In a research paper, I read the following statement

The computations of S (...) and C (...) involve computing ratios of factorials such as (2n)!/(2k)!, where 0 ≤k ≤ n. This can be done in time O(n^2(logn)^2) by a straightforward algorithm.

They have not mentioned which straightforward algorithm they are talking about. If they are talking about direct multiplication of integers, then according to this link, the total time for n! calculation alone would be O(n^2 log n) which leaves us with around O(log n) time for division, which I think is not possible.

One approach which I can think of is:- 1.) Choosing a fast factorial algorithm from here. 2.) Dividing using Schönhage–Strassen algorithm combined with Newton’s reciprocal method.

It's just an initial idea though.

Is there a more specific efficient algorithm for calculating ratio of two factorials with arbitrary precision?


You do not need to divide, you just multiply numbers from (2k+1) to (2n), this is obviously can be done in the limits specified;).

  • Haha...ofcourse. Thanks. :) That answers finding the answer withing the specified limits. Though does there exist a more efficient algorithm? – Paagalpan May 21 '13 at 17:30
  • I'm not sure, but probably in the algorithm pointed by your link we can find multiplicity of the prime factor in the (2k)! and (2n)! simultaneously and then subtract one from another? – begemotv2718 May 21 '13 at 17:49

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