# Authors: # Jason Gerard DeRose # # Copyright (C) 2008 Red Hat # see file 'COPYING' for use and warranty information # # This program is free software; you can redistribute it and/or modify # it under the terms of the GNU General Public License as published by # the Free Software Foundation, either version 3 of the License, or # (at your option) any later version. # # This program is distributed in the hope that it will be useful, # but WITHOUT ANY WARRANTY; without even the implied warranty of # MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the # GNU General Public License for more details. # # You should have received a copy of the GNU General Public License # along with this program. If not, see . """ Test the `ipalib.base` module. """ from tests.util import ClassChecker, raises from ipalib.constants import NAME_REGEX, NAME_ERROR from ipalib.constants import TYPE_ERROR, SET_ERROR, DEL_ERROR, OVERRIDE_ERROR from ipalib import base class test_ReadOnly(ClassChecker): """ Test the `ipalib.base.ReadOnly` class """ _cls = base.ReadOnly def test_lock(self): """ Test the `ipalib.base.ReadOnly.__lock__` method. """ o = self.cls() assert o._ReadOnly__locked is False o.__lock__() assert o._ReadOnly__locked is True e = raises(AssertionError, o.__lock__) # Can only be locked once assert str(e) == '__lock__() can only be called once' assert o._ReadOnly__locked is True # This should still be True def test_islocked(self): """ Test the `ipalib.base.ReadOnly.__islocked__` method. """ o = self.cls() assert o.__islocked__() is False o.__lock__() assert o.__islocked__() is True def test_setattr(self): """ Test the `ipalib.base.ReadOnly.__setattr__` method. """ o = self.cls() o.attr1 = 'Hello, world!' assert o.attr1 == 'Hello, world!' o.__lock__() for name in ('attr1', 'attr2'): e = raises(AttributeError, setattr, o, name, 'whatever') assert str(e) == SET_ERROR % ('ReadOnly', name, 'whatever') assert o.attr1 == 'Hello, world!' def test_delattr(self): """ Test the `ipalib.base.ReadOnly.__delattr__` method. """ o = self.cls() o.attr1 = 'Hello, world!' o.attr2 = 'How are you?' assert o.attr1 == 'Hello, world!' assert o.attr2 == 'How are you?' del o.attr1 assert not hasattr(o, 'attr1') o.__lock__() e = raises(AttributeError, delattr, o, 'attr2') assert str(e) == DEL_ERROR % ('ReadOnly', 'attr2') assert o.attr2 == 'How are you?' def test_lock(): """ Test the `ipalib.base.lock` function """ f = base.lock # Test with ReadOnly instance: o = base.ReadOnly() assert o.__islocked__() is False assert f(o) is o assert o.__islocked__() is True e = raises(AssertionError, f, o) assert str(e) == 'already locked: %r' % o # Test with another class implemented locking protocol: class Lockable(object): __locked = False def __lock__(self): self.__locked = True def __islocked__(self): return self.__locked o = Lockable() assert o.__islocked__() is False assert f(o) is o assert o.__islocked__() is True e = raises(AssertionError, f, o) assert str(e) == 'already locked: %r' % o # Test with a class incorrectly implementing the locking protocol: class Broken(object): def __lock__(self): pass def __islocked__(self): return False o = Broken() e = raises(AssertionError, f, o) assert str(e) == 'failed to lock: %r' % o def test_islocked(): """ Test the `ipalib.base.islocked` function. """ f = base.islocked # Test with ReadOnly instance: o = base.ReadOnly() assert f(o) is False o.__lock__() assert f(o) is True # Test with another class implemented locking protocol: class Lockable(object): __locked = False def __lock__(self): self.__locked = True def __islocked__(self): return self.__locked o = Lockable() assert f(o) is False o.__lock__() assert f(o) is True # Test with a class incorrectly implementing the locking protocol: class Broken(object): __lock__ = False def __islocked__(self): return False o = Broken() e = raises(AssertionError, f, o) assert str(e) == 'no __lock__() method: %r' % o def test_check_name(): """ Test the `ipalib.base.check_name` function. """ f = base.check_name okay = [ 'user_add', 'stuff2junk', 'sixty9', ] nope = [ '_user_add', '__user_add', 'user_add_', 'user_add__', '_user_add_', '__user_add__', '60nine', ] for name in okay: assert name is f(name) e = raises(TypeError, f, unicode(name)) assert str(e) == TYPE_ERROR % ('name', str, unicode(name), unicode) for name in nope: e = raises(ValueError, f, name) assert str(e) == NAME_ERROR % (NAME_REGEX, name) for name in okay: e = raises(ValueError, f, name.upper()) assert str(e) == NAME_ERROR % (NAME_REGEX, name.upper()) def membername(i): return 'member%03d' % i class DummyMember(object): def __init__(self, i): self.i = i self.name = membername(i) def gen_members(*indexes): return tuple(DummyMember(i) for i in indexes) class test_NameSpace(ClassChecker): """ Test the `ipalib.base.NameSpace` class. """ _cls = base.NameSpace def new(self, count, sort=True): members = tuple(DummyMember(i) for i in xrange(count, 0, -1)) assert len(members) == count o = self.cls(members, sort=sort) return (o, members) def test_init(self): """ Test the `ipalib.base.NameSpace.__init__` method. """ o = self.cls([]) assert len(o) == 0 assert list(o) == [] assert list(o()) == [] # Test members as attribute and item: for cnt in (3, 42): for sort in (True, False): (o, members) = self.new(cnt, sort=sort) assert len(members) == cnt for m in members: assert getattr(o, m.name) is m assert o[m.name] is m # Test that TypeError is raised if sort is not a bool: e = raises(TypeError, self.cls, [], sort=None) assert str(e) == TYPE_ERROR % ('sort', bool, None, type(None)) # Test that AttributeError is raised with duplicate member name: members = gen_members(0, 1, 2, 1, 3) e = raises(AttributeError, self.cls, members) assert str(e) == OVERRIDE_ERROR % ( 'NameSpace', membername(1), members[1], members[3] ) def test_len(self): """ Test the `ipalib.base.NameSpace.__len__` method. """ for count in (5, 18, 127): (o, members) = self.new(count) assert len(o) == count (o, members) = self.new(count, sort=False) assert len(o) == count def test_iter(self): """ Test the `ipalib.base.NameSpace.__iter__` method. """ (o, members) = self.new(25) assert list(o) == sorted(m.name for m in members) (o, members) = self.new(25, sort=False) assert list(o) == list(m.name for m in members) def test_call(self): """ Test the `ipalib.base.NameSpace.__call__` method. """ (o, members) = self.new(25) assert list(o()) == sorted(members, key=lambda m: m.name) (o, members) = self.new(25, sort=False) assert tuple(o()) == members def test_contains(self): """ Test the `ipalib.base.NameSpace.__contains__` method. """ yes = (99, 3, 777) no = (9, 333, 77) for sort in (True, False): members = gen_members(*yes) o = self.cls(members, sort=sort) for i in yes: assert membername(i) in o assert membername(i).upper() not in o for i in no: assert membername(i) not in o def test_getitem(self): """ Test the `ipalib.base.NameSpace.__getitem__` method. """ cnt = 17 for sort in (True, False): (o, members) = self.new(cnt, sort=sort) assert len(members) == cnt if sort is True: members = tuple(sorted(members, key=lambda m: m.name)) # Test str keys: for m in members: assert o[m.name] is m e = raises(KeyError, o.__getitem__, 'nope') # Test int indexes: for i in xrange(cnt): assert o[i] is members[i] e = raises(IndexError, o.__getitem__, cnt) # Test negative int indexes: for i in xrange(1, cnt + 1): assert o[-i] is members[-i] e = raises(IndexError, o.__getitem__, -(cnt + 1)) # Test slicing: assert o[3:] == members[3:] assert o[:10] == members[:10] assert o[3:10] == members[3:10] assert o[-9:] == members[-9:] assert o[:-4] == members[:-4] assert o[-9:-4] == members[-9:-4] # Test that TypeError is raised with wrong type e = raises(TypeError, o.__getitem__, 3.0) assert str(e) == TYPE_ERROR % ('key', (str, int, slice), 3.0, float) def test_repr(self): """ Test the `ipalib.base.NameSpace.__repr__` method. """ for cnt in (0, 1, 2): for sort in (True, False): (o, members) = self.new(cnt, sort=sort) if cnt == 1: assert repr(o) == \ 'NameSpace(<%d member>, sort=%r)' % (cnt, sort) else: assert repr(o) == \ 'NameSpace(<%d members>, sort=%r)' % (cnt, sort) def test_todict(self): """ Test the `ipalib.base.NameSpace.__todict__` method. """ for cnt in (3, 101): for sort in (True, False): (o, members) = self.new(cnt, sort=sort) d = o.__todict__() assert d == dict((m.name, m) for m in members) # Test that a copy is returned: assert o.__todict__() is not d