GLSL: How to get pixel x,y,z world position?

Question

I want to adjust the colors depending on which xyz position they are in the world.

I tried this in my fragment shader:

varying vec4 verpos;

void mai         


        

Answer 1

The easiest way is to pass the world-position down from the vertex shader via a varying variable.

However, if you really must reconstruct it from gl_FragCoord, the only way to do this is to invert all the steps that led to the gl_FragCoord coordinates. Consult the OpenGL specs, if you really have to do this, because a deep understanding of the transformations will be necessary.

Answer 2

You need to pass the World/Model matrix as a uniform to the vertex shader, and then multiply it by the vertex position and send it as a varying to the fragment shader:

/*Vertex Shader*/

layout (location = 0) in vec3 Position

uniform mat4 World;
uniform mat4 WVP;

//World FragPos
out vec4 FragPos;

void main()
{
 FragPos = World * vec4(Position, 1.0);
 gl_Position = WVP * vec4(Position, 1.0);
}

/*Fragment Shader*/

layout (location = 0) out vec4 Color;

... 

in vec4 FragPos

void main()
{
 Color = FragPos;
}

Answer 3

Or you could just divide the z coordinate by the w coordinate, which essentially un-does the perspective projection; giving you your original world coordinates.

ie.

depth = gl_FragCoord.z / gl_FragCoord.w;

Of course, this will only work for non-clipped coordinates..

But who cares about clipped ones anyway?

Answer 4

In vertex shader you have gl_Vertex (or something else if you don't use fixed pipeline) which is the position of a vertex in model coordinates. Multiply the model matrix by gl_Vertex and you'll get the vertex position in world coordinates. Assign this to a varying variable, and then read its value in fragment shader and you'll get the position of the fragment in world coordinates.

Now the problem in this is that you don't necessarily have any model matrix if you use the default modelview matrix of OpenGL, which is a combination of both model and view matrices. I usually solve this problem by having two separate matrices instead of just one modelview matrix:

1. model matrix (maps model coordinates to world coordinates), and
2. view matrix (maps world coordinates to camera coordinates).

So just pass two different matrices to your vertex shader separately. You can do this by defining

uniform mat4 view_matrix;
uniform mat4 model_matrix;

In the beginning of your vertex shader. And then instead of ftransform(), say:

gl_Position = gl_ProjectionMatrix * view_matrix * model_matrix * gl_Vertex;

In the main program you must write values to both of these new matrices. First, to get the view matrix, do the camera transformations with glLoadIdentity(), glTranslate(), glRotate() or gluLookAt() or what ever you prefer as you would normally do, but then call glGetFloatv(GL_MODELVIEW_MATRIX, &array); in order to get the matrix data to an array. And secondly, in a similar way, to get the model matrix, also call glLoadIdentity(); and do the object transformations with glTranslate(), glRotate(), glScale() etc. and finally call glGetFloatv(GL_MODELVIEW_MATRIX, &array); to get the matrix data out of OpenGL, so you can send it to your vertex shader. Especially note that you need to call glLoadIdentity() before beginning to transform the object. Normally you would first transform the camera and then transform the object which would result in one matrix that does both the view and model functions. But because you're using separate matrices you need to reset the matrix after camera transformations with glLoadIdentity().

gl_FragCoord are the pixel coordinates and not world coordinates.