File: check-classes.test

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-- Methods
-- -------


[case testMethodCall]
class A:
    def foo(self, x: 'A') -> None: pass
class B:
    def bar(self, x: 'B', y: A) -> None: pass

a: A
b: B

a.foo(B())  # E: Argument 1 to "foo" of "A" has incompatible type "B"; expected "A"
a.bar(B(), A())  # E: "A" has no attribute "bar"

a.foo(A())
b.bar(B(), A())

[case testMethodCallWithSubtype]
class A:
    def foo(self, x: 'A') -> None: pass
    def bar(self, x: 'B') -> None: pass
class B(A): pass

a: A
a.foo(A())
a.foo(B())
a.bar(A()) # E: Argument 1 to "bar" of "A" has incompatible type "A"; expected "B"
a.bar(B())

[case testInheritingMethod]
class A:
    def foo(self, x: 'B') -> None: pass
class B(A): pass

a: B
a.foo(A()) # Fail
a.foo(B())

[targets __main__, __main__.A.foo]
[out]
main:6: error: Argument 1 to "foo" of "A" has incompatible type "A"; expected "B"

[case testMethodCallWithInvalidNumberOfArguments]
class A:
    def foo(self, x: 'A') -> None: pass

a: A
a.foo()               # Fail
a.foo(object(), A())  # Fail
[out]
main:5: error: Missing positional argument "x" in call to "foo" of "A"
main:6: error: Too many arguments for "foo" of "A"
main:6: error: Argument 1 to "foo" of "A" has incompatible type "object"; expected "A"

[case testMethodBody]
import typing
class A:
    def f(self) -> None:
        a = object() # type: A    # Fail
[out]
main:4: error: Incompatible types in assignment (expression has type "object", variable has type "A")

[case testMethodArguments]
import typing
class A:
    def f(self, a: 'A', b: 'B') -> None:
        if int():
            a = B() # E: Incompatible types in assignment (expression has type "B", variable has type "A")
            b = A() # E: Incompatible types in assignment (expression has type "A", variable has type "B")
            a = A()
            b = B()
            a = a
            a = b # E: Incompatible types in assignment (expression has type "B", variable has type "A")
class B: pass
[out]

[case testReturnFromMethod]
import typing
class A:
    def f(self) -> 'A':
        return B() # Fail
        return A()
class B: pass
[out]
main:4: error: Incompatible return value type (got "B", expected "A")

[case testSelfArgument]
import typing
class A:
    def f(self) -> None:
        o = self # type: B    # Fail
        self.g()      # Fail
        a = self # type: A
        self.f()
class B: pass
[out]
main:4: error: Incompatible types in assignment (expression has type "A", variable has type "B")
main:5: error: "A" has no attribute "g"

[case testAssignToMethodViaInstance]
import typing
class A:
    def f(self): pass
A().f = None  # E: Cannot assign to a method \
              # E: Incompatible types in assignment (expression has type "None", variable has type "Callable[[], Any]")


[case testOverrideAttributeWithMethod]
# This was crashing:
# https://github.com/python/mypy/issues/10134
from typing import Protocol

class Base:
    __hash__: None = None

class Derived(Base):
    def __hash__(self) -> int:  # E: Signature of "__hash__" incompatible with supertype "Base" \
                                # N:      Superclass: \
                                # N:          None \
                                # N:      Subclass: \
                                # N:          def __hash__(self) -> int
        pass

# Correct:

class CallableProtocol(Protocol):
    def __call__(self, arg: int) -> int:
        pass

class CorrectBase:
    attr: CallableProtocol

class CorrectDerived(CorrectBase):
    def attr(self, arg: int) -> int:
        pass

[case testOverrideMethodWithAttribute]
# The reverse should not crash as well:
from typing import Callable

class Base:
    def __hash__(self) -> int:
        pass

class Derived(Base):
    __hash__ = 1  # E: Incompatible types in assignment (expression has type "int", base class "Base" defined the type as "Callable[[], int]")

[case testOverridePartialAttributeWithMethod]
# This was crashing: https://github.com/python/mypy/issues/11686.
class Base:
    def __init__(self, arg: int):
        self.partial_type = []  # E: Need type annotation for "partial_type" (hint: "partial_type: list[<type>] = ...")
        self.force_deferral = []

    # Force inference of the `force_deferral` attribute in `__init__` to be
    # deferred to a later pass by providing a definition in another context,
    # which means `partial_type` remains only partially inferred.
    force_deferral = []  # E: Need type annotation for "force_deferral" (hint: "force_deferral: list[<type>] = ...")


class Derived(Base):
    def partial_type(self) -> int:  # E: Signature of "partial_type" incompatible with supertype "Base" \
                                    # N:      Superclass: \
                                    # N:          list[Any] \
                                    # N:      Subclass: \
                                    # N:          def partial_type(self) -> int
        ...


-- Attributes
-- ----------


[case testReferToInvalidAttribute]

class A:
    def __init__(self) -> None:
        self.x = object()
a: A
a.y  # E: "A" has no attribute "y"
a.y = object()  # E: "A" has no attribute "y"
a.x
a.x = object()

[case testReferToInvalidAttributeUnannotatedInit]
class A:
    def __init__(self):
        self.x = object()

a: A
a.y  # E: "A" has no attribute "y"
a.y = object()  # E: "A" has no attribute "y"
a.x
a.x = object()

[case testArgumentTypeInference]

class A:
    def __init__(self, aa: 'A', bb: 'B') -> None:
        self.a = aa
        self.b = bb
class B: pass
a: A
b: B
a.a = b # Fail
a.b = a # Fail
b.a     # Fail
a.a = a
a.b = b
[out]
main:9: error: Incompatible types in assignment (expression has type "B", variable has type "A")
main:10: error: Incompatible types in assignment (expression has type "A", variable has type "B")
main:11: error: "B" has no attribute "a"

[case testExplicitAttributeInBody]

class A:
  x: A
a: A
a.x = object() # E: Incompatible types in assignment (expression has type "object", variable has type "A")
a.x = A()

[case testAttributeDefinedInNonInitMethod]
import typing
class A:
    def f(self) -> None:
        self.x = 1
        self.y = ''
        self.x = 1
a = A()
a.x = 1
a.y = ''
a.x = '' # E: Incompatible types in assignment (expression has type "str", variable has type "int")
a.z = 0  # E: "A" has no attribute "z"

[case testInheritanceAndAttributeAssignment]
import typing
class A:
    def f(self) -> None:
        self.x = 0
class B(A):
    def f(self) -> None:
        self.x = '' # E: Incompatible types in assignment (expression has type "str", variable has type "int")
[targets __main__, __main__.A.f, __main__.B.f]

[case testAssignmentToAttributeInMultipleMethods]
import typing
class A:
    def f(self) -> None:
        self.x = 0
    def g(self) -> None:
        self.x = '' # Fail
    def __init__(self) -> None:
        self.x = '' # Fail
[out]
main:6: error: Incompatible types in assignment (expression has type "str", variable has type "int")
main:8: error: Incompatible types in assignment (expression has type "str", variable has type "int")

[case testClassNamesDefinedOnSelUsedInClassBody]
class A(object):
    def f(self):
        self.attr = 1
    attr = 0

class B(object):
    attr = 0
    def f(self):
        self.attr = 1

class C(object):
    attr = 0
    def f(self):
        self.attr = 1
    attr = 0

class D(object):
    def g(self):
        self.attr = 1
    attr = 0
    def f(self):
        self.attr = 1
[out]

[case testClassNamesDefinedOnSelUsedInClassBodyReveal]

class A(object):
    def f(self) -> None:
        self.attr = 1
    attr  # E: Name "attr" is not defined

class B(object):
    attr = 0
    def f(self) -> None:
        reveal_type(self.attr)  # N: Revealed type is "builtins.int"
[out]


-- Method overriding
-- -----------------


[case testMethodOverridingWithIdenticalSignature]
import typing
class A:
    def f(self, x: 'A') -> None: pass
    def g(self, x: 'B' , y: object) -> 'A': pass
    def h(self) -> None: pass
class B(A):
    def f(self, x: A) -> None: pass
    def g(self, x: 'B' , y: object) -> A: pass
    def h(self) -> None: pass
[out]

[case testMethodOverridingWithCovariantType]
import typing
class A:
  def f(self, x: 'A', y: 'B') -> 'A': pass
  def g(self, x: 'A', y: 'B') -> 'A': pass
class B(A):
  def f(self, x: A, y: 'B') -> 'B': pass
  def g(self, x: A, y: A) -> 'A': pass
[out]

[case testMethodOverridingWithIncompatibleTypes]
import typing
class A:
  def f(self, x: 'A', y: 'B') -> 'A': pass
  def g(self, x: 'A', y: 'B') -> 'A': pass
  def h(self, x: 'A', y: 'B') -> 'A': pass
class B(A):
  def f(self, x: 'B', y: 'B') -> A: pass  # Fail
  def g(self, x: A, y: A) -> A: pass
  def h(self, x: A, y: 'B') -> object: pass  # Fail
[out]
main:7: error: Argument 1 of "f" is incompatible with supertype "A"; supertype defines the argument type as "A"
main:7: note: This violates the Liskov substitution principle
main:7: note: See https://mypy.readthedocs.io/en/stable/common_issues.html#incompatible-overrides
main:9: error: Return type "object" of "h" incompatible with return type "A" in supertype "A"

[case testMethodOverridingWithIncompatibleTypesOnMultipleLines]
class A:
    def f(self, x: int, y: str) -> None: pass
class B(A):
    def f(
        self,
        x: int,
        y: bool,
    ) -> None:
        pass
[out]
main:7: error: Argument 2 of "f" is incompatible with supertype "A"; supertype defines the argument type as "str"
main:7: note: This violates the Liskov substitution principle
main:7: note: See https://mypy.readthedocs.io/en/stable/common_issues.html#incompatible-overrides

[case testMultiLineMethodOverridingWithIncompatibleTypesIgnorableAtArgument]
class A:
    def f(self, x: int, y: str) -> None: pass

class B(A):
    def f(
        self,
        x: int,
        y: bool,  # type: ignore[override]
    ) -> None:
        pass

[case testMultiLineMethodOverridingWithIncompatibleTypesIgnorableAtDefinition]
class A:
    def f(self, x: int, y: str) -> None: pass
class B(A):
    def f(  # type: ignore[override]
        self,
        x: int,
        y: bool,
    ) -> None:
        pass

[case testMultiLineMethodOverridingWithIncompatibleTypesWrongIgnore]
class A:
    def f(self, x: int, y: str) -> None: pass
class B(A):
    def f(  # type: ignore[return-type]
        self,
        x: int,
        y: bool,
    ) -> None:
        pass
[out]
main:7: error: Argument 2 of "f" is incompatible with supertype "A"; supertype defines the argument type as "str"
main:7: note: This violates the Liskov substitution principle
main:7: note: See https://mypy.readthedocs.io/en/stable/common_issues.html#incompatible-overrides

[case testEqMethodsOverridingWithNonObjects]
class A:
  def __eq__(self, other: A) -> bool: pass  # Fail
[builtins fixtures/plugin_attrs.pyi]
[out]
main:2: error: Argument 1 of "__eq__" is incompatible with supertype "builtins.object"; supertype defines the argument type as "object"
main:2: note: This violates the Liskov substitution principle
main:2: note: See https://mypy.readthedocs.io/en/stable/common_issues.html#incompatible-overrides
main:2: note: It is recommended for "__eq__" to work with arbitrary objects, for example:
main:2: note:     def __eq__(self, other: object) -> bool:
main:2: note:         if not isinstance(other, A):
main:2: note:             return NotImplemented
main:2: note:         return <logic to compare two A instances>

[case testMethodOverridingWithIncompatibleArgumentCount]
import typing
class A:
    def f(self, x: 'A') -> None: pass
    def g(self, x: 'A', y: 'B') -> 'A': pass
class B(A):
    def f(self, x: A, y: A) -> None: pass # Fail
    def g(self, x: A) -> A: pass # Fail
[out]
main:6: error: Signature of "f" incompatible with supertype "A"
main:6: note:      Superclass:
main:6: note:          def f(self, x: A) -> None
main:6: note:      Subclass:
main:6: note:          def f(self, x: A, y: A) -> None
main:7: error: Signature of "g" incompatible with supertype "A"
main:7: note:      Superclass:
main:7: note:          def g(self, x: A, y: B) -> A
main:7: note:      Subclass:
main:7: note:          def g(self, x: A) -> A

[case testMethodOverridingAcrossDeepInheritanceHierarchy1]
import typing
class A:
    def f(self, x: 'B') -> None: pass
class B(A): pass
class C(B): # with gap in implementations
    def f(self, x: 'C') -> None:  # Fail
        pass
[out]
main:6: error: Argument 1 of "f" is incompatible with supertype "A"; supertype defines the argument type as "B"
main:6: note: This violates the Liskov substitution principle
main:6: note: See https://mypy.readthedocs.io/en/stable/common_issues.html#incompatible-overrides

[case testMethodOverridingAcrossDeepInheritanceHierarchy2]
import typing
class A:
    def f(self) -> 'B': pass
class B(A):
    def f(self) -> 'C': pass
class C(B): # with multiple implementations
    def f(self) -> B:  # Fail
        pass
[out]
main:7: error: Return type "B" of "f" incompatible with return type "C" in supertype "B"

[case testMethodOverridingWithVoidReturnValue]
import typing
class A:
    def f(self) -> None: pass
    def g(self) -> 'A': pass
class B(A):
    def f(self) -> A: pass  # Fail
    def g(self) -> None: pass  # Fail
[out]
main:6: error: Return type "A" of "f" incompatible with return type "None" in supertype "A"
main:7: error: Return type "None" of "g" incompatible with return type "A" in supertype "A"

[case testOverride__new__WithDifferentSignature]
class A:
    def __new__(cls, x: int) -> A:
        pass

class B(A):
    def __new__(cls) -> B:
        pass

[case testOverride__new__WithLiteralReturnPassing]
from typing import Literal

class Falsy:
    def __bool__(self) -> Literal[False]: pass

reveal_type(bool(Falsy()))  # N: Revealed type is "Literal[False]"
reveal_type(int())  # N: Revealed type is "Literal[0]"

[builtins fixtures/literal__new__.pyi]
[typing fixtures/typing-medium.pyi]

[case testOverride__new__WithLiteralReturnFailing]
from typing import Literal

class Foo:
    def __new__(cls) -> Literal[1]: pass # E: Incompatible return type for "__new__" (returns "Literal[1]", but must return a subtype of "Foo")

[builtins fixtures/__new__.pyi]
[typing fixtures/typing-medium.pyi]

[case testOverride__new__AndCallObject]
from typing import TypeVar, Generic

class A:
    def __new__(cls, x: int) -> 'A':
        return object.__new__(cls)

T = TypeVar('T')
class B(Generic[T]):
    def __new__(cls, foo: T) -> 'B[T]':
        x = object.__new__(cls)
        # object.__new__ doesn't have a great type :(
        reveal_type(x)  # N: Revealed type is "Any"
        return x

[builtins fixtures/__new__.pyi]

[case testInnerFunctionNotOverriding]
class A:
    def f(self) -> int: pass

class B(A):
    def g(self) -> None:
        def f(self) -> str: pass

[case testOverride__init_subclass__WithDifferentSignature]
class A:
    def __init_subclass__(cls, x: int) -> None: pass
class B(A):  # E: Missing positional argument "x" in call to "__init_subclass__" of "A"
    def __init_subclass__(cls) -> None: pass

[case testOverrideWithDecorator]
from typing import Callable

def int_to_none(f: Callable[..., int]) -> Callable[..., None]: ...
def str_to_int(f: Callable[..., str]) -> Callable[..., int]: ...

class A:
    def f(self) -> None: pass
    def g(self) -> str: pass
    def h(self) -> None: pass

class B(A):
    @int_to_none
    def f(self) -> int: pass
    @str_to_int
    def g(self) -> str: pass # Fail
    @int_to_none
    @str_to_int
    def h(self) -> str: pass
[out]
main:15: error: Signature of "g" incompatible with supertype "A"
main:15: note:      Superclass:
main:15: note:          def g(self) -> str
main:15: note:      Subclass:
main:15: note:          def g(*Any, **Any) -> int

[case testOverrideDecorated]
from typing import Callable

def str_to_int(f: Callable[..., str]) -> Callable[..., int]: ...

class A:
    @str_to_int
    def f(self) -> str: pass
    @str_to_int
    def g(self) -> str: pass
    @str_to_int
    def h(self) -> str: pass

class B(A):
    def f(self) -> int: pass
    def g(self) -> str: pass # Fail
    @str_to_int
    def h(self) -> str: pass
[out]
main:15: error: Signature of "g" incompatible with supertype "A"
main:15: note:      Superclass:
main:15: note:          def g(*Any, **Any) -> int
main:15: note:      Subclass:
main:15: note:          def g(self) -> str

[case testOverrideWithDecoratorReturningAny]
def dec(f): pass

class A:
    def f(self) -> str: pass

class B(A):
    @dec
    def f(self) -> int: pass

[case testOverrideWithDecoratorReturningCallable]
from typing import Any, Callable, TypeVar

class Base:
    def get(self, a: str) -> None: ...

def dec(fn: Any) -> Callable[[Any, int], None]: ...

class Derived(Base):
    @dec
    def get(self) -> None: ...  # E: Argument 1 of "get" is incompatible with supertype "Base"; supertype defines the argument type as "str" \
                                # N: This violates the Liskov substitution principle \
                                # N: See https://mypy.readthedocs.io/en/stable/common_issues.html#incompatible-overrides
[builtins fixtures/tuple.pyi]

[case testOverrideWithDecoratorReturningCallable2]
# flags: --pretty
from typing import Any, Callable, TypeVar

_C = TypeVar("_C", bound=Callable[..., Any])

def infer_signature(f: _C) -> Callable[[Any], _C]: ...

class Base:
    def get(self, a: str, b: str, c: str) -> None: ...
    def post(self, a: str, b: str) -> None: ...

# Third argument incompatible
def get(self, a: str, b: str, c: int) -> None: ...

# Second argument incompatible - still should not map to **kwargs
def post(self, a: str, b: int) -> None: ...

class Derived(Base):
    @infer_signature(get)
    def get(self, *args: Any, **kwargs: Any) -> None: ...

    @infer_signature(post)
    def post(self, *args: Any, **kwargs: Any) -> None: ...
[builtins fixtures/tuple.pyi]
[out]
main:20: error: Argument 3 of "get" is incompatible with supertype "Base"; supertype defines the argument type as "str"
        def get(self, *args: Any, **kwargs: Any) -> None: ...
        ^~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
main:20: note: This violates the Liskov substitution principle
main:20: note: See https://mypy.readthedocs.io/en/stable/common_issues.html#incompatible-overrides
main:23: error: Argument 2 of "post" is incompatible with supertype "Base"; supertype defines the argument type as "str"
        def post(self, *args: Any, **kwargs: Any) -> None: ...
        ^~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
main:23: note: This violates the Liskov substitution principle
main:23: note: See https://mypy.readthedocs.io/en/stable/common_issues.html#incompatible-overrides

[case testOverrideWithDecoratorReturningInstance]
def dec(f) -> str: pass

class A:
    def f(self) -> str: pass
    @dec
    def g(self) -> int: pass
    @dec
    def h(self) -> int: pass

class B(A):
    @dec
    def f(self) -> int: pass # E: Signature of "f" incompatible with supertype "A" \
                             # N:      Superclass: \
                             # N:          def f(self) -> str \
                             # N:      Subclass: \
                             # N:          str
    def g(self) -> int: pass # E: Signature of "g" incompatible with supertype "A" \
                             # N:      Superclass: \
                             # N:          str \
                             # N:      Subclass: \
                             # N:          def g(self) -> int
    @dec
    def h(self) -> str: pass

[case testOverrideIncompatibleWithMultipleSupertypes]
class A:
    def f(self, *, a: int) -> None:
        return

class B(A):
    def f(self, *, b: int) -> None:  # E: Signature of "f" incompatible with supertype "A" \
                                     # N:      Superclass: \
                                     # N:          def f(self, *, a: int) -> None \
                                     # N:      Subclass: \
                                     # N:          def f(self, *, b: int) -> None
        return

class C(B):
    def f(self, *, c: int) -> None:  # E: Signature of "f" incompatible with supertype "B" \
                                     # N:      Superclass: \
                                     # N:          def f(self, *, b: int) -> None \
                                     # N:      Subclass: \
                                     # N:          def f(self, *, c: int) -> None \
                                     # E: Signature of "f" incompatible with supertype "A" \
                                     # N:      Superclass: \
                                     # N:          def f(self, *, a: int) -> None \
                                     # N:      Subclass: \
                                     # N:          def f(self, *, c: int) -> None
        return

[case testOverrideStaticMethodWithStaticMethod]
class A:
    @staticmethod
    def f(x: int, y: str) -> None: pass
    @staticmethod
    def g(x: int, y: str) -> None: pass

class B(A):
    @staticmethod
    def f(x: int, y: str) -> None: pass
    @staticmethod
    def g(x: str, y: str) -> None: pass # E: Argument 1 of "g" is incompatible with supertype "A"; supertype defines the argument type as "int" \
                                        # N: This violates the Liskov substitution principle \
                                        # N: See https://mypy.readthedocs.io/en/stable/common_issues.html#incompatible-overrides
[builtins fixtures/classmethod.pyi]

[case testOverrideClassMethodWithClassMethod]
class A:
    @classmethod
    def f(cls, x: int, y: str) -> None: pass
    @classmethod
    def g(cls, x: int, y: str) -> None: pass

class B(A):
    @classmethod
    def f(cls, x: int, y: str) -> None: pass
    @classmethod
    def g(cls, x: str, y: str) -> None: pass # E: Argument 1 of "g" is incompatible with supertype "A"; supertype defines the argument type as "int" \
                                             # N: This violates the Liskov substitution principle \
                                             # N: See https://mypy.readthedocs.io/en/stable/common_issues.html#incompatible-overrides
[builtins fixtures/classmethod.pyi]

[case testOverrideClassMethodWithStaticMethod]
class A:
    @classmethod
    def f(cls, x: int) -> None: pass
    @classmethod
    def g(cls, x: int) -> int: pass
    @classmethod
    def h(cls) -> int: pass

class B(A):
    @staticmethod
    def f(x: int) -> None: pass
    @staticmethod
    def g(x: str) -> int: pass # E: Argument 1 of "g" is incompatible with supertype "A"; supertype defines the argument type as "int" \
                               # N: This violates the Liskov substitution principle \
                               # N: See https://mypy.readthedocs.io/en/stable/common_issues.html#incompatible-overrides
    @staticmethod
    def h() -> int: pass
[builtins fixtures/classmethod.pyi]

[case testOverrideStaticMethodWithClassMethod]
class A:
    @staticmethod
    def f(x: int) -> None: pass
    @staticmethod
    def g(x: str) -> int: pass
    @staticmethod
    def h() -> int: pass

class B(A):
    @classmethod
    def f(cls, x: int) -> None: pass
    @classmethod
    def g(cls, x: int) -> int: pass # E: Argument 1 of "g" is incompatible with supertype "A"; supertype defines the argument type as "str" \
                                    # N: This violates the Liskov substitution principle \
                                    # N: See https://mypy.readthedocs.io/en/stable/common_issues.html#incompatible-overrides
    @classmethod
    def h(cls) -> int: pass
[builtins fixtures/classmethod.pyi]

[case testOverrideReplaceMethod]
# flags: --show-error-codes
from typing import Optional
from typing_extensions import Self
class A:
    def __replace__(self, x: Optional[str]) -> Self: pass

class B(A):
    def __replace__(self, x: str) -> Self: pass # E: \
        # E: Argument 1 of "__replace__" is incompatible with supertype "A"; supertype defines the argument type as "Optional[str]"  [override] \
        # N: This violates the Liskov substitution principle \
        # N: See https://mypy.readthedocs.io/en/stable/common_issues.html#incompatible-overrides
[builtins fixtures/tuple.pyi]

[case testAllowCovarianceInReadOnlyAttributes]
from typing import Callable, TypeVar

T = TypeVar('T')

class X:
    pass


class Y(X):
    pass

def dec(f: Callable[..., T]) -> T: pass

class A:
    @dec
    def f(self) -> X: pass

class B(A):
    @dec
    def f(self) -> Y: pass

[case testOverrideCallableAttributeWithMethod]
from typing import Callable

class A:
    f1: Callable[[str], None]
    f2: Callable[[str], None]
    f3: Callable[[str], None]

class B(A):
    def f1(self, x: object) -> None:
        pass

    @classmethod
    def f2(cls, x: object) -> None:
        pass

    @staticmethod
    def f3(x: object) -> None:
        pass
[builtins fixtures/classmethod.pyi]

[case testOverrideCallableAttributeWithMethodMutableOverride]
# flags: --enable-error-code=mutable-override
from typing import Callable

class A:
    f1: Callable[[str], None]
    f2: Callable[[str], None]
    f3: Callable[[str], None]

class B(A):
    def f1(self, x: object) -> None: pass   # E: Covariant override of a mutable attribute (base class "A" defined the type as "Callable[[str], None]", override has type "Callable[[object], None]")

    @classmethod
    def f2(cls, x: object) -> None: pass    # E: Covariant override of a mutable attribute (base class "A" defined the type as "Callable[[str], None]", override has type "Callable[[object], None]")

    @staticmethod
    def f3(x: object) -> None: pass         # E: Covariant override of a mutable attribute (base class "A" defined the type as "Callable[[str], None]", override has type "Callable[[object], None]")
[builtins fixtures/classmethod.pyi]

[case testOverrideCallableAttributeWithSettableProperty]
from typing import Callable

class A:
    f: Callable[[str], None]

class B(A):
    @property
    def f(self) -> Callable[[object], None]: pass
    @f.setter
    def f(self, x: object) -> None: pass
[builtins fixtures/property.pyi]

[case testOverrideCallableAttributeWithSettablePropertyMutableOverride]
# flags: --enable-error-code=mutable-override
from typing import Callable

class A:
    f: Callable[[str], None]

class B(A):
    @property
    def f(self) -> Callable[[object], None]: pass
    @f.setter
    def f(self, x: object) -> None: pass
[builtins fixtures/property.pyi]

[case testOverrideCallableUnionAttributeWithMethod]
from typing import Callable, Union

class A:
    f1: Union[Callable[[str], str], str]
    f2: Union[Callable[[str], str], str]
    f3: Union[Callable[[str], str], str]
    f4: Union[Callable[[str], str], str]

class B(A):
    def f1(self, x: str) -> str:
        pass

    def f2(self, x: object) -> str:
        pass

    @classmethod
    def f3(cls, x: str) -> str:
        pass

    @staticmethod
    def f4(x: str) -> str:
        pass
[builtins fixtures/classmethod.pyi]

[case testOverrideCallableUnionAttributeWithMethodMutableOverride]
# flags: --enable-error-code=mutable-override
from typing import Callable, Union

class A:
    f1: Union[Callable[[str], str], str]
    f2: Union[Callable[[str], str], str]
    f3: Union[Callable[[str], str], str]
    f4: Union[Callable[[str], str], str]

class B(A):
    def f1(self, x: str) -> str:     # E: Covariant override of a mutable attribute (base class "A" defined the type as "Union[Callable[[str], str], str]", override has type "Callable[[str], str]")
        pass

    def f2(self, x: object) -> str:  # E: Covariant override of a mutable attribute (base class "A" defined the type as "Union[Callable[[str], str], str]", override has type "Callable[[object], str]")
        pass

    @classmethod
    def f3(cls, x: str) -> str:      # E: Covariant override of a mutable attribute (base class "A" defined the type as "Union[Callable[[str], str], str]", override has type "Callable[[str], str]")
        pass

    @staticmethod
    def f4(x: str) -> str:           # E: Covariant override of a mutable attribute (base class "A" defined the type as "Union[Callable[[str], str], str]", override has type "Callable[[str], str]")
        pass
[builtins fixtures/classmethod.pyi]

-- Constructors
-- ------------


[case testTrivialConstructor]
class A:
    def __init__(self) -> None: pass

a = A() # type: A
b = A() # type: B # E: Incompatible types in assignment (expression has type "A", variable has type "B")
class B: pass
[case testConstructor]
class A:
    def __init__(self, x: 'B') -> None: pass
class B: pass

a = A(B()) # type: A
aa = A(object()) # type: A  # E: Argument 1 to "A" has incompatible type "object"; expected "B"
b = A(B()) # type: B # E: Incompatible types in assignment (expression has type "A", variable has type "B")

[case testConstructorWithTwoArguments]
class A:
    def __init__(self, x: 'B', y: 'C') -> None: pass
class B: pass
class C(B): pass

a = A(C(), B()) # type: A  # E: Argument 2 to "A" has incompatible type "B"; expected "C"

[case testInheritedConstructor]
class B(A): pass
class C: pass
class D: pass

b = B(C()) # type: B
a = B(D()) # type: A # E: Argument 1 to "B" has incompatible type "D"; expected "C"
class A:
    def __init__(self, x: 'C') -> None: pass

[case testOverridingWithIncompatibleConstructor]
class A:
    def __init__(self, x: 'C') -> None: pass
class B(A):
    def __init__(self) -> None: pass
class C: pass

A()    # E: Missing positional argument "x" in call to "A"
B(C()) # E: Too many arguments for "B"
A(C())
B()

[case testConstructorWithReturnValueType]
import typing
class A:
    def __init__(self) -> 'A': pass
[out]
main:3: error: The return type of "__init__" must be None

[case testConstructorWithImplicitReturnValueType]
import typing
class A:
    def __init__(self, x: int): pass
[out]

[case testDecoratedConstructorWithImplicitReturnValueType]
import typing
from typing import Callable

def deco(fn: Callable) -> Callable:
    return fn

class A:
    @deco
    def __init__(self, x: int): pass
[out]

[case testOverloadedConstructorWithImplicitReturnValueType]
from foo import *
[file foo.pyi]
from typing import overload
class Foo:
    @overload
    def __init__(self, a: int):
        pass

    @overload
    def __init__(self, a: str):
        pass

[case testConstructorWithAnyReturnValueType]
import typing
from typing import Any
class A:
    def __init__(self) -> Any: pass # E: The return type of "__init__" must be None

[case testDecoratedConstructorWithAnyReturnValueType]
import typing
from typing import Callable, Any

def deco(fn: Callable) -> Callable:
    return fn

class A:
    @deco
    def __init__(self) -> Any: pass # E: The return type of "__init__" must be None

[case testOverloadedConstructorWithAnyReturnValueType]
from foo import *
[file foo.pyi]
from typing import overload, Any
class Foo:
    @overload
    def __init__(self, a: int) -> Any: # E: The return type of "__init__" must be None
        pass

    @overload
    def __init__(self, a: str) -> Any: # E: The return type of "__init__" must be None
        pass

[case testInitSubclassWithReturnValueType]
import typing
class A:
    def __init_subclass__(cls) -> 'A': pass
[out]
main:3: error: The return type of "__init_subclass__" must be None

[case testInitSubclassWithImplicitReturnValueType]
import typing
class A:
    def __init_subclass__(cls, x: int=1): pass
[out]

[case testDecoratedInitSubclassWithImplicitReturnValueType]
import typing
from typing import Callable

def deco(fn: Callable) -> Callable:
    return fn

class A:
    @deco
    def __init_subclass__(cls, x: int=1): pass
[out]

[case testOverloadedInitSubclassWithImplicitReturnValueType]
from foo import *
[file foo.pyi]
from typing import overload
class Foo:
    @overload
    def __init_subclass__(cls, a: int):
        pass

    @overload
    def __init_subclass__(cls, a: str):
        pass

[case testInitSubclassWithAnyReturnValueType]
import typing
from typing import Any
class A:
    def __init_subclass__(cls) -> Any: pass # E: The return type of "__init_subclass__" must be None

[case testDecoratedInitSubclassWithAnyReturnValueType]
import typing
from typing import Callable, Any

def deco(fn: Callable) -> Callable:
    return fn

class A:
    @deco
    def __init_subclass__(cls) -> Any: pass # E: The return type of "__init_subclass__" must be None
[out]

[case testOverloadedInitSubclassWithAnyReturnValueType]
from foo import *
[file foo.pyi]
from typing import overload, Any
class Foo:
    @overload
    def __init_subclass__(cls, a: int) -> Any: # E: The return type of "__init_subclass__" must be None
        pass

    @overload
    def __init_subclass__(cls, a: str) -> Any: # E: The return type of "__init_subclass__" must be None
        pass

[case testGlobalFunctionInitWithReturnType]
class A: pass
class B: pass
def __init__() -> 'A': pass

a = __init__() # type: A
b = __init__() # type: B # E: Incompatible types in assignment (expression has type "A", variable has type "B")
[case testAccessingInit]
from typing import Any, cast
class A:
    def __init__(self, a: 'A') -> None: pass
a: A
a.__init__(a)  # E: Accessing "__init__" on an instance is unsound, since instance.__init__ could be from an incompatible subclass
(cast(Any, a)).__init__(a)

[case testDeepInheritanceHierarchy]
class A: pass
class B(A): pass
class C(B): pass
class D(C): pass
class D2(C): pass

d = C() # type: D  # E: Incompatible types in assignment (expression has type "C", variable has type "D")
if int():
    d = B()      # E: Incompatible types in assignment (expression has type "B", variable has type "D")
if int():
    d = A()      # E: Incompatible types in assignment (expression has type "A", variable has type "D")
if int():
    d = D2()     # E: Incompatible types in assignment (expression has type "D2", variable has type "D")
a = D() # type: A
if int():
    a = D2()
b = D() # type: B
if int():
    b = D2()

[case testConstructorJoinsWithCustomMetaclass]
from typing import TypeVar
import abc

def func() -> None: pass
class NormalClass: pass
class WithMetaclass(metaclass=abc.ABCMeta): pass

T = TypeVar('T')
def join(x: T, y: T) -> T: pass

f1 = join(func, WithMetaclass)
reveal_type(f1())  # N: Revealed type is "Union[__main__.WithMetaclass, None]"

f2 = join(WithMetaclass, func)
reveal_type(f2())  # N: Revealed type is "Union[__main__.WithMetaclass, None]"

-- Attribute access in class body
-- ------------------------------


[case testDataAttributeRefInClassBody]
import typing
class B: pass
class A:
    x = B()
    y = x
    b = x # type: B
    if int():
        b = x
    c = x # type: A # E: Incompatible types in assignment (expression has type "B", variable has type "A")
    if int():
        c = b   # E: Incompatible types in assignment (expression has type "B", variable has type "A")
[out]

[case testMethodRefInClassBody]
from typing import Callable
class B: pass
class A:
    def f(self) -> None: pass
    g = f
    h = f # type: Callable[[A], None]
    if int():
        h = f
        g = h
    ff = f # type: Callable[[B], None]  # E: Incompatible types in assignment (expression has type "Callable[[A], None]", variable has type "Callable[[B], None]")
    if int():
        g = ff  # E: Incompatible types in assignment (expression has type "Callable[[B], None]", variable has type "Callable[[A], None]")
[out]


-- Arbitrary statements in class body
-- ----------------------------------


[case testStatementsInClassBody]
import typing
class B: pass
class A:
    for x in [A()]:
        y = x
        if int():
            y = B() # E: Incompatible types in assignment (expression has type "B", variable has type "A")
    if int():
        x = A()
    if int():
        y = A()
    if int():
        x = B() # E: Incompatible types in assignment (expression has type "B", variable has type "A")
[builtins fixtures/for.pyi]
[out]


-- Class attributes
-- ----------------


[case testAccessMethodViaClass]
import typing
class A:
    def f(self) -> None: pass
A.f(A())
A.f(object())     # E: Argument 1 to "f" of "A" has incompatible type "object"; expected "A"
A.f()             # E: Missing positional argument "self" in call to "f" of "A"
A.f(None, None)   # E: Too many arguments for "f" of "A" \
                  # E: Argument 1 to "f" of "A" has incompatible type "None"; expected "A"

[case testAccessAttributeViaClass]
import typing
class B: pass
class A:
    x: A
a = A.x # type: A
b = A.x # type: B # E: Incompatible types in assignment (expression has type "A", variable has type "B")

[case testAccessingUndefinedAttributeViaClass]
import typing
class A: pass
A.x # E: "type[A]" has no attribute "x"

[case testAccessingUndefinedAttributeViaClassWithOverloadedInit]
from foo import *
[file foo.pyi]
from typing import overload
class A:
    @overload
    def __init__(self): pass
    @overload
    def __init__(self, x): pass
A.x # E: "type[A]" has no attribute "x"

[case testAccessMethodOfClassWithOverloadedInit]
from foo import *
[file foo.pyi]
from typing import overload, Any
class A:
    @overload
    def __init__(self) -> None: pass
    @overload
    def __init__(self, x: Any) -> None: pass
    def f(self) -> None: pass
A.f(A())
A.f()    # E: Missing positional argument "self" in call to "f" of "A"

[case testAssignmentToClassDataAttribute]
import typing
class B: pass
class A:
    x: B
A.x = B()
A.x = object()  # E: Incompatible types in assignment (expression has type "object", variable has type "B")

[case testAssignmentToInferredClassDataAttribute]
import typing
class B: pass
class A:
     x = B()
A.x = B()
A.x = A()   # E: Incompatible types in assignment (expression has type "A", variable has type "B")

[case testInitMethodUnbound]

class B: pass
class A:
    def __init__(self, b: B) -> None: pass
a: A
b: B
A.__init__(a, b)
A.__init__(b, b) # E: Argument 1 to "__init__" of "A" has incompatible type "B"; expected "A"
A.__init__(a, a) # E: Argument 2 to "__init__" of "A" has incompatible type "A"; expected "B"

[case testAssignToMethodViaClass]
import typing
class A:
    def f(self): pass
A.f = None  # E: Cannot assign to a method \
            # E: Incompatible types in assignment (expression has type "None", variable has type "Callable[[A], Any]")

[case testAssignToNestedClassViaClass]
import typing
class A:
    class B: pass
A.B = None  # E: Cannot assign to a type \
            # E: Incompatible types in assignment (expression has type "None", variable has type "type[B]")
[targets __main__]

[case testAccessingClassAttributeWithTypeInferenceIssue]
x = C.x # E: Cannot determine type of "x" # E: Name "C" is used before definition
def f() -> int: return 1
class C:
    x = f()
[builtins fixtures/list.pyi]

[case testAccessingClassAttributeWithTypeInferenceIssue2]
class C:
    x = []
x = C.x
[builtins fixtures/list.pyi]
[out]
main:2: error: Need type annotation for "x" (hint: "x: list[<type>] = ...")

[case testAccessingGenericClassAttribute]
from typing import Generic, TypeVar
T = TypeVar('T')
class A(Generic[T]):
    x = None  # type: T
A.x  # E: Access to generic instance variables via class is ambiguous
A[int].x  # E: Access to generic instance variables via class is ambiguous
[targets __main__]

[case testAccessingNestedGenericClassAttribute]
from typing import Generic, List, TypeVar, Union
T = TypeVar('T')
U = TypeVar('U')
class A(Generic[T, U]):
    x = None  # type: Union[T, List[U]]
A.x  # E: Access to generic instance variables via class is ambiguous
A[int, int].x  # E: Access to generic instance variables via class is ambiguous
[builtins fixtures/list.pyi]


-- Nested classes
-- --------------


[case testClassWithinFunction]
def f() -> None:
    class A:
        def g(self) -> None: pass
    a: A
    a.g()
    a.g(a) # E: Too many arguments for "g" of "A"
[targets __main__, __main__.f]

[case testGenericClassWithinFunction]
from typing import TypeVar

def test() -> None:
    T = TypeVar('T', bound='Foo')
    class Foo:
        def returns_int(self) -> int:
            return 0

        def bar(self, foo: T) -> T:
            x: T = foo
            reveal_type(x)  # N: Revealed type is "T`-1"
            reveal_type(x.returns_int())  # N: Revealed type is "builtins.int"
            return foo
    reveal_type(Foo.bar)  # N: Revealed type is "def [T <: __main__.Foo@5] (self: __main__.Foo@5, foo: T`1) -> T`1"

[case testGenericClassWithInvalidTypevarUseWithinFunction]
from typing import TypeVar

def test() -> None:
    T = TypeVar('T', bound='Foo')
    class Foo:
        invalid: T  # E: Type variable "T" is unbound \
                    # N: (Hint: Use "Generic[T]" or "Protocol[T]" base class to bind "T" inside a class) \
                    # N: (Hint: Use "T" in function signature to bind "T" inside a function)

        def bar(self, foo: T) -> T:
            pass

[case testConstructNestedClass]
import typing
class A:
    class B: pass
    b = B()
    if int():
        b = A() # E: Incompatible types in assignment (expression has type "A", variable has type "B")
    if int():
        b = B(b) # E: Too many arguments for "B"
[out]

[case testConstructNestedClassWithCustomInit]
import typing
class A:
    def f(self) -> None:
        class B:
            def __init__(self, a: 'A') -> None: pass
        b = B(A())
        if int():
            b = A() # E: Incompatible types in assignment (expression has type "A", variable has type "B")
            b = B() # E: Missing positional argument "a" in call to "B"
[out]

[case testDeclareVariableWithNestedClassType]

def f() -> None:
    class A: pass
    a: A
    if int():
        a = A()
        a = object() # E: Incompatible types in assignment (expression has type "object", variable has type "A")
[out]

[case testExternalReferenceToClassWithinClass]
class A:
    class B: pass
b: A.B
if int():
    b = A.B()
if int():
    b = A() # E: Incompatible types in assignment (expression has type "A", variable has type "B")
if int():
    b = A.B(b) # E: Too many arguments for "B"

[case testAliasNestedClass]
class Outer:
    class Inner:
        def make_int(self) -> int: return 1
    reveal_type(Inner().make_int)  # N: Revealed type is "def () -> builtins.int"
    some_int = Inner().make_int()

reveal_type(Outer.Inner.make_int)  # N: Revealed type is "def (self: __main__.Outer.Inner) -> builtins.int"
reveal_type(Outer().some_int) # N: Revealed type is "builtins.int"
Bar = Outer.Inner
reveal_type(Bar.make_int)  # N: Revealed type is "def (self: __main__.Outer.Inner) -> builtins.int"
x = Bar()  # type: Bar
def produce() -> Bar:
    reveal_type(Bar().make_int)  # N: Revealed type is "def () -> builtins.int"
    return Bar()

[case testInnerClassPropertyAccess]
class Foo:
    class Meta:
        name = 'Bar'
    meta = Meta

reveal_type(Foo.Meta)  # N: Revealed type is "def () -> __main__.Foo.Meta"
reveal_type(Foo.meta)  # N: Revealed type is "def () -> __main__.Foo.Meta"
reveal_type(Foo.Meta.name)  # N: Revealed type is "builtins.str"
reveal_type(Foo.meta.name)  # N: Revealed type is "builtins.str"
reveal_type(Foo().Meta)  # N: Revealed type is "def () -> __main__.Foo.Meta"
reveal_type(Foo().meta)  # N: Revealed type is "def () -> __main__.Foo.Meta"
reveal_type(Foo().meta.name)  # N: Revealed type is "builtins.str"
reveal_type(Foo().Meta.name)  # N: Revealed type is "builtins.str"

-- Declaring attribute type in method
-- ----------------------------------


[case testDeclareAttributeTypeInInit]

class A:
    def __init__(self):
        self.x: int  # N: By default the bodies of untyped functions are not checked, consider using --check-untyped-defs
a: A
a.x = 1
a.x = '' # E: Incompatible types in assignment (expression has type "str", variable has type "int")

[case testAccessAttributeDeclaredInInitBeforeDeclaration]

a: A
a.x = 1
a.x = '' # E: Incompatible types in assignment (expression has type "str", variable has type "int")
class A:
    def __init__(self):
        self.x: int  # N: By default the bodies of untyped functions are not checked, consider using --check-untyped-defs


-- Special cases
-- -------------


[case testMultipleClassDefinition]
class A: pass
class A: pass  # E: Name "A" already defined on line 1
A()
[case testDocstringInClass]
import typing
class A:
    """Foo"""
class B:
    'x'
    y = B()
[builtins fixtures/primitives.pyi]

[case testErrorMessageInFunctionNestedWithinMethod]
import typing
class A:
    def f(self) -> None:
        def g() -> None:
            "" + 1  # E: Unsupported operand types for + ("str" and "int")
        "" + 1  # E: Unsupported operand types for + ("str" and "int")
[builtins fixtures/primitives.pyi]

-- Static methods
-- --------------


[case testSimpleStaticMethod]
import typing
class A:
  @staticmethod
  def f(x: int) -> None: pass
A.f(1)
A().f(1)
A.f('') # E: Argument 1 to "f" of "A" has incompatible type "str"; expected "int"
A().f('') # E: Argument 1 to "f" of "A" has incompatible type "str"; expected "int"
[builtins fixtures/staticmethod.pyi]

[case testBuiltinStaticMethod]
import typing
int.from_bytes(b'', '')
int.from_bytes('', '') # E: Argument 1 to "from_bytes" of "int" has incompatible type "str"; expected "bytes"
[builtins fixtures/staticmethod.pyi]

[case testAssignStaticMethodOnInstance]
import typing
class A:
  @staticmethod
  def f(x: int) -> None: pass
A().f = A.f # E: Cannot assign to a method
[builtins fixtures/staticmethod.pyi]


-- Class methods
-- -------------


[case testSimpleClassMethod]
import typing
class A:
  @classmethod
  def f(cls, x: int) -> None: pass
A.f(1)
A().f(1)
A.f('') # E: Argument 1 to "f" of "A" has incompatible type "str"; expected "int"
A().f('') # E: Argument 1 to "f" of "A" has incompatible type "str"; expected "int"
[builtins fixtures/classmethod.pyi]
[targets __main__, __main__.A.f]

[case testBuiltinClassMethod]
import typing
int.from_bytes(b'', '')
int.from_bytes('', '') # E: Argument 1 to "from_bytes" of "int" has incompatible type "str"; expected "bytes"
[builtins fixtures/classmethod.pyi]

[case testAssignClassMethodOnClass]
import typing
class A:
  @classmethod
  def f(cls, x: int) -> None: pass
A.f = A.f # E: Cannot assign to a method
[builtins fixtures/classmethod.pyi]

[case testAssignClassMethodOnInstance]
import typing
class A:
  @classmethod
  def f(cls, x: int) -> None: pass
A().f = A.f # E: Cannot assign to a method
[builtins fixtures/classmethod.pyi]

[case testClassMethodCalledInClassMethod]
import typing
class C:
  @classmethod
  def foo(cls) -> None: pass
  @classmethod
  def bar(cls) -> None:
    cls()
    cls(1)      # E: Too many arguments for "C"
    cls.bar()
    cls.bar(1)  # E: Too many arguments for "bar" of "C"
    cls.bozo()  # E: "type[C]" has no attribute "bozo"
[builtins fixtures/classmethod.pyi]
[out]

[case testClassMethodCalledOnClass]
import typing
class C:
  @classmethod
  def foo(cls) -> None: pass
C.foo()
C.foo(1)  # E: Too many arguments for "foo" of "C"
C.bozo()  # E: "type[C]" has no attribute "bozo"
[builtins fixtures/classmethod.pyi]

[case testClassMethodCalledOnInstance]
import typing
class C:
  @classmethod
  def foo(cls) -> None: pass
C().foo()
C().foo(1)  # E: Too many arguments for "foo" of "C"
C.bozo()    # E: "type[C]" has no attribute "bozo"
[builtins fixtures/classmethod.pyi]

[case testClassMethodMayCallAbstractMethod]
from abc import abstractmethod
import typing
class C:
  @classmethod
  def foo(cls) -> None:
      cls().bar()
  @abstractmethod
  def bar(self) -> None:
      pass
[builtins fixtures/classmethod.pyi]

[case testClassMethodSubclassing]
class A:
    @classmethod
    def f(cls) -> None: pass

    def g(self) -> None: pass

class B(A):
    def f(self) -> None: pass  # Fail

    @classmethod
    def g(cls) -> None: pass

class C(A):
    @staticmethod
    def f() -> None: pass
[builtins fixtures/classmethod.pyi]
[out]
main:8: error: Signature of "f" incompatible with supertype "A"
main:8: note:      Superclass:
main:8: note:          @classmethod
main:8: note:          def f(cls) -> None
main:8: note:      Subclass:
main:8: note:          def f(self) -> None

[case testClassMethodAndStaticMethod]
class C:
  @classmethod  # E: Cannot have both classmethod and staticmethod
  @staticmethod
  def foo(cls) -> None: pass
[builtins fixtures/classmethod.pyi]

-- Properties
-- ----------


[case testAccessingReadOnlyProperty]
import typing
class A:
    @property
    def f(self) -> str: pass
a = A()
reveal_type(a.f)  # N: Revealed type is "builtins.str"
[builtins fixtures/property.pyi]

[case testAssigningToReadOnlyProperty]
import typing
class A:
    @property
    def f(self) -> str: pass
A().f = '' # E: Property "f" defined in "A" is read-only
[builtins fixtures/property.pyi]

[case testAssigningToInheritedReadOnlyProperty]
class A:
    @property
    def f(self) -> str: pass
class B(A): pass
class C(A):
    @property
    def f(self) -> str: pass

A().f = '' # E: Property "f" defined in "A" is read-only
B().f = '' # E: Property "f" defined in "A" is read-only
C().f = '' # E: Property "f" defined in "C" is read-only
[builtins fixtures/property.pyi]

[case testPropertyGetterBody]
import typing
class A:
    @property
    def f(self) -> str:
        self.x = 1
        self.x = '' # E: Incompatible types in assignment (expression has type "str", variable has type "int")
        return ''
[builtins fixtures/property.pyi]

[case testPropertyNameIsChecked]
class A:
    @property
    def f(self) -> str: ...
    @not_f.setter  # E: Only supported top decorators are "@f.setter" and "@f.deleter"
    def f(self, val: str) -> None: ...

a = A()
reveal_type(a.f)  # N: Revealed type is "builtins.str"
a.f = ''  # E: Property "f" defined in "A" is read-only

class B:
    @property
    def f(self) -> str: ...
    @not_f.deleter  # E: Only supported top decorators are "@f.setter" and "@f.deleter"
    def f(self) -> None: ...

class C:
    @property
    def f(self) -> str: ...
    @not_f.setter  # E: Only supported top decorators are "@f.setter" and "@f.deleter"
    def f(self, val: str) -> None: ...
    @not_f.deleter  # E: Only supported top decorators are "@f.setter" and "@f.deleter"
    def f(self) -> None: ...
[builtins fixtures/property.pyi]

[case testPropertyAttributeIsChecked]
class A:
    @property
    def f(self) -> str: ...
    @f.unknown  # E: Only supported top decorators are "@f.setter" and "@f.deleter"
    def f(self, val: str) -> None: ...
    @f.bad.setter  # E: Only supported top decorators are "@f.setter" and "@f.deleter"
    def f(self, val: str) -> None: ...
    @f  # E: Only supported top decorators are "@f.setter" and "@f.deleter"
    def f(self, val: str) -> None: ...
    @int  # E: Only supported top decorators are "@f.setter" and "@f.deleter"
    def f(self, val: str) -> None: ...
[builtins fixtures/property.pyi]

[case testPropertyNameAndAttributeIsCheckedPretty]
# flags: --pretty
class A:
    @property
    def f(self) -> str: ...
    @not_f.setter
    def f(self, val: str) -> None: ...
    @not_f.deleter
    def f(self) -> None: ...

class B:
    @property
    def f(self) -> str: ...
    @f.unknown
    def f(self, val: str) -> None: ...
[builtins fixtures/property.pyi]
[out]
main:5: error: Only supported top decorators are "@f.setter" and "@f.deleter"
        @not_f.setter
         ^~~~~~~~~~~~
main:7: error: Only supported top decorators are "@f.setter" and "@f.deleter"
        @not_f.deleter
         ^~~~~~~~~~~~~
main:13: error: Only supported top decorators are "@f.setter" and "@f.deleter"
        @f.unknown
         ^~~~~~~~~

[case testPropertyGetterDecoratorIsRejected]
class A:
    @property
    def f(self) -> str: ...
    @f.getter  # E: Only supported top decorators are "@f.setter" and "@f.deleter"
    def f(self, val: str) -> None: ...
[builtins fixtures/property.pyi]

[case testDynamicallyTypedProperty]
import typing
class A:
    @property
    def f(self): pass
a = A()
a.f.xx
a.f = '' # E: Property "f" defined in "A" is read-only
[builtins fixtures/property.pyi]

[case testPropertyWithSetter]
import typing
class A:
    @property
    def f(self) -> int:
        return 1
    @f.setter
    def f(self, x: int) -> None:
        pass
a = A()
a.f = a.f
a.f.x # E: "int" has no attribute "x"
a.f = '' # E: Incompatible types in assignment (expression has type "str", variable has type "int")
a.f = 1
reveal_type(a.f)  # N: Revealed type is "builtins.int"
[builtins fixtures/property.pyi]

[case testPropertyWithDeleterButNoSetter]
import typing
class A:
    @property
    def f(self) -> int:
        return 1
    @f.deleter
    def f(self, x) -> None:
        pass
a = A()
a.f = a.f # E: Property "f" defined in "A" is read-only
a.f.x # E: "int" has no attribute "x"
[builtins fixtures/property.pyi]

-- Descriptors
-- -----------


[case testAccessingNonDataDescriptor]
from typing import Any
class D:
    def __get__(self, inst: Any, own: Any) -> str: return 's'
class A:
    f = D()
a = A()
reveal_type(a.f)  # N: Revealed type is "builtins.str"

[case testSettingNonDataDescriptor]
from typing import Any
class D:
    def __get__(self, inst: Any, own: Any) -> str: return 's'
class A:
    f = D()
a = A()
a.f = 'foo'
a.f = D()  # E: Incompatible types in assignment (expression has type "D", variable has type "str")

[case testSettingDataDescriptor]
from typing import Any
class D:
    def __get__(self, inst: Any, own: Any) -> str: return 's'
    def __set__(self, inst: Any, value: str) -> None: pass
class A:
    f = D()
a = A()
a.f = ''
a.f = 1 # E: Incompatible types in assignment (expression has type "int", variable has type "str")

[case testSettingDescriptorWithOverloadedDunderSet1]
from typing import Any, overload, Union
class D:
    @overload
    def __set__(self, inst: Any, value: str) -> None: pass
    @overload
    def __set__(self, inst: Any, value: int) -> None: pass
    def __set__(self, inst: Any, value: Union[str, int]) -> None: pass
class A:
    f = D()
a = A()
a.f = ''
a.f = 1
a.f = 1.5  # E
[out]
main:13: error: No overload variant of "__set__" of "D" matches argument types "A", "float"
main:13: note: Possible overload variants:
main:13: note:     def __set__(self, inst: Any, value: str) -> None
main:13: note:     def __set__(self, inst: Any, value: int) -> None

[case testSettingDescriptorWithOverloadedDunderSet2]
from typing import overload, Union
class D:
    @overload
    def __set__(self, inst: A, value: str) -> None: pass
    @overload
    def __set__(self, inst: B, value: int) -> None: pass
    def __set__(self, inst: Union[A, B], value: Union[str, int]) -> None: pass
class A:
    f = D()
class B:
    f = D()
a = A()
b = B()
a.f = ''
b.f = 1
a.f = 1   # E
b.f = ''  # E
[out]
main:16: error: No overload variant of "__set__" of "D" matches argument types "A", "int"
main:16: note: Possible overload variants:
main:16: note:     def __set__(self, inst: A, value: str) -> None
main:16: note:     def __set__(self, inst: B, value: int) -> None
main:17: error: No overload variant of "__set__" of "D" matches argument types "B", "str"
main:17: note: Possible overload variants:
main:17: note:     def __set__(self, inst: A, value: str) -> None
main:17: note:     def __set__(self, inst: B, value: int) -> None

[case testReadingDescriptorWithoutDunderGet]
from typing import Union, Any
class D:
    def __set__(self, inst: Any, value: str) -> None: pass
class A:
    f = D()
    def __init__(self): self.f = 's'
a = A()
reveal_type(a.f)  # N: Revealed type is "__main__.D"

[case testAccessingDescriptorFromClass]
from d import D, Base
class A(Base):
    f = D()
reveal_type(A.f)  # N: Revealed type is "d.D"
reveal_type(A().f)  # N: Revealed type is "builtins.str"
[file d.pyi]
from typing import TypeVar, Type, Generic, overload
class Base: pass
class D:
    def __init__(self) -> None: pass
    @overload
    def __get__(self, inst: None, own: Type[Base]) -> D: pass
    @overload
    def __get__(self, inst: Base, own: Type[Base]) -> str: pass
[builtins fixtures/bool.pyi]

[case testAccessingDescriptorFromClassWrongBase]
from d import D, Base
class A:
    f = D()
reveal_type(A.f)
reveal_type(A().f)
[file d.pyi]
from typing import TypeVar, Type, Generic, overload
class Base: pass
class D:
    def __init__(self) -> None: pass
    @overload
    def __get__(self, inst: None, own: Type[Base]) -> D: pass
    @overload
    def __get__(self, inst: Base, own: Type[Base]) -> str: pass
[builtins fixtures/bool.pyi]
[out]
main:4: error: Argument 2 to "__get__" of "D" has incompatible type "type[A]"; expected "type[Base]"
main:4: note: Revealed type is "d.D"
main:5: error: No overload variant of "__get__" of "D" matches argument types "A", "type[A]"
main:5: note: Possible overload variants:
main:5: note:     def __get__(self, inst: None, own: type[Base]) -> D
main:5: note:     def __get__(self, inst: Base, own: type[Base]) -> str
main:5: note: Revealed type is "Any"

[case testAccessingGenericNonDataDescriptor]
from typing import TypeVar, Type, Generic, Any
V = TypeVar('V')
class D(Generic[V]):
    def __init__(self, v: V) -> None: self.v = v
    def __get__(self, inst: Any, own: Type) -> V: return self.v
class A:
    f = D(10)
    g = D('10')
a = A()
reveal_type(a.f)  # N: Revealed type is "builtins.int"
reveal_type(a.g)  # N: Revealed type is "builtins.str"

[case testSettingGenericDataDescriptor]
from typing import TypeVar, Type, Generic, Any
V = TypeVar('V')
class D(Generic[V]):
    def __init__(self, v: V) -> None: self.v = v
    def __get__(self, inst: Any, own: Type) -> V: return self.v
    def __set__(self, inst: Any, v: V) -> None: pass
class A:
    f = D(10)
    g = D('10')
a = A()
a.f = 1
a.f = '' # E: Incompatible types in assignment (expression has type "str", variable has type "int")
a.g = ''
a.g = 1 # E: Incompatible types in assignment (expression has type "int", variable has type "str")

[case testAccessingGenericDescriptorFromClass]
from d import D
class A:
    f = D(10)  # type: D[A, int]
    g = D('10')  # type: D[A, str]
reveal_type(A.f)  # N: Revealed type is "d.D[__main__.A, builtins.int]"
reveal_type(A.g)  # N: Revealed type is "d.D[__main__.A, builtins.str]"
reveal_type(A().f)  # N: Revealed type is "builtins.int"
reveal_type(A().g)  # N: Revealed type is "builtins.str"
[file d.pyi]
from typing import TypeVar, Type, Generic, overload
T = TypeVar('T')
V = TypeVar('V')
class D(Generic[T, V]):
    def __init__(self, v: V) -> None: pass
    @overload
    def __get__(self, inst: None, own: Type[T]) -> 'D[T, V]': pass
    @overload
    def __get__(self, inst: T, own: Type[T]) -> V: pass
[builtins fixtures/bool.pyi]

[case testAccessingGenericDescriptorFromInferredClass]
from typing import Type
from d import D
class A:
    f = D(10)  # type: D[A, int]
    g = D('10')  # type: D[A, str]
def f(some_class: Type[A]):
    reveal_type(some_class.f)
    reveal_type(some_class.g)
[file d.pyi]
from typing import TypeVar, Type, Generic, overload
T = TypeVar('T')
V = TypeVar('V')
class D(Generic[T, V]):
    def __init__(self, v: V) -> None: pass
    @overload
    def __get__(self, inst: None, own: Type[T]) -> 'D[T, V]': pass
    @overload
    def __get__(self, inst: T, own: Type[T]) -> V: pass
[builtins fixtures/bool.pyi]
[out]
main:7: note: Revealed type is "d.D[__main__.A, builtins.int]"
main:8: note: Revealed type is "d.D[__main__.A, builtins.str]"

[case testAccessingGenericDescriptorFromClassBadOverload]
from d import D
class A:
    f = D(10)  # type: D[A, int]
reveal_type(A.f)
[file d.pyi]
from typing import TypeVar, Type, Generic, overload
T = TypeVar('T')
V = TypeVar('V')
class D(Generic[T, V]):
    def __init__(self, v: V) -> None: pass
    @overload
    def __get__(self, inst: None, own: None) -> 'D[T, V]': pass
    @overload
    def __get__(self, inst: T, own: Type[T]) -> V: pass
[builtins fixtures/bool.pyi]
[out]
main:4: error: No overload variant of "__get__" of "D" matches argument types "None", "type[A]"
main:4: note: Possible overload variants:
main:4: note:     def __get__(self, inst: None, own: None) -> D[A, int]
main:4: note:     def __get__(self, inst: A, own: type[A]) -> int
main:4: note: Revealed type is "Any"

[case testAccessingNonDataDescriptorSubclass]
from typing import Any
class C:
    def __get__(self, inst: Any, own: Any) -> str: return 's'
class D(C): pass
class A:
    f = D()
a = A()
reveal_type(a.f)  # N: Revealed type is "builtins.str"

[case testSettingDataDescriptorSubclass]
from typing import Any
class C:
    def __get__(self, inst: Any, own: Any) -> str: return 's'
    def __set__(self, inst: Any, v: str) -> None: pass
class D(C): pass
class A:
    f = D()
a = A()
a.f = ''
a.f = 1 # E: Incompatible types in assignment (expression has type "int", variable has type "str")

[case testReadingDescriptorSubclassWithoutDunderGet]
from typing import Union, Any
class C:
    def __set__(self, inst: Any, v: str) -> None: pass
class D(C): pass
class A:
    f = D()
    def __init__(self): self.f = 's'
a = A()
reveal_type(a.f)  # N: Revealed type is "__main__.D"

[case testAccessingGenericNonDataDescriptorSubclass]
from typing import TypeVar, Type, Generic, Any
V = TypeVar('V')
class C(Generic[V]):
    def __init__(self, v: V) -> None: self.v = v
    def __get__(self, inst: Any, own: Type) -> V: return self.v
class D(C[V], Generic[V]): pass
class A:
    f = D(10)
    g = D('10')
a = A()
reveal_type(a.f)  # N: Revealed type is "builtins.int"
reveal_type(a.g)  # N: Revealed type is "builtins.str"

[case testSettingGenericDataDescriptorSubclass]
from typing import TypeVar, Type, Generic
T = TypeVar('T')
V = TypeVar('V')
class C(Generic[T, V]):
    def __init__(self, v: V) -> None: self.v = v
    def __get__(self, inst: T, own: Type[T]) -> V: return self.v
    def __set__(self, inst: T, v: V) -> None: pass
class D(C[T, V], Generic[T, V]): pass
class A:
    f = D(10)  # type: D[A, int]
    g = D('10')  # type: D[A, str]
a = A()
a.f = 1
a.f = '' # E: Incompatible types in assignment (expression has type "str", variable has type "int")
a.g = ''
a.g = 1 # E: Incompatible types in assignment (expression has type "int", variable has type "str")

[case testSetDescriptorOnClass]
from typing import TypeVar, Type, Generic
T = TypeVar('T')
V = TypeVar('V')
class D(Generic[T, V]):
    def __init__(self, v: V) -> None: self.v = v
    def __get__(self, inst: T, own: Type[T]) -> V: return self.v
    def __set__(self, inst: T, v: V) -> None: pass
class A:
    f = D(10)  # type: D[A, int]
A.f = D(20)
A.f = D('some string')  # E: Argument 1 to "D" has incompatible type "str"; expected "int"

[case testSetDescriptorOnInferredClass]
from typing import TypeVar, Type, Generic, Any
V = TypeVar('V')
class D(Generic[V]):
    def __init__(self, v: V) -> None: self.v = v
    def __get__(self, inst: Any, own: Type) -> V: return self.v
    def __set__(self, inst: Any, v: V) -> None: pass
class A:
    f = D(10)
def f(some_class: Type[A]):
    A.f = D(20)
    A.f = D('some string')
[out]
main:11: error: Argument 1 to "D" has incompatible type "str"; expected "int"

[case testDescriptorUncallableDunderSet]
class D:
    __set__ = 's'
class A:
    f = D()
A().f = 'x'  # E: __main__.D.__set__ is not callable

[case testDescriptorDunderSetTooFewArgs]
class D:
    def __set__(self, inst): pass
class A:
    f = D()
A().f = 'x'  # E: Too many arguments for "__set__"

[case testDescriptorDunderSetTooManyArgs]
class D:
    def __set__(self, inst, v, other): pass
class A:
    f = D()
A().f = 'x'  # E: Too few arguments for "__set__"

[case testDescriptorDunderSetWrongArgTypes]
class D:
    def __set__(self, inst: str, v:str) -> None: pass
class A:
    f = D()
A().f = 'x'  # E: Argument 1 to "__set__" of "D" has incompatible type "A"; expected "str"

[case testDescriptorUncallableDunderGet]
class D:
    __get__ = 's'
class A:
    f = D()
A().f  # E: __main__.D.__get__ is not callable

[case testDescriptorDunderGetTooFewArgs]
class D:
    def __get__(self, inst): pass
class A:
    f = D()
A().f  # E: Too many arguments for "__get__"

[case testDescriptorDunderGetTooManyArgs]
class D:
    def __get__(self, inst, own, other): pass
class A:
    f = D()
A().f = 'x'  # E: Too few arguments for "__get__"

[case testDescriptorDunderGetWrongArgTypeForInstance]
from typing import Any
class D:
    def __get__(self, inst: str, own: Any) -> Any: pass
class A:
    f = D()
A().f  # E: Argument 1 to "__get__" of "D" has incompatible type "A"; expected "str"

[case testDescriptorDunderGetWrongArgTypeForOwner]
from typing import Any
class D:
    def __get__(self, inst: Any, own: str) -> Any: pass
class A:
    f = D()
A().f  # E: Argument 2 to "__get__" of "D" has incompatible type "type[A]"; expected "str"

[case testDescriptorGetSetDifferentTypes]
from typing import Any
class D:
    def __get__(self, inst: Any, own: Any) -> str: return 's'
    def __set__(self, inst: Any, v: int) -> None: pass
class A:
    f = D()
a = A()
a.f = 1
reveal_type(a.f)  # N: Revealed type is "builtins.str"

[case testDescriptorGetUnion]
from typing import Any, Union
class String:
    def __get__(self, inst: Any, owner: Any) -> str:
        return ''

class A:
    attr: str

class B:
    attr = String()

def foo(x: Union[A, B]) -> None:
    reveal_type(x.attr)  # N: Revealed type is "builtins.str"

[case testDescriptorGetUnionRestricted]
from typing import Any, Union

class getter:
    def __get__(self, instance: X1, owner: Any) -> str: ...

class X1:
    prop = getter()

class X2:
    prop: str

def foo(x: Union[X1, X2]) -> None:
    reveal_type(x.prop)  # N: Revealed type is "builtins.str"

[case testDescriptorGetUnionType]
from typing import Any, Union, Type, overload

class getter:
    @overload
    def __get__(self, instance: None, owner: Any) -> getter: ...
    @overload
    def __get__(self, instance: object, owner: Any) -> str: ...
    def __get__(self, instance, owner):
        ...

class X1:
    prop = getter()
class X2:
    prop = getter()

def foo(x: Type[Union[X1, X2]]) -> None:
    reveal_type(x.prop)  # N: Revealed type is "__main__.getter"


-- _promote decorators
-- -------------------


[case testSimpleDucktypeDecorator]
from typing import _promote
class A: pass
@_promote(A)
class B: pass
a: A
b: B
if int():
    b = a # E: Incompatible types in assignment (expression has type "A", variable has type "B")
    a = b
[typing fixtures/typing-medium.pyi]

[case testDucktypeTransitivityDecorator]
from typing import _promote
class A: pass
@_promote(A)
class B: pass
@_promote(B)
class C: pass
a: A
c: C
if int():
    c = a # E: Incompatible types in assignment (expression has type "A", variable has type "C")
    a = c
[typing fixtures/typing-medium.pyi]


-- Hard coded type promotions
-- --------------------------

[case testHardCodedTypePromotions]
import typing
def f(x: float) -> None: pass
def g(x: complex) -> None: pass
f(1)
g(1)
g(1.1)
[builtins fixtures/complex.pyi]


-- Operator methods
-- ----------------


[case testOperatorMethodOverrideIntroducingOverloading]
from foo import *
[file foo.pyi]
from typing import overload
class A:
    def __add__(self, x: int) -> int: pass
class B(A):
    @overload  # Fail
    def __add__(self, x: int) -> int: pass
    @overload
    def __add__(self, x: str) -> str: pass
[out]
tmp/foo.pyi:5: error: Signature of "__add__" incompatible with supertype "A"
tmp/foo.pyi:5: note:      Superclass:
tmp/foo.pyi:5: note:          def __add__(self, int, /) -> int
tmp/foo.pyi:5: note:      Subclass:
tmp/foo.pyi:5: note:          @overload
tmp/foo.pyi:5: note:          def __add__(self, int, /) -> int
tmp/foo.pyi:5: note:          @overload
tmp/foo.pyi:5: note:          def __add__(self, str, /) -> str
tmp/foo.pyi:5: note: Overloaded operator methods can't have wider argument types in overrides

[case testOperatorMethodOverrideWideningArgumentType]
import typing
class A:
    def __add__(self, x: int) -> int: pass
class B(A):
    def __add__(self, x: object) -> int: pass
[out]

[case testOperatorMethodOverrideNarrowingReturnType]
import typing
class A:
    def __add__(self, x: int) -> 'A': pass
class B(A):
    def __add__(self, x: int) -> 'B': pass

[case testOperatorMethodOverrideWithDynamicallyTyped]
import typing
class A:
    def __add__(self, x: int) -> 'A': pass
class B(A):
    def __add__(self, x): pass

[case testOperatorMethodAgainstSameType]
class A:
    def __add__(self, x: int) -> 'A':
        if isinstance(x, int):
            return A()
        else:
            return NotImplemented

    def __radd__(self, x: 'A') -> 'A':
        if isinstance(x, A):
            return A()
        else:
            return NotImplemented

class B(A): pass

# Note: This is a runtime error. If we run x.__add__(y)
# where x and y are *not* the same type, Python will not try
# calling __radd__.
A() + A()               # E: Unsupported operand types for + ("A" and "A")

# Here, Python *will* call __radd__(...)
reveal_type(B() + A())  # N: Revealed type is "__main__.A"
reveal_type(A() + B())  # N: Revealed type is "__main__.A"
[builtins fixtures/isinstance.pyi]

[case testBinaryOperatorMethodPositionalArgumentsOnly]
class A:
    def __add__(self, other: int) -> int: pass
    def __iadd__(self, other: int) -> int: pass
    def __radd__(self, other: int) -> int: pass

reveal_type(A.__add__)  # N: Revealed type is "def (__main__.A, builtins.int) -> builtins.int"
reveal_type(A.__iadd__) # N: Revealed type is "def (__main__.A, builtins.int) -> builtins.int"
reveal_type(A.__radd__) # N: Revealed type is "def (__main__.A, builtins.int) -> builtins.int"

[case testOperatorMethodOverrideWithIdenticalOverloadedType]
from foo import *
[file foo.pyi]
from typing import overload
class A:
    @overload
    def __add__(self, x: int) -> 'A': pass
    @overload
    def __add__(self, x: str) -> 'A': pass
class B(A):
    @overload
    def __add__(self, x: int) -> 'A': pass
    @overload
    def __add__(self, x: str) -> 'A': pass

[case testOverloadedOperatorMethodOverrideWithDynamicallyTypedMethod]
from foo import *
[file foo.pyi]
from typing import overload, Any
class A:
    @overload
    def __add__(self, x: int) -> 'A': pass
    @overload
    def __add__(self, x: str) -> 'A': pass
class B(A):
    def __add__(self, x): pass
class C(A):
    def __add__(self, x: Any) -> A: pass

[case testOverloadedOperatorMethodOverrideWithNewItem]
from foo import *
[file foo.pyi]
from typing import overload, Any
class A:
    @overload
    def __add__(self, x: int) -> 'A': pass
    @overload
    def __add__(self, x: str) -> 'A': pass
class B(A):
    @overload  # Fail
    def __add__(self, x: int) -> A: pass
    @overload
    def __add__(self, x: str) -> A: pass
    @overload
    def __add__(self, x: type) -> A: pass
[out]
tmp/foo.pyi:8: error: Signature of "__add__" incompatible with supertype "A"
tmp/foo.pyi:8: note:      Superclass:
tmp/foo.pyi:8: note:          @overload
tmp/foo.pyi:8: note:          def __add__(self, int, /) -> A
tmp/foo.pyi:8: note:          @overload
tmp/foo.pyi:8: note:          def __add__(self, str, /) -> A
tmp/foo.pyi:8: note:      Subclass:
tmp/foo.pyi:8: note:          @overload
tmp/foo.pyi:8: note:          def __add__(self, int, /) -> A
tmp/foo.pyi:8: note:          @overload
tmp/foo.pyi:8: note:          def __add__(self, str, /) -> A
tmp/foo.pyi:8: note:          @overload
tmp/foo.pyi:8: note:          def __add__(self, type, /) -> A
tmp/foo.pyi:8: note: Overloaded operator methods can't have wider argument types in overrides

[case testOverloadedOperatorMethodOverrideWithSwitchedItemOrder]
from foo import *
[file foo.pyi]
from typing import overload, Any
class A:
    @overload
    def __add__(self, x: 'B') -> 'B': pass
    @overload
    def __add__(self, x: 'A') -> 'A': pass
class B(A):
    @overload
    def __add__(self, x: 'A') -> 'A': pass
    @overload
    def __add__(self, x: 'B') -> 'B': pass
class C(A):
    @overload
    def __add__(self, x: 'B') -> 'B': pass
    @overload
    def __add__(self, x: 'A') -> 'A': pass
[out]
tmp/foo.pyi:8: error: Signature of "__add__" incompatible with supertype "A"
tmp/foo.pyi:8: note: Overload variants must be defined in the same order as they are in "A"
tmp/foo.pyi:11: error: Overloaded function signature 2 will never be matched: signature 1's parameter type(s) are the same or broader

[case testReverseOperatorMethodArgumentType]
from typing import Any
class A: pass
class B:
    def __radd__(self, x: A) -> int: pass # Error
class C:
    def __radd__(self, x: A) -> Any: pass
class D:
    def __radd__(self, x: A) -> object: pass
[out]

[case testReverseOperatorMethodArgumentType2]
from typing import Any, Tuple, Callable
class A:
    def __radd__(self, x: Tuple[int, str]) -> int: pass
class B:
    def __radd__(self, x: Callable[[], int]) -> int: pass
class C:
    def __radd__(self, x: Any) -> int: pass
[builtins fixtures/tuple.pyi]
[out]

[case testReverseOperatorMethodInvalid]
from foo import *
[file foo.pyi]
class A: ...
class B:
    def __rmul__(self) -> A: ...
class C:
    def __radd__(self, other, oops) -> int: ...
[out]
tmp/foo.pyi:3: error: Invalid signature "Callable[[B], A]"
tmp/foo.pyi:5: error: Invalid signature "Callable[[C, Any, Any], int]"

[case testReverseOperatorOrderingCase1]
class A:
    def __radd__(self, other: 'A') -> int: ...

# Note: Python only tries calling __add__ and never __radd__, even though it's present
A() + A()  # E: Unsupported left operand type for + ("A")

[case testReverseOperatorOrderingCase2]
class A:
    def __lt__(self, other: object) -> bool: ...

# Not all operators have the above shortcut though.
reveal_type(A() > A())   # N: Revealed type is "builtins.bool"
reveal_type(A() < A())   # N: Revealed type is "builtins.bool"
[builtins fixtures/bool.pyi]

[case testReverseOperatorOrderingCase3]
class A:
    def __add__(self, other: B) -> int: ...

class B:
    def __radd__(self, other: A) -> str: ...  # E: Signatures of "__radd__" of "B" and "__add__" of "A" are unsafely overlapping

# Normally, we try calling __add__ before __radd__
reveal_type(A() + B())  # N: Revealed type is "builtins.int"

[case testReverseOperatorOrderingCase4]
class A:
    def __add__(self, other: B) -> int: ...

class B(A):
    def __radd__(self, other: A) -> str: ...  # E: Signatures of "__radd__" of "B" and "__add__" of "A" are unsafely overlapping

# However, if B is a subtype of A, we try calling __radd__ first.
reveal_type(A() + B())  # N: Revealed type is "builtins.str"

[case testReverseOperatorOrderingCase5]
# Note: these two methods are not unsafely overlapping because __radd__ is
# never called -- see case 1.
class A:
    def __add__(self, other: B) -> int: ...
    def __radd__(self, other: A) -> str: ...

class B(A): pass

# ...but only if B specifically defines a new __radd__.
reveal_type(A() + B())  # N: Revealed type is "builtins.int"

[case testReverseOperatorOrderingCase6]
class A:
    def __add__(self, other: B) -> int: ...
    def __radd__(self, other: A) -> str: ...

class B(A):
    # Although A.__radd__ can never be called, B.__radd__ *can* be -- so the
    # unsafe overlap check kicks in here.
    def __radd__(self, other: A) -> str: ...  # E: Signatures of "__radd__" of "B" and "__add__" of "A" are unsafely overlapping

reveal_type(A() + B())  # N: Revealed type is "builtins.str"

[case testReverseOperatorOrderingCase7]
class A:
    def __add__(self, other: B) -> int: ...
    def __radd__(self, other: A) -> str: ...

class B(A):
    def __radd__(self, other: A) -> str: ...  # E: Signatures of "__radd__" of "B" and "__add__" of "A" are unsafely overlapping

class C(B): pass

# A refinement made by a parent also counts
reveal_type(A() + C())  # N: Revealed type is "builtins.str"

[case testReverseOperatorWithOverloads1]
from typing import overload

class A:
    def __add__(self, other: C) -> int: ...

class B:
    def __add__(self, other: C) -> int: ...

class C:
    @overload
    def __radd__(self, other: A) -> str: ...   # E: Signatures of "__radd__" of "C" and "__add__" of "A" are unsafely overlapping
    @overload
    def __radd__(self, other: B) -> str: ...   # E: Signatures of "__radd__" of "C" and "__add__" of "B" are unsafely overlapping
    def __radd__(self, other): pass

reveal_type(A() + C())   # N: Revealed type is "builtins.int"
reveal_type(B() + C())   # N: Revealed type is "builtins.int"

[case testReverseOperatorWithOverloads2]
from typing import overload, Union

class Num1:
    def __add__(self, other: Num1) -> Num1: ...
    def __radd__(self, other: Num1) -> Num1: ...

class Num2(Num1):
    @overload
    def __add__(self, other: Num2) -> Num2: ...
    @overload
    def __add__(self, other: Num1) -> Num2: ...
    def __add__(self, other): pass

    @overload
    def __radd__(self, other: Num2) -> Num2: ...
    @overload
    def __radd__(self, other: Num1) -> Num2: ...
    def __radd__(self, other): pass

class Num3(Num1):
    def __add__(self, other: Union[Num1, Num3]) -> Num3: ...
    def __radd__(self, other: Union[Num1, Num3]) -> Num3: ...

reveal_type(Num1() + Num2())  # N: Revealed type is "__main__.Num2"
reveal_type(Num2() + Num1())  # N: Revealed type is "__main__.Num2"

reveal_type(Num1() + Num3())  # N: Revealed type is "__main__.Num3"
reveal_type(Num3() + Num1())  # N: Revealed type is "__main__.Num3"

reveal_type(Num2() + Num3())  # N: Revealed type is "__main__.Num2"
reveal_type(Num3() + Num2())  # N: Revealed type is "__main__.Num3"

[case testReverseOperatorWithOverloads3]
from typing import Union, overload

class A:
    def __mul__(self, value: A, /) -> A: ...
    def __rmul__(self, value: A, /) -> A: ...

class B:
    @overload
    def __mul__(self, other: B, /) -> B: ...
    @overload
    def __mul__(self, other: A, /) -> str: ...
    def __mul__(self, other: Union[B, A], /) -> Union[B, str]: pass

    @overload
    def __rmul__(self, other: B, /) -> B: ...
    @overload
    def __rmul__(self, other: A, /) -> str: ...
    def __rmul__(self, other: Union[B, A], /) -> Union[B, str]: pass

[case testReverseOperatorWithOverloadsNested]
from typing import Union, overload

class A:
    def __mul__(self, value: A, /) -> A: ...
    def __rmul__(self, value: A, /) -> A: ...

class B:
    @overload
    def __mul__(self, other: B, /) -> B: ...
    @overload
    def __mul__(self, other: A, /) -> str: ...
    def __mul__(self, other: Union[B, A], /) -> Union[B, str]: pass

    @overload
    def __rmul__(self, other: B, /) -> B: ...
    @overload
    def __rmul__(self, other: A, /) -> str: ...
    def __rmul__(self, other: Union[B, A], /) -> Union[B, str]:
        class A1:
            def __add__(self, other: C1) -> int: ...

        class B1:
            def __add__(self, other: C1) -> int: ...

        class C1:
            @overload
            def __radd__(self, other: A1) -> str: ...   # E: Signatures of "__radd__" of "C1" and "__add__" of "A1" are unsafely overlapping
            @overload
            def __radd__(self, other: B1) -> str: ...   # E: Signatures of "__radd__" of "C1" and "__add__" of "B1" are unsafely overlapping
            def __radd__(self, other): pass

        return ""

[case testDivReverseOperator]
# No error: __div__ has no special meaning in Python 3
class A1:
    def __div__(self, x: B1) -> int: ...
class B1:
    def __rdiv__(self, x: A1) -> str: ...

class A2:
    def __truediv__(self, x: B2) -> int: ...
class B2:
    def __rtruediv__(self, x: A2) -> str: ...  # E: Signatures of "__rtruediv__" of "B2" and "__truediv__" of "A2" are unsafely overlapping

A1() / B1()                 # E: Unsupported left operand type for / ("A1")
reveal_type(A2() / B2())    # N: Revealed type is "builtins.int"

[case testReverseOperatorMethodForwardIsAny]
from typing import Any
def deco(f: Any) -> Any: return f
class C:
    @deco
    def __add__(self, other: C) -> C: return C()
    def __radd__(self, other: C) -> C: return C()
[out]

[case testReverseOperatorMethodForwardIsAny2]
from typing import Any
def deco(f: Any) -> Any: return f
class C:
    __add__ = None  # type: Any
    def __radd__(self, other: C) -> C: return C()
[out]

[case testReverseOperatorMethodForwardIsAny3]
from typing import Any
def deco(f: Any) -> Any: return f
class C:
    __add__ = 42
    def __radd__(self, other: C) -> C: return C()
[out]
main:5: error: Forward operator "__add__" is not callable

[case testOverloadedReverseOperatorMethodArgumentType]
from foo import *
[file foo.pyi]
from typing import overload, Any
class A:
    @overload
    def __radd__(self, x: 'A') -> str: pass
    @overload
    def __radd__(self, x: 'A') -> Any: pass  # E: Overloaded function signature 2 will never be matched: signature 1's parameter type(s) are the same or broader
[out]

[case testReverseOperatorMethodArgumentTypeAndOverloadedMethod]
from foo import *
[file foo.pyi]
from typing import overload
class A:
    @overload
    def __add__(self, x: int) -> int: pass
    @overload
    def __add__(self, x: str) -> int: pass
    def __radd__(self, x: 'A') -> str: pass

[case testReverseOperatorStar]
class B:
    def __radd__(*self) -> int: pass
    def __rsub__(*self: 'B') -> int: pass
[builtins fixtures/tuple.pyi]

[case testReverseOperatorTypeVar1]
from typing import TypeVar
T = TypeVar("T", bound='Real')
class Real:
    def __add__(self, other: object) -> str: ...
class Fraction(Real):
    def __radd__(self, other: T) -> T: ...  # E: Signatures of "__radd__" of "Fraction" and "__add__" of "T" are unsafely overlapping

# Note: When doing A + B and if B is a subtype of A, we will always call B.__radd__(A) first
# and only try A.__add__(B) second if necessary.
reveal_type(Real() + Fraction())      # N: Revealed type is "__main__.Real"

# Note: When doing A + A, we only ever call A.__add__(A), never A.__radd__(A).
reveal_type(Fraction() + Fraction())  # N: Revealed type is "builtins.str"

[case testReverseOperatorTypeVar2a]
from typing import TypeVar
T = TypeVar("T", bound='Real')
class Real:
    def __add__(self, other: Fraction) -> str: ...
class Fraction(Real):
    def __radd__(self, other: T) -> T: ...  # E: Signatures of "__radd__" of "Fraction" and "__add__" of "T" are unsafely overlapping

reveal_type(Real() + Fraction())      # N: Revealed type is "__main__.Real"
reveal_type(Fraction() + Fraction())  # N: Revealed type is "builtins.str"


[case testReverseOperatorTypeVar2b]
from typing import TypeVar
T = TypeVar("T", "Real", "Fraction")
class Real:
    def __add__(self, other: Fraction) -> str: ...
class Fraction(Real):
    def __radd__(self, other: T) -> T: ...  # E: Signatures of "__radd__" of "Fraction" and "__add__" of "Real" are unsafely overlapping

reveal_type(Real() + Fraction())      # N: Revealed type is "__main__.Real"
reveal_type(Fraction() + Fraction())  # N: Revealed type is "builtins.str"

[case testReverseOperatorTypeVar3]
from typing import TypeVar
T = TypeVar("T", bound='Real')
class Real:
    def __add__(self, other: FractionChild) -> str: ...
class Fraction(Real):
    def __radd__(self, other: T) -> T: ...  # E: Signatures of "__radd__" of "Fraction" and "__add__" of "T" are unsafely overlapping
class FractionChild(Fraction): pass

reveal_type(Real() + Fraction())                # N: Revealed type is "__main__.Real"
reveal_type(FractionChild() + Fraction())       # N: Revealed type is "__main__.FractionChild"
reveal_type(FractionChild() + FractionChild())  # N: Revealed type is "builtins.str"

# Runtime error: we try calling __add__, it doesn't match, and we don't try __radd__ since
# the LHS and the RHS are not the same.
Fraction() + Fraction()                         # E: Unsupported operand types for + ("Fraction" and "Fraction")

[case testReverseOperatorTypeType]
from typing import TypeVar, Type
class Real(type):
    def __add__(self, other: FractionChild) -> str: ...
class Fraction(Real):
    def __radd__(self, other: Type['A']) -> Real: ...  # E: Signatures of "__radd__" of "Fraction" and "__add__" of "type[A]" are unsafely overlapping
class FractionChild(Fraction): pass

class A(metaclass=Real): pass

[case testOperatorDoubleUnionIntFloat]
from typing import Union

a: Union[int, float]
b: int
c: float

reveal_type(a + a)  # N: Revealed type is "Union[builtins.int, builtins.float]"
reveal_type(a + b)  # N: Revealed type is "Union[builtins.int, builtins.float]"
reveal_type(b + a)  # N: Revealed type is "Union[builtins.int, builtins.float]"
reveal_type(a + c)  # N: Revealed type is "builtins.float"
reveal_type(c + a)  # N: Revealed type is "builtins.float"
[builtins fixtures/ops.pyi]

[case testOperatorDoubleUnionStandardSubtyping]
from typing import Union

class Parent:
    def __add__(self, x: Parent) -> Parent: pass
    def __radd__(self, x: Parent) -> Parent: pass

class Child(Parent):
    def __add__(self, x: Parent) -> Child: pass
    def __radd__(self, x: Parent) -> Child: pass

a: Union[Parent, Child]
b: Parent
c: Child

reveal_type(a + a)  # N: Revealed type is "__main__.Parent"
reveal_type(a + b)  # N: Revealed type is "__main__.Parent"
reveal_type(b + a)  # N: Revealed type is "__main__.Parent"
reveal_type(a + c)  # N: Revealed type is "__main__.Child"
reveal_type(c + a)  # N: Revealed type is "__main__.Child"

[case testOperatorDoubleUnionNoRelationship1]
from typing import Union

class Foo:
    def __add__(self, x: Foo) -> Foo: pass
    def __radd__(self, x: Foo) -> Foo: pass

class Bar:
    def __add__(self, x: Bar) -> Bar: pass
    def __radd__(self, x: Bar) -> Bar: pass

a: Union[Foo, Bar]
b: Foo
c: Bar

a + a  # E: Unsupported operand types for + ("Foo" and "Bar") \
       # E: Unsupported operand types for + ("Bar" and "Foo") \
       # N: Both left and right operands are unions

a + b  # E: Unsupported operand types for + ("Bar" and "Foo") \
       # N: Left operand is of type "Union[Foo, Bar]"

b + a  # E: Unsupported operand types for + ("Foo" and "Bar") \
       # N: Right operand is of type "Union[Foo, Bar]"

a + c  # E: Unsupported operand types for + ("Foo" and "Bar") \
       # N: Left operand is of type "Union[Foo, Bar]"

c + a  # E: Unsupported operand types for + ("Bar" and "Foo") \
       # N: Right operand is of type "Union[Foo, Bar]"

[case testOperatorDoubleUnionNoRelationship2]
from typing import Union

class Foo:
    def __add__(self, x: Foo) -> Foo: pass
    def __radd__(self, x: Foo) -> Foo: pass

class Bar:
    def __add__(self, x: Union[Foo, Bar]) -> Bar: pass
    def __radd__(self, x: Union[Foo, Bar]) -> Bar: pass

a: Union[Foo, Bar]
b: Foo
c: Bar

reveal_type(a + a)  # N: Revealed type is "Union[__main__.Foo, __main__.Bar]"
reveal_type(a + b)  # N: Revealed type is "Union[__main__.Foo, __main__.Bar]"
reveal_type(b + a)  # N: Revealed type is "Union[__main__.Foo, __main__.Bar]"
reveal_type(a + c)  # N: Revealed type is "__main__.Bar"
reveal_type(c + a)  # N: Revealed type is "__main__.Bar"

[case testOperatorDoubleUnionNaiveAdd]
from typing import Union

class A: pass
class B: pass
class C:
    def __radd__(self, x: A) -> int: pass
class D:
    def __radd__(self, x: B) -> str: pass

x: Union[A, B]
y: Union[C, D]

x + y  # E: Unsupported operand types for + ("A" and "D") \
       # E: Unsupported operand types for + ("B" and "C") \
       # N: Both left and right operands are unions

[case testOperatorDoubleUnionInterwovenUnionAdd]
from typing import Union

class Out1: pass
class Out2: pass
class Out3: pass
class Out4: pass

class A:
    def __add__(self, x: D) -> Out1: pass
class B:
    def __add__(self, x: C) -> Out2: pass
class C:
    def __radd__(self, x: A) -> Out3: pass
class D:
    def __radd__(self, x: B) -> Out4: pass

x: Union[A, B]
y: Union[C, D]

reveal_type(x + y)    # N: Revealed type is "Union[__main__.Out3, __main__.Out1, __main__.Out2, __main__.Out4]"
reveal_type(A() + y)  # N: Revealed type is "Union[__main__.Out3, __main__.Out1]"
reveal_type(B() + y)  # N: Revealed type is "Union[__main__.Out2, __main__.Out4]"
reveal_type(x + C())  # N: Revealed type is "Union[__main__.Out3, __main__.Out2]"
reveal_type(x + D())  # N: Revealed type is "Union[__main__.Out1, __main__.Out4]"

[case testOperatorDoubleUnionDivision]
from typing import Union
def f(a):
    # type: (Union[int, float]) -> None
    a /= 1.1
    b = a / 1.1
    reveal_type(b)  # N: Revealed type is "builtins.float"
[builtins fixtures/ops.pyi]

[case testOperatorWithInference]
from typing import TypeVar, Iterable, Union

T = TypeVar('T')
def sum(x: Iterable[T]) -> Union[T, int]: ...

def len(x: Iterable[T]) -> int: ...

x = [1.1, 2.2, 3.3]
reveal_type(sum(x))  # N: Revealed type is "Union[builtins.float, builtins.int]"
reveal_type(sum(x) / len(x))  # N: Revealed type is "Union[builtins.float, builtins.int]"
[builtins fixtures/floatdict.pyi]

[case testOperatorWithEmptyListAndSum]
from typing import TypeVar, Iterable, Union, overload

T = TypeVar('T')
S = TypeVar('S')
@overload
def sum(x: Iterable[T]) -> Union[T, int]: ...
@overload
def sum(x: Iterable[T], default: S) -> Union[T, S]: ...
def sum(*args): pass

x = ["a", "b", "c"]
reveal_type(x + sum([x, x, x], []))  # N: Revealed type is "builtins.list[builtins.str]"
[builtins fixtures/floatdict.pyi]

[case testAbstractReverseOperatorMethod]
import typing
from abc import abstractmethod
class A:
    @abstractmethod
    def __lt__(self, x: 'A') -> int: pass
class B:
    @abstractmethod
    def __lt__(self, x: 'B') -> int: pass
    @abstractmethod
    def __gt__(self, x: 'B') -> int: pass
[out]

[case testOperatorMethodsAndOverloadingSpecialCase]
from foo import *
[file foo.pyi]
from typing import overload
class A:
    @overload
    def __add__(self, x: 'A') -> int: pass
    @overload
    def __add__(self, x: str) -> int: pass
class B:
    def __radd__(self, x: 'A') -> str: pass
[out]

[case testUnsafeOverlappingWithOperatorMethodsAndOverloading2]
from foo import A, B
from foo import *
[file foo.pyi]
from typing import overload
class A:
    def __add__(self, x: 'A') -> int: pass
class B:
    @overload
    def __radd__(self, x: 'X') -> str: pass # Error
    @overload
    def __radd__(self, x: A) -> str: pass   # Error
class X:
    def __add__(self, x: B) -> int: pass
[out]
tmp/foo.pyi:6: error: Signatures of "__radd__" of "B" and "__add__" of "X" are unsafely overlapping

[case testUnsafeOverlappingNotWithAny]
from typing import TypeVar
class Real:
    def __add__(self, other) -> str: ...
class Fraction(Real):
    def __radd__(self, other: Real) -> Real: ...

[case testOverlappingNormalAndInplaceOperatorMethod]
import typing
class A:
    # Incompatible (potential trouble with __radd__)
    def __add__(self, x: 'A') -> int: pass
    def __iadd__(self, x: 'B') -> int: pass
class B:
    # Safe
    def __add__(self, x: 'C') -> int: pass
    def __iadd__(self, x: A) -> int: pass
class C(A): pass
[out]
main:5: error: Signatures of "__iadd__" and "__add__" are incompatible

[case testOverloadedNormalAndInplaceOperatorMethod]
from foo import *
[file foo.pyi]
from typing import overload
class A:
    @overload
    def __add__(self, x: int) -> int: pass
    @overload
    def __add__(self, x: str) -> int: pass
    @overload # Error
    def __iadd__(self, x: int) -> int: pass
    @overload
    def __iadd__(self, x: object) -> int: pass
class B:
    @overload
    def __add__(self, x: int) -> int: pass
    @overload
    def __add__(self, x: str) -> str: pass
    @overload
    def __iadd__(self, x: int) -> int: pass
    @overload
    def __iadd__(self, x: str) -> str: pass
[out]
tmp/foo.pyi:7: error: Signatures of "__iadd__" and "__add__" are incompatible

[case testIntroducingInplaceOperatorInSubclass]
import typing
class A:
    def __add__(self, x: 'A') -> 'B': pass
class B(A):
    # __iadd__ effectively partially overrides __add__
    def __iadd__(self, x: 'A') -> 'A': pass # Error
class C(A):
    def __iadd__(self, x: int) -> 'B': pass # Error
class D(A):
    def __iadd__(self, x: 'A') -> 'B': pass
[out]
main:6: error: Return type "A" of "__iadd__" incompatible with return type "B" in "__add__" of supertype "A"
main:8: error: Signatures of "__iadd__" and "__add__" are incompatible
main:8: error: Argument 1 of "__iadd__" is incompatible with "__add__" of supertype "A"; supertype defines the argument type as "A"
main:8: note: This violates the Liskov substitution principle
main:8: note: See https://mypy.readthedocs.io/en/stable/common_issues.html#incompatible-overrides

[case testGetattribute]
a: A
b: B
class A:
    def __getattribute__(self, x: str) -> A:
        return A()
class B: pass

a = a.foo
b = a.bar
[builtins fixtures/tuple.pyi]
[out]
main:9: error: Incompatible types in assignment (expression has type "A", variable has type "B")

[case testDecoratedGetAttribute]
from typing import Callable, TypeVar

T = TypeVar('T', bound=Callable)

def decorator(f: T) -> T:
    return f

def bad(f: Callable) -> Callable[..., int]:
    return f

class A:
    @decorator
    def __getattribute__(self, x: str) -> A:
        return A()
class B:
    @bad  # We test that type will be taken from decorated type, not node itself
    def __getattribute__(self, x: str) -> A:
        return A()

a: A
b: B

a1: A = a.foo
b1: B = a.bar  # E: Incompatible types in assignment (expression has type "A", variable has type "B")
a2: A = b.baz  # E: Incompatible types in assignment (expression has type "int", variable has type "A")
b2: B = b.roo  # E: Incompatible types in assignment (expression has type "int", variable has type "B")
[builtins fixtures/tuple.pyi]

[case testGetattributeSignature]
class A:
    def __getattribute__(self, x: str) -> A: pass
class B:
    def __getattribute__(self, x: A) -> B: pass
class C:
    def __getattribute__(self, x: str, y: str) -> C: pass
class D:
    def __getattribute__(self, x: str) -> None: pass
[out]
main:4: error: Invalid signature "Callable[[B, A], B]" for "__getattribute__"
main:6: error: Invalid signature "Callable[[C, str, str], C]" for "__getattribute__"

[case testGetattr]
a: A
b: B
class A:
    def __getattr__(self, x: str) -> A:
        return A()
class B: pass

a = a.foo
b = a.bar
[builtins fixtures/tuple.pyi]
[out]
main:9: error: Incompatible types in assignment (expression has type "A", variable has type "B")

[case testDecoratedGetattr]
from typing import Callable, TypeVar

T = TypeVar('T', bound=Callable)

def decorator(f: T) -> T:
    return f

def bad(f: Callable) -> Callable[..., int]:
    return f

class A:
    @decorator
    def __getattr__(self, x: str) -> A:
        return A()
class B:
    @bad  # We test that type will be taken from decorated type, not node itself
    def __getattr__(self, x: str) -> A:
        return A()

a: A
b: B

a1: A = a.foo
b1: B = a.bar  # E: Incompatible types in assignment (expression has type "A", variable has type "B")
a2: A = b.baz  # E: Incompatible types in assignment (expression has type "int", variable has type "A")
b2: B = b.roo  # E: Incompatible types in assignment (expression has type "int", variable has type "B")
[builtins fixtures/tuple.pyi]

[case testGetattrWithGetitem]
class A:
    def __getattr__(self, x: str) -> 'A':
        return A()

a = A()
a[0]  # E: Value of type "A" is not indexable

[case testGetattrWithCall]
class A:
    def __getattr__(self, x: str) -> 'A':
        return A()

a = A()
a.y()  # E: "A" not callable

[case testGetattrWithCallable]
from typing import Callable, Any

class C:
    def __getattr__(self, attr: str) -> C: ...

def do(cd: Callable[..., Any]) -> None: ...

do(C())  # E: Argument 1 to "do" has incompatible type "C"; expected "Callable[..., Any]"

[case testGetattrWithCallableTypeVar]
from typing import Callable, Any, TypeVar

class C:
    def __getattr__(self, attr: str) -> C: ...

T = TypeVar('T', bound=Callable[..., Any])

def do(cd: T) -> T: ...

do(C())  # E: Value of type variable "T" of "do" cannot be "C"

[case testNestedGetattr]
def foo() -> object:
    def __getattr__() -> None:  # no error because not in a class
        pass
    return __getattr__

class X:
    def foo(self) -> object:
        def __getattr__() -> None:  # no error because not directly inside a class
            pass
        return __getattr__

[case testGetattrSignature]
class A:
    def __getattr__(self, x: str) -> A: pass
class B:
    def __getattr__(self, x: A) -> B: pass
class C:
    def __getattr__(self, x: str, y: str) -> C: pass
class D:
    def __getattr__(self, x: str) -> None: pass
[out]
main:4: error: Invalid signature "Callable[[B, A], B]" for "__getattr__"
main:6: error: Invalid signature "Callable[[C, str, str], C]" for "__getattr__"

[case testSetattr]
from typing import Union, Any
class A:
    def __setattr__(self, name: str, value: Any) -> None: ...

a = A()
a.test = 'hello'

class B:
   def __setattr__(self, name: str, value: Union[int, str]) -> None: ...

b = B()
b.both = 1
b.work = '2'

class C:
    def __setattr__(self, name: str, value: str) -> None: ...

c = C()
c.fail = 4  # E: Incompatible types in assignment (expression has type "int", variable has type "str")

class D:
    __setattr__ = 'hello'  # E: Invalid signature "str" for "__setattr__"

d = D()
d.crash = 4  # E: "D" has no attribute "crash"

class Ex:
    def __setattr__(self, name: str, value: int) -> None:...
    test = '42'  # type: str
e = Ex()
e.test = 'hello'
e.t = 4

class Super:
    def __setattr__(self, name: str, value: int) -> None: ...

class Sub(Super):
    ...
s = Sub()
s.success = 4
s.fail = 'fail'  # E: Incompatible types in assignment (expression has type "str", variable has type "int")

[case testDecoratedSetattr]
from typing import Any, Callable, TypeVar

T = TypeVar('T', bound=Callable)

def decorator(f: T) -> T:
    return f

def bad(f: Callable) -> Callable[[Any, str, int], None]:
    return f

class A:
    @decorator
    def __setattr__(self, k: str, v: str) -> None:
        pass
class B:
    @bad  # We test that type will be taken from decorated type, not node itself
    def __setattr__(self, k: str, v: str) -> None:
        pass

a: A
a.foo = 'a'
a.bar = 1  # E: Incompatible types in assignment (expression has type "int", variable has type "str")

b: B
b.good = 1
b.bad = 'a'  # E: Incompatible types in assignment (expression has type "str", variable has type "int")
[builtins fixtures/tuple.pyi]

[case testSetattrSignature]
from typing import Any

class Test:
    def __setattr__() -> None: ... \
        # E: Invalid signature "Callable[[], None]" for "__setattr__" \
        # E: Method must have at least one argument. Did you forget the "self" argument?

t = Test()
t.crash = 'test'  # E: Attribute function "__setattr__" with type "Callable[[], None]" does not accept self argument \
                  # E: "Test" has no attribute "crash"

class A:
    def __setattr__(self): ...  # E: Invalid signature "Callable[[A], Any]" for "__setattr__"
a = A()
a.test = 4  # E: "A" has no attribute "test"

class B:
    def __setattr__(self, name, value: int): ...
b = B()
b.integer = 5

class C:
    def __setattr__(self, name: int, value: int) -> None: ...  # E: Invalid signature "Callable[[C, int, int], None]" for "__setattr__"
c = C()
c.check = 13

class X:
    __setattr__ = ...  # type: Any

[case testGetattrAndSetattr]
from typing import Any
class A:
    def __setattr__(self, name: str, value: Any) -> None: ...
    def __getattr__(self, name: str) -> Any: ...
a = A()
a.test = 4
t = a.test

class B:
    def __setattr__(self, name: str, value: int) -> None: ...
    def __getattr__(self, name: str) -> str: ...
integer = 0
b = B()
b.at = '3'  # E: Incompatible types in assignment (expression has type "str", variable has type "int")
if int():
    integer = b.at  # E: Incompatible types in assignment (expression has type "str", variable has type "int")

[case testSetattrKeywordArg]
from typing import Any

class C:
    def __setattr__(self, key: str, value: Any, p: bool = False) -> None: ...

c: C
c.__setattr__("x", 42, p=True)

-- CallableType objects
-- ----------------


[case testCallableObject]
class A:
    def __call__(self, x: 'A') -> 'A':
        pass
class B: pass

a = A()
b = B()

a()  # E: Missing positional argument "x" in call to "__call__" of "A"
a(a, a)  # E: Too many arguments for "__call__" of "A"
if int():
    a = a(a)
if int():
    a = a(b)  # E: Argument 1 to "__call__" of "A" has incompatible type "B"; expected "A"
if int():
    b = a(a)  # E: Incompatible types in assignment (expression has type "A", variable has type "B")


-- __new__
-- --------


[case testConstructInstanceWith__new__]
from typing import Optional
class C:
    def __new__(cls, foo: Optional[int] = None) -> 'C':
        obj = object.__new__(cls)
        return obj

x = C(foo=12)
x.a # E: "C" has no attribute "a"
C(foo='') # E: Argument "foo" to "C" has incompatible type "str"; expected "Optional[int]"
[builtins fixtures/__new__.pyi]

[case testConstructInstanceWithDynamicallyTyped__new__]
class C:
    def __new__(cls, foo):  # N: "C" defined here
        obj = object.__new__(cls)
        return obj

x = C(foo=12)
x = C(foo='x')
x.a # E: "C" has no attribute "a"
C(bar='') # E: Unexpected keyword argument "bar" for "C"
[builtins fixtures/__new__.pyi]

[case testClassWith__new__AndCompatibilityWithType]
from typing import Optional
class C:
    def __new__(cls, foo: Optional[int] = None) -> 'C':
        obj = object.__new__(cls)
        return obj
def f(x: type) -> None: pass
def g(x: int) -> None: pass
f(C)
g(C) # E: Argument 1 to "g" has incompatible type "type[C]"; expected "int"
[builtins fixtures/__new__.pyi]

[case testClassWith__new__AndCompatibilityWithType2]
class C:
    def __new__(cls, foo):
        obj = object.__new__(cls)
        return obj
def f(x: type) -> None: pass
def g(x: int) -> None: pass
f(C)
g(C) # E: Argument 1 to "g" has incompatible type "type[C]"; expected "int"
[builtins fixtures/__new__.pyi]

[case testGenericClassWith__new__]
from typing import TypeVar, Generic
T = TypeVar('T')
class C(Generic[T]):
    def __new__(cls, foo: T) -> 'C[T]':
        obj = object.__new__(cls)
        return obj
    def set(self, x: T) -> None: pass
c = C('')
c.set('')
c.set(1) # E: Argument 1 to "set" of "C" has incompatible type "int"; expected "str"
[builtins fixtures/__new__.pyi]

[case testOverloaded__new__]
from foo import *
[file foo.pyi]
from typing import overload
class C:
    @overload
    def __new__(cls, foo: int) -> 'C':
        obj = object.__new__(cls)
        return obj
    @overload
    def __new__(cls, x: str, y: str) -> 'C':
        obj = object.__new__(cls)
        return obj
c = C(1)
c.a # E: "C" has no attribute "a"
C('', '')
C('') # E: No overload variant of "C" matches argument type "str" \
      # N: Possible overload variants: \
      # N:     def __new__(cls, foo: int) -> C \
      # N:     def __new__(cls, x: str, y: str) -> C
[builtins fixtures/__new__.pyi]


-- Special cases
-- -------------


[case testSubclassInt]
import typing
class A(int): pass
n = 0
if int():
    n = A()
a = A()
if int():
    a = 0 # E: Incompatible types in assignment (expression has type "int", variable has type "A")

[case testForwardReferenceToNestedClass]
def f(o: 'B.C') -> None:
    o.f('') # E: Argument 1 to "f" of "C" has incompatible type "str"; expected "int"

class B:
    class C:
        def f(self, x: int) -> None: pass
[out]

[case testForwardReferenceToNestedClassDeep]
def f(o: 'B.C.D') -> None:
    o.f('') # E: Argument 1 to "f" of "D" has incompatible type "str"; expected "int"

class B:
    class C:
        class D:
            def f(self, x: int) -> None: pass
[out]

[case testForwardReferenceToNestedClassWithinClass]
class B:
    def f(self, o: 'C.D') -> None:
        o.f('') # E: Argument 1 to "f" of "D" has incompatible type "str"; expected "int"

    class C:
        class D:
            def f(self, x: int) -> None: pass
[out]

[case testClassVsInstanceDisambiguation]
class A: pass
def f(x: A) -> None: pass
f(A) # E: Argument 1 to "f" has incompatible type "type[A]"; expected "A"
[out]

-- TODO
--   attribute inherited from superclass; assign in __init__
--   refer to attribute before type has been inferred (the initialization in
--   __init__ has not been analyzed)

[case testAnyBaseClassUnconstrainedConstructor]
from typing import Any
B = None  # type: Any
class C(B): pass
C(0)
C(arg=0)
[out]

[case testErrorMapToSupertype]
import typing
class X(Nope): pass  # E: Name "Nope" is not defined
a, b = X()  # Used to crash here (#2244)


-- Class-valued attributes
-- -----------------------

[case testClassValuedAttributesBasics]
class A: ...
class B:
    a = A
    bad = lambda: 42

B().bad() # E: Attribute function "bad" with type "Callable[[], int]" does not accept self argument
reveal_type(B.a) # N: Revealed type is "def () -> __main__.A"
reveal_type(B().a) # N: Revealed type is "def () -> __main__.A"
reveal_type(B().a()) # N: Revealed type is "__main__.A"

class C:
    a = A
    def __init__(self) -> None:
        self.aa = self.a()

reveal_type(C().aa) # N: Revealed type is "__main__.A"
[out]

[case testClassValuedAttributesGeneric]
from typing import Generic, TypeVar, Type
T = TypeVar('T')

class A(Generic[T]):
    def __init__(self, x: T) -> None:
        self.x = x
class B(Generic[T]):
    a: Type[A[T]] = A

reveal_type(B[int]().a) # N: Revealed type is "type[__main__.A[builtins.int]]"
B[int]().a('hi') # E: Argument 1 to "A" has incompatible type "str"; expected "int"

class C(Generic[T]):
    a = A
    def __init__(self) -> None:
        self.aa = self.a(42)

reveal_type(C().aa) # N: Revealed type is "__main__.A[builtins.int]"
[out]

[case testClassValuedAttributesAlias]
from typing import Generic, TypeVar
T = TypeVar('T')
S = TypeVar('S')

class A(Generic[T, S]): ...

SameA = A[T, T]

class B:
    a_any = SameA
    a_int = SameA[int]

reveal_type(B().a_any) # N: Revealed type is "def () -> __main__.A[Any, Any]"
reveal_type(B().a_int()) # N: Revealed type is "__main__.A[builtins.int, builtins.int]"

class C:
    a_int = SameA[int]
    def __init__(self) -> None:
        self.aa = self.a_int()

reveal_type(C().aa) # N: Revealed type is "__main__.A[builtins.int, builtins.int]"
[out]


-- Type[C]
-- -------


[case testTypeUsingTypeCBasic]
from typing import Type
class User: pass
class ProUser(User): pass
def new_user(user_class: Type[User]) -> User:
    return user_class()
reveal_type(new_user(User))  # N: Revealed type is "__main__.User"
reveal_type(new_user(ProUser))  # N: Revealed type is "__main__.User"
[out]

[case testTypeUsingTypeCDefaultInit]
from typing import Type
class B:
    pass
def f(A: Type[B]) -> None:
    A(0)  # E: Too many arguments for "B"
    A()
[out]

[case testTypeUsingTypeCInitWithArg]
from typing import Type
class B:
    def __init__(self, a: int) -> None: pass
def f(A: Type[B]) -> None:
    A(0)
    A()  # E: Missing positional argument "a" in call to "B"
[out]

[case testTypeUsingTypeCTypeVar]
from typing import Type, TypeVar
class User: pass
class ProUser(User): pass
U = TypeVar('U', bound=User)
def new_user(user_class: Type[U]) -> U:
    user = user_class()
    reveal_type(user)
    return user
pro_user = new_user(ProUser)
reveal_type(pro_user)
[out]
main:7: note: Revealed type is "U`-1"
main:10: note: Revealed type is "__main__.ProUser"

[case testTypeUsingTypeCTypeVarDefaultInit]
from typing import Type, TypeVar
class B:
    pass
T = TypeVar('T', bound=B)
def f(A: Type[T]) -> None:
    A()
    A(0)  # E: Too many arguments for "B"
[out]

[case testTypeUsingTypeCTypeVarWithInit]
from typing import Type, TypeVar
class B:
    def __init__(self, a: int) -> None: pass
T = TypeVar('T', bound=B)
def f(A: Type[T]) -> None:
    A()  # E: Missing positional argument "a" in call to "B"
    A(0)
[out]

[case testTypeUsingTypeCTwoTypeVars]
from typing import Type, TypeVar
class User: pass
class ProUser(User): pass
class WizUser(ProUser): pass
U = TypeVar('U', bound=User)
def new_user(u_c: Type[U]) -> U: pass
P = TypeVar('P', bound=ProUser)
def new_pro(pro_c: Type[P]) -> P:
    return new_user(pro_c)
wiz = new_pro(WizUser)
reveal_type(wiz)
def error(u_c: Type[U]) -> P: # Error here, see below
    return new_pro(u_c)  # Error here, see below
[out]
main:11: note: Revealed type is "__main__.WizUser"
main:12: error: A function returning TypeVar should receive at least one argument containing the same TypeVar
main:12: note: Consider using the upper bound "ProUser" instead
main:13: error: Value of type variable "P" of "new_pro" cannot be "U"
main:13: error: Incompatible return value type (got "U", expected "P")

[case testTypeUsingTypeCCovariance]
from typing import Type, TypeVar
class User: pass
class ProUser(User): pass
def new_user(user_class: Type[User]) -> User:
    return user_class()
def new_pro_user(user_class: Type[ProUser]):
    new_user(user_class)
[out]

[case testAllowCovariantArgsInConstructor]
from typing import Generic, TypeVar

T_co = TypeVar('T_co', covariant=True)

class C(Generic[T_co]):
    def __init__(self, x: T_co) -> None: # This should be allowed
        self.x = x
    def meth(self) -> None:
        reveal_type(self.x) # N: Revealed type is "T_co`1"

reveal_type(C(1).x) # N: Revealed type is "builtins.int"
[builtins fixtures/property.pyi]
[out]

[case testTypeUsingTypeCErrorCovariance]
from typing import Type, TypeVar
class User: pass
def new_user(user_class: Type[User]):
    return user_class()
def foo(arg: Type[int]):
    new_user(arg)  # E: Argument 1 to "new_user" has incompatible type "type[int]"; expected "type[User]"
[out]

[case testTypeUsingTypeCUnionOverload]
from foo import *
[file foo.pyi]
from typing import Type, Union, overload
class X:
    @overload
    def __init__(self) -> None: pass
    @overload
    def __init__(self, a: int) -> None: pass
class Y:
    def __init__(self) -> None: pass
def bar(o: Type[Union[X, Y]]): pass
bar(X)
bar(Y)
[out]

[case testTypeUsingTypeCTypeAny]
from typing import Type, Any
def foo(arg: Type[Any]):
    x = arg()
    x = arg(0)
    x = arg('', ())
    reveal_type(x)  # N: Revealed type is "Any"
    x.foo
class X: pass
foo(X)
[builtins fixtures/tuple.pyi]
[out]

[case testTypeUsingTypeCTypeAnyMember]
from typing import Type, Any
def foo(arg: Type[Any]):
    x = arg.member_name
    arg.new_member_name = 42
    # Member access is ok and types as Any
    reveal_type(x)  # N: Revealed type is "Any"
    # But type[Any] is distinct from Any
    y: int = arg  # E: Incompatible types in assignment (expression has type "type[Any]", variable has type "int")
[out]

[case testTypeUsingTypeCTypeAnyMemberFallback]
from typing import Type, Any
def foo(arg: Type[Any]):
    reveal_type(arg.__str__)  # N: Revealed type is "def () -> builtins.str"
    reveal_type(arg.mro())  # N: Revealed type is "builtins.list[builtins.type]"
[builtins fixtures/type.pyi]
[out]

[case testTypeUsingTypeCTypeNoArg]
from typing import Type
def foo(arg: Type):
    x = arg()
    reveal_type(x)  # N: Revealed type is "Any"
class X: pass
foo(X)
[out]

[case testTypeUsingTypeCBuiltinType]
from typing import Type
def foo(arg: type): pass
class X: pass
def bar(arg: Type[X]):
    foo(arg)
foo(X)
[builtins fixtures/tuple.pyi]
[out]

[case testTypeUsingTypeCClassMethod]
from typing import Type
class User:
    @classmethod
    def foo(cls) -> int: pass
    def bar(self) -> int: pass
def process(cls: Type[User]):
    reveal_type(cls.foo())  # N: Revealed type is "builtins.int"
    obj = cls()
    reveal_type(cls.bar(obj))  # N: Revealed type is "builtins.int"
    cls.mro()  # Defined in class type
    cls.error  # E: "type[User]" has no attribute "error"
[builtins fixtures/classmethod.pyi]
[out]

[case testTypeUsingTypeCClassMethodUnion]
from typing import Type, Union
class User:
    @classmethod
    def foo(cls) -> int: pass
    def bar(self) -> int: pass
class ProUser(User): pass
class BasicUser(User): pass
def process(cls: Type[Union[BasicUser, ProUser]]):
    cls.foo()
    obj = cls()
    cls.bar(obj)
    cls.mro()  # Defined in class type
    cls.error  # E: Item "type" of "Union[type[BasicUser], type[ProUser]]" has no attribute "error"
[builtins fixtures/classmethod.pyi]
[out]

[case testTypeUsingTypeCClassMethodFromTypeVar]
from typing import Type, TypeVar
class User:
    @classmethod
    def foo(cls) -> int: pass
    def bar(self) -> int: pass
U = TypeVar('U', bound=User)
def process(cls: Type[U]):
    reveal_type(cls.foo())  # N: Revealed type is "builtins.int"
    obj = cls()
    reveal_type(cls.bar(obj))  # N: Revealed type is "builtins.int"
    cls.mro()  # Defined in class type
    cls.error  # E: "type[U]" has no attribute "error"
[builtins fixtures/classmethod.pyi]
[out]

[case testTypeUsingTypeCClassMethodFromTypeVarUnionBound]
# Ideally this would work, but not worth the effort; just don't crash
from typing import Type, TypeVar, Union
class User:
    @classmethod
    def foo(cls) -> int: pass
    def bar(self) -> int: pass
class ProUser(User): pass
class BasicUser(User): pass
U = TypeVar('U', bound=Union[ProUser, BasicUser])
def process(cls: Type[U]):
    cls.foo()
    obj = cls()
    cls.bar(obj)
    cls.mro()  # Defined in class type
    cls.error  # E: "type[U]" has no attribute "error"
[builtins fixtures/classmethod.pyi]
[out]

[case testTypeUsingTypeCErrorUnsupportedType]
from typing import Type, Tuple
def foo(arg: Type[Tuple[int]]):
    arg()  # E: Cannot instantiate type "type[tuple[int]]"
[builtins fixtures/tuple.pyi]

[case testTypeUsingTypeCOverloadedClass]
from foo import *
[file foo.pyi]
from typing import Type, TypeVar, overload
class User:
    @overload
    def __init__(self) -> None: pass
    @overload
    def __init__(self, arg: int) -> None: pass
    @classmethod
    def foo(cls) -> None: pass
U = TypeVar('U', bound=User)
def new(uc: Type[U]) -> U:
    uc.foo()
    u = uc()
    u.foo()
    if 1:
        u = uc(0)
        u.foo()
        uc('')  # Error
        u.foo(0)  # Error
        return uc()
u = new(User)
[builtins fixtures/classmethod.pyi]
[out]
tmp/foo.pyi:17: error: No overload variant of "User" matches argument type "str"
tmp/foo.pyi:17: note: Possible overload variants:
tmp/foo.pyi:17: note:     def __init__(self) -> U
tmp/foo.pyi:17: note:     def __init__(self, arg: int) -> U
tmp/foo.pyi:18: error: Too many arguments for "foo" of "User"

[case testTypeUsingTypeCInUpperBound]
from typing import TypeVar, Type
class B: pass
T = TypeVar('T', bound=Type[B])
def f(a: T): pass
[out]

[case testTypeUsingTypeCTuple]
from typing import Type, Tuple
def f(a: Type[Tuple[int, int]]):
    a()  # E: Cannot instantiate type "type[tuple[int, int]]"
[builtins fixtures/tuple.pyi]

[case testTypeUsingTypeCNamedTuple]
from typing import Type, NamedTuple
N = NamedTuple('N', [('x', int), ('y', int)])
def f(a: Type[N]):
    a()
[builtins fixtures/list.pyi]
[out]
main:4: error: Missing positional arguments "x", "y" in call to "N"

[case testTypeUsingTypeCJoin]
from typing import Type
class B: pass
class C(B): pass
class D(B): pass
def foo(c: Type[C], d: Type[D]) -> None:
    x = [c, d]
    reveal_type(x)

[builtins fixtures/list.pyi]
[out]
main:7: note: Revealed type is "builtins.list[type[__main__.B]]"

[case testTypeEquivalentTypeAny]
from typing import Type, Any

a: Type[Any]
b = a # type: type

x: type
y = x # type: Type[Any]

class C: ...

p: type
q = p # type: Type[C]

[builtins fixtures/list.pyi]
[out]

[case testTypeEquivalentTypeAny2]
from typing import Type, Any, TypeVar, Generic

class C: ...
x: type
y: Type[Any]
z: Type[C]

lst = [x, y, z]
reveal_type(lst) # N: Revealed type is "builtins.list[builtins.type]"

T1 = TypeVar('T1', bound=type)
T2 = TypeVar('T2', bound=Type[Any])
class C1(Generic[T1]): ...
class C2(Generic[T2]): ...

C1[Type[Any]], C2[type] # both these should not fail
[builtins fixtures/list.pyi]
[out]

[case testTypeEquivalentTypeAnyEdgeCase]
class C:
    pass

class M(type):
    def __init__(cls, x) -> None:
        type.__init__(cls, x)

class Mbad(type):
    def __init__(cls, x) -> None:
        type.__init__(C(), x) # E: Argument 1 to "__init__" of "type" has incompatible type "C"; expected "type"
[builtins fixtures/primitives.pyi]
[out]

[case testTypeMatchesOverloadedFunctions]
from foo import *
[file foo.pyi]
from typing import Type, overload, Any

class User: pass
UserType = User  # type: Type[User]

@overload
def f(a: int) -> Any: pass
@overload
def f(a: object) -> int: pass

reveal_type(f(User))  # N: Revealed type is "builtins.int"
reveal_type(f(UserType))  # N: Revealed type is "builtins.int"
[builtins fixtures/classmethod.pyi]
[out]

[case testTypeMatchesGeneralTypeInOverloadedFunctions]
from foo import *
[file foo.pyi]
from typing import Type, overload

class User: pass
UserType = User  # type: Type[User]

@overload
def f(a: type) -> int:
    return 1
@overload
def f(a: int) -> str:
    return "a"

reveal_type(f(User))  # N: Revealed type is "builtins.int"
reveal_type(f(UserType))  # N: Revealed type is "builtins.int"
reveal_type(f(1))  # N: Revealed type is "builtins.str"
[builtins fixtures/classmethod.pyi]
[out]

[case testTypeMatchesSpecificTypeInOverloadedFunctions]
from foo import *
[file foo.pyi]
from typing import Type, overload

class User: pass
UserType = User  # type: Type[User]

@overload
def f(a: User) -> User:
    return User()
@overload
def f(a: Type[User]) -> int:
    return 1
@overload
def f(a: int) -> str:
    return "a"

reveal_type(f(User))  # N: Revealed type is "builtins.int"
reveal_type(f(UserType))  # N: Revealed type is "builtins.int"
reveal_type(f(User()))  # N: Revealed type is "foo.User"
reveal_type(f(1))  # N: Revealed type is "builtins.str"
[builtins fixtures/classmethod.pyi]
[out]

[case testMixingTypeTypeInOverloadedFunctions]
from foo import *
[file foo.pyi]
from typing import Type, overload

class User: pass

@overload
def f(a: User) -> Type[User]:
    return User
@overload
def f(a: Type[User]) -> User:
    return a()
@overload
def f(a: int) -> Type[User]:
    return User
@overload
def f(a: str) -> User:
    return User()

reveal_type(f(User()))  # N: Revealed type is "type[foo.User]"
reveal_type(f(User))  # N: Revealed type is "foo.User"
reveal_type(f(3))  # N: Revealed type is "type[foo.User]"
reveal_type(f("hi"))  # N: Revealed type is "foo.User"
[builtins fixtures/classmethod.pyi]
[out]

[case testGeneralTypeMatchesSpecificTypeInOverloadedFunctions]
from foo import *
[file foo.pyi]
from typing import Type, Any, overload

class User: pass

@overload
def f(a: Type[User]) -> None: pass
@overload
def f(a: int) -> None: pass

def mock_1() -> type: return User
def mock_2() -> Type[Any]: return User

f(User)
f(mock_1())
f(mock_2())
[builtins fixtures/classmethod.pyi]
[out]

[case testNonTypeDoesNotMatchOverloadedFunctions]
from foo import *
[file foo.pyi]
from typing import Type, overload

class User: pass

@overload
def f(a: Type[User]) -> None: pass
@overload
def f(a: type) -> None: pass

f(3)  # E: No overload variant of "f" matches argument type "int" \
      # N: Possible overload variants: \
      # N:     def f(a: type[User]) -> None \
      # N:     def f(a: type) -> None
[builtins fixtures/classmethod.pyi]
[out]

[case testInstancesDoNotMatchTypeInOverloadedFunctions]
from foo import *
[file foo.pyi]
from typing import Type, overload

class User: pass

@overload
def f(a: Type[User]) -> None: pass
@overload
def f(a: int) -> None: pass

f(User)
f(User())  # E: No overload variant of "f" matches argument type "User" \
           # N: Possible overload variants: \
           # N:     def f(a: type[User]) -> None \
           # N:     def f(a: int) -> None
[builtins fixtures/classmethod.pyi]
[out]

[case testTypeCovarianceWithOverloadedFunctions]
from foo import *
[file foo.pyi]
from typing import Type, overload

class A: pass
class B(A): pass
class C(B): pass
AType = A  # type: Type[A]
BType = B  # type: Type[B]
CType = C  # type: Type[C]

@overload
def f(a: Type[B]) -> None: pass
@overload
def f(a: int) -> None: pass

f(A)  # E: Argument 1 to "f" has incompatible type "type[A]"; expected "type[B]"
f(B)
f(C)
f(AType)  # E: Argument 1 to "f" has incompatible type "type[A]"; expected "type[B]"
f(BType)
f(CType)
[builtins fixtures/classmethod.pyi]
[out]


[case testOverloadedCovariantTypesFail]
from foo import *
[file foo.pyi]
from typing import Type, overload

class A: pass
class B(A): pass

@overload
def f(a: Type[B]) -> int: pass  # E: Overloaded function signatures 1 and 2 overlap with incompatible return types
@overload
def f(a: Type[A]) -> str: pass
[builtins fixtures/classmethod.pyi]
[out]

[case testDistinctOverloadedCovariantTypesSucceed]
from foo import *
[file foo.pyi]
from typing import Type, overload

class A: pass
class AChild(A): pass
class B: pass
class BChild(B): pass

@overload
def f(a: Type[A]) -> int: pass
@overload
def f(a: Type[B]) -> str: pass
@overload
def f(a: A) -> A: pass
@overload
def f(a: B) -> B: pass

reveal_type(f(A))  # N: Revealed type is "builtins.int"
reveal_type(f(AChild))  # N: Revealed type is "builtins.int"
reveal_type(f(B))  # N: Revealed type is "builtins.str"
reveal_type(f(BChild))  # N: Revealed type is "builtins.str"

reveal_type(f(A()))  # N: Revealed type is "foo.A"
reveal_type(f(AChild()))  # N: Revealed type is "foo.A"
reveal_type(f(B()))  # N: Revealed type is "foo.B"
reveal_type(f(BChild()))  # N: Revealed type is "foo.B"
[builtins fixtures/classmethod.pyi]
[out]

[case testSubtypeWithMoreOverloadsThanSupertypeSucceeds]
from foo import *
[file foo.pyi]
from typing import overload


class X: pass
class Y: pass
class Z: pass


class A:
    @overload
    def f(self, x: X) -> X: pass
    @overload
    def f(self, y: Y) -> Y: pass

class B(A):
    @overload
    def f(self, x: X) -> X: pass
    @overload
    def f(self, y: Y) -> Y: pass
    @overload
    def f(self, z: Z) -> Z: pass
[builtins fixtures/classmethod.pyi]
[out]

[case testSubtypeOverloadCoveringMultipleSupertypeOverloadsSucceeds]
from foo import *
[file foo.pyi]
from typing import overload


class A: pass
class B(A): pass
class C(A): pass
class D: pass


class Super:
    @overload
    def foo(self, a: B) -> C: pass
    @overload
    def foo(self, a: C) -> A: pass
    @overload
    def foo(self, a: D) -> D: pass

class Sub(Super):
    @overload
    def foo(self, a: A) -> C: pass
    @overload
    def foo(self, a: D) -> D: pass
[builtins fixtures/classmethod.pyi]
[out]

[case testSubtypeOverloadWithOverlappingArgumentsButWrongReturnType]
from foo import *
[file foo.pyi]
from typing import overload


class A: pass
class B(A): pass
class C: pass


class Super:
    @overload
    def foo(self, a: A) -> A: pass
    @overload
    def foo(self, a: C) -> C: pass

class Sub(Super):
    @overload
    def foo(self, a: A) -> A: pass
    @overload
    def foo(self, a: B) -> C: pass  # Fail
    @overload
    def foo(self, a: C) -> C: pass

class Sub2(Super):
    @overload
    def foo(self, a: B) -> C: pass  # Fail
    @overload
    def foo(self, a: A) -> A: pass
    @overload
    def foo(self, a: C) -> C: pass

class Sub3(Super):
    @overload
    def foo(self, a: A) -> int: pass
    @overload
    def foo(self, a: A) -> A: pass
    @overload
    def foo(self, a: C) -> C: pass
[builtins fixtures/classmethod.pyi]
[out]
tmp/foo.pyi:19: error: Overloaded function signature 2 will never be matched: signature 1's parameter type(s) are the same or broader
tmp/foo.pyi:24: error: Signature of "foo" incompatible with supertype "Super"
tmp/foo.pyi:24: note:      Superclass:
tmp/foo.pyi:24: note:          @overload
tmp/foo.pyi:24: note:          def foo(self, a: A) -> A
tmp/foo.pyi:24: note:          @overload
tmp/foo.pyi:24: note:          def foo(self, a: C) -> C
tmp/foo.pyi:24: note:      Subclass:
tmp/foo.pyi:24: note:          @overload
tmp/foo.pyi:24: note:          def foo(self, a: B) -> C
tmp/foo.pyi:24: note:          @overload
tmp/foo.pyi:24: note:          def foo(self, a: A) -> A
tmp/foo.pyi:24: note:          @overload
tmp/foo.pyi:24: note:          def foo(self, a: C) -> C
tmp/foo.pyi:25: error: Overloaded function signatures 1 and 2 overlap with incompatible return types
tmp/foo.pyi:32: error: Signature of "foo" incompatible with supertype "Super"
tmp/foo.pyi:32: note:      Superclass:
tmp/foo.pyi:32: note:          @overload
tmp/foo.pyi:32: note:          def foo(self, a: A) -> A
tmp/foo.pyi:32: note:          @overload
tmp/foo.pyi:32: note:          def foo(self, a: C) -> C
tmp/foo.pyi:32: note:      Subclass:
tmp/foo.pyi:32: note:          @overload
tmp/foo.pyi:32: note:          def foo(self, a: A) -> int
tmp/foo.pyi:32: note:          @overload
tmp/foo.pyi:32: note:          def foo(self, a: A) -> A
tmp/foo.pyi:32: note:          @overload
tmp/foo.pyi:32: note:          def foo(self, a: C) -> C
tmp/foo.pyi:35: error: Overloaded function signature 2 will never be matched: signature 1's parameter type(s) are the same or broader

[case testTypeTypeOverlapsWithObjectAndType]
from foo import *
[file foo.pyi]
from typing import Type, overload

class User: pass

@overload
def f(a: Type[User]) -> int: pass  # E: Overloaded function signatures 1 and 2 overlap with incompatible return types
@overload
def f(a: object) -> str: pass

# Note: plain type is equivalent to Type[Any] so no error here
@overload
def g(a: Type[User]) -> int: pass
@overload
def g(a: type) -> str: pass

@overload
def h(a: Type[User]) -> int: pass  # E: Overloaded function signatures 1 and 2 overlap with incompatible return types
@overload
def h(a: Type[object]) -> str: pass
[builtins fixtures/classmethod.pyi]
[out]

[case testTypeOverlapsWithObject]
from foo import *
[file foo.pyi]
from typing import Type, overload

class User: pass

@overload
def f(a: type) -> int: pass  # E: Overloaded function signatures 1 and 2 overlap with incompatible return types
@overload
def f(a: object) -> str: pass
[builtins fixtures/classmethod.pyi]
[out]

[case testTypeConstructorReturnsTypeType]
class User:
    @classmethod
    def test_class_method(cls) -> int: pass
    @staticmethod
    def test_static_method() -> str: pass
    def test_instance_method(self) -> None: pass

u = User()

reveal_type(type(u))  # N: Revealed type is "type[__main__.User]"
reveal_type(type(u).test_class_method())  # N: Revealed type is "builtins.int"
reveal_type(type(u).test_static_method())  # N: Revealed type is "builtins.str"
type(u).test_instance_method()  # E: Missing positional argument "self" in call to "test_instance_method" of "User"
[builtins fixtures/classmethod.pyi]
[out]

[case testObfuscatedTypeConstructorReturnsTypeType]
from typing import TypeVar
class User: pass

f1 = type

A = TypeVar('A')
def f2(func: A) -> A:
    return func

u = User()

reveal_type(f1(u))  # N: Revealed type is "type[__main__.User]"
reveal_type(f2(type)(u))  # N: Revealed type is "type[__main__.User]"
[builtins fixtures/classmethod.pyi]
[out]

[case testTypeConstructorLookalikeFails]
class User: pass

def fake1(a: object) -> type:
    return User
def fake2(a: int) -> type:
    return User

reveal_type(type(User()))  # N: Revealed type is "type[__main__.User]"
reveal_type(fake1(User()))  # N: Revealed type is "builtins.type"
reveal_type(fake2(3))  # N: Revealed type is "builtins.type"
[builtins fixtures/classmethod.pyi]
[out]

[case testOtherTypeConstructorsSucceed]
def foo(self) -> int: return self.attr

User = type('User', (object,), {'foo': foo, 'attr': 3})
reveal_type(User)  # N: Revealed type is "builtins.type"
[builtins fixtures/args.pyi]
[out]

[case testTypeTypeComparisonWorks]
class User: pass

User == User
User == type(User())
type(User()) == User
type(User()) == type(User())

User != User
User != type(User())
type(User()) != User
type(User()) != type(User())

int == int
int == type(3)
type(3) == int
type(3) == type(3)

int != int
int != type(3)
type(3) != int
type(3) != type(3)

User is User
User is type(User)
type(User) is User
type(User) is type(User)

int is int
int is type(3)
type(3) is int
type(3) is type(3)

int.__eq__(int)
int.__eq__(3, 4)
[builtins fixtures/args.pyi]
[out]
main:33: error: Too few arguments for "__eq__" of "int"
main:33: error: Unsupported operand types for == ("type[int]" and "type[int]")

[case testDupBaseClasses]
class A:
    def method(self) -> str: ...

class B(A, A):  # E: Duplicate base class "A"
    attr: int

b: B

reveal_type(b.method())  # N: Revealed type is "Any"
reveal_type(b.missing())  # N: Revealed type is "Any"
reveal_type(b.attr)  # N: Revealed type is "builtins.int"

[case testDupBaseClassesGeneric]
from typing import Generic, TypeVar

T = TypeVar('T')
class A(Generic[T]):
    def method(self) -> T: ...

class B(A[int], A[str]):  # E: Duplicate base class "A"
    attr: int

reveal_type(B().method())  # N: Revealed type is "Any"
reveal_type(B().attr)   # N: Revealed type is "builtins.int"

[case testCannotDetermineMro]
class A: pass
class B(A): pass
class C(B): pass
class D(A, B): pass # E: Cannot determine consistent method resolution order (MRO) for "D"
class E(C, D): pass

[case testInconsistentMroLocalRef]
class A: pass
class B(object, A): # E: Cannot determine consistent method resolution order (MRO) for "B"
    def readlines(self): pass
    __iter__ = readlines

[case testDynamicMetaclass]
class C(metaclass=int()):  # E: Dynamic metaclass not supported for "C"
    pass

[case testDynamicMetaclassCrash]
class C(metaclass=int().x):  # E: Dynamic metaclass not supported for "C"
    pass

[case testVariableSubclass]
class A:
    a = 1  # type: int
class B(A):
    a = 1
[out]

[case testVariableSubclassAssignMismatch]
class A:
    a = 1  # type: int
class B(A):
    a = "a"
[out]
main:4: error: Incompatible types in assignment (expression has type "str", base class "A" defined the type as "int")

[case testVariableSubclassAssignment]
class A:
    a = None  # type: int
class B(A):
    def __init__(self) -> None:
        self.a = "a"
[out]
main:5: error: Incompatible types in assignment (expression has type "str", variable has type "int")

[case testVariableSubclassTypeOverwrite]
class A:
    a = None  # type: int
class B(A):
    a = None  # type: str
class C(B):
    a = "a"
[out]
main:4: error: Incompatible types in assignment (expression has type "str", base class "A" defined the type as "int")

[case testVariableSubclassTypeOverwriteImplicit]
class A:
    a = 1
class B(A):
    a = None  # type: str
[out]
main:4: error: Incompatible types in assignment (expression has type "str", base class "A" defined the type as "int")

[case testVariableSuperUsage]
class A:
    a = []  # type: list
class B(A):
    a = [1, 2]
class C(B):
    a = B.a + [3]
[builtins fixtures/list.pyi]
[out]

[case testClassAllBases]
from typing import Union
class A:
    a = None  # type: Union[int, str]
class B(A):
    a = 1
class C(B):
    a = "str"
class D(A):
    a = "str"
[out]
main:7: error: Incompatible types in assignment (expression has type "str", base class "B" defined the type as "int")

[case testVariableTypeVar]
from typing import TypeVar, Generic
T = TypeVar('T')
class A(Generic[T]):
    a = None  # type: T
class B(A[int]):
    a = 1

[case testVariableTypeVarInvalid]
from typing import TypeVar, Generic
T = TypeVar('T')
class A(Generic[T]):
    a = None  # type: T
class B(A[int]):
    a = "abc"
[out]
main:6: error: Incompatible types in assignment (expression has type "str", base class "A" defined the type as "int")

[case testVariableTypeVarIndirectly]
from typing import TypeVar, Generic
T = TypeVar('T')
class A(Generic[T]):
    a = None  # type: T
class B(A[int]):
    pass
class C(B):
    a = "a"
[out]
main:8: error: Incompatible types in assignment (expression has type "str", base class "A" defined the type as "int")

[case testVariableTypeVarList]
from typing import List, TypeVar, Generic
T = TypeVar('T')
class A(Generic[T]):
    a = None  # type: List[T]
    b = None  # type: List[T]
class B(A[int]):
    a = [1]
    b = ['']
[builtins fixtures/list.pyi]
[out]
main:8: error: List item 0 has incompatible type "str"; expected "int"

[case testVariableMethod]
class A:
    def a(self) -> None: pass
    b = 1
class B(A):
    a = 1  # E: Incompatible types in assignment (expression has type "int", base class "A" defined the type as "Callable[[], None]")
    def b(self) -> None: pass  # E: Signature of "b" incompatible with supertype "A" \
                               # N:      Superclass: \
                               # N:          int \
                               # N:      Subclass: \
                               # N:          def b(self) -> None

[case testVariableProperty]
class A:
    @property
    def a(self) -> bool: pass
class B(A):
    a = None  # type: bool
class C(A):
    a = True
class D(A):
    a = 1
[builtins fixtures/property.pyi]
[out]
main:9: error: Incompatible types in assignment (expression has type "int", base class "A" defined the type as "bool")

[case testVariableOverwriteAny]
from typing import Any
class A:
    a = 1
class B(A):
    a = 'x'  # type: Any
[out]

[case testInstanceMethodOverwrite]
class B():
    def n(self, a: int) -> None: pass
class C(B):
    def m(self, a: int) -> None: pass
    n = m
[out]

[case testInstanceMethodOverwriteError]
class B():
    def n(self, a: int) -> None: pass
class C(B):
    def m(self, a: str) -> None: pass
    n = m
[out]
main:5: error: Incompatible types in assignment (expression has type "Callable[[str], None]", base class "B" defined the type as "Callable[[int], None]")

[case testInstanceMethodOverwriteTypevar]
from typing import Generic, TypeVar
T = TypeVar("T")
class B(Generic[T]):
    def n(self, a: T) -> None: pass
class C(B[int]):
    def m(self, a: int) -> None: pass
    n = m

[case testInstanceMethodOverwriteTwice]
class I:
    def foo(self) -> None: pass
class A(I):
    def foo(self) -> None: pass
class B(A):
    def bar(self) -> None: pass
    foo = bar
class C(B):
    def bar(self) -> None: pass
    foo = bar

[case testClassMethodOverwrite]
class B():
    @classmethod
    def n(self, a: int) -> None: pass
class C(B):
    @classmethod
    def m(self, a: int) -> None: pass
    n = m
[builtins fixtures/classmethod.pyi]
[out]

[case testClassMethodOverwriteError]
class B():
    @classmethod
    def n(self, a: int) -> None: pass
class C(B):
    @classmethod
    def m(self, a: str) -> None: pass
    n = m
[builtins fixtures/classmethod.pyi]
[out]
main:7: error: Incompatible types in assignment (expression has type "Callable[[str], None]", base class "B" defined the type as "Callable[[int], None]")

[case testClassSpec]
from typing import Callable
class A():
    b = None  # type: Callable[[int], int]
class B(A):
    def c(self, a: int) -> int: pass
    b = c
reveal_type(A().b)  # N: Revealed type is "def (builtins.int) -> builtins.int"
reveal_type(B().b)  # N: Revealed type is "def (a: builtins.int) -> builtins.int"

[case testClassSpecError]
from typing import Callable
class A():
    b = None  # type: Callable[[int], int]
class B(A):
    def c(self, a: str) -> int: pass
    b = c  # E: Incompatible types in assignment (expression has type "Callable[[str], int]", base class "A" defined the type as "Callable[[int], int]")

[case testClassStaticMethod]
class A():
    @staticmethod
    def a(a: int) -> None: pass
class B(A):
    @staticmethod
    def b(a: str) -> None: pass
    a = b
[builtins fixtures/staticmethod.pyi]
[out]
main:7: error: Incompatible types in assignment (expression has type "Callable[[str], None]", base class "A" defined the type as "Callable[[int], None]")

[case testClassStaticMethodIndirect]
class A():
    @staticmethod
    def a(a: int) -> None: pass
    c = a
class B(A):
    @staticmethod
    def b(a: str) -> None: pass
    c = b  # E: Incompatible types in assignment (expression has type "Callable[[str], None]", base class "A" defined the type as "Callable[[int], None]")
a: A
reveal_type(a.a)  # N: Revealed type is "def (a: builtins.int)"
reveal_type(a.c)  # N: Revealed type is "def (a: builtins.int)"
[builtins fixtures/staticmethod.pyi]

[case testClassStaticMethodIndirectOverloaded]
from typing import overload
class A:
    @overload
    @staticmethod
    def a(x: int) -> int: ...
    @overload
    @staticmethod
    def a(x: str) -> str: ...
    @staticmethod
    def a(x):
        ...
    c = a
reveal_type(A.c)  # N: Revealed type is "Overload(def (x: builtins.int) -> builtins.int, def (x: builtins.str) -> builtins.str)"
reveal_type(A().c)  # N: Revealed type is "Overload(def (x: builtins.int) -> builtins.int, def (x: builtins.str) -> builtins.str)"
[builtins fixtures/staticmethod.pyi]

[case testClassStaticMethodSubclassing]
class A:
    @staticmethod
    def a() -> None: pass

    def b(self) -> None: pass

    @staticmethod
    def c() -> None: pass

class B(A):
    def a(self) -> None: pass  # Fail

    @classmethod
    def b(cls) -> None: pass

    @staticmethod
    def c() -> None: pass
[builtins fixtures/classmethod.pyi]
[out]
main:11: error: Signature of "a" incompatible with supertype "A"
main:11: note:      Superclass:
main:11: note:          @staticmethod
main:11: note:          def a() -> None
main:11: note:      Subclass:
main:11: note:          def a(self) -> None

[case testTempNode]
class A():
    def a(self) -> None: pass
class B(A):
    def b(self) -> None: pass
    a = c = b

[case testListObject]
from typing import List
class A:
    x = []  # type: List[object]
class B(A):
    x = [1]
[builtins fixtures/list.pyi]

[case testClassMemberObject]
class A:
    x = object()
class B(A):
    x = 1
class C(B):
    x = ''
[out]
main:6: error: Incompatible types in assignment (expression has type "str", base class "B" defined the type as "int")

[case testSlots]
class A:
    __slots__ = ("a")
class B(A):
    __slots__ = ("a", "b")
[builtins fixtures/tuple.pyi]

[case testClassOrderOfError]
class A:
    x = 1
class B(A):
    x = "a"  # E: Incompatible types in assignment (expression has type "str", base class "A" defined the type as "int")
class C(B):
    x = object()  # E: Incompatible types in assignment (expression has type "object", base class "B" defined the type as "str")

[case testClassOneErrorPerLine]
class A:
    x = 1
class B(A):
    x: str = ""  # E: Incompatible types in assignment (expression has type "str", base class "A" defined the type as "int")
    x = 1.0  # E: Incompatible types in assignment (expression has type "float", variable has type "str")
class BInfer(A):
    x = ""  # E: Incompatible types in assignment (expression has type "str", base class "A" defined the type as "int")
    x = 1.0  # E: Incompatible types in assignment (expression has type "float", variable has type "str") \
             # E: Incompatible types in assignment (expression has type "float", base class "A" defined the type as "int")

[case testClassIgnoreType_RedefinedAttributeAndGrandparentAttributeTypesNotIgnored]
class A:
    x = 0
class B(A):
    x = ''  # type: ignore
class C(B):
    x = ''

[case testClassIgnoreType_RedefinedAttributeTypeIgnoredInChildren]
class A:
    x = 0
class B(A):
    x = ''  # type: ignore
class C(B):
    x = ''  # type: ignore

[case testInvalidMetaclassStructure]
class X(type): pass
class Y(type): pass
class A(metaclass=X): pass
class B(A, metaclass=Y): pass  # E: Metaclass conflict: the metaclass of a derived class must be a (non-strict) subclass of the metaclasses of all its bases \
                               # N: "__main__.Y" (metaclass of "__main__.B") conflicts with "__main__.X" (metaclass of "__main__.A")
[case testMetaclassNoTypeReveal]
class M:
    x = 0  # type: int

class A(metaclass=M): pass  # E: Metaclasses not inheriting from "type" are not supported

A.x  # E: "type[A]" has no attribute "x"

[case testMetaclassTypeReveal]
from typing import Type
class M(type):
    x = 0  # type: int

class A(metaclass=M): pass

def f(TA: Type[A]):
    reveal_type(TA)  # N: Revealed type is "type[__main__.A]"
    reveal_type(TA.x)  # N: Revealed type is "builtins.int"

[case testMetaclassConflictingInstanceVars]
from typing import ClassVar

class Meta(type):
    foo: int
    bar: int
    eggs: ClassVar[int] = 42
    spam: ClassVar[int] = 42

class Foo(metaclass=Meta):
    foo: str
    bar: ClassVar[str] = 'bar'
    eggs: str
    spam: ClassVar[str] = 'spam'

reveal_type(Foo.foo)  # N: Revealed type is "builtins.int"
reveal_type(Foo.bar)  # N: Revealed type is "builtins.str"
reveal_type(Foo.eggs)  # N: Revealed type is "builtins.int"
reveal_type(Foo.spam)  # N: Revealed type is "builtins.str"

class MetaSub(Meta): ...

class Bar(metaclass=MetaSub):
    foo: str
    bar: ClassVar[str] = 'bar'
    eggs: str
    spam: ClassVar[str] = 'spam'

reveal_type(Bar.foo)  # N: Revealed type is "builtins.int"
reveal_type(Bar.bar)  # N: Revealed type is "builtins.str"
reveal_type(Bar.eggs)  # N: Revealed type is "builtins.int"
reveal_type(Bar.spam)  # N: Revealed type is "builtins.str"

[case testSubclassMetaclass]
class M1(type):
    x = 0
class M2(M1): pass
class C(metaclass=M2):
    pass
reveal_type(C.x) # N: Revealed type is "builtins.int"

[case testMetaclassSubclass]
from typing import Type
class M(type):
    x = 0  # type: int

class A(metaclass=M): pass
class B(A): pass

def f(TB: Type[B]):
    reveal_type(TB)  # N: Revealed type is "type[__main__.B]"
    reveal_type(TB.x)  # N: Revealed type is "builtins.int"

[case testMetaclassAsAny]
from typing import Any, ClassVar, Type

MyAny: Any
class WithMeta(metaclass=MyAny):
    x: ClassVar[int]

reveal_type(WithMeta.a)   # N: Revealed type is "Any"
reveal_type(WithMeta.m)   # N: Revealed type is "Any"
reveal_type(WithMeta.x)   # N: Revealed type is "builtins.int"
reveal_type(WithMeta().x) # N: Revealed type is "builtins.int"
WithMeta().m              # E: "WithMeta" has no attribute "m"
WithMeta().a              # E: "WithMeta" has no attribute "a"
t: Type[WithMeta]
t.unknown  # OK

[case testMetaclassAsAnyWithAFlag]
# flags: --disallow-subclassing-any
from typing import Any, ClassVar, Type

MyAny: Any
class WithMeta(metaclass=MyAny):  # E: Class cannot use "MyAny" as a metaclass (has type "Any")
    x: ClassVar[int]

reveal_type(WithMeta.a)   # N: Revealed type is "Any"
reveal_type(WithMeta.m)   # N: Revealed type is "Any"
reveal_type(WithMeta.x)   # N: Revealed type is "builtins.int"
reveal_type(WithMeta().x) # N: Revealed type is "builtins.int"
WithMeta().m              # E: "WithMeta" has no attribute "m"
WithMeta().a              # E: "WithMeta" has no attribute "a"
t: Type[WithMeta]
t.unknown  # OK

[case testUnpackIterableClassWithOverloadedIter]
from typing import Generic, overload, Iterator, TypeVar, Union

AnyNum = TypeVar('AnyNum', int, float)

class Foo(Generic[AnyNum]):
    @overload
    def __iter__(self: Foo[int]) -> Iterator[float]: ...
    @overload
    def __iter__(self: Foo[float]) -> Iterator[int]: ...
    def __iter__(self) -> Iterator[Union[float, int]]:
        ...

a, b, c = Foo[int]()
reveal_type(a)  # N: Revealed type is "builtins.float"
reveal_type(b)  # N: Revealed type is "builtins.float"
reveal_type(c)  # N: Revealed type is "builtins.float"

x, y = Foo[float]()
reveal_type(x)  # N: Revealed type is "builtins.int"
reveal_type(y)  # N: Revealed type is "builtins.int"
[builtins fixtures/list.pyi]

[case testUnpackIterableClassWithOverloadedIter2]
from typing import Union, TypeVar, Generic, overload, Iterator

X = TypeVar('X')

class Foo(Generic[X]):
    @overload
    def __iter__(self: Foo[str]) -> Iterator[int]: ...  # type: ignore
    @overload
    def __iter__(self: Foo[X]) -> Iterator[str]: ...
    def __iter__(self) -> Iterator[Union[int, str]]:
        ...

a, b, c = Foo[str]()
reveal_type(a)  # N: Revealed type is "builtins.int"
reveal_type(b)  # N: Revealed type is "builtins.int"
reveal_type(c)  # N: Revealed type is "builtins.int"

x, y = Foo[float]()
reveal_type(x)  # N: Revealed type is "builtins.str"
reveal_type(y)  # N: Revealed type is "builtins.str"
[builtins fixtures/list.pyi]

[case testUnpackIterableRegular]
from typing import TypeVar, Generic, Iterator

X = TypeVar('X')

class Foo(Generic[X]):
    def __iter__(self) -> Iterator[X]:
        ...

a, b = Foo[int]()
reveal_type(a)  # N: Revealed type is "builtins.int"
reveal_type(b)  # N: Revealed type is "builtins.int"
[builtins fixtures/list.pyi]

[case testUnpackNotIterableClass]
class Foo: ...

a, b, c = Foo()  # E: "Foo" object is not iterable
[builtins fixtures/list.pyi]

[case testMetaclassIterable]
from typing import Iterable, Iterator

class ImplicitMeta(type):
    def __iter__(self) -> Iterator[int]: yield 1

class Implicit(metaclass=ImplicitMeta): pass

for _ in Implicit: pass
reveal_type(list(Implicit))  # N: Revealed type is "builtins.list[builtins.int]"

class ExplicitMeta(type, Iterable[int]):
    def __iter__(self) -> Iterator[int]: yield 1

class Explicit(metaclass=ExplicitMeta): pass
for _ in Explicit: pass
reveal_type(list(Explicit))  # N: Revealed type is "builtins.list[builtins.int]"

[builtins fixtures/list.pyi]

[case testMetaclassTuple]
from typing import Tuple

class M(Tuple[int]): pass
class C(metaclass=M): pass  # E: Invalid metaclass "M"

[builtins fixtures/tuple.pyi]

[case testMetaclassOperatorBeforeReversed]
class X:
    def __radd__(self, x: int) -> int: ...

class Meta(type):
    def __add__(cls, x: X) -> str: ...

class Concrete(metaclass=Meta):
    pass

reveal_type(Concrete + X())  # N: Revealed type is "builtins.str"
Concrete + "hello"  # E: Unsupported operand types for + ("type[Concrete]" and "str")

[case testMetaclassOperatorTypeVar]
from typing import Type, TypeVar

class MetaClass(type):
    def __mul__(cls, other: int) -> str:
        return ""

class Test(metaclass=MetaClass):
    pass

S = TypeVar("S", bound=Test)

def f(x: Type[Test]) -> str:
    return x * 0
def g(x: Type[S]) -> str:
    return reveal_type(x * 0)  # N: Revealed type is "builtins.str"

[case testMetaclassGetitem]
import types

class M(type):
    def __getitem__(self, key) -> int: return 1

class A(metaclass=M): pass

reveal_type(A[M])  # N: Revealed type is "builtins.int"
[builtins fixtures/tuple.pyi]

[case testMetaclassSelfType]
from typing import TypeVar, Type

class M(type): pass
T = TypeVar('T')

class M1(M):
    def foo(cls: Type[T]) -> T: ...

class A(metaclass=M1): pass
reveal_type(A.foo())  # N: Revealed type is "__main__.A"

[case testMetaclassAndSkippedImport]
# flags: --ignore-missing-imports
from missing import M
class A(metaclass=M):
    y = 0
reveal_type(A.y) # N: Revealed type is "builtins.int"
reveal_type(A.x) # N: Revealed type is "Any"

[case testValidTypeAliasAsMetaclass]
from typing_extensions import TypeAlias

Explicit: TypeAlias = type
Implicit = type

class E(metaclass=Explicit): ...
class I(metaclass=Implicit): ...
[builtins fixtures/classmethod.pyi]

[case testValidTypeAliasOfTypeAliasAsMetaclass]
from typing_extensions import TypeAlias

Explicit: TypeAlias = type
Implicit = type

A1: TypeAlias = Explicit
A2 = Explicit
A3: TypeAlias = Implicit
A4 = Implicit

class C1(metaclass=A1): ...
class C2(metaclass=A2): ...
class C3(metaclass=A3): ...
class C4(metaclass=A4): ...
[builtins fixtures/classmethod.pyi]

[case testTypeAliasWithArgsAsMetaclass]
from typing import Generic, TypeVar
from typing_extensions import TypeAlias

T = TypeVar('T')
class Meta(Generic[T]): ...

Explicit: TypeAlias = Meta[T]
Implicit = Meta[T]

class E(metaclass=Explicit): ...  # E: Invalid metaclass "Explicit"
class I(metaclass=Implicit): ...  # E: Invalid metaclass "Implicit"
[builtins fixtures/classmethod.pyi]

[case testTypeAliasNonTypeAsMetaclass]
from typing_extensions import TypeAlias

Explicit: TypeAlias = int
Implicit = int

class E(metaclass=Explicit): ...  # E: Metaclasses not inheriting from "type" are not supported
class I(metaclass=Implicit): ...  # E: Metaclasses not inheriting from "type" are not supported
[builtins fixtures/classmethod.pyi]

[case testInvalidVariableAsMetaclass]
from typing import Any
M = 0  # type: int
MM = 0
class A(metaclass=M): # E: Invalid metaclass "M"
    y = 0
class B(metaclass=MM): # E: Invalid metaclass "MM"
    y = 0
reveal_type(A.y) # N: Revealed type is "builtins.int"
A.x # E: "type[A]" has no attribute "x"

[case testAnyAsBaseOfMetaclass]
from typing import Any, Type
M = None  # type: Any
class MM(M): pass

class A(metaclass=MM):
    y = 0
    @classmethod
    def f(cls) -> None: pass
    def g(self) -> None: pass

def h(a: Type[A], b: Type[object]) -> None:
    h(a, a)
    h(b, a) # E: Argument 1 to "h" has incompatible type "type[object]"; expected "type[A]"
    a.f(1) # E: Too many arguments for "f" of "A"
    reveal_type(a.y) # N: Revealed type is "builtins.int"

x = A # type: MM
reveal_type(A.y) # N: Revealed type is "builtins.int"
reveal_type(A.x) # N: Revealed type is "Any"
A.f(1) # E: Too many arguments for "f" of "A"
A().g(1) # E: Too many arguments for "g" of "A"
[builtins fixtures/classmethod.pyi]

[case testMetaclassTypeCallable]
class M(type):
    x = 5

class A(metaclass=M): pass
reveal_type(type(A).x)  # N: Revealed type is "builtins.int"

[case testMetaclassStrictSupertypeOfTypeWithClassmethods]
from typing import Type, TypeVar
TA = TypeVar('TA', bound='A')
TTA = TypeVar('TTA', bound='Type[A]')
TM = TypeVar('TM', bound='M')

class M(type):
    def g1(cls: 'Type[A]') -> A: pass  # E: The erased type of self "type[__main__.A]" is not a supertype of its class "__main__.M"
    def g2(cls: Type[TA]) -> TA: pass  # E: The erased type of self "type[__main__.A]" is not a supertype of its class "__main__.M"
    def g3(cls: TTA) -> TTA: pass  # E: The erased type of self "type[__main__.A]" is not a supertype of its class "__main__.M"
    def g4(cls: TM) -> TM: pass
m: M

class A(metaclass=M):
    def foo(self): pass

reveal_type(A.g1)  # N: Revealed type is "def () -> __main__.A"
reveal_type(A.g2)  # N: Revealed type is "def () -> __main__.A"
reveal_type(A.g3)  # N: Revealed type is "def () -> def () -> __main__.A"
reveal_type(A.g4)  # N: Revealed type is "def () -> def () -> __main__.A"

class B(metaclass=M):
    def foo(self): pass

B.g1  # E: Invalid self argument "type[B]" to attribute function "g1" with type "Callable[[type[A]], A]"
B.g2  # E: Invalid self argument "type[B]" to attribute function "g2" with type "Callable[[type[TA]], TA]"
B.g3  # E: Invalid self argument "type[B]" to attribute function "g3" with type "Callable[[TTA], TTA]"
reveal_type(B.g4)  # N: Revealed type is "def () -> def () -> __main__.B"

# 4 examples of unsoundness - instantiation, classmethod, staticmethod and ClassVar:

ta: Type[A] = m  # E: Incompatible types in assignment (expression has type "M", variable has type "type[A]")
a: A = ta()
reveal_type(ta.g1)  # N: Revealed type is "def () -> __main__.A"
reveal_type(ta.g2)  # N: Revealed type is "def () -> __main__.A"
reveal_type(ta.g3)  # N: Revealed type is "def () -> type[__main__.A]"
reveal_type(ta.g4)  # N: Revealed type is "def () -> type[__main__.A]"

x: M = ta
x.g1  # E: Invalid self argument "M" to attribute function "g1" with type "Callable[[type[A]], A]"
x.g2  # E: Invalid self argument "M" to attribute function "g2" with type "Callable[[type[TA]], TA]"
x.g3  # E: Invalid self argument "M" to attribute function "g3" with type "Callable[[TTA], TTA]"
reveal_type(x.g4)  # N: Revealed type is "def () -> __main__.M"

def r(ta: Type[TA], tta: TTA) -> None:
    x: M = ta
    y: M = tta

class Class(metaclass=M):
    @classmethod
    def f1(cls: Type[Class]) -> None: pass
    @classmethod
    def f2(cls: M) -> None: pass
cl: Type[Class] = m  # E: Incompatible types in assignment (expression has type "M", variable has type "type[Class]")
reveal_type(cl.f1)  # N: Revealed type is "def ()"
reveal_type(cl.f2)  # N: Revealed type is "def ()"
x1: M = cl

class Static(metaclass=M):
    @staticmethod
    def f() -> None: pass
s: Type[Static] = m  # E: Incompatible types in assignment (expression has type "M", variable has type "type[Static]")
reveal_type(s.f)  # N: Revealed type is "def ()"
x2: M = s

from typing import ClassVar
class Cvar(metaclass=M):
    x = 1  # type: ClassVar[int]
cv: Type[Cvar] = m  # E: Incompatible types in assignment (expression has type "M", variable has type "type[Cvar]")
cv.x
x3: M = cv

[builtins fixtures/classmethod.pyi]

[case testMetaclassOverloadResolution]
from typing import Type, overload
class A: pass

class EM(type): pass
class E(metaclass=EM): pass

class EM1(type): pass
class E1(metaclass=EM1): pass

@overload
def f(x: EM) -> int: ...
@overload
def f(x: EM1) -> A: ...
@overload
def f(x: str) -> str: ...
def f(x: object) -> object: return ''

e: EM
reveal_type(f(e))  # N: Revealed type is "builtins.int"

et: Type[E]
reveal_type(f(et))  # N: Revealed type is "builtins.int"

e1: EM1
reveal_type(f(e1))  # N: Revealed type is "__main__.A"

e1t: Type[E1]
reveal_type(f(e1t))  # N: Revealed type is "__main__.A"

reveal_type(f(''))  # N: Revealed type is "builtins.str"

[case testTypeCErasesGenericsFromC]
from typing import Generic, Type, TypeVar

K = TypeVar('K')
V = TypeVar('V')
class ExampleDict(Generic[K, V]): ...

D = TypeVar('D')
def mkdict(dict_type: Type[D]) -> D: ...
reveal_type(mkdict(ExampleDict))  # N: Revealed type is "__main__.ExampleDict[Any, Any]"

[case testTupleForwardBase]
from m import a
a[0]()  # E: "int" not callable

[file m.py]
from typing import Tuple
a: A
class A(Tuple[int, str]): pass
[builtins fixtures/tuple.pyi]

-- Synthetic types crashes
-- -----------------------

[case testCrashOnSelfRecursiveNamedTupleVar]
from typing import NamedTuple

def test() -> None:
    N = NamedTuple('N', [('x', N)]) # E: Cannot resolve name "N" (possible cyclic definition) \
                                    # N: Recursive types are not allowed at function scope
    n: N
    reveal_type(n) # N: Revealed type is "tuple[Any, fallback=__main__.N@4]"
[builtins fixtures/tuple.pyi]

[case testCrashOnSelfRecursiveTypedDictVar]
from typing import TypedDict

A = TypedDict('A', {'a': 'A'})  # type: ignore
a: A
[builtins fixtures/isinstancelist.pyi]
[typing fixtures/typing-typeddict.pyi]

[case testCrashInJoinOfSelfRecursiveNamedTuples]

from typing import NamedTuple

class N(NamedTuple):
    x: N # type: ignore
class M(NamedTuple):
    x: M # type: ignore

n: N
m: M
lst = [n, m]
[builtins fixtures/isinstancelist.pyi]

[case testCorrectJoinOfSelfRecursiveTypedDicts]
from typing import TypedDict

def test() -> None:
    class N(TypedDict):
        x: N  # E: Cannot resolve name "N" (possible cyclic definition) \
              # N: Recursive types are not allowed at function scope
    class M(TypedDict):
        x: M  # E: Cannot resolve name "M" (possible cyclic definition) \
              # N: Recursive types are not allowed at function scope

    n: N
    m: M
    lst = [n, m]
    reveal_type(lst[0]['x'])  # N: Revealed type is "Any"
[builtins fixtures/isinstancelist.pyi]
[typing fixtures/typing-typeddict.pyi]

[case testCrashInForwardRefToNamedTupleWithIsinstance]
from typing import Dict, NamedTuple

NameDict = Dict[str, 'NameInfo']
class NameInfo(NamedTuple):
    ast: bool

def parse_ast(name_dict: NameDict) -> None:
    if isinstance(name_dict[''], int):
        pass
    reveal_type(name_dict['test']) # N: Revealed type is "tuple[builtins.bool, fallback=__main__.NameInfo]"
[builtins fixtures/isinstancelist.pyi]
[typing fixtures/typing-medium.pyi]

[case testCrashInForwardRefToTypedDictWithIsinstance]
from typing import Dict, TypedDict

NameDict = Dict[str, 'NameInfo']
class NameInfo(TypedDict):
    ast: bool

def parse_ast(name_dict: NameDict) -> None:
    if isinstance(name_dict[''], int):
        pass
    reveal_type(name_dict['']['ast'])  # N: Revealed type is "builtins.bool"
[builtins fixtures/isinstancelist.pyi]
[typing fixtures/typing-typeddict.pyi]

[case testCorrectIsinstanceInForwardRefToNewType]
from typing import Dict, NewType

NameDict = Dict[str, 'NameInfo']
class Base:
    ast: bool
NameInfo = NewType('NameInfo', Base)

def parse_ast(name_dict: NameDict) -> None:
    if isinstance(name_dict[''], int):
        pass
    x = name_dict['']
    reveal_type(x) # N: Revealed type is "__main__.NameInfo"
    if int():
        x = NameInfo(Base()) # OK
        x = Base() # E: Incompatible types in assignment (expression has type "Base", variable has type "NameInfo")
[builtins fixtures/isinstancelist.pyi]
[typing fixtures/typing-medium.pyi]

[case testNoCrashForwardRefToBrokenDoubleNewType]
from typing import Any, Dict, List, NewType

Foo = NewType('NotFoo', int) # E: String argument 1 "NotFoo" to NewType(...) does not match variable name "Foo"
Foos = NewType('Foos', List[Foo]) # type: ignore

def frob(foos: Dict[Any, Foos]) -> None:
    foo = foos.get(1)
    assert foo
    dict(foo)
[builtins fixtures/dict.pyi]
[out]

[case testNoCrashForwardRefToBrokenDoubleNewTypeClass]
from typing import Any, Dict, List, NewType

Foo = NewType('NotFoo', int) # type: ignore
Foos = NewType('Foos', List[Foo]) # type: ignore

x: C
class C:
    def frob(self, foos: Dict[Any, Foos]) -> None:
        foo = foos.get(1)
        assert foo
        dict(foo)

reveal_type(x.frob) # N: Revealed type is "def (foos: builtins.dict[Any, __main__.Foos])"
[builtins fixtures/dict.pyi]
[out]

[case testNewTypeFromForwardNamedTuple]
from typing import NewType, NamedTuple, Tuple

NT = NewType('NT', 'N')
class N(NamedTuple):
    x: int

x: NT = N(1) # E: Incompatible types in assignment (expression has type "N", variable has type "NT")
x = NT(N(1))
[builtins fixtures/tuple.pyi]
[out]

[case testNewTypeFromForwardTypedDict]

from typing import NewType, Tuple, TypedDict

NT = NewType('NT', 'N') # E: Argument 2 to NewType(...) must be subclassable (got "N")
class N(TypedDict):
    x: int
[builtins fixtures/dict.pyi]
[typing fixtures/typing-typeddict.pyi]
[out]

[case testCorrectAttributeInForwardRefToNamedTuple]
from typing import NamedTuple
proc: Process
reveal_type(proc.state)  # N: Revealed type is "builtins.int"

def get_state(proc: 'Process') -> int:
    return proc.state
class Process(NamedTuple):
     state: int
[builtins fixtures/tuple.pyi]
[out]

[case testCorrectItemTypeInForwardRefToTypedDict]
from typing import TypedDict
proc: Process
reveal_type(proc['state'])  # N: Revealed type is "builtins.int"

def get_state(proc: 'Process') -> int:
    return proc['state']
class Process(TypedDict):
     state: int
[builtins fixtures/isinstancelist.pyi]
[typing fixtures/typing-typeddict.pyi]
[out]

[case testCorrectDoubleForwardNamedTuple]
from typing import NamedTuple

x: A
class A(NamedTuple):
    one: 'B'
    other: int
class B(NamedTuple):
    attr: str
y: A
y = x
reveal_type(x.one.attr)  # N: Revealed type is "builtins.str"
[builtins fixtures/tuple.pyi]
[out]

[case testCrashOnDoubleForwardTypedDict]
from typing import TypedDict

x: A
class A(TypedDict):
    one: 'B'
    other: int
class B(TypedDict):
    attr: str

reveal_type(x['one']['attr'])  # N: Revealed type is "builtins.str"
[builtins fixtures/isinstancelist.pyi]
[typing fixtures/typing-typeddict.pyi]
[out]

[case testCrashOnForwardUnionOfNamedTuples]
from typing import Union, NamedTuple

Node = Union['Foo', 'Bar']
class Foo(NamedTuple):
    x: int
class Bar(NamedTuple):
    x: int

def foo(node: Node) -> int:
    x = node
    reveal_type(node) # N: Revealed type is "Union[tuple[builtins.int, fallback=__main__.Foo], tuple[builtins.int, fallback=__main__.Bar]]"
    return x.x
[builtins fixtures/tuple.pyi]
[out]

[case testCrashOnForwardUnionOfTypedDicts]
from typing import TypedDict, Union

NodeType = Union['Foo', 'Bar']
class Foo(TypedDict):
    x: int
class Bar(TypedDict):
    x: int

def foo(node: NodeType) -> int:
    x = node
    return x['x']
[builtins fixtures/isinstancelist.pyi]
[typing fixtures/typing-typeddict.pyi]
[out]

[case testSupportForwardUnionOfNewTypes]
from typing import Union, NewType
x: Node
reveal_type(x.x) # N: Revealed type is "builtins.int"

class A:
    x: int
class B:
    x: int

Node = Union['Foo', 'Bar']
Foo = NewType('Foo', A)
Bar = NewType('Bar', B)

def foo(node: Node) -> Node:
    x = node
    return Foo(A())
[out]

[case testForwardReferencesInNewTypeMRORecomputed]
from typing import NewType
x: Foo
Foo = NewType('Foo', 'B')
class A:
    x: int
class B(A):
    pass

reveal_type(x.x) # N: Revealed type is "builtins.int"
[out]

[case testCrashOnComplexNamedTupleUnionProperty]
from typing import NamedTuple, Union

x: AOrB
AOrB = Union['A', 'B']
class A(NamedTuple):
    x: int

class B(object):
    def __init__(self, a: AOrB) -> None:
        self.a = a
    @property
    def x(self) -> int:
        return self.a.x

reveal_type(x.x) # N: Revealed type is "builtins.int"
[builtins fixtures/property.pyi]
[out]

[case testCorrectIsinstanceWithForwardUnion]
from typing import Union, NamedTuple

ForwardUnion = Union['TP', int]
class TP(NamedTuple('TP', [('x', int)])): pass

def f(x: ForwardUnion) -> None:
  reveal_type(x)  # N: Revealed type is "Union[tuple[builtins.int, fallback=__main__.TP], builtins.int]"
  if isinstance(x, TP):
    reveal_type(x)  # N: Revealed type is "tuple[builtins.int, fallback=__main__.TP]"
[builtins fixtures/isinstance.pyi]
[out]

[case testCrashInvalidArgsSyntheticClassSyntax]
from typing import List, NamedTuple, TypedDict
class TD(TypedDict):
    x: List[int, str] # E: "list" expects 1 type argument, but 2 given
class NM(NamedTuple):
    x: List[int, str] # E: "list" expects 1 type argument, but 2 given

# These two should never crash, reveals are in the next test
TD({'x': []})
NM(x=[])
[builtins fixtures/dict.pyi]
[typing fixtures/typing-typeddict.pyi]
[out]

[case testCrashInvalidArgsSyntheticClassSyntaxReveals]
from typing import List, NamedTuple, TypedDict
class TD(TypedDict):
    x: List[int, str] # E: "list" expects 1 type argument, but 2 given
class NM(NamedTuple):
    x: List[int, str] # E: "list" expects 1 type argument, but 2 given

x: TD
x1 = TD({'x': []})
y: NM
y1 = NM(x=[])
reveal_type(x) # N: Revealed type is "TypedDict('__main__.TD', {'x': builtins.list[Any]})"
reveal_type(x1) # N: Revealed type is "TypedDict('__main__.TD', {'x': builtins.list[Any]})"
reveal_type(y) # N: Revealed type is "tuple[builtins.list[Any], fallback=__main__.NM]"
reveal_type(y1) # N: Revealed type is "tuple[builtins.list[Any], fallback=__main__.NM]"
[builtins fixtures/dict.pyi]
[typing fixtures/typing-typeddict.pyi]
[out]

[case testCrashInvalidArgsSyntheticFunctionSyntax]
from typing import List, NewType, NamedTuple, TypedDict
TD = TypedDict('TD', {'x': List[int, str]}) # E: "list" expects 1 type argument, but 2 given
NM = NamedTuple('NM', [('x', List[int, str])]) # E: "list" expects 1 type argument, but 2 given
NT = NewType('NT', List[int, str]) # E: "list" expects 1 type argument, but 2 given

# These three should not crash
TD({'x': []})
NM(x=[])
NT([])
[builtins fixtures/dict.pyi]
[typing fixtures/typing-typeddict.pyi]
[out]

[case testCrashForwardSyntheticClassSyntax]
from typing import NamedTuple, TypedDict
class A1(NamedTuple):
    b: 'B'
    x: int
class A2(TypedDict):
    b: 'B'
    x: int
class B:
    pass
x: A1
y: A2
reveal_type(x.b) # N: Revealed type is "__main__.B"
reveal_type(y['b']) # N: Revealed type is "__main__.B"
[builtins fixtures/dict.pyi]
[typing fixtures/typing-typeddict.pyi]
[out]

[case testCrashForwardSyntheticFunctionSyntax]
from typing import NamedTuple, TypedDict
A1 = NamedTuple('A1', [('b', 'B'), ('x', int)])
A2 = TypedDict('A2', {'b': 'B', 'x': int})
class B:
    pass
x: A1
y: A2
reveal_type(x.b) # N: Revealed type is "__main__.B"
reveal_type(y['b']) # N: Revealed type is "__main__.B"
[builtins fixtures/dict.pyi]
[typing fixtures/typing-typeddict.pyi]
[out]

-- Special support for six
-- -----------------------

[case testSixMetaclass]
import six
class M(type):
    x = 5
class A(six.with_metaclass(M)): pass
@six.add_metaclass(M)
class B: pass
reveal_type(type(A).x)  # N: Revealed type is "builtins.int"
reveal_type(type(B).x)  # N: Revealed type is "builtins.int"
[builtins fixtures/tuple.pyi]

[case testFromSixMetaclass]
from six import with_metaclass, add_metaclass
class M(type):
    x = 5
class A(with_metaclass(M)): pass
@add_metaclass(M)
class B: pass
reveal_type(type(A).x)  # N: Revealed type is "builtins.int"
reveal_type(type(B).x)  # N: Revealed type is "builtins.int"
[builtins fixtures/tuple.pyi]

[case testSixMetaclassImportFrom]
import six
from metadefs import M
class A(six.with_metaclass(M)): pass
@six.add_metaclass(M)
class B: pass
reveal_type(type(A).x)  # N: Revealed type is "builtins.int"
reveal_type(type(B).x)  # N: Revealed type is "builtins.int"
[file metadefs.py]
class M(type):
    x = 5
[builtins fixtures/tuple.pyi]

[case testSixMetaclassImport]
import six
import metadefs
class A(six.with_metaclass(metadefs.M)): pass
@six.add_metaclass(metadefs.M)
class B: pass
reveal_type(type(A).x)  # N: Revealed type is "builtins.int"
reveal_type(type(B).x)  # N: Revealed type is "builtins.int"
[file metadefs.py]
class M(type):
    x = 5
[builtins fixtures/tuple.pyi]

[case testSixMetaclassAndBase]
from typing import Iterable, Iterator
import six
class M(type, Iterable[int]):
    x = 5
    def __iter__(self) -> Iterator[int]: ...
class A:
    def foo(self): pass
class B:
    def bar(self): pass
class C1(six.with_metaclass(M, A)): pass
@six.add_metaclass(M)
class D1(A): pass
class C2(six.with_metaclass(M, A, B)): pass
@six.add_metaclass(M)
class D2(A, B): pass
reveal_type(type(C1).x)  # N: Revealed type is "builtins.int"
reveal_type(type(D1).x)  # N: Revealed type is "builtins.int"
reveal_type(type(C2).x)  # N: Revealed type is "builtins.int"
reveal_type(type(D2).x)  # N: Revealed type is "builtins.int"
C1().foo()
D1().foo()
C1().bar()  # E: "C1" has no attribute "bar"
D1().bar()  # E: "D1" has no attribute "bar"
for x in C1: reveal_type(x)  # N: Revealed type is "builtins.int"
for x in C2: reveal_type(x)  # N: Revealed type is "builtins.int"
C2().foo()
D2().foo()
C2().bar()
D2().bar()
C2().baz()  # E: "C2" has no attribute "baz"
D2().baz()  # E: "D2" has no attribute "baz"
[builtins fixtures/tuple.pyi]

[case testSixMetaclassGenerics]
from typing import Generic, GenericMeta, TypeVar
import six
class DestroyableMeta(type):
    pass
class Destroyable(six.with_metaclass(DestroyableMeta)):
    pass
T_co = TypeVar('T_co', bound='Destroyable', covariant=True)
class ArcMeta(GenericMeta, DestroyableMeta):
    pass
class Arc(six.with_metaclass(ArcMeta, Generic[T_co], Destroyable)):
    pass
@six.add_metaclass(ArcMeta)
class Arc1(Generic[T_co], Destroyable):
    pass
class MyDestr(Destroyable):
    pass
reveal_type(Arc[MyDestr]())  # N: Revealed type is "__main__.Arc[__main__.MyDestr]"
reveal_type(Arc1[MyDestr]())  # N: Revealed type is "__main__.Arc1[__main__.MyDestr]"
[builtins fixtures/bool.pyi]
[typing fixtures/typing-full.pyi]

[case testSixMetaclassErrors]

import six
class M(type): pass
class A(object): pass
def f() -> type: return M
class C1(six.with_metaclass(M), object): pass  # E: Unsupported dynamic base class "six.with_metaclass"
class C2(C1, six.with_metaclass(M)): pass  # E: Unsupported dynamic base class "six.with_metaclass"
class C3(six.with_metaclass(A)): pass  # E: Metaclasses not inheriting from "type" are not supported
@six.add_metaclass(A)  # E: Metaclasses not inheriting from "type" are not supported \
                       # E: Argument 1 to "add_metaclass" has incompatible type "type[A]"; expected "type[type]"

class D3(A): pass
class C4(six.with_metaclass(M), metaclass=M): pass  # E: Multiple metaclass definitions
@six.add_metaclass(M)
class D4(metaclass=M): pass  # E: Multiple metaclass definitions
class C5(six.with_metaclass(f())): pass  # E: Dynamic metaclass not supported for "C5"
@six.add_metaclass(f())  # E: Dynamic metaclass not supported for "D5"
class D5: pass

@six.add_metaclass(M)
class CD(six.with_metaclass(M)): pass  # E: Multiple metaclass definitions

class M1(type): pass
class Q1(metaclass=M1): pass
@six.add_metaclass(M)
class CQA(Q1): pass  # E: Metaclass conflict: the metaclass of a derived class must be a (non-strict) subclass of the metaclasses of all its bases \
                     # N: "__main__.M" (metaclass of "__main__.CQA") conflicts with "__main__.M1" (metaclass of "__main__.Q1")
class CQW(six.with_metaclass(M, Q1)): pass  # E: Metaclass conflict: the metaclass of a derived class must be a (non-strict) subclass of the metaclasses of all its bases \
                                            # N: "__main__.M" (metaclass of "__main__.CQW") conflicts with "__main__.M1" (metaclass of "__main__.Q1")
[builtins fixtures/tuple.pyi]

[case testSixMetaclassAny]
import t  # type: ignore
import six
class E(metaclass=t.M): pass
class F(six.with_metaclass(t.M)): pass
@six.add_metaclass(t.M)
class G: pass
[builtins fixtures/tuple.pyi]

[case testSixMetaclassGenericBase]
import six
import abc
from typing import TypeVar, Generic

T = TypeVar("T")

class C(six.with_metaclass(abc.ABCMeta, Generic[T])):
    pass
class D(six.with_metaclass(abc.ABCMeta, C[T])):
    pass
[builtins fixtures/tuple.pyi]

-- Special support for future.utils
-- --------------------------------

[case testFutureMetaclass]
import future.utils
class M(type):
    x = 5
class A(future.utils.with_metaclass(M)): pass
reveal_type(type(A).x)  # N: Revealed type is "builtins.int"
[builtins fixtures/tuple.pyi]

[case testFromFutureMetaclass]
from future.utils import with_metaclass
class M(type):
    x = 5
class A(with_metaclass(M)): pass
reveal_type(type(A).x)  # N: Revealed type is "builtins.int"
[builtins fixtures/tuple.pyi]

[case testFutureMetaclassImportFrom]
import future.utils
from metadefs import M
class A(future.utils.with_metaclass(M)): pass
reveal_type(type(A).x)  # N: Revealed type is "builtins.int"
[file metadefs.py]
class M(type):
    x = 5
[builtins fixtures/tuple.pyi]

[case testFutureMetaclassImport]
import future.utils
import metadefs
class A(future.utils.with_metaclass(metadefs.M)): pass
reveal_type(type(A).x)  # N: Revealed type is "builtins.int"
[file metadefs.py]
class M(type):
    x = 5
[builtins fixtures/tuple.pyi]

[case testFutureMetaclassAndBase]
from typing import Iterable, Iterator
import future.utils
class M(type, Iterable[int]):
    x = 5
    def __iter__(self) -> Iterator[int]: ...
class A:
    def foo(self): pass
class B:
    def bar(self): pass
class C1(future.utils.with_metaclass(M, A)): pass
class C2(future.utils.with_metaclass(M, A, B)): pass
reveal_type(type(C1).x)  # N: Revealed type is "builtins.int"
reveal_type(type(C2).x)  # N: Revealed type is "builtins.int"
C1().foo()
C1().bar()  # E: "C1" has no attribute "bar"
for x in C1: reveal_type(x)  # N: Revealed type is "builtins.int"
for x in C2: reveal_type(x)  # N: Revealed type is "builtins.int"
C2().foo()
C2().bar()
C2().baz()  # E: "C2" has no attribute "baz"
[builtins fixtures/tuple.pyi]

[case testFutureMetaclassGenerics]
from typing import Generic, GenericMeta, TypeVar
import future.utils
class DestroyableMeta(type):
    pass
class Destroyable(future.utils.with_metaclass(DestroyableMeta)):
    pass
T_co = TypeVar('T_co', bound='Destroyable', covariant=True)
class ArcMeta(GenericMeta, DestroyableMeta):
    pass
class Arc(future.utils.with_metaclass(ArcMeta, Generic[T_co], Destroyable)):
    pass
class MyDestr(Destroyable):
    pass
reveal_type(Arc[MyDestr]())  # N: Revealed type is "__main__.Arc[__main__.MyDestr]"
[builtins fixtures/bool.pyi]
[typing fixtures/typing-full.pyi]

[case testFutureMetaclassErrors]
import future.utils
class M(type): pass
class A(object): pass
def f() -> type: return M
class C1(future.utils.with_metaclass(M), object): pass  # E: Unsupported dynamic base class "future.utils.with_metaclass"
class C2(C1, future.utils.with_metaclass(M)): pass  # E: Unsupported dynamic base class "future.utils.with_metaclass"
class C3(future.utils.with_metaclass(A)): pass  # E: Metaclasses not inheriting from "type" are not supported
class C4(future.utils.with_metaclass(M), metaclass=M): pass  # E: Multiple metaclass definitions
class C5(future.utils.with_metaclass(f())): pass  # E: Dynamic metaclass not supported for "C5"

class M1(type): pass
class Q1(metaclass=M1): pass
class CQW(future.utils.with_metaclass(M, Q1)): pass  # E: Metaclass conflict: the metaclass of a derived class must be a (non-strict) subclass of the metaclasses of all its bases \
                                                     # N: "__main__.M" (metaclass of "__main__.CQW") conflicts with "__main__.M1" (metaclass of "__main__.Q1")
[builtins fixtures/tuple.pyi]

[case testFutureMetaclassAny]
import t  # type: ignore
import future.utils
class E(metaclass=t.M): pass
class F(future.utils.with_metaclass(t.M)): pass

-- Misc
-- ----
[builtins fixtures/tuple.pyi]

[case testCorrectEnclosingClassPushedInDeferred]
class C:
    def __getattr__(self, attr: str) -> int:
        x: F
        return x.f

class F:
    def __init__(self, f: int) -> None:
        self.f = f
[out]

[case testCorrectEnclosingClassPushedInDeferred2]
from typing import TypeVar
T = TypeVar('T', bound='C')
class C:
    def m(self: T) -> T:
        class Inner:
            x: F
            f = x.f
        return self

class F:
    def __init__(self, f: int) -> None:
        self.f = f
[out]

[case testCorrectEnclosingClassPushedInDeferred3]
class A:
    def f(self) -> None:
        def g(x: int) -> int:
            return y

y = int()
[out]

[case testMetaclassMemberAccessViaType]
from typing import Type
class M(type):
    def m(cls, x: int) -> int:
        pass

class C(metaclass=M):
    pass
x = C
y: Type[C] = C

reveal_type(type(C).m) # N: Revealed type is "def (cls: __main__.M, x: builtins.int) -> builtins.int"
reveal_type(type(x).m) # N: Revealed type is "def (cls: __main__.M, x: builtins.int) -> builtins.int"
reveal_type(type(y).m) # N: Revealed type is "def (cls: __main__.M, x: builtins.int) -> builtins.int"
[out]

[case testMetaclassMemberAccessViaType2]
from typing import Any, Type
class M(type):
    def m(cls, x: int) -> int:
        pass
B: Any
class C(B, metaclass=M):
    pass

x: Type[C]
reveal_type(x.m) # N: Revealed type is "def (x: builtins.int) -> builtins.int"
reveal_type(x.whatever) # N: Revealed type is "Any"
[out]

[case testMetaclassMemberAccessViaType3]
from typing import Any, Type, TypeVar
T = TypeVar('T')
class C(Any):
    def bar(self: T) -> Type[T]: pass
    def foo(self) -> None:
        reveal_type(self.bar()) # N: Revealed type is "type[__main__.C]"
        reveal_type(self.bar().__name__) # N: Revealed type is "builtins.str"
[builtins fixtures/type.pyi]
[out]

[case testClassDecoratorIsTypeChecked]
from typing import Callable, Type
def decorate(x: int) -> Callable[[type], type]:  # N: "decorate" defined here
    ...
def decorate_forward_ref() -> Callable[[Type[A]], Type[A]]:
    ...
@decorate(y=17)    # E: Unexpected keyword argument "y" for "decorate"
@decorate()        # E: Missing positional argument "x" in call to "decorate"
@decorate(22, 25)  # E: Too many arguments for "decorate"
@decorate_forward_ref()
@decorate(11)
class A: pass

@decorate  # E: Argument 1 to "decorate" has incompatible type "type[A2]"; expected "int"
class A2: pass

[case testClassDecoratorIncorrect]
def not_a_class_decorator(x: int) -> int: ...
@not_a_class_decorator(7)
class A3: pass  # E: "int" not callable

not_a_function = 17
@not_a_function()  # E: "int" not callable
class B: pass

@not_a_function
class B2: pass    # E: "int" not callable

b = object()
@b.nothing         # E: "object" has no attribute "nothing"
class C: pass

@undefined         # E: Name "undefined" is not defined
class D: pass

[case testSlotsCompatibility]
class A:
    __slots__ = ()
class B(A):
    __slots__ = ('a', 'b')
class C:
    __slots__ = ('x',)
class D(B, C):  # E: Class "D" has incompatible disjoint bases
    __slots__ = ('aa', 'bb', 'cc')
[builtins fixtures/tuple.pyi]

[case testRevealLocalsOnClassVars]
class C1(object):
    t = 'a'
    y = 3.0
    class Inner(object): pass
    reveal_locals()

[out]
main:5: note: Revealed local types are:
main:5: note:     t: builtins.str
main:5: note:     y: builtins.float

[case testAbstractClasses]
import a
import b

[file a.pyi]
from abc import ABCMeta, abstractmethod
from typing import Protocol

class A:  # OK, has @abstractmethod
    @abstractmethod
    def f(self) -> None:
        pass

class B(A):  # E: Class a.B has abstract attributes "f"  # N: If it is meant to be abstract, add 'abc.ABCMeta' as an explicit metaclass
    pass

class C(A, metaclass=ABCMeta):  # OK, has ABCMeta as a metaclass
    pass

class D(A):  # OK, implements the abstract method
    def f(self) -> None:
        pass

class E(Protocol):  # OK, is a protocol
    @abstractmethod
    def f(self) -> None:
        pass

class F(E, Protocol):  # OK, is a protocol
    pass

# Custom metaclass subclassing `ABCMeta`, see #13561
class CustomMeta(ABCMeta):
    pass

class G(A, metaclass=CustomMeta):  # Ok, has CustomMeta as a metaclass
    pass

[file b.py]
# All of these are OK because this is not a stub file.
from abc import ABCMeta, abstractmethod
from typing import Protocol

class A:
    @abstractmethod
    def f(self) -> None:
        pass

class B(A):
    pass

class C(A, metaclass=ABCMeta):
    pass

class D(A):
    def f(self) -> None:
        pass

class E(Protocol):
    @abstractmethod
    def f(self) -> None:
        pass

class F(E, Protocol):
    pass

class CustomMeta(ABCMeta):
    pass

class G(A, metaclass=CustomMeta):
    pass

[case testClassMethodOverride]
from typing import Callable, Any

def deco(f: Callable[..., Any]) -> Callable[..., Any]: ...

class B:
    @classmethod
    def meth(cls, x: int) -> int: ...

class C(B):
    @classmethod
    @deco
    def meth(cls, x: int) -> int: ...
[builtins fixtures/classmethod.pyi]
[out]

[case testGetAttrImportAnnotation]
import a
x: a.A
y: a.A.B.C
reveal_type(x)  # N: Revealed type is "Any"
reveal_type(y)  # N: Revealed type is "Any"
[file a.pyi]
from typing import Any
def __getattr__(attr: str) -> Any: ...
[builtins fixtures/module.pyi]
[out]

[case testGetAttrImportBaseClass]
import a
class B(a.A): ...
[file a.pyi]
from typing import Any
def __getattr__(attr: str) -> Any: ...
[builtins fixtures/module.pyi]
[out]

[case testGetAttrDescriptor]
from typing import TypeVar, Generic, Any

T = TypeVar('T')
class C(Generic[T]):
    normal: T
    def __getattr__(self, attr: str) -> T: ...

class Descr:
    def __get__(self, inst: Any, owner: Any) -> int: ...

class D(C[Descr]):
    other: Descr

d: D
reveal_type(d.normal)  # N: Revealed type is "builtins.int"
reveal_type(d.dynamic)  # N: Revealed type is "__main__.Descr"
reveal_type(D.other)  # N: Revealed type is "builtins.int"
D.dynamic  # E: "type[D]" has no attribute "dynamic"
[out]

[case testSelfDescriptorAssign]
from typing import Any

class Descr:
    def __get__(self, inst: Any, owner: Any) -> int: ...

class C:
    def __init__(self, x: Descr) -> None:
        self.x = x

c = C(Descr())
reveal_type(c.x)  # N: Revealed type is "__main__.Descr"
[out]

[case testForwardInstanceWithWrongArgCount]
from typing import TypeVar, Generic

T = TypeVar('T')
class G(Generic[T]): ...

A = G
x: A[B[int, int]]  # E: "G" expects 1 type argument, but 2 given
B = G
[out]

[case testForwardInstanceWithNoArgs]
from typing import TypeVar, Generic

T = TypeVar('T')
class G(Generic[T]): ...

A = G
x: A[B]
reveal_type(x)  # N: Revealed type is "__main__.G[__main__.G[Any]]"
B = G
[out]

[case testForwardInstanceWithBound]
# flags: --show-column-numbers
from typing import TypeVar, Generic

T = TypeVar('T', bound=str)
class G(Generic[T]): ...

A = G
x: A[B[int]] # E
B = G
[out]
main:8:6: error: Type argument "G[int]" of "G" must be a subtype of "str"
main:8:8: error: Type argument "int" of "G" must be a subtype of "str"

[case testExtremeForwardReferencing]
from typing import TypeVar, Generic

T = TypeVar('T', covariant=True)
class B(Generic[T]): ...

y: A
z: A[int]
x = [y, z]
reveal_type(x)  # N: Revealed type is "builtins.list[__main__.B[Any]]"

A = B
[builtins fixtures/list.pyi]
[out]

[case testNoneAnyFallback]
from typing import Any
dynamic: Any
class C(dynamic): pass
x: None = C()  # E: Incompatible types in assignment (expression has type "C", variable has type "None")
[out]

[case testNoneAnyFallbackDescriptor]
from typing import Any
from d import Descr

dynamic: Any
class C(dynamic):
    id = Descr(int)
    name = Descr(str)

c: C
reveal_type(c.id)  # N: Revealed type is "builtins.int"
reveal_type(C.name)  # N: Revealed type is "d.Descr[builtins.str]"

[file d.pyi]
from typing import Any, overload, Generic, TypeVar, Type

T = TypeVar('T')
class Descr(Generic[T]):
    def __init__(self, tp: Type[T]) -> None: ...
    @overload
    def __get__(self, inst: None, owner: Any) -> Descr[T]: ...
    @overload
    def __get__(self, inst: object, owner: Any) -> T: ...
[out]

[case testClassCustomPropertyWorks]
from typing import TypeVar, Generic, Callable, Any

V = TypeVar('V')

class classproperty(Generic[V]):
    def __init__(self, getter: Callable[[Any], V]) -> None:
        self.getter = getter
    def __get__(self, instance: Any, owner: Any) -> V:
        return self.getter(owner)

class C:
    @classproperty
    def foo(cls) -> int:
        return 42

reveal_type(C.foo)  # N: Revealed type is "builtins.int"
reveal_type(C().foo)  # N: Revealed type is "builtins.int"
[out]

[case testMultipleInheritanceCycle]
import b
[file a.py]
from b import B
class A: ...
class C(A, B): ...
class D(C): ...
class Other: ...
[file b.py]
from a import Other
class B: ...
[out]

[case testMultipleInheritanceCycle2]
import b
[file a.py]
from b import B
class A: ...
class C(A, B): ...
class D(C): ...
class Other: ...
a: A
b: B
c: C
d: D
d = A()  # E: Incompatible types in assignment (expression has type "A", variable has type "D")
if int():
    d = B()  # E: Incompatible types in assignment (expression has type "B", variable has type "D")
if int():
    d = C()  # E: Incompatible types in assignment (expression has type "C", variable has type "D")
a = D()
b = D()
c = D()
[file b.py]
from a import Other
class B: ...
[out]

[case testAllowPropertyAndInit1]
class C:
    def __init__(self, x: int) -> None:
        self.x = x
    @property
    def x(self) -> int: pass
    @x.setter
    def x(self, x: int) -> None: pass
[builtins fixtures/property.pyi]
[out]

[case testAllowPropertyAndInit2]
class C:
    @property
    def x(self) -> int: pass
    @x.setter
    def x(self, x: int) -> None: pass
    def __init__(self, x: int) -> None:
        self.x = x
[builtins fixtures/property.pyi]

[case testAllowPropertyAndInit3]
class C:
    def __init__(self, x: int) -> None:
        self.x = x  # type: ignore
    @property  # Should be no error here
    def x(self) -> int: pass
[builtins fixtures/property.pyi]
[out]

[case testClassMethodBeforeInit1]
class Foo:
    @classmethod
    def bar(cls) -> Foo:
        return cls("bar")

    def __init__(self, baz: str) -> None:
        self.baz = baz
[builtins fixtures/classmethod.pyi]

[case testClassMethodBeforeInit2]
class Foo:
    @classmethod
    def bar(cls) -> Foo:
        return cls(Bar())

    def __init__(self, baz: 'Bar') -> None:
        self.baz = baz

class Bar: pass
[builtins fixtures/classmethod.pyi]

[case testClassMethodBeforeInit3]
from typing import overload
class Foo:
    @classmethod
    @overload
    def bar(cls, x: int) -> Foo: ...
    @classmethod
    @overload
    def bar(cls, x: str) -> Foo: ...
    @classmethod
    def bar(cls, x: object) -> Foo:
        return cls(x)

    def __init__(self, baz: object) -> None:
        self.baz = baz

[builtins fixtures/classmethod.pyi]

[case testNewAndInit1]
class A:
    def __init__(self, x: int) -> None:
        pass

class B(A):
    def __new__(cls) -> B:
        pass

B()

[case testNewAndInit2]
from typing import Any

class A:
    def __new__(cls, *args: Any) -> 'A':
        ...

class B(A):
    def __init__(self, x: int) -> None:
        pass

reveal_type(B)  # N: Revealed type is "def (x: builtins.int) -> __main__.B"
[builtins fixtures/tuple.pyi]

[case testNewAndInit3]
from typing import Any

class A:
    def __new__(cls, *args: Any) -> 'A':
        ...
    def __init__(self, x: int) -> None:
        pass

reveal_type(A)  # N: Revealed type is "def (x: builtins.int) -> __main__.A"
[builtins fixtures/tuple.pyi]

[case testCyclicDecorator]
import b
[file a.py]
import b
import c

class A(b.B):
    @c.deco
    def meth(self) -> int: ...
[file b.py]
import a
import c

class B:
    @c.deco
    def meth(self) -> int: ...
[file c.py]
from typing import TypeVar, Tuple, Callable
T = TypeVar('T')
def deco(f: Callable[..., T]) -> Callable[..., Tuple[T, int]]: ...
[builtins fixtures/tuple.pyi]
[out]

[case testCyclicOverload]
import b
[file a.pyi]
import b
from typing import overload

class A(b.B):
    @overload
    def meth(self, x: int) -> int: ...
    @overload
    def meth(self, x: str) -> str: ...
[file b.pyi]
import a
from typing import overload

class B:
    @overload
    def meth(self, x: int) -> int: ...
    @overload
    def meth(self, x: str) -> str: ...
[out]

[case testCyclicOverloadDeferred]
import b
[file a.py]
import b
from typing import overload, Union

class A(b.B):
    @overload
    def meth(self, x: int) -> int: ...
    @overload
    def meth(self, x: str) -> str: ...
    def meth(self, x) -> Union[int, str]:
        reveal_type(other.x)  # N: Revealed type is "builtins.int"
        return 0

other: Other
class Other:
    def __init__(self) -> None:
        self.x = f()
def f() -> int: ...
[file b.py]
import a
from typing import overload

class B:
    @overload
    def meth(self, x: int) -> int: ...
    @overload
    def meth(self, x: str) -> str: ...
    def meth(self, x):
        pass
[out]

[case testCyclicOverrideAny]
import a
[file b.py]
import a
class Sub(a.Base):
    def x(self) -> int: pass

[file a.py]
import b
class Base:
    def __init__(self):
        self.x = 1
[out]

[case testCyclicOverrideChecked]
import a
[file b.py]
import a
class Sub(a.Base):
    def x(self) -> int: pass  # E: Signature of "x" incompatible with supertype "Base" \
                              # N:      Superclass: \
                              # N:          int \
                              # N:      Subclass: \
                              # N:          def x(self) -> int

[file a.py]
import b
class Base:
    def __init__(self) -> None:
        self.x = 1
[out]

[case testCyclicOverrideCheckedDecorator]
import a
[file b.py]
import a
import c
class Sub(a.Base):
    @c.deco
    def x(self) -> int: pass  # E: Signature of "x" incompatible with supertype "Base" \
                              # N:      Superclass: \
                              # N:          int \
                              # N:      Subclass: \
                              # N:          def x(*Any, **Any) -> tuple[int, int]

[file a.py]
import b
import c
class Base:
    def __init__(self) -> None:
        self.x = 1
[file c.py]
from typing import TypeVar, Tuple, Callable
T = TypeVar('T')
def deco(f: Callable[..., T]) -> Callable[..., Tuple[T, int]]: ...
[builtins fixtures/tuple.pyi]
[out]

[case testCyclicOverrideCheckedDecoratorDeferred]
import a
[file b.py]
import a
import c
class Sub(a.Base):
    @c.deco
    def x(self) -> int: pass  # E: Signature of "x" incompatible with supertype "Base" \
                              # N:      Superclass: \
                              # N:          int \
                              # N:      Subclass: \
                              # N:          def x(*Any, **Any) -> tuple[int, int]

[file a.py]
import b
import c
class Base:
    def __init__(self) -> None:
        self.x = f()

def f() -> int: ...
[file c.py]
from typing import TypeVar, Tuple, Callable
T = TypeVar('T')
def deco(f: Callable[..., T]) -> Callable[..., Tuple[T, int]]: ...
[builtins fixtures/tuple.pyi]
[out]

[case testCyclicOverrideAnyDecoratorDeferred]
import a
[file b.py]
import a
import c
class Sub(a.Base):
    @c.deco
    def x(self) -> int: pass

[file a.py]
from b import Sub
import c
class Base:
    def __init__(self) -> None:
        self.x = f()

def f() -> int: ...
[file c.py]
from typing import Any, Callable
def deco(f: Callable[..., Any]) -> Any: ...
[out]

[case testCyclicDecoratorDoubleDeferred]
import b
[file a.py]
import b
import c

class A(b.B):
    @c.deco
    def meth(self) -> int:
        reveal_type(other.x)  # N: Revealed type is "builtins.int"
        return 0

other: Other
class Other:
    def __init__(self) -> None:
        self.x = f()
def f() -> int: ...
[file b.py]
from a import A
import c

class B:
    @c.deco
    def meth(self) -> int:
        pass
[file c.py]
from typing import TypeVar, Tuple, Callable
T = TypeVar('T')
def deco(f: Callable[..., T]) -> Callable[..., Tuple[T, int]]: ...
[builtins fixtures/tuple.pyi]
[out]

[case testCyclicDecoratorSuper]
import b
[file a.py]
import b
import c

class A(b.B):
    @c.deco
    def meth(self) -> int:
        y = super().meth()
        reveal_type(y)  # N: Revealed type is "tuple[builtins.int, builtins.int]"
        return 0
[file b.py]
from a import A
import c

class B:
    @c.deco
    def meth(self) -> int:
        pass
[file c.py]
from typing import TypeVar, Tuple, Callable
T = TypeVar('T')
def deco(f: Callable[..., T]) -> Callable[..., Tuple[T, int]]: ...
[builtins fixtures/tuple.pyi]
[out]

[case testCyclicDecoratorBothDeferred]
import b
[file a.py]
import b
import c

class A(b.B):
    @c.deco
    def meth(self) -> int:
        pass
[file b.py]
from a import A
import c

class B:
    @c.deco
    def meth(self) -> int:
        reveal_type(other.x)  # N: Revealed type is "builtins.int"
        return 0

other: Other
class Other:
    def __init__(self) -> None:
        self.x = f()
def f() -> int: ...
[file c.py]
from typing import TypeVar, Tuple, Callable
T = TypeVar('T')
def deco(f: Callable[..., T]) -> Callable[..., Tuple[T, int]]: ...
[builtins fixtures/tuple.pyi]
[out]

[case testCyclicDecoratorSuperDeferred]
import b
[file a.py]
import b
import c

class A(b.B):
    @c.deco
    def meth(self) -> int:
        y = super().meth()
        reveal_type(y)  # N: Revealed type is "tuple[builtins.int, builtins.int]"
        reveal_type(other.x)  # N: Revealed type is "builtins.int"
        return 0

other: Other
class Other:
    def __init__(self) -> None:
        self.x = f()
def f() -> int: ...
[file b.py]
from a import A
import c

class B:
    @c.deco
    def meth(self) -> int:
        pass
[file c.py]
from typing import TypeVar, Tuple, Callable
T = TypeVar('T')
def deco(f: Callable[..., T]) -> Callable[..., Tuple[T, int]]: ...
[builtins fixtures/tuple.pyi]

[case testOverrideWithUntypedNotChecked]
class Parent:
    def foo(self, x):
        ...
    def bar(self, x):
        ...
    def baz(self, x: int) -> str:
        return ""

class Child(Parent):
    def foo(self, y):  # OK: names not checked
        ...
    def bar(self, x, y):
        ...
    def baz(self, x, y):
        return ""
[builtins fixtures/tuple.pyi]

[case testOverrideWithUntypedCheckedWithCheckUntypedDefs]
# flags: --check-untyped-defs
class Parent:
    def foo(self, x):
        ...
    def bar(self, x):
        ...
    def baz(self, x: int) -> str:
        return ""

class Child(Parent):
    def foo(self, y):  # OK: names not checked
        ...
    def bar(self, x, y) -> None:  # E: Signature of "bar" incompatible with supertype "Parent" \
                                  # N:      Superclass: \
                                  # N:          def bar(self, x: Any) -> Any \
                                  # N:      Subclass: \
                                  # N:          def bar(self, x: Any, y: Any) -> None
        ...
    def baz(self, x, y):  # E: Signature of "baz" incompatible with supertype "Parent" \
                          # N:      Superclass: \
                          # N:          def baz(self, x: int) -> str \
                          # N:      Subclass: \
                          # N:          def baz(self, x: Any, y: Any) -> Any
        return ""
[builtins fixtures/tuple.pyi]

[case testOptionalDescriptorsBinder]
from typing import Type, TypeVar, Optional
T = TypeVar('T')

class IntDescr:
    def __get__(self, obj: T, typ: Type[T]) -> Optional[int]: ...
    def __set__(self, obj: T, value: Optional[int]) -> None: ...

class C:
    spec = IntDescr()

    def meth_spec(self) -> None:
        if self.spec is None:
            self.spec = 0
        reveal_type(self.spec)  # N: Revealed type is "builtins.int"
[builtins fixtures/bool.pyi]

[case testUnionDescriptorsBinder]
from typing import Type, TypeVar, Union
T = TypeVar('T')

class A: ...
class B: ...

class UnionDescr:
    def __get__(self, obj: T, typ: Type[T]) -> Union[A, B]: ...
    def __set__(self, obj: T, value: Union[A, B]) -> None: ...

class C:
    spec = UnionDescr()

    def meth_spec(self) -> None:
        self.spec = A()
        reveal_type(self.spec)  # N: Revealed type is "__main__.A"
[builtins fixtures/bool.pyi]

[case testSubclassDescriptorsBinder]
from typing import Type, TypeVar, Optional
T = TypeVar('T')

class A: ...
class B(A): ...

class SubDescr:
    def __get__(self, obj: T, typ: Type[T]) -> A: ...
    def __set__(self, obj: T, value: A) -> None: ...

class C:
    spec = SubDescr()

    def meth_spec(self) -> None:
        self.spec = B()
        reveal_type(self.spec)  # N: Revealed type is "__main__.B"
[builtins fixtures/bool.pyi]

[case testDecoratedDunderGet]
from typing import Any, Callable, TypeVar, Type

F = TypeVar('F', bound=Callable)
T = TypeVar('T')

def decorator(f: F) -> F:
    return f

def change(f: Callable) -> Callable[..., int]:
    pass

def untyped(f):
    return f

class A: ...

class Descr1:
    @decorator
    def __get__(self, obj: T, typ: Type[T]) -> A: ...
class Descr2:
    @change
    def __get__(self, obj: T, typ: Type[T]) -> A: ...
class Descr3:
    @untyped
    def __get__(self, obj: T, typ: Type[T]) -> A: ...

class C:
    spec1 = Descr1()
    spec2 = Descr2()
    spec3 = Descr3()

c: C
reveal_type(c.spec1)  # N: Revealed type is "__main__.A"
reveal_type(c.spec2)  # N: Revealed type is "builtins.int"
reveal_type(c.spec3)  # N: Revealed type is "Any"
[builtins fixtures/bool.pyi]

[case testDecoratedDunderSet]
from typing import Any, Callable, TypeVar, Type

F = TypeVar('F', bound=Callable)
T = TypeVar('T')

def decorator(f: F) -> F:
    return f

def change(f: Callable) -> Callable[[Any, Any, int], None]:
    pass

def untyped(f):
    return f

class A: ...

class Descr1:
    @decorator
    def __set__(self, obj: T, value: A) -> None: ...
class Descr2:
    @change
    def __set__(self, obj: T, value: A) -> None: ...
class Descr3:
    @untyped
    def __set__(self, obj: T, value: A) -> None: ...

class C:
    spec1 = Descr1()
    spec2 = Descr2()
    spec3 = Descr3()

c: C
c.spec1 = A()
c.spec1 = 1  # E: Incompatible types in assignment (expression has type "int", variable has type "A")
c.spec2 = A()  # E: Incompatible types in assignment (expression has type "A", variable has type "int")
c.spec2 = 1
c.spec3 = A()
c.spec3 = 1
[builtins fixtures/bool.pyi]

[case testClassLevelImport]
# flags: --ignore-missing-imports
class Test:
    import a
    def __init__(self) -> None:
        some_module = self.a
[out]

[case testIsInstanceTypeVsMetaclass]
from typing import Type
class Meta(type):
    pass
class Thing(metaclass=Meta):
    pass

def foo(x: Type[Thing]) -> Type[Thing]:
    assert isinstance(x, Meta)
    return x
[builtins fixtures/isinstancelist.pyi]

[case testIsInstanceTypeVsUnionOfType]
from typing import Type, Union

class AA: pass
class AB: pass

class M: pass

class A(M, AA): pass
class B(M, AB): pass

AOrB = Union[A, B]

class T(object):
    def __init__(self, typ: Type[AOrB] = A) -> None:
        assert isinstance(typ, type(M))
        self.typ: Type[AOrB] = typ
[builtins fixtures/isinstancelist.pyi]

[case testIsInstanceTypeIsSubclass]
from typing import Union, Type

class C: ...

x: Union[C, Type[C]]

if isinstance(x, type) and issubclass(x, C):
    reveal_type(x)  # N: Revealed type is "type[__main__.C]"
[builtins fixtures/isinstancelist.pyi]

[case testIsInstanceTypeByAssert]
class A:
    x = 42

i: type = A
assert issubclass(i, A)
reveal_type(i.x)  # N: Revealed type is "builtins.int"
[builtins fixtures/isinstancelist.pyi]

[case testIsInstanceTypeTypeVar]
from typing import Type, TypeVar, Generic, ClassVar

class Base: ...
class Sub(Base):
    other: ClassVar[int]

T = TypeVar('T', bound=Base)

class C(Generic[T]):
    def meth(self, cls: Type[T]) -> None:
        if not issubclass(cls, Sub):
            return
        reveal_type(cls)  # N: Revealed type is "type[T`1]"
        reveal_type(cls.other)  # N: Revealed type is "builtins.int"
[builtins fixtures/isinstance.pyi]

[case testIsInstanceTypeSubclass]
from typing import Type, Optional
class Base: ...
class One(Base):
    x: int
class Other(Base):
    x: int

def test() -> None:
    x: Optional[Type[Base]]
    if int():
        x = One
    elif int():
        x = Other
    else:
        return
    reveal_type(x)  # N: Revealed type is "Union[def () -> __main__.One, def () -> __main__.Other]"
    reveal_type(x.x)  # N: Revealed type is "builtins.int"
[builtins fixtures/isinstancelist.pyi]

[case testMemberRedefinition]
class C:
    def __init__(self) -> None:
        self.foo = 12
        self.foo: int = 12  # E: Attribute "foo" already defined on line 3

[case testMemberRedefinitionDefinedInClass]
class C:
    foo = 12
    def __init__(self) -> None:
        self.foo: int = 12  # E: Attribute "foo" already defined on line 2

[case testAbstractInit]
from abc import abstractmethod, ABCMeta
class A(metaclass=ABCMeta):
    @abstractmethod
    def __init__(self, a: int) -> None:
        pass
class B(A):
    pass
class C(B):
    def __init__(self, a: int) -> None:
        self.c = a
a = A(1) # E: Cannot instantiate abstract class "A" with abstract attribute "__init__"
A.c # E: "type[A]" has no attribute "c"
b = B(2) # E: Cannot instantiate abstract class "B" with abstract attribute "__init__"
B.c # E: "type[B]" has no attribute "c"
c = C(3)
c.c
C.c

[case testDecoratedConstructors]
from typing import TypeVar, Callable, Any

F = TypeVar('F', bound=Callable[..., Any])

def dec(f: F) -> F: ...

class A:
    @dec
    def __init__(self, x: int) -> None: ...

class B:
    @dec
    def __new__(cls, x: int) -> B: ...

reveal_type(A)  # N: Revealed type is "def (x: builtins.int) -> __main__.A"
reveal_type(B)  # N: Revealed type is "def (x: builtins.int) -> __main__.B"

[case testDecoratedConstructorsBad]
from typing import Callable, Any

def dec(f: Callable[[Any, int], Any]) -> int: ...

class A:
    @dec  # E: Unsupported decorated constructor type
    def __init__(self, x: int) -> None: ...

class B:
    @dec  # E: Unsupported decorated constructor type
    def __new__(cls, x: int) -> B: ...

[case testIgnorePrivateAttributesTypeCheck]
class B:
    __foo_: int
class C(B):
    __foo_: str
[out]

[case testIgnorePrivateMethodsTypeCheck]
class B:
    def __foo_(self) -> int: ...
class C(B):
    def __foo_(self) -> str: ...
[out]

[case testCheckForPrivateMethodsWhenPublicCheck]
class B:
    __foo__: int
class C(B):
    __foo__: str
[out]
main:4: error: Incompatible types in assignment (expression has type "str", base class "B" defined the type as "int")

[case testIgnorePrivateMethodsTypeCheck2]
class A:
    def __foo_(self) -> int: ...
class B:
    def __foo_(self) -> str: ...

class C(A, B): pass
[out]

[case testAttributeDefOrder1]
import a

[file a.py]
from b import C

class D(C):
    def g(self) -> None:
        self.x = '' # E: Incompatible types in assignment (expression has type "str", variable has type "int")

    def f(self) -> None:
        reveal_type(self.x) # N: Revealed type is "builtins.int"


[file b.py]
import a

class C:
    def __init__(self) -> None:
        self.x = 0

[targets b, a, b.C.__init__, a.D.g, a.D.f, __main__]

[case testAttributeDefOrder2]
class D(C):
    def g(self) -> None:
        self.x = ''  # E: Incompatible types in assignment (expression has type "str", variable has type "int")

    def f(self) -> None:
        reveal_type(self.x) # N: Revealed type is "builtins.int"


class C:
    def __init__(self) -> None:
        self.x = 0

class E(C):
    def g(self) -> None:
        self.x = '' # E: Incompatible types in assignment (expression has type "str", variable has type "int")

    def f(self) -> None:
        reveal_type(self.x) # N: Revealed type is "builtins.int"

[targets __main__, __main__, __main__.C.__init__, __main__.D.g, __main__.D.f, __main__.E.g, __main__.E.f]

[case testNewReturnType1]
class A:
    def __new__(cls) -> B:
        pass

class B(A): pass

reveal_type(A())  # N: Revealed type is "__main__.B"
reveal_type(B())  # N: Revealed type is "__main__.B"

[case testNewReturnType2]
from typing import Any

# make sure that __new__ method that return Any are ignored when
# determining the return type
class A:
    def __new__(cls):
        pass

class B:
    def __new__(cls) -> Any:
        pass

reveal_type(A())  # N: Revealed type is "__main__.A"
reveal_type(B())  # N: Revealed type is "__main__.B"

[case testNewReturnType3]

# Check for invalid __new__ typing

class A:
    def __new__(cls) -> int:  # E: Incompatible return type for "__new__" (returns "int", but must return a subtype of "A")
        pass

reveal_type(A())  # N: Revealed type is "__main__.A"

[case testNewReturnType4]
from typing import TypeVar, Type

# Check for __new__ using type vars

TX = TypeVar('TX', bound='X')
class X:
    def __new__(lol: Type[TX], x: int) -> TX:
        pass
class Y(X): pass

reveal_type(X(20))  # N: Revealed type is "__main__.X"
reveal_type(Y(20))  # N: Revealed type is "__main__.Y"

[case testNewReturnType5]
from typing import Any, TypeVar, Generic, overload

T = TypeVar('T')
class O(Generic[T]):
    @overload
    def __new__(cls) -> O[int]:
        pass
    @overload
    def __new__(cls, x: int) -> O[str]:
        pass
    def __new__(cls, x: int = 0) -> O[Any]:
        pass

reveal_type(O())  # N: Revealed type is "__main__.O[builtins.int]"
reveal_type(O(10))  # N: Revealed type is "__main__.O[builtins.str]"

[case testNewReturnType6]
from typing import Tuple, Optional

# Check for some cases that aren't allowed

class X:
    def __new__(cls) -> Optional[Y]:  # E: "__new__" must return a class instance (got "Optional[Y]")
        pass
class Y:
    def __new__(cls) -> Optional[int]:  # E: "__new__" must return a class instance (got "Optional[int]")
        pass


[case testNewReturnType7]
from typing import NamedTuple

# ... test __new__ returning tuple type
class A:
    def __new__(cls) -> 'B':
        pass

N = NamedTuple('N', [('x', int)])
class B(A, N): pass

reveal_type(A())  # N: Revealed type is "tuple[builtins.int, fallback=__main__.B]"
[builtins fixtures/tuple.pyi]

[case testNewReturnType8]
from typing import TypeVar, Any

# test type var from a different argument
TX = TypeVar('TX', bound='X')
class X:
    def __new__(cls, x: TX) -> TX:  # E: "__new__" must return a class instance (got "TX")
        pass

[case testNewReturnType9]
class A:
    def __new__(cls) -> A:
        pass

class B(A):
    pass

reveal_type(B())  # N: Revealed type is "__main__.B"

[case testNewReturnType10]
# https://github.com/python/mypy/issues/11398
from typing import Type

class MyMetaClass(type):
    def __new__(cls, name, bases, attrs) -> Type['MyClass']:
        pass

class MyClass(metaclass=MyMetaClass):
    pass

[case testNewReturnType11]
# https://github.com/python/mypy/issues/11398
class MyMetaClass(type):
    def __new__(cls, name, bases, attrs) -> type:
        pass

class MyClass(metaclass=MyMetaClass):
    pass

[case testNewReturnType12]
# https://github.com/python/mypy/issues/11398
from typing import Type

class MyMetaClass(type):
    def __new__(cls, name, bases, attrs) -> int:  # E: Incompatible return type for "__new__" (returns "int", but must return a subtype of "type")
        pass

class MyClass(metaclass=MyMetaClass):
    pass


[case testMetaclassPlaceholderNode]
from sympy.assumptions import ManagedProperties
from sympy.ops import AssocOp
reveal_type(AssocOp.x)  # N: Revealed type is "sympy.basic.Basic"
reveal_type(AssocOp.y)  # N: Revealed type is "builtins.int"

[file sympy/__init__.py]

[file sympy/assumptions.py]
from .basic import Basic
class ManagedProperties(type):
    x: Basic
    y: int
# The problem is with the next line,
# it creates the following order (classname, metaclass):
# 1. Basic NameExpr(ManagedProperties)
# 2. AssocOp None
# 3. ManagedProperties None
# 4. Basic NameExpr(ManagedProperties [sympy.assumptions.ManagedProperties])
# So, `AssocOp` will still have `metaclass_type` as `None`
# and all its `mro` types will have `declared_metaclass` as `None`.
from sympy.ops import AssocOp

[file sympy/basic.py]
from .assumptions import ManagedProperties
class Basic(metaclass=ManagedProperties): ...

[file sympy/ops.py]
from sympy.basic import Basic
class AssocOp(Basic): ...

[case testMetaclassSubclassSelf]
# This does not make much sense, but we must not crash:
import a
[file m.py]
from a import A  # E: Module "a" has no attribute "A"
class Meta(A): pass
[file a.py]
from m import Meta
class A(metaclass=Meta): pass

[case testMetaclassConflict]
class MyMeta1(type): ...
class MyMeta2(type): ...
class MyMeta3(type): ...
class A(metaclass=MyMeta1): ...
class B(metaclass=MyMeta2): ...
class C(metaclass=type): ...
class A1(A): ...
class E: ...

class CorrectMeta(MyMeta1, MyMeta2): ...
class CorrectSubclass1(A1, B, E, metaclass=CorrectMeta): ...
class CorrectSubclass2(A, B, E, metaclass=CorrectMeta): ...
class CorrectSubclass3(B, A, metaclass=CorrectMeta): ...

class ChildOfCorrectSubclass1(CorrectSubclass1): ...

class CorrectWithType1(C, A1): ...
class CorrectWithType2(B, C): ...

class Conflict1(A1, B, E): ...  # E: Metaclass conflict: the metaclass of a derived class must be a (non-strict) subclass of the metaclasses of all its bases \
                                # N: "__main__.MyMeta1" (metaclass of "__main__.A") conflicts with "__main__.MyMeta2" (metaclass of "__main__.B")
class Conflict2(A, B): ...  # E: Metaclass conflict: the metaclass of a derived class must be a (non-strict) subclass of the metaclasses of all its bases \
                            # N: "__main__.MyMeta1" (metaclass of "__main__.A") conflicts with "__main__.MyMeta2" (metaclass of "__main__.B")
class Conflict3(B, A): ...  # E: Metaclass conflict: the metaclass of a derived class must be a (non-strict) subclass of the metaclasses of all its bases \
                            # N: "__main__.MyMeta2" (metaclass of "__main__.B") conflicts with "__main__.MyMeta1" (metaclass of "__main__.A")

class ChildOfConflict1(Conflict3): ...
class ChildOfConflict2(Conflict3, metaclass=CorrectMeta): ...

class ConflictingMeta(MyMeta1, MyMeta3): ...
class Conflict4(A1, B, E, metaclass=ConflictingMeta): ...  # E: Metaclass conflict: the metaclass of a derived class must be a (non-strict) subclass of the metaclasses of all its bases \
                                                           # N: "__main__.ConflictingMeta" (metaclass of "__main__.Conflict4") conflicts with "__main__.MyMeta2" (metaclass of "__main__.B")

class ChildOfCorrectButWrongMeta(CorrectSubclass1, metaclass=ConflictingMeta):  # E: Metaclass conflict: the metaclass of a derived class must be a (non-strict) subclass of the metaclasses of all its bases \
                                                                                # N: "__main__.ConflictingMeta" (metaclass of "__main__.ChildOfCorrectButWrongMeta") conflicts with "__main__.CorrectMeta" (metaclass of "__main__.CorrectSubclass1")
    ...

[case testMetaClassConflictIssue14033]
class M1(type): pass
class M2(type): pass
class Mx(M1, M2): pass

class A1(metaclass=M1): pass
class A2(A1): pass

class B1(metaclass=M2): pass

class C1(metaclass=Mx): pass

class TestABC(A2, B1, C1): pass  # E: Metaclass conflict: the metaclass of a derived class must be a (non-strict) subclass of the metaclasses of all its bases \
                                 # N: "__main__.M1" (metaclass of "__main__.A1") conflicts with "__main__.M2" (metaclass of "__main__.B1")
class TestBAC(B1, A2, C1): pass  # E: Metaclass conflict: the metaclass of a derived class must be a (non-strict) subclass of the metaclasses of all its bases \
                                 # N: "__main__.M2" (metaclass of "__main__.B1") conflicts with "__main__.M1" (metaclass of "__main__.A1")

# should not warn again for children
class ChildOfTestABC(TestABC): pass

# no metaclass is assumed if super class has a metaclass conflict
class ChildOfTestABCMetaMx(TestABC, metaclass=Mx): pass
class ChildOfTestABCMetaM1(TestABC, metaclass=M1): pass

class TestABCMx(A2, B1, C1, metaclass=Mx): pass
class TestBACMx(B1, A2, C1, metaclass=Mx): pass

class TestACB(A2, C1, B1): pass
class TestBCA(B1, C1, A2): pass

class TestCAB(C1, A2, B1): pass
class TestCBA(C1, B1, A2): pass

[case testGenericOverride]
from typing import Generic, TypeVar, Any

T = TypeVar('T')

class B(Generic[T]):
    x: T

class C(B):
    def __init__(self) -> None:
        self.x: Any

[case testGenericOverridePreciseInvalid]
from typing import Generic, TypeVar, Any

T = TypeVar('T')

class B(Generic[T]):
    x: T

class C(B[str]):
    def __init__(self) -> None:
        self.x: int  # E: Incompatible types in assignment (expression has type "int", base class "B" defined the type as "str")

[case testGenericOverridePreciseValid]
from typing import Generic, TypeVar

T = TypeVar('T')

class B(Generic[T]):
    x: T

class C(B[float]):
    def __init__(self) -> None:
        self.x: int  # We currently allow covariant overriding.

[case testGenericOverrideGeneric]
from typing import Generic, TypeVar, List

T = TypeVar('T')

class B(Generic[T]):
    x: T

class C(B[T]):
    def __init__(self) -> None:
        self.x: List[T]  # E: Incompatible types in assignment (expression has type "list[T]", base class "B" defined the type as "T")
[builtins fixtures/list.pyi]

[case testGenericOverrideGenericChained]
from typing import Generic, TypeVar, Tuple

T = TypeVar('T')
S = TypeVar('S')

class A(Generic[T]):
    x: T

class B(A[Tuple[T, S]]): ...

class C(B[int, T]):
    def __init__(self) -> None:
        # TODO: error message could be better.
        self.x: Tuple[str, T]  # E: Incompatible types in assignment (expression has type "tuple[str, T]", base class "A" defined the type as "tuple[int, T]")
[builtins fixtures/tuple.pyi]

[case testInitSubclassWrongType]
class Base:
    default_name: str

    def __init_subclass__(cls, default_name: str):
        super().__init_subclass__()
        cls.default_name = default_name
        return

class Child(Base, default_name=5):  # E: Argument "default_name" to "__init_subclass__" of "Base" has incompatible type "int"; expected "str"
    pass
[builtins fixtures/object_with_init_subclass.pyi]

[case testInitSubclassTooFewArgs]
class Base:
    default_name: str

    def __init_subclass__(cls, default_name: str, **kwargs):
        super().__init_subclass__()
        cls.default_name = default_name
        return

class Child(Base):  # E: Missing positional argument "default_name" in call to "__init_subclass__" of "Base"
    pass
[builtins fixtures/object_with_init_subclass.pyi]

[case testInitSubclassTooFewArgs2]
class Base:
    default_name: str

    def __init_subclass__(cls, default_name: str, thing: int):
        super().__init_subclass__()
        cls.default_name = default_name
        return
# TODO implement this, so that no error is raised?
d = {"default_name": "abc", "thing": 0}
class Child(Base, **d):  # E: Missing positional arguments "default_name", "thing" in call to "__init_subclass__" of "Base"
    pass
[builtins fixtures/object_with_init_subclass.pyi]

[case testInitSubclassOK]
class Base:
    default_name: str
    thing: int

    def __init_subclass__(cls, default_name: str, thing:int, **kwargs):
        super().__init_subclass__()
        cls.default_name = default_name
        return

class Child(Base, thing=5, default_name=""):
    pass
[builtins fixtures/object_with_init_subclass.pyi]

[case testInitSubclassWithMetaclassOK]
class Base:
    thing: int

    def __init_subclass__(cls, thing: int):
        cls.thing = thing

class Child(Base, metaclass=type, thing=0):
    pass
[builtins fixtures/object_with_init_subclass.pyi]

[case testInitSubclassWithCustomMetaclassOK]
class M(type): ...
class Child(metaclass=M, thing=0):
    pass
[builtins fixtures/object_with_init_subclass.pyi]

[case testTooManyArgsForObject]
class A(thing=5):
    pass
[out]
main:1: error: Unexpected keyword argument "thing" for "__init_subclass__" of "object"
tmp/builtins.pyi:5: note: "__init_subclass__" of "object" defined here
[builtins fixtures/object_with_init_subclass.pyi]

[case testInitSubclassWithImports]
from init_subclass.a import Base
class Child(Base, thing=5):  # E: Missing positional argument "default_name" in call to "__init_subclass__" of "Base"
    pass
[file init_subclass/a.py]
class Base:
    default_name: str
    thing: int

    def __init_subclass__(cls, default_name: str, thing:int, **kwargs):
        pass
[file init_subclass/__init__.py]
[builtins fixtures/object_with_init_subclass.pyi]

[case testInitSubclassWithImportsOK]
from init_subclass.a import MidBase
class Main(MidBase, test=True): pass
[file init_subclass/a.py]
class Base:
    def __init_subclass__(cls, **kwargs) -> None: pass
class MidBase(Base): pass
[file init_subclass/__init__.py]
[builtins fixtures/object_with_init_subclass.pyi]

[case testInitSubclassUnannotated]
class A:
    def __init_subclass__(cls, *args, **kwargs):
        super().__init_subclass__(*args, **kwargs)

class B(A):
    pass

reveal_type(A.__init_subclass__)  # N: Revealed type is "def (*args: Any, **kwargs: Any) -> Any"
[builtins fixtures/object_with_init_subclass.pyi]

[case testInitSubclassUnannotatedMulti]
from typing import ClassVar, List, Type

class A:
    registered_classes: ClassVar[List[Type[A]]] = []
    def __init_subclass__(cls, *args, register=True, **kwargs):
        if register:
            cls.registered_classes.append(cls)
        super().__init_subclass__(*args, **kwargs)

class B(A): ...
class C(A, register=False): ...
class D(C): ...
[builtins fixtures/object_with_init_subclass.pyi]

[case testClassMethodUnannotated]
class C:
    def __new__(cls): ...
    @classmethod
    def meth(cls): ...

reveal_type(C.meth)  # N: Revealed type is "def () -> Any"
reveal_type(C.__new__)  # N: Revealed type is "def (cls: type[__main__.C]) -> Any"
[builtins fixtures/classmethod.pyi]

[case testOverrideGenericSelfClassMethod]
from typing import Generic, TypeVar, Type, List

T = TypeVar('T', bound='A')

class A:
    @classmethod
    def meth(cls: Type[T]) -> List[T]: ...

class B(A):
    @classmethod
    def meth(cls: Type[T]) -> List[T]: ...

[builtins fixtures/isinstancelist.pyi]

[case testCheckUntypedDefsSelf1]
# flags: --check-untyped-defs

from typing import Generic, TypeVar
T = TypeVar('T')

class Desc:
    def __get__(self, x, y):
        # type: (...) -> bool
        pass

class Foo:
    y = Desc()

    def __init__(self):
        self.x = 0

    def foo(self):
        reveal_type(self.x)  # N: Revealed type is "builtins.int"
        reveal_type(self.y)  # N: Revealed type is "builtins.bool"
        self.bar()
        self.baz()  # E: "Foo" has no attribute "baz"

    @classmethod
    def bar(cls):
        cls.baz()  # E: "type[Foo]" has no attribute "baz"

class C(Generic[T]):
    x: T
    def meth(self):
        self.x + 1  # E: Unsupported left operand type for + ("T")
[builtins fixtures/classmethod.pyi]

[case testCheckUntypedDefsSelf2]
# flags: --check-untyped-defs

class Foo:
    def __init__(self):
        self.x = None
        self.y = []

reveal_type(Foo().x)  # N: Revealed type is "Union[Any, None]"
reveal_type(Foo().y)  # N: Revealed type is "builtins.list[Any]"
[builtins fixtures/list.pyi]

[case testCheckUntypedDefsSelf3]
# flags: --check-untyped-defs

class Foo:
    def bad():  # E: Method must have at least one argument. Did you forget the "self" argument?
        self.x = 0  # E: Name "self" is not defined

[case testMethodSelfArgumentChecks]
from typing import Callable, ParamSpec, TypeVar

T = TypeVar("T")
P = ParamSpec("P")

def to_number_1(fn: Callable[[], int]) -> int:
    return 0

def to_number_2(fn: Callable[[int], int]) -> int:
    return 0

def to_same_callable(fn: Callable[P, T]) -> Callable[P, T]:
    return fn

class A:
    def undecorated() -> None: ...  # E: Method must have at least one argument. Did you forget the "self" argument?

    def undecorated_not_self(x: int) -> None: ...  # E: Self argument missing for a non-static method (or an invalid type for self)

    def undecorated_not_self_2(self: int) -> None: ...  # E: The erased type of self "builtins.int" is not a supertype of its class "__main__.A"

    @to_number_1
    def fn1() -> int:
        return 0

    @to_number_1  # E: Argument 1 to "to_number_1" has incompatible type "Callable[[int], int]"; expected "Callable[[], int]"
    def fn2(_x: int) -> int:
        return 0

    @to_number_2  # E: Argument 1 to "to_number_2" has incompatible type "Callable[[], int]"; expected "Callable[[int], int]"
    def fn3() -> int:
        return 0

    @to_number_2
    def fn4(_x: int) -> int:
        return 0

    @to_number_2  # E: Argument 1 to "to_number_2" has incompatible type "Callable[[str], int]"; expected "Callable[[int], int]"
    def fn5(_x: str) -> int:
        return 0

    @to_same_callable
    def g1() -> None: ...  # E: Method must have at least one argument. Did you forget the "self" argument?

    @to_same_callable
    def g2(x: int) -> None: ...  # E: Self argument missing for a non-static method (or an invalid type for self)

    @to_same_callable
    def g3(self: int) -> None: ...  # E: The erased type of self "builtins.int" is not a supertype of its class "__main__.A"

reveal_type(A().fn1)  # N: Revealed type is "builtins.int"
reveal_type(A().fn2)  # N: Revealed type is "builtins.int"
reveal_type(A().fn3)  # N: Revealed type is "builtins.int"
reveal_type(A().fn4)  # N: Revealed type is "builtins.int"
reveal_type(A().fn5)  # N: Revealed type is "builtins.int"

reveal_type(A().g1)  # E: Attribute function "g1" with type "Callable[[], None]" does not accept self argument \
                     # N: Revealed type is "def ()"
reveal_type(A().g2)  # E: Invalid self argument "A" to attribute function "g2" with type "Callable[[int], None]" \
                     # N: Revealed type is "def ()"
reveal_type(A().g3)  # E: Invalid self argument "A" to attribute function "g3" with type "Callable[[int], None]" \
                     # N: Revealed type is "def ()"
[builtins fixtures/tuple.pyi]

[case testMethodSelfArgumentChecksConcatenate]
from typing import Callable, ParamSpec, TypeVar
from typing_extensions import Concatenate

T = TypeVar("T")
P = ParamSpec("P")
R = TypeVar("R")

def to_same_callable(fn: Callable[Concatenate[T, P], R]) -> Callable[Concatenate[T, P], R]:
    return fn

def remove_first(fn: Callable[Concatenate[T, P], R]) -> Callable[P, R]:
    ...

def add_correct_first(fn: Callable[P, R]) -> Callable[Concatenate["C", P], R]:
    ...

def add_wrong_first(fn: Callable[P, R]) -> Callable[Concatenate[int, P], R]:
    ...

class A:
    @to_same_callable  # E: Argument 1 to "to_same_callable" has incompatible type "Callable[[], int]"; expected "Callable[[T], int]"
    def fn1() -> int:
        return 0

    @to_same_callable
    def fn2(_x: int) -> int:  # E: Self argument missing for a non-static method (or an invalid type for self)
        return 0

    @to_same_callable
    def fn3(self, _x: int) -> int:
        return 0

reveal_type(A().fn1)  # N: Revealed type is "def () -> builtins.int"
reveal_type(A().fn2)  # E: Invalid self argument "A" to attribute function "fn2" with type "Callable[[int], int]" \
                      # N: Revealed type is "def () -> builtins.int"
reveal_type(A().fn3)  # N: Revealed type is "def (_x: builtins.int) -> builtins.int"

class B:
    @remove_first  # E: Argument 1 to "remove_first" has incompatible type "Callable[[], int]"; expected "Callable[[T], int]"
    def fn1() -> int:  # E: Method must have at least one argument. Did you forget the "self" argument?
        return 0

    @remove_first
    def fn2(_x: int) -> int:  # E: Method must have at least one argument. Did you forget the "self" argument?
        return 0

    @remove_first
    def fn3(self, _x: int) -> int:  # E: Self argument missing for a non-static method (or an invalid type for self)
        return 0

    @remove_first
    def fn4(self, new_self: 'B') -> int:
        return 0

reveal_type(B().fn1)  # E: Attribute function "fn1" with type "Callable[[], int]" does not accept self argument \
                      # N: Revealed type is "def () -> builtins.int"
reveal_type(B().fn2)  # E: Attribute function "fn2" with type "Callable[[], int]" does not accept self argument \
                      # N: Revealed type is "def () -> builtins.int"
reveal_type(B().fn3)  # E: Invalid self argument "B" to attribute function "fn3" with type "Callable[[int], int]" \
                      # N: Revealed type is "def () -> builtins.int"
reveal_type(B().fn4)  # N: Revealed type is "def () -> builtins.int"

class C:
    @add_correct_first
    def fn1() -> int:
        return 0

    @add_correct_first
    def fn2(_x: int) -> int:
        return 0

    @add_correct_first
    def fn3(self, _x: int) -> int:
        return 0

reveal_type(C().fn1)  # N: Revealed type is "def () -> builtins.int"
reveal_type(C().fn2)  # N: Revealed type is "def (_x: builtins.int) -> builtins.int"
reveal_type(C().fn3)  # N: Revealed type is "def (self: __main__.C, _x: builtins.int) -> builtins.int"

class D:
    @add_wrong_first
    def fn1() -> int:  # E: Self argument missing for a non-static method (or an invalid type for self)
        return 0

    @add_wrong_first
    def fn2(_x: int) -> int:  # E: Self argument missing for a non-static method (or an invalid type for self)
        return 0

    @add_wrong_first
    def fn3(self, _x: int) -> int:  # E: Self argument missing for a non-static method (or an invalid type for self)
        return 0

reveal_type(D().fn1)  # E: Invalid self argument "D" to attribute function "fn1" with type "Callable[[int], int]" \
                      # N: Revealed type is "def () -> builtins.int"
reveal_type(D().fn2)  # E: Invalid self argument "D" to attribute function "fn2" with type "Callable[[int, int], int]" \
                      # N: Revealed type is "def (_x: builtins.int) -> builtins.int"
reveal_type(D().fn3)  # E: Invalid self argument "D" to attribute function "fn3" with type "Callable[[int, D, int], int]" \
                      # N: Revealed type is "def (self: __main__.D, _x: builtins.int) -> builtins.int"
[builtins fixtures/tuple.pyi]

[case testMethodSelfArgumentChecksInUntyped]
from typing import Callable, ParamSpec, TypeVar

T = TypeVar("T")
P = ParamSpec("P")

def to_same_callable(fn: Callable[P, T]) -> Callable[P, T]:
    return fn

def unchecked():
    class Bad:
        def fn() -> None: ...  # E: Method must have at least one argument. Did you forget the "self" argument?
        def fn2(x: int) -> None: ...  # E: Self argument missing for a non-static method (or an invalid type for self)

        # TODO: would be nice to make this error, but now we see the func
        # being decorated as Any, not as a callable
        @to_same_callable
        def gaaa() -> None: ...
        @to_same_callable
        def gaaa2(x: int) -> None: ...

    class Ok:
        def fn(): ...
        def fn2(x): ...

        @to_same_callable
        def g(): ...
        @to_same_callable
        def g2(x): ...

def checked() -> None:
    class Bad:
        def fn() -> None: ...  # E: Method must have at least one argument. Did you forget the "self" argument?
        def fn2(x: int) -> None: ...  # E: Self argument missing for a non-static method (or an invalid type for self)

        @to_same_callable
        def g() -> None: ...  # E: Method must have at least one argument. Did you forget the "self" argument?
        @to_same_callable
        def g2(x: int) -> None: ...  # E: Self argument missing for a non-static method (or an invalid type for self)

    class AlsoBad:
        def fn(): ...  # E: Method must have at least one argument. Did you forget the "self" argument?
        def fn2(x): ...

        @to_same_callable
        def g(): ...  # E: Method must have at least one argument. Did you forget the "self" argument?
        @to_same_callable
        def g2(x): ...

class Ok:
    def fn(): ...  # E: Method must have at least one argument. Did you forget the "self" argument?
    def fn2(x): ...

    @to_same_callable
    def g(): ...  # E: Method must have at least one argument. Did you forget the "self" argument?
    @to_same_callable
    def g2(x): ...
[builtins fixtures/tuple.pyi]

[case testTypeAfterAttributeAccessWithDisallowAnyExpr]
# flags: --disallow-any-expr

def access_before_declaration(self) -> None:
    obj = Foo('bar')
    obj.value
    x = 1

    reveal_type(x)  # N: Revealed type is "builtins.int"
    x = x + 1

class Foo:
    def __init__(self, value: str) -> None:
        self.value = value

def access_after_declaration(self) -> None:
    obj = Foo('bar')
    obj.value
    x = 1

    reveal_type(x)  # N: Revealed type is "builtins.int"
    x = x + 1

[case testIsSubClassNarrowDownTypesOfTypeVariables]
from typing import Type, TypeVar, Generic

class Base:
    field: int = 42

TypeT = TypeVar("TypeT", bound=type)

TypeT1 = TypeVar("TypeT1", bound=Type[Base])

class C1:
    def method(self, other: type) -> int:
        if issubclass(other, Base):
            reveal_type(other)  # N: Revealed type is "type[__main__.Base]"
            return other.field
        return 0

class C2(Generic[TypeT]):
    def method(self, other: TypeT) -> int:
        if issubclass(other, Base):
            reveal_type(other)  # N: Revealed type is "TypeT`1"
            return other.field
        return 0

class C3(Generic[TypeT1]):
    def method(self, other: TypeT1) -> int:
        if issubclass(other, Base):
            reveal_type(other)  # N: Revealed type is "TypeT1`1"
            return other.field
        return 0

[builtins fixtures/isinstancelist.pyi]

[case testPropertyWithExtraMethod]
def dec(f):
    return f

class A:
    @property
    def x(self): ...
    @x.setter
    def x(self, value) -> None: ...
    def x(self) -> None: ...  # E: Unexpected definition for property "x"

    @property
    def y(self) -> int: ...
    @y.setter
    def y(self, value: int) -> None: ...
    @dec  # E: Only supported top decorators are "@y.setter" and "@y.deleter"
    def y(self) -> None: ...

reveal_type(A().y)  # N: Revealed type is "builtins.int"
[builtins fixtures/property.pyi]

[case testEnclosingScopeLambdaNoCrash]
class C:
    x = lambda x: x.y.g()

[case testEnclosingScopeLambdaNoCrashExplicit]
from typing import Callable
class C:
    x: Callable[[C], int] = lambda x: x.y.g()  # E: "C" has no attribute "y"

[case testOpWithInheritedFromAny-xfail]
from typing import Any
C: Any
class D(C):
    pass

class D1(C):
    def __add__(self, rhs: float) -> D1:
        return self

reveal_type(0.5 + C)  # N: Revealed type is "Any"

reveal_type(0.5 + D())  # N: Revealed type is "Any"
reveal_type(D() + 0.5)  # N: Revealed type is "Any"
reveal_type("str" + D())  # N: Revealed type is "builtins.str"
reveal_type(D() + "str")  # N: Revealed type is "Any"


reveal_type(0.5 + D1())  # N: Revealed type is "Any"
reveal_type(D1() + 0.5)  # N: Revealed type is "__main__.D1"
[builtins fixtures/primitives.pyi]

[case testRefMethodWithDecorator]
from typing import Type, final

class A:
    pass

class B:
    @staticmethod
    def A() -> Type[A]: ...
    @staticmethod
    def B() -> Type[A]:  # E: Function "__main__.B.A" is not valid as a type \
                         # N: Perhaps you need "Callable[...]" or a callback protocol?
        return A

class C:
    @final
    @staticmethod
    def A() -> Type[A]:
        return A

[builtins fixtures/staticmethod.pyi]

[case testRefMethodWithOverloadDecorator]
from typing import Type, overload

class A:
    pass

class B:
    @classmethod
    @overload
    def A(cls, x: int) -> Type[A]: ...
    @classmethod
    @overload
    def A(cls, x: str) -> Type[A]: ...
    @classmethod
    def A(cls, x: object) -> Type[A]: ...
    def B(cls, x: int) -> Type[A]: ...  # E: Function "__main__.B.A" is not valid as a type \
                                        # N: Perhaps you need "Callable[...]" or a callback protocol?

[builtins fixtures/classmethod.pyi]

[case testFinalClassWithAbstractAttributes]
from abc import abstractmethod, ABCMeta
from typing import final

@final
class A(metaclass=ABCMeta):  # E: Final class __main__.A has abstract attributes "bar", "foo"
    @abstractmethod
    def foo(self):
        pass

    @property
    @abstractmethod
    def bar(self):
        pass

[builtins fixtures/property.pyi]

[case testFinalClassWithoutABCMeta]
from abc import abstractmethod
from typing import final

@final
class A():  # E: Final class __main__.A has abstract attributes "bar", "foo"
    @abstractmethod
    def foo(self):
        pass

    @property
    @abstractmethod
    def bar(self):
        pass

[builtins fixtures/property.pyi]

[case testFinalClassInheritedAbstractAttributes]
from abc import abstractmethod, ABCMeta
from typing import final

class A(metaclass=ABCMeta):
    @abstractmethod
    def foo(self):
        pass

@final
class B(A):  # E: Final class __main__.B has abstract attributes "foo"
    pass

[case testUndefinedBaseclassInNestedClass]
class C:
    class C1(XX): pass  # E: Name "XX" is not defined

[case testArgsKwargsInheritance]
from typing import Any

class A(object):
    def f(self, *args: Any, **kwargs: Any) -> int: ...

class B(A):
    def f(self, x: int) -> int: ...
[builtins fixtures/dict.pyi]

[case testClassScopeImports]
class Foo:
    from mod import plain_function  # E: Unsupported class scoped import
    from mod import plain_var

reveal_type(Foo.plain_function)  # N: Revealed type is "Any"
reveal_type(Foo().plain_function)  # N: Revealed type is "Any"

reveal_type(Foo.plain_var)  # N: Revealed type is "builtins.int"
reveal_type(Foo().plain_var)  # N: Revealed type is "builtins.int"

[file mod.py]
def plain_function(x: int, y: int) -> int: ...
plain_var: int

[case testClassScopeImportModule]
class Foo:
    import mod

reveal_type(Foo.mod)  # N: Revealed type is "builtins.object"
reveal_type(Foo.mod.foo)  # N: Revealed type is "builtins.int"
[file mod.py]
foo: int

[case testClassScopeImportAlias]
class Foo:
    from mod import function  # E: Unsupported class scoped import
    foo = function

    from mod import var1
    bar = var1

    from mod import var2
    baz = var2

    from mod import var3
    qux = var3

reveal_type(Foo.foo)  # N: Revealed type is "Any"
reveal_type(Foo.function)  # N: Revealed type is "Any"

reveal_type(Foo.bar)  # N: Revealed type is "builtins.int"
reveal_type(Foo.var1)  # N: Revealed type is "builtins.int"

reveal_type(Foo.baz)  # N: Revealed type is "mod.C"
reveal_type(Foo.var2)  # N: Revealed type is "mod.C"

reveal_type(Foo.qux)  # N: Revealed type is "builtins.int"
reveal_type(Foo.var3)  # N: Revealed type is "builtins.int"

[file mod.py]
def function(x: int, y: int) -> int: ...
var1: int

class C: ...
var2: C

A = int
var3: A


[case testClassScopeImportModuleStar]
class Foo:
    from mod import *  # E: Unsupported class scoped import

reveal_type(Foo.foo)  # N: Revealed type is "builtins.int"
reveal_type(Foo.bar)  # N: Revealed type is "Any"
reveal_type(Foo.baz)  # E: "type[Foo]" has no attribute "baz" \
                      # N: Revealed type is "Any"

[file mod.py]
foo: int
def bar(x: int) -> int: ...

[case testClassScopeImportFunctionNested]
class Foo:
    class Bar:
        from mod import baz  # E: Unsupported class scoped import

reveal_type(Foo.Bar.baz)  # N: Revealed type is "Any"
reveal_type(Foo.Bar().baz)  # N: Revealed type is "Any"

[file mod.py]
def baz(x: int) -> int: ...

[case testClassScopeImportUndefined]
class Foo:
    from unknown import foo  # E: Cannot find implementation or library stub for module named "unknown" \
                             # N: See https://mypy.readthedocs.io/en/stable/running_mypy.html#missing-imports

reveal_type(Foo.foo)  # N: Revealed type is "Any"
reveal_type(Foo().foo)  # N: Revealed type is "Any"

[case testClassScopeImportWithFollowImports]
# flags: --follow-imports=skip
class Foo:
    from mod import foo

reveal_type(Foo().foo)  # N: Revealed type is "Any"
[file mod.py]
def foo(x: int, y: int) -> int: ...

[case testClassScopeImportVarious]
class Foo:
    from mod1 import foo  # E: Unsupported class scoped import
    from mod2 import foo

    from mod1 import meth1  # E: Unsupported class scoped import
    def meth1(self, a: str) -> str: ...  # E: Name "meth1" already defined on line 5

    def meth2(self, a: str) -> str: ...
    from mod1 import meth2  # E: Incompatible import of "meth2" (imported name has type "Callable[[int], int]", local name has type "Callable[[Foo, str], str]")

class Bar:
    from mod1 import foo  # E: Unsupported class scoped import

import mod1
reveal_type(Foo.foo)  # N: Revealed type is "Any"
reveal_type(Bar.foo)  # N: Revealed type is "Any"
reveal_type(mod1.foo)  # N: Revealed type is "def (x: builtins.int, y: builtins.int) -> builtins.int"

[file mod1.py]
def foo(x: int, y: int) -> int: ...
def meth1(x: int) -> int: ...
def meth2(x: int) -> int: ...
[file mod2.py]
def foo(z: str) -> int: ...


[case testClassScopeImportWithError]
class Foo:
    from mod import meth1  # E: Unsupported class scoped import
    from mod import meth2  # E: Unsupported class scoped import
    from mod import T

reveal_type(Foo.T)  # N: Revealed type is "typing.TypeVar"

[file mod.pyi]
from typing import Any, TypeVar, overload

@overload
def meth1(self: Any, y: int) -> int: ...
@overload
def meth1(self: Any, y: str) -> str: ...

T = TypeVar("T")
def meth2(self: Any, y: T) -> T: ...
[builtins fixtures/tuple.pyi]
[typing fixtures/typing-full.pyi]

[case testNewAndInitNoReturn]
from typing import NoReturn

class A:
    def __new__(cls) -> NoReturn: ...

class B:
    def __init__(self) -> NoReturn: ...

class C:
    def __new__(cls) -> "C": ...
    def __init__(self) -> NoReturn: ...

class D:
    def __new__(cls) -> NoReturn: ...
    def __init__(self) -> NoReturn: ...

if object():
    reveal_type(A())  # N: Revealed type is "Never"
if object():
    reveal_type(B())  # N: Revealed type is "Never"
if object():
    reveal_type(C())  # N: Revealed type is "Never"
if object():
    reveal_type(D())  # N: Revealed type is "Never"

[case testOverloadedNewAndInitNoReturn]
from typing import NoReturn, overload

class A:
    @overload
    def __new__(cls) -> NoReturn: ...
    @overload
    def __new__(cls, a: int) -> "A": ...
    def __new__(cls, a: int = ...) -> "A": ...

class B:
    @overload
    def __init__(self) -> NoReturn: ...
    @overload
    def __init__(self, a: int) -> None: ...
    def __init__(self, a: int = ...) -> None: ...

class C:
    def __new__(cls, a: int = ...) -> "C": ...
    @overload
    def __init__(self) -> NoReturn: ...
    @overload
    def __init__(self, a: int) -> None: ...
    def __init__(self, a: int = ...) -> None: ...

class D:
    @overload
    def __new__(cls) -> NoReturn: ...
    @overload
    def __new__(cls, a: int) -> "D": ...
    def __new__(cls, a: int = ...) -> "D": ...
    @overload
    def __init__(self) -> NoReturn: ...
    @overload
    def __init__(self, a: int) -> None: ...
    def __init__(self, a: int = ...) -> None: ...

if object():
    reveal_type(A())  # N: Revealed type is "Never"
reveal_type(A(1))  # N: Revealed type is "__main__.A"

if object():
    reveal_type(B())  # N: Revealed type is "Never"
reveal_type(B(1))  # N: Revealed type is "__main__.B"

if object():
    reveal_type(C())  # N: Revealed type is "Never"
reveal_type(C(1))  # N: Revealed type is "__main__.C"

if object():
    reveal_type(D())  # N: Revealed type is "Never"
reveal_type(D(1))  # N: Revealed type is "__main__.D"

[case testClassScopeImportWithWrapperAndError]
class Foo:
    from mod import foo # E: Unsupported class scoped import

[file mod.py]
from typing import Any, Callable, TypeVar

FuncT = TypeVar("FuncT", bound=Callable[..., Any])
def identity_wrapper(func: FuncT) -> FuncT:
    return func

@identity_wrapper
def foo(self: Any) -> str:
    return ""

[case testParentClassWithTypeAliasAndSubclassWithMethod]
from typing import Any, Callable, TypeVar

class Parent:
    foo = Callable[..., int]
    class bar:
        pass
    import typing as baz
    foobar = TypeVar("foobar")

class Child(Parent):
    def foo(self, val: int) -> int:  # E: Signature of "foo" incompatible with supertype "Parent" \
                                     # N:      Superclass: \
                                     # N:          <typing special form> \
                                     # N:      Subclass: \
                                     # N:          def foo(self, val: int) -> int
        return val
    def bar(self, val: str) -> str:  # E: Signature of "bar" incompatible with supertype "Parent" \
                                     # N:      Superclass: \
                                     # N:          def __init__(self) -> bar \
                                     # N:      Subclass: \
                                     # N:          def bar(self, val: str) -> str
        return val
    def baz(self, val: float) -> float:  # E: Signature of "baz" incompatible with supertype "Parent" \
                                         # N:      Superclass: \
                                         # N:          Module \
                                         # N:      Subclass: \
                                         # N:          def baz(self, val: float) -> float
        return val
    def foobar(self) -> bool:  # E: Signature of "foobar" incompatible with supertype "Parent" \
                               # N:      Superclass: \
                               # N:          TypeVar \
                               # N:      Subclass: \
                               # N:          def foobar(self) -> bool
        return False

x: Parent.foo = lambda: 5
y: Parent.bar = Parent.bar()
z: Parent.baz.Any = 1
child = Child()
a: int = child.foo(1)
b: str = child.bar("abc")
c: float = child.baz(3.4)
d: bool = child.foobar()
[builtins fixtures/module.pyi]
[typing fixtures/typing-full.pyi]

[case testGenericTupleTypeCreation]
from typing import Generic, Tuple, TypeVar

T = TypeVar("T")
S = TypeVar("S")
class C(Tuple[T, S]):
    def __init__(self, x: T, y: S) -> None: ...
    def foo(self, arg: T) -> S: ...

cis: C[int, str]
reveal_type(cis)  # N: Revealed type is "tuple[builtins.int, builtins.str, fallback=__main__.C[builtins.int, builtins.str]]"
cii = C(0, 1)
reveal_type(cii)  # N: Revealed type is "tuple[builtins.int, builtins.int, fallback=__main__.C[builtins.int, builtins.int]]"
reveal_type(cis.foo)  # N: Revealed type is "def (arg: builtins.int) -> builtins.str"
[builtins fixtures/tuple.pyi]

[case testGenericTupleTypeSubclassing]
from typing import Generic, Tuple, TypeVar, List

T = TypeVar("T")
class C(Tuple[T, T]): ...
class D(C[List[T]]): ...

di: D[int]
reveal_type(di)  # N: Revealed type is "tuple[builtins.list[builtins.int], builtins.list[builtins.int], fallback=__main__.D[builtins.int]]"
[builtins fixtures/tuple.pyi]

[case testOverrideAttrWithSettableProperty]
class Foo:
    def __init__(self) -> None:
        self.x = 42

class Bar(Foo):
    @property
    def x(self) -> int: ...
    @x.setter
    def x(self, value: int) -> None: ...
[builtins fixtures/property.pyi]

[case testOverrideAttrWithSettablePropertyAnnotation]
class Foo:
    x: int

class Bar(Foo):
    @property
    def x(self) -> int: ...
    @x.setter
    def x(self, value: int) -> None: ...
[builtins fixtures/property.pyi]

[case testOverridePropertyDifferentSetterBoth]
class B: ...
class C(B): ...

class B1:
    @property
    def foo(self) -> str: ...
    @foo.setter
    def foo(self, x: C) -> None: ...
class C1(B1):
    @property
    def foo(self) -> str: ...
    @foo.setter
    def foo(self, x: B) -> None: ...

class B2:
    @property
    def foo(self) -> str: ...
    @foo.setter
    def foo(self, x: B) -> None: ...
class C2(B2):
    @property
    def foo(self) -> str: ...
    @foo.setter  # E: Incompatible override of a setter type \
                 # N:  (base class "B2" defined the type as "B", \
                 # N:  override has type "C") \
                 # N:  Setter types should behave contravariantly
    def foo(self, x: C) -> None: ...

class B3:
    @property
    def foo(self) -> C: ...
    @foo.setter
    def foo(self, x: C) -> None: ...
class C3(B3):
    @property
    def foo(self) -> C: ...
    @foo.setter
    def foo(self, x: B) -> None: ...

class B4:
    @property
    def foo(self) -> C: ...
    @foo.setter
    def foo(self, x: B) -> None: ...
class C4(B4):
    @property
    def foo(self) -> C: ...
    @foo.setter  # E: Incompatible override of a setter type \
                 # N:  (base class "B4" defined the type as "B", \
                 # N:  override has type "C") \
                 # N:  Setter types should behave contravariantly
    def foo(self, x: C) -> None: ...

class B5:
    @property
    def foo(self) -> str: ...
    @foo.setter
    def foo(self, x: B) -> None: ...
class C5(B5):
    @property  # E: Signature of "foo" incompatible with supertype "B5" \
               # N:      Superclass: \
               # N:          str \
               # N:      Subclass: \
               # N:          C
    def foo(self) -> C: ...
    @foo.setter  # E: Incompatible override of a setter type \
                 # N:  (base class "B5" defined the type as "B", \
                 # N:  override has type "str")
    def foo(self, x: str) -> None: ...

class B6:
    @property
    def foo(self) -> B: ...
    @foo.setter
    def foo(self, x: B) -> None: ...
class C6(B6):
    @property
    def foo(self) -> C: ...
    @foo.setter
    def foo(self, x: B) -> None: ...
[builtins fixtures/property.pyi]

[case testOverridePropertyDifferentSetterVarSuper]
class B: ...
class C(B): ...

class B1:
    foo: B
class C1(B1):
    @property
    def foo(self) -> B: ...
    @foo.setter  # E: Incompatible override of a setter type \
                 # N:  (base class "B1" defined the type as "B", \
                 # N:  override has type "C") \
                 # N:  Setter types should behave contravariantly
    def foo(self, x: C) -> None: ...

class B2:
    foo: C
class C2(B2):
    @property
    def foo(self) -> C: ...
    @foo.setter
    def foo(self, x: B) -> None: ...

class B3:
    foo: B
class C3(B3):
    @property
    def foo(self) -> C: ...
    @foo.setter
    def foo(self, x: B) -> None: ...
[builtins fixtures/property.pyi]

[case testOverridePropertyDifferentSetterVarSub]
class B: ...
class C(B): ...

class B1:
    @property
    def foo(self) -> B: ...
    @foo.setter
    def foo(self, x: C) -> None: ...
class C1(B1):
    foo: C

class B2:
    @property
    def foo(self) -> B: ...
    @foo.setter
    def foo(self, x: C) -> None: ...
class C2(B2):
    foo: B

class B3:
    @property
    def foo(self) -> C: ...
    @foo.setter
    def foo(self, x: B) -> None: ...
class C3(B3):
    foo: C  # E: Incompatible override of a setter type \
            # N:  (base class "B3" defined the type as "B", \
            # N:  override has type "C") \
            # N:  Setter types should behave contravariantly
[builtins fixtures/property.pyi]

[case testOverridePropertyInvalidSetter]
class B1:
    @property
    def foo(self) -> int: ...
    @foo.setter
    def foo(self, x: str) -> None: ...
class C1(B1):
    @property
    def foo(self) -> int: ...
    @foo.setter
    def foo(self) -> None: ...  # E: Invalid property setter signature

class B2:
    @property
    def foo(self) -> int: ...
    @foo.setter
    def foo(self) -> None: ...  # E: Invalid property setter signature
class C2(B2):
    @property
    def foo(self) -> int: ...
    @foo.setter
    def foo(self, x: str) -> None: ...

class B3:
    @property
    def foo(self) -> int: ...
    @foo.setter
    def foo(self) -> None: ...  # E: Invalid property setter signature
class C3(B3):
    foo: int
[builtins fixtures/property.pyi]

[case testOverridePropertyGeneric]
from typing import TypeVar, Generic

T = TypeVar("T")

class B1(Generic[T]):
    @property
    def foo(self) -> int: ...
    @foo.setter
    def foo(self, x: T) -> None: ...
class C1(B1[str]):
    @property
    def foo(self) -> int: ...
    @foo.setter  # E: Incompatible override of a setter type \
                 # N:  (base class "B1" defined the type as "str", \
                 # N:  override has type "int")
    def foo(self, x: int) -> None: ...

class B2:
    @property
    def foo(self) -> int: ...
    @foo.setter
    def foo(self: T, x: T) -> None: ...
class C2(B2):
    @property
    def foo(self) -> int: ...
    @foo.setter  # E: Incompatible override of a setter type \
                 # N:  (base class "B2" defined the type as "C2", \
                 # N:  override has type "int")
    def foo(self, x: int) -> None: ...
[builtins fixtures/property.pyi]

[case testOverrideMethodProperty]
class B:
    def foo(self) -> int:
        ...
class C(B):
    @property
    def foo(self) -> int:  # E: Signature of "foo" incompatible with supertype "B" \
                           # N:      Superclass: \
                           # N:          def foo(self) -> int \
                           # N:      Subclass: \
                           # N:          int
        ...
[builtins fixtures/property.pyi]

[case testOverridePropertyMethod]
class B:
    @property
    def foo(self) -> int:
        ...
class C(B):
    def foo(self) -> int:  # E: Signature of "foo" incompatible with supertype "B" \
                           # N:      Superclass: \
                           # N:          int \
                           # N:      Subclass: \
                           # N:          def foo(self) -> int
        ...
[builtins fixtures/property.pyi]

[case testAllowArgumentAsBaseClass]
from typing import Any, Type

def e(b) -> None:
    class D(b): ...

def f(b: Any) -> None:
    class D(b): ...

def g(b: Type[Any]) -> None:
    class D(b): ...

def h(b: type) -> None:
    class D(b): ...

[case testNoCrashOnSelfWithForwardRefGenericClass]
from typing import Generic, Sequence, TypeVar, Self

_T = TypeVar('_T', bound="Foo")

class Foo:
    foo: int

class Element(Generic[_T]):
    elements: Sequence[Self]

class Bar(Foo): ...
e: Element[Bar]
reveal_type(e.elements)  # N: Revealed type is "typing.Sequence[__main__.Element[__main__.Bar]]"

[case testIterableUnpackingWithGetAttr]
from typing import Union, Tuple

class C:
    def __getattr__(self, name):
        pass

class D:
    def f(self) -> C:
        return C()

    def g(self) -> None:
        # iter(x) looks up `__iter__` on the type of x rather than x itself,
        # so this is correct behaviour.
        # Instances of C should not be treated as being iterable,
        # despite having a __getattr__ method
        # that could allow for arbitrary attributes to be accessed on instances,
        # since `type(C()).__iter__` still raises AttributeError at runtime,
        # and that's what matters.
        a, b = self.f()  # E: "C" has no attribute "__iter__" (not iterable)
[builtins fixtures/tuple.pyi]

[case testUsingNumbersType]
from numbers import Number, Complex, Real, Rational, Integral

def f1(x: Number) -> None: pass
f1(1)  # E: Argument 1 to "f1" has incompatible type "int"; expected "Number" \
       # N: Types from "numbers" aren't supported for static type checking \
       # N: See https://peps.python.org/pep-0484/#the-numeric-tower \
       # N: Consider using a protocol instead, such as typing.SupportsFloat

def f2(x: Complex) -> None: pass
f2(1)  # E: Argument 1 to "f2" has incompatible type "int"; expected "Complex" \
       # N: Types from "numbers" aren't supported for static type checking \
       # N: See https://peps.python.org/pep-0484/#the-numeric-tower \
       # N: Consider using a protocol instead, such as typing.SupportsFloat

def f3(x: Real) -> None: pass
f3(1)  # E: Argument 1 to "f3" has incompatible type "int"; expected "Real" \
       # N: Types from "numbers" aren't supported for static type checking \
       # N: See https://peps.python.org/pep-0484/#the-numeric-tower \
       # N: Consider using a protocol instead, such as typing.SupportsFloat

def f4(x: Rational) -> None: pass
f4(1)  # E: Argument 1 to "f4" has incompatible type "int"; expected "Rational" \
       # N: Types from "numbers" aren't supported for static type checking \
       # N: See https://peps.python.org/pep-0484/#the-numeric-tower \
       # N: Consider using a protocol instead, such as typing.SupportsFloat

def f5(x: Integral) -> None: pass
f5(1)  # E: Argument 1 to "f5" has incompatible type "int"; expected "Integral" \
       # N: Types from "numbers" aren't supported for static type checking \
       # N: See https://peps.python.org/pep-0484/#the-numeric-tower \
       # N: Consider using a protocol instead, such as typing.SupportsFloat

[case testImplicitClassScopedNames]
class C:
    reveal_type(__module__)  # N: Revealed type is "builtins.str"
    reveal_type(__qualname__)  # N: Revealed type is "builtins.str"
    def f(self) -> None:
        __module__  # E: Name "__module__" is not defined
        __qualname__  # E: Name "__qualname__" is not defined

[case testPropertySetterType]
class A:
    @property
    def f(self) -> int:
        return 1
    @f.setter
    def f(self, x: str) -> None:
        pass
a = A()
a.f = ''  # OK
reveal_type(a.f)  # N: Revealed type is "builtins.int"
a.f = 1  # E: Incompatible types in assignment (expression has type "int", variable has type "str")
reveal_type(a.f)  # N: Revealed type is "builtins.int"
[builtins fixtures/property.pyi]

[case testPropertySetterTypeGeneric]
from typing import TypeVar, Generic, List

T = TypeVar("T")

class B(Generic[T]):
    @property
    def foo(self) -> int: ...
    @foo.setter
    def foo(self, x: T) -> None: ...

class C(B[List[T]]): ...

a = C[str]()
a.foo = ["foo", "bar"]
reveal_type(a.foo)  # N: Revealed type is "builtins.int"
a.foo = 1  # E: Incompatible types in assignment (expression has type "int", variable has type "list[str]")
reveal_type(a.foo)  # N: Revealed type is "builtins.int"
[builtins fixtures/property.pyi]

[case testPropertyDeleterNoSetterOK]
class C:
    @property
    def x(self) -> int:
        return 0
    @x.deleter
    def x(self) -> None:
        pass
[builtins fixtures/property.pyi]

[case testPropertySetterSuperclassDeferred]
from typing import Callable, TypeVar

class B:
    def __init__(self) -> None:
        self.foo = f()

class C(B):
    @property
    def foo(self) -> str: ...
    @foo.setter  # E: Incompatible override of a setter type \
                 # N:  (base class "B" defined the type as "str", \
                 # N:  override has type "int")
    def foo(self, x: int) -> None: ...

T = TypeVar("T")
def deco(fn: Callable[[], list[T]]) -> Callable[[], T]: ...

@deco
def f() -> list[str]: ...
[builtins fixtures/property.pyi]

[case testPropertySetterSuperclassDeferred2]
import a
[file a.py]
import b
class D(b.C):
    @property
    def foo(self) -> str: ...
    @foo.setter  # E: Incompatible override of a setter type \
                 # N:  (base class "C" defined the type as "str", \
                 # N:  override has type "int")
    def foo(self, x: int) -> None: ...
[file b.py]
from a import D
class C:
    @property
    def foo(self) -> str: ...
    @foo.setter
    def foo(self, x: str) -> None: ...
[builtins fixtures/property.pyi]

[case testPropertySetterDecorated]
from typing import Callable, TypeVar, Generic

class B:
    def __init__(self) -> None:
        self.foo: str
        self.bar: int

class C(B):
    @property
    def foo(self) -> str: ...
    @foo.setter  # E: Incompatible override of a setter type \
                 # N:  (base class "B" defined the type as "str", \
                 # N:  override has type "int")
    @deco
    def foo(self, x: int, y: int) -> None: ...

    @property
    def bar(self) -> int: ...
    @bar.setter
    @deco
    def bar(self, x: int, y: int) -> None: ...

    @property
    def baz(self) -> int: ...
    @baz.setter
    @deco_untyped
    def baz(self, x: int) -> None: ...

    @property
    def tricky(self) -> int: ...
    @tricky.setter
    @deco_instance
    def tricky(self, x: int) -> None: ...

c: C
c.baz = "yes"  # OK, because of untyped decorator
c.tricky = 1  # E: Incompatible types in assignment (expression has type "int", variable has type "list[int]")

T = TypeVar("T")
def deco(fn: Callable[[T, int, int], None]) -> Callable[[T, int], None]: ...
def deco_untyped(fn): ...

class Wrapper(Generic[T]):
    def __call__(self, s: T, x: list[int]) -> None: ...
def deco_instance(fn: Callable[[T, int], None]) -> Wrapper[T]: ...
[builtins fixtures/property.pyi]

[case testPropertyDeleterBodyChecked]
class C:
    @property
    def foo(self) -> int: ...
    @foo.deleter
    def foo(self) -> None:
        1()  # E: "int" not callable

    @property
    def bar(self) -> int: ...
    @bar.setter
    def bar(self, x: str) -> None: ...
    @bar.deleter
    def bar(self) -> None:
        1()  # E: "int" not callable
[builtins fixtures/property.pyi]

[case testSettablePropertyGetterDecorated]
from typing import Callable, TypeVar, Generic

class C:
    @property
    @deco
    def foo(self, ok: int) -> str: ...
    @foo.setter
    def foo(self, x: str) -> None: ...

    @property
    @deco_instance
    def bar(self, ok: int) -> int: ...
    @bar.setter
    def bar(self, x: int) -> None: ...

    @property
    @deco_untyped
    def baz(self) -> int: ...
    @baz.setter
    def baz(self, x: int) -> None: ...

c: C
reveal_type(c.foo)  # N: Revealed type is "builtins.list[builtins.str]"
reveal_type(c.bar)  # N: Revealed type is "builtins.list[builtins.int]"
reveal_type(c.baz)  # N: Revealed type is "Any"

T = TypeVar("T")
R = TypeVar("R")
def deco(fn: Callable[[T, int], R]) -> Callable[[T], list[R]]: ...
def deco_untyped(fn): ...

class Wrapper(Generic[T, R]):
    def __call__(self, s: T) -> list[R]: ...
def deco_instance(fn: Callable[[T, int], R]) -> Wrapper[T, R]: ...
[builtins fixtures/property.pyi]

[case testOverridePropertyWithDescriptor]
from typing import Any

class StrProperty:
    def __get__(self, instance: Any, owner: Any) -> str: ...

class Base:
    @property
    def id(self) -> str: ...

class BadBase:
    @property
    def id(self) -> int: ...

class Derived(Base):
    id = StrProperty()

class BadDerived(BadBase):
    id = StrProperty()  # E: Incompatible types in assignment (expression has type "str", base class "BadBase" defined the type as "int")
[builtins fixtures/property.pyi]

[case testLambdaInOverrideInference]
class B:
    def f(self, x: int) -> int: ...
class C(B):
    f = lambda s, x: x

reveal_type(C().f)  # N: Revealed type is "def (x: builtins.int) -> builtins.int"

[case testGenericDecoratorInOverrideInference]
from typing import Any, Callable, TypeVar
from typing_extensions import ParamSpec, Concatenate

P = ParamSpec("P")
T = TypeVar("T")
def wrap(f: Callable[Concatenate[Any, P], T]) -> Callable[Concatenate[Any, P], T]: ...

class Base:
    def g(self, a: int) -> int:
        return a + 1

class Derived(Base):
    def _g(self, a: int) -> int:
        return a + 2
    g = wrap(_g)

reveal_type(Derived().g)  # N: Revealed type is "def (a: builtins.int) -> builtins.int"
[builtins fixtures/paramspec.pyi]

[case testClassVarOverrideWithSubclass]
class A: ...
class B(A): ...
class AA:
    cls = A
class BB(AA):
    cls = B

[case testSelfReferenceWithinMethodFunction]
class B:
    x: str
class C(B):
    def meth(self) -> None:
        def cb() -> None:
            self.x: int = 1  # E: Incompatible types in assignment (expression has type "int", base class "B" defined the type as "str")

[case testOverloadedDescriptorSelected]
from typing import Generic, TypeVar, Any, overload

T_co = TypeVar("T_co", covariant=True)
class Field(Generic[T_co]):
    @overload
    def __get__(self: Field[bool], instance: None, owner: Any) -> BoolField: ...
    @overload
    def __get__(self: Field[int], instance: None, owner: Any) -> NumField: ...
    @overload
    def __get__(self: Field[Any], instance: None, owner: Any) -> AnyField[T_co]: ...
    @overload
    def __get__(self, instance: Any, owner: Any) -> T_co: ...

    def __get__(self, instance: Any, owner: Any) -> Any:
        pass

class BoolField(Field[bool]): ...
class NumField(Field[int]): ...
class AnyField(Field[T_co]): ...
class Custom: ...

class Fields:
    bool_f: Field[bool]
    int_f: Field[int]
    custom_f: Field[Custom]

reveal_type(Fields.bool_f)  # N: Revealed type is "__main__.BoolField"
reveal_type(Fields.int_f)  # N: Revealed type is "__main__.NumField"
reveal_type(Fields.custom_f)  # N: Revealed type is "__main__.AnyField[__main__.Custom]"

[case testRecursivePropertyWithInvalidSetterNoCrash]
class NoopPowerResource:
    _hardware_type: int

    @property
    def hardware_type(self) -> int:
        return self._hardware_type

    @hardware_type.setter
    def hardware_type(self) -> None:  # E: Invalid property setter signature
        self.hardware_type = None  # Note: intentionally recursive
[builtins fixtures/property.pyi]

[case testOverrideErrorReportingNoDuplicates]
from typing import Callable, TypeVar

def nested() -> None:
    class B:
        def meth(self, x: str) -> int: ...
    class C(B):
        def meth(self) -> str:  # E: Signature of "meth" incompatible with supertype "B" \
                # N:      Superclass: \
                # N:          def meth(self, x: str) -> int \
                # N:      Subclass: \
                # N:          def meth(self) -> str
            pass
    x = defer()

T = TypeVar("T")
def deco(fn: Callable[[], T]) -> Callable[[], list[T]]: ...

@deco
def defer() -> int: ...
[builtins fixtures/list.pyi]

[case testPropertyAllowsDeleterBeforeSetter]
class C:
    @property
    def foo(self) -> str: ...
    @foo.deleter
    def foo(self) -> None: ...
    @foo.setter
    def foo(self, val: int) -> None: ...

    @property
    def bar(self) -> int: ...
    @bar.deleter
    def bar(self) -> None: ...
    @bar.setter
    def bar(self, value: int, val: int) -> None: ...  # E: Invalid property setter signature

C().foo = "no"  # E: Incompatible types in assignment (expression has type "str", variable has type "int")
C().bar = "fine"
[builtins fixtures/property.pyi]

[case testCorrectConstructorTypeWithAnyFallback]
from typing import Generic, TypeVar

class B(Unknown):  # type: ignore
    def __init__(self) -> None: ...
class C(B): ...

reveal_type(C)  # N: Revealed type is "def () -> __main__.C"

T = TypeVar("T")
class BG(Generic[T], Unknown):  # type: ignore
    def __init__(self) -> None: ...
class CGI(BG[int]): ...
class CGT(BG[T]): ...

reveal_type(CGI)  # N: Revealed type is "def () -> __main__.CGI"
reveal_type(CGT)  # N: Revealed type is "def [T] () -> __main__.CGT[T`1]"

[case testSettablePropertyAlias]
from typing import Any, TypeVar

class A:
    @property
    def prop(self: Any) -> str: ...
    @prop.setter
    def prop(self, val: str) -> None: ...

T = TypeVar("T")
class AT:
    @property
    def prop(self: T) -> T: ...
    @prop.setter
    def prop(self: T, val: list[T]) -> None: ...

class B:
    prop: str
    prop_t: str

class C(B):
    prop = A.prop
    prop_t = AT.prop  # E: Incompatible types in assignment (expression has type "C", base class "B" defined the type as "str")

reveal_type(C().prop)  # N: Revealed type is "builtins.str"
C().prop = "no"  # E: Invalid self argument "C" to attribute function "prop" with type "Callable[[A, str], None]"
reveal_type(C().prop_t)  # N: Revealed type is "__main__.C"
C().prop_t = 1  # E: Incompatible types in assignment (expression has type "int", variable has type "list[C]")
[builtins fixtures/property.pyi]

[case testClassEqDecoratedAbstractNote]
from abc import abstractmethod

class C:
    @abstractmethod
    def __eq__(self, other: C) -> bool: ...
[builtins fixtures/plugin_attrs.pyi]
[out]
main:5: error: Argument 1 of "__eq__" is incompatible with supertype "builtins.object"; supertype defines the argument type as "object"
main:5: note: This violates the Liskov substitution principle
main:5: note: See https://mypy.readthedocs.io/en/stable/common_issues.html#incompatible-overrides
main:5: note: It is recommended for "__eq__" to work with arbitrary objects, for example:
main:5: note:     def __eq__(self, other: object) -> bool:
main:5: note:         if not isinstance(other, C):
main:5: note:             return NotImplemented
main:5: note:         return <logic to compare two C instances>

[case testLambdaInAttributeCallValue]
# https://github.com/python/mypy/issues/19632
import foo

def nop(fn: object) -> foo.Bar:
    return foo.Bar()

class Bar:
    foo: foo.Bar = nop(
        lambda: 0
    )
[file foo.py]
class Bar:
    ...

[case testConstructorWithoutStrictOptionalNoCache]
import mod
a = mod.NT(x=None)  # OK

[file typ.py]
from typing import NamedTuple, Optional
NT = NamedTuple("NT", [("x", Optional[str])])

[file mod.py]
# mypy: no-strict-optional
from typ import NT

def f() -> NT:
    return NT(x='')
[builtins fixtures/tuple.pyi]