This answer addresses some conceptual problems with the question itself. I don't intend it as a complete answer.
The first is that in the situation given there's always a function. Mathematically, you describe a curve as a function from the real numbers, roughly representing "time", to your space. This is often called a parametric representation of the curve. We write the function as
f(t) =( x(t), y(t) ), where
y(t) are the individual parameter functions.
The problem is that the function you have may not be the function you want. Every problem of this type, in order to have hope of an answer, has to state explicitly what class of functions are admissible as an answer. Just saying "functions" has little meaning. The question is missing a statement of admissible classes of functions are viable. There's a mention of splines, though, so let's pursue that. Given a class of splines (bi-cubic ones are common), in general you can only fit to so many points on the spline, not an arbitrary number. So what you want is the class of piecewise spline functions, that is, a sequence of splines.
Once you have an admissible class of function, you also have to decide how to pick them. The condition you seem to have stated is that you want the spline to pass through the given points. That's a common condition, but not the only one. Others are to minimize curvature, to minimize length, to minimize the total distance of the points to the curve, etc. The fitting condition is also part of the statement of the problem.
Summarizing, it sounds like you want to fit a piecewise spline curve to pass through a sequence of points. Now see the other answers, because that's the question they're answering.