cpython/Lib/test/test_binop.py

"""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

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()
A test suite for binary operators, disguised as a rational number class. 2001-08-08 19:27:20 -03:00			`"""Tests for binary operators on subtypes of built-in types."""`

			`import unittest`
Get rid of relative imports in all unittests. Now anything that imports e.g. test_support must do so using an absolute package name such as "import test.test_support" or "from test import test_support". This also updates the README in Lib/test, and gets rid of the duplicate data dirctory in Lib/test/data (replaced by Lib/email/test/data). Now Tim and Jack can have at it. :) 2002-07-23 16:04:11 -03:00			`from test import test_support`
A test suite for binary operators, disguised as a rational number class. 2001-08-08 19:27:20 -03:00
			`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)`
The first batch of changes recommended by the fixdiv tool. These are mostly changes of / operators into //. Once or twice I did more or less than recommended. 2001-09-04 16:14:14 -03:00			`self.__num = long(num//g)`
			`self.__den = long(den//g)`
A test suite for binary operators, disguised as a rational number class. 2001-08-08 19:27:20 -03:00
			`def _get_num(self):`
			`"""Accessor function for read-only 'num' attribute of Rat."""`
			`return self.__num`
Rename 'getset' to 'property'. 2001-09-06 18:56:42 -03:00			`num = property(_get_num, None)`
A test suite for binary operators, disguised as a rational number class. 2001-08-08 19:27:20 -03:00
			`def _get_den(self):`
			`"""Accessor function for read-only 'den' attribute of Rat."""`
			`return self.__den`
Rename 'getset' to 'property'. 2001-09-06 18:56:42 -03:00			`den = property(_get_den, None)`
A test suite for binary operators, disguised as a rational number class. 2001-08-08 19:27:20 -03:00
			`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):`
Fix error in a docstring where a single quote started the docstring but triple quote ended it. Closes bug #1192777. Thanks Christopher Smith. 2005-04-30 02:50:19 -03:00			`"""Divide two Rats, returning quotient and remainder (reversed args)."""`
A test suite for binary operators, disguised as a rational number class. 2001-08-08 19:27:20 -03:00			`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`

			`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):`
convert usage of fail* to assert* 2009-06-30 19:57:08 -03:00			`self.assertTrue(gcd(i, j) > 0)`
			`self.assertTrue(gcd(-i, j) < 0)`
			`self.assertTrue(gcd(i, -j) > 0)`
			`self.assertTrue(gcd(-i, -j) < 0)`
A test suite for binary operators, disguised as a rational number class. 2001-08-08 19:27:20 -03:00
			`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)`
Fix for bug [#452230] future division isn't propagated. builtin_eval wasn't merging in the compiler flags from the current frame; I suppose we never noticed this before because future division is the first future-feature that can affect expressions (nested_scopes and generators had only statement-level effects). 2001-08-17 20:04:59 -03:00			`self.assertEqual(eval('1/2'), 0.5)`
A test suite for binary operators, disguised as a rational number class. 2001-08-08 19:27:20 -03:00			`"""`

Change the PyUnit-based tests to use the test_main() approach. This allows using the tests with unittest.py as a script. The tests will still run when run as a script themselves. 2001-09-20 18:33:42 -03:00			`def test_main():`
			`test_support.run_unittest(RatTestCase)`


			`if __name__ == "__main__":`
			`test_main()`