418 lines
15 KiB
Groff
418 lines
15 KiB
Groff
.\" Copyright (c) 2001, Matthew Dillon. Terms and conditions are those of
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.\" the BSD Copyright as specified in the file "/usr/src/COPYRIGHT" in
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.\" the source tree.
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.\"
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.\" $FreeBSD$
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.\"
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.Dd May 26, 2001
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.Dt FIREWALL 7
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.Os
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.Sh NAME
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.Nm firewall
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.Nd simple firewalls under FreeBSD
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.Sh FIREWALL BASICS
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A Firewall is most commonly used to protect an internal network
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from an outside network by preventing the outside network from
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making arbitrary connections into the internal network.
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Firewalls
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are also used to prevent outside entities from spoofing internal
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IP addresses and to isolate services such as NFS or SMBFS (Windows
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file sharing) within LAN segments.
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.Pp
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The
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.Fx
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firewalling system also has the capability to limit bandwidth using
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.Xr dummynet 4 .
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This feature can be useful when you need to guarantee a certain
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amount of bandwidth for a critical purpose.
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For example, if you
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are doing video conferencing over the Internet via your
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office T1 (1.5 MBits/s), you may wish to bandwidth-limit all other
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T1 traffic to 1 MBit/s in order to reserve at least 0.5 MBits
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for your video conferencing connections.
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Similarly if you are
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running a popular web or ftp site from a colocation facility
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you might want to limit bandwidth to prevent excessive bandwidth
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charges from your provider.
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.Pp
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Finally,
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.Fx
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firewalls may be used to divert packets or change the next-hop
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address for packets to help route them to the correct destination.
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Packet diversion is most often used to support NAT (network
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address translation), which allows an internal network using
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a private IP space to make connections to the outside for browsing
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or other purposes.
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.Pp
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Constructing a firewall may appear to be trivial, but most people
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get them wrong.
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The most common mistake is to create an exclusive
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firewall rather than an inclusive firewall.
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An exclusive firewall
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allows all packets through except for those matching a set of rules.
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An inclusive firewall allows only packets matching the ruleset
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through.
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Inclusive firewalls are much, much safer than exclusive
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firewalls but a tad more difficult to build properly.
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The
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second most common mistake is to blackhole everything except the
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particular port you want to let through.
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TCP/IP needs to be able
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to get certain types of ICMP errors to function properly - for
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example, to implement MTU discovery.
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Also, a number of common
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system daemons make reverse connections to the
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.Sy auth
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service in an attempt to authenticate the user making a connection.
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Auth is rather dangerous but the proper implementation is to return
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a TCP reset for the connection attempt rather than simply blackholing
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the packet.
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We cover these and other quirks involved with constructing
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a firewall in the sample firewall section below.
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.Sh IPFW KERNEL CONFIGURATION
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You do not need to create a custom kernel to use the IP firewalling features.
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If you enable firewalling in your
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.Em /etc/rc.conf
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(see below), the ipfw kernel module will be loaded automatically
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when necessary.
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However,
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if you are paranoid you can compile IPFW directly into the
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.Fx
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kernel by using the
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.Sy IPFIREWALL
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option set.
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If compiled in the kernel, ipfw denies all
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packets by default, which means that, if you do not load in
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a permissive ruleset via
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.Em /etc/rc.conf ,
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rebooting into your new kernel will take the network offline.
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This can prevent you from being able to access your system if you
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are not sitting at the console.
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It is also quite common to
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update a kernel to a new release and reboot before updating
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the binaries.
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This can result in an incompatibility between
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the
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.Xr ipfw 8
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program and the kernel which prevents it from running in the
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boot sequence, also resulting in an inaccessible machine.
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Because of these problems the
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.Sy IPFIREWALL_DEFAULT_TO_ACCEPT
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kernel option is also available which changes the default firewall
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to pass through all packets.
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Note, however, that using this option
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may open a small window of opportunity during booting where your
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firewall passes all packets.
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Still, it's a good option to use
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while getting up to speed with
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.Fx
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firewalling.
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Get rid of it once you understand how it all works
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to close the loophole, though.
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There is a third option called
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.Sy IPDIVERT
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which allows you to use the firewall to divert packets to a user program
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and is necessary if you wish to use
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.Xr natd 8
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to give private internal networks access to the outside world.
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If you want to be able to limit the bandwidth used by certain types of
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traffic, the
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.Sy DUMMYNET
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option must be used to enable
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.Em ipfw pipe
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rules.
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.Sh SAMPLE IPFW-BASED FIREWALL
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Here is an example ipfw-based firewall taken from a machine with three
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interface cards.
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fxp0 is connected to the 'exposed' LAN.
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Machines
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on this LAN are dual-homed with both internal 10.\& IP addresses and
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Internet-routed IP addresses.
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In our example, 192.100.5.x represents
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the Internet-routed IP block while 10.x.x.x represents the internal
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networks.
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While it isn't relevant to the example, 10.0.1.x is
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assigned as the internal address block for the LAN on fxp0, 10.0.2.x
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for the LAN on fxp1, and 10.0.3.x for the LAN on fxp2.
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.Pp
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In this example we want to isolate all three LANs from the Internet
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as well as isolate them from each other, and we want to give all
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internal addresses access to the Internet through a NAT gateway running
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on this machine.
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To make the NAT gateway work, the firewall machine
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is given two Internet-exposed addresses on fxp0 in addition to an
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internal 10.\& address on fxp0: one exposed address (not shown)
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represents the machine's official address, and the second exposed
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address (192.100.5.5 in our example) represents the NAT gateway
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rendezvous IP.
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We make the example more complex by giving the machines
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on the exposed LAN internal 10.0.0.x addresses as well as exposed
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addresses.
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The idea here is that you can bind internal services
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to internal addresses even on exposed machines and still protect
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those services from the Internet.
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The only services you run on
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exposed IP addresses would be the ones you wish to expose to the
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Internet.
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.Pp
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It is important to note that the 10.0.0.x network in our example
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is not protected by our firewall.
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You must make sure that your
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Internet router protects this network from outside spoofing.
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Also, in our example, we pretty much give the exposed hosts free
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reign on our internal network when operating services through
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internal IP addresses (10.0.0.x).
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This is somewhat of security
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risk: what if an exposed host is compromised?
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To remove the
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risk and force everything coming in via LAN0 to go through
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the firewall, remove rules 01010 and 01011.
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.Pp
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Finally, note that the use of internal addresses represents a
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big piece of our firewall protection mechanism.
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With proper
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spoofing safeguards in place, nothing outside can directly
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access an internal (LAN1 or LAN2) host.
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.Bd -literal
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# /etc/rc.conf
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#
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firewall_enable="YES"
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firewall_type="/etc/ipfw.conf"
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# temporary port binding range let
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# through the firewall.
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#
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# NOTE: heavily loaded services running through the firewall may require
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# a larger port range for local-size binding. 4000-10000 or 4000-30000
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# might be a better choice.
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ip_portrange_first=4000
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ip_portrange_last=5000
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\&...
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.Ed
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.Pp
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.Bd -literal
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# /etc/ipfw.conf
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#
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# FIREWALL: the firewall machine / nat gateway
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# LAN0 10.0.0.X and 192.100.5.X (dual homed)
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# LAN1 10.0.1.X
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# LAN2 10.0.2.X
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# sw: ethernet switch (unmanaged)
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#
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# 192.100.5.x represents IP addresses exposed to the Internet
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# (i.e. Internet routeable). 10.x.x.x represent internal IPs
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# (not exposed)
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#
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# [LAN1]
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# ^
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# |
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# FIREWALL -->[LAN2]
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# |
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# [LAN0]
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# |
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# +--> exposed host A
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# +--> exposed host B
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# +--> exposed host C
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# |
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# INTERNET (secondary firewall)
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# ROUTER
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# |
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# [Internet]
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#
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# NOT SHOWN: The INTERNET ROUTER must contain rules to disallow
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# all packets with source IP addresses in the 10. block in order
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# to protect the dual-homed 10.0.0.x block. Exposed hosts are
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# not otherwise protected in this example - they should only bind
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# exposed services to exposed IPs but can safely bind internal
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# services to internal IPs.
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#
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# The NAT gateway works by taking packets sent from internal
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# IP addresses to external IP addresses and routing them to natd, which
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# is listening on port 8668. This is handled by rule 00300. Data coming
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# back to natd from the outside world must also be routed to natd using
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# rule 00301. To make the example interesting, we note that we do
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# NOT have to run internal requests to exposed hosts through natd
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# (rule 00290) because those exposed hosts know about our
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# 10. network. This can reduce the load on natd. Also note that we
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# of course do not have to route internal<->internal traffic through
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# natd since those hosts know how to route our 10. internal network.
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# The natd command we run from /etc/rc.local is shown below. See
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# also the in-kernel version of natd, ipnat.
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#
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# natd -s -u -a 208.161.114.67
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#
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#
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add 00290 skipto 1000 ip from 10.0.0.0/8 to 192.100.5.0/24
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add 00300 divert 8668 ip from 10.0.0.0/8 to not 10.0.0.0/8
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add 00301 divert 8668 ip from not 10.0.0.0/8 to 192.100.5.5
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# Short cut the rules to avoid running high bandwidths through
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# the entire rule set. Allow established tcp connections through,
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# and shortcut all outgoing packets under the assumption that
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# we need only firewall incoming packets.
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#
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# Allowing established tcp connections through creates a small
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# hole but may be necessary to avoid overloading your firewall.
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# If you are worried, you can move the rule to after the spoof
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# checks.
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#
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add 01000 allow tcp from any to any established
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add 01001 allow all from any to any out via fxp0
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add 01001 allow all from any to any out via fxp1
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add 01001 allow all from any to any out via fxp2
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# Spoof protection. This depends on how well you trust your
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# internal networks. Packets received via fxp1 MUST come from
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# 10.0.1.x. Packets received via fxp2 MUST come from 10.0.2.x.
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# Packets received via fxp0 cannot come from the LAN1 or LAN2
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# blocks. We can't protect 10.0.0.x here, the Internet router
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# must do that for us.
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#
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add 01500 deny all from not 10.0.1.0/24 in via fxp1
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add 01500 deny all from not 10.0.2.0/24 in via fxp2
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add 01501 deny all from 10.0.1.0/24 in via fxp0
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add 01501 deny all from 10.0.2.0/24 in via fxp0
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# In this example rule set there are no restrictions between
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# internal hosts, even those on the exposed LAN (as long as
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# they use an internal IP address). This represents a
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# potential security hole (what if an exposed host is
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# compromised?). If you want full restrictions to apply
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# between the three LANs, firewalling them off from each
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# other for added security, remove these two rules.
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#
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# If you want to isolate LAN1 and LAN2, but still want
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# to give exposed hosts free reign with each other, get
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# rid of rule 01010 and keep rule 01011.
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#
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# (commented out, uncomment for less restrictive firewall)
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#add 01010 allow all from 10.0.0.0/8 to 10.0.0.0/8
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#add 01011 allow all from 192.100.5.0/24 to 192.100.5.0/24
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#
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# SPECIFIC SERVICES ALLOWED FROM SPECIFIC LANS
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#
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# If using a more restrictive firewall, allow specific LANs
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# access to specific services running on the firewall itself.
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# In this case we assume LAN1 needs access to filesharing running
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# on the firewall. If using a less restrictive firewall
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# (allowing rule 01010), you don't need these rules.
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#
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add 01012 allow tcp from 10.0.1.0/8 to 10.0.1.1 139
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add 01012 allow udp from 10.0.1.0/8 to 10.0.1.1 137,138
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# GENERAL SERVICES ALLOWED TO CROSS INTERNAL AND EXPOSED LANS
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#
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# We allow specific UDP services through: DNS lookups, ntalk, and ntp.
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# Note that internal services are protected by virtue of having
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# spoof-proof internal IP addresses (10. net), so these rules
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# really only apply to services bound to exposed IPs. We have
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# to allow UDP fragments or larger fragmented UDP packets will
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# not survive the firewall.
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#
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# If we want to expose high-numbered temporary service ports
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# for things like DNS lookup responses we can use a port range,
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# in this example 4000-65535, and we set to /etc/rc.conf variables
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# on all exposed machines to make sure they bind temporary ports
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# to the exposed port range (see rc.conf example above)
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#
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add 02000 allow udp from any to any 4000-65535,domain,ntalk,ntp
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add 02500 allow udp from any to any frag
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# Allow similar services for TCP. Again, these only apply to
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# services bound to exposed addresses. NOTE: we allow 'auth'
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# through but do not actually run an identd server on any exposed
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# port. This allows the machine being authed to respond with a
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# TCP RESET. Throwing the packet away would result in delays
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# when connecting to remote services that do reverse ident lookups.
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#
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# Note that we do not allow tcp fragments through, and that we do
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# not allow fragments in general (except for UDP fragments). We
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# expect the TCP mtu discovery protocol to work properly so there
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# should be no TCP fragments.
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#
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add 03000 allow tcp from any to any http,https
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add 03000 allow tcp from any to any 4000-65535,ssh,smtp,domain,ntalk
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add 03000 allow tcp from any to any auth,pop3,ftp,ftp-data
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# It is important to allow certain ICMP types through, here is a list
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# of general ICMP types. Note that it is important to let ICMP type 3
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# through.
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#
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# 0 Echo Reply
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# 3 Destination Unreachable (used by TCP MTU discovery, aka
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# packet-too-big)
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# 4 Source Quench (typically not allowed)
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# 5 Redirect (typically not allowed - can be dangerous!)
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# 8 Echo
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# 11 Time Exceeded
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# 12 Parameter Problem
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# 13 Timestamp
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# 14 Timestamp Reply
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#
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# Sometimes people need to allow ICMP REDIRECT packets, which is
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# type 5, but if you allow it make sure that your Internet router
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# disallows it.
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add 04000 allow icmp from any to any icmptypes 0,3,8,11,12,13,14
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# log any remaining fragments that get through. Might be useful,
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# otherwise don't bother. Have a final deny rule as a safety to
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# guarantee that your firewall is inclusive no matter how the kernel
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# is configured.
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#
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add 05000 deny log ip from any to any frag
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add 06000 deny all from any to any
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.Ed
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.Sh PORT BINDING INTERNAL AND EXTERNAL SERVICES
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We've mentioned multi-homing hosts and binding services to internal or
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external addresses but we haven't really explained it.
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When you have a
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host with multiple IP addresses assigned to it, you can bind services run
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on that host to specific IPs or interfaces rather than all IPs.
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Take
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the firewall machine for example: with three interfaces
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and two exposed IP addresses
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on one of those interfaces, the firewall machine is known by 5 different
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IP addresses (10.0.0.1, 10.0.1.1, 10.0.2.1, 192.100.5.5, and say
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192.100.5.1).
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If the firewall is providing file sharing services to the
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windows LAN segment (say it is LAN1), you can use samba's 'bind interfaces'
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directive to specifically bind it to just the LAN1 IP address.
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That
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way the file sharing services will not be made available to other LAN
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segments.
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The same goes for NFS.
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If LAN2 has your UNIX engineering
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workstations, you can tell nfsd to bind specifically to 10.0.2.1.
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You
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can specify how to bind virtually every service on the machine and you
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can use a light
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.Xr jail 8
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to indirectly bind services that do not otherwise give you the option.
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.Sh SEE ALSO
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.Xr ipnat 1 ,
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.Xr dummynet 4 ,
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.Xr ipnat 5 ,
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.Xr rc.conf 5 ,
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.Xr smb.conf 5 Pq Pa ports/net/samba ,
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.Xr samba 7 Pq Pa ports/net/samba ,
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.Xr config 8 ,
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.Xr ipfw 8 ,
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.Xr jail 8 ,
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.Xr natd 8 ,
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.Xr nfsd 8
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.Sh ADDITIONAL READING
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.Xr ipf 5 ,
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.Xr ipf 8 ,
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.Xr ipfstat 8
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.Sh HISTORY
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The
|
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.Nm
|
|
manual page was originally written by
|
|
.An Matthew Dillon
|
|
and first appeared
|
|
in
|
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.Fx 4.3 ,
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May 2001.
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