PFP Laboratory 4
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List comprehension
Using the list comprehension implement following functions:
- Create a function that generates a list of all odd numbers in given interval.
oddList :: Int -> Int -> [Int]
*Main> oddList 1 10
[1,3,5,7,9]
oddList :: Int -> Int -> [Int]
oddList a b = [ x |x<-[a..b], odd x]
- Create a function that removes all upper case letters from a string.
removeAllUpper :: String -> String
*Main> removeAllUpper "ABCabcABC"
"abc"
import Data.Char
removeAllUpper :: String -> String
removeAllUpper xs = [ x |x<-xs, not (isUpper x)]
- Create functions that computes union and intersection of two sets.
union :: Eq a => [a] -> [a] -> [a]
intersection :: Eq a => [a] -> [a] -> [a]
*Main> union [1..5] [3..10]
[1,2,3,4,5,6,7,8,9,10]
*Main> intersection [1..5] [3..10]
[3,4,5]
union :: Eq a => [a] -> [a] -> [a]
union xs ys = xs ++ [y| y<-ys, not (elem y xs)]
intersection :: Eq a => [a] -> [a] -> [a]
intersection xs ys = [y| y<-ys, elem y xs]
More complex functions
- Create a function that count the number of occurrences of all characters from a given string.
countThem :: String -> [(Char, Int)]
*Main>countThem "hello hello hello"
[('h',3),('e',3),('l',6),('o',3),(' ',2)]
unique :: String -> String
unique n = reverse(tmp n "") where
tmp [] store = store
tmp (x:xs) store | x `elem` store = tmp xs store
| otherwise = tmp xs (x:store)
unique' :: String -> String
unique' [] = []
unique' (x:xs) = x: unique' (filter (/=x)xs)
countThem :: String -> [(Char, Int)]
countThem xs = let u = unique xs
in [(x, length (filter (==x) xs)) |x<-u]
- Create a function that generates all combinations of given length from the characters from given string. You can assume, that all character are unique and the given length is not bigger then the length of this string.
combinations :: Int -> String -> [String]
*Main> combinations 3 "abcdef"
["abc","abd","abe",...]
combinations :: Int -> String -> [String]
combinations 1 xs = [[x]| x<-xs]
combinations n (x:xs) | n == length (x:xs) = [(x:xs)]
|otherwise = [[x] ++ y |y<-combinations (n-1) xs ]
++ (combinations n xs)
List of lists
Consider following type representing picture:
type Pic = [String]
If you want to print this picture you can use:
pp :: Pic -> IO ()
pp x = putStr (concat (map (++"\n") x))
Picture example:
pic :: Pic
pic = [ "....#....",
"...###...",
"..#.#.#..",
".#..#..#.",
"....#....",
"....#....",
"....#####"]
*Main> pp pic
....#....
...###...
..#.#.#..
.#..#..#.
....#....
....#....
....#####
Create functions that:
- Flips picture veriticaly and horizontally.
flipV :: Pic -> Pic
flipH :: Pic -> Pic
*Main> pp(flipV pic)
....#....
...###...
..#.#.#..
.#..#..#.
....#....
....#....
#####....
*Main> pp(flipH pic)
....#####
....#....
....#....
.#..#..#.
..#.#.#..
...###...
....#....
flipV :: Pic -> Pic
flipV = map reverse
flipV' :: Pic -> Pic
flipV' xs = [reverse x|x<-xs]
flipH :: Pic -> Pic
flipH = reverse
- Place one picture above another.
above :: Pic -> Pic -> Pic
*Main> pp(above pic pic)
....#....
...###...
..#.#.#..
.#..#..#.
....#....
....#....
....#####
....#....
...###...
..#.#.#..
.#..#..#.
....#....
....#....
....#####
above :: Pic -> Pic -> Pic
above x y = x ++ y
- Place two pictures side by side (consider, that they have the same height).
sideBySide :: Pic -> Pic -> Pic
*Main> pp(sideBySide pic pic)
....#........#....
...###......###...
..#.#.#....#.#.#..
.#..#..#..#..#..#.
....#........#....
....#........#....
....#####....#####
sideBySide :: Pic -> Pic -> Pic
sideBySide xs ys = map (\(x,y) -> x ++ y)(zip xs ys)
sideBySide':: Pic -> Pic -> Pic
sideBySide' (x:xs) (y:ys) = (x ++ y) : sideBySide' xs ys
sideBySide' _ _ = []
sideBySide'' :: Pic -> Pic -> Pic
sideBySide'' = zipWith (++)
- Rotate picture to the left and to the right.
rotateR :: Pic -> Pic
rotateL :: Pic -> Pic
*Main> pp(rotateR pic)
.......
...#...
....#..
.....#.
#######
#....#.
#...#..
#..#...
#......
*Main> pp(rotateL pic)
......#
...#..#
..#...#
.#....#
#######
.#.....
..#....
...#...
.......
toRow :: String -> Pic
toRow xs = map (\x -> [x]) xs -- [[x]|x<-xs]
rotateR :: Pic -> Pic
rotateR [x] = toRow x
rotateR (x:xs) = (rotateR xs) `sideBySide` (toRow x)
rotateR' :: Pic -> Pic
rotateR' x = foldl1 sideBySide (reverse (map toRow x))
rotateL :: Pic -> Pic
rotateL [x] = reverse(toRow x)
rotateL (x:xs) = reverse(toRow x) `sideBySide` (rotateL xs)
rotateL' :: Pic -> Pic
rotateL' x = foldl1 sideBySide (map (reverse.toRow) x)
User defined data types and type classes
Consider following representation of expressions
data Expr = Num Int
| Add Expr Expr
| Sub Expr Expr
| Mul Expr Expr
| Div Expr Expr
| Var Char
deriving (Eq)
- Create function eval that evaluates expresions.
eval :: Expr -> Int
*Main> eval (Add (Num 1) (Num 2))
3
*Main> eval (Mul (Add (Num 1) (Num 2)) (Num 3))
9
eval :: Expr -> Int
eval (Num x) = x
eval (Add l r) = (eval l) + (eval r)
eval (Sub l r) = (eval l) - (eval r)
eval (Mul l r) = (eval l) * (eval r)
eval (Div l r) = (eval l) `div` (eval r)
- Create function showExpr that shows expression as a String.
showExpr :: Expr -> String
*Main> showExpr (Add (Num 1) (Num 2))
"1+2"
*Main> showExpr (Mul (Add (Num 1) (Num 2)) (Num 3))
"(1+2)*3"
*Main> showExpr (Mul (Add (Num 1) (Mul (Num 2) (Var 'x'))) (Mul (Num 3) (Var 'x')))
"(1+2*x)*3*x"
*Main> showExpr (Mul (Num 2) (Mul (Var 'x') (Var 'x')))
"2*x*x"
showExpr :: Expr -> String
showExpr expr = showExpr' expr NoOp
data Operation = Hi | HiDiv | Lo | LoSub | NoOp deriving (Eq)
showExpr' :: Expr -> Operation -> String
showExpr' (Num x) _ = show x
showExpr' (Var x) _ = [x]
showExpr' (Add l r) op = let
x = showExpr' l Lo ++"+"++showExpr' r Lo
in if op == Hi || op == HiDiv || op==LoSub
then "(" ++ x ++")"
else x
showExpr' (Sub l r) op = let
x = showExpr' l Lo ++"-"++showExpr' r LoSub
in if op == Hi || op == HiDiv || op==LoSub
then "(" ++ x ++")"
else x
showExpr' (Mul l r) op = let
x = showExpr' l Hi ++"*"++showExpr' r Hi
in if op == HiDiv
then "(" ++ x ++")"
else x
showExpr' (Div l r) op = let
x = showExpr' l Hi ++"/"++showExpr' r HiDiv
in if op == HiDiv
then "(" ++ x ++")"
else x
- Extend class Show to be usable with our expressions.
*Main> Add (Num 1) (Num 2)
"1+2"
*Main> Mul (Add (Num 1) (Num 2)) (Num 3)
"(1+2)*3"
*Main> Mul (Add (Num 1) (Mul (Num 2) (Var 'x'))) (Mul (Num 3) (Var 'x'))
"(1+2*x)*3*x"
*Main> Mul (Num 2) (Mul (Var 'x') (Var 'x'))
"2*x*x"
instance (Show Expr) where
show = showExpr
- Create function derivation representing symbolic derivation of a given expression.
deriv :: Expr-> Char -> Expr
*Main> deriv (Add (Num 1) (Num 2)) 'x'
0+0
*Main> deriv (Mul (Num 2) (Mul (Var 'x') (Var 'x'))) 'x'
0*x*x+2*(1*x+x*1)
*Main> deriv (Mul (Num 2) (Mul (Var 'x') (Var 'x'))) 'x'
0*x*x+2*(1*x+x*1)
deriv :: Expr-> Char -> Expr
deriv (Num _) _ = (Num 0)
deriv (Var x) y | x==y = (Num 1)
| otherwise = (Num 0)
deriv (Add l r) x = Add (deriv l x) (deriv r x)
deriv (Sub l r) x = Sub (deriv l x) (deriv r x)
deriv (Mul l r) x = Add (Mul (deriv l x) r) (Mul l (deriv r x))
deriv (Div l r) x =
Div
(Sub (Mul (deriv l x) r) (Mul l (deriv r x)))
(Mul r r)
