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I was watching the presentation : " Why Do Monads Matter? "

I simplified one code example which compiles and runs (please see below) but I still don't understand how it works.

More precisely: I don't understand the composePref function. According to the type definition it should take 2 parameters of Ize type and return one result of Ize type. (Ize means "whatdoyoucallit"/thingy/something in Hungarian.)

But it takes three parameters (f g x), could someone please explain how the composePref function works and what are the types of f, g, x, y and c ?

I have to admit that I am very beginner in Haskell. Maybe I don't understand how currying works in this case ?

module Dependence where
main = putStrLn (f "foo" cfg)
         where f = right `composePref` right `composePref` left
               cfg = 2

left :: Ize
left s = \i -> (repeatString i "< ") ++ s

right ::Ize
right s = \i -> s ++ (repeatString i " >")

repeatString :: Integer -> String -> String
repeatString i s = if (i <= 0)
                    then ""
                    else s ++ repeatString (i - 1) s

type Ize = String -> Integer -> String

composePref :: Ize -> Ize -> Ize
composePref f g x = \c -> let y =  (g x) c 
                          in       (f y) c

Produces output:

< < foo > > > >
share|improve this question
up vote 6 down vote accepted

You are right in thinking that it is currying that allows this behavior. If we look at the definition of Ize, it's just a type synonym for String -> Integer -> String. If we plug this in to the type signature of composePref, we'd get

composePref :: (String -> Integer -> String) -> (String -> Integer -> String) -> (String -> Integer -> String)

(I hope you see now why a type alias was used, it greatly shortens the signature). Since -> in type signatures is right associative, it means that something like

a -> b -> c -> d

Is equivalent to

a -> (b -> (c -> d))

So we can further simplify the signature to be (with some extra type aliases because I don't want to type them all)

type I = Integer
type S = String

composePref :: (S -> I -> S) -> (S -> I -> S) -> S -> I -> S
composePref f g x = \c -> ...

Then f :: (S -> I -> S), g :: (S -> I -> S), and x :: S. I included the beginning of that labmda so that I could say that c :: I. You could actually write this function as:

composePref :: Ize -> Ize -> Ize
composePref f g x c = let y = (g x) c in (f y) c

Which is also equivalent to

composePref f g x c = let y = g x c in f y c
-- (map show) [1, 2, 3] === map show [1, 2, 3]


composePref f g x c = f (g x c) c

Or even

composePref f g = \x c -> f (g x c) c

These are all equivalent definitions of composePref. I think the last might make it most clear that it's a function that takes two functions and returns a new function of the same type.

To try to make it even more clear, I'll write some illegal syntax with type annotations where you aren't really supposed to use them:

composePref (f :: Ize) (g :: Ize) = h
        h :: Ize
        h (x :: String) (c :: Integer) =
            let (y :: String) = (g x) c
            in (f y) c
share|improve this answer
Thanks for the explanation, how does the compiler figure out all this ? Is this not ambigous without explicit type declaration on f g and x ? How does the compiler know that x is meant to be integer and not, say Int -> String? By looking at the expression in the function body ? Would the compiler complain if it could not infer the types of f g and x unambigously? – jhegedus Mar 28 '14 at 17:33
Yes, the compiler complains if there is any ambiguity. – augustss Mar 28 '14 at 17:34
@jhegedus The compiler uses some pretty intelligent algorithms to infer types. If it can't figure it out, then it has no choice but to throw an error. Since you've provided the function composePref a type signature of Ize -> Ize -> Ize, it reduces that down to the non-aliased long form and it can figure out that x :: String and c :: Integer. – bheklilr Mar 28 '14 at 17:37
@bheklilr I said "the", because it is the principal one. So it's special. :) Admittedly, it's not the same one as the was given. – augustss Mar 28 '14 at 19:04
@augustss Your statement was in no way incorrect, I just wanted to make sure that it was clarified for someone who might not have a full understanding of the compiler's type-inferring abilities. – bheklilr Mar 28 '14 at 19:30

If you expand the type of the last Ize in your function you get:

composePref :: Ize -> Ize -> (String -> Integer -> String)
composePref f g x = \c -> let y =  (g x) c 
                          in       (f y) c

which is the same as

composePref :: Ize -> Ize -> String -> Integer -> String

which is also the same as:

composePref :: Ize -> Ize -> String -> (Integer -> String)

which matches your definition of composePref more closely. Now f and g are both Ize while x is a String and c is an Integer

share|improve this answer

You could use the following alternative definition, if this makes things clearer

 composePref :: Ize -> Ize -> Ize
 composePref f g = \x -> \c -> let y =  (g x) c 
                               in       (f y) c
share|improve this answer

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