This page explains the two options for configuring the topology of your highly available (HA) Kubernetes clusters.
You can set up an HA cluster:
You should carefully consider the advantages and disadvantages of each topology before setting up an HA cluster.
A stacked HA cluster is a topology where the distributed data storage cluster provided by etcd is stacked on top of the cluster formed by the nodes managed by kubeadm that run control plane components.
Each control plane node runs an instance of the kube-apiserver
, kube-scheduler
, and kube-controller-manager
.
The kube-apiserver
is exposed to worker nodes using a load balancer.
Each control plane node creates a local etcd member and this etcd member communicate only with
the kube-apiserver
of this node. The same applies to the local kube-controller-manager
and kube-scheduler
instances.
This topology couples the control planes and etcd members on the same nodes. It is simpler to set up than a cluster with external etcd nodes, and simpler to manage for replication.
However, a stacked cluster runs the risk of failed coupling. If one node goes down, both an etcd member and a control plane instance are lost, and redundancy is compromised. You can mitigate this risk by adding more control plane nodes.
You should therefore run a minimum of three stacked control plane nodes for an HA cluster.
This is the default topology in kubeadm. A local etcd member is created automatically
on control plane nodes when using kubeadm init
and kubeadm join --experimental-control-plane
.
An HA cluster with external etcd is a topology where the distributed data storage cluster provided by etcd is external to the cluster formed by the nodes that run control plane components.
Like the stacked etcd topology, each control plane node in an external etcd topology runs an instance of the kube-apiserver
, kube-scheduler
, and kube-controller-manager
. And the kube-apiserver
is exposed to worker nodes using a load balancer. However, etcd members run on separate hosts, and each etcd host communicates with the kube-apiserver
of each control plane node.
This topology decouples the control plane and etcd member. It therefore provides an HA setup where losing a control plane instance or an etcd member has less impact and does not affect the cluster redundancy as much as the stacked HA topology.
However, this topology requires twice the number of hosts as the stacked HA topology. A minimum of three hosts for control plane nodes and three hosts for etcd nodes are required for an HA cluster with this topology.
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