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As part of a bigger problem of enumerating a set, I need to write an OCaml function 'choose' which takes a list and outputs as the list of all possible sequences of size k made up of elements of that list (without repeating sequences which can be obtained from each other by permutation). The order they are put in the end list is not relevant.

For example,

choose 2 [1;2;3;4] = [[1;2];[1;3];[1;4];[2;3];[2;4];[3;4]]

Any ideas?

I would like to have the whole thing to be lazy, outputting a lazy list, but if you have a strict solution, that'll be very useful too.

share|improve this question
If it's lazy, its type can not be to return a list. A lazy list should be enough for what you want:… – Pascal Cuoq Oct 19 '10 at 14:21
Hi Pascal. I wrote the example in strict notation so that it would be easier to read. I'd like it to be lazy, yes. But my question is not how to use lazy lists. It's about the specific "choose" function. I don't know how to make it choose all possibilities of length k out of the initial list. – Surikator Oct 19 '10 at 14:26
Your question is clear, and my remark was just on the off-chance you were confused about laziness in OCaml (hence putting it in the comments). I'm sure someone will provide something more constructive in the answers. – Pascal Cuoq Oct 19 '10 at 14:36
up vote 9 down vote accepted

Here is a strict and suboptimal version. I hope it is clear. It avoids duplicates by assuming there are no duplicates in the input list, and by generating only sublists that are in the same order as in the original list.

The length computation could be factored by passing l's length as an argument of choose. That would make the code less readable but more efficient.

For the lazy version, sprinkle "lazy" and "Lazy.force" on the code...

let rec choose k l =
  if k = 0 
  then [ [] ]
    let len = List.length l in
    if len < k
    then []
    else if k = len
    then [ l ]
      match l with
      h :: t ->
          let starting_with_h =
            ( (fun sublist -> h :: sublist) (choose (pred k) t))
          let not_starting_with_h = choose k t in
          starting_with_h @ not_starting_with_h
      | [] -> assert false
  val choose : int -> 'a list -> 'a list list = <fun>

# choose 3 [1; 2; 3; 4; 5; 6; 7] ;;                        
- : int list list =
[[1; 2; 3]; [1; 2; 4]; [1; 2; 5]; [1; 2; 6]; [1; 2; 7]; [1; 3; 4]; [1; 3; 5];
 [1; 3; 6]; [1; 3; 7]; [1; 4; 5]; [1; 4; 6]; [1; 4; 7]; [1; 5; 6]; [1; 5; 7];
 [1; 6; 7]; [2; 3; 4]; [2; 3; 5]; [2; 3; 6]; [2; 3; 7]; [2; 4; 5]; [2; 4; 6];
 [2; 4; 7]; [2; 5; 6]; [2; 5; 7]; [2; 6; 7]; [3; 4; 5]; [3; 4; 6]; [3; 4; 7];
 [3; 5; 6]; [3; 5; 7]; [3; 6; 7]; [4; 5; 6]; [4; 5; 7]; [4; 6; 7]; [5; 6; 7]]


A lazy_list_append as appears necessary from the comments below:

type 'a node_t =             
      | Empty
      | Node of 'a * 'a zlist_t
and 'a zlist_t = 'a node_t lazy_t

let rec lazy_list_append l1 l2 =
    (match Lazy.force l1 with
      Empty -> Lazy.force l2 
    | Node (h, lt) ->
    Node (h, lazy_list_append lt l2))
share|improve this answer
That's great! Thanks a lot. Do you have any idea on how to get rid of the @ operator? My lists will have thousands of elements and I can't afford @'s inefficiency. Note that making it lazy is not a matter of sprinkling lazy and force because you use List.length. The lazy counterpart gives you inifinity... – Surikator Oct 19 '10 at 15:42
@Surikator The @ removal comes for free with the laziness, if you do it right. That is, your lazy version will use lazy_list_append that is not inefficient in the way @ is. – Pascal Cuoq Oct 19 '10 at 15:44
If you don't care about the order of the values that return, then can substitute it with List.rev_append; which is tail-recursive, and more efficient then @. – nlucaroni Oct 19 '10 at 15:46
@Surikator For the lazy version, do pass the list's length as an argument of choose. You can use type extended_int = Finite of int | Infinite if you wish to lazily start enumerating infinite possibilities, but my algorithm is not "fair": you will never see some sublists if the input is actually infinite. You will need to change it to generate all possible combinations with the elements already seen. – Pascal Cuoq Oct 19 '10 at 15:48
@Pascal Ignore my comment on List.length. It's clearly resolvable. I kind of see what you mean concerning @ becoming efficient in the lazy context but I miss the details. Do you have any pointer/suggestion concerning an efficient implementation of lazy_list_append? Thanks a lot, again! – Surikator Oct 19 '10 at 15:51

Plugging in again with a Haskell solution (it's just easier to work with lazy lists since they are built-in):

combinations 0 _ = [[]]
combinations k [] = []
combinations k (x:xs) = map (x:) (combinations (k-1) xs) ++ combinations k xs

The first two cases follow from the properties of binomial coefficients and more specifically: n choose 0 = 1 for all n including n=0 (that's why it is first to handle the case 0 choose 0). The other one is 0 choose k = 0. The third equation is exact translation of the recursive definition of combinations.

Unfortunately when you apply it to an infinite list it returns a trivial solution:

> take 10 $ combinations 3 [1..]

EDIT: OK, so we really want to go trough each combination in a finite number of steps. With the above version we are obviously using only the expression to the left of ++ which generates only combinations starting with 1. We can work around this problem by defining an interesting list zipping function which builds a list by alternately picking the head of each of its argument lists (it's important to be non-strict in the second argument):

merge [] ys = ys
merge (x:xs) ys = x:merge ys xs

and use it instead of ++:

combinations k (x:xs) = map (x:) (combinations (k-1) xs) `merge` combinations k xs

lets see:

> let comb_10_3 = combinations 3 [1..10]
> let comb_inf_3 = combinations 3 [1..]
> take 10 comb_inf_3 
> comb_10_3 `intersect` comb_inf_3 == comb_10_3 
> last $ combinations 3 [1..10]
> elemIndex [6,8,10] $ combinations 3 [1..]
Just 351

All 10 choose 3 combinations are there!

share|improve this answer
I was more hoping to see an actual working lazy solution in Haskell, not the dysfunctional solution that had already been built and pointed out as flawed. Any ideas for that? – Pascal Cuoq Oct 19 '10 at 18:08
Actually, the lazy answer I proposed above in OCaml, based on Pascal strict stuff, although not working for infinite lists, works for lazy lists of arbitrary size (just not 'infinite size') =) – Surikator Oct 19 '10 at 18:14
@Pascal check the edit I made. – Daniel Velkov Oct 19 '10 at 21:27
@Daniel Velkov The PS: goes without saying (that is, you do not have to say it. We all know how elegant Haskell is. You can stop saying it now. Stop!). +1 despite the PS: – Pascal Cuoq Oct 19 '10 at 21:31
OK, no PS, lets have peace. – Daniel Velkov Oct 19 '10 at 21:35

Just for the sake of completeness, I am putting here the final code which brings together the strict code from Pascal with my lazy stuff and all other Pascal's useful comments.

The lazy list type is defined, then two auxiliary lazy functions (append and map), and finally the function "choose" that we aim to define.

type 'a node_t =
  | Nil                                            
  | Cons of 'a * 'a t
and 'a t = ('a node_t) Lazy.t

let rec append l1 l2 = 
match Lazy.force l1 with
    | Nil -> l2 
    | Cons (a, l) -> lazy (Cons (a, append l l2))

let rec map f ll = lazy (
match Lazy.force ll with
    | Nil ->    Nil
    | Cons(h,t) -> Cons(f h, map f t) )

let rec choose k l len =
  if k = 0 
  then lazy (Cons(lazy Nil,lazy Nil))
        if len < k
        then lazy Nil
        else if k = len
    then lazy (Cons (l,lazy Nil))
      match Lazy.force l with
          | Cons(h,t) ->  let g h sublist = lazy (Cons (h,sublist))
                          in let starting_with_h = (map (g h) (choose (k-1) t (len-1)))
                          in let not_starting_with_h = choose k t (len-1)
                          in append starting_with_h not_starting_with_h
          | Nil -> assert false

The result of evaluating "choose k ls n" is a lazy list of all choices of k elements of list ls, with ls considered up to size n. Note that, as pointed out by Pascal, because of the way the enumeration takes place, the function choose will not cover all choices of an infinite list.

Thanks, this was really useful!

Best, Surikator.

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