merged
This commit is contained in:
commit
7395ae5657
651
pep-0362.txt
651
pep-0362.txt
|
@ -2,332 +2,468 @@ PEP: 362
|
|||
Title: Function Signature Object
|
||||
Version: $Revision$
|
||||
Last-Modified: $Date$
|
||||
Author: Brett Cannon <brett@python.org>, Jiwon Seo <seojiwon@gmail.com>
|
||||
Author: Brett Cannon <brett@python.org>, Jiwon Seo <seojiwon@gmail.com>,
|
||||
Yury Selivanov <yselivanov@sprymix.com>, Larry Hastings <larry@hastings.org>
|
||||
Status: Draft
|
||||
Type: Standards Track
|
||||
Content-Type: text/x-rst
|
||||
Created: 21-Aug-2006
|
||||
Python-Version: 2.6
|
||||
Post-History: 05-Sep-2007
|
||||
Python-Version: 3.3
|
||||
Post-History: 04-Jun-2012
|
||||
|
||||
|
||||
Abstract
|
||||
========
|
||||
|
||||
Python has always supported powerful introspection capabilities,
|
||||
including that for functions and methods (for the rest of this PEP the
|
||||
word "function" refers to both functions and methods). Taking a
|
||||
function object, you can fully reconstruct the function's signature.
|
||||
Unfortunately it is a little unruly having to look at all the
|
||||
different attributes to pull together complete information for a
|
||||
function's signature.
|
||||
including introspecting functions and methods (for the rest of
|
||||
this PEP, "function" refers to both functions and methods). By
|
||||
examining a function object you can fully reconstruct the function's
|
||||
signature. Unfortunately this information is stored in an inconvenient
|
||||
manner, and is spread across a half-dozen deeply nested attributes.
|
||||
|
||||
This PEP proposes an object representation for function signatures.
|
||||
This should help facilitate introspection on functions for various
|
||||
uses. The introspection information contains all possible information
|
||||
about the parameters in a signature (including Python 3.0 features).
|
||||
This PEP proposes a new representation for function signatures.
|
||||
The new representation contains all necessary information about a function
|
||||
and its parameters, and makes introspection easy and straightforward.
|
||||
|
||||
This object, though, is not meant to replace existing ways of
|
||||
introspection on a function's signature. The current solutions are
|
||||
there to make Python's execution work in an efficient manner. The
|
||||
proposed object representation is only meant to help make application
|
||||
code have an easier time to query a function on its signature.
|
||||
|
||||
|
||||
Purpose
|
||||
=======
|
||||
|
||||
An object representation of a function's call signature should provide
|
||||
an easy way to introspect what a function expects as arguments. It
|
||||
does not need to be a "live" representation, though; the signature can
|
||||
be inferred once and stored without changes to the signature object
|
||||
representation affecting the function it represents (but this is an
|
||||
`Open Issues`_).
|
||||
|
||||
Indirection of signature introspection can also occur. If a
|
||||
decorator took a decorated function's signature object and set it on
|
||||
the decorating function then introspection could be redirected to what
|
||||
is actually expected instead of the typical ``*args, **kwargs``
|
||||
signature of decorating functions.
|
||||
However, this object does not replace the existing function
|
||||
metadata, which is used by Python itself to execute those
|
||||
functions. The new metadata object is intended solely to make
|
||||
function introspection easier for Python programmers.
|
||||
|
||||
|
||||
Signature Object
|
||||
================
|
||||
|
||||
The overall signature of an object is represented by the Signature
|
||||
object. This object is to store a `Parameter object`_ for each
|
||||
parameter in the signature. It is also to store any information
|
||||
about the function itself that is pertinent to the signature.
|
||||
A Signature object represents the call signature of a function and
|
||||
its return annotation. For each parameter accepted by the function
|
||||
it stores a `Parameter object`_ in its ``parameters`` collection.
|
||||
|
||||
A Signature object has the following structure attributes:
|
||||
A Signature object has the following public attributes and methods:
|
||||
|
||||
* name : str
|
||||
Name of the function. This is not fully qualified because
|
||||
function objects for methods do not know the class they are
|
||||
contained within. This makes functions and methods
|
||||
indistinguishable from one another when passed to decorators,
|
||||
preventing proper creation of a fully qualified name.
|
||||
* var_args : str
|
||||
Name of the variable positional parameter (i.e., ``*args``), if
|
||||
present, or the empty string.
|
||||
* var_kw_args : str
|
||||
Name of the variable keyword parameter (i.e., ``**kwargs``), if
|
||||
present, or the empty string.
|
||||
* var_annotations: dict(str, object)
|
||||
Dict that contains the annotations for the variable parameters.
|
||||
The keys are of the variable parameter with values of the
|
||||
annotation. If an annotation does not exist for a variable
|
||||
parameter then the key does not exist in the dict.
|
||||
* return_annotation : object
|
||||
If present, the attribute is set to the annotation for the return
|
||||
type of the function.
|
||||
* parameters : list(Parameter)
|
||||
List of the parameters of the function as represented by
|
||||
Parameter objects in the order of its definition (keyword-only
|
||||
arguments are in the order listed by ``code.co_varnames``).
|
||||
* bind(\*args, \*\*kwargs) -> dict(str, object)
|
||||
Create a mapping from arguments to parameters. The keys are the
|
||||
names of the parameter that an argument maps to with the value
|
||||
being the value the parameter would have if this function was
|
||||
called with the given arguments.
|
||||
The annotation for the return type of the function if specified.
|
||||
If the function has no annotation for its return type, this
|
||||
attribute is not set.
|
||||
* parameters : OrderedDict
|
||||
An ordered mapping of parameters' names to the corresponding
|
||||
Parameter objects (keyword-only arguments are in the same order
|
||||
as listed in ``code.co_varnames``).
|
||||
* bind(\*args, \*\*kwargs) -> BoundArguments
|
||||
Creates a mapping from positional and keyword arguments to
|
||||
parameters. Raises a ``TypeError`` if the passed arguments do
|
||||
not match the signature.
|
||||
* bind_partial(\*args, \*\*kwargs) -> BoundArguments
|
||||
Works the same way as ``bind()``, but allows the omission
|
||||
of some required arguments (mimics ``functools.partial``
|
||||
behavior.) Raises a ``TypeError`` if the passed arguments do
|
||||
not match the signature.
|
||||
* format(...) -> str
|
||||
Formats the Signature object to a string. Optional arguments allow
|
||||
for custom render functions for parameter names,
|
||||
annotations and default values, along with custom separators.
|
||||
|
||||
Signature objects also have the following methods:
|
||||
Signature implements the ``__str__`` method, which fallbacks to the
|
||||
``Signature.format()`` call.
|
||||
|
||||
* __getitem__(self, key : str) -> Parameter
|
||||
Returns the Parameter object for the named parameter.
|
||||
* __iter__(self)
|
||||
Returns an iterator that returns Parameter objects in their
|
||||
sequential order based on their 'position' attribute.
|
||||
It's possible to test Signatures for equality. Two signatures
|
||||
are equal when they have equal parameters and return annotations.
|
||||
|
||||
The Signature object is stored in the ``__signature__`` attribute of
|
||||
a function. When it is to be created is discussed in
|
||||
`Open Issues`_.
|
||||
Changes to the Signature object, or to any of its data members,
|
||||
do not affect the function itself.
|
||||
|
||||
|
||||
Parameter Object
|
||||
================
|
||||
|
||||
A function's signature is made up of several parameters. Python's
|
||||
different kinds of parameters is quite large and rich and continues to
|
||||
grow. Parameter objects represent any possible parameter.
|
||||
|
||||
Originally the plan was to represent parameters using a list of
|
||||
parameter names on the Signature object along with various dicts keyed
|
||||
on parameter names to disseminate the various pieces of information
|
||||
one can know about a parameter. But the decision was made to
|
||||
incorporate all information about a parameter in a single object so
|
||||
as to make extending the information easier. This was originally put
|
||||
forth by Talin and the preferred form of Guido (as discussed at the
|
||||
2006 Google Sprint).
|
||||
Python's expressive syntax means functions can accept many different
|
||||
kinds of parameters with many subtle semantic differences. We
|
||||
propose a rich Parameter object designed to represent any possible
|
||||
function parameter.
|
||||
|
||||
The structure of the Parameter object is:
|
||||
|
||||
* name : (str | tuple(str))
|
||||
The name of the parameter as a string if it is not a tuple. If
|
||||
the argument is a tuple then a tuple of strings is used.
|
||||
* position : int
|
||||
The position of the parameter within the signature of the
|
||||
function (zero-indexed). For keyword-only parameters the position
|
||||
value is arbitrary while not conflicting with positional
|
||||
parameters. The suggestion of setting the attribute to None or -1
|
||||
to represent keyword-only parameters was rejected to prevent
|
||||
variable type usage and as a possible point of errors,
|
||||
respectively.
|
||||
* default_value : object
|
||||
The default value for the parameter, if present, else the
|
||||
attribute does not exist.
|
||||
* keyword_only : bool
|
||||
True if the parameter is keyword-only, else False.
|
||||
* annotation
|
||||
Set to the annotation for the parameter. If ``has_annotation`` is
|
||||
False then the attribute does not exist to prevent accidental use.
|
||||
* name : str
|
||||
The name of the parameter as a string.
|
||||
|
||||
* default : object
|
||||
The default value for the parameter, if specified. If the
|
||||
parameter has no default value, this attribute is not set.
|
||||
|
||||
* annotation : object
|
||||
The annotation for the parameter if specified. If the
|
||||
parameter has no annotation, this attribute is not set.
|
||||
|
||||
* kind : str
|
||||
Describes how argument values are bound to the parameter.
|
||||
Possible values:
|
||||
|
||||
* ``Parameter.POSITIONAL_ONLY`` - value must be supplied
|
||||
as a positional argument.
|
||||
|
||||
Python has no explicit syntax for defining positional-only
|
||||
parameters, but many builtin and extension module functions
|
||||
(especially those that accept only one or two parameters)
|
||||
accept them.
|
||||
|
||||
* ``Parameter.POSITIONAL_OR_KEYWORD`` - value may be
|
||||
supplied as either a keyword or positional argument
|
||||
(this is the standard binding behaviour for functions
|
||||
implemented in Python.)
|
||||
|
||||
* ``Parameter.KEYWORD_ONLY`` - value must be supplied
|
||||
as a keyword argument. Keyword only parameters are those
|
||||
which appear after a "*" or "\*args" entry in a Python
|
||||
function definition.
|
||||
|
||||
* ``Parameter.VAR_POSITIONAL`` - a tuple of positional
|
||||
arguments that aren't bound to any other parameter.
|
||||
This corresponds to a "\*args" parameter in a Python
|
||||
function definition.
|
||||
|
||||
* ``Parameter.VAR_KEYWORD`` - a dict of keyword arguments
|
||||
that aren't bound to any other parameter. This corresponds
|
||||
to a "\*\*kwds" parameter in a Python function definition.
|
||||
|
||||
* implemented : bool
|
||||
True if the parameter is implemented for use. Some platforms
|
||||
implement functions but can't support specific parameters
|
||||
(e.g. "mode" for ``os.mkdir``). Passing in an unimplemented
|
||||
parameter may result in the parameter being ignored,
|
||||
or in NotImplementedError being raised. It is intended that
|
||||
all conditions where ``implemented`` may be False be
|
||||
thoroughly documented.
|
||||
|
||||
Two parameters are equal when all their attributes are equal.
|
||||
|
||||
|
||||
BoundArguments Object
|
||||
=====================
|
||||
|
||||
Result of a ``Signature.bind`` call. Holds the mapping of arguments
|
||||
to the function's parameters.
|
||||
|
||||
Has the following public attributes:
|
||||
|
||||
* arguments : OrderedDict
|
||||
An ordered, mutable mapping of parameters' names to arguments' values.
|
||||
Does not contain arguments' default values.
|
||||
* args : tuple
|
||||
Tuple of positional arguments values. Dynamically computed from
|
||||
the 'arguments' attribute.
|
||||
* kwargs : dict
|
||||
Dict of keyword arguments values. Dynamically computed from
|
||||
the 'arguments' attribute.
|
||||
|
||||
The ``arguments`` attribute should be used in conjunction with
|
||||
``Signature.parameters`` for any arguments processing purposes.
|
||||
|
||||
``args`` and ``kwargs`` properties can be used to invoke functions:
|
||||
::
|
||||
|
||||
def test(a, *, b):
|
||||
...
|
||||
|
||||
sig = signature(test)
|
||||
ba = sig.bind(10, b=20)
|
||||
test(*ba.args, **ba.kwargs)
|
||||
|
||||
|
||||
Implementation
|
||||
==============
|
||||
|
||||
An implementation can be found in Python's sandbox [#impl]_.
|
||||
There is a function named ``signature()`` which
|
||||
returns the value stored on the ``__signature__`` attribute if it
|
||||
exists, else it creates the Signature object for the
|
||||
function and sets ``__signature__``. For methods this is stored
|
||||
directly on the im_func function object since that is what decorators
|
||||
work with.
|
||||
The implementation adds a new function ``signature()`` to the ``inspect``
|
||||
module. The function is the preferred way of getting a ``Signature`` for
|
||||
a callable object.
|
||||
|
||||
The function implements the following algorithm:
|
||||
|
||||
- If the object is not callable - raise a TypeError
|
||||
|
||||
- If the object has a ``__signature__`` attribute and if it
|
||||
is not ``None`` - return a deepcopy of it
|
||||
|
||||
- If it is ``None`` and the object is an instance of
|
||||
``BuiltinFunction``, raise a ``ValueError``
|
||||
|
||||
- If it has a ``__wrapped__`` attribute, return
|
||||
``signature(object.__wrapped__)``
|
||||
|
||||
- If the object is a an instance of ``FunctionType`` construct
|
||||
and return a new ``Signature`` for it
|
||||
|
||||
- If the object is a method or a classmethod, construct and return
|
||||
a new ``Signature`` object, with its first parameter (usually
|
||||
``self`` or ``cls``) removed
|
||||
|
||||
- If the object is a staticmethod, construct and return
|
||||
a new ``Signature`` object
|
||||
|
||||
- If the object is an instance of ``functools.partial``, construct
|
||||
a new ``Signature`` from its ``partial.func`` attribute, and
|
||||
account for already bound ``partial.args`` and ``partial.kwargs``
|
||||
|
||||
- If the object is a class or metaclass:
|
||||
|
||||
- If the object's type has a ``__call__`` method defined in
|
||||
its MRO, return a Signature for it
|
||||
|
||||
- If the object has a ``__new__`` method defined in its class,
|
||||
return a Signature object for it
|
||||
|
||||
- If the object has a ``__init__`` method defined in its class,
|
||||
return a Signature object for it
|
||||
|
||||
- Return ``signature(object.__call__)``
|
||||
|
||||
Note, that the ``Signature`` object is created in a lazy manner, and
|
||||
is not automatically cached. If, however, the Signature object was
|
||||
explicitly cached by the user, ``signature()`` returns a new deepcopy
|
||||
of it on each invocation.
|
||||
|
||||
An implementation for Python 3.3 can be found at [#impl]_.
|
||||
The python issue tracking the patch is [#issue]_.
|
||||
|
||||
|
||||
Design Considerations
|
||||
=====================
|
||||
|
||||
No implicit caching of Signature objects
|
||||
----------------------------------------
|
||||
|
||||
The first PEP design had a provision for implicit caching of ``Signature``
|
||||
objects in the ``inspect.signature()`` function. However, this has the
|
||||
following downsides:
|
||||
|
||||
* If the ``Signature`` object is cached then any changes to the function
|
||||
it describes will not be reflected in it. However, If the caching is
|
||||
needed, it can be always done manually and explicitly
|
||||
|
||||
* It is better to reserve the ``__signature__`` attribute for the cases
|
||||
when there is a need to explicitly set to a ``Signature`` object that
|
||||
is different from the actual one
|
||||
|
||||
|
||||
Examples
|
||||
========
|
||||
|
||||
Visualizing Callable Objects' Signature
|
||||
---------------------------------------
|
||||
|
||||
Let's define some classes and functions:
|
||||
|
||||
::
|
||||
|
||||
from inspect import signature
|
||||
from functools import partial, wraps
|
||||
|
||||
|
||||
class FooMeta(type):
|
||||
def __new__(mcls, name, bases, dct, *, bar:bool=False):
|
||||
return super().__new__(mcls, name, bases, dct)
|
||||
|
||||
def __init__(cls, name, bases, dct, **kwargs):
|
||||
return super().__init__(name, bases, dct)
|
||||
|
||||
|
||||
class Foo(metaclass=FooMeta):
|
||||
def __init__(self, spam:int=42):
|
||||
self.spam = spam
|
||||
|
||||
def __call__(self, a, b, *, c) -> tuple:
|
||||
return a, b, c
|
||||
|
||||
|
||||
def shared_vars(*shared_args):
|
||||
"""Decorator factory that defines shared variables that are
|
||||
passed to every invocation of the function"""
|
||||
|
||||
def decorator(f):
|
||||
@wraps(f)
|
||||
def wrapper(*args, **kwds):
|
||||
full_args = shared_args + args
|
||||
return f(*full_args, **kwds)
|
||||
# Override signature
|
||||
sig = wrapper.__signature__ = signature(f)
|
||||
for __ in shared_args:
|
||||
sig.parameters.popitem(last=False)
|
||||
return wrapper
|
||||
return decorator
|
||||
|
||||
|
||||
@shared_vars({})
|
||||
def example(_state, a, b, c):
|
||||
return _state, a, b, c
|
||||
|
||||
|
||||
def format_signature(obj):
|
||||
return str(signature(obj))
|
||||
|
||||
|
||||
Now, in the python REPL:
|
||||
|
||||
::
|
||||
|
||||
>>> format_signature(FooMeta)
|
||||
'(name, bases, dct, *, bar:bool=False)'
|
||||
|
||||
>>> format_signature(Foo)
|
||||
'(spam:int=42)'
|
||||
|
||||
>>> format_signature(Foo.__call__)
|
||||
'(self, a, b, *, c) -> tuple'
|
||||
|
||||
>>> format_signature(Foo().__call__)
|
||||
'(a, b, *, c) -> tuple'
|
||||
|
||||
>>> format_signature(partial(Foo().__call__, 1, c=3))
|
||||
'(b, *, c=3) -> tuple'
|
||||
|
||||
>>> format_signature(partial(partial(Foo().__call__, 1, c=3), 2, c=20))
|
||||
'(*, c=20) -> tuple'
|
||||
|
||||
>>> format_signature(example)
|
||||
'(a, b, c)'
|
||||
|
||||
>>> format_signature(partial(example, 1, 2))
|
||||
'(c)'
|
||||
|
||||
>>> format_signature(partial(partial(example, 1, b=2), c=3))
|
||||
'(b=2, c=3)'
|
||||
|
||||
|
||||
Annotation Checker
|
||||
------------------
|
||||
::
|
||||
|
||||
def quack_check(fxn):
|
||||
"""Decorator to verify arguments and return value quack as they should.
|
||||
import inspect
|
||||
import functools
|
||||
|
||||
Positional arguments.
|
||||
>>> @quack_check
|
||||
... def one_arg(x:int): pass
|
||||
...
|
||||
>>> one_arg(42)
|
||||
>>> one_arg('a')
|
||||
Traceback (most recent call last):
|
||||
...
|
||||
TypeError: 'a' does not quack like a <type 'int'>
|
||||
def checktypes(func):
|
||||
'''Decorator to verify arguments and return types
|
||||
|
||||
Example:
|
||||
|
||||
*args
|
||||
>>> @quack_check
|
||||
... def var_args(*args:int): pass
|
||||
...
|
||||
>>> var_args(*[1,2,3])
|
||||
>>> var_args(*[1,'b',3])
|
||||
Traceback (most recent call last):
|
||||
...
|
||||
TypeError: *args contains a a value that does not quack like a <type 'int'>
|
||||
>>> @checktypes
|
||||
... def test(a:int, b:str) -> int:
|
||||
... return int(a * b)
|
||||
|
||||
**kwargs
|
||||
>>> @quack_check
|
||||
... def var_kw_args(**kwargs:int): pass
|
||||
...
|
||||
>>> var_kw_args(**{'a': 1})
|
||||
>>> var_kw_args(**{'a': 'A'})
|
||||
Traceback (most recent call last):
|
||||
...
|
||||
TypeError: **kwargs contains a value that does not quack like a <type 'int'>
|
||||
>>> test(10, '1')
|
||||
1111111111
|
||||
|
||||
Return annotations.
|
||||
>>> @quack_check
|
||||
... def returned(x) -> int: return x
|
||||
...
|
||||
>>> returned(42)
|
||||
42
|
||||
>>> returned('a')
|
||||
Traceback (most recent call last):
|
||||
...
|
||||
TypeError: the return value 'a' does not quack like a <type 'int'>
|
||||
>>> test(10, 1)
|
||||
Traceback (most recent call last):
|
||||
...
|
||||
ValueError: foo: wrong type of 'b' argument, 'str' expected, got 'int'
|
||||
'''
|
||||
|
||||
"""
|
||||
# Get the signature; only needs to be calculated once.
|
||||
sig = Signature(fxn)
|
||||
def check(*args, **kwargs):
|
||||
# Find out the variable -> value bindings.
|
||||
bindings = sig.bind(*args, **kwargs)
|
||||
# Check *args for the proper quack.
|
||||
sig = inspect.signature(func)
|
||||
|
||||
types = {}
|
||||
for param in sig.parameters.values():
|
||||
# Iterate through function's parameters and build the list of
|
||||
# arguments types
|
||||
try:
|
||||
duck = sig.var_annotations[sig.var_args]
|
||||
except KeyError:
|
||||
pass
|
||||
type_ = param.annotation
|
||||
except AttributeError:
|
||||
continue
|
||||
else:
|
||||
# Check every value in *args.
|
||||
for value in bindings[sig.var_args]:
|
||||
if not isinstance(value, duck):
|
||||
raise TypeError("*%s contains a a value that does not "
|
||||
"quack like a %r" %
|
||||
(sig.var_args, duck))
|
||||
# Remove it from the bindings so as to not check it again.
|
||||
del bindings[sig.var_args]
|
||||
# **kwargs.
|
||||
try:
|
||||
duck = sig.var_annotations[sig.var_kw_args]
|
||||
except (KeyError, AttributeError):
|
||||
pass
|
||||
else:
|
||||
# Check every value in **kwargs.
|
||||
for value in bindings[sig.var_kw_args].values():
|
||||
if not isinstance(value, duck):
|
||||
raise TypeError("**%s contains a value that does not "
|
||||
"quack like a %r" %
|
||||
(sig.var_kw_args, duck))
|
||||
# Remove from bindings so as to not check again.
|
||||
del bindings[sig.var_kw_args]
|
||||
# For each remaining variable ...
|
||||
for var, value in bindings.items():
|
||||
# See if an annotation was set.
|
||||
if not inspect.isclass(type_):
|
||||
# Not a type, skip it
|
||||
continue
|
||||
|
||||
types[param.name] = type_
|
||||
|
||||
# If the argument has a type specified, let's check that its
|
||||
# default value (if present) conforms with the type.
|
||||
try:
|
||||
duck = sig[var].annotation
|
||||
default = param.default
|
||||
except AttributeError:
|
||||
continue
|
||||
# Check that the value quacks like it should.
|
||||
if not isinstance(value, duck):
|
||||
raise TypeError('%r does not quack like a %s' % (value, duck))
|
||||
else:
|
||||
# All the ducks quack fine; let the call proceed.
|
||||
returned = fxn(*args, **kwargs)
|
||||
# Check the return value.
|
||||
else:
|
||||
if not isinstance(default, type_):
|
||||
raise ValueError("{func}: wrong type of a default value for {arg!r}". \
|
||||
format(func=func.__qualname__, arg=param.name))
|
||||
|
||||
def check_type(sig, arg_name, arg_type, arg_value):
|
||||
# Internal function that encapsulates arguments type checking
|
||||
if not isinstance(arg_value, arg_type):
|
||||
raise ValueError("{func}: wrong type of {arg!r} argument, " \
|
||||
"{exp!r} expected, got {got!r}". \
|
||||
format(func=func.__qualname__, arg=arg_name,
|
||||
exp=arg_type.__name__, got=type(arg_value).__name__))
|
||||
|
||||
@functools.wraps(func)
|
||||
def wrapper(*args, **kwargs):
|
||||
# Let's bind the arguments
|
||||
ba = sig.bind(*args, **kwargs)
|
||||
for arg_name, arg in ba.arguments.items():
|
||||
# And iterate through the bound arguments
|
||||
try:
|
||||
if not isinstance(returned, sig.return_annotation):
|
||||
raise TypeError('the return value %r does not quack like '
|
||||
'a %r' % (returned,
|
||||
sig.return_annotation))
|
||||
except AttributeError:
|
||||
pass
|
||||
return returned
|
||||
# Full-featured version would set function metadata.
|
||||
return check
|
||||
type_ = types[arg_name]
|
||||
except KeyError:
|
||||
continue
|
||||
else:
|
||||
# OK, we have a type for the argument, lets get the corresponding
|
||||
# parameter description from the signature object
|
||||
param = sig.parameters[arg_name]
|
||||
if param.kind == param.VAR_POSITIONAL:
|
||||
# If this parameter is a variable-argument parameter,
|
||||
# then we need to check each of its values
|
||||
for value in arg:
|
||||
check_type(sig, arg_name, type_, value)
|
||||
elif param.kind == param.VAR_KEYWORD:
|
||||
# If this parameter is a variable-keyword-argument parameter:
|
||||
for subname, value in arg.items():
|
||||
check_type(sig, arg_name + ':' + subname, type_, value)
|
||||
else:
|
||||
# And, finally, if this parameter a regular one:
|
||||
check_type(sig, arg_name, type_, arg)
|
||||
|
||||
result = func(*ba.args, **ba.kwargs)
|
||||
# The last bit - let's check that the result is correct
|
||||
try:
|
||||
return_type = sig.return_annotation
|
||||
except AttributeError:
|
||||
# Looks like we don't have any restriction on the return type
|
||||
pass
|
||||
else:
|
||||
if isinstance(return_type, type) and not isinstance(result, return_type):
|
||||
raise ValueError('{func}: wrong return type, {exp} expected, got {got}'. \
|
||||
format(func=func.__qualname__, exp=return_type.__name__,
|
||||
got=type(result).__name__))
|
||||
return result
|
||||
|
||||
return wrapper
|
||||
|
||||
|
||||
Open Issues
|
||||
===========
|
||||
Render Function Signature to HTML
|
||||
---------------------------------
|
||||
|
||||
When to construct the Signature object?
|
||||
---------------------------------------
|
||||
::
|
||||
|
||||
The Signature object can either be created in an eager or lazy
|
||||
fashion. In the eager situation, the object can be created during
|
||||
creation of the function object. In the lazy situation, one would
|
||||
pass a function object to a function and that would generate the
|
||||
Signature object and store it to ``__signature__`` if
|
||||
needed, and then return the value of ``__signature__``.
|
||||
import inspect
|
||||
|
||||
def format_to_html(func):
|
||||
sig = inspect.signature(func)
|
||||
|
||||
Should ``Signature.bind`` return Parameter objects as keys?
|
||||
-----------------------------------------------------------
|
||||
html = sig.format(token_params_separator='<span class="t-comma">,</span>',
|
||||
token_colon='<span class="t-colon">:</span>',
|
||||
token_eq='<span class="t-eq">=</span>',
|
||||
token_return_annotation='<span class="t-ra">-></span>',
|
||||
token_left_paren='<span class="t-lp">(</span>',
|
||||
token_right_paren='<span class="t-lp">)</span>',
|
||||
token_kwonly_separator='<span class="t-ast">*</span>',
|
||||
format_name=lambda name: '<span class="name">'+name+'</span>')
|
||||
|
||||
Instead of returning a dict with keys consisting of the name of the
|
||||
parameters, would it be more useful to instead use Parameter
|
||||
objects? The name of the argument can easily be retrieved from the
|
||||
key (and the name would be used as the hash for a Parameter object).
|
||||
|
||||
|
||||
Have ``var_args`` and ``_var_kw_args`` default to ``None``?
|
||||
------------------------------------------------------------
|
||||
|
||||
It has been suggested by Fred Drake that these two attributes have a
|
||||
value of ``None`` instead of empty strings when they do not exist.
|
||||
The answer to this question will influence what the defaults are for
|
||||
other attributes as well.
|
||||
|
||||
|
||||
Deprecate ``inspect.getargspec()`` and ``.formatargspec()``?
|
||||
-------------------------------------------------------------
|
||||
|
||||
Since the Signature object replicates the use of ``getargspec()``
|
||||
from the ``inspect`` module it might make sense to deprecate it in
|
||||
2.6. ``formatargspec()`` could also go if Signature objects gained a
|
||||
__str__ representation.
|
||||
|
||||
Issue with that is types such as ``int``, when used as annotations,
|
||||
do not lend themselves for output (e.g., ``"<type 'int'>"`` is the
|
||||
string represenation for ``int``). The repr representation of types
|
||||
would need to change in order to make this reasonable.
|
||||
|
||||
|
||||
Have the objects be "live"?
|
||||
---------------------------
|
||||
|
||||
Jim Jewett pointed out that Signature and Parameter objects could be
|
||||
"live". That would mean requesting information would be done on the
|
||||
fly instead of caching it on the objects. It would also allow for
|
||||
mutating the function if the Signature or Parameter objects were
|
||||
mutated.
|
||||
return '<span class="py-func">{}</span>'.format(html)
|
||||
|
||||
|
||||
References
|
||||
==========
|
||||
|
||||
.. [#impl] pep362 directory in Python's sandbox
|
||||
(http://svn.python.org/view/sandbox/trunk/pep362/)
|
||||
.. [#impl] pep362 branch (https://bitbucket.org/1st1/cpython/overview)
|
||||
.. [#issue] issue 15008 (http://bugs.python.org/issue15008)
|
||||
|
||||
|
||||
Copyright
|
||||
|
@ -335,7 +471,6 @@ Copyright
|
|||
|
||||
This document has been placed in the public domain.
|
||||
|
||||
|
||||
|
||||
..
|
||||
Local Variables:
|
||||
|
|
|
@ -70,6 +70,7 @@ Implemented / Final PEPs:
|
|||
* PEP 417: Including mock in the Standard Library
|
||||
* PEP 418: Add monotonic time, performance counter, and process time functions
|
||||
* PEP 420: Implicit Namespace Packages
|
||||
* PEP 421: Adding sys.implementation
|
||||
* PEP 3118: Revising the buffer protocol (protocol semantics finalised)
|
||||
* PEP 3144: IP Address manipulation library
|
||||
* PEP 3151: Reworking the OS and IO exception hierarchy
|
||||
|
@ -87,8 +88,6 @@ Candidate PEPs:
|
|||
|
||||
* PEP 362: Function Signature Object
|
||||
* PEP 397: Python launcher for Windows
|
||||
* PEP 421: Adding sys.implementation
|
||||
* PEP 3143: Standard daemon process library
|
||||
* PEP 3154: Pickle protocol version 4
|
||||
|
||||
(Note that these are not accepted yet and even if they are, they might
|
||||
|
@ -105,6 +104,7 @@ Other planned large-scale changes:
|
|||
Deferred to post-3.3:
|
||||
|
||||
* PEP 395: Qualified Names for Modules
|
||||
* PEP 3143: Standard daemon process library
|
||||
* Breaking out standard library and docs in separate repos
|
||||
|
||||
Copyright
|
||||
|
|
18
pep-0405.txt
18
pep-0405.txt
|
@ -4,7 +4,7 @@ Version: $Revision$
|
|||
Last-Modified: $Date$
|
||||
Author: Carl Meyer <carl@oddbird.net>
|
||||
BDFL-Delegate: Nick Coghlan
|
||||
Status: Accepted
|
||||
Status: Final
|
||||
Type: Standards Track
|
||||
Content-Type: text/x-rst
|
||||
Created: 13-Jun-2011
|
||||
|
@ -285,15 +285,15 @@ Include files
|
|||
|
||||
Current virtualenv handles include files in this way:
|
||||
|
||||
On POSIX systems where the installed Python's include files are found
|
||||
in ``${base_prefix}/include/pythonX.X``, virtualenv creates
|
||||
``${venv}/include/`` and symlink ``${base_prefix}/include/pythonX.X``
|
||||
On POSIX systems where the installed Python's include files are found in
|
||||
``${base_prefix}/include/pythonX.X``, virtualenv creates
|
||||
``${venv}/include/`` and symlinks ``${base_prefix}/include/pythonX.X``
|
||||
to ``${venv}/include/pythonX.X``. On Windows, where Python's include
|
||||
files are found in ``{{ sys.prefix }}/Include`` and symlinks are not
|
||||
reliably available, virtualenv copies ``{{ sys.prefix }}/Include`` to
|
||||
``${venv}/Include``. This ensures that extension modules built and
|
||||
installed within the virtualenv will always find the Python header
|
||||
files they need in the expected location relative to ``sys.prefix``.
|
||||
installed within the virtualenv will always find the Python header files
|
||||
they need in the expected location relative to ``sys.prefix``.
|
||||
|
||||
This solution is not ideal when an extension module installs its own
|
||||
header files, as the default installation location for those header
|
||||
|
@ -467,10 +467,10 @@ than ``sys.site_prefix`` or the appropriate ``site`` API to find
|
|||
site-packages directories.
|
||||
|
||||
The most notable case is probably `setuptools`_ and its fork
|
||||
`distribute`_, which mostly use ``distutils``and ``sysconfig`` APIs,
|
||||
`distribute`_, which mostly use ``distutils`` and ``sysconfig`` APIs,
|
||||
but do use ``sys.prefix`` directly to build up a list of site
|
||||
directories for pre-flight checking where ``pth`` files can usefully
|
||||
be placed.
|
||||
directories for pre-flight checking where ``pth`` files can usefully be
|
||||
placed.
|
||||
|
||||
Otherwise, a `Google Code Search`_ turns up what appears to be a
|
||||
roughly even mix of usage between packages using ``sys.prefix`` to
|
||||
|
|
|
@ -3,7 +3,7 @@ Title: Implicit Namespace Packages
|
|||
Version: $Revision$
|
||||
Last-Modified: $Date$
|
||||
Author: Eric V. Smith <eric@trueblade.com>
|
||||
Status: Accepted
|
||||
Status: Final
|
||||
Type: Standards Track
|
||||
Content-Type: text/x-rst
|
||||
Created: 19-Apr-2012
|
||||
|
|
|
@ -4,7 +4,7 @@ Version: $Revision$
|
|||
Last-Modified: $Date$
|
||||
Author: Eric Snow <ericsnowcurrently@gmail.com>
|
||||
BDFL-Delegate: Barry Warsaw
|
||||
Status: Accepted
|
||||
Status: Final
|
||||
Type: Standards Track
|
||||
Content-Type: text/x-rst
|
||||
Created: 26-April-2012
|
||||
|
|
|
@ -0,0 +1,354 @@
|
|||
PEP: 422
|
||||
Title: Simple class initialisation hook
|
||||
Version: $Revision$
|
||||
Last-Modified: $Date$
|
||||
Author: Nick Coghlan <ncoghlan@gmail.com>
|
||||
Status: Draft
|
||||
Type: Standards Track
|
||||
Content-Type: text/x-rst
|
||||
Created: 5-Jun-2012
|
||||
Python-Version: 3.4
|
||||
Post-History: 5-Jun-2012
|
||||
|
||||
|
||||
Abstract
|
||||
========
|
||||
|
||||
In Python 2, the body of a class definition could modify the way a class
|
||||
was created (or simply arrange to run other code after the class was created)
|
||||
by setting the ``__metaclass__`` attribute in the class body. While doing
|
||||
this implicitly from called code required the use of an implementation detail
|
||||
(specifically, ``sys._getframes()``), it could also be done explicitly in a
|
||||
fully supported fashion (for example, by passing ``locals()`` to an
|
||||
function that calculated a suitable ``__metaclass__`` value)
|
||||
|
||||
There is currently no corresponding mechanism in Python 3 that allows the
|
||||
code executed in the class body to directly influence how the class object
|
||||
is created. Instead, the class creation process is fully defined by the
|
||||
class header, before the class body even begins executing.
|
||||
|
||||
This PEP proposes a mechanism that will once again allow the body of a
|
||||
class definition to more directly influence the way a class is created
|
||||
(albeit in a more constrained fashion), as well as replacing some current
|
||||
uses of metaclasses with a simpler, easier to understand alternative.
|
||||
|
||||
|
||||
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 a subclass 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 machiner).
|
||||
|
||||
|
||||
Proposal
|
||||
========
|
||||
|
||||
This PEP proposes that a mechanism be added to Python 3 that meets the
|
||||
following criteria:
|
||||
|
||||
1. 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
|
||||
2. Integrates nicely with class inheritance structures (including mixins and
|
||||
multiple inheritance)
|
||||
3. Integrates nicely with the implicit ``__class__`` reference and
|
||||
zero-argument ``super()`` syntax introduced by PEP 3135
|
||||
4. Can be added to an existing base class without a significant risk of
|
||||
introducing backwards compatibility problems
|
||||
|
||||
One mechanism that can achieve this goal is to add a new class
|
||||
initialisation hook, modelled directly on the existing instance
|
||||
initialisation hook, but with the signature constrained to match that
|
||||
of an ordinary class decorator.
|
||||
|
||||
Specifically, it is proposed that class definitions be able to provide a
|
||||
class initialisation hook as follows::
|
||||
|
||||
class Example:
|
||||
@classmethod
|
||||
def __init_class__(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 decorator style invocation helps
|
||||
# ensure that invoking the parent class is as simple as possible.
|
||||
|
||||
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.
|
||||
|
||||
If a metaclass wishes to block class initialisation for some reason, it
|
||||
must arrange for ``cls.__init_class__`` to trigger ``AttributeError``.
|
||||
|
||||
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 I believe the situation has changed sufficiently in recent years that
|
||||
the idea is worth reconsidering.
|
||||
|
||||
|
||||
Key Benefits
|
||||
============
|
||||
|
||||
|
||||
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 ``__init_class__`` 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.
|
||||
|
||||
|
||||
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 "instance of type" for a constraint that is actually "subclass of
|
||||
type".
|
||||
|
||||
Understanding the proposed class initialisation 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 ``__init_class__`` 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 ``__init_class__``, 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()``.
|
||||
|
||||
|
||||
Alternatives
|
||||
============
|
||||
|
||||
|
||||
The Python 3 Status Quo
|
||||
-----------------------
|
||||
|
||||
The Python 3 status quo already offers a great deal of flexibility. For
|
||||
changes which only affect a single class definition and which can be
|
||||
specified at the time the code is written, then class decorators can be
|
||||
used to modify a class explicitly. Class decorators largely ignore class
|
||||
inheritance and can make full use of methods that rely on the ``__class__``
|
||||
reference being populated.
|
||||
|
||||
Using a custom metaclass provides the same level of power as it did in
|
||||
Python 2. However, it's notable that, unlike class decorators, a metaclass
|
||||
cannot call any methods that rely on the ``__class__`` reference, as that
|
||||
reference is not populated until after the metaclass constructor returns
|
||||
control to the class creation code.
|
||||
|
||||
One major use case for metaclasses actually closely resembles the use of
|
||||
class decorators. It occurs whenever a metaclass has an implementation that
|
||||
uses the following pattern::
|
||||
|
||||
class Metaclass(type):
|
||||
def __new__(meta, *args, **kwds):
|
||||
cls = super(Metaclass, meta).__new__(meta, *args, **kwds)
|
||||
# Do something with cls
|
||||
return cls
|
||||
|
||||
The key difference between this pattern and a class decorator is that it
|
||||
is automatically inherited by subclasses. However, it also comes with a
|
||||
major disadvantage: Python does not allow you to inherit from classes with
|
||||
unrelated metaclasses.
|
||||
|
||||
Thus, the status quo requires that developers choose between the following
|
||||
two alternatives:
|
||||
|
||||
* Use a class decorator, meaning that behaviour is not inherited and must be
|
||||
requested explicitly on every subclass
|
||||
* Use a metaclass, meaning that behaviour is inherited, but metaclass
|
||||
conflicts may make integration with other libraries and frameworks more
|
||||
difficult than it otherwise would be
|
||||
|
||||
If this PEP is ultimately rejected, then this is the existing design that
|
||||
will remain in place by default.
|
||||
|
||||
|
||||
Restoring the Python 2 metaclass hook
|
||||
-------------------------------------
|
||||
|
||||
One simple alternative would be to restore support for a Python 2 style
|
||||
``metaclass`` hook in the class body. This would be checked after the class
|
||||
body was executed, potentially overwriting the metaclass hint provided in the
|
||||
class header.
|
||||
|
||||
The main attraction of such an approach is that it would simplify porting
|
||||
Python 2 applications that make use of this hook (especially those that do
|
||||
so dynamically).
|
||||
|
||||
However, this approach does nothing to simplify the process of adding
|
||||
*inherited* class definition time behaviour, nor does it interoperate
|
||||
cleanly with the PEP 3135 ``__class__`` and ``super()`` semantics (as with
|
||||
any metaclass based solution, the ``__metaclass__`` hook would have to run
|
||||
before the ``__class__`` reference has been populated.
|
||||
|
||||
|
||||
Dynamic class decorators
|
||||
------------------------
|
||||
|
||||
The original version of this PEP was called "Dynamic class decorators" and
|
||||
focused solely on a significantly more complicated proposal than that
|
||||
presented in the current version.
|
||||
|
||||
As with the current version, it proposed that a new step be added to the
|
||||
class creation process, after the metaclass invocation to construct the
|
||||
class instance and before the application of lexical decorators. However,
|
||||
instead of a simple process of calling a single class method that relies
|
||||
on normal inheritance mechanisms, it proposed a far more complicated
|
||||
procedure that walked the class MRO looking for decorators stored in
|
||||
iterable ``__decorators__`` attributes.
|
||||
|
||||
Using the current version of the PEP, the scheme originally proposed could
|
||||
be implemented as::
|
||||
|
||||
class DynamicDecorators:
|
||||
@classmethod
|
||||
def __init_class__(cls):
|
||||
super(DynamicDecorators, cls).__init_class__()
|
||||
for entry in reversed(cls.mro()):
|
||||
decorators = entry.__dict__.get("__decorators__", ())
|
||||
for deco in reversed(decorators):
|
||||
cls = deco(cls)
|
||||
|
||||
Any subclasses of this type would automatically have the contents of any
|
||||
``__decorators__`` attributes processed and invoked.
|
||||
|
||||
The mechanism in the current PEP is considered superior, as many issues
|
||||
to do with ordering and the same decorator being invoked multiple times
|
||||
just go away, as that kind of thing is taken care of through the use of an
|
||||
ordinary class method invocation.
|
||||
|
||||
|
||||
Automatic metaclass derivation
|
||||
------------------------------
|
||||
|
||||
When no appropriate metaclass is found, it's theoretically possible to
|
||||
automatically derive a metaclass for a new type based on the metaclass hint
|
||||
and the metaclasses of the bases.
|
||||
|
||||
While adding such a mechanism would reduce the risk of spurious metaclass
|
||||
conflicts, it would do nothing to improve integration with PEP 3135, would
|
||||
not help with porting Python 2 code that set ``__metaclass__`` dynamically
|
||||
and would not provide a more straightforward inherited mechanism for invoking
|
||||
additional operations after the class invocation is complete.
|
||||
|
||||
In addition, there would still be a risk of metaclass conflicts in cases
|
||||
where the base metaclasses were not written with multiple inheritance in
|
||||
mind. In such situations, there's a chance of introducing latent defects
|
||||
if one or more metaclasses are not invoked correctly.
|
||||
|
||||
|
||||
Calling the new hook 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
|
||||
``__init_class__`` 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.
|
||||
|
||||
|
||||
References
|
||||
==========
|
||||
|
||||
.. _published code:
|
||||
http://mail.python.org/pipermail/python-dev/2012-June/119878.html
|
||||
|
||||
.. _more than 10 years ago:
|
||||
http://mail.python.org/pipermail/python-dev/2001-November/018651.html
|
||||
|
||||
.. _Zope's ExtensionClass:
|
||||
http://docs.zope.org/zope_secrets/extensionclass.html
|
||||
|
||||
Copyright
|
||||
=========
|
||||
|
||||
This document has been placed in the public domain.
|
||||
|
||||
|
||||
..
|
||||
Local Variables:
|
||||
mode: indented-text
|
||||
indent-tabs-mode: nil
|
||||
sentence-end-double-space: t
|
||||
fill-column: 70
|
||||
coding: utf-8
|
||||
End:
|
||||
|
Loading…
Reference in New Issue