I just started learning haskell and i'm not able to solve this issue. Can someone tell me why i get error that g is applied to too few arguments in the code below.

f :: Int -> Int
f first  = 5+first

g :: Int -> Int -> Int
g  first second = first+second


compute :: (Int -> Int) -> (Int -> Int -> Int) -> Int -> Int -> Int
compute f g x y = (f . g) x y
  • 1
    Technically, you cannot apply a function to too few arguments, because every function takes exactly one argument. – chepner Dec 6 at 18:54
  • 3
    This should be the other way around with the brackets: compute f g x y = f (g x y). – Willem Van Onsem Dec 6 at 18:55
  • Thank you very much @WillemVanOnsem :) – Khan Saab Dec 6 at 18:57
  • @chepner, you can of course fail to apply it to any arguments at all. And if you're applying seq to a function (don't do that!) things get more subtle. – dfeuer Dec 6 at 19:03
  • @dfeuer I don't count not applying it as a degenerate form of application. – chepner Dec 6 at 19:48
up vote 5 down vote accepted

First, look at the definition of f . g:

f . g = \x -> f (g x)

Then we can expand the definition of compute as follows:

compute f g x y = (f . g) x y
                = (\z -> f (g z)) x y
                = (f (g x)) y
                = (5 + (g x)) y

g x : Int -> Int, for which there is no Num instance, so you can't add it to 5.

The problem is that you want g applied to both x and y before its result is passed to f. To do that, you need something more than simple composition. The simplest way to write this is directly:

compute f g x y = f (g x y)

If you are aiming for something more point-free, you need to get fancy with the composition:

compute f g = \x -> \y -> f (g x y)
            -- application is left-associative
            = \x -> \y -> f ((g x) y)
            -- def'n of (.)
            = \x -> f . (g x)
            -- eta abstraction
            = \x -> (\z -> f . z) (g x)
            -- def'n of an operator section
            = \x -> (f .) (g x)
            -- def'n of (.)
            = (f .) . g

If you want to be completely point-free, you can write

compute = (.) . (.)

You compose the composition operator with itself.

  • Stylistically I prefer to write this sort of composition as fmap f . g: fmap in the (->) r functor is just (.), but written as fmap it’s more clearly “mapping over” or “skipping” an argument, so (f . g) x y = f (g x) y, (fmap f . g) x y = f (g x y); or with higher numbers of arguments: (fmap (fmap f) . g) x y z = f (g x y z), and so on. – Jon Purdy Dec 7 at 2:23
  • @JonPurdy Odd. What motivates using (.) instead of fmap at the last layer? Why not fmap (fmap f) g instead of fmap f . g, for example, and fmap (fmap (fmap f)) g instead of fmap (fmap f) . g? – Daniel Wagner Dec 7 at 2:35
  • @DanielWagner: The fact that it’s fully applied, I suppose, and I still want the overall expression to look like a pipeline; to me, the fmap is clearer to read than a section with (.), but it’s also just an incidental bit to get around the fact that (.) is only really made for single-valued/linear dataflow pipelines. Similarly, I think f <$> getX <*> getY is clearer than the specialised f . getX <*> getY, because the former has the typical idiomatic … <$> … <*> … <*> … pattern of applicative code. – Jon Purdy Dec 7 at 6:27

A common mistake is to think that the function composition operator . passes along "as many arguments as needed". But this isn't the case: it threads only one argument through.

So when you write

(f . g) x y

you are probably hoping that this meant

f (g x y)

but it actually means

f (g x) y

-- that is, y gets passed to f as a second argument, instead of g. Whoops!

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