import Data.Bits (xor)
import qualified Data.Map.Strict as M
import qualified Data.Graph as G
-
+import Control.Parallel.Strategies (parMap, rpar)
type CellMap = M.Map (Int, Int) Bool
puzzleKey = "xlqgujun"
part1 :: String -> Int
part1 key = sum rowCounts
- where binHashes = map binHash $ rowSpecs key
- rowCounts = map countSetBits binHashes
+ where rowCounts = parMap rpar countSetBits $ binHashes key
part2 :: String -> Int
part2 key = length $ cellEdges cells
- where binHashes = map binHash $ rowSpecs key
- cells = presentCells binHashes
+ where cells = presentCells $ binHashes key
+
+binHashes :: String -> [String]
+binHashes key = parMap rpar binHash $ rowSpecs key
+
binHash :: String -> String
binHash = binify . knotHash
presentCells :: [String] -> CellMap
-presentCells binHashes = M.fromList [((r, c), True) | r <- [0..127], c <- [0..127], (binHashes!!r)!!c == '1']
+presentCells bhs = M.fromList [((r, c), True) | r <- [0..127], c <- [0..127], (bhs!!r)!!c == '1']
adjacentCells :: CellMap -> (Int, Int) -> [(Int, Int)]
adjacentCells cells (r, c) = filter (\k -> M.member k cells) possibles
--- /dev/null
+import Data.List.Split (chunksOf)
+import Data.Char (ord)
+import Text.Printf (printf)
+import Data.Bits (xor)
+import qualified Data.Map.Strict as M
+import qualified Data.Graph as G
+-- import Control.Parallel.Strategies (parMap, rpar)
+type CellMap = M.Map (Int, Int) Bool
+
+puzzleKey = "xlqgujun"
+
+main :: IO ()
+main = do
+ print $ part1 puzzleKey
+ print $ part2 puzzleKey
+
+
+part1 :: String -> Int
+part1 key = sum rowCounts
+ where rowCounts = map countSetBits $ binHashes key
+
+
+part2 :: String -> Int
+part2 key = length $ cellEdges cells
+ where cells = presentCells $ binHashes key
+
+binHashes :: String -> [String]
+binHashes key = map binHash $ rowSpecs key
+
+
+binHash :: String -> String
+binHash = binify . knotHash
+
+numKey :: (Int, Int) -> Int
+numKey (r, c) = 128 * r + c
+
+
+presentCells :: [String] -> CellMap
+presentCells bhs = M.fromList [((r, c), True) | r <- [0..127], c <- [0..127], (bhs!!r)!!c == '1']
+
+adjacentCells :: CellMap -> (Int, Int) -> [(Int, Int)]
+adjacentCells cells (r, c) = filter (\k -> M.member k cells) possibles
+ where possibles = [(r, c - 1), (r, c + 1), (r - 1, c), (r + 1, c)]
+
+
+cellEdges :: CellMap -> [G.SCC (Int, Int)]
+cellEdges cells = G.stronglyConnComp [(k, numKey k, map numKey $ adjacentCells cells k) | k <- M.keys cells]
+
+rowSpecs :: String -> [String]
+rowSpecs key = map (((key ++ "-") ++) . show) ([0..127] :: [Integer])
+
+countSetBits :: String -> Int
+countSetBits = length . filter (== '1')
+
+
+
+knotHash :: String -> [Int]
+knotHash input = densify tied
+ where (tied, _, _) = foldl step ([0..255], 0, 0) hashTerms
+ hashTerms = mkHashTerms input
+
+step :: ([Int], Int, Int) -> Int -> ([Int], Int, Int)
+step (original, start, skip) len = (replaced, start', skip + 1)
+ where replaced = tie original start len
+ start' = (start + len + skip) `mod` (length original)
+
+tie :: [a] -> Int -> Int -> [a]
+tie original start len = replace original replacement start
+ where replacement = reverse $ extract original start len
+
+extract :: [a] -> Int -> Int -> [a]
+extract items from len = take len $ drop from $ items ++ items
+
+replace :: [a] -> [a] -> Int -> [a]
+replace original replacement from = take (length original) (start ++ replacement ++ remainder)
+ where excess = drop (length original - from) replacement
+ stub = drop (length excess) original
+ start = take from (excess ++ stub)
+ remainder = drop (length $ start ++ replacement) original
+
+
+mkHashTerms :: String -> [Int]
+mkHashTerms text = take (length chunk * 64) $ cycle chunk
+ where chunk = map ord text ++ [17, 31, 73, 47, 23]
+
+-- hexify :: [Int] -> String
+-- hexify = concatMap (printf "%02x")
+
+binify :: [Int] -> String
+binify = concatMap (printf "%08b")
+
+densify :: [Int] -> [Int]
+densify ns = codes
+ where chunks = chunksOf 16 ns
+ compress = foldl1 xor
+ codes = map compress chunks
projects / advent-of-code-17.git / commitdiff