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What is the difference, and how do I get WebGL's sin to produce the same result as Math.sin?

EDIT: I have some code in my vertex shader (this is not all code), that computes a fibonacci point around a sphere and is supposed to place the vertex on this new spot:

attribute float index;

   float inc = 3.141592653589793238462643383279 * (3.0 - sqrt(5.0));
   float off = 2.0 / 2500000;
   float yy = index * off - 1.0 + (off / 2.0);
   float rr = sqrt(1.0 - yy * yy);
   float phi = index* inc;
   vec3 fibPoint = vec3(cos(phi) * rr, yy, sin(phi) * rr);

This doesn't work, it gives me awkward vertex locations like this: http://i.imgur.com/Z1crisy.png

If I instead compute cos(phi) and sin(phi) on the CPU with javascript's Math.sin and Math.cos and throw them in as an attribute, like this:

attribute float index;
attribute float sinphi;
attribute float cosphi;

   float inc = 3.141592653589793238462643383279 * (3.0 - sqrt(5.0));
   float off = 2.0 / 2500000;
   float yy = index * off - 1.0 + (off / 2.0);
   float rr = sqrt(1.0 - yy * yy);
   float phi = index* inc;
   vec3 fibPoint = vec3(cosphi * rr, yy, sinphi * rr);

I get a fine fibonacci distribution like this: http://i.imgur.com/DeRoXkL.png

Any ideas on why, obviously it seems like there is some difference in the cos/sin functions between GLSL and Javascript? Phi can become quite large numbers, like "5476389.695241543" kind of large. Maybe that is too big for GLSL's precision?


vertexShader: [
    "attribute float index;",
    "attribute float cosphi;",
    "attribute float sinphi;",
    "attribute float displacementType;",
    "uniform vec3 faceCorner;",
    "uniform vec3 faceNormal;",
    "uniform vec3 faceCenter;",
    "varying vec2 vTexCoord;",

    "void main()",

          "vTexCoord = uv;",

          // find fibonacci distribution of points on sphere
          "float inc = 3.141592653589793238462643383279 * 0.7639320225002102;",
          "float off = 0.0000008;",

          "float yy = index* off - 1.0 + (off / 2.0);",
          "float rr = sqrt(1.0 - yy * yy);",
          "float phi = index* inc;",
          "vec3 fibPoint = vec3(cos(phi) * rr * -1.0, yy, sin(phi) * rr * -1.0);",

          // intersecting face
          "vec3 normalizedFaceNormal = normalize(faceNormal);",
          "float planeConstant = - dot(faceCorner, normalizedFaceNormal);", 
          "float denominator = dot(normalizedFaceNormal, fibPoint);",
          "float distanceToPlane = - planeConstant / denominator;",

          "vec3 intersectPoint = normalize(fibPoint) * distanceToPlane;",
          "intersectPoint = faceCenter;",

          // displacement
          "float buildingRadius = 3.0;",                
          "vec3 newPosition = position;",
          "vec3 cornerVec = normalize(faceCorner - intersectPoint) * buildingRadius;",

            // ground vertices
           "if(displacementType == 0.0){",
                "newPosition = intersectPoint + cornerVec;",
           "} else if(displacementType == 1.0){",
                "newPosition = cross(cornerVec, normalizedFaceNormal);",    
                "newPosition = intersectPoint + newPosition;",
            "} else if(displacementType == 2.0){",
                "newPosition = intersectPoint - cornerVec;",
           "} else if(displacementType == 3.0){",
                "newPosition = cross(normalizedFaceNormal, cornerVec);",    
                "newPosition = intersectPoint + newPosition;",

           "} else {",
                  // roof vertices
               "vec3 corner0 = intersectPoint + cornerVec;",
               "vec3 corner1 = intersectPoint + cross(cornerVec, normalizedFaceNormal);",

                "float UVdistance = length(corner0 - corner1);",
                "float buildingHeight = UVdistance * 2.0;",

                "vec3 roofCentroid = intersectPoint + normalizedFaceNormal * (-buildingHeight);",

                "if(displacementType == 4.0){",
                    "newPosition = roofCentroid + cornerVec;",
                "} else if(displacementType == 5.0){",
                    "newPosition = cross(cornerVec, normalizedFaceNormal);",
                    "newPosition = roofCentroid + newPosition;",
                "} else if(displacementType == 6.0){",
                    "newPosition = roofCentroid - cornerVec;",
                "} else {",
                    "newPosition = cross(normalizedFaceNormal, cornerVec);",    
                    "newPosition = roofCentroid + newPosition;",

            "gl_Position = projectionMatrix * modelViewMatrix * vec4(newPosition.xyz, 1.0);",

So this one gives the faulty vertex positions, if I change "cos(phi)" and "sin(phi)" to cosphi and sinphi, which are the attributes, calculated on the CPU, by javascript's Math.sin(phi) and Math.cos(phi), then the code works. The buildings/cubes are intact, so the displacement works and the intersecting works since the buildings/cubes get put at the surface of the sphere, with correct distanceToPlane.

ANSWER by Cornstalks on gamedev.net:

The big number is an issue. If your vertex shader is working with 32-bit floats, that only gives you 6 decimal digits of precision. 5476389.695241543 to 6 decimal digits of precision is 5476380.000000 (truncating everything after the 6 digits). Pi is only ~3.14, and since sin/cos are periodic, using large numbers doesn't give you any benefit over using smaller numbers (because the large numbers just wrap around). However, your numbers are so large that they wrap around so much that they don't even precisely map to the [-pi, pi] (or [0, 2pi]) range. Basically, the wrapping around throws away all the "high" digits and only keeps the relevant low digits, but unfortunately for you all your low digits are junk because you spent all 6 of your precision digits on the ones that get thrown away, and now all your low (but most important) digits are meaningless.

In short, yes, those huge numbers will kill you.

However, in JavaScript, all floating point numbers are 64-bit, which gives you 15 decimal digits of precision. That means in JavaScript you can actually properly represent 5476389.69524154, so your trig calculations are actually accurate (assuming your JavaScript code is processing the same large values that your vertex shader is).

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For interest, here's the whole thread over on gamedev.net: gamedev.net/topic/… –  Air May 23 at 19:07

1 Answer 1

There is not difference sin denotes the sine function.

Make sure you are using the radians.

to convert you may use

var angleInRadians = angleInDegrees * Math.PI / 180;
share|improve this answer
Where is index coming from? Seems like it's null and you try to multiply inc with it –  raam86 Jul 6 '13 at 11:11
Index is just a counter for every vertex, between 1 and 2500000, I group them by 8, so a one cube you see on these pictures are 8 vertices with same index, the index gives that fibonacci point. And I don't think it's null because it isn't null in the second code snip, and it's the same index I put in. –  user2010496 Jul 6 '13 at 19:58
Your code doesnt reflect this –  raam86 Jul 6 '13 at 20:17
Yea I know, it wasn't necessary to show all the code, it would just confuse everyone. The interesting part is why vec3 fibPoint have a corrent result if I pre-calculate sin and cos on the CPU and throw them in as an attribute, but becomes completely different if I calculate sin and cos in the shader. –  user2010496 Jul 6 '13 at 20:43
I can show you the complete vertex shader if you're interested, putting in new edit –  user2010496 Jul 6 '13 at 20:52

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