-- File created: 2008-11-11 11:24:30 {-# LANGUAGE CPP, MultiParamTypeClasses, FlexibleInstances , FlexibleContexts, UndecidableInstances #-} #include "exports.h" -- | The base implementation of a trie representing a map with list keys, -- generalized over any type of map from element values to tries. -- -- Worst-case complexities are given in terms of @n@, @m@, and @k@. @n@ refers -- to the number of keys in the map and @m@ to their maximum length. @k@ refers -- to the length of a key given to the function, not any property of the map. -- -- In addition, the trie's branching factor plays a part in almost every -- operation, but the complexity depends on the underlying 'Map'. Thus, for -- instance, 'member' is actually @O(m f(b))@ where @f(b)@ is the complexity of -- a lookup operation on the 'Map' used. This complexity depends on the -- underlying operation, which is not part of the specification of the visible -- function. Thus it could change whilst affecting the complexity only for -- certain Map types: hence this \"b factor\" is not shown explicitly. -- -- Disclaimer: the complexities have not been proven. -- -- Strict versions of functions are provided for those who want to be certain -- that their 'TrieMap' doesn't contain values consisting of unevaluated -- thunks. Note, however, that they do not evaluate the whole trie strictly, -- only the values. And only to one level of depth: for instance, 'alter'' does -- not 'seq' the value within the 'Maybe', only the 'Maybe' itself. The user -- should add the strictness in such cases himself, if he so wishes. -- -- Many functions come in both ordinary and @WithKey@ forms, where the former -- takes a function of type @a -> b@ and the latter of type @[k] -> a -> b@, -- where @[k]@ is the key associated with the value @a@. For most of these -- functions, there is additional overhead involved in keeping track of the -- key: don't use the latter form of the function unless you need it. module Data.ListTrie.Map (MAP_EXPORTS) where import Control.Applicative ((<*>),(<$>)) import Control.Arrow ((***), second) import qualified Data.DList as DL import Data.Either (partitionEithers) import Data.Function (on) import qualified Data.Foldable as F import qualified Data.Maybe as Maybe import Data.Monoid (Monoid(..)) import Data.Traversable (Traversable(traverse)) import Prelude hiding (filter, foldl, foldr, lookup, map, null) import qualified Prelude #if __GLASGOW_HASKELL__ import Text.Read (readPrec, lexP, parens, prec, Lexeme(Ident)) #endif import qualified Data.ListTrie.Base as Base import qualified Data.ListTrie.Base.Map as Map import Data.ListTrie.Base.Classes (fmap') import Data.ListTrie.Base.Map (Map, OrdMap) #include "docs.h" -- Invariant: any (Tr Nothing _) has a Just descendant. -- -- | The data structure itself: a map from keys of type @[k]@ to values of type -- @v@ implemented as a trie, using @map@ to map keys of type @k@ to sub-tries. -- -- Regarding the instances: -- -- - The @Trie@ class is internal, ignore it. -- -- - The 'Eq' constraint for the 'Ord' instance is misleading: it is needed -- only because 'Eq' is a superclass of 'Ord'. -- -- - The 'Foldable' and 'Traversable' instances allow folding over and -- traversing only the values, not the keys. -- -- - The 'Monoid' instance defines 'mappend' as 'union' and 'mempty' as -- 'empty'. data TrieMap map k v = Tr (Maybe v) !(CMap map k v) type CMap map k v = map k (TrieMap map k v) instance Map map k => Base.Trie TrieMap Maybe map k where mkTrie = Tr tParts (Tr v m) = (v,m) -- Don't use CMap in these instances since Haddock won't expand it instance (Eq (map k (TrieMap map k a)), Eq a) => Eq (TrieMap map k a) where Tr v1 m1 == Tr v2 m2 = v1 == v2 && m1 == m2 -- Eq constraint only needed because of superclassness... sigh instance (Eq (map k (TrieMap map k a)), OrdMap map k, Ord k, Ord a) => Ord (TrieMap map k a) where compare = compare `on` toAscList instance Map map k => Monoid (TrieMap map k a) where mempty = empty mappend = union mconcat = unions instance Map map k => Functor (TrieMap map k) where fmap = map instance Map map k => F.Foldable (TrieMap map k) where foldl = foldl . flip foldr = foldr instance (Map map k, Traversable (map k)) => Traversable (TrieMap map k) where traverse f (Tr v m) = Tr <$> traverse f v <*> traverse (traverse f) m instance (Map map k, Show k, Show a) => Show (TrieMap map k a) where showsPrec p s = showParen (p > 10) $ showString "fromList " . shows (toList s) instance (Map map k, Read k, Read a) => Read (TrieMap map k a) where #if __GLASGOW_HASKELL__ readPrec = parens $ prec 10 $ do Ident "fromList" <- lexP fmap fromList readPrec #else readsPrec p = readParen (p > 10) $ \r -> do ("fromList", list) <- lex r (xs, rest) <- readsPrec (p+1) list [(fromList xs, rest)] #endif -- * Construction -- | @O(1)@. The empty map. empty :: Map map k => TrieMap map k a empty = Base.empty -- | @O(s)@. The singleton map containing only the given key-value pair. singleton :: Map map k => [k] -> a -> TrieMap map k a singleton = Base.singleton -- * Modification -- | @O(min(m,s))@. Inserts the key-value pair into the map. If the key is -- already a member of the map, the given value replaces the old one. insert :: Map map k => [k] -> a -> TrieMap map k a -> TrieMap map k a insert = Base.insert -- | @O(min(m,s))@. Inserts the key-value pair into the map. If the key is -- already a member of the map, the given value replaces the old one. insert' :: Map map k => [k] -> a -> TrieMap map k a -> TrieMap map k a insert' = Base.insert' -- | @O(min(m,s))@. Inserts the key-value pair into the map. If the key is -- already a member of the map, the old value is replaced by @f givenValue -- oldValue@ where @f@ is the given function. insertWith :: Map map k => (a -> a -> a) -> [k] -> a -> TrieMap map k a -> TrieMap map k a insertWith = Base.insertWith -- | @O(min(m,s))@. Like 'insertWith', but the new value is reduced to weak -- head normal form before being placed into the map, whether it is the given -- value or a result of the combining function. insertWith' :: Map map k => (a -> a -> a) -> [k] -> a -> TrieMap map k a -> TrieMap map k a insertWith' = Base.insertWith' -- | @O(min(m,s))@. Removes the key from the map along with its associated -- value. If the key is not a member of the map, the map is unchanged. delete :: Map map k => [k] -> TrieMap map k a -> TrieMap map k a delete = Base.delete -- | @O(min(m,s))@. Adjusts the value at the given key by calling the given -- function on it. If the key is not a member of the map, the map is unchanged. adjust :: Map map k => (a -> a) -> [k] -> TrieMap map k a -> TrieMap map k a adjust = Base.adjust -- | @O(min(m,s))@. Like 'adjust', but the function is applied strictly. adjust' :: Map map k => (a -> a) -> [k] -> TrieMap map k a -> TrieMap map k a adjust' = Base.adjust' -- | @O(min(m,s))@. Updates the value at the given key: if the given -- function returns 'Nothing', the value and its associated key are removed; if -- 'Just'@ a@is returned, the old value is replaced with @a@. If the key is -- not a member of the map, the map is unchanged. update :: Map map k => (a -> Maybe a) -> [k] -> TrieMap map k a -> TrieMap map k a update f k = snd . updateLookup f k -- | @O(min(m,s))@. Like 'update', but also returns 'Just' the original value, -- or 'Nothing' if the key is not a member of the map. updateLookup :: Map map k => (a -> Maybe a) -> [k] -> TrieMap map k a -> (Maybe a, TrieMap map k a) updateLookup = Base.updateLookup -- | @O(min(m,s))@. The most general modification function, allowing you to -- modify the value at the given key, whether or not it is a member of the map. -- In short: the given function is passed 'Just' the value at the key if it is -- present, or 'Nothing' otherwise; if the function returns 'Just' a value, the -- new value is inserted into the map, otherwise the old value is removed. More -- precisely, for @alter f k m@: -- -- If @k@ is a member of @m@, @f (@'Just'@ oldValue)@ is called. Now: -- -- - If @f@ returned 'Just'@ newValue@, @oldValue@ is replaced with @newValue@. -- -- - If @f@ returned 'Nothing', @k@ and @oldValue@ are removed from the map. -- -- If, instead, @k@ is not a member of @m@, @f @'Nothing' is called, and: -- -- - If @f@ returned 'Just'@ value@, @value@ is inserted into the map, at @k@. -- -- - If @f@ returned 'Nothing', the map is unchanged. -- -- The function is applied lazily only if the given key is a prefix of another -- key in the map. alter :: Map map k => (Maybe a -> Maybe a) -> [k] -> TrieMap map k a -> TrieMap map k a alter = Base.alter -- | @O(min(m,s))@. Like 'alter', but the function is always applied strictly. alter' :: Map map k => (Maybe a -> Maybe a) -> [k] -> TrieMap map k a -> TrieMap map k a alter' = Base.alter' -- * Querying -- | @O(1)@. 'True' iff the map is empty. null :: Map map k => TrieMap map k a -> Bool null = Base.null -- | @O(n m)@. The number of elements in the map. The value is built up lazily, -- allowing for delivery of partial results without traversing the whole map. size :: (Map map k, Num n) => TrieMap map k a -> n size = Base.size -- | @O(n m)@. The number of elements in the map. The value is built strictly: -- no value is returned until the map has been fully traversed. size' :: (Map map k, Num n) => TrieMap map k a -> n size' = Base.size' -- | @O(min(m,s))@. 'True' iff the given key is associated with a value in the -- map. member :: Map map k => [k] -> TrieMap map k a -> Bool member = Base.member -- | @O(min(m,s))@. 'False' iff the given key is associated with a value in the -- map. notMember :: Map map k => [k] -> TrieMap map k a -> Bool notMember = Base.notMember -- | @O(min(m,s))@. 'Just' the value in the map associated with the given key, -- or 'Nothing' if the key is not a member of the map. lookup :: Map map k => [k] -> TrieMap map k a -> Maybe a lookup = Base.lookup -- | @O(min(m,s))@. Like 'lookup', but returns the given value when the key is -- not a member of the map. lookupWithDefault :: Map map k => a -> [k] -> TrieMap map k a -> a lookupWithDefault = Base.lookupWithDefault -- | @O(min(n1 m1,n2 m2))@. 'True' iff the first map is a submap of the second, -- i.e. all keys that are members of the first map are also members of the -- second map, and their associated values are the same. -- -- > isSubmapOf = isSubmapOfBy (==) isSubmapOf :: (Map map k, Eq a) => TrieMap map k a -> TrieMap map k a -> Bool isSubmapOf = isSubmapOfBy (==) -- | @O(min(n1 m1,n2 m2))@. Like 'isSubmapOf', but one can specify the equality -- relation applied to the values. -- -- 'True' iff all keys that are members of the first map are also members of -- the second map, and the given function @f@ returns 'True' for all @f -- firstMapValue secondMapValue@ where @firstMapValue@ and @secondMapValue@ are -- associated with the same key. isSubmapOfBy :: Map map k => (a -> b -> Bool) -> TrieMap map k a -> TrieMap map k b -> Bool isSubmapOfBy = Base.isSubmapOfBy -- | @O(min(n1 m1,n2 m2))@. 'True' iff the first map is a proper submap of the -- second, i.e. all keys that are members of the first map are also members of -- the second map, and their associated values are the same, but the maps are -- not equal. That is, at least one key was a member of the second map but not -- the first. -- -- > isProperSubmapOf = isProperSubmapOfBy (==) isProperSubmapOf :: (Map map k, Eq a) => TrieMap map k a -> TrieMap map k a -> Bool isProperSubmapOf = isProperSubmapOfBy (==) -- | @O(min(n1 m1,n2 m2))@. Like 'isProperSubmapOf', but one can specify the -- equality relation applied to the values. -- -- 'True' iff all keys that are members of the first map are also members of -- the second map, and the given function @f@ returns 'True' for all @f -- firstMapValue secondMapValue@ where @firstMapValue@ and @secondMapValue@ are -- associated with the same key, and at least one key in the second map is not -- a member of the first. isProperSubmapOfBy :: Map map k => (a -> b -> Bool) -> TrieMap map k a -> TrieMap map k b -> Bool isProperSubmapOfBy = Base.isProperSubmapOfBy -- * Combination defaultUnion :: a -> a -> a defaultUnion = const -- | @O(min(n1 m1,n2 m2))@. The union of the two maps: the map which contains -- all keys that are members of either map. This union is left-biased: if a key -- is a member of both maps, the value from the first map is chosen. -- -- The worst-case performance occurs when the two maps are identical. -- -- > union = unionWith const union :: Map map k => TrieMap map k a -> TrieMap map k a -> TrieMap map k a union = unionWith defaultUnion -- | @O(min(n1 m1,n2 m2))@. Like 'union', but the combining function ('const') is -- applied strictly. -- -- > union' = unionWith' const union' :: Map map k => TrieMap map k a -> TrieMap map k a -> TrieMap map k a union' = unionWith' defaultUnion -- | @O(min(n1 m1,n2 m2))@. Like 'union', but the given function is used to -- determine the new value if a key is a member of both given maps. For a -- function @f@, the new value is @f firstMapValue secondMapValue@. unionWith :: Map map k => (a -> a -> a) -> TrieMap map k a -> TrieMap map k a -> TrieMap map k a unionWith = Base.unionWith -- | @O(min(n1 m1,n2 m2))@. Like 'unionWith', but the combining function is -- applied strictly. unionWith' :: Map map k => (a -> a -> a) -> TrieMap map k a -> TrieMap map k a -> TrieMap map k a unionWith' = Base.unionWith' -- | @O(min(n1 m1,n2 m2))@. Like 'unionWith', but in addition to the two -- values, the key is passed to the combining function. unionWithKey :: Map map k => ([k] -> a -> a -> a) -> TrieMap map k a -> TrieMap map k a -> TrieMap map k a unionWithKey = Base.unionWithKey -- | @O(min(n1 m1,n2 m2))@. Like 'unionWithKey', but the combining function is -- applied strictly. unionWithKey' :: Map map k => ([k] -> a -> a -> a) -> TrieMap map k a -> TrieMap map k a -> TrieMap map k a unionWithKey' = Base.unionWithKey' -- | @O(sum(n))@. The union of all the maps: the map which contains all keys -- that are members of any of the maps. If a key is a member of multiple maps, -- the value that occurs in the earliest of the maps (according to the order of -- the given list) is chosen. -- -- The worst-case performance occurs when all the maps are identical. -- -- > unions = unionsWith const unions :: Map map k => [TrieMap map k a] -> TrieMap map k a unions = unionsWith defaultUnion -- | @O(sum(n))@. Like 'unions', but the combining function ('const') is -- applied strictly. -- -- > unions' = unionsWith' const unions' :: Map map k => [TrieMap map k a] -> TrieMap map k a unions' = unionsWith' defaultUnion -- | @O(sum(n))@. Like 'unions', but the given function determines the final -- value if a key is a member of more than one map. The function is applied as -- a left fold over the values in the given list's order. For example: -- -- > unionsWith (-) [fromList [("a",1)],fromList [("a",2)],fromList [("a",3)]] -- > == fromList [("a",(1-2)-3)] -- > == fromList [("a",-4)] unionsWith :: Map map k => (a -> a -> a) -> [TrieMap map k a] -> TrieMap map k a unionsWith = Base.unionsWith -- | @O(sum(n))@. Like 'unionsWith', but the combining function is applied -- strictly. unionsWith' :: Map map k => (a -> a -> a) -> [TrieMap map k a] -> TrieMap map k a unionsWith' = Base.unionsWith' -- | @O(sum(n))@. Like 'unionsWith', but in addition to the two values under -- consideration, the key is passed to the combining function. unionsWithKey :: Map map k => ([k] -> a -> a -> a) -> [TrieMap map k a] -> TrieMap map k a unionsWithKey = Base.unionsWithKey -- | @O(sum(n))@. Like 'unionsWithKey', but the combining function is applied -- strictly. unionsWithKey' :: Map map k => ([k] -> a -> a -> a) -> [TrieMap map k a] -> TrieMap map k a unionsWithKey' = Base.unionsWithKey' -- | @O(min(n1 m1,n2 m2))@. The difference of the two maps: the map which -- contains all keys that are members of the first map and not of the second. -- -- The worst-case performance occurs when the two maps are identical. -- -- > difference = differenceWith (\_ _ -> Nothing) difference :: Map map k => TrieMap map k a -> TrieMap map k b -> TrieMap map k a difference = differenceWith (\_ _ -> Nothing) -- | @O(min(n1 m1,n2 m2))@. Like 'difference', but the given function -- determines what to do when a key is a member of both maps. If the function -- returns 'Nothing', the key is removed; if it returns 'Just' a new value, -- that value replaces the old one in the first map. differenceWith :: Map map k => (a -> b -> Maybe a) -> TrieMap map k a -> TrieMap map k b -> TrieMap map k a differenceWith = Base.differenceWith -- | @O(min(n1 m1,n2 m2))@. Like 'differenceWith', but in addition to the two -- values, the key they are associated with is passed to the combining -- function. differenceWithKey :: Map map k => ([k] -> a -> b -> Maybe a) -> TrieMap map k a -> TrieMap map k b -> TrieMap map k a differenceWithKey = Base.differenceWithKey -- | @O(min(n1 m1,n2 m2))@. The intersection of the two maps: the map which -- contains all keys that are members of both maps. -- -- The worst-case performance occurs when the two maps are identical. -- -- > intersection = intersectionWith const intersection :: Map map k => TrieMap map k a -> TrieMap map k b -> TrieMap map k a intersection = intersectionWith const -- | @O(min(n1 m1,n2 m2))@. Like 'intersection', but the combining function is -- applied strictly. -- -- > intersection' = intersectionWith' const intersection' :: Map map k => TrieMap map k a -> TrieMap map k b -> TrieMap map k a intersection' = intersectionWith' const -- | @O(min(n1 m1,n2 m2))@. Like 'intersection', but the given function -- determines the new values. intersectionWith :: Map map k => (a -> b -> c) -> TrieMap map k a -> TrieMap map k b -> TrieMap map k c intersectionWith = Base.intersectionWith -- | @O(min(n1 m1,n2 m2))@. Like 'intersectionWith', but the combining function -- is applied strictly. intersectionWith' :: Map map k => (a -> b -> c) -> TrieMap map k a -> TrieMap map k b -> TrieMap map k c intersectionWith' = Base.intersectionWith' -- | @O(min(n1 m1,n2 m2))@. Like 'intersectionWith', but in addition to the two -- values, the key they are associated with is passed to the combining -- function. intersectionWithKey :: Map map k => ([k] -> a -> b -> c) -> TrieMap map k a -> TrieMap map k b -> TrieMap map k c intersectionWithKey = Base.intersectionWithKey -- | @O(min(n1 m1,n2 m2))@. Like 'intersectionWithKey', but the combining -- function is applied strictly. intersectionWithKey' :: Map map k => ([k] -> a -> b -> c) -> TrieMap map k a -> TrieMap map k b -> TrieMap map k c intersectionWithKey' = Base.intersectionWithKey' -- * Filtering -- | @O(n m)@. Apply the given function to the elements in the map, discarding -- those for which the function returns 'False'. filter :: Map map k => (a -> Bool) -> TrieMap map k a -> TrieMap map k a filter = filterWithKey . const -- | @O(n m)@. Like 'filter', but the key associated with the element is also -- passed to the given predicate. filterWithKey :: Map map k => ([k] -> a -> Bool) -> TrieMap map k a -> TrieMap map k a filterWithKey = Base.filterWithKey -- | @O(n m)@. A pair of maps: the first element contains those values for -- which the given predicate returns 'True', and the second contains those for -- which it was 'False'. partition :: Map map k => (a -> Bool) -> TrieMap map k a -> (TrieMap map k a, TrieMap map k a) partition = partitionWithKey . const -- | @O(n m)@. Like 'partition', but the key associated with the element is -- also passed to the given predicate. partitionWithKey :: Map map k => ([k] -> a -> Bool) -> TrieMap map k a -> (TrieMap map k a, TrieMap map k a) partitionWithKey = Base.partitionWithKey -- | @O(n m)@. Apply the given function to the elements in the map, preserving -- only the 'Just' results. mapMaybe :: Map map k => (a -> Maybe b) -> TrieMap map k a -> TrieMap map k b mapMaybe = mapMaybeWithKey . const -- | @O(n m)@. Like 'mapMaybe', but the key associated with the element is also -- passed to the given function. mapMaybeWithKey :: Map map k => ([k] -> a -> Maybe b) -> TrieMap map k a -> TrieMap map k b mapMaybeWithKey f = fromList . Maybe.mapMaybe (\(k,v) -> fmap ((,) k) (f k v)) . toList -- | @O(n m)@. Apply the given function to the elements in the map, separating -- the 'Left' results from the 'Right'. The first element of the pair contains -- the former results, and the second the latter. mapEither :: Map map k => (a -> Either b c) -> TrieMap map k a -> (TrieMap map k b, TrieMap map k c) mapEither = mapEitherWithKey . const -- | @O(n m)@. Like 'mapEither', but the key associated with the element is -- also passed to the given function. mapEitherWithKey :: Map map k => ([k] -> a -> Either b c) -> TrieMap map k a -> (TrieMap map k b, TrieMap map k c) mapEitherWithKey f = (fromList *** fromList) . partitionEithers . Prelude.map (\(k,v) -> either (Left . (,) k) (Right . (,) k) (f k v)) . toList -- * Mapping -- | @O(n m)@. Apply the given function to all the elements in the map. map :: Map map k => (a -> b) -> TrieMap map k a -> TrieMap map k b map = genericMap fmap -- | @O(n m)@. Like 'map', but apply the function strictly. map' :: Map map k => (a -> b) -> TrieMap map k a -> TrieMap map k b map' = genericMap fmap' genericMap :: Map map k => ((a -> b) -> Maybe a -> Maybe b) -> (a -> b) -> TrieMap map k a -> TrieMap map k b genericMap myFmap f (Tr v m) = Tr (myFmap f v) (Map.map (genericMap myFmap f) m) -- | @O(n m)@. Like 'map', but also pass the key associated with the element to -- the given function. mapWithKey :: Map map k => ([k] -> a -> b) -> TrieMap map k a -> TrieMap map k b mapWithKey = genericMapWithKey fmap -- | @O(n m)@. Like 'mapWithKey', but apply the function strictly. mapWithKey' :: Map map k => ([k] -> a -> b) -> TrieMap map k a -> TrieMap map k b mapWithKey' = genericMapWithKey fmap' genericMapWithKey :: Map map k => ((a -> b) -> Maybe a -> Maybe b) -> ([k] -> a -> b) -> TrieMap map k a -> TrieMap map k b genericMapWithKey = go DL.empty where go k myFmap f (Tr v m) = Tr (myFmap (f $ DL.toList k) v) (Map.mapWithKey (\x -> go (k `DL.snoc` x) myFmap f) m) -- | @O(n m)@. Apply the given function to all the keys in a map. -- -- > mapKeys = mapKeysWith const mapKeys :: (Map map k1, Map map k2) => ([k1] -> [k2]) -> TrieMap map k1 a -> TrieMap map k2 a mapKeys = mapKeysWith const -- | @O(n m)@. Like 'mapKeys', but use the first given function to combine -- elements if the second function gives two keys the same value. mapKeysWith :: (Map map k1, Map map k2) => (a -> a -> a) -> ([k1] -> [k2]) -> TrieMap map k1 a -> TrieMap map k2 a mapKeysWith = Base.mapKeysWith . fromListWith -- | @O(n m)@. Apply the given function to the contents of all the keys in the -- map. -- -- > mapInKeys = mapInKeysWith const mapInKeys :: (Map map k1, Map map k2) => (k1 -> k2) -> TrieMap map k1 a -> TrieMap map k2 a mapInKeys = mapInKeysWith defaultUnion -- | @O(n m)@. Like 'mapInKeys', but combine identical keys strictly. -- -- > mapInKeys' = mapInKeysWith' const mapInKeys' :: (Map map k1, Map map k2) => (k1 -> k2) -> TrieMap map k1 a -> TrieMap map k2 a mapInKeys' = mapInKeysWith' defaultUnion -- | @O(n m)@. Like 'mapInKeys', but use the first given function to combine -- elements if the second function gives two keys the same value. mapInKeysWith :: (Map map k1, Map map k2) => (a -> a -> a) -> (k1 -> k2) -> TrieMap map k1 a -> TrieMap map k2 a mapInKeysWith = Base.mapInKeysWith -- | @O(n m)@. Like 'mapInKeysWith', but apply the combining function strictly. mapInKeysWith' :: (Map map k1, Map map k2) => (a -> a -> a) -> (k1 -> k2) -> TrieMap map k1 a -> TrieMap map k2 a mapInKeysWith' = Base.mapInKeysWith' -- | @O(n m)@. Like "Data.List".@mapAccumL@ on the 'toList' representation. -- -- Essentially a combination of 'map' and 'foldl': the given -- function is applied to each element of the map, resulting in a new value for -- the accumulator and a replacement element for the map. mapAccum :: Map map k => (acc -> a -> (acc, b)) -> acc -> TrieMap map k a -> (acc, TrieMap map k b) mapAccum = genericMapAccum Map.mapAccum (flip const) -- | @O(n m)@. Like 'mapAccum', but the function is applied strictly. mapAccum' :: Map map k => (acc -> a -> (acc, b)) -> acc -> TrieMap map k a -> (acc, TrieMap map k b) mapAccum' = genericMapAccum Map.mapAccum seq -- | @O(n m)@. Like 'mapAccum', but the function receives the key in addition -- to the value associated with it. mapAccumWithKey :: Map map k => (acc -> [k] -> a -> (acc, b)) -> acc -> TrieMap map k a -> (acc, TrieMap map k b) mapAccumWithKey = genericMapAccumWithKey Map.mapAccumWithKey (flip const) -- | @O(n m)@. Like 'mapAccumWithKey', but the function is applied strictly. mapAccumWithKey' :: Map map k => (acc -> [k] -> a -> (acc, b)) -> acc -> TrieMap map k a -> (acc, TrieMap map k b) mapAccumWithKey' = genericMapAccumWithKey Map.mapAccumWithKey seq -- | @O(n m)@. Like 'mapAccum', but in ascending order, as though operating on -- the 'toAscList' representation. mapAccumAsc :: OrdMap map k => (acc -> a -> (acc, b)) -> acc -> TrieMap map k a -> (acc, TrieMap map k b) mapAccumAsc = genericMapAccum Map.mapAccumAsc (flip const) -- | @O(n m)@. Like 'mapAccumAsc', but the function is applied strictly. mapAccumAsc' :: OrdMap map k => (acc -> a -> (acc, b)) -> acc -> TrieMap map k a -> (acc, TrieMap map k b) mapAccumAsc' = genericMapAccum Map.mapAccumAsc seq -- | @O(n m)@. Like 'mapAccumAsc', but the function receives the key in -- addition to the value associated with it. mapAccumAscWithKey :: OrdMap map k => (acc -> [k] -> a -> (acc, b)) -> acc -> TrieMap map k a -> (acc, TrieMap map k b) mapAccumAscWithKey = genericMapAccumWithKey Map.mapAccumAscWithKey (flip const) -- | @O(n m)@. Like 'mapAccumAscWithKey', but the function is applied strictly. mapAccumAscWithKey' :: OrdMap map k => (acc -> [k] -> a -> (acc, b)) -> acc -> TrieMap map k a -> (acc, TrieMap map k b) mapAccumAscWithKey' = genericMapAccumWithKey Map.mapAccumAscWithKey seq -- | @O(n m)@. Like 'mapAccum', but in descending order, as though operating on -- the 'toDescList' representation. mapAccumDesc :: OrdMap map k => (acc -> a -> (acc, b)) -> acc -> TrieMap map k a -> (acc, TrieMap map k b) mapAccumDesc = genericMapAccum Map.mapAccumDesc (flip const) -- | @O(n m)@. Like 'mapAccumDesc', but the function is applied strictly. mapAccumDesc' :: OrdMap map k => (acc -> a -> (acc, b)) -> acc -> TrieMap map k a -> (acc, TrieMap map k b) mapAccumDesc' = genericMapAccum Map.mapAccumDesc seq -- | @O(n m)@. Like 'mapAccumDesc', but the function receives the key in -- addition to the value associated with it. mapAccumDescWithKey :: OrdMap map k => (acc -> [k] -> a -> (acc, b)) -> acc -> TrieMap map k a -> (acc, TrieMap map k b) mapAccumDescWithKey = genericMapAccumWithKey Map.mapAccumDescWithKey (flip const) -- | @O(n m)@. Like 'mapAccumDescWithKey', but the function is applied -- strictly. mapAccumDescWithKey' :: OrdMap map k => (acc -> [k] -> a -> (acc, b)) -> acc -> TrieMap map k a -> (acc, TrieMap map k b) mapAccumDescWithKey' = genericMapAccumWithKey Map.mapAccumDescWithKey seq genericMapAccum :: Map map k => ( (acc -> TrieMap map k a -> (acc, TrieMap map k b)) -> acc -> CMap map k a -> (acc, CMap map k b) ) -> (b -> (acc, Maybe b) -> (acc, Maybe b)) -> (acc -> a -> (acc, b)) -> acc -> TrieMap map k a -> (acc, TrieMap map k b) genericMapAccum subMapAccum seeq f acc (Tr mv m) = let (acc', mv') = case mv of Nothing -> (acc, Nothing) Just v -> let (acc'', v') = f acc v in v' `seeq` (acc'', Just v') in second (Tr mv') $ subMapAccum (genericMapAccum subMapAccum seeq f) acc' m genericMapAccumWithKey :: Map map k => ( ( acc -> k -> TrieMap map k a -> (acc, TrieMap map k b) ) -> acc -> CMap map k a -> (acc, CMap map k b) ) -> (b -> (acc, Maybe b) -> (acc, Maybe b)) -> (acc -> [k] -> a -> (acc, b)) -> acc -> TrieMap map k a -> (acc, TrieMap map k b) genericMapAccumWithKey = go DL.empty where go k subMapAccum seeq f acc (Tr mv m) = let (acc', mv') = case mv of Nothing -> (acc, Nothing) Just v -> let (acc'', v') = f acc (DL.toList k) v in v' `seeq` (acc'', Just v') in second (Tr mv') $ subMapAccum (\a x -> go (k `DL.snoc` x) subMapAccum seeq f a) acc' m -- * Folding -- | @O(n m)@. Equivalent to a list @foldr@ on the 'toList' representation, -- folding only over the elements. foldr :: Map map k => (a -> b -> b) -> b -> TrieMap map k a -> b foldr = foldrWithKey . const -- | @O(n m)@. Equivalent to a list @foldr@ on the 'toList' representation, -- folding over both the keys and the elements. foldrWithKey :: Map map k => ([k] -> a -> b -> b) -> b -> TrieMap map k a -> b foldrWithKey = Base.foldrWithKey -- | @O(n m)@. Equivalent to a list @foldr@ on the 'toAscList' representation. foldrAsc :: OrdMap map k => (a -> b -> b) -> b -> TrieMap map k a -> b foldrAsc = foldrAscWithKey . const -- | @O(n m)@. Equivalent to a list @foldr@ on the 'toAscList' representation, -- folding over both the keys and the elements. foldrAscWithKey :: OrdMap map k => ([k] -> a -> b -> b) -> b -> TrieMap map k a -> b foldrAscWithKey = Base.foldrAscWithKey -- | @O(n m)@. Equivalent to a list @foldr@ on the 'toDescList' representation. foldrDesc :: OrdMap map k => (a -> b -> b) -> b -> TrieMap map k a -> b foldrDesc = foldrDescWithKey . const -- | @O(n m)@. Equivalent to a list @foldr@ on the 'toDescList' representation, -- folding over both the keys and the elements. foldrDescWithKey :: OrdMap map k => ([k] -> a -> b -> b) -> b -> TrieMap map k a -> b foldrDescWithKey = Base.foldrDescWithKey -- | @O(n m)@. Equivalent to a list @foldl@ on the toList representation. foldl :: Map map k => (a -> b -> b) -> b -> TrieMap map k a -> b foldl = foldlWithKey . const -- | @O(n m)@. Equivalent to a list @foldl@ on the toList representation, -- folding over both the keys and the elements. foldlWithKey :: Map map k => ([k] -> a -> b -> b) -> b -> TrieMap map k a -> b foldlWithKey = Base.foldlWithKey -- | @O(n m)@. Equivalent to a list @foldl@ on the toAscList representation. foldlAsc :: OrdMap map k => (a -> b -> b) -> b -> TrieMap map k a -> b foldlAsc = foldlAscWithKey . const -- | @O(n m)@. Equivalent to a list @foldl@ on the toAscList representation, -- folding over both the keys and the elements. foldlAscWithKey :: OrdMap map k => ([k] -> a -> b -> b) -> b -> TrieMap map k a -> b foldlAscWithKey = Base.foldlAscWithKey -- | @O(n m)@. Equivalent to a list @foldl@ on the toDescList representation. foldlDesc :: OrdMap map k => (a -> b -> b) -> b -> TrieMap map k a -> b foldlDesc = foldlDescWithKey . const -- | @O(n m)@. Equivalent to a list @foldl@ on the toDescList representation, -- folding over both the keys and the elements. foldlDescWithKey :: OrdMap map k => ([k] -> a -> b -> b) -> b -> TrieMap map k a -> b foldlDescWithKey = Base.foldlDescWithKey -- | @O(n m)@. Equivalent to a list @foldl'@ on the 'toList' representation. foldl' :: Map map k => (a -> b -> b) -> b -> TrieMap map k a -> b foldl' = foldlWithKey' . const -- | @O(n m)@. Equivalent to a list @foldl'@ on the 'toList' representation, -- folding over both the keys and the elements. foldlWithKey' :: Map map k => ([k] -> a -> b -> b) -> b -> TrieMap map k a -> b foldlWithKey' = Base.foldlWithKey' -- | @O(n m)@. Equivalent to a list @foldl'@ on the 'toAscList' representation. foldlAsc' :: OrdMap map k => (a -> b -> b) -> b -> TrieMap map k a -> b foldlAsc' = foldlAscWithKey' . const -- | @O(n m)@. Equivalent to a list @foldl'@ on the 'toAscList' representation, -- folding over both the keys and the elements. foldlAscWithKey' :: OrdMap map k => ([k] -> a -> b -> b) -> b -> TrieMap map k a -> b foldlAscWithKey' = Base.foldlAscWithKey' -- | @O(n m)@. Equivalent to a list @foldl'@ on the 'toDescList' -- representation. foldlDesc' :: OrdMap map k => (a -> b -> b) -> b -> TrieMap map k a -> b foldlDesc' = foldlDescWithKey' . const -- | @O(n m)@. Equivalent to a list @foldl'@ on the 'toDescList' -- representation, folding over both the keys and the elements. foldlDescWithKey' :: OrdMap map k => ([k] -> a -> b -> b) -> b -> TrieMap map k a -> b foldlDescWithKey' = Base.foldlDescWithKey' -- * Conversion between lists -- | @O(n m)@. Converts the map to a list of the key-value pairs contained -- within, in undefined order. toList :: Map map k => TrieMap map k a -> [([k],a)] toList = Base.toList -- | @O(n m)@. Converts the map to a list of the key-value pairs contained -- within, in ascending order. toAscList :: OrdMap map k => TrieMap map k a -> [([k],a)] toAscList = Base.toAscList -- | @O(n m)@. Converts the map to a list of the key-value pairs contained -- within, in descending order. toDescList :: OrdMap map k => TrieMap map k a -> [([k],a)] toDescList = Base.toDescList -- | @O(n m)@. Creates a map from a list of key-value pairs. If a key occurs -- more than once, the value from the last pair (according to the list's order) -- is the one which ends up in the map. -- -- > fromList = fromListWith const fromList :: Map map k => [([k],a)] -> TrieMap map k a fromList = Base.fromList -- | @O(n m)@. Like 'fromList', but the given function is used to determine the -- final value if a key occurs more than once. The function is applied as -- though it were flipped and then applied as a left fold over the values in -- the given list's order. Or, equivalently (except as far as performance is -- concerned), as though the function were applied as a right fold over the -- values in the reverse of the given list's order. For example: -- -- > fromListWith (-) [("a",1),("a",2),("a",3),("a",4)] -- > == fromList [("a",4-(3-(2-1)))] -- > == fromList [("a",2)] fromListWith :: Map map k => (a -> a -> a) -> [([k],a)] -> TrieMap map k a fromListWith = Base.fromListWith -- | @O(n m)@. Like 'fromListWith', but the combining function is applied -- strictly. fromListWith' :: Map map k => (a -> a -> a) -> [([k],a)] -> TrieMap map k a fromListWith' = Base.fromListWith' -- | @O(n m)@. Like 'fromListWith', but the key, in addition to the values to -- be combined, is passed to the combining function. fromListWithKey :: Map map k => ([k] -> a -> a -> a) -> [([k],a)] -> TrieMap map k a fromListWithKey = Base.fromListWithKey -- | @O(n m)@. Like 'fromListWithKey', but the combining function is applied -- strictly. fromListWithKey' :: Map map k => ([k] -> a -> a -> a) -> [([k],a)] -> TrieMap map k a fromListWithKey' = Base.fromListWithKey' -- * Ordering ops -- | @O(m)@. Removes and returns the minimal key in the map, along with the -- value associated with it. If the map is empty, 'Nothing' and the original -- map are returned. minView :: OrdMap map k => TrieMap map k a -> (Maybe ([k], a), TrieMap map k a) minView = Base.minView -- | @O(m)@. Removes and returns the maximal key in the map, along with the -- value associated with it. If the map is empty, 'Nothing' and the original -- map are returned. maxView :: OrdMap map k => TrieMap map k a -> (Maybe ([k], a), TrieMap map k a) maxView = Base.maxView -- | @O(m)@. Like 'fst' composed with 'minView'. 'Just' the minimal key in the -- map and its associated value, or 'Nothing' if the map is empty. findMin :: OrdMap map k => TrieMap map k a -> Maybe ([k], a) findMin = Base.findMin -- | @O(m)@. Like 'fst' composed with 'maxView'. 'Just' the minimal key in the -- map and its associated value, or 'Nothing' if the map is empty. findMax :: OrdMap map k => TrieMap map k a -> Maybe ([k], a) findMax = Base.findMax -- | @O(m)@. Like 'snd' composed with 'minView'. The map without its minimal -- key, or the unchanged original map if it was empty. deleteMin :: OrdMap map k => TrieMap map k a -> TrieMap map k a deleteMin = Base.deleteMin -- | @O(m)@. Like 'snd' composed with 'maxView'. The map without its maximal -- key, or the unchanged original map if it was empty. deleteMax :: OrdMap map k => TrieMap map k a -> TrieMap map k a deleteMax = Base.deleteMax -- | @O(min(m,s))@. Splits the map in two about the given key. The first -- element of the resulting pair is a map containing the keys lesser than the -- given key; the second contains those keys that are greater. split :: OrdMap map k => [k] -> TrieMap map k a -> (TrieMap map k a, TrieMap map k a) split = Base.split -- | @O(min(m,s))@. Like 'split', but also returns the value associated with -- the given key, if any. splitLookup :: OrdMap map k => [k] -> TrieMap map k a -> (TrieMap map k a, Maybe a, TrieMap map k a) splitLookup = Base.splitLookup -- | @O(m)@. 'Just' the key of the map which precedes the given key in order, -- along with its associated value, or 'Nothing' if the map is empty. findPredecessor :: OrdMap map k => [k] -> TrieMap map k a -> Maybe ([k], a) findPredecessor = Base.findPredecessor -- | @O(m)@. 'Just' the key of the map which succeeds the given key in order, -- along with its associated value, or 'Nothing' if the map is empty. findSuccessor :: OrdMap map k => [k] -> TrieMap map k a -> Maybe ([k], a) findSuccessor = Base.findSuccessor -- * Trie-only operations -- | @O(s)@. Prepends the given key to all the keys of the map. For example: -- -- > addPrefix "xa" (fromList [("a",1),("b",2)]) -- > == fromList [("xaa",1),("xab",2)] addPrefix :: Map map k => [k] -> TrieMap map k a -> TrieMap map k a addPrefix = Base.addPrefix -- | @O(m)@. The map which contains all keys of which the given key is a -- prefix, with the prefix removed from each key. If the given key is not a -- prefix of any key in the map, the map is returned unchanged. For example: -- -- > deletePrefix "a" (fromList [("a",1),("ab",2),("ac",3)]) -- > == fromList [("",1),("b",2),("c",3)] -- -- This function can be used, for instance, to reduce potentially expensive I/O -- operations: if you need to find the value in a map associated with a string, -- but you only have a prefix of it and retrieving the rest is an expensive -- operation, calling 'deletePrefix' with what you have might allow you to -- avoid the operation: if the resulting map is empty, the entire string cannot -- be a member of the map. deletePrefix :: Map map k => [k] -> TrieMap map k a -> TrieMap map k a deletePrefix = Base.deletePrefix -- | @O(m)@. A triple containing the longest common prefix of all keys in the -- map, the value associated with that prefix, if any, and the map with that -- prefix removed from all the keys as well as the map itself. Examples: -- -- > splitPrefix (fromList [("a",1),("b",2)]) -- > == ("", Nothing, fromList [("a",1),("b",2)]) -- > splitPrefix (fromList [("a",1),("ab",2),("ac",3)]) -- > == ("a", Just 1, fromList [("b",2),("c",3)]) splitPrefix :: Map map k => TrieMap map k a -> ([k], Maybe a, TrieMap map k a) splitPrefix = Base.splitPrefix -- | @O(m)@. The children of the longest common prefix in the trie as maps, -- associated with their distinguishing key value. If the map contains less -- than two keys, this function will return the empty list. Examples; -- -- > children (fromList [("a",1),("abc",2),("abcd",3)]) -- > == [('b',fromList [("c",2),("cd",3)])] -- > children (fromList [("b",1),("c",2)]) -- > == [('b',fromList [("",1)]),('c',fromList [("",2)])] children :: Map map k => TrieMap map k a -> [(k, TrieMap map k a)] children = Base.children -- * Visualization -- | @O(n m)@. Displays the map's internal structure in an undefined way. That -- is to say, no program should depend on the function's results. showTrie :: (Show k, Show a, Map map k) => TrieMap map k a -> ShowS showTrie = Base.showTrieWith $ \mv -> case mv of Nothing -> showChar ' ' Just v -> showsPrec 11 v -- | @O(n m)@. Like 'showTrie', but uses the given function to display the -- elements of the map. Still undefined. showTrieWith :: (Show k, Map map k) => (Maybe a -> ShowS) -> TrieMap map k a -> ShowS showTrieWith = Base.showTrieWith