You probably got your answer already, but just to reiterate:

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
```

instead of having to say

```
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.