454 lines
17 KiB
Markdown
454 lines
17 KiB
Markdown
# Kubernetes on Openstack with Terraform
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Provision a Kubernetes cluster with [Terraform](https://www.terraform.io) on
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Openstack.
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## Status
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This will install a Kubernetes cluster on an Openstack Cloud. It should work on
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most modern installs of OpenStack that support the basic services.
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### Known compatible public clouds
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- [Auro](https://auro.io/)
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- [Betacloud](https://www.betacloud.io/)
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- [CityCloud](https://www.citycloud.com/)
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- [DreamHost](https://www.dreamhost.com/cloud/computing/)
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- [ELASTX](https://elastx.se/)
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- [EnterCloudSuite](https://www.entercloudsuite.com/)
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- [FugaCloud](https://fuga.cloud/)
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- [OVH](https://www.ovh.com/)
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- [Rackspace](https://www.rackspace.com/)
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- [Ultimum](https://ultimum.io/)
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- [VexxHost](https://vexxhost.com/)
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- [Zetta](https://www.zetta.io/)
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### Known incompatible public clouds
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- T-Systems / Open Telekom Cloud: requires `wait_until_associated`
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## Approach
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The terraform configuration inspects variables found in
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[variables.tf](variables.tf) to create resources in your OpenStack cluster.
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There is a [python script](../terraform.py) that reads the generated`.tfstate`
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file to generate a dynamic inventory that is consumed by the main ansible script
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to actually install kubernetes and stand up the cluster.
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### Networking
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The configuration includes creating a private subnet with a router to the
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external net. It will allocate floating IPs from a pool and assign them to the
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hosts where that makes sense. You have the option of creating bastion hosts
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inside the private subnet to access the nodes there. Alternatively, a node with
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a floating IP can be used as a jump host to nodes without.
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### Kubernetes Nodes
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You can create many different kubernetes topologies by setting the number of
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different classes of hosts. For each class there are options for allocating
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floating IP addresses or not.
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- Master nodes with etcd
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- Master nodes without etcd
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- Standalone etcd hosts
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- Kubernetes worker nodes
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Note that the Ansible script will report an invalid configuration if you wind up
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with an even number of etcd instances since that is not a valid configuration. This
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restriction includes standalone etcd nodes that are deployed in a cluster along with
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master nodes with etcd replicas. As an example, if you have three master nodes with
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etcd replicas and three standalone etcd nodes, the script will fail since there are
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now six total etcd replicas.
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### GlusterFS
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The Terraform configuration supports provisioning of an optional GlusterFS
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shared file system based on a separate set of VMs. To enable this, you need to
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specify:
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- the number of Gluster hosts (minimum 2)
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- Size of the non-ephemeral volumes to be attached to store the GlusterFS bricks
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- Other properties related to provisioning the hosts
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Even if you are using Container Linux by CoreOS for your cluster, you will still
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need the GlusterFS VMs to be based on either Debian or RedHat based images.
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Container Linux by CoreOS cannot serve GlusterFS, but can connect to it through
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binaries available on hyperkube v1.4.3_coreos.0 or higher.
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## Requirements
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- [Install Terraform](https://www.terraform.io/intro/getting-started/install.html)
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- [Install Ansible](http://docs.ansible.com/ansible/latest/intro_installation.html)
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- you already have a suitable OS image in Glance
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- you already have a floating IP pool created
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- you have security groups enabled
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- you have a pair of keys generated that can be used to secure the new hosts
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## Module Architecture
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The configuration is divided into three modules:
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- Network
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- IPs
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- Compute
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The main reason for splitting the configuration up in this way is to easily
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accommodate situations where floating IPs are limited by a quota or if you have
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any external references to the floating IP (e.g. DNS) that would otherwise have
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to be updated.
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You can force your existing IPs by modifying the compute variables in
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`kubespray.tf` as follows:
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```
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k8s_master_fips = ["151.101.129.67"]
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k8s_node_fips = ["151.101.129.68"]
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```
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## Terraform
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Terraform will be used to provision all of the OpenStack resources with base software as appropriate.
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### Configuration
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#### Inventory files
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Create an inventory directory for your cluster by copying the existing sample and linking the `hosts` script (used to build the inventory based on Terraform state):
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```ShellSession
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$ cp -LRp contrib/terraform/openstack/sample-inventory inventory/$CLUSTER
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$ cd inventory/$CLUSTER
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$ ln -s ../../contrib/terraform/openstack/hosts
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$ ln -s ../../contrib
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```
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This will be the base for subsequent Terraform commands.
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#### OpenStack access and credentials
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No provider variables are hardcoded inside `variables.tf` because Terraform
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supports various authentication methods for OpenStack: the older script and
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environment method (using `openrc`) as well as a newer declarative method, and
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different OpenStack environments may support Identity API version 2 or 3.
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These are examples and may vary depending on your OpenStack cloud provider,
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for an exhaustive list on how to authenticate on OpenStack with Terraform
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please read the [OpenStack provider documentation](https://www.terraform.io/docs/providers/openstack/).
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##### Declarative method (recommended)
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The recommended authentication method is to describe credentials in a YAML file `clouds.yaml` that can be stored in:
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* the current directory
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* `~/.config/openstack`
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* `/etc/openstack`
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`clouds.yaml`:
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```
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clouds:
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mycloud:
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auth:
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auth_url: https://openstack:5000/v3
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username: "username"
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project_name: "projectname"
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project_id: projectid
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user_domain_name: "Default"
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password: "password"
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region_name: "RegionOne"
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interface: "public"
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identity_api_version: 3
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```
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If you have multiple clouds defined in your `clouds.yaml` file you can choose
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the one you want to use with the environment variable `OS_CLOUD`:
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```
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export OS_CLOUD=mycloud
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```
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##### Openrc method
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When using classic environment variables, Terraform uses default `OS_*`
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environment variables. A script suitable for your environment may be available
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from Horizon under *Project* -> *Compute* -> *Access & Security* -> *API Access*.
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With identity v2:
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```
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source openrc
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env | grep OS
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OS_AUTH_URL=https://openstack:5000/v2.0
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OS_PROJECT_ID=projectid
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OS_PROJECT_NAME=projectname
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OS_USERNAME=username
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OS_PASSWORD=password
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OS_REGION_NAME=RegionOne
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OS_INTERFACE=public
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OS_IDENTITY_API_VERSION=2
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```
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With identity v3:
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```
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source openrc
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env | grep OS
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OS_AUTH_URL=https://openstack:5000/v3
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OS_PROJECT_ID=projectid
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OS_PROJECT_NAME=username
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OS_PROJECT_DOMAIN_ID=default
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OS_USERNAME=username
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OS_PASSWORD=password
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OS_REGION_NAME=RegionOne
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OS_INTERFACE=public
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OS_IDENTITY_API_VERSION=3
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OS_USER_DOMAIN_NAME=Default
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```
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Terraform does not support a mix of DomainName and DomainID, choose one or the
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other:
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```
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* provider.openstack: You must provide exactly one of DomainID or DomainName to authenticate by Username
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```
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```
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unset OS_USER_DOMAIN_NAME
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export OS_USER_DOMAIN_ID=default
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or
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unset OS_PROJECT_DOMAIN_ID
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set OS_PROJECT_DOMAIN_NAME=Default
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```
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#### Cluster variables
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The construction of the cluster is driven by values found in
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[variables.tf](variables.tf).
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For your cluster, edit `inventory/$CLUSTER/cluster.tf`.
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|Variable | Description |
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|`cluster_name` | All OpenStack resources will use the Terraform variable`cluster_name` (default`example`) in their name to make it easier to track. For example the first compute resource will be named`example-kubernetes-1`. |
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|`network_name` | The name to be given to the internal network that will be generated |
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|`dns_nameservers`| An array of DNS name server names to be used by hosts in the internal subnet. |
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|`floatingip_pool` | Name of the pool from which floating IPs will be allocated |
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|`external_net` | UUID of the external network that will be routed to |
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|`flavor_k8s_master`,`flavor_k8s_node`,`flavor_etcd`, `flavor_bastion`,`flavor_gfs_node` | Flavor depends on your openstack installation, you can get available flavor IDs through`nova flavor-list` |
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|`image`,`image_gfs` | Name of the image to use in provisioning the compute resources. Should already be loaded into glance. |
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|`ssh_user`,`ssh_user_gfs` | The username to ssh into the image with. This usually depends on the image you have selected |
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|`public_key_path` | Path on your local workstation to the public key file you wish to use in creating the key pairs |
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|`number_of_k8s_masters`, `number_of_k8s_masters_no_floating_ip` | Number of nodes that serve as both master and etcd. These can be provisioned with or without floating IP addresses|
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|`number_of_k8s_masters_no_etcd`, `number_of_k8s_masters_no_floating_ip_no_etcd` | Number of nodes that serve as just master with no etcd. These can be provisioned with or without floating IP addresses |
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|`number_of_etcd` | Number of pure etcd nodes |
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|`number_of_k8s_nodes`, `number_of_k8s_nodes_no_floating_ip` | Kubernetes worker nodes. These can be provisioned with or without floating ip addresses. |
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|`number_of_bastions` | Number of bastion hosts to create. Scripts assume this is really just zero or one |
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|`number_of_gfs_nodes_no_floating_ip` | Number of gluster servers to provision. |
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| `gfs_volume_size_in_gb` | Size of the non-ephemeral volumes to be attached to store the GlusterFS bricks |
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|`supplementary_master_groups` | To add ansible groups to the masters, such as `kube-node` for tainting them as nodes, empty by default. |
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|`supplementary_node_groups` | To add ansible groups to the nodes, such as `kube-ingress` for running ingress controller pods, empty by default. |
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|`bastion_allowed_remote_ips` | List of CIDR allowed to initiate a SSH connection, `["0.0.0.0/0"]` by default |
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|`worker_allowed_ports` | List of ports to open on worker nodes, `[{ "protocol" = "tcp", "port_range_min" = 30000, "port_range_max" = 32767, "remote_ip_prefix" = "0.0.0.0/0"}]` by default |
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#### Terraform state files
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In the cluster's inventory folder, the following files might be created (either by Terraform
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or manually), to prevent you from pushing them accidentally they are in a
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`.gitignore` file in the `terraform/openstack` directory :
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* `.terraform`
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* `.tfvars`
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* `.tfstate`
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* `.tfstate.backup`
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You can still add them manually if you want to.
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### Initialization
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Before Terraform can operate on your cluster you need to install the required
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plugins. This is accomplished as follows:
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```ShellSession
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$ cd inventory/$CLUSTER
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$ terraform init ../../contrib/terraform/openstack
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```
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This should finish fairly quickly telling you Terraform has successfully initialized and loaded necessary modules.
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### Provisioning cluster
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You can apply the Terraform configuration to your cluster with the following command
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issued from your cluster's inventory directory (`inventory/$CLUSTER`):
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```ShellSession
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$ terraform apply -var-file=cluster.tf ../../contrib/terraform/openstack
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```
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if you chose to create a bastion host, this script will create
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`contrib/terraform/openstack/k8s-cluster.yml` with an ssh command for Ansible to
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be able to access your machines tunneling through the bastion's IP address. If
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you want to manually handle the ssh tunneling to these machines, please delete
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or move that file. If you want to use this, just leave it there, as ansible will
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pick it up automatically.
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### Destroying cluster
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You can destroy your new cluster with the following command issued from the cluster's inventory directory:
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```ShellSession
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$ terraform destroy -var-file=cluster.tf ../../contrib/terraform/openstack
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```
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If you've started the Ansible run, it may also be a good idea to do some manual cleanup:
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* remove SSH keys from the destroyed cluster from your `~/.ssh/known_hosts` file
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* clean up any temporary cache files: `rm /tmp/$CLUSTER-*`
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### Debugging
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You can enable debugging output from Terraform by setting
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`OS_DEBUG` to 1 and`TF_LOG` to`DEBUG` before running the Terraform command.
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### Terraform output
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Terraform can output values that are useful for configure Neutron/Octavia LBaaS or Cinder persistent volume provisioning as part of your Kubernetes deployment:
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- `private_subnet_id`: the subnet where your instances are running is used for `openstack_lbaas_subnet_id`
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- `floating_network_id`: the network_id where the floating IP are provisioned is used for `openstack_lbaas_floating_network_id`
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## Ansible
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### Node access
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#### SSH
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Ensure your local ssh-agent is running and your ssh key has been added. This
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step is required by the terraform provisioner:
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```
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$ eval $(ssh-agent -s)
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$ ssh-add ~/.ssh/id_rsa
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```
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If you have deployed and destroyed a previous iteration of your cluster, you will need to clear out any stale keys from your SSH "known hosts" file ( `~/.ssh/known_hosts`).
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#### Bastion host
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Bastion access will be determined by:
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- Your choice on the amount of bastion hosts (set by `number_of_bastions` terraform variable).
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- The existence of nodes/masters with floating IPs (set by `number_of_k8s_masters`, `number_of_k8s_nodes`, `number_of_k8s_masters_no_etcd` terraform variables).
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If you have a bastion host, your ssh traffic will be directly routed through it. This is regardless of whether you have masters/nodes with a floating IP assigned.
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If you don't have a bastion host, but at least one of your masters/nodes have a floating IP, then ssh traffic will be tunneled by one of these machines.
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So, either a bastion host, or at least master/node with a floating IP are required.
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#### Test access
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Make sure you can connect to the hosts. Note that Container Linux by CoreOS will have a state `FAILED` due to Python not being present. This is okay, because Python will be installed during bootstrapping, so long as the hosts are not `UNREACHABLE`.
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```
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$ ansible -i inventory/$CLUSTER/hosts -m ping all
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example-k8s_node-1 | SUCCESS => {
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"changed": false,
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"ping": "pong"
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}
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example-etcd-1 | SUCCESS => {
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"changed": false,
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"ping": "pong"
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}
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example-k8s-master-1 | SUCCESS => {
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"changed": false,
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"ping": "pong"
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}
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```
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If it fails try to connect manually via SSH. It could be something as simple as a stale host key.
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### Configure cluster variables
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Edit `inventory/$CLUSTER/group_vars/all/all.yml`:
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- **bin_dir**:
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```
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# Directory where the binaries will be installed
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# Default:
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# bin_dir: /usr/local/bin
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# For Container Linux by CoreOS:
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bin_dir: /opt/bin
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```
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- and **cloud_provider**:
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```
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cloud_provider: openstack
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```
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Edit `inventory/$CLUSTER/group_vars/k8s-cluster/k8s-cluster.yml`:
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- Set variable **kube_network_plugin** to your desired networking plugin.
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- **flannel** works out-of-the-box
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- **calico** requires [configuring OpenStack Neutron ports](/docs/openstack.md) to allow service and pod subnets
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```
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# Choose network plugin (calico, weave or flannel)
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# Can also be set to 'cloud', which lets the cloud provider setup appropriate routing
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kube_network_plugin: flannel
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```
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- Set variable **resolvconf_mode**
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```
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# Can be docker_dns, host_resolvconf or none
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# Default:
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# resolvconf_mode: docker_dns
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# For Container Linux by CoreOS:
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resolvconf_mode: host_resolvconf
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```
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### Deploy Kubernetes
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```
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$ ansible-playbook --become -i inventory/$CLUSTER/hosts cluster.yml
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```
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This will take some time as there are many tasks to run.
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## Kubernetes
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### Set up kubectl
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1. [Install kubectl](https://kubernetes.io/docs/tasks/tools/install-kubectl/) on your workstation
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2. Add a route to the internal IP of a master node (if needed):
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```
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sudo route add [master-internal-ip] gw [router-ip]
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```
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or
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```
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sudo route add -net [internal-subnet]/24 gw [router-ip]
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```
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3. List Kubernetes certificates & keys:
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```
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ssh [os-user]@[master-ip] sudo ls /etc/kubernetes/ssl/
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```
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4. Get `admin`'s certificates and keys:
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```
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ssh [os-user]@[master-ip] sudo cat /etc/kubernetes/ssl/admin-kube-master-1-key.pem > admin-key.pem
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ssh [os-user]@[master-ip] sudo cat /etc/kubernetes/ssl/admin-kube-master-1.pem > admin.pem
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ssh [os-user]@[master-ip] sudo cat /etc/kubernetes/ssl/ca.pem > ca.pem
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```
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5. Configure kubectl:
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```ShellSession
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$ kubectl config set-cluster default-cluster --server=https://[master-internal-ip]:6443 \
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--certificate-authority=ca.pem
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$ kubectl config set-credentials default-admin \
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--certificate-authority=ca.pem \
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--client-key=admin-key.pem \
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--client-certificate=admin.pem
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$ kubectl config set-context default-system --cluster=default-cluster --user=default-admin
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$ kubectl config use-context default-system
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```
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7. Check it:
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```
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kubectl version
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```
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## GlusterFS
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GlusterFS is not deployed by the standard`cluster.yml` playbook, see the
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[GlusterFS playbook documentation](../../network-storage/glusterfs/README.md)
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for instructions.
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Basically you will install Gluster as
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```ShellSession
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$ ansible-playbook --become -i inventory/$CLUSTER/hosts ./contrib/network-storage/glusterfs/glusterfs.yml
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```
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## What's next
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Try out your new Kubernetes cluster with the [Hello Kubernetes service](https://kubernetes.io/docs/tasks/access-application-cluster/service-access-application-cluster/).
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