I am trying to split a directed (acyclic) graph into direction-connected path, relying on connectivity :

Example graph

When I test weak and strong connectivity subgraphs, here is what I get :

Weak connectivity :
['16', '17'], ['3', '41', '39', '42']
Strong connectivity :
['17'], ['16'], ['39'], ['41'], ['3'], ['42']

I understand the weak connectivity result, but not the strong-connectivity one, as I would expect 3 subgraphs : [16, 17], [42, 39] and [3, 41, 39].

What am I missing here, why those single node lists ? How to get the expected result ?

Here is the code :

import networkx as nx
import matplotlib.pyplot as plt

G = nx.DiGraph()
G.add_edges_from([('16', '17'), ('3', '41'), ('41', '39'), ('42', '39')])

print("Weak connectivity : ")
for subgraph in (G.subgraph(c).copy() for c in nx.weakly_connected_components(G)) :
print("Strong connectivity : ")
for subgraph in (G.subgraph(c).copy() for c in nx.strongly_connected_components(G)) :

nx.draw_networkx(G, pos=nx.circular_layout(G))
  • A strongly connected component is defined as a subgraph such that there exists a path from any node to any other node. The answer given by networkx is correct. Perhaps you are looking for something else?
    – DYZ
    Apr 16, 2019 at 15:55
  • Well, then [16, 17] would be a strongly connected subgraph, as you can reach 17 from 16, no ? Or would you also need to be able to reach 16 from 17 ?
    – Arkeen
    Apr 16, 2019 at 16:01
  • What I try to achieve it to get all possible full directed paths in this graph, so I would get [16, 17], [42, 39] and [3, 41, 39] from my example.
    – Arkeen
    Apr 16, 2019 at 16:06
  • [16,17] is not strongly directed because there is no path from 17 to 16.
    – DYZ
    Apr 16, 2019 at 16:35
  • 1
    (I now realize how this has nothing to do with connectivity, I made up my mind on cases that were too specific. I will edit my post once I know what I am truly looking for)
    – Arkeen
    Apr 16, 2019 at 18:55

3 Answers 3


So, thanks to comments & answers, I realised that "connectivity" was a false lead for what I want to achieve. To be clear : I want to get every possible path between all starting nodes to their connected ending nodes, in a directed acyclic graph.

So I ended up writing my own solution, which is quite simple to understand, but probably not the best, regarding performance or style (pythonic / networkx). Improvment suggestions are welcome :)

import networkx as nx
import matplotlib.pyplot as plt

G = nx.DiGraph()
G.add_edges_from([('16', '17'), ('3', '41'), ('41', '39'), ('42', '39')])

roots = []
leaves = []
for node in G.nodes :
  if G.in_degree(node) == 0 : # it's a root
  elif G.out_degree(node) == 0 : # it's a leaf

for root in roots :
  for leaf in leaves :
    for path in nx.all_simple_paths(G, root, leaf) :

nx.draw_networkx(G, pos=nx.circular_layout(G))

(If there is a built-in function in networkx, I clearly missed it)


What you're missing is the definition of strongly connected:

[A directed graph] is strongly connected, diconnected, or simply strong if it contains a directed path from u to v and a directed path from v to u for every pair of vertices u, v. The strong components are the maximal strongly connected subgraphs.

You have no strong connection between any two nodes of the graph shown, let alone the 3-node subgraph you list. You can, indeed, traverse 3 -> 41 -> 39, but there is no path back to 41, let alone 3. That graph is, therefore, not strongly connected.


According to the definition of strongly connected graph, the result you get is correct.

DEFINITION: strongly connected graph

A directed graph G=(V,E) is said to be strongly connected if every vertex v in V is reachable from every other vertex in V.

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