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I quote from Artificial Intelligence: A Modern Approach:

The properties of depth-first search depend strongly on whether the graph-search or tree-search version is used. The graph-search version, which avoids repeated states and redundant paths, is complete in finite state spaces because it will eventually expand every node. The tree-search version, on the other hand, is not complete [...]. Depth-first tree search can be modified at no extra memory cost so that it checks new states against those on the path from the root to the current node; this avoids infinite loops in finite state spaces but does not avoid the proliferation of redundant paths.

I don't understand how can graph-search be complete and tree-search be not, being a tree a particular graph.

Besides, I don't clearly get the difference between "infinite loops" and "redundant paths"...

May someone explain this to me?

ps. For those who have the book it's page 86 (3rd edition).

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1 Answer 1

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Depth-first tree search can get stuck in an infinite loop, which is why it is not "complete". Graph search keeps track of the nodes it has already searched, so it can avoid following infinite loops.

"Redundant paths" are different paths which lead from the same start node to the same end node. Graph search will still explore all these redundant paths, but once it reaches a node which it has visited before, it will not go any further, but will back up and look for more paths which it hasn't tried yet.

This is different from an "infinite loop" which is a path which leads from a node back to itself.

In response to your comment, look at the quote which you just posted:

Depth-first tree search can be modified at no extra memory cost so that it checks new states against those on the path from the root to the current node.

So while depth-first tree search does keep track of the path from the root to the current node, to avoid infinite loops, it needs to do a linear search over that path each time it visits a new node. If you wrote an implementation of depth-first tree search which didn't do that check, it could get into an infinite loop.

You are right, what the book said about the "proliferation of redundant paths" doesn't relate to completeness. It is just pointing out a difference between graph and tree search. Because tree search just keeps track of the current path, it can run over the same path more than once in the same search (even if doing the check I just mentioned).

Say your root node has 2 branches. Each of those branches leads to the same single node, which has a long path leading out from it. Tree search will follow that long path twice, once for each of the 2 branches which leads to it. That is what the author is pointing out.

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Even tree-search keeps track of the visited nodes (at least, from the root to the current node), thus I don't understand how can it get stuck in an infinite loop. Besides, I now understand the difference between "infinite loop" and "redundant path" (+1), but I don't think this is related with completeness since, even if the path is redundant, it will eventually find a goal node... –  Saphrosit Feb 12 '12 at 17:12
    
@Saphrosit, see my now edited answer. –  Alex D Feb 12 '12 at 17:20
    
Of course, if I do not check for repeated nodes I may get in an infinite loop. How can this be if I do check for repeated nodes? –  Saphrosit Feb 12 '12 at 17:28
    
If you do check for repeated nodes (in a depth-first tree search), you won't get into an infinite loop. That's what your textbook is saying. –  Alex D Feb 12 '12 at 18:27
    
So tree-search with occurrences check is actually complete? I think it's a little bit confusing that the book make a differentiation between graph-search and tree-search while it is enough to say "both are complete only with occurrences check". Seems he's pointing out a difference that does not exists... –  Saphrosit Feb 12 '12 at 21:51

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