Really, I'd like to figure out the more general solution of composing a fold with a zipwith in a single function point free.

zWMult :: Num c => [c] -> [c] -> [c]
zWMult = zipWith (*)

foldPl0 :: Num c => [c] -> c
foldPl0 = foldl (+) 0

I get the correct solution when I use arguements

dPr x y = foldPl0 (zWMult x y)
dPr x y = foldPl0 $ zWMult x y

But have no idea how to naturally compose these without arguments. Both these fail:

Prelude> :{
Prelude| let dPr1 :: Num c => [c] -> [c] -> c
Prelude|     dPr1 = fPl0 $ zWMult
Prelude| :}

Couldn't match expected type ‘[[c] -> [c] -> c]’
            with actual type ‘[Integer] -> [Integer] -> [Integer]’
Relevant bindings include
  dPr1 :: [c] -> [c] -> c (bound at <interactive>:171:5)
Probable cause: ‘zWMult’ is applied to too few arguments
In the second argument of ‘($)’, namely ‘zWMult’
In the expression: fPl0 $ zWMult

Prelude> :{
Prelude| let dPr1 :: Int c => [c] -> [c] -> c
Prelude|     dPr1 = foldPl0 $ zWMult
Prelude| :}

‘Int’ is applied to too many type arguments
In the type signature for ‘dPr1’: dPr1 :: Int c => [c] -> [c] -> c

As well as

dPr2 = foldPl0 . zWMult

Edit: Cool, one should cross reference this post if you want a more complete understanding of the solution below. What does (f .) . g mean in Haskell?

  • 1
    You can use pointfree.io to convert to pointfree. Use with care, since pointfree easily turns into obfuscation.
    – chi
    Mar 26, 2018 at 11:53

1 Answer 1


Starting with a simpler version:

dot x y = sum (zipWith (*) x y)

you can convert \x -> f (g x) with function composition to f . g:

dot x = sum . zipWith (*) x

f . g means (.) f g:

dot x = (sum.) (zipWith (*) x)

and you can convert \x -> f (g x) with function composition to f . g:

dot = (sum.) . zipWith (*)
  • 3
    While this (f .) . g idiom is a common point-free way to compose a 1-argument function with a 2-argument one, it can also be written fmap sum . zipWith (*) or even fmap sum <$> zipWith (*) which I find slightly more descriptive than partial application of (.), since while fmap in the (->) functor is equivalent to composition, it illustrates the fact that you’re “mapping” over the result of a function by ignoring arguments (one fmap for each argument).
    – Jon Purdy
    Mar 26, 2018 at 1:14

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