As iuliux points out, your problem is that you are treating your BTree as though it were a mutable structure. Remember functions in haskell take arguments and return a value. That is all. So when you "map over" a list, or traverse a tree your function needs to return a new tree.

The code you have is traversing the recursive tree and only returning the *last leaf*. Imagine for now that the leaf at the end of the path will *always* be `ND`

. This is what you want:

```
add :: a -> Path -> Btree a -> Btree a
add da xs ND = Data da
add _ [] _ = error "You should make sure this doesn't happen or handle it"
add da (x:xs) (Branch st st2) =
case x of
L -> Branch (add da xs st) st2
R -> Branch st (add da xs st2)
```

Notice how in your original code you discard the `Branch`

you pattern match against, when what you need to do is return it "behind you" as it were.

Now, on to the issue of handling situations where the leaf you arrive it is not a `ND`

constructor:

This type of problem is common in functional programming. How can you return your recursive data structure "as you go" when the final result depends on a leaf far down the tree?

One solution for the trickiest of cases is the Zipper, which is a data structure that lets you go up down and sideways as you please. For your case that would be overkill.

I would suggest you change your function to the following:

```
add :: a -> Path -> Btree a -> Maybe (Btree a)
```

which means at each level you must return a `Maybe (Btree a)`

. Then use the `Functor`

instance of `Maybe`

in your recursive calls. Notice:

```
fmap (+1) (Just 2) == Just 3
fmap (+1) (Nothing) == Nothing
```

You should try to puzzle out the implementation for yourself!

`BTree`

defined? – FUZxxl Mar 27 '11 at 16:57