I'm working with omnidirectional point lights. I already implemented shadow mapping using a cubemap texture as color attachement of 6 framebuffers, and encoding the light-to-fragment distance in each pixel of it.

Now I would like, if this is possible, to change my implementation this way:

  • 1) attach a depth cubemap texture to the depth buffer of my framebuffers, instead of colors.
  • 2) render depth only, do not write color in this pass
  • 3) in the main pass, read the depth from the cubemap texture, convert it to a distance, and check whether the current fragment is occluded by the light or not.

My problem comes when converting back a depth value from the cubemap into a distance. I use the light-to-fragment vector (in world space) to fetch my depth value in the cubemap. At this point, I don't know which of the six faces is being used, nor what 2D texture coordinates match the depth value I'm reading. Then how can I convert that depth value to a distance?

Here are snippets of my code to illustrate:

Depth texture:

glGenTextures(1, &TextureHandle);
glBindTexture(GL_TEXTURE_CUBE_MAP, TextureHandle);
for (int i = 0; i < 6; ++i)
              Width, Height, 0, GL_DEPTH_COMPONENT, GL_FLOAT, 0);



Framebuffers construction:

for (int i = 0; i < 6; ++i)
    glGenFramebuffers(1, &FBO->FrameBufferID);
    glBindFramebuffer(GL_FRAMEBUFFER, FBO->FrameBufferID);
            GL_TEXTURE_CUBE_MAP_POSITIVE_X + i, TextureHandle, 0);

The piece of fragment shader I'm trying to write to achieve my code:

float ComputeShadowFactor(samplerCubeShadow ShadowCubeMap, vec3 VertToLightWS)
    float ShadowVec = texture(ShadowCubeMap, vec4(VertToLightWS, 1.0));
    ShadowVec = DepthValueToDistance(ShadowVec);
    if (ShadowVec * ShadowVec > dot(VertToLightWS, VertToLightWS))
        return 1.0;

    return 0.0;

The DepthValueToDistance function being my actual problem.

  • "Is there a solution to my problem?" Convert distance to depth, compare with stored depth in cubemap. "unappliable for cube map shadows" I think 5..7 years ago somebody called "ron frazier" wrote an article about using cubemaps for shadow mapping.
    – SigTerm
    May 28, 2012 at 16:29
  • @SigTerm ronfrazier.net/apparition/index.html?appmain=research/… is what I think you are talking about. May 28, 2012 at 17:41
  • @JohnRiselvato: Yep. I think it was this article. It is obviously possible to do something similar with modern OpenGL/better precision (there are floating point textures, GLSL, *shadow samplers, etc) - I just don't have a working snippet nearby and don't feel like writing one.
    – SigTerm
    May 28, 2012 at 17:57
  • Although this page is quite old, it gives the reason why I should do distance-to-depth conversion instead of the inverse: "unfortunately the depth buffer uses a camera space z distance for the depth value rather than the Cartesian distance". Finding the matching "camera z distance" from a world space vector into one of the cubemap face is easy. I managed to have my shadow working now. When I'll have cleaned a bit my code, I will clean the question and post the answer. Thanks for the link
    – Benlitz
    May 28, 2012 at 18:54

2 Answers 2


So, the solution was to convert the light-to-fragment vector to a depth value, instead of converting the depth read from the cubemap into a distance.

Here is the modified shader code:

float VectorToDepthValue(vec3 Vec)
    vec3 AbsVec = abs(Vec);
    float LocalZcomp = max(AbsVec.x, max(AbsVec.y, AbsVec.z));

    const float f = 2048.0;
    const float n = 1.0;
    float NormZComp = (f+n) / (f-n) - (2*f*n)/(f-n)/LocalZcomp;
    return (NormZComp + 1.0) * 0.5;

float ComputeShadowFactor(samplerCubeShadow ShadowCubeMap, vec3 VertToLightWS)
    float ShadowVec = texture(ShadowCubeMap, vec4(VertToLightWS, 1.0));
    if (ShadowVec + 0.0001 > VectorToDepthValue(VertToLightWS))
        return 1.0;

    return 0.0;

Explaination on VectorToDepthValue(vec3 Vec) :

LocalZComp corresponds to what would be the Z-component of the given Vec into the matching frustum of the cubemap. It's actually the largest component of Vec (for instance if Vec.y is the biggest component, we will look either on the Y+ or the Y- face of the cubemap).

If you look at this wikipedia article, you will understand the math just after (I kept it in a formal form for understanding), which simply convert the LocalZComp into a normalized Z value (between in [-1..1]) and then map it into [0..1] which is the actual range for depth buffer values. (assuming you didn't change it). n and f are the near and far values of the frustums used to generate the cubemap.

ComputeShadowFactor then just compare the depth value from the cubemap with the depth value computed from the fragment-to-light vector (named VertToLightWS here), also add a small depth bias (which was missing in the question), and returns 1 if the fragment is not occluded by the light.


I would like to add more details regarding the derivation.

Let V be the light-to-fragment direction vector.

As Benlitz already said, the Z value in the respective cube side frustum/"eye space" can be calculated by taking the max of the absolute values of V's components.

Z = max(abs(V.x),abs(V.y),abs(V.z))

Then, to be precise, we should negate Z because in OpenGL, the negative Z-axis points into the screen/view frustum.

Now we want to get the depth buffer "compatible" value of that -Z.

Looking at the OpenGL perspective matrix...


http://i.stack.imgur.com/mN7ke.png (backup link)

...we see that, for any homogeneous vector multiplied with that matrix, the resulting z value is completely independent of the vector's x and y components.

So we can simply multiply this matrix with the homogeneous vector (0,0,-Z,1) and we get the vector (components):

x = 0
y = 0
z = (-Z * -(f+n) / (f-n)) + (-2*f*n / (f-n))
w = Z

Then we need to do the perspective divide, so we divide z by w (Z) which gives us:

z' = (f+n) / (f-n) - 2*f*n / (Z* (f-n))

This z' is in OpenGL's normalized device coordinate (NDC) range [-1,1] and needs to be transformed into a depth buffer compatible range of [0,1]:

z_depth_buffer_compatible = (z' + 1.0) * 0.5

Further notes:

  • It might make sense to upload the results of (f+n), (f-n) and (f*n) as shader uniforms to save computation.

  • V needs to be in world space since the shadow cube map is normally axis aligned in world space thus the "max(abs(V.x),abs(V.y),abs(V.z))"-part only works if V is a world space direction vector.

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