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cpython/Lib/test/test_descr.py

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Merge of descr-branch back into trunk.
2001-08-02 01:15:00 -03:00
# Test descriptor-related enhancements
SF bug [#460467] file objects should be subclassable. Preliminary support. What's here works, but needs fine-tuning.
2001-09-13 02:38:56 -03:00
from test_support import verify, verbose, TestFailed, TESTFN
Merge of descr-branch back into trunk.
2001-08-02 01:15:00 -03:00
from copy import deepcopy
def testunop(a, res, expr="len(a)", meth="__len__"):
if verbose: print "checking", expr
dict = {'a': a}
verify(eval(expr, dict) == res)
t = type(a)
m = getattr(t, meth)
verify(m == t.__dict__[meth])
verify(m(a) == res)
bm = getattr(a, meth)
verify(bm() == res)
def testbinop(a, b, res, expr="a+b", meth="__add__"):
if verbose: print "checking", expr
dict = {'a': a, 'b': b}
verify(eval(expr, dict) == res)
t = type(a)
m = getattr(t, meth)
verify(m == t.__dict__[meth])
verify(m(a, b) == res)
bm = getattr(a, meth)
verify(bm(b) == res)
def testternop(a, b, c, res, expr="a[b:c]", meth="__getslice__"):
if verbose: print "checking", expr
dict = {'a': a, 'b': b, 'c': c}
verify(eval(expr, dict) == res)
t = type(a)
m = getattr(t, meth)
verify(m == t.__dict__[meth])
verify(m(a, b, c) == res)
bm = getattr(a, meth)
verify(bm(b, c) == res)
def testsetop(a, b, res, stmt="a+=b", meth="__iadd__"):
if verbose: print "checking", stmt
dict = {'a': deepcopy(a), 'b': b}
exec stmt in dict
verify(dict['a'] == res)
t = type(a)
m = getattr(t, meth)
verify(m == t.__dict__[meth])
dict['a'] = deepcopy(a)
m(dict['a'], b)
verify(dict['a'] == res)
dict['a'] = deepcopy(a)
bm = getattr(dict['a'], meth)
bm(b)
verify(dict['a'] == res)
def testset2op(a, b, c, res, stmt="a[b]=c", meth="__setitem__"):
if verbose: print "checking", stmt
dict = {'a': deepcopy(a), 'b': b, 'c': c}
exec stmt in dict
verify(dict['a'] == res)
t = type(a)
m = getattr(t, meth)
verify(m == t.__dict__[meth])
dict['a'] = deepcopy(a)
m(dict['a'], b, c)
verify(dict['a'] == res)
dict['a'] = deepcopy(a)
bm = getattr(dict['a'], meth)
bm(b, c)
verify(dict['a'] == res)
def testset3op(a, b, c, d, res, stmt="a[b:c]=d", meth="__setslice__"):
if verbose: print "checking", stmt
dict = {'a': deepcopy(a), 'b': b, 'c': c, 'd': d}
exec stmt in dict
verify(dict['a'] == res)
t = type(a)
m = getattr(t, meth)
verify(m == t.__dict__[meth])
dict['a'] = deepcopy(a)
m(dict['a'], b, c, d)
verify(dict['a'] == res)
dict['a'] = deepcopy(a)
bm = getattr(dict['a'], meth)
bm(b, c, d)
verify(dict['a'] == res)
def lists():
if verbose: print "Testing list operations..."
testbinop([1], [2], [1,2], "a+b", "__add__")
testbinop([1,2,3], 2, 1, "b in a", "__contains__")
testbinop([1,2,3], 4, 0, "b in a", "__contains__")
testbinop([1,2,3], 1, 2, "a[b]", "__getitem__")
testternop([1,2,3], 0, 2, [1,2], "a[b:c]", "__getslice__")
testsetop([1], [2], [1,2], "a+=b", "__iadd__")
testsetop([1,2], 3, [1,2,1,2,1,2], "a*=b", "__imul__")
testunop([1,2,3], 3, "len(a)", "__len__")
testbinop([1,2], 3, [1,2,1,2,1,2], "a*b", "__mul__")
testbinop([1,2], 3, [1,2,1,2,1,2], "b*a", "__rmul__")
testset2op([1,2], 1, 3, [1,3], "a[b]=c", "__setitem__")
testset3op([1,2,3,4], 1, 3, [5,6], [1,5,6,4], "a[b:c]=d", "__setslice__")
def dicts():
if verbose: print "Testing dict operations..."
testbinop({1:2}, {2:1}, -1, "cmp(a,b)", "__cmp__")
testbinop({1:2,3:4}, 1, 1, "b in a", "__contains__")
testbinop({1:2,3:4}, 2, 0, "b in a", "__contains__")
testbinop({1:2,3:4}, 1, 2, "a[b]", "__getitem__")
d = {1:2,3:4}
l1 = []
for i in d.keys(): l1.append(i)
l = []
for i in iter(d): l.append(i)
verify(l == l1)
l = []
for i in d.__iter__(): l.append(i)
verify(l == l1)
l = []
for i in dictionary.__iter__(d): l.append(i)
verify(l == l1)
d = {1:2, 3:4}
testunop(d, 2, "len(a)", "__len__")
verify(eval(repr(d), {}) == d)
verify(eval(d.__repr__(), {}) == d)
testset2op({1:2,3:4}, 2, 3, {1:2,2:3,3:4}, "a[b]=c", "__setitem__")
Make dictionary() a real constructor. Accepts at most one argument, "a mapping object", in the same sense dict.update(x) requires of x (that x has a keys() method and a getitem). Questionable: The other type constructors accept a keyword argument, so I did that here too (e.g., dictionary(mapping={1:2}) works). But type_call doesn't pass the keyword args to the tp_new slot (it passes NULL), it only passes them to the tp_init slot, so getting at them required adding a tp_init slot to dicts. Looks like that makes the normal case (i.e., no args at all) a little slower (the time it takes to call dict.tp_init and have it figure out there's nothing to do).
2001-09-02 05:22:48 -03:00
def dict_constructor():
if verbose:
print "Testing dictionary constructor ..."
d = dictionary()
verify(d == {})
d = dictionary({})
verify(d == {})
d = dictionary(mapping={})
verify(d == {})
d = dictionary({1: 2, 'a': 'b'})
verify(d == {1: 2, 'a': 'b'})
for badarg in 0, 0L, 0j, "0", [0], (0,):
try:
dictionary(badarg)
except TypeError:
pass
else:
raise TestFailed("no TypeError from dictionary(%r)" % badarg)
try:
dictionary(senseless={})
except TypeError:
pass
else:
raise TestFailed("no TypeError from dictionary(senseless={}")
try:
dictionary({}, {})
except TypeError:
pass
else:
raise TestFailed("no TypeError from dictionary({}, {})")
class Mapping:
dict = {1:2, 3:4, 'a':1j}
def __getitem__(self, i):
return self.dict[i]
try:
dictionary(Mapping())
except TypeError:
pass
else:
raise TestFailed("no TypeError from dictionary(incomplete mapping)")
Mapping.keys = lambda self: self.dict.keys()
d = dictionary(mapping=Mapping())
verify(d == Mapping.dict)
Make dir() wordier (see the new docstring). The new behavior is a mixed bag. It's clearly wrong for classic classes, at heart because a classic class doesn't have a __class__ attribute, and I'm unclear on whether that's feature or bug. I'll repair this once I find out (in the meantime, dir() applied to classic classes won't find the base classes, while dir() applied to a classic-class instance *will* find the base classes but not *their* base classes). Please give the new dir() a try and see whether you love it or hate it. The new dir([]) behavior is something I could come to love. Here's something to hate: >>> class C: ... pass ... >>> c = C() >>> dir(c) ['__doc__', '__module__'] >>> The idea that an instance has a __doc__ attribute is jarring (of course it's really c.__class__.__doc__ == C.__doc__; likewise for __module__). OTOH, the code already has too many special cases, and dir(x) doesn't have a compelling or clear purpose when x isn't a module.
2001-09-03 02:47:38 -03:00
def test_dir():
if verbose:
print "Testing dir() ..."
junk = 12
verify(dir() == ['junk'])
del junk
# Just make sure these don't blow up!
for arg in 2, 2L, 2j, 2e0, [2], "2", u"2", (2,), {2:2}, type, test_dir:
dir(arg)
builtin_dir(): Treat classic classes like types. Use PyDict_Keys instead of PyMapping_Keys because we know we have a real dict. Tolerate that objects may have an attr named "__dict__" that's not a dict (Py_None popped up during testing). test_descr.py, test_dir(): Test the new classic-class behavior; beef up the new-style class test similarly. test_pyclbr.py, checkModule(): dir(C) is no longer a synonym for C.__dict__.keys() when C is a classic class (looks like the same thing that burned distutils! -- should it be *made* a synoym again? Then it would be inconsistent with new-style class behavior.).
2001-09-03 22:20:04 -03:00
# Try classic classes.
Make dir() wordier (see the new docstring). The new behavior is a mixed bag. It's clearly wrong for classic classes, at heart because a classic class doesn't have a __class__ attribute, and I'm unclear on whether that's feature or bug. I'll repair this once I find out (in the meantime, dir() applied to classic classes won't find the base classes, while dir() applied to a classic-class instance *will* find the base classes but not *their* base classes). Please give the new dir() a try and see whether you love it or hate it. The new dir([]) behavior is something I could come to love. Here's something to hate: >>> class C: ... pass ... >>> c = C() >>> dir(c) ['__doc__', '__module__'] >>> The idea that an instance has a __doc__ attribute is jarring (of course it's really c.__class__.__doc__ == C.__doc__; likewise for __module__). OTOH, the code already has too many special cases, and dir(x) doesn't have a compelling or clear purpose when x isn't a module.
2001-09-03 02:47:38 -03:00
class C:
Cdata = 1
def Cmethod(self): pass
cstuff = ['Cdata', 'Cmethod', '__doc__', '__module__']
verify(dir(C) == cstuff)
c = C() # c.__doc__ is an odd thing to see here; ditto c.__module__.
verify(dir(c) == cstuff)
c.cdata = 2
c.cmethod = lambda self: 0
verify(dir(c) == cstuff + ['cdata', 'cmethod'])
class A(C):
Adata = 1
def Amethod(self): pass
builtin_dir(): Treat classic classes like types. Use PyDict_Keys instead of PyMapping_Keys because we know we have a real dict. Tolerate that objects may have an attr named "__dict__" that's not a dict (Py_None popped up during testing). test_descr.py, test_dir(): Test the new classic-class behavior; beef up the new-style class test similarly. test_pyclbr.py, checkModule(): dir(C) is no longer a synonym for C.__dict__.keys() when C is a classic class (looks like the same thing that burned distutils! -- should it be *made* a synoym again? Then it would be inconsistent with new-style class behavior.).
2001-09-03 22:20:04 -03:00
astuff = ['Adata', 'Amethod'] + cstuff
Make dir() wordier (see the new docstring). The new behavior is a mixed bag. It's clearly wrong for classic classes, at heart because a classic class doesn't have a __class__ attribute, and I'm unclear on whether that's feature or bug. I'll repair this once I find out (in the meantime, dir() applied to classic classes won't find the base classes, while dir() applied to a classic-class instance *will* find the base classes but not *their* base classes). Please give the new dir() a try and see whether you love it or hate it. The new dir([]) behavior is something I could come to love. Here's something to hate: >>> class C: ... pass ... >>> c = C() >>> dir(c) ['__doc__', '__module__'] >>> The idea that an instance has a __doc__ attribute is jarring (of course it's really c.__class__.__doc__ == C.__doc__; likewise for __module__). OTOH, the code already has too many special cases, and dir(x) doesn't have a compelling or clear purpose when x isn't a module.
2001-09-03 02:47:38 -03:00
verify(dir(A) == astuff)
a = A()
builtin_dir(): Treat classic classes like types. Use PyDict_Keys instead of PyMapping_Keys because we know we have a real dict. Tolerate that objects may have an attr named "__dict__" that's not a dict (Py_None popped up during testing). test_descr.py, test_dir(): Test the new classic-class behavior; beef up the new-style class test similarly. test_pyclbr.py, checkModule(): dir(C) is no longer a synonym for C.__dict__.keys() when C is a classic class (looks like the same thing that burned distutils! -- should it be *made* a synoym again? Then it would be inconsistent with new-style class behavior.).
2001-09-03 22:20:04 -03:00
verify(dir(a) == astuff)
a.adata = 42
a.amethod = lambda self: 3
verify(dir(a) == astuff + ['adata', 'amethod'])
# The same, but with 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('_')]
Make dir() wordier (see the new docstring). The new behavior is a mixed bag. It's clearly wrong for classic classes, at heart because a classic class doesn't have a __class__ attribute, and I'm unclear on whether that's feature or bug. I'll repair this once I find out (in the meantime, dir() applied to classic classes won't find the base classes, while dir() applied to a classic-class instance *will* find the base classes but not *their* base classes). Please give the new dir() a try and see whether you love it or hate it. The new dir([]) behavior is something I could come to love. Here's something to hate: >>> class C: ... pass ... >>> c = C() >>> dir(c) ['__doc__', '__module__'] >>> The idea that an instance has a __doc__ attribute is jarring (of course it's really c.__class__.__doc__ == C.__doc__; likewise for __module__). OTOH, the code already has too many special cases, and dir(x) doesn't have a compelling or clear purpose when x isn't a module.
2001-09-03 02:47:38 -03:00
class C(object):
Cdata = 1
def Cmethod(self): pass
builtin_dir(): Treat classic classes like types. Use PyDict_Keys instead of PyMapping_Keys because we know we have a real dict. Tolerate that objects may have an attr named "__dict__" that's not a dict (Py_None popped up during testing). test_descr.py, test_dir(): Test the new classic-class behavior; beef up the new-style class test similarly. test_pyclbr.py, checkModule(): dir(C) is no longer a synonym for C.__dict__.keys() when C is a classic class (looks like the same thing that burned distutils! -- should it be *made* a synoym again? Then it would be inconsistent with new-style class behavior.).
2001-09-03 22:20:04 -03:00
cstuff = ['Cdata', 'Cmethod']
verify(interesting(dir(C)) == cstuff)
c = C()
verify(interesting(dir(c)) == cstuff)
c.cdata = 2
c.cmethod = lambda self: 0
verify(interesting(dir(c)) == cstuff + ['cdata', 'cmethod'])
Make dir() wordier (see the new docstring). The new behavior is a mixed bag. It's clearly wrong for classic classes, at heart because a classic class doesn't have a __class__ attribute, and I'm unclear on whether that's feature or bug. I'll repair this once I find out (in the meantime, dir() applied to classic classes won't find the base classes, while dir() applied to a classic-class instance *will* find the base classes but not *their* base classes). Please give the new dir() a try and see whether you love it or hate it. The new dir([]) behavior is something I could come to love. Here's something to hate: >>> class C: ... pass ... >>> c = C() >>> dir(c) ['__doc__', '__module__'] >>> The idea that an instance has a __doc__ attribute is jarring (of course it's really c.__class__.__doc__ == C.__doc__; likewise for __module__). OTOH, the code already has too many special cases, and dir(x) doesn't have a compelling or clear purpose when x isn't a module.
2001-09-03 02:47:38 -03:00
class A(C):
Adata = 1
def Amethod(self): pass
builtin_dir(): Treat classic classes like types. Use PyDict_Keys instead of PyMapping_Keys because we know we have a real dict. Tolerate that objects may have an attr named "__dict__" that's not a dict (Py_None popped up during testing). test_descr.py, test_dir(): Test the new classic-class behavior; beef up the new-style class test similarly. test_pyclbr.py, checkModule(): dir(C) is no longer a synonym for C.__dict__.keys() when C is a classic class (looks like the same thing that burned distutils! -- should it be *made* a synoym again? Then it would be inconsistent with new-style class behavior.).
2001-09-03 22:20:04 -03:00
astuff = ['Adata', 'Amethod'] + cstuff
verify(interesting(dir(A)) == astuff)
a = A()
verify(interesting(dir(a)) == astuff)
a.adata = 42
a.amethod = lambda self: 3
verify(interesting(dir(a)) == astuff + ['adata', 'amethod'])
Make dir() wordier (see the new docstring). The new behavior is a mixed bag. It's clearly wrong for classic classes, at heart because a classic class doesn't have a __class__ attribute, and I'm unclear on whether that's feature or bug. I'll repair this once I find out (in the meantime, dir() applied to classic classes won't find the base classes, while dir() applied to a classic-class instance *will* find the base classes but not *their* base classes). Please give the new dir() a try and see whether you love it or hate it. The new dir([]) behavior is something I could come to love. Here's something to hate: >>> class C: ... pass ... >>> c = C() >>> dir(c) ['__doc__', '__module__'] >>> The idea that an instance has a __doc__ attribute is jarring (of course it's really c.__class__.__doc__ == C.__doc__; likewise for __module__). OTOH, the code already has too many special cases, and dir(x) doesn't have a compelling or clear purpose when x isn't a module.
2001-09-03 02:47:38 -03:00
test_dir(): Add tests for dir(i) where i is a module subclass.
2001-09-10 20:12:14 -03:00
# Try a module subclass.
import sys
class M(type(sys)):
pass
minstance = M()
minstance.b = 2
minstance.a = 1
verify(dir(minstance) == ['a', 'b'])
class M2(M):
def getdict(self):
return "Not a dict!"
__dict__ = property(getdict)
m2instance = M2()
m2instance.b = 2
m2instance.a = 1
verify(m2instance.__dict__ == "Not a dict!")
try:
dir(m2instance)
except TypeError:
pass
Merge of descr-branch back into trunk.
2001-08-02 01:15:00 -03:00
binops = {
'add': '+',
'sub': '-',
'mul': '*',
'div': '/',
'mod': '%',
'divmod': 'divmod',
'pow': '**',
'lshift': '<<',
'rshift': '>>',
'and': '&',
'xor': '^',
'or': '|',
'cmp': 'cmp',
'lt': '<',
'le': '<=',
'eq': '==',
'ne': '!=',
'gt': '>',
'ge': '>=',
}
for name, expr in binops.items():
if expr.islower():
expr = expr + "(a, b)"
else:
expr = 'a %s b' % expr
binops[name] = expr
unops = {
'pos': '+',
'neg': '-',
'abs': 'abs',
'invert': '~',
'int': 'int',
'long': 'long',
'float': 'float',
'oct': 'oct',
'hex': 'hex',
}
for name, expr in unops.items():
if expr.islower():
expr = expr + "(a)"
else:
expr = '%s a' % expr
unops[name] = expr
def numops(a, b, skip=[]):
dict = {'a': a, 'b': b}
for name, expr in binops.items():
if name not in skip:
name = "__%s__" % name
if hasattr(a, name):
res = eval(expr, dict)
testbinop(a, b, res, expr, name)
for name, expr in unops.items():
name = "__%s__" % name
if hasattr(a, name):
res = eval(expr, dict)
testunop(a, res, expr, name)
def ints():
if verbose: print "Testing int operations..."
numops(100, 3)
def longs():
if verbose: print "Testing long operations..."
numops(100L, 3L)
def floats():
if verbose: print "Testing float operations..."
numops(100.0, 3.0)
def complexes():
if verbose: print "Testing complex operations..."
numops(100.0j, 3.0j, skip=['lt', 'le', 'gt', 'ge'])
class Number(complex):
__slots__ = ['prec']
type_call(): Change in policy. The keyword args (if any) are now passed on to the tp_new slot (if non-NULL), as well as to the tp_init slot (if any). A sane type implementing both tp_new and tp_init should probably pay attention to the arguments in only one of them.
2001-09-13 16:18:27 -03:00
def __new__(cls, *args, **kwds):
result = complex.__new__(cls, *args)
result.prec = kwds.get('prec', 12)
return result
Merge of descr-branch back into trunk.
2001-08-02 01:15:00 -03:00
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__
type_call(): Change in policy. The keyword args (if any) are now passed on to the tp_new slot (if non-NULL), as well as to the tp_init slot (if any). A sane type implementing both tp_new and tp_init should probably pay attention to the arguments in only one of them.
2001-09-13 16:18:27 -03:00
Merge of descr-branch back into trunk.
2001-08-02 01:15:00 -03:00
a = Number(3.14, prec=6)
verify(`a` == "3.14")
verify(a.prec == 6)
type_call(): Change in policy. The keyword args (if any) are now passed on to the tp_new slot (if non-NULL), as well as to the tp_init slot (if any). A sane type implementing both tp_new and tp_init should probably pay attention to the arguments in only one of them.
2001-09-13 16:18:27 -03:00
a = Number(a, prec=2)
verify(`a` == "3.1")
verify(a.prec == 2)
a = Number(234.5)
verify(`a` == "234.5")
verify(a.prec == 12)
Merge of descr-branch back into trunk.
2001-08-02 01:15:00 -03:00
def spamlists():
if verbose: print "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
testbinop(spamlist([1]), spamlist([2]), spamlist([1,2]), "a+b", "__add__")
testbinop(spamlist([1,2,3]), 2, 1, "b in a", "__contains__")
testbinop(spamlist([1,2,3]), 4, 0, "b in a", "__contains__")
testbinop(spamlist([1,2,3]), 1, 2, "a[b]", "__getitem__")
testternop(spamlist([1,2,3]), 0, 2, spamlist([1,2]),
"a[b:c]", "__getslice__")
testsetop(spamlist([1]), spamlist([2]), spamlist([1,2]),
"a+=b", "__iadd__")
testsetop(spamlist([1,2]), 3, spamlist([1,2,1,2,1,2]), "a*=b", "__imul__")
testunop(spamlist([1,2,3]), 3, "len(a)", "__len__")
testbinop(spamlist([1,2]), 3, spamlist([1,2,1,2,1,2]), "a*b", "__mul__")
testbinop(spamlist([1,2]), 3, spamlist([1,2,1,2,1,2]), "b*a", "__rmul__")
testset2op(spamlist([1,2]), 1, 3, spamlist([1,3]), "a[b]=c", "__setitem__")
testset3op(spamlist([1,2,3,4]), 1, 3, spamlist([5,6]),
spamlist([1,5,6,4]), "a[b:c]=d", "__setslice__")
# Test subclassing
class C(spam.spamlist):
def foo(self): return 1
a = C()
verify(a == [])
verify(a.foo() == 1)
a.append(100)
verify(a == [100])
verify(a.getstate() == 0)
a.setstate(42)
verify(a.getstate() == 42)
def spamdicts():
if verbose: print "Testing spamdict operations..."
import copy, xxsubtype as spam
def spamdict(d, memo=None):
import xxsubtype as spam
sd = spam.spamdict()
for k, v in d.items(): sd[k] = v
return sd
# This is an ugly hack:
copy._deepcopy_dispatch[spam.spamdict] = spamdict
testbinop(spamdict({1:2}), spamdict({2:1}), -1, "cmp(a,b)", "__cmp__")
testbinop(spamdict({1:2,3:4}), 1, 1, "b in a", "__contains__")
testbinop(spamdict({1:2,3:4}), 2, 0, "b in a", "__contains__")
testbinop(spamdict({1:2,3:4}), 1, 2, "a[b]", "__getitem__")
d = spamdict({1:2,3:4})
l1 = []
for i in d.keys(): l1.append(i)
l = []
for i in iter(d): l.append(i)
verify(l == l1)
l = []
for i in d.__iter__(): l.append(i)
verify(l == l1)
l = []
for i in type(spamdict({})).__iter__(d): l.append(i)
verify(l == l1)
straightd = {1:2, 3:4}
spamd = spamdict(straightd)
testunop(spamd, 2, "len(a)", "__len__")
testunop(spamd, repr(straightd), "repr(a)", "__repr__")
testset2op(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()
verify(a.items() == [])
verify(a.foo() == 1)
a['foo'] = 'bar'
verify(a.items() == [('foo', 'bar')])
verify(a.getstate() == 0)
a.setstate(100)
verify(a.getstate() == 100)
def pydicts():
if verbose: print "Testing Python subclass of dict..."
verify(issubclass(dictionary, dictionary))
verify(isinstance({}, dictionary))
d = dictionary()
verify(d == {})
verify(d.__class__ is dictionary)
verify(isinstance(d, dictionary))
class C(dictionary):
state = -1
def __init__(self, *a, **kw):
if a:
assert len(a) == 1
self.state = a[0]
if kw:
for k, v in kw.items(): self[v] = k
def __getitem__(self, key):
return self.get(key, 0)
def __setitem__(self, key, value):
assert isinstance(key, type(0))
dictionary.__setitem__(self, key, value)
def setstate(self, state):
self.state = state
def getstate(self):
return self.state
verify(issubclass(C, dictionary))
a1 = C(12)
verify(a1.state == 12)
a2 = C(foo=1, bar=2)
verify(a2[1] == 'foo' and a2[2] == 'bar')
a = C()
verify(a.state == -1)
verify(a.getstate() == -1)
a.setstate(0)
verify(a.state == 0)
verify(a.getstate() == 0)
a.setstate(10)
verify(a.state == 10)
verify(a.getstate() == 10)
verify(a[42] == 0)
a[42] = 24
verify(a[42] == 24)
if verbose: print "pydict stress test ..."
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):
verify(a[i][j] == i*j)
def pylists():
if verbose: print "Testing Python subclass of list..."
class C(list):
def __getitem__(self, i):
return list.__getitem__(self, i) + 100
def __getslice__(self, i, j):
return (i, j)
a = C()
a.extend([0,1,2])
verify(a[0] == 100)
verify(a[1] == 101)
verify(a[2] == 102)
verify(a[100:200] == (100,200))
def metaclass():
if verbose: print "Testing __metaclass__..."
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()
verify(a.getstate() == 0)
a.setstate(10)
verify(a.getstate() == 10)
class D:
class __metaclass__(type):
def myself(cls): return cls
verify(D.myself() == D)
metaclass(): add tests for metaclasses written in Python: one that subclasses type, one that doesn't (the latter isn't fully functional yet).
2001-08-17 08:43:17 -03:00
d = D()
verify(d.__class__ is D)
class M1(type):
def __new__(cls, name, bases, dict):
dict['__spam__'] = 1
return type.__new__(cls, name, bases, dict)
class C:
__metaclass__ = M1
verify(C.__spam__ == 1)
c = C()
verify(c.__spam__ == 1)
metaclass(): add some more examples of metaclasses, including one using cooperative multiple inheritance. inherits(): add a test for subclassing the unicode type.
2001-08-30 17:52:40 -03:00
metaclass(): add tests for metaclasses written in Python: one that subclasses type, one that doesn't (the latter isn't fully functional yet).
2001-08-17 08:43:17 -03:00
class _instance(object):
pass
class M2(object):
def __new__(cls, name, bases, dict):
self = object.__new__(cls)
self.name = name
self.bases = bases
self.dict = dict
return self
__new__ = staticmethod(__new__)
def __call__(self):
it = _instance()
Add early binding of methods to the 2nd metaclass example.
2001-08-17 08:55:58 -03:00
# Early binding of methods
for key in self.dict:
if key.startswith("__"):
continue
setattr(it, key, self.dict[key].__get__(it, self))
metaclass(): add tests for metaclasses written in Python: one that subclasses type, one that doesn't (the latter isn't fully functional yet).
2001-08-17 08:43:17 -03:00
return it
class C:
__metaclass__ = M2
def spam(self):
return 42
verify(C.name == 'C')
verify(C.bases == ())
verify('spam' in C.dict)
c = C()
Add early binding of methods to the 2nd metaclass example.
2001-08-17 08:55:58 -03:00
verify(c.spam() == 42)
Merge of descr-branch back into trunk.
2001-08-02 01:15:00 -03:00
metaclass(): add some more examples of metaclasses, including one using cooperative multiple inheritance. inherits(): add a test for subclassing the unicode type.
2001-08-30 17:52:40 -03:00
# More metaclass examples
class autosuper(type):
# Automatically add __super to the class
# This trick only works for dynamic classes
# so we force __dynamic__ = 1
def __new__(metaclass, name, bases, dict):
# XXX Should check that name isn't already a base class name
dict["__dynamic__"] = 1
cls = super(autosuper, metaclass).__new__(metaclass,
name, bases, dict)
Correct name mangling algorithm, and add a comment.
2001-08-31 01:35:14 -03:00
# Name mangling for __super removes leading underscores
metaclass(): add some more examples of metaclasses, including one using cooperative multiple inheritance. inherits(): add a test for subclassing the unicode type.
2001-08-30 17:52:40 -03:00
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()
verify(D().meth() == "DCBA")
class E(B, C):
def meth(self):
return "E" + self.__super.meth()
verify(E().meth() == "EBCA")
Rename 'getset' to 'property'.
2001-09-06 18:56:42 -03:00
class autoproperty(type):
# Automatically create property attributes when methods
metaclass(): add some more examples of metaclasses, including one using cooperative multiple inheritance. inherits(): add a test for subclassing the unicode type.
2001-08-30 17:52:40 -03:00
# named _get_x and/or _set_x are found
def __new__(metaclass, name, bases, dict):
hits = {}
for key, val in dict.iteritems():
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.iteritems():
Rename 'getset' to 'property'.
2001-09-06 18:56:42 -03:00
dict[key] = property(get, set)
return super(autoproperty, metaclass).__new__(metaclass,
metaclass(): add some more examples of metaclasses, including one using cooperative multiple inheritance. inherits(): add a test for subclassing the unicode type.
2001-08-30 17:52:40 -03:00
name, bases, dict)
class A:
Rename 'getset' to 'property'.
2001-09-06 18:56:42 -03:00
__metaclass__ = autoproperty
metaclass(): add some more examples of metaclasses, including one using cooperative multiple inheritance. inherits(): add a test for subclassing the unicode type.
2001-08-30 17:52:40 -03:00
def _get_x(self):
return -self.__x
def _set_x(self, x):
self.__x = -x
a = A()
verify(not hasattr(a, "x"))
a.x = 12
verify(a.x == 12)
verify(a._A__x == -12)
Rename 'getset' to 'property'.
2001-09-06 18:56:42 -03:00
class multimetaclass(autoproperty, autosuper):
metaclass(): add some more examples of metaclasses, including one using cooperative multiple inheritance. inherits(): add a test for subclassing the unicode type.
2001-08-30 17:52:40 -03:00
# 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()
verify(D().x == "DCBA")
Merge of descr-branch back into trunk.
2001-08-02 01:15:00 -03:00
def pymods():
if verbose: print "Testing Python subclass of module..."
log = []
- Expand test for dynamic objects. - Remove various 'global' directives and move some global definitions inside the test functions that use them -- we have nested scopes so the old hacks using globals are no longer needed.
2001-08-12 02:24:18 -03:00
import sys
MT = type(sys)
Merge of descr-branch back into trunk.
2001-08-02 01:15:00 -03:00
class MM(MT):
def __init__(self):
MT.__init__(self)
def __getattr__(self, name):
log.append(("getattr", name))
return MT.__getattr__(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.foo = 12
x = a.foo
del a.foo
Fix the test again due to fewer calls to __getattr__.
2001-08-28 15:23:24 -03:00
verify(log == [("setattr", "foo", 12),
Merge of descr-branch back into trunk.
2001-08-02 01:15:00 -03:00
("getattr", "foo"),
("delattr", "foo")], log)
def multi():
if verbose: print "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()
verify(a.getstate() == 0)
a.setstate(10)
verify(a.getstate() == 10)
class D(dictionary, C):
def __init__(self):
type({}).__init__(self)
C.__init__(self)
d = D()
verify(d.keys() == [])
d["hello"] = "world"
verify(d.items() == [("hello", "world")])
verify(d["hello"] == "world")
verify(d.getstate() == 0)
d.setstate(10)
verify(d.getstate() == 10)
verify(D.__mro__ == (D, dictionary, C, object))
Add test for SF bug #442833 (multiple inheritance).
2001-08-10 18:28:46 -03:00
# 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"
verify(Node().__int__() == 23)
verify(int(Node()) == 23)
verify(Frag().__int__() == 42)
verify(int(Frag()) == 42)
Merge of descr-branch back into trunk.
2001-08-02 01:15:00 -03:00
def diamond():
if verbose: print "Testing multiple inheritance special cases..."
class A(object):
def spam(self): return "A"
verify(A().spam() == "A")
class B(A):
def boo(self): return "B"
def spam(self): return "B"
verify(B().spam() == "B")
verify(B().boo() == "B")
class C(A):
def boo(self): return "C"
verify(C().spam() == "A")
verify(C().boo() == "C")
class D(B, C): pass
verify(D().spam() == "B")
verify(D().boo() == "B")
verify(D.__mro__ == (D, B, C, A, object))
class E(C, B): pass
verify(E().spam() == "B")
verify(E().boo() == "C")
verify(E.__mro__ == (E, C, B, A, object))
class F(D, E): pass
verify(F().spam() == "B")
verify(F().boo() == "B")
verify(F.__mro__ == (F, D, E, B, C, A, object))
class G(E, D): pass
verify(G().spam() == "B")
verify(G().boo() == "C")
verify(G.__mro__ == (G, E, D, C, B, A, object))
Restore the test for 'object' that I removed when object was uninstantiable. All is well now.
2001-08-09 16:45:21 -03:00
def objects():
if verbose: print "Testing object class..."
a = object()
verify(a.__class__ == object == type(a))
b = object()
verify(a is not b)
verify(not hasattr(a, "foo"))
try:
a.foo = 12
Allow AttributeError as well as TypeError for attribute-less objects.
2001-08-10 16:42:38 -03:00
except (AttributeError, TypeError):
Restore the test for 'object' that I removed when object was uninstantiable. All is well now.
2001-08-09 16:45:21 -03:00
pass
else:
verify(0, "object() should not allow setting a foo attribute")
verify(not hasattr(object(), "__dict__"))
class Cdict(object):
pass
x = Cdict()
verify(x.__dict__ is None)
x.foo = 1
verify(x.foo == 1)
verify(x.__dict__ == {'foo': 1})
Merge of descr-branch back into trunk.
2001-08-02 01:15:00 -03:00
def slots():
if verbose: print "Testing __slots__..."
class C0(object):
__slots__ = []
x = C0()
verify(not hasattr(x, "__dict__"))
verify(not hasattr(x, "foo"))
class C1(object):
__slots__ = ['a']
x = C1()
verify(not hasattr(x, "__dict__"))
verify(x.a == None)
x.a = 1
verify(x.a == 1)
del x.a
verify(x.a == None)
class C3(object):
__slots__ = ['a', 'b', 'c']
x = C3()
verify(not hasattr(x, "__dict__"))
verify(x.a is None)
verify(x.b is None)
verify(x.c is None)
x.a = 1
x.b = 2
x.c = 3
verify(x.a == 1)
verify(x.b == 2)
verify(x.c == 3)
def dynamics():
if verbose: print "Testing __dynamic__..."
verify(object.__dynamic__ == 0)
verify(list.__dynamic__ == 0)
class S1:
__metaclass__ = type
verify(S1.__dynamic__ == 0)
class S(object):
pass
dynamics(): add tests for dynamic *instances* (which are currently broken). Also fix an invalid reference to C (should be S).
2001-08-12 00:38:18 -03:00
verify(S.__dynamic__ == 0)
Merge of descr-branch back into trunk.
2001-08-02 01:15:00 -03:00
class D(object):
__dynamic__ = 1
verify(D.__dynamic__ == 1)
class E(D, S):
pass
verify(E.__dynamic__ == 1)
class F(S, D):
pass
verify(F.__dynamic__ == 1)
try:
S.foo = 1
except (AttributeError, TypeError):
pass
else:
verify(0, "assignment to a static class attribute should be illegal")
D.foo = 1
verify(D.foo == 1)
# Test that dynamic attributes are inherited
verify(E.foo == 1)
verify(F.foo == 1)
class SS(D):
__dynamic__ = 0
verify(SS.__dynamic__ == 0)
verify(SS.foo == 1)
try:
SS.foo = 1
except (AttributeError, TypeError):
pass
else:
verify(0, "assignment to SS.foo should be illegal")
dynamics(): add tests for dynamic *instances* (which are currently broken). Also fix an invalid reference to C (should be S).
2001-08-12 00:38:18 -03:00
# Test dynamic instances
class C(object):
__dynamic__ = 1
a = C()
- Expand test for dynamic objects. - Remove various 'global' directives and move some global definitions inside the test functions that use them -- we have nested scopes so the old hacks using globals are no longer needed.
2001-08-12 02:24:18 -03:00
verify(not hasattr(a, "foobar"))
dynamics(): add tests for dynamic *instances* (which are currently broken). Also fix an invalid reference to C (should be S).
2001-08-12 00:38:18 -03:00
C.foobar = 2
verify(a.foobar == 2)
C.method = lambda self: 42
verify(a.method() == 42)
C.__repr__ = lambda self: "C()"
verify(repr(a) == "C()")
- Expand test for dynamic objects. - Remove various 'global' directives and move some global definitions inside the test functions that use them -- we have nested scopes so the old hacks using globals are no longer needed.
2001-08-12 02:24:18 -03:00
C.__int__ = lambda self: 100
verify(int(a) == 100)
verify(a.foobar == 2)
verify(not hasattr(a, "spam"))
def mygetattr(self, name):
if name == "spam":
return "spam"
else:
return object.__getattr__(self, name)
C.__getattr__ = mygetattr
verify(a.spam == "spam")
a.new = 12
verify(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:
verify(0, "expected AttributeError")
verify(a.spam == "spam")
Add a test for a weird bug I just discovered: a dynamic subclass doesn't have a __dict__!
2001-08-14 17:00:33 -03:00
class D(C):
pass
d = D()
d.foo = 1
verify(d.foo == 1)
Merge of descr-branch back into trunk.
2001-08-02 01:15:00 -03:00
def errors():
if verbose: print "Testing errors..."
try:
class C(list, dictionary):
pass
except TypeError:
pass
else:
verify(0, "inheritance from both list and dict should be illegal")
try:
class C(object, None):
pass
except TypeError:
pass
else:
verify(0, "inheritance from non-type should be illegal")
class Classic:
pass
try:
class C(object, Classic):
pass
except TypeError:
pass
else:
verify(0, "inheritance from object and Classic should be illegal")
try:
Now that int is subclassable, have to change a test that tests for non-subclassability. (More tests for number subclassing should follow.)
2001-08-29 12:48:43 -03:00
class C(type(len)):
Merge of descr-branch back into trunk.
2001-08-02 01:15:00 -03:00
pass
except TypeError:
pass
else:
Now that int is subclassable, have to change a test that tests for non-subclassability. (More tests for number subclassing should follow.)
2001-08-29 12:48:43 -03:00
verify(0, "inheritance from CFunction should be illegal")
Merge of descr-branch back into trunk.
2001-08-02 01:15:00 -03:00
try:
class C(object):
__slots__ = 1
except TypeError:
pass
else:
verify(0, "__slots__ = 1 should be illegal")
try:
class C(object):
__slots__ = [1]
except TypeError:
pass
else:
verify(0, "__slots__ = [1] should be illegal")
def classmethods():
if verbose: print "Testing class methods..."
class C(object):
def foo(*a): return a
goo = classmethod(foo)
c = C()
verify(C.goo(1) == (C, 1))
verify(c.goo(1) == (C, 1))
verify(c.foo(1) == (c, 1))
class D(C):
pass
d = D()
verify(D.goo(1) == (D, 1))
verify(d.goo(1) == (D, 1))
verify(d.foo(1) == (d, 1))
verify(D.foo(d, 1) == (d, 1))
def staticmethods():
if verbose: print "Testing static methods..."
class C(object):
def foo(*a): return a
goo = staticmethod(foo)
c = C()
verify(C.goo(1) == (1,))
verify(c.goo(1) == (1,))
verify(c.foo(1) == (c, 1,))
class D(C):
pass
d = D()
verify(D.goo(1) == (1,))
verify(d.goo(1) == (1,))
verify(d.foo(1) == (d, 1))
verify(D.foo(d, 1) == (d, 1))
def classic():
if verbose: print "Testing classic classes..."
class C:
def foo(*a): return a
goo = classmethod(foo)
c = C()
verify(C.goo(1) == (C, 1))
verify(c.goo(1) == (C, 1))
verify(c.foo(1) == (c, 1))
class D(C):
pass
d = D()
verify(D.goo(1) == (D, 1))
verify(d.goo(1) == (D, 1))
verify(d.foo(1) == (d, 1))
verify(D.foo(d, 1) == (d, 1))
classic(), methods(): add another test relating to unbound methods: when an unbound method of class A is stored as a class variable of class B, and class B is *not* a subclass of class A, that method should *not* get bound to B instances.
2001-08-17 10:40:47 -03:00
class E: # *not* subclassing from C
foo = C.foo
verify(E().foo == C.foo) # i.e., unbound
classic(),metods(): add tests to verify that a bound method without a class has a correct repr().
2001-08-17 10:58:31 -03:00
verify(repr(C.foo.__get__(C())).startswith("<bound method "))
Merge of descr-branch back into trunk.
2001-08-02 01:15:00 -03:00
def compattr():
if verbose: print "Testing computed attributes..."
class C(object):
class computed_attribute(object):
def __init__(self, get, set=None):
self.__get = get
self.__set = set
def __get__(self, obj, type=None):
return self.__get(obj)
def __set__(self, obj, value):
return self.__set(obj, value)
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
x = computed_attribute(__get_x, __set_x)
a = C()
verify(a.x == 0)
verify(a.x == 1)
a.x = 10
verify(a.x == 10)
verify(a.x == 11)
def newslot():
if verbose: print "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()
verify(a.foo == 3)
verify(a.__class__ is C)
class D(C):
pass
b = D()
verify(b.foo == 3)
verify(b.__class__ is D)
def altmro():
if verbose: print "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
verify(D.mro() == [D, B, C, A, object] == list(D.__mro__))
verify(D().f() == "C")
- Expand test for dynamic objects. - Remove various 'global' directives and move some global definitions inside the test functions that use them -- we have nested scopes so the old hacks using globals are no longer needed.
2001-08-12 02:24:18 -03:00
class PerverseMetaType(type):
def mro(cls):
L = type.mro(cls)
L.reverse()
return L
Merge of descr-branch back into trunk.
2001-08-02 01:15:00 -03:00
class X(A,B,C,D):
__metaclass__ = PerverseMetaType
verify(X.__mro__ == (object, A, C, B, D, X))
verify(X().f() == "A")
def overloading():
Add test for weak references.
2001-08-17 18:27:53 -03:00
if verbose: print "Testing operator overloading..."
Merge of descr-branch back into trunk.
2001-08-02 01:15:00 -03:00
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:
return B.__getattr__(self, name)
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
def __getslice__(self, i, j):
return ("getslice", i, j)
def __setslice__(self, i, j, value):
self.setslice = (i, j, value)
def __delslice__(self, i, j):
self.delslice = (i, j)
a = C()
verify(a.foo == ("getattr", "foo"))
a.foo = 12
verify(a.setattr == ("foo", 12))
del a.foo
verify(a.delattr == "foo")
verify(a[12] == ("getitem", 12))
a[12] = 21
verify(a.setitem == (12, 21))
del a[12]
verify(a.delitem == 12)
verify(a[0:10] == ("getslice", 0, 10))
a[0:10] = "foo"
verify(a.setslice == (0, 10, "foo"))
del a[0:10]
verify(a.delslice == (0, 10))
Add a test to verify that bound methods work correctly.
2001-08-15 14:51:17 -03:00
def methods():
Add test for weak references.
2001-08-17 18:27:53 -03:00
if verbose: print "Testing methods..."
Add a test to verify that bound methods work correctly.
2001-08-15 14:51:17 -03:00
class C(object):
def __init__(self, x):
self.x = x
def foo(self):
return self.x
c1 = C(1)
verify(c1.foo() == 1)
class D(C):
boo = C.foo
goo = c1.foo
d2 = D(2)
verify(d2.foo() == 2)
verify(d2.boo() == 2)
classobject.c:instancemethod_descr_get(): when a bound method is assigned to a class variable and then accessed via an instance, it should not be rebound. test_descr.py:methods(): test for the condition above.
2001-08-16 17:41:56 -03:00
verify(d2.goo() == 1)
classic(), methods(): add another test relating to unbound methods: when an unbound method of class A is stored as a class variable of class B, and class B is *not* a subclass of class A, that method should *not* get bound to B instances.
2001-08-17 10:40:47 -03:00
class E(object):
foo = C.foo
verify(E().foo == C.foo) # i.e., unbound
classic(),metods(): add tests to verify that a bound method without a class has a correct repr().
2001-08-17 10:58:31 -03:00
verify(repr(C.foo.__get__(C(1))).startswith("<bound method "))
Add a test to verify that bound methods work correctly.
2001-08-15 14:51:17 -03:00
Add tests for overridable operators that have default interpretations (__hash__ etc.), in static and dynamic classes, overridden and default.
2001-08-15 20:57:59 -03:00
def specials():
# Test operators like __hash__ for which a built-in default exists
Add test for weak references.
2001-08-17 18:27:53 -03:00
if verbose: print "Testing special operators..."
Add tests for overridable operators that have default interpretations (__hash__ etc.), in static and dynamic classes, overridden and default.
2001-08-15 20:57:59 -03:00
# 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()
verify(not not c1)
verify(hash(c1) == id(c1))
verify(cmp(c1, c2) == cmp(id(c1), id(c2)))
verify(c1 == c1)
verify(c1 != c2)
verify(not c1 != c1)
verify(not c1 == c2)
test_descr started breaking in yet another way in the same place.
2001-08-16 16:50:51 -03:00
# Note that the module name appears in str/repr, and that varies
# depending on whether this test is run standalone or from a framework.
verify(str(c1).find('C instance at ') >= 0)
Repair some accidents causing Windows failures: + test_compare. While None compares less than anything else, it's not always the case that None has the smallest id(). + test_descr. The output of %p (pointer) formats varies across platforms. In particular, on Windows it doesn't produce a leading "0x".
2001-08-16 13:56:16 -03:00
verify(str(c1) == repr(c1))
Add tests for overridable operators that have default interpretations (__hash__ etc.), in static and dynamic classes, overridden and default.
2001-08-15 20:57:59 -03:00
verify(-1 not in c1)
for i in range(10):
verify(i in c1)
verify(10 not in c1)
# Test the default behavior for dynamic classes
class D(object):
__dynamic__ = 1
def __getitem__(self, i):
if 0 <= i < 10: return i
raise IndexError
d1 = D()
d2 = D()
verify(not not d1)
verify(hash(d1) == id(d1))
verify(cmp(d1, d2) == cmp(id(d1), id(d2)))
verify(d1 == d1)
verify(d1 != d2)
verify(not d1 != d1)
verify(not d1 == d2)
test_descr started breaking in yet another way in the same place.
2001-08-16 16:50:51 -03:00
# Note that the module name appears in str/repr, and that varies
# depending on whether this test is run standalone or from a framework.
verify(str(d1).find('D instance at ') >= 0)
Repair some accidents causing Windows failures: + test_compare. While None compares less than anything else, it's not always the case that None has the smallest id(). + test_descr. The output of %p (pointer) formats varies across platforms. In particular, on Windows it doesn't produce a leading "0x".
2001-08-16 13:56:16 -03:00
verify(str(d1) == repr(d1))
Add tests for overridable operators that have default interpretations (__hash__ etc.), in static and dynamic classes, overridden and default.
2001-08-15 20:57:59 -03:00
verify(-1 not in d1)
for i in range(10):
verify(i in d1)
verify(10 not in d1)
# Test overridden behavior for static classes
class Proxy(object):
def __init__(self, x):
self.x = x
def __nonzero__(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 __cmp__(self, other):
return cmp(self.x, other.x)
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)
verify(not p0)
verify(not not p1)
verify(hash(p0) == hash(0))
verify(p0 == p0)
verify(p0 != p1)
verify(not p0 != p0)
verify(not p0 == p1)
verify(cmp(p0, p1) == -1)
verify(cmp(p0, p0) == 0)
verify(cmp(p0, p_1) == 1)
verify(str(p0) == "Proxy:0")
verify(repr(p0) == "Proxy(0)")
p10 = Proxy(range(10))
verify(-1 not in p10)
for i in range(10):
verify(i in p10)
verify(10 not in p10)
# Test overridden behavior for dynamic classes
class DProxy(object):
__dynamic__ = 1
def __init__(self, x):
self.x = x
def __nonzero__(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 __cmp__(self, other):
return cmp(self.x, other.x)
def __str__(self):
return "DProxy:%s" % self.x
def __repr__(self):
return "DProxy(%r)" % self.x
def __contains__(self, value):
return value in self.x
p0 = DProxy(0)
p1 = DProxy(1)
p_1 = DProxy(-1)
verify(not p0)
verify(not not p1)
verify(hash(p0) == hash(0))
verify(p0 == p0)
verify(p0 != p1)
verify(not p0 != p0)
verify(not p0 == p1)
verify(cmp(p0, p1) == -1)
verify(cmp(p0, p0) == 0)
verify(cmp(p0, p_1) == 1)
verify(str(p0) == "DProxy:0")
verify(repr(p0) == "DProxy(0)")
p10 = DProxy(range(10))
verify(-1 not in p10)
for i in range(10):
verify(i in p10)
verify(10 not in p10)
Add test for weak references.
2001-08-17 18:27:53 -03:00
def weakrefs():
if verbose: print "Testing weak references..."
import weakref
class C(object):
pass
c = C()
r = weakref.ref(c)
verify(r() is c)
del c
verify(r() is None)
del r
class NoWeak(object):
__slots__ = ['foo']
no = NoWeak()
try:
weakref.ref(no)
except TypeError, msg:
verify(str(msg).find("weakly") >= 0)
else:
verify(0, "weakref.ref(no) should be illegal")
class Weak(object):
__slots__ = ['foo', '__weakref__']
yes = Weak()
r = weakref.ref(yes)
verify(r() is yes)
del yes
verify(r() is None)
del r
Rename 'getset' to 'property'.
2001-09-06 18:56:42 -03:00
def properties():
if verbose: print "Testing property..."
Add a test for the new getset type.
2001-08-24 12:24:24 -03:00
class C(object):
def getx(self):
return self.__x
def setx(self, value):
self.__x = value
def delx(self):
del self.__x
Rename 'getset' to 'property'.
2001-09-06 18:56:42 -03:00
x = property(getx, setx, delx)
Add a test for the new getset type.
2001-08-24 12:24:24 -03:00
a = C()
verify(not hasattr(a, "x"))
a.x = 42
verify(a._C__x == 42)
verify(a.x == 42)
del a.x
verify(not hasattr(a, "x"))
verify(not hasattr(a, "_C__x"))
C.x.__set__(a, 100)
verify(C.x.__get__(a) == 100)
## C.x.__set__(a)
## verify(not hasattr(a, "x"))
Add test suite for super().
2001-08-24 13:55:27 -03:00
def supers():
supers(): typo -- "if verify" should be "if verbose".
2001-08-24 14:07:20 -03:00
if verbose: print "Testing super..."
Add test suite for super().
2001-08-24 13:55:27 -03:00
class A(object):
def meth(self, a):
return "A(%r)" % a
verify(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)
verify(B().meth(2) == "B(2)A(2)")
class C(A):
__dynamic__ = 1
def meth(self, a):
return "C(%r)" % a + self.__super.meth(a)
C._C__super = super(C)
verify(C().meth(3) == "C(3)A(3)")
class D(C, B):
def meth(self, a):
return "D(%r)" % a + super(D, self).meth(a)
verify (D().meth(4) == "D(4)C(4)B(4)A(4)")
Add testcases for inheritance from tricky builtins (numbers, strings, tuples).
2001-08-30 17:06:08 -03:00
def inherits():
if verbose: print "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.)
verify(repr(hexint(7) + 9) == "0x10")
verify(repr(hexint(1000) + 7) == "0x3ef")
SF bug #460020: bug or feature: unicode() and subclasses. Given an immutable type M, and an instance I of a subclass of M, the constructor call M(I) was just returning I as-is; but it should return a new instance of M. This fixes it for M in {int, long}. Strings, floats and tuples remain to be done. Added new macros PyInt_CheckExact and PyLong_CheckExact, to more easily distinguish between "is" and "is a" (i.e., only an int passes PyInt_CheckExact, while any sublass of int passes PyInt_Check). Added private API function _PyLong_Copy.
2001-09-10 17:52:51 -03:00
a = hexint(12345)
Added subclass equality tests. Almost all of these are commented out now, because they don't work yet.
2001-09-12 16:53:15 -03:00
#XXX verify(a == 12345)
Restore the comparisons that I initially put in the test but that Tim XXX'ed out. Turns out that after fixing the constructors, the comparisons in fact succeed. E.g. int(hexint(12345)) returns an int with value 12345.
2001-09-11 11:02:22 -03:00
verify(int(a) == 12345)
SF bug #460020: bug or feature: unicode() and subclasses. Given an immutable type M, and an instance I of a subclass of M, the constructor call M(I) was just returning I as-is; but it should return a new instance of M. This fixes it for M in {int, long}. Strings, floats and tuples remain to be done. Added new macros PyInt_CheckExact and PyLong_CheckExact, to more easily distinguish between "is" and "is a" (i.e., only an int passes PyInt_CheckExact, while any sublass of int passes PyInt_Check). Added private API function _PyLong_Copy.
2001-09-10 17:52:51 -03:00
verify(int(a).__class__ is int)
str_subtype_new, unicode_subtype_new: + These were leaving the hash fields at 0, which all string and unicode routines believe is a legitimate hash code. As a result, hash() applied to str and unicode subclass instances always returned 0, which in turn confused dict operations, etc. + Changed local names "new"; no point to antagonizing C++ compilers.
2001-09-12 02:18:58 -03:00
verify(hash(a) == hash(12345))
More bug 460020. When I is a subclass of int, disable the +I(whatever), I(0) << whatever, I(0) >> whatever, I(whatever) << 0 and I(whatever) >> 0 optimizations.
2001-09-11 18:44:14 -03:00
verify((+a).__class__ is int)
verify((a >> 0).__class__ is int)
verify((a << 0).__class__ is int)
verify((hexint(0) << 12).__class__ is int)
verify((hexint(0) >> 12).__class__ is int)
Add testcases for inheritance from tricky builtins (numbers, strings, tuples).
2001-08-30 17:06:08 -03:00
class octlong(long):
__slots__ = []
def __str__(self):
s = oct(self)
if s[-1] == 'L':
s = s[:-1]
return s
def __add__(self, other):
return self.__class__(super(octlong, self).__add__(other))
__radd__ = __add__
verify(str(octlong(3) + 5) == "010")
# (Note that overriding __radd__ here only seems to work
# because the example uses a short int left argument.)
verify(str(5 + octlong(3000)) == "05675")
SF bug #460020: bug or feature: unicode() and subclasses. Given an immutable type M, and an instance I of a subclass of M, the constructor call M(I) was just returning I as-is; but it should return a new instance of M. This fixes it for M in {int, long}. Strings, floats and tuples remain to be done. Added new macros PyInt_CheckExact and PyLong_CheckExact, to more easily distinguish between "is" and "is a" (i.e., only an int passes PyInt_CheckExact, while any sublass of int passes PyInt_Check). Added private API function _PyLong_Copy.
2001-09-10 17:52:51 -03:00
a = octlong(12345)
Added subclass equality tests. Almost all of these are commented out now, because they don't work yet.
2001-09-12 16:53:15 -03:00
#XXX verify(a == 12345L)
Restore the comparisons that I initially put in the test but that Tim XXX'ed out. Turns out that after fixing the constructors, the comparisons in fact succeed. E.g. int(hexint(12345)) returns an int with value 12345.
2001-09-11 11:02:22 -03:00
verify(long(a) == 12345L)
str_subtype_new, unicode_subtype_new: + These were leaving the hash fields at 0, which all string and unicode routines believe is a legitimate hash code. As a result, hash() applied to str and unicode subclass instances always returned 0, which in turn confused dict operations, etc. + Changed local names "new"; no point to antagonizing C++ compilers.
2001-09-12 02:18:58 -03:00
verify(hash(a) == hash(12345L))
SF bug #460020: bug or feature: unicode() and subclasses. Given an immutable type M, and an instance I of a subclass of M, the constructor call M(I) was just returning I as-is; but it should return a new instance of M. This fixes it for M in {int, long}. Strings, floats and tuples remain to be done. Added new macros PyInt_CheckExact and PyLong_CheckExact, to more easily distinguish between "is" and "is a" (i.e., only an int passes PyInt_CheckExact, while any sublass of int passes PyInt_Check). Added private API function _PyLong_Copy.
2001-09-10 17:52:51 -03:00
verify(long(a).__class__ is long)
More bug 460020. Disable a number of long optimizations for long subclasses.
2001-09-11 19:31:33 -03:00
verify((+a).__class__ is long)
verify((-a).__class__ is long)
verify((-octlong(0)).__class__ is long)
verify((a >> 0).__class__ is long)
verify((a << 0).__class__ is long)
verify((a - 0).__class__ is long)
verify((a * 1).__class__ is long)
verify((a ** 1).__class__ is long)
verify((a // 1).__class__ is long)
verify((1 * a).__class__ is long)
verify((a | 0).__class__ is long)
verify((a ^ 0).__class__ is long)
verify((a & -1L).__class__ is long)
verify((octlong(0) << 12).__class__ is long)
verify((octlong(0) >> 12).__class__ is long)
verify(abs(octlong(0)).__class__ is long)
# Because octlong overrides __add__, we can't check the absence of +0
# optimizations using octlong.
class longclone(long):
pass
a = longclone(1)
verify((a + 0).__class__ is long)
verify((0 + a).__class__ is long)
Add testcases for inheritance from tricky builtins (numbers, strings, tuples).
2001-08-30 17:06:08 -03:00
class precfloat(float):
__slots__ = ['prec']
def __init__(self, value=0.0, prec=12):
self.prec = int(prec)
float.__init__(value)
def __repr__(self):
return "%.*g" % (self.prec, self)
verify(repr(precfloat(1.1)) == "1.1")
SF bug #460020: bug or feature: unicode() and subclasses. Given an immutable type M, and an instance I of a subclass of M, the constructor call M(I) was just returning I as-is; but it should return a new instance of M. This fixes it for M in {int, long}. Strings, floats and tuples remain to be done. Added new macros PyInt_CheckExact and PyLong_CheckExact, to more easily distinguish between "is" and "is a" (i.e., only an int passes PyInt_CheckExact, while any sublass of int passes PyInt_Check). Added private API function _PyLong_Copy.
2001-09-10 17:52:51 -03:00
a = precfloat(12345)
Added subclass equality tests. Almost all of these are commented out now, because they don't work yet.
2001-09-12 16:53:15 -03:00
#XXX verify(a == 12345.0)
Restore the comparisons that I initially put in the test but that Tim XXX'ed out. Turns out that after fixing the constructors, the comparisons in fact succeed. E.g. int(hexint(12345)) returns an int with value 12345.
2001-09-11 11:02:22 -03:00
verify(float(a) == 12345.0)
More for SF bug [#460020] bug or feature: unicode() and subclasses Repair float constructor to return a true float when passed a subclass instance. New PyFloat_CheckExact macro.
2001-09-10 18:28:20 -03:00
verify(float(a).__class__ is float)
str_subtype_new, unicode_subtype_new: + These were leaving the hash fields at 0, which all string and unicode routines believe is a legitimate hash code. As a result, hash() applied to str and unicode subclass instances always returned 0, which in turn confused dict operations, etc. + Changed local names "new"; no point to antagonizing C++ compilers.
2001-09-12 02:18:58 -03:00
verify(hash(a) == hash(12345.0))
More bug 460020: when F is a subclass of float, disable the unary plus optimization (+F(whatever)).
2001-09-11 18:53:35 -03:00
verify((+a).__class__ is float)
Add testcases for inheritance from tricky builtins (numbers, strings, tuples).
2001-08-30 17:06:08 -03:00
Again perhaps the end of [#460020] bug or feature: unicode() and subclasses. Inhibited complex unary plus optimization when applied to a complex subtype. Added PyComplex_CheckExact macro. Some comments and minor code fiddling.
2001-09-12 16:12:49 -03:00
class madcomplex(complex):
def __repr__(self):
return "%.17gj%+.17g" % (self.imag, self.real)
a = madcomplex(-3, 4)
verify(repr(a) == "4j-3")
base = complex(-3, 4)
verify(base.__class__ is complex)
Added subclass equality tests. Almost all of these are commented out now, because they don't work yet.
2001-09-12 16:53:15 -03:00
#XXX verify(a == base)
Again perhaps the end of [#460020] bug or feature: unicode() and subclasses. Inhibited complex unary plus optimization when applied to a complex subtype. Added PyComplex_CheckExact macro. Some comments and minor code fiddling.
2001-09-12 16:12:49 -03:00
verify(complex(a) == base)
verify(complex(a).__class__ is complex)
a = madcomplex(a) # just trying another form of the constructor
verify(repr(a) == "4j-3")
Added subclass equality tests. Almost all of these are commented out now, because they don't work yet.
2001-09-12 16:53:15 -03:00
#XXX verify(a == base)
Again perhaps the end of [#460020] bug or feature: unicode() and subclasses. Inhibited complex unary plus optimization when applied to a complex subtype. Added PyComplex_CheckExact macro. Some comments and minor code fiddling.
2001-09-12 16:12:49 -03:00
verify(complex(a) == base)
verify(complex(a).__class__ is complex)
verify(hash(a) == hash(base))
verify((+a).__class__ is complex)
verify((a + 0).__class__ is complex)
verify(a + 0 == base)
verify((a - 0).__class__ is complex)
verify(a - 0 == base)
verify((a * 1).__class__ is complex)
verify(a * 1 == base)
verify((a / 1).__class__ is complex)
verify(a / 1 == base)
Add testcases for inheritance from tricky builtins (numbers, strings, tuples).
2001-08-30 17:06:08 -03:00
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))
Added subclass equality tests. Almost all of these are commented out now, because they don't work yet.
2001-09-12 16:53:15 -03:00
verify(a == (1,2,3,4,5,6,7,8,9,0))
Add testcases for inheritance from tricky builtins (numbers, strings, tuples).
2001-08-30 17:06:08 -03:00
verify(a.rev() == madtuple((0,9,8,7,6,5,4,3,2,1)))
verify(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()
verify(v == t)
SF bug #460020: bug or feature: unicode() and subclasses. Given an immutable type M, and an instance I of a subclass of M, the constructor call M(I) was just returning I as-is; but it should return a new instance of M. This fixes it for M in {int, long}. Strings, floats and tuples remain to be done. Added new macros PyInt_CheckExact and PyLong_CheckExact, to more easily distinguish between "is" and "is a" (i.e., only an int passes PyInt_CheckExact, while any sublass of int passes PyInt_Check). Added private API function _PyLong_Copy.
2001-09-10 17:52:51 -03:00
a = madtuple((1,2,3,4,5))
verify(tuple(a) == (1,2,3,4,5))
More on SF bug [#460020] bug or feature: unicode() and subclasses. tuple(i) repaired to return a true tuple when i is an instance of a tuple subclass. Added PyTuple_CheckExact macro. PySequence_Tuple(): if a tuple-like object isn't exactly a tuple, it's not safe to return the object as-is -- make a new tuple of it instead.
2001-09-10 20:37:46 -03:00
verify(tuple(a).__class__ is tuple)
str_subtype_new, unicode_subtype_new: + These were leaving the hash fields at 0, which all string and unicode routines believe is a legitimate hash code. As a result, hash() applied to str and unicode subclass instances always returned 0, which in turn confused dict operations, etc. + Changed local names "new"; no point to antagonizing C++ compilers.
2001-09-12 02:18:58 -03:00
verify(hash(a) == hash((1,2,3,4,5)))
The endless 460020 bug. Disable t[:], t*0, t*1 optimizations when t is of a tuple subclass type.
2001-09-11 16:48:03 -03:00
verify(a[:].__class__ is tuple)
verify((a * 1).__class__ is tuple)
verify((a * 0).__class__ is tuple)
verify((a + ()).__class__ is tuple)
SF bug #460020: bug or feature: unicode() and subclasses. Given an immutable type M, and an instance I of a subclass of M, the constructor call M(I) was just returning I as-is; but it should return a new instance of M. This fixes it for M in {int, long}. Strings, floats and tuples remain to be done. Added new macros PyInt_CheckExact and PyLong_CheckExact, to more easily distinguish between "is" and "is a" (i.e., only an int passes PyInt_CheckExact, while any sublass of int passes PyInt_Check). Added private API function _PyLong_Copy.
2001-09-10 17:52:51 -03:00
a = madtuple(())
verify(tuple(a) == ())
Restore the comparisons that I initially put in the test but that Tim XXX'ed out. Turns out that after fixing the constructors, the comparisons in fact succeed. E.g. int(hexint(12345)) returns an int with value 12345.
2001-09-11 11:02:22 -03:00
verify(tuple(a).__class__ is tuple)
The endless 460020 bug. Disable t[:], t*0, t*1 optimizations when t is of a tuple subclass type.
2001-09-11 16:48:03 -03:00
verify((a + a).__class__ is tuple)
verify((a * 0).__class__ is tuple)
verify((a * 1).__class__ is tuple)
verify((a * 2).__class__ is tuple)
verify(a[:].__class__ is tuple)
Add testcases for inheritance from tricky builtins (numbers, strings, tuples).
2001-08-30 17:06:08 -03:00
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")
Added subclass equality tests. Almost all of these are commented out now, because they don't work yet.
2001-09-12 16:53:15 -03:00
#XXX verify(s == "abcdefghijklmnopqrstuvwxyz")
Add testcases for inheritance from tricky builtins (numbers, strings, tuples).
2001-08-30 17:06:08 -03:00
verify(s.rev() == madstring("zyxwvutsrqponmlkjihgfedcba"))
verify(s.rev().rev() == madstring("abcdefghijklmnopqrstuvwxyz"))
for i in range(256):
s = madstring("".join(map(chr, range(i))))
t = s.rev()
u = t.rev()
verify(u == s)
SF bug #460020: bug or feature: unicode() and subclasses. Given an immutable type M, and an instance I of a subclass of M, the constructor call M(I) was just returning I as-is; but it should return a new instance of M. This fixes it for M in {int, long}. Strings, floats and tuples remain to be done. Added new macros PyInt_CheckExact and PyLong_CheckExact, to more easily distinguish between "is" and "is a" (i.e., only an int passes PyInt_CheckExact, while any sublass of int passes PyInt_Check). Added private API function _PyLong_Copy.
2001-09-10 17:52:51 -03:00
s = madstring("12345")
Restore the comparisons that I initially put in the test but that Tim XXX'ed out. Turns out that after fixing the constructors, the comparisons in fact succeed. E.g. int(hexint(12345)) returns an int with value 12345.
2001-09-11 11:02:22 -03:00
verify(str(s) == "12345")
More on SF bug [#460020] bug or feature: unicode() and subclasses. Repaired str(i) to return a genuine string when i is an instance of a str subclass. New PyString_CheckExact() macro.
2001-09-10 22:41:59 -03:00
verify(str(s).__class__ is str)
Add testcases for inheritance from tricky builtins (numbers, strings, tuples).
2001-08-30 17:06:08 -03:00
More bug 460020: lots of string optimizations inhibited for string subclasses, all "the usual" ones (slicing etc), plus replace, translate, ljust, rjust, center and strip. I don't know how to be sure they've all been caught. Question: Should we complain if someone tries to intern an instance of a string subclass? I hate to slow any code on those paths.
2001-09-11 23:18:30 -03:00
base = "\x00" * 5
s = madstring(base)
Added subclass equality tests. Almost all of these are commented out now, because they don't work yet.
2001-09-12 16:53:15 -03:00
#XXX verify(s == base)
More bug 460020: lots of string optimizations inhibited for string subclasses, all "the usual" ones (slicing etc), plus replace, translate, ljust, rjust, center and strip. I don't know how to be sure they've all been caught. Question: Should we complain if someone tries to intern an instance of a string subclass? I hate to slow any code on those paths.
2001-09-11 23:18:30 -03:00
verify(str(s) == base)
Added another test of str() applied to a string subclass instance, involving embedded null bytes, since it's possible to screw that up w/o screwing up cases w/o embedded nulls.
2001-09-10 22:52:02 -03:00
verify(str(s).__class__ is str)
str_subtype_new, unicode_subtype_new: + These were leaving the hash fields at 0, which all string and unicode routines believe is a legitimate hash code. As a result, hash() applied to str and unicode subclass instances always returned 0, which in turn confused dict operations, etc. + Changed local names "new"; no point to antagonizing C++ compilers.
2001-09-12 02:18:58 -03:00
verify(hash(s) == hash(base))
verify({s: 1}[base] == 1)
verify({base: 1}[s] == 1)
More bug 460020: lots of string optimizations inhibited for string subclasses, all "the usual" ones (slicing etc), plus replace, translate, ljust, rjust, center and strip. I don't know how to be sure they've all been caught. Question: Should we complain if someone tries to intern an instance of a string subclass? I hate to slow any code on those paths.
2001-09-11 23:18:30 -03:00
verify((s + "").__class__ is str)
More on bug 460020: disable many optimizations of unicode subclasses.
2001-09-12 00:03:31 -03:00
verify(s + "" == base)
More bug 460020: lots of string optimizations inhibited for string subclasses, all "the usual" ones (slicing etc), plus replace, translate, ljust, rjust, center and strip. I don't know how to be sure they've all been caught. Question: Should we complain if someone tries to intern an instance of a string subclass? I hate to slow any code on those paths.
2001-09-11 23:18:30 -03:00
verify(("" + s).__class__ is str)
More on bug 460020: disable many optimizations of unicode subclasses.
2001-09-12 00:03:31 -03:00
verify("" + s == base)
More bug 460020: lots of string optimizations inhibited for string subclasses, all "the usual" ones (slicing etc), plus replace, translate, ljust, rjust, center and strip. I don't know how to be sure they've all been caught. Question: Should we complain if someone tries to intern an instance of a string subclass? I hate to slow any code on those paths.
2001-09-11 23:18:30 -03:00
verify((s * 0).__class__ is str)
More on bug 460020: disable many optimizations of unicode subclasses.
2001-09-12 00:03:31 -03:00
verify(s * 0 == "")
More bug 460020: lots of string optimizations inhibited for string subclasses, all "the usual" ones (slicing etc), plus replace, translate, ljust, rjust, center and strip. I don't know how to be sure they've all been caught. Question: Should we complain if someone tries to intern an instance of a string subclass? I hate to slow any code on those paths.
2001-09-11 23:18:30 -03:00
verify((s * 1).__class__ is str)
More on bug 460020: disable many optimizations of unicode subclasses.
2001-09-12 00:03:31 -03:00
verify(s * 1 == base)
More bug 460020: lots of string optimizations inhibited for string subclasses, all "the usual" ones (slicing etc), plus replace, translate, ljust, rjust, center and strip. I don't know how to be sure they've all been caught. Question: Should we complain if someone tries to intern an instance of a string subclass? I hate to slow any code on those paths.
2001-09-11 23:18:30 -03:00
verify((s * 2).__class__ is str)
More on bug 460020: disable many optimizations of unicode subclasses.
2001-09-12 00:03:31 -03:00
verify(s * 2 == base + base)
More bug 460020: lots of string optimizations inhibited for string subclasses, all "the usual" ones (slicing etc), plus replace, translate, ljust, rjust, center and strip. I don't know how to be sure they've all been caught. Question: Should we complain if someone tries to intern an instance of a string subclass? I hate to slow any code on those paths.
2001-09-11 23:18:30 -03:00
verify(s[:].__class__ is str)
More on bug 460020: disable many optimizations of unicode subclasses.
2001-09-12 00:03:31 -03:00
verify(s[:] == base)
More bug 460020: lots of string optimizations inhibited for string subclasses, all "the usual" ones (slicing etc), plus replace, translate, ljust, rjust, center and strip. I don't know how to be sure they've all been caught. Question: Should we complain if someone tries to intern an instance of a string subclass? I hate to slow any code on those paths.
2001-09-11 23:18:30 -03:00
verify(s[0:0].__class__ is str)
More on bug 460020: disable many optimizations of unicode subclasses.
2001-09-12 00:03:31 -03:00
verify(s[0:0] == "")
More bug 460020: lots of string optimizations inhibited for string subclasses, all "the usual" ones (slicing etc), plus replace, translate, ljust, rjust, center and strip. I don't know how to be sure they've all been caught. Question: Should we complain if someone tries to intern an instance of a string subclass? I hate to slow any code on those paths.
2001-09-11 23:18:30 -03:00
verify(s.strip().__class__ is str)
More on bug 460020: disable many optimizations of unicode subclasses.
2001-09-12 00:03:31 -03:00
verify(s.strip() == base)
verify(s.lstrip().__class__ is str)
verify(s.lstrip() == base)
verify(s.rstrip().__class__ is str)
verify(s.rstrip() == base)
More bug 460020: lots of string optimizations inhibited for string subclasses, all "the usual" ones (slicing etc), plus replace, translate, ljust, rjust, center and strip. I don't know how to be sure they've all been caught. Question: Should we complain if someone tries to intern an instance of a string subclass? I hate to slow any code on those paths.
2001-09-11 23:18:30 -03:00
identitytab = ''.join([chr(i) for i in range(256)])
verify(s.translate(identitytab).__class__ is str)
verify(s.translate(identitytab) == base)
verify(s.translate(identitytab, "x").__class__ is str)
verify(s.translate(identitytab, "x") == base)
verify(s.translate(identitytab, "\x00") == "")
verify(s.replace("x", "x").__class__ is str)
verify(s.replace("x", "x") == base)
verify(s.ljust(len(s)).__class__ is str)
verify(s.ljust(len(s)) == base)
verify(s.rjust(len(s)).__class__ is str)
verify(s.rjust(len(s)) == base)
verify(s.center(len(s)).__class__ is str)
verify(s.center(len(s)) == base)
More on bug 460020: disable many optimizations of unicode subclasses.
2001-09-12 00:03:31 -03:00
verify(s.lower().__class__ is str)
verify(s.lower() == base)
Added another test of str() applied to a string subclass instance, involving embedded null bytes, since it's possible to screw that up w/o screwing up cases w/o embedded nulls.
2001-09-10 22:52:02 -03:00
If interning an instance of a string subclass, intern a real string object with the same value instead. This ensures that a string (or string subclass) object's ob_sinterned pointer is always a str (or NULL), and that the dict of interned strings only has strs as keys.
2001-09-12 04:54:51 -03:00
s = madstring("x y")
Added subclass equality tests. Almost all of these are commented out now, because they don't work yet.
2001-09-12 16:53:15 -03:00
#XXX verify(s == "x y")
If interning an instance of a string subclass, intern a real string object with the same value instead. This ensures that a string (or string subclass) object's ob_sinterned pointer is always a str (or NULL), and that the dict of interned strings only has strs as keys.
2001-09-12 04:54:51 -03:00
verify(intern(s).__class__ is str)
verify(intern(s) is intern("x y"))
verify(intern(s) == "x y")
i = intern("y x")
s = madstring("y x")
Added subclass equality tests. Almost all of these are commented out now, because they don't work yet.
2001-09-12 16:53:15 -03:00
#XXX verify(s == i)
If interning an instance of a string subclass, intern a real string object with the same value instead. This ensures that a string (or string subclass) object's ob_sinterned pointer is always a str (or NULL), and that the dict of interned strings only has strs as keys.
2001-09-12 04:54:51 -03:00
verify(intern(s).__class__ is str)
verify(intern(s) is i)
s = madstring(i)
verify(intern(s).__class__ is str)
verify(intern(s) is i)
metaclass(): add some more examples of metaclasses, including one using cooperative multiple inheritance. inherits(): add a test for subclassing the unicode type.
2001-08-30 17:52:40 -03:00
class madunicode(unicode):
_rev = None
def rev(self):
if self._rev is not None:
return self._rev
L = list(self)
L.reverse()
self._rev = self.__class__(u"".join(L))
return self._rev
u = madunicode("ABCDEF")
Added subclass equality tests. Almost all of these are commented out now, because they don't work yet.
2001-09-12 16:53:15 -03:00
verify(u == u"ABCDEF")
metaclass(): add some more examples of metaclasses, including one using cooperative multiple inheritance. inherits(): add a test for subclassing the unicode type.
2001-08-30 17:52:40 -03:00
verify(u.rev() == madunicode(u"FEDCBA"))
verify(u.rev().rev() == madunicode(u"ABCDEF"))
More on bug 460020: disable many optimizations of unicode subclasses.
2001-09-12 00:03:31 -03:00
base = u"12345"
u = madunicode(base)
verify(unicode(u) == base)
Possibly the end of SF [#460020] bug or feature: unicode() and subclasses. Changed unicode(i) to return a true Unicode object when i is an instance of a unicode subclass. Added PyUnicode_CheckExact macro.
2001-09-11 00:07:38 -03:00
verify(unicode(u).__class__ is unicode)
str_subtype_new, unicode_subtype_new: + These were leaving the hash fields at 0, which all string and unicode routines believe is a legitimate hash code. As a result, hash() applied to str and unicode subclass instances always returned 0, which in turn confused dict operations, etc. + Changed local names "new"; no point to antagonizing C++ compilers.
2001-09-12 02:18:58 -03:00
verify(hash(u) == hash(base))
verify({u: 1}[base] == 1)
verify({base: 1}[u] == 1)
More on bug 460020: disable many optimizations of unicode subclasses.
2001-09-12 00:03:31 -03:00
verify(u.strip().__class__ is unicode)
verify(u.strip() == base)
verify(u.lstrip().__class__ is unicode)
verify(u.lstrip() == base)
verify(u.rstrip().__class__ is unicode)
verify(u.rstrip() == base)
verify(u.replace(u"x", u"x").__class__ is unicode)
verify(u.replace(u"x", u"x") == base)
verify(u.replace(u"xy", u"xy").__class__ is unicode)
verify(u.replace(u"xy", u"xy") == base)
verify(u.center(len(u)).__class__ is unicode)
verify(u.center(len(u)) == base)
verify(u.ljust(len(u)).__class__ is unicode)
verify(u.ljust(len(u)) == base)
verify(u.rjust(len(u)).__class__ is unicode)
verify(u.rjust(len(u)) == base)
verify(u.lower().__class__ is unicode)
verify(u.lower() == base)
verify(u.upper().__class__ is unicode)
verify(u.upper() == base)
verify(u.capitalize().__class__ is unicode)
verify(u.capitalize() == base)
verify(u.title().__class__ is unicode)
verify(u.title() == base)
verify((u + u"").__class__ is unicode)
verify(u + u"" == base)
verify((u"" + u).__class__ is unicode)
verify(u"" + u == base)
verify((u * 0).__class__ is unicode)
verify(u * 0 == u"")
verify((u * 1).__class__ is unicode)
verify(u * 1 == base)
verify((u * 2).__class__ is unicode)
verify(u * 2 == base + base)
verify(u[:].__class__ is unicode)
verify(u[:] == base)
verify(u[0:0].__class__ is unicode)
verify(u[0:0] == u"")
metaclass(): add some more examples of metaclasses, including one using cooperative multiple inheritance. inherits(): add a test for subclassing the unicode type.
2001-08-30 17:52:40 -03:00
SF bug [#460467] file objects should be subclassable. Preliminary support. What's here works, but needs fine-tuning.
2001-09-13 02:38:56 -03:00
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
Use the keyword form of file() instead of open() to create TESTFN.
2001-09-13 16:36:36 -03:00
f = file(name=TESTFN, mode='w')
SF bug [#460467] file objects should be subclassable. Preliminary support. What's here works, but needs fine-tuning.
2001-09-13 02:38:56 -03:00
lines = ['a\n', 'b\n', 'c\n']
try:
f.writelines(lines)
f.close()
f = CountedInput(TESTFN)
for (i, expected) in zip(range(1, 5) + [4], lines + 2 * [""]):
got = f.readline()
verify(expected == got)
verify(f.lineno == i)
verify(f.ateof == (i > len(lines)))
f.close()
finally:
try:
f.close()
except:
pass
try:
import os
os.unlink(TESTFN)
except:
pass
Added simple tests of keyword arguments in the basic type constructors.
2001-09-13 16:33:07 -03:00
def keywords():
if verbose:
print "Testing keyword args to basic type constructors ..."
verify(int(x=1) == 1)
verify(float(x=2) == 2.0)
verify(long(x=3) == 3L)
verify(complex(imag=42, real=666) == complex(666, 42))
verify(str(object=500) == '500')
verify(unicode(string='abc', errors='strict') == u'abc')
verify(tuple(sequence=range(3)) == (0, 1, 2))
verify(list(sequence=(0, 1, 2)) == range(3))
verify(dictionary(mapping={1: 2}) == {1: 2})
for constructor in (int, float, long, complex, str, unicode,
tuple, list, dictionary, file):
try:
constructor(bogus_keyword_arg=1)
except TypeError:
pass
else:
raise TestFailed("expected TypeError from bogus keyword "
"argument to %r" % constructor)
Use the keyword form of file() instead of open() to create TESTFN.
2001-09-13 16:36:36 -03:00
Now that file objects are subclassable, you can get at the file constructor just by doing type(f) where f is any file object. This left a hole in restricted execution mode that rexec.py can't plug by itself (although it can plug part of it; the rest is plugged in fileobject.c now).
2001-09-13 18:01:29 -03:00
def restricted():
import rexec
if verbose:
print "Testing interaction with restricted execution ..."
sandbox = rexec.RExec()
code1 = """f = open(%r, 'w')""" % TESTFN
code2 = """f = file(%r, 'w')""" % TESTFN
code3 = """\
f = open(%r)
t = type(f) # a sneaky way to get the file() constructor
f.close()
f = t(%r, 'w') # rexec can't catch this by itself
""" % (TESTFN, TESTFN)
f = open(TESTFN, 'w') # Create the file so code3 can find it.
f.close()
try:
for code in code1, code2, code3:
try:
sandbox.r_exec(code)
except IOError, msg:
if str(msg).find("restricted") >= 0:
outcome = "OK"
else:
outcome = "got an exception, but not an expected one"
else:
outcome = "expected a restricted-execution exception"
if outcome != "OK":
raise TestFailed("%s, in %r" % (outcome, code))
finally:
try:
import os
os.unlink(TESTFN)
except:
pass
Merge of descr-branch back into trunk.
2001-08-02 01:15:00 -03:00
def all():
lists()
dicts()
Make dictionary() a real constructor. Accepts at most one argument, "a mapping object", in the same sense dict.update(x) requires of x (that x has a keys() method and a getitem). Questionable: The other type constructors accept a keyword argument, so I did that here too (e.g., dictionary(mapping={1:2}) works). But type_call doesn't pass the keyword args to the tp_new slot (it passes NULL), it only passes them to the tp_init slot, so getting at them required adding a tp_init slot to dicts. Looks like that makes the normal case (i.e., no args at all) a little slower (the time it takes to call dict.tp_init and have it figure out there's nothing to do).
2001-09-02 05:22:48 -03:00
dict_constructor()
Make dir() wordier (see the new docstring). The new behavior is a mixed bag. It's clearly wrong for classic classes, at heart because a classic class doesn't have a __class__ attribute, and I'm unclear on whether that's feature or bug. I'll repair this once I find out (in the meantime, dir() applied to classic classes won't find the base classes, while dir() applied to a classic-class instance *will* find the base classes but not *their* base classes). Please give the new dir() a try and see whether you love it or hate it. The new dir([]) behavior is something I could come to love. Here's something to hate: >>> class C: ... pass ... >>> c = C() >>> dir(c) ['__doc__', '__module__'] >>> The idea that an instance has a __doc__ attribute is jarring (of course it's really c.__class__.__doc__ == C.__doc__; likewise for __module__). OTOH, the code already has too many special cases, and dir(x) doesn't have a compelling or clear purpose when x isn't a module.
2001-09-03 02:47:38 -03:00
test_dir()
Merge of descr-branch back into trunk.
2001-08-02 01:15:00 -03:00
ints()
longs()
floats()
complexes()
spamlists()
spamdicts()
pydicts()
pylists()
metaclass()
pymods()
multi()
diamond()
Restore the test for 'object' that I removed when object was uninstantiable. All is well now.
2001-08-09 16:45:21 -03:00
objects()
Merge of descr-branch back into trunk.
2001-08-02 01:15:00 -03:00
slots()
dynamics()
errors()
classmethods()
staticmethods()
classic()
compattr()
newslot()
altmro()
overloading()
Add a test to verify that bound methods work correctly.
2001-08-15 14:51:17 -03:00
methods()
Add tests for overridable operators that have default interpretations (__hash__ etc.), in static and dynamic classes, overridden and default.
2001-08-15 20:57:59 -03:00
specials()
Add test for weak references.
2001-08-17 18:27:53 -03:00
weakrefs()
Rename 'getset' to 'property'.
2001-09-06 18:56:42 -03:00
properties()
Add test suite for super().
2001-08-24 13:55:27 -03:00
supers()
Add testcases for inheritance from tricky builtins (numbers, strings, tuples).
2001-08-30 17:06:08 -03:00
inherits()
Added simple tests of keyword arguments in the basic type constructors.
2001-09-13 16:33:07 -03:00
keywords()
Now that file objects are subclassable, you can get at the file constructor just by doing type(f) where f is any file object. This left a hole in restricted execution mode that rexec.py can't plug by itself (although it can plug part of it; the rest is plugged in fileobject.c now).
2001-09-13 18:01:29 -03:00
restricted()
Merge of descr-branch back into trunk.
2001-08-02 01:15:00 -03:00
all()
if verbose: print "All OK"