# -*- coding: utf-8 -*- """ pySim: various utilities """ import json from io import BytesIO from typing import Optional, List, Dict, Any, Tuple # Copyright (C) 2009-2010 Sylvain Munaut # Copyright (C) 2021 Harald Welte # # This program is free software: you can redistribute it and/or modify # it under the terms of the GNU General Public License as published by # the Free Software Foundation, either version 2 of the License, or # (at your option) any later version. # # This program 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 General Public License for more details. # # You should have received a copy of the GNU General Public License # along with this program. If not, see . # # just to differentiate strings of hex nibbles from everything else Hexstr = str def h2b(s:Hexstr) -> bytearray: """convert from a string of hex nibbles to a sequence of bytes""" return bytearray.fromhex(s) def b2h(b:bytearray) -> Hexstr: """convert from a sequence of bytes to a string of hex nibbles""" return ''.join(['%02x'%(x) for x in b]) def h2i(s:Hexstr) -> List[int]: """convert from a string of hex nibbles to a list of integers""" return [(int(x,16)<<4)+int(y,16) for x,y in zip(s[0::2], s[1::2])] def i2h(s:List[int]) -> Hexstr: """convert from a list of integers to a string of hex nibbles""" return ''.join(['%02x'%(x) for x in s]) def h2s(s:Hexstr) -> str: """convert from a string of hex nibbles to an ASCII string""" return ''.join([chr((int(x,16)<<4)+int(y,16)) for x,y in zip(s[0::2], s[1::2]) if int(x + y, 16) != 0xff]) def s2h(s:str) -> Hexstr: """convert from an ASCII string to a string of hex nibbles""" b = bytearray() b.extend(map(ord, s)) return b2h(b) # List of bytes to string def i2s(s:List[int]) -> str: """convert from a list of integers to an ASCII string""" return ''.join([chr(x) for x in s]) def swap_nibbles(s:Hexstr) -> Hexstr: """swap the nibbles in a hex string""" return ''.join([x+y for x,y in zip(s[1::2], s[0::2])]) def rpad(s:str, l:int, c='f') -> str: """pad string on the right side. Args: s : string to pad l : total length to pad to c : padding character Returns: String 's' padded with as many 'c' as needed to reach total length of 'l' """ return s + c * (l - len(s)) def lpad(s:str, l:int, c='f') -> str: """pad string on the left side. Args: s : string to pad l : total length to pad to c : padding character Returns: String 's' padded with as many 'c' as needed to reach total length of 'l' """ return c * (l - len(s)) + s def half_round_up(n:int) -> int: return (n + 1)//2 # IMSI encoded format: # For IMSI 0123456789ABCDE: # # | byte 1 | 2 upper | 2 lower | 3 upper | 3 lower | ... | 9 upper | 9 lower | # | length in bytes | 0 | odd/even | 2 | 1 | ... | E | D | # # If the IMSI is less than 15 characters, it should be padded with 'f' from the end. # # The length is the total number of bytes used to encoded the IMSI. This includes the odd/even # parity bit. E.g. an IMSI of length 14 is 8 bytes long, not 7, as it uses bytes 2 to 9 to # encode itself. # # Because of this, an odd length IMSI fits exactly into len(imsi) + 1 // 2 bytes, whereas an # even length IMSI only uses half of the last byte. def enc_imsi(imsi:str): """Converts a string IMSI into the encoded value of the EF""" l = half_round_up(len(imsi) + 1) # Required bytes - include space for odd/even indicator oe = len(imsi) & 1 # Odd (1) / Even (0) ei = '%02x' % l + swap_nibbles('%01x%s' % ((oe<<3)|1, rpad(imsi, 15))) return ei def dec_imsi(ef:Hexstr) -> Optional[str]: """Converts an EF value to the IMSI string representation""" if len(ef) < 4: return None l = int(ef[0:2], 16) * 2 # Length of the IMSI string l = l - 1 # Encoded length byte includes oe nibble swapped = swap_nibbles(ef[2:]).rstrip('f') if len(swapped) < 1: return None oe = (int(swapped[0])>>3) & 1 # Odd (1) / Even (0) if not oe: # if even, only half of last byte was used l = l-1 if l != len(swapped) - 1: return None imsi = swapped[1:] return imsi def dec_iccid(ef:Hexstr) -> str: return swap_nibbles(ef).strip('f') def enc_iccid(iccid:str) -> Hexstr: return swap_nibbles(rpad(iccid, 20)) def enc_plmn(mcc, mnc): """Converts integer MCC/MNC into 3 bytes for EF""" if len(mnc) == 2: mnc += "F" # pad to 3 digits if needed return (mcc[1] + mcc[0]) + (mnc[2] + mcc[2]) + (mnc[1] + mnc[0]) def dec_plmn(threehexbytes:Hexstr) -> dict: res = {'mcc': 0, 'mnc': 0 } res['mcc'] = dec_mcc_from_plmn(threehexbytes) res['mnc'] = dec_mnc_from_plmn(threehexbytes) return res def dec_spn(ef): byte1 = int(ef[0:2]) hplmn_disp = (byte1&0x01 == 0x01) oplmn_disp = (byte1&0x02 == 0x02) name = h2s(ef[2:]) return (name, hplmn_disp, oplmn_disp) def enc_spn(name, hplmn_disp=False, oplmn_disp=False): byte1 = 0x00 if hplmn_disp: byte1 = byte1|0x01 if oplmn_disp: byte1 = byte1|0x02 return i2h([byte1])+s2h(name) def hexstr_to_Nbytearr(s, nbytes): return [s[i:i+(nbytes*2)] for i in range(0, len(s), (nbytes*2)) ] # Accepts hex string representing three bytes def dec_mcc_from_plmn(plmn:Hexstr) -> int: ia = h2i(plmn) digit1 = ia[0] & 0x0F # 1st byte, LSB digit2 = (ia[0] & 0xF0) >> 4 # 1st byte, MSB digit3 = ia[1] & 0x0F # 2nd byte, LSB if digit3 == 0xF and digit2 == 0xF and digit1 == 0xF: return 0xFFF # 4095 return derive_mcc(digit1, digit2, digit3) def dec_mnc_from_plmn(plmn:Hexstr) -> int: ia = h2i(plmn) digit1 = ia[2] & 0x0F # 3rd byte, LSB digit2 = (ia[2] & 0xF0) >> 4 # 3rd byte, MSB digit3 = (ia[1] & 0xF0) >> 4 # 2nd byte, MSB if digit3 == 0xF and digit2 == 0xF and digit1 == 0xF: return 0xFFF # 4095 return derive_mnc(digit1, digit2, digit3) def dec_act(twohexbytes:Hexstr) -> List[str]: act_list = [ {'bit': 15, 'name': "UTRAN"}, {'bit': 14, 'name': "E-UTRAN"}, {'bit': 7, 'name': "GSM"}, {'bit': 6, 'name': "GSM COMPACT"}, {'bit': 5, 'name': "cdma2000 HRPD"}, {'bit': 4, 'name': "cdma2000 1xRTT"}, ] ia = h2i(twohexbytes) u16t = (ia[0] << 8)|ia[1] sel = [] for a in act_list: if u16t & (1 << a['bit']): sel.append(a['name']) return sel def dec_xplmn_w_act(fivehexbytes:Hexstr) -> Dict[str,Any]: res = {'mcc': 0, 'mnc': 0, 'act': []} plmn_chars = 6 act_chars = 4 plmn_str = fivehexbytes[:plmn_chars] # first three bytes (six ascii hex chars) act_str = fivehexbytes[plmn_chars:plmn_chars + act_chars] # two bytes after first three bytes res['mcc'] = dec_mcc_from_plmn(plmn_str) res['mnc'] = dec_mnc_from_plmn(plmn_str) res['act'] = dec_act(act_str) return res def format_xplmn_w_act(hexstr): s = "" for rec_data in hexstr_to_Nbytearr(hexstr, 5): rec_info = dec_xplmn_w_act(rec_data) if rec_info['mcc'] == 0xFFF and rec_info['mnc'] == 0xFFF: rec_str = "unused" else: rec_str = "MCC: %03d MNC: %03d AcT: %s" % (rec_info['mcc'], rec_info['mnc'], ", ".join(rec_info['act'])) s += "\t%s # %s\n" % (rec_data, rec_str) return s def dec_loci(hexstr): res = {'tmsi': '', 'mcc': 0, 'mnc': 0, 'lac': '', 'status': 0} res['tmsi'] = hexstr[:8] res['mcc'] = dec_mcc_from_plmn(hexstr[8:14]) res['mnc'] = dec_mnc_from_plmn(hexstr[8:14]) res['lac'] = hexstr[14:18] res['status'] = h2i(hexstr[20:22]) return res def dec_psloci(hexstr): res = {'p-tmsi': '', 'p-tmsi-sig': '', 'mcc': 0, 'mnc': 0, 'lac': '', 'rac': '', 'status': 0} res['p-tmsi'] = hexstr[:8] res['p-tmsi-sig'] = hexstr[8:14] res['mcc'] = dec_mcc_from_plmn(hexstr[14:20]) res['mnc'] = dec_mnc_from_plmn(hexstr[14:20]) res['lac'] = hexstr[20:24] res['rac'] = hexstr[24:26] res['status'] = h2i(hexstr[26:28]) return res def dec_epsloci(hexstr): res = {'guti': '', 'mcc': 0, 'mnc': 0, 'tac': '', 'status': 0} res['guti'] = hexstr[:24] res['tai'] = hexstr[24:34] res['mcc'] = dec_mcc_from_plmn(hexstr[24:30]) res['mnc'] = dec_mnc_from_plmn(hexstr[24:30]) res['tac'] = hexstr[30:34] res['status'] = h2i(hexstr[34:36]) return res def dec_xplmn(threehexbytes:Hexstr) -> dict: res = {'mcc': 0, 'mnc': 0, 'act': []} plmn_chars = 6 plmn_str = threehexbytes[:plmn_chars] # first three bytes (six ascii hex chars) res['mcc'] = dec_mcc_from_plmn(plmn_str) res['mnc'] = dec_mnc_from_plmn(plmn_str) return res def format_xplmn(hexstr:Hexstr) -> str: s = "" for rec_data in hexstr_to_Nbytearr(hexstr, 3): rec_info = dec_xplmn(rec_data) if rec_info['mcc'] == 0xFFF and rec_info['mnc'] == 0xFFF: rec_str = "unused" else: rec_str = "MCC: %03d MNC: %03d" % (rec_info['mcc'], rec_info['mnc']) s += "\t%s # %s\n" % (rec_data, rec_str) return s def derive_milenage_opc(ki_hex:Hexstr, op_hex:Hexstr) -> Hexstr: """ Run the milenage algorithm to calculate OPC from Ki and OP """ from Crypto.Cipher import AES from Crypto.Util.strxor import strxor from pySim.utils import b2h # We pass in hex string and now need to work on bytes ki_bytes = bytes(h2b(ki_hex)) op_bytes = bytes(h2b(op_hex)) aes = AES.new(ki_bytes, AES.MODE_ECB) opc_bytes = aes.encrypt(op_bytes) return b2h(strxor(opc_bytes, op_bytes)) def calculate_luhn(cc) -> int: """ Calculate Luhn checksum used in e.g. ICCID and IMEI """ num = list(map(int, str(cc))) check_digit = 10 - sum(num[-2::-2] + [sum(divmod(d * 2, 10)) for d in num[::-2]]) % 10 return 0 if check_digit == 10 else check_digit def mcc_from_imsi(imsi:str) -> Optional[str]: """ Derive the MCC (Mobile Country Code) from the first three digits of an IMSI """ if imsi == None: return None if len(imsi) > 3: return imsi[:3] else: return None def mnc_from_imsi(imsi:str, long:bool=False) -> Optional[str]: """ Derive the MNC (Mobile Country Code) from the 4th to 6th digit of an IMSI """ if imsi == None: return None if len(imsi) > 3: if long: return imsi[3:6] else: return imsi[3:5] else: return None def derive_mcc(digit1:int, digit2:int, digit3:int) -> int: """ Derive decimal representation of the MCC (Mobile Country Code) from three given digits. """ mcc = 0 if digit1 != 0x0f: mcc += digit1 * 100 if digit2 != 0x0f: mcc += digit2 * 10 if digit3 != 0x0f: mcc += digit3 return mcc def derive_mnc(digit1:int, digit2:int, digit3:int=0x0f) -> int: """ Derive decimal representation of the MNC (Mobile Network Code) from two or (optionally) three given digits. """ mnc = 0 # 3-rd digit is optional for the MNC. If present # the algorythm is the same as for the MCC. if digit3 != 0x0f: return derive_mcc(digit1, digit2, digit3) if digit1 != 0x0f: mnc += digit1 * 10 if digit2 != 0x0f: mnc += digit2 return mnc def dec_msisdn(ef_msisdn:Hexstr) -> Optional[Tuple[int,int,Optional[str]]]: """ Decode MSISDN from EF.MSISDN or EF.ADN (same structure). See 3GPP TS 31.102, section 4.2.26 and 4.4.2.3. """ # Convert from str to (kind of) 'bytes' ef_msisdn = h2b(ef_msisdn) # Make sure mandatory fields are present if len(ef_msisdn) < 14: raise ValueError("EF.MSISDN is too short") # Skip optional Alpha Identifier xlen = len(ef_msisdn) - 14 msisdn_lhv = ef_msisdn[xlen:] # Parse the length (in bytes) of the BCD encoded number bcd_len = msisdn_lhv[0] # BCD length = length of dial num (max. 10 bytes) + 1 byte ToN and NPI if bcd_len == 0xff: return None elif bcd_len > 11 or bcd_len < 1: raise ValueError("Length of MSISDN (%d bytes) is out of range" % bcd_len) # Parse ToN / NPI ton = (msisdn_lhv[1] >> 4) & 0x07 npi = msisdn_lhv[1] & 0x0f bcd_len -= 1 # No MSISDN? if not bcd_len: return (npi, ton, None) msisdn = swap_nibbles(b2h(msisdn_lhv[2:][:bcd_len])).rstrip('f') # International number 10.5.118/3GPP TS 24.008 if ton == 0x01: msisdn = '+' + msisdn return (npi, ton, msisdn) def enc_msisdn(msisdn:str, npi:int=0x01, ton:int=0x03) -> Hexstr: """ Encode MSISDN as LHV so it can be stored to EF.MSISDN. See 3GPP TS 31.102, section 4.2.26 and 4.4.2.3. Default NPI / ToN values: - NPI: ISDN / telephony numbering plan (E.164 / E.163), - ToN: network specific or international number (if starts with '+'). """ # Leading '+' indicates International Number if msisdn[0] == '+': msisdn = msisdn[1:] ton = 0x01 # Append 'f' padding if number of digits is odd if len(msisdn) % 2 > 0: msisdn += 'f' # BCD length also includes NPI/ToN header bcd_len = len(msisdn) // 2 + 1 npi_ton = (npi & 0x0f) | ((ton & 0x07) << 4) | 0x80 bcd = rpad(swap_nibbles(msisdn), 10 * 2) # pad to 10 octets return ('%02x' % bcd_len) + ('%02x' % npi_ton) + bcd def dec_st(st, table="sim") -> str: """ Parses the EF S/U/IST and prints the list of available services in EF S/U/IST """ if table == "isim": from pySim.ts_31_103 import EF_IST_map lookup_map = EF_IST_map elif table == "usim": from pySim.ts_31_102 import EF_UST_map lookup_map = EF_UST_map else: from pySim.ts_51_011 import EF_SST_map lookup_map = EF_SST_map st_bytes = [st[i:i+2] for i in range(0, len(st), 2) ] avail_st = "" # Get each byte and check for available services for i in range(0, len(st_bytes)): # Byte i contains info about Services num (8i+1) to num (8i+8) byte = int(st_bytes[i], 16) # Services in each byte are in order MSB to LSB # MSB - Service (8i+8) # LSB - Service (8i+1) for j in range(1, 9): if byte&0x01 == 0x01 and ((8*i) + j in lookup_map): # Byte X contains info about Services num (8X-7) to num (8X) # bit = 1: service available # bit = 0: service not available avail_st += '\tService %d - %s\n' % ((8*i) + j, lookup_map[(8*i) + j]) byte = byte >> 1 return avail_st def first_TLV_parser(bytelist): ''' first_TLV_parser([0xAA, 0x02, 0xAB, 0xCD, 0xFF, 0x00]) -> (170, 2, [171, 205]) parses first TLV format record in a list of bytelist returns a 3-Tuple: Tag, Length, Value Value is a list of bytes parsing of length is ETSI'style 101.220 ''' Tag = bytelist[0] if bytelist[1] == 0xFF: Len = bytelist[2]*256 + bytelist[3] Val = bytelist[4:4+Len] else: Len = bytelist[1] Val = bytelist[2:2+Len] return (Tag, Len, Val) def TLV_parser(bytelist): ''' TLV_parser([0xAA, ..., 0xFF]) -> [(T, L, [V]), (T, L, [V]), ...] loops on the input list of bytes with the "first_TLV_parser()" function returns a list of 3-Tuples ''' ret = [] while len(bytelist) > 0: T, L, V = first_TLV_parser(bytelist) if T == 0xFF: # padding bytes break ret.append( (T, L, V) ) # need to manage length of L if L > 0xFE: bytelist = bytelist[ L+4 : ] else: bytelist = bytelist[ L+2 : ] return ret def enc_st(st, service, state=1): """ Encodes the EF S/U/IST/EST and returns the updated Service Table Parameters: st - Current value of SIM/USIM/ISIM Service Table service - Service Number to encode as activated/de-activated state - 1 mean activate, 0 means de-activate Returns: s - Modified value of SIM/USIM/ISIM Service Table Default values: - state: 1 - Sets the particular Service bit to 1 """ st_bytes = [st[i:i+2] for i in range(0, len(st), 2) ] s = "" # Check whether the requested service is present in each byte for i in range(0, len(st_bytes)): # Byte i contains info about Services num (8i+1) to num (8i+8) if service in range((8*i) + 1, (8*i) + 9): byte = int(st_bytes[i], 16) # Services in each byte are in order MSB to LSB # MSB - Service (8i+8) # LSB - Service (8i+1) mod_byte = 0x00 # Copy bit by bit contents of byte to mod_byte with modified bit # for requested service for j in range(1, 9): mod_byte = mod_byte >> 1 if service == (8*i) + j: mod_byte = state == 1 and mod_byte|0x80 or mod_byte&0x7f else: mod_byte = byte&0x01 == 0x01 and mod_byte|0x80 or mod_byte&0x7f byte = byte >> 1 s += ('%02x' % (mod_byte)) else: s += st_bytes[i] return s def dec_addr_tlv(hexstr): """ Decode hex string to get EF.P-CSCF Address or EF.ePDGId or EF.ePDGIdEm. See 3GPP TS 31.102 version 13.4.0 Release 13, section 4.2.8, 4.2.102 and 4.2.104. """ # Convert from hex str to int bytes list addr_tlv_bytes = h2i(hexstr) s = "" # Get list of tuples containing parsed TLVs tlvs = TLV_parser(addr_tlv_bytes) for tlv in tlvs: # tlv = (T, L, [V]) # T = Tag # L = Length # [V] = List of value # Invalid Tag value scenario if tlv[0] != 0x80: continue # Empty field - Zero length if tlv[1] == 0: continue # First byte in the value has the address type addr_type = tlv[2][0] # TODO: Support parsing of IPv6 # Address Type: 0x00 (FQDN), 0x01 (IPv4), 0x02 (IPv6), other (Reserved) if addr_type == 0x00: #FQDN # Skip address tye byte i.e. first byte in value list content = tlv[2][1:] s += "\t%s # %s\n" % (i2h(content), i2s(content)) elif addr_type == 0x01: #IPv4 # Skip address tye byte i.e. first byte in value list # Skip the unused byte in Octect 4 after address type byte as per 3GPP TS 31.102 ipv4 = tlv[2][2:] content = '.'.join(str(x) for x in ipv4) s += "\t%s # %s\n" % (i2h(ipv4), content) return s def enc_addr_tlv(addr, addr_type='00'): """ Encode address TLV object used in EF.P-CSCF Address, EF.ePDGId and EF.ePDGIdEm. See 3GPP TS 31.102 version 13.4.0 Release 13, section 4.2.8, 4.2.102 and 4.2.104. Default values: - addr_type: 00 - FQDN format of Address """ s = "" # TODO: Encoding of IPv6 address if addr_type == '00': #FQDN hex_str = s2h(addr) s += '80' + ('%02x' % ((len(hex_str)//2)+1)) + '00' + hex_str elif addr_type == '01': #IPv4 ipv4_list = addr.split('.') ipv4_str = "" for i in ipv4_list: ipv4_str += ('%02x' % (int(i))) # Unused bytes shall be set to 'ff'. i.e 4th Octet after Address Type is not used # IPv4 Address is in octet 5 to octet 8 of the TLV data object s += '80' + ('%02x' % ((len(ipv4_str)//2)+2)) + '01' + 'ff' + ipv4_str return s def is_hex(string:str, minlen:int=2, maxlen:Optional[int]=None) -> bool: """ Check if a string is a valid hexstring """ # Filter obviously bad strings if not string: return False if len(string) < minlen or minlen < 2: return False if len(string) % 2: return False if maxlen and len(string) > maxlen: return False # Try actual encoding to be sure try: try_encode = h2b(string) return True except: return False def sanitize_pin_adm(pin_adm, pin_adm_hex = None) -> Hexstr: """ The ADM pin can be supplied either in its hexadecimal form or as ascii string. This function checks the supplied opts parameter and returns the pin_adm as hex encoded string, regardless in which form it was originally supplied by the user """ if pin_adm is not None: if len(pin_adm) <= 8: pin_adm = ''.join(['%02x'%(ord(x)) for x in pin_adm]) pin_adm = rpad(pin_adm, 16) else: raise ValueError("PIN-ADM needs to be <=8 digits (ascii)") if pin_adm_hex is not None: if len(pin_adm_hex) == 16: pin_adm = pin_adm_hex # Ensure that it's hex-encoded try: try_encode = h2b(pin_adm) except ValueError: raise ValueError("PIN-ADM needs to be hex encoded using this option") else: raise ValueError("PIN-ADM needs to be exactly 16 digits (hex encoded)") return pin_adm def enc_ePDGSelection(hexstr, mcc, mnc, epdg_priority='0001', epdg_fqdn_format='00'): """ Encode ePDGSelection so it can be stored at EF.ePDGSelection or EF.ePDGSelectionEm. See 3GPP TS 31.102 version 15.2.0 Release 15, section 4.2.104 and 4.2.106. Default values: - epdg_priority: '0001' - 1st Priority - epdg_fqdn_format: '00' - Operator Identifier FQDN """ plmn1 = enc_plmn(mcc, mnc) + epdg_priority + epdg_fqdn_format # TODO: Handle encoding of Length field for length more than 127 Bytes content = '80' + ('%02x' % (len(plmn1)//2)) + plmn1 content = rpad(content, len(hexstr)) return content def dec_ePDGSelection(sixhexbytes): """ Decode ePDGSelection to get EF.ePDGSelection or EF.ePDGSelectionEm. See 3GPP TS 31.102 version 15.2.0 Release 15, section 4.2.104 and 4.2.106. """ res = {'mcc': 0, 'mnc': 0, 'epdg_priority': 0, 'epdg_fqdn_format': ''} plmn_chars = 6 epdg_priority_chars = 4 epdg_fqdn_format_chars = 2 # first three bytes (six ascii hex chars) plmn_str = sixhexbytes[:plmn_chars] # two bytes after first three bytes epdg_priority_str = sixhexbytes[plmn_chars:plmn_chars + epdg_priority_chars] # one byte after first five bytes epdg_fqdn_format_str = sixhexbytes[plmn_chars + epdg_priority_chars:plmn_chars + epdg_priority_chars + epdg_fqdn_format_chars] res['mcc'] = dec_mcc_from_plmn(plmn_str) res['mnc'] = dec_mnc_from_plmn(plmn_str) res['epdg_priority'] = epdg_priority_str res['epdg_fqdn_format'] = epdg_fqdn_format_str == '00' and 'Operator Identifier FQDN' or 'Location based FQDN' return res def format_ePDGSelection(hexstr): ePDGSelection_info_tag_chars = 2 ePDGSelection_info_tag_str = hexstr[:2] s = "" # Minimum length len_chars = 2 # TODO: Need to determine length properly - definite length support only # Inconsistency in spec: 3GPP TS 31.102 version 15.2.0 Release 15, 4.2.104 # As per spec, length is 5n, n - number of PLMNs # But, each PLMN entry is made of PLMN (3 Bytes) + ePDG Priority (2 Bytes) + ePDG FQDN format (1 Byte) # Totalling to 6 Bytes, maybe length should be 6n len_str = hexstr[ePDGSelection_info_tag_chars:ePDGSelection_info_tag_chars+len_chars] # Not programmed scenario if int(len_str, 16) == 255 or int(ePDGSelection_info_tag_str, 16) == 255: len_chars = 0 ePDGSelection_info_tag_chars = 0 if len_str[0] == '8': # The bits 7 to 1 denotes the number of length octets if length > 127 if int(len_str[1]) > 0: # Update number of length octets len_chars = len_chars * int(len_str[1]) len_str = hexstr[ePDGSelection_info_tag_chars:len_chars] content_str = hexstr[ePDGSelection_info_tag_chars+len_chars:] # Right pad to prevent index out of range - multiple of 6 bytes content_str = rpad(content_str, len(content_str) + (12 - (len(content_str) % 12))) for rec_data in hexstr_to_Nbytearr(content_str, 6): rec_info = dec_ePDGSelection(rec_data) if rec_info['mcc'] == 0xFFF and rec_info['mnc'] == 0xFFF: rec_str = "unused" else: rec_str = "MCC: %03d MNC: %03d ePDG Priority: %s ePDG FQDN format: %s" % \ (rec_info['mcc'], rec_info['mnc'], rec_info['epdg_priority'], rec_info['epdg_fqdn_format']) s += "\t%s # %s\n" % (rec_data, rec_str) return s def get_addr_type(addr): """ Validates the given address and returns it's type (FQDN or IPv4 or IPv6) Return: 0x00 (FQDN), 0x01 (IPv4), 0x02 (IPv6), None (Bad address argument given) TODO: Handle IPv6 """ # Empty address string if not len(addr): return None addr_list = addr.split('.') # Check for IPv4/IPv6 try: import ipaddress # Throws ValueError if addr is not correct ipa = ipaddress.ip_address(addr) if ipa.version == 4: return 0x01 elif ipa.version == 6: return 0x02 except Exception as e: invalid_ipv4 = True for i in addr_list: # Invalid IPv4 may qualify for a valid FQDN, so make check here # e.g. 172.24.15.300 import re if not re.match('^[0-9_]+$', i): invalid_ipv4 = False break if invalid_ipv4: return None fqdn_flag = True for i in addr_list: # Only Alpha-numeric characters and hyphen - RFC 1035 import re if not re.match("^[a-zA-Z0-9]+(?:-[a-zA-Z0-9]+)?$", i): fqdn_flag = False break # FQDN if fqdn_flag: return 0x00 return None def sw_match(sw:str, pattern:str) -> bool: """Match given SW against given pattern.""" # Create a masked version of the returned status word sw_lower = sw.lower() sw_masked = "" for i in range(0, 4): if pattern[i] == '?': sw_masked = sw_masked + '?' elif pattern[i] == 'x': sw_masked = sw_masked + 'x' else: sw_masked = sw_masked + sw_lower[i] # Compare the masked version against the pattern return sw_masked == pattern def tabulate_str_list(str_list, width:int = 79, hspace:int = 2, lspace:int = 1, align_left:bool = True) -> str: """Pretty print a list of strings into a tabulated form. Args: width : total width in characters per line space : horizontal space between cells lspace : number of spaces before row align_lef : Align text to the left side Returns: multi-line string containing formatted table """ if str_list == None: return "" if len(str_list) <= 0: return "" longest_str = max(str_list, key=len) cellwith = len(longest_str) + hspace cols = width // cellwith rows = (len(str_list) - 1) // cols + 1 table = [] for i in iter(range(rows)): str_list_row = str_list[i::rows] if (align_left): format_str_cell = '%%-%ds' else: format_str_cell = '%%%ds' format_str_row = (format_str_cell % cellwith) * len(str_list_row) format_str_row = (" " * lspace) + format_str_row table.append(format_str_row % tuple(str_list_row)) return '\n'.join(table) class JsonEncoder(json.JSONEncoder): """Extend the standard library JSONEncoder with support for more types.""" def default(self, o): if isinstance(o, BytesIO) or isinstance(o, bytes) or isinstance(o, bytearray): return b2h(o) return json.JSONEncoder.default(self, o)