ref: d9b9e15d6bbdae625b3613bb0a704d269cc83098
dir: /sys/man/6/authsrv/
.TH AUTHSRV 6 .SH NAME authsrv, p9any, p9sk1, dp9ik \- authentication protocols .SH DESCRIPTION This manual page describes the protocols used to authorize connections, confirm the identities of users and machines, and maintain the associated databases. The machine that provides these services is called the .I authentication server (AS). The AS may be a stand-alone machine or a general-use machine such as a CPU server. The network database .IR ndb (6) holds for each public machine, such as a CPU server or file server, the name of the authentication server that machine uses. .PP Each machine contains four values important to authentication; a 56-bit DES key, a 128-bit AES key, a 28-byte authentication ID, and a 48-byte authentication domain name. The ID is a user name and identifies who is currently responsible for the kernel running on that machine. The domain name identifies the machines across which the ID is valid. Together, the ID and domain name identify the owner of a key. .PP When a terminal boots, .IR factotum (4) prompts for user name and password. The user name becomes the terminal's authentication ID. The password is converted using .I passtokey (see .IR authsrv (2)) into a 56-bit DES and 128-bit AES keys and saved in memory. The authentication domain is set to the null string. If possible, .I factotum validates the key with the AS before saving it. For Internet machines the correct AS to ask is found using .IR dhcpd (8). .PP When a CPU or file server boots, .I factotum reads the key, ID, and domain name from non-volatile RAM. This allows servers to reboot without operator intervention. .PP The details of any authentication are mixed with the semantics of the particular service they are authenticating so we describe them one case at a time. The following definitions will be used in the descriptions: .TF nullx .TP .I Ks server's host ID's key .TP .I Kc client's host ID's key .TP .I Kn a nonce key created for a ticket .RB ( key ) .TP .I K{m} message .I m encrypted with key .I K .TP .I CHc an 8-byte random challenge from a client .RB ( chal ) .TP .I CHs an 8-byte random challenge from a server .RB ( chal ) .TP .I IDs server's ID .RB ( authid ) .TP .I DN server's authentication domain name .RB ( authdom ) .TP .I IDc client's ID .RB ( hostid , .BR cuid ) .TP .I IDr client's desired ID on server .RB ( uid , .BR suid ) .TP .I YAc client → AS DH public key .TP .I YBc AS → client DH public key .TP .I YAs server → AS DH public key .TP .I YBs AS → server DH public key .TP .I RNc client's 32-byte random string .TP .I RNs server's 32-byte random string .PD .PP The parenthesized names are the ones used in the .B Ticketreq and .B Ticket structures in .BR <authsrv.h> . .PP The message type constants .IR AuthTreq , .IR AuthChal , .IR AuthPass , .IR AuthOK , .IR AuthErr , .IR AuthMod , .IR AuthApop , .IR AuthOKvar , .IR AuthChap , .IR AuthMSchap , .IR AuthCram , .IR AuthVNC , and .IR AuthPAK .RB ( type ) are defined in .BR <authsrv.h> , as are the encrypted message types .IR AuthTs , .IR AuthAs , .IR AuthAc , .IR AuthTp , and .IR AuthHr .RB ( num ). .SS "Ticket Service When a client and server wish to authenticate to each other, they do so using .I tickets issued by the AS. Obtaining tickets from the AS is the client's responsibility. .PP The protocol to obtain a ticket pair is: .TP .I C→A: .IR AuthTreq , .IR IDs , .IR DN , .IR CHs , .IR IDc , .IR IDr .TP .I A→C: .IR AuthOK , .IR Kc { AuthTc , .IR CHs , .IR IDc , .IR IDr , .IR Kn }, .IR Ks { AuthTs , .IR CHs , .IR IDc , .IR IDr , .IR Kn } .PP The two tickets are identical except for their type fields and the keys with which they are encrypted. The client and server can each decrypt one of the tickets, establishing a shared secret .IR Kn . .PP The tickets can be viewed as a statement by the AS that ``a client possessing the .I Kn key is allowed to authenticate as .IR IDr .'' .PP The presence of the server challenge .I CHs in the ticket allows the server to verify the freshness of the ticket pair. .PP The AS sets the .I IDr in the tickets to the requested .I IDr only if .I IDc is allowed to .I "speak for .RI ( q.v. ) .IR IDr . If not, the AS sets .I IDr to the empty string. .PP If the users .I IDc or .I IDs do not exist, the AS silently generates one-time random keys to use in place of .I Kc or .IR Ks , so that clients cannot probe the AS to learn whether a user name is valid. .SS "P9sk1 The Plan 9 shared key protocol .I p9sk1 allows a client and server to authenticate each other. The protocol is: .TP .I C→S: .I CHc .br The client starts by sending a random challenge to the server. .TP .I S→C: .IR AuthTreq , .IR IDs , .IR DN , .IR CHs , .IR \- , .IR \- .br The server replies with a ticket request giving its id and authentication domain along with its own random challenge. .TP .I C→S: .IR Ks { AuthTs , .IR CHs , .IR IDc , .IR IDr , .IR Kn }, .IR Kn { AuthAc , .IR CHs } .br The client adds .I IDc and .I IDr to the ticket request and obtains a ticket pair from the AS as described above. The client relays the server's ticket along with an .IR authenticator , the .I AuthAc message. The authenticator proves to the server that the client knows .I Kn and is therefore allowed to authenticate as .IR IDr . (The inclusion of .IR CHs in the authenticator avoids replay attacks.) .TP .I S→C: .IR Kn { AuthAs , .IR CHc } .br The server replies with its own authenticator, proving to the client that it also knows .I Kn and therefore .I Ks . .PP The 64-bit shared secret .I Kn is used as the session secret. .SS "Password authenticated key exchange" Initially, the server and client keys .I Ks and .I Kc were equivalent to the password derived 56-bit DES keys, which made the encrypted tickets subject to offline dictionary attacks and provided too small a key space against brute force attacks on current hardware. .PP The .I AuthPAK protocol is used to establish new 256-bit random keys with the AS for .I Ks and .I Kc before each ticket request on the connection. .PP The protocol is based on SPAKE2EE, where a hash of the user's secret is used to encypt the public keys of a Elliptic-Curve Diffie-Hellman key exchange. The user's .I ID and 128-bit AES key is hashed and mapped (using Elligator2) into two curve points .I PM and .IR PN , called the .IR pakhash . Both sides generate a random number .IR xa / xb and make the public keys .IR YA / YB as: .IR YA = xa*G+PM , .IR YB = xb*G+PN . After the public keys have been exchanged, each side calculates the shared secret as: .IR Z = xa*(YB-PN) = xb*(YA-PM) . The shared secret .I Z is then hashed with the transmitted public keys .IR YA | YB producing the 256-bit .IR pakkey . .PP The .I pakkey is then used in place of .I Ks and .I Kc to authenticate and encrypt tickets from the AS using Chacha20/Poly1305 AEAD for the next following request made on the connection. .PP The protocol (for .IR AuthTreq ) to establish keys .I Ks and .I Kc with the AS for .I IDs and .I IDc is: .TP .I C→A: .IR AuthPAK , .IR IDs , .IR DN , .IR CHs , .IR IDc , .IR IDr , .IR YAs , .I YAc .TP .I A→C: .IR AuthOK , .IR YBs , .I YBc .PP The protocol (for .IR AuthApop , .IR AuthChap ...) to establish a single server key .I Ks for .IR IDs : .TP .I C→A: .IR AuthPAK , .IR \- , .IR DN , .IR CHs , .IR IDs , .IR IDc , .I YAs .TP .I A→C: .IR AuthOK , .I YBs .PP The protocol (for .IR AuthPass ) to establish a single client key .I Kc for .IR IDc : .TP .I C→A: .IR AuthPAK , .IR \- , .IR \- , .IR CHc , .IR \- , .IR IDc , .I YAc .TP .I A→C: .IR AuthOK , .I YBc .SS "Dp9ik" The .I dp9ik protocol is an extended version of .I p9sk1 that adds the random strings .I RNc and .I RNs in the .I authenticator messages for the session key derivation and uses the password authenticated key exchange as described above to derive the ticket encryption keys .I Ks and .IR Kc : .TP .I C→S: .I CHc .br The client starts by sending a random challenge to the server. .TP .I S→C: .IR AuthPAK , .IR IDs , .IR DN , .IR CHs , .IR \- , .IR \- , .IR YAs .br The server generates a new public key .I YAs and replies with a .I AuthPAK request giving its .I IDs and authentication domain .I DNs along with its own random challenge .I CHs and its public key .IR YAs . .TP .I C→S: .IR YBs , .IR Ks { AuthTs , .IR CHs , .IR IDc , .IR IDr , .IR Kn }, .IR Kn { AuthAc , .IR CHs , .IR RNc } .br The client generates its own public key .I YAc and adds it along with .I IDc and .I IDr to the .I AuthPAK request and obtains the public keys .I YBs and .I YBc from the AS response. At this point, client and AS have completed their authenticated key exchange and derive .I Kc as described above. Then the client requests a ticket pair using the same message but with .I AuthPAK type changed to .IR AuthTreq . It decrypts his ticket with .I Kc extracting the shared secret .IR Kn . The client relays the server's .I YBs and ticket along with an .IR authenticator , the .I AuthAc message. The server finishes his authenticated key exchange using .I YBs and derives .I Ks to decrypt his ticket to extract the shared secret .IR Kn . When the decryption of the clients authenticator using .I Kn is successfull then this proves to the server that the client knows .I Kn and is therefore allowed to authenticate as .IR IDr . The random string .I RNc is used in the derivation of the session secret. .TP .I S→C: .IR Kn { AuthAs , .IR CHc , .IR RNs } .br The server replies with its own authenticator, proving to the client that it also knows .I Kn and contributes its random string .IR RNs for the session secret. .PP The 2048-bit session secret is derived with HKDF-SHA256 hashing the concatenated random strings .IR RNc | RNs with the the shared secret key .IR Kn . .SS "P9any .I P9any is the standard Plan 9 authentication protocol. It consists of a negotiation to determine a common protocol, followed by the agreed-upon protocol. .PP The negotiation protocol is: .TP .I S→C: .IB proto@authdom .IB proto@authdom .I ... .TP .I C→S: .I proto .I dom .PP Each message is a NUL-terminated UTF string. The server begins by sending a list of .IR proto , .I authdom pairs it is willing to use. The client responds with its choice. .PP A second version of this protocol exists (indicated by the .B v.2 prefix before the list) where the server sends an explicit confirmation with a OK message before the agreed-upon protocol starts. .TP .I S→C: .B v.2 .IB proto@authdom .IB proto@authdom .I ... .TP .I C→S: .I proto .I dom .TP .I S→C: .B OK .PP The .I p9any protocol is the protocol used by all Plan 9 services. The file server runs it over special authentication files (see .IR fauth (2) and .IR attach (5)). Other services, such as .IR cpu (1), .IR exportfs (4) and .IR tlssrv (8) run .I p9any over the network and then use the session secret to derive an .IR ssl (3) or .IR tls (3) 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 \- , .IR \- , .IR CHc , .IR \- , .IR IDc .br 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)