`nx.connected_components`

You can use `networkx`

for that. Generate a graph, and add your list as the graph edges using `add_edges_from`

. Then use `connected_components`

, which will precisely give you a list of sets of the connected components in the graph:

```
import networkx as nx
L = [['John','Sayyed'], ['John' , 'Simon'] ,['bush','trump']]
G=nx.Graph()
G.add_edges_from(L)
list(nx.connected_components(G))
[{'John', 'Sayyed', 'Simon'}, {'bush', 'trump'}]
```

### What about lists with multiple (>2) items?

In the case of having sublists with more than `2`

elements, you can *add them as paths* instead of nodes using `nx.add_path`

, since they can connect multiple nodes:

```
L = [['John','Sayyed'], ['John' , 'Simon'] ,['bush','trump'],
['Sam','Suri','NewYork'],['Suri','Orlando','Canada']]
G=nx.Graph()
for l in L:
nx.add_path(G, l)
list(nx.connected_components(G))
[{'John', 'Sayyed', 'Simon'},
{'bush', 'trump'},
{'Canada', 'NewYork', 'Orlando', 'Sam', 'Suri'}]
```

We can also vivisualize these connected components with `nx.draw`

:

```
pos = nx.spring_layout(G, scale=20)
nx.draw(G, pos, node_color='lightblue', node_size=500, with_labels=True)
```

### On connected components (graph theory)

More detailed explanation on connected components:

In graph theory, a connected component (or just component) of an undirected graph is a subgraph in which any two vertices are connected to each other by paths, and which is connected to no additional vertices in the supergraph

So essentially, this code creates a graph, with edges from the list, where each edge is composed by two values `u,v`

where `u`

and `v`

will be nodes connected by this edge.

And hence, the union of sublists with at least one sublist with a common element can be translated into a Graph Theory problem as all nodes that are reachable between each other through the existing paths.

`list(set(L[0]) | set(L[1]))`

. Your example is hard to exploit. It should containquotedstrings – Jean-François Fabre♦ Dec 21 '18 at 14:08