CGAL 4.5.2 - 3D Mesh Generation
|
The concept MeshComplexWithFeatures_3InTriangulation_3
describes a data structure to represent and maintain a 3D complex embedded in a 3D triangulation. The concept MeshComplexWithFeatures_3InTriangulation_3
refines the minimal concept MeshComplex_3InTriangulation_3
, designed to represent 3D complexes having only faces with dimension 2 and 3. Therefore, the concept MeshComplexWithFeatures_3InTriangulation_3
may represent embedded complexes including features, i.e. faces with dimension \( 0\) and \( 1\).
The data structure includes a 3D triangulation which is itself a 3D complex. To distinguish the faces of the embedded 3D complex from the faces of the triangulation, we call respectively subdomains, surface patches curve segments and corners the faces of the complex with respective dimensions \( 3\), \( 2\), \( 1\) and \( 0\). The triangulations faces are called respectively cells, facets, edges and vertices.
Each subdomain of the embedded 3D complex is a union of triangulation cells. Likewise, each surface patch is a union of triangulation facets and each curve segment is a union of triangulation edges. The corners form a subset of the triangulation vertices. Note that subdomains, surface patches and and curved segments are not necessarily connected. Likewise each corner may be related to several mesh vertices. Triangulation facets that belong to some surface patch are called surface facets.
The concept MeshComplexWithFeatures_3InTriangulation_3
allows us to mark and retrieve the cells of the triangulation belonging to the subdomains, the facets of the triangulation belonging to surface patches, the edges belonging to curve segments and the vertices that are corners of the embedded complex.
Within the mesh generation functions, the concept MeshComplexWithFeatures_3InTriangulation_3
is the concept describing the data structure used to maintain the current approximation of the input domain. At the end of the meshing process, the data structure encodes the resulting mesh. In particular, each subdomain (resp. surface patch) of the input domain is then approximated by a subdomain (resp. a surface patch) of the embedded complex while the curve segments and corners represent the \( 1\) and \( 0\)-dimensional features of the input complex.
CGAL::Mesh_complex_3_in_triangulation_3<Tr,CornerIndex,CurveSegmentIndex>
Types | |
typedef unspecified_type | Curve_segment_index |
A type for indexes of curve segment. More... | |
typedef unspecified_type | Corner_index |
A type for indexes of corners. More... | |
typedef unspecified_type | Edges_in_complex_iterator |
An iterator type to visit the edges of the triangulation belonging to curve segments. | |
typedef unspecified_type | Vertices_in_complex_iterator |
An iterator type to visit the vertices of the triangulation that are corners of the embedded complex. | |
Modifiers | |
void | add_to_complex (Edge e, const Curve_segment_index &index) |
Adds edge e as an element of the curve segment with index index . | |
void | add_to_complex (const Vertex_handle &v1, const Vertex_handle &v2, const Curve_segment_index &index) |
Same as above with e=(v1,v2) . | |
void | add_to_complex (const Vertex_handle &v, const Corner_index &index) |
Marks vertex v as a corner with index index . | |
void | remove_from_complex (const Edge &e) |
Removes edge e from the embedded complex. | |
void | remove_from_complex (const Vertex_handle &v1, const Vertex_handle &v2) |
Same as above with e=(v1,v2) . | |
void | remove_from_complex (const Vertex_handle &v) |
Removes vertex v from the embedded complex. | |
Queries | |
size_type | number_of_edges () const |
Returns the number of edges which belong to curve segments. | |
size_type | number_of_edges (Curve_segment_index index) const |
Returns the number of edges which belong to curve segment with index index . | |
size_type | number_of_corners () const |
Returns the number of vertices which are corners of the complex. | |
size_type | number_of_corners (Corner_index index) const |
Returns the number of vertices which are corners of the complex with index index . | |
bool | is_in_complex (const Edge &e) const |
Returns true iff edge e belongs to some curve segment. | |
bool | is_in_complex (const Vertex_handle &v1, const Vertex_handle &v2) const |
Same as above with e=(v1,v2) . | |
bool | is_in_complex (const Vertex_handle &v) const |
Returns true if vertex v is a corner. | |
Curve_segment_index | curve_segment_index (const Edge &e) |
Returns Curve_segment_index of edge e . More... | |
Curve_segment_index | curve_segment_index (const Vertex_handle &v1, const Vertex_handle &v2) |
Same as above with e=(v1,v2) . | |
Corner_index | corner_index (const Vertex_handle &v) |
Returns Corner_index of vertex v . More... | |
Traversal of the complex | |
Edges_in_complex_iterator | edges_in_complex_begin () const |
Returns an Edges_in_complex_iterator to visit the edges of the triangulation belonging to curve segments. | |
Edge_in_complex_iterator | edges_in_complex_end () const |
Returns the past-the-end iterator for the above iterator. | |
Edges_in_complex_iterator | edges_in_complex_begin (Curve_segment_index index) const |
Returns an Edges_in_complex_iterator to visit the edges of the triangulation belonging to curve segments of index index . | |
Edge_in_complex_iterator | edges_in_complex_end (Curve_segment_index index) const |
Returns the past-the-end iterator for the above iterator. | |
template<typename OutputIterator > | |
OutputIterator | adjacent_vertices_in_complex (const Vertex_handle &v, OutputIterator out) const |
Fills out with the vertices of the triangulation that are adjacent to vertex v through an edge belonging to some curve segment. More... | |
Vertices_in_complex_iterator | vertices_in_complex_begin () const |
Returns a Vertices_in_complex_iterator to visit the vertices of the triangulation that are corners. | |
Vertices_in_complex_iterator | vertices_in_complex_end () const |
Returns the past-the-end iterator for the above iterator. | |
Vertices_in_complex_iterator | vertices_in_complex_begin (Corner_index index) const |
Returns a Vertices_in_complex_iterator to visit the vertices of the triangulation that are corners of index index . | |
Vertices_in_complex_iterator | vertices_in_complex_end (Corner_index index) const |
Returns the past-the-end iterator for the above iterator. | |
A type for indexes of corners.
The type must match the type MeshDomainWithFeatures_3::Corner_index
when the concept is used for mesh generation.
A type for indexes of curve segment.
The type must match the type MeshDomainWithFeatures_3::Curve_segment_index
when the concept is used for mesh generation.
OutputIterator MeshComplexWithFeatures_3InTriangulation_3::adjacent_vertices_in_complex | ( | const Vertex_handle & | v, |
OutputIterator | out | ||
) | const |
Fills out
with the vertices of the triangulation that are adjacent to vertex v
through an edge belonging to some curve segment.
The value type of out
must be std::pair<Vertex_handle,Curve_segment_index>
.
c3t3.in_dimension(v) < 2
Corner_index MeshComplexWithFeatures_3InTriangulation_3::corner_index | ( | const Vertex_handle & | v) |
Returns Corner_index
of vertex v
.
The default Corner_index
value is returned if vertex v
is not a corner of the complex.
Curve_segment_index MeshComplexWithFeatures_3InTriangulation_3::curve_segment_index | ( | const Edge & | e) |
Returns Curve_segment_index
of edge e
.
The default Curve_segment_index
value is returned if edge e
does not belong to any curve segment.