**Update**
I implemented an networkx_addon library. SimRank is included in the library. Check out: https://github.com/hhchen1105/networkx_addon for details.

Sample Usage:

```
>>> import networkx
>>> import networkx_addon
>>> G = networkx.Graph()
>>> G.add_edges_from([('a','b'), ('b','c'), ('a','c'), ('c','d')])
>>> s = networkx_addon.similarity.simrank(G)
```

You may obtain the similarity score between two nodes (say, node 'a' and node 'b') by

```
>>> print s['a']['b']
```

SimRank is a vertex similarity measure. It computes the similarity between two nodes on a graph based on the topology, i.e., the nodes and the links of the graph. To illustrate SimRank, let's consider the following graph, in which *a*, *b*, *c* connect to each other, and *d* is connected to *d*. How a node *a* is similar to a node *d*, is based on how *a*'s neighbor nodes, *b* and *c*, similar to *d*'s neighbors, *c*.

```
+-------+
| |
a---b---c---d
```

As seen, this is a **recursive** definition. Thus, SimRank is recursively computed until the similarity values converges. Note that SimRank introduces a constant *r* to represents the relative importance between in-direct neighbors and direct neighbors. The formal equation of SimRank can be found here.

The following function takes a networkx graph $G$ and the relative imporance parameter *r* as input, and returns the simrank similarity value *sim* between any two nodes in *G*. The return value *sim* is a dictionary of dictionary of float. To access the similarity between node *a* and node *b* in graph *G*, one can simply access sim[a][b].

```
def simrank(G, r=0.9, max_iter=100):
# init. vars
sim_old = defaultdict(list)
sim = defaultdict(list)
for n in G.nodes():
sim[n] = defaultdict(int)
sim[n][n] = 1
sim_old[n] = defaultdict(int)
sim_old[n][n] = 0
# recursively calculate simrank
for iter_ctr in range(max_iter):
if _is_converge(sim, sim_old):
break
sim_old = copy.deepcopy(sim)
for u in G.nodes():
for v in G.nodes():
if u == v:
continue
s_uv = 0.0
for n_u in G.neighbors(u):
for n_v in G.neighbors(v):
s_uv += sim_old[n_u][n_v]
sim[u][v] = (r * s_uv / (len(G.neighbors(u)) * len(G.neighbors(v))))
return sim
def _is_converge(s1, s2, eps=1e-4):
for i in s1.keys():
for j in s1[i].keys():
if abs(s1[i][j] - s2[i][j]) >= eps:
return False
return True
```

To calculate the similarity values between nodes in the above graph, you can try this.

```
>> G = networkx.Graph()
>> G.add_edges_from([('a','b'), ('b', 'c'), ('c','a'), ('c','d')])
>> simrank(G)
```

You'll get

```
defaultdict(<type 'list'>, {'a': defaultdict(<type 'int'>, {'a': 0, 'c': 0.62607626807407868, 'b': 0.65379221101693585, 'd': 0.7317028881451203}), 'c': defaultdict(<type 'int'>, {'a': 0.62607626807407868, 'c': 0, 'b': 0.62607626807407868, 'd': 0.53653543888775579}), 'b': defaultdict(<type 'int'>, {'a': 0.65379221101693585, 'c': 0.62607626807407868, 'b': 0, 'd': 0.73170288814512019}), 'd': defaultdict(<type 'int'>, {'a': 0.73170288814512019, 'c': 0.53653543888775579, 'b': 0.73170288814512019, 'd': 0})})
```

Let's verify the result by calculating similarity between, say, node *a* and node *b*, denoted by *S(a,b)*.

S(a,b) = r * (S(b,a)+S(b,c)+S(c,a)+S(c,c))/(2*2) = 0.9 * (0.6538+0.6261+0.6261+1)/4 = 0.6538,

which is the same as our calculated *S(a,b)* above.

For more details, you may want to checkout the following paper:

G. Jeh and J. Widom. SimRank: a measure of structural-context similarity. In KDD'02 pages 538-543. ACM Press, 2002.