I was working on a Project Euler problem and ended up with a Haskell file that included a function that looked like this:

```
matches :: (a -> a -> Bool) -> a -> [(a, Int)] -> Int
matches f cs = foldr (\(cs', n) a -> fromBool (f cs cs') * n + a) 0
```

With `fromBool`

imported from `Foreign.Marshal.Utils`

just to quickly convert `True`

to `1`

and `False`

to `0`

.

I was trying to get a little more speed out of my solution so I tried switching from `foldr`

to `foldl'`

(switching the arguments in the process) as I assumed `foldr`

didn't make much sense to use on numbers.

Switching from `foldr`

to `foldl'`

caused me to allocate more than twice as much memory according to GHC's profiler.

For fun I also decided to replace the lambda with a pointfree version of the function:

```
matches :: (a -> a -> Bool) -> a -> [(a, Int)] -> Int
matches f cs = foldr ((+) . uncurry ((*) . fromBool . f cs)) 0
```

This caused my memory allocation to increase 20x from the `foldr`

version.

Now this isn't a huge deal as even in the 20x case the total memory allocation was only about `135Mb`

and the runtime of the program was relatively unaffected, if anything the higher memory allocation versions ran slightly faster.

But I am really curious as to how these results could be possible, so that in future I will be able to pick the "right" function when I don't have as much leeway.

EDIT:

GHC version 7.10.2, compiled with `-O2 -prof -fprof-auto`

. Executed with `+RTS -p`

.

EDIT 2:

Alright it looks like this is too difficult to reproduce to omit the rest of the code, well here is the entire program:

SPOILERS BELOW:

```
{-# LANGUAGE NoMonomorphismRestriction #-}
import Control.Monad
import Data.List
import Foreign.Marshal.Utils
data Color = Red | Green | Blue deriving (Eq, Enum, Bounded, Show)
colors :: [Color]
colors = [Red ..]
matches :: (a -> a -> Bool) -> a -> [(a, Int)] -> Int
matches f x = foldr ((+) . uncurry ((*) . fromBool . f x)) 0
-- matches f x = foldr (\(y, n) a -> fromBool (f x y) * n + a) 0
-- matches f x = foldl' (\a (y, n) -> fromBool (f x y) * n + a) 0
invert :: [([Color], Int)] -> [([Color], Int)]
invert rs = (\cs -> (cs, matches valid cs rs)) <$> choices
where
len = maximum $ length . fst <$> rs
choices = replicateM len colors
valid (x : xs) (y : ys) = x /= y && valid xs ys
valid _ _ = True
expand :: [([Color], Int)] -> [([Color], Int)]
expand rs = (\cs -> (cs, matches valid cs rs)) <$> choices
where
len = maximum $ length . fst <$> rs
choices = replicateM (len + 1) colors
valid (x1 : x2 : xs) (y : ys) = x1 /= y && x2 /= y && valid (x2 : xs) ys
valid _ _ = True
getRow :: Int -> [([Color], Int)]
getRow 1 = flip (,) 1 . pure <$> colors
getRow n = expand . invert $ getRow (n - 1)
result :: Int -> Int
result n = sum $ snd <$> getRow n
main :: IO ()
main = print $ result 8
```

`cs`

lists themselves and what is your`f`

?`fromBool`

and not just`fromEnum`

?`uncurry`

and some optimizations, that's for sure, but in order to provide a complete answer, some example functions/values would bereallyhelpful.`a ~ Int`

, GHC creates a point-free variant with the same allocation behaviour,. If you useunless you call the function twice`a ~ Bool`

, point-free functionsalwayslead to the allocation behavior. So, long story short, it's a PITA to reproduce your behaviour exactly. Please add at least the used type for`a`

.`fromBool`

appears before`fromEnum`

in hoogle when I searched for`Bool -> Int`

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