path: root/Lib/test/test_descr.py

import builtins
import copyreg
import gc
import itertools
import math
import pickle
import sys
import types
import unittest
import warnings
import weakref

from copy import deepcopy
from test import support


class OperatorsTest(unittest.TestCase):

    def __init__(self, *args, **kwargs):
        unittest.TestCase.__init__(self, *args, **kwargs)
        self.binops = {
            'add': '+',
            'sub': '-',
            'mul': '*',
            'matmul': '@',
            'truediv': '/',
            'floordiv': '//',
            'divmod': 'divmod',
            'pow': '**',
            'lshift': '<<',
            'rshift': '>>',
            'and': '&',
            'xor': '^',
            'or': '|',
            'cmp': 'cmp',
            'lt': '<',
            'le': '<=',
            'eq': '==',
            'ne': '!=',
            'gt': '>',
            'ge': '>=',
        }

        for name, expr in list(self.binops.items()):
            if expr.islower():
                expr = expr + "(a, b)"
            else:
                expr = 'a %s b' % expr
            self.binops[name] = expr

        self.unops = {
            'pos': '+',
            'neg': '-',
            'abs': 'abs',
            'invert': '~',
            'int': 'int',
            'float': 'float',
        }

        for name, expr in list(self.unops.items()):
            if expr.islower():
                expr = expr + "(a)"
            else:
                expr = '%s a' % expr
            self.unops[name] = expr

    def unop_test(self, a, res, expr="len(a)", meth="__len__"):
        d = {'a': a}
        self.assertEqual(eval(expr, d), res)
        t = type(a)
        m = getattr(t, meth)

        # Find method in parent class
        while meth not in t.__dict__:
            t = t.__bases__[0]
        # in some implementations (e.g. PyPy), 'm' can be a regular unbound
        # method object; the getattr() below obtains its underlying function.
        self.assertEqual(getattr(m, 'im_func', m), t.__dict__[meth])
        self.assertEqual(m(a), res)
        bm = getattr(a, meth)
        self.assertEqual(bm(), res)

    def binop_test(self, a, b, res, expr="a+b", meth="__add__"):
        d = {'a': a, 'b': b}

        self.assertEqual(eval(expr, d), res)
        t = type(a)
        m = getattr(t, meth)
        while meth not in t.__dict__:
            t = t.__bases__[0]
        # in some implementations (e.g. PyPy), 'm' can be a regular unbound
        # method object; the getattr() below obtains its underlying function.
        self.assertEqual(getattr(m, 'im_func', m), t.__dict__[meth])
        self.assertEqual(m(a, b), res)
        bm = getattr(a, meth)
        self.assertEqual(bm(b), res)

    def sliceop_test(self, a, b, c, res, expr="a[b:c]", meth="__getitem__"):
        d = {'a': a, 'b': b, 'c': c}
        self.assertEqual(eval(expr, d), res)
        t = type(a)
        m = getattr(t, meth)
        while meth not in t.__dict__:
            t = t.__bases__[0]
        # in some implementations (e.g. PyPy), 'm' can be a regular unbound
        # method object; the getattr() below obtains its underlying function.
        self.assertEqual(getattr(m, 'im_func', m), t.__dict__[meth])
        self.assertEqual(m(a, slice(b, c)), res)
        bm = getattr(a, meth)
        self.assertEqual(bm(slice(b, c)), res)

    def setop_test(self, a, b, res, stmt="a+=b", meth="__iadd__"):
        d = {'a': deepcopy(a), 'b': b}
        exec(stmt, d)
        self.assertEqual(d['a'], res)
        t = type(a)
        m = getattr(t, meth)
        while meth not in t.__dict__:
            t = t.__bases__[0]
        # in some implementations (e.g. PyPy), 'm' can be a regular unbound
        # method object; the getattr() below obtains its underlying function.
        self.assertEqual(getattr(m, 'im_func', m), t.__dict__[meth])
        d['a'] = deepcopy(a)
        m(d['a'], b)
        self.assertEqual(d['a'], res)
        d['a'] = deepcopy(a)
        bm = getattr(d['a'], meth)
        bm(b)
        self.assertEqual(d['a'], res)

    def set2op_test(self, a, b, c, res, stmt="a[b]=c", meth="__setitem__"):
        d = {'a': deepcopy(a), 'b': b, 'c': c}
        exec(stmt, d)
        self.assertEqual(d['a'], res)
        t = type(a)
        m = getattr(t, meth)
        while meth not in t.__dict__:
            t = t.__bases__[0]
        # in some implementations (e.g. PyPy), 'm' can be a regular unbound
        # method object; the getattr() below obtains its underlying function.
        self.assertEqual(getattr(m, 'im_func', m), t.__dict__[meth])
        d['a'] = deepcopy(a)
        m(d['a'], b, c)
        self.assertEqual(d['a'], res)
        d['a'] = deepcopy(a)
        bm = getattr(d['a'], meth)
        bm(b, c)
        self.assertEqual(d['a'], res)

    def setsliceop_test(self, a, b, c, d, res, stmt="a[b:c]=d", meth="__setitem__"):
        dictionary = {'a': deepcopy(a), 'b': b, 'c': c, 'd': d}
        exec(stmt, dictionary)
        self.assertEqual(dictionary['a'], res)
        t = type(a)
        while meth not in t.__dict__:
            t = t.__bases__[0]
        m = getattr(t, meth)
        # in some implementations (e.g. PyPy), 'm' can be a regular unbound
        # method object; the getattr() below obtains its underlying function.
        self.assertEqual(getattr(m, 'im_func', m), t.__dict__[meth])
        dictionary['a'] = deepcopy(a)
        m(dictionary['a'], slice(b, c), d)
        self.assertEqual(dictionary['a'], res)
        dictionary['a'] = deepcopy(a)
        bm = getattr(dictionary['a'], meth)
        bm(slice(b, c), d)
        self.assertEqual(dictionary['a'], res)

    def test_lists(self):
        # Testing list operations...
        # Asserts are within individual test methods
        self.binop_test([1], [2], [1,2], "a+b", "__add__")
        self.binop_test([1,2,3], 2, 1, "b in a", "__contains__")
        self.binop_test([1,2,3], 4, 0, "b in a", "__contains__")
        self.binop_test([1,2,3], 1, 2, "a[b]", "__getitem__")
        self.sliceop_test([1,2,3], 0, 2, [1,2], "a[b:c]", "__getitem__")
        self.setop_test([1], [2], [1,2], "a+=b", "__iadd__")
        self.setop_test([1,2], 3, [1,2,1,2,1,2], "a*=b", "__imul__")
        self.unop_test([1,2,3], 3, "len(a)", "__len__")
        self.binop_test([1,2], 3, [1,2,1,2,1,2], "a*b", "__mul__")
        self.binop_test([1,2], 3, [1,2,1,2,1,2], "b*a", "__rmul__")
        self.set2op_test([1,2], 1, 3, [1,3], "a[b]=c", "__setitem__")
        self.setsliceop_test([1,2,3,4], 1, 3, [5,6], [1,5,6,4], "a[b:c]=d",
                        "__setitem__")

    def test_dicts(self):
        # Testing dict operations...
        self.binop_test({1:2,3:4}, 1, 1, "b in a", "__contains__")
        self.binop_test({1:2,3:4}, 2, 0, "b in a", "__contains__")
        self.binop_test({1:2,3:4}, 1, 2, "a[b]", "__getitem__")

        d = {1:2, 3:4}
        l1 = []
        for i in list(d.keys()):
            l1.append(i)
        l = []
        for i in iter(d):
            l.append(i)
        self.assertEqual(l, l1)
        l = []
        for i in d.__iter__():
            l.append(i)
        self.assertEqual(l, l1)
        l = []
        for i in dict.__iter__(d):
            l.append(i)
        self.assertEqual(l, l1)
        d = {1:2, 3:4}
        self.unop_test(d, 2, "len(a)", "__len__")
        self.assertEqual(eval(repr(d), {}), d)
        self.assertEqual(eval(d.__repr__(), {}), d)
        self.set2op_test({1:2,3:4}, 2, 3, {1:2,2:3,3:4}, "a[b]=c",
                        "__setitem__")

    # Tests for unary and binary operators
    def number_operators(self, a, b, skip=[]):
        dict = {'a': a, 'b': b}

        for name, expr in self.binops.items():
            if name not in skip:
                name = "__%s__" % name
                if hasattr(a, name):
                    res = eval(expr, dict)
                    self.binop_test(a, b, res, expr, name)

        for name, expr in list(self.unops.items()):
            if name not in skip:
                name = "__%s__" % name
                if hasattr(a, name):
                    res = eval(expr, dict)
                    self.unop_test(a, res, expr, name)

    def test_ints(self):
        # Testing int operations...
        self.number_operators(100, 3)
        # The following crashes in Python 2.2
        self.assertEqual((1).__bool__(), 1)
        self.assertEqual((0).__bool__(), 0)
        # This returns 'NotImplemented' in Python 2.2
        class C(int):
            def __add__(self, other):
                return NotImplemented
        self.assertEqual(C(5), 5)
        try:
            C() + ""
        except TypeError:
            pass
        else:
            self.fail("NotImplemented should have caused TypeError")

    def test_floats(self):
        # Testing float operations...
        self.number_operators(100.0, 3.0)

    def test_complexes(self):
        # Testing complex operations...
        self.number_operators(100.0j, 3.0j, skip=['lt', 'le', 'gt', 'ge',
                                                  'int', 'float',
                                                  'floordiv', 'divmod', 'mod'])

        class Number(complex):
            __slots__ = ['prec']
            def __new__(cls, *args, **kwds):
                result = complex.__new__(cls, *args)
                result.prec = kwds.get('prec', 12)
                return result
            def __repr__(self):
                prec = self.prec
                if self.imag == 0.0:
                    return "%.*g" % (prec, self.real)
                if self.real == 0.0:
                    return "%.*gj" % (prec, self.imag)
                return "(%.*g+%.*gj)" % (prec, self.real, prec, self.imag)
            __str__ = __repr__

        a = Number(3.14, prec=6)
        self.assertEqual(repr(a), "3.14")
        self.assertEqual(a.prec, 6)

        a = Number(a, prec=2)
        self.assertEqual(repr(a), "3.1")
        self.assertEqual(a.prec, 2)

        a = Number(234.5)
        self.assertEqual(repr(a), "234.5")
        self.assertEqual(a.prec, 12)

    def test_explicit_reverse_methods(self):
        # see issue 9930
        self.assertEqual(complex.__radd__(3j, 4.0), complex(4.0, 3.0))
        self.assertEqual(float.__rsub__(3.0, 1), -2.0)

    @support.impl_detail("the module 'xxsubtype' is internal")
    def test_spam_lists(self):
        # Testing spamlist operations...
        import copy, xxsubtype as spam

        def spamlist(l, memo=None):
            import xxsubtype as spam
            return spam.spamlist(l)

        # This is an ugly hack:
        copy._deepcopy_dispatch[spam.spamlist] = spamlist

        self.binop_test(spamlist([1]), spamlist([2]), spamlist([1,2]), "a+b",
                       "__add__")
        self.binop_test(spamlist([1,2,3]), 2, 1, "b in a", "__contains__")
        self.binop_test(spamlist([1,2,3]), 4, 0, "b in a", "__contains__")
        self.binop_test(spamlist([1,2,3]), 1, 2, "a[b]", "__getitem__")
        self.sliceop_test(spamlist([1,2,3]), 0, 2, spamlist([1,2]), "a[b:c]",
                          "__getitem__")
        self.setop_test(spamlist([1]), spamlist([2]), spamlist([1,2]), "a+=b",
                        "__iadd__")
        self.setop_test(spamlist([1,2]), 3, spamlist([1,2,1,2,1,2]), "a*=b",
                        "__imul__")
        self.unop_test(spamlist([1,2,3]), 3, "len(a)", "__len__")
        self.binop_test(spamlist([1,2]), 3, spamlist([1,2,1,2,1,2]), "a*b",
                        "__mul__")
        self.binop_test(spamlist([1,2]), 3, spamlist([1,2,1,2,1,2]), "b*a",
                        "__rmul__")
        self.set2op_test(spamlist([1,2]), 1, 3, spamlist([1,3]), "a[b]=c",
                         "__setitem__")
        self.setsliceop_test(spamlist([1,2,3,4]), 1, 3, spamlist([5,6]),
                             spamlist([1,5,6,4]), "a[b:c]=d", "__setitem__")
        # Test subclassing
        class C(spam.spamlist):
            def foo(self): return 1
        a = C()
        self.assertEqual(a, [])
        self.assertEqual(a.foo(), 1)
        a.append(100)
        self.assertEqual(a, [100])
        self.assertEqual(a.getstate(), 0)
        a.setstate(42)
        self.assertEqual(a.getstate(), 42)

    @support.impl_detail("the module 'xxsubtype' is internal")
    def test_spam_dicts(self):
        # Testing spamdict operations...
        import copy, xxsubtype as spam
        def spamdict(d, memo=None):
            import xxsubtype as spam
            sd = spam.spamdict()
            for k, v in list(d.items()):
                sd[k] = v
            return sd
        # This is an ugly hack:
        copy._deepcopy_dispatch[spam.spamdict] = spamdict

        self.binop_test(spamdict({1:2,3:4}), 1, 1, "b in a", "__contains__")
        self.binop_test(spamdict({1:2,3:4}), 2, 0, "b in a", "__contains__")
        self.binop_test(spamdict({1:2,3:4}), 1, 2, "a[b]", "__getitem__")
        d = spamdict({1:2,3:4})
        l1 = []
        for i in list(d.keys()):
            l1.append(i)
        l = []
        for i in iter(d):
            l.append(i)
        self.assertEqual(l, l1)
        l = []
        for i in d.__iter__():
            l.append(i)
        self.assertEqual(l, l1)
        l = []
        for i in type(spamdict({})).__iter__(d):
            l.append(i)
        self.assertEqual(l, l1)
        straightd = {1:2, 3:4}
        spamd = spamdict(straightd)
        self.unop_test(spamd, 2, "len(a)", "__len__")
        self.unop_test(spamd, repr(straightd), "repr(a)", "__repr__")
        self.set2op_test(spamdict({1:2,3:4}), 2, 3, spamdict({1:2,2:3,3:4}),
                   "a[b]=c", "__setitem__")
        # Test subclassing
        class C(spam.spamdict):
            def foo(self): return 1
        a = C()
        self.assertEqual(list(a.items()), [])
        self.assertEqual(a.foo(), 1)
        a['foo'] = 'bar'
        self.assertEqual(list(a.items()), [('foo', 'bar')])
        self.assertEqual(a.getstate(), 0)
        a.setstate(100)
        self.assertEqual(a.getstate(), 100)

class ClassPropertiesAndMethods(unittest.TestCase):

    def assertHasAttr(self, obj, name):
        self.assertTrue(hasattr(obj, name),
                        '%r has no attribute %r' % (obj, name))

    def assertNotHasAttr(self, obj, name):
        self.assertFalse(hasattr(obj, name),
                         '%r has unexpected attribute %r' % (obj, name))

    def test_python_dicts(self):
        # Testing Python subclass of dict...
        self.assertTrue(issubclass(dict, dict))
        self.assertIsInstance({}, dict)
        d = dict()
        self.assertEqual(d, {})
        self.assertIs(d.__class__, dict)
        self.assertIsInstance(d, dict)
        class C(dict):
            state = -1
            def __init__(self_local, *a, **kw):
                if a:
                    self.assertEqual(len(a), 1)
                    self_local.state = a[0]
                if kw:
                    for k, v in list(kw.items()):
                        self_local[v] = k
            def __getitem__(self, key):
                return self.get(key, 0)
            def __setitem__(self_local, key, value):
                self.assertIsInstance(key, type(0))
                dict.__setitem__(self_local, key, value)
            def setstate(self, state):
                self.state = state
            def getstate(self):
                return self.state
        self.assertTrue(issubclass(C, dict))
        a1 = C(12)
        self.assertEqual(a1.state, 12)
        a2 = C(foo=1, bar=2)
        self.assertEqual(a2[1] == 'foo' and a2[2], 'bar')
        a = C()
        self.assertEqual(a.state, -1)
        self.assertEqual(a.getstate(), -1)
        a.setstate(0)
        self.assertEqual(a.state, 0)
        self.assertEqual(a.getstate(), 0)
        a.setstate(10)
        self.assertEqual(a.state, 10)
        self.assertEqual(a.getstate(), 10)
        self.assertEqual(a[42], 0)
        a[42] = 24
        self.assertEqual(a[42], 24)
        N = 50
        for i in range(N):
            a[i] = C()
            for j in range(N):
                a[i][j] = i*j
        for i in range(N):
            for j in range(N):
                self.assertEqual(a[i][j], i*j)

    def test_python_lists(self):
        # Testing Python subclass of list...
        class C(list):
            def __getitem__(self, i):
                if isinstance(i, slice):
                    return i.start, i.stop
                return list.__getitem__(self, i) + 100
        a = C()
        a.extend([0,1,2])
        self.assertEqual(a[0], 100)
        self.assertEqual(a[1], 101)
        self.assertEqual(a[2], 102)
        self.assertEqual(a[100:200], (100,200))

    def test_metaclass(self):
        # Testing metaclasses...
        class C(metaclass=type):
            def __init__(self):
                self.__state = 0
            def getstate(self):
                return self.__state
            def setstate(self, state):
                self.__state = state
        a = C()
        self.assertEqual(a.getstate(), 0)
        a.setstate(10)
        self.assertEqual(a.getstate(), 10)
        class _metaclass(type):
            def myself(cls): return cls
        class D(metaclass=_metaclass):
            pass
        self.assertEqual(D.myself(), D)
        d = D()
        self.assertEqual(d.__class__, D)
        class M1(type):
            def __new__(cls, name, bases, dict):
                dict['__spam__'] = 1
                return type.__new__(cls, name, bases, dict)
        class C(metaclass=M1):
            pass
        self.assertEqual(C.__spam__, 1)
        c = C()
        self.assertEqual(c.__spam__, 1)

        class _instance(object):
            pass
        class M2(object):
            @staticmethod
            def __new__(cls, name, bases, dict):
                self = object.__new__(cls)
                self.name = name
                self.bases = bases
                self.dict = dict
                return self
            def __call__(self):
                it = _instance()
                # Early binding of methods
                for key in self.dict:
                    if key.startswith("__"):
                        continue
                    setattr(it, key, self.dict[key].__get__(it, self))
                return it
        class C(metaclass=M2):
            def spam(self):
                return 42
        self.assertEqual(C.name, 'C')
        self.assertEqual(C.bases, ())
        self.assertIn('spam', C.dict)
        c = C()
        self.assertEqual(c.spam(), 42)

        # More metaclass examples

        class autosuper(type):
            # Automatically add __super to the class
            # This trick only works for dynamic classes
            def __new__(metaclass, name, bases, dict):
                cls = super(autosuper, metaclass).__new__(metaclass,
                                                          name, bases, dict)
                # Name mangling for __super removes leading underscores
                while name[:1] == "_":
                    name = name[1:]
                if name:
                    name = "_%s__super" % name
                else:
                    name = "__super"
                setattr(cls, name, super(cls))
                return cls
        class A(metaclass=autosuper):
            def meth(self):
                return "A"
        class B(A):
            def meth(self):
                return "B" + self.__super.meth()
        class C(A):
            def meth(self):
                return "C" + self.__super.meth()
        class D(C, B):
            def meth(self):
                return "D" + self.__super.meth()
        self.assertEqual(D().meth(), "DCBA")
        class E(B, C):
            def meth(self):
                return "E" + self.__super.meth()
        self.assertEqual(E().meth(), "EBCA")

        class autoproperty(type):
            # Automatically create property attributes when methods
            # named _get_x and/or _set_x are found
            def __new__(metaclass, name, bases, dict):
                hits = {}
                for key, val in dict.items():
                    if key.startswith("_get_"):
                        key = key[5:]
                        get, set = hits.get(key, (None, None))
                        get = val
                        hits[key] = get, set
                    elif key.startswith("_set_"):
                        key = key[5:]
                        get, set = hits.get(key, (None, None))
                        set = val
                        hits[key] = get, set
                for key, (get, set) in hits.items():
                    dict[key] = property(get, set)
                return super(autoproperty, metaclass).__new__(metaclass,
                                                            name, bases, dict)
        class A(metaclass=autoproperty):
            def _get_x(self):
                return -self.__x
            def _set_x(self, x):
                self.__x = -x
        a = A()
        self.assertNotHasAttr(a, "x")
        a.x = 12
        self.assertEqual(a.x, 12)
        self.assertEqual(a._A__x, -12)

        class multimetaclass(autoproperty, autosuper):
            # Merge of multiple cooperating metaclasses
            pass
        class A(metaclass=multimetaclass):
            def _get_x(self):
                return "A"
        class B(A):
            def _get_x(self):
                return "B" + self.__super._get_x()
        class C(A):
            def _get_x(self):
                return "C" + self.__super._get_x()
        class D(C, B):
            def _get_x(self):
                return "D" + self.__super._get_x()
        self.assertEqual(D().x, "DCBA")

        # Make sure type(x) doesn't call x.__class__.__init__
        class T(type):
            counter = 0
            def __init__(self, *args):
                T.counter += 1
        class C(metaclass=T):
            pass
        self.assertEqual(T.counter, 1)
        a = C()
        self.assertEqual(type(a), C)
        self.assertEqual(T.counter, 1)

        class C(object): pass
        c = C()
        try: c()
        except TypeError: pass
        else: self.fail("calling object w/o call method should raise "
                        "TypeError")

        # Testing code to find most derived baseclass
        class A(type):
            def __new__(*args, **kwargs):
                return type.__new__(*args, **kwargs)

        class B(object):
            pass

        class C(object, metaclass=A):
            pass

        # The most derived metaclass of D is A rather than type.
        class D(B, C):
            pass
        self.assertIs(A, type(D))

        # issue1294232: correct metaclass calculation
        new_calls = []  # to check the order of __new__ calls
        class AMeta(type):
            @staticmethod
            def __new__(mcls, name, bases, ns):
                new_calls.append('AMeta')
                return super().__new__(mcls, name, bases, ns)
            @classmethod
            def __prepare__(mcls, name, bases):
                return {}

        class BMeta(AMeta):
            @staticmethod
            def __new__(mcls, name, bases, ns):
                new_calls.append('BMeta')
                return super().__new__(mcls, name, bases, ns)
            @classmethod
            def __prepare__(mcls, name, bases):
                ns = super().__prepare__(name, bases)
                ns['BMeta_was_here'] = True
                return ns

        class A(metaclass=AMeta):
            pass
        self.assertEqual(['AMeta'], new_calls)
        new_calls.clear()

        class B(metaclass=BMeta):
            pass
        # BMeta.__new__ calls AMeta.__new__ with super:
        self.assertEqual(['BMeta', 'AMeta'], new_calls)
        new_calls.clear()

        class C(A, B):
            pass
        # The most derived metaclass is BMeta:
        self.assertEqual(['BMeta', 'AMeta'], new_calls)
        new_calls.clear()
        # BMeta.__prepare__ should've been called:
        self.assertIn('BMeta_was_here', C.__dict__)

        # The order of the bases shouldn't matter:
        class C2(B, A):
            pass
        self.assertEqual(['BMeta', 'AMeta'], new_calls)
        new_calls.clear()
        self.assertIn('BMeta_was_here', C2.__dict__)

        # Check correct metaclass calculation when a metaclass is declared:
        class D(C, metaclass=type):
            pass
        self.assertEqual(['BMeta', 'AMeta'], new_calls)
        new_calls.clear()
        self.assertIn('BMeta_was_here', D.__dict__)

        class E(C, metaclass=AMeta):
            pass
        self.assertEqual(['BMeta', 'AMeta'], new_calls)
        new_calls.clear()
        self.assertIn('BMeta_was_here', E.__dict__)

        # Special case: the given metaclass isn't a class,
        # so there is no metaclass calculation.
        marker = object()
        def func(*args, **kwargs):
            return marker
        class X(metaclass=func):
            pass
        class Y(object, metaclass=func):
            pass
        class Z(D, metaclass=func):
            pass
        self.assertIs(marker, X)
        self.assertIs(marker, Y)
        self.assertIs(marker, Z)

        # The given metaclass is a class,
        # but not a descendant of type.
        prepare_calls = []  # to track __prepare__ calls
        class ANotMeta:
            def __new__(mcls, *args, **kwargs):
                new_calls.append('ANotMeta')
                return super().__new__(mcls)
            @classmethod
            def __prepare__(mcls, name, bases):
                prepare_calls.append('ANotMeta')
                return {}
        class BNotMeta(ANotMeta):
            def __new__(mcls, *args, **kwargs):
                new_calls.append('BNotMeta')
                return super().__new__(mcls)
            @classmethod
            def __prepare__(mcls, name, bases):
                prepare_calls.append('BNotMeta')
                return super().__prepare__(name, bases)

        class A(metaclass=ANotMeta):
            pass
        self.assertIs(ANotMeta, type(A))
        self.assertEqual(['ANotMeta'], prepare_calls)
        prepare_calls.clear()
        self.assertEqual(['ANotMeta'], new_calls)
        new_calls.clear()

        class B(metaclass=BNotMeta):
            pass
        self.assertIs(BNotMeta, type(B))
        self.assertEqual(['BNotMeta', 'ANotMeta'], prepare_calls)
        prepare_calls.clear()
        self.assertEqual(['BNotMeta', 'ANotMeta'], new_calls)
        new_calls.clear()

        class C(A, B):
            pass
        self.assertIs(BNotMeta, type(C))
        self.assertEqual(['BNotMeta', 'ANotMeta'], new_calls)
        new_calls.clear()
        self.assertEqual(['BNotMeta', 'ANotMeta'], prepare_calls)
        prepare_calls.clear()

        class C2(B, A):
            pass
        self.assertIs(BNotMeta, type(C2))
        self.assertEqual(['BNotMeta', 'ANotMeta'], new_calls)
        new_calls.clear()
        self.assertEqual(['BNotMeta', 'ANotMeta'], prepare_calls)
        prepare_calls.clear()

        # This is a TypeError, because of a metaclass conflict:
        # BNotMeta is neither a subclass, nor a superclass of type
        with self.assertRaises(TypeError):
            class D(C, metaclass=type):
                pass

        class E(C, metaclass=ANotMeta):
            pass
        self.assertIs(BNotMeta, type(E))
        self.assertEqual(['BNotMeta', 'ANotMeta'], new_calls)
        new_calls.clear()
        self.assertEqual(['BNotMeta', 'ANotMeta'], prepare_calls)
        prepare_calls.clear()

        class F(object(), C):
            pass
        self.assertIs(BNotMeta, type(F))
        self.assertEqual(['BNotMeta', 'ANotMeta'], new_calls)
        new_calls.clear()
        self.assertEqual(['BNotMeta', 'ANotMeta'], prepare_calls)
        prepare_calls.clear()

        class F2(C, object()):
            pass
        self.assertIs(BNotMeta, type(F2))
        self.assertEqual(['BNotMeta', 'ANotMeta'], new_calls)
        new_calls.clear()
        self.assertEqual(['BNotMeta', 'ANotMeta'], prepare_calls)
        prepare_calls.clear()

        # TypeError: BNotMeta is neither a
        # subclass, nor a superclass of int
        with self.assertRaises(TypeError):
            class X(C, int()):
                pass
        with self.assertRaises(TypeError):
            class X(int(), C):
                pass

    def test_module_subclasses(self):
        # Testing Python subclass of module...
        log = []
        MT = type(sys)
        class MM(MT):
            def __init__(self, name):
                MT.__init__(self, name)
            def __getattribute__(self, name):
                log.append(("getattr", name))
                return MT.__getattribute__(self, name)
            def __setattr__(self, name, value):
                log.append(("setattr", name, value))
                MT.__setattr__(self, name, value)
            def __delattr__(self, name):
                log.append(("delattr", name))
                MT.__delattr__(self, name)
        a = MM("a")
        a.foo = 12
        x = a.foo
        del a.foo
        self.assertEqual(log, [("setattr", "foo", 12),
                               ("getattr", "foo"),
                               ("delattr", "foo")])

        # http://python.org/sf/1174712
        try:
            class Module(types.ModuleType, str):
                pass
        except TypeError:
            pass
        else:
            self.fail("inheriting from ModuleType and str at the same time "
                      "should fail")

    def test_multiple_inheritance(self):
        # Testing multiple inheritance...
        class C(object):
            def __init__(self):
                self.__state = 0
            def getstate(self):
                return self.__state
            def setstate(self, state):
                self.__state = state
        a = C()
        self.assertEqual(a.getstate(), 0)
        a.setstate(10)
        self.assertEqual(a.getstate(), 10)
        class D(dict, C):
            def __init__(self):
                type({}).__init__(self)
                C.__init__(self)
        d = D()
        self.assertEqual(list(d.keys()), [])
        d["hello"] = "world"
        self.assertEqual(list(d.items()), [("hello", "world")])
        self.assertEqual(d["hello"], "world")
        self.assertEqual(d.getstate(), 0)
        d.setstate(10)
        self.assertEqual(d.getstate(), 10)
        self.assertEqual(D.__mro__, (D, dict, C, object))

        # SF bug #442833
        class Node(object):
            def __int__(self):
                return int(self.foo())
            def foo(self):
                return "23"
        class Frag(Node, list):
            def foo(self):
                return "42"
        self.assertEqual(Node().__int__(), 23)
        self.assertEqual(int(Node()), 23)
        self.assertEqual(Frag().__int__(), 42)
        self.assertEqual(int(Frag()), 42)

    def test_diamond_inheritance(self):
        # Testing multiple inheritance special cases...
        class A(object):
            def spam(self): return "A"
        self.assertEqual(A().spam(), "A")
        class B(A):
            def boo(self): return "B"
            def spam(self): return "B"
        self.assertEqual(B().spam(), "B")
        self.assertEqual(B().boo(), "B")
        class C(A):
            def boo(self): return "C"
        self.assertEqual(C().spam(), "A")
        self.assertEqual(C().boo(), "C")
        class D(B, C): pass
        self.assertEqual(D().spam(), "B")
        self.assertEqual(D().boo(), "B")
        self.assertEqual(D.__mro__, (D, B, C, A, object))
        class E(C, B): pass
        self.assertEqual(E().spam(), "B")
        self.assertEqual(E().boo(), "C")
        self.assertEqual(E.__mro__, (E, C, B, A, object))
        # MRO order disagreement
        try:
            class F(D, E): pass
        except TypeError:
            pass
        else:
            self.fail("expected MRO order disagreement (F)")
        try:
            class G(E, D): pass
        except TypeError:
            pass
        else:
            self.fail("expected MRO order disagreement (G)")

    # see thread python-dev/2002-October/029035.html
    def test_ex5_from_c3_switch(self):
        # Testing ex5 from C3 switch discussion...
        class A(object): pass
        class B(object): pass
        class C(object): pass
        class X(A): pass
        class Y(A): pass
        class Z(X,B,Y,C): pass
        self.assertEqual(Z.__mro__, (Z, X, B, Y, A, C, object))

    # see "A Monotonic Superclass Linearization for Dylan",
    # by Kim Barrett et al. (OOPSLA 1996)
    def test_monotonicity(self):
        # Testing MRO monotonicity...
        class Boat(object): pass
        class DayBoat(Boat): pass
        class WheelBoat(Boat): pass
        class EngineLess(DayBoat): pass
        class SmallMultihull(DayBoat): pass
        class PedalWheelBoat(EngineLess,WheelBoat): pass
        class SmallCatamaran(SmallMultihull): pass
        class Pedalo(PedalWheelBoat,SmallCatamaran): pass

        self.assertEqual(PedalWheelBoat.__mro__,
              (PedalWheelBoat, EngineLess, DayBoat, WheelBoat, Boat, object))
        self.assertEqual(SmallCatamaran.__mro__,
              (SmallCatamaran, SmallMultihull, DayBoat, Boat, object))
        self.assertEqual(Pedalo.__mro__,
              (Pedalo, PedalWheelBoat, EngineLess, SmallCatamaran,
               SmallMultihull, DayBoat, WheelBoat, Boat, object))

    # see "A Monotonic Superclass Linearization for Dylan",
    # by Kim Barrett et al. (OOPSLA 1996)
    def test_consistency_with_epg(self):
        # Testing consistency with EPG...
        class Pane(object): pass
        class ScrollingMixin(object): pass
        class EditingMixin(object): pass
        class ScrollablePane(Pane,ScrollingMixin): pass
        class EditablePane(Pane,EditingMixin): pass
        class EditableScrollablePane(ScrollablePane,EditablePane): pass

        self.assertEqual(EditableScrollablePane.__mro__,
              (EditableScrollablePane, ScrollablePane, EditablePane, Pane,
                ScrollingMixin, EditingMixin, object))

    def test_mro_disagreement(self):
        # Testing error messages for MRO disagreement...
        mro_err_msg = """Cannot create a consistent method resolution
order (MRO) for bases """

        def raises(exc, expected, callable, *args):
            try:
                callable(*args)
            except exc as msg:
                # the exact msg is generally considered an impl detail
                if support.check_impl_detail():
                    if not str(msg).startswith(expected):
                        self.fail("Message %r, expected %r" %
                                  (str(msg), expected))
            else:
                self.fail("Expected %s" % exc)

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

        # Test some very simple errors
        raises(TypeError, "duplicate base class A",
               type, "X", (A, A), {})
        raises(TypeError, mro_err_msg,
               type, "X", (A, B), {})
        raises(TypeError, mro_err_msg,
               type, "X", (A, C, B), {})
        # Test a slightly more complex error
        class GridLayout(object): pass
        class HorizontalGrid(GridLayout): pass
        class VerticalGrid(GridLayout): pass
        class HVGrid(HorizontalGrid, VerticalGrid): pass
        class VHGrid(VerticalGrid, HorizontalGrid): pass
        raises(TypeError, mro_err_msg,
               type, "ConfusedGrid", (HVGrid, VHGrid), {})

    def test_object_class(self):
        # Testing object class...
        a = object()
        self.assertEqual(a.__class__, object)
        self.assertEqual(type(a), object)
        b = object()
        self.assertNotEqual(a, b)
        self.assertNotHasAttr(a, "foo")
        try:
            a.foo = 12
        except (AttributeError, TypeError):
            pass
        else:
            self.fail("object() should not allow setting a foo attribute")
        self.assertNotHasAttr(object(), "__dict__")

        class Cdict(object):
            pass
        x = Cdict()
        self.assertEqual(x.__dict__, {})
        x.foo = 1
        self.assertEqual(x.foo, 1)
        self.assertEqual(x.__dict__, {'foo': 1})

    def test_object_class_assignment_between_heaptypes_and_nonheaptypes(self):
        class SubType(types.ModuleType):
            a = 1

        m = types.ModuleType("m")
        self.assertTrue(m.__class__ is types.ModuleType)
        self.assertFalse(hasattr(m, "a"))

        m.__class__ = SubType
        self.assertTrue(m.__class__ is SubType)
        self.assertTrue(hasattr(m, "a"))

        m.__class__ = types.ModuleType
        self.assertTrue(m.__class__ is types.ModuleType)
        self.assertFalse(hasattr(m, "a"))

        # Make sure that builtin immutable objects don't support __class__
        # assignment, because the object instances may be interned.
        # We set __slots__ = () to ensure that the subclasses are
        # memory-layout compatible, and thus otherwise reasonable candidates
        # for __class__ assignment.

        # The following types have immutable instances, but are not
        # subclassable and thus don't need to be checked:
        #   NoneType, bool

        class MyInt(int):
            __slots__ = ()
        with self.assertRaises(TypeError):
            (1).__class__ = MyInt

        class MyFloat(float):
            __slots__ = ()
        with self.assertRaises(TypeError):
            (1.0).__class__ = MyFloat

        class MyComplex(complex):
            __slots__ = ()
        with self.assertRaises(TypeError):
            (1 + 2j).__class__ = MyComplex

        class MyStr(str):
            __slots__ = ()
        with self.assertRaises(TypeError):
            "a".__class__ = MyStr

        class MyBytes(bytes):
            __slots__ = ()
        with self.assertRaises(TypeError):
            b"a".__class__ = MyBytes

        class MyTuple(tuple):
            __slots__ = ()
        with self.assertRaises(TypeError):
            ().__class__ = MyTuple

        class MyFrozenSet(frozenset):
            __slots__ = ()
        with self.assertRaises(TypeError):
            frozenset().__class__ = MyFrozenSet

    def test_slots(self):
        # Testing __slots__...
        class C0(object):
            __slots__ = []
        x = C0()
        self.assertNotHasAttr(x, "__dict__")
        self.assertNotHasAttr(x, "foo")

        class C1(object):
            __slots__ = ['a']
        x = C1()
        self.assertNotHasAttr(x, "__dict__")
        self.assertNotHasAttr(x, "a")
        x.a = 1
        self.assertEqual(x.a, 1)
        x.a = None
        self.assertEqual(x.a, None)
        del x.a
        self.assertNotHasAttr(x, "a")

        class C3(object):
            __slots__ = ['a', 'b', 'c']
        x = C3()
        self.assertNotHasAttr(x, "__dict__")
        self.assertNotHasAttr(x, 'a')
        self.assertNotHasAttr(x, 'b')
        self.assertNotHasAttr(x, 'c')
        x.a = 1
        x.b = 2
        x.c = 3
        self.assertEqual(x.a, 1)
        self.assertEqual(x.b, 2)
        self.assertEqual(x.c, 3)

        class C4(object):
            """Validate name mangling"""
            __slots__ = ['__a']
            def __init__(self, value):
                self.__a = value
            def get(self):
                return self.__a
        x = C4(5)
        self.assertNotHasAttr(x, '__dict__')
        self.assertNotHasAttr(x, '__a')
        self.assertEqual(x.get(), 5)
        try:
            x.__a = 6
        except AttributeError:
            pass
        else:
            self.fail("Double underscored names not mangled")

        # Make sure slot names are proper identifiers
        try:
            class C(object):
                __slots__ = [None]
        except TypeError:
            pass
        else:
            self.fail("[None] slots not caught")
        try:
            class C(object):
                __slots__ = ["foo bar"]
        except TypeError:
            pass
        else:
            self.fail("['foo bar'] slots not caught")
        try:
            class C(object):
                __slots__ = ["foo\0bar"]
        except TypeError:
            pass
        else:
            self.fail("['foo\\0bar'] slots not caught")
        try:
            class C(object):
                __slots__ = ["1"]
        except TypeError:
            pass
        else:
            self.fail("['1'] slots not caught")
        try:
            class C(object):
                __slots__ = [""]
        except TypeError:
            pass
        else:
            self.fail("[''] slots not caught")
        class C(object):
            __slots__ = ["a", "a_b", "_a", "A0123456789Z"]
        # XXX(nnorwitz): was there supposed to be something tested
        # from the class above?

        # Test a single string is not expanded as a sequence.
        class C(object):
            __slots__ = "abc"
        c = C()
        c.abc = 5
        self.assertEqual(c.abc, 5)

        # Test unicode slot names
        # Test a single unicode string is not expanded as a sequence.
        class C(object):
            __slots__ = "abc"
        c = C()
        c.abc = 5
        self.assertEqual(c.abc, 5)

        # _unicode_to_string used to modify slots in certain circumstances
        slots = ("foo", "bar")
        class C(object):
            __slots__ = slots
        x = C()
        x.foo = 5
        self.assertEqual(x.foo, 5)
        self.assertIs(type(slots[0]), str)
        # this used to leak references
        try:
            class C(object):
                __slots__ = [chr(128)]
        except (TypeError, UnicodeEncodeError):
            pass
        else:
            self.fail("[chr(128)] slots not caught")

        # Test leaks
        class Counted(object):
            counter = 0    # counts the number of instances alive
            def __init__(self):
                Counted.counter += 1
            def __del__(self):
                Counted.counter -= 1
        class C(object):
            __slots__ = ['a', 'b', 'c']
        x = C()
        x.a = Counted()
        x.b = Counted()
        x.c = Counted()
        self.assertEqual(Counted.counter, 3)
        del x
        support.gc_collect()
        self.assertEqual(Counted.counter, 0)
        class D(C):
            pass
        x = D()
        x.a = Counted()
        x.z = Counted()
        self.assertEqual(Counted.counter, 2)
        del x
        support.gc_collect()
        self.assertEqual(Counted.counter, 0)
        class E(D):
            __slots__ = ['e']
        x = E()
        x.a = Counted()
        x.z = Counted()
        x.e = Counted()
        self.assertEqual(Counted.counter, 3)
        del x
        support.gc_collect()
        self.assertEqual(Counted.counter, 0)

        # Test cyclical leaks [SF bug 519621]
        class F(object):
            __slots__ = ['a', 'b']
        s = F()
        s.a = [Counted(), s]
        self.assertEqual(Counted.counter, 1)
        s = None
        support.gc_collect()
        self.assertEqual(Counted.counter, 0)

        # Test lookup leaks [SF bug 572567]
        if hasattr(gc, 'get_objects'):
            class G(object):
                def __eq__(self, other):
                    return False
            g = G()
            orig_objects = len(gc.get_objects())
            for i in range(10):
                g==g
            new_objects = len(gc.get_objects())
            self.assertEqual(orig_objects, new_objects)

        class H(object):
            __slots__ = ['a', 'b']
            def __init__(self):
                self.a = 1
                self.b = 2
            def __del__(self_):
                self.assertEqual(self_.a, 1)
                self.assertEqual(self_.b, 2)
        with support.captured_output('stderr') as s:
            h = H()
            del h
        self.assertEqual(s.getvalue(), '')

        class X(object):
            __slots__ = "a"
        with self.assertRaises(AttributeError):
            del X().a

    def test_slots_special(self):
        # Testing __dict__ and __weakref__ in __slots__...
        class D(object):
            __slots__ = ["__dict__"]
        a = D()
        self.assertHasAttr(a, "__dict__")
        self.assertNotHasAttr(a, "__weakref__")
        a.foo = 42
        self.assertEqual(a.__dict__, {"foo": 42})

        class W(object):
            __slots__ = ["__weakref__"]
        a = W()
        self.assertHasAttr(a, "__weakref__")
        self.assertNotHasAttr(a, "__dict__")
        try:
            a.foo = 42
        except AttributeError:
            pass
        else:
            self.fail("shouldn't be allowed to set a.foo")

        class C1(W, D):
            __slots__ = []
        a = C1()
        self.assertHasAttr(a, "__dict__")
        self.assertHasAttr(a, "__weakref__")
        a.foo = 42
        self.assertEqual(a.__dict__, {"foo": 42})

        class C2(D, W):
            __slots__ = []
        a = C2()
        self.assertHasAttr(a, "__dict__")
        self.assertHasAttr(a, "__weakref__")
        a.foo = 42
        self.assertEqual(a.__dict__, {"foo": 42})

    def test_slots_descriptor(self):
        # Issue2115: slot descriptors did not correctly check
        # the type of the given object
        import abc
        class MyABC(metaclass=abc.ABCMeta):
            __slots__ = "a"

        class Unrelated(object):
            pass
        MyABC.register(Unrelated)

        u = Unrelated()
        self.assertIsInstance(u, MyABC)

        # This used to crash
        self.assertRaises(TypeError, MyABC.a.__set__, u, 3)

    def test_dynamics(self):
        # Testing class attribute propagation...
        class D(object):
            pass
        class E(D):
            pass
        class F(D):
            pass
        D.foo = 1
        self.assertEqual(D.foo, 1)
        # Test that dynamic attributes are inherited
        self.assertEqual(E.foo, 1)
        self.assertEqual(F.foo, 1)
        # Test dynamic instances
        class C(object):
            pass
        a = C()
        self.assertNotHasAttr(a, "foobar")
        C.foobar = 2
        self.assertEqual(a.foobar, 2)
        C.method = lambda self: 42
        self.assertEqual(a.method(), 42)
        C.__repr__ = lambda self: "C()"
        self.assertEqual(repr(a), "C()")
        C.__int__ = lambda self: 100
        self.assertEqual(int(a), 100)
        self.assertEqual(a.foobar, 2)
        self.assertNotHasAttr(a, "spam")
        def mygetattr(self, name):
            if name == "spam":
                return "spam"
            raise AttributeError
        C.__getattr__ = mygetattr
        self.assertEqual(a.spam, "spam")
        a.new = 12
        self.assertEqual(a.new, 12)
        def mysetattr(self, name, value):
            if name == "spam":
                raise AttributeError
            return object.__setattr__(self, name, value)
        C.__setattr__ = mysetattr
        try:
            a.spam = "not spam"
        except AttributeError:
            pass
        else:
            self.fail("expected AttributeError")
        self.assertEqual(a.spam, "spam")
        class D(C):
            pass
        d = D()
        d.foo = 1
        self.assertEqual(d.foo, 1)

        # Test handling of int*seq and seq*int
        class I(int):
            pass
        self.assertEqual("a"*I(2), "aa")
        self.assertEqual(I(2)*"a", "aa")
        self.assertEqual(2*I(3), 6)
        self.assertEqual(I(3)*2, 6)
        self.assertEqual(I(3)*I(2), 6)

        # Test comparison of classes with dynamic metaclasses
        class dynamicmetaclass(type):
            pass
        class someclass(metaclass=dynamicmetaclass):
            pass
        self.assertNotEqual(someclass, object)

    def test_errors(self):
        # Testing errors...
        try:
            class C(list, dict):
                pass
        except TypeError:
            pass
        else:
            self.fail("inheritance from both list and dict should be illegal")

        try:
            class C(object, None):
                pass
        except TypeError:
            pass
        else:
            self.fail("inheritance from non-type should be illegal")
        class Classic:
            pass

        try:
            class C(type(len)):
                pass
        except TypeError:
            pass
        else:
            self.fail("inheritance from CFunction should be illegal")

        try:
            class C(object):
                __slots__ = 1
        except TypeError:
            pass
        else:
            self.fail("__slots__ = 1 should be illegal")

        try:
            class C(object):
                __slots__ = [1]
        except TypeError:
            pass
        else:
            self.fail("__slots__ = [1] should be illegal")

        class M1(type):
            pass
        class M2(type):
            pass
        class A1(object, metaclass=M1):
            pass
        class A2(object, metaclass=M2):
            pass
        try:
            class B(A1, A2):
                pass
        except TypeError:
            pass
        else:
            self.fail("finding the most derived metaclass should have failed")

    def test_classmethods(self):
        # Testing class methods...
        class C(object):
            def foo(*a): return a
            goo = classmethod(foo)
        c = C()
        self.assertEqual(C.goo(1), (C, 1))
        self.assertEqual(c.goo(1), (C, 1))
        self.assertEqual(c.foo(1), (c, 1))
        class D(C):
            pass
        d = D()
        self.assertEqual(D.goo(1), (D, 1))
        self.assertEqual(d.goo(1), (D, 1))
        self.assertEqual(d.foo(1), (d, 1))
        self.assertEqual(D.foo(d, 1), (d, 1))
        # Test for a specific crash (SF bug 528132)
        def f(cls, arg): return (cls, arg)
        ff = classmethod(f)
        self.assertEqual(ff.__get__(0, int)(42), (int, 42))
        self.assertEqual(ff.__get__(0)(42), (int, 42))

        # Test super() with classmethods (SF bug 535444)
        self.assertEqual(C.goo.__self__, C)
        self.assertEqual(D.goo.__self__, D)
        self.assertEqual(super(D,D).goo.__self__, D)
        self.assertEqual(super(D,d).goo.__self__, D)
        self.assertEqual(super(D,D).goo(), (D,))
        self.assertEqual(super(D,d).goo(), (D,))

        # Verify that a non-callable will raise
        meth = classmethod(1).__get__(1)
        self.assertRaises(TypeError, meth)

        # Verify that classmethod() doesn't allow keyword args
        try:
            classmethod(f, kw=1)
        except TypeError:
            pass
        else:
            self.fail("classmethod shouldn't accept keyword args")

        cm = classmethod(f)
        self.assertEqual(cm.__dict__, {})
        cm.x = 42
        self.assertEqual(cm.x, 42)
        self.assertEqual(cm.__dict__, {"x" : 42})
        del cm.x
        self.assertNotHasAttr(cm, "x")

    @support.impl_detail("the module 'xxsubtype' is internal")
    def test_classmethods_in_c(self):
        # Testing C-based class methods...
        import xxsubtype as spam
        a = (1, 2, 3)
        d = {'abc': 123}
        x, a1, d1 = spam.spamlist.classmeth(*a, **d)
        self.assertEqual(x, spam.spamlist)
        self.assertEqual(a, a1)
        self.assertEqual(d, d1)
        x, a1, d1 = spam.spamlist().classmeth(*a, **d)
        self.assertEqual(x, spam.spamlist)
        self.assertEqual(a, a1)
        self.assertEqual(d, d1)
        spam_cm = spam.spamlist.__dict__['classmeth']
        x2, a2, d2 = spam_cm(spam.spamlist, *a, **d)
        self.assertEqual(x2, spam.spamlist)
        self.assertEqual(a2, a1)
        self.assertEqual(d2, d1)
        class SubSpam(spam.spamlist): pass
        x2, a2, d2 = spam_cm(SubSpam, *a, **d)
        self.assertEqual(x2, SubSpam)
        self.assertEqual(a2, a1)
        self.assertEqual(d2, d1)
        with self.assertRaises(TypeError):
            spam_cm()
        with self.assertRaises(TypeError):
            spam_cm(spam.spamlist())
        with self.assertRaises(TypeError):
            spam_cm(list)

    def test_staticmethods(self):
        # Testing static methods...
        class C(object):
            def foo(*a): return a
            goo = staticmethod(foo)
        c = C()
        self.assertEqual(C.goo(1), (1,))
        self.assertEqual(c.goo(1), (1,))
        self.assertEqual(c.foo(1), (c, 1,))
        class D(C):
            pass
        d = D()
        self.assertEqual(D.goo(1), (1,))
        self.assertEqual(d.goo(1), (1,))
        self.assertEqual(d.foo(1), (d, 1))
        self.assertEqual(D.foo(d, 1), (d, 1))
        sm = staticmethod(None)
        self.assertEqual(sm.__dict__, {})
        sm.x = 42
        self.assertEqual(sm.x, 42)
        self.assertEqual(sm.__dict__, {"x" : 42})
        del sm.x
        self.assertNotHasAttr(sm, "x")

    @support.impl_detail("the module 'xxsubtype' is internal")
    def test_staticmethods_in_c(self):
        # Testing C-based static methods...
        import xxsubtype as spam
        a = (1, 2, 3)
        d = {"abc": 123}
        x, a1, d1 = spam.spamlist.staticmeth(*a, **d)
        self.assertEqual(x, None)
        self.assertEqual(a, a1)
        self.assertEqual(d, d1)
        x, a1, d2 = spam.spamlist().staticmeth(*a, **d)
        self.assertEqual(x, None)
        self.assertEqual(a, a1)
        self.assertEqual(d, d1)

    def test_classic(self):
        # Testing classic classes...
        class C:
            def foo(*a): return a
            goo = classmethod(foo)
        c = C()
        self.assertEqual(C.goo(1), (C, 1))
        self.assertEqual(c.goo(1), (C, 1))
        self.assertEqual(c.foo(1), (c, 1))
        class D(C):
            pass
        d = D()
        self.assertEqual(D.goo(1), (D, 1))
        self.assertEqual(d.goo(1), (D, 1))
        self.assertEqual(d.foo(1), (d, 1))
        self.assertEqual(D.foo(d, 1), (d, 1))
        class E: # *not* subclassing from C
            foo = C.foo
        self.assertEqual(E().foo.__func__, C.foo) # i.e., unbound
        self.assertTrue(repr(C.foo.__get__(C())).startswith("<bound method "))

    def test_compattr(self):
        # Testing computed attributes...
        class C(object):
            class computed_attribute(object):
                def __init__(self, get, set=None, delete=None):
                    self.__get = get
                    self.__set = set
                    self.__delete = delete
                def __get__(self, obj, type=None):
                    return self.__get(obj)
                def __set__(self, obj, value):
                    return self.__set(obj, value)
                def __delete__(self, obj):
                    return self.__delete(obj)
            def __init__(self):
                self.__x = 0
            def __get_x(self):
                x = self.__x
                self.__x = x+1
                return x
            def __set_x(self, x):
                self.__x = x
            def __delete_x(self):
                del self.__x
            x = computed_attribute(__get_x, __set_x, __delete_x)
        a = C()
        self.assertEqual(a.x, 0)
        self.assertEqual(a.x, 1)
        a.x = 10
        self.assertEqual(a.x, 10)
        self.assertEqual(a.x, 11)
        del a.x
        self.assertNotHasAttr(a, 'x')

    def test_newslots(self):
        # Testing __new__ slot override...
        class C(list):
            def __new__(cls):
                self = list.__new__(cls)
                self.foo = 1
                return self
            def __init__(self):
                self.foo = self.foo + 2
        a = C()
        self.assertEqual(a.foo, 3)
        self.assertEqual(a.__class__, C)
        class D(C):
            pass
        b = D()
        self.assertEqual(b.foo, 3)
        self.assertEqual(b.__class__, D)

    @unittest.expectedFailure
    def test_bad_new(self):
        self.assertRaises(TypeError, object.__new__)
        self.assertRaises(TypeError, object.__new__, '')
        self.assertRaises(TypeError, list.__new__, object)
        self.assertRaises(TypeError, object.__new__, list)
        class C(object):
            __new__ = list.__new__
        self.assertRaises(TypeError, C)
        class C(list):
            __new__ = object.__new__
        self.assertRaises(TypeError, C)

    def test_object_new(self):
        class A(object):
            pass
        object.__new__(A)
        self.assertRaises(TypeError, object.__new__, A, 5)
        object.__init__(A())
        self.assertRaises(TypeError, object.__init__, A(), 5)

        class A(object):
            def __init__(self, foo):
                self.foo = foo
        object.__new__(A)
        object.__new__(A, 5)
        object.__init__(A(3))
        self.assertRaises(TypeError, object.__init__, A(3), 5)

        class A(object):
            def __new__(cls, foo):
                return object.__new__(cls)
        object.__new__(A)
        self.assertRaises(TypeError, object.__new__, A, 5)
        object.__init__(A(3))
        object.__init__(A(3), 5)

        class A(object):
            def __new__(cls, foo):
                return object.__new__(cls)
            def __init__(self, foo):
                self.foo = foo
        object.__new__(A)
        self.assertRaises(TypeError, object.__new__, A, 5)
        object.__init__(A(3))
        self.assertRaises(TypeError, object.__init__, A(3), 5)

    @unittest.expectedFailure
    def test_restored_object_new(self):
        class A(object):
            def __new__(cls, *args, **kwargs):
                raise AssertionError
        self.assertRaises(AssertionError, A)
        class B(A):
            __new__ = object.__new__
            def __init__(self, foo):
                self.foo = foo
        with warnings.catch_warnings():
            warnings.simplefilter('error', DeprecationWarning)
            b = B(3)
        self.assertEqual(b.foo, 3)
        self.assertEqual(b.__class__, B)
        del B.__new__
        self.assertRaises(AssertionError, B)
        del A.__new__
        with warnings.catch_warnings():
            warnings.simplefilter('error', DeprecationWarning)
            b = B(3)
        self.assertEqual(b.foo, 3)
        self.assertEqual(b.__class__, B)

    def test_altmro(self):
        # Testing mro() and overriding it...
        class A(object):
            def f(self): return "A"
        class B(A):
            pass
        class C(A):
            def f(self): return "C"
        class D(B, C):
            pass
        self.assertEqual(D.mro(), [D, B, C, A, object])
        self.assertEqual(D.__mro__, (D, B, C, A, object))
        self.assertEqual(D().f(), "C")

        class PerverseMetaType(type):
            def mro(cls):
                L = type.mro(cls)
                L.reverse()
                return L
        class X(D,B,C,A, metaclass=PerverseMetaType):
            pass
        self.assertEqual(X.__mro__, (object, A, C, B, D, X))
        self.assertEqual(X().f(), "A")

        try:
            class _metaclass(type):
                def mro(self):
                    return [self, dict, object]
            class X(object, metaclass=_metaclass):
                pass
            # In CPython, the class creation above already raises
            # TypeError, as a protection against the fact that
            # instances of X would segfault it.  In other Python
            # implementations it would be ok to let the class X
            # be created, but instead get a clean TypeError on the
            # __setitem__ below.
            x = object.__new__(X)
            x[5] = 6
        except TypeError:
            pass
        else:
            self.fail("devious mro() return not caught")

        try:
            class _metaclass(type):
                def mro(self):
                    return [1]
            class X(object, metaclass=_metaclass):
                pass
        except TypeError:
            pass
        else:
            self.fail("non-class mro() return not caught")

        try:
            class _metaclass(type):
                def mro(self):
                    return 1
            class X(object, metaclass=_metaclass):
                pass
        except TypeError:
            pass
        else:
            self.fail("non-sequence mro() return not caught")

    def test_overloading(self):
        # Testing operator overloading...

        class B(object):
            "Intermediate class because object doesn't have a __setattr__"

        class C(B):
            def __getattr__(self, name):
                if name == "foo":
                    return ("getattr", name)
                else:
                    raise AttributeError
            def __setattr__(self, name, value):
                if name == "foo":
                    self.setattr = (name, value)
                else:
                    return B.__setattr__(self, name, value)
            def __delattr__(self, name):
                if name == "foo":
                    self.delattr = name
                else:
                    return B.__delattr__(self, name)

            def __getitem__(self, key):
                return ("getitem", key)
            def __setitem__(self, key, value):
                self.setitem = (key, value)
            def __delitem__(self, key):
                self.delitem = key

        a = C()
        self.assertEqual(a.foo, ("getattr", "foo"))
        a.foo = 12
        self.assertEqual(a.setattr, ("foo", 12))
        del a.foo
        self.assertEqual(a.delattr, "foo")

        self.assertEqual(a[12], ("getitem", 12))
        a[12] = 21
        self.assertEqual(a.setitem, (12, 21))
        del a[12]
        self.assertEqual(a.delitem, 12)

        self.assertEqual(a[0:10], ("getitem", slice(0, 10)))
        a[0:10] = "foo"
        self.assertEqual(a.setitem, (slice(0, 10), "foo"))
        del a[0:10]
        self.assertEqual(a.delitem, (slice(0, 10)))

    def test_methods(self):
        # Testing methods...
        class C(object):
            def __init__(self, x):
                self.x = x
            def foo(self):
                return self.x
        c1 = C(1)
        self.assertEqual(c1.foo(), 1)
        class D(C):
            boo = C.foo
            goo = c1.foo
        d2 = D(2)
        self.assertEqual(d2.foo(), 2)
        self.assertEqual(d2.boo(), 2)
        self.assertEqual(d2.goo(), 1)
        class E(object):
            foo = C.foo
        self.assertEqual(E().foo.__func__, C.foo) # i.e., unbound
        self.assertTrue(repr(C.foo.__get__(C(1))).startswith("<bound method "))

    def test_special_method_lookup(self):
        # The lookup of special methods bypasses __getattr__ and
        # __getattribute__, but they still can be descriptors.

        def run_context(manager):
            with manager:
                pass
        def iden(self):
            return self
        def hello(self):
            return b"hello"
        def empty_seq(self):
            return []
        def zero(self):
            return 0
        def complex_num(self):
            return 1j
        def stop(self):
            raise StopIteration
        def return_true(self, thing=None):
            return True
        def do_isinstance(obj):
            return isinstance(int, obj)
        def do_issubclass(obj):
            return issubclass(int, obj)
        def do_dict_missing(checker):
            class DictSub(checker.__class__, dict):
                pass
            self.assertEqual(DictSub()["hi"], 4)
        def some_number(self_, key):
            self.assertEqual(key, "hi")
            return 4
        def swallow(*args): pass
        def format_impl(self, spec):
            return "hello"

        # It would be nice to have every special method tested here, but I'm
        # only listing the ones I can remember outside of typeobject.c, since it
        # does it right.
        specials = [
            ("__bytes__", bytes, hello, set(), {}),
            ("__reversed__", reversed, empty_seq, set(), {}),
            ("__length_hint__", list, zero, set(),
             {"__iter__" : iden, "__next__" : stop}),
            ("__sizeof__", sys.getsizeof, zero, set(), {}),
            ("__instancecheck__", do_isinstance, return_true, set(), {}),
            ("__missing__", do_dict_missing, some_number,
             set(("__class__",)), {}),
            ("__subclasscheck__", do_issubclass, return_true,
             set(("__bases__",)), {}),
            ("__enter__", run_context, iden, set(), {"__exit__" : swallow}),
            ("__exit__", run_context, swallow, set(), {"__enter__" : iden}),
            ("__complex__", complex, complex_num, set(), {}),
            ("__format__", format, format_impl, set(), {}),
            ("__floor__", math.floor, zero, set(), {}),
            ("__trunc__", math.trunc, zero, set(), {}),
            ("__trunc__", int, zero, set(), {}),
            ("__ceil__", math.ceil, zero, set(), {}),
            ("__dir__", dir, empty_seq, set(), {}),
            ("__round__", round, zero, set(), {}),
            ]

        class Checker(object):
            def __getattr__(self, attr, test=self):
                test.fail("__getattr__ called with {0}".format(attr))
            def __getattribute__(self, attr, test=self):
                if attr not in ok:
                    test.fail("__getattribute__ called with {0}".format(attr))
                return object.__getattribute__(self, attr)
        class SpecialDescr(object):
            def __init__(self, impl):
                self.impl = impl
            def __get__(self, obj, owner):
                record.append(1)
                return self.impl.__get__(obj, owner)
        class MyException(Exception):
            pass
        class ErrDescr(object):
            def __get__(self, obj, owner):
                raise MyException

        for name, runner, meth_impl, ok, env in specials:
            class X(Checker):
                pass
            for attr, obj in env.items():
                setattr(X, attr, obj)
            setattr(X, name, meth_impl)
            runner(X())

            record = []
            class X(Checker):
                pass
            for attr, obj in env.items():
                setattr(X, attr, obj)
            setattr(X, name, SpecialDescr(meth_impl))
            runner(X())
            self.assertEqual(record, [1], name)

            class X(Checker):
                pass
            for attr, obj in env.items():
                setattr(X, attr, obj)
            setattr(X, name, ErrDescr())
            self.assertRaises(MyException, runner, X())

    def test_specials(self):
        # Testing special operators...
        # Test operators like __hash__ for which a built-in default exists

        # Test the default behavior for static classes
        class C(object):
            def __getitem__(self, i):
                if 0 <= i < 10: return i
                raise IndexError
        c1 = C()
        c2 = C()
        self.assertFalse(not c1)
        self.assertNotEqual(id(c1), id(c2))
        hash(c1)
        hash(c2)
        self.assertEqual(c1, c1)
        self.assertTrue(c1 != c2)
        self.assertFalse(c1 != c1)
        self.assertFalse(c1 == c2)
        # Note that the module name appears in str/repr, and that varies
        # depending on whether this test is run standalone or from a framework.
        self.assertGreaterEqual(str(c1).find('C object at '), 0)
        self.assertEqual(str(c1), repr(c1))
        self.assertNotIn(-1, c1)
        for i in range(10):
            self.assertIn(i, c1)
        self.assertNotIn(10, c1)
        # Test the default behavior for dynamic classes
        class D(object):
            def __getitem__(self, i):
                if 0 <= i < 10: return i
                raise IndexError
        d1 = D()
        d2 = D()
        self.assertFalse(not d1)
        self.assertNotEqual(id(d1), id(d2))
        hash(d1)
        hash(d2)
        self.assertEqual(d1, d1)
        self.assertNotEqual(d1, d2)
        self.assertFalse(d1 != d1)
        self.assertFalse(d1 == d2)
        # Note that the module name appears in str/repr, and that varies
        # depending on whether this test is run standalone or from a framework.
        self.assertGreaterEqual(str(d1).find('D object at '), 0)
        self.assertEqual(str(d1), repr(d1))
        self.assertNotIn(-1, d1)
        for i in range(10):
            self.assertIn(i, d1)
        self.assertNotIn(10, d1)
        # Test overridden behavior
        class Proxy(object):
            def __init__(self, x):
                self.x = x
            def __bool__(self):
                return not not self.x
            def __hash__(self):
                return hash(self.x)
            def __eq__(self, other):
                return self.x == other
            def __ne__(self, other):
                return self.x != other
            def __ge__(self, other):
                return self.x >= other
            def __gt__(self, other):
                return self.x > other
            def __le__(self, other):
                return self.x <= other
            def __lt__(self, other):
                return self.x < other
            def __str__(self):
                return "Proxy:%s" % self.x
            def __repr__(self):
                return "Proxy(%r)" % self.x
            def __contains__(self, value):
                return value in self.x
        p0 = Proxy(0)
        p1 = Proxy(1)
        p_1 = Proxy(-1)
        self.assertFalse(p0)
        self.assertFalse(not p1)
        self.assertEqual(hash(p0), hash(0))
        self.assertEqual(p0, p0)
        self.assertNotEqual(p0, p1)
        self.assertFalse(p0 != p0)
        self.assertEqual(not p0, p1)
        self.assertTrue(p0 < p1)
        self.assertTrue(p0 <= p1)
        self.assertTrue(p1 > p0)
        self.assertTrue(p1 >= p0)
        self.assertEqual(str(p0), "Proxy:0")
        self.assertEqual(repr(p0), "Proxy(0)")
        p10 = Proxy(range(10))
        self.assertNotIn(-1, p10)
        for i in range(10):
            self.assertIn(i, p10)
        self.assertNotIn(10, p10)

    def test_weakrefs(self):
        # Testing weak references...
        import weakref
        class C(object):
            pass
        c = C()
        r = weakref.ref(c)
        self.assertEqual(r(), c)
        del c
        support.gc_collect()
        self.assertEqual(r(), None)
        del r
        class NoWeak(object):
            __slots__ = ['foo']
        no = NoWeak()
        try:
            weakref.ref(no)
        except TypeError as msg:
            self.assertIn("weak reference", str(msg))
        else:
            self.fail("weakref.ref(no) should be illegal")
        class Weak(object):
            __slots__ = ['foo', '__weakref__']
        yes = Weak()
        r = weakref.ref(yes)
        self.assertEqual(r(), yes)
        del yes
        support.gc_collect()
        self.assertEqual(r(), None)
        del r

    def test_properties(self):
        # Testing property...
        class C(object):
            def getx(self):
                return self.__x
            def setx(self, value):
                self.__x = value
            def delx(self):
                del self.__x
            x = property(getx, setx, delx, doc="I'm the x property.")
        a = C()
        self.assertNotHasAttr(a, "x")
        a.x = 42
        self.assertEqual(a._C__x, 42)
        self.assertEqual(a.x, 42)
        del a.x
        self.assertNotHasAttr(a, "x")
        self.assertNotHasAttr(a, "_C__x")
        C.x.__set__(a, 100)
        self.assertEqual(C.x.__get__(a), 100)
        C.x.__delete__(a)
        self.assertNotHasAttr(a, "x")

        raw = C.__dict__['x']
        self.assertIsInstance(raw, property)

        attrs = dir(raw)
        self.assertIn("__doc__", attrs)
        self.assertIn("fget", attrs)
        self.assertIn("fset", attrs)
        self.assertIn("fdel", attrs)

        self.assertEqual(raw.__doc__, "I'm the x property.")
        self.assertIs(raw.fget, C.__dict__['getx'])
        self.assertIs(raw.fset, C.__dict__['setx'])
        self.assertIs(raw.fdel, C.__dict__['delx'])

        for attr in "fget", "fset", "fdel":
            try:
                setattr(raw, attr, 42)
            except AttributeError as msg:
                if str(msg).find('readonly') < 0:
                    self.fail("when setting readonly attr %r on a property, "
                              "got unexpected AttributeError msg %r" % (attr, str(msg)))
            else:
                self.fail("expected AttributeError from trying to set readonly %r "
                          "attr on a property" % attr)

        raw.__doc__ = 42
        self.assertEqual(raw.__doc__, 42)

        class D(object):
            __getitem__ = property(lambda s: 1/0)

        d = D()
        try:
            for i in d:
                str(i)
        except ZeroDivisionError:
            pass
        else:
            self.fail("expected ZeroDivisionError from bad property")

    @unittest.skipIf(sys.flags.optimize >= 2,
                     "Docstrings are omitted with -O2 and above")
    def test_properties_doc_attrib(self):
        class E(object):
            def getter(self):
                "getter method"
                return 0
            def setter(self_, value):
                "setter method"
                pass
            prop = property(getter)
            self.assertEqual(prop.__doc__, "getter method")
            prop2 = property(fset=setter)
            self.assertEqual(prop2.__doc__, None)

    @support.cpython_only
    def test_testcapi_no_segfault(self):
        # this segfaulted in 2.5b2
        try:
            import _testcapi
        except ImportError:
            pass
        else:
            class X(object):
                p = property(_testcapi.test_with_docstring)

    def test_properties_plus(self):
        class C(object):
            foo = property(doc="hello")
            @foo.getter
            def foo(self):
                return self._foo
            @foo.setter
            def foo(self, value):
                self._foo = abs(value)
            @foo.deleter
            def foo(self):
                del self._foo
        c = C()
        self.assertEqual(C.foo.__doc__, "hello")
        self.assertNotHasAttr(c, "foo")
        c.foo = -42
        self.assertHasAttr(c, '_foo')
        self.assertEqual(c._foo, 42)
        self.assertEqual(c.foo, 42)
        del c.foo
        self.assertNotHasAttr(c, '_foo')
        self.assertNotHasAttr(c, "foo")

        class D(C):
            @C.foo.deleter
            def foo(self):
                try:
                    del self._foo
                except AttributeError:
                    pass
        d = D()
        d.foo = 24
        self.assertEqual(d.foo, 24)
        del d.foo
        del d.foo

        class E(object):
            @property
            def foo(self):
                return self._foo
            @foo.setter
            def foo(self, value):
                raise RuntimeError
            @foo.setter
            def foo(self, value):
                self._foo = abs(value)
            @foo.deleter
            def foo(self, value=None):
                del self._foo

        e = E()
        e.foo = -42
        self.assertEqual(e.foo, 42)
        del e.foo

        class F(E):
            @E.foo.deleter
            def foo(self):
                del self._foo
            @foo.setter
            def foo(self, value):
                self._foo = max(0, value)
        f = F()
        f.foo = -10
        self.assertEqual(f.foo, 0)
        del f.foo

    def test_dict_constructors(self):
        # Testing dict constructor ...
        d = dict()
        self.assertEqual(d, {})
        d = dict({})
        self.assertEqual(d, {})
        d = dict({1: 2, 'a': 'b'})
        self.assertEqual(d, {1: 2, 'a': 'b'})
        self.assertEqual(d, dict(list(d.items())))
        self.assertEqual(d, dict(iter(d.items())))
        d = dict({'one':1, 'two':2})
        self.assertEqual(d, dict(one=1, two=2))
        self.assertEqual(d, dict(**d))
        self.assertEqual(d, dict({"one": 1}, two=2))
        self.assertEqual(d, dict([("two", 2)], one=1))
        self.assertEqual(d, dict([("one", 100), ("two", 200)], **d))
        self.assertEqual(d, dict(**d))

        for badarg in 0, 0, 0j, "0", [0], (0,):
            try:
                dict(badarg)
            except TypeError:
                pass
            except ValueError:
                if badarg == "0":
                    # It's a sequence, and its elements are also sequences (gotta
                    # love strings <wink>), but they aren't of length 2, so this
                    # one seemed better as a ValueError than a TypeError.
                    pass
                else:
                    self.fail("no TypeError from dict(%r)" % badarg)
            else:
                self.fail("no TypeError from dict(%r)" % badarg)

        try:
            dict({}, {})
        except TypeError:
            pass
        else:
            self.fail("no TypeError from dict({}, {})")

        class Mapping:
            # Lacks a .keys() method; will be added later.
            dict = {1:2, 3:4, 'a':1j}

        try:
            dict(Mapping())
        except TypeError:
            pass
        else:
            self.fail("no TypeError from dict(incomplete mapping)")

        Mapping.keys = lambda self: list(self.dict.keys())
        Mapping.__getitem__ = lambda self, i: self.dict[i]
        d = dict(Mapping())
        self.assertEqual(d, Mapping.dict)

        # Init from sequence of iterable objects, each producing a 2-sequence.
        class AddressBookEntry:
            def __init__(self, first, last):
                self.first = first
                self.last = last
            def __iter__(self):
                return iter([self.first, self.last])

        d = dict([AddressBookEntry('Tim', 'Warsaw'),
                  AddressBookEntry('Barry', 'Peters'),
                  AddressBookEntry('Tim', 'Peters'),
                  AddressBookEntry('Barry', 'Warsaw')])
        self.assertEqual(d, {'Barry': 'Warsaw', 'Tim': 'Peters'})

        d = dict(zip(range(4), range(1, 5)))
        self.assertEqual(d, dict([(i, i+1) for i in range(4)]))

        # Bad sequence lengths.
        for bad in [('tooshort',)], [('too', 'long', 'by 1')]:
            try:
                dict(bad)
            except ValueError:
                pass
            else:
                self.fail("no ValueError from dict(%r)" % bad)

    def test_dir(self):
        # Testing dir() ...
        junk = 12
        self.assertEqual(dir(), ['junk', 'self'])
        del junk

        # Just make sure these don't blow up!
        for arg in 2, 2, 2j, 2e0, [2], "2", b"2", (2,), {2:2}, type, self.test_dir:
            dir(arg)

        # Test dir on new-style classes.  Since these have object as a
        # base class, a lot more gets sucked in.
        def interesting(strings):
            return [s for s in strings if not s.startswith('_')]

        class C(object):
            Cdata = 1
            def Cmethod(self): pass

        cstuff = ['Cdata', 'Cmethod']
        self.assertEqual(interesting(dir(C)), cstuff)

        c = C()
        self.assertEqual(interesting(dir(c)), cstuff)
        ## self.assertIn('__self__', dir(C.Cmethod))

        c.cdata = 2
        c.cmethod = lambda self: 0
        self.assertEqual(interesting(dir(c)), cstuff + ['cdata', 'cmethod'])
        ## self.assertIn('__self__', dir(c.Cmethod))

        class A(C):
            Adata = 1
            def Amethod(self): pass

        astuff = ['Adata', 'Amethod'] + cstuff
        self.assertEqual(interesting(dir(A)), astuff)
        ## self.assertIn('__self__', dir(A.Amethod))
        a = A()
        self.assertEqual(interesting(dir(a)), astuff)
        a.adata = 42
        a.amethod = lambda self: 3
        self.assertEqual(interesting(dir(a)), astuff + ['adata', 'amethod'])
        ## self.assertIn('__self__', dir(a.Amethod))

        # Try a module subclass.
        class M(type(sys)):
            pass
        minstance = M("m")
        minstance.b = 2
        minstance.a = 1
        default_attributes = ['__name__', '__doc__', '__package__',
                              '__loader__', '__spec__']
        names = [x for x in dir(minstance) if x not in default_attributes]
        self.assertEqual(names, ['a', 'b'])

        class M2(M):
            def getdict(self):
                return "Not a dict!"
            __dict__ = property(getdict)

        m2instance = M2("m2")
        m2instance.b = 2
        m2instance.a = 1
        self.assertEqual(m2instance.__dict__, "Not a dict!")
        try:
            dir(m2instance)
        except TypeError:
            pass

        # Two essentially featureless objects, just inheriting stuff from
        # object.
        self.assertEqual(dir(NotImplemented), dir(Ellipsis))

        # Nasty test case for proxied objects
        class Wrapper(object):
            def __init__(self, obj):
                self.__obj = obj
            def __repr__(self):
                return "Wrapper(%s)" % repr(self.__obj)
            def __getitem__(self, key):
                return Wrapper(self.__obj[key])
            def __len__(self):
                return len(self.__obj)
            def __getattr__(self, name):
                return Wrapper(getattr(self.__obj, name))

        class C(object):
            def __getclass(self):
                return Wrapper(type(self))
            __class__ = property(__getclass)

        dir(C()) # This used to segfault

    def test_supers(self):
        # Testing super...

        class A(object):
            def meth(self, a):
                return "A(%r)" % a

        self.assertEqual(A().meth(1), "A(1)")

        class B(A):
            def __init__(self):
                self.__super = super(B, self)
            def meth(self, a):
                return "B(%r)" % a + self.__super.meth(a)

        self.assertEqual(B().meth(2), "B(2)A(2)")

        class C(A):
            def meth(self, a):
                return "C(%r)" % a + self.__super.meth(a)
        C._C__super = super(C)

        self.assertEqual(C().meth(3), "C(3)A(3)")

        class D(C, B):
            def meth(self, a):
                return "D(%r)" % a + super(D, self).meth(a)

        self.assertEqual(D().meth(4), "D(4)C(4)B(4)A(4)")

        # Test for subclassing super

        class mysuper(super):
            def __init__(self, *args):
                return super(mysuper, self).__init__(*args)

        class E(D):
            def meth(self, a):
                return "E(%r)" % a + mysuper(E, self).meth(a)

        self.assertEqual(E().meth(5), "E(5)D(5)C(5)B(5)A(5)")

        class F(E):
            def meth(self, a):
                s = self.__super # == mysuper(F, self)
                return "F(%r)[%s]" % (a, s.__class__.__name__) + s.meth(a)
        F._F__super = mysuper(F)

        self.assertEqual(F().meth(6), "F(6)[mysuper]E(6)D(6)C(6)B(6)A(6)")

        # Make sure certain errors are raised

        try:
            super(D, 42)
        except TypeError:
            pass
        else:
            self.fail("shouldn't allow super(D, 42)")

        try:
            super(D, C())
        except TypeError:
            pass
        else:
            self.fail("shouldn't allow super(D, C())")

        try:
            super(D).__get__(12)
        except TypeError:
            pass
        else:
            self.fail("shouldn't allow super(D).__get__(12)")

        try:
            super(D).__get__(C())
        except TypeError:
            pass
        else:
            self.fail("shouldn't allow super(D).__get__(C())")

        # Make sure data descriptors can be overridden and accessed via super
        # (new feature in Python 2.3)

        class DDbase(object):
            def getx(self): return 42
            x = property(getx)

        class DDsub(DDbase):
            def getx(self): return "hello"
            x = property(getx)

        dd = DDsub()
        self.assertEqual(dd.x, "hello")
        self.assertEqual(super(DDsub, dd).x, 42)

        # Ensure that super() lookup of descriptor from classmethod
        # works (SF ID# 743627)

        class Base(object):
            aProp = property(lambda self: "foo")

        class Sub(Base):
            @classmethod
            def test(klass):
                return super(Sub,klass).aProp

        self.assertEqual(Sub.test(), Base.aProp)

        # Verify that super() doesn't allow keyword args
        try:
            super(Base, kw=1)
        except TypeError:
            pass
        else:
            self.assertEqual("super shouldn't accept keyword args")

    def test_basic_inheritance(self):
        # Testing inheritance from basic types...

        class hexint(int):
            def __repr__(self):
                return hex(self)
            def __add__(self, other):
                return hexint(int.__add__(self, other))
            # (Note that overriding __radd__ doesn't work,
            # because the int type gets first dibs.)
        self.assertEqual(repr(hexint(7) + 9), "0x10")
        self.assertEqual(repr(hexint(1000) + 7), "0x3ef")
        a = hexint(12345)
        self.assertEqual(a, 12345)
        self.assertEqual(int(a), 12345)
        self.assertIs(int(a).__class__, int)
        self.assertEqual(hash(a), hash(12345))
        self.assertIs((+a).__class__, int)
        self.assertIs((a >> 0).__class__, int)
        self.assertIs((a << 0).__class__, int)
        self.assertIs((hexint(0) << 12).__class__, int)
        self.assertIs((hexint(0) >> 12).__class__, int)

        class octlong(int):
            __slots__ = []
            def __str__(self):
                return oct(self)
            def __add__(self, other):
                return self.__class__(super(octlong, self).__add__(other))
            __radd__ = __add__
        self.assertEqual(str(octlong(3) + 5), "0o10")
        # (Note that overriding __radd__ here only seems to work
        # because the example uses a short int left argument.)
        self.assertEqual(str(5 + octlong(3000)), "0o5675")
        a = octlong(12345)
        self.assertEqual(a, 12345)
        self.assertEqual(int(a), 12345)
        self.assertEqual(hash(a), hash(12345))
        self.assertIs(int(a).__class__, int)
        self.assertIs((+a).__class__, int)
        self.assertIs((-a).__class__, int)
        self.assertIs((-octlong(0)).__class__, int)
        self.assertIs((a >> 0).__class__, int)
        self.assertIs((a << 0).__class__, int)
        self.assertIs((a - 0).__class__, int)
        self.assertIs((a * 1).__class__, int)
        self.assertIs((a ** 1).__class__, int)
        self.assertIs((a // 1).__class__, int)
        self.assertIs((1 * a).__class__, int)
        self.assertIs((a | 0).__class__, int)
        self.assertIs((a ^ 0).__class__, int)
        self.assertIs((a & -1).__class__, int)
        self.assertIs((octlong(0) << 12).__class__, int)
        self.assertIs((octlong(0) >> 12).__class__, int)
        self.assertIs(abs(octlong(0)).__class__, int)

        # Because octlong overrides __add__, we can't check the absence of +0
        # optimizations using octlong.
        class longclone(int):
            pass
        a = longclone(1)
        self.assertIs((a + 0).__class__, int)
        self.assertIs((0 + a).__class__, int)

        # Check that negative clones don't segfault
        a = longclone(-1)
        self.assertEqual(a.__dict__, {})
        self.assertEqual(int(a), -1)  # self.assertTrue PyNumber_Long() copies the sign bit

        class precfloat(float):
            __slots__ = ['prec']
            def __init__(self, value=0.0, prec=12):
                self.prec = int(prec)
            def __repr__(self):
                return "%.*g" % (self.prec, self)
        self.assertEqual(repr(precfloat(1.1)), "1.1")
        a = precfloat(12345)
        self.assertEqual(a, 12345.0)
        self.assertEqual(float(a), 12345.0)
        self.assertIs(float(a).__class__, float)
        self.assertEqual(hash(a), hash(12345.0))
        self.assertIs((+a).__class__, float)

        class madcomplex(complex):
            def __repr__(self):
                return "%.17gj%+.17g" % (self.imag, self.real)
        a = madcomplex(-3, 4)
        self.assertEqual(repr(a), "4j-3")
        base = complex(-3, 4)
        self.assertEqual(base.__class__, complex)
        self.assertEqual(a, base)
        self.assertEqual(complex(a), base)
        self.assertEqual(complex(a).__class__, complex)
        a = madcomplex(a)  # just trying another form of the constructor
        self.assertEqual(repr(a), "4j-3")
        self.assertEqual(a, base)
        self.assertEqual(complex(a), base)
        self.assertEqual(complex(a).__class__, complex)
        self.assertEqual(hash(a), hash(base))
        self.assertEqual((+a).__class__, complex)
        self.assertEqual((a + 0).__class__, complex)
        self.assertEqual(a + 0, base)
        self.assertEqual((a - 0).__class__, complex)
        self.assertEqual(a - 0, base)
        self.assertEqual((a * 1).__class__, complex)
        self.assertEqual(a * 1, base)
        self.assertEqual((a / 1).__class__, complex)
        self.assertEqual(a / 1, base)

        class madtuple(tuple):
            _rev = None
            def rev(self):
                if self._rev is not None:
                    return self._rev
                L = list(self)
                L.reverse()
                self._rev = self.__class__(L)
                return self._rev
        a = madtuple((1,2,3,4,5,6,7,8,9,0))
        self.assertEqual(a, (1,2,3,4,5,6,7,8,9,0))
        self.assertEqual(a.rev(), madtuple((0,9,8,7,6,5,4,3,2,1)))
        self.assertEqual(a.rev().rev(), madtuple((1,2,3,4,5,6,7,8,9,0)))
        for i in range(512):
            t = madtuple(range(i))
            u = t.rev()
            v = u.rev()
            self.assertEqual(v, t)
        a = madtuple((1,2,3,4,5))
        self.assertEqual(tuple(a), (1,2,3,4,5))
        self.assertIs(tuple(a).__class__, tuple)
        self.assertEqual(hash(a), hash((1,2,3,4,5)))
        self.assertIs(a[:].__class__, tuple)
        self.assertIs((a * 1).__class__, tuple)
        self.assertIs((a * 0).__class__, tuple)
        self.assertIs((a + ()).__class__, tuple)
        a = madtuple(())
        self.assertEqual(tuple(a), ())
        self.assertIs(tuple(a).__class__, tuple)
        self.assertIs((a + a).__class__, tuple)
        self.assertIs((a * 0).__class__, tuple)
        self.assertIs((a * 1).__class__, tuple)
        self.assertIs((a * 2).__class__, tuple)
        self.assertIs(a[:].__class__, tuple)

        class madstring(str):
            _rev = None
            def rev(self):
                if self._rev is not None:
                    return self._rev
                L = list(self)
                L.reverse()
                self._rev = self.__class__("".join(L))
                return self._rev
        s = madstring("abcdefghijklmnopqrstuvwxyz")
        self.assertEqual(s, "abcdefghijklmnopqrstuvwxyz")
        self.assertEqual(s.rev(), madstring("zyxwvutsrqponmlkjihgfedcba"))
        self.assertEqual(s.rev().rev(), madstring("abcdefghijklmnopqrstuvwxyz"))
        for i in range(256):
            s = madstring("".join(map(chr, range(i))))
            t = s.rev()
            u = t.rev()
            self.assertEqual(u, s)
        s = madstring("12345")
        self.assertEqual(str(s), "12345")
        self.assertIs(str(s).__class__, str)

        base = "\x00" * 5
        s = madstring(base)
        self.assertEqual(s, base)
        self.assertEqual(str(s), base)
        self.assertIs(str(s).__class__, str)
        self.assertEqual(hash(s), hash(base))
        self.assertEqual({s: 1}[base], 1)
        self.assertEqual({base: 1}[s], 1)
        self.assertIs((s + "").__class__, str)
        self.assertEqual(s + "", base)
        self.assertIs(("" + s).__class__, str)
        self.assertEqual("" + s, base)
        self.assertIs((s * 0).__class__, str)
        self.assertEqual(s * 0, "")
        self.assertIs((s * 1).__class__, str)
        self.assertEqual(s * 1, base)
        self.assertIs((s * 2).__class__, str)
        self.assertEqual(s * 2, base + base)
        self.assertIs(s[:].__class__, str)
        self.assertEqual(s[:], base)
        self.assertIs(s[0:0].__class__, str)
        self.assertEqual(s[0:0], "")
        self.assertIs(s.strip().__class__, str)
        self.assertEqual(s.strip(), base)
        self.assertIs(s.lstrip().__class__, str)
        self.assertEqual(s.lstrip(), base)
        self.assertIs(s.rstrip().__class__, str)
        self.assertEqual(s.rstrip(), base)
        identitytab = {}
        self.assertIs(s.translate(identitytab).__class__, str)
        self.assertEqual(s.translate(identitytab), base)
        self.assertIs(s.replace("x", "x").__class__, str)
        self.assertEqual(s.replace("x", "x"), base)
        self.assertIs(s.ljust(len(s)).__class__, str)
        self.assertEqual(s.ljust(len(s)), base)
        self.assertIs(s.rjust(len(s)).__class__, str)
        self.assertEqual(s.rjust(len(s)), base)
        self.assertIs(s.center(len(s)).__class__, str)
        self.assertEqual(s.center(len(s)), base)
        self.assertIs(s.lower().__class__, str)
        self.assertEqual(s.lower(), base)

        class madunicode(str):
            _rev = None
            def rev(self):
                if self._rev is not None:
                    return self._rev
                L = list(self)
                L.reverse()
                self._rev = self.__class__("".join(L))
                return self._rev
        u = madunicode("ABCDEF")
        self.assertEqual(u, "ABCDEF")
        self.assertEqual(u.rev(), madunicode("FEDCBA"))
        self.assertEqual(u.rev().rev(), madunicode("ABCDEF"))
        base = "12345"
        u = madunicode(base)
        self.assertEqual(str(u), base)
        self.assertIs(str(u).__class__, str)
        self.assertEqual(hash(u), hash(base))
        self.assertEqual({u: 1}[base], 1)
        self.assertEqual({base: 1}[u], 1)
        self.assertIs(u.strip().__class__, str)
        self.assertEqual(u.strip(), base)
        self.assertIs(u.lstrip().__class__, str)
        self.assertEqual(u.lstrip(), base)
        self.assertIs(u.rstrip().__class__, str)
        self.assertEqual(u.rstrip(), base)
        self.assertIs(u.replace("x", "x").__class__, str)
        self.assertEqual(u.replace("x", "x"), base)
        self.assertIs(u.replace("xy", "xy").__class__, str)
        self.assertEqual(u.replace("xy", "xy"), base)
        self.assertIs(u.center(len(u)).__class__, str)
        self.assertEqual(u.center(len(u)), base)
        self.assertIs(u.ljust(len(u)).__class__, str)
        self.assertEqual(u.ljust(len(u)), base)
        self.assertIs(u.rjust(len(u)).__class__, str)
        self.assertEqual(u.rjust(len(u)), base)
        self.assertIs(u.lower().__class__, str)
        self.assertEqual(u.lower(), base)
        self.assertIs(u.upper().__class__, str)
        self.assertEqual(u.upper(), base)
        self.assertIs(u.capitalize().__class__, str)
        self.assertEqual(u.capitalize(), base)
        self.assertIs(u.title().__class__, str)
        self.assertEqual(u.title(), base)
        self.assertIs((u + "").__class__, str)
        self.assertEqual(u + "", base)
        self.assertIs(("" + u).__class__, str)
        self.assertEqual("" + u, base)
        self.assertIs((u * 0).__class__, str)
        self.assertEqual(u * 0, "")
        self.assertIs((u * 1).__class__, str)
        self.assertEqual(u * 1, base)
        self.assertIs((u * 2).__class__, str)
        self.assertEqual(u * 2, base + base)
        self.assertIs(u[:].__class__, str)
        self.assertEqual(u[:], base)
        self.assertIs(u[0:0].__class__, str)
        self.assertEqual(u[0:0], "")

        class sublist(list):
            pass
        a = sublist(range(5))
        self.assertEqual(a, list(range(5)))
        a.append("hello")
        self.assertEqual(a, list(range(5)) + ["hello"])
        a[5] = 5
        self.assertEqual(a, list(range(6)))
        a.extend(range(6, 20))
        self.assertEqual(a, list(range(20)))
        a[-5:] = []
        self.assertEqual(a, list(range(15)))
        del a[10:15]
        self.assertEqual(len(a), 10)
        self.assertEqual(a, list(range(10)))
        self.assertEqual(list(a), list(range(10)))
        self.assertEqual(a[0], 0)
        self.assertEqual(a[9], 9)
        self.assertEqual(a[-10], 0)
        self.assertEqual(a[-1], 9)
        self.assertEqual(a[:5], list(range(5)))

        ## class CountedInput(file):
        ##    """Counts lines read by self.readline().
        ##
        ##     self.lineno is the 0-based ordinal of the last line read, up to
        ##     a maximum of one greater than the number of lines in the file.
        ##
        ##     self.ateof is true if and only if the final "" line has been read,
        ##     at which point self.lineno stops incrementing, and further calls
        ##     to readline() continue to return "".
        ##     """
        ##
        ##     lineno = 0
        ##     ateof = 0
        ##     def readline(self):
        ##         if self.ateof:
        ##             return ""
        ##         s = file.readline(self)
        ##         # Next line works too.
        ##         # s = super(CountedInput, self).readline()
        ##         self.lineno += 1
        ##         if s == "":
        ##             self.ateof = 1
        ##        return s
        ##
        ## f = file(name=support.TESTFN, mode='w')
        ## lines = ['a\n', 'b\n', 'c\n']
        ## try:
        ##     f.writelines(lines)
        ##     f.close()
        ##     f = CountedInput(support.TESTFN)
        ##     for (i, expected) in zip(range(1, 5) + [4], lines + 2 * [""]):
        ##         got = f.readline()
        ##         self.assertEqual(expected, got)
        ##         self.assertEqual(f.lineno, i)
        ##         self.assertEqual(f.ateof, (i > len(lines)))
        ##     f.close()
        ## finally:
        ##     try:
        ##         f.close()
        ##     except:
        ##         pass
        ##     support.unlink(support.TESTFN)

    def test_keywords(self):
        # Testing keyword args to basic type constructors ...
        self.assertEqual(int(x=1), 1)
        self.assertEqual(float(x=2), 2.0)
        self.assertEqual(int(x=3), 3)
        self.assertEqual(complex(imag=42, real=666), complex(666, 42))
        self.assertEqual(str(object=500), '500')
        self.assertEqual(str(object=b'abc', errors='strict'), 'abc')
        self.assertEqual(tuple(sequence=range(3)), (0, 1, 2))
        self.assertEqual(list(sequence=(0, 1, 2)), list(range(3)))
        # note: as of Python 2.3, dict() no longer has an "items" keyword arg

        for constructor in (int, float, int, complex, str, str,
                            tuple, list):
            try:
                constructor(bogus_keyword_arg=1)
            except TypeError:
                pass
            else:
                self.fail("expected TypeError from bogus keyword argument to %r"
                            % constructor)

    def test_str_subclass_as_dict_key(self):
        # Testing a str subclass used as dict key ..

        class cistr(str):
            """Sublcass of str that computes __eq__ case-insensitively.

            Also computes a hash code of the string in canonical form.
            """

            def __init__(self, value):
                self.canonical = value.lower()
                self.hashcode = hash(self.canonical)

            def __eq__(self, other):
                if not isinstance(other, cistr):
                    other = cistr(other)
                return self.canonical == other.canonical

            def __hash__(self):
                return self.hashcode

        self.assertEqual(cistr('ABC'), 'abc')
        self.assertEqual('aBc', cistr('ABC'))
        self.assertEqual(str(cistr('ABC')), 'ABC')

        d = {cistr('one'): 1, cistr('two'): 2, cistr('tHree'): 3}
        self.assertEqual(d[cistr('one')], 1)
        self.assertEqual(d[cistr('tWo')], 2)
        self.assertEqual(d[cistr('THrEE')], 3)
        self.assertIn(cistr('ONe'), d)
        self.assertEqual(d.get(cistr('thrEE')), 3)

    def test_classic_comparisons(self):
        # Testing classic comparisons...
        class classic:
            pass

        for base in (classic, int, object):
            class C(base):
                def __init__(self, value):
                    self.value = int(value)
                def __eq__(self, other):
                    if isinstance(other, C):
                        return self.value == other.value
                    if isinstance(other, int) or isinstance(other, int):
                        return self.value == other
                    return NotImplemented
                def __ne__(self, other):
                    if isinstance(other, C):
                        return self.value != other.value
                    if isinstance(other, int) or isinstance(other, int):
                        return self.value != other
                    return NotImplemented
                def __lt__(self, other):
                    if isinstance(other, C):
                        return self.value < other.value
                    if isinstance(other, int) or isinstance(other, int):
                        return self.value < other
                    return NotImplemented
                def __le__(self, other):
                    if isinstance(other, C):
                        return self.value <= other.value
                    if isinstance(other, int) or isinstance(other, int):
                        return self.value <= other
                    return NotImplemented
                def __gt__(self, other):
                    if isinstance(other, C):
                        return self.value > other.value
                    if isinstance(other, int) or isinstance(other, int):
                        return self.value > other
                    return NotImplemented
                def __ge__(self, other):
                    if isinstance(other, C):
                        return self.value >= other.value
                    if isinstance(other, int) or isinstance(other, int):
                        return self.value >= other
                    return NotImplemented

            c1 = C(1)
            c2 = C(2)
            c3 = C(3)
            self.assertEqual(c1, 1)
            c = {1: c1, 2: c2, 3: c3}
            for x in 1, 2, 3:
                for y in 1, 2, 3:
                    for op in "<", "<=", "==", "!=", ">", ">=":
                        self.assertEqual(eval("c[x] %s c[y]" % op),
                                     eval("x %s y" % op),
                                     "x=%d, y=%d" % (x, y))
                        self.assertEqual(eval("c[x] %s y" % op),
                                     eval("x %s y" % op),
                                     "x=%d, y=%d" % (x, y))
                        self.assertEqual(eval("x %s c[y]" % op),
                                     eval("x %s y" % op),
                                     "x=%d, y=%d" % (x, y))

    def test_rich_comparisons(self):
        # Testing rich comparisons...
        class Z(complex):
            pass
        z = Z(1)
        self.assertEqual(z, 1+0j)
        self.assertEqual(1+0j, z)
        class ZZ(complex):
            def __eq__(self, other):
                try:
                    return abs(self - other) <= 1e-6
                except:
                    return NotImplemented
        zz = ZZ(1.0000003)
        self.assertEqual(zz, 1+0j)
        self.assertEqual(1+0j, zz)

        class classic:
            pass
        for base in (classic, int, object, list):
            class C(base):
                def __init__(self, value):
                    self.value = int(value)
                def __cmp__(self_, other):
                    self.fail("shouldn't call __cmp__")
                def __eq__(self, other):
                    if isinstance(other, C):
                        return self.value == other.value
                    if isinstance(other, int) or isinstance(other, int):
                        return self.value == other
                    return NotImplemented
                def __ne__(self, other):
                    if isinstance(other, C):
                        return self.value != other.value
                    if isinstance(other, int) or isinstance(other, int):
                        return self.value != other
                    return NotImplemented
                def __lt__(self, other):
                    if isinstance(other, C):
                        return self.value < other.value
                    if isinstance(other, int) or isinstance(other, int):
                        return self.value < other
                    return NotImplemented
                def __le__(self, other):
                    if isinstance(other, C):
                        return self.value <= other.value
                    if isinstance(other, int) or isinstance(other, int):
                        return self.value <= other
                    return NotImplemented
                def __gt__(self, other):
                    if isinstance(other, C):
                        return self.value > other.value
                    if isinstance(other, int) or isinstance(other, int):
                        return self.value > other
                    return NotImplemented
                def __ge__(self, other):
                    if isinstance(other, C):
                        return self.value >= other.value
                    if isinstance(other, int) or isinstance(other, int):
                        return self.value >= other
                    return NotImplemented
            c1 = C(1)
            c2 = C(2)
            c3 = C(3)
            self.assertEqual(c1, 1)
            c = {1: c1, 2: c2, 3: c3}
            for x in 1, 2, 3:
                for y in 1, 2, 3:
                    for op in "<", "<=", "==", "!=", ">", ">=":
                        self.assertEqual(eval("c[x] %s c[y]" % op),
                                         eval("x %s y" % op),
                                         "x=%d, y=%d" % (x, y))
                        self.assertEqual(eval("c[x] %s y" % op),
                                         eval("x %s y" % op),
                                         "x=%d, y=%d" % (x, y))
                        self.assertEqual(eval("x %s c[y]" % op),
                                         eval("x %s y" % op),
                                         "x=%d, y=%d" % (x, y))

    def test_descrdoc(self):
        # Testing descriptor doc strings...
        from _io import FileIO
        def check(descr, what):
            self.assertEqual(descr.__doc__, what)
        check(FileIO.closed, "True if the file is closed") # getset descriptor
        check(complex.real, "the real part of a complex number") # member descriptor

    def test_doc_descriptor(self):
        # Testing __doc__ descriptor...
        # SF bug 542984
        class DocDescr(object):
            def __get__(self, object, otype):
                if object:
                    object = object.__class__.__name__ + ' instance'
                if otype:
                    otype = otype.__name__
                return 'object=%s; type=%s' % (object, otype)
        class OldClass:
            __doc__ = DocDescr()
        class NewClass(object):
            __doc__ = DocDescr()
        self.assertEqual(OldClass.__doc__, 'object=None; type=OldClass')
        self.assertEqual(OldClass().__doc__, 'object=OldClass instance; type=OldClass')
        self.assertEqual(NewClass.__doc__, 'object=None; type=NewClass')
        self.assertEqual(NewClass().__doc__, 'object=NewClass instance; type=NewClass')

    def test_set_class(self):
        # Testing __class__ assignment...
        class C(object): pass
        class D(object): pass
        class E(object): pass
        class F(D, E): pass
        for cls in C, D, E, F:
            for cls2 in C, D, E, F:
                x = cls()
                x.__class__ = cls2
                self.assertIs(x.__class__, cls2)
                x.__class__ = cls
                self.assertIs(x.__class__, cls)
        def cant(x, C):
            try:
                x.__class__ = C
            except TypeError:
                pass
            else:
                self.fail("shouldn't allow %r.__class__ = %r" % (x, C))
            try:
                delattr(x, "__class__")
            except (TypeError, AttributeError):
                pass
            else:
                self.fail("shouldn't allow del %r.__class__" % x)
        cant(C(), list)
        cant(list(), C)
        cant(C(), 1)
        cant(C(), object)
        cant(object(), list)
        cant(list(), object)
        class Int(int): __slots__ = []
        cant(True, int)
        cant(2, bool)
        o = object()
        cant(o, type(1))
        cant(o, type(None))
        del o
        class G(object):
            __slots__ = ["a", "b"]
        class H(object):
            __slots__ = ["b", "a"]
        class I(object):
            __slots__ = ["a", "b"]
        class J(object):
            __slots__ = ["c", "b"]
        class K(object):
            __slots__ = ["a", "b", "d"]
        class L(H):
            __slots__ = ["e"]
        class M(I):
            __slots__ = ["e"]
        class N(J):
            __slots__ = ["__weakref__"]
        class P(J):
            __slots__ = ["__dict__"]
        class Q(J):
            pass
        class R(J):
            __slots__ = ["__dict__", "__weakref__"]

        for cls, cls2 in ((G, H), (G, I), (I, H), (Q, R), (R, Q)):
            x = cls()
            x.a = 1
            x.__class__ = cls2
            self.assertIs(x.__class__, cls2,
                   "assigning %r as __class__ for %r silently failed" % (cls2, x))
            self.assertEqual(x.a, 1)
            x.__class__ = cls
            self.assertIs(x.__class__, cls,
                   "assigning %r as __class__ for %r silently failed" % (cls, x))
            self.assertEqual(x.a, 1)
        for cls in G, J, K, L, M, N, P, R, list, Int:
            for cls2 in G, J, K, L, M, N, P, R, list, Int:
                if cls is cls2:
                    continue
                cant(cls(), cls2)

        # Issue5283: when __class__ changes in __del__, the wrong
        # type gets DECREF'd.
        class O(object):
            pass
        class A(object):
            def __del__(self):
                self.__class__ = O
        l = [A() for x in range(100)]
        del l

    def test_set_dict(self):
        # Testing __dict__ assignment...
        class C(object): pass
        a = C()
        a.__dict__ = {'b': 1}
        self.assertEqual(a.b, 1)
        def cant(x, dict):
            try:
                x.__dict__ = dict
            except (AttributeError, TypeError):
                pass
            else:
                self.fail("shouldn't allow %r.__dict__ = %r" % (x, dict))
        cant(a, None)
        cant(a, [])
        cant(a, 1)
        del a.__dict__ # Deleting __dict__ is allowed

        class Base(object):
            pass
        def verify_dict_readonly(x):
            """
            x has to be an instance of a class inheriting from Base.
            """
            cant(x, {})
            try:
                del x.__dict__
            except (AttributeError, TypeError):
                pass
            else:
                self.fail("shouldn't allow del %r.__dict__" % x)
            dict_descr = Base.__dict__["__dict__"]
            try:
                dict_descr.__set__(x, {})
            except (AttributeError, TypeError):
                pass
            else:
                self.fail("dict_descr allowed access to %r's dict" % x)

        # Classes don't allow __dict__ assignment and have readonly dicts
        class Meta1(type, Base):
            pass
        class Meta2(Base, type):
            pass
        class D(object, metaclass=Meta1):
            pass
        class E(object, metaclass=Meta2):
            pass
        for cls in C, D, E:
            verify_dict_readonly(cls)
            class_dict = cls.__dict__
            try:
                class_dict["spam"] = "eggs"
            except TypeError:
                pass
            else:
                self.fail("%r's __dict__ can be modified" % cls)

        # Modules also disallow __dict__ assignment
        class Module1(types.ModuleType, Base):
            pass
        class Module2(Base, types.ModuleType):
            pass
        for ModuleType in Module1, Module2:
            mod = ModuleType("spam")
            verify_dict_readonly(mod)
            mod.__dict__["spam"] = "eggs"

        # Exception's __dict__ can be replaced, but not deleted
        # (at least not any more than regular exception's __dict__ can
        # be deleted; on CPython it is not the case, whereas on PyPy they
        # can, just like any other new-style instance's __dict__.)
        def can_delete_dict(e):
            try:
                del e.__dict__
            except (TypeError, AttributeError):
                return False
            else:
                return True
        class Exception1(Exception, Base):
            pass
        class Exception2(Base, Exception):
            pass
        for ExceptionType in Exception, Exception1, Exception2:
            e = ExceptionType()
            e.__dict__ = {"a": 1}
            self.assertEqual(e.a, 1)
            self.assertEqual(can_delete_dict(e), can_delete_dict(ValueError()))

    def test_binary_operator_override(self):
        # Testing overrides of binary operations...
        class I(int):
            def __repr__(self):
                return "I(%r)" % int(self)
            def __add__(self, other):
                return I(int(self) + int(other))
            __radd__ = __add__
            def __pow__(self, other, mod=None):
                if mod is None:
                    return I(pow(int(self), int(other)))
                else:
                    return I(pow(int(self), int(other), int(mod)))
            def __rpow__(self, other, mod=None):
                if mod is None:
                    return I(pow(int(other), int(self), mod))
                else:
                    return I(pow(int(other), int(self), int(mod)))

        self.assertEqual(repr(I(1) + I(2)), "I(3)")
        self.assertEqual(repr(I(1) + 2), "I(3)")
        self.assertEqual(repr(1 + I(2)), "I(3)")
        self.assertEqual(repr(I(2) ** I(3)), "I(8)")
        self.assertEqual(repr(2 ** I(3)), "I(8)")
        self.assertEqual(repr(I(2) ** 3), "I(8)")
        self.assertEqual(repr(pow(I(2), I(3), I(5))), "I(3)")
        class S(str):
            def __eq__(self, other):
                return self.lower() == other.lower()

    def test_subclass_propagation(self):
        # Testing propagation of slot functions to subclasses...
        class A(object):
            pass
        class B(A):
            pass
        class C(A):
            pass
        class D(B, C):
            pass
        d = D()
        orig_hash = hash(d) # related to id(d) in platform-dependent ways
        A.__hash__ = lambda self: 42
        self.assertEqual(hash(d), 42)
        C.__hash__ = lambda self: 314
        self.assertEqual(hash(d), 314)
        B.__hash__ = lambda self: 144
        self.assertEqual(hash(d), 144)
        D.__hash__ = lambda self: 100
        self.assertEqual(hash(d), 100)
        D.__hash__ = None
        self.assertRaises(TypeError, hash, d)
        del D.__hash__
        self.assertEqual(hash(d), 144)
        B.__hash__ = None
        self.assertRaises(TypeError, hash, d)
        del B.__hash__
        self.assertEqual(hash(d), 314)
        C.__hash__ = None
        self.assertRaises(TypeError, hash, d)
        del C.__hash__
        self.assertEqual(hash(d), 42)
        A.__hash__ = None
        self.assertRaises(TypeError, hash, d)
        del A.__hash__
        self.assertEqual(hash(d), orig_hash)
        d.foo = 42
        d.bar = 42
        self.assertEqual(d.foo, 42)
        self.assertEqual(d.bar, 42)
        def __getattribute__(self, name):
            if name == "foo":
                return 24
            return object.__getattribute__(self, name)
        A.__getattribute__ = __getattribute__
        self.assertEqual(d.foo, 24)
        self.assertEqual(d.bar, 42)
        def __getattr__(self, name):
            if name in ("spam", "foo", "bar"):
                return "hello"
            raise AttributeError(name)
        B.__getattr__ = __getattr__
        self.assertEqual(d.spam, "hello")
        self.assertEqual(d.foo, 24)
        self.assertEqual(d.bar, 42)
        del A.__getattribute__
        self.assertEqual(d.foo, 42)
        del d.foo
        self.assertEqual(d.foo, "hello")
        self.assertEqual(d.bar, 42)
        del B.__getattr__
        try:
            d.foo
        except AttributeError:
            pass
        else:
            self.fail("d.foo should be undefined now")

        # Test a nasty bug in recurse_down_subclasses()
        class A(object):
            pass
        class B(A):
            pass
        del B
        support.gc_collect()
        A.__setitem__ = lambda *a: None # crash

    def test_buffer_inheritance(self):
        # Testing that buffer interface is inherited ...

        import binascii
        # SF bug [#470040] ParseTuple t# vs subclasses.

        class MyBytes(bytes):
            pass
        base = b'abc'
        m = MyBytes(base)
        # b2a_hex uses the buffer interface to get its argument's value, via
        # PyArg_ParseTuple 't#' code.
        self.assertEqual(binascii.b2a_hex(m), binascii.b2a_hex(base))

        class MyInt(int):
            pass
        m = MyInt(42)
        try:
            binascii.b2a_hex(m)
            self.fail('subclass of int should not have a buffer interface')
        except TypeError:
            pass

    def test_str_of_str_subclass(self):
        # Testing __str__ defined in subclass of str ...
        import binascii
        import io

        class octetstring(str):
            def __str__(self):
                return binascii.b2a_hex(self.encode('ascii')).decode("ascii")
            def __repr__(self):
                return self + " repr"

        o = octetstring('A')
        self.assertEqual(type(o), octetstring)
        self.assertEqual(type(str(o)), str)
        self.assertEqual(type(repr(o)), str)
        self.assertEqual(ord(o), 0x41)
        self.assertEqual(str(o), '41')
        self.assertEqual(repr(o), 'A repr')
        self.assertEqual(o.__str__(), '41')
        self.assertEqual(o.__repr__(), 'A repr')

        capture = io.StringIO()
        # Calling str() or not exercises different internal paths.
        print(o, file=capture)
        print(str(o), file=capture)
        self.assertEqual(capture.getvalue(), '41\n41\n')
        capture.close()

    def test_keyword_arguments(self):
        # Testing keyword arguments to __init__, __call__...
        def f(a): return a
        self.assertEqual(f.__call__(a=42), 42)
        a = []
        list.__init__(a, sequence=[0, 1, 2])
        self.assertEqual(a, [0, 1, 2])

    def test_recursive_call(self):
        # Testing recursive __call__() by setting to instance of class...
        class A(object):
            pass

        A.__call__ = A()
        try:
            A()()
        except RecursionError:
            pass
        else:
            self.fail("Recursion limit should have been reached for __call__()")

    def test_delete_hook(self):
        # Testing __del__ hook...
        log = []
        class C(object):
            def __del__(self):
                log.append(1)
        c = C()
        self.assertEqual(log, [])
        del c
        support.gc_collect()
        self.assertEqual(log, [1])

        class D(object): pass
        d = D()
        try: del d[0]
        except TypeError: pass
        else: self.fail("invalid del() didn't raise TypeError")

    def test_hash_inheritance(self):
        # Testing hash of mutable subclasses...

        class mydict(dict):
            pass
        d = mydict()
        try:
            hash(d)
        except TypeError:
            pass
        else:
            self.fail("hash() of dict subclass should fail")

        class mylist(list):
            pass
        d = mylist()
        try:
            hash(d)
        except TypeError:
            pass
        else:
            self.fail("hash() of list subclass should fail")

    def test_str_operations(self):
        try: 'a' + 5
        except TypeError: pass
        else: self.fail("'' + 5 doesn't raise TypeError")

        try: ''.split('')
        except ValueError: pass
        else: self.fail("''.split('') doesn't raise ValueError")

        try: ''.join([0])
        except TypeError: pass
        else: self.fail("''.join([0]) doesn't raise TypeError")

        try: ''.rindex('5')
        except ValueError: pass
        else: self.fail("''.rindex('5') doesn't raise ValueError")

        try: '%(n)s' % None
        except TypeError: pass
        else: self.fail("'%(n)s' % None doesn't raise TypeError")

        try: '%(n' % {}
        except ValueError: pass
        else: self.fail("'%(n' % {} '' doesn't raise ValueError")

        try: '%*s' % ('abc')
        except TypeError: pass
        else: self.fail("'%*s' % ('abc') doesn't raise TypeError")

        try: '%*.*s' % ('abc', 5)
        except TypeError: pass
        else: self.fail("'%*.*s' % ('abc', 5) doesn't raise TypeError")

        try: '%s' % (1, 2)
        except TypeError: pass
        else: self.fail("'%s' % (1, 2) doesn't raise TypeError")

        try: '%' % None
        except ValueError: pass
        else: self.fail("'%' % None doesn't raise ValueError")

        self.assertEqual('534253'.isdigit(), 1)
        self.assertEqual('534253x'.isdigit(), 0)
        self.assertEqual('%c' % 5, '\x05')
        self.assertEqual('%c' % '5', '5')

    def test_deepcopy_recursive(self):
        # Testing deepcopy of recursive objects...
        class Node:
            pass
        a = Node()
        b = Node()
        a.b = b
        b.a = a
        z = deepcopy(a) # This blew up before

    def test_uninitialized_modules(self):
        # Testing uninitialized module objects...
        from types import ModuleType as M
        m = M.__new__(M)
        str(m)
        self.assertNotHasAttr(m, "__name__")
        self.assertNotHasAttr(m, "__file__")
        self.assertNotHasAttr(m, "foo")
        self.assertFalse(m.__dict__)   # None or {} are both reasonable answers
        m.foo = 1
        self.assertEqual(m.__dict__, {"foo": 1})

    def test_funny_new(self):
        # Testing __new__ returning something unexpected...
        class C(object):
            def __new__(cls, arg):
                if isinstance(arg, str): return [1, 2, 3]
                elif isinstance(arg, int): return object.__new__(D)
                else: return object.__new__(cls)
        class D(C):
            def __init__(self, arg):
                self.foo = arg
        self.assertEqual(C("1"), [1, 2, 3])
        self.assertEqual(D("1"), [1, 2, 3])
        d = D(None)
        self.assertEqual(d.foo, None)
        d = C(1)
        self.assertIsInstance(d, D)
        self.assertEqual(d.foo, 1)
        d = D(1)
        self.assertIsInstance(d, D)
        self.assertEqual(d.foo, 1)

        class C(object):
            @staticmethod
            def __new__(*args):
                return args
        self.assertEqual(C(1, 2), (C, 1, 2))
        class D(C):
            pass
        self.assertEqual(D(1, 2), (D, 1, 2))

        class C(object):
            @classmethod
            def __new__(*args):
                return args
        self.assertEqual(C(1, 2), (C, C, 1, 2))
        class D(C):
            pass
        self.assertEqual(D(1, 2), (D, D, 1, 2))

    def test_imul_bug(self):
        # Testing for __imul__ problems...
        # SF bug 544647
        class C(object):
            def __imul__(self, other):
                return (self, other)
        x = C()
        y = x
        y *= 1.0
        self.assertEqual(y, (x, 1.0))
        y = x
        y *= 2
        self.assertEqual(y, (x, 2))
        y = x
        y *= 3
        self.assertEqual(y, (x, 3))
        y = x
        y *= 1<<100
        self.assertEqual(y, (x, 1<<100))
        y = x
        y *= None
        self.assertEqual(y, (x, None))
        y = x
        y *= "foo"
        self.assertEqual(y, (x, "foo"))

    def test_copy_setstate(self):
        # Testing that copy.*copy() correctly uses __setstate__...
        import copy
        class C(object):
            def __init__(self, foo=None):
                self.foo = foo
                self.__foo = foo
            def setfoo(self, foo=None):
                self.foo = foo
            def getfoo(self):
                return self.__foo
            def __getstate__(self):
                return [self.foo]
            def __setstate__(self_, lst):
                self.assertEqual(len(lst), 1)
                self_.__foo = self_.foo = lst[0]
        a = C(42)
        a.setfoo(24)
        self.assertEqual(a.foo, 24)
        self.assertEqual(a.getfoo(), 42)
        b = copy.copy(a)
        self.assertEqual(b.foo, 24)
        self.assertEqual(b.getfoo(), 24)
        b = copy.deepcopy(a)
        self.assertEqual(b.foo, 24)
        self.assertEqual(b.getfoo(), 24)

    def test_slices(self):
        # Testing cases with slices and overridden __getitem__ ...

        # Strings
        self.assertEqual("hello"[:4], "hell")
        self.assertEqual("hello"[slice(4)], "hell")
        self.assertEqual(str.__getitem__("hello", slice(4)), "hell")
        class S(str):
            def __getitem__(self, x):
                return str.__getitem__(self, x)
        self.assertEqual(S("hello")[:4], "hell")
        self.assertEqual(S("hello")[slice(4)], "hell")
        self.assertEqual(S("hello").__getitem__(slice(4)), "hell")
        # Tuples
        self.assertEqual((1,2,3)[:2], (1,2))
        self.assertEqual((1,2,3)[slice(2)], (1,2))
        self.assertEqual(tuple.__getitem__((1,2,3), slice(2)), (1,2))
        class T(tuple):
            def __getitem__(self, x):
                return tuple.__getitem__(self, x)
        self.assertEqual(T((1,2,3))[:2], (1,2))
        self.assertEqual(T((1,2,3))[slice(2)], (1,2))
        self.assertEqual(T((1,2,3)).__getitem__(slice(2)), (1,2))
        # Lists
        self.assertEqual([1,2,3][:2], [1,2])
        self.assertEqual([1,2,3][slice(2)], [1,2])
        self.assertEqual(list.__getitem__([1,2,3], slice(2)), [1,2])
        class L(list):
            def __getitem__(self, x):
                return list.__getitem__(self, x)
        self.assertEqual(L([1,2,3])[:2], [1,2])
        self.assertEqual(L([1,2,3])[slice(2)], [1,2])
        self.assertEqual(L([1,2,3]).__getitem__(slice(2)), [1,2])
        # Now do lists and __setitem__
        a = L([1,2,3])
        a[slice(1, 3)] = [3,2]
        self.assertEqual(a, [1,3,2])
        a[slice(0, 2, 1)] = [3,1]
        self.assertEqual(a, [3,1,2])
        a.__setitem__(slice(1, 3), [2,1])
        self.assertEqual(a, [3,2,1])
        a.__setitem__(slice(0, 2, 1), [2,3])
        self.assertEqual(a, [2,3,1])

    def test_subtype_resurrection(self):
        # Testing resurrection of new-style instance...

        class C(object):
            container = []

            def __del__(self):
                # resurrect the instance
                C.container.append(self)

        c = C()
        c.attr = 42

        # The most interesting thing here is whether this blows up, due to
        # flawed GC tracking logic in typeobject.c's call_finalizer() (a 2.2.1
        # bug).
        del c

        support.gc_collect()
        self.assertEqual(len(C.container), 1)

        # Make c mortal again, so that the test framework with -l doesn't report
        # it as a leak.
        del C.__del__

    def test_slots_trash(self):
        # Testing slot trash...
        # Deallocating deeply nested slotted trash caused stack overflows
        class trash(object):
            __slots__ = ['x']
            def __init__(self, x):
                self.x = x
        o = None
        for i in range(50000):
            o = trash(o)
        del o

    def test_slots_multiple_inheritance(self):
        # SF bug 575229, multiple inheritance w/ slots dumps core
        class A(object):
            __slots__=()
        class B(object):
            pass
        class C(A,B) :
            __slots__=()
        if support.check_impl_detail():
            self.assertEqual(C.__basicsize__, B.__basicsize__)
        self.assertHasAttr(C, '__dict__')
        self.assertHasAttr(C, '__weakref__')
        C().x = 2

    def test_rmul(self):
        # Testing correct invocation of __rmul__...
        # SF patch 592646
        class C(object):
            def __mul__(self, other):
                return "mul"
            def __rmul__(self, other):
                return "rmul"
        a = C()
        self.assertEqual(a*2, "mul")
        self.assertEqual(a*2.2, "mul")
        self.assertEqual(2*a, "rmul")
        self.assertEqual(2.2*a, "rmul")

    def test_ipow(self):
        # Testing correct invocation of __ipow__...
        # [SF bug 620179]
        class C(object):
            def __ipow__(self, other):
                pass
        a = C()
        a **= 2

    def test_mutable_bases(self):
        # Testing mutable bases...

        # stuff that should work:
        class C(object):
            pass
        class C2(object):
            def __getattribute__(self, attr):
                if attr == 'a':
                    return 2
                else:
                    return super(C2, self).__getattribute__(attr)
            def meth(self):
                return 1
        class D(C):
            pass
        class E(D):
            pass
        d = D()
        e = E()
        D.__bases__ = (C,)
        D.__bases__ = (C2,)
        self.assertEqual(d.meth(), 1)
        self.assertEqual(e.meth(), 1)
        self.assertEqual(d.a, 2)
        self.assertEqual(e.a, 2)
        self.assertEqual(C2.__subclasses__(), [D])

        try:
            del D.__bases__
        except (TypeError, AttributeError):
            pass
        else:
            self.fail("shouldn't be able to delete .__bases__")

        try:
            D.__bases__ = ()
        except TypeError as msg:
            if str(msg) == "a new-style class can't have only classic bases":
                self.fail("wrong error message for .__bases__ = ()")
        else:
            self.fail("shouldn't be able to set .__bases__ to ()")

        try:
            D.__bases__ = (D,)
        except TypeError:
            pass
        else:
            # actually, we'll have crashed by here...
            self.fail("shouldn't be able to create inheritance cycles")

        try:
            D.__bases__ = (C, C)
        except TypeError:
            pass
        else:
            self.fail("didn't detect repeated base classes")

        try:
            D.__bases__ = (E,)
        except TypeError:
            pass
        else:
            self.fail("shouldn't be able to create inheritance cycles")

    def test_builtin_bases(self):
        # Make sure all the builtin types can have their base queried without
        # segfaulting. See issue #5787.
        builtin_types = [tp for tp in builtins.__dict__.values()
                         if isinstance(tp, type)]
        for tp in builtin_types:
            object.__getattribute__(tp, "__bases__")
            if tp is not object:
                self.assertEqual(len(tp.__bases__), 1, tp)

        class L(list):
            pass

        class C(object):
            pass

        class D(C):
            pass

        try:
            L.__bases__ = (dict,)
        except TypeError:
            pass
        else:
            self.fail("shouldn't turn list subclass into dict subclass")

        try:
            list.__bases__ = (dict,)
        except TypeError:
            pass
        else:
            self.fail("shouldn't be able to assign to list.__bases__")

        try:
            D.__bases__ = (C, list)
        except TypeError:
            pass
        else:
            assert 0, "best_base calculation found wanting"

    def test_unsubclassable_types(self):
        with self.assertRaises(TypeError):
            class X(type(None)):
                pass
        with self.assertRaises(TypeError):
            class X(object, type(None)):
                pass
        with self.assertRaises(TypeError):
            class X(type(None), object):
                pass
        class O(object):
            pass
        with self.assertRaises(TypeError):
            class X(O, type(None)):
                pass
        with self.assertRaises(TypeError):
            class X(type(None), O):
                pass

        class X(object):
            pass
        with self.assertRaises(TypeError):
            X.__bases__ = type(None),
        with self.assertRaises(TypeError):
            X.__bases__ = object, type(None)
        with self.assertRaises(TypeError):
            X.__bases__ = type(None), object
        with self.assertRaises(TypeError):
            X.__bases__ = O, type(None)
        with self.assertRaises(TypeError):
            X.__bases__ = type(None), O

    def test_mutable_bases_with_failing_mro(self):
        # Testing mutable bases with failing mro...
        class WorkOnce(type):
            def __new__(self, name, bases, ns):
                self.flag = 0
                return super(WorkOnce, self).__new__(WorkOnce, name, bases, ns)
            def mro(self):
                if self.flag > 0:
                    raise RuntimeError("bozo")
                else:
                    self.flag += 1
                    return type.mro(self)

        class WorkAlways(type):
            def mro(self):
                # this is here to make sure that .mro()s aren't called
                # with an exception set (which was possible at one point).
                # An error message will be printed in a debug build.
                # What's a good way to test for this?
                return type.mro(self)

        class C(object):
            pass

        class C2(object):
            pass

        class D(C):
            pass

        class E(D):
            pass

        class F(D, metaclass=WorkOnce):
            pass

        class G(D, metaclass=WorkAlways):
            pass

        # Immediate subclasses have their mro's adjusted in alphabetical
        # order, so E's will get adjusted before adjusting F's fails.  We
        # check here that E's gets restored.

        E_mro_before = E.__mro__
        D_mro_before = D.__mro__

        try:
            D.__bases__ = (C2,)
        except RuntimeError:
            self.assertEqual(E.__mro__, E_mro_before)
            self.assertEqual(D.__mro__, D_mro_before)
        else:
            self.fail("exception not propagated")

    def test_mutable_bases_catch_mro_conflict(self):
        # Testing mutable bases catch mro conflict...
        class A(object):
            pass

        class B(object):
            pass

        class C(A, B):
            pass

        class D(A, B):
            pass

        class E(C, D):
            pass

        try:
            C.__bases__ = (B, A)
        except TypeError:
            pass
        else:
            self.fail("didn't catch MRO conflict")

    def test_mutable_names(self):
        # Testing mutable names...
        class C(object):
            pass

        # C.__module__ could be 'test_descr' or '__main__'
        mod = C.__module__

        C.__name__ = 'D'
        self.assertEqual((C.__module__, C.__name__), (mod, 'D'))

        C.__name__ = 'D.E'
        self.assertEqual((C.__module__, C.__name__), (mod, 'D.E'))

    def test_evil_type_name(self):
        # A badly placed Py_DECREF in type_set_name led to arbitrary code
        # execution while the type structure was not in a sane state, and a
        # possible segmentation fault as a result.  See bug #16447.
        class Nasty(str):
            def __del__(self):
                C.__name__ = "other"

        class C:
            pass

        C.__name__ = Nasty("abc")
        C.__name__ = "normal"

    def test_subclass_right_op(self):
        # Testing correct dispatch of subclass overloading __r<op>__...

        # This code tests various cases where right-dispatch of a subclass
        # should be preferred over left-dispatch of a base class.

        # Case 1: subclass of int; this tests code in abstract.c::binary_op1()

        class B(int):
            def __floordiv__(self, other):
                return "B.__floordiv__"
            def __rfloordiv__(self, other):
                return "B.__rfloordiv__"

        self.assertEqual(B(1) // 1, "B.__floordiv__")
        self.assertEqual(1 // B(1), "B.__rfloordiv__")

        # Case 2: subclass of object; this is just the baseline for case 3

        class C(object):
            def __floordiv__(self, other):
                return "C.__floordiv__"
            def __rfloordiv__(self, other):
                return "C.__rfloordiv__"

        self.assertEqual(C() // 1, "C.__floordiv__")
        self.assertEqual(1 // C(), "C.__rfloordiv__")

        # Case 3: subclass of new-style class; here it gets interesting

        class D(C):
            def __floordiv__(self, other):
                return "D.__floordiv__"
            def __rfloordiv__(self, other):
                return "D.__rfloordiv__"

        self.assertEqual(D() // C(), "D.__floordiv__")
        self.assertEqual(C() // D(), "D.__rfloordiv__")

        # Case 4: this didn't work right in 2.2.2 and 2.3a1

        class E(C):
            pass

        self.assertEqual(E.__rfloordiv__, C.__rfloordiv__)

        self.assertEqual(E() // 1, "C.__floordiv__")
        self.assertEqual(1 // E(), "C.__rfloordiv__")
        self.assertEqual(E() // C(), "C.__floordiv__")
        self.assertEqual(C() // E(), "C.__floordiv__") # This one would fail

    @support.impl_detail("testing an internal kind of method object")
    def test_meth_class_get(self):
        # Testing __get__ method of METH_CLASS C methods...
        # Full coverage of descrobject.c::classmethod_get()

        # Baseline
        arg = [1, 2, 3]
        res = {1: None, 2: None, 3: None}
        self.assertEqual(dict.fromkeys(arg), res)
        self.assertEqual({}.fromkeys(arg), res)

        # Now get the descriptor
        descr = dict.__dict__["fromkeys"]

        # More baseline using the descriptor directly
        self.assertEqual(descr.__get__(None, dict)(arg), res)
        self.assertEqual(descr.__get__({})(arg), res)

        # Now check various error cases
        try:
            descr.__get__(None, None)
        except TypeError:
            pass
        else:
            self.fail("shouldn't have allowed descr.__get__(None, None)")
        try:
            descr.__get__(42)
        except TypeError:
            pass
        else:
            self.fail("shouldn't have allowed descr.__get__(42)")
        try:
            descr.__get__(None, 42)
        except TypeError:
            pass
        else:
            self.fail("shouldn't have allowed descr.__get__(None, 42)")
        try:
            descr.__get__(None, int)
        except TypeError:
            pass
        else:
            self.fail("shouldn't have allowed descr.__get__(None, int)")

    def test_isinst_isclass(self):
        # Testing proxy isinstance() and isclass()...
        class Proxy(object):
            def __init__(self, obj):
                self.__obj = obj
            def __getattribute__(self, name):
                if name.startswith("_Proxy__"):
                    return object.__getattribute__(self, name)
                else:
                    return getattr(self.__obj, name)
        # Test with a classic class
        class C:
            pass
        a = C()
        pa = Proxy(a)
        self.assertIsInstance(a, C)  # Baseline
        self.assertIsInstance(pa, C) # Test
        # Test with a classic subclass
        class D(C):
            pass
        a = D()
        pa = Proxy(a)
        self.assertIsInstance(a, C)  # Baseline
        self.assertIsInstance(pa, C) # Test
        # Test with a new-style class
        class C(object):
            pass
        a = C()
        pa = Proxy(a)
        self.assertIsInstance(a, C)  # Baseline
        self.assertIsInstance(pa, C) # Test
        # Test with a new-style subclass
        class D(C):
            pass
        a = D()
        pa = Proxy(a)
        self.assertIsInstance(a, C)  # Baseline
        self.assertIsInstance(pa, C) # Test

    def test_proxy_super(self):
        # Testing super() for a proxy object...
        class Proxy(object):
            def __init__(self, obj):
                self.__obj = obj
            def __getattribute__(self, name):
                if name.startswith("_Proxy__"):
                    return object.__getattribute__(self, name)
                else:
                    return getattr(self.__obj, name)

        class B(object):
            def f(self):
                return "B.f"

        class C(B):
            def f(self):
                return super(C, self).f() + "->C.f"

        obj = C()
        p = Proxy(obj)
        self.assertEqual(C.__dict__["f"](p), "B.f->C.f")

    def test_carloverre(self):
        # Testing prohibition of Carlo Verre's hack...
        try:
            object.__setattr__(str, "foo", 42)
        except TypeError:
            pass
        else:
            self.fail("Carlo Verre __setattr__ succeeded!")
        try:
            object.__delattr__(str, "lower")
        except TypeError:
            pass
        else:
            self.fail("Carlo Verre __delattr__ succeeded!")

    def test_weakref_segfault(self):
        # Testing weakref segfault...
        # SF 742911
        import weakref

        class Provoker:
            def __init__(self, referrent):
                self.ref = weakref.ref(referrent)

            def __del__(self):
                x = self.ref()

        class Oops(object):
            pass

        o = Oops()
        o.whatever = Provoker(o)
        del o

    def test_wrapper_segfault(self):
        # SF 927248: deeply nested wrappers could cause stack overflow
        f = lambda:None
        for i in range(1000000):
            f = f.__call__
        f = None

    def test_file_fault(self):
        # Testing sys.stdout is changed in getattr...
        test_stdout = sys.stdout
        class StdoutGuard:
            def __getattr__(self, attr):
                sys.stdout = sys.__stdout__
                raise RuntimeError("Premature access to sys.stdout.%s" % attr)
        sys.stdout = StdoutGuard()
        try:
            print("Oops!")
        except RuntimeError:
            pass
        finally:
            sys.stdout = test_stdout

    def test_vicious_descriptor_nonsense(self):
        # Testing vicious_descriptor_nonsense...

        # A potential segfault spotted by Thomas Wouters in mail to
        # python-dev 2003-04-17, turned into an example & fixed by Michael
        # Hudson just less than four months later...

        class Evil(object):
            def __hash__(self):
                return hash('attr')
            def __eq__(self, other):
                del C.attr
                return 0

        class Descr(object):
            def __get__(self, ob, type=None):
                return 1

        class C(object):
            attr = Descr()

        c = C()
        c.__dict__[Evil()] = 0

        self.assertEqual(c.attr, 1)
        # this makes a crash more likely:
        support.gc_collect()
        self.assertNotHasAttr(c, 'attr')

    def test_init(self):
        # SF 1155938
        class Foo(object):
            def __init__(self):
                return 10
        try:
            Foo()
        except TypeError:
            pass
        else:
            self.fail("did not test __init__() for None return")

    def test_method_wrapper(self):
        # Testing method-wrapper objects...
        # <type 'method-wrapper'> did not support any reflection before 2.5

        # XXX should methods really support __eq__?

        l = []
        self.assertEqual(l.__add__, l.__add__)
        self.assertEqual(l.__add__, [].__add__)
        self.assertNotEqual(l.__add__, [5].__add__)
        self.assertNotEqual(l.__add__, l.__mul__)
        self.assertEqual(l.__add__.__name__, '__add__')
        if hasattr(l.__add__, '__self__'):
            # CPython
            self.assertIs(l.__add__.__self__, l)
            self.assertIs(l.__add__.__objclass__, list)
        else:
            # Python implementations where [].__add__ is a normal bound method
            self.assertIs(l.__add__.im_self, l)
            self.assertIs(l.__add__.im_class, list)
        self.assertEqual(l.__add__.__doc__, list.__add__.__doc__)
        try:
            hash(l.__add__)
        except TypeError:
            pass
        else:
            self.fail("no TypeError from hash([].__add__)")

        t = ()
        t += (7,)
        self.assertEqual(t.__add__, (7,).__add__)
        self.assertEqual(hash(t.__add__), hash((7,).__add__))

    def test_not_implemented(self):
        # Testing NotImplemented...
        # all binary methods should be able to return a NotImplemented
        import operator

        def specialmethod(self, other):
            return NotImplemented

        def check(expr, x, y):
            try:
                exec(expr, {'x': x, 'y': y, 'operator': operator})
            except TypeError:
                pass
            else:
                self.fail("no TypeError from %r" % (expr,))

        N1 = sys.maxsize + 1    # might trigger OverflowErrors instead of
                                # TypeErrors
        N2 = sys.maxsize         # if sizeof(int) < sizeof(long), might trigger
                                #   ValueErrors instead of TypeErrors
        for name, expr, iexpr in [
                ('__add__',      'x + y',                   'x += y'),
                ('__sub__',      'x - y',                   'x -= y'),
                ('__mul__',      'x * y',                   'x *= y'),
                ('__matmul__',   'x @ y',                   'x @= y'),
                ('__truediv__',  'x / y',                   'x /= y'),
                ('__floordiv__', 'x // y',                  'x //= y'),
                ('__mod__',      'x % y',                   'x %= y'),
                ('__divmod__',   'divmod(x, y)',            None),
                ('__pow__',      'x ** y',                  'x **= y'),
                ('__lshift__',   'x << y',                  'x <<= y'),
                ('__rshift__',   'x >> y',                  'x >>= y'),
                ('__and__',      'x & y',                   'x &= y'),
                ('__or__',       'x | y',                   'x |= y'),
                ('__xor__',      'x ^ y',                   'x ^= y')]:
            rname = '__r' + name[2:]
            A = type('A', (), {name: specialmethod})
            a = A()
            check(expr, a, a)
            check(expr, a, N1)
            check(expr, a, N2)
            if iexpr:
                check(iexpr, a, a)
                check(iexpr, a, N1)
                check(iexpr, a, N2)
                iname = '__i' + name[2:]
                C = type('C', (), {iname: specialmethod})
                c = C()
                check(iexpr, c, a)
                check(iexpr, c, N1)
                check(iexpr, c, N2)

    def test_assign_slice(self):
        # ceval.c's assign_slice used to check for
        # tp->tp_as_sequence->sq_slice instead of
        # tp->tp_as_sequence->sq_ass_slice

        class C(object):
            def __setitem__(self, idx, value):
                self.value = value

        c = C()
        c[1:2] = 3
        self.assertEqual(c.value, 3)

    def test_set_and_no_get(self):
        # See
        # http://mail.python.org/pipermail/python-dev/2010-January/095637.html
        class Descr(object):

            def __init__(self, name):
                self.name = name

            def __set__(self, obj, value):
                obj.__dict__[self.name] = value
        descr = Descr("a")

        class X(object):
            a = descr

        x = X()
        self.assertIs(x.a, descr)
        x.a = 42
        self.assertEqual(x.a, 42)

        # Also check type_getattro for correctness.
        class Meta(type):
            pass
        class X(metaclass=Meta):
            pass
        X.a = 42
        Meta.a = Descr("a")
        self.assertEqual(X.a, 42)

    def test_getattr_hooks(self):
        # issue 4230

        class Descriptor(object):
            counter = 0
            def __get__(self, obj, objtype=None):
                def getter(name):
                    self.counter += 1
                    raise AttributeError(name)
                return getter

        descr = Descriptor()
        class A(object):
            __getattribute__ = descr
        class B(object):
            __getattr__ = descr
        class C(object):
            __getattribute__ = descr
            __getattr__ = descr

        self.assertRaises(AttributeError, getattr, A(), "attr")
        self.assertEqual(descr.counter, 1)
        self.assertRaises(AttributeError, getattr, B(), "attr")
        self.assertEqual(descr.counter, 2)
        self.assertRaises(AttributeError, getattr, C(), "attr")
        self.assertEqual(descr.counter, 4)

        class EvilGetattribute(object):
            # This used to segfault
            def __getattr__(self, name):
                raise AttributeError(name)
            def __getattribute__(self, name):
                del EvilGetattribute.__getattr__
                for i in range(5):
                    gc.collect()
                raise AttributeError(name)

        self.assertRaises(AttributeError, getattr, EvilGetattribute(), "attr")

    def test_type___getattribute__(self):
        self.assertRaises(TypeError, type.__getattribute__, list, type)

    def test_abstractmethods(self):
        # type pretends not to have __abstractmethods__.
        self.assertRaises(AttributeError, getattr, type, "__abstractmethods__")
        class meta(type):
            pass
        self.assertRaises(AttributeError, getattr, meta, "__abstractmethods__")
        class X(object):
            pass
        with self.assertRaises(AttributeError):
            del X.__abstractmethods__

    def test_proxy_call(self):
        class FakeStr:
            __class__ = str

        fake_str = FakeStr()
        # isinstance() reads __class__
        self.assertIsInstance(fake_str, str)

        # call a method descriptor
        with self.assertRaises(TypeError):
            str.split(fake_str)

        # call a slot wrapper descriptor
        with self.assertRaises(TypeError):
            str.__add__(fake_str, "abc")

    def test_repr_as_str(self):
        # Issue #11603: crash or infinite loop when rebinding __str__ as
        # __repr__.
        class Foo:
            pass
        Foo.__repr__ = Foo.__str__
        foo = Foo()
        self.assertRaises(RecursionError, str, foo)
        self.assertRaises(RecursionError, repr, foo)

    def test_mixing_slot_wrappers(self):
        class X(dict):
            __setattr__ = dict.__setitem__
        x = X()
        x.y = 42
        self.assertEqual(x["y"], 42)

    def test_slot_shadows_class_variable(self):
        with self.assertRaises(ValueError) as cm:
            class X:
                __slots__ = ["foo"]
                foo = None
        m = str(cm.exception)
        self.assertEqual("'foo' in __slots__ conflicts with class variable", m)

    def test_set_doc(self):
        class X:
            "elephant"
        X.__doc__ = "banana"
        self.assertEqual(X.__doc__, "banana")
        with self.assertRaises(TypeError) as cm:
            type(list).__dict__["__doc__"].__set__(list, "blah")
        self.assertIn("can't set list.__doc__", str(cm.exception))
        with self.assertRaises(TypeError) as cm:
            type(X).__dict__["__doc__"].__delete__(X)
        self.assertIn("can't delete X.__doc__", str(cm.exception))
        self.assertEqual(X.__doc__, "banana")

    def test_qualname(self):
        descriptors = [str.lower, complex.real, float.real, int.__add__]
        types = ['method', 'member', 'getset', 'wrapper']

        # make sure we have an example of each type of descriptor
        for d, n in zip(descriptors, types):
            self.assertEqual(type(d).__name__, n + '_descriptor')

        for d in descriptors:
            qualname = d.__objclass__.__qualname__ + '.' + d.__name__
            self.assertEqual(d.__qualname__, qualname)

        self.assertEqual(str.lower.__qualname__, 'str.lower')
        self.assertEqual(complex.real.__qualname__, 'complex.real')
        self.assertEqual(float.real.__qualname__, 'float.real')
        self.assertEqual(int.__add__.__qualname__, 'int.__add__')

        class X:
            pass
        with self.assertRaises(TypeError):
            del X.__qualname__

        self.assertRaises(TypeError, type.__dict__['__qualname__'].__set__,
                          str, 'Oink')

        global Y
        class Y:
            class Inside:
                pass
        self.assertEqual(Y.__qualname__, 'Y')
        self.assertEqual(Y.Inside.__qualname__, 'Y.Inside')

    def test_qualname_dict(self):
        ns = {'__qualname__': 'some.name'}
        tp = type('Foo', (), ns)
        self.assertEqual(tp.__qualname__, 'some.name')
        self.assertNotIn('__qualname__', tp.__dict__)
        self.assertEqual(ns, {'__qualname__': 'some.name'})

        ns = {'__qualname__': 1}
        self.assertRaises(TypeError, type, 'Foo', (), ns)

    def test_cycle_through_dict(self):
        # See bug #1469629
        class X(dict):
            def __init__(self):
                dict.__init__(self)
                self.__dict__ = self
        x = X()
        x.attr = 42
        wr = weakref.ref(x)
        del x
        support.gc_collect()
        self.assertIsNone(wr())
        for o in gc.get_objects():
            self.assertIsNot(type(o), X)

    def test_object_new_and_init_with_parameters(self):
        # See issue #1683368
        class OverrideNeither:
            pass
        self.assertRaises(TypeError, OverrideNeither, 1)
        self.assertRaises(TypeError, OverrideNeither, kw=1)
        class OverrideNew:
            def __new__(cls, foo, kw=0, *args, **kwds):
                return object.__new__(cls, *args, **kwds)
        class OverrideInit:
            def __init__(self, foo, kw=0, *args, **kwargs):
                return object.__init__(self, *args, **kwargs)
        class OverrideBoth(OverrideNew, OverrideInit):
            pass
        for case in OverrideNew, OverrideInit, OverrideBoth:
            case(1)
            case(1, kw=2)
            self.assertRaises(TypeError, case, 1, 2, 3)
            self.assertRaises(TypeError, case, 1, 2, foo=3)

    def test_subclassing_does_not_duplicate_dict_descriptors(self):
        class Base:
            pass
        class Sub(Base):
            pass
        self.assertIn("__dict__", Base.__dict__)
        self.assertNotIn("__dict__", Sub.__dict__)

    def test_bound_method_repr(self):
        class Foo:
            def method(self):
                pass
        self.assertRegex(repr(Foo().method),
            r"<bound method .*Foo\.method of <.*Foo object at .*>>")


        class Base:
            def method(self):
                pass
        class Derived1(Base):
            pass
        class Derived2(Base):
            def method(self):
                pass
        base = Base()
        derived1 = Derived1()
        derived2 = Derived2()
        super_d2 = super(Derived2, derived2)
        self.assertRegex(repr(base.method),
            r"<bound method .*Base\.method of <.*Base object at .*>>")
        self.assertRegex(repr(derived1.method),
            r"<bound method .*Base\.method of <.*Derived1 object at .*>>")
        self.assertRegex(repr(derived2.method),
            r"<bound method .*Derived2\.method of <.*Derived2 object at .*>>")
        self.assertRegex(repr(super_d2.method),
            r"<bound method .*Base\.method of <.*Derived2 object at .*>>")

        class Foo:
            @classmethod
            def method(cls):
                pass
        foo = Foo()
        self.assertRegex(repr(foo.method), # access via instance
            r"<bound method .*Foo\.method of <class '.*Foo'>>")
        self.assertRegex(repr(Foo.method), # access via the class
            r"<bound method .*Foo\.method of <class '.*Foo'>>")


        class MyCallable:
            def __call__(self, arg):
                pass
        func = MyCallable() # func has no __name__ or __qualname__ attributes
        instance = object()
        method = types.MethodType(func, instance)
        self.assertRegex(repr(method),
            r"<bound method \? of <object object at .*>>")
        func.__name__ = "name"
        self.assertRegex(repr(method),
            r"<bound method name of <object object at .*>>")
        func.__qualname__ = "qualname"
        self.assertRegex(repr(method),
            r"<bound method qualname of <object object at .*>>")


class DictProxyTests(unittest.TestCase):
    def setUp(self):
        class C(object):
            def meth(self):
                pass
        self.C = C

    @unittest.skipIf(hasattr(sys, 'gettrace') and sys.gettrace(),
                        'trace function introduces __local__')
    def test_iter_keys(self):
        # Testing dict-proxy keys...
        it = self.C.__dict__.keys()
        self.assertNotIsInstance(it, list)
        keys = list(it)
        keys.sort()
        self.assertEqual(keys, ['__dict__', '__doc__', '__module__',
                                '__weakref__', 'meth'])

    @unittest.skipIf(hasattr(sys, 'gettrace') and sys.gettrace(),
                        'trace function introduces __local__')
    def test_iter_values(self):
        # Testing dict-proxy values...
        it = self.C.__dict__.values()
        self.assertNotIsInstance(it, list)
        values = list(it)
        self.assertEqual(len(values), 5)

    @unittest.skipIf(hasattr(sys, 'gettrace') and sys.gettrace(),
                        'trace function introduces __local__')
    def test_iter_items(self):
        # Testing dict-proxy iteritems...
        it = self.C.__dict__.items()
        self.assertNotIsInstance(it, list)
        keys = [item[0] for item in it]
        keys.sort()
        self.assertEqual(keys, ['__dict__', '__doc__', '__module__',
                                '__weakref__', 'meth'])

    def test_dict_type_with_metaclass(self):
        # Testing type of __dict__ when metaclass set...
        class B(object):
            pass
        class M(type):
            pass
        class C(metaclass=M):
            # In 2.3a1, C.__dict__ was a real dict rather than a dict proxy
            pass
        self.assertEqual(type(C.__dict__), type(B.__dict__))

    def test_repr(self):
        # Testing mappingproxy.__repr__.
        # We can't blindly compare with the repr of another dict as ordering
        # of keys and values is arbitrary and may differ.
        r = repr(self.C.__dict__)
        self.assertTrue(r.startswith('mappingproxy('), r)
        self.assertTrue(r.endswith(')'), r)
        for k, v in self.C.__dict__.items():
            self.assertIn('{!r}: {!r}'.format(k, v), r)


class PTypesLongInitTest(unittest.TestCase):
    # This is in its own TestCase so that it can be run before any other tests.
    def test_pytype_long_ready(self):
        # Testing SF bug 551412 ...

        # This dumps core when SF bug 551412 isn't fixed --
        # but only when test_descr.py is run separately.
        # (That can't be helped -- as soon as PyType_Ready()
        # is called for PyLong_Type, the bug is gone.)
        class UserLong(object):
            def __pow__(self, *args):
                pass
        try:
            pow(0, UserLong(), 0)
        except:
            pass

        # Another segfault only when run early
        # (before PyType_Ready(tuple) is called)
        type.mro(tuple)


class MiscTests(unittest.TestCase):
    def test_type_lookup_mro_reference(self):
        # Issue #14199: _PyType_Lookup() has to keep a strong reference to
        # the type MRO because it may be modified during the lookup, if
        # __bases__ is set during the lookup for example.
        class MyKey(object):
            def __hash__(self):
                return hash('mykey')

            def __eq__(self, other):
                X.__bases__ = (Base2,)

        class Base(object):
            mykey = 'from Base'
            mykey2 = 'from Base'

        class Base2(object):
            mykey = 'from Base2'
            mykey2 = 'from Base2'

        X = type('X', (Base,), {MyKey(): 5})
        # mykey is read from Base
        self.assertEqual(X.mykey, 'from Base')
        # mykey2 is read from Base2 because MyKey.__eq__ has set __bases__
        self.assertEqual(X.mykey2, 'from Base2')


class PicklingTests(unittest.TestCase):

    def _check_reduce(self, proto, obj, args=(), kwargs={}, state=None,
                      listitems=None, dictitems=None):
        if proto >= 2:
            reduce_value = obj.__reduce_ex__(proto)
            if kwargs:
                self.assertEqual(reduce_value[0], copyreg.__newobj_ex__)
                self.assertEqual(reduce_value[1], (type(obj), args, kwargs))
            else:
                self.assertEqual(reduce_value[0], copyreg.__newobj__)
                self.assertEqual(reduce_value[1], (type(obj),) + args)
            self.assertEqual(reduce_value[2], state)
            if listitems is not None:
                self.assertListEqual(list(reduce_value[3]), listitems)
            else:
                self.assertIsNone(reduce_value[3])
            if dictitems is not None:
                self.assertDictEqual(dict(reduce_value[4]), dictitems)
            else:
                self.assertIsNone(reduce_value[4])
        else:
            base_type = type(obj).__base__
            reduce_value = (copyreg._reconstructor,
                            (type(obj),
                             base_type,
                             None if base_type is object else base_type(obj)))
            if state is not None:
                reduce_value += (state,)
            self.assertEqual(obj.__reduce_ex__(proto), reduce_value)
            self.assertEqual(obj.__reduce__(), reduce_value)

    def test_reduce(self):
        protocols = range(pickle.HIGHEST_PROTOCOL + 1)
        args = (-101, "spam")
        kwargs = {'bacon': -201, 'fish': -301}
        state = {'cheese': -401}

        class C1:
            def __getnewargs__(self):
                return args
        obj = C1()
        for proto in protocols:
            self._check_reduce(proto, obj, args)

        for name, value in state.items():
            setattr(obj, name, value)
        for proto in protocols:
            self._check_reduce(proto, obj, args, state=state)

        class C2:
            def __getnewargs__(self):
                return "bad args"
        obj = C2()
        for proto in protocols:
            if proto >= 2:
                with self.assertRaises(TypeError):
                    obj.__reduce_ex__(proto)

        class C3:
            def __getnewargs_ex__(self):
                return (args, kwargs)
        obj = C3()
        for proto in protocols:
            if proto >= 2:
                self._check_reduce(proto, obj, args, kwargs)

        class C4:
            def __getnewargs_ex__(self):
                return (args, "bad dict")
        class C5:
            def __getnewargs_ex__(self):
                return ("bad tuple", kwargs)
        class C6:
            def __getnewargs_ex__(self):
                return ()
        class C7:
            def __getnewargs_ex__(self):
                return "bad args"
        for proto in protocols:
            for cls in C4, C5, C6, C7:
                obj = cls()
                if proto >= 2:
                    with self.assertRaises((TypeError, ValueError)):
                        obj.__reduce_ex__(proto)

        class C9:
            def __getnewargs_ex__(self):
                return (args, {})
        obj = C9()
        for proto in protocols:
            self._check_reduce(proto, obj, args)

        class C10:
            def __getnewargs_ex__(self):
                raise IndexError
        obj = C10()
        for proto in protocols:
            if proto >= 2:
                with self.assertRaises(IndexError):
                    obj.__reduce_ex__(proto)

        class C11:
            def __getstate__(self):
                return state
        obj = C11()
        for proto in protocols:
            self._check_reduce(proto, obj, state=state)

        class C12:
            def __getstate__(self):
                return "not dict"
        obj = C12()
        for proto in protocols:
            self._check_reduce(proto, obj, state="not dict")

        class C13:
            def __getstate__(self):
                raise IndexError
        obj = C13()
        for proto in protocols:
            with self.assertRaises(IndexError):
                obj.__reduce_ex__(proto)
            if proto < 2:
                with self.assertRaises(IndexError):
                    obj.__reduce__()

        class C14:
            __slots__ = tuple(state)
            def __init__(self):
                for name, value in state.items():
                    setattr(self, name, value)

        obj = C14()
        for proto in protocols:
            if proto >= 2:
                self._check_reduce(proto, obj, state=(None, state))
            else:
                with self.assertRaises(TypeError):
                    obj.__reduce_ex__(proto)
                with self.assertRaises(TypeError):
                    obj.__reduce__()

        class C15(dict):
            pass
        obj = C15({"quebec": -601})
        for proto in protocols:
            self._check_reduce(proto, obj, dictitems=dict(obj))

        class C16(list):
            pass
        obj = C16(["yukon"])
        for proto in protocols:
            self._check_reduce(proto, obj, listitems=list(obj))

    def test_special_method_lookup(self):
        protocols = range(pickle.HIGHEST_PROTOCOL + 1)
        class Picky:
            def __getstate__(self):
                return {}

            def __getattr__(self, attr):
                if attr in ("__getnewargs__", "__getnewargs_ex__"):
                    raise AssertionError(attr)
                return None
        for protocol in protocols:
            state = {} if protocol >= 2 else None
            self._check_reduce(protocol, Picky(), state=state)

    def _assert_is_copy(self, obj, objcopy, msg=None):
        """Utility method to verify if two objects are copies of each others.
        """
        if msg is None:
            msg = "{!r} is not a copy of {!r}".format(obj, objcopy)
        if type(obj).__repr__ is object.__repr__:
            # We have this limitation for now because we use the object's repr
            # to help us verify that the two objects are copies. This allows
            # us to delegate the non-generic verification logic to the objects
            # themselves.
            raise ValueError("object passed to _assert_is_copy must " +
                             "override the __repr__ method.")
        self.assertIsNot(obj, objcopy, msg=msg)
        self.assertIs(type(obj), type(objcopy), msg=msg)
        if hasattr(obj, '__dict__'):
            self.assertDictEqual(obj.__dict__, objcopy.__dict__, msg=msg)
            self.assertIsNot(obj.__dict__, objcopy.__dict__, msg=msg)
        if hasattr(obj, '__slots__'):
            self.assertListEqual(obj.__slots__, objcopy.__slots__, msg=msg)
            for slot in obj.__slots__:
                self.assertEqual(
                    hasattr(obj, slot), hasattr(objcopy, slot), msg=msg)
                self.assertEqual(getattr(obj, slot, None),
                                 getattr(objcopy, slot, None), msg=msg)
        self.assertEqual(repr(obj), repr(objcopy), msg=msg)

    @staticmethod
    def _generate_pickle_copiers():
        """Utility method to generate the many possible pickle configurations.
        """
        class PickleCopier:
            "This class copies object using pickle."
            def __init__(self, proto, dumps, loads):
                self.proto = proto
                self.dumps = dumps
                self.loads = loads
            def copy(self, obj):
                return self.loads(self.dumps(obj, self.proto))
            def __repr__(self):
                # We try to be as descriptive as possible here since this is
                # the string which we will allow us to tell the pickle
                # configuration we are using during debugging.
                return ("PickleCopier(proto={}, dumps={}.{}, loads={}.{})"
                        .format(self.proto,
                                self.dumps.__module__, self.dumps.__qualname__,
                                self.loads.__module__, self.loads.__qualname__))
        return (PickleCopier(*args) for args in
                   itertools.product(range(pickle.HIGHEST_PROTOCOL + 1),
                                     {pickle.dumps, pickle._dumps},
                                     {pickle.loads, pickle._loads}))

    def test_pickle_slots(self):
        # Tests pickling of classes with __slots__.

        # Pickling of classes with __slots__ but without __getstate__ should
        # fail (if using protocol 0 or 1)
        global C
        class C:
            __slots__ = ['a']
        with self.assertRaises(TypeError):
            pickle.dumps(C(), 0)

        global D
        class D(C):
            pass
        with self.assertRaises(TypeError):
            pickle.dumps(D(), 0)

        class C:
            "A class with __getstate__ and __setstate__ implemented."
            __slots__ = ['a']
            def __getstate__(self):
                state = getattr(self, '__dict__', {}).copy()
                for cls in type(self).__mro__:
                    for slot in cls.__dict__.get('__slots__', ()):
                        try:
                            state[slot] = getattr(self, slot)
                        except AttributeError:
                            pass
                return state
            def __setstate__(self, state):
                for k, v in state.items():
                    setattr(self, k, v)
            def __repr__(self):
                return "%s()<%r>" % (type(self).__name__, self.__getstate__())

        class D(C):
            "A subclass of a class with slots."
            pass

        global E
        class E(C):
            "A subclass with an extra slot."
            __slots__ = ['b']

        # Now it should work
        for pickle_copier in self._generate_pickle_copiers():
            with self.subTest(pickle_copier=pickle_copier):
                x = C()
                y = pickle_copier.copy(x)
                self._assert_is_copy(x, y)

                x.a = 42
                y = pickle_copier.copy(x)
                self._assert_is_copy(x, y)

                x = D()
                x.a = 42
                x.b = 100
                y = pickle_copier.copy(x)
                self._assert_is_copy(x, y)

                x = E()
                x.a = 42
                x.b = "foo"
                y = pickle_copier.copy(x)
                self._assert_is_copy(x, y)

    def test_reduce_copying(self):
        # Tests pickling and copying new-style classes and objects.
        global C1
        class C1:
            "The state of this class is copyable via its instance dict."
            ARGS = (1, 2)
            NEED_DICT_COPYING = True
            def __init__(self, a, b):
                super().__init__()
                self.a = a
                self.b = b
            def __repr__(self):
                return "C1(%r, %r)" % (self.a, self.b)

        global C2
        class C2(list):
            "A list subclass copyable via __getnewargs__."
            ARGS = (1, 2)
            NEED_DICT_COPYING = False
            def __new__(cls, a, b):
                self = super().__new__(cls)
                self.a = a
                self.b = b
                return self
            def __init__(self, *args):
                super().__init__()
                # This helps testing that __init__ is not called during the
                # unpickling process, which would cause extra appends.
                self.append("cheese")
            @classmethod
            def __getnewargs__(cls):
                return cls.ARGS
            def __repr__(self):
                return "C2(%r, %r)<%r>" % (self.a, self.b, list(self))

        global C3
        class C3(list):
            "A list subclass copyable via __getstate__."
            ARGS = (1, 2)
            NEED_DICT_COPYING = False
            def __init__(self, a, b):
                self.a = a
                self.b = b
                # This helps testing that __init__ is not called during the
                # unpickling process, which would cause extra appends.
                self.append("cheese")
            @classmethod
            def __getstate__(cls):
                return cls.ARGS
            def __setstate__(self, state):
                a, b = state
                self.a = a
                self.b = b
            def __repr__(self):
                return "C3(%r, %r)<%r>" % (self.a, self.b, list(self))

        global C4
        class C4(int):
            "An int subclass copyable via __getnewargs__."
            ARGS = ("hello", "world", 1)
            NEED_DICT_COPYING = False
            def __new__(cls, a, b, value):
                self = super().__new__(cls, value)
                self.a = a
                self.b = b
                return self
            @classmethod
            def __getnewargs__(cls):
                return cls.ARGS
            def __repr__(self):
                return "C4(%r, %r)<%r>" % (self.a, self.b, int(self))

        global C5
        class C5(int):
            "An int subclass copyable via __getnewargs_ex__."
            ARGS = (1, 2)
            KWARGS = {'value': 3}
            NEED_DICT_COPYING = False
            def __new__(cls, a, b, *, value=0):
                self = super().__new__(cls, value)
                self.a = a
                self.b = b
                return self
            @classmethod
            def __getnewargs_ex__(cls):
                return (cls.ARGS, cls.KWARGS)
            def __repr__(self):
                return "C5(%r, %r)<%r>" % (self.a, self.b, int(self))

        test_classes = (C1, C2, C3, C4, C5)
        # Testing copying through pickle
        pickle_copiers = self._generate_pickle_copiers()
        for cls, pickle_copier in itertools.product(test_classes, pickle_copiers):
            with self.subTest(cls=cls, pickle_copier=pickle_copier):
                kwargs = getattr(cls, 'KWARGS', {})
                obj = cls(*cls.ARGS, **kwargs)
                proto = pickle_copier.proto
                objcopy = pickle_copier.copy(obj)
                self._assert_is_copy(obj, objcopy)
                # For test classes that supports this, make sure we didn't go
                # around the reduce protocol by simply copying the attribute
                # dictionary. We clear attributes using the previous copy to
                # not mutate the original argument.
                if proto >= 2 and not cls.NEED_DICT_COPYING:
                    objcopy.__dict__.clear()
                    objcopy2 = pickle_copier.copy(objcopy)
                    self._assert_is_copy(obj, objcopy2)

        # Testing copying through copy.deepcopy()
        for cls in test_classes:
            with self.subTest(cls=cls):
                kwargs = getattr(cls, 'KWARGS', {})
                obj = cls(*cls.ARGS, **kwargs)
                objcopy = deepcopy(obj)
                self._assert_is_copy(obj, objcopy)
                # For test classes that supports this, make sure we didn't go
                # around the reduce protocol by simply copying the attribute
                # dictionary. We clear attributes using the previous copy to
                # not mutate the original argument.
                if not cls.NEED_DICT_COPYING:
                    objcopy.__dict__.clear()
                    objcopy2 = deepcopy(objcopy)
                    self._assert_is_copy(obj, objcopy2)

    def test_issue24097(self):
        # Slot name is freed inside __getattr__ and is later used.
        class S(str):  # Not interned
            pass
        class A:
            __slotnames__ = [S('spam')]
            def __getattr__(self, attr):
                if attr == 'spam':
                    A.__slotnames__[:] = [S('spam')]
                    return 42
                else:
                    raise AttributeError

        import copyreg
        expected = (copyreg.__newobj__, (A,), (None, {'spam': 42}), None, None)
        self.assertEqual(A().__reduce__(2), expected)  # Shouldn't crash


class SharedKeyTests(unittest.TestCase):

    @support.cpython_only
    def test_subclasses(self):
        # Verify that subclasses can share keys (per PEP 412)
        class A:
            pass
        class B(A):
            pass

        a, b = A(), B()
        self.assertEqual(sys.getsizeof(vars(a)), sys.getsizeof(vars(b)))
        self.assertLess(sys.getsizeof(vars(a)), sys.getsizeof({}))
        # Initial hash table can contain at most 5 elements.
        # Set 6 attributes to cause internal resizing.
        a.x, a.y, a.z, a.w, a.v, a.u = range(6)
        self.assertNotEqual(sys.getsizeof(vars(a)), sys.getsizeof(vars(b)))
        a2 = A()
        self.assertEqual(sys.getsizeof(vars(a)), sys.getsizeof(vars(a2)))
        self.assertLess(sys.getsizeof(vars(a)), sys.getsizeof({}))
        b.u, b.v, b.w, b.t, b.s, b.r = range(6)
        self.assertLess(sys.getsizeof(vars(b)), sys.getsizeof({}))


class DebugHelperMeta(type):
    """
    Sets default __doc__ and simplifies repr() output.
    """
    def __new__(mcls, name, bases, attrs):
        if attrs.get('__doc__') is None:
            attrs['__doc__'] = name  # helps when debugging with gdb
        return type.__new__(mcls, name, bases, attrs)
    def __repr__(cls):
        return repr(cls.__name__)


class MroTest(unittest.TestCase):
    """
    Regressions for some bugs revealed through
    mcsl.mro() customization (typeobject.c: mro_internal()) and
    cls.__bases__ assignment (typeobject.c: type_set_bases()).
    """

    def setUp(self):
        self.step = 0
        self.ready = False

    def step_until(self, limit):
        ret = (self.step < limit)
        if ret:
            self.step += 1
        return ret

    def test_incomplete_set_bases_on_self(self):
        """
        type_set_bases must be aware that type->tp_mro can be NULL.
        """
        class M(DebugHelperMeta):
            def mro(cls):
                if self.step_until(1):
                    assert cls.__mro__ is None
                    cls.__bases__ += ()

                return type.mro(cls)

        class A(metaclass=M):
            pass

    def test_reent_set_bases_on_base(self):
        """
        Deep reentrancy must not over-decref old_mro.
        """
        class M(DebugHelperMeta):
            def mro(cls):
                if cls.__mro__ is not None and cls.__name__ == 'B':
                    # 4-5 steps are usually enough to make it crash somewhere
                    if self.step_until(10):
                        A.__bases__ += ()

                return type.mro(cls)

        class A(metaclass=M):
            pass
        class B(A):
            pass
        B.__bases__ += ()

    def test_reent_set_bases_on_direct_base(self):
        """
        Similar to test_reent_set_bases_on_base, but may crash differently.
        """
        class M(DebugHelperMeta):
            def mro(cls):
                base = cls.__bases__[0]
                if base is not object:
                    if self.step_until(5):
                        base.__bases__ += ()

                return type.mro(cls)

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

    def test_reent_set_bases_tp_base_cycle(self):
        """
        type_set_bases must check for an inheritance cycle not only through
        MRO of the type, which may be not yet updated in case of reentrance,
        but also through tp_base chain, which is assigned before diving into
        inner calls to mro().

        Otherwise, the following snippet can loop forever:
            do {
                // ...
                type = type->tp_base;
            } while (type != NULL);

        Functions that rely on tp_base (like solid_base and PyType_IsSubtype)
        would not be happy in that case, causing a stack overflow.
        """
        class M(DebugHelperMeta):
            def mro(cls):
                if self.ready:
                    if cls.__name__ == 'B1':
                        B2.__bases__ = (B1,)
                    if cls.__name__ == 'B2':
                        B1.__bases__ = (B2,)
                return type.mro(cls)

        class A(metaclass=M):
            pass
        class B1(A):
            pass
        class B2(A):
            pass

        self.ready = True
        with self.assertRaises(TypeError):
            B1.__bases__ += ()

    def test_tp_subclasses_cycle_in_update_slots(self):
        """
        type_set_bases must check for reentrancy upon finishing its job
        by updating tp_subclasses of old/new bases of the type.
        Otherwise, an implicit inheritance cycle through tp_subclasses
        can break functions that recurse on elements of that field
        (like recurse_down_subclasses and mro_hierarchy) eventually
        leading to a stack overflow.
        """
        class M(DebugHelperMeta):
            def mro(cls):
                if self.ready and cls.__name__ == 'C':
                    self.ready = False
                    C.__bases__ = (B2,)
                return type.mro(cls)

        class A(metaclass=M):
            pass
        class B1(A):
            pass
        class B2(A):
            pass
        class C(A):
            pass

        self.ready = True
        C.__bases__ = (B1,)
        B1.__bases__ = (C,)

        self.assertEqual(C.__bases__, (B2,))
        self.assertEqual(B2.__subclasses__(), [C])
        self.assertEqual(B1.__subclasses__(), [])

        self.assertEqual(B1.__bases__, (C,))
        self.assertEqual(C.__subclasses__(), [B1])

    def test_tp_subclasses_cycle_error_return_path(self):
        """
        The same as test_tp_subclasses_cycle_in_update_slots, but tests
        a code path executed on error (goto bail).
        """
        class E(Exception):
            pass
        class M(DebugHelperMeta):
            def mro(cls):
                if self.ready and cls.__name__ == 'C':
                    if C.__bases__ == (B2,):
                        self.ready = False
                    else:
                        C.__bases__ = (B2,)
                        raise E
                return type.mro(cls)

        class A(metaclass=M):
            pass
        class B1(A):
            pass
        class B2(A):
            pass
        class C(A):
            pass

        self.ready = True
        with self.assertRaises(E):
            C.__bases__ = (B1,)
        B1.__bases__ = (C,)

        self.assertEqual(C.__bases__, (B2,))
        self.assertEqual(C.__mro__, tuple(type.mro(C)))

    def test_incomplete_extend(self):
        """
        Extending an unitialized type with type->tp_mro == NULL must
        throw a reasonable TypeError exception, instead of failing
        with PyErr_BadInternalCall.
        """
        class M(DebugHelperMeta):
            def mro(cls):
                if cls.__mro__ is None and cls.__name__ != 'X':
                    with self.assertRaises(TypeError):
                        class X(cls):
                            pass

                return type.mro(cls)

        class A(metaclass=M):
            pass

    def test_incomplete_super(self):
        """
        Attrubute lookup on a super object must be aware that
        its target type can be uninitialized (type->tp_mro == NULL).
        """
        class M(DebugHelperMeta):
            def mro(cls):
                if cls.__mro__ is None:
                    with self.assertRaises(AttributeError):
                        super(cls, cls).xxx

                return type.mro(cls)

        class A(metaclass=M):
            pass


def test_main():
    # Run all local test cases, with PTypesLongInitTest first.
    support.run_unittest(PTypesLongInitTest, OperatorsTest,
                         ClassPropertiesAndMethods, DictProxyTests,
                         MiscTests, PicklingTests, SharedKeyTests,
                         MroTest)

if __name__ == "__main__":
    test_main()