# 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 `tests.util` module. """ import re import util from util import raises, TYPE, VALUE, LEN, KEYS class Prop(object): def __init__(self, *ops): self.__ops = frozenset(ops) self.__prop = 'prop value' def __get_prop(self): if 'get' not in self.__ops: raise AttributeError('get prop') return self.__prop def __set_prop(self, value): if 'set' not in self.__ops: raise AttributeError('set prop') self.__prop = value def __del_prop(self): if 'del' not in self.__ops: raise AttributeError('del prop') self.__prop = None prop = property(__get_prop, __set_prop, __del_prop) class test_Fuzzy(object): klass = util.Fuzzy def test_init(self): inst = self.klass() assert inst.regex is None assert inst.type is None assert inst.test is None assert inst.re is None inst = self.klass('(foo|bar)') assert inst.regex == '(foo|bar)' assert inst.type is unicode assert inst.test is None assert isinstance(inst.re, re._pattern_type) inst = self.klass('(foo|bar)', type=str) assert inst.regex == '(foo|bar)' assert inst.type is str assert inst.test is None assert isinstance(inst.re, re._pattern_type) t = lambda other: other > 500 inst = self.klass(test=t) assert inst.regex is None assert inst.type is None assert inst.test is t assert inst.re is None inst = self.klass(type=(int, float), test=t) assert inst.regex is None assert inst.type == (int, float) assert inst.test is t assert inst.re is None def test_repr(self): s = 'Fuzzy(%r, %r, %r)' t = lambda other: 0.0 <= other <= 1.0 inst = self.klass() assert repr(inst) == s % (None, None, None) inst = self.klass('foo') assert repr(inst) == s % ('foo', unicode, None) inst = self.klass(type=(int, float)) assert repr(inst) == s % (None, (int, float), None) inst = self.klass(type=(int, float), test=t) assert repr(inst) == s % (None, (int, float), t) inst = self.klass(test=t) assert repr(inst) == s % (None, None, t) def test_eq(self): assert (self.klass('bar') == u'foobar') is True assert (self.klass('^bar') == u'foobar') is False assert (self.klass('bar', type=str) == u'foobar') is False assert ('18' == self.klass()) is True assert ('18' == self.klass(type=int)) is False assert (18 == self.klass(type=int)) is True assert ('18' == self.klass(type=(int, str))) is True assert (self.klass() == '18') is True assert (self.klass(type=int) == '18') is False assert (self.klass(type=int) == 18) is True assert (self.klass(type=(int, str)) == '18') is True t = lambda other: other.endswith('bar') assert (self.klass(test=t) == 'foobar') is True assert (self.klass(test=t, type=unicode) == 'foobar') is False assert (self.klass(test=t) == 'barfoo') is False assert (False == self.klass()) is True assert (True == self.klass()) is True assert (None == self.klass()) is True def test_assert_deepequal(): f = util.assert_deepequal # Test with good scalar values: f(u'hello', u'hello') f(util.Fuzzy(), u'hello') f(util.Fuzzy(type=unicode), u'hello') f(util.Fuzzy('ell'), u'hello') f(util.Fuzzy(test=lambda other: other.endswith('llo')), u'hello') f(18, 18) f(util.Fuzzy(), 18) f(util.Fuzzy(type=int), 18) f(util.Fuzzy(type=(int, float), test=lambda other: other > 17.9), 18) # Test with bad scalar values: e = raises(AssertionError, f, u'hello', u'world', 'foo') assert str(e) == VALUE % ( 'foo', u'hello', u'world', tuple() ) e = raises(AssertionError, f, 'hello', u'hello', 'foo') assert str(e) == TYPE % ( 'foo', str, unicode, 'hello', u'hello', tuple() ) e = raises(AssertionError, f, 18, 18.0, 'foo') assert str(e) == TYPE % ( 'foo', int, float, 18, 18.0, tuple() ) # Test with good compound values: a = [ u'hello', dict(naughty=u'nurse'), 18, ] b = [ u'hello', dict(naughty=u'nurse'), 18, ] f(a, b) # Test with bad compound values: b = [ 'hello', dict(naughty=u'nurse'), 18, ] e = raises(AssertionError, f, a, b, 'foo') assert str(e) == TYPE % ( 'foo', unicode, str, u'hello', 'hello', (2,) ) b = [ u'hello', dict(naughty='nurse'), 18, ] e = raises(AssertionError, f, a, b, 'foo') assert str(e) == TYPE % ( 'foo', unicode, str, u'nurse', 'nurse', (1, 'naughty') ) b = [ u'hello', dict(naughty=u'nurse'), 18.0, ] e = raises(AssertionError, f, a, b, 'foo') assert str(e) == TYPE % ( 'foo', int, float, 18, 18.0, (0,) ) # List length mismatch b = [ u'hello', dict(naughty=u'nurse'), 18, 19 ] e = raises(AssertionError, f, a, b, 'foo') assert str(e) == LEN % ( 'foo', 3, 4, a, b, tuple() ) b = [ dict(naughty=u'nurse'), 18, ] e = raises(AssertionError, f, a, b, 'foo') assert str(e) == LEN % ( 'foo', 3, 2, a, b, tuple() ) # Dict keys mismatch: # Missing b = [ u'hello', dict(), 18, ] e = raises(AssertionError, f, a, b, 'foo') assert str(e) == KEYS % ('foo', ['naughty'], [], dict(naughty=u'nurse'), dict(), (1,) ) # Extra b = [ u'hello', dict(naughty=u'nurse', barely=u'legal'), 18, ] e = raises(AssertionError, f, a, b, 'foo') assert str(e) == KEYS % ('foo', [], ['barely'], dict(naughty=u'nurse'), dict(naughty=u'nurse', barely=u'legal'), (1,) ) # Missing + Extra b = [ u'hello', dict(barely=u'legal'), 18, ] e = raises(AssertionError, f, a, b, 'foo') assert str(e) == KEYS % ('foo', ['naughty'], ['barely'], dict(naughty=u'nurse'), dict(barely=u'legal'), (1,) ) def test_yes_raised(): f = util.raises class SomeError(Exception): pass class AnotherError(Exception): pass def callback1(): 'raises correct exception' raise SomeError() def callback2(): 'raises wrong exception' raise AnotherError() def callback3(): 'raises no exception' f(SomeError, callback1) raised = False try: f(SomeError, callback2) except AnotherError: raised = True assert raised raised = False try: f(SomeError, callback3) except util.ExceptionNotRaised: raised = True assert raised def test_no_set(): # Tests that it works when prop cannot be set: util.no_set(Prop('get', 'del'), 'prop') # Tests that ExceptionNotRaised is raised when prop *can* be set: raised = False try: util.no_set(Prop('set'), 'prop') except util.ExceptionNotRaised: raised = True assert raised def test_no_del(): # Tests that it works when prop cannot be deleted: util.no_del(Prop('get', 'set'), 'prop') # Tests that ExceptionNotRaised is raised when prop *can* be set: raised = False try: util.no_del(Prop('del'), 'prop') except util.ExceptionNotRaised: raised = True assert raised def test_read_only(): # Test that it works when prop is read only: assert util.read_only(Prop('get'), 'prop') == 'prop value' # Test that ExceptionNotRaised is raised when prop can be set: raised = False try: util.read_only(Prop('get', 'set'), 'prop') except util.ExceptionNotRaised: raised = True assert raised # Test that ExceptionNotRaised is raised when prop can be deleted: raised = False try: util.read_only(Prop('get', 'del'), 'prop') except util.ExceptionNotRaised: raised = True assert raised # Test that ExceptionNotRaised is raised when prop can be both set and # deleted: raised = False try: util.read_only(Prop('get', 'del'), 'prop') except util.ExceptionNotRaised: raised = True assert raised # Test that AttributeError is raised when prop can't be read: raised = False try: util.read_only(Prop(), 'prop') except AttributeError: raised = True assert raised