# Split list into two equal lists in F#

I'm really new to F#, and I need a bit of help with an F# problem.

I need to implement a cut function that splits a list in half so that the output would be...

cut [1;2;3;4;5;6];;

val it : int list * int list = ([1; 2; 3], [4; 5; 6])

I can assume that the length of the list is even.

I'm also expected to define an auxiliary function gencut(n, xs) that cuts xs into two pieces, where n gives the size of the first piece:

gencut(2, [1;3;4;2;7;0;9]);;

val it : int list * int list = ([1; 3], [4; 2; 7; 0; 9])

I wouldn't normally ask for exercise help here, but I'm really at a loss as to where to even start. Any help, even if it's just a nudge in the right direction, would help.

Thanks!

-

Since your list has an even length, and you're cutting it cleanly in half, I recommend the following (psuedocode first):

• Start with two pointers: `slow` and `fast`.
• `slow` steps through the list one element at a time, `fast` steps two elements at a time.
• `slow` adds each element to an accumulator variable, while `fast` moves foward.
• When the `fast` pointer reaches the end of the list, the `slow` pointer will have only stepped half the number of elements, so its in the middle of the array.
• Return the elements `slow` stepped over + the elements remaining. This should be two lists cut neatly in half.

The process above requires one traversal over the list and runs in O(n) time.

Since this is homework, I won't give a complete answer, but just to get you partway started, here's what it takes to cut the list cleanly in half:

``````let cut l =
let rec cut = function
| xs, ([] | [_]) -> xs
| [], _ -> []
| x::xs, y::y'::ys -> cut (xs, ys)
cut (l, l)
``````

Note `x::xs` steps 1 element, `y::y'::ys` steps two.

This function returns the second half of the list. It is very easy to modify it so it returns the first half of the list as well.

-
+1 @Juliet - that's really neat! –  Stephen Swensen Feb 1 '11 at 22:21
I really appreciate the help! Thanks! –  user598907 Feb 2 '11 at 22:58

You are looking for list slicing in F#. There was a great answer by @Juliet in this SO Thread: Slice like functionality from a List in F#

Basically it comes down to - this is not built in since there is no constant time index access in F# lists, but you can work around this as detailed. Her approach applied to your problem would yield a (not so efficient but working) solution:

``````let gencut(n, list) =
let firstList = list |> Seq.take n |> Seq.toList
let secondList = list |> Seq.skip n |> Seq.toList
(firstList, secondList)
``````
-

(I didn't like my previous answer so I deleted it)

The first place to start when attacking `list` problems is to look at the `List` module which is filled with higher order functions which generalize many common problems and can give you succinct solutions. If you can't find anything suitable there, then you can look at the `Seq` module for solutions like @BrokenGlass demonstrated (but you can run into performance issues there). Next you'll want to consider recursion and pattern matching. There are two kinds of recursion you'll have to consider when processing lists: tail and non-tail. There are trade-offs. Tail-recursive solutions involve using an accumulator to pass state around, allowing you to place the recursive call in the tail position and avoid stack-overflows with large lists. But then you'll typically end up with a reversed list! For example,

Tail-recursive `gencut` solution:

``````let gencutTailRecursive n input =
let rec gencut cur acc = function
| hd::tl when cur < n ->
gencut (cur+1) (hd::acc) tl
| rest -> (List.rev acc), rest //need to reverse accumulator!
gencut 0 [] input
``````

Non-tail-recursive `gencut` solution:

``````let gencutNonTailRecursive n input =
let rec gencut cur = function
| hd::tl when cur < n ->
let x, y = gencut (cur+1) tl //stackoverflow with big lists!
hd::x, y
| rest -> [], rest
gencut 0 input
``````

Once you have your `gencut` solution, it's really easy to define `cut`:

``````let cut input = gencut ((List.length input)/2) input
``````
-
+1 nice explanation - but you didn't call out why one should aim for tail-recursion in the first place: they can be optimized by the compiler to not use any call stack space (since there is no state left on the stack you would have to get back to) so they allow for (essentially) infinite recursion. –  BrokenGlass Feb 2 '11 at 0:12
@BrokenGlass - Thanks! And you are absolutely right, that is an important point to make. Thinking about how to answer this question, and reflecting on my own learning experience, I realized that it is really tough to explain something as basic has recursive list processing to an FP beginner since there are so many fundamentals you need to grasp first. –  Stephen Swensen Feb 2 '11 at 0:59

Here's yet another way to do it using inbuilt library functions, which may or may not be easier to understand than some of the other answers. This solution also only requires one traversal across the input. My first thought after I looked at your problem was that you want something along the lines of List.partition, which splits a list into two lists based on a given predicate. However, in your case this predicate would be based on the index of the current element, which partition cannot handle, short of looking up the index for each element.

We can accomplish creating our own equivalent of this behavior using a fold or foldBack. I will use foldBack here as it means you won't have to reverse the lists afterward (see Stephens excellent answer). What we are going to do here is use the fold to provide our own index, along with the two output lists, all as the accumulator. Here is the generic function that will split your list into two lists based on n index:

``````let gencut n input =
//calculate the length of the list first so we can work out the index
let inputLength = input |> List.length
let results =
List.foldBack( fun elem acc->
let a,b,index = acc     //decompose accumulator
if (inputLength - index) <= n then (elem::a,b,index+1)
else (a,elem::b,index+1)  ) input ([],[],0)
let a,b,c = results
(a,b) //dump the index, leaving the two lists as output.
``````

So here you see we start the foldBack with an initial accumulator value of ([],[],0). However, because we are starting at the end of the list, the 0 representing the current index needs to be subtracted from the total length of the list to get the actual index of the current element.

Then we simply check if the current index falls within the range of n. If it does, we update the accumulator by adding the current element to list a, leave list b alone, and increase the index by 1 : (elem::a,b,index+1). In all other cases, we do exactly the same but add the element to list b instead: (a,elem::b,index+1).

Now you can easily create your function that splits a list in half by creating another function over this one like so:

``````let cut input =
let half = (input |> List.length) / 2
input |> gencut half
``````

I hope that can help you somewhat!

``````> cut data;;
val it : int list * int list = ([1; 2; 3], [4; 5; 6])

> gencut 5 data;;
val it : int list * int list = ([1; 2; 3; 4; 5], [6])
``````

EDIT: you could avoid the index negation by supplying the length as the initial accumulator value and negating it on each cycle instead of increasing it - probably simpler that way :)

``````let gencut n input =
let results =
List.foldBack( fun elem acc->
let a,b,index = acc     //decompose accumulator
if index <= n then (elem::a,b,index-1)
else (a,elem::b,index-1)  ) input ([],[],List.length input)
let a,b,c = results
(a,b) //dump the index, leaving the two lists as output.
``````
-

I have the same Homework, this was my solution. I'm just a student and new in F#

``````let rec gencut(n, listb) =
let rec cut  n (lista : int list)  (listb : int list) =
match (n , listb ) with
| 0, _   ->  lista, listb
| _, []  -> lista, listb
| _, b :: listb -> cut  (n - 1) (List.rev (b :: lista ))  listb
cut n [] listb

let cut xs = gencut((List.length xs) / 2, xs)
``````

Probably is not the best recursive solution, but it works. I think

-
``````let Sublist x y data = [ for z in x..(y - 1) -> List.nth data z ]