[case testMaybeUninitVar] class C: def __init__(self, x: int) -> None: self.x = x def f(b: bool) -> None: u = C(1) while b: v = C(2) if v is not u: break print(v.x) [file driver.py] from native import f f(True) [out] 2 [case testUninitBoom] def f(a: bool, b: bool) -> None: if a: x = 'lol' if b: print(x) def g() -> None: try: [0][1] y = 1 except Exception: pass print(y) [file driver.py] from native import f, g from testutil import assertRaises f(True, True) f(False, False) with assertRaises(NameError): f(False, True) with assertRaises(NameError): g() [out] lol [case testBuiltins] y = 10 def f(x: int) -> None: print(5) d = globals() assert d['y'] == 10 d['y'] = 20 assert y == 20 [file driver.py] from native import f f(5) [out] 5 [case testOptional] from typing import Optional class A: pass def f(x: Optional[A]) -> Optional[A]: return x def g(x: Optional[A]) -> int: if x is None: return 1 if x is not None: return 2 return 3 def h(x: Optional[int], y: Optional[bool]) -> None: pass [file driver.py] from native import f, g, A a = A() assert f(None) is None assert f(a) is a assert g(None) == 1 assert g(a) == 2 [case testInferredOptionalAssignment] from typing import Any, Generator def f(b: bool) -> Any: if b: x = None else: x = 1 if b: y = 1 else: y = None m = 1 if b else None n = None if b else 1 return ((x, y), (m, n)) def gen(b: bool) -> Generator[Any, None, None]: if b: y = 1 else: y = None yield y assert f(False) == ((1, None), (None, 1)) assert f(True) == ((None, 1), (1, None)) assert next(gen(False)) is None assert next(gen(True)) == 1 [case testWith] from typing import Any class Thing: def __init__(self, x: str) -> None: self.x = x def __enter__(self) -> str: print('enter!', self.x) if self.x == 'crash': raise Exception('ohno') return self.x def __exit__(self, x: Any, y: Any, z: Any) -> None: print('exit!', self.x, y) def foo(i: int) -> int: with Thing('a') as x: print("yooo?", x) if i == 0: return 10 elif i == 1: raise Exception('exception!') return -1 def bar() -> None: with Thing('a') as x, Thing('b') as y: print("yooo?", x, y) def baz() -> None: with Thing('a') as x, Thing('crash') as y: print("yooo?", x, y) [file driver.py] from native import foo, bar, baz assert foo(0) == 10 print('== foo ==') try: foo(1) except Exception: print('caught') assert foo(2) == -1 print('== bar ==') bar() print('== baz ==') try: baz() except Exception: print('caught') [out] enter! a yooo? a exit! a None == foo == enter! a yooo? a exit! a exception! caught enter! a yooo? a exit! a None == bar == enter! a enter! b yooo? a b exit! b None exit! a None == baz == enter! a enter! crash exit! a ohno caught [case testDisplays] from typing import List, Set, Tuple, Sequence, Dict, Any, Mapping def listDisplay(x: List[int], y: List[int]) -> List[int]: return [1, 2, *x, *y, 3] def setDisplay(x: Set[int], y: Set[int]) -> Set[int]: return {1, 2, *x, *y, 3} def tupleDisplay(x: Sequence[str], y: Sequence[str]) -> Tuple[str, ...]: return ('1', '2', *x, *y, '3') def dictDisplay(x: str, y1: Dict[str, int], y2: Dict[str, int]) -> Dict[str, int]: return {x: 2, **y1, 'z': 3, **y2} def dictDisplayUnpackMapping(obj: Mapping[str, str]) -> Dict[str, str]: return {**obj, "env": "value"} [file driver.py] import os from native import listDisplay, setDisplay, tupleDisplay, dictDisplay, dictDisplayUnpackMapping assert listDisplay([4], [5, 6]) == [1, 2, 4, 5, 6, 3] assert setDisplay({4}, {5}) == {1, 2, 3, 4, 5} assert tupleDisplay(['4', '5'], ['6']) == ('1', '2', '4', '5', '6', '3') assert dictDisplay('x', {'y1': 1}, {'y2': 2, 'z': 5}) == {'x': 2, 'y1': 1, 'y2': 2, 'z': 5} assert dictDisplayUnpackMapping(os.environ) == {**os.environ, "env": "value"} [case testArbitraryLvalues] from typing import List, Dict, Any class O(object): def __init__(self) -> None: self.x = 1 def increment_attr(a: Any) -> Any: a.x += 1 return a def increment_attr_o(o: O) -> O: o.x += 1 return o def increment_all_indices(l: List[int]) -> List[int]: for i in range(len(l)): l[i] += 1 return l def increment_all_keys(d: Dict[str, int]) -> Dict[str, int]: for k in d: d[k] += 1 return d [file driver.py] from native import O, increment_attr, increment_attr_o, increment_all_indices, increment_all_keys class P(object): def __init__(self) -> None: self.x = 0 assert increment_attr(P()).x == 1 assert increment_attr_o(O()).x == 2 assert increment_all_indices([1, 2, 3]) == [2, 3, 4] assert increment_all_keys({'a':1, 'b':2, 'c':3}) == {'a':2, 'b':3, 'c':4} [case testControlFlowExprs] from typing import Tuple def foo() -> object: print('foo') return 'foo' def bar() -> object: print('bar') return 'bar' def t(x: int) -> int: print(x) return x def f(b: bool) -> Tuple[object, object, object]: x = foo() if b else bar() y = b or foo() z = b and foo() return (x, y, z) def g() -> Tuple[object, object]: return (foo() or bar(), foo() and bar()) def nand(p: bool, q: bool) -> bool: if not (p and q): return True return False def chained(x: int, y: int, z: int) -> bool: return t(x) < t(y) > t(z) def chained2(x: int, y: int, z: int, w: int) -> bool: return t(x) < t(y) < t(z) < t(w) [file driver.py] from native import f, g, nand, chained, chained2 assert f(True) == ('foo', True, 'foo') print() assert f(False) == ('bar', 'foo', False) print() assert g() == ('foo', 'bar') assert nand(True, True) == False assert nand(True, False) == True assert nand(False, True) == True assert nand(False, False) == True print() assert chained(10, 20, 15) == True print() assert chained(10, 20, 30) == False print() assert chained(21, 20, 30) == False print() assert chained2(1, 2, 3, 4) == True print() assert chained2(1, 0, 3, 4) == False print() assert chained2(1, 2, 0, 4) == False [out] foo foo bar foo foo foo bar 10 20 15 10 20 30 21 20 1 2 3 4 1 0 1 2 0 [case testMultipleAssignment] from typing import Tuple, List, Any def from_tuple(t: Tuple[int, str]) -> List[Any]: x, y = t return [y, x] def from_tuple_sequence(t: Tuple[int, ...]) -> List[int]: x, y, z = t return [z, y, x] def from_list(l: List[int]) -> List[int]: x, y = l return [y, x] def from_list_complex(l: List[int]) -> List[int]: ll = l[:] ll[1], ll[0] = l return ll def from_any(o: Any) -> List[Any]: x, y = o return [y, x] def multiple_assignments(t: Tuple[int, str]) -> List[Any]: a, b = c, d = t e, f = g, h = 1, 2 return [a, b, c, d, e, f, g, h] [file driver.py] from native import ( from_tuple, from_tuple_sequence, from_list, from_list_complex, from_any, multiple_assignments ) assert from_tuple((1, 'x')) == ['x', 1] assert from_tuple_sequence((1, 5, 4)) == [4, 5, 1] try: from_tuple_sequence((1, 5)) except ValueError as e: assert 'not enough values to unpack (expected 3, got 2)' in str(e) else: assert False assert from_list([3, 4]) == [4, 3] try: from_list([5, 4, 3]) except ValueError as e: assert 'too many values to unpack (expected 2)' in str(e) else: assert False assert from_list_complex([7, 6]) == [6, 7] try: from_list_complex([5, 4, 3]) except ValueError as e: assert 'too many values to unpack (expected 2)' in str(e) else: assert False assert from_any('xy') == ['y', 'x'] assert multiple_assignments((4, 'x')) == [4, 'x', 4, 'x', 1, 2, 1, 2] [case testUnpack] from typing import List a, *b = [1, 2, 3, 4, 5] *c, d = [1, 2, 3, 4, 5] e, *f = [1,2] j, *k, l = [1, 2, 3] m, *n, o = [1, 2, 3, 4, 5, 6] p, q, r, *s, t = [1,2,3,4,5,6,7,8,9,10] tup = (1,2,3) y, *z = tup def unpack1(l : List[int]) -> None: *v1, v2, v3 = l def unpack2(l : List[int]) -> None: v1, *v2, v3 = l def unpack3(l : List[int]) -> None: v1, v2, *v3 = l [file driver.py] from native import a, b, c, d, e, f, j, k, l, m, n, o, p, q, r, s, t, y, z from native import unpack1, unpack2, unpack3 from testutil import assertRaises assert a == 1 assert b == [2,3,4,5] assert c == [1,2,3,4] assert d == 5 assert e == 1 assert f == [2] assert j == 1 assert k == [2] assert l == 3 assert m == 1 assert n == [2,3,4,5] assert o == 6 assert p == 1 assert q == 2 assert r == 3 assert s == [4,5,6,7,8,9] assert t == 10 assert y == 1 assert z == [2,3] with assertRaises(ValueError, "not enough values to unpack"): unpack1([1]) with assertRaises(ValueError, "not enough values to unpack"): unpack2([1]) with assertRaises(ValueError, "not enough values to unpack"): unpack3([1]) [out] [case testModuleTopLevel] x = 1 print(x) def f() -> None: print(x + 1) def g() -> None: global x x = 77 [file driver.py] import native native.f() native.x = 5 native.f() native.g() print(native.x) [out] 1 2 6 77 [case testComprehensions] from typing import List # A list comprehension l = [str(x) + " " + str(y) + " " + str(x*y) for x in range(10) if x != 6 if x != 5 for y in range(x) if y*x != 8] # Test short-circuiting as well def pred(x: int) -> bool: if x > 6: raise Exception() return x > 3 # If we fail to short-circuit, pred(x) will be called with x=7 # eventually and will raise an exception. l2 = [x for x in range(10) if x <= 6 if pred(x)] src = ['x'] def f() -> List[str]: global src res = src src = [] return res l3 = [s for s in f()] l4 = [s for s in f()] # A dictionary comprehension d = {k: k*k for k in range(10) if k != 5 if k != 6} # A set comprehension s = {str(x) + " " + str(y) + " " + str(x*y) for x in range(10) if x != 6 if x != 5 for y in range(x) if y*x != 8} [file driver.py] from native import l, l2, l3, l4, d, s for a in l: print(a) print(tuple(l2)) assert l3 == ['x'] assert l4 == [] for k in sorted(d): print(k, d[k]) for a in sorted(s): print(a) [out] 1 0 0 2 0 0 2 1 2 3 0 0 3 1 3 3 2 6 4 0 0 4 1 4 4 3 12 7 0 0 7 1 7 7 2 14 7 3 21 7 4 28 7 5 35 7 6 42 8 0 0 8 2 16 8 3 24 8 4 32 8 5 40 8 6 48 8 7 56 9 0 0 9 1 9 9 2 18 9 3 27 9 4 36 9 5 45 9 6 54 9 7 63 9 8 72 (4, 5, 6) 0 0 1 1 2 4 3 9 4 16 7 49 8 64 9 81 1 0 0 2 0 0 2 1 2 3 0 0 3 1 3 3 2 6 4 0 0 4 1 4 4 3 12 7 0 0 7 1 7 7 2 14 7 3 21 7 4 28 7 5 35 7 6 42 8 0 0 8 2 16 8 3 24 8 4 32 8 5 40 8 6 48 8 7 56 9 0 0 9 1 9 9 2 18 9 3 27 9 4 36 9 5 45 9 6 54 9 7 63 9 8 72 [case testDummyTypes] from typing import Tuple, List, Dict, NamedTuple from typing_extensions import Literal, TypedDict, NewType class A: pass T = List[A] U = List[Tuple[int, str]] Z = List[List[int]] D = Dict[int, List[int]] N = NewType('N', int) G = Tuple[int, str] def foo(x: N) -> int: return x foo(N(10)) z = N(10) Lol = NamedTuple('Lol', (('a', int), ('b', T))) x = Lol(1, []) def take_lol(x: Lol) -> int: return x.a TD = TypedDict('TD', {'a': int}) def take_typed_dict(x: TD) -> int: return x['a'] def take_literal(x: Literal[1, 2, 3]) -> None: print(x) [file driver.py] import sys from native import * if sys.version_info[:3] > (3, 5, 2): assert "%s %s %s %s" % (T, U, Z, D) == "typing.List[native.A] typing.List[typing.Tuple[int, str]] typing.List[typing.List[int]] typing.Dict[int, typing.List[int]]" print(x) print(z) print(take_lol(x)) print(take_typed_dict({'a': 20})) try: take_typed_dict(None) except Exception as e: print(type(e).__name__) take_literal(1) # We check that the type is the real underlying type try: take_literal(None) except Exception as e: print(type(e).__name__) # ... but not that it is a valid literal value take_literal(10) [out] Lol(a=1, b=[]) 10 1 20 TypeError 1 TypeError 10 [case testClassBasedTypedDict] from typing_extensions import TypedDict class TD(TypedDict): a: int class TD2(TD): b: int class TD3(TypedDict, total=False): c: int class TD4(TD3, TD2, total=False): d: int def test_typed_dict() -> None: d = TD(a=5) assert d['a'] == 5 assert type(d) == dict # TODO: This doesn't work yet # assert TD.__annotations__ == {'a': int} def test_inherited_typed_dict() -> None: d = TD2(a=5, b=3) assert d['a'] == 5 assert d['b'] == 3 assert type(d) == dict def test_non_total_typed_dict() -> None: d3 = TD3(c=3) d4 = TD4(a=1, b=2, c=3, d=4) assert d3['c'] == 3 assert d4['d'] == 4 [case testClassBasedNamedTuple] from typing import NamedTuple import sys # Class-based NamedTuple requires Python 3.6+ version = sys.version_info[:2] if version[0] == 3 and version[1] < 6: exit() class NT(NamedTuple): a: int def test_named_tuple() -> None: t = NT(a=1) assert t.a == 1 assert type(t) is NT assert isinstance(t, tuple) assert not isinstance(tuple([1]), NT) [case testUnion] from typing import Union class A: def __init__(self, x: int) -> None: self.x = x def f(self, y: int) -> int: return y + self.x class B: def __init__(self, x: object) -> None: self.x = x def f(self, y: object) -> object: return y def f(x: Union[A, str]) -> object: if isinstance(x, A): return x.x else: return x + 'x' def g(x: int) -> Union[A, int]: if x == 0: return A(1) else: return x + 1 def get(x: Union[A, B]) -> object: return x.x def call(x: Union[A, B]) -> object: return x.f(5) [file driver.py] from native import A, B, f, g, get, call assert f('a') == 'ax' assert f(A(4)) == 4 assert isinstance(g(0), A) assert g(2) == 3 assert get(A(5)) == 5 assert get(B('x')) == 'x' assert call(A(4)) == 9 assert call(B('x')) == 5 try: f(1) except TypeError: pass else: assert False [case testAnyAll] from typing import Iterable def call_any_nested(l: Iterable[Iterable[int]], val: int = 0) -> int: res = any(i == val for l2 in l for i in l2) return 0 if res else 1 def call_any(l: Iterable[int], val: int = 0) -> int: res = any(i == val for i in l) return 0 if res else 1 def call_all(l: Iterable[int], val: int = 0) -> int: res = all(i == val for i in l) return 0 if res else 1 [file driver.py] from native import call_any, call_all, call_any_nested zeros = [0, 0, 0] ones = [1, 1, 1] mixed_001 = [0, 0, 1] mixed_010 = [0, 1, 0] mixed_100 = [1, 0, 0] mixed_011 = [0, 1, 1] mixed_101 = [1, 0, 1] mixed_110 = [1, 1, 0] assert call_any([]) == 1 assert call_any(zeros) == 0 assert call_any(ones) == 1 assert call_any(mixed_001) == 0 assert call_any(mixed_010) == 0 assert call_any(mixed_100) == 0 assert call_any(mixed_011) == 0 assert call_any(mixed_101) == 0 assert call_any(mixed_110) == 0 assert call_all([]) == 0 assert call_all(zeros) == 0 assert call_all(ones) == 1 assert call_all(mixed_001) == 1 assert call_all(mixed_010) == 1 assert call_all(mixed_100) == 1 assert call_all(mixed_011) == 1 assert call_all(mixed_101) == 1 assert call_all(mixed_110) == 1 assert call_any_nested([[1, 1, 1], [1, 1], []]) == 1 assert call_any_nested([[1, 1, 1], [0, 1], []]) == 0 [case testSum] [typing fixtures/typing-full.pyi] from typing import Any, List def test_sum_of_numbers() -> None: assert sum(x for x in [1, 2, 3]) == 6 assert sum(x for x in [0.0, 1.2, 2]) == 6.2 assert sum(x for x in [1, 1j]) == 1 + 1j def test_sum_callables() -> None: assert sum((lambda x: x == 0)(x) for x in []) == 0 assert sum((lambda x: x == 0)(x) for x in [0]) == 1 assert sum((lambda x: x == 0)(x) for x in [0, 0, 0]) == 3 assert sum((lambda x: x == 0)(x) for x in [0, 1, 0]) == 2 assert sum((lambda x: x % 2 == 0)(x) for x in range(2**10)) == 2**9 def test_sum_comparisons() -> None: assert sum(x == 0 for x in []) == 0 assert sum(x == 0 for x in [0]) == 1 assert sum(x == 0 for x in [0, 0, 0]) == 3 assert sum(x == 0 for x in [0, 1, 0]) == 2 assert sum(x % 2 == 0 for x in range(2**10)) == 2**9 def test_sum_multi() -> None: assert sum(i + j == 0 for i, j in zip([0, 0, 0], [0, 1, 0])) == 2 def test_sum_misc() -> None: # misc cases we do optimize (note, according to sum's helptext, we don't need to support # non-numeric cases, but CPython and mypyc both do anyway) assert sum(c == 'd' for c in 'abcdd') == 2 # misc cases we do not optimize assert sum([0, 1]) == 1 assert sum([0, 1], 1) == 2 def test_sum_start_given() -> None: a = 1 assert sum((x == 0 for x in [0, 1]), a) == 2 assert sum(((lambda x: x == 0)(x) for x in []), 1) == 1 assert sum(((lambda x: x == 0)(x) for x in [0]), 1) == 2 assert sum(((lambda x: x == 0)(x) for x in [0, 0, 0]), 1) == 4 assert sum(((lambda x: x == 0)(x) for x in [0, 1, 0]), 1) == 3 assert sum(((lambda x: x % 2 == 0)(x) for x in range(2**10)), 1) == 2**9 + 1 assert sum((x for x in [1, 1j]), 2j) == 1 + 3j assert sum((c == 'd' for c in 'abcdd'), 1) == 3 [case testNoneStuff] from typing import Optional class A: x: int def lol(x: A) -> None: setattr(x, 'x', 5) def none() -> None: return def arg(x: Optional[A]) -> bool: return x is None [file driver.py] import native native.lol(native.A()) # Catch refcounting failures for i in range(10000): native.none() native.arg(None) [case testBorrowRefs] def make_garbage(arg: object) -> None: b = True while b: arg = None b = False [file driver.py] from native import make_garbage import sys def test(): x = object() r0 = sys.getrefcount(x) make_garbage(x) r1 = sys.getrefcount(x) assert r0 == r1 test() [case testFinalStaticRunFail] if False: from typing import Final if bool(): x: 'Final' = [1] def f() -> int: return x[0] [file driver.py] from native import f try: print(f()) except NameError as e: print(e.args[0]) [out] value for final name "x" was not set [case testFinalStaticRunListTupleInt] if False: from typing import Final x: 'Final' = [1] y: 'Final' = (1, 2) z: 'Final' = 1 + 1 def f() -> int: return x[0] def g() -> int: return y[0] def h() -> int: return z - 1 [file driver.py] from native import f, g, h, x, y, z print(f()) print(x[0]) print(g()) print(y) print(h()) print(z) [out] 1 1 1 (1, 2) 1 2 [case testCheckVersion] import sys if sys.version_info[:2] == (3, 12): def version() -> int: return 12 elif sys.version_info[:2] == (3, 11): def version() -> int: return 11 elif sys.version_info[:2] == (3, 10): def version() -> int: return 10 elif sys.version_info[:2] == (3, 9): def version() -> int: return 9 elif sys.version_info[:2] == (3, 8): def version() -> int: return 8 elif sys.version_info[:2] == (3, 7): def version() -> int: return 7 elif sys.version_info[:2] == (3, 6): def version() -> int: return 6 else: raise Exception("we don't support this version yet!") [file driver.py] import sys version = sys.version_info[:2] import native assert native.version() == sys.version_info[1] [case testTypeErrorMessages] from typing import Tuple class A: pass class B: pass def f(x: B) -> None: pass def g(x: Tuple[int, A]) -> None: pass [file driver.py] from testutil import assertRaises from native import A, f, g class Busted: pass Busted.__module__ = None with assertRaises(TypeError, "int"): f(0) with assertRaises(TypeError, "native.A"): f(A()) with assertRaises(TypeError, "tuple[None, native.A]"): f((None, A())) with assertRaises(TypeError, "tuple[tuple[int, str], native.A]"): f(((1, "ha"), A())) with assertRaises(TypeError, "tuple[<50 items>]"): f(tuple(range(50))) with assertRaises(TypeError, "errored formatting real type!"): f(Busted()) with assertRaises(TypeError, "tuple[int, native.A] object expected; got tuple[int, int]"): g((20, 30)) [case testComprehensionShadowBinder] def foo(x: object) -> object: if isinstance(x, list): return tuple(x for x in x), x return None [file driver.py] from native import foo assert foo(None) == None assert foo([1, 2, 3]) == ((1, 2, 3), [1, 2, 3]) [case testAllLiterals] # Test having all sorts of literals in a single file def test_str() -> None: assert '' == eval("''") assert len('foo bar' + str()) == 7 assert 'foo bar' == eval("'foo bar'") assert 'foo\u1245\0bar' == eval("'foo' + chr(0x1245) + chr(0) + 'bar'") assert 'foobar12345foobar12345foobar12345foobar12345foobar12345foobar12345foobar12345foobar12345foobar12345foobar12345foobar12345foobar12345foobar12345foobar12345' == eval("'foobar12345foobar12345foobar12345foobar12345foobar12345foobar12345foobar12345foobar12345foobar12345foobar12345foobar12345foobar12345foobar12345foobar12345'") assert 'Zoobar12345foobar12345foobar12345foobar12345foobar12345foobar12345foobar12345foobar12345foobar12345foobar12345foobar12345foobar12345foobar12345foobar123' == eval("'Zoobar12345foobar12345foobar12345foobar12345foobar12345foobar12345foobar12345foobar12345foobar12345foobar12345foobar12345foobar12345foobar12345foobar123'") def test_bytes() -> None: assert b'' == eval("b''") assert b'foo bar' == eval("b'foo bar'") assert b'\xafde' == eval(r"b'\xafde'") assert b'foo\xde\0bar' == eval("b'foo' + bytes([0xde, 0]) + b'bar'") assert b'foobar12345foobar12345foobar12345foobar12345foobar12345foobar12345foobar12345foobar12345foobar12345foobar12345foobar12345foobar12345foobar12345foobar12345' == eval("b'foobar12345foobar12345foobar12345foobar12345foobar12345foobar12345foobar12345foobar12345foobar12345foobar12345foobar12345foobar12345foobar12345foobar12345'") def test_int() -> None: assert 2875872359823758923758923759 == eval('2875872359823758923758923759') assert -552875872359823758923758923759 == eval('-552875872359823758923758923759') def test_float() -> None: assert 1.5 == eval('1.5') assert -3.75 == eval('-3.75') assert 2.5e10 == eval('2.5e10') assert 2.5e50 == eval('2.5e50') assert 2.5e1000 == eval('2.5e1000') assert -2.5e1000 == eval('-2.5e1000') def test_complex() -> None: assert 1.5j == eval('1.5j') assert 1.5j + 2.5 == eval('2.5 + 1.5j') assert -3.75j == eval('-3.75j') assert 2.5e10j == eval('2.5e10j') assert 2.5e50j == eval('2.5e50j') assert 2.5e1000j == eval('2.5e1000j') assert 2.5e1000j + 3.5e2000 == eval('3.5e2000 + 2.5e1000j') assert -2.5e1000j == eval('-2.5e1000j') [case testUnreachableExpressions] from typing import cast import sys A = sys.platform == 'x' and foobar B = sys.platform == 'x' and sys.foobar C = sys.platform == 'x' and f(a, -b, 'y') > [c + e, g(y=2)] C = sys.platform == 'x' and cast(a, b[c]) C = sys.platform == 'x' and (lambda x: y + x) # TODO: This still doesn't work # C = sys.platform == 'x' and (x for y in z) assert not A assert not B assert not C [case testDoesntSegfaultWhenTopLevelFails] # make the initial import fail assert False [file driver.py] # load native, cause PyInit to be run, create the module but don't finish initializing the globals for _ in range(2): try: import native raise RuntimeError('exception expected') except AssertionError: pass [case testRepeatedUnderscoreFunctions] def _(arg): pass def _(arg): pass [case testUnderscoreFunctionsInMethods] class A: def _(arg): pass def _(arg): pass class B(A): def _(arg): pass def _(arg): pass [case testGlobalRedefinition_toplevel] # mypy: allow-redefinition i = 0 i += 1 i = "foo" i += i i = b"foo" def test_redefinition() -> None: assert i == b"foo" [case testWithNative] class DummyContext: def __init__(self): self.c = 0 def __enter__(self) -> None: self.c += 1 def __exit__(self, exc_type, exc_val, exc_tb) -> None: self.c -= 1 def test_dummy_context() -> None: c = DummyContext() with c: assert c.c == 1 assert c.c == 0 [case testWithNativeVarArgs] class DummyContext: def __init__(self): self.c = 0 def __enter__(self) -> None: self.c += 1 def __exit__(self, *args: object) -> None: self.c -= 1 def test_dummy_context() -> None: c = DummyContext() with c: assert c.c == 1 assert c.c == 0