Installing the Sidecar
Injection
In order to take advantage of all of Istio’s features, pods in the mesh must be running an Istio sidecar proxy.
The following sections describe two
ways of injecting the Istio sidecar into a pod: enabling automatic Istio sidecar injection in the pod’s namespace,
or by manually using the istioctl
command.
When enabled in a pod’s namespace, automatic injection injects the proxy configuration at pod creation time using an admission controller.
Manual injection directly modifies configuration, like deployments, by adding the proxy configuration into it.
If you are not sure which one to use, automatic injection is recommended.
Automatic sidecar injection
Sidecars can be automatically added to applicable Kubernetes pods using a mutating webhook admission controller provided by Istio.
When you set the istio-injection=enabled
label on a namespace and the injection webhook is enabled, any new pods that are created in that namespace will automatically have a sidecar added to them.
Note that unlike manual injection, automatic injection occurs at the pod-level. You won’t see any change to the deployment itself. Instead, you’ll want to check individual pods (via kubectl describe
) to see the injected proxy.
Manual sidecar injection
To manually inject a deployment, use istioctl kube-inject
:
$ istioctl kube-inject -f @samples/sleep/sleep.yaml@ | kubectl apply -f -
serviceaccount/sleep created
service/sleep created
deployment.apps/sleep created
By default, this will use the in-cluster configuration. Alternatively, injection can be done using local copies of the configuration.
$ kubectl -n istio-system get configmap istio-sidecar-injector -o=jsonpath='{.data.config}' > inject-config.yaml
$ kubectl -n istio-system get configmap istio-sidecar-injector -o=jsonpath='{.data.values}' > inject-values.yaml
$ kubectl -n istio-system get configmap istio -o=jsonpath='{.data.mesh}' > mesh-config.yaml
Run kube-inject
over the input file and deploy.
$ istioctl kube-inject \
--injectConfigFile inject-config.yaml \
--meshConfigFile mesh-config.yaml \
--valuesFile inject-values.yaml \
--filename @samples/sleep/sleep.yaml@ \
| kubectl apply -f -
serviceaccount/sleep created
service/sleep created
deployment.apps/sleep created
Verify that the sidecar has been injected into the sleep pod with 2/2
under the READY column.
$ kubectl get pod -l app=sleep
NAME READY STATUS RESTARTS AGE
sleep-64c6f57bc8-f5n4x 2/2 Running 0 24s
Deploying an app
Deploy sleep app. Verify both deployment and pod have a single container.
$ kubectl apply -f @samples/sleep/sleep.yaml@
$ kubectl get deployment -o wide
NAME READY UP-TO-DATE AVAILABLE AGE CONTAINERS IMAGES SELECTOR
sleep 1/1 1 1 12s sleep curlimages/curl app=sleep
$ kubectl get pod
NAME READY STATUS RESTARTS AGE
sleep-8f795f47d-hdcgs 1/1 Running 0 42s
Label the default
namespace with istio-injection=enabled
$ kubectl label namespace default istio-injection=enabled --overwrite
$ kubectl get namespace -L istio-injection
NAME STATUS AGE ISTIO-INJECTION
default Active 5m9s enabled
...
Injection occurs at pod creation time. Kill the running pod and verify a new pod is created with the injected sidecar. The original pod has 1/1 READY
containers, and the pod with injected sidecar has 2/2 READY
containers.
$ kubectl delete pod -l app=sleep
$ kubectl get pod -l app=sleep
pod "sleep-776b7bcdcd-7hpnk" deleted
NAME READY STATUS RESTARTS AGE
sleep-776b7bcdcd-7hpnk 1/1 Terminating 0 1m
sleep-776b7bcdcd-bhn9m 2/2 Running 0 7s
View detailed state of the injected pod. You should see the injected istio-proxy
container and corresponding volumes.
$ kubectl describe pod -l app=sleep
...
Events:
Type Reason Age From Message
---- ------ ---- ---- -------
...
Normal Created 11s kubelet Created container istio-init
Normal Started 11s kubelet Started container istio-init
...
Normal Created 10s kubelet Created container sleep
Normal Started 10s kubelet Started container sleep
...
Normal Created 9s kubelet Created container istio-proxy
Normal Started 8s kubelet Started container istio-proxy
Disable injection for the default
namespace and verify new pods are created without the sidecar.
$ kubectl label namespace default istio-injection-
$ kubectl delete pod -l app=sleep
$ kubectl get pod
namespace/default labeled
pod "sleep-776b7bcdcd-bhn9m" deleted
NAME READY STATUS RESTARTS AGE
sleep-776b7bcdcd-bhn9m 2/2 Terminating 0 2m
sleep-776b7bcdcd-gmvnr 1/1 Running 0 2s
Controlling the injection policy
In the above examples, you enabled and disabled injection at the namespace level. Injection can also be controlled
on a per-pod basis, by configuring the sidecar.istio.io/inject
label on a pod:
Resource | Label | Enabled value | Disabled value |
---|---|---|---|
Namespace | istio-injection | enabled | disabled |
Pod | sidecar.istio.io/inject | "true" | "false" |
If you are using control plane revisions, revision specific labels are instead used by a matching istio.io/rev
label.
For example, for a revision named canary
:
Resource | Enabled label | Disabled label |
---|---|---|
Namespace | istio.io/rev=canary | istio-injection=disabled |
Pod | istio.io/rev=canary | sidecar.istio.io/inject="false" |
If the istio-injection
label and the istio.io/rev
label are both present on the same namespace,
the istio-injection
label will take precedence.
The injector is configured with the following logic:
- If either label is disabled, the pod is not injected
- If either label is enabled, the pod is injected
- If neither label is set, the pod is injected if
.values.sidecarInjectorWebhook.enableNamespacesByDefault
is enabled. This is not enabled by default, so generally this means the pod is not injected.
Customizing injection
Generally, pod are injected based on the sidecar injection template, configured in the istio-sidecar-injector
configmap.
Per-pod configuration is available to override these options on individual pods. This is done by adding an istio-proxy
container
to your pod. The sidecar injection will treat any configuration defined here as an override to the default injection template.
Care should be taken when customizing these settings, as this allows complete customization of the resulting Pod
, including making changes that cause the sidecar container to not function properly.
For example, the following configuration customizes a variety of settings, including lowering the CPU requests, adding a volume mount, and adding a preStop
hook:
apiVersion: v1
kind: Pod
metadata:
name: example
spec:
containers:
- name: hello
image: alpine
- name: istio-proxy
image: auto
resources:
requests:
cpu: "100m"
volumeMounts:
- mountPath: /etc/certs
name: certs
lifecycle:
preStop:
exec:
command: ["sleep", "10"]
volumes:
- name: certs
secret:
secretName: istio-certs
In general, any field in a pod can be set. However, care must be taken for certain fields:
- Kubernetes requires the
image
field to be set before the injection has run. While you can set a specific image to override the default one, it is recommended to set theimage
toauto
which will cause the sidecar injector to automatically select the image to use. - Some fields in
Pod
are dependent on related settings. For example, CPU request must be less than CPU limit. If both fields are not configured together, the pod may fail to start.
Additionally, certain fields are configurable by annotations on the pod, although it is recommended to use the above approach to customizing settings.
Custom templates (experimental)
Completely custom templates can also be defined at installation time.
For example, to define a custom template that injects the GREETING
environment variable into the istio-proxy
container:
apiVersion: operator.istio.io/v1alpha1
kind: IstioOperator
metadata:
name: istio
spec:
values:
sidecarInjectorWebhook:
templates:
custom: |
spec:
containers:
- name: istio-proxy
env:
- name: GREETING
value: hello-world
Pods will, by default, use the sidecar
injection template, which is automatically created.
This can be overridden by the inject.istio.io/templates
annotation.
For example, to apply the default template and our customization, you can set inject.istio.io/templates=sidecar,custom
.
In addition to the sidecar
, a gateway
template is provided by default to support proxy injection into Gateway deployments.