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I have been grappling with the Hartmann/Gribbs method of extracting the Frustum planes for some time now, with little success. I want to build a camera view-frustum to cull my scene.

I am working with column-major matrices in a right-handed coordinate system. (OpenGL style - I'm using C# and Playstation Mobile, but the math should be the same)

I want to get my planes in World-Space, so I build my frustum from the View-Projection Matrix (that's projectionMatrix * viewMatrix). The view Matrix is the inverse of the camera's World-Transform.

The problem is; regardless of what I tweak, I can't seem to get a correct frustum. I think that I may be missing something obvious.

If I "strafe" my camera left or right while still looking down the z-axis, the normals of my planes change so that they are always pointing at the origin of the scene - which makes me think that they are not in world-space...

  • I was stuck with the same issue yesterday. I have a feeling the OpenGL code might be wrong on that paper, or at least I used the DirectX code and it worked fine, even though I am using OpenGL. I visualized the planes with a point cloud and they look right now. Have you tried that? – PolyMesh Apr 2 '14 at 16:39
  • I have the same exact issue. I have implemented the algorithm described in the DirectX style paragraph as I am using a row-major matrix query. I was unable to get the correct culling to work. But I have noticed that if the object to be culled is exactly in the world center (0, 0, 0) the culling works perfectly. @DAVco were you able to resolve this? – Haeri Apr 9 '18 at 15:26
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The planes from a projection matrix can be extracted using the hartmann/gribbs method as follows, (column major):

void extract_planes_from_projmat(
        const float mat[4][4],
        float left[4], float right[4], float top[4], float bottom[4],
        float near[4], float far[4])
{   
    for (int i = 4; i--; ) left[i]      = mat[i][3] + mat[i][0];
    for (int i = 4; i--; ) right[i]     = mat[i][3] - mat[i][0]; 
    for (int i = 4; i--; ) bottom[i]    = mat[i][3] + mat[i][1];
    for (int i = 4; i--; ) top[i]       = mat[i][3] - mat[i][1];
    for (int i = 4; i--; ) near[i]      = mat[i][3] + mat[i][2];
    for (int i = 4; i--; ) far[i]       = mat[i][3] - mat[i][2];
}

Where mat4 is the product of the projection matrix and the model-view matrix.

See:

Note: if the matrix components aren't normalized and you require a Hessian Normal Form plane, then you will need to normalize the resulting planes.

  • You still need to normalize the planes in case of arbitrary transforms. – Matthias Aug 7 '17 at 18:17
  • Wouldn't this only be if the planes need to be normalized by whatever code uses them? - Many plane operations don't require this, even so, thanks for the heads up - noted in the answer. – ideasman42 Dec 13 '17 at 0:36
  • you are right that you do not need normalized planes for all operations. Though, code can be more robust if you remove some degrees of freedom. – Matthias Dec 13 '17 at 13:11
  • 1
    Sure you might want to, but under some conditions it might be fine not to as well - since normalize can be expensive. Noted in answer that normalizing can be done if its needed. – ideasman42 Dec 13 '17 at 13:28
0

The missing part:

comboMatrix = projection_matrix * Matrix4_Transpose(modelview_matrix)

Then the world-space frustum plane extraction for OpenGL is exactly as mentioned in the Hartmann/Gribbs method:

p_planes[0].a = comboMatrix._41 + comboMatrix._11;
p_planes[0].b = comboMatrix._42 + comboMatrix._12;
p_planes[0].c = comboMatrix._43 + comboMatrix._13;
p_planes[0].d = comboMatrix._44 + comboMatrix._14;
// Right clipping plane
p_planes[1].a = comboMatrix._41 - comboMatrix._11;
p_planes[1].b = comboMatrix._42 - comboMatrix._12;
p_planes[1].c = comboMatrix._43 - comboMatrix._13;
p_planes[1].d = comboMatrix._44 - comboMatrix._14;
// Top clipping plane
p_planes[2].a = comboMatrix._41 - comboMatrix._21;
p_planes[2].b = comboMatrix._42 - comboMatrix._22;
p_planes[2].c = comboMatrix._43 - comboMatrix._23;
p_planes[2].d = comboMatrix._44 - comboMatrix._24;
// Bottom clipping plane
p_planes[3].a = comboMatrix._41 + comboMatrix._21;
p_planes[3].b = comboMatrix._42 + comboMatrix._22;
p_planes[3].c = comboMatrix._43 + comboMatrix._23;
p_planes[3].d = comboMatrix._44 + comboMatrix._24;
// Near clipping plane
p_planes[4].a = comboMatrix._41 + comboMatrix._31;
p_planes[4].b = comboMatrix._42 + comboMatrix._32;
p_planes[4].c = comboMatrix._43 + comboMatrix._33;
p_planes[4].d = comboMatrix._44 + comboMatrix._34;
// Far clipping plane
p_planes[5].a = comboMatrix._41 - comboMatrix._31;
p_planes[5].b = comboMatrix._42 - comboMatrix._32;
p_planes[5].c = comboMatrix._43 - comboMatrix._33;
p_planes[5].d = comboMatrix._44 - comboMatrix._34;

These planes now are in world-space and can be used to frustum cull world-space objects.

for(int i = 0; i < 6; i++)
{
    var dist = dot3(world_space_point.xyz, p_planes[i].xyz) + p_planes[i].d + sphere_radius;
    if(dist < 0) return false; // sphere culled
}

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