The OKD installation program offers you flexibility. You can use the installation program to deploy a cluster on infrastructure that the installation program provisions and the cluster maintains or deploy a cluster on infrastructure that you prepare and maintain.
These two basic types of OKD clusters are frequently called installer-provisioned infrastructure clusters and user-provisioned infrastructure clusters.
Both types of clusters have the following characteristics:
Highly available infrastructure with no single points of failure is available by default
Administrators maintain control over what updates are applied and when
You use the same installation program to deploy both types of clusters. The main assets generated by the installation program are the Ignition config files for the bootstrap, master, and worker machines. With these three configurations and correctly configured infrastructure, you can start an OKD cluster.
The OKD installation program uses a set of targets and dependencies to manage cluster installation. The installation program has a set of targets that it must achieve, and each target has a set of dependencies. Because each target is only concerned with its own dependencies, the installation program can act to achieve multiple targets in parallel. The ultimate target is a running cluster. By meeting dependencies instead of running commands, the installation program is able to recognize and use existing components instead of running the commands to create them again.
The following diagram shows a subset of the installation targets and dependencies:
After installation, each cluster machine uses Fedora CoreOS (FCOS) as the operating system. FCOS is the immutable container host version of Fedora and features a Fedora kernel with SELinux enabled by default. It includes the
kubelet, which is the Kubernetes node agent, and the CRI-O container runtime, which is optimized for Kubernetes.
Every control plane machine in an OKD 4.9 cluster must use FCOS, which includes a critical first-boot provisioning tool called Ignition. This tool enables the cluster to configure the machines. Operating system updates are delivered as an Atomic OSTree repository that is embedded in a container image that is rolled out across the cluster by an Operator. Actual operating system changes are made in-place on each machine as an atomic operation by using rpm-ostree. Together, these technologies enable OKD to manage the operating system like it manages any other application on the cluster, via in-place upgrades that keep the entire platform up-to-date. These in-place updates can reduce the burden on operations teams.
If you use FCOS as the operating system for all cluster machines, the cluster manages all aspects of its components and machines, including the operating system. Because of this, only the installation program and the Machine Config Operator can change machines. The installation program uses Ignition config files to set the exact state of each machine, and the Machine Config Operator completes more changes to the machines, such as the application of new certificates or keys, after installation.
In OKD 4.9, you can install a cluster that uses installer-provisioned infrastructure on the following platforms:
Amazon Web Services (AWS)
Google Cloud Platform (GCP)
OpenStack versions 16.1 and 16.2
The latest OKD release supports both the latest OpenStack long-life release and intermediate release. For complete OpenStack release compatibility, see the OKD on OpenStack support matrix.
VMware Cloud (VMC) on AWS
For these clusters, all machines, including the computer that you run the installation process on, must have direct internet access to pull images for platform containers and provide telemetry data to Red Hat.
After installation, the following changes are not supported:
In OKD 4.9, you can install a cluster that uses user-provisioned infrastructure on the following platforms:
Azure Stack Hub
OpenStack versions 16.1 and 16.2
VMware Cloud on AWS
IBM Z or LinuxONE
Depending on the supported cases for the platform, installations on user-provisioned infrastructure allow you to run machines with full internet access, place your cluster behind a proxy, or perform a restricted network installation. In a restricted network installation, you can download the images that are required to install a cluster, place them in a mirror registry, and use that data to install your cluster. While you require internet access to pull images for platform containers, with a restricted network installation on vSphere or bare metal infrastructure, your cluster machines do not require direct internet access.
The OpenShift Container Platform 4.x Tested Integrations page contains details about integration testing for different platforms.
When you install an OKD cluster, you download the installation program from
In OKD 4.9, the installation program is a Go binary file that performs a series of file transformations on a set of assets. The way you interact with the installation program differs depending on your installation type.
For clusters with installer-provisioned infrastructure, you delegate the infrastructure bootstrapping and provisioning to the installation program instead of doing it yourself. The installation program creates all of the networking, machines, and operating systems that are required to support the cluster.
If you provision and manage the infrastructure for your cluster, you must provide all of the cluster infrastructure and resources, including the bootstrap machine, networking, load balancing, storage, and individual cluster machines.
You use three sets of files during installation: an installation configuration file that is named
install-config.yaml, Kubernetes manifests, and Ignition config files for your machine types.
It is possible to modify Kubernetes and the Ignition config files that control the underlying FCOS operating system during installation. However, no validation is available to confirm the suitability of any modifications that you make to these objects. If you modify these objects, you might render your cluster non-functional. Because of this risk, modifying Kubernetes and Ignition config files is not supported unless you are following documented procedures or are instructed to do so by Red Hat support.
The installation configuration file is transformed into Kubernetes manifests, and then the manifests are wrapped into Ignition config files. The installation program uses these Ignition config files to create the cluster.
The installation configuration files are all pruned when you run the installation program, so be sure to back up all configuration files that you want to use again.
You cannot modify the parameters that you set during installation, but you can modify many cluster attributes after installation.
The default installation type uses installer-provisioned infrastructure. By default, the installation program acts as an installation wizard, prompting you for values that it cannot determine on its own and providing reasonable default values for the remaining parameters. You can also customize the installation process to support advanced infrastructure scenarios. The installation program provisions the underlying infrastructure for the cluster.
You can install either a standard cluster or a customized cluster. With a standard cluster, you provide minimum details that are required to install the cluster. With a customized cluster, you can specify more details about the platform, such as the number of machines that the control plane uses, the type of virtual machine that the cluster deploys, or the CIDR range for the Kubernetes service network.
If possible, use this feature to avoid having to provision and maintain the cluster infrastructure. In all other environments, you use the installation program to generate the assets that you require to provision your cluster infrastructure.
With installer-provisioned infrastructure clusters, OKD manages all aspects of the cluster, including the operating system itself. Each machine boots with a configuration that references resources hosted in the cluster that it joins. This configuration allows the cluster to manage itself as updates are applied.
You can also install OKD on infrastructure that you provide. You use the installation program to generate the assets that you require to provision the cluster infrastructure, create the cluster infrastructure, and then deploy the cluster to the infrastructure that you provided.
If you do not use infrastructure that the installation program provisioned, you must manage and maintain the cluster resources yourself, including:
The underlying infrastructure for the control plane and compute machines that make up the cluster
Cluster networking, including the DNS records and required subnets
Storage for the cluster infrastructure and applications
If your cluster uses user-provisioned infrastructure, you have the option of adding Fedora compute machines to your cluster.
Because each machine in the cluster requires information about the cluster when it is provisioned, OKD uses a temporary bootstrap machine during initial configuration to provide the required information to the permanent control plane. It boots by using an Ignition config file that describes how to create the cluster. The bootstrap machine creates the control plane machines that make up the control plane. The control plane machines then create the compute machines, which are also known as worker machines. The following figure illustrates this process:
After the cluster machines initialize, the bootstrap machine is destroyed. All clusters use the bootstrap process to initialize the cluster, but if you provision the infrastructure for your cluster, you must complete many of the steps manually.
Bootstrapping a cluster involves the following steps:
The bootstrap machine boots and starts hosting the remote resources required for the control plane machines to boot. (Requires manual intervention if you provision the infrastructure)
The bootstrap machine starts a single-node etcd cluster and a temporary Kubernetes control plane.
The control plane machines fetch the remote resources from the bootstrap machine and finish booting. (Requires manual intervention if you provision the infrastructure)
The temporary control plane schedules the production control plane to the production control plane machines.
The Cluster Version Operator (CVO) comes online and installs the etcd Operator. The etcd Operator scales up etcd on all control plane nodes.
The temporary control plane shuts down and passes control to the production control plane.
The bootstrap machine injects OKD components into the production control plane.
The installation program shuts down the bootstrap machine. (Requires manual intervention if you provision the infrastructure)
The control plane sets up the compute nodes.
The control plane installs additional services in the form of a set of Operators.
The result of this bootstrapping process is a running OKD cluster. The cluster then downloads and configures remaining components needed for the day-to-day operation, including the creation of compute machines in supported environments.
The scope of the OKD installation program is intentionally narrow. It is designed for simplicity and ensured success. You can complete many more configuration tasks after installation completes.
See Available cluster customizations for details about OKD configuration resources.
The OpenShift Update Service (OSUS) provides over-the-air updates to OKD, including Fedora CoreOS (FCOS). It provides a graph, or diagram, that contains the vertices of component Operators and the edges that connect them. The edges in the graph show which versions you can safely update to. The vertices are update payloads that specify the intended state of the managed cluster components.
The Cluster Version Operator (CVO) in your cluster checks with the OpenShift Update Service to see the valid updates and update paths based on current component versions and information in the graph. When you request an update, the CVO uses the release image for that update to update your cluster. The release artifacts are hosted in Quay as container images.
To allow the OpenShift Update Service to provide only compatible updates, a release verification pipeline drives automation. Each release artifact is verified for compatibility with supported cloud platforms and system architectures, as well as other component packages. After the pipeline confirms the suitability of a release, the OpenShift Update Service notifies you that it is available.
The OpenShift Update Service displays all recommended updates for your current cluster. If an update path is not recommended by the OpenShift Update Service, it might be because of a known issue with the update or the target release.
Two controllers run during continuous update mode. The first controller continuously updates the payload manifests, applies the manifests to the cluster, and outputs the controlled rollout status of the Operators to indicate whether they are available, upgrading, or failed. The second controller polls the OpenShift Update Service to determine if updates are available.
Only upgrading to a newer version is supported. Reverting or rolling back your cluster to a previous version is not supported. If your update fails, contact Red Hat support.
During the update process, the Machine Config Operator (MCO) applies the new configuration to your cluster machines. The MCO cordons the number of nodes as specified by the
maxUnavailable field on the machine configuration pool and marks them as unavailable. By default, this value is set to
1. The MCO then applies the new configuration and reboots the machine.
If you use Fedora machines as workers, the MCO does not update the kubelet because you must update the OpenShift API on the machines first.
With the specification for the new version applied to the old kubelet, the Fedora machine cannot return to the
Ready state. You cannot complete the update until the machines are available. However, the maximum number of unavailable nodes is set to ensure that normal cluster operations can continue with that number of machines out of service.
The OpenShift Update Service is composed of an Operator and one or more application instances.
The management state of an Operator determines whether an Operator is actively managing the resources for its related component in the cluster as designed. If an Operator is set to an unmanaged state, it does not respond to changes in configuration nor does it receive updates.
While this can be helpful in non-production clusters or during debugging, Operators in an unmanaged state are unsupported and the cluster administrator assumes full control of the individual component configurations and upgrades.
An Operator can be set to an unmanaged state using the following methods:
Individual Operator configuration
Individual Operators have a
managementState parameter in their configuration.
This can be accessed in different ways, depending on the Operator. For example,
the Red Hat OpenShift Logging Operator accomplishes this by modifying a custom resource
(CR) that it manages, while the Cluster Samples Operator uses a cluster-wide
managementState parameter to
Unmanaged means that the Operator
is not actively managing its resources and will take no action related to the
related component. Some Operators might not support this management state as it
might damage the cluster and require manual recovery.
Changing individual Operators to the
Cluster Version Operator (CVO) overrides
spec.overrides parameter can be added to the CVO’s configuration to allow
administrators to provide a list of overrides to the CVO’s behavior for a
component. Setting the
spec.overrides.unmanaged parameter to
true for a
component blocks cluster upgrades and alerts the administrator after a CVO
override has been set:
Disabling ownership via cluster version overrides prevents upgrades. Please remove overrides before continuing.
Setting a CVO override puts the entire cluster in an unsupported state. Reported issues must be reproduced after removing any overrides for support to proceed.