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Given an undirected graph G = (V, E), such that u, v, w are some edges in G.

Describe an algorithm to determine whether

"if there is a path from u to w that passes through v"

A simple algorithm for that using DFS is given below:

bool checkFunction(){

  graph g; // containing u, w, v
  dfs(v);

  if(isVisited(u) && isVisited(w))
    return true;
  else
    return false;
   
}

For the above algorithm,

  • time complexity : O(V+E)
  • space complexity : O(V)

But can we reduce the time complexity?

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    There are abundant tutorials on the internet about this. You also didn't show any effort to at least initiate the solution (i.e. by showing what you have done so far). Jul 9 '20 at 5:21
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    First of all, welcome to SO @AnupamKumar. Please edit to add useful information like links about the techniques you already know and you mentioned; research that you did; and why not a minimal reproducible code in your language, so that we can experiment too, based on your initial approach. This will encourage more people to try to solve your question.
    – Basj
    Nov 21 '20 at 22:40
14

Note: This post doesn't provide a solution to the question posted, but it does provide some information regarding common mistakes one can make while solving such problems.

(This post also assumes paths to not allow duplicate vertices. If you remove this constraint, the problem can be solved easily by finding a path from u to v, and a path from v to w and just concatenating these 2 paths to get a walk from u to w passing through v. This can be achieved by running BFS once from u and once from v)

The answer given by amit isn't correct.


Edit:
The below counter example is incorrect, see the comment by Steve. I have provided another counter example after this one.
Consider a counter example.
V = {u, v, w, x}
E = {{u,v}, {u,w}, {u,x}, {v,x}, {w,x}}
Then, the path (u,v,x,w) is a valid path.
Now lets say we apply BFS on w, the corresponding paths (not unique) we get from w to u and w to v will be (w,u) and (w, u, v)
Now, the "path" (v,u,w,u) has a repeated node u, so it's not a path.


Another counter example:
Consider V = {u,v,w,x,y,z} E = {{u,x}, {v,x}, {x,w}, {v,y}, {y,z}, {z,w}}
A BFS Tree from w will have the edges {{w,x}, {w,z}, {x,u}, {x,v}} (we treat u,v as sinks)
This gives the "path" {u,x,w,x,v} which is invalid

The answer by Matt is also incorrect.

A path exists iff u, v, and w are in the same connected component.

Consider a line graph {w, u, v}, then all these 3 lie in the same connected component, but there is no path from u to w that passes through v


This problem (for undirected graphs) is also stated here (See problem 7), which I think is a reputable source, so we can safely assume that there does exist an efficient algorithm for this.
This also argues for the existence of a solution, as well as provides an algorithm.
For directed graphs, this is a "hard" problem.

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    Please note that this Answer is being discussed on meta in Is an answer that says that other answers are wrong not an answer?. If you have a solution to the problem, it would be very helpful, if you added it to your Answer here :)
    – Scratte
    Nov 20 '20 at 18:21
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    Undeleting this because (A) it might contain useful information, and (B) it's currently being discussed on Meta, and it's unreasonable to discuss the deletion of an answer when that answer has already been mod-deleted. If you have an opinion about why this answer should or should not be deleted, please post on the Meta question that Scratte linked (do not leave a comment here). Thank you!
    – Cody Gray
    Nov 21 '20 at 1:52
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    The way I was taught, paths which allow repetition are called walks (mathworld.wolfram.com/Walk.html). I agree it depends on convention, but finding a u-v-w walk is hardly an interesting problem. Nov 21 '20 at 13:32
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    in a line graph {v, u, w}, there is a path [u,v,u,w] that passes through v. There was no requirement that paths must be simple. Also, you should really comment on my answer if you want to say that it's wrong. Nov 21 '20 at 14:49
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    For some reason you assume a path with repeated nodes is "not a path". It is, it is not a simple path - but it is a path. The question does not ask for simple paths. Thus, the counter example you provide, does not hold.
    – amit
    Nov 21 '20 at 18:59
2

Without any more constraints, there aren't any available optimizations that aren't kind of obvious.

A path exists iff u, v, and w are in the same connected component. That can be easily determined by running a BFS or DFS from any one to see if it finds the other two.

For some graphs there is an opportunity to do better when a path does not exist and one of the vertices is in a small connected component. You can do a single BFS from your initial 3 vertices, and when you discover a new vertex, remember which source it came from. You will also find connections when you discover a redundant edge from, for example, a u vertex to a v vertex. If you run out of edges from any one source before all 3 are connected, then you can stop, because you know that that vertex is isolated.

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A naive way to do it is just to find all paths you can take from u to w, and then see if v exists in one of those sets.

Or just see if a path exists from u to v and a path exists from v to w

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  • A good option but those are very expensive algorithms and are not optimized. It will take a lot of space and time in complicated networks.
    – anon
    Jul 5 '20 at 17:17
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Do a BFS starting from u. Stop it when you find v.

Now, do a BFS from v. Stop it when you find w and return true.

If you don't find v in the first BFS or w in the second BFS, it means there is no path from u to w passing through v and you can stop the prodecure returning false.

Complexity: O(|V| + |E|)

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Since the graph is undirected, simply do a BFS starting from w.

This ensures that if you find paths w->...->u and w->...->v, there is also a path v->...->w->...->u, which is also the shortest path with these restrictions

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  • Rightly said, can we do a bfs from v & it visits both u and w. That would work too.
    – anon
    Nov 21 '20 at 18:33
  • @superbrain Title explicitly says: Determine whether there is a path from vertex **u to v passing through w**
    – amit
    Nov 21 '20 at 18:54
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    @amit Ah, right, title disagrees with the body. Sigh. Why do people do that... Nov 21 '20 at 19:05