I'm looking for a algorithim that can compute an approximation of the Kolmogorov complexity of given input string. So if K is the Kolmogorov complexity of a string S, and t represents time, then the function would behave something like this.. limit(t>inf)[K_approx(t,S)] = K.
In theory, a program could converge on the Kolmogorov complexity of its input string as the running time approaches infinity. It could work by running every possible program in parallel that is the length of the input string or shorter. When a program of a given length is found, that length is identified as the minimum length known for now, is printed, and no more programs >= that length are tried. This algorithm will (most likely) run forever, printing shorter and shorter lengths, converging on the exact Kolmogorov complexity given infinite time. Of course, running an exponential number of programs is highly intractible. A more efficient algorithm is to post a code golf on StackOverflow. A few drawbacks:



The wikipedia page for Kolmogorov complexity has a subsection entitled "Incomputability of Kolmogorov complexity", under the "Basic results" section. This is not intended to be a basic measure that you can compute, or even approximate productively. There are better ways of achieving what you want, without a doubt. If a measure of randomness is what you want, you could try the binary entropy function. Compressibility by one of the standard algorithms might also fit the bill. 


I think this might work? If somebody sees an error, please point it out.



It looks like Ray Solomonoff did a lot of work in this field. Publications of Ray Solomonoff Does Algorithmic Probability Solve the Problem of Induction? 


The first issue that I notice is that "the Kolmogorov Complexity" isn't well defined. It depends to some degree on the choice of how to represent programs. So, the first thing you would need to do is fix some encoding of programs (for example, Joey Adams' specification that programs be written in J). Once you have the encoding, the algorithm you are looking for is quite simple. See Joey's answer for that. But the situation is even worse than having to run exponentially many programs. Each of those programs could run as long as you could possibly imagine (technically: running time as a function input size could grow faster than any recursive function). What's more, it could be the case that some of the shortest programs are the ones that run the longest. So while the parallel approach will approach the correct value as time goes to infinity, it will do so unimaginably slowly. You could stop the program prematurely, figuring that the approximation at that point is good enough. However, you have no idea in general how good that approximation is. In fact, there are theorems that show you can never know. So the short answer is "easy, just use Joey's algorithm", but by any measure of practicality, the answer is, "you don't have a chance". As has been recommended by rwong, you are better off just using a heavyduty compression algorithm. 


K(x) is not computable. Unfortunately that means your "limit(t>inf)[K_approx(t,S)] = K" won't work. K(x) is also not approximable. For example, it is possible that the smallest program p that produces S is both unique and never halts. Then K_appox(t,S) will never = K(S), no matter how much time or resources it is given. 


*/~1+i.9
) with the J programming language ( see here ). From this, you could say that a 9x9 multiplication table has a Kolmogorov complexity of 8 or less with respect to the J programming language. – Joey Adams Aug 19 '10 at 14:45