I have problem, i can't figure out how i must decide what sub-tree my function
indexJ must to choose at the each step walks through the my balanced binary tree -
The idea is to cache the size (number of data elements) of each sub-tree. This can then be used at each step to determine if the desired index is in the left or the right branch.
I have this code:
data JoinList m a = Empty | Single m a | Append m (JoinList m a) (JoinList m a) deriving (Eq, Show) newtype Size = Size Int deriving (Eq, Ord, Show, Num) getSize :: Size -> Int getSize (Size i) = i class Sized a where size :: a -> Size instance Sized Size where size = id instance Monoid Size where mempty = Size 0 mappend = (+)
i write functions:
tag :: Monoid m => JoinList m a -> m tag Empty = mempty tag (Single x dt) = x tag (Append x l_list r_list) = x (+++) :: Monoid m => JoinList m a -> JoinList m a -> JoinList m a (+++) jl1 jl2 = Append (mappend (tag jl1) (tag jl2)) jl1 jl2 indexJ :: (Sized b, Monoid b) => Int -> JoinList b a -> Maybe a indexJ _ Empty = Nothing indexJ i jl | i < 0 || (i+1) > (sizeJl jl) = Nothing where sizeJl = getSize . size . tag indexJ 0 (Single m d) = Just d indexJ 0 (Append m (Single sz1 dt1) jl2) = Just dt1 indexJ i (Append m jl1 jl2) = if (sizeJl jl1) >= (sizeJl jl2) then indexJ (i-1) jl1 else indexJ (i-1) jl2 where sizeJl = getSize . size . tag
(+++) working well, but i need to finish
indexJ function, which must return i-th element from my JoinList tree, i = [0..n]
indexJ working wrong =)
if i have empty tree - it's (Size 0)
if i have Single (Size 1) "data" - it's (Size 1)
but what about if i have Append (Size 2) (Single (Size 1) 'k') (Single (Size 1) 'l') what branch i must choose? i-1 = 1 and i have two branches with 1 data element in each.
UPDATE: if someone needs take and drop functions for JoinList's trees i make it:
dropJ :: (Sized b, Monoid b) => Int -> JoinList b a -> JoinList b a dropJ _ Empty = Empty dropJ n jl | n <= 0 = jl dropJ n jl | n >= (getSize . size $ tag jl) = Empty dropJ n (Append m jL1 jL2) | n == s1 = jL2 | n < s1 = (dropJ n jL1) +++ jL2 | otherwise = dropJ (n - s1) jL2 where s1 = getSize . size $ tag jL1 takeJ :: (Sized b, Monoid b) => Int -> JoinList b a -> JoinList b a takeJ _ Empty = Empty takeJ n jl | n <= 0 = Empty takeJ n jl | n >= (getSize . size $ tag jl) = jl takeJ n (Append m jL1 jL2) | n == s1 = jL1 | n < s1 = (takeJ n jL1) | otherwise = jL1 +++ takeJ (n - s1) jL2 where s1 = getSize . size $ tag jL1