{-# LANGUAGE CPP #-}
{-# LANGUAGE BangPatterns #-}
{-# LANGUAGE PatternGuards #-}
#if __GLASGOW_HASKELL__
{-# LANGUAGE DeriveDataTypeable, StandaloneDeriving #-}
#endif
#if !defined(TESTING) && defined(__GLASGOW_HASKELL__)
{-# LANGUAGE Trustworthy #-}
#endif
#if __GLASGOW_HASKELL__ >= 708
{-# LANGUAGE RoleAnnotations #-}
{-# LANGUAGE TypeFamilies #-}
#endif
{-# OPTIONS_HADDOCK not-home #-}
#include "containers.h"
-----------------------------------------------------------------------------
-- |
-- Module : Data.Set.Internal
-- Copyright : (c) Daan Leijen 2002
-- License : BSD-style
-- Maintainer : libraries@haskell.org
-- Portability : portable
--
-- = WARNING
--
-- This module is considered __internal__.
--
-- The Package Versioning Policy __does not apply__.
--
-- The contents of this module may change __in any way whatsoever__
-- and __without any warning__ between minor versions of this package.
--
-- Authors importing this module are expected to track development
-- closely.
--
-- = Description
--
-- An efficient implementation of sets.
--
-- These modules are intended to be imported qualified, to avoid name
-- clashes with Prelude functions, e.g.
--
-- > import Data.Set (Set)
-- > import qualified Data.Set as Set
--
-- The implementation of 'Set' 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,
-- .
-- * J. Nievergelt and E.M. Reingold,
-- \"/Binary search trees of bounded balance/\",
-- SIAM journal of computing 2(1), March 1973.
--
-- Bounds for 'union', 'intersection', and 'difference' are as given
-- by
--
-- * Guy Blelloch, Daniel Ferizovic, and Yihan Sun,
-- \"/Just Join for Parallel Ordered Sets/\",
-- .
--
-- 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.
--
-- /Warning/: The size of the set must not exceed @maxBound::Int@. Violation of
-- this condition is not detected and if the size limit is exceeded, the
-- behavior of the set is completely undefined.
--
-- @since 0.5.9
-----------------------------------------------------------------------------
-- [Note: Using INLINABLE]
-- ~~~~~~~~~~~~~~~~~~~~~~~
-- It is crucial to the performance that the functions specialize on the Ord
-- type when possible. GHC 7.0 and higher does this by itself when it sees th
-- unfolding of a function -- that is why all public functions are marked
-- INLINABLE (that exposes the unfolding).
-- [Note: Using INLINE]
-- ~~~~~~~~~~~~~~~~~~~~
-- For other compilers and GHC pre 7.0, we mark some of the functions INLINE.
-- We mark the functions that just navigate down the tree (lookup, insert,
-- delete and similar). That navigation code gets inlined and thus specialized
-- when possible. There is a price to pay -- code growth. The code INLINED is
-- therefore only the tree navigation, all the real work (rebalancing) is not
-- INLINED by using a NOINLINE.
--
-- All methods marked INLINE have to be nonrecursive -- a 'go' function doing
-- the real work is provided.
-- [Note: Type of local 'go' function]
-- ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
-- If the local 'go' function uses an Ord class, it sometimes heap-allocates
-- the Ord dictionary when the 'go' function does not have explicit type.
-- In that case we give 'go' explicit type. But this slightly decrease
-- performance, as the resulting 'go' function can float out to top level.
-- [Note: Local 'go' functions and capturing]
-- ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
-- As opposed to IntSet, when 'go' function captures an argument, increased
-- heap-allocation can occur: sometimes in a polymorphic function, the 'go'
-- floats out of its enclosing function and then it heap-allocates the
-- dictionary and the argument. Maybe it floats out too late and strictness
-- analyzer cannot see that these could be passed on stack.
-- [Note: Order of constructors]
-- ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
-- The order of constructors of Set matters when considering performance.
-- Currently in GHC 7.0, when type has 2 constructors, a forward conditional
-- jump is made when successfully matching second constructor. Successful match
-- of first constructor results in the forward jump not taken.
-- On GHC 7.0, reordering constructors from Tip | Bin to Bin | Tip
-- improves the benchmark by up to 10% on x86.
module Data.Set.Internal (
-- * Set type
Set(..) -- instance Eq,Ord,Show,Read,Data,Typeable
, Size
-- * Operators
, (\\)
-- * Query
, null
, size
, member
, notMember
, lookupLT
, lookupGT
, lookupLE
, lookupGE
, isSubsetOf
, isProperSubsetOf
, disjoint
-- * Construction
, empty
, singleton
, insert
, delete
, alterF
, powerSet
-- * Combine
, union
, unions
, difference
, intersection
, cartesianProduct
, disjointUnion
-- * Filter
, filter
, takeWhileAntitone
, dropWhileAntitone
, spanAntitone
, partition
, split
, splitMember
, splitRoot
-- * Indexed
, lookupIndex
, findIndex
, elemAt
, deleteAt
, take
, drop
, splitAt
-- * Map
, map
, mapMonotonic
-- * Folds
, foldr
, foldl
-- ** Strict folds
, foldr'
, foldl'
-- ** Legacy folds
, fold
-- * Min\/Max
, lookupMin
, lookupMax
, findMin
, findMax
, deleteMin
, deleteMax
, deleteFindMin
, deleteFindMax
, maxView
, minView
-- * Conversion
-- ** List
, elems
, toList
, fromList
-- ** Ordered list
, toAscList
, toDescList
, fromAscList
, fromDistinctAscList
, fromDescList
, fromDistinctDescList
-- * Debugging
, showTree
, showTreeWith
, valid
-- Internals (for testing)
, bin
, balanced
, link
, merge
) where
import Prelude hiding (filter,foldl,foldr,null,map,take,drop,splitAt)
import Control.Applicative (Const(..))
import qualified Data.List as List
import Data.Bits (shiftL, shiftR)
#if !MIN_VERSION_base(4,8,0)
import Data.Monoid (Monoid(..))
#endif
#if MIN_VERSION_base(4,9,0)
import Data.Semigroup (Semigroup(stimes))
#endif
#if !(MIN_VERSION_base(4,11,0)) && MIN_VERSION_base(4,9,0)
import Data.Semigroup (Semigroup((<>)))
#endif
#if MIN_VERSION_base(4,9,0)
import Data.Semigroup (stimesIdempotentMonoid)
import Data.Functor.Classes
#endif
#if MIN_VERSION_base(4,8,0)
import Data.Functor.Identity (Identity)
#endif
import qualified Data.Foldable as Foldable
#if !MIN_VERSION_base(4,8,0)
import Data.Foldable (Foldable (foldMap))
#endif
import Data.Typeable
import Control.DeepSeq (NFData(rnf))
import Utils.Containers.Internal.StrictPair
import Utils.Containers.Internal.PtrEquality
#if __GLASGOW_HASKELL__
import GHC.Exts ( build, lazy )
#if __GLASGOW_HASKELL__ >= 708
import qualified GHC.Exts as GHCExts
#endif
import Text.Read ( readPrec, Read (..), Lexeme (..), parens, prec
, lexP, readListPrecDefault )
import Data.Data
#endif
{--------------------------------------------------------------------
Operators
--------------------------------------------------------------------}
infixl 9 \\ --
-- | /O(m*log(n\/m+1)), m <= n/. See 'difference'.
(\\) :: Ord a => Set a -> Set a -> Set a
m1 \\ m2 = difference m1 m2
#if __GLASGOW_HASKELL__
{-# INLINABLE (\\) #-}
#endif
{--------------------------------------------------------------------
Sets are size balanced trees
--------------------------------------------------------------------}
-- | A set of values @a@.
-- See Note: Order of constructors
data Set a = Bin {-# UNPACK #-} !Size !a !(Set a) !(Set a)
| Tip
type Size = Int
#if __GLASGOW_HASKELL__ >= 708
type role Set nominal
#endif
instance Ord a => Monoid (Set a) where
mempty = empty
mconcat = unions
#if !(MIN_VERSION_base(4,9,0))
mappend = union
#else
mappend = (<>)
-- | @since 0.5.7
instance Ord a => Semigroup (Set a) where
(<>) = union
stimes = stimesIdempotentMonoid
#endif
-- | Folds in order of increasing key.
instance Foldable.Foldable Set where
fold = go
where go Tip = mempty
go (Bin 1 k _ _) = k
go (Bin _ k l r) = go l `mappend` (k `mappend` go r)
{-# INLINABLE fold #-}
foldr = foldr
{-# INLINE foldr #-}
foldl = foldl
{-# INLINE foldl #-}
foldMap f t = go t
where go Tip = mempty
go (Bin 1 k _ _) = f k
go (Bin _ k l r) = go l `mappend` (f k `mappend` go r)
{-# INLINE foldMap #-}
foldl' = foldl'
{-# INLINE foldl' #-}
foldr' = foldr'
{-# INLINE foldr' #-}
#if MIN_VERSION_base(4,8,0)
length = size
{-# INLINE length #-}
null = null
{-# INLINE null #-}
toList = toList
{-# INLINE toList #-}
elem = go
where go !_ Tip = False
go x (Bin _ y l r) = x == y || go x l || go x r
{-# INLINABLE elem #-}
minimum = findMin
{-# INLINE minimum #-}
maximum = findMax
{-# INLINE maximum #-}
sum = foldl' (+) 0
{-# INLINABLE sum #-}
product = foldl' (*) 1
{-# INLINABLE product #-}
#endif
#if __GLASGOW_HASKELL__
{--------------------------------------------------------------------
A Data instance
--------------------------------------------------------------------}
-- This instance preserves data abstraction at the cost of inefficiency.
-- We provide limited reflection services for the sake of data abstraction.
instance (Data a, Ord a) => Data (Set a) where
gfoldl f z set = z fromList `f` (toList set)
toConstr _ = fromListConstr
gunfold k z c = case constrIndex c of
1 -> k (z fromList)
_ -> error "gunfold"
dataTypeOf _ = setDataType
dataCast1 f = gcast1 f
fromListConstr :: Constr
fromListConstr = mkConstr setDataType "fromList" [] Prefix
setDataType :: DataType
setDataType = mkDataType "Data.Set.Internal.Set" [fromListConstr]
#endif
{--------------------------------------------------------------------
Query
--------------------------------------------------------------------}
-- | /O(1)/. Is this the empty set?
null :: Set a -> Bool
null Tip = True
null (Bin {}) = False
{-# INLINE null #-}
-- | /O(1)/. The number of elements in the set.
size :: Set a -> Int
size Tip = 0
size (Bin sz _ _ _) = sz
{-# INLINE size #-}
-- | /O(log n)/. Is the element in the set?
member :: Ord a => a -> Set a -> Bool
member = go
where
go !_ Tip = False
go x (Bin _ y l r) = case compare x y of
LT -> go x l
GT -> go x r
EQ -> True
#if __GLASGOW_HASKELL__
{-# INLINABLE member #-}
#else
{-# INLINE member #-}
#endif
-- | /O(log n)/. Is the element not in the set?
notMember :: Ord a => a -> Set a -> Bool
notMember a t = not $ member a t
#if __GLASGOW_HASKELL__
{-# INLINABLE notMember #-}
#else
{-# INLINE notMember #-}
#endif
-- | /O(log n)/. Find largest element smaller than the given one.
--
-- > lookupLT 3 (fromList [3, 5]) == Nothing
-- > lookupLT 5 (fromList [3, 5]) == Just 3
lookupLT :: Ord a => a -> Set a -> Maybe a
lookupLT = goNothing
where
goNothing !_ Tip = Nothing
goNothing x (Bin _ y l r) | x <= y = goNothing x l
| otherwise = goJust x y r
goJust !_ best Tip = Just best
goJust x best (Bin _ y l r) | x <= y = goJust x best l
| otherwise = goJust x y r
#if __GLASGOW_HASKELL__
{-# INLINABLE lookupLT #-}
#else
{-# INLINE lookupLT #-}
#endif
-- | /O(log n)/. Find smallest element greater than the given one.
--
-- > lookupGT 4 (fromList [3, 5]) == Just 5
-- > lookupGT 5 (fromList [3, 5]) == Nothing
lookupGT :: Ord a => a -> Set a -> Maybe a
lookupGT = goNothing
where
goNothing !_ Tip = Nothing
goNothing x (Bin _ y l r) | x < y = goJust x y l
| otherwise = goNothing x r
goJust !_ best Tip = Just best
goJust x best (Bin _ y l r) | x < y = goJust x y l
| otherwise = goJust x best r
#if __GLASGOW_HASKELL__
{-# INLINABLE lookupGT #-}
#else
{-# INLINE lookupGT #-}
#endif
-- | /O(log n)/. Find largest element smaller or equal to the given one.
--
-- > lookupLE 2 (fromList [3, 5]) == Nothing
-- > lookupLE 4 (fromList [3, 5]) == Just 3
-- > lookupLE 5 (fromList [3, 5]) == Just 5
lookupLE :: Ord a => a -> Set a -> Maybe a
lookupLE = goNothing
where
goNothing !_ Tip = Nothing
goNothing x (Bin _ y l r) = case compare x y of LT -> goNothing x l
EQ -> Just y
GT -> goJust x y r
goJust !_ best Tip = Just best
goJust x best (Bin _ y l r) = case compare x y of LT -> goJust x best l
EQ -> Just y
GT -> goJust x y r
#if __GLASGOW_HASKELL__
{-# INLINABLE lookupLE #-}
#else
{-# INLINE lookupLE #-}
#endif
-- | /O(log n)/. Find smallest element greater or equal to the given one.
--
-- > lookupGE 3 (fromList [3, 5]) == Just 3
-- > lookupGE 4 (fromList [3, 5]) == Just 5
-- > lookupGE 6 (fromList [3, 5]) == Nothing
lookupGE :: Ord a => a -> Set a -> Maybe a
lookupGE = goNothing
where
goNothing !_ Tip = Nothing
goNothing x (Bin _ y l r) = case compare x y of LT -> goJust x y l
EQ -> Just y
GT -> goNothing x r
goJust !_ best Tip = Just best
goJust x best (Bin _ y l r) = case compare x y of LT -> goJust x y l
EQ -> Just y
GT -> goJust x best r
#if __GLASGOW_HASKELL__
{-# INLINABLE lookupGE #-}
#else
{-# INLINE lookupGE #-}
#endif
{--------------------------------------------------------------------
Construction
--------------------------------------------------------------------}
-- | /O(1)/. The empty set.
empty :: Set a
empty = Tip
{-# INLINE empty #-}
-- | /O(1)/. Create a singleton set.
singleton :: a -> Set a
singleton x = Bin 1 x Tip Tip
{-# INLINE singleton #-}
{--------------------------------------------------------------------
Insertion, Deletion
--------------------------------------------------------------------}
-- | /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.
-- See Note: Type of local 'go' function
-- See Note: Avoiding worker/wrapper (in Data.Map.Internal)
insert :: Ord a => a -> Set a -> Set a
insert x0 = go x0 x0
where
go :: Ord a => a -> a -> Set a -> Set a
go orig !_ Tip = singleton (lazy orig)
go orig !x t@(Bin sz y l r) = case compare x y of
LT | l' `ptrEq` l -> t
| otherwise -> balanceL y l' r
where !l' = go orig x l
GT | r' `ptrEq` r -> t
| otherwise -> balanceR y l r'
where !r' = go orig x r
EQ | lazy orig `seq` (orig `ptrEq` y) -> t
| otherwise -> Bin sz (lazy orig) l r
#if __GLASGOW_HASKELL__
{-# INLINABLE insert #-}
#else
{-# INLINE insert #-}
#endif
#ifndef __GLASGOW_HASKELL__
lazy :: a -> a
lazy a = a
#endif
-- Insert an element to the set only if it is not in the set.
-- Used by `union`.
-- See Note: Type of local 'go' function
-- See Note: Avoiding worker/wrapper (in Data.Map.Internal)
insertR :: Ord a => a -> Set a -> Set a
insertR x0 = go x0 x0
where
go :: Ord a => a -> a -> Set a -> Set a
go orig !_ Tip = singleton (lazy orig)
go orig !x t@(Bin _ y l r) = case compare x y of
LT | l' `ptrEq` l -> t
| otherwise -> balanceL y l' r
where !l' = go orig x l
GT | r' `ptrEq` r -> t
| otherwise -> balanceR y l r'
where !r' = go orig x r
EQ -> t
#if __GLASGOW_HASKELL__
{-# INLINABLE insertR #-}
#else
{-# INLINE insertR #-}
#endif
-- | /O(log n)/. Delete an element from a set.
-- See Note: Type of local 'go' function
delete :: Ord a => a -> Set a -> Set a
delete = go
where
go :: Ord a => a -> Set a -> Set a
go !_ Tip = Tip
go x t@(Bin _ y l r) = case compare x y of
LT | l' `ptrEq` l -> t
| otherwise -> balanceR y l' r
where !l' = go x l
GT | r' `ptrEq` r -> t
| otherwise -> balanceL y l r'
where !r' = go x r
EQ -> glue l r
#if __GLASGOW_HASKELL__
{-# INLINABLE delete #-}
#else
{-# INLINE delete #-}
#endif
-- | /O(log n)/ @('alterF' f x s)@ can delete or insert @x@ in @s@ depending on
-- whether an equal element is found in @s@.
--
-- In short:
--
-- @
-- 'member' x \<$\> 'alterF' f x s = f ('member' x s)
-- @
--
-- Note that unlike 'insert', 'alterF' will /not/ replace an element equal to
-- the given value.
--
-- Note: 'alterF' is a variant of the @at@ combinator from "Control.Lens.At".
--
-- @since 0.6.3.1
alterF :: (Ord a, Functor f) => (Bool -> f Bool) -> a -> Set a -> f (Set a)
alterF f k s = fmap choose (f member_)
where
(member_, inserted, deleted) = case alteredSet k s of
Deleted d -> (True , s, d)
Inserted i -> (False, i, s)
choose True = inserted
choose False = deleted
#ifndef __GLASGOW_HASKELL__
{-# INLINE alterF #-}
#else
{-# INLINABLE [2] alterF #-}
{-# RULES
"alterF/Const" forall k (f :: Bool -> Const a Bool) . alterF f k = \s -> Const . getConst . f $ member k s
#-}
#endif
#if MIN_VERSION_base(4,8,0)
{-# SPECIALIZE alterF :: Ord a => (Bool -> Identity Bool) -> a -> Set a -> Identity (Set a) #-}
#endif
data AlteredSet a
-- | The needle is present in the original set.
-- We return the set where the needle is deleted.
= Deleted !(Set a)
-- | The needle is not present in the original set.
-- We return the set with the needle inserted.
| Inserted !(Set a)
alteredSet :: Ord a => a -> Set a -> AlteredSet a
alteredSet x0 s0 = go x0 s0
where
go :: Ord a => a -> Set a -> AlteredSet a
go x Tip = Inserted (singleton x)
go x (Bin _ y l r) = case compare x y of
LT -> case go x l of
Deleted d -> Deleted (balanceR y d r)
Inserted i -> Inserted (balanceL y i r)
GT -> case go x r of
Deleted d -> Deleted (balanceL y l d)
Inserted i -> Inserted (balanceR y l i)
EQ -> Deleted (glue l r)
#if __GLASGOW_HASKELL__
{-# INLINABLE alteredSet #-}
#else
{-# INLINE alteredSet #-}
#endif
{--------------------------------------------------------------------
Subset
--------------------------------------------------------------------}
-- | /O(m*log(n\/m + 1)), m <= n/.
-- @(s1 \`isProperSubsetOf\` s2)@ indicates whether @s1@ is a
-- proper subset of @s2@.
--
-- @
-- s1 \`isProperSubsetOf\` s2 = s1 ``isSubsetOf`` s2 && s1 /= s2
-- @
isProperSubsetOf :: Ord a => Set a -> Set a -> Bool
isProperSubsetOf s1 s2
= size s1 < size s2 && isSubsetOfX s1 s2
#if __GLASGOW_HASKELL__
{-# INLINABLE isProperSubsetOf #-}
#endif
-- | /O(m*log(n\/m + 1)), m <= n/.
-- @(s1 \`isSubsetOf\` s2)@ indicates whether @s1@ is a subset of @s2@.
--
-- @
-- s1 \`isSubsetOf\` s2 = all (``member`` s2) s1
-- s1 \`isSubsetOf\` s2 = null (s1 ``difference`` s2)
-- s1 \`isSubsetOf\` s2 = s1 ``union`` s2 == s2
-- s1 \`isSubsetOf\` s2 = s1 ``intersection`` s2 == s1
-- @
isSubsetOf :: Ord a => Set a -> Set a -> Bool
isSubsetOf t1 t2
= size t1 <= size t2 && isSubsetOfX t1 t2
#if __GLASGOW_HASKELL__
{-# INLINABLE isSubsetOf #-}
#endif
-- Test whether a set is a subset of another without the *initial*
-- size test.
--
-- This function is structured very much like `difference`, `union`,
-- and `intersection`. Whereas the bounds proofs for those in Blelloch
-- et al needed to accound for both "split work" and "merge work", we
-- only have to worry about split work here, which is the same as in
-- those functions.
isSubsetOfX :: Ord a => Set a -> Set a -> Bool
isSubsetOfX Tip _ = True
isSubsetOfX _ Tip = False
-- Skip the final split when we hit a singleton.
isSubsetOfX (Bin 1 x _ _) t = member x t
isSubsetOfX (Bin _ x l r) t
= found &&
-- Cheap size checks can sometimes save expensive recursive calls when the
-- result will be False. Suppose we check whether [1..10] (with root 4) is
-- a subset of [0..9]. After the first split, we have to check if [1..3] is
-- a subset of [0..3] and if [5..10] is a subset of [5..9]. But we can bail
-- immediately because size [5..10] > size [5..9].
--
-- Why not just call `isSubsetOf` on each side to do the size checks?
-- Because that could make a recursive call on the left even though the
-- size check would fail on the right. In principle, we could take this to
-- extremes by maintaining a queue of pairs of sets to be checked, working
-- through the tree level-wise. But that would impose higher administrative
-- costs without obvious benefits. It might be worth considering if we find
-- a way to use it to tighten the bounds in some useful/comprehensible way.
size l <= size lt && size r <= size gt &&
isSubsetOfX l lt && isSubsetOfX r gt
where
(lt,found,gt) = splitMember x t
#if __GLASGOW_HASKELL__
{-# INLINABLE isSubsetOfX #-}
#endif
{--------------------------------------------------------------------
Disjoint
--------------------------------------------------------------------}
-- | /O(m*log(n\/m + 1)), m <= n/. Check whether two sets are disjoint
-- (i.e., their intersection is empty).
--
-- > disjoint (fromList [2,4,6]) (fromList [1,3]) == True
-- > disjoint (fromList [2,4,6,8]) (fromList [2,3,5,7]) == False
-- > disjoint (fromList [1,2]) (fromList [1,2,3,4]) == False
-- > disjoint (fromList []) (fromList []) == True
--
-- @
-- xs ``disjoint`` ys = null (xs ``intersection`` ys)
-- @
--
-- @since 0.5.11
disjoint :: Ord a => Set a -> Set a -> Bool
disjoint Tip _ = True
disjoint _ Tip = True
-- Avoid a split for the singleton case.
disjoint (Bin 1 x _ _) t = x `notMember` t
disjoint (Bin _ x l r) t
-- Analogous implementation to `subsetOfX`
= not found && disjoint l lt && disjoint r gt
where
(lt,found,gt) = splitMember x t
{--------------------------------------------------------------------
Minimal, Maximal
--------------------------------------------------------------------}
-- We perform call-pattern specialization manually on lookupMin
-- and lookupMax. Otherwise, GHC doesn't seem to do it, which is
-- unfortunate if, for example, someone uses findMin or findMax.
lookupMinSure :: a -> Set a -> a
lookupMinSure x Tip = x
lookupMinSure _ (Bin _ x l _) = lookupMinSure x l
-- | /O(log n)/. The minimal element of a set.
--
-- @since 0.5.9
lookupMin :: Set a -> Maybe a
lookupMin Tip = Nothing
lookupMin (Bin _ x l _) = Just $! lookupMinSure x l
-- | /O(log n)/. The minimal element of a set.
findMin :: Set a -> a
findMin t
| Just r <- lookupMin t = r
| otherwise = error "Set.findMin: empty set has no minimal element"
lookupMaxSure :: a -> Set a -> a
lookupMaxSure x Tip = x
lookupMaxSure _ (Bin _ x _ r) = lookupMaxSure x r
-- | /O(log n)/. The maximal element of a set.
--
-- @since 0.5.9
lookupMax :: Set a -> Maybe a
lookupMax Tip = Nothing
lookupMax (Bin _ x _ r) = Just $! lookupMaxSure x r
-- | /O(log n)/. The maximal element of a set.
findMax :: Set a -> a
findMax t
| Just r <- lookupMax t = r
| otherwise = error "Set.findMax: empty set has no maximal element"
-- | /O(log n)/. Delete the minimal element. Returns an empty set if the set is empty.
deleteMin :: Set a -> Set a
deleteMin (Bin _ _ Tip r) = r
deleteMin (Bin _ x l r) = balanceR x (deleteMin l) r
deleteMin Tip = Tip
-- | /O(log n)/. Delete the maximal element. Returns an empty set if the set is empty.
deleteMax :: Set a -> Set a
deleteMax (Bin _ _ l Tip) = l
deleteMax (Bin _ x l r) = balanceL x l (deleteMax r)
deleteMax Tip = Tip
{--------------------------------------------------------------------
Union.
--------------------------------------------------------------------}
-- | The union of the sets in a Foldable structure : (@'unions' == 'foldl' 'union' 'empty'@).
unions :: (Foldable f, Ord a) => f (Set a) -> Set a
unions = Foldable.foldl' union empty
#if __GLASGOW_HASKELL__
{-# INLINABLE unions #-}
#endif
-- | /O(m*log(n\/m + 1)), m <= n/. The union of two sets, preferring the first set when
-- equal elements are encountered.
union :: Ord a => Set a -> Set a -> Set a
union t1 Tip = t1
union t1 (Bin 1 x _ _) = insertR x t1
union (Bin 1 x _ _) t2 = insert x t2
union Tip t2 = t2
union t1@(Bin _ x l1 r1) t2 = case splitS x t2 of
(l2 :*: r2)
| l1l2 `ptrEq` l1 && r1r2 `ptrEq` r1 -> t1
| otherwise -> link x l1l2 r1r2
where !l1l2 = union l1 l2
!r1r2 = union r1 r2
#if __GLASGOW_HASKELL__
{-# INLINABLE union #-}
#endif
{--------------------------------------------------------------------
Difference
--------------------------------------------------------------------}
-- | /O(m*log(n\/m + 1)), m <= n/. Difference of two sets.
difference :: Ord a => Set a -> Set a -> Set a
difference Tip _ = Tip
difference t1 Tip = t1
difference t1 (Bin _ x l2 r2) = case split x t1 of
(l1, r1)
| size l1l2 + size r1r2 == size t1 -> t1
| otherwise -> merge l1l2 r1r2
where !l1l2 = difference l1 l2
!r1r2 = difference r1 r2
#if __GLASGOW_HASKELL__
{-# INLINABLE difference #-}
#endif
{--------------------------------------------------------------------
Intersection
--------------------------------------------------------------------}
-- | /O(m*log(n\/m + 1)), m <= n/. 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 :: Ord a => Set a -> Set a -> Set a
intersection Tip _ = Tip
intersection _ Tip = Tip
intersection t1@(Bin _ x l1 r1) t2
| b = if l1l2 `ptrEq` l1 && r1r2 `ptrEq` r1
then t1
else link x l1l2 r1r2
| otherwise = merge l1l2 r1r2
where
!(l2, b, r2) = splitMember x t2
!l1l2 = intersection l1 l2
!r1r2 = intersection r1 r2
#if __GLASGOW_HASKELL__
{-# INLINABLE intersection #-}
#endif
{--------------------------------------------------------------------
Filter and partition
--------------------------------------------------------------------}
-- | /O(n)/. Filter all elements that satisfy the predicate.
filter :: (a -> Bool) -> Set a -> Set a
filter _ Tip = Tip
filter p t@(Bin _ x l r)
| p x = if l `ptrEq` l' && r `ptrEq` r'
then t
else link x l' r'
| otherwise = merge l' r'
where
!l' = filter p l
!r' = filter p 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 :: (a -> Bool) -> Set a -> (Set a,Set a)
partition p0 t0 = toPair $ go p0 t0
where
go _ Tip = (Tip :*: Tip)
go p t@(Bin _ x l r) = case (go p l, go p r) of
((l1 :*: l2), (r1 :*: r2))
| p x -> (if l1 `ptrEq` l && r1 `ptrEq` r
then t
else link x l1 r1) :*: merge l2 r2
| otherwise -> merge l1 r1 :*:
(if l2 `ptrEq` l && r2 `ptrEq` r
then t
else link 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 :: Ord b => (a->b) -> Set a -> Set b
map f = fromList . List.map f . toList
#if __GLASGOW_HASKELL__
{-# INLINABLE map #-}
#endif
-- | /O(n)/. The
--
-- @'mapMonotonic' f s == 'map' f s@, but works only when @f@ is strictly increasing.
-- /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 :: (a->b) -> Set a -> Set b
mapMonotonic _ Tip = Tip
mapMonotonic f (Bin sz x l r) = Bin sz (f x) (mapMonotonic f l) (mapMonotonic f r)
{--------------------------------------------------------------------
Fold
--------------------------------------------------------------------}
-- | /O(n)/. Fold the elements in the set using the given right-associative
-- binary operator. This function is an equivalent of 'foldr' and is present
-- for compatibility only.
--
-- /Please note that fold will be deprecated in the future and removed./
fold :: (a -> b -> b) -> b -> Set a -> b
fold = foldr
{-# INLINE fold #-}
-- | /O(n)/. Fold the elements in the set using the given right-associative
-- binary operator, such that @'foldr' f z == 'Prelude.foldr' f z . 'toAscList'@.
--
-- For example,
--
-- > toAscList set = foldr (:) [] set
foldr :: (a -> b -> b) -> b -> Set a -> b
foldr f z = go z
where
go z' Tip = z'
go z' (Bin _ x l r) = go (f x (go z' r)) l
{-# INLINE foldr #-}
-- | /O(n)/. A strict version of 'foldr'. Each application of the operator is
-- evaluated before using the result in the next application. This
-- function is strict in the starting value.
foldr' :: (a -> b -> b) -> b -> Set a -> b
foldr' f z = go z
where
go !z' Tip = z'
go z' (Bin _ x l r) = go (f x (go z' r)) l
{-# INLINE foldr' #-}
-- | /O(n)/. Fold the elements in the set using the given left-associative
-- binary operator, such that @'foldl' f z == 'Prelude.foldl' f z . 'toAscList'@.
--
-- For example,
--
-- > toDescList set = foldl (flip (:)) [] set
foldl :: (a -> b -> a) -> a -> Set b -> a
foldl f z = go z
where
go z' Tip = z'
go z' (Bin _ x l r) = go (f (go z' l) x) r
{-# INLINE foldl #-}
-- | /O(n)/. A strict version of 'foldl'. Each application of the operator is
-- evaluated before using the result in the next application. This
-- function is strict in the starting value.
foldl' :: (a -> b -> a) -> a -> Set b -> a
foldl' f z = go z
where
go !z' Tip = z'
go z' (Bin _ x l r) = go (f (go z' l) x) r
{-# INLINE foldl' #-}
{--------------------------------------------------------------------
List variations
--------------------------------------------------------------------}
-- | /O(n)/. An alias of 'toAscList'. The elements of a set in ascending order.
-- Subject to list fusion.
elems :: Set a -> [a]
elems = toAscList
{--------------------------------------------------------------------
Lists
--------------------------------------------------------------------}
#if __GLASGOW_HASKELL__ >= 708
-- | @since 0.5.6.2
instance (Ord a) => GHCExts.IsList (Set a) where
type Item (Set a) = a
fromList = fromList
toList = toList
#endif
-- | /O(n)/. Convert the set to a list of elements. Subject to list fusion.
toList :: Set a -> [a]
toList = toAscList
-- | /O(n)/. Convert the set to an ascending list of elements. Subject to list fusion.
toAscList :: Set a -> [a]
toAscList = foldr (:) []
-- | /O(n)/. Convert the set to a descending list of elements. Subject to list
-- fusion.
toDescList :: Set a -> [a]
toDescList = foldl (flip (:)) []
-- List fusion for the list generating functions.
#if __GLASGOW_HASKELL__
-- The foldrFB and foldlFB are foldr and foldl equivalents, used for list fusion.
-- They are important to convert unfused to{Asc,Desc}List back, see mapFB in prelude.
foldrFB :: (a -> b -> b) -> b -> Set a -> b
foldrFB = foldr
{-# INLINE[0] foldrFB #-}
foldlFB :: (a -> b -> a) -> a -> Set b -> a
foldlFB = foldl
{-# INLINE[0] foldlFB #-}
-- Inline elems and toList, so that we need to fuse only toAscList.
{-# INLINE elems #-}
{-# INLINE toList #-}
-- The fusion is enabled up to phase 2 included. If it does not succeed,
-- convert in phase 1 the expanded to{Asc,Desc}List calls back to
-- to{Asc,Desc}List. In phase 0, we inline fold{lr}FB (which were used in
-- a list fusion, otherwise it would go away in phase 1), and let compiler do
-- whatever it wants with to{Asc,Desc}List -- it was forbidden to inline it
-- before phase 0, otherwise the fusion rules would not fire at all.
{-# NOINLINE[0] toAscList #-}
{-# NOINLINE[0] toDescList #-}
{-# RULES "Set.toAscList" [~1] forall s . toAscList s = build (\c n -> foldrFB c n s) #-}
{-# RULES "Set.toAscListBack" [1] foldrFB (:) [] = toAscList #-}
{-# RULES "Set.toDescList" [~1] forall s . toDescList s = build (\c n -> foldlFB (\xs x -> c x xs) n s) #-}
{-# RULES "Set.toDescListBack" [1] foldlFB (\xs x -> x : xs) [] = toDescList #-}
#endif
-- | /O(n*log n)/. Create a set from a list of elements.
--
-- If the elements are ordered, a linear-time implementation is used,
-- with the performance equal to 'fromDistinctAscList'.
-- For some reason, when 'singleton' is used in fromList or in
-- create, it is not inlined, so we inline it manually.
fromList :: Ord a => [a] -> Set a
fromList [] = Tip
fromList [x] = Bin 1 x Tip Tip
fromList (x0 : xs0) | not_ordered x0 xs0 = fromList' (Bin 1 x0 Tip Tip) xs0
| otherwise = go (1::Int) (Bin 1 x0 Tip Tip) xs0
where
not_ordered _ [] = False
not_ordered x (y : _) = x >= y
{-# INLINE not_ordered #-}
fromList' t0 xs = Foldable.foldl' ins t0 xs
where ins t x = insert x t
go !_ t [] = t
go _ t [x] = insertMax x t
go s l xs@(x : xss) | not_ordered x xss = fromList' l xs
| otherwise = case create s xss of
(r, ys, []) -> go (s `shiftL` 1) (link x l r) ys
(r, _, ys) -> fromList' (link x l r) ys
-- The create is returning a triple (tree, xs, ys). Both xs and ys
-- represent not yet processed elements and only one of them can be nonempty.
-- If ys is nonempty, the keys in ys are not ordered with respect to tree
-- and must be inserted using fromList'. Otherwise the keys have been
-- ordered so far.
create !_ [] = (Tip, [], [])
create s xs@(x : xss)
| s == 1 = if not_ordered x xss then (Bin 1 x Tip Tip, [], xss)
else (Bin 1 x Tip Tip, xss, [])
| otherwise = case create (s `shiftR` 1) xs of
res@(_, [], _) -> res
(l, [y], zs) -> (insertMax y l, [], zs)
(l, ys@(y:yss), _) | not_ordered y yss -> (l, [], ys)
| otherwise -> case create (s `shiftR` 1) yss of
(r, zs, ws) -> (link y l r, zs, ws)
#if __GLASGOW_HASKELL__
{-# INLINABLE fromList #-}
#endif
{--------------------------------------------------------------------
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 :: Eq a => [a] -> Set a
fromAscList xs = fromDistinctAscList (combineEq xs)
#if __GLASGOW_HASKELL__
{-# INLINABLE fromAscList #-}
#endif
-- | /O(n)/. Build a set from a descending list in linear time.
-- /The precondition (input list is descending) is not checked./
--
-- @since 0.5.8
fromDescList :: Eq a => [a] -> Set a
fromDescList xs = fromDistinctDescList (combineEq xs)
#if __GLASGOW_HASKELL__
{-# INLINABLE fromDescList #-}
#endif
-- [combineEq xs] combines equal elements with [const] in an ordered list [xs]
--
-- TODO: combineEq allocates an intermediate list. It *should* be better to
-- make fromAscListBy and fromDescListBy the fundamental operations, and to
-- implement the rest using those.
combineEq :: Eq a => [a] -> [a]
combineEq [] = []
combineEq (x : xs) = combineEq' x xs
where
combineEq' z [] = [z]
combineEq' z (y:ys)
| z == y = combineEq' z ys
| otherwise = z : combineEq' y ys
-- | /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./
-- For some reason, when 'singleton' is used in fromDistinctAscList or in
-- create, it is not inlined, so we inline it manually.
fromDistinctAscList :: [a] -> Set a
fromDistinctAscList [] = Tip
fromDistinctAscList (x0 : xs0) = go (1::Int) (Bin 1 x0 Tip Tip) xs0
where
go !_ t [] = t
go s l (x : xs) = case create s xs of
(r :*: ys) -> let !t' = link x l r
in go (s `shiftL` 1) t' ys
create !_ [] = (Tip :*: [])
create s xs@(x : xs')
| s == 1 = (Bin 1 x Tip Tip :*: xs')
| otherwise = case create (s `shiftR` 1) xs of
res@(_ :*: []) -> res
(l :*: (y:ys)) -> case create (s `shiftR` 1) ys of
(r :*: zs) -> (link y l r :*: zs)
-- | /O(n)/. Build a set from a descending list of distinct elements in linear time.
-- /The precondition (input list is strictly descending) is not checked./
-- For some reason, when 'singleton' is used in fromDistinctDescList or in
-- create, it is not inlined, so we inline it manually.
--
-- @since 0.5.8
fromDistinctDescList :: [a] -> Set a
fromDistinctDescList [] = Tip
fromDistinctDescList (x0 : xs0) = go (1::Int) (Bin 1 x0 Tip Tip) xs0
where
go !_ t [] = t
go s r (x : xs) = case create s xs of
(l :*: ys) -> let !t' = link x l r
in go (s `shiftL` 1) t' ys
create !_ [] = (Tip :*: [])
create s xs@(x : xs')
| s == 1 = (Bin 1 x Tip Tip :*: xs')
| otherwise = case create (s `shiftR` 1) xs of
res@(_ :*: []) -> res
(r :*: (y:ys)) -> case create (s `shiftR` 1) ys of
(l :*: zs) -> (link y 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 Eq a => Eq (Set a) where
t1 == t2 = (size t1 == size t2) && (toAscList t1 == toAscList t2)
{--------------------------------------------------------------------
Ord
--------------------------------------------------------------------}
instance Ord a => Ord (Set a) where
compare s1 s2 = compare (toAscList s1) (toAscList s2)
{--------------------------------------------------------------------
Show
--------------------------------------------------------------------}
instance Show a => Show (Set a) where
showsPrec p xs = showParen (p > 10) $
showString "fromList " . shows (toList xs)
#if MIN_VERSION_base(4,9,0)
-- | @since 0.5.9
instance Eq1 Set where
liftEq eq m n =
size m == size n && liftEq eq (toList m) (toList n)
-- | @since 0.5.9
instance Ord1 Set where
liftCompare cmp m n =
liftCompare cmp (toList m) (toList n)
-- | @since 0.5.9
instance Show1 Set where
liftShowsPrec sp sl d m =
showsUnaryWith (liftShowsPrec sp sl) "fromList" d (toList m)
#endif
{--------------------------------------------------------------------
Read
--------------------------------------------------------------------}
instance (Read a, Ord a) => Read (Set a) where
#ifdef __GLASGOW_HASKELL__
readPrec = parens $ prec 10 $ do
Ident "fromList" <- lexP
xs <- readPrec
return (fromList xs)
readListPrec = readListPrecDefault
#else
readsPrec p = readParen (p > 10) $ \ r -> do
("fromList",s) <- lex r
(xs,t) <- reads s
return (fromList xs,t)
#endif
{--------------------------------------------------------------------
Typeable/Data
--------------------------------------------------------------------}
INSTANCE_TYPEABLE1(Set)
{--------------------------------------------------------------------
NFData
--------------------------------------------------------------------}
instance NFData a => NFData (Set a) where
rnf Tip = ()
rnf (Bin _ y l r) = rnf y `seq` rnf l `seq` rnf r
{--------------------------------------------------------------------
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 :: Ord a => a -> Set a -> (Set a,Set a)
split x t = toPair $ splitS x t
{-# INLINABLE split #-}
splitS :: Ord a => a -> Set a -> StrictPair (Set a) (Set a)
splitS _ Tip = (Tip :*: Tip)
splitS x (Bin _ y l r)
= case compare x y of
LT -> let (lt :*: gt) = splitS x l in (lt :*: link y gt r)
GT -> let (lt :*: gt) = splitS x r in (link y l lt :*: gt)
EQ -> (l :*: r)
{-# INLINABLE splitS #-}
-- | /O(log n)/. Performs a 'split' but also returns whether the pivot
-- element was found in the original set.
splitMember :: Ord a => a -> Set a -> (Set a,Bool,Set a)
splitMember _ Tip = (Tip, False, Tip)
splitMember x (Bin _ y l r)
= case compare x y of
LT -> let (lt, found, gt) = splitMember x l
!gt' = link y gt r
in (lt, found, gt')
GT -> let (lt, found, gt) = splitMember x r
!lt' = link y l lt
in (lt', found, gt)
EQ -> (l, True, r)
#if __GLASGOW_HASKELL__
{-# INLINABLE splitMember #-}
#endif
{--------------------------------------------------------------------
Indexing
--------------------------------------------------------------------}
-- | /O(log n)/. Return the /index/ of an element, which is its zero-based
-- index in the sorted sequence of elements. The index is a number from /0/ up
-- to, but not including, the 'size' of the set. Calls 'error' when the element
-- is not a 'member' of the set.
--
-- > findIndex 2 (fromList [5,3]) Error: element is not in the set
-- > findIndex 3 (fromList [5,3]) == 0
-- > findIndex 5 (fromList [5,3]) == 1
-- > findIndex 6 (fromList [5,3]) Error: element is not in the set
--
-- @since 0.5.4
-- See Note: Type of local 'go' function
findIndex :: Ord a => a -> Set a -> Int
findIndex = go 0
where
go :: Ord a => Int -> a -> Set a -> Int
go !_ !_ Tip = error "Set.findIndex: element is not in the set"
go idx x (Bin _ kx l r) = case compare x kx of
LT -> go idx x l
GT -> go (idx + size l + 1) x r
EQ -> idx + size l
#if __GLASGOW_HASKELL__
{-# INLINABLE findIndex #-}
#endif
-- | /O(log n)/. Lookup the /index/ of an element, which is its zero-based index in
-- the sorted sequence of elements. The index is a number from /0/ up to, but not
-- including, the 'size' of the set.
--
-- > isJust (lookupIndex 2 (fromList [5,3])) == False
-- > fromJust (lookupIndex 3 (fromList [5,3])) == 0
-- > fromJust (lookupIndex 5 (fromList [5,3])) == 1
-- > isJust (lookupIndex 6 (fromList [5,3])) == False
--
-- @since 0.5.4
-- See Note: Type of local 'go' function
lookupIndex :: Ord a => a -> Set a -> Maybe Int
lookupIndex = go 0
where
go :: Ord a => Int -> a -> Set a -> Maybe Int
go !_ !_ Tip = Nothing
go idx x (Bin _ kx l r) = case compare x kx of
LT -> go idx x l
GT -> go (idx + size l + 1) x r
EQ -> Just $! idx + size l
#if __GLASGOW_HASKELL__
{-# INLINABLE lookupIndex #-}
#endif
-- | /O(log n)/. Retrieve an element by its /index/, i.e. by its zero-based
-- index in the sorted sequence of elements. If the /index/ is out of range (less
-- than zero, greater or equal to 'size' of the set), 'error' is called.
--
-- > elemAt 0 (fromList [5,3]) == 3
-- > elemAt 1 (fromList [5,3]) == 5
-- > elemAt 2 (fromList [5,3]) Error: index out of range
--
-- @since 0.5.4
elemAt :: Int -> Set a -> a
elemAt !_ Tip = error "Set.elemAt: index out of range"
elemAt i (Bin _ x l r)
= case compare i sizeL of
LT -> elemAt i l
GT -> elemAt (i-sizeL-1) r
EQ -> x
where
sizeL = size l
-- | /O(log n)/. Delete the element at /index/, i.e. by its zero-based index in
-- the sorted sequence of elements. If the /index/ is out of range (less than zero,
-- greater or equal to 'size' of the set), 'error' is called.
--
-- > deleteAt 0 (fromList [5,3]) == singleton 5
-- > deleteAt 1 (fromList [5,3]) == singleton 3
-- > deleteAt 2 (fromList [5,3]) Error: index out of range
-- > deleteAt (-1) (fromList [5,3]) Error: index out of range
--
-- @since 0.5.4
deleteAt :: Int -> Set a -> Set a
deleteAt !i t =
case t of
Tip -> error "Set.deleteAt: index out of range"
Bin _ x l r -> case compare i sizeL of
LT -> balanceR x (deleteAt i l) r
GT -> balanceL x l (deleteAt (i-sizeL-1) r)
EQ -> glue l r
where
sizeL = size l
-- | Take a given number of elements in order, beginning
-- with the smallest ones.
--
-- @
-- take n = 'fromDistinctAscList' . 'Prelude.take' n . 'toAscList'
-- @
--
-- @since 0.5.8
take :: Int -> Set a -> Set a
take i m | i >= size m = m
take i0 m0 = go i0 m0
where
go i !_ | i <= 0 = Tip
go !_ Tip = Tip
go i (Bin _ x l r) =
case compare i sizeL of
LT -> go i l
GT -> link x l (go (i - sizeL - 1) r)
EQ -> l
where sizeL = size l
-- | Drop a given number of elements in order, beginning
-- with the smallest ones.
--
-- @
-- drop n = 'fromDistinctAscList' . 'Prelude.drop' n . 'toAscList'
-- @
--
-- @since 0.5.8
drop :: Int -> Set a -> Set a
drop i m | i >= size m = Tip
drop i0 m0 = go i0 m0
where
go i m | i <= 0 = m
go !_ Tip = Tip
go i (Bin _ x l r) =
case compare i sizeL of
LT -> link x (go i l) r
GT -> go (i - sizeL - 1) r
EQ -> insertMin x r
where sizeL = size l
-- | /O(log n)/. Split a set at a particular index.
--
-- @
-- splitAt !n !xs = ('take' n xs, 'drop' n xs)
-- @
splitAt :: Int -> Set a -> (Set a, Set a)
splitAt i0 m0
| i0 >= size m0 = (m0, Tip)
| otherwise = toPair $ go i0 m0
where
go i m | i <= 0 = Tip :*: m
go !_ Tip = Tip :*: Tip
go i (Bin _ x l r)
= case compare i sizeL of
LT -> case go i l of
ll :*: lr -> ll :*: link x lr r
GT -> case go (i - sizeL - 1) r of
rl :*: rr -> link x l rl :*: rr
EQ -> l :*: insertMin x r
where sizeL = size l
-- | /O(log n)/. Take while a predicate on the elements holds.
-- The user is responsible for ensuring that for all elements @j@ and @k@ in the set,
-- @j \< k ==\> p j \>= p k@. See note at 'spanAntitone'.
--
-- @
-- takeWhileAntitone p = 'fromDistinctAscList' . 'Data.List.takeWhile' p . 'toList'
-- takeWhileAntitone p = 'filter' p
-- @
--
-- @since 0.5.8
takeWhileAntitone :: (a -> Bool) -> Set a -> Set a
takeWhileAntitone _ Tip = Tip
takeWhileAntitone p (Bin _ x l r)
| p x = link x l (takeWhileAntitone p r)
| otherwise = takeWhileAntitone p l
-- | /O(log n)/. Drop while a predicate on the elements holds.
-- The user is responsible for ensuring that for all elements @j@ and @k@ in the set,
-- @j \< k ==\> p j \>= p k@. See note at 'spanAntitone'.
--
-- @
-- dropWhileAntitone p = 'fromDistinctAscList' . 'Data.List.dropWhile' p . 'toList'
-- dropWhileAntitone p = 'filter' (not . p)
-- @
--
-- @since 0.5.8
dropWhileAntitone :: (a -> Bool) -> Set a -> Set a
dropWhileAntitone _ Tip = Tip
dropWhileAntitone p (Bin _ x l r)
| p x = dropWhileAntitone p r
| otherwise = link x (dropWhileAntitone p l) r
-- | /O(log n)/. Divide a set at the point where a predicate on the elements stops holding.
-- The user is responsible for ensuring that for all elements @j@ and @k@ in the set,
-- @j \< k ==\> p j \>= p k@.
--
-- @
-- spanAntitone p xs = ('takeWhileAntitone' p xs, 'dropWhileAntitone' p xs)
-- spanAntitone p xs = partition p xs
-- @
--
-- Note: if @p@ is not actually antitone, then @spanAntitone@ will split the set
-- at some /unspecified/ point where the predicate switches from holding to not
-- holding (where the predicate is seen to hold before the first element and to fail
-- after the last element).
--
-- @since 0.5.8
spanAntitone :: (a -> Bool) -> Set a -> (Set a, Set a)
spanAntitone p0 m = toPair (go p0 m)
where
go _ Tip = Tip :*: Tip
go p (Bin _ x l r)
| p x = let u :*: v = go p r in link x l u :*: v
| otherwise = let u :*: v = go p l in u :*: link x v r
{--------------------------------------------------------------------
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.
[link 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.
--------------------------------------------------------------------}
{--------------------------------------------------------------------
Link
--------------------------------------------------------------------}
link :: a -> Set a -> Set a -> Set a
link x Tip r = insertMin x r
link x l Tip = insertMax x l
link x l@(Bin sizeL y ly ry) r@(Bin sizeR z lz rz)
| delta*sizeL < sizeR = balanceL z (link x l lz) rz
| delta*sizeR < sizeL = balanceR y ly (link x ry r)
| otherwise = bin x l r
-- insertMin and insertMax don't perform potentially expensive comparisons.
insertMax,insertMin :: a -> Set a -> Set a
insertMax x t
= case t of
Tip -> singleton x
Bin _ y l r
-> balanceR y l (insertMax x r)
insertMin x t
= case t of
Tip -> singleton x
Bin _ y l r
-> balanceL y (insertMin x l) r
{--------------------------------------------------------------------
[merge l r]: merges two trees.
--------------------------------------------------------------------}
merge :: Set a -> Set a -> Set a
merge Tip r = r
merge l Tip = l
merge l@(Bin sizeL x lx rx) r@(Bin sizeR y ly ry)
| delta*sizeL < sizeR = balanceL y (merge l ly) ry
| delta*sizeR < sizeL = balanceR 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 :: Set a -> Set a -> Set a
glue Tip r = r
glue l Tip = l
glue l@(Bin sl xl ll lr) r@(Bin sr xr rl rr)
| sl > sr = let !(m :*: l') = maxViewSure xl ll lr in balanceR m l' r
| otherwise = let !(m :*: r') = minViewSure xr rl rr in balanceL m l r'
-- | /O(log n)/. Delete and find the minimal element.
--
-- > deleteFindMin set = (findMin set, deleteMin set)
deleteFindMin :: Set a -> (a,Set a)
deleteFindMin t
| Just r <- minView t = r
| otherwise = (error "Set.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 :: Set a -> (a,Set a)
deleteFindMax t
| Just r <- maxView t = r
| otherwise = (error "Set.deleteFindMax: can not return the maximal element of an empty set", Tip)
minViewSure :: a -> Set a -> Set a -> StrictPair a (Set a)
minViewSure = go
where
go x Tip r = x :*: r
go x (Bin _ xl ll lr) r =
case go xl ll lr of
xm :*: l' -> xm :*: balanceR x l' r
-- | /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 :: Set a -> Maybe (a, Set a)
minView Tip = Nothing
minView (Bin _ x l r) = Just $! toPair $ minViewSure x l r
maxViewSure :: a -> Set a -> Set a -> StrictPair a (Set a)
maxViewSure = go
where
go x l Tip = x :*: l
go x l (Bin _ xr rl rr) =
case go xr rl rr of
xm :*: r' -> xm :*: balanceL x l r'
-- | /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 :: Set a -> Maybe (a, Set a)
maxView Tip = Nothing
maxView (Bin _ x l r) = Just $! toPair $ maxViewSure x l r
{--------------------------------------------------------------------
[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.
[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 according to the Adam's paper:
- [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.
But the Adam's paper is errorneous:
- it can be proved that for delta=2 and delta>=5 there does
not exist any ratio that would work
- delta=4.5 and ratio=2 does not work
That leaves two reasonable variants, delta=3 and delta=4,
both with ratio=2.
- A lower [delta] leads to a more 'perfectly' balanced tree.
- A higher [delta] performs less rebalancing.
In the benchmarks, delta=3 is faster on insert operations,
and delta=4 has slightly better deletes. As the insert speedup
is larger, we currently use delta=3.
--------------------------------------------------------------------}
delta,ratio :: Int
delta = 3
ratio = 2
-- The balance function is equivalent to the following:
--
-- balance :: a -> Set a -> Set a -> Set a
-- balance x l r
-- | sizeL + sizeR <= 1 = Bin sizeX x l r
-- | sizeR > delta*sizeL = rotateL x l r
-- | sizeL > delta*sizeR = rotateR x l r
-- | otherwise = Bin sizeX x l r
-- where
-- sizeL = size l
-- sizeR = size r
-- sizeX = sizeL + sizeR + 1
--
-- rotateL :: a -> Set a -> Set a -> Set a
-- rotateL x l r@(Bin _ _ ly ry) | size ly < ratio*size ry = singleL x l r
-- | otherwise = doubleL x l r
-- rotateR :: a -> Set a -> Set a -> Set a
-- rotateR x l@(Bin _ _ ly ry) r | size ry < ratio*size ly = singleR x l r
-- | otherwise = doubleR x l r
--
-- singleL, singleR :: a -> Set a -> Set a -> Set a
-- singleL x1 t1 (Bin _ x2 t2 t3) = bin x2 (bin x1 t1 t2) t3
-- singleR x1 (Bin _ x2 t1 t2) t3 = bin x2 t1 (bin x1 t2 t3)
--
-- doubleL, doubleR :: a -> Set a -> Set a -> Set a
-- doubleL x1 t1 (Bin _ x2 (Bin _ x3 t2 t3) t4) = bin x3 (bin x1 t1 t2) (bin x2 t3 t4)
-- doubleR x1 (Bin _ x2 t1 (Bin _ x3 t2 t3)) t4 = bin x3 (bin x2 t1 t2) (bin x1 t3 t4)
--
-- It is only written in such a way that every node is pattern-matched only once.
--
-- Only balanceL and balanceR are needed at the moment, so balance is not here anymore.
-- In case it is needed, it can be found in Data.Map.
-- Functions balanceL and balanceR are specialised versions of balance.
-- balanceL only checks whether the left subtree is too big,
-- balanceR only checks whether the right subtree is too big.
-- balanceL is called when left subtree might have been inserted to or when
-- right subtree might have been deleted from.
balanceL :: a -> Set a -> Set a -> Set a
balanceL x l r = case r of
Tip -> case l of
Tip -> Bin 1 x Tip Tip
(Bin _ _ Tip Tip) -> Bin 2 x l Tip
(Bin _ lx Tip (Bin _ lrx _ _)) -> Bin 3 lrx (Bin 1 lx Tip Tip) (Bin 1 x Tip Tip)
(Bin _ lx ll@(Bin _ _ _ _) Tip) -> Bin 3 lx ll (Bin 1 x Tip Tip)
(Bin ls lx ll@(Bin lls _ _ _) lr@(Bin lrs lrx lrl lrr))
| lrs < ratio*lls -> Bin (1+ls) lx ll (Bin (1+lrs) x lr Tip)
| otherwise -> Bin (1+ls) lrx (Bin (1+lls+size lrl) lx ll lrl) (Bin (1+size lrr) x lrr Tip)
(Bin rs _ _ _) -> case l of
Tip -> Bin (1+rs) x Tip r
(Bin ls lx ll lr)
| ls > delta*rs -> case (ll, lr) of
(Bin lls _ _ _, Bin lrs lrx lrl lrr)
| lrs < ratio*lls -> Bin (1+ls+rs) lx ll (Bin (1+rs+lrs) x lr r)
| otherwise -> Bin (1+ls+rs) lrx (Bin (1+lls+size lrl) lx ll lrl) (Bin (1+rs+size lrr) x lrr r)
(_, _) -> error "Failure in Data.Map.balanceL"
| otherwise -> Bin (1+ls+rs) x l r
{-# NOINLINE balanceL #-}
-- balanceR is called when right subtree might have been inserted to or when
-- left subtree might have been deleted from.
balanceR :: a -> Set a -> Set a -> Set a
balanceR x l r = case l of
Tip -> case r of
Tip -> Bin 1 x Tip Tip
(Bin _ _ Tip Tip) -> Bin 2 x Tip r
(Bin _ rx Tip rr@(Bin _ _ _ _)) -> Bin 3 rx (Bin 1 x Tip Tip) rr
(Bin _ rx (Bin _ rlx _ _) Tip) -> Bin 3 rlx (Bin 1 x Tip Tip) (Bin 1 rx Tip Tip)
(Bin rs rx rl@(Bin rls rlx rll rlr) rr@(Bin rrs _ _ _))
| rls < ratio*rrs -> Bin (1+rs) rx (Bin (1+rls) x Tip rl) rr
| otherwise -> Bin (1+rs) rlx (Bin (1+size rll) x Tip rll) (Bin (1+rrs+size rlr) rx rlr rr)
(Bin ls _ _ _) -> case r of
Tip -> Bin (1+ls) x l Tip
(Bin rs rx rl rr)
| rs > delta*ls -> case (rl, rr) of
(Bin rls rlx rll rlr, Bin rrs _ _ _)
| rls < ratio*rrs -> Bin (1+ls+rs) rx (Bin (1+ls+rls) x l rl) rr
| otherwise -> Bin (1+ls+rs) rlx (Bin (1+ls+size rll) x l rll) (Bin (1+rrs+size rlr) rx rlr rr)
(_, _) -> error "Failure in Data.Map.balanceR"
| otherwise -> Bin (1+ls+rs) x l r
{-# NOINLINE balanceR #-}
{--------------------------------------------------------------------
The bin constructor maintains the size of the tree
--------------------------------------------------------------------}
bin :: a -> Set a -> Set a -> Set a
bin x l r
= Bin (size l + size r + 1) x l r
{-# INLINE bin #-}
{--------------------------------------------------------------------
Utilities
--------------------------------------------------------------------}
-- | /O(1)/. Decompose a set into pieces based on the structure of the underlying
-- tree. This function is useful for consuming a set in parallel.
--
-- No guarantee is made as to the sizes of the pieces; an internal, but
-- deterministic process determines this. However, it is guaranteed that the pieces
-- returned will be in ascending order (all elements in the first subset less than all
-- elements in the second, and so on).
--
-- Examples:
--
-- > splitRoot (fromList [1..6]) ==
-- > [fromList [1,2,3],fromList [4],fromList [5,6]]
--
-- > splitRoot empty == []
--
-- Note that the current implementation does not return more than three subsets,
-- but you should not depend on this behaviour because it can change in the
-- future without notice.
--
-- @since 0.5.4
splitRoot :: Set a -> [Set a]
splitRoot orig =
case orig of
Tip -> []
Bin _ v l r -> [l, singleton v, r]
{-# INLINE splitRoot #-}
-- | Calculate the power set of a set: the set of all its subsets.
--
-- @
-- t ``member`` powerSet s == t ``isSubsetOf`` s
-- @
--
-- Example:
--
-- @
-- powerSet (fromList [1,2,3]) =
-- fromList $ map fromList [[],[1],[1,2],[1,2,3],[1,3],[2],[2,3],[3]]
-- @
--
-- @since 0.5.11
powerSet :: Set a -> Set (Set a)
powerSet xs0 = insertMin empty (foldr' step Tip xs0) where
step x pxs = insertMin (singleton x) (insertMin x `mapMonotonic` pxs) `glue` pxs
-- | /O(m*n)/ (conjectured). Calculate the Cartesian product of two sets.
--
-- @
-- cartesianProduct xs ys = fromList $ liftA2 (,) (toList xs) (toList ys)
-- @
--
-- Example:
--
-- @
-- cartesianProduct (fromList [1,2]) (fromList [\'a\',\'b\']) =
-- fromList [(1,\'a\'), (1,\'b\'), (2,\'a\'), (2,\'b\')]
-- @
--
-- @since 0.5.11
cartesianProduct :: Set a -> Set b -> Set (a, b)
-- I don't know for sure if this implementation (slightly modified from one
-- that Edward Kmett hacked together) is optimal. TODO: try to prove or
-- refute it.
--
-- We could definitely get big-O optimal (O(m * n)) in a rather simple way:
--
-- cartesianProduct _as Tip = Tip
-- cartesianProduct as bs = fromDistinctAscList
-- [(a,b) | a <- toList as, b <- toList bs]
--
-- Unfortunately, this is much slower in practice, at least when the sets are
-- constructed from ascending lists. I tried doing the same thing using a
-- known-length (perfect balancing) variant of fromDistinctAscList, but it
-- still didn't come close to the performance of Kmett's version in my very
-- informal tests.
-- When the second argument has at most one element, we can be a little
-- clever.
cartesianProduct !_as Tip = Tip
cartesianProduct as (Bin 1 b _ _) = mapMonotonic (flip (,) b) as
cartesianProduct as bs =
getMergeSet $ foldMap (\a -> MergeSet $ mapMonotonic ((,) a) bs) as
-- A version of Set with peculiar Semigroup and Monoid instances.
-- The result of xs <> ys will only be a valid set if the greatest
-- element of xs is strictly less than the least element of ys.
-- This is used to define cartesianProduct.
newtype MergeSet a = MergeSet { getMergeSet :: Set a }
#if (MIN_VERSION_base(4,9,0))
instance Semigroup (MergeSet a) where
MergeSet xs <> MergeSet ys = MergeSet (merge xs ys)
#endif
instance Monoid (MergeSet a) where
mempty = MergeSet empty
#if (MIN_VERSION_base(4,9,0))
mappend = (<>)
#else
mappend (MergeSet xs) (MergeSet ys) = MergeSet (merge xs ys)
#endif
-- | Calculate the disjoint union of two sets.
--
-- @ disjointUnion xs ys = map Left xs ``union`` map Right ys @
--
-- Example:
--
-- @
-- disjointUnion (fromList [1,2]) (fromList ["hi", "bye"]) =
-- fromList [Left 1, Left 2, Right "hi", Right "bye"]
-- @
--
-- @since 0.5.11
disjointUnion :: Set a -> Set b -> Set (Either a b)
disjointUnion as bs = merge (mapMonotonic Left as) (mapMonotonic Right bs)
{--------------------------------------------------------------------
Debugging
--------------------------------------------------------------------}
-- | /O(n)/. Show the tree that implements the set. The tree is shown
-- in a compressed, hanging format.
showTree :: Show a => Set 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 :: Show a => Bool -> Bool -> Set a -> String
showTreeWith hang wide t
| hang = (showsTreeHang wide [] t) ""
| otherwise = (showsTree wide [] [] t) ""
showsTree :: Show a => Bool -> [String] -> [String] -> Set a -> ShowS
showsTree wide lbars rbars t
= case t of
Tip -> showsBars lbars . showString "|\n"
Bin _ x Tip Tip
-> 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 :: Show a => Bool -> [String] -> Set a -> ShowS
showsTreeHang wide bars t
= case t of
Tip -> showsBars bars . showString "|\n"
Bin _ x Tip Tip
-> 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 :: Ord a => Set a -> Bool
valid t
= balanced t && ordered t && validsize t
ordered :: Ord a => Set a -> Bool
ordered t
= bounded (const True) (const True) t
where
bounded lo hi t'
= case t' of
Tip -> True
Bin _ x l r -> (lo x) && (hi x) && bounded lo (x) hi r
balanced :: Set a -> Bool
balanced t
= case t of
Tip -> True
Bin _ _ l r -> (size l + size r <= 1 || (size l <= delta*size r && size r <= delta*size l)) &&
balanced l && balanced r
validsize :: Set a -> Bool
validsize t
= (realsize t == Just (size t))
where
realsize t'
= case t' of
Tip -> Just 0
Bin sz _ l r -> case (realsize l,realsize r) of
(Just n,Just m) | n+m+1 == sz -> Just sz
_ -> Nothing