{-# LANGUAGE TypeFamilies, CPP, ViewPatterns, MagicHash, UnboxedTuples, PatternGuards, FlexibleContexts, FlexibleInstances #-} {-# OPTIONS_GHC -fno-warn-overlapping-patterns #-} {------------------------------------------------------------------------------ -- | -- Module : Data.Set.Unboxed -- Copyright : (c) Edward Kmett 2009 -- (c) Daan Leijen 2002 -- License : BSD3 -- Maintainer : ekmett@gmail.com -- Stability : experimental -- Portability : non-portable (type families, view patterns, unboxed tuples) -- -- An efficient implementation of sets. -- -- Since many function names (but not the type name) clash with -- "Prelude" names, this module is usually imported @qualified@, e.g. -- -- > import Data.Set.Unboxed (USet) -- > import qualified Data.Set.Unboxed as USet -- -- The implementation of 'USet' is based on /size balanced/ binary trees (or -- trees of /bounded balance/) as described by: -- -- * Stephen Adams, \"/Efficient sets: a balancing act/\", -- Journal of Functional Programming 3(4):553-562, October 1993, -- <http://www.swiss.ai.mit.edu/~adams/BB/>. -- -- * J. Nievergelt and E.M. Reingold, -- \"/Binary search trees of bounded balance/\", -- SIAM journal of computing 2(1), March 1973. -- -- Note that the implementation is /left-biased/ -- the elements of a -- first argument are always preferred to the second, for example in -- 'union' or 'insert'. Of course, left-biasing can only be observed -- when equality is an equivalence relation instead of structural -- equality. -- -- Modified from "Data.Set" to use type families for automatic unboxing -- ----------------------------------------------------------------------------- -} module Data.Set.Unboxed ( -- * Set type USet -- instance Eq,Ord,Show,Read,Data,Typeable , US , Boxed(Boxed) -- * Operators , (\\) -- * Query , null , size , member , notMember , isSubsetOf , isProperSubsetOf -- * Construction , empty , singleton , insert , delete -- * Combine , union, unions , difference , intersection -- * Filter , filter , partition , split , splitMember -- * Map , map , mapMonotonic -- * Fold , fold -- * Min\/Max , findMin , findMax , deleteMin , deleteMax , deleteFindMin , deleteFindMax , maxView , minView -- * Conversion -- ** List , elems , toList , fromList -- ** Ordered list , toAscList , fromAscList , fromDistinctAscList -- * Debugging , showTree , showTreeWith , valid ) where import Prelude hiding (filter,foldr,null,map) import qualified Data.List as List import Data.Monoid (Monoid(..)) import Data.Word import Data.Int {- -- just for testing import Test.QuickCheck import Data.List (nub,sort) import qualified Data.List as List -} #if __GLASGOW_HASKELL__ import Text.Read #endif {-------------------------------------------------------------------- Operators --------------------------------------------------------------------} infixl 9 \\ -- -- | /O(n+m)/. See 'difference'. (\\) :: (US a, Ord a) => USet a -> USet a -> USet a m1 \\ m2 = difference m1 m2 {-------------------------------------------------------------------- Sets are size balanced trees --------------------------------------------------------------------} type Size = Int -- | A set of values @a@. data Set a = Tip | Bin {-# UNPACK #-} !Size !a !(USet a) !(USet a) class US a where data USet a -- | Extract and rebox the specialized node format view :: USet a -> Set a -- | Apply the view to tip and bin continuations viewk :: b -> (Size -> a -> USet a -> USet a -> b) -> USet a -> b viewk f k x = case view x of Bin s i l r -> k s i l r Tip -> f -- | View just the value and left and right child of a bin viewBin :: USet a -> (# a, USet a, USet a #) viewBin x = case view x of Bin _ i l r -> (# i, l, r #) Tip -> error "Data.Set.Unboxed.viewBin" -- | /O(1)/. The number of elements in the set. size :: USet a -> Size size = viewk 0 size' where size' s _ _ _ = s -- | /O(1)/. Is this the empty set? null :: USet a -> Bool null x = size x == 0 -- | Smart tip constructor tip :: USet a -- | Smart bin constructor bin :: Size -> a -> USet a -> USet a -> USet a -- | Balance the tree balance :: a -> USet a -> USet a -> USet a balance x l r | sizeL + sizeR <= 1 = bin sizeX x l r | sizeR >= delta*sizeL = case viewBin r of (# v, ly, ry #) | size ly < ratio*size ry -> bin_ v (bin_ x l ly) ry | (# x3, t2, t3 #) <- viewBin ly -> bin_ x3 (bin_ x l t2) (bin_ v t3 ry) | sizeL >= delta*sizeR = case viewBin l of (# v, ly, ry #) | size ry < ratio*size ly -> bin_ v ly (bin_ x ry r) | (# x3, t2, t3 #) <- viewBin ry -> bin_ x3 (bin_ v ly t2) (bin_ x t3 r) | otherwise = bin sizeX x l r where sizeL = size l sizeR = size r sizeX = sizeL + sizeR + 1 instance (US a, Ord a) => Monoid (USet a) where mempty = empty mappend = union mconcat = unions {- instance US a => Generator (USet a) where type Elem (USet a) = a mapReduce _ (null -> True) = mempty mapReduce f (view -> Bin _s k l r) = mapReduce f l `mappend` f k `mappend` mapReduce f r -} {-------------------------------------------------------------------- Query --------------------------------------------------------------------} -- | /O(log n)/. Is the element in the set? member :: (US a, Ord a) => a -> USet a -> Bool member x = go where cmpx = compare x go = viewk False $ \_ y l r -> case cmpx y of LT -> go l GT -> go r EQ -> True -- | /O(log n)/. Is the element not in the set? notMember :: (US a, Ord a) => a -> USet a -> Bool notMember x t = not $ member x t {-------------------------------------------------------------------- Construction --------------------------------------------------------------------} -- | /O(1)/. The empty set. empty :: US a => USet a empty = tip -- | /O(1)/. Create a singleton set. singleton :: US a => a -> USet a singleton x = bin 1 x tip tip {-------------------------------------------------------------------- Deletion --------------------------------------------------------------------} -- | /O(log n)/. Delete an element from a set. delete :: (US a, Ord a) => a -> USet a -> USet a delete x = go where go = viewk tip $ \ _ y l r -> case compare x y of LT -> balance y (go l) r GT -> balance y l (go r) EQ -> glue l r {-------------------------------------------------------------------- Subset --------------------------------------------------------------------} -- | /O(n+m)/. Is this a proper subset? (ie. a subset but not equal). isProperSubsetOf :: (US a, Ord a) => USet a -> USet a -> Bool isProperSubsetOf s1 s2 = (size s1 < size s2) && (isSubsetOf s1 s2) -- | /O(n+m)/. Is this a subset? -- @(s1 `isSubsetOf` s2)@ tells whether @s1@ is a subset of @s2@. isSubsetOf :: (US a, Ord a) => USet a -> USet a -> Bool isSubsetOf t1 t2 = (size t1 <= size t2) && (isSubsetOfX t1 t2) isSubsetOfX :: (US a, Ord a) => USet a -> USet a -> Bool isSubsetOfX _ (null -> True) = False isSubsetOfX (null -> True) _ = True isSubsetOfX (view -> Bin _ x l r) t = found && isSubsetOfX l lt && isSubsetOfX r gt where (lt,found,gt) = splitMember x t {-------------------------------------------------------------------- Minimal, Maximal --------------------------------------------------------------------} -- | /O(log n)/. The minimal element of a set. findMin :: US a => USet a -> a findMin (view -> Bin _ x (null -> True) _) = x findMin (view -> Bin _ _ l _) = findMin l findMin _ = error "Data.Set.Unboxed.findMin: empty set has no minimal element" -- | /O(log n)/. The maximal element of a set. findMax :: US a => USet a -> a findMax (view -> Bin _ x _ (null -> True)) = x findMax (view -> Bin _ _ _ r) = findMax r findMax _ = error "Data.Set.Unboxed.findMax: empty set has no maximal element" -- | /O(log n)/. Delete the minimal element. deleteMin :: US a => USet a -> USet a deleteMin (view -> Bin _ _ (null -> True) r) = r deleteMin (view -> Bin _ x l r) = balance x (deleteMin l) r deleteMin _ = tip -- | /O(log n)/. Delete the maximal element. deleteMax :: US a => USet a -> USet a deleteMax (view -> Bin _ _ l (null -> True)) = l deleteMax (view -> Bin _ x l r) = balance x l (deleteMax r) deleteMax _ = tip {-------------------------------------------------------------------- Union. --------------------------------------------------------------------} -- | The union of a list of sets: (@'unions' == 'foldl' 'union' 'empty'@). unions :: (US a, Ord a) => [USet a] -> USet a unions ts = foldlStrict union empty ts -- | /O(n+m)/. The union of two sets, preferring the first set when -- equal elements are encountered. -- The implementation uses the efficient /hedge-union/ algorithm. -- Hedge-union is more efficient on (bigset `union` smallset). union :: (US a, Ord a) => USet a -> USet a -> USet a union (null -> True) t2 = t2 union t1 (null -> True) = t1 union t1 t2 = hedgeUnion (const LT) (const GT) t1 t2 hedgeUnion :: (US a, Ord a) => (a -> Ordering) -> (a -> Ordering) -> USet a -> USet a -> USet a hedgeUnion _ _ t1 (null -> True) = t1 hedgeUnion cmplo cmphi (null -> True) (view -> Bin _ x l r) = join x (filterGt cmplo l) (filterLt cmphi r) hedgeUnion cmplo cmphi (view -> Bin _ x l r) t2 = join x (hedgeUnion cmplo cmpx l (trim cmplo cmpx t2)) (hedgeUnion cmpx cmphi r (trim cmpx cmphi t2)) where cmpx = compare x {-------------------------------------------------------------------- Difference --------------------------------------------------------------------} -- | /O(n+m)/. Difference of two sets. -- The implementation uses an efficient /hedge/ algorithm comparable with /hedge-union/. difference :: (US a, Ord a) => USet a -> USet a -> USet a difference (null -> True) _ = tip difference t1 (null -> True) = t1 difference t1 t2 = hedgeDiff (const LT) (const GT) t1 t2 hedgeDiff :: (US a, Ord a) => (a -> Ordering) -> (a -> Ordering) -> USet a -> USet a -> USet a hedgeDiff _ _ (null -> True) _ = tip hedgeDiff cmplo cmphi (view -> Bin _ x l r) (null -> True) = join x (filterGt cmplo l) (filterLt cmphi r) hedgeDiff cmplo cmphi t (view -> Bin _ x l r) = merge (hedgeDiff cmplo cmpx (trim cmplo cmpx t) l) (hedgeDiff cmpx cmphi (trim cmpx cmphi t) r) where cmpx = compare x {-------------------------------------------------------------------- Intersection --------------------------------------------------------------------} -- | /O(n+m)/. The intersection of two sets. -- Elements of the result come from the first set, so for example -- -- > import qualified Data.Set as S -- > data AB = A | B deriving Show -- > instance Ord AB where compare _ _ = EQ -- > instance Eq AB where _ == _ = True -- > main = print (S.singleton A `S.intersection` S.singleton B, -- > S.singleton B `S.intersection` S.singleton A) -- -- prints @(fromList [A],fromList [B])@. intersection :: (US a, Ord a) => USet a -> USet a -> USet a intersection (null -> True) _ = tip intersection _ (null -> True) = tip intersection t1@(view -> Bin s1 x1 l1 r1) t2@(view -> Bin s2 x2 l2 r2) = if s1 >= s2 then let (lt,found,gt) = splitLookup x2 t1 tl = intersection lt l2 tr = intersection gt r2 in case found of Just x -> join x tl tr Nothing -> merge tl tr else let (lt,found,gt) = splitMember x1 t2 tl = intersection l1 lt tr = intersection r1 gt in if found then join x1 tl tr else merge tl tr {-------------------------------------------------------------------- Filter and partition --------------------------------------------------------------------} -- | /O(n)/. Filter all elements that satisfy the predicate. filter :: (US a, Ord a) => (a -> Bool) -> USet a -> USet a filter p = go where go = viewk tip (\_ x l r -> if p x then join x (go l) (go r) else merge (go l) (go r) ) -- | /O(n)/. Partition the set into two sets, one with all elements that satisfy -- the predicate and one with all elements that don't satisfy the predicate. -- See also 'split'. partition :: (US a, Ord a) => (a -> Bool) -> USet a -> (USet a,USet a) partition p = go where go = viewk (tip,tip) (\_ x l r -> let (l1,l2) = go l (r1,r2) = go r in if p x then (join x l1 r1,merge l2 r2) else (merge l1 r1,join x l2 r2) ) {---------------------------------------------------------------------- Map ----------------------------------------------------------------------} -- | /O(n*log n)/. -- @'map' f s@ is the set obtained by applying @f@ to each element of @s@. -- -- It's worth noting that the size of the result may be smaller if, -- for some @(x,y)@, @x \/= y && f x == f y@ map :: (US a, US b, Ord a, Ord b) => (a->b) -> USet a -> USet b map f = fromList . List.map f . toList -- | /O(n)/. The -- -- @'mapMonotonic' f s == 'map' f s@, but works only when @f@ is monotonic. -- /The precondition is not checked./ -- Semi-formally, we have: -- -- > and [x < y ==> f x < f y | x <- ls, y <- ls] -- > ==> mapMonotonic f s == map f s -- > where ls = toList s mapMonotonic :: (US a, US b) => (a->b) -> USet a -> USet b mapMonotonic f (view -> Bin sz x l r) = bin sz (f x) (mapMonotonic f l) (mapMonotonic f r) mapMonotonic _ _ = tip {-------------------------------------------------------------------- Fold --------------------------------------------------------------------} -- | /O(n)/. Fold over the elements of a set in an unspecified order. fold :: US a => (a -> b -> b) -> b -> USet a -> b fold f z s = foldr f z s -- | /O(n)/. Post-order fold. foldr :: US a => (a -> b -> b) -> b -> USet a -> b --foldr f z (view -> Bin _ x l r) = foldr f (f x (foldr f z r)) l --foldr _ z _ = z foldr f z x | null x = z | (# x, l, r #) <- viewBin x = foldr f (f x (foldr f z r)) l {-------------------------------------------------------------------- List variations --------------------------------------------------------------------} -- | /O(n)/. The elements of a set. elems :: US a => USet a -> [a] elems x = toList x {-------------------------------------------------------------------- Lists --------------------------------------------------------------------} -- | /O(n)/. Convert the set to a list of elements. toList :: US a => USet a -> [a] toList x = toAscList x -- | /O(n)/. Convert the set to an ascending list of elements. toAscList :: US a => USet a -> [a] toAscList = foldr (:) [] -- | /O(n*log n)/. Create a set from a list of elements. fromList :: (US a, Ord a) => [a] -> USet a fromList = foldlStrict ins empty where ins t x = insert x t {-------------------------------------------------------------------- Building trees from ascending/descending lists can be done in linear time. Note that if [xs] is ascending that: fromAscList xs == fromList xs --------------------------------------------------------------------} -- | /O(n)/. Build a set from an ascending list in linear time. -- /The precondition (input list is ascending) is not checked./ fromAscList :: (US a, Eq a) => [a] -> USet a fromAscList xs = fromDistinctAscList (combineEq xs) where -- [combineEq xs] combines equal elements with [const] in an ordered list [xs] combineEq xs' = case xs' of [] -> [] [x] -> [x] (x:xx) -> combineEq' x xx combineEq' z [] = [z] combineEq' z (x:xs') | z==x = combineEq' z xs' | otherwise = z:combineEq' x xs' -- | /O(n)/. Build a set from an ascending list of distinct elements in linear time. -- /The precondition (input list is strictly ascending) is not checked./ fromDistinctAscList :: US a => [a] -> USet a fromDistinctAscList xs = build const (length xs) xs where -- 1) use continutations so that we use heap space instead of stack space. -- 2) special case for n==5 to build bushier trees. build c 0 xs' = c tip xs' build c 5 xs' = case xs' of (x1:x2:x3:x4:x5:xx) -> c (bin_ x4 (bin_ x2 (singleton x1) (singleton x3)) (singleton x5)) xx _ -> error "Data.Set.Unboxed.fromDistinctAscList build 5" build c n xs' = seq nr $ build (buildR nr c) nl xs' where nl = n `div` 2 nr = n - nl - 1 buildR n c l (x:ys) = build (buildB l x c) n ys buildR _ _ _ [] = error "Data.Set.Unboxed.fromDistinctAscList buildR []" buildB l x c r zs = c (bin_ x l r) zs {-------------------------------------------------------------------- Eq converts the set to a list. In a lazy setting, this actually seems one of the faster methods to compare two trees and it is certainly the simplest :-) --------------------------------------------------------------------} instance (US a, Eq a) => Eq (USet a) where t1 == t2 = (size t1 == size t2) && (toAscList t1 == toAscList t2) {-------------------------------------------------------------------- Ord --------------------------------------------------------------------} instance (US a, Ord a) => Ord (USet a) where compare s1 s2 = compare (toAscList s1) (toAscList s2) {-------------------------------------------------------------------- Show --------------------------------------------------------------------} instance (US a, Show a) => Show (USet a) where showsPrec p xs = showParen (p > 10) $ showString "fromList " . shows (toList xs) {-------------------------------------------------------------------- Read --------------------------------------------------------------------} instance (US a, Read a, Ord a) => Read (USet a) where #ifdef __GLASGOW_HASKELL__ readPrec = parens $ prec 10 $ do Ident "fromList" <- lexP fromList `fmap` readPrec readListPrec = readListPrecDefault #else readsPrec p = readParen (p > 10) $ \ r -> do ("fromList",s) <- lex r (xs,t) <- reads s return (fromList xs,t) #endif {-------------------------------------------------------------------- Utility functions that return sub-ranges of the original tree. Some functions take a comparison function as argument to allow comparisons against infinite values. A function [cmplo x] should be read as [compare lo x]. [trim cmplo cmphi t] A tree that is either empty or where [cmplo x == LT] and [cmphi x == GT] for the value [x] of the root. [filterGt cmp t] A tree where for all values [k]. [cmp k == LT] [filterLt cmp t] A tree where for all values [k]. [cmp k == GT] [split k t] Returns two trees [l] and [r] where all values in [l] are <[k] and all keys in [r] are >[k]. [splitMember k t] Just like [split] but also returns whether [k] was found in the tree. --------------------------------------------------------------------} {-------------------------------------------------------------------- [trim lo hi t] trims away all subtrees that surely contain no values between the range [lo] to [hi]. The returned tree is either empty or the key of the root is between @lo@ and @hi@. --------------------------------------------------------------------} trim :: US a => (a -> Ordering) -> (a -> Ordering) -> USet a -> USet a trim cmplo cmphi t@(view -> Bin _ x l r) = case cmplo x of LT -> case cmphi x of GT -> t _ -> trim cmplo cmphi l _ -> trim cmplo cmphi r trim _ _ _ = tip {-------------------------------------------------------------------- [filterGt x t] filter all values >[x] from tree [t] [filterLt x t] filter all values <[x] from tree [t] --------------------------------------------------------------------} filterGt :: US a => (a -> Ordering) -> USet a -> USet a filterGt cmp (view -> Bin _ x l r) = case cmp x of LT -> join x (filterGt cmp l) r GT -> filterGt cmp r EQ -> r filterGt _ _ = tip filterLt :: US a => (a -> Ordering) -> USet a -> USet a filterLt cmp (view -> Bin _ x l r) = case cmp x of LT -> filterLt cmp l GT -> join x l (filterLt cmp r) EQ -> l filterLt _ _ = tip {-------------------------------------------------------------------- Split --------------------------------------------------------------------} -- | /O(log n)/. The expression (@'split' x set@) is a pair @(set1,set2)@ -- where @set1@ comprises the elements of @set@ less than @x@ and @set2@ -- comprises the elements of @set@ greater than @x@. split :: (US a, Ord a) => a -> USet a -> (USet a,USet a) split x (view -> Bin _ y l r) = case compare x y of LT -> let (lt,gt) = split x l in (lt,join y gt r) GT -> let (lt,gt) = split x r in (join y l lt,gt) EQ -> (l,r) split _ _ = (tip,tip) -- | /O(log n)/. Performs a 'split' but also returns whether the pivot -- element was found in the original set. splitMember :: (US a, Ord a) => a -> USet a -> (USet a,Bool,USet a) splitMember x t = let (l,m,r) = splitLookup x t in (l,maybe False (const True) m,r) -- | /O(log n)/. Performs a 'split' but also returns the pivot -- element that was found in the original set. splitLookup :: (US a, Ord a) => a -> USet a -> (USet a,Maybe a,USet a) splitLookup x (view -> Bin _ y l r) = case compare x y of LT -> let (lt,found,gt) = splitLookup x l in (lt,found,join y gt r) GT -> let (lt,found,gt) = splitLookup x r in (join y l lt,found,gt) EQ -> (l,Just y,r) splitLookup _ _ = (tip,Nothing,tip) {-------------------------------------------------------------------- Utility functions that maintain the balance properties of the tree. All constructors assume that all values in [l] < [x] and all values in [r] > [x], and that [l] and [r] are valid trees. In order of sophistication: [Bin sz x l r] The type constructor. [bin_ x l r] Maintains the correct size, assumes that both [l] and [r] are balanced with respect to each other. [balance x l r] Restores the balance and size. Assumes that the original tree was balanced and that [l] or [r] has changed by at most one element. [join x l r] Restores balance and size. Furthermore, we can construct a new tree from two trees. Both operations assume that all values in [l] < all values in [r] and that [l] and [r] are valid: [glue l r] Glues [l] and [r] together. Assumes that [l] and [r] are already balanced with respect to each other. [merge l r] Merges two trees and restores balance. Note: in contrast to Adam's paper, we use (<=) comparisons instead of (<) comparisons in [join], [merge] and [balance]. Quickcheck (on [difference]) showed that this was necessary in order to maintain the invariants. It is quite unsatisfactory that I haven't been able to find out why this is actually the case! Fortunately, it doesn't hurt to be a bit more conservative. --------------------------------------------------------------------} {-------------------------------------------------------------------- Join --------------------------------------------------------------------} join :: US a => a -> USet a -> USet a -> USet a join x (null -> True) r = insertMin x r join x l (null -> True) = insertMax x l join x l@(view -> Bin sizeL y ly ry) r@(view -> Bin sizeR z lz rz) | delta*sizeL <= sizeR = balance z (join x l lz) rz | delta*sizeR <= sizeL = balance y ly (join x ry r) | otherwise = bin_ x l r -- insertMin and insertMax don't perform potentially expensive comparisons. insertMax,insertMin :: US a => a -> USet a -> USet a insertMax x t = case view t of Bin _ y l r -> balance y l (insertMax x r) _ -> singleton x insertMin x t = case view t of Bin _ y l r -> balance y (insertMin x l) r _ -> singleton x {-------------------------------------------------------------------- [merge l r]: merges two trees. --------------------------------------------------------------------} merge :: US a => USet a -> USet a -> USet a merge (null -> True) r = r merge l (null -> True) = l merge l@(view -> Bin sizeL x lx rx) r@(view -> Bin sizeR y ly ry) | delta*sizeL <= sizeR = balance y (merge l ly) ry | delta*sizeR <= sizeL = balance x lx (merge rx r) | otherwise = glue l r {-------------------------------------------------------------------- [glue l r]: glues two trees together. Assumes that [l] and [r] are already balanced with respect to each other. --------------------------------------------------------------------} glue :: US a => USet a -> USet a -> USet a glue (null -> True) r = r glue l (null -> True) = l glue l r | size l > size r = let (m,l') = deleteFindMax l in balance m l' r | otherwise = let (m,r') = deleteFindMin r in balance m l r' -- | /O(log n)/. Delete and find the minimal element. -- -- > deleteFindMin set = (findMin set, deleteMin set) deleteFindMin :: US a => USet a -> (a,USet a) deleteFindMin t = case view t of Bin _ x (null -> True) r -> (x,r) Bin _ x l r -> let (xm,l') = deleteFindMin l in (xm,balance x l' r) Tip -> (error "Data.Set.Unboxed.deleteFindMin: can not return the minimal element of an empty set", tip) -- | /O(log n)/. Delete and find the maximal element. -- -- > deleteFindMax set = (findMax set, deleteMax set) deleteFindMax :: US a => USet a -> (a,USet a) deleteFindMax t = case view t of Bin _ x l (null -> True) -> (x,l) Bin _ x l r -> let (xm,r') = deleteFindMax r in (xm,balance x l r') _ -> (error "Data.Set.Unboxed.deleteFindMax: can not return the maximal element of an empty set", tip) -- | /O(log n)/. Retrieves the minimal key of the set, and the set -- stripped of that element, or 'Nothing' if passed an empty set. minView :: US a => USet a -> Maybe (a, USet a) minView (null -> True) = Nothing minView x = Just (deleteFindMin x) -- | /O(log n)/. Retrieves the maximal key of the set, and the set -- stripped of that element, or 'Nothing' if passed an empty set. maxView :: US a => USet a -> Maybe (a, USet a) maxView (null -> True) = Nothing maxView x = Just (deleteFindMax x) {-------------------------------------------------------------------- [balance x l r] balances two trees with value x. The sizes of the trees should balance after decreasing the size of one of them. (a rotation). [delta] is the maximal relative difference between the sizes of two trees, it corresponds with the [w] in Adams' paper, or equivalently, [1/delta] corresponds with the $\alpha$ in Nievergelt's paper. Adams shows that [delta] should be larger than 3.745 in order to garantee that the rotations can always restore balance. [ratio] is the ratio between an outer and inner sibling of the heavier subtree in an unbalanced setting. It determines whether a double or single rotation should be performed to restore balance. It is correspondes with the inverse of $\alpha$ in Adam's article. Note that: - [delta] should be larger than 4.646 with a [ratio] of 2. - [delta] should be larger than 3.745 with a [ratio] of 1.534. - A lower [delta] leads to a more 'perfectly' balanced tree. - A higher [delta] performs less rebalancing. - Balancing is automatic for random data and a balancing scheme is only necessary to avoid pathological worst cases. Almost any choice will do in practice - Allthough it seems that a rather large [delta] may perform better than smaller one, measurements have shown that the smallest [delta] of 4 is actually the fastest on a wide range of operations. It especially improves performance on worst-case scenarios like a sequence of ordered insertions. Note: in contrast to Adams' paper, we use a ratio of (at least) 2 to decide whether a single or double rotation is needed. Allthough he actually proves that this ratio is needed to maintain the invariants, his implementation uses a (invalid) ratio of 1. He is aware of the problem though since he has put a comment in his original source code that he doesn't care about generating a slightly inbalanced tree since it doesn't seem to matter in practice. However (since we use quickcheck :-) we will stick to strictly balanced trees. --------------------------------------------------------------------} delta,ratio :: Int delta = 4 ratio = 2 {-------------------------------------------------------------------- Utilities --------------------------------------------------------------------} foldlStrict :: (a -> b -> a) -> a -> [b] -> a foldlStrict f z xs = case xs of [] -> z (x:xx) -> let z' = f z x in seq z' (foldlStrict f z' xx) {-------------------------------------------------------------------- Debugging --------------------------------------------------------------------} -- | /O(n)/. Show the tree that implements the set. The tree is shown -- in a compressed, hanging format. showTree :: (US a, Show a) => USet a -> String showTree s = showTreeWith True False s {- | /O(n)/. The expression (@showTreeWith hang wide map@) shows the tree that implements the set. If @hang@ is @True@, a /hanging/ tree is shown otherwise a rotated tree is shown. If @wide@ is 'True', an extra wide version is shown. > Set> putStrLn $ showTreeWith True False $ fromDistinctAscList [1..5] > 4 > +--2 > | +--1 > | +--3 > +--5 > > Set> putStrLn $ showTreeWith True True $ fromDistinctAscList [1..5] > 4 > | > +--2 > | | > | +--1 > | | > | +--3 > | > +--5 > > Set> putStrLn $ showTreeWith False True $ fromDistinctAscList [1..5] > +--5 > | > 4 > | > | +--3 > | | > +--2 > | > +--1 -} showTreeWith :: (US a, Show a) => Bool -> Bool -> USet a -> String showTreeWith hang wide t | hang = (showsTreeHang wide [] t) "" | otherwise = (showsTree wide [] [] t) "" showsTree :: (US a, Show a) => Bool -> [String] -> [String] -> USet a -> ShowS showsTree wide lbars rbars t = case view t of Tip -> showsBars lbars . showString "|\n" Bin _ x (null -> True) (null -> True) -> showsBars lbars . shows x . showString "\n" Bin _ x l r -> showsTree wide (withBar rbars) (withEmpty rbars) r . showWide wide rbars . showsBars lbars . shows x . showString "\n" . showWide wide lbars . showsTree wide (withEmpty lbars) (withBar lbars) l showsTreeHang :: (US a, Show a) => Bool -> [String] -> USet a -> ShowS showsTreeHang wide bars t = case view t of Tip -> showsBars bars . showString "|\n" Bin _ x (null -> True) (null -> True) -> showsBars bars . shows x . showString "\n" Bin _ x l r -> showsBars bars . shows x . showString "\n" . showWide wide bars . showsTreeHang wide (withBar bars) l . showWide wide bars . showsTreeHang wide (withEmpty bars) r showWide :: Bool -> [String] -> String -> String showWide wide bars | wide = showString (concat (reverse bars)) . showString "|\n" | otherwise = id showsBars :: [String] -> ShowS showsBars bars = case bars of [] -> id _ -> showString (concat (reverse (tail bars))) . showString node node :: String node = "+--" withBar, withEmpty :: [String] -> [String] withBar bars = "| ":bars withEmpty bars = " ":bars {-------------------------------------------------------------------- Assertions --------------------------------------------------------------------} -- | /O(n)/. Test if the internal set structure is valid. valid :: (US a, Ord a) => USet a -> Bool valid t = balanced t && ordered t && validsize t ordered :: (US a, Ord a) => USet a -> Bool ordered t = bounded (const True) (const True) t where bounded lo hi t' = case view t' of Bin _ x l r -> (lo x) && (hi x) && bounded lo (<x) l && bounded (>x) hi r _ -> True balanced :: US a => USet a -> Bool balanced t = case view t of Bin _ _ l r -> (size l + size r <= 1 || (size l <= delta*size r && size r <= delta*size l)) && balanced l && balanced r _ -> True validsize :: US a => USet a -> Bool validsize t = (realsize t == Just (size t)) where realsize t' = case view t' of Bin sz _ l r -> case (realsize l,realsize r) of (Just n,Just m) | n+m+1 == sz -> Just sz _ -> Nothing _ -> Just 0 {- {-------------------------------------------------------------------- Testing --------------------------------------------------------------------} testTree :: [Int] -> USet Int testTree xs = fromList xs test1 = testTree [1..20] test2 = testTree [30,29..10] test3 = testTree [1,4,6,89,2323,53,43,234,5,79,12,9,24,9,8,423,8,42,4,8,9,3] {-------------------------------------------------------------------- QuickCheck --------------------------------------------------------------------} {- qcheck prop = check config prop where config = Config { configMaxTest = 500 , configMaxFail = 5000 , configSize = \n -> (div n 2 + 3) , configEvery = \n args -> let s = show n in s ++ [ '\b' | _ <- s ] } -} {-------------------------------------------------------------------- Arbitrary, reasonably balanced trees --------------------------------------------------------------------} instance (US a, Enum a) => Arbitrary (USet a) where arbitrary = sized (arbtree 0 maxkey) where maxkey = 10000 arbtree :: (US a, Enum a) => Int -> Int -> Int -> Gen (USet a) arbtree lo hi n | n <= 0 = return tip | lo >= hi = return tip | otherwise = do{ i <- choose (lo,hi) ; m <- choose (1,30) ; let (ml,mr) | m==(1::Int)= (1,2) | m==2 = (2,1) | m==3 = (1,1) | otherwise = (2,2) ; l <- arbtree lo (i-1) (n `div` ml) ; r <- arbtree (i+1) hi (n `div` mr) ; return (bin_ (toEnum i) l r) } {-------------------------------------------------------------------- Valid tree's --------------------------------------------------------------------} forValid :: (US a, Enum a,Show a,Testable b) => (USet a -> b) -> Property forValid f = forAll arbitrary $ \t -> -- classify (balanced t) "balanced" $ classify (size t == 0) "empty" $ classify (size t > 0 && size t <= 10) "small" $ classify (size t > 10 && size t <= 64) "medium" $ classify (size t > 64) "large" $ balanced t ==> f t forValidIntTree :: Testable a => (USet Int -> a) -> Property forValidIntTree f = forValid f forValidUnitTree :: Testable a => (USet Int -> a) -> Property forValidUnitTree f = forValid f prop_Valid = forValidUnitTree $ \t -> valid t {-------------------------------------------------------------------- Single, Insert, Delete --------------------------------------------------------------------} prop_Single :: Int -> Bool prop_Single x = (insert x empty == singleton x) prop_InsertValid :: Int -> Property prop_InsertValid k = forValidUnitTree $ \t -> valid (insert k t) prop_InsertDelete :: Int -> USet Int -> Property prop_InsertDelete k t = not (member k t) ==> delete k (insert k t) == t prop_DeleteValid :: Int -> Property prop_DeleteValid k = forValidUnitTree $ \t -> valid (delete k (insert k t)) {-------------------------------------------------------------------- Balance --------------------------------------------------------------------} prop_Join :: Int -> Property prop_Join x = forValidUnitTree $ \t -> let (l,r) = split x t in valid (join x l r) prop_Merge :: Int -> Property prop_Merge x = forValidUnitTree $ \t -> let (l,r) = split x t in valid (merge l r) {-------------------------------------------------------------------- Union --------------------------------------------------------------------} prop_UnionValid :: Property prop_UnionValid = forValidUnitTree $ \t1 -> forValidUnitTree $ \t2 -> valid (union t1 t2) prop_UnionInsert :: Int -> USet Int -> Bool prop_UnionInsert x t = union t (singleton x) == insert x t prop_UnionAssoc :: USet Int -> USet Int -> USet Int -> Bool prop_UnionAssoc t1 t2 t3 = union t1 (union t2 t3) == union (union t1 t2) t3 prop_UnionComm :: USet Int -> USet Int -> Bool prop_UnionComm t1 t2 = (union t1 t2 == union t2 t1) prop_DiffValid = forValidUnitTree $ \t1 -> forValidUnitTree $ \t2 -> valid (difference t1 t2) prop_Diff :: [Int] -> [Int] -> Bool prop_Diff xs ys = toAscList (difference (fromList xs) (fromList ys)) == List.sort ((List.\\) (nub xs) (nub ys)) prop_IntValid = forValidUnitTree $ \t1 -> forValidUnitTree $ \t2 -> valid (intersection t1 t2) prop_Int :: [Int] -> [Int] -> Bool prop_Int xs ys = toAscList (intersection (fromList xs) (fromList ys)) == List.sort (nub ((List.intersect) (xs) (ys))) {-------------------------------------------------------------------- Lists --------------------------------------------------------------------} prop_Ordered = forAll (choose (5,100)) $ \n -> let xs = [0..n::Int] in fromAscList xs == fromList xs prop_List :: [Int] -> Bool prop_List xs = (sort (nub xs) == toList (fromList xs)) -} -- | /O(log n)/. Insert an element in a set. -- If the set already contains an element equal to the given value, -- it is replaced with the new value. insert :: (US a, Ord a) => a -> USet a -> USet a insert x = go where cmpx = compare x go = viewk (singleton x) $ \sz y l r -> case cmpx y of LT -> balance y (go l) r GT -> balance y l (go r) EQ -> bin sz x l r {- {-# SPECIALIZE INLINE insert :: Int -> USet Int -> USet Int #-} {-# SPECIALIZE INLINE insert :: Integer -> USet Integer -> USet Integer #-} {-# SPECIALIZE INLINE insert :: Char -> USet Char -> USet Char #-} {-# SPECIALIZE INLINE insert :: Int8 -> USet Int8 -> USet Int8 #-} {-# SPECIALIZE INLINE insert :: Int16 -> USet Int16 -> USet Int16 #-} {-# SPECIALIZE INLINE insert :: Int32 -> USet Int32 -> USet Int32 #-} {-# SPECIALIZE INLINE insert :: Int64 -> USet Int64 -> USet Int64 #-} {-# SPECIALIZE INLINE insert :: Word8 -> USet Word8 -> USet Word8 #-} {-# SPECIALIZE INLINE insert :: Word16 -> USet Word16 -> USet Word16 #-} {-# SPECIALIZE INLINE insert :: Word32 -> USet Word32 -> USet Word32 #-} {-# SPECIALIZE INLINE insert :: Word64 -> USet Word64 -> USet Word64 #-} {-# SPECIALIZE INLINE insert :: Double -> USet Double -> USet Double #-} {-# SPECIALIZE INLINE insert :: Float -> USet Float -> USet Float #-} {-# SPECIALIZE INLINE insert :: (Int,Int)-> USet (Int,Int) -> USet (Int,Int) #-} -} bin_ :: US a => a -> USet a -> USet a -> USet a bin_ x l r = bin (size l + size r + 1) x l r {- {-# SPECIALIZE INLINE bin_ :: Int -> USet Int -> USet Int -> USet Int #-} {-# SPECIALIZE INLINE bin_ :: Integer -> USet Integer -> USet Integer -> USet Integer #-} {-# SPECIALIZE INLINE bin_ :: Char -> USet Char -> USet Char -> USet Char #-} {-# SPECIALIZE INLINE bin_ :: Int8 -> USet Int8 -> USet Int8 -> USet Int8 #-} {-# SPECIALIZE INLINE bin_ :: Int16 -> USet Int16 -> USet Int16 -> USet Int16 #-} {-# SPECIALIZE INLINE bin_ :: Int32 -> USet Int32 -> USet Int32 -> USet Int32 #-} {-# SPECIALIZE INLINE bin_ :: Int64 -> USet Int64 -> USet Int64 -> USet Int64 #-} {-# SPECIALIZE INLINE bin_ :: Word8 -> USet Word8 -> USet Word8 -> USet Word8 #-} {-# SPECIALIZE INLINE bin_ :: Word16 -> USet Word16 -> USet Word16 -> USet Word16 #-} {-# SPECIALIZE INLINE bin_ :: Word32 -> USet Word32 -> USet Word32 -> USet Word32 #-} {-# SPECIALIZE INLINE bin_ :: Word64 -> USet Word64 -> USet Word64 -> USet Word64 #-} {-# SPECIALIZE INLINE bin_ :: Double -> USet Double -> USet Double -> USet Double #-} {-# SPECIALIZE INLINE bin_ :: Float -> USet Float -> USet Float -> USet Float #-} {-# SPECIALIZE INLINE bin_ :: (Int,Int)-> USet (Int,Int) -> USet (Int,Int) -> USet (Int,Int) #-} -} newtype Boxed a = Boxed a deriving (Eq,Ord,Show,Read,Bounded) {-- everything below this point AUTOMATICALLY GENERATED by instances.pl. Don't edit by hand! --} instance US Int where data USet Int = IntTip | IntBin {-# UNPACK #-} !Size {-# UNPACK #-} !Int !(USet Int) !(USet Int) view IntTip = Tip view (IntBin s i l r) = Bin s i l r tip = IntTip bin = IntBin instance US Char where data USet Char = CharTip | CharBin {-# UNPACK #-} !Size {-# UNPACK #-} !Char !(USet Char) !(USet Char) view CharTip = Tip view (CharBin s i l r) = Bin s i l r tip = CharTip bin = CharBin instance US Int8 where data USet Int8 = Int8Tip | Int8Bin {-# UNPACK #-} !Size {-# UNPACK #-} !Int8 !(USet Int8) !(USet Int8) view Int8Tip = Tip view (Int8Bin s i l r) = Bin s i l r tip = Int8Tip bin = Int8Bin instance US Int16 where data USet Int16 = Int16Tip | Int16Bin {-# UNPACK #-} !Size {-# UNPACK #-} !Int16 !(USet Int16) !(USet Int16) view Int16Tip = Tip view (Int16Bin s i l r) = Bin s i l r tip = Int16Tip bin = Int16Bin instance US Int32 where data USet Int32 = Int32Tip | Int32Bin {-# UNPACK #-} !Size {-# UNPACK #-} !Int32 !(USet Int32) !(USet Int32) view Int32Tip = Tip view (Int32Bin s i l r) = Bin s i l r tip = Int32Tip bin = Int32Bin instance US Int64 where data USet Int64 = Int64Tip | Int64Bin {-# UNPACK #-} !Size {-# UNPACK #-} !Int64 !(USet Int64) !(USet Int64) view Int64Tip = Tip view (Int64Bin s i l r) = Bin s i l r tip = Int64Tip bin = Int64Bin instance US Word8 where data USet Word8 = Word8Tip | Word8Bin {-# UNPACK #-} !Size {-# UNPACK #-} !Word8 !(USet Word8) !(USet Word8) view Word8Tip = Tip view (Word8Bin s i l r) = Bin s i l r tip = Word8Tip bin = Word8Bin instance US Word16 where data USet Word16 = Word16Tip | Word16Bin {-# UNPACK #-} !Size {-# UNPACK #-} !Word16 !(USet Word16) !(USet Word16) view Word16Tip = Tip view (Word16Bin s i l r) = Bin s i l r tip = Word16Tip bin = Word16Bin instance US Word32 where data USet Word32 = Word32Tip | Word32Bin {-# UNPACK #-} !Size {-# UNPACK #-} !Word32 !(USet Word32) !(USet Word32) view Word32Tip = Tip view (Word32Bin s i l r) = Bin s i l r tip = Word32Tip bin = Word32Bin instance US Word64 where data USet Word64 = Word64Tip | Word64Bin {-# UNPACK #-} !Size {-# UNPACK #-} !Word64 !(USet Word64) !(USet Word64) view Word64Tip = Tip view (Word64Bin s i l r) = Bin s i l r tip = Word64Tip bin = Word64Bin instance US Double where data USet Double = DoubleTip | DoubleBin {-# UNPACK #-} !Size {-# UNPACK #-} !Double !(USet Double) !(USet Double) view DoubleTip = Tip view (DoubleBin s i l r) = Bin s i l r tip = DoubleTip bin = DoubleBin instance US Float where data USet Float = FloatTip | FloatBin {-# UNPACK #-} !Size {-# UNPACK #-} !Float !(USet Float) !(USet Float) view FloatTip = Tip view (FloatBin s i l r) = Bin s i l r tip = FloatTip bin = FloatBin instance US Integer where data USet Integer = IntegerTip | IntegerBin {-# UNPACK #-} !Size {-# UNPACK #-} !Integer !(USet Integer) !(USet Integer) view IntegerTip = Tip view (IntegerBin s i l r) = Bin s i l r tip = IntegerTip bin = IntegerBin instance US (Boxed a) where data USet (Boxed a) = BoxedTip | BoxedBin {-# UNPACK #-} !Size (Boxed a) !(USet (Boxed a)) !(USet (Boxed a)) view BoxedTip = Tip view (BoxedBin s i l r) = Bin s i l r tip = BoxedTip bin = BoxedBin