If I may suggest an alternative - **I would have reduced the problem and use DFS instead of modifying DFS**.

Given a graph `G = (V,E)`

, cretae a graph `G' = (V,E')`

where `E'={(u,v) | there is w in V such that (u,w) and (w,v) are in E)`

In other words - we are creating a graph G', which has edge (u,v) if and only if there is a path of length 2 from u to v.

Given that graph, we can derive the following **algorithm [high level pseudo-code]**:

- Create G' from G
- run DFS on G' from the source
`s`

, and mark the same nodes DFS marked.

Correctness and time complexity analysis of the solution:

**Complexity:**
The complexity is obviously `O(min{|V|^2,|E|^2} + |V|)`

, because of part 1 - since there are at most `min{|E|^2,|V|^2}`

edges in G', so DFS on step 2 runs in `O(|E'| + |V|) = O(min{|V|^2,|E|^2} + |V|)`

**Correctness:**

If the algorithm found that there is a path from v0 to vk, then from the correctness of DFS - there is a path v0->v1->...->vk on G', so there is a path `v0->v0'->v1->v1'->...->vk`

of even length on G.

If there is a path of even length on `G`

from `v0`

to `vk`

, let it be `v0->v1->...->vk`

. then `v0->v2->...->vk`

is a path on `G'`

, and will be found by DFS - from the correctness of DFS.

**As a side note:**

Reducing problems instead of modifying algorithms is usually less vulnurable to bugs, and easier to analyze and prove correctness on, so you should usually prefer these over modifying algorithms when possible.

**EDIT:** regarding your solution: Well, analysing it shows they are both pretty much identical - with the exception of I was generating `E'`

as pre-processing, and you are generating it on the fly, in each iteration.

Since your solution is generating the edges on the fly - it might to doing some work more then once. However, it is bounded to the job at most `|V|`

times more, since each vertex is being visited at most once.

Assuming `|E| = O(|V|^2)`

for simplicity, giving us total an upper bound for the run time of `O(|V|^3)`

for your solution.

It is also a lower bound, look at the example of a clique, During each `visit()`

of any node, the algorithm will do `O(|V|^2)`

to generate all possibilities, and `visit()`

one of the possibilities, since we visit exactly `|V|`

nodes, we get total run time of `Omega(|V|^3)`

Since we found the solution is both `O(|V|^3)`

and `Omega(|V|^3)`

, it is total of `Theta(O(|V|^3))`