Nobody has discussed the BigInteger version. For that I'd look at 10^{1}, 10^{2}, 10^{4}, 10^{8} and so on until you find the last 10^{2n} that is less than your value. Take your number div and mod 10^{2n} to come up with 2 smaller values. Wash, rinse, and repeat recursively. (You should keep your iterated squares of 10 in an array, and in the recursive part pass along the information about the next power to use.)

With a BigInteger with k digits, dividing by 10 is O(k). Therefore finding the sum of the digits with the naive algorithm is O(k^{2}).

I don't know what C# uses internally, but the non-naive algorithms out there for multiplying or dividing a k-bit by a k-bit integer all work in time O(k^{1.6}) or better (most are much, much better, but have an overhead that makes them worse for "small big integers"). In that case preparing your initial list of powers and splitting once takes times O(k^{1.6}). This gives you 2 problems of size O((k/2)^{1.6}) = 2^{-0.6}O(k^{1.6}). At the next level you have 4 problems of size O((k/4)^{1.6}) for another 2^{-1.2}O(k^{1.6}) work. Add up all of the terms and the powers of 2 turn into a geometric series converging to a constant, so the total work is O(k^{1.6}).

This is a definite win, and the win will be very, very evident if you're working with numbers in the many thousands of digits.

repeated sumthen there is a trick. See this recent question: stackoverflow.com/questions/5151224/… – Eric Lippert Mar 11 '11 at 19:31