We'll start with the first signature:

```
(t -> a) -> Tree t -> Tree a
```

This essentially says, "Given a function that takes something of type `t`

and produces an `a`

and also a `Tree`

containing items of type `t`

, produce a `Tree`

containing elements of type `a`

.

`t`

and `a`

are completely arbitrary names that GHCi generated; we could have easily said:

```
(originalType -> newType) -> Tree originalType -> Tree newType
```

Although most programmers would write:

```
(a -> b) -> Tree a -> Tree b
```

Now, the second signature:

```
t -> Tree t1 -> Tree a
```

This signature's strange because, like Hammar pointed out, the two `maptree`

definitions you wrote in GHCi are completely independent. So let's look at the second definition all by itself:

```
maptree f (Node xl xr) = Node (maptree f xl) (maptree f xr)
```

Here, the type of `f`

does not matter as you don't apply it to any arguments and you only pass it to `maptree`

, which recursively doesn't care what type `f`

is. So let's give `f`

type `t`

, as it doesn't matter.

Now, similarly, there's no constraint on `xl`

and `xr`

, as they are only passed to `maptree`

which doesn't know their types except that it should be a `Tree`

. Thus, we might as well call their type `Tree t1`

.

We know this function will return a `Tree`

because of the `Node`

constructor, but the previous two types we looked at have no bearing on the type of elements in the tree, so we may as well call it `Tree a`

.

As an example, let's see what happens when we expand the following:

```
maptree True (Node (Leaf 0) (Leaf 1))
= Node (maptree True (Leaf 0)) (maptree True (Leaf 1))
```

Which then fails because there's no way for `maptree`

to expand a `Leaf`

in this case.

However, the types work out:

```
True :: t
Node (Leaf 0) (Leaf 1) :: Tree t1
0 :: t1
1 :: t1
```

So that signature was very odd, but it does make sense. Remember to not overwrite definitions, I guess.