152 lines
5.2 KiB
Haskell
152 lines
5.2 KiB
Haskell
module Algorithms.PolygonIntersection.Core where
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import Algebra.Vector
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import Algebra.VectorTypes
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import Control.Applicative
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import Data.Dequeue (BankersDequeue)
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import qualified Data.Dequeue as Q
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import Data.List
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import Data.Maybe
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import Diagrams.TwoD.Types
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import MyPrelude
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import QueueEx
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-- TODO: probably use a zipper.
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-- |Describes a point on the convex hull of the polygon.
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-- In addition to the point itself, both it's predecessor and
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-- successor are saved for convenience.
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data PolyPT =
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PolyA {
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id' :: PT
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, pre :: PT
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, suc :: PT
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}
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| PolyB {
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id' :: PT
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, pre :: PT
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, suc :: PT
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}
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deriving (Show, Eq)
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isPolyA :: PolyPT -> Bool
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isPolyA PolyA {} = True
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isPolyA _ = False
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isPolyB :: PolyPT -> Bool
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isPolyB = not . isPolyA
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-- |Shift a list of sorted convex hull points of a polygon so that
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-- the first element in the list is the one with the highest y-coordinate.
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-- This is done in O(n).
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sortLexPoly :: [PT] -> [PT]
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sortLexPoly ps = maybe [] (`shiftM` ps) (elemIndex (yMax ps) ps)
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where
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yMax = foldl1 (\x y -> if ptCmpY x y == GT then x else y)
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-- |Make a PolyPT list out of a regular list of points, so
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-- the predecessor and successors are all saved.
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mkPolyPTList :: (PT -> PT -> PT -> PolyPT) -- ^ PolyA or PolyB function
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-> [PT] -- ^ polygon points
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-> [PolyPT]
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mkPolyPTList f' pts@(x':y':_:_) =
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f' x' (last pts) y' : go f' pts
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where
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go f (x:y:z:xs) = f y x z : go f (y:z:xs)
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go f [x, y] = [f y x x']
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go _ _ = []
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mkPolyPTList _ _ = []
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-- |Sort the points of two polygons according to their y-coordinates,
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-- while saving the origin of that point. This is done in O(n).
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sortLexPolys :: ([PT], [PT]) -> [PolyPT]
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sortLexPolys (pA'@(_:_), pB'@(_:_)) =
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queueToList $ go (Q.fromList . mkPolyPTList PolyA . sortLexPoly $ pA')
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(Q.fromList . mkPolyPTList PolyB . sortLexPoly $ pB')
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where
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-- Start recursive algorithm, each polygon is represented by a Queue.
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-- Traverse predecessor and successor and insert them in the right
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-- order into the resulting queue.
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-- We start at the max y-coordinates of both polygons.
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go :: BankersDequeue PolyPT -- polyA
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-> BankersDequeue PolyPT -- polyB
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-> BankersDequeue PolyPT -- sorted queue
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go pA pB
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-- Nothing to sort.
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| Q.null pA && Q.null pB = Q.empty
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-- Current point of polygon A is higher on the y-axis than the
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-- current point of polygon B, so insert it into the resulting
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-- queue and traverse the rest.
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| ptCmpY (fromMaybe negInfPT (id' <$> Q.first pA))
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(fromMaybe negInfPT (id' <$> Q.first pB)) == GT
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= Q.pushFront (go (maybeShift . snd . Q.popFront $ pA) pB)
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(fromJust . Q.first $ pA)
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-- Same as above, except that the current point of polygon B
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-- is higher.
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| otherwise = Q.pushFront (go pA (maybeShift . snd . Q.popFront $ pB))
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(fromJust . Q.first $ pB)
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-- Compare the first and the last element of the queue according
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-- to their y-coordinate and shift the queue (if necessary) so that
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-- the element with the highest value is at the front.
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maybeShift :: BankersDequeue PolyPT -> BankersDequeue PolyPT
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maybeShift q = if ptCmpY (fromMaybe posInfPT (id' <$> Q.first q))
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(fromMaybe negInfPT (id' <$> Q.last q)) == GT
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then q
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else shiftQueueRight q
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sortLexPolys _ = []
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-- |Get all points that intersect between both polygons. This is done
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-- in O(n).
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intersectionPoints :: [PolyPT] -> [PT]
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intersectionPoints xs' = rmdups . go $ xs'
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where
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go [] = []
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go xs = (++) (segIntersections . scanLine $ xs)
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(go (tail xs))
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-- Get the scan line or in other words the
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-- Segment pairs we are going to check for intersection.
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scanLine :: [PolyPT] -> ([Segment], [Segment])
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scanLine sp@(_:_) = (,) (getSegment isPolyA) (getSegment isPolyB)
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where
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getSegment f = fromMaybe []
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((\x -> [(id' x, suc x), (id' x, pre x)])
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<$> (listToMaybe . filter f $ sp))
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scanLine _ = ([], [])
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-- Gets the actual intersections between the segments of
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-- both polygons we currently examine. This is done in O(1)
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-- since we have max 4 segments.
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segIntersections :: ([Segment], [Segment]) -> [PT]
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segIntersections (a@(_:_), b@(_:_)) =
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catMaybes
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. fmap (\[x, y] -> intersectSeg' x y)
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$ combinations a b
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segIntersections _ = []
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-- Gets all unique(!) combinations of two arrays. Both arrays
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-- are max 2, so this is actually O(1) for this algorithm.
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combinations :: [a] -> [a] -> [[a]]
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combinations xs ys = concat . fmap (\y -> fmap (\x -> [y, x]) xs) $ ys
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testArr :: ([PT], [PT])
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testArr = ([p2 (200.0, 500.0),
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p2 (0.0, 200.0),
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p2 (200.0, 100.0),
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p2 (400.0, 300.0)],
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[p2 (350.0, 450.0),
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p2 (275.0, 225.0),
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p2 (350.0, 50.0),
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p2 (500.0, 0.0),
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p2 (450.0, 400.0)])
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