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diff --git a/venv/Lib/site-packages/astroid/brain/brain_builtin_inference.py b/venv/Lib/site-packages/astroid/brain/brain_builtin_inference.py
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@@ -1,829 +0,0 @@
-# Copyright (c) 2014-2018 Claudiu Popa <pcmanticore@gmail.com>
-# Copyright (c) 2014-2015 LOGILAB S.A. (Paris, FRANCE) <contact@logilab.fr>
-# Copyright (c) 2015-2016 Ceridwen <ceridwenv@gmail.com>
-# Copyright (c) 2015 Rene Zhang <rz99@cornell.edu>
-# Copyright (c) 2018 Bryce Guinta <bryce.paul.guinta@gmail.com>
-
-# Licensed under the LGPL: https://www.gnu.org/licenses/old-licenses/lgpl-2.1.en.html
-# For details: https://github.com/PyCQA/astroid/blob/master/COPYING.LESSER
-
-"""Astroid hooks for various builtins."""
-
-from functools import partial
-from textwrap import dedent
-
-import six
-from astroid import (
- MANAGER,
- UseInferenceDefault,
- AttributeInferenceError,
- inference_tip,
- InferenceError,
- NameInferenceError,
- AstroidTypeError,
- MroError,
-)
-from astroid import arguments
-from astroid.builder import AstroidBuilder
-from astroid import helpers
-from astroid import nodes
-from astroid import objects
-from astroid import scoped_nodes
-from astroid import util
-
-
-OBJECT_DUNDER_NEW = "object.__new__"
-
-
-def _extend_str(class_node, rvalue):
- """function to extend builtin str/unicode class"""
- code = dedent(
- """
- class whatever(object):
- def join(self, iterable):
- return {rvalue}
- def replace(self, old, new, count=None):
- return {rvalue}
- def format(self, *args, **kwargs):
- return {rvalue}
- def encode(self, encoding='ascii', errors=None):
- return ''
- def decode(self, encoding='ascii', errors=None):
- return u''
- def capitalize(self):
- return {rvalue}
- def title(self):
- return {rvalue}
- def lower(self):
- return {rvalue}
- def upper(self):
- return {rvalue}
- def swapcase(self):
- return {rvalue}
- def index(self, sub, start=None, end=None):
- return 0
- def find(self, sub, start=None, end=None):
- return 0
- def count(self, sub, start=None, end=None):
- return 0
- def strip(self, chars=None):
- return {rvalue}
- def lstrip(self, chars=None):
- return {rvalue}
- def rstrip(self, chars=None):
- return {rvalue}
- def rjust(self, width, fillchar=None):
- return {rvalue}
- def center(self, width, fillchar=None):
- return {rvalue}
- def ljust(self, width, fillchar=None):
- return {rvalue}
- """
- )
- code = code.format(rvalue=rvalue)
- fake = AstroidBuilder(MANAGER).string_build(code)["whatever"]
- for method in fake.mymethods():
- method.parent = class_node
- method.lineno = None
- method.col_offset = None
- if "__class__" in method.locals:
- method.locals["__class__"] = [class_node]
- class_node.locals[method.name] = [method]
- method.parent = class_node
-
-
-def _extend_builtins(class_transforms):
- builtin_ast = MANAGER.builtins_module
- for class_name, transform in class_transforms.items():
- transform(builtin_ast[class_name])
-
-
-_extend_builtins(
- {
- "bytes": partial(_extend_str, rvalue="b''"),
- "str": partial(_extend_str, rvalue="''"),
- }
-)
-
-
-def _builtin_filter_predicate(node, builtin_name):
- if isinstance(node.func, nodes.Name) and node.func.name == builtin_name:
- return True
- if isinstance(node.func, nodes.Attribute):
- return (
- node.func.attrname == "fromkeys"
- and isinstance(node.func.expr, nodes.Name)
- and node.func.expr.name == "dict"
- )
- return False
-
-
-def register_builtin_transform(transform, builtin_name):
- """Register a new transform function for the given *builtin_name*.
-
- The transform function must accept two parameters, a node and
- an optional context.
- """
-
- def _transform_wrapper(node, context=None):
- result = transform(node, context=context)
- if result:
- if not result.parent:
- # Let the transformation function determine
- # the parent for its result. Otherwise,
- # we set it to be the node we transformed from.
- result.parent = node
-
- if result.lineno is None:
- result.lineno = node.lineno
- if result.col_offset is None:
- result.col_offset = node.col_offset
- return iter([result])
-
- MANAGER.register_transform(
- nodes.Call,
- inference_tip(_transform_wrapper),
- partial(_builtin_filter_predicate, builtin_name=builtin_name),
- )
-
-
-def _container_generic_inference(node, context, node_type, transform):
- args = node.args
- if not args:
- return node_type()
- if len(node.args) > 1:
- raise UseInferenceDefault()
-
- arg, = args
- transformed = transform(arg)
- if not transformed:
- try:
- inferred = next(arg.infer(context=context))
- except (InferenceError, StopIteration):
- raise UseInferenceDefault()
- if inferred is util.Uninferable:
- raise UseInferenceDefault()
- transformed = transform(inferred)
- if not transformed or transformed is util.Uninferable:
- raise UseInferenceDefault()
- return transformed
-
-
-def _container_generic_transform(arg, klass, iterables, build_elts):
- if isinstance(arg, klass):
- return arg
- elif isinstance(arg, iterables):
- if all(isinstance(elt, nodes.Const) for elt in arg.elts):
- elts = [elt.value for elt in arg.elts]
- else:
- # TODO: Does not handle deduplication for sets.
- elts = filter(None, map(helpers.safe_infer, arg.elts))
- elif isinstance(arg, nodes.Dict):
- # Dicts need to have consts as strings already.
- if not all(isinstance(elt[0], nodes.Const) for elt in arg.items):
- raise UseInferenceDefault()
- elts = [item[0].value for item in arg.items]
- elif isinstance(arg, nodes.Const) and isinstance(
- arg.value, (six.string_types, six.binary_type)
- ):
- elts = arg.value
- else:
- return
- return klass.from_elements(elts=build_elts(elts))
-
-
-def _infer_builtin_container(
- node, context, klass=None, iterables=None, build_elts=None
-):
- transform_func = partial(
- _container_generic_transform,
- klass=klass,
- iterables=iterables,
- build_elts=build_elts,
- )
-
- return _container_generic_inference(node, context, klass, transform_func)
-
-
-# pylint: disable=invalid-name
-infer_tuple = partial(
- _infer_builtin_container,
- klass=nodes.Tuple,
- iterables=(
- nodes.List,
- nodes.Set,
- objects.FrozenSet,
- objects.DictItems,
- objects.DictKeys,
- objects.DictValues,
- ),
- build_elts=tuple,
-)
-
-infer_list = partial(
- _infer_builtin_container,
- klass=nodes.List,
- iterables=(
- nodes.Tuple,
- nodes.Set,
- objects.FrozenSet,
- objects.DictItems,
- objects.DictKeys,
- objects.DictValues,
- ),
- build_elts=list,
-)
-
-infer_set = partial(
- _infer_builtin_container,
- klass=nodes.Set,
- iterables=(nodes.List, nodes.Tuple, objects.FrozenSet, objects.DictKeys),
- build_elts=set,
-)
-
-infer_frozenset = partial(
- _infer_builtin_container,
- klass=objects.FrozenSet,
- iterables=(nodes.List, nodes.Tuple, nodes.Set, objects.FrozenSet, objects.DictKeys),
- build_elts=frozenset,
-)
-
-
-def _get_elts(arg, context):
- is_iterable = lambda n: isinstance(n, (nodes.List, nodes.Tuple, nodes.Set))
- try:
- inferred = next(arg.infer(context))
- except (InferenceError, NameInferenceError):
- raise UseInferenceDefault()
- if isinstance(inferred, nodes.Dict):
- items = inferred.items
- elif is_iterable(inferred):
- items = []
- for elt in inferred.elts:
- # If an item is not a pair of two items,
- # then fallback to the default inference.
- # Also, take in consideration only hashable items,
- # tuples and consts. We are choosing Names as well.
- if not is_iterable(elt):
- raise UseInferenceDefault()
- if len(elt.elts) != 2:
- raise UseInferenceDefault()
- if not isinstance(elt.elts[0], (nodes.Tuple, nodes.Const, nodes.Name)):
- raise UseInferenceDefault()
- items.append(tuple(elt.elts))
- else:
- raise UseInferenceDefault()
- return items
-
-
-def infer_dict(node, context=None):
- """Try to infer a dict call to a Dict node.
-
- The function treats the following cases:
-
- * dict()
- * dict(mapping)
- * dict(iterable)
- * dict(iterable, **kwargs)
- * dict(mapping, **kwargs)
- * dict(**kwargs)
-
- If a case can't be inferred, we'll fallback to default inference.
- """
- call = arguments.CallSite.from_call(node)
- if call.has_invalid_arguments() or call.has_invalid_keywords():
- raise UseInferenceDefault
-
- args = call.positional_arguments
- kwargs = list(call.keyword_arguments.items())
-
- if not args and not kwargs:
- # dict()
- return nodes.Dict()
- elif kwargs and not args:
- # dict(a=1, b=2, c=4)
- items = [(nodes.Const(key), value) for key, value in kwargs]
- elif len(args) == 1 and kwargs:
- # dict(some_iterable, b=2, c=4)
- elts = _get_elts(args[0], context)
- keys = [(nodes.Const(key), value) for key, value in kwargs]
- items = elts + keys
- elif len(args) == 1:
- items = _get_elts(args[0], context)
- else:
- raise UseInferenceDefault()
-
- value = nodes.Dict(
- col_offset=node.col_offset, lineno=node.lineno, parent=node.parent
- )
- value.postinit(items)
- return value
-
-
-def infer_super(node, context=None):
- """Understand super calls.
-
- There are some restrictions for what can be understood:
-
- * unbounded super (one argument form) is not understood.
-
- * if the super call is not inside a function (classmethod or method),
- then the default inference will be used.
-
- * if the super arguments can't be inferred, the default inference
- will be used.
- """
- if len(node.args) == 1:
- # Ignore unbounded super.
- raise UseInferenceDefault
-
- scope = node.scope()
- if not isinstance(scope, nodes.FunctionDef):
- # Ignore non-method uses of super.
- raise UseInferenceDefault
- if scope.type not in ("classmethod", "method"):
- # Not interested in staticmethods.
- raise UseInferenceDefault
-
- cls = scoped_nodes.get_wrapping_class(scope)
- if not len(node.args):
- mro_pointer = cls
- # In we are in a classmethod, the interpreter will fill
- # automatically the class as the second argument, not an instance.
- if scope.type == "classmethod":
- mro_type = cls
- else:
- mro_type = cls.instantiate_class()
- else:
- try:
- mro_pointer = next(node.args[0].infer(context=context))
- except InferenceError:
- raise UseInferenceDefault
- try:
- mro_type = next(node.args[1].infer(context=context))
- except InferenceError:
- raise UseInferenceDefault
-
- if mro_pointer is util.Uninferable or mro_type is util.Uninferable:
- # No way we could understand this.
- raise UseInferenceDefault
-
- super_obj = objects.Super(
- mro_pointer=mro_pointer, mro_type=mro_type, self_class=cls, scope=scope
- )
- super_obj.parent = node
- return super_obj
-
-
-def _infer_getattr_args(node, context):
- if len(node.args) not in (2, 3):
- # Not a valid getattr call.
- raise UseInferenceDefault
-
- try:
- obj = next(node.args[0].infer(context=context))
- attr = next(node.args[1].infer(context=context))
- except InferenceError:
- raise UseInferenceDefault
-
- if obj is util.Uninferable or attr is util.Uninferable:
- # If one of the arguments is something we can't infer,
- # then also make the result of the getattr call something
- # which is unknown.
- return util.Uninferable, util.Uninferable
-
- is_string = isinstance(attr, nodes.Const) and isinstance(
- attr.value, six.string_types
- )
- if not is_string:
- raise UseInferenceDefault
-
- return obj, attr.value
-
-
-def infer_getattr(node, context=None):
- """Understand getattr calls
-
- If one of the arguments is an Uninferable object, then the
- result will be an Uninferable object. Otherwise, the normal attribute
- lookup will be done.
- """
- obj, attr = _infer_getattr_args(node, context)
- if (
- obj is util.Uninferable
- or attr is util.Uninferable
- or not hasattr(obj, "igetattr")
- ):
- return util.Uninferable
-
- try:
- return next(obj.igetattr(attr, context=context))
- except (StopIteration, InferenceError, AttributeInferenceError):
- if len(node.args) == 3:
- # Try to infer the default and return it instead.
- try:
- return next(node.args[2].infer(context=context))
- except InferenceError:
- raise UseInferenceDefault
-
- raise UseInferenceDefault
-
-
-def infer_hasattr(node, context=None):
- """Understand hasattr calls
-
- This always guarantees three possible outcomes for calling
- hasattr: Const(False) when we are sure that the object
- doesn't have the intended attribute, Const(True) when
- we know that the object has the attribute and Uninferable
- when we are unsure of the outcome of the function call.
- """
- try:
- obj, attr = _infer_getattr_args(node, context)
- if (
- obj is util.Uninferable
- or attr is util.Uninferable
- or not hasattr(obj, "getattr")
- ):
- return util.Uninferable
- obj.getattr(attr, context=context)
- except UseInferenceDefault:
- # Can't infer something from this function call.
- return util.Uninferable
- except AttributeInferenceError:
- # Doesn't have it.
- return nodes.Const(False)
- return nodes.Const(True)
-
-
-def infer_callable(node, context=None):
- """Understand callable calls
-
- This follows Python's semantics, where an object
- is callable if it provides an attribute __call__,
- even though that attribute is something which can't be
- called.
- """
- if len(node.args) != 1:
- # Invalid callable call.
- raise UseInferenceDefault
-
- argument = node.args[0]
- try:
- inferred = next(argument.infer(context=context))
- except InferenceError:
- return util.Uninferable
- if inferred is util.Uninferable:
- return util.Uninferable
- return nodes.Const(inferred.callable())
-
-
-def infer_bool(node, context=None):
- """Understand bool calls."""
- if len(node.args) > 1:
- # Invalid bool call.
- raise UseInferenceDefault
-
- if not node.args:
- return nodes.Const(False)
-
- argument = node.args[0]
- try:
- inferred = next(argument.infer(context=context))
- except InferenceError:
- return util.Uninferable
- if inferred is util.Uninferable:
- return util.Uninferable
-
- bool_value = inferred.bool_value()
- if bool_value is util.Uninferable:
- return util.Uninferable
- return nodes.Const(bool_value)
-
-
-def infer_type(node, context=None):
- """Understand the one-argument form of *type*."""
- if len(node.args) != 1:
- raise UseInferenceDefault
-
- return helpers.object_type(node.args[0], context)
-
-
-def infer_slice(node, context=None):
- """Understand `slice` calls."""
- args = node.args
- if not 0 < len(args) <= 3:
- raise UseInferenceDefault
-
- infer_func = partial(helpers.safe_infer, context=context)
- args = [infer_func(arg) for arg in args]
- for arg in args:
- if not arg or arg is util.Uninferable:
- raise UseInferenceDefault
- if not isinstance(arg, nodes.Const):
- raise UseInferenceDefault
- if not isinstance(arg.value, (type(None), int)):
- raise UseInferenceDefault
-
- if len(args) < 3:
- # Make sure we have 3 arguments.
- args.extend([None] * (3 - len(args)))
-
- slice_node = nodes.Slice(
- lineno=node.lineno, col_offset=node.col_offset, parent=node.parent
- )
- slice_node.postinit(*args)
- return slice_node
-
-
-def _infer_object__new__decorator(node, context=None):
- # Instantiate class immediately
- # since that's what @object.__new__ does
- return iter((node.instantiate_class(),))
-
-
-def _infer_object__new__decorator_check(node):
- """Predicate before inference_tip
-
- Check if the given ClassDef has an @object.__new__ decorator
- """
- if not node.decorators:
- return False
-
- for decorator in node.decorators.nodes:
- if isinstance(decorator, nodes.Attribute):
- if decorator.as_string() == OBJECT_DUNDER_NEW:
- return True
- return False
-
-
-def infer_issubclass(callnode, context=None):
- """Infer issubclass() calls
-
- :param nodes.Call callnode: an `issubclass` call
- :param InferenceContext: the context for the inference
- :rtype nodes.Const: Boolean Const value of the `issubclass` call
- :raises UseInferenceDefault: If the node cannot be inferred
- """
- call = arguments.CallSite.from_call(callnode)
- if call.keyword_arguments:
- # issubclass doesn't support keyword arguments
- raise UseInferenceDefault("TypeError: issubclass() takes no keyword arguments")
- if len(call.positional_arguments) != 2:
- raise UseInferenceDefault(
- "Expected two arguments, got {count}".format(
- count=len(call.positional_arguments)
- )
- )
- # The left hand argument is the obj to be checked
- obj_node, class_or_tuple_node = call.positional_arguments
-
- try:
- obj_type = next(obj_node.infer(context=context))
- except InferenceError as exc:
- raise UseInferenceDefault from exc
- if not isinstance(obj_type, nodes.ClassDef):
- raise UseInferenceDefault("TypeError: arg 1 must be class")
-
- # The right hand argument is the class(es) that the given
- # object is to be checked against.
- try:
- class_container = _class_or_tuple_to_container(
- class_or_tuple_node, context=context
- )
- except InferenceError as exc:
- raise UseInferenceDefault from exc
- try:
- issubclass_bool = helpers.object_issubclass(obj_type, class_container, context)
- except AstroidTypeError as exc:
- raise UseInferenceDefault("TypeError: " + str(exc)) from exc
- except MroError as exc:
- raise UseInferenceDefault from exc
- return nodes.Const(issubclass_bool)
-
-
-def infer_isinstance(callnode, context=None):
- """Infer isinstance calls
-
- :param nodes.Call callnode: an isinstance call
- :param InferenceContext: context for call
- (currently unused but is a common interface for inference)
- :rtype nodes.Const: Boolean Const value of isinstance call
-
- :raises UseInferenceDefault: If the node cannot be inferred
- """
- call = arguments.CallSite.from_call(callnode)
- if call.keyword_arguments:
- # isinstance doesn't support keyword arguments
- raise UseInferenceDefault("TypeError: isinstance() takes no keyword arguments")
- if len(call.positional_arguments) != 2:
- raise UseInferenceDefault(
- "Expected two arguments, got {count}".format(
- count=len(call.positional_arguments)
- )
- )
- # The left hand argument is the obj to be checked
- obj_node, class_or_tuple_node = call.positional_arguments
- # The right hand argument is the class(es) that the given
- # obj is to be check is an instance of
- try:
- class_container = _class_or_tuple_to_container(
- class_or_tuple_node, context=context
- )
- except InferenceError:
- raise UseInferenceDefault
- try:
- isinstance_bool = helpers.object_isinstance(obj_node, class_container, context)
- except AstroidTypeError as exc:
- raise UseInferenceDefault("TypeError: " + str(exc))
- except MroError as exc:
- raise UseInferenceDefault from exc
- if isinstance_bool is util.Uninferable:
- raise UseInferenceDefault
- return nodes.Const(isinstance_bool)
-
-
-def _class_or_tuple_to_container(node, context=None):
- # Move inferences results into container
- # to simplify later logic
- # raises InferenceError if any of the inferences fall through
- node_infer = next(node.infer(context=context))
- # arg2 MUST be a type or a TUPLE of types
- # for isinstance
- if isinstance(node_infer, nodes.Tuple):
- class_container = [
- next(node.infer(context=context)) for node in node_infer.elts
- ]
- class_container = [
- klass_node for klass_node in class_container if klass_node is not None
- ]
- else:
- class_container = [node_infer]
- return class_container
-
-
-def infer_len(node, context=None):
- """Infer length calls
-
- :param nodes.Call node: len call to infer
- :param context.InferenceContext: node context
- :rtype nodes.Const: a Const node with the inferred length, if possible
- """
- call = arguments.CallSite.from_call(node)
- if call.keyword_arguments:
- raise UseInferenceDefault("TypeError: len() must take no keyword arguments")
- if len(call.positional_arguments) != 1:
- raise UseInferenceDefault(
- "TypeError: len() must take exactly one argument "
- "({len}) given".format(len=len(call.positional_arguments))
- )
- [argument_node] = call.positional_arguments
- try:
- return nodes.Const(helpers.object_len(argument_node, context=context))
- except (AstroidTypeError, InferenceError) as exc:
- raise UseInferenceDefault(str(exc)) from exc
-
-
-def infer_str(node, context=None):
- """Infer str() calls
-
- :param nodes.Call node: str() call to infer
- :param context.InferenceContext: node context
- :rtype nodes.Const: a Const containing an empty string
- """
- call = arguments.CallSite.from_call(node)
- if call.keyword_arguments:
- raise UseInferenceDefault("TypeError: str() must take no keyword arguments")
- try:
- return nodes.Const("")
- except (AstroidTypeError, InferenceError) as exc:
- raise UseInferenceDefault(str(exc)) from exc
-
-
-def infer_int(node, context=None):
- """Infer int() calls
-
- :param nodes.Call node: int() call to infer
- :param context.InferenceContext: node context
- :rtype nodes.Const: a Const containing the integer value of the int() call
- """
- call = arguments.CallSite.from_call(node)
- if call.keyword_arguments:
- raise UseInferenceDefault("TypeError: int() must take no keyword arguments")
-
- if call.positional_arguments:
- try:
- first_value = next(call.positional_arguments[0].infer(context=context))
- except InferenceError as exc:
- raise UseInferenceDefault(str(exc)) from exc
-
- if first_value is util.Uninferable:
- raise UseInferenceDefault
-
- if isinstance(first_value, nodes.Const) and isinstance(
- first_value.value, (int, str)
- ):
- try:
- actual_value = int(first_value.value)
- except ValueError:
- return nodes.Const(0)
- return nodes.Const(actual_value)
-
- return nodes.Const(0)
-
-
-def infer_dict_fromkeys(node, context=None):
- """Infer dict.fromkeys
-
- :param nodes.Call node: dict.fromkeys() call to infer
- :param context.InferenceContext: node context
- :rtype nodes.Dict:
- a Dictionary containing the values that astroid was able to infer.
- In case the inference failed for any reason, an empty dictionary
- will be inferred instead.
- """
-
- def _build_dict_with_elements(elements):
- new_node = nodes.Dict(
- col_offset=node.col_offset, lineno=node.lineno, parent=node.parent
- )
- new_node.postinit(elements)
- return new_node
-
- call = arguments.CallSite.from_call(node)
- if call.keyword_arguments:
- raise UseInferenceDefault("TypeError: int() must take no keyword arguments")
- if len(call.positional_arguments) not in {1, 2}:
- raise UseInferenceDefault(
- "TypeError: Needs between 1 and 2 positional arguments"
- )
-
- default = nodes.Const(None)
- values = call.positional_arguments[0]
- try:
- inferred_values = next(values.infer(context=context))
- except InferenceError:
- return _build_dict_with_elements([])
- if inferred_values is util.Uninferable:
- return _build_dict_with_elements([])
-
- # Limit to a couple of potential values, as this can become pretty complicated
- accepted_iterable_elements = (nodes.Const,)
- if isinstance(inferred_values, (nodes.List, nodes.Set, nodes.Tuple)):
- elements = inferred_values.elts
- for element in elements:
- if not isinstance(element, accepted_iterable_elements):
- # Fallback to an empty dict
- return _build_dict_with_elements([])
-
- elements_with_value = [(element, default) for element in elements]
- return _build_dict_with_elements(elements_with_value)
-
- elif isinstance(inferred_values, nodes.Const) and isinstance(
- inferred_values.value, (str, bytes)
- ):
- elements = [
- (nodes.Const(element), default) for element in inferred_values.value
- ]
- return _build_dict_with_elements(elements)
- elif isinstance(inferred_values, nodes.Dict):
- keys = inferred_values.itered()
- for key in keys:
- if not isinstance(key, accepted_iterable_elements):
- # Fallback to an empty dict
- return _build_dict_with_elements([])
-
- elements_with_value = [(element, default) for element in keys]
- return _build_dict_with_elements(elements_with_value)
-
- # Fallback to an empty dictionary
- return _build_dict_with_elements([])
-
-
-# Builtins inference
-register_builtin_transform(infer_bool, "bool")
-register_builtin_transform(infer_super, "super")
-register_builtin_transform(infer_callable, "callable")
-register_builtin_transform(infer_getattr, "getattr")
-register_builtin_transform(infer_hasattr, "hasattr")
-register_builtin_transform(infer_tuple, "tuple")
-register_builtin_transform(infer_set, "set")
-register_builtin_transform(infer_list, "list")
-register_builtin_transform(infer_dict, "dict")
-register_builtin_transform(infer_frozenset, "frozenset")
-register_builtin_transform(infer_type, "type")
-register_builtin_transform(infer_slice, "slice")
-register_builtin_transform(infer_isinstance, "isinstance")
-register_builtin_transform(infer_issubclass, "issubclass")
-register_builtin_transform(infer_len, "len")
-register_builtin_transform(infer_str, "str")
-register_builtin_transform(infer_int, "int")
-register_builtin_transform(infer_dict_fromkeys, "dict.fromkeys")
-
-
-# Infer object.__new__ calls
-MANAGER.register_transform(
- nodes.ClassDef,
- inference_tip(_infer_object__new__decorator),
- _infer_object__new__decorator_check,
-)
generated by cgit (git 2.34.1) at 2024-12-19 09:50:31 +0000