# GLSL compute world coordinate from eye depth and screen position

I'm trying to recover WORLD position of a point knowing it's depth in EYE space, computed as follow (in a vertex shader) :

``````float depth = - uModelView * vec4( inPos , 1.0 ) ;
``````

where inPos is a point in world space (Obviously, I don't want to recover this particular point, but a point where depth is expressed in that format).

And it's normalized screen position (between 0 and 1), computed as follow (in a fragment shader ) :

``````vec2 screen_pos = ( vec2( gl_FragCoord.xy ) - vec2( 0.5 ) ) / uScreenSize.xy ;
``````

• uScreenSize : as it's name suggest, it's screen width and height
• uCameraPos : camera position in WORLD space

and standard matrices :

• uModelView : model view camera matrix
• uModelViewProj : model view projection matrix
• uProjMatrix : projection matrix

How can I compute position (X,Y,Z) of a point in WORLD space ? (not in EYE space)

I can't have access to other (I can't use near, far, left, right, ...) because projection matrix is not restricted to perspective or orthogonal.

I get your question right, you have `x` and `y` as window space (and already converted to normalized device space [-1,1]), but `z` in eye space, and want to recosntruct the world space position.

I can't have access to other (I can't use near, far, left, right, ...) because projection matrix is not restricted to perspective or orthogonal.

Well, actually, there is not much besides an orthogonal or projective mapping which can be achieved by matrix multiplication in homogenous space. However, the projection matrix is sufficient, as long as it is invertible (In theory, a projection matrix could transform all points to a plane, line or a single point. In that case, some information is lost and it will never be able to reconstruct the original data. But that would be a very untypical case).

So what you can get from the projection matrix and your 2D position is actually a ray in eye space. And you can intersect this with the `z=depth` plane to get the point back.

So what you have to do is calculate the two points

``````vec4 p = inverse(uProjMatrix) * vec4 (ndc_x,  ndc_y, -1, 1);
vec4 q = inverse(uProjMatrix) * vec4 (ndc_x,  ndc_y,  1, 1);
``````

which will mark two points on the ray in eye space. Do not forget to divide `p` and `q` by the respective `w` component to get the 3D coordinates. Now, you simply need to intersect this with your `z=depth` plane and get the eye space `x` and `y`. Finally, you can use the inverse of the `uModelView` matrix to project that point back to object space.

However, you said that you want world space. But that is impossible. You would need the `view` matrix to do that, but you have not listed that as a given. All you have is the compisition of the `model` and `view` matrix, and you need to know at least one of these to reconstruct the world space position. The `cameraPosition` is not enoguh. You also need the orientation.

• Well. I Like your answer. I think I can pass the view matrix to the shader and compute the intersection. I can't test now but I'll tell you if it works. – rperrot Nov 1 '14 at 19:02
• That works great. Thank you ! – rperrot Nov 1 '14 at 20:41
• I want to point out that `(inverse(uProjMatrix) * vec4 (ndc_x, ndc_y, 1, 1)).xyz` should already give you a vector with `z = 1`. So you can just multiply that by the negative depth to obtain the point coordinate in eye space. – nils Aug 22 '18 at 9:29
• @nils: what I wrote is valid for the most generic case of a projection matrix. If one knows something more about the matrix in use, this can be optimized further, i.e, a classical GL projection matrix with tyipcal GL conventions has a last row encoding `w_clip=-z_eye`, so the inverse will be `z_eye=-w_clip`, and the resulting `z` from above will be `-1`. So yes, you can take some shortcuts. – derhass Aug 22 '18 at 12:09