module Data.SortedMap import Data.SortedMap.Dependent %hide Prelude.toList export record SortedMap k v where constructor M unM : SortedDMap k $ const v -- Helper function unDPair : (x : a ** const b x) -> (a, b) unDPair (k ** v) = (k, v) export empty : Ord k => SortedMap k v empty = M empty export lookup : k -> SortedMap k v -> Maybe v lookup k = map snd . lookup k . unM export insert : k -> v -> SortedMap k v -> SortedMap k v insert k v = M . insert k v . unM export singleton : Ord k => k -> v -> SortedMap k v singleton = M .: singleton export insertFrom : Foldable f => f (k, v) -> SortedMap k v -> SortedMap k v insertFrom = flip $ foldl $ flip $ uncurry insert export delete : k -> SortedMap k v -> SortedMap k v delete k = M . delete k . unM export fromList : Ord k => List (k, v) -> SortedMap k v fromList = flip insertFrom empty export toList : SortedMap k v -> List (k, v) toList = map unDPair . toList . unM ||| Gets the keys of the map. export keys : SortedMap k v -> List k keys = map fst . toList ||| Gets the values of the map. Could contain duplicates. export values : SortedMap k v -> List v values = map snd . toList export implementation Functor (SortedMap k) where map f = M . map f . unM export implementation Foldable (SortedMap k) where foldr f z = foldr f z . values foldl f z = foldl f z . values null = null . unM foldMap f = foldMap f . values export implementation Traversable (SortedMap k) where traverse f = map M . traverse f . unM ||| Merge two maps. When encountering duplicate keys, using a function to combine the values. ||| Uses the ordering of the first map given. export mergeWith : (v -> v -> v) -> SortedMap k v -> SortedMap k v -> SortedMap k v mergeWith f x y = insertFrom inserted x where inserted : List (k, v) inserted = do (k, v) <- toList y let v' = (maybe id f $ lookup k x) v pure (k, v') ||| Merge two maps using the Semigroup (and by extension, Monoid) operation. ||| Uses mergeWith internally, so the ordering of the left map is kept. export merge : Semigroup v => SortedMap k v -> SortedMap k v -> SortedMap k v merge = mergeWith (<+>) ||| Left-biased merge, also keeps the ordering specified by the left map. export mergeLeft : SortedMap k v -> SortedMap k v -> SortedMap k v mergeLeft = mergeWith const ||| looks up a key in map, returning the left and right closest values, so that ||| k1 <= k < k2. If at the end of the beginning and/or end of the sorted map, returns ||| nothing appropriately export lookupBetween : key -> SortedMap key val -> (Maybe (key,val), Maybe (key,val)) lookupBetween k = bimap (map unDPair) (map unDPair) . lookupBetween k . unM ||| Returns the leftmost (least) key and value export leftMost : SortedMap key val -> Maybe (key,val) leftMost = map unDPair . leftMost . unM ||| Returns the rightmost (greatest) key and value export rightMost : SortedMap key val -> Maybe (key,val) rightMost = map unDPair . rightMost . unM export (Show k, Show v) => Show (SortedMap k v) where show m = "fromList " ++ (show $ toList m) export (Eq k, Eq v) => Eq (SortedMap k v) where (==) = (==) `on` toList -- TODO: is this the right variant of merge to use for this? I think it is, but -- I could also see the advantages of using `mergeLeft`. The current approach is -- strictly more powerful I believe, because `mergeLeft` can be emulated with -- the `First` monoid. However, this does require more code to do the same -- thing. export Semigroup v => Semigroup (SortedMap k v) where (<+>) = merge ||| For `neutral <+> y`, y is rebuilt in `Ord k`, so this is not a "strict" Monoid. ||| However, semantically, it should be equal. export (Ord k, Semigroup v) => Monoid (SortedMap k v) where neutral = empty export %inline Cast (SortedDMap k (const v)) (SortedMap k v) where cast = M export %inline Cast (SortedMap k v) (SortedDMap k (const v)) where cast = unM