PEP 422 – Simpler customisation of class creation

Author:: Nick Coghlan <ncoghlan at gmail.com>, Daniel Urban <urban.dani+py at gmail.com>
Status:: Withdrawn
Type:: Standards Track
Created:: 05-Jun-2012
Python-Version:: 3.5
Post-History:: 05-Jun-2012, 10-Feb-2013

Table of Contents

Abstract
PEP Withdrawal
Background
Proposal
Key Benefits
Design Notes
- Determining if the class being decorated is the base class
- Replacing a class with a different kind of object
Open Questions
- Is the namespace concept worth the extra complexity?
New Ways of Using Classes
Rejected Design Options
Reference Implementation
TODO
Copyright

Abstract

Currently, customising class creation requires the use of a custom metaclass. This custom metaclass then persists for the entire lifecycle of the class, creating the potential for spurious metaclass conflicts.

This PEP proposes to instead support a wide range of customisation scenarios through a new namespace parameter in the class header, and a new __autodecorate__ hook in the class body.

The new mechanism should be easier to understand and use than implementing a custom metaclass, and thus should provide a gentler introduction to the full power Python’s metaclass machinery.

PEP Withdrawal

This proposal has been withdrawn in favour of Martin Teichmann’s proposal in PEP 487, which achieves the same goals through a simpler, easier to use __init_subclass__ hook that simply isn’t invoked for the base class that defines the hook.

Background

For an already created class cls, the term “metaclass” has a clear meaning: it is the value of type(cls).

During class creation, it has another meaning: it is also used to refer to the metaclass hint that may be provided as part of the class definition. While in many cases these two meanings end up referring to one and the same object, there are two situations where that is not the case:

If the metaclass hint refers to an instance of type, then it is considered as a candidate metaclass along with the metaclasses of all of the parents of the class being defined. If a more appropriate metaclass is found amongst the candidates, then it will be used instead of the one given in the metaclass hint.
Otherwise, an explicit metaclass hint is assumed to be a factory function and is called directly to create the class object. In this case, the final metaclass will be determined by the factory function definition. In the typical case (where the factory functions just calls type, or, in Python 3.3 or later, types.new_class) the actual metaclass is then determined based on the parent classes.

It is notable that only the actual metaclass is inherited - a factory function used as a metaclass hook sees only the class currently being defined, and is not invoked for any subclasses.

In Python 3, the metaclass hint is provided using the metaclass=Meta keyword syntax in the class header. This allows the __prepare__ method on the metaclass to be used to create the locals() namespace used during execution of the class body (for example, specifying the use of collections.OrderedDict instead of a regular dict).

In Python 2, there was no __prepare__ method (that API was added for Python 3 by PEP 3115). Instead, a class body could set the __metaclass__ attribute, and the class creation process would extract that value from the class namespace to use as the metaclass hint. There is published code that makes use of this feature.

Another new feature in Python 3 is the zero-argument form of the super() builtin, introduced by PEP 3135. This feature uses an implicit __class__ reference to the class being defined to replace the “by name” references required in Python 2. Just as code invoked during execution of a Python 2 metaclass could not call methods that referenced the class by name (as the name had not yet been bound in the containing scope), similarly, Python 3 metaclasses cannot call methods that rely on the implicit __class__ reference (as it is not populated until after the metaclass has returned control to the class creation machinery).

Finally, when a class uses a custom metaclass, it can pose additional challenges to the use of multiple inheritance, as a new class cannot inherit from parent classes with unrelated metaclasses. This means that it is impossible to add a metaclass to an already published class: such an addition is a backwards incompatible change due to the risk of metaclass conflicts.

Proposal

This PEP proposes that a new mechanism to customise class creation be added to Python 3.4 that meets the following criteria:

Integrates nicely with class inheritance structures (including mixins and multiple inheritance)
Integrates nicely with the implicit __class__ reference and zero-argument super() syntax introduced by PEP 3135
Can be added to an existing base class without a significant risk of introducing backwards compatibility problems
Restores the ability for class namespaces to have some influence on the class creation process (above and beyond populating the namespace itself), but potentially without the full flexibility of the Python 2 style __metaclass__ hook

One mechanism that can achieve this goal is to add a new implicit class decoration hook, modelled directly on the existing explicit class decorators, but defined in the class body or in a parent class, rather than being part of the class definition header.

Specifically, it is proposed that class definitions be able to provide a class initialisation hook as follows:

class Example:
    def __autodecorate__(cls):
        # This is invoked after the class is created, but before any
        # explicit decorators are called
        # The usual super() mechanisms are used to correctly support
        # multiple inheritance. The class decorator style signature helps
        # ensure that invoking the parent class is as simple as possible.
        cls = super().__autodecorate__()
        return cls

To simplify the cooperative multiple inheritance case, object will gain a default implementation of the hook that returns the class unmodified:

class object:
    def __autodecorate__(cls):
        return cls

If a metaclass wishes to block implicit class decoration for some reason, it must arrange for cls.__autodecorate__ to trigger AttributeError.

If present on the created object, this new hook will be called by the class creation machinery after the __class__ reference has been initialised. For types.new_class(), it will be called as the last step before returning the created class object. __autodecorate__ is implicitly converted to a class method when the class is created (prior to the hook being invoked).

Note, that when __autodecorate__ is called, the name of the class is not yet bound to the new class object. As a consequence, the two argument form of super() cannot be used to call methods (e.g., super(Example, cls) wouldn’t work in the example above). However, the zero argument form of super() works as expected, since the __class__ reference is already initialised.

This general proposal is not a new idea (it was first suggested for inclusion in the language definition more than 10 years ago, and a similar mechanism has long been supported by Zope’s ExtensionClass), but the situation has changed sufficiently in recent years that the idea is worth reconsidering for inclusion as a native language feature.

In addition, the introduction of the metaclass __prepare__ method in PEP 3115 allows a further enhancement that was not possible in Python 2: this PEP also proposes that type.__prepare__ be updated to accept a factory function as a namespace keyword-only argument. If present, the value provided as the namespace argument will be called without arguments to create the result of type.__prepare__ instead of using a freshly created dictionary instance. For example, the following will use an ordered dictionary as the class namespace:

class OrderedExample(namespace=collections.OrderedDict):
    def __autodecorate__(cls):
        # cls.__dict__ is still a read-only proxy to the class namespace,
        # but the underlying storage is an OrderedDict instance

备注

This PEP, along with the existing ability to use __prepare__ to share a single namespace amongst multiple class objects, highlights a possible issue with the attribute lookup caching: when the underlying mapping is updated by other means, the attribute lookup cache is not invalidated correctly (this is a key part of the reason class __dict__ attributes produce a read-only view of the underlying storage).

Since the optimisation provided by that cache is highly desirable, the use of a preexisting namespace as the class namespace may need to be declared as officially unsupported (since the observed behaviour is rather strange when the caches get out of sync).

Key Benefits

Easier use of custom namespaces for a class

Currently, to use a different type (such as collections.OrderedDict) for a class namespace, or to use a pre-populated namespace, it is necessary to write and use a custom metaclass. With this PEP, using a custom namespace becomes as simple as specifying an appropriate factory function in the class header.

Easier inheritance of definition time behaviour

Understanding Python’s metaclasses requires a deep understanding of the type system and the class construction process. This is legitimately seen as challenging, due to the need to keep multiple moving parts (the code, the metaclass hint, the actual metaclass, the class object, instances of the class object) clearly distinct in your mind. Even when you know the rules, it’s still easy to make a mistake if you’re not being extremely careful. An earlier version of this PEP actually included such a mistake: it stated “subclass of type” for a constraint that is actually “instance of type”.

Understanding the proposed implicit class decoration hook only requires understanding decorators and ordinary method inheritance, which isn’t quite as daunting a task. The new hook provides a more gradual path towards understanding all of the phases involved in the class definition process.

Reduced chance of metaclass conflicts

One of the big issues that makes library authors reluctant to use metaclasses (even when they would be appropriate) is the risk of metaclass conflicts. These occur whenever two unrelated metaclasses are used by the desired parents of a class definition. This risk also makes it very difficult to add a metaclass to a class that has previously been published without one.

By contrast, adding an __autodecorate__ method to an existing type poses a similar level of risk to adding an __init__ method: technically, there is a risk of breaking poorly implemented subclasses, but when that occurs, it is recognised as a bug in the subclass rather than the library author breaching backwards compatibility guarantees. In fact, due to the constrained signature of __autodecorate__, the risk in this case is actually even lower than in the case of __init__.

Integrates cleanly with PEP 3135

Unlike code that runs as part of the metaclass, code that runs as part of the new hook will be able to freely invoke class methods that rely on the implicit __class__ reference introduced by PEP 3135, including methods that use the zero argument form of super().

Replaces many use cases for dynamic setting of `metaclass`

For use cases that don’t involve completely replacing the defined class, Python 2 code that dynamically set __metaclass__ can now dynamically set __autodecorate__ instead. For more advanced use cases, introduction of an explicit metaclass (possibly made available as a required base class) will still be necessary in order to support Python 3.

Design Notes

Determining if the class being decorated is the base class

In the body of an __autodecorate__ method, as in any other class method, __class__ will be bound to the class declaring the method, while the value passed in may be a subclass.

This makes it relatively straightforward to skip processing the base class if necessary:

class Example:
    def __autodecorate__(cls):
        cls = super().__autodecorate__()
        # Don't process the base class
        if cls is __class__:
            return
        # Process subclasses here
        ...

Replacing a class with a different kind of object

As an implicit decorator, __autodecorate__ is able to relatively easily replace the defined class with a different kind of object. Technically custom metaclasses and even __new__ methods can already do this implicitly, but the decorator model makes such code much easier to understand and implement.

class BuildDict:
    def __autodecorate__(cls):
        cls = super().__autodecorate__()
        # Don't process the base class
        if cls is __class__:
            return
        # Convert subclasses to ordinary dictionaries
        return cls.__dict__.copy()

It’s not clear why anyone would ever do this implicitly based on inheritance rather than just using an explicit decorator, but the possibility seems worth noting.

Open Questions

Is the `namespace` concept worth the extra complexity?

Unlike the new __autodecorate__ hook the proposed namespace keyword argument is not automatically inherited by subclasses. Given the way this proposal is currently written , the only way to get a special namespace used consistently in subclasses is still to write a custom metaclass with a suitable __prepare__ implementation.

Changing the custom namespace factory to also be inherited would significantly increase the complexity of this proposal, and introduce a number of the same potential base class conflict issues as arise with the use of custom metaclasses.

Eric Snow has put forward a separate proposal to instead make the execution namespace for class bodies an ordered dictionary by default, and capture the class attribute definition order for future reference as an attribute (e.g. __definition_order__) on the class object.

Eric’s suggested approach may be a better choice for a new default behaviour for type that combines well with the proposed __autodecorate__ hook, leaving the more complex configurable namespace factory idea to a custom metaclass like the one shown below.

New Ways of Using Classes

The new namespace keyword in the class header enables a number of interesting options for controlling the way a class is initialised, including some aspects of the object models of both Javascript and Ruby.

All of the examples below are actually possible today through the use of a custom metaclass:

class CustomNamespace(type):
    @classmethod
    def __prepare__(meta, name, bases, *, namespace=None, **kwds):
        parent_namespace = super().__prepare__(name, bases, **kwds)
        return namespace() if namespace is not None else parent_namespace
    def __new__(meta, name, bases, ns, *, namespace=None, **kwds):
        return super().__new__(meta, name, bases, ns, **kwds)
    def __init__(cls, name, bases, ns, *, namespace=None, **kwds):
        return super().__init__(name, bases, ns, **kwds)

The advantage of implementing the new keyword directly in type.__prepare__ is that the only persistent effect is then the change in the underlying storage of the class attributes. The metaclass of the class remains unchanged, eliminating many of the drawbacks typically associated with these kinds of customisations.

Order preserving classes

class OrderedClass(namespace=collections.OrderedDict):
    a = 1
    b = 2
    c = 3

Prepopulated namespaces

seed_data = dict(a=1, b=2, c=3)
class PrepopulatedClass(namespace=seed_data.copy):
    pass

Cloning a prototype class

class NewClass(namespace=Prototype.__dict__.copy):
    pass

Extending a class

备注

Just because the PEP makes it possible to do this relatively cleanly doesn’t mean anyone should do this!

from collections import MutableMapping

# The MutableMapping + dict combination should give something that
# generally behaves correctly as a mapping, while still being accepted
# as a class namespace
class ClassNamespace(MutableMapping, dict):
    def __init__(self, cls):
        self._cls = cls
    def __len__(self):
        return len(dir(self._cls))
    def __iter__(self):
        for attr in dir(self._cls):
            yield attr
    def __contains__(self, attr):
        return hasattr(self._cls, attr)
    def __getitem__(self, attr):
        return getattr(self._cls, attr)
    def __setitem__(self, attr, value):
        setattr(self._cls, attr, value)
    def __delitem__(self, attr):
        delattr(self._cls, attr)

def extend(cls):
    return lambda: ClassNamespace(cls)

class Example:
    pass

class ExtendedExample(namespace=extend(Example)):
    a = 1
    b = 2
    c = 3

>>> Example.a, Example.b, Example.c
(1, 2, 3)

Rejected Design Options

Calling `autodecorate` from `type.init`

Calling the new hook automatically from type.__init__, would achieve most of the goals of this PEP. However, using that approach would mean that __autodecorate__ implementations would be unable to call any methods that relied on the __class__ reference (or used the zero-argument form of super()), and could not make use of those features themselves.

The current design instead ensures that the implicit decorator hook is able to do anything an explicit decorator can do by running it after the initial class creation is already complete.

Calling the automatic decoration hook `__init_class__`

Earlier versions of the PEP used the name __init_class__ for the name of the new hook. There were three significant problems with this name:

it was hard to remember if the correct spelling was __init_class__ or __class_init__
the use of “init” in the name suggested the signature should match that of type.__init__, which is not the case
the use of “init” in the name suggested the method would be run as part of initial class object creation, which is not the case

The new name __autodecorate__ was chosen to make it clear that the new initialisation hook is most usefully thought of as an implicitly invoked class decorator, rather than as being like an __init__ method.

Requiring an explicit decorator on `autodecorate`

Originally, this PEP required the explicit use of @classmethod on the __autodecorate__ decorator. It was made implicit since there’s no sensible interpretation for leaving it out, and that case would need to be detected anyway in order to give a useful error message.

This decision was reinforced after noticing that the user experience of defining __prepare__ and forgetting the @classmethod method decorator is singularly incomprehensible (particularly since PEP 3115 documents it as an ordinary method, and the current documentation doesn’t explicitly say anything one way or the other).

Making `autodecorate` implicitly static, like `new`

While it accepts the class to be instantiated as the first argument, __new__ is actually implicitly treated as a static method rather than as a class method. This allows it to be readily extracted from its defining class and called directly on a subclass, rather than being coupled to the class object it is retrieved from.

Such behaviour initially appears to be potentially useful for the new __autodecorate__ hook, as it would allow __autodecorate__ methods to readily be used as explicit decorators on other classes.

However, that apparent support would be an illusion as it would only work correctly if invoked on a subclass, in which case the method can just as readily be retrieved from the subclass and called that way. Unlike __new__, there’s no issue with potentially changing method signatures at different points in the inheritance chain.

Passing in the namespace directly rather than a factory function

At one point, this PEP proposed that the class namespace be passed directly as a keyword argument, rather than passing a factory function. However, this encourages an unsupported behaviour (that is, passing the same namespace to multiple classes, or retaining direct write access to a mapping used as a class namespace), so the API was switched to the factory function version.

Reference Implementation

A reference implementation for __autodecorate__ has been posted to the issue tracker. It uses the original __init_class__ naming. does not yet allow the implicit decorator to replace the class with a different object and does not implement the suggested namespace parameter for type.__prepare__.

TODO

address the 5 points in https://mail.python.org/pipermail/python-dev/2013-February/123970.html

Copyright

This document has been placed in the public domain.

Source: https://github.com/python/peps/blob/main/pep-0422.txt

Last modified: 2022-03-09 16:04:44 GMT