Kaspar Fischer, Bernd Gärtner, Thomas Herrmann, Michael Hoffmann, and Sven Schönherr

This package provides algorithms for computing the distance between the convex hulls of two point sets in d-dimensional space, without explicitly constructing the convex hulls. It further provides an algorithm to compute the width of a point set, and the furthest point for each vertex of a convex polygon.

Introduced in: CGAL 1.1
BibTeX: cgal:fghhs-od-21a
License: GPL

Assertions

The optimization code uses infix OPTIMISATION in the assertions, e.g. defining the compiler flag CGAL_OPTIMISATION_NO_PRECONDITIONS switches precondition checking off, cf. Section Checks.

Classified Reference Pages

All Furthest Neighbors

Width

Polytope Distance

CGAL::Polytope_distance_d<Traits>
CGAL::Polytope_distance_d_traits_2<K,ET,NT>
CGAL::Polytope_distance_d_traits_3<K,ET,NT>
CGAL::Polytope_distance_d_traits_d<K,ET,NT>
PolytopeDistanceDTraits

Modules
	Concepts

Classes
class	CGAL::Polytope_distance_d< Traits >
	An object of the class `Polytope_distance_d` represents the (squared) distance between two convex polytopes, given as the convex hulls of two finite point sets in \( d\)-dimensional Euclidean space \( \E^d\). More...

class	CGAL::Polytope_distance_d_traits_2< K, ET, NT >
	The class `Polytope_distance_d_traits_2` is a traits class for the \( d\)-dimensional optimisation algorithms using the two-dimensional CGAL kernel. More...

class	CGAL::Polytope_distance_d_traits_3< K, ET, NT >
	The class `Polytope_distance_d_traits_3` is a traits class for the \( d\)-dimensional optimisation algorithms using the three-dimensional CGAL kernel. More...

class	CGAL::Polytope_distance_d_traits_d< K, ET, NT >
	The class `Polytope_distance_d_traits_d` is a traits class for the \( d\)-dimensional optimisation algorithms using the \( d\)-dimensional CGAL kernel. More...

class	CGAL::Width_3< Traits >
	Given a set of points \( \mathcal{S}=\left\{p_1,\ldots , p_n\right\}\) in \( \mathbb{R}^3\). More...

class	CGAL::Width_default_traits_3< K >
	The class `Width_default_traits_3` is a traits class for `Width_3<Traits>` using the three-dimensional CGAL kernel. More...

Functions
template<class RandomAccessIterator , class OutputIterator , class Traits >
OutputIterator	CGAL::all_furthest_neighbors_2 (RandomAccessIterator points_begin, RandomAccessIterator points_end, OutputIterator o, Traits t=Default_traits)
	computes all furthest neighbors for the vertices of the convex polygon described by the range [`points_begin`, `points_end`), writes their indices (relative to `points_begin`) to `o`the furthest neighbor of `points_begin[i]` is `points_begin[i-th number written to o]` and returns the past-the-end iterator of this sequence. More...

Function Documentation

◆ all_furthest_neighbors_2()

template<class RandomAccessIterator , class OutputIterator , class Traits >

OutputIterator CGAL::all_furthest_neighbors_2	(	RandomAccessIterator	points_begin,
		RandomAccessIterator	points_end,
		OutputIterator	o,
		Traits	t = `Default_traits`
	)

#include <CGAL/all_furthest_neighbors_2.h>

computes all furthest neighbors for the vertices of the convex polygon described by the range [points_begin, points_end), writes their indices (relative to points_begin) to othe furthest neighbor of points_begin[i] is points_begin[i-th number written to o] and returns the past-the-end iterator of this sequence.

The function all_furthest_neighbors_2() computes all furthest neighbors for the vertices of a convex polygon \( P\), i.e. for each vertex \( v\) of \( P\) a vertex \( f_v\) of \( P\) such that the distance between \( v\) and \( f_v\) is maximized.

Precondition: The points denoted by the non-empty range [points_begin, points_end) form the boundary of a convex polygon \( P\) (oriented clock- or counterclockwise).

The geometric types and operations to be used for the computation are specified by the traits class parameter t. This parameter can be omitted if RandomAccessIterator refers to a point type from a Kernel. In this case, the kernel is used as default traits class.

Requires

If t is specified explicitly, Traits is a model for AllFurthestNeighborsTraits_2.
Value type of RandomAccessIterator is Traits::Point_2 or, if t is not specified explicitly, K::Point_2 where K is a model for Kernel.
OutputIterator accepts int as value type.

See also: AllFurthestNeighborsTraits_2; CGAL::monotone_matrix_search()

Implementation

The implementation uses monotone matrix search [1]. Its runtime complexity is linear in the number of vertices of \( P\).

Example

The following code generates a random convex polygon p with ten vertices, computes all furthest neighbors and writes the sequence of their indices (relative to points_begin) to cout (e.g. a sequence of 4788911224 means the furthest neighbor of points_begin[0] is points_begin[4], the furthest neighbor of points_begin[1] is points_begin[7] etc.).

File Polytope_distance_d/all_furthest_neighbors_2.cpp

#include <CGAL/Cartesian.h>
#include <CGAL/Polygon_2.h>
#include <CGAL/point_generators_2.h>
#include <CGAL/random_convex_set_2.h>
#include <CGAL/all_furthest_neighbors_2.h>
#include <CGAL/IO/Ostream_iterator.h>
#include <iostream>
#include <vector>
typedef double                                    FT;
typedef CGAL::Cartesian<FT>                       Kernel;
typedef Kernel::Point_2                           Point;
typedef std::vector<int>                          Index_cont;
typedef CGAL::Polygon_2<Kernel>                   Polygon_2;
typedef CGAL::Random_points_in_square_2<Point>    Generator;
typedef CGAL::Ostream_iterator<int,std::ostream>  Oiterator;
int main()
{
  // generate random convex polygon:
  Polygon_2 p;
  CGAL::random_convex_set_2(10, std::back_inserter(p), Generator(1));
  // compute all furthest neighbors:
  CGAL::all_furthest_neighbors_2(p.vertices_begin(), p.vertices_end(),
                                 Oiterator(std::cout));
  std::cout << std::endl;
  return 0;
}

Examples:: Polytope_distance_d/all_furthest_neighbors_2.cpp.