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PrefaceIntended
AudienceThe FreeBSD newcomer will find that the first section of this
book guides the user through the FreeBSD installation process, and
gently introduces the concepts and conventions that underpin Unix.
Working through this section requires little more than the desire
to explore, and the ability to take on board new concepts as they
are introduced.Once you have travelled this far, the second, far larger,
section of the Handbook is a comprehensive reference to all manner
of topics of interest to FreeBSD system administrators. Some of
these chapters may recommend that you do some prior reading, and
this is noted in the synopsis at the beginning of each
chapter.For a list of additional sources of information, please see .Changes from the
First EditionThis second edition is the culmination of over two years of
work by the dedicated members of the FreeBSD Documentation
Project. The following are the major changes in this new
edition:A complete Index has been added.All ASCII figures have been replaced by graphical diagrams.A standard synopsis has been added to each chapter to
give a quick summary of what information the chapter contains,
and what the reader is expected to know.The content has been logically reorganized into three
parts: "Getting Started", "System Administration", and
"Appendices".Chapter 2 ("Installing FreeBSD") was completely
rewritten with many screenshots to make it much easier for new
users to grasp the text.Chapter 3 ("Unix Basics") has been expanded to contain
additional information about processes, daemons, and
signals.Chapter 4 ("Installing Applications") has been expanded
to contain additional information about binary package
management.Chapter 5 ("The X Window System") has been completely
rewritten with an emphasis on using modern desktop
technologies such as KDE and GNOME on XFree86 4.X.Chapter 7 ("The FreeBSD Booting Process") has been
expanded.Chapter 12 ("Storage") has been written from what used
to be two separate chapters on "Disks" and "Backups". We feel
that the topics are easier to comprehend when presented as a
single chapter. A section on RAID (both hardware and
software) has also been added.Chapter 15 ("Serial Communications") has been completely
reorganized and updated for FreeBSD 4.X/5.X.Chapter 16 ("PPP and SLIP") has been substantially
updated.Many new sections have been added to Chapter 17
("Advanced Networking").Chapter 18 ("Electronic Mail") has been expanded to
include more information about configuring
sendmail.Chapter 20 ("Linux Compatibility") has been expanded to
include information about installing
Oracle and
SAP/R3.The following new topics are covered in this second
edition:Configuration and Tuning (Chapter 6).Sound (Chapter 14)Organization of This
BookThis book is split into three logically distinct sections.
The first section, Getting Started, covers
the installation and basic usage of FreeBSD. It is expected that
the reader will follow these chapters in sequence, possibly
skipping chapters covering familiar topics. The second section,
System Administration, covers a broad
collection of subjects that are of interest to more advanced
FreeBSD users. Each section begins with a succinct synopsis that
describes what the chapter covers and what the reader is expected
to already know. This is meant to allow the casual reader to skip
around to find chapters of interest. The third section contains
appendices of reference information.Chapter 1, IntroductionIntroduces FreeBSD to a new user. It describes the
history of the FreeBSD Project, its goals and development model.Chapter 2, InstallationWalks a user through the entire installation process.
Some advanced installation topics, such as installing through
a serial console, are also covered.Chapter 3, Unix BasicsCovers the basic commands and functionality of the
FreeBSD operating system. If you are familiar with Linux or
another flavor of Unix then you can probably skip this
chapter.Chapter 4, Installing ApplicationsCovers the installation of third-party software with
both FreeBSD's innovative "Ports Collection" and standard
binary packages.Chapter 5, The X Window SystemDescribes the X Window System in general and using
XFree86 on FreeBSD in particular. Also describes common
desktop environments such as KDE and GNOME.Chapter 6, Configuration and TuningDescribes the parameters available for system
administrators to tune a FreeBSD system for optimum
performance. Also describes the various configuration files
used in FreeBSD and where to find them.Chapter 7, Booting ProcessDescribes the FreeBSD boot process and explains
how to control this process with configuration options.Chapter 8, Users and Basic Account
ManagementDescribes the creation and manipulation of user
accounts. Also discusses resource limitations that can be
set on users and other account management tasks.Chapter 9, Configuring the FreeBSD
KernelExplains why you might need to configure a new kernel
and provides detailed instructions for configuring, building,
and installing a custom kernel.Chapter 10, SecurityDescribes many different tools available to help keep your
- FreeBSD system secure, including Kerberos, IPSec, OpenSSH, and
+ FreeBSD system secure, including Kerberos, IPsec, OpenSSH, and
network firewalls.Chapter 11, PrintingDescribes managing printers on FreeBSD, including
information about banner pages, printer accounting, and
initial setup.Chapter 12, StorageDescribes how to manage storage media and filesystems
with FreeBSD. This includes physical disks, RAID arrays,
optical and tape media, memory-backed disks, and network
filesystems.Chapter 13, LocalizationDescribes how to use FreeBSD in languages other than
English. Covers both system and application level
localization.Chapter 14, SoundShows how to setup sound support for your system. Also
describes some sample audio applications.Chapter 15, Serial CommunicationsExplains how to connect terminals and modems to your
FreeBSD system for both dial in and dial out connections.Chapter 16, PPP and SLIPDescribes how to use PPP, SLIP, or PPP over Ethernet to
connect to remote systems with FreeBSD.Chapter 17, Advanced NetworkingDescribes many networking topics, including sharing an
Internet connection with other computers on your LAN, using
network filesystems, sharing account information via NIS,
setting up a name server, and much more.Chapter 18, Electronic MailExplains the different components of an email server and
dives into simple configuration topics for the most popular
mail server software:
sendmail.Chapter 19, The Cutting EdgeExplains the differences between FreeBSD-STABLE,
FreeBSD-CURRENT, and FreeBSD releases. Describes which users
would benefit from tracking a development system and outlines
that process.Chapter 20, Linux Binary CompatibilityDescribes the Linux compatibility features of FreeBSD.
Also provides detailed installation instructions for many
popular Linux applications such as Oracle, SAP/R3, and
Mathematica.Appendix A, Obtaining FreeBSD Lists different sources for obtaining FreeBSD media on CDROM
or DVD as well as different sites on the Internet that allow
you to download and install FreeBSD.Appendix B, Bibliography This book touches on many different subjects that may
leave you hungry for a more detailed explanation. The
bibliography lists many excellent books that are referenced in
the text.Appendix C, Resources on the InternetDescribes the many forums available for FreeBSD users to
post questions and engage in technical conversations about
FreeBSD.Appendix D, PGP KeysLists the PGP fingerprints of several FreeBSD Developers.Conventions used
in this bookTo provide a consistent and easy to read text, several
conventions are followed throughout the book.Typographic
ConventionsItalicAn italic font is used for filenames, URLs,
emphasized text, and the first usage of technical terms.MonospaceA monospaced font is
used for error messages, commands, environment variables,
names of ports, hostnames, user names, group names, device
names, variables, and code fragments.BoldA bold font is used for
applications, commands, and keys.User InputKeys are rendered in bold to stand out from
other text. Key combinations that are meant to be typed
simultaneously are rendered with `+' between
the keys, such as:CtrlAltDelKeys that are meant to be typed in sequence will be separated with
commas, for example:CtrlX,
CtrlSWould mean that the user is expected to type the
Ctrl and X keys simultaneously
and then to type the Ctrl and S
keys simultaneously.ExamplesExamples starting with E:\>
indicate a MS-DOS command. Unless otherwise noted, these commands
may be executed from a "Command Prompt" window in a modern Microsoft
Windows environment.E:\>tools\fdimage floppies\kern.flp A:Examples starting with &prompt.root; indicate a command that
must be invoked as the superuser in FreeBSD. You can login as
root to type the command, or login as your
normal account and use &man.su.1; to gain
superuser privileges.&prompt.root; dd if=kern.flp of=/dev/fd0Examples starting with &prompt.user; indicate a command that
should be invoked from a normal user account. Unless otherwise
noted, C-shell syntax is used for setting environment variables
and other shell commands.&prompt.user; topAcknowledgmentsThe book you are holding represents the efforts of many hundreds of
people around the world. Whether they sent in fixes for typos, or
submitted complete chapters, all the contributions have been
useful.Several companies have supported the development of this
document by paying authors to work on it full-time, paying for
publication, etc. In particular, BSDi (subsequently acquired by
Wind River Systems)
paid members of the FreeBSD Documentation Project to work on
improving this book full time leading up to the publication of the
first printed edition in March 2000 (ISBN 1-57176-241-8). Wind
River Systems then paid several additional authors to make a
number of improvements to the print-output infrastructure and to add
additional chapters to the text. This work culminated in the
publication of the second printed edition in November 2001 (ISBN
1-57176-303-1).
diff --git a/en_US.ISO8859-1/books/handbook/security/chapter.sgml b/en_US.ISO8859-1/books/handbook/security/chapter.sgml
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MatthewDillonMuch of this chapter has been taken from the
security(7) manual page by SecuritysecuritySynopsisThis chapter will provide a basic introduction to system security
concepts, some general good rules of thumb, and some advanced topics
under FreeBSD. A lot of the topics covered here can be applied
to system and Internet security in general as well. The Internet
is no longer a friendly place in which everyone
wants to be your kind neighbor. Securing your system is imperative
to protect your data, intellectual property, time, and much more
from the hands of hackers and the like.FreeBSD provides an array of utilities and mechanisms to
ensure the integrity and security of your system and
network.After reading this chapter, you will know:Basic system security concepts, in respect to FreeBSD.About the various crypt mechanisms available in FreeBSD,
such as DES and MD5.How to setup S/Key, an alternative, one-time password
authentication system.How to setup Kerberos, another alternative
authentication system.How to create firewalls using IPFW.
- How to configure IPSec.
+ How to configure IPsec.How to configure and use OpenSSH, FreeBSD's SSH
implementation.Before reading this chapter, you should:Understand basic FreeBSD and Internet concepts.IntroductionSecurity is a function that begins and ends with the system
administrator. While all BSD Unix multi-user systems have some
inherent security, the job of building and maintaining additional
security mechanisms to keep those users honest is
probably one of the single largest undertakings of the sysadmin.
Machines are only as secure as you make them, and security concerns
are ever competing with the human necessity for convenience. Unix
systems, in general, are capable of running a huge number of
simultaneous processes and many of these processes operate as
servers – meaning that external entities can connect and talk
to them. As yesterday's mini-computers and mainframes become
today's desktops, and as computers become networked and
internetworked, security becomes an even bigger issue.Security is best implemented through a layered
onion approach. In a nutshell, what you want to do is
to create as many layers of security as are convenient and then
carefully monitor the system for intrusions. You do not want to
overbuild your security or you will interfere with the detection
side, and detection is one of the single most important aspects of
any security mechanism. For example, it makes little sense to set
the schg flags (see &man.chflags.1;) on every
system binary because
while this may temporarily protect the binaries, it prevents an
attacker who has broken in from making an easily detectable change
that may result in your security mechanisms not detecting the attacker
at all.System security also pertains to dealing with various forms of
attack, including attacks that attempt to crash, or otherwise make a
system unusable, but do not attempt to compromise the
root account (break root).
Security concerns
can be split up into several categories:Denial of service attacks.User account compromises.Root compromise through accessible servers.Root compromise via user accounts.Backdoor creation.DoS attacksDenial of Service (DoS)securityDoS attacksDenial of Service (DoS)Denial of Service (DoS)A denial of service attack is an action that deprives the
machine of needed resources. Typically, DoS attacks are
brute-force mechanisms that attempt to crash or otherwise make a
machine unusable by overwhelming its servers or network stack. Some
DoS attacks try to take advantage of bugs in the networking
stack to crash a machine with a single packet. The latter can only
be fixed by applying a bug fix to the kernel. Attacks on servers
can often be fixed by properly specifying options to limit the load
the servers incur on the system under adverse conditions.
Brute-force network attacks are harder to deal with. A
spoofed-packet attack, for example, is nearly impossible to stop,
short of cutting your system off from the Internet. It may not be
able to take your machine down, but it can saturate your
Internet connection.securityaccount compromisesA user account compromise is even more common than a DoS
attack. Many sysadmins still run standard
telnetd, rlogind,
rshd,
and ftpd servers on their machines.
These servers, by default, do
not operate over encrypted connections. The result is that if you
have any moderate-sized user base, one or more of your users logging
into your system from a remote location (which is the most common
and convenient way to login to a system) will have his or her
password sniffed. The attentive system admin will analyze his
remote access logs looking for suspicious source addresses even for
successful logins.One must always assume that once an attacker has access to a
user account, the attacker can break root.
However, the reality is that in a well secured and maintained system,
access to a user account does not necessarily give the attacker
access to root. The distinction is important
because without access to root the attacker
cannot generally hide his tracks and may, at best, be able to do
nothing more than mess with the user's files, or crash the machine.
User account compromises are very common because users tend not to
take the precautions that sysadmins take.securitybackdoorsSystem administrators must keep in mind that there are
potentially many ways to break root on a machine.
The attacker may know the root password,
the attacker may find a bug in a root-run server and be able
to break root over a network
connection to that server, or the attacker may know of a bug in
a suid-root program that allows the attacker to break
root once he has broken into a user's account.
If an attacker has found a way to break root
on a machine, the attacker may not have a need
to install a backdoor. Many of the root holes
found and closed to date involve a considerable amount of work
by the attacker to cleanup after himself, so most attackers install
backdoors. A backdoor provides the attacker with a way to easily
regain root access to the system, but it
also gives the smart system administrator a convenient way
to detect the intrusion.
Making it impossible for an attacker to install a backdoor may
actually be detrimental to your security, because it will not
close off the hole the attacker found to break in the first
place.Security remedies should always be implemented with a
multi-layered onion peel approach and can be
categorized as follows:Securing root and staff accounts.Securing root – root-run servers
and suid/sgid binaries.Securing user accounts.Securing the password file.Securing the kernel core, raw devices, and
filesystems.Quick detection of inappropriate changes made to the
system.Paranoia.The next section of this chapter will cover the above bullet
items in greater depth.securitysecuringSecuring FreeBSDCommand vs. ProtocolThroughout this document, we will use
bold text to refer to a command or
application. This is used for instances such as ssh, since it is
a protocol as well as command.The sections that follow will cover the methods of securing your
FreeBSD system that were mentioned in the last section of this chapter.Securing the root Account and
Staff AccountssuFirst off, do not bother securing staff accounts if you have
not secured the root account.
Most systems have a password assigned to the root
account. The first thing you do is assume
that the password is always compromised.
This does not mean that you should remove the password. The
password is almost always necessary for console access to the
machine. What it does mean is that you should not make it
possible to use the password outside of the console or possibly
even with the &man.su.1; command. For example, make sure that
your pty's are specified as being insecure in the
/etc/ttys file so that direct
root logins
via telnet or rlogin are
disallowed. If using other login services such as
sshd, make sure that direct
root logins are disabled there as well.
You can do this by editing
your /etc/ssh/sshd_config file, and making
sure that PermitRootLogin is set to
NO. Consider every access method –
services such as FTP often fall through the cracks.
Direct root logins should only be allowed
via the system console.wheelOf course, as a sysadmin you have to be able to get to
root, so we open up a few holes.
But we make sure these holes require additional password
verification to operate. One way to make root
accessible is to add appropriate staff accounts to the
wheel group (in
/etc/group). The staff members placed in the
wheel group are allowed to
su to root.
You should never give staff
members native wheel access by putting them in the
wheel group in their password entry. Staff
accounts should be placed in a staff group, and
then added to the wheel group via the
/etc/group file. Only those staff members
who actually need to have root access
should be placed in the
wheel group. It is also possible, when using
an authentication method such as Kerberos, to use Kerberos'
.k5login file in the root
account to allow a &man.ksu.1; to root
without having to place anyone at all in the
wheel group. This may be the better solution
since the wheel mechanism still allows an
intruder to break root if the intruder
has gotten hold of your
password file and can break into a staff account. While having
the wheel mechanism is better than having
nothing at all, it is not necessarily the safest option.An indirect way to secure staff accounts, and ultimately
root access is to use an alternative
login access method and
do what is known as starring out the encrypted
password for the staff accounts. Using the &man.vipw.8;
command, one can replace each instance of an encrypted password
with a single * character.
This command will update the /etc/master.passwd
file and user/password database to disable password-authenticated
logins.A staff account entry such as:foobar:R9DT/Fa1/LV9U:1000:1000::0:0:Foo Bar:/home/foobar:/usr/local/bin/tcshShould be changed to this:foobar:*:1000:1000::0:0:Foo Bar:/home/foobar:/usr/local/bin/tcshThis change will prevent normal logins from occurring,
since the encrypted password will never match
*. With this done,
staff members must use
another mechanism to authenticate themselves such as
&man.kerberos.1; or &man.ssh.1; using a public/private key
pair. When using something like Kerberos, one generally must
secure the machines which run the Kerberos servers and your
desktop workstation. When using a public/private key pair
with ssh, one must generally secure
the machine used to login from (typically
one's workstation). An additional layer of protection can be
added to the key pair by password protecting the key pair when
creating it with &man.ssh-keygen.1;. Being able to
star out the passwords for staff accounts also
guarantees that staff members can only login through secure
access methods that you have setup. This forces all staff
members to use secure, encrypted connections for all of their
sessions, which closes an important hole used by many
intruders: sniffing the network from an unrelated,
less secure machine.The more indirect security mechanisms also assume that you are
logging in from a more restrictive server to a less restrictive
server. For example, if your main box is running all sorts of
servers, your workstation should not be running any. In order for
your workstation to be reasonably secure you should run as few
servers as possible, up to and including no servers at all, and
you should run a password-protected screen blanker. Of course,
given physical access to a workstation an attacker can break any
sort of security you put on it. This is definitely a problem that
you should consider, but you should also consider the fact that the
vast majority of break-ins occur remotely, over a network, from
people who do not have physical access to your workstation or
servers.KerberosUsing something like Kerberos also gives you the ability to
disable or change the password for a staff account in one place,
and have it immediately effect all the machines on which the staff
member may have an account. If a staff member's account gets
compromised, the ability to instantly change his password on all
machines should not be underrated. With discrete passwords,
changing a password on N machines can be a mess. You can also
impose re-passwording restrictions with Kerberos: not only can a
Kerberos ticket be made to timeout after a while, but the Kerberos
system can require that the user choose a new password after a
certain period of time (say, once a month).Securing Root-run Servers and SUID/SGID BinariesntalkcomsatfingersandboxessshdtelnetdrshdrlogindThe prudent sysadmin only runs the servers he needs to, no
more, no less. Be aware that third party servers are often the
most bug-prone. For example, running an old version of
imapd or
popper is like giving a universal
root ticket out to the entire world.
Never run a server that you have not checked out carefully.
Many servers do not need to be run as root.
For example, the ntalk,
comsat, and
finger daemons can be run in special
user sandboxes. A sandbox is not perfect,
unless you go through a large amount of trouble, but the onion
approach to security still stands: If someone is able to break
in through a server running in a sandbox, they still have to
break out of the sandbox. The more layers the attacker must
break through, the lower the likelihood of his success. Root
holes have historically been found in virtually every server
ever run as root, including basic system servers.
If you are running a machine through which people only login via
sshd and never login via
telnetd or
rshd or
rlogind, then turn off those
services!FreeBSD now defaults to running
ntalkd,
comsat, and
finger in a sandbox. Another program
which may be a candidate for running in a sandbox is &man.named.8;.
/etc/defaults/rc.conf includes the arguments
necessary to run named in a sandbox in a
commented-out form. Depending on whether you are installing a new
system or upgrading an existing system, the special user accounts
used by these sandboxes may not be installed. The prudent
sysadmin would research and implement sandboxes for servers
whenever possible.sendmailThere are a number of other servers that typically do not run
in sandboxes: sendmail,
popper,
imapd, ftpd,
and others. There are alternatives to some of these, but
installing them may require more work than you are willing to
perform (the convenience factor strikes again). You may have to
run these servers as root and rely on other
mechanisms to detect break-ins that might occur through them.The other big potential root holes in a
system are the
suid-root and sgid binaries installed on the system. Most of
these binaries, such as rlogin, reside
in /bin, /sbin,
/usr/bin, or /usr/sbin.
While nothing is 100% safe, the system-default suid and sgid
binaries can be considered reasonably safe. Still,
root holes are occasionally found in these
binaries. A root hole was found in
Xlib in 1998 that made
xterm (which is typically suid)
vulnerable. It is better to be safe than sorry and the prudent
sysadmin will restrict suid binaries, that only staff should run,
to a special group that only staff can access, and get rid of
(chmod 000) any suid binaries that nobody uses.
A server with no display generally does not need an
xterm binary. Sgid binaries can be
almost as dangerous. If an intruder can break an sgid-kmem binary,
the intruder might be able to read /dev/kmem
and thus read the encrypted password file, potentially compromising
any passworded account. Alternatively an intruder who breaks
group kmem can monitor keystrokes sent through
pty's, including pty's used by users who login through secure
methods. An intruder that breaks the tty
group can write to
almost any user's tty. If a user is running a terminal program or
emulator with a keyboard-simulation feature, the intruder can
potentially generate a data stream that causes the user's terminal
to echo a command, which is then run as that user.Securing User AccountsUser accounts are usually the most difficult to secure. While
you can impose Draconian access restrictions on your staff and
star out their passwords, you may not be able to
do so with any general user accounts you might have. If you do
have sufficient control, then you may win out and be able to secure
the user accounts properly. If not, you simply have to be more
vigilant in your monitoring of those accounts. Use of
ssh and Kerberos for user accounts is
more problematic, due to the extra administration and technical
support required, but still a very good solution compared to a
crypted password file.Securing the Password FileThe only sure fire way is to * out as many
passwords as you can and use ssh or
Kerberos for access to those accounts. Even though the encrypted
password file (/etc/spwd.db) can only be read
by root, it may be possible for an intruder
to obtain read access to that file even if the attacker cannot
obtain root-write access.Your security scripts should always check for and report
changes to the password file (see the Checking file integrity section
below).Securing the Kernel Core, Raw Devices, and
FilesystemsIf an attacker breaks root he can do
just about anything, but
there are certain conveniences. For example, most modern kernels
have a packet sniffing device driver built in. Under FreeBSD it
is called the bpf device. An intruder
will commonly attempt to run a packet sniffer on a compromised
machine. You do not need to give the intruder the capability and
most systems do not have the need for the
bpf device compiled in.sysctlBut even if you turn off the bpf
device, you still have
/dev/mem and
/dev/kmem
to worry about. For that matter, the intruder can still write to
raw disk devices. Also, there is another kernel feature called
the module loader, &man.kldload.8;. An enterprising intruder can
use a KLD module to install his own bpf
device, or other sniffing
device, on a running kernel. To avoid these problems you have to
run the kernel at a higher secure level, at least securelevel 1.
The securelevel can be set with a sysctl on
the kern.securelevel variable. Once you have
set the securelevel to 1, write access to raw devices will be
denied and special chflags flags,
such as schg,
will be enforced. You must also ensure that the
schg flag is set on critical startup binaries,
directories, and script files – everything that gets run up
to the point where the securelevel is set. This might be overdoing
it, and upgrading the system is much more difficult when you
operate at a higher secure level. You may compromise and run the
system at a higher secure level but not set the
schg flag for every system file and directory
under the sun. Another possibility is to simply mount
/ and /usr 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.Checking File Integrity: Binaries, Configuration 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
chflags to set the schg bit
on most of the files in / and
/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 – 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 side of the equation a chance to catch
him in the act.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 key-pairs to
allow the limited-access box to ssh to
the other machines. Except for its network traffic, NFS is the
least visible method – allowing you to monitor the
filesystems 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.Once you give a limited-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 &man.find.1; and
&man.md5.1;. It is best to physically md5 the client-box files
at least once a day, and to test control files such as those
found in /etc and
/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 / and
/usr.When using ssh rather than NFS,
writing the security script is much more difficult. You
essentially have to scp the scripts to the client
box in order to
run them, making them visible, and for safety you also need to
scp the binaries (such as find) that those
scripts use. The ssh client on the
client box may already be compromised. All in all, using
ssh may be necessary when running over
insecure links, but it is also a lot harder to deal with.A good security script will also check for changes to user and
staff members access configuration files:
.rhosts, .shosts,
.ssh/authorized_keys and so forth…
files that might fall outside the purview of the
MD5 check.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 and devices on those
partitions is a good idea. The nodev and
nosuid options (see &man.mount.8;) are what you
want to look into. You should probably 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.Process accounting (see &man.accton.8;) is a relatively
low-overhead feature of the operating system which might help
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.Finally, security scripts should process the log files, and the
logs themselves should be generated in as secure a manner as
possible – 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.ParanoiaA little paranoia never hurts. As a rule, a sysadmin can add
any number of security features, as long as they do not effect
convenience, and can add security features that
do effect convenience with some added thought.
Even more importantly, a security administrator should mix it up a
bit – if you use recommendations such as those given by this
document verbatim, you give away your methodologies to the
prospective attacker who also has access to this document.Denial of Service AttacksDenial of Service (DoS)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.Limiting server forks.Limiting springboard attacks (ICMP response attacks, ping
broadcast, etc.).Kernel Route Cache.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. inetd
(see &man.inetd.8;) 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 inetd manual
page carefully and pay
specific attention to the , ,
and options. Note that spoofed-IP attacks
will circumvent the option to
inetd, so
typically a combination of options must be used. Some standalone
servers have self-fork-limitation parameters.Sendmail has its
option, which tends to work
much better than trying to use sendmail's load limiting options
due to the load lag. You should specify a
MaxDaemonChildren parameter, when you start
sendmail, high enough to handle your
expected load, but not so high that the computer cannot handle that
number of sendmails without falling on
its face. It is also prudent to run sendmail in queued mode
() and to run the daemon
(sendmail -bd) separate from the queue-runs
(sendmail -q15m). If you still want real-time
delivery you can run the queue at a much lower interval, such as
, but be sure to specify a reasonable
MaxDaemonChildren option for
that sendmail to prevent cascade failures.Syslogd can be attacked directly
and it is strongly recommended that you use the
option whenever possible, and the option
otherwise.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.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.,
firewall everything except ports A, B,
C, D, and M-Z. This way you can firewall off all of your
low ports except for certain specific services such as
named (if you are primary for a zone),
ntalkd,
sendmail, and other Internet-accessible
services. If you try to configure the firewall the other way
– as an inclusive or permissive firewall, there is a good
chance that you will forget to 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 FreeBSD
allows you to control the range of port numbers used for dynamic
binding, via the various net.inet.ip.portrangesysctl's (sysctl -a | fgrep
portrange), which can also ease the complexity of your
firewall's configuration. For example, you might use a normal
first/last range of 4000 to 5000, and a hiport range of 49152 to
65535, then block off everything under 4000 in your firewall
(except for certain specific Internet-accessible ports, of
course).ICMP_BANDLIMAnother common DoS attack is called a springboard attack
– to attack a server in a manner that causes the server to
generate responses which overloads 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
mbuf's, especially if the server cannot drain the ICMP responses
it generates fast enough. The FreeBSD kernel has a new kernel
compile option called
which limits the effectiveness
of these sorts of attacks. The last major class of springboard
attacks is related to certain internal
inetd 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 inetd-internal test
services.Spoofed packet attacks may also be used to overload the kernel
route cache. Refer to the net.inet.ip.rtexpire,
rtminexpire, and rtmaxcachesysctl parameters. 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
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 rtexpire but will never decrease it
to less than rtminexpire. There are two
problems:The kernel does not react quickly enough when a lightly
loaded server is suddenly attacked.The 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
rtexpire and rtminexpire
via &man.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.Access Issues with Kerberos and SSHsshKerberosThere are a few issues with both Kerberos and
ssh that need to be addressed if
you intend to use them. Kerberos V is an excellent
authentication protocol, but there are bugs in the kerberized
telnet and
rlogin applications that make them
unsuitable for dealing with binary streams. Also, by default
Kerberos does not encrypt a session unless you use the
option. ssh
encrypts everything by default.ssh works quite well in every
respect except that it forwards encryption keys by default. 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
ssh to an insecure machine, your keys
becomes exposed. The actual keys themselves are not exposed, but
ssh installs a forwarding port for the
duration of your login, and if an attacker has broken
root on the
insecure machine he can utilize that port to use your keys to gain
access to any other machine that your keys unlock.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 do). We also recommend that
you either turn off key-forwarding in the
ssh configuration, or that you make use
of the from=IP/DOMAIN option that
ssh allows in its
authorized_keys file to make the key only
usable to entities logging in from specific machines.BillSwingleParts rewritten and updated by DES, MD5, and CryptsecuritycryptcryptDESMD5Every user on a Unix system has a password associated with
their account. It seems obvious that these passwords need to be
known only to the user and the actual operating system. In
order to keep these passwords secret, they are encrypted with
what is known as a one-way hash, that is, they can
only be easily encrypted but not decrypted. In other words, what
we told you a moment ago was obvious is not even true: the
operating system itself does not really know
the password. It only knows the encrypted
form of the password. The only way to get the
plain-text password is by a brute force search of the
space of possible passwords.Unfortunately the only secure way to encrypt passwords when
Unix came into being was based on DES, the Data Encryption
Standard. This was not such a problem for users resident in
the US, but since the source code for DES could not be exported
outside the US, FreeBSD had to find a way to both comply with
US law and retain compatibility with all the other Unix
variants that still used DES.The solution was to divide up the encryption libraries
so that US users could install the DES libraries and use
DES but international users still had an encryption method
that could be exported abroad. This is how FreeBSD came to
use MD5 as its default encryption method. MD5 is believed to
be more secure than DES, so installing DES is offered primarily
for compatibility reasons.Recognizing Your Crypt MechanismBefore FreeBSD 4.4 libcrypt.a was a
symbolic link pointing to the library which was used for
encryption. FreeBSD 4.4 changed libcrypt.a to
provide a configurable password authentication hash library.
Currently the library supports DES, MD5 and Blowfish hash
functions. By default FreeBSD uses MD5 to encrypt
passwords.It is pretty easy to identify which encryption method
FreeBSD is set up to use. Examining the encrypted passwords in
the /etc/master.passwd file is one way.
Passwords encrypted with the MD5 hash are longer than those
encrypted with the DES hash and also begin with the characters
$1$. Passwords starting with
$2$ are encrypted with the
Blowfish hash function. DES password strings do not
have any particular identifying characteristics, but they are
shorter than MD5 passwords, and are coded in a 64-character
alphabet which does not include the $
character, so a relatively short string which does not begin with
a dollar sign is very likely a DES password.The password format used for new passwords is controlled
by the passwd_format login capability in
/etc/login.conf, which takes values of
des or md5 or
blf. See the &man.login.conf.5; manual page
for more information about login capabilities.S/KeyS/KeysecurityS/KeyS/Key is a one-time password scheme based on a one-way hash
function. FreeBSD uses the MD4 hash for compatibility but other
systems have used MD5 and DES-MAC. S/Key has been part of the
FreeBSD base system since version 1.1.5 and is also used on a
growing number of other operating systems. S/Key is a registered
trademark of Bell Communications Research, Inc.From version 5.0 of FreeBSD, S/Key has been replaced with
the functionally equivalent OPIE (Onetime Passwords In
Everything). OPIE uses the MD5 hash by default.There are three different sorts of passwords which we will talk
about in the discussion below. The first is your usual Unix-style or
Kerberos password; we will call this a Unix password.
The second sort is the one-time password which is generated by the
S/Key key program or the OPIE
opiekey program and accepted by the
keyinit or opiepasswd programs
and the login prompt; we will
call this a one-time password. The final sort of
password is the secret password which you give to the
key/opiekey programs (and
sometimes the
keyinit/opiepasswd programs)
which it uses to generate
one-time passwords; we will call it a secret password
or just unqualified password.The secret password does not have anything to do with your Unix
password; they can be the same but this is not recommended. S/Key
and OPIE secret passwords are not limited to 8 characters like Unix
passwords, they can be as long as you like. Passwords of six or
seven word long phrases are fairly common. For the most part, the
S/Key or OPIE system operates completely independently of the Unix
password system.Besides the password, there are two other pieces of data that
are important to S/Key and OPIE. One is what is known as the
seed or key, consisting of two letters
and five digits. The other is what is called the iteration
count, a number between 1 and 100. S/Key creates the
one-time password by concatenating the seed and the secret password,
then applying the MD4/MD5 hash as many times as specified by the
iteration count and turning the result into six short English words.
These six English words are your one-time password. The
authentication system (primarily PAM) keeps
track of the last one-time password used, and the user is
authenticated if the hash of the user-provided password is equal to
the previous password. Because a one-way hash is used it is
impossible to generate future one-time passwords if a successfully
used password is captured; the iteration count is decremented after
each successful login to keep the user and the login program in
sync. When the iteration count gets down to 1, S/Key and OPIE must be
reinitialized.There are three programs involved in each system
which we will discuss below. The key and
opiekey programs accept an iteration
count, a seed, and a secret password, and generate a one-time
password or a consecutive list of one-time passwords. The
keyinit and opiepasswd
programs are used to initialize S/Key and OPIE respectively,
and to change passwords, iteration counts, or seeds; they
take either a secret passphrase, or an iteration count,
seed, and one-time password. The keyinfo
and opieinfo programs examine the
relevant credentials files (/etc/skeykeys or
/etc/opiekeys) and print out the invoking user's
current iteration count and seed.There are four different sorts of operations we will cover. The
first is using keyinit or
opiepasswd over a secure connection to set up
one-time-passwords for the first time, or to change your password
or seed. The second operation is using keyinit
or opiepasswd over an insecure connection, in
conjunction with key or opiekey
over a secure connection, to do the same. The third is using
key/opiekey to log in over
an insecure connection. The fourth is using key
or opiekey to generate a number of keys which
can be written down or printed out to carry with you when going to
some location without secure connections to anywhere.Secure Connection InitializationTo initialize S/Key for the first time, change your password,
or change your seed while logged in over a secure connection
(e.g., on the console of a machine or via ssh), use the
keyinit command without any parameters while
logged in as yourself:&prompt.user; keyinit
Adding unfurl:
Reminder - Only use this method if you are directly connected.
If you are using telnet or rlogin exit with no password and use keyinit -s.
Enter secret password:
Again secret password:
ID unfurl s/key is 99 to17757
DEFY CLUB PRO NASH LACE SOFTFor OPIE, opiepasswd is used instead:&prompt.user; opiepasswd -c
[grimreaper] ~ $ opiepasswd -f -c
Adding unfurl:
Only use this method from the console; NEVER from remote. If you are using
telnet, xterm, or a dial-in, type ^C now or exit with no password.
Then run opiepasswd without the -c parameter.
Using MD5 to compute responses.
Enter new secret pass phrase:
Again new secret pass phrase:
ID unfurl OTP key is 499 to4268
MOS MALL GOAT ARM AVID COED
At the Enter new secret pass phrase: or
Enter secret password: prompts, you
should enter a password or phrase. Remember, this is not the
password that you will use to login with, this is used to generate
your one-time login keys. The ID line gives the
parameters of your particular instance; your login name, the
iteration count, and seed. When logging in the system
will remember these parameters and present them back to you so you
do not have to remember them. The last line gives the particular
one-time password which corresponds to those parameters and your
secret password; if you were to re-login immediately, this
one-time password is the one you would use.Insecure Connection InitializationTo initialize or change your secret password over an
insecure connection, you will need to already have a secure
connection to some place where you can run key
or opiekey; this might be in the form of a
desk accessory on a Macintosh, or a shell prompt on a machine you
trust. You will also need to make up an iteration count (100 is
probably a good value), and you may make up your own seed or use a
randomly-generated one. Over on the insecure connection (to the
machine you are initializing), use the keyinit
-s command:&prompt.user; keyinit -s
Updating unfurl:
Old key: to17758
Reminder you need the 6 English words from the key command.
Enter sequence count from 1 to 9999: 100
Enter new key [default to17759]:
s/key 100 to 17759
s/key access password:
s/key access password:CURE MIKE BANE HIM RACY GOREFor OPIE, you need to use opiepasswd:&prompt.user; opiepasswd
Updating unfurl:
You need the response from an OTP generator.
Old secret pass phrase:
otp-md5 498 to4268 ext
Response: GAME GAG WELT OUT DOWN CHAT
New secret pass phrase:
otp-md5 499 to4269
Response: LINE PAP MILK NELL BUOY TROY
ID mark OTP key is 499 gr4269
LINE PAP MILK NELL BUOY TROY
To accept the default seed (which the
keyinit program confusingly calls a
key), press Return.
Then before entering an
access password, move over to your secure connection or S/Key desk
accessory, and give it the same parameters:&prompt.user; key 100 to17759
Reminder - Do not use this program while logged in via telnet or rlogin.
Enter secret password: <secret password>
CURE MIKE BANE HIM RACY GOREOr for OPIE:&prompt.user; opiekey 498 to4268
Using the MD5 algorithm to compute response.
Reminder: Don't use opiekey from telnet or dial-in sessions.
Enter secret pass phrase:
GAME GAG WELT OUT DOWN CHAT
Now switch back over to the insecure connection, and copy the
one-time password generated over to the relevant program.Generating a Single one-time PasswordOnce you have initialized S/Key or OPIE, when you login you will be
presented with a prompt like this:&prompt.user; telnet example.com
Trying 10.0.0.1...
Connected to example.com
Escape character is '^]'.
FreeBSD/i386 (example.com) (ttypa)
login: <username>
s/key 97 fw13894
Password: Or for OPIE:&prompt.user; telnet example.com
Trying 10.0.0.1...
Connected to example.com
Escape character is '^]'.
FreeBSD/i386 (example.com) (ttypa)
login: <username>
otp-md5 498 gr4269 ext
Password: As a side note, the S/Key and OPIE prompts have a useful feature
(not shown here): if you press Return
at the password prompt, the
prompter will turn echo on, so you can see what you are
typing. This can be extremely useful if you are attempting to
type in a password by hand, such as from a printout.MS-DOSWindowsMacOSAt this point you need to generate your one-time password to
answer this login prompt. This must be done on a trusted system
that you can run key or
opiekey on. (There are versions of these for DOS,
Windows and MacOS as well.) They need both the iteration count and
the seed as command line options. You can cut-and-paste these
right from the login prompt on the machine that you are logging
in to.On the trusted system:&prompt.user; key 97 fw13894
Reminder - Do not use this program while logged in via telnet or rlogin.
Enter secret password:
WELD LIP ACTS ENDS ME HAAGFor OPIE:&prompt.user; opiekey 498 to4268
Using the MD5 algorithm to compute response.
Reminder: Don't use opiekey from telnet or dial-in sessions.
Enter secret pass phrase:
GAME GAG WELT OUT DOWN CHATNow that you have your one-time password you can continue
logging in:login: <username>
s/key 97 fw13894
Password: <return to enable echo>
s/key 97 fw13894
Password [echo on]: WELD LIP ACTS ENDS ME HAAG
Last login: Tue Mar 21 11:56:41 from 10.0.0.2 ... Generating Multiple one-time PasswordsSometimes you have to go places where you do not have
access to a trusted machine or secure connection. In this case,
it is possible to use the key command to
generate a number of one-time passwords before hand to be printed
out and taken with you. For example:&prompt.user; key -n 5 30 zz99999
Reminder - Do not use this program while logged in via telnet or rlogin.
Enter secret password: <secret password>
26: SODA RUDE LEA LIND BUDD SILT
27: JILT SPY DUTY GLOW COWL ROT
28: THEM OW COLA RUNT BONG SCOT
29: COT MASH BARR BRIM NAN FLAG
30: CAN KNEE CAST NAME FOLK BILKThe requests five keys in sequence, the
specifies what the last iteration number
should be. Note that these are printed out in
reverse order of eventual use. If you are
really paranoid, you might want to write the results down by hand;
otherwise you can cut-and-paste into lpr. Note
that each line shows both the iteration count and the one-time
password; you may still find it handy to scratch off passwords as
you use them.Restricting Use of Unix PasswordsRestrictions can be placed on the use of Unix passwords based
on the host name, user name, terminal port, or IP address of a
login session. These restrictions can be found in the
configuration file /etc/skey.access. The
&man.skey.access.5; manual page has more information on the complete
format of the file and also details some security cautions to be
aware of before depending on this file for security.If there is no /etc/skey.access file
(this is the FreeBSD default), then all users will be allowed to
use Unix passwords. If the file exists, however, then all users
will be required to use S/Key unless explicitly permitted to do
otherwise by configuration statements in the
skey.access file. In all cases, Unix
passwords are permitted on the console.Here is a sample configuration file which illustrates the
three most common sorts of configuration statements:permit internet 192.168.0.0 255.255.0.0
permit user fnord
permit port ttyd0The first line (permit internet) allows
users whose IP source address (which is vulnerable to spoofing)
matches the specified value and mask, to use Unix passwords. This
should not be considered a security mechanism, but rather, a means
to remind authorized users that they are using an insecure network
and need to use S/Key for authentication.The second line (permit user) allows the
specified username, in this case fnord, to use
Unix passwords at any time. Generally speaking, this should only
be used for people who are either unable to use the
key program, like those with dumb terminals, or
those who are uneducable.The third line (permit port) allows all
users logging in on the specified terminal line to use Unix
passwords; this would be used for dial-ups.MarkMurrayContributed by MarkDapozBased on a contribution by KerberosKerberosKerberos is a network add-on system/protocol that allows users to
authenticate themselves through the services of a secure server.
Services such as remote login, remote copy, secure inter-system file
copying and other high-risk tasks are made considerably safer and more
controllable.The following instructions can be used as a guide on how to set up
Kerberos as distributed for FreeBSD. However, you should refer to the
relevant manual pages for a complete description.Installing KerberosMITKerberosinstallingKerberos is an optional component of FreeBSD. The easiest
way to install this software is by selecting the 'krb4' or
'krb5' distribution in sysinstall
during the initial installation of FreeBSD. This will install
the 'eBones' (KerberosIV) or 'Heimdal' (Kerberos5)
implementation of Kerberos. These implementations are
included because they are developed outside the USA/Canada and
were thus available to system owners outside those countries
during the era of restrictive export controls on cryptographic
code from the USA.Alternatively, the MIT implementation of Kerberos is
available from the ports collection as
security/krb5.Creating the Initial DatabaseThis is done on the Kerberos server only. First make sure that
you do not have any old Kerberos databases around. You should change
to the directory /etc/kerberosIV and check that
only the following files are present:&prompt.root; cd /etc/kerberosIV
&prompt.root; ls
README krb.conf krb.realmsIf any additional files (such as principal.*
or master_key) exist, then use the
kdb_destroy command to destroy the old Kerberos
database, or if Kerberos is not running, simply delete the extra
files.You should now edit the krb.conf and
krb.realms files to define your Kerberos realm.
In this case the realm will be EXAMPLE.COM and the
server is grunt.example.com. We edit
or create the krb.conf file:&prompt.root; cat krb.conf
EXAMPLE.COM
EXAMPLE.COM grunt.example.com admin server
CS.BERKELEY.EDU okeeffe.berkeley.edu
ATHENA.MIT.EDU kerberos.mit.edu
ATHENA.MIT.EDU kerberos-1.mit.edu
ATHENA.MIT.EDU kerberos-2.mit.edu
ATHENA.MIT.EDU kerberos-3.mit.edu
LCS.MIT.EDU kerberos.lcs.mit.edu
TELECOM.MIT.EDU bitsy.mit.edu
ARC.NASA.GOV trident.arc.nasa.govIn this case, the other realms do not need to be there. They are
here as an example of how a machine may be made aware of multiple
realms. You may wish to not include them for simplicity.The first line names the realm in which this system works. The
other lines contain realm/host entries. The first item on a line is a
realm, and the second is a host in that realm that is acting as a
key distribution center. The words admin
server following a host's name means that host also
provides an administrative database server. For further explanation
of these terms, please consult the Kerberos manual pages.Now we have to add grunt.example.com
to the EXAMPLE.COM realm and also add an entry to
put all hosts in the .example.com
domain in the EXAMPLE.COM realm. The
krb.realms file would be updated as
follows:&prompt.root; cat krb.realms
grunt.example.com EXAMPLE.COM
.example.com EXAMPLE.COM
.berkeley.edu CS.BERKELEY.EDU
.MIT.EDU ATHENA.MIT.EDU
.mit.edu ATHENA.MIT.EDUAgain, the other realms do not need to be there. They are here as
an example of how a machine may be made aware of multiple realms. You
may wish to remove them to simplify things.The first line puts the specific system into
the named realm. The rest of the lines show how to default systems of
a particular subdomain to a named realm.Now we are ready to create the database. This only needs to run
on the Kerberos server (or Key Distribution Center). Issue the
kdb_init command to do this:&prompt.root; kdb_initRealm name [default ATHENA.MIT.EDU ]:EXAMPLE.COM
You will be prompted for the database Master Password.
It is important that you NOT FORGET this password.
Enter Kerberos master key:Now we have to save the key so that servers on the local machine
can pick it up. Use the kstash command to do
this.&prompt.root; kstashEnter Kerberos master key:
Current Kerberos master key version is 1.
Master key entered. BEWARE!This saves the encrypted master password in
/etc/kerberosIV/master_key.Making It All RunTwo principals need to be added to the database for
each system that will be secured with Kerberos.
Their names are kpasswd and rcmd
These two principals are made for each system, with the instance being
the name of the individual system.These daemons, kpasswd and
rcmd allow other systems to change Kerberos
passwords and run commands like rcp,
rlogin and rsh.Now let us add these entries:&prompt.root; kdb_edit
Opening database...
Enter Kerberos master key:
Current Kerberos master key version is 1.
Master key entered. BEWARE!
Previous or default values are in [brackets] ,
enter return to leave the same, or new value.
Principal name:passwdInstance:grunt
<Not found>, Create [y] ?y
Principal: passwd, Instance: grunt, kdc_key_ver: 1
New Password: <---- enter RANDOM here
Verifying password
New Password: <---- enter RANDOM here
Random password [y] ?y
Principal's new key version = 1
Expiration date (enter yyyy-mm-dd) [ 2000-01-01 ] ?Max ticket lifetime (*5 minutes) [ 255 ] ?Attributes [ 0 ] ?
Edit O.K.
Principal name:rcmdInstance:grunt
<Not found>, Create [y] ?
Principal: rcmd, Instance: grunt, kdc_key_ver: 1
New Password: <---- enter RANDOM here
Verifying password
New Password: <---- enter RANDOM here
Random password [y] ?
Principal's new key version = 1
Expiration date (enter yyyy-mm-dd) [ 2000-01-01 ] ?Max ticket lifetime (*5 minutes) [ 255 ] ?Attributes [ 0 ] ?
Edit O.K.
Principal name: <---- null entry here will cause an exitCreating the Server FileWe now have to extract all the instances which define the
services on each machine. For this we use the
ext_srvtab command. This will create a file
which must be copied or moved by secure
means to each Kerberos client's
/etc/kerberosIV directory. This file must
be present on each server and client, and is crucial to the
operation of Kerberos.&prompt.root; ext_srvtab gruntEnter Kerberos master key:
Current Kerberos master key version is 1.
Master key entered. BEWARE!
Generating 'grunt-new-srvtab'....Now, this command only generates a temporary file which must be
renamed to srvtab so that all the servers can pick
it up. Use the mv command to move it into place on
the original system:&prompt.root; mv grunt-new-srvtab srvtabIf the file is for a client system, and the network is not deemed
safe, then copy the
client-new-srvtab to
removable media and transport it by secure physical means. Be sure to
rename it to srvtab in the client's
/etc/kerberosIV directory, and make sure it is
mode 600:&prompt.root; mv grumble-new-srvtab srvtab
&prompt.root; chmod 600 srvtabPopulating the DatabaseWe now have to add some user entries into the database. First
let us create an entry for the user jane. Use the
kdb_edit command to do this:&prompt.root; kdb_edit
Opening database...
Enter Kerberos master key:
Current Kerberos master key version is 1.
Master key entered. BEWARE!
Previous or default values are in [brackets] ,
enter return to leave the same, or new value.
Principal name:janeInstance:
<Not found>, Create [y] ?y
Principal: jane, Instance: , kdc_key_ver: 1
New Password: <---- enter a secure password here
Verifying password
New Password: <---- re-enter the password here
Principal's new key version = 1
Expiration date (enter yyyy-mm-dd) [ 2000-01-01 ] ?Max ticket lifetime (*5 minutes) [ 255 ] ?Attributes [ 0 ] ?
Edit O.K.
Principal name: <---- null entry here will cause an exitTesting It All OutFirst we have to start the Kerberos daemons. NOTE that if you
have correctly edited your /etc/rc.conf then this
will happen automatically when you reboot. This is only necessary on
the Kerberos server. Kerberos clients will automagically get what
they need from the /etc/kerberosIV
directory.&prompt.root; kerberos &
Kerberos server starting
Sleep forever on error
Log file is /var/log/kerberos.log
Current Kerberos master key version is 1.
Master key entered. BEWARE!
Current Kerberos master key version is 1
Local realm: EXAMPLE.COM
&prompt.root; kadmind -n &
KADM Server KADM0.0A initializing
Please do not use 'kill -9' to kill this job, use a
regular kill instead
Current Kerberos master key version is 1.
Master key entered. BEWARE!Now we can try using the kinit command to get a
ticket for the id jane that we created
above:&prompt.user; kinit jane
MIT Project Athena (grunt.example.com)
Kerberos Initialization for "jane"
Password:Try listing the tokens using klist to see if we
really have them:&prompt.user; klist
Ticket file: /tmp/tkt245
Principal: jane@EXAMPLE.COM
Issued Expires Principal
Apr 30 11:23:22 Apr 30 19:23:22 krbtgt.EXAMPLE.COM@EXAMPLE.COMNow try changing the password using passwd to
check if the kpasswd daemon can get
authorization to the Kerberos database:&prompt.user; passwd
realm EXAMPLE.COM
Old password for jane:New Password for jane:
Verifying password
New Password for jane:
Password changed.Adding su PrivilegesKerberos allows us to give each user
who needs root privileges their own
separatesu password.
We could now add an id which is authorized to
su to root. This is
controlled by having an instance of root
associated with a principal. Using kdb_edit
we can create the entry jane.root in the
Kerberos database:&prompt.root; kdb_edit
Opening database...
Enter Kerberos master key:
Current Kerberos master key version is 1.
Master key entered. BEWARE!
Previous or default values are in [brackets] ,
enter return to leave the same, or new value.
Principal name:janeInstance:root
<Not found>, Create [y] ? y
Principal: jane, Instance: root, kdc_key_ver: 1
New Password: <---- enter a SECURE password here
Verifying password
New Password: <---- re-enter the password here
Principal's new key version = 1
Expiration date (enter yyyy-mm-dd) [ 2000-01-01 ] ?Max ticket lifetime (*5 minutes) [ 255 ] ?12 <--- Keep this short!
Attributes [ 0 ] ?
Edit O.K.
Principal name: <---- null entry here will cause an exitNow try getting tokens for it to make sure it works:&prompt.root; kinit jane.root
MIT Project Athena (grunt.example.com)
Kerberos Initialization for "jane.root"
Password:Now we need to add the user to root's
.klogin file:&prompt.root; cat /root/.klogin
jane.root@EXAMPLE.COMNow try doing the su:&prompt.user; suPassword:and take a look at what tokens we have:&prompt.root; klist
Ticket file: /tmp/tkt_root_245
Principal: jane.root@EXAMPLE.COM
Issued Expires Principal
May 2 20:43:12 May 3 04:43:12 krbtgt.EXAMPLE.COM@EXAMPLE.COMUsing Other CommandsIn an earlier example, we created a principal called
jane with an instance root.
This was based on a user with the same name as the principal, and this
is a Kerberos default; that a
<principal>.<instance> of the form
<username>.root will allow
that <username> to su to
root if the necessary entries are in the
.klogin file in root's
home directory:&prompt.root; cat /root/.klogin
jane.root@EXAMPLE.COMLikewise, if a user has in their own home directory lines of the
form:&prompt.user; cat ~/.klogin
jane@EXAMPLE.COM
jack@EXAMPLE.COMThis allows anyone in the EXAMPLE.COM realm
who has authenticated themselves to jane or
jack (via kinit, see above)
access to rlogin to jane's
account or files on this system (grunt) via
rlogin, rsh or
rcp.For example, jane now logs into another system using
Kerberos:&prompt.user; kinit
MIT Project Athena (grunt.example.com)
Password:
&prompt.user; rlogin grunt
Last login: Mon May 1 21:14:47 from grumble
Copyright (c) 1980, 1983, 1986, 1988, 1990, 1991, 1993, 1994
The Regents of the University of California. All rights reserved.
FreeBSD BUILT-19950429 (GR386) #0: Sat Apr 29 17:50:09 SAT 1995Or Jack logs into Jane's account on the same machine
(jane having
set up the .klogin file as above, and the person
in charge of Kerberos having set up principal
jack with a null instance:&prompt.user; kinit
&prompt.user; rlogin grunt -l jane
MIT Project Athena (grunt.example.com)
Password:
Last login: Mon May 1 21:16:55 from grumble
Copyright (c) 1980, 1983, 1986, 1988, 1990, 1991, 1993, 1994
The Regents of the University of California. All rights reserved.
FreeBSD BUILT-19950429 (GR386) #0: Sat Apr 29 17:50:09 SAT 1995GaryPalmerContributed by AlexNashFirewallsfirewallsecurityfirewallsFirewalls are an area of increasing interest for people who are
connected to the Internet, and are even finding applications on private
networks to provide enhanced security. This section will hopefully
explain what firewalls are, how to use them, and how to use the
facilities provided in the FreeBSD kernel to implement them.People often think that having a firewall between your
internal network and the Big Bad Internet will solve all
your security problems. It may help, but a poorly setup firewall
system is more of a security risk than not having one at all. A
firewall can add another layer of security to your systems, but it
cannot stop a really determined cracker from penetrating your internal
network. If you let internal security lapse because you believe your
firewall to be impenetrable, you have just made the crackers job that
much easier.What Is a Firewall?There are currently two distinct types of firewalls in common use
on the Internet today. The first type is more properly called a
packet filtering router, where the kernel on a
multi-homed machine chooses whether to forward or block packets based
on a set of rules. The second type, known as a proxy
server, relies on daemons to provide authentication and to
forward packets, possibly on a multi-homed machine which has kernel
packet forwarding disabled.Sometimes sites combine the two types of firewalls, so that only a
certain machine (known as a bastion host) is
allowed to send packets through a packet filtering router onto an
internal network. Proxy services are run on the bastion host, which
are generally more secure than normal authentication
mechanisms.FreeBSD comes with a kernel packet filter (known as
IPFW), which is what the rest of this
section will concentrate on. Proxy servers can be built on FreeBSD
from third party software, but there is such a variety of proxy
servers available that it would be impossible to cover them in this
section.Packet Filtering RoutersA router is a machine which forwards packets between two or more
networks. A packet filtering router has an extra piece of code in
its kernel which compares each packet to a list of rules before
deciding if it should be forwarded or not. Most modern IP routing
software has packet filtering code within it that defaults to
forwarding all packets. To enable the filters, you need to define a
set of rules for the filtering code so it can decide if the
packet should be allowed to pass or not.To decide whether a packet should be passed on, the code looks
through its set of rules for a rule which matches the contents of
this packets headers. Once a match is found, the rule action is
obeyed. The rule action could be to drop the packet, to forward the
packet, or even to send an ICMP message back to the originator.
Only the first match counts, as the rules are searched in order.
Hence, the list of rules can be referred to as a rule
chain.The packet matching criteria varies depending on the software
used, but typically you can specify rules which depend on the source
IP address of the packet, the destination IP address, the source
port number, the destination port number (for protocols which
support ports), or even the packet type (UDP, TCP, ICMP,
etc).Proxy ServersProxy servers are machines which have had the normal system
daemons (telnetd,
ftpd, etc) replaced with special servers.
These
servers are called proxy servers as they
normally only allow onward connections to be made. This enables you
to run (for example) a proxy telnet server on your firewall host,
and people can telnet in to your firewall from the outside, go
through some authentication mechanism, and then gain access to the
internal network (alternatively, proxy servers can be used for
signals coming from the internal network and heading out).Proxy servers are normally more secure than normal servers, and
often have a wider variety of authentication mechanisms available,
including one-shot password systems so that even if
someone manages to discover what password you used, they will not be
able to use it to gain access to your systems as the password
instantly expires. As they do not actually give users access to the
host machine, it becomes a lot more difficult for someone to install
backdoors around your security system.Proxy servers often have ways of restricting access further, so
that only certain hosts can gain access to the servers, and often
they can be set up so that you can limit which users can talk to
which destination machine. Again, what facilities are available
depends largely on what proxy software you choose.What Does IPFW Allow Me to Do?ipfwIPFW, the software supplied with
FreeBSD, is a packet filtering and accounting system which resides in
the kernel, and has a user-land control utility,
&man.ipfw.8;. Together, they allow you to define and query the
rules currently used by the kernel in its routing decisions.There are two related parts to IPFW.
The firewall section allows you to perform packet filtering. There is
also an IP accounting section which allows you to track usage of your
router, based on similar rules to the firewall section. This allows
you to see (for example) how much traffic your router is getting from
a certain machine, or how much WWW (World Wide Web) traffic it is
forwarding.As a result of the way that IPFW is
designed, you can use IPFW on non-router
machines to perform packet filtering on incoming and outgoing
connections. This is a special case of the more general use of
IPFW, and the same commands and techniques
should be used in this situation.Enabling IPFW on FreeBSDipfwenablingAs the main part of the IPFW system
lives in the kernel, you will need to add one or more options to your
kernel configuration file, depending on what facilities you want, and
recompile your kernel. See "Reconfiguring your Kernel" ()
for more details on how to recompile your
kernel.There are currently three kernel configuration options relevant to
IPFW:options IPFIREWALLCompiles into the kernel the code for packet
filtering.options IPFIREWALL_VERBOSEEnables code to allow logging of packets through
&man.syslogd.8;. Without this option, even if you specify
that packets should be logged in the filter rules, nothing will
happen.options IPFIREWALL_VERBOSE_LIMIT=10Limits the number of packets logged through
&man.syslogd.8; on a per entry basis. You may wish to use
this option in hostile environments in which you want to log
firewall activity, but do not want to be open to a denial of
service attack via syslog flooding.When a chain entry reaches the packet limit specified,
logging is turned off for that particular entry. To resume
logging, you will need to reset the associated counter using the
&man.ipfw.8; utility:&prompt.root; ipfw zero 4500Where 4500 is the chain entry you wish to continue
logging.Previous versions of FreeBSD contained an
IPFIREWALL_ACCT option. This is now obsolete as
the firewall code automatically includes accounting
facilities.Configuring IPFWipfwconfiguringThe configuration of the IPFW software
is done through the &man.ipfw.8; utility. The syntax for this
command looks quite complicated, but it is relatively simple once you
understand its structure.There are currently four different command categories used by the
utility: addition/deletion, listing, flushing, and clearing.
Addition/deletion is used to build the rules that control how packets
are accepted, rejected, and logged. Listing is used to examine the
contents of your rule set (otherwise known as the chain) and packet
counters (accounting). Flushing is used to remove all entries from
the chain. Clearing is used to zero out one or more accounting
entries.Altering the IPFW RulesThe syntax for this form of the command is:
ipfw-NcommandindexactionlogprotocoladdressesoptionsThere is one valid flag when using this form of the
command:-NResolve addresses and service names in output.The command given can be shortened to the
shortest unique form. The valid commands
are:addAdd an entry to the firewall/accounting rule listdeleteDelete an entry from the firewall/accounting rule
listPrevious versions of IPFW used
separate firewall and accounting entries. The present version
provides packet accounting with each firewall entry.If an index value is supplied, it is used to
place the entry at a specific point in the chain. Otherwise, the
entry is placed at the end of the chain at an index 100 greater than
the last chain entry (this does not include the default policy, rule
65535, deny).The log option causes matching rules to be
output to the system console if the kernel was compiled with
IPFIREWALL_VERBOSE.Valid actions are:rejectDrop the packet, and send an ICMP host or port unreachable
(as appropriate) packet to the source.allowPass the packet on as normal. (aliases:
pass and
accept)denyDrop the packet. The source is not notified via an
ICMP message (thus it appears that the packet never
arrived at the destination).countUpdate packet counters but do not allow/deny the packet
based on this rule. The search continues with the next chain
entry.Each action will be recognized by the
shortest unambiguous prefix.The protocols which can be specified
are:allMatches any IP packeticmpMatches ICMP packetstcpMatches TCP packetsudpMatches UDP packetsThe address specification is:fromaddress/maskporttoaddress/maskportvia interfaceYou can only specify port in
conjunction with protocols which support ports
(UDP and TCP).The is optional and may specify the IP
address or domain name of a local IP interface, or an interface name
(e.g. ed0) to match only packets coming
through this interface. Interface unit numbers can be specified
with an optional wildcard. For example, ppp*
would match all kernel PPP interfaces.The syntax used to specify an
address/mask is:
address
or
address/mask-bits
or
address:mask-patternA valid hostname may be specified in place of the IP address.
is a decimal
number representing how many bits in the address mask should be set.
e.g. specifying 192.216.222.1/24 will create a
mask which will allow any address in a class C subnet (in this case,
192.216.222) to be matched.
is an IP
address which will be logically AND'ed with the address given. The
keyword any may be used to specify any IP
address.The port numbers to be blocked are specified as:
port,port,port…
to specify either a single port or a list of ports, or
port-port
to specify a range of ports. You may also combine a single range
with a list, but the range must always be specified first.The options available are:fragMatches if the packet is not the first fragment of the
datagram.inMatches if the packet is on the way in.outMatches if the packet is on the way out.ipoptions specMatches if the IP header contains the comma separated list
of options specified in spec. The
supported list of IP options are: ssrr
(strict source route), lsrr (loose source
route), rr (record packet route), and
ts (time stamp). The absence of a
particular option may be denoted with a leading
!.establishedMatches if the packet is part of an already established
TCP connection (i.e. it has the RST or ACK bits set). You can
optimize the performance of the firewall by placing
established rules early in the
chain.setupMatches if the packet is an attempt to establish a TCP
connection (the SYN bit is set but the ACK bit is
not).tcpflags flagsMatches if the TCP header contains the comma separated
list of flags. The supported flags
are fin, syn,
rst, psh,
ack, and urg. The
absence of a particular flag may be indicated by a leading
!.icmptypes typesMatches if the ICMP type is present in the list
types. The list may be specified
as any combination of ranges and/or individual types separated
by commas. Commonly used ICMP types are: 0
echo reply (ping reply), 3 destination
unreachable, 5 redirect,
8 echo request (ping request), and
11 time exceeded (used to indicate TTL
expiration as with &man.traceroute.8;).Listing the IPFW RulesThe syntax for this form of the command is:
ipfw-a-t-NlThere are three valid flags when using this form of the
command:-aWhile listing, show counter values. This option is the
only way to see accounting counters.-tDisplay the last match times for each chain entry. The
time listing is incompatible with the input syntax used by the
&man.ipfw.8; utility.-NAttempt to resolve given addresses and service
names.Flushing the IPFW RulesThe syntax for flushing the chain is:
ipfwflushThis causes all entries in the firewall chain to be removed
except the fixed default policy enforced by the kernel (index
65535). Use caution when flushing rules, the default deny policy
will leave your system cut off from the network until allow entries
are added to the chain.Clearing the IPFW Packet CountersThe syntax for clearing one or more packet counters is:
ipfwzeroindexWhen used without an index argument,
all packet counters are cleared. If an
index is supplied, the clearing operation
only affects a specific chain entry.Example Commands for ipfwThis command will deny all packets from the host evil.crackers.org to the telnet port of the
host nice.people.org:&prompt.root; ipfw add deny tcp from evil.crackers.org to nice.people.org 23The next example denies and logs any TCP traffic from the entire
crackers.org network (a class C) to
the nice.people.org machine (any
port).&prompt.root; ipfw add deny log tcp from evil.crackers.org/24 to nice.people.orgIf you do not want people sending X sessions to your internal
network (a subnet of a class C), the following command will do the
necessary filtering:&prompt.root; ipfw add deny tcp from any to my.org/28 6000 setupTo see the accounting records:
&prompt.root; ipfw -a list
or in the short form
&prompt.root; ipfw -a lYou can also see the last time a chain entry was matched
with:&prompt.root; ipfw -at lBuilding a Packet Filtering FirewallThe following suggestions are just that: suggestions. The
requirements of each firewall are different and we cannot tell you
how to build a firewall to meet your particular requirements.When initially setting up your firewall, unless you have a test
bench setup where you can configure your firewall host in a controlled
environment, it is strongly recommend you use the logging version of the
commands and enable logging in the kernel. This will allow you to
quickly identify problem areas and cure them without too much
disruption. Even after the initial setup phase is complete, I
recommend using the logging for `deny' as it allows tracing of
possible attacks and also modification of the firewall rules if your
requirements alter.If you use the logging versions of the accept
command, it can generate large amounts of log
data as one log line will be generated for every packet that passes
through the firewall, so large FTP/http transfers, etc, will really
slow the system down. It also increases the latencies on those
packets as it requires more work to be done by the kernel before the
packet can be passed on. syslogd will
also start using up a lot
more processor time as it logs all the extra data to disk, and it
could quite easily fill the partition /var/log
is located on.You should enable your firewall from
/etc/rc.conf.local or
/etc/rc.conf. The associated manual page explains
which knobs to fiddle and lists some preset firewall configurations.
If you do not use a preset configuration, ipfw list
will output the current ruleset into a file that you can
pass to rc.conf. If you do not use
/etc/rc.conf.local or
/etc/rc.conf to enable your firewall,
it is important to make sure your firewall is enabled before
any IP interfaces are configured.The next problem is what your firewall should actually
do! This is largely dependent on what access to
your network you want to allow from the outside, and how much access
to the outside world you want to allow from the inside. Some general
rules are:Block all incoming access to ports below 1024 for TCP. This is
where most of the security sensitive services are, like finger,
SMTP (mail) and telnet.Block all incoming UDP traffic. There
are very few useful services that travel over UDP, and what useful
traffic there is, is normally a security threat (e.g. Suns RPC and
NFS protocols). This has its disadvantages also, since UDP is a
connectionless protocol, denying incoming UDP traffic also blocks
the replies to outgoing UDP traffic. This can cause a problem for
people (on the inside) using external archie (prospero) servers.
If you want to allow access to archie, you will have to allow
packets coming from ports 191 and 1525 to any internal UDP port
through the firewall. ntp is another
service you may consider allowing through, which comes from port
123.Block traffic to port 6000 from the outside. Port 6000 is the
port used for access to X11 servers, and can be a security threat
(especially if people are in the habit of doing xhost
+ on their workstations). X11 can actually use a
range of ports starting at 6000, the upper limit being how many X
displays you can run on the machine. The upper limit as defined
by RFC 1700 (Assigned Numbers) is 6063.Check what ports any internal servers use (e.g. SQL servers,
etc). It is probably a good idea to block those as well, as they
normally fall outside the 1-1024 range specified above.Another checklist for firewall configuration is available from
CERT at http://www.cert.org/tech_tips/packet_filtering.htmlAs stated above, these are only guidelines.
You will have to decide what filter rules you want to use on your
firewall yourself. We cannot accept ANY responsibility if someone
breaks into your network, even if you follow the advice given
above.IPFW Overhead and OptimizationMany people want to know how much overhead IPFW adds to a
system. The answer to this depends mostly on your rule set and
processor speed. For most applications dealing with Ethernet
and small rule sets, the answer is
negligible. For those of you that need actual
measurements to satisfy your curiosity, read on.The following measurements were made using 2.2.5-STABLE on
a 486-66. (While IPFW has changed slightly in later releases
of FreeBSD, it still performs with similar speed.) IPFW was
modified to measure the time spent within the
ip_fw_chk routine, displaying the results
to the console every 1000 packets.Two rule sets, each with 1000 rules were tested. The
first set was designed to demonstrate a worst case scenario by
repeating the rule:&prompt.root; ipfw add deny tcp from any to any 55555This demonstrates worst case by causing most of IPFW's
packet check routine to be executed before finally deciding
that the packet does not match the rule (by virtue of the port
number). Following the 999th iteration of this rule was an
allow ip from any to any.The second set of rules were designed to abort the rule
check quickly:&prompt.root; ipfw add deny ip from 1.2.3.4 to 1.2.3.4The non-matching source IP address for the above rule
causes these rules to be skipped very quickly. As before, the
1000th rule was an allow ip from any to
any.The per-packet processing overhead in the former case was
approximately 2.703ms/packet, or roughly 2.7 microseconds per
rule. Thus the theoretical packet processing limit with these
rules is around 370 packets per second. Assuming 10Mbps
Ethernet and a ~1500 byte packet size, we would only be able
to achieve a 55.5% bandwidth utilization.For the latter case each packet was processed in
approximately 1.172ms, or roughly 1.2 microseconds per rule.
The theoretical packet processing limit here would be about
853 packets per second, which could consume 10Mbps Ethernet
bandwidth.The excessive number of rules tested and the nature of
those rules do not provide a real-world scenario -- they were
used only to generate the timing information presented here.
Here are a few things to keep in mind when building an
efficient rule set:Place an established rule early on
to handle the majority of TCP traffic. Do not put any
allow tcp statements before this
rule.Place heavily triggered rules earlier in the rule set
than those rarely used (without changing the
permissiveness of the firewall, of course).
You can see which rules are used most often by examining
the packet counting statistics with ipfw -a
l.OpenSSLsecurityOpenSSLOpenSSLAs of FreeBSD 4.0, the OpenSSL toolkit is a part of the base
system. OpenSSL
provides a general-purpose cryptography library, as well as the
Secure Sockets Layer v2/v3 (SSLv2/SSLv3) and Transport Layer
Security v1 (TLSv1) network security protocols.However, one of the algorithms (specifically IDEA)
included in OpenSSL is protected by patents in the USA and
elsewhere, and is not available for unrestricted use.
IDEA is included in the OpenSSL sources in FreeBSD, but it is not
built by default. If you wish to use it, and you comply with the
license terms, enable the MAKE_IDEA switch in
/etc/make.conf and
rebuild your sources using make world.Today, the RSA algorithm is free for use in USA and other
countries. In the past it was protected by a patent.OpenSSLinstallSource Code InstallationsOpenSSL is part of the src-crypto and
src-secure cvsup collections. See the Obtaining FreeBSD section for more
information about obtaining and updating FreeBSD source
code.YoshinobuInoueContributed by IPsecIPsecsecurityIPsecTerminating CharactersThroughout examples in this section, and other sections,
you will notice that there is a ^D at the end
of some examples. This means to hold down the Control
key and hit the D key. Another commonly used
character is ^C, which respectively means to hold
down Control and press C.
- For other HOWTOs detailing IPSec implementation in
+ For other HOWTOs detailing IPsec implementation in
FreeBSD, take a look at
and .The IPsec mechanism provides secure communication for IP
layer and socket layer communication. This section should
explain how to use them. For implementation details, please
refer to The
Developers' Handbook.The current IPsec implementation supports both transport mode
and tunnel mode. However, tunnel mode comes with some restrictions.
http://www.kame.net/newsletter/
has more comprehensive examples.Please be aware that in order to use this functionality, you
must have the following options compiled into your kernel:options IPSEC #IP security
options IPSEC_ESP #IP security (crypto; define w/IPSEC)Transport Mode Example with IPv4Let us setup security association to deploy a secure channel
between HOST A (10.2.3.4) and HOST B (10.6.7.8). Here we show a little
complicated example. From HOST A to HOST B, only old AH is used.
From HOST B to HOST A, new AH and new ESP are combined.Now we should choose an algorithm to be used corresponding to
AH/new AH/ESP/
new ESP. Please refer to the &man.setkey.8; man
page to know algorithm names. Our choice is MD5 for AH, new-HMAC-SHA1
for new AH, and new-DES-expIV with 8 byte IV for new ESP.Key length highly depends on each algorithm. For example, key
length must be equal to 16 bytes for MD5, 20 for new-HMAC-SHA1,
and 8 for new-DES-expIV. Now we choose MYSECRETMYSECRET,
KAMEKAMEKAMEKAMEKAME, PASSWORD,
respectively.OK, let us assign SPI (Security Parameter Index) for each protocol.
Please note that we need 3 SPIs for this secure channel since three
security headers are produced (one for from HOST A to HOST B, two for
from HOST B to HOST A). Please also note that SPI MUST be greater
than or equal to 256. We choose, 1000, 2000, and 3000,
respectively.
(1)
HOST A ------> HOST B
(1)PROTO=AH
ALG=MD5(RFC1826)
KEY=MYSECRETMYSECRET
SPI=1000
(2.1)
HOST A <------ HOST B
<------
(2.2)
(2.1)
PROTO=AH
ALG=new-HMAC-SHA1(new AH)
KEY=KAMEKAMEKAMEKAMEKAME
SPI=2000
(2.2)
PROTO=ESP
ALG=new-DES-expIV(new ESP)
IV length = 8
KEY=PASSWORD
SPI=3000
Now, let us setup security association. Execute &man.setkey.8;
on both HOST A and B:
&prompt.root; setkey -c
add 10.2.3.4 10.6.7.8 ah-old 1000 -m transport -A keyed-md5 "MYSECRETMYSECRET" ;
add 10.6.7.8 10.2.3.4 ah 2000 -m transport -A hmac-sha1 "KAMEKAMEKAMEKAMEKAME" ;
add 10.6.7.8 10.2.3.4 esp 3000 -m transport -E des-cbc "PASSWORD" ;
^D
Actually, IPsec communication does not process until security policy
entries are defined. In this case, you must setup each host.
At A:
&prompt.root; setkey -c
spdadd 10.2.3.4 10.6.7.8 any -P out ipsec
ah/transport/10.2.3.4-10.6.7.8/require ;
^D
At B:
&prompt.root; setkey -c
spdadd 10.6.7.8 10.2.3.4 any -P out ipsec
esp/transport/10.6.7.8-10.2.3.4/require ;
spdadd 10.6.7.8 10.2.3.4 any -P out ipsec
ah/transport/10.6.7.8-10.2.3.4/require ;
^D
HOST A --------------------------------------> HOST E
10.2.3.4 10.6.7.8
| |
========== old AH keyed-md5 ==========>
<========= new AH hmac-sha1 ===========
<========= new ESP des-cbc ============
Transport Mode Example with IPv6Another example using IPv6.ESP transport mode is recommended for TCP port number 110 between
Host-A and Host-B.
============ ESP ============
| |
Host-A Host-B
fec0::10 -------------------- fec0::11
Encryption algorithm is blowfish-cbc whose key is
kamekame, and authentication algorithm is hmac-sha1
whose key is this is the test key.
Configuration at Host-A:
&prompt.root; setkey -c <<EOF
spdadd fec0::10[any] fec0::11[110] tcp -P out ipsec
esp/transport/fec0::10-fec0::11/use ;
spdadd fec0::11[110] fec0::10[any] tcp -P in ipsec
esp/transport/fec0::11-fec0::10/use ;
add fec0::10 fec0::11 esp 0x10001
-m transport
-E blowfish-cbc "kamekame"
-A hmac-sha1 "this is the test key" ;
add fec0::11 fec0::10 esp 0x10002
-m transport
-E blowfish-cbc "kamekame"
-A hmac-sha1 "this is the test key" ;
EOF
and at Host-B:&prompt.root; setkey -c <<EOF
spdadd fec0::11[110] fec0::10[any] tcp -P out ipsec
esp/transport/fec0::11-fec0::10/use ;
spdadd fec0::10[any] fec0::11[110] tcp -P in ipsec
esp/transport/fec0::10-fec0::11/use ;
add fec0::10 fec0::11 esp 0x10001 -m transport
-E blowfish-cbc "kamekame"
-A hmac-sha1 "this is the test key" ;
add fec0::11 fec0::10 esp 0x10002 -m transport
-E blowfish-cbc "kamekame"
-A hmac-sha1 "this is the test key" ;
EOF
Note the direction of SP.Tunnel Mode Example with IPv4Tunnel mode between two security gatewaysSecurity protocol is old AH tunnel mode, i.e. specified by
RFC1826, with keyed-md5 whose key is this is the test as
authentication algorithm.
======= AH =======
| |
Network-A Gateway-A Gateway-B Network-B
10.0.1.0/24 ---- 172.16.0.1 ----- 172.16.0.2 ---- 10.0.2.0/24
Configuration at Gateway-A:
&prompt.root; setkey -c <<EOF
spdadd 10.0.1.0/24 10.0.2.0/24 any -P out ipsec
ah/tunnel/172.16.0.1-172.16.0.2/require ;
spdadd 10.0.2.0/24 10.0.1.0/24 any -P in ipsec
ah/tunnel/172.16.0.2-172.16.0.1/require ;
add 172.16.0.1 172.16.0.2 ah-old 0x10003 -m any
-A keyed-md5 "this is the test" ;
add 172.16.0.2 172.16.0.1 ah-old 0x10004 -m any
-A keyed-md5 "this is the test" ;
EOF
If the port number field is omitted such as above then
[any] is employed. -m
specifies the mode of SA to be used. -m any means
wild-card of mode of security protocol. You can use this SA for both
tunnel and transport mode.and at Gateway-B:
&prompt.root; setkey -c <<EOF
spdadd 10.0.2.0/24 10.0.1.0/24 any -P out ipsec
ah/tunnel/172.16.0.2-172.16.0.1/require ;
spdadd 10.0.1.0/24 10.0.2.0/24 any -P in ipsec
ah/tunnel/172.16.0.1-172.16.0.2/require ;
add 172.16.0.1 172.16.0.2 ah-old 0x10003 -m any
-A keyed-md5 "this is the test" ;
add 172.16.0.2 172.16.0.1 ah-old 0x10004 -m any
-A keyed-md5 "this is the test" ;
EOF
Making SA bundle between two security gatewaysAH transport mode and ESP tunnel mode is required between
Gateway-A and Gateway-B. In this case, ESP tunnel mode is applied first,
and AH transport mode is next.
========== AH =========
| ======= ESP ===== |
| | | |
Network-A Gateway-A Gateway-B Network-B
fec0:0:0:1::/64 --- fec0:0:0:1::1 ---- fec0:0:0:2::1 --- fec0:0:0:2::/64
Tunnel Mode Example with IPv6Encryption algorithm is 3des-cbc, and authentication algorithm
for ESP is hmac-sha1. Authentication algorithm for AH is hmac-md5.
Configuration at Gateway-A:
&prompt.root; setkey -c <<EOF
spdadd fec0:0:0:1::/64 fec0:0:0:2::/64 any -P out ipsec
esp/tunnel/fec0:0:0:1::1-fec0:0:0:2::1/require
ah/transport/fec0:0:0:1::1-fec0:0:0:2::1/require ;
spdadd fec0:0:0:2::/64 fec0:0:0:1::/64 any -P in ipsec
esp/tunnel/fec0:0:0:2::1-fec0:0:0:1::1/require
ah/transport/fec0:0:0:2::1-fec0:0:0:1::1/require ;
add fec0:0:0:1::1 fec0:0:0:2::1 esp 0x10001 -m tunnel
-E 3des-cbc "kamekame12341234kame1234"
-A hmac-sha1 "this is the test key" ;
add fec0:0:0:1::1 fec0:0:0:2::1 ah 0x10001 -m transport
-A hmac-md5 "this is the test" ;
add fec0:0:0:2::1 fec0:0:0:1::1 esp 0x10001 -m tunnel
-E 3des-cbc "kamekame12341234kame1234"
-A hmac-sha1 "this is the test key" ;
add fec0:0:0:2::1 fec0:0:0:1::1 ah 0x10001 -m transport
-A hmac-md5 "this is the test" ;
EOF
Making SAs with the different endESP tunnel mode is required between Host-A and Gateway-A. Encryption
algorithm is cast128-cbc, and authentication algorithm for ESP is
hmac-sha1. ESP transport mode is recommended between Host-A and Host-B.
Encryption algorithm is rc5-cbc, and authentication algorithm for ESP is
hmac-md5.
================== ESP =================
| ======= ESP ======= |
| | | |
Host-A Gateway-A Host-B
fec0:0:0:1::1 ---- fec0:0:0:2::1 ---- fec0:0:0:2::2
Configuration at Host-A:
&prompt.root; setkey -c <<EOF
spdadd fec0:0:0:1::1[any] fec0:0:0:2::2[80] tcp -P out ipsec
esp/transport/fec0:0:0:1::1-fec0:0:0:2::2/use
esp/tunnel/fec0:0:0:1::1-fec0:0:0:2::1/require ;
spdadd fec0:0:0:2::1[80] fec0:0:0:1::1[any] tcp -P in ipsec
esp/transport/fec0:0:0:2::2-fec0:0:0:l::1/use
esp/tunnel/fec0:0:0:2::1-fec0:0:0:1::1/require ;
add fec0:0:0:1::1 fec0:0:0:2::2 esp 0x10001
-m transport
-E cast128-cbc "12341234"
-A hmac-sha1 "this is the test key" ;
add fec0:0:0:1::1 fec0:0:0:2::1 esp 0x10002
-E rc5-cbc "kamekame"
-A hmac-md5 "this is the test" ;
add fec0:0:0:2::2 fec0:0:0:1::1 esp 0x10003
-m transport
-E cast128-cbc "12341234"
-A hmac-sha1 "this is the test key" ;
add fec0:0:0:2::1 fec0:0:0:1::1 esp 0x10004
-E rc5-cbc "kamekame"
-A hmac-md5 "this is the test" ;
EOF
ChernLeeContributed by OpenSSHOpenSSHsecurityOpenSSHSecure shell is a set of network connectivity tools used to
access remote machines securely. It can be used as a direct
replacement for rlogin,
rsh, rcp, and
telnet. Additionally, any other TCP/IP
connections can be tunneled/forwarded securely through ssh.
ssh encrypts all traffic to effectively eliminate eavesdropping,
connection hijacking, and other network-level attacks.OpenSSH is maintained by the OpenBSD project, and is based
upon SSH v1.2.12 with all the recent bug fixes and updates. It
is compatible with both SSH protocols 1 and 2. OpenSSH has been
in the base system since FreeBSD 4.0.Advantages of Using OpenSSHNormally, when using &man.telnet.1; or &man.rlogin.1;,
data is sent over the network in an clear, un-encrypted form.
Network sniffers anywhere in between the client and server can
steal your user/password information or data transferred in
your session. OpenSSH offers a variety of authentication and
encryption methods to prevent this from happening.Enabling sshdOpenSSHenablingBe sure to make the following additions to your
rc.conf file:sshd_enable="YES"This will load the ssh daemon
the next time your system initializes. Alternatively, you can
simply run the sshd daemon.SSH ClientOpenSSHclientThe &man.ssh.1; utility works similarly to
&man.rlogin.1;.&prompt.root; ssh user@example.com
Host key not found from the list of known hosts.
Are you sure you want to continue connecting (yes/no)? yes
Host 'example.com' added to the list of known hosts.
user@example.com's password: *******The login will continue just as it would have if a session was
created using rlogin or
telnet. SSH utilizes a key fingerprint
system for verifying the authenticity of the server when the
client connects. The user is prompted to enter
yes only when
connecting for the first time. Future attempts to login are all
verified against the saved fingerprint key. The SSH client
will alert you if the saved fingerprint differs from the
received fingerprint on future login attempts. The fingerprints
are saved in ~/.ssh/known_hosts, or
~/.ssh/known_hosts2 for SSH v2
fingerprints.By default, OpenSSH servers are configured to accept both
SSH v1 and SSH v2 connections. The client, however, can choose
between the two. Version 2 is known to be more robust and
secure than its predecessor.ssh can be forced to use either protocol
by passing it the or argument
for v1 and v2, respectively.Secure CopyOpenSSHsecure copyscpThe scp command works similarly to
rcp; it copies a file to or from a remote machine,
except in a secure fashion.&prompt.root; scp user@example.com:/COPYRIGHT COPYRIGHT
user@example.com's password:
COPYRIGHT 100% |*****************************| 4735
00:00
&prompt.root;Since the fingerprint was already saved for this host in the
previous example, it is verified when using scp
here.The arguments passed to scp are similar
to cp, with the file or files in the first
argument, and the destination in the second. Since the file is
fetched over the network, through SSH, one or more of the file
arguments takes on the form
.ConfigurationOpenSSHconfigurationThe system-wide configuration files for both the OpenSSH
daemon and client reside within the /etc/ssh
directory.ssh_config configures the client
settings, while sshd_config configures the
daemon.Additionally, the
(/usr/sbin/sshd by default), and
rc.conf
options can provide more levels of configuration.ssh-keygenInstead of using passwords, &man.ssh-keygen.1; can
be used to generate RSA keys to authenticate a user.&prompt.user; ssh-keygen
Initializing random number generator...
Generating p: .++ (distance 66)
Generating q: ..............................++ (distance 498)
Computing the keys...
Key generation complete.
Enter file in which to save the key (/home/user/.ssh/identity):
Enter passphrase:
Enter the same passphrase again:
Your identification has been saved in /home/user/.ssh/identity.
...&man.ssh-keygen.1; will create a public and private
key pair for use in authentication. The private key is stored in
~/.ssh/identity, whereas the public key is
stored in ~/.ssh/identity.pub. The public
key must be placed in ~/.ssh/authorized_keys
of the remote machine in order for the setup to work.This will allow connection to the remote machine based upon
RSA authentication instead of passwords.If a passphrase is used in &man.ssh-keygen.1;, the user
will be prompted for a password each time in order to use the private
key.A SSH v2 DSA key can be created for the same purpose by using
the ssh-keygen -d command (or
ssh-keygen -t dsa for FreeBSD &os.current;).
This will
create a public/private DSA key for use in SSH v2 sessions only.
The public key is stored in ~/.ssh/id_dsa.pub,
while the private key is in ~/.ssh/id_dsa.DSA public keys are placed in
~/.ssh/authorized_keys2 on the remote
machine.&man.ssh-agent.1; and &man.ssh-add.1; are
utilities used in managing multiple passworded private keys.SSH TunnelingOpenSSHtunnelingOpenSSH has the ability to create a tunnel to encapsulate
another protocol in an encrypted session.The following command tells &man.ssh.1; to create a tunnel
for telnet.&prompt.user; ssh -2 -N -f -L 5023:localhost:23 user@foo.example.com
&prompt.user;The ssh command is used with the
following options:Forces ssh to use version 2 of
the protocol. (Do not use if you are working with older
ssh servers)Indicates no command, or tunnel only. If omitted,
ssh would initiate a normal
session.Forces ssh to run in the
background.Indicates a local tunnel in
localport:remotehost:remoteport
fashion.The remote SSH server.An SSH tunnel works by creating a listen socket on
localhost on the specified port.
It then forwards any connection received
on the local host/port via the SSH connection to the specified
remote host and port.In the example, port 5023 on
localhost is being forwarded to port
23 on localhost
of the remote machine. Since 23 is telnet,
this would create a secure telnet session through an SSH tunnel.This can be used to wrap any number of insecure TCP protocols
such as SMTP, POP3, FTP, etc.Using SSH to create a secure tunnel for SMTP&prompt.user; ssh -2 -N -f -L 5025:localhost:25 user@mailserver.example.com
user@mailserver.example.com's password: *****
&prompt.user; telnet localhost 5025
Trying 127.0.0.1...
Connected to localhost.
Escape character is '^]'.
220 mailserver.example.com ESMTPThis can be used in conjunction with an
&man.ssh-keygen.1; and additional user accounts to create a
more seamless/hassle-free SSH tunneling environment. Keys
can be used in place of typing a password, and the tunnels
can be run as a separate user.Practical SSH Tunneling ExamplesSecure Access of a POP3 serverAt work, there is an SSH server that accepts
connections from the outside. On the same office network
resides a mail server running a POP3 server. The network,
or network path between your home and office may or may not
be completely trustable. Because of this, you need to check
your e-mail in a secure manner. The solution is to create
an SSH connection to your office's SSH server, and tunnel
through to the mail server.&prompt.user; ssh -2 -N -f -L 2110:mail.example.com:110 user@ssh-server.example.com
user@ssh-server.example.com's password: ******When the tunnel is up and running, you can point your
mail client to send POP3 requests to localhost
port 2110. A connection here will be forwarded securely across
the tunnel to mail.example.com.Bypassing a Draconian FirewallSome network administrators impose extremely Draconian
firewall rules, filtering not only incoming connections,
but outgoing connections. You may be only given access
to contact remote machines on ports 22 and 80 for SSH
and web surfing.You may wish to access another (perhaps non-work
related) service, such as an Ogg Vorbis server to stream
music. If this Ogg Vorbis server is streaming on some other
port than 22 or 80, you will not be able to access it.The solution is to create an SSH connection to a machine
outside of your network's firewall, and use it to tunnel to
the Ogg Vorbis server.&prompt.user; ssh -2 -N -f -L 8888:music.example.com:8000 user@unfirewalled.myserver.com
user@unfirewalled.myserver.com's password: *******Your streaming client can now be pointed to
localhost port 8888, which will be
forwarded over to music.example.com port
8000, successfully evading the firewall.Further ReadingOpenSSH&man.ssh.1; &man.scp.1; &man.ssh-keygen.1;
&man.ssh-agent.1; &man.ssh-add.1;&man.sshd.8; &man.sftp-server.8;