Install Istio with an External Control Plane
This guide walks you through the process of installing an external control plane and then connecting one or more remote clusters to it. The external control plane deployment model allows a mesh operator to install and manage a control plane on an external cluster, separate from the data plane cluster (or multiple clusters) comprising the mesh. This deployment model allows a clear separation between mesh operators and mesh administrators. Mesh operators install and manage Istio control planes while mesh admins only need to configure the mesh.
Envoy proxies (sidecars and gateways) running in the remote cluster access the external istiod via an ingress gateway which exposes the endpoints needed for discovery, CA, injection, and validation.
While configuration and management of the external control plane is done by the mesh operator in the external cluster, the first remote cluster connected to an external control plane serves as the config cluster for the mesh itself. The mesh administrator will use the config cluster to configure the mesh resources (gateways, virtual services, etc.) in addition to the mesh services themselves. The external control plane will remotely access this configuration from the Kubernetes API server, as shown in the above diagram.
Before you begin
Clusters
This guide requires that you have two Kubernetes clusters with any of the supported Kubernetes versions: 1.18, 1.19, 1.20, 1.21.
The first cluster will host the external control plane installed in the
external-istiod
namespace. An ingress gateway is also installed in the istio-system
namespace to provide
cross-cluster access to the external control plane.
The second cluster is a remote cluster that will run the mesh application workloads. Its Kubernetes API server also provides the mesh configuration used by the external control plane (istiod) to configure the workload proxies.
API server access
The Kubernetes API server in the remote cluster must be accessible to the external control plane cluster. Many cloud providers make API servers publicly accessible via network load balancers (NLBs). If the API server is not directly accessible, you will need to modify the installation procedure to enable access. For example, the east-west gateway used in a multicluster configuration could also be used to enable access to the API server.
Environment Variables
The following environment variables will be used throughout to simplify the instructions:
Variable | Description |
---|---|
CTX_EXTERNAL_CLUSTER | The context name in the default Kubernetes configuration file used for accessing the external control plane cluster. |
CTX_REMOTE_CLUSTER | The context name in the default Kubernetes configuration file used for accessing the remote cluster. |
REMOTE_CLUSTER_NAME | The name of the remote cluster. |
EXTERNAL_ISTIOD_ADDR | The hostname for the ingress gateway on the external control plane cluster. This is used by the remote cluster to access the external control plane. |
SSL_SECRET_NAME | The name of the secret that holds the TLS certs for the ingress gateway on the external control plane cluster. |
Set the CTX_EXTERNAL_CLUSTER
, CTX_REMOTE_CLUSTER
, and REMOTE_CLUSTER_NAME
now. You will set the others later.
$ export CTX_EXTERNAL_CLUSTER=<your external cluster context>
$ export CTX_REMOTE_CLUSTER=<your remote cluster context>
$ export REMOTE_CLUSTER_NAME=<your remote cluster name>
Cluster configuration
Mesh operator steps
A mesh operator is responsible for installing and managing the external Istio control plane on the external cluster. This includes configuring an ingress gateway on the external cluster, which allows the remote cluster to access the control plane, and installing the sidecar injector webhook configuration on the remote cluster so that it will use the external control plane.
Set up a gateway in the external cluster
Create the Istio install configuration for the ingress gateway that will expose the external control plane ports to other clusters:
$ cat <<EOF > controlplane-gateway.yaml apiVersion: install.istio.io/v1alpha1 kind: IstioOperator metadata: namespace: istio-system spec: components: ingressGateways: - name: istio-ingressgateway enabled: true k8s: service: ports: - port: 15021 targetPort: 15021 name: status-port - port: 15012 targetPort: 15012 name: tls-xds - port: 15017 targetPort: 15017 name: tls-webhook EOF
Then, install the gateway in the
istio-system
namespace of the external cluster:$ istioctl install -f controlplane-gateway.yaml --context="${CTX_EXTERNAL_CLUSTER}"
Run the following command to confirm that the ingress gateway is up and running:
$ kubectl get po -n istio-system --context="${CTX_EXTERNAL_CLUSTER}" NAME READY STATUS RESTARTS AGE istio-ingressgateway-9d4c7f5c7-7qpzz 1/1 Running 0 29s istiod-68488cd797-mq8dn 1/1 Running 0 38s
You will notice an istiod deployment is also created in the
istio-system
namespace. This is used to configure the ingress gateway and is NOT the control plane used by remote clusters.Configure your environment to expose the Istio ingress gateway service using a public hostname with TLS. Set the
EXTERNAL_ISTIOD_ADDR
environment variable to the hostname andSSL_SECRET_NAME
environment variable to the secret that holds the TLS certs:$ export EXTERNAL_ISTIOD_ADDR=<your external istiod host> $ export SSL_SECRET_NAME=<your external istiod secret>
Set up the remote config cluster
Create the remote cluster’s Istio install configuration, which installs the injection webhook that uses the external control plane’s injector, instead of a locally deployed one. Because this cluster also serves as the config cluster, the Istio CRDs and
istio
configmap (i.e., global mesh config) are also installed by settingbase.enabled
andpilot.configMap
totrue
:$ cat <<EOF > remote-config-cluster.yaml apiVersion: install.istio.io/v1alpha1 kind: IstioOperator metadata: namespace: external-istiod spec: profile: external components: base: enabled: true values: global: istioNamespace: external-istiod pilot: configMap: true istiodRemote: injectionURL: https://${EXTERNAL_ISTIOD_ADDR}:15017/inject/:ENV:cluster=${REMOTE_CLUSTER_NAME}:ENV:net=network1 base: validationURL: https://${EXTERNAL_ISTIOD_ADDR}:15017/validate EOF
Then, install the configuration on the remote cluster:
$ kubectl create namespace external-istiod --context="${CTX_REMOTE_CLUSTER}" $ istioctl manifest generate -f remote-config-cluster.yaml | kubectl apply --context="${CTX_REMOTE_CLUSTER}" -f -
Confirm that the remote cluster’s webhook configuration has been installed:
$ kubectl get mutatingwebhookconfiguration -n external-istiod --context="${CTX_REMOTE_CLUSTER}" NAME WEBHOOKS AGE istio-sidecar-injector-external-istiod 4 6m24s
Set up the control plane in the external cluster
Create the
external-istiod
namespace, which will be used to host the external control plane:$ kubectl create namespace external-istiod --context="${CTX_EXTERNAL_CLUSTER}"
The control plane in the external cluster needs access to the remote cluster to discover services, endpoints, and pod attributes. Create a secret with credentials to access the remote cluster’s
kube-apiserver
and install it in the external cluster:$ kubectl create sa istiod-service-account -n external-istiod --context="${CTX_EXTERNAL_CLUSTER}" $ istioctl x create-remote-secret \ --context="${CTX_REMOTE_CLUSTER}" \ --type=config \ --namespace=external-istiod | \ kubectl apply -f - --context="${CTX_EXTERNAL_CLUSTER}"
Create the Istio configuration to install the control plane in the
external-istiod
namespace of the external cluster. Notice that istiod is configured to use the locally mountedistio
configmap and theSHARED_MESH_CONFIG
environment variable is set toistio
. This instructs istiod to merge the values set by the mesh admin in the config cluster’s configmap with the values in the local configmap set by the mesh operator, here, which will take precedence if there are any conflicts:$ cat <<EOF > external-istiod.yaml apiVersion: install.istio.io/v1alpha1 kind: IstioOperator metadata: namespace: external-istiod spec: profile: empty meshConfig: rootNamespace: external-istiod defaultConfig: discoveryAddress: $EXTERNAL_ISTIOD_ADDR:15012 proxyMetadata: XDS_ROOT_CA: /etc/ssl/certs/ca-certificates.crt CA_ROOT_CA: /etc/ssl/certs/ca-certificates.crt components: pilot: enabled: true k8s: overlays: - kind: Deployment name: istiod patches: - path: spec.template.spec.volumes[100] value: |- name: config-volume configMap: name: istio - path: spec.template.spec.volumes[100] value: |- name: inject-volume configMap: name: istio-sidecar-injector - path: spec.template.spec.containers[0].volumeMounts[100] value: |- name: config-volume mountPath: /etc/istio/config - path: spec.template.spec.containers[0].volumeMounts[100] value: |- name: inject-volume mountPath: /var/lib/istio/inject env: - name: INJECTION_WEBHOOK_CONFIG_NAME value: "" - name: VALIDATION_WEBHOOK_CONFIG_NAME value: "" - name: EXTERNAL_ISTIOD value: "true" - name: CLUSTER_ID value: ${REMOTE_CLUSTER_NAME} - name: SHARED_MESH_CONFIG value: istio values: global: caAddress: $EXTERNAL_ISTIOD_ADDR:15012 istioNamespace: external-istiod operatorManageWebhooks: true meshID: mesh1 EOF
Then, apply the Istio configuration on the external cluster:
$ istioctl install -f external-istiod.yaml --context="${CTX_EXTERNAL_CLUSTER}"
Confirm that the external istiod has been successfully deployed:
$ kubectl get po -n external-istiod --context="${CTX_EXTERNAL_CLUSTER}" NAME READY STATUS RESTARTS AGE istiod-779bd6fdcf-bd6rg 1/1 Running 0 70s
Create the Istio
Gateway
,VirtualService
, andDestinationRule
configuration to route traffic from the ingress gateway to the external control plane:$ cat <<EOF > external-istiod-gw.yaml apiVersion: networking.istio.io/v1beta1 kind: Gateway metadata: name: external-istiod-gw namespace: external-istiod spec: selector: istio: ingressgateway servers: - port: number: 15012 protocol: https name: https-XDS tls: mode: SIMPLE credentialName: $SSL_SECRET_NAME hosts: - $EXTERNAL_ISTIOD_ADDR - port: number: 15017 protocol: https name: https-WEBHOOK tls: mode: SIMPLE credentialName: $SSL_SECRET_NAME hosts: - $EXTERNAL_ISTIOD_ADDR --- apiVersion: networking.istio.io/v1beta1 kind: VirtualService metadata: name: external-istiod-vs namespace: external-istiod spec: hosts: - $EXTERNAL_ISTIOD_ADDR gateways: - external-istiod-gw http: - match: - port: 15012 route: - destination: host: istiod.external-istiod.svc.cluster.local port: number: 15012 - match: - port: 15017 route: - destination: host: istiod.external-istiod.svc.cluster.local port: number: 443 --- apiVersion: networking.istio.io/v1alpha3 kind: DestinationRule metadata: name: external-istiod-dr namespace: external-istiod spec: host: istiod.external-istiod.svc.cluster.local trafficPolicy: portLevelSettings: - port: number: 15012 tls: mode: SIMPLE connectionPool: http: h2UpgradePolicy: UPGRADE - port: number: 443 tls: mode: SIMPLE EOF
Then, apply the configuration on the external cluster:
$ kubectl apply -f external-istiod-gw.yaml --context="${CTX_EXTERNAL_CLUSTER}"
Mesh admin steps
Now that Istio is up and running, a mesh administrator only needs to deploy and configure services in the mesh, including gateways, if needed.
Deploy a sample application
Create, and label for injection, the
sample
namespace on the remote cluster:$ kubectl create --context="${CTX_REMOTE_CLUSTER}" namespace sample $ kubectl label --context="${CTX_REMOTE_CLUSTER}" namespace sample istio-injection=enabled
Deploy the
helloworld
(v1
) andsleep
samples:$ kubectl apply -f @samples/helloworld/helloworld.yaml@ -l service=helloworld -n sample --context="${CTX_REMOTE_CLUSTER}" $ kubectl apply -f @samples/helloworld/helloworld.yaml@ -l version=v1 -n sample --context="${CTX_REMOTE_CLUSTER}" $ kubectl apply -f @samples/sleep/sleep.yaml@ -n sample --context="${CTX_REMOTE_CLUSTER}"
Wait a few seconds for the
helloworld
andsleep
pods to be running with sidecars injected:$ kubectl get pod -n sample --context="${CTX_REMOTE_CLUSTER}" NAME READY STATUS RESTARTS AGE helloworld-v1-776f57d5f6-s7zfc 2/2 Running 0 10s sleep-64d7d56698-wqjnm 2/2 Running 0 9s
Send a request from the
sleep
pod to thehelloworld
service:$ kubectl exec --context="${CTX_REMOTE_CLUSTER}" -n sample -c sleep \ "$(kubectl get pod --context="${CTX_REMOTE_CLUSTER}" -n sample -l app=sleep -o jsonpath='{.items[0].metadata.name}')" \ -- curl -sS helloworld.sample:5000/hello Hello version: v1, instance: helloworld-v1-776f57d5f6-s7zfc
Enable gateways
Enable an ingress gateway on the remote cluster:
$ cat <<EOF > istio-ingressgateway.yaml apiVersion: install.istio.io/v1alpha1 kind: IstioOperator spec: profile: empty components: ingressGateways: - namespace: external-istiod name: istio-ingressgateway enabled: true values: gateways: istio-ingressgateway: injectionTemplate: gateway EOF $ istioctl install -f istio-ingressgateway.yaml --context="${CTX_REMOTE_CLUSTER}"
Enable an egress gateway, or other gateways, on the remote cluster (optional):
$ cat <<EOF > istio-egressgateway.yaml apiVersion: install.istio.io/v1alpha1 kind: IstioOperator spec: profile: empty components: egressGateways: - namespace: external-istiod name: istio-egressgateway enabled: true values: gateways: istio-egressgateway: injectionTemplate: gateway EOF $ istioctl install -f istio-egressgateway.yaml --context="${CTX_REMOTE_CLUSTER}"
Confirm that the Istio ingress gateway is running:
$ kubectl get pod -l app=istio-ingressgateway -n external-istiod --context="${CTX_REMOTE_CLUSTER}" NAME READY STATUS RESTARTS AGE istio-ingressgateway-7bcd5c6bbd-kmtl4 1/1 Running 0 8m4s
Expose the
helloworld
application on the ingress gateway:$ kubectl apply -f @samples/helloworld/helloworld-gateway.yaml@ -n sample --context="${CTX_REMOTE_CLUSTER}"
Set the
GATEWAY_URL
environment variable (see determining the ingress IP and ports for details):$ export INGRESS_HOST=$(kubectl -n external-istiod --context="${CTX_REMOTE_CLUSTER}" get service istio-ingressgateway -o jsonpath='{.status.loadBalancer.ingress[0].ip}') $ export INGRESS_PORT=$(kubectl -n external-istiod --context="${CTX_REMOTE_CLUSTER}" get service istio-ingressgateway -o jsonpath='{.spec.ports[?(@.name=="http2")].port}') $ export GATEWAY_URL=$INGRESS_HOST:$INGRESS_PORT
Confirm you can access the
helloworld
application through the ingress gateway:$ curl -s "http://${GATEWAY_URL}/hello" Hello version: v1, instance: helloworld-v1-776f57d5f6-s7zfc
Adding clusters to the mesh (optional)
This section shows you how to expand an existing external control plane mesh to multicluster by adding another remote cluster. This allows you to easily distribute services and use location-aware routing and fail over to support high availability of your application.
Unlike the first remote cluster, the second and subsequent clusters added to the same external control plane do not provide mesh config, but instead are only sources of endpoint configuration, just like remote clusters in a primary-remote Istio multicluster configuration.
To proceed, you’ll need another Kubernetes cluster for the second remote cluster of the mesh. Set the following environment variables to the context name and cluster name of the cluster:
$ export CTX_SECOND_CLUSTER=<your second remote cluster context>
$ export SECOND_CLUSTER_NAME=<your second remote cluster name>
Register the new cluster
Create a secret with credentials to allow the control plane to access the endpoints on the second remote cluster and install it:
$ istioctl x create-remote-secret \ --context="${CTX_SECOND_CLUSTER}" \ --name="${SECOND_CLUSTER_NAME}" \ --type=remote \ --namespace=external-istiod | \ kubectl apply -f - --context="${CTX_REMOTE_CLUSTER}" #TODO use --context="{CTX_EXTERNAL_CLUSTER}" when #31946 is fixed.
Note that unlike the first remote cluster of the mesh, which also serves as the config cluster, the
--type
argument is set toremote
this time, instead ofconfig
.Create the remote Istio install configuration, which installs the injection webhook that uses the external control plane’s injector, instead of a locally deployed one:
$ cat <<EOF > second-config-cluster.yaml apiVersion: install.istio.io/v1alpha1 kind: IstioOperator metadata: namespace: external-istiod spec: profile: external values: global: istioNamespace: external-istiod istiodRemote: injectionURL: https://${EXTERNAL_ISTIOD_ADDR}:15017/inject/:ENV:cluster=${SECOND_CLUSTER_NAME}:ENV:net=network2 EOF
Then, install the configuration on the remote cluster:
$ istioctl manifest generate -f second-config-cluster.yaml | kubectl apply --context="${CTX_SECOND_CLUSTER}" -f -
Confirm that the remote cluster’s webhook configuration has been installed:
$ kubectl get mutatingwebhookconfiguration -n external-istiod --context="${CTX_SECOND_CLUSTER}" NAME WEBHOOKS AGE istio-sidecar-injector-external-istiod 4 4m13s
Setup east-west gateways
Deploy east-west gateways on both remote clusters:
$ @samples/multicluster/gen-eastwest-gateway.sh@ \ --mesh mesh1 --cluster "${REMOTE_CLUSTER_NAME}" --network network1 > eastwest-gateway-1.yaml $ istioctl manifest generate -f eastwest-gateway-1.yaml \ --set values.gateways.istio-ingressgateway.injectionTemplate=gateway \ --set values.global.istioNamespace=external-istiod | \ kubectl apply --context="${CTX_REMOTE_CLUSTER}" -f -
$ @samples/multicluster/gen-eastwest-gateway.sh@ \ --mesh mesh1 --cluster "${SECOND_CLUSTER_NAME}" --network network2 > eastwest-gateway-2.yaml $ istioctl manifest generate -f eastwest-gateway-2.yaml \ --set values.gateways.istio-ingressgateway.injectionTemplate=gateway \ --set values.global.istioNamespace=external-istiod | \ kubectl apply --context="${CTX_SECOND_CLUSTER}" -f -
Wait for the east-west gateways to be assigned external IP addresses:
$ kubectl --context="${CTX_REMOTE_CLUSTER}" get svc istio-eastwestgateway -n external-istiod NAME TYPE CLUSTER-IP EXTERNAL-IP PORT(S) AGE istio-eastwestgateway LoadBalancer 10.0.12.121 34.122.91.98 ... 51s
$ kubectl --context="${CTX_SECOND_CLUSTER}" get svc istio-eastwestgateway -n external-istiod NAME TYPE CLUSTER-IP EXTERNAL-IP PORT(S) AGE istio-eastwestgateway LoadBalancer 10.0.12.121 34.122.91.99 ... 51s
Expose services via the east-west gateways:
$ kubectl --context="${CTX_REMOTE_CLUSTER}" apply -n external-istiod -f \ @samples/multicluster/expose-services.yaml@
$ kubectl --context="${CTX_SECOND_CLUSTER}" apply -n external-istiod -f \ @samples/multicluster/expose-services.yaml@
Validate the installation
Create, and label for injection, the
sample
namespace on the remote cluster:$ kubectl create --context="${CTX_SECOND_CLUSTER}" namespace sample $ kubectl label --context="${CTX_SECOND_CLUSTER}" namespace sample istio-injection=enabled
Deploy the
helloworld
(v2
) andsleep
samples:$ kubectl apply -f @samples/helloworld/helloworld.yaml@ -l service=helloworld -n sample --context="${CTX_SECOND_CLUSTER}" $ kubectl apply -f @samples/helloworld/helloworld.yaml@ -l version=v2 -n sample --context="${CTX_SECOND_CLUSTER}" $ kubectl apply -f @samples/sleep/sleep.yaml@ -n sample --context="${CTX_SECOND_CLUSTER}"
Wait a few seconds for the
helloworld
andsleep
pods to be running with sidecars injected:$ kubectl get pod -n sample --context="${CTX_SECOND_CLUSTER}" NAME READY STATUS RESTARTS AGE helloworld-v2-54df5f84b-9hxgw 2/2 Running 0 10s sleep-557747455f-wtdbr 2/2 Running 0 9s
Send a request from the
sleep
pod to thehelloworld
service:$ kubectl exec --context="${CTX_SECOND_CLUSTER}" -n sample -c sleep \ "$(kubectl get pod --context="${CTX_SECOND_CLUSTER}" -n sample -l app=sleep -o jsonpath='{.items[0].metadata.name}')" \ -- curl -sS helloworld.sample:5000/hello Hello version: v2, instance: helloworld-v2-54df5f84b-9hxgw
Confirm that when accessing the
helloworld
application several times through the ingress gateway, both versionv1
andv2
are now being called:$ for i in {1..10}; do curl -s "http://${GATEWAY_URL}/hello"; done Hello version: v1, instance: helloworld-v1-776f57d5f6-s7zfc Hello version: v2, instance: helloworld-v2-54df5f84b-9hxgw Hello version: v1, instance: helloworld-v1-776f57d5f6-s7zfc Hello version: v2, instance: helloworld-v2-54df5f84b-9hxgw ...