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Haskell newbie here. I was going through Learn you a haskell, and came across this definition of the flip function.

flip' :: (a -> b -> c) -> (b -> a -> c)  
flip' f = g  
    where g x y = f y x

What I don't get is, where did x and y come from? I mean, the signature tells me that flip' is a function that takes a function (with two parameters), and returns a function (again, with two parameters).

If I'm understanding this right, when I write a function which goes like

foo :: (a -> b) -> a -> b
foo f x = f x   -- applies the function f on x

But then, in this case I'm passing the parameter explicitly [ ie x ] and so I'm able to access it in the function body. So how come the flip' function can access the parameters x and y?

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Do you know that (a -> b) -> a -> b and (a -> b) -> (a -> b) are equivalent? – Rhymoid Jan 18 '13 at 11:04
Equivalent because -> operator associates to the right? Similar to how I can write a -> (b -> c) as a -> b -> c. – ersran9 Jan 18 '13 at 11:10
Exactly. I thought it would help to see that foo f x = f x is the same as foo f = f (given the same type signature). Anyway, those parameters x and y you mention are bound in the definition of g, that's where they come from. The definition of g can also be written as g = (\x y -> f y x). This means that flip' could also be defined as flip' f = (\x y -> f y x), which is equivalent to flip' f x y = f y x. This is in a way related to the right-associativity of (->). – Rhymoid Jan 18 '13 at 11:29
up vote 23 down vote accepted

The Prelude, which is in the base package at hackage.haskell.org, is included with an implicit import in every Haskell file is where the flip function is found. On the right side you can click "source" and see the source code for flip.

flip         :: (a -> b -> c) -> b -> a -> c
flip f x y   =  f y x

The where clause allows for local definitions, x=10 or y="bla". You can also define functions locally with the same syntax you would for the top level. add x y = x + y

In the below equivalent formulation I make the substitution g = f y x

flip         :: (a -> b -> c) -> b -> a -> c
flip f x y   =  g
    g = f y x

Right now g takes no parameters. But what if we defined g as g a b = f b a well then we would have:

flip         :: (a -> b -> c) -> b -> a -> c
flip f x y   =  g x y
    g a b = f b a

No we can do a little algebraic cancelation(if you think of it like algebra from math class you will be pretty safe). Focusing in on:

flip f x y   =  g x y

Cancel the y on each side for:

flip f x   =  g x

Now cancel the x:

flip f   =  g

and now to put it back in the full expression:

flip     :: (a -> b -> c) -> b -> a -> c
flip f   =  g
    g a b = f b a

As a last cosmetic step we can make the substitution a to x and b to y to recover the function down to argument names:

flip     :: (a -> b -> c) -> b -> a -> c
flip f   =  g
    g x y = f y x

As you can see this definition of flip is a little round about and what we start with in the prelude is simple and is the definition I prefer. Hope that helps explain how where works and how to do a little algebraic manipulation of Haskell code.

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My last edit was so I did not shadow any names n my g definition, hopefully that will make it clearer for those not used to how scoping works yet in Haskell. – Davorak Jan 18 '13 at 11:32

flip' doesn't access x and y. It receives an argument f, and evaluates to the expression g. No x or y in sight.

However, g is itself a function, defined with an auxiliary equation in the where clause of flip'.

You can read g x y = f y x exactly as if it were a top level equation like flip'. So g is a function of two arguments, x and y. It's g that has access to x and y, not flip'. Values for those arguments don't exist until g is applied, which is not until after flip' has returned the function g (if ever).

The thing that's special that about g being defined in the where clause of flip' is that it can have access to the arguments of flip', which is how g can be defined in terms of f.

So when flip' is invoked it receives a function f. For each particular invocation of flip', it constructs a new function g. g would receive two arguments, x and y, when it is called, but that hasn't happened yet. flip' then just returns g as its result.

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Okay, I think things are getting less foggier. The way I see it - g is a kind of delegate (is that the right term? ) which will be evaluated when flip' gets called. – ersran9 Jan 18 '13 at 11:19
@ersran9 Not really. g is the return value of flip'. Someone who calls flip' gets the return value; it's up to them when (and if, and how many times) they call it. Like any return value, what is done with it afterwards has nothing to do with flip'. – Ben Jan 18 '13 at 13:37

Let's find the type of g.

We know flip type : (a -> b -> c) -> (b -> a -> c)

Therefore we can deduce f type : (a -> b -> c)

We have this definition for g

g x y = f y x

From the right-hand-side we deduce that y :: a and x :: b.

Hence g :: b -> a -> c

Note that the definition could be rewritten without the 'where' clause.

flip' f = g where g x y = f y x
-> flip' f a b = g a b where g a b = f b a
-> flip' f a b = f b a
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That barely answers the question. The question is about binding and using x and y. – Rhymoid Jan 18 '13 at 10:53
I think the type analysis explains much of the definition. However, I edited to better address the question of the bindings, hopefully. – Paul R Jan 18 '13 at 11:04

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