Your problem can easily be conceived as a graph problem where we have to find the shortest path between two nodes.

To convert your dependency parse in a graph, we first have to deal with the fact that it comes as a string. You want to get this:

```
'nsubj(are-5, Robots-1)\nxsubj(remind-8, Robots-1)\namod(culture-4, popular-3)\nprep_in(Robots-1, culture-4)\nroot(ROOT-0, are-5)\nadvmod(are-5, there-6)\naux(remind-8, to-7)\nxcomp(are-5, remind-8)\ndobj(remind-8, us-9)\ndet(awesomeness-12, the-11)\nprep_of(remind-8, awesomeness-12)\namod(agency-16, unbound-14)\namod(agency-16, human-15)\nprep_of(awesomeness-12, agency-16)'
```

to look like this:

```
[('are-5', 'Robots-1'), ('remind-8', 'Robots-1'), ('culture-4', 'popular-3'), ('Robots-1', 'culture-4'), ('ROOT-0', 'are-5'), ('are-5', 'there-6'), ('remind-8', 'to-7'), ('are-5', 'remind-8'), ('remind-8', 'us-9'), ('awesomeness-12', 'the-11'), ('remind-8', 'awesomeness-12'), ('agency-16', 'unbound-14'), ('agency-16', 'human-15'), ('awesomeness-12', 'agency-16')]
```

This way you can feed the tuple list to a graph constructor from the networkx module that will analyze the list and build a graph for you, plus give you a neat method that gives you the length of the shortest path between two given nodes.

**Necessary imports**

```
import re
import networkx as nx
from practnlptools.tools import Annotator
```

**How to get your string in the desired tuple list format**

```
annotator = Annotator()
text = """Robots in popular culture are there to remind us of the awesomeness of unbound human agency."""
dep_parse = annotator.getAnnotations(text, dep_parse=True)['dep_parse']
dp_list = dep_parse.split('\n')
pattern = re.compile(r'.+?\((.+?), (.+?)\)')
edges = []
for dep in dp_list:
m = pattern.search(dep)
edges.append((m.group(1), m.group(2)))
```

**How to build the graph**

```
graph = nx.Graph(edges) # Well that was easy
```

**How to compute shortest path length**

```
print(nx.shortest_path_length(graph, source='Robots-1', target='awesomeness-12'))
```

This script will reveal that the shortest path given the dependency parse is actually of length 2, since you can get from `Robots-1`

to `awesomeness-12`

by going through `remind-8`

```
1. xsubj(remind-8, Robots-1)
2. prep_of(remind-8, awesomeness-12)
```

If you don't like this result, you might want to think about filtering some dependencies, in this case not allow the `xsubj`

dependency to be added to the graph.