# meid.py - functions for handling Mobile Equipment Identifiers (MEIDs) # # Copyright (C) 2010-2017 Arthur de Jong # # This library is free software; you can redistribute it and/or # modify it under the terms of the GNU Lesser General Public # License as published by the Free Software Foundation; either # version 2.1 of the License, or (at your option) any later version. # # This library is distributed in the hope that it will be useful, # but WITHOUT ANY WARRANTY; without even the implied warranty of # MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU # Lesser General Public License for more details. # # You should have received a copy of the GNU Lesser General Public # License along with this library; if not, write to the Free Software # Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA # 02110-1301 USA """MEID (Mobile Equipment Identifier). The Mobile Equipment Identifier is used to identify a physical piece of CDMA mobile station equipment. >>> validate('AF 01 23 45 0A BC DE C') 'AF0123450ABCDE' >>> validate('29360 87365 0070 3710 0') 'AF0123450ABCDE' >>> validate('29360 87365 0070 3710 0', strip_check_digit=False) 'AF0123450ABCDEC' >>> validate('29360 87365 0070 3710 1') Traceback (most recent call last): ... InvalidChecksum: ... >>> format('af0123450abcDEC', add_check_digit=True) 'AF 01 23 45 0A BC DE C' >>> format('af0123450abcDEC', format='dec', add_check_digit=True) '29360 87365 0070 3710 0' """ from stdnum.exceptions import * from stdnum.util import clean _hex_alphabet = '0123456789ABCDEF' def _cleanup(number): """Remove any grouping information from the number and removes surrounding whitespace.""" return clean(number, ' -').strip().upper() def _ishex(number): for x in number: if x not in _hex_alphabet: return False return True def _parse(number): number = _cleanup(number) if len(number) in (14, 15): # 14 or 15 digit hex representation if not _ishex(number): raise InvalidFormat() return number[0:14], number[14:] elif len(number) in (18, 19): # 18-digit decimal representation if not number.isdigit(): raise InvalidFormat() return number[0:18], number[18:] else: raise InvalidLength() def calc_check_digit(number): """Calculate the check digit for the number. The number should not already have a check digit.""" # both the 18-digit decimal format and the 14-digit hex format # containing only decimal digits should use the decimal Luhn check from stdnum import luhn if number.isdigit(): return luhn.calc_check_digit(number) else: return luhn.calc_check_digit(number, alphabet=_hex_alphabet) def compact(number, strip_check_digit=True): """Convert the MEID number to the minimal (hexadecimal) representation. This strips grouping information, removes surrounding whitespace and converts to hexadecimal if needed. If the check digit is to be preserved and conversion is done a new check digit is recalculated.""" # first parse the number number, cd = _parse(number) # strip check digit if needed if strip_check_digit: cd = '' # convert to hex if needed if len(number) == 18: number = '%08X%06X' % (int(number[0:10]), int(number[10:18])) if cd: cd = calc_check_digit(number) # put parts back together again return number + cd def _bit_length(n): """Return the number of bits necessary to store the number in binary.""" try: return n.bit_length() except AttributeError: # pragma: no cover (Python 2.6 only) import math return int(math.log(n, 2)) + 1 def validate(number, strip_check_digit=True): """Check if the number is a valid MEID number. This converts the representation format of the number (if it is decimal it is not converted to hexadecimal).""" from stdnum import luhn # first parse the number number, cd = _parse(number) if len(number) == 18: # decimal format can be easily determined if cd: luhn.validate(number + cd) # convert to hex manufacturer_code = int(number[0:10]) serial_num = int(number[10:18]) if _bit_length(manufacturer_code) > 32 or _bit_length(serial_num) > 24: raise InvalidComponent() number = '%08X%06X' % (manufacturer_code, serial_num) cd = calc_check_digit(number) elif number.isdigit(): # if the remaining hex format is fully decimal it is an IMEI number from stdnum import imei imei.validate(number + cd) else: # normal hex Luhn validation if cd: luhn.validate(number + cd, alphabet=_hex_alphabet) if strip_check_digit: cd = '' return number + cd def is_valid(number): """Check if the number is a valid MEID number.""" try: return bool(validate(number)) except ValidationError: return False def format(number, separator=' ', format=None, add_check_digit=False): """Reformat the number to the standard presentation format. The separator used can be provided. If the format is specified (either 'hex' or 'dec') the number is reformatted in that format, otherwise the current representation is kept. If add_check_digit is True a check digit will be added if it is not present yet.""" # first parse the number number, cd = _parse(number) # format conversions if needed if format == 'dec' and len(number) == 14: # convert to decimal number = '%010d%08d' % (int(number[0:8], 16), int(number[8:14], 16)) if cd: cd = calc_check_digit(number) elif format == 'hex' and len(number) == 18: # convert to hex number = '%08X%06X' % (int(number[0:10]), int(number[10:18])) if cd: cd = calc_check_digit(number) # see if we need to add a check digit if add_check_digit and not cd: cd = calc_check_digit(number) # split number according to format if len(number) == 14: number = [number[i * 2:i * 2 + 2] for i in range(7)] + [cd] else: number = (number[:5], number[5:10], number[10:14], number[14:], cd) return separator.join(x for x in number if x) def to_binary(number): """Convert the number to its binary representation (without the check digit).""" from binascii import a2b_hex return a2b_hex(compact(number, strip_check_digit=True)) def to_pseudo_esn(number): """Convert the provided MEID to a pseudo ESN (pESN). The ESN is returned in compact hexadecimal representation.""" import hashlib # return the last 6 digits of the SHA1 hash prefixed with the reserved # manufacturer code return '80' + hashlib.sha1(to_binary(number)).hexdigest()[-6:].upper()