a520dd9199
MFC after: 1 week
1004 lines
33 KiB
Groff
1004 lines
33 KiB
Groff
.\" Copyright (C) 1998 Matthew Dillon. All rights reserved.
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.\"
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.\" Redistribution and use in source and binary forms, with or without
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.\" modification, are permitted provided that the following conditions
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.\" are met:
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.\" 1. Redistributions of source code must retain the above copyright
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.\" notice, this list of conditions and the following disclaimer.
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.\" 2. Redistributions in binary form must reproduce the above copyright
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.\" notice, this list of conditions and the following disclaimer in the
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.\" documentation and/or other materials provided with the distribution.
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.\"
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.\" THIS SOFTWARE IS PROVIDED BY AUTHOR AND CONTRIBUTORS ``AS IS'' AND
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.\" ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
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.\" IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
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.\" ARE DISCLAIMED. IN NO EVENT SHALL AUTHOR OR CONTRIBUTORS BE LIABLE
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.\" FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL
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.\" DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS
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.\" OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION)
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.\" HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT
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.\" LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY
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.\" OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF
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.\" SUCH DAMAGE.
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.\"
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.\" $FreeBSD$
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.\"
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.Dd December 25, 2013
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.Dt SECURITY 7
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.Os
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.Sh NAME
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.Nm security
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.Nd introduction to security under FreeBSD
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.Sh DESCRIPTION
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Security is a function that begins and ends with the system administrator.
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While all
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.Bx
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multi-user systems have some inherent security, the job of building and
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maintaining additional security mechanisms to keep users
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.Dq honest
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is probably
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one of the single largest undertakings of the sysadmin.
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Machines are
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only as secure as you make them, and security concerns are ever competing
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with the human necessity for convenience.
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.Ux
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systems,
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in general, are capable of running a huge number of simultaneous processes
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and many of these processes operate as servers \(em meaning that external
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entities can connect and talk to them.
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As yesterday's mini-computers and mainframes
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become today's desktops, and as computers become networked and internetworked,
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security becomes an ever bigger issue.
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.Pp
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Security is best implemented through a layered onion approach.
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In a nutshell,
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what you want to do is to create as many layers of security as are convenient
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and then carefully monitor the system for intrusions.
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.Pp
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System security also pertains to dealing with various forms of attacks,
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including attacks that attempt to crash or otherwise make a system unusable
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but do not attempt to break root.
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Security concerns can be split up into
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several categories:
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.Bl -enum -offset indent
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.It
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Denial of Service attacks (DoS)
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.It
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User account compromises
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.It
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Root compromise through accessible servers
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.It
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Root compromise via user accounts
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.It
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Backdoor creation
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.El
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.Pp
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A denial of service attack is an action that deprives the machine of needed
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resources.
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Typically, DoS attacks are brute-force mechanisms that attempt
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to crash or otherwise make a machine unusable by overwhelming its servers or
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network stack.
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Some DoS attacks try to take advantages of bugs in the
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networking stack to crash a machine with a single packet.
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The latter can
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only be fixed by applying a bug fix to the kernel.
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Attacks on servers can
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often be fixed by properly specifying options to limit the load the servers
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incur on the system under adverse conditions.
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Brute-force network attacks are harder to deal with.
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A spoofed-packet attack, for example, is
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nearly impossible to stop short of cutting your system off from the Internet.
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It may not be able to take your machine down, but it can fill up your Internet
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pipe.
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.Pp
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A user account compromise is even more common than a DoS attack.
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Many
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sysadmins still run standard
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.Xr telnetd 8 ,
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.Xr rlogind 8 ,
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.Xr rshd 8 ,
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and
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.Xr ftpd 8
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servers on their machines.
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These servers, by default, do not operate over encrypted
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connections.
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The result is that if you have any moderate-sized user base,
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one or more of your users logging into your system from a remote location
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(which is the most common and convenient way to log in to a system)
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will have his or her password sniffed.
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The attentive system administrator will analyze
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his remote access logs looking for suspicious source addresses
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even for successful logins.
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.Pp
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One must always assume that once an attacker has access to a user account,
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the attacker can break root.
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However, the reality is that in a well secured
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and maintained system, access to a user account does not necessarily give the
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attacker access to root.
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The distinction is important because without access
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to root the attacker cannot generally hide his tracks and may, at best, be
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able to do nothing more than mess with the user's files or crash the machine.
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User account compromises are very common because users tend not to take the
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precautions that sysadmins take.
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.Pp
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System administrators must keep in mind that there are potentially many ways
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to break root on a machine.
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The attacker may know the root password,
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the attacker
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may find a bug in a root-run server and be able to break root over a network
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connection to that server, or the attacker may know of a bug in an SUID-root
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program that allows the attacker to break root once he has broken into a
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user's account.
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If an attacker has found a way to break root on a machine,
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the attacker may not have a need to install a backdoor.
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Many of the root holes found and closed to date involve a considerable amount
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of work by the attacker to clean up after himself, so most attackers do install
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backdoors.
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This gives you a convenient way to detect the attacker.
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Making
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it impossible for an attacker to install a backdoor may actually be detrimental
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to your security because it will not close off the hole the attacker used to
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break in originally.
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.Pp
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Security remedies should always be implemented with a multi-layered
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.Dq onion peel
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approach and can be categorized as follows:
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.Bl -enum -offset indent
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.It
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Securing root and staff accounts
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.It
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Securing root \(em root-run servers and SUID/SGID binaries
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.It
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Securing user accounts
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.It
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Securing the password file
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.It
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Securing the kernel core, raw devices, and file systems
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.It
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Quick detection of inappropriate changes made to the system
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.It
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Paranoia
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.El
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.Sh SECURING THE ROOT ACCOUNT AND SECURING STAFF ACCOUNTS
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Do not bother securing staff accounts if you have not secured the root
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account.
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Most systems have a password assigned to the root account.
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The
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first thing you do is assume that the password is
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.Em always
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compromised.
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This does not mean that you should remove the password.
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The
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password is almost always necessary for console access to the machine.
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What it does mean is that you should not make it possible to use the password
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outside of the console or possibly even with a
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.Xr su 1
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utility.
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For example, make sure that your PTYs are specified as being
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.Dq Li insecure
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in the
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.Pa /etc/ttys
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file
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so that direct root logins via
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.Xr telnet 1
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or
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.Xr rlogin 1
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are disallowed.
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If using
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other login services such as
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.Xr sshd 8 ,
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make sure that direct root logins are
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disabled there as well.
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Consider every access method \(em services such as
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.Xr ftp 1
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often fall through the cracks.
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Direct root logins should only be allowed
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via the system console.
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.Pp
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Of course, as a sysadmin you have to be able to get to root, so we open up
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a few holes.
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But we make sure these holes require additional password
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verification to operate.
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One way to make root accessible is to add appropriate
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staff accounts to the
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.Dq Li wheel
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group (in
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.Pa /etc/group ) .
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The staff members placed in the
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.Li wheel
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group are allowed to
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.Xr su 1
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to root.
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You should never give staff
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members native
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.Li wheel
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access by putting them in the
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.Li wheel
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group in their password entry.
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Staff accounts should be placed in a
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.Dq Li staff
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group, and then added to the
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.Li wheel
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group via the
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.Pa /etc/group
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file.
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Only those staff members who actually need to have root access
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should be placed in the
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.Li wheel
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group.
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It is also possible, when using an
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authentication method such as Kerberos, to use Kerberos's
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.Pa .k5login
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file in the root account to allow a
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.Xr ksu 1
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to root without having to place anyone at all in the
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.Li wheel
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group.
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This
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may be the better solution since the
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.Li wheel
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mechanism still allows an
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intruder to break root if the intruder has gotten hold of your password
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file and can break into a staff account.
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While having the
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.Li wheel
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mechanism
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is better than having nothing at all, it is not necessarily the safest
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option.
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.Pp
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An indirect way to secure the root account is to secure your staff accounts
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by using an alternative login access method and *'ing out the crypted password
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for the staff accounts.
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This way an intruder may be able to steal the password
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file but will not be able to break into any staff accounts or root, even if
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root has a crypted password associated with it (assuming, of course, that
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you have limited root access to the console).
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Staff members
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get into their staff accounts through a secure login mechanism such as
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.Xr kerberos 8
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or
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.Xr ssh 1
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using a private/public
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key pair.
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When you use something like Kerberos you generally must secure
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the machines which run the Kerberos servers and your desktop workstation.
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When you use a public/private key pair with SSH, you must generally secure
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the machine you are logging in
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.Em from
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(typically your workstation),
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but you can
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also add an additional layer of protection to the key pair by password
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protecting the keypair when you create it with
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.Xr ssh-keygen 1 .
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Being able
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to *-out the passwords for staff accounts also guarantees that staff members
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can only log in through secure access methods that you have set up.
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You can
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thus force all staff members to use secure, encrypted connections for
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all their sessions which closes an important hole used by many intruders: that
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of sniffing the network from an unrelated, less secure machine.
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.Pp
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The more indirect security mechanisms also assume that you are logging in
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from a more restrictive server to a less restrictive server.
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For example,
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if your main box is running all sorts of servers, your workstation should not
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be running any.
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In order for your workstation to be reasonably secure
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you should run as few servers as possible, up to and including no servers
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at all, and you should run a password-protected screen blanker.
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Of course, given physical access to
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a workstation, an attacker can break any sort of security you put on it.
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This is definitely a problem that you should consider but you should also
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consider the fact that the vast majority of break-ins occur remotely, over
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a network, from people who do not have physical access to your workstation or
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servers.
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.Pp
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Using something like Kerberos also gives you the ability to disable or
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change the password for a staff account in one place and have it immediately
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affect all the machines the staff member may have an account on.
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If a staff
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member's account gets compromised, the ability to instantly change his
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password on all machines should not be underrated.
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With discrete passwords, changing a password on N machines can be a mess.
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You can also impose
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re-passwording restrictions with Kerberos: not only can a Kerberos ticket
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be made to timeout after a while, but the Kerberos system can require that
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the user choose a new password after a certain period of time
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(say, once a month).
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.Sh SECURING ROOT \(em ROOT-RUN SERVERS AND SUID/SGID BINARIES
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The prudent sysadmin only runs the servers he needs to, no more, no less.
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Be aware that third party servers are often the most bug-prone.
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For example,
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running an old version of
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.Xr imapd 8
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or
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.Xr popper 8 Pq Pa ports/mail/popper
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is like giving a universal root
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ticket out to the entire world.
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Never run a server that you have not checked
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out carefully.
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Many servers do not need to be run as root.
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For example,
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the
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.Xr talkd 8 ,
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.Xr comsat 8 ,
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and
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.Xr fingerd 8
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daemons can be run in special user
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.Dq sandboxes .
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A sandbox is not perfect unless you go to a large amount of trouble, but the
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onion approach to security still stands: if someone is able to break in
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through a server running in a sandbox, they still have to break out of the
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sandbox.
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The more layers the attacker must break through, the lower the
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likelihood of his success.
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Root holes have historically been found in
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virtually every server ever run as root, including basic system servers.
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If you are running a machine through which people only log in via
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.Xr sshd 8
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and never log in via
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.Xr telnetd 8 ,
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.Xr rshd 8 ,
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or
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.Xr rlogind 8 ,
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then turn off those services!
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.Pp
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.Fx
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now defaults to running
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.Xr talkd 8 ,
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.Xr comsat 8 ,
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and
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.Xr fingerd 8
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in a sandbox.
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Depending on whether you
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are installing a new system or upgrading an existing system, the special
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user accounts used by these sandboxes may not be installed.
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The prudent
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sysadmin would research and implement sandboxes for servers whenever possible.
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.Pp
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There are a number of other servers that typically do not run in sandboxes:
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.Xr sendmail 8 ,
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.Xr popper 8 ,
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.Xr imapd 8 ,
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.Xr ftpd 8 ,
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and others.
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There are alternatives to
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some of these, but installing them may require more work than you are willing
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to put
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(the convenience factor strikes again).
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You may have to run these
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servers as root and rely on other mechanisms to detect break-ins that might
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occur through them.
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.Pp
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The other big potential root hole in a system are the SUID-root and SGID
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binaries installed on the system.
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Most of these binaries, such as
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.Xr rlogin 1 ,
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reside in
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.Pa /bin , /sbin , /usr/bin ,
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or
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.Pa /usr/sbin .
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While nothing is 100% safe,
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the system-default SUID and SGID binaries can be considered reasonably safe.
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Still, root holes are occasionally found in these binaries.
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A root hole
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was found in Xlib in 1998 that made
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.Xr xterm 1 Pq Pa ports/x11/xterm
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(which is typically SUID)
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vulnerable.
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It is better to be safe than sorry and the prudent sysadmin will restrict SUID
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binaries that only staff should run to a special group that only staff can
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access, and get rid of
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.Pq Dq Li "chmod 000"
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any SUID binaries that nobody uses.
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A server with no display generally does not need an
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.Xr xterm 1
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binary.
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SGID binaries can be almost as dangerous.
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If an intruder can break an SGID-kmem binary the
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intruder might be able to read
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.Pa /dev/kmem
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and thus read the crypted password
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file, potentially compromising any passworded account.
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Alternatively an
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intruder who breaks group
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.Dq Li kmem
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can monitor keystrokes sent through PTYs,
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including PTYs used by users who log in through secure methods.
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An intruder
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that breaks the
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.Dq Li tty
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group can write to almost any user's TTY.
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If a user
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is running a terminal
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program or emulator with a keyboard-simulation feature, the intruder can
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potentially
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generate a data stream that causes the user's terminal to echo a command, which
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is then run as that user.
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.Sh SECURING USER ACCOUNTS
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User accounts are usually the most difficult to secure.
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While you can impose
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draconian access restrictions on your staff and *-out their passwords, you
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may not be able to do so with any general user accounts you might have.
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If
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you do have sufficient control then you may win out and be able to secure the
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user accounts properly.
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If not, you simply have to be more vigilant in your
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monitoring of those accounts.
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Use of SSH and Kerberos for user accounts is
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more problematic due to the extra administration and technical support
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required, but still a very good solution compared to a crypted password
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file.
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.Sh SECURING THE PASSWORD FILE
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The only sure fire way is to *-out as many passwords as you can and
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use SSH or Kerberos for access to those accounts.
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Even though the
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crypted password file
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.Pq Pa /etc/spwd.db
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can only be read by root, it may
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be possible for an intruder to obtain read access to that file even if the
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attacker cannot obtain root-write access.
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.Pp
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Your security scripts should always check for and report changes to
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the password file
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(see
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.Sx CHECKING FILE INTEGRITY
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below).
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.Sh SECURING THE KERNEL CORE, RAW DEVICES, AND FILE SYSTEMS
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If an attacker breaks root he can do just about anything, but there
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are certain conveniences.
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For example, most modern kernels have a packet sniffing device driver built in.
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Under
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.Fx
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it is called
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the
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.Xr bpf 4
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device.
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An intruder will commonly attempt to run a packet sniffer
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on a compromised machine.
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You do not need to give the intruder the
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capability and most systems should not have the
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.Xr bpf 4
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device compiled in.
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.Pp
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But even if you turn off the
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.Xr bpf 4
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device, you still have
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.Pa /dev/mem
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and
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.Pa /dev/kmem
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to worry about.
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For that matter,
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the intruder can still write to raw disk devices.
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Also, there is another kernel feature called the module loader,
|
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.Xr kldload 8 .
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An enterprising intruder can use a KLD module to install
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his own
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.Xr bpf 4
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device or other sniffing device on a running kernel.
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To avoid these problems you have to run
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the kernel at a higher security level, at least level 1.
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The security level can be set with a
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.Xr sysctl 8
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on the
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.Va kern.securelevel
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variable.
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Once you have
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set the security level to 1, write access to raw devices will be denied and
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special
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.Xr chflags 1
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flags, such as
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.Cm schg ,
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will be enforced.
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You must also ensure
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that the
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.Cm schg
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flag is set on critical startup binaries, directories, and
|
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script files \(em everything that gets run
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up to the point where the security level is set.
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|
This might be overdoing it, and upgrading the system is much more
|
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difficult when you operate at a higher security level.
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|
You may compromise and
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run the system at a higher security level but not set the
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.Cm schg
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flag for every
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system file and directory under the sun.
|
|
Another possibility is to simply
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mount
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.Pa /
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and
|
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.Pa /usr
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read-only.
|
|
It should be noted that being too draconian in
|
|
what you attempt to protect may prevent the all-important detection of an
|
|
intrusion.
|
|
.Pp
|
|
The kernel runs with five different security levels.
|
|
Any super-user process can raise the level, but no process
|
|
can lower it.
|
|
The security levels are:
|
|
.Bl -tag -width flag
|
|
.It Ic -1
|
|
Permanently insecure mode \- always run the system in insecure mode.
|
|
This is the default initial value.
|
|
.It Ic 0
|
|
Insecure mode \- immutable and append-only flags may be turned off.
|
|
All devices may be read or written subject to their permissions.
|
|
.It Ic 1
|
|
Secure mode \- the system immutable and system append-only flags may not
|
|
be turned off;
|
|
disks for mounted file systems,
|
|
.Pa /dev/mem
|
|
and
|
|
.Pa /dev/kmem
|
|
may not be opened for writing;
|
|
.Pa /dev/io
|
|
(if your platform has it) may not be opened at all;
|
|
kernel modules (see
|
|
.Xr kld 4 )
|
|
may not be loaded or unloaded.
|
|
The kernel debugger may not be entered using the
|
|
.Va debug.kdb.enter
|
|
sysctl.
|
|
A panic or trap cannot be forced using the
|
|
.Va debug.kdb.panic
|
|
and other sysctl's.
|
|
.It Ic 2
|
|
Highly secure mode \- same as secure mode, plus disks may not be
|
|
opened for writing (except by
|
|
.Xr mount 2 )
|
|
whether mounted or not.
|
|
This level precludes tampering with file systems by unmounting them,
|
|
but also inhibits running
|
|
.Xr newfs 8
|
|
while the system is multi-user.
|
|
.Pp
|
|
In addition, kernel time changes are restricted to less than or equal to one
|
|
second.
|
|
Attempts to change the time by more than this will log the message
|
|
.Dq Time adjustment clamped to +1 second .
|
|
.It Ic 3
|
|
Network secure mode \- same as highly secure mode, plus
|
|
IP packet filter rules (see
|
|
.Xr ipfw 8 ,
|
|
.Xr ipfirewall 4
|
|
and
|
|
.Xr pfctl 8 )
|
|
cannot be changed and
|
|
.Xr dummynet 4
|
|
or
|
|
.Xr pf 4
|
|
configuration cannot be adjusted.
|
|
.El
|
|
.Pp
|
|
The security level can be configured with variables documented in
|
|
.Xr rc.conf 5 .
|
|
.Sh CHECKING FILE INTEGRITY: BINARIES, CONFIG FILES, ETC
|
|
When it comes right down to it, you can only protect your core system
|
|
configuration and control files so much before the convenience factor
|
|
rears its ugly head.
|
|
For example, using
|
|
.Xr chflags 1
|
|
to set the
|
|
.Cm schg
|
|
bit on most of the files in
|
|
.Pa /
|
|
and
|
|
.Pa /usr
|
|
is probably counterproductive because
|
|
while it may protect the files, it also closes a detection window.
|
|
The
|
|
last layer of your security onion is perhaps the most important \(em detection.
|
|
The rest of your security is pretty much useless (or, worse, presents you with
|
|
a false sense of safety) if you cannot detect potential incursions.
|
|
Half
|
|
the job of the onion is to slow down the attacker rather than stop him
|
|
in order to give the detection layer a chance to catch him in
|
|
the act.
|
|
.Pp
|
|
The best way to detect an incursion is to look for modified, missing, or
|
|
unexpected files.
|
|
The best
|
|
way to look for modified files is from another (often centralized)
|
|
limited-access system.
|
|
Writing your security scripts on the extra-secure limited-access system
|
|
makes them mostly invisible to potential attackers, and this is important.
|
|
In order to take maximum advantage you generally have to give the
|
|
limited-access box significant access to the other machines in the business,
|
|
usually either by doing a read-only NFS export of the other machines to the
|
|
limited-access box, or by setting up SSH keypairs to allow the limit-access
|
|
box to SSH to the other machines.
|
|
Except for its network traffic, NFS is
|
|
the least visible method \(em allowing you to monitor the file systems on each
|
|
client box virtually undetected.
|
|
If your
|
|
limited-access server is connected to the client boxes through a switch,
|
|
the NFS method is often the better choice.
|
|
If your limited-access server
|
|
is connected to the client boxes through a hub or through several layers
|
|
of routing, the NFS method may be too insecure (network-wise) and using SSH
|
|
may be the better choice even with the audit-trail tracks that SSH lays.
|
|
.Pp
|
|
Once you give a limit-access box at least read access to the client systems
|
|
it is supposed to monitor, you must write scripts to do the actual
|
|
monitoring.
|
|
Given an NFS mount, you can write scripts out of simple system
|
|
utilities such as
|
|
.Xr find 1
|
|
and
|
|
.Xr md5 1 .
|
|
It is best to physically
|
|
.Xr md5 1
|
|
the client-box files boxes at least once a
|
|
day, and to test control files such as those found in
|
|
.Pa /etc
|
|
and
|
|
.Pa /usr/local/etc
|
|
even more often.
|
|
When mismatches are found relative to the base MD5
|
|
information the limited-access machine knows is valid, it should scream at
|
|
a sysadmin to go check it out.
|
|
A good security script will also check for
|
|
inappropriate SUID binaries and for new or deleted files on system partitions
|
|
such as
|
|
.Pa /
|
|
and
|
|
.Pa /usr .
|
|
.Pp
|
|
When using SSH rather than NFS, writing the security script is much more
|
|
difficult.
|
|
You essentially have to
|
|
.Xr scp 1
|
|
the scripts to the client box in order to run them, making them visible, and
|
|
for safety you also need to
|
|
.Xr scp 1
|
|
the binaries (such as
|
|
.Xr find 1 )
|
|
that those scripts use.
|
|
The
|
|
.Xr sshd 8
|
|
daemon on the client box may already be compromised.
|
|
All in all,
|
|
using SSH may be necessary when running over unsecure links, but it is also a
|
|
lot harder to deal with.
|
|
.Pp
|
|
A good security script will also check for changes to user and staff members
|
|
access configuration files:
|
|
.Pa .rhosts , .shosts , .ssh/authorized_keys
|
|
and so forth, files that might fall outside the purview of the MD5 check.
|
|
.Pp
|
|
If you have a huge amount of user disk space it may take too long to run
|
|
through every file on those partitions.
|
|
In this case, setting mount
|
|
flags to disallow SUID binaries on those partitions is a good
|
|
idea.
|
|
The
|
|
.Cm nosuid
|
|
option
|
|
(see
|
|
.Xr mount 8 )
|
|
is what you want to look into.
|
|
I would scan them anyway at least once a
|
|
week, since the object of this layer is to detect a break-in whether or
|
|
not the break-in is effective.
|
|
.Pp
|
|
Process accounting
|
|
(see
|
|
.Xr accton 8 )
|
|
is a relatively low-overhead feature of
|
|
the operating system which I recommend using as a post-break-in evaluation
|
|
mechanism.
|
|
It is especially useful in tracking down how an intruder has
|
|
actually broken into a system, assuming the file is still intact after
|
|
the break-in occurs.
|
|
.Pp
|
|
Finally, security scripts should process the log files and the logs themselves
|
|
should be generated in as secure a manner as possible \(em remote syslog can be
|
|
very useful.
|
|
An intruder tries to cover his tracks, and log files are critical
|
|
to the sysadmin trying to track down the time and method of the initial
|
|
break-in.
|
|
One way to keep a permanent record of the log files is to run
|
|
the system console to a serial port and collect the information on a
|
|
continuing basis through a secure machine monitoring the consoles.
|
|
.Sh PARANOIA
|
|
A little paranoia never hurts.
|
|
As a rule, a sysadmin can add any number
|
|
of security features as long as they do not affect convenience, and
|
|
can add security features that do affect convenience with some added
|
|
thought.
|
|
Even more importantly, a security administrator should mix it up
|
|
a bit \(em if you use recommendations such as those given by this manual
|
|
page verbatim, you give away your methodologies to the prospective
|
|
attacker who also has access to this manual page.
|
|
.Sh SPECIAL SECTION ON DoS ATTACKS
|
|
This section covers Denial of Service attacks.
|
|
A DoS attack is typically a packet attack.
|
|
While there is not much you can do about modern spoofed
|
|
packet attacks that saturate your network, you can generally limit the damage
|
|
by ensuring that the attacks cannot take down your servers.
|
|
.Bl -enum -offset indent
|
|
.It
|
|
Limiting server forks
|
|
.It
|
|
Limiting springboard attacks (ICMP response attacks, ping broadcast, etc.)
|
|
.It
|
|
Kernel Route Cache
|
|
.El
|
|
.Pp
|
|
A common DoS attack is against a forking server that attempts to cause the
|
|
server to eat processes, file descriptors, and memory until the machine
|
|
dies.
|
|
The
|
|
.Xr inetd 8
|
|
server
|
|
has several options to limit this sort of attack.
|
|
It should be noted that while it is possible to prevent a machine from going
|
|
down it is not generally possible to prevent a service from being disrupted
|
|
by the attack.
|
|
Read the
|
|
.Xr inetd 8
|
|
manual page carefully and pay specific attention
|
|
to the
|
|
.Fl c , C ,
|
|
and
|
|
.Fl R
|
|
options.
|
|
Note that spoofed-IP attacks will circumvent
|
|
the
|
|
.Fl C
|
|
option to
|
|
.Xr inetd 8 ,
|
|
so typically a combination of options must be used.
|
|
Some standalone servers have self-fork-limitation parameters.
|
|
.Pp
|
|
The
|
|
.Xr sendmail 8
|
|
daemon has its
|
|
.Fl OMaxDaemonChildren
|
|
option which tends to work much
|
|
better than trying to use
|
|
.Xr sendmail 8 Ns 's
|
|
load limiting options due to the
|
|
load lag.
|
|
You should specify a
|
|
.Va MaxDaemonChildren
|
|
parameter when you start
|
|
.Xr sendmail 8
|
|
high enough to handle your expected load but not so high that the
|
|
computer cannot handle that number of
|
|
.Nm sendmail Ns 's
|
|
without falling on its face.
|
|
It is also prudent to run
|
|
.Xr sendmail 8
|
|
in
|
|
.Dq queued
|
|
mode
|
|
.Pq Fl ODeliveryMode=queued
|
|
and to run the daemon
|
|
.Pq Dq Nm sendmail Fl bd
|
|
separate from the queue-runs
|
|
.Pq Dq Nm sendmail Fl q15m .
|
|
If you still want real-time delivery you can run the queue
|
|
at a much lower interval, such as
|
|
.Fl q1m ,
|
|
but be sure to specify a reasonable
|
|
.Va MaxDaemonChildren
|
|
option for that
|
|
.Xr sendmail 8
|
|
to prevent cascade failures.
|
|
.Pp
|
|
The
|
|
.Xr syslogd 8
|
|
daemon can be attacked directly and it is strongly recommended that you use
|
|
the
|
|
.Fl s
|
|
option whenever possible, and the
|
|
.Fl a
|
|
option otherwise.
|
|
.Pp
|
|
You should also be fairly careful
|
|
with connect-back services such as tcpwrapper's reverse-identd, which can
|
|
be attacked directly.
|
|
You generally do not want to use the reverse-ident
|
|
feature of tcpwrappers for this reason.
|
|
.Pp
|
|
It is a very good idea to protect internal services from external access
|
|
by firewalling them off at your border routers.
|
|
The idea here is to prevent
|
|
saturation attacks from outside your LAN, not so much to protect internal
|
|
services from network-based root compromise.
|
|
Always configure an exclusive
|
|
firewall, i.e.,
|
|
.So
|
|
firewall everything
|
|
.Em except
|
|
ports A, B, C, D, and M-Z
|
|
.Sc .
|
|
This
|
|
way you can firewall off all of your low ports except for certain specific
|
|
services such as
|
|
.Xr talkd 8 ,
|
|
.Xr sendmail 8 ,
|
|
and other internet-accessible services.
|
|
If you try to configure the firewall the other
|
|
way \(em as an inclusive or permissive firewall, there is a good chance that you
|
|
will forget to
|
|
.Dq close
|
|
a couple of services or that you will add a new internal
|
|
service and forget to update the firewall.
|
|
You can still open up the
|
|
high-numbered port range on the firewall to allow permissive-like operation
|
|
without compromising your low ports.
|
|
Also take note that
|
|
.Fx
|
|
allows you to
|
|
control the range of port numbers used for dynamic binding via the various
|
|
.Va net.inet.ip.portrange
|
|
sysctl's
|
|
.Pq Dq Li "sysctl net.inet.ip.portrange" ,
|
|
which can also
|
|
ease the complexity of your firewall's configuration.
|
|
I usually use a normal
|
|
first/last range of 4000 to 5000, and a hiport range of 49152 to 65535, then
|
|
block everything under 4000 off in my firewall
|
|
(except for certain specific
|
|
internet-accessible ports, of course).
|
|
.Pp
|
|
Another common DoS attack is called a springboard attack \(em to attack a server
|
|
in a manner that causes the server to generate responses which then overload
|
|
the server, the local network, or some other machine.
|
|
The most common attack
|
|
of this nature is the ICMP PING BROADCAST attack.
|
|
The attacker spoofs ping
|
|
packets sent to your LAN's broadcast address with the source IP address set
|
|
to the actual machine they wish to attack.
|
|
If your border routers are not
|
|
configured to stomp on ping's to broadcast addresses, your LAN winds up
|
|
generating sufficient responses to the spoofed source address to saturate the
|
|
victim, especially when the attacker uses the same trick on several dozen
|
|
broadcast addresses over several dozen different networks at once.
|
|
Broadcast attacks of over a hundred and twenty megabits have been measured.
|
|
A second common springboard attack is against the ICMP error reporting system.
|
|
By
|
|
constructing packets that generate ICMP error responses, an attacker can
|
|
saturate a server's incoming network and cause the server to saturate its
|
|
outgoing network with ICMP responses.
|
|
This type of attack can also crash the
|
|
server by running it out of
|
|
.Vt mbuf Ns 's ,
|
|
especially if the server cannot drain the
|
|
ICMP responses it generates fast enough.
|
|
The
|
|
.Fx
|
|
kernel has a new kernel
|
|
compile option called
|
|
.Dv ICMP_BANDLIM
|
|
which limits the effectiveness of these
|
|
sorts of attacks.
|
|
The last major class of springboard attacks is related to
|
|
certain internal
|
|
.Xr inetd 8
|
|
services such as the UDP echo service.
|
|
An attacker
|
|
simply spoofs a UDP packet with the source address being server A's echo port,
|
|
and the destination address being server B's echo port, where server A and B
|
|
are both on your LAN.
|
|
The two servers then bounce this one packet back and
|
|
forth between each other.
|
|
The attacker can overload both servers and their
|
|
LANs simply by injecting a few packets in this manner.
|
|
Similar problems
|
|
exist with the internal chargen port.
|
|
A competent sysadmin will turn off all
|
|
of these
|
|
.Xr inetd 8 Ns -internal
|
|
test services.
|
|
.Pp
|
|
Spoofed packet attacks may also be used to overload the kernel route cache.
|
|
Refer to the
|
|
.Va net.inet.ip.rtexpire , net.inet.ip.rtminexpire ,
|
|
and
|
|
.Va net.inet.ip.rtmaxcache
|
|
.Xr sysctl 8
|
|
variables.
|
|
A spoofed packet attack that uses a random source IP will cause
|
|
the kernel to generate a temporary cached route in the route table, viewable
|
|
with
|
|
.Dq Li "netstat -rna | fgrep W3" .
|
|
These routes typically timeout in 1600
|
|
seconds or so.
|
|
If the kernel detects that the cached route table has gotten
|
|
too big it will dynamically reduce the
|
|
.Va rtexpire
|
|
but will never decrease it to
|
|
less than
|
|
.Va rtminexpire .
|
|
There are two problems: (1) The kernel does not react
|
|
quickly enough when a lightly loaded server is suddenly attacked, and (2) The
|
|
.Va rtminexpire
|
|
is not low enough for the kernel to survive a sustained attack.
|
|
If your servers are connected to the internet via a T3 or better it may be
|
|
prudent to manually override both
|
|
.Va rtexpire
|
|
and
|
|
.Va rtminexpire
|
|
via
|
|
.Xr sysctl 8 .
|
|
Never set either parameter to zero
|
|
(unless you want to crash the machine :-)).
|
|
Setting both parameters to 2 seconds should be sufficient to protect the route
|
|
table from attack.
|
|
.Sh ACCESS ISSUES WITH KERBEROS AND SSH
|
|
There are a few issues with both Kerberos and SSH that need to be addressed
|
|
if you intend to use them.
|
|
Kerberos5 is an excellent authentication
|
|
protocol but the kerberized
|
|
.Xr telnet 1
|
|
and
|
|
.Xr rlogin 1
|
|
suck rocks.
|
|
There are bugs that make them unsuitable for dealing with binary streams.
|
|
Also, by default
|
|
Kerberos does not encrypt a session unless you use the
|
|
.Fl x
|
|
option.
|
|
SSH encrypts everything by default.
|
|
.Pp
|
|
SSH works quite well in every respect except when it is set up to
|
|
forward encryption keys.
|
|
What this means is that if you have a secure workstation holding
|
|
keys that give you access to the rest of the system, and you
|
|
.Xr ssh 1
|
|
to an
|
|
unsecure machine, your keys become exposed.
|
|
The actual keys themselves are
|
|
not exposed, but
|
|
.Xr ssh 1
|
|
installs a forwarding port for the duration of your
|
|
login and if an attacker has broken root on the unsecure machine he can utilize
|
|
that port to use your keys to gain access to any other machine that your
|
|
keys unlock.
|
|
.Pp
|
|
We recommend that you use SSH in combination with Kerberos whenever possible
|
|
for staff logins.
|
|
SSH can be compiled with Kerberos support.
|
|
This reduces
|
|
your reliance on potentially exposable SSH keys while at the same time
|
|
protecting passwords via Kerberos.
|
|
SSH keys
|
|
should only be used for automated tasks from secure machines (something
|
|
that Kerberos is unsuited to).
|
|
We also recommend that you either turn off
|
|
key-forwarding in the SSH configuration, or that you make use of the
|
|
.Va from Ns = Ns Ar IP/DOMAIN
|
|
option that SSH allows in its
|
|
.Pa authorized_keys
|
|
file to make the key only usable to entities logging in from specific
|
|
machines.
|
|
.Sh SEE ALSO
|
|
.Xr chflags 1 ,
|
|
.Xr find 1 ,
|
|
.Xr md5 1 ,
|
|
.Xr netstat 1 ,
|
|
.Xr openssl 1 ,
|
|
.Xr ssh 1 ,
|
|
.Xr xdm 1 Pq Pa ports/x11/xorg-clients ,
|
|
.Xr group 5 ,
|
|
.Xr ttys 5 ,
|
|
.Xr accton 8 ,
|
|
.Xr init 8 ,
|
|
.Xr sshd 8 ,
|
|
.Xr sysctl 8 ,
|
|
.Xr syslogd 8 ,
|
|
.Xr vipw 8
|
|
.Sh HISTORY
|
|
The
|
|
.Nm
|
|
manual page was originally written by
|
|
.An Matthew Dillon
|
|
and first appeared
|
|
in
|
|
.Fx 3.1 ,
|
|
December 1998.
|