""" Functions inferring the syntax tree. """ import copy from parso.python import tree from jedi._compatibility import force_unicode, unicode from jedi import debug from jedi import parser_utils from jedi.inference.base_value import ValueSet, NO_VALUES, ContextualizedNode, \ iterator_to_value_set, iterate_values from jedi.inference.lazy_value import LazyTreeValue from jedi.inference import compiled from jedi.inference import recursion from jedi.inference import analysis from jedi.inference import imports from jedi.inference import arguments from jedi.inference.value import ClassValue, FunctionValue from jedi.inference.value import iterable from jedi.inference.value.dynamic_arrays import ListModification, DictModification from jedi.inference.value import TreeInstance from jedi.inference.helpers import is_string, is_literal, is_number, \ get_names_of_node, is_big_annoying_library from jedi.inference.compiled.access import COMPARISON_OPERATORS from jedi.inference.cache import inference_state_method_cache from jedi.inference.gradual.stub_value import VersionInfo from jedi.inference.gradual import annotation from jedi.inference.names import TreeNameDefinition from jedi.inference.context import CompForContext from jedi.inference.value.decorator import Decoratee from jedi.plugins import plugin_manager operator_to_magic_method = { '+': '__add__', '-': '__sub__', '*': '__mul__', '@': '__matmul__', '/': '__truediv__', '//': '__floordiv__', '%': '__mod__', '**': '__pow__', '<<': '__lshift__', '>>': '__rshift__', '&': '__and__', '|': '__or__', '^': '__xor__', } reverse_operator_to_magic_method = { k: '__r' + v[2:] for k, v in operator_to_magic_method.items() } def _limit_value_infers(func): """ This is for now the way how we limit type inference going wild. There are other ways to ensure recursion limits as well. This is mostly necessary because of instance (self) access that can be quite tricky to limit. I'm still not sure this is the way to go, but it looks okay for now and we can still go anther way in the future. Tests are there. ~ dave """ def wrapper(context, *args, **kwargs): n = context.tree_node inference_state = context.inference_state try: inference_state.inferred_element_counts[n] += 1 maximum = 300 if context.parent_context is None \ and context.get_value() is inference_state.builtins_module: # Builtins should have a more generous inference limit. # It is important that builtins can be executed, otherwise some # functions that depend on certain builtins features would be # broken, see e.g. GH #1432 maximum *= 100 if inference_state.inferred_element_counts[n] > maximum: debug.warning('In value %s there were too many inferences.', n) return NO_VALUES except KeyError: inference_state.inferred_element_counts[n] = 1 return func(context, *args, **kwargs) return wrapper def infer_node(context, element): if isinstance(context, CompForContext): return _infer_node(context, element) if_stmt = element while if_stmt is not None: if_stmt = if_stmt.parent if if_stmt.type in ('if_stmt', 'for_stmt'): break if parser_utils.is_scope(if_stmt): if_stmt = None break predefined_if_name_dict = context.predefined_names.get(if_stmt) # TODO there's a lot of issues with this one. We actually should do # this in a different way. Caching should only be active in certain # cases and this all sucks. if predefined_if_name_dict is None and if_stmt \ and if_stmt.type == 'if_stmt' and context.inference_state.is_analysis: if_stmt_test = if_stmt.children[1] name_dicts = [{}] # If we already did a check, we don't want to do it again -> If # value.predefined_names is filled, we stop. # We don't want to check the if stmt itself, it's just about # the content. if element.start_pos > if_stmt_test.end_pos: # Now we need to check if the names in the if_stmt match the # names in the suite. if_names = get_names_of_node(if_stmt_test) element_names = get_names_of_node(element) str_element_names = [e.value for e in element_names] if any(i.value in str_element_names for i in if_names): for if_name in if_names: definitions = context.inference_state.infer(context, if_name) # Every name that has multiple different definitions # causes the complexity to rise. The complexity should # never fall below 1. if len(definitions) > 1: if len(name_dicts) * len(definitions) > 16: debug.dbg('Too many options for if branch inference %s.', if_stmt) # There's only a certain amount of branches # Jedi can infer, otherwise it will take to # long. name_dicts = [{}] break original_name_dicts = list(name_dicts) name_dicts = [] for definition in definitions: new_name_dicts = list(original_name_dicts) for i, name_dict in enumerate(new_name_dicts): new_name_dicts[i] = name_dict.copy() new_name_dicts[i][if_name.value] = ValueSet([definition]) name_dicts += new_name_dicts else: for name_dict in name_dicts: name_dict[if_name.value] = definitions if len(name_dicts) > 1: result = NO_VALUES for name_dict in name_dicts: with context.predefine_names(if_stmt, name_dict): result |= _infer_node(context, element) return result else: return _infer_node_if_inferred(context, element) else: if predefined_if_name_dict: return _infer_node(context, element) else: return _infer_node_if_inferred(context, element) def _infer_node_if_inferred(context, element): """ TODO This function is temporary: Merge with infer_node. """ parent = element while parent is not None: parent = parent.parent predefined_if_name_dict = context.predefined_names.get(parent) if predefined_if_name_dict is not None: return _infer_node(context, element) return _infer_node_cached(context, element) @inference_state_method_cache(default=NO_VALUES) def _infer_node_cached(context, element): return _infer_node(context, element) @debug.increase_indent @_limit_value_infers def _infer_node(context, element): debug.dbg('infer_node %s@%s in %s', element, element.start_pos, context) inference_state = context.inference_state typ = element.type if typ in ('name', 'number', 'string', 'atom', 'strings', 'keyword', 'fstring'): return infer_atom(context, element) elif typ == 'lambdef': return ValueSet([FunctionValue.from_context(context, element)]) elif typ == 'expr_stmt': return infer_expr_stmt(context, element) elif typ in ('power', 'atom_expr'): first_child = element.children[0] children = element.children[1:] had_await = False if first_child.type == 'keyword' and first_child.value == 'await': had_await = True first_child = children.pop(0) value_set = context.infer_node(first_child) for (i, trailer) in enumerate(children): if trailer == '**': # has a power operation. right = context.infer_node(children[i + 1]) value_set = _infer_comparison( context, value_set, trailer, right ) break value_set = infer_trailer(context, value_set, trailer) if had_await: return value_set.py__await__().py__stop_iteration_returns() return value_set elif typ in ('testlist_star_expr', 'testlist',): # The implicit tuple in statements. return ValueSet([iterable.SequenceLiteralValue(inference_state, context, element)]) elif typ in ('not_test', 'factor'): value_set = context.infer_node(element.children[-1]) for operator in element.children[:-1]: value_set = infer_factor(value_set, operator) return value_set elif typ == 'test': # `x if foo else y` case. return (context.infer_node(element.children[0]) | context.infer_node(element.children[-1])) elif typ == 'operator': # Must be an ellipsis, other operators are not inferred. # In Python 2 ellipsis is coded as three single dot tokens, not # as one token 3 dot token. if element.value not in ('.', '...'): origin = element.parent raise AssertionError("unhandled operator %s in %s " % (repr(element.value), origin)) return ValueSet([compiled.builtin_from_name(inference_state, u'Ellipsis')]) elif typ == 'dotted_name': value_set = infer_atom(context, element.children[0]) for next_name in element.children[2::2]: value_set = value_set.py__getattribute__(next_name, name_context=context) return value_set elif typ == 'eval_input': return context.infer_node(element.children[0]) elif typ == 'annassign': return annotation.infer_annotation(context, element.children[1]) \ .execute_annotation() elif typ == 'yield_expr': if len(element.children) and element.children[1].type == 'yield_arg': # Implies that it's a yield from. element = element.children[1].children[1] generators = context.infer_node(element) \ .py__getattribute__('__iter__').execute_with_values() return generators.py__stop_iteration_returns() # Generator.send() is not implemented. return NO_VALUES elif typ == 'namedexpr_test': return context.infer_node(element.children[2]) else: return infer_or_test(context, element) def infer_trailer(context, atom_values, trailer): trailer_op, node = trailer.children[:2] if node == ')': # `arglist` is optional. node = None if trailer_op == '[': trailer_op, node, _ = trailer.children return atom_values.get_item( _infer_subscript_list(context, node), ContextualizedNode(context, trailer) ) else: debug.dbg('infer_trailer: %s in %s', trailer, atom_values) if trailer_op == '.': return atom_values.py__getattribute__( name_context=context, name_or_str=node ) else: assert trailer_op == '(', 'trailer_op is actually %s' % trailer_op args = arguments.TreeArguments(context.inference_state, context, node, trailer) return atom_values.execute(args) def infer_atom(context, atom): """ Basically to process ``atom`` nodes. The parser sometimes doesn't generate the node (because it has just one child). In that case an atom might be a name or a literal as well. """ state = context.inference_state if atom.type == 'name': if atom.value in ('True', 'False', 'None'): # Python 2... return ValueSet([compiled.builtin_from_name(state, atom.value)]) # This is the first global lookup. stmt = tree.search_ancestor( atom, 'expr_stmt', 'lambdef' ) or atom if stmt.type == 'lambdef': stmt = atom position = stmt.start_pos if _is_annotation_name(atom): # Since Python 3.7 (with from __future__ import annotations), # annotations are essentially strings and can reference objects # that are defined further down in code. Therefore just set the # position to None, so the finder will not try to stop at a certain # position in the module. position = None return context.py__getattribute__(atom, position=position) elif atom.type == 'keyword': # For False/True/None if atom.value in ('False', 'True', 'None'): return ValueSet([compiled.builtin_from_name(state, atom.value)]) elif atom.value == 'print': # print e.g. could be inferred like this in Python 2.7 return NO_VALUES elif atom.value == 'yield': # Contrary to yield from, yield can just appear alone to return a # value when used with `.send()`. return NO_VALUES assert False, 'Cannot infer the keyword %s' % atom elif isinstance(atom, tree.Literal): string = state.compiled_subprocess.safe_literal_eval(atom.value) return ValueSet([compiled.create_simple_object(state, string)]) elif atom.type == 'strings': # Will be multiple string. value_set = infer_atom(context, atom.children[0]) for string in atom.children[1:]: right = infer_atom(context, string) value_set = _infer_comparison(context, value_set, u'+', right) return value_set elif atom.type == 'fstring': return compiled.get_string_value_set(state) else: c = atom.children # Parentheses without commas are not tuples. if c[0] == '(' and not len(c) == 2 \ and not(c[1].type == 'testlist_comp' and len(c[1].children) > 1): return context.infer_node(c[1]) try: comp_for = c[1].children[1] except (IndexError, AttributeError): pass else: if comp_for == ':': # Dict comprehensions have a colon at the 3rd index. try: comp_for = c[1].children[3] except IndexError: pass if comp_for.type in ('comp_for', 'sync_comp_for'): return ValueSet([iterable.comprehension_from_atom( state, context, atom )]) # It's a dict/list/tuple literal. array_node = c[1] try: array_node_c = array_node.children except AttributeError: array_node_c = [] if c[0] == '{' and (array_node == '}' or ':' in array_node_c or '**' in array_node_c): new_value = iterable.DictLiteralValue(state, context, atom) else: new_value = iterable.SequenceLiteralValue(state, context, atom) return ValueSet([new_value]) @_limit_value_infers def infer_expr_stmt(context, stmt, seek_name=None): with recursion.execution_allowed(context.inference_state, stmt) as allowed: if allowed: if seek_name is not None: pep0484_values = \ annotation.find_type_from_comment_hint_assign(context, stmt, seek_name) if pep0484_values: return pep0484_values return _infer_expr_stmt(context, stmt, seek_name) return NO_VALUES @debug.increase_indent def _infer_expr_stmt(context, stmt, seek_name=None): """ The starting point of the completion. A statement always owns a call list, which are the calls, that a statement does. In case multiple names are defined in the statement, `seek_name` returns the result for this name. expr_stmt: testlist_star_expr (annassign | augassign (yield_expr|testlist) | ('=' (yield_expr|testlist_star_expr))*) annassign: ':' test ['=' test] augassign: ('+=' | '-=' | '*=' | '@=' | '/=' | '%=' | '&=' | '|=' | '^=' | '<<=' | '>>=' | '**=' | '//=') :param stmt: A `tree.ExprStmt`. """ def check_setitem(stmt): atom_expr = stmt.children[0] if atom_expr.type not in ('atom_expr', 'power'): return False, None name = atom_expr.children[0] if name.type != 'name' or len(atom_expr.children) != 2: return False, None trailer = atom_expr.children[-1] return trailer.children[0] == '[', trailer.children[1] debug.dbg('infer_expr_stmt %s (%s)', stmt, seek_name) rhs = stmt.get_rhs() value_set = context.infer_node(rhs) if seek_name: n = TreeNameDefinition(context, seek_name) value_set = check_tuple_assignments(n, value_set) first_operator = next(stmt.yield_operators(), None) is_setitem, subscriptlist = check_setitem(stmt) is_annassign = first_operator not in ('=', None) and first_operator.type == 'operator' if is_annassign or is_setitem: # `=` is always the last character in aug assignments -> -1 name = stmt.get_defined_names(include_setitem=True)[0].value left_values = context.py__getattribute__(name, position=stmt.start_pos) if is_setitem: def to_mod(v): c = ContextualizedSubscriptListNode(context, subscriptlist) if v.array_type == 'dict': return DictModification(v, value_set, c) elif v.array_type == 'list': return ListModification(v, value_set, c) return v value_set = ValueSet(to_mod(v) for v in left_values) else: operator = copy.copy(first_operator) operator.value = operator.value[:-1] for_stmt = tree.search_ancestor(stmt, 'for_stmt') if for_stmt is not None and for_stmt.type == 'for_stmt' and value_set \ and parser_utils.for_stmt_defines_one_name(for_stmt): # Iterate through result and add the values, that's possible # only in for loops without clutter, because they are # predictable. Also only do it, if the variable is not a tuple. node = for_stmt.get_testlist() cn = ContextualizedNode(context, node) ordered = list(cn.infer().iterate(cn)) for lazy_value in ordered: dct = {for_stmt.children[1].value: lazy_value.infer()} with context.predefine_names(for_stmt, dct): t = context.infer_node(rhs) left_values = _infer_comparison(context, left_values, operator, t) value_set = left_values else: value_set = _infer_comparison(context, left_values, operator, value_set) debug.dbg('infer_expr_stmt result %s', value_set) return value_set def infer_or_test(context, or_test): iterator = iter(or_test.children) types = context.infer_node(next(iterator)) for operator in iterator: right = next(iterator) if operator.type == 'comp_op': # not in / is not operator = ' '.join(c.value for c in operator.children) # handle type inference of and/or here. if operator in ('and', 'or'): left_bools = set(left.py__bool__() for left in types) if left_bools == {True}: if operator == 'and': types = context.infer_node(right) elif left_bools == {False}: if operator != 'and': types = context.infer_node(right) # Otherwise continue, because of uncertainty. else: types = _infer_comparison(context, types, operator, context.infer_node(right)) debug.dbg('infer_or_test types %s', types) return types @iterator_to_value_set def infer_factor(value_set, operator): """ Calculates `+`, `-`, `~` and `not` prefixes. """ for value in value_set: if operator == '-': if is_number(value): yield value.negate() elif operator == 'not': b = value.py__bool__() if b is None: # Uncertainty. return yield compiled.create_simple_object(value.inference_state, not b) else: yield value def _literals_to_types(inference_state, result): # Changes literals ('a', 1, 1.0, etc) to its type instances (str(), # int(), float(), etc). new_result = NO_VALUES for typ in result: if is_literal(typ): # Literals are only valid as long as the operations are # correct. Otherwise add a value-free instance. cls = compiled.builtin_from_name(inference_state, typ.name.string_name) new_result |= cls.execute_with_values() else: new_result |= ValueSet([typ]) return new_result def _infer_comparison(context, left_values, operator, right_values): state = context.inference_state if not left_values or not right_values: # illegal slices e.g. cause left/right_result to be None result = (left_values or NO_VALUES) | (right_values or NO_VALUES) return _literals_to_types(state, result) else: # I don't think there's a reasonable chance that a string # operation is still correct, once we pass something like six # objects. if len(left_values) * len(right_values) > 6: return _literals_to_types(state, left_values | right_values) else: return ValueSet.from_sets( _infer_comparison_part(state, context, left, operator, right) for left in left_values for right in right_values ) def _is_annotation_name(name): ancestor = tree.search_ancestor(name, 'param', 'funcdef', 'expr_stmt') if ancestor is None: return False if ancestor.type in ('param', 'funcdef'): ann = ancestor.annotation if ann is not None: return ann.start_pos <= name.start_pos < ann.end_pos elif ancestor.type == 'expr_stmt': c = ancestor.children if len(c) > 1 and c[1].type == 'annassign': return c[1].start_pos <= name.start_pos < c[1].end_pos return False def _is_list(value): return value.array_type == 'list' def _is_tuple(value): return value.array_type == 'tuple' def _bool_to_value(inference_state, bool_): return compiled.builtin_from_name(inference_state, force_unicode(str(bool_))) def _get_tuple_ints(value): if not isinstance(value, iterable.SequenceLiteralValue): return None numbers = [] for lazy_value in value.py__iter__(): if not isinstance(lazy_value, LazyTreeValue): return None node = lazy_value.data if node.type != 'number': return None try: numbers.append(int(node.value)) except ValueError: return None return numbers def _infer_comparison_part(inference_state, context, left, operator, right): l_is_num = is_number(left) r_is_num = is_number(right) if isinstance(operator, unicode): str_operator = operator else: str_operator = force_unicode(str(operator.value)) if str_operator == '*': # for iterables, ignore * operations if isinstance(left, iterable.Sequence) or is_string(left): return ValueSet([left]) elif isinstance(right, iterable.Sequence) or is_string(right): return ValueSet([right]) elif str_operator == '+': if l_is_num and r_is_num or is_string(left) and is_string(right): return left.execute_operation(right, str_operator) elif _is_list(left) and _is_list(right) or _is_tuple(left) and _is_tuple(right): return ValueSet([iterable.MergedArray(inference_state, (left, right))]) elif str_operator == '-': if l_is_num and r_is_num: return left.execute_operation(right, str_operator) elif str_operator == '%': # With strings and numbers the left type typically remains. Except for # `int() % float()`. return ValueSet([left]) elif str_operator in COMPARISON_OPERATORS: if left.is_compiled() and right.is_compiled(): # Possible, because the return is not an option. Just compare. result = left.execute_operation(right, str_operator) if result: return result else: if str_operator in ('is', '!=', '==', 'is not'): operation = COMPARISON_OPERATORS[str_operator] bool_ = operation(left, right) # Only if == returns True or != returns False, we can continue. # There's no guarantee that they are not equal. This can help # in some cases, but does not cover everything. if (str_operator in ('is', '==')) == bool_: return ValueSet([_bool_to_value(inference_state, bool_)]) if isinstance(left, VersionInfo): version_info = _get_tuple_ints(right) if version_info is not None: bool_result = compiled.access.COMPARISON_OPERATORS[operator]( inference_state.environment.version_info, tuple(version_info) ) return ValueSet([_bool_to_value(inference_state, bool_result)]) return ValueSet([ _bool_to_value(inference_state, True), _bool_to_value(inference_state, False) ]) elif str_operator in ('in', 'not in'): return NO_VALUES def check(obj): """Checks if a Jedi object is either a float or an int.""" return isinstance(obj, TreeInstance) and \ obj.name.string_name in ('int', 'float') # Static analysis, one is a number, the other one is not. if str_operator in ('+', '-') and l_is_num != r_is_num \ and not (check(left) or check(right)): message = "TypeError: unsupported operand type(s) for +: %s and %s" analysis.add(context, 'type-error-operation', operator, message % (left, right)) if left.is_class() or right.is_class(): return NO_VALUES method_name = operator_to_magic_method[str_operator] magic_methods = left.py__getattribute__(method_name) if magic_methods: result = magic_methods.execute_with_values(right) if result: return result if not magic_methods: reverse_method_name = reverse_operator_to_magic_method[str_operator] magic_methods = right.py__getattribute__(reverse_method_name) result = magic_methods.execute_with_values(left) if result: return result result = ValueSet([left, right]) debug.dbg('Used operator %s resulting in %s', operator, result) return result @plugin_manager.decorate() def tree_name_to_values(inference_state, context, tree_name): value_set = NO_VALUES module_node = context.get_root_context().tree_node # First check for annotations, like: `foo: int = 3` if module_node is not None: names = module_node.get_used_names().get(tree_name.value, []) found_annotation = False for name in names: expr_stmt = name.parent if expr_stmt.type == "expr_stmt" and expr_stmt.children[1].type == "annassign": correct_scope = parser_utils.get_parent_scope(name) == context.tree_node if correct_scope: found_annotation = True value_set |= annotation.infer_annotation( context, expr_stmt.children[1].children[1] ).execute_annotation() if found_annotation: return value_set types = [] node = tree_name.get_definition(import_name_always=True, include_setitem=True) if node is None: node = tree_name.parent if node.type == 'global_stmt': c = context.create_context(tree_name) if c.is_module(): # In case we are already part of the module, there is no point # in looking up the global statement anymore, because it's not # valid at that point anyway. return NO_VALUES # For global_stmt lookups, we only need the first possible scope, # which means the function itself. filter = next(c.get_filters()) names = filter.get(tree_name.value) return ValueSet.from_sets(name.infer() for name in names) elif node.type not in ('import_from', 'import_name'): c = context.create_context(tree_name) return infer_atom(c, tree_name) typ = node.type if typ == 'for_stmt': types = annotation.find_type_from_comment_hint_for(context, node, tree_name) if types: return types if typ == 'with_stmt': types = annotation.find_type_from_comment_hint_with(context, node, tree_name) if types: return types if typ in ('for_stmt', 'comp_for', 'sync_comp_for'): try: types = context.predefined_names[node][tree_name.value] except KeyError: cn = ContextualizedNode(context, node.children[3]) for_types = iterate_values( cn.infer(), contextualized_node=cn, is_async=node.parent.type == 'async_stmt', ) n = TreeNameDefinition(context, tree_name) types = check_tuple_assignments(n, for_types) elif typ == 'expr_stmt': types = infer_expr_stmt(context, node, tree_name) elif typ == 'with_stmt': value_managers = context.infer_node(node.get_test_node_from_name(tree_name)) enter_methods = value_managers.py__getattribute__(u'__enter__') return enter_methods.execute_with_values() elif typ in ('import_from', 'import_name'): types = imports.infer_import(context, tree_name) elif typ in ('funcdef', 'classdef'): types = _apply_decorators(context, node) elif typ == 'try_stmt': # TODO an exception can also be a tuple. Check for those. # TODO check for types that are not classes and add it to # the static analysis report. exceptions = context.infer_node(tree_name.get_previous_sibling().get_previous_sibling()) types = exceptions.execute_with_values() elif typ == 'param': types = NO_VALUES elif typ == 'del_stmt': types = NO_VALUES else: raise ValueError("Should not happen. type: %s" % typ) return types # We don't want to have functions/classes that are created by the same # tree_node. @inference_state_method_cache() def _apply_decorators(context, node): """ Returns the function, that should to be executed in the end. This is also the places where the decorators are processed. """ if node.type == 'classdef': decoratee_value = ClassValue( context.inference_state, parent_context=context, tree_node=node ) else: decoratee_value = FunctionValue.from_context(context, node) initial = values = ValueSet([decoratee_value]) if is_big_annoying_library(context): return values for dec in reversed(node.get_decorators()): debug.dbg('decorator: %s %s', dec, values, color="MAGENTA") with debug.increase_indent_cm(): dec_values = context.infer_node(dec.children[1]) trailer_nodes = dec.children[2:-1] if trailer_nodes: # Create a trailer and infer it. trailer = tree.PythonNode('trailer', trailer_nodes) trailer.parent = dec dec_values = infer_trailer(context, dec_values, trailer) if not len(dec_values): code = dec.get_code(include_prefix=False) # For the short future, we don't want to hear about the runtime # decorator in typing that was intentionally omitted. This is not # "correct", but helps with debugging. if code != '@runtime\n': debug.warning('decorator not found: %s on %s', dec, node) return initial values = dec_values.execute(arguments.ValuesArguments([values])) if not len(values): debug.warning('not possible to resolve wrappers found %s', node) return initial debug.dbg('decorator end %s', values, color="MAGENTA") if values != initial: return ValueSet([Decoratee(c, decoratee_value) for c in values]) return values def check_tuple_assignments(name, value_set): """ Checks if tuples are assigned. """ lazy_value = None for index, node in name.assignment_indexes(): cn = ContextualizedNode(name.parent_context, node) iterated = value_set.iterate(cn) if isinstance(index, slice): # For no star unpacking is not possible. return NO_VALUES i = 0 while i <= index: try: lazy_value = next(iterated) except StopIteration: # We could do this with the default param in next. But this # would allow this loop to run for a very long time if the # index number is high. Therefore break if the loop is # finished. return NO_VALUES else: i += lazy_value.max value_set = lazy_value.infer() return value_set class ContextualizedSubscriptListNode(ContextualizedNode): def infer(self): return _infer_subscript_list(self.context, self.node) def _infer_subscript_list(context, index): """ Handles slices in subscript nodes. """ if index == ':': # Like array[:] return ValueSet([iterable.Slice(context, None, None, None)]) elif index.type == 'subscript' and not index.children[0] == '.': # subscript basically implies a slice operation, except for Python 2's # Ellipsis. # e.g. array[:3] result = [] for el in index.children: if el == ':': if not result: result.append(None) elif el.type == 'sliceop': if len(el.children) == 2: result.append(el.children[1]) else: result.append(el) result += [None] * (3 - len(result)) return ValueSet([iterable.Slice(context, *result)]) elif index.type == 'subscriptlist': return ValueSet([iterable.SequenceLiteralValue(context.inference_state, context, index)]) # No slices return context.infer_node(index)