IP Spoofing and TCP Sequence Number Prediction
                             by Gregory Gilliss

   On  February  19th, 1995, Kevin Mitnick was arrested in Raleigh, NC on
   charges  of violating the Cellular Piracy Act by making cellular phone
   calls  on a cloned phone. His arrest was precipitated by the intrusion
   into  the  system of computer security consultant Tsutomu Shimomura on
   Christmas  Day in 1994. While much was written by the media concerning
   Mitnick's  alleged  criminal  career,  no technical description of the
   techniques   used   for  the  intrusion  was  published.  Fortunately,
   Shimomura's  system  logged  the intrusion, and his description of the
   intrusion  was  e-mailed  to  various  security  administrators on the
   internet.

   This  article  is  a  technical  description  of  the  methods used to
   infiltrate  Shimomura's system. The techniques described can easily be
   used  to penetrate a UNIX system using TCP sequence number prediction.
   To   do  so  requires  a  program  (not  described  here,  but  easily
   implemented) to generate TCP packets. An understanding of TCP protocol
   data  units is useful in following the discussion. A great deal of the
   following  information  is  taken from the description of the break in
   provided  by  Shimomura. Thanks and credit where credit is due. Now on
   to the hack.

   The  following  names  are  used  to  describe  the  various  machines
   involved:

   server = a SPARCstation running Solaris 1 serving an X terminal
   X-terminal = a diskless SPARCstation running Solaris 1
   target = the apparent primary target of the attack

   The  first  step  of  the  attack  involved  determining  the  machine
   configuration  of the target system. The IP spoofing attack began with
   the  following  commands  being  issued  from  a machine identified as
   toad.com:

   finger -l @target
   finger -l @server
   finger -l @X-terminal
   finger -l root@server
   finger -l root@X-terminal

   The  finger commands generate a display of the user's login name, real
   name,  terminal  name,  write  status,  idle  time, login time, office
   location  and  office  phone number. The -l option displays the user's
   home  directory,  home  phone number, login shell, and contents of the
   .forward,  .plan, and .project files for the user's home directory, if
   they exist.

   showmount -e X-terminal

   The  showmount  command  displays the names of all hosts that have NFS
   file  systems  mounted  on the X-terminal machine. The -e option shows
   the export list for X-terminal.

   rpcinfo -p X-terminal

   The  rpcinfo  command  displays  the connections of the port mapper of
   X-terminal.  The  -p  option  displays the programs that are currently
   being tracked by the port mapper.
   The   above  commands  would  indicate  whether  some  kind  of  trust
   relationship   existed   between  the  systems,  and  how  that  trust
   relationship could be exploited with an IP spoofing attack.
   The  source  port  numbers  for  the  showmount  and  rpcinfo commands
   indicated that the attacker was logged in as root on toad.com.

   The  second  step  involved  generating  a large number of TCP initial
   connection  requests  (SYNs)  in order to fill up the connection queue
   for  port 513 on the server with "half-open" connections. This ensures
   that  the  server  will not respond to any new connection requests. In
   particular,  it  will  not generate TCP RSTs in response to unexpected
   SYN-ACKs.  Port  513 is a privileged port, and will allow server.login
   to  be  used  as the putative source for an address spoofing attack on
   the  UNIX  "r-services"  (rsh,  rlogin). 130.92.6.97 is a non-existent
   address that will not generate a response to packets sent to it.

   Below  is  a  portion of Shimomura's log showing some of the generated

   SYN records:
   14:18:22.516699 130.92.6.97.600 > server.login: S 1382726960:1382726960(0) win 4096
   14:18:22.566069 130.92.6.97.601 > server.login: S 1382726961:1382726961(0) win 4096
   14:18:22.744477 130.92.6.97.602 > server.login: S 1382726962:1382726962(0) win 4096
   14:18:22.830111 130.92.6.97.603 > server.login: S 1382726963:1382726963(0) win 4096
                                     .
                                     .
                                     .

   The  server generated SYN-ACKs for the first eight SYN requests before
   the  connection  queue  filled  up.  The  machine  would  periodically
   retransmit the SYN-ACKs as there is no ACK response to them.

   The  third  step involved sending a series of SYN packets to determine
   the behavior of the TCP sequence number generator. This allows for the
   prediction  of what the sequence number of the SYN-ACK from the target
   machine  would  be,  and  for subsequent simulation of the response to
   that  machine. Note that the initial sequence numbers increment by one
   for  each  connection,  indicating  that the SYN packets are not being
   generated   by   the  system's  TCP  implementation.  This  cause  the
   generation  of TCP RSTs in response to each unexpected SYN-ACK, so the
   connection  queue  on  x-terminal does not fill up. The source machine
   for the connection requests is apollo.it.luc.edu.

   Below is a portion of the log showing two of the server's responses:

   14:18:25.906002 apollo.it.luc.edu.1000 > x-terminal.shell: S 1382726990:1382726 990(0) win 4096
   14:18:26.094731 x-terminal.shell > apollo.it.luc.edu.1000: S 2021824000:2021824 000(0) ack 1382726991 win 4096 
   14:18:26.172394 apollo.it.luc.edu.1000 > x-terminal.shell: R 1382726991:1382726 991(0) win 0
   14:18:26.507560 apollo.it.luc.edu.999 > x-terminal.shell: S 1382726991:13827269 91(0) win 4096
   14:18:26.694691 x-terminal.shell > apollo.it.luc.edu.999: S 2021952000:20219520 00(0) ack 1382726992 win 4096
                                     .
                                     .
                                     .

   Note  that  the  SYN-ACK  packet  sent  by  X-terminal  has an initial
   sequence number that is 128,000 greater than the previous one.

   The fourth step involved sending a false SYN connection request to the
   target  machine.  The  SYN  appears to be from server.login, a trusted
   host,  using  the  predicted  sequence  number to simulate the trusted
   host.  X-terminal  will  reply to server with a SYN-ACK, which must be
   ACK'd  in  order  for  a  connection  to  be opened. Because server is
   ignoring packets sent to server.login, because the connection queue is
   full, the ACK must be forged as well.

   TCP  uses  a three way handshake to establish communications between a
   client  and  a  server.  The  SYN  bit in the control field of the TCP
   protocol  data  unit  (PDU)  is  used  to  establish  initial sequence
   numbers.  The  first PDU does not acknowledge any data. The second PDU
   has  both the SYN and the ACK bits set. The third PDU acknowledges the
   second  PDU  and  has  the  ACK  bit  set.  The three way handshake is
   illustrated below:

            Client                               Server

        1st SYN (seq #1)  - - - - - - - - >  Receives SYN - - - - |

                                                                  |

    | - Receives SYN-ACK < - - - - - Sends SYN-ACK (seq #?) - - - |

    |                                                              

    | - Sends ACK (seq # = ?+1) - - - - - > Connection established!


   The  sequence number from the SYN-ACK is required in order to generate
   a  valid  ACK. By knowing the interval between the sequence numbers of
   the  SYN-ACKs  sent by X-terminal, the attacker is able to predict the
   sequence  number  contained in the SYN-ACK based on the known behavior
   of X-terminal's TCP sequence number generator, and is thus able to ACK
   the SYN-ACK without seeing it.

   Below is a portion of the log containing the generated ACK:

   14:18:36.245045 server.login > x-terminal.shell: S 1382727010:1382727010(0) win 4096
   14:18:36.755522 server.login > x-terminal.shell: . ack 2024384001 win 4096

   The  spoofing machine now has a one-way connection to x-terminal.shell
   which  appears to be from server.login. It can maintain the connection
   and  send  data  provided  that  it  can properly ACK any data sent by
   x-terminal.

   The fifth step requires the attacker to send the UNIX command

   rsh x-terminal "echo + + >>/.rhosts"

   to the target machine. This command generates a line of two plus signs
   and  either  appends  that  line to the end of the .rhosts file in the
   root  directory  of the target machine, or creates the file if it does
   not exist. The line with two plus signs in the .rhosts file allows any
   user to perform remote logins from any host without being prompted for
   a  password.  The  attacker now have root access to the target machine
   without password authorization prompting.

   Finally  the  spoofed connection is shut down and TCP RSTs are sent to
   the  server machine to reset the "half-open" connections and empty the
   connection  queue  for  server.login  so  that  server.login can again
   accept connections. Below is a portion of the log containing the RSTs:

   14:18:52.298431 130.92.6.97.600 > server.login: R 1382726960:1382726960(0) win 4096
   14:18:52.363877 130.92.6.97.601 > server.login: R 1382726961:1382726961(0) win 4096
   14:18:52.416916 130.92.6.97.602 > server.login: R 1382726962:1382726962(0) win 4096
   14:18:52.476873 130.92.6.97.603 > server.login: R 1382726963:1382726963(0) win 4096
                                     .
                                     .
                                     .

   The  information  in  this article is for demonstration purposes only.
   Tsutomu Shimomura's e-mail is tsutomu@ucsd.edu.