I've been trying to figure out a way to generate all distinct size-n partitions of a multiset, but so far have come up empty handed. First let me show what I'm trying to archieve.

Let's say we have an input vector of `uint32_t`

:

```
std::vector<uint32_t> input = {1, 1, 2, 2}
```

An let's say we want to create all distinct 2-size partitions. There's only two of these, namely:

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

Note that order does not matter, i.e. all of the following are duplicate, incorrect solutions.

Duplicate because order within a permutation group does not matter:

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

Duplicate because order of groups does not matter:

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

Not homework of some kind BTW. I encountered this while coding something at work, but by now it is out of personal interest that I'd like to know how to deal with this. The parameters for the work-related problem were small enough that generating a couple thousand duplicate solutions didn't really matter.

# Current solution (generates duplicates)

In order to illustrate that I'm not just asking without having tried to come up with a solution, let me try to explain my current algorithm (which generates duplicate solutions when used with multisets).

It works as follows: the state has a bitset with n bits set to 1 for each partition block. The length of the bitsets is `size(input) - n * index_block()`

, e.g. if the input vector has 8 elements and n = 2, then the first partition block uses an 8-bit bitset with 2 bits set to 1, the next partition block uses a 6-bit bitset with 2 bits set to 1, etc.

A partition is created from these bitsets by iterating over each bitset in order and extracting the elements of the input vector with indices equal to the position of 1-bits in the current bitset.

In order to generate the next partition, I iterate over the bitsets in reverse order. The next bitset permutation is calculated (using a reverse of Gosper's hack). If the first bit in the current bitset is not set (i.e. vector index 0 not selected), then that bitset is reset to its starting state. Enforcing that the first bit is always set prevents generating duplicates when creating size-n set partitions (duplicates of the 2nd kind shown above). If the current bitset is equal to its starting value, this step is then repeated for the previous (longer) bitset.

This works great (and very fast) for sets. However, when used with multisets it generates duplicate solutions, since it is unaware that both elements appear more than once in the input vector. Here's some example output:

```
std::vector<uint32_t> input = {1, 2, 3, 4};
printAllSolutions(myCurrentAlgo(input, 2));
=> [[2, 1], [4, 3]], [[3, 1], [4, 2]], [[4, 1], [3, 2]]
std::vector<uint32_t> input = {1, 1, 2, 2};
printAllSolutions(myCurrentAlgo(input, 2));
=> [[1, 1], [2, 2]], [[2, 1], [2, 1]], [[2, 1], [2, 1]]
```

That last (duplicate) solution is generated simply because the algorithm is unaware of duplicates in the input, it generates the exact same internal states (i.e. which indices to select) in both examples.

# Wanted solution

I guess it's pretty clear by now what I'm trying to end up with. Just for the sake of completeness, it would look somewhat as follows:

```
std::vector<uint32_t> multiset = {1, 1, 2, 2};
MagicClass myGenerator(multiset, 2);
do {
std::vector<std::vector<uint32_t> > nextSolution = myGenerator.getCurrent();
std::cout << nextSolution << std::endl;
} while (myGenerator.calcNext());
=> [[1, 1], [2, 2]]
[[1, 2], [1, 2]]
```

I.e. the code would work somewhat like `std::next_permutation`

, informing that is has generated all solutions and has ended back at the "first" solution (for whatever definition of first you want to use, probably lexicographically, but doesn't need to be).

The closest related algorithm I found is Algorithm M from Knuth's The Art of Computer Programming, Volume 4 Part 1, section 7.2.1.5 (p. 430). However, that generates all possible multiset partitions. There is also an exercise in the book (7.2.1.5.69, solution on p. 778) about how to modify Alg. M in order to generate only solutions with at most r partitions. However, that still allows partitions of different sizes (e.g. `[[1, 2, 2], [1]]`

would be a valid output for r = 2).

Any ideas/tricks/existing algorithms on how to go about this? Note that the solution should be efficient, i.e. keeping track of all previously generated solutions, figuring out if the currently generated one is a permutation and if so skipping it, is infeasible because of the rate by which the solution space explodes for longer inputs with more duplicates.