Take the 2-minute tour ×
Stack Overflow is a question and answer site for professional and enthusiast programmers. It's 100% free, no registration required.

I'm looking to sample from a texture along a circular arc in a fragment shader. That kind of rules out recursive methods such as this.

I have come up with a few different ways to accomplish this: Two that seem the most reasonable are (Given start position p, center c, radius r = length(c-p), angle (arc extent) theta in radians and N positions):

1) Rotate the vector p-c about c by theta/N, N times: This requires the construction of a rotation matrix which will be repeatedly used: cost is two trig functions, N 2x2 matrix multiplies, N or so vector subtractions

2) Find the chord length of one segment traversing a sector: Its length is 2*r*sin(theta/2). Once I have the first vector I can rotate it and add it to the previous position to "step along" my arc. The problem with this method is that I still don't know the expression to obtain the orientation of my length 2*r*sin(theta/2) vector. Even if I did I'd likely need trig functions to construct it. I still need to rotate it so that might require me to still build a rotation matrix. Ugh.

Are there other methods I could consider?

share|improve this question
Can you elaborate on what you mean by "sample ... along a circular arc"? Would you be sampling in a circle (or portion of a circle) around each pixel? And would the arc be the same for every pixel (same angle and/or radius)? Or something else? Also, why are you trying to do this? Are you by any chance trying to produce a radial blur? –  user1118321 Jan 17 '12 at 4:21
I'll not reveal exactly what it is i'm doing. Hopefully you'll see it in a game someday. As for a radial blur, acceptable results are usually obtained by sampling along a line. –  Steven Lu Jan 17 '12 at 19:03
It is more of a curved blur. A blur that follows the motion of a rigid object, to be exact, and it is a linear combination of a circular motion about a fixed center (rotation) and linear motion –  Steven Lu Feb 13 '13 at 20:33

1 Answer 1

up vote 2 down vote accepted

I think that once you start using circles and angles you are bound to have a couple of trig calls. Given that, the first method seems OK. I'd only note that I do not see the need for 2D matrix multiplies as such if act iteratively on the points.

void f(float cx, float cy, float px, float py, float theta, int N)
    float dx = px - cx;
    float dy = py - cy;
    float r2 = dx * dx + dy * dy;
    float r = sqrt(r2);
    float ctheta = cos(theta/(N-1));
    float stheta = sin(theta/(N-1));
    std::cout << cx + dx << "," << cy + dy << std::endl;
    for(int i = 1; i != N; ++i)
        float dxtemp = ctheta * dx - stheta * dy;
        dy = stheta * dx + ctheta * dy;
        dx = dxtemp;
        std::cout << cx + dx << "," << cy + dy << std::endl;

Given large N, you might find that some errors accumulate here. Given some assumptions around N and theta you might be able to make some small angle approximations for the trig.

Summary: If you want the specified number of points and are using arcs, I cannot see that you are really going to find a way to do much less computation than something close to option 1).

share|improve this answer
Seems to me like this is performing the same operations as a rotation matrix multiplication would. I reckon doing the matrix mult should be faster on the hardware. I figured if I know my value of N and theta to begin with I can generate the matrix in the vertex shader. Thanks though. –  Steven Lu Jan 17 '12 at 19:11
Yep this works. Performance is amazing also. –  Steven Lu Jan 20 '12 at 5:17
Fine! Fast and can even be made faster in cases where tens or thousands of arcs are drawn eg. rounded corners in polygons. I implemented a version where c/sthetas are calculated outside that function for full circle (angles 0-2PI) and implemented custom stopping criterion: drawing is started from px,py as normally, but there is also end coord ex, ey and the exit occurs when current x is more or less than ex (different behavior in upper and lower half). I added also CCW/CW functionality (essential in polygon drawing, there can be holes:). Thanks for this snippet! –  Timo Feb 11 '13 at 18:55

Your Answer


By posting your answer, you agree to the privacy policy and terms of service.

Not the answer you're looking for? Browse other questions tagged or ask your own question.