chrisyco/BirdTree.hs

## BirdTree.hs
import Data.ByteString.Char8 ( ByteString )
import qualified Data.ByteString.Char8 as B

import Data.Char ( isSpace )
import Data.Functor ( (<$>) )
import Data.List ( intercalate, unfoldr )
import Data.Maybe ( fromJust )
import Data.Ratio ( (%) )

{-

A bird tree is an infinite binary tree, whose definition is as follows:

bird =         1/1

              /   \
             /     \
            /       \

     1/(bird+1)   (1/bird)+1

-}

------------------------------------------------------------------------
-- Entry point
------------------------------------------------------------------------

main :: IO ()
main = (run <$> B.readFile "bird.in") >>= B.writeFile "bird.out"
    where
        run = convey . contemplate . consume

consume :: ByteString -> [Rational]
consume = map (fst . fromJust . readRational . skipSpaces) . tail . B.lines

contemplate :: [Rational] -> [[Direction]]
contemplate = map findInTree

convey :: [[Direction]] -> ByteString
convey = B.unlines . map (B.pack . map directionToChar)

directionToChar :: Direction -> Char
directionToChar L = 'L'
directionToChar R = 'R'

readRational :: ByteString -> Maybe (Rational, ByteString)
readRational str = do
    (x, str'  ) <- B.readInteger str
    (_, str'' ) <- checkChar '/' str'
    (y, str''') <- B.readInteger str''
    return (x % y, str''')

skipSpaces :: ByteString -> ByteString
skipSpaces = B.filter (not . isSpace)

checkChar :: Char -> ByteString -> Maybe (Char, ByteString)
checkChar c str = do
    (x, xs) <- B.uncons str
    if x == c
        then Just (x, xs)
        else Nothing


------------------------------------------------------------------------
-- Main code
------------------------------------------------------------------------

birdTree :: Tree Rational
birdTree = Branch (1 % 1) --> fmap (\n -> 1 / (n + 1)) birdTree
                          --> fmap (\n -> (1 / n) + 1) birdTree
    where
        f --> x = f x

data Direction = L | R
    deriving (Enum, Eq, Ord, Show)

findInTree :: Rational -> [Direction]
findInTree = search birdTree False
    where
        search (Branch value left right) isOdd target
            | value == target = []
            | isOdd `xor` (target < value) = L : search left (not isOdd) target
            | otherwise                    = R : search right (not isOdd) target


------------------------------------------------------------------------
-- Data structures and utility functions
------------------------------------------------------------------------

-- | An infinite binary tree. Each node has an attached value and two
-- children.
data Tree v = Branch v (Tree v) (Tree v)

instance Functor Tree where
    fmap f (Branch value left right) = Branch (f value) (fmap f left) (fmap f right)

-- | Get a node's attached value.
rootValue :: Tree v -> v
rootValue (Branch value _left _right) = value

-- | Get the direct children of a node, as a two element list.
children :: Tree v -> [Tree v]
children (Branch _value left right) = [left, right]

-- | Get a list of nodes at each level of the tree.
levels :: Tree v -> [[Tree v]]
levels tree = iterate (concatMap children) [tree]

-- | Dump a human-readable representation of the tree, down to a
-- specified depth. Useful for debugging.
--
-- The depth should be greater than or equal to 0.
showTree :: Show v => Int -> Tree v -> String
showTree depth | depth < 0 = error "BirdTree.showTree: depth must be positive"
               | otherwise = showLevels . take depth . levels

showLevels :: Show v => [[Tree v]] -> String
showLevels = unlines . map (intercalate " | " . map (show . rootValue))

-- | Boolean XOR.
xor :: Bool -> Bool -> Bool
xor True False = True
xor False True = True
xor _ _ = False
	import Data.ByteString.Char8 ( ByteString )
	import qualified Data.ByteString.Char8 as B

	import Data.Char ( isSpace )
	import Data.Functor ( (<$>) )
	import Data.List ( intercalate, unfoldr )
	import Data.Maybe ( fromJust )
	import Data.Ratio ( (%) )

	{-

	A bird tree is an infinite binary tree, whose definition is as follows:

	bird = 1/1

	/ \
	/ \
	/ \

	1/(bird+1) (1/bird)+1

	-}

	------------------------------------------------------------------------
	-- Entry point
	------------------------------------------------------------------------

	main :: IO ()
	main = (run <$> B.readFile "bird.in") >>= B.writeFile "bird.out"
	where
	run = convey . contemplate . consume

	consume :: ByteString -> [Rational]
	consume = map (fst . fromJust . readRational . skipSpaces) . tail . B.lines

	contemplate :: [Rational] -> [[Direction]]
	contemplate = map findInTree

	convey :: [[Direction]] -> ByteString
	convey = B.unlines . map (B.pack . map directionToChar)

	directionToChar :: Direction -> Char
	directionToChar L = 'L'
	directionToChar R = 'R'

	readRational :: ByteString -> Maybe (Rational, ByteString)
	readRational str = do
	(x, str' ) <- B.readInteger str
	(_, str'' ) <- checkChar '/' str'
	(y, str''') <- B.readInteger str''
	return (x % y, str''')

	skipSpaces :: ByteString -> ByteString
	skipSpaces = B.filter (not . isSpace)

	checkChar :: Char -> ByteString -> Maybe (Char, ByteString)
	checkChar c str = do
	(x, xs) <- B.uncons str
	if x == c
	then Just (x, xs)
	else Nothing


	------------------------------------------------------------------------
	-- Main code
	------------------------------------------------------------------------

	birdTree :: Tree Rational
	birdTree = Branch (1 % 1) --> fmap (\n -> 1 / (n + 1)) birdTree
	--> fmap (\n -> (1 / n) + 1) birdTree
	where
	f --> x = f x

	data Direction = L \| R
	deriving (Enum, Eq, Ord, Show)

	findInTree :: Rational -> [Direction]
	findInTree = search birdTree False
	where
	search (Branch value left right) isOdd target
	\| value == target = []
	\| isOdd `xor` (target < value) = L : search left (not isOdd) target
	\| otherwise = R : search right (not isOdd) target


	------------------------------------------------------------------------
	-- Data structures and utility functions
	------------------------------------------------------------------------

	-- \| An infinite binary tree. Each node has an attached value and two
	-- children.
	data Tree v = Branch v (Tree v) (Tree v)

	instance Functor Tree where
	fmap f (Branch value left right) = Branch (f value) (fmap f left) (fmap f right)

	-- \| Get a node's attached value.
	rootValue :: Tree v -> v
	rootValue (Branch value _left _right) = value

	-- \| Get the direct children of a node, as a two element list.
	children :: Tree v -> [Tree v]
	children (Branch _value left right) = [left, right]

	-- \| Get a list of nodes at each level of the tree.
	levels :: Tree v -> [[Tree v]]
	levels tree = iterate (concatMap children) [tree]

	-- \| Dump a human-readable representation of the tree, down to a
	-- specified depth. Useful for debugging.
	--
	-- The depth should be greater than or equal to 0.
	showTree :: Show v => Int -> Tree v -> String
	showTree depth \| depth < 0 = error "BirdTree.showTree: depth must be positive"
	\| otherwise = showLevels . take depth . levels

	showLevels :: Show v => [[Tree v]] -> String
	showLevels = unlines . map (intercalate " \| " . map (show . rootValue))

	-- \| Boolean XOR.
	xor :: Bool -> Bool -> Bool
	xor True False = True
	xor False True = True
	xor _ _ = False