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ruby--ruby/test/ruby/test_bignum.rb
nobu ed4c5f38ba * bignum.c (rb_big_pow): estimate result bit size more precisely.
[ruby-core:30735][Feature #3429]


git-svn-id: svn+ssh://ci.ruby-lang.org/ruby/trunk@35081 b2dd03c8-39d4-4d8f-98ff-823fe69b080e
2012-03-18 08:17:50 +00:00

508 lines
14 KiB
Ruby

require 'test/unit'
class TestBignum < Test::Unit::TestCase
def setup
@verbose = $VERBOSE
$VERBOSE = nil
@fmax = Float::MAX.to_i
@fmax2 = @fmax * 2
@big = (1 << 63) - 1
end
def teardown
$VERBOSE = @verbose
end
def fact(n)
return 1 if n == 0
f = 1
while n>0
f *= n
n -= 1
end
return f
end
def test_bignum
$x = fact(40)
assert_equal($x, $x)
assert_equal($x, fact(40))
assert_operator($x, :<, $x+2)
assert_operator($x, :>, $x-2)
assert_equal(815915283247897734345611269596115894272000000000, $x)
assert_not_equal(815915283247897734345611269596115894272000000001, $x)
assert_equal(815915283247897734345611269596115894272000000001, $x+1)
assert_equal(335367096786357081410764800000, $x/fact(20))
$x = -$x
assert_equal(-815915283247897734345611269596115894272000000000, $x)
assert_equal(2-(2**32), -(2**32-2))
assert_equal(2**32 - 5, (2**32-3)-2)
for i in 1000..1014
assert_equal(2 ** i, 1 << i)
end
n1 = 1 << 1000
for i in 1000..1014
assert_equal(n1, 1 << i)
n1 *= 2
end
n2=n1
for i in 1..10
n1 = n1 / 2
n2 = n2 >> 1
assert_equal(n1, n2)
end
for i in 4000..4096
n1 = 1 << i;
assert_equal(n1-1, (n1**2-1) / (n1+1))
end
end
def test_calc
b = 10**80
a = b * 9 + 7
assert_equal(7, a.modulo(b))
assert_equal(-b + 7, a.modulo(-b))
assert_equal(b + -7, (-a).modulo(b))
assert_equal(-7, (-a).modulo(-b))
assert_equal(7, a.remainder(b))
assert_equal(7, a.remainder(-b))
assert_equal(-7, (-a).remainder(b))
assert_equal(-7, (-a).remainder(-b))
assert_equal(10000000000000000000100000000000000000000, 10**40+10**20)
assert_equal(100000000000000000000, 10**40/10**20)
a = 677330545177305025495135714080
b = 14269972710765292560
assert_equal(0, a % b)
assert_equal(0, -a % b)
end
def shift_test(a)
b = a / (2 ** 32)
c = a >> 32
assert_equal(b, c)
b = a * (2 ** 32)
c = a << 32
assert_equal(b, c)
end
def test_shift
shift_test(-4518325415524767873)
shift_test(-0xfffffffffffffffff)
end
def test_to_s
assert_equal("fvvvvvvvvvvvv" ,18446744073709551615.to_s(32), "[ruby-core:10686]")
assert_equal("g000000000000" ,18446744073709551616.to_s(32), "[ruby-core:10686]")
assert_equal("3w5e11264sgsf" ,18446744073709551615.to_s(36), "[ruby-core:10686]")
assert_equal("3w5e11264sgsg" ,18446744073709551616.to_s(36), "[ruby-core:10686]")
assert_equal("nd075ib45k86f" ,18446744073709551615.to_s(31), "[ruby-core:10686]")
assert_equal("nd075ib45k86g" ,18446744073709551616.to_s(31), "[ruby-core:10686]")
assert_equal("1777777777777777777777" ,18446744073709551615.to_s(8))
assert_equal("-1777777777777777777777" ,-18446744073709551615.to_s(8))
end
b = 2**64
b *= b until Bignum === b
T_ZERO = b.coerce(0).first
T_ONE = b.coerce(1).first
T_MONE = b.coerce(-1).first
T31 = b.coerce(2**31).first # 2147483648
T31P = b.coerce(T31 - 1).first # 2147483647
T32 = b.coerce(2**32).first # 4294967296
T32P = b.coerce(T32 - 1).first # 4294967295
T64 = b.coerce(2**64).first # 18446744073709551616
T64P = b.coerce(T64 - 1).first # 18446744073709551615
T1024 = b.coerce(2**1024).first
T1024P = b.coerce(T1024 - 1).first
def test_prepare
assert_instance_of(Bignum, T_ZERO)
assert_instance_of(Bignum, T_ONE)
assert_instance_of(Bignum, T_MONE)
assert_instance_of(Bignum, T31)
assert_instance_of(Bignum, T31P)
assert_instance_of(Bignum, T32)
assert_instance_of(Bignum, T32P)
assert_instance_of(Bignum, T64)
assert_instance_of(Bignum, T64P)
assert_instance_of(Bignum, T1024)
assert_instance_of(Bignum, T1024P)
end
def test_big_2comp
assert_equal("-4294967296", (~T32P).to_s)
assert_equal("..f00000000", "%x" % -T32)
end
def test_int2inum
assert_equal([T31P], [T31P].pack("I").unpack("I"))
assert_equal([T31P], [T31P].pack("i").unpack("i"))
end
def test_quad_pack
assert_equal([ 1], [ 1].pack("q").unpack("q"))
assert_equal([- 1], [- 1].pack("q").unpack("q"))
assert_equal([ T31P], [ T31P].pack("q").unpack("q"))
assert_equal([-T31P], [-T31P].pack("q").unpack("q"))
assert_equal([ T64P], [ T64P].pack("Q").unpack("Q"))
assert_equal([ 0], [ T64 ].pack("Q").unpack("Q"))
end
def test_str_to_inum
assert_equal(1, " +1".to_i)
assert_equal(-1, " -1".to_i)
assert_equal(0, "++1".to_i)
assert_equal(73, "111".oct)
assert_equal(273, "0x111".oct)
assert_equal(7, "0b111".oct)
assert_equal(73, "0o111".oct)
assert_equal(111, "0d111".oct)
assert_equal(73, "0111".oct)
assert_equal(111, Integer("111"))
assert_equal(13, "111".to_i(3))
assert_raise(ArgumentError) { "111".to_i(37) }
assert_equal(1333, "111".to_i(36))
assert_equal(1057, "111".to_i(32))
assert_equal(0, "00a".to_i)
assert_equal(1, Integer("1 "))
assert_raise(ArgumentError) { Integer("1_") }
assert_raise(ArgumentError) { Integer("1__") }
assert_raise(ArgumentError) { Integer("1_0 x") }
assert_equal(T31P, "1111111111111111111111111111111".to_i(2))
assert_equal(0_2, '0_2'.to_i)
assert_equal(00_2, '00_2'.to_i)
assert_equal(00_02, '00_02'.to_i)
end
def test_to_s2
assert_raise(ArgumentError) { T31P.to_s(37) }
assert_equal("9" * 32768, (10**32768-1).to_s)
assert_raise(RangeError) { Process.wait(1, T64P) }
assert_equal("0", T_ZERO.to_s)
assert_equal("1", T_ONE.to_s)
end
def test_to_f
assert_nothing_raised { T31P.to_f.to_i }
assert_raise(FloatDomainError) { (1024**1024).to_f.to_i }
assert_equal(1, (2**50000).to_f.infinite?)
assert_equal(-1, (-(2**50000)).to_f.infinite?)
end
def test_cmp
assert_operator(T31P, :>, 1)
assert_operator(T31P, :<, 2147483648.0)
assert_operator(T31P, :<, T64P)
assert_operator(T64P, :>, T31P)
assert_raise(ArgumentError) { T31P < "foo" }
assert_operator(T64, :<, (1.0/0.0))
assert_not_operator(T64, :>, (1.0/0.0))
end
def test_eq
assert_not_equal(T31P, 1)
assert_equal(T31P, 2147483647.0)
assert_not_equal(T31P, "foo")
assert_not_equal(2**77889, (1.0/0.0), '[ruby-core:31603]')
end
def test_eql
assert_send([T31P, :eql?, T31P])
end
def test_convert
assert_equal([255], [T_MONE].pack("C").unpack("C"))
assert_equal([0], [T32].pack("C").unpack("C"))
assert_raise(RangeError) { 0.to_s(T32) }
end
def test_sub
assert_equal(-T31, T32 - (T32 + T31))
x = 2**100
assert_equal(1, (x+2) - (x+1))
assert_equal(-1, (x+1) - (x+2))
assert_equal(0, (2**100) - (2.0**100))
o = Object.new
def o.coerce(x); [x, 2**100+2]; end
assert_equal(-1, (2**100+1) - o)
assert_equal(-1, T_ONE - 2)
end
def test_plus
assert_equal(T32.to_f, T32P + 1.0)
assert_raise(TypeError) { T32 + "foo" }
assert_equal(1267651809154049016125877911552, (2**100) + (2**80))
assert_equal(1267651809154049016125877911552, (2**80) + (2**100))
assert_equal(2**101, (2**100) + (2.0**100))
o = Object.new
def o.coerce(x); [x, 2**80]; end
assert_equal(1267651809154049016125877911552, (2**100) + o)
end
def test_minus
assert_equal(T32P.to_f, T32 - 1.0)
assert_raise(TypeError) { T32 - "foo" }
end
def test_mul
assert_equal(T32.to_f, T32 * 1.0)
assert_raise(TypeError) { T32 * "foo" }
o = Object.new
def o.coerce(x); [x, 2**100]; end
assert_equal(2**180, (2**80) * o)
end
def test_mul_balance
assert_equal(3**7000, (3**5000) * (3**2000))
end
def test_divrem
assert_equal(0, T32 / T64)
end
def test_divide
bug5490 = '[ruby-core:40429]'
assert_raise(ZeroDivisionError, bug5490) {T1024./(0)}
assert_equal(Float::INFINITY, T1024./(0.0), bug5490)
end
def test_div
assert_equal(T32.to_f, T32 / 1.0)
assert_raise(TypeError) { T32 / "foo" }
assert_equal(0x20000000, 0x40000001.div(2.0), "[ruby-dev:34553]")
bug5490 = '[ruby-core:40429]'
assert_raise(ZeroDivisionError, bug5490) {T1024.div(0)}
assert_raise(ZeroDivisionError, bug5490) {T1024.div(0.0)}
end
def test_idiv
assert_equal(715827882, 1073741824.div(Rational(3,2)), ' [ruby-dev:34066]')
end
def test_modulo
assert_raise(TypeError) { T32 % "foo" }
end
def test_remainder
assert_equal(0, T32.remainder(1))
assert_raise(TypeError) { T32.remainder("foo") }
end
def test_divmod
assert_equal([T32, 0], T32.divmod(1))
assert_equal([2, 0], T32.divmod(T31))
assert_raise(TypeError) { T32.divmod("foo") }
end
def test_quo
assert_equal(T32.to_f, T32.quo(1))
assert_equal(T32.to_f, T32.quo(1.0))
assert_equal(T32.to_f, T32.quo(T_ONE))
assert_raise(TypeError) { T32.quo("foo") }
assert_equal(1024**1024, (1024**1024).quo(1))
assert_equal(1024**1024, (1024**1024).quo(1.0))
assert_equal(1024**1024*2, (1024**1024*2).quo(1))
inf = 1 / 0.0; nan = inf / inf
assert_send([(1024**1024*2).quo(nan), :nan?])
end
def test_pow
assert_equal(1.0, T32 ** 0.0)
assert_equal(1.0 / T32, T32 ** -1)
assert_equal(1, (T32 ** T32).infinite?)
assert_equal(1, (T32 ** (2**30-1)).infinite?)
### rational changes the behavior of Bignum#**
#assert_raise(TypeError) { T32**"foo" }
assert_raise(TypeError, ArgumentError) { T32**"foo" }
feature3429 = '[ruby-core:30735]'
assert_instance_of(Bignum, (2 ** 7830457), feature3429)
end
def test_and
assert_equal(0, T32 & 1)
assert_equal(-T32, (-T32) & (-T31))
assert_equal(0, T32 & T64)
end
def test_or
assert_equal(T32 + 1, T32 | 1)
assert_equal(T32 + T31, T32 | T31)
assert_equal(-T31, (-T32) | (-T31))
assert_equal(T64 + T32, T32 | T64)
end
def test_xor
assert_equal(T32 + 1, T32 ^ 1)
assert_equal(T32 + T31, T32 ^ T31)
assert_equal(T31, (-T32) ^ (-T31))
assert_equal(T64 + T32, T32 ^ T64)
end
class DummyNumeric < Numeric
def to_int
1
end
end
def test_and_with_float
assert_raise(TypeError) { T1024 & 1.5 }
end
def test_and_with_rational
assert_raise(TypeError, "#1792") { T1024 & Rational(3, 2) }
end
def test_and_with_nonintegral_numeric
assert_raise(TypeError, "#1792") { T1024 & DummyNumeric.new }
end
def test_or_with_float
assert_raise(TypeError) { T1024 | 1.5 }
end
def test_or_with_rational
assert_raise(TypeError, "#1792") { T1024 | Rational(3, 2) }
end
def test_or_with_nonintegral_numeric
assert_raise(TypeError, "#1792") { T1024 | DummyNumeric.new }
end
def test_xor_with_float
assert_raise(TypeError) { T1024 ^ 1.5 }
end
def test_xor_with_rational
assert_raise(TypeError, "#1792") { T1024 ^ Rational(3, 2) }
end
def test_xor_with_nonintegral_numeric
assert_raise(TypeError, "#1792") { T1024 ^ DummyNumeric.new }
end
def test_shift2
assert_equal(2**33, (2**32) << 1)
assert_equal(2**31, (2**32) << -1)
assert_equal(2**33, (2**32) << 1.0)
assert_equal(2**31, (2**32) << -1.0)
assert_equal(2**33, (2**32) << T_ONE)
assert_equal(2**31, (2**32) << T_MONE)
assert_equal(2**31, (2**32) >> 1)
assert_equal(2**33, (2**32) >> -1)
assert_equal(2**31, (2**32) >> 1.0)
assert_equal(2**33, (2**32) >> -1.0)
assert_equal(2**31, (2**32) >> T_ONE)
assert_equal(2**33, (2**32) >> T_MONE)
assert_equal( 0, (2**32) >> (2**32))
assert_equal(-1, -(2**32) >> (2**32))
assert_equal( 0, (2**32) >> 128)
assert_equal(-1, -(2**32) >> 128)
assert_equal( 0, (2**31) >> 32)
assert_equal(-1, -(2**31) >> 32)
end
def test_aref
assert_equal(0, (2**32)[0])
assert_equal(0, (2**32)[2**32])
assert_equal(0, (2**32)[-(2**32)])
assert_equal(0, (2**32)[T_ZERO])
assert_equal(0, (-(2**64))[0])
assert_equal(1, (-2**256)[256])
end
def test_hash
assert_nothing_raised { T31P.hash }
end
def test_coerce
assert_equal([T64P, T31P], T31P.coerce(T64P))
assert_raise(TypeError) { T31P.coerce(nil) }
end
def test_abs
assert_equal(T31P, (-T31P).abs)
end
def test_size
assert_kind_of(Integer, T31P.size)
end
def test_odd
assert_equal(true, (2**32+1).odd?)
assert_equal(false, (2**32).odd?)
end
def test_even
assert_equal(false, (2**32+1).even?)
assert_equal(true, (2**32).even?)
end
def assert_interrupt
time = Time.now
start_flag = false
end_flag = false
thread = Thread.new do
start_flag = true
yield
end_flag = true
end
Thread.pass until start_flag
thread.raise
thread.join rescue nil
time = Time.now - time
assert_equal([true, false], [start_flag, end_flag])
assert_operator(time, :<, 10)
end
def test_interrupt
assert_interrupt {(65536 ** 65536).to_s}
end
def test_too_big_to_s
if (big = 2**31-1).is_a?(Fixnum)
return
end
e = assert_raise(RangeError) {(1 << big).to_s}
assert_match(/too big to convert/, e.message)
end
def test_fix_fdiv
assert_not_equal(0, 1.fdiv(@fmax2))
assert_in_delta(0.5, 1.fdiv(@fmax2) * @fmax, 0.01)
end
def test_big_fdiv
assert_equal(1, @big.fdiv(@big))
assert_not_equal(0, @big.fdiv(@fmax2))
assert_not_equal(0, @fmax2.fdiv(@big))
assert_not_equal(0, @fmax2.fdiv(@fmax2))
assert_in_delta(0.5, @fmax.fdiv(@fmax2), 0.01)
assert_in_delta(1.0, @fmax2.fdiv(@fmax2), 0.01)
end
def test_float_fdiv
b = 1E+300.to_i
assert_equal(b, (b ** 2).fdiv(b))
assert_send([@big.fdiv(0.0 / 0.0), :nan?])
assert_in_delta(1E+300, (10**500).fdiv(1E+200), 1E+285)
end
def test_obj_fdiv
o = Object.new
def o.coerce(x); [x, 2**100]; end
assert_equal((2**200).to_f, (2**300).fdiv(o))
end
end