Optimising GLSL code in fragment shader (iOS 5 + OpenGL ES 2.0)

I have some computations (below) in my fragment shader function which is called a huge number of times. I'd like to know if it is possible to optimize this code. I took a look at the OpenGL.org glsl optimisation page, and made some modifications, but it is possible to make this code faster?

``````uniform int mn;
highp float Nx;
highp float Ny;
highp float Nz;
highp float invXTMax;
highp float invYTMax;
int m;
int n;

highp vec4 func(in highp vec3 texCoords3D)
{

// tile index
int Ti = int(texCoords3D.z * Nz);

// (r, c) position of tile withn texture unit
int r = Ti / n; // integer division
int c = Ti - r * n;

// x/y offsets in pixels of tile origin with the texture unit
highp float xOff = float(c) * Nx;
highp float yOff = float(r) * Ny;

// 2D texture coordinates
highp vec2 texCoords2D;
texCoords2D.x = (Nx * texCoords3D.x + xOff)*invXTMax;
texCoords2D.y = (Ny * texCoords3D.y + yOff)*invYTMax;

return texture2D(uSamplerTex0, texCoords2D);
}
``````

Edit:

To give some context, func() is used as part of a ray casting setup. It is called up to 300 times from main() for each fragment.

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It doesn't seem to use much computation time to me... –  TheAmateurProgrammer Jul 30 '12 at 2:43
Show more context. The optimal solution may require altering the function and its relationship to the caller. –  Brian Cain Jul 30 '12 at 3:01
func() is called in a loop up to 300 times from the main function. It's part of a ray casting setup. For each fragment on the screen this could be called so many times, and so it does take up a lot of computation time. –  M-V Jul 30 '12 at 4:38
I doubt it will give huge boost, but you could try running glsl-optimizer on your shader: github.com/aras-p/glsl-optimizer –  Mārtiņš Možeiko Jul 30 '12 at 5:18
The first problem I see is the integer stuff. Don't do that; round instead. As there is no round function in OpenGL ES 2.0's GLSL, you have to roll your own: sign(x) * floor(abs(x) + .5). –  Jessy Jul 30 '12 at 14:30

It is very easy to vectorize the code as follows:

``````highp vec3 N;
highp vec2 invTMax;

highp vec4 func(in highp vec3 texCoords3D)
{
// tile index
int Ti = int(texCoords3D.z * N.z);

// (r, c) position of tile within texture unit
int r = Ti / n;
int c = Ti - r * n;

// x/y offsets in pixels of tile origin with the texture unit
highp vec2 Off = vec2( float(c), float(r) ) * N;

// 2D texture coordinates
highp vec2 texCoords2D = ( N * texCoords3D.xy + Off ) * invTMax;

return texture2D(uSamplerTex0, texCoords2D);
}
``````

To make sure the similar calculations run in parallel.

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Modifying the texture coordinates instead of using the ones passed into the fragment shader creates a dynamic texture read and the largest performance hit on earlier hardware.

Check the last section on Dynamic Texture Lookups

They suggest moving the texture coordinates up into the fragment shader. Looks like you can without much issue if I understand the intent of the code correctly. Your adding offset and tile support for fine adjustments, scaling, and animation on your UVs (and thus textures) ? Thought so. Use this.

``````//
//

attribute vec4 position;
attribute vec2 texture;

uniform mat4 modelViewProjectionMatrix;

// tiling parameters:
// -- x and y components of the Tiling (x,y)
// -- x and y components of the Offset (w,z)
// a value of vec4(1.0, 1.0, 0.0, 0.0) means no adjustment

uniform vec4 texture_ST;

// UV calculated in the vertex shader, GL will interpolate over the pixels
// and prefetch the texel to avoid dynamic texture read on pre ES 3.0 hw.
// This should be highp in the fragment shader.

varying vec2 uv;

void main()
{
uv = ((texture.xy * texture_ST.xy) + texture_ST.zw);

gl_Position = modelViewProjectionMatrix * position;
}
``````
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