Take the 2-minute tour ×
Stack Overflow is a question and answer site for professional and enthusiast programmers. It's 100% free, no registration required.

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 - JoinList.

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

functions tag and (+++) working well, but i need to finish indexJ function, which must return i-th element from my JoinList tree, i = [0..n]

my function 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
share|improve this question

2 Answers 2

up vote 6 down vote accepted

I suppose in

Append m joinList1 joinList2

the elements of joinList1 are meant to take up the first indices, followed by the elements of joinList2.

Then, when indexing

indexJ i (Append m jL1 jL2)

you have to compare i to the size of jL1 - let us call that s1. Then the elements of jL1 occupy the indices 0 to s1 - 1, and the elements of jL2 occupy the indices from s1 to s1 + s2 - 1, hence

indexJ :: (Sized b, Monoid b) => Int -> JoinList b a -> Maybe a
indexJ _ Empty  = Nothing
indexJ i (Single m d)
    | i == 0    = Just d
    | otherwise = Nothing
indexJ i (Append m jL1 jL2)
    | i < 0     = Nothing
    | i >= getSize (size m) = Nothing     -- optional, more efficient to have it
    | i < s1    = indexJ i jL1
    | otherwise = indexJ (i - s1) jL2
      where
        s1 = getSize . size $ tag jL1

if the index is smaller than s1, we look in the first sublist, otherwise in the second.

share|improve this answer
    
Thank you! Your version working right. I test it on my JoinLists with 1,2,3,4 and 8 data elements =) –  Сергей Кузминский May 11 '13 at 13:28

Typically you would encode the position in a tree-structure by sequences of numbers, not just a single number. For example (assuming indices start at 0):

[] -- empty sequence = root of tree
[0,1] -- first follow the first child, then the second child
[0,0,0] -- go 3 levels down in the leftmost branch

That would make the implementation of an index function much simpler.

share|improve this answer

Your Answer

 
discard

By posting your answer, you agree to the privacy policy and terms of service.

Not the answer you're looking for? Browse other questions tagged or ask your own question.