First, consider the following variation of the serial algorithm. Take the element `a`

, and assign it to the subset #0 (this is always valid, because the order of subsets inside a partition does not matter). The next element `b`

might belong either to the same subset as `a`

or to a different one, i.e. to subset #1. Then, the element `c`

belongs to either #0 (together with `a`

) or #1 (together with `b`

if it's separate from `a`

), or to its own subset (which will be #1 if #0={`a`

,`b`

}, or #2 if #0={`a`

} and #1={`b`

}). And so on. So you add new elements one by one to partially built partitions, producing a few possible outputs for each input - until you put all the elements. The key to parallelization is that each incomplete partition can be appended with new elements independently, i.e. in parallel with, all other variants.

The algorithm can be implemented in different ways. I would use a recursive approach, in which a function is given a partially filled array and its current length, copies the array as many times as there are possible values for the next element (which is one more than the current last value of the array), sets the next element to every possible value and calls itself recursively for each new array, with increased length. This approach seems particularly good for work-stealing parallel engines, such as cilk or tbb. An implementation similar to suggested by @swen is also possible: you use a collection of all incomplete partitions and a pool of threads, and each thread takes one partition from the collection, produces all possible extensions and put those back to the collection; partitions with all elements added should obviously go into a different collection.