# How do I implement marching cubes contouring on the geometry shader?

I have a uniformly sampled grid of distances:

D(x_i, y_j, z_k), where

x_i = x0 + i*dx, 0 <= i < nx

y_j = y0 + j*dy, 0 <= j < ny

z_k = z0 + k*dz, 0 <= k < nz

I want to pass each cell in this grid to the geometry shader and output 0 to 5 triangles as specified in the marching cubes algorithm.

I was thinking sending x0, dx, y0, dy, z0, dz and the value to contour on to the shader using uniform values and encode the index of the cell as the position of a point:

``````glBegin(GL_POINTS);
for(int i = 0; i < nx - 1; i++) {
for(int j = 0; j < ny - 1; j++) {
for(int k = 0; k < nz - 1; k++) {
glVertex3f(i, j, k);
}
}
}
glEnd();
``````

Inside the geometry shader however I must look-up the distance values of the 8 corners in the (i,j,k) cell. How can I pass the 3D array of distances to the geometry shader?

-
Why do you want to do this? Even ignoring the fact that you're using immediate mode rendering, this kind of GS usage is going to be much slower than just doing it once on the CPU and rendering a nice, fast mesh. – Nicol Bolas Jan 22 '13 at 22:57
Take a look at using a 3D texture for storing your grid data. Here's a nice article describing the technique. – radical7 Jan 23 '13 at 4:31
@NicolBolas While the immediate-mode point bit isn't optimal, if the application's going to change the isosurface value (as suggested in the OP), this seems like a great use for a GS. Sending long lists of triangles to the GPU each frame won't be competitive with generating the geometry on the GPU (assuming that geometry shading is hardware accelerated, of course). – radical7 Jan 23 '13 at 4:37
@radical7: "Sending long lists of triangles to the GPU each frame won't be competitive with generating the geometry on the GPU" GPUs are designed to process "long lists of triangles" efficiently. As for changing it every frame, the amount of data you'd be changing would be far from prohibitive for real-time applications. Unless you're rewriting every single cell every frame, you can always find ways to optimize the memory transfer. And it's not like upload speeds are incredibly slow these days. If you manage to make this work, you're going to be disappointed by the performance. – Nicol Bolas Jan 23 '13 at 4:59
@NicolBolas GPU transform efficiency relies on the vertex data being GPU resident, as I believe you know. While the OP never mentions any dataset sizes, consider a feasible scenario: given a 256^3 volume where 30% (to pick a number) of the voxels emit a single triangle (which is low-balling it - marching cubes can emit up to five tris per voxel), with 36 bytes/triangle yields 172 MB/frame in position-only vertex data. At 60 Hz, that's over 10 GB/s. PCIe 2.0 x16 @ 5GHz is only 8 GB/s. – radical7 Jan 23 '13 at 5:42