Geant4 10.7.0
Toolkit for the simulation of the passage of particles through matter
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G4ParameterisedNavigation.cc
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1//
2// ********************************************************************
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24// ********************************************************************
25//
26// class G4ParameterisedNavigation Implementation
27//
28// Initial Author: P.Kent, 1996
29// Revisions:
30// J. Apostolakis 24 Nov 2005, Revised/fixed treatment of nested params
31// J. Apostolakis 4 Feb 2005, Reintroducting multi-level parameterisation
32// for materials only - see note 1 below
33// G. Cosmo 11 Mar 2004, Added Check mode
34// G. Cosmo 15 May 2002, Extended to 3-d voxelisation, made subclass
35// J. Apostolakis 5 Mar 1998, Enabled parameterisation of mat & solid type
36// --------------------------------------------------------------------
37
38// Note 1: Design/implementation note for extensions - JAp, March 1st, 2005
39// We cannot make the solid, dimensions and transformation dependent on
40// parent because the voxelisation will not have access to this.
41// So the following can NOT be done:
42// sampleSolid = curParam->ComputeSolid(num, curPhysical, pParentTouch);
43// sampleSolid->ComputeDimensions(curParam, num, curPhysical, pParentTouch);
44// curParam->ComputeTransformation(num, curPhysical, pParentTouch);
45
47#include "G4TouchableHistory.hh"
49
51
52// ********************************************************************
53// Constructor
54// ********************************************************************
55//
57{
58}
59
60// ***************************************************************************
61// Destructor
62// ***************************************************************************
63//
65{
66}
67
68// ***************************************************************************
69// ComputeStep
70// ***************************************************************************
71//
73 ComputeStep(const G4ThreeVector& localPoint,
74 const G4ThreeVector& localDirection,
75 const G4double currentProposedStepLength,
76 G4double& newSafety,
77 G4NavigationHistory& history,
78 G4bool& validExitNormal,
79 G4ThreeVector& exitNormal,
80 G4bool& exiting,
81 G4bool& entering,
82 G4VPhysicalVolume *(*pBlockedPhysical),
83 G4int& blockedReplicaNo)
84{
85 G4VPhysicalVolume *motherPhysical, *samplePhysical;
86 G4VPVParameterisation *sampleParam;
87 G4LogicalVolume *motherLogical;
88 G4VSolid *motherSolid, *sampleSolid;
89 G4ThreeVector sampleDirection;
90 G4double ourStep=currentProposedStepLength, ourSafety;
91 G4double motherSafety, motherStep = DBL_MAX;
92 G4bool motherValidExitNormal = false;
93 G4ThreeVector motherExitNormal;
94
95 G4int sampleNo;
96
97 G4bool initialNode, noStep;
98 G4SmartVoxelNode *curVoxelNode;
99 G4int curNoVolumes, contentNo;
100 G4double voxelSafety;
101
102 // Replication data
103 //
104 EAxis axis;
105 G4int nReplicas;
106 G4double width, offset;
107 G4bool consuming;
108
109 motherPhysical = history.GetTopVolume();
110 motherLogical = motherPhysical->GetLogicalVolume();
111 motherSolid = motherLogical->GetSolid();
112
113 //
114 // Compute mother safety
115 //
116
117 motherSafety = motherSolid->DistanceToOut(localPoint);
118 ourSafety = motherSafety; // Working isotropic safety
119
120#ifdef G4VERBOSE
121 if ( fCheck )
122 {
123 if( motherSafety < 0.0 )
124 {
125 motherSolid->DumpInfo();
126 std::ostringstream message;
127 message << "Negative Safety In Voxel Navigation !" << G4endl
128 << " Current solid " << motherSolid->GetName()
129 << " gave negative safety: " << motherSafety << G4endl
130 << " for the current (local) point " << localPoint;
131 G4Exception("G4ParameterisedNavigation::ComputeStep()",
132 "GeomNav0003", FatalException, message);
133 }
134 if( motherSolid->Inside(localPoint) == kOutside )
135 {
136 std::ostringstream message;
137 message << "Point is outside Current Volume !" << G4endl
138 << " Point " << localPoint
139 << " is outside current volume " << motherPhysical->GetName()
140 << G4endl;
141 G4double estDistToSolid = motherSolid->DistanceToIn(localPoint);
142 G4cout << " Estimated isotropic distance to solid (distToIn)= "
143 << estDistToSolid;
144 if( estDistToSolid > 100.0 * motherSolid->GetTolerance() )
145 {
146 motherSolid->DumpInfo();
147 G4Exception("G4ParameterisedNavigation::ComputeStep()",
148 "GeomNav0003", FatalException, message,
149 "Point is far outside Current Volume !");
150 }
151 else
152 {
153 G4Exception("G4ParameterisedNavigation::ComputeStep()",
154 "GeomNav1002", JustWarning, message,
155 "Point is a little outside Current Volume.");
156 }
157 }
158
159 // Compute early:
160 // a) to check whether point is (wrongly) outside
161 // (signaled if step < 0 or step == kInfinity )
162 // b) to check value against answer of daughters!
163 //
164 motherStep = motherSolid->DistanceToOut(localPoint,
165 localDirection,
166 true,
167 &motherValidExitNormal,
168 &motherExitNormal);
169
170 if( (motherStep >= kInfinity) || (motherStep < 0.0) )
171 {
172 // Error - indication of being outside solid !!
173 //
174 fLogger->ReportOutsideMother(localPoint, localDirection, motherPhysical);
175
176 ourStep = motherStep = 0.0;
177 exiting = true;
178 entering = false;
179
180 // If we are outside the solid does the normal make sense?
181 validExitNormal = motherValidExitNormal;
182 exitNormal = motherExitNormal;
183
184 *pBlockedPhysical = nullptr; // or motherPhysical ?
185 blockedReplicaNo = 0; // or motherReplicaNumber ?
186
187 newSafety = 0.0;
188 return ourStep;
189 }
190 }
191#endif
192
193 initialNode = true;
194 noStep = true;
195
196 // By definition, the parameterised volume is the first
197 // (and only) daughter of the mother volume
198 //
199 samplePhysical = motherLogical->GetDaughter(0);
200 samplePhysical->GetReplicationData(axis,nReplicas,width,offset,consuming);
201 fBList.Enlarge(nReplicas);
202 fBList.Reset();
203
204 // Exiting normal optimisation
205 //
206 if (exiting && (*pBlockedPhysical==samplePhysical) && validExitNormal)
207 {
208 if (localDirection.dot(exitNormal)>=kMinExitingNormalCosine)
209 {
210 // Block exited daughter replica; Must be on boundary => zero safety
211 //
212 fBList.BlockVolume(blockedReplicaNo);
213 ourSafety = 0;
214 }
215 }
216 exiting = false;
217 entering = false;
218
219 sampleParam = samplePhysical->GetParameterisation();
220
221 // Loop over voxels & compute daughter safeties & intersections
222
223 do
224 {
225 curVoxelNode = fVoxelNode;
226 curNoVolumes = curVoxelNode->GetNoContained();
227
228 for ( contentNo=curNoVolumes-1; contentNo>=0; contentNo-- )
229 {
230 sampleNo = curVoxelNode->GetVolume(contentNo);
231 if ( !fBList.IsBlocked(sampleNo) )
232 {
233 fBList.BlockVolume(sampleNo);
234
235 // Call virtual methods, and copy information if needed
236 //
237 sampleSolid = IdentifyAndPlaceSolid( sampleNo, samplePhysical,
238 sampleParam );
239
240 G4AffineTransform sampleTf(samplePhysical->GetRotation(),
241 samplePhysical->GetTranslation());
242 sampleTf.Invert();
243 const G4ThreeVector samplePoint = sampleTf.TransformPoint(localPoint);
244 const G4double sampleSafety = sampleSolid->DistanceToIn(samplePoint);
245 if ( sampleSafety<ourSafety )
246 {
247 ourSafety = sampleSafety;
248 }
249 if ( sampleSafety<=ourStep )
250 {
251 sampleDirection = sampleTf.TransformAxis(localDirection);
252 G4double sampleStep =
253 sampleSolid->DistanceToIn(samplePoint, sampleDirection);
254 if ( sampleStep<=ourStep )
255 {
256 ourStep = sampleStep;
257 entering = true;
258 exiting = false;
259 *pBlockedPhysical = samplePhysical;
260 blockedReplicaNo = sampleNo;
261#ifdef G4VERBOSE
262 // Check to see that the resulting point is indeed in/on volume.
263 // This check could eventually be made only for successful
264 // candidate.
265
266 if ( ( fCheck ) && ( sampleStep < kInfinity ) )
267 {
268 G4ThreeVector intersectionPoint;
269 intersectionPoint = samplePoint + sampleStep * sampleDirection;
270 EInside insideIntPt = sampleSolid->Inside(intersectionPoint);
271 if( insideIntPt != kSurface )
272 {
273 G4int oldcoutPrec = G4cout.precision(16);
274 std::ostringstream message;
275 message << "Navigator gets conflicting response from Solid."
276 << G4endl
277 << " Inaccurate solid DistanceToIn"
278 << " for solid " << sampleSolid->GetName() << G4endl
279 << " Solid gave DistanceToIn = "
280 << sampleStep << " yet returns " ;
281 if( insideIntPt == kInside )
282 message << "-kInside-";
283 else if( insideIntPt == kOutside )
284 message << "-kOutside-";
285 else
286 message << "-kSurface-";
287 message << " for this point !" << G4endl
288 << " Point = " << intersectionPoint
289 << G4endl;
290 if ( insideIntPt != kInside )
291 message << " DistanceToIn(p) = "
292 << sampleSolid->DistanceToIn(intersectionPoint);
293 if ( insideIntPt != kOutside )
294 message << " DistanceToOut(p) = "
295 << sampleSolid->DistanceToOut(intersectionPoint);
296 G4Exception("G4ParameterisedNavigation::ComputeStep()",
297 "GeomNav1002", JustWarning, message);
298 G4cout.precision(oldcoutPrec);
299 }
300 }
301#endif
302 }
303 }
304 }
305 }
306
307 if ( initialNode )
308 {
309 initialNode = false;
310 voxelSafety = ComputeVoxelSafety(localPoint,axis);
311 if ( voxelSafety<ourSafety )
312 {
313 ourSafety = voxelSafety;
314 }
315 if ( currentProposedStepLength<ourSafety )
316 {
317 // Guaranteed physics limited
318 //
319 noStep = false;
320 entering = false;
321 exiting = false;
322 *pBlockedPhysical = nullptr;
323 ourStep = kInfinity;
324 }
325 else
326 {
327 // Consider intersection with mother solid
328 //
329 if ( motherSafety<=ourStep )
330 {
331 if ( !fCheck )
332 {
333 motherStep = motherSolid->DistanceToOut(localPoint,
334 localDirection,
335 true,
336 &motherValidExitNormal,
337 &motherExitNormal);
338 }
339
340 if( ( motherStep < 0.0 ) || ( motherStep >= kInfinity) )
341 {
342#ifdef G4VERBOSE
343 fLogger->ReportOutsideMother(localPoint, localDirection,
344 motherPhysical);
345#endif
346 ourStep = motherStep = 0.0;
347 // Rely on the code below to set the remaining state, i.e.
348 // exiting, entering, exitNormal & validExitNormal,
349 // pBlockedPhysical etc.
350 }
351#ifdef G4VERBOSE
352 if( motherValidExitNormal && ( fCheck || (motherStep<=ourStep)) )
353 {
354 fLogger->CheckAndReportBadNormal(motherExitNormal,
355 localPoint, localDirection,
356 motherStep, motherSolid,
357 "From motherSolid::DistanceToOut");
358 }
359#endif
360 if ( motherStep<=ourStep )
361 {
362 ourStep = motherStep;
363 exiting = true;
364 entering = false;
365 if ( validExitNormal )
366 {
367 const G4RotationMatrix* rot = motherPhysical->GetRotation();
368 if (rot)
369 {
370 exitNormal *= rot->inverse();
371 }
372 }
373 }
374 else
375 {
376 validExitNormal = false;
377 }
378 }
379 }
380 newSafety = ourSafety;
381 }
382 if (noStep)
383 {
384 noStep = LocateNextVoxel(localPoint, localDirection, ourStep, axis);
385 }
386 } while (noStep);
387
388 return ourStep;
389}
390
391// ***************************************************************************
392// ComputeSafety
393// ***************************************************************************
394//
397 const G4NavigationHistory& history,
398 const G4double )
399{
400 G4VPhysicalVolume *motherPhysical, *samplePhysical;
401 G4VPVParameterisation *sampleParam;
402 G4LogicalVolume *motherLogical;
403 G4VSolid *motherSolid, *sampleSolid;
404 G4double motherSafety, ourSafety;
405 G4int sampleNo, curVoxelNodeNo;
406
407 G4SmartVoxelNode *curVoxelNode;
408 G4int curNoVolumes, contentNo;
409 G4double voxelSafety;
410
411 // Replication data
412 //
413 EAxis axis;
414 G4int nReplicas;
415 G4double width, offset;
416 G4bool consuming;
417
418 motherPhysical = history.GetTopVolume();
419 motherLogical = motherPhysical->GetLogicalVolume();
420 motherSolid = motherLogical->GetSolid();
421
422 //
423 // Compute mother safety
424 //
425
426 motherSafety = motherSolid->DistanceToOut(localPoint);
427 ourSafety = motherSafety; // Working isotropic safety
428
429 //
430 // Compute daughter safeties
431 //
432
433 // By definition, parameterised volumes exist as first
434 // daughter of the mother volume
435 //
436 samplePhysical = motherLogical->GetDaughter(0);
437 samplePhysical->GetReplicationData(axis, nReplicas,
438 width, offset, consuming);
439 sampleParam = samplePhysical->GetParameterisation();
440
441 // Look inside the current Voxel only at the current point
442 //
443 if ( axis==kUndefined ) // 3D case: current voxel node is retrieved
444 { // from G4VoxelNavigation.
445 curVoxelNode = fVoxelNode;
446 }
447 else // 1D case: current voxel node is computed here.
448 {
449 curVoxelNodeNo = G4int((localPoint(fVoxelAxis)
450 -fVoxelHeader->GetMinExtent()) / fVoxelSliceWidth );
451 curVoxelNode = fVoxelHeader->GetSlice(curVoxelNodeNo)->GetNode();
452 fVoxelNodeNo = curVoxelNodeNo;
453 fVoxelNode = curVoxelNode;
454 }
455 curNoVolumes = curVoxelNode->GetNoContained();
456
457 for ( contentNo=curNoVolumes-1; contentNo>=0; contentNo-- )
458 {
459 sampleNo = curVoxelNode->GetVolume(contentNo);
460
461 // Call virtual methods, and copy information if needed
462 //
463 sampleSolid= IdentifyAndPlaceSolid( sampleNo,samplePhysical,sampleParam );
464
465 G4AffineTransform sampleTf(samplePhysical->GetRotation(),
466 samplePhysical->GetTranslation());
467 sampleTf.Invert();
468 const G4ThreeVector samplePoint = sampleTf.TransformPoint(localPoint);
469 G4double sampleSafety = sampleSolid->DistanceToIn(samplePoint);
470 if ( sampleSafety<ourSafety )
471 {
472 ourSafety = sampleSafety;
473 }
474 }
475
476 voxelSafety = ComputeVoxelSafety(localPoint,axis);
477 if ( voxelSafety<ourSafety )
478 {
479 ourSafety=voxelSafety;
480 }
481
482 return ourSafety;
483}
484
485// ********************************************************************
486// ComputeVoxelSafety
487//
488// Computes safety from specified point to collected voxel boundaries
489// using already located point.
490// ********************************************************************
491//
492G4double G4ParameterisedNavigation::
493ComputeVoxelSafety(const G4ThreeVector& localPoint,
494 const EAxis pAxis) const
495{
496 // If no best axis is specified, adopt default
497 // strategy as for placements
498 //
499 if ( pAxis==kUndefined )
500 {
501 return G4VoxelNavigation::ComputeVoxelSafety(localPoint);
502 }
503
504 G4double voxelSafety, plusVoxelSafety, minusVoxelSafety;
505 G4double curNodeOffset, minCurCommonDelta, maxCurCommonDelta;
506 G4int minCurNodeNoDelta, maxCurNodeNoDelta;
507
508 // Compute linear intersection distance to boundaries of max/min
509 // to collected nodes at current level
510 //
511 curNodeOffset = fVoxelNodeNo*fVoxelSliceWidth;
512 minCurCommonDelta = localPoint(fVoxelAxis)
513 - fVoxelHeader->GetMinExtent()-curNodeOffset;
514 maxCurNodeNoDelta = fVoxelNode->GetMaxEquivalentSliceNo()-fVoxelNodeNo;
515 minCurNodeNoDelta = fVoxelNodeNo-fVoxelNode->GetMinEquivalentSliceNo();
516 maxCurCommonDelta = fVoxelSliceWidth-minCurCommonDelta;
517 plusVoxelSafety = minCurNodeNoDelta*fVoxelSliceWidth+minCurCommonDelta;
518 minusVoxelSafety = maxCurNodeNoDelta*fVoxelSliceWidth+maxCurCommonDelta;
519 voxelSafety = std::min(plusVoxelSafety,minusVoxelSafety);
520
521 if ( voxelSafety<0 )
522 {
523 voxelSafety = 0;
524 }
525
526 return voxelSafety;
527}
528
529// ********************************************************************
530// LocateNextVoxel
531//
532// Finds the next voxel from the current voxel and point
533// in the specified direction.
534//
535// Returns false if all voxels considered
536// true otherwise
537// [current Step ends inside same voxel or leaves all voxels]
538// ********************************************************************
539//
540G4bool G4ParameterisedNavigation::
541LocateNextVoxel( const G4ThreeVector& localPoint,
542 const G4ThreeVector& localDirection,
543 const G4double currentStep,
544 const EAxis pAxis)
545{
546 // If no best axis is specified, adopt default
547 // location strategy as for placements
548 //
549 if ( pAxis==kUndefined )
550 {
551 return G4VoxelNavigation::LocateNextVoxel(localPoint,
552 localDirection,
553 currentStep);
554 }
555
556 G4bool isNewVoxel;
557 G4int newNodeNo;
558 G4double minVal, maxVal, curMinExtent, curCoord;
559
560 curMinExtent = fVoxelHeader->GetMinExtent();
561 curCoord = localPoint(fVoxelAxis)+currentStep*localDirection(fVoxelAxis);
562 minVal = curMinExtent+fVoxelNode->GetMinEquivalentSliceNo()*fVoxelSliceWidth;
563 isNewVoxel = false;
564
565 if ( minVal<=curCoord )
566 {
567 maxVal = curMinExtent
568 + (fVoxelNode->GetMaxEquivalentSliceNo()+1)*fVoxelSliceWidth;
569 if ( maxVal<curCoord )
570 {
571 newNodeNo = fVoxelNode->GetMaxEquivalentSliceNo()+1;
572 if ( newNodeNo<G4int(fVoxelHeader->GetNoSlices()) )
573 {
574 fVoxelNodeNo = newNodeNo;
575 fVoxelNode = fVoxelHeader->GetSlice(newNodeNo)->GetNode();
576 isNewVoxel = true;
577 }
578 }
579 }
580 else
581 {
582 newNodeNo = fVoxelNode->GetMinEquivalentSliceNo()-1;
583
584 // Must locate from newNodeNo no and down to setup stack and fVoxelNode
585 // Repeat or earlier code...
586 //
587 if ( newNodeNo>=0 )
588 {
589 fVoxelNodeNo = newNodeNo;
590 fVoxelNode = fVoxelHeader->GetSlice(newNodeNo)->GetNode();
591 isNewVoxel = true;
592 }
593 }
594 return isNewVoxel;
595}
596
597// ********************************************************************
598// LevelLocate
599// ********************************************************************
600//
601G4bool
603 const G4VPhysicalVolume* blockedVol,
604 const G4int blockedNum,
605 const G4ThreeVector& globalPoint,
606 const G4ThreeVector* globalDirection,
607 const G4bool pLocatedOnEdge,
608 G4ThreeVector& localPoint )
609{
610 G4SmartVoxelHeader *motherVoxelHeader;
611 G4SmartVoxelNode *motherVoxelNode;
612 G4VPhysicalVolume *motherPhysical, *pPhysical;
613 G4VPVParameterisation *pParam;
614 G4LogicalVolume *motherLogical;
615 G4VSolid *pSolid;
616 G4ThreeVector samplePoint;
617 G4int voxelNoDaughters, replicaNo;
618
619 motherPhysical = history.GetTopVolume();
620 motherLogical = motherPhysical->GetLogicalVolume();
621 motherVoxelHeader = motherLogical->GetVoxelHeader();
622
623 // Find the voxel containing the point
624 //
625 motherVoxelNode = ParamVoxelLocate(motherVoxelHeader,localPoint);
626
627 voxelNoDaughters = motherVoxelNode->GetNoContained();
628 if ( voxelNoDaughters==0 ) { return false; }
629
630 pPhysical = motherLogical->GetDaughter(0);
631 pParam = pPhysical->GetParameterisation();
632
633 // Save parent history in touchable history
634 // ... for use as parent t-h in ComputeMaterial method of param
635 //
636 G4TouchableHistory parentTouchable( history );
637
638 // Search replicated daughter volume
639 //
640 for ( auto sampleNo=voxelNoDaughters-1; sampleNo>=0; sampleNo-- )
641 {
642 replicaNo = motherVoxelNode->GetVolume(sampleNo);
643 if ( (replicaNo!=blockedNum) || (pPhysical!=blockedVol) )
644 {
645 // Obtain solid (as it can vary) and obtain its parameters
646 //
647 pSolid = IdentifyAndPlaceSolid( replicaNo, pPhysical, pParam );
648
649 // Setup history
650 //
651 history.NewLevel(pPhysical, kParameterised, replicaNo);
652 samplePoint = history.GetTopTransform().TransformPoint(globalPoint);
653 if ( !G4AuxiliaryNavServices::CheckPointOnSurface( pSolid, samplePoint,
654 globalDirection, history.GetTopTransform(), pLocatedOnEdge) )
655 {
656 history.BackLevel();
657 }
658 else
659 {
660 // Enter this daughter
661 //
662 localPoint = samplePoint;
663
664 // Set the correct copy number in physical
665 //
666 pPhysical->SetCopyNo(replicaNo);
667
668 // Set the correct solid and material in Logical Volume
669 //
670 G4LogicalVolume *pLogical = pPhysical->GetLogicalVolume();
671 pLogical->SetSolid(pSolid);
672 pLogical->UpdateMaterial(pParam->ComputeMaterial(replicaNo,
673 pPhysical, &parentTouchable) );
674 return true;
675 }
676 }
677 }
678 return false;
679}
@ JustWarning
@ FatalException
void G4Exception(const char *originOfException, const char *exceptionCode, G4ExceptionSeverity severity, const char *description)
Definition: G4Exception.cc:35
double G4double
Definition: G4Types.hh:83
bool G4bool
Definition: G4Types.hh:86
int G4int
Definition: G4Types.hh:85
#define G4endl
Definition: G4ios.hh:57
G4GLOB_DLL std::ostream G4cout
double dot(const Hep3Vector &) const
HepRotation inverse() const
G4AffineTransform & Invert()
G4ThreeVector TransformPoint(const G4ThreeVector &vec) const
G4ThreeVector TransformAxis(const G4ThreeVector &axis) const
static G4bool CheckPointOnSurface(const G4VSolid *sampleSolid, const G4ThreeVector &localPoint, const G4ThreeVector *globalDirection, const G4AffineTransform &sampleTransform, const G4bool locatedOnEdge)
void BlockVolume(const G4int v)
void Enlarge(const G4int nv)
G4bool IsBlocked(const G4int v) const
G4VSolid * GetSolid() const
G4VPhysicalVolume * GetDaughter(const G4int i) const
void SetSolid(G4VSolid *pSolid)
G4SmartVoxelHeader * GetVoxelHeader() const
void UpdateMaterial(G4Material *pMaterial)
void NewLevel(G4VPhysicalVolume *pNewMother, EVolume vType=kNormal, G4int nReplica=-1)
const G4AffineTransform & GetTopTransform() const
G4VPhysicalVolume * GetTopVolume() const
G4bool CheckAndReportBadNormal(const G4ThreeVector &unitNormal, const G4ThreeVector &localPoint, const G4ThreeVector &localDirection, G4double step, const G4VSolid *solid, const char *msg) const
void ReportOutsideMother(const G4ThreeVector &localPoint, const G4ThreeVector &localDirection, const G4VPhysicalVolume *motherPV, G4double tDist=30.0 *CLHEP::cm) const
G4double ComputeStep(const G4ThreeVector &globalPoint, const G4ThreeVector &globalDirection, const G4double currentProposedStepLength, G4double &newSafety, G4NavigationHistory &history, G4bool &validExitNormal, G4ThreeVector &exitNormal, G4bool &exiting, G4bool &entering, G4VPhysicalVolume *(*pBlockedPhysical), G4int &blockedReplicaNo)
G4SmartVoxelNode * ParamVoxelLocate(G4SmartVoxelHeader *pHead, const G4ThreeVector &localPoint)
G4bool LevelLocate(G4NavigationHistory &history, const G4VPhysicalVolume *blockedVol, const G4int blockedNum, const G4ThreeVector &globalPoint, const G4ThreeVector *globalDirection, const G4bool pLocatedOnEdge, G4ThreeVector &localPoint)
G4double ComputeSafety(const G4ThreeVector &localPoint, const G4NavigationHistory &history, const G4double pProposedMaxLength=DBL_MAX)
G4double GetMinExtent() const
G4SmartVoxelProxy * GetSlice(G4int n) const
size_t GetNoSlices() const
G4int GetMaxEquivalentSliceNo() const
G4int GetVolume(G4int pVolumeNo) const
size_t GetNoContained() const
G4int GetMinEquivalentSliceNo() const
G4SmartVoxelNode * GetNode() const
virtual G4Material * ComputeMaterial(const G4int repNo, G4VPhysicalVolume *currentVol, const G4VTouchable *parentTouch=nullptr)
const G4RotationMatrix * GetRotation() const
virtual void SetCopyNo(G4int CopyNo)=0
const G4ThreeVector GetTranslation() const
G4LogicalVolume * GetLogicalVolume() const
virtual void GetReplicationData(EAxis &axis, G4int &nReplicas, G4double &width, G4double &offset, G4bool &consuming) const =0
const G4String & GetName() const
virtual G4VPVParameterisation * GetParameterisation() const =0
G4String GetName() const
G4double GetTolerance() const
virtual EInside Inside(const G4ThreeVector &p) const =0
virtual G4double DistanceToOut(const G4ThreeVector &p, const G4ThreeVector &v, const G4bool calcNorm=false, G4bool *validNorm=nullptr, G4ThreeVector *n=nullptr) const =0
void DumpInfo() const
virtual G4double DistanceToIn(const G4ThreeVector &p, const G4ThreeVector &v) const =0
G4NavigationLogger * fLogger
G4SmartVoxelNode * fVoxelNode
G4bool LocateNextVoxel(const G4ThreeVector &localPoint, const G4ThreeVector &localDirection, const G4double currentStep)
G4BlockingList fBList
G4double ComputeVoxelSafety(const G4ThreeVector &localPoint) const
EAxis
Definition: geomdefs.hh:54
@ kUndefined
Definition: geomdefs.hh:61
EInside
Definition: geomdefs.hh:67
@ kInside
Definition: geomdefs.hh:70
@ kOutside
Definition: geomdefs.hh:68
@ kSurface
Definition: geomdefs.hh:69
@ kParameterised
Definition: geomdefs.hh:86
#define DBL_MAX
Definition: templates.hh:62