CGAL::Mesh_complex_3_in_triangulation_3< Tr, CornerIndex, CurveIndex > Class Template Reference

#include <CGAL/Mesh_complex_3_in_triangulation_3.h>

Definition

template<typename Tr, typename CornerIndex, typename CurveIndex>
class CGAL::Mesh_complex_3_in_triangulation_3< Tr, CornerIndex, CurveIndex >

A data structure to represent and maintain a 3D complex embedded in a 3D triangulation.

The class Mesh_complex_3_in_triangulation_3 implements a data structure to store the 3D restricted Delaunay triangulation used by a mesh generation process.

This class is a model of the concept MeshComplexWithFeatures_3InTriangulation_3.

Template Parameters

Tr	can be instantiated with any 3D triangulation of CGAL provided that its vertex and cell base class are models of the concepts SimplicialMeshVertexBase_3 and SimplicialMeshCellBase_3, respectively.
CornerIndex	Type of indices for corners (i.e. \( 0\)–dimensional features) of the discretized geometric domain. It must be a model of CopyConstructible, Assignable, DefaultConstructible and LessThanComparable. It must match the Corner_index of the model of the MeshDomainWithFeatures_3 concept when used for mesh generation.
CurveIndex	Type of indices for curves (i.e. \( 1\)-dimensional features) of the discretized geometric domain. It must be a model of CopyConstructible, Assignable, DefaultConstructible and LessThanComparable. The default constructed value must be the value for an edge which does not approximate a 1-dimensional feature of the geometric domain. It must match the Curve_index types of the model of the MeshDomainWithFeatures_3 concept when used for mesh generation.

Those two last template parameters default to int, so that they can be ignored if the domain used for mesh generation does not include 0 and 1-dimensionnal features (i.e is only a model of the concept MeshDomain_3).

Is model of

MeshComplexWithFeatures_3InTriangulation_3

See also

CGAL::make_mesh_3()

CGAL::refine_mesh_3()

MeshComplex_3InTriangulation_3

MeshComplexWithFeatures_3InTriangulation_3

SimplicialMeshCellBase_3,

SimplicialMeshVertexBase_3

Examples

SMDS_3/c3t3_example.cpp, and SMDS_3/tetrahedron_soup_to_c3t3_example.cpp.

Public Member Functions
void	remove_isolated_vertices ()
	The tetrahedral mesh generation algorithm implemented in CGAL::make_mesh_3() and CGAL::refine_mesh_3() does not guarantee that all the points inserted by the algorithm are actually present in the final mesh.
template<typename OutputIterator >
OutputIterator	adjacent_vertices_in_complex (const Vertex_handle &v, OutputIterator out) const
	fills out with incident edges (1-dimensional features of v).
bool	has_incident_facets_in_complex (const Vertex_handle &v) const
	Returns true if the vertex v has is incident to at least a facet of the complex.

Types
typedef Tr	Triangulation
typedef Tr::size_type	size_type
typedef Tr::Point	Point
typedef Tr::Edge	Edge
typedef Tr::Facet	Facet
typedef Tr::Vertex_handle	Vertex_handle
typedef Tr::Cell_handle	Cell_handle
typedef Tr::Vertex::Index	Index
	Index type.
typedef Tr::Cell::Surface_patch_index	Surface_patch_index
	Surface index type.
typedef Tr::Cell::Subdomain_index	Subdomain_index
	Subdomain index type.
typedef CornerIndex	Corner_index
	Corner index type.
typedef CurveIndex	Curve_index
	Curve index type.

Traversal of the complex
typedef unspecified_type	Cells_in_complex_iterator
	Iterator type to visit the cells of the 3D complex.
typedef unspecified_type	Facets_in_complex_iterator
	Iterator type to visit the facets of the 2D complex.
typedef unspecified_type	Edges_in_complex_iterator
	Iterator type to visit the edges of the 1D complex.
typedef unspecified_type	Vertices_in_complex_iterator
	Iterator type to visit the vertices of the 0D complex.
typedef Iterator_range< unspecified_type >	Cells_in_complex
	Range type for iterating over all cells of the 3D complex, with a nested type iterator that has as value type Cell_handle.
typedef Iterator_range< unspecified_type >	Facets_in_complex
	Range type for iterating over all facets of the 2D complex, with a nested type iterator that has as value type Facet.
typedef Iterator_range< unspecified_type >	Edges_in_complex
	Range type for iterating over all cells of the 1D complex, with a nested type iterator that has as value type Edge.
typedef Iterator_range< unspecified_type >	Vertices_in_complex
	Range type for iterating over all vertices of the 0D complex, with a nested type iterator that has as value type Vertex_handle.

Creation
	Mesh_complex_3_in_triangulation_3 ()
	Constructor builds an empty 3D complex.
	Mesh_complex_3_in_triangulation_3 (const Self &rhs)
	Copy constructor.
	Mesh_complex_3_in_triangulation_3 (Self &&rhs)
	Move constructor.
Self &	operator= (Self rhs)
	Assignment operator, also serves as move-assignment.
void	swap (Self &rhs)
	swaps this and rhs

Access Functions
const Triangulation &	triangulation () const
	returns a const reference to the triangulation

Non const access
Triangulation &	triangulation ()
	returns a reference to the triangulation

Modifiers
void	clear ()
	clears data of the complex
void	add_to_complex (const Cell_handle &cell, const Subdomain_index &index)
	adds cell cell to the 3D complex, with subdomain index index
void	add_to_complex (const Facet &facet, const Surface_patch_index &index)
	adds facet facet to the 2D complex, with surface index index
void	add_to_complex (const Cell_handle &cell, const int i, const Surface_patch_index &index)
	adds facet(cell, i) to the 2D complex, with surface index index
void	add_to_complex (const Edge &e, const Curve_index &index)
	adds edge e to complex, with curve index index
void	add_to_complex (const Vertex_handle &v1, const Vertex_handle &v2, const Curve_index &index)
	adds edge (v1, v2) to the 1D complex, with Curve_index index
void	add_to_complex (const Vertex_handle &v, const Corner_index &index)
	marks vertex v as a corner of the complex
void	remove_from_complex (const Cell_handle &cell)
	removes cell cell from the 3D complex
void	remove_from_complex (const Facet &facet)
	removes facet facet from the 2D complex
void	remove_from_complex (const Cell_handle &c, const int i)
	removes facet(cell, i) from the 2D complex
void	remove_from_complex (const Edge &e)
	removes edge e from the 1D complex
void	remove_from_complex (const Vertex_handle &v1, const Vertex_handle &v2)
	removes edge (v1,v2) from the 1D complex
void	remove_from_complex (const Vertex_handle &v)
	removes vertex v from the complex
void	set_index (const Vertex_handle &vertex, const Index &index) const
	sets the index of vertex vertex to index
void	set_surface_patch_index (const Facet &f, const Surface_patch_index &index)
	sets the surface index of facet facet to index
void	set_surface_patch_index (const Cell_handle &cell, const int i, const Surface_patch_index &index) const
	sets the surface index of facet(cell, i) to index
void	set_subdomain_index (const Cell_handle &cell, const Subdomain_index &index) const
	sets the subdomain index of cell cell to index
void	set_dimension (const Vertex_handle &vertex, int dimension) const
	sets the dimension of vertex vertex to dimension

Queries on the identifier of the face complex including triangulation cells, facets, and vertices.
Index	index (const Vertex_handle &v) const
	returns the index of vertex v
Subdomain_index	subdomain_index (const Cell_handle &cell) const
	returns the subdomain index of cell cell
Surface_patch_index	surface_patch_index (const Facet &f) const
	returns the surface index of facet f
Surface_patch_index	surface_patch_index (const Cell_handle &cell, const int i) const
	returns the surface index of facet(cell, i)
int	in_dimension (const Vertex_handle &v) const
	returns the dimension of the lowest dimensional face of the input 3D complex that contains the vertex
Curve_index	curve_index (const Edge &e) const
	returns the curve index of edge e
Curve_index	curve_index (const Vertex_handle &v1, const Vertex_handle &v2) const
	returns the curve index of the edge formed by v1 and v2
Corner_index	corner_index (const Vertex_handle &v) const
	returns the corner index of vertex v

Queries on the faces of the embedded complex
size_type	number_of_cells_in_complex () const
	returns the number of cells which belong to the 3D complex
size_type	number_of_cells () const
	returns the number of cells which belong to the 3D complex
size_type	number_of_facets_in_complex () const
	returns the number of surface facets of the complex
size_type	number_of_facets () const
	returns the number of surface facets of the complex
size_type	number_of_edges_in_complex () const
	returns the number of edges of the complex
size_type	number_of_edges () const
	returns the number of edges of the complex
size_type	number_of_vertices_in_complex () const
	returns the number of corners of the complex
size_type	number_of_corners () const
	returns the number of corners of the complex
bool	is_in_complex (const Cell_handle &cell) const
	returns true if cell cell belongs to the 3D complex
bool	is_in_complex (const Facet &facet) const
	returns true if facet facet belongs to the 2D complex
bool	is_in_complex (const Cell_handle &cell, const int i) const
	returns true if facet (cell, i) belongs to the 2D complex
bool	is_in_complex (const Edge &e) const
	returns true if edge e belongs to the 1D complex
bool	is_in_complex (const Vertex_handle &v1, const Vertex_handle &v2) const
	returns true if edge (v1,v2) belongs to the 1D complex
bool	is_in_complex (const Vertex_handle &v) const
	returns true if v is a 0-dimensionnal feature in the complex

I/O Functions
std::ostream &	output_boundary_to_off (std::ostream &out) const
	outputs the outer boundary of the entire domain, with facets oriented outward.
std::ostream &	output_boundary_to_off (std::ostream &out, Subdomain_index subdomain) const
	outputs the outer boundary of the selected subdomain, with facets oriented outward.
std::ostream &	output_facets_in_complex_to_off (std::ostream &out) const
	outputs the surface facets, with a consistent orientation at the interface of two subdomains.
void	output_to_medit (std::ostream &os) const
	outputs the mesh to os in Medit format.
void	output_to_maya (std::ostream &os, bool surfaceOnly=true) const

Iterators
Cells_in_complex_iterator	cells_in_complex_begin () const
	returns a Cells_in_complex_iterator to the first cell of the 3D complex
Cells_in_complex_iterator	cells_in_complex_begin (const Subdomain_index &index) const
	returns a Cells_in_complex_iterator to the first cell of the 3D complex
Cells_in_complex_iterator	cells_in_complex_end () const
	returns the past-the-end iterator for the cells of the 3D complex
Facets_in_complex_iterator	facets_in_complex_begin () const
	returns a Facets_in_complex_iterator to the first facet of the 2D complex
Facets_in_complex_iterator	facets_in_complex_begin (const Surface_patch_index &index) const
	returns a Facets_in_complex_iterator to the first facet of the 2D complex
Facets_in_complex_iterator	facets_in_complex_end (const Surface_patch_index=Surface_patch_index()) const
	returns past-the-end iterator on facet of the 2D complex
Edges_in_complex_iterator	edges_in_complex_begin () const
	returns a Edges_in_complex_iterator to the first edge of the 1D complex
Edges_in_complex_iterator	edges_in_complex_begin (const Curve_index &index) const
	returns a Edges_in_complex_iterator to the first edge of the 1D complex
Edges_in_complex_iterator	edges_in_complex_end (const Curve_index &=Curve_index()) const
	returns past-the-end iterator on edges of the 1D complex
Vertices_in_complex_iterator	vertices_in_complex_begin () const
	returns a Vertices_in_complex_iterator to the first vertex of the 0D complex
Vertices_in_complex_iterator	vertices_in_complex_begin (const Corner_index &index) const
	returns a Vertices_in_complex_iterator to the first vertex of the 0D complex
Vertices_in_complex_iterator	vertices_in_complex_end () const
	returns past-the-end iterator on vertices of the 0D complex
Vertices_in_complex	vertices_in_complex () const
	returns a range of iterators over vertices of the 0D complex
Edges_in_complex	edges_in_complex () const
	returns a range of iterators over the edges of the 1D complex, starting at an arbitrary edge.
Facets_in_complex	facets_in_complex () const
	returns a range of iterators over the facets of the 2D complex, starting at an arbitrary facet.
Cells_in_complex	cells_in_complex () const
	returns a range of iterators over cells of the 3D complex.

Member Function Documentation

adjacent_vertices_in_complex()

template<typename Tr , typename CI_ , typename CSI_ >

template<typename OutputIterator >

OutputIterator CGAL::Mesh_complex_3_in_triangulation_3< Tr, CI_, CSI_ >::adjacent_vertices_in_complex	(	const Vertex_handle &	v,
		OutputIterator	out
	)		const

fills out with incident edges (1-dimensional features of v).

OutputIterator value type is std::pair<Vertex_handle,Curve_index>

Precondition

v->in_dimension() < 2

cells_in_complex()

template<typename Tr , typename CornerIndex , typename CurveIndex >

Cells_in_complex CGAL::Mesh_complex_3_in_triangulation_3< Tr, CornerIndex, CurveIndex >::cells_in_complex

(

)

const

returns a range of iterators over cells of the 3D complex.

Returns an empty range when triangulation().number_of_cells() == 0 or complex is empty.

Note

The value type of Cells_in_complex::iterator is Cell_handle.

edges_in_complex()

template<typename Tr , typename CornerIndex , typename CurveIndex >

Edges_in_complex CGAL::Mesh_complex_3_in_triangulation_3< Tr, CornerIndex, CurveIndex >::edges_in_complex

(

)

const

returns a range of iterators over the edges of the 1D complex, starting at an arbitrary edge.

Returns an empty range when t.dimension() < 2.

facets_in_complex()

template<typename Tr , typename CornerIndex , typename CurveIndex >

Facets_in_complex CGAL::Mesh_complex_3_in_triangulation_3< Tr, CornerIndex, CurveIndex >::facets_in_complex

(

)

const

returns a range of iterators over the facets of the 2D complex, starting at an arbitrary facet.

Returns an empty range when t.dimension() < 2.

remove_isolated_vertices()

template<typename Tr , typename CornerIndex , typename CurveIndex >

void CGAL::Mesh_complex_3_in_triangulation_3< Tr, CornerIndex, CurveIndex >::remove_isolated_vertices

(

)

The tetrahedral mesh generation algorithm implemented in CGAL::make_mesh_3() and CGAL::refine_mesh_3() does not guarantee that all the points inserted by the algorithm are actually present in the final mesh.

In most cases, all points are used, but if the geometry of the object has small features compared to the size of the simplices (triangles and tetrahedra), it might be that the Delaunay facets that are selected in the restricted Delaunay triangulation miss some vertices of the triangulation. The concurrent version of the tetrahedral mesh generation algorithm also inserts a small set of auxiliary vertices that belong to the triangulation but are isolated from the complex at the end of the meshing process.

This function removes these so-called isolated vertices, that belong to the triangulation but not to any simplex of the C3T3, from the triangulation.

vertices_in_complex()

template<typename Tr , typename CornerIndex , typename CurveIndex >

Vertices_in_complex CGAL::Mesh_complex_3_in_triangulation_3< Tr, CornerIndex, CurveIndex >::vertices_in_complex

(

)

const

returns a range of iterators over vertices of the 0D complex

Note

The value type of Vertices_in_complex::iterator is Vertex_handle.