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A.18.4.3 Specifying the Destination

As mentioned above, the syntax of the export statement varies depending on the protocol it is being applied to. One thing that applies in all cases is the specification of a metric. All protocols define a default metric to be used for routes being exported, in most cases this can be overridden at several levels of the export statement.

The specification of the source of the routing information being exported (the export_list ) is described below.

Exporting to EGP and BGP


export proto bgp | egp as autonomous system
    restrict ; 
export proto bgp | egp as autonomous system [ aspath-opt ] 
    [ metric metric ] { 
    export_list ; 
} ; 

Exportation to EGP and BGP is controlled by an autonomous system. The same policy is applied to all routers in the AS. EGP metrics range from 0 to 255 inclusive, with zero being the most attractive.

BGP metrics are 16 bit unsigned quantities; that is, they range from 0 to 65535 inclusive with 0 being the most attractive. While BGP version 4 actually supports 32 bit unsigned quantities, GATED does not yet support this. In BGP version 4, the metric is otherwise known as the Multi-Exit Discriminator, or MED.

In BGP, the aspath-opt option may be used to send the BGP community attribute. Any communities specified with the aspath-opt option are sent in addition to any received with the route or specified in the group statement.

If no export policy is specified, only routes to attached interfaces will be exported. If any policy is specified the defaults are overridden; it is necessary to explicitly specify everything that should be exported.

Note that EGP and BGP versions 2 and 3 only support the propagation of natural networks, so the host and default route filters are meaningless. BGP version 4 supports the propagation of any destination along with a contiguous network mask.

Exporting to RIP


 
export proto rip 
    [ ( interface interface_list ) | (gateway gateway_list ) ] 
    restrict ; 
export proto rip 
    [ ( interface interface_list ) | (gateway gateway_list ) ] 
    [ metric metric ] { 
    export_list ; 
} ;                        

Exportation to RIP is controlled by any of protocol, interface or gateway. If more than one is specified, they are processed from most general (protocol) to most specific (gateway).

It is not possible to set metrics for exporting RIP routes into RIP. Attempts to do this are silently ignored.

If no export policy is specified, RIP and interface routes are exported into RIP. If any policy is specified, the defaults are overridden; it is necessary to explicitly specify everything that should be exported in the export_list .

When exporting routes from other protocols, it is important to specify a metric on the export statement or in the route filters. Unless this is done, the value specified in defaultmetric is used. If not specified, the defaultmetric value is 16 (unreachable). It is likely that this is not the desired result.

RIP version 1 assumes that all subnets of the shared network have the same subnet mask so they are only able to propagate subnets of that network. RIP version 2 removes that restriction and is capable of propagating all routes when not sending version 1 compatible updates.

To announce routes which specify a next hop of the loopback interface (that is, static and internally generated default routes) via RIP, it is necessary to specify the metric at some level in the export clause. Just setting a default metric for RIP is not sufficient. This is a safeguard to verify that the announcement is intended.

Exporting to OSPF


 
export proto osfpase [ type 1 | 2 ] [ tag ospf_tag ] 
    restrict ; 
export proto osfpase [ type 1 | 2 ] [ tag ospf_tag ] 
    [ metric metric ] { 
    export_list ; 
} ;                        
 

It is not possible to create OSPF intra- or interarea routes by exporting routes from the GATED routing table into OSPF. It is only possible to export from the GATED routing table into OSPF ASE routes. It is also not possible to control the propagation of OSPF routes within the OSPF protocol.

There are two types of OSPF ASE routes, type 1 and type 2. The default type is specified by the defaults subclause of the ospf clause. This may be overridden by a specification on the export statement.

OSPF ASE routes also have the provision to carry a tag. This is an arbitrary 32 bit number that can be used on OSPF routers to filter routing information. The default tag specified by the OSPF defaults clause may be overridden by a tag specified on the export statement.

A.18.5 Specifying the Source

The export list specifies export based on the origin of a route and the syntax varies depending on the source.

Exporting BGP and EGP Routes


 
proto bgp | egp autonomoussystem autonomous_system
    restrict ; 
proto bgp | egp autonomoussystem autonomous_system
    [ metric metric ] { 
    route_filter [ restrict | ( metric metric ) ] ; 
} ; 

BGP and EGP routes may be specified as the source autonomous system. All routes may be exported by AS path.

Exporting RIP Routes


 
proto rip 
    [ ( interface interface_list ) | (gateway gateway_list ) ] 
    restrict ; 
proto rip 
    [ ( interface interface_list ) | (gateway gateway_list ) ] 
    [ metric metric ] { 
    route_filter [ restrict | ( metric metric ) ] ; 
} ; 

RIP routes may be exported by protocol, source interface, or source gateway.

Exporting OSPF Routes


 
proto ospf | ospfase restrict ; 
proto ospf | ospfase [ metric metric ] { 
    route_filter [ restrict | ( metric metric ) ] ; 
} ; 
 

Both OSPF, and OSPF ASE routes may be exported into other protocols.

Exporting Routes from Nonrouting Protocols


 
Non-routing with interface 
 
proto direct | static | kernel 
    [ (interface interface_list ) ] 
    restrict ; 
proto direct | static | kernel 
    [ (interface interface_list ) ] 
    [ metric metric ] { 
    route_filter [ restrict | ( metric metric ) ] ; 
} ; 

These protocols may be exported by protocol, or by the interface of the next hop. These protocols are:

Nonrouting by Protocol


 
proto default | aggregate 
    restrict ; 
proto default | aggregate 
    [ metric metric ] { 
    route_filter [ restrict | ( metric metric ) ] ; 
} ; 
 

These protocols can only be referenced by protocol.

Exporting by AS Path


 
proto proto | all aspath aspath_regexp
    origin any | ( [ igp ] [egp ] [ incomplete ] ) 
    restrict ; 
proto proto | all aspath aspath_regexp
    origin any | ( [ igp ] [egp ] [ incomplete ] ) 
    [ metric metric ] { 
    route_filter [ restrict | ( metric metric ) ] ; 
} ; 

When BGP is configured, all routes are assigned an AS path when they are added to the routing table. For all interior routes, this AS path specifies IGP as the origin and no AS in the AS path; the current AS is added when the route is exported. For EGP routes, this AS path specifies EGP as the origin and the source AS as the AS path. For BGP routes, the AS path is stored as learned from BGP.

AS path regular expressions are described in Section A.18.2.

Exporting by Route Tag


 
proto proto | all tag tag restrict ; 
proto proto | all tag tag 
    [ metric metric ] { 
    route_filter [ restrict | ( metric metric ) ] ; 
} ; 
 

Both OSPF and RIP version 2 currently support tags, all other protocols always have a tag of zero. The source of exported routes may be selected based on this tag. This is useful when routes are classified by tag when they are exported into a given routing protocol.

A.18.6 Route Aggregation

Route aggregation is a method of generating a more general route given the presence of a specific route. It is used, for example, at an autonomous system border to generate a route to a network to be advertised using EGP, if one or more subnets of that network have been learned using RIP. Older versions of GATED automatically performed this function, generating an aggregate route to a natural network (using the old Class A, B and C concept), if there is an interface to a subnet of that natural network. However, that was not always the correct thing to do, and, with the advent of classless interdomain routing it is even more frequently the wrong thing to do. Therefore, aggregation must be explicitly configured. No aggregation is performed unless explicitly requested in an aggregate statement.

Route aggregation is also used by regional and national networks to reduce the amount of routing information passed around. With careful allocation of network addresses to clients, regional networks can just announce one route to regional networks instead of hundreds.

Aggregate routes are not actually used for packet forwarding by the originator of the aggregate route; they are used only by the receiver, if it wishes. A router receiving a packet that does not match one of the component routes that led to the generation of an aggregate route is supposed to respond with an ICMP network unreachable message. This is to prevent packets for unknown component routes from following a default route into another network where they would be forwarded back to the border router, and around and around again and again, until their TTL expires. Sending an unreachable message for a missing piece of an aggregate is only possible on systems with support for reject routes.

A slight variation of aggregation is the generation of a route based on the existence of certain conditions. This is sometimes known as the route of last resort. This route inherits the next hops and AS path from the contributor specified with the lowest (most favorable) preference. The most common usage for this is to generate a default based on the presence of a route from a peer on a neighboring backbone.

A.18.6.1 Aggregation and Generation Syntax

The syntax of the aggregate and generation statements are as follows:


 
aggregate default 
    | ( network [ ( mask mask ) | ( masklen number ) ] ) 
    [ preference preference ] [ brief ] { 
    proto [ all | direct | static | kernel | aggregate | proto ] 
        [ ( as autonomous system ) | ( tag tag ) 
            | ( aspath aspath_regexp ) ] 
        restrict ; 
    proto [ all | direct | static | kernel | aggregate | proto ] 
        [ ( as autonomous system ) | ( tag tag ) 
            | ( aspath aspath_regexp ) ] 
        [ preference preference ] { 
        route_filter [ restrict | ( preference preference ) ] ; 
    } ; 
} ; 
 
generate dffault 
| ( network [ ( mask mask ) | ( masklen ) 
    [ preference preference ] [ brief ] { 
    proto [ all | direct | static | kernel | aggregate | 
proto ] 
        [ ( as autonomous system ) | ( tag tag 
) 
            | ( aspath aspath_regexp ) ] 
        restrict ; 
    proto [ all | direct | static | kernel | aggregate | 
proto ] 
        [ ( as autonomous system ) | ( tag tag 
) 
            | ( aspath aspath_regexp ) ] 
        [ preference preference ] { 
        route_filter [ restrict | ( preference preference ) ]; 
    } ; 
} ; 
 

Routes that match the route filters are called contributing routes. They are ordered according to the aggregation preference that applies to them. If there are more than one contributing routes with the same aggregating preference, the route's own preferences are used to order the routes. The preference of the aggregate route will be that of contributing route with the lowest aggregate preference.

A route may only contribute to an aggregate route which is more general than itself; it must match the aggregate under its mask. Any given route may only contribute to one aggregate route, which will be the most specific configured, but an aggregate route may contribute to a more general aggregate.

Route Filters

All the formats allow route filters as shown below. See Section A.18.4.2 for a detailed explaination of how they work. When no route filtering is specified (that is, when restrict is specified on the first line of a statement), all routes from the specified source will match that statement. If any filters are specified, only routes that match the specified filters will be considered as contributors. That is, if any filters are specified, an all restrict ; statement is assumed at the end of the list.


network [exact | refines | between number and number ] 
network mask mask [exact | refines | between number and number ] 
network masklen number [ exact | refines | between number and number ] ] 
default 
host host

A.19 Sample Host Configurations

The configuration file for end systems is simple, usually containing only two configuration statements.

A.19.1 Sample RIP and EGP Configuration

The following sample enables both an interior (RIP) and an exterior (EGP) protocol and sets certain protocol-specific parameters:


       #  generate a default route if an EGP neighbor is acquired 
       # 
       options gendefault ; 
       # 
       # define the autonomous system number for EGP 
       # 
       autonomoussystem 303 ; 
       # 
       # enable RIP 
       # 
       rip yes ; 
       # 
       # enable EGP with hello interval 1 1/2 minute, poll 
       #  interval 10 minutes, neighbors 26.6.0.103 and 26.20.0.72 
       # 
       egp yes { 
          packetsize 24488 ; 
          group minhello 1:30 minpoll 10:00 { 
              neighbor 26.6.0.103 ; 
              neighbor 26.20.0.72 ; 
          } ; 
       } ; 
       # 
       # announce 136.66 to AS 183 
       # 
       export proto egp as 183 { 
          proto direct { 
          136.66 metric 0 ; 
          } ; 
       } ; 
       # 
       # announce default through  RIP with a metric of 3 
       # 
       export proto rip interface 136.66.12.1 { 
        proto default { 
        announce 0.0.0.0 metric 3 ; 
        } ; 
       } ; 
 

The AS number 303 is defined early because it is a definition statement and must occur before the first protocol statement. EGP is enabled by the yes keyword in the EGP statement. This statement also defines the following EGP parameters:

The first export statement directs GATED to use EGP to advertise the network (136.66.0.0) to the Internet. This is the address of the network, not of a gateway. The second export statement is used to announce the default route to subnet 136.66.12.0 with a metric of 3.

A.19.2 Sample BGP and OSPF Configuration

The following sample implements the transformation of distance metrics between the internal (OSPF) and external (BGP) protocols. Autonomous system 1019, of which GATED is a member, contains network 19.0.0.0. The GATED machine has several interfaces into this autonomous system. The GATED daemon is using BGP to peer with AS 2021, neighbor 21.5.1.21.


       # # # # # # # # # # # # # # # # # # # 
       interfaces {options all passive; }; 
       autonomoussystem 1019; 
       routerid 19.1.1.18; 
       rip no; 
       hello no; 
       egp no; 
       bgp yes { 
         preference 50 ; 
         group type 
         External peeras 2021 
         { 
 
           peer 21.5.1.21 
           ; 
         } ; 
         group type 
         IGP peeras 1019 
         { 
 
           peer 19.1.1.19 
           ; 
         } ; 
       } ; 
       ospf yes { 
         area 0.0.0.2 { 
           authtype none; 
           networks { 
             119.0.0.0 mask 255.0.0.0 ; 
           } ; 
           interface 119.2.128.18 
           cost 1 { 
              retransmitinterval 5; 
              transitdelay 1; 
              priority 1; 
              hello interval 10; 
              routerdeadinterval 40; 
           } ; 
           interface 119.4.128.18 
           cost 1 { 
              retransmitinterval 5; 
              transitdelay 1; 
              priority 1; 
              hellointerval 60; 
              routerdeadinterval 180; 
           } ; 
         } ; 
         backbone { 
           authype none; 
           interface 19.1.1.19 
           cost 1 { 
              retransmitinterval 5; 
              transitdelay 1; 
              priority 1; 
              hellointerval 60; 
              routerdeadinterval 180; 
           } ; 
         } ; 
       } ; 
       export proto ospfase type 1 { 
         proto bgp as 2021 { 
           ALL 
           metric 1; }; 
         proto direct { 
           ALL 
           metric 1;  }; 
       } ; 
       export proto bgp as 2021 { 
         proto direct { 
           ALL 
           metric 1; } ; 
         proto ospfase { 
           ALL 
           metric 1; } ; 
       } ; 

In this example, two autonomous systems (one internal, one external) are directly connected through a router that is attached to a backbone speaking OSPF. The AS number 1019 is defined early, because it is a definition statement that occurs again in the first protocol statement, which enables BGP. The first export statement directs GATED to advertise routes from the internal group AS 1019. The group AS 1019 is running OSPF as its interior gateway protocol and is running BGP as its exterior routing protocol to route information to the external group AS 2021.

Routes to two local Ethernets in AS 1019, identified as 119.2.128.18 and 119.4.128.18 (119.0.0.0 mask 255.0.0.0), are advertised along with the OSPF backbone (19.1.1.19). The parameters for AS path, path origin, and transitive optional attributes, including transmission intervals, are defined. The second export statement announces the default route to AS 2021 with a metric of 1.


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