list of all paths from source to sink in directed acyclic graph [duplicate]

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[python]: path between two nodes

Can anyone point me to some resources on how to do this? I'm using `networkx` as my python library.

Thanks!

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marked as duplicate by Jeff Atwood♦Apr 16 '11 at 21:12

Are you guaranteed that there is only one source that all node changes eventually lead back to, and there is only one sink that all node chains eventually lead to? Or are the source and sink part of a larger graph that extends to things that lead from the source, or lead into the sink? – Omnifarious Jul 19 '10 at 5:15
Hmmm. I don't exactly know what you mean by node change, but there are finite X distinct sources and very finite Y distinct sinks – Tyler Jul 19 '10 at 5:21
@Tyler - And the goal is given a distinct source, find all paths to a distinct sink? – Omnifarious Jul 19 '10 at 7:16
@Omnifarious Yes. That's it. :) – Tyler Jul 19 '10 at 7:34
@Tyler - I gave an algorithm that should work, though I haven't tested it. It's more clearly correct than Alex's I think, and there's a fairly simple optimization that could be made. – Omnifarious Jul 19 '10 at 7:36

This is based on Alex Martelli's answer, but it should work. It depends on the expression `source_node.children` yielding an iterable that will iterate over all the children of `source_node`. It also relies on there being a working way for the `==` operator to compare two nodes to see if they are the same. Using `is` may be a better choice. Apparently, in the library you're using, the syntax for getting an iterable over all the children is `graph[source_node]`, so you will need to adjust the code accordingly.

``````def allpaths(source_node, sink_node):
if source_node == sink_node: # Handle trivial case
return frozenset([(source_node,)])
else:
result = set()
for new_source in source_node.children:
paths = allpaths(new_source, sink_node, memo_dict)
for path in paths:
path = (source_node,) + path
result = frozenset(result)
return result
``````

My main concern is that this does a depth first search, it will waste effort when there are several paths from the source to a node that's a grandchild, great grandchild, etc all of source, but not necessarily a parent of sink. If it memoized the answer for a given source and sink node it would be possible to avoid the extra effort.

Here is an example of how that would work:

``````def allpaths(source_node, sink_node, memo_dict = None):
if memo_dict is None:
# putting {}, or any other mutable object
# as the default argument is wrong
memo_dict = dict()

if source_node == sink_node: # Don't memoize trivial case
return frozenset([(source_node,)])
else:
pair = (source_node, sink_node)
return memo_dict[pair]
else:
result = set()
for new_source in source_node.children:
paths = allpaths(new_source, sink_node, memo_dict)
for path in paths:
path = (source_node,) + path
result = frozenset(result)
memo_dict[(source_node, sink_node)] = result
return result
``````

This also allows you to save the memoization dictionary between invocations so if you need to compute the answer for multiple source and sink nodes you can avoid a lot of extra effort.

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Cool. Can you explain to me how you did this? – Tyler Jul 19 '10 at 5:10
@Tyler, yeah, I'm trying to remember exactly how it went. :-) – Omnifarious Jul 19 '10 at 5:11
Awesome, this would be really useful. – Tyler Jul 19 '10 at 5:14
@Tyler - I realized that the algorithm I wrote only bears a passing resemblance to what you want. I'm going to think about this really hard for a bit, but in the meantime I'm deleting my answer. – Omnifarious Jul 19 '10 at 5:22
I'm getting `TypeError: can only concatenate tuple (not "instance") to tuple` with `path = (source_node,) + path` – Tyler Jul 19 '10 at 12:00

This one actually works with networkx, and it's non-recursive, which may be nice for large graphs.

``````def find_all_paths(graph, start, end):
path  = []
paths = []
queue = [(start, end, path)]
while queue:
start, end, path = queue.pop()
print 'PATH', path

path = path + [start]
if start == end:
paths.append(path)
for node in set(graph[start]).difference(path):
queue.append((node, end, path))
return paths
``````
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I'm not sure if there are special optimizations available -- before looking for any of them, I'd do a simple recursive solution, something like (using of networkx only the feature that indexing a graph by a node gives an iterable yielding its neighbor nodes [[a dict, in networkx's case, but I'm not making use of that in particular]])...:

``````def allpaths(G, source_nodes, set_of_sink_nodes, path_prefix=()):
set_of_result_paths = set()
for n in source_nodes:
next_from_n = []
for an in G[n]:
if an in set_of_sink_nodes:
else:
next_from_n.append(an)
if next_from_n:
set_of_result_paths.update(
allpaths(G, next_from_n, set_of_sink_nodes, path_prefix + (n,)))
return set_of_result_paths
``````

This should be provably correct (but I'm not going to do the proof because it's very late and I'm tired and fuzzy-headed;-) and usable to verify any further optimizations;-).

First optimization I'd try would be some kind of simple memoizing: if I've already computed the set of paths from some node N to any goal node (whatever the prefix leading to N was when I did that computation), I can stash that away in a dict under key N and avoid further recomputations if and when I get to N again by a different route;-).

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I would up-vote your post for its coolness, but I'd feel an obligation to verify its correctness first. – Eric Walker Jul 19 '10 at 6:30