PFSYNC(4)						   BSD Kernel Interfaces Manual 						 PFSYNC(4)

NAME

     pfsync -- packet filter state table logging interface

SYNOPSIS

     pseudo-device pfsync

DESCRIPTION

     The pfsync interface is a pseudo-device which exposes certain changes to the state table used by pf(4).  State changes can be viewed by
     invoking tcpdump(8) on the pfsync interface.  If configured with a physical synchronisation interface, pfsync will also send state changes
     out on that interface using IP multicast, and insert state changes received on that interface from other systems into the state table.

     By default, all local changes to the state table are exposed via pfsync.  However, state changes from packets received by pfsync over the
     network are not rebroadcast.  States created by a rule marked with the no-sync keyword are omitted from the pfsync interface (see pf.conf(5)
     for details).

     The pfsync interface will attempt to collapse multiple updates of the same state into one message where possible.	The maximum number of
     times this can be done before the update is sent out is controlled by the maxupd parameter to ifconfig (see ifconfig(8) and the example below
     for more details).

     Each packet retrieved on this interface has a header associated with it of length PFSYNC_HDRLEN.  The header indicates the version of the
     protocol, address family, action taken on the following states, and the number of state table entries attached in this packet.  This struc-
     ture is defined in <net/if_pfsync.h> as:

	   struct pfsync_header {
		   u_int8_t version;
		   u_int8_t af;
		   u_int8_t action;
		   u_int8_t count;
	   };

NETWORK SYNCHRONISATION

     States can be synchronised between two or more firewalls using this interface, by specifying a synchronisation interface using ifconfig(8).
     For example, the following command sets fxp0 as the synchronisation interface:

	   # ifconfig pfsync0 syncdev fxp0

     By default, state change messages are sent out on the synchronisation interface using IP multicast packets.  The protocol is IP protocol 240,
     PFSYNC, and the multicast group used is 224.0.0.240.  When a peer address is specified using the syncpeer keyword, the peer address is used
     as a destination for the pfsync traffic.

     It is important that the pfsync traffic be well secured as there is no authentication on the protocol and it would be trivial to spoof pack-
     ets which create states, bypassing the pf ruleset.  Either run the pfsync protocol on a trusted network - ideally	a network dedicated to
     pfsync messages such as a crossover cable between two firewalls, or specify a peer address and protect the traffic with ipsec(4) (it is not
     supported at the moment on NetBSD due to the lack of any encapsulation pseudo-device).

     There is a one-to-one correspondence between packets seen by bpf(4) on the pfsync interface, and packets sent out on the synchronisation
     interface, i.e. a packet with 4 state deletion messages on pfsync means that the same 4 deletions were sent out on the synchronisation inter-
     face.  However, the actual packet contents may differ as the messages sent over the network are "compressed" where possible, containing only
     the necessary information.

EXAMPLES

     pfsync and carp(4) can be used together to provide automatic failover of a pair of firewalls configured in parallel.  One firewall handles
     all traffic - if it dies or is shut down, the second firewall takes over automatically.

     Both firewalls in this example have three sis(4) interfaces.  sis0 is the external interface, on the 10.0.0.0/24 subnet; sis1 is the internal
     interface, on the 192.168.0.0/24 subnet; and sis2 is the pfsync interface, using the 192.168.254.0/24 subnet.  A crossover cable connects the
     two firewalls via their sis2 interfaces.  On all three interfaces, firewall A uses the .254 address, while firewall B uses .253.  The inter-
     faces are configured as follows (firewall A unless otherwise indicated):

     /etc/ifconfig.sis0:

	   inet 10.0.0.254 255.255.255.0 NONE

     /etc/ifconfig.sis1:

	   inet 192.168.0.254 255.255.255.0 NONE

     /etc/ifconfig.sis2:

	   inet 192.168.254.254 255.255.255.0 NONE

     /etc/ifconfig.carp0:

	   inet 10.0.0.1 255.255.255.0 10.0.0.255 vhid 1 pass foo

     /etc/ifconfig.carp1:

	   inet 192.168.0.1 255.255.255.0 192.168.0.255 vhid 2 pass bar

     /etc/ifconfig.pfsync0:

	   up syncdev sis2

     pf(4) must also be configured to allow pfsync and carp(4) traffic through.  The following should be added to the top of /etc/pf.conf:

	   pass quick on { sis2 } proto pfsync
	   pass on { sis0 sis1 } proto carp

     If it is preferable that one firewall handle the traffic, the advskew on the backup firewall's carp(4) interfaces should be set to something
     higher than the primary's.  For example, if firewall B is the backup, its /etc/ifconfig.carp1 would look like this:

	   inet 192.168.0.1 255.255.255.0 192.168.0.255 vhid 2 pass bar 
		   advskew 100

     The following must also be added to /etc/sysctl.conf:

	   net.inet.carp.preempt=1

SEE ALSO

     bpf(4), carp(4), inet(4), inet6(4), ipsec(4), netintro(4), pf(4), ifconfig.if(5), pf.conf(5), protocols(5), ifconfig(8), tcpdump(8)

HISTORY

     The pfsync device first appeared in OpenBSD 3.3.

CAVEATS

     pfsync is not available when using pf(4) as a kernel module.

BSD
								  April 12, 2010							       BSD