# Multi-zone deployment
Kuma supports running your service mesh in multiple zones. It is even possible to run with a mix of Kubernetes and Universal zones. Your mesh environment can include multiple isolated service meshes (multi-tenancy), and workloads running in different regions, on different clouds, or in different datacenters. A zone can be a Kubernetes cluster, a VPC, or any other deployment you need to include in the same distributed mesh environment.
# How it works
Kuma manages service connectivity -- establishing and maintaining connections across zones in the mesh -- with the zone ingress and with a DNS resolver.
The DNS resolver is embedded in each data plane proxy and configured through XDS. It resolves each service address to a virtual IP address for all service-to-service communication.
The global control plane and the zone control planes communicate to synchronize resources such as Kuma policy configurations over Kuma Discovery Service (KDS), which is a protocol based on xDS.
A zone ingress is not an API gateway. Instead, it is specific to internal cross-zone communication within the mesh. API gateways are supported in Kuma gateway mode which can be deployed in addition to zone ingresses.
# Components of a multi-zone deployment
A multi-zone deployment includes:
- The global control plane:
- Accept connections only from zone control planes.
- Accept creation and changes to policies that will be applied to the data plane proxies.
- Send policies down to zone control planes.
- Send zone ingresses down to zone control plane.
- Keep an inventory of all data plane proxies running in all zones (this is only done for observability but is not required for operations).
- Reject connections from data plane proxies.
- The zone control planes:
- Accept connections from data plane proxies started within this zone.
- Receive policy updates from the global control plane.
- Send data plane proxies and zone ingress changes to the global control plane.
- Compute and send configurations using XDS to the local data plane proxies.
- Update list of services which exist in the zone in the zone ingress.
- Reject policy changes that do not come from global.
- The data plane proxies:
- Connect to the local zone control plane.
- Receive configurations using XDS from the local zone control plane.
- Connect to other local data plane proxies.
- Connect to zone ingresses for sending cross zone traffic.
- Receive traffic from local data plane proxies and local zone ingresses.
- The zone ingress:
- Receive XDS configuration from the local zone control plane.
- Proxy traffic from other zone data plane proxies to local data plane proxies.
- (optional) The zone egress:
- Receive XDS configuration from the local zone control plane.
- Proxy traffic from local data plane proxies:
- to zone ingress proxies from other zones;
- to external services from local zone;
To set up a multi-zone deployment we will need to:
- Set up the global control plane
- Set up the zone control planes
- Verify control plane connectivity
- Set up cross-zone communication between data plane proxies
# Set up the global control plane
The global control plane must run on a dedicated cluster, and cannot be assigned to a zone.
# Set up the zone control planes
You need the following values to pass to each zone control plane setup:
zone-- the zone name. An arbitrary string. This value registers the zone control plane with the global control plane.
kds-global-address-- the external IP and port of the global control plane.
# Verify control plane connectivity
You can run
kumactl get zones, or check the list of zones in the web UI for the global control plane, to verify zone control plane connections.
When a zone control plane connects to the global control plane, the
Zone resource is created automatically in the global control plane.
The Zone Ingress tab of the web UI also lists zone control planes that you deployed with zone ingress.
# Set up cross-zone communication
# Enable mTLS
Kuma uses the Server Name Indication field, part of the TLS protocol, as a way to pass routing information cross zones. Thus, mTLS is mandatory to enable cross-zone service communication.
# Ensure Zone Ingress has an external advertised address and port
Cross-zone communication between services is available only if Zone Ingress has an external advertised address and port.
This address doesn't need to be public to the internet. It only needs to be reachable from all data plane proxies in other zones.
# Cross-zone communication details
The Kuma DNS service format (e.g.
echo-server_kuma-test_svc_1010.mesh) is a composition of Kubernetes Service Name (
kuma-test), a fixed string (
svc), the service port (
1010). The service is resolvable in the DNS zone
the Kuma DNS service is hooked.
# Delete a zone
To delete a
Zone we must first shut down the corresponding Kuma zone control plane instances. As long as the Remote CP is running this will not be possible, and Kuma returns a validation error like:
zone: unable to delete Zone, Remote CP is still connected, please shut it down first
When the Remote CP is fully disconnected and shut down, then the
Zone can be deleted. All corresponding resources (like
DataplaneInsight) will be deleted automatically as well.
# Disable a zone
enabled property value to
false in the global control plane:
With this setting, the global control plane will stop exchanging configuration with this zone. As a result, the zone's ingress from zone-1 will be deleted from other zone and traffic won't be routed to it anymore. The zone will show as Offline in the GUI and CLI.
# Failure modes
# Global control plane offline
- Policy updates will be impossible
- Change in service list between zones will not propagate:
- New services will not be discoverable in other zones.
- Services removed from a zone will still appear available in other zones.
- You won't be able to disable or delete a zone.
Note that both local and cross-zone application traffic is not impacted by this failure case. Data plane proxy changes will be propagated within their zones.
# Zone control plane offline
- New data plane proxies won't be able to join the mesh.
- Data plane proxy configuration will not be updated.
- Communication between data plane proxies will still work.
- Cross zone communication will still work.
- Other zones are unaffected.
You can think of this failure case as "Freezing" the zone mesh configuration. Communication will still work but changes will not be reflected on existing data plane proxies.
# Communication between Global and Zone control plane failing
This can happen with misconfiguration or network connectivity issues between control planes.
- Operations inside the zone will happen correctly (data plane proxies can join, leave and all configuration will be updated and sent correctly).
- Policy changes will not be propagated to the zone control plane.
Dataplanechanges will not be propagated to the global control plane:
- The global inventory view of the data plane proxies will be outdated (this only impacts observability).
- Other zones will not see new services registered inside this zone.
- Other zones will not see services no longer running inside this zone.
- Other zones will not see changes in number of instances of each service running in the local zone.
- Global control plane will not send changes from other zone ingress to the zone:
- Local data plane proxies will not see new services registered in other zones.
- Local data plane proxies will not see services no longer running in other zones.
- Local data plane proxies will not see changes in number of instances of each service running in other zones.
- Global control plane will not send changes from other zone ingress to the zone.
Note that both local and cross-zone application traffic is not impacted by this failure case.
# Communication between 2 zones failing
This can happen if there are network connectivity issues:
- Between control plane and zone ingress from other zone.
- Between control plane and zone egress (when present).
- Between zone egress (when present) and zone ingress from other zone.
- All Zone egress instances of a zone (when present) are down.
- All zone ingress instances of a zone are down.
When it happens:
- Communication and operation within each zone is unaffected.
- Communication across each zone will fail.