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Given two sorted vectors a and b, find all vectors which are sums of a and some permutation of b, and which are unique once sorted.

You can create one of the sought vectors in the following way:

  • Take vector a and a permutation of vector b.
  • Sum them together so c[i]=a[i]+b[i].
  • Sort c.

I'm interested in finding the set of b-permutations that yield the entire set of unique c vectors.

Example 0: a='ccdd' and b='xxyy'
Gives the summed vectors: 'cycydxdx', 'cxcxdydy', 'cxcydxdy'.
Notice that the permutations of b: 'xyxy' and 'yxyx' are equal, because in both cases the "box c" and the "box d" both get exactly one 'x' and one 'y'.

I guess this is similar to putting M balls in M boxes (one in each) with some groups of balls and boxes being identical.
Update: Given a string a='aabbbcdddd' and b='xxyyzzttqq' your problem will be 10 balls in 4 boxes. There are 4 distinct boxes of size 2, 3, 1 and 4. The balls are pair wise indistinguishable.

Example 1: Given strings are a='xyy' and b='kkd'.
Possible solution: 'kkd', 'dkk'.
Reason: We see that all unique permutations of b are 'kkd', 'kdk' and 'dkk'. However with our restraints, the two first permutations are considered equal as the indices on which the differ maps to the same char 'y' in string a.

Example 2: Given strings are a='xyy' and b='khd'.
Possible solution: 'khd', 'dkh', 'hkd'.

Example 3: Given strings are a='xxxx' and b='khhd'.
Possible solution: 'khhd'.

I can solve the problem of generating unique candidate b permutations using Narayana Pandita's algorithm as decribed on Wikipedia/Permutation.
The second part seams harder. My best shot is to join the two strings pairwise to a list, sort it and use it as a key in a lookup set. ('xx'+'hd' join→'xh','xd' sort→'xd','xh').

As my M is often very big, and as similarities in the strings are common, I currently generate way more b permutations than actually goes through the set filter. I would love to have an algorithm generating the correct ones directly. Any improvement is welcome.

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I'm really having trouble understanding your constraint and the examples. Can you rephrase it more formally? The wording is also a little hard to understand (e.g. "the indices on which the differ maps to the same char"). –  John Feminella Jun 18 '10 at 23:24
Also having a hard time on this. Maybe you consider b[i] equal to b[j] if a[i] == a[j]?! So in example 1 with i=1 and j=2 because both are 'y' in a they are considered equal in b? –  Eiko Jun 18 '10 at 23:37
I'm not sure I understand your question. Can you put the first sentence into a complete sentence? –  Justin L. Jun 19 '10 at 8:14
Ok, I've cleared up the first part again. @Eiko: In example one i=1 and j=2 and a[i]=a[j]. Thus permutations which only differ in i of j are equal. –  Thomas Ahle Jun 19 '10 at 23:37

2 Answers 2

To generate k-combinations of possibly repeated elements (multiset), the following could be useful: A Gray Code for Combinations of a Multiset (1995).

For a recursive solution you try the following:

Count the number of times each character appears. Say they are x1 x2 ... xm, corresponding to m distinct characters.

Then you need to find all possible ordered pairs (y1 y2 ... ym) such that

0 <= yi <= xi

and Sum yi = k.

Here yi is the number of times character i appears.

The idea is, fix the number of times char 1 appears (y1). Then recursively generate all combinations of k-y1 from the remaining.


List Generate (int [] x /* array index starting at 1*/, 
               int k /* size of set */) {

    list = List.Empty;

    if (Sum(x) < k) return list;

    for (int i = 0; i <= x[1], i++) {

        // Remove first element and generate subsets of size k-i.

        remaining = x.Remove(1);

        list_i = Generate(remaining, k-i);

        if (list_i.NotEmpty()) {

            list = list + list_i;    

        } else {

            return list;


    return list;


If I understood it correctly, you need to look at string a, see the symbols that appear exactly once. Say there are k such symbols. Then you need to generate all possible permutations of b, which contain k elements and map to those symbols at the corresponding positions. The rest you can ignore/fill in as you see fit.

I remember posting C# code for that here: http://stackoverflow.com/questions/2350211/how-to-find-permutation-of-k-in-a-given-length/2350399#2350399

I am assuming xxyy will give only 1 unique string and the ones that appear exactly once are the 'distinguishing' points.

Eg in case of a=xyy, b=add

distinguishing point is x

So you select permuations of 'add' of length 1. Those gives you a and d.

Thus add and dad (or dda) are the ones you need.

For a=xyyz b=good

distinguishing points are x and z

So you generate permutations of b of length 2 giving


giving you 7 unique permutations.

Does that help? Is my understanding correct?

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No sorry, Is my new explaination better? –  Thomas Ahle Jun 19 '10 at 8:17
+1 because I understood the same thing ... –  belisarius Jun 19 '10 at 8:20
No, the solution doesn't work. That seams clear for a case where there are no unique symbols in a? –  Thomas Ahle Jun 19 '10 at 23:27
@THomas: For no unique symbols, there is exactly one generated by this method. Anyway, this was before the edits you made. Perhaps you should give longer/more examples (with what output you expect) to make it clearer. –  Aryabhatta Jun 20 '10 at 1:12
If you see example 0, you'll notice that a='xxyy', b='ccdd' gives three unique solutions. –  Thomas Ahle Jun 20 '10 at 6:11
up vote 0 down vote accepted

Ok, I'm sorry I never was able to clearly explain the problem, but here is a solution.

We need two functions combinations and runvector(v). combinations(s,k) generates the unique combinations of a multiset of a length k. For s='xxyy' these would be ['xx','xy','yy']. runvector(v) transforms a multiset represented as a sorted vector into a more simple structure, the runvector. runvector('cddeee')=[1,2,3].

To solve the problem, we will use recursive generators. We run through all the combinations that fits in box1 and the recourse on the rest of the boxes, banning the values we already chose. To accomplish the banning, combinations will maintain a bitarray across of calls.

In python the approach looks like this:

def fillrest(banned,out,rv,b,i):
    if i == len(rv):
        yield None
    for comb in combinations(b,rv[i],banned):
        out[i] = comb
        for rest in fillrest(banned,out,rv,b,i+1):
            yield None

def balls(a,b):
    rv = runvector(a)
    banned = [False for _ in b]
    out = [None for _ in rv]
    for _ in fill(out,rv,0,b,banned):
        yield out[:]

>>> print list(balls('abbccc','xyyzzz'))
[['x', 'yy', 'zzz'],
 ['x', 'yz', 'yzz'],
 ['x', 'zz', 'yyz'],
 ['y', 'xy', 'zzz'],
 ['y', 'xz', 'yzz'],
 ['y', 'yz', 'xzz'],
 ['y', 'zz', 'xyz'],
 ['z', 'xy', 'yzz'],
 ['z', 'xz', 'yyz'],
 ['z', 'yy', 'xzz'],
 ['z', 'yz', 'xyz'],
 ['z', 'zz', 'xyy']]

The output are in 'box' format, but can easily be merged back to simple strings: 'xyyzzzz', 'xyzyzz'...

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If you're done with the question you should accept your own answer. –  Greg Kuperberg Jun 29 '10 at 20:10

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