Here's how to "magically" replace a class in a module with a custom-made subclass without touching the module. It's only a few extra lines from a normal subclassing procedure, and therefore gives you (almost) all the power and flexibility of subclassing as a bonus. For instance this allows you to add new attributes, if you wish.
import networkx as nx
def __getattribute__(self, attr):
"This is just to show off, not needed"
print "getattribute %s" % (attr,)
return nx.Graph.__getattribute__(self, attr)
def __setattr__(self, attr, value):
"More showing off."
print " setattr %s = %r" % (attr, value)
return nx.Graph.__setattr__(self, attr, value)
"A convenience method"
import matplotlib.pyplot as plt
So far this is exactly like normal subclassing. Now we need to hook this subclass into the
networkx module so that all instantiation of
nx.Graph results in a
NewGraph object instead. Here's what normally happens when you instantiate an
nx.Graph object with
1. nx.Graph.__new__(nx.Graph) is called
2. If the returned object is a subclass of nx.Graph,
__init__ is called on the object
3. The object is returned as the instance
We will replace
nx.Graph.__new__ and make it return
NewGraph instead. In it, we call the
__new__ method of
object instead of the
__new__ method of
NewGraph, because the latter is just another way of calling the method we're replacing, and would therefore result in endless recursion.
if cls == nx.Graph:
# We substitute the __new__ method of the nx.Graph class
# with our own.
nx.Graph.__new__ = staticmethod(__new__)
# Test if it works
graph = nx.generators.random_graphs.fast_gnp_random_graph(7, 0.6)
In most cases this is all you need to know, but there is one gotcha. Our overriding of the
__new__ method only affects
nx.Graph, not its subclasses. For example, if you call
nx.gn_graph, which returns an instance of
nx.DiGraph, it will have none of our fancy extensions. You need to subclass each of the subclasses of
nx.Graph that you wish to work with and add your required methods and attributes. Using mix-ins may make it easier to consistently extend the subclasses while obeying the DRY principle.
Though this example may seem straightforward enough, this method of hooking into a module is hard to generalize in a way that covers all the little problems that may crop up. I believe it's easier to just tailor it to the problem at hand. For instance, if the class you're hooking into defines its own custom
__new__ method, you need to store it before replacing it, and call this method instead of