr; 264 std::vector<G4double>* CPHist = nullptr;
265 std::vector<G4double>* CP_x = nullptr; 265 std::vector<G4double>* CP_x = nullptr;
266 G4bool CPhistInit = false; 266 G4bool CPhistInit = false;
267 G4bool CPhistCalcd = false; 267 G4bool CPhistCalcd = false;
268 268
269 G4String IntType; // Interpolation type 269 G4String IntType; // Interpolation type
270 G4double* Arb_grad = nullptr; 270 G4double* Arb_grad = nullptr;
271 G4double* Arb_cept = nullptr; 271 G4double* Arb_cept = nullptr;
272 G4bool Arb_grad_cept_flag = false; 272 G4bool Arb_grad_cept_flag = false;
273 G4double* Arb_alpha = nullptr; 273 G4double* Arb_alpha = nullptr;
274 G4double* Arb_Const = nullptr; 274 G4double* Arb_Const = nullptr;
275 G4bool Arb_alpha_Const_flag = false; 275 G4bool Arb_alpha_Const_flag = false;
276 G4double* Arb_ezero = nullptr; 276 G4double* Arb_ezero = nullptr;
277 G4bool Arb_ezero_flag = false; 277 G4bool Arb_ezero_flag = false;
278 278
279 G4bool applyEvergyWeight = false; 279 G4bool applyEvergyWeight = false;
280 280
281 G4double ArbEmin, ArbEmax; 281 G4double ArbEmin, ArbEmax;
282 // Emin and Emax for the whole arb distr 282 // Emin and Emax for the whole arb distribution used primarily for debug.
283 283
284 G4double particle_energy; 284 G4double particle_energy;
285 285
286 G4SPSRandomGenerator* eneRndm = nullptr; 286 G4SPSRandomGenerator* eneRndm = nullptr;
287 287
288 G4int verbosityLevel; 288 G4int verbosityLevel;
289 289
290 G4PhysicsFreeVector ZeroPhysVector; // for << 290 G4PhysicsOrderedFreeVector ZeroPhysVector; // for re-set only
291 291
292 std::vector<G4DataInterpolation*> SplineIn 292 std::vector<G4DataInterpolation*> SplineInt;
293 // Holds Spline stuff required for sampl 293 // Holds Spline stuff required for sampling
294 G4DataInterpolation* Splinetemp = nullptr; 294 G4DataInterpolation* Splinetemp = nullptr;
295 // Holds a temp Spline used for calculat 295 // Holds a temp Spline used for calculating area
296 296
297 G4Mutex mutex; // protect access to shared 297 G4Mutex mutex; // protect access to shared resources
298 298
299 // Thread local data (non-invariant during 299 // Thread local data (non-invariant during event loop).
300 // These are copied from master one at the 300 // These are copied from master one at the beginning of
301 // generation of each event 301 // generation of each event
302 // 302 //
303 struct threadLocal_t 303 struct threadLocal_t
304 { 304 {
305 G4double Emin; 305 G4double Emin;
306 G4double Emax; 306 G4double Emax;
307 G4double alpha; 307 G4double alpha;
308 G4double Ezero; 308 G4double Ezero;
309 G4double grad; 309 G4double grad;
310 G4double cept; 310 G4double cept;
311 G4ParticleDefinition* particle_definitio 311 G4ParticleDefinition* particle_definition;
312 G4double weight; 312 G4double weight;
313 G4double particle_energy; 313 G4double particle_energy;
314 }; 314 };
315 G4Cache<threadLocal_t> threadLocalData; 315 G4Cache<threadLocal_t> threadLocalData;
316 }; 316 };
317 317
318 #endif 318 #endif
319 319