Add new pySim.ota library, implement SIM OTA crypto

This introduces a hierarchy of classes implementing

* ETS TS 102 225 (general command structure)
* 3GPP TS 31.115 (dialects for SMS-PP)

In this initial patch only the SMS "dialect" is supported,
but it is foreseen that USSD/SMSCB/HTTPS dialects can be
added at a later point.

Change-Id: I193ff4712c8503279c017b4b1324f0c3d38b9f84
This commit is contained in:
Harald Welte 2022-07-31 15:51:19 +02:00
parent 7d05e49f11
commit 75a58d1a87
5 changed files with 584 additions and 1 deletions

443
pySim/ota.py Normal file
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"""Code related to SIM/UICC OTA according to TS 102 225 + TS 31.115."""
# (C) 2021-2022 by Harald Welte <laforge@osmocom.org>
#
# 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.construct import *
from pySim.utils import b2h
from pySim.sms import UserDataHeader
from construct import *
import zlib
import abc
import struct
from typing import Optional
# ETS TS 102 225 gives the general command structure and the dialects for CAT_TP, TCP/IP and HTTPS
# 3GPP TS 31.115 gives the dialects for SMS-PP, SMS-CB, USSD and HTTP
# CPI CPL CHI CHL SPI KIc KID TAR CNTR PCNTR RC/CC/DS data
# CAT_TP TCP/IP SMS
# CPI 0x01 0x01 =IEIa=70,len=0
# CHI NULL NULL NULL
# CPI, CPL and CHL included in RC/CC/DS true true
# RPI 0x02 0x02 =IEIa=71,len=0
# RHI NULL NULL
# RPI, RPL and RHL included in RC/CC/DS true true
# packet-id 0-bf,ff 0-bf,ff
# identification packet false 102 225 tbl 6
# KVN 1..f; KI1=KIc, KI2=KID, KI3=DEK
# ETSI TS 102 225 Table 5 + 3GPP TS 31.115 Section 7
ResponseStatus = Enum(Int8ub, por_ok=0, rc_cc_ds_failed=1, cntr_low=2, cntr_high=3,
cntr_blocked=4, ciphering_error=5, undefined_security_error=6,
insufficient_memory=7, more_time_needed=8, tar_unknown=9,
insufficient_security_level=0x0A,
actual_response_sms_submit=0x0B,
actual_response_ussd=0x0C)
# ETSI TS 102 226 Section 5.1.2
CompactRemoteResp = Struct('number_of_commands'/Int8ub,
'last_status_word'/HexAdapter(Bytes(2)),
'last_response_data'/HexAdapter(GreedyBytes))
RC_CC_DS = Enum(BitsInteger(2), no_rc_cc_ds=0, rc=1, cc=2, ds=3)
# TS 102 225 Section 5.1.1 + TS 31.115 Section 4.2
SPI = BitStruct( # first octet
Padding(3),
'counter'/Enum(BitsInteger(2), no_counter=0, counter_no_replay_or_seq=1,
counter_must_be_higher=2, counter_must_be_lower=3),
'ciphering'/Flag,
'rc_cc_ds'/RC_CC_DS,
# second octet
Padding(2),
'por_in_submit'/Flag,
'por_shall_be_ciphered'/Flag,
'por_rc_cc_ds'/RC_CC_DS,
'por'/Enum(BitsInteger(2), no_por=0,
por_required=1, por_only_when_error=2)
)
# TS 102 225 Section 5.1.2
KIC = BitStruct('key'/BitsInteger(4),
'algo'/Enum(BitsInteger(4), implicit=0, single_des=1, triple_des_cbc2=5, triple_des_cbc3=9,
aes_cbc=2)
)
# TS 102 225 Section 5.1.3.1
KID_CC = BitStruct('key'/BitsInteger(4),
'algo'/Enum(BitsInteger(4), implicit=0, single_des=1, triple_des_cbc2=5, triple_des_cbc3=9,
aes_cmac=2)
)
# TS 102 225 Section 5.1.3.2
KID_RC = BitStruct('key'/BitsInteger(4),
'algo'/Enum(BitsInteger(4), implicit=0, crc16=1, crc32=5, proprietary=3)
)
SmsCommandPacket = Struct('cmd_pkt_len'/Int16ub,
'cmd_hdr_len'/Int8ub,
'spi'/SPI,
'kic'/KIC,
'kid'/Switch(this.spi.rc_cc_ds, {'cc': KID_CC, 'rc': KID_RC }),
'tar'/Bytes(3),
'secured_data'/GreedyBytes)
class OtaKeyset:
"""The OTA related data (key material, counter) to be used in encrypt/decrypt."""
def __init__(self, algo_crypt: str, kic_idx: int, kic: bytes,
algo_auth: str, kid_idx: int, kid: bytes, cntr: int = 0):
self.algo_crypt = algo_crypt
self.kic = bytes(kic)
self.kic_idx = kic_idx
self.algo_auth = algo_auth
self.kid = bytes(kid)
self.kid_idx = kid_idx
self.cntr = cntr
@property
def auth(self):
"""Return an instance of the matching OtaAlgoAuth."""
return OtaAlgoAuth.fromKeyset(self)
@property
def crypt(self):
"""Return an instance of the matching OtaAlgoCrypt."""
return OtaAlgoCrypt.fromKeyset(self)
class OtaCheckError(Exception):
pass
class OtaDialect(abc.ABC):
"""Base Class for OTA dialects such as SMS, BIP, ..."""
def _compute_sig_len(self, spi:SPI):
if spi['rc_cc_ds'] == 'no_rc_cc_ds':
return 0
elif spi['rc_cc_ds'] == 'rc': # CRC-32
return 4
elif spi['rc_cc_ds'] == 'cc': # Cryptographic Checksum (CC)
# TODO: this is not entirely correct, as in AES case it could be 4 or 8
return 8
else:
raise ValueError("Invalid rc_cc_ds: %s" % spi['rc_cc_ds'])
@abc.abstractmethod
def encode_cmd(self, otak: OtaKeyset, tar: bytes, apdu: bytes) -> bytes:
pass
@abc.abstractmethod
def decode_resp(self, otak: OtaKeyset, apdu: bytes) -> (object, Optional["CompactRemoteResp"]):
"""Decode a response into a response packet and, if indicted (by a
response status of `"por_ok"`) a decoded response.
The response packet's common characteristics are not fully determined,
and (so far) completely proprietary per dialect."""
pass
from Crypto.Cipher import DES, DES3, AES
from Crypto.Hash import CMAC
class OtaAlgo(abc.ABC):
iv = b'\x00\x00\x00\x00\x00\x00\x00\x00'
blocksize = None
enum_name = None
@staticmethod
def _get_padding(in_len: int, multiple: int, padding: int = 0):
"""Return padding bytes towards multiple of N."""
if in_len % multiple == 0:
return b''
pad_cnt = multiple - (in_len % multiple)
return b'\x00' * pad_cnt
@staticmethod
def _pad_to_multiple(indat: bytes, multiple: int, padding: int = 0):
"""Pad input bytes to multiple of N."""
return indat + OtaAlgo._get_padding(len(indat), multiple, padding)
def pad_to_blocksize(self, indat: bytes, padding: int = 0):
"""Pad the given input data to multiple of the cipher block size."""
return self._pad_to_multiple(indat, self.blocksize, padding)
def __init__(self, otak: OtaKeyset):
self.otak = otak
def __str__(self):
return self.__class__.__name__
class OtaAlgoCrypt(OtaAlgo, abc.ABC):
def __init__(self, otak: OtaKeyset):
if self.enum_name != otak.algo_crypt:
raise ValueError('Cannot use algorithm %s with key for %s' % (self.enum_name, otak.algo_crypt))
super().__init__(otak)
def encrypt(self, data:bytes) -> bytes:
"""Encrypt given input bytes using the key material given in constructor."""
padded_data = self.pad_to_blocksize(data)
return self._encrypt(data)
def decrypt(self, data:bytes) -> bytes:
"""Decrypt given input bytes using the key material given in constructor."""
return self._decrypt(data)
@abc.abstractmethod
def _encrypt(self, data:bytes) -> bytes:
"""Actual implementation, to be implemented by derived class."""
pass
@abc.abstractmethod
def _decrypt(self, data:bytes) -> bytes:
"""Actual implementation, to be implemented by derived class."""
pass
@classmethod
def fromKeyset(cls, otak: OtaKeyset) -> 'OtaAlgoCrypt':
"""Resolve the class for the encryption algorithm of otak and instantiate it."""
for subc in cls.__subclasses__():
if subc.enum_name == otak.algo_crypt:
return subc(otak)
raise ValueError('No implementation for crypt algorithm %s' % otak.algo_auth)
class OtaAlgoAuth(OtaAlgo, abc.ABC):
def __init__(self, otak: OtaKeyset):
if self.enum_name != otak.algo_auth:
raise ValueError('Cannot use algorithm %s with key for %s' % (self.enum_name, otak.algo_crypt))
super().__init__(otak)
def sign(self, data:bytes) -> bytes:
"""Compute the CC/CR check bytes for the input data using key material
given in constructor."""
padded_data = self.pad_to_blocksize(data)
sig = self._sign(padded_data)
return sig
def check_sig(self, data:bytes, cc_received:bytes):
"""Compute the CC/CR check bytes for the input data and compare against cc_received."""
cc = self.sign(data)
if cc_received != cc:
raise OtaCheckError('Received CC (%s) != Computed CC (%s)' % (b2h(cc_received), b2h(cc)))
@abc.abstractmethod
def _sign(self, data:bytes) -> bytes:
"""Actual implementation, to be implemented by derived class."""
pass
@classmethod
def fromKeyset(cls, otak: OtaKeyset) -> 'OtaAlgoAuth':
"""Resolve the class for the authentication algorithm of otak and instantiate it."""
for subc in cls.__subclasses__():
if subc.enum_name == otak.algo_auth:
return subc(otak)
raise ValueError('No implementation for auth algorithm %s' % otak.algo_auth)
class OtaAlgoCryptDES(OtaAlgoCrypt):
"""DES is insecure. For backwards compatibility with pre-Rel8"""
name = 'DES'
enum_name = 'single_des'
blocksize = 8
def _encrypt(self, data:bytes) -> bytes:
cipher = DES.new(self.otak.kic, DES.MODE_CBC, self.iv)
return cipher.encrypt(data)
def _decrypt(self, data:bytes) -> bytes:
cipher = DES.new(self.otak.kic, DES.MODE_CBC, self.iv)
return cipher.decrypt(data)
class OtaAlgoAuthDES(OtaAlgoAuth):
"""DES is insecure. For backwards compatibility with pre-Rel8"""
name = 'DES'
enum_name = 'single_des'
blocksize = 8
def _sign(self, data:bytes) -> bytes:
cipher = DES.new(self.otak.kid, DES.MODE_CBC, self.iv)
ciph = cipher.encrypt(data)
return ciph[len(ciph) - 8:]
class OtaAlgoCryptDES3(OtaAlgoCrypt):
name = '3DES'
enum_name = 'triple_des_cbc2'
blocksize = 8
def _encrypt(self, data:bytes) -> bytes:
cipher = DES3.new(self.otak.kic, DES3.MODE_CBC, self.iv)
return cipher.encrypt(data)
def _decrypt(self, data:bytes) -> bytes:
cipher = DES3.new(self.otak.kic, DES3.MODE_CBC, self.iv)
return cipher.decrypt(data)
class OtaAlgoAuthDES3(OtaAlgoAuth):
name = '3DES'
enum_name = 'triple_des_cbc2'
blocksize = 8
def _sign(self, data:bytes) -> bytes:
cipher = DES3.new(self.otak.kid, DES3.MODE_CBC, self.iv)
ciph = cipher.encrypt(data)
return ciph[len(ciph) - 8:]
class OtaAlgoCryptAES(OtaAlgoCrypt):
name = 'AES'
enum_name = 'aes_cbc'
blocksize = 16 # TODO: is this needed?
def _encrypt(self, data:bytes) -> bytes:
cipher = AES.new(self.otak.kic, AES.MODE_CBC, self.iv)
return cipher.encrypt(data)
def _decrypt(self, data:bytes) -> bytes:
cipher = AES.new(self.otak.kic, AES.MODE_CBC, self.iv)
return cipher.decrypt(data)
class OtaAlgoAuthAES(OtaAlgoAuth):
name = 'AES'
enum_name = 'aes_cmac'
blocksize = 16 # TODO: is this needed?
def _sign(self, data:bytes) -> bytes:
cmac = CMAC.new(self.otak.kid, ciphermod=AES, mac_len=8)
cmac.update(data)
ciph = cmac.digest()
return ciph[len(ciph) - 8:]
class OtaDialectSms(OtaDialect):
"""OTA dialect for SMS based transport, as described in 3GPP TS 31.115."""
SmsResponsePacket = Struct('rpl'/Int16ub,
'rhl'/Int8ub,
'tar'/Bytes(3),
'cntr'/Bytes(5),
'pcntr'/Int8ub,
'response_status'/ResponseStatus,
'cc_rc'/Bytes(this.rhl-10),
'secured_data'/GreedyBytes)
def encode_cmd(self, otak: OtaKeyset, tar: bytes, spi: dict, apdu: bytes) -> bytes:
# length of signature in octets
len_sig = self._compute_sig_len(spi)
pad_cnt = 0
if spi['ciphering']: # ciphering is requested
# append padding bytes to end up with blocksize
len_cipher = 6 + len_sig + len(apdu)
padding = otak.crypt._get_padding(len_cipher, otak.crypt.blocksize)
pad_cnt = len(padding)
apdu += padding
kic = {'key': otak.kic_idx, 'algo': otak.algo_crypt}
kid = {'key': otak.kid_idx, 'algo': otak.algo_auth}
# CHL = number of octets from (and including) SPI to the end of RC/CC/DS
# 13 == SPI(2) + KIc(1) + KId(1) + TAR(3) + CNTR(5) + PCNTR(1)
chl = 13 + len_sig
# CHL + SPI (+ KIC + KID)
c = Struct('chl'/Int8ub, 'spi'/SPI, 'kic'/KIC, 'kid'/KID_CC, 'tar'/Bytes(3))
part_head = c.build({'chl': chl, 'spi':spi, 'kic':kic, 'kid':kid, 'tar':tar})
#print("part_head: %s" % b2h(part_head))
# CNTR + PCNTR (CNTR not used)
part_cnt = otak.cntr.to_bytes(5, 'big') + pad_cnt.to_bytes(1, 'big')
#print("part_cnt: %s" % b2h(part_cnt))
envelope_data = part_head + part_cnt + apdu
#print("envelope_data: %s" % b2h(envelope_data))
# 2-byte CPL. CPL is part of RC/CC/CPI to end of secured data, including any padding for ciphering
# CPL from and including CPI to end of secured data, including any padding for ciphering
cpl = len(envelope_data) + len_sig
envelope_data = cpl.to_bytes(2, 'big') + envelope_data
#print("envelope_data with cpl: %s" % b2h(envelope_data))
if spi['rc_cc_ds'] == 'cc':
cc = otak.auth.sign(envelope_data)
envelope_data = part_cnt + cc + apdu
elif spi['rc_cc_ds'] == 'rc':
# CRC32
crc32 = zlib.crc32(envelope_data) & 0xffffffff
envelope_data = part_cnt + crc32.to_bytes(4, 'big') + apdu
elif spi['rc_cc_ds'] == 'no_rc_cc_ds':
envelope_data = part_cnt + apdu
else:
raise ValueError("Invalid rc_cc_ds: %s" % spi['rc_cc_ds'])
#print("envelope_data with sig: %s" % b2h(envelope_data))
# encrypt as needed
if spi['ciphering']: # ciphering is requested
ciph = otak.crypt.encrypt(envelope_data)
envelope_data = part_head + ciph
# prefix with another CPL
cpl = len(envelope_data)
envelope_data = cpl.to_bytes(2, 'big') + envelope_data
else:
envelope_data = part_head + envelope_data
#print("envelope_data: %s" % b2h(envelope_data))
return envelope_data
def decode_resp(self, otak: OtaKeyset, spi: dict, data: bytes) -> ("OtaDialectSms.SmsResponsePacket", Optional["CompactRemoteResp"]):
if isinstance(data, str):
data = h2b(data)
# plain-text POR: 027100000e0ab000110000000000000001612f
# UDHL RPI IEDLa RPL RHL TAR CNTR PCNTR STS
# 02 71 00 000e 0a b00011 0000000000 00 00 01 612f
# POR with CC: 027100001612b000110000000000000055f47118381175fb01612f
# POR with CC+CIPH: 027100001c12b000119660ebdb81be189b5e4389e9e7ab2bc0954f963ad869ed7c
if data[0] != 0x02:
raise ValueError('Unexpected UDL=0x%02x' % data[0])
udhd, remainder = UserDataHeader.fromBytes(data)
if not udhd.has_ie(0x71):
raise ValueError('RPI 0x71 not found in UDH')
rph_rhl_tar = remainder[:6] # RPH+RHL+TAR; not ciphered
res = self.SmsResponsePacket.parse(remainder)
if spi['por_shall_be_ciphered']:
# decrypt
ciphered_part = remainder[6:]
deciph = otak.crypt.decrypt(ciphered_part)
temp_data = rph_rhl_tar + deciph
res = self.SmsResponsePacket.parse(temp_data)
# remove specified number of padding bytes, if any
if res['pcntr'] != 0:
# this conditional is needed as python [:-0] renders an empty return!
res['secured_data'] = res['secured_data'][:-res['pcntr']]
remainder = temp_data
# is there a CC/RC present?
len_sig = res['rhl'] - 10
if spi['por_rc_cc_ds'] == 'no_rc_cc_ds':
if len_sig:
raise OtaCheckError('No RC/CC/DS requested, but len_sig=%u' % len_sig)
elif spi['por_rc_cc_ds'] == 'cc':
# verify signature
# UDH is part of CC/RC!
udh = data[:3]
# RPL, RHL, TAR, CNTR, PCNTR and STSare part of CC/RC
rpl_rhl_tar_cntr_pcntr_sts = remainder[:13]
# remove the CC/RC bytes
temp_data = udh + rpl_rhl_tar_cntr_pcntr_sts + remainder[13+len_sig:]
otak.auth.check_sig(temp_data, res['cc_rc'])
# TODO: CRC
else:
raise OtaCheckError('Unknown por_rc_cc_ds: %s' % spi['por_rc_cc_ds'])
# TODO: ExpandedRemoteResponse according to TS 102 226 5.2.2
if res.response_status == 'por_ok':
dec = CompactRemoteResp.parse(res['secured_data'])
else:
dec = None
return (res, dec)

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pySim/sms.py Normal file
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"""Code related to SMS Encoding/Decoding"""
# simplistic SMS T-PDU code, as unfortunately nobody bothered to port the python smspdu
# module to python3, and I gave up after >= 3 hours of trying and failing to do so
# (C) 2022 by Harald Welte <laforge@osmocom.org>
#
# 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/>.
import typing
from construct import Int8ub, Bytes
from construct import Struct, Tell, this, RepeatUntil
from pySim.utils import Hexstr, h2b, b2h
BytesOrHex = typing.Union[Hexstr, bytes]
class UserDataHeader:
# a single IE in the user data header
ie_c = Struct('offset'/Tell, 'iei'/Int8ub, 'length'/Int8ub, 'data'/Bytes(this.length))
# parser for the full UDH: Length octet followed by sequence of IEs
_construct = Struct('udhl'/Int8ub,
# FIXME: somehow the below lambda is not working, we always only get the first IE?
'ies'/RepeatUntil(lambda obj,lst,ctx: ctx._io.tell() > 1+this.udhl, ie_c))
def __init__(self, ies=[]):
self.ies = ies
def __repr__(self) -> str:
return 'UDH(%r)' % self.ies
def has_ie(self, iei:int) -> bool:
for ie in self.ies:
if ie['iei'] == iei:
return True
return False
@classmethod
def fromBytes(cls, inb: BytesOrHex) -> typing.Tuple['UserDataHeader', bytes]:
if isinstance(inb, str):
inb = h2b(inb)
res = cls._construct.parse(inb)
return cls(res['ies']), inb[1+res['udhl']:]

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@ -9,3 +9,4 @@ gsm0338
pyyaml>=5.1
termcolor
colorlog
pycryptodome

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@ -18,7 +18,8 @@ setup(
"bidict",
"gsm0338",
"termcolor",
"colorlog"
"colorlog",
"pycryptodome"
],
scripts=[
'pySim-prog.py',

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tests/test_ota.py Normal file
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#!/usr/bin/env python3
import unittest
from pySim.utils import h2b, b2h
from pySim.ota import *
class Test_SMS_3DES(unittest.TestCase):
tar = h2b('b00000')
"""Test the OtaDialectSms for 3DES algorithms."""
def __init__(self, foo, **kwargs):
super().__init__(foo, **kwargs)
# KIC1 + KID1 of 8988211000000467285
KIC1 = h2b('D0FDA31990D8D64178601317191669B4')
KID1 = h2b('D24EB461799C5E035C77451FD9404463')
KIC3 = h2b('C21DD66ACAC13CB3BC8B331B24AFB57B')
KID3 = h2b('12110C78E678C25408233076AA033615')
self.od = OtaKeyset(algo_crypt='triple_des_cbc2', kic_idx=3, kic=KIC3,
algo_auth='triple_des_cbc2', kid_idx=3, kid=KID3)
self.dialect = OtaDialectSms()
self.spi_base = {
'counter':'no_counter',
'ciphering': True,
'rc_cc_ds': 'cc',
'por_in_submit':False,
'por': 'por_required',
'por_shall_be_ciphered': True,
'por_rc_cc_ds': 'cc',
}
def _check_response(self, r, d):
self.assertEqual(d['number_of_commands'], 1)
self.assertEqual(d['last_status_word'], '612f')
self.assertEqual(d['last_response_data'], u'')
self.assertEqual(r['response_status'], 'por_ok')
def test_resp_3des_ciphered(self):
spi = self.spi_base
spi['por_shall_be_ciphered'] = True
spi['por_rc_cc_ds'] = 'cc'
r, d = self.dialect.decode_resp(self.od, spi, '027100001c12b000119660ebdb81be189b5e4389e9e7ab2bc0954f963ad869ed7c')
self._check_response(r, d)
def test_resp_3des_signed(self):
spi = self.spi_base
spi['por_shall_be_ciphered'] = False
spi['por_rc_cc_ds'] = 'cc'
r, d = self.dialect.decode_resp(self.od, spi, '027100001612b000110000000000000055f47118381175fb01612f')
self._check_response(r, d)
def test_resp_3des_signed_err(self):
"""Expect an OtaCheckError exception if the computed CC != received CC"""
spi = self.spi_base
spi['por_shall_be_ciphered'] = False
spi['por_rc_cc_ds'] = 'cc'
with self.assertRaises(OtaCheckError) as context:
r, d = self.dialect.decode_resp(self.od, spi, '027100001612b000110000000000000055f47118381175fb02612f')
self.assertTrue('!= Computed CC' in str(context.exception))
def test_resp_3des_none(self):
spi = self.spi_base
spi['por_shall_be_ciphered'] = False
spi['por_rc_cc_ds'] = 'no_rc_cc_ds'
r, d = self.dialect.decode_resp(self.od, spi, '027100000e0ab000110000000000000001612f')
self._check_response(r, d)
def test_cmd_3des_ciphered(self):
spi = self.spi_base
spi['ciphering'] = True
spi['rc_cc_ds'] = 'no_rc_cc_ds'
r = self.dialect.encode_cmd(self.od, self.tar, spi, h2b('00a40000023f00'))
self.assertEqual(b2h(r), '00180d04193535b00000e3ec80a849b554421276af3883927c20')
def test_cmd_3des_signed(self):
spi = self.spi_base
spi['ciphering'] = False
spi['rc_cc_ds'] = 'cc'
r = self.dialect.encode_cmd(self.od, self.tar, spi, h2b('00a40000023f00'))
self.assertEqual(b2h(r), '1502193535b00000000000000000072ea17bdb72060e00a40000023f00')
def test_cmd_3des_none(self):
spi = self.spi_base
spi['ciphering'] = False
spi['rc_cc_ds'] = 'no_rc_cc_ds'
r = self.dialect.encode_cmd(self.od, self.tar, spi, h2b('00a40000023f00'))
self.assertEqual(b2h(r), '0d00193535b0000000000000000000a40000023f00')