This document describes how to set up and use bundled load balancers with Border
Gateway Protocol (BGP) for Google Distributed Cloud. This load-balancing mode
supports the advertisement of ServiceType
LoadBalancer
virtual IP addresses
(VIPs) through external Border Gateway Protocol (eBGP) for your clusters. In
this scenario, your cluster network is an autonomous system, which interconnects
with another autonomous system, an external network, through peering.
The bundled load balancers with BGP capability apply to all cluster types, but admin clusters only support the control plane load-balancing part of this capability.
Using the bundled load balancers with BGP feature provides the following benefits:
- Uses N-way active/active load-balancing capability, providing faster failover and more efficient use of available bandwidth.
- Supports Layer 3 protocol that operates with third-party top-of-rack (ToR) switches and routers that are compatible with eBGP.
- Enables data centers that are running an advanced software-defined networking (SDN) stack to push the Layer 3 boundary all the way to the clusters.
How bundled load balancing with BGP works
The following sections provide a quick summary of how bundled load balancers with BGP work.
BGP peering
The bundled load balancers with BGP feature starts several BGP connections to your infrastructure. BGP has the following technical requirements:
- Peering sessions are separate for control plane VIP and for service VIPs.
- Control plane peering sessions are initiated from the IP addresses of the control plane nodes.
- Service peering sessions are initiated from floating IP addresses that you
specify in the
NetworkGatewayGroup
custom resource. - Anthos Network Gateway controller manages the floating IP addresses.
- Bundled BGP-based load balancing supports eBGP peering only.
- Multi-hop peering is supported by default.
- MD5 passwords on BGP sessions are not supported.
- IPv6-based peering sessions are not supported.
- Routes advertised to any peer are expected to be redistributed throughout the network and reachable from anywhere else in the cluster.
- Use of BGP
ADD-PATH
capability in receive mode is recommended for peering sessions. - Advertising multiple paths from each peer results in active/active load balancing.
- Equal-cost multipath routing (ECMP) should be enabled for your network so that multiple paths can be used to spread traffic across a set of load balancer nodes.
Control plane load balancing
Each control plane node in your cluster establishes BGP sessions with one or more peers in your infrastructure. We require that each control plane node has at least one peer. In the cluster configuration file, you can configure which control plane nodes connect to which external peers.
The following diagram shows an example of control plane peering. The cluster has two control plane nodes in one subnet and one in another. There is an external peer (TOR) in each subnet and the Google Distributed Cloud control plane nodes peer with their TOR.
Service load balancing
In addition to the peering sessions that are initiated from each control plane
node for the control plane peering, additional peering sessions are initiated
for LoadBalancer
Services. These peering sessions are not initiated from
cluster node IP addresses directly, but use floating IP addresses instead.
Services with an externalTrafficPolicy=Local
network policy are not supported.
Floating IP addresses
Service load balancing requires you to reserve floating IP addresses in the
cluster node subnets to use for BGP peering. At least one floating IP address is
required for the cluster, but we recommend you reserve at least two addresses to
ensure high availability for BGP sessions. The floating IP addresses are
specified in the NetworkGatewayGroup
custom resource (CR), which can be
included in the cluster configuration file.
Floating IP addresses remove the worry about mapping BGP speaker IP addresses to
nodes. The Anthos Network Gateway controller takes care of assigning the
NetworkGatewayGroup
to nodes and also manages the floating IP addresses. If a
node goes down, the Anthos Network Gateway controller reassigns floating IP
addresses to ensure that external peers have a deterministic IP address to peer
with.
External peers
For data plane load balancing, you can use the same external peers that were
specified for control plane peering in the loadBalancer.controlPlaneBGP
section of the cluster configuration file. Alternatively, you can specify
different BGP peers.
If you want to specify different BGP peers for data plane peering, append
BGPLoadBalancer
and BGPPeer
resource specifications to the cluster
configuration file. If you don't specify these custom resources, the control
plane peers are used automatically for the data plane.
You specify the external peers used for peering sessions with the floating IP
addresses in the BGPPeer
custom resource, which you add to the cluster
configuration file. The BGPPeer
resource includes a label for identification
by the corresponding BGPLoadBalancer
custom resource. You specify the matching
label in the peerSelector
field in the BGPLoadBalancer
custom resource to
select the BGPPeer
for use.
The Anthos Network Gateway controller attempts to establish sessions (the number
of sessions is configurable) to each external peer from the set of reserved
floating IP addresses. We recommend that you specify at least two external peers
to ensure high availability for BGP sessions. Each external peer designated for
Services load balancing must be configured to peer with every floating IP
address specified in the NetworkGatewayGroup
custom resource.
Load balancer nodes
A subset of nodes from the cluster is used for load balancing, which means they
are the nodes advertised to be able to accept incoming load-balancing traffic.
This set of nodes defaults to the control plane node pool, but you can specify a
different node pool in the loadBalancer
section of the cluster configuration
file. If you specify a node pool, it is used for the load balancer nodes,
instead of the control plane node pool.
The floating IP addresses, which function as BGP speakers, may or may not run on the load balancer nodes. The floating IP addresses are assigned to a node in the same subnet and peering is initiated from there, regardless of whether it is a load balancer node. However, next hops advertised over BGP are always the load balancer nodes.
Example peering topology
The following diagram shows an example of Service load balancing with BGP peering. There are two floating IP addresses assigned to nodes in their respective subnets. There are two external peers defined. Each floating IP peers with both external peers.
Set up the BGP load balancer
The following sections describe how to configure your clusters and your external network to use the bundled load balancer with BGP.
Plan your integration with external infrastructure
In order to use the bundled load balancer with BGP, you must set up the external infrastructure:
External infrastructure must be configured to peer with each of the control plane nodes in the cluster to set up the control plane communication. These peering sessions are used to advertise the Kubernetes control plane VIPs.
External infrastructure must be configured to peer with a set of reserved floating IP addresses for data plane communication. The floating IP addresses are used for BGP peering for the Service VIPs. We recommend you use two floating IP addresses and two peers to ensure high availability for BGP sessions. The process of reserving floating IP is described as part of configuring your cluster for bundled load balancing with BGP.
When you've configured the infrastructure, add the BGP peering information to the cluster configuration file. The cluster you create can initiate peering sessions with the external infrastructure.
Configure your cluster for bundled load balancing with BGP
You enable and configure bundled load balancing with BGP in the cluster
configuration file when you create a cluster. In the cluster configuration file,
you enable advanced networking and update the loadBalancer
section. You also
append specifications for the following three custom resources:
NetworkGatewayGroup
: specifies floating IP addresses that are used for Services BGP peering sessions.BGPLoadBalancer
: specifies with label selectors which peers are used for BGP load balancing.BGPPeer
: specifies individual peers, including a label for selection purposes, for BGP peering sessions.
The following instructions describe how to configure your cluster and the three custom resources to set up bundled load balancing with BGP.
Add the
advancedNetworking
field to the cluster configuration file in theclusterNetwork
section and set it totrue
.This field enables advanced networking capability, specifically the Network Gateway Group resource.
apiVersion: baremetal.cluster.gke.io/v1 kind: Cluster metadata: name: bm namespace: CLUSTER_NAMESPACE spec: ... clusterNetwork: advancedNetworking: true
Replace
CLUSTER_NAMESPACE
with the namespace for the cluster. By default, the cluster namespaces for Google Distributed Cloud are the name of the cluster prefaced withcluster-
. For example, if you name your clustertest
, the namespace iscluster-test
.In the
loadBalancer
section of the cluster configuration file, setmode
tobundled
and add atype
field with a value ofbgp
.These field values enable BGP-based bundled load balancing.
... loadBalancer: mode: bundled # type can be 'bgp' or 'layer2'. If no type is specified, we default to layer2. type: bgp ...
To specify the BGP-peering information for the control plane, add the following fields to the
loadBalancer
section:... # AS number for the cluster localASN: CLUSTER_ASN # List of BGP peers used for the control plane peering sessions. bgpPeers: - ip: PEER_IP asn: PEER_ASN # optional; if not specified, all CP nodes connect to all peers. controlPlaneNodes: # optional - CP_NODE_IP ...
Replace the following:
CLUSTER_ASN
: the autonomous system number for the cluster being created.PEER_IP
: the IP address of the external peer device.PEER_ASN
: the autonomous system number for the network that contains the external peer device.CP_NODE_IP
: (optional) the IP address of the control plane node that connects to the external peer. If you don't specify any control plane nodes, all control plane nodes can connect to the external peer. If you specify one or more IP addresses, only the nodes specified participate in peering sessions.
You may specify multiple external peers,
bgpPeers
takes a list of mappings. We recommend you specify at least two external peers for high availability for BGP sessions. For an example with multiple peers, see Example configurations.Set the
loadBalancer.ports
,loadBalancer.vips
, andloadBalancer.addressPools
fields (default values shown).... loadBalancer: ... # Other existing load balancer options remain the same ports: controlPlaneLBPort: 443 # When type=bgp, the VIPs are advertised over BGP vips: controlPlaneVIP: 10.0.0.8 ingressVIP: 10.0.0.1 addressPools: - name: pool1 addresses: - 10.0.0.1-10.0.0.4 ...
Specify the cluster node to use for load balancing the data plane.
This step is optional. If you do not uncomment the
nodePoolSpec
section, the control plane nodes are used for data plane load balancing.... # Node pool used for load balancing data plane (nodes where incoming traffic # arrives. If not specified, this defaults to the control plane node pool. # nodePoolSpec: # nodes: # - address: <Machine 1 IP> ...
Reserve floating IP addresses by configuring the
NetworkGatewayGroup
custom resource:The floating IP addresses are used in peering sessions for data plane load balancing.
... --- apiVersion: networking.gke.io/v1 kind: NetworkGatewayGroup metadata: name: default namespace: CLUSTER_NAMESPACE spec: floatingIPs: - FLOATING_IP ...
Replace the following:
CLUSTER_NAMESPACE
: the namespace for the cluster. By default, the cluster namespaces for Google Distributed Cloud are the name of the cluster prefaced withcluster-
. For example, if you name your clustertest
, the namespace iscluster-test
.FLOATING_IP
: an IP address from one of the cluster's subnets. You must specify at least one IP address, but we recommend you specify at least two IP addresses.
Ensure the
NetworkGatewayGroup
custom resource is nameddefault
and uses the cluster namespace. For an example of how theNetworkGatewayGroup
custom resource specification might look, see Example configurations.(Optional) Specify the peers to use for data plane load balancing by configuring the
BGPLoadBalancer
custom resource:... --- apiVersion: networking.gke.io/v1 kind: BGPLoadBalancer metadata: name: default namespace: CLUSTER_NAMESPACE spec: peerSelector: PEER_LABEL: "true" ...
Replace the following:
CLUSTER_NAMESPACE
: the namespace of the cluster. By default, the cluster namespaces for Google Distributed Cloud are the name of the cluster prefaced withcluster-
. For example, if you name your clustertest
, the namespace iscluster-test
.PEER_LABEL
: the label used to identify which peers to use for load balancing. AnyBGPPeer
custom resource with a matching label specifies the details of each peer.
Ensure the
BGPLoadBalancer
custom resource is nameddefault
and uses the cluster namespace. If you don't specify aBGPLoadBalancer
custom resource, the control plane peers are used automatically for data plane load balancing. For comprehensive examples, see Example configurations.(Optional) Specify the external peers for the data plane by configuring one or more
BGPPeer
custom resources:... --- apiVersion: networking.gke.io/v1 kind: BGPPeer metadata: name: BGP_PEER_NAME namespace: CLUSTER_NAMESPACE labels: PEER_LABEL: "true" spec: localASN: CLUSTER_ASN peerASN: PEER_ASN peerIP: PEER_IP sessions: SESSION_QTY ...
Replace the following:
BGP_PEER_NAME
: the name of the peer.CLUSTER_NAMESPACE
: the namespace for the cluster. By default, the cluster namespaces for Google Distributed Cloud are the name of the cluster prefaced withcluster-
. For example, if you name your clustertest
, the namespace iscluster-test
.PEER_LABEL
: the label used to identify which peers to use for load balancing. This label should correspond with the label specified in theBGPLoadBalancer
custom resource.CLUSTER_ASN
: the autonomous system number for the cluster being created.PEER_IP
: the IP address of the external peer device. We recommend that you specify at least two external peers, but you must specify at least one.PEER_ASN
: the autonomous system number for the network that contains the external peer device.SESSION_QTY
: the number of sessions to establish for this peer. We recommend that you establish at least two sessions to ensure that you maintain a connection to the peer in case one of your nodes goes down.
You may specify multiple external peers by creating additional
BGPPeer
custom resources. We recommend you specify at least two external peers (two custom resources) for high availability for BGP sessions. If you don't specify aBGPPeer
custom resource, the control plane peers are used automatically for data plane load balancing.When you run
bmctl cluster create
to create your cluster, preflight checks run. Among other checks, the preflight checks validate the BGP peering configuration for the control plane and report any issues directly to the admin workstation before the cluster can be created.On success, the added BGP load balancing resources (NetworkGatewayGroup, BGPLoadBalancer, and BGPPeer) go into the admin cluster in the user cluster namespace. Use the admin cluster kubeconfig file when you make subsequent updates to these resources. The admin cluster then reconciles changes to the user cluster. If you edit these resources on the user cluster directly, the admin cluster overwrites your changes in subsequent reconciliations.
Advertise multiple next-hops per session with BGP ADD-PATH
We recommend that you use the BGP ADD-PATH
capability for peering sessions as
specified in
RFC 7911.
By default, the BGP protocol allows only a single next hop to be advertised to
peers for a single prefix. BGP ADD-PATH
enables advertising multiple next hops
for the same prefix. When ADD-PATH
is used with BGP-based bundled load
balancing, the cluster can advertise multiple cluster nodes as frontend nodes
(next hops) for a load balancer service (prefix). Enable ECMP in the network so
that traffic can be spread over multiple paths. The ability to fan out traffic
by advertising multiple cluster nodes as next hops, provides improved scaling of
data plane capacity for load balancing.
If your external peer device, such as a top-of-rack (ToR) switch or router,
supports BGP ADD-PATH
, it is sufficient to turn on the receive extension only.
Bundled load balancing with BGP works without the ADD-PATH
capability, but the
restriction of advertising a single load-balancing node per peering session
limits load balancer data plane capacity. Without ADD-PATH
,
Google Distributed Cloud picks nodes to advertise from the load balancer node pool
and attempts to spread next hops for different VIPs across different nodes.
Restrict BGP peering to load balancer nodes
Google Distributed Cloud automatically assigns floating IP addresses on any node in the same subnet as the floating IP address. BGP sessions are initiated from these IP addresses even if they do not land on the load balancer nodes. This behavior is by design, because we have decoupled the control plane (BGP) from the data plane (LB node pools).
If you want to restrict the set of nodes which can be used for BGP peering, you can designate one subnet to be used only for load balancer nodes. That is, you can configure all nodes in that subnet to be in the load balancer node pool. Then, when you configure floating IP addresses which are used for BGP peering, ensure they are from this same subnet. Google Distributed Cloud ensures that the floating IP address assignments and BGP peering take place from load balancer nodes only.
Set up BGP load balancing with dual-stack networking
Starting with Google Distributed Cloud release 1.14.0, the BGP-based bundled load balancer supports IPv6. With the introduction of IPv6 support, you can configure IPv6 and dual-stack LoadBalancer Services on a cluster configured for dual-stack networking. This section describes the changes required to configure dual-stack, bundled load balancing with BGP.
To enable dual-stack LoadBalancer Services, the following configuration changes are required:
The underlying cluster must be a configured for dual-stack networking:
Specify both IPv4 and IPv6 Service CIDRs in the cluster configuration file under
spec.clusterNetwork.services.cidrBlocks
.Define appropriate ClusterCIDRConfig resources for specifying IPv4 and IPv6 CIDR ranges for Pods.
For more information on configuring a cluster for dual-stack networking, see IPv4/IPv6 dual-stack networking.
Specify an IPv6 address pool in the cluster configuration file under
spec.loadBalancer.addressPools
. In order for MetalLB to allocate IP addresses to a Dual Stack Service, there must be at least one address pool having both IPv4 and IPv6 format addresses.
The following example configuration highlights the changes needed for dual-stack bundled load balancing with BGP:
apiVersion: baremetal.cluster.gke.io/v1
kind: Cluster
metadata:
name: bm
namespace: cluster-bm
spec:
...
clusterNetwork:
services:
cidrBlocks:
# Dual-stack Service IP addresses must be provided
- 10.96.0.0/16
- fd00::/112
...
loadBalancer:
mode: bundled
# type can be 'bgp' or 'layer2'. If no type is specified we default to layer2.
type: bgp
# AS number for the cluster
localASN: 65001
bgpPeers:
- ip: 10.8.0.10
asn: 65002
- ip: 10.8.0.11
asn: 65002
addressPools:
- name: pool1
addresses:
# Each address must be either in the CIDR form (1.2.3.0/24)
# or range form (1.2.3.1-1.2.3.5).
- "203.0.113.1-203.0.113.20"
- "2001:db8::1-2001:db8::20" # Note the additional IPv6 range
... # Other cluster config info omitted
---
apiVersion: networking.gke.io/v1
kind: NetworkGatewayGroup
metadata:
name: default
namespace: cluster-bm
spec:
floatingIPs:
- 10.0.1.100
- 10.0.2.100
---
apiVersion: baremetal.cluster.gke.io/v1alpha1
kind: ClusterCIDRConfig
metadata:
name: cluster-wide-1
namespace: cluster-bm
spec:
ipv4:
cidr: "192.168.0.0/16"
perNodeMaskSize: 24
ipv6:
cidr: "2001:db8:1::/112"
perNodeMaskSize: 120
Limitations for dual-stack, bundled load balancing with BGP
When configuring your cluster to use dual-stack, bundled load balancing with BGP, note the following limitations:
IPv6 control plane load balancing isn't supported.
IPv6 BGP sessions aren't supported, but IPv6 routes can be advertised over IPv4 sessions using Multiprotocol BGP.
Example configurations
The following sections demonstrate how to configure BGP-based load balancing for different options or behavior.
Configure all nodes use the same peers
As shown in the following diagram, this configuration results in a set of
external peers (10.8.0.10
and 10.8.0.11
) that are reachable by all nodes.
Control plane nodes (10.0.1.10
, 10.0.1.11
, and 10.0.2.10
) and floating IP
addresses (10.0.1.100
and 10.0.2.100
) assigned to data plane nodes all reach
the peers.
The same external peers are both reachable by either of the floating IP
addresses (10.0.1.100
or 10.0.2.100
) that are reserved for loadBalancer
Services peering. The floating IP addresses can be assigned to nodes that are in
the same subnet.
As shown in the following cluster configuration sample, you configure the peers
for the control plane nodes, bgpPeers
, without specifying controlPlaneNodes
.
When no nodes are specified for peers, then all control plane nodes connect to
all peers.
You specify the floating IP addresses to use for Services load-balancing peering
sessions in the NetworkGatewayGroup
custom resource. In this example, since no
BGPLoadBalancer
is specified, the control plane peers are used automatically
for the data plane BGP sessions.
apiVersion: baremetal.cluster.gke.io/v1
kind: Cluster
metadata:
name: bm
namespace: cluster-bm
spec:
...
loadBalancer:
mode: bundled
# type can be 'bgp' or 'layer2'. If no type is specified, we default to layer2.
type: bgp
# AS number for the cluster
localASN: 65001
bgpPeers:
- ip: 10.8.0.10
asn: 65002
- ip: 10.8.0.11
asn: 65002
... (other cluster config omitted)
---
apiVersion: networking.gke.io/v1
kind: NetworkGatewayGroup
metadata:
name: default
namespace: cluster-bm
spec:
floatingIPs:
- 10.0.1.100
- 10.0.2.100
Configure specific control plane nodes to peer with specific external peers
As shown in the following diagram, this configuration results in two control
plane nodes (10.0.1.10
and 10.0.1.11
) peering with one external peer
(10.0.1.254
). The third control plane node (10.0.2.10
) is peering with
another external peer (10.0.2.254
). This configuration is useful when you
don't want all nodes to connect to all peers. For example, you may want control
plane nodes to peer with their corresponding top-of-rack (ToR) switches only.
The same external peers are both reachable by either of the floating IP
addresses (10.0.1.100
or 10.0.2.100
) that are reserved for Services
load-balancing peering sessions. The floating IP addresses can be assigned to
nodes that are in the same subnet.
As shown in the following cluster configuration sample, you restrict which
control plane nodes can connect to a given peer by specifying their IP addresses
in the controlPlaneNodes
field for the peer in the bgpPeers
section.
You specify the floating IP addresses to use for Services load-balancing peering
sessions in the NetworkGatewayGroup
custom resource. In this example, since no
BGPLoadBalancer
is specified, the control plane peers are used automatically
for the data plane BGP sessions.
apiVersion: baremetal.cluster.gke.io/v1
kind: Cluster
metadata:
name: bm
namespace: cluster-bm
spec:
...
loadBalancer:
mode: bundled
# type can be 'bgp' or 'layer2'. If no type is specified, we default to layer2.
type: bgp
# AS number for the cluster
localASN: 65001
bgpPeers:
- ip: 10.0.1.254
asn: 65002
controlPlaneNodes:
- 10.0.1.10
- 10.0.1.11
- ip: 10.0.2.254
asn: 65002
controlPlaneNodes:
- 10.0.2.10
... (other cluster config omitted)
---
apiVersion: networking.gke.io/v1
kind: NetworkGatewayGroup
name: default
namespace: cluster-bm
spec:
floatingIPs:
- 10.0.1.100
- 10.0.2.100
Configure control plane and data plane separately
As shown in the following diagram, this configuration results in two control
plane nodes (10.0.1.10
and 10.0.1.11
) peering with one external peer
(10.0.1.254
) and the third control plane node (10.0.2.11
) peering with
another external peer (10.0.2.254
).
A third external peer (10.0.3.254
) is reachable by either of the floating IP
addresses (10.0.3.100
or 10.0.3.101
) that are reserved for Services
load-balancing peering sessions. The floating IP addresses can be assigned to
nodes that are in the same subnet.
As shown in the following cluster configuration sample, you restrict which
control plane nodes can connect to a given peer by specifying their IP addresses
in the controlPlaneNodes
field for the peer in the bgpPeers
section.
You specify the floating IP addresses to use for Services load-balancing peering
sessions in the NetworkGatewayGroup
custom resource.
To configure the data plane load balancing:
Specify the external peer for the data plane in the
BGPPeer
resource and add a label to use for peer selection, such ascluster.baremetal.gke.io/default-peer: "true"
.Specify the matching label for the
peerSelector
field in theBGPLoadBalancer
resource.
apiVersion: baremetal.cluster.gke.io/v1
kind: Cluster
metadata:
name: bm
namespace: cluster-bm
spec:
...
loadBalancer:
mode: bundled
# type can be 'bgp' or 'layer2'. If no type is specified, we default to layer2.
type: bgp
# AS number for the cluster
localASN: 65001
bgpPeers:
- ip: 10.0.1.254
asn: 65002
controlPlaneNodes:
- 10.0.1.10
- 10.0.1.11
- ip: 10.0.2.254
asn: 65002
controlPlaneNodes:
- 10.0.2.11
... (other cluster config omitted)
---
apiVersion: networking.gke.io/v1
kind: NetworkGatewayGroup
name: default
namespace: cluster-bm
spec:
floatingIPs:
- 10.0.3.100
- 10.0.3.101
---
apiVersion: networking.gke.io/v1
kind: BGPLoadBalancer
metadata:
name: default
namespace: cluster-bm
spec:
peerSelector:
cluster.baremetal.gke.io/default-peer: "true"
---
apiVersion: networking.gke.io/v1
kind: BGPPeer
metadata:
name: bgppeer1
namespace: cluster-bm
labels:
cluster.baremetal.gke.io/default-peer: "true"
spec:
localASN: 65001
peerASN: 65002
peerIP: 10.0.3.254
sessions: 2
Modify your BGP-based load-balancing configuration
After you have created your cluster configured to use bundled load balancing with BGP, some configuration settings can be updated, but some can't be updated after the cluster is created.
Use the admin cluster kubeconfig file when you make subsequent updates to the BGP-related resources (NetworkGatewayGroup, BGPLoadBalancer, and BGPPeer). The admin cluster then reconciles the changes to the user cluster. If you edit these resources on the user cluster directly, the admin cluster overwrites your changes in subsequent reconciliations.
Control plane
Control plane BGP-peering information can be updated in the Cluster
resource.
You may add or remove peers specified in the control plane load balancing
section.
The following sections outline the best practices for updating your control plane BGP peering information.
Check peer status before updating
To minimize the risk of misconfiguring peers, check that control plane BGP
peering sessions are in the expected state before making changes. For example,
if you expect that all BGP peering sessions are currently up, then verify that
all bgp-advertiser
Pods report ready
, indicating that the sessions are up.
If the current status doesn't match what you expect, then fix the issue before
updating a peer configuration.
For information about retrieving control plane BGP session details, see Control plane BGP sessions.
Update peers in a controlled manner
Update one peer at a time, if possible, to help isolate possible problems:
- Add or update a single peer.
- Wait for the configuration to reconcile.
- Verify that the cluster is able to connect to the new or updated peer.
- Remove the old or unneeded peers.
Services
To update address pools and load balancer node settings, edit nodePoolSpec
in
the Cluster
resource.
To modify the BGP peering configuration after your cluster has been created,
edit the NetworkGatewayGroup
and BGPLoadBalancer
custom resources. Any
modifications to the peering information in these custom resources are reflected
in the configuration of the load-balancing solution in the target cluster.
Make updates in the source resources in the cluster namespace in the admin cluster only. Any modifications made to the resources in the target (user) cluster are overwritten.
Troubleshooting
The following sections describe how to access troubleshooting information for bundled load balancing with BGP.
Control plane BGP sessions
The control plane BGP-peering configuration is validated with preflight checks during cluster creation. The preflight checks attempt to:
- Establish a BGP connection with each peer.
- Advertise the control plane VIP.
- Verify that the control plane node can be reached, using the VIP.
If your cluster creation fails preflight checks, then review the preflight check
logs for errors. Datestamped preflight check log files are located in the
baremetal/bmctl-workspace/CLUSTER_NAME/log
directory.
At runtime, the control plane BGP speakers run as static pods on each control
plane node and write event information to logs. These static pods include
"bgpadvertiser" in their name, so use the following kubectl get pods
command
to view the status of the BGP speaker Pods:
kubectl -n kube-system get pods | grep bgpadvertiser
When the Pods are operating properly, the response looks something like the following:
bgpadvertiser-node-01 1/1 Running 1 167m
bgpadvertiser-node-02 1/1 Running 1 165m
bgpadvertiser-node-03 1/1 Running 1 163m
Use the following command to view the logs for the bgpadvertiser-node-01
Pod:
kubectl -n kube-system logs bgpadvertiser-node-01
Services BGP sessions
The BGPSession
resource provides information about current BGP sessions. To
get session information, first get the current sessions, then retrieve the
BGPSession
resource for one of the sessions.
Use the following kubectl get
command to list the current sessions:
kubectl -n kube-system get bgpsessions
The command returns a list of sessions like the following example:
NAME LOCAL ASN PEER ASN LOCAL IP PEER IP STATE LAST REPORT
10.0.1.254-node-01 65500 65000 10.0.1.178 10.0.1.254 Established 2s
10.0.1.254-node-02 65500 65000 10.0.3.212 10.0.1.254 Established 2s
10.0.3.254-node-01 65500 65000 10.0.1.178 10.0.3.254 Established 2s
10.0.3.254-node-02 65500 65000 10.0.3.212 10.0.3.254 Established 2s
Use the following kubectl describe
command to get the BGPSession
resource
for the 10.0.1.254-node-01
BGP session:
kubectl -n kube-system describe bgpsession 10.0.1.254-node-01
The BGPSession
resource returned should look something like the following
example:
Name: 10.0.1.254-node-01
Namespace: kube-system
Labels: <none>
Annotations: <none>
API Version: networking.gke.io/v1
Kind: BGPSession
Metadata:
(omitted)
Spec:
Floating IP: 10.0.1.178
Local ASN: 65500
Local IP: 10.0.1.178
Node Name: node-01
Peer ASN: 65000
Peer IP: 10.0.1.254
Status:
Advertised Routes:
10.0.4.1/32
Last Report Time: 2021-06-14T22:09:36Z
State: Established
Use the kubectl get
command to get the BGPAdvertisedRoute
resources:
kubectl -n kube-system get bgpadvertisedroutes
The response, which should look similar to the following example, shows the routes currently being advertised:
NAME PREFIX METRIC
default-default-load-balancer-example 10.1.1.34/32
default-gke-system-istio-ingress 10.1.1.107/32
Use kubectl describe
to view details about which next hops each route is
advertising.
Recovering access to the control plane VIP for self-managed clusters
To regain access to the control plane VIP on an admin, hybrid, or standalone
cluster, you must update the BGP configuration on the cluster. As shown in the
following command sample, use SSH to connect to the node, then use kubectl
to
open the cluster resource for editing.
ssh -i IDENTITY_FILE root@CLUSTER_NODE_IP
kubectl --kubeconfig /etc/kubernetes/admin.conf edit -n CLUSTER_NAMESPACE cluster CLUSTER_NAME
Replace the following:
IDENTITY_FILE
: the name of the SSH identity file that contains the identity key for public key authentication.CLUSTER_NODE_IP
: the IP address for the cluster node.CLUSTER_NAMESPACE
: the namespace of the cluster.CLUSTER_NAME
: the name of the cluster.
Modify the BGP peering configuration in the cluster object. After saving the new
cluster configuration, monitor the health of the bgpadvertiser
pods. If the
configuration works, then the pods restart and become healthy once they connect
to their peers.
Manual BGP verification
This section contains instructions for manually verifying your BGP configuration. The procedure sets up a long-running BGP connection so that you can further debug the BGP configuration with your network team. Use this procedure to verify your configuration before you create a cluster or use it if BGP-related preflight checks fail.
Preflight checks automate the following BGP verification tasks:
- Set up a BGP connection to a peer.
- Advertise the control plane VIP.
- Verify that traffic sent from all other cluster nodes to the VIP reaches the current load balancer node.
These tasks are run for each BGP peer on each control plane node. Passing these checks is critical when creating a cluster. The preflight checks, however, don't create long-running connections, so debugging a failure is difficult.
The following sections provide instructions to set up a BGP connection and advertise a route from a single cluster machine to one peer. To test multiple machines and multiple peers, repeat the instructions again, using a different machine and peer combination.
Remember that BGP connections are established from the control plane nodes, so be sure to test this procedure from one of your planned control plane nodes.
Obtain the BGP test program binary
Run the steps in this section on your admin workstation. These steps get the
bgpadvertiser
program that is used to test BGP connections and copy it to
control plane nodes where you want to test.
Pull the ansible-runner docker image.
Without Registry Mirror
If you don't use a registry mirror, run the following commands to pull the ansible-runner docker image:
gcloud auth login gcloud auth configure-docker docker pull gcr.io/anthos-baremetal-release/ansible-runner:1.10.0-gke.13
With Registry Mirror
If you use a registry mirror, run the following commands to pull the ansible-runner docker image:
docker login REGISTRY_HOST docker pull REGISTRY_HOST/anthos-baremetal-release/ansible-runner:1.10.0-gke.13
Replace REGISTRY_HOST with the name of your registry mirror server.
To extract the
bgpadvertiser
binary.Without Registry Mirror
To extract the
bgpadvertiser
binary, run the following command:docker cp $(docker create gcr.io/anthos-baremetal-release/ansible-runner:1.10.0-gke.13):/bgpadvertiser .
With Registry Mirror
To extract the
bgpadvertiser
binary, run the following command:docker cp $(docker create REGISTRY_HOST/anthos-baremetal-release/ansible-runner:1.10.0-gke.13):/bgpadvertiser .
To copy the
bgpadvertiser
binary to the control plane node that you want to test with, run the following command:scp bgpadvertiser USERNAME>@CP_NODE_IP:/tmp/
Replace the following:
USERNAME
: the username that you use to access the control plane node.CP_NODE_IP
: the IP address of the control plane node.
Set up a BGP connection
Run the steps in this section on a control plane node.
Create a configuration file on the node at
/tmp/bgpadvertiser.conf
that looks like the following:localIP: NODE_IP localASN: CLUSTER_ASN peers: - peerIP: PEER_IP peerASN: PEER_ASN
Replace the following:
NODE_IP
: IP address of the control plane node that you're on.CLUSTER_ASN
: the autonomous system number used by the cluster.PEER_IP
: the IP address of one of the external peers you want to test.PEER_ASN
: the autonomous system number for the network that contains the external peer device.
Run the
bgpadvertiser
daemon, substituting the control plane VIP in the following command:/tmp/bgpadvertiser --config /tmp/bgpadvertiser.conf --advertise-ip CONTROL_PLANE_VIP
Replace
CONTROL_PLANE_VIP
with the IP address that you're going to use for your control plane VIP. This command causes the BGP advertiser to advertise this address to the peer.View the program output.
At this point, the
bgpadvertiser
daemon starts up, attempts to connect to the peer, and advertises the VIP. The program periodically prints messages (see the following sample output) that includeBGP_FSM_ESTABLISHED
when the BGP connection is established.{"level":"info","ts":1646788815.5588224,"logger":"BGPSpeaker","msg":"GoBGP gRPC debug endpoint disabled","localIP":"21.0.101.64"} {"level":"info","ts":1646788815.5596201,"logger":"BGPSpeaker","msg":"Started.","localIP":"21.0.101.64"} I0309 01:20:15.559667 1320826 main.go:154] BGP advertiser started. I0309 01:20:15.561434 1320826 main.go:170] Health status HTTP server started at "127.0.0.1:8080". INFO[0000] Add a peer configuration for:21.0.101.80 Topic=Peer {"level":"info","ts":1646788815.5623345,"logger":"BGPSpeaker","msg":"Peer added.","localIP":"21.0.101.64","peer":"21.0.101.80/4273481989"} DEBU[0000] IdleHoldTimer expired Duration=0 Key=21.0.101.80 Topic=Peer I0309 01:20:15.563503 1320826 main.go:187] Peer applied: {4273481989 21.0.101.80} DEBU[0000] state changed Key=21.0.101.80 Topic=Peer new=BGP_FSM_ACTIVE old=BGP_FSM_IDLE reason=idle-hold-timer-expired DEBU[0000] create Destination Nlri=10.0.0.1/32 Topic=Table {"level":"info","ts":1646788815.5670514,"logger":"BGPSpeaker","msg":"Route added.","localIP":"21.0.101.64","route":{"ID":0,"Metric":0,"NextHop":"21.0.101.64","Prefix":"10.0.0.1/32","VRF":""}} I0309 01:20:15.568029 1320826 main.go:199] Route added: {0 0 21.0.101.64 10.0.0.1/32 } I0309 01:20:15.568073 1320826 main.go:201] BGP advertiser serving... DEBU[0005] try to connect Key=21.0.101.80 Topic=Peer DEBU[0005] state changed Key=21.0.101.80 Topic=Peer new=BGP_FSM_OPENSENT old=BGP_FSM_ACTIVE reason=new-connection DEBU[0005] state changed Key=21.0.101.80 Topic=Peer new=BGP_FSM_OPENCONFIRM old=BGP_FSM_OPENSENT reason=open-msg-received INFO[0005] Peer Up Key=21.0.101.80 State=BGP_FSM_OPENCONFIRM Topic=Peer DEBU[0005] state changed Key=21.0.101.80 Topic=Peer new=BGP_FSM_ESTABLISHED old=BGP_FSM_OPENCONFIRM reason=open-msg-negotiated DEBU[0005] sent update Key=21.0.101.80 State=BGP_FSM_ESTABLISHED Topic=Peer attributes="[{Origin: i} 4273481990 {Nexthop: 21.0.101.64}]" nlri="[10.0.0.1/32]" withdrawals="[]" DEBU[0006] received update Key=21.0.101.80 Topic=Peer attributes="[{Origin: i} 4273481989 4273481990 {Nexthop: 21.0.101.64}]" nlri="[10.0.0.1/32]" withdrawals="[]" DEBU[0006] create Destination Nlri=10.0.0.1/32 Topic=Table DEBU[0035] sent Key=21.0.101.80 State=BGP_FSM_ESTABLISHED Topic=Peer data="&{{[] 19 4} 0x166e528}" DEBU[0065] sent Key=21.0.101.80 State=BGP_FSM_ESTABLISHED Topic=Peer data="&{{[] 19 4} 0x166e528}"
If you do not see these messages, then double-check the BGP configuration parameters in the config file and verify with the network administrator. Now you have a BGP connection set up. You can verify with the network administrator that they see the connection established on their side and that they see the route advertised to them.
Traffic test
To test that the network can forward traffic to the VIP, you must add the VIP to
your control plane node that's running bgpadvertiser
. Run the following
command in a different terminal so you can leave the bgpadvertiser
running:
Add the VIP to your control plane node:
ip addr add CONTROL_PLANE_VIP/32 dev INTF_NAME
Replace the following:
CONTROL_PLANE_VIP
: the VIP--advertise-ip
argument of thebgpadvertiser
.INTF_NAME
: the Kubernetes interface on the node. That is, the interface that has the IP address that you put in the Google Distributed Cloud configuration forloadBalancer.bgpPeers.controlPlaneNodes
.
Ping the VIP from a different node:
ping CONTROL_PLANE_VIP
If the ping does not succeed, then there may be an issue with the BGP configuration on the network device. Work with your network administrator to verify the configuration and resolve the issue.
Clean up
Be sure to follow these steps to reset the node after you've manually verified that BGP is working. If you don't reset the node properly, the manual setup may interfere with the preflight check or subsequent cluster creation.
Remove the VIP from the control plane node if you added it for the traffic test:
ip addr del CONTROL_PLANE_VIP/32 dev INTF_NAME
On the control plane node, press
Ctrl
+C
in thebgpadvertiser
terminal to stop the bgpadvertiser.Verify that no
bgpadvertiser
processes are running:ps -ef | grep bgpadvertiser
If you see processes running, then stop them using the
kill
command.