import sys from _typeshed import ReadableBuffer, WriteableBuffer from abc import abstractmethod from collections.abc import Callable, Iterable, Iterator, Mapping, Sequence from ctypes import CDLL from typing import Any, ClassVar, Generic, TypeVar, overload from typing_extensions import Self, TypeAlias if sys.version_info >= (3, 9): from types import GenericAlias _T = TypeVar("_T") _CT = TypeVar("_CT", bound=_CData) FUNCFLAG_CDECL: int FUNCFLAG_PYTHONAPI: int FUNCFLAG_USE_ERRNO: int FUNCFLAG_USE_LASTERROR: int RTLD_GLOBAL: int RTLD_LOCAL: int if sys.version_info >= (3, 11): CTYPES_MAX_ARGCOUNT: int if sys.version_info >= (3, 12): SIZEOF_TIME_T: int if sys.platform == "win32": # Description, Source, HelpFile, HelpContext, scode _COMError_Details: TypeAlias = tuple[str | None, str | None, str | None, int | None, int | None] class COMError(Exception): hresult: int text: str | None details: _COMError_Details def __init__(self, hresult: int, text: str | None, details: _COMError_Details) -> None: ... def CopyComPointer(src: _PointerLike, dst: _PointerLike | _CArgObject) -> int: ... FUNCFLAG_HRESULT: int FUNCFLAG_STDCALL: int def FormatError(code: int = ...) -> str: ... def get_last_error() -> int: ... def set_last_error(value: int) -> int: ... class _CDataMeta(type): # By default mypy complains about the following two methods, because strictly speaking cls # might not be a Type[_CT]. However this can never actually happen, because the only class that # uses _CDataMeta as its metaclass is _CData. So it's safe to ignore the errors here. def __mul__(cls: type[_CT], other: int) -> type[Array[_CT]]: ... # type: ignore[misc] # pyright: ignore[reportGeneralTypeIssues] def __rmul__(cls: type[_CT], other: int) -> type[Array[_CT]]: ... # type: ignore[misc] # pyright: ignore[reportGeneralTypeIssues] class _CData(metaclass=_CDataMeta): _b_base_: int _b_needsfree_: bool _objects: Mapping[Any, int] | None @classmethod def from_buffer(cls, source: WriteableBuffer, offset: int = ...) -> Self: ... @classmethod def from_buffer_copy(cls, source: ReadableBuffer, offset: int = ...) -> Self: ... @classmethod def from_address(cls, address: int) -> Self: ... @classmethod def from_param(cls, obj: Any) -> Self | _CArgObject: ... @classmethod def in_dll(cls, library: CDLL, name: str) -> Self: ... def __buffer__(self, __flags: int) -> memoryview: ... def __release_buffer__(self, __buffer: memoryview) -> None: ... class _SimpleCData(Generic[_T], _CData): value: _T # The TypeVar can be unsolved here, # but we can't use overloads without creating many, many mypy false-positive errors def __init__(self, value: _T = ...) -> None: ... # pyright: ignore[reportInvalidTypeVarUse] class _CanCastTo(_CData): ... class _PointerLike(_CanCastTo): ... class _Pointer(Generic[_CT], _PointerLike, _CData): _type_: type[_CT] contents: _CT @overload def __init__(self) -> None: ... @overload def __init__(self, arg: _CT) -> None: ... @overload def __getitem__(self, __key: int) -> Any: ... @overload def __getitem__(self, __key: slice) -> list[Any]: ... def __setitem__(self, __key: int, __value: Any) -> None: ... def POINTER(type: type[_CT]) -> type[_Pointer[_CT]]: ... def pointer(__arg: _CT) -> _Pointer[_CT]: ... class _CArgObject: ... def byref(obj: _CData, offset: int = ...) -> _CArgObject: ... _ECT: TypeAlias = Callable[[type[_CData] | None, CFuncPtr, tuple[_CData, ...]], _CData] _PF: TypeAlias = tuple[int] | tuple[int, str | None] | tuple[int, str | None, Any] class CFuncPtr(_PointerLike, _CData): restype: type[_CData] | Callable[[int], Any] | None argtypes: Sequence[type[_CData]] errcheck: _ECT _flags_: ClassVar[int] # Abstract attribute that must be defined on subclasses @overload def __init__(self) -> None: ... @overload def __init__(self, __address: int) -> None: ... @overload def __init__(self, __callable: Callable[..., Any]) -> None: ... @overload def __init__(self, __func_spec: tuple[str | int, CDLL], __paramflags: tuple[_PF, ...] | None = ...) -> None: ... if sys.platform == "win32": @overload def __init__( self, __vtbl_index: int, __name: str, __paramflags: tuple[_PF, ...] | None = ..., __iid: _CData | None = ... ) -> None: ... def __call__(self, *args: Any, **kwargs: Any) -> Any: ... class _CField: offset: int size: int class _StructUnionMeta(_CDataMeta): _fields_: Sequence[tuple[str, type[_CData]] | tuple[str, type[_CData], int]] _pack_: int _anonymous_: Sequence[str] def __getattr__(self, name: str) -> _CField: ... class _StructUnionBase(_CData, metaclass=_StructUnionMeta): def __init__(self, *args: Any, **kw: Any) -> None: ... def __getattr__(self, name: str) -> Any: ... def __setattr__(self, name: str, value: Any) -> None: ... class Union(_StructUnionBase): ... class Structure(_StructUnionBase): ... class Array(Generic[_CT], _CData): @property @abstractmethod def _length_(self) -> int: ... @_length_.setter def _length_(self, value: int) -> None: ... @property @abstractmethod def _type_(self) -> type[_CT]: ... @_type_.setter def _type_(self, value: type[_CT]) -> None: ... # Note: only available if _CT == c_char @property def raw(self) -> bytes: ... @raw.setter def raw(self, value: ReadableBuffer) -> None: ... value: Any # Note: bytes if _CT == c_char, str if _CT == c_wchar, unavailable otherwise # TODO These methods cannot be annotated correctly at the moment. # All of these "Any"s stand for the array's element type, but it's not possible to use _CT # here, because of a special feature of ctypes. # By default, when accessing an element of an Array[_CT], the returned object has type _CT. # However, when _CT is a "simple type" like c_int, ctypes automatically "unboxes" the object # and converts it to the corresponding Python primitive. For example, when accessing an element # of an Array[c_int], a Python int object is returned, not a c_int. # This behavior does *not* apply to subclasses of "simple types". # If MyInt is a subclass of c_int, then accessing an element of an Array[MyInt] returns # a MyInt, not an int. # This special behavior is not easy to model in a stub, so for now all places where # the array element type would belong are annotated with Any instead. def __init__(self, *args: Any) -> None: ... @overload def __getitem__(self, __key: int) -> Any: ... @overload def __getitem__(self, __key: slice) -> list[Any]: ... @overload def __setitem__(self, __key: int, __value: Any) -> None: ... @overload def __setitem__(self, __key: slice, __value: Iterable[Any]) -> None: ... def __iter__(self) -> Iterator[Any]: ... # Can't inherit from Sized because the metaclass conflict between # Sized and _CData prevents using _CDataMeta. def __len__(self) -> int: ... if sys.version_info >= (3, 9): def __class_getitem__(cls, item: Any) -> GenericAlias: ... class ArgumentError(Exception): ... def addressof(obj: _CData) -> int: ... def alignment(obj_or_type: _CData | type[_CData]) -> int: ... def get_errno() -> int: ... def resize(obj: _CData, size: int) -> None: ... def set_errno(value: int) -> int: ... def sizeof(obj_or_type: _CData | type[_CData]) -> int: ...