I'm faced with a handling of IDs in a way that I never tackled before. I don't think there is some amazing solution to this but I thought I might as well ask.

I have a hash-table of objects.

Each is identified by an id which is, for the sake of demonstration, a number. Although it is actually a GUID.

The number of objects is unlimited, and for the sake of this exercise on the scale of billions.

The application logic defines that translations exist between groups of IDs.
For example the group of IDs `{4, 7, 12}`

can be defined to be translated to `{5, 16}`

.
Every ID can be present in any number of grouping translations.
A group from a grouping translation can be translated to multiple other groups but each is a translation rule by it self, independent of the others.
A group in a grouping translation can contain from 1 ID to tens of thousands. Empty groups are not allowed.
Self translations like `{3} => {3}`

or `{5, 17} => {5, 17}`

are allowed.
There is no mathematical or otherwise calculable relation between IDs or groups, They are arbitrarily defined.

I'm looking for a data structure and/or search algorithm that can perform the translation. The speed of querying a group for translation is critical and must be O(1) or very close to it.

Adding or removing translations from the index can be performed at scheduled maintenance sessions and does not have to be very fast, although it has to be fast enough to be practical to execute at up to, say, 20%-30% downtime.

Memory usage is irrelevant for the sake of this discussion. Assume that the same scale of storage needed to store the hash-table of IDs is available many times more.

Known algorithms, Ideas, Suggestions, Proofs that this is impossible are all welcome.

`{3,7}`

and the rule`{3}=>{5}`

, do I need to translate to`{5,7}`

? – Keith Randall Sep 27 '12 at 23:46