# Depth First Search?

Forward edges lead to non-child descendants

• If a vertex leads to another vertex, by definition the second vertex is the first vertex's child. Therefore how can a vertex lead to a non-child? By definition a child of a vertex is something led to by it.

Cross edges lead to neither ancestor nor descendant

• If a vertex leads to another vertex, the second vertex is the first one's child. Therefore how can a cross edge lead to a non-descendant if by definition anything a vertex leads to is its child?

• How is the source picked? How does the DFS algorithm know where to start?

• Does the type of edge depend on where the algorithm starts? For example if the algorithm starts at vertex A and and ends at vertex Z, a edge from Z to A would be a back edge. Hower if the algorithm started at Z and ended at A, it would be a forward edge. Is my reasoning correct? Does the type of edge change on each run?

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-1 because I think lots of information is missing here. Where did you get those quotes from? What datastructure are we talking about? Can it have loops or is it a strict hierarchical structure? Where did you get that definition of a child? Is it from the definition of the datastructure you're talking about? –  Emil Vikström Jun 17 '12 at 19:37
@EmilVikstrom I got the quotes from the book Algorithms. My data structure is a graph. I am talking about both cyclical and acyclical graphs. –  fdh Jun 17 '12 at 19:39
The CLRS Introduction to Algorithms or some other book? I also think you should add this to your question because some people don't read the comments. –  Emil Vikström Jun 17 '12 at 19:46

If a vertex leads to another vertex, by definition the second vertex is the first vertex's child.

No; the "child" here refers to the tree representing the search space, not the graph which is "superimposed" on it to show the order of search. See the helpful illustration in Wikipedia.

Similar confusion for your other question.

The source is picked to reflect the problem. It continues until you arrive at an acceptable solution.

Let's say you're trying to see how to get from the bathroom to your bedroom. Your start node must be a bathroom then - the place where you are actually lost. You wander around the house, backing up and trying other doors, and when you find the bedroom (the solution), you stop. There are two graphs: one is the search tree; the other is the linear path of your search order. Actually three, if you include the problem space itself.

Problem space, with `<>` signifying bidirectional edges (all the doors in most peoples' houses can admit people in either direction):

``````            BATHROOM
<>
ENTRANCE <> HALLWAY  <>  DINING ROOM
<>
STAIRWAY <>  KIDS ROOM
<>
BEDROOM
``````

Search graph - a tree (`->` signify a mother-daughter relationship; in a tree, they are normally regarded as unidirectional)

``````Bathroom -> Hallway -> Entrance
-> Stairway -> Kids Room
-> Bedroom
-> Dining Room
``````

Search order - a linear graph showing how you traverse the tree.

``````Bathroom -> Hallway -> Entrance -> Stairway -> Kids Room -> Bedroom
``````

In a BFS, given the same graph, it would be:

``````Bathroom -> Hallway -> Entrance -> Stairway -> Dining Room -> Kids Room -> Bedroom
``````

The start node is set by the problem: "I'm in the bathroom". The goal node is also set by the problem: "I want to get to the bedroom".

In another problem: "I'm at a specific position in Othello. (start) I want to win. (goal)"

Note also that if I was lost in the hallway, I could still use DFS; you just translate the graph into a tree, and fix any edges as leading away from the start:

``````Hallway -> Entrance
-> Dining Room
-> Stairway -> Kids Room
-> Bedroom
-> Bathroom
``````
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What's the difference between a tree and a graph? Isn't th tree just a hierarchal representation of the graph? –  fdh Jun 17 '12 at 19:41
A tree is indeed a graph; but as you can see in my expanded answer, there are two graphs in what you're talking about, and one is a tree while the other is linear. –  Amadan Jun 17 '12 at 19:42
Riddler: Or again, I might have misunderstood your quote to mean something else; a descendant is not the same thing as a child. Every child is a descendant, but not every descendant is a child (notably, grandchildren are descendants, but are not children). –  Amadan Jun 17 '12 at 19:47
@Alexander: Oh, indeed. Any space in a connected graph can be a starting point. But for a majority of DFS problems, you have a starting position defined. Like in "find the bedroom from the bathroom" problem, or in "how to win this position of othello" problem. Also, DFS works on cyclic graphs just fine, as long as you remember where you've been to. –  Amadan Jun 17 '12 at 19:50
@Amadan, that was meant for Riddler. Sorry for the confusion. –  Alexander Jun 17 '12 at 19:58