netwatch.py/netaddr-0.7.10/netaddr/strategy/eui64.py

185 lines
5.9 KiB
Python

#-----------------------------------------------------------------------------
# Copyright (c) 2008-2012, David P. D. Moss. All rights reserved.
#
# Released under the BSD license. See the LICENSE file for details.
#-----------------------------------------------------------------------------
"""
IEEE 64-bit EUI (Extended Unique Indentifier) logic.
"""
import struct as _struct
import re as _re
# This is a fake constant that doesn't really exist. Here for completeness.
AF_EUI64 = 64
from netaddr.core import AddrFormatError
from netaddr.strategy import BYTES_TO_BITS as _BYTES_TO_BITS, \
valid_words as _valid_words, \
int_to_words as _int_to_words, \
words_to_int as _words_to_int, \
valid_bits as _valid_bits, \
bits_to_int as _bits_to_int, \
int_to_bits as _int_to_bits, \
valid_bin as _valid_bin, \
int_to_bin as _int_to_bin, \
bin_to_int as _bin_to_int
#: The width (in bits) of this address type.
width = 64
#: The individual word size (in bits) of this address type.
word_size = 8
#: The format string to be used when converting words to string values.
word_fmt = '%.2X'
#: The separator character used between each word.
word_sep = '-'
#: The AF_* constant value of this address type.
family = AF_EUI64
#: A friendly string name address type.
family_name = 'EUI-64'
#: The version of this address type.
version = 64
#: The number base to be used when interpreting word values as integers.
word_base = 16
#: The maximum integer value that can be represented by this address type.
max_int = 2 ** width - 1
#: The number of words in this address type.
num_words = width // word_size
#: The maximum integer value for an individual word in this address type.
max_word = 2 ** word_size - 1
#: Compiled regular expression for detecting value EUI-64 identifiers.
RE_EUI64_FORMAT = _re.compile('^' + '-'.join(['([0-9A-F]{1,2})'] * 8) + '$',
_re.IGNORECASE)
#-----------------------------------------------------------------------------
def valid_str(addr):
"""
:param addr: An IEEE EUI-64 indentifier in string form.
:return: ``True`` if EUI-64 indentifier is valid, ``False`` otherwise.
"""
try:
match_result = RE_EUI64_FORMAT.findall(addr)
if len(match_result) != 0:
return True
except TypeError:
pass
return False
#-----------------------------------------------------------------------------
def str_to_int(addr):
"""
:param addr: An IEEE EUI-64 indentifier in string form.
:return: An unsigned integer that is equivalent to value represented
by EUI-64 string identifier.
"""
words = []
try:
match_result = RE_EUI64_FORMAT.findall(addr)
if not match_result:
raise TypeError
except TypeError:
raise AddrFormatError('invalid IEEE EUI-64 identifier: %r!' % addr)
words = match_result[0]
if len(words) != num_words:
raise AddrFormatError('bad word count for EUI-64 identifier: %r!' \
% addr)
return int(''.join(['%.2x' % int(w, 16) for w in words]), 16)
#-----------------------------------------------------------------------------
def int_to_str(int_val, dialect=None):
"""
:param int_val: An unsigned integer.
:param dialect: (optional) a Python class defining formatting options
(Please Note - not currently in use).
:return: An IEEE EUI-64 identifier that is equivalent to unsigned integer.
"""
words = int_to_words(int_val)
tokens = [word_fmt % i for i in words]
addr = word_sep.join(tokens)
return addr
#-----------------------------------------------------------------------------
def int_to_packed(int_val):
"""
:param int_val: the integer to be packed.
:return: a packed string that is equivalent to value represented by an
unsigned integer.
"""
words = int_to_words(int_val)
return _struct.pack('>8B', *words)
#-----------------------------------------------------------------------------
def packed_to_int(packed_int):
"""
:param packed_int: a packed string containing an unsigned integer.
It is assumed that string is packed in network byte order.
:return: An unsigned integer equivalent to value of network address
represented by packed binary string.
"""
words = list(_struct.unpack('>8B', packed_int))
int_val = 0
for i, num in enumerate(reversed(words)):
word = num
word = word << 8 * i
int_val = int_val | word
return int_val
#-----------------------------------------------------------------------------
def valid_words(words, dialect=None):
return _valid_words(words, word_size, num_words)
#-----------------------------------------------------------------------------
def int_to_words(int_val, dialect=None):
return _int_to_words(int_val, word_size, num_words)
#-----------------------------------------------------------------------------
def words_to_int(words, dialect=None):
return _words_to_int(words, word_size, num_words)
#-----------------------------------------------------------------------------
def valid_bits(bits, dialect=None):
return _valid_bits(bits, width, word_sep)
#-----------------------------------------------------------------------------
def bits_to_int(bits, dialect=None):
return _bits_to_int(bits, width, word_sep)
#-----------------------------------------------------------------------------
def int_to_bits(int_val, dialect=None):
return _int_to_bits(int_val, word_size, num_words, word_sep)
#-----------------------------------------------------------------------------
def valid_bin(bin_val):
return _valid_bin(bin_val, width)
#-----------------------------------------------------------------------------
def int_to_bin(int_val):
return _int_to_bin(int_val, width)
#-----------------------------------------------------------------------------
def bin_to_int(bin_val):
return _bin_to_int(bin_val, width)