In most well-known OO languages, an expression like
SomeClass(arg1, arg2) will allocate a new instance, initialise the instance's attributes, and then return it.
In most well-known OO languages, the "initialise the instance's attributes" part can be customised for each class by defining a constructor, which is basically just a block of code that operates on the new instance (using the arguments provided to the constructor expression) to set up whatever initial conditions are desired. In Python, this corresponds to the class'
__new__ is nothing more and nothing less than similar per-class customisation of the "allocate a new instance" part. This of course allows you to do unusual things such as returning an existing instance rather than allocating a new one. So in Python, we shouldn't really think of this part as necessarily involving allocation; all that we require is that
__new__ comes up with a suitable instance from somewhere.
But it's still only half of the job, and there's no way for the Python system to know that sometimes you want to run the other half of the job (
__init__) afterwards and sometimes you don't. If you want that behavior, you have to say so explicitly.
Often, you can refactor so you only need
__new__, or so you don't need
__new__, or so that
__init__ behaves differently on an already-initialised object. But if you really want to, Python does actually allow you to redefine "the job", so that
SomeClass(arg1, arg2) doesn't necessarily call
__new__ followed by
__init__. To do this, you need to create a metaclass, and define its
A metaclass is just the class of a class. And a class'
__call__ method controls what happens when you call instances of the class. So a metaclass'
__call__ method controls what happens when you call a class; i.e. it allows you to redefine the instance-creation mechanism from start to finish. This is the level at which you can most elegantly implement a completely non-standard instance creation process such as the singleton pattern. In fact, with less than 10 lines of code you can implement a
Singleton metaclass that then doesn't even require you to futz with
__new__ at all, and can turn any otherwise-normal class into a singleton by simply adding
__metaclass__ = Singleton!
def __init__(self, *args, **kwargs):
super(Singleton, self).__init__(*args, **kwargs)
self.__instance = None
def __call__(self, *args, **kwargs):
if self.__instance is None:
self.__instance = super(Singleton, self).__call__(*args, **kwargs)
However this is probably deeper magic than is really warranted for this situation!