972 lines
17 KiB
Text
972 lines
17 KiB
Text
.TH AUTHSRV 6
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.SH NAME
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authsrv, p9any, p9sk1, dp9ik \- authentication protocols
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.SH DESCRIPTION
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This manual page describes
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the protocols used to authorize connections, confirm the identities
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of users and machines, and maintain the associated databases.
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The machine that provides these services is called the
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.I authentication server
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(AS).
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The AS may be a stand-alone machine or a general-use machine such as a CPU server.
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The network database
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.IR ndb (6)
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holds for each public machine, such as a CPU server or
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file server, the name of the authentication server that machine uses.
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.PP
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Each machine contains four values important to authentication; a 56-bit DES
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key, a 128-bit AES key, a 28-byte authentication ID, and a 48-byte authentication
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domain name.
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The ID is a user name and identifies who is currently responsible for the
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kernel running on that machine.
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The domain name identifies the machines across which the ID is valid.
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Together, the ID and domain name identify the owner of a key.
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.PP
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When a terminal boots,
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.IR factotum (4)
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prompts for user name and password.
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The user name becomes the terminal's authentication ID.
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The password is converted using
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.I passtokey
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(see
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.IR authsrv (2))
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into a 56-bit DES and 128-bit AES keys and saved in memory.
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The authentication domain is set to the null string.
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If possible,
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.I factotum
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validates the key with the AS
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before saving it.
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For Internet machines the correct AS to ask is found using
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.IR dhcpd (8).
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.PP
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When a CPU or file server boots,
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.I factotum
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reads the key, ID, and domain name from
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non-volatile RAM.
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This allows servers to reboot without operator intervention.
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.PP
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The details of any authentication are mixed with the semantics
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of the particular service they are authenticating so we describe
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them one case at a time. The following definitions will be used
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in the descriptions:
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.TF nullx
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.TP
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.I Ks
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server's host ID's key
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.TP
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.I Kc
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client's host ID's key
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.TP
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.I Kn
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a nonce key created for a ticket
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.RB ( key )
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.TP
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.I K{m}
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message
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.I m
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encrypted with key
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.I K
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.TP
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.I CHc
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an 8-byte random challenge from a client
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.RB ( chal )
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.TP
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.I CHs
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an 8-byte random challenge from a server
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.RB ( chal )
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.TP
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.I IDs
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server's ID
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.RB ( authid )
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.TP
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.I DN
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server's authentication domain name
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.RB ( authdom )
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.TP
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.I IDc
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client's ID
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.RB ( hostid ,
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.BR cuid )
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.TP
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.I IDr
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client's desired ID on server
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.RB ( uid ,
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.BR suid )
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.TP
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.I YAc
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client → AS DH public key
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.TP
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.I YBc
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AS → client DH public key
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.TP
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.I YAs
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server → AS DH public key
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.TP
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.I YBs
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AS → server DH public key
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.TP
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.I RNc
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client's 32-byte random string
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.TP
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.I RNs
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server's 32-byte random string
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.PD
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.PP
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The parenthesized names are the ones used in the
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.B Ticketreq
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and
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.B Ticket
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structures in
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.BR <authsrv.h> .
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.PP
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The message type constants
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.IR AuthTreq ,
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.IR AuthChal ,
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.IR AuthPass ,
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.IR AuthOK ,
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.IR AuthErr ,
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.IR AuthMod ,
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.IR AuthApop ,
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.IR AuthOKvar ,
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.IR AuthChap ,
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.IR AuthMSchap ,
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.IR AuthCram ,
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.IR AuthVNC ,
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and
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.IR AuthPAK
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.RB ( type )
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are defined in
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.BR <authsrv.h> ,
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as are the encrypted message types
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.IR AuthTs ,
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.IR AuthAs ,
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.IR AuthAc ,
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.IR AuthTp ,
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and
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.IR AuthHr
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.RB ( num ).
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.SS "Ticket Service
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When a client and server wish to authenticate to each other,
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they do so using
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.I tickets
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issued by the AS.
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Obtaining tickets from the AS
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is the client's responsibility.
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.PP
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The protocol to obtain a ticket pair is:
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.TP
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.I C→A:
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.IR AuthTreq ,
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.IR IDs ,
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.IR DN ,
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.IR CHs ,
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.IR IDc ,
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.IR IDr
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.TP
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.I A→C:
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.IR AuthOK ,
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.IR Kc { AuthTc ,
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.IR CHs ,
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.IR IDc ,
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.IR IDr ,
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.IR Kn },
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.IR Ks { AuthTs ,
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.IR CHs ,
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.IR IDc ,
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.IR IDr ,
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.IR Kn }
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.PP
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The two tickets are identical except for their type fields
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and the keys with which they are encrypted.
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The client and server can each decrypt one of the tickets,
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establishing a shared secret
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.IR Kn .
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.PP
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The
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tickets can be viewed as a statement by the
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AS that
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``a client possessing the
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.I Kn
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key is allowed to authenticate as
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.IR IDr .''
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.PP
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The presence of the server challenge
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.I CHs
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in the ticket allows the server to verify the freshness
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of the ticket pair.
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.PP
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The AS sets the
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.I IDr
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in the tickets to the requested
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.I IDr
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only if
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.I IDc
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is allowed to
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.I "speak for
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.RI ( q.v. )
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.IR IDr .
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If not,
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the AS sets
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.I IDr
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to the empty string.
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.PP
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If the users
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.I IDc
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or
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.I IDs
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do not exist,
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the AS silently generates one-time
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random keys to use in place of
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.I Kc
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or
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.IR Ks ,
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so that clients cannot probe the AS
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to learn whether a user name is valid.
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.SS "P9sk1
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The Plan 9 shared key protocol
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.I p9sk1
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allows a client and server to authenticate each other.
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The protocol is:
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.TP
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.I C→S:
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.I CHc
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.br
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The client starts by sending a random challenge to the server.
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.TP
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.I S→C:
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.IR AuthTreq ,
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.IR IDs ,
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.IR DN ,
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.IR CHs ,
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.IR \- ,
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.IR \-
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.br
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The server replies with a ticket request giving its
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id and authentication domain along with its own
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random challenge.
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.TP
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.I C→S:
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.IR Ks { AuthTs ,
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.IR CHs ,
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.IR IDc ,
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.IR IDr ,
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.IR Kn },
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.IR Kn { AuthAc ,
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.IR CHs }
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.br
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The client adds
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.I IDc
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and
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.I IDr
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to the ticket request and obtains a ticket pair
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from the AS as described above.
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The client relays the server's ticket along with
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an
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.IR authenticator ,
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the
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.I AuthAc
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message.
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The authenticator proves to the server that the
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client knows
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.I Kn
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and is therefore allowed to authenticate as
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.IR IDr .
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(The inclusion of
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.IR CHs
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in the authenticator avoids replay attacks.)
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.TP
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.I S→C:
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.IR Kn { AuthAs ,
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.IR CHc }
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.br
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The server replies with its own authenticator,
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proving to the client that it also knows
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.I Kn
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and therefore
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.I Ks .
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.PP
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The 64-bit shared secret
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.I Kn
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is used as the session secret.
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.SS "Password authenticated key exchange"
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Initially, the server and client keys
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.I Ks
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and
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.I Kc
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where equivalent to the password derived 56-bit DES keys, which
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made the encrypted tickets subject to offline dictionary attacks
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and provided too small a key space against brute force attacks
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on current hardware.
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.PP
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The
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.I AuthPAK
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protocol is used to establish new 256-bit random keys with the
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AS for
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.I Ks
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and
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.I Kc
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before each ticket request on the connection.
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.PP
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The protocol is based on SPAKE2EE, where a hash of the user's secret
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is used to encypt the public keys of a Elliptic-Curve Diffie-Hellman
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key exchange. The user's
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.I ID
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and 128-bit AES key is hashed and mapped (using Elligator2)
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into two curve points
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.I PM
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and
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.IR PN ,
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called the
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.IR pakhash .
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Both sides generate a random number
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.IR xa / xb
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and make the public keys
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.IR YA / YB
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as:
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.IR YA = xa*G+PM ,
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.IR YB = xb*G+PN .
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After the public keys have been exchanged, each side calculates the
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shared secret as:
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.IR Z = xa*(YB-PN) = xb*(YA-PM) .
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The shared secret
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.I Z
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is then hashed with the transmitted public keys
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.IR YA | YB
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producing the 256-bit
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.IR pakkey .
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.PP
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The
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.I pakkey
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is then used in place of
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.I Ks
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and
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.I Kc
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to authenticate and encrypt tickets from the AS using
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Chacha20/Poly1305 AEAD for the next following
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request made on the connection.
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.PP
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The protocol (for
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.IR AuthTreq )
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to establish keys
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.I Ks
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and
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.I Kc
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with the AS for
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.I IDs
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and
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.I IDc
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is:
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.TP
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.I C→A:
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.IR AuthPAK ,
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.IR IDs ,
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.IR DN ,
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.IR CHs ,
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.IR IDc ,
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.IR IDr ,
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.IR YAs ,
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.I YAc
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.TP
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.I A→C:
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.IR AuthOK ,
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.IR YBs ,
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.I YBc
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.PP
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The protocol (for
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.IR AuthApop ,
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.IR AuthChap ...)
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to establish a single server key
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.I Ks
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for
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.IR IDs :
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.TP
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.I C→A:
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.IR AuthPAK ,
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.IR \- ,
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.IR DN ,
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.IR CHs ,
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.IR IDs ,
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.IR IDc ,
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.I YAs
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.TP
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.I A→C:
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.IR AuthOK ,
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.I YBs
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.PP
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The protocol (for
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.IR AuthPass )
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to establish a single client key
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.I Kc
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for
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.IR IDc :
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.TP
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.I C→A:
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.IR AuthPAK ,
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.IR \- ,
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.IR \- ,
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.IR CHc ,
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.IR \- ,
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.IR IDc ,
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.I YAc
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.TP
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.I A→C:
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.IR AuthOK ,
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.I YBc
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.SS "Dp9ik"
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The
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.I dp9ik
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protocol is an extended version of
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.I p9sk1
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that adds the random strings
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.I RNc
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and
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.I RNs
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in the
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.I authenticator
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messages for the session key derivation and uses the
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password authenticated key exchange as described above
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to derive the ticket encryption keys
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.I Ks
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and
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.IR Kc :
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.TP
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.I C→S:
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.I CHc
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.br
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The client starts by sending a random challenge to the server.
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.TP
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.I S→C:
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.IR AuthPAK ,
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.IR IDs ,
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.IR DN ,
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.IR CHs ,
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.IR \- ,
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.IR \- ,
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.IR YAs
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.br
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The server generates a new public key
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.I YAs
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and replies with a
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.I AuthPAK
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request giving its
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.I IDs
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and authentication domain
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.I DNs
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along with its own random challenge
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.I CHs
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and its public key
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.IR YAs .
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.TP
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.I C→S:
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.IR YBs ,
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.IR Ks { AuthTs ,
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.IR CHs ,
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.IR IDc ,
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.IR IDr ,
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.IR Kn },
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.IR Kn { AuthAc ,
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.IR CHs ,
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.IR RNc }
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.br
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The client generates its own public key
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.I YAc
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and adds it along with
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.I IDc
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and
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.I IDr
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to the
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.I AuthPAK
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request and obtains the public keys
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.I YBs
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and
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.I YBc
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from the AS response. At this point, client and AS
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have completed their authenticated key exchange and
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derive
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.I Kc
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as described above.
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Then the client requests a ticket pair using the same
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message but with
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.I AuthPAK
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type changed to
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.IR AuthTreq .
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It decrypts his ticket with
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.I Kc
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extracting the shared secret
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.IR Kn .
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The client relays the server's
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.I YBs
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and ticket along with an
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.IR authenticator ,
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the
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.I AuthAc
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message.
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The server finishes his authenticated key exchange
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using
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.I YBs
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and derives
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.I Ks
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to decrypt his ticket to extract the shared secret
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.IR Kn .
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When the decryption of the clients authenticator using
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.I Kn
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is successfull then this proves to the server that the
|
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client knows
|
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.I Kn
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and is therefore allowed to authenticate as
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.IR IDr .
|
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The random string
|
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.I RNc
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is used in the derivation of the session secret.
|
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.TP
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.I S→C:
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.IR Kn { AuthAs ,
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.IR CHc ,
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.IR RNs }
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.br
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The server replies with its own authenticator,
|
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proving to the client that it also knows
|
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.I Kn
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and contributes its random string
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.IR RNs
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for the session secret.
|
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.PP
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The 2048-bit session secret is derived with HKDF-SHA256 hashing the
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concatenated random strings
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.IR RNc | RNs
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with the the shared secret key
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.IR Kn .
|
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.SS "P9any
|
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.I P9any
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is the standard Plan 9 authentication protocol.
|
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It consists of a negotiation to determine a common
|
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protocol, followed by the agreed-upon protocol.
|
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.PP
|
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The negotiation protocol is:
|
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.TP
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.I S→C:
|
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.B v.2
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.IB proto@authdom
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.IB proto@authdom
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.I ...
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.TP
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.I C→S:
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.I proto
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.I dom
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.TP
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.I S→C:
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.B OK
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.PP
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Each message is a NUL-terminated UTF string.
|
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The server begins by sending a list of
|
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.IR proto ,
|
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.I authdom
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pairs it is willing to use.
|
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The client
|
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responds with its choice.
|
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Requiring the client to wait for the final
|
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.B OK
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ensures that the client will not start
|
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the chosen protocol until the server is ready.
|
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.PP
|
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The above is version 2 of the protocol.
|
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Version 1,
|
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no longer used,
|
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omitted the first message's
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.B v.2
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prefix
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and the
|
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.B OK
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message.
|
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.PP
|
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The
|
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.I p9any
|
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protocol is the protocol used by all
|
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Plan 9 services.
|
|
The file server runs it over special
|
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authentication files
|
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(see
|
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.IR fauth (2)
|
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and
|
|
.IR attach (5)).
|
|
Other services, such as
|
|
.IR cpu (1),
|
|
.IR exportfs (4)
|
|
and
|
|
.IR tlssrv (8)
|
|
run
|
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.I p9any
|
|
over the network and then use the session secret to derive an
|
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.IR ssl (3)
|
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or
|
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.IR tls (3)
|
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key to encrypt the rest of their communications.
|
|
.SS "Password Change
|
|
Users connect directly to the AS
|
|
to change their passwords.
|
|
The protocol is:
|
|
.TP
|
|
.I C→A:
|
|
.IR AuthPass ,
|
|
.IR \- ,
|
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.IR \- ,
|
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.IR CHc ,
|
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.IR \- ,
|
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.IR IDc
|
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.br
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|
The client sends a password change ticket request.
|
|
.TP
|
|
.I A→C:
|
|
.IR Kc { AuthTp ,
|
|
.IR CHc ,
|
|
.IR IDc ,
|
|
.IR IDc ,
|
|
.IR Kn }
|
|
.br
|
|
The server responds with a ticket containing the key
|
|
.I Kn
|
|
encrypted with the client's key
|
|
.IR Kc
|
|
.TP
|
|
.I C→A:
|
|
.IR Kn { AuthPass ,
|
|
.IR old ,
|
|
.IR new ,
|
|
.IR changesecret ,
|
|
.IR secret }
|
|
.br
|
|
The client decrypts the ticket using the old password
|
|
and then sends back an encrypted password request
|
|
.RB ( Passwordreq
|
|
structure)
|
|
containing the old password and the new password.
|
|
If
|
|
.I changesecret
|
|
is set, the AS also changes
|
|
the user's
|
|
.IR secret ,
|
|
the password used for non-Plan 9 authentications.
|
|
.TP
|
|
.I A→C:
|
|
.I AuthOK
|
|
or
|
|
.IR AuthErr ,
|
|
64-byte error message
|
|
.br
|
|
The AS responds with simply
|
|
.I AuthOK
|
|
or with
|
|
.I AuthErr
|
|
followed by a 64-byte error message.
|
|
.SS "Authentication Database
|
|
An
|
|
.IR ndb (2)
|
|
database file
|
|
.B /lib/ndb/auth
|
|
exists for the AS.
|
|
This database maintains ``speaks for'' relationships, i.e.,
|
|
it lists which users may speak for other users when
|
|
authenticating.
|
|
The attribute types used by the AS are
|
|
.B hostid
|
|
and
|
|
.BR uid .
|
|
The value in the
|
|
.B hostid
|
|
is a client host's ID.
|
|
The values in the
|
|
.B uid
|
|
pairs in the same entry list which users that host ID
|
|
may speak for.
|
|
A uid value of
|
|
.B *
|
|
means the host ID may speak for all users.
|
|
A uid value of
|
|
.BI ! user
|
|
means the host ID may not speak for
|
|
.IR user .
|
|
For example:
|
|
.PP
|
|
.EX
|
|
hostid=bootes
|
|
uid=!sys uid=!adm uid=*
|
|
.EE
|
|
.PP
|
|
is interpreted as
|
|
.B bootes
|
|
may speak for any user except
|
|
.B sys
|
|
and
|
|
.BR adm .
|
|
This property is used heavily on CPU servers.
|
|
.SS "Foreign Protocols
|
|
The AS accepts ticket request
|
|
messages of types other than
|
|
.I AuthTreq
|
|
to allow users to
|
|
authenticate using non-Plan 9 protocols.
|
|
In these situations, the server communicates
|
|
directly with the AS.
|
|
Some protocols must begin without knowing the
|
|
client's name. They ignore the client name in the
|
|
ticket request.
|
|
All the protocols end
|
|
with the AS sending
|
|
an
|
|
.I AuthOK
|
|
message containing a server ticket and authenticator.
|
|
.PP
|
|
.I AuthOK
|
|
messages
|
|
always have a fixed but context-dependent size.
|
|
The occasional variable-length OK message starts with a
|
|
.I AuthOKvar
|
|
byte and a five-byte space-padded decimal length of the
|
|
data that follows.
|
|
.PP
|
|
Anywhere an
|
|
.I AuthOK
|
|
message is expected, a
|
|
.I AuthErr
|
|
message may be substituted.
|
|
.de Ok
|
|
.TP
|
|
.I A→S:
|
|
.IR AuthOK ,
|
|
.IR Ks { AuthTs ,
|
|
.IR CHs ,
|
|
.IR IDc ,
|
|
.IR IDc ,
|
|
.IR Kn },
|
|
.IR Kn { AuthAc ,
|
|
.IR CHs }
|
|
..
|
|
.PP
|
|
.TP
|
|
.I S→A:
|
|
.IR AuthChal ,
|
|
.IR \- ,
|
|
.IR DN ,
|
|
.IR CHs ,
|
|
.IR IDs ,
|
|
.IR IDc
|
|
.TP
|
|
.I A→S:
|
|
.IR AuthOK ,
|
|
.IR challenge
|
|
.TP
|
|
.I S→A:
|
|
.IR response
|
|
.Ok
|
|
.IP
|
|
This protocol allows the use of
|
|
handheld authenticators such as SecureNet
|
|
keys and SecureID tokens
|
|
in programs such as
|
|
.I telnetd
|
|
and
|
|
.I ftpd
|
|
(see
|
|
.IR ipserv (8)).
|
|
.IP
|
|
.I Challenge
|
|
and
|
|
.I response
|
|
are text strings,
|
|
.SM NUL -padded
|
|
to 16 bytes
|
|
.RB ( NETCHLEN ).
|
|
The
|
|
.I challenge
|
|
is a random five-digit decimal number.
|
|
When using a SecureNet key or
|
|
.I netkey
|
|
(see
|
|
.IR passwd (1)),
|
|
the
|
|
.I response
|
|
is an eight-digit decimal or hexadecimal number
|
|
that is an encryption of the challenge
|
|
using the user's DES key.
|
|
.IP
|
|
When using a SecureID token,
|
|
the challenge is ignored.
|
|
The response is the user's PIN followed by
|
|
the six-digit number currently displayed
|
|
on the token.
|
|
In this case, the AS
|
|
queries an external RADIUS server
|
|
to check the response.
|
|
Use of a RADIUS server requires an entry in
|
|
the authentication database. For example:
|
|
.IP
|
|
.EX
|
|
radius=server-name secret=xyzzy
|
|
uid=howard rid=trickey
|
|
uid=sape rid=smullender
|
|
.EE
|
|
.IP
|
|
In this example, the secret
|
|
.B xyzzy
|
|
is the hash key used in talking to the RADIUS server.
|
|
The
|
|
.BR uid / rid
|
|
lines map from Plan 9 user ids to RADIUS ids.
|
|
Users not listed are assumed to have the
|
|
same id in both places.
|
|
.TP
|
|
.I S→A:
|
|
.IR AuthApop ,
|
|
.IR \- ,
|
|
.IR DN ,
|
|
.IR CHs ,
|
|
.IR IDs ,
|
|
.IR \-
|
|
.TP
|
|
.I A→S:
|
|
.IR AuthOKvar ,
|
|
.IR challenge
|
|
.TP
|
|
.I S→A:
|
|
.IR AuthApop ,
|
|
.IR \- ,
|
|
.IR DN ,
|
|
.IR CHs ,
|
|
.IR IDs ,
|
|
.IR IDc ;
|
|
hexadecimal MD5 checksum
|
|
.Ok
|
|
.IP
|
|
This protocol implements APOP authentication
|
|
(see
|
|
.IR pop3 (8)).
|
|
After receiving a ticket request of type
|
|
.IR AuthApop ,
|
|
the AS generates a random challenge
|
|
of the form
|
|
.BI < random @ domain >\fR.
|
|
The client then replies with a new ticket request
|
|
giving the user name
|
|
followed by the MD5 checksum of
|
|
the challenge concatenated with the user's secret.
|
|
If the response is correct, the authentication
|
|
server sends back a ticket
|
|
and authenticator.
|
|
If the response is incorrect, the client may repeat the
|
|
ticket request/MD5 checksum message to try again.
|
|
.IP
|
|
The
|
|
.I AuthCram
|
|
protocol runs identically to the
|
|
.I AuthApop
|
|
protocol, except that the expected MD5 checksum
|
|
is the keyed MD5 hash using the user's secret as the key
|
|
(see
|
|
.I hmac_md5
|
|
in
|
|
.IR sechash (2)).
|
|
.TP
|
|
.I S→A:
|
|
.IR AuthChap ,
|
|
.IR \- ,
|
|
.IR DN ,
|
|
.IR CHs ,
|
|
.IR IDs ,
|
|
.IR \-
|
|
.TP
|
|
.I A→S:
|
|
.I challenge
|
|
.TP
|
|
.I S→A:
|
|
.IR pktid ,
|
|
.IR IDc ,
|
|
.IR response
|
|
.Ok
|
|
.IP
|
|
This protocol implements CHAP authentication
|
|
(see
|
|
.IR ppp (8)).
|
|
The
|
|
.I challenge
|
|
is eight random bytes.
|
|
The response is a 16-byte MD5 checksum
|
|
over the packet id, user's secret, and challenge.
|
|
The reply packet is defined as
|
|
.B OChapreply
|
|
in
|
|
.BR <authsrv.h> .
|
|
.TP
|
|
.I S→A:
|
|
.IR AuthMSchap ,
|
|
.IR \- ,
|
|
.IR DN ,
|
|
.IR CHs ,
|
|
.IR IDs ,
|
|
.IR \-
|
|
.TP
|
|
.I A→S:
|
|
.I challenge
|
|
.TP
|
|
.I S→A:
|
|
.IR IDc ,
|
|
.IR lm-response ,
|
|
.IR nt-response
|
|
.Ok
|
|
.IP
|
|
This protocol implements Microsoft's MS-CHAP
|
|
authentication
|
|
(see
|
|
.IR ppp (8)).
|
|
The
|
|
.I challenge
|
|
is eight random bytes.
|
|
The two responses are Microsoft's LM and NT hashes.
|
|
Only the NT hash may be used to authenticate,
|
|
as the LM hash is considered too weak.
|
|
The reply packet is defined as
|
|
.B OMSchapreply
|
|
in
|
|
.BR <authsrv.h> .
|
|
.TP
|
|
.I S→A:
|
|
.IR AuthVNC ,
|
|
.IR \- ,
|
|
.IR DN ,
|
|
.IR CHs ,
|
|
.IR IDs ,
|
|
.IR IDc
|
|
.TP
|
|
.I A→S:
|
|
.IR AuthOKvar ,
|
|
.I challenge
|
|
.TP
|
|
.I S→A:
|
|
.I response
|
|
.Ok
|
|
.IP
|
|
This protocol implements VNC authentication
|
|
(see
|
|
.I vncs
|
|
in
|
|
.IR vnc (1)).
|
|
The challenge is 16 random bytes, and the response
|
|
is a DES ECB encryption of the challenge.
|
|
The method by which VNC converts the user's
|
|
secret into a DES key is weak,
|
|
considering only the first eight bytes of the secret.
|
|
.PD
|
|
.SH FILES
|
|
.TF /lib/ndb/auth.*xxx
|
|
.TP
|
|
.B /lib/ndb/auth
|
|
database file
|
|
.TP
|
|
.B /lib/ndb/auth.*
|
|
hash files for
|
|
.B /lib/ndb/auth
|
|
.SH SEE ALSO
|
|
.IR auth (2),
|
|
.IR fauth (2),
|
|
.IR cons (3),
|
|
.IR attach (5),
|
|
.IR auth (8)
|