# Projecting a list of lists efficiently in F#

I have to do projection of a list of lists which returns all combinations with each element from each list. For example:

``````projection([[1]; [2; 3]]) = [[1; 2]; [1; 3]].
projection([[1]; [2; 3]; [4; 5]]) = [[1; 2; 4]; [1; 2; 5]; [1; 3; 4]; [1; 3; 5]].
``````

I come up with a function:

``````let projection lss0 =
let rec projectionUtil lss accs =
match lss with
| []        ->  accs
| ls::lss'  ->  projectionUtil lss' (List.fold (fun accs' l ->
accs' @ List.map (fun acc -> acc @ [l]) accs)
[] ls)
match lss0 with
| [] -> []
| ls::lss' ->
projectionUtil lss' (List.map (fun l -> [l]) ls)
``````

and a testcase:

``````#time "on";;
let N = 10
let fss0 = List.init N (fun i -> List.init (i+1) (fun j -> j+i*i+i));;
let fss1 = projection fss0;;
``````

The function is quite slow now, with `N = 10` it takes more than 10 seconds to complete. Moreover, I think the solution is unnatural because I have to breakdown the same list in two different ways. Any suggestion how I can improve performance and readability of the function?

-
Basically, any of the top search results for F# cross product and F# cartesian... –  Benjol Jun 1 '11 at 8:39
For comparison, here's my Scheme version of Cartesian product: stackoverflow.com/questions/5546552/… –  Chris Jester-Young Jun 1 '11 at 17:02

First of all, try to avoid list concatenation (@) whenever possible, since it's O(N) instead of O(1) prepend.

I'd start with a (relatively) easy to follow plan of how to compute the cartesian outer product of lists.

• Prepend each element of the first list to each sublist in the cartesian product of the remaining lists.
• Take care of the base case.

First version:

``````let rec cartesian = function
| [] -> [[]]
| L::Ls -> [for C in cartesian Ls do yield! [for x in L do yield x::C]]
``````

This is the direct translation of the sentences above to code.

Now speed this up: instead of list comprehensions, use list concatenations and maps:

``````let rec cartesian2 = function
| [] -> [[]]
| L::Ls -> cartesian2 Ls |> List.collect (fun C -> L |> List.map (fun x->x::C))
``````

This can be made faster still by computing the lists on demand via a sequence:

``````let rec cartesian3 = function
| [] -> Seq.singleton []
| L::Ls -> cartesian3 Ls |> Seq.collect (fun C -> L |> Seq.map (fun x->x::C))
``````

This last form is what I use myself, since I most often just need to iterate over the results instead of having them all at once.

Some benchmarks on my machine: Test code:

``````let test f N =
let fss0 = List.init N (fun i -> List.init (i+1) (fun j -> j+i*i+i))
f fss0 |> Seq.length
``````

Results in FSI:

``````> test projection 10;;
Real: 00:00:18.066, CPU: 00:00:18.062, GC gen0: 168, gen1: 157, gen2: 7
val it : int = 3628800
> test cartesian 10;;
Real: 00:00:19.822, CPU: 00:00:19.828, GC gen0: 244, gen1: 121, gen2: 3
val it : int = 3628800
> test cartesian2 10;;
Real: 00:00:09.247, CPU: 00:00:09.250, GC gen0: 94, gen1: 52, gen2: 2
val it : int = 3628800
> test cartesian3 10;;
Real: 00:00:04.254, CPU: 00:00:04.250, GC gen0: 359, gen1: 1, gen2: 0
val it : int = 3628800
``````
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Excellent answer, I can see the flow of thinking and how you come up with the efficient solution. –  pad Jun 1 '11 at 9:55
I would suggest to make a tail recursive version too. –  Ankur Jun 1 '11 at 10:15
@Ankur: look at Ed'ka's answer for a version that won't kill the stack. Implementing my version in a tail-recursive way will probably involve lots of continuations and headaches, and won't perform well. –  cfern Jun 1 '11 at 11:59

This function is Haskell's sequence (although `sequence` is more generic). Translating to F#:

``````let sequence lss =
let k l ls = [ for x in l do for xs in ls -> x::xs ]
List.foldBack k lss [[]]
``````

in interactive:

``````> test projection 10;;
Real: 00:00:12.240, CPU: 00:00:12.807, GC gen0: 163, gen1: 155, gen2: 4
val it : int = 3628800
> test sequence 10;;
Real: 00:00:06.038, CPU: 00:00:06.021, GC gen0: 75, gen1: 74, gen2: 0
val it : int = 3628800
``````

General idea: avoid explicit recursion in favor to standard combinators (fold, map etc.)

-
+1 for foldBack. I somehow never think of traversing lists in F# backwards because of their head::tail structure. But this version won't nuke the stack. –  cfern Jun 1 '11 at 11:57

You implementation is slow because of the @ (i.e List concat) operation, which is a slow operation and it is being done many a times in recursive way. The reason for @ being slow is that List are Linked list in functional programming and to concat 2 list you have to first go till the end of the list (one by one traversing through elements) and then append another list .

``````let cartesian l =