`xs !! n`

has a linear complexity. You should rather try using a logarithmic or constant-access data structure.

Edit : here is a quick implementation I came up with by copying a similar one by augustss :

```
psOpt x = psArr x
where psCall 0 = 1
psCall n = sum $ map getP $ takeWhile ((<= n).fst) pents where
getP (pent,sign) = sign * (psArr (n-pent))
psArr n = if n > ncache then psCall n else psCache ! n
psCache = listArray (0,ncache) $ map psCall [0..ncache]
```

In ghci, I observe no spectacular speedup over your list version. No luck !

**Edit :**
Indeed, with `-O2`

as suggested by Chris Kuklewicz, this solution is eight times faster than your for `n=5000`

. Combined with Hammar insight of doing sums modulo 10^6, I get a solution that is fast enough (find the hopefully correct answer in about 10 seconds on my machine):

```
import Data.List (find)
import Data.Array
ps = 1 : map p [1..] where
p n = sum $ map getP $ takeWhile ((<= n).fst) pents where
getP (pent,sign) = sign * (ps !! (n-pent))
summod li = foldl (\a b -> (a + b) `mod` 10^6) 0 li
ps' = 1 : map p [1..] where
p n = summod $ map getP $ takeWhile ((<= n).fst) pents where
getP (pent,sign) = sign * (ps !! (n-pent))
ncache = 1000000
psCall 0 = 1
psCall n = summod $ map getP $ takeWhile ((<= n).fst) pents
where getP (pent,sign) = sign * (psArr (n-pent))
psArr n = if n > ncache then psCall n else psCache ! n
psCache = listArray (0,ncache) $ map psCall [0..ncache]
pents = zip (map (\n -> ((3*n-1)*n `div` 2) `mod` 10^6) $ [1..] >>= (\x -> [x,-x]))
(cycle [1,1,-1,-1])
```

(I broke the psCache abstraction, so you should use `psArr`

instead of `psOpt`

; this ensures that different call to `psArr`

will reuse the same memoized array. This is useful when you write `find ((== 0) . ...)`

... well, I thought it was better not to publish the *complete* solution.)

Thanks to all for the additional advice.