# How to find the shortest path satisfying constraints on a graph

I'm trying to find the shortest path on a weighted graph given the constraint that the path must have a total distance less than some parameter (let's say 1000).

I tried the following but I don't know why my code is wrong.

def directedDFS(digraph, start, end, maxTotalDist):
visited = []
if not (digraph.hasNode(start) and digraph.hasNode(end)):
raise ValueError('Start or end not in graph.')
path = [str(start)]
if start == end:
return path
shortest = None
for node in digraph.childrenOf(start):
if (str(node) not in visited):
visited = visited + [str(node)]
firststep_distance = digraph.childrenOf(start)[node][0]
firststep_outer_distance = digraph.childrenOf(start)[node][1]
if (firststep_distance <= maxTotalDist):
newPath = directedDFS(digraph, node, end, maxTotalDist-firststep_distance)
if newPath == None:
continue
if (shortest == None or TotalDistance(digraph,newPath) < TotalDistance(digraph,shortest)):
shortest = newPath
if shortest != None:
path = path + shortest
else:
path = None
return path


Another thing is that I don't want to compare based on the distance of the path starting from the given node but based on the distance of the ENTIRE PATH from the original starting point. I don't know the best way to do that here though.

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Do you mean the shortest in terms on the number of hops, or the distance (the latter is trivial so I'm guessing it's the former)? –  NPE May 6 '11 at 16:12
Are you trying to find the path containing the fewest edges where the total path cost (the sum of its edge weights) is less than 1000? –  Josh Rosen May 7 '11 at 3:15

I really can't make heads or tails of the code you provided (firststep_distance? firststep_outer_distance?). Could you provide the name of the algorithm you're trying to implement?

If you're just making something up on the fly, and you're not doing with the goal of reinventing graph theory for educational purposes, I'd suggest looking up a standard shortest-path algorithm. If you can guarantee that your weights are non-negative, then the standard is Dijkstra's algorithm. Wikipedia will report an improved asymptotic runtime if you back it with a Fibonacci heap, but don't fall for that trap---apparently, Fibonacci heaps have horrible performance in practice.

If Dijkstra's isn't good enough, take a look into A*-search methods. Here, as in all algorithm questions, CLR is your best guide, but Wikipedia is damn close. Hope that helps!

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I also can't really tell what's going on without more code or info, but this is concerning:

        if (firststep_distance <= maxTotalDist):
newPath = directedDFS(digraph, node, end, maxTotalDist-firststep_distance)


If you are decreasing the maxTotalDistance in each recursive call, then firststep_distance (which I assume is the weight of the path) must be greater than the remaining distance, not less.

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Nope, firststep_distance is the weight of the first step in the path. I should have clarified that. –  Glassjawed May 6 '11 at 16:27
I misspoke, by weight of the path, I mean the weight of the edge from start to node. –  dfb May 6 '11 at 16:34