# Decompose cyclic graph into minimal number of shortest path subgraphs

Given a cyclic graph, I'm looking for an algorithm that decomposes this graph into acyclic subgraphs. Each of these subgraphs would have a root vertex, where this vertex was the source from which the shortest path was computed. For example, given the cyclic graph below, where the cycle is between 3,4, and 5:

``````                      +-------------------------+
|                         |
|                         |
+----------+----------+              |
v          |          v              |
+---+     +---+      +---+      +---+     +---+  |
| 1 | --> | 3 | <--> | 4 | <--> | 5 | --> | 6 |  |
+---+     +---+      +---+      +---+     +---+  |
^                         |
|                         |
|                         |
+---+                       |
| 2 |                       |
+---+                       |
+---+                       |
| 7 | <---------------------+
+---+
``````

The shortest path subgraph with respect to 1 would be:

``````+---+     +---+     +---+     +---+
| 1 | --> | 3 | --> | 4 | --> | 7 |
+---+     +---+     +---+     +---+
|
|
v
+---+     +---+
| 5 | --> | 6 |
+---+     +---+
``````

The shortest path subgraph with respect to 2 would be:

``````          +---+
| 7 |
+---+
^
|
|
+---+     +---+     +---+     +---+
| 2 | --> | 4 | --> | 5 | --> | 6 |
+---+     +---+     +---+     +---+
|
|
v
+---+
| 3 |
+---+
``````

The shortest path sugraph with respect to 5 would be:

``````+---+     +---+     +---+     +---+
| 6 | <-- | 5 | --> | 4 | --> | 7 |
+---+     +---+     +---+     +---+
|
|
v
+---+
| 3 |
+---+
``````

Notice that the shortest path subgraph with respect to 3 is a subset of 1's, 4 is a subset of 2's. 6 and 7 are leafs.

My current (naive) solution would be to perform a BFS for each node, flagging nodes as visited to prevent cycles. Then to check if the subgraphs are subsets of each other to create the minimal number of distinct subgraphs. Any ideas for a better, more formal, solution?

EDIT The graph in my situation is unweighted, but having the general solution for posterity is nice.

-

templatetypedef, OP's use of "BFS" suggests that the graph is unweighted.

Here's an algorithm that runs in time proportional to the sum, for each root in the final collection, of the size of the subgraph reachable from that root. For, say, graphs of bounded degree, this is on the order of the size of the output.

For the sake of uniqueness I'm going to assume that "shortest path" means least in length-lex order. At a high-level, we compute an order in which to process the vertices so that if vertex u's BFS tree subsumes vertex v's, then u is ordered before v. Each vertex is processed in linear time, which includes determining the vertices it subsumes.

The order is computed by finding the strong components, topologically sorting the strong components, and then ordering the vertices within each single component arbitrarily. Clearly u subsumes v only if the set of vertices reachable from u is a proper superset of the vertices reachable from v.

To process a vertex u, compute the BFS tree from u and then determine the set of vertices whose subtrees have no arc leaving the subtree - these are the ones that get subsumed. Determine the latter by traversing the tree depth-first, recording, for each vertex v, an interval I(v) whose left endpoint is the entry time and whose right endpoint is the exit time. For each vertex v, compute the smallest interval J(v) containing I(v) and all I(w) with an arc v->w. Using DFS, compute, for each vertex v, the smallest interval K(v) containing K(w) for all descendants w of v. A vertex v other than u is subsumed if and only if K(v) = I(v).

Why should this work? We know that v's subtree of the tree rooted at u is a subset of the tree rooted at v. Suppose that u subsumes v (in other words, these two trees are equal). Then clearly the head of every arc from v's subtree goes to v's subtree, as otherwise, the head should have been explored. Conversely, suppose that u does not subsume v. The tree rooted at v contains a vertex not in v's subtree, and thus there's an arc leaving v's subtree.

I hope this description is useful to you, but I fear that your actual question involves fast point-to-point shortest path queries with subquadratic space, for which there might be better approaches.

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@comestibles- I found a paper where someone came up with an extremely fast algorithm for APSP in unweighted graphs and added it to my answer. Also, I'm a little skeptical about your algorithm because I don't think your definition of "subsumes" is necessarily correct. Just because u can reach the same set of vertices as v doesn't mean that the BFS tree from v will be contained in the BFS tree for u. Or am I wrong about this? –  templatetypedef Aug 25 '11 at 21:14
@templatetypedef I said "Clearly u subsumes v only if ...", not if and only if. In other words, it's possible that there's a path from u to v but u doesn't subsume v. The false positives are weeded out in the second phase. Also, the paper you linked is about saving time; if the OP was willing to run all of the BFSes anyway, it seems as if time isn't the issue, but only OP can tell us for sure. –  comestibles Aug 25 '11 at 21:32
@comestibles- Ah, my mistake, I misread that. Looking over this, it seems like in the worst case you would need to run O(n) different iterations of the BFS, which would give a runtime of O(n(n + m)) = O(n^2 + nm), which is better than the iterated Dijkstra's on graphs where m = o(n log n) and better than Floyd-Warshall for graphs where m = o(n^2). Very nice! –  templatetypedef Aug 25 '11 at 21:35
@comestibles The actual problem involves applying a mathematical function at each node. Previously I performed a BFS, storing the results of each function application in the queue with additional book-keeping to break cycles. By decomposing the graph into the acyclic subgraphs I'll increase my memory usage by having more graphs, but should decrease the memory usage on a per-input basis to virtually nothing assuming tail-recursion. –  tgoodhart Aug 25 '11 at 23:38
@comestibles As I finally get around to trying to implement this, I'm wondering if there is a typo and that K(v) is defined as the smallest interval containing all J(w) (not K(w)) for all descendants w of v? –  tgoodhart Sep 12 '11 at 19:49