@c -*-texinfo-*- @c This is part of the Frr Manual. @c @value{COPYRIGHT_STR} @c Portions: @c Copyright @copyright{} 2015 Hewlett Packard Enterprise Development LP @c See file frr.texi for copying conditions. @node BGP @chapter BGP @acronym{BGP} stands for a Border Gateway Protocol. The lastest BGP version is 4. It is referred as BGP-4. BGP-4 is one of the Exterior Gateway Protocols and de-fact standard of Inter Domain routing protocol. BGP-4 is described in @cite{RFC1771, A Border Gateway Protocol 4 (BGP-4)}. Many extensions have been added to @cite{RFC1771}. @cite{RFC2858, Multiprotocol Extensions for BGP-4} provides multiprotocol support to BGP-4. @menu * Starting BGP:: * BGP router:: * BGP MED:: * BGP network:: * BGP Peer:: * BGP Peer Group:: * BGP Address Family:: * Autonomous System:: * BGP Communities Attribute:: * BGP Extended Communities Attribute:: * Displaying BGP routes:: * Capability Negotiation:: * Route Reflector:: * Route Server:: * How to set up a 6-Bone connection:: * Dump BGP packets and table:: * BGP Configuration Examples:: @end menu @node Starting BGP @section Starting BGP Default configuration file of @command{bgpd} is @file{bgpd.conf}. @command{bgpd} searches the current directory first then @value{INSTALL_PREFIX_ETC}/bgpd.conf. All of bgpd's command must be configured in @file{bgpd.conf}. @command{bgpd} specific invocation options are described below. Common options may also be specified (@pxref{Common Invocation Options}). @table @samp @item -p @var{PORT} @itemx --bgp_port=@var{PORT} Set the bgp protocol's port number. @item -r @itemx --retain When program terminates, retain BGP routes added by zebra. @item -l @itemx --listenon Specify a specific IP address for bgpd to listen on, rather than its default of INADDR_ANY / IN6ADDR_ANY. This can be useful to constrain bgpd to an internal address, or to run multiple bgpd processes on one host. @end table @node BGP router @section BGP router First of all you must configure BGP router with @command{router bgp} command. To configure BGP router, you need AS number. AS number is an identification of autonomous system. BGP protocol uses the AS number for detecting whether the BGP connection is internal one or external one. @deffn Command {router bgp @var{asn}} {} Enable a BGP protocol process with the specified @var{asn}. After this statement you can input any @code{BGP Commands}. You can not create different BGP process under different @var{asn} without specifying @code{multiple-instance} (@pxref{Multiple instance}). @end deffn @deffn Command {no router bgp @var{asn}} {} Destroy a BGP protocol process with the specified @var{asn}. @end deffn @deffn {BGP} {bgp router-id @var{A.B.C.D}} {} This command specifies the router-ID. If @command{bgpd} connects to @command{zebra} it gets interface and address information. In that case default router ID value is selected as the largest IP Address of the interfaces. When @code{router zebra} is not enabled @command{bgpd} can't get interface information so @code{router-id} is set to 0.0.0.0. So please set router-id by hand. @end deffn @menu * BGP distance:: * BGP decision process:: * BGP route flap dampening:: @end menu @node BGP distance @subsection BGP distance @deffn {BGP} {distance bgp <1-255> <1-255> <1-255>} {} This command change distance value of BGP. Each argument is distance value for external routes, internal routes and local routes. @end deffn @deffn {BGP} {distance <1-255> @var{A.B.C.D/M}} {} @deffnx {BGP} {distance <1-255> @var{A.B.C.D/M} @var{word}} {} This command set distance value to @end deffn @node BGP decision process @subsection BGP decision process The decision process Frr BGP uses to select routes is as follows: @table @asis @item 1. Weight check prefer higher local weight routes to lower routes. @item 2. Local preference check prefer higher local preference routes to lower. @item 3. Local route check Prefer local routes (statics, aggregates, redistributed) to received routes. @item 4. AS path length check Prefer shortest hop-count AS_PATHs. @item 5. Origin check Prefer the lowest origin type route. That is, prefer IGP origin routes to EGP, to Incomplete routes. @item 6. MED check Where routes with a MED were received from the same AS, prefer the route with the lowest MED. @xref{BGP MED}. @item 7. External check Prefer the route received from an external, eBGP peer over routes received from other types of peers. @item 8. IGP cost check Prefer the route with the lower IGP cost. @item 9. Multi-path check If multi-pathing is enabled, then check whether the routes not yet distinguished in preference may be considered equal. If @ref{bgp bestpath as-path multipath-relax} is set, all such routes are considered equal, otherwise routes received via iBGP with identical AS_PATHs or routes received from eBGP neighbours in the same AS are considered equal. @item 10 Already-selected external check Where both routes were received from eBGP peers, then prefer the route which is already selected. Note that this check is not applied if @ref{bgp bestpath compare-routerid} is configured. This check can prevent some cases of oscillation. @item 11. Router-ID check Prefer the route with the lowest @w{router-ID}. If the route has an @w{ORIGINATOR_ID} attribute, through iBGP reflection, then that router ID is used, otherwise the @w{router-ID} of the peer the route was received from is used. @item 12. Cluster-List length check The route with the shortest cluster-list length is used. The cluster-list reflects the iBGP reflection path the route has taken. @item 13. Peer address Prefer the route received from the peer with the higher transport layer address, as a last-resort tie-breaker. @end table @deffn {BGP} {bgp bestpath as-path confed} {} This command specifies that the length of confederation path sets and sequences should should be taken into account during the BGP best path decision process. @end deffn @deffn {BGP} {bgp bestpath as-path multipath-relax} {} @anchor{bgp bestpath as-path multipath-relax} This command specifies that BGP decision process should consider paths of equal AS_PATH length candidates for multipath computation. Without the knob, the entire AS_PATH must match for multipath computation. @end deffn @deffn {BGP} {bgp bestpath compare-routerid} {} @anchor{bgp bestpath compare-routerid} Ensure that when comparing routes where both are equal on most metrics, including local-pref, AS_PATH length, IGP cost, MED, that the tie is broken based on router-ID. If this option is enabled, then the already-selected check, where already selected eBGP routes are preferred, is skipped. If a route has an @w{ORIGINATOR_ID} attribute because it has been reflected, that @w{ORIGINATOR_ID} will be used. Otherwise, the router-ID of the peer the route was received from will be used. The advantage of this is that the route-selection (at this point) will be more deterministic. The disadvantage is that a few or even one lowest-ID router may attract all trafic to otherwise-equal paths because of this check. It may increase the possibility of MED or IGP oscillation, unless other measures were taken to avoid these. The exact behaviour will be sensitive to the iBGP and reflection topology. @end deffn @node BGP route flap dampening @subsection BGP route flap dampening @deffn {BGP} {bgp dampening @var{<1-45>} @var{<1-20000>} @var{<1-20000>} @var{<1-255>}} {} This command enables BGP route-flap dampening and specifies dampening parameters. @table @asis @item @asis{half-life} Half-life time for the penalty @item @asis{reuse-threshold} Value to start reusing a route @item @asis{suppress-threshold} Value to start suppressing a route @item @asis{max-suppress} Maximum duration to suppress a stable route @end table The route-flap damping algorithm is compatible with @cite{RFC2439}. The use of this command is not recommended nowadays, see @uref{http://www.ripe.net/ripe/docs/ripe-378,,RIPE-378}. @end deffn @node BGP MED @section BGP MED The BGP MED (Multi_Exit_Discriminator) attribute has properties which can cause subtle convergence problems in BGP. These properties and problems have proven to be hard to understand, at least historically, and may still not be widely understood. The following attempts to collect together and present what is known about MED, to help operators and Frr users in designing and configuring their networks. The BGP @acronym{MED, Multi_Exit_Discriminator} attribute is intended to allow one AS to indicate its preferences for its ingress points to another AS. The MED attribute will not be propagated on to another AS by the receiving AS - it is `non-transitive' in the BGP sense. E.g., if AS X and AS Y have 2 different BGP peering points, then AS X might set a MED of 100 on routes advertised at one and a MED of 200 at the other. When AS Y selects between otherwise equal routes to or via AS X, AS Y should prefer to take the path via the lower MED peering of 100 with AS X. Setting the MED allows an AS to influence the routing taken to it within another, neighbouring AS. In this use of MED it is not really meaningful to compare the MED value on routes where the next AS on the paths differs. E.g., if AS Y also had a route for some destination via AS Z in addition to the routes from AS X, and AS Z had also set a MED, it wouldn't make sense for AS Y to compare AS Z's MED values to those of AS X. The MED values have been set by different administrators, with different frames of reference. The default behaviour of BGP therefore is to not compare MED values across routes received from different neighbouring ASes. In Frr this is done by comparing the neighbouring, left-most AS in the received AS_PATHs of the routes and only comparing MED if those are the same. @c TeXInfo uses the old, non-UTF-8 capable, pdftex, and so @c doesn't render TeX the unicode precedes character correctly in PDF, etc. @c Using a TeX code on the other hand doesn't work for non-TeX outputs @c (plaintext, e.g.). So, use an output-conditional macro. @iftex @macro mprec{} @math{\\prec} @end macro @end iftex @ifnottex @macro mprec{} @math{≺} @end macro @end ifnottex Unfortunately, this behaviour of MED, of sometimes being compared across routes and sometimes not, depending on the properties of those other routes, means MED can cause the order of preference over all the routes to be undefined. That is, given routes A, B, and C, if A is preferred to B, and B is preferred to C, then a well-defined order should mean the preference is transitive (in the sense of orders @footnote{For some set of objects to have an order, there @emph{must} be some binary ordering relation that is defined for @emph{every} combination of those objects, and that relation @emph{must} be transitive. I.e.@:, if the relation operator is @mprec{}, and if a @mprec{} b and b @mprec{} c then that relation must carry over and it @emph{must} be that a @mprec{} c for the objects to have an order. The ordering relation may allow for equality, i.e. a @mprec{} b and b @mprec{} a may both be true amd imply that a and b are equal in the order and not distinguished by it, in which case the set has a partial order. Otherwise, if there is an order, all the objects have a distinct place in the order and the set has a total order.}) and that A would be preferred to C. However, when MED is involved this need not be the case. With MED it is possible that C is actually preferred over A. So A is preferred to B, B is preferred to C, but C is preferred to A. This can be true even where BGP defines a deterministic ``most preferred'' route out of the full set of A,B,C. With MED, for any given set of routes there may be a deterministically preferred route, but there need not be any way to arrange them into any order of preference. With unmodified MED, the order of preference of routes literally becomes undefined. That MED can induce non-transitive preferences over routes can cause issues. Firstly, it may be perceived to cause routing table churn locally at speakers; secondly, and more seriously, it may cause routing instability in iBGP topologies, where sets of speakers continually oscillate between different paths. The first issue arises from how speakers often implement routing decisions. Though BGP defines a selection process that will deterministically select the same route as best at any given speaker, even with MED, that process requires evaluating all routes together. For performance and ease of implementation reasons, many implementations evaluate route preferences in a pair-wise fashion instead. Given there is no well-defined order when MED is involved, the best route that will be chosen becomes subject to implementation details, such as the order the routes are stored in. That may be (locally) non-deterministic, e.g.@: it may be the order the routes were received in. This indeterminism may be considered undesirable, though it need not cause problems. It may mean additional routing churn is perceived, as sometimes more updates may be produced than at other times in reaction to some event . This first issue can be fixed with a more deterministic route selection that ensures routes are ordered by the neighbouring AS during selection. @xref{bgp deterministic-med}. This may reduce the number of updates as routes are received, and may in some cases reduce routing churn. Though, it could equally deterministically produce the largest possible set of updates in response to the most common sequence of received updates. A deterministic order of evaluation tends to imply an additional overhead of sorting over any set of n routes to a destination. The implementation of deterministic MED in Frr scales significantly worse than most sorting algorithms at present, with the number of paths to a given destination. That number is often low enough to not cause any issues, but where there are many paths, the deterministic comparison may quickly become increasingly expensive in terms of CPU. Deterministic local evaluation can @emph{not} fix the second, more major, issue of MED however. Which is that the non-transitive preference of routes MED can cause may lead to routing instability or oscillation across multiple speakers in iBGP topologies. This can occur with full-mesh iBGP, but is particularly problematic in non-full-mesh iBGP topologies that further reduce the routing information known to each speaker. This has primarily been documented with iBGP route-reflection topologies. However, any route-hiding technologies potentially could also exacerbate oscillation with MED. This second issue occurs where speakers each have only a subset of routes, and there are cycles in the preferences between different combinations of routes - as the undefined order of preference of MED allows - and the routes are distributed in a way that causes the BGP speakers to 'chase' those cycles. This can occur even if all speakers use a deterministic order of evaluation in route selection. E.g., speaker 4 in AS A might receive a route from speaker 2 in AS X, and from speaker 3 in AS Y; while speaker 5 in AS A might receive that route from speaker 1 in AS Y. AS Y might set a MED of 200 at speaker 1, and 100 at speaker 3. I.e, using ASN:ID:MED to label the speakers: @example /---------------\ X:2------|--A:4-------A:5--|-Y:1:200 Y:3:100--|-/ | \---------------/ @end example Assuming all other metrics are equal (AS_PATH, ORIGIN, 0 IGP costs), then based on the RFC4271 decision process speaker 4 will choose X:2 over Y:3:100, based on the lower ID of 2. Speaker 4 advertises X:2 to speaker 5. Speaker 5 will continue to prefer Y:1:200 based on the ID, and advertise this to speaker 4. Speaker 4 will now have the full set of routes, and the Y:1:200 it receives from 5 will beat X:2, but when speaker 4 compares Y:1:200 to Y:3:100 the MED check now becomes active as the ASes match, and now Y:3:100 is preferred. Speaker 4 therefore now advertises Y:3:100 to 5, which will also agrees that Y:3:100 is preferred to Y:1:200, and so withdraws the latter route from 4. Speaker 4 now has only X:2 and Y:3:100, and X:2 beats Y:3:100, and so speaker 4 implicitly updates its route to speaker 5 to X:2. Speaker 5 sees that Y:1:200 beats X:2 based on the ID, and advertises Y:1:200 to speaker 4, and the cycle continues. The root cause is the lack of a clear order of preference caused by how MED sometimes is and sometimes is not compared, leading to this cycle in the preferences between the routes: @example /---> X:2 ---beats---> Y:3:100 --\ | | | | \---beats--- Y:1:200 <---beats---/ @end example This particular type of oscillation in full-mesh iBGP topologies can be avoided by speakers preferring already selected, external routes rather than choosing to update to new a route based on a post-MED metric (e.g. router-ID), at the cost of a non-deterministic selection process. Frr implements this, as do many other implementations, so long as it is not overridden by setting @ref{bgp bestpath compare-routerid}, and see also @ref{BGP decision process}, . However, more complex and insidious cycles of oscillation are possible with iBGP route-reflection, which are not so easily avoided. These have been documented in various places. See, e.g., @cite{McPherson, D. and Gill, V. and Walton, D., "Border Gateway Protocol (BGP) Persistent Route Oscillation Condition", IETF RFC3345}, and @cite{Flavel, A. and M. Roughan, "Stable and flexible iBGP", ACM SIGCOMM 2009}, and @cite{Griffin, T. and G. Wilfong, "On the correctness of IBGP configuration", ACM SIGCOMM 2002} for concrete examples and further references. There is as of this writing @emph{no} known way to use MED for its original purpose; @emph{and} reduce routing information in iBGP topologies; @emph{and} be sure to avoid the instability problems of MED due the non-transitive routing preferences it can induce; in general on arbitrary networks. There may be iBGP topology specific ways to reduce the instability risks, even while using MED, e.g.@: by constraining the reflection topology and by tuning IGP costs between route-reflector clusters, see RFC3345 for details. In the near future, the Add-Path extension to BGP may also solve MED oscillation while still allowing MED to be used as intended, by distributing "best-paths per neighbour AS". This would be at the cost of distributing at least as many routes to all speakers as a full-mesh iBGP would, if not more, while also imposing similar CPU overheads as the "Deterministic MED" feature at each Add-Path reflector. More generally, the instability problems that MED can introduce on more complex, non-full-mesh, iBGP topologies may be avoided either by: @itemize @item Setting @ref{bgp always-compare-med}, however this allows MED to be compared across values set by different neighbour ASes, which may not produce coherent desirable results, of itself. @item Effectively ignoring MED by setting MED to the same value (e.g.@: 0) using @ref{routemap set metric} on all received routes, in combination with setting @ref{bgp always-compare-med} on all speakers. This is the simplest and most performant way to avoid MED oscillation issues, where an AS is happy not to allow neighbours to inject this problematic metric. @end itemize As MED is evaluated after the AS_PATH length check, another possible use for MED is for intra-AS steering of routes with equal AS_PATH length, as an extension of the last case above. As MED is evaluated before IGP metric, this can allow cold-potato routing to be implemented to send traffic to preferred hand-offs with neighbours, rather than the closest hand-off according to the IGP metric. Note that even if action is taken to address the MED non-transitivity issues, other oscillations may still be possible. E.g., on IGP cost if iBGP and IGP topologies are at cross-purposes with each other - see the Flavel and Roughan paper above for an example. Hence the guideline that the iBGP topology should follow the IGP topology. @deffn {BGP} {bgp deterministic-med} {} @anchor{bgp deterministic-med} Carry out route-selection in way that produces deterministic answers locally, even in the face of MED and the lack of a well-defined order of preference it can induce on routes. Without this option the preferred route with MED may be determined largely by the order that routes were received in. Setting this option will have a performance cost that may be noticeable when there are many routes for each destination. Currently in Frr it is implemented in a way that scales poorly as the number of routes per destination increases. The default is that this option is not set. @end deffn Note that there are other sources of indeterminism in the route selection process, specifically, the preference for older and already selected routes from eBGP peers, @xref{BGP decision process}. @deffn {BGP} {bgp always-compare-med} {} @anchor{bgp always-compare-med} Always compare the MED on routes, even when they were received from different neighbouring ASes. Setting this option makes the order of preference of routes more defined, and should eliminate MED induced oscillations. If using this option, it may also be desirable to use @ref{routemap set metric} to set MED to 0 on routes received from external neighbours. This option can be used, together with @ref{routemap set metric} to use MED as an intra-AS metric to steer equal-length AS_PATH routes to, e.g., desired exit points. @end deffn @node BGP network @section BGP network @menu * BGP route:: * Route Aggregation:: * Redistribute to BGP:: @end menu @node BGP route @subsection BGP route @deffn {BGP} {network @var{A.B.C.D/M}} {} This command adds the announcement network. @example @group router bgp 1 address-family ipv4 unicast network 10.0.0.0/8 exit-address-family @end group @end example This configuration example says that network 10.0.0.0/8 will be announced to all neighbors. Some vendors' routers don't advertise routes if they aren't present in their IGP routing tables; @code{bgpd} doesn't care about IGP routes when announcing its routes. @end deffn @deffn {BGP} {no network @var{A.B.C.D/M}} {} @end deffn @node Route Aggregation @subsection Route Aggregation @deffn {BGP} {aggregate-address @var{A.B.C.D/M}} {} This command specifies an aggregate address. @end deffn @deffn {BGP} {aggregate-address @var{A.B.C.D/M} as-set} {} This command specifies an aggregate address. Resulting routes include AS set. @end deffn @deffn {BGP} {aggregate-address @var{A.B.C.D/M} summary-only} {} This command specifies an aggregate address. Aggreated routes will not be announce. @end deffn @deffn {BGP} {no aggregate-address @var{A.B.C.D/M}} {} @end deffn @node Redistribute to BGP @subsection Redistribute to BGP @deffn {BGP} {redistribute kernel} {} Redistribute kernel route to BGP process. @end deffn @deffn {BGP} {redistribute static} {} Redistribute static route to BGP process. @end deffn @deffn {BGP} {redistribute connected} {} Redistribute connected route to BGP process. @end deffn @deffn {BGP} {redistribute rip} {} Redistribute RIP route to BGP process. @end deffn @deffn {BGP} {redistribute ospf} {} Redistribute OSPF route to BGP process. @end deffn @deffn {BGP} {redistribute vpn} {} Redistribute VNC routes to BGP process. @end deffn @deffn {BGP} {update-delay @var{max-delay}} {} @deffnx {BGP} {update-delay @var{max-delay} @var{establish-wait}} {} This feature is used to enable read-only mode on BGP process restart or when BGP process is cleared using 'clear ip bgp *'. When applicable, read-only mode would begin as soon as the first peer reaches Established status and a timer for max-delay seconds is started. During this mode BGP doesn't run any best-path or generate any updates to its peers. This mode continues until: 1. All the configured peers, except the shutdown peers, have sent explicit EOR (End-Of-RIB) or an implicit-EOR. The first keep-alive after BGP has reached Established is considered an implicit-EOR. If the establish-wait optional value is given, then BGP will wait for peers to reach established from the begining of the update-delay till the establish-wait period is over, i.e. the minimum set of established peers for which EOR is expected would be peers established during the establish-wait window, not necessarily all the configured neighbors. 2. max-delay period is over. On hitting any of the above two conditions, BGP resumes the decision process and generates updates to its peers. Default max-delay is 0, i.e. the feature is off by default. @end deffn @deffn {BGP} {table-map @var{route-map-name}} {} This feature is used to apply a route-map on route updates from BGP to Zebra. All the applicable match operations are allowed, such as match on prefix, next-hop, communities, etc. Set operations for this attach-point are limited to metric and next-hop only. Any operation of this feature does not affect BGPs internal RIB. Supported for ipv4 and ipv6 address families. It works on multi-paths as well, however, metric setting is based on the best-path only. @end deffn @node BGP Peer @section BGP Peer @menu * Defining Peer:: * BGP Peer commands:: * Peer filtering:: @end menu @node Defining Peer @subsection Defining Peer @deffn {BGP} {neighbor @var{peer} remote-as @var{asn}} {} Creates a new neighbor whose remote-as is @var{asn}. @var{peer} can be an IPv4 address or an IPv6 address. @example @group router bgp 1 neighbor 10.0.0.1 remote-as 2 @end group @end example In this case my router, in AS-1, is trying to peer with AS-2 at 10.0.0.1. This command must be the first command used when configuring a neighbor. If the remote-as is not specified, @command{bgpd} will complain like this: @example can't find neighbor 10.0.0.1 @end example @end deffn @node BGP Peer commands @subsection BGP Peer commands In a @code{router bgp} clause there are neighbor specific configurations required. @deffn {BGP} {neighbor @var{peer} shutdown} {} @deffnx {BGP} {no neighbor @var{peer} shutdown} {} Shutdown the peer. We can delete the neighbor's configuration by @code{no neighbor @var{peer} remote-as @var{as-number}} but all configuration of the neighbor will be deleted. When you want to preserve the configuration, but want to drop the BGP peer, use this syntax. @end deffn @deffn {BGP} {neighbor @var{peer} ebgp-multihop} {} @deffnx {BGP} {no neighbor @var{peer} ebgp-multihop} {} @end deffn @deffn {BGP} {neighbor @var{peer} description ...} {} @deffnx {BGP} {no neighbor @var{peer} description ...} {} Set description of the peer. @end deffn @deffn {BGP} {neighbor @var{peer} version @var{version}} {} Set up the neighbor's BGP version. @var{version} can be @var{4}, @var{4+} or @var{4-}. BGP version @var{4} is the default value used for BGP peering. BGP version @var{4+} means that the neighbor supports Multiprotocol Extensions for BGP-4. BGP version @var{4-} is similar but the neighbor speaks the old Internet-Draft revision 00's Multiprotocol Extensions for BGP-4. Some routing software is still using this version. @end deffn @deffn {BGP} {neighbor @var{peer} interface @var{ifname}} {} @deffnx {BGP} {no neighbor @var{peer} interface @var{ifname}} {} When you connect to a BGP peer over an IPv6 link-local address, you have to specify the @var{ifname} of the interface used for the connection. To specify IPv4 session addresses, see the @code{neighbor @var{peer} update-source} command below. This command is deprecated and may be removed in a future release. Its use should be avoided. @end deffn @c for some reason, using [all] here triggers a bug in texinfo... @deffn {BGP} {neighbor @var{peer} next-hop-self} {} @deffnx {BGP} {no neighbor @var{peer} next-hop-self} {} @deffnx {BGP} {neighbor @var{peer} next-hop-self all} {} @deffnx {BGP} {no neighbor @var{peer} next-hop-self all} {} This command specifies an announced route's nexthop as being equivalent to the address of the bgp router if it is learned via eBGP. If the optional keyword @code{all} is specified the modifiation is done also for routes learned via iBGP. @end deffn @deffn {BGP} {neighbor @var{peer} update-source @var{}} {} @deffnx {BGP} {no neighbor @var{peer} update-source} {} Specify the IPv4 source address to use for the @acronym{BGP} session to this neighbour, may be specified as either an IPv4 address directly or as an interface name (in which case the @command{zebra} daemon MUST be running in order for @command{bgpd} to be able to retrieve interface state). @example @group router bgp 64555 neighbor foo update-source 192.168.0.1 neighbor bar update-source lo0 @end group @end example @end deffn @deffn {BGP} {neighbor @var{peer} default-originate} {} @deffnx {BGP} {no neighbor @var{peer} default-originate} {} @command{bgpd}'s default is to not announce the default route (0.0.0.0/0) even it is in routing table. When you want to announce default routes to the peer, use this command. @end deffn @deffn {BGP} {neighbor @var{peer} port @var{port}} {} @deffnx {BGP} {neighbor @var{peer} port @var{port}} {} @end deffn @deffn {BGP} {neighbor @var{peer} send-community} {} @deffnx {BGP} {neighbor @var{peer} send-community} {} @end deffn @deffn {BGP} {neighbor @var{peer} weight @var{weight}} {} @deffnx {BGP} {no neighbor @var{peer} weight @var{weight}} {} This command specifies a default @var{weight} value for the neighbor's routes. @end deffn @deffn {BGP} {neighbor @var{peer} maximum-prefix @var{number}} {} @deffnx {BGP} {no neighbor @var{peer} maximum-prefix @var{number}} {} @end deffn @deffn {BGP} {neighbor @var{peer} local-as @var{as-number}} {} @deffnx {BGP} {neighbor @var{peer} local-as @var{as-number} no-prepend} {} @deffnx {BGP} {neighbor @var{peer} local-as @var{as-number} no-prepend replace-as} {} @deffnx {BGP} {no neighbor @var{peer} local-as} {} Specify an alternate AS for this BGP process when interacting with the specified peer. With no modifiers, the specified local-as is prepended to the received AS_PATH when receiving routing updates from the peer, and prepended to the outgoing AS_PATH (after the process local AS) when transmitting local routes to the peer. If the no-prepend attribute is specified, then the supplied local-as is not prepended to the received AS_PATH. If the replace-as attribute is specified, then only the supplied local-as is prepended to the AS_PATH when transmitting local-route updates to this peer. Note that replace-as can only be specified if no-prepend is. This command is only allowed for eBGP peers. @end deffn @deffn {BGP} {neighbor @var{peer} ttl-security hops @var{number}} {} @deffnx {BGP} {no neighbor @var{peer} ttl-security hops @var{number}} {} This command enforces Generalized TTL Security Mechanism (GTSM), as specified in RFC 5082. With this command, only neighbors that are the specified number of hops away will be allowed to become neighbors. This command is mututally exclusive with @command{ebgp-multihop}. @end deffn @node Peer filtering @subsection Peer filtering @deffn {BGP} {neighbor @var{peer} distribute-list @var{name} [in|out]} {} This command specifies a distribute-list for the peer. @var{direct} is @samp{in} or @samp{out}. @end deffn @deffn {BGP command} {neighbor @var{peer} prefix-list @var{name} [in|out]} {} @end deffn @deffn {BGP command} {neighbor @var{peer} filter-list @var{name} [in|out]} {} @end deffn @deffn {BGP} {neighbor @var{peer} route-map @var{name} [in|out]} {} Apply a route-map on the neighbor. @var{direct} must be @code{in} or @code{out}. @end deffn @deffn {BGP} {bgp route-reflector allow-outbound-policy} {} By default, attribute modification via route-map policy out is not reflected on reflected routes. This option allows the modifications to be reflected as well. Once enabled, it affects all reflected routes. @end deffn @c ----------------------------------------------------------------------- @node BGP Peer Group @section BGP Peer Group @deffn {BGP} {neighbor @var{word} peer-group} {} This command defines a new peer group. @end deffn @deffn {BGP} {neighbor @var{peer} peer-group @var{word}} {} This command bind specific peer to peer group @var{word}. @end deffn @node BGP Address Family @section BGP Address Family Multiprotocol BGP enables BGP to carry routing information for multiple Network Layer protocols. BGP supports multiple Address Family Identifier (AFI), namely IPv4 and IPv6. Support is also provided for multiple sets of per-AFI information via Subsequent Address Family Identifiers (SAFI). In addition to unicast information, VPN information @cite{RFC4364} and @cite{RFC4659}, and Encapsulation information @cite{RFC5512} is supported. @deffn {Command} {show ip bgp vpnv4 all} {} @deffnx {Command} {show ipv6 bgp vpn all} {} Print active IPV4 or IPV6 routes advertised via the VPN SAFI. @end deffn @deffn {Command} {show ip bgp encap all} {} @deffnx {Command} {show ipv6 bgp encap all} {} Print active IPV4 or IPV6 routes advertised via the Encapsulation SAFI. @end deffn @deffn {Command} {show bgp ipv4 encap summary} {} @deffnx {Command} {show bgp ipv4 vpn summary} {} @deffnx {Command} {show bgp ipv6 encap summary} {} @deffnx {Command} {show bgp ipv6 vpn summary} {} Print a summary of neighbor connections for the specified AFI/SAFI combination. @end deffn @c ----------------------------------------------------------------------- @node Autonomous System @section Autonomous System The @acronym{AS,Autonomous System} number is one of the essential element of BGP. BGP is a distance vector routing protocol, and the AS-Path framework provides distance vector metric and loop detection to BGP. @cite{RFC1930, Guidelines for creation, selection, and registration of an Autonomous System (AS)} provides some background on the concepts of an AS. The AS number is a two octet value, ranging in value from 1 to 65535. The AS numbers 64512 through 65535 are defined as private AS numbers. Private AS numbers must not to be advertised in the global Internet. @menu * AS Path Regular Expression:: * Display BGP Routes by AS Path:: * AS Path Access List:: * Using AS Path in Route Map:: * Private AS Numbers:: @end menu @node AS Path Regular Expression @subsection AS Path Regular Expression AS path regular expression can be used for displaying BGP routes and AS path access list. AS path regular expression is based on @code{POSIX 1003.2} regular expressions. Following description is just a subset of @code{POSIX} regular expression. User can use full @code{POSIX} regular expression. Adding to that special character '_' is added for AS path regular expression. @table @code @item . Matches any single character. @item * Matches 0 or more occurrences of pattern. @item + Matches 1 or more occurrences of pattern. @item ? Match 0 or 1 occurrences of pattern. @item ^ Matches the beginning of the line. @item $ Matches the end of the line. @item _ Character @code{_} has special meanings in AS path regular expression. It matches to space and comma , and AS set delimiter @{ and @} and AS confederation delimiter @code{(} and @code{)}. And it also matches to the beginning of the line and the end of the line. So @code{_} can be used for AS value boundaries match. @code{show ip bgp regexp _7675_} matches to all of BGP routes which as AS number include @var{7675}. @end table @node Display BGP Routes by AS Path @subsection Display BGP Routes by AS Path To show BGP routes which has specific AS path information @code{show ip bgp} command can be used. @deffn Command {show ip bgp regexp @var{line}} {} This commands display BGP routes that matches AS path regular expression @var{line}. @end deffn @node AS Path Access List @subsection AS Path Access List AS path access list is user defined AS path. @deffn {Command} {ip as-path access-list @var{word} @{permit|deny@} @var{line}} {} This command defines a new AS path access list. @end deffn @deffn {Command} {no ip as-path access-list @var{word}} {} @deffnx {Command} {no ip as-path access-list @var{word} @{permit|deny@} @var{line}} {} @end deffn @node Using AS Path in Route Map @subsection Using AS Path in Route Map @deffn {Route Map} {match as-path @var{word}} {} @end deffn @deffn {Route Map} {set as-path prepend @var{as-path}} {} Prepend the given string of AS numbers to the AS_PATH. @end deffn @deffn {Route Map} {set as-path prepend last-as @var{num}} {} Prepend the existing last AS number (the leftmost ASN) to the AS_PATH. @end deffn @node Private AS Numbers @subsection Private AS Numbers @c ----------------------------------------------------------------------- @node BGP Communities Attribute @section BGP Communities Attribute BGP communities attribute is widely used for implementing policy routing. Network operators can manipulate BGP communities attribute based on their network policy. BGP communities attribute is defined in @cite{RFC1997, BGP Communities Attribute} and @cite{RFC1998, An Application of the BGP Community Attribute in Multi-home Routing}. It is an optional transitive attribute, therefore local policy can travel through different autonomous system. Communities attribute is a set of communities values. Each communities value is 4 octet long. The following format is used to define communities value. @table @code @item AS:VAL This format represents 4 octet communities value. @code{AS} is high order 2 octet in digit format. @code{VAL} is low order 2 octet in digit format. This format is useful to define AS oriented policy value. For example, @code{7675:80} can be used when AS 7675 wants to pass local policy value 80 to neighboring peer. @item internet @code{internet} represents well-known communities value 0. @item no-export @code{no-export} represents well-known communities value @code{NO_EXPORT}@* @r{(0xFFFFFF01)}. All routes carry this value must not be advertised to outside a BGP confederation boundary. If neighboring BGP peer is part of BGP confederation, the peer is considered as inside a BGP confederation boundary, so the route will be announced to the peer. @item no-advertise @code{no-advertise} represents well-known communities value @code{NO_ADVERTISE}@*@r{(0xFFFFFF02)}. All routes carry this value must not be advertise to other BGP peers. @item local-AS @code{local-AS} represents well-known communities value @code{NO_EXPORT_SUBCONFED} @r{(0xFFFFFF03)}. All routes carry this value must not be advertised to external BGP peers. Even if the neighboring router is part of confederation, it is considered as external BGP peer, so the route will not be announced to the peer. @end table When BGP communities attribute is received, duplicated communities value in the communities attribute is ignored and each communities values are sorted in numerical order. @menu * BGP Community Lists:: * Numbered BGP Community Lists:: * BGP Community in Route Map:: * Display BGP Routes by Community:: * Using BGP Communities Attribute:: @end menu @node BGP Community Lists @subsection BGP Community Lists BGP community list is a user defined BGP communites attribute list. BGP community list can be used for matching or manipulating BGP communities attribute in updates. There are two types of community list. One is standard community list and another is expanded community list. Standard community list defines communities attribute. Expanded community list defines communities attribute string with regular expression. Standard community list is compiled into binary format when user define it. Standard community list will be directly compared to BGP communities attribute in BGP updates. Therefore the comparison is faster than expanded community list. @deffn Command {ip community-list standard @var{name} @{permit|deny@} @var{community}} {} This command defines a new standard community list. @var{community} is communities value. The @var{community} is compiled into community structure. We can define multiple community list under same name. In that case match will happen user defined order. Once the community list matches to communities attribute in BGP updates it return permit or deny by the community list definition. When there is no matched entry, deny will be returned. When @var{community} is empty it matches to any routes. @end deffn @deffn Command {ip community-list expanded @var{name} @{permit|deny@} @var{line}} {} This command defines a new expanded community list. @var{line} is a string expression of communities attribute. @var{line} can include regular expression to match communities attribute in BGP updates. @end deffn @deffn Command {no ip community-list @var{name}} {} @deffnx Command {no ip community-list standard @var{name}} {} @deffnx Command {no ip community-list expanded @var{name}} {} These commands delete community lists specified by @var{name}. All of community lists shares a single name space. So community lists can be removed simpley specifying community lists name. @end deffn @deffn {Command} {show ip community-list} {} @deffnx {Command} {show ip community-list @var{name}} {} This command display current community list information. When @var{name} is specified the specified community list's information is shown. @example # show ip community-list Named Community standard list CLIST permit 7675:80 7675:100 no-export deny internet Named Community expanded list EXPAND permit : # show ip community-list CLIST Named Community standard list CLIST permit 7675:80 7675:100 no-export deny internet @end example @end deffn @node Numbered BGP Community Lists @subsection Numbered BGP Community Lists When number is used for BGP community list name, the number has special meanings. Community list number in the range from 1 and 99 is standard community list. Community list number in the range from 100 to 199 is expanded community list. These community lists are called as numbered community lists. On the other hand normal community lists is called as named community lists. @deffn Command {ip community-list <1-99> @{permit|deny@} @var{community}} {} This command defines a new community list. <1-99> is standard community list number. Community list name within this range defines standard community list. When @var{community} is empty it matches to any routes. @end deffn @deffn Command {ip community-list <100-199> @{permit|deny@} @var{community}} {} This command defines a new community list. <100-199> is expanded community list number. Community list name within this range defines expanded community list. @end deffn @deffn Command {ip community-list @var{name} @{permit|deny@} @var{community}} {} When community list type is not specifed, the community list type is automatically detected. If @var{community} can be compiled into communities attribute, the community list is defined as a standard community list. Otherwise it is defined as an expanded community list. This feature is left for backward compability. Use of this feature is not recommended. @end deffn @node BGP Community in Route Map @subsection BGP Community in Route Map In Route Map (@pxref{Route Map}), we can match or set BGP communities attribute. Using this feature network operator can implement their network policy based on BGP communities attribute. Following commands can be used in Route Map. @deffn {Route Map} {match community @var{word}} {} @deffnx {Route Map} {match community @var{word} exact-match} {} This command perform match to BGP updates using community list @var{word}. When the one of BGP communities value match to the one of communities value in community list, it is match. When @code{exact-match} keyword is spcified, match happen only when BGP updates have completely same communities value specified in the community list. @end deffn @deffn {Route Map} {set community none} {} @deffnx {Route Map} {set community @var{community}} {} @deffnx {Route Map} {set community @var{community} additive} {} This command manipulate communities value in BGP updates. When @code{none} is specified as communities value, it removes entire communities attribute from BGP updates. When @var{community} is not @code{none}, specified communities value is set to BGP updates. If BGP updates already has BGP communities value, the existing BGP communities value is replaced with specified @var{community} value. When @code{additive} keyword is specified, @var{community} is appended to the existing communities value. @end deffn @deffn {Route Map} {set comm-list @var{word} delete} {} This command remove communities value from BGP communities attribute. The @var{word} is community list name. When BGP route's communities value matches to the community list @var{word}, the communities value is removed. When all of communities value is removed eventually, the BGP update's communities attribute is completely removed. @end deffn @node Display BGP Routes by Community @subsection Display BGP Routes by Community To show BGP routes which has specific BGP communities attribute, @code{show ip bgp} command can be used. The @var{community} value and community list can be used for @code{show ip bgp} command. @deffn Command {show ip bgp community} {} @deffnx Command {show ip bgp community @var{community}} {} @deffnx Command {show ip bgp community @var{community} exact-match} {} @code{show ip bgp community} displays BGP routes which has communities attribute. When @var{community} is specified, BGP routes that matches @var{community} value is displayed. For this command, @code{internet} keyword can't be used for @var{community} value. When @code{exact-match} is specified, it display only routes that have an exact match. @end deffn @deffn Command {show ip bgp community-list @var{word}} {} @deffnx Command {show ip bgp community-list @var{word} exact-match} {} This commands display BGP routes that matches community list @var{word}. When @code{exact-match} is specified, display only routes that have an exact match. @end deffn @node Using BGP Communities Attribute @subsection Using BGP Communities Attribute Following configuration is the most typical usage of BGP communities attribute. AS 7675 provides upstream Internet connection to AS 100. When following configuration exists in AS 7675, AS 100 networks operator can set local preference in AS 7675 network by setting BGP communities attribute to the updates. @example router bgp 7675 neighbor 192.168.0.1 remote-as 100 address-family ipv4 unicast neighbor 192.168.0.1 route-map RMAP in exit-address-family ! ip community-list 70 permit 7675:70 ip community-list 70 deny ip community-list 80 permit 7675:80 ip community-list 80 deny ip community-list 90 permit 7675:90 ip community-list 90 deny ! route-map RMAP permit 10 match community 70 set local-preference 70 ! route-map RMAP permit 20 match community 80 set local-preference 80 ! route-map RMAP permit 30 match community 90 set local-preference 90 @end example Following configuration announce 10.0.0.0/8 from AS 100 to AS 7675. The route has communities value 7675:80 so when above configuration exists in AS 7675, announced route's local preference will be set to value 80. @example router bgp 100 network 10.0.0.0/8 neighbor 192.168.0.2 remote-as 7675 address-family ipv4 unicast neighbor 192.168.0.2 route-map RMAP out exit-address-family ! ip prefix-list PLIST permit 10.0.0.0/8 ! route-map RMAP permit 10 match ip address prefix-list PLIST set community 7675:80 @end example Following configuration is an example of BGP route filtering using communities attribute. This configuration only permit BGP routes which has BGP communities value 0:80 or 0:90. Network operator can put special internal communities value at BGP border router, then limit the BGP routes announcement into the internal network. @example router bgp 7675 neighbor 192.168.0.1 remote-as 100 address-family ipv4 unicast neighbor 192.168.0.1 route-map RMAP in exit-address-family ! ip community-list 1 permit 0:80 0:90 ! route-map RMAP permit in match community 1 @end example Following exmaple filter BGP routes which has communities value 1:1. When there is no match community-list returns deny. To avoid filtering all of routes, we need to define permit any at last. @example router bgp 7675 neighbor 192.168.0.1 remote-as 100 address-family ipv4 unicast neighbor 192.168.0.1 route-map RMAP in exit-address-family ! ip community-list standard FILTER deny 1:1 ip community-list standard FILTER permit ! route-map RMAP permit 10 match community FILTER @end example Communities value keyword @code{internet} has special meanings in standard community lists. In below example @code{internet} act as match any. It matches all of BGP routes even if the route does not have communities attribute at all. So community list @code{INTERNET} is same as above example's @code{FILTER}. @example ip community-list standard INTERNET deny 1:1 ip community-list standard INTERNET permit internet @end example Following configuration is an example of communities value deletion. With this configuration communities value 100:1 and 100:2 is removed from BGP updates. For communities value deletion, only @code{permit} community-list is used. @code{deny} community-list is ignored. @example router bgp 7675 neighbor 192.168.0.1 remote-as 100 address-family ipv4 unicast neighbor 192.168.0.1 route-map RMAP in exit-address-family ! ip community-list standard DEL permit 100:1 100:2 ! route-map RMAP permit 10 set comm-list DEL delete @end example @c ----------------------------------------------------------------------- @node BGP Extended Communities Attribute @section BGP Extended Communities Attribute BGP extended communities attribute is introduced with MPLS VPN/BGP technology. MPLS VPN/BGP expands capability of network infrastructure to provide VPN functionality. At the same time it requires a new framework for policy routing. With BGP Extended Communities Attribute we can use Route Target or Site of Origin for implementing network policy for MPLS VPN/BGP. BGP Extended Communities Attribute is similar to BGP Communities Attribute. It is an optional transitive attribute. BGP Extended Communities Attribute can carry multiple Extended Community value. Each Extended Community value is eight octet length. BGP Extended Communities Attribute provides an extended range compared with BGP Communities Attribute. Adding to that there is a type field in each value to provides community space structure. There are two format to define Extended Community value. One is AS based format the other is IP address based format. @table @code @item AS:VAL This is a format to define AS based Extended Community value. @code{AS} part is 2 octets Global Administrator subfield in Extended Community value. @code{VAL} part is 4 octets Local Administrator subfield. @code{7675:100} represents AS 7675 policy value 100. @item IP-Address:VAL This is a format to define IP address based Extended Community value. @code{IP-Address} part is 4 octets Global Administrator subfield. @code{VAL} part is 2 octets Local Administrator subfield. @code{10.0.0.1:100} represents @end table @menu * BGP Extended Community Lists:: * BGP Extended Communities in Route Map:: @end menu @node BGP Extended Community Lists @subsection BGP Extended Community Lists Expanded Community Lists is a user defined BGP Expanded Community Lists. @deffn Command {ip extcommunity-list standard @var{name} @{permit|deny@} @var{extcommunity}} {} This command defines a new standard extcommunity-list. @var{extcommunity} is extended communities value. The @var{extcommunity} is compiled into extended community structure. We can define multiple extcommunity-list under same name. In that case match will happen user defined order. Once the extcommunity-list matches to extended communities attribute in BGP updates it return permit or deny based upon the extcommunity-list definition. When there is no matched entry, deny will be returned. When @var{extcommunity} is empty it matches to any routes. @end deffn @deffn Command {ip extcommunity-list expanded @var{name} @{permit|deny@} @var{line}} {} This command defines a new expanded extcommunity-list. @var{line} is a string expression of extended communities attribute. @var{line} can include regular expression to match extended communities attribute in BGP updates. @end deffn @deffn Command {no ip extcommunity-list @var{name}} {} @deffnx Command {no ip extcommunity-list standard @var{name}} {} @deffnx Command {no ip extcommunity-list expanded @var{name}} {} These commands delete extended community lists specified by @var{name}. All of extended community lists shares a single name space. So extended community lists can be removed simpley specifying the name. @end deffn @deffn {Command} {show ip extcommunity-list} {} @deffnx {Command} {show ip extcommunity-list @var{name}} {} This command display current extcommunity-list information. When @var{name} is specified the community list's information is shown. @example # show ip extcommunity-list @end example @end deffn @node BGP Extended Communities in Route Map @subsection BGP Extended Communities in Route Map @deffn {Route Map} {match extcommunity @var{word}} {} @end deffn @deffn {Route Map} {set extcommunity rt @var{extcommunity}} {} This command set Route Target value. @end deffn @deffn {Route Map} {set extcommunity soo @var{extcommunity}} {} This command set Site of Origin value. @end deffn @c ----------------------------------------------------------------------- @node Displaying BGP routes @section Displaying BGP Routes @menu * Show IP BGP:: * More Show IP BGP:: @end menu @node Show IP BGP @subsection Show IP BGP @deffn {Command} {show ip bgp} {} @deffnx {Command} {show ip bgp @var{A.B.C.D}} {} @deffnx {Command} {show ip bgp @var{X:X::X:X}} {} This command displays BGP routes. When no route is specified it display all of IPv4 BGP routes. @end deffn @example BGP table version is 0, local router ID is 10.1.1.1 Status codes: s suppressed, d damped, h history, * valid, > best, i - internal Origin codes: i - IGP, e - EGP, ? - incomplete Network Next Hop Metric LocPrf Weight Path *> 1.1.1.1/32 0.0.0.0 0 32768 i Total number of prefixes 1 @end example @node More Show IP BGP @subsection More Show IP BGP @deffn {Command} {show ip bgp regexp @var{line}} {} This command display BGP routes using AS path regular expression (@pxref{Display BGP Routes by AS Path}). @end deffn @deffn Command {show ip bgp community @var{community}} {} @deffnx Command {show ip bgp community @var{community} exact-match} {} This command display BGP routes using @var{community} (@pxref{Display BGP Routes by Community}). @end deffn @deffn Command {show ip bgp community-list @var{word}} {} @deffnx Command {show ip bgp community-list @var{word} exact-match} {} This command display BGP routes using community list (@pxref{Display BGP Routes by Community}). @end deffn @deffn {Command} {show ip bgp summary} {} @end deffn @deffn {Command} {show ip bgp neighbor [@var{peer}]} {} @end deffn @deffn {Command} {clear ip bgp @var{peer}} {} Clear peers which have addresses of X.X.X.X @end deffn @deffn {Command} {clear ip bgp @var{peer} soft in} {} Clear peer using soft reconfiguration. @end deffn @deffn {Command} {show ip bgp dampened-paths} {} Display paths suppressed due to dampening @end deffn @deffn {Command} {show ip bgp flap-statistics} {} Display flap statistics of routes @end deffn @deffn {Command} {show debug} {} @end deffn @deffn {Command} {debug event} {} @end deffn @deffn {Command} {debug update} {} @end deffn @deffn {Command} {debug keepalive} {} @end deffn @deffn {Command} {no debug event} {} @end deffn @deffn {Command} {no debug update} {} @end deffn @deffn {Command} {no debug keepalive} {} @end deffn @node Capability Negotiation @section Capability Negotiation When adding IPv6 routing information exchange feature to BGP. There were some proposals. @acronym{IETF,Internet Engineering Task Force} @acronym{IDR, Inter Domain Routing} @acronym{WG, Working group} adopted a proposal called Multiprotocol Extension for BGP. The specification is described in @cite{RFC2283}. The protocol does not define new protocols. It defines new attributes to existing BGP. When it is used exchanging IPv6 routing information it is called BGP-4+. When it is used for exchanging multicast routing information it is called MBGP. @command{bgpd} supports Multiprotocol Extension for BGP. So if remote peer supports the protocol, @command{bgpd} can exchange IPv6 and/or multicast routing information. Traditional BGP did not have the feature to detect remote peer's capabilities, e.g. whether it can handle prefix types other than IPv4 unicast routes. This was a big problem using Multiprotocol Extension for BGP to operational network. @cite{RFC2842, Capabilities Advertisement with BGP-4} adopted a feature called Capability Negotiation. @command{bgpd} use this Capability Negotiation to detect the remote peer's capabilities. If the peer is only configured as IPv4 unicast neighbor, @command{bgpd} does not send these Capability Negotiation packets (at least not unless other optional BGP features require capability negotation). By default, Frr will bring up peering with minimal common capability for the both sides. For example, local router has unicast and multicast capabilitie and remote router has unicast capability. In this case, the local router will establish the connection with unicast only capability. When there are no common capabilities, Frr sends Unsupported Capability error and then resets the connection. If you want to completely match capabilities with remote peer. Please use @command{strict-capability-match} command. @deffn {BGP} {neighbor @var{peer} strict-capability-match} {} @deffnx {BGP} {no neighbor @var{peer} strict-capability-match} {} Strictly compares remote capabilities and local capabilities. If capabilities are different, send Unsupported Capability error then reset connection. @end deffn You may want to disable sending Capability Negotiation OPEN message optional parameter to the peer when remote peer does not implement Capability Negotiation. Please use @command{dont-capability-negotiate} command to disable the feature. @deffn {BGP} {neighbor @var{peer} dont-capability-negotiate} {} @deffnx {BGP} {no neighbor @var{peer} dont-capability-negotiate} {} Suppress sending Capability Negotiation as OPEN message optional parameter to the peer. This command only affects the peer is configured other than IPv4 unicast configuration. @end deffn When remote peer does not have capability negotiation feature, remote peer will not send any capabilities at all. In that case, bgp configures the peer with configured capabilities. You may prefer locally configured capabilities more than the negotiated capabilities even though remote peer sends capabilities. If the peer is configured by @command{override-capability}, @command{bgpd} ignores received capabilities then override negotiated capabilities with configured values. @deffn {BGP} {neighbor @var{peer} override-capability} {} @deffnx {BGP} {no neighbor @var{peer} override-capability} {} Override the result of Capability Negotiation with local configuration. Ignore remote peer's capability value. @end deffn @node Route Reflector @section Route Reflector @deffn {BGP} {bgp cluster-id @var{a.b.c.d}} {} @end deffn @deffn {BGP} {neighbor @var{peer} route-reflector-client} {} @deffnx {BGP} {no neighbor @var{peer} route-reflector-client} {} @end deffn @node Route Server @section Route Server At an Internet Exchange point, many ISPs are connected to each other by external BGP peering. Normally these external BGP connection are done by @samp{full mesh} method. As with internal BGP full mesh formation, this method has a scaling problem. This scaling problem is well known. Route Server is a method to resolve the problem. Each ISP's BGP router only peers to Route Server. Route Server serves as BGP information exchange to other BGP routers. By applying this method, numbers of BGP connections is reduced from O(n*(n-1)/2) to O(n). Unlike normal BGP router, Route Server must have several routing tables for managing different routing policies for each BGP speaker. We call the routing tables as different @code{view}s. @command{bgpd} can work as normal BGP router or Route Server or both at the same time. @menu * Multiple instance:: * BGP instance and view:: * Routing policy:: * Viewing the view:: @end menu @node Multiple instance @subsection Multiple instance To enable multiple view function of @code{bgpd}, you must turn on multiple instance feature beforehand. @deffn {Command} {bgp multiple-instance} {} Enable BGP multiple instance feature. After this feature is enabled, you can make multiple BGP instances or multiple BGP views. @end deffn @deffn {Command} {no bgp multiple-instance} {} Disable BGP multiple instance feature. You can not disable this feature when BGP multiple instances or views exist. @end deffn When you want to make configuration more Cisco like one, @deffn {Command} {bgp config-type cisco} {} Cisco compatible BGP configuration output. @end deffn When bgp config-type cisco is specified, ``no synchronization'' is displayed. ``no auto-summary'' is displayed. ``network'' and ``aggregate-address'' argument is displayed as ``A.B.C.D M.M.M.M'' Frr: network 10.0.0.0/8 Cisco: network 10.0.0.0 Frr: aggregate-address 192.168.0.0/24 Cisco: aggregate-address 192.168.0.0 255.255.255.0 Community attribute handling is also different. If there is no configuration is specified community attribute and extended community attribute are sent to neighbor. When user manually disable the feature community attribute is not sent to the neighbor. In case of @command{bgp config-type cisco} is specified, community attribute is not sent to the neighbor by default. To send community attribute user has to specify @command{neighbor A.B.C.D send-community} command. @example ! router bgp 1 neighbor 10.0.0.1 remote-as 1 address-family ipv4 unicast no neighbor 10.0.0.1 send-community exit-address-family ! router bgp 1 neighbor 10.0.0.1 remote-as 1 address-family ipv4 unicast neighbor 10.0.0.1 send-community exit-address-family ! @end example @deffn {Command} {bgp config-type zebra} {} Frr style BGP configuration. This is default. @end deffn @node BGP instance and view @subsection BGP instance and view BGP instance is a normal BGP process. The result of route selection goes to the kernel routing table. You can setup different AS at the same time when BGP multiple instance feature is enabled. @deffn {Command} {router bgp @var{as-number}} {} Make a new BGP instance. You can use arbitrary word for the @var{name}. @end deffn @example @group bgp multiple-instance ! router bgp 1 neighbor 10.0.0.1 remote-as 2 neighbor 10.0.0.2 remote-as 3 ! router bgp 2 neighbor 10.0.0.3 remote-as 4 neighbor 10.0.0.4 remote-as 5 @end group @end example BGP view is almost same as normal BGP process. The result of route selection does not go to the kernel routing table. BGP view is only for exchanging BGP routing information. @deffn {Command} {router bgp @var{as-number} view @var{name}} {} Make a new BGP view. You can use arbitrary word for the @var{name}. This view's route selection result does not go to the kernel routing table. @end deffn With this command, you can setup Route Server like below. @example @group bgp multiple-instance ! router bgp 1 view 1 neighbor 10.0.0.1 remote-as 2 neighbor 10.0.0.2 remote-as 3 ! router bgp 2 view 2 neighbor 10.0.0.3 remote-as 4 neighbor 10.0.0.4 remote-as 5 @end group @end example @node Routing policy @subsection Routing policy You can set different routing policy for a peer. For example, you can set different filter for a peer. @example @group bgp multiple-instance ! router bgp 1 view 1 neighbor 10.0.0.1 remote-as 2 address-family ipv4 unicast neighbor 10.0.0.1 distribute-list 1 in exit-address-family ! router bgp 1 view 2 neighbor 10.0.0.1 remote-as 2 address-family ipv4 unicast neighbor 10.0.0.1 distribute-list 2 in exit-address-family @end group @end example This means BGP update from a peer 10.0.0.1 goes to both BGP view 1 and view 2. When the update is inserted into view 1, distribute-list 1 is applied. On the other hand, when the update is inserted into view 2, distribute-list 2 is applied. @node Viewing the view @subsection Viewing the view To display routing table of BGP view, you must specify view name. @deffn {Command} {show ip bgp view @var{name}} {} Display routing table of BGP view @var{name}. @end deffn @node How to set up a 6-Bone connection @section How to set up a 6-Bone connection @example @group zebra configuration =================== ! ! Actually there is no need to configure zebra ! bgpd configuration ================== ! ! This means that routes go through zebra and into the kernel. ! router zebra ! ! MP-BGP configuration ! router bgp 7675 bgp router-id 10.0.0.1 neighbor 3ffe:1cfa:0:2:2a0:c9ff:fe9e:f56 remote-as @var{as-number} ! address-family ipv6 network 3ffe:506::/32 neighbor 3ffe:1cfa:0:2:2a0:c9ff:fe9e:f56 activate neighbor 3ffe:1cfa:0:2:2a0:c9ff:fe9e:f56 route-map set-nexthop out neighbor 3ffe:1cfa:0:2:2c0:4fff:fe68:a231 remote-as @var{as-number} neighbor 3ffe:1cfa:0:2:2c0:4fff:fe68:a231 route-map set-nexthop out exit-address-family ! ipv6 access-list all permit any ! ! Set output nexthop address. ! route-map set-nexthop permit 10 match ipv6 address all set ipv6 nexthop global 3ffe:1cfa:0:2:2c0:4fff:fe68:a225 set ipv6 nexthop local fe80::2c0:4fff:fe68:a225 ! ! logfile FILENAME is obsolete. Please use log file FILENAME log file bgpd.log ! @end group @end example @node Dump BGP packets and table @section Dump BGP packets and table @deffn Command {dump bgp all @var{path} [@var{interval}]} {} @deffnx Command {dump bgp all-et @var{path} [@var{interval}]} {} @deffnx Command {no dump bgp all [@var{path}] [@var{interval}]} {} Dump all BGP packet and events to @var{path} file. If @var{interval} is set, a new file will be created for echo @var{interval} of seconds. The path @var{path} can be set with date and time formatting (strftime). The type ‘all-et’ enables support for Extended Timestamp Header (@pxref{Packet Binary Dump Format}). (@pxref{Packet Binary Dump Format}) @end deffn @deffn Command {dump bgp updates @var{path} [@var{interval}]} {} @deffnx Command {dump bgp updates-et @var{path} [@var{interval}]} {} @deffnx Command {no dump bgp updates [@var{path}] [@var{interval}]} {} Dump only BGP updates messages to @var{path} file. If @var{interval} is set, a new file will be created for echo @var{interval} of seconds. The path @var{path} can be set with date and time formatting (strftime). The type ‘updates-et’ enables support for Extended Timestamp Header (@pxref{Packet Binary Dump Format}). @end deffn @deffn Command {dump bgp routes-mrt @var{path}} {} @deffnx Command {dump bgp routes-mrt @var{path} @var{interval}} {} @deffnx Command {no dump bgp route-mrt [@var{path}] [@var{interval}]} {} Dump whole BGP routing table to @var{path}. This is heavy process. The path @var{path} can be set with date and time formatting (strftime). If @var{interval} is set, a new file will be created for echo @var{interval} of seconds. @end deffn Note: the interval variable can also be set using hours and minutes: 04h20m00. @node BGP Configuration Examples @section BGP Configuration Examples Example of a session to an upstream, advertising only one prefix to it. @example router bgp 64512 bgp router-id 10.236.87.1 neighbor upstream peer-group neighbor upstream remote-as 64515 neighbor upstream capability dynamic neighbor 10.1.1.1 peer-group upstream neighbor 10.1.1.1 description ACME ISP address-family ipv4 unicast network 10.236.87.0/24 neighbor upstream prefix-list pl-allowed-adv out exit-address-family ! ip prefix-list pl-allowed-adv seq 5 permit 82.195.133.0/25 ip prefix-list pl-allowed-adv seq 10 deny any @end example A more complex example. With upstream, peer and customer sessions. Advertising global prefixes and NO_EXPORT prefixes and providing actions for customer routes based on community values. Extensive use of route-maps and the 'call' feature to support selective advertising of prefixes. This example is intended as guidance only, it has NOT been tested and almost certainly containts silly mistakes, if not serious flaws. @example router bgp 64512 bgp router-id 10.236.87.1 neighbor upstream capability dynamic neighbor cust capability dynamic neighbor peer capability dynamic neighbor 10.1.1.1 remote-as 64515 neighbor 10.1.1.1 peer-group upstream neighbor 10.2.1.1 remote-as 64516 neighbor 10.2.1.1 peer-group upstream neighbor 10.3.1.1 remote-as 64517 neighbor 10.3.1.1 peer-group cust-default neighbor 10.3.1.1 description customer1 neighbor 10.4.1.1 remote-as 64518 neighbor 10.4.1.1 peer-group cust neighbor 10.4.1.1 description customer2 neighbor 10.5.1.1 remote-as 64519 neighbor 10.5.1.1 peer-group peer neighbor 10.5.1.1 description peer AS 1 neighbor 10.6.1.1 remote-as 64520 neighbor 10.6.1.1 peer-group peer neighbor 10.6.1.1 description peer AS 2 address-family ipv4 unicast network 10.123.456.0/24 network 10.123.456.128/25 route-map rm-no-export neighbor upstream route-map rm-upstream-out out neighbor cust route-map rm-cust-in in neighbor cust route-map rm-cust-out out neighbor cust send-community both neighbor peer route-map rm-peer-in in neighbor peer route-map rm-peer-out out neighbor peer send-community both neighbor 10.3.1.1 prefix-list pl-cust1-network in neighbor 10.4.1.1 prefix-list pl-cust2-network in neighbor 10.5.1.1 prefix-list pl-peer1-network in neighbor 10.6.1.1 prefix-list pl-peer2-network in exit-address-family ! ip prefix-list pl-default permit 0.0.0.0/0 ! ip prefix-list pl-upstream-peers permit 10.1.1.1/32 ip prefix-list pl-upstream-peers permit 10.2.1.1/32 ! ip prefix-list pl-cust1-network permit 10.3.1.0/24 ip prefix-list pl-cust1-network permit 10.3.2.0/24 ! ip prefix-list pl-cust2-network permit 10.4.1.0/24 ! ip prefix-list pl-peer1-network permit 10.5.1.0/24 ip prefix-list pl-peer1-network permit 10.5.2.0/24 ip prefix-list pl-peer1-network permit 192.168.0.0/24 ! ip prefix-list pl-peer2-network permit 10.6.1.0/24 ip prefix-list pl-peer2-network permit 10.6.2.0/24 ip prefix-list pl-peer2-network permit 192.168.1.0/24 ip prefix-list pl-peer2-network permit 192.168.2.0/24 ip prefix-list pl-peer2-network permit 172.16.1/24 ! ip as-path access-list asp-own-as permit ^$ ip as-path access-list asp-own-as permit _64512_ ! ! ################################################################# ! Match communities we provide actions for, on routes receives from ! customers. Communities values of :X, with X, have actions: ! ! 100 - blackhole the prefix ! 200 - set no_export ! 300 - advertise only to other customers ! 400 - advertise only to upstreams ! 500 - set no_export when advertising to upstreams ! 2X00 - set local_preference to X00 ! ! blackhole the prefix of the route ip community-list standard cm-blackhole permit 64512:100 ! ! set no-export community before advertising ip community-list standard cm-set-no-export permit 64512:200 ! ! advertise only to other customers ip community-list standard cm-cust-only permit 64512:300 ! ! advertise only to upstreams ip community-list standard cm-upstream-only permit 64512:400 ! ! advertise to upstreams with no-export ip community-list standard cm-upstream-noexport permit 64512:500 ! ! set local-pref to least significant 3 digits of the community ip community-list standard cm-prefmod-100 permit 64512:2100 ip community-list standard cm-prefmod-200 permit 64512:2200 ip community-list standard cm-prefmod-300 permit 64512:2300 ip community-list standard cm-prefmod-400 permit 64512:2400 ip community-list expanded cme-prefmod-range permit 64512:2... ! ! Informational communities ! ! 3000 - learned from upstream ! 3100 - learned from customer ! 3200 - learned from peer ! ip community-list standard cm-learnt-upstream permit 64512:3000 ip community-list standard cm-learnt-cust permit 64512:3100 ip community-list standard cm-learnt-peer permit 64512:3200 ! ! ################################################################### ! Utility route-maps ! ! These utility route-maps generally should not used to permit/deny ! routes, i.e. they do not have meaning as filters, and hence probably ! should be used with 'on-match next'. These all finish with an empty ! permit entry so as not interfere with processing in the caller. ! route-map rm-no-export permit 10 set community additive no-export route-map rm-no-export permit 20 ! route-map rm-blackhole permit 10 description blackhole, up-pref and ensure it cant escape this AS set ip next-hop 127.0.0.1 set local-preference 10 set community additive no-export route-map rm-blackhole permit 20 ! ! Set local-pref as requested route-map rm-prefmod permit 10 match community cm-prefmod-100 set local-preference 100 route-map rm-prefmod permit 20 match community cm-prefmod-200 set local-preference 200 route-map rm-prefmod permit 30 match community cm-prefmod-300 set local-preference 300 route-map rm-prefmod permit 40 match community cm-prefmod-400 set local-preference 400 route-map rm-prefmod permit 50 ! ! Community actions to take on receipt of route. route-map rm-community-in permit 10 description check for blackholing, no point continuing if it matches. match community cm-blackhole call rm-blackhole route-map rm-community-in permit 20 match community cm-set-no-export call rm-no-export on-match next route-map rm-community-in permit 30 match community cme-prefmod-range call rm-prefmod route-map rm-community-in permit 40 ! ! ##################################################################### ! Community actions to take when advertising a route. ! These are filtering route-maps, ! ! Deny customer routes to upstream with cust-only set. route-map rm-community-filt-to-upstream deny 10 match community cm-learnt-cust match community cm-cust-only route-map rm-community-filt-to-upstream permit 20 ! ! Deny customer routes to other customers with upstream-only set. route-map rm-community-filt-to-cust deny 10 match community cm-learnt-cust match community cm-upstream-only route-map rm-community-filt-to-cust permit 20 ! ! ################################################################### ! The top-level route-maps applied to sessions. Further entries could ! be added obviously.. ! ! Customers route-map rm-cust-in permit 10 call rm-community-in on-match next route-map rm-cust-in permit 20 set community additive 64512:3100 route-map rm-cust-in permit 30 ! route-map rm-cust-out permit 10 call rm-community-filt-to-cust on-match next route-map rm-cust-out permit 20 ! ! Upstream transit ASes route-map rm-upstream-out permit 10 description filter customer prefixes which are marked cust-only call rm-community-filt-to-upstream on-match next route-map rm-upstream-out permit 20 description only customer routes are provided to upstreams/peers match community cm-learnt-cust ! ! Peer ASes ! outbound policy is same as for upstream route-map rm-peer-out permit 10 call rm-upstream-out ! route-map rm-peer-in permit 10 set community additive 64512:3200 @end example