Let's say we have a fully connected directed graph `G`

. The vertices are `[a,b,c]`

. There are edges in both directions between each vertex.

Given a starting vertex `a`

, I would like to traverse the graph in all directions and save the path only when I hit a vertex which is already in the path.

So, the function `full_paths(a,G)`

should return:

```
- [{a,b}, {b,c}, {c,d}]
- [{a,b}, {b,d}, {d,c}]
- [{a,c}, {c,b}, {b,d}]
- [{a,c}, {c,d}, {d,b}]
- [{a,d}, {d,c}, {c,b}]
- [{a,d}, {d,b}, {b,c}]
```

I do not need 'incomplete' results like `[{a,b}]`

or `[{a,b}, {b,c}]`

, because it is contained in the first result already.

Is there any other way to do it except of generating a powerset of G and filtering out results of certain size?

How can I calculate this?

**Edit**: As Ethan pointed out, this could be solved with depth-first search method, but unfortunately I do not understand how to modify it, making it store a path before it backtracks (I use Ruby Gratr to implement my algorithm)