I can think of three solutions, each with a different time\space tradeoff.

## n x n array

If you have a small number *n* of objects and a distance function D(n_{1}, n_{2}), you can compute the distances in advance.

Create a 2D n X n array. In array[i, j] store the result of D(n_{i}, n_{j}).

**Pros:**

- After the initial calculation, the answer for any two objects is given in O(1).
- Simplicity

**Cons:**

- inefficiency for large data sets
- Can't easily add new objects on-the-fly

## Memoization

Memoize your distance function to remember previous calls.

## R-Tree

The standard data structure for storing objects in 2D\3D Objects like Points and Polyhedrons is R-Trees. In short, your objects are grouped into 3D cubes of near-by items. It provides efficient insertion and lookup time of log(n) time, and threshold distance lookup is extremely efficient, especially when the answer is negative.

Quoting the Wikipedia article:

A common real-world usage for an R-tree might be to store ... polygons that typical maps
are made of: streets, buildings, outlines of lakes, coastlines, etc.
and then find answers quickly to queries such as "Find all museums
within 2 km of my current location", "retrieve all road segments
within 2 km of my location"

And:

The key idea of the data structure is to group nearby objects and
represent them with their minimum bounding rectangle in the next
higher level of the tree; the "R" in R-tree is for rectangle.

You have R-Tree implementations in most modern programming languages.

otherobject: take distance } - this is N*N-1 – CapelliC Feb 21 '12 at 7:59