- Installing a cluster on oVirt in a restricted network
- Prerequisites
- About installations in restricted networks
- Requirements for the oVirt environment
- Verifying the requirements for the oVirt environment
- Networking requirements for user-provisioned infrastructure
- User-provisioned DNS requirements
- Setting up the installation machine
- Setting up the CA certificate for oVirt
- Generating a key pair for cluster node SSH access
- Downloading the Ansible playbooks
- The inventory.yml file
- Specifying the FCOS image settings
- Creating the install config file
- Sample install-config.yaml file for RHV
- Customizing install-config.yaml
- Generate manifest files
- Making control-plane nodes non-schedulable
- Building the Ignition files
- Creating templates and virtual machines
- Creating the bootstrap machine
- Creating the control plane nodes
- Verifying cluster status
- Removing the bootstrap machine
- Creating the worker nodes and completing the installation
- Disabling the default OperatorHub catalog sources
Installing a cluster on oVirt in a restricted network
In OKD version 4.12, you can install a customized OKD cluster on oVirt in a restricted network by creating an internal mirror of the installation release content.
Prerequisites
The following items are required to install an OKD cluster on a oVirt environment.
You reviewed details about the OKD installation and update processes.
You read the documentation on selecting a cluster installation method and preparing it for users.
You have a supported combination of versions in the Support Matrix for OKD on oVirt.
You created a registry on your mirror host and obtained the
imageContentSources
data for your version of OKD.Because the installation media is on the mirror host, you can use that computer to complete all installation steps.
You provisioned persistent storage for your cluster. To deploy a private image registry, your storage must provide ReadWriteMany access modes.
If you use a firewall and plan to use the Telemetry service, you configured the firewall to allow the sites that your cluster requires access to.
Be sure to also review this site list if you are configuring a proxy.
About installations in restricted networks
In OKD 4.12, you can perform an installation that does not require an active connection to the internet to obtain software components. Restricted network installations can be completed using installer-provisioned infrastructure or user-provisioned infrastructure, depending on the cloud platform to which you are installing the cluster.
If you choose to perform a restricted network installation on a cloud platform, you still require access to its cloud APIs. Some cloud functions, like Amazon Web Service’s Route 53 DNS and IAM services, require internet access. Depending on your network, you might require less internet access for an installation on bare metal hardware or on VMware vSphere.
To complete a restricted network installation, you must create a registry that mirrors the contents of the OKD registry and contains the installation media. You can create this registry on a mirror host, which can access both the internet and your closed network, or by using other methods that meet your restrictions.
Additional limits
Clusters in restricted networks have the following additional limitations and restrictions:
The
ClusterVersion
status includes anUnable to retrieve available updates
error.By default, you cannot use the contents of the Developer Catalog because you cannot access the required image stream tags.
Requirements for the oVirt environment
To install and run an OKD version 4.12 cluster, the oVirt environment must meet the following requirements.
Not meeting these requirements can cause the installation or process to fail. Additionally, not meeting these requirements can cause the OKD cluster to fail days or weeks after installation.
The following requirements for CPU, memory, and storage resources are based on default values multiplied by the default number of virtual machines the installation program creates. These resources must be available in addition to what the oVirt environment uses for non-OKD operations.
By default, the installation program creates seven virtual machines during the installation process. First, it creates a bootstrap virtual machine to provide temporary services and a control plane while it creates the rest of the OKD cluster. When the installation program finishes creating the cluster, deleting the bootstrap machine frees up its resources.
If you increase the number of virtual machines in the oVirt environment, you must increase the resources accordingly.
Requirements
The oVirt version is 4.4.
The oVirt environment has one data center whose state is Up.
The oVirt data center contains an oVirt cluster.
The oVirt cluster has the following resources exclusively for the OKD cluster:
Minimum 28 vCPUs: four for each of the seven virtual machines created during installation.
112 GiB RAM or more, including:
16 GiB or more for the bootstrap machine, which provides the temporary control plane.
16 GiB or more for each of the three control plane machines which provide the control plane.
16 GiB or more for each of the three compute machines, which run the application workloads.
The oVirt storage domain must meet these etcd backend performance requirements.
In production environments, each virtual machine must have 120 GiB or more. Therefore, the storage domain must provide 840 GiB or more for the default OKD cluster. In resource-constrained or non-production environments, each virtual machine must have 32 GiB or more, so the storage domain must have 230 GiB or more for the default OKD cluster.
To download images from the Red Hat Ecosystem Catalog during installation and update procedures, the oVirt cluster must have access to an internet connection. The Telemetry service also needs an internet connection to simplify the subscription and entitlement process.
The oVirt cluster must have a virtual network with access to the REST API on the oVirt Engine. Ensure that DHCP is enabled on this network, because the VMs that the installer creates obtain their IP address by using DHCP.
A user account and group with the following least privileges for installing and managing an OKD cluster on the target oVirt cluster:
DiskOperator
DiskCreator
UserTemplateBasedVm
TemplateOwner
TemplateCreator
ClusterAdmin
on the target cluster
Apply the principle of least privilege: Avoid using an administrator account with |
Verifying the requirements for the oVirt environment
Verify that the oVirt environment meets the requirements to install and run an OKD cluster. Not meeting these requirements can cause failures.
These requirements are based on the default resources the installation program uses to create control plane and compute machines. These resources include vCPUs, memory, and storage. If you change these resources or increase the number of OKD machines, adjust these requirements accordingly. |
Procedure
Check that the oVirt version supports installation of OKD version 4.12.
In the oVirt Administration Portal, click the ? help icon in the upper-right corner and select About.
In the window that opens, make a note of the oVirt Software Version.
Confirm that the oVirt version is 4.4. For more information about supported version combinations, see Support Matrix for OKD on oVirt.
Inspect the data center, cluster, and storage.
In the oVirt Administration Portal, click Compute → Data Centers.
Confirm that the data center where you plan to install OKD is accessible.
Click the name of that data center.
In the data center details, on the Storage tab, confirm the storage domain where you plan to install OKD is Active.
Record the Domain Name for use later on.
Confirm Free Space has at least 230 GiB.
Confirm that the storage domain meets these etcd backend performance requirements, which you can measure by using the fio performance benchmarking tool.
In the data center details, click the Clusters tab.
Find the oVirt cluster where you plan to install OKD. Record the cluster name for use later on.
Inspect the oVirt host resources.
In the oVirt Administration Portal, click Compute > Clusters.
Click the cluster where you plan to install OKD.
In the cluster details, click the Hosts tab.
Inspect the hosts and confirm they have a combined total of at least 28 Logical CPU Cores available exclusively for the OKD cluster.
Record the number of available Logical CPU Cores for use later on.
Confirm that these CPU cores are distributed so that each of the seven virtual machines created during installation can have four cores.
Confirm that, all together, the hosts have 112 GiB of Max free Memory for scheduling new virtual machines distributed to meet the requirements for each of the following OKD machines:
16 GiB required for the bootstrap machine
16 GiB required for each of the three control plane machines
16 GiB for each of the three compute machines
Record the amount of Max free Memory for scheduling new virtual machines for use later on.
Verify that the virtual network for installing OKD has access to the oVirt Engine’s REST API. From a virtual machine on this network, use curl to reach the oVirt Engine’s REST API:
$ curl -k -u <username>@<profile>:<password> \ (1)
https://<engine-fqdn>/ovirt-engine/api (2)
1 For <username>
, specify the user name of an oVirt account with privileges to create and manage an OKD cluster on oVirt. For<profile>
, specify the login profile, which you can get by going to the oVirt Administration Portal login page and reviewing the Profile dropdown list. For<password>
, specify the password for that user name.2 For <engine-fqdn>
, specify the fully qualified domain name of the oVirt environment.For example:
$ curl -k -u admin@internal:pw123 \
https://ovirtlab.example.com/ovirt-engine/api
Networking requirements for user-provisioned infrastructure
All the Fedora CoreOS (FCOS) machines require networking to be configured in initramfs
during boot to fetch their Ignition config files.
During the initial boot, the machines require an IP address configuration that is set either through a DHCP server or statically by providing the required boot options. After a network connection is established, the machines download their Ignition config files from an HTTP or HTTPS server. The Ignition config files are then used to set the exact state of each machine. The Machine Config Operator completes more changes to the machines, such as the application of new certificates or keys, after installation.
It is recommended to use a DHCP server for long-term management of the cluster machines. Ensure that the DHCP server is configured to provide persistent IP addresses, DNS server information, and hostnames to the cluster machines.
If a DHCP service is not available for your user-provisioned infrastructure, you can instead provide the IP networking configuration and the address of the DNS server to the nodes at FCOS install time. These can be passed as boot arguments if you are installing from an ISO image. See the Installing FCOS and starting the OKD bootstrap process section for more information about static IP provisioning and advanced networking options. |
The Kubernetes API server must be able to resolve the node names of the cluster machines. If the API servers and worker nodes are in different zones, you can configure a default DNS search zone to allow the API server to resolve the node names. Another supported approach is to always refer to hosts by their fully-qualified domain names in both the node objects and all DNS requests.
Firewall
Configure your firewall so your cluster has access to required sites.
See also:
DNS
Configure infrastructure-provided DNS to allow the correct resolution of the main components and services. If you use only one load balancer, these DNS records can point to the same IP address.
Create DNS records for
api.<cluster_name>.<base_domain>
(internal and external resolution) andapi-int.<cluster_name>.<base_domain>
(internal resolution) that point to the load balancer for the control plane machines.Create a DNS record for
*.apps.<cluster_name>.<base_domain>
that points to the load balancer for the Ingress router. For example, ports443
and80
of the compute machines.
Setting the cluster node hostnames through DHCP
On Fedora CoreOS (FCOS) machines, the hostname is set through NetworkManager. By default, the machines obtain their hostname through DHCP. If the hostname is not provided by DHCP, set statically through kernel arguments, or another method, it is obtained through a reverse DNS lookup. Reverse DNS lookup occurs after the network has been initialized on a node and can take time to resolve. Other system services can start prior to this and detect the hostname as localhost
or similar. You can avoid this by using DHCP to provide the hostname for each cluster node.
Additionally, setting the hostnames through DHCP can bypass any manual DNS record name configuration errors in environments that have a DNS split-horizon implementation.
Network connectivity requirements
You must configure the network connectivity between machines to allow OKD cluster components to communicate. Each machine must be able to resolve the hostnames of all other machines in the cluster.
This section provides details about the ports that are required.
In connected OKD environments, all nodes are required to have internet access to pull images for platform containers and provide telemetry data to Red Hat. |
Protocol | Port | Description |
---|---|---|
ICMP | N/A | Network reachability tests |
TCP |
| Metrics |
| Host level services, including the node exporter on ports | |
| The default ports that Kubernetes reserves | |
| openshift-sdn | |
UDP |
| VXLAN |
| Geneve | |
| Host level services, including the node exporter on ports | |
| IPsec IKE packets | |
| IPsec NAT-T packets | |
TCP/UDP |
| Kubernetes node port |
ESP | N/A | IPsec Encapsulating Security Payload (ESP) |
Protocol | Port | Description |
---|---|---|
TCP |
| Kubernetes API |
Protocol | Port | Description |
---|---|---|
TCP |
| etcd server and peer ports |
NTP configuration for user-provisioned infrastructure
OKD clusters are configured to use a public Network Time Protocol (NTP) server by default. If you want to use a local enterprise NTP server, or if your cluster is being deployed in a disconnected network, you can configure the cluster to use a specific time server. For more information, see the documentation for Configuring chrony time service.
If a DHCP server provides NTP server information, the chrony time service on the Fedora CoreOS (FCOS) machines read the information and can sync the clock with the NTP servers.
User-provisioned DNS requirements
In OKD deployments, DNS name resolution is required for the following components:
The Kubernetes API
The OKD application wildcard
The bootstrap, control plane, and compute machines
Reverse DNS resolution is also required for the Kubernetes API, the bootstrap machine, the control plane machines, and the compute machines.
DNS A/AAAA or CNAME records are used for name resolution and PTR records are used for reverse name resolution. The reverse records are important because Fedora CoreOS (FCOS) uses the reverse records to set the hostnames for all the nodes, unless the hostnames are provided by DHCP. Additionally, the reverse records are used to generate the certificate signing requests (CSR) that OKD needs to operate.
It is recommended to use a DHCP server to provide the hostnames to each cluster node. See the DHCP recommendations for user-provisioned infrastructure section for more information. |
The following DNS records are required for a user-provisioned OKD cluster and they must be in place before installation. In each record, <cluster_name>
is the cluster name and <base_domain>
is the base domain that you specify in the install-config.yaml
file. A complete DNS record takes the form: <component>.<cluster_name>.<base_domain>.
.
Component | Record | Description | |
---|---|---|---|
Kubernetes API |
| A DNS A/AAAA or CNAME record, and a DNS PTR record, to identify the API load balancer. These records must be resolvable by both clients external to the cluster and from all the nodes within the cluster. | |
| A DNS A/AAAA or CNAME record, and a DNS PTR record, to internally identify the API load balancer. These records must be resolvable from all the nodes within the cluster.
| ||
Routes |
| A wildcard DNS A/AAAA or CNAME record that refers to the application ingress load balancer. The application ingress load balancer targets the machines that run the Ingress Controller pods. The Ingress Controller pods run on the compute machines by default. These records must be resolvable by both clients external to the cluster and from all the nodes within the cluster. For example, | |
Bootstrap machine |
| A DNS A/AAAA or CNAME record, and a DNS PTR record, to identify the bootstrap machine. These records must be resolvable by the nodes within the cluster. | |
Control plane machines |
| DNS A/AAAA or CNAME records and DNS PTR records to identify each machine for the control plane nodes. These records must be resolvable by the nodes within the cluster. | |
Compute machines |
| DNS A/AAAA or CNAME records and DNS PTR records to identify each machine for the worker nodes. These records must be resolvable by the nodes within the cluster. |
In OKD 4.4 and later, you do not need to specify etcd host and SRV records in your DNS configuration. |
You can use the |
Example DNS configuration for user-provisioned clusters
This section provides A and PTR record configuration samples that meet the DNS requirements for deploying OKD on user-provisioned infrastructure. The samples are not meant to provide advice for choosing one DNS solution over another.
In the examples, the cluster name is ocp4
and the base domain is example.com
.
Example DNS A record configuration for a user-provisioned cluster
The following example is a BIND zone file that shows sample A records for name resolution in a user-provisioned cluster.
Sample DNS zone database
$TTL 1W
@ IN SOA ns1.example.com. root (
2019070700 ; serial
3H ; refresh (3 hours)
30M ; retry (30 minutes)
2W ; expiry (2 weeks)
1W ) ; minimum (1 week)
IN NS ns1.example.com.
IN MX 10 smtp.example.com.
;
;
ns1.example.com. IN A 192.168.1.5
smtp.example.com. IN A 192.168.1.5
;
helper.example.com. IN A 192.168.1.5
helper.ocp4.example.com. IN A 192.168.1.5
;
api.ocp4.example.com. IN A 192.168.1.5 (1)
api-int.ocp4.example.com. IN A 192.168.1.5 (2)
;
*.apps.ocp4.example.com. IN A 192.168.1.5 (3)
;
bootstrap.ocp4.example.com. IN A 192.168.1.96 (4)
;
master0.ocp4.example.com. IN A 192.168.1.97 (5)
master1.ocp4.example.com. IN A 192.168.1.98 (5)
master2.ocp4.example.com. IN A 192.168.1.99 (5)
;
worker0.ocp4.example.com. IN A 192.168.1.11 (6)
worker1.ocp4.example.com. IN A 192.168.1.7 (6)
;
;EOF
1 | Provides name resolution for the Kubernetes API. The record refers to the IP address of the API load balancer. | ||
2 | Provides name resolution for the Kubernetes API. The record refers to the IP address of the API load balancer and is used for internal cluster communications. | ||
3 | Provides name resolution for the wildcard routes. The record refers to the IP address of the application ingress load balancer. The application ingress load balancer targets the machines that run the Ingress Controller pods. The Ingress Controller pods run on the compute machines by default.
| ||
4 | Provides name resolution for the bootstrap machine. | ||
5 | Provides name resolution for the control plane machines. | ||
6 | Provides name resolution for the compute machines. |
Example DNS PTR record configuration for a user-provisioned cluster
The following example BIND zone file shows sample PTR records for reverse name resolution in a user-provisioned cluster.
Sample DNS zone database for reverse records
$TTL 1W
@ IN SOA ns1.example.com. root (
2019070700 ; serial
3H ; refresh (3 hours)
30M ; retry (30 minutes)
2W ; expiry (2 weeks)
1W ) ; minimum (1 week)
IN NS ns1.example.com.
;
5.1.168.192.in-addr.arpa. IN PTR api.ocp4.example.com. (1)
5.1.168.192.in-addr.arpa. IN PTR api-int.ocp4.example.com. (2)
;
96.1.168.192.in-addr.arpa. IN PTR bootstrap.ocp4.example.com. (3)
;
97.1.168.192.in-addr.arpa. IN PTR master0.ocp4.example.com. (4)
98.1.168.192.in-addr.arpa. IN PTR master1.ocp4.example.com. (4)
99.1.168.192.in-addr.arpa. IN PTR master2.ocp4.example.com. (4)
;
11.1.168.192.in-addr.arpa. IN PTR worker0.ocp4.example.com. (5)
7.1.168.192.in-addr.arpa. IN PTR worker1.ocp4.example.com. (5)
;
;EOF
1 | Provides reverse DNS resolution for the Kubernetes API. The PTR record refers to the record name of the API load balancer. |
2 | Provides reverse DNS resolution for the Kubernetes API. The PTR record refers to the record name of the API load balancer and is used for internal cluster communications. |
3 | Provides reverse DNS resolution for the bootstrap machine. |
4 | Provides reverse DNS resolution for the control plane machines. |
5 | Provides reverse DNS resolution for the compute machines. |
A PTR record is not required for the OKD application wildcard. |
Load balancing requirements for user-provisioned infrastructure
Before you install OKD, you must provision the API and application ingress load balancing infrastructure. In production scenarios, you can deploy the API and application ingress load balancers separately so that you can scale the load balancer infrastructure for each in isolation.
If you want to deploy the API and application ingress load balancers with a Fedora instance, you must purchase the Fedora subscription separately. |
The load balancing infrastructure must meet the following requirements:
API load balancer: Provides a common endpoint for users, both human and machine, to interact with and configure the platform. Configure the following conditions:
Layer 4 load balancing only. This can be referred to as Raw TCP, SSL Passthrough, or SSL Bridge mode. If you use SSL Bridge mode, you must enable Server Name Indication (SNI) for the API routes.
A stateless load balancing algorithm. The options vary based on the load balancer implementation.
Session persistence is not required for the API load balancer to function properly.
Configure the following ports on both the front and back of the load balancers:
Table 5. API load balancer Port Back-end machines (pool members) Internal External Description 6443
Bootstrap and control plane. You remove the bootstrap machine from the load balancer after the bootstrap machine initializes the cluster control plane. You must configure the
/readyz
endpoint for the API server health check probe.X
X
Kubernetes API server
22623
Bootstrap and control plane. You remove the bootstrap machine from the load balancer after the bootstrap machine initializes the cluster control plane.
X
Machine config server
The load balancer must be configured to take a maximum of 30 seconds from the time the API server turns off the
/readyz
endpoint to the removal of the API server instance from the pool. Within the time frame after/readyz
returns an error or becomes healthy, the endpoint must have been removed or added. Probing every 5 or 10 seconds, with two successful requests to become healthy and three to become unhealthy, are well-tested values.Application ingress load balancer: Provides an ingress point for application traffic flowing in from outside the cluster. Configure the following conditions:
Layer 4 load balancing only. This can be referred to as Raw TCP, SSL Passthrough, or SSL Bridge mode. If you use SSL Bridge mode, you must enable Server Name Indication (SNI) for the ingress routes.
A connection-based or session-based persistence is recommended, based on the options available and types of applications that will be hosted on the platform.
If the true IP address of the client can be seen by the application ingress load balancer, enabling source IP-based session persistence can improve performance for applications that use end-to-end TLS encryption.
Configure the following ports on both the front and back of the load balancers:
Table 6. Application ingress load balancer Port Back-end machines (pool members) Internal External Description 443
The machines that run the Ingress Controller pods, compute, or worker, by default.
X
X
HTTPS traffic
80
The machines that run the Ingress Controller pods, compute, or worker, by default.
X
X
HTTP traffic
1936
The worker nodes that run the Ingress Controller pods, by default. You must configure the
/healthz/ready
endpoint for the ingress health check probe.X
X
HTTP traffic
If you are deploying a three-node cluster with zero compute nodes, the Ingress Controller pods run on the control plane nodes. In three-node cluster deployments, you must configure your application ingress load balancer to route HTTP and HTTPS traffic to the control plane nodes. |
A working configuration for the Ingress router is required for an OKD cluster. You must configure the Ingress router after the control plane initializes. |
Example load balancer configuration for user-provisioned clusters
This section provides an example API and application ingress load balancer configuration that meets the load balancing requirements for user-provisioned clusters. The sample is an /etc/haproxy/haproxy.cfg
configuration for an HAProxy load balancer. The example is not meant to provide advice for choosing one load balancing solution over another.
In the example, the same load balancer is used for the Kubernetes API and application ingress traffic. In production scenarios you can deploy the API and application ingress load balancers separately so that you can scale the load balancer infrastructure for each in isolation. |
Sample API and application ingress load balancer configuration
global
log 127.0.0.1 local2
pidfile /var/run/haproxy.pid
maxconn 4000
daemon
defaults
mode http
log global
option dontlognull
option http-server-close
option redispatch
retries 3
timeout http-request 10s
timeout queue 1m
timeout connect 10s
timeout client 1m
timeout server 1m
timeout http-keep-alive 10s
timeout check 10s
maxconn 3000
frontend stats
bind *:1936
mode http
log global
maxconn 10
stats enable
stats hide-version
stats refresh 30s
stats show-node
stats show-desc Stats for ocp4 cluster (1)
stats auth admin:ocp4
stats uri /stats
listen api-server-6443 (2)
bind *:6443
mode tcp
server bootstrap bootstrap.ocp4.example.com:6443 check inter 1s backup (3)
server master0 master0.ocp4.example.com:6443 check inter 1s
server master1 master1.ocp4.example.com:6443 check inter 1s
server master2 master2.ocp4.example.com:6443 check inter 1s
listen machine-config-server-22623 (4)
bind *:22623
mode tcp
server bootstrap bootstrap.ocp4.example.com:22623 check inter 1s backup (3)
server master0 master0.ocp4.example.com:22623 check inter 1s
server master1 master1.ocp4.example.com:22623 check inter 1s
server master2 master2.ocp4.example.com:22623 check inter 1s
listen ingress-router-443 (5)
bind *:443
mode tcp
balance source
server worker0 worker0.ocp4.example.com:443 check inter 1s
server worker1 worker1.ocp4.example.com:443 check inter 1s
listen ingress-router-80 (6)
bind *:80
mode tcp
balance source
server worker0 worker0.ocp4.example.com:80 check inter 1s
server worker1 worker1.ocp4.example.com:80 check inter 1s
1 | In the example, the cluster name is ocp4 . | ||
2 | Port 6443 handles the Kubernetes API traffic and points to the control plane machines. | ||
3 | The bootstrap entries must be in place before the OKD cluster installation and they must be removed after the bootstrap process is complete. | ||
4 | Port 22623 handles the machine config server traffic and points to the control plane machines. | ||
5 | Port 443 handles the HTTPS traffic and points to the machines that run the Ingress Controller pods. The Ingress Controller pods run on the compute machines by default. | ||
6 | Port 80 handles the HTTP traffic and points to the machines that run the Ingress Controller pods. The Ingress Controller pods run on the compute machines by default.
|
If you are using HAProxy as a load balancer, you can check that the |
If you are using HAProxy as a load balancer and SELinux is set to |
Setting up the installation machine
To run the binary openshift-install
installation program and Ansible scripts, set up the oVirt Engine or an Fedora computer with network access to the oVirt environment and the REST API on the Engine.
Procedure
Update or install Python3 and Ansible. For example:
# dnf update python3 ansible
Install the python3-ovirt-engine-sdk4 package to get the Python Software Development Kit.
Install the
ovirt.image-template
Ansible role. On the oVirt Engine and other Fedora machines, this role is distributed as theovirt-ansible-image-template
package. For example, enter:# dnf install ovirt-ansible-image-template
Install the
ovirt.vm-infra
Ansible role. On the oVirt Engine and other Fedora machines, this role is distributed as theovirt-ansible-vm-infra
package.# dnf install ovirt-ansible-vm-infra
Create an environment variable and assign an absolute or relative path to it. For example, enter:
$ export ASSETS_DIR=./wrk
The installation program uses this variable to create a directory where it saves important installation-related files. Later, the installation process reuses this variable to locate those asset files. Avoid deleting this assets directory; it is required for uninstalling the cluster.
Setting up the CA certificate for oVirt
Download the CA certificate from the oVirt Manager and set it up on the installation machine.
You can download the certificate from a webpage on the oVirt Engine or by using a curl
command.
Later, you provide the certificate to the installation program.
Procedure
Use either of these two methods to download the CA certificate:
Go to the Engine’s webpage,
https://<engine-fqdn>/ovirt-engine/
. Then, under Downloads, click the CA Certificate link.Run the following command:
$ curl -k 'https://<engine-fqdn>/ovirt-engine/services/pki-resource?resource=ca-certificate&format=X509-PEM-CA' -o /tmp/ca.pem (1)
1 For <engine-fqdn>
, specify the fully qualified domain name of the oVirt Engine, such asrhv-env.virtlab.example.com
.
Configure the CA file to grant rootless user access to the Engine. Set the CA file permissions to have an octal value of
0644
(symbolic value:-rw-r—r--
):$ sudo chmod 0644 /tmp/ca.pem
For Linux, copy the CA certificate to the directory for server certificates. Use
-p
to preserve the permissions:$ sudo cp -p /tmp/ca.pem /etc/pki/ca-trust/source/anchors/ca.pem
Add the certificate to the certificate manager for your operating system:
For macOS, double-click the certificate file and use the Keychain Access utility to add the file to the System keychain.
For Linux, update the CA trust:
$ sudo update-ca-trust
If you use your own certificate authority, make sure the system trusts it.
Additional resources
- To learn more, see Authentication and Security in the oVirt documentation.
Generating a key pair for cluster node SSH access
During an OKD installation, you can provide an SSH public key to the installation program. The key is passed to the Fedora CoreOS (FCOS) nodes through their Ignition config files and is used to authenticate SSH access to the nodes. The key is added to the ~/.ssh/authorized_keys
list for the core
user on each node, which enables password-less authentication.
After the key is passed to the nodes, you can use the key pair to SSH in to the FCOS nodes as the user core
. To access the nodes through SSH, the private key identity must be managed by SSH for your local user.
If you want to SSH in to your cluster nodes to perform installation debugging or disaster recovery, you must provide the SSH public key during the installation process. The ./openshift-install gather
command also requires the SSH public key to be in place on the cluster nodes.
Do not skip this procedure in production environments, where disaster recovery and debugging is required. |
You must use a local key, not one that you configured with platform-specific approaches such as AWS key pairs. |
On clusters running Fedora CoreOS (FCOS), the SSH keys specified in the Ignition config files are written to the |
Procedure
If you do not have an existing SSH key pair on your local machine to use for authentication onto your cluster nodes, create one. For example, on a computer that uses a Linux operating system, run the following command:
$ ssh-keygen -t ed25519 -N '' -f <path>/<file_name> (1)
1 Specify the path and file name, such as ~/.ssh/id_ed25519
, of the new SSH key. If you have an existing key pair, ensure your public key is in the your~/.ssh
directory.If you plan to install an OKD cluster that uses FIPS Validated / Modules in Process cryptographic libraries on the
x86_64
architecture, do not create a key that uses theed25519
algorithm. Instead, create a key that uses thersa
orecdsa
algorithm.View the public SSH key:
$ cat <path>/<file_name>.pub
For example, run the following to view the
~/.ssh/id_ed25519.pub
public key:$ cat ~/.ssh/id_ed25519.pub
Add the SSH private key identity to the SSH agent for your local user, if it has not already been added. SSH agent management of the key is required for password-less SSH authentication onto your cluster nodes, or if you want to use the
./openshift-install gather
command.On some distributions, default SSH private key identities such as
~/.ssh/id_rsa
and~/.ssh/id_dsa
are managed automatically.If the
ssh-agent
process is not already running for your local user, start it as a background task:$ eval "$(ssh-agent -s)"
Example output
Agent pid 31874
If your cluster is in FIPS mode, only use FIPS-compliant algorithms to generate the SSH key. The key must be either RSA or ECDSA.
Add your SSH private key to the
ssh-agent
:$ ssh-add <path>/<file_name> (1)
1 Specify the path and file name for your SSH private key, such as ~/.ssh/id_ed25519
Example output
Identity added: /home/<you>/<path>/<file_name> (<computer_name>)
Next steps
- When you install OKD, provide the SSH public key to the installation program.
Downloading the Ansible playbooks
Download the Ansible playbooks for installing OKD version 4.12 on oVirt.
Procedure
On your installation machine, run the following commands:
$ mkdir playbooks
$ cd playbooks
$ xargs -n 1 curl -O <<< '
https://raw.githubusercontent.com/openshift/installer/release-4.12/upi/ovirt/bootstrap.yml
https://raw.githubusercontent.com/openshift/installer/release-4.12/upi/ovirt/common-auth.yml
https://raw.githubusercontent.com/openshift/installer/release-4.12/upi/ovirt/create-templates-and-vms.yml
https://raw.githubusercontent.com/openshift/installer/release-4.12/upi/ovirt/inventory.yml
https://raw.githubusercontent.com/openshift/installer/release-4.12/upi/ovirt/masters.yml
https://raw.githubusercontent.com/openshift/installer/release-4.12/upi/ovirt/retire-bootstrap.yml
https://raw.githubusercontent.com/openshift/installer/release-4.12/upi/ovirt/retire-masters.yml
https://raw.githubusercontent.com/openshift/installer/release-4.12/upi/ovirt/retire-workers.yml
https://raw.githubusercontent.com/openshift/installer/release-4.12/upi/ovirt/workers.yml'
Next steps
- After you download these Ansible playbooks, you must also create the environment variable for the assets directory and customize the
inventory.yml
file before you create an installation configuration file by running the installation program.
The inventory.yml file
You use the inventory.yml
file to define and create elements of the OKD cluster you are installing. This includes elements such as the Fedora CoreOS (FCOS) image, virtual machine templates, bootstrap machine, control plane nodes, and worker nodes. You also use inventory.yml
to destroy the cluster.
The following inventory.yml
example shows you the parameters and their default values. The quantities and numbers in these default values meet the requirements for running a production OKD cluster in a oVirt environment.
Example inventory.yml
file
---
all:
vars:
ovirt_cluster: "Default"
ocp:
assets_dir: "{{ lookup('env', 'ASSETS_DIR') }}"
ovirt_config_path: "{{ lookup('env', 'HOME') }}/.ovirt/ovirt-config.yaml"
# ---
# {op-system} section
# ---
rhcos:
image_url: "https://mirror.openshift.com/pub/openshift-v4/dependencies/rhcos/4.12/latest/rhcos-openstack.x86_64.qcow2.gz"
local_cmp_image_path: "/tmp/rhcos.qcow2.gz"
local_image_path: "/tmp/rhcos.qcow2"
# ---
# Profiles section
# ---
control_plane:
cluster: "{{ ovirt_cluster }}"
memory: 16GiB
sockets: 4
cores: 1
template: rhcos_tpl
operating_system: "rhcos_x64"
type: high_performance
graphical_console:
headless_mode: false
protocol:
- spice
- vnc
disks:
- size: 120GiB
name: os
interface: virtio_scsi
storage_domain: depot_nvme
nics:
- name: nic1
network: lab
profile: lab
compute:
cluster: "{{ ovirt_cluster }}"
memory: 16GiB
sockets: 4
cores: 1
template: worker_rhcos_tpl
operating_system: "rhcos_x64"
type: high_performance
graphical_console:
headless_mode: false
protocol:
- spice
- vnc
disks:
- size: 120GiB
name: os
interface: virtio_scsi
storage_domain: depot_nvme
nics:
- name: nic1
network: lab
profile: lab
# ---
# Virtual machines section
# ---
vms:
- name: "{{ metadata.infraID }}-bootstrap"
ocp_type: bootstrap
profile: "{{ control_plane }}"
type: server
- name: "{{ metadata.infraID }}-master0"
ocp_type: master
profile: "{{ control_plane }}"
- name: "{{ metadata.infraID }}-master1"
ocp_type: master
profile: "{{ control_plane }}"
- name: "{{ metadata.infraID }}-master2"
ocp_type: master
profile: "{{ control_plane }}"
- name: "{{ metadata.infraID }}-worker0"
ocp_type: worker
profile: "{{ compute }}"
- name: "{{ metadata.infraID }}-worker1"
ocp_type: worker
profile: "{{ compute }}"
- name: "{{ metadata.infraID }}-worker2"
ocp_type: worker
profile: "{{ compute }}"
Enter values for parameters whose descriptions begin with “Enter.” Otherwise, you can use the default value or replace it with a new value. |
General section
ovirt_cluster
: Enter the name of an existing oVirt cluster in which to install the OKD cluster.ocp.assets_dir
: The path of a directory theopenshift-install
installation program creates to store the files that it generates.ocp.ovirt_config_path
: The path of theovirt-config.yaml
file the installation program generates, for example,./wrk/install-config.yaml
. This file contains the credentials required to interact with the REST API of the Engine.
Fedora CoreOS (FCOS) section
image_url
: Enter the URL of the FCOS image you specified for download.local_cmp_image_path
: The path of a local download directory for the compressed FCOS image.local_image_path
: The path of a local directory for the extracted FCOS image.
Profiles section
This section consists of two profiles:
control_plane
: The profile of the bootstrap and control plane nodes.compute
: The profile of workers nodes in the compute plane.
These profiles have the following parameters. The default values of the parameters meet the minimum requirements for running a production cluster. You can increase or customize these values to meet your workload requirements.
cluster
: The value gets the cluster name fromovirt_cluster
in the General Section.memory
: The amount of memory, in GB, for the virtual machine.sockets
: The number of sockets for the virtual machine.cores
: The number of cores for the virtual machine.template
: The name of the virtual machine template. If plan to install multiple clusters, and these clusters use templates that contain different specifications, prepend the template name with the ID of the cluster.operating_system
: The type of guest operating system in the virtual machine. With oVirt/oVirt version 4.4, this value must berhcos_x64
so the value ofIgnition script
can be passed to the VM.type
: Enterserver
as the type of the virtual machine.You must change the value of the
type
parameter fromhigh_performance
toserver
.disks
: The disk specifications. Thecontrol_plane
andcompute
nodes can have different storage domains.size
: The minimum disk size.name
: Enter the name of a disk connected to the target cluster in oVirt.interface
: Enter the interface type of the disk you specified.storage_domain
: Enter the storage domain of the disk you specified.nics
: Enter thename
andnetwork
the virtual machines use. You can also specify the virtual network interface profile. By default, NICs obtain their MAC addresses from the oVirt/oVirt MAC pool.
Virtual machines section
This final section, vms
, defines the virtual machines you plan to create and deploy in the cluster. By default, it provides the minimum number of control plane and worker nodes for a production environment.
vms
contains three required elements:
name
: The name of the virtual machine. In this case,metadata.infraID
prepends the virtual machine name with the infrastructure ID from themetadata.yml
file.ocp_type
: The role of the virtual machine in the OKD cluster. Possible values arebootstrap
,master
,worker
.profile
: The name of the profile from which each virtual machine inherits specifications. Possible values in this example arecontrol_plane
orcompute
.You can override the value a virtual machine inherits from its profile. To do this, you add the name of the profile attribute to the virtual machine in
inventory.yml
and assign it an overriding value. To see an example of this, examine thename: "{{ metadata.infraID }}-bootstrap"
virtual machine in the precedinginventory.yml
example: It has atype
attribute whose value,server
, overrides the value of thetype
attribute this virtual machine would otherwise inherit from thecontrol_plane
profile.
Metadata variables
For virtual machines, metadata.infraID
prepends the name of the virtual machine with the infrastructure ID from the metadata.json
file you create when you build the Ignition files.
The playbooks use the following code to read infraID
from the specific file located in the ocp.assets_dir
.
---
- name: include metadata.json vars
include_vars:
file: "{{ ocp.assets_dir }}/metadata.json"
name: metadata
...
Specifying the FCOS image settings
Update the Fedora CoreOS (FCOS) image settings of the inventory.yml
file. Later, when you run this file one of the playbooks, it downloads a compressed Fedora CoreOS (FCOS) image from the image_url
URL to the local_cmp_image_path
directory. The playbook then uncompresses the image to the local_image_path
directory and uses it to create oVirt/oVirt templates.
Procedure
Locate the FCOS image download page, such as Download Fedora CoreOS.
From that download page, copy the URL of an OpenStack
qcow2
image, such ashttps://builds.coreos.fedoraproject.org/prod/streams/stable/builds/34.20210611.3.0/x86_64/fedora-coreos-34.20210611.3.0-openstack.x86_64.qcow2.xz
.Edit the
inventory.yml
playbook you downloaded earlier. In it, replace therhcos
stanza and paste the URL as the value forimage_url
. For example:rhcos:
image_url: "https://builds.coreos.fedoraproject.org/prod/streams/stable/builds/34.20210611.3.0/x86_64/fedora-coreos-34.20210611.3.0-openstack.x86_64.qcow2.xz"
Creating the install config file
You create an installation configuration file by running the installation program, openshift-install
, and responding to its prompts with information you specified or gathered earlier.
When you finish responding to the prompts, the installation program creates an initial version of the install-config.yaml
file in the assets directory you specified earlier, for example, ./wrk/install-config.yaml
The installation program also creates a file, $HOME/.ovirt/ovirt-config.yaml
, that contains all the connection parameters that are required to reach the Engine and use its REST API.
NOTE: The installation process does not use values you supply for some parameters, such as Internal API virtual IP
and Ingress virtual IP
, because you have already configured them in your infrastructure DNS.
It also uses the values you supply for parameters in inventory.yml
, like the ones for oVirt cluster
, oVirt storage
, and oVirt network
. And uses a script to remove or replace these same values from install-config.yaml
with the previously mentioned virtual IPs
.
Procedure
Run the installation program:
$ openshift-install create install-config --dir $ASSETS_DIR
Respond to the installation program’s prompts with information about your system.
For
Internal API virtual IP
andIngress virtual IP
, supply the IP addresses you specified when you configured the DNS service.
Together, the values you enter for the oVirt cluster
and Base Domain
prompts form the FQDN portion of URLs for the REST API and any applications you create, such as https://api.ocp4.example.org:6443/
and https://console-openshift-console.apps.ocp4.example.org
.
You can get the pull secret from the Red Hat OpenShift Cluster Manager.
Sample install-config.yaml file for RHV
You can customize the install-config.yaml
file to specify more details about your OKD cluster’s platform or modify the values of the required parameters.
apiVersion: v1
baseDomain: example.com (1)
compute: (2)
- hyperthreading: Enabled (3)
name: worker
replicas: 0 (4)
controlPlane: (2)
hyperthreading: Enabled (3)
name: master
replicas: 3 (5)
metadata:
name: test (6)
networking:
clusterNetwork:
- cidr: 10.128.0.0/14 (7)
hostPrefix: 23 (8)
networkType: OVNKubernetes (9)
serviceNetwork: (10)
- 172.30.0.0/16
platform:
none: {} (11)
pullSecret: '{"auths": ...}' (12)
sshKey: 'ssh-ed25519 AAAA...' (13)
1 | The base domain of the cluster. All DNS records must be sub-domains of this base and include the cluster name. | ||||
2 | The controlPlane section is a single mapping, but the compute section is a sequence of mappings. To meet the requirements of the different data structures, the first line of the compute section must begin with a hyphen, - , and the first line of the controlPlane section must not. Only one control plane pool is used. | ||||
3 | Specifies whether to enable or disable simultaneous multithreading (SMT), or hyperthreading. By default, SMT is enabled to increase the performance of the cores in your machines. You can disable it by setting the parameter value to Disabled . If you disable SMT, you must disable it in all cluster machines; this includes both control plane and compute machines.
| ||||
4 | You must set this value to 0 when you install OKD on user-provisioned infrastructure. In installer-provisioned installations, the parameter controls the number of compute machines that the cluster creates and manages for you. In user-provisioned installations, you must manually deploy the compute machines before you finish installing the cluster.
| ||||
5 | The number of control plane machines that you add to the cluster. Because the cluster uses these values as the number of etcd endpoints in the cluster, the value must match the number of control plane machines that you deploy. | ||||
6 | The cluster name that you specified in your DNS records. | ||||
7 | A block of IP addresses from which pod IP addresses are allocated. This block must not overlap with existing physical networks. These IP addresses are used for the pod network. If you need to access the pods from an external network, you must configure load balancers and routers to manage the traffic.
| ||||
8 | The subnet prefix length to assign to each individual node. For example, if hostPrefix is set to 23 , then each node is assigned a /23 subnet out of the given cidr , which allows for 510 (2^(32 - 23) - 2) pod IP addresses. If you are required to provide access to nodes from an external network, configure load balancers and routers to manage the traffic. | ||||
9 | The cluster network plugin to install. The supported values are OVNKubernetes and OpenShiftSDN . The default value is OVNKubernetes . | ||||
10 | The IP address pool to use for service IP addresses. You can enter only one IP address pool. This block must not overlap with existing physical networks. If you need to access the services from an external network, configure load balancers and routers to manage the traffic. | ||||
11 | You must set the platform to none . You cannot provide additional platform configuration variables for RHV infrastructure. | ||||
12 | The pull secret from the Red Hat OpenShift Cluster Manager. This pull secret allows you to authenticate with the services that are provided by the included authorities, including Quay.io, which serves the container images for OKD components. | ||||
13 | The SSH public key for the core user in Fedora CoreOS (FCOS).
|
Configuring the cluster-wide proxy during installation
Production environments can deny direct access to the internet and instead have an HTTP or HTTPS proxy available. You can configure a new OKD cluster to use a proxy by configuring the proxy settings in the install-config.yaml
file.
Prerequisites
You have an existing
install-config.yaml
file.You reviewed the sites that your cluster requires access to and determined whether any of them need to bypass the proxy. By default, all cluster egress traffic is proxied, including calls to hosting cloud provider APIs. You added sites to the
Proxy
object’sspec.noProxy
field to bypass the proxy if necessary.The
Proxy
objectstatus.noProxy
field is populated with the values of thenetworking.machineNetwork[].cidr
,networking.clusterNetwork[].cidr
, andnetworking.serviceNetwork[]
fields from your installation configuration.For installations on Amazon Web Services (AWS), Google Cloud Platform (GCP), Microsoft Azure, and OpenStack, the
Proxy
objectstatus.noProxy
field is also populated with the instance metadata endpoint (169.254.169.254
).
Procedure
Edit your
install-config.yaml
file and add the proxy settings. For example:apiVersion: v1
baseDomain: my.domain.com
proxy:
httpProxy: http://<username>:<pswd>@<ip>:<port> (1)
httpsProxy: https://<username>:<pswd>@<ip>:<port> (2)
noProxy: example.com (3)
additionalTrustBundle: | (4)
-----BEGIN CERTIFICATE-----
<MY_TRUSTED_CA_CERT>
-----END CERTIFICATE-----
additionalTrustBundlePolicy: <policy_to_add_additionalTrustBundle> (5)
1 A proxy URL to use for creating HTTP connections outside the cluster. The URL scheme must be http
.2 A proxy URL to use for creating HTTPS connections outside the cluster. 3 A comma-separated list of destination domain names, IP addresses, or other network CIDRs to exclude from proxying. Preface a domain with .
to match subdomains only. For example,.y.com
matchesx.y.com
, but noty.com
. Use*
to bypass the proxy for all destinations.4 If provided, the installation program generates a config map that is named user-ca-bundle
in theopenshift-config
namespace that contains one or more additional CA certificates that are required for proxying HTTPS connections. The Cluster Network Operator then creates atrusted-ca-bundle
config map that merges these contents with the Fedora CoreOS (FCOS) trust bundle, and this config map is referenced in thetrustedCA
field of theProxy
object. TheadditionalTrustBundle
field is required unless the proxy’s identity certificate is signed by an authority from the FCOS trust bundle.5 Optional: The policy to determine the configuration of the Proxy
object to reference theuser-ca-bundle
config map in thetrustedCA
field. The allowed values areProxyonly
andAlways
. UseProxyonly
to reference theuser-ca-bundle
config map only whenhttp/https
proxy is configured. UseAlways
to always reference theuser-ca-bundle
config map. The default value isProxyonly
.The installation program does not support the proxy
readinessEndpoints
field.Save the file and reference it when installing OKD.
The installation program creates a cluster-wide proxy that is named cluster
that uses the proxy settings in the provided install-config.yaml
file. If no proxy settings are provided, a cluster
Proxy
object is still created, but it will have a nil spec
.
Only the |
Customizing install-config.yaml
Here, you use three Python scripts to override some of the installation program’s default behaviors:
By default, the installation program uses the machine API to create nodes. To override this default behavior, you set the number of compute nodes to zero replicas. Later, you use Ansible playbooks to create the compute nodes.
By default, the installation program sets the IP range of the machine network for nodes. To override this default behavior, you set the IP range to match your infrastructure.
By default, the installation program sets the platform to
ovirt
. However, installing a cluster on user-provisioned infrastructure is more similar to installing a cluster on bare metal. Therefore, you delete the ovirt platform section frominstall-config.yaml
and change the platform tonone
. Instead, you useinventory.yml
to specify all of the required settings.
These snippets work with Python 3 and Python 2. |
Procedure
Set the number of compute nodes to zero replicas:
$ python3 -c 'import os, yaml
path = "%s/install-config.yaml" % os.environ["ASSETS_DIR"]
conf = yaml.safe_load(open(path))
conf["compute"][0]["replicas"] = 0
open(path, "w").write(yaml.dump(conf, default_flow_style=False))'
Set the IP range of the machine network. For example, to set the range to
172.16.0.0/16
, enter:$ python3 -c 'import os, yaml
path = "%s/install-config.yaml" % os.environ["ASSETS_DIR"]
conf = yaml.safe_load(open(path))
conf["networking"]["machineNetwork"][0]["cidr"] = "172.16.0.0/16"
open(path, "w").write(yaml.dump(conf, default_flow_style=False))'
Remove the
ovirt
section and change the platform tonone
:$ python3 -c 'import os, yaml
path = "%s/install-config.yaml" % os.environ["ASSETS_DIR"]
conf = yaml.safe_load(open(path))
platform = conf["platform"]
del platform["ovirt"]
platform["none"] = {}
open(path, "w").write(yaml.dump(conf, default_flow_style=False))'
Red Hat Virtualization does not currently support installation with user-provisioned infrastructure on the oVirt platform. Therefore, you must set the platform to
none
, allowing OKD to identify each node as a bare-metal node and the cluster as a bare-metal cluster. This is the same as installing a cluster on any platform, and has the following limitations:There will be no cluster provider so you must manually add each machine and there will be no node scaling capabilities.
The oVirt CSI driver will not be installed and there will be no CSI capabilities.
Generate manifest files
Use the installation program to generate a set of manifest files in the assets directory.
The command to generate the manifest files displays a warning message before it consumes the install-config.yaml
file.
If you plan to reuse the install-config.yaml
file, create a backup copy of it before you back it up before you generate the manifest files.
Procedure
Optional: Create a backup copy of the
install-config.yaml
file:$ cp install-config.yaml install-config.yaml.backup
Generate a set of manifests in your assets directory:
$ openshift-install create manifests --dir $ASSETS_DIR
This command displays the following messages.
Example output
INFO Consuming Install Config from target directory
WARNING Making control-plane schedulable by setting MastersSchedulable to true for Scheduler cluster settings
The command generates the following manifest files:
Example output
$ tree
.
└── wrk
├── manifests
│ ├── 04-openshift-machine-config-operator.yaml
│ ├── cluster-config.yaml
│ ├── cluster-dns-02-config.yml
│ ├── cluster-infrastructure-02-config.yml
│ ├── cluster-ingress-02-config.yml
│ ├── cluster-network-01-crd.yml
│ ├── cluster-network-02-config.yml
│ ├── cluster-proxy-01-config.yaml
│ ├── cluster-scheduler-02-config.yml
│ ├── cvo-overrides.yaml
│ ├── etcd-ca-bundle-configmap.yaml
│ ├── etcd-client-secret.yaml
│ ├── etcd-host-service-endpoints.yaml
│ ├── etcd-host-service.yaml
│ ├── etcd-metric-client-secret.yaml
│ ├── etcd-metric-serving-ca-configmap.yaml
│ ├── etcd-metric-signer-secret.yaml
│ ├── etcd-namespace.yaml
│ ├── etcd-service.yaml
│ ├── etcd-serving-ca-configmap.yaml
│ ├── etcd-signer-secret.yaml
│ ├── kube-cloud-config.yaml
│ ├── kube-system-configmap-root-ca.yaml
│ ├── machine-config-server-tls-secret.yaml
│ └── openshift-config-secret-pull-secret.yaml
└── openshift
├── 99_kubeadmin-password-secret.yaml
├── 99_openshift-cluster-api_master-user-data-secret.yaml
├── 99_openshift-cluster-api_worker-user-data-secret.yaml
├── 99_openshift-machineconfig_99-master-ssh.yaml
├── 99_openshift-machineconfig_99-worker-ssh.yaml
└── openshift-install-manifests.yaml
Next steps
- Make control plane nodes non-schedulable.
Making control-plane nodes non-schedulable
Because you are manually creating and deploying the control plane machines, you must configure a manifest file to make the control plane nodes non-schedulable.
Procedure
To make the control plane nodes non-schedulable, enter:
$ python3 -c 'import os, yaml
path = "%s/manifests/cluster-scheduler-02-config.yml" % os.environ["ASSETS_DIR"]
data = yaml.safe_load(open(path))
data["spec"]["mastersSchedulable"] = False
open(path, "w").write(yaml.dump(data, default_flow_style=False))'
Building the Ignition files
To build the Ignition files from the manifest files you just generated and modified, you run the installation program. This action creates a Fedora CoreOS (FCOS) machine, initramfs
, which fetches the Ignition files and performs the configurations needed to create a node.
In addition to the Ignition files, the installation program generates the following:
An
auth
directory that contains the admin credentials for connecting to the cluster with theoc
andkubectl
utilities.A
metadata.json
file that contains information such as the OKD cluster name, cluster ID, and infrastructure ID for the current installation.
The Ansible playbooks for this installation process use the value of infraID
as a prefix for the virtual machines they create. This prevents naming conflicts when there are multiple installations in the same oVirt/oVirt cluster.
Certificates in Ignition configuration files expire after 24 hours. Complete the cluster installation and keep the cluster running in a non-degraded state for 24 hours so that the first certificate rotation can finish. |
Procedure
To build the Ignition files, enter:
$ openshift-install create ignition-configs --dir $ASSETS_DIR
Example output
$ tree
.
└── wrk
├── auth
│ ├── kubeadmin-password
│ └── kubeconfig
├── bootstrap.ign
├── master.ign
├── metadata.json
└── worker.ign
Creating templates and virtual machines
After confirming the variables in the inventory.yml
, you run the first Ansible provisioning playbook, create-templates-and-vms.yml
.
This playbook uses the connection parameters for the oVirt Engine from $HOME/.ovirt/ovirt-config.yaml
and reads metadata.json
in the assets directory.
If a local Fedora CoreOS (FCOS) image is not already present, the playbook downloads one from the URL you specified for image_url
in inventory.yml
. It extracts the image and uploads it to oVirt to create templates.
The playbook creates a template based on the control_plane
and compute
profiles in the inventory.yml
file. If these profiles have different names, it creates two templates.
When the playbook finishes, the virtual machines it creates are stopped. You can get information from them to help configure other infrastructure elements. For example, you can get the virtual machines’ MAC addresses to configure DHCP to assign permanent IP addresses to the virtual machines.
Procedure
In
inventory.yml
, under thecontrol_plane
andcompute
variables, change both instances oftype: high_performance
totype: server
.Optional: If you plan to perform multiple installations to the same cluster, create different templates for each OKD installation. In the
inventory.yml
file, prepend the value oftemplate
withinfraID
. For example:control_plane:
cluster: "{{ ovirt_cluster }}"
memory: 16GiB
sockets: 4
cores: 1
template: "{{ metadata.infraID }}-rhcos_tpl"
operating_system: "rhcos_x64"
...
Create the templates and virtual machines:
$ ansible-playbook -i inventory.yml create-templates-and-vms.yml
Creating the bootstrap machine
You create a bootstrap machine by running the bootstrap.yml
playbook. This playbook starts the bootstrap virtual machine, and passes it the bootstrap.ign
Ignition file from the assets directory. The bootstrap node configures itself so it can serve Ignition files to the control plane nodes.
To monitor the bootstrap process, you use the console in the oVirt Administration Portal or connect to the virtual machine by using SSH.
Procedure
Create the bootstrap machine:
$ ansible-playbook -i inventory.yml bootstrap.yml
Connect to the bootstrap machine using a console in the Administration Portal or SSH. Replace
<bootstrap_ip>
with the bootstrap node IP address. To use SSH, enter:$ ssh core@<boostrap.ip>
Collect
bootkube.service
journald unit logs for the release image service from the bootstrap node:[core@ocp4-lk6b4-bootstrap ~]$ journalctl -b -f -u release-image.service -u bootkube.service
The
bootkube.service
log on the bootstrap node outputs etcdconnection refused
errors, indicating that the bootstrap server is unable to connect to etcd on control plane nodes. After etcd has started on each control plane node and the nodes have joined the cluster, the errors should stop.
Creating the control plane nodes
You create the control plane nodes by running the masters.yml
playbook. This playbook passes the master.ign
Ignition file to each of the virtual machines. The Ignition file contains a directive for the control plane node to get the Ignition from a URL such as [https://api-int.ocp4.example.org:22623/config/master](https://api-int.ocp4.example.org:22623/config/master)
. The port number in this URL is managed by the load balancer, and is accessible only inside the cluster.
Procedure
Create the control plane nodes:
$ ansible-playbook -i inventory.yml masters.yml
While the playbook creates your control plane, monitor the bootstrapping process:
$ openshift-install wait-for bootstrap-complete --dir $ASSETS_DIR
Example output
INFO API v1.25.0 up
INFO Waiting up to 40m0s for bootstrapping to complete...
When all the pods on the control plane nodes and etcd are up and running, the installation program displays the following output.
Example output
INFO It is now safe to remove the bootstrap resources
Verifying cluster status
You can verify your OKD cluster’s status during or after installation.
Procedure
In the cluster environment, export the administrator’s kubeconfig file:
$ export KUBECONFIG=<installation_directory>/auth/kubeconfig (1)
1 For <installation_directory>
, specify the path to the directory that you stored the installation files in.The
kubeconfig
file contains information about the cluster that is used by the CLI to connect a client to the correct cluster and API server.View the control plane and compute machines created after a deployment:
$ oc get nodes
View your cluster’s version:
$ oc get clusterversion
View your Operators’ status:
$ oc get clusteroperator
View all running pods in the cluster:
$ oc get pods -A
Removing the bootstrap machine
After the wait-for
command shows that the bootstrap process is complete, you must remove the bootstrap virtual machine to free up compute, memory, and storage resources. Also, remove settings for the bootstrap machine from the load balancer directives.
Procedure
To remove the bootstrap machine from the cluster, enter:
$ ansible-playbook -i inventory.yml retire-bootstrap.yml
Remove settings for the bootstrap machine from the load balancer directives.
Creating the worker nodes and completing the installation
Creating worker nodes is similar to creating control plane nodes. However, worker nodes workers do not automatically join the cluster. To add them to the cluster, you review and approve the workers’ pending CSRs (Certificate Signing Requests).
After approving the first requests, you continue approving CSR until all of the worker nodes are approved. When you complete this process, the worker nodes become Ready
and can have pods scheduled to run on them.
Finally, monitor the command line to see when the installation process completes.
Procedure
Create the worker nodes:
$ ansible-playbook -i inventory.yml workers.yml
To list all of the CSRs, enter:
$ oc get csr -A
Eventually, this command displays one CSR per node. For example:
Example output
NAME AGE SIGNERNAME REQUESTOR CONDITION
csr-2lnxd 63m kubernetes.io/kubelet-serving system:node:ocp4-lk6b4-master0.ocp4.example.org Approved,Issued
csr-hff4q 64m kubernetes.io/kube-apiserver-client-kubelet system:serviceaccount:openshift-machine-config-operator:node-bootstrapper Approved,Issued
csr-hsn96 60m kubernetes.io/kubelet-serving system:node:ocp4-lk6b4-master2.ocp4.example.org Approved,Issued
csr-m724n 6m2s kubernetes.io/kube-apiserver-client-kubelet system:serviceaccount:openshift-machine-config-operator:node-bootstrapper Pending
csr-p4dz2 60m kubernetes.io/kube-apiserver-client-kubelet system:serviceaccount:openshift-machine-config-operator:node-bootstrapper Approved,Issued
csr-t9vfj 60m kubernetes.io/kubelet-serving system:node:ocp4-lk6b4-master1.ocp4.example.org Approved,Issued
csr-tggtr 61m kubernetes.io/kube-apiserver-client-kubelet system:serviceaccount:openshift-machine-config-operator:node-bootstrapper Approved,Issued
csr-wcbrf 7m6s kubernetes.io/kube-apiserver-client-kubelet system:serviceaccount:openshift-machine-config-operator:node-bootstrapper Pending
To filter the list and see only pending CSRs, enter:
$ watch "oc get csr -A | grep pending -i"
This command refreshes the output every two seconds and displays only pending CSRs. For example:
Example output
Every 2.0s: oc get csr -A | grep pending -i
csr-m724n 10m kubernetes.io/kube-apiserver-client-kubelet system:serviceaccount:openshift-machine-config-operator:node-bootstrapper Pending
csr-wcbrf 11m kubernetes.io/kube-apiserver-client-kubelet system:serviceaccount:openshift-machine-config-operator:node-bootstrapper Pending
Inspect each pending request. For example:
Example output
$ oc describe csr csr-m724n
Example output
Name: csr-m724n
Labels: <none>
Annotations: <none>
CreationTimestamp: Sun, 19 Jul 2020 15:59:37 +0200
Requesting User: system:serviceaccount:openshift-machine-config-operator:node-bootstrapper
Signer: kubernetes.io/kube-apiserver-client-kubelet
Status: Pending
Subject:
Common Name: system:node:ocp4-lk6b4-worker1.ocp4.example.org
Serial Number:
Organization: system:nodes
Events: <none>
If the CSR information is correct, approve the request:
$ oc adm certificate approve csr-m724n
Wait for the installation process to finish:
$ openshift-install wait-for install-complete --dir $ASSETS_DIR --log-level debug
When the installation completes, the command line displays the URL of the OKD web console and the administrator user name and password.
Additional resources
- See About remote health monitoring for more information about the Telemetry service
Disabling the default OperatorHub catalog sources
Operator catalogs that source content provided by Red Hat and community projects are configured for OperatorHub by default during an OKD installation. In a restricted network environment, you must disable the default catalogs as a cluster administrator.
Procedure
Disable the sources for the default catalogs by adding
disableAllDefaultSources: true
to theOperatorHub
object:$ oc patch OperatorHub cluster --type json \
-p '[{"op": "add", "path": "/spec/disableAllDefaultSources", "value": true}]'
Alternatively, you can use the web console to manage catalog sources. From the Administration → Cluster Settings → Configuration → OperatorHub page, click the Sources tab, where you can create, delete, disable, and enable individual sources. |