Source code for netaddr.strategy.eui48

#-----------------------------------------------------------------------------
#   Copyright (c) 2008 by David P. D. Moss. All rights reserved.
#
#   Released under the BSD license. See the LICENSE file for details.
#-----------------------------------------------------------------------------
"""
IEEE 48-bit EUI (MAC address) logic.

Supports numerous MAC string formats including Cisco's triple hextet as well
as bare MACs containing no delimiters.
"""
import struct as _struct
import re as _re

#   Check whether we need to use fallback code or not.
try:
    from socket import AF_LINK
except ImportError:
    AF_LINK = 48

from netaddr.core import AddrFormatError
from netaddr.compat import _is_str
from netaddr.strategy import (
    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 = 48

#: The AF_* constant value of this address type.
family = AF_LINK

#: A friendly string name address type.
family_name = 'MAC'

#: The version of this address type.
version = 48

#: The maximum integer value that can be represented by this address type.
max_int = 2 ** width - 1

#-----------------------------------------------------------------------------
#   Dialect classes.
#-----------------------------------------------------------------------------

[docs]class mac_eui48(object): """A standard IEEE EUI-48 dialect class.""" #: The individual word size (in bits) of this address type. word_size = 8 #: 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 #: The separator character used between each word. word_sep = '-' #: The format string to be used when converting words to string values. word_fmt = '%.2X' #: The number base to be used when interpreting word values as integers. word_base = 16
[docs]class mac_unix(mac_eui48): """A UNIX-style MAC address dialect class.""" word_size = 8 num_words = width // word_size word_sep = ':' word_fmt = '%x' word_base = 16
class mac_unix_expanded(mac_unix): """A UNIX-style MAC address dialect class with leading zeroes.""" word_fmt = '%.2x'
[docs]class mac_cisco(mac_eui48): """A Cisco 'triple hextet' MAC address dialect class.""" word_size = 16 num_words = width // word_size word_sep = '.' word_fmt = '%.4x' word_base = 16
[docs]class mac_bare(mac_eui48): """A bare (no delimiters) MAC address dialect class.""" word_size = 48 num_words = width // word_size word_sep = '' word_fmt = '%.12X' word_base = 16
[docs]class mac_pgsql(mac_eui48): """A PostgreSQL style (2 x 24-bit words) MAC address dialect class.""" word_size = 24 num_words = width // word_size word_sep = ':' word_fmt = '%.6x' word_base = 16
#: The default dialect to be used when not specified by the user. DEFAULT_DIALECT = mac_eui48 #----------------------------------------------------------------------------- #: Regular expressions to match all supported MAC address formats. RE_MAC_FORMATS = ( # 2 bytes x 6 (UNIX, Windows, EUI-48) '^' + ':'.join(['([0-9A-F]{1,2})'] * 6) + '$', '^' + '-'.join(['([0-9A-F]{1,2})'] * 6) + '$', # 4 bytes x 3 (Cisco) '^' + ':'.join(['([0-9A-F]{1,4})'] * 3) + '$', '^' + '-'.join(['([0-9A-F]{1,4})'] * 3) + '$', '^' + '\.'.join(['([0-9A-F]{1,4})'] * 3) + '$', # 6 bytes x 2 (PostgreSQL) '^' + '-'.join(['([0-9A-F]{5,6})'] * 2) + '$', '^' + ':'.join(['([0-9A-F]{5,6})'] * 2) + '$', # 12 bytes (bare, no delimiters) '^(' + ''.join(['[0-9A-F]'] * 12) + ')$', '^(' + ''.join(['[0-9A-F]'] * 11) + ')$', ) # For efficiency, each string regexp converted in place to its compiled # counterpart. RE_MAC_FORMATS = [_re.compile(_, _re.IGNORECASE) for _ in RE_MAC_FORMATS] def valid_str(addr): """ :param addr: An IEEE EUI-48 (MAC) address in string form. :return: ``True`` if MAC address string is valid, ``False`` otherwise. """ for regexp in RE_MAC_FORMATS: try: match_result = regexp.findall(addr) if len(match_result) != 0: return True except TypeError: pass return False def str_to_int(addr): """ :param addr: An IEEE EUI-48 (MAC) address in string form. :return: An unsigned integer that is equivalent to value represented by EUI-48/MAC string address formatted according to the dialect settings. """ words = [] if _is_str(addr): found_match = False for regexp in RE_MAC_FORMATS: match_result = regexp.findall(addr) if len(match_result) != 0: found_match = True if isinstance(match_result[0], tuple): words = match_result[0] else: words = (match_result[0],) break if not found_match: raise AddrFormatError('%r is not a supported MAC format!' % addr) else: raise TypeError('%r is not str() or unicode()!' % addr) int_val = None if len(words) == 6: # 2 bytes x 6 (UNIX, Windows, EUI-48) int_val = int(''.join(['%.2x' % int(w, 16) for w in words]), 16) elif len(words) == 3: # 4 bytes x 3 (Cisco) int_val = int(''.join(['%.4x' % int(w, 16) for w in words]), 16) elif len(words) == 2: # 6 bytes x 2 (PostgreSQL) int_val = int(''.join(['%.6x' % int(w, 16) for w in words]), 16) elif len(words) == 1: # 12 bytes (bare, no delimiters) int_val = int('%012x' % int(words[0], 16), 16) else: raise AddrFormatError('unexpected word count in MAC address %r!' % addr) return int_val def int_to_str(int_val, dialect=None): """ :param int_val: An unsigned integer. :param dialect: (optional) a Python class defining formatting options. :return: An IEEE EUI-48 (MAC) address string that is equivalent to unsigned integer formatted according to the dialect settings. """ if dialect is None: dialect = mac_eui48 words = int_to_words(int_val, dialect) tokens = [dialect.word_fmt % i for i in words] addr = dialect.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. """ return _struct.pack(">HI", int_val >> 32, int_val & 0xffffffff) 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('>6B', 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): if dialect is None: dialect = DEFAULT_DIALECT return _valid_words(words, dialect.word_size, dialect.num_words) def int_to_words(int_val, dialect=None): if dialect is None: dialect = DEFAULT_DIALECT return _int_to_words(int_val, dialect.word_size, dialect.num_words) def words_to_int(words, dialect=None): if dialect is None: dialect = DEFAULT_DIALECT return _words_to_int(words, dialect.word_size, dialect.num_words) def valid_bits(bits, dialect=None): if dialect is None: dialect = DEFAULT_DIALECT return _valid_bits(bits, width, dialect.word_sep) def bits_to_int(bits, dialect=None): if dialect is None: dialect = DEFAULT_DIALECT return _bits_to_int(bits, width, dialect.word_sep) def int_to_bits(int_val, dialect=None): if dialect is None: dialect = DEFAULT_DIALECT return _int_to_bits( int_val, dialect.word_size, dialect.num_words, dialect.word_sep) def valid_bin(bin_val, dialect=None): if dialect is None: dialect = DEFAULT_DIALECT 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)