lib/python2.7/test/test_richcmp.py - platform/prebuilts/python/darwin-x86/2.7.5 - Git at Google

 # Tests for rich comparisons

 import unittest
 from test import test_support

 import operator

 class Number:

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

     def __lt__(self, other):
         return self.x < other

     def __le__(self, other):
         return self.x <= other

     def __eq__(self, other):
         return self.x == other

     def __ne__(self, other):
         return self.x != other

     def __gt__(self, other):
         return self.x > other

     def __ge__(self, other):
         return self.x >= other

     def __cmp__(self, other):
         raise test_support.TestFailed, "Number.__cmp__() should not be called"

     def __repr__(self):
         return "Number(%r)" % (self.x, )

 class Vector:

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

     def __len__(self):
         return len(self.data)

     def __getitem__(self, i):
         return self.data[i]

     def __setitem__(self, i, v):
         self.data[i] = v

     __hash__ = None # Vectors cannot be hashed

     def __nonzero__(self):
         raise TypeError, "Vectors cannot be used in Boolean contexts"

     def __cmp__(self, other):
         raise test_support.TestFailed, "Vector.__cmp__() should not be called"

     def __repr__(self):
         return "Vector(%r)" % (self.data, )

     def __lt__(self, other):
         return Vector([a < b for a, b in zip(self.data, self.__cast(other))])

     def __le__(self, other):
         return Vector([a <= b for a, b in zip(self.data, self.__cast(other))])

     def __eq__(self, other):
         return Vector([a == b for a, b in zip(self.data, self.__cast(other))])

     def __ne__(self, other):
         return Vector([a != b for a, b in zip(self.data, self.__cast(other))])

     def __gt__(self, other):
         return Vector([a > b for a, b in zip(self.data, self.__cast(other))])

     def __ge__(self, other):
         return Vector([a >= b for a, b in zip(self.data, self.__cast(other))])

     def __cast(self, other):
         if isinstance(other, Vector):
             other = other.data
         if len(self.data) != len(other):
             raise ValueError, "Cannot compare vectors of different length"
         return other

 opmap = {
     "lt": (lambda a,b: a< b, operator.lt, operator.__lt__),
     "le": (lambda a,b: a<=b, operator.le, operator.__le__),
     "eq": (lambda a,b: a==b, operator.eq, operator.__eq__),
     "ne": (lambda a,b: a!=b, operator.ne, operator.__ne__),
     "gt": (lambda a,b: a> b, operator.gt, operator.__gt__),
     "ge": (lambda a,b: a>=b, operator.ge, operator.__ge__)
 }

 class VectorTest(unittest.TestCase):

     def checkfail(self, error, opname, *args):
         for op in opmap[opname]:
             self.assertRaises(error, op, *args)

     def checkequal(self, opname, a, b, expres):
         for op in opmap[opname]:
             realres = op(a, b)
             # can't use assertEqual(realres, expres) here
             self.assertEqual(len(realres), len(expres))
             for i in xrange(len(realres)):
                 # results are bool, so we can use "is" here
                 self.assertTrue(realres[i] is expres[i])

     def test_mixed(self):
         # check that comparisons involving Vector objects
         # which return rich results (i.e. Vectors with itemwise
         # comparison results) work
         a = Vector(range(2))
         b = Vector(range(3))
         # all comparisons should fail for different length
         for opname in opmap:
             self.checkfail(ValueError, opname, a, b)

         a = range(5)
         b = 5 * [2]
         # try mixed arguments (but not (a, b) as that won't return a bool vector)
         args = [(a, Vector(b)), (Vector(a), b), (Vector(a), Vector(b))]
         for (a, b) in args:
             self.checkequal("lt", a, b, [True,  True,  False, False, False])
             self.checkequal("le", a, b, [True,  True,  True,  False, False])
             self.checkequal("eq", a, b, [False, False, True,  False, False])
             self.checkequal("ne", a, b, [True,  True,  False, True,  True ])
             self.checkequal("gt", a, b, [False, False, False, True,  True ])
             self.checkequal("ge", a, b, [False, False, True,  True,  True ])

             for ops in opmap.itervalues():
                 for op in ops:
                     # calls __nonzero__, which should fail
                     self.assertRaises(TypeError, bool, op(a, b))

 class NumberTest(unittest.TestCase):

     def test_basic(self):
         # Check that comparisons involving Number objects
         # give the same results give as comparing the
         # corresponding ints
         for a in xrange(3):
             for b in xrange(3):
                 for typea in (int, Number):
                     for typeb in (int, Number):
                         if typea==typeb==int:
                             continue # the combination int, int is useless
                         ta = typea(a)
                         tb = typeb(b)
                         for ops in opmap.itervalues():
                             for op in ops:
                                 realoutcome = op(a, b)
                                 testoutcome = op(ta, tb)
                                 self.assertEqual(realoutcome, testoutcome)

     def checkvalue(self, opname, a, b, expres):
         for typea in (int, Number):
             for typeb in (int, Number):
                 ta = typea(a)
                 tb = typeb(b)
                 for op in opmap[opname]:
                     realres = op(ta, tb)
                     realres = getattr(realres, "x", realres)
                     self.assertTrue(realres is expres)

     def test_values(self):
         # check all operators and all comparison results
         self.checkvalue("lt", 0, 0, False)
         self.checkvalue("le", 0, 0, True )
         self.checkvalue("eq", 0, 0, True )
         self.checkvalue("ne", 0, 0, False)
         self.checkvalue("gt", 0, 0, False)
         self.checkvalue("ge", 0, 0, True )

         self.checkvalue("lt", 0, 1, True )
         self.checkvalue("le", 0, 1, True )
         self.checkvalue("eq", 0, 1, False)
         self.checkvalue("ne", 0, 1, True )
         self.checkvalue("gt", 0, 1, False)
         self.checkvalue("ge", 0, 1, False)

         self.checkvalue("lt", 1, 0, False)
         self.checkvalue("le", 1, 0, False)
         self.checkvalue("eq", 1, 0, False)
         self.checkvalue("ne", 1, 0, True )
         self.checkvalue("gt", 1, 0, True )
         self.checkvalue("ge", 1, 0, True )

 class MiscTest(unittest.TestCase):

     def test_misbehavin(self):
         class Misb:
             def __lt__(self_, other): return 0
             def __gt__(self_, other): return 0
             def __eq__(self_, other): return 0
             def __le__(self_, other): self.fail("This shouldn't happen")
             def __ge__(self_, other): self.fail("This shouldn't happen")
             def __ne__(self_, other): self.fail("This shouldn't happen")
             def __cmp__(self_, other): raise RuntimeError, "expected"
         a = Misb()
         b = Misb()
         self.assertEqual(a<b, 0)
         self.assertEqual(a==b, 0)
         self.assertEqual(a>b, 0)
         self.assertRaises(RuntimeError, cmp, a, b)

     def test_not(self):
         # Check that exceptions in __nonzero__ are properly
         # propagated by the not operator
         import operator
         class Exc(Exception):
             pass
         class Bad:
             def __nonzero__(self):
                 raise Exc

         def do(bad):
             not bad

         for func in (do, operator.not_):
             self.assertRaises(Exc, func, Bad())

     def test_recursion(self):
         # Check that comparison for recursive objects fails gracefully
         from UserList import UserList
         a = UserList()
         b = UserList()
         a.append(b)
         b.append(a)
         self.assertRaises(RuntimeError, operator.eq, a, b)
         self.assertRaises(RuntimeError, operator.ne, a, b)
         self.assertRaises(RuntimeError, operator.lt, a, b)
         self.assertRaises(RuntimeError, operator.le, a, b)
         self.assertRaises(RuntimeError, operator.gt, a, b)
         self.assertRaises(RuntimeError, operator.ge, a, b)

         b.append(17)
         # Even recursive lists of different lengths are different,
         # but they cannot be ordered
         self.assertTrue(not (a == b))
         self.assertTrue(a != b)
         self.assertRaises(RuntimeError, operator.lt, a, b)
         self.assertRaises(RuntimeError, operator.le, a, b)
         self.assertRaises(RuntimeError, operator.gt, a, b)
         self.assertRaises(RuntimeError, operator.ge, a, b)
         a.append(17)
         self.assertRaises(RuntimeError, operator.eq, a, b)
         self.assertRaises(RuntimeError, operator.ne, a, b)
         a.insert(0, 11)
         b.insert(0, 12)
         self.assertTrue(not (a == b))
         self.assertTrue(a != b)
         self.assertTrue(a < b)

 class DictTest(unittest.TestCase):

     def test_dicts(self):
         # Verify that __eq__ and __ne__ work for dicts even if the keys and
         # values don't support anything other than __eq__ and __ne__ (and
         # __hash__).  Complex numbers are a fine example of that.
         import random
         imag1a = {}
         for i in range(50):
             imag1a[random.randrange(100)*1j] = random.randrange(100)*1j
         items = imag1a.items()
         random.shuffle(items)
         imag1b = {}
         for k, v in items:
             imag1b[k] = v
         imag2 = imag1b.copy()
         imag2[k] = v + 1.0
         self.assertTrue(imag1a == imag1a)
         self.assertTrue(imag1a == imag1b)
         self.assertTrue(imag2 == imag2)
         self.assertTrue(imag1a != imag2)
         for opname in ("lt", "le", "gt", "ge"):
             for op in opmap[opname]:
                 self.assertRaises(TypeError, op, imag1a, imag2)

 class ListTest(unittest.TestCase):

     def test_coverage(self):
         # exercise all comparisons for lists
         x = [42]
         self.assertIs(x<x, False)
         self.assertIs(x<=x, True)
         self.assertIs(x==x, True)
         self.assertIs(x!=x, False)
         self.assertIs(x>x, False)
         self.assertIs(x>=x, True)
         y = [42, 42]
         self.assertIs(x<y, True)
         self.assertIs(x<=y, True)
         self.assertIs(x==y, False)
         self.assertIs(x!=y, True)
         self.assertIs(x>y, False)
         self.assertIs(x>=y, False)

     def test_badentry(self):
         # make sure that exceptions for item comparison are properly
         # propagated in list comparisons
         class Exc(Exception):
             pass
         class Bad:
             def __eq__(self, other):
                 raise Exc

         x = [Bad()]
         y = [Bad()]

         for op in opmap["eq"]:
             self.assertRaises(Exc, op, x, y)

     def test_goodentry(self):
         # This test exercises the final call to PyObject_RichCompare()
         # in Objects/listobject.c::list_richcompare()
         class Good:
             def __lt__(self, other):
                 return True

         x = [Good()]
         y = [Good()]

         for op in opmap["lt"]:
             self.assertIs(op(x, y), True)

 def test_main():
     test_support.run_unittest(VectorTest, NumberTest, MiscTest, ListTest)
     with test_support.check_py3k_warnings(("dict inequality comparisons "
                                              "not supported in 3.x",
                                              DeprecationWarning)):
         test_support.run_unittest(DictTest)


 if __name__ == "__main__":
     test_main()
	# Tests for rich comparisons

	import unittest
	from test import test_support

	import operator

	class Number:

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

	def __lt__(self, other):
	return self.x < other

	def __le__(self, other):
	return self.x <= other

	def __eq__(self, other):
	return self.x == other

	def __ne__(self, other):
	return self.x != other

	def __gt__(self, other):
	return self.x > other

	def __ge__(self, other):
	return self.x >= other

	def __cmp__(self, other):
	raise test_support.TestFailed, "Number.__cmp__() should not be called"

	def __repr__(self):
	return "Number(%r)" % (self.x, )

	class Vector:

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

	def __len__(self):
	return len(self.data)

	def __getitem__(self, i):
	return self.data[i]

	def __setitem__(self, i, v):
	self.data[i] = v

	__hash__ = None # Vectors cannot be hashed

	def __nonzero__(self):
	raise TypeError, "Vectors cannot be used in Boolean contexts"

	def __cmp__(self, other):
	raise test_support.TestFailed, "Vector.__cmp__() should not be called"

	def __repr__(self):
	return "Vector(%r)" % (self.data, )

	def __lt__(self, other):
	return Vector([a < b for a, b in zip(self.data, self.__cast(other))])

	def __le__(self, other):
	return Vector([a <= b for a, b in zip(self.data, self.__cast(other))])

	def __eq__(self, other):
	return Vector([a == b for a, b in zip(self.data, self.__cast(other))])

	def __ne__(self, other):
	return Vector([a != b for a, b in zip(self.data, self.__cast(other))])

	def __gt__(self, other):
	return Vector([a > b for a, b in zip(self.data, self.__cast(other))])

	def __ge__(self, other):
	return Vector([a >= b for a, b in zip(self.data, self.__cast(other))])

	def __cast(self, other):
	if isinstance(other, Vector):
	other = other.data
	if len(self.data) != len(other):
	raise ValueError, "Cannot compare vectors of different length"
	return other

	opmap = {
	"lt": (lambda a,b: a< b, operator.lt, operator.__lt__),
	"le": (lambda a,b: a<=b, operator.le, operator.__le__),
	"eq": (lambda a,b: a==b, operator.eq, operator.__eq__),
	"ne": (lambda a,b: a!=b, operator.ne, operator.__ne__),
	"gt": (lambda a,b: a> b, operator.gt, operator.__gt__),
	"ge": (lambda a,b: a>=b, operator.ge, operator.__ge__)
	}

	class VectorTest(unittest.TestCase):

	def checkfail(self, error, opname, *args):
	for op in opmap[opname]:
	self.assertRaises(error, op, *args)

	def checkequal(self, opname, a, b, expres):
	for op in opmap[opname]:
	realres = op(a, b)
	# can't use assertEqual(realres, expres) here
	self.assertEqual(len(realres), len(expres))
	for i in xrange(len(realres)):
	# results are bool, so we can use "is" here
	self.assertTrue(realres[i] is expres[i])

	def test_mixed(self):
	# check that comparisons involving Vector objects
	# which return rich results (i.e. Vectors with itemwise
	# comparison results) work
	a = Vector(range(2))
	b = Vector(range(3))
	# all comparisons should fail for different length
	for opname in opmap:
	self.checkfail(ValueError, opname, a, b)

	a = range(5)
	b = 5 * [2]
	# try mixed arguments (but not (a, b) as that won't return a bool vector)
	args = [(a, Vector(b)), (Vector(a), b), (Vector(a), Vector(b))]
	for (a, b) in args:
	self.checkequal("lt", a, b, [True, True, False, False, False])
	self.checkequal("le", a, b, [True, True, True, False, False])
	self.checkequal("eq", a, b, [False, False, True, False, False])
	self.checkequal("ne", a, b, [True, True, False, True, True ])
	self.checkequal("gt", a, b, [False, False, False, True, True ])
	self.checkequal("ge", a, b, [False, False, True, True, True ])

	for ops in opmap.itervalues():
	for op in ops:
	# calls __nonzero__, which should fail
	self.assertRaises(TypeError, bool, op(a, b))

	class NumberTest(unittest.TestCase):

	def test_basic(self):
	# Check that comparisons involving Number objects
	# give the same results give as comparing the
	# corresponding ints
	for a in xrange(3):
	for b in xrange(3):
	for typea in (int, Number):
	for typeb in (int, Number):
	if typea==typeb==int:
	continue # the combination int, int is useless
	ta = typea(a)
	tb = typeb(b)
	for ops in opmap.itervalues():
	for op in ops:
	realoutcome = op(a, b)
	testoutcome = op(ta, tb)
	self.assertEqual(realoutcome, testoutcome)

	def checkvalue(self, opname, a, b, expres):
	for typea in (int, Number):
	for typeb in (int, Number):
	ta = typea(a)
	tb = typeb(b)
	for op in opmap[opname]:
	realres = op(ta, tb)
	realres = getattr(realres, "x", realres)
	self.assertTrue(realres is expres)

	def test_values(self):
	# check all operators and all comparison results
	self.checkvalue("lt", 0, 0, False)
	self.checkvalue("le", 0, 0, True )
	self.checkvalue("eq", 0, 0, True )
	self.checkvalue("ne", 0, 0, False)
	self.checkvalue("gt", 0, 0, False)
	self.checkvalue("ge", 0, 0, True )

	self.checkvalue("lt", 0, 1, True )
	self.checkvalue("le", 0, 1, True )
	self.checkvalue("eq", 0, 1, False)
	self.checkvalue("ne", 0, 1, True )
	self.checkvalue("gt", 0, 1, False)
	self.checkvalue("ge", 0, 1, False)

	self.checkvalue("lt", 1, 0, False)
	self.checkvalue("le", 1, 0, False)
	self.checkvalue("eq", 1, 0, False)
	self.checkvalue("ne", 1, 0, True )
	self.checkvalue("gt", 1, 0, True )
	self.checkvalue("ge", 1, 0, True )

	class MiscTest(unittest.TestCase):

	def test_misbehavin(self):
	class Misb:
	def __lt__(self_, other): return 0
	def __gt__(self_, other): return 0
	def __eq__(self_, other): return 0
	def __le__(self_, other): self.fail("This shouldn't happen")
	def __ge__(self_, other): self.fail("This shouldn't happen")
	def __ne__(self_, other): self.fail("This shouldn't happen")
	def __cmp__(self_, other): raise RuntimeError, "expected"
	a = Misb()
	b = Misb()
	self.assertEqual(a<b, 0)
	self.assertEqual(a==b, 0)
	self.assertEqual(a>b, 0)
	self.assertRaises(RuntimeError, cmp, a, b)

	def test_not(self):
	# Check that exceptions in __nonzero__ are properly
	# propagated by the not operator
	import operator
	class Exc(Exception):
	pass
	class Bad:
	def __nonzero__(self):
	raise Exc

	def do(bad):
	not bad

	for func in (do, operator.not_):
	self.assertRaises(Exc, func, Bad())

	def test_recursion(self):
	# Check that comparison for recursive objects fails gracefully
	from UserList import UserList
	a = UserList()
	b = UserList()
	a.append(b)
	b.append(a)
	self.assertRaises(RuntimeError, operator.eq, a, b)
	self.assertRaises(RuntimeError, operator.ne, a, b)
	self.assertRaises(RuntimeError, operator.lt, a, b)
	self.assertRaises(RuntimeError, operator.le, a, b)
	self.assertRaises(RuntimeError, operator.gt, a, b)
	self.assertRaises(RuntimeError, operator.ge, a, b)

	b.append(17)
	# Even recursive lists of different lengths are different,
	# but they cannot be ordered
	self.assertTrue(not (a == b))
	self.assertTrue(a != b)
	self.assertRaises(RuntimeError, operator.lt, a, b)
	self.assertRaises(RuntimeError, operator.le, a, b)
	self.assertRaises(RuntimeError, operator.gt, a, b)
	self.assertRaises(RuntimeError, operator.ge, a, b)
	a.append(17)
	self.assertRaises(RuntimeError, operator.eq, a, b)
	self.assertRaises(RuntimeError, operator.ne, a, b)
	a.insert(0, 11)
	b.insert(0, 12)
	self.assertTrue(not (a == b))
	self.assertTrue(a != b)
	self.assertTrue(a < b)

	class DictTest(unittest.TestCase):

	def test_dicts(self):
	# Verify that __eq__ and __ne__ work for dicts even if the keys and
	# values don't support anything other than __eq__ and __ne__ (and
	# __hash__). Complex numbers are a fine example of that.
	import random
	imag1a = {}
	for i in range(50):
	imag1a[random.randrange(100)1j] = random.randrange(100)1j
	items = imag1a.items()
	random.shuffle(items)
	imag1b = {}
	for k, v in items:
	imag1b[k] = v
	imag2 = imag1b.copy()
	imag2[k] = v + 1.0
	self.assertTrue(imag1a == imag1a)
	self.assertTrue(imag1a == imag1b)
	self.assertTrue(imag2 == imag2)
	self.assertTrue(imag1a != imag2)
	for opname in ("lt", "le", "gt", "ge"):
	for op in opmap[opname]:
	self.assertRaises(TypeError, op, imag1a, imag2)

	class ListTest(unittest.TestCase):

	def test_coverage(self):
	# exercise all comparisons for lists
	x = [42]
	self.assertIs(x<x, False)
	self.assertIs(x<=x, True)
	self.assertIs(x==x, True)
	self.assertIs(x!=x, False)
	self.assertIs(x>x, False)
	self.assertIs(x>=x, True)
	y = [42, 42]
	self.assertIs(x<y, True)
	self.assertIs(x<=y, True)
	self.assertIs(x==y, False)
	self.assertIs(x!=y, True)
	self.assertIs(x>y, False)
	self.assertIs(x>=y, False)

	def test_badentry(self):
	# make sure that exceptions for item comparison are properly
	# propagated in list comparisons
	class Exc(Exception):
	pass
	class Bad:
	def __eq__(self, other):
	raise Exc

	x = [Bad()]
	y = [Bad()]

	for op in opmap["eq"]:
	self.assertRaises(Exc, op, x, y)

	def test_goodentry(self):
	# This test exercises the final call to PyObject_RichCompare()
	# in Objects/listobject.c::list_richcompare()
	class Good:
	def __lt__(self, other):
	return True

	x = [Good()]
	y = [Good()]

	for op in opmap["lt"]:
	self.assertIs(op(x, y), True)

	def test_main():
	test_support.run_unittest(VectorTest, NumberTest, MiscTest, ListTest)
	with test_support.check_py3k_warnings(("dict inequality comparisons "
	"not supported in 3.x",
	DeprecationWarning)):
	test_support.run_unittest(DictTest)


	if __name__ == "__main__":
	test_main()