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?