AlkantarClanX12
Current Path : /opt/cloudlinux/venv/lib/python3.11/site-packages/astroid/brain/ |
Current File : //opt/cloudlinux/venv/lib/python3.11/site-packages/astroid/brain/brain_builtin_inference.py |
# Licensed under the LGPL: https://www.gnu.org/licenses/old-licenses/lgpl-2.1.en.html # For details: https://github.com/PyCQA/astroid/blob/main/LICENSE # Copyright (c) https://github.com/PyCQA/astroid/blob/main/CONTRIBUTORS.txt """Astroid hooks for various builtins.""" from __future__ import annotations import itertools from collections.abc import Iterator from functools import partial from astroid import arguments, helpers, inference_tip, nodes, objects, util from astroid.builder import AstroidBuilder from astroid.context import InferenceContext from astroid.exceptions import ( AstroidTypeError, AttributeInferenceError, InferenceError, MroError, UseInferenceDefault, ) from astroid.manager import AstroidManager from astroid.nodes import scoped_nodes OBJECT_DUNDER_NEW = "object.__new__" STR_CLASS = """ 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 b'' 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} """ BYTES_CLASS = """ class whatever(object): def join(self, iterable): return {rvalue} def replace(self, old, new, count=None): return {rvalue} 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} """ def _extend_string_class(class_node, code, rvalue): """Function to extend builtin str/unicode class.""" code = code.format(rvalue=rvalue) fake = AstroidBuilder(AstroidManager()).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 = AstroidManager().builtins_module for class_name, transform in class_transforms.items(): transform(builtin_ast[class_name]) _extend_builtins( { "bytes": partial(_extend_string_class, code=BYTES_CLASS, rvalue="b''"), "str": partial(_extend_string_class, code=STR_CLASS, rvalue="''"), } ) def _builtin_filter_predicate(node, builtin_name) -> bool: if ( builtin_name == "type" and node.root().name == "re" and isinstance(node.func, nodes.Name) and node.func.name == "type" and isinstance(node.parent, nodes.Assign) and len(node.parent.targets) == 1 and isinstance(node.parent.targets[0], nodes.AssignName) and node.parent.targets[0].name in {"Pattern", "Match"} ): # Handle re.Pattern and re.Match in brain_re # Match these patterns from stdlib/re.py # ```py # Pattern = type(...) # Match = type(...) # ``` return False 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) -> None: """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: InferenceContext | None = 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 # Can be a 'Module' see https://github.com/PyCQA/pylint/issues/4671 # We don't have a regression test on this one: tread carefully if hasattr(result, "col_offset") and result.col_offset is None: result.col_offset = node.col_offset return iter([result]) AstroidManager().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) as exc: raise UseInferenceDefault from exc if isinstance(inferred, util.UninferableBase): raise UseInferenceDefault transformed = transform(inferred) if not transformed or isinstance(transformed, util.UninferableBase): raise UseInferenceDefault return transformed def _container_generic_transform( # pylint: disable=inconsistent-return-statements arg, context, klass, iterables, build_elts ): if isinstance(arg, klass): return arg if 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 = [] for element in arg.elts: if not element: continue inferred = helpers.safe_infer(element, context=context) if inferred: evaluated_object = nodes.EvaluatedObject( original=element, value=inferred ) elts.append(evaluated_object) 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, (str, bytes)): 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, context=context, 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): def is_iterable(n): return isinstance(n, (nodes.List, nodes.Tuple, nodes.Set)) try: inferred = next(arg.infer(context)) except (InferenceError, StopIteration) as exc: raise UseInferenceDefault from exc 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: InferenceContext | None = 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, context=context) 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() if 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: InferenceContext | None = 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 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, StopIteration) as exc: raise UseInferenceDefault from exc try: mro_type = next(node.args[1].infer(context=context)) except (InferenceError, StopIteration) as exc: raise UseInferenceDefault from exc if isinstance(mro_pointer, util.UninferableBase) or isinstance( mro_type, util.UninferableBase ): # 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, StopIteration) as exc: raise UseInferenceDefault from exc if isinstance(obj, util.UninferableBase) or isinstance(attr, util.UninferableBase): # 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, str) if not is_string: raise UseInferenceDefault return obj, attr.value def infer_getattr(node, context: InferenceContext | None = 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 ( isinstance(obj, util.UninferableBase) or isinstance(attr, util.UninferableBase) 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 (StopIteration, InferenceError) as exc: raise UseInferenceDefault from exc raise UseInferenceDefault def infer_hasattr(node, context: InferenceContext | None = 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 ( isinstance(obj, util.UninferableBase) or isinstance(attr, util.UninferableBase) 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: InferenceContext | None = 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, StopIteration): return util.Uninferable if isinstance(inferred, util.UninferableBase): return util.Uninferable return nodes.Const(inferred.callable()) def infer_property( node: nodes.Call, context: InferenceContext | None = None ) -> objects.Property: """Understand `property` class. This only infers the output of `property` call, not the arguments themselves. """ if len(node.args) < 1: # Invalid property call. raise UseInferenceDefault getter = node.args[0] try: inferred = next(getter.infer(context=context)) except (InferenceError, StopIteration) as exc: raise UseInferenceDefault from exc if not isinstance(inferred, (nodes.FunctionDef, nodes.Lambda)): raise UseInferenceDefault prop_func = objects.Property( function=inferred, name=inferred.name, lineno=node.lineno, parent=node, col_offset=node.col_offset, ) prop_func.postinit( body=[], args=inferred.args, doc_node=getattr(inferred, "doc_node", None), ) return prop_func def infer_bool(node, context: InferenceContext | None = 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, StopIteration): return util.Uninferable if isinstance(inferred, util.UninferableBase): return util.Uninferable bool_value = inferred.bool_value(context=context) if isinstance(bool_value, util.UninferableBase): return util.Uninferable return nodes.Const(bool_value) def infer_type(node, context: InferenceContext | None = 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: InferenceContext | None = 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 isinstance(arg, util.UninferableBase): 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: InferenceContext | None = None): # Instantiate class immediately # since that's what @object.__new__ does return iter((node.instantiate_class(),)) def _infer_object__new__decorator_check(node) -> bool: """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: InferenceContext | None = None): """Infer issubclass() calls. :param nodes.Call callnode: an `issubclass` call :param InferenceContext context: 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, context=context) 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( f"Expected two arguments, got {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, StopIteration) 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: InferenceContext | None = None): """Infer isinstance calls. :param nodes.Call callnode: an isinstance call :rtype nodes.Const: Boolean Const value of isinstance call :raises UseInferenceDefault: If the node cannot be inferred """ call = arguments.CallSite.from_call(callnode, context=context) 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( f"Expected two arguments, got {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 as exc: raise UseInferenceDefault from exc try: isinstance_bool = helpers.object_isinstance(obj_node, class_container, context) except AstroidTypeError as exc: raise UseInferenceDefault("TypeError: " + str(exc)) from exc except MroError as exc: raise UseInferenceDefault from exc if isinstance(isinstance_bool, util.UninferableBase): raise UseInferenceDefault return nodes.Const(isinstance_bool) def _class_or_tuple_to_container(node, context: InferenceContext | None = None): # Move inferences results into container # to simplify later logic # raises InferenceError if any of the inferences fall through try: node_infer = next(node.infer(context=context)) except StopIteration as e: raise InferenceError(node=node, context=context) from e # arg2 MUST be a type or a TUPLE of types # for isinstance if isinstance(node_infer, nodes.Tuple): try: class_container = [ next(node.infer(context=context)) for node in node_infer.elts ] except StopIteration as e: raise InferenceError(node=node, context=context) from e 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: InferenceContext | None = 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, context=context) 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: InferenceContext | None = 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, context=context) 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: InferenceContext | None = 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, context=context) 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, StopIteration) as exc: raise UseInferenceDefault(str(exc)) from exc if isinstance(first_value, util.UninferableBase): 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: InferenceContext | None = None): """Infer dict.fromkeys. :param nodes.Call node: dict.fromkeys() call to infer :param context.InferenceContext context: 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, context=context) 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, StopIteration): 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) if 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) if 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([]) def _infer_copy_method( node: nodes.Call, context: InferenceContext | None = None ) -> Iterator[nodes.NodeNG]: assert isinstance(node.func, nodes.Attribute) inferred_orig, inferred_copy = itertools.tee(node.func.expr.infer(context=context)) if all( isinstance( inferred_node, (nodes.Dict, nodes.List, nodes.Set, objects.FrozenSet) ) for inferred_node in inferred_orig ): return inferred_copy raise UseInferenceDefault() def _is_str_format_call(node: nodes.Call) -> bool: """Catch calls to str.format().""" if not isinstance(node.func, nodes.Attribute) or not node.func.attrname == "format": return False if isinstance(node.func.expr, nodes.Name): value = helpers.safe_infer(node.func.expr) else: value = node.func.expr return isinstance(value, nodes.Const) and isinstance(value.value, str) def _infer_str_format_call( node: nodes.Call, context: InferenceContext | None = None ) -> Iterator[nodes.Const | util.UninferableBase]: """Return a Const node based on the template and passed arguments.""" call = arguments.CallSite.from_call(node, context=context) if isinstance(node.func.expr, nodes.Name): value: nodes.Const | None = helpers.safe_infer(node.func.expr) if value is None: return iter([util.Uninferable]) else: value = node.func.expr format_template = value.value # Get the positional arguments passed inferred_positional = [ helpers.safe_infer(i, context) for i in call.positional_arguments ] if not all(isinstance(i, nodes.Const) for i in inferred_positional): return iter([util.Uninferable]) pos_values: list[str] = [i.value for i in inferred_positional] # Get the keyword arguments passed inferred_keyword = { k: helpers.safe_infer(v, context) for k, v in call.keyword_arguments.items() } if not all(isinstance(i, nodes.Const) for i in inferred_keyword.values()): return iter([util.Uninferable]) keyword_values: dict[str, str] = {k: v.value for k, v in inferred_keyword.items()} try: formatted_string = format_template.format(*pos_values, **keyword_values) except (AttributeError, IndexError, KeyError, TypeError, ValueError): # AttributeError: named field in format string was not found in the arguments # IndexError: there are too few arguments to interpolate # TypeError: Unsupported format string # ValueError: Unknown format code return iter([util.Uninferable]) return iter([nodes.const_factory(formatted_string)]) # Builtins inference register_builtin_transform(infer_bool, "bool") register_builtin_transform(infer_super, "super") register_builtin_transform(infer_callable, "callable") register_builtin_transform(infer_property, "property") 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 AstroidManager().register_transform( nodes.ClassDef, inference_tip(_infer_object__new__decorator), _infer_object__new__decorator_check, ) AstroidManager().register_transform( nodes.Call, inference_tip(_infer_copy_method), lambda node: isinstance(node.func, nodes.Attribute) and node.func.attrname == "copy", ) AstroidManager().register_transform( nodes.Call, inference_tip(_infer_str_format_call), _is_str_format_call )