-- requires cabal install --lib megaparsec parser-combinators heap vector module Main (main) where import Control.Monad (void, when) import Data.Functor import qualified Data.Heap as H import qualified Data.List as L import qualified Data.Map as M import qualified Data.Vector as V import Data.Void (Void) import Text.Megaparsec import Text.Megaparsec.Char exampleExpectedOutput = 22 type Coord = (Int, Int) type Input = [Coord] type Parser = Parsec Void String parseNumber :: Parser Int parseNumber = read <$> some digitChar parseCoord :: Parser Coord parseCoord = (,) <$> parseNumber <* char ',' <*> parseNumber <* eol parseInput' :: Parser Input parseInput' = some parseCoord <* eof parseInput :: String -> IO Input parseInput filename = do input <- readFile filename case runParser parseInput' filename input of Left bundle -> error $ errorBundlePretty bundle Right input' -> return input' type Cost = Int data Position = Position Coord Cost deriving Show instance Ord Position where compare (Position _ c1) (Position _ c2) = c1 `compare` c2 instance Eq Position where (Position p1 _ ) == (Position p2 _ ) = p1 == p2 type Visited = M.Map Coord Cost type Maze = M.Map Coord () type Candidates = H.MinHeap Position compute :: Int -> Int -> Input -> Int compute size cutoff input = walk (M.singleton (0, 0) 0) $ H.singleton (Position (0, 0) 0) where walk :: Visited -> Candidates -> Int walk v h | x == size && y == size = c | otherwise = walk v' $ H.union h' $ H.fromList n where ([pos@(Position p@(x, y) c)], h') = H.splitAt 1 h n = nexts v pos v' = L.foldl' (\acc (Position a b) -> M.insert a b acc) v n nexts :: Visited -> Position -> [Position] nexts v (Position p c) = L.filter (valid v) . map (\p' -> Position p' (c+1)) $ candidates p valid :: Visited -> Position -> Bool valid v (Position p@(x, y) c) = x >= 0 && x <= size && y >= 0 && y <= size && not (M.member p maze) && case M.lookup p v of Just c' -> c < c' Nothing -> True candidates :: Coord -> [Coord] candidates (x, y) = [ (x-1, y), (x+1, y), (x, y-1), (x, y+1) ] maze = M.fromList $ zip (take cutoff input) (L.repeat ()) main :: IO () main = do example <- parseInput "example" let exampleOutput = compute 6 12 example when (exampleOutput /= exampleExpectedOutput) (error $ "example failed: got " ++ show exampleOutput ++ " instead of " ++ show exampleExpectedOutput) input <- parseInput "input" print $ compute 70 1024 input