Interesting question, I never heard of this problem, probably because I don't have much background in this topic, nor much experience with NetworkX. However, I do have a idea for a algorithm. This may just be the most naive way to do this and I'd be glad to hear of a cleverer algorithm.

The idea is that you can use your restriction rules to transform you graph to a new graph where all edges are valid, using the following algorithm.

The restriction of path (1,2,3) can be split in two rules:

- If you came over (1,2) then remove (2,3)
- If you leave over (2,3) then remove (1,2)

To put this in the graph you can insert copies of node 2 for each case. I'll call the new nodes **1_2** and **2_3** after the valid edge in the respective case. For both nodes, you copy all incoming and outgoing edges minus the restricted edge.

For example:

```
Nodes = [1,2,3,4]
Edges = [(1,2),(2,3),(4,2)]
```

The valid path shall only be 4->2->3 not 1->2->3. So we expand the graph:

```
Nodes = [1,1_2,2_3,3,4] # insert the two states of 2
Edges = [ # first case: no (1_2,3) because of the restriction
(1,1_2), (4, 1_2)
# 2nd case, no (1,2_3)
(2_3,3), (4,2_3)]
```

The only valid path in this graph is 4->2_3->3. This simply maps to 4->2->3 in the original graph.

I hope this answer can at least help you if you find no existing solution. Longer restriction rules would blow up the graph with a exponentially growing number of state nodes, so either this algorithm is too simple, or the problem is hard ;-)