Lib/test/test_struct.py - platform/external/python/cpython2 - Gitiles

 from test.test_support import TestFailed, verbose, verify
 import struct

 import sys
 ISBIGENDIAN = sys.byteorder == "big"
 del sys
 verify((struct.pack('=i', 1)[0] == chr(0)) == ISBIGENDIAN,
        "bigendian determination appears wrong")

 def string_reverse(s):
     chars = list(s)
     chars.reverse()
     return "".join(chars)

 def bigendian_to_native(value):
     if ISBIGENDIAN:
         return value
     else:
         return string_reverse(value)

 def simple_err(func, *args):
     try:
         func(*args)
     except struct.error:
         pass
     else:
         raise TestFailed, "%s%s did not raise struct.error" % (
             func.__name__, args)

 def any_err(func, *args):
     try:
         func(*args)
     except (struct.error, OverflowError, TypeError):
         pass
     else:
         raise TestFailed, "%s%s did not raise error" % (
             func.__name__, args)


 simple_err(struct.calcsize, 'Z')

 sz = struct.calcsize('i')
 if sz * 3 != struct.calcsize('iii'):
     raise TestFailed, 'inconsistent sizes'

 fmt = 'cbxxxxxxhhhhiillffd'
 fmt3 = '3c3b18x12h6i6l6f3d'
 sz = struct.calcsize(fmt)
 sz3 = struct.calcsize(fmt3)
 if sz * 3 != sz3:
     raise TestFailed, 'inconsistent sizes (3*%s -> 3*%d = %d, %s -> %d)' % (
         `fmt`, sz, 3*sz, `fmt3`, sz3)

 simple_err(struct.pack, 'iii', 3)
 simple_err(struct.pack, 'i', 3, 3, 3)
 simple_err(struct.pack, 'i', 'foo')
 simple_err(struct.unpack, 'd', 'flap')
 s = struct.pack('ii', 1, 2)
 simple_err(struct.unpack, 'iii', s)
 simple_err(struct.unpack, 'i', s)

 c = 'a'
 b = 1
 h = 255
 i = 65535
 l = 65536
 f = 3.1415
 d = 3.1415

 for prefix in ('', '@', '<', '>', '=', '!'):
     for format in ('xcbhilfd', 'xcBHILfd'):
         format = prefix + format
         if verbose:
             print "trying:", format
         s = struct.pack(format, c, b, h, i, l, f, d)
         cp, bp, hp, ip, lp, fp, dp = struct.unpack(format, s)
         if (cp != c or bp != b or hp != h or ip != i or lp != l or
             int(100 * fp) != int(100 * f) or int(100 * dp) != int(100 * d)):
             # ^^^ calculate only to two decimal places
             raise TestFailed, "unpack/pack not transitive (%s, %s)" % (
                 str(format), str((cp, bp, hp, ip, lp, fp, dp)))

 # Test some of the new features in detail

 # (format, argument, big-endian result, little-endian result, asymmetric)
 tests = [
     ('c', 'a', 'a', 'a', 0),
     ('xc', 'a', '\0a', '\0a', 0),
     ('cx', 'a', 'a\0', 'a\0', 0),
     ('s', 'a', 'a', 'a', 0),
     ('0s', 'helloworld', '', '', 1),
     ('1s', 'helloworld', 'h', 'h', 1),
     ('9s', 'helloworld', 'helloworl', 'helloworl', 1),
     ('10s', 'helloworld', 'helloworld', 'helloworld', 0),
     ('11s', 'helloworld', 'helloworld\0', 'helloworld\0', 1),
     ('20s', 'helloworld', 'helloworld'+10*'\0', 'helloworld'+10*'\0', 1),
     ('b', 7, '\7', '\7', 0),
     ('b', -7, '\371', '\371', 0),
     ('B', 7, '\7', '\7', 0),
     ('B', 249, '\371', '\371', 0),
     ('h', 700, '\002\274', '\274\002', 0),
     ('h', -700, '\375D', 'D\375', 0),
     ('H', 700, '\002\274', '\274\002', 0),
     ('H', 0x10000-700, '\375D', 'D\375', 0),
     ('i', 70000000, '\004,\035\200', '\200\035,\004', 0),
     ('i', -70000000, '\373\323\342\200', '\200\342\323\373', 0),
     ('I', 70000000L, '\004,\035\200', '\200\035,\004', 0),
     ('I', 0x100000000L-70000000, '\373\323\342\200', '\200\342\323\373', 0),
     ('l', 70000000, '\004,\035\200', '\200\035,\004', 0),
     ('l', -70000000, '\373\323\342\200', '\200\342\323\373', 0),
     ('L', 70000000L, '\004,\035\200', '\200\035,\004', 0),
     ('L', 0x100000000L-70000000, '\373\323\342\200', '\200\342\323\373', 0),
     ('f', 2.0, '@\000\000\000', '\000\000\000@', 0),
     ('d', 2.0, '@\000\000\000\000\000\000\000',
                '\000\000\000\000\000\000\000@', 0),
     ('f', -2.0, '\300\000\000\000', '\000\000\000\300', 0),
     ('d', -2.0, '\300\000\000\000\000\000\000\000',
                '\000\000\000\000\000\000\000\300', 0),
 ]

 for fmt, arg, big, lil, asy in tests:
     if verbose:
         print `fmt`, `arg`, `big`, `lil`
     for (xfmt, exp) in [('>'+fmt, big), ('!'+fmt, big), ('<'+fmt, lil),
                         ('='+fmt, ISBIGENDIAN and big or lil)]:
         res = struct.pack(xfmt, arg)
         if res != exp:
             raise TestFailed, "pack(%s, %s) -> %s # expected %s" % (
                 `fmt`, `arg`, `res`, `exp`)
         n = struct.calcsize(xfmt)
         if n != len(res):
             raise TestFailed, "calcsize(%s) -> %d # expected %d" % (
                 `xfmt`, n, len(res))
         rev = struct.unpack(xfmt, res)[0]
         if rev != arg and not asy:
             raise TestFailed, "unpack(%s, %s) -> (%s,) # expected (%s,)" % (
                 `fmt`, `res`, `rev`, `arg`)

 ###########################################################################
 # Simple native q/Q tests.

 has_native_qQ = 1
 try:
     struct.pack("q", 5)
 except struct.error:
     has_native_qQ = 0

 if verbose:
     print "Platform has native q/Q?", has_native_qQ and "Yes." or "No."

 any_err(struct.pack, "Q", -1)   # can't pack -1 as unsigned regardless
 simple_err(struct.pack, "q", "a")  # can't pack string as 'q' regardless
 simple_err(struct.pack, "Q", "a")  # ditto, but 'Q'

 def test_native_qQ():
     bytes = struct.calcsize('q')
     # The expected values here are in big-endian format, primarily because
     # I'm on a little-endian machine and so this is the clearest way (for
     # me) to force the code to get exercised.
     for format, input, expected in (
             ('q', -1, '\xff' * bytes),
             ('q', 0, '\x00' * bytes),
             ('Q', 0, '\x00' * bytes),
             ('q', 1L, '\x00' * (bytes-1) + '\x01'),
             ('Q', (1L << (8*bytes))-1, '\xff' * bytes),
             ('q', (1L << (8*bytes-1))-1, '\x7f' + '\xff' * (bytes - 1))):
         got = struct.pack(format, input)
         native_expected = bigendian_to_native(expected)
         verify(got == native_expected,
                "%r-pack of %r gave %r, not %r" %
                     (format, input, got, native_expected))
         retrieved = struct.unpack(format, got)[0]
         verify(retrieved == input,
                "%r-unpack of %r gave %r, not %r" %
                     (format, got, retrieved, input))

 if has_native_qQ:
     test_native_qQ()

 ###########################################################################
 # Standard integer tests (bBhHiIlLqQ).

 import binascii

 class IntTester:

     # XXX Most std integer modes fail to test for out-of-range.
     # The "i" and "l" codes appear to range-check OK on 32-bit boxes, but
     # fail to check correctly on some 64-bit ones (Tru64 Unix + Compaq C
     # reported by Mark Favas).
     BUGGY_RANGE_CHECK = "bBhHiIlL"

     def __init__(self, formatpair, bytesize):
         assert len(formatpair) == 2
         self.formatpair = formatpair
         for direction in "<>!=":
             for code in formatpair:
                 format = direction + code
                 verify(struct.calcsize(format) == bytesize)
         self.bytesize = bytesize
         self.bitsize = bytesize * 8
         self.signed_code, self.unsigned_code = formatpair
         self.unsigned_min = 0
         self.unsigned_max = 2L**self.bitsize - 1
         self.signed_min = -(2L**(self.bitsize-1))
         self.signed_max = 2L**(self.bitsize-1) - 1

     def test_one(self, x, pack=struct.pack,
                           unpack=struct.unpack,
                           unhexlify=binascii.unhexlify):
         if verbose:
             print "trying std", self.formatpair, "on", x, "==", hex(x)

         # Try signed.
         code = self.signed_code
         if self.signed_min <= x <= self.signed_max:
             # Try big-endian.
             expected = long(x)
             if x < 0:
                 expected += 1L << self.bitsize
                 assert expected > 0
             expected = hex(expected)[2:-1] # chop "0x" and trailing 'L'
             if len(expected) & 1:
                 expected = "0" + expected
             expected = unhexlify(expected)
             expected = "\x00" * (self.bytesize - len(expected)) + expected

             # Pack work?
             format = ">" + code
             got = pack(format, x)
             verify(got == expected,
                    "'%s'-pack of %r gave %r, not %r" %
                     (format, x, got, expected))

             # Unpack work?
             retrieved = unpack(format, got)[0]
             verify(x == retrieved,
                    "'%s'-unpack of %r gave %r, not %r" %
                     (format, got, retrieved, x))

             # Adding any byte should cause a "too big" error.
             any_err(unpack, format, '\x01' + got)

             # Try little-endian.
             format = "<" + code
             expected = string_reverse(expected)

             # Pack work?
             got = pack(format, x)
             verify(got == expected,
                    "'%s'-pack of %r gave %r, not %r" %
                     (format, x, got, expected))

             # Unpack work?
             retrieved = unpack(format, got)[0]
             verify(x == retrieved,
                    "'%s'-unpack of %r gave %r, not %r" %
                     (format, got, retrieved, x))

             # Adding any byte should cause a "too big" error.
             any_err(unpack, format, '\x01' + got)

         else:
             # x is out of range -- verify pack realizes that.
             if code in self.BUGGY_RANGE_CHECK:
                 if verbose:
                     print "Skipping buggy range check for code", code
             else:
                 any_err(pack, ">" + code, x)
                 any_err(pack, "<" + code, x)

         # Much the same for unsigned.
         code = self.unsigned_code
         if self.unsigned_min <= x <= self.unsigned_max:
             # Try big-endian.
             format = ">" + code
             expected = long(x)
             expected = hex(expected)[2:-1] # chop "0x" and trailing 'L'
             if len(expected) & 1:
                 expected = "0" + expected
             expected = unhexlify(expected)
             expected = "\x00" * (self.bytesize - len(expected)) + expected

             # Pack work?
             got = pack(format, x)
             verify(got == expected,
                    "'%s'-pack of %r gave %r, not %r" %
                     (format, x, got, expected))

             # Unpack work?
             retrieved = unpack(format, got)[0]
             verify(x == retrieved,
                    "'%s'-unpack of %r gave %r, not %r" %
                     (format, got, retrieved, x))

             # Adding any byte should cause a "too big" error.
             any_err(unpack, format, '\x01' + got)

             # Try little-endian.
             format = "<" + code
             expected = string_reverse(expected)

             # Pack work?
             got = pack(format, x)
             verify(got == expected,
                    "'%s'-pack of %r gave %r, not %r" %
                     (format, x, got, expected))

             # Unpack work?
             retrieved = unpack(format, got)[0]
             verify(x == retrieved,
                    "'%s'-unpack of %r gave %r, not %r" %
                     (format, got, retrieved, x))

             # Adding any byte should cause a "too big" error.
             any_err(unpack, format, '\x01' + got)

         else:
             # x is out of range -- verify pack realizes that.
             if code in self.BUGGY_RANGE_CHECK:
                 if verbose:
                     print "Skipping buggy range check for code", code
             else:
                 any_err(pack, ">" + code, x)
                 any_err(pack, "<" + code, x)

     def run(self):
         from random import randrange

         # Create all interesting powers of 2.
         values = []
         for exp in range(self.bitsize + 3):
             values.append(1L << exp)

         # Add some random values.
         for i in range(self.bitsize):
             val = 0L
             for j in range(self.bytesize):
                 val = (val << 8) | randrange(256)
             values.append(val)

         # Try all those, and their negations, and +-1 from them.  Note
         # that this tests all power-of-2 boundaries in range, and a few out
         # of range, plus +-(2**n +- 1).
         for base in values:
             for val in -base, base:
                 for incr in -1, 0, 1:
                     x = val + incr
                     try:
                         x = int(x)
                     except OverflowError:
                         pass
                     self.test_one(x)

         # Some error cases.
         for direction in "<>":
             for code in self.formatpair:
                 for badobject in "a string", 3+42j, randrange:
                     any_err(struct.pack, direction + code, badobject)

 for args in [("bB", 1),
              ("hH", 2),
              ("iI", 4),
              ("lL", 4),
              ("qQ", 8)]:
     t = IntTester(*args)
     t.run()


 ###########################################################################
 # The p ("Pascal string") code.

 def test_p_code():
     for code, input, expected, expectedback in [
             ('p','abc', '\x00', ''),
             ('1p', 'abc', '\x00', ''),
             ('2p', 'abc', '\x01a', 'a'),
             ('3p', 'abc', '\x02ab', 'ab'),
             ('4p', 'abc', '\x03abc', 'abc'),
             ('5p', 'abc', '\x03abc\x00', 'abc'),
             ('6p', 'abc', '\x03abc\x00\x00', 'abc'),
             ('1000p', 'x'*1000, '\xff' + 'x'*999, 'x'*255)]:
         got = struct.pack(code, input)
         if got != expected:
             raise TestFailed("pack(%r, %r) == %r but expected %r" %
                              (code, input, got, expected))
         (got,) = struct.unpack(code, got)
         if got != expectedback:
             raise TestFailed("unpack(%r, %r) == %r but expected %r" %
                              (code, input, got, expectedback))

 test_p_code()


 ###########################################################################
 # SF bug 705836.  "<f" and ">f" had a severe rounding bug, where a carry
 # from the low-order discarded bits could propagate into the exponent
 # field, causing the result to be wrong by a factor of 2.

 def test_705836():
     import math

     for base in range(1, 33):
         # smaller <- largest representable float less than base.
         delta = 0.5
         while base - delta / 2.0 != base:
             delta /= 2.0
         smaller = base - delta
         # Packing this rounds away a solid string of trailing 1 bits.
         packed = struct.pack("<f", smaller)
         unpacked = struct.unpack("<f", packed)[0]
         # This failed at base = 2, 4, and 32, with unpacked = 1, 2, and
         # 16, respectively.
         verify(base == unpacked)
         bigpacked = struct.pack(">f", smaller)
         verify(bigpacked == string_reverse(packed),
                ">f pack should be byte-reversal of <f pack")
         unpacked = struct.unpack(">f", bigpacked)[0]
         verify(base == unpacked)

     # Largest finite IEEE single.
     big = (1 << 24) - 1
     big = math.ldexp(big, 127 - 23)
     packed = struct.pack(">f", big)
     unpacked = struct.unpack(">f", packed)[0]
     verify(big == unpacked)

     # The same, but tack on a 1 bit so it rounds up to infinity.
     big = (1 << 25) - 1
     big = math.ldexp(big, 127 - 24)
     try:
         packed = struct.pack(">f", big)
     except OverflowError:
         pass
     else:
         TestFailed("expected OverflowError")

 test_705836()
	from test.test_support import TestFailed, verbose, verify
	import struct

	import sys
	ISBIGENDIAN = sys.byteorder == "big"
	del sys
	verify((struct.pack('=i', 1)[0] == chr(0)) == ISBIGENDIAN,
	"bigendian determination appears wrong")

	def string_reverse(s):
	chars = list(s)
	chars.reverse()
	return "".join(chars)

	def bigendian_to_native(value):
	if ISBIGENDIAN:
	return value
	else:
	return string_reverse(value)

	def simple_err(func, *args):
	try:
	func(*args)
	except struct.error:
	pass
	else:
	raise TestFailed, "%s%s did not raise struct.error" % (
	func.__name__, args)

	def any_err(func, *args):
	try:
	func(*args)
	except (struct.error, OverflowError, TypeError):
	pass
	else:
	raise TestFailed, "%s%s did not raise error" % (
	func.__name__, args)


	simple_err(struct.calcsize, 'Z')

	sz = struct.calcsize('i')
	if sz * 3 != struct.calcsize('iii'):
	raise TestFailed, 'inconsistent sizes'

	fmt = 'cbxxxxxxhhhhiillffd'
	fmt3 = '3c3b18x12h6i6l6f3d'
	sz = struct.calcsize(fmt)
	sz3 = struct.calcsize(fmt3)
	if sz * 3 != sz3:
	raise TestFailed, 'inconsistent sizes (3%s -> 3%d = %d, %s -> %d)' % (
	`fmt`, sz, 3*sz, `fmt3`, sz3)

	simple_err(struct.pack, 'iii', 3)
	simple_err(struct.pack, 'i', 3, 3, 3)
	simple_err(struct.pack, 'i', 'foo')
	simple_err(struct.unpack, 'd', 'flap')
	s = struct.pack('ii', 1, 2)
	simple_err(struct.unpack, 'iii', s)
	simple_err(struct.unpack, 'i', s)

	c = 'a'
	b = 1
	h = 255
	i = 65535
	l = 65536
	f = 3.1415
	d = 3.1415

	for prefix in ('', '@', '<', '>', '=', '!'):
	for format in ('xcbhilfd', 'xcBHILfd'):
	format = prefix + format
	if verbose:
	print "trying:", format
	s = struct.pack(format, c, b, h, i, l, f, d)
	cp, bp, hp, ip, lp, fp, dp = struct.unpack(format, s)
	if (cp != c or bp != b or hp != h or ip != i or lp != l or
	int(100 * fp) != int(100 * f) or int(100 * dp) != int(100 * d)):
	# ^^^ calculate only to two decimal places
	raise TestFailed, "unpack/pack not transitive (%s, %s)" % (
	str(format), str((cp, bp, hp, ip, lp, fp, dp)))

	# Test some of the new features in detail

	# (format, argument, big-endian result, little-endian result, asymmetric)
	tests = [
	('c', 'a', 'a', 'a', 0),
	('xc', 'a', '\0a', '\0a', 0),
	('cx', 'a', 'a\0', 'a\0', 0),
	('s', 'a', 'a', 'a', 0),
	('0s', 'helloworld', '', '', 1),
	('1s', 'helloworld', 'h', 'h', 1),
	('9s', 'helloworld', 'helloworl', 'helloworl', 1),
	('10s', 'helloworld', 'helloworld', 'helloworld', 0),
	('11s', 'helloworld', 'helloworld\0', 'helloworld\0', 1),
	('20s', 'helloworld', 'helloworld'+10'\0', 'helloworld'+10'\0', 1),
	('b', 7, '\7', '\7', 0),
	('b', -7, '\371', '\371', 0),
	('B', 7, '\7', '\7', 0),
	('B', 249, '\371', '\371', 0),
	('h', 700, '\002\274', '\274\002', 0),
	('h', -700, '\375D', 'D\375', 0),
	('H', 700, '\002\274', '\274\002', 0),
	('H', 0x10000-700, '\375D', 'D\375', 0),
	('i', 70000000, '\004,\035\200', '\200\035,\004', 0),
	('i', -70000000, '\373\323\342\200', '\200\342\323\373', 0),
	('I', 70000000L, '\004,\035\200', '\200\035,\004', 0),
	('I', 0x100000000L-70000000, '\373\323\342\200', '\200\342\323\373', 0),
	('l', 70000000, '\004,\035\200', '\200\035,\004', 0),
	('l', -70000000, '\373\323\342\200', '\200\342\323\373', 0),
	('L', 70000000L, '\004,\035\200', '\200\035,\004', 0),
	('L', 0x100000000L-70000000, '\373\323\342\200', '\200\342\323\373', 0),
	('f', 2.0, '@\000\000\000', '\000\000\000@', 0),
	('d', 2.0, '@\000\000\000\000\000\000\000',
	'\000\000\000\000\000\000\000@', 0),
	('f', -2.0, '\300\000\000\000', '\000\000\000\300', 0),
	('d', -2.0, '\300\000\000\000\000\000\000\000',
	'\000\000\000\000\000\000\000\300', 0),
	]

	for fmt, arg, big, lil, asy in tests:
	if verbose:
	print `fmt`, `arg`, `big`, `lil`
	for (xfmt, exp) in [('>'+fmt, big), ('!'+fmt, big), ('<'+fmt, lil),
	('='+fmt, ISBIGENDIAN and big or lil)]:
	res = struct.pack(xfmt, arg)
	if res != exp:
	raise TestFailed, "pack(%s, %s) -> %s # expected %s" % (
	`fmt`, `arg`, `res`, `exp`)
	n = struct.calcsize(xfmt)
	if n != len(res):
	raise TestFailed, "calcsize(%s) -> %d # expected %d" % (
	`xfmt`, n, len(res))
	rev = struct.unpack(xfmt, res)[0]
	if rev != arg and not asy:
	raise TestFailed, "unpack(%s, %s) -> (%s,) # expected (%s,)" % (
	`fmt`, `res`, `rev`, `arg`)

	###########################################################################
	# Simple native q/Q tests.

	has_native_qQ = 1
	try:
	struct.pack("q", 5)
	except struct.error:
	has_native_qQ = 0

	if verbose:
	print "Platform has native q/Q?", has_native_qQ and "Yes." or "No."

	any_err(struct.pack, "Q", -1) # can't pack -1 as unsigned regardless
	simple_err(struct.pack, "q", "a") # can't pack string as 'q' regardless
	simple_err(struct.pack, "Q", "a") # ditto, but 'Q'

	def test_native_qQ():
	bytes = struct.calcsize('q')
	# The expected values here are in big-endian format, primarily because
	# I'm on a little-endian machine and so this is the clearest way (for
	# me) to force the code to get exercised.
	for format, input, expected in (
	('q', -1, '\xff' * bytes),
	('q', 0, '\x00' * bytes),
	('Q', 0, '\x00' * bytes),
	('q', 1L, '\x00' * (bytes-1) + '\x01'),
	('Q', (1L << (8bytes))-1, '\xff' bytes),
	('q', (1L << (8bytes-1))-1, '\x7f' + '\xff' (bytes - 1))):
	got = struct.pack(format, input)
	native_expected = bigendian_to_native(expected)
	verify(got == native_expected,
	"%r-pack of %r gave %r, not %r" %
	(format, input, got, native_expected))
	retrieved = struct.unpack(format, got)[0]
	verify(retrieved == input,
	"%r-unpack of %r gave %r, not %r" %
	(format, got, retrieved, input))

	if has_native_qQ:
	test_native_qQ()

	###########################################################################
	# Standard integer tests (bBhHiIlLqQ).

	import binascii

	class IntTester:

	# XXX Most std integer modes fail to test for out-of-range.
	# The "i" and "l" codes appear to range-check OK on 32-bit boxes, but
	# fail to check correctly on some 64-bit ones (Tru64 Unix + Compaq C
	# reported by Mark Favas).
	BUGGY_RANGE_CHECK = "bBhHiIlL"

	def __init__(self, formatpair, bytesize):
	assert len(formatpair) == 2
	self.formatpair = formatpair
	for direction in "<>!=":
	for code in formatpair:
	format = direction + code
	verify(struct.calcsize(format) == bytesize)
	self.bytesize = bytesize
	self.bitsize = bytesize * 8
	self.signed_code, self.unsigned_code = formatpair
	self.unsigned_min = 0
	self.unsigned_max = 2L**self.bitsize - 1
	self.signed_min = -(2L**(self.bitsize-1))
	self.signed_max = 2L**(self.bitsize-1) - 1

	def test_one(self, x, pack=struct.pack,
	unpack=struct.unpack,
	unhexlify=binascii.unhexlify):
	if verbose:
	print "trying std", self.formatpair, "on", x, "==", hex(x)

	# Try signed.
	code = self.signed_code
	if self.signed_min <= x <= self.signed_max:
	# Try big-endian.
	expected = long(x)
	if x < 0:
	expected += 1L << self.bitsize
	assert expected > 0
	expected = hex(expected)[2:-1] # chop "0x" and trailing 'L'
	if len(expected) & 1:
	expected = "0" + expected
	expected = unhexlify(expected)
	expected = "\x00" * (self.bytesize - len(expected)) + expected

	# Pack work?
	format = ">" + code
	got = pack(format, x)
	verify(got == expected,
	"'%s'-pack of %r gave %r, not %r" %
	(format, x, got, expected))

	# Unpack work?
	retrieved = unpack(format, got)[0]
	verify(x == retrieved,
	"'%s'-unpack of %r gave %r, not %r" %
	(format, got, retrieved, x))

	# Adding any byte should cause a "too big" error.
	any_err(unpack, format, '\x01' + got)

	# Try little-endian.
	format = "<" + code
	expected = string_reverse(expected)

	# Pack work?
	got = pack(format, x)
	verify(got == expected,
	"'%s'-pack of %r gave %r, not %r" %
	(format, x, got, expected))

	# Unpack work?
	retrieved = unpack(format, got)[0]
	verify(x == retrieved,
	"'%s'-unpack of %r gave %r, not %r" %
	(format, got, retrieved, x))

	# Adding any byte should cause a "too big" error.
	any_err(unpack, format, '\x01' + got)

	else:
	# x is out of range -- verify pack realizes that.
	if code in self.BUGGY_RANGE_CHECK:
	if verbose:
	print "Skipping buggy range check for code", code
	else:
	any_err(pack, ">" + code, x)
	any_err(pack, "<" + code, x)

	# Much the same for unsigned.
	code = self.unsigned_code
	if self.unsigned_min <= x <= self.unsigned_max:
	# Try big-endian.
	format = ">" + code
	expected = long(x)
	expected = hex(expected)[2:-1] # chop "0x" and trailing 'L'
	if len(expected) & 1:
	expected = "0" + expected
	expected = unhexlify(expected)
	expected = "\x00" * (self.bytesize - len(expected)) + expected

	# Pack work?
	got = pack(format, x)
	verify(got == expected,
	"'%s'-pack of %r gave %r, not %r" %
	(format, x, got, expected))

	# Unpack work?
	retrieved = unpack(format, got)[0]
	verify(x == retrieved,
	"'%s'-unpack of %r gave %r, not %r" %
	(format, got, retrieved, x))

	# Adding any byte should cause a "too big" error.
	any_err(unpack, format, '\x01' + got)

	# Try little-endian.
	format = "<" + code
	expected = string_reverse(expected)

	# Pack work?
	got = pack(format, x)
	verify(got == expected,
	"'%s'-pack of %r gave %r, not %r" %
	(format, x, got, expected))

	# Unpack work?
	retrieved = unpack(format, got)[0]
	verify(x == retrieved,
	"'%s'-unpack of %r gave %r, not %r" %
	(format, got, retrieved, x))

	# Adding any byte should cause a "too big" error.
	any_err(unpack, format, '\x01' + got)

	else:
	# x is out of range -- verify pack realizes that.
	if code in self.BUGGY_RANGE_CHECK:
	if verbose:
	print "Skipping buggy range check for code", code
	else:
	any_err(pack, ">" + code, x)
	any_err(pack, "<" + code, x)

	def run(self):
	from random import randrange

	# Create all interesting powers of 2.
	values = []
	for exp in range(self.bitsize + 3):
	values.append(1L << exp)

	# Add some random values.
	for i in range(self.bitsize):
	val = 0L
	for j in range(self.bytesize):
	val = (val << 8) \| randrange(256)
	values.append(val)

	# Try all those, and their negations, and +-1 from them. Note
	# that this tests all power-of-2 boundaries in range, and a few out
	# of range, plus +-(2**n +- 1).
	for base in values:
	for val in -base, base:
	for incr in -1, 0, 1:
	x = val + incr
	try:
	x = int(x)
	except OverflowError:
	pass
	self.test_one(x)

	# Some error cases.
	for direction in "<>":
	for code in self.formatpair:
	for badobject in "a string", 3+42j, randrange:
	any_err(struct.pack, direction + code, badobject)

	for args in [("bB", 1),
	("hH", 2),
	("iI", 4),
	("lL", 4),
	("qQ", 8)]:
	t = IntTester(*args)
	t.run()


	###########################################################################
	# The p ("Pascal string") code.

	def test_p_code():
	for code, input, expected, expectedback in [
	('p','abc', '\x00', ''),
	('1p', 'abc', '\x00', ''),
	('2p', 'abc', '\x01a', 'a'),
	('3p', 'abc', '\x02ab', 'ab'),
	('4p', 'abc', '\x03abc', 'abc'),
	('5p', 'abc', '\x03abc\x00', 'abc'),
	('6p', 'abc', '\x03abc\x00\x00', 'abc'),
	('1000p', 'x'1000, '\xff' + 'x'999, 'x'*255)]:
	got = struct.pack(code, input)
	if got != expected:
	raise TestFailed("pack(%r, %r) == %r but expected %r" %
	(code, input, got, expected))
	(got,) = struct.unpack(code, got)
	if got != expectedback:
	raise TestFailed("unpack(%r, %r) == %r but expected %r" %
	(code, input, got, expectedback))

	test_p_code()


	###########################################################################
	# SF bug 705836. "<f" and ">f" had a severe rounding bug, where a carry
	# from the low-order discarded bits could propagate into the exponent
	# field, causing the result to be wrong by a factor of 2.

	def test_705836():
	import math

	for base in range(1, 33):
	# smaller <- largest representable float less than base.
	delta = 0.5
	while base - delta / 2.0 != base:
	delta /= 2.0
	smaller = base - delta
	# Packing this rounds away a solid string of trailing 1 bits.
	packed = struct.pack("<f", smaller)
	unpacked = struct.unpack("<f", packed)[0]
	# This failed at base = 2, 4, and 32, with unpacked = 1, 2, and
	# 16, respectively.
	verify(base == unpacked)
	bigpacked = struct.pack(">f", smaller)
	verify(bigpacked == string_reverse(packed),
	">f pack should be byte-reversal of <f pack")
	unpacked = struct.unpack(">f", bigpacked)[0]
	verify(base == unpacked)

	# Largest finite IEEE single.
	big = (1 << 24) - 1
	big = math.ldexp(big, 127 - 23)
	packed = struct.pack(">f", big)
	unpacked = struct.unpack(">f", packed)[0]
	verify(big == unpacked)

	# The same, but tack on a 1 bit so it rounds up to infinity.
	big = (1 << 25) - 1
	big = math.ldexp(big, 127 - 24)
	try:
	packed = struct.pack(">f", big)
	except OverflowError:
	pass
	else:
	TestFailed("expected OverflowError")

	test_705836()