dflemstr's answer is spot on, but I thought I'd add two remarks (that can't be accommodated by a comment to the original answer).

First, by the same logic that the second definition can save memory, a similar argument can be made for this one:

```
data Tree a = Empty
| Leaf a
| LeftOnly a (Tree a)
| RightOnly a (Tree a)
| Branch a (Tree a) (Tree a)
```

Whether this actually matters depends on your application.

The second and more important remark is that if you avoid using data constructors directly, you can abstract away from these implementation choices. For example, equivalent `foldTree`

functions can be written for any of these types. For the shorter type you do it like this:

```
data Tree a = Empty | Node a (Tree a) (Tree a)
foldTree :: (a -> b -> b -> b) -> b -> Tree a -> b
foldTree f z Empty = z
foldTree f z (Node v l r) = f v (subfold l) (subfold r)
where subfold = foldTree f z
```

And for the longer one you can write it like this:

```
data Tree a = Empty | Leaf a | Node a (Tree a) (Tree a)
foldTree :: (a -> b -> b -> b) -> b -> Tree a -> b
foldTree f z Empty = z
foldTree f z (Leaf v) = f v z z
foldTree f z (Node v l r) = f v (subfold l) (subfold r)
where subfold = foldTree f z
```

The same can be done for your `Maybe`

-based alternative or for my five-constructor alternative. Also, this technique can be applied to whatever other generic functions on trees that you need. (In fact, a lot of these functions can be written in terms of `foldTree`

, so most of it falls out of the definitions above.)

`Tree (Maybe a (Tree a) (Tree a))`

doesn't compile. Did you mean`Tree (Maybe (a, Tree a, Tree a))`

? – Daniel Fischer Jul 31 '12 at 20:30