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I'm searching for an algorithm that generates all permutations of fixed-length partitions of an integer. Order does not matter.

For example, for n=4 and length L=3:

[(0, 2, 2), (2, 0, 2), (2, 2, 0),
 (2, 1, 1), (1, 2, 1), (1, 1, 2),
 (0, 1, 3), (0, 3, 1), (3, 0, 1), (3, 1, 0), (1, 3, 0), (1, 0, 3),
 (0, 0, 4), (4, 0, 0), (0, 4, 0)]

I bumbled about with integer partitions + permutations for partitions whose length is lesser than L; but that was too slow because I got the same partition multiple times (because [0, 0, 1] may be a permutation of [0, 0, 1] ;-)

Any help appreciated, and no, this isn't homework -- personal interest :-)

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Shouldn't permutations of (2, 1, 1) be in that list? – Martin Broadhurst Nov 10 '10 at 16:43
I knew I forgot something. Thanks, added. – deleted77 Nov 10 '10 at 17:08
Permutions of integer partitions are called "compositions". – Martin Broadhurst Nov 10 '10 at 18:04
Would it be simpler to first generate all ordered permutations (4,0,0),(3,1,0),(2,2,0),(2,1,1) and then generate all permutations of those? – Svein Bringsli Nov 29 '10 at 12:42
You say that order doesn't matter, but then your answer has entries which are identical except for ordering. Which part is wrong? – bukzor Aug 1 '11 at 2:21
up vote 2 down vote accepted

Okay. First, forget about the permutations and just generate the partitions of length L (as suggested by @Svein Bringsli). Note that for each partition, you may impose an ordering on the elements, such as >. Now just "count," maintaining your ordering. For n = 4, k = 3:

(4, 0, 0)
(3, 1, 0)
(2, 2, 0)
(2, 1, 1)

So, how to implement this? It looks like: while subtracting 1 from position i and adding it to the next position maintains our order, subtract 1 from position i, add 1 to position i + 1, and move to the next position. If we're in the last position, step back.

Here's a little python which does just that:

def partition_helper(l, i, result):
    if i == len(l) - 1:
    while l[i] - 1 >= l[i + 1] + 1:
        l[i]        -= 1
        l[i + 1]    += 1
        partition_helper(l, i + 1, result)

def partition(n, k):
    l = [n] + [0] * (k - 1)
    result = [list(l)]
    partition_helper(l, 0, result)
    return result

Now you have a list of lists (really a list of multisets), and generating all permutations of each multiset of the list gives you your solution. I won't go into that, there's a recursive algorithm which basically says, for each position, choose each unique element in the multiset and append the permutations of the multiset resulting from removing that element from the multiset.

share|improve this answer
I tried running this solution, and it didn't work for me for most cases; it did n=4 & l=3, but few others. I'm need an algorithm for the subset where n=l, and this algorithm didn't produce the (1,1,1,...) solution for any case except n=2. I tried to make it work, but ultimately had to make a whole new solution (below). – pbarranis Jul 2 '12 at 12:38

Given that you ask this out of interest, you would probably be interested an authorative answer! It can be found in " - Generating all permutations" of Knuth's The Art of Computer Programming (subvolume 4A).

Also, 3 concrete algorithms can be found here.

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Hear hear! If you're into these kinds of problems, that subvolume contains many, many more variations. The solutions Knuth proposes are a feast for the mind: Very elegant and clever. – Arjen Kruithof Apr 6 '11 at 1:43

As noted by @pbarranis, the code by @rlibby does not include all lists when n equals k. Below is Python code which does include all lists. This code is non-recursive, which may be more efficient with respect to memory usage.

def successor(n, l):
  idx = [j for j in range(len(l)) if l[j] < l[0]-1]
  if not idx:
    return False

  i = idx[0]
  l[1:i+1] = [l[i]+1]*(len(l[1:i+1]))
  l[0] = n - sum(l[1:])
  return True

def partitions(n, k):
  l = [0]*k
  l[0] = n
  results = []
  while successor(n, l):
  return results

The lists are created in colexicographic order (algorithm and more description here).

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Like I mentioned above, I couldn't get @rlibby's code to work for my needs, and I needed code where n=l, so just a subset of your need. Here's my code below, in C#. I know it's not perfectly an answer to the question above, but I believe you'd only have to modify the first method to make it work for different values of l; basically add the same code @rlibby did, making the array of length l instead of length n.

public static List<int[]> GetPartitionPermutations(int n)
    int[] l = new int[n];

    var results = new List<int[]>();

    GeneratePermutations(l, n, n, 0, results);
    return results;

private static void GeneratePermutations(int[] l, int n, int nMax, int i, List<int[]> results)
    if (n == 0)
        for (; i < l.Length; ++i)
            l[i] = 0;

    for (int cnt = Math.Min(nMax, n); cnt > 0; --cnt)
        l[i] = cnt;
        GeneratePermutations(l, (n - cnt), cnt, i + 1, results);
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Port of @GJJ code in PHP.

function successor($n, array &$l)
    $index = array_values(array_filter(range(0, count($l)-1), function ($value) use ($l) { return ($l[$value] < ($l[0]-1)); }));
    if (!$index)
        return false;

    $i = $index[0];
    array_splice($l, 1, $i, array_fill(0, count(array_slice($l, 1, $i)), $l[$i]+1));
    $l[0] = $n - array_sum(array_slice($l,1));
    return true;

function partitions($n, $k)
    $l = array_fill(0,$k,0);
    $l[0] = $n;
    $result = array($l);
        $result[] = $l;
    return $result;
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