I'd like to generate all possible pairs of pairs from a list, with the restriction that (a,b) == (b,a) and that ((a,b),(c,d)) == ((c,d),(a,b)) for all a, b, c, d. Additionally, I can assume that all elements in the list I supply as an argument are distinct.

The first thing I did was to write down this list comprehension:

```
pairsOfPairs :: [a] -> [((a,a),(a,a))]
pairsOfPairs xs = [((w,x),(y,z)) | w <- xs, x <- xs, y <- xs, z <- xs,
w < x, y < z, w < y, w /= z, x /= y, x /= z]
```

This has the virtue of being idiomatic, but is very slow (profiling reveals that close to 90% of the running time was spent in this function and another, similar, function).

The reason for the slowness is that for a list of n elements it generates n^4 candidate pairs of pairs, but the restrictions eventually cut it down to n!/(8 * (n-4)!), meaning that we are doing at least 8 times too much work.

Is there a way to rewrite the function `pairsOfPairs`

that will give it a speed boost? Obviously it will still be O(n^4), but I'm hoping to bring down the constant.

**Edit:** In fact, I almost always call this function with a list of length 5, meaning that there are 5!/8 = 15 elements in the result, but the function generates a list of 5^4 = 625 elements as an intermediate step. If I could eliminate all of these intermediate elements I'd therefore get a speedup of around 40x!