How can I write a program to find the factorial of any number?
This will work for the factorial (although a very small subset) of positive integers:
Due to the nature of your problem (and level that you have admitted), this solution is based more in the concept of solving this rather than a function that will be used in the next "Permutation Engine". 


This calculates factorials of nonnegative integers[*] up to ULONG_MAX, which will have so many digits that it's unlikely your machine can store a whole lot more, even if it has time to calculate them. Uses the GNU multiple precision library, which you need to link against.
Example output:
[*] If you mean something else by "number" then you'll have to be more specific. I'm not aware of any other numbers for which the factorial is defined, despite valiant efforts by Pascal to extend the domain by use of the Gamma function. 


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Thanks to Christoph, a C99 solution that works for quite a few "numbers":
produces 6.000000 120.000000 


For large n you may run into some issues and you may want to use Stirling's approximation: Which is: 


a tailrecursive version:



If your main objective is an interesting looking function:
(Not recommended as an algorithm for real use.) 


Here's a C program that uses OPENSSL's BIGNUM implementation, and therefore is not particularly useful for students. (Of course accepting a BIGNUM as the input parameter is crazy, but helpful for demonstrating interaction between BIGNUMs).
This test program shows how to create a number for input and what to do with the return value:
Compiled with gcc:






You use the following code to do it.



For large numbers you probably can get away with an approximate solution, which If you're working somewhere without a full C99 math.h, you can easily do this type of thing yourself:



source http://gist.github.com/25049 


In C99 (or Java) I would write the factorial function iteratively like this:



Example in C (C was tagged so i guess that's what you want) using recursion



I don't think I'd use this in most cases, but one wellknown practice which is becoming less widely used is to have a lookup table. If we're only working with builtin types, the memory hit is tiny. Just another approach, to make the poster aware of a different technique. Many recursive solutions also can be memoized whereby a lookup table is filled in when the algorithm runs, drastically reducing the cost on future calls (kind of like the principle behind .NET JIT compilation I guess). 


I have to make my CS professors proud and say that this is a perfect Dynamic Programming problem :) 


We have to start from In c, i am writing it as a function.



Simplest and efficent is to sum up logarhitms. If you use Log10 you get power and exponent. Pseudocode
You might need to add the code so the integer part does not increase to much and thus decrease accuracy, but result suld be ok for even very large factorials. 


I would do this with a precalculated lookup table, as John said. This would be faster to calculate than an iterative or recursive solution. It relies on how fast



long
. Factorial not being defined for negative numbers and "number" usually being interpreted as "element of Z" makes it ambiguous, too. – Pascal Cuoq Mar 10 '10 at 13:16