# Interpreting graph as a hash table (python dict)

I understand simple directed graph interpretation like this:

``````graph = {1: [2], 2: [3], 3: [4, 5, 1], 4: [], 5: [4]}
#               1
#              / .
#             /   \
#            .     \
#       4--.3 ------.2
#        \  .
#         \ |
#          .5
``````

But do not know how to interpret dict of dicts, such as:

``````{1: {2: 3, 3: 8, 5: -4}, 2: {4: 1, 5: 7}, 3: {2: 4}, 4: {1: 2, 3: -5}, 5: {4: 6}}
``````

Is it weighted graph? How should I understand this kind of graphs write?

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Where did your dictionary structure come from? Either: 1) you defined the structure yourself, and the question is moot, or 2) someone else built the structure, and failed to document what it represented. Without having produced that structure, there is no way to know how to interpret it. Closing as too localized. –  Eric Jun 2 '13 at 16:43

Yes, it's a directed graph with weighted edges. The following graph

is represented as..

``````L = {'A': {'C':2, 'D':6}, 'B': {'D':8, 'A':3},
'C': {'D':7, 'E':5}, 'D': {'E':-2}, 'E': {}}
``````
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Thanks, got it) –  I159 Jun 2 '13 at 16:10

This is a weighted edge directed graph. You can also use graphviz to visualize your particular data:

``````nestedg={1: {2: 3, 3: 8, 5: -4},
2: {4: 1, 5: 7},
3: {2: 4},
4: {1: 2, 3: -5},
5: {4: 6}}

with open('/tmp/graph.dot','w') as out:
for line in ('digraph G {','size="16,16";','splines=true;'):
out.write('{}\n'.format(line))
for start,d in nestedg.items():
for end,weight in d.items():
out.write('{} -> {} [ label="{}" ];\n'.format(start,end,weight))
out.write('}\n')
``````

Which produces this graphical representation:

You could use something like Dijkstra's Algorithm to navigate paths through it. An example use would be for routing with certain routes having a greater 'cost':

``````def find_all_paths(graph, start, end, path=[]):
path = path + [start]
if start == end:
return [path]
if start not in graph:
return []
paths = []
for node in graph[start]:
if node not in path:
newpaths = find_all_paths(graph, node, end, path)
for newpath in newpaths:
paths.append(newpath)
return paths

def min_path(graph, start, end):
paths=find_all_paths(graph,start,end)
mt=10**99
mpath=[]
print '\tAll paths from {} to {}: {}'.format(start,end,paths)
for path in paths:
t=sum(graph[i][j] for i,j in zip(path,path[1::]))
print '\t\tevaluating: {}, cost: {}'.format(path, t)
if t<mt:
mt=t
mpath=path

e1=' '.join('{}->{}:{}'.format(i,j,graph[i][j]) for i,j in zip(mpath,mpath[1::]))
e2=str(sum(graph[i][j] for i,j in zip(mpath,mpath[1::])))
print 'Best path: '+e1+'   Total: '+e2+'\n'

if __name__ == "__main__":
nestedg={1: {2: 3, 3: 8, 5: -4},
2: {4: 1, 5: 7},
3: {2: 4},
4: {1: 2, 3: -5},
5: {4: 6}}

min_path(nestedg,1,5)
min_path(nestedg,1,4)
min_path(nestedg,2,1)
``````

Using your data, some example routes through the graph are:

``````    All paths from 1 to 5: [[1, 2, 5], [1, 3, 2, 5], [1, 5]]
evaluating: [1, 2, 5], cost: 10
evaluating: [1, 3, 2, 5], cost: 19
evaluating: [1, 5], cost: -4
Best path: 1->5:-4   Total: -4

All paths from 1 to 4: [[1, 2, 4], [1, 2, 5, 4], [1, 3, 2, 4], [1, 3, 2, 5, 4], [1, 5, 4]]
evaluating: [1, 2, 4], cost: 4
evaluating: [1, 2, 5, 4], cost: 16
evaluating: [1, 3, 2, 4], cost: 13
evaluating: [1, 3, 2, 5, 4], cost: 25
evaluating: [1, 5, 4], cost: 2
Best path: 1->5:-4 5->4:6   Total: 2

All paths from 2 to 1: [[2, 4, 1], [2, 5, 4, 1]]
evaluating: [2, 4, 1], cost: 3
evaluating: [2, 5, 4, 1], cost: 15
Best path: 2->4:1 4->1:2   Total: 3
``````
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