Network Working Group D. Borman, Editor Request for Comments: 1416 Cray Research, Inc. Obsoletes: 1409 February 1993
This memo defines an Experimental Protocol for the Internet community. Discussion and suggestions for improvement are requested. Please refer to the current edition of the "IAB Official Protocol Standards" for the standardization state and status of this protocol. Distribution of this memo is unlimited.
This RFC 1416 replaces RFC 1409, which has an important typographical error in the example on page 6 (one occurance of "REPLY" should be "IS").
IS 0 SEND 1 REPLY 2 NAME 3
NULL 0 KERBEROS_V4 1 KERBEROS_V5 2 SPX 3 RSA 6 LOKI 10
AUTH_WHO_MASK 1 AUTH_CLIENT_TO_SERVER 0 AUTH_SERVER_TO_CLIENT 1 AUTH_HOW_MASK 2 AUTH_HOW_ONE_WAY 0 AUTH_HOW_MUTUAL 2
This document makes reference to a "server" and a "client". For the purposes of this document, the "server" is the side of the connection that did the passive TCP open (TCP LISTEN state), and the "client" is the side of the connection that did the active open.
IAC WILL AUTHENTICATION
The client side of the connection sends this command to indicate that it is willing to send and receive authentication information.
IAC DO AUTHENTICATION
The servers side of the connection sends this command to indicate that it is willing to send and receive authentication information.
IAC WONT AUTHENTICATION
The client side of the connection sends this command to indicate that it refuses to send or receive authentication information; the server side sends this command if it receives a DO AUTHENTICATION command.
IAC DONT AUTHENTICATION
The server side of the connection sends this command to indicate
that it refuses to send or receive authentication information; the
client side sends this command if it receives a WILL
IAC SB AUTHENTICATION SEND authentication-type-pair-list IAC SE
The sender of this command (the server) requests that the remote
side send authentication information for one of the authentication
types listed in "authentication-type-pair-list". The
"authentication-type-pair-list" is an ordered list of
"authentication-type" pairs. Only the server side (DO AUTHENTICATION) is allowed to send this.
IAC SB AUTHENTICATION IS authentication-type-pair <auth data> IAC SE
The sender of this command (the client) is sending the
authentication information for authentication type
"authentication-type-pair". Only the client side (WILL AUTHENTICATION) is allowed to send this.
IAC SB AUTHENTICATION REPLY authentication-type-pair <auth data> IAC SE
The sender of this command (the server) is sending a reply to the the authentication information received in a previous IS command. Only the server side (DO AUTHENTICATION) is allowed to send this.
IAC SB AUTHENTICATION NAME remote-user IAC SE
This optional command is sent to specify the account name on the remote host that the user wishes to be authorized to use. Note that authentication may succeed, and the authorization to use a particular account may still fail. Some authentication mechanisms may ignore this command.
The "authentication-type-pair" is two octets, the first is the authentication type (as listed in Section 1, additions to this list must be registered with the Internet Assigned Numbers Authority (IANA)), and the second is a modifier to the type. There are currently two one bit fields defined in the modifier, the AUTH_WHO_MASK bit and the AUTH_HOW_MASK bit, so there are four possible combinations:
The client will send authentication information about the local user to the server. If the negotiation is successful, the server will have authenticated the user on the client side of the connection.
The server will authenticate itself to the client. If the negotiation is successful, the client will know that it is connected to the server that it wants to be connected to.
The client will send authentication information about the local user to the server, and then the server will authenticate itself to the client. If the negotiation is successful, the server will have authenticated the user on the client side of the connection, and the client will know that it is connected to the server that it wants to be connected to.
The server will authenticate itself to the client, and then the client will authenticate itself to the server. If the negotiation is successful, the client will know that it is connected to the server that it wants to be connected to, and the server will know that the client is who it claims to be.
The default specification for this option is
meaning there will not be any exchange of authentication information.
One of the deficiencies of the Telnet protocol is that in order to log into remote systems, users have to type their passwords, which are passed in clear text through the network. If the connections goes through untrusted networks, there is the possibility that passwords will be compromised by someone watching the packets as they go by.
The purpose of the AUTHENTICATION option is to provide a framework for the passing of authentication information through the TELNET session. This means that: 1) the users password will not be sent in clear text across the network, and 2) if the front end telnet process has the appropriate authentication information, it can automatically send the information, and the user will not have to type any password.
It is intended that the AUTHENTICATION option be general enough that it can be used to pass information for any authentication system.
The ability to negotiate a common authentication mechanism between client and server is a feature of the authentication option that should be used with caution. When the negotiation is performed, no authentication has yet occurred. Therefore, each system has no way of knowing whether or not it is talking to the system it intends. An intruder could attempt to negotiate the use of an authentication system which is either weak, or already compromised by the intruder.
WILL and DO are used only at the beginning of the connection to obtain and grant permission for future negotiations.
The authentication is only negotiated in one directions; the server must send the "DO", and the client must send the "WILL". This restriction is due to the nature of authentication; there are three possible cases; server authenticates client, client authenticates server, and server and client authenticate each other. By only negotiating the option in one direction, and then determining which of the three cases is being used via the suboption, potential ambiguity is removed. If the server receives a "DO", it must respond with a "WONT". If the client receives a "WILL", it must respond with a "DONT".
Once the two hosts have exchanged a DO and a WILL, the server is free to request authentication information. In the request, a list of supported authentication types is sent. Only the server may send requests ("IAC SB AUTHENTICATION SEND authentication-type-pair-list IAC SE"). Only the client may transmit authentication information via the "IAC SB AUTHENTICATION IS authentication-type ... IAC SE" command. Only the server may send replys ("IAC SB AUTHENTICATION REPLY authentication-type ... IAC SE"). As many IS and REPLY suboptions may be exchanged as are needed for the particular authentication scheme chosen.
If the client does not support any of the authentication types listed in the authentication-type-pair-list, a type of NULL should be used to indicate this in the IS reply. Note that in this case, the server may choose to close the connection.
The order of the authentication types MUST be ordered to indicate a preference for different authentication types, the first type being the most preferred, and the last type the least preferred.
The following is an example of use of the option:
Client Server IAC DO AUTHENTICATION IAC WILL AUTHENTICATION [ The server is now free to request authentication information. ] IAC SB AUTHENTICATION SEND KERBEROS_V4 CLIENT|MUTUAL KERBEROS_V4 CLIENT|ONE_WAY IAC SE [ The server has requested mutual Kerberos authentication, but is
willing to do just one-way Kerberos authentication. The client
will now respond with the name of the user that it wants to log
in as, and the Kerberos ticket. ]
IAC SB AUTHENTICATION NAME "joe"
IAC SB AUTHENTICATION IS
KERBEROS_V4 CLIENT|MUTUAL AUTH 4
7 1 67 82 65 89 46 67 7 9 77 0
48 24 49 244 109 240 50 208 43
35 25 116 104 44 167 21 201 224
229 145 20 2 244 213 220 33 134
148 4 251 249 233 229 152 77 2
109 130 231 33 146 190 248 1 9
31 95 94 15 120 224 0 225 76 205
70 136 245 190 199 147 155 13
[ The server responds with an ACCEPT command to state that the authentication was successful. ]
IAC SB AUTHENTICATION REPLY KERBEROS_V4 CLIENT|MUTUAL ACCEPT IAC SE
[ Next, the client sends across a CHALLENGE to verify that it is really talking to the right server. ]
IAC SB AUTHENTICATION IS
CHALLENGE xx xx xx xx xx xx xx
xx IAC SE
[ Lastly, the server sends across a RESPONSE to prove that it really is the right server.
IAC SB AUTHENTICATION REPLY KERBEROS_V4 CLIENT|MUTUAL RESPONSE yy yy yy yy yy yy yy yy IAC SE
It is expected that any implementation that supports the Telnet AUTHENTICATION option will support all of this specification.
 Reynolds, J., and J. Postel, "Assigned Numbers", STD 2, RFC 1340, USC/Information Sciences Institute, July 1992.
Security issues are discussed in Section 5.
David A. Borman, Editor
Cray Research, Inc.
655F Lone Oak Drive
Eagan, MN 55123
Phone: (612) 452-6650
Mailing List: telnet-ietf@CRAY.COM
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