Day 14: Parabolic Reflector Dish

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  • LeixB@lemmy.world
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    1 year ago

    Haskell

    Managed to do part1 in one line using ByteString operations:

    import Control.Monad
    import qualified Data.ByteString.Char8 as BS
    
    part1 :: IO Int
    part1 =
      sum
        . ( BS.transpose . BS.split '\n'
              >=> fmap succ
              . BS.elemIndices 'O' . BS.reverse . BS.intercalate "#"
              . fmap (BS.reverse . BS.sort) . BS.split '#'
          )
        <$> BS.readFile "inp"
    

    Part 2

    {-# LANGUAGE NumericUnderscores #-}
    
    import qualified Data.ByteString.Char8 as BS
    import qualified Data.Map as M
    import Relude
    
    type Problem = [ByteString]
    
    -- We apply rotation so that north is to the right, this makes
    -- all computations easier since we can just sort the rows.
    parse :: ByteString -> Problem
    parse = rotate . BS.split '\n'
    
    count :: Problem -> [[Int]]
    count = fmap (fmap succ . BS.elemIndices 'O')
    
    rotate, move, rotMov, doCycle :: Problem -> Problem
    rotate = fmap BS.reverse . BS.transpose
    move = fmap (BS.intercalate "#" . fmap BS.sort . BS.split '#')
    rotMov = rotate . move
    doCycle = rotMov . rotMov . rotMov . rotMov
    
    doNcycles :: Int -> Problem -> Problem
    doNcycles n = foldl' (.) id (replicate n doCycle)
    
    findCycle :: Problem -> (Int, Int)
    findCycle = go 0 M.empty
      where
        go :: Int -> M.Map Problem Int -> Problem -> (Int, Int)
        go n m p =
          let p' = doCycle p
           in case M.lookup p' m of
                Just n' -> (n', n + 1)
                Nothing -> go (n + 1) (M.insert p' n m) p'
    
    part1, part2 :: ByteString -> Int
    part1 = sum . join . count . move . parse
    part2 input =
      let n = 1_000_000_000
          p = parse input
          (s, r) = findCycle p
          numRots = s + ((n - s) `mod` (r - s - 1))
       in sum . join . count $ doNcycles numRots p