CGAL 5.2.4 - 3D Fast Intersection and Distance Computation (AABB Tree)
User Manual

Authors
Pierre Alliez, Stephane Tayeb, and Camille Wormser

Introduction

The AABB tree component offers a static data structure and algorithms to perform efficient intersection and distance queries against sets of finite 3D geometric objects. The set of geometric objects stored in the data structure can be queried for intersection detection, intersection computation and distance. The intersection queries can be of any type, provided that the corresponding intersection predicates and constructors are implemented in the traits class. The distance queries are limited to point queries. Examples of intersection queries include line objects (rays, lines, segments) against sets of triangles, or plane objects (planes, triangles) against sets of segments. An example of a distance query consists of finding the closest point from a point query to a set of triangles.

Note that this component is not suited to the problem of finding all intersecting pairs of objects. We refer to the component Intersecting Sequences of dD Iso-oriented Boxes which can find all intersecting pairs of iso-oriented boxes.

The AABB tree data structure takes as input an iterator range of geometric data, which is then converted into primitives. From these primitives a hierarchy of axis-aligned bounding boxes (AABBs) is constructed and used to speed up intersection and distance queries. Each primitive gives access to both one input geometric object (so-called datum) and one reference id to this object. A typical example primitive wraps a 3D triangle as datum and a face handle of a polyhedral surface as id. Each intersection query can return the intersection objects (e.g., 3D points or segments for ray queries) as well as the id (here the face handle) of the intersected primitives. Similarly, each distance query can return the closest point from the point query as well as the id of the closest primitive.

anchor.png
Figure 88.1 Left: surface triangle mesh of a mechanical part. Right: AABB tree constructed.

Interface

The main entry point to the component is the class AABB_tree which represents a static AABB tree constructed from an iterator range of geometric data. Once instantiated an AABB tree can be queried for intersection and distance queries.

Intersections. Assume for example that the tree contains triangle primitives. The tree can be queried for intersection against line objects (rays, segments or line) in various ways. We distinguish intersection tests which do not construct any intersection objects, from intersections which construct the intersection objects.

Tests:

  • Function AABB_tree::do_intersect() tests if the input primitives are intersected by the query. This function is fast as it involves only predicates and stops after the first encountered intersection.
  • Function AABB_tree::number_of_intersected_primitives() counts all intersected primitives.
  • Function AABB_tree::all_intersected_primitives() enumerates all intersected primitives ids without constructing the corresponding intersection objects.
  • Function AABB_tree::any_intersected_primitive() returns the first encountered intersecting primitive id (if any) without constructing the corresponding intersection object, and stops after the first encountered intersection. Note that the traversal order of the tree is such that first herein does not refer to any particular ordering of the intersections with respect to the query.
  • Function AABB_tree::first_intersected_primitive() returns the intersecting primitive id (if any) of the corresponding intersection object that is closest to the source of the ray.

Constructions:

  • Function AABB_tree::all_intersections() detects and constructs all intersection objects with the input primitives.
  • Function AABB_tree::any_intersection() detects and constructs the first encountered intersection and constructs the corresponding object. This function is fast as it stops after the first encountered intersection.
  • Function AABB_tree::first_intersection() detects and constructs the intersection object that is closest to the source of the ray.

Distance. An AABB tree computes the closest point from a given point query to the input primitives through the function AABB_tree::closest_point(). In addition, it can compute the id of the closest primitive from a given point query through the function AABB_tree::closest_point_and_primitive(), i.e., the id of the primitive which realizes the minimum distance from the point query. The AABB tree uses a secondary search structure to speed up the distance queries. The construction of this secondary structure should be requested by the user by a call to AABB_tree::accelerate_distance_queries() before the first the distance computation. This data structure is not generated by default because it is used only for distance computations.

Warning
Having degenerate primitives in the AABB-tree is not recommended as the underlying predicates and constructions of the traits class might not be able to handle them. For example if one is using CGAL::AABB_traits with a Kernel from CGAL, having degenerate triangles or segments in the AABB-tree will results in an undefined behavior or a crash.

Examples

Tree of Triangles, for Intersection and Distance Queries

In the following example a set of 3D triangles is stored in a list. The AABB primitive wraps a triangle as datum and an iterator in the list as id. We compute the number of input triangles intersected by a ray query, as well as the closest point and the squared distance from a point query.


File AABB_tree/AABB_triangle_3_example.cpp

// Author(s) : Camille Wormser, Pierre Alliez
#include <iostream>
#include <list>
#include <CGAL/Simple_cartesian.h>
#include <CGAL/AABB_tree.h>
#include <CGAL/AABB_traits.h>
#include <CGAL/AABB_triangle_primitive.h>
typedef K::FT FT;
typedef K::Ray_3 Ray;
typedef K::Line_3 Line;
typedef K::Point_3 Point;
typedef K::Triangle_3 Triangle;
typedef std::list<Triangle>::iterator Iterator;
typedef CGAL::AABB_traits<K, Primitive> AABB_triangle_traits;
int main()
{
Point a(1.0, 0.0, 0.0);
Point b(0.0, 1.0, 0.0);
Point c(0.0, 0.0, 1.0);
Point d(0.0, 0.0, 0.0);
std::list<Triangle> triangles;
triangles.push_back(Triangle(a,b,c));
triangles.push_back(Triangle(a,b,d));
triangles.push_back(Triangle(a,d,c));
// constructs AABB tree
Tree tree(triangles.begin(),triangles.end());
// counts #intersections
Ray ray_query(a,b);
std::cout << tree.number_of_intersected_primitives(ray_query)
<< " intersections(s) with ray query" << std::endl;
// compute closest point and squared distance
Point point_query(2.0, 2.0, 2.0);
Point closest_point = tree.closest_point(point_query);
std::cerr << "closest point is: " << closest_point << std::endl;
FT sqd = tree.squared_distance(point_query);
std::cout << "squared distance: " << sqd << std::endl;
return EXIT_SUCCESS;
}

Tree of Polyhedron Triangle Facets for Intersection Queries

In the following example the AABB primitive wraps a facet handle of a triangle polyhedral surface as id and the corresponding 3D triangle as geometric object. From a segment query we test the intersections, then compute the number of intersections, compute the first encountered intersection (generally a point), compute all intersections (where each intersection is a pair of one CGAL object and one primitive id - here a face handle) and compute all intersected primitives. The latter involves only tests and no predicates and is hence faster than computing all intersections. We also compute the first encountered intersection with a plane query, which is generally a segment. We finally compute the first intersection along a ray.


File AABB_tree/AABB_polyhedron_facet_intersection_example.cpp

// Author(s) : Camille Wormser, Pierre Alliez
#include <iostream>
#include <list>
#include <CGAL/Simple_cartesian.h>
#include <CGAL/AABB_tree.h>
#include <CGAL/AABB_traits.h>
#include <CGAL/Polyhedron_3.h>
#include <CGAL/AABB_face_graph_triangle_primitive.h>
typedef K::Point_3 Point;
typedef K::Plane_3 Plane;
typedef K::Vector_3 Vector;
typedef K::Segment_3 Segment;
typedef K::Ray_3 Ray;
typedef CGAL::Polyhedron_3<K> Polyhedron;
typedef boost::optional< Tree::Intersection_and_primitive_id<Segment>::Type > Segment_intersection;
typedef boost::optional< Tree::Intersection_and_primitive_id<Plane>::Type > Plane_intersection;
typedef Tree::Primitive_id Primitive_id;
int main()
{
Point p(1.0, 0.0, 0.0);
Point q(0.0, 1.0, 0.0);
Point r(0.0, 0.0, 1.0);
Point s(0.0, 0.0, 0.0);
Polyhedron polyhedron;
polyhedron.make_tetrahedron(p, q, r, s);
// constructs AABB tree
Tree tree(faces(polyhedron).first, faces(polyhedron).second, polyhedron);
// constructs segment query
Point a(-0.2, 0.2, -0.2);
Point b(1.3, 0.2, 1.3);
Segment segment_query(a,b);
// tests intersections with segment query
if(tree.do_intersect(segment_query))
std::cout << "intersection(s)" << std::endl;
else
std::cout << "no intersection" << std::endl;
// computes #intersections with segment query
std::cout << tree.number_of_intersected_primitives(segment_query)
<< " intersection(s)" << std::endl;
// computes first encountered intersection with segment query
// (generally a point)
Segment_intersection intersection =
tree.any_intersection(segment_query);
if(intersection)
{
// gets intersection object
const Point* p = boost::get<Point>(&(intersection->first));
if(p)
std::cout << "intersection object is a point " << *p << std::endl;
}
// computes all intersections with segment query (as pairs object - primitive_id)
std::list<Segment_intersection> intersections;
tree.all_intersections(segment_query, std::back_inserter(intersections));
// computes all intersected primitives with segment query as primitive ids
std::list<Primitive_id> primitives;
tree.all_intersected_primitives(segment_query, std::back_inserter(primitives));
// constructs plane query
Vector vec(0.0,0.0,1.0);
Plane plane_query(a,vec);
// computes first encountered intersection with plane query
// (generally a segment)
Plane_intersection plane_intersection = tree.any_intersection(plane_query);
if(plane_intersection)
{
if(boost::get<Segment>(&(plane_intersection->first)))
std::cout << "intersection object is a segment" << std::endl;
}
return EXIT_SUCCESS;
}

Ray Shooting

In the following example we load a closed polyhedral surface and perform a ray shooting query from the centroid of each face, orthogonally to the face towards the interior. As the centroid is computed with floating point arithmetic the first face hit by the ray may be the face of the centroid. The skip functor takes care of ignoring the face.


File AABB_tree/AABB_ray_shooting_example.cpp

#include <iostream>
#include <fstream>
#include <CGAL/Simple_cartesian.h>
#include <CGAL/AABB_tree.h>
#include <CGAL/AABB_traits.h>
#include <CGAL/Surface_mesh.h>
#include <CGAL/AABB_face_graph_triangle_primitive.h>
#include <CGAL/Polygon_mesh_processing/compute_normal.h>
#include <CGAL/Polygon_mesh_processing/orientation.h>
typedef K::FT FT;
typedef K::Point_3 Point;
typedef K::Vector_3 Vector;
typedef K::Ray_3 Ray;
typedef CGAL::Surface_mesh<Point> Mesh;
typedef boost::graph_traits<Mesh>::face_descriptor face_descriptor;
typedef boost::graph_traits<Mesh>::halfedge_descriptor halfedge_descriptor;
typedef boost::optional<Tree::Intersection_and_primitive_id<Ray>::Type> Ray_intersection;
struct Skip {
face_descriptor fd;
Skip(const face_descriptor fd)
: fd(fd)
{}
bool operator()(const face_descriptor& t) const
{ if(t == fd){
std::cerr << "ignore " << t <<std::endl;
};
return(t == fd);
}
};
int main(int argc, char* argv[])
{
const char* filename = (argc > 1) ? argv[1] : "data/tetrahedron.off";
std::ifstream input(filename);
Mesh mesh;
input >> mesh;
Tree tree(faces(mesh).first, faces(mesh).second, mesh);
double d = CGAL::Polygon_mesh_processing::is_outward_oriented(mesh)?-1:1;
for(face_descriptor fd : faces(mesh)){
halfedge_descriptor hd = halfedge(fd,mesh);
Point p = CGAL::centroid(mesh.point(source(hd,mesh)),
mesh.point(target(hd,mesh)),
mesh.point(target(next(hd,mesh),mesh)));
Vector v = CGAL::Polygon_mesh_processing::compute_face_normal(fd,mesh);
Ray ray(p,d * v);
Skip skip(fd);
Ray_intersection intersection = tree.first_intersection(ray, skip);
if(intersection){
if(boost::get<Point>(&(intersection->first))){
const Point* p = boost::get<Point>(&(intersection->first) );
std::cout << *p << std::endl;
}
}
}
std::cerr << "done" << std::endl;
return 0;
}

Tree of Polyhedron Triangle Facets for Distance Queries

In the following example the AABB primitive wraps a facet handle of a triangle polyhedral surface as id and the corresponding 3D triangle as geometric object. From a point query we compute the squared distance, the closest point as well as the closest point and primitive id. The latter returns a pair composed of a point and a face handle.


File AABB_tree/AABB_polyhedron_facet_distance_example.cpp

// Author(s) : Pierre Alliez
#include <iostream>
#include <CGAL/Simple_cartesian.h>
#include <CGAL/AABB_tree.h>
#include <CGAL/AABB_traits.h>
#include <CGAL/Polyhedron_3.h>
#include <CGAL/AABB_face_graph_triangle_primitive.h>
typedef K::FT FT;
typedef K::Point_3 Point;
typedef K::Segment_3 Segment;
typedef CGAL::Polyhedron_3<K> Polyhedron;
typedef Tree::Point_and_primitive_id Point_and_primitive_id;
int main()
{
Point p(1.0, 0.0, 0.0);
Point q(0.0, 1.0, 0.0);
Point r(0.0, 0.0, 1.0);
Point s(0.0, 0.0, 0.0);
Polyhedron polyhedron;
polyhedron.make_tetrahedron(p, q, r, s);
// constructs AABB tree and computes internal KD-tree
// data structure to accelerate distance queries
Tree tree(faces(polyhedron).first, faces(polyhedron).second, polyhedron);
// query point
Point query(0.0, 0.0, 3.0);
// computes squared distance from query
FT sqd = tree.squared_distance(query);
std::cout << "squared distance: " << sqd << std::endl;
// computes closest point
Point closest = tree.closest_point(query);
std::cout << "closest point: " << closest << std::endl;
// computes closest point and primitive id
Point_and_primitive_id pp = tree.closest_point_and_primitive(query);
Point closest_point = pp.first;
Polyhedron::Face_handle f = pp.second; // closest primitive id
std::cout << "closest point: " << closest_point << std::endl;
std::cout << "closest triangle: ( "
<< f->halfedge()->vertex()->point() << " , "
<< f->halfedge()->next()->vertex()->point() << " , "
<< f->halfedge()->next()->next()->vertex()->point()
<< " )" << std::endl;
return EXIT_SUCCESS;
}

Tree of Segments for Intersection and Distance Queries

In the following example the segments are stored into a list, and the AABB primitive wraps a segment as datum and an iterator in the list as id. We compute the number of intersections with plane and triangles queries, and the closest point from a point query.
File AABB_tree/AABB_segment_3_example.cpp

// Author : Pierre Alliez
#include <iostream>
#include <list>
#include <CGAL/Simple_cartesian.h>
#include <CGAL/AABB_tree.h>
#include <CGAL/AABB_traits.h>
#include <CGAL/AABB_segment_primitive.h>
typedef K::FT FT;
typedef K::Point_3 Point;
typedef K::Plane_3 Plane;
typedef K::Segment_3 Segment;
typedef K::Triangle_3 Triangle;
typedef std::list<Segment>::iterator Iterator;
int main()
{
Point a(1.0, 0.0, 0.0);
Point b(0.0, 1.0, 0.0);
Point c(0.0, 0.0, 1.0);
Point d(0.0, 0.0, 0.0);
std::list<Segment> segments;
segments.push_back(Segment(a,b));
segments.push_back(Segment(a,c));
segments.push_back(Segment(c,d));
// constructs the AABB tree and the internal search tree for
// efficient distance computations.
Tree tree(segments.begin(),segments.end());
// counts #intersections with a plane query
Plane plane_query(a,b,d);
std::cout << tree.number_of_intersected_primitives(plane_query)
<< " intersections(s) with plane" << std::endl;
// counts #intersections with a triangle query
Triangle triangle_query(a,b,c);
std::cout << tree.number_of_intersected_primitives(triangle_query)
<< " intersections(s) with triangle" << std::endl;
// computes the closest point from a point query
Point point_query(2.0, 2.0, 2.0);
Point closest = tree.closest_point(point_query);
std::cerr << "closest point is: " << closest << std::endl;
return EXIT_SUCCESS;
}

Tree of Polyhedron Edge Segments for Intersection and Distance Queries

In the following example the AABB primitive wraps a halfedge handle as id and generates a 3D segment on the fly, each time its method datum is called. We compute the number of intersections with a triangle query and the closest point from a point query.
File AABB_tree/AABB_polyhedron_edge_example.cpp

// Author(s) : Pierre Alliez
#include <iostream>
#include <CGAL/Simple_cartesian.h>
#include <CGAL/AABB_tree.h>
#include <CGAL/AABB_traits.h>
#include <CGAL/Polyhedron_3.h>
#include <CGAL/AABB_halfedge_graph_segment_primitive.h>
typedef K::FT FT;
typedef K::Point_3 Point;
typedef K::Triangle_3 Triangle;
typedef CGAL::Polyhedron_3<K> Polyhedron;
int main()
{
Point p(1.0, 0.0, 0.0);
Point q(0.0, 1.0, 0.0);
Point r(0.0, 0.0, 1.0);
Point s(0.0, 0.0, 0.0);
Polyhedron polyhedron;
polyhedron.make_tetrahedron(p, q, r, s);
// constructs the AABB tree and the internal search tree for
// efficient distance queries.
Tree tree( CGAL::edges(polyhedron).first,
CGAL::edges(polyhedron).second,
polyhedron);
// counts #intersections with a triangle query
Triangle triangle_query(p,q,r);
std::cout << tree.number_of_intersected_primitives(triangle_query)
<< " intersections(s) with triangle" << std::endl;
// computes the closest point from a query point
Point point_query(2.0, 2.0, 2.0);
Point closest = tree.closest_point(point_query);
std::cerr << "closest point is: " << closest << std::endl;
return EXIT_SUCCESS;
}

Incremental Insertion of Primitives

The AABB tree is a static data structure, but it allows to insert primitives, and will internally rebuild triggered by the first query, or because the user calls the AABB_tree::build() method. The following example illustrates this for two polyhedral surfaces.


File AABB_tree/AABB_insertion_example.cpp

#include <iostream>
#include <CGAL/Simple_cartesian.h>
#include <CGAL/AABB_tree.h>
#include <CGAL/AABB_traits.h>
#include <CGAL/Polyhedron_3.h>
#include <CGAL/AABB_face_graph_triangle_primitive.h>
typedef K::FT FT;
typedef K::Point_3 Point;
typedef K::Segment_3 Segment;
typedef CGAL::Polyhedron_3<K> Polyhedron;
typedef Tree::Point_and_primitive_id Point_and_primitive_id;
int main()
{
Point p(1.0, 0.0, 0.0);
Point q(0.0, 1.0, 0.0);
Point r(0.0, 0.0, 1.0);
Point s(0.0, 0.0, 0.0);
Polyhedron polyhedron1;
polyhedron1.make_tetrahedron(p, q, r, s);
Point p2(11.0, 0.0, 0.0);
Point q2(10.0, 1.0, 0.0);
Point r2(10.0, 0.0, 1.0);
Point s2(10.0, 0.0, 0.0);
Polyhedron polyhedron2;
polyhedron2.make_tetrahedron(p2, q2, r2, s2);
// constructs AABB tree and computes internal KD-tree
// data structure to accelerate distance queries
Tree tree(faces(polyhedron1).first, faces(polyhedron1).second, polyhedron1);
tree.insert(faces(polyhedron2).first, faces(polyhedron2).second, polyhedron2);
// query point
Point query(0.0, 0.0, 3.0);
// computes squared distance from query
FT sqd = tree.squared_distance(query);
std::cout << "squared distance: " << sqd << std::endl;
return EXIT_SUCCESS;
}

Trees of Custom Primitives

The AABB tree example folder contains three examples of trees constructed with custom primitives. In AABB_custom_example.cpp the primitive contains triangles which are defined by three pointers to custom points. In AABB_custom_triangle_soup_example.cpp all input triangles are stored into a single array so as to form a triangle soup. The primitive internally uses a boost::iterator_adaptor so as to provide the three functions AABBPrimitive::id(), AABBPrimitive::datum(), and AABBPrimitive::reference_point()) required by the primitive concept. In AABB_custom_indexed_triangle_set_example.cpp the input is an indexed triangle set stored through two arrays: one array of points and one array of indices which refer to the point array. Here also the primitive internally uses a boost::iterator_adaptor.

Performances

We provide some performance numbers for the case where the AABB tree contains a set of polyhedron triangle facets. We measure the tree construction time, the memory occupancy and the number of queries per second for a variety of intersection and distance queries. The machine used is a PC running Windows XP64 with an Intel CPU Core2 Extreme clocked at 3.06 GHz with 4GB of RAM. By default the kernel used is Simple_cartesian<double> (the fastest in our experiments). The program has been compiled with Visual C++ 2005 compiler with the O2 option which maximizes speed.

Construction

The surface triangle mesh chosen for benchmarking the tree construction is the knot model (14,400 triangles) depicted by Figure 88.2. We measure the tree construction time (both AABB tree alone and AABB tree with internal KD-tree) for this model as well as for three denser versions subdivided through the Loop subdivision scheme which multiplies the number of triangles by four.

Number of triangles Construction (in ms) Construction with internal KD-tree (in ms)
14,400 156 157
57,600 328 328
230,400 1,141 1,437
921,600 4,813 5,953

Memory

When using the polyhedron triangle facet primitive (defined in AABB_polyhedron_triangle_primitive.h) the AABB tree occupies approximately 61 bytes per primitive (without constructing the internal KD-tree). It increases to approximately 150 bytes per primitive when constructing the internal KD-tree with one reference point per primitive (the default mode when calling the function AABB_tree::accelerate_distance_queries()). Note that the polyhedron facet primitive primitive stores only one facet handle as primitive id and computes on the fly a 3D triangle from the facet handle stored internally. When explicitly storing a 3D triangle in the primitive the tree occupies approximately 140 bytes per primitive instead of 60 (without constructing the internal KD-tree).

The following table provides orders of memory occupancy in MBytes for an increasing number of triangles. As the internal KD-tree used to accelerate the distance queries dominates the memory occupancy, we recommend to specify for large models a lower number of reference point (evenly distributed) to construct the internal KD-tree through the function AABB_tree::accelerate_distance_queries() which takes an iterator range as input.

Number of triangles AABB tree (in MBytes) AABB tree with internal KD-tree (in MBytes)
18,400 1.10 2.76
102,400 6.33 14.73
1,022,400 59.56 151.31
1,822,400 108.34 291.84

Intersections

The following table measures the number of intersection queries per second on the 14,400 triangle version of the knot mesh model for ray, line, segment and plane queries. Each ray query is generated by choosing a random source point within the mesh bounding box and a random vector. A line or segment query is generated by choosing two random points inside the bounding box. A plane query is generated by picking a random point inside the bounding box and a random normal vector. Note that a plane query generally intersects many triangles of the input surface mesh. This explains the low performance numbers for the intersection functions which enumerate all intersections.

Function Segment Ray Line Plane
AABB_tree::do_intersect() 187,868 185,649 206,096 377,969
AABB_tree::any_intersected_primitive() 190,684 190,027 208,941 360,337
AABB_tree::any_intersection() 147,468 143,230 148,235 229,336
AABB_tree::number_of_intersected_primitives() 64,389 52,943 54,559 7,906
AABB_tree::all_intersected_primitives() 65,553 54,838 53,183 5,693
AABB_tree::all_intersections() 46,507 38,471 36,374 2,644

Curve of Figure 88.2 plots the number of queries per second (here the AABB_tree::all_intersections() function with random segment queries) against the number of input triangles for the knot triangle surface mesh.

bench.png
Figure 88.2 Number of queries per second against number of triangles for the knot model with 14K (shown), 57K, 230K and 921K triangles. We call the all_intersections() function with segment queries randomly chosen within the bounding box.

The following table measures the number of AABB_tree::all_intersections() queries per second against several kernels. We use the 14,400 triangle version of the knot mesh model for random segment queries. Note how the Simple_cartesian kernel is substantially faster than the Cartesian kernel.

Kernel Queries/s (all_intersections() with segment queries)
Simple_cartesian<double> 46,507
Simple_cartesian<float> 43,187
Cartesian<double> 5,335
Cartesian<float> 5,522
Exact_predicates_inexact_constructions_kernel 18,411

Distances

The surface triangle mesh chosen for benchmarking distances is again the knot model in four increasing resolutions obtained through Loop subdivision. In the following table we first measure the tree construction time (which includes the construction of the internal KD-tree data structure used to accelerate the distance queries by up to one order of magnitude in our experiments). We then measure the number of queries per second for the three types distance queries (AABB_tree::closest_point(), AABB_tree::squared_distance() and AABB_tree::closest_point_and_primitive()) from point queries randomly chosen inside the bounding box.

Nb triangles Construction (ms) Closest_point() Squared_distance() Closest_point_and_primitive()
14,400 157.000 45,132 45,626 45,770
57,600 328.000 21,589 21,312 21,137
230,400 1.437 11,063 10,962 11,086
921,600 5.953 5,636 5,722 5,703

Summary

The experiments described above are neither exhaustive nor conclusive as we have chosen one specific case where the input primitives are the facets of a triangle surface polyhedron. Nevertheless we now provide some general observations and advises about how to put the AABB tree to use with satisfactory performances. While the tree construction times and memory occupancy do not fluctuate much in our experiments depending on the input surface triangle mesh, the performance expressed in number of queries varies greatly depending on a complex combination of criteria: type of kernel, number of input primitives, distribution of primitives in space, type of function queried, type of query and location of query in space.

  • Kernel: The type of CGAL kernel turns out to dominate the final execution times, the maximum performances being obtained with the Simple_cartesian kernel parameterized with the double precision number type. In applications where the intersection and distance execution times are crucial it is possible to use this kernel for the AABB tree in combination with a more robust kernel for the main data structure.
  • Primitives: Although the number of input primitives plays an obvious role in the final performance, their distribution in space is at least equally important in order to obtain a well-balanced AABB tree. Ideally the primitives must be evenly distributed in space and the long primitives spanning the bounding box of the tree root node must be avoided as much as possible. It is often beneficial to split these long primitives into smaller ones before constructing the tree, e.g., through recursive longest edge bisection for triangle surface meshes.
  • Function: The type of function queried plays another important role. Obviously the exhaustive functions, which list all intersections, are slower than the ones stopping after the first intersection. Within each of these functions the ones which call only intersection tests (AABB_tree::do_intersect(), AABB_tree::number_of_intersected_primitives(), AABB_tree::any_intersected_primitive(), AABB_tree::all_intersected_primitives()) are faster than the ones which explicitly construct the intersections (AABB_tree::any_intersection() and AABB_tree::all_intersections()).
  • Query: The type of query (e.g., line, ray, segment or plane used above) plays another role, strongly correlated with the type of function (exhaustive or not, and whether or not it constructs the intersections). When all intersection constructions are needed, the final execution times highly depend on the complexity of the general intersection object. For example a plane query generally intersects a surface triangle mesh into many segments while a segment query generally intersects a surface triangle mesh into few points. Finally, the location of the query in space also plays an obvious role in the performances, especially for the distance queries. Assuming the internal KD-tree constructed through the function AABB_tree::accelerate_distance_queries(), it is preferable to specify a query point already close to the surface triangle mesh so that the query traverses only few AABBs of the tree. For a large number of primitive data (greater than 2M faces in our experiments) however we noticed that it is not necessary (and sometimes even slower) to use all reference points when constructing the KD-tree. In these cases we recommend to specify trough the function AABB_tree::accelerate_distance_queries() fewer reference points (typically not more than 100K) evenly distributed over the input primitives.

Implementation Details

The AABB tree construction is initialized by computing the AABB of the whole set of input primitives. All primitives are then sorted along the longest coordinate axis of this box, and the primitives are separated into two equal size sets. This procedure is applied recursively until an AABB contains a single primitive. The tree is leafless as presented in OPCODE [1]. An intersection query traverses the tree by computing intersection tests only with respect to the AABBs during traversal, and with respect to the input primitives at the end of traversal (in the leafs of the tree).

The reference id is not used internally but simply used by the AABB tree to refer to the primitive in the results provided to the user. It follows that, while in most cases each reference id corresponds to a unique primitive, this is not a requirement of the component. This way a user may use these reference ids as labels, each of them being shared by several geometric objects.

A distance query between a query point q and the input primitives is turned into a ball query centered at q. The ball traverses the tree while recursively querying intersections with the AABBs, and computes the closest point p from the query point to the input primitives at the leafs of the tree. The ball radius is then shrunk to the distance between p and q for all remaining recursive traversals of the tree. Efficiency is achieved through setting the initial ball radius to a small value still guaranteed to intersect the input primitives. This is achieved by constructing an internal secondary data structure which provides a good hint to the algorithm at the beginning of the traversal (done by default). Calling do_not_accelerate_distance_queries() will disable the construction and the usage of this internal secondary data structure.

Design and Implementation History

Camille Wormser and Pierre Alliez started working on a data structure for efficient collision detection in 2007. The generic design for implementing both intersection and distance queries, and for generic queries and primitives was developed by Camille Wormser. In 2009, Pierre Alliez, Stéphane Tayeb and Camille Wormser made the implementation CGAL-compliant, with the help of Laurent Rineau for optimizing the tree construction. The authors wish to thank Andreas Fabri, Jane Tournois, Mariette Yvinec and Sylvain Lefèbvre for helpful comments and discussions.