# Calculating permutations in F#

Inspired by this question and answer, how do I create a generic permutations algorithm in F#? Google doesn't give any useful answers to this.

EDIT: I provide my best answer below, but I suspect that Tomas's is better (certainly shorter!)

-

you can also write something like this:

``````let rec permutations list taken =
seq { if Set.count taken = List.length list then yield [] else
for l in list do
if not (Set.contains l taken) then
for perm in permutations list (Set.add l taken)  do
yield l::perm }
``````

The 'list' argument contains all the numbers that you want to permute and 'taken' is a set that contains numbers already used. The function returns empty list when all numbers all taken. Otherwise, it iterates over all numbers that are still available, gets all possible permutations of the remaining numbers (recursively using 'permutations') and appends the current number to each of them before returning (l::perm).

To run this, you'll give it an empty set, because no numbers are used at the beginning:

``````permutations [1;2;3] Set.empty;;
``````
-
FYI - Set.mem has been renamed Set.contains –  Stephen Swensen Jul 5 '10 at 14:56
@Stephen, I've edited the code to suit... –  Benjol Apr 28 '11 at 5:53

``````//mini-extension to List for removing 1 element from a list
module List =
let remove n lst = List.filter (fun x -> x <> n) lst

//Node type declared outside permutations function allows us to define a pruning filter
type Node<'a> =
| Branch of ('a * Node<'a> seq)
| Leaf of 'a

let permutations treefilter lst =
//Builds a tree representing all possible permutations
let rec nodeBuilder lst x = //x is the next element to use
match lst with  //lst is all the remaining elements to be permuted
| [x] -> seq { yield Leaf(x) }  //only x left in list -> we are at a leaf
| h ->   //anything else left -> we are at a branch, recurse
let ilst = List.remove x lst   //get new list without i, use this to build subnodes of branch
seq { yield Branch(x, Seq.map_concat (nodeBuilder ilst) ilst) }

//converts a tree to a list for each leafpath
let rec pathBuilder pth n = // pth is the accumulated path, n is the current node
match n with
| Leaf(i) -> seq { yield List.rev (i :: pth) } //path list is constructed from root to leaf, so have to reverse it
| Branch(i, nodes) -> Seq.map_concat (pathBuilder (i :: pth)) nodes

let nodes =
lst                                     //using input list
|> Seq.map_concat (nodeBuilder lst)     //build permutations tree
|> Seq.choose treefilter                //prune tree if necessary
|> Seq.map_concat (pathBuilder [])      //convert to seq of path lists

nodes
``````

The permutations function works by constructing an n-ary tree representing all possible permutations of the list of 'things' passed in, then traversing the tree to construct a list of lists. Using 'Seq' dramatically improves performance as it makes everything lazy.

The second parameter of the permutations function allows the caller to define a filter for 'pruning' the tree before generating the paths (see my example below, where I don't want any leading zeros).

Some example usage: Node<'a> is generic, so we can do permutations of 'anything':

``````let myfilter n = Some(n)  //i.e., don't filter
permutations myfilter ['A';'B';'C';'D']

//in this case, I want to 'prune' leading zeros from my list before generating paths
match n with
| Branch(0, _) -> None
| n -> Some(n)

//Curry myself an int-list permutations function with no leading zeros
noLZperm [0..9]
``````

(Special thanks to Tomas Petricek, any comments welcome)

-
Note that F# has a List.permute function, but that doesn't do quite the same thing (I'm not sure what it does actually...) –  Benjol Nov 13 '08 at 8:46

I like this implementation (but can't remember the source of it):

``````let rec insertions x = function
| []             -> [[x]]
| (y :: ys) as l -> (x::l)::(List.map (fun x -> y::x) (insertions x ys))

let rec permutations = function
| []      -> seq [ [] ]
| x :: xs -> Seq.concat (Seq.map (insertions x) (permutations xs))
``````
-
This looks really nice. Could this be transformed in a version for distinct permutations? See my own solution below which does not look as good as yours. Thanks. –  Emile Aug 23 '10 at 19:13
I wish you could remember the source. In terms of speed, this beats the pants off of every other permutation function I've tried. –  Rick Minerich Apr 27 '11 at 16:16
@rick-minerich This is almost identical to stackoverflow.com/questions/1526046/f-permutations/… though IMO is a bit clearer... –  Sergey Aldoukhov Jul 26 '11 at 7:38

Take a look at this one:

http://fsharpcode.blogspot.com/2010/04/permutations.html

``````let length = Seq.length
let take = Seq.take
let skip = Seq.skip
let (++) = Seq.append
let concat = Seq.concat
let map = Seq.map

let (|Empty|Cons|) (xs:seq<'a>) : Choice<Unit, 'a * seq<'a>> =
if (Seq.isEmpty xs) then Empty else Cons(Seq.head xs, Seq.skip 1 xs)

let interleave x ys =
seq { for i in [0..length ys] ->
(take i ys) ++ seq [x] ++ (skip i ys) }

let rec permutations xs =
match xs with
| Empty -> seq [seq []]
| Cons(x,xs) -> concat(map (interleave x) (permutations xs))
``````
-

Tomas' solution is quite elegant: it's short, purely functional, and lazy. I think it may even be tail-recursive. Also, it produces permutations lexicographically. However, we can improve performance two-fold using an imperative solution internally while still exposing a functional interface externally.

The function `permutations` takes a generic sequence `e` as well as a generic comparison function `f : ('a -> 'a -> int)` and lazily yields immutable permutations lexicographically. The comparison functional allows us to generate permutations of elements which are not necessarily `comparable` as well as easily specify reverse or custom orderings.

The inner function `permute` is the imperative implementation of the algorithm described here. The conversion function `let comparer f = { new System.Collections.Generic.IComparer<'a> with member self.Compare(x,y) = f x y }` allows us to use the `System.Array.Sort` overload which does in-place sub-range custom sorts using an `IComparer`.

``````let permutations f e =
///Advances (mutating) perm to the next lexical permutation.
let permute (perm:'a[]) (f: 'a->'a->int) (comparer:System.Collections.Generic.IComparer<'a>) : bool =
try
//Find the longest "tail" that is ordered in decreasing order ((s+1)..perm.Length-1).
//will throw an index out of bounds exception if perm is the last permuation,
//but will not corrupt perm.
let rec find i =
if (f perm.[i] perm.[i-1]) >= 0 then i-1
else find (i-1)
let s = find (perm.Length-1)
let s' = perm.[s]

//Change the number just before the tail (s') to the smallest number bigger than it in the tail (perm.[t]).
let rec find i imin =
if i = perm.Length then imin
elif (f perm.[i] s') > 0 && (f perm.[i] perm.[imin]) < 0 then find (i+1) i
else find (i+1) imin
let t = find (s+1) (s+1)

perm.[s] <- perm.[t]
perm.[t] <- s'

//Sort the tail in increasing order.
System.Array.Sort(perm, s+1, perm.Length - s - 1, comparer)
true
with
| _ -> false

//permuation sequence expression
let c = f |> comparer
let freeze arr = arr |> Array.copy |> Seq.readonly
seq { let e' = Seq.toArray e
yield freeze e'
while permute e' f c do
yield freeze e' }
``````

Now for convenience we have the following where `let flip f x y = f y x`:

``````let permutationsAsc e = permutations compare e
let permutationsDesc e = permutations (flip compare) e
``````
-

If you need distinct permuations (when the original set has duplicates), you can use this:

``````let rec insertions pre c post =
seq {
if List.length post = 0 then
yield pre @ [c]
else
if List.forall (fun x->x<>c) post then
yield pre@[c]@post
}

let rec permutations l =
seq {
if List.length l = 1 then
yield l
else
let subperms = permutations l.Tail
for sub in subperms do