Day 12: Hot Springs

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  • LeixB@lemmy.world
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    11 months ago

    Haskell

    Abused ParserCombinators for the first part. For the second, I took quite a while to figure out dynamic programming in Haskell.

    Solution
    module Day12 where
    
    import Data.Array
    import Data.Char (isDigit)
    import Data.List ((!!))
    import Relude hiding (get, many)
    import Relude.Unsafe (read)
    import Text.ParserCombinators.ReadP
    
    type Spring = (String, [Int])
    
    type Problem = [Spring]
    
    parseStatus :: ReadP Char
    parseStatus = choice $ char <$> ".#?"
    
    parseSpring :: ReadP Spring
    parseSpring = do
      status <- many1 parseStatus <* char ' '
      listFailed <- (read <$> munch1 isDigit) `sepBy` char ','
      return (status, listFailed)
    
    parseProblem :: ReadP Problem
    parseProblem = parseSpring `sepBy` char '\n'
    
    parse :: ByteString -> Maybe Problem
    parse = fmap fst . viaNonEmpty last . readP_to_S parseProblem . decodeUtf8
    
    good :: ReadP ()
    good = choice [char '.', char '?'] $> ()
    
    bad :: ReadP ()
    bad = choice [char '#', char '?'] $> ()
    
    buildParser :: [Int] -> ReadP ()
    buildParser l = do
      _ <- many good
      sequenceA_ $ intersperse (many1 good) [count x bad | x <- l]
      _ <- many good <* eof
    
      return ()
    
    combinations :: Spring -> Int
    combinations (s, l) = length $ readP_to_S (buildParser l) s
    
    part1, part2 :: Problem -> Int
    part1 = sum . fmap combinations
    part2 = sum . fmap (combinations' . toSpring' . bimap (join . intersperse "?" . replicate 5) (join . replicate 5))
    
    run1, run2 :: FilePath -> IO Int
    run1 f = readFileBS f >>= maybe (fail "parse error") (return . part1) . parse
    run2 f = readFileBS f >>= maybe (fail "parse error") (return . part2) . parse
    
    data Status = Good | Bad | Unknown deriving (Eq, Show)
    
    type Spring' = ([Status], [Int])
    
    type Problem' = [Spring']
    
    toSpring' :: Spring -> Spring'
    toSpring' (s, l) = (fmap toStatus s, l)
      where
        toStatus :: Char -> Status
        toStatus '.' = Good
        toStatus '#' = Bad
        toStatus '?' = Unknown
        toStatus _ = error "impossible"
    
    isGood, isBad :: Status -> Bool
    isGood Bad = False
    isGood _ = True
    isBad Good = False
    isBad _ = True
    
    combinations' :: Spring' -> Int
    combinations' (s, l) = t ! (0, 0)
      where
        n = length s
        m = length l
    
        t = listArray ((0, 0), (n, m)) [f i j | i <- [0 .. n], j <- [0 .. m]]
    
        f :: Int -> Int -> Int
        f n' m'
          | n' >= n = if m' >= m then 1 else 0
          | v == Unknown = tGood + tBad
          | v == Good = tGood
          | v == Bad = tBad
          | otherwise = error "impossible"
          where
            v = s !! n'
            x = l !! m'
    
            ss = drop n' s
    
            (bads, rest) = splitAt x ss
            badsDelimited = maybe True isGood (viaNonEmpty head rest)
            off = if null rest then 0 else 1
    
            tGood = t ! (n' + 1, m')
    
            tBad =
              if m' + 1 <= m && length bads == x && all isBad bads && badsDelimited
                then t ! (n' + x + off, m' + 1)
                else 0