Fast path cache generation for a connected node graph

I'm trying to get a faster pathfinding mechanism in place in a game I'm working on for a connected node graph. The nodes are classed into two types, "Networks" and "Routers."

In this picture, the blue circles represent routers and the grey rectangles networks.

Each network keeps a list of which routers it is connected to, and vice-versa. Routers cannot connect directly to other routers, and networks cannot connect directly to other networks.

Networks list which routers they're connected to

Routers do the same

I need to get an algorithm that will map out a path, measured in the number of networks crossed, for each possible source and destination network excluding paths where the source and destination are the same network. I have one right now, however it is unusably slow, taking about two seconds to map the paths, which becomes incredibly noticeable for all connected players.

The current algorithm is a depth-first brute-force search (It was thrown together in about an hour to just get the path caching working) which returns an array of networks in the order they are traversed, which explains why it's so slow. Are there any algorithms that are more efficient?

As a side note, while these example graphs have four networks, the in-practice graphs have 55 networks and about 20 routers in use. Paths which are not possible also can occur, and as well at any time the network/router graph topography can change, requiring the path cache to be rebuilt.

What approach/algorithm would likely provide the best results for this type of a graph?

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If needed I can provide the code used to build the cache at the time the question was asked –  Sukasa Jun 1 '10 at 5:18

Dijkstra's shortest path algorithm is the classic, but is only designed for static graphs.

You can try searching the web for dynamic shortest past algorithms.

Here is one paper which seems relevant: http://www.utdallas.edu/~edsha/papers/bin/Globecom04_SPT.pdf (and might give you other leads).

This paper describes a network of routers, where each router maintains it's own Shortest Path Table. Perhaps you can do something similar.

I suggest you also look at routing algorithms in general as taking the shortest path always might cause congestion etc (I am thinking 16 team Halo!). You might also want to incorporate load balancing etc.

Hope it helps.

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In the context of the network, traffic levels/etc are not relevant, as it is only a simple high-level simulation. The game is coded in a language compiled to bytecode and then interpreted, so the functions need to be relatively lightweight (And the code that moves pathables from one network to another is about as efficient as it'll get without removing functionality). As long as I can quickly build any valid path or quickly determine no such path exists (Or some compromise of the two), I'm happy. –  Sukasa Jun 2 '10 at 22:25
@Sukasa: You might find splitting your graph into bi-connected components useful, then. –  Aryabhatta Jun 2 '10 at 23:28
@Moron could you perhaps give a bit more info? The wikipedia article on them leaves me a little unsure –  Sukasa Jun 3 '10 at 3:01
@Sukasa: A bi-connected (or 2-connected) component is a graph where there are at least two disjoint paths between each pair of vertices. So if you split your graph into 2-connected components, and then find the 'edge' networks/routers it might speed up things a little. For instance to get from component A to C, you might have to go through component B, if you know the edge connectors, then you might quickly be able to find a path. It will take at least 2 edge deletions before you (possibly) need to do some remapping. It was just an idea which I thought you might find useful. –  Aryabhatta Jun 3 '10 at 3:23
@Sukasa: Also, you might find the Other Algorithms section of en.wikipedia.org/wiki/Biconnected_component useful, which talks about a dynamic bi-connected components algorithm (by Westbrook and Tarjan). –  Aryabhatta Jun 3 '10 at 3:27

You might want to look in the classical networking domain. This isn't the exact answer, but should give you a starting point for "better than brute force" algorithms.

http://en.wikipedia.org/wiki/Dijkstra%27s_algorithm

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