```
clipspace.xy = FragCoord.xy / viewport * 2.0 - 1.0;
```

This is wrong in terms of nomenclature. "Clip space" is the space that the vertex shader (or whatever the last Vertex Processing stage is) outputs. Between clip space and window space is normalized device coordinate (NDC) space. NDC space is clip space divided by the clip space W coordinate:

```
vec3 ndcspace = clipspace.xyz / clipspace.w;
```

So the first step is to take our window space coordinates and get NDC space coordinates. Which is easy:

```
vec3 ndcspace = vec3(FragCoord.xy / viewport * 2.0 - 1.0, depth);
```

Now, I'm going to *assume* that your `depth`

value is the proper NDC-space depth. I'm assuming that you fetch the value from a depth texture, then used the depth range near/far values it was rendered with to map it into a [-1, 1] range. If you didn't, you should.

So, now that we have `ndcspace`

, how do we compute `clipspace`

? Well, that's obvious:

```
vec4 clipspace = vec4(ndcspace * clipspace.w, clipspace.w);
```

Obvious and... not helpful, since we don't have `clipspace.w`

. So how do we get it?

To get this, we need to look at how `clipspace`

was computed the first time:

```
vec4 clipspace = Proj * cameraspace;
```

This means that `clipspace.w`

is computed by taking `cameraspace`

and dot-producting it by the fourth row of `Proj`

.

Well, that's not very helpful. It gets more helpful if we actually look at the fourth row of `Proj`

. Granted, you *could* be using any projection matrix, and if you're not using the typical projection matrix, this computation becomes more difficult (potentially impossible).

The fourth row of `Proj`

, using the typical projection matrix, is really just this:

```
[0, 0, -1, 0]
```

This means that the `clipspace.w`

is really just `-cameraspace.z`

. How does that help us?

It helps by remembering this:

```
ndcspace.z = clipspace.z / clipspace.w;
ndcspace.z = clipspace.z / -cameraspace.z;
```

Well, that's nice, but it just trades one unknown for another; we still have an equation with two unknowns (`clipspace.z`

and `cameraspace.z`

). However, we do know something else: `clipspace.z`

comes from dot-producting `cameraspace`

with the *third* row of our projection matrix. The traditional projection matrix's third row looks like this:

```
[0, 0, T1, T2]
```

Where T1 and T2 are non-zero numbers. We'll ignore what these numbers are for the time being. Therefore, `clipspace.z`

is really just `T1 * cameraspace.z + T2 * cameraspace.w`

. And if we know `cameraspace.w`

is 1.0 (as it usually is), then we can remove it:

```
ndcspace.z = (T1 * cameraspace.z + T2) / -cameraspace.z;
```

So, we still have a problem. Actually, we don't. Why? Because there is only one unknown in this euqation. Remember: *we already know *`ndcspace.z`

. We can therefore use ndcspace.z to compute `cameraspace.z`

:

```
ndcspace.z = -T1 + (-T2 / cameraspace.z);
ndcspace.z + T1 = -T2 / cameraspace.z;
cameraspace.z = -T2 / (ndcspace.z + T1);
```

`T1`

and `T2`

come right out of our projection matrix (the one the scene was originally rendered with). And we already have `ndcspace.z`

. So we can compute `cameraspace.z`

. And we know that:

```
clispace.w = -cameraspace.z;
```

Therefore, we can do this:

```
vec4 clipspace = vec4(ndcspace * clipspace.w, clipspace.w);
```

Obviously you'll need a float for `clipspace.w`

rather than the literal code, but you get my point. Once you have `clipspace`

, to get camera space, you multiply by the inverse projection matrix:

```
vec4 cameraspace = InvProj * clipspace;
```