Difference between revisions of "99 questions/Solutions/18"
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(another entry) |
(Added solution using fold) |
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| (4 intermediate revisions by 3 users not shown) | |||
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<haskell> |
<haskell> |
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| − | slice :: [a]->Int->Int->[a] |
+ | slice :: [a] -> Int -> Int -> [a] |
| − | slice lst 1 m = slice' lst m [] |
+ | slice lst 1 m = slice' lst m [] |
where |
where |
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slice' :: [a]->Int->[a]->[a] |
slice' :: [a]->Int->[a]->[a] |
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slice' _ 0 acc = reverse acc |
slice' _ 0 acc = reverse acc |
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slice' (x:xs) n acc = slice' xs (n - 1) (x:acc) |
slice' (x:xs) n acc = slice' xs (n - 1) (x:acc) |
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| + | slice' [] _ _ = [] |
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slice (x:xs) n m = slice xs (n - 1) (m - 1) |
slice (x:xs) n m = slice xs (n - 1) (m - 1) |
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| + | slice [] _ _ = [] |
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</haskell> |
</haskell> |
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| Line 35: | Line 37: | ||
<haskell> |
<haskell> |
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slice :: [a] -> Int -> Int -> [a] |
slice :: [a] -> Int -> Int -> [a] |
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| + | slice [] _ _ = [] |
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slice (x:xs) i k |
slice (x:xs) i k |
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| − | | i > 1 |
+ | | i > 1 = slice xs (i - 1) (k - 1) |
| − | | k < 1 |
+ | | k < 1 = [] |
| − | | otherwise |
+ | | otherwise = x:slice xs (i - 1) (k - 1) |
</haskell> |
</haskell> |
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| Line 80: | Line 83: | ||
slice xs a b = fst $ unzip $ filter ((>=a) . snd) $ zip xs [1..b] |
slice xs a b = fst $ unzip $ filter ((>=a) . snd) $ zip xs [1..b] |
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</haskell> |
</haskell> |
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| + | |||
| + | Take and drop can be applied in the opposite order too: |
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| + | <haskell> |
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| + | slice xs i k = drop (i-1) $ take k xs |
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| + | </haskell> |
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| + | |||
| + | Using a fold: |
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| + | <haskell> |
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| + | slice :: [a] -> Int -> Int -> [a] |
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| + | slice (x:xs) begin end = snd $ foldl helper (1, []) (x:xs) |
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| + | where helper (i, acc) x = if (i >= begin) && (i <= end) then (i+1, acc ++ [x]) else (i+1, acc) |
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| + | </haskell> |
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| + | |||
| + | [[Category:Programming exercise spoilers]] |
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Revision as of 15:44, 18 May 2014
(**) Extract a slice from a list.
Given two indices, i and k, the slice is the list containing the elements between the i'th and k'th element of the original list (both limits included). Start counting the elements with 1.
slice xs i k | i>0 = take (k-i+1) $ drop (i-1) xs
The same solution as above, but the more paranoid (maybe too paranoid?) version of it (uses guards and Maybe):
slice :: [a] -> Int -> Int -> Maybe [a]
slice [] _ _ = Just []
slice xs k n | k == n = Just []
| k > n || k > length xs ||
n > length xs || k < 0 || n < 0 = Nothing
| k == 0 = Just (take n xs)
| otherwise = Just (drop (k-1) $ take n xs)
Or, an iterative solution:
slice :: [a] -> Int -> Int -> [a]
slice lst 1 m = slice' lst m []
where
slice' :: [a]->Int->[a]->[a]
slice' _ 0 acc = reverse acc
slice' (x:xs) n acc = slice' xs (n - 1) (x:acc)
slice' [] _ _ = []
slice (x:xs) n m = slice xs (n - 1) (m - 1)
slice [] _ _ = []
Or:
slice :: [a] -> Int -> Int -> [a]
slice [] _ _ = []
slice (x:xs) i k
| i > 1 = slice xs (i - 1) (k - 1)
| k < 1 = []
| otherwise = x:slice xs (i - 1) (k - 1)
Another way using splitAt, though not nearly as elegant as the take and drop version:
slice :: [a] -> Int -> Int -> [a]
slice xs i k = chunk
where chop = snd $ splitAt i' xs -- Get the piece starting at i
chunk = fst $ splitAt (k - i') chop -- Remove the part after k
i' = i - 1
A little cleaner, using the previous problem's split (a.k.a. splitAt):
slice xs (i+1) k = snd (split (fst (split xs k)) i)
A solution using zip, filter then map seems straight-forward to me (NB: this won't work for infinite lists):
slice xs i j = map snd
$ filter (\(x,_) -> x >= i && x <= j)
$ zip [1..] xs
A solution using list comprehension:
slice xs i k = [x | (x,j) <- zip xs [1..k], i <= j]
Another simple solution using take and drop:
slice :: [a] -> Int -> Int -> [a]
slice l i k
| i > k = []
| otherwise = (take (k-i+1) (drop (i-1) l))
Zip, filter, unzip:
slice :: [a] -> Int -> Int -> [a]
slice xs a b = fst $ unzip $ filter ((>=a) . snd) $ zip xs [1..b]
Take and drop can be applied in the opposite order too:
slice xs i k = drop (i-1) $ take k xs
Using a fold:
slice :: [a] -> Int -> Int -> [a]
slice (x:xs) begin end = snd $ foldl helper (1, []) (x:xs)
where helper (i, acc) x = if (i >= begin) && (i <= end) then (i+1, acc ++ [x]) else (i+1, acc)