## The problem

I am given N arrays of C booleans. I want to organize these into a datastructure that allows me to do the following operation as fast as possible: Given a new array, return true if this array is a "superset" of any of the stored arrays. With superset I mean this: A is a superset of B if A[i] is true for every i where B[i] is true. If B[i] is false, then A[i] can be anything.

Or, in terms of sets instead of arrays:

**Store N sets (each with C possible elements) into a datastructure so you can quickly look up if a given set is a superset of any of the stored sets.**

Building the datastructure can take as long as possible, but the lookup should be as efficient as possible, and the datastructure can't take too much space.

## Some context

I think this is an interesting problem on its own, but for the thing I'm really trying to solve, you can assume the following:

- N = 10000
- C = 1000
- The stored arrays are sparse
- The looked up arrays are random (so not sparse)

## What I've come up with so far

**For O(NC) lookup**: Just iterate all the arrays. This is just too slow though.**For O(C) lookup**: I had a long description here, but as Amit pointed out in the comments, it was basically a BDD. While this has great lookup speed, it has an exponential number of nodes. With N and C so large, this takes too much space.

I hope that in between this O(N*C) and O(C) solution, there's maybe a O(log(N)*C) solution that doesn't require an exponential amount of space.

## EDIT: A new idea I've come up with

**For O(sqrt(N)C) lookup**: Store the arrays as a prefix trie. When looking up an array A, go to the appropriate subtree if A[i]=0, but visit**both**subtrees if A[i]=1.My intuition tells me that this should make the (average) complexity of the lookup O(sqrt(N)C), if you assume that the stored arrays are random. But: 1. they're not, the arrays are sparse. And 2. it's only intuition, I can't prove it.

I will try out both this new idea and the BDD method, and see which of the 2 work out best.

But in the meantime, doesn't this problem occur more often? Doesn't it have a name? Hasn't there been previous research? It really feels like I'm reinventing the wheel here.