{-# LANGUAGE TemplateHaskell #-}
module Data.Geometry.SegmentTree.Generic( NodeData(..), splitPoint, range, assoc
, LeafData(..), atomicRange, leafAssoc
, SegmentTree(..), unSegmentTree
, Assoc(..)
, createTree, fromIntervals
, insert, delete
, search, stab
, I(..), fromIntervals'
, Count(..)
) where
import Control.DeepSeq
import Control.Lens
import Data.BinaryTree
import Data.Geometry.Interval
import Data.Geometry.IntervalTree (IntervalLike(..))
import Data.Geometry.Properties
import qualified Data.List as List
import Data.List.NonEmpty (NonEmpty)
import qualified Data.List.NonEmpty as NonEmpty
import GHC.Generics (Generic)
data NodeData v r = NodeData { _splitPoint :: !(EndPoint r)
, _range :: !(Range r)
, _assoc :: !v
} deriving (Show,Eq,Functor,Generic)
makeLenses ''NodeData
instance (NFData v, NFData r) => NFData (NodeData v r)
data AtomicRange r = Singleton !r | AtomicRange deriving (Show,Eq,Functor,Generic)
instance NFData r => NFData (AtomicRange r)
data LeafData v r = LeafData { _atomicRange :: !(AtomicRange r)
, _leafAssoc :: !v
} deriving (Show,Eq,Functor,Generic)
makeLenses ''LeafData
instance (NFData v, NFData r) => NFData (LeafData v r)
newtype SegmentTree v r =
SegmentTree { _unSegmentTree :: BinLeafTree (NodeData v r) (LeafData v r) }
deriving (Show,Eq,Generic,NFData)
makeLenses ''SegmentTree
data BuildLeaf a = LeafSingleton a | LeafRange a a deriving (Show,Eq)
createTree :: NonEmpty r -> v -> SegmentTree v r
createTree pts v = SegmentTree . fmap h . foldUpData f g . fmap _unElem
. asBalancedBinLeafTree $ ranges
where
h (LeafSingleton r) = LeafData (Singleton r) v
h (LeafRange _ _) = LeafData AtomicRange v
f l _ r = let m = l^.range.upper
ll = l^.range.lower
rr = r^.range.upper
in NodeData m (Range ll rr) v
g (LeafSingleton r) = NodeData (Closed r) (ClosedRange r r) v
g (LeafRange s r) = NodeData (Open r) (OpenRange s r) v
ranges = interleave (fmap LeafSingleton pts) ranges'
ranges' = zipWith LeafRange (NonEmpty.toList pts) (NonEmpty.tail pts)
interleave :: NonEmpty a -> [a] -> NonEmpty a
interleave (x NonEmpty.:| xs) ys = x NonEmpty.:| concat (zipWith (\a b -> [a,b]) ys xs)
fromIntervals :: (Ord r, Eq p, Assoc v i, IntervalLike i, Monoid v, NumType i ~ r)
=> (Interval p r -> i)
-> NonEmpty (Interval p r) -> SegmentTree v r
fromIntervals f is = foldr (insert . f) (createTree pts mempty) is
where
endPoints (toRange -> Range' a b) = [a,b]
pts = nub' . NonEmpty.sort . NonEmpty.fromList . concatMap endPoints $ is
nub' = fmap NonEmpty.head . NonEmpty.group1
toList :: SegmentTree v r -> [i]
toList = undefined
search :: (Ord r, Monoid v) => r -> SegmentTree v r -> v
search x = mconcat . stab x
inAtomicRange :: Eq r => r -> AtomicRange r -> Bool
x `inAtomicRange` (Singleton r) = x == r
_ `inAtomicRange` AtomicRange = True
stab :: Ord r => r -> SegmentTree v r -> [v]
stab x (SegmentTree t) = stabRoot t
where
stabRoot (Leaf (LeafData rr v))
| x `inAtomicRange` rr = [v]
| otherwise = []
stabRoot (Node l (NodeData m rr v) r) = case (x `inRange` rr, Closed x <= m) of
(False,_) -> []
(True,True) -> v : stab' l
_ -> v : stab' r
stab' (Leaf (LeafData rr v)) | x `inAtomicRange` rr = [v]
| otherwise = []
stab' (Node l (NodeData m _ v) r) | Closed x <= m = v : stab' l
| otherwise = v : stab' r
class Measured v i => Assoc v i where
insertAssoc :: i -> v -> v
deleteAssoc :: i -> v -> v
getRange :: BinLeafTree (NodeData v r) (LeafData t r) -> Maybe (Range r)
getRange (Leaf (LeafData (Singleton r) _)) = Just $ Range (Closed r) (Closed r)
getRange (Leaf _) = Nothing
getRange (Node _ nd _) = Just $ nd^.range
coversAtomic :: Ord r
=> Range r -> Range r -> AtomicRange r -> Bool
coversAtomic ri _ (Singleton r) = r `inRange` ri
coversAtomic ri inR AtomicRange = ri `covers` inR
insert :: (Assoc v i, NumType i ~ r, Ord r, IntervalLike i)
=> i -> SegmentTree v r -> SegmentTree v r
insert i (SegmentTree t) = SegmentTree $ insertRoot t
where
ri@(Range a b) = toRange i
insertRoot t' = maybe t' (flip insert' t') $ getRange t'
insert' inR lf@(Leaf nd@(LeafData rr _))
| coversAtomic ri inR rr = Leaf $ nd&leafAssoc %~ insertAssoc i
| otherwise = lf
insert' (Range c d) (Node l nd@(NodeData m rr _) r)
| ri `covers` rr = Node l (nd&assoc %~ insertAssoc i) r
| otherwise = Node l' nd r'
where
l' = if a <= m then insert' (Range c m) l else l
r' = if m < b then insert' (Range (toOpen m) d) r else r
toOpen = Open . view unEndPoint
delete :: (Assoc v i, NumType i ~ r, Ord r, IntervalLike i)
=> i -> SegmentTree v r -> SegmentTree v r
delete i (SegmentTree t) = SegmentTree $ delete' t
where
(Range a b) = toRange i
delete' (Leaf ld) = Leaf $ ld&leafAssoc %~ deleteAssoc i
delete' (Node l nd@(_splitPoint -> m) r)
| b <= m = Node (delete' l) (nd&assoc %~ deleteAssoc i) r
| otherwise = Node l (nd&assoc %~ deleteAssoc i) (delete' r)
newtype I a = I { _unI :: a} deriving (Show,Read,Eq,Ord,Generic,NFData)
type instance NumType (I a) = NumType a
instance Measured [I a] (I a) where
measure = (:[])
instance Eq a => Assoc [I a] (I a) where
insertAssoc = (:)
deleteAssoc = List.delete
instance IntervalLike a => IntervalLike (I a) where
toRange = toRange . _unI
fromIntervals' :: (Eq p, Ord r)
=> NonEmpty (Interval p r) -> SegmentTree [I (Interval p r)] r
fromIntervals' = fromIntervals I
newtype Count = Count { getCount :: Word }
deriving (Show,Eq,Ord,Num,Integral,Enum,Real,Generic,NFData)
newtype C a = C { _unC :: a} deriving (Show,Read,Eq,Ord,Generic,NFData)
instance Semigroup Count where
a <> b = Count $ getCount a + getCount b
instance Monoid Count where
mempty = 0
mappend = (<>)
instance Measured Count (C i) where
measure _ = 1
instance Assoc Count (C i) where
insertAssoc _ v = v + 1
deleteAssoc _ v = v - 1