Well, let's take a look at the type signature for the curried function `foldr`

:

```
>:t foldr
foldr :: (a -> b -> b) -> b -> [a] -> b
```

So `foldr`

takes a binary function (i.e. `a->b->b`

), a `b`

value, a list of `a`

values, and returns a `b`

value.

Let's also look at the documentation for `foldr`

to get a more clear definition:

foldr, applied to a binary operator, a starting value (typically the
right-identity of the operator), and a list, reduces the list using
the binary operator, from right to left:

Now, let's take a look at the type signature for `myConcat xs = foldr (++) []`

```
> :t myConcat
myConcat :: t -> [[a]] -> [a]
```

Hmm...that's not what we wanted...

The problem is that you never provided `foldr`

a value of type `[a]`

. So now, `myConcat`

needs some value, of any type, to satisfy `xs`

*and* a value of type `[a]`

to complete `foldr (++) []`

, like:

```
> myConcat 2 [[1,2],[3,4]]
[1,2,3,4]
> myConcat Nothing [[1,2],[3,4]]
[1,2,3,4]
```

That works, but the first argument is just a waste.

However, if we pass that `xs`

value over to `foldr (++) []`

, like:

`myConcat xs = foldr (++) [] xs`

and check its type signature

```
> :t myConcat
myConcat :: [[a]] -> [a]
```

Ah, much better. Now myConcat uses `xs`

to complete the `foldr`

function.

Also, `myConcat = foldr (++) []`

also works, and is actually an example of point-free style programming. If we check the type signature of `foldr (++) []`

,

```
> :t foldr (++) []
foldr (++) [] :: [[a]] -> [a]
```

Since we already provided `foldr`

its first two arguments through partial application, we get a function back that will takes a `[[a]]`

value and do what we want! So we just assign it to a name, and it works just like the example above, but we didn't need to explicitly pass arguments!

```
> let myConcat = foldr (++) []
> :t myConcat
myConcat :: [[a]] -> [a]
> myConcat [[1,2],[3,4]]
[1,2,3,4]
```