doc/main.texi - quagga - Gitiles

 @node Zebra
 @chapter Zebra

 @c SYNOPSIS
 @command{zebra} is an IP routing manager.  It provides kernel routing
 table updates, interface lookups, and redistribution of routes between
 different routing protocols.

 @menu
 * Invoking zebra::              Running the program
 * Interface Commands::          Commands for zebra interfaces
 * Static Route Commands::       Commands for adding static routes
 * zebra Route Filtering::       Commands for zebra route filtering
 * zebra FIB push interface::    Interface to optional FPM component
 * zebra Terminal Mode Commands::  Commands for zebra's VTY
 @end menu


 @node Invoking zebra
 @section Invoking zebra

 Besides the common invocation options (@pxref{Common Invocation Options}), the
 @command{zebra} specific invocation options are listed below.

 @table @samp
 @item -b
 @itemx --batch
 Runs in batch mode.  @command{zebra} parses configuration file and terminates
 immediately.

 @item -k
 @itemx --keep_kernel
 When zebra starts up, don't delete old self inserted routes.

 @item -r
 @itemx --retain
 When program terminates, retain routes added by zebra.

 @end table

 @node Interface Commands
 @section Interface Commands

 @deffn Command {interface @var{ifname}} {}
 @end deffn

 @deffn {Interface Command} {shutdown} {}
 @deffnx {Interface Command} {no shutdown} {}
 Up or down the current interface.
 @end deffn

 @deffn {Interface Command} {ip address @var{address/prefix}} {}
 @deffnx {Interface Command} {ipv6 address @var{address/prefix}} {}
 @deffnx {Interface Command} {no ip address @var{address/prefix}} {}
 @deffnx {Interface Command} {no ipv6 address @var{address/prefix}} {}
 Set the IPv4 or IPv6 address/prefix for the interface.
 @end deffn

 @deffn {Interface Command} {ip address @var{address/prefix} secondary} {}
 @deffnx {Interface Command} {no ip address @var{address/prefix} secondary} {}
 Set the secondary flag for this address. This causes ospfd to not treat the
 address as a distinct subnet.
 @end deffn

 @deffn {Interface Command} {description @var{description} ...} {}
 Set description for the interface.
 @end deffn

 @deffn {Interface Command} {multicast} {}
 @deffnx {Interface Command} {no multicast} {}
 Enable or disables multicast flag for the interface.
 @end deffn

 @deffn {Interface Command} {bandwidth <1-10000000>} {}
 @deffnx {Interface Command} {no bandwidth <1-10000000>} {}
 Set bandwidth value of the interface in kilobits/sec.  This is for
 calculating OSPF cost. This command does not affect the actual device
 configuration.
 @end deffn

 @deffn {Interface Command} {link-detect} {}
 @deffnx {Interface Command} {no link-detect} {}
 Enable/disable link-detect on platforms which support this. Currently
 only Linux and Solaris, and only where network interface drivers support reporting
 link-state via the IFF_RUNNING flag.
 @end deffn

 @node Static Route Commands
 @section Static Route Commands

 Static routing is a very fundamental feature of routing technology.  It
 defines static prefix and gateway.

 @deffn Command {ip route @var{network} @var{gateway}} {}
 @var{network} is destination prefix with format of A.B.C.D/M.
 @var{gateway} is gateway for the prefix.  When @var{gateway} is
 A.B.C.D format.  It is taken as a IPv4 address gateway.  Otherwise it
 is treated as an interface name. If the interface name is @var{null0} then
 zebra installs a blackhole route.

 @example
 ip route 10.0.0.0/8 10.0.0.2
 ip route 10.0.0.0/8 ppp0
 ip route 10.0.0.0/8 null0
 @end example

 First example defines 10.0.0.0/8 static route with gateway 10.0.0.2.
 Second one defines the same prefix but with gateway to interface ppp0. The
 third install a blackhole route.
 @end deffn

 @deffn Command {ip route @var{network} @var{netmask} @var{gateway}} {}
 This is alternate version of above command.  When @var{network} is
 A.B.C.D format, user must define @var{netmask} value with A.B.C.D
 format.  @var{gateway} is same option as above command

 @example
 ip route 10.0.0.0 255.255.255.0 10.0.0.2
 ip route 10.0.0.0 255.255.255.0 ppp0
 ip route 10.0.0.0 255.255.255.0 null0
 @end example

 These statements are equivalent to those in the previous example.
 @end deffn

 @deffn Command {ip route @var{network} @var{gateway} @var{distance}} {}
 Installs the route with the specified distance.
 @end deffn

 Multiple nexthop static route

 @example
 ip route 10.0.0.1/32 10.0.0.2
 ip route 10.0.0.1/32 10.0.0.3
 ip route 10.0.0.1/32 eth0
 @end example

 If there is no route to 10.0.0.2 and 10.0.0.3, and interface eth0
 is reachable, then the last route is installed into the kernel.

 If zebra has been compiled with multipath support, and both 10.0.0.2 and
 10.0.0.3 are reachable, zebra will install a multipath route via both
 nexthops, if the platform supports this.

 @example
 zebra> show ip route
 S>  10.0.0.1/32 [1/0] via 10.0.0.2 inactive
                       via 10.0.0.3 inactive
   *                   is directly connected, eth0
 @end example

 @example
 ip route 10.0.0.0/8 10.0.0.2
 ip route 10.0.0.0/8 10.0.0.3
 ip route 10.0.0.0/8 null0 255
 @end example

 This will install a multihop route via the specified next-hops if they are
 reachable, as well as a high-metric blackhole route, which can be useful to
 prevent traffic destined for a prefix to match less-specific routes (eg
 default) should the specified gateways not be reachable. Eg:

 @example
 zebra> show ip route 10.0.0.0/8
 Routing entry for 10.0.0.0/8
   Known via "static", distance 1, metric 0
     10.0.0.2 inactive
     10.0.0.3 inactive

 Routing entry for 10.0.0.0/8
   Known via "static", distance 255, metric 0
     directly connected, Null0
 @end example

 @deffn Command {ipv6 route @var{network} @var{gateway}} {}
 @deffnx Command {ipv6 route @var{network} @var{gateway} @var{distance}} {}
 These behave similarly to their ipv4 counterparts.
 @end deffn


 @deffn Command {table @var{tableno}} {}
 Select the primary kernel routing table to be used.  This only works
 for kernels supporting multiple routing tables (like GNU/Linux 2.2.x
 and later).  After setting @var{tableno} with this command,
 static routes defined after this are added to the specified table.
 @end deffn

 @node zebra Route Filtering
 @section zebra Route Filtering
 Zebra supports @command{prefix-list} and @command{route-map} to match
 routes received from other quagga components.  The
 @command{permit}/@command{deny} facilities provided by these commands
 can be used to filter which routes zebra will install in the kernel.

 @deffn Command {ip protocol @var{protocol} route-map @var{routemap}} {}
 Apply a route-map filter to routes for the specified protocol. @var{protocol}
 can be @b{any} or one of
 @b{system},
 @b{kernel},
 @b{connected},
 @b{static},
 @b{rip},
 @b{ripng},
 @b{ospf},
 @b{ospf6},
 @b{isis},
 @b{bgp},
 @b{hsls}.
 @end deffn

 @deffn {Route Map} {set src @var{address}}
 Within a route-map, set the preferred source address for matching routes
 when installing in the kernel.
 @end deffn

 @example
 The following creates a prefix-list that matches all addresses, a route-map
 that sets the preferred source address, and applies the route-map to all
 @command{rip} routes.

 @group
 ip prefix-list ANY permit 0.0.0.0/0 le 32
 route-map RM1 permit 10
      match ip address prefix-list ANY
      set src 10.0.0.1

 ip protocol rip route-map RM1
 @end group
 @end example

 @node zebra FIB push interface
 @section zebra FIB push interface

 Zebra supports a 'FIB push' interface that allows an external
 component to learn the forwarding information computed by the Quagga
 routing suite.

 In Quagga, the Routing Information Base (RIB) resides inside
 zebra. Routing protocols communicate their best routes to zebra, and
 zebra computes the best route across protocols for each prefix. This
 latter information makes up the Forwarding Information Base
 (FIB). Zebra feeds the FIB to the kernel, which allows the IP stack in
 the kernel to forward packets according to the routes computed by
 Quagga. The kernel FIB is updated in an OS-specific way. For example,
 the @code{netlink} interface is used on Linux, and route sockets are
 used on FreeBSD.

 The FIB push interface aims to provide a cross-platform mechanism to
 support scenarios where the router has a forwarding path that is
 distinct from the kernel, commonly a hardware-based fast path. In
 these cases, the FIB needs to be maintained reliably in the fast path
 as well. We refer to the component that programs the forwarding plane
 (directly or indirectly) as the Forwarding Plane Manager or FPM.

 The FIB push interface comprises of a TCP connection between zebra and
 the FPM. The connection is initiated by zebra -- that is, the FPM acts
 as the TCP server.

 The relevant zebra code kicks in when zebra is configured with the
 @code{--enable-fpm} flag. Zebra periodically attempts to connect to
 the well-known FPM port. Once the connection is up, zebra starts
 sending messages containing routes over the socket to the FPM. Zebra
 sends a complete copy of the forwarding table to the FPM, including
 routes that it may have picked up from the kernel. The existing
 interaction of zebra with the kernel remains unchanged -- that is, the
 kernel continues to receive FIB updates as before.

 The format of the messages exchanged with the FPM is defined by the
 file @file{fpm/fpm.h} in the quagga tree.

 The zebra FPM interface uses replace semantics. That is, if a 'route
 add' message for a prefix is followed by another 'route add' message,
 the information in the second message is complete by itself, and
 replaces the information sent in the first message.

 If the connection to the FPM goes down for some reason, zebra sends
 the FPM a complete copy of the forwarding table(s) when it reconnects.

 @node zebra Terminal Mode Commands
 @section zebra Terminal Mode Commands

 @deffn Command {show ip route} {}
 Display current routes which zebra holds in its database.

 @example
 @group
 Router# show ip route
 Codes: K - kernel route, C - connected, S - static, R - RIP,
        B - BGP * - FIB route.

 K* 0.0.0.0/0              203.181.89.241
 S  0.0.0.0/0              203.181.89.1
 C* 127.0.0.0/8            lo
 C* 203.181.89.240/28      eth0
 @end group
 @end example
 @end deffn

 @deffn Command {show ipv6 route} {}
 @end deffn

 @deffn Command {show interface} {}
 @end deffn

 @deffn Command {show ip prefix-list [@var{name}]} {}
 @end deffn

 @deffn Command {show route-map [@var{name}]} {}
 @end deffn

 @deffn Command {show ip protocol} {}
 @end deffn

 @deffn Command {show ipforward} {}
 Display whether the host's IP forwarding function is enabled or not.
 Almost any UNIX kernel can be configured with IP forwarding disabled.
 If so, the box can't work as a router.
 @end deffn

 @deffn Command {show ipv6forward} {}
 Display whether the host's IP v6 forwarding is enabled or not.
 @end deffn

 @deffn Command {show zebra fpm stats} {}
 Display statistics related to the zebra code that interacts with the
 optional Forwarding Plane Manager (FPM) component.
 @end deffn

 @deffn Command {clear zebra fpm stats} {}
 Reset statistics related to the zebra code that interacts with the
 optional Forwarding Plane Manager (FPM) component.
 @end deffn
	@node Zebra
	@chapter Zebra

	@c SYNOPSIS
	@command{zebra} is an IP routing manager. It provides kernel routing
	table updates, interface lookups, and redistribution of routes between
	different routing protocols.

	@menu
	* Invoking zebra:: Running the program
	* Interface Commands:: Commands for zebra interfaces
	* Static Route Commands:: Commands for adding static routes
	* zebra Route Filtering:: Commands for zebra route filtering
	* zebra FIB push interface:: Interface to optional FPM component
	* zebra Terminal Mode Commands:: Commands for zebra's VTY
	@end menu


	@node Invoking zebra
	@section Invoking zebra

	Besides the common invocation options (@pxref{Common Invocation Options}), the
	@command{zebra} specific invocation options are listed below.

	@table @samp
	@item -b
	@itemx --batch
	Runs in batch mode. @command{zebra} parses configuration file and terminates
	immediately.

	@item -k
	@itemx --keep_kernel
	When zebra starts up, don't delete old self inserted routes.

	@item -r
	@itemx --retain
	When program terminates, retain routes added by zebra.

	@end table

	@node Interface Commands
	@section Interface Commands

	@deffn Command {interface @var{ifname}} {}
	@end deffn

	@deffn {Interface Command} {shutdown} {}
	@deffnx {Interface Command} {no shutdown} {}
	Up or down the current interface.
	@end deffn

	@deffn {Interface Command} {ip address @var{address/prefix}} {}
	@deffnx {Interface Command} {ipv6 address @var{address/prefix}} {}
	@deffnx {Interface Command} {no ip address @var{address/prefix}} {}
	@deffnx {Interface Command} {no ipv6 address @var{address/prefix}} {}
	Set the IPv4 or IPv6 address/prefix for the interface.
	@end deffn

	@deffn {Interface Command} {ip address @var{address/prefix} secondary} {}
	@deffnx {Interface Command} {no ip address @var{address/prefix} secondary} {}
	Set the secondary flag for this address. This causes ospfd to not treat the
	address as a distinct subnet.
	@end deffn

	@deffn {Interface Command} {description @var{description} ...} {}
	Set description for the interface.
	@end deffn

	@deffn {Interface Command} {multicast} {}
	@deffnx {Interface Command} {no multicast} {}
	Enable or disables multicast flag for the interface.
	@end deffn

	@deffn {Interface Command} {bandwidth <1-10000000>} {}
	@deffnx {Interface Command} {no bandwidth <1-10000000>} {}
	Set bandwidth value of the interface in kilobits/sec. This is for
	calculating OSPF cost. This command does not affect the actual device
	configuration.
	@end deffn

	@deffn {Interface Command} {link-detect} {}
	@deffnx {Interface Command} {no link-detect} {}
	Enable/disable link-detect on platforms which support this. Currently
	only Linux and Solaris, and only where network interface drivers support reporting
	link-state via the IFF_RUNNING flag.
	@end deffn

	@node Static Route Commands
	@section Static Route Commands

	Static routing is a very fundamental feature of routing technology. It
	defines static prefix and gateway.

	@deffn Command {ip route @var{network} @var{gateway}} {}
	@var{network} is destination prefix with format of A.B.C.D/M.
	@var{gateway} is gateway for the prefix. When @var{gateway} is
	A.B.C.D format. It is taken as a IPv4 address gateway. Otherwise it
	is treated as an interface name. If the interface name is @var{null0} then
	zebra installs a blackhole route.

	@example
	ip route 10.0.0.0/8 10.0.0.2
	ip route 10.0.0.0/8 ppp0
	ip route 10.0.0.0/8 null0
	@end example

	First example defines 10.0.0.0/8 static route with gateway 10.0.0.2.
	Second one defines the same prefix but with gateway to interface ppp0. The
	third install a blackhole route.
	@end deffn

	@deffn Command {ip route @var{network} @var{netmask} @var{gateway}} {}
	This is alternate version of above command. When @var{network} is
	A.B.C.D format, user must define @var{netmask} value with A.B.C.D
	format. @var{gateway} is same option as above command

	@example
	ip route 10.0.0.0 255.255.255.0 10.0.0.2
	ip route 10.0.0.0 255.255.255.0 ppp0
	ip route 10.0.0.0 255.255.255.0 null0
	@end example

	These statements are equivalent to those in the previous example.
	@end deffn

	@deffn Command {ip route @var{network} @var{gateway} @var{distance}} {}
	Installs the route with the specified distance.
	@end deffn

	Multiple nexthop static route

	@example
	ip route 10.0.0.1/32 10.0.0.2
	ip route 10.0.0.1/32 10.0.0.3
	ip route 10.0.0.1/32 eth0
	@end example

	If there is no route to 10.0.0.2 and 10.0.0.3, and interface eth0
	is reachable, then the last route is installed into the kernel.

	If zebra has been compiled with multipath support, and both 10.0.0.2 and
	10.0.0.3 are reachable, zebra will install a multipath route via both
	nexthops, if the platform supports this.

	@example
	zebra> show ip route
	S> 10.0.0.1/32 [1/0] via 10.0.0.2 inactive
	via 10.0.0.3 inactive
	* is directly connected, eth0
	@end example

	@example
	ip route 10.0.0.0/8 10.0.0.2
	ip route 10.0.0.0/8 10.0.0.3
	ip route 10.0.0.0/8 null0 255
	@end example

	This will install a multihop route via the specified next-hops if they are
	reachable, as well as a high-metric blackhole route, which can be useful to
	prevent traffic destined for a prefix to match less-specific routes (eg
	default) should the specified gateways not be reachable. Eg:

	@example
	zebra> show ip route 10.0.0.0/8
	Routing entry for 10.0.0.0/8
	Known via "static", distance 1, metric 0
	10.0.0.2 inactive
	10.0.0.3 inactive

	Routing entry for 10.0.0.0/8
	Known via "static", distance 255, metric 0
	directly connected, Null0
	@end example

	@deffn Command {ipv6 route @var{network} @var{gateway}} {}
	@deffnx Command {ipv6 route @var{network} @var{gateway} @var{distance}} {}
	These behave similarly to their ipv4 counterparts.
	@end deffn


	@deffn Command {table @var{tableno}} {}
	Select the primary kernel routing table to be used. This only works
	for kernels supporting multiple routing tables (like GNU/Linux 2.2.x
	and later). After setting @var{tableno} with this command,
	static routes defined after this are added to the specified table.
	@end deffn

	@node zebra Route Filtering
	@section zebra Route Filtering
	Zebra supports @command{prefix-list} and @command{route-map} to match
	routes received from other quagga components. The
	@command{permit}/@command{deny} facilities provided by these commands
	can be used to filter which routes zebra will install in the kernel.

	@deffn Command {ip protocol @var{protocol} route-map @var{routemap}} {}
	Apply a route-map filter to routes for the specified protocol. @var{protocol}
	can be @b{any} or one of
	@b{system},
	@b{kernel},
	@b{connected},
	@b{static},
	@b{rip},
	@b{ripng},
	@b{ospf},
	@b{ospf6},
	@b{isis},
	@b{bgp},
	@b{hsls}.
	@end deffn

	@deffn {Route Map} {set src @var{address}}
	Within a route-map, set the preferred source address for matching routes
	when installing in the kernel.
	@end deffn

	@example
	The following creates a prefix-list that matches all addresses, a route-map
	that sets the preferred source address, and applies the route-map to all
	@command{rip} routes.

	@group
	ip prefix-list ANY permit 0.0.0.0/0 le 32
	route-map RM1 permit 10
	match ip address prefix-list ANY
	set src 10.0.0.1

	ip protocol rip route-map RM1
	@end group
	@end example

	@node zebra FIB push interface
	@section zebra FIB push interface

	Zebra supports a 'FIB push' interface that allows an external
	component to learn the forwarding information computed by the Quagga
	routing suite.

	In Quagga, the Routing Information Base (RIB) resides inside
	zebra. Routing protocols communicate their best routes to zebra, and
	zebra computes the best route across protocols for each prefix. This
	latter information makes up the Forwarding Information Base
	(FIB). Zebra feeds the FIB to the kernel, which allows the IP stack in
	the kernel to forward packets according to the routes computed by
	Quagga. The kernel FIB is updated in an OS-specific way. For example,
	the @code{netlink} interface is used on Linux, and route sockets are
	used on FreeBSD.

	The FIB push interface aims to provide a cross-platform mechanism to
	support scenarios where the router has a forwarding path that is
	distinct from the kernel, commonly a hardware-based fast path. In
	these cases, the FIB needs to be maintained reliably in the fast path
	as well. We refer to the component that programs the forwarding plane
	(directly or indirectly) as the Forwarding Plane Manager or FPM.

	The FIB push interface comprises of a TCP connection between zebra and
	the FPM. The connection is initiated by zebra -- that is, the FPM acts
	as the TCP server.

	The relevant zebra code kicks in when zebra is configured with the
	@code{--enable-fpm} flag. Zebra periodically attempts to connect to
	the well-known FPM port. Once the connection is up, zebra starts
	sending messages containing routes over the socket to the FPM. Zebra
	sends a complete copy of the forwarding table to the FPM, including
	routes that it may have picked up from the kernel. The existing
	interaction of zebra with the kernel remains unchanged -- that is, the
	kernel continues to receive FIB updates as before.

	The format of the messages exchanged with the FPM is defined by the
	file @file{fpm/fpm.h} in the quagga tree.

	The zebra FPM interface uses replace semantics. That is, if a 'route
	add' message for a prefix is followed by another 'route add' message,
	the information in the second message is complete by itself, and
	replaces the information sent in the first message.

	If the connection to the FPM goes down for some reason, zebra sends
	the FPM a complete copy of the forwarding table(s) when it reconnects.

	@node zebra Terminal Mode Commands
	@section zebra Terminal Mode Commands

	@deffn Command {show ip route} {}
	Display current routes which zebra holds in its database.

	@example
	@group
	Router# show ip route
	Codes: K - kernel route, C - connected, S - static, R - RIP,
	B - BGP * - FIB route.

	K* 0.0.0.0/0 203.181.89.241
	S 0.0.0.0/0 203.181.89.1
	C* 127.0.0.0/8 lo
	C* 203.181.89.240/28 eth0
	@end group
	@end example
	@end deffn

	@deffn Command {show ipv6 route} {}
	@end deffn

	@deffn Command {show interface} {}
	@end deffn

	@deffn Command {show ip prefix-list [@var{name}]} {}
	@end deffn

	@deffn Command {show route-map [@var{name}]} {}
	@end deffn

	@deffn Command {show ip protocol} {}
	@end deffn

	@deffn Command {show ipforward} {}
	Display whether the host's IP forwarding function is enabled or not.
	Almost any UNIX kernel can be configured with IP forwarding disabled.
	If so, the box can't work as a router.
	@end deffn

	@deffn Command {show ipv6forward} {}
	Display whether the host's IP v6 forwarding is enabled or not.
	@end deffn

	@deffn Command {show zebra fpm stats} {}
	Display statistics related to the zebra code that interacts with the
	optional Forwarding Plane Manager (FPM) component.
	@end deffn

	@deffn Command {clear zebra fpm stats} {}
	Reset statistics related to the zebra code that interacts with the
	optional Forwarding Plane Manager (FPM) component.
	@end deffn