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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
2  
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

5 Answers 5

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:
        return 
    while l[i] - 1 >= l[i + 1] + 1:
        l[i]        -= 1
        l[i + 1]    += 1
        result.append(list(l))
        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.

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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

Port of @GJJ code in PHP.

<?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);
    while(successor($n,&$l))
    {
        $result[] = $l;
    }
    return $result;
}
?>
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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 = []
  results.append(list(l))
  while successor(n, l):
    results.append(list(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;
        }
        results.Add(l.ToArray());
        return;
    }

    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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Given that you ask this out of interest, you would probably be interested an authorative answer! It can be found in "7.2.1.2 - 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

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