I've just started working my way through Okasaki's Purely Functional Data Structures, but have been doing things in Haskell rather than Standard ML. However, I've come across an early exercise (2.5) that's left me a bit stumped on how to do things in Haskell:
Inserting an existing element into a binary search tree copies the entire search path even though the copied nodes are indistinguishable from the originals. Rewrite insert using exceptions to avoid this copying. Establish only one handler per insertion rather than one handler per iteration.
Now, my understanding is that ML, being an impure language, gets by with a conventional approach to exception handling not so different to, say, Java's, so you can accomplish it something like this:
type Tree = E | T of Tree * int * Tree exception ElementPresent fun insert (x, t) = let fun go E = T (E, x, E) fun go T(l, y, r) = if x < y then T(go (l), x, r) else if y < x then T(l, x, go (r)) else raise ElementPresent in go t end handle ElementPresent => t
I don't have an ML implementation, so this may not be quite right in terms of the syntax.
My issue is that I have no idea how this can be done in Haskell, outside of doing everything in the
IO monad, which seems like cheating and even if it's not cheating, would seriously limit the usefulness of a function which really doesn't do any mutation. I could use the
data Tree a = Empty | Fork (Tree a) a (Tree a) deriving (Show) insert :: (Ord a) => a -> Tree a -> Tree a insert x t = maybe t id (go t) where go Empty = return (Fork Empty x Empty) go (Fork l y r) | x < y = do l' <- go l; return (Fork l' y r) | x > y = do r' <- go r; return (Fork l y r') | otherwise = Nothing
This means everything winds up wrapped in
Just on the way back up when the element isn't found, which requires more heap allocation, and sort of defeats the purpose. Is this allocation just the price of purity?
EDIT to add: A lot of why I'm wondering about the suitability of the
Maybe solution is that the optimization described only seems to save you all the constructor calls you would need in the case where the element already exists, which means heap allocations proportional to the length of the search path. The
Maybe also avoids those constructor calls when the element already exists, but then you get a number of
Just constructor calls equal to the length of the search path. I understand that a sufficiently smart compiler could elide all the
Just allocations, but I don't know if, say, the current version of GHC is really that smart.