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 // ------------------------------------------- 29 // GEANT 4 class implementation 30 // 31 // =========================================== 32 // Created: 19 March 1997, J. Apostolakis 33 // =========================================== 34 35 #include "G4CoupledTransportation.hh" 36 #include "G4TransportationProcessType.hh" 37 #include "G4TransportationLogger.hh" 38 39 #include "G4PhysicalConstants.hh" 40 #include "G4SystemOfUnits.hh" 41 #include "G4ProductionCutsTable.hh" 42 #include "G4ParticleTable.hh" 43 #include "G4ChordFinder.hh" 44 #include "G4Field.hh" 45 #include "G4FieldTrack.hh" 46 #include "G4FieldManagerStore.hh" 47 #include "G4PathFinder.hh" 48 49 #include "G4PropagatorInField.hh" 50 #include "G4TransportationManager.hh" 51 52 class G4VSensitiveDetector; 53 54 G4bool G4CoupledTransportation::fSignifyStepIn 55 // This mode must apply to all threads 56 57 ////////////////////////////////////////////// 58 // 59 // Constructor 60 61 G4CoupledTransportation::G4CoupledTransportati 62 : G4Transportation( verbosity, "CoupledTrans 63 fPreviousMassSafety( 0.0 ), 64 fPreviousFullSafety( 0.0 ), 65 fMassGeometryLimitedStep( false ), 66 fFirstStepInMassVolume( true ) 67 { 68 SetProcessSubType(static_cast<G4int>(COUPLED 69 // SetVerboseLevel is called in the construc 70 71 if( verboseLevel > 0 ) 72 { 73 G4cout << " G4CoupledTransportation constr 74 G4cout << " Verbose level is " << verboseL 75 G4cout << " Reports First/Last in " 76 << (fSignifyStepInAnyVolume ? " any 77 << " geometry " << G4endl; 78 } 79 fPathFinder= G4PathFinder::GetInstance(); 80 } 81 82 ////////////////////////////////////////////// 83 84 G4CoupledTransportation::~G4CoupledTransportat 85 { 86 } 87 88 ////////////////////////////////////////////// 89 // 90 // Responsibilities: 91 // Find whether the geometry limits the Ste 92 // Calculate the new value of the safety an 93 // Store the final time, position and momen 94 95 G4double G4CoupledTransportation:: 96 AlongStepGetPhysicalInteractionLength( const G 97 G 98 G 99 G 100 G 101 { 102 G4double geometryStepLength; 103 G4double startFullSafety= 0.0; // estimated 104 G4double safetyProposal= -1.0; // local copy 105 106 G4ThreeVector EndUnitMomentum ; 107 G4double lengthAlongCurve = 0.0 ; 108 109 fParticleIsLooping = false ; 110 111 // Initial actions moved to StartTrack() 112 // -------------------------------------- 113 // Note: in case another process changes tou 114 // it will be necessary to add here (for 115 // fCurrentTouchableHandle = aTrack->GetTouc 116 117 // GPILSelection is set to defaule value of 118 // It is a return value 119 // 120 *selection = CandidateForSelection ; 121 122 fFirstStepInMassVolume = fNewTrack || fMassG 123 fFirstStepInVolume = fNewTrack || fGeome 124 125 #ifdef G4DEBUG_TRANSPORT 126 G4cout << " CoupledTransport::AlongStep GPI 127 << " 1st-step: any= " <<fFirstStep 128 << fGeometryLimitedStep << " ) " 129 << " mass= " << fFirstStepI 130 << fMassGeometryLimitedStep << " ) " 131 << " newTrack= " << fNewTrack << G4e 132 #endif 133 134 // fLastStepInVolume= false; 135 fNewTrack = false; 136 137 // Get initial Energy/Momentum of the track 138 // 139 const G4DynamicParticle* pParticle = tra 140 const G4ParticleDefinition* pParticleDef = 141 G4ThreeVector startMomentumDir = pPart 142 G4ThreeVector startPosition = track 143 G4VPhysicalVolume* currentVolume= track.GetV 144 145 #ifdef G4DEBUG_TRANSPORT 146 if( verboseLevel > 1 ) 147 { 148 G4cout << "G4CoupledTransportation::AlongS 149 << currentVolume->GetName() << G4en 150 } 151 #endif 152 // G4double theTime = track.GetGlob 153 154 // The Step Point safety can be limited by o 155 // assumptions of any process - it's not alw 156 // We calculate the starting point's isotrop 157 // 158 G4ThreeVector OriginShift = startPosition - 159 G4double MagSqShift = OriginShift.mag2 160 startFullSafety= 0.0; 161 162 // Recall that FullSafety <= MassSafety 163 // Original: if( MagSqShift < sqr(fPreviousM 164 if( MagSqShift < sqr(fPreviousFullSafety) ) 165 { 166 G4double mag_shift= std::sqrt(MagSqShift) 167 startFullSafety = std::max( (fPreviousFul 168 // Need to be consistent between full s 169 // in order reproduce results in simple 170 // --> use same calculation method 171 172 // Only compute full safety if massSafety 173 // startFullSafety = fPathFinder->Compute 174 } 175 176 // Is the particle charged or has it a magne 177 // 178 G4double particleCharge = pParticle->GetChar 179 G4double magneticMoment = pParticle->GetMagn 180 G4double restMass = pParticle->GetMass 181 182 fMassGeometryLimitedStep = false ; // Set d 183 fGeometryLimitedStep = false; 184 185 // There is no need to locate the current vo 186 // On track construction 187 // By the tracking, after all AlongStepDoI 188 189 // Check if the particle has a force, EM or 190 // 191 G4FieldManager* fieldMgr= nullptr; 192 G4bool fieldExertsForce = false ; 193 194 const G4Field* ptrField= nullptr; 195 196 fieldMgr = fFieldPropagator->FindAndSetField 197 G4bool eligibleEM = (particleCharge != 0.0) 198 || ( fUseMagneticMoment && 199 G4bool eligibleGrav = fUseGravity && (restM 200 201 if( (fieldMgr!=nullptr) && (eligibleEM||elig 202 { 203 // Message the field Manager, to configur 204 // 205 fieldMgr->ConfigureForTrack( &track ); 206 207 // The above call can transition from a n 208 // If the field manager has no field ptr, 209 // by definition ( = there is no field ! 210 // 211 ptrField= fieldMgr->GetDetectorField(); 212 213 if( ptrField != nullptr) 214 { 215 fieldExertsForce = eligibleEM 216 || ( eligibleGrav && ptrField->I 217 } 218 } 219 G4double momentumMagnitude = pParticle->GetT 220 221 if( fieldExertsForce ) 222 { 223 auto equationOfMotion= fFieldPropagator-> 224 225 G4ChargeState chargeState(particleCharge, 226 magneticMoment, 227 pParticleDef->G 228 if( equationOfMotion ) 229 { 230 equationOfMotion->SetChargeMomentumMas 231 232 233 } 234 #ifdef G4DEBUG_TRANSPORT 235 else 236 { 237 G4cerr << " ERROR in G4CoupledTranspor 238 << "Cannot find valid Equation 239 << " Unable to pass Charge, Mom 240 } 241 #endif 242 } 243 244 G4ThreeVector polarizationVec = track.GetPo 245 G4FieldTrack aFieldTrack = G4FieldTrack(sta 246 tra 247 tra 248 tra 249 res 250 par 251 pol 252 pPa 253 0.0 254 pPa 255 G4int stepNo= track.GetCurrentStepNumber(); 256 257 ELimited limitedStep; 258 G4FieldTrack endTrackState('a'); // Defaul 259 260 fMassGeometryLimitedStep = false ; // de 261 fGeometryLimitedStep = false; 262 if( currentMinimumStep > 0 ) 263 { 264 G4double newMassSafety= 0.0; // tem 265 266 // Do the Transport in the field (non re 267 // 268 lengthAlongCurve = fPathFinder->ComputeS 269 270 271 272 273 274 275 276 277 G4double newFullSafety= fPathFinder->Get 278 // this was estimated already in step 279 280 if( limitedStep == kUnique || limitedSte 281 { 282 fMassGeometryLimitedStep = true ; 283 } 284 285 fGeometryLimitedStep = (fPathFinder->Get 286 287 #ifdef G4DEBUG_TRANSPORT 288 if( fMassGeometryLimitedStep && !fGeomet 289 { 290 std::ostringstream message; 291 message << " ERROR in determining geom 292 message << " Limiting: mass=" << fMa 293 << " any= " << fGeometryLimite 294 message << "Incompatible conditions - 295 G4Exception("G4CoupledTransportation:: 296 "PathFinderConfused", Fata 297 } 298 #endif 299 300 geometryStepLength = std::min( lengthAlo 301 302 // Momentum: Magnitude and direction ca 303 // 304 fMomentumChanged = true ; 305 fTransportEndMomentumDir = endTrackState 306 307 // Remember last safety origin & value. 308 fPreviousSftOrigin = startPosition ; 309 fPreviousMassSafety = newMassSafety ; 310 fPreviousFullSafety = newFullSafety ; 311 // fpSafetyHelper->SetCurrentSafety( new 312 313 #ifdef G4DEBUG_TRANSPORT 314 if( verboseLevel > 1 ) 315 { 316 G4cout << "G4Transport:CompStep> " 317 << " called the pathfinder for 318 << " and obtained step = " << l 319 G4cout << " New safety (preStep) = " 320 } 321 #endif 322 323 // Store as best estimate value 324 startFullSafety = newFullSafety ; 325 326 // Get the End-Position and End-Momentum 327 fTransportEndPosition = endTrackState.Ge 328 fTransportEndKineticEnergy = endTrackSt 329 } 330 else 331 { 332 geometryStepLength = lengthAlongCurve= 333 fMomentumChanged = false ; 334 // fMassGeometryLimitedStep = false ; 335 // fGeometryLimitedStep = true; 336 fTransportEndMomentumDir = track.GetMome 337 fTransportEndKineticEnergy = track.GetK 338 339 fTransportEndPosition = startPosition; 340 341 endTrackState= aFieldTrack; // Ensures 342 } 343 // G4FieldTrack aTrackState(endTrackState); 344 345 if( !fieldExertsForce ) 346 { 347 fParticleIsLooping = false ; 348 fMomentumChanged = false ; 349 fEndGlobalTimeComputed = false ; 350 } 351 else 352 { 353 fParticleIsLooping = fFieldPropagator->I 354 355 #ifdef G4DEBUG_TRANSPORT 356 if( verboseLevel > 1 ) 357 { 358 G4cout << " G4CT::CS End Position = " 359 << fTransportEndPosition << G4e 360 G4cout << " G4CT::CS End Direction = " 361 << fTransportEndMomentumDir << 362 } 363 #endif 364 if( fFieldPropagator->GetCurrentFieldMan 365 { 366 // If the field can change energy, t 367 // - so this should have been upd 368 // 369 fCandidateEndGlobalTime = endTrack 370 fEndGlobalTimeComputed = true; 371 372 // was ( fCandidateEndGlobalTime != 373 // a cleaner way is to have FieldTra 374 // is updated 375 } 376 else 377 { 378 // The energy should be unchanged by 379 // - so the time changed will be 380 // 381 fEndGlobalTimeComputed = false; 382 383 #ifdef G4VERBOSE 384 // Check that the integration preser 385 // - and if not correct this! 386 G4double startEnergy= track.GetKine 387 G4double endEnergy= fTransportEndKi 388 389 G4double absEdiff = std::fabs(startE 390 if( (verboseLevel > 1) && ( absEdiff 391 { 392 ReportInexactEnergy(startEnergy, e 393 } // end of if (verboseLevel) 394 #endif 395 // Correct the energy for fields tha 396 // This - hides the integration err 397 // - but gives a better physic 398 fTransportEndKineticEnergy= track.Ge 399 } 400 } 401 402 fEndPointDistance = (fTransportEndPosition 403 fTransportEndSpin = endTrackState.GetSpin(); 404 405 // Calculate the safety 406 407 safetyProposal= startFullSafety; // used t 408 // Changed to accomodate processes that ca 409 410 // Update safety for the end-point, if becom 411 412 if( (startFullSafety < fEndPointDistance ) 413 && ( particleCharge != 0.0 ) ) // Onl 414 // && !fGeometryLimitedStep ) // To-Try: 415 { 416 G4double endFullSafety = 417 fPathFinder->ComputeSafety( fTransport 418 // Expected mission -- only mass geome 419 // fLinearNavigator->ComputeSafety( 420 // Yet discrete processes only have po 421 // currently revise the safety 422 // ==> so we use the all-geometry sa 423 424 fpSafetyHelper->SetCurrentSafety( endFul 425 // Pushing safety to Helper avoids rec 426 427 G4ThreeVector centerPt= G4ThreeVector(0. 428 G4double endMassSafety= fPathFinder->Obt 429 // Retrieves the mass value from Path 430 431 fPreviousMassSafety = endMassSafety ; 432 fPreviousFullSafety = endFullSafety; 433 fPreviousSftOrigin = fTransportEndPositi 434 435 // The convention (Stepping Manager's) i 436 // 437 safetyProposal = endFullSafety + fEndPoi 438 // --> was endMassSafety 439 // Changed to accomodate processes that 440 441 #ifdef G4DEBUG_TRANSPORT 442 G4int prec= G4cout.precision(12) ; 443 G4cout << "***CoupledTransportation::Alo 444 G4cout << " Revised Safety at endpoint 445 << " give safety values: Mass= 446 << " All= " << endFullSafety << 447 G4cout << " Adding endpoint distance " 448 << " to obtain pseudo-safety= " 449 G4cout.precision(prec); 450 } 451 else 452 { 453 G4int prec= G4cout.precision(12) ; 454 G4cout << "***CoupledTransportation::Alo 455 G4cout << " Quick Safety estimate at en 456 << fTransportEndPosition 457 << " gives safety endpoint valu 458 << startFullSafety - fEndPointDis 459 << " using start-point value " < 460 << " and endpointDistance " << f 461 G4cout.precision(prec); 462 #endif 463 } 464 465 proposedSafetyForStart= safetyProposal; 466 fParticleChange.ProposeTrueStepLength(geomet 467 468 return geometryStepLength ; 469 } 470 471 ////////////////////////////////////////////// 472 473 void G4CoupledTransportation:: 474 ReportMove( G4ThreeVector OldVector, G4ThreeVe 475 const G4String& Quantity ) 476 { 477 G4ThreeVector moveVec = ( NewVector - OldV 478 479 G4cerr << G4endl 480 << "******************************* 481 << G4endl; 482 G4cerr << "Endpoint has moved between valu 483 << " and value from Track in PostSt 484 << "Change of " << Quantity << " is 485 << " mm long, " 486 << " and its vector is " << (1.0/mm 487 << "Endpoint of ComputeStep was " < 488 << " and current position to locate 489 } 490 491 ////////////////////////////////////////////// 492 493 G4VParticleChange* G4CoupledTransportation::Po 494 495 { 496 G4TouchableHandle retCurrentTouchable ; // 497 498 // Initialize ParticleChange (by setting al 499 // to correspond 500 // fParticleChange.Initialize(track) ; // T 501 502 fParticleChange.ProposeTrackStatus(track.Get 503 504 if( fSignifyStepInAnyVolume ) 505 { 506 fParticleChange.ProposeFirstStepInVolume( 507 } 508 else 509 { 510 fParticleChange.ProposeFirstStepInVolume( 511 } 512 513 // Check that the end position and direction 514 // since call to AlongStepDoIt 515 516 #ifdef G4DEBUG_TRANSPORT 517 if( ( verboseLevel > 0 ) 518 && ((fTransportEndPosition - track.GetPos 519 { 520 ReportMove( track.GetPosition(), fTranspo 521 "End of Step Position" ); 522 G4cerr << " Problem in G4CoupledTransport 523 } 524 525 // If the Step was determined by the volume 526 // The pathFinder will know that the geometr 527 528 if( verboseLevel > 0 ) 529 { 530 G4cout << " Calling PathFinder::Locate() 531 << " G4CoupledTransportation::Post 532 G4cout << " fGeometryLimitedStep is " < 533 } 534 #endif 535 536 if(fGeometryLimitedStep) 537 { 538 fPathFinder->Locate( track.GetPosition(), 539 track.GetMomentumDire 540 true); 541 542 // fCurrentTouchable will now become the p 543 // and what was the previous will be freed 544 // (Needed because the preStepPoint can po 545 546 fCurrentTouchableHandle= 547 fPathFinder->CreateTouchableHandle( G4Tr 548 549 #ifdef G4DEBUG_TRANSPORT 550 if( verboseLevel > 1 ) 551 { 552 G4VPhysicalVolume* vol= fCurrentTouchab 553 G4cout << "CHECK !!!!!!!!!!! fCurrentTo 554 << vol; 555 if( vol ) { G4cout << "Name=" << vol->G 556 G4cout << G4endl; 557 } 558 #endif 559 560 // Check whether the particle is out of th 561 // If so it has exited and must be killed. 562 // 563 if( fCurrentTouchableHandle->GetVolume() = 564 { 565 fParticleChange.ProposeTrackStatus( fSt 566 } 567 retCurrentTouchable = fCurrentTouchableHan 568 // fParticleChange.SetTouchableHandle( fCu 569 } 570 else // fGeometryLimitedStep is false 571 { 572 #ifdef G4DEBUG_TRANSPORT 573 if( verboseLevel > 1 ) 574 { 575 G4cout << "G4CoupledTransportation::Post 576 << " fGeometryLimitedStep = " << 577 << " must be false " << G4endl; 578 } 579 #endif 580 // This serves only to move each of the Na 581 // 582 // fLinearNavigator->LocateGlobalPointWith 583 584 fPathFinder->ReLocate( track.GetPosition() 585 // track.GetMomentu 586 587 // Keep the value of the track's current T 588 // and use it to overwrite the (unset) on 589 // Expect this must be fCurrentTouchable t 590 // - could it be different, eg at the st 591 // 592 retCurrentTouchable = track.GetTouchableHa 593 // fParticleChange.SetTouchableHandle( tra 594 } // endif ( fGeometryLimitedStep ) 595 596 #ifdef G4DEBUG_NAVIGATION 597 G4cout << " CoupledTransport::AlongStep GPI 598 << " last-step: any= " << fGeometryL 599 << " mass= " << fMassGeometryLimitedS 600 #endif 601 602 if( fSignifyStepInAnyVolume ) 603 fParticleChange.ProposeLastStepInVolume(fG 604 else 605 fParticleChange.ProposeLastStepInVolume(f 606 607 SetTouchableInformation(retCurrentTouchable) 608 609 return &fParticleChange ; 610 } 611 612 ////////////////////////////////////////////// 613 // New method takes over the responsibility to 614 // G4CoupledTransportation object: 615 // - at the start of a new track, and 616 // - on the resumption of a suspended tra 617 // 618 void 619 G4CoupledTransportation::StartTracking(G4Track 620 { 621 G4Transportation::StartTracking(aTrack); 622 623 G4ThreeVector position = aTrack->GetPosition 624 G4ThreeVector direction = aTrack->GetMomentu 625 626 fPathFinder->PrepareNewTrack( position, dire 627 // This implies a call to fPathFinder->Locat 628 629 // reset safety value and center 630 // 631 fPreviousMassSafety = 0.0 ; 632 fPreviousFullSafety = 0.0 ; 633 fPreviousSftOrigin = G4ThreeVector(0.,0.,0.) 634 } 635 636 ////////////////////////////////////////////// 637 638 void 639 G4CoupledTransportation::EndTracking() 640 { 641 G4TransportationManager::GetTransportationMa 642 fPathFinder->EndTrack(); 643 // Resets TransportationManager to use ord 644 } 645 646 ////////////////////////////////////////////// 647 648 void 649 G4CoupledTransportation:: 650 ReportInexactEnergy(G4double startEnergy, G4do 651 { 652 static G4ThreadLocal G4int no_warnings= 0, w 653 moduloFactor= 10, 654 655 if( std::fabs(startEnergy- endEnergy) > perT 656 { 657 no_large_ediff ++; 658 if( (no_large_ediff% warnModulo) == 0 ) 659 { 660 no_warnings++; 661 std::ostringstream message; 662 message << "Energy change in Step is abo 663 << G4endl 664 << " Relative change in 'track 665 << std::setw(15) << (endEnergy-s 666 << G4endl 667 << " Starting E= " << std::set 668 << " MeV " << G4endl 669 << " Ending E= " << std::set 670 << " MeV " << G4endl 671 << "Energy has been corrected -- 672 << " field propagation parameter 673 if ( (verboseLevel > 2 ) || (no_warnings 674 || (no_large_ediff == warnModulo * mod 675 { 676 message << "These include EpsilonStepM 677 << G4endl 678 << "which determine fractional 679 << G4endl 680 << "Note also the influence of 681 << G4endl; 682 } 683 message << "Bad 'endpoint'. Energy chang 684 << G4endl 685 << "Has occurred already " << no 686 G4Exception("G4CoupledTransportation::Al 687 "EnergyChange", JustWarning, 688 if( no_large_ediff == warnModulo * modul 689 { 690 warnModulo *= moduloFactor; 691 } 692 } 693 } 694 } 695