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# Uncurried functions

I'm having trouble understanding curried and uncurried functions. All the sites I Google'd to try to provide me a definition were unclear to me.

In one example I found them saying that

`max 4 5` is the same as `(max 4) 5`

But I don't understand what they're doing. How can you have a function `(max 4)` when max requires 2 parameters? I'm completely lost.

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I think this question and my answer there might help: stackoverflow.com/questions/8148253/how-are-functions-curried/… – Ben Mar 21 '13 at 5:54

The trick with Haskell is that functions only take one argument. This seems totally crazy but it actually works.

``````foo :: Int -> Int -> Int
foo a b = a + b
``````

Really means: A function which takes in 1 argument, and then returns another function which takes one argument. This is called currying.

So using this, we can really write this function definition like this:

``````foo :: Int -> (Int -> Int) --In math speak: right associative
``````

and mean exactly the same thing.

This is actually super useful because we can now write concise code like:

``````foo1 :: Int -> Int
foo1 = foo 1
``````

Since function application in haskell is just whitespace, most of the time you can just pretend that curried functions are uncurried (taking more than one argument and just returning a result).

If you really really realllly need uncurried functions: Use tuples.

``````uncFoo :: (Int, Int) -> Int
uncFoo (a, b) = a + b
``````

Edit

OK so to understand whats going on with partial application consider `bar`

``````bar a b c = [a, b, c]
``````

The thing is, the compiler will desugar what you just typed into lambdas like this

``````bar = \a ->
\b ->
\c ->
[a, b, c]
``````

This takes advantage of closures (each inner function can 'remember' the arguments to the previous ones.

so when we say `bar 1`, the compiler goes and looks at `bar` and sees the outermost lambda, and applies it giving

``````bar 1 = \b ->
\c ->
[1, b, c]
``````

If we say `bar 1 2`

``````bar 1 2 = \c ->
[1, 2, c]
``````

If what I mean when I say "apply" is hazy, then it may help to know that I really mean beta reduction from lambda calculus.

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I understand that it takes one argument and returns another function which takes another argument, but how does it calculate anything? So in your case if I had the function `foo a` how is it supposed to do anything with just one argument? I think I need a more detailed explanation as to the process of it working. – dtgee Mar 21 '13 at 4:52
Look at the lambdas. That's what's actually happening. Hang on, im editing cause this is too small – jozefg Mar 21 '13 at 4:52
@user1831442 There you are – jozefg Mar 21 '13 at 5:03
Hmmm, so are you saying that for `foo a b = a + b` `(foo 4) 5` just plugs in `4` so we get `4 + b`? What I'm getting from your example is that `bar` is just plugging stuff in. Gah, currying seems like such a simple concept to understand, why am I having so much trouble understanding it?! – dtgee Mar 21 '13 at 5:09
Yeah thats it! It's basically boils down to substitution. And don't worry everyone who learns Haskell hits stuff like this :) – jozefg Mar 21 '13 at 5:10

Depending on your background, you may find this paper enlightening: How to Make a Fast Curry: Push/Enter vs Eval Apply. While it's true that multi-argument functions can be understood as functions which bind a single parameter and return another function: `max = (\a -> (\b -> if a > b then a else b))`, the actual implementation is quite a bit more efficient.

If the compiler knows statically that `max` requires two arguments, the compiler will always translate `max 4 5` by pushing the two arguments on the stack (or in registers) and then invoking `max`. This is essentially the same as how a C compiler would translate `max(4, 5)`.

On the other hand, if for instance `max` is an argument to a higher-order function, the compiler may not know statically how many arguments `max` takes. Perhaps in one instance it takes three, so `max 4 5` is a partial application, or perhaps in another it takes only one and `max 4` generates a new function to which `5` is applied. The paper discusses the two common approaches to handling the case where the arity isn't known statically.

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If we have

``````add x y = x + y
``````

then we can say the following:

``````add = \ x y -> x + y
add 3 = \ y -> 3 + y
add 3 5 = 3 + 5 = 8
``````

You ask "how can `max 3` calculate anything?", and the answer is "it can't". It just gives you another function. This function can do something when you call it, but you don't "get an answer" as such until all the arguments have been supplied. Until then, you just get functions.

Most of the time, this is just a useful syntactic shortcut. For example, you can write

``````uppercase :: String -> String
uppercase = map toUpper
``````

``````uppercase xs = map toUpper xs
``````

Notice that if `map` had its arguments the other way around, we wouldn't be able to do this (you can only curry away the last argument, not the _first), so it can be important to think about which order you define your functions' arguments.

I say "most of the time" because this is more than syntax sugar. There are several places in the language where you can handle functions with different numbers of arguments polymorphically because of currying. Every function either returns an answer, or another function. If you think of it like a linked list (which either contains the next item of data or the end-of-list marker), you can see how this lets you recursively process functions.

So what the heck do I mean by that? Well, for example, QuickCheck can test functions with any number of arguments (provided there's a way to auto-generate test data for each argument). This is possible because function types are curried. Every function either returns another function, or a result. If you think about it like a linked list, you can imagine QuickCheck recursively iterating over the function until no more arguments are left.

The following code snippet may or may not explain the idea:

``````class Arbitrary a where
autogenerate :: RandomGenerator -> a

instance Arbitrary Int
instance Arbitrary Char
...

class Testable t where
test t :: RandomGenerator -> Bool

instance Testable Bool where
test rnd b = b

instance (Arbitrary a, Testable t) => Testable (a -> t) where
test rnd f = test \$ f (autogenerate rnd)
``````

If we have a function `foo :: Int -> Int -> Bool`, then this is `Testable`. Why? Well, `Bool` is testable, therefore so is `Int -> Bool`, and therefore so is `Int -> (Int -> Bool)`.

By contrast, each size of tuple is a different size, so you have to write separate functions (or instances) for each and every size of tuple. You can't recursively process tuples, because they don't have a recursive structure.

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To relate to your own example...

Suppose that you want a function that gives the maximum of 4 and the functions argument. You could implement it like this:

``````max4 :: Integer -> Integer
max4 x = max 4 x
``````

What `max 4` does is just to return the function `max4` created on the fly.

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