# Copyright (c) 2015-2020 Claudiu Popa # Copyright (c) 2015-2016 Ceridwen # Copyright (c) 2018 Bryce Guinta # 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 """ Various helper utilities. """ import builtins as builtins_mod from astroid import bases from astroid import context as contextmod from astroid import exceptions from astroid import manager from astroid import nodes from astroid import raw_building from astroid import scoped_nodes from astroid import util BUILTINS = builtins_mod.__name__ def _build_proxy_class(cls_name, builtins): proxy = raw_building.build_class(cls_name) proxy.parent = builtins return proxy def _function_type(function, builtins): if isinstance(function, scoped_nodes.Lambda): if function.root().name == BUILTINS: cls_name = "builtin_function_or_method" else: cls_name = "function" elif isinstance(function, bases.BoundMethod): cls_name = "method" elif isinstance(function, bases.UnboundMethod): cls_name = "function" return _build_proxy_class(cls_name, builtins) def _object_type(node, context=None): astroid_manager = manager.AstroidManager() builtins = astroid_manager.builtins_module context = context or contextmod.InferenceContext() for inferred in node.infer(context=context): if isinstance(inferred, scoped_nodes.ClassDef): if inferred.newstyle: metaclass = inferred.metaclass(context=context) if metaclass: yield metaclass continue yield builtins.getattr("type")[0] elif isinstance(inferred, (scoped_nodes.Lambda, bases.UnboundMethod)): yield _function_type(inferred, builtins) elif isinstance(inferred, scoped_nodes.Module): yield _build_proxy_class("module", builtins) else: yield inferred._proxied def object_type(node, context=None): """Obtain the type of the given node This is used to implement the ``type`` builtin, which means that it's used for inferring type calls, as well as used in a couple of other places in the inference. The node will be inferred first, so this function can support all sorts of objects, as long as they support inference. """ try: types = set(_object_type(node, context)) except exceptions.InferenceError: return util.Uninferable if len(types) > 1 or not types: return util.Uninferable return list(types)[0] def _object_type_is_subclass(obj_type, class_or_seq, context=None): if not isinstance(class_or_seq, (tuple, list)): class_seq = (class_or_seq,) else: class_seq = class_or_seq if obj_type is util.Uninferable: return util.Uninferable # Instances are not types class_seq = [ item if not isinstance(item, bases.Instance) else util.Uninferable for item in class_seq ] # strict compatibility with issubclass # issubclass(type, (object, 1)) evaluates to true # issubclass(object, (1, type)) raises TypeError for klass in class_seq: if klass is util.Uninferable: raise exceptions.AstroidTypeError("arg 2 must be a type or tuple of types") for obj_subclass in obj_type.mro(): if obj_subclass == klass: return True return False def object_isinstance(node, class_or_seq, context=None): """Check if a node 'isinstance' any node in class_or_seq :param node: A given node :param class_or_seq: Union[nodes.NodeNG, Sequence[nodes.NodeNG]] :rtype: bool :raises AstroidTypeError: if the given ``classes_or_seq`` are not types """ obj_type = object_type(node, context) if obj_type is util.Uninferable: return util.Uninferable return _object_type_is_subclass(obj_type, class_or_seq, context=context) def object_issubclass(node, class_or_seq, context=None): """Check if a type is a subclass of any node in class_or_seq :param node: A given node :param class_or_seq: Union[Nodes.NodeNG, Sequence[nodes.NodeNG]] :rtype: bool :raises AstroidTypeError: if the given ``classes_or_seq`` are not types :raises AstroidError: if the type of the given node cannot be inferred or its type's mro doesn't work """ if not isinstance(node, nodes.ClassDef): raise TypeError("{node} needs to be a ClassDef node".format(node=node)) return _object_type_is_subclass(node, class_or_seq, context=context) def safe_infer(node, context=None): """Return the inferred value for the given node. Return None if inference failed or if there is some ambiguity (more than one node has been inferred). """ try: inferit = node.infer(context=context) value = next(inferit) except exceptions.InferenceError: return None try: next(inferit) return None # None if there is ambiguity on the inferred node except exceptions.InferenceError: return None # there is some kind of ambiguity except StopIteration: return value def has_known_bases(klass, context=None): """Return true if all base classes of a class could be inferred.""" try: return klass._all_bases_known except AttributeError: pass for base in klass.bases: result = safe_infer(base, context=context) # TODO: check for A->B->A->B pattern in class structure too? if ( not isinstance(result, scoped_nodes.ClassDef) or result is klass or not has_known_bases(result, context=context) ): klass._all_bases_known = False return False klass._all_bases_known = True return True def _type_check(type1, type2): if not all(map(has_known_bases, (type1, type2))): raise exceptions._NonDeducibleTypeHierarchy if not all([type1.newstyle, type2.newstyle]): return False try: return type1 in type2.mro()[:-1] except exceptions.MroError: # The MRO is invalid. raise exceptions._NonDeducibleTypeHierarchy def is_subtype(type1, type2): """Check if *type1* is a subtype of *type2*.""" return _type_check(type1=type2, type2=type1) def is_supertype(type1, type2): """Check if *type2* is a supertype of *type1*.""" return _type_check(type1, type2) def class_instance_as_index(node): """Get the value as an index for the given instance. If an instance provides an __index__ method, then it can be used in some scenarios where an integer is expected, for instance when multiplying or subscripting a list. """ context = contextmod.InferenceContext() context.callcontext = contextmod.CallContext(args=[node]) try: for inferred in node.igetattr("__index__", context=context): if not isinstance(inferred, bases.BoundMethod): continue for result in inferred.infer_call_result(node, context=context): if isinstance(result, nodes.Const) and isinstance(result.value, int): return result except exceptions.InferenceError: pass return None def object_len(node, context=None): """Infer length of given node object :param Union[nodes.ClassDef, nodes.Instance] node: :param node: Node to infer length of :raises AstroidTypeError: If an invalid node is returned from __len__ method or no __len__ method exists :raises InferenceError: If the given node cannot be inferred or if multiple nodes are inferred :rtype int: Integer length of node """ # pylint: disable=import-outside-toplevel; circular import from astroid.objects import FrozenSet inferred_node = safe_infer(node, context=context) if inferred_node is None or inferred_node is util.Uninferable: raise exceptions.InferenceError(node=node) if isinstance(inferred_node, nodes.Const) and isinstance( inferred_node.value, (bytes, str) ): return len(inferred_node.value) if isinstance(inferred_node, (nodes.List, nodes.Set, nodes.Tuple, FrozenSet)): return len(inferred_node.elts) if isinstance(inferred_node, nodes.Dict): return len(inferred_node.items) node_type = object_type(inferred_node, context=context) if not node_type: raise exceptions.InferenceError(node=node) try: len_call = next(node_type.igetattr("__len__", context=context)) except exceptions.AttributeInferenceError: raise exceptions.AstroidTypeError( "object of type '{}' has no len()".format(node_type.pytype()) ) result_of_len = next(len_call.infer_call_result(node, context)) if ( isinstance(result_of_len, nodes.Const) and result_of_len.pytype() == "builtins.int" ): return result_of_len.value if isinstance(result_of_len, bases.Instance) and result_of_len.is_subtype_of( "builtins.int" ): # Fake a result as we don't know the arguments of the instance call. return 0 raise exceptions.AstroidTypeError( "'{}' object cannot be interpreted as an integer".format(result_of_len) )