Initial commit of OpenSPARC T2 architecture model.

[OpenSPARC-T2-SAM] / sam-t2 / devtools / amd64 / lib / python2.4 / test / test_long.py

from test.test_support import verify, verbose, TestFailed, fcmp
from string import join
from random import random, randint

# SHIFT should match the value in longintrepr.h for best testing.
SHIFT = 15
BASE = 2 ** SHIFT
MASK = BASE - 1
KARATSUBA_CUTOFF = 70   # from longobject.c

# Max number of base BASE digits to use in test cases.  Doubling
# this will more than double the runtime.
MAXDIGITS = 15

# build some special values
special = map(long, [0, 1, 2, BASE, BASE >> 1])
special.append(0x5555555555555555L)
special.append(0xaaaaaaaaaaaaaaaaL)
#  some solid strings of one bits
p2 = 4L  # 0 and 1 already added
for i in range(2*SHIFT):
   special.append(p2 - 1)
   p2 = p2 << 1
del p2
# add complements & negations
special = special + map(lambda x: ~x, special) + \
                   map(lambda x: -x, special)

# ------------------------------------------------------------ utilities

# Use check instead of assert so the test still does something
# under -O.

def check(ok, *args):
   if not ok:
       raise TestFailed, join(map(str, args), " ")

# Get quasi-random long consisting of ndigits digits (in base BASE).
# quasi == the most-significant digit will not be 0, and the number
# is constructed to contain long strings of 0 and 1 bits.  These are
# more likely than random bits to provoke digit-boundary errors.
# The sign of the number is also random.

def getran(ndigits):
   verify(ndigits > 0)
   nbits_hi = ndigits * SHIFT
   nbits_lo = nbits_hi - SHIFT + 1
   answer = 0L
   nbits = 0
   r = int(random() * (SHIFT * 2)) | 1  # force 1 bits to start
   while nbits < nbits_lo:
       bits = (r >> 1) + 1
       bits = min(bits, nbits_hi - nbits)
       verify(1 <= bits <= SHIFT)
       nbits = nbits + bits
       answer = answer << bits
       if r & 1:
           answer = answer | ((1 << bits) - 1)
       r = int(random() * (SHIFT * 2))
   verify(nbits_lo <= nbits <= nbits_hi)
   if random() < 0.5:
       answer = -answer
   return answer

# Get random long consisting of ndigits random digits (relative to base
# BASE).  The sign bit is also random.

def getran2(ndigits):
   answer = 0L
   for i in range(ndigits):
       answer = (answer << SHIFT) | randint(0, MASK)
   if random() < 0.5:
       answer = -answer
   return answer

# --------------------------------------------------------------- divmod

def test_division_2(x, y):
   q, r = divmod(x, y)
   q2, r2 = x//y, x%y
   pab, pba = x*y, y*x
   check(pab == pba, "multiplication does not commute for", x, y)
   check(q == q2, "divmod returns different quotient than / for", x, y)
   check(r == r2, "divmod returns different mod than % for", x, y)
   check(x == q*y + r, "x != q*y + r after divmod on", x, y)
   if y > 0:
       check(0 <= r < y, "bad mod from divmod on", x, y)
   else:
       check(y < r <= 0, "bad mod from divmod on", x, y)

def test_division(maxdigits=MAXDIGITS):
   if verbose:
       print "long / * % divmod"
   digits = range(1, maxdigits+1) + range(KARATSUBA_CUTOFF,
                                          KARATSUBA_CUTOFF + 14)
   digits.append(KARATSUBA_CUTOFF * 3)
   for lenx in digits:
       x = getran(lenx)
       for leny in digits:
           y = getran(leny) or 1L
           test_division_2(x, y)
# ------------------------------------------------------------ karatsuba

def test_karatsuba():

   if verbose:
       print "Karatsuba"

   digits = range(1, 5) + range(KARATSUBA_CUTOFF, KARATSUBA_CUTOFF + 10)
   digits.extend([KARATSUBA_CUTOFF * 10, KARATSUBA_CUTOFF * 100])

   bits = [digit * SHIFT for digit in digits]

   # Test products of long strings of 1 bits -- (2**x-1)*(2**y-1) ==
   # 2**(x+y) - 2**x - 2**y + 1, so the proper result is easy to check.
   for abits in bits:
       a = (1L << abits) - 1
       for bbits in bits:
           if bbits < abits:
               continue
           b = (1L << bbits) - 1
           x = a * b
           y = ((1L << (abits + bbits)) -
                (1L << abits) -
                (1L << bbits) +
                1)
           check(x == y, "bad result for", a, "*", b, x, y)
# -------------------------------------------------------------- ~ & | ^

def test_bitop_identities_1(x):
   check(x & 0 == 0, "x & 0 != 0 for", x)
   check(x | 0 == x, "x | 0 != x for", x)
   check(x ^ 0 == x, "x ^ 0 != x for", x)
   check(x & -1 == x, "x & -1 != x for", x)
   check(x | -1 == -1, "x | -1 != -1 for", x)
   check(x ^ -1 == ~x, "x ^ -1 != ~x for", x)
   check(x == ~~x, "x != ~~x for", x)
   check(x & x == x, "x & x != x for", x)
   check(x | x == x, "x | x != x for", x)
   check(x ^ x == 0, "x ^ x != 0 for", x)
   check(x & ~x == 0, "x & ~x != 0 for", x)
   check(x | ~x == -1, "x | ~x != -1 for", x)
   check(x ^ ~x == -1, "x ^ ~x != -1 for", x)
   check(-x == 1 + ~x == ~(x-1), "not -x == 1 + ~x == ~(x-1) for", x)
   for n in range(2*SHIFT):
       p2 = 2L ** n
       check(x << n >> n == x, "x << n >> n != x for", x, n)
       check(x // p2 == x >> n, "x // p2 != x >> n for x n p2", x, n, p2)
       check(x * p2 == x << n, "x * p2 != x << n for x n p2", x, n, p2)
       check(x & -p2 == x >> n << n == x & ~(p2 - 1),
           "not x & -p2 == x >> n << n == x & ~(p2 - 1) for x n p2",
           x, n, p2)

def test_bitop_identities_2(x, y):
   check(x & y == y & x, "x & y != y & x for", x, y)
   check(x | y == y | x, "x | y != y | x for", x, y)
   check(x ^ y == y ^ x, "x ^ y != y ^ x for", x, y)
   check(x ^ y ^ x == y, "x ^ y ^ x != y for", x, y)
   check(x & y == ~(~x | ~y), "x & y != ~(~x | ~y) for", x, y)
   check(x | y == ~(~x & ~y), "x | y != ~(~x & ~y) for", x, y)
   check(x ^ y == (x | y) & ~(x & y),
        "x ^ y != (x | y) & ~(x & y) for", x, y)
   check(x ^ y == (x & ~y) | (~x & y),
        "x ^ y == (x & ~y) | (~x & y) for", x, y)
   check(x ^ y == (x | y) & (~x | ~y),
        "x ^ y == (x | y) & (~x | ~y) for", x, y)

def test_bitop_identities_3(x, y, z):
   check((x & y) & z == x & (y & z),
        "(x & y) & z != x & (y & z) for", x, y, z)
   check((x | y) | z == x | (y | z),
        "(x | y) | z != x | (y | z) for", x, y, z)
   check((x ^ y) ^ z == x ^ (y ^ z),
        "(x ^ y) ^ z != x ^ (y ^ z) for", x, y, z)
   check(x & (y | z) == (x & y) | (x & z),
        "x & (y | z) != (x & y) | (x & z) for", x, y, z)
   check(x | (y & z) == (x | y) & (x | z),
        "x | (y & z) != (x | y) & (x | z) for", x, y, z)

def test_bitop_identities(maxdigits=MAXDIGITS):
   if verbose:
       print "long bit-operation identities"
   for x in special:
       test_bitop_identities_1(x)
   digits = range(1, maxdigits+1)
   for lenx in digits:
       x = getran(lenx)
       test_bitop_identities_1(x)
       for leny in digits:
           y = getran(leny)
           test_bitop_identities_2(x, y)
           test_bitop_identities_3(x, y, getran((lenx + leny)//2))

# ------------------------------------------------- hex oct repr str atol

def slow_format(x, base):
   if (x, base) == (0, 8):
       # this is an oddball!
       return "0L"
   digits = []
   sign = 0
   if x < 0:
       sign, x = 1, -x
   while x:
       x, r = divmod(x, base)
       digits.append(int(r))
   digits.reverse()
   digits = digits or [0]
   return '-'[:sign] + \
          {8: '0', 10: '', 16: '0x'}[base] + \
          join(map(lambda i: "0123456789ABCDEF"[i], digits), '') + \
          "L"

def test_format_1(x):
   from string import atol
   for base, mapper in (8, oct), (10, repr), (16, hex):
       got = mapper(x)
       expected = slow_format(x, base)
       check(got == expected, mapper.__name__, "returned",
             got, "but expected", expected, "for", x)
       check(atol(got, 0) == x, 'atol("%s", 0) !=' % got, x)
   # str() has to be checked a little differently since there's no
   # trailing "L"
   got = str(x)
   expected = slow_format(x, 10)[:-1]
   check(got == expected, mapper.__name__, "returned",
         got, "but expected", expected, "for", x)

def test_format(maxdigits=MAXDIGITS):
   if verbose:
       print "long str/hex/oct/atol"
   for x in special:
       test_format_1(x)
   for i in range(10):
       for lenx in range(1, maxdigits+1):
           x = getran(lenx)
           test_format_1(x)

# ----------------------------------------------------------------- misc

def test_misc(maxdigits=MAXDIGITS):
   if verbose:
       print "long miscellaneous operations"
   import sys

   # check the extremes in int<->long conversion
   hugepos = sys.maxint
   hugeneg = -hugepos - 1
   hugepos_aslong = long(hugepos)
   hugeneg_aslong = long(hugeneg)
   check(hugepos == hugepos_aslong, "long(sys.maxint) != sys.maxint")
   check(hugeneg == hugeneg_aslong,
       "long(-sys.maxint-1) != -sys.maxint-1")

   # long -> int should not fail for hugepos_aslong or hugeneg_aslong
   try:
       check(int(hugepos_aslong) == hugepos,
             "converting sys.maxint to long and back to int fails")
   except OverflowError:
       raise TestFailed, "int(long(sys.maxint)) overflowed!"
   try:
       check(int(hugeneg_aslong) == hugeneg,
             "converting -sys.maxint-1 to long and back to int fails")
   except OverflowError:
       raise TestFailed, "int(long(-sys.maxint-1)) overflowed!"

   # but long -> int should overflow for hugepos+1 and hugeneg-1
   x = hugepos_aslong + 1
   try:
       y = int(x)
   except OverflowError:
       raise TestFailed, "int(long(sys.maxint) + 1) mustn't overflow"
   if not isinstance(y, long):
       raise TestFailed("int(long(sys.maxint) + 1) should have returned long")

   x = hugeneg_aslong - 1
   try:
       y = int(x)
   except OverflowError:
       raise TestFailed, "int(long(-sys.maxint-1) - 1) mustn't overflow"
   if not isinstance(y, long):
       raise TestFailed("int(long(-sys.maxint-1) - 1) should have returned long")

   class long2(long):
       pass
   x = long2(1L<<100)
   y = int(x)
   if type(y) is not long:
       raise TestFailed("overflowing int conversion must return long not long subtype")
# ----------------------------------- tests of auto int->long conversion

def test_auto_overflow():
   import math, sys

   if verbose:
       print "auto-convert int->long on overflow"

   special = [0, 1, 2, 3, sys.maxint-1, sys.maxint, sys.maxint+1]
   sqrt = int(math.sqrt(sys.maxint))
   special.extend([sqrt-1, sqrt, sqrt+1])
   special.extend([-i for i in special])

   def checkit(*args):
       # Heavy use of nested scopes here!
       verify(got == expected, "for %r expected %r got %r" %
                               (args, expected, got))

   for x in special:
       longx = long(x)

       expected = -longx
       got = -x
       checkit('-', x)

       for y in special:
           longy = long(y)

           expected = longx + longy
           got = x + y
           checkit(x, '+', y)

           expected = longx - longy
           got = x - y
           checkit(x, '-', y)

           expected = longx * longy
           got = x * y
           checkit(x, '*', y)

           if y:
               expected = longx / longy
               got = x / y
               checkit(x, '/', y)

               expected = longx // longy
               got = x // y
               checkit(x, '//', y)

               expected = divmod(longx, longy)
               got = divmod(longx, longy)
               checkit(x, 'divmod', y)

           if abs(y) < 5 and not (x == 0 and y < 0):
               expected = longx ** longy
               got = x ** y
               checkit(x, '**', y)

               for z in special:
                   if z != 0 :
                       if y >= 0:
                           expected = pow(longx, longy, long(z))
                           got = pow(x, y, z)
                           checkit('pow', x, y, '%', z)
                       else:
                           try:
                               pow(longx, longy, long(z))
                           except TypeError:
                               pass
                           else:
                               raise TestFailed("pow%r should have raised "
                               "TypeError" % ((longx, longy, long(z)),))

# ---------------------------------------- tests of long->float overflow

def test_float_overflow():
   import math

   if verbose:
       print "long->float overflow"

   for x in -2.0, -1.0, 0.0, 1.0, 2.0:
       verify(float(long(x)) == x)

   shuge = '12345' * 120
   huge = 1L << 30000
   mhuge = -huge
   namespace = {'huge': huge, 'mhuge': mhuge, 'shuge': shuge, 'math': math}
   for test in ["float(huge)", "float(mhuge)",
                "complex(huge)", "complex(mhuge)",
                "complex(huge, 1)", "complex(mhuge, 1)",
                "complex(1, huge)", "complex(1, mhuge)",
                "1. + huge", "huge + 1.", "1. + mhuge", "mhuge + 1.",
                "1. - huge", "huge - 1.", "1. - mhuge", "mhuge - 1.",
                "1. * huge", "huge * 1.", "1. * mhuge", "mhuge * 1.",
                "1. // huge", "huge // 1.", "1. // mhuge", "mhuge // 1.",
                "1. / huge", "huge / 1.", "1. / mhuge", "mhuge / 1.",
                "1. ** huge", "huge ** 1.", "1. ** mhuge", "mhuge ** 1.",
                "math.sin(huge)", "math.sin(mhuge)",
                "math.sqrt(huge)", "math.sqrt(mhuge)", # should do better
                "math.floor(huge)", "math.floor(mhuge)"]:

       try:
           eval(test, namespace)
       except OverflowError:
           pass
       else:
           raise TestFailed("expected OverflowError from %s" % test)

       # XXX Perhaps float(shuge) can raise OverflowError on some box?
       # The comparison should not.
       if float(shuge) == int(shuge):
           raise TestFailed("float(shuge) should not equal int(shuge)")

# ---------------------------------------------- test huge log and log10

def test_logs():
   import math

   if verbose:
       print "log and log10"

   LOG10E = math.log10(math.e)

   for exp in range(10) + [100, 1000, 10000]:
       value = 10 ** exp
       log10 = math.log10(value)
       verify(fcmp(log10, exp) == 0)

       # log10(value) == exp, so log(value) == log10(value)/log10(e) ==
       # exp/LOG10E
       expected = exp / LOG10E
       log = math.log(value)
       verify(fcmp(log, expected) == 0)

   for bad in -(1L << 10000), -2L, 0L:
       try:
           math.log(bad)
           raise TestFailed("expected ValueError from log(<= 0)")
       except ValueError:
           pass

       try:
           math.log10(bad)
           raise TestFailed("expected ValueError from log10(<= 0)")
       except ValueError:
           pass

# ----------------------------------------------- test mixed comparisons

def test_mixed_compares():
   import math
   import sys

   if verbose:
       print "mixed comparisons"

   # We're mostly concerned with that mixing floats and longs does the
   # right stuff, even when longs are too large to fit in a float.
   # The safest way to check the results is to use an entirely different
   # method, which we do here via a skeletal rational class (which
   # represents all Python ints, longs and floats exactly).
   class Rat:
       def __init__(self, value):
           if isinstance(value, (int, long)):
               self.n = value
               self.d = 1

           elif isinstance(value, float):
               # Convert to exact rational equivalent.
               f, e = math.frexp(abs(value))
               assert f == 0 or 0.5 <= f < 1.0
               # |value| = f * 2**e exactly

               # Suck up CHUNK bits at a time; 28 is enough so that we suck
               # up all bits in 2 iterations for all known binary double-
               # precision formats, and small enough to fit in an int.
               CHUNK = 28
               top = 0
               # invariant: |value| = (top + f) * 2**e exactly
               while f:
                   f = math.ldexp(f, CHUNK)
                   digit = int(f)
                   assert digit >> CHUNK == 0
                   top = (top << CHUNK) | digit
                   f -= digit
                   assert 0.0 <= f < 1.0
                   e -= CHUNK

               # Now |value| = top * 2**e exactly.
               if e >= 0:
                   n = top << e
                   d = 1
               else:
                   n = top
                   d = 1 << -e
               if value < 0:
                   n = -n
               self.n = n
               self.d = d
               assert float(n) / float(d) == value

           else:
               raise TypeError("can't deal with %r" % val)

       def __cmp__(self, other):
           if not isinstance(other, Rat):
               other = Rat(other)
           return cmp(self.n * other.d, self.d * other.n)

   cases = [0, 0.001, 0.99, 1.0, 1.5, 1e20, 1e200]
   # 2**48 is an important boundary in the internals.  2**53 is an
   # important boundary for IEEE double precision.
   for t in 2.0**48, 2.0**50, 2.0**53:
       cases.extend([t - 1.0, t - 0.3, t, t + 0.3, t + 1.0,
                     long(t-1), long(t), long(t+1)])
   cases.extend([0, 1, 2, sys.maxint, float(sys.maxint)])
   # 1L<<20000 should exceed all double formats.  long(1e200) is to
   # check that we get equality with 1e200 above.
   t = long(1e200)
   cases.extend([0L, 1L, 2L, 1L << 20000, t-1, t, t+1])
   cases.extend([-x for x in cases])
   for x in cases:
       Rx = Rat(x)
       for y in cases:
           Ry = Rat(y)
           Rcmp = cmp(Rx, Ry)
           xycmp = cmp(x, y)
           if Rcmp != xycmp:
               raise TestFailed('%r %r %d %d' % (x, y, Rcmp, xycmp))
           if (x == y) != (Rcmp == 0):
               raise TestFailed('%r == %r %d' % (x, y, Rcmp))
           if (x != y) != (Rcmp != 0):
               raise TestFailed('%r != %r %d' % (x, y, Rcmp))
           if (x < y) != (Rcmp < 0):
               raise TestFailed('%r < %r %d' % (x, y, Rcmp))
           if (x <= y) != (Rcmp <= 0):
               raise TestFailed('%r <= %r %d' % (x, y, Rcmp))
           if (x > y) != (Rcmp > 0):
               raise TestFailed('%r > %r %d' % (x, y, Rcmp))
           if (x >= y) != (Rcmp >= 0):
               raise TestFailed('%r >= %r %d' % (x, y, Rcmp))

# ---------------------------------------------------------------- do it

test_division()
test_karatsuba()
test_bitop_identities()
test_format()
test_misc()
test_auto_overflow()
test_float_overflow()
test_logs()
test_mixed_compares()