I'm looking for a data structure that roughly corresponds to (in Java terms)
Map<Set<int>, double>. Essentially a set of sets of labeled marbles, where each set of marbles is associated with a scalar. I want it to be able to efficiently handle the following operations:
- Add a given integer to every set.
- Remove every set that contains (or does not contain) a given integer, or at least set the associated double to 0.
- Union two of the maps, adding together the doubles for sets that appear in both.
- Multiply all of the doubles by a given double.
- Rarely, iterate over the entire map.
under the following conditions:
- The integers will fall within a constrained range (between 1 and 10,000 or so); the exact range will be known at compile-time.
- Most of the integers within the range (80-90%) will never be used, but which ones will not be easily determinable until the end of the calculation.
- The number of integers used will almost always still be over 100.
- Many of the sets will be very similar, differing only by a few elements.
- It may be possible to identify certain groups of integers that frequently appear only in sequential order: for example, if a set contains the integers 27 and 29 then it (almost?) certainly contains 28 as well.
- It may be possible to identify these groups prior to running the calculation.
- These groups would typically have 100 or so integers.
I've considered tries, but I don't see a good way to handle the "remove every set that contains a given integer" operation.
The purpose of this data structure would be to represent discrete random variables and permit addition, multiplication, and scalar multiplication operations on them. Each of these discrete random variables would ultimately have been created by applying these operations to a fixed (at compile-time) set of independent Bernoulli random variables (i.e. each takes the value 1 or 0 with some probability).
The systems being modeled are close to being representable as a time-inhomogeneous Markov chains (which would of course simplify this immensely) but, unfortunately, it is essential to track the duration since various transitions.