# Test various flavors of legal and illegal future statements

import __future__
import ast
import unittest
from test import support
from test.support import import_helper
from textwrap import dedent
import os
import re
import sys

rx = re.compile(r'\((\S+).py, line (\d+)')

def get_error_location(msg):
    mo = rx.search(str(msg))
    return mo.group(1, 2)

class FutureTest(unittest.TestCase):

    def check_syntax_error(self, err, basename, lineno, offset=1):
        self.assertIn('%s.py, line %d' % (basename, lineno), str(err))
        self.assertEqual(os.path.basename(err.filename), basename + '.py')
        self.assertEqual(err.lineno, lineno)
        self.assertEqual(err.offset, offset)

    def test_future1(self):
        with import_helper.CleanImport('test.test_future_stmt.future_test1'):
            from test.test_future_stmt import future_test1
            self.assertEqual(future_test1.result, 6)

    def test_future2(self):
        with import_helper.CleanImport('test.test_future_stmt.future_test2'):
            from test.test_future_stmt import future_test2
            self.assertEqual(future_test2.result, 6)

    def test_future_single_import(self):
        with import_helper.CleanImport(
            'test.test_future_stmt.test_future_single_import',
        ):
            from test.test_future_stmt import test_future_single_import

    def test_future_multiple_imports(self):
        with import_helper.CleanImport(
            'test.test_future_stmt.test_future_multiple_imports',
        ):
            from test.test_future_stmt import test_future_multiple_imports

    def test_future_multiple_features(self):
        with import_helper.CleanImport(
            "test.test_future_stmt.test_future_multiple_features",
        ):
            from test.test_future_stmt import test_future_multiple_features

    def test_badfuture3(self):
        with self.assertRaises(SyntaxError) as cm:
            from test.test_future_stmt import badsyntax_future3
        self.check_syntax_error(cm.exception, "badsyntax_future3", 3)

    def test_badfuture4(self):
        with self.assertRaises(SyntaxError) as cm:
            from test.test_future_stmt import badsyntax_future4
        self.check_syntax_error(cm.exception, "badsyntax_future4", 3)

    def test_badfuture5(self):
        with self.assertRaises(SyntaxError) as cm:
            from test.test_future_stmt import badsyntax_future5
        self.check_syntax_error(cm.exception, "badsyntax_future5", 4)

    def test_badfuture6(self):
        with self.assertRaises(SyntaxError) as cm:
            from test.test_future_stmt import badsyntax_future6
        self.check_syntax_error(cm.exception, "badsyntax_future6", 3)

    def test_badfuture7(self):
        with self.assertRaises(SyntaxError) as cm:
            from test.test_future_stmt import badsyntax_future7
        self.check_syntax_error(cm.exception, "badsyntax_future7", 3, 53)

    def test_badfuture8(self):
        with self.assertRaises(SyntaxError) as cm:
            from test.test_future_stmt import badsyntax_future8
        self.check_syntax_error(cm.exception, "badsyntax_future8", 3)

    def test_badfuture9(self):
        with self.assertRaises(SyntaxError) as cm:
            from test.test_future_stmt import badsyntax_future9
        self.check_syntax_error(cm.exception, "badsyntax_future9", 3)

    def test_badfuture10(self):
        with self.assertRaises(SyntaxError) as cm:
            from test.test_future_stmt import badsyntax_future10
        self.check_syntax_error(cm.exception, "badsyntax_future10", 3)

    def test_ensure_flags_dont_clash(self):
        # bpo-39562: test that future flags and compiler flags doesn't clash

        # obtain future flags (CO_FUTURE_***) from the __future__ module
        flags = {
            f"CO_FUTURE_{future.upper()}": getattr(__future__, future).compiler_flag
            for future in __future__.all_feature_names
        }
        # obtain some of the exported compiler flags (PyCF_***) from the ast module
        flags |= {
            flag: getattr(ast, flag)
            for flag in dir(ast) if flag.startswith("PyCF_")
        }
        self.assertCountEqual(set(flags.values()), flags.values())

    def test_parserhack(self):
        # test that the parser.c::future_hack function works as expected
        # Note: although this test must pass, it's not testing the original
        #       bug as of 2.6 since the with statement is not optional and
        #       the parser hack disabled. If a new keyword is introduced in
        #       2.6, change this to refer to the new future import.
        try:
            exec("from __future__ import print_function; print 0")
        except SyntaxError:
            pass
        else:
            self.fail("syntax error didn't occur")

        try:
            exec("from __future__ import (print_function); print 0")
        except SyntaxError:
            pass
        else:
            self.fail("syntax error didn't occur")

    def test_unicode_literals_exec(self):
        scope = {}
        exec("from __future__ import unicode_literals; x = ''", {}, scope)
        self.assertIsInstance(scope["x"], str)

class AnnotationsFutureTestCase(unittest.TestCase):
    template = dedent(
        """
        from __future__ import annotations
        def f() -> {ann}:
            ...
        def g(arg: {ann}) -> None:
            ...
        async def f2() -> {ann}:
            ...
        async def g2(arg: {ann}) -> None:
            ...
        class H:
            var: {ann}
            object.attr: {ann}
        var: {ann}
        var2: {ann} = None
        object.attr: {ann}
        """
    )

    def getActual(self, annotation):
        scope = {}
        exec(self.template.format(ann=annotation), {}, scope)
        func_ret_ann = scope['f'].__annotations__['return']
        func_arg_ann = scope['g'].__annotations__['arg']
        async_func_ret_ann = scope['f2'].__annotations__['return']
        async_func_arg_ann = scope['g2'].__annotations__['arg']
        var_ann1 = scope['__annotations__']['var']
        var_ann2 = scope['__annotations__']['var2']
        self.assertEqual(func_ret_ann, func_arg_ann)
        self.assertEqual(func_ret_ann, async_func_ret_ann)
        self.assertEqual(func_ret_ann, async_func_arg_ann)
        self.assertEqual(func_ret_ann, var_ann1)
        self.assertEqual(func_ret_ann, var_ann2)
        return func_ret_ann

    def assertAnnotationEqual(
        self, annotation, expected=None, drop_parens=False, is_tuple=False,
    ):
        actual = self.getActual(annotation)
        if expected is None:
            expected = annotation if not is_tuple else annotation[1:-1]
        if drop_parens:
            self.assertNotEqual(actual, expected)
            actual = actual.replace("(", "").replace(")", "")

        self.assertEqual(actual, expected)

    def _exec_future(self, code):
        scope = {}
        exec(
            "from __future__ import annotations\n"
            + code, scope
        )
        return scope

    def test_annotations(self):
        eq = self.assertAnnotationEqual
        eq('...')
        eq("'some_string'")
        eq("u'some_string'")
        eq("b'\\xa3'")
        eq('Name')
        eq('None')
        eq('True')
        eq('False')
        eq('1')
        eq('1.0')
        eq('1j')
        eq('True or False')
        eq('True or False or None')
        eq('True and False')
        eq('True and False and None')
        eq('Name1 and Name2 or Name3')
        eq('Name1 and (Name2 or Name3)')
        eq('Name1 or Name2 and Name3')
        eq('(Name1 or Name2) and Name3')
        eq('Name1 and Name2 or Name3 and Name4')
        eq('Name1 or Name2 and Name3 or Name4')
        eq('a + b + (c + d)')
        eq('a * b * (c * d)')
        eq('(a ** b) ** c ** d')
        eq('v1 << 2')
        eq('1 >> v2')
        eq('1 % finished')
        eq('1 + v2 - v3 * 4 ^ 5 ** v6 / 7 // 8')
        eq('not great')
        eq('not not great')
        eq('~great')
        eq('+value')
        eq('++value')
        eq('-1')
        eq('~int and not v1 ^ 123 + v2 | True')
        eq('a + (not b)')
        eq('lambda: None')
        eq('lambda arg: None')
        eq('lambda a=True: a')
        eq('lambda a, b, c=True: a')
        eq("lambda a, b, c=True, *, d=1 << v2, e='str': a")
        eq("lambda a, b, c=True, *vararg, d, e='str', **kwargs: a + b")
        eq("lambda a, /, b, c=True, *vararg, d, e='str', **kwargs: a + b")
        eq('lambda x, /: x')
        eq('lambda x=1, /: x')
        eq('lambda x, /, y: x + y')
        eq('lambda x=1, /, y=2: x + y')
        eq('lambda x, /, y=1: x + y')
        eq('lambda x, /, y=1, *, z=3: x + y + z')
        eq('lambda x=1, /, y=2, *, z=3: x + y + z')
        eq('lambda x=1, /, y=2, *, z: x + y + z')
        eq('lambda x=1, y=2, z=3, /, w=4, *, l, l2: x + y + z + w + l + l2')
        eq('lambda x=1, y=2, z=3, /, w=4, *, l, l2, **kwargs: x + y + z + w + l + l2')
        eq('lambda x, /, y=1, *, z: x + y + z')
        eq('lambda x: lambda y: x + y')
        eq('1 if True else 2')
        eq('str or None if int or True else str or bytes or None')
        eq('str or None if (1 if True else 2) else str or bytes or None')
        eq("0 if not x else 1 if x > 0 else -1")
        eq("(1 if x > 0 else -1) if x else 0")
        eq("{'2.7': dead, '3.7': long_live or die_hard}")
        eq("{'2.7': dead, '3.7': long_live or die_hard, **{'3.6': verygood}}")
        eq("{**a, **b, **c}")
        eq("{'2.7', '3.6', '3.7', '3.8', '3.9', '4.0' if gilectomy else '3.10'}")
        eq("{*a, *b, *c}")
        eq("({'a': 'b'}, True or False, +value, 'string', b'bytes') or None")
        eq("()")
        eq("(a,)")
        eq("(a, b)")
        eq("(a, b, c)")
        eq("(*a, *b, *c)")
        eq("[]")
        eq("[1, 2, 3, 4, 5, 6, 7, 8, 9, 10 or A, 11 or B, 12 or C]")
        eq("[*a, *b, *c]")
        eq("{i for i in (1, 2, 3)}")
        eq("{i ** 2 for i in (1, 2, 3)}")
        eq("{i ** 2 for i, _ in ((1, 'a'), (2, 'b'), (3, 'c'))}")
        eq("{i ** 2 + j for i in (1, 2, 3) for j in (1, 2, 3)}")
        eq("[i for i in (1, 2, 3)]")
        eq("[i ** 2 for i in (1, 2, 3)]")
        eq("[i ** 2 for i, _ in ((1, 'a'), (2, 'b'), (3, 'c'))]")
        eq("[i ** 2 + j for i in (1, 2, 3) for j in (1, 2, 3)]")
        eq("(i for i in (1, 2, 3))")
        eq("(i ** 2 for i in (1, 2, 3))")
        eq("(i ** 2 for i, _ in ((1, 'a'), (2, 'b'), (3, 'c')))")
        eq("(i ** 2 + j for i in (1, 2, 3) for j in (1, 2, 3))")
        eq("{i: 0 for i in (1, 2, 3)}")
        eq("{i: j for i, j in ((1, 'a'), (2, 'b'), (3, 'c'))}")
        eq("[(x, y) for x, y in (a, b)]")
        eq("[(x,) for x, in (a,)]")
        eq("Python3 > Python2 > COBOL")
        eq("Life is Life")
        eq("call()")
        eq("call(arg)")
        eq("call(kwarg='hey')")
        eq("call(arg, kwarg='hey')")
        eq("call(arg, *args, another, kwarg='hey')")
        eq("call(arg, another, kwarg='hey', **kwargs, kwarg2='ho')")
        eq("lukasz.langa.pl")
        eq("call.me(maybe)")
        eq("1 .real")
        eq("1.0.real")
        eq("....__class__")
        eq("list[str]")
        eq("dict[str, int]")
        eq("set[str,]")
        eq("tuple[()]")
        eq("tuple[str, ...]")
        eq("tuple[str, *types]")
        eq("tuple[str, int, (str, int)]")
        eq("tuple[*int, str, str, (str, int)]")
        eq("tuple[str, int, float, dict[str, int]]")
        eq("slice[0]")
        eq("slice[0:1]")
        eq("slice[0:1:2]")
        eq("slice[:]")
        eq("slice[:-1]")
        eq("slice[1:]")
        eq("slice[::-1]")
        eq("slice[:,]")
        eq("slice[1:2,]")
        eq("slice[1:2:3,]")
        eq("slice[1:2, 1]")
        eq("slice[1:2, 2, 3]")
        eq("slice[()]")
        # Note that `slice[*Ts]`, `slice[*Ts,]`, and `slice[(*Ts,)]` all have
        # the same AST, but only `slice[*Ts,]` passes this test, because that's
        # what the unparser produces.
        eq("slice[*Ts,]")
        eq("slice[1, *Ts]")
        eq("slice[*Ts, 2]")
        eq("slice[1, *Ts, 2]")
        eq("slice[*Ts, *Ts]")
        eq("slice[1, *Ts, *Ts]")
        eq("slice[*Ts, 1, *Ts]")
        eq("slice[*Ts, *Ts, 1]")
        eq("slice[1, *Ts, *Ts, 2]")
        eq("slice[1:2, *Ts]")
        eq("slice[*Ts, 1:2]")
        eq("slice[1:2, *Ts, 3:4]")
        eq("slice[a, b:c, d:e:f]")
        eq("slice[(x for x in a)]")
        eq('str or None if sys.version_info[0] > (3,) else str or bytes or None')
        eq("f'f-string without formatted values is just a string'")
        eq("f'{{NOT a formatted value}}'")
        eq("f'some f-string with {a} {few():.2f} {formatted.values!r}'")
        eq('''f"{f'{nested} inner'} outer"''')
        eq("f'space between opening braces: { {a for a in (1, 2, 3)}}'")
        eq("f'{(lambda x: x)}'")
        eq("f'{(None if a else lambda x: x)}'")
        eq("f'{x}'")
        eq("f'{x!r}'")
        eq("f'{x!a}'")
        eq('[x for x in (a if b else c)]')
        eq('[x for x in a if (b if c else d)]')
        eq('f(x for x in a)')
        eq('f(1, (x for x in a))')
        eq('f((x for x in a), 2)')
        eq('(((a)))', 'a')
        eq('(((a, b)))', '(a, b)')
        eq("1 + 2 + 3")

    def test_fstring_debug_annotations(self):
        # f-strings with '=' don't round trip very well, so set the expected
        # result explicitly.
        self.assertAnnotationEqual("f'{x=!r}'", expected="f'x={x!r}'")
        self.assertAnnotationEqual("f'{x=:}'", expected="f'x={x:}'")
        self.assertAnnotationEqual("f'{x=:.2f}'", expected="f'x={x:.2f}'")
        self.assertAnnotationEqual("f'{x=!r}'", expected="f'x={x!r}'")
        self.assertAnnotationEqual("f'{x=!a}'", expected="f'x={x!a}'")
        self.assertAnnotationEqual("f'{x=!s:*^20}'", expected="f'x={x!s:*^20}'")

    def test_infinity_numbers(self):
        inf = "1e" + repr(sys.float_info.max_10_exp + 1)
        infj = f"{inf}j"
        self.assertAnnotationEqual("1e1000", expected=inf)
        self.assertAnnotationEqual("1e1000j", expected=infj)
        self.assertAnnotationEqual("-1e1000", expected=f"-{inf}")
        self.assertAnnotationEqual("3+1e1000j", expected=f"3 + {infj}")
        self.assertAnnotationEqual("(1e1000, 1e1000j)", expected=f"({inf}, {infj})")
        self.assertAnnotationEqual("'inf'")
        self.assertAnnotationEqual("('inf', 1e1000, 'infxxx', 1e1000j)", expected=f"('inf', {inf}, 'infxxx', {infj})")
        self.assertAnnotationEqual("(1e1000, (1e1000j,))", expected=f"({inf}, ({infj},))")

    def test_annotation_with_complex_target(self):
        with self.assertRaises(SyntaxError):
            exec(
                "from __future__ import annotations\n"
                "object.__debug__: int"
            )

    def test_annotations_symbol_table_pass(self):
        namespace = self._exec_future(dedent("""
        from __future__ import annotations

        def foo():
            outer = 1
            def bar():
                inner: outer = 1
            return bar
        """))

        foo = namespace.pop("foo")
        self.assertIsNone(foo().__closure__)
        self.assertEqual(foo.__code__.co_cellvars, ())
        self.assertEqual(foo().__code__.co_freevars, ())

    def test_annotations_forbidden(self):
        with self.assertRaises(SyntaxError):
            self._exec_future("test: (yield)")

        with self.assertRaises(SyntaxError):
            self._exec_future("test.test: (yield a + b)")

        with self.assertRaises(SyntaxError):
            self._exec_future("test[something]: (yield from x)")

        with self.assertRaises(SyntaxError):
            self._exec_future("def func(test: (yield from outside_of_generator)): pass")

        with self.assertRaises(SyntaxError):
            self._exec_future("def test() -> (await y): pass")

        with self.assertRaises(SyntaxError):
            self._exec_future("async def test() -> something((a := b)): pass")

        with self.assertRaises(SyntaxError):
            self._exec_future("test: await some.complicated[0].call(with_args=True or 1 is not 1)")

        with self.assertRaises(SyntaxError):
            self._exec_future("test: f'{(x := 10):=10}'")

        with self.assertRaises(SyntaxError):
            self._exec_future(dedent("""\
            def foo():
                def bar(arg: (yield)): pass
            """))

    def test_get_type_hints_on_func_with_variadic_arg(self):
        # `typing.get_type_hints` might break on a function with a variadic
        # annotation (e.g. `f(*args: *Ts)`) if `from __future__ import
        # annotations`, because it could try to evaluate `*Ts` as an expression,
        # which on its own isn't value syntax.
        namespace = self._exec_future(dedent("""\
        class StarredC: pass
        class C:
          def __iter__(self):
            yield StarredC()
        c = C()
        def f(*args: *c): pass
        import typing
        hints = typing.get_type_hints(f)
        """))

        hints = namespace.pop('hints')
        self.assertIsInstance(hints['args'], namespace['StarredC'])


if __name__ == "__main__":
    unittest.main()