yen3/p01.hs

## p01.hs
sol1 = takeWhile (<1000) $ filter (\x -> x `mod` 3 == 0 || x `mod` 5 == 0) [1..]
sol2 = takeWhile (<1000) [x| x<-[1..], x `mod` 3 ==0 || x `mod` 5 ==0]

## p01.py
print reduce(lambda y, x: y + [x] if x%3 == 0 or x% 5 == 0 else y, xrange(3, 1000), [])

## p01_just_3_5.py
def m35():
    n = [3, 5]
    while (len(n) <= 100):
        n.append(min(filter(lambda x: x>n[-1], reduce(lambda y, x: y + [x*3, x*5], n, []))))
    return n

n = m35()
print n

## p05.hs
import qualified Data.Map as Map

-- The answer for Problem 5
smallestMultiple :: Integer -> Integer
smallestMultiple n = Map.foldWithKey (\k v sm-> sm * (power k v)) 1 (numFactorMapList n)

numFactorMapList :: Integer -> Map.Map Integer Integer
numFactorMapList n = foldr mergeMap (Map.fromList []) (map numFactorMap [2..n])

mergeMap :: Map.Map Integer Integer -> Map.Map Integer Integer -> Map.Map Integer Integer
mergeMap = Map.unionWithKey (\k v1 v2-> if v1 > v2 then v1 else v2)

numFactorMap :: Integer -> Map.Map Integer Integer
numFactorMap = flip get_num_factor_map $ (Map.fromList [])


get_num_factor_map :: Integer -> Map.Map Integer Integer -> Map.Map Integer Integer
get_num_factor_map 0 m = m
get_num_factor_map 1 m = m
get_num_factor_map n m =
    if Map.member factor m then
        get_num_factor_map next_n (updateValue m)
    else
        get_num_factor_map next_n (insertValue m)
    where next_n = quot n factor
          factor = getFirstFactor n
          insertValue m = Map.insert factor 1 m
          updateValue m = snd $ Map.updateLookupWithKey (\k v-> if k == factor then Just (v+1) else Nothing) factor m

getFirstFactor :: Integer -> Integer
getFirstFactor = flip get_first_factor $ 2

get_first_factor :: Integer -> Integer -> Integer
get_first_factor 0 _ = 0
get_first_factor 1 _ = 1
get_first_factor 2 _ = 2
get_first_factor n p = if n `mod` p == 0 then p else get_first_factor n (p+1)

power _ 0 = 1
power 0 _ = 0
power x n  = let sqr k = k * k
                 half_n = n `div` 2
                 sqrHalfPower = sqr ( power x half_n )
             in if even n then sqrHalfPower else x * sqrHalfPower

## p13.hs
import Data.Char

sumNumStrList :: String -> String
sumNumStrList = numListToString . adjustDec . addNumList . getNumList

getNumList:: String -> [[Int]]
getNumList s = map getNumAsList $ lines s
    where getNumAsList = reverse . map (\x -> Data.Char.ord x - 48)

addNumList :: [[Int]] -> [Int]
addNumList = foldr1 (zipWith (+))

adjustDec :: [Int] -> [Int]
adjustDec = (flip adjustDec') 0

adjustDec' :: [Int] -> Int -> [Int]
adjustDec' [] carry_in =
    if carry_in > 10 then (carry_in `mod` 10) : (adjustDec' [] (carry_in `quot` 10))
    else carry_in : []
adjustDec' (x:xs) carry_in = ((x + carry_in) `mod` 10): (adjustDec' xs ((x + carry_in) `quot` 10))

numListToString :: [Int] -> String
numListToString nl = reverse $ map (\x -> Data.Char.chr (x+48)) nl


main :: IO()
main = do
    contents <- readFile "pe13.input"
    let result = sumNumStrList contents
    putStrLn result
	sol1 = takeWhile (<1000) $ filter (\x -> x `mod` 3 == 0 \|\| x `mod` 5 == 0) [1..]
	sol2 = takeWhile (<1000) [x\| x<-[1..], x `mod` 3 ==0 \|\| x `mod` 5 ==0]
	def m35():
	n = [3, 5]
	while (len(n) <= 100):
	n.append(min(filter(lambda x: x>n[-1], reduce(lambda y, x: y + [x3, x5], n, []))))
	return n

	n = m35()
	print n
	import qualified Data.Map as Map

	-- The answer for Problem 5
	smallestMultiple :: Integer -> Integer
	smallestMultiple n = Map.foldWithKey (\k v sm-> sm * (power k v)) 1 (numFactorMapList n)

	numFactorMapList :: Integer -> Map.Map Integer Integer
	numFactorMapList n = foldr mergeMap (Map.fromList []) (map numFactorMap [2..n])

	mergeMap :: Map.Map Integer Integer -> Map.Map Integer Integer -> Map.Map Integer Integer
	mergeMap = Map.unionWithKey (\k v1 v2-> if v1 > v2 then v1 else v2)

	numFactorMap :: Integer -> Map.Map Integer Integer
	numFactorMap = flip get_num_factor_map $ (Map.fromList [])


	get_num_factor_map :: Integer -> Map.Map Integer Integer -> Map.Map Integer Integer
	get_num_factor_map 0 m = m
	get_num_factor_map 1 m = m
	get_num_factor_map n m =
	if Map.member factor m then
	get_num_factor_map next_n (updateValue m)
	else
	get_num_factor_map next_n (insertValue m)
	where next_n = quot n factor
	factor = getFirstFactor n
	insertValue m = Map.insert factor 1 m
	updateValue m = snd $ Map.updateLookupWithKey (\k v-> if k == factor then Just (v+1) else Nothing) factor m

	getFirstFactor :: Integer -> Integer
	getFirstFactor = flip get_first_factor $ 2

	get_first_factor :: Integer -> Integer -> Integer
	get_first_factor 0 _ = 0
	get_first_factor 1 _ = 1
	get_first_factor 2 _ = 2
	get_first_factor n p = if n `mod` p == 0 then p else get_first_factor n (p+1)

	power _ 0 = 1
	power 0 _ = 0
	power x n = let sqr k = k * k
	half_n = n `div` 2
	sqrHalfPower = sqr ( power x half_n )
	in if even n then sqrHalfPower else x * sqrHalfPower
	import Data.Char

	sumNumStrList :: String -> String
	sumNumStrList = numListToString . adjustDec . addNumList . getNumList

	getNumList:: String -> [[Int]]
	getNumList s = map getNumAsList $ lines s
	where getNumAsList = reverse . map (\x -> Data.Char.ord x - 48)

	addNumList :: [[Int]] -> [Int]
	addNumList = foldr1 (zipWith (+))

	adjustDec :: [Int] -> [Int]
	adjustDec = (flip adjustDec') 0

	adjustDec' :: [Int] -> Int -> [Int]
	adjustDec' [] carry_in =
	if carry_in > 10 then (carry_in `mod` 10) : (adjustDec' [] (carry_in `quot` 10))
	else carry_in : []
	adjustDec' (x:xs) carry_in = ((x + carry_in) `mod` 10): (adjustDec' xs ((x + carry_in) `quot` 10))

	numListToString :: [Int] -> String
	numListToString nl = reverse $ map (\x -> Data.Char.chr (x+48)) nl


	main :: IO()
	main = do
	contents <- readFile "pe13.input"
	let result = sumNumStrList contents
	putStrLn result