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Which python package implements the Bellman-Ford shortest path algorithm?

Given a starting node i and an adjacency matrix G with negative weights I want to find the shortest path from i to another node j. E.g. my graph looks like:

import numpy
G = numpy.array([[ 0.  ,  0.55,  1.22],
                 [-0.54,  0.  ,  0.63],
                 [-1.3 , -0.63,  0.  ]])

I can only find an all-pairs shortest path implementation which seems too wasteful for my needs given my graph is large and I only need the shortest path for 1 pair of nodes. Performance will be important for me given I will use it for thousands of graphs.

Hence I'm looking around for a Bellman-Ford implementation -- has anyone seen one?

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  • This is off-topic (since it is asking for an off-site library or software tool). A Google search for "Bellman-Ford Python" has a great many hits, including several complete implementations (e.g. dzone.com/articles/bellman-ford-algorithm-python ). Why not start there? Oct 14, 2016 at 11:13

1 Answer 1

4

Rolled my own

def bellmanFord(source, weights):
    '''
    This implementation takes in a graph and fills two arrays
    (distance and predecessor) with shortest-path (less cost/distance/metric) information

    https://en.wikipedia.org/wiki/Bellman%E2%80%93Ford_algorithm
    '''
    n = weights.shape[0]

    # Step 1: initialize graph
    distance = np.empty(n)
    distance.fill(float('Inf'))      # At the beginning, all vertices have a weight of infinity
    predecessor = np.empty(n)
    predecessor.fill(float('NaN'))   # And a null predecessor

    distance[source] = 0             # Except for the Source, where the Weight is zero

    # Step 2: relax edges repeatedly
    for _ in xrange(1, n):
        for (u, v), w in np.ndenumerate(weights):
        if distance[u] + w < distance[v]:
        distance[v] = distance[u] + w
    predecessor[v] = u

    # Step 3: check for negative-weight cycles
    for (u, v), w in np.ndenumerate(weights):
        if distance[u] + w < distance[v]:
        raise ValueError("Graph contains a negative-weight cycle")

    return distance, predecessor
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  • Nice (+1). The link I gave above gives a fast vectorized version. It would be interesting to compare the two. Oct 14, 2016 at 11:37
  • @JohnColeman thanks, but the vectorized version only returns the optimal costs, not the paths. The predecessors information is internally lost after each iteration.
    – mchen
    Oct 15, 2016 at 11:43

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