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.

`(\x y -> x*y)`

? – Mikhail Glushenkov Apr 15 '13 at 21:56`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`(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