All the sets in question are subsets of a known finite set, say {0..10^4}.

Let's call this N = 10^4. This is reasonably small, and this will prove useful. Let's say you have S sets.

'Logically' this means you have an N*S matrix.

You will already have a set of sets. There are S sets in this primary structure.

10^4 is sufficiently small that you could maintain a *secondary* data structure which stores, for each the N values, the list of *sets* that it is in. This structure is sort of like the transpose of the primary structure. This could be a vector of length N, allowing constant time lookup to find the list of sets that a particular value is in.

Now, when you add a new set, it will be possible to use this secondary structure to find which other sets each of its values are in. For example, we add a new set with values 2,5, 10

```
new_set = {2,5,10}
```

The secondary structure tells us which sets they are in:

```
2 : {A,B,D}
5 : {B,D}
10 : {B}
```

We can merge and sort these three lists to get `ABBBDD`

which tells us not only which sets it overlaps with, but the size of the overlaps. Three nodes are shared with B, which means that our new set is a subset of, or equal to, B. We share 1 node with A, and two nodes with D. If it turns out that the total size of A is 1, then we now know that A is a subset of our new set.