code: 9ferno

ref: e16b4d85dd6b1cf14834387b765113114dabeae2
dir: /man/6/login/

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.TH LOGIN 6
.SH NAME
login \- key exchange protocol
.SH DESCRIPTION
The following encrypted key exchange protocol is used between a client such as
.B login
in
.IR security-login (2),
and a certificate signing process such as
.IR logind (8),
to justify the latter's issuing a certificate that can
later be presented to an Inferno service
to establish credentials.
.PP
A shared secret must previously be agreed between
user and certifying authority (CA).
It is used by the protocol to establish a secure channel between user and CA.
.PP
In the description below:
.TF key(m)
.PD
.TP
.I ivec
is an 8 byte random number (`initialisation vector') chosen for
this conversation.
.TP
.I sha
is the 20 byte secure hash (SHA-1) of the password
.TP
.I key
is an 8 byte secret formed as follows:
.EX
.br
key[0] = ivec[0]^sha[0]^sha[8]^sha[16]
key[1] = ivec[1]^sha[1]^sha[9]^sha[17]
.EE
\&...
.EX
key[5] = ivec[5]^sha[5]^sha[13];
key[6] = ivec[6]^sha[6]^sha[14];
key[7] = ivec[7]^sha[7]^sha[15];
.EE
.TP
.I alpha
is a Diffie-Hellman base used system wide
.TP
.I p
is a Diffie-Hellman modulus used system wide
.TP
.I "key(m)"
is
.I m
encrypted using the RC4 algorithm with
.IR key .
.TP
.I Rx
is a random number of the same order as
.IR p .
.TP
.I "secret"
is the Diffie-Hellman secret
.IR "alpha**(r0*r1) mod p" .
.PP
The protocol follows.  ``user→CA xxx'' means that the user
sends the message ``xxx'' to the certifying authority.
Any party can send an error instead of a message at any
point to terminate the protocol.
.IP
.EX
user→CA	name
CA→user	ACK
.sp 1v
user→CA	ivec
CA→user	key(alpha**r0 mod p), alpha, p
.sp 1v
user→CA	alpha**r1 mod p
CA→user	CA's public key, SHA(CA's public key + secret)
.sp 1v
user→CA	user's public key, SHA(user's public key + secret)
CA→user	user's public key certificate
.EE
.PP
The complexity of this protocol is intended to shield the password.
To start a clear text attack against the password, one
needs to first attack the Diffie-Hellman exponential
to determine
.IR "alpha**r0 mod p" .
A possible weakness is that the encrypted quantity
is base64 encoded, constraining
the possible values of each byte.
This could aid a brute force attack.
.PP
.I Alpha
and
.I p
are sent unprotected, though the user code does a few sanity checks
on the values it receives.
This is another likely point of attack.
We should like to know about any.
.PP
The role of
.I ivec
is to foil any replay attacks by someone spoofing the CA
though this is probably overkill.
.SH SEE ALSO
.IR security-intro (2),
.IR security-login (2),
.IR logind (8),
.IR signer (8)