To override a property you have to act on the class and not on the instance, because their machinery, on the instance, gets called before __dict__
lookup and you end up with AttributeError
s. Instead you can set a different property on the class.
But to do so you either have to modify your class every time you create an instance(which I bet you do not want), or you have to generate new classes dynamically.
For example:
class Foo(object):
def __init__(self, val):
self._val = val
@property
def val(self):
return self._val
class SubType(Foo):
def __new__(cls, val):
if val % 2:
#random condition to change the property
subtype = type('SubFoo', (SubType,),
{'val': property((lambda self: self._val + 1))})
return object.__new__(subtype)
else:
return object.__new__(cls)
And the results are:
>>> d = SubType(3) #property changed
>>> d.val
4
>>> f = SubType(2) #same property as super class
>>> f.val
2
I don't like much this kind of hacks. Probably the easier way of doing thing is calling a private method that computes the property value, for example:
class Foo(object):
def __init__(self, val):
self._val = val
def _compute_val(self):
return self._val
@property
def val(self):
return self._compute_val()
class SubFoo(Foo):
def _compute_val(self):
if self._val % 2:
return self._val + 1
else:
return self._val
Which yields the same results as before:
>>> d = SubFoo(3)
>>> d.val
4
>>> f = SubFoo(2)
>>> f.val
2
I believe this trick could be seen as an application of the Template Method design pattern, even though it is applied to properties.
my_foo.bar
to return the empty string that you passed in, but if you didother_foo = Foo(**{'bar': None})
then you wantother_foo.bar
to run the property?__new__
. Anyway I think it easier if, inside the property you call a private method, and you override this private method instead of the property.