ref: 9faf1dec1c5cef20366e2e5babc94e4376a8bb18
dir: /lib/Data/Map.hs/
--
-- Balanced binary trees
-- Similar to Data.Map
-- Based on https://ufal.mff.cuni.cz/~straka/papers/2011-bbtree.pdf
--
module Data.Map(
Map,
insert, insertWith, fromListWith, fromList, lookup, delete,
insertBy, insertByWith, fromListByWith, fromListBy, lookupBy, empty, elems, size, toList, deleteBy,
) where
import Prelude hiding (lookup)
data Map k a
= Nil -- empty tree
| One k a -- singleton
| Node -- tree node
(Map k a) -- left subtree
Int -- size of this tree
k -- key stored in the node
a -- element stored in the node
(Map k a) -- right subtree
--Xderiving(Show)
empty :: forall k a . Map k a
empty = Nil
elems :: forall k v . Map k v -> [v]
elems = map snd . toList
toList :: forall k v . Map k v -> [(k, v)]
toList t = to t []
where
to Nil q = q
to (One k v) q = (k, v):q
to (Node l _ k v r) q = to l ((k, v) : to r q)
fromListBy :: forall k v . (k -> k -> Ordering) -> [(k, v)] -> Map k v
fromListBy cmp = fromListByWith cmp const
fromListByWith :: forall k v . (k -> k -> Ordering) -> (v -> v -> v) -> [(k, v)] -> Map k v
fromListByWith cmp comb = foldr (uncurry (insertByWith cmp comb)) empty
size :: forall k a . Map k a -> Int
size Nil = 0
size (One _ _) = 1
size (Node _ s _ _ _) = s
node :: forall k a . Map k a -> k -> a -> Map k a -> Map k a
node Nil key val Nil = One key val
node left key val right = Node left (size left + 1 + size right) key val right
lookupBy :: forall k a . (k -> k -> Ordering) -> k -> Map k a -> Maybe a
lookupBy cmp k = look
where
look Nil = Nothing
look (One key val) | isEQ (cmp k key) = Just val
| otherwise = Nothing
look (Node left _ key val right) =
case k `cmp` key of
LT -> look left
EQ -> Just val
GT -> look right
insertBy :: forall k a . (k -> k -> Ordering) -> k -> a -> Map k a -> Map k a
insertBy cmp = insertByWith cmp const
insertByWith :: forall k a . (k -> k -> Ordering) -> (a -> a -> a) -> k -> a -> Map k a -> Map k a
insertByWith cmp comb k v = ins
where
ins Nil = One k v
ins (One a v) = ins (Node Nil 1 a v Nil)
ins (Node left _ key val right) =
case k `cmp` key of
LT -> balance (ins left) key val right
EQ -> node left k (comb v val) right
GT -> balance left key val (ins right)
deleteBy :: forall k a . (k -> k -> Ordering) -> k -> Map k a -> Map k a
deleteBy cmp k = del
where
del Nil = Nil
del t@(One a _) | isEQ (k `cmp` a) = Nil
| otherwise = t
del (Node left _ key val right) =
case k `cmp` key of
LT -> balance (del left) key val right
EQ -> glue left right
GT -> balance left key val (del right)
where
glue Nil right = right
glue left Nil = left
glue left right
| size left > size right =
let (key', val', left') = extractMax left
in node left' key' val' right
| otherwise =
let (key', val', right') = extractMin right
in node left key' val' right'
extractMin :: forall k a . Map k a -> (k, a, Map k a)
extractMin Nil = undefined
extractMin (One key val) = (key, val, Nil)
extractMin (Node Nil _ key val right) = (key, val, right)
extractMin (Node left _ key val right) =
case extractMin left of
(min, vmin, left') -> (min, vmin, balance left' key val right)
extractMax :: forall k a . Map k a -> (k, a, Map k a)
extractMax Nil = undefined
extractMax (One key val) = (key, val, Nil)
extractMax (Node left _ key val Nil) = (key, val, left)
extractMax (Node left _ key val right) =
case extractMax right of
(max, vmax, right') -> (max, vmax, balance left key val right')
omega :: Int
omega = 3
alpha :: Int
alpha = 2
delta :: Int
delta = 0
balance :: forall k a . Map k a -> k -> a -> Map k a -> Map k a
balance left key val right
| size left + size right <= 1 = node left key val right
balance (One k v) key val right = balance (Node Nil 1 k v Nil) key val right
balance left key val (One k v) = balance left key val (Node Nil 1 k v Nil)
balance left key val right
| size right > omega * size left + delta =
case right of
(Node rl _ _ _ rr) | size rl < alpha*size rr -> singleL left key val right
| otherwise -> doubleL left key val right
_ -> undefined
| size left > omega * size right + delta =
case left of
(Node ll _ _ _ lr) | size lr < alpha*size ll -> singleR left key val right
| otherwise -> doubleR left key val right
_ -> undefined
| otherwise = node left key val right
singleL :: forall k a . Map k a -> k -> a -> Map k a -> Map k a
singleL l k v (Node rl _ rk rv rr) = node (node l k v rl) rk rv rr
singleL _ _ _ _ = undefined
singleR :: forall k a . Map k a -> k -> a -> Map k a -> Map k a
singleR (Node ll _ lk lv lr) k v r = node ll lk lv (node lr k v r)
singleR _ _ _ _ = undefined
doubleL :: forall k a . Map k a -> k -> a -> Map k a -> Map k a
doubleL l k v (Node (Node rll _ rlk rlv rlr) _ rk rv rr) = node (node l k v rll) rlk rlv (node rlr rk rv rr)
doubleL l k v (Node (One rlk rlv ) _ rk rv rr) = node (node l k v Nil) rlk rlv (node Nil rk rv rr)
doubleL _ _ _ _ = undefined
doubleR :: forall k a . Map k a -> k -> a -> Map k a -> Map k a
doubleR (Node ll _ lk lv (Node lrl _ lrk lrv lrr)) k v r = node (node ll lk lv lrl) lrk lrv (node lrr k v r)
doubleR (Node ll _ lk lv (One lrk lrv )) k v r = node (node ll lk lv Nil) lrk lrv (node Nil k v r)
doubleR _ _ _ _ = undefined
isEQ :: Ordering -> Bool
isEQ EQ = True
isEQ _ = False
insert :: (Ord k) => k -> a -> Map k a -> Map k a
insert = insertBy compare
insertWith :: (Ord k) => (a -> a -> a) -> k -> a -> Map k a -> Map k a
insertWith = insertByWith compare
fromListWith :: (Ord k) => (v -> v -> v) -> [(k, v)] -> Map k v
fromListWith = fromListByWith compare
fromList :: (Ord k) => [(k, v)] -> Map k v
fromList = fromListBy compare
lookup :: (Ord k) => k -> Map k a -> Maybe a
lookup = lookupBy compare
delete :: (Ord k) => k -> Map k a -> Map k a
delete = deleteBy compare