mirror of
https://git.FreeBSD.org/src.git
synced 2024-12-27 11:55:06 +00:00
341 lines
14 KiB
Groff
341 lines
14 KiB
Groff
.\" opie.4: Overview of the OPIE software.
|
|
.\"
|
|
.\" %%% portions-copyright-cmetz-96
|
|
.\" Portions of this software are Copyright 1996-1999 by Craig Metz, All Rights
|
|
.\" Reserved. The Inner Net License Version 2 applies to these portions of
|
|
.\" the software.
|
|
.\" You should have received a copy of the license with this software. If
|
|
.\" you didn't get a copy, you may request one from <license@inner.net>.
|
|
.\"
|
|
.\" Portions of this software are Copyright 1995 by Randall Atkinson and Dan
|
|
.\" McDonald, All Rights Reserved. All Rights under this copyright are assigned
|
|
.\" to the U.S. Naval Research Laboratory (NRL). The NRL Copyright Notice and
|
|
.\" License Agreement applies to this software.
|
|
.\"
|
|
.\" History:
|
|
.\"
|
|
.\" Modified by cmetz for OPIE 2.4. Spelling fixes.
|
|
.\" Modified by cmetz for OPIE 2.2. Removed MJR DES documentation. Removed
|
|
.\" references to the old square brackets challenge delimiters.
|
|
.\" Modified at NRL for OPIE 2.01. Updated UNIX trademark credit.
|
|
.\" Definition of "seed" written by Neil Haller of Bellcore
|
|
.\" Written at NRL for OPIE 2.0.
|
|
.\"
|
|
.\" $FreeBSD$
|
|
.\"
|
|
.TH OPIE 4 "January 10, 1995"
|
|
.SH NAME
|
|
.B OPIE \- One-time Passwords In Everything
|
|
.SH DESCRIPTION
|
|
.LP
|
|
OPIE is a package derived from the Bellcore S/Key Version 1 distribution
|
|
that helps to secure a system against replay attacks (see below). It does so
|
|
using a secure hash function and a challenge/response system. It provides
|
|
replacements for the
|
|
.IR login (1),
|
|
.IR su (1),
|
|
and
|
|
.IR ftpd (8)
|
|
programs that use OPIE
|
|
authentication as well as demonstrate how a program might be adapted to use
|
|
OPIE authentication. OPIE was developed at and for the United States Naval
|
|
Research Laboratory (NRL). OPIE is derived in part from Berkeley Standard
|
|
Distribution UNIX and the Bellcore S/Key Version 1 distribution.
|
|
.LP
|
|
From the average user's perspective, OPIE is a nuisance that prevents their
|
|
account from being broken into. The first time a user wishes to use OPIE,
|
|
(s)he needs to use the
|
|
.IR opiepasswd (1)
|
|
command to put an entry for them into
|
|
the OPIE database. The user can then use OPIE to authenticate themselves
|
|
with any program that supports it. If no other clients are being used,
|
|
this means they can use OPIE to
|
|
.I telnet,
|
|
.I rlogin,
|
|
or
|
|
.I ftp
|
|
into the system,
|
|
log in on a terminal port (like a modem), or switch to another user's
|
|
account. When they would normally be asked for a password, they will get
|
|
a challenge from the server. They then need to copy that challenge (or
|
|
re-type, if they don't have the ability to copy and paste through something
|
|
like a window system) to their calculator program, enter their password,
|
|
then copy (or re-type) the response from the calculator as their password.
|
|
While this will seem cumbersome at first, with some practice, it becomes
|
|
easy.
|
|
|
|
.SH TERMS
|
|
.TP
|
|
.I user name
|
|
The name that the system knows you as. For example, "jdoe".
|
|
.TP
|
|
.I secret password
|
|
A password, usually selected by the user, that is needed to gain access to the
|
|
system. For example, "SEc1_rt".
|
|
.TP
|
|
.I challenge
|
|
A packet of information output by a system when it wishes to authenticate a
|
|
user. In OPIE, this is a three-item group consisting of a hash identifier,
|
|
a sequence number, and a seed. This
|
|
information is needed by the OPIE calculator to generate a proper response.
|
|
For example, "otp-md5 95 wi14321".
|
|
.TP
|
|
.I response
|
|
A packet of information generated from a challenge that is used by a system to
|
|
authenticate a user. In OPIE, this is a group of six words that is generated by
|
|
the calculator given the challenge and the secret password. For example,
|
|
"PUP SOFT ROSE BIAS FLAG END".
|
|
.TP
|
|
.I seed
|
|
A piece of information that is used in conjunction with the secret password
|
|
and sequence number to compute the response. Its purpose is to allow the same
|
|
secret password to be used for multiple sequences, by changing the seed, or
|
|
for authentication to multiple machines by using different seeds.
|
|
.TP
|
|
.I sequence number
|
|
A counter used to keep track of key iterations. In OPIE, each time a successful
|
|
response is received by the system, the sequence number is decremented. For
|
|
example, "95".
|
|
.TP
|
|
.I hash identifier
|
|
A piece of text that identifies the actual algorithm that needs to be used to
|
|
generate a proper response. In OPIE, the only two valid hash identifiers are
|
|
"otp-md4", which selects MD4 hashing, and "otp-md5", which selects MD5.
|
|
|
|
.SH REPLAY ATTACKS
|
|
When you use a network terminal program like
|
|
.IR telnet (1)
|
|
or even use a modem to log into a
|
|
computer system, you need a user name and a secret password. Anyone who can
|
|
provide those to the system is recognized as you because, in theory, only you
|
|
would have your secret password. Unfortunately, it is now easy to listen in
|
|
on many computer communications media. From modem communication to many
|
|
networks, your password is not usually safe over remote links. If a
|
|
cracker can listen in when you send your password, (s)he then has a copy
|
|
of your password that can be used at any time in the future to access your
|
|
account. On more than one occasion, major sites on the Internet have been
|
|
broken into exactly this way.
|
|
.LP
|
|
All an attacker has to
|
|
do is capture your password once and then replay it to the server when it's
|
|
asked for. Even if the password is communicated between machines in encoded
|
|
or encrypted form, as long as a cracker can get in by simply replaying
|
|
a previously captured communication, you are at risk. Up until very recently,
|
|
Novell NetWare was vulnerable this way. A cracker couldn't find out what your
|
|
password actually is, but (s)he didn't need to -- all that was necessary to
|
|
get into your account was to capture the encrypted password and send that
|
|
back to the server when asked for it.
|
|
|
|
.SH ONE-TIME PASSWORDS
|
|
One solution to the problem of replay attacks
|
|
is to keep changing the way that a password is being encoded so that what is
|
|
sent over the link to another system can only be used once. If you can do that,
|
|
then a cracker can replay it as many times as (s)he wants -- it's just not
|
|
going to get them anywhere. It's important, however, to make sure you encode
|
|
the password in such a way that the cracker can't use the encoded version to
|
|
figure out what the password is or what a future encoded password will be.
|
|
Otherwise, while still an improvement over no encoding or a fixed encoding,
|
|
you can still be broken into.
|
|
|
|
.SH THE S/KEY ALGORITHM
|
|
|
|
A solution to this whole problem was invented by Lamport in 1981. This
|
|
technique was implemented by Haller, Karn, and Walden at Bellcore. They
|
|
created a free software package called "S/Key" that used an algorithm
|
|
called a cryptographic checksum. A cryptographic checksum is a strong one-way
|
|
function such that, knowing the result of such a function, an attacker still
|
|
cannot feasibly determine the input. Further, unlike cyclic redundancy
|
|
checksums (CRCs), cryptographic checksums have few inputs that result in the
|
|
same output.
|
|
.LP
|
|
In S/Key, what changes is the number of
|
|
times the password is run through the secure hash. The password is run through
|
|
the secure hash once, then the output of the hash is run through the secure
|
|
hash again, that output is run through the secure hash again, and so on until
|
|
the number of times the password has been run through the secure hash is equal
|
|
to the desired sequence number. This is much slower than just, say, putting
|
|
the sequence number in before the password and running that through the secure
|
|
hash once, but it gains you one significant benefit. The server machine you
|
|
are trying to connect to has to have some way to determine whether the output
|
|
of that whole mess is right. If it stores it either without any encoding or
|
|
with a normal encoding, a cracker could still get at your password. But if it
|
|
stores it with a secure hash, then how does it account for the response
|
|
changing every time because the sequence number is changing? Also what if you
|
|
can never get to the machine any way that can't be listened in on? How do you
|
|
change your password without sending it over the link?
|
|
.LP
|
|
The clever solution
|
|
devised by Lamport is to keep in mind that the sequence number is
|
|
always decrementing by one and that, in the S/Key system, simply by running any
|
|
response with a sequence number N through the secure hash, you can get the
|
|
response with a sequence number N+1, but you can't go the other way. At any
|
|
given time, call the sequence number of the last valid response that the
|
|
system got N+1 and the sequence number of the response you are giving it N.
|
|
If the password that generated the response for N is the same as the one for
|
|
N+1, then you should be able to run the response for N through the secure hash
|
|
one more time, for a total of N+1 times, and get the same response as you got
|
|
back for N+1. Once you compare the two and find that they are the same, you
|
|
subtract one from N so that, now, the key for N that you just verified becomes
|
|
the new key for N+1 that you can store away to use the next time you need to
|
|
verify a key. This also means that if you need to change your password but
|
|
don't have a secure way to access your machine, all the system really needs to
|
|
have to verify your password is a valid response for one more than the sequence
|
|
number you want to start with.
|
|
.LP
|
|
Just for good measure, each side of
|
|
all of this uses a seed in conjunction with your password when it actually
|
|
generates and verifies the responses. This helps to jumble things up a little
|
|
bit more, just in case. Otherwise, someone with a lot of time and disk space
|
|
on their hands could generate all the responses for a lot of frequent passwords
|
|
and defeat the system.
|
|
.LP
|
|
This is not, by any means, the best explanation of how the S/Key algorithm
|
|
works or some of the more minor details. For that, you should go to some of
|
|
the papers now published on the topic. It is simply a quick-and-dirty
|
|
introduction to what's going on under the hood.
|
|
|
|
.SH OPIE COMPONENTS
|
|
|
|
The OPIE distribution has been incorporated into three standard client
|
|
programs:
|
|
.IR login (1),
|
|
.IR su (1),
|
|
and
|
|
.IR ftpd (8),
|
|
.LP
|
|
There are also three programs in the OPIE distribution that are specific to
|
|
the OPIE system:
|
|
.IR opiepasswd (1),
|
|
which allows a user to set and change their
|
|
OPIE password,
|
|
.IR opieinfo (1),
|
|
which allows a user to find out what their current
|
|
sequence number and seed are, and
|
|
.IR opiekey(1),
|
|
which is an OPIE key calculator.
|
|
|
|
.SH ADDING OPIE TO OTHER PROGRAMS
|
|
|
|
Adding OPIE authentication to programs other than the ones included as clients
|
|
in the OPIE distribution isn't very difficult. First, you will need to make
|
|
sure that the program includes <stdio.h> somewhere. Then, below the other
|
|
includes such as <stdio.h>, but before variable declarations, you need to
|
|
include <opie.h>. You need to add a variable of type "struct opie" to your
|
|
program, you need to make sure that the buffer that you use to get a password
|
|
from the user is big enough to hold OPIE_RESPONSE_MAX+1 characters, and you
|
|
need to have a buffer in which to store the challenge string that is big enough
|
|
to hold OPIE_CHALLENGE_MAX+1 characters.
|
|
.LP
|
|
When you are ready to output the challenge string and know the user's name,
|
|
you would use a call to opiechallenge. Later, to verify the response received,
|
|
you would use a call to opieverify. For example:
|
|
.sp 0
|
|
|
|
.sp 0
|
|
#include <stdio.h>
|
|
.sp 0
|
|
.
|
|
.sp 0
|
|
.
|
|
.sp 0
|
|
#include <opie.h>
|
|
.sp 0
|
|
.
|
|
.sp 0
|
|
.
|
|
.sp 0
|
|
char *user_name;
|
|
.sp 0
|
|
/* Always remember the trailing null! */
|
|
.sp 0
|
|
char password[OPIE_RESPONSE_MAX+1];
|
|
.sp 0
|
|
.
|
|
.sp 0
|
|
.
|
|
.sp 0
|
|
struct opie opiedata;
|
|
.sp 0
|
|
char opieprompt[OPIE_CHALLENGE_MAX+1];
|
|
.sp 0
|
|
.
|
|
.sp 0
|
|
.
|
|
.sp 0
|
|
opiechallenge(&opiedata, user_name, opieprompt);
|
|
.sp 0
|
|
.
|
|
.sp 0
|
|
.
|
|
.sp 0
|
|
if (opieverify(&opiedata, password)) {
|
|
.sp 0
|
|
printf("Login incorrect");
|
|
.sp 0
|
|
.SH TERMINAL SECURITY AND OPIE
|
|
|
|
When using OPIE, you need to be careful not to allow your password to be
|
|
communicated over an insecure channel where someone might be able to listen
|
|
in and capture it. OPIE can protect you against people who might get your
|
|
password from snooping on the line, but only if you make sure that the password
|
|
itself never gets sent over the line. The important thing is to always run the
|
|
OPIE calculator on whichever machine you are actually using - never on a machine
|
|
you are connected to by network or by dialup.
|
|
.LP
|
|
You need to be careful about the
|
|
X Window System, because it changes things quite a bit. For instance, if you
|
|
run an xterm (or your favorite equivalent) on another machine and display it
|
|
on your machine, you should not run an OPIE calculator in that window. When you
|
|
type in your secret password, it still gets transmitted over the network to go
|
|
to the machine the xterm is running on. People with machines such as
|
|
X terminals that can only run the calculator over the network are in an
|
|
especially precarious position because they really have no choice. Also, with
|
|
the X Window System, as with some other window system (NeWS as an example),
|
|
it is sometimes possible for people to read your keystrokes and capture your
|
|
password even if you are running the OPIE calculator on your local machine.
|
|
You should always use the best security mechanism available on your system to
|
|
protect your X server, be it XDM-AUTHORIZATION-1, XDM-MAGIC-COOKIE-1, or host
|
|
access control. *Never* just allow any machine to connect to your server
|
|
because, by doing so, you are allowing any machine to read any of your windows
|
|
or your keystrokes without you knowing it.
|
|
|
|
.SH SEE ALSO
|
|
.BR ftpd (8)
|
|
.BR login (1),
|
|
.BR opie (4),
|
|
.BR opiekeys (5),
|
|
.BR opieaccess (5),
|
|
.BR opiekey (1),
|
|
.BR opieinfo (1),
|
|
.BR opiepasswd (1),
|
|
.sp
|
|
Lamport, L. "Password Authentication with Insecure Communication",
|
|
Communications of the ACM 24.11 (November 1981), pp. 770-772.
|
|
.sp
|
|
Haller, N. "The S/KEY One-Time Password System", Proceedings of the ISOC
|
|
Symposium on Network and Distributed System Security, February 1994,
|
|
San Diego, CA.
|
|
.sp
|
|
Haller, N. and Atkinson, R, "On Internet Authentication", RFC-1704,
|
|
DDN Network Information Center, October 1994.
|
|
.sp
|
|
Rivest, R. "The MD5 Message Digest Algorithm", RFC-1321,
|
|
DDN Network Information Center, April 1992.
|
|
.sp
|
|
Rivest, R. "The MD4 Message Digest Algorithm", RFC-1320,
|
|
DDN Network Information Center, April 1992.
|
|
|
|
.SH AUTHOR
|
|
Bellcore's S/Key was written by Phil Karn, Neil M. Haller, and John S. Walden
|
|
of Bellcore. OPIE was created at NRL by Randall Atkinson, Dan McDonald, and
|
|
Craig Metz.
|
|
|
|
S/Key is a trademark of Bell Communications Research (Bellcore).
|
|
UNIX is a trademark of X/Open.
|
|
|
|
.SH CONTACT
|
|
OPIE is discussed on the Bellcore "S/Key Users" mailing list. To join,
|
|
send an email request to:
|
|
.sp
|
|
skey-users-request@thumper.bellcore.com
|