Day 12: Garden Groups

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FAQ

  • lwhjp@lemmy.sdf.org
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    3 days ago

    Haskell

    This was a bit of a fiddly one. There’s probably scope for golfing it down some more, but I’ve had enough for today :3

    Solution
    import Control.Arrow
    import Data.List
    import Data.Map (Map)
    import Data.Map qualified as Map
    import Data.Set (Set)
    import Data.Set qualified as Set
    
    readInput :: String -> Map (Int, Int) Char
    readInput s = Map.fromList [((i, j), c) | (i, l) <- zip [0 ..] (lines s), (j, c) <- zip [0 ..] l]
    
    (i1, j1) .+. (i2, j2) = (i1 + i2, j1 + j2)
    
    (i1, j1) .-. (i2, j2) = (i1 - i2, j1 - j2)
    
    directions = [(0, 1), (1, 0), (0, -1), (-1, 0)] :: [(Int, Int)]
    
    edges = zip ps (drop 1 ps) :: [((Int, Int), (Int, Int))]
      where
        ps = [(0, 1), (1, 1), (1, 0), (0, 0), (0, 1)]
    
    regions :: Map (Int, Int) Char -> [Set (Int, Int)]
    regions = unfoldr (fmap (uncurry removeRegion) . Map.minViewWithKey)
      where
        removeRegion (p, t) = go Set.empty (Set.singleton p)
          where
            go r ps plots
              | Set.null ps = (r, plots)
              | otherwise =
                  let ps' =
                        Set.filter (\p -> plots Map.!? p == Just t) $
                          Set.fromList (concatMap adjacent ps) Set.\\ ps
                   in go (Set.union r ps) ps' (Map.withoutKeys plots ps')
            adjacent = (`map` directions) . (.+.)
    
    boundary :: Set (Int, Int) -> Set ((Int, Int), (Int, Int))
    boundary region =
      Set.fromList $
        [ (p .+. e1, p .+. e2)
          | p <- Set.elems region,
            (d, (e1, e2)) <- zip directions edges,
            p .+. d `Set.notMember` region
        ]
    
    perimeter :: Set (Int, Int) -> [[(Int, Int)]]
    perimeter = unfoldr (fmap (uncurry removeChain) . Set.minView) . boundary
      where
        removeChain e@(e1, e2) es = first (e1 :) $ go [] e es
        go c e@(e1, e2) es =
          case find ((== e2) . fst) es of
            Nothing -> (e1 : c, es)
            Just e' -> go (e1 : c) e' (Set.delete e' es)
    
    countSides :: [(Int, Int)] -> Int
    countSides ps = length $ group $ zipWith (.-.) (drop 1 ps) ps
    
    main = do
      input <- readInput <$> readFile "input12"
      let rs = map (Set.size &&& perimeter) $ regions input
      print . sum $ map (\(a, p) -> a * sum (map (subtract 1 . length) p)) rs
      print . sum $ map (\(a, p) -> a * sum (map countSides p)) rs
    
    • VegOwOtenks@lemmy.world
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      3 days ago

      Thank you for showing the floodfill-algorithm using explored/open sets, mine was hellish inefficiently, reminds me of A*.