Zekt · July 19, 2022 15:03
diff --git a/FLOLAC-22-Tasks.hs b/FLOLAC-22-Tasks.hs
 -- This exercise covers the first 6 and the 8th chapters of "Learn You a Haskell for Great Good!"

 -- Chapter 1 - http://learnyouahaskell.com/introduction
 -- Chapter 2 - http://learnyouahaskell.com/starting-out
 -- Chapter 3 - http://learnyouahaskell.com/types-and-typeclasses
 -- Chapter 4 - http://learnyouahaskell.com/syntax-in-functions
 -- Chapter 5 - http://learnyouahaskell.com/recursion
 -- Chapter 6 - http://learnyouahaskell.com/higher-order-functions
 -- Chapter 8 - http://learnyouahaskell.com/making-our-own-types-and-typeclasses 

 -- Download this file and then type ":l FLOLAC-22-Tasks.hs" in GHCi to load this exercise
 -- Some of the definitions are left "undefined", you should replace them with your answers.

 -- 0. Example: find the penultimate (second-to-last) element in list xs
 penultimate xs = last (init xs)

 -- 1. Find the antepenultimate (third-to-last) element in list xs
 antepenultimate xs = undefined

 -- 2. Left shift list xs by 1
 --    For example, "shiftLeft [1, 2, 3]" should return "[2, 3, 1]"
 shiftLeft xs = undefined

 -- 3. Left shift list xs by n
 --    For example, "rotateLeft 2 [1, 2, 3]" should return "[3, 1, 2]"
 rotateLeft n xs = undefined

 -- 4. Insert element x in list xs at index k
 --    For example, "insertElem 100 3 [0,0,0,0,0]" should return [0,0,0,100,0,0]
 insertElem x k xs = undefined

 -- Here we have a type for the 7 days of the week
 -- Try typeclass functions like "show" or "maxBound" on them
 data Day = Mon | Tue | Wed | Thu | Fri | Sat | Sun
         deriving (Eq, Ord, Show, Bounded, Enum)   

 -- 5. Note that if you try "succ Sun", you should get an error, because "succ" is not defined on "Sun"
 --    Define "next", which is like "succ", but returns "Mon" on "next Sun"
 next :: Day -> Day
 next day = undefined

 -- 6. Return "True" on weekend
 isWeekend :: Day -> Bool
 isWeekend = undefined

 data Task = Work | Shop | Play deriving (Eq, Show)

 -- You are given a schedule, which is a list of pairs of Tasks and Days
 schedule :: [(Task, Day)]
 schedule = [(Shop, Fri), (Work, Tue), (Play, Mon), (Play, Fri)]

 -- 7. However, the schedule is a mess
 --    Sort the schedule by Day, and return only a list of Tasks. 
 --    If there are many Tasks in a Day, you should keep its original ordering
 --    For example, "sortTask schedule" should return "[(Play, Mon), (Work, Tue), (Shop, Fri), (Play, Fri)]"
 sortTask :: [(Task, Day)] -> [(Task, Day)]
 sortTask = undefined

 -- 8. This function converts days to names, like "show", but a bit fancier
 --    For example, "nameOfDay Mon" should return "Monday"
 nameOfDay :: Day -> String
 nameOfDay x = undefined

 -- 9. You shouldn't be working on the weekends
 --     Return "False" if the Task is "Work" and the Day is "Sat" or "Sun"
 labourCheck :: Task -> Day -> Bool
 labourCheck task day = undefined

 -- 10. Raise x to the power y using recursion
 --     For example, "power 3 4" should return "81"
 power :: Int -> Int -> Int
 power x y = undefined

 -- 11. Convert a list of booleans (big-endian) to a interger using recursion
 --     For example, "convertBinaryDigit [True, False, False]" should return 4
 convertBinaryDigit :: [Bool] -> Int
 convertBinaryDigit bits = undefined

 -- 12. Create a fibbonaci sequence of length N in reverse order
 --     For example, "fib 5" should return "[3, 2, 1, 1, 0]"
 fib :: Int -> [Int]
 fib n = undefined

 -- 13. Determine whether a given list is a palindrome
 --     For example, "palindrome []" or "palindrome [1, 3, 1]" should return "True"
 palindrome :: Eq a => [a] -> Bool
 palindrome xs = undefined

 -- 14. Map the first component of a pair with the given function
 --     For example, "mapFirst (+3) (4, True)" should return "(7, True)"
 mapFirst :: (a -> b) -> (a, c) -> (b, c)
 mapFirst f pair = undefined

 -- 15. Devise a function that has the following type
 someFunction :: (a -> b -> c) -> (a -> b) -> a -> c
 someFunction = undefined

 -- Here is an algebraic datatype representing trees.
 -- Be careful, these trees are somehow different from those defined in the book!
 -- Apparently our trees are better, they have leaves, and data is stored on leaves.
 data Tree a = Leaf a | Node (Tree a) (Tree a)

 -- 16. What is the map function as well as the Functor instance for this tree?
 --     (You may want to lookup the Functor typeclass.)
 instance Functor Tree where
  fmap = undefined

 -- We say a tree is flattenable if it can be turned into a list
 -- which contains all elements originally in the tree.
 data List a = Nil | Cons a (List a)

 -- We can define a typeclass to express that.
 class Flattenable t where
  flatten :: t a -> List a

 -- 17. Show that our Tree is flattenable:
 instance Flattenable Tree where
  flatten = undefined

 -- 18. Define a type of trees that have leaves and two kinds of nodes:
 --     one with two branches and another with three branches.
 --     Your tree should have three constructors.
 --     You can choose where to store data (either on leaves, nodes, or both).
 --
 --   data TwoThreeTree = ...

 -- 19. Show that the datatype you just defined is flattenable:
 --
 --   instance Flattenable TwoThreeTree where
 --     flatten = ...
	-- This exercise covers the first 6 and the 8th chapters of "Learn You a Haskell for Great Good!"

	-- Chapter 1 - http://learnyouahaskell.com/introduction
	-- Chapter 2 - http://learnyouahaskell.com/starting-out
	-- Chapter 3 - http://learnyouahaskell.com/types-and-typeclasses
	-- Chapter 4 - http://learnyouahaskell.com/syntax-in-functions
	-- Chapter 5 - http://learnyouahaskell.com/recursion
	-- Chapter 6 - http://learnyouahaskell.com/higher-order-functions
	-- Chapter 8 - http://learnyouahaskell.com/making-our-own-types-and-typeclasses

	-- Download this file and then type ":l FLOLAC-22-Tasks.hs" in GHCi to load this exercise
	-- Some of the definitions are left "undefined", you should replace them with your answers.

	-- 0. Example: find the penultimate (second-to-last) element in list xs
	penultimate xs = last (init xs)

	-- 1. Find the antepenultimate (third-to-last) element in list xs
	antepenultimate xs = undefined

	-- 2. Left shift list xs by 1
	-- For example, "shiftLeft [1, 2, 3]" should return "[2, 3, 1]"
	shiftLeft xs = undefined

	-- 3. Left shift list xs by n
	-- For example, "rotateLeft 2 [1, 2, 3]" should return "[3, 1, 2]"
	rotateLeft n xs = undefined

	-- 4. Insert element x in list xs at index k
	-- For example, "insertElem 100 3 [0,0,0,0,0]" should return [0,0,0,100,0,0]
	insertElem x k xs = undefined

	-- Here we have a type for the 7 days of the week
	-- Try typeclass functions like "show" or "maxBound" on them
	data Day = Mon \| Tue \| Wed \| Thu \| Fri \| Sat \| Sun
	deriving (Eq, Ord, Show, Bounded, Enum)

	-- 5. Note that if you try "succ Sun", you should get an error, because "succ" is not defined on "Sun"
	-- Define "next", which is like "succ", but returns "Mon" on "next Sun"
	next :: Day -> Day
	next day = undefined

	-- 6. Return "True" on weekend
	isWeekend :: Day -> Bool
	isWeekend = undefined

	data Task = Work \| Shop \| Play deriving (Eq, Show)

	-- You are given a schedule, which is a list of pairs of Tasks and Days
	schedule :: [(Task, Day)]
	schedule = [(Shop, Fri), (Work, Tue), (Play, Mon), (Play, Fri)]

	-- 7. However, the schedule is a mess
	-- Sort the schedule by Day, and return only a list of Tasks.
	-- If there are many Tasks in a Day, you should keep its original ordering
	-- For example, "sortTask schedule" should return "[(Play, Mon), (Work, Tue), (Shop, Fri), (Play, Fri)]"
	sortTask :: [(Task, Day)] -> [(Task, Day)]
	sortTask = undefined

	-- 8. This function converts days to names, like "show", but a bit fancier
	-- For example, "nameOfDay Mon" should return "Monday"
	nameOfDay :: Day -> String
	nameOfDay x = undefined

	-- 9. You shouldn't be working on the weekends
	-- Return "False" if the Task is "Work" and the Day is "Sat" or "Sun"
	labourCheck :: Task -> Day -> Bool
	labourCheck task day = undefined

	-- 10. Raise x to the power y using recursion
	-- For example, "power 3 4" should return "81"
	power :: Int -> Int -> Int
	power x y = undefined

	-- 11. Convert a list of booleans (big-endian) to a interger using recursion
	-- For example, "convertBinaryDigit [True, False, False]" should return 4
	convertBinaryDigit :: [Bool] -> Int
	convertBinaryDigit bits = undefined

	-- 12. Create a fibbonaci sequence of length N in reverse order
	-- For example, "fib 5" should return "[3, 2, 1, 1, 0]"
	fib :: Int -> [Int]
	fib n = undefined

	-- 13. Determine whether a given list is a palindrome
	-- For example, "palindrome []" or "palindrome [1, 3, 1]" should return "True"
	palindrome :: Eq a => [a] -> Bool
	palindrome xs = undefined

	-- 14. Map the first component of a pair with the given function
	-- For example, "mapFirst (+3) (4, True)" should return "(7, True)"
	mapFirst :: (a -> b) -> (a, c) -> (b, c)
	mapFirst f pair = undefined

	-- 15. Devise a function that has the following type
	someFunction :: (a -> b -> c) -> (a -> b) -> a -> c
	someFunction = undefined

	-- Here is an algebraic datatype representing trees.
	-- Be careful, these trees are somehow different from those defined in the book!
	-- Apparently our trees are better, they have leaves, and data is stored on leaves.
	data Tree a = Leaf a \| Node (Tree a) (Tree a)

	-- 16. What is the map function as well as the Functor instance for this tree?
	-- (You may want to lookup the Functor typeclass.)
	instance Functor Tree where
	fmap = undefined

	-- We say a tree is flattenable if it can be turned into a list
	-- which contains all elements originally in the tree.
	data List a = Nil \| Cons a (List a)

	-- We can define a typeclass to express that.
	class Flattenable t where
	flatten :: t a -> List a

	-- 17. Show that our Tree is flattenable:
	instance Flattenable Tree where
	flatten = undefined

	-- 18. Define a type of trees that have leaves and two kinds of nodes:
	-- one with two branches and another with three branches.
	-- Your tree should have three constructors.
	-- You can choose where to store data (either on leaves, nodes, or both).
	--
	-- data TwoThreeTree = ...

	-- 19. Show that the datatype you just defined is flattenable:
	--
	-- instance Flattenable TwoThreeTree where
	-- flatten = ...