module Algorithms.QuadTree.QuadTree (quadTree, quadTreeSquares, qtFoldl, qtFoldr, goQuad, findNeighbor, lookupByPath', getSquareByZipper, rootNode, quadTreeToRoseTree, lookupByNeighbors, Orient(North,East,West,South), Quad(NW,NE,SW,SE), QuadTree, Zipper) where import Algebra.VectorTypes import Algebra.Vector import Data.Foldable (foldlM) import Data.List (partition) import Data.Maybe (fromJust) import Data.Tree import Diagrams.TwoD.Types -- |The quad tree structure. data QuadTree a -- |An empty node. = TNil -- |A leaf containing some value. | TLeaf a -- |A node with four children. | TNode (QuadTree a) (QuadTree a) -- NW NE (QuadTree a) (QuadTree a) -- SW SE deriving (Show, Eq) -- |Represents a Quadrant in the 2D plane. data Quad = NW | NE | SW | SE deriving (Show) -- |A Crumb used for the QuadTree Zipper. data Crumb a = NWCrumb (QuadTree a) (QuadTree a) (QuadTree a) | NECrumb (QuadTree a) (QuadTree a) (QuadTree a) | SWCrumb (QuadTree a) (QuadTree a) (QuadTree a) | SECrumb (QuadTree a) (QuadTree a) (QuadTree a) deriving (Show, Eq) -- |A list of Crumbs. type Breadcrumbs a = [Crumb a] -- |Zipper for the QuadTree. type Zipper a = (QuadTree a, Breadcrumbs a) -- |Orientation. data Orient = North | South | East | West deriving (Show) -- |Get a sub-square of the current square, e.g. nw, ne, sw or se. nwSq, neSq, swSq, seSq :: Square -> Square nwSq ((xl, xu), (yl, yu)) = (,) (xl, (xl + xu) / 2) ((yl + yu) / 2, yu) neSq ((xl, xu), (yl, yu)) = (,) ((xl + xu) / 2, xu) ((yl + yu) / 2, yu) swSq ((xl, xu), (yl, yu)) = (,) (xl, (xl + xu) / 2) (yl, (yl + yu) / 2) seSq ((xl, xu), (yl, yu)) = (,) ((xl + xu) / 2, xu) (yl, (yl + yu) / 2) -- |Check whether the current Node is an nw, ne, sw or se child of it's -- parent. isNWchild, isNEchild, isSWchild, isSEchild :: Zipper a -> Bool isNWchild (_, NWCrumb {}:_) = True isNWchild _ = False isNEchild (_, NECrumb {}:_) = True isNEchild _ = False isSWchild (_, SWCrumb {}:_) = True isSWchild _ = False isSEchild (_, SECrumb {}:_) = True isSEchild _ = False -- |Builds a quadtree of a list of points which recursively divides up 2D -- space into quadrants, so that every leaf-quadrant stores either zero or one -- point. quadTree :: [PT] -- ^ the points to divide -> Square -- ^ the initial square around the points -> QuadTree PT -- ^ the quad tree quadTree [] _ = TNil quadTree [pt] _ = TLeaf pt quadTree pts sq = TNode (quadTree nWPT . nwSq $ sq) (quadTree nEPT . neSq $ sq) (quadTree sWPT . swSq $ sq) (quadTree sEPT . seSq $ sq) where -- this sets the priority in case a point is between multiple quads (sWPT, sWO) = flip partition pts . inRange . swSq $ sq (nWPT, nWO) = flip partition sWO . inRange . nwSq $ sq (nEPT, nEO) = flip partition nWO . inRange . neSq $ sq sEPT = flip filter nEO . inRange . seSq $ sq -- |Get all squares of a quad tree. quadTreeSquares :: Square -- ^ the initial square around the points -> QuadTree PT -- ^ the quad tree -> [Square] -- ^ all squares of the quad tree quadTreeSquares sq (TNil) = [sq] quadTreeSquares sq (TLeaf _) = [sq] quadTreeSquares sq (TNode nw ne sw se) = quadTreeSquares (nwSq sq) nw ++ quadTreeSquares (neSq sq) ne ++ quadTreeSquares (swSq sq) sw ++ quadTreeSquares (seSq sq) se -- |Get the current square of the zipper, relative to the given top -- square. getSquareByZipper :: Square -> Zipper a -> Square getSquareByZipper sq z = go sq (reverse . snd $ z) where go sq' [] = sq' go sq' (NWCrumb {}:zs) = go (nwSq sq') zs go sq' (NECrumb {}:zs) = go (neSq sq') zs go sq' (SWCrumb {}:zs) = go (swSq sq') zs go sq' (SECrumb {}:zs) = go (seSq sq') zs -- |Left fold over the tree. qtFoldl :: (a -> QuadTree b -> a) -> a -> QuadTree b -> a qtFoldl f sv qt@(TNode nw ne sw se) = foldl (qtFoldl f) (f sv qt) [nw, ne, sw, se] qtFoldl f sv qt = f sv qt -- |Right fold over the tree. qtFoldr :: (QuadTree b -> a -> a) -> a -> QuadTree b -> a qtFoldr f sv qt = qtFoldl (\g b x -> g (f b x)) id qt sv -- |Go to nw, ne, sw or se from the current node, one level deeper. goNW, goNE, goSW, goSE :: Zipper a -> Maybe (Zipper a) goNW (TNode nw ne sw se, bs) = Just (nw, NWCrumb ne sw se:bs) goNW _ = Nothing goNE (TNode nw ne sw se, bs) = Just (ne, NECrumb nw sw se:bs) goNE _ = Nothing goSW (TNode nw ne sw se, bs) = Just (sw, SWCrumb nw ne se:bs) goSW _ = Nothing goSE (TNode nw ne sw se, bs) = Just (se, SECrumb nw ne sw:bs) goSE _ = Nothing -- |Go to the given Quad from the current Node, one level deeper. goQuad :: Quad -> Zipper a -> Maybe (Zipper a) goQuad q = case q of NW -> goNW NE -> goNE SW -> goSW SE -> goSE -- |Go up to the parent node, if any. goUp :: Zipper a -> Maybe (Zipper a) goUp (qt, NWCrumb ne sw se:bs) = Just (TNode qt ne sw se, bs) goUp (qt, NECrumb nw sw se:bs) = Just (TNode nw qt sw se, bs) goUp (qt, SWCrumb nw ne se:bs) = Just (TNode nw ne qt se, bs) goUp (qt, SECrumb nw ne sw:bs) = Just (TNode nw ne sw qt, bs) goUp _ = Nothing -- |Get the root node. rootNode :: Zipper a -> Zipper a rootNode (qt, []) = (qt, []) rootNode z = rootNode . fromJust . goUp $ z -- |Look up a node by a given path of Quads. lookupByPath' :: [Quad] -> QuadTree a -> Maybe (Zipper a) lookupByPath' qs qt = foldlM (flip goQuad) (qt, []) qs -- |Find the north, south, east or west neighbor of a given node. findNeighbor :: Orient -> Zipper a -> Maybe (Zipper a) findNeighbor ot zr = case ot of North -> go isSWchild isSEchild isNWchild goNW goNE goSW goSE zr South -> go isNWchild isNEchild isSWchild goSW goSE goNW goNE zr East -> go isNWchild isSWchild isNEchild goNE goSE goNW goSW zr West -> go isNEchild isSEchild isNWchild goNW goSW goNE goSE zr where go _ _ _ _ _ _ _ (_, []) = Nothing go is1 is2 is3 go1 go2 go3 go4 z@(_, _:_) | is1 z = goUp z >>= go1 | is2 z = goUp z >>= go2 | otherwise = checkParent . go is1 is2 is3 go1 go2 go3 go4 . fromJust . goUp $ z where checkParent (Just (z'@(TNode {}, _))) | is3 z = go3 z' | otherwise = go4 z' checkParent (Just z') = Just z' checkParent _ = Nothing lookupByNeighbors :: [Orient] -> Zipper a -> Maybe (Zipper a) lookupByNeighbors = flip (foldlM (flip findNeighbor)) quadTreeToRoseTree :: Zipper PT -> Tree String quadTreeToRoseTree z' = go (rootNode z') where go z = case z of (TNil, _) -> Node markAndPrintOrigin [] (TLeaf a, _) -> Node (markAndPrintOrigin ++ "\n" ++ (show . unp2 $ a)) [] _ -> Node markAndPrintOrigin [go (fromJust . goNW $ z) , go (fromJust . goNE $ z) , go (fromJust . goSW $ z) , go (fromJust . goSE $ z)] where markAndPrintOrigin | z' == z = "* " ++ printOrigin | otherwise = printOrigin printOrigin | isNWchild z = "NW" | isNEchild z = "NE" | isSWchild z = "SW" | isSEchild z = "SE" | otherwise = "root"