AppPkg/Applications/Python/Python-2.7.2/Lib/test/test_binop.py - edk2 - Git at Google

 """Tests for binary operators on subtypes of built-in types."""

 import unittest
 from test import test_support

 def gcd(a, b):
     """Greatest common divisor using Euclid's algorithm."""
     while a:
         a, b = b%a, a
     return b

 def isint(x):
     """Test whether an object is an instance of int or long."""
     return isinstance(x, int) or isinstance(x, long)

 def isnum(x):
     """Test whether an object is an instance of a built-in numeric type."""
     for T in int, long, float, complex:
         if isinstance(x, T):
             return 1
     return 0

 def isRat(x):
     """Test wheter an object is an instance of the Rat class."""
     return isinstance(x, Rat)

 class Rat(object):

     """Rational number implemented as a normalized pair of longs."""

     __slots__ = ['_Rat__num', '_Rat__den']

     def __init__(self, num=0L, den=1L):
         """Constructor: Rat([num[, den]]).

         The arguments must be ints or longs, and default to (0, 1)."""
         if not isint(num):
             raise TypeError, "Rat numerator must be int or long (%r)" % num
         if not isint(den):
             raise TypeError, "Rat denominator must be int or long (%r)" % den
         # But the zero is always on
         if den == 0:
             raise ZeroDivisionError, "zero denominator"
         g = gcd(den, num)
         self.__num = long(num//g)
         self.__den = long(den//g)

     def _get_num(self):
         """Accessor function for read-only 'num' attribute of Rat."""
         return self.__num
     num = property(_get_num, None)

     def _get_den(self):
         """Accessor function for read-only 'den' attribute of Rat."""
         return self.__den
     den = property(_get_den, None)

     def __repr__(self):
         """Convert a Rat to an string resembling a Rat constructor call."""
         return "Rat(%d, %d)" % (self.__num, self.__den)

     def __str__(self):
         """Convert a Rat to a string resembling a decimal numeric value."""
         return str(float(self))

     def __float__(self):
         """Convert a Rat to a float."""
         return self.__num*1.0/self.__den

     def __int__(self):
         """Convert a Rat to an int; self.den must be 1."""
         if self.__den == 1:
             try:
                 return int(self.__num)
             except OverflowError:
                 raise OverflowError, ("%s too large to convert to int" %
                                       repr(self))
         raise ValueError, "can't convert %s to int" % repr(self)

     def __long__(self):
         """Convert a Rat to an long; self.den must be 1."""
         if self.__den == 1:
             return long(self.__num)
         raise ValueError, "can't convert %s to long" % repr(self)

     def __add__(self, other):
         """Add two Rats, or a Rat and a number."""
         if isint(other):
             other = Rat(other)
         if isRat(other):
             return Rat(self.__num*other.__den + other.__num*self.__den,
                        self.__den*other.__den)
         if isnum(other):
             return float(self) + other
         return NotImplemented

     __radd__ = __add__

     def __sub__(self, other):
         """Subtract two Rats, or a Rat and a number."""
         if isint(other):
             other = Rat(other)
         if isRat(other):
             return Rat(self.__num*other.__den - other.__num*self.__den,
                        self.__den*other.__den)
         if isnum(other):
             return float(self) - other
         return NotImplemented

     def __rsub__(self, other):
         """Subtract two Rats, or a Rat and a number (reversed args)."""
         if isint(other):
             other = Rat(other)
         if isRat(other):
             return Rat(other.__num*self.__den - self.__num*other.__den,
                        self.__den*other.__den)
         if isnum(other):
             return other - float(self)
         return NotImplemented

     def __mul__(self, other):
         """Multiply two Rats, or a Rat and a number."""
         if isRat(other):
             return Rat(self.__num*other.__num, self.__den*other.__den)
         if isint(other):
             return Rat(self.__num*other, self.__den)
         if isnum(other):
             return float(self)*other
         return NotImplemented

     __rmul__ = __mul__

     def __truediv__(self, other):
         """Divide two Rats, or a Rat and a number."""
         if isRat(other):
             return Rat(self.__num*other.__den, self.__den*other.__num)
         if isint(other):
             return Rat(self.__num, self.__den*other)
         if isnum(other):
             return float(self) / other
         return NotImplemented

     __div__ = __truediv__

     def __rtruediv__(self, other):
         """Divide two Rats, or a Rat and a number (reversed args)."""
         if isRat(other):
             return Rat(other.__num*self.__den, other.__den*self.__num)
         if isint(other):
             return Rat(other*self.__den, self.__num)
         if isnum(other):
             return other / float(self)
         return NotImplemented

     __rdiv__ = __rtruediv__

     def __floordiv__(self, other):
         """Divide two Rats, returning the floored result."""
         if isint(other):
             other = Rat(other)
         elif not isRat(other):
             return NotImplemented
         x = self/other
         return x.__num // x.__den

     def __rfloordiv__(self, other):
         """Divide two Rats, returning the floored result (reversed args)."""
         x = other/self
         return x.__num // x.__den

     def __divmod__(self, other):
         """Divide two Rats, returning quotient and remainder."""
         if isint(other):
             other = Rat(other)
         elif not isRat(other):
             return NotImplemented
         x = self//other
         return (x, self - other * x)

     def __rdivmod__(self, other):
         """Divide two Rats, returning quotient and remainder (reversed args)."""
         if isint(other):
             other = Rat(other)
         elif not isRat(other):
             return NotImplemented
         return divmod(other, self)

     def __mod__(self, other):
         """Take one Rat modulo another."""
         return divmod(self, other)[1]

     def __rmod__(self, other):
         """Take one Rat modulo another (reversed args)."""
         return divmod(other, self)[1]

     def __eq__(self, other):
         """Compare two Rats for equality."""
         if isint(other):
             return self.__den == 1 and self.__num == other
         if isRat(other):
             return self.__num == other.__num and self.__den == other.__den
         if isnum(other):
             return float(self) == other
         return NotImplemented

     def __ne__(self, other):
         """Compare two Rats for inequality."""
         return not self == other

     # Silence Py3k warning
     __hash__ = None

 class RatTestCase(unittest.TestCase):
     """Unit tests for Rat class and its support utilities."""

     def test_gcd(self):
         self.assertEqual(gcd(10, 12), 2)
         self.assertEqual(gcd(10, 15), 5)
         self.assertEqual(gcd(10, 11), 1)
         self.assertEqual(gcd(100, 15), 5)
         self.assertEqual(gcd(-10, 2), -2)
         self.assertEqual(gcd(10, -2), 2)
         self.assertEqual(gcd(-10, -2), -2)
         for i in range(1, 20):
             for j in range(1, 20):
                 self.assertTrue(gcd(i, j) > 0)
                 self.assertTrue(gcd(-i, j) < 0)
                 self.assertTrue(gcd(i, -j) > 0)
                 self.assertTrue(gcd(-i, -j) < 0)

     def test_constructor(self):
         a = Rat(10, 15)
         self.assertEqual(a.num, 2)
         self.assertEqual(a.den, 3)
         a = Rat(10L, 15L)
         self.assertEqual(a.num, 2)
         self.assertEqual(a.den, 3)
         a = Rat(10, -15)
         self.assertEqual(a.num, -2)
         self.assertEqual(a.den, 3)
         a = Rat(-10, 15)
         self.assertEqual(a.num, -2)
         self.assertEqual(a.den, 3)
         a = Rat(-10, -15)
         self.assertEqual(a.num, 2)
         self.assertEqual(a.den, 3)
         a = Rat(7)
         self.assertEqual(a.num, 7)
         self.assertEqual(a.den, 1)
         try:
             a = Rat(1, 0)
         except ZeroDivisionError:
             pass
         else:
             self.fail("Rat(1, 0) didn't raise ZeroDivisionError")
         for bad in "0", 0.0, 0j, (), [], {}, None, Rat, unittest:
             try:
                 a = Rat(bad)
             except TypeError:
                 pass
             else:
                 self.fail("Rat(%r) didn't raise TypeError" % bad)
             try:
                 a = Rat(1, bad)
             except TypeError:
                 pass
             else:
                 self.fail("Rat(1, %r) didn't raise TypeError" % bad)

     def test_add(self):
         self.assertEqual(Rat(2, 3) + Rat(1, 3), 1)
         self.assertEqual(Rat(2, 3) + 1, Rat(5, 3))
         self.assertEqual(1 + Rat(2, 3), Rat(5, 3))
         self.assertEqual(1.0 + Rat(1, 2), 1.5)
         self.assertEqual(Rat(1, 2) + 1.0, 1.5)

     def test_sub(self):
         self.assertEqual(Rat(7, 2) - Rat(7, 5), Rat(21, 10))
         self.assertEqual(Rat(7, 5) - 1, Rat(2, 5))
         self.assertEqual(1 - Rat(3, 5), Rat(2, 5))
         self.assertEqual(Rat(3, 2) - 1.0, 0.5)
         self.assertEqual(1.0 - Rat(1, 2), 0.5)

     def test_mul(self):
         self.assertEqual(Rat(2, 3) * Rat(5, 7), Rat(10, 21))
         self.assertEqual(Rat(10, 3) * 3, 10)
         self.assertEqual(3 * Rat(10, 3), 10)
         self.assertEqual(Rat(10, 5) * 0.5, 1.0)
         self.assertEqual(0.5 * Rat(10, 5), 1.0)

     def test_div(self):
         self.assertEqual(Rat(10, 3) / Rat(5, 7), Rat(14, 3))
         self.assertEqual(Rat(10, 3) / 3, Rat(10, 9))
         self.assertEqual(2 / Rat(5), Rat(2, 5))
         self.assertEqual(3.0 * Rat(1, 2), 1.5)
         self.assertEqual(Rat(1, 2) * 3.0, 1.5)

     def test_floordiv(self):
         self.assertEqual(Rat(10) // Rat(4), 2)
         self.assertEqual(Rat(10, 3) // Rat(4, 3), 2)
         self.assertEqual(Rat(10) // 4, 2)
         self.assertEqual(10 // Rat(4), 2)

     def test_eq(self):
         self.assertEqual(Rat(10), Rat(20, 2))
         self.assertEqual(Rat(10), 10)
         self.assertEqual(10, Rat(10))
         self.assertEqual(Rat(10), 10.0)
         self.assertEqual(10.0, Rat(10))

     def test_future_div(self):
         exec future_test

     # XXX Ran out of steam; TO DO: divmod, div, future division

 future_test = """
 from __future__ import division
 self.assertEqual(Rat(10, 3) / Rat(5, 7), Rat(14, 3))
 self.assertEqual(Rat(10, 3) / 3, Rat(10, 9))
 self.assertEqual(2 / Rat(5), Rat(2, 5))
 self.assertEqual(3.0 * Rat(1, 2), 1.5)
 self.assertEqual(Rat(1, 2) * 3.0, 1.5)
 self.assertEqual(eval('1/2'), 0.5)
 """

 def test_main():
     test_support.run_unittest(RatTestCase)


 if __name__ == "__main__":
     test_main()
	"""Tests for binary operators on subtypes of built-in types."""

	import unittest
	from test import test_support

	def gcd(a, b):
	"""Greatest common divisor using Euclid's algorithm."""
	while a:
	a, b = b%a, a
	return b

	def isint(x):
	"""Test whether an object is an instance of int or long."""
	return isinstance(x, int) or isinstance(x, long)

	def isnum(x):
	"""Test whether an object is an instance of a built-in numeric type."""
	for T in int, long, float, complex:
	if isinstance(x, T):
	return 1
	return 0

	def isRat(x):
	"""Test wheter an object is an instance of the Rat class."""
	return isinstance(x, Rat)

	class Rat(object):

	"""Rational number implemented as a normalized pair of longs."""

	__slots__ = ['_Rat__num', '_Rat__den']

	def __init__(self, num=0L, den=1L):
	"""Constructor: Rat([num[, den]]).

	The arguments must be ints or longs, and default to (0, 1)."""
	if not isint(num):
	raise TypeError, "Rat numerator must be int or long (%r)" % num
	if not isint(den):
	raise TypeError, "Rat denominator must be int or long (%r)" % den
	# But the zero is always on
	if den == 0:
	raise ZeroDivisionError, "zero denominator"
	g = gcd(den, num)
	self.__num = long(num//g)
	self.__den = long(den//g)

	def _get_num(self):
	"""Accessor function for read-only 'num' attribute of Rat."""
	return self.__num
	num = property(_get_num, None)

	def _get_den(self):
	"""Accessor function for read-only 'den' attribute of Rat."""
	return self.__den
	den = property(_get_den, None)

	def __repr__(self):
	"""Convert a Rat to an string resembling a Rat constructor call."""
	return "Rat(%d, %d)" % (self.__num, self.__den)

	def __str__(self):
	"""Convert a Rat to a string resembling a decimal numeric value."""
	return str(float(self))

	def __float__(self):
	"""Convert a Rat to a float."""
	return self.__num*1.0/self.__den

	def __int__(self):
	"""Convert a Rat to an int; self.den must be 1."""
	if self.__den == 1:
	try:
	return int(self.__num)
	except OverflowError:
	raise OverflowError, ("%s too large to convert to int" %
	repr(self))
	raise ValueError, "can't convert %s to int" % repr(self)

	def __long__(self):
	"""Convert a Rat to an long; self.den must be 1."""
	if self.__den == 1:
	return long(self.__num)
	raise ValueError, "can't convert %s to long" % repr(self)

	def __add__(self, other):
	"""Add two Rats, or a Rat and a number."""
	if isint(other):
	other = Rat(other)
	if isRat(other):
	return Rat(self.__numother.__den + other.__numself.__den,
	self.__den*other.__den)
	if isnum(other):
	return float(self) + other
	return NotImplemented

	__radd__ = __add__

	def __sub__(self, other):
	"""Subtract two Rats, or a Rat and a number."""
	if isint(other):
	other = Rat(other)
	if isRat(other):
	return Rat(self.__numother.__den - other.__numself.__den,
	self.__den*other.__den)
	if isnum(other):
	return float(self) - other
	return NotImplemented

	def __rsub__(self, other):
	"""Subtract two Rats, or a Rat and a number (reversed args)."""
	if isint(other):
	other = Rat(other)
	if isRat(other):
	return Rat(other.__numself.__den - self.__numother.__den,
	self.__den*other.__den)
	if isnum(other):
	return other - float(self)
	return NotImplemented

	def __mul__(self, other):
	"""Multiply two Rats, or a Rat and a number."""
	if isRat(other):
	return Rat(self.__numother.__num, self.__denother.__den)
	if isint(other):
	return Rat(self.__num*other, self.__den)
	if isnum(other):
	return float(self)*other
	return NotImplemented

	__rmul__ = __mul__

	def __truediv__(self, other):
	"""Divide two Rats, or a Rat and a number."""
	if isRat(other):
	return Rat(self.__numother.__den, self.__denother.__num)
	if isint(other):
	return Rat(self.__num, self.__den*other)
	if isnum(other):
	return float(self) / other
	return NotImplemented

	__div__ = __truediv__

	def __rtruediv__(self, other):
	"""Divide two Rats, or a Rat and a number (reversed args)."""
	if isRat(other):
	return Rat(other.__numself.__den, other.__denself.__num)
	if isint(other):
	return Rat(other*self.__den, self.__num)
	if isnum(other):
	return other / float(self)
	return NotImplemented

	__rdiv__ = __rtruediv__

	def __floordiv__(self, other):
	"""Divide two Rats, returning the floored result."""
	if isint(other):
	other = Rat(other)
	elif not isRat(other):
	return NotImplemented
	x = self/other
	return x.__num // x.__den

	def __rfloordiv__(self, other):
	"""Divide two Rats, returning the floored result (reversed args)."""
	x = other/self
	return x.__num // x.__den

	def __divmod__(self, other):
	"""Divide two Rats, returning quotient and remainder."""
	if isint(other):
	other = Rat(other)
	elif not isRat(other):
	return NotImplemented
	x = self//other
	return (x, self - other * x)

	def __rdivmod__(self, other):
	"""Divide two Rats, returning quotient and remainder (reversed args)."""
	if isint(other):
	other = Rat(other)
	elif not isRat(other):
	return NotImplemented
	return divmod(other, self)

	def __mod__(self, other):
	"""Take one Rat modulo another."""
	return divmod(self, other)[1]

	def __rmod__(self, other):
	"""Take one Rat modulo another (reversed args)."""
	return divmod(other, self)[1]

	def __eq__(self, other):
	"""Compare two Rats for equality."""
	if isint(other):
	return self.__den == 1 and self.__num == other
	if isRat(other):
	return self.__num == other.__num and self.__den == other.__den
	if isnum(other):
	return float(self) == other
	return NotImplemented

	def __ne__(self, other):
	"""Compare two Rats for inequality."""
	return not self == other

	# Silence Py3k warning
	__hash__ = None

	class RatTestCase(unittest.TestCase):
	"""Unit tests for Rat class and its support utilities."""

	def test_gcd(self):
	self.assertEqual(gcd(10, 12), 2)
	self.assertEqual(gcd(10, 15), 5)
	self.assertEqual(gcd(10, 11), 1)
	self.assertEqual(gcd(100, 15), 5)
	self.assertEqual(gcd(-10, 2), -2)
	self.assertEqual(gcd(10, -2), 2)
	self.assertEqual(gcd(-10, -2), -2)
	for i in range(1, 20):
	for j in range(1, 20):
	self.assertTrue(gcd(i, j) > 0)
	self.assertTrue(gcd(-i, j) < 0)
	self.assertTrue(gcd(i, -j) > 0)
	self.assertTrue(gcd(-i, -j) < 0)

	def test_constructor(self):
	a = Rat(10, 15)
	self.assertEqual(a.num, 2)
	self.assertEqual(a.den, 3)
	a = Rat(10L, 15L)
	self.assertEqual(a.num, 2)
	self.assertEqual(a.den, 3)
	a = Rat(10, -15)
	self.assertEqual(a.num, -2)
	self.assertEqual(a.den, 3)
	a = Rat(-10, 15)
	self.assertEqual(a.num, -2)
	self.assertEqual(a.den, 3)
	a = Rat(-10, -15)
	self.assertEqual(a.num, 2)
	self.assertEqual(a.den, 3)
	a = Rat(7)
	self.assertEqual(a.num, 7)
	self.assertEqual(a.den, 1)
	try:
	a = Rat(1, 0)
	except ZeroDivisionError:
	pass
	else:
	self.fail("Rat(1, 0) didn't raise ZeroDivisionError")
	for bad in "0", 0.0, 0j, (), [], {}, None, Rat, unittest:
	try:
	a = Rat(bad)
	except TypeError:
	pass
	else:
	self.fail("Rat(%r) didn't raise TypeError" % bad)
	try:
	a = Rat(1, bad)
	except TypeError:
	pass
	else:
	self.fail("Rat(1, %r) didn't raise TypeError" % bad)

	def test_add(self):
	self.assertEqual(Rat(2, 3) + Rat(1, 3), 1)
	self.assertEqual(Rat(2, 3) + 1, Rat(5, 3))
	self.assertEqual(1 + Rat(2, 3), Rat(5, 3))
	self.assertEqual(1.0 + Rat(1, 2), 1.5)
	self.assertEqual(Rat(1, 2) + 1.0, 1.5)

	def test_sub(self):
	self.assertEqual(Rat(7, 2) - Rat(7, 5), Rat(21, 10))
	self.assertEqual(Rat(7, 5) - 1, Rat(2, 5))
	self.assertEqual(1 - Rat(3, 5), Rat(2, 5))
	self.assertEqual(Rat(3, 2) - 1.0, 0.5)
	self.assertEqual(1.0 - Rat(1, 2), 0.5)

	def test_mul(self):
	self.assertEqual(Rat(2, 3) * Rat(5, 7), Rat(10, 21))
	self.assertEqual(Rat(10, 3) * 3, 10)
	self.assertEqual(3 * Rat(10, 3), 10)
	self.assertEqual(Rat(10, 5) * 0.5, 1.0)
	self.assertEqual(0.5 * Rat(10, 5), 1.0)

	def test_div(self):
	self.assertEqual(Rat(10, 3) / Rat(5, 7), Rat(14, 3))
	self.assertEqual(Rat(10, 3) / 3, Rat(10, 9))
	self.assertEqual(2 / Rat(5), Rat(2, 5))
	self.assertEqual(3.0 * Rat(1, 2), 1.5)
	self.assertEqual(Rat(1, 2) * 3.0, 1.5)

	def test_floordiv(self):
	self.assertEqual(Rat(10) // Rat(4), 2)
	self.assertEqual(Rat(10, 3) // Rat(4, 3), 2)
	self.assertEqual(Rat(10) // 4, 2)
	self.assertEqual(10 // Rat(4), 2)

	def test_eq(self):
	self.assertEqual(Rat(10), Rat(20, 2))
	self.assertEqual(Rat(10), 10)
	self.assertEqual(10, Rat(10))
	self.assertEqual(Rat(10), 10.0)
	self.assertEqual(10.0, Rat(10))

	def test_future_div(self):
	exec future_test

	# XXX Ran out of steam; TO DO: divmod, div, future division

	future_test = """
	from __future__ import division
	self.assertEqual(Rat(10, 3) / Rat(5, 7), Rat(14, 3))
	self.assertEqual(Rat(10, 3) / 3, Rat(10, 9))
	self.assertEqual(2 / Rat(5), Rat(2, 5))
	self.assertEqual(3.0 * Rat(1, 2), 1.5)
	self.assertEqual(Rat(1, 2) * 3.0, 1.5)
	self.assertEqual(eval('1/2'), 0.5)
	"""

	def test_main():
	test_support.run_unittest(RatTestCase)


	if __name__ == "__main__":
	test_main()