# Python test set -- part 1, grammar. # This just tests whether the parser accepts them all. from test.support import check_syntax_error from test.support import import_helper import inspect import unittest import sys import warnings # testing import * from sys import * # different import patterns to check that __annotations__ does not interfere # with import machinery import test.typinganndata.ann_module as ann_module import typing from test.typinganndata import ann_module2 import test # These are shared with test_tokenize and other test modules. # # Note: since several test cases filter out floats by looking for "e" and ".", # don't add hexadecimal literals that contain "e" or "E". VALID_UNDERSCORE_LITERALS = [ '0_0_0', '4_2', '1_0000_0000', '0b1001_0100', '0xffff_ffff', '0o5_7_7', '1_00_00.5', '1_00_00.5e5', '1_00_00e5_1', '1e1_0', '.1_4', '.1_4e1', '0b_0', '0x_f', '0o_5', '1_00_00j', '1_00_00.5j', '1_00_00e5_1j', '.1_4j', '(1_2.5+3_3j)', '(.5_6j)', ] INVALID_UNDERSCORE_LITERALS = [ # Trailing underscores: '0_', '42_', '1.4j_', '0x_', '0b1_', '0xf_', '0o5_', '0 if 1_Else 1', # Underscores in the base selector: '0_b0', '0_xf', '0_o5', # Old-style octal, still disallowed: '0_7', '09_99', # Multiple consecutive underscores: '4_______2', '0.1__4', '0.1__4j', '0b1001__0100', '0xffff__ffff', '0x___', '0o5__77', '1e1__0', '1e1__0j', # Underscore right before a dot: '1_.4', '1_.4j', # Underscore right after a dot: '1._4', '1._4j', '._5', '._5j', # Underscore right after a sign: '1.0e+_1', '1.0e+_1j', # Underscore right before j: '1.4_j', '1.4e5_j', # Underscore right before e: '1_e1', '1.4_e1', '1.4_e1j', # Underscore right after e: '1e_1', '1.4e_1', '1.4e_1j', # Complex cases with parens: '(1+1.5_j_)', '(1+1.5_j)', ] class TokenTests(unittest.TestCase): from test.support import check_syntax_error from test.support.warnings_helper import check_syntax_warning def test_backslash(self): # Backslash means line continuation: x = 1 \ + 1 self.assertEqual(x, 2, 'backslash for line continuation') # Backslash does not means continuation in comments :\ x = 0 self.assertEqual(x, 0, 'backslash ending comment') def test_plain_integers(self): self.assertEqual(type(000), type(0)) self.assertEqual(0xff, 255) self.assertEqual(0o377, 255) self.assertEqual(2147483647, 0o17777777777) self.assertEqual(0b1001, 9) # "0x" is not a valid literal self.assertRaises(SyntaxError, eval, "0x") from sys import maxsize if maxsize == 2147483647: self.assertEqual(-2147483647-1, -0o20000000000) # XXX -2147483648 self.assertTrue(0o37777777777 > 0) self.assertTrue(0xffffffff > 0) self.assertTrue(0b1111111111111111111111111111111 > 0) for s in ('2147483648', '0o40000000000', '0x100000000', '0b10000000000000000000000000000000'): try: x = eval(s) except OverflowError: self.fail("OverflowError on huge integer literal %r" % s) elif maxsize == 9223372036854775807: self.assertEqual(-9223372036854775807-1, -0o1000000000000000000000) self.assertTrue(0o1777777777777777777777 > 0) self.assertTrue(0xffffffffffffffff > 0) self.assertTrue(0b11111111111111111111111111111111111111111111111111111111111111 > 0) for s in '9223372036854775808', '0o2000000000000000000000', \ '0x10000000000000000', \ '0b100000000000000000000000000000000000000000000000000000000000000': try: x = eval(s) except OverflowError: self.fail("OverflowError on huge integer literal %r" % s) else: self.fail('Weird maxsize value %r' % maxsize) def test_long_integers(self): x = 0 x = 0xffffffffffffffff x = 0Xffffffffffffffff x = 0o77777777777777777 x = 0O77777777777777777 x = 123456789012345678901234567890 x = 0b100000000000000000000000000000000000000000000000000000000000000000000 x = 0B111111111111111111111111111111111111111111111111111111111111111111111 def test_floats(self): x = 3.14 x = 314. x = 0.314 x = 000.314 x = .314 x = 3e14 x = 3E14 x = 3e-14 x = 3e+14 x = 3.e14 x = .3e14 x = 3.1e4 def test_float_exponent_tokenization(self): # See issue 21642. with warnings.catch_warnings(): warnings.simplefilter('ignore', SyntaxWarning) self.assertEqual(eval("1 if 1else 0"), 1) self.assertEqual(eval("1 if 0else 0"), 0) self.assertRaises(SyntaxError, eval, "0 if 1Else 0") def test_underscore_literals(self): for lit in VALID_UNDERSCORE_LITERALS: self.assertEqual(eval(lit), eval(lit.replace('_', ''))) for lit in INVALID_UNDERSCORE_LITERALS: self.assertRaises(SyntaxError, eval, lit) # Sanity check: no literal begins with an underscore self.assertRaises(NameError, eval, "_0") def test_bad_numerical_literals(self): check = self.check_syntax_error check("0b12", "invalid digit '2' in binary literal") check("0b1_2", "invalid digit '2' in binary literal") check("0b2", "invalid digit '2' in binary literal") check("0b1_", "invalid binary literal") check("0b", "invalid binary literal") check("0o18", "invalid digit '8' in octal literal") check("0o1_8", "invalid digit '8' in octal literal") check("0o8", "invalid digit '8' in octal literal") check("0o1_", "invalid octal literal") check("0o", "invalid octal literal") check("0x1_", "invalid hexadecimal literal") check("0x", "invalid hexadecimal literal") check("1_", "invalid decimal literal") check("012", "leading zeros in decimal integer literals are not permitted; " "use an 0o prefix for octal integers") check("1.2_", "invalid decimal literal") check("1e2_", "invalid decimal literal") check("1e+", "invalid decimal literal") def test_end_of_numerical_literals(self): def check(test, error=False): with self.subTest(expr=test): if error: with warnings.catch_warnings(record=True) as w: with self.assertRaisesRegex(SyntaxError, r'invalid \w+ literal'): compile(test, "", "eval") self.assertEqual(w, []) else: self.check_syntax_warning(test, errtext=r'invalid \w+ literal') for num in "0xf", "0o7", "0b1", "9", "0", "1.", "1e3", "1j": compile(num, "", "eval") check(f"{num}and x", error=(num == "0xf")) check(f"{num}or x", error=(num == "0")) check(f"{num}in x") check(f"{num}not in x") check(f"{num}if x else y") check(f"x if {num}else y", error=(num == "0xf")) check(f"[{num}for x in ()]") check(f"{num}spam", error=True) # gh-88943: Invalid non-ASCII character following a numerical literal. with self.assertRaisesRegex(SyntaxError, r"invalid character '⁄' \(U\+2044\)"): compile(f"{num}⁄7", "", "eval") with self.assertWarnsRegex(SyntaxWarning, r'invalid \w+ literal'): compile(f"{num}is x", "", "eval") with warnings.catch_warnings(): warnings.simplefilter('error', SyntaxWarning) with self.assertRaisesRegex(SyntaxError, r'invalid \w+ literal'): compile(f"{num}is x", "", "eval") check("[0x1ffor x in ()]") check("[0x1for x in ()]") check("[0xfor x in ()]") def test_string_literals(self): x = ''; y = ""; self.assertTrue(len(x) == 0 and x == y) x = '\''; y = "'"; self.assertTrue(len(x) == 1 and x == y and ord(x) == 39) x = '"'; y = "\""; self.assertTrue(len(x) == 1 and x == y and ord(x) == 34) x = "doesn't \"shrink\" does it" y = 'doesn\'t "shrink" does it' self.assertTrue(len(x) == 24 and x == y) x = "does \"shrink\" doesn't it" y = 'does "shrink" doesn\'t it' self.assertTrue(len(x) == 24 and x == y) x = """ The "quick" brown fox jumps over the 'lazy' dog. """ y = '\nThe "quick"\nbrown fox\njumps over\nthe \'lazy\' dog.\n' self.assertEqual(x, y) y = ''' The "quick" brown fox jumps over the 'lazy' dog. ''' self.assertEqual(x, y) y = "\n\ The \"quick\"\n\ brown fox\n\ jumps over\n\ the 'lazy' dog.\n\ " self.assertEqual(x, y) y = '\n\ The \"quick\"\n\ brown fox\n\ jumps over\n\ the \'lazy\' dog.\n\ ' self.assertEqual(x, y) def test_ellipsis(self): x = ... self.assertTrue(x is Ellipsis) self.assertRaises(SyntaxError, eval, ".. .") def test_eof_error(self): samples = ("def foo(", "\ndef foo(", "def foo(\n") for s in samples: with self.assertRaises(SyntaxError) as cm: compile(s, "", "exec") self.assertIn("was never closed", str(cm.exception)) var_annot_global: int # a global annotated is necessary for test_var_annot # custom namespace for testing __annotations__ class CNS: def __init__(self): self._dct = {} def __setitem__(self, item, value): self._dct[item.lower()] = value def __getitem__(self, item): return self._dct[item] class GrammarTests(unittest.TestCase): from test.support import check_syntax_error from test.support.warnings_helper import check_syntax_warning from test.support.warnings_helper import check_no_warnings # single_input: NEWLINE | simple_stmt | compound_stmt NEWLINE # XXX can't test in a script -- this rule is only used when interactive # file_input: (NEWLINE | stmt)* ENDMARKER # Being tested as this very moment this very module # expr_input: testlist NEWLINE # XXX Hard to test -- used only in calls to input() def test_eval_input(self): # testlist ENDMARKER x = eval('1, 0 or 1') def test_var_annot_basics(self): # all these should be allowed var1: int = 5 var2: [int, str] my_lst = [42] def one(): return 1 int.new_attr: int [list][0]: type my_lst[one()-1]: int = 5 self.assertEqual(my_lst, [5]) def test_var_annot_syntax_errors(self): # parser pass check_syntax_error(self, "def f: int") check_syntax_error(self, "x: int: str") check_syntax_error(self, "def f():\n" " nonlocal x: int\n") check_syntax_error(self, "def f():\n" " global x: int\n") check_syntax_error(self, "x: int = y = 1") check_syntax_error(self, "z = w: int = 1") check_syntax_error(self, "x: int = y: int = 1") # AST pass check_syntax_error(self, "[x, 0]: int\n") check_syntax_error(self, "f(): int\n") check_syntax_error(self, "(x,): int") check_syntax_error(self, "def f():\n" " (x, y): int = (1, 2)\n") # symtable pass check_syntax_error(self, "def f():\n" " x: int\n" " global x\n") check_syntax_error(self, "def f():\n" " global x\n" " x: int\n") check_syntax_error(self, "def f():\n" " x: int\n" " nonlocal x\n") check_syntax_error(self, "def f():\n" " nonlocal x\n" " x: int\n") def test_var_annot_basic_semantics(self): # execution order with self.assertRaises(ZeroDivisionError): no_name[does_not_exist]: no_name_again = 1/0 with self.assertRaises(NameError): no_name[does_not_exist]: 1/0 = 0 global var_annot_global # function semantics def f(): st: str = "Hello" a.b: int = (1, 2) return st self.assertEqual(f.__annotations__, {}) def f_OK(): x: 1/0 f_OK() def fbad(): x: int print(x) with self.assertRaises(UnboundLocalError): fbad() def f2bad(): (no_such_global): int print(no_such_global) try: f2bad() except Exception as e: self.assertIs(type(e), NameError) # class semantics class C: __foo: int s: str = "attr" z = 2 def __init__(self, x): self.x: int = x self.assertEqual(C.__annotations__, {'_C__foo': int, 's': str}) with self.assertRaises(NameError): class CBad: no_such_name_defined.attr: int = 0 with self.assertRaises(NameError): class Cbad2(C): x: int x.y: list = [] def test_annotations_inheritance(self): # Check that annotations are not inherited by derived classes class A: attr: int class B(A): pass class C(A): attr: str class D: attr2: int class E(A, D): pass class F(C, A): pass self.assertEqual(A.__annotations__, {"attr": int}) self.assertEqual(B.__annotations__, {}) self.assertEqual(C.__annotations__, {"attr" : str}) self.assertEqual(D.__annotations__, {"attr2" : int}) self.assertEqual(E.__annotations__, {}) self.assertEqual(F.__annotations__, {}) def test_var_annot_metaclass_semantics(self): class CMeta(type): @classmethod def __prepare__(metacls, name, bases, **kwds): return {'__annotations__': CNS()} class CC(metaclass=CMeta): XX: 'ANNOT' self.assertEqual(CC.__annotations__['xx'], 'ANNOT') def test_var_annot_module_semantics(self): self.assertEqual(test.__annotations__, {}) self.assertEqual(ann_module.__annotations__, {1: 2, 'x': int, 'y': str, 'f': typing.Tuple[int, int], 'u': int | float}) self.assertEqual(ann_module.M.__annotations__, {'123': 123, 'o': type}) self.assertEqual(ann_module2.__annotations__, {}) def test_var_annot_in_module(self): # check that functions fail the same way when executed # outside of module where they were defined ann_module3 = import_helper.import_fresh_module("test.typinganndata.ann_module3") with self.assertRaises(NameError): ann_module3.f_bad_ann() with self.assertRaises(NameError): ann_module3.g_bad_ann() with self.assertRaises(NameError): ann_module3.D_bad_ann(5) def test_var_annot_simple_exec(self): gns = {}; lns= {} exec("'docstring'\n" "__annotations__[1] = 2\n" "x: int = 5\n", gns, lns) self.assertEqual(lns["__annotations__"], {1: 2, 'x': int}) with self.assertRaises(KeyError): gns['__annotations__'] def test_var_annot_custom_maps(self): # tests with custom locals() and __annotations__ ns = {'__annotations__': CNS()} exec('X: int; Z: str = "Z"; (w): complex = 1j', ns) self.assertEqual(ns['__annotations__']['x'], int) self.assertEqual(ns['__annotations__']['z'], str) with self.assertRaises(KeyError): ns['__annotations__']['w'] nonloc_ns = {} class CNS2: def __init__(self): self._dct = {} def __setitem__(self, item, value): nonlocal nonloc_ns self._dct[item] = value nonloc_ns[item] = value def __getitem__(self, item): return self._dct[item] exec('x: int = 1', {}, CNS2()) self.assertEqual(nonloc_ns['__annotations__']['x'], int) def test_var_annot_refleak(self): # complex case: custom locals plus custom __annotations__ # this was causing refleak cns = CNS() nonloc_ns = {'__annotations__': cns} class CNS2: def __init__(self): self._dct = {'__annotations__': cns} def __setitem__(self, item, value): nonlocal nonloc_ns self._dct[item] = value nonloc_ns[item] = value def __getitem__(self, item): return self._dct[item] exec('X: str', {}, CNS2()) self.assertEqual(nonloc_ns['__annotations__']['x'], str) def test_var_annot_rhs(self): ns = {} exec('x: tuple = 1, 2', ns) self.assertEqual(ns['x'], (1, 2)) stmt = ('def f():\n' ' x: int = yield') exec(stmt, ns) self.assertEqual(list(ns['f']()), [None]) ns = {"a": 1, 'b': (2, 3, 4), "c":5, "Tuple": typing.Tuple} exec('x: Tuple[int, ...] = a,*b,c', ns) self.assertEqual(ns['x'], (1, 2, 3, 4, 5)) def test_funcdef(self): ### [decorators] 'def' NAME parameters ['->' test] ':' suite ### decorator: '@' namedexpr_test NEWLINE ### decorators: decorator+ ### parameters: '(' [typedargslist] ')' ### typedargslist: ((tfpdef ['=' test] ',')* ### ('*' [tfpdef] (',' tfpdef ['=' test])* [',' '**' tfpdef] | '**' tfpdef) ### | tfpdef ['=' test] (',' tfpdef ['=' test])* [',']) ### tfpdef: NAME [':' test] ### varargslist: ((vfpdef ['=' test] ',')* ### ('*' [vfpdef] (',' vfpdef ['=' test])* [',' '**' vfpdef] | '**' vfpdef) ### | vfpdef ['=' test] (',' vfpdef ['=' test])* [',']) ### vfpdef: NAME def f1(): pass f1() f1(*()) f1(*(), **{}) def f2(one_argument): pass def f3(two, arguments): pass self.assertEqual(f2.__code__.co_varnames, ('one_argument',)) self.assertEqual(f3.__code__.co_varnames, ('two', 'arguments')) def a1(one_arg,): pass def a2(two, args,): pass def v0(*rest): pass def v1(a, *rest): pass def v2(a, b, *rest): pass f1() f2(1) f2(1,) f3(1, 2) f3(1, 2,) v0() v0(1) v0(1,) v0(1,2) v0(1,2,3,4,5,6,7,8,9,0) v1(1) v1(1,) v1(1,2) v1(1,2,3) v1(1,2,3,4,5,6,7,8,9,0) v2(1,2) v2(1,2,3) v2(1,2,3,4) v2(1,2,3,4,5,6,7,8,9,0) def d01(a=1): pass d01() d01(1) d01(*(1,)) d01(*[] or [2]) d01(*() or (), *{} and (), **() or {}) d01(**{'a':2}) d01(**{'a':2} or {}) def d11(a, b=1): pass d11(1) d11(1, 2) d11(1, **{'b':2}) def d21(a, b, c=1): pass d21(1, 2) d21(1, 2, 3) d21(*(1, 2, 3)) d21(1, *(2, 3)) d21(1, 2, *(3,)) d21(1, 2, **{'c':3}) def d02(a=1, b=2): pass d02() d02(1) d02(1, 2) d02(*(1, 2)) d02(1, *(2,)) d02(1, **{'b':2}) d02(**{'a': 1, 'b': 2}) def d12(a, b=1, c=2): pass d12(1) d12(1, 2) d12(1, 2, 3) def d22(a, b, c=1, d=2): pass d22(1, 2) d22(1, 2, 3) d22(1, 2, 3, 4) def d01v(a=1, *rest): pass d01v() d01v(1) d01v(1, 2) d01v(*(1, 2, 3, 4)) d01v(*(1,)) d01v(**{'a':2}) def d11v(a, b=1, *rest): pass d11v(1) d11v(1, 2) d11v(1, 2, 3) def d21v(a, b, c=1, *rest): pass d21v(1, 2) d21v(1, 2, 3) d21v(1, 2, 3, 4) d21v(*(1, 2, 3, 4)) d21v(1, 2, **{'c': 3}) def d02v(a=1, b=2, *rest): pass d02v() d02v(1) d02v(1, 2) d02v(1, 2, 3) d02v(1, *(2, 3, 4)) d02v(**{'a': 1, 'b': 2}) def d12v(a, b=1, c=2, *rest): pass d12v(1) d12v(1, 2) d12v(1, 2, 3) d12v(1, 2, 3, 4) d12v(*(1, 2, 3, 4)) d12v(1, 2, *(3, 4, 5)) d12v(1, *(2,), **{'c': 3}) def d22v(a, b, c=1, d=2, *rest): pass d22v(1, 2) d22v(1, 2, 3) d22v(1, 2, 3, 4) d22v(1, 2, 3, 4, 5) d22v(*(1, 2, 3, 4)) d22v(1, 2, *(3, 4, 5)) d22v(1, *(2, 3), **{'d': 4}) # keyword argument type tests with warnings.catch_warnings(): warnings.simplefilter('ignore', BytesWarning) try: str('x', **{b'foo':1 }) except TypeError: pass else: self.fail('Bytes should not work as keyword argument names') # keyword only argument tests def pos0key1(*, key): return key pos0key1(key=100) def pos2key2(p1, p2, *, k1, k2=100): return p1,p2,k1,k2 pos2key2(1, 2, k1=100) pos2key2(1, 2, k1=100, k2=200) pos2key2(1, 2, k2=100, k1=200) def pos2key2dict(p1, p2, *, k1=100, k2, **kwarg): return p1,p2,k1,k2,kwarg pos2key2dict(1,2,k2=100,tokwarg1=100,tokwarg2=200) pos2key2dict(1,2,tokwarg1=100,tokwarg2=200, k2=100) self.assertRaises(SyntaxError, eval, "def f(*): pass") self.assertRaises(SyntaxError, eval, "def f(*,): pass") self.assertRaises(SyntaxError, eval, "def f(*, **kwds): pass") # keyword arguments after *arglist def f(*args, **kwargs): return args, kwargs self.assertEqual(f(1, x=2, *[3, 4], y=5), ((1, 3, 4), {'x':2, 'y':5})) self.assertEqual(f(1, *(2,3), 4), ((1, 2, 3, 4), {})) self.assertRaises(SyntaxError, eval, "f(1, x=2, *(3,4), x=5)") self.assertEqual(f(**{'eggs':'scrambled', 'spam':'fried'}), ((), {'eggs':'scrambled', 'spam':'fried'})) self.assertEqual(f(spam='fried', **{'eggs':'scrambled'}), ((), {'eggs':'scrambled', 'spam':'fried'})) # Check ast errors in *args and *kwargs check_syntax_error(self, "f(*g(1=2))") check_syntax_error(self, "f(**g(1=2))") # argument annotation tests def f(x) -> list: pass self.assertEqual(f.__annotations__, {'return': list}) def f(x: int): pass self.assertEqual(f.__annotations__, {'x': int}) def f(x: int, /): pass self.assertEqual(f.__annotations__, {'x': int}) def f(x: int = 34, /): pass self.assertEqual(f.__annotations__, {'x': int}) def f(*x: str): pass self.assertEqual(f.__annotations__, {'x': str}) def f(**x: float): pass self.assertEqual(f.__annotations__, {'x': float}) def f(x, y: 1+2): pass self.assertEqual(f.__annotations__, {'y': 3}) def f(x, y: 1+2, /): pass self.assertEqual(f.__annotations__, {'y': 3}) def f(a, b: 1, c: 2, d): pass self.assertEqual(f.__annotations__, {'b': 1, 'c': 2}) def f(a, b: 1, /, c: 2, d): pass self.assertEqual(f.__annotations__, {'b': 1, 'c': 2}) def f(a, b: 1, c: 2, d, e: 3 = 4, f=5, *g: 6): pass self.assertEqual(f.__annotations__, {'b': 1, 'c': 2, 'e': 3, 'g': 6}) def f(a, b: 1, c: 2, d, e: 3 = 4, f=5, *g: 6, h: 7, i=8, j: 9 = 10, **k: 11) -> 12: pass self.assertEqual(f.__annotations__, {'b': 1, 'c': 2, 'e': 3, 'g': 6, 'h': 7, 'j': 9, 'k': 11, 'return': 12}) def f(a, b: 1, c: 2, d, e: 3 = 4, f: int = 5, /, *g: 6, h: 7, i=8, j: 9 = 10, **k: 11) -> 12: pass self.assertEqual(f.__annotations__, {'b': 1, 'c': 2, 'e': 3, 'f': int, 'g': 6, 'h': 7, 'j': 9, 'k': 11, 'return': 12}) # Check for issue #20625 -- annotations mangling class Spam: def f(self, *, __kw: 1): pass class Ham(Spam): pass self.assertEqual(Spam.f.__annotations__, {'_Spam__kw': 1}) self.assertEqual(Ham.f.__annotations__, {'_Spam__kw': 1}) # Check for SF Bug #1697248 - mixing decorators and a return annotation def null(x): return x @null def f(x) -> list: pass self.assertEqual(f.__annotations__, {'return': list}) # Test expressions as decorators (PEP 614): @False or null def f(x): pass @d := null def f(x): pass @lambda f: null(f) def f(x): pass @[..., null, ...][1] def f(x): pass @null(null)(null) def f(x): pass @[null][0].__call__.__call__ def f(x): pass # test closures with a variety of opargs closure = 1 def f(): return closure def f(x=1): return closure def f(*, k=1): return closure def f() -> int: return closure # Check trailing commas are permitted in funcdef argument list def f(a,): pass def f(*args,): pass def f(**kwds,): pass def f(a, *args,): pass def f(a, **kwds,): pass def f(*args, b,): pass def f(*, b,): pass def f(*args, **kwds,): pass def f(a, *args, b,): pass def f(a, *, b,): pass def f(a, *args, **kwds,): pass def f(*args, b, **kwds,): pass def f(*, b, **kwds,): pass def f(a, *args, b, **kwds,): pass def f(a, *, b, **kwds,): pass def test_lambdef(self): ### lambdef: 'lambda' [varargslist] ':' test l1 = lambda : 0 self.assertEqual(l1(), 0) l2 = lambda : a[d] # XXX just testing the expression l3 = lambda : [2 < x for x in [-1, 3, 0]] self.assertEqual(l3(), [0, 1, 0]) l4 = lambda x = lambda y = lambda z=1 : z : y() : x() self.assertEqual(l4(), 1) l5 = lambda x, y, z=2: x + y + z self.assertEqual(l5(1, 2), 5) self.assertEqual(l5(1, 2, 3), 6) check_syntax_error(self, "lambda x: x = 2") check_syntax_error(self, "lambda (None,): None") l6 = lambda x, y, *, k=20: x+y+k self.assertEqual(l6(1,2), 1+2+20) self.assertEqual(l6(1,2,k=10), 1+2+10) # check that trailing commas are permitted l10 = lambda a,: 0 l11 = lambda *args,: 0 l12 = lambda **kwds,: 0 l13 = lambda a, *args,: 0 l14 = lambda a, **kwds,: 0 l15 = lambda *args, b,: 0 l16 = lambda *, b,: 0 l17 = lambda *args, **kwds,: 0 l18 = lambda a, *args, b,: 0 l19 = lambda a, *, b,: 0 l20 = lambda a, *args, **kwds,: 0 l21 = lambda *args, b, **kwds,: 0 l22 = lambda *, b, **kwds,: 0 l23 = lambda a, *args, b, **kwds,: 0 l24 = lambda a, *, b, **kwds,: 0 ### stmt: simple_stmt | compound_stmt # Tested below def test_simple_stmt(self): ### simple_stmt: small_stmt (';' small_stmt)* [';'] x = 1; pass; del x def foo(): # verify statements that end with semi-colons x = 1; pass; del x; foo() ### small_stmt: expr_stmt | pass_stmt | del_stmt | flow_stmt | import_stmt | global_stmt | access_stmt # Tested below def test_expr_stmt(self): # (exprlist '=')* exprlist 1 1, 2, 3 x = 1 x = 1, 2, 3 x = y = z = 1, 2, 3 x, y, z = 1, 2, 3 abc = a, b, c = x, y, z = xyz = 1, 2, (3, 4) check_syntax_error(self, "x + 1 = 1") check_syntax_error(self, "a + 1 = b + 2") # Check the heuristic for print & exec covers significant cases # As well as placing some limits on false positives def test_former_statements_refer_to_builtins(self): keywords = "print", "exec" # Cases where we want the custom error cases = [ "{} foo", "{} {{1:foo}}", "if 1: {} foo", "if 1: {} {{1:foo}}", "if 1:\n {} foo", "if 1:\n {} {{1:foo}}", ] for keyword in keywords: custom_msg = "call to '{}'".format(keyword) for case in cases: source = case.format(keyword) with self.subTest(source=source): with self.assertRaisesRegex(SyntaxError, custom_msg): exec(source) source = source.replace("foo", "(foo.)") with self.subTest(source=source): with self.assertRaisesRegex(SyntaxError, "invalid syntax"): exec(source) def test_del_stmt(self): # 'del' exprlist abc = [1,2,3] x, y, z = abc xyz = x, y, z del abc del x, y, (z, xyz) x, y, z = "xyz" del x del y, del (z) del () a, b, c, d, e, f, g = "abcdefg" del a, (b, c), (d, (e, f)) a, b, c, d, e, f, g = "abcdefg" del a, [b, c], (d, [e, f]) abcd = list("abcd") del abcd[1:2] compile("del a, (b[0].c, (d.e, f.g[1:2])), [h.i.j], ()", "", "exec") def test_pass_stmt(self): # 'pass' pass # flow_stmt: break_stmt | continue_stmt | return_stmt | raise_stmt # Tested below def test_break_stmt(self): # 'break' while 1: break def test_continue_stmt(self): # 'continue' i = 1 while i: i = 0; continue msg = "" while not msg: msg = "ok" try: continue msg = "continue failed to continue inside try" except: msg = "continue inside try called except block" if msg != "ok": self.fail(msg) msg = "" while not msg: msg = "finally block not called" try: continue finally: msg = "ok" if msg != "ok": self.fail(msg) def test_break_continue_loop(self): # This test warrants an explanation. It is a test specifically for SF bugs # #463359 and #462937. The bug is that a 'break' statement executed or # exception raised inside a try/except inside a loop, *after* a continue # statement has been executed in that loop, will cause the wrong number of # arguments to be popped off the stack and the instruction pointer reset to # a very small number (usually 0.) Because of this, the following test # *must* written as a function, and the tracking vars *must* be function # arguments with default values. Otherwise, the test will loop and loop. def test_inner(extra_burning_oil = 1, count=0): big_hippo = 2 while big_hippo: count += 1 try: if extra_burning_oil and big_hippo == 1: extra_burning_oil -= 1 break big_hippo -= 1 continue except: raise if count > 2 or big_hippo != 1: self.fail("continue then break in try/except in loop broken!") test_inner() def test_return(self): # 'return' [testlist_star_expr] def g1(): return def g2(): return 1 def g3(): z = [2, 3] return 1, *z g1() x = g2() y = g3() self.assertEqual(y, (1, 2, 3), "unparenthesized star expr return") check_syntax_error(self, "class foo:return 1") def test_break_in_finally(self): count = 0 while count < 2: count += 1 try: pass finally: break self.assertEqual(count, 1) count = 0 while count < 2: count += 1 try: continue finally: break self.assertEqual(count, 1) count = 0 while count < 2: count += 1 try: 1/0 finally: break self.assertEqual(count, 1) for count in [0, 1]: self.assertEqual(count, 0) try: pass finally: break self.assertEqual(count, 0) for count in [0, 1]: self.assertEqual(count, 0) try: continue finally: break self.assertEqual(count, 0) for count in [0, 1]: self.assertEqual(count, 0) try: 1/0 finally: break self.assertEqual(count, 0) def test_continue_in_finally(self): count = 0 while count < 2: count += 1 try: pass finally: continue break self.assertEqual(count, 2) count = 0 while count < 2: count += 1 try: break finally: continue self.assertEqual(count, 2) count = 0 while count < 2: count += 1 try: 1/0 finally: continue break self.assertEqual(count, 2) for count in [0, 1]: try: pass finally: continue break self.assertEqual(count, 1) for count in [0, 1]: try: break finally: continue self.assertEqual(count, 1) for count in [0, 1]: try: 1/0 finally: continue break self.assertEqual(count, 1) def test_return_in_finally(self): def g1(): try: pass finally: return 1 self.assertEqual(g1(), 1) def g2(): try: return 2 finally: return 3 self.assertEqual(g2(), 3) def g3(): try: 1/0 finally: return 4 self.assertEqual(g3(), 4) def test_break_in_finally_after_return(self): # See issue #37830 def g1(x): for count in [0, 1]: count2 = 0 while count2 < 20: count2 += 10 try: return count + count2 finally: if x: break return 'end', count, count2 self.assertEqual(g1(False), 10) self.assertEqual(g1(True), ('end', 1, 10)) def g2(x): for count in [0, 1]: for count2 in [10, 20]: try: return count + count2 finally: if x: break return 'end', count, count2 self.assertEqual(g2(False), 10) self.assertEqual(g2(True), ('end', 1, 10)) def test_continue_in_finally_after_return(self): # See issue #37830 def g1(x): count = 0 while count < 100: count += 1 try: return count finally: if x: continue return 'end', count self.assertEqual(g1(False), 1) self.assertEqual(g1(True), ('end', 100)) def g2(x): for count in [0, 1]: try: return count finally: if x: continue return 'end', count self.assertEqual(g2(False), 0) self.assertEqual(g2(True), ('end', 1)) def test_yield(self): # Allowed as standalone statement def g(): yield 1 def g(): yield from () # Allowed as RHS of assignment def g(): x = yield 1 def g(): x = yield from () # Ordinary yield accepts implicit tuples def g(): yield 1, 1 def g(): x = yield 1, 1 # 'yield from' does not check_syntax_error(self, "def g(): yield from (), 1") check_syntax_error(self, "def g(): x = yield from (), 1") # Requires parentheses as subexpression def g(): 1, (yield 1) def g(): 1, (yield from ()) check_syntax_error(self, "def g(): 1, yield 1") check_syntax_error(self, "def g(): 1, yield from ()") # Requires parentheses as call argument def g(): f((yield 1)) def g(): f((yield 1), 1) def g(): f((yield from ())) def g(): f((yield from ()), 1) # Do not require parenthesis for tuple unpacking def g(): rest = 4, 5, 6; yield 1, 2, 3, *rest self.assertEqual(list(g()), [(1, 2, 3, 4, 5, 6)]) check_syntax_error(self, "def g(): f(yield 1)") check_syntax_error(self, "def g(): f(yield 1, 1)") check_syntax_error(self, "def g(): f(yield from ())") check_syntax_error(self, "def g(): f(yield from (), 1)") # Not allowed at top level check_syntax_error(self, "yield") check_syntax_error(self, "yield from") # Not allowed at class scope check_syntax_error(self, "class foo:yield 1") check_syntax_error(self, "class foo:yield from ()") # Check annotation refleak on SyntaxError check_syntax_error(self, "def g(a:(yield)): pass") def test_yield_in_comprehensions(self): # Check yield in comprehensions def g(): [x for x in [(yield 1)]] def g(): [x for x in [(yield from ())]] check = self.check_syntax_error check("def g(): [(yield x) for x in ()]", "'yield' inside list comprehension") check("def g(): [x for x in () if not (yield x)]", "'yield' inside list comprehension") check("def g(): [y for x in () for y in [(yield x)]]", "'yield' inside list comprehension") check("def g(): {(yield x) for x in ()}", "'yield' inside set comprehension") check("def g(): {(yield x): x for x in ()}", "'yield' inside dict comprehension") check("def g(): {x: (yield x) for x in ()}", "'yield' inside dict comprehension") check("def g(): ((yield x) for x in ())", "'yield' inside generator expression") check("def g(): [(yield from x) for x in ()]", "'yield' inside list comprehension") check("class C: [(yield x) for x in ()]", "'yield' inside list comprehension") check("[(yield x) for x in ()]", "'yield' inside list comprehension") def test_raise(self): # 'raise' test [',' test] try: raise RuntimeError('just testing') except RuntimeError: pass try: raise KeyboardInterrupt except KeyboardInterrupt: pass def test_import(self): # 'import' dotted_as_names import sys import time, sys # 'from' dotted_name 'import' ('*' | '(' import_as_names ')' | import_as_names) from time import time from time import (time) # not testable inside a function, but already done at top of the module # from sys import * from sys import path, argv from sys import (path, argv) from sys import (path, argv,) def test_global(self): # 'global' NAME (',' NAME)* global a global a, b global one, two, three, four, five, six, seven, eight, nine, ten def test_nonlocal(self): # 'nonlocal' NAME (',' NAME)* x = 0 y = 0 def f(): nonlocal x nonlocal x, y def test_assert(self): # assertTruestmt: 'assert' test [',' test] assert 1 assert 1, 1 assert lambda x:x assert 1, lambda x:x+1 try: assert True except AssertionError as e: self.fail("'assert True' should not have raised an AssertionError") try: assert True, 'this should always pass' except AssertionError as e: self.fail("'assert True, msg' should not have " "raised an AssertionError") # these tests fail if python is run with -O, so check __debug__ @unittest.skipUnless(__debug__, "Won't work if __debug__ is False") def test_assert_failures(self): try: assert 0, "msg" except AssertionError as e: self.assertEqual(e.args[0], "msg") else: self.fail("AssertionError not raised by assert 0") try: assert False except AssertionError as e: self.assertEqual(len(e.args), 0) else: self.fail("AssertionError not raised by 'assert False'") def test_assert_syntax_warnings(self): # Ensure that we warn users if they provide a non-zero length tuple as # the assertion test. self.check_syntax_warning('assert(x, "msg")', 'assertion is always true') self.check_syntax_warning('assert(False, "msg")', 'assertion is always true') self.check_syntax_warning('assert(False,)', 'assertion is always true') with self.check_no_warnings(category=SyntaxWarning): compile('assert x, "msg"', '', 'exec') compile('assert False, "msg"', '', 'exec') def test_assert_warning_promotes_to_syntax_error(self): # If SyntaxWarning is configured to be an error, it actually raises a # SyntaxError. # https://bugs.python.org/issue35029 with warnings.catch_warnings(): warnings.simplefilter('error', SyntaxWarning) try: compile('assert x, "msg" ', '', 'exec') except SyntaxError: self.fail('SyntaxError incorrectly raised for \'assert x, "msg"\'') with self.assertRaises(SyntaxError): compile('assert(x, "msg")', '', 'exec') with self.assertRaises(SyntaxError): compile('assert(False, "msg")', '', 'exec') with self.assertRaises(SyntaxError): compile('assert(False,)', '', 'exec') ### compound_stmt: if_stmt | while_stmt | for_stmt | try_stmt | funcdef | classdef # Tested below def test_if(self): # 'if' test ':' suite ('elif' test ':' suite)* ['else' ':' suite] if 1: pass if 1: pass else: pass if 0: pass elif 0: pass if 0: pass elif 0: pass elif 0: pass elif 0: pass else: pass def test_while(self): # 'while' test ':' suite ['else' ':' suite] while 0: pass while 0: pass else: pass # Issue1920: "while 0" is optimized away, # ensure that the "else" clause is still present. x = 0 while 0: x = 1 else: x = 2 self.assertEqual(x, 2) def test_for(self): # 'for' exprlist 'in' exprlist ':' suite ['else' ':' suite] for i in 1, 2, 3: pass for i, j, k in (): pass else: pass class Squares: def __init__(self, max): self.max = max self.sofar = [] def __len__(self): return len(self.sofar) def __getitem__(self, i): if not 0 <= i < self.max: raise IndexError n = len(self.sofar) while n <= i: self.sofar.append(n*n) n = n+1 return self.sofar[i] n = 0 for x in Squares(10): n = n+x if n != 285: self.fail('for over growing sequence') result = [] for x, in [(1,), (2,), (3,)]: result.append(x) self.assertEqual(result, [1, 2, 3]) result = [] a = b = c = [1, 2, 3] for x in *a, *b, *c: result.append(x) self.assertEqual(result, 3 * a) def test_try(self): ### try_stmt: 'try' ':' suite (except_clause ':' suite)+ ['else' ':' suite] ### | 'try' ':' suite 'finally' ':' suite ### except_clause: 'except' [expr ['as' NAME]] try: 1/0 except ZeroDivisionError: pass else: pass try: 1/0 except EOFError: pass except TypeError as msg: pass except: pass else: pass try: 1/0 except (EOFError, TypeError, ZeroDivisionError): pass try: 1/0 except (EOFError, TypeError, ZeroDivisionError) as msg: pass try: pass finally: pass with self.assertRaises(SyntaxError): compile("try:\n pass\nexcept Exception as a.b:\n pass", "?", "exec") compile("try:\n pass\nexcept Exception as a[b]:\n pass", "?", "exec") def test_try_star(self): ### try_stmt: 'try': suite (except_star_clause : suite) + ['else' ':' suite] ### except_star_clause: 'except*' expr ['as' NAME] try: 1/0 except* ZeroDivisionError: pass else: pass try: 1/0 except* EOFError: pass except* ZeroDivisionError as msg: pass else: pass try: 1/0 except* (EOFError, TypeError, ZeroDivisionError): pass try: 1/0 except* (EOFError, TypeError, ZeroDivisionError) as msg: pass try: pass finally: pass with self.assertRaises(SyntaxError): compile("try:\n pass\nexcept* Exception as a.b:\n pass", "?", "exec") compile("try:\n pass\nexcept* Exception as a[b]:\n pass", "?", "exec") compile("try:\n pass\nexcept*:\n pass", "?", "exec") def test_suite(self): # simple_stmt | NEWLINE INDENT NEWLINE* (stmt NEWLINE*)+ DEDENT if 1: pass if 1: pass if 1: # # # pass pass # pass # def test_test(self): ### and_test ('or' and_test)* ### and_test: not_test ('and' not_test)* ### not_test: 'not' not_test | comparison if not 1: pass if 1 and 1: pass if 1 or 1: pass if not not not 1: pass if not 1 and 1 and 1: pass if 1 and 1 or 1 and 1 and 1 or not 1 and 1: pass def test_comparison(self): ### comparison: expr (comp_op expr)* ### comp_op: '<'|'>'|'=='|'>='|'<='|'!='|'in'|'not' 'in'|'is'|'is' 'not' if 1: pass x = (1 == 1) if 1 == 1: pass if 1 != 1: pass if 1 < 1: pass if 1 > 1: pass if 1 <= 1: pass if 1 >= 1: pass if x is x: pass if x is not x: pass if 1 in (): pass if 1 not in (): pass if 1 < 1 > 1 == 1 >= 1 <= 1 != 1 in 1 not in x is x is not x: pass def test_comparison_is_literal(self): def check(test, msg): self.check_syntax_warning(test, msg) check('x is 1', '"is" with \'int\' literal') check('x is "thing"', '"is" with \'str\' literal') check('1 is x', '"is" with \'int\' literal') check('x is y is 1', '"is" with \'int\' literal') check('x is not 1', '"is not" with \'int\' literal') check('x is not (1, 2)', '"is not" with \'tuple\' literal') check('(1, 2) is not x', '"is not" with \'tuple\' literal') check('None is 1', '"is" with \'int\' literal') check('1 is None', '"is" with \'int\' literal') check('x == 3 is y', '"is" with \'int\' literal') check('x == "thing" is y', '"is" with \'str\' literal') with warnings.catch_warnings(): warnings.simplefilter('error', SyntaxWarning) compile('x is None', '', 'exec') compile('x is False', '', 'exec') compile('x is True', '', 'exec') compile('x is ...', '', 'exec') compile('None is x', '', 'exec') compile('False is x', '', 'exec') compile('True is x', '', 'exec') compile('... is x', '', 'exec') def test_warn_missed_comma(self): def check(test): self.check_syntax_warning(test, msg) msg=r'is not callable; perhaps you missed a comma\?' check('[(1, 2) (3, 4)]') check('[(x, y) (3, 4)]') check('[[1, 2] (3, 4)]') check('[{1, 2} (3, 4)]') check('[{1: 2} (3, 4)]') check('[[i for i in range(5)] (3, 4)]') check('[{i for i in range(5)} (3, 4)]') check('[(i for i in range(5)) (3, 4)]') check('[{i: i for i in range(5)} (3, 4)]') check('[f"{x}" (3, 4)]') check('[f"x={x}" (3, 4)]') check('["abc" (3, 4)]') check('[b"abc" (3, 4)]') check('[123 (3, 4)]') check('[12.3 (3, 4)]') check('[12.3j (3, 4)]') check('[None (3, 4)]') check('[True (3, 4)]') check('[... (3, 4)]') msg=r'is not subscriptable; perhaps you missed a comma\?' check('[{1, 2} [i, j]]') check('[{i for i in range(5)} [i, j]]') check('[(i for i in range(5)) [i, j]]') check('[(lambda x, y: x) [i, j]]') check('[123 [i, j]]') check('[12.3 [i, j]]') check('[12.3j [i, j]]') check('[None [i, j]]') check('[True [i, j]]') check('[... [i, j]]') msg=r'indices must be integers or slices, not tuple; perhaps you missed a comma\?' check('[(1, 2) [i, j]]') check('[(x, y) [i, j]]') check('[[1, 2] [i, j]]') check('[[i for i in range(5)] [i, j]]') check('[f"{x}" [i, j]]') check('[f"x={x}" [i, j]]') check('["abc" [i, j]]') check('[b"abc" [i, j]]') msg=r'indices must be integers or slices, not tuple;' check('[[1, 2] [3, 4]]') msg=r'indices must be integers or slices, not list;' check('[[1, 2] [[3, 4]]]') check('[[1, 2] [[i for i in range(5)]]]') msg=r'indices must be integers or slices, not set;' check('[[1, 2] [{3, 4}]]') check('[[1, 2] [{i for i in range(5)}]]') msg=r'indices must be integers or slices, not dict;' check('[[1, 2] [{3: 4}]]') check('[[1, 2] [{i: i for i in range(5)}]]') msg=r'indices must be integers or slices, not generator;' check('[[1, 2] [(i for i in range(5))]]') msg=r'indices must be integers or slices, not function;' check('[[1, 2] [(lambda x, y: x)]]') msg=r'indices must be integers or slices, not str;' check('[[1, 2] [f"{x}"]]') check('[[1, 2] [f"x={x}"]]') check('[[1, 2] ["abc"]]') msg=r'indices must be integers or slices, not' check('[[1, 2] [b"abc"]]') check('[[1, 2] [12.3]]') check('[[1, 2] [12.3j]]') check('[[1, 2] [None]]') check('[[1, 2] [...]]') with warnings.catch_warnings(): warnings.simplefilter('error', SyntaxWarning) compile('[(lambda x, y: x) (3, 4)]', '', 'exec') compile('[[1, 2] [i]]', '', 'exec') compile('[[1, 2] [0]]', '', 'exec') compile('[[1, 2] [True]]', '', 'exec') compile('[[1, 2] [1:2]]', '', 'exec') compile('[{(1, 2): 3} [i, j]]', '', 'exec') def test_binary_mask_ops(self): x = 1 & 1 x = 1 ^ 1 x = 1 | 1 def test_shift_ops(self): x = 1 << 1 x = 1 >> 1 x = 1 << 1 >> 1 def test_additive_ops(self): x = 1 x = 1 + 1 x = 1 - 1 - 1 x = 1 - 1 + 1 - 1 + 1 def test_multiplicative_ops(self): x = 1 * 1 x = 1 / 1 x = 1 % 1 x = 1 / 1 * 1 % 1 def test_unary_ops(self): x = +1 x = -1 x = ~1 x = ~1 ^ 1 & 1 | 1 & 1 ^ -1 x = -1*1/1 + 1*1 - ---1*1 def test_selectors(self): ### trailer: '(' [testlist] ')' | '[' subscript ']' | '.' NAME ### subscript: expr | [expr] ':' [expr] import sys, time c = sys.path[0] x = time.time() x = sys.modules['time'].time() a = '01234' c = a[0] c = a[-1] s = a[0:5] s = a[:5] s = a[0:] s = a[:] s = a[-5:] s = a[:-1] s = a[-4:-3] # A rough test of SF bug 1333982. https://bugs.python.org/issue1333982 # The testing here is fairly incomplete. # Test cases should include: commas with 1 and 2 colons d = {} d[1] = 1 d[1,] = 2 d[1,2] = 3 d[1,2,3] = 4 L = list(d) L.sort(key=lambda x: (type(x).__name__, x)) self.assertEqual(str(L), '[1, (1,), (1, 2), (1, 2, 3)]') def test_atoms(self): ### atom: '(' [testlist] ')' | '[' [testlist] ']' | '{' [dictsetmaker] '}' | NAME | NUMBER | STRING ### dictsetmaker: (test ':' test (',' test ':' test)* [',']) | (test (',' test)* [',']) x = (1) x = (1 or 2 or 3) x = (1 or 2 or 3, 2, 3) x = [] x = [1] x = [1 or 2 or 3] x = [1 or 2 or 3, 2, 3] x = [] x = {} x = {'one': 1} x = {'one': 1,} x = {'one' or 'two': 1 or 2} x = {'one': 1, 'two': 2} x = {'one': 1, 'two': 2,} x = {'one': 1, 'two': 2, 'three': 3, 'four': 4, 'five': 5, 'six': 6} x = {'one'} x = {'one', 1,} x = {'one', 'two', 'three'} x = {2, 3, 4,} x = x x = 'x' x = 123 ### exprlist: expr (',' expr)* [','] ### testlist: test (',' test)* [','] # These have been exercised enough above def test_classdef(self): # 'class' NAME ['(' [testlist] ')'] ':' suite class B: pass class B2(): pass class C1(B): pass class C2(B): pass class D(C1, C2, B): pass class C: def meth1(self): pass def meth2(self, arg): pass def meth3(self, a1, a2): pass # decorator: '@' namedexpr_test NEWLINE # decorators: decorator+ # decorated: decorators (classdef | funcdef) def class_decorator(x): return x @class_decorator class G: pass # Test expressions as decorators (PEP 614): @False or class_decorator class H: pass @d := class_decorator class I: pass @lambda c: class_decorator(c) class J: pass @[..., class_decorator, ...][1] class K: pass @class_decorator(class_decorator)(class_decorator) class L: pass @[class_decorator][0].__call__.__call__ class M: pass def test_dictcomps(self): # dictorsetmaker: ( (test ':' test (comp_for | # (',' test ':' test)* [','])) | # (test (comp_for | (',' test)* [','])) ) nums = [1, 2, 3] self.assertEqual({i:i+1 for i in nums}, {1: 2, 2: 3, 3: 4}) def test_listcomps(self): # list comprehension tests nums = [1, 2, 3, 4, 5] strs = ["Apple", "Banana", "Coconut"] spcs = [" Apple", " Banana ", "Coco nut "] self.assertEqual([s.strip() for s in spcs], ['Apple', 'Banana', 'Coco nut']) self.assertEqual([3 * x for x in nums], [3, 6, 9, 12, 15]) self.assertEqual([x for x in nums if x > 2], [3, 4, 5]) self.assertEqual([(i, s) for i in nums for s in strs], [(1, 'Apple'), (1, 'Banana'), (1, 'Coconut'), (2, 'Apple'), (2, 'Banana'), (2, 'Coconut'), (3, 'Apple'), (3, 'Banana'), (3, 'Coconut'), (4, 'Apple'), (4, 'Banana'), (4, 'Coconut'), (5, 'Apple'), (5, 'Banana'), (5, 'Coconut')]) self.assertEqual([(i, s) for i in nums for s in [f for f in strs if "n" in f]], [(1, 'Banana'), (1, 'Coconut'), (2, 'Banana'), (2, 'Coconut'), (3, 'Banana'), (3, 'Coconut'), (4, 'Banana'), (4, 'Coconut'), (5, 'Banana'), (5, 'Coconut')]) self.assertEqual([(lambda a:[a**i for i in range(a+1)])(j) for j in range(5)], [[1], [1, 1], [1, 2, 4], [1, 3, 9, 27], [1, 4, 16, 64, 256]]) def test_in_func(l): return [0 < x < 3 for x in l if x > 2] self.assertEqual(test_in_func(nums), [False, False, False]) def test_nested_front(): self.assertEqual([[y for y in [x, x + 1]] for x in [1,3,5]], [[1, 2], [3, 4], [5, 6]]) test_nested_front() check_syntax_error(self, "[i, s for i in nums for s in strs]") check_syntax_error(self, "[x if y]") suppliers = [ (1, "Boeing"), (2, "Ford"), (3, "Macdonalds") ] parts = [ (10, "Airliner"), (20, "Engine"), (30, "Cheeseburger") ] suppart = [ (1, 10), (1, 20), (2, 20), (3, 30) ] x = [ (sname, pname) for (sno, sname) in suppliers for (pno, pname) in parts for (sp_sno, sp_pno) in suppart if sno == sp_sno and pno == sp_pno ] self.assertEqual(x, [('Boeing', 'Airliner'), ('Boeing', 'Engine'), ('Ford', 'Engine'), ('Macdonalds', 'Cheeseburger')]) def test_genexps(self): # generator expression tests g = ([x for x in range(10)] for x in range(1)) self.assertEqual(next(g), [x for x in range(10)]) try: next(g) self.fail('should produce StopIteration exception') except StopIteration: pass a = 1 try: g = (a for d in a) next(g) self.fail('should produce TypeError') except TypeError: pass self.assertEqual(list((x, y) for x in 'abcd' for y in 'abcd'), [(x, y) for x in 'abcd' for y in 'abcd']) self.assertEqual(list((x, y) for x in 'ab' for y in 'xy'), [(x, y) for x in 'ab' for y in 'xy']) a = [x for x in range(10)] b = (x for x in (y for y in a)) self.assertEqual(sum(b), sum([x for x in range(10)])) self.assertEqual(sum(x**2 for x in range(10)), sum([x**2 for x in range(10)])) self.assertEqual(sum(x*x for x in range(10) if x%2), sum([x*x for x in range(10) if x%2])) self.assertEqual(sum(x for x in (y for y in range(10))), sum([x for x in range(10)])) self.assertEqual(sum(x for x in (y for y in (z for z in range(10)))), sum([x for x in range(10)])) self.assertEqual(sum(x for x in [y for y in (z for z in range(10))]), sum([x for x in range(10)])) self.assertEqual(sum(x for x in (y for y in (z for z in range(10) if True)) if True), sum([x for x in range(10)])) self.assertEqual(sum(x for x in (y for y in (z for z in range(10) if True) if False) if True), 0) check_syntax_error(self, "foo(x for x in range(10), 100)") check_syntax_error(self, "foo(100, x for x in range(10))") def test_comprehension_specials(self): # test for outmost iterable precomputation x = 10; g = (i for i in range(x)); x = 5 self.assertEqual(len(list(g)), 10) # This should hold, since we're only precomputing outmost iterable. x = 10; t = False; g = ((i,j) for i in range(x) if t for j in range(x)) x = 5; t = True; self.assertEqual([(i,j) for i in range(10) for j in range(5)], list(g)) # Grammar allows multiple adjacent 'if's in listcomps and genexps, # even though it's silly. Make sure it works (ifelse broke this.) self.assertEqual([ x for x in range(10) if x % 2 if x % 3 ], [1, 5, 7]) self.assertEqual(list(x for x in range(10) if x % 2 if x % 3), [1, 5, 7]) # verify unpacking single element tuples in listcomp/genexp. self.assertEqual([x for x, in [(4,), (5,), (6,)]], [4, 5, 6]) self.assertEqual(list(x for x, in [(7,), (8,), (9,)]), [7, 8, 9]) def test_with_statement(self): class manager(object): def __enter__(self): return (1, 2) def __exit__(self, *args): pass with manager(): pass with manager() as x: pass with manager() as (x, y): pass with manager(), manager(): pass with manager() as x, manager() as y: pass with manager() as x, manager(): pass with ( manager() ): pass with ( manager() as x ): pass with ( manager() as (x, y), manager() as z, ): pass with ( manager(), manager() ): pass with ( manager() as x, manager() as y ): pass with ( manager() as x, manager() ): pass with ( manager() as x, manager() as y, manager() as z, ): pass with ( manager() as x, manager() as y, manager(), ): pass def test_if_else_expr(self): # Test ifelse expressions in various cases def _checkeval(msg, ret): "helper to check that evaluation of expressions is done correctly" print(msg) return ret # the next line is not allowed anymore #self.assertEqual([ x() for x in lambda: True, lambda: False if x() ], [True]) self.assertEqual([ x() for x in (lambda: True, lambda: False) if x() ], [True]) self.assertEqual([ x(False) for x in (lambda x: False if x else True, lambda x: True if x else False) if x(False) ], [True]) self.assertEqual((5 if 1 else _checkeval("check 1", 0)), 5) self.assertEqual((_checkeval("check 2", 0) if 0 else 5), 5) self.assertEqual((5 and 6 if 0 else 1), 1) self.assertEqual(((5 and 6) if 0 else 1), 1) self.assertEqual((5 and (6 if 1 else 1)), 6) self.assertEqual((0 or _checkeval("check 3", 2) if 0 else 3), 3) self.assertEqual((1 or _checkeval("check 4", 2) if 1 else _checkeval("check 5", 3)), 1) self.assertEqual((0 or 5 if 1 else _checkeval("check 6", 3)), 5) self.assertEqual((not 5 if 1 else 1), False) self.assertEqual((not 5 if 0 else 1), 1) self.assertEqual((6 + 1 if 1 else 2), 7) self.assertEqual((6 - 1 if 1 else 2), 5) self.assertEqual((6 * 2 if 1 else 4), 12) self.assertEqual((6 / 2 if 1 else 3), 3) self.assertEqual((6 < 4 if 0 else 2), 2) def test_paren_evaluation(self): self.assertEqual(16 // (4 // 2), 8) self.assertEqual((16 // 4) // 2, 2) self.assertEqual(16 // 4 // 2, 2) x = 2 y = 3 self.assertTrue(False is (x is y)) self.assertFalse((False is x) is y) self.assertFalse(False is x is y) def test_matrix_mul(self): # This is not intended to be a comprehensive test, rather just to be few # samples of the @ operator in test_grammar.py. class M: def __matmul__(self, o): return 4 def __imatmul__(self, o): self.other = o return self m = M() self.assertEqual(m @ m, 4) m @= 42 self.assertEqual(m.other, 42) def test_async_await(self): async def test(): def sum(): pass if 1: await someobj() self.assertEqual(test.__name__, 'test') self.assertTrue(bool(test.__code__.co_flags & inspect.CO_COROUTINE)) def decorator(func): setattr(func, '_marked', True) return func @decorator async def test2(): return 22 self.assertTrue(test2._marked) self.assertEqual(test2.__name__, 'test2') self.assertTrue(bool(test2.__code__.co_flags & inspect.CO_COROUTINE)) def test_async_for(self): class Done(Exception): pass class AIter: def __aiter__(self): return self async def __anext__(self): raise StopAsyncIteration async def foo(): async for i in AIter(): pass async for i, j in AIter(): pass async for i in AIter(): pass else: pass raise Done with self.assertRaises(Done): foo().send(None) def test_async_with(self): class Done(Exception): pass class manager: async def __aenter__(self): return (1, 2) async def __aexit__(self, *exc): return False async def foo(): async with manager(): pass async with manager() as x: pass async with manager() as (x, y): pass async with manager(), manager(): pass async with manager() as x, manager() as y: pass async with manager() as x, manager(): pass raise Done with self.assertRaises(Done): foo().send(None) if __name__ == '__main__': unittest.main()