Demo/rpc/xdr.py - platform/external/python/cpython3 - Gitiles

 # Implement (a subset of) Sun XDR -- RFC1014.


 try:
 	import struct
 except ImportError:
 	struct = None


 Long = type(0L)


 class Packer:

 	def __init__(self):
 		self.reset()

 	def reset(self):
 		self.buf = ''

 	def get_buf(self):
 		return self.buf

 	def pack_uint(self, x):
 		self.buf = self.buf + \
 			(chr(int(x>>24 & 0xff)) + chr(int(x>>16 & 0xff)) + \
 			 chr(int(x>>8 & 0xff)) + chr(int(x & 0xff)))
 	if struct and struct.pack('l', 1) == '\0\0\0\1':
 		def pack_uint(self, x):
 			if type(x) == Long:
 				x = int((x + 0x80000000L) % 0x100000000L \
 					   - 0x80000000L)
 			self.buf = self.buf + struct.pack('l', x)

 	pack_int = pack_uint

 	pack_enum = pack_int

 	def pack_bool(self, x):
 		if x: self.buf = self.buf + '\0\0\0\1'
 		else: self.buf = self.buf + '\0\0\0\0'

 	def pack_uhyper(self, x):
 		self.pack_uint(int(x>>32 & 0xffffffff))
 		self.pack_uint(int(x & 0xffffffff))

 	pack_hyper = pack_uhyper

 	def pack_float(self, x):
 		# XXX
 		self.buf = self.buf + struct.pack('f', x)

 	def pack_double(self, x):
 		# XXX
 		self.buf = self.buf + struct.pack('d', x)

 	def pack_fstring(self, n, s):
 		if n < 0:
 			raise ValueError, 'fstring size must be nonnegative'
 		n = ((n+3)/4)*4
 		data = s[:n]
 		data = data + (n - len(data)) * '\0'
 		self.buf = self.buf + data

 	pack_fopaque = pack_fstring

 	def pack_string(self, s):
 		n = len(s)
 		self.pack_uint(n)
 		self.pack_fstring(n, s)

 	pack_opaque = pack_string

 	def pack_list(self, list, pack_item):
 		for item in list:
 			self.pack_uint(1)
 			pack_item(item)
 		self.pack_uint(0)

 	def pack_farray(self, n, list, pack_item):
 		if len(list) <> n:
 			raise ValueError, 'wrong array size'
 		for item in list:
 			pack_item(item)

 	def pack_array(self, list, pack_item):
 		n = len(list)
 		self.pack_uint(n)
 		self.pack_farray(n, list, pack_item)


 class Unpacker:

 	def __init__(self, data):
 		self.reset(data)

 	def reset(self, data):
 		self.buf = data
 		self.pos = 0

 	def done(self):
 		if self.pos < len(self.buf):
 			raise RuntimeError, 'unextracted data remains'

 	def unpack_uint(self):
 		i = self.pos
 		self.pos = j = i+4
 		data = self.buf[i:j]
 		if len(data) < 4:
 			raise EOFError
 		x = long(ord(data[0]))<<24 | ord(data[1])<<16 | \
 			ord(data[2])<<8 | ord(data[3])
 		# Return a Python long only if the value is not representable
 		# as a nonnegative Python int
 		if x < 0x80000000L: x = int(x)
 		return x
 	if struct and struct.unpack('l', '\0\0\0\1') == 1:
 		def unpack_uint(self):
 			i = self.pos
 			self.pos = j = i+4
 			data = self.buf[i:j]
 			if len(data) < 4:
 				raise EOFError
 			return struct.unpack('l', data)

 	def unpack_int(self):
 		x = self.unpack_uint()
 		if x >= 0x80000000L: x = x - 0x100000000L
 		return int(x)

 	unpack_enum = unpack_int

 	unpack_bool = unpack_int

 	def unpack_uhyper(self):
 		hi = self.unpack_uint()
 		lo = self.unpack_uint()
 		return long(hi)<<32 | lo

 	def unpack_hyper(self):
 		x = self.unpack_uhyper()
 		if x >= 0x8000000000000000L: x = x - 0x10000000000000000L
 		return x

 	def unpack_float(self):
 		# XXX
 		i = self.pos
 		self.pos = j = i+4
 		data = self.buf[i:j]
 		if len(data) < 4:
 			raise EOFError
 		return struct.unpack('f', data)[0]

 	def unpack_double(self):
 		# XXX
 		i = self.pos
 		self.pos = j = i+8
 		data = self.buf[i:j]
 		if len(data) < 8:
 			raise EOFError
 		return struct.unpack('d', data)[0]

 	def unpack_fstring(self, n):
 		if n < 0:
 			raise ValueError, 'fstring size must be nonnegative'
 		i = self.pos
 		j = i + (n+3)/4*4
 		if j > len(self.buf):
 			raise EOFError
 		self.pos = j
 		return self.buf[i:i+n]

 	unpack_fopaque = unpack_fstring

 	def unpack_string(self):
 		n = self.unpack_uint()
 		return self.unpack_fstring(n)

 	unpack_opaque = unpack_string

 	def unpack_list(self, unpack_item):
 		list = []
 		while 1:
 			x = self.unpack_uint()
 			if x == 0: break
 			if x <> 1:
 				raise RuntimeError, \
 					'0 or 1 expected, got ' + `x`
 			item = unpack_item()
 			list.append(item)
 		return list

 	def unpack_farray(self, n, unpack_item):
 		list = []
 		for i in range(n):
 			list.append(unpack_item())
 		return list

 	def unpack_array(self, unpack_item):
 		n = self.unpack_uint()
 		return self.unpack_farray(n, unpack_item)
	# Implement (a subset of) Sun XDR -- RFC1014.


	try:
	import struct
	except ImportError:
	struct = None


	Long = type(0L)


	class Packer:

	def __init__(self):
	self.reset()

	def reset(self):
	self.buf = ''

	def get_buf(self):
	return self.buf

	def pack_uint(self, x):
	self.buf = self.buf + \
	(chr(int(x>>24 & 0xff)) + chr(int(x>>16 & 0xff)) + \
	chr(int(x>>8 & 0xff)) + chr(int(x & 0xff)))
	if struct and struct.pack('l', 1) == '\0\0\0\1':
	def pack_uint(self, x):
	if type(x) == Long:
	x = int((x + 0x80000000L) % 0x100000000L \
	- 0x80000000L)
	self.buf = self.buf + struct.pack('l', x)

	pack_int = pack_uint

	pack_enum = pack_int

	def pack_bool(self, x):
	if x: self.buf = self.buf + '\0\0\0\1'
	else: self.buf = self.buf + '\0\0\0\0'

	def pack_uhyper(self, x):
	self.pack_uint(int(x>>32 & 0xffffffff))
	self.pack_uint(int(x & 0xffffffff))

	pack_hyper = pack_uhyper

	def pack_float(self, x):
	# XXX
	self.buf = self.buf + struct.pack('f', x)

	def pack_double(self, x):
	# XXX
	self.buf = self.buf + struct.pack('d', x)

	def pack_fstring(self, n, s):
	if n < 0:
	raise ValueError, 'fstring size must be nonnegative'
	n = ((n+3)/4)*4
	data = s[:n]
	data = data + (n - len(data)) * '\0'
	self.buf = self.buf + data

	pack_fopaque = pack_fstring

	def pack_string(self, s):
	n = len(s)
	self.pack_uint(n)
	self.pack_fstring(n, s)

	pack_opaque = pack_string

	def pack_list(self, list, pack_item):
	for item in list:
	self.pack_uint(1)
	pack_item(item)
	self.pack_uint(0)

	def pack_farray(self, n, list, pack_item):
	if len(list) <> n:
	raise ValueError, 'wrong array size'
	for item in list:
	pack_item(item)

	def pack_array(self, list, pack_item):
	n = len(list)
	self.pack_uint(n)
	self.pack_farray(n, list, pack_item)


	class Unpacker:

	def __init__(self, data):
	self.reset(data)

	def reset(self, data):
	self.buf = data
	self.pos = 0

	def done(self):
	if self.pos < len(self.buf):
	raise RuntimeError, 'unextracted data remains'

	def unpack_uint(self):
	i = self.pos
	self.pos = j = i+4
	data = self.buf[i:j]
	if len(data) < 4:
	raise EOFError
	x = long(ord(data[0]))<<24 \| ord(data[1])<<16 \| \
	ord(data[2])<<8 \| ord(data[3])
	# Return a Python long only if the value is not representable
	# as a nonnegative Python int
	if x < 0x80000000L: x = int(x)
	return x
	if struct and struct.unpack('l', '\0\0\0\1') == 1:
	def unpack_uint(self):
	i = self.pos
	self.pos = j = i+4
	data = self.buf[i:j]
	if len(data) < 4:
	raise EOFError
	return struct.unpack('l', data)

	def unpack_int(self):
	x = self.unpack_uint()
	if x >= 0x80000000L: x = x - 0x100000000L
	return int(x)

	unpack_enum = unpack_int

	unpack_bool = unpack_int

	def unpack_uhyper(self):
	hi = self.unpack_uint()
	lo = self.unpack_uint()
	return long(hi)<<32 \| lo

	def unpack_hyper(self):
	x = self.unpack_uhyper()
	if x >= 0x8000000000000000L: x = x - 0x10000000000000000L
	return x

	def unpack_float(self):
	# XXX
	i = self.pos
	self.pos = j = i+4
	data = self.buf[i:j]
	if len(data) < 4:
	raise EOFError
	return struct.unpack('f', data)[0]

	def unpack_double(self):
	# XXX
	i = self.pos
	self.pos = j = i+8
	data = self.buf[i:j]
	if len(data) < 8:
	raise EOFError
	return struct.unpack('d', data)[0]

	def unpack_fstring(self, n):
	if n < 0:
	raise ValueError, 'fstring size must be nonnegative'
	i = self.pos
	j = i + (n+3)/4*4
	if j > len(self.buf):
	raise EOFError
	self.pos = j
	return self.buf[i:i+n]

	unpack_fopaque = unpack_fstring

	def unpack_string(self):
	n = self.unpack_uint()
	return self.unpack_fstring(n)

	unpack_opaque = unpack_string

	def unpack_list(self, unpack_item):
	list = []
	while 1:
	x = self.unpack_uint()
	if x == 0: break
	if x <> 1:
	raise RuntimeError, \
	'0 or 1 expected, got ' + `x`
	item = unpack_item()
	list.append(item)
	return list

	def unpack_farray(self, n, unpack_item):
	list = []
	for i in range(n):
	list.append(unpack_item())
	return list

	def unpack_array(self, unpack_item):
	n = self.unpack_uint()
	return self.unpack_farray(n, unpack_item)