If you simplify the problem to only clusters of length 2 (ie, pairs of dictionaries) it becomes slightly clearer: generating fixed-length subsequences from a given iterable is exactly the job of itertools.combinations:

```
>>> list(itertools.combinations(d, 2))
[('g5', 'g4'), ('g5', 'g3'), ('g5', 'g2'), ('g5', 'g1'), ('g4', 'g3'), ('g4', 'g
2'), ('g4', 'g1'), ('g3', 'g2'), ('g3', 'g1'), ('g2', 'g1')]
```

We can see the number of keys any dictionaries have in common by realising that the view d.keys() behaves like a set (in Python 3; in Python 2, it may be a list):

```
>>> d['g1'].keys() & d['g2'].keys()
{'p3', 'p1', 'p4'}
```

& is the set intersection operator - it gives us the set of all items these sets have in common. We can therefore check that there are atleast two of these by checking the length of this set, which gives us:

```
>>> common_pairs = [[x,y] for x,y in itertools.combinations(d, 2)
if len(d[x].keys() & d[y].keys()) >= 2]
>>> common_pairs
[['g2', 'g1']]
```

Solving for an unknown cluster size is slightly harder - we can't use the & operator directly if we aren't hardcoding this. Thankfully, the set class provides us with a method to take the intersection of *n* sets in the form of set.intersection. It won't accept a dict_keys instance, but you can easily fix that with a call to set:

```
>>> set.intersection(d['g1'].keys(), d['g2'].keys(), d['g5'].keys())
Traceback (most recent call last):
File "<stdin>", line 1, in <module>
TypeError: descriptor 'intersection' requires a 'set' object but received a 'dict_keys'
>>> set.intersection(set(d['g1']), set(d['g1']), set(d['g5']))
{'p1'}
```

You should be able to generalise this to the clusters of size 2 through *n* fairly trivially.