English
Finally, the last type of peering relationship is the `sibling`. Such a relationship is used when two domains exchange all their routes in both directions. In practice, such a relationship is only used between domains that belong to the same company.
These different types of relationships are implemented in the `interdomain routing policies` defined by each domain. The `interdomain routing policy` of a domain is composed of three main parts :
the `import filter` that specifies, for each peering relationship, the routes that can be accepted from the neighboring domain (the non-acceptable routes are ignored and the domain never uses them to forward packets)
the `export filter` that specifies, for each peering relationship, the routes that can be advertised to the neighboring domain
the `ranking` algorithm that is used to select the best route among all the routes that the domain has received towards the same destination prefix
A domain's import and export filters can be defined by using the Route Policy Specification Language (RPSL) specified in :rfc:`2622` [GAVE1999]_ . Some Internet Service Providers, notably in Europe, use RPSL to document [#fripedb]_ their import and export policies. Several tools help to easily convert a RPSL policy into router commands.
The figure below provides a simple example of import and export filters for two domains in a simple internetwork. In RPSL, the keyword `ANY` is used to replace any route from any domain. It is typically used by a provider to indicate that it announces all its routes to a customer over a `provider->customer` relationship. This is the case for `AS4`'s export policy. The example below clearly shows the difference between a `provider->customer` and a `shared-cost` peering relationship. `AS4`'s export filter indicates that it announces only its internal routes (`AS4`) and the routes learned from its clients (`AS7`) over its `shared-cost` peering with `AS3`, while it advertises all the routes that it uses (including the routes learned from `AS3`) to `AS7`.
Import and export policies
The Border Gateway Protocol
The Internet uses a single interdomain routing protocol : the Border Gateway Protocol (BGP). The current version of BGP is defined in :rfc:`4271`. BGP differs from the intradomain routing protocols that we have already discussed in several ways. First, BGP is a `path-vector` protocol. When a BGP router advertises a route towards a prefix, it announces the IP prefix and the interdomain path used to reach this prefix. From BGP's point of view, each domain is identified by a unique `Autonomous System` (AS) number [#fasdomain]_ and the interdomain path contains the AS numbers of the transit domains that are used to reach the associated prefix. This interdomain path is called the `AS Path`. Thanks to these AS-Paths, BGP does not suffer from the count-to-infinity problems that affect distance vector routing protocols. Furthermore, the AS-Path can be used to implement some routing policies. Another difference between BGP and the intradomain routing protocols is that a BGP router does not send the entire contents of its routing table to its neighbors regularly. Given the size of the global Internet, routers would be overloaded by the number of BGP messages that they would need to process. BGP uses incremental updates, i.e. it only announces the routes that have changed to its neighbors.
The figure below shows a simple example of the BGP routes that are exchanged between domains. In this example, prefix `2001:db8:cafe::/48` is announced by `AS1`. `AS1` advertises a BGP route towards this prefix to `AS2`. The AS-Path of this route indicates that `AS1` is the originator of the prefix. When `AS4` receives the BGP route from `AS1`, it re-announces it to `AS2` and adds its AS number to the AS-Path. `AS2` has learned two routes towards prefix `2001:db8:cafe::/48`. It compares the two routes and prefers the route learned from `AS4` based on its own ranking algorithm. `AS2` advertises to `AS5` a route towards `2001:db8:cafe::/48` with its AS-Path set to `AS2:AS4:AS1`. Thanks to the AS-Path, `AS5` knows that if it sends a packet towards `2001:db8:cafe::/48` the packet first passes through `AS2`, then through `AS4` before reaching its destination inside `AS1`.
Simple exchange of BGP routes
BGP routers exchange routes over BGP sessions. A BGP session is established between two routers belonging to two different domains that are directly connected. As explained earlier, the physical connection between the two routers can be implemented as a private peering link or over an Internet eXchange Point. A BGP session between two adjacent routers runs above a TCP connection (the default BGP port is 179). In contrast with intradomain routing protocols that exchange IP packets or UDP segments, BGP runs above TCP because TCP ensures a reliable delivery of the BGP messages sent by each router without forcing the routers to implement acknowledgments, checksums, etc. Furthermore, the two routers consider the peering link to be up as long as the BGP session and the underlying TCP connection remain up [#flifetimebgp]_. The two endpoints of a BGP session are called `BGP peers`.
A BGP peering session between two directly connected routers
In practice, to establish a BGP session between routers `R1` and `R2` in the figure above, the network administrator of `AS3` must first configure on `R1` the IP address of `R2` on the `R1-R2` link and the AS number of `R2`. Router `R1` then regularly tries to establish the BGP session with `R2`. `R2` only agrees to establish the BGP session with `R1` once it has been configured with the IP address of `R1` and its AS number. For security reasons, a router never establishes a BGP session that has not been manually configured on the router.
The BGP protocol :rfc:`4271` defines several types of messages that can be exchanged over a BGP session :
`OPEN` : this message is sent as soon as the TCP connection between the two routers has been established. It initializes the BGP session and allows the negotiation of some options. Details about this message may be found in :rfc:`4271`.
`NOTIFICATION` : this message is used to terminate a BGP session, usually because an error has been detected by the BGP peer. A router that sends or receives a `NOTIFICATION` message immediately shutdowns the corresponding BGP session.
`UPDATE`: this message is used to advertise new or modified routes or to withdraw previously advertised routes.
`KEEPALIVE` : this message is used to ensure a regular exchange of messages on the BGP session, even when no route changes. When a BGP router has not sent an `UPDATE` message during the last 30 seconds, it shall send a `KEEPALIVE` message to confirm to the other peer that it is still up. If a peer does not receive any BGP message during a period of 90 seconds [#fdefaultkeepalive]_, the BGP session is considered to be down and all the routes learned over this session are withdrawn.