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How do you trace the path of a Breadth-first search such that in the following example:

If searching for key 11, return the shortest list connecting 1 to 11.

return [1,4,7,11]
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10  
Why does this feel like homework? –  Peter Rowell Jan 19 '12 at 6:55
    
It was actually an old assignment I was helping a friend on months ago, based on the Kevin Bacon Law. My final solution was very sloppy, I basically did another Breadth-first search to "rewind" and backtrack. I wan't to find a better solution. –  Christopher Markieta Jan 19 '12 at 6:58
3  
Excellent. I consider revisiting an old problem in an attempt to find a better answer to be an admirable trait in an engineer. I wish you well in your studies and career. –  Peter Rowell Jan 19 '12 at 17:14
    
Thanks for the praise, I just believe if I don't learn it now, I will be faced with the same problem again. –  Christopher Markieta Jan 20 '12 at 6:23

2 Answers 2

up vote 43 down vote accepted
+50

You should have look at http://en.wikipedia.org/wiki/Breadth-first_search first.

Below is a quick implementation, in which I used a list of list to represent the queue of paths.

# graph is in adjacent list representation
graph = {
        '1': ['2', '3', '4'],
        '2': ['5', '6'],
        '5': ['9', '10'],
        '4': ['7', '8'],
        '7': ['11', '12']
        }

def bfs(graph, start, end):
    # maintain a queue of paths
    queue = []
    # push the first path into the queue
    queue.append([start])
    while queue:
        # get the first path from the queue
        path = queue.pop(0)
        # get the last node from the path
        node = path[-1]
        # path found
        if node == end:
            return path
        # enumerate all adjacent nodes, construct a new path and push it into the queue
        for adjacent in graph.get(node, []):
            new_path = list(path)
            new_path.append(adjacent)
            queue.append(new_path)

print bfs(graph, '1', '11')

Another approach would be maintaining a mapping from each node to its parent, and when inspecting the ajacent node, record its parent. When the search is done, simply backtrace according the parent mapping.

graph = {
        '1': ['2', '3', '4'],
        '2': ['5', '6'],
        '5': ['9', '10'],
        '4': ['7', '8'],
        '7': ['11', '12']
        }

def backtrace(parent, start, end):
    path = [end]
    while path[-1] != start:
        path.append(parent[path[-1]])
    path.reverse()
    return path


def bfs(graph, start, end):
    parent = {}
    queue = []
    queue.append(start)
    while queue:
        node = queue.pop(0)
        if node == end:
            return backtrace(parent, start, end)
        for adjacent in graph.get(node, []):
            parent[adjacent] = node # <<<<< record its parent 
            queue.append(adjacent)

print bfs(graph, '1', '11')

EDIT: the above codes are based on the assumption that there's no cycles.(thanks to @roberking).

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1  
This is excellent! My thought process lead me to believe in creating some type of table or matrix, I have yet to learn about graphs. Thank you. –  Christopher Markieta Jan 19 '12 at 7:04
    
I also tried using a back tracing approach although this seems much cleaner. Would it be possible to make a graph if you only know the start and the end but none of the nodes in-between? Or even another approach besides graphs? –  Christopher Markieta Jan 19 '12 at 7:19
    
@ChristopherM I failed to understand your question :( –  qiao Jan 19 '12 at 7:30
    
If we know the start node is "1" and the end node is "11" but the other nodes are unknown until we begin to search them; such that the graph is dynamic and will still work even if the tree had 100 nodes. For ex: { '1': [a, b, c], a: [d, e], d: [f, g], c: [h, i], h: [11, k] } –  Christopher Markieta Jan 19 '12 at 7:45
    
@ChristopherM As long as the adjacent nodes are being determined when a node is reached, then the above algorithm will be fine. –  qiao Jan 19 '12 at 8:01

I thought i'd try code this up for fun:

graph = {
        '1': ['2', '3', '4'],
        '2': ['5', '6'],
        '5': ['9', '10'],
        '4': ['7', '8'],
        '7': ['11', '12']
        }

    def bfs(graph,for_front,end):
        #assumes no cycles.
        next_for_front=[(node,path+','+node) for i,path in for_front if i in graph for node in graph[i]]
        for node,path in next_for_front:
            if node==end:
                return path
        else:
            return bfs(graph,next_for_front,end)

    print bfs(graph,[('1','1')],'11')

    #>>>
    #1,4,7,11

if you want cycles you could add this:

for i,j in for_front: #allow cycles, add this code
        if i in graph:
            del graph[i]
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2  
+1, you reminded me of one thing: assume no cycles :) –  qiao Jan 19 '12 at 8:35
    
Where would you add this piece of code? –  Liondancer Dec 3 '13 at 13:25
    
after you have built the next_for_front. A follow on question, what if the graph contains loops? E.g. if node 1 had an edge connecting back to itself? What if the graph has multiple edges going between two nodes? –  robert king Dec 3 '13 at 21:33

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