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craftbeerpi4-pione/venv/lib/python3.8/site-packages/pylint/checkers/classes.py

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# -*- coding: utf-8 -*-
# Copyright (c) 2006-2016 LOGILAB S.A. (Paris, FRANCE) <contact@logilab.fr>
# Copyright (c) 2010 Maarten ter Huurne <maarten@treewalker.org>
# Copyright (c) 2012-2014 Google, Inc.
# Copyright (c) 2012 FELD Boris <lothiraldan@gmail.com>
# Copyright (c) 2013-2020 Claudiu Popa <pcmanticore@gmail.com>
# Copyright (c) 2014 Michal Nowikowski <godfryd@gmail.com>
# Copyright (c) 2014 Brett Cannon <brett@python.org>
# Copyright (c) 2014 Arun Persaud <arun@nubati.net>
# Copyright (c) 2014 David Pursehouse <david.pursehouse@gmail.com>
# Copyright (c) 2015 Dmitry Pribysh <dmand@yandex.ru>
# Copyright (c) 2015 Ionel Cristian Maries <contact@ionelmc.ro>
# Copyright (c) 2016-2017 Łukasz Rogalski <rogalski.91@gmail.com>
# Copyright (c) 2016 Alexander Todorov <atodorov@otb.bg>
# Copyright (c) 2016 Anthony Foglia <afoglia@users.noreply.github.com>
# Copyright (c) 2016 Florian Bruhin <me@the-compiler.org>
# Copyright (c) 2016 Moises Lopez <moylop260@vauxoo.com>
# Copyright (c) 2016 Jakub Wilk <jwilk@jwilk.net>
# Copyright (c) 2017, 2019 hippo91 <guillaume.peillex@gmail.com>
# Copyright (c) 2018, 2020 Anthony Sottile <asottile@umich.edu>
# Copyright (c) 2018-2019 Nick Drozd <nicholasdrozd@gmail.com>
# Copyright (c) 2018-2019 Ashley Whetter <ashley@awhetter.co.uk>
# Copyright (c) 2018 Lucas Cimon <lucas.cimon@gmail.com>
# Copyright (c) 2018 Bryce Guinta <bryce.paul.guinta@gmail.com>
# Copyright (c) 2018 ssolanki <sushobhitsolanki@gmail.com>
# Copyright (c) 2018 Ben Green <benhgreen@icloud.com>
# Copyright (c) 2018 Ville Skyttä <ville.skytta@iki.fi>
# Copyright (c) 2019-2020 Pierre Sassoulas <pierre.sassoulas@gmail.com>
# Copyright (c) 2019 mattlbeck <17108752+mattlbeck@users.noreply.github.com>
# Copyright (c) 2019-2020 craig-sh <craig-sh@users.noreply.github.com>
# Copyright (c) 2019 Janne Rönkkö <jannero@users.noreply.github.com>
# Copyright (c) 2019 Hugo van Kemenade <hugovk@users.noreply.github.com>
# Copyright (c) 2019 Grygorii Iermolenko <gyermolenko@gmail.com>
# Copyright (c) 2019 Andrzej Klajnert <github@aklajnert.pl>
# Copyright (c) 2019 Pascal Corpet <pcorpet@users.noreply.github.com>
# Licensed under the GPL: https://www.gnu.org/licenses/old-licenses/gpl-2.0.html
# For details: https://github.com/PyCQA/pylint/blob/master/COPYING
"""classes checker for Python code
"""
import collections
from itertools import chain, zip_longest
import astroid
from astroid import decorators, objects
from astroid.bases import BUILTINS, Generator
from astroid.exceptions import DuplicateBasesError, InconsistentMroError
from astroid.scoped_nodes import function_to_method
from pylint.checkers import BaseChecker
from pylint.checkers.utils import (
PYMETHODS,
SPECIAL_METHODS_PARAMS,
check_messages,
class_is_abstract,
decorated_with,
decorated_with_property,
has_known_bases,
is_attr_private,
is_attr_protected,
is_builtin_object,
is_comprehension,
is_iterable,
is_overload_stub,
is_property_setter,
is_property_setter_or_deleter,
is_protocol_class,
node_frame_class,
overrides_a_method,
safe_infer,
unimplemented_abstract_methods,
)
from pylint.interfaces import IAstroidChecker
from pylint.utils import get_global_option
NEXT_METHOD = "__next__"
INVALID_BASE_CLASSES = {"bool", "range", "slice", "memoryview"}
BUILTIN_DECORATORS = {"builtins.property", "builtins.classmethod"}
# Dealing with useless override detection, with regard
# to parameters vs arguments
_CallSignature = collections.namedtuple(
"_CallSignature", "args kws starred_args starred_kws"
)
_ParameterSignature = collections.namedtuple(
"_ParameterSignature", "args kwonlyargs varargs kwargs"
)
def _signature_from_call(call):
kws = {}
args = []
starred_kws = []
starred_args = []
for keyword in call.keywords or []:
arg, value = keyword.arg, keyword.value
if arg is None and isinstance(value, astroid.Name):
# Starred node and we are interested only in names,
# otherwise some transformation might occur for the parameter.
starred_kws.append(value.name)
elif isinstance(value, astroid.Name):
kws[arg] = value.name
else:
kws[arg] = None
for arg in call.args:
if isinstance(arg, astroid.Starred) and isinstance(arg.value, astroid.Name):
# Positional variadic and a name, otherwise some transformation
# might have occurred.
starred_args.append(arg.value.name)
elif isinstance(arg, astroid.Name):
args.append(arg.name)
else:
args.append(None)
return _CallSignature(args, kws, starred_args, starred_kws)
def _signature_from_arguments(arguments):
kwarg = arguments.kwarg
vararg = arguments.vararg
args = [
arg.name
for arg in chain(arguments.posonlyargs, arguments.args)
if arg.name != "self"
]
kwonlyargs = [arg.name for arg in arguments.kwonlyargs]
return _ParameterSignature(args, kwonlyargs, vararg, kwarg)
def _definition_equivalent_to_call(definition, call):
"""Check if a definition signature is equivalent to a call."""
if definition.kwargs:
same_kw_variadics = definition.kwargs in call.starred_kws
else:
same_kw_variadics = not call.starred_kws
if definition.varargs:
same_args_variadics = definition.varargs in call.starred_args
else:
same_args_variadics = not call.starred_args
same_kwonlyargs = all(kw in call.kws for kw in definition.kwonlyargs)
same_args = definition.args == call.args
no_additional_kwarg_arguments = True
if call.kws:
for keyword in call.kws:
is_arg = keyword in call.args
is_kwonly = keyword in definition.kwonlyargs
if not is_arg and not is_kwonly:
# Maybe this argument goes into **kwargs,
# or it is an extraneous argument.
# In any case, the signature is different than
# the call site, which stops our search.
no_additional_kwarg_arguments = False
break
return all(
(
same_args,
same_kwonlyargs,
same_args_variadics,
same_kw_variadics,
no_additional_kwarg_arguments,
)
)
# Deal with parameters overridding in two methods.
def _positional_parameters(method):
positional = method.args.args
if method.type in ("classmethod", "method"):
positional = positional[1:]
return positional
def _get_node_type(node, potential_types):
"""
Return the type of the node if it exists in potential_types.
Args:
node (astroid.node): node to get the type of.
potential_types (tuple): potential types of the node.
Returns:
type: type of the node or None.
"""
for potential_type in potential_types:
if isinstance(node, potential_type):
return potential_type
return None
def _check_arg_equality(node_a, node_b, attr_name):
"""
Check equality of nodes based on the comparison of their attributes named attr_name.
Args:
node_a (astroid.node): first node to compare.
node_b (astroid.node): second node to compare.
attr_name (str): name of the nodes attribute to use for comparison.
Returns:
bool: True if node_a.attr_name == node_b.attr_name, False otherwise.
"""
return getattr(node_a, attr_name) == getattr(node_b, attr_name)
def _has_different_parameters_default_value(original, overridden):
"""
Check if original and overridden methods arguments have different default values
Return True if one of the overridden arguments has a default
value different from the default value of the original argument
If one of the method doesn't have argument (.args is None)
return False
"""
if original.args is None or overridden.args is None:
return False
all_args = chain(original.args, original.kwonlyargs)
original_param_names = [param.name for param in all_args]
default_missing = object()
for param_name in original_param_names:
try:
original_default = original.default_value(param_name)
except astroid.exceptions.NoDefault:
original_default = default_missing
try:
overridden_default = overridden.default_value(param_name)
except astroid.exceptions.NoDefault:
overridden_default = default_missing
default_list = [
arg == default_missing for arg in (original_default, overridden_default)
]
if any(default_list) and not all(default_list):
# Only one arg has no default value
return True
astroid_type_compared_attr = {
astroid.Const: "value",
astroid.ClassDef: "name",
astroid.Tuple: "elts",
astroid.List: "elts",
}
handled_types = tuple(
astroid_type for astroid_type in astroid_type_compared_attr
)
original_type = _get_node_type(original_default, handled_types)
if original_type:
#  We handle only astroid types that are inside the dict astroid_type_compared_attr
if not isinstance(overridden_default, original_type):
#  Two args with same name but different types
return True
if not _check_arg_equality(
original_default,
overridden_default,
astroid_type_compared_attr[original_type],
):
# Two args with same type but different values
return True
return False
def _has_different_parameters(original, overridden, dummy_parameter_regex):
zipped = zip_longest(original, overridden)
for original_param, overridden_param in zipped:
params = (original_param, overridden_param)
if not all(params):
return True
names = [param.name for param in params]
if any(map(dummy_parameter_regex.match, names)):
continue
if original_param.name != overridden_param.name:
return True
return False
def _different_parameters(original, overridden, dummy_parameter_regex):
"""Determine if the two methods have different parameters
They are considered to have different parameters if:
* they have different positional parameters, including different names
* one of the methods is having variadics, while the other is not
* they have different keyword only parameters.
"""
original_parameters = _positional_parameters(original)
overridden_parameters = _positional_parameters(overridden)
# Copy kwonlyargs list so that we don't affect later function linting
original_kwonlyargs = original.args.kwonlyargs
# Allow positional/keyword variadic in overridden to match against any
# positional/keyword argument in original.
# Keep any arguments that are found seperately in overridden to satisfy
# later tests
if overridden.args.vararg:
overidden_names = [v.name for v in overridden_parameters]
original_parameters = [
v for v in original_parameters if v.name in overidden_names
]
if overridden.args.kwarg:
overidden_names = [v.name for v in overridden.args.kwonlyargs]
original_kwonlyargs = [
v for v in original.args.kwonlyargs if v.name in overidden_names
]
different_positional = _has_different_parameters(
original_parameters, overridden_parameters, dummy_parameter_regex
)
different_kwonly = _has_different_parameters(
original_kwonlyargs, overridden.args.kwonlyargs, dummy_parameter_regex
)
if original.name in PYMETHODS:
# Ignore the difference for special methods. If the parameter
# numbers are different, then that is going to be caught by
# unexpected-special-method-signature.
# If the names are different, it doesn't matter, since they can't
# be used as keyword arguments anyway.
different_positional = different_kwonly = False
# Arguments will only violate LSP if there are variadics in the original
# that are then removed from the overridden
kwarg_lost = original.args.kwarg and not overridden.args.kwarg
vararg_lost = original.args.vararg and not overridden.args.vararg
return any((different_positional, kwarg_lost, vararg_lost, different_kwonly))
def _is_invalid_base_class(cls):
return cls.name in INVALID_BASE_CLASSES and is_builtin_object(cls)
def _has_data_descriptor(cls, attr):
attributes = cls.getattr(attr)
for attribute in attributes:
try:
for inferred in attribute.infer():
if isinstance(inferred, astroid.Instance):
try:
inferred.getattr("__get__")
inferred.getattr("__set__")
except astroid.NotFoundError:
continue
else:
return True
except astroid.InferenceError:
# Can't infer, avoid emitting a false positive in this case.
return True
return False
def _called_in_methods(func, klass, methods):
""" Check if the func was called in any of the given methods,
belonging to the *klass*. Returns True if so, False otherwise.
"""
if not isinstance(func, astroid.FunctionDef):
return False
for method in methods:
try:
inferred = klass.getattr(method)
except astroid.NotFoundError:
continue
for infer_method in inferred:
for call in infer_method.nodes_of_class(astroid.Call):
try:
bound = next(call.func.infer())
except (astroid.InferenceError, StopIteration):
continue
if not isinstance(bound, astroid.BoundMethod):
continue
func_obj = bound._proxied
if isinstance(func_obj, astroid.UnboundMethod):
func_obj = func_obj._proxied
if func_obj.name == func.name:
return True
return False
def _is_attribute_property(name, klass):
"""Check if the given attribute *name* is a property in the given *klass*.
It will look for `property` calls or for functions
with the given name, decorated by `property` or `property`
subclasses.
Returns ``True`` if the name is a property in the given klass,
``False`` otherwise.
"""
try:
attributes = klass.getattr(name)
except astroid.NotFoundError:
return False
property_name = "{}.property".format(BUILTINS)
for attr in attributes:
if attr is astroid.Uninferable:
continue
try:
inferred = next(attr.infer())
except astroid.InferenceError:
continue
if isinstance(inferred, astroid.FunctionDef) and decorated_with_property(
inferred
):
return True
if inferred.pytype() != property_name:
continue
cls = node_frame_class(inferred)
if cls == klass.declared_metaclass():
continue
return True
return False
def _has_bare_super_call(fundef_node):
for call in fundef_node.nodes_of_class(astroid.Call):
func = call.func
if isinstance(func, astroid.Name) and func.name == "super" and not call.args:
return True
return False
def _safe_infer_call_result(node, caller, context=None):
"""
Safely infer the return value of a function.
Returns None if inference failed or if there is some ambiguity (more than
one node has been inferred). Otherwise returns inferred value.
"""
try:
inferit = node.infer_call_result(caller, context=context)
value = next(inferit)
except astroid.InferenceError:
return None # inference failed
except StopIteration:
return None # no values inferred
try:
next(inferit)
return None # there is ambiguity on the inferred node
except astroid.InferenceError:
return None # there is some kind of ambiguity
except StopIteration:
return value
def _has_same_layout_slots(slots, assigned_value):
inferred = next(assigned_value.infer())
if isinstance(inferred, astroid.ClassDef):
other_slots = inferred.slots()
if all(
first_slot and second_slot and first_slot.value == second_slot.value
for (first_slot, second_slot) in zip_longest(slots, other_slots)
):
return True
return False
MSGS = {
"F0202": (
"Unable to check methods signature (%s / %s)",
"method-check-failed",
"Used when Pylint has been unable to check methods signature "
"compatibility for an unexpected reason. Please report this kind "
"if you don't make sense of it.",
),
"E0202": (
"An attribute defined in %s line %s hides this method",
"method-hidden",
"Used when a class defines a method which is hidden by an "
"instance attribute from an ancestor class or set by some "
"client code.",
),
"E0203": (
"Access to member %r before its definition line %s",
"access-member-before-definition",
"Used when an instance member is accessed before it's actually assigned.",
),
"W0201": (
"Attribute %r defined outside __init__",
"attribute-defined-outside-init",
"Used when an instance attribute is defined outside the __init__ method.",
),
"W0212": (
"Access to a protected member %s of a client class", # E0214
"protected-access",
"Used when a protected member (i.e. class member with a name "
"beginning with an underscore) is access outside the class or a "
"descendant of the class where it's defined.",
),
"E0211": (
"Method has no argument",
"no-method-argument",
"Used when a method which should have the bound instance as "
"first argument has no argument defined.",
),
"E0213": (
'Method should have "self" as first argument',
"no-self-argument",
'Used when a method has an attribute different the "self" as '
"first argument. This is considered as an error since this is "
"a so common convention that you shouldn't break it!",
),
"C0202": (
"Class method %s should have %s as first argument",
"bad-classmethod-argument",
"Used when a class method has a first argument named differently "
"than the value specified in valid-classmethod-first-arg option "
'(default to "cls"), recommended to easily differentiate them '
"from regular instance methods.",
),
"C0203": (
"Metaclass method %s should have %s as first argument",
"bad-mcs-method-argument",
"Used when a metaclass method has a first argument named "
"differently than the value specified in valid-classmethod-first"
'-arg option (default to "cls"), recommended to easily '
"differentiate them from regular instance methods.",
),
"C0204": (
"Metaclass class method %s should have %s as first argument",
"bad-mcs-classmethod-argument",
"Used when a metaclass class method has a first argument named "
"differently than the value specified in valid-metaclass-"
'classmethod-first-arg option (default to "mcs"), recommended to '
"easily differentiate them from regular instance methods.",
),
"W0211": (
"Static method with %r as first argument",
"bad-staticmethod-argument",
'Used when a static method has "self" or a value specified in '
"valid-classmethod-first-arg option or "
"valid-metaclass-classmethod-first-arg option as first argument.",
),
"R0201": (
"Method could be a function",
"no-self-use",
"Used when a method doesn't use its bound instance, and so could "
"be written as a function.",
),
"W0221": (
"Parameters differ from %s %r method",
"arguments-differ",
"Used when a method has a different number of arguments than in "
"the implemented interface or in an overridden method.",
),
"W0222": (
"Signature differs from %s %r method",
"signature-differs",
"Used when a method signature is different than in the "
"implemented interface or in an overridden method.",
),
"W0223": (
"Method %r is abstract in class %r but is not overridden",
"abstract-method",
"Used when an abstract method (i.e. raise NotImplementedError) is "
"not overridden in concrete class.",
),
"W0231": (
"__init__ method from base class %r is not called",
"super-init-not-called",
"Used when an ancestor class method has an __init__ method "
"which is not called by a derived class.",
),
"W0232": (
"Class has no __init__ method",
"no-init",
"Used when a class has no __init__ method, neither its parent classes.",
),
"W0233": (
"__init__ method from a non direct base class %r is called",
"non-parent-init-called",
"Used when an __init__ method is called on a class which is not "
"in the direct ancestors for the analysed class.",
),
"W0235": (
"Useless super delegation in method %r",
"useless-super-delegation",
"Used whenever we can detect that an overridden method is useless, "
"relying on super() delegation to do the same thing as another method "
"from the MRO.",
),
"W0236": (
"Method %r was expected to be %r, found it instead as %r",
"invalid-overridden-method",
"Used when we detect that a method was overridden in a way "
"that does not match its base class "
"which could result in potential bugs at runtime.",
),
"E0236": (
"Invalid object %r in __slots__, must contain only non empty strings",
"invalid-slots-object",
"Used when an invalid (non-string) object occurs in __slots__.",
),
"E0237": (
"Assigning to attribute %r not defined in class slots",
"assigning-non-slot",
"Used when assigning to an attribute not defined in the class slots.",
),
"E0238": (
"Invalid __slots__ object",
"invalid-slots",
"Used when an invalid __slots__ is found in class. "
"Only a string, an iterable or a sequence is permitted.",
),
"E0239": (
"Inheriting %r, which is not a class.",
"inherit-non-class",
"Used when a class inherits from something which is not a class.",
),
"E0240": (
"Inconsistent method resolution order for class %r",
"inconsistent-mro",
"Used when a class has an inconsistent method resolution order.",
),
"E0241": (
"Duplicate bases for class %r",
"duplicate-bases",
"Used when a class has duplicate bases.",
),
"E0242": (
"Value %r in slots conflicts with class variable",
"class-variable-slots-conflict",
"Used when a value in __slots__ conflicts with a class variable, property or method.",
),
"R0202": (
"Consider using a decorator instead of calling classmethod",
"no-classmethod-decorator",
"Used when a class method is defined without using the decorator syntax.",
),
"R0203": (
"Consider using a decorator instead of calling staticmethod",
"no-staticmethod-decorator",
"Used when a static method is defined without using the decorator syntax.",
),
"C0205": (
"Class __slots__ should be a non-string iterable",
"single-string-used-for-slots",
"Used when a class __slots__ is a simple string, rather than an iterable.",
),
"R0205": (
"Class %r inherits from object, can be safely removed from bases in python3",
"useless-object-inheritance",
"Used when a class inherit from object, which under python3 is implicit, "
"hence can be safely removed from bases.",
),
"R0206": (
"Cannot have defined parameters for properties",
"property-with-parameters",
"Used when we detect that a property also has parameters, which are useless, "
"given that properties cannot be called with additional arguments.",
),
}
def _scope_default():
return collections.defaultdict(list)
class ScopeAccessMap:
"""Store the accessed variables per scope."""
def __init__(self):
self._scopes = collections.defaultdict(_scope_default)
def set_accessed(self, node):
"""Set the given node as accessed."""
frame = node_frame_class(node)
if frame is None:
# The node does not live in a class.
return
self._scopes[frame][node.attrname].append(node)
def accessed(self, scope):
"""Get the accessed variables for the given scope."""
return self._scopes.get(scope, {})
class ClassChecker(BaseChecker):
"""checks for :
* methods without self as first argument
* overridden methods signature
* access only to existent members via self
* attributes not defined in the __init__ method
* unreachable code
"""
__implements__ = (IAstroidChecker,)
# configuration section name
name = "classes"
# messages
msgs = MSGS
priority = -2
# configuration options
options = (
(
"defining-attr-methods",
{
"default": ("__init__", "__new__", "setUp", "__post_init__"),
"type": "csv",
"metavar": "<method names>",
"help": "List of method names used to declare (i.e. assign) \
instance attributes.",
},
),
(
"valid-classmethod-first-arg",
{
"default": ("cls",),
"type": "csv",
"metavar": "<argument names>",
"help": "List of valid names for the first argument in \
a class method.",
},
),
(
"valid-metaclass-classmethod-first-arg",
{
"default": ("cls",),
"type": "csv",
"metavar": "<argument names>",
"help": "List of valid names for the first argument in \
a metaclass class method.",
},
),
(
"exclude-protected",
{
"default": (
# namedtuple public API.
"_asdict",
"_fields",
"_replace",
"_source",
"_make",
),
"type": "csv",
"metavar": "<protected access exclusions>",
"help": (
"List of member names, which should be excluded "
"from the protected access warning."
),
},
),
)
def __init__(self, linter=None):
BaseChecker.__init__(self, linter)
self._accessed = ScopeAccessMap()
self._first_attrs = []
self._meth_could_be_func = None
@decorators.cachedproperty
def _dummy_rgx(self):
return get_global_option(self, "dummy-variables-rgx", default=None)
@decorators.cachedproperty
def _ignore_mixin(self):
return get_global_option(self, "ignore-mixin-members", default=True)
@check_messages(
"abstract-method",
"no-init",
"invalid-slots",
"single-string-used-for-slots",
"invalid-slots-object",
"class-variable-slots-conflict",
"inherit-non-class",
"useless-object-inheritance",
"inconsistent-mro",
"duplicate-bases",
)
def visit_classdef(self, node):
"""init visit variable _accessed
"""
self._check_bases_classes(node)
# if not an exception or a metaclass
if node.type == "class" and has_known_bases(node):
try:
node.local_attr("__init__")
except astroid.NotFoundError:
self.add_message("no-init", args=node, node=node)
self._check_slots(node)
self._check_proper_bases(node)
self._check_consistent_mro(node)
def _check_consistent_mro(self, node):
"""Detect that a class has a consistent mro or duplicate bases."""
try:
node.mro()
except InconsistentMroError:
self.add_message("inconsistent-mro", args=node.name, node=node)
except DuplicateBasesError:
self.add_message("duplicate-bases", args=node.name, node=node)
except NotImplementedError:
# Old style class, there's no mro so don't do anything.
pass
def _check_proper_bases(self, node):
"""
Detect that a class inherits something which is not
a class or a type.
"""
for base in node.bases:
ancestor = safe_infer(base)
if not ancestor:
continue
if isinstance(ancestor, astroid.Instance) and ancestor.is_subtype_of(
"%s.type" % (BUILTINS,)
):
continue
if not isinstance(ancestor, astroid.ClassDef) or _is_invalid_base_class(
ancestor
):
self.add_message("inherit-non-class", args=base.as_string(), node=node)
if ancestor.name == object.__name__:
self.add_message(
"useless-object-inheritance", args=node.name, node=node
)
def leave_classdef(self, cnode):
"""close a class node:
check that instance attributes are defined in __init__ and check
access to existent members
"""
# check access to existent members on non metaclass classes
if self._ignore_mixin and cnode.name[-5:].lower() == "mixin":
# We are in a mixin class. No need to try to figure out if
# something is missing, since it is most likely that it will
# miss.
return
accessed = self._accessed.accessed(cnode)
if cnode.type != "metaclass":
self._check_accessed_members(cnode, accessed)
# checks attributes are defined in an allowed method such as __init__
if not self.linter.is_message_enabled("attribute-defined-outside-init"):
return
defining_methods = self.config.defining_attr_methods
current_module = cnode.root()
for attr, nodes in cnode.instance_attrs.items():
# Exclude `__dict__` as it is already defined.
if attr == "__dict__":
continue
# Skip nodes which are not in the current module and it may screw up
# the output, while it's not worth it
nodes = [
n
for n in nodes
if not isinstance(n.statement(), (astroid.Delete, astroid.AugAssign))
and n.root() is current_module
]
if not nodes:
continue # error detected by typechecking
# Check if any method attr is defined in is a defining method
# or if we have the attribute defined in a setter.
frames = (node.frame() for node in nodes)
if any(
frame.name in defining_methods or is_property_setter(frame)
for frame in frames
):
continue
# check attribute is defined in a parent's __init__
for parent in cnode.instance_attr_ancestors(attr):
attr_defined = False
# check if any parent method attr is defined in is a defining method
for node in parent.instance_attrs[attr]:
if node.frame().name in defining_methods:
attr_defined = True
if attr_defined:
# we're done :)
break
else:
# check attribute is defined as a class attribute
try:
cnode.local_attr(attr)
except astroid.NotFoundError:
for node in nodes:
if node.frame().name not in defining_methods:
# If the attribute was set by a call in any
# of the defining methods, then don't emit
# the warning.
if _called_in_methods(
node.frame(), cnode, defining_methods
):
continue
self.add_message(
"attribute-defined-outside-init", args=attr, node=node
)
def visit_functiondef(self, node):
"""check method arguments, overriding"""
# ignore actual functions
if not node.is_method():
return
self._check_useless_super_delegation(node)
self._check_property_with_parameters(node)
klass = node.parent.frame()
self._meth_could_be_func = True
# check first argument is self if this is actually a method
self._check_first_arg_for_type(node, klass.type == "metaclass")
if node.name == "__init__":
self._check_init(node)
return
# check signature if the method overloads inherited method
for overridden in klass.local_attr_ancestors(node.name):
# get astroid for the searched method
try:
parent_function = overridden[node.name]
except KeyError:
# we have found the method but it's not in the local
# dictionary.
# This may happen with astroid build from living objects
continue
if not isinstance(parent_function, astroid.FunctionDef):
continue
self._check_signature(node, parent_function, "overridden", klass)
self._check_invalid_overridden_method(node, parent_function)
break
if node.decorators:
for decorator in node.decorators.nodes:
if isinstance(decorator, astroid.Attribute) and decorator.attrname in (
"getter",
"setter",
"deleter",
):
# attribute affectation will call this method, not hiding it
return
if isinstance(decorator, astroid.Name):
if decorator.name == "property":
# attribute affectation will either call a setter or raise
# an attribute error, anyway not hiding the function
return
# Infer the decorator and see if it returns something useful
inferred = safe_infer(decorator)
if not inferred:
return
if isinstance(inferred, astroid.FunctionDef):
# Okay, it's a decorator, let's see what it can infer.
try:
inferred = next(inferred.infer_call_result(inferred))
except astroid.InferenceError:
return
try:
if (
isinstance(inferred, (astroid.Instance, astroid.ClassDef))
and inferred.getattr("__get__")
and inferred.getattr("__set__")
):
return
except astroid.AttributeInferenceError:
pass
# check if the method is hidden by an attribute
try:
overridden = klass.instance_attr(node.name)[0]
overridden_frame = overridden.frame()
if (
isinstance(overridden_frame, astroid.FunctionDef)
and overridden_frame.type == "method"
):
overridden_frame = overridden_frame.parent.frame()
if not (
isinstance(overridden_frame, astroid.ClassDef)
and klass.is_subtype_of(overridden_frame.qname())
):
return
# If a subclass defined the method then it's not our fault.
for ancestor in klass.ancestors():
for obj in ancestor.lookup(node.name)[1]:
if isinstance(obj, astroid.FunctionDef):
return
args = (overridden.root().name, overridden.fromlineno)
self.add_message("method-hidden", args=args, node=node)
except astroid.NotFoundError:
pass
visit_asyncfunctiondef = visit_functiondef
def _check_useless_super_delegation(self, function):
"""Check if the given function node is an useless method override
We consider it *useless* if it uses the super() builtin, but having
nothing additional whatsoever than not implementing the method at all.
If the method uses super() to delegate an operation to the rest of the MRO,
and if the method called is the same as the current one, the arguments
passed to super() are the same as the parameters that were passed to
this method, then the method could be removed altogether, by letting
other implementation to take precedence.
"""
if (
not function.is_method()
# With decorators is a change of use
or function.decorators
):
return
body = function.body
if len(body) != 1:
# Multiple statements, which means this overridden method
# could do multiple things we are not aware of.
return
statement = body[0]
if not isinstance(statement, (astroid.Expr, astroid.Return)):
# Doing something else than what we are interested into.
return
call = statement.value
if (
not isinstance(call, astroid.Call)
# Not a super() attribute access.
or not isinstance(call.func, astroid.Attribute)
):
return
# Should be a super call.
try:
super_call = next(call.func.expr.infer())
except astroid.InferenceError:
return
else:
if not isinstance(super_call, objects.Super):
return
# The name should be the same.
if call.func.attrname != function.name:
return
# Should be a super call with the MRO pointer being the
# current class and the type being the current instance.
current_scope = function.parent.scope()
if (
super_call.mro_pointer != current_scope
or not isinstance(super_call.type, astroid.Instance)
or super_call.type.name != current_scope.name
):
return
#  Check values of default args
klass = function.parent.frame()
meth_node = None
for overridden in klass.local_attr_ancestors(function.name):
# get astroid for the searched method
try:
meth_node = overridden[function.name]
except KeyError:
# we have found the method but it's not in the local
# dictionary.
# This may happen with astroid build from living objects
continue
if (
not isinstance(meth_node, astroid.FunctionDef)
# If the method have an ancestor which is not a
# function then it is legitimate to redefine it
or _has_different_parameters_default_value(
meth_node.args, function.args
)
):
return
break
# Detect if the parameters are the same as the call's arguments.
params = _signature_from_arguments(function.args)
args = _signature_from_call(call)
if meth_node is not None:
def form_annotations(arguments):
annotations = chain(
(arguments.posonlyargs_annotations or []), arguments.annotations
)
return [
annotation.as_string() for annotation in filter(None, annotations)
]
called_annotations = form_annotations(function.args)
overridden_annotations = form_annotations(meth_node.args)
if called_annotations and overridden_annotations:
if called_annotations != overridden_annotations:
return
if _definition_equivalent_to_call(params, args):
self.add_message(
"useless-super-delegation", node=function, args=(function.name,)
)
def _check_property_with_parameters(self, node):
if (
node.args.args
and len(node.args.args) > 1
and decorated_with_property(node)
and not is_property_setter(node)
):
self.add_message("property-with-parameters", node=node)
def _check_invalid_overridden_method(self, function_node, parent_function_node):
parent_is_property = decorated_with_property(
parent_function_node
) or is_property_setter_or_deleter(parent_function_node)
current_is_property = decorated_with_property(
function_node
) or is_property_setter_or_deleter(function_node)
if parent_is_property and not current_is_property:
self.add_message(
"invalid-overridden-method",
args=(function_node.name, "property", function_node.type),
node=function_node,
)
elif not parent_is_property and current_is_property:
self.add_message(
"invalid-overridden-method",
args=(function_node.name, "method", "property"),
node=function_node,
)
parent_is_async = isinstance(parent_function_node, astroid.AsyncFunctionDef)
current_is_async = isinstance(function_node, astroid.AsyncFunctionDef)
if parent_is_async and not current_is_async:
self.add_message(
"invalid-overridden-method",
args=(function_node.name, "async", "non-async"),
node=function_node,
)
elif not parent_is_async and current_is_async:
self.add_message(
"invalid-overridden-method",
args=(function_node.name, "non-async", "async"),
node=function_node,
)
def _check_slots(self, node):
if "__slots__" not in node.locals:
return
for slots in node.igetattr("__slots__"):
# check if __slots__ is a valid type
if slots is astroid.Uninferable:
continue
if not is_iterable(slots) and not is_comprehension(slots):
self.add_message("invalid-slots", node=node)
continue
if isinstance(slots, astroid.Const):
# a string, ignore the following checks
self.add_message("single-string-used-for-slots", node=node)
continue
if not hasattr(slots, "itered"):
# we can't obtain the values, maybe a .deque?
continue
if isinstance(slots, astroid.Dict):
values = [item[0] for item in slots.items]
else:
values = slots.itered()
if values is astroid.Uninferable:
return
for elt in values:
try:
self._check_slots_elt(elt, node)
except astroid.InferenceError:
continue
def _check_slots_elt(self, elt, node):
for inferred in elt.infer():
if inferred is astroid.Uninferable:
continue
if not isinstance(inferred, astroid.Const) or not isinstance(
inferred.value, str
):
self.add_message(
"invalid-slots-object", args=inferred.as_string(), node=elt
)
continue
if not inferred.value:
self.add_message(
"invalid-slots-object", args=inferred.as_string(), node=elt
)
# Check if we have a conflict with a class variable.
class_variable = node.locals.get(inferred.value)
if class_variable:
# Skip annotated assignments which don't conflict at all with slots.
if len(class_variable) == 1:
parent = class_variable[0].parent
if isinstance(parent, astroid.AnnAssign) and parent.value is None:
return
self.add_message(
"class-variable-slots-conflict", args=(inferred.value,), node=elt
)
def leave_functiondef(self, node):
"""on method node, check if this method couldn't be a function
ignore class, static and abstract methods, initializer,
methods overridden from a parent class.
"""
if node.is_method():
if node.args.args is not None:
self._first_attrs.pop()
if not self.linter.is_message_enabled("no-self-use"):
return
class_node = node.parent.frame()
if (
self._meth_could_be_func
and node.type == "method"
and node.name not in PYMETHODS
and not (
node.is_abstract()
or overrides_a_method(class_node, node.name)
or decorated_with_property(node)
or _has_bare_super_call(node)
or is_protocol_class(class_node)
or is_overload_stub(node)
)
):
self.add_message("no-self-use", node=node)
def visit_attribute(self, node):
"""check if the getattr is an access to a class member
if so, register it. Also check for access to protected
class member from outside its class (but ignore __special__
methods)
"""
# Check self
if self._uses_mandatory_method_param(node):
self._accessed.set_accessed(node)
return
if not self.linter.is_message_enabled("protected-access"):
return
self._check_protected_attribute_access(node)
def visit_assignattr(self, node):
if isinstance(
node.assign_type(), astroid.AugAssign
) and self._uses_mandatory_method_param(node):
self._accessed.set_accessed(node)
self._check_in_slots(node)
def _check_in_slots(self, node):
""" Check that the given AssignAttr node
is defined in the class slots.
"""
inferred = safe_infer(node.expr)
if not isinstance(inferred, astroid.Instance):
return
klass = inferred._proxied
if not has_known_bases(klass):
return
if "__slots__" not in klass.locals or not klass.newstyle:
return
slots = klass.slots()
if slots is None:
return
# If any ancestor doesn't use slots, the slots
# defined for this class are superfluous.
if any(
"__slots__" not in ancestor.locals and ancestor.name != "object"
for ancestor in klass.ancestors()
):
return
if not any(slot.value == node.attrname for slot in slots):
# If we have a '__dict__' in slots, then
# assigning any name is valid.
if not any(slot.value == "__dict__" for slot in slots):
if _is_attribute_property(node.attrname, klass):
# Properties circumvent the slots mechanism,
# so we should not emit a warning for them.
return
if node.attrname in klass.locals and _has_data_descriptor(
klass, node.attrname
):
# Descriptors circumvent the slots mechanism as well.
return
if node.attrname == "__class__" and _has_same_layout_slots(
slots, node.parent.value
):
return
self.add_message("assigning-non-slot", args=(node.attrname,), node=node)
@check_messages(
"protected-access", "no-classmethod-decorator", "no-staticmethod-decorator"
)
def visit_assign(self, assign_node):
self._check_classmethod_declaration(assign_node)
node = assign_node.targets[0]
if not isinstance(node, astroid.AssignAttr):
return
if self._uses_mandatory_method_param(node):
return
self._check_protected_attribute_access(node)
def _check_classmethod_declaration(self, node):
"""Checks for uses of classmethod() or staticmethod()
When a @classmethod or @staticmethod decorator should be used instead.
A message will be emitted only if the assignment is at a class scope
and only if the classmethod's argument belongs to the class where it
is defined.
`node` is an assign node.
"""
if not isinstance(node.value, astroid.Call):
return
# check the function called is "classmethod" or "staticmethod"
func = node.value.func
if not isinstance(func, astroid.Name) or func.name not in (
"classmethod",
"staticmethod",
):
return
msg = (
"no-classmethod-decorator"
if func.name == "classmethod"
else "no-staticmethod-decorator"
)
# assignment must be at a class scope
parent_class = node.scope()
if not isinstance(parent_class, astroid.ClassDef):
return
# Check if the arg passed to classmethod is a class member
classmeth_arg = node.value.args[0]
if not isinstance(classmeth_arg, astroid.Name):
return
method_name = classmeth_arg.name
if any(method_name == member.name for member in parent_class.mymethods()):
self.add_message(msg, node=node.targets[0])
def _check_protected_attribute_access(self, node):
"""Given an attribute access node (set or get), check if attribute
access is legitimate. Call _check_first_attr with node before calling
this method. Valid cases are:
* self._attr in a method or cls._attr in a classmethod. Checked by
_check_first_attr.
* Klass._attr inside "Klass" class.
* Klass2._attr inside "Klass" class when Klass2 is a base class of
Klass.
"""
attrname = node.attrname
if (
is_attr_protected(attrname)
and attrname not in self.config.exclude_protected
):
klass = node_frame_class(node)
# In classes, check we are not getting a parent method
# through the class object or through super
callee = node.expr.as_string()
# We are not in a class, no remaining valid case
if klass is None:
self.add_message("protected-access", node=node, args=attrname)
return
# If the expression begins with a call to super, that's ok.
if (
isinstance(node.expr, astroid.Call)
and isinstance(node.expr.func, astroid.Name)
and node.expr.func.name == "super"
):
return
# If the expression begins with a call to type(self), that's ok.
if self._is_type_self_call(node.expr):
return
# We are in a class, one remaining valid cases, Klass._attr inside
# Klass
if not (callee == klass.name or callee in klass.basenames):
# Detect property assignments in the body of the class.
# This is acceptable:
#
# class A:
# b = property(lambda: self._b)
stmt = node.parent.statement()
if (
isinstance(stmt, astroid.Assign)
and len(stmt.targets) == 1
and isinstance(stmt.targets[0], astroid.AssignName)
):
name = stmt.targets[0].name
if _is_attribute_property(name, klass):
return
#  A licit use of protected member is inside a special method
if not attrname.startswith(
"__"
) and self._is_called_inside_special_method(node):
return
self.add_message("protected-access", node=node, args=attrname)
@staticmethod
def _is_called_inside_special_method(node: astroid.node_classes.NodeNG) -> bool:
"""
Returns true if the node is located inside a special (aka dunder) method
"""
try:
frame_name = node.frame().name
except AttributeError:
return False
return frame_name and frame_name in PYMETHODS
def _is_type_self_call(self, expr):
return (
isinstance(expr, astroid.Call)
and isinstance(expr.func, astroid.Name)
and expr.func.name == "type"
and len(expr.args) == 1
and self._is_mandatory_method_param(expr.args[0])
)
def visit_name(self, node):
"""check if the name handle an access to a class member
if so, register it
"""
if self._first_attrs and (
node.name == self._first_attrs[-1] or not self._first_attrs[-1]
):
self._meth_could_be_func = False
def _check_accessed_members(self, node, accessed):
"""check that accessed members are defined"""
excs = ("AttributeError", "Exception", "BaseException")
for attr, nodes in accessed.items():
try:
# is it a class attribute ?
node.local_attr(attr)
# yes, stop here
continue
except astroid.NotFoundError:
pass
# is it an instance attribute of a parent class ?
try:
next(node.instance_attr_ancestors(attr))
# yes, stop here
continue
except StopIteration:
pass
# is it an instance attribute ?
try:
defstmts = node.instance_attr(attr)
except astroid.NotFoundError:
pass
else:
# filter out augment assignment nodes
defstmts = [stmt for stmt in defstmts if stmt not in nodes]
if not defstmts:
# only augment assignment for this node, no-member should be
# triggered by the typecheck checker
continue
# filter defstmts to only pick the first one when there are
# several assignments in the same scope
scope = defstmts[0].scope()
defstmts = [
stmt
for i, stmt in enumerate(defstmts)
if i == 0 or stmt.scope() is not scope
]
# if there are still more than one, don't attempt to be smarter
# than we can be
if len(defstmts) == 1:
defstmt = defstmts[0]
# check that if the node is accessed in the same method as
# it's defined, it's accessed after the initial assignment
frame = defstmt.frame()
lno = defstmt.fromlineno
for _node in nodes:
if (
_node.frame() is frame
and _node.fromlineno < lno
and not astroid.are_exclusive(
_node.statement(), defstmt, excs
)
):
self.add_message(
"access-member-before-definition",
node=_node,
args=(attr, lno),
)
def _check_first_arg_for_type(self, node, metaclass=0):
"""check the name of first argument, expect:
* 'self' for a regular method
* 'cls' for a class method or a metaclass regular method (actually
valid-classmethod-first-arg value)
* 'mcs' for a metaclass class method (actually
valid-metaclass-classmethod-first-arg)
* not one of the above for a static method
"""
# don't care about functions with unknown argument (builtins)
if node.args.args is None:
return
if node.args.posonlyargs:
first_arg = node.args.posonlyargs[0].name
elif node.args.args:
first_arg = node.argnames()[0]
else:
first_arg = None
self._first_attrs.append(first_arg)
first = self._first_attrs[-1]
# static method
if node.type == "staticmethod":
if (
first_arg == "self"
or first_arg in self.config.valid_classmethod_first_arg
or first_arg in self.config.valid_metaclass_classmethod_first_arg
):
self.add_message("bad-staticmethod-argument", args=first, node=node)
return
self._first_attrs[-1] = None
# class / regular method with no args
elif not node.args.args and not node.args.posonlyargs:
self.add_message("no-method-argument", node=node)
# metaclass
elif metaclass:
# metaclass __new__ or classmethod
if node.type == "classmethod":
self._check_first_arg_config(
first,
self.config.valid_metaclass_classmethod_first_arg,
node,
"bad-mcs-classmethod-argument",
node.name,
)
# metaclass regular method
else:
self._check_first_arg_config(
first,
self.config.valid_classmethod_first_arg,
node,
"bad-mcs-method-argument",
node.name,
)
# regular class
else: # pylint: disable=else-if-used
# class method
if node.type == "classmethod" or node.name == "__class_getitem__":
self._check_first_arg_config(
first,
self.config.valid_classmethod_first_arg,
node,
"bad-classmethod-argument",
node.name,
)
# regular method without self as argument
elif first != "self":
self.add_message("no-self-argument", node=node)
def _check_first_arg_config(self, first, config, node, message, method_name):
if first not in config:
if len(config) == 1:
valid = repr(config[0])
else:
valid = ", ".join(repr(v) for v in config[:-1])
valid = "%s or %r" % (valid, config[-1])
self.add_message(message, args=(method_name, valid), node=node)
def _check_bases_classes(self, node):
"""check that the given class node implements abstract methods from
base classes
"""
def is_abstract(method):
return method.is_abstract(pass_is_abstract=False)
# check if this class abstract
if class_is_abstract(node):
return
methods = sorted(
unimplemented_abstract_methods(node, is_abstract).items(),
key=lambda item: item[0],
)
for name, method in methods:
owner = method.parent.frame()
if owner is node:
continue
# owner is not this class, it must be a parent class
# check that the ancestor's method is not abstract
if name in node.locals:
# it is redefined as an attribute or with a descriptor
continue
self.add_message("abstract-method", node=node, args=(name, owner.name))
def _check_init(self, node):
"""check that the __init__ method call super or ancestors'__init__
method (unless it is used for type hinting with `typing.overload`)
"""
if not self.linter.is_message_enabled(
"super-init-not-called"
) and not self.linter.is_message_enabled("non-parent-init-called"):
return
klass_node = node.parent.frame()
to_call = _ancestors_to_call(klass_node)
not_called_yet = dict(to_call)
for stmt in node.nodes_of_class(astroid.Call):
expr = stmt.func
if not isinstance(expr, astroid.Attribute) or expr.attrname != "__init__":
continue
# skip the test if using super
if (
isinstance(expr.expr, astroid.Call)
and isinstance(expr.expr.func, astroid.Name)
and expr.expr.func.name == "super"
):
return
try:
for klass in expr.expr.infer():
if klass is astroid.Uninferable:
continue
# The inferred klass can be super(), which was
# assigned to a variable and the `__init__`
# was called later.
#
# base = super()
# base.__init__(...)
if (
isinstance(klass, astroid.Instance)
and isinstance(klass._proxied, astroid.ClassDef)
and is_builtin_object(klass._proxied)
and klass._proxied.name == "super"
):
return
if isinstance(klass, objects.Super):
return
try:
del not_called_yet[klass]
except KeyError:
if klass not in to_call:
self.add_message(
"non-parent-init-called", node=expr, args=klass.name
)
except astroid.InferenceError:
continue
for klass, method in not_called_yet.items():
if decorated_with(node, ["typing.overload"]):
continue
cls = node_frame_class(method)
if klass.name == "object" or (cls and cls.name == "object"):
continue
self.add_message("super-init-not-called", args=klass.name, node=node)
def _check_signature(self, method1, refmethod, class_type, cls):
"""check that the signature of the two given methods match
"""
if not (
isinstance(method1, astroid.FunctionDef)
and isinstance(refmethod, astroid.FunctionDef)
):
self.add_message(
"method-check-failed", args=(method1, refmethod), node=method1
)
return
instance = cls.instantiate_class()
method1 = function_to_method(method1, instance)
refmethod = function_to_method(refmethod, instance)
# Don't care about functions with unknown argument (builtins).
if method1.args.args is None or refmethod.args.args is None:
return
# Ignore private to class methods.
if is_attr_private(method1.name):
return
# Ignore setters, they have an implicit extra argument,
# which shouldn't be taken in consideration.
if is_property_setter(method1):
return
if _different_parameters(
refmethod, method1, dummy_parameter_regex=self._dummy_rgx
):
self.add_message(
"arguments-differ", args=(class_type, method1.name), node=method1
)
elif len(method1.args.defaults) < len(refmethod.args.defaults):
self.add_message(
"signature-differs", args=(class_type, method1.name), node=method1
)
def _uses_mandatory_method_param(self, node):
"""Check that attribute lookup name use first attribute variable name
Name is `self` for method, `cls` for classmethod and `mcs` for metaclass.
"""
return self._is_mandatory_method_param(node.expr)
def _is_mandatory_method_param(self, node):
"""Check if astroid.Name corresponds to first attribute variable name
Name is `self` for method, `cls` for classmethod and `mcs` for metaclass.
"""
return (
self._first_attrs
and isinstance(node, astroid.Name)
and node.name == self._first_attrs[-1]
)
class SpecialMethodsChecker(BaseChecker):
"""Checker which verifies that special methods
are implemented correctly.
"""
__implements__ = (IAstroidChecker,)
name = "classes"
msgs = {
"E0301": (
"__iter__ returns non-iterator",
"non-iterator-returned",
"Used when an __iter__ method returns something which is not an "
"iterable (i.e. has no `%s` method)" % NEXT_METHOD,
{
"old_names": [
("W0234", "old-non-iterator-returned-1"),
("E0234", "old-non-iterator-returned-2"),
]
},
),
"E0302": (
"The special method %r expects %s param(s), %d %s given",
"unexpected-special-method-signature",
"Emitted when a special method was defined with an "
"invalid number of parameters. If it has too few or "
"too many, it might not work at all.",
{"old_names": [("E0235", "bad-context-manager")]},
),
"E0303": (
"__len__ does not return non-negative integer",
"invalid-length-returned",
"Used when a __len__ method returns something which is not a "
"non-negative integer",
),
"E0304": (
"__bool__ does not return bool",
"invalid-bool-returned",
"Used when a __bool__ method returns something which is not a bool",
),
"E0305": (
"__index__ does not return int",
"invalid-index-returned",
"Used when an __index__ method returns something which is not "
"an integer",
),
"E0306": (
"__repr__ does not return str",
"invalid-repr-returned",
"Used when a __repr__ method returns something which is not a string",
),
"E0307": (
"__str__ does not return str",
"invalid-str-returned",
"Used when a __str__ method returns something which is not a string",
),
"E0308": (
"__bytes__ does not return bytes",
"invalid-bytes-returned",
"Used when a __bytes__ method returns something which is not bytes",
),
"E0309": (
"__hash__ does not return int",
"invalid-hash-returned",
"Used when a __hash__ method returns something which is not an integer",
),
"E0310": (
"__length_hint__ does not return non-negative integer",
"invalid-length-hint-returned",
"Used when a __length_hint__ method returns something which is not a "
"non-negative integer",
),
"E0311": (
"__format__ does not return str",
"invalid-format-returned",
"Used when a __format__ method returns something which is not a string",
),
"E0312": (
"__getnewargs__ does not return a tuple",
"invalid-getnewargs-returned",
"Used when a __getnewargs__ method returns something which is not "
"a tuple",
),
"E0313": (
"__getnewargs_ex__ does not return a tuple containing (tuple, dict)",
"invalid-getnewargs-ex-returned",
"Used when a __getnewargs_ex__ method returns something which is not "
"of the form tuple(tuple, dict)",
),
}
priority = -2
def __init__(self, linter=None):
BaseChecker.__init__(self, linter)
self._protocol_map = {
"__iter__": self._check_iter,
"__len__": self._check_len,
"__bool__": self._check_bool,
"__index__": self._check_index,
"__repr__": self._check_repr,
"__str__": self._check_str,
"__bytes__": self._check_bytes,
"__hash__": self._check_hash,
"__length_hint__": self._check_length_hint,
"__format__": self._check_format,
"__getnewargs__": self._check_getnewargs,
"__getnewargs_ex__": self._check_getnewargs_ex,
}
@check_messages(
"unexpected-special-method-signature",
"non-iterator-returned",
"invalid-length-returned",
"invalid-bool-returned",
"invalid-index-returned",
"invalid-repr-returned",
"invalid-str-returned",
"invalid-bytes-returned",
"invalid-hash-returned",
"invalid-length-hint-returned",
"invalid-format-returned",
"invalid-getnewargs-returned",
"invalid-getnewargs-ex-returned",
)
def visit_functiondef(self, node):
if not node.is_method():
return
inferred = _safe_infer_call_result(node, node)
# Only want to check types that we are able to infer
if inferred and node.name in self._protocol_map:
self._protocol_map[node.name](node, inferred)
if node.name in PYMETHODS:
self._check_unexpected_method_signature(node)
visit_asyncfunctiondef = visit_functiondef
def _check_unexpected_method_signature(self, node):
expected_params = SPECIAL_METHODS_PARAMS[node.name]
if expected_params is None:
# This can support a variable number of parameters.
return
if not node.args.args and not node.args.vararg:
# Method has no parameter, will be caught
# by no-method-argument.
return
if decorated_with(node, [BUILTINS + ".staticmethod"]):
# We expect to not take in consideration self.
all_args = node.args.args
else:
all_args = node.args.args[1:]
mandatory = len(all_args) - len(node.args.defaults)
optional = len(node.args.defaults)
current_params = mandatory + optional
if isinstance(expected_params, tuple):
# The expected number of parameters can be any value from this
# tuple, although the user should implement the method
# to take all of them in consideration.
emit = mandatory not in expected_params
expected_params = "between %d or %d" % expected_params
else:
# If the number of mandatory parameters doesn't
# suffice, the expected parameters for this
# function will be deduced from the optional
# parameters.
rest = expected_params - mandatory
if rest == 0:
emit = False
elif rest < 0:
emit = True
elif rest > 0:
emit = not ((optional - rest) >= 0 or node.args.vararg)
if emit:
verb = "was" if current_params <= 1 else "were"
self.add_message(
"unexpected-special-method-signature",
args=(node.name, expected_params, current_params, verb),
node=node,
)
@staticmethod
def _is_wrapped_type(node, type_):
return (
isinstance(node, astroid.Instance)
and node.name == type_
and not isinstance(node, astroid.Const)
)
@staticmethod
def _is_int(node):
if SpecialMethodsChecker._is_wrapped_type(node, "int"):
return True
return isinstance(node, astroid.Const) and isinstance(node.value, int)
@staticmethod
def _is_str(node):
if SpecialMethodsChecker._is_wrapped_type(node, "str"):
return True
return isinstance(node, astroid.Const) and isinstance(node.value, str)
@staticmethod
def _is_bool(node):
if SpecialMethodsChecker._is_wrapped_type(node, "bool"):
return True
return isinstance(node, astroid.Const) and isinstance(node.value, bool)
@staticmethod
def _is_bytes(node):
if SpecialMethodsChecker._is_wrapped_type(node, "bytes"):
return True
return isinstance(node, astroid.Const) and isinstance(node.value, bytes)
@staticmethod
def _is_tuple(node):
if SpecialMethodsChecker._is_wrapped_type(node, "tuple"):
return True
return isinstance(node, astroid.Const) and isinstance(node.value, tuple)
@staticmethod
def _is_dict(node):
if SpecialMethodsChecker._is_wrapped_type(node, "dict"):
return True
return isinstance(node, astroid.Const) and isinstance(node.value, dict)
@staticmethod
def _is_iterator(node):
if node is astroid.Uninferable:
# Just ignore Uninferable objects.
return True
if isinstance(node, Generator):
# Generators can be itered.
return True
if isinstance(node, astroid.Instance):
try:
node.local_attr(NEXT_METHOD)
return True
except astroid.NotFoundError:
pass
elif isinstance(node, astroid.ClassDef):
metaclass = node.metaclass()
if metaclass and isinstance(metaclass, astroid.ClassDef):
try:
metaclass.local_attr(NEXT_METHOD)
return True
except astroid.NotFoundError:
pass
return False
def _check_iter(self, node, inferred):
if not self._is_iterator(inferred):
self.add_message("non-iterator-returned", node=node)
def _check_len(self, node, inferred):
if not self._is_int(inferred):
self.add_message("invalid-length-returned", node=node)
elif isinstance(inferred, astroid.Const) and inferred.value < 0:
self.add_message("invalid-length-returned", node=node)
def _check_bool(self, node, inferred):
if not self._is_bool(inferred):
self.add_message("invalid-bool-returned", node=node)
def _check_index(self, node, inferred):
if not self._is_int(inferred):
self.add_message("invalid-index-returned", node=node)
def _check_repr(self, node, inferred):
if not self._is_str(inferred):
self.add_message("invalid-repr-returned", node=node)
def _check_str(self, node, inferred):
if not self._is_str(inferred):
self.add_message("invalid-str-returned", node=node)
def _check_bytes(self, node, inferred):
if not self._is_bytes(inferred):
self.add_message("invalid-bytes-returned", node=node)
def _check_hash(self, node, inferred):
if not self._is_int(inferred):
self.add_message("invalid-hash-returned", node=node)
def _check_length_hint(self, node, inferred):
if not self._is_int(inferred):
self.add_message("invalid-length-hint-returned", node=node)
elif isinstance(inferred, astroid.Const) and inferred.value < 0:
self.add_message("invalid-length-hint-returned", node=node)
def _check_format(self, node, inferred):
if not self._is_str(inferred):
self.add_message("invalid-format-returned", node=node)
def _check_getnewargs(self, node, inferred):
if not self._is_tuple(inferred):
self.add_message("invalid-getnewargs-returned", node=node)
def _check_getnewargs_ex(self, node, inferred):
if not self._is_tuple(inferred):
self.add_message("invalid-getnewargs-ex-returned", node=node)
return
if not isinstance(inferred, astroid.Tuple):
# If it's not an astroid.Tuple we can't analyze it further
return
found_error = False
if len(inferred.elts) != 2:
found_error = True
else:
for arg, check in [
(inferred.elts[0], self._is_tuple),
(inferred.elts[1], self._is_dict),
]:
if isinstance(arg, astroid.Call):
arg = safe_infer(arg)
if arg and arg is not astroid.Uninferable:
if not check(arg):
found_error = True
break
if found_error:
self.add_message("invalid-getnewargs-ex-returned", node=node)
def _ancestors_to_call(klass_node, method="__init__"):
"""return a dictionary where keys are the list of base classes providing
the queried method, and so that should/may be called from the method node
"""
to_call = {}
for base_node in klass_node.ancestors(recurs=False):
try:
to_call[base_node] = next(base_node.igetattr(method))
except astroid.InferenceError:
continue
return to_call
def register(linter):
"""required method to auto register this checker """
linter.register_checker(ClassChecker(linter))
linter.register_checker(SpecialMethodsChecker(linter))
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