# given a graph to detect if it is a tree or not in directed and undirected graphs?

I would like to know of a fast algorithm to determine if a given graph is a tree or not. This post seems to deal with it, but not very clear. According to this, if the graph is acyclic, then it is a tree. if you consider the examples of directed and undirected graph shown, in my opinion only 1 and 4 are tree, but 3 is neither cyclic nor a tree I suppose.

so my question is: what needs to be checked to see if a graph is a tree or not for both directed and undirected graph in efficient way?

taking one step ahead to see, if a tree exists then is it a binary tree or not?

• A quick note, the linked question does deal with only the undirected case. My understanding is that you wanted to deal with the directed case? In the directed case, there are also other cases to worry about (is `A -> B <- C` a tree?). – Dennis Meng Dec 13 '13 at 0:27

For a directed graph:

• Find the vertex with only outgoing edges (if there is more than one or no such vertex, fail).

• Do a BFS or DFS from that vertex. If you encounter an already visited vertex, it's not a tree.

• If you're done and there are unexplored vertices, it's not a tree - the graph is not connected.

• Otherwise, it's a tree.

• To check for a binary tree, additionally check if each vertex has at most 2 outgoing edges.

For an undirected graph:

• Check for a cycle with a simple depth-first search (starting from any vertex) - "If an unexplored edge leads to a node visited before, then the graph contains a cycle." If there's a cycle, it's not a tree.

• If the above process leaves some vertices unexplored, it's not a tree, because it's not connected.

• Otherwise, it's a tree.

• To check for a binary tree, additionally check that all vertices have 1-3 edges (one to the parent and 2 to the children).

Checking for the root, i.e. whether one vertex contains 1-2 edges, is not necessary as there has to be vertices with 1-2 edges in an acyclic connected undirected graph.

Note that identifying the root is not generically possible (it may be possible in special cases) as, in many undirected graphs, more than one of the nodes can be made the root if we were to make it a binary tree.

• regarding point 1 : I could have a private `OutgoingEdge` array field in the Vertex class, such that when each edge is added to graph, I can update this field. for every vertex, I check if this array length is > 1. if it is, it is not a tree.. – brain storm Dec 13 '13 at 1:59
• regarding point 2: this is nothing but cycle detection right? any specific reason for BFS over DFS – brain storm Dec 13 '13 at 2:06
• regarding point 3: I can get this information from my `outgoingEdge` array field if its length is <=2 – brain storm Dec 13 '13 at 2:07
• as you mention checking for the root in undirected acyclic connected graph is not essential, because there are possible of multiple nodes that could act as roots? – brain storm Dec 13 '13 at 2:13
• `#1` Makes sense, this is typically how adjacency lists work, which is mostly used in graph implementations. `#2` Yes, I believe you can also use DFS, no particular reason for picking BFS. `#3` Yes. Yes, in many cases multiple nodes could act as the root. – Dukeling Dec 13 '13 at 2:41