Why did the Python designers decide that subclasses' __init__() methods don't automatically call the __init__() methods of their superclasses, as in some other languages? Is the Pythonic and recommended idiom really like the following?
class Superclass(object):
def __init__(self):
print 'Do something'
class Subclass(Superclass):
def __init__(self):
super(Subclass, self).__init__()
print 'Do something else'
The crucial distinction between Python's __init__ and those other languages constructors is that __init__ is not a constructor: it's an initializer (the actual constructor (if any, but, see later;-) is __new__ and works completely differently again). While constructing all superclasses (and, no doubt, doing so "before" you continue constructing downwards) is obviously part of saying you're constructing a subclass's instance, that is clearly not the case for initializing, since there are many use cases in which superclasses' initialization needs to be skipped, altered, controlled -- happening, if at all, "in the middle" of the subclass initialization, and so forth.
Basically, super-class delegation of the initializer is not automatic in Python for exactly the same reasons such delegation is also not automatic for any other methods -- and note that those "other languages" don't do automatic super-class delegation for any other method either... just for the constructor (and if applicable, destructor), which, as I mentioned, is not what Python's __init__ is. (Behavior of __new__ is also quite peculiar, though really not directly related to your question, since __new__ is such a peculiar constructor that it doesn't actually necessarily need to construct anything -- could perfectly well return an existing instance, or even a non-instance... clearly Python offers you a lot more control of the mechanics than the "other languages" you have in mind, which also includes having no automatic delegation in __new__ itself!-).
__init__ is not a constructor... the actual constructor ... is __new__". As you yourself note, __new__ behaves nothing like a constructor from other languages. __init__ is in fact very similar (it is called during the creation of a new object, after that object is allocated, to set member variables on the new object), and is almost always the place to implement functionality that in other languages you would put in a constructor. So just call it a constructor!
__new__ doesn't automatically invoke superclass __new__ either. So your claim that the key distinction is that construction necessarily involves the construction of superclasses, while initialization does not is inconsistent with your claim that __new__ is the constructor.
__init__ at docs.python.org/reference/datamodel.html#basic-customization : "As a special constraint on constructors, no value may be returned; doing so will cause a TypeError to be raised at runtime" (emphasis mine). So there, it's official, __init__ is a constructor.
__init__ is called a constructor. This constructor is an initialization function called after the object has been completely constructed and initialized to a default state including its final runtime type. It is not equivalent to C++ constructors, that are called on a statically typed, allocated object with an undefined state. These are also different from __new__, so we really have at least four different kinds of allocation/construction/initialization functions. Languages uses mixed terminology, and the important part is the behavior and not the terminology.
I'm somewhat embarrassed when people parrot the "Zen of Python", as if it's a justification for anything. It's a design philosophy; particular design decisions can always be explained in more specific terms--and they must be, or else the "Zen of Python" becomes an excuse for doing anything.
The reason is simple: you don't necessarily construct a derived class in a way similar at all to how you construct the base class. You may have more parameters, fewer, they may be in a different order or not related at all.
class myFile(object):
def __init__(self, filename, mode):
self.f = open(filename, mode)
class readFile(myFile):
def __init__(self, filename):
super(readFile, self).__init__(filename, "r")
class tempFile(myFile):
def __init__(self, mode):
super(tempFile, self).__init__("/tmp/file", mode)
class wordsFile(myFile):
def __init__(self, language):
super(wordsFile, self).__init__("/usr/share/dict/%s" % language, "r")
This applies to all derived methods, not just __init__.
Java and C++ require that a base class constructor is called because of memory layout.
If you have a class BaseClass with a member field1, and you create a new class SubClass that adds a member field2, then an instance of SubClass contains space for field1 and field2. You need a constructor of BaseClass to fill in field1, unless you require all inheriting classes to repeat BaseClass's initialization in their own constructors. And if field1 is private, then inheriting classes can't initialise field1.
Python is not Java or C++. All instances of all user-defined classes have the same 'shape'. They're basically just dictionaries in which attributes can be inserted. Before any initialisation has been done, all instances of all user-defined classes are almost exactly the same; they're just places to store attributes that aren't storing any yet.
So it makes perfect sense for a Python subclass not to call its base class constructor. It could just add the attributes itself if it wanted to. There's no space reserved for a given number of fields for each class in the hierarchy, and there's no difference between an attribute added by code from a BaseClass method and an attribute added by code from a SubClass method.
If, as is common, SubClass actually does want to have all of BaseClass's invariants set up before it goes on to do its own customisation, then yes you can just call BaseClass.__init__() (or use super, but that's complicated and has its own problems sometimes). But you don't have to. And you can do it before, or after, or with different arguments. Hell, if you wanted you could call the BaseClass.__init__ from another method entirely than __init__; maybe you have some bizarre lazy initialization thing going.
Python achieves this flexibility by keeping things simple. You initialise objects by writing an __init__ method that sets attributes on self. That's it. It behaves exactly like a method, because it is exactly a method. There are no other strange and unintuitive rules about things having to be done first, or things that will automatically happen if you don't do other things. The only purpose it needs to serve is to be a hook to execute during object initialisation to set initial attribute values, and it does just that. If you want it to do something else, you explicitly write that in your code.
To avoid confusion it is useful to know that you can invoke the base_class __init__() method if the child_class does not have an __init__() class.
Example:
class parent:
def __init__(self, a=1, b=0):
self.a = a
self.b = b
class child(parent):
def me(self):
pass
p = child(5, 4)
q = child(7)
z= child()
print p.a # prints 5
print q.b # prints 0
print z.a # prints 1
In fact the MRO in python will look for __init__() in the parent class when can not find it in the children class. You need to invoke the parent class constructor directly if you have already an __init__() method in the children class.
For example the following code will return an error: class parent: def init(self, a=1, b=0): self.a = a self.b = b
class child(parent):
def __init__(self):
pass
def me(self):
pass
p = child(5, 4) # Error: constructor gets one argument 3 is provided.
q = child(7) # Error: constructor gets one argument 2 is provided.
z= child()
print z.a # Error: No attribute named as a can be found.
object.__init__() and read "If a base class has an __init__() method, the derived class’s __init__() method, if any, must explicitly call it to ensure proper initialization of the base class part of the instance". But that does not specify the behavior when a derived class lacks an __init__().
__init__ method.
Apr 29, 2022 at 10:52
object.__init__(). Incidentally, if one wants to emulate an __init__() in a subclass without overloading the parent __init__, a main() (or whatever other name, doesn't matter) method can be defined and called from __init__() in the base and then overloaded in a child class. The overloaded main() method from the child class will be run by its call in the base parent init instead.
"Explicit is better than implicit." It's the same reasoning that indicates we should explicitly write 'self'.
I think in in the end it is a benefit-- can you recite all of the rules Java has regarding calling superclasses' constructors?
Right now, we have a rather long page describing the method resolution order in case of multiple inheritance: http://www.python.org/download/releases/2.3/mro/
If constructors were called automatically, you'd need another page of at least the same length explaining the order of that happening. That would be hell...
Often the subclass has extra parameters which can't be passed to the superclass.
Maybe __init__ is the method that the subclass needs to override. Sometimes subclasses need the parent's function to run before they add class-specific code, and other times they need to set up instance variables before calling the parent's function. Since there's no way Python could possibly know when it would be most appropriate to call those functions, it shouldn't guess.
If those don't sway you, consider that __init__ is Just Another Function. If the function in question were dostuff instead, would you still want Python to automatically call the corresponding function in the parent class?
i believe the one very important consideration here is that with an automatic call to super.__init__(), you proscribe, by design, when that initialization method is called, and with what arguments. eschewing automatically calling it, and requiring the programmer to explicitly do that call, entails a lot of flexibility.
after all, just because class B is derived from class A does not mean A.__init__() can or should be called with the same arguments as B.__init__(). making the call explicit means a programmer can have e.g. define B.__init__() with completely different parameters, do some computation with that data, call A.__init__() with arguments as appropriate for that method, and then do some postprocessing. this kind of flexibility would be awkward to attain if A.__init__() would be called from B.__init__() implicitly, either before B.__init__() executes or right after it.
As Sergey Orshanskiy pointed out in the comments, it is also convenient to write a decorator to inherit the __init__ method.
You can write a decorator to inherit the
__init__method, and even perhaps automatically search for subclasses and decorate them. – Sergey Orshanskiy Jun 9 '15 at 23:17
Note: actually this is only useful if you want to call both the base and the derived class's __init__ since __init__ is inherited automatically. See the previous answers for this question.
def default_init(func):
def wrapper(self, *args, **kwargs) -> None:
super(type(self), self).__init__(*args, **kwargs)
return wrapper
class base():
def __init__(self, n: int) -> None:
print(f'Base: {n}')
class child(base):
@default_init
def __init__(self, n: int) -> None:
pass
child(42)
Outputs:
Base: 42
Warning: this doesn't work if base itself called super(type(self), self).
def default_init(func):
def wrapper(self, *args, **kwargs) -> None:
'''Warning: recursive calls.'''
super(type(self), self).__init__(*args, **kwargs)
return wrapper
class base():
def __init__(self, n: int) -> None:
print(f'Base: {n}')
class child(base):
@default_init
def __init__(self, n: int) -> None:
pass
class child2(child):
@default_init
def __init__(self, n: int) -> None:
pass
child2(42)
RecursionError: maximum recursion depth exceeded while calling a Python object.
super()?But why not just use the safe plain super()? Because it doesn't work since the new rebinded __init__ is from outside the class, and super(type(self), self) is required.
def default_init(func):
def wrapper(self, *args, **kwargs) -> None:
super().__init__(*args, **kwargs)
return wrapper
class base():
def __init__(self, n: int) -> None:
print(f'Base: {n}')
class child(base):
@default_init
def __init__(self, n: int) -> None:
pass
child(42)
Errors:
---------------------------------------------------------------------------
RuntimeError Traceback (most recent call last)
<ipython-input-9-6f580b3839cd> in <module>
13 pass
14
---> 15 child(42)
<ipython-input-9-6f580b3839cd> in wrapper(self, *args, **kwargs)
1 def default_init(func):
2 def wrapper(self, *args, **kwargs) -> None:
----> 3 super().__init__(*args, **kwargs)
4 return wrapper
5
RuntimeError: super(): __class__ cell not found
A lot of answers here and say "This is not the python way, use super().__init__() from the subclass". The question is not asking for the pythonic way, it's comparing to the expected behavior from other languages to python's obviously different one.
The MRO document is pretty and colorful but it's really a TLDR situation and still doesn't quite answer the question, as is often the case in these types of comparisons - "Do it the Python way, because.".
Inherited objects can be overloaded by later declarations in subclasses, a pattern building on @keyvanrm's (https://stackoverflow.com/a/46943772/1112676) answer solves the case where I want to AUTOMATICALLY init a parent class as part of calling a class without explicitly calling super().__init__() in every child class.
In my case where a new team member might be asked to use a boilerplate module template (for making extensions to our application without touching the core application source) which we want to make as bare and easy to adopt without them needing to know or understand the underlying machinery - to only need to know of and use what is provided by the application's base interface which is well documented.
For those who will say "Explicit is better than implicit." I generally agree, however, when coming from many other popular languages inherited automatic initialization is the expected behavior and it is very useful if it can be leveraged for projects where some work on a core application and others work on extending it.
This technique can even pass args/keyword args for init which means pretty much any object can be pushed to the parent and used by the parent class or its relatives.
class Parent:
def __init__(self, *args, **kwargs):
self.somevar = "test"
self.anothervar = "anothertest"
#important part, call the init surrogate pass through args:
self._init(*args, **kwargs)
#important part, a placeholder init surrogate:
def _init(self, *args, **kwargs):
print("Parent class _init; ", self, args, kwargs)
def some_base_method(self):
print("some base method in Parent")
self.a_new_dict={}
class Child1(Parent):
# when omitted, the parent class's __init__() is run
#def __init__(self):
# pass
#overloading the parent class's _init() surrogate
def _init(self, *args, **kwargs):
print(f"Child1 class _init() overload; ",self, args, kwargs)
self.a_var_set_from_child = "This is a new var!"
class Child2(Parent):
def __init__(self, onevar, twovar, akeyword):
print(f"Child2 class __init__() overload; ", self)
#call some_base_method from parent
self.some_base_method()
#the parent's base method set a_new_dict
print(self.a_new_dict)
class Child3(Parent):
pass
print("\nRunning Parent()")
Parent()
Parent("a string", "something else", akeyword="a kwarg")
print("\nRunning Child1(), keep Parent.__init__(), overload surrogate Parent._init()")
Child1()
Child1("a string", "something else", akeyword="a kwarg")
print("\nRunning Child2(), overload Parent.__init__()")
#Child2() # __init__() requires arguments
Child2("a string", "something else", akeyword="a kwarg")
print("\nRunning Child3(), empty class, inherits everything")
Child3().some_base_method()
Output:
Running Parent()
Parent class _init; <__main__.Parent object at 0x7f84a721fdc0> () {}
Parent class _init; <__main__.Parent object at 0x7f84a721fdc0> ('a string', 'something else') {'akeyword': 'a kwarg'}
Running Child1(), keep Parent.__init__(), overload surrogate Parent._init()
Child1 class _init() overload; <__main__.Child1 object at 0x7f84a721fdc0> () {}
Child1 class _init() overload; <__main__.Child1 object at 0x7f84a721fdc0> ('a string', 'something else') {'akeyword': 'a kwarg'}
Running Child2(), overload Parent.__init__()
Child2 class __init__() overload; <__main__.Child2 object at 0x7f84a721fdc0>
some base method in Parent
{}
Running Child3(), empty class, inherits everything, access things set by other children
Parent class _init; <__main__.Child3 object at 0x7f84a721fdc0> () {}
some base method in Parent
As one can see, the overloaded definition(s) take the place of those declared in Parent class but can still be called BY the Parent class thereby allowing one to emulate the classical implicit inheritance initialization behavior Parent and Child classes both initialize without needing to explicitly invoke the Parent's init() from the Child class.
Personally, I call the surrogate _init() method main() because it makes sense to me when switching between C++ and Python for example since it is a function that will be automatically run for any subclass of Parent (the last declared definition of main(), that is).
__init__method, and even perhaps automatically search for subclasses and decorate them.super().