I'm trying to write code that will traverse an undirected, unweighted graph. Essentially, the method will be passed a node (which knows all its neighbors). The method then has to build a model of the graph as efficiently* by going from node to node and collecting information which nodes link to each other. At the end, the method will have a complete list of all the nodes and all the vertices that connect them.
*The crux of the problem lies in the word efficiently and what I mean by it. Let me direct your attention to this small graph:
Let's say I start at node G. I can either visit C, B, F, D, H, J or E. I want to minimize the amount of times I visit a node and in order to visit a node, I must pass through all nodes on the way to that node.
Example: let's say I decide to visit node C. The next node to visit could be either A, B, F, D, H, J or E. However, to visit any node except for A, I would have to pass through G again which is considered inefficient. And in order to visit A, I would have to visit G and C again and then pass through C and then G to get back to the rest of the graph. So I decide to visit A. This means I have to pass through C again to reach G. Thus, from a logical point of view, it makes sense to visit the C branch last.
However, the program, when it starts at Node G, is unaware that branch C leads to a dead-end. As I write this, I think it might be impossible, but I ask it anyways: is there anyway to traverse this graph as efficiently as possible (as I have previously defined it) using only the information given (i.e. that the program only knows about the nodes its visited and the edges emanating from those nodes? Or should I just go with a variation Dijkstra's algorithm in order to insure I visit every node?
This will all be written in Java if that matters.