```
uncurry f=\(a,b)->f a b
```

`uncurry`

converts a curried function to a function on pairs, but the function above just converts it to a curried function `f a b`

. Doesn't that contradict the definition of the `uncurry`

function?

What pelotom and Chuck said is 100% right. I think you just got a little confused at some point about curry vs uncurry and function definitions.

We know that a curried function is one like:

`add x y = x + y`

It's definition would be:

`add :: (Num a) => a -> a -> a`

Add takes a `Num`

, and returns a **function** that takes a `Num`

and returns a `Num`

.

By having it this way, we can get a **partially applied** function, like

`add3 = add 3`

Thanks to `add`

being curried, when we can pass just one parameter (in this case, 3), we can get back a function that takes a `Num`

and returns a `Num`

.

```
>add3 5
8
```

Uncurried functions takes **tuples**, or grouped together values, like (1,2). (Note, tuples don't have to pairs. You can have a tuple of the form of (1,2,3,4,5). Just regular old uncurry deals with specifically pairs). If we changed our add to be uncurried, it'd be:

```
add :: (Num t) => (t, t) -> t
add (x, y) = x + y
```

Which takes a tuple of two `Num`

s and returns a Num. We can't partially apply this like we did with add as a curried function. It needs **both** parameters, passed in a tuple.

Now, onto the uncurry function! (If you want to know the type of a function, use `:t <some function>`

in GHCi, or use Hoogle).

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

So what do we know from this? It takes **f**, which we notice from the definition is a **curried** function from (a->b->c), and it returns a **uncurried function** ((a,b)->c).

If we feed uncurry our curried add (remember: `add x y`

), what do we get back?

We get an **anonymous function**, or lambda function, that takes a tuple, and applies the values of the tuple, `a`

and `b`

, to our function, `add`

.

`f a b`

doesn't mean we get a function -- you'd see a `->`

if that was the case. We just get the **value** of `f`

with `a`

and `b`

.

It's kind of like if we did this by hand:

`tupleAdd (a,b) = add a b`

But `uncurry`

does this all for us, and we can just continue along with our brand new uncurried form of our originally curried function.

Cool, hunh?

Another way of writing this definition so it's clearer what's going on would be:

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

The variable `f`

has type `a -> b -> c`

, i.e. it is a curried function, and `uncurry g`

for some curried function `g`

has the type `(a, b) -> c`

, i.e. an uncurried function.

Remember that when `x`

and `y`

are terms, `x y`

means *apply the function x to y*. And

`f a b`

(or `(f a) b`

) means `f`

to the argument `a`

, producing a function of type `b -> c`

, then immediately apply this function to `b`

, producing a result of type `c`

You can write a function which behaves the same way (and with the same signature) without a lambda:

```
uncurry' :: (a -> b -> c) -> ((a, b) -> c)
uncurry' f (a,b) = f a b
```

I think this version is easier to read. If you have a tupel and a function which takes two single values (or more exact, which takes one value and returns a function that takes the next value), the uncurry' function does the "unwrapping" of the tuple for us.

Generally if you see something like

```
f x y z = x + y + z
```

it's the same as

```
f = \x y z -> x + y + z
```

or

```
f x = \y -> (\z -> x + y + z)
```

`\(a,b)->`

part means — it defines an anonymous function that takes a pair and performs the given function on the values in that pair.

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