1 // Copyright (C) 2007-2021 CEA/DEN, EDF R&D, OPEN CASCADE
3 // Copyright (C) 2003-2007 OPEN CASCADE, EADS/CCR, LIP6, CEA/DEN,
4 // CEDRAT, EDF R&D, LEG, PRINCIPIA R&D, BUREAU VERITAS
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14 // Lesser General Public License for more details.
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18 // Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA
20 // See http://www.salome-platform.org/ or email : webmaster.salome@opencascade.com
22 // File : SMESH_MeshAlgos.hxx
23 // Created : Tue Apr 30 18:00:36 2013
24 // Author : Edward AGAPOV (eap)
26 // Initially this file held some low level algorithms extracted from SMESH_MeshEditor
27 // to make them accessible from Controls package, and more
30 #ifndef __SMESH_MeshAlgos_HXX__
31 #define __SMESH_MeshAlgos_HXX__
33 #include "SMESH_Utils.hxx"
35 #include "SMDSAbs_ElementType.hxx"
36 #include "SMDS_ElemIterator.hxx"
37 #include "SMESH_TypeDefs.hxx"
39 #include <TopAbs_State.hxx>
48 class SMDS_MeshElement;
52 //=======================================================================
54 * \brief Searcher for the node closest to a point
56 //=======================================================================
58 struct SMESHUtils_EXPORT SMESH_NodeSearcher
60 virtual const SMDS_MeshNode* FindClosestTo( const gp_Pnt& pnt ) = 0;
61 virtual void MoveNode( const SMDS_MeshNode* node, const gp_Pnt& toPnt ) = 0;
62 virtual int FindNearPoint(const gp_Pnt& point,
63 const double tolerance,
64 std::vector< const SMDS_MeshNode* >& foundNodes) = 0;
65 virtual ~SMESH_NodeSearcher() {}
68 //=======================================================================
70 * \brief Searcher for elements
72 //=======================================================================
74 struct SMESHUtils_EXPORT SMESH_ElementSearcher
77 * \brief Find elements of given type where the given point is IN or ON.
78 * Returns nb of found elements and elements them-selves.
80 * 'ALL' type means elements of any type excluding nodes and 0D elements
82 virtual int FindElementsByPoint(const gp_Pnt& point,
83 SMDSAbs_ElementType type,
84 std::vector< const SMDS_MeshElement* >& foundElems) = 0;
86 * \brief Return an element most close to the given point
88 virtual const SMDS_MeshElement* FindClosestTo( const gp_Pnt& point,
89 SMDSAbs_ElementType type) = 0;
91 * \brief Return elements possibly intersecting the line
93 virtual void GetElementsNearLine( const gp_Ax1& line,
94 SMDSAbs_ElementType type,
95 std::vector< const SMDS_MeshElement* >& foundElems) = 0;
97 * \brief Return elements whose bounding box intersects a sphere
99 virtual void GetElementsInSphere( const gp_XYZ& center,
101 SMDSAbs_ElementType type,
102 std::vector< const SMDS_MeshElement* >& foundElems) = 0;
104 * \brief Return elements whose bounding box intersects a given bounding box
106 virtual void GetElementsInBox( const Bnd_B3d& box,
107 SMDSAbs_ElementType type,
108 std::vector< const SMDS_MeshElement* >& foundElems) = 0;
110 * \brief Find out if the given point is out of closed 2D mesh.
112 virtual TopAbs_State GetPointState(const gp_Pnt& point) = 0;
115 * \brief Return a projection of a given point to a 2D mesh.
116 * Optionally return the closest face
118 virtual gp_XYZ Project(const gp_Pnt& point,
119 SMDSAbs_ElementType type,
120 const SMDS_MeshElement** closestFace= 0) = 0;
122 virtual ~SMESH_ElementSearcher();
125 namespace SMESH_MeshAlgos
128 * \brief Return SMESH_NodeSearcher. The caller is responsible for deleting it
131 SMESH_NodeSearcher* GetNodeSearcher( SMDS_Mesh& mesh );
134 SMESH_NodeSearcher* GetNodeSearcher( SMDS_ElemIteratorPtr elemIt );
137 * \brief Return SMESH_ElementSearcher. The caller is responsible for deleting it
140 SMESH_ElementSearcher* GetElementSearcher( SMDS_Mesh& mesh,
141 double tolerance=-1.);
143 SMESH_ElementSearcher* GetElementSearcher( SMDS_Mesh& mesh,
144 SMDS_ElemIteratorPtr elemIt,
145 double tolerance=-1. );
149 * \brief Return true if the point is IN or ON of the element
152 bool IsOut( const SMDS_MeshElement* element, const gp_Pnt& point, double tol );
155 double GetDistance( const SMDS_MeshElement* elem, const gp_Pnt& point, gp_XYZ* closestPnt = 0 );
158 double GetDistance( const SMDS_MeshEdge* edge, const gp_Pnt& point, gp_XYZ* closestPnt = 0 );
161 double GetDistance( const SMDS_MeshFace* face, const gp_Pnt& point, gp_XYZ* closestPnt = 0 );
164 double GetDistance( const SMDS_MeshVolume* volume, const gp_Pnt& point, gp_XYZ* closestPnt = 0 );
167 void GetBarycentricCoords( const gp_XY& point,
168 const gp_XY& t0, const gp_XY& t1, const gp_XY& t2,
169 double & bc0, double & bc1);
172 * Return a face having linked nodes n1 and n2 and which is
174 * - in elemSet provided that !elemSet.empty()
175 * i1 and i2 optionally returns indices of n1 and n2
178 const SMDS_MeshElement* FindFaceInSet(const SMDS_MeshNode* n1,
179 const SMDS_MeshNode* n2,
180 const TIDSortedElemSet& elemSet,
181 const TIDSortedElemSet& avoidSet,
185 * \brief Calculate normal of a mesh face
188 bool FaceNormal(const SMDS_MeshElement* F, gp_XYZ& normal, bool normalized=true);
191 * \brief Return number of nodes common to two elements
194 int NbCommonNodes(const SMDS_MeshElement* e1,
195 const SMDS_MeshElement* e2);
197 * \brief Return nodes common to two elements
200 std::vector< const SMDS_MeshNode*> GetCommonNodes(const SMDS_MeshElement* e1,
201 const SMDS_MeshElement* e2);
203 * \brief Return true if a node is on a boundary of 2D mesh.
204 * Optionally returns two neighboring boundary nodes (or more in non-manifold mesh)
206 SMESHUtils_EXPORT bool IsOn2DBoundary( const SMDS_MeshNode* node,
207 std::vector< const SMDS_MeshNode*> * neibors = nullptr );
209 * \brief Return true if node1 encounters first in the face and node2, after.
210 * The nodes are supposed to be neighbor nodes in the face.
213 bool IsRightOrder( const SMDS_MeshElement* face,
214 const SMDS_MeshNode* node0,
215 const SMDS_MeshNode* node1 );
217 typedef std::vector< std::vector< const SMDS_MeshElement* > > TElemGroupVector;
218 typedef std::vector< std::vector< const SMDS_MeshNode* > > TNodeGroupVector;
220 * \brief Partition given 1D elements into groups of contiguous edges.
221 * A node where number of meeting edges != 2 is a group end.
222 * An optional startNode is used to orient groups it belongs to.
223 * \return a list of edge groups and a list of corresponding node groups.
224 * If a group is closed, the first and last nodes of the group are same.
227 void Get1DBranches( SMDS_ElemIteratorPtr edgeIt,
228 TElemGroupVector& edgeGroups,
229 TNodeGroupVector& nodeGroups,
230 const SMDS_MeshNode* startNode = 0 );
233 * \brief Mark elements given by SMDS_Iterator
234 * \sa SMDS_Mesh::SetAllNodesNotMarked() and SMDS_Mesh::SetAllCellsNotMarked()
236 template< class ElemIter >
237 void MarkElems( ElemIter it, const bool isMarked )
239 while ( it->more() ) it->next()->setIsMarked( isMarked );
242 * \brief Mark elements given by std iterators
244 template< class ElemIter >
245 void MarkElems( ElemIter it, ElemIter end, const bool isMarked )
247 for ( ; it != end; ++it ) (*it)->setIsMarked( isMarked );
250 * \brief Mark nodes of elements given by SMDS_Iterator
252 template< class ElemIter >
253 void MarkElemNodes( ElemIter it, const bool isMarked, const bool markElem = false )
256 while ( it->more() ) {
257 const SMDS_MeshElement* e = it->next();
258 e->setIsMarked( isMarked );
259 MarkElems( e->nodesIterator(), isMarked );
263 MarkElems( it->next()->nodesIterator(), isMarked );
266 * \brief Mark elements given by std iterators
268 template< class ElemIter >
269 void MarkElemNodes( ElemIter it, ElemIter end, const bool isMarked, const bool markElem = false )
272 for ( ; it != end; ++it ) {
273 (*it)->setIsMarked( isMarked );
274 MarkElems( (*it)->nodesIterator(), isMarked );
277 for ( ; it != end; ++it )
278 MarkElems( (*it)->nodesIterator(), isMarked );
281 // 2 nodes + optional medium node
284 const SMDS_MeshNode* _node1;
285 const SMDS_MeshNode* _node2;
286 const SMDS_MeshNode* _medium;
290 * Return sharp edges of faces and non-manifold ones.
291 * Optionally adds existing edges to the result. Angle is in degrees.
294 std::vector< Edge > FindSharpEdges( SMDS_Mesh* mesh,
299 * Distribute all faces of the mesh between groups using given edges.
302 std::vector< std::vector< const SMDS_MeshElement* > >
303 SeparateFacesByEdges( SMDS_Mesh* mesh, const std::vector< Edge >& edges );
306 typedef std::vector<const SMDS_MeshNode*> TFreeBorder;
307 typedef std::vector<TFreeBorder> TFreeBorderVec;
308 struct TFreeBorderPart
310 int _border; // border index within a TFreeBorderVec
311 int _node1; // node index within the border-th TFreeBorder
315 typedef std::vector<TFreeBorderPart> TCoincidentGroup;
316 typedef std::vector<TCoincidentGroup> TCoincidentGroupVec;
317 struct CoincidentFreeBorders
319 TFreeBorderVec _borders; // nodes of all free borders
320 TCoincidentGroupVec _coincidentGroups; // groups of coincident parts of borders
324 * Returns TFreeBorder's coincident within the given tolerance.
325 * If the tolerance <= 0.0 then one tenth of an average size of elements adjacent
326 * to free borders being compared is used.
329 void FindCoincidentFreeBorders(SMDS_Mesh& mesh,
331 CoincidentFreeBorders & foundFreeBordes);
332 // Implemented in ./SMESH_FreeBorders.cxx
335 * Returns all or only closed TFreeBorder's.
336 * Optionally check if the mesh is manifold and if faces are correctly oriented.
339 void FindFreeBorders(SMDS_Mesh& mesh,
340 TFreeBorderVec & foundFreeBordes,
341 const bool closedOnly,
342 bool* isManifold = 0,
343 bool* isGoodOri = 0);
344 // Implemented in ./SMESH_FreeBorders.cxx
347 * Fill a hole defined by a TFreeBorder with 2D elements.
350 void FillHole(const TFreeBorder & freeBorder,
352 std::vector<const SMDS_MeshElement*>& newFaces);
353 // Implemented in ./SMESH_FillHole.cxx
356 * \brief Find nodes whose merge makes the element invalid
359 void DeMerge(const SMDS_MeshElement* elem,
360 std::vector< const SMDS_MeshNode* >& newNodes,
361 std::vector< const SMDS_MeshNode* >& noMergeNodes);
362 // Implemented in SMESH_DeMerge.cxx
365 typedef std::vector< std::pair< const SMDS_MeshElement*, int > > TElemIntPairVec;
366 typedef std::vector< std::pair< const SMDS_MeshNode*, int > > TNodeIntPairVec;
368 * \brief Create an offset mesh of given faces
369 * \param [in] faceIt - the input faces
370 * \param [in] theFixIntersections - to fix self intersections of the offset mesh or not
371 * \param [out] new2OldFaces - history of faces
372 * \param [out] new2OldNodes - history of nodes
373 * \return SMDS_Mesh* - the new offset mesh, a caller should delete
376 SMDS_Mesh* MakeOffset( SMDS_ElemIteratorPtr faceIt,
379 const bool theFixIntersections,
380 TElemIntPairVec& new2OldFaces,
381 TNodeIntPairVec& new2OldNodes );
382 // Implemented in ./SMESH_Offset.cxx
385 //=======================================================================
387 * \brief Cut faces of a triangular mesh.
388 * Usage work-flow: 1) call Cut() methods as many times as needed
389 * 2) call MakeNewFaces() to really modify the mesh faces
391 //=======================================================================
392 // implemented in SMESH_Offset.cxx
394 class SMESHUtils_EXPORT Intersector
397 Intersector( SMDS_Mesh* mesh, double tol, const std::vector< gp_XYZ >& normals );
400 //! Compute cut of two faces of the mesh
401 void Cut( const SMDS_MeshElement* face1,
402 const SMDS_MeshElement* face2,
403 const int nbCommonNodes = -1 );
405 //! Store a face cut by a line given by its ends lying either on face edges or inside the face.
406 // Line ends are accompanied by indices of intersected face edges.
407 // Edge index is <0 if a line end is inside the face.
408 void Cut( const SMDS_MeshElement* face,
409 SMESH_NodeXYZ& lineEnd1,
411 SMESH_NodeXYZ& lineEnd2,
414 //! Split all faces intersected by Cut() methods.
415 // theSign = (-1|1) is used to choose which part of a face cut by another one to remove.
416 // 1 means to remove a part opposite to face normal.
417 // Optionally optimize quality of split faces by edge swapping.
418 void MakeNewFaces( SMESH_MeshAlgos::TElemIntPairVec& theNew2OldFaces,
419 SMESH_MeshAlgos::TNodeIntPairVec& theNew2OldNodes,
420 const double theSign = 1.,
421 const bool theOptimize = false );
423 typedef std::vector< SMESH_NodeXYZ > TFace;
425 //! Cut a face by planes, whose normals point to parts to keep.
426 // Return true if the whole face is cut off
427 static bool CutByPlanes(const SMDS_MeshElement* face,
428 const std::vector< gp_Ax1 > & planes,
430 std::vector< TFace > & newFaceConnectivity );
437 //=======================================================================
439 * \brief Divide a mesh face into triangles
441 //=======================================================================
442 // Implemented in ./SMESH_Triangulate.cxx
444 class SMESHUtils_EXPORT Triangulate
448 Triangulate(bool optimize=false);
451 static int GetNbTriangles( const SMDS_MeshElement* face );
453 int GetTriangles( const SMDS_MeshElement* face,
454 std::vector< const SMDS_MeshNode*>& nodes);
457 bool triangulate( std::vector< const SMDS_MeshNode*>& nodes, const size_t nbNodes );
464 Optimizer* _optimizer;
467 // structure used in MakePolyLine() to define a cutting plane
470 // 2 points, each defined as follows:
471 // ( myNode1 && myNode2 ) ==> point is in the middle of an edge defined by two nodes
472 // ( myNode1 && !myNode2 ) ==> point is at myNode1 of a some face
473 // else ==> point is at myXYZ
474 const SMDS_MeshNode* myNode1[2];
475 const SMDS_MeshNode* myNode2[2];
478 // face on which myXYZ projects (found by MakePolyLine())
479 const SMDS_MeshElement* myFace [2];
481 // vector on the plane; to use a default plane set vector = (0,0,0)
484 // point returning coordinates of a middle of the two points, projected to mesh
485 gp_Pnt myMidProjPoint;
487 typedef std::vector<PolySegment> TListOfPolySegments;
490 * \brief Create a polyline consisting of 1D mesh elements each lying on a 2D element of
491 * the initial mesh. Positions of new nodes are found by cutting the mesh by the
492 * plane passing through pairs of points specified by each PolySegment structure.
493 * If there are several paths connecting a pair of points, the shortest path is
494 * selected by the module. Position of the cutting plane is defined by the two
495 * points and an optional vector lying on the plane specified by a PolySegment.
496 * By default the vector is defined by Mesh module as following. A middle point
497 * of the two given points is computed. The middle point is projected to the mesh.
498 * The vector goes from the middle point to the projection point. In case of planar
499 * mesh, the vector is normal to the mesh.
500 * \param [inout] segments - PolySegment's defining positions of cutting planes.
501 * Return the used vector and position of the middle point.
502 * \param [in] group - an optional group where created mesh segments will
505 // Implemented in ./SMESH_PolyLine.cxx
507 void MakePolyLine( SMDS_Mesh* mesh,
508 TListOfPolySegments& segments,
509 std::vector<const SMDS_MeshElement*>& newEdges,
510 std::vector<const SMDS_MeshNode*>& newNodes,
511 SMDS_MeshGroup* group=0,
512 SMESH_ElementSearcher* searcher=0);
515 * Create a slot of given width around given 1D elements lying on a triangle mesh.
516 * The slot is constructed by cutting faces by cylindrical surfaces made around each segment.
517 * \return Edges located at the slot boundary
519 // Implemented in ./SMESH_Slot.cxx
521 std::vector< Edge > MakeSlot( SMDS_ElemIteratorPtr segmentIt,
524 std::vector< SMDS_MeshGroup* > & groupsToUpdate);
526 } // namespace SMESH_MeshAlgos