"""Verify properties of type arguments, like 'int' in C[int] being valid. This must happen after semantic analysis since there can be placeholder types until the end of semantic analysis, and these break various type operations, including subtype checks. """ from __future__ import annotations from typing import Callable from mypy import errorcodes as codes, message_registry from mypy.errorcodes import ErrorCode from mypy.errors import Errors from mypy.message_registry import INVALID_PARAM_SPEC_LOCATION, INVALID_PARAM_SPEC_LOCATION_NOTE from mypy.messages import format_type from mypy.mixedtraverser import MixedTraverserVisitor from mypy.nodes import Block, ClassDef, Context, FakeInfo, FuncItem, MypyFile from mypy.options import Options from mypy.scope import Scope from mypy.subtypes import is_same_type, is_subtype from mypy.types import ( AnyType, CallableType, Instance, Parameters, ParamSpecType, TupleType, Type, TypeAliasType, TypeOfAny, TypeVarLikeType, TypeVarTupleType, TypeVarType, UnboundType, UnpackType, flatten_nested_tuples, get_proper_type, get_proper_types, split_with_prefix_and_suffix, ) from mypy.typevartuples import erased_vars class TypeArgumentAnalyzer(MixedTraverserVisitor): def __init__( self, errors: Errors, options: Options, is_typeshed_file: bool, named_type: Callable[[str, list[Type]], Instance], ) -> None: super().__init__() self.errors = errors self.options = options self.is_typeshed_file = is_typeshed_file self.named_type = named_type self.scope = Scope() # Should we also analyze function definitions, or only module top-levels? self.recurse_into_functions = True # Keep track of the type aliases already visited. This is needed to avoid # infinite recursion on types like A = Union[int, List[A]]. self.seen_aliases: set[TypeAliasType] = set() def visit_mypy_file(self, o: MypyFile) -> None: self.errors.set_file(o.path, o.fullname, scope=self.scope, options=self.options) with self.scope.module_scope(o.fullname): super().visit_mypy_file(o) def visit_func(self, defn: FuncItem) -> None: if not self.recurse_into_functions: return with self.scope.function_scope(defn): super().visit_func(defn) def visit_class_def(self, defn: ClassDef) -> None: with self.scope.class_scope(defn.info): super().visit_class_def(defn) def visit_block(self, o: Block) -> None: if not o.is_unreachable: super().visit_block(o) def visit_type_alias_type(self, t: TypeAliasType) -> None: super().visit_type_alias_type(t) if t in self.seen_aliases: # Avoid infinite recursion on recursive type aliases. # Note: it is fine to skip the aliases we have already seen in non-recursive # types, since errors there have already been reported. return self.seen_aliases.add(t) assert t.alias is not None, f"Unfixed type alias {t.type_ref}" is_error, is_invalid = self.validate_args( t.alias.name, tuple(t.args), t.alias.alias_tvars, t ) if is_invalid: # If there is an arity error (e.g. non-Parameters used for ParamSpec etc.), # then it is safer to erase the arguments completely, to avoid crashes later. # TODO: can we move this logic to typeanal.py? t.args = erased_vars(t.alias.alias_tvars, TypeOfAny.from_error) if not is_error: # If there was already an error for the alias itself, there is no point in checking # the expansion, most likely it will result in the same kind of error. get_proper_type(t).accept(self) def visit_tuple_type(self, t: TupleType) -> None: t.items = flatten_nested_tuples(t.items) # We could also normalize Tuple[*tuple[X, ...]] -> tuple[X, ...] like in # expand_type() but we can't do this here since it is not a translator visitor, # and we need to return an Instance instead of TupleType. super().visit_tuple_type(t) def visit_callable_type(self, t: CallableType) -> None: super().visit_callable_type(t) t.normalize_trivial_unpack() def visit_instance(self, t: Instance) -> None: super().visit_instance(t) # Type argument counts were checked in the main semantic analyzer pass. We assume # that the counts are correct here. info = t.type if isinstance(info, FakeInfo): return # https://github.com/python/mypy/issues/11079 _, is_invalid = self.validate_args(info.name, t.args, info.defn.type_vars, t) if is_invalid: t.args = tuple(erased_vars(info.defn.type_vars, TypeOfAny.from_error)) if t.type.fullname == "builtins.tuple" and len(t.args) == 1: # Normalize Tuple[*Tuple[X, ...], ...] -> Tuple[X, ...] arg = t.args[0] if isinstance(arg, UnpackType): unpacked = get_proper_type(arg.type) if isinstance(unpacked, Instance): assert unpacked.type.fullname == "builtins.tuple" t.args = unpacked.args def validate_args( self, name: str, args: tuple[Type, ...], type_vars: list[TypeVarLikeType], ctx: Context ) -> tuple[bool, bool]: if any(isinstance(v, TypeVarTupleType) for v in type_vars): prefix = next(i for (i, v) in enumerate(type_vars) if isinstance(v, TypeVarTupleType)) tvt = type_vars[prefix] assert isinstance(tvt, TypeVarTupleType) start, middle, end = split_with_prefix_and_suffix( tuple(args), prefix, len(type_vars) - prefix - 1 ) args = start + (TupleType(list(middle), tvt.tuple_fallback),) + end is_error = False is_invalid = False for (i, arg), tvar in zip(enumerate(args), type_vars): context = ctx if arg.line < 0 else arg if isinstance(tvar, TypeVarType): if isinstance(arg, ParamSpecType): is_invalid = True self.fail( INVALID_PARAM_SPEC_LOCATION.format(format_type(arg, self.options)), context, code=codes.VALID_TYPE, ) self.note( INVALID_PARAM_SPEC_LOCATION_NOTE.format(arg.name), context, code=codes.VALID_TYPE, ) continue if isinstance(arg, Parameters): is_invalid = True self.fail( f"Cannot use {format_type(arg, self.options)} for regular type variable," " only for ParamSpec", context, code=codes.VALID_TYPE, ) continue if tvar.values: if isinstance(arg, TypeVarType): if self.in_type_alias_expr: # Type aliases are allowed to use unconstrained type variables # error will be checked at substitution point. continue arg_values = arg.values if not arg_values: is_error = True self.fail( message_registry.INVALID_TYPEVAR_AS_TYPEARG.format(arg.name, name), context, code=codes.TYPE_VAR, ) continue else: arg_values = [arg] if self.check_type_var_values( name, arg_values, tvar.name, tvar.values, context ): is_error = True # Check against upper bound. Since it's object the vast majority of the time, # add fast path to avoid a potentially slow subtype check. upper_bound = tvar.upper_bound object_upper_bound = ( type(upper_bound) is Instance and upper_bound.type.fullname == "builtins.object" ) if not object_upper_bound and not is_subtype(arg, upper_bound): if self.in_type_alias_expr and isinstance(arg, TypeVarType): # Type aliases are allowed to use unconstrained type variables # error will be checked at substitution point. continue is_error = True self.fail( message_registry.INVALID_TYPEVAR_ARG_BOUND.format( format_type(arg, self.options), name, format_type(upper_bound, self.options), ), context, code=codes.TYPE_VAR, ) elif isinstance(tvar, ParamSpecType): if not isinstance( get_proper_type(arg), (ParamSpecType, Parameters, AnyType, UnboundType) ): is_invalid = True self.fail( "Can only replace ParamSpec with a parameter types list or" f" another ParamSpec, got {format_type(arg, self.options)}", context, code=codes.VALID_TYPE, ) if is_invalid: is_error = True return is_error, is_invalid def visit_unpack_type(self, typ: UnpackType) -> None: super().visit_unpack_type(typ) proper_type = get_proper_type(typ.type) if isinstance(proper_type, TupleType): return if isinstance(proper_type, TypeVarTupleType): return # TODO: this should probably be .has_base("builtins.tuple"), also elsewhere. This is # tricky however, since this needs map_instance_to_supertype() available in many places. if isinstance(proper_type, Instance) and proper_type.type.fullname == "builtins.tuple": return if not isinstance(proper_type, (UnboundType, AnyType)): # Avoid extra errors if there were some errors already. Also interpret plain Any # as tuple[Any, ...] (this is better for the code in type checker). self.fail( message_registry.INVALID_UNPACK.format(format_type(proper_type, self.options)), typ.type, code=codes.VALID_TYPE, ) typ.type = self.named_type("builtins.tuple", [AnyType(TypeOfAny.from_error)]) def check_type_var_values( self, name: str, actuals: list[Type], arg_name: str, valids: list[Type], context: Context ) -> bool: is_error = False for actual in get_proper_types(actuals): # We skip UnboundType here, since they may appear in defn.bases, # the error will be caught when visiting info.bases, that have bound type # variables. if not isinstance(actual, (AnyType, UnboundType)) and not any( is_same_type(actual, value) for value in valids ): is_error = True if len(actuals) > 1 or not isinstance(actual, Instance): self.fail( message_registry.INVALID_TYPEVAR_ARG_VALUE.format(name), context, code=codes.TYPE_VAR, ) else: class_name = f'"{name}"' actual_type_name = f'"{actual.type.name}"' self.fail( message_registry.INCOMPATIBLE_TYPEVAR_VALUE.format( arg_name, class_name, actual_type_name ), context, code=codes.TYPE_VAR, ) return is_error def fail(self, msg: str, context: Context, *, code: ErrorCode | None = None) -> None: self.errors.report(context.line, context.column, msg, code=code) def note(self, msg: str, context: Context, *, code: ErrorCode | None = None) -> None: self.errors.report(context.line, context.column, msg, severity="note", code=code)