Firstly....to answer why your approach

simply finding the prime factors of n and searching for the combination where a,b are factors of n and a - b is minimized

is not optimal:

Suppose your number is `n = 2^7 * 3^4 * 5^2 * 7 * 11 * 13 (=259459200)`

, well within range of `int`

. From the combinatorics theory, this number has exactly `(8 * 5 * 3 * 2 * 2 * 2 = 960)`

factors. So, firstly you find all of these 960 factors, then find all pairs (a,b) such that `a * b = n`

, which in this case will be `(6C1 + 9C2 + 11C3 + 13C4 + 14C5 + 15C6 + 16C7 + 16C8)`

ways. (if I'm not wrong, my combinatorics is a bit weak). This is of the order `1e5`

if implemented optimally. Also, implementation of this approach is hard.

Now, why the difference of squares approach

represent S - n = Q, such that S and Q are perfect squares

is good:

This is because if you can represent `S - n = Q`

, this implies, `n = S - Q`

```
=> n = s^2 - q^2
=> n = (s+q)(s-q)
=> Your reqd ans = 2 * q
```

Now, even if you iterate for all squares, you will either find your answer or terminate when difference of 2 consecutive squares is greater than `n`

But I don't think this will be doable for all `n`

(eg. if `n=6`

, there is no solution for `(S,Q)`

.)

Another approach:

Iterate from `floor(sqrt(n))`

to 1. The first number (say, x), such that `x|n`

will be one of the numbers in the required pair `(a,b)`

. Other will be, obvs, `y = x/n`

. So, your answer will be `y - x`

.

This is `O(sqrt(n))`

time complex algorithm.