Shared control plane (single-network)

Follow this guide to install an Istio multicluster service mesh where the Kubernetes cluster services and the applications in each cluster have the capability to expose their internal Kubernetes network to other clusters.

In this configuration, multiple Kubernetes clusters running a remote configuration connect to a shared Istio control plane. Once one or more remote Kubernetes clusters are connected to the Istio control plane, Envoy can then form a mesh network across multiple clusters.

Istio mesh spanning multiple Kubernetes clusters with direct network access to remote pods over VPN
Istio mesh spanning multiple Kubernetes clusters with direct network access to remote pods over VPN

Prerequisites

  • Two or more clusters running a supported Kubernetes version (1.14, 1.15, 1.16).

  • The ability to deploy the Istio control plane on one of the clusters.

  • A RFC1918 network, VPN, or an alternative more advanced network technique meeting the following requirements:

    • Individual cluster Pod CIDR ranges and service CIDR ranges must be unique across the multicluster environment and may not overlap.

    • All pod CIDRs in every cluster must be routable to each other.

    • All Kubernetes control plane API servers must be routable to each other.

This guide describes how to install a multicluster Istio topology using the remote configuration profile provided by Istio.

Deploy the local control plane

Install the Istio control plane on one Kubernetes cluster.

Set environment variables

Wait for the Istio control plane to finish initializing before following the steps in this section.

You must run these operations on the Istio control plane cluster to capture the Istio control plane service endpoints, for example, the Pilot and Policy Pod IP endpoints.

Set the environment variables with the following commands:

$ export PILOT_POD_IP=$(kubectl -n istio-system get pod -l istio=pilot -o jsonpath='{.items[0].status.podIP}')
$ export POLICY_POD_IP=$(kubectl -n istio-system get pod -l istio-mixer-type=policy -o jsonpath='{.items[0].status.podIP}')
$ export TELEMETRY_POD_IP=$(kubectl -n istio-system get pod -l istio-mixer-type=telemetry -o jsonpath='{.items[0].status.podIP}')

Normally, automatic sidecar injection on the remote clusters is enabled. To perform a manual sidecar injection refer to the manual sidecar example

Install the Istio remote

You must deploy the istio-remote component to each remote Kubernetes cluster. You can install the component in one of two ways:

  1. Use the following command on the remote cluster to install the Istio control plane service endpoints:

    $ istioctl manifest apply \
    --set profile=remote \
    --set values.global.controlPlaneSecurityEnabled=false \
    --set values.global.createRemoteSvcEndpoints=true \
    --set values.global.remotePilotCreateSvcEndpoint=true \
    --set values.global.remotePilotAddress=${PILOT_POD_IP} \
    --set values.global.remotePolicyAddress=${POLICY_POD_IP} \
    --set values.global.remoteTelemetryAddress=${TELEMETRY_POD_IP} \
    --set gateways.enabled=false \
    --set autoInjection.enabled=true
    
  2. The following command example labels the default namespace. Use similar commands to label all the remote cluster’s namespaces requiring automatic sidecar injection.

    $ kubectl label namespace default istio-injection=enabled
    

    Repeat for all Kubernetes namespaces that need to setup automatic sidecar injection.

Installation configuration parameters

You must configure the remote cluster’s sidecars interaction with the Istio control plane including the following endpoints in the istio-remote profile: pilot, policy, telemetry and tracing service. The profile enables automatic sidecar injection in the remote cluster by default. You can disable the automatic sidecar injection via a separate setting.

The following table shows the istioctl configuration values for remote clusters:

Install settingAccepted ValuesDefaultPurpose of Value
values.global.remotePilotAddressA valid IP address or hostnameNoneSpecifies the Istio control plane’s pilot Pod IP address or remote cluster DNS resolvable hostname
values.global.remotePolicyAddressA valid IP address or hostnameNoneSpecifies the Istio control plane’s policy Pod IP address or remote cluster DNS resolvable hostname
values.global.remoteTelemetryAddressA valid IP address or hostnameNoneSpecifies the Istio control plane’s telemetry Pod IP address or remote cluster DNS resolvable hostname
values.sidecarInjectorWebhook.enabledtrue, falsetrueSpecifies whether to enable automatic sidecar injection on the remote cluster
values.global.remotePilotCreateSvcEndpointtrue, falsefalseIf set, a selector-less service and endpoint for istio-pilot are created with the remotePilotAddress IP, which ensures the istio-pilot.<namespace> is DNS resolvable in the remote cluster.
values.global.createRemoteSvcEndpointstrue, falsefalseIf set, selector-less services and endpoints for istio-pilot, istio-telemetry, istio-policy are created with the corresponding remote IPs: remotePilotAddress, remoteTelmetryAddress, remotePolicyAddress, which ensures the service names are DNS resolvable in the remote cluster.

Generate configuration files for remote clusters

The Istio control plane requires access to all clusters in the mesh to discover services, endpoints, and pod attributes. The following steps describe how to generate a kubeconfig configuration file for the Istio control plane to use a remote cluster.

Perform this procedure on each remote cluster to add the cluster to the service mesh. This procedure requires the cluster-admin user access permission to the remote cluster.

  1. Set the environment variables needed to build the kubeconfig file for the istio-reader-service-account service account with the following commands:

    $ export WORK_DIR=$(pwd)
    $ CLUSTER_NAME=$(kubectl config view --minify=true -o jsonpath='{.clusters[].name}')
    $ export KUBECFG_FILE=${WORK_DIR}/${CLUSTER_NAME}
    $ SERVER=$(kubectl config view --minify=true -o jsonpath='{.clusters[].cluster.server}')
    $ NAMESPACE=istio-system
    $ SERVICE_ACCOUNT=istio-reader-service-account
    $ SECRET_NAME=$(kubectl get sa ${SERVICE_ACCOUNT} -n ${NAMESPACE} -o jsonpath='{.secrets[].name}')
    $ CA_DATA=$(kubectl get secret ${SECRET_NAME} -n ${NAMESPACE} -o jsonpath="{.data['ca\.crt']}")
    $ TOKEN=$(kubectl get secret ${SECRET_NAME} -n ${NAMESPACE} -o jsonpath="{.data['token']}" | base64 --decode)
    
  2. Create a kubeconfig file in the working directory for the istio-reader-service-account service account with the following command:

    $ cat <<EOF > ${KUBECFG_FILE}
    apiVersion: v1
    clusters:
       - cluster:
           certificate-authority-data: ${CA_DATA}
           server: ${SERVER}
         name: ${CLUSTER_NAME}
    contexts:
       - context:
           cluster: ${CLUSTER_NAME}
           user: ${CLUSTER_NAME}
         name: ${CLUSTER_NAME}
    current-context: ${CLUSTER_NAME}
    kind: Config
    preferences: {}
    users:
       - name: ${CLUSTER_NAME}
         user:
           token: ${TOKEN}
    EOF
    
  3. (Optional) Create file with environment variables to create the remote cluster’s secret:

    $ cat <<EOF > remote_cluster_env_vars
    export CLUSTER_NAME=${CLUSTER_NAME}
    export KUBECFG_FILE=${KUBECFG_FILE}
    export NAMESPACE=${NAMESPACE}
    EOF
    

At this point, you created the remote clusters’ kubeconfig files in the current directory. The filename of the kubeconfig file is the same as the original cluster name.

Instantiate the credentials

Perform this procedure on the cluster running the Istio control plane. This procedure uses the WORK_DIR, CLUSTER_NAME, and NAMESPACE environment values set and the file created for the remote cluster’s secret from the previous section.

If you created the environment variables file for the remote cluster’s secret, source the file with the following command:

$ source remote_cluster_env_vars

You can install Istio in a different namespace. This procedure uses the istio-system namespace.

Create a secret and label it properly for each remote cluster:

$ kubectl create secret generic ${CLUSTER_NAME} --from-file ${KUBECFG_FILE} -n ${NAMESPACE}
$ kubectl label secret ${CLUSTER_NAME} istio/multiCluster=true -n ${NAMESPACE}

Uninstalling the remote cluster

To uninstall the cluster run the following command:

$ istioctl manifest generate \
--set profile=remote \
--set values.global.controlPlaneSecurityEnabled=false \
--set values.global.createRemoteSvcEndpoints=true \
--set values.global.remotePilotCreateSvcEndpoint=true \
--set values.global.remotePilotAddress=${PILOT_POD_IP} \
--set values.global.remotePolicyAddress=${POLICY_POD_IP} \
--set values.global.remoteTelemetryAddress=${TELEMETRY_POD_IP} \
--set gateways.enabled=false \
--set autoInjection.enabled=true | kubectl delete -f -

Manual sidecar injection example

The following example shows how to use the istioctl manifest command to generate the manifest for a remote cluster with the automatic sidecar injection disabled. Additionally, the example shows how to use the configmaps of the remote cluster with the istioctl kube-inject command to generate any application manifests for the remote cluster.

Perform the following procedure against the remote cluster.

Before you begin, set the endpoint IP environment variables as described in the set the environment variables section

  1. Install the Istio remote profile:

    $ istioctl manifest apply \
    --set profile=remote \
    --set values.global.controlPlaneSecurityEnabled=false \
    --set values.global.createRemoteSvcEndpoints=true \
    --set values.global.remotePilotCreateSvcEndpoint=true \
    --set values.global.remotePilotAddress=${PILOT_POD_IP} \
    --set values.global.remotePolicyAddress=${POLICY_POD_IP} \
    --set values.global.remoteTelemetryAddress=${TELEMETRY_POD_IP} \
    --set gateways.enabled=false \
    --set autoInjection.enabled=false
    
  2. Generate the kubeconfig configuration file for each remote cluster.

  3. Instantiate the credentials for each remote cluster.

Manually inject the sidecars into the application manifests

The following example istioctl command injects the sidecars into the application manifests. Run the following commands in a shell with the kubeconfig context set up for the remote cluster.

$ ORIGINAL_SVC_MANIFEST=mysvc-v1.yaml
$ istioctl kube-inject --injectConfigMapName istio-sidecar-injector --meshConfigMapName istio -f ${ORIGINAL_SVC_MANIFEST} | kubectl apply -f -

Access services from different clusters

Kubernetes resolves DNS on a cluster basis. Because the DNS resolution is tied to the cluster, you must define the service object in every cluster where a client runs, regardless of the location of the service’s endpoints. To ensure this is the case, duplicate the service object to every cluster using kubectl. Duplication ensures Kubernetes can resolve the service name in any cluster. Since the service objects are defined in a namespace, you must define the namespace if it doesn’t exist, and include it in the service definitions in all clusters.

Deployment considerations

The previous procedures provide a simple and step-by-step guide to deploy a multicluster environment. A production environment might require additional steps or more complex deployment options. The procedures gather the endpoint IPs of the Istio services and use them to invoke istioctl. This process creates Istio services on the remote clusters. As part of creating those services and endpoints in the remote cluster, Kubernetes adds DNS entries to the kube-dns configuration object.

This allows the kube-dns configuration object in the remote clusters to resolve the Istio service names for all Envoy sidecars in those remote clusters. Since Kubernetes pods don’t have stable IPs, restart of any Istio service pod in the control plane cluster causes its endpoint to change. Therefore, any connection made from remote clusters to that endpoint are broken. This behavior is documented in Istio issue #4822

To either avoid or resolve this scenario several options are available. This section provides a high level overview of these options:

  • Update the DNS entries
  • Use a load balancer service type
  • Expose the Istio services via a gateway

Update the DNS entries

Upon any failure or restart of the local Istio control plane, kube-dns on the remote clusters must be updated with the correct endpoint mappings for the Istio services. There are a number of ways this can be done. The most obvious is to rerun the istioctl command in the remote cluster after the Istio services on the control plane cluster have restarted.

Use load balance service type

In Kubernetes, you can declare a service with a service type of LoadBalancer. See the Kubernetes documentation on service types for more information.

A simple solution to the pod restart issue is to use load balancers for the Istio services. Then, you can use the load balancers’ IPs as the Istio services’ endpoint IPs to configure the remote clusters. You may need load balancer IPs for these Istio services:

  • istio-pilot
  • istio-telemetry
  • istio-policy

Currently, the Istio installation doesn’t provide an option to specify service types for the Istio services. You can manually specify the service types in the Istio manifests.

Expose the Istio services via a gateway

This method uses the Istio ingress gateway functionality. The remote clusters have the istio-pilot, istio-telemetry and istio-policy services pointing to the load balanced IP of the Istio ingress gateway. Then, all the services point to the same IP. You must then create the destination rules to reach the proper Istio service in the main cluster in the ingress gateway.

This method provides two alternatives:

  • Re-use the default Istio ingress gateway installed with the provided manifests. You only need to add the correct destination rules.

  • Create another Istio ingress gateway specifically for the multicluster.

Security

Istio supports deployment of mutual TLS between the control plane components as well as between sidecar injected application pods.

Control plane security

To enable control plane security follow these general steps:

  1. Deploy the Istio control plane cluster with:

  2. Deploy the Istio remote clusters with:

    • The control plane security enabled.

    • The citadel certificate self signing disabled.

    • A secret named cacerts in the Istio control plane namespace with the CA certificates. The Certificate Authority (CA) of the main cluster or a root CA must sign the CA certificate for the remote clusters too.

    • The Istio pilot service hostname must be resolvable via DNS. DNS resolution is required because Istio configures the sidecar to verify the certificate subject names using the istio-pilot.<namespace> subject name format.

    • Set control plane IPs or resolvable host names.

Mutual TLS between application pods

To enable mutual TLS for all application pods, follow these general steps:

  1. Deploy the Istio control plane cluster with:

    • Mutual TLS globally enabled.

    • The Citadel certificate self-signing disabled.

    • A secret named cacerts in the Istio control plane namespace with the CA certificates

  2. Deploy the Istio remote clusters with:

    • Mutual TLS globally enabled.

    • The Citadel certificate self-signing disabled.

    • A secret named cacerts in the Istio control plane namespace with the CA certificates The CA of the main cluster or a root CA must sign the CA certificate for the remote clusters too.

Example deployment

This example procedure installs Istio with both the control plane mutual TLS and the application pod mutual TLS enabled. The procedure sets up a remote cluster with a selector-less service and endpoint. Istio Pilot uses the service and endpoint to allow the remote sidecars to resolve the istio-pilot.istio-system hostname via Istio’s local Kubernetes DNS.

Primary cluster: deploy the control plane cluster

  1. Create the cacerts secret using the Istio certificate samples in the istio-system namespace:

    $ kubectl create ns istio-system
    $ kubectl create secret generic cacerts -n istio-system --from-file=samples/certs/ca-cert.pem --from-file=samples/certs/ca-key.pem --from-file=samples/certs/root-cert.pem --from-file=samples/certs/cert-chain.pem
    
  2. Deploy the Istio control plane with security enabled for the control plane and the application pod:

    $ istioctl manifest apply \
      --set values.global.mtls.enabled=true \
      --set values.security.selfSigned=false
    

Remote cluster: deploy Istio components

  1. Create the cacerts secret using the Istio certificate samples in the istio-system namespace:

    $ kubectl create ns istio-system
    $ kubectl create secret generic cacerts -n istio-system --from-file=samples/certs/ca-cert.pem --from-file=samples/certs/ca-key.pem --from-file=samples/certs/root-cert.pem --from-file=samples/certs/cert-chain.pem
    
  2. Set the environment variables for the IP addresses of the pods as described in the setting environment variables section.

  3. The following command deploys the remote cluster’s components with security enabled for the control plane and the application pod and enables the creation of the an Istio Pilot selector-less service and endpoint to get a DNS entry in the remote cluster.

    $ istioctl manifest apply \
      --set profile=remote \
      --set values.global.mtls.enabled=true \
      --set values.security.selfSigned=false \
      --set values.global.createRemoteSvcEndpoints=true \
      --set values.global.remotePilotCreateSvcEndpoint=true \
      --set values.global.remotePilotAddress=${PILOT_POD_IP} \
      --set values.global.remotePolicyAddress=${POLICY_POD_IP} \
      --set values.global.remoteTelemetryAddress=${TELEMETRY_POD_IP} \
      --set gateways.enabled=false \
      --set autoInjection.enabled=true
    
  4. To generate the kubeconfig configuration file for the remote cluster, follow the steps in the Kubernetes configuration section

Primary cluster: instantiate credentials

You must instantiate credentials for each remote cluster. Follow the instantiate credentials procedure to complete the deployment.

Congratulations!

You have configured all the Istio components in both clusters to use mutual TLS between application sidecars, the control plane components, and other application sidecars.

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