So I've got a special case set of cubic splines, whose 2d control points will always result in a curve that will never cross itself in the *x* axis. That is, the curves look like they could be a simple polynomial function such that *y*=*f*(*x*). I want to efficiently create an array of *y* coordinates along the spline that correspond to evenly-spaced x coordinates running the length of the spline segment.

I want to efficiently find the y coordinates along the spline where, for instance, *x*=0.0, *x*=0.1, *x*=0.2, etc., or approached another way, effectively transform the *f _{x,y}*(

*t*) style function into an

*f*(

*x*) function.

I'm currently using a 4x4 constant matrix and four 2d control points to describe the spline, using matrix constants for either Hermite or Catmull-Rom splines, and plugging them into a cubic function of *t* going from 0 to 1.

Given the matrix and the control points, what's the best way to obtain these y values over the x axis?

EDIT: I should add that an approximation good enough to draw is sufficient.

xcoordinates, whereas the edit requires a solution suitable for drawing. In the presence of pronounced cusps, an evenly spaced sampling will probably be unable to capture these cusps. So I suggest you leave the question as it originally was, as that is what the answers refer to. You might want to ask a new question about the drawing problem, preferrably giving details on what exactly you try to achieve, i.e. why simply drawing the 2D spline isn't enough. – MvG Jul 19 '12 at 8:41