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pysim
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pysim/pySim/cards.py

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#!/usr/bin/env python
# -*- coding: utf-8 -*-
""" pySim: Card programmation logic
"""
#
# Copyright (C) 2009-2010 Sylvain Munaut <tnt@246tNt.com>
# Copyright (C) 2011 Harald Welte <laforge@gnumonks.org>
# Copyright (C) 2017 Alexander.Chemeris <Alexander.Chemeris@gmail.com>
#
# 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 <http://www.gnu.org/licenses/>.
#
from pySim.ts_51_011 import EF, DF
from pySim.utils import *
from smartcard.util import toBytes
class Card(object):
def __init__(self, scc):
self._scc = scc
self._adm_chv_num = 4
def reset(self):
self._scc.reset_card()
def verify_adm(self, key):
'''
Authenticate with ADM key
'''
(res, sw) = self._scc.verify_chv(self._adm_chv_num, key)
return sw
def read_iccid(self):
(res, sw) = self._scc.read_binary(EF['ICCID'])
if sw == '9000':
return (dec_iccid(res), sw)
else:
return (None, sw)
def read_imsi(self):
(res, sw) = self._scc.read_binary(EF['IMSI'])
if sw == '9000':
return (dec_imsi(res), sw)
else:
return (None, sw)
def update_imsi(self, imsi):
data, sw = self._scc.update_binary(EF['IMSI'], enc_imsi(imsi))
return sw
def update_acc(self, acc):
data, sw = self._scc.update_binary(EF['ACC'], lpad(acc, 4))
return sw
def update_hplmn_act(self, mcc, mnc, access_tech='FFFF'):
"""
Update Home PLMN with access technology bit-field
See Section "10.3.37 EFHPLMNwAcT (HPLMN Selector with Access Technology)"
in ETSI TS 151 011 for the details of the access_tech field coding.
Some common values:
access_tech = '0080' # Only GSM is selected
access_tech = 'FFFF' # All technologues selected, even Reserved for Future Use ones
"""
# get size and write EF.HPLMNwAcT
r = self._scc.select_file(EF['HPLMNwAcT'])
size = int(r[-1][4:8], 16)
hplmn = enc_plmn(mcc, mnc)
content = hplmn + access_tech
data, sw = self._scc.update_binary(EF['HPLMNwAcT'], content + 'ffffff0000' * (size/5-1))
return sw
def update_oplmn_act(self, mcc, mnc, access_tech='FFFF'):
"""
See note in update_hplmn_act()
"""
# get size and write EF.OPLMNwAcT
data = self._scc.read_binary(EF['OPLMNwAcT'], length=None, offset=0)
size = len(data[0])/2
hplmn = enc_plmn(mcc, mnc)
content = hplmn + access_tech
data, sw = self._scc.update_binary(EF['OPLMNwAcT'], content + 'ffffff0000' * (size/5-1))
return sw
def update_plmn_act(self, mcc, mnc, access_tech='FFFF'):
"""
See note in update_hplmn_act()
"""
# get size and write EF.PLMNwAcT
data = self._scc.read_binary(EF['PLMNwAcT'], length=None, offset=0)
size = len(data[0])/2
hplmn = enc_plmn(mcc, mnc)
content = hplmn + access_tech
data, sw = self._scc.update_binary(EF['PLMNwAcT'], content + 'ffffff0000' * (size/5-1))
return sw
def update_plmnsel(self, mcc, mnc):
data = self._scc.read_binary(EF['PLMNsel'], length=None, offset=0)
size = len(data[0])/2
hplmn = enc_plmn(mcc, mnc)
data, sw = self._scc.update_binary(EF['PLMNsel'], hplmn + 'ff' * (size-3))
return sw
def update_smsp(self, smsp):
data, sw = self._scc.update_record(EF['SMSP'], 1, rpad(smsp, 84))
return sw
def update_ad(self, mnc):
#See also: 3GPP TS 31.102, chapter 4.2.18
mnclen = len(str(mnc))
if mnclen == 1:
mnclen = 2
if mnclen > 3:
raise RuntimeError('unable to calculate proper mnclen')
data = self._scc.read_binary(EF['AD'], length=None, offset=0)
size = len(data[0])/2
content = data[0][0:6] + "%02X" % mnclen
data, sw = self._scc.update_binary(EF['AD'], content)
return sw
def read_spn(self):
(spn, sw) = self._scc.read_binary(EF['SPN'])
if sw == '9000':
return (dec_spn(spn), sw)
else:
return (None, sw)
def update_spn(self, name, hplmn_disp=False, oplmn_disp=False):
content = enc_spn(name, hplmn_disp, oplmn_disp)
data, sw = self._scc.update_binary(EF['SPN'], rpad(content, 32))
return sw
class _MagicSimBase(Card):
"""
Theses cards uses several record based EFs to store the provider infos,
each possible provider uses a specific record number in each EF. The
indexes used are ( where N is the number of providers supported ) :
- [2 .. N+1] for the operator name
- [1 .. N] for the programable EFs
* 3f00/7f4d/8f0c : Operator Name
bytes 0-15 : provider name, padded with 0xff
byte 16 : length of the provider name
byte 17 : 01 for valid records, 00 otherwise
* 3f00/7f4d/8f0d : Programmable Binary EFs
* 3f00/7f4d/8f0e : Programmable Record EFs
"""
@classmethod
def autodetect(kls, scc):
try:
for p, l, t in kls._files.values():
if not t:
continue
if scc.record_size(['3f00', '7f4d', p]) != l:
return None
except:
return None
return kls(scc)
def _get_count(self):
"""
Selects the file and returns the total number of entries
and entry size
"""
f = self._files['name']
r = self._scc.select_file(['3f00', '7f4d', f[0]])
rec_len = int(r[-1][28:30], 16)
tlen = int(r[-1][4:8],16)
rec_cnt = (tlen / rec_len) - 1;
if (rec_cnt < 1) or (rec_len != f[1]):
raise RuntimeError('Bad card type')
return rec_cnt
def program(self, p):
# Go to dir
self._scc.select_file(['3f00', '7f4d'])
# Home PLMN in PLMN_Sel format
hplmn = enc_plmn(p['mcc'], p['mnc'])
# Operator name ( 3f00/7f4d/8f0c )
self._scc.update_record(self._files['name'][0], 2,
rpad(b2h(p['name']), 32) + ('%02x' % len(p['name'])) + '01'
)
# ICCID/IMSI/Ki/HPLMN ( 3f00/7f4d/8f0d )
v = ''
# inline Ki
if self._ki_file is None:
v += p['ki']
# ICCID
v += '3f00' + '2fe2' + '0a' + enc_iccid(p['iccid'])
# IMSI
v += '7f20' + '6f07' + '09' + enc_imsi(p['imsi'])
# Ki
if self._ki_file:
v += self._ki_file + '10' + p['ki']
# PLMN_Sel
v+= '6f30' + '18' + rpad(hplmn, 36)
# ACC
# This doesn't work with "fake" SuperSIM cards,
# but will hopefully work with real SuperSIMs.
if p.get('acc') is not None:
v+= '6f78' + '02' + lpad(p['acc'], 4)
self._scc.update_record(self._files['b_ef'][0], 1,
rpad(v, self._files['b_ef'][1]*2)
)
# SMSP ( 3f00/7f4d/8f0e )
# FIXME
# Write PLMN_Sel forcefully as well
r = self._scc.select_file(['3f00', '7f20', '6f30'])
tl = int(r[-1][4:8], 16)
hplmn = enc_plmn(p['mcc'], p['mnc'])
self._scc.update_binary('6f30', hplmn + 'ff' * (tl-3))
def erase(self):
# Dummy
df = {}
for k, v in self._files.iteritems():
ofs = 1
fv = v[1] * 'ff'
if k == 'name':
ofs = 2
fv = fv[0:-4] + '0000'
df[v[0]] = (fv, ofs)
# Write
for n in range(0,self._get_count()):
for k, (msg, ofs) in df.iteritems():
self._scc.update_record(['3f00', '7f4d', k], n + ofs, msg)
class SuperSim(_MagicSimBase):
name = 'supersim'
_files = {
'name' : ('8f0c', 18, True),
'b_ef' : ('8f0d', 74, True),
'r_ef' : ('8f0e', 50, True),
}
_ki_file = None
class MagicSim(_MagicSimBase):
name = 'magicsim'
_files = {
'name' : ('8f0c', 18, True),
'b_ef' : ('8f0d', 130, True),
'r_ef' : ('8f0e', 102, False),
}
_ki_file = '6f1b'
class FakeMagicSim(Card):
"""
Theses cards have a record based EF 3f00/000c that contains the provider
informations. See the program method for its format. The records go from
1 to N.
"""
name = 'fakemagicsim'
@classmethod
def autodetect(kls, scc):
try:
if scc.record_size(['3f00', '000c']) != 0x5a:
return None
except:
return None
return kls(scc)
def _get_infos(self):
"""
Selects the file and returns the total number of entries
and entry size
"""
r = self._scc.select_file(['3f00', '000c'])
rec_len = int(r[-1][28:30], 16)
tlen = int(r[-1][4:8],16)
rec_cnt = (tlen / rec_len) - 1;
if (rec_cnt < 1) or (rec_len != 0x5a):
raise RuntimeError('Bad card type')
return rec_cnt, rec_len
def program(self, p):
# Home PLMN
r = self._scc.select_file(['3f00', '7f20', '6f30'])
tl = int(r[-1][4:8], 16)
hplmn = enc_plmn(p['mcc'], p['mnc'])
self._scc.update_binary('6f30', hplmn + 'ff' * (tl-3))
# Get total number of entries and entry size
rec_cnt, rec_len = self._get_infos()
# Set first entry
entry = (
'81' + # 1b Status: Valid & Active
rpad(b2h(p['name'][0:14]), 28) + # 14b Entry Name
enc_iccid(p['iccid']) + # 10b ICCID
enc_imsi(p['imsi']) + # 9b IMSI_len + id_type(9) + IMSI
p['ki'] + # 16b Ki
lpad(p['smsp'], 80) # 40b SMSP (padded with ff if needed)
)
self._scc.update_record('000c', 1, entry)
def erase(self):
# Get total number of entries and entry size
rec_cnt, rec_len = self._get_infos()
# Erase all entries
entry = 'ff' * rec_len
for i in range(0, rec_cnt):
self._scc.update_record('000c', 1+i, entry)
class GrcardSim(Card):
"""
Greencard (grcard.cn) HZCOS GSM SIM
These cards have a much more regular ISO 7816-4 / TS 11.11 structure,
and use standard UPDATE RECORD / UPDATE BINARY commands except for Ki.
"""
name = 'grcardsim'
@classmethod
def autodetect(kls, scc):
return None
def program(self, p):
# We don't really know yet what ADM PIN 4 is about
#self._scc.verify_chv(4, h2b("4444444444444444"))
# Authenticate using ADM PIN 5
if p['pin_adm']:
pin = h2b(p['pin_adm'])
else:
pin = h2b("4444444444444444")
self._scc.verify_chv(5, pin)
# EF.ICCID
r = self._scc.select_file(['3f00', '2fe2'])
data, sw = self._scc.update_binary('2fe2', enc_iccid(p['iccid']))
# EF.IMSI
r = self._scc.select_file(['3f00', '7f20', '6f07'])
data, sw = self._scc.update_binary('6f07', enc_imsi(p['imsi']))
# EF.ACC
if p.get('acc') is not None:
data, sw = self._scc.update_binary('6f78', lpad(p['acc'], 4))
# EF.SMSP
if p.get('smsp'):
r = self._scc.select_file(['3f00', '7f10', '6f42'])
data, sw = self._scc.update_record('6f42', 1, lpad(p['smsp'], 80))
# Set the Ki using proprietary command
pdu = '80d4020010' + p['ki']
data, sw = self._scc._tp.send_apdu(pdu)
# EF.HPLMN
r = self._scc.select_file(['3f00', '7f20', '6f30'])
size = int(r[-1][4:8], 16)
hplmn = enc_plmn(p['mcc'], p['mnc'])
self._scc.update_binary('6f30', hplmn + 'ff' * (size-3))
# EF.SPN (Service Provider Name)
r = self._scc.select_file(['3f00', '7f20', '6f30'])
size = int(r[-1][4:8], 16)
# FIXME
# FIXME: EF.MSISDN
def erase(self):
return
class SysmoSIMgr1(GrcardSim):
"""
sysmocom sysmoSIM-GR1
These cards have a much more regular ISO 7816-4 / TS 11.11 structure,
and use standard UPDATE RECORD / UPDATE BINARY commands except for Ki.
"""
name = 'sysmosim-gr1'
@classmethod
def autodetect(kls, scc):
try:
# Look for ATR
if scc.get_atr() == toBytes("3B 99 18 00 11 88 22 33 44 55 66 77 60"):
return kls(scc)
except:
return None
return None
class SysmoUSIMgr1(Card):
"""
sysmocom sysmoUSIM-GR1
"""
name = 'sysmoUSIM-GR1'
@classmethod
def autodetect(kls, scc):
# TODO: Access the ATR
return None
def program(self, p):
# TODO: check if verify_chv could be used or what it needs
# self._scc.verify_chv(0x0A, [0x33,0x32,0x32,0x31,0x33,0x32,0x33,0x32])
# Unlock the card..
data, sw = self._scc._tp.send_apdu_checksw("0020000A083332323133323332")
# TODO: move into SimCardCommands
par = ( p['ki'] + # 16b K
p['opc'] + # 32b OPC
enc_iccid(p['iccid']) + # 10b ICCID
enc_imsi(p['imsi']) # 9b IMSI_len + id_type(9) + IMSI
)
data, sw = self._scc._tp.send_apdu_checksw("0099000033" + par)
def erase(self):
return
class SysmoSIMgr2(Card):
"""
sysmocom sysmoSIM-GR2
"""
name = 'sysmoSIM-GR2'
@classmethod
def autodetect(kls, scc):
try:
# Look for ATR
if scc.get_atr() == toBytes("3B 7D 94 00 00 55 55 53 0A 74 86 93 0B 24 7C 4D 54 68"):
return kls(scc)
except:
return None
return None
def program(self, p):
# select MF
r = self._scc.select_file(['3f00'])
# authenticate as SUPER ADM using default key
self._scc.verify_chv(0x0b, h2b("3838383838383838"))
# set ADM pin using proprietary command
# INS: D4
# P1: 3A for PIN, 3B for PUK
# P2: CHV number, as in VERIFY CHV for PIN, and as in UNBLOCK CHV for PUK
# P3: 08, CHV length (curiously the PUK is also 08 length, instead of 10)
if p['pin_adm']:
pin = h2b(p['pin_adm'])
else:
pin = h2b("4444444444444444")
pdu = 'A0D43A0508' + b2h(pin)
data, sw = self._scc._tp.send_apdu(pdu)
# authenticate as ADM (enough to write file, and can set PINs)
self._scc.verify_chv(0x05, pin)
# write EF.ICCID
data, sw = self._scc.update_binary('2fe2', enc_iccid(p['iccid']))
# select DF_GSM
r = self._scc.select_file(['7f20'])
# write EF.IMSI
data, sw = self._scc.update_binary('6f07', enc_imsi(p['imsi']))
# write EF.ACC
if p.get('acc') is not None:
data, sw = self._scc.update_binary('6f78', lpad(p['acc'], 4))
# get size and write EF.HPLMN
r = self._scc.select_file(['6f30'])
size = int(r[-1][4:8], 16)
hplmn = enc_plmn(p['mcc'], p['mnc'])
self._scc.update_binary('6f30', hplmn + 'ff' * (size-3))
# set COMP128 version 0 in proprietary file
data, sw = self._scc.update_binary('0001', '001000')
# set Ki in proprietary file
data, sw = self._scc.update_binary('0001', p['ki'], 3)
# select DF_TELECOM
r = self._scc.select_file(['3f00', '7f10'])
# write EF.SMSP
if p.get('smsp'):
data, sw = self._scc.update_record('6f42', 1, lpad(p['smsp'], 80))
def erase(self):
return
class SysmoUSIMSJS1(Card):
"""
sysmocom sysmoUSIM-SJS1
"""
name = 'sysmoUSIM-SJS1'
def __init__(self, ssc):
super(SysmoUSIMSJS1, self).__init__(ssc)
self._scc.cla_byte = "00"
self._scc.sel_ctrl = "0004" #request an FCP
@classmethod
def autodetect(kls, scc):
try:
# Look for ATR
if scc.get_atr() == toBytes("3B 9F 96 80 1F C7 80 31 A0 73 BE 21 13 67 43 20 07 18 00 00 01 A5"):
return kls(scc)
except:
return None
return None
def program(self, p):
# authenticate as ADM using default key (written on the card..)
if not p['pin_adm']:
raise ValueError("Please provide a PIN-ADM as there is no default one")
self._scc.verify_chv(0x0A, h2b(p['pin_adm']))
# select MF
r = self._scc.select_file(['3f00'])
# write EF.ICCID
data, sw = self._scc.update_binary('2fe2', enc_iccid(p['iccid']))
# select DF_GSM
r = self._scc.select_file(['7f20'])
# set Ki in proprietary file
data, sw = self._scc.update_binary('00FF', p['ki'])
# set OPc in proprietary file
if 'opc' in p:
content = "01" + p['opc']
data, sw = self._scc.update_binary('00F7', content)
# write EF.IMSI
data, sw = self._scc.update_binary('6f07', enc_imsi(p['imsi']))
# EF.PLMNsel
if p.get('mcc') and p.get('mnc'):
sw = self.update_plmnsel(p['mcc'], p['mnc'])
if sw != '9000':
print("Programming PLMNsel failed with code %s"%sw)
# EF.PLMNwAcT
if p.get('mcc') and p.get('mnc'):
sw = self.update_plmn_act(p['mcc'], p['mnc'])
if sw != '9000':
print("Programming PLMNwAcT failed with code %s"%sw)
# EF.OPLMNwAcT
if p.get('mcc') and p.get('mnc'):
sw = self.update_oplmn_act(p['mcc'], p['mnc'])
if sw != '9000':
print("Programming OPLMNwAcT failed with code %s"%sw)
# EF.AD
if p.get('mcc') and p.get('mnc'):
sw = self.update_ad(p['mnc'])
if sw != '9000':
print("Programming AD failed with code %s"%sw)
# EF.SMSP
if p.get('smsp'):
r = self._scc.select_file(['3f00', '7f10'])
data, sw = self._scc.update_record('6f42', 1, lpad(p['smsp'], 104), force_len=True)
def erase(self):
return
class FairwavesSIM(Card):
"""
FairwavesSIM
The SIM card is operating according to the standard.
For Ki/OP/OPC programming the following files are additionally open for writing:
3F00/7F20/FF01 OP/OPC:
byte 1 = 0x01, bytes 2-17: OPC;
byte 1 = 0x00, bytes 2-17: OP;
3F00/7F20/FF02: Ki
"""
name = 'Fairwaves SIM'
# Propriatary files
_EF_num = {
'Ki': 'FF02',
'OP/OPC': 'FF01',
}
_EF = {
'Ki': DF['GSM']+[_EF_num['Ki']],
'OP/OPC': DF['GSM']+[_EF_num['OP/OPC']],
}
def __init__(self, ssc):
super(FairwavesSIM, self).__init__(ssc)
self._adm_chv_num = 0x11
self._adm2_chv_num = 0x12
@classmethod
def autodetect(kls, scc):
try:
# Look for ATR
if scc.get_atr() == toBytes("3B 9F 96 80 1F C7 80 31 A0 73 BE 21 13 67 44 22 06 10 00 00 01 A9"):
return kls(scc)
except:
return None
return None
def verify_adm2(self, key):
'''
Authenticate with ADM2 key.
Fairwaves SIM cards support hierarchical key structure and ADM2 key
is a key which has access to proprietary files (Ki and OP/OPC).
That said, ADM key inherits permissions of ADM2 key and thus we rarely
need ADM2 key per se.
'''
(res, sw) = self._scc.verify_chv(self._adm2_chv_num, key)
return sw
def read_ki(self):
"""
Read Ki in proprietary file.
Requires ADM1 access level
"""
return self._scc.read_binary(self._EF['Ki'])
def update_ki(self, ki):
"""
Set Ki in proprietary file.
Requires ADM1 access level
"""
data, sw = self._scc.update_binary(self._EF['Ki'], ki)
return sw
def read_op_opc(self):
"""
Read Ki in proprietary file.
Requires ADM1 access level
"""
(ef, sw) = self._scc.read_binary(self._EF['OP/OPC'])
type = 'OP' if ef[0:2] == '00' else 'OPC'
return ((type, ef[2:]), sw)
def update_op(self, op):
"""
Set OP in proprietary file.
Requires ADM1 access level
"""
content = '00' + op
data, sw = self._scc.update_binary(self._EF['OP/OPC'], content)
return sw
def update_opc(self, opc):
"""
Set OPC in proprietary file.
Requires ADM1 access level
"""
content = '01' + opc
data, sw = self._scc.update_binary(self._EF['OP/OPC'], content)
return sw
def program(self, p):
# authenticate as ADM1
if not p['pin_adm']:
raise ValueError("Please provide a PIN-ADM as there is no default one")
sw = self.verify_adm(h2b(p['pin_adm']))
if sw != '9000':
raise RuntimeError('Failed to authenticate with ADM key %s'%(p['pin_adm'],))
# TODO: Set operator name
if p.get('smsp') is not None:
sw = self.update_smsp(p['smsp'])
if sw != '9000':
print("Programming SMSP failed with code %s"%sw)
# This SIM doesn't support changing ICCID
if p.get('mcc') is not None and p.get('mnc') is not None:
sw = self.update_hplmn_act(p['mcc'], p['mnc'])
if sw != '9000':
print("Programming MCC/MNC failed with code %s"%sw)
if p.get('imsi') is not None:
sw = self.update_imsi(p['imsi'])
if sw != '9000':
print("Programming IMSI failed with code %s"%sw)
if p.get('ki') is not None:
sw = self.update_ki(p['ki'])
if sw != '9000':
print("Programming Ki failed with code %s"%sw)
if p.get('opc') is not None:
sw = self.update_opc(p['opc'])
if sw != '9000':
print("Programming OPC failed with code %s"%sw)
if p.get('acc') is not None:
sw = self.update_acc(p['acc'])
if sw != '9000':
print("Programming ACC failed with code %s"%sw)
def erase(self):
return
class OpenCellsSim(Card):
"""
OpenCellsSim
"""
name = 'OpenCells SIM'
def __init__(self, ssc):
super(OpenCellsSim, self).__init__(ssc)
self._adm_chv_num = 0x0A
@classmethod
def autodetect(kls, scc):
try:
# Look for ATR
if scc.get_atr() == toBytes("3B 9F 95 80 1F C3 80 31 E0 73 FE 21 13 57 86 81 02 86 98 44 18 A8"):
return kls(scc)
except:
return None
return None
def program(self, p):
if not p['pin_adm']:
raise ValueError("Please provide a PIN-ADM as there is no default one")
self._scc.verify_chv(0x0A, h2b(p['pin_adm']))
# select MF
r = self._scc.select_file(['3f00'])
# write EF.ICCID
data, sw = self._scc.update_binary('2fe2', enc_iccid(p['iccid']))
r = self._scc.select_file(['7ff0'])
# set Ki in proprietary file
data, sw = self._scc.update_binary('FF02', p['ki'])
# set OPC in proprietary file
data, sw = self._scc.update_binary('FF01', p['opc'])
# select DF_GSM
r = self._scc.select_file(['7f20'])
# write EF.IMSI
data, sw = self._scc.update_binary('6f07', enc_imsi(p['imsi']))
class WavemobileSim(Card):
"""
WavemobileSim
"""
name = 'Wavemobile-SIM'
def __init__(self, ssc):
super(WavemobileSim, self).__init__(ssc)
self._adm_chv_num = 0x0A
self._scc.cla_byte = "00"
self._scc.sel_ctrl = "0004" #request an FCP
@classmethod
def autodetect(kls, scc):
try:
# Look for ATR
if scc.get_atr() == toBytes("3B 9F 95 80 1F C7 80 31 E0 73 F6 21 13 67 4D 45 16 00 43 01 00 8F"):
return kls(scc)
except:
return None
return None
def program(self, p):
if not p['pin_adm']:
raise ValueError("Please provide a PIN-ADM as there is no default one")
sw = self.verify_adm(h2b(p['pin_adm']))
if sw != '9000':
raise RuntimeError('Failed to authenticate with ADM key %s'%(p['pin_adm'],))
# EF.ICCID
# TODO: Add programming of the ICCID
if p.get('iccid'):
print("Warning: Programming of the ICCID is not implemented for this type of card.")
# KI (Presumably a propritary file)
# TODO: Add programming of KI
if p.get('ki'):
print("Warning: Programming of the KI is not implemented for this type of card.")
# OPc (Presumably a propritary file)
# TODO: Add programming of OPc
if p.get('opc'):
print("Warning: Programming of the OPc is not implemented for this type of card.")
# EF.SMSP
if p.get('smsp'):
sw = self.update_smsp(p['smsp'])
if sw != '9000':
print("Programming SMSP failed with code %s"%sw)
# EF.IMSI
if p.get('imsi'):
sw = self.update_imsi(p['imsi'])
if sw != '9000':
print("Programming IMSI failed with code %s"%sw)
# EF.ACC
if p.get('acc'):
sw = self.update_acc(p['acc'])
if sw != '9000':
print("Programming ACC failed with code %s"%sw)
# EF.PLMNsel
if p.get('mcc') and p.get('mnc'):
sw = self.update_plmnsel(p['mcc'], p['mnc'])
if sw != '9000':
print("Programming PLMNsel failed with code %s"%sw)
# EF.PLMNwAcT
if p.get('mcc') and p.get('mnc'):
sw = self.update_plmn_act(p['mcc'], p['mnc'])
if sw != '9000':
print("Programming PLMNwAcT failed with code %s"%sw)
# EF.OPLMNwAcT
if p.get('mcc') and p.get('mnc'):
sw = self.update_oplmn_act(p['mcc'], p['mnc'])
if sw != '9000':
print("Programming OPLMNwAcT failed with code %s"%sw)
# EF.AD
if p.get('mcc') and p.get('mnc'):
sw = self.update_ad(p['mnc'])
if sw != '9000':
print("Programming AD failed with code %s"%sw)
return None
def erase(self):
return
# In order for autodetection ...
_cards_classes = [ FakeMagicSim, SuperSim, MagicSim, GrcardSim,
SysmoSIMgr1, SysmoSIMgr2, SysmoUSIMgr1, SysmoUSIMSJS1,
FairwavesSIM, OpenCellsSim, WavemobileSim ]
def card_autodetect(scc):
for kls in _cards_classes:
card = kls.autodetect(scc)
if card is not None:
card.reset()
return card
return None
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