I have a directed graph with millions of vertices and edges. A set of vertices are given, let's assume that they are called "START_POINTS". Another set of vertices, called "END_POINTS" are also given. The problem is to find which END_POINTS can be reached from which START_POINTS.
Here is an example:
START_POINTS: S1 S2 S3 S4 S5 S6 S7 ... END_POINTS : E1 E2 E3 E4 E5 E6 E7 ...
The algorithm should be able tell the following:
S1 can reach to E1, E2, E6 S2 can reach to E9, E10 S3 cannot reach any END_POINT S4 can reach to ..... ....
Some of the END_POINTS might not be reached from any START_POINT.
Now, the question is: What is the most efficient way to implement it?
I tried starting from each START_POINT one-by-one and finding the reachable END_POINTS using depth-first search (or BFS, it does change the run-time much). However, it takes a lot of time because there are so many START_POINTS (there are also a lot of END_POINTS).
The search can be optimized because there is a huge overlap between the traced paths of START_POINTS. One needs to remember which paths can reach which END_POINTS. What is the most efficient way to accomplish this? This might be well-known problem but I could not find a solution yet.
EDIT on Jan 6:
I tried to implement highBandWidth's idea (in a way similar to what Keith Randall proposed) : For each node, if this node is not START or END point, connect all of inputs to outputs, then remove the node.
foreach NODE in NODES Skip if NODE is START_POINT or END_POINT foreach OUTPUT_NODE of NODE Disconnect NODE from INPUT_NODE end foreach INPUT_NODE of NODE Disconnect NODE from INPUT_NODE foreach OUTPUT_NODE of NODE Connect INPUT_NODE to OUTPUT_NODE end end Remove NODE from NODES end
This starts very fast and quickly becomes very slow, mainly because the input/output counts of remaining nodes get very large and nested for loops kills the performance. Any idea how it can be made more efficient?