CGAL 6.0.1 - 2D and 3D Linear Geometry Kernel
|
Functions | |
template<typename Kernel > | |
decltype(auto) | CGAL::intersection (Type1< Kernel > obj1, Type2< Kernel > obj2) |
Two objects obj1 and obj2 intersect if there is a point p that is part of both obj1 and obj2 . | |
template<typename Kernel > | |
decltype(auto) | CGAL::intersection (const Plane_3< Kernel > &pl1, const Plane_3< Kernel > &pl2, const Plane_3< Kernel > &pl3) |
returns the intersection of 3 planes, which can be a point, a line, a plane, or empty. | |
decltype(auto) CGAL::intersection | ( | Type1< Kernel > | obj1, |
Type2< Kernel > | obj2 | ||
) |
#include <CGAL/intersections.h>
Two objects obj1
and obj2
intersect if there is a point p
that is part of both obj1
and obj2
.
The intersection region of those two objects is defined as the set of all points p
that are part of both obj1
and obj2
. Note that for objects like triangles and polygons that enclose a bounded region, this region is considered part of the object. If a segment lies completely inside a triangle, then those two objects intersect and the intersection region is the complete segment.
Here, Intersect_23
means either Intersect_2
or Intersect_3
, depending on the arguments.
The following tables give the possible values for Type1
and Type2
.
2D Intersections
The return type of intersecting two objects of the types Type1
and Type2
can be specified through the placeholder type specifier auto
. It is equivalent to std::optional< std::variant< T... > >
, the last column in the table providing the template parameter pack.
Type1 | Type2 | Return Type: T... |
---|---|---|
Iso_rectangle_2 | Iso_rectangle_2 | |
Iso_rectangle_2 | Line_2 | Point_2, or Segment_2 |
Iso_rectangle_2 | Ray_2 | Point_2, or Segment_2 |
Iso_rectangle_2 | Segment_2 | Point_2, or Segment_2 |
Iso_rectangle_2 | Triangle_2 | Point_2, or Segment_2, or Triangle_2, or std::vector<Point_2> |
Line_2 | Line_2 | Point_2, or Line_2 |
Line_2 | Ray_2 | Point_2, or Ray_2 |
Line_2 | Segment_2 | Point_2, or Segment_2 |
Line_2 | Triangle_2 | Point_2, or Segment_2 |
Ray_2 | Ray_2 | Point_2, or Segment_2, or Ray_2 |
Ray_2 | Segment_2 | Point_2, or Segment_2 |
Ray_2 | Triangle_2 | Point_2, or Segment_2 |
Segment_2 | Segment_2 | Point_2, or Segment_2 |
Segment_2 | Triangle_2 | Point_2, or Segment_2 |
Triangle_2 | Triangle_2 | Point_2, or Segment_2, or Triangle_2, or std::vector<Point_2> |
Additional overloads are provided for the type Point_2
combined with any other type with the result type being std::optional< std::variant< Point_2 > >
. Overloads are also provided for the type Bbox_2
, for all intersections existing with the type Iso_rectangle_2
. Note that the return type for Bbox_2
- Bbox_2
is Bbox_2
and not Iso_rectangle_2
.
3D Intersections
The return type of intersecting two objects of the types Type1
and Type2
can be specified through the placeholder type specifier auto
. It is equivalent to std::optional< std::variant< T... > >
, the last column in the table providing the template parameter pack.
Additional overloads are provided for the type Point_3
combined with any other type with the result type being std::optional< std::variant< Point_3 > >
. Overloads are also provided for the type Bbox_3
, for all intersections existing with the type Iso_cuboid_3
. Note that the return type for Bbox_3
- Bbox_3
is Bbox_3
and not Iso_cuboid_3
.
Examples
The following examples demonstrate the most common use of intersection()
functions with the 2D and 3D Linear Kernel.
In the first two examples we intersect a segment and a line. The result type can be specified through the placeholder type specifier auto
, but you must anyway know that the result type is a std::optional<std::variant<..> >
, in order to unpack the point or segment.
std::optional
comes in as there might be no intersection. std::variant
comes in as, if there is an intersection, it is either a point or a segment.
As explained in the boost manual pages for std::variant
, there are two ways to access the variants. The first examples uses boost::get
.
File Kernel_23/intersection_get.cpp
The second example uses std::visit
.
File Kernel_23/intersection_visitor.cpp
A third example shows the use of the intersection function as a plain function call and with Dispatch_output_iterator
, combined with a standard library algorithm.
File Kernel_23/intersections.cpp