Install Kubernetes Platform on Bare Metal Standard with Rook Storage¶
Overview¶
The Standard with Rook Storage deployment option is a standard installation with independent controller and worker nodes.
A Standard with Rook Storage configuration provides the following benefits:
A pool of up to 100 worker nodes
A 2x node high availability (HA) controller cluster with HA services running across the controller nodes in either active/active or active/standby mode
A Rook storage back end solution using a two-to-9x node HA Rook storage cluster that supports a replication factor of two or three
Note
If you are behind a corporate firewall or proxy, you need to set proxy settings. Refer to Docker Proxy Configuration for details.
Note
By default, StarlingX uses IPv4. To use StarlingX with IPv6:
The entire infrastructure and cluster configuration must be IPv6, with the exception of the PXE boot network.
Not all external servers are reachable via IPv6 addresses (for example Docker registries). Depending on your infrastructure, it may be necessary to deploy a NAT64/DNS64 gateway to translate the IPv4 addresses to IPv6.
Refer to StarlingX IPv6 Deployment for details on how to deploy a NAT64/DNS64 gateway to use StarlingX with IPv6.
Hardware requirements¶
This section describes the hardware requirements and server preparation for a StarlingX R7.0 bare metal Standard with Rook Storage deployment configuration.
Minimum hardware requirements¶
The recommended minimum hardware requirements for bare metal servers for various host types are:
Minimum Requirement |
Controller Node |
Worker Node for rook storage |
Worker Node for application |
---|---|---|---|
Number of servers |
2 |
2-9 |
2-100 |
Minimum processor class |
Dual-CPU Intel® Xeon® E5 26xx family (SandyBridge) 8 cores/socket |
||
Minimum memory |
64 GB |
64 GB |
32 GB |
Primary disk |
500 GB SSD or NVMe (see Configure NVMe Drive as Primary Disk) |
120 GB (min. 10k RPM) |
120 GB (min. 10k RPM) |
Additional disks |
None |
|
|
Minimum network ports |
|
|
|
BIOS settings |
|
Prepare bare metal servers¶
Prior to starting the StarlingX installation, the bare metal servers must be in the following condition:
Physically installed
Cabled for power
All disks wiped
Ensures that servers will boot from either the network or USB storage (if present)
Powered off
Cabled for networking
Far-end switch ports should be properly configured to realize the networking shown in the diagram above.
This section describes the steps to install the StarlingX Kubernetes platform on a StarlingX R7.0 bare metal Standard with Rook Storage deployment configuration.
Create bootable USB¶
Refer to Create Bootable USB for instructions on how to create a bootable USB with the StarlingX ISO on your system.
Install software on controller-0¶
Insert the bootable USB into a bootable USB port on the host you are configuring as controller-0.
Power on the host.
Attach to a console, ensure the host boots from the USB, and wait for the StarlingX Installer Menus.
Make the following menu selections in the installer:
First menu: Select ‘Standard Controller Configuration’
Second menu: Select ‘Graphical Console’ or ‘Textual Console’ depending on your terminal access to the console port
Wait for non-interactive install of software to complete and server to reboot. This can take 5-10 minutes, depending on the performance of the server.
Bootstrap system on controller-0¶
Login using the username / password of “sysadmin” / “sysadmin”.
When logging in for the first time, you will be forced to change the password.
Login: sysadmin Password: Changing password for sysadmin. (current) UNIX Password: sysadmin New Password: (repeat) New Password:
Verify and/or configure IP connectivity.
External connectivity is required to run the Ansible bootstrap playbook. The StarlingX boot image will DHCP out all interfaces so the server may have obtained an IP address and have external IP connectivity if a DHCP server is present in your environment. Verify this using the ip addr and ping 8.8.8.8 commands.
Otherwise, manually configure an IP address and default IP route. Use the PORT, IP-ADDRESS/SUBNET-LENGTH and GATEWAY-IP-ADDRESS applicable to your deployment environment.
sudo ip address add <IP-ADDRESS>/<SUBNET-LENGTH> dev <PORT> sudo ip link set up dev <PORT> sudo ip route add default via <GATEWAY-IP-ADDRESS> dev <PORT> ping 8.8.8.8
Specify user configuration overrides for the Ansible bootstrap playbook.
Ansible is used to bootstrap StarlingX on controller-0. Key files for Ansible configuration are:
/etc/ansible/hosts
The default Ansible inventory file. Contains a single host: localhost.
/usr/share/ansible/stx-ansible/playbooks/bootstrap.yml
The Ansible bootstrap playbook.
/usr/share/ansible/stx-ansible/playbooks/host_vars/bootstrap/default.yml
The default configuration values for the bootstrap playbook.
sysadmin home directory ($HOME)
The default location where Ansible looks for and imports user configuration override files for hosts. For example:
$HOME/<hostname>.yml
.
Important
Some Ansible bootstrap parameters cannot be changed or are very difficult to change after installation is complete.
Review the set of install-time-only parameters before installation and confirm that your values for these parameters are correct for the desired installation.
Refer to Ansible install-time-only parameters for details.
Specify the user configuration override file for the Ansible bootstrap playbook using one of the following methods:
Use a copy of the default.yml file listed above to provide your overrides.
The default.yml file lists all available parameters for bootstrap configuration with a brief description for each parameter in the file comments.
To use this method, copy the default.yml file listed above to
$HOME/localhost.yml
and edit the configurable values as desired.Create a minimal user configuration override file.
To use this method, create your override file at
$HOME/localhost.yml
and provide the minimum required parameters for the deployment configuration as shown in the example below. Use the OAM IP SUBNET and IP ADDRESSing applicable to your deployment environment.cd ~ cat <<EOF > localhost.yml system_mode: duplex dns_servers: - 8.8.8.8 - 8.8.4.4 external_oam_subnet: <OAM-IP-SUBNET>/<OAM-IP-SUBNET-LENGTH> external_oam_gateway_address: <OAM-GATEWAY-IP-ADDRESS> external_oam_floating_address: <OAM-FLOATING-IP-ADDRESS> external_oam_node_0_address: <OAM-CONTROLLER-0-IP-ADDRESS> external_oam_node_1_address: <OAM-CONTROLLER-1-IP-ADDRESS> admin_username: admin admin_password: <admin-password> ansible_become_pass: <sysadmin-password> # Add these lines to configure Docker to use a proxy server # docker_http_proxy: http://my.proxy.com:1080 # docker_https_proxy: https://my.proxy.com:1443 # docker_no_proxy: # - 1.2.3.4 EOF
Refer to Ansible Bootstrap Configurations for information on additional Ansible bootstrap configurations for advanced Ansible bootstrap scenarios, such as Docker proxies when deploying behind a firewall, etc. Refer to Docker Proxy Configuration for details about Docker proxy settings.
Run the Ansible bootstrap playbook:
ansible-playbook /usr/share/ansible/stx-ansible/playbooks/bootstrap.yml
Wait for Ansible bootstrap playbook to complete. This can take 5-10 minutes, depending on the performance of the host machine.
Configure controller-0¶
Acquire admin credentials:
source /etc/platform/openrc
Configure the OAM and MGMT interfaces of controller-0 and specify the attached networks. Use the OAM and MGMT port names, for example eth0, that are applicable to your deployment environment.
OAM_IF=<OAM-PORT> MGMT_IF=<MGMT-PORT> system host-if-modify controller-0 lo -c none IFNET_UUIDS=$(system interface-network-list controller-0 | awk '{if ($6=="lo") print $4;}') for UUID in $IFNET_UUIDS; do system interface-network-remove ${UUID} done system host-if-modify controller-0 $OAM_IF -c platform system interface-network-assign controller-0 $OAM_IF oam system host-if-modify controller-0 $MGMT_IF -c platform system interface-network-assign controller-0 $MGMT_IF mgmt system interface-network-assign controller-0 $MGMT_IF cluster-host
Configure NTP servers for network time synchronization:
system ntp-modify ntpservers=0.pool.ntp.org,1.pool.ntp.org
If required, and not already done as part of bootstrap, configure Docker to use a proxy server.
List Docker proxy parameters:
system service-parameter-list platform docker
Refer to Docker Proxy Configuration for details about Docker proxy settings.
OpenStack-specific host configuration¶
Important
This step is required only if the StarlingX OpenStack application (stx-openstack) will be installed.
For OpenStack only: Assign OpenStack host labels to controller-0 in support of installing the stx-openstack manifest and helm-charts later.
system host-label-assign controller-0 openstack-control-plane=enabled
For OpenStack only: Configure the system setting for the vSwitch.
StarlingX has OVS (kernel-based) vSwitch configured as default:
Runs in a container; defined within the helm charts of stx-openstack manifest.
Shares the core(s) assigned to the platform.
If you require better performance, OVS-DPDK (OVS with the Data Plane Development Kit, which is supported only on bare metal hardware) should be used:
Runs directly on the host (it is not containerized).
Requires that at least 1 core be assigned/dedicated to the vSwitch function.
To deploy the default containerized OVS:
system modify --vswitch_type none
Do not run any vSwitch directly on the host, instead, use the containerized OVS defined in the helm charts of stx-openstack manifest.
To deploy OVS-DPDK, run the following command:
system modify --vswitch_type ovs-dpdk system host-cpu-modify -f vswitch -p0 1 controller-0
Once vswitch_type is set to OVS-DPDK, any subsequent nodes created will default to automatically assigning 1 vSwitch core for AIO controllers and 2 vSwitch cores for compute-labeled worker nodes.
When using OVS-DPDK, configure vSwitch memory per NUMA node with the following command:
system host-memory-modify -f <function> -1G <1G hugepages number> <hostname or id> <processor>
For example:
system host-memory-modify -f vswitch -1G 1 worker-0 0
VMs created in an OVS-DPDK environment must be configured to use huge pages to enable networking and must use a flavor with property: hw:mem_page_size=large
Configure the huge pages for VMs in an OVS-DPDK environment with the command:
system host-memory-modify -1G <1G hugepages number> <hostname or id> <processor>
For example:
system host-memory-modify worker-0 0 -1G 10
Note
After controller-0 is unlocked, changing vswitch_type requires locking and unlocking all compute-labeled worker nodes (and/or AIO controllers) to apply the change.
Rook-specific host configuration¶
Important
This step is required only if the StarlingX Rook application will be installed.
For Rook only: Assign Rook host labels to controller-0 in support of installing the rook-ceph-apps manifest/helm-charts later and add ceph-rook as storage backend:
system host-label-assign controller-0 ceph-mon-placement=enabled
system host-label-assign controller-0 ceph-mgr-placement=enabled
system storage-backend-add ceph-rook --confirmed
Unlock controller-0¶
Unlock controller-0 in order to bring it into service:
system host-unlock controller-0
Controller-0 will reboot in order to apply configuration changes and come into service. This can take 5-10 minutes, depending on the performance of the host machine.
Install software on controller-1 and worker nodes¶
Power on the controller-1 server and force it to network boot with the appropriate BIOS boot options for your particular server.
As controller-1 boots, a message appears on its console instructing you to configure the personality of the node.
On the console of controller-0, list hosts to see newly discovered controller-1 host (hostname=None):
system host-list +----+--------------+-------------+----------------+-------------+--------------+ | id | hostname | personality | administrative | operational | availability | +----+--------------+-------------+----------------+-------------+--------------+ | 1 | controller-0 | controller | unlocked | enabled | available | | 2 | None | None | locked | disabled | offline | +----+--------------+-------------+----------------+-------------+--------------+
Using the host id, set the personality of this host to ‘controller’:
system host-update 2 personality=controller
This initiates the install of software on controller-1. This can take 5-10 minutes, depending on the performance of the host machine.
While waiting for the previous step to complete, power on the worker nodes. Set the personality to ‘worker’ and assign a unique hostname for each.
For example, power on worker-0 and wait for the new host (hostname=None) to be discovered by checking ‘system host-list’:
system host-update 3 personality=worker hostname=worker-0
Repeat for worker-1. Power on worker-1 and wait for the new host (hostname=None) to be discovered by checking ‘system host-list’:
system host-update 4 personality=worker hostname=worker-1
For rook storage, there is no storage personality. Some hosts with worker personality providers storage service. Here we still named these worker host storage-x. Repeat for storage-0 and storage-1. Power on storage-0, storage-1 and wait for the new host (hostname=None) to be discovered by checking ‘system host-list’:
system host-update 5 personality=worker hostname=storage-0 system host-update 6 personality=worker hostname=storage-1
Note
A node with Edgeworker personality is also available. See Deploy Edgeworker Nodes for details.
Wait for the software installation on controller-1, worker-0, and worker-1 to complete, for all servers to reboot, and for all to show as locked/disabled/online in ‘system host-list’.
system host-list +----+--------------+-------------+----------------+-------------+--------------+ | id | hostname | personality | administrative | operational | availability | +----+--------------+-------------+----------------+-------------+--------------+ | 1 | controller-0 | controller | unlocked | enabled | available | | 2 | controller-1 | controller | locked | disabled | online | | 3 | worker-0 | worker | locked | disabled | online | | 4 | worker-1 | worker | locked | disabled | online | | 5 | storage-0 | worker | locked | disabled | online | | 6 | storage-1 | worker | locked | disabled | online | +----+--------------+-------------+----------------+-------------+--------------+
Configure controller-1¶
Configure the OAM and MGMT interfaces of controller-0 and specify the attached networks. Use the OAM and MGMT port names, for example eth0, that are applicable to your deployment environment.
(Note that the MGMT interface is partially set up automatically by the network install procedure.)
OAM_IF=<OAM-PORT>
MGMT_IF=<MGMT-PORT>
system host-if-modify controller-1 $OAM_IF -c platform
system interface-network-assign controller-1 $OAM_IF oam
system interface-network-assign controller-1 $MGMT_IF cluster-host
OpenStack-specific host configuration¶
Important
This step is required only if the StarlingX OpenStack application (stx-openstack) will be installed.
For OpenStack only: Assign OpenStack host labels to controller-1 in support of installing the stx-openstack manifest and helm-charts later.
system host-label-assign controller-1 openstack-control-plane=enabled
Rook-specific host configuration¶
Important
This step is required only if the StarlingX Rook application will be installed.
For Rook only: Assign Rook host labels to controller-1 in support of installing the rook-ceph-apps manifest/helm-charts later:
system host-label-assign controller-1 ceph-mon-placement=enabled
system host-label-assign controller-1 ceph-mgr-placement=enabled
Unlock controller-1¶
Unlock controller-1 in order to bring it into service:
system host-unlock controller-1
Controller-1 will reboot in order to apply configuration changes and come into service. This can take 5-10 minutes, depending on the performance of the host machine.
Configure worker nodes¶
Assign the cluster-host network to the MGMT interface for the worker nodes:
(Note that the MGMT interfaces are partially set up automatically by the network install procedure.)
for NODE in worker-0 worker-1; do system interface-network-assign $NODE mgmt0 cluster-host done
Configure data interfaces for worker nodes. Use the DATA port names, for example eth0, that are applicable to your deployment environment.
Important
This step is required for OpenStack.
This step is optional for Kubernetes: Do this step if using SR-IOV network attachments in hosted application containers.
For Kubernetes SR-IOV network attachments:
Configure SR-IOV device plug in:
for NODE in worker-0 worker-1; do system host-label-assign ${NODE} sriovdp=enabled done
If planning on running DPDK in containers on this host, configure the number of 1G Huge pages required on both NUMA nodes:
for NODE in worker-0 worker-1; do system host-memory-modify ${NODE} 0 -1G 100 system host-memory-modify ${NODE} 1 -1G 100 done
For both Kubernetes and OpenStack:
DATA0IF=<DATA-0-PORT> DATA1IF=<DATA-1-PORT> PHYSNET0='physnet0' PHYSNET1='physnet1' SPL=/tmp/tmp-system-port-list SPIL=/tmp/tmp-system-host-if-list # configure the datanetworks in sysinv, prior to referencing it # in the ``system host-if-modify`` command'. system datanetwork-add ${PHYSNET0} vlan system datanetwork-add ${PHYSNET1} vlan for NODE in worker-0 worker-1; do echo "Configuring interface for: $NODE" set -ex system host-port-list ${NODE} --nowrap > ${SPL} system host-if-list -a ${NODE} --nowrap > ${SPIL} DATA0PCIADDR=$(cat $SPL | grep $DATA0IF |awk '{print $8}') DATA1PCIADDR=$(cat $SPL | grep $DATA1IF |awk '{print $8}') DATA0PORTUUID=$(cat $SPL | grep ${DATA0PCIADDR} | awk '{print $2}') DATA1PORTUUID=$(cat $SPL | grep ${DATA1PCIADDR} | awk '{print $2}') DATA0PORTNAME=$(cat $SPL | grep ${DATA0PCIADDR} | awk '{print $4}') DATA1PORTNAME=$(cat $SPL | grep ${DATA1PCIADDR} | awk '{print $4}') DATA0IFUUID=$(cat $SPIL | awk -v DATA0PORTNAME=$DATA0PORTNAME '($12 ~ DATA0PORTNAME) {print $2}') DATA1IFUUID=$(cat $SPIL | awk -v DATA1PORTNAME=$DATA1PORTNAME '($12 ~ DATA1PORTNAME) {print $2}') system host-if-modify -m 1500 -n data0 -c data ${NODE} ${DATA0IFUUID} system host-if-modify -m 1500 -n data1 -c data ${NODE} ${DATA1IFUUID} system interface-datanetwork-assign ${NODE} ${DATA0IFUUID} ${PHYSNET0} system interface-datanetwork-assign ${NODE} ${DATA1IFUUID} ${PHYSNET1} set +ex done
OpenStack-specific host configuration¶
Important
This step is required only if the StarlingX OpenStack application (stx-openstack) will be installed.
For OpenStack only: Assign OpenStack host labels to the worker nodes in support of installing the stx-openstack manifest and helm-charts later.
for NODE in worker-0 worker-1; do system host-label-assign $NODE openstack-compute-node=enabled kubectl taint nodes $NODE openstack-compute-node:NoSchedule system host-label-assign $NODE openvswitch=enabled system host-label-assign $NODE sriov=enabled done
For OpenStack only: Set up ‘instances’ filesystem, which is needed for stx-openstack nova ephemeral disks.
for NODE in worker-0 worker-1; do echo "Configuring 'instances' for Nova ephemeral storage: $NODE" system host-fs-add ${NODE} instances=10 done
Unlock worker nodes¶
Unlock worker nodes in order to bring them into service:
for NODE in worker-0 worker-1; do
system host-unlock $NODE
done
The worker nodes will reboot in order to apply configuration changes and come into service. This can take 5-10 minutes, depending on the performance of the host machine.
Configure storage nodes¶
Assign the cluster-host network to the MGMT interface for the storage nodes.
Note that the MGMT interfaces are partially set up by the network install procedure.
for NODE in storage-0 storage-1; do system interface-network-assign $NODE mgmt0 cluster-host done
For Rook only: Assign Rook host labels to storage-0 in support of installing the rook-ceph-apps manifest/helm-charts later:
system host-label-assign storage-0 ceph-mon-placement=enabled
Unlock storage nodes¶
Unlock storage nodes in order to bring them into service:
for STORAGE in storage-0 storage-1; do
system host-unlock $STORAGE
done
The storage nodes will reboot in order to apply configuration changes and come into service. This can take 5-10 minutes, depending on the performance of the host machine.
Install Rook application manifest and helm-charts¶
On host storage-0 and storage-1:
Erase gpt header of disk sdb.
$ system host-disk-wipe -s --confirm storage-0 /dev/sdb $ system host-disk-wipe -s --confirm storage-1 /dev/sdb
Wait for application “rook-ceph-apps” uploaded
$ source /etc/platform/openrc $ system application-list +---------------------+---------+-------------------------------+---------------+----------+-----------+ | application | version | manifest name | manifest file | status | progress | +---------------------+---------+-------------------------------+---------------+----------+-----------+ | oidc-auth-apps | 1.0-0 | oidc-auth-manifest | manifest.yaml | uploaded | completed | | platform-integ-apps | 1.0-8 | platform-integration-manifest | manifest.yaml | uploaded | completed | | rook-ceph-apps | 1.0-1 | rook-ceph-manifest | manifest.yaml | uploaded | completed | +---------------------+---------+-------------------------------+---------------+----------+-----------+
Edit values.yaml for rook-ceph-apps.
cluster: storage: nodes: - name: storage-0 devices: - name: /dev/disk/by-path/pci-0000:00:03.0-ata-2.0 - name: storage-1 devices: - name: /dev/disk/by-path/pci-0000:00:03.0-ata-2.0
Update rook-ceph-apps override value.
system helm-override-update rook-ceph-apps rook-ceph kube-system --values values.yaml
Apply the rook-ceph-apps application.
system application-apply rook-ceph-apps
Wait for OSDs pod ready.
kubectl get pods -n kube-system rook-ceph-mgr-a-ddffc8fbb-zkvln 1/1 Running 0 66s rook-ceph-mon-a-c67fdb6c8-tlbvk 1/1 Running 0 2m11s rook-ceph-mon-b-76969d8685-wcq62 1/1 Running 0 2m2s rook-ceph-mon-c-5bc47c6cb9-vm4j8 1/1 Running 0 97s rook-ceph-operator-6fc8cfb68b-bb57z 1/1 Running 1 7m9s rook-ceph-osd-0-689b6f65b-2nvcx 1/1 Running 0 12s rook-ceph-osd-1-7bfd69fdf9-vjqmp 1/1 Running 0 4s rook-ceph-osd-prepare-rook-storage-0-hf28p 0/1 Completed 0 50s rook-ceph-osd-prepare-rook-storage-1-r6lsd 0/1 Completed 0 50s rook-ceph-tools-84c7fff88c-x5trx 1/1 Running 0 6m11s
Next steps¶
Your Kubernetes cluster is now up and running.
For instructions on how to access StarlingX Kubernetes see Access StarlingX Kubernetes.
For instructions on how to install and access StarlingX OpenStack see StarlingX OpenStack.