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cpython/Lib/test/test_fractions.py

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"""Tests for Lib/fractions.py."""
from decimal import Decimal
from test.support import requires_IEEE_754
import math
import numbers
import operator
import fractions
import functools
import os
import sys
import typing
import unittest
from copy import copy, deepcopy
import pickle
from pickle import dumps, loads
F = fractions.Fraction
#locate file with float format test values
test_dir = os.path.dirname(__file__) or os.curdir
format_testfile = os.path.join(test_dir, 'mathdata', 'formatfloat_testcases.txt')
class DummyFloat(object):
"""Dummy float class for testing comparisons with Fractions"""
def __init__(self, value):
if not isinstance(value, float):
raise TypeError("DummyFloat can only be initialized from float")
self.value = value
def _richcmp(self, other, op):
if isinstance(other, numbers.Rational):
return op(F.from_float(self.value), other)
elif isinstance(other, DummyFloat):
return op(self.value, other.value)
else:
return NotImplemented
def __eq__(self, other): return self._richcmp(other, operator.eq)
def __le__(self, other): return self._richcmp(other, operator.le)
def __lt__(self, other): return self._richcmp(other, operator.lt)
def __ge__(self, other): return self._richcmp(other, operator.ge)
def __gt__(self, other): return self._richcmp(other, operator.gt)
# shouldn't be calling __float__ at all when doing comparisons
def __float__(self):
assert False, "__float__ should not be invoked for comparisons"
# same goes for subtraction
def __sub__(self, other):
assert False, "__sub__ should not be invoked for comparisons"
__rsub__ = __sub__
class DummyRational(object):
"""Test comparison of Fraction with a naive rational implementation."""
def __init__(self, num, den):
g = math.gcd(num, den)
self.num = num // g
self.den = den // g
def __eq__(self, other):
if isinstance(other, fractions.Fraction):
return (self.num == other._numerator and
self.den == other._denominator)
else:
return NotImplemented
def __lt__(self, other):
return(self.num * other._denominator < self.den * other._numerator)
def __gt__(self, other):
return(self.num * other._denominator > self.den * other._numerator)
def __le__(self, other):
return(self.num * other._denominator <= self.den * other._numerator)
def __ge__(self, other):
return(self.num * other._denominator >= self.den * other._numerator)
# this class is for testing comparisons; conversion to float
# should never be used for a comparison, since it loses accuracy
def __float__(self):
assert False, "__float__ should not be invoked"
class DummyFraction(fractions.Fraction):
"""Dummy Fraction subclass for copy and deepcopy testing."""
def _components(r):
return (r.numerator, r.denominator)
def typed_approx_eq(a, b):
return type(a) == type(b) and (a == b or math.isclose(a, b))
class Symbolic:
"""Simple non-numeric class for testing mixed arithmetic.
It is not Integral, Rational, Real or Complex, and cannot be conveted
to int, float or complex. but it supports some arithmetic operations.
"""
def __init__(self, value):
self.value = value
def __mul__(self, other):
if isinstance(other, F):
return NotImplemented
return self.__class__(f'{self} * {other}')
def __rmul__(self, other):
return self.__class__(f'{other} * {self}')
def __truediv__(self, other):
if isinstance(other, F):
return NotImplemented
return self.__class__(f'{self} / {other}')
def __rtruediv__(self, other):
return self.__class__(f'{other} / {self}')
def __mod__(self, other):
if isinstance(other, F):
return NotImplemented
return self.__class__(f'{self} % {other}')
def __rmod__(self, other):
return self.__class__(f'{other} % {self}')
def __pow__(self, other):
if isinstance(other, F):
return NotImplemented
return self.__class__(f'{self} ** {other}')
def __rpow__(self, other):
return self.__class__(f'{other} ** {self}')
def __eq__(self, other):
if other.__class__ != self.__class__:
return NotImplemented
return self.value == other.value
def __str__(self):
return f'{self.value}'
def __repr__(self):
return f'{self.__class__.__name__}({self.value!r})'
class SymbolicReal(Symbolic):
pass
numbers.Real.register(SymbolicReal)
class SymbolicComplex(Symbolic):
pass
numbers.Complex.register(SymbolicComplex)
class Rat:
"""Simple Rational class for testing mixed arithmetic."""
def __init__(self, n, d):
self.numerator = n
self.denominator = d
def __mul__(self, other):
if isinstance(other, F):
return NotImplemented
return self.__class__(self.numerator * other.numerator,
self.denominator * other.denominator)
def __rmul__(self, other):
return self.__class__(other.numerator * self.numerator,
other.denominator * self.denominator)
def __truediv__(self, other):
if isinstance(other, F):
return NotImplemented
return self.__class__(self.numerator * other.denominator,
self.denominator * other.numerator)
def __rtruediv__(self, other):
return self.__class__(other.numerator * self.denominator,
other.denominator * self.numerator)
def __mod__(self, other):
if isinstance(other, F):
return NotImplemented
d = self.denominator * other.numerator
return self.__class__(self.numerator * other.denominator % d, d)
def __rmod__(self, other):
d = other.denominator * self.numerator
return self.__class__(other.numerator * self.denominator % d, d)
return self.__class__(other.numerator / self.numerator,
other.denominator / self.denominator)
def __pow__(self, other):
if isinstance(other, F):
return NotImplemented
return self.__class__(self.numerator ** other,
self.denominator ** other)
def __float__(self):
return self.numerator / self.denominator
def __eq__(self, other):
if self.__class__ != other.__class__:
return NotImplemented
return (typed_approx_eq(self.numerator, other.numerator) and
typed_approx_eq(self.denominator, other.denominator))
def __repr__(self):
return f'{self.__class__.__name__}({self.numerator!r}, {self.denominator!r})'
numbers.Rational.register(Rat)
class Root:
"""Simple Real class for testing mixed arithmetic."""
def __init__(self, v, n=F(2)):
self.base = v
self.degree = n
def __mul__(self, other):
if isinstance(other, F):
return NotImplemented
return self.__class__(self.base * other**self.degree, self.degree)
def __rmul__(self, other):
return self.__class__(other**self.degree * self.base, self.degree)
def __truediv__(self, other):
if isinstance(other, F):
return NotImplemented
return self.__class__(self.base / other**self.degree, self.degree)
def __rtruediv__(self, other):
return self.__class__(other**self.degree / self.base, self.degree)
def __pow__(self, other):
if isinstance(other, F):
return NotImplemented
return self.__class__(self.base, self.degree / other)
def __float__(self):
return float(self.base) ** (1 / float(self.degree))
def __eq__(self, other):
if self.__class__ != other.__class__:
return NotImplemented
return typed_approx_eq(self.base, other.base) and typed_approx_eq(self.degree, other.degree)
def __repr__(self):
return f'{self.__class__.__name__}({self.base!r}, {self.degree!r})'
numbers.Real.register(Root)
class Polar:
"""Simple Complex class for testing mixed arithmetic."""
def __init__(self, r, phi):
self.r = r
self.phi = phi
def __mul__(self, other):
if isinstance(other, F):
return NotImplemented
return self.__class__(self.r * other, self.phi)
def __rmul__(self, other):
return self.__class__(other * self.r, self.phi)
def __truediv__(self, other):
if isinstance(other, F):
return NotImplemented
return self.__class__(self.r / other, self.phi)
def __rtruediv__(self, other):
return self.__class__(other / self.r, -self.phi)
def __pow__(self, other):
if isinstance(other, F):
return NotImplemented
return self.__class__(self.r ** other, self.phi * other)
def __eq__(self, other):
if self.__class__ != other.__class__:
return NotImplemented
return typed_approx_eq(self.r, other.r) and typed_approx_eq(self.phi, other.phi)
def __repr__(self):
return f'{self.__class__.__name__}({self.r!r}, {self.phi!r})'
numbers.Complex.register(Polar)
class Rect:
"""Other simple Complex class for testing mixed arithmetic."""
def __init__(self, x, y):
self.x = x
self.y = y
def __mul__(self, other):
if isinstance(other, F):
return NotImplemented
return self.__class__(self.x * other, self.y * other)
def __rmul__(self, other):
return self.__class__(other * self.x, other * self.y)
def __truediv__(self, other):
if isinstance(other, F):
return NotImplemented
return self.__class__(self.x / other, self.y / other)
def __rtruediv__(self, other):
r = self.x * self.x + self.y * self.y
return self.__class__(other * (self.x / r), other * (self.y / r))
def __rpow__(self, other):
return Polar(other ** self.x, math.log(other) * self.y)
def __complex__(self):
return complex(self.x, self.y)
def __eq__(self, other):
if self.__class__ != other.__class__:
return NotImplemented
return typed_approx_eq(self.x, other.x) and typed_approx_eq(self.y, other.y)
def __repr__(self):
return f'{self.__class__.__name__}({self.x!r}, {self.y!r})'
numbers.Complex.register(Rect)
class RectComplex(Rect, complex):
pass
class FractionTest(unittest.TestCase):
def assertTypedEquals(self, expected, actual):
"""Asserts that both the types and values are the same."""
self.assertEqual(type(expected), type(actual))
self.assertEqual(expected, actual)
def assertTypedTupleEquals(self, expected, actual):
"""Asserts that both the types and values in the tuples are the same."""
self.assertTupleEqual(expected, actual)
self.assertListEqual(list(map(type, expected)), list(map(type, actual)))
def assertRaisesMessage(self, exc_type, message,
callable, *args, **kwargs):
"""Asserts that callable(*args, **kwargs) raises exc_type(message)."""
try:
callable(*args, **kwargs)
except exc_type as e:
self.assertEqual(message, str(e))
else:
self.fail("%s not raised" % exc_type.__name__)
def testInit(self):
self.assertEqual((0, 1), _components(F()))
self.assertEqual((7, 1), _components(F(7)))
self.assertEqual((7, 3), _components(F(F(7, 3))))
self.assertEqual((-1, 1), _components(F(-1, 1)))
self.assertEqual((-1, 1), _components(F(1, -1)))
self.assertEqual((1, 1), _components(F(-2, -2)))
self.assertEqual((1, 2), _components(F(5, 10)))
self.assertEqual((7, 15), _components(F(7, 15)))
self.assertEqual((10**23, 1), _components(F(10**23)))
self.assertEqual((3, 77), _components(F(F(3, 7), 11)))
self.assertEqual((-9, 5), _components(F(2, F(-10, 9))))
self.assertEqual((2486, 2485), _components(F(F(22, 7), F(355, 113))))
self.assertRaisesMessage(ZeroDivisionError, "Fraction(12, 0)",
F, 12, 0)
self.assertRaises(TypeError, F, 1.5 + 3j)
self.assertRaises(TypeError, F, "3/2", 3)
self.assertRaises(TypeError, F, 3, 0j)
self.assertRaises(TypeError, F, 3, 1j)
self.assertRaises(TypeError, F, 1, 2, 3)
@requires_IEEE_754
def testInitFromFloat(self):
self.assertEqual((5, 2), _components(F(2.5)))
self.assertEqual((0, 1), _components(F(-0.0)))
self.assertEqual((3602879701896397, 36028797018963968),
_components(F(0.1)))
# bug 16469: error types should be consistent with float -> int
self.assertRaises(ValueError, F, float('nan'))
self.assertRaises(OverflowError, F, float('inf'))
self.assertRaises(OverflowError, F, float('-inf'))
def testInitFromDecimal(self):
self.assertEqual((11, 10),
_components(F(Decimal('1.1'))))
self.assertEqual((7, 200),
_components(F(Decimal('3.5e-2'))))
self.assertEqual((0, 1),
_components(F(Decimal('.000e20'))))
# bug 16469: error types should be consistent with decimal -> int
self.assertRaises(ValueError, F, Decimal('nan'))
self.assertRaises(ValueError, F, Decimal('snan'))
self.assertRaises(OverflowError, F, Decimal('inf'))
self.assertRaises(OverflowError, F, Decimal('-inf'))
def testInitFromIntegerRatio(self):
class Ratio:
def __init__(self, ratio):
self._ratio = ratio
def as_integer_ratio(self):
return self._ratio
self.assertEqual((7, 3), _components(F(Ratio((7, 3)))))
errmsg = "argument should be a string or a number"
# the type also has an "as_integer_ratio" attribute.
self.assertRaisesRegex(TypeError, errmsg, F, Ratio)
# bad ratio
self.assertRaises(TypeError, F, Ratio(7))
self.assertRaises(ValueError, F, Ratio((7,)))
self.assertRaises(ValueError, F, Ratio((7, 3, 1)))
# only single-argument form
self.assertRaises(TypeError, F, Ratio((3, 7)), 11)
self.assertRaises(TypeError, F, 2, Ratio((-10, 9)))
# as_integer_ratio not defined in a class
class A:
pass
a = A()
a.as_integer_ratio = lambda: (9, 5)
self.assertEqual((9, 5), _components(F(a)))
# as_integer_ratio defined in a metaclass
class M(type):
def as_integer_ratio(self):
return (11, 9)
class B(metaclass=M):
pass
self.assertRaisesRegex(TypeError, errmsg, F, B)
self.assertRaisesRegex(TypeError, errmsg, F, B())
def testFromString(self):
self.assertEqual((5, 1), _components(F("5")))
self.assertEqual((3, 2), _components(F("3/2")))
self.assertEqual((3, 2), _components(F("3 / 2")))
self.assertEqual((3, 2), _components(F(" \n +3/2")))
self.assertEqual((-3, 2), _components(F("-3/2 ")))
self.assertEqual((13, 2), _components(F(" 013/02 \n ")))
self.assertEqual((16, 5), _components(F(" 3.2 ")))
self.assertEqual((-16, 5), _components(F(" -3.2 ")))
self.assertEqual((-3, 1), _components(F(" -3. ")))
self.assertEqual((3, 5), _components(F(" .6 ")))
self.assertEqual((1, 3125), _components(F("32.e-5")))
self.assertEqual((1000000, 1), _components(F("1E+06")))
self.assertEqual((-12300, 1), _components(F("-1.23e4")))
self.assertEqual((0, 1), _components(F(" .0e+0\t")))
self.assertEqual((0, 1), _components(F("-0.000e0")))
self.assertEqual((123, 1), _components(F("1_2_3")))
self.assertEqual((41, 107), _components(F("1_2_3/3_2_1")))
self.assertEqual((6283, 2000), _components(F("3.14_15")))
self.assertEqual((6283, 2*10**13), _components(F("3.14_15e-1_0")))
self.assertEqual((101, 100), _components(F("1.01")))
self.assertEqual((101, 100), _components(F("1.0_1")))
self.assertRaisesMessage(
ZeroDivisionError, "Fraction(3, 0)",
F, "3/0")
self.assertRaisesMessage(
ValueError, "Invalid literal for Fraction: '3/'",
F, "3/")
self.assertRaisesMessage(
ValueError, "Invalid literal for Fraction: '/2'",
F, "/2")
self.assertRaisesMessage(
# Denominators don't need a sign.
ValueError, "Invalid literal for Fraction: '3/+2'",
F, "3/+2")
self.assertRaisesMessage(
# Imitate float's parsing.
ValueError, "Invalid literal for Fraction: '+ 3/2'",
F, "+ 3/2")
self.assertRaisesMessage(
# Avoid treating '.' as a regex special character.
ValueError, "Invalid literal for Fraction: '3a2'",
F, "3a2")
self.assertRaisesMessage(
# Don't accept combinations of decimals and rationals.
ValueError, "Invalid literal for Fraction: '3/7.2'",
F, "3/7.2")
self.assertRaisesMessage(
# Don't accept combinations of decimals and rationals.
ValueError, "Invalid literal for Fraction: '3.2/7'",
F, "3.2/7")
self.assertRaisesMessage(
# Allow 3. and .3, but not .
ValueError, "Invalid literal for Fraction: '.'",
F, ".")
self.assertRaisesMessage(
ValueError, "Invalid literal for Fraction: '_'",
F, "_")
self.assertRaisesMessage(
ValueError, "Invalid literal for Fraction: '_1'",
F, "_1")
self.assertRaisesMessage(
ValueError, "Invalid literal for Fraction: '1__2'",
F, "1__2")
self.assertRaisesMessage(
ValueError, "Invalid literal for Fraction: '/_'",
F, "/_")
self.assertRaisesMessage(
ValueError, "Invalid literal for Fraction: '1_/'",
F, "1_/")
self.assertRaisesMessage(
ValueError, "Invalid literal for Fraction: '_1/'",
F, "_1/")
self.assertRaisesMessage(
ValueError, "Invalid literal for Fraction: '1__2/'",
F, "1__2/")
self.assertRaisesMessage(
ValueError, "Invalid literal for Fraction: '1/_'",
F, "1/_")
self.assertRaisesMessage(
ValueError, "Invalid literal for Fraction: '1/_1'",
F, "1/_1")
self.assertRaisesMessage(
ValueError, "Invalid literal for Fraction: '1/1__2'",
F, "1/1__2")
self.assertRaisesMessage(
ValueError, "Invalid literal for Fraction: '1._111'",
F, "1._111")
self.assertRaisesMessage(
ValueError, "Invalid literal for Fraction: '1.1__1'",
F, "1.1__1")
self.assertRaisesMessage(
ValueError, "Invalid literal for Fraction: '1.1e+_1'",
F, "1.1e+_1")
self.assertRaisesMessage(
ValueError, "Invalid literal for Fraction: '1.1e+1__1'",
F, "1.1e+1__1")
self.assertRaisesMessage(
ValueError, "Invalid literal for Fraction: '123.dd'",
F, "123.dd")
self.assertRaisesMessage(
ValueError, "Invalid literal for Fraction: '123.5_dd'",
F, "123.5_dd")
self.assertRaisesMessage(
ValueError, "Invalid literal for Fraction: 'dd.5'",
F, "dd.5")
self.assertRaisesMessage(
ValueError, "Invalid literal for Fraction: '7_dd'",
F, "7_dd")
self.assertRaisesMessage(
ValueError, "Invalid literal for Fraction: '1/dd'",
F, "1/dd")
self.assertRaisesMessage(
ValueError, "Invalid literal for Fraction: '1/123_dd'",
F, "1/123_dd")
self.assertRaisesMessage(
ValueError, "Invalid literal for Fraction: '789edd'",
F, "789edd")
self.assertRaisesMessage(
ValueError, "Invalid literal for Fraction: '789e2_dd'",
F, "789e2_dd")
# Test catastrophic backtracking.
val = "9"*50 + "_"
self.assertRaisesMessage(
ValueError, "Invalid literal for Fraction: '" + val + "'",
F, val)
self.assertRaisesMessage(
ValueError, "Invalid literal for Fraction: '1/" + val + "'",
F, "1/" + val)
self.assertRaisesMessage(
ValueError, "Invalid literal for Fraction: '1." + val + "'",
F, "1." + val)
self.assertRaisesMessage(
ValueError, "Invalid literal for Fraction: '1.1+e" + val + "'",
F, "1.1+e" + val)
def testImmutable(self):
r = F(7, 3)
r.__init__(2, 15)
self.assertEqual((7, 3), _components(r))
self.assertRaises(AttributeError, setattr, r, 'numerator', 12)
self.assertRaises(AttributeError, setattr, r, 'denominator', 6)
self.assertEqual((7, 3), _components(r))
# But if you _really_ need to:
r._numerator = 4
r._denominator = 2
self.assertEqual((4, 2), _components(r))
# Which breaks some important operations:
self.assertNotEqual(F(4, 2), r)
def testFromFloat(self):
self.assertRaises(TypeError, F.from_float, 3+4j)
self.assertEqual((10, 1), _components(F.from_float(10)))
bigint = 1234567890123456789
self.assertEqual((bigint, 1), _components(F.from_float(bigint)))
self.assertEqual((0, 1), _components(F.from_float(-0.0)))
self.assertEqual((10, 1), _components(F.from_float(10.0)))
self.assertEqual((-5, 2), _components(F.from_float(-2.5)))
self.assertEqual((99999999999999991611392, 1),
_components(F.from_float(1e23)))
self.assertEqual(float(10**23), float(F.from_float(1e23)))
self.assertEqual((3602879701896397, 1125899906842624),
_components(F.from_float(3.2)))
self.assertEqual(3.2, float(F.from_float(3.2)))
inf = 1e1000
nan = inf - inf
# bug 16469: error types should be consistent with float -> int
self.assertRaisesMessage(
OverflowError, "cannot convert Infinity to integer ratio",
F.from_float, inf)
self.assertRaisesMessage(
OverflowError, "cannot convert Infinity to integer ratio",
F.from_float, -inf)
self.assertRaisesMessage(
ValueError, "cannot convert NaN to integer ratio",
F.from_float, nan)
def testFromDecimal(self):
self.assertRaises(TypeError, F.from_decimal, 3+4j)
self.assertEqual(F(10, 1), F.from_decimal(10))
self.assertEqual(F(0), F.from_decimal(Decimal("-0")))
self.assertEqual(F(5, 10), F.from_decimal(Decimal("0.5")))
self.assertEqual(F(5, 1000), F.from_decimal(Decimal("5e-3")))
self.assertEqual(F(5000), F.from_decimal(Decimal("5e3")))
self.assertEqual(1 - F(1, 10**30),
F.from_decimal(Decimal("0." + "9" * 30)))
# bug 16469: error types should be consistent with decimal -> int
self.assertRaisesMessage(
OverflowError, "cannot convert Infinity to integer ratio",
F.from_decimal, Decimal("inf"))
self.assertRaisesMessage(
OverflowError, "cannot convert Infinity to integer ratio",
F.from_decimal, Decimal("-inf"))
self.assertRaisesMessage(
ValueError, "cannot convert NaN to integer ratio",
F.from_decimal, Decimal("nan"))
self.assertRaisesMessage(
ValueError, "cannot convert NaN to integer ratio",
F.from_decimal, Decimal("snan"))
def test_is_integer(self):
self.assertTrue(F(1, 1).is_integer())
self.assertTrue(F(-1, 1).is_integer())
self.assertTrue(F(1, -1).is_integer())
self.assertTrue(F(2, 2).is_integer())
self.assertTrue(F(-2, 2).is_integer())
self.assertTrue(F(2, -2).is_integer())
self.assertFalse(F(1, 2).is_integer())
self.assertFalse(F(-1, 2).is_integer())
self.assertFalse(F(1, -2).is_integer())
self.assertFalse(F(-1, -2).is_integer())
def test_as_integer_ratio(self):
self.assertEqual(F(4, 6).as_integer_ratio(), (2, 3))
self.assertEqual(F(-4, 6).as_integer_ratio(), (-2, 3))
self.assertEqual(F(4, -6).as_integer_ratio(), (-2, 3))
self.assertEqual(F(0, 6).as_integer_ratio(), (0, 1))
def testLimitDenominator(self):
rpi = F('3.1415926535897932')
self.assertEqual(rpi.limit_denominator(10000), F(355, 113))
self.assertEqual(-rpi.limit_denominator(10000), F(-355, 113))
self.assertEqual(rpi.limit_denominator(113), F(355, 113))
self.assertEqual(rpi.limit_denominator(112), F(333, 106))
self.assertEqual(F(201, 200).limit_denominator(100), F(1))
self.assertEqual(F(201, 200).limit_denominator(101), F(102, 101))
self.assertEqual(F(0).limit_denominator(10000), F(0))
for i in (0, -1):
self.assertRaisesMessage(
ValueError, "max_denominator should be at least 1",
F(1).limit_denominator, i)
def testConversions(self):
self.assertTypedEquals(-1, math.trunc(F(-11, 10)))
self.assertTypedEquals(1, math.trunc(F(11, 10)))
self.assertTypedEquals(-2, math.floor(F(-11, 10)))
self.assertTypedEquals(-1, math.ceil(F(-11, 10)))
self.assertTypedEquals(-1, math.ceil(F(-10, 10)))
self.assertTypedEquals(-1, int(F(-11, 10)))
self.assertTypedEquals(0, round(F(-1, 10)))
self.assertTypedEquals(0, round(F(-5, 10)))
self.assertTypedEquals(-2, round(F(-15, 10)))
self.assertTypedEquals(-1, round(F(-7, 10)))
self.assertEqual(False, bool(F(0, 1)))
self.assertEqual(True, bool(F(3, 2)))
self.assertTypedEquals(0.1, float(F(1, 10)))
# Check that __float__ isn't implemented by converting the
# numerator and denominator to float before dividing.
self.assertRaises(OverflowError, float, int('2'*400+'7'))
self.assertAlmostEqual(2.0/3,
float(F(int('2'*400+'7'), int('3'*400+'1'))))
self.assertTypedEquals(0.1+0j, complex(F(1,10)))
def testSupportsInt(self):
# See bpo-44547.
f = F(3, 2)
self.assertIsInstance(f, typing.SupportsInt)
self.assertEqual(int(f), 1)
self.assertEqual(type(int(f)), int)
def testIntGuaranteesIntReturn(self):
# Check that int(some_fraction) gives a result of exact type `int`
# even if the fraction is using some other Integral type for its
# numerator and denominator.
class CustomInt(int):
"""
Subclass of int with just enough machinery to convince the Fraction
constructor to produce something with CustomInt numerator and
denominator.
"""
@property
def numerator(self):
return self
@property
def denominator(self):
return CustomInt(1)
def __mul__(self, other):
return CustomInt(int(self) * int(other))
def __floordiv__(self, other):
return CustomInt(int(self) // int(other))
f = F(CustomInt(13), CustomInt(5))
self.assertIsInstance(f.numerator, CustomInt)
self.assertIsInstance(f.denominator, CustomInt)
self.assertIsInstance(f, typing.SupportsInt)
self.assertEqual(int(f), 2)
self.assertEqual(type(int(f)), int)
def testBoolGuarateesBoolReturn(self):
# Ensure that __bool__ is used on numerator which guarantees a bool
# return. See also bpo-39274.
@functools.total_ordering
class CustomValue:
denominator = 1
def __init__(self, value):
self.value = value
def __bool__(self):
return bool(self.value)
@property
def numerator(self):
# required to preserve `self` during instantiation
return self
def __eq__(self, other):
raise AssertionError("Avoid comparisons in Fraction.__bool__")
__lt__ = __eq__
# We did not implement all abstract methods, so register:
numbers.Rational.register(CustomValue)
numerator = CustomValue(1)
r = F(numerator)
# ensure the numerator was not lost during instantiation:
self.assertIs(r.numerator, numerator)
self.assertIs(bool(r), True)
numerator = CustomValue(0)
r = F(numerator)
self.assertIs(bool(r), False)
def testRound(self):
self.assertTypedEquals(F(-200), round(F(-150), -2))
self.assertTypedEquals(F(-200), round(F(-250), -2))
self.assertTypedEquals(F(30), round(F(26), -1))
self.assertTypedEquals(F(-2, 10), round(F(-15, 100), 1))
self.assertTypedEquals(F(-2, 10), round(F(-25, 100), 1))
def testArithmetic(self):
self.assertEqual(F(1, 2), F(1, 10) + F(2, 5))
self.assertEqual(F(-3, 10), F(1, 10) - F(2, 5))
self.assertEqual(F(1, 25), F(1, 10) * F(2, 5))
self.assertEqual(F(5, 6), F(2, 3) * F(5, 4))
self.assertEqual(F(1, 4), F(1, 10) / F(2, 5))
self.assertEqual(F(-15, 8), F(3, 4) / F(-2, 5))
self.assertRaises(ZeroDivisionError, operator.truediv, F(1), F(0))
self.assertTypedEquals(2, F(9, 10) // F(2, 5))
self.assertTypedEquals(10**23, F(10**23, 1) // F(1))
self.assertEqual(F(5, 6), F(7, 3) % F(3, 2))
self.assertEqual(F(2, 3), F(-7, 3) % F(3, 2))
self.assertEqual((F(1), F(5, 6)), divmod(F(7, 3), F(3, 2)))
self.assertEqual((F(-2), F(2, 3)), divmod(F(-7, 3), F(3, 2)))
self.assertEqual(F(8, 27), F(2, 3) ** F(3))
self.assertEqual(F(27, 8), F(2, 3) ** F(-3))
self.assertTypedEquals(2.0, F(4) ** F(1, 2))
self.assertEqual(F(1, 1), +F(1, 1))
z = pow(F(-1), F(1, 2))
self.assertAlmostEqual(z.real, 0)
self.assertEqual(z.imag, 1)
# Regression test for #27539.
p = F(-1, 2) ** 0
self.assertEqual(p, F(1, 1))
self.assertEqual(p.numerator, 1)
self.assertEqual(p.denominator, 1)
p = F(-1, 2) ** -1
self.assertEqual(p, F(-2, 1))
self.assertEqual(p.numerator, -2)
self.assertEqual(p.denominator, 1)
p = F(-1, 2) ** -2
self.assertEqual(p, F(4, 1))
self.assertEqual(p.numerator, 4)
self.assertEqual(p.denominator, 1)
def testLargeArithmetic(self):
self.assertTypedEquals(
F(10101010100808080808080808101010101010000000000000000,
1010101010101010101010101011111111101010101010101010101010101),
F(10**35+1, 10**27+1) % F(10**27+1, 10**35-1)
)
self.assertTypedEquals(
F(7, 1901475900342344102245054808064),
F(-2**100, 3) % F(5, 2**100)
)
self.assertTypedTupleEquals(
(9999999999999999,
F(10101010100808080808080808101010101010000000000000000,
1010101010101010101010101011111111101010101010101010101010101)),
divmod(F(10**35+1, 10**27+1), F(10**27+1, 10**35-1))
)
self.assertTypedEquals(
-2 ** 200 // 15,
F(-2**100, 3) // F(5, 2**100)
)
self.assertTypedEquals(
1,
F(5, 2**100) // F(3, 2**100)
)
self.assertTypedEquals(
(1, F(2, 2**100)),
divmod(F(5, 2**100), F(3, 2**100))
)
self.assertTypedTupleEquals(
(-2 ** 200 // 15,
F(7, 1901475900342344102245054808064)),
divmod(F(-2**100, 3), F(5, 2**100))
)
def testMixedArithmetic(self):
self.assertTypedEquals(F(11, 10), F(1, 10) + 1)
self.assertTypedEquals(1.1, F(1, 10) + 1.0)
self.assertTypedEquals(1.1 + 0j, F(1, 10) + (1.0 + 0j))
self.assertTypedEquals(F(11, 10), 1 + F(1, 10))
self.assertTypedEquals(1.1, 1.0 + F(1, 10))
self.assertTypedEquals(1.1 + 0j, (1.0 + 0j) + F(1, 10))
self.assertTypedEquals(F(-9, 10), F(1, 10) - 1)
self.assertTypedEquals(-0.9, F(1, 10) - 1.0)
self.assertTypedEquals(-0.9 + 0j, F(1, 10) - (1.0 + 0j))
self.assertTypedEquals(F(9, 10), 1 - F(1, 10))
self.assertTypedEquals(0.9, 1.0 - F(1, 10))
self.assertTypedEquals(0.9 + 0j, (1.0 + 0j) - F(1, 10))
def testMixedMultiplication(self):
self.assertTypedEquals(F(1, 10), F(1, 10) * 1)
self.assertTypedEquals(0.1, F(1, 10) * 1.0)
self.assertTypedEquals(0.1 + 0j, F(1, 10) * (1.0 + 0j))
self.assertTypedEquals(F(1, 10), 1 * F(1, 10))
self.assertTypedEquals(0.1, 1.0 * F(1, 10))
self.assertTypedEquals(0.1 + 0j, (1.0 + 0j) * F(1, 10))
self.assertTypedEquals(F(3, 2) * DummyFraction(5, 3), F(5, 2))
self.assertTypedEquals(DummyFraction(5, 3) * F(3, 2), F(5, 2))
self.assertTypedEquals(F(3, 2) * Rat(5, 3), Rat(15, 6))
self.assertTypedEquals(Rat(5, 3) * F(3, 2), F(5, 2))
self.assertTypedEquals(F(3, 2) * Root(4), Root(F(9, 1)))
self.assertTypedEquals(Root(4) * F(3, 2), 3.0)
self.assertEqual(F(3, 2) * SymbolicReal('X'), SymbolicReal('3/2 * X'))
self.assertRaises(TypeError, operator.mul, SymbolicReal('X'), F(3, 2))
self.assertTypedEquals(F(3, 2) * Polar(4, 2), Polar(F(6, 1), 2))
self.assertTypedEquals(F(3, 2) * Polar(4.0, 2), Polar(6.0, 2))
self.assertTypedEquals(F(3, 2) * Rect(4, 3), Rect(F(6, 1), F(9, 2)))
self.assertTypedEquals(F(3, 2) * RectComplex(4, 3), RectComplex(6.0, 4.5))
self.assertRaises(TypeError, operator.mul, Polar(4, 2), F(3, 2))
self.assertTypedEquals(Rect(4, 3) * F(3, 2), 6.0 + 4.5j)
self.assertEqual(F(3, 2) * SymbolicComplex('X'), SymbolicComplex('3/2 * X'))
self.assertRaises(TypeError, operator.mul, SymbolicComplex('X'), F(3, 2))
self.assertEqual(F(3, 2) * Symbolic('X'), Symbolic('3/2 * X'))
self.assertRaises(TypeError, operator.mul, Symbolic('X'), F(3, 2))
def testMixedDivision(self):
self.assertTypedEquals(F(1, 10), F(1, 10) / 1)
self.assertTypedEquals(0.1, F(1, 10) / 1.0)
self.assertTypedEquals(0.1 + 0j, F(1, 10) / (1.0 + 0j))
self.assertTypedEquals(F(10, 1), 1 / F(1, 10))
self.assertTypedEquals(10.0, 1.0 / F(1, 10))
self.assertTypedEquals(10.0 + 0j, (1.0 + 0j) / F(1, 10))
self.assertTypedEquals(F(3, 2) / DummyFraction(3, 5), F(5, 2))
self.assertTypedEquals(DummyFraction(5, 3) / F(2, 3), F(5, 2))
self.assertTypedEquals(F(3, 2) / Rat(3, 5), Rat(15, 6))
self.assertTypedEquals(Rat(5, 3) / F(2, 3), F(5, 2))
self.assertTypedEquals(F(2, 3) / Root(4), Root(F(1, 9)))
self.assertTypedEquals(Root(4) / F(2, 3), 3.0)
self.assertEqual(F(3, 2) / SymbolicReal('X'), SymbolicReal('3/2 / X'))
self.assertRaises(TypeError, operator.truediv, SymbolicReal('X'), F(3, 2))
self.assertTypedEquals(F(3, 2) / Polar(4, 2), Polar(F(3, 8), -2))
self.assertTypedEquals(F(3, 2) / Polar(4.0, 2), Polar(0.375, -2))
self.assertTypedEquals(F(3, 2) / Rect(4, 3), Rect(0.24, 0.18))
self.assertRaises(TypeError, operator.truediv, Polar(4, 2), F(2, 3))
self.assertTypedEquals(Rect(4, 3) / F(2, 3), 6.0 + 4.5j)
self.assertEqual(F(3, 2) / SymbolicComplex('X'), SymbolicComplex('3/2 / X'))
self.assertRaises(TypeError, operator.truediv, SymbolicComplex('X'), F(3, 2))
self.assertEqual(F(3, 2) / Symbolic('X'), Symbolic('3/2 / X'))
self.assertRaises(TypeError, operator.truediv, Symbolic('X'), F(2, 3))
def testMixedIntegerDivision(self):
self.assertTypedEquals(0, F(1, 10) // 1)
self.assertTypedEquals(0.0, F(1, 10) // 1.0)
self.assertTypedEquals(10, 1 // F(1, 10))
self.assertTypedEquals(10**23, 10**22 // F(1, 10))
self.assertTypedEquals(1.0 // 0.1, 1.0 // F(1, 10))
self.assertTypedEquals(F(1, 10), F(1, 10) % 1)
self.assertTypedEquals(0.1, F(1, 10) % 1.0)
self.assertTypedEquals(F(0, 1), 1 % F(1, 10))
self.assertTypedEquals(1.0 % 0.1, 1.0 % F(1, 10))
self.assertTypedEquals(0.1, F(1, 10) % float('inf'))
self.assertTypedEquals(float('-inf'), F(1, 10) % float('-inf'))
self.assertTypedEquals(float('inf'), F(-1, 10) % float('inf'))
self.assertTypedEquals(-0.1, F(-1, 10) % float('-inf'))
self.assertTypedTupleEquals((0, F(1, 10)), divmod(F(1, 10), 1))
self.assertTypedTupleEquals(divmod(0.1, 1.0), divmod(F(1, 10), 1.0))
self.assertTypedTupleEquals((10, F(0)), divmod(1, F(1, 10)))
self.assertTypedTupleEquals(divmod(1.0, 0.1), divmod(1.0, F(1, 10)))
self.assertTypedTupleEquals(divmod(0.1, float('inf')), divmod(F(1, 10), float('inf')))
self.assertTypedTupleEquals(divmod(0.1, float('-inf')), divmod(F(1, 10), float('-inf')))
self.assertTypedTupleEquals(divmod(-0.1, float('inf')), divmod(F(-1, 10), float('inf')))
self.assertTypedTupleEquals(divmod(-0.1, float('-inf')), divmod(F(-1, 10), float('-inf')))
self.assertTypedEquals(F(3, 2) % DummyFraction(3, 5), F(3, 10))
self.assertTypedEquals(DummyFraction(5, 3) % F(2, 3), F(1, 3))
self.assertTypedEquals(F(3, 2) % Rat(3, 5), Rat(3, 6))
self.assertTypedEquals(Rat(5, 3) % F(2, 3), F(1, 3))
self.assertRaises(TypeError, operator.mod, F(2, 3), Root(4))
self.assertTypedEquals(Root(4) % F(3, 2), 0.5)
self.assertEqual(F(3, 2) % SymbolicReal('X'), SymbolicReal('3/2 % X'))
self.assertRaises(TypeError, operator.mod, SymbolicReal('X'), F(3, 2))
self.assertRaises(TypeError, operator.mod, F(3, 2), Polar(4, 2))
self.assertRaises(TypeError, operator.mod, F(3, 2), RectComplex(4, 3))
self.assertRaises(TypeError, operator.mod, Rect(4, 3), F(2, 3))
self.assertEqual(F(3, 2) % SymbolicComplex('X'), SymbolicComplex('3/2 % X'))
self.assertRaises(TypeError, operator.mod, SymbolicComplex('X'), F(3, 2))
self.assertEqual(F(3, 2) % Symbolic('X'), Symbolic('3/2 % X'))
self.assertRaises(TypeError, operator.mod, Symbolic('X'), F(2, 3))
def testMixedPower(self):
# ** has more interesting conversion rules.
self.assertTypedEquals(F(100, 1), F(1, 10) ** -2)
self.assertTypedEquals(F(100, 1), F(10, 1) ** 2)
self.assertTypedEquals(0.1, F(1, 10) ** 1.0)
self.assertTypedEquals(0.1 + 0j, F(1, 10) ** (1.0 + 0j))
self.assertTypedEquals(4 , 2 ** F(2, 1))
z = pow(-1, F(1, 2))
self.assertAlmostEqual(0, z.real)
self.assertEqual(1, z.imag)
self.assertTypedEquals(F(1, 4) , 2 ** F(-2, 1))
self.assertTypedEquals(2.0 , 4 ** F(1, 2))
self.assertTypedEquals(0.25, 2.0 ** F(-2, 1))
self.assertTypedEquals(1.0 + 0j, (1.0 + 0j) ** F(1, 10))
self.assertRaises(ZeroDivisionError, operator.pow,
F(0, 1), -2)
self.assertTypedEquals(F(3, 2) ** Rat(3, 1), F(27, 8))
self.assertTypedEquals(F(3, 2) ** Rat(-3, 1), F(8, 27))
self.assertTypedEquals(F(-3, 2) ** Rat(-3, 1), F(-8, 27))
self.assertTypedEquals(F(9, 4) ** Rat(3, 2), 3.375)
self.assertIsInstance(F(4, 9) ** Rat(-3, 2), float)
self.assertAlmostEqual(F(4, 9) ** Rat(-3, 2), 3.375)
self.assertAlmostEqual(F(-4, 9) ** Rat(-3, 2), 3.375j)
self.assertTypedEquals(Rat(9, 4) ** F(3, 2), 3.375)
self.assertTypedEquals(Rat(3, 2) ** F(3, 1), Rat(27, 8))
self.assertTypedEquals(Rat(3, 2) ** F(-3, 1), F(8, 27))
self.assertIsInstance(Rat(4, 9) ** F(-3, 2), float)
self.assertAlmostEqual(Rat(4, 9) ** F(-3, 2), 3.375)
self.assertTypedEquals(Root(4) ** F(2, 3), Root(4, 3.0))
self.assertTypedEquals(Root(4) ** F(2, 1), Root(4, F(1)))
self.assertTypedEquals(Root(4) ** F(-2, 1), Root(4, -F(1)))
self.assertTypedEquals(Root(4) ** F(-2, 3), Root(4, -3.0))
self.assertEqual(F(3, 2) ** SymbolicReal('X'), SymbolicReal('3/2 ** X'))
self.assertEqual(SymbolicReal('X') ** F(3, 2), SymbolicReal('X ** 1.5'))
self.assertTypedEquals(F(3, 2) ** Rect(2, 0), Polar(F(9,4), 0.0))
self.assertTypedEquals(F(1, 1) ** Rect(2, 3), Polar(F(1), 0.0))
self.assertTypedEquals(F(3, 2) ** RectComplex(2, 0), Polar(2.25, 0.0))
self.assertTypedEquals(F(1, 1) ** RectComplex(2, 3), Polar(1.0, 0.0))
self.assertTypedEquals(Polar(4, 2) ** F(3, 2), Polar(8.0, 3.0))
self.assertTypedEquals(Polar(4, 2) ** F(3, 1), Polar(64, 6))
self.assertTypedEquals(Polar(4, 2) ** F(-3, 1), Polar(0.015625, -6))
self.assertTypedEquals(Polar(4, 2) ** F(-3, 2), Polar(0.125, -3.0))
self.assertEqual(F(3, 2) ** SymbolicComplex('X'), SymbolicComplex('3/2 ** X'))
self.assertEqual(SymbolicComplex('X') ** F(3, 2), SymbolicComplex('X ** 1.5'))
self.assertEqual(F(3, 2) ** Symbolic('X'), Symbolic('3/2 ** X'))
self.assertEqual(Symbolic('X') ** F(3, 2), Symbolic('X ** 1.5'))
def testMixingWithDecimal(self):
# Decimal refuses mixed arithmetic (but not mixed comparisons)
self.assertRaises(TypeError, operator.add,
F(3,11), Decimal('3.1415926'))
self.assertRaises(TypeError, operator.add,
Decimal('3.1415926'), F(3,11))
def testComparisons(self):
self.assertTrue(F(1, 2) < F(2, 3))
self.assertFalse(F(1, 2) < F(1, 2))
self.assertTrue(F(1, 2) <= F(2, 3))
self.assertTrue(F(1, 2) <= F(1, 2))
self.assertFalse(F(2, 3) <= F(1, 2))
self.assertTrue(F(1, 2) == F(1, 2))
self.assertFalse(F(1, 2) == F(1, 3))
self.assertFalse(F(1, 2) != F(1, 2))
self.assertTrue(F(1, 2) != F(1, 3))
def testComparisonsDummyRational(self):
self.assertTrue(F(1, 2) == DummyRational(1, 2))
self.assertTrue(DummyRational(1, 2) == F(1, 2))
self.assertFalse(F(1, 2) == DummyRational(3, 4))
self.assertFalse(DummyRational(3, 4) == F(1, 2))
self.assertTrue(F(1, 2) < DummyRational(3, 4))
self.assertFalse(F(1, 2) < DummyRational(1, 2))
self.assertFalse(F(1, 2) < DummyRational(1, 7))
self.assertFalse(F(1, 2) > DummyRational(3, 4))
self.assertFalse(F(1, 2) > DummyRational(1, 2))
self.assertTrue(F(1, 2) > DummyRational(1, 7))
self.assertTrue(F(1, 2) <= DummyRational(3, 4))
self.assertTrue(F(1, 2) <= DummyRational(1, 2))
self.assertFalse(F(1, 2) <= DummyRational(1, 7))
self.assertFalse(F(1, 2) >= DummyRational(3, 4))
self.assertTrue(F(1, 2) >= DummyRational(1, 2))
self.assertTrue(F(1, 2) >= DummyRational(1, 7))
self.assertTrue(DummyRational(1, 2) < F(3, 4))
self.assertFalse(DummyRational(1, 2) < F(1, 2))
self.assertFalse(DummyRational(1, 2) < F(1, 7))
self.assertFalse(DummyRational(1, 2) > F(3, 4))
self.assertFalse(DummyRational(1, 2) > F(1, 2))
self.assertTrue(DummyRational(1, 2) > F(1, 7))
self.assertTrue(DummyRational(1, 2) <= F(3, 4))
self.assertTrue(DummyRational(1, 2) <= F(1, 2))
self.assertFalse(DummyRational(1, 2) <= F(1, 7))
self.assertFalse(DummyRational(1, 2) >= F(3, 4))
self.assertTrue(DummyRational(1, 2) >= F(1, 2))
self.assertTrue(DummyRational(1, 2) >= F(1, 7))
def testComparisonsDummyFloat(self):
x = DummyFloat(1./3.)
y = F(1, 3)
self.assertTrue(x != y)
self.assertTrue(x < y or x > y)
self.assertFalse(x == y)
self.assertFalse(x <= y and x >= y)
self.assertTrue(y != x)
self.assertTrue(y < x or y > x)
self.assertFalse(y == x)
self.assertFalse(y <= x and y >= x)
def testMixedLess(self):
self.assertTrue(2 < F(5, 2))
self.assertFalse(2 < F(4, 2))
self.assertTrue(F(5, 2) < 3)
self.assertFalse(F(4, 2) < 2)
self.assertTrue(F(1, 2) < 0.6)
self.assertFalse(F(1, 2) < 0.4)
self.assertTrue(0.4 < F(1, 2))
self.assertFalse(0.5 < F(1, 2))
self.assertFalse(float('inf') < F(1, 2))
self.assertTrue(float('-inf') < F(0, 10))
self.assertFalse(float('nan') < F(-3, 7))
self.assertTrue(F(1, 2) < float('inf'))
self.assertFalse(F(17, 12) < float('-inf'))
self.assertFalse(F(144, -89) < float('nan'))
def testMixedLessEqual(self):
self.assertTrue(0.5 <= F(1, 2))
self.assertFalse(0.6 <= F(1, 2))
self.assertTrue(F(1, 2) <= 0.5)
self.assertFalse(F(1, 2) <= 0.4)
self.assertTrue(2 <= F(4, 2))
self.assertFalse(2 <= F(3, 2))
self.assertTrue(F(4, 2) <= 2)
self.assertFalse(F(5, 2) <= 2)
self.assertFalse(float('inf') <= F(1, 2))
self.assertTrue(float('-inf') <= F(0, 10))
self.assertFalse(float('nan') <= F(-3, 7))
self.assertTrue(F(1, 2) <= float('inf'))
self.assertFalse(F(17, 12) <= float('-inf'))
self.assertFalse(F(144, -89) <= float('nan'))
def testBigFloatComparisons(self):
# Because 10**23 can't be represented exactly as a float:
self.assertFalse(F(10**23) == float(10**23))
# The first test demonstrates why these are important.
self.assertFalse(1e23 < float(F(math.trunc(1e23) + 1)))
self.assertTrue(1e23 < F(math.trunc(1e23) + 1))
self.assertFalse(1e23 <= F(math.trunc(1e23) - 1))
self.assertTrue(1e23 > F(math.trunc(1e23) - 1))
self.assertFalse(1e23 >= F(math.trunc(1e23) + 1))
def testBigComplexComparisons(self):
self.assertFalse(F(10**23) == complex(10**23))
self.assertRaises(TypeError, operator.gt, F(10**23), complex(10**23))
self.assertRaises(TypeError, operator.le, F(10**23), complex(10**23))
x = F(3, 8)
z = complex(0.375, 0.0)
w = complex(0.375, 0.2)
self.assertTrue(x == z)
self.assertFalse(x != z)
self.assertFalse(x == w)
self.assertTrue(x != w)
for op in operator.lt, operator.le, operator.gt, operator.ge:
self.assertRaises(TypeError, op, x, z)
self.assertRaises(TypeError, op, z, x)
self.assertRaises(TypeError, op, x, w)
self.assertRaises(TypeError, op, w, x)
def testMixedEqual(self):
self.assertTrue(0.5 == F(1, 2))
self.assertFalse(0.6 == F(1, 2))
self.assertTrue(F(1, 2) == 0.5)
self.assertFalse(F(1, 2) == 0.4)
self.assertTrue(2 == F(4, 2))
self.assertFalse(2 == F(3, 2))
self.assertTrue(F(4, 2) == 2)
self.assertFalse(F(5, 2) == 2)
self.assertFalse(F(5, 2) == float('nan'))
self.assertFalse(float('nan') == F(3, 7))
self.assertFalse(F(5, 2) == float('inf'))
self.assertFalse(float('-inf') == F(2, 5))
def testStringification(self):
self.assertEqual("Fraction(7, 3)", repr(F(7, 3)))
self.assertEqual("Fraction(6283185307, 2000000000)",
repr(F('3.1415926535')))
self.assertEqual("Fraction(-1, 100000000000000000000)",
repr(F(1, -10**20)))
self.assertEqual("7/3", str(F(7, 3)))
self.assertEqual("7", str(F(7, 1)))
def testHash(self):
hmod = sys.hash_info.modulus
hinf = sys.hash_info.inf
self.assertEqual(hash(2.5), hash(F(5, 2)))
self.assertEqual(hash(10**50), hash(F(10**50)))
self.assertNotEqual(hash(float(10**23)), hash(F(10**23)))
self.assertEqual(hinf, hash(F(1, hmod)))
# Check that __hash__ produces the same value as hash(), for
# consistency with int and Decimal. (See issue #10356.)
self.assertEqual(hash(F(-1)), F(-1).__hash__())
def testApproximatePi(self):
# Algorithm borrowed from
# http://docs.python.org/lib/decimal-recipes.html
three = F(3)
lasts, t, s, n, na, d, da = 0, three, 3, 1, 0, 0, 24
while abs(s - lasts) > F(1, 10**9):
lasts = s
n, na = n+na, na+8
d, da = d+da, da+32
t = (t * n) / d
s += t
self.assertAlmostEqual(math.pi, s)
def testApproximateCos1(self):
# Algorithm borrowed from
# http://docs.python.org/lib/decimal-recipes.html
x = F(1)
i, lasts, s, fact, num, sign = 0, 0, F(1), 1, 1, 1
while abs(s - lasts) > F(1, 10**9):
lasts = s
i += 2
fact *= i * (i-1)
num *= x * x
sign *= -1
s += num / fact * sign
self.assertAlmostEqual(math.cos(1), s)
def test_copy_deepcopy_pickle(self):
r = F(13, 7)
dr = DummyFraction(13, 7)
for proto in range(0, pickle.HIGHEST_PROTOCOL + 1):
self.assertEqual(r, loads(dumps(r, proto)))
self.assertEqual(id(r), id(copy(r)))
self.assertEqual(id(r), id(deepcopy(r)))
self.assertNotEqual(id(dr), id(copy(dr)))
self.assertNotEqual(id(dr), id(deepcopy(dr)))
self.assertTypedEquals(dr, copy(dr))
self.assertTypedEquals(dr, deepcopy(dr))
def test_slots(self):
# Issue 4998
r = F(13, 7)
self.assertRaises(AttributeError, setattr, r, 'a', 10)
def test_int_subclass(self):
class myint(int):
def __mul__(self, other):
return type(self)(int(self) * int(other))
def __floordiv__(self, other):
return type(self)(int(self) // int(other))
def __mod__(self, other):
x = type(self)(int(self) % int(other))
return x
@property
def numerator(self):
return type(self)(int(self))
@property
def denominator(self):
return type(self)(1)
f = fractions.Fraction(myint(1 * 3), myint(2 * 3))
self.assertEqual(f.numerator, 1)
self.assertEqual(f.denominator, 2)
self.assertEqual(type(f.numerator), myint)
self.assertEqual(type(f.denominator), myint)
def test_format_no_presentation_type(self):
# Triples (fraction, specification, expected_result).
testcases = [
# Explicit sign handling
(F(2, 3), '+', '+2/3'),
(F(-2, 3), '+', '-2/3'),
(F(3), '+', '+3'),
(F(-3), '+', '-3'),
(F(2, 3), ' ', ' 2/3'),
(F(-2, 3), ' ', '-2/3'),
(F(3), ' ', ' 3'),
(F(-3), ' ', '-3'),
(F(2, 3), '-', '2/3'),
(F(-2, 3), '-', '-2/3'),
(F(3), '-', '3'),
(F(-3), '-', '-3'),
# Padding
(F(0), '5', ' 0'),
(F(2, 3), '5', ' 2/3'),
(F(-2, 3), '5', ' -2/3'),
(F(2, 3), '0', '2/3'),
(F(2, 3), '1', '2/3'),
(F(2, 3), '2', '2/3'),
# Alignment
(F(2, 3), '<5', '2/3 '),
(F(2, 3), '>5', ' 2/3'),
(F(2, 3), '^5', ' 2/3 '),
(F(2, 3), '=5', ' 2/3'),
(F(-2, 3), '<5', '-2/3 '),
(F(-2, 3), '>5', ' -2/3'),
(F(-2, 3), '^5', '-2/3 '),
(F(-2, 3), '=5', '- 2/3'),
# Fill
(F(2, 3), 'X>5', 'XX2/3'),
(F(-2, 3), '.<5', '-2/3.'),
(F(-2, 3), '\n^6', '\n-2/3\n'),
# Thousands separators
(F(1234, 5679), ',', '1,234/5,679'),
(F(-1234, 5679), '_', '-1_234/5_679'),
(F(1234567), '_', '1_234_567'),
(F(-1234567), ',', '-1,234,567'),
# Alternate form forces a slash in the output
(F(123), '#', '123/1'),
(F(-123), '#', '-123/1'),
(F(0), '#', '0/1'),
]
for fraction, spec, expected in testcases:
with self.subTest(fraction=fraction, spec=spec):
self.assertEqual(format(fraction, spec), expected)
def test_format_e_presentation_type(self):
# Triples (fraction, specification, expected_result)
testcases = [
(F(2, 3), '.6e', '6.666667e-01'),
(F(3, 2), '.6e', '1.500000e+00'),
(F(2, 13), '.6e', '1.538462e-01'),
(F(2, 23), '.6e', '8.695652e-02'),
(F(2, 33), '.6e', '6.060606e-02'),
(F(13, 2), '.6e', '6.500000e+00'),
(F(20, 2), '.6e', '1.000000e+01'),
(F(23, 2), '.6e', '1.150000e+01'),
(F(33, 2), '.6e', '1.650000e+01'),
(F(2, 3), '.6e', '6.666667e-01'),
(F(3, 2), '.6e', '1.500000e+00'),
# Zero
(F(0), '.3e', '0.000e+00'),
# Powers of 10, to exercise the log10 boundary logic
(F(1, 1000), '.3e', '1.000e-03'),
(F(1, 100), '.3e', '1.000e-02'),
(F(1, 10), '.3e', '1.000e-01'),
(F(1, 1), '.3e', '1.000e+00'),
(F(10), '.3e', '1.000e+01'),
(F(100), '.3e', '1.000e+02'),
(F(1000), '.3e', '1.000e+03'),
# Boundary where we round up to the next power of 10
(F('99.999994999999'), '.6e', '9.999999e+01'),
(F('99.999995'), '.6e', '1.000000e+02'),
(F('99.999995000001'), '.6e', '1.000000e+02'),
# Negatives
(F(-2, 3), '.6e', '-6.666667e-01'),
(F(-3, 2), '.6e', '-1.500000e+00'),
(F(-100), '.6e', '-1.000000e+02'),
# Large and small
(F('1e1000'), '.3e', '1.000e+1000'),
(F('1e-1000'), '.3e', '1.000e-1000'),
# Using 'E' instead of 'e' should give us a capital 'E'
(F(2, 3), '.6E', '6.666667E-01'),
# Tiny precision
(F(2, 3), '.1e', '6.7e-01'),
(F('0.995'), '.0e', '1e+00'),
# Default precision is 6
(F(22, 7), 'e', '3.142857e+00'),
# Alternate form forces a decimal point
(F('0.995'), '#.0e', '1.e+00'),
# Check that padding takes the exponent into account.
(F(22, 7), '11.6e', '3.142857e+00'),
(F(22, 7), '12.6e', '3.142857e+00'),
(F(22, 7), '13.6e', ' 3.142857e+00'),
# Thousands separators
(F('1234567.123456'), ',.5e', '1.23457e+06'),
(F('123.123456'), '012_.2e', '0_001.23e+02'),
# z flag is legal, but never makes a difference to the output
(F(-1, 7**100), 'z.6e', '-3.091690e-85'),
]
for fraction, spec, expected in testcases:
with self.subTest(fraction=fraction, spec=spec):
self.assertEqual(format(fraction, spec), expected)
def test_format_f_presentation_type(self):
# Triples (fraction, specification, expected_result)
testcases = [
# Simple .f formatting
(F(0, 1), '.2f', '0.00'),
(F(1, 3), '.2f', '0.33'),
(F(2, 3), '.2f', '0.67'),
(F(4, 3), '.2f', '1.33'),
(F(1, 8), '.2f', '0.12'),
(F(3, 8), '.2f', '0.38'),
(F(1, 13), '.2f', '0.08'),
(F(1, 199), '.2f', '0.01'),
(F(1, 200), '.2f', '0.00'),
(F(22, 7), '.5f', '3.14286'),
(F('399024789'), '.2f', '399024789.00'),
# Large precision (more than float can provide)
(F(104348, 33215), '.50f',
'3.14159265392142104470871594159265392142104470871594'),
# Precision defaults to 6 if not given
(F(22, 7), 'f', '3.142857'),
(F(0), 'f', '0.000000'),
(F(-22, 7), 'f', '-3.142857'),
# Round-ties-to-even checks
(F('1.225'), '.2f', '1.22'),
(F('1.2250000001'), '.2f', '1.23'),
(F('1.2349999999'), '.2f', '1.23'),
(F('1.235'), '.2f', '1.24'),
(F('1.245'), '.2f', '1.24'),
(F('1.2450000001'), '.2f', '1.25'),
(F('1.2549999999'), '.2f', '1.25'),
(F('1.255'), '.2f', '1.26'),
(F('-1.225'), '.2f', '-1.22'),
(F('-1.2250000001'), '.2f', '-1.23'),
(F('-1.2349999999'), '.2f', '-1.23'),
(F('-1.235'), '.2f', '-1.24'),
(F('-1.245'), '.2f', '-1.24'),
(F('-1.2450000001'), '.2f', '-1.25'),
(F('-1.2549999999'), '.2f', '-1.25'),
(F('-1.255'), '.2f', '-1.26'),
# Negatives and sign handling
(F(2, 3), '.2f', '0.67'),
(F(2, 3), '-.2f', '0.67'),
(F(2, 3), '+.2f', '+0.67'),
(F(2, 3), ' .2f', ' 0.67'),
(F(-2, 3), '.2f', '-0.67'),
(F(-2, 3), '-.2f', '-0.67'),
(F(-2, 3), '+.2f', '-0.67'),
(F(-2, 3), ' .2f', '-0.67'),
# Formatting to zero places
(F(1, 2), '.0f', '0'),
(F(-1, 2), '.0f', '-0'),
(F(22, 7), '.0f', '3'),
(F(-22, 7), '.0f', '-3'),
# Formatting to zero places, alternate form
(F(1, 2), '#.0f', '0.'),
(F(-1, 2), '#.0f', '-0.'),
(F(22, 7), '#.0f', '3.'),
(F(-22, 7), '#.0f', '-3.'),
# z flag for suppressing negative zeros
(F('-0.001'), 'z.2f', '0.00'),
(F('-0.001'), '-z.2f', '0.00'),
(F('-0.001'), '+z.2f', '+0.00'),
(F('-0.001'), ' z.2f', ' 0.00'),
(F('0.001'), 'z.2f', '0.00'),
(F('0.001'), '-z.2f', '0.00'),
(F('0.001'), '+z.2f', '+0.00'),
(F('0.001'), ' z.2f', ' 0.00'),
# Specifying a minimum width
(F(2, 3), '6.2f', ' 0.67'),
(F(12345), '6.2f', '12345.00'),
(F(12345), '12f', '12345.000000'),
# Fill and alignment
(F(2, 3), '>6.2f', ' 0.67'),
(F(2, 3), '<6.2f', '0.67 '),
(F(2, 3), '^3.2f', '0.67'),
(F(2, 3), '^4.2f', '0.67'),
(F(2, 3), '^5.2f', '0.67 '),
(F(2, 3), '^6.2f', ' 0.67 '),
(F(2, 3), '^7.2f', ' 0.67 '),
(F(2, 3), '^8.2f', ' 0.67 '),
# '=' alignment
(F(-2, 3), '=+8.2f', '- 0.67'),
(F(2, 3), '=+8.2f', '+ 0.67'),
# Fill character
(F(-2, 3), 'X>3.2f', '-0.67'),
(F(-2, 3), 'X>7.2f', 'XX-0.67'),
(F(-2, 3), 'X<7.2f', '-0.67XX'),
(F(-2, 3), 'X^7.2f', 'X-0.67X'),
(F(-2, 3), 'X=7.2f', '-XX0.67'),
(F(-2, 3), ' >7.2f', ' -0.67'),
# Corner cases: weird fill characters
(F(-2, 3), '\x00>7.2f', '\x00\x00-0.67'),
(F(-2, 3), '\n>7.2f', '\n\n-0.67'),
(F(-2, 3), '\t>7.2f', '\t\t-0.67'),
(F(-2, 3), '>>7.2f', '>>-0.67'),
(F(-2, 3), '<>7.2f', '<<-0.67'),
(F(-2, 3), '→>7.2f', '→→-0.67'),
# Zero-padding
(F(-2, 3), '07.2f', '-000.67'),
(F(-2, 3), '-07.2f', '-000.67'),
(F(2, 3), '+07.2f', '+000.67'),
(F(2, 3), ' 07.2f', ' 000.67'),
# An isolated zero is a minimum width, not a zero-pad flag.
# So unlike zero-padding, it's legal in combination with alignment.
(F(2, 3), '0.2f', '0.67'),
(F(2, 3), '>0.2f', '0.67'),
(F(2, 3), '<0.2f', '0.67'),
(F(2, 3), '^0.2f', '0.67'),
(F(2, 3), '=0.2f', '0.67'),
# Corner case: zero-padding _and_ a zero minimum width.
(F(2, 3), '00.2f', '0.67'),
# Thousands separator (only affects portion before the point)
(F(2, 3), ',.2f', '0.67'),
(F(2, 3), ',.7f', '0.6666667'),
(F('123456.789'), ',.2f', '123,456.79'),
(F('1234567'), ',.2f', '1,234,567.00'),
(F('12345678'), ',.2f', '12,345,678.00'),
(F('12345678'), ',f', '12,345,678.000000'),
# Underscore as thousands separator
(F(2, 3), '_.2f', '0.67'),
(F(2, 3), '_.7f', '0.6666667'),
(F('123456.789'), '_.2f', '123_456.79'),
(F('1234567'), '_.2f', '1_234_567.00'),
(F('12345678'), '_.2f', '12_345_678.00'),
# Thousands and zero-padding
(F('1234.5678'), '07,.2f', '1,234.57'),
(F('1234.5678'), '08,.2f', '1,234.57'),
(F('1234.5678'), '09,.2f', '01,234.57'),
(F('1234.5678'), '010,.2f', '001,234.57'),
(F('1234.5678'), '011,.2f', '0,001,234.57'),
(F('1234.5678'), '012,.2f', '0,001,234.57'),
(F('1234.5678'), '013,.2f', '00,001,234.57'),
(F('1234.5678'), '014,.2f', '000,001,234.57'),
(F('1234.5678'), '015,.2f', '0,000,001,234.57'),
(F('1234.5678'), '016,.2f', '0,000,001,234.57'),
(F('-1234.5678'), '07,.2f', '-1,234.57'),
(F('-1234.5678'), '08,.2f', '-1,234.57'),
(F('-1234.5678'), '09,.2f', '-1,234.57'),
(F('-1234.5678'), '010,.2f', '-01,234.57'),
(F('-1234.5678'), '011,.2f', '-001,234.57'),
(F('-1234.5678'), '012,.2f', '-0,001,234.57'),
(F('-1234.5678'), '013,.2f', '-0,001,234.57'),
(F('-1234.5678'), '014,.2f', '-00,001,234.57'),
(F('-1234.5678'), '015,.2f', '-000,001,234.57'),
(F('-1234.5678'), '016,.2f', '-0,000,001,234.57'),
# Corner case: no decimal point
(F('-1234.5678'), '06,.0f', '-1,235'),
(F('-1234.5678'), '07,.0f', '-01,235'),
(F('-1234.5678'), '08,.0f', '-001,235'),
(F('-1234.5678'), '09,.0f', '-0,001,235'),
# Corner-case - zero-padding specified through fill and align
# instead of the zero-pad character - in this case, treat '0' as a
# regular fill character and don't attempt to insert commas into
# the filled portion. This differs from the int and float
# behaviour.
(F('1234.5678'), '0=12,.2f', '00001,234.57'),
# Corner case where it's not clear whether the '0' indicates zero
# padding or gives the minimum width, but there's still an obvious
# answer to give. We want this to work in case the minimum width
# is being inserted programmatically: spec = f'{width}.2f'.
(F('12.34'), '0.2f', '12.34'),
(F('12.34'), 'X>0.2f', '12.34'),
# 'F' should work identically to 'f'
(F(22, 7), '.5F', '3.14286'),
# %-specifier
(F(22, 7), '.2%', '314.29%'),
(F(1, 7), '.2%', '14.29%'),
(F(1, 70), '.2%', '1.43%'),
(F(1, 700), '.2%', '0.14%'),
(F(1, 7000), '.2%', '0.01%'),
(F(1, 70000), '.2%', '0.00%'),
(F(1, 7), '.0%', '14%'),
(F(1, 7), '#.0%', '14.%'),
(F(100, 7), ',.2%', '1,428.57%'),
(F(22, 7), '7.2%', '314.29%'),
(F(22, 7), '8.2%', ' 314.29%'),
(F(22, 7), '08.2%', '0314.29%'),
# Test cases from #67790 and discuss.python.org Ideas thread.
(F(1, 3), '.2f', '0.33'),
(F(1, 8), '.2f', '0.12'),
(F(3, 8), '.2f', '0.38'),
(F(2545, 1000), '.2f', '2.54'),
(F(2549, 1000), '.2f', '2.55'),
(F(2635, 1000), '.2f', '2.64'),
(F(1, 100), '.1f', '0.0'),
(F(49, 1000), '.1f', '0.0'),
(F(51, 1000), '.1f', '0.1'),
(F(149, 1000), '.1f', '0.1'),
(F(151, 1000), '.1f', '0.2'),
]
for fraction, spec, expected in testcases:
with self.subTest(fraction=fraction, spec=spec):
self.assertEqual(format(fraction, spec), expected)
def test_format_g_presentation_type(self):
# Triples (fraction, specification, expected_result)
testcases = [
(F('0.000012345678'), '.6g', '1.23457e-05'),
(F('0.00012345678'), '.6g', '0.000123457'),
(F('0.0012345678'), '.6g', '0.00123457'),
(F('0.012345678'), '.6g', '0.0123457'),
(F('0.12345678'), '.6g', '0.123457'),
(F('1.2345678'), '.6g', '1.23457'),
(F('12.345678'), '.6g', '12.3457'),
(F('123.45678'), '.6g', '123.457'),
(F('1234.5678'), '.6g', '1234.57'),
(F('12345.678'), '.6g', '12345.7'),
(F('123456.78'), '.6g', '123457'),
(F('1234567.8'), '.6g', '1.23457e+06'),
# Rounding up cases
(F('9.99999e+2'), '.4g', '1000'),
(F('9.99999e-8'), '.4g', '1e-07'),
(F('9.99999e+8'), '.4g', '1e+09'),
# Check round-ties-to-even behaviour
(F('-0.115'), '.2g', '-0.12'),
(F('-0.125'), '.2g', '-0.12'),
(F('-0.135'), '.2g', '-0.14'),
(F('-0.145'), '.2g', '-0.14'),
(F('0.115'), '.2g', '0.12'),
(F('0.125'), '.2g', '0.12'),
(F('0.135'), '.2g', '0.14'),
(F('0.145'), '.2g', '0.14'),
# Trailing zeros and decimal point suppressed by default ...
(F(0), '.6g', '0'),
(F('123.400'), '.6g', '123.4'),
(F('123.000'), '.6g', '123'),
(F('120.000'), '.6g', '120'),
(F('12000000'), '.6g', '1.2e+07'),
# ... but not when alternate form is in effect
(F(0), '#.6g', '0.00000'),
(F('123.400'), '#.6g', '123.400'),
(F('123.000'), '#.6g', '123.000'),
(F('120.000'), '#.6g', '120.000'),
(F('12000000'), '#.6g', '1.20000e+07'),
# 'G' format (uses 'E' instead of 'e' for the exponent indicator)
(F('123.45678'), '.6G', '123.457'),
(F('1234567.8'), '.6G', '1.23457E+06'),
# Default precision is 6 significant figures
(F('3.1415926535'), 'g', '3.14159'),
# Precision 0 is treated the same as precision 1.
(F('0.000031415'), '.0g', '3e-05'),
(F('0.00031415'), '.0g', '0.0003'),
(F('0.31415'), '.0g', '0.3'),
(F('3.1415'), '.0g', '3'),
(F('3.1415'), '#.0g', '3.'),
(F('31.415'), '.0g', '3e+01'),
(F('31.415'), '#.0g', '3.e+01'),
(F('0.000031415'), '.1g', '3e-05'),
(F('0.00031415'), '.1g', '0.0003'),
(F('0.31415'), '.1g', '0.3'),
(F('3.1415'), '.1g', '3'),
(F('3.1415'), '#.1g', '3.'),
(F('31.415'), '.1g', '3e+01'),
# Thousands separator
(F(2**64), '_.25g', '18_446_744_073_709_551_616'),
# As with 'e' format, z flag is legal, but has no effect
(F(-1, 7**100), 'zg', '-3.09169e-85'),
]
for fraction, spec, expected in testcases:
with self.subTest(fraction=fraction, spec=spec):
self.assertEqual(format(fraction, spec), expected)
def test_invalid_formats(self):
fraction = F(2, 3)
with self.assertRaises(TypeError):
format(fraction, None)
invalid_specs = [
'Q6f', # regression test
# illegal to use fill or alignment when zero padding
'X>010f',
'X<010f',
'X^010f',
'X=010f',
'0>010f',
'0<010f',
'0^010f',
'0=010f',
'>010f',
'<010f',
'^010f',
'=010e',
'=010f',
'=010g',
'=010%',
'>00.2f',
'>00f',
# Too many zeros - minimum width should not have leading zeros
'006f',
# Leading zeros in precision
'.010f',
'.02f',
'.000f',
# Missing precision
'.e',
'.f',
'.g',
'.%',
# Z instead of z for negative zero suppression
'Z.2f'
# z flag not supported for general formatting
'z',
# zero padding not supported for general formatting
'05',
]
for spec in invalid_specs:
with self.subTest(spec=spec):
with self.assertRaises(ValueError):
format(fraction, spec)
@requires_IEEE_754
def test_float_format_testfile(self):
with open(format_testfile, encoding="utf-8") as testfile:
for line in testfile:
if line.startswith('--'):
continue
line = line.strip()
if not line:
continue
lhs, rhs = map(str.strip, line.split('->'))
fmt, arg = lhs.split()
if fmt == '%r':
continue
fmt2 = fmt[1:]
with self.subTest(fmt=fmt, arg=arg):
f = F(float(arg))
self.assertEqual(format(f, fmt2), rhs)
if f: # skip negative zero
self.assertEqual(format(-f, fmt2), '-' + rhs)
f = F(arg)
self.assertEqual(float(format(f, fmt2)), float(rhs))
self.assertEqual(float(format(-f, fmt2)), float('-' + rhs))
def test_complex_handling(self):
# See issue gh-102840 for more details.
a = F(1, 2)
b = 1j
message = "unsupported operand type(s) for %s: '%s' and '%s'"
# test forward
self.assertRaisesMessage(TypeError,
message % ("%", "Fraction", "complex"),
operator.mod, a, b)
self.assertRaisesMessage(TypeError,
message % ("//", "Fraction", "complex"),
operator.floordiv, a, b)
self.assertRaisesMessage(TypeError,
message % ("divmod()", "Fraction", "complex"),
divmod, a, b)
# test reverse
self.assertRaisesMessage(TypeError,
message % ("%", "complex", "Fraction"),
operator.mod, b, a)
self.assertRaisesMessage(TypeError,
message % ("//", "complex", "Fraction"),
operator.floordiv, b, a)
self.assertRaisesMessage(TypeError,
message % ("divmod()", "complex", "Fraction"),
divmod, b, a)
def test_three_argument_pow(self):
message = "unsupported operand type(s) for ** or pow(): '%s', '%s', '%s'"
self.assertRaisesMessage(TypeError,
message % ("Fraction", "int", "int"),
pow, F(3), 4, 5)
if __name__ == '__main__':
unittest.main()
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