# DFS algorithm in Python with generators

### Background:

I was working on a project were I needed to write some rules for text processing. After working on this project for a couple of days and implementing some rules, I realized I needed to determine the order of the rules. No problems, we have topological sorting to help. But then I realized that I can't expect the graph to be always full. So I came up with this idea, that given a single rule with a set of dependencies (or a single dependency) I need to check the dependencies of the dependencies. Sounds familiar? Yes. This subject is very similar to Depth-first-searching of a graph.
I am not a mathematician, nor did I study C.S. Hence, Graph Theory is a new field for me. Nevertheless, I implemented something (see below) which works (inefficiently, I suspect).

### The code:

This is my search and yield algorithm. If you run it on the examples below, you will see it visits some nodes more then once. Hence, the speculated inefficiency.
A word about the input. The rules I wrote are basically python classes, which have a class property `depends`. I was criticized for not using `inspect.getmro`- But this would complicate thing terribly because the class would need to inherit from each other (See example here)

``````def _yield_name_dep(rules_deps):
global recursion_counter
recursion_counter = recursion_counter +1
# yield all rules by their named and dependencies
for rule, dep in rules_deps.items():
if not dep:
yield rule, dep
continue
else:
yield rule, dep
for ii in dep:
i = getattr(rules, ii)
instance = i()
if instance.depends:
new_dep={str(instance): instance.depends}
for dep in _yield_name_dep(new_dep):
yield dep
else:
yield str(instance), instance.depends
``````

OK, now that you stared in the code, here is some input you can test:

``````demo_class_content ="""
class A(object):
depends = ('B')
def __str__(self):
return self.__class__.__name__

class B(object):
depends = ('C','F')
def __str__(self):
return self.__class__.__name__

class C(object):
depends = ('D', 'E')
def __str__(self):
return self.__class__.__name__

class D(object):
depends = None
def __str__(self):
return self.__class__.__name__

class F(object):
depends = ('E')
def __str__(self):
return self.__class__.__name__

class E(object):
depends = None
def __str__(self):
return self.__class__.__name__
"""

with open('demo_classes.py', 'w') as clsdemo:
clsdemo.write(demo_class_content)

import demo_classes as rules

rule_start={'A': ('B')}

def _yield_name_dep(rules_deps):
# yield all rules by their named and dependencies
for rule, dep in rules_deps.items():
if not dep:
yield rule, dep
continue
else:
yield rule, dep
for ii in dep:
i = getattr(rules, ii)
instance = i()
if instance.depends:
new_dep={str(instance): instance.depends}
for dep in _yield_name_dep(new_dep):
yield dep
else:
yield str(instance), instance.depends

if __name__ == '__main__':
# this is yielding nodes visited multiple times,
# list(_yield_name_dep(rule_start))
# hence, my work around was to use set() ...
rule_dependencies = list(set(_yield_name_dep(rule_start)))
print rule_dependencies
``````

### The questions:

• I tried classifying my work, and I think what I did is similar to DFS. Can you really classify it like this?
• How can I improve this function to skip visited nodes, and still use generators ?

### update:

Just to save you the trouble running the code, the output of the above function is:

``````>>> print list(_yield_name_dep(rule_wd))
[('A', 'B'), ('B', ('C', 'F')), ('C', ('D', 'E')), ('D', None), ('E', None), ('F', 'E'), ('E', None)]
>>> print list(set(_yield_name_dep(rule_wd)))
[('B', ('C', 'F')), ('E', None), ('D', None), ('F', 'E'), ('C', ('D', 'E')), ('A', 'B')]
``````

In the mean while I came up with a better solution, the question above still remain. So feel free to criticize my solution:

``````visited = []
def _yield_name_dep_wvisited(rules_deps, visited):
# yield all rules by their name and dependencies
for rule, dep in rules_deps.items():
if not dep and rule not in visited:
yield rule, dep
visited.append(rule)
continue
elif rule not in visited:
yield rule, dep
visited.append(rule)
for ii in dep:
i = getattr(grules, ii)
instance = i()
if instance.depends:
new_dep={str(instance): instance.depends}
for dep in _yield_name_dep_wvisited(new_dep, visited):
if dep not in visited:
yield dep

elif str(instance) not in visited:
visited.append(str(instance))
yield str(instance), instance.depends
``````

The output of the above is:

``````>>>list(_yield_name_dep_wvisited(rule_wd, visited))
[('A', 'B'), ('B', ('C', 'F')), ('C', ('D', 'E')), ('D', None), ('E', None), ('F', 'E')]
``````

So as you can see now the node E is visited only once.

-
Why not store the class itself in `depends` rather than the name of a class? – Eric Oct 14 '13 at 10:40
@Eric, first because I would not know how to do it. Second, classes here are just for the demo. The code works on some properties defined in configuration file, and I wanted a self-containing example. Can you show what you mean? – Oz123 Oct 14 '13 at 10:43
`depends = (E, F)`, without quotes. Note you'll need to define the things being depended on earlier in the file than the things which depend on them, but that's probably a good idea for readability anyway. – Eric Oct 14 '13 at 10:59
I believe this question is more suited to codereview.SE Anyway, I believe you could simplify the code if you always used tuples for `depends`. I mean, having `depends = None`, `depends = 'A'` and `depends = ('A', 'B')` you have to treat explicitly each of these cases. You could simply use `depends = ()`, `depends = ('A',)` and `depends = ('A', 'B')` and have more uniform code. An other thing: `instance = i(); if instance.depends:` Since `depends` is a class attribute you don't have to instantiate the class. Simply do `if i.depends:`. – Bakuriu Oct 14 '13 at 11:34
If you always used tuples you could remove completely the `if not dep ...`, since the `for` would never be executed without dependencies. Right know your code works only if dependencies have single letter names, in other cases you'd have problems with `depends = 'MultiLetterName'` vs `depends = ('A', 'B')` and you'd have to check whether `dep` is a string. – Bakuriu Oct 14 '13 at 11:37

Using the feedback from Gareth and other kind users of Stackoverflow, here is what I came up with. It is clearer, and also more general:

``````def _dfs(start_nodes, rules, visited):
"""
Depth First Search
start_nodes - Dictionary of Rule with dependencies (as Tuples):

start_nodes = {'A': ('B','C')}

rules - Dictionary of Rules with dependencies (as Tuples):
e.g.
rules = {'A':('B','C'), 'B':('D','E'), 'C':('E','F'),
'D':(), 'E':(), 'F':()}
The above rules describe the following DAG:

A
/ \
B   C
/ \ / \
D   E   F
usage:
>>> rules = {'A':('B','C'), 'B':('D','E'), 'C':('E','F'),
'D':(), 'E':(), 'F':()}
>>> visited = []
>>> list(_dfs({'A': ('B','C')}, rules, visited))
[('A', ('B', 'C')), ('B', ('D', 'E')), ('D', ()), ('E', ()),
('C', ('E', 'F')), ('F', ())]
"""

for rule, dep in start_nodes.items():
if rule not in visited:
yield rule, dep
visited.append(rule)
for ii in dep:
new_dep={ ii : rules[ii]}
for dep in _dfs(new_dep, rules, visited):
if dep not in visited:
yield dep
``````
-

Here is another way to do do a breadth first search without duplicating the visited nodes.

``````import pylab
import networkx as nx

G = nx.DiGraph()
G.nodes()
``````

returns ['A', 'C', 'B', 'E', 'D', 'F']

``````G.add_edge('A','B')
``````

and here is how you can traverse the tree without duplicating nodes.

``````nx.traversal.dfs_successors(G)
``````

returns {'A': ['C', 'B'], 'B': ['D'], 'C': ['E', 'F']} and you can draw the graph.

``````nx.draw(G,node_size=1000)
``````
-
actually, that was my prefered solution. My Colleague was really against adding 'another dependency' to out project. I think it is always better to avoid re-inventing the wheel. Although, when you re-invent the wheel you learn alot. – Oz123 Oct 27 '13 at 18:20
You can spend your time learning a lot about what others have done or continuing with your research which may help everyone learn something new. There are a lot of algorithms out there. Be careful with your time. I wish you well. – Back2Basics Oct 28 '13 at 4:48