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When Traversing a Tree/Graph what is the difference between Breadth First and Depth first? Any coding or pseudocode examples would be great.

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Did you check wikipedia (depth first, breadth first)? There are code examples on those pages, along with lots of pretty pictures. – rmeador Mar 26 '09 at 22:03
up vote 155 down vote accepted

These two terms differentiate between two different ways of walking a tree.

It is probably easiest just to exhibit the difference. Consider the tree:

   / \
  B   C
 /   / \
D   E   F

A depth first traversal would visit the nodes in this order

A, B, D, C, E, F

Notice that you go all the way down one leg before moving on.

A breadth first traversal would visit the node in this order

A, B, C, D, E, F

Here we work all the way across each level before going down.

(Note that there is some ambiguity in the traversal orders, and I've cheated to maintain the "reading" order at each level of the tree. In either case I could get to B before or after C, and likewise I could get to E before or after F. This may or may not matter, depends on you application...)

Both kinds of traversal can be achieved with the pseudocode:

Store the root node in Container
While (there are nodes in Container)
   N = Get the "next" node from Container
   Store all the children of N in Container
   Do some work on N

The difference between the two traversal orders lies in the choice of Container.

  • For depth first use a stack. (The recursive implementation uses the call-stack...)
  • For breadth-first use a queue.

The recursive implementation looks like

   Work on the payload Node
   Foreach child of Node
   /* Alternate time to work on the payload Node (see below) */

The recursion ends when you reach a node that has no children, so it is guaranteed to end for finite, acyclic graphs.

At this point, I've still cheated a little. With a little cleverness you can also work-on the nodes in this order:

D, B, E, F, C, A

which is a variation of depth-first, where I don't do the work at each node until I'm walking back up the tree. I have however visited the higher nodes on the way down to find their children.

This traversal is fairly natural in the recursive implementation (use the "Alternate time" line above instead of the first "Work" line), and not too hard if you use a explicit stack, but I'll leave it as an exercise.

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@dmckee Thanks! I believe you meant "Work on the payload at Node," right? – batbrat Feb 13 '12 at 6:42
It may worth noting that you can modify the depth-first version to get prefix (A, B, D, C, E, F - the first one presented), infix (D, B, A, E, C, F - used for sorting: add as an AVL tree then read infix) or postfix (D, B, E, F, C, A the alternative presented) traversal. The names are given by the position in which you process the root. It should be noted that infix only really makes sense for binary trees. @batbrat those are the names... given the time since you asked, you probably already know. – Theraot Nov 1 '15 at 13:27
@Theraot thanks for adding that in! Yes, I do know about these kinds of traversals and why Infix makes sense only for binary trees. – batbrat Nov 18 '15 at 9:28
How to decide which solution has a better space or time complexity? – Igor Ganapolsky Mar 10 at 1:42
@IgorGanapolsky Should be the same for both on principle (after all, they use essentially the same code). A more interesting question would be how they impact the cache and working set, but I think that will depend on the morphology of the tree. – dmckee Mar 10 at 1:45

I would like to share some notes that I took down while learning this:

Understanding the terms:

This picture should give you the idea about the context in which the words breadth and depth are used.

Understanding Breadth and Depth

Depth-First Search:

Depth-First Search

  • Depth-first search algorithm acts as if it wants to get as far away from the starting point as quickly as possible.

  • It generally uses a Stack to remember where it should go when it reaches a dead end.

  • Rules to follow: Push first vertex A on to the Stack

    1. If possible, visit an adjacent unvisited vertex, mark it as visited, and push it on the stack.
    2. If you can’t follow Rule 1, then, if possible, pop a vertex off the stack.
    3. If you can’t follow Rule 1 or Rule 2, you’re done.
  • Java code:

    public void searchDepthFirst() {
        // Begin at vertex 0 (A)
        vertexList[0].wasVisited = true;
        while (!stack.isEmpty()) {
            int adjacentVertex = getAdjacentUnvisitedVertex(stack.peek());
            // If no such vertex
            if (adjacentVertex == -1) {
            } else {
                vertexList[adjacentVertex].wasVisited = true;
                // Do something
        // Stack is empty, so we're done, reset flags
        for (int j = 0; j < nVerts; j++)
            vertexList[j].wasVisited = false;
  • Application: Depth-first searches are often used in simulations of games (and game-like situations in the real world). In a typical game you can choose one of several possible actions. Each choice leads to further choices, each of which leads to further choices, and so on into an ever-expanding tree-shaped graph of possibilities.

Breadth-First Search:

Breadth-First Search

  • The breadth-first search algorithm likes to stay as close as possible to the starting point.
  • This kind of search is generally implemented using a Queue.
  • Rules to follow: Make starting Vertex A the current vertex
    1. Visit the next unvisited vertex (if there is one) that’s adjacent to the current vertex, mark it, and insert it into the queue.
    2. If you can’t carry out Rule 1 because there are no more unvisited vertices, remove a vertex from the queue (if possible) and make it the current vertex.
    3. If you can’t carry out Rule 2 because the queue is empty, you’re done.
  • Java code:

    public void searchBreadthFirst() {
        vertexList[0].wasVisited = true;
        int v2;
        while (!queue.isEmpty()) {
            int v1 = queue.remove();
            // Until it has no unvisited neighbors, get one
            while ((v2 = getAdjUnvisitedVertex(v1)) != -1) {
                vertexList[v2].wasVisited = true;
                // Do something
        // Queue is empty, so we're done, reset flags
        for (int j = 0; j < nVerts; j++) 
            vertexList[j].wasVisited = false;
  • Application: Breadth-first search first finds all the vertices that are one edge away from the starting point, then all the vertices that are two edges away, and so on. This is useful if you’re trying to find the shortest path from the starting vertex to a given vertex.

Hopefully that should be enough for understanding the Breadth-First and Depth-First searches. For further reading I would recommend the Graphs chapter from an excellent data structures book by Robert Lafore.

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