Here's a solution which might scale better for large lists of small numbers. At least it's different ;v) .

According to http://en.wikipedia.org/wiki/Pythagorean_triple#Generating_a_triple,

```
a = m^2 - n^2, b = 2mn, c = m^2 + n^2
```

`b`

looks nice, eh?

- Sort the array in O(N log N) time.
- For each element
`b`

, find the prime factorization. Naively using a table of primes up to the square root of the largest input value M would take O(sqrt M/log M) time and space* per element.
- For each pair
`(m,n), m > n, b = 2mn`

(skip odd `b`

), search for `m^2-n^2`

and `m^2+n^2`

in the sorted array. O(log N) per pair, O(2^(Ω(M))) = O(log M)** pairs per element, O(N (log N) (log M)) total.

Final analysis: O( N ( (sqrt M/log M) + (log N * log M) ) ), N = array size, M = magnitude of values.

(* To accept 64-bit input, there are about 203M 32-bit primes, but we can use a table of differences at one byte per prime, since the differences are all even, and perhaps also generate large primes in sequence on demand. To accept 32-bit input, a table of 16-bit primes is needed, which is small enough to fit in L1 cache. Time here is an overestimate assuming all prime factors are just less than the square root.)

(** Actual bound lower because of duplicate prime factors.)