# Longest path in a DAG

To find the longest path in a DAG, I'm aware of 2 algorithms: algo 1: do a topological sort + use dynamic programming on the result of the sort ~ or ~ algo 2: enumerate all the paths in the DAG using DFS, and record the longest. It seems like enumerating all the paths with DFS has better complexity than algo 1. Is that true?

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Your second option is incorrect: DFS does not explore all possible paths, unless your graph is a tree or a forest, and you start from the roots. The second algorithm that I know is negating the weights and finding the shortest path, but it is somewhat slower than the top sort + DP algorithm that you listed as #1.

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OK, I meant DFS with restart from any vertex that has not been visited in the previous DFS passes. That will explore the whole DAG. Shouldn't that be faster than topo sort + DP? –  Frank May 23 '12 at 2:53
@Frank DFS with restart from vertexes that has not been visited will not explore all paths. Consider a graph `A->B->C`; you start DFS from B, go to C, and stop; then restart from A, go to B, and stop again, because you have visited C already. Both path that DFS found, `B-C` and `A-B`, are of length 1; the longest path `A-B-C` is of length 2. –  dasblinkenlight May 23 '12 at 3:00
Why would you start from B? You have to start the DFS from sources. –  Frank May 23 '12 at 3:08
Even if you start at the sources, consider a graph with diamonds: `A->B,C ; B->D ; C->D ; D->E,F ; E->G ; F->G`. `A` is a source, so you start exploring from it. You go `A-B-D-E,G`, go back to `D`, try `A-B-D-F-G`, go back to `A`, try `A-C-D`, and stop, because `D` has been fully explored now. If the longest path by weight is `A-C-D-E-G`, DFS is not going to find it. –  dasblinkenlight May 23 '12 at 3:33
OK, I'm going to post some Python code that does it. –  Frank May 23 '12 at 3:38

Enumerate all paths in a DAG using "DFS":

``````def enumerate_dag(g):

def enumerate_r(n, paths, visited, a_path = []):
a_path += [n]
visited[n] = 1
if not g[n]:
paths += [list(a_path)]
else:
for nn in g[n]:
enumerate_r(nn, paths, visited, list(a_path))

paths, N = [], len(g)
visited = np.zeros((N), dtype='int32')

for root in range(N):
if visited[root]: continue
enumerate_r(root, paths, visited, [])

return paths
``````
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Did you try passing a double-diamond graph to this code? It looks like it has a 50/50 chance of missing the longest path. –  dasblinkenlight May 23 '12 at 3:47
I've just tried with: [[1,2],[3],[3],[4],[5,6],[7],[7],[8],[9],[]]. I get 4 paths: [[0, 1, 3, 4, 5, 7, 8, 9], [0, 1, 3, 4, 6, 7, 8, 9], [0, 2, 3, 4, 5, 7, 8, 9], [0, 2, 3, 4, 6, 7, 8, 9]], which I believe is the correct answer. As far as I can tell (from many other tests), this algorithm correctly enumerates the paths in a DAG. Topo sort is based on a very similar use of DFS. Provided you start/restart at sources, DFS will explore all the nodes reachable from each source hence the code above completely explores the DAG, no vertex is missed. –  Frank May 23 '12 at 5:35
I misunderstood the use of `visited` in your code: you set it, but you do not use it to decide if you should continue the traversal. This is not what's called DFS, because DFS does not visit nodes that have been completely explored. The biggest difference between DFS and your code is that your code is hugely inefficient. Try repeating the same diamond pattern fifty times to see what I mean: your program will explore all `2^50` paths, and that's a lot of paths to explore. –  dasblinkenlight May 23 '12 at 10:13
@dasblinkenlight the exploration strategy of the DAG is "DFS": it expands each path to a sink, then backtracks. As for "hugely inefficient", the intent IS to enumerate all the paths for this function. So yes, it has to visit some nodes many times. –  Frank May 23 '12 at 13:58
But I can see how enumerating all the paths to find the longest one is going to have bad complexity compared to topo sort + ordering. –  Frank May 23 '12 at 14:00
``````for each node with no predecessor :