####!!!Work in progress!!! ##Useful functions:
- ifM (from Control.Monad.Extra):
- liftA(n)/liftM(n):
- if'/ifThenElse (from Data.Bool.HT (package utilities-ht)):
- over (from Control.Lens):
- set (from Control.Lens):
- view (from Control.Lens):
I will present only some of my solutions. For more solutions have a look at the sources.
In some cases I decided to split up the one-line to make it more readable.
Problem 1: Find the last element of a list
--using ifM from Control.Monad.Extra
p01_6 :: [a] -> Maybe a
p01_6 = ifM null (const Nothing) (Just . last)
p01_8 :: [a] -> Maybe a
p01_8 = flip if' Nothing . null <*> Just .last
p01_10 :: [a] -> Maybe a
p01_10 = listToMaybe . reverse
--from the safe package
p01_11 :: [a] -> Maybe a
p01_11 = lastMayProblem 2: Find the last but one element of a list
--using (<*>) from Control.Applicative
p02_3A :: [a] -> Maybe a
p02_3A = flip if' Nothing . (< 2) . length <*> Just . last . init
--using liftA3 from Control.Applicatice
p02_4 :: [a] -> Maybe a
p02_4 = liftA3 ifThenElse ( (<=) 2 . length ) (Just . head . tail . reverse ) (const Nothing)
--using functions from the safe package
p02_10 :: [a] -> Maybe a
p02_10 = initMay >=> lastMayProblem 3: Return the nth element of a list
p03_4 :: [a] -> Int -> Maybe a
p03_4 = ( . subtract 1 ) . ap ( liftM2 (flip ( `if'` Nothing)) (Just . head) . ( . null) . (||) . (>) 0) . flip drop
p03_6 :: [a] -> Int -> Maybe a
p03_6 = (fmap snd . ) . ( . ((. fst) . (==))) . flip find . zip [1..]
p03_13 :: [a] -> Int -> Maybe a
p03_13 = (>=> lastMay ) . flip takeExactMayProblem 4: Return the length of a list
p04_7 :: [a] -> Int
p04_7 = sum . map (const 1)
--using fix from Control.Monad.Fix
p04_8 :: [a] -> Int
p04_8 = fix (ifM null (const 0) . ( . tail) . ((+1). ))
--using the list Monad
p04_9 :: [a] -> Int
p04_9 = sum . flip (>>) [1]Problem 5: Reverse a list
p05_2 :: [a] -> [a]
p05_2 = liftA3 ifThenElse null (const []) ( flip (flip (++) . take 1) =<< p05_2 . tail )
--using snoc from Data.List.Extra
p05_7 :: [a] -> [a]
p05_7 = foldr (flip snoc) []
p05_8 :: [a] -> [a]
p05_8 = foldl (flip (:)) []Problem 6: Check if a given list is a palindrom
--does redundant comparisons
p06_3 :: Eq a => [a] -> Bool
p06_3 = and . liftA2 (zipWith (==)) id reverse
p06_7 :: Eq a => [a] -> Bool
p06_7 = uncurry isPrefixOf . second reverse . ap (flip splitAt) (flip div 2 . length) Problem 7:
--using Prisms
data NestedList a = List [NestedList a] | Elem a
makePrisms ''NestedList
--recursive
p07_1 :: NestedList a -> [a]
p07_1 = ifM (is _Elem) ( (:[]) . fromJust . preview _Elem) (concatMap p07_1 . fromJust . preview _List)Problem 8:
p08_1 :: Eq a => [a] -> [a]
p08_1 = map head . group
p08_4 :: Eq a => [a] -> [a]
p08_4 = reverse . snd . until ( null . fst ) (liftA2 (,) ( join (dropWhile . (==) . head) . fst) (liftA2 (:) (head . fst) snd ) ) . (,[])Problem 9:
--trivial solution
p09_1 :: Eq a => [a] -> [[a]]
p09_1 = group
p09_3 :: Eq a => [a] -> [[a]]
p09_3 = reverse . snd . until ( null . fst ) nextStep . (,[])
where
nextStep :: Eq a => ([a],[[a]]) -> ([a],[[a]])
nextStep = liftA2 (,) (join (dropWhile . (==) . head) . fst) ( (flip (:) . snd) <*> join (takeWhile . (==) . head) . fst )Problem 10:
p10_1 :: Eq a => [a] -> [(Integer,a)]
p10_1 = map (liftA2 (,) genericLength head) . p09_1
--using arrows
p10_3 :: Eq a => [a] -> [(Int,a)]
p10_3 = map ( length &&& head ) . p09_3Problem 11:
data ListItem a = Multiple Integer a | Single a deriving Show
p11_1 :: Eq a => [a] -> [ListItem a]
p11_1 = map ( ifM ( (==1) . fst) ( Single . snd) (liftA2 Multiple fst snd) ) . p10_1Problem 12:
data MorS a = Multiple {nm::Int, val::a} | Single {val::a} deriving (Data,Typeable)
p12_1 :: Data a => [MorS a] -> [a]
p12_1 = concatMap (liftA3 ifThenElse ( (==) (toConstr (Single ())) . toConstr ) (replicate 1 . val) (liftA2 replicate nm val) )
data MorS2 a = Multiple2 Int a | Single2 a deriving (Data,Typeable)
p12_2 :: Data a => [MorS2 a] -> [a]
p12_2 = concatMap (liftA3 ifThenElse ( (==) (toConstr (Single2 ())) . toConstr ) ( flip (:) [] . fromJust . gmapQi 0 cast ) ( uncurry replicate . ((fromJust . gmapQi 0 cast) &&& (fromJust . gmapQi 1 cast)) ) )Problem 13:
p13_2 :: Eq a => [a] -> [ListItem a]
p13_2 = liftA2 (`if'` [] ) null (reverse . ( (:) . ifM ( (==1) . view _1) (Single . (^._2) ) ( Multiple . (^._1) <*> view _2) <*> view _4) . join ((until (null . view _3) nextStep . ) . (. tail) . (1,,,[]) . head))
where
nextStep :: Eq a => (Integer , a , [a], [ListItem a]) -> (Integer ,a , [a] , [ListItem a])
nextStep = ifM ( join (( . view _2 ) . (==) . head . view _3 )) ( over _3 tail . over _1 (+1) ) ( liftA3 (1,,,) (head . view _3) (tail . view _3 ) (liftA2 (:) (ifM ( (==1) . view _1) (Single . view _2) (liftA2 Multiple (^._1) (^._2)) ) (view _4) ) )Problem 14:
p14_1 :: [a] -> [a]
p14_1 = concatMap (replicate 2)
p14_4 :: [a] -> [a]
p14_4 =concat . fix ( ifM null (const []) . liftM2 (:) (replicate 2 . head) . ( . tail))Problem 15:
--the "&" is almost the same as "$" but with arguments flipped (but is precedece is one higher)
p15_1 :: [a] -> Int -> [a]
p15_1 = concatMap . replicate & flip
p15_2 :: [a] -> Int -> [a]
p15_2 = ( . (,[]) ) . flip ( ( (concat . snd) . ) . foldr ( ap ( (,) . fst ) . liftA2 (flip (:)) snd . ( . fst) . flip replicate ))Problem 16:
p16_4 :: [a] -> Int -> [a]
p16_4 = (map fst . ) . ap (filter . ( . snd) . (/=) ) . ( . (cycle . enumFromTo (1::Int) . max 1 )) . zipProblem 17:
p17_1 :: [a] -> Int -> ([a],[a])
p17_1 = flip splitAt
p17_2 :: [a] -> Int -> ([a],[a])
p17_2 = (liftA2 (,) . take) <*> drop & flipProblem 18:
p18_1 :: [a] -> Int -> Int -> [a]
p18_1 = ( . (subtract 1 . max 1)) . ap ( (. flip take) . flip ( . ) . subtract ) . flip dropProblem 19:
p19_1 :: [a] -> Int -> [a]
p19_1 = ( . ) . ( ( uncurry (++) .swap) . ) . flip splitAt <*> flip mod . lengthProblem 20:
--unsafe for index <= 0
p20 :: [a] -> Int -> (a , [a])
p20 = ( liftA2 (,) (last . fst) (liftA2 (++) (init . fst ) snd) . ) . flip splitAt
--using find,filter and zip, safe, does not change the list in case of invalid index
p20_2 :: [a] -> Int -> (Maybe a,[a])
p20_2 = ( . liftA2 (,) ( (fmap snd . ) . find . ( . fst) . (==)) ( (map snd . ) . filter . ( . fst) . (/=) ) ) . flip (uncurry (liftA2 (,))) . zip [1..]Problem 21:
p21_1 :: a -> [a] -> Int -> [a]
p21_1 = ( . ( (. subtract 1) . flip splitAt ) ) . (.) . liftA2 (++) fst . ( . snd) . (:)Problem 22:
--trivial soution, ignoring descending cases
p22_1 :: Integer -> Integer -> [Integer]
p22_1 = enumFromTo
--imporved version of p22_1 where descending cases are taken into account
p22_2 :: Int -> Int -> [Int]
p22_2 = ( liftA3 ifThenElse (uncurry (<)) (uncurry enumFromTo) (reverse . uncurry (flip enumFromTo)) . ) . (,)Problem 23:
-- If the index is too large or negative , Nothing is returned
p23_2 :: [a] -> Int -> IO (Maybe [a])
p23_2 = liftA2 (`if'` return Nothing) . liftA2 (||) (<0) . (<) . length <*> trueBranch
where
trueBranch = ((( flip fmap newStdGen . ) . ( . (take:: Int -> [a] -> [a]))) . ) . ( . (((Just .) . ) . (.) )) . flip (.) . flip ( . ) . (nub . ) . randomRs . (0,) . subtract 1 . length <*> map . (!!)Problem 24:
p24_2 :: Int -> Int -> IO (Maybe [Int])
p24_2 = liftM2 ( `if'` return Nothing) . (>) <*> ( . (randomRs . (1,))) . (flip fmap newStdGen .) . (.) . ( . nub) . (Just .) . takeProblem 25:
p25_1 :: [a] -> IO [a]
p25_1 = ( newStdGen <&> ) . ((view _2 . until condition nextStep) . ) . ap (,[],,) ( subtract 1 . length ) --first postition is the actual list , second is the new list ,
where --third contains the length and fourth will contain the "Gen"
condition = null . view _1
nextStep = over _3 (subtract 1) . join (( . snd) . set _4 . view (_1._2)). ( ap (liftA2 (++) . take) (drop. (+1)) . view (_1._1) >>= over (_2._1) ) . ( ((:) . liftA2 (!!) (view (_2._1) ) (view (_1._1))) >>= over (_2._2) ) . join ((,) . liftA2 (randomR . (0,)) (view _3) (view _4))Problem 26:
p26_2 :: Int -> [a] -> [[a]]
p26_2 = flip ( ap ( filter . ( . length) . (==) ) . ((map (map snd) . nubOn (map fst) . map (sortOn fst. nubOn fst)) . ) . flip replicateM . zip [1..])