It's always a good idea to benchmark (and Criterion makes it so easy). Here are the results for the original solution (`insertEdgeO`

), Geoff's `foldr`

(`insertEdgeF`

), and `Data.Map`

(`insertEdgeM`

):

```
benchmarking insertEdgeO...
mean: 380.5062 ms, lb 379.5357 ms, ub 381.1074 ms, ci 0.950
benchmarking insertEdgeF...
mean: 74.54564 ms, lb 74.40043 ms, ub 74.71190 ms, ci 0.950
benchmarking insertEdgeM...
mean: 18.12264 ms, lb 18.03029 ms, ub 18.21342 ms, ci 0.950
```

Here's the code (I compiled with `-O2`

):

```
module Main where
import Criterion.Main
import Data.List (foldl')
import qualified Data.Map as M
insertEdgeO :: (Int, Int, Int) -> [(Int, Int, Int)] -> [(Int, Int, Int)]
insertEdgeO (x, y, z) cs =
if length [(a, b, c) | (a, b, c) <- cs, a /= x || b /= y] == length cs
then (x, y, z) : cs
else [if (a == x && b == y) then (a, b, c + z) else (a, b, c) | (a, b, c) <- cs]
insertEdgeF :: (Int, Int, Int) -> [(Int, Int, Int)] -> [(Int, Int, Int)]
insertEdgeF (x,y,z) cs =
case foldr f (False, []) cs of
(False, cs') -> (x, y, z) : cs'
(True, cs') -> cs'
where
f (a, b, c) (e, cs')
| (a, b) == (x, y) = (True, (a, b, c + z) : cs')
| otherwise = (e, (a, b, c) : cs')
insertEdgeM :: (Int, Int, Int) -> M.Map (Int, Int) Int -> M.Map (Int, Int) Int
insertEdgeM (a, b, c) = M.insertWith (+) (a, b) c
testSet n = [(a, b, c) | a <- [1..n], b <- [1..n], c <- [1..n]]
testO = foldl' (flip insertEdgeO) [] . testSet
testF = foldl' (flip insertEdgeF) [] . testSet
testM = triplify . M.toDescList . foldl' (flip insertEdgeM) M.empty . testSet
where
triplify = map (\((a, b), c) -> (a, b, c))
main = let n = 25 in defaultMain
[ bench "insertEdgeO" $ nf testO n
, bench "insertEdgeF" $ nf testF n
, bench "insertEdgeM" $ nf testM n
]
```

You can improve `insertEdgeF`

a bit by using `foldl'`

(55.88634 ms), but `Data.Map`

still wins.

`c = c + z`

but have`c + 1`

in your code. Which is the desired behavior? – Travis Brown Sep 13 '10 at 18:02