In Google Distributed Cloud, hybrid clusters perform the dual role of an admin cluster and a user cluster. They run workloads, and at the same time, manage other clusters, and themselves.
Hybrid clusters eliminate the need to run a separate admin cluster in resource-constrained scenarios, and can provide highly available (HA) reliability. In a HA hybrid cluster, if one node fails, then others will take its place.
Hybrid clusters are different from standalone clusters in that they can also manage other clusters. Standalone clusters can't create or manage other clusters.
When you create hybrid clusters, there is some tradeoff between flexibility and security, however. Since hybrid clusters manage themselves, running workloads on the same cluster increases the risk of security exposure to sensitive administrative data, like SSH keys.
You create a hybrid cluster with a high availability (HA) control plane using
the bmctl
command. The bmctl
command can be run on a separate workstation or on one
of the hybrid cluster nodes.
Prerequisites
- Latest
bmctl
is downloaded (gs://anthos-baremetal-release/bmctl/1.9.8/linux-amd64/bmctl
) from Cloud Storage. - Workstation running
bmctl
has network connectivity to all nodes in the target hybrid cluster. - Workstation running
bmctl
has network connectivity to the control plane VIP of the target hybrid cluster. - SSH key used to create the hybrid cluster is available to root, or there is SUDO user access on all nodes in the target hybrid cluster.
- Connect-register service account is configured for use with Connect.
See the Google Distributed Cloud quickstart for expanded step-by-step instructions for creating a hybrid cluster.
Enable SELinux
If you want to enable SELinux to secure your containers, you must make sure that
SELinux is enabled in Enforced
mode on all your host machines. Starting with
Google Distributed Cloud release 1.9.0 or later, you can enable or disable SELinux
before or after cluster creation or cluster upgrades. SELinux is enabled by
default on Red Hat Enterprise Linux (RHEL) and CentOS. If SELinux is disabled on
your host machines or you aren't sure, see
Securing your containers using SELinux
for instructions on how to enable it.
Google Distributed Cloud supports SELinux in only RHEL and CentOS systems.
Log into gcloud and create a hybrid cluster config file
- Login to gcloud as a user using
gcloud auth application-default
login: - Service Account Admin
- Service Account Key Admin
- Project IAM Admin
- Compute Viewer
- Service Usage Admin
- Get your Cloud project id to use with cluster creation:
gcloud auth application-default loginYou need to have a Project Owner/Editor role to use the automatic API enablement and Service Account creation features, described below. You can also add the following IAM roles to the user:
export GOOGLE_APPLICATION_CREDENTIALS=JSON_KEY_FILEJSON_KEY_FILE specifies the path to your service account JSON key file.
export CLOUD_PROJECT_ID=$(gcloud config get-value project)
Create the hybrid cluster with bmctl
After you've logged into gcloud and have your project set up, you can create the
cluster config file with the bmctl
command. Note that in this example,
all service accounts are automatically created by the bmctl create config
command:
bmctl create config -c HYBRID_CLUSTER_NAME --enable-apis \ --create-service-accounts --project-id=CLOUD_PROJECT_ID
Here's an example to create a config file for a hybrid cluster
called hybrid1
associated with project ID my-gcp-project
:
bmctl create config -c hybrid1 --create-service-accounts --project-id=my-gcp-project
The file is written to bmctl-workspace/hybrid1/hybrid1.yaml.
As an alternative to automatically enabling APIs and creating service accounts,
you can also provide your existing service accounts with proper
IAM permissions. Thie means you can skip the automatic service account creation
in the previous step in the bmctl
command:
bmctl create config -c hybrid1
Edit the cluster config file
Now that you have a cluster config file, edit it to make the following changes:
Provide the SSH private key to access the hybrid cluster nodes:
# bmctl configuration variables. Because this section is valid YAML but not a valid Kubernetes # resource, this section can only be included when using bmctl to # create the initial admin/hybrid cluster. Afterwards, when creating user clusters by directly # applying the cluster and node pool resources to the existing cluster, you must remove this # section. gcrKeyPath: bmctl-workspace/.sa-keys/my-gcp-project-anthos-baremetal-gcr.json sshPrivateKeyPath: /path/to/your/ssh_private_key gkeConnectAgentServiceAccountKeyPath: bmctl-workspace/.sa-keys/my-gcp-project-anthos-baremetal-connect.json gkeConnectRegisterServiceAccountKeyPath: bmctl-workspace/.sa-keys/my-gcp-project-anthos-baremetal-register.json cloudOperationsServiceAccountKeyPath: bmctl-workspace/.sa-keys/my-gcp-project-anthos-baremetal-cloud-ops.json
You must register your clusters with Connect to your project fleet.
- If you created your config file, using the automatic API enablement and Service Account creation features, you can skip this step.
- If you created the config file without using the automatic API enablement
and Service Account creation features, reference the downloaded service
account JSON keys in the corresponding
gkeConnectAgentServiceAccountKeyPath
andgkeConnectRegisterServiceAccountKeyPath
fields of the cluster config file.
Change the config to specify a cluster type of
hybrid
instead ofadmin
:spec: # Cluster type. This can be: # 1) admin: to create an admin cluster. This can later be used to create user clusters. # 2) user: to create a user cluster. Requires an existing admin cluster. # 3) hybrid: to create a hybrid cluster that runs admin cluster components and user workloads. # 4) standalone: to create a cluster that manages itself, runs user workloads, but does not manage other clusters. type: hybrid
Change the config to specify a multi-node, high availability, control plane. You want to specify an odd number of nodes to be able to have a majority quorum for HA:
# Control plane configuration controlPlane: nodePoolSpec: nodes: # Control plane node pools. Typically, this is either a single machine # or 3 machines if using a high availability deployment. - address: 10.200.0.4 - address: 10.200.0.5 - address: 10.200.0.6
Specify the pod density of cluster nodes and the container runtime:
.... # NodeConfig specifies the configuration that applies to all nodes in the cluster. nodeConfig: # podDensity specifies the pod density configuration. podDensity: # maxPodsPerNode specifies at most how many pods can be run on a single node. maxPodsPerNode: 250 # containerRuntime specifies which container runtime to use for scheduling containers on nodes. # containerd and docker are supported. containerRuntime: containerd ....
For hybrid clusters, allowable values for
maxPodsPerNode
are32-250
for HA clusters and64-250
for non-HA clusters. The default value formaxPodsPerNode
if unspecified is110
. Once the cluster is created, this value cannot be updated.The default container runtime is containerd. Alternatively, you can use Docker. For more information about changing your runtime, see our Change your container runtime guide.
Pod density is also limited by your cluster's available IP resources. For details, see Pod networking.
Create the hybrid cluster with the cluster config
Use the bmctl
command to deploy the cluster:
bmctl create cluster -c CLUSTER_NAME
CLUSTER_NAME specifies cluster name you created in the previous section.
The following shows an example of the command to create a config file for a cluster
called hybrid1
:
bmctl create cluster -c hybrid1
Sample complete hybrid cluster config
The following is a sample hybrid cluster config file created by the bmctl
command.
Note that in this sample config, placeholder cluster names, VIPs and addresses
are used. They may not work for your network.
gcrKeyPath: bmctl-workspace/.sa-keys/my-gcp-project-anthos-baremetal-gcr.json
sshPrivateKeyPath: /home/myusername/.ssh/id_rsa
gkeConnectAgentServiceAccountKeyPath: bmctl-workspace/.sa-keys/my-gcp-project-anthos-baremetal-connect.json
gkeConnectRegisterServiceAccountKeyPath: bmctl-workspace/.sa-keys/my-gcp-project-anthos-baremetal-register.json
cloudOperationsServiceAccountKeyPath: bmctl-workspace/.sa-keys/my-gcp-project-anthos-baremetal-cloud-ops.json
---
apiVersion: v1
kind: Namespace
metadata:
name: cluster-hybrid1
---
apiVersion: baremetal.cluster.gke.io/v1
kind: Cluster
metadata:
name: hybrid1
namespace: cluster-hybrid1
spec:
# Cluster type. This can be:
# 1) admin: to create an admin cluster. This can later be used to create user clusters.
# 2) user: to create a user cluster. Requires an existing admin cluster.
# 3) hybrid: to create a hybrid cluster that runs admin cluster components and user workloads.
# 4) standalone: to create a cluster that manages itself, runs user workloads, but does not manage other clusters.
type: hybrid
# Anthos cluster version.
anthosBareMetalVersion: 1.9.8
# GKE connect configuration
gkeConnect:
projectID: $GOOGLE_PROJECT_ID
# Control plane configuration
controlPlane:
nodePoolSpec:
nodes:
# Control plane node pools. Typically, this is either a single machine
# or 3 machines if using a high availability deployment.
- address: 10.200.0.4
- address: 10.200.0.5
- address: 10.200.0.6
# Cluster networking configuration
clusterNetwork:
# Pods specify the IP ranges from which pod networks are allocated.
pods:
cidrBlocks:
- 192.168.0.0/16
# Services specify the network ranges from which service virtual IPs are allocated.
# This can be any RFC 1918 range that does not conflict with any other IP range
# in the cluster and node pool resources.
services:
cidrBlocks:
- 10.96.0.0/20
# Load balancer configuration
loadBalancer:
# Load balancer mode can be either 'bundled' or 'manual'.
# In 'bundled' mode a load balancer will be installed on load balancer nodes during cluster creation.
# In 'manual' mode the cluster relies on a manually-configured external load balancer.
mode: bundled
# Load balancer port configuration
ports:
# Specifies the port the load balancer serves the Kubernetes control plane on.
# In 'manual' mode the external load balancer must be listening on this port.
controlPlaneLBPort: 443
# There are two load balancer virtual IP (VIP) addresses: one for the control plane
# and one for the L7 Ingress service. The VIPs must be in the same subnet as the load balancer nodes.
# These IP addresses do not correspond to physical network interfaces.
vips:
# ControlPlaneVIP specifies the VIP to connect to the Kubernetes API server.
# This address must not be in the address pools below.
controlPlaneVIP: 10.200.0.71
# IngressVIP specifies the VIP shared by all services for ingress traffic.
# Allowed only in non-admin clusters.
# This address must be in the address pools below.
ingressVIP: 10.200.0.72
# AddressPools is a list of non-overlapping IP ranges for the data plane load balancer.
# All addresses must be in the same subnet as the load balancer nodes.
# Address pool configuration is only valid for 'bundled' LB mode in non-admin clusters.
addressPools:
- name: pool1
addresses:
# Each address must be either in the CIDR form (1.2.3.0/24)
# or range form (1.2.3.1-1.2.3.5).
- 10.200.0.72-10.200.0.90
# A load balancer node pool can be configured to specify nodes used for load balancing.
# These nodes are part of the Kubernetes cluster and run regular workloads as well as load balancers.
# If the node pool config is absent then the control plane nodes are used.
# Node pool configuration is only valid for 'bundled' LB mode.
# nodePoolSpec:
# nodes:
# - address: <Machine 1 IP>
# Proxy configuration
# proxy:
# url: http://[username:password@]domain
# # A list of IPs, hostnames or domains that should not be proxied.
# noProxy:
# - 127.0.0.1
# - localhost
# Logging and Monitoring
clusterOperations:
# Cloud project for logs and metrics.
projectID: $GOOGLE_PROJECT_ID
# Cloud location for logs and metrics.
location: us-central1
# Whether collection of application logs/metrics should be enabled (in addition to
# collection of system logs/metrics which correspond to system components such as
# Kubernetes control plane or cluster management agents).
# enableApplication: false
# Storage configuration
storage:
# lvpNodeMounts specifies the config for local PersistentVolumes backed by mounted disks.
# These disks need to be formatted and mounted by the user, which can be done before or after
# cluster creation.
lvpNodeMounts:
# path specifies the host machine path where mounted disks will be discovered and a local PV
# will be created for each mount.
path: /mnt/localpv-disk
# storageClassName specifies the StorageClass that PVs will be created with. The StorageClass
# is created during cluster creation.
storageClassName: local-disks
# lvpShare specifies the config for local PersistentVolumes backed by subdirectories in a shared filesystem.
# These subdirectories are automatically created during cluster creation.
lvpShare:
# path specifies the host machine path where subdirectories will be created on each host. A local PV
# will be created for each subdirectory.
path: /mnt/localpv-share
# storageClassName specifies the StorageClass that PVs will be created with. The StorageClass
# is created during cluster creation.
storageClassName: local-shared
# numPVUnderSharedPath specifies the number of subdirectories to create under path.
numPVUnderSharedPath: 5
# NodeConfig specifies the configuration that applies to all nodes in the cluster.
nodeConfig:
# podDensity specifies the pod density configuration.
podDensity:
# maxPodsPerNode specifies at most how many pods can be run on a single node.
maxPodsPerNode: 250
# containerRuntime specifies which container runtime to use for scheduling containers on nodes.
# containerd and docker are supported.
containerRuntime: containerd
# KubeVirt configuration, uncomment this section if you want to install kubevirt to the cluster
# kubevirt:
# # if useEmulation is enabled, hardware accelerator (i.e relies on cpu feature like vmx or svm)
# # will not be attempted. QEMU will be used for software emulation.
# # useEmulation must be specified for KubeVirt installation
# useEmulation: false
# Authentication; uncomment this section if you wish to enable authentication to the cluster with OpenID Connect.
# authentication:
# oidc:
# # issuerURL specifies the URL of your OpenID provider, such as "https://accounts.google.com". The Kubernetes API
# # server uses this URL to discover public keys for verifying tokens. Must use HTTPS.
# issuerURL: <URL for OIDC Provider; required>
# # clientID specifies the ID for the client application that makes authentication requests to the OpenID
# # provider.
# clientID: <ID for OIDC client application; required>
# # clientSecret specifies the secret for the client application.
# clientSecret: <Secret for OIDC client application; optional>
# # kubectlRedirectURL specifies the redirect URL (required) for the gcloud CLI, such as
# # "http://localhost:[PORT]/callback".
# kubectlRedirectURL: <Redirect URL for the gcloud CLI; optional, default is "http://kubectl.redirect.invalid">
# # username specifies the JWT claim to use as the username. The default is "sub", which is expected to be a
# # unique identifier of the end user.
# username: <JWT claim to use as the username; optional, default is "sub">
# # usernamePrefix specifies the prefix prepended to username claims to prevent clashes with existing names.
# usernamePrefix: <Prefix prepended to username claims; optional>
# # group specifies the JWT claim that the provider will use to return your security groups.
# group: <JWT claim to use as the group name; optional>
# # groupPrefix specifies the prefix prepended to group claims to prevent clashes with existing names.
# groupPrefix: <Prefix prepended to group claims; optional>
# # scopes specifies additional scopes to send to the OpenID provider as a comma-delimited list.
# scopes: <Additional scopes to send to OIDC provider as a comma-separated list; optional>
# # extraParams specifies additional key-value parameters to send to the OpenID provider as a comma-delimited
# # list.
# extraParams: <Additional key-value parameters to send to OIDC provider as a comma-separated list; optional>
# # proxy specifies the proxy server to use for the cluster to connect to your OIDC provider, if applicable.
# # Example: https://user:password@10.10.10.10:8888. If left blank, this defaults to no proxy.
# proxy: <Proxy server to use for the cluster to connect to your OIDC provider; optional, default is no proxy>
# # deployCloudConsoleProxy specifies whether to deploy a reverse proxy in the cluster to allow Google Cloud
# # Console access to the on-premises OIDC provider for authenticating users. If your identity provider is not
# # reachable over the public internet, and you wish to authenticate using Google Cloud console, then this field
# # must be set to true. If left blank, this field defaults to false.
# deployCloudConsoleProxy: <Whether to deploy a reverse proxy for Google Cloud console authentication; optional>
# # certificateAuthorityData specifies a Base64 PEM-encoded certificate authority certificate of your identity
# # provider. It's not needed if your identity provider's certificate was issued by a well-known public CA.
# # However, if deployCloudConsoleProxy is true, then this value must be provided, even for a well-known public
# # CA.
# certificateAuthorityData: <Base64 PEM-encoded certificate authority certificate of your OIDC provider; optional>
# Node access configuration; uncomment this section if you wish to use a non-root user
# with passwordless sudo capability for machine login.
# nodeAccess:
# loginUser: <login user name>
---
# Node pools for worker nodes
apiVersion: baremetal.cluster.gke.io/v1
kind: NodePool
metadata:
name: node-pool-1
namespace: cluster-hybrid1
spec:
clusterName: hybrid1
nodes:
- address: 10.200.0.7
- address: 10.200.0.8