Given an array of numbers A, you can identify the denominator by multiplying all the numbers together to give E, then testing each i^{th} element by dividing E by A_{i}^{2}. If this is a whole number, you have found the denominator, as no other factors can be introduced by multiplication.

Once you have the denominator, it's a simple task to do a second, independent loop searching for the paired numerator.

This eliminates the n^{2} comparisons.

**Why does this work?** First, we have an n-2 collection of non-divisors: abcde..
To complete the array, we also have numerator x and denominator y.

However, we know that x and only x has a factor of y, so it can be expressed as yz (z being a whole remainder from the division of x by y)

When we multiply out all the numbers, we end up with xyabcde.., but as x = yz, we can also say y^{2}zabcde..

When we loop through dividing by the squared i'th element from the array, for most of the elements we create a fraction, e.g. for a:

y^{2}zabcde.. / a^{2} = y^{2}zbcde.. / a

However, for y and y only:

y^{2}zabcde.. / y^2 = zabcde..

**Why doesn't this work?** The same is true of the other numbers. There's no guarantee that a and b can't produce another common factor when multiplied. Take the example of [9, 8, 6, 4], 9 and 8 multiplied equals 72, but as they both include prime factors 2 and 3, 72 has a factor of 6, also in the array. When we multiply it all out to 1728, those combine with the original 6 so that it can divide soundly by 36.

**How might this be fixed?** More accurately, if y is a factor of x, then y's prime factors will uniquely be a subset of x's prime factors, so maybe things can be refined along those lines. Obtaining a prime factorization should not scale according to the size of the array, but comparing subsets would, so it's not clear to me if this is at all useful.