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Merge commit '4f2aa1319c1ff80939c656bba7d529d84d1af350' into mq-merge-step-2

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Maria Matejka 2024-01-26 23:26:08 +01:00
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@ -431,7 +431,7 @@ mixed together, or particular paths for specific flows could be defined. Another
advantage is that MPLS forwarding by internal routers can be much simpler than advantage is that MPLS forwarding by internal routers can be much simpler than
IP forwarding, as instead of the longest prefix match algorithm it uses simpler IP forwarding, as instead of the longest prefix match algorithm it uses simpler
exact match for MPLS route selection. The disadvantage is additional complexity exact match for MPLS route selection. The disadvantage is additional complexity
in signalling. For further details, see <rfc id="3031">. in signaling. For further details, see <rfc id="3031">.
MPLS-aware routing protocols not only distribute IP routing information, but MPLS-aware routing protocols not only distribute IP routing information, but
they also distribute labels. Therefore, they produce labeled routes - routes they also distribute labels. Therefore, they produce labeled routes - routes
@ -1019,7 +1019,7 @@ inherited from templates can be updated by new definitions.
<tag><label id="proto-export">export <m/filter/</tag> <tag><label id="proto-export">export <m/filter/</tag>
This is similar to the <cf>import</cf> keyword, except that it works in This is similar to the <cf>import</cf> keyword, except that it works in
the direction from the routing table to the protocol. Default: <cf/none/ the direction from the routing table to the protocol. Default: <cf/none/
(except for EBGP). (except for EBGP and L3VPN).
<tag><label id="proto-import-keep-filtered">import keep filtered <m/switch/</tag> <tag><label id="proto-import-keep-filtered">import keep filtered <m/switch/</tag>
Usually, if an import filter rejects a route, the route is forgotten. Usually, if an import filter rejects a route, the route is forgotten.
@ -3917,7 +3917,7 @@ protocol kernel {
<p><code> <p><code>
protocol kernel { # Primary routing table protocol kernel { # Primary routing table
learn; # Learn alien routes from the kernel learn; # Learn alien routes from the kernel
persist; # Don't remove routes on bird shutdown persist; # Do not remove routes on bird shutdown
scan time 10; # Scan kernel routing table every 10 seconds scan time 10; # Scan kernel routing table every 10 seconds
ipv4 { ipv4 {
import all; import all;
@ -3935,6 +3935,138 @@ protocol kernel { # Secondary routing table
</code> </code>
<sect>L3VPN
<label id="l3vpn">
<sect1>Introduction
<label id="l3vpn-intro">
<p>The L3VPN protocol serves as a translator between IP routes and VPN
routes. It is a component for BGP/MPLS IP VPNs (<rfc id="4364">) and implements
policies defined there. In import direction (VPN -&gt; IP), VPN routes matching
import target specification are stripped of route distinguisher and MPLS labels
and announced as IP routes, In export direction (IP -&gt; VPN), IP routes are
expanded with specific route distinguisher, export target communities and MPLS
label and announced as labeled VPN routes. Unlike the Pipe protocol, the L3VPN
protocol propagates just the best route for each network.
<p>In BGP/MPLS IP VPNs, route distribution is controlled by Route Targets (RT).
VRFs are associated with one or more RTs. Routes are also associated with one or
more RTs, which are encoded as route target extended communities
in <ref id="rta-bgp-ext-community" name="bgp_ext_community">. A route is then
imported into each VRF that shares an associated Route Target. The L3VPN
protocol implements this mechanism through mandatory <cf/import target/ and
<cf/export target/ protocol options.
<sect1>Configuration
<label id="l3vpn-config">
<p>L3VPN configuration consists of a few mandatory options and multiple channel
definitions. For convenience, the default export filter in L3VPN channels is
<cf/all/, as the primary way to control import and export of routes is through
protocol options <cf/import target/ and <cf/export target/. If custom filters
are used, note that the export filter of the input channel is applied before
the route translation, while the import filter of the output channel is applied
after that.
<p>In contrast to the Pipe protocol, the L3VPN protocol can handle both IPv4 and
IPv6 routes in one instance, also both IP side and VPN side are represented as
separate channels, although that may change in the future. The L3VPN is always
MPLS-aware protocol, therefore a MPLS channel is mandatory. Altogether, L3VPN
could have up to 5 channels: <cf/ipv4/, <cf/ipv6/, <cf/vpn4/, <cf/vpn6/, and
<cf/mpls/.
<p><descrip>
<tag><label id="l3vpn-route-distinguisher">route distinguisher <m/vpn-rd/</tag>
<tag><label id="l3vpn-rd">rd <m/vpn-rd/</tag>
The route distinguisher that is attached to routes in the export
direction. Mandatory.
<tag><label id="l3vpn-import-target">import target <m/ec/|<m/ec-set/</tag>
Route target extended communities specifying which routes should be
imported. Either one community or a set. A route is imported if there is
non-empty intersection between extended communities of the route and the
import target of the L3VPN protocol. Mandatory.
<tag><label id="l3vpn-export-target">export target <m/ec/|<m/ec-set/</tag>
Route target extended communities that are attached to the route in the
export direction. Either one community or a set. Other route target
extended communities are removed. Mandatory.
<tag><label id="l3vpn-route-target">route target <m/ec/|<m/ec-set/</tag>
A shorthand for both <cf/import target/ and <cf/export target/.
</descrip>
<sect1>Attributes
<label id="l3vpn-attr">
<p>The L3VPN protocol does not define any route attributes.
<sect1>Example
<label id="l3vpn-exam">
<p>Here is an example of L3VPN setup with one VPN and BGP uplink. IP routes
learned from a customer in the VPN are stored in <cf/vrf0vX/ tables, which are
mapped to kernel VRF vrf0. Routes can also be exchanged through BGP with
different sites hosting that VPN. Forwarding of VPN traffic through the network
is handled by MPLS.
<p>Omitted from the example are some routing protocol to exchange routes with
the customer and some sort of MPLS-aware IGP to resolve next hops for BGP VPN
routes.
<code>
# MPLS basics
mpls domain mdom;
mpls table mtab;
protocol kernel krt_mpls {
mpls { table mtab; export all; };
}
vpn4 table vpntab4;
vpn6 table vpntab6;
# Exchange VPN routes through BGP
protocol bgp {
vpn4 { table vpntab4; import all; export all; };
vpn6 { table vpntab6; import all; export all; };
mpls { label policy aggregate; };
local 10.0.0.1 as 10;
neighbor 10.0.0.2 as 10;
}
# VRF 0
ipv4 table vrf0v4;
ipv6 table vrf0v6;
protocol kernel kernel0v4 {
vrf "vrf0";
ipv4 { table vrf0v4; export all; };
kernel table 100;
}
protocol kernel kernel0v6 {
vrf "vrf0";
ipv6 { table vrf0v6; export all; };
kernel table 100;
}
protocol l3vpn l3vpn0 {
vrf "vrf0";
ipv4 { table vrf0v4; };
ipv6 { table vrf0v6; };
vpn4 { table vpntab4; };
vpn6 { table vpntab6; };
mpls { label policy vrf; };
rd 10:12;
import target [(rt, 10, 32..40)];
export target [(rt, 10, 30), (rt, 10, 31)];
}
</code>
<sect>MRT <sect>MRT
<label id="mrt"> <label id="mrt">