To do this transform, you must first take your model-space positions and transform them to clip-space. This is done with matrix multiplies. I will use GLSL-style code to make it obvious what I'm doing:

```
vec4 clipSpacePos = projectionMatrix * (viewMatrix * vec4(point3D, 1.0));
```

Notice how I convert your 3D vector into a 4D vector before the multiplication. This is necessary because the matrices are 4x4, and you cannot multiply a 4x4 matrix with a 3D vector. You need a fourth component.

The next step is to transform this position from clip-space to normalized device coordinate space (NDC space). NDC space is on the range [-1, 1] in all three axes. This is done by dividing the first three coordinates by the fourth:

```
vec3 ndcSpacePos = clipSpacePos.xyz / clipSpacePos.w;
```

Obviously, if `clipSpacePos.w`

is zero, you have a problem, so you should check that beforehand. If it is zero, then that means that the object is in the plane of projection; it's view-space depth is zero. And such vertices are automatically clipped by OpenGL.

The next step is to transform from this [-1, 1] space to window-relative coordinates. This requires the use of the values you passed to `glViewport`

. The first two parameters are the offset from the bottom-left of the window (`vec2 viewOffset`

), and the second two parameters are the width/height of the viewport area (`vec2 viewSize`

). Given these, the window-space position is:

```
vec2 windowSpacePos = ((ndcSpacePos.xy + 1.0) / 2.0) * viewSize + viewOffset;
```

And that's as far as you go. Remember: OpenGL's window-space is relative to the *bottom-left* of the window, not the top-left.