Understanding the difference between __getattr__ and __getattribute__
I have gone through other's excellent explanation. However, I found a simple answer from this blog Python Magic Methods and __getattr__
. All the following are from there.
Using the __getattr__
magic method, we can intercept that inexistent attribute lookup and do something so it doesn’t fail:
class Dummy(object):
def __getattr__(self, attr):
return attr.upper()
d = Dummy()
d.does_not_exist # 'DOES_NOT_EXIST'
d.what_about_this_one # 'WHAT_ABOUT_THIS_ONE'
But if the attribute does exist, __getattr__
won’t be invoked:
class Dummy(object):
def __getattr__(self, attr):
return attr.upper()
d = Dummy()
d.value = "Python"
print(d.value) # "Python"
__getattribute__
is similar to __getattr__
, with the important difference that __getattribute__
will intercept EVERY attribute lookup, doesn’t matter if the attribute exists or not.
class Dummy(object):
def __getattribute__(self, attr):
return 'YOU SEE ME?'
d = Dummy()
d.value = "Python"
print(d.value) # "YOU SEE ME?"
In that example, the d
object already has an attribute value. But when we try to access it, we don’t get the original expected value (“Python”); we’re just getting whatever __getattribute__
returned. It means that we’ve virtually lost the value attribute; it has become “unreachable”.
I think the other answers have done a great job of explaining the difference between __getattr__
and __getattribute__
, but one thing that might not be clear is why you would want to use __getattribute__
. The cool thing about __getattribute__
is that it essentially allows you to overload the dot when accessing a class. This allows you to customize how attributes are accessed at a low level. For instance, suppose I want to define a class where all methods that only take a self argument are treated as properties:
# prop.py
import inspect
class PropClass(object):
def __getattribute__(self, attr):
val = super(PropClass, self).__getattribute__(attr)
if callable(val):
argcount = len(inspect.getargspec(val).args)
# Account for self
if argcount == 1:
return val()
else:
return val
else:
return val
And from the interactive interpreter:
>>> import prop
>>> class A(prop.PropClass):
... def f(self):
... return 1
...
>>> a = A()
>>> a.f
1
Of course this is a silly example and you probably wouldn't ever want to do this, but it shows you the power you can get from overriding __getattribute__
.
Some basics first.
With objects, you need to deal with their attributes. Ordinarily, we do instance.attribute
. Sometimes we need more control (when we do not know the name of the attribute in advance).
For example, instance.attribute
would become getattr(instance, attribute_name)
. Using this model, we can get the attribute by supplying the attribute_name as a string.
Use of __getattr__
You can also tell a class how to deal with attributes which it doesn't explicitly manage and do that via __getattr__
method.
Python will call this method whenever you request an attribute that hasn't already been defined, so you can define what to do with it.
A classic use case:
class A(dict):
def __getattr__(self, name):
return self[name]
a = A()
# Now a.somekey will give a['somekey']
Caveats and use of __getattribute__
If you need to catch every attribute regardless whether it exists or not, use __getattribute__
instead. The difference is that __getattr__
only gets called for attributes that don't actually exist. If you set an attribute directly, referencing that attribute will retrieve it without calling __getattr__
.
__getattribute__
is called all the times.
__getattribute__
is called whenever an attribute access occurs.
class Foo(object):
def __init__(self, a):
self.a = 1
def __getattribute__(self, attr):
try:
return self.__dict__[attr]
except KeyError:
return 'default'
f = Foo(1)
f.a
This will cause infinite recursion. The culprit here is the line return self.__dict__[attr]
. Let's pretend (It's close enough to the truth) that all attributes are stored in self.__dict__
and available by their name. The line
f.a
attempts to access the a
attribute of f
. This calls f.__getattribute__('a')
. __getattribute__
then tries to load self.__dict__
. __dict__
is an attribute of self == f
and so python calls f.__getattribute__('__dict__')
which again tries to access the attribute '__dict__
'. This is infinite recursion.
If __getattr__
had been used instead then
- It never would have run because
f
has ana
attribute. - If it had run, (let's say that you asked for
f.b
) then it would not have been called to find__dict__
because it's already there and__getattr__
is invoked only if all other methods of finding the attribute have failed.
The 'correct' way to write the above class using __getattribute__
is
class Foo(object):
# Same __init__
def __getattribute__(self, attr):
return super(Foo, self).__getattribute__(attr)
super(Foo, self).__getattribute__(attr)
binds the __getattribute__
method of the 'nearest' superclass (formally, the next class in the class's Method Resolution Order, or MRO) to the current object self
and then calls it and lets that do the work.
All of this trouble is avoided by using __getattr__
which lets Python do it's normal thing until an attribute isn't found. At that point, Python hands control over to your __getattr__
method and lets it come up with something.
It's also worth noting that you can run into infinite recursion with __getattr__
.
class Foo(object):
def __getattr__(self, attr):
return self.attr
I'll leave that one as an exercise.