When kube-router is used to provide pod-to-pod networking, BGP is used to exchange routes across the nodes. Kube-router provides flexible networking models to support different deployments (public vs private cloud, routable vs non-routable pod IP's, service ip's etc).
This is the default mode. All nodes in the clusters form iBGP peering
relationship with rest of the nodes forming full node-to-node mesh. Each node
advertise the pod CIDR allocated to the nodes with peers (rest of the nodes in
the cluster). There is no configuration required in this mode. All the nodes in
the cluster are associated with private ASN 64512 implicitly (which can be
configured with --cluster-asn flag). Users are transparent to use of iBGP.
This mode is suitable in public cloud environments or small cluster deployments.
This model support more than a single AS per cluster to allow AS per rack or AS
per node models. Nodes in the cluster does not form full node-to-node mesh.
Users has to explicitly select this mode by specifying --nodes-full-mesh=false
when launching kube-router. In this mode kube-router expects each node is
configured with an ASN number from the node's API object annonations. Kube-router
will use the node's kube-router.io/node.asn annotation value as the ASN
number for the node.
Users can annotate node objects with the following command:
kubectl annotate node <kube-node> "kube-router.io/node.asn=64512"
Only nodes with in same ASN form full mesh. Two nodes with different ASNs never get peered.
This model support the common scheme of using Route Reflector Server node to concentrate
peering from Client Peer. This has the big advantage of not needing full mesh, and
scale better. In this mode kube-router expects each node is configured either in
Route Reflector server mode or in Route Reflector client mode. This is done
with node kube-router.io/rr.server=ClusterID, kube-router.io/rr.client=ClusterId
respectively. In this mode each Route Reflector Client will only peer with Route
Reflector Servers. Each Route Reflector Server will peer other Route Reflector
Server and with Route Reflector Clients enabling reflection.
Users can annotate node objects with the following command:
kubectl annotate node <kube-node> "kube-router.io/rr.server=42"
for Route Reflector server mode, and
kubectl annotate node <kube-node> "kube-router.io/rr.client=42"
for Route Reflector client mode.
Only nodes with the same ClusterID in client and server mode will peer together.
When joining new nodes to the cluster, remember to annotate them with kube-router.io/rr.client=42, and then restart kube-router on the new nodes and the route reflector server nodes to let them successfully read the annotations and peer with each other.
An optional global BGP peer can be configured by specifying --peer-router-asns
and --peer-router-ips parameters. When configured each node in the cluster
forms a peer relationship with specified global peer. Pod CIDR and Cluster IP's
get advertised to the global BGP peer. For redundancy you can also configure
more than one peer router by specifying a slice of BGP peers.
For example:
--peer-router-ips="192.168.1.99,192.168.1.100"
--peer-router-asns=65000,65000
Alternatively, each node can be configured with one or more node specific BGP peers. Information regarding node specific BGP peer is read from node API object annotations:
kube-router.io/peer.ipskube-router.io/peer.asns
For e.g users can annotate node object with below commands
kubectl annotate node <kube-node> "kube-router.io/peer.ips=192.168.1.99,192.168.1.100"
kubectl annotate node <kube-node> "kube-router.io/peer.asns=65000,65000"
For traffic shaping purposes, you may want to prepend the AS path announced to peers. This can be accomplished on a per-node basis with annotations:
kube-router.io/path-prepend.askube-router.io/path-prepend.repeat-n
If you wanted to prepend all routes from a particular node with the AS 65000 five times, you would run the following commands:
kubectl annotate node <kube-node> "kube-router.io/path-prepend.as=65000"
kubectl annotate node <kube-node> "kube-router.io/path-prepend.repeat-n=5"
The examples above have assumed there is no password authentication with BGP
peer routers. If you need to use a password for peering, you can use the
--peer-router-passwords command-line option, the kube-router.io/peer.passwords node
annotation, or the --peer-router-passwords-file command-line option.
To ensure passwords are easily parsed, but not easily read by human eyes, kube-router requires that they are encoded as base64.
On a Linux or MacOS system you can encode your passwords on the command line:
$ printf "SecurePassword" | base64
U2VjdXJlUGFzc3dvcmQ=
In this CLI flag example the first router (192.168.1.99) uses a password, while the second (192.168.1.100) does not.
--peer-router-ips="192.168.1.99,192.168.1.100"
--peer-router-asns="65000,65000"
--peer-router-passwords="U2VjdXJlUGFzc3dvcmQK,"
Note the comma indicating the end of the first password.
Now here's the same example but configured as node annotations:
kubectl annotate node <kube-node> "kube-router.io/peer.ips=192.168.1.99,192.168.1.100"
kubectl annotate node <kube-node> "kube-router.io/peer.asns=65000,65000"
kubectl annotate node <kube-node> "kube-router.io/peer.passwords=U2VjdXJlUGFzc3dvcmQK,"
Finally, to include peer passwords as a file you would run kube-router with the following option:
--peer-router-ips="192.168.1.99,192.168.1.100"
--peer-router-asns="65000,65000"
--peer-router-passwords-file="/etc/kube-router/bgp-passwords.conf"
The password file, closely follows the syntax of the command-line and node annotation options. Here, the first peer IP (192.168.1.99) would be configured with a password, while the second would not.
U2VjdXJlUGFzc3dvcmQK,
Note, complex parsing is not done on this file, please do not include any content other than the passwords on a single line in this file.
Global peers support the addition of BGP communities via node annotations. Node annotations can be formulated either as:
- a single 32-bit integer
- two 16-bit integers separated by a colon (
:) - common BGP community names (e.g.
no-export,internet,no-peer, etc.) (see: WellKnownCommunityNameMap)
In the following example we add the NO_EXPORT BGP community to two of our nodes via annotation using all three forms of the annotation:
kubectl annotate node <kube-node> "kube-router.io/node.bgp.communities=4294967041"
kubectl annotate node <kube-node> "kube-router.io/node.bgp.communities=65535:65281"
kubectl annotate node <kube-node> "kube-router.io/node.bgp.communities=no-export"
By default, GoBGP server binds on the node IP address. However in case of nodes with multiple IP address it is desirable to bind GoBGP to multiple local adresses. Local IP address on which GoGBP should listen on a node can be configured with annotation kube-router.io/bgp-local-addresses.
Here is sample example to make GoBGP server to listen on multiple IP address
kubectl annotate node ip-172-20-46-87.us-west-2.compute.internal "kube-router.io/bgp-local-addresses=172.20.56.25,192.168.1.99"
By default kube-router populates GoBGP RIB with node IP as next hop for the advertised pod CIDR's and service VIP. While this works for most cases, overriding the next hop for the advertised rotues is necessary when node has multiple interfaces over which external peers are reached. Next hop need to be as per the interface local IP over which external peer can be reached. --override-nexthop let you override the next hop for the advertised route. Setting --override-nexthop to true leverages BGP next-hop-self functionality implemented in GoBGP. Next hop will automatically selected appropriately when advertising routes irrespective of the next hop in the RIB.
A common scenario exists where each node in the cluster is connected to two upstream routers that are in two different subnets. For example, one router is connected to a public network subnet and the other router is connected to a private network subnet. Additionally, nodes may be split across different subnets (e.g. different racks) each of which has their own routers.
In this scenario, --override-nexthop can be used to correctly peer with each upstream router, ensuring that the BGP next-hop attribute is correctly set to the node's IP address that faces the upstream router. The --enable-overlay option can be set to allow overlay/underlay tunneling across the different subnets to achieve an interconnected pod network.
This configuration would have the following effects:
- Peering Outside the Cluster (https://github.com/cloudnativelabs/kube-router/blob/master/docs/bgp.md#peering-outside-the-cluster) via one of the many means that kube-router makes that option available
- Overriding Next Hop
- Enabling overlays in either full mode or with nodes in different subnets
The warning here is that when using --override-nexthop in the above scenario, it may cause kube-router to advertise an IP address other than the node IP which is what kube-router connects the tunnel to when the --enable-overlay option is given. If this happens it may cause some network flows to become un-routable.
Specifically, people need to take care when combining --override-nexthop and --enable-overlay and make sure that they understand their network, the flows they desire, how the kube-router logic works, and the possible side-effects that are created from their configuration. Please refer to this PR for the risk and impact discussion cloudnativelabs#1025.