Python - Graph Data Structure - How Do I Implement Breadth-First Search to Find Reachable Vertices Correctly

In Python, I have a Graph class that has a dictionary of vertex objects. Each vertex object has a dictionary of edges (which consist of a starting node, ending node, and a weight...imagine the end of arrow pointing to another node with a cost-to-travel number assigned to it).

With these classes, I'm graphing--well, a graph--for the time it takes for planes to fly from city to city. From this graph, I'm supposed to determine the shortest-path (fastest-path) between two nodes using Dijkstra's algorithm. I'm also supposed to determine all the vertices reachable from a starting vertex.

I'm able to add edges and delete edges (and consequently, add nodes) perfectly in the Graph. However, for the life of me, I can not seem to figure out a simple way to implement Dijkstra's algorithm or Breadth-First Search (to determine the reachable vertices) using the data structures I have created.

If anyone could suggest what I need to do to alter or implement these algorithms so that they work correctly, I would greatly appreciate any help. This is a homework assignment that I have been working on for nearly a week, many hours per day, and I just can't seem to get passed this wall. Again, I would appreciate any advice or help. I'm not expecting anyone to write code for me, but pseudocode would help (and applying it--copying and pasting pseudocode from Wikipedia won't help me out as I've already been there).

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You've looked at the simple description at the top of en.wikipedia.org/wiki/Dijkstra's_algorithm, right? –  thouis May 11 '11 at 8:30

Your code is way too complicated.

Start with a code just implementing the fundamentals and add features gradually. In order to get you started I'll post something simple but fundamental when handling graphs.

``````from collections import deque

class fringe(object):
def __init__(self, kind= 'stack'):
f= deque()
self._p= f.append if kind is 'stack' else f.appendleft
self._f= f

def __call__(self, item):
self._p(item)
return self

def __iter__(self):
while len(self._f):
item= self._f.pop()
yield item

def __repr__(self):
return self._f.__repr__().replace('deque', 'fringe')

def paths(G, start, terminal, F= fringe()):
for node, path in F((start, [start])):
for node in G[node]:
if node is terminal:
yield path+ [terminal]
elif node not in path:
F((node, path+ [node]))
``````

and a test:

``````if __name__ == '__main__':
a, b, c, d, e, f= 'A', 'B', 'C', 'D', 'E', 'F'
G= {a: [b, c], b: [c, d], c: [d], d: [c], e: [f], f: [c]}
print 'All paths from:', a, 'to:', d
print 'BFS'
for path in paths(G, a, d): print path
print 'DFS'
for path in paths(G, a, d, fringe('queue')): print path
``````

run will produce:

``````All paths from: A to: D
BFS
['A', 'C', 'D']
['A', 'B', 'D']
['A', 'B', 'C', 'D']
DFS
['A', 'B', 'D']
['A', 'C', 'D']
['A', 'B', 'C', 'D']
``````
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