Difference between revisions of "FP Laboratory 5/cs"

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(Created page with "== Generátory seznamů == Implementujte následující funkce s využitím genrátoru seznamu: * Vytvořte funkci, která generuje seznam všech lichých čísel v daném int...")
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== List comprehension ==
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== Generátory seznamů ==
Using the list comprehension implement following functions:
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Implementujte následující funkce s využitím genrátoru seznamu:
* Create a function that generates a list of all odd numbers in given interval.
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* Vytvořte funkci, která generuje seznam všech lichých čísel v daném intervalu.
 
<syntaxhighlight lang="Haskell">oddList :: Int -> Int -> [Int]</syntaxhighlight>
 
<syntaxhighlight lang="Haskell">oddList :: Int -> Int -> [Int]</syntaxhighlight>
 
<syntaxhighlight lang="Haskell" class="myDark">
 
<syntaxhighlight lang="Haskell" class="myDark">
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</div>
 
</div>
 
<div style="clear:both"></div>
 
<div style="clear:both"></div>
 
 
* Create a function that removes all upper case letters from a string.
 
* Create a function that removes all upper case letters from a string.
 
<syntaxhighlight lang="Haskell">removeAllUpper :: String -> String</syntaxhighlight>
 
<syntaxhighlight lang="Haskell">removeAllUpper :: String -> String</syntaxhighlight>

Revision as of 08:12, 19 October 2021

Generátory seznamů

Implementujte následující funkce s využitím genrátoru seznamu:

  • Vytvořte funkci, která generuje seznam všech lichých čísel v daném intervalu.
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]
Try it!
  • 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)]
Try it!
  • 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]
Try it!

More complex functions

  • Create a function that count the number of occurrences of all characters from a given string.
    Video logo.png
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]
Try it!
  • Goldbach's conjecture says that every positive even number greater than 2 is the sum of two prime numbers. Example: 28 = 5 + 23. It is one of the most famous facts in number theory that has not been proved to be correct in the general case yet. Create a function, that computes for a given even integer number the list of pairs of primes, that satisfies the rule of Goldbach's conjecture.
    Video logo.png
goldbach :: Int-> [(Int, Int)]
*Main>goldbach 28
[(5, 23),(11,17)]
isPrime :: Int -> Bool
isPrime n = null [x |x<-[2..ceiling (sqrt (fromIntegral n)::Double)], n `mod` x == 0]

goldbach :: Int-> [(Int, Int)]
goldbach n = let primes = [x |x<-[2..(n `div` 2)], isPrime x]
             in [(x,n-x) |x<-primes, isPrime (n-x)]
Try it!
  • In most cases, if an even number is written as the sum of two prime numbers, one of them is very small. We will be searching for cases that violates this rule. Create a function, that has three parameters. First two defines an interval, where we will be searching for Goldbach numbers. The last parameter is the limit. For each number in this interval, find Goldbach's pair with smallest prime number. If this smallest number is bigger than given limit, the corresponding pair will be in the result.
    Video logo.png
goldbachList :: Int -> Int-> Int -> [(Int, Int)]
*Main>goldbachList 4 2000 50
[(73,919),(61,1321),(67,1789),(61,1867)]
isPrime :: Int -> Bool
isPrime n = null [x |x<-[2..ceiling (sqrt (fromIntegral n)::Double)], n `mod` x == 0]

goldbach :: Int-> [(Int, Int)]
goldbach n = let primes = [x |x<-[2..(n `div` 2)+1], isPrime x]
             in [(x,n-x) |x<-primes, isPrime (n-x)]

goldbachList :: Int -> Int-> Int -> [(Int, Int)]
goldbachList a b limit = filter (\(x,_)-> x>limit) [head (goldbach x) | x<-[a..b], even x]
Try it!
  • 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.
    Video logo.png
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)
Try it!