Take the 2-minute tour ×
Stack Overflow is a question and answer site for professional and enthusiast programmers. It's 100% free, no registration required.

Can anyone recommend an efficient port to CSharp of any of the public AABB/triangle intersection algorithms.

I've been looking at Moller's approach, described abstractly here, and if I were to port it, I would probably start from this C++ version. This C++ library by Mike Vandelay seems like it could also be a great starting point.

...or... any other "wheel" that can take a triangle of Vector3's and tell me if it intersects with an AABB), relatively efficiently.

There seem to be a variety of algorithms, but most seem to be written in c++, or just described abstractly in white papers and I need a c# specific implementation for our application. Efficiency is not key, but c# is. (though efficiency is obviously nice too of course ;p )

Any C# options, before I wade through a "math" port ;) would be greatly appreciated! Thanks.

share|improve this question
Are you interested in 3D or 2D? –  ja72 Jul 3 '13 at 22:07
I am looking for a 3D solution (trying to Voxelize a mesh in c#). –  eejai42 Jul 3 '13 at 22:25
Do you just want to find out if they intersect or not, or do you want to find the line of intersection? –  Markus Jarderot Jul 6 '13 at 12:45
I just need a true/false indicating if they do (or do not) intersect. –  eejai42 Jul 8 '13 at 16:48

2 Answers 2

up vote 7 down vote accepted

For any two convex meshes, to find whether they intersect, you need to check if there exist a separating plane. If it does, they do not intersect. The plane can be picked from any face of either shape, or the edge cross-products.

The plane is defined as a normal and an offset from Origo. So, you only have to check three faces of the AABB, and one face of the triangle.

bool IsIntersecting(IAABox box, ITriangle triangle)
    double triangleMin, triangleMax;
    double boxMin, boxMax;

    // Test the box normals (x-, y- and z-axes)
    var boxNormals = new IVector[] {
        new Vector(1,0,0),
        new Vector(0,1,0),
        new Vector(0,0,1)
    for (int i = 0; i < 3; i++)
        IVector n = boxNormals[i];
        Project(triangle.Vertices, boxNormals[i], out triangleMin, out triangleMax);
        if (triangleMax < box.Start.Coords[i] || triangleMin > box.End.Coords[i])
            return false; // No intersection possible.

    // Test the triangle normal
    double triangleOffset = triangle.Normal.Dot(triangle.A);
    Project(box.Vertices, triangle.Normal, out boxMin, out boxMax);
    if (boxMax < triangleOffset || boxMin > triangleOffset)
        return false; // No intersection possible.

    // Test the nine edge cross-products
    IVector[] triangleEdges = new IVector[] {
    for (int i = 0; i < 3; i++)
    for (int j = 0; j < 3; j++)
        // The box normals are the same as it's edge tangents
        IVector axis = triangleEdges[i].Cross(boxNormals[j]);
        Project(box.Vertices, axis, out boxMin, out boxMax);
        Project(triangle.Vertices, axis, out triangleMin, out triangleMax);
        if (boxMax <= triangleMin || boxMin >= triangleMax)
            return false; // No intersection possible

    // No separating axis found.
    return true;

void Project(IEnumerable<IVector> points, IVector axis,
        out double min, out double max)
    double min = double.PositiveInfinity;
    double max = double.NegativeInfinity;
    foreach (var p in points)
        double val = axis.Dot(p);
        if (val < min) min = val;
        if (val > max) max = val;

interface IVector
    double X { get; }
    double Y { get; }
    double Z { get; }
    double[] Coords { get; }
    double Dot(IVector other);
    IVector Minus(IVector other);
    IVector Cross(IVector other);

interface IShape
    IEnumerable<IVector> Vertices { get; }

interface IAABox : IShape
    IVector Start { get; }
    IVector End { get; }

interface ITriangle : IShape {
    IVector Normal { get; }
    IVector A { get; }
    IVector B { get; }
    IVector C { get; }

A good example is the box (±10, ±10, ±10) and the triangle (12,9,9),(9,12,9),(19,19,20). None of the faces can be used as a separating plane, yet they do not intersect. The separating axis is <1,1,0>, which is obtained from the cross product between <1,0,0> and <-3,3,0>.


share|improve this answer
This looks PERFECT. Having done a fair amount of research on this problem, this looks (massively) like the most efficient way to test for intersection... Does this actually handle all of the many different edge cases for intersection? –  eejai42 Jul 8 '13 at 17:29
I was close. In the 2D case that would have been enough, but in 3D you also need to check the edge cross-products. –  Markus Jarderot Jul 8 '13 at 19:30
Nice graphics.. –  ja72 Jul 8 '13 at 19:34
Awesome, thanks - I will test it out! I have found (in other testing) that for performance reasons it will probably run faster (while not being nearly as elegant) to harden the interfaces into actual classes and turn the properties into fields - but, this looks like a beautiful implementation of the separating axis algorithm. Thank you again! –  eejai42 Jul 9 '13 at 20:56

I noticed a small bug in this implementation which leads to false negatives. If your triangle has one edge parallel to one axis (for example (1, 0, 0)), then you will have a null vector when computing


This will lead to equality in the test below and give you a false negative.

replace <= and >= by < and > (strict comparers to remove thos cases).

Works well except for that!

Thank you

share|improve this answer

Your Answer


By posting your answer, you agree to the privacy policy and terms of service.

Not the answer you're looking for? Browse other questions tagged or ask your own question.