Ok my problem is of mathematical nature. I have an array of bytes whose length is X, i need to find the two closest numbers which multiplied together equal X. I need to do this because i am bulding a bitmap from an array of bytes and i need to make the bitmap look like a square as much as possible. I am coding this in C# but don' t worry about syntax, any algorithm or pseudocode will do. Thanks in advance for your help
There's probably a better algorithm for this, but off the top of my head:



Note that if X is at all large, then starting from sqrt(X) and working downwards one step at a time will be a miserable task. This may take a huge amount of time. If you can find the factors of the number however, then simply compute all divisors of X that are less than sqrt(X). Consider the number X = 123456789012345678901234567890. The smallest integer less than sqrt(X) is 351364182882014, so simply decrementing that value to test for a divisor may be problematic. Factoring X, we get this list of prime factors:
It is a fairly quick operation to compute the divisors less then sqrt(N) given the prime factors, which yields a divisor 349788919693221, so we have
These are the closest pair of divisors of the number N. But, how many times would we have needed to decrement, starting at sqrt(N)? That difference is: 1575263188793, so over 1.5e12 steps. A simple scheme to determine the indicated factors (in MATLAB)
The other factor is obtained simply enough. If the numbers are too large to exceed the dynamic range of a flint as a double, then you will need to use some variation of higher precision arithmetic. 


I have rewritten the MATLAB answer proposed above by user85109 in a detailed function with sufficient comments and some simpler terms. Certainly quite efficient, works for large numbers and hopefully easy to write in any language which provides a library function for getting prime factorization of an integer.



A perfect square would have a side of SQRT(X) so start from there and work downward.
Note this will only work if 


One alternative is to set up this optimization problem Minimize the difference of the factors X and Y the difference of the product X × Y and P. You have thus an objective function that is weighted some of two objective:
where c, d are nonnegative numbers that define which objective you value how much. Like the 

