Well, we all know that if N is given it's easy to calculate N!. But what about the inverse?
N! is given and you are about to find N  Is that possible ? I'm curious.

You can optimize by using the previous result of It's just as fast as going the opposite direction, if not faster, given that division generally takes longer than multiplication. A given factorial 





If you have Q=N! in binary, count the trailing zeros. Call this number J. If N is 2K or 2K+1, then J is equal to 2K minus the number of 1's in the binary representation of 2K, so add 1 over and over until the number of 1's you have added is equal to the number of 1's in the result. Now you know 2K, and N is either 2K or 2K+1. To tell which one it is, count the factors of the biggest prime (or any prime, really) in 2K+1, and use that to test Q=(2K+1)!. For example, suppose Q (in binary) is
(Sorry it's so small, but I don't have tools handy to manipulate larger numbers.) There are 19 trailing zeros, which is
Now increment:
So N is 22 or 23. I need a prime factor of 23, and, well, I have to pick 23 (it happens that 2K+1 is prime, but I didn't plan that and it isn't needed). So 23^1 should divide 23!, it doesn't divide Q, so



Yes. Let's call your input x. For small values of x, you can just try all values of n and see if n! = x. For larger x, you can binarysearch over n to find the right n (if one exists). Note hat we have n! ≈ e^(n ln n  n) (this is Stirling's approximation), so you know approximately where to look. The problem of course, is that very few numbers are factorials; so your question makes sense for only a small set of inputs. If your input is small (e.g. fits in a 32bit or 64bit integer) a lookup table would be the best solution. (You could of course consider the more general problem of inverting the Gamma function. Again, binary search would probably be the best way, rather than something analytic. I'd be glad to be shown wrong here.) Edit: Actually, in the case where you don't know for sure that x is a factorial number, you may not gain all that much (or anything) with binary search using Stirling's approximation or the Gamma function, over simple solutions. The inverse factorial grows slower than logarithmic (this is because the factorial is superexponential), and you have to do arbitraryprecision arithmetic to find factorials and multiply those numbers anyway. For instance, see Draco Ater's answer for an idea that (when extended to arbitraryprecision arithmetic) will work for all x. Even simpler, and probably even faster because multiplication is faster than division, is Dav's answer which is the most natural algorithm... this problem is another triumph of simplicity, it appears. :) 


Multiple ways. Use lookup tables, use binary search, use a linear search... Lookup tables is an obvious one:
You could implement this using hash tables for example, or if you use C++/C#/Java, they have their own hash tablelike containers. This is useful if you have to do this a lot of times and each time it has to be fast, but you can afford to spend some time building this table. Binary search: assume the number is Of course, these numbers might be very big and you might end up doing a lot of unwanted operations. A better idea is to search between 1 and Linear search: Probably the best in this case. Calculate 


Well, if you know that M is really the factorial of some integer, then you can use
You can solve this (or, really, solve 


Here is some clojure code:
Suppose n=120, div=2. 120/2=60, 60/3=20, 20/4=5, 5/5=1, return 5 Suppose n=12, div=2. 12/2=6, 6/3=2, 2/4=.5, return 'nil' 


I know it isn't a pseudocode, but it's pretty easy to understand 





This function is based on successive approximations! I created it and implemented it in Advanced Trigonometry Calculator 1.7.0



If you do not know whether a number 


Check inverse gamma functions from here http://functions.wolfram.com/GammaBetaErf/InverseGammaRegularized/ They have multiple aproximations 


In C from my app Advanced Trigonometry Calculator v1.6.8
What you think about that? Works correctly for factorials integers. 

