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I'm studying Haskell and am trying to understand how to applying the concept of currying to functions. I understand the currying is essentially a means of taking a function with several arguments and applying the function to one argument, returning a function that is applied to the second, and so on... without losing any expressiveness. One tutorial I'm working on asks:

"Write a curried version of 2 * (\x y -> x*y)2 3"

I'm hoping someone can help show me how to work this out. Thanks in advance

Edit: In response to two commenters, I can see that recognising

(\x y -> x*y) :: Num a => a -> a -> a

... is my first step. I have a fairly slow learning curve when it comes to functional programming (also new SO poster so excuse any etiquette I break) ... what would my next step be?

Edit 2: @Mikhail, I see that uncurry applied to the type of the lambda expression would something of the form (given uncurry :: (a -> b -> c) -> (a,b) -> c)

Num a => (a,a) -> a 
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Start by answering a simpler question: what is the type of (\x y -> x*y)? –  Mikhail Glushenkov Apr 15 '13 at 21:56
Int -> Int -> Int ? or Num a => a -> a -> a –  Steve Apr 15 '13 at 22:02
The latter. But the former will do too for this purpose. –  Daniel Fischer Apr 15 '13 at 22:03
@Steve Now look at the type of the standard function uncurry and try to work out what is the type of the expression uncurry (\x y -> x * y). –  Mikhail Glushenkov Apr 15 '13 at 22:12
The last step is to create a lambda expression that has the type you just gave: (Int, Int) -> Int. In other words, instead of accepting two arguments in succession, it now takes a pair of arguments. –  Gabriel Gonzalez Apr 15 '13 at 22:32

1 Answer 1

up vote 5 down vote accepted

Your basic understanding of what currying is is correct. Concretely, it is about transforming a function that takes its arguments as a tuple, such as for example

add :: (Int, Int) -> Int
add    (x, y)     =  x + y

into a function that takes its arguments one at a time:

add' :: Int -> Int -> Int
add'    x      y   =  x + y

This scheme allows you to subject the now-curried function to partial application, i.e., applying it with some but not all of its arguments yet. For example we can have

succ :: Int -> Int
succ =  add' 1

where we apply add' to its first argument and yield a function that still expects the remaining argument.

The inverse transformation is called uncurrying and turns a function that takes it arguments "one by one" into a function that takes its arguments "all at once" as a tuple.

Both transformations can be captured by families of higher-order functions. That is, for binary functions there is

curry :: ((a, b) -> c) -> (a -> b -> c)
curry    f             =  \x y -> f (x, y)

uncurry :: (a -> b -> c) -> ((a, b) -> c)
uncurry    f             =  \(x, y) -> f x y

For ternary functions there is

curry3 :: ((a, b, c) -> d) -> (a -> b -> c -> d)
curry3    f                =  \x y z -> f (x, y, z)

uncurry3 :: (a -> b -> c -> d) -> ((a, b, c) -> d)
uncurry3    f                  =  \(x, y, z) -> f x y z

And so forth.

Now let us have a look at your example:

2 * (\x y -> x * y) 2 3

Here you are multiplying the literal 2 with the result of an application of the function (\x y -> x * y) that multiplies its two arguments x and y. As you can see, this function already takes its arguments "one by one". Hence, it is already curried. So, what is meant in your tutorial if they ask to write a curried version of this expression is beyond me. What we could do is write an uncurried version by having the multiplication function takes it arguments "all at once": (\(x, y) -> x * y). Then we get

2 * (\(x, y) -> x * y) (2, 3)

Now note that one could write (\(x, y) -> x * y) as uncurry (*), which would give us

2 * uncurry (*) (2, 3)

If we also uncurry the first application (or actually applications, plural ;-)) of (*), we yield

uncurry (*) (2, uncurry (*) (2, 3))

I doubt whether this was the intention behind the exercise in your tutorial, but I hope this provides you some insight in currying and uncurrying.

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Thank you for the response. It certainly helped me understand the concept a little better. –  Steve Apr 16 '13 at 10:36
Probably worth mentioning, the preceding question looks like this: 3) Write f:: Int -> Int -> Int f x y = 2*x+y f 2 3 using a lambda expression 4) Write a curried version of this lambda expression ... The expression you see above is my answer to 3), thus I suspect this is what question 4 is asking for –  Steve Apr 16 '13 at 10:38
@Steve: Perhaps it wanted you to write it out explicitly as multiple single-argument lambdas? e.g., (\x -> (\y -> ...)). That's... kind of pointless, and using the term "curried" wrong, but I suppose it emphasizes that the (\x y -> ...) form is equivalent (a shorthand, really). –  C. A. McCann Apr 16 '13 at 15:11

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