Deploy KubeSphere on QingCloud Instances

Introduction

For a production environment, you need to consider the high availability of the cluster. If key components (for example, kube-apiserver, kube-scheduler, and kube-controller-manager) are all running on the same control plane node, Kubernetes and KubeSphere will be unavailable once the control plane node goes down. Therefore, you need to set up a high-availability cluster by provisioning load balancers with multiple control plane nodes. You can use any cloud load balancer, or any hardware load balancer (for example, F5). In addition, Keepalived and HAproxy, or Nginx is also an alternative for creating high-availability clusters.

This tutorial walks you through an example of how to create two QingCloud load balancers, serving as the internal load balancer and external load balancer respectively, and of how to implement high availability of control plane and etcd nodes using the load balancers.

Prerequisites

  • Make sure you already know how to install KubeSphere on a multi-node cluster by following the guide. For detailed information about the configuration file that is used for installation, see Edit the configuration file. This tutorial focuses more on how to configure load balancers.
  • You need a QingCloud account to create load balancers, or follow the guide of any other cloud provider to create load balancers.
  • For a production environment, it is recommended that you prepare persistent storage and create a StorageClass in advance. For development and testing, you can use the integrated OpenEBS to provision LocalPV as the storage service directly.

Architecture

This example prepares six machines of Ubuntu 16.04.6. You will create two load balancers, and deploy three control plane nodes and etcd nodes on three of the machines. You can configure these control plane and etcd nodes in config-sample.yaml created by KubeKey (Please note that this is the default name, which can be changed by yourself).

ha-architecture

Note

The Kubernetes document Options for Highly Available topology demonstrates that there are two options for configuring the topology of a highly available (HA) Kubernetes cluster, i.e. stacked etcd topology and external etcd topology. You should carefully consider the advantages and disadvantages of each topology before setting up an HA cluster according to this document. This tutorial adopts stacked etcd topology to bootstrap an HA cluster for demonstration purposes.

Install an HA Cluster

Step 1: Create load balancers

This step demonstrates how to create load balancers on the QingCloud platform.

Create an internal load balancer

  1. Log in to the QingCloud console. In the menu on the left, under Network & CDN, select Load Balancers. Click Create to create a load balancer.

    create-lb

  2. In the pop-up window, set a name for the load balancer. Choose the VxNet where your machines are created from the Network drop-down list. Here is pn. Other fields can be default values as shown below. Click Submit to finish.

    qingcloud-lb

  3. Click the load balancer. On the detail page, create a listener that listens on port 6443 with the Listener Protocol set to TCP.

    listener

    • Name: Define a name for this Listener
    • Listener Protocol: Select TCP protocol
    • Port: 6443
    • Balance mode: Poll

    Click Submit to continue.

    Note

    After you create the listener, check the firewall rules of the load balancer. Make sure that port 6443 has been added to the firewall rules and that external traffic is allowed to port 6443. Otherwise, the installation will fail. You can find the information in Security Groups under Security on the QingCloud platform.
  4. Click Add Backend, and choose the VxNet you just selected (in this example, it is pn). Click Advanced Search, choose the three control plane nodes, and set the port to 6443 which is the default secure port of api-server.

    3-master

    Click Submit when you finish.

  5. Click Apply Changes to use the configurations. At this point, you can find the three control plane nodes have been added as the backend servers of the listener that is behind the internal load balancer.

    Note

    The status of all control plane nodes might show Not Available after you added them as backends. This is normal since port 6443 of api-server is not active on control plane nodes yet. The status will change to Active and the port of api-server will be exposed after the installation finishes, which means the internal load balancer you configured works as expected.

    apply-change

    Record the Intranet VIP shown under Networks. The IP address will be added later to the configuration file.

Create an external load balancer

You need to create an EIP in advance. To create an EIP, go to Elastic IPs under Networks & CDN.

Note

Two elastic IPs are needed for this tutorial, one for the VPC network and the other for the external load balancer created in this step. You cannot associate the same EIP to the VPC network and the load balancer at the same time.
  1. Similarly, create an external load balancer while don't select VxNet for the Network field. Bind the EIP that you created to this load balancer by clicking Add IPv4.

    bind-eip

  2. On the load balancer's detail page, create a listener that listens on port 30880 (NodePort of KubeSphere console) with Listener Protocol set to HTTP.

    Note

    After you create the listener, check the firewall rules of the load balancer. Make sure that port 30880 has been added to the firewall rules and that external traffic is allowed to port 30880. Otherwise, the installation will fail. You can find the information in Security Groups under Security on the QingCloud platform.

    listener2

  3. Click Add Backend. In Advanced Search, choose the six machines on which you are going to install KubeSphere within the VxNet pn, and set the port to 30880.

    six-instances

    Click Submit when you finish.

  4. Click Apply Changes to use the configurations. At this point, you can find the six machines have been added as the backend servers of the listener that is behind the external load balancer.

Step 2: Download KubeKey

Kubekey is the next-gen installer which provides an easy, fast and flexible way to install Kubernetes and KubeSphere.

Follow the step below to download KubeKey.

Download KubeKey from its GitHub Release Page or use the following command directly.

curl -sfL https://get-kk.kubesphere.io | VERSION=v2.0.0 sh -

Run the following command first to make sure you download KubeKey from the correct zone.

export KKZONE=cn

Run the following command to download KubeKey:

curl -sfL https://get-kk.kubesphere.io | VERSION=v2.0.0 sh -

Note

After you download KubeKey, if you transfer it to a new machine also with poor network connections to Googleapis, you must run export KKZONE=cn again before you proceed with the steps below.

Note

The commands above download the latest release (v2.0.0) of KubeKey. You can change the version number in the command to download a specific version.

Make kk executable:

chmod +x kk

Create an example configuration file with default configurations. Here Kubernetes v1.21.5 is used as an example.

./kk create config --with-kubesphere v3.2.1 --with-kubernetes v1.21.5

Note

  • Recommended Kubernetes versions for KubeSphere 3.2.1: v1.19.x, v1.20.x, v1.21.x or v1.22.x (experimental). If you do not specify a Kubernetes version, KubeKey will install Kubernetes v1.21.5 by default. For more information about supported Kubernetes versions, see Support Matrix.

  • If you do not add the flag --with-kubesphere in the command in this step, KubeSphere will not be deployed unless you install it using the addons field in the configuration file or add this flag again when you use ./kk create cluster later.

  • If you add the flag --with-kubesphere without specifying a KubeSphere version, the latest version of KubeSphere will be installed.

Step 3: Set cluster nodes

As you adopt the HA topology with stacked control plane nodes, the control plane nodes and etcd nodes are on the same three machines.

Property Description
hosts Detailed information of all nodes
etcd etcd node names
control-plane Control plane node names
worker Worker node names

Put the control plane nodes (master1, master2 and master3) under etcd and master respectively as below, which means these three machines will serve as both the control plane and etcd nodes. Note that the number of etcd needs to be odd. Meanwhile, it is not recommended that you install etcd on worker nodes since the memory consumption of etcd is very high.

config-sample.yaml Example

spec:
  hosts:
  - {name: master1, address: 192.168.0.2, internalAddress: 192.168.0.2, user: ubuntu, password: Testing123}
  - {name: master2, address: 192.168.0.3, internalAddress: 192.168.0.3, user: ubuntu, password: Testing123}
  - {name: master3, address: 192.168.0.4, internalAddress: 192.168.0.4, user: ubuntu, password: Testing123}
  - {name: node1, address: 192.168.0.5, internalAddress: 192.168.0.5, user: ubuntu, password: Testing123}
  - {name: node2, address: 192.168.0.6, internalAddress: 192.168.0.6, user: ubuntu, password: Testing123}
  - {name: node3, address: 192.168.0.7, internalAddress: 192.168.0.7, user: ubuntu, password: Testing123}
  roleGroups:
    etcd:
    - master1
    - master2
    - master3
    control-plane:
    - master1
    - master2
    - master3
    worker:
    - node1
    - node2
    - node3

For a complete configuration sample explanation, see this file.

Step 4: Configure the load balancer

In addition to the node information, you need to provide the load balancer information in the same YAML file. For the Intranet VIP address, you can find it in the last part when you create an internal load balancer. Assume the VIP address and listening port of the internal load balancer are 192.168.0.253 and 6443

respectively, and you can refer to the following example.

The configuration example in config-sample.yaml

## Internal LB config example
## apiserver_loadbalancer_domain_name: "lb.kubesphere.local"
  controlPlaneEndpoint:
    domain: lb.kubesphere.local
    address: "192.168.0.253"
    port: 6443

Note

  • The address and port should be indented by two spaces in config-sample.yaml, and the address should be VIP.
  • The domain name of the load balancer is lb.kubesphere.local by default for internal access. If you need to change the domain name, uncomment and modify it.

Step 5: Kubernetes cluster configurations (Optional)

Kubekey provides some fields and parameters to allow the cluster administrator to customize Kubernetes installation, including Kubernetes version, network plugins and image registry. There are some default values provided in config-sample.yaml. You can modify Kubernetes-related configurations in the file based on your needs. For more information, see Kubernetes Cluster Configurations.

Step 6: Persistent storage plugin configurations

Considering data persistence in a production environment, you need to prepare persistent storage and configure the storage plugin (for example, CSI) in config-sample.yaml to define which storage service you want.

Note

For testing or development, you can skip this part. KubeKey will use the integrated OpenEBS to provision LocalPV as the storage service directly.

Available storage plugins and clients

  • Ceph RBD & CephFS
  • GlusterFS
  • QingCloud CSI
  • QingStor CSI
  • More plugins will be supported in future releases

Make sure you have configured the storage plugin before you get started. KubeKey will create a StorageClass and persistent volumes for related workloads during the installation. For more information, see Persistent Storage Configurations.

Step 7: Enable pluggable components (Optional)

KubeSphere has decoupled some core feature components since v2.1.0. These components are designed to be pluggable which means you can enable them either before or after installation. By default, KubeSphere will be installed with the minimal package if you do not enable them.

You can enable any of them according to your demands. It is highly recommended that you install these pluggable components to discover the full-stack features and capabilities provided by KubeSphere. Make sure your machines have sufficient CPU and memory before you enable them. See Enable Pluggable Components for details.

Step 8: Start to bootstrap a cluster

After you complete the configuration, you can execute the following command to start the installation:

./kk create cluster -f config-sample.yaml

Step 9: Verify the installation

Inspect the logs of installation. When you see output logs as follows, it means KubeSphere has been successfully deployed.

kubectl logs -n kubesphere-system $(kubectl get pod -n kubesphere-system -l app=ks-install -o jsonpath='{.items[0].metadata.name}') -f
#####################################################
###              Welcome to KubeSphere!           ###
#####################################################

Console: http://192.168.0.3:30880
Account: admin
Password: P@88w0rd

NOTES:
  1. After you log into the console, please check the
     monitoring status of service components in
     the "Cluster Management". If any service is not
     ready, please wait patiently until all components
     are up and running.
  2. Please change the default password after login.

#####################################################
https://kubesphere.io             2020-08-13 10:50:24
#####################################################

Step 10: Verify the HA cluster

Now that you have finished the installation, go back to the detail page of both the internal and external load balancers to see the status.

active

Both listeners show that the status is Active, meaning nodes are up and running.

active-listener

In the web console of KubeSphere, you can also see that all the nodes are functioning well.

To verify if the cluster is highly available, you can turn off an instance on purpose. For example, the above console is accessed through the address IP: 30880 (the EIP address here is the one bound to the external load balancer). If the cluster is highly available, the console will still work well even if you shut down a control plane node.

See Also

Multi-node Installation

Kubernetes Cluster Configurations

Persistent Storage Configurations

Enable Pluggable Components

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