I recently wrote a program to do what was described in HAKMEM 123. Copy-pasting verbatim...
Consider the image of the circle $|z| = 1$ under the function
$f(z) = \sum_n \frac{z^{2^{n}}}{2^{n}}$
This is physically analogous to a series of clock hands placed end to end. The first hand rotates around the center (0,0) at some rate. the next hand is half as long and rotates around the end of the first hand at twice this rate. The third hand rotates around the end of the second at four times this rate; etc. It would seem that the end of the "last" hand (really there are infinitely many) would sweep through space very fast, tracing out an (infinitely) long curve in the time the first hand rotates once. The hands shrink, however, because of the $2^n$ in the denominator. Thus it is unclear whether the curve's arc length is really infinite.
Was this problem ever solved? Is the curve's arc length infinite or finite? My gut feeling says that it's infinite, but I don't really know how to go about proving it.
(By the way, tagging help would be appreciated.)