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I am trying to solve one of the problem in H99: Split a list into two parts; the length of the first part is given.

Do not use any predefined predicates.


> (split '(a b c d e f g h i k) 3)
( (A B C) (D E F G H I K))

And I can quickly come with a solution:

split' [] _ _ _     = []
split' (x:xs) y z w = if y == z then [w,xs] else split' xs y (z+1) (w++[x])

split x y = split' x y 0 []

My question is that what I am doing is kind of just rewriting the loop version in a recursion format. Is this the right way you do things in Haskell? Isn't it just the same as imperative programming?

EDIT: Also, how do you generally avoid the extra function here?

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3 Answers 3

up vote 6 down vote accepted

It's convenient that you can often convert an imperative solution to Haskell, but you're right, you do usually want to find a more natural recursive statement. For this one in particular, reasoning in terms of base case and inductive case can be very helpful. So what's your base case? Why, when the split location is 0:

split x 0 = ([], x)

The inductive case can be built on that by prepending the first element of the list onto the result of splitting with n-1:

split (x:xs) n = (x:left, right)
  where (left, right) = split xs (n-1)

This may not perform wonderfully (it's probably not as bad as you'd think) but it illustrates my thought process when I first encounter a problem and want to approach it functionally.

Edit: Another solution relying more heavily on the Prelude might be:

split l n = (take n l, drop n l)
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Oh that "Un-haskellish" remark was for the OP original solution, I like yours :) It's how I first wrote is as well, but I think tail recursion is important for these sort of functions –  jozefg Dec 10 '13 at 21:37
I agree that tail recursion is important, but I think beginners are here for elegance first, and should grasp the basics before worrying about performance. –  Daniel Lyons Dec 10 '13 at 21:38
I was curious what the Platform/GHC has, and it's the (take n l, drop n l) solution. Dunno exactly why, but it's worth mentioning that the Platform/GHC versions of take and drop have the list fusion optimization, so the point is that both elements of the tuple are "good producers" such that they can fuse into the same loop as their consumers. (Which is another reason why Haskell beginners should not be pushed into tail recursion—in Haskell, thanks to laziness and fusion optimizations, we often have "tail recursion bad, non-tail recursion good" situations... –  Luis Casillas Dec 10 '13 at 21:41
@jozefg Yes, but when it comes to explaining things to newcomers, you often have to battle the misconceptions (often from previous exposure to strict functional languages like ML or Scheme) that tail recursion will necessarily use constant space and non-tail recursion will necessarily use linear space. As you and I know, neither of these statements is generally true in Haskell. But I too often see newcomers bend themselves backwards to write a tail-recursive version of something that is best written as a foldr—one of my favorite examples is find. –  Luis Casillas Dec 10 '13 at 21:47
@bheklilr Yeah, however tail recursion is applicable here because even a tail recursive solution terminates on an infinite list (it's recursing on the Int not the list) –  jozefg Dec 10 '13 at 22:12

It's not the same as imperative programming really, each function call avoids any side effects, they're just simple expressions. But I have a suggestion for your code

split :: Int -> [a] -> ([a], [a])
split p xs = go p ([], xs)
  where go 0 (xs, ys) = (reverse xs, ys)
        go n (xs, y:ys) = go (n-1) (y : xs, ys)

So how we've declared that we're only returning two things ([a], [a]) instead of a list of things (which is a bit misleading) and that we've constrained our tail recursive call to be in local scope.

I'm also using pattern matching, which is a more idiomatic way to write recursive functions in Haskell, when go is called with a zero, then the first case is run. It's more pleasant generally to write recursive functions that go down rather than up since you can use pattern matching rather than if statements.

Finally this is more efficient since ++ is linear in the length of the first list, which means that the complexity of your function is quadratic rather than linear. This method is also tail recursive unlike Daniel's solution, which is important for handling any large lists.

TLDR: Both versions are functional style, avoiding mutation, using recursion instead of loops. But the version I've presented is a little more Haskell-ish and slightly faster.

A word on tail recursion

This solution uses tail recursion which isn't always essential in Haskell but in this case is helpful when you use the resulting lists, but at other times is actually a bad thing. For example, map isn't tail recursive, but if it was you couldn't use it over infinite lists!

In this case, we can use tail recursion, since an integer is always finite. But, if we only use the first element of the list, Daniel's solution is much faster, since it produces the list lazily. On the other hand, if we use the whole list, my solution is much faster.

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tail recursion is only good in Haskell when it builds the value that is needed in full (like numbers). Not so with lists. your version is unnecessarily strict. guarded recursion is always preferable, is my understanding. and seeing reverse is just terrible, :) w.r.t. laziness etc. –  Will Ness Dec 10 '13 at 23:09
@WillNess Yeah, this solution isn't lazy in the first list, but I addressed this in the "A word on tail recursion" part. –  jozefg Dec 10 '13 at 23:10
yes, I see it now. that reverse just jumped at me. :) I think rule of thumb can safely be set, tail recursion is almost always the wrong thing to do in Haskell, unless it's a right thing to do. In the end what matters is run time behaviour - time and space. Guarded rec will more likely run in constant space. –  Will Ness Dec 10 '13 at 23:14

split' [] _ = ([],[])
split' xs 0 = ([],xs)
split' (x:xs) n = (x:(fst splitResult),snd splitResult) 
                  where splitResult = split' xs (n-1)

It seems you have already shown an example of a better solution.

I would recommend you read SICP. Then you come to the conclusion that the extra function is normal. There's also widely used approach to hide functions in the local area. The book may seem boring to you but in the early chapters she will get used to the functional approach in solving problems.

There are tasks in which the recursive approach is more necessary. But for example if you use tail recursion (which is so often praised without cause) then you will notice that this is just the usual iteration. Often with "extra-function" which hide iteration variable (oh.. word variable is not very appropriate, likely argument).

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I think "the extra function is normal" is easy enough to grasp it needn't necessitate a year-long study of a long and dense computer science tome. –  Daniel Lyons Dec 10 '13 at 22:11
@DanielLyons But this book is for first-year students. And there is beginner question (it seemed). –  vlastachu Dec 10 '13 at 22:17
I love SICP and think everyone should read it, but to doing it to learn that idiomatic Scheme uses block structure to make hidden local functions isn't really relevant to the task at hand. Also, what makes a good functional program in a lazy vs strict language is a big difference –  jozefg Dec 10 '13 at 22:30
@DanielLyons SICP is fun and good and is really accessible. You don't really need to know Scheme to read it, just go ahead and skim through the book. When you see (define (sqrt a b) ...) it is indeed what you think it is. :) –  Will Ness Dec 10 '13 at 23:30
@WillNess All that's accomplished by mentioning SICP here is meaningless flashing of gang signs. Neither the question nor the answer relate to it. The dictionary defines every word, but that doesn't make it pertain to every question and every answer. Stick to the point. –  Daniel Lyons Dec 10 '13 at 23:54

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