# How would you calculate all possible permutations of 0 through N iteratively?

I need to calculate permutations iteratively. The method signature looks like:

`int[][] permute(int n)`

For `n = 3` for example, the return value would be:

``````[[0,1,2],
[0,2,1],
[1,0,2],
[1,2,0],
[2,0,1],
[2,1,0]]
``````

How would you go about doing this iteratively in the most efficient way possible? I can do this recursively, but I'm interested in seeing lots of alternate ways to doing it iteratively.

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As I mentioned in my answer (after I edited to use the QuickPerm algorithm as uray suggested), the most efficient way would be to iterate over the permutations live. Building up a complete list is likely not to be very useful, as you can just process the current iteration. –  Matthew Mar 6 '10 at 2:23
Right, which is why the Ruby code I added to uray's answer uses yield and blocks. It passes each permutation to the supplied code block before calculating the next permutation. –  Bob Aman Mar 6 '10 at 4:53
See this question and answers: stackoverflow.com/questions/352203/… –  ShreevatsaR Mar 6 '10 at 17:04
@Bob, the C# version I posted uses the same approach of yielding results as they become available. Hope it helps someone out. –  Drew Noakes Dec 5 '11 at 11:03

see QuickPerm algorithm, it's iterative : http://www.quickperm.org/

Edit:

Rewritten in Ruby for clarity:

``````def permute_map(n)
results = []
a, p = (0...n).to_a, [0] * n
i, j = 0, 0
i = 1
results << yield(a)
while i < n
if p[i] < i
j = i % 2 * p[i] # If i is odd, then j = p[i], else j = 0
a[j], a[i] = a[i], a[j] # Swap
results << yield(a)
p[i] += 1
i = 1
else
p[i] = 0
i += 1
end
end
return results
end
``````
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+1: Yes, that was the one I was thinking of. –  Matthew Mar 6 '10 at 1:28
I snuck in there and attached a Ruby implementation of this algorithm for my own personal reference. Would've put it in the comments, but you can't have syntax highlighting there. –  Bob Aman Mar 6 '10 at 1:30
Incidentally, the current version of Ruby has this built-in: `(0...n).to_a.permutation { |a| puts a.inspect }` –  Bob Aman Apr 22 '13 at 1:19
what's time complexity of this one? –  Aidan Miles Mar 10 at 22:34

Is using 1.9's Array#permutation an option?

``````>> a = [0,1,2].permutation(3).to_a
=> [[0, 1, 2], [0, 2, 1], [1, 0, 2], [1, 2, 0], [2, 0, 1], [2, 1, 0]]
``````
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No, the algorithm itself is what I'm looking for. I marked this as language-agnostic precisely for that reason. –  Bob Aman Mar 8 '10 at 16:49

The algorithm for stepping from one permutation to the next is very similar to elementary school addition - when an overflow occurs, "carry the one".

Here's an implementation I wrote in C:

``````#include <stdio.h>

//Convenience macro.  Its function should be obvious.
#define swap(a,b) do { \
typeof(a) __tmp = (a); \
(a) = (b); \
(b) = __tmp; \
} while(0)

void perm_start(unsigned int n[], unsigned int count) {
unsigned int i;
for (i=0; i<count; i++)
n[i] = i;
}

//Returns 0 on wraparound
int perm_next(unsigned int n[], unsigned int count) {
unsigned int tail, i, j;

if (count <= 1)
return 0;

/* Find all terms at the end that are in reverse order.
Example: 0 3 (5 4 2 1) (i becomes 2) */
for (i=count-1; i>0 && n[i-1] >= n[i]; i--);
tail = i;

if (tail > 0) {
/* Find the last item from the tail set greater than
the last item from the head set, and swap them.
Example: 0 3* (5 4* 2 1)
Becomes: 0 4* (5 3* 2 1) */
for (j=count-1; j>tail && n[j] <= n[tail-1]; j--);

swap(n[tail-1], n[j]);
}

/* Reverse the tail set's order */
for (i=tail, j=count-1; i<j; i++, j--)
swap(n[i], n[j]);

/* If the entire list was in reverse order, tail will be zero. */
return (tail != 0);
}

int main(void)
{
#define N 3
unsigned int perm[N];

perm_start(perm, N);
do {
int i;
for (i = 0; i < N; i++)
printf("%d ", perm[i]);
printf("\n");
} while (perm_next(perm, N));

return 0;
}
``````
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I found Joey Adams' version to be the most readable, but I couldn't port it directly to C# because of how C# handles the scoping of for-loop variables. Hence, this is a slightly tweaked version of his code:

``````/// <summary>
/// Performs an in-place permutation of <paramref name="values"/>, and returns if there
/// are any more permutations remaining.
/// </summary>
private static bool NextPermutation(int[] values)
{
if (values.Length == 0)
throw new ArgumentException("Cannot permutate an empty collection.");

//Find all terms at the end that are in reverse order.
//  Example: 0 3 (5 4 2 1) (i becomes 2)
int tail = values.Length - 1;
while(tail > 0 && values[tail - 1] >= values[tail])
tail--;

if (tail > 0)
{
//Find the last item from the tail set greater than the last item from the head
//set, and swap them.
//  Example: 0 3* (5 4* 2 1)
//  Becomes: 0 4* (5 3* 2 1)
int index = values.Length - 1;
while (index > tail && values[index] <= values[tail - 1])
index--;

Swap(ref values[tail - 1], ref values[index]);
}

//Reverse the tail set's order.
int limit = (values.Length - tail) / 2;
for (int index = 0; index < limit; index++)
Swap(ref values[tail + index], ref values[values.Length - 1 - index]);

//If the entire list was in reverse order, tail will be zero.
return (tail != 0);
}

private static void Swap<T>(ref T left, ref T right)
{
T temp = left;
left = right;
right = temp;
}
``````
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Here's an implementation in C#, as an extension method:

``````public static IEnumerable<List<T>> Permute<T>(this IList<T> items)
{
var indexes = Enumerable.Range(0, items.Count).ToArray();

yield return indexes.Select(idx => items[idx]).ToList();

var weights = new int[items.Count];
var idxUpper = 1;
while (idxUpper < items.Count)
{
if (weights[idxUpper] < idxUpper)
{
var idxLower = idxUpper % 2 * weights[idxUpper];
var tmp = indexes[idxLower];
indexes[idxLower] = indexes[idxUpper];
indexes[idxUpper] = tmp;
yield return indexes.Select(idx => items[idx]).ToList();
weights[idxUpper]++;
idxUpper = 1;
}
else
{
weights[idxUpper] = 0;
idxUpper++;
}
}
}
``````

And a unit test:

``````[TestMethod]
public void Permute()
{
var ints = new[] { 1, 2, 3 };
var orderings = ints.Permute().ToList();
Assert.AreEqual(6, orderings.Count);
AssertUtil.SequencesAreEqual(new[] { 1, 2, 3 }, orderings[0]);
AssertUtil.SequencesAreEqual(new[] { 2, 1, 3 }, orderings[1]);
AssertUtil.SequencesAreEqual(new[] { 3, 1, 2 }, orderings[2]);
AssertUtil.SequencesAreEqual(new[] { 1, 3, 2 }, orderings[3]);
AssertUtil.SequencesAreEqual(new[] { 2, 3, 1 }, orderings[4]);
AssertUtil.SequencesAreEqual(new[] { 3, 2, 1 }, orderings[5]);
}
``````

The method `AssertUtil.SequencesAreEqual` is a custom test helper which can be recreated easily enough.

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I've used the algorithms from here. The page contains a lot of useful information.

Edit: Sorry, those were recursive. uray posted the link to the iterative algorithm in his answer.

I've created a PHP example. Unless you really need to return all of the results, I would only create an iterative class like the following:

``````<?php
class Permutator implements Iterator
{
private \$a, \$n, \$p, \$i, \$j, \$k;
private \$stop;

public function __construct(array \$a)
{
\$this->a = array_values(\$a);
\$this->n = count(\$this->a);
}

public function current()
{
return \$this->a;
}

public function next()
{
++\$this->k;
while (\$this->i < \$this->n)
{
if (\$this->p[\$this->i] < \$this->i)
{
\$this->j = (\$this->i % 2) * \$this->p[\$this->i];

\$tmp = \$this->a[\$this->j];
\$this->a[\$this->j] = \$this->a[\$this->i];
\$this->a[\$this->i] = \$tmp;

\$this->p[\$this->i]++;
\$this->i = 1;
return;
}

\$this->p[\$this->i++] = 0;
}

\$this->stop = true;
}

public function key()
{
return \$this->k;
}

public function valid()
{
return !\$this->stop;
}

public function rewind()
{
if (\$this->n) \$this->p = array_fill(0, \$this->n, 0);
\$this->stop = \$this->n == 0;
\$this->i = 1;
\$this->j = 0;
\$this->k = 0;
}

}

foreach (new Permutator(array(1,2,3,4,5)) as \$permutation)
{
var_dump(\$permutation);
}
?>
``````

Note that it treats every PHP array as an indexed array.

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Below is my generics version of the next permutation algorithm in C# closely resembling the STL's next_permutation function (but it doesn't reverse the collection if it is the max possible permutation already, like the C++ version does)

In theory it should work with any IList<> of IComparables.

``````    static bool NextPermutation<T>(IList<T> a) where T: IComparable
{
if (a.Count < 2) return false;
var k = a.Count-2;

while (k >= 0 && a[k].CompareTo( a[k+1]) >=0) k--;
if(k<0)return false;

var l = a.Count - 1;
while (l > k && a[l].CompareTo(a[k]) <= 0) l--;

var tmp = a[k];
a[k] = a[l];
a[l] = tmp;

var i = k + 1;
var j = a.Count - 1;
while(i<j)
{
tmp = a[i];
a[i] = a[j];
a[j] = tmp;
i++;
j--;
}

return true;
}
``````

And the demo/test code:

``````        var src = "1234".ToCharArray();
do
{
Console.WriteLine(src);
}
while (NextPermutation(src));
``````
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How about a recursive algorithm you can call iteratively? If you'd actually need that stuff as a list like that (you should clearly inline that rather than allocate a bunch of pointless memory). You could simply calculate the permutation on the fly, by its index.

Much like the permutation is carry-the-one addition re-reversing the tail (rather than reverting to 0), indexing the specific permutation value is finding the digits of a number in base n then n-1 then n-2... through each iteration.

``````public static <T> boolean permutation(List<T> values, int index) {
return permutation(values, values.size() - 1, index);
}
private static <T> boolean permutation(List<T> values, int n, int index) {
if ((index == 0) || (n == 0))  return (index == 0);
Collections.swap(values, n, n-(index % n));
return permutation(values,n-1,index/n);
}
``````

The boolean returns whether your index value was out of bounds. Namely that it ran out of n values but still had remaining index left over.

And it can't get all the permutations for more than 12 objects. 12! < Integer.MAX_VALUE < 13!

-- But, it's so very very pretty. And if you do a lot of things wrong might be useful.

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