How can we computer (N choose K)% M in C or C++ without invoking overflow ?
For the particular case when N (4<=N<=1000) and K (1<=K<=N) and M = 1000000003.

To compute (n choose k) % M, you can separately compute the nominator (n!) modulus M and the denominator (k!*(n  k)!) modulus M and then multiply the nominator by the denominator's modular multiplicative inverse (in M). Since M is prime, you can use Fermat's Little Theorem to calculate the multiplicative inverse. There is a nice explanation, with sample code, on the following link (problem SuperSum): 


Since 1000000003 = 23 * 307 * 141623 you can calculate (n choses k) mod 23, 307 and 141623 and then apply the chinese reminder theorem[1]. When calculating n!, k! and (nk)!, you should calculate everythinng mod 23, 307 and 141623 each step to prevent overflow. In this way you should avoid overflow even in 32bit machines. A little improvement would be to calculate (n choses k) mod 141623 and 7061 (23 * 307) (edit: but it can be a little tricky to calculate the inverse modulus 7061, so I wouldn't do this) I'm sorry for my poor English. [1]http://en.wikipedia.org/wiki/Chinese_remainder_theorem Edit2: Another potentially problem I've found is when calculating n! mod 23 (for example) it will probably be 0, but that doesn't implies that (n choses k) is 0 mod 23, so you should count how many times 23 divides n!, (nk)! and k! before calculating (n choses k). Calculating this is easy, p divides n! exactly floor(n/p) + floor(n/p²) + ... times. If it happens that 23 divides n! the same times it divides k! and (nk)!, the you proceed to calculate (n choses k) mod 23 dividing by 23 every multipler of it every time.The same applies for 307, but not for 141623 


You could use the recursive formula from the link you gave and do the calculation mod M. 


Seems to have been answered elsewhere already 


Here is a simple example:
That is, all you need to apply modulus to every operand and product, or as soon as it becomes big a number. And last the modulus must apply to the overall result. 


Use Stirling's approximation to calculate the binomial coefficient. Then just calculate the modulus as usual. 

