The type is defined as

data BST = MakeNode BST String BST
| Empty

I'm trying to add a new leaf to the tree, but I don't really understand how to do it with recursion.

the function is set up like this

add :: String -> BST -> BST
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Your definition of BST won't work. I think you mean data BST = MakeNode String BST BST | Empty, right? –  dflemstr Mar 8 '12 at 17:32
yeah, that was a typo. thanks –  user1204349 Mar 8 '12 at 17:36

The advantage of using binary trees is that you only need to look at the "current part" of the tree to know where to insert the node.

So, let's define the add function:

add :: String -> BST -> BST

If you insert something into an empty tree (Case #1), you just create a leaf directly:

add s Empty = MakeNode Empty s Empty

If you want to insert something into a node (Case #2), you have to decide which sub-node to insert the value in. You use comparisons to do this test:

add s t@(MakeNode l p r) -- left, pivot, right
| s > p     = Node l p (add s r) -- Insert into right subtree
| s < p     = Node (add s l) p r -- Insert into left subtree
| otherwise = t -- The tree already contains the value, so just return it

Note that this will not rebalance the binary tree. Binary tree rebalancing algorithms can be very complicated and will require a lot of code. So, if you insert a sorted list into the binary tree (e.g. ["a", "b", "c", "d"]), it will become very unbalanced, but such cases are very uncommon in practice.

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insert should be add –  pat Mar 8 '12 at 17:55
@pat, indeed; corrected. –  dflemstr Mar 8 '12 at 18:01
@dflemstr could you explain the @ symbol quickly? –  user1204349 Mar 8 '12 at 18:15
The @ symbol creates a name for the whole pattern to the right of it. So, if I do t @ (MakeNode l p r), it's like saying let t = MakeNode l p r in in the code that follows, except that the program won't create a new MakeNode; it will just reuse the old one. –  dflemstr Mar 8 '12 at 18:19
okay, so its makes it so you can either use the the whole BST by using t, and use the pattern by using (MakeNode l p r), basically? –  user1204349 Mar 8 '12 at 18:21

Re-define your data as ( I used Int as the data type but replace with whatever )

data BST = Node BST Int BST | Leaf

Then you can have an insert function like this ( I don't allow duplicates in this!):

insert :: Int -> BST -> BST
insert n (Leaf _) = Node Leaf n Leaf
insert n (Node lt x rt)
| n > x     = Node lt x (insert n rt)
| n < x     = Node (insert n lt) x rt
| otherwise = Node lt x rt
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thanks, why are there 3 nodes? –  user1204349 Mar 8 '12 at 17:40
@ExtremeCoder, your code doesn't compile, because you are using Leaf which you didn't define, and your definition of Node won't work. –  dflemstr Mar 8 '12 at 17:50
Sorry about that. edited my code so it should work. Still not tested though! I have other things to do!! –  ExtremeCoder Mar 9 '12 at 16:58