""" The typing module: Support for gradual typing as defined by PEP 484. At large scale, the structure of the module is following: * Imports and exports, all public names should be explicitly added to __all__. * Internal helper functions: these should never be used in code outside this module. * _SpecialForm and its instances (special forms): Any, NoReturn, Never, ClassVar, Union, Optional, Concatenate, Unpack * Classes whose instances can be type arguments in addition to types: ForwardRef, TypeVar and ParamSpec * The core of internal generics API: _GenericAlias and _VariadicGenericAlias, the latter is currently only used by Tuple and Callable. All subscripted types like X[int], Union[int, str], etc., are instances of either of these classes. * The public counterpart of the generics API consists of two classes: Generic and Protocol. * Public helper functions: get_type_hints, overload, cast, no_type_check, no_type_check_decorator. * Generic aliases for collections.abc ABCs and few additional protocols. * Special types: NewType, NamedTuple, TypedDict. * Wrapper submodules for re and io related types. """ from abc import abstractmethod, ABCMeta import collections from collections import defaultdict import collections.abc import contextlib import functools import operator import re as stdlib_re # Avoid confusion with the re we export. import sys import types import warnings from types import WrapperDescriptorType, MethodWrapperType, MethodDescriptorType, GenericAlias try: from _typing import _idfunc except ImportError: def _idfunc(_, x): return x # Please keep __all__ alphabetized within each category. __all__ = [ # Super-special typing primitives. 'Annotated', 'Any', 'Callable', 'ClassVar', 'Concatenate', 'Final', 'ForwardRef', 'Generic', 'Literal', 'Optional', 'ParamSpec', 'Protocol', 'Tuple', 'Type', 'TypeVar', 'TypeVarTuple', 'Union', # ABCs (from collections.abc). 'AbstractSet', # collections.abc.Set. 'ByteString', 'Container', 'ContextManager', 'Hashable', 'ItemsView', 'Iterable', 'Iterator', 'KeysView', 'Mapping', 'MappingView', 'MutableMapping', 'MutableSequence', 'MutableSet', 'Sequence', 'Sized', 'ValuesView', 'Awaitable', 'AsyncIterator', 'AsyncIterable', 'Coroutine', 'Collection', 'AsyncGenerator', 'AsyncContextManager', # Structural checks, a.k.a. protocols. 'Reversible', 'SupportsAbs', 'SupportsBytes', 'SupportsComplex', 'SupportsFloat', 'SupportsIndex', 'SupportsInt', 'SupportsRound', # Concrete collection types. 'ChainMap', 'Counter', 'Deque', 'Dict', 'DefaultDict', 'List', 'OrderedDict', 'Set', 'FrozenSet', 'NamedTuple', # Not really a type. 'TypedDict', # Not really a type. 'Generator', # Other concrete types. 'BinaryIO', 'IO', 'Match', 'Pattern', 'TextIO', # One-off things. 'AnyStr', 'assert_type', 'assert_never', 'cast', 'clear_overloads', 'dataclass_transform', 'final', 'get_args', 'get_origin', 'get_overloads', 'get_type_hints', 'is_typeddict', 'LiteralString', 'Never', 'NewType', 'no_type_check', 'no_type_check_decorator', 'NoReturn', 'NotRequired', 'overload', 'ParamSpecArgs', 'ParamSpecKwargs', 'Required', 'reveal_type', 'runtime_checkable', 'Self', 'Text', 'TYPE_CHECKING', 'TypeAlias', 'TypeGuard', 'Unpack', ] # The pseudo-submodules 're' and 'io' are part of the public # namespace, but excluded from __all__ because they might stomp on # legitimate imports of those modules. def _type_convert(arg, module=None, *, allow_special_forms=False): """For converting None to type(None), and strings to ForwardRef.""" if arg is None: return type(None) if isinstance(arg, str): return ForwardRef(arg, module=module, is_class=allow_special_forms) return arg def _type_check(arg, msg, is_argument=True, module=None, *, allow_special_forms=False): """Check that the argument is a type, and return it (internal helper). As a special case, accept None and return type(None) instead. Also wrap strings into ForwardRef instances. Consider several corner cases, for example plain special forms like Union are not valid, while Union[int, str] is OK, etc. The msg argument is a human-readable error message, e.g:: "Union[arg, ...]: arg should be a type." We append the repr() of the actual value (truncated to 100 chars). """ invalid_generic_forms = (Generic, Protocol) if not allow_special_forms: invalid_generic_forms += (ClassVar,) if is_argument: invalid_generic_forms += (Final,) arg = _type_convert(arg, module=module, allow_special_forms=allow_special_forms) if (isinstance(arg, _GenericAlias) and arg.__origin__ in invalid_generic_forms): raise TypeError(f"{arg} is not valid as type argument") if arg in (Any, LiteralString, NoReturn, Never, Self, TypeAlias): return arg if allow_special_forms and arg in (ClassVar, Final): return arg if isinstance(arg, _SpecialForm) or arg in (Generic, Protocol): raise TypeError(f"Plain {arg} is not valid as type argument") if type(arg) is tuple: raise TypeError(f"{msg} Got {arg!r:.100}.") return arg def _is_param_expr(arg): return arg is ... or isinstance(arg, (tuple, list, ParamSpec, _ConcatenateGenericAlias)) def _should_unflatten_callable_args(typ, args): """Internal helper for munging collections.abc.Callable's __args__. The canonical representation for a Callable's __args__ flattens the argument types, see https://bugs.python.org/issue42195. For example: collections.abc.Callable[[int, int], str].__args__ == (int, int, str) collections.abc.Callable[ParamSpec, str].__args__ == (ParamSpec, str) As a result, if we need to reconstruct the Callable from its __args__, we need to unflatten it. """ return ( typ.__origin__ is collections.abc.Callable and not (len(args) == 2 and _is_param_expr(args[0])) ) def _type_repr(obj): """Return the repr() of an object, special-casing types (internal helper). If obj is a type, we return a shorter version than the default type.__repr__, based on the module and qualified name, which is typically enough to uniquely identify a type. For everything else, we fall back on repr(obj). """ if isinstance(obj, types.GenericAlias): return repr(obj) if isinstance(obj, type): if obj.__module__ == 'builtins': return obj.__qualname__ return f'{obj.__module__}.{obj.__qualname__}' if obj is ...: return('...') if isinstance(obj, types.FunctionType): return obj.__name__ return repr(obj) def _collect_parameters(args): """Collect all type variables and parameter specifications in args in order of first appearance (lexicographic order). For example:: _collect_parameters((T, Callable[P, T])) == (T, P) """ parameters = [] for t in args: if hasattr(t, '__typing_subst__'): if t not in parameters: parameters.append(t) else: for x in getattr(t, '__parameters__', ()): if x not in parameters: parameters.append(x) return tuple(parameters) def _check_generic(cls, parameters, elen): """Check correct count for parameters of a generic cls (internal helper). This gives a nice error message in case of count mismatch. """ if not elen: raise TypeError(f"{cls} is not a generic class") alen = len(parameters) if alen != elen: raise TypeError(f"Too {'many' if alen > elen else 'few'} arguments for {cls};" f" actual {alen}, expected {elen}") def _prepare_paramspec_params(cls, params): """Prepares the parameters for a Generic containing ParamSpec variables (internal helper). """ # Special case where Z[[int, str, bool]] == Z[int, str, bool] in PEP 612. if (len(cls.__parameters__) == 1 and params and not _is_param_expr(params[0])): assert isinstance(cls.__parameters__[0], ParamSpec) return (params,) else: _check_generic(cls, params, len(cls.__parameters__)) _params = [] # Convert lists to tuples to help other libraries cache the results. for p, tvar in zip(params, cls.__parameters__): if isinstance(tvar, ParamSpec) and isinstance(p, list): p = tuple(p) _params.append(p) return tuple(_params) def _deduplicate(params): # Weed out strict duplicates, preserving the first of each occurrence. all_params = set(params) if len(all_params) < len(params): new_params = [] for t in params: if t in all_params: new_params.append(t) all_params.remove(t) params = new_params assert not all_params, all_params return params def _remove_dups_flatten(parameters): """An internal helper for Union creation and substitution: flatten Unions among parameters, then remove duplicates. """ # Flatten out Union[Union[...], ...]. params = [] for p in parameters: if isinstance(p, (_UnionGenericAlias, types.UnionType)): params.extend(p.__args__) else: params.append(p) return tuple(_deduplicate(params)) def _flatten_literal_params(parameters): """An internal helper for Literal creation: flatten Literals among parameters""" params = [] for p in parameters: if isinstance(p, _LiteralGenericAlias): params.extend(p.__args__) else: params.append(p) return tuple(params) _cleanups = [] def _tp_cache(func=None, /, *, typed=False): """Internal wrapper caching __getitem__ of generic types with a fallback to original function for non-hashable arguments. """ def decorator(func): cached = functools.lru_cache(typed=typed)(func) _cleanups.append(cached.cache_clear) @functools.wraps(func) def inner(*args, **kwds): try: return cached(*args, **kwds) except TypeError: pass # All real errors (not unhashable args) are raised below. return func(*args, **kwds) return inner if func is not None: return decorator(func) return decorator def _eval_type(t, globalns, localns, recursive_guard=frozenset()): """Evaluate all forward references in the given type t. For use of globalns and localns see the docstring for get_type_hints(). recursive_guard is used to prevent infinite recursion with a recursive ForwardRef. """ if isinstance(t, ForwardRef): return t._evaluate(globalns, localns, recursive_guard) if isinstance(t, (_GenericAlias, GenericAlias, types.UnionType)): if isinstance(t, GenericAlias): args = tuple( ForwardRef(arg) if isinstance(arg, str) else arg for arg in t.__args__ ) if _should_unflatten_callable_args(t, args): t = t.__origin__[(args[:-1], args[-1])] else: t = t.__origin__[args] ev_args = tuple(_eval_type(a, globalns, localns, recursive_guard) for a in t.__args__) if ev_args == t.__args__: return t if isinstance(t, GenericAlias): return GenericAlias(t.__origin__, ev_args) if isinstance(t, types.UnionType): return functools.reduce(operator.or_, ev_args) else: return t.copy_with(ev_args) return t class _Final: """Mixin to prohibit subclassing""" __slots__ = ('__weakref__',) def __init_subclass__(cls, /, *args, **kwds): if '_root' not in kwds: raise TypeError("Cannot subclass special typing classes") class _Immutable: """Mixin to indicate that object should not be copied.""" __slots__ = () def __copy__(self): return self def __deepcopy__(self, memo): return self class _NotIterable: """Mixin to prevent iteration, without being compatible with Iterable. That is, we could do: def __iter__(self): raise TypeError() But this would make users of this mixin duck type-compatible with collections.abc.Iterable - isinstance(foo, Iterable) would be True. Luckily, we can instead prevent iteration by setting __iter__ to None, which is treated specially. """ __slots__ = () __iter__ = None # Internal indicator of special typing constructs. # See __doc__ instance attribute for specific docs. class _SpecialForm(_Final, _NotIterable, _root=True): __slots__ = ('_name', '__doc__', '_getitem') def __init__(self, getitem): self._getitem = getitem self._name = getitem.__name__ self.__doc__ = getitem.__doc__ def __getattr__(self, item): if item in {'__name__', '__qualname__'}: return self._name raise AttributeError(item) def __mro_entries__(self, bases): raise TypeError(f"Cannot subclass {self!r}") def __repr__(self): return 'typing.' + self._name def __reduce__(self): return self._name def __call__(self, *args, **kwds): raise TypeError(f"Cannot instantiate {self!r}") def __or__(self, other): return Union[self, other] def __ror__(self, other): return Union[other, self] def __instancecheck__(self, obj): raise TypeError(f"{self} cannot be used with isinstance()") def __subclasscheck__(self, cls): raise TypeError(f"{self} cannot be used with issubclass()") @_tp_cache def __getitem__(self, parameters): return self._getitem(self, parameters) class _LiteralSpecialForm(_SpecialForm, _root=True): def __getitem__(self, parameters): if not isinstance(parameters, tuple): parameters = (parameters,) return self._getitem(self, *parameters) class _AnyMeta(type): def __instancecheck__(self, obj): if self is Any: raise TypeError("typing.Any cannot be used with isinstance()") return super().__instancecheck__(obj) def __repr__(self): return "typing.Any" class Any(metaclass=_AnyMeta): """Special type indicating an unconstrained type. - Any is compatible with every type. - Any assumed to have all methods. - All values assumed to be instances of Any. Note that all the above statements are true from the point of view of static type checkers. At runtime, Any should not be used with instance checks. """ def __new__(cls, *args, **kwargs): if cls is Any: raise TypeError("Any cannot be instantiated") return super().__new__(cls, *args, **kwargs) @_SpecialForm def NoReturn(self, parameters): """Special type indicating functions that never return. Example:: from typing import NoReturn def stop() -> NoReturn: raise Exception('no way') NoReturn can also be used as a bottom type, a type that has no values. Starting in Python 3.11, the Never type should be used for this concept instead. Type checkers should treat the two equivalently. """ raise TypeError(f"{self} is not subscriptable") # This is semantically identical to NoReturn, but it is implemented # separately so that type checkers can distinguish between the two # if they want. @_SpecialForm def Never(self, parameters): """The bottom type, a type that has no members. This can be used to define a function that should never be called, or a function that never returns:: from typing import Never def never_call_me(arg: Never) -> None: pass def int_or_str(arg: int | str) -> None: never_call_me(arg) # type checker error match arg: case int(): print("It's an int") case str(): print("It's a str") case _: never_call_me(arg) # ok, arg is of type Never """ raise TypeError(f"{self} is not subscriptable") @_SpecialForm def Self(self, parameters): """Used to spell the type of "self" in classes. Example:: from typing import Self class Foo: def returns_self(self) -> Self: ... return self This is especially useful for: - classmethods that are used as alternative constructors - annotating an `__enter__` method which returns self """ raise TypeError(f"{self} is not subscriptable") @_SpecialForm def LiteralString(self, parameters): """Represents an arbitrary literal string. Example:: from typing import LiteralString def run_query(sql: LiteralString) -> ... ... def caller(arbitrary_string: str, literal_string: LiteralString) -> None: run_query("SELECT * FROM students") # ok run_query(literal_string) # ok run_query("SELECT * FROM " + literal_string) # ok run_query(arbitrary_string) # type checker error run_query( # type checker error f"SELECT * FROM students WHERE name = {arbitrary_string}" ) Only string literals and other LiteralStrings are compatible with LiteralString. This provides a tool to help prevent security issues such as SQL injection. """ raise TypeError(f"{self} is not subscriptable") @_SpecialForm def ClassVar(self, parameters): """Special type construct to mark class variables. An annotation wrapped in ClassVar indicates that a given attribute is intended to be used as a class variable and should not be set on instances of that class. Usage:: class Starship: stats: ClassVar[Dict[str, int]] = {} # class variable damage: int = 10 # instance variable ClassVar accepts only types and cannot be further subscribed. Note that ClassVar is not a class itself, and should not be used with isinstance() or issubclass(). """ item = _type_check(parameters, f'{self} accepts only single type.') return _GenericAlias(self, (item,)) @_SpecialForm def Final(self, parameters): """Special typing construct to indicate final names to type checkers. A final name cannot be re-assigned or overridden in a subclass. For example: MAX_SIZE: Final = 9000 MAX_SIZE += 1 # Error reported by type checker class Connection: TIMEOUT: Final[int] = 10 class FastConnector(Connection): TIMEOUT = 1 # Error reported by type checker There is no runtime checking of these properties. """ item = _type_check(parameters, f'{self} accepts only single type.') return _GenericAlias(self, (item,)) @_SpecialForm def Union(self, parameters): """Union type; Union[X, Y] means either X or Y. To define a union, use e.g. Union[int, str]. Details: - The arguments must be types and there must be at least one. - None as an argument is a special case and is replaced by type(None). - Unions of unions are flattened, e.g.:: Union[Union[int, str], float] == Union[int, str, float] - Unions of a single argument vanish, e.g.:: Union[int] == int # The constructor actually returns int - Redundant arguments are skipped, e.g.:: Union[int, str, int] == Union[int, str] - When comparing unions, the argument order is ignored, e.g.:: Union[int, str] == Union[str, int] - You cannot subclass or instantiate a union. - You can use Optional[X] as a shorthand for Union[X, None]. """ if parameters == (): raise TypeError("Cannot take a Union of no types.") if not isinstance(parameters, tuple): parameters = (parameters,) msg = "Union[arg, ...]: each arg must be a type." parameters = tuple(_type_check(p, msg) for p in parameters) parameters = _remove_dups_flatten(parameters) if len(parameters) == 1: return parameters[0] if len(parameters) == 2 and type(None) in parameters: return _UnionGenericAlias(self, parameters, name="Optional") return _UnionGenericAlias(self, parameters) @_SpecialForm def Optional(self, parameters): """Optional type. Optional[X] is equivalent to Union[X, None]. """ arg = _type_check(parameters, f"{self} requires a single type.") return Union[arg, type(None)] @_LiteralSpecialForm @_tp_cache(typed=True) def Literal(self, *parameters): """Special typing form to define literal types (a.k.a. value types). This form can be used to indicate to type checkers that the corresponding variable or function parameter has a value equivalent to the provided literal (or one of several literals): def validate_simple(data: Any) -> Literal[True]: # always returns True ... MODE = Literal['r', 'rb', 'w', 'wb'] def open_helper(file: str, mode: MODE) -> str: ... open_helper('/some/path', 'r') # Passes type check open_helper('/other/path', 'typo') # Error in type checker Literal[...] cannot be subclassed. At runtime, an arbitrary value is allowed as type argument to Literal[...], but type checkers may impose restrictions. """ # There is no '_type_check' call because arguments to Literal[...] are # values, not types. parameters = _flatten_literal_params(parameters) try: parameters = tuple(p for p, _ in _deduplicate(list(_value_and_type_iter(parameters)))) except TypeError: # unhashable parameters pass return _LiteralGenericAlias(self, parameters) @_SpecialForm def TypeAlias(self, parameters): """Special marker indicating that an assignment should be recognized as a proper type alias definition by type checkers. For example:: Predicate: TypeAlias = Callable[..., bool] It's invalid when used anywhere except as in the example above. """ raise TypeError(f"{self} is not subscriptable") @_SpecialForm def Concatenate(self, parameters): """Used in conjunction with ``ParamSpec`` and ``Callable`` to represent a higher order function which adds, removes or transforms parameters of a callable. For example:: Callable[Concatenate[int, P], int] See PEP 612 for detailed information. """ if parameters == (): raise TypeError("Cannot take a Concatenate of no types.") if not isinstance(parameters, tuple): parameters = (parameters,) if not (parameters[-1] is ... or isinstance(parameters[-1], ParamSpec)): raise TypeError("The last parameter to Concatenate should be a " "ParamSpec variable or ellipsis.") msg = "Concatenate[arg, ...]: each arg must be a type." parameters = (*(_type_check(p, msg) for p in parameters[:-1]), parameters[-1]) return _ConcatenateGenericAlias(self, parameters, _paramspec_tvars=True) @_SpecialForm def TypeGuard(self, parameters): """Special typing form used to annotate the return type of a user-defined type guard function. ``TypeGuard`` only accepts a single type argument. At runtime, functions marked this way should return a boolean. ``TypeGuard`` aims to benefit *type narrowing* -- a technique used by static type checkers to determine a more precise type of an expression within a program's code flow. Usually type narrowing is done by analyzing conditional code flow and applying the narrowing to a block of code. The conditional expression here is sometimes referred to as a "type guard". Sometimes it would be convenient to use a user-defined boolean function as a type guard. Such a function should use ``TypeGuard[...]`` as its return type to alert static type checkers to this intention. Using ``-> TypeGuard`` tells the static type checker that for a given function: 1. The return value is a boolean. 2. If the return value is ``True``, the type of its argument is the type inside ``TypeGuard``. For example:: def is_str(val: Union[str, float]): # "isinstance" type guard if isinstance(val, str): # Type of ``val`` is narrowed to ``str`` ... else: # Else, type of ``val`` is narrowed to ``float``. ... Strict type narrowing is not enforced -- ``TypeB`` need not be a narrower form of ``TypeA`` (it can even be a wider form) and this may lead to type-unsafe results. The main reason is to allow for things like narrowing ``List[object]`` to ``List[str]`` even though the latter is not a subtype of the former, since ``List`` is invariant. The responsibility of writing type-safe type guards is left to the user. ``TypeGuard`` also works with type variables. For more information, see PEP 647 (User-Defined Type Guards). """ item = _type_check(parameters, f'{self} accepts only single type.') return _GenericAlias(self, (item,)) class ForwardRef(_Final, _root=True): """Internal wrapper to hold a forward reference.""" __slots__ = ('__forward_arg__', '__forward_code__', '__forward_evaluated__', '__forward_value__', '__forward_is_argument__', '__forward_is_class__', '__forward_module__') def __init__(self, arg, is_argument=True, module=None, *, is_class=False): if not isinstance(arg, str): raise TypeError(f"Forward reference must be a string -- got {arg!r}") # If we do `def f(*args: *Ts)`, then we'll have `arg = '*Ts'`. # Unfortunately, this isn't a valid expression on its own, so we # do the unpacking manually. if arg[0] == '*': arg_to_compile = f'({arg},)[0]' # E.g. (*Ts,)[0] else: arg_to_compile = arg try: code = compile(arg_to_compile, '', 'eval') except SyntaxError: raise SyntaxError(f"Forward reference must be an expression -- got {arg!r}") self.__forward_arg__ = arg self.__forward_code__ = code self.__forward_evaluated__ = False self.__forward_value__ = None self.__forward_is_argument__ = is_argument self.__forward_is_class__ = is_class self.__forward_module__ = module def _evaluate(self, globalns, localns, recursive_guard): if self.__forward_arg__ in recursive_guard: return self if not self.__forward_evaluated__ or localns is not globalns: if globalns is None and localns is None: globalns = localns = {} elif globalns is None: globalns = localns elif localns is None: localns = globalns if self.__forward_module__ is not None: globalns = getattr( sys.modules.get(self.__forward_module__, None), '__dict__', globalns ) type_ = _type_check( eval(self.__forward_code__, globalns, localns), "Forward references must evaluate to types.", is_argument=self.__forward_is_argument__, allow_special_forms=self.__forward_is_class__, ) self.__forward_value__ = _eval_type( type_, globalns, localns, recursive_guard | {self.__forward_arg__} ) self.__forward_evaluated__ = True return self.__forward_value__ def __eq__(self, other): if not isinstance(other, ForwardRef): return NotImplemented if self.__forward_evaluated__ and other.__forward_evaluated__: return (self.__forward_arg__ == other.__forward_arg__ and self.__forward_value__ == other.__forward_value__) return (self.__forward_arg__ == other.__forward_arg__ and self.__forward_module__ == other.__forward_module__) def __hash__(self): return hash((self.__forward_arg__, self.__forward_module__)) def __or__(self, other): return Union[self, other] def __ror__(self, other): return Union[other, self] def __repr__(self): if self.__forward_module__ is None: module_repr = '' else: module_repr = f', module={self.__forward_module__!r}' return f'ForwardRef({self.__forward_arg__!r}{module_repr})' def _is_unpacked_typevartuple(x: Any) -> bool: return ( isinstance(x, _UnpackGenericAlias) # If x is Unpack[tuple[...]], __parameters__ will be empty. and x.__parameters__ and isinstance(x.__parameters__[0], TypeVarTuple) ) def _is_typevar_like(x: Any) -> bool: return isinstance(x, (TypeVar, ParamSpec)) or _is_unpacked_typevartuple(x) class _PickleUsingNameMixin: """Mixin enabling pickling based on self.__name__.""" def __reduce__(self): return self.__name__ class _BoundVarianceMixin: """Mixin giving __init__ bound and variance arguments. This is used by TypeVar and ParamSpec, which both employ the notions of a type 'bound' (restricting type arguments to be a subtype of some specified type) and type 'variance' (determining subtype relations between generic types). """ def __init__(self, bound, covariant, contravariant): """Used to setup TypeVars and ParamSpec's bound, covariant and contravariant attributes. """ if covariant and contravariant: raise ValueError("Bivariant types are not supported.") self.__covariant__ = bool(covariant) self.__contravariant__ = bool(contravariant) if bound: self.__bound__ = _type_check(bound, "Bound must be a type.") else: self.__bound__ = None def __or__(self, right): return Union[self, right] def __ror__(self, left): return Union[left, self] def __repr__(self): if self.__covariant__: prefix = '+' elif self.__contravariant__: prefix = '-' else: prefix = '~' return prefix + self.__name__ class TypeVar(_Final, _Immutable, _BoundVarianceMixin, _PickleUsingNameMixin, _root=True): """Type variable. Usage:: T = TypeVar('T') # Can be anything A = TypeVar('A', str, bytes) # Must be str or bytes Type variables exist primarily for the benefit of static type checkers. They serve as the parameters for generic types as well as for generic function definitions. See class Generic for more information on generic types. Generic functions work as follows: def repeat(x: T, n: int) -> List[T]: '''Return a list containing n references to x.''' return [x]*n def longest(x: A, y: A) -> A: '''Return the longest of two strings.''' return x if len(x) >= len(y) else y The latter example's signature is essentially the overloading of (str, str) -> str and (bytes, bytes) -> bytes. Also note that if the arguments are instances of some subclass of str, the return type is still plain str. At runtime, isinstance(x, T) and issubclass(C, T) will raise TypeError. Type variables defined with covariant=True or contravariant=True can be used to declare covariant or contravariant generic types. See PEP 484 for more details. By default generic types are invariant in all type variables. Type variables can be introspected. e.g.: T.__name__ == 'T' T.__constraints__ == () T.__covariant__ == False T.__contravariant__ = False A.__constraints__ == (str, bytes) Note that only type variables defined in global scope can be pickled. """ def __init__(self, name, *constraints, bound=None, covariant=False, contravariant=False): self.__name__ = name super().__init__(bound, covariant, contravariant) if constraints and bound is not None: raise TypeError("Constraints cannot be combined with bound=...") if constraints and len(constraints) == 1: raise TypeError("A single constraint is not allowed") msg = "TypeVar(name, constraint, ...): constraints must be types." self.__constraints__ = tuple(_type_check(t, msg) for t in constraints) def_mod = _caller() if def_mod != 'typing': self.__module__ = def_mod def __typing_subst__(self, arg): msg = "Parameters to generic types must be types." arg = _type_check(arg, msg, is_argument=True) if (isinstance(arg, _GenericAlias) and arg.__origin__ is Unpack): raise TypeError(f"{arg} is not valid as type argument") return arg class TypeVarTuple(_Final, _Immutable, _PickleUsingNameMixin, _root=True): """Type variable tuple. Usage: Ts = TypeVarTuple('Ts') # Can be given any name Just as a TypeVar (type variable) is a placeholder for a single type, a TypeVarTuple is a placeholder for an *arbitrary* number of types. For example, if we define a generic class using a TypeVarTuple: class C(Generic[*Ts]): ... Then we can parameterize that class with an arbitrary number of type arguments: C[int] # Fine C[int, str] # Also fine C[()] # Even this is fine For more details, see PEP 646. Note that only TypeVarTuples defined in global scope can be pickled. """ def __init__(self, name): self.__name__ = name # Used for pickling. def_mod = _caller() if def_mod != 'typing': self.__module__ = def_mod def __iter__(self): yield Unpack[self] def __repr__(self): return self.__name__ def __typing_subst__(self, arg): raise TypeError("Substitution of bare TypeVarTuple is not supported") class ParamSpecArgs(_Final, _Immutable, _root=True): """The args for a ParamSpec object. Given a ParamSpec object P, P.args is an instance of ParamSpecArgs. ParamSpecArgs objects have a reference back to their ParamSpec: P.args.__origin__ is P This type is meant for runtime introspection and has no special meaning to static type checkers. """ def __init__(self, origin): self.__origin__ = origin def __repr__(self): return f"{self.__origin__.__name__}.args" def __eq__(self, other): if not isinstance(other, ParamSpecArgs): return NotImplemented return self.__origin__ == other.__origin__ class ParamSpecKwargs(_Final, _Immutable, _root=True): """The kwargs for a ParamSpec object. Given a ParamSpec object P, P.kwargs is an instance of ParamSpecKwargs. ParamSpecKwargs objects have a reference back to their ParamSpec: P.kwargs.__origin__ is P This type is meant for runtime introspection and has no special meaning to static type checkers. """ def __init__(self, origin): self.__origin__ = origin def __repr__(self): return f"{self.__origin__.__name__}.kwargs" def __eq__(self, other): if not isinstance(other, ParamSpecKwargs): return NotImplemented return self.__origin__ == other.__origin__ class ParamSpec(_Final, _Immutable, _BoundVarianceMixin, _PickleUsingNameMixin, _root=True): """Parameter specification variable. Usage:: P = ParamSpec('P') Parameter specification variables exist primarily for the benefit of static type checkers. They are used to forward the parameter types of one callable to another callable, a pattern commonly found in higher order functions and decorators. They are only valid when used in ``Concatenate``, or as the first argument to ``Callable``, or as parameters for user-defined Generics. See class Generic for more information on generic types. An example for annotating a decorator:: T = TypeVar('T') P = ParamSpec('P') def add_logging(f: Callable[P, T]) -> Callable[P, T]: '''A type-safe decorator to add logging to a function.''' def inner(*args: P.args, **kwargs: P.kwargs) -> T: logging.info(f'{f.__name__} was called') return f(*args, **kwargs) return inner @add_logging def add_two(x: float, y: float) -> float: '''Add two numbers together.''' return x + y Parameter specification variables defined with covariant=True or contravariant=True can be used to declare covariant or contravariant generic types. These keyword arguments are valid, but their actual semantics are yet to be decided. See PEP 612 for details. Parameter specification variables can be introspected. e.g.: P.__name__ == 'T' P.__bound__ == None P.__covariant__ == False P.__contravariant__ == False Note that only parameter specification variables defined in global scope can be pickled. """ @property def args(self): return ParamSpecArgs(self) @property def kwargs(self): return ParamSpecKwargs(self) def __init__(self, name, *, bound=None, covariant=False, contravariant=False): self.__name__ = name super().__init__(bound, covariant, contravariant) def_mod = _caller() if def_mod != 'typing': self.__module__ = def_mod def __typing_subst__(self, arg): if isinstance(arg, (list, tuple)): arg = tuple(_type_check(a, "Expected a type.") for a in arg) elif not _is_param_expr(arg): raise TypeError(f"Expected a list of types, an ellipsis, " f"ParamSpec, or Concatenate. Got {arg}") return arg def _is_dunder(attr): return attr.startswith('__') and attr.endswith('__') class _BaseGenericAlias(_Final, _root=True): """The central part of internal API. This represents a generic version of type 'origin' with type arguments 'params'. There are two kind of these aliases: user defined and special. The special ones are wrappers around builtin collections and ABCs in collections.abc. These must have 'name' always set. If 'inst' is False, then the alias can't be instantiated, this is used by e.g. typing.List and typing.Dict. """ def __init__(self, origin, *, inst=True, name=None): self._inst = inst self._name = name self.__origin__ = origin self.__slots__ = None # This is not documented. def __call__(self, *args, **kwargs): if not self._inst: raise TypeError(f"Type {self._name} cannot be instantiated; " f"use {self.__origin__.__name__}() instead") result = self.__origin__(*args, **kwargs) try: result.__orig_class__ = self except AttributeError: pass return result def __mro_entries__(self, bases): res = [] if self.__origin__ not in bases: res.append(self.__origin__) i = bases.index(self) for b in bases[i+1:]: if isinstance(b, _BaseGenericAlias) or issubclass(b, Generic): break else: res.append(Generic) return tuple(res) def __getattr__(self, attr): if attr in {'__name__', '__qualname__'}: return self._name or self.__origin__.__name__ # We are careful for copy and pickle. # Also for simplicity we don't relay any dunder names if '__origin__' in self.__dict__ and not _is_dunder(attr): return getattr(self.__origin__, attr) raise AttributeError(attr) def __setattr__(self, attr, val): if _is_dunder(attr) or attr in {'_name', '_inst', '_nparams', '_paramspec_tvars'}: super().__setattr__(attr, val) else: setattr(self.__origin__, attr, val) def __instancecheck__(self, obj): return self.__subclasscheck__(type(obj)) def __subclasscheck__(self, cls): raise TypeError("Subscripted generics cannot be used with" " class and instance checks") def __dir__(self): return list(set(super().__dir__() + [attr for attr in dir(self.__origin__) if not _is_dunder(attr)])) def _is_unpacked_tuple(x: Any) -> bool: # Is `x` something like `*tuple[int]` or `*tuple[int, ...]`? if not isinstance(x, _UnpackGenericAlias): return False # Alright, `x` is `Unpack[something]`. # `x` will always have `__args__`, because Unpack[] and Unpack[()] # aren't legal. unpacked_type = x.__args__[0] return getattr(unpacked_type, '__origin__', None) is tuple def _is_unpacked_arbitrary_length_tuple(x: Any) -> bool: if not _is_unpacked_tuple(x): return False unpacked_tuple = x.__args__[0] if not hasattr(unpacked_tuple, '__args__'): # It's `Unpack[tuple]`. We can't make any assumptions about the length # of the tuple, so it's effectively an arbitrary-length tuple. return True tuple_args = unpacked_tuple.__args__ if not tuple_args: # It's `Unpack[tuple[()]]`. return False last_arg = tuple_args[-1] if last_arg is Ellipsis: # It's `Unpack[tuple[something, ...]]`, which is arbitrary-length. return True # If the arguments didn't end with an ellipsis, then it's not an # arbitrary-length tuple. return False # Special typing constructs Union, Optional, Generic, Callable and Tuple # use three special attributes for internal bookkeeping of generic types: # * __parameters__ is a tuple of unique free type parameters of a generic # type, for example, Dict[T, T].__parameters__ == (T,); # * __origin__ keeps a reference to a type that was subscripted, # e.g., Union[T, int].__origin__ == Union, or the non-generic version of # the type. # * __args__ is a tuple of all arguments used in subscripting, # e.g., Dict[T, int].__args__ == (T, int). class _GenericAlias(_BaseGenericAlias, _root=True): # The type of parameterized generics. # # That is, for example, `type(List[int])` is `_GenericAlias`. # # Objects which are instances of this class include: # * Parameterized container types, e.g. `Tuple[int]`, `List[int]`. # * Note that native container types, e.g. `tuple`, `list`, use # `types.GenericAlias` instead. # * Parameterized classes: # T = TypeVar('T') # class C(Generic[T]): pass # # C[int] is a _GenericAlias # * `Callable` aliases, generic `Callable` aliases, and # parameterized `Callable` aliases: # T = TypeVar('T') # # _CallableGenericAlias inherits from _GenericAlias. # A = Callable[[], None] # _CallableGenericAlias # B = Callable[[T], None] # _CallableGenericAlias # C = B[int] # _CallableGenericAlias # * Parameterized `Final`, `ClassVar` and `TypeGuard`: # # All _GenericAlias # Final[int] # ClassVar[float] # TypeVar[bool] def __init__(self, origin, args, *, inst=True, name=None, _paramspec_tvars=False): super().__init__(origin, inst=inst, name=name) if not isinstance(args, tuple): args = (args,) self.__args__ = tuple(... if a is _TypingEllipsis else a for a in args) self.__parameters__ = _collect_parameters(args) self._paramspec_tvars = _paramspec_tvars if not name: self.__module__ = origin.__module__ def __eq__(self, other): if not isinstance(other, _GenericAlias): return NotImplemented return (self.__origin__ == other.__origin__ and self.__args__ == other.__args__) def __hash__(self): return hash((self.__origin__, self.__args__)) def __or__(self, right): return Union[self, right] def __ror__(self, left): return Union[left, self] @_tp_cache def __getitem__(self, args): # Parameterizes an already-parameterized object. # # For example, we arrive here doing something like: # T1 = TypeVar('T1') # T2 = TypeVar('T2') # T3 = TypeVar('T3') # class A(Generic[T1]): pass # B = A[T2] # B is a _GenericAlias # C = B[T3] # Invokes _GenericAlias.__getitem__ # # We also arrive here when parameterizing a generic `Callable` alias: # T = TypeVar('T') # C = Callable[[T], None] # C[int] # Invokes _GenericAlias.__getitem__ if self.__origin__ in (Generic, Protocol): # Can't subscript Generic[...] or Protocol[...]. raise TypeError(f"Cannot subscript already-subscripted {self}") # Preprocess `args`. if not isinstance(args, tuple): args = (args,) args = tuple(_type_convert(p) for p in args) if (self._paramspec_tvars and any(isinstance(t, ParamSpec) for t in self.__parameters__)): args = _prepare_paramspec_params(self, args) elif not any(isinstance(p, TypeVarTuple) for p in self.__parameters__): # We only run this if there are no TypeVarTuples, because we # don't check variadic generic arity at runtime (to reduce # complexity of typing.py). _check_generic(self, args, len(self.__parameters__)) new_args = self._determine_new_args(args) r = self.copy_with(new_args) return r def _determine_new_args(self, args): # Determines new __args__ for __getitem__. # # For example, suppose we had: # T1 = TypeVar('T1') # T2 = TypeVar('T2') # class A(Generic[T1, T2]): pass # T3 = TypeVar('T3') # B = A[int, T3] # C = B[str] # `B.__args__` is `(int, T3)`, so `C.__args__` should be `(int, str)`. # Unfortunately, this is harder than it looks, because if `T3` is # anything more exotic than a plain `TypeVar`, we need to consider # edge cases. params = self.__parameters__ # In the example above, this would be {T3: str} new_arg_by_param = {} for i, param in enumerate(params): if isinstance(param, TypeVarTuple): j = len(args) - (len(params) - i - 1) if j < i: raise TypeError(f"Too few arguments for {self}") new_arg_by_param.update(zip(params[:i], args[:i])) new_arg_by_param[param] = args[i: j] new_arg_by_param.update(zip(params[i + 1:], args[j:])) break else: new_arg_by_param.update(zip(params, args)) new_args = [] for old_arg in self.__args__: substfunc = getattr(old_arg, '__typing_subst__', None) if substfunc: new_arg = substfunc(new_arg_by_param[old_arg]) else: subparams = getattr(old_arg, '__parameters__', ()) if not subparams: new_arg = old_arg else: subargs = [] for x in subparams: if isinstance(x, TypeVarTuple): subargs.extend(new_arg_by_param[x]) else: subargs.append(new_arg_by_param[x]) new_arg = old_arg[tuple(subargs)] if self.__origin__ == collections.abc.Callable and isinstance(new_arg, tuple): # Consider the following `Callable`. # C = Callable[[int], str] # Here, `C.__args__` should be (int, str) - NOT ([int], str). # That means that if we had something like... # P = ParamSpec('P') # T = TypeVar('T') # C = Callable[P, T] # D = C[[int, str], float] # ...we need to be careful; `new_args` should end up as # `(int, str, float)` rather than `([int, str], float)`. new_args.extend(new_arg) elif _is_unpacked_typevartuple(old_arg): # Consider the following `_GenericAlias`, `B`: # class A(Generic[*Ts]): ... # B = A[T, *Ts] # If we then do: # B[float, int, str] # The `new_arg` corresponding to `T` will be `float`, and the # `new_arg` corresponding to `*Ts` will be `(int, str)`. We # should join all these types together in a flat list # `(float, int, str)` - so again, we should `extend`. new_args.extend(new_arg) else: new_args.append(new_arg) return tuple(new_args) def copy_with(self, args): return self.__class__(self.__origin__, args, name=self._name, inst=self._inst, _paramspec_tvars=self._paramspec_tvars) def __repr__(self): if self._name: name = 'typing.' + self._name else: name = _type_repr(self.__origin__) if self.__args__: args = ", ".join([_type_repr(a) for a in self.__args__]) else: # To ensure the repr is eval-able. args = "()" return f'{name}[{args}]' def __reduce__(self): if self._name: origin = globals()[self._name] else: origin = self.__origin__ args = tuple(self.__args__) if len(args) == 1 and not isinstance(args[0], tuple): args, = args return operator.getitem, (origin, args) def __mro_entries__(self, bases): if isinstance(self.__origin__, _SpecialForm): raise TypeError(f"Cannot subclass {self!r}") if self._name: # generic version of an ABC or built-in class return super().__mro_entries__(bases) if self.__origin__ is Generic: if Protocol in bases: return () i = bases.index(self) for b in bases[i+1:]: if isinstance(b, _BaseGenericAlias) and b is not self: return () return (self.__origin__,) def __iter__(self): yield Unpack[self] # _nparams is the number of accepted parameters, e.g. 0 for Hashable, # 1 for List and 2 for Dict. It may be -1 if variable number of # parameters are accepted (needs custom __getitem__). class _SpecialGenericAlias(_NotIterable, _BaseGenericAlias, _root=True): def __init__(self, origin, nparams, *, inst=True, name=None): if name is None: name = origin.__name__ super().__init__(origin, inst=inst, name=name) self._nparams = nparams if origin.__module__ == 'builtins': self.__doc__ = f'A generic version of {origin.__qualname__}.' else: self.__doc__ = f'A generic version of {origin.__module__}.{origin.__qualname__}.' @_tp_cache def __getitem__(self, params): if not isinstance(params, tuple): params = (params,) msg = "Parameters to generic types must be types." params = tuple(_type_check(p, msg) for p in params) _check_generic(self, params, self._nparams) return self.copy_with(params) def copy_with(self, params): return _GenericAlias(self.__origin__, params, name=self._name, inst=self._inst) def __repr__(self): return 'typing.' + self._name def __subclasscheck__(self, cls): if isinstance(cls, _SpecialGenericAlias): return issubclass(cls.__origin__, self.__origin__) if not isinstance(cls, _GenericAlias): return issubclass(cls, self.__origin__) return super().__subclasscheck__(cls) def __reduce__(self): return self._name def __or__(self, right): return Union[self, right] def __ror__(self, left): return Union[left, self] class _CallableGenericAlias(_NotIterable, _GenericAlias, _root=True): def __repr__(self): assert self._name == 'Callable' args = self.__args__ if len(args) == 2 and _is_param_expr(args[0]): return super().__repr__() return (f'typing.Callable' f'[[{", ".join([_type_repr(a) for a in args[:-1]])}], ' f'{_type_repr(args[-1])}]') def __reduce__(self): args = self.__args__ if not (len(args) == 2 and _is_param_expr(args[0])): args = list(args[:-1]), args[-1] return operator.getitem, (Callable, args) class _CallableType(_SpecialGenericAlias, _root=True): def copy_with(self, params): return _CallableGenericAlias(self.__origin__, params, name=self._name, inst=self._inst, _paramspec_tvars=True) def __getitem__(self, params): if not isinstance(params, tuple) or len(params) != 2: raise TypeError("Callable must be used as " "Callable[[arg, ...], result].") args, result = params # This relaxes what args can be on purpose to allow things like # PEP 612 ParamSpec. Responsibility for whether a user is using # Callable[...] properly is deferred to static type checkers. if isinstance(args, list): params = (tuple(args), result) else: params = (args, result) return self.__getitem_inner__(params) @_tp_cache def __getitem_inner__(self, params): args, result = params msg = "Callable[args, result]: result must be a type." result = _type_check(result, msg) if args is Ellipsis: return self.copy_with((_TypingEllipsis, result)) if not isinstance(args, tuple): args = (args,) args = tuple(_type_convert(arg) for arg in args) params = args + (result,) return self.copy_with(params) class _TupleType(_SpecialGenericAlias, _root=True): @_tp_cache def __getitem__(self, params): if not isinstance(params, tuple): params = (params,) if len(params) >= 2 and params[-1] is ...: msg = "Tuple[t, ...]: t must be a type." params = tuple(_type_check(p, msg) for p in params[:-1]) return self.copy_with((*params, _TypingEllipsis)) msg = "Tuple[t0, t1, ...]: each t must be a type." params = tuple(_type_check(p, msg) for p in params) return self.copy_with(params) class _UnionGenericAlias(_NotIterable, _GenericAlias, _root=True): def copy_with(self, params): return Union[params] def __eq__(self, other): if not isinstance(other, (_UnionGenericAlias, types.UnionType)): return NotImplemented return set(self.__args__) == set(other.__args__) def __hash__(self): return hash(frozenset(self.__args__)) def __repr__(self): args = self.__args__ if len(args) == 2: if args[0] is type(None): return f'typing.Optional[{_type_repr(args[1])}]' elif args[1] is type(None): return f'typing.Optional[{_type_repr(args[0])}]' return super().__repr__() def __instancecheck__(self, obj): return self.__subclasscheck__(type(obj)) def __subclasscheck__(self, cls): for arg in self.__args__: if issubclass(cls, arg): return True def __reduce__(self): func, (origin, args) = super().__reduce__() return func, (Union, args) def _value_and_type_iter(parameters): return ((p, type(p)) for p in parameters) class _LiteralGenericAlias(_GenericAlias, _root=True): def __eq__(self, other): if not isinstance(other, _LiteralGenericAlias): return NotImplemented return set(_value_and_type_iter(self.__args__)) == set(_value_and_type_iter(other.__args__)) def __hash__(self): return hash(frozenset(_value_and_type_iter(self.__args__))) class _ConcatenateGenericAlias(_GenericAlias, _root=True): def copy_with(self, params): if isinstance(params[-1], (list, tuple)): return (*params[:-1], *params[-1]) if isinstance(params[-1], _ConcatenateGenericAlias): params = (*params[:-1], *params[-1].__args__) return super().copy_with(params) @_SpecialForm def Unpack(self, parameters): """Type unpack operator. The type unpack operator takes the child types from some container type, such as `tuple[int, str]` or a `TypeVarTuple`, and 'pulls them out'. For example: # For some generic class `Foo`: Foo[Unpack[tuple[int, str]]] # Equivalent to Foo[int, str] Ts = TypeVarTuple('Ts') # Specifies that `Bar` is generic in an arbitrary number of types. # (Think of `Ts` as a tuple of an arbitrary number of individual # `TypeVar`s, which the `Unpack` is 'pulling out' directly into the # `Generic[]`.) class Bar(Generic[Unpack[Ts]]): ... Bar[int] # Valid Bar[int, str] # Also valid From Python 3.11, this can also be done using the `*` operator: Foo[*tuple[int, str]] class Bar(Generic[*Ts]): ... Note that there is only some runtime checking of this operator. Not everything the runtime allows may be accepted by static type checkers. For more information, see PEP 646. """ item = _type_check(parameters, f'{self} accepts only single type.') return _UnpackGenericAlias(origin=self, args=(item,)) class _UnpackGenericAlias(_GenericAlias, _root=True): def __repr__(self): # `Unpack` only takes one argument, so __args__ should contain only # a single item. return '*' + repr(self.__args__[0]) def __getitem__(self, args): if self.__typing_unpacked__(): return args return super().__getitem__(args) def __typing_unpacked__(self): # If x is Unpack[tuple[...]], __parameters__ will be empty. return bool(self.__parameters__ and isinstance(self.__parameters__[0], TypeVarTuple)) class Generic: """Abstract base class for generic types. A generic type is typically declared by inheriting from this class parameterized with one or more type variables. For example, a generic mapping type might be defined as:: class Mapping(Generic[KT, VT]): def __getitem__(self, key: KT) -> VT: ... # Etc. This class can then be used as follows:: def lookup_name(mapping: Mapping[KT, VT], key: KT, default: VT) -> VT: try: return mapping[key] except KeyError: return default """ __slots__ = () _is_protocol = False @_tp_cache def __class_getitem__(cls, params): """Parameterizes a generic class. At least, parameterizing a generic class is the *main* thing this method does. For example, for some generic class `Foo`, this is called when we do `Foo[int]` - there, with `cls=Foo` and `params=int`. However, note that this method is also called when defining generic classes in the first place with `class Foo(Generic[T]): ...`. """ if not isinstance(params, tuple): params = (params,) if not params: # We're only ok with `params` being empty if the class's only type # parameter is a `TypeVarTuple` (which can contain zero types). class_params = getattr(cls, "__parameters__", None) only_class_parameter_is_typevartuple = ( class_params is not None and len(class_params) == 1 and isinstance(class_params[0], TypeVarTuple) ) if not only_class_parameter_is_typevartuple: raise TypeError( f"Parameter list to {cls.__qualname__}[...] cannot be empty" ) params = tuple(_type_convert(p) for p in params) if cls in (Generic, Protocol): # Generic and Protocol can only be subscripted with unique type variables. if not all(_is_typevar_like(p) for p in params): raise TypeError( f"Parameters to {cls.__name__}[...] must all be type variables " f"or parameter specification variables.") if len(set(params)) != len(params): raise TypeError( f"Parameters to {cls.__name__}[...] must all be unique") else: # Subscripting a regular Generic subclass. if any(isinstance(t, ParamSpec) for t in cls.__parameters__): params = _prepare_paramspec_params(cls, params) elif not any(isinstance(p, TypeVarTuple) for p in cls.__parameters__): # We only run this if there are no TypeVarTuples, because we # don't check variadic generic arity at runtime (to reduce # complexity of typing.py). _check_generic(cls, params, len(cls.__parameters__)) return _GenericAlias(cls, params, _paramspec_tvars=True) def __init_subclass__(cls, *args, **kwargs): super().__init_subclass__(*args, **kwargs) tvars = [] if '__orig_bases__' in cls.__dict__: error = Generic in cls.__orig_bases__ else: error = (Generic in cls.__bases__ and cls.__name__ != 'Protocol' and type(cls) != _TypedDictMeta) if error: raise TypeError("Cannot inherit from plain Generic") if '__orig_bases__' in cls.__dict__: tvars = _collect_parameters(cls.__orig_bases__) # Look for Generic[T1, ..., Tn]. # If found, tvars must be a subset of it. # If not found, tvars is it. # Also check for and reject plain Generic, # and reject multiple Generic[...]. gvars = None for base in cls.__orig_bases__: if (isinstance(base, _GenericAlias) and base.__origin__ is Generic): if gvars is not None: raise TypeError( "Cannot inherit from Generic[...] multiple types.") gvars = base.__parameters__ if gvars is not None: tvarset = set(tvars) gvarset = set(gvars) if not tvarset <= gvarset: s_vars = ', '.join(str(t) for t in tvars if t not in gvarset) s_args = ', '.join(str(g) for g in gvars) raise TypeError(f"Some type variables ({s_vars}) are" f" not listed in Generic[{s_args}]") tvars = gvars cls.__parameters__ = tuple(tvars) class _TypingEllipsis: """Internal placeholder for ... (ellipsis).""" _TYPING_INTERNALS = ['__parameters__', '__orig_bases__', '__orig_class__', '_is_protocol', '_is_runtime_protocol'] _SPECIAL_NAMES = ['__abstractmethods__', '__annotations__', '__dict__', '__doc__', '__init__', '__module__', '__new__', '__slots__', '__subclasshook__', '__weakref__', '__class_getitem__'] # These special attributes will be not collected as protocol members. EXCLUDED_ATTRIBUTES = _TYPING_INTERNALS + _SPECIAL_NAMES + ['_MutableMapping__marker'] def _get_protocol_attrs(cls): """Collect protocol members from a protocol class objects. This includes names actually defined in the class dictionary, as well as names that appear in annotations. Special names (above) are skipped. """ attrs = set() for base in cls.__mro__[:-1]: # without object if base.__name__ in ('Protocol', 'Generic'): continue annotations = getattr(base, '__annotations__', {}) for attr in list(base.__dict__.keys()) + list(annotations.keys()): if not attr.startswith('_abc_') and attr not in EXCLUDED_ATTRIBUTES: attrs.add(attr) return attrs def _is_callable_members_only(cls): # PEP 544 prohibits using issubclass() with protocols that have non-method members. return all(callable(getattr(cls, attr, None)) for attr in _get_protocol_attrs(cls)) def _no_init_or_replace_init(self, *args, **kwargs): cls = type(self) if cls._is_protocol: raise TypeError('Protocols cannot be instantiated') # Already using a custom `__init__`. No need to calculate correct # `__init__` to call. This can lead to RecursionError. See bpo-45121. if cls.__init__ is not _no_init_or_replace_init: return # Initially, `__init__` of a protocol subclass is set to `_no_init_or_replace_init`. # The first instantiation of the subclass will call `_no_init_or_replace_init` which # searches for a proper new `__init__` in the MRO. The new `__init__` # replaces the subclass' old `__init__` (ie `_no_init_or_replace_init`). Subsequent # instantiation of the protocol subclass will thus use the new # `__init__` and no longer call `_no_init_or_replace_init`. for base in cls.__mro__: init = base.__dict__.get('__init__', _no_init_or_replace_init) if init is not _no_init_or_replace_init: cls.__init__ = init break else: # should not happen cls.__init__ = object.__init__ cls.__init__(self, *args, **kwargs) def _caller(depth=1, default='__main__'): try: return sys._getframe(depth + 1).f_globals.get('__name__', default) except (AttributeError, ValueError): # For platforms without _getframe() return None def _allow_reckless_class_checks(depth=3): """Allow instance and class checks for special stdlib modules. The abc and functools modules indiscriminately call isinstance() and issubclass() on the whole MRO of a user class, which may contain protocols. """ return _caller(depth) in {'abc', 'functools', None} _PROTO_ALLOWLIST = { 'collections.abc': [ 'Callable', 'Awaitable', 'Iterable', 'Iterator', 'AsyncIterable', 'Hashable', 'Sized', 'Container', 'Collection', 'Reversible', ], 'contextlib': ['AbstractContextManager', 'AbstractAsyncContextManager'], } class _ProtocolMeta(ABCMeta): # This metaclass is really unfortunate and exists only because of # the lack of __instancehook__. def __instancecheck__(cls, instance): # We need this method for situations where attributes are # assigned in __init__. if ( getattr(cls, '_is_protocol', False) and not getattr(cls, '_is_runtime_protocol', False) and not _allow_reckless_class_checks(depth=2) ): raise TypeError("Instance and class checks can only be used with" " @runtime_checkable protocols") if ((not getattr(cls, '_is_protocol', False) or _is_callable_members_only(cls)) and issubclass(instance.__class__, cls)): return True if cls._is_protocol: if all(hasattr(instance, attr) and # All *methods* can be blocked by setting them to None. (not callable(getattr(cls, attr, None)) or getattr(instance, attr) is not None) for attr in _get_protocol_attrs(cls)): return True return super().__instancecheck__(instance) class Protocol(Generic, metaclass=_ProtocolMeta): """Base class for protocol classes. Protocol classes are defined as:: class Proto(Protocol): def meth(self) -> int: ... Such classes are primarily used with static type checkers that recognize structural subtyping (static duck-typing), for example:: class C: def meth(self) -> int: return 0 def func(x: Proto) -> int: return x.meth() func(C()) # Passes static type check See PEP 544 for details. Protocol classes decorated with @typing.runtime_checkable act as simple-minded runtime protocols that check only the presence of given attributes, ignoring their type signatures. Protocol classes can be generic, they are defined as:: class GenProto(Protocol[T]): def meth(self) -> T: ... """ __slots__ = () _is_protocol = True _is_runtime_protocol = False def __init_subclass__(cls, *args, **kwargs): super().__init_subclass__(*args, **kwargs) # Determine if this is a protocol or a concrete subclass. if not cls.__dict__.get('_is_protocol', False): cls._is_protocol = any(b is Protocol for b in cls.__bases__) # Set (or override) the protocol subclass hook. def _proto_hook(other): if not cls.__dict__.get('_is_protocol', False): return NotImplemented # First, perform various sanity checks. if not getattr(cls, '_is_runtime_protocol', False): if _allow_reckless_class_checks(): return NotImplemented raise TypeError("Instance and class checks can only be used with" " @runtime_checkable protocols") if not _is_callable_members_only(cls): if _allow_reckless_class_checks(): return NotImplemented raise TypeError("Protocols with non-method members" " don't support issubclass()") if not isinstance(other, type): # Same error message as for issubclass(1, int). raise TypeError('issubclass() arg 1 must be a class') # Second, perform the actual structural compatibility check. for attr in _get_protocol_attrs(cls): for base in other.__mro__: # Check if the members appears in the class dictionary... if attr in base.__dict__: if base.__dict__[attr] is None: return NotImplemented break # ...or in annotations, if it is a sub-protocol. annotations = getattr(base, '__annotations__', {}) if (isinstance(annotations, collections.abc.Mapping) and attr in annotations and issubclass(other, Generic) and other._is_protocol): break else: return NotImplemented return True if '__subclasshook__' not in cls.__dict__: cls.__subclasshook__ = _proto_hook # We have nothing more to do for non-protocols... if not cls._is_protocol: return # ... otherwise check consistency of bases, and prohibit instantiation. for base in cls.__bases__: if not (base in (object, Generic) or base.__module__ in _PROTO_ALLOWLIST and base.__name__ in _PROTO_ALLOWLIST[base.__module__] or issubclass(base, Generic) and base._is_protocol): raise TypeError('Protocols can only inherit from other' ' protocols, got %r' % base) if cls.__init__ is Protocol.__init__: cls.__init__ = _no_init_or_replace_init class _AnnotatedAlias(_NotIterable, _GenericAlias, _root=True): """Runtime representation of an annotated type. At its core 'Annotated[t, dec1, dec2, ...]' is an alias for the type 't' with extra annotations. The alias behaves like a normal typing alias, instantiating is the same as instantiating the underlying type, binding it to types is also the same. """ def __init__(self, origin, metadata): if isinstance(origin, _AnnotatedAlias): metadata = origin.__metadata__ + metadata origin = origin.__origin__ super().__init__(origin, origin) self.__metadata__ = metadata def copy_with(self, params): assert len(params) == 1 new_type = params[0] return _AnnotatedAlias(new_type, self.__metadata__) def __repr__(self): return "typing.Annotated[{}, {}]".format( _type_repr(self.__origin__), ", ".join(repr(a) for a in self.__metadata__) ) def __reduce__(self): return operator.getitem, ( Annotated, (self.__origin__,) + self.__metadata__ ) def __eq__(self, other): if not isinstance(other, _AnnotatedAlias): return NotImplemented return (self.__origin__ == other.__origin__ and self.__metadata__ == other.__metadata__) def __hash__(self): return hash((self.__origin__, self.__metadata__)) def __getattr__(self, attr): if attr in {'__name__', '__qualname__'}: return 'Annotated' return super().__getattr__(attr) class Annotated: """Add context specific metadata to a type. Example: Annotated[int, runtime_check.Unsigned] indicates to the hypothetical runtime_check module that this type is an unsigned int. Every other consumer of this type can ignore this metadata and treat this type as int. The first argument to Annotated must be a valid type. Details: - It's an error to call `Annotated` with less than two arguments. - Nested Annotated are flattened:: Annotated[Annotated[T, Ann1, Ann2], Ann3] == Annotated[T, Ann1, Ann2, Ann3] - Instantiating an annotated type is equivalent to instantiating the underlying type:: Annotated[C, Ann1](5) == C(5) - Annotated can be used as a generic type alias:: Optimized = Annotated[T, runtime.Optimize()] Optimized[int] == Annotated[int, runtime.Optimize()] OptimizedList = Annotated[List[T], runtime.Optimize()] OptimizedList[int] == Annotated[List[int], runtime.Optimize()] - Annotated cannot be used with an unpacked TypeVarTuple:: Annotated[*Ts, Ann1] # NOT valid This would be equivalent to Annotated[T1, T2, T3, ..., Ann1] where T1, T2 etc. are TypeVars, which would be invalid, because only one type should be passed to Annotated. """ __slots__ = () def __new__(cls, *args, **kwargs): raise TypeError("Type Annotated cannot be instantiated.") @_tp_cache def __class_getitem__(cls, params): if not isinstance(params, tuple) or len(params) < 2: raise TypeError("Annotated[...] should be used " "with at least two arguments (a type and an " "annotation).") if _is_unpacked_typevartuple(params[0]): raise TypeError("Annotated[...] should not be used with an " "unpacked TypeVarTuple") msg = "Annotated[t, ...]: t must be a type." origin = _type_check(params[0], msg, allow_special_forms=True) metadata = tuple(params[1:]) return _AnnotatedAlias(origin, metadata) def __init_subclass__(cls, *args, **kwargs): raise TypeError( "Cannot subclass {}.Annotated".format(cls.__module__) ) def runtime_checkable(cls): """Mark a protocol class as a runtime protocol. Such protocol can be used with isinstance() and issubclass(). Raise TypeError if applied to a non-protocol class. This allows a simple-minded structural check very similar to one trick ponies in collections.abc such as Iterable. For example:: @runtime_checkable class Closable(Protocol): def close(self): ... assert isinstance(open('/some/file'), Closable) Warning: this will check only the presence of the required methods, not their type signatures! """ if not issubclass(cls, Generic) or not cls._is_protocol: raise TypeError('@runtime_checkable can be only applied to protocol classes,' ' got %r' % cls) cls._is_runtime_protocol = True return cls def cast(typ, val): """Cast a value to a type. This returns the value unchanged. To the type checker this signals that the return value has the designated type, but at runtime we intentionally don't check anything (we want this to be as fast as possible). """ return val def assert_type(val, typ, /): """Ask a static type checker to confirm that the value is of the given type. When the type checker encounters a call to assert_type(), it emits an error if the value is not of the specified type:: def greet(name: str) -> None: assert_type(name, str) # ok assert_type(name, int) # type checker error At runtime this returns the first argument unchanged and otherwise does nothing. """ return val _allowed_types = (types.FunctionType, types.BuiltinFunctionType, types.MethodType, types.ModuleType, WrapperDescriptorType, MethodWrapperType, MethodDescriptorType) def get_type_hints(obj, globalns=None, localns=None, include_extras=False): """Return type hints for an object. This is often the same as obj.__annotations__, but it handles forward references encoded as string literals and recursively replaces all 'Annotated[T, ...]' with 'T' (unless 'include_extras=True'). The argument may be a module, class, method, or function. The annotations are returned as a dictionary. For classes, annotations include also inherited members. TypeError is raised if the argument is not of a type that can contain annotations, and an empty dictionary is returned if no annotations are present. BEWARE -- the behavior of globalns and localns is counterintuitive (unless you are familiar with how eval() and exec() work). The search order is locals first, then globals. - If no dict arguments are passed, an attempt is made to use the globals from obj (or the respective module's globals for classes), and these are also used as the locals. If the object does not appear to have globals, an empty dictionary is used. For classes, the search order is globals first then locals. - If one dict argument is passed, it is used for both globals and locals. - If two dict arguments are passed, they specify globals and locals, respectively. """ if getattr(obj, '__no_type_check__', None): return {} # Classes require a special treatment. if isinstance(obj, type): hints = {} for base in reversed(obj.__mro__): if globalns is None: base_globals = getattr(sys.modules.get(base.__module__, None), '__dict__', {}) else: base_globals = globalns ann = base.__dict__.get('__annotations__', {}) if isinstance(ann, types.GetSetDescriptorType): ann = {} base_locals = dict(vars(base)) if localns is None else localns if localns is None and globalns is None: # This is surprising, but required. Before Python 3.10, # get_type_hints only evaluated the globalns of # a class. To maintain backwards compatibility, we reverse # the globalns and localns order so that eval() looks into # *base_globals* first rather than *base_locals*. # This only affects ForwardRefs. base_globals, base_locals = base_locals, base_globals for name, value in ann.items(): if value is None: value = type(None) if isinstance(value, str): value = ForwardRef(value, is_argument=False, is_class=True) value = _eval_type(value, base_globals, base_locals) hints[name] = value return hints if include_extras else {k: _strip_annotations(t) for k, t in hints.items()} if globalns is None: if isinstance(obj, types.ModuleType): globalns = obj.__dict__ else: nsobj = obj # Find globalns for the unwrapped object. while hasattr(nsobj, '__wrapped__'): nsobj = nsobj.__wrapped__ globalns = getattr(nsobj, '__globals__', {}) if localns is None: localns = globalns elif localns is None: localns = globalns hints = getattr(obj, '__annotations__', None) if hints is None: # Return empty annotations for something that _could_ have them. if isinstance(obj, _allowed_types): return {} else: raise TypeError('{!r} is not a module, class, method, ' 'or function.'.format(obj)) hints = dict(hints) for name, value in hints.items(): if value is None: value = type(None) if isinstance(value, str): # class-level forward refs were handled above, this must be either # a module-level annotation or a function argument annotation value = ForwardRef( value, is_argument=not isinstance(obj, types.ModuleType), is_class=False, ) hints[name] = _eval_type(value, globalns, localns) return hints if include_extras else {k: _strip_annotations(t) for k, t in hints.items()} def _strip_annotations(t): """Strips the annotations from a given type. """ if isinstance(t, _AnnotatedAlias): return _strip_annotations(t.__origin__) if hasattr(t, "__origin__") and t.__origin__ in (Required, NotRequired): return _strip_annotations(t.__args__[0]) if isinstance(t, _GenericAlias): stripped_args = tuple(_strip_annotations(a) for a in t.__args__) if stripped_args == t.__args__: return t return t.copy_with(stripped_args) if isinstance(t, GenericAlias): stripped_args = tuple(_strip_annotations(a) for a in t.__args__) if stripped_args == t.__args__: return t return GenericAlias(t.__origin__, stripped_args) if isinstance(t, types.UnionType): stripped_args = tuple(_strip_annotations(a) for a in t.__args__) if stripped_args == t.__args__: return t return functools.reduce(operator.or_, stripped_args) return t def get_origin(tp): """Get the unsubscripted version of a type. This supports generic types, Callable, Tuple, Union, Literal, Final, ClassVar and Annotated. Return None for unsupported types. Examples:: get_origin(Literal[42]) is Literal get_origin(int) is None get_origin(ClassVar[int]) is ClassVar get_origin(Generic) is Generic get_origin(Generic[T]) is Generic get_origin(Union[T, int]) is Union get_origin(List[Tuple[T, T]][int]) == list get_origin(P.args) is P """ if isinstance(tp, _AnnotatedAlias): return Annotated if isinstance(tp, (_BaseGenericAlias, GenericAlias, ParamSpecArgs, ParamSpecKwargs)): return tp.__origin__ if tp is Generic: return Generic if isinstance(tp, types.UnionType): return types.UnionType return None def get_args(tp): """Get type arguments with all substitutions performed. For unions, basic simplifications used by Union constructor are performed. Examples:: get_args(Dict[str, int]) == (str, int) get_args(int) == () get_args(Union[int, Union[T, int], str][int]) == (int, str) get_args(Union[int, Tuple[T, int]][str]) == (int, Tuple[str, int]) get_args(Callable[[], T][int]) == ([], int) """ if isinstance(tp, _AnnotatedAlias): return (tp.__origin__,) + tp.__metadata__ if isinstance(tp, (_GenericAlias, GenericAlias)): res = tp.__args__ if _should_unflatten_callable_args(tp, res): res = (list(res[:-1]), res[-1]) return res if isinstance(tp, types.UnionType): return tp.__args__ return () def is_typeddict(tp): """Check if an annotation is a TypedDict class For example:: class Film(TypedDict): title: str year: int is_typeddict(Film) # => True is_typeddict(Union[list, str]) # => False """ return isinstance(tp, _TypedDictMeta) _ASSERT_NEVER_REPR_MAX_LENGTH = 100 def assert_never(arg: Never, /) -> Never: """Statically assert that a line of code is unreachable. Example:: def int_or_str(arg: int | str) -> None: match arg: case int(): print("It's an int") case str(): print("It's a str") case _: assert_never(arg) If a type checker finds that a call to assert_never() is reachable, it will emit an error. At runtime, this throws an exception when called. """ value = repr(arg) if len(value) > _ASSERT_NEVER_REPR_MAX_LENGTH: value = value[:_ASSERT_NEVER_REPR_MAX_LENGTH] + '...' raise AssertionError(f"Expected code to be unreachable, but got: {value}") def no_type_check(arg): """Decorator to indicate that annotations are not type hints. The argument must be a class or function; if it is a class, it applies recursively to all methods and classes defined in that class (but not to methods defined in its superclasses or subclasses). This mutates the function(s) or class(es) in place. """ if isinstance(arg, type): for key in dir(arg): obj = getattr(arg, key) if ( not hasattr(obj, '__qualname__') or obj.__qualname__ != f'{arg.__qualname__}.{obj.__name__}' or getattr(obj, '__module__', None) != arg.__module__ ): # We only modify objects that are defined in this type directly. # If classes / methods are nested in multiple layers, # we will modify them when processing their direct holders. continue # Instance, class, and static methods: if isinstance(obj, types.FunctionType): obj.__no_type_check__ = True if isinstance(obj, types.MethodType): obj.__func__.__no_type_check__ = True # Nested types: if isinstance(obj, type): no_type_check(obj) try: arg.__no_type_check__ = True except TypeError: # built-in classes pass return arg def no_type_check_decorator(decorator): """Decorator to give another decorator the @no_type_check effect. This wraps the decorator with something that wraps the decorated function in @no_type_check. """ @functools.wraps(decorator) def wrapped_decorator(*args, **kwds): func = decorator(*args, **kwds) func = no_type_check(func) return func return wrapped_decorator def _overload_dummy(*args, **kwds): """Helper for @overload to raise when called.""" raise NotImplementedError( "You should not call an overloaded function. " "A series of @overload-decorated functions " "outside a stub module should always be followed " "by an implementation that is not @overload-ed.") # {module: {qualname: {firstlineno: func}}} _overload_registry = defaultdict(functools.partial(defaultdict, dict)) def overload(func): """Decorator for overloaded functions/methods. In a stub file, place two or more stub definitions for the same function in a row, each decorated with @overload. For example: @overload def utf8(value: None) -> None: ... @overload def utf8(value: bytes) -> bytes: ... @overload def utf8(value: str) -> bytes: ... In a non-stub file (i.e. a regular .py file), do the same but follow it with an implementation. The implementation should *not* be decorated with @overload. For example: @overload def utf8(value: None) -> None: ... @overload def utf8(value: bytes) -> bytes: ... @overload def utf8(value: str) -> bytes: ... def utf8(value): # implementation goes here The overloads for a function can be retrieved at runtime using the get_overloads() function. """ # classmethod and staticmethod f = getattr(func, "__func__", func) try: _overload_registry[f.__module__][f.__qualname__][f.__code__.co_firstlineno] = func except AttributeError: # Not a normal function; ignore. pass return _overload_dummy def get_overloads(func): """Return all defined overloads for *func* as a sequence.""" # classmethod and staticmethod f = getattr(func, "__func__", func) if f.__module__ not in _overload_registry: return [] mod_dict = _overload_registry[f.__module__] if f.__qualname__ not in mod_dict: return [] return list(mod_dict[f.__qualname__].values()) def clear_overloads(): """Clear all overloads in the registry.""" _overload_registry.clear() def final(f): """A decorator to indicate final methods and final classes. Use this decorator to indicate to type checkers that the decorated method cannot be overridden, and decorated class cannot be subclassed. For example: class Base: @final def done(self) -> None: ... class Sub(Base): def done(self) -> None: # Error reported by type checker ... @final class Leaf: ... class Other(Leaf): # Error reported by type checker ... There is no runtime checking of these properties. The decorator sets the ``__final__`` attribute to ``True`` on the decorated object to allow runtime introspection. """ try: f.__final__ = True except (AttributeError, TypeError): # Skip the attribute silently if it is not writable. # AttributeError happens if the object has __slots__ or a # read-only property, TypeError if it's a builtin class. pass return f # Some unconstrained type variables. These are used by the container types. # (These are not for export.) T = TypeVar('T') # Any type. KT = TypeVar('KT') # Key type. VT = TypeVar('VT') # Value type. T_co = TypeVar('T_co', covariant=True) # Any type covariant containers. V_co = TypeVar('V_co', covariant=True) # Any type covariant containers. VT_co = TypeVar('VT_co', covariant=True) # Value type covariant containers. T_contra = TypeVar('T_contra', contravariant=True) # Ditto contravariant. # Internal type variable used for Type[]. CT_co = TypeVar('CT_co', covariant=True, bound=type) # A useful type variable with constraints. This represents string types. # (This one *is* for export!) AnyStr = TypeVar('AnyStr', bytes, str) # Various ABCs mimicking those in collections.abc. _alias = _SpecialGenericAlias Hashable = _alias(collections.abc.Hashable, 0) # Not generic. Awaitable = _alias(collections.abc.Awaitable, 1) Coroutine = _alias(collections.abc.Coroutine, 3) AsyncIterable = _alias(collections.abc.AsyncIterable, 1) AsyncIterator = _alias(collections.abc.AsyncIterator, 1) Iterable = _alias(collections.abc.Iterable, 1) Iterator = _alias(collections.abc.Iterator, 1) Reversible = _alias(collections.abc.Reversible, 1) Sized = _alias(collections.abc.Sized, 0) # Not generic. Container = _alias(collections.abc.Container, 1) Collection = _alias(collections.abc.Collection, 1) Callable = _CallableType(collections.abc.Callable, 2) Callable.__doc__ = \ """Callable type; Callable[[int], str] is a function of (int) -> str. The subscription syntax must always be used with exactly two values: the argument list and the return type. The argument list must be a list of types or ellipsis; the return type must be a single type. There is no syntax to indicate optional or keyword arguments, such function types are rarely used as callback types. """ AbstractSet = _alias(collections.abc.Set, 1, name='AbstractSet') MutableSet = _alias(collections.abc.MutableSet, 1) # NOTE: Mapping is only covariant in the value type. Mapping = _alias(collections.abc.Mapping, 2) MutableMapping = _alias(collections.abc.MutableMapping, 2) Sequence = _alias(collections.abc.Sequence, 1) MutableSequence = _alias(collections.abc.MutableSequence, 1) ByteString = _alias(collections.abc.ByteString, 0) # Not generic # Tuple accepts variable number of parameters. Tuple = _TupleType(tuple, -1, inst=False, name='Tuple') Tuple.__doc__ = \ """Tuple type; Tuple[X, Y] is the cross-product type of X and Y. Example: Tuple[T1, T2] is a tuple of two elements corresponding to type variables T1 and T2. Tuple[int, float, str] is a tuple of an int, a float and a string. To specify a variable-length tuple of homogeneous type, use Tuple[T, ...]. """ List = _alias(list, 1, inst=False, name='List') Deque = _alias(collections.deque, 1, name='Deque') Set = _alias(set, 1, inst=False, name='Set') FrozenSet = _alias(frozenset, 1, inst=False, name='FrozenSet') MappingView = _alias(collections.abc.MappingView, 1) KeysView = _alias(collections.abc.KeysView, 1) ItemsView = _alias(collections.abc.ItemsView, 2) ValuesView = _alias(collections.abc.ValuesView, 1) ContextManager = _alias(contextlib.AbstractContextManager, 1, name='ContextManager') AsyncContextManager = _alias(contextlib.AbstractAsyncContextManager, 1, name='AsyncContextManager') Dict = _alias(dict, 2, inst=False, name='Dict') DefaultDict = _alias(collections.defaultdict, 2, name='DefaultDict') OrderedDict = _alias(collections.OrderedDict, 2) Counter = _alias(collections.Counter, 1) ChainMap = _alias(collections.ChainMap, 2) Generator = _alias(collections.abc.Generator, 3) AsyncGenerator = _alias(collections.abc.AsyncGenerator, 2) Type = _alias(type, 1, inst=False, name='Type') Type.__doc__ = \ """A special construct usable to annotate class objects. For example, suppose we have the following classes:: class User: ... # Abstract base for User classes class BasicUser(User): ... class ProUser(User): ... class TeamUser(User): ... And a function that takes a class argument that's a subclass of User and returns an instance of the corresponding class:: U = TypeVar('U', bound=User) def new_user(user_class: Type[U]) -> U: user = user_class() # (Here we could write the user object to a database) return user joe = new_user(BasicUser) At this point the type checker knows that joe has type BasicUser. """ @runtime_checkable class SupportsInt(Protocol): """An ABC with one abstract method __int__.""" __slots__ = () @abstractmethod def __int__(self) -> int: pass @runtime_checkable class SupportsFloat(Protocol): """An ABC with one abstract method __float__.""" __slots__ = () @abstractmethod def __float__(self) -> float: pass @runtime_checkable class SupportsComplex(Protocol): """An ABC with one abstract method __complex__.""" __slots__ = () @abstractmethod def __complex__(self) -> complex: pass @runtime_checkable class SupportsBytes(Protocol): """An ABC with one abstract method __bytes__.""" __slots__ = () @abstractmethod def __bytes__(self) -> bytes: pass @runtime_checkable class SupportsIndex(Protocol): """An ABC with one abstract method __index__.""" __slots__ = () @abstractmethod def __index__(self) -> int: pass @runtime_checkable class SupportsAbs(Protocol[T_co]): """An ABC with one abstract method __abs__ that is covariant in its return type.""" __slots__ = () @abstractmethod def __abs__(self) -> T_co: pass @runtime_checkable class SupportsRound(Protocol[T_co]): """An ABC with one abstract method __round__ that is covariant in its return type.""" __slots__ = () @abstractmethod def __round__(self, ndigits: int = 0) -> T_co: pass def _make_nmtuple(name, types, module, defaults = ()): fields = [n for n, t in types] types = {n: _type_check(t, f"field {n} annotation must be a type") for n, t in types} nm_tpl = collections.namedtuple(name, fields, defaults=defaults, module=module) nm_tpl.__annotations__ = nm_tpl.__new__.__annotations__ = types return nm_tpl # attributes prohibited to set in NamedTuple class syntax _prohibited = frozenset({'__new__', '__init__', '__slots__', '__getnewargs__', '_fields', '_field_defaults', '_make', '_replace', '_asdict', '_source'}) _special = frozenset({'__module__', '__name__', '__annotations__'}) class NamedTupleMeta(type): def __new__(cls, typename, bases, ns): assert _NamedTuple in bases for base in bases: if base is not _NamedTuple and base is not Generic: raise TypeError( 'can only inherit from a NamedTuple type and Generic') bases = tuple(tuple if base is _NamedTuple else base for base in bases) types = ns.get('__annotations__', {}) default_names = [] for field_name in types: if field_name in ns: default_names.append(field_name) elif default_names: raise TypeError(f"Non-default namedtuple field {field_name} " f"cannot follow default field" f"{'s' if len(default_names) > 1 else ''} " f"{', '.join(default_names)}") nm_tpl = _make_nmtuple(typename, types.items(), defaults=[ns[n] for n in default_names], module=ns['__module__']) nm_tpl.__bases__ = bases if Generic in bases: class_getitem = Generic.__class_getitem__.__func__ nm_tpl.__class_getitem__ = classmethod(class_getitem) # update from user namespace without overriding special namedtuple attributes for key in ns: if key in _prohibited: raise AttributeError("Cannot overwrite NamedTuple attribute " + key) elif key not in _special and key not in nm_tpl._fields: setattr(nm_tpl, key, ns[key]) if Generic in bases: nm_tpl.__init_subclass__() return nm_tpl def NamedTuple(typename, fields=None, /, **kwargs): """Typed version of namedtuple. Usage in Python versions >= 3.6:: class Employee(NamedTuple): name: str id: int This is equivalent to:: Employee = collections.namedtuple('Employee', ['name', 'id']) The resulting class has an extra __annotations__ attribute, giving a dict that maps field names to types. (The field names are also in the _fields attribute, which is part of the namedtuple API.) Alternative equivalent keyword syntax is also accepted:: Employee = NamedTuple('Employee', name=str, id=int) In Python versions <= 3.5 use:: Employee = NamedTuple('Employee', [('name', str), ('id', int)]) """ if fields is None: fields = kwargs.items() elif kwargs: raise TypeError("Either list of fields or keywords" " can be provided to NamedTuple, not both") return _make_nmtuple(typename, fields, module=_caller()) _NamedTuple = type.__new__(NamedTupleMeta, 'NamedTuple', (), {}) def _namedtuple_mro_entries(bases): assert NamedTuple in bases return (_NamedTuple,) NamedTuple.__mro_entries__ = _namedtuple_mro_entries class _TypedDictMeta(type): def __new__(cls, name, bases, ns, total=True): """Create new typed dict class object. This method is called when TypedDict is subclassed, or when TypedDict is instantiated. This way TypedDict supports all three syntax forms described in its docstring. Subclasses and instances of TypedDict return actual dictionaries. """ for base in bases: if type(base) is not _TypedDictMeta and base is not Generic: raise TypeError('cannot inherit from both a TypedDict type ' 'and a non-TypedDict base class') if any(issubclass(b, Generic) for b in bases): generic_base = (Generic,) else: generic_base = () tp_dict = type.__new__(_TypedDictMeta, name, (*generic_base, dict), ns) annotations = {} own_annotations = ns.get('__annotations__', {}) msg = "TypedDict('Name', {f0: t0, f1: t1, ...}); each t must be a type" own_annotations = { n: _type_check(tp, msg, module=tp_dict.__module__) for n, tp in own_annotations.items() } required_keys = set() optional_keys = set() for base in bases: annotations.update(base.__dict__.get('__annotations__', {})) required_keys.update(base.__dict__.get('__required_keys__', ())) optional_keys.update(base.__dict__.get('__optional_keys__', ())) annotations.update(own_annotations) for annotation_key, annotation_type in own_annotations.items(): annotation_origin = get_origin(annotation_type) if annotation_origin is Annotated: annotation_args = get_args(annotation_type) if annotation_args: annotation_type = annotation_args[0] annotation_origin = get_origin(annotation_type) if annotation_origin is Required: required_keys.add(annotation_key) elif annotation_origin is NotRequired: optional_keys.add(annotation_key) elif total: required_keys.add(annotation_key) else: optional_keys.add(annotation_key) tp_dict.__annotations__ = annotations tp_dict.__required_keys__ = frozenset(required_keys) tp_dict.__optional_keys__ = frozenset(optional_keys) if not hasattr(tp_dict, '__total__'): tp_dict.__total__ = total return tp_dict __call__ = dict # static method def __subclasscheck__(cls, other): # Typed dicts are only for static structural subtyping. raise TypeError('TypedDict does not support instance and class checks') __instancecheck__ = __subclasscheck__ def TypedDict(typename, fields=None, /, *, total=True, **kwargs): """A simple typed namespace. At runtime it is equivalent to a plain dict. TypedDict creates a dictionary type that expects all of its instances to have a certain set of keys, where each key is associated with a value of a consistent type. This expectation is not checked at runtime but is only enforced by type checkers. Usage:: class Point2D(TypedDict): x: int y: int label: str a: Point2D = {'x': 1, 'y': 2, 'label': 'good'} # OK b: Point2D = {'z': 3, 'label': 'bad'} # Fails type check assert Point2D(x=1, y=2, label='first') == dict(x=1, y=2, label='first') The type info can be accessed via the Point2D.__annotations__ dict, and the Point2D.__required_keys__ and Point2D.__optional_keys__ frozensets. TypedDict supports an additional equivalent form:: Point2D = TypedDict('Point2D', {'x': int, 'y': int, 'label': str}) By default, all keys must be present in a TypedDict. It is possible to override this by specifying totality. Usage:: class point2D(TypedDict, total=False): x: int y: int This means that a point2D TypedDict can have any of the keys omitted.A type checker is only expected to support a literal False or True as the value of the total argument. True is the default, and makes all items defined in the class body be required. The class syntax is only supported in Python 3.6+, while the other syntax form works for Python 2.7 and 3.2+ """ if fields is None: fields = kwargs elif kwargs: raise TypeError("TypedDict takes either a dict or keyword arguments," " but not both") if kwargs: warnings.warn( "The kwargs-based syntax for TypedDict definitions is deprecated " "in Python 3.11, will be removed in Python 3.13, and may not be " "understood by third-party type checkers.", DeprecationWarning, stacklevel=2, ) ns = {'__annotations__': dict(fields)} module = _caller() if module is not None: # Setting correct module is necessary to make typed dict classes pickleable. ns['__module__'] = module return _TypedDictMeta(typename, (), ns, total=total) _TypedDict = type.__new__(_TypedDictMeta, 'TypedDict', (), {}) TypedDict.__mro_entries__ = lambda bases: (_TypedDict,) @_SpecialForm def Required(self, parameters): """A special typing construct to mark a key of a total=False TypedDict as required. For example: class Movie(TypedDict, total=False): title: Required[str] year: int m = Movie( title='The Matrix', # typechecker error if key is omitted year=1999, ) There is no runtime checking that a required key is actually provided when instantiating a related TypedDict. """ item = _type_check(parameters, f'{self._name} accepts only a single type.') return _GenericAlias(self, (item,)) @_SpecialForm def NotRequired(self, parameters): """A special typing construct to mark a key of a TypedDict as potentially missing. For example: class Movie(TypedDict): title: str year: NotRequired[int] m = Movie( title='The Matrix', # typechecker error if key is omitted year=1999, ) """ item = _type_check(parameters, f'{self._name} accepts only a single type.') return _GenericAlias(self, (item,)) class NewType: """NewType creates simple unique types with almost zero runtime overhead. NewType(name, tp) is considered a subtype of tp by static type checkers. At runtime, NewType(name, tp) returns a dummy callable that simply returns its argument. Usage:: UserId = NewType('UserId', int) def name_by_id(user_id: UserId) -> str: ... UserId('user') # Fails type check name_by_id(42) # Fails type check name_by_id(UserId(42)) # OK num = UserId(5) + 1 # type: int """ __call__ = _idfunc def __init__(self, name, tp): self.__qualname__ = name if '.' in name: name = name.rpartition('.')[-1] self.__name__ = name self.__supertype__ = tp def_mod = _caller() if def_mod != 'typing': self.__module__ = def_mod def __mro_entries__(self, bases): # We defined __mro_entries__ to get a better error message # if a user attempts to subclass a NewType instance. bpo-46170 superclass_name = self.__name__ class Dummy: def __init_subclass__(cls): subclass_name = cls.__name__ raise TypeError( f"Cannot subclass an instance of NewType. Perhaps you were looking for: " f"`{subclass_name} = NewType({subclass_name!r}, {superclass_name})`" ) return (Dummy,) def __repr__(self): return f'{self.__module__}.{self.__qualname__}' def __reduce__(self): return self.__qualname__ def __or__(self, other): return Union[self, other] def __ror__(self, other): return Union[other, self] # Python-version-specific alias (Python 2: unicode; Python 3: str) Text = str # Constant that's True when type checking, but False here. TYPE_CHECKING = False class IO(Generic[AnyStr]): """Generic base class for TextIO and BinaryIO. This is an abstract, generic version of the return of open(). NOTE: This does not distinguish between the different possible classes (text vs. binary, read vs. write vs. read/write, append-only, unbuffered). The TextIO and BinaryIO subclasses below capture the distinctions between text vs. binary, which is pervasive in the interface; however we currently do not offer a way to track the other distinctions in the type system. """ __slots__ = () @property @abstractmethod def mode(self) -> str: pass @property @abstractmethod def name(self) -> str: pass @abstractmethod def close(self) -> None: pass @property @abstractmethod def closed(self) -> bool: pass @abstractmethod def fileno(self) -> int: pass @abstractmethod def flush(self) -> None: pass @abstractmethod def isatty(self) -> bool: pass @abstractmethod def read(self, n: int = -1) -> AnyStr: pass @abstractmethod def readable(self) -> bool: pass @abstractmethod def readline(self, limit: int = -1) -> AnyStr: pass @abstractmethod def readlines(self, hint: int = -1) -> List[AnyStr]: pass @abstractmethod def seek(self, offset: int, whence: int = 0) -> int: pass @abstractmethod def seekable(self) -> bool: pass @abstractmethod def tell(self) -> int: pass @abstractmethod def truncate(self, size: int = None) -> int: pass @abstractmethod def writable(self) -> bool: pass @abstractmethod def write(self, s: AnyStr) -> int: pass @abstractmethod def writelines(self, lines: List[AnyStr]) -> None: pass @abstractmethod def __enter__(self) -> 'IO[AnyStr]': pass @abstractmethod def __exit__(self, type, value, traceback) -> None: pass class BinaryIO(IO[bytes]): """Typed version of the return of open() in binary mode.""" __slots__ = () @abstractmethod def write(self, s: Union[bytes, bytearray]) -> int: pass @abstractmethod def __enter__(self) -> 'BinaryIO': pass class TextIO(IO[str]): """Typed version of the return of open() in text mode.""" __slots__ = () @property @abstractmethod def buffer(self) -> BinaryIO: pass @property @abstractmethod def encoding(self) -> str: pass @property @abstractmethod def errors(self) -> Optional[str]: pass @property @abstractmethod def line_buffering(self) -> bool: pass @property @abstractmethod def newlines(self) -> Any: pass @abstractmethod def __enter__(self) -> 'TextIO': pass class _DeprecatedType(type): def __getattribute__(cls, name): if name not in ("__dict__", "__module__") and name in cls.__dict__: warnings.warn( f"{cls.__name__} is deprecated, import directly " f"from typing instead. {cls.__name__} will be removed " "in Python 3.12.", DeprecationWarning, stacklevel=2, ) return super().__getattribute__(name) class io(metaclass=_DeprecatedType): """Wrapper namespace for IO generic classes.""" __all__ = ['IO', 'TextIO', 'BinaryIO'] IO = IO TextIO = TextIO BinaryIO = BinaryIO io.__name__ = __name__ + '.io' sys.modules[io.__name__] = io Pattern = _alias(stdlib_re.Pattern, 1) Match = _alias(stdlib_re.Match, 1) class re(metaclass=_DeprecatedType): """Wrapper namespace for re type aliases.""" __all__ = ['Pattern', 'Match'] Pattern = Pattern Match = Match re.__name__ = __name__ + '.re' sys.modules[re.__name__] = re def reveal_type(obj: T, /) -> T: """Reveal the inferred type of a variable. When a static type checker encounters a call to ``reveal_type()``, it will emit the inferred type of the argument:: x: int = 1 reveal_type(x) Running a static type checker (e.g., ``mypy``) on this example will produce output similar to 'Revealed type is "builtins.int"'. At runtime, the function prints the runtime type of the argument and returns it unchanged. """ print(f"Runtime type is {type(obj).__name__!r}", file=sys.stderr) return obj def dataclass_transform( *, eq_default: bool = True, order_default: bool = False, kw_only_default: bool = False, field_specifiers: tuple[type[Any] | Callable[..., Any], ...] = (), **kwargs: Any, ) -> Callable[[T], T]: """Decorator that marks a function, class, or metaclass as providing dataclass-like behavior. Example usage with a decorator function: _T = TypeVar("_T") @dataclass_transform() def create_model(cls: type[_T]) -> type[_T]: ... return cls @create_model class CustomerModel: id: int name: str On a base class: @dataclass_transform() class ModelBase: ... class CustomerModel(ModelBase): id: int name: str On a metaclass: @dataclass_transform() class ModelMeta(type): ... class ModelBase(metaclass=ModelMeta): ... class CustomerModel(ModelBase): id: int name: str Each of the ``CustomerModel`` classes defined in this example will now behave similarly to a dataclass created with the ``@dataclasses.dataclass`` decorator. For example, the type checker will synthesize an ``__init__`` method. The arguments to this decorator can be used to customize this behavior: - ``eq_default`` indicates whether the ``eq`` parameter is assumed to be True or False if it is omitted by the caller. - ``order_default`` indicates whether the ``order`` parameter is assumed to be True or False if it is omitted by the caller. - ``kw_only_default`` indicates whether the ``kw_only`` parameter is assumed to be True or False if it is omitted by the caller. - ``field_specifiers`` specifies a static list of supported classes or functions that describe fields, similar to ``dataclasses.field()``. At runtime, this decorator records its arguments in the ``__dataclass_transform__`` attribute on the decorated object. It has no other runtime effect. See PEP 681 for more details. """ def decorator(cls_or_fn): cls_or_fn.__dataclass_transform__ = { "eq_default": eq_default, "order_default": order_default, "kw_only_default": kw_only_default, "field_specifiers": field_specifiers, "kwargs": kwargs, } return cls_or_fn return decorator