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I am a little confused about what the "partial" application of flip might do.

Since the type of the flip function is:

flip :: (a -> b -> c) -> b -> a -> c

which we can write without the parenthesis as:

flip :: a -> b -> c -> b -> a -> c

How can I partially apply it to only the first argument a? To get a function with the type:

flipa ::     b -> c -> b -> a -> c

Or it doesn't make sense?

For example if I have something like:

let foo a b = (Just a, b)
:t foo
> foo:: a -> t -> (Maybe a, t)

It makes sense to partially apply it:

let a = foo 1
:t a
a :: t -> (Maybe Integer, t)
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(->) is right-associative, not left-associative: the flipa you describe is an entirely different function (AFAIK the type dictates it must be flipa _ x _ _ = x). – delnan Feb 24 '12 at 15:40
Another view of why aren't these two equivalent: let's take f :: (a → a) → a and g :: a → a → a. By Curry-Howard isomorphism, g represents theorem a ⇒ a ⇒ a, i.e. if a is true, then a implies a (which is true; it can be derived from a ⇒ (b ⇒ a) (axiom of intuitionistic logic)). On the other hand, (a ⇒ a) ⇒ a tells us nothing about a (if a implies a then a; but as you can see, a could also be false and a ⇒ a still holds). Indeed, if you have f :: (a → a) → a, you can prove that false is true: boom :: False; boom = f id (where False is empty data type) – Vitus Feb 24 '12 at 16:19

3 Answers 3

up vote 19 down vote accepted

It doesn't make sense. The signature

f :: a -> b -> c

is equivalent to

f :: a -> (b -> c)

and not equivalent to

f :: (a -> b) -> c

This convention is why you can partially apply function in Haskell in the first place. Since all functions are curried by default, the signature f :: a -> b -> c can be interpreted as

f takes a and b, and returns c

or can equally validly be interpreted as

f takes a, and returns a function that takes b and returns c

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Hm.. what about a simple function as see in my updated question. – drozzy Feb 24 '12 at 15:47
What's your question about that function? – Chris Taylor Feb 24 '12 at 15:51
"Partial application" is a valid synonym for "currying" – amindfv Feb 24 '12 at 15:58
Well, yes, considering function (a × b × c) → d, currying turns it into a → b → c → d, while partial application fixes any of the arguments into function (b × c) → d (or other pair depending on the argument being applied). – Vitus Feb 24 '12 at 16:56
@drozzy: You can and you in fact already did! Imagine that flip has type d → b → a → c, where d must be a function of type a → b → c. If you apply flip to a function f of type d, you get back a new function b → a → c with the d argument fixed. – Vitus Feb 24 '12 at 19:23

(a -> b -> c) -> b -> a -> c is not the same as a -> b -> c -> b -> a -> c because the -> operator is right-associative, not left-associative. Therefore, partially applying flip is meaningless because it only has one parameter in the first place.

Also, your example doesn't make much sense because it would still produce an output function taking an a, which you would presumably not want. But if you take that out, you get a function which takes a unary function and produces exactly the same unary function, so just partially apply the original function and you're done.

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I see three parameters :D (but surely, not five!) – Ptival Feb 24 '12 at 15:55
It depends how you look at it, but in its normal usage flip has one parameter and produces a function which takes two parameters. Of course in Haskell because of currying this is exactly the same as partially applying a function that takes three parameters. – Matthew Walton Feb 27 '12 at 12:58

As others have noted, the type (a -> b -> c) -> b -> a -> c is not the same as a -> b -> c -> b -> a -> c.

However, it is the same as (a -> b -> c) -> (b -> a -> c).

That shows that flip is a function that takes a single argument as input and therefore can't be partially applied*.

*: from the point of view of that flip returns a function of type b -> a -> c, which is not the only valid point of view in Haskell.

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Why is it the same as (a -> b -> c) -> (b -> a -> c)? How come you can take the parenthesis of the last triple, but not the first? – drozzy Feb 24 '12 at 19:15
@drozzy -- Learn You a Haskell says because functions are curried by default, the second pair of parentheses is really unnecessary, because -> is right associative by default. (a -> b -> c) -> (b -> a -> c) is the same as (a -> b -> c) -> (b -> (a -> c)), which is the same as (a -> b -> c) -> b -> a -> c. So it's because of the associativity of ->. – Matt Fenwick Feb 24 '12 at 19:25
@drozzy: That's because -> is right associative. In other words, a → (b → (c → (d → e))) is the same as a → b → c → d → e. As an example, division on real numbers is left associative, that means ((5 / 4) / 3) / 2 = 5 / 4 / 3 / 2 but not 5 / (4 / (3 / 2)). edit: perhaps even more suggestive example: (5 / 4) / (3 / 2) ≠ 5 / 4 / 3 / 2 – Vitus Feb 24 '12 at 19:26

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