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Being used to the old ways of duck typing in Python, I failed to understand the need for ABC (abstract base classes). The help is good on how to use them.

I tried to read the rationale in the PEP, but it went over my head. If I was looking for a mutable sequence container, I would check for __setitem__, or more likely tried to use it (EAFP). I haven't come across a real life use for the numbers module, which does use ABCs, but that is the closest I have to understanding.

Can anyone explain to me the rationale, please?

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up vote 73 down vote accepted

Short version: ABCs offer a higher level of semantic contract between clients and the implemented classes.

Long version:

There is a contract between a class and its callers. The class promises to do certain things and have certain properties.

There are different levels to the contract.

At a very low level, the contract might include the name of a method or its number of parameters.

In a staticly-typed language, that contract would actually be enforced by the compiler. In Python, you can use EAFP or introspection to confirm that the unknown object meets this expected contract.

But there are also higher-level, semantic promises in the contract.

For example, if there is a __str__() method, it is expected to return a string representation of the object. It could delete all contents of the object, commit the transaction and spit a blank page out of the printer... but there is a common understanding of what it should do, described in the Python manual.

That's a special case, where the semantic contract is described in the manual. What should the print() method do? Should it write the object to a printer or a line to the screen, or something else? It depends - you need to read the comments to understand the full contract here. A piece of client code that simply checks that the print() method exists has confirmed part of the contract - that a method call can be made, but not that there is agreement on the higher level semantics of the call.

Defining an Abstract Base Class (ABC) is a way of producing a contract between the class implementers and the callers. It isn't just a list of method names, but a shared understanding of what those methods should do. If you inherit from this ABC, you are promising to follow all the rules described in the comments, including the semantics of the print() method.

Python's duck-typing has many advantages in flexibility over static-typing, but it doesn't solve all the problems. ABCs offer an intermediate solution between the free-form of Python and the bondage-and-discipline of a staticly-typed language.

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I think that you have a point there, but I can't follow you. So what is the difference, in terms of contract, between a class that implements __contains__ and a class that inherits from collections.Container? In your example, in Python there was always a shared understanding of __str__. Implementing __str__ makes the same promises as inheriting from some ABC and then implementing __str__. In both cases you can break the contract; there are no provable semantics such as the ones we have in static typing. – Muhammad Alkarouri Aug 26 '10 at 11:05
collections.Container is a degenerate case, that only includes \_\_contains\_\_, and only to mean the predefined convention. Using an ABC doesn't add much value by itself, I agree. I suspect it was added to allow (for e.g.) Set to inherit from it. By the time you get to Set, suddenly belonging to the the ABC has considerable semantics. An item can't belong to the collection twice. That is NOT detectable by the existence of methods. – Oddthinking Aug 26 '10 at 16:55
The Set example looks better to me than the print() function. In particular, I didn't understand the higher level contract of the print() method. It looks to me similar to the __contains__ and __str__ cases, where the semantics of these are documented in their respective help/comments. But when you have a complex object like Set, the semantics are not the semantics of any one function or property of the object. Am I missing something? – Muhammad Alkarouri Aug 27 '10 at 22:16
Yes, I think Set is a better example than print(). I was attempting to find a method name whose meaning was ambiguous, and couldn't be grokked by the name alone, so you couldn't be sure that it would do the right thing just by its name and the Python manual. – Oddthinking Aug 28 '10 at 16:12
So it's kind of like an interface in said bondage programming languages? – ashes999 Mar 3 '13 at 23:25

@Oddthinking's answer is not wrong, but I think it misses the real, practical reason Python has ABCs in a world of duck-typing.

Abstract methods are neat, but in my opinion they don't really fill any use-cases not already covered by duck typing. Abstract base classes' real power lies in the way they allow you to customise the behaviour of isinstance and issubclass. (__subclasshook__ is basically a friendlier API on top of Python's __instancecheck__ and __subclasscheck__ hooks.) Adapting built-in constructs to work on custom types is very much part of Python's philosophy.

Python's source code is exemplary. Here is how collections.Container is defined in the standard library (at time of writing):

class Container(metaclass=ABCMeta):
    __slots__ = ()

    def __contains__(self, x):
        return False

    def __subclasshook__(cls, C):
        if cls is Container:
            if any("__contains__" in B.__dict__ for B in C.__mro__):
                return True
        return NotImplemented

This definition of __subclasshook__ says that any class with a __contains__ attribute is considered to be a subclass of Container, even if it doesn't subclass it directly. So I can write this:

class ContainAllTheThings(object):
    def __contains__(self, item):
        return True

>>> issubclass(ContainAllTheThings, collections.Container)
>>> isinstance(ContainAllTheThings(), collections.Container)

In other words, if you implement the right interface, you're a subclass! ABCs provide a formal way to define interfaces in Python, while staying true to the spirit of duck-typing. Besides, this works in a way that honours the Open-Closed Principle.

Python's object model looks superficially similar to that of a more "traditional" OO system (by which I mean Java*) - we got yer classes, yer objects, yer methods - but when you scratch the surface you'll find something far richer and more flexible. Likewise, Python's notion of abstract base classes may be recognisable to a Java developer, but in practice they are intended for a very different purpose.

I sometimes find myself writing polymorphic functions that can act on a single item or a collection of items, and I find isinstance(x, collections.Iterable) to be much more readable than hasattr(x, '__iter__') or an equivalent try...except block. (If you didn't know Python, which of those three would make the intention of the code clearest?)

I find that I rarely need to write my own ABC - I prefer to rely on duck typing - and I typically discover the need for one through refactoring. If I see a polymorphic function making a lot of attribute checks, or lots of functions making the same attribute checks, that smell suggests the existence of an ABC waiting to be extracted.

*without getting into the debate over whether Java is a "traditional" OO system...

Addendum: Even though an abstract base class can override the behaviour of isinstance and issubclass, it still doesn't enter the MRO of the virtual subclass. This is a potential pitfall for clients: not every object for which isinstance(x, MyABC) == True has the methods defined on MyABC.

class MyABC(metaclass=abc.ABCMeta):
    def abc_method(self):
    def __subclasshook__(cls, C):
        return True

class C(object):

# typical client code
c = C()
if isinstance(c, MyABC):  # will be true
    c.abc_method()  # raises AttributeError

Unfortunately this one of those "just don't do that" traps (of which Python has relatively few!): avoid defining ABCs with both a __subclasshook__ and non-abstract methods. Moreover, you should make your definition of __subclasshook__ consistent with the set of abstract methods your ABC defines.

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"if you implement the right interface, you're a subclass" Thanks a lot for that. I don't know if Oddthinking missed it, but I certainly did. FWIW, isinstance(x, collections.Iterable) is clearer for me, and I do know Python. – Muhammad Alkarouri Oct 31 '13 at 20:40
Excellent post. Thank you. I think that the Addendum, "just don't do that" trap, is a bit like doing normal subclass inheritance but then having the C subclass delete (or screw up beyond repair) the abc_method() inherited from MyABC. The principal difference is that it's the superclass that is screwing up the inheritance contract, not the subclass. – Michael Scott Cuthbert Sep 14 '15 at 15:05
This post blew my mind. Awesome explanation!! – Alvaro Sep 29 '15 at 13:17
Would you not have to do Container.register(ContainAllTheThings) for the given example to work? – BoZenKhaa Feb 24 at 10:27
@BoZenKhaa The code in the answer works! Try it! The meaning of __subclasshook__ is "any class which satisfies this predicate is considered a subclass for the purposes of isinstance and issubclass checks, regardless of whether it was registered with the ABC, and regardless of whether it's a direct subclass". As I said in the answer, if you implement the right interface, you're a subclass! – Benjamin Hodgson Feb 24 at 11:11

A handy feature of ABCs is that if you don't implement all necessary methods (and properties) you get an error upon instantiation, rather than an AttributeError, potentially much later, when you actually try to use the missing method.

from abc import ABCMeta, abstractmethod

class Base(object):
    __metaclass__ = ABCMeta

    def foo(self):

    def bar(self):

class Concrete(Base):
    def foo(self):

    # We forget to declare `bar`

c = Concrete()
# TypeError: "Can't instantiate abstract class Concrete with abstract methods bar"

Example from https://dbader.org/blog/abstract-base-classes-in-python

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The example and the link were both very helpful. Thanks! – nalyd88 May 29 '15 at 22:51

It will make determining whether an object supports a given protocol without having to check for presence of all the methods in the protocol or without triggering an exception deep in "enemy" territory due to non-support much easier.

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