Geant4 Cross Reference |
1 // 1 2 // ******************************************* 3 // * License and Disclaimer 4 // * 5 // * The Geant4 software is copyright of th 6 // * the Geant4 Collaboration. It is provided 7 // * conditions of the Geant4 Software License 8 // * LICENSE and available at http://cern.ch/ 9 // * include a list of copyright holders. 10 // * 11 // * Neither the authors of this software syst 12 // * institutes,nor the agencies providing fin 13 // * work make any representation or warran 14 // * regarding this software system or assum 15 // * use. Please see the license in the file 16 // * for the full disclaimer and the limitatio 17 // * 18 // * This code implementation is the result 19 // * technical work of the GEANT4 collaboratio 20 // * By using, copying, modifying or distri 21 // * any work based on the software) you ag 22 // * use in resulting scientific publicati 23 // * acceptance of all terms of the Geant4 Sof 24 // ******************************************* 25 // 26 // ------------------------------------------- 27 // 28 // GEANT4 Class header file 29 // 30 // File name: G4EmParameters 31 // 32 // Author: Vladimir Ivanchenko for migr 33 // 34 // 35 // Creation date: 17.05.2013 36 // 37 // Modifications: 38 // 39 // 40 // Class Description: 41 // 42 // A utility static class, responsable for kee 43 // for all EM physics processes and models. 44 // 45 // It is initialized by the master thread but 46 // at any moment. Parameters may be used in ru 47 // initialisation 48 // 49 // ------------------------------------------- 50 // 51 52 #ifndef G4EmParameters_h 53 #define G4EmParameters_h 1 54 55 #include "globals.hh" 56 #include "G4ios.hh" 57 #include "G4MscStepLimitType.hh" 58 #include "G4NuclearFormfactorType.hh" 59 #include "G4DNAModelSubType.hh" 60 #include "G4EmFluoDirectory.hh" 61 #include "G4EmSaturation.hh" 62 #include "G4ThreeVector.hh" 63 #include "G4ChemTimeStepModel.hh" 64 #include <vector> 65 #include <map> 66 enum G4eSingleScatteringType 67 { 68 fWVI = 0, 69 fMott, 70 fDPWA 71 }; 72 73 enum class G4TransportationWithMscType 74 { 75 fDisabled = 0, 76 fEnabled, 77 fMultipleSteps, 78 }; 79 80 enum G4EmFluctuationType 81 { 82 fDummyFluctuation = 0, 83 fUniversalFluctuation, 84 fUrbanFluctuation 85 }; 86 87 enum G4PositronAtRestModelType 88 { 89 fSimplePositronium = 0, 90 fAllisonPositronium, 91 fOrePowell, 92 fOrePowellPolar 93 }; 94 95 class G4EmParametersMessenger; 96 class G4EmExtraParameters; 97 class G4EmLowEParameters; 98 class G4VAtomDeexcitation; 99 class G4VEnergyLossProcess; 100 class G4VEmProcess; 101 class G4StateManager; 102 103 class G4EmParameters 104 { 105 public: 106 107 static G4EmParameters* Instance(); 108 109 ~G4EmParameters(); 110 111 void SetDefaults(); 112 113 // printing 114 void StreamInfo(std::ostream& os) const; 115 void Dump(); 116 friend std::ostream& operator<< (std::ostrea 117 118 // boolean flags 119 void SetLossFluctuations(G4bool val); 120 G4bool LossFluctuation() const; 121 122 void SetBuildCSDARange(G4bool val); 123 G4bool BuildCSDARange() const; 124 125 void SetLPM(G4bool val); 126 G4bool LPM() const; 127 128 void SetUseCutAsFinalRange(G4bool val); 129 G4bool UseCutAsFinalRange() const; 130 131 void SetApplyCuts(G4bool val); 132 G4bool ApplyCuts() const; 133 134 void SetFluo(G4bool val); 135 G4bool Fluo() const; 136 137 G4EmFluoDirectory FluoDirectory() const; 138 139 void SetFluoDirectory(G4EmFluoDirectory); 140 void SetBeardenFluoDir(G4bool val); 141 void SetANSTOFluoDir(G4bool val); 142 void SetXDB_EADLFluoDir(G4bool val); 143 144 G4bool BeardenFluoDir(); 145 G4bool ANSTOFluoDir(); 146 147 void SetAuger(G4bool val); 148 void SetAugerCascade(G4bool val) { SetAuger( 149 G4bool Auger() const; 150 G4bool AugerCascade() const { return Auger() 151 152 void SetPixe(G4bool val); 153 G4bool Pixe() const; 154 155 void SetDeexcitationIgnoreCut(G4bool val); 156 G4bool DeexcitationIgnoreCut() const; 157 158 void SetLateralDisplacement(G4bool val); 159 G4bool LateralDisplacement() const; 160 161 void SetLateralDisplacementAlg96(G4bool val) 162 G4bool LateralDisplacementAlg96() const; 163 164 void SetMuHadLateralDisplacement(G4bool val) 165 G4bool MuHadLateralDisplacement() const; 166 167 void ActivateAngularGeneratorForIonisation(G 168 G4bool UseAngularGeneratorForIonisation() co 169 170 void SetUseMottCorrection(G4bool val); 171 G4bool UseMottCorrection() const; 172 173 void SetIntegral(G4bool val); 174 G4bool Integral() const; 175 176 void SetBirksActive(G4bool val); 177 G4bool BirksActive() const; 178 179 void SetUseICRU90Data(G4bool val); 180 G4bool UseICRU90Data() const; 181 182 void SetFluctuationType(G4EmFluctuationType 183 G4EmFluctuationType FluctuationType() const; 184 185 void SetPositronAtRestModelType(G4PositronAt 186 G4PositronAtRestModelType PositronAtRestMode 187 188 void SetDNAFast(G4bool val); 189 G4bool DNAFast() const; 190 191 void SetDNAStationary(G4bool val); 192 G4bool DNAStationary() const; 193 194 void SetDNAElectronMsc(G4bool val); 195 G4bool DNAElectronMsc() const; 196 197 // if general interaction is enabled then 198 // force interaction options should be disab 199 void SetGeneralProcessActive(G4bool val); 200 G4bool GeneralProcessActive() const; 201 202 void SetEnableSamplingTable(G4bool val); 203 G4bool EnableSamplingTable() const; 204 205 void SetEnablePolarisation(G4bool val); 206 G4bool EnablePolarisation() const; 207 208 G4bool GetDirectionalSplitting() const; 209 void SetDirectionalSplitting(G4bool v); 210 211 G4bool QuantumEntanglement() const; 212 void SetQuantumEntanglement(G4bool v); 213 214 G4bool RetrieveMuDataFromFile() const; 215 void SetRetrieveMuDataFromFile(G4bool v); 216 217 G4bool PhotoeffectBelowKShell() const; 218 void SetPhotoeffectBelowKShell(G4bool v); 219 220 G4bool MscPositronCorrection() const; 221 void SetMscPositronCorrection(G4bool v); 222 223 G4bool UseEPICS2017XS() const; 224 void SetUseEPICS2017XS(G4bool v); 225 226 G4bool Use3GammaAnnihilationOnFly() const; 227 void Set3GammaAnnihilationOnFly(G4bool v); 228 229 G4bool UseRiGePairProductionModel() const; 230 void SetUseRiGePairProductionModel(G4bool v) 231 232 // 5d 233 void SetOnIsolated(G4bool val); 234 G4bool OnIsolated() const; 235 236 void ActivateDNA(); 237 void SetIsPrintedFlag(G4bool val); 238 G4bool IsPrintLocked() const; 239 240 // double parameters with values 241 void SetMinEnergy(G4double val); 242 G4double MinKinEnergy() const; 243 244 void SetMaxEnergy(G4double val); 245 G4double MaxKinEnergy() const; 246 247 void SetMaxEnergyForCSDARange(G4double val); 248 G4double MaxEnergyForCSDARange() const; 249 250 void SetLowestElectronEnergy(G4double val); 251 G4double LowestElectronEnergy() const; 252 253 void SetLowestMuHadEnergy(G4double val); 254 G4double LowestMuHadEnergy() const; 255 256 void SetLowestTripletEnergy(G4double val); 257 G4double LowestTripletEnergy() const; 258 259 void SetLinearLossLimit(G4double val); 260 G4double LinearLossLimit() const; 261 262 void SetBremsstrahlungTh(G4double val); 263 G4double BremsstrahlungTh() const; 264 void SetMuHadBremsstrahlungTh(G4double val); 265 G4double MuHadBremsstrahlungTh() const; 266 267 void SetLambdaFactor(G4double val); 268 G4double LambdaFactor() const; 269 270 void SetFactorForAngleLimit(G4double val); 271 G4double FactorForAngleLimit() const; 272 273 void SetMscThetaLimit(G4double val); 274 G4double MscThetaLimit() const; 275 276 void SetMscEnergyLimit(G4double val); 277 G4double MscEnergyLimit() const; 278 279 void SetMscRangeFactor(G4double val); 280 G4double MscRangeFactor() const; 281 282 void SetMscMuHadRangeFactor(G4double val); 283 G4double MscMuHadRangeFactor() const; 284 285 void SetMscGeomFactor(G4double val); 286 G4double MscGeomFactor() const; 287 288 void SetMscSafetyFactor(G4double val); 289 G4double MscSafetyFactor() const; 290 291 void SetMscLambdaLimit(G4double val); 292 G4double MscLambdaLimit() const; 293 294 void SetMscSkin(G4double val); 295 G4double MscSkin() const; 296 297 void SetScreeningFactor(G4double val); 298 G4double ScreeningFactor() const; 299 300 void SetMaxNIELEnergy(G4double val); 301 G4double MaxNIELEnergy() const; 302 303 void SetMaxEnergyFor5DMuPair(G4double val); 304 G4double MaxEnergyFor5DMuPair() const; 305 306 void SetStepFunction(G4double v1, G4double v 307 void SetStepFunctionMuHad(G4double v1, G4dou 308 void SetStepFunctionLightIons(G4double v1, G 309 void SetStepFunctionIons(G4double v1, G4doub 310 void FillStepFunction(const G4ParticleDefini 311 312 void SetDirectionalSplittingRadius(G4double 313 G4double GetDirectionalSplittingRadius(); 314 315 void SetDirectionalSplittingTarget(const G4T 316 G4ThreeVector GetDirectionalSplittingTarget( 317 318 // integer parameters 319 320 void SetNumberOfBinsPerDecade(G4int val); 321 G4int NumberOfBinsPerDecade() const; 322 G4int NumberOfBins() const; 323 324 void SetVerbose(G4int val); 325 G4int Verbose() const; 326 327 void SetWorkerVerbose(G4int val); 328 G4int WorkerVerbose() const; 329 330 void SetNumberForFreeVector(G4int val); 331 G4int NumberForFreeVector() const; 332 333 void SetTransportationWithMsc(G4Transportati 334 G4TransportationWithMscType TransportationWi 335 336 void SetMscStepLimitType(G4MscStepLimitType 337 G4MscStepLimitType MscStepLimitType() const; 338 339 void SetMscMuHadStepLimitType(G4MscStepLimit 340 G4MscStepLimitType MscMuHadStepLimitType() c 341 342 void SetSingleScatteringType(G4eSingleScatte 343 G4eSingleScatteringType SingleScatteringType 344 345 void SetNuclearFormfactorType(G4NuclearFormf 346 G4NuclearFormfactorType NuclearFormfactorTyp 347 348 void SetDNAeSolvationSubType(G4DNAModelSubTy 349 G4DNAModelSubType DNAeSolvationSubType() con 350 351 //DNA chemistry model 352 void SetTimeStepModel(const G4ChemTimeStepMo 353 G4ChemTimeStepModel GetTimeStepModel() const 354 //5d 355 void SetConversionType(G4int val); 356 G4int GetConversionType() const; 357 358 // string parameters 359 void SetPIXECrossSectionModel(const G4String 360 const G4String& PIXECrossSectionModel(); 361 362 void SetPIXEElectronCrossSectionModel(const 363 const G4String& PIXEElectronCrossSectionMode 364 365 void SetLivermoreDataDir(const G4String&); 366 const G4String& LivermoreDataDir(); 367 368 // parameters per region or per process 369 void AddPAIModel(const G4String& particle, 370 const G4String& region, 371 const G4String& type); 372 const std::vector<G4String>& ParticlesPAI() 373 const std::vector<G4String>& RegionsPAI() co 374 const std::vector<G4String>& TypesPAI() cons 375 376 void AddMicroElec(const G4String& region); 377 const std::vector<G4String>& RegionsMicroEle 378 379 void AddDNA(const G4String& region, const G4 380 const std::vector<G4String>& RegionsDNA() co 381 const std::vector<G4String>& TypesDNA() cons 382 383 void AddPhysics(const G4String& region, cons 384 const std::vector<G4String>& RegionsPhysics( 385 const std::vector<G4String>& TypesPhysics() 386 387 void SetSubCutRegion(const G4String& region 388 389 void SetDeexActiveRegion(const G4String& reg 390 G4bool fauger, G4bool fpixe); 391 392 void SetProcessBiasingFactor(const G4String& 393 G4double val, G 394 395 void ActivateForcedInteraction(const G4Strin 396 const G4Strin 397 G4double leng 398 G4bool wflag) 399 400 void ActivateSecondaryBiasing(const G4String 401 const G4String& region, 402 G4double factor, 403 G4double energyLimit); 404 405 // define external saturation class 406 void SetEmSaturation(G4EmSaturation*); 407 // create and access saturation class 408 G4EmSaturation* GetEmSaturation(); 409 410 // initialisation methods 411 void DefineRegParamForLoss(G4VEnergyLossProc 412 void DefineRegParamForEM(G4VEmProcess*) cons 413 void DefineRegParamForDeex(G4VAtomDeexcitati 414 415 const G4String& GetDirLEDATA() const; 416 417 G4EmParameters(G4EmParameters &) = delete; 418 G4EmParameters & operator=(const G4EmParamet 419 420 private: 421 422 G4EmParameters(); 423 424 void Initialise(); 425 426 G4bool IsLocked() const; 427 428 void PrintWarning(G4ExceptionDescription& ed 429 430 static G4EmParameters* theInstance; 431 432 G4EmParametersMessenger* theMessenger; 433 G4EmExtraParameters* fBParameters; 434 G4EmLowEParameters* fCParameters; 435 G4StateManager* fStateManager; 436 G4EmSaturation* emSaturation; 437 438 G4bool lossFluctuation; 439 G4bool buildCSDARange; 440 G4bool flagLPM; 441 G4bool cutAsFinalRange; 442 G4bool applyCuts; 443 G4bool lateralDisplacement; 444 G4bool lateralDisplacementAlg96; 445 G4bool muhadLateralDisplacement; 446 G4bool useAngGeneratorForIonisation; 447 G4bool useMottCorrection; 448 G4bool integral; 449 G4bool birks; 450 G4bool fICRU90; 451 G4bool gener; 452 G4bool fSamplingTable; 453 G4bool fPolarisation; 454 G4bool fMuDataFromFile; 455 G4bool fPEKShell; 456 G4bool fMscPosiCorr; 457 G4bool fUseEPICS2017XS; 458 G4bool f3GammaAnnihilationOnFly; 459 G4bool fUseRiGePairProductionModel; 460 G4bool onIsolated; // 5d model conversion on 461 G4bool fDNA; 462 G4bool fIsPrinted; 463 464 G4double minKinEnergy; 465 G4double maxKinEnergy; 466 G4double maxKinEnergyCSDA; 467 G4double max5DEnergyForMuPair; 468 G4double lowestElectronEnergy; 469 G4double lowestMuHadEnergy; 470 G4double lowestTripletEnergy; 471 G4double linLossLimit; 472 G4double bremsTh; 473 G4double bremsMuHadTh; 474 G4double lambdaFactor; 475 G4double factorForAngleLimit; 476 G4double thetaLimit; 477 G4double energyLimit; 478 G4double maxNIELEnergy; 479 G4double rangeFactor; 480 G4double rangeFactorMuHad; 481 G4double geomFactor; 482 G4double safetyFactor; 483 G4double lambdaLimit; 484 G4double skin; 485 G4double factorScreen; 486 487 G4int nbinsPerDecade; 488 G4int verbose; 489 G4int workerVerbose; 490 G4int nForFreeVector; 491 G4int tripletConv; // 5d model triplet gene 492 493 G4TransportationWithMscType fTransportationW 494 G4MscStepLimitType mscStepLimit; 495 G4MscStepLimitType mscStepLimitMuHad; 496 G4NuclearFormfactorType nucFormfactor; 497 G4eSingleScatteringType fSStype; 498 G4EmFluctuationType fFluct; 499 G4PositronAtRestModelType fPositronium; 500 501 G4String fDirLEDATA; 502 }; 503 504 //....oooOO0OOooo........oooOO0OOooo........oo 505 506 #endif 507 508