Data plane on Kubernetes

On Kubernetes the Dataplane entity is automatically created for you, and because transparent proxying is used to communicate between the service and the sidecar proxy, no code changes are required in your applications.

You can control where Kuma automatically injects the data plane proxy by labeling either the Namespace or the Pod with kuma.io/sidecar-injection=enabled, e.g.

  1. apiVersion: v1
  2. kind: Namespace
  3. metadata:
  4. name: kuma-example
  5. labels:
  6. # inject Kuma sidecar into every Pod in that Namespace,
  7. # unless a user explicitly opts out on per-Pod basis
  8. kuma.io/sidecar-injection: enabled

To opt out of data-plane injection into a particular Pod, you need to label it with kuma.io/sidecar-injection=disabled, e.g.

  1. apiVersion: apps/v1
  2. kind: Deployment
  3. metadata:
  4. name: example-app
  5. namespace: kuma-example
  6. spec:
  7. ...
  8. template:
  9. metadata:
  10. ...
  11. labels:
  12. # indicate to Kuma that this Pod doesn't need a sidecar
  13. kuma.io/sidecar-injection: disabled
  14. spec:
  15. containers:
  16. ...

In previous versions the recommended way was to use annotations. While annotations are still supported, we strongly recommend using labels. This is the only way to guarantee that applications can only be started with sidecar.

Once your pod is running you can see the data plane CRD that matches it using kubectl:

  1. kubectl get dataplanes <podName>

Tag generation

When Dataplane entities are automatically created, all labels from Pod are converted into Dataplane tags. Labels with keys that contains kuma.io/ are not converted because they are reserved to Kuma. The following tags are added automatically and cannot be overridden using Pod labels.

  • kuma.io/service: Identifies the service name based on a Service that selects a Pod. This will be of format <name>_<namespace>_svc_<port> where <name>, <namespace> and <port> are from the Kubernetes service that is associated with this particular pod. When a pod is spawned without being associated with any Kubernetes Service resource the data plane tag will be kuma.io/service: <name>_<namespace>_svc, where <name> and<namespace> are extracted from the Pod resource metadata.
  • kuma.io/zone: Identifies the zone name in a multi-zone deployment .
  • kuma.io/protocol: Identifies the protocol that was defined by the appProtocol field on the Service that selects the Pod.
  • k8s.kuma.io/namespace: Identifies the Pod’s namespace. Example: kuma-demo.
  • k8s.kuma.io/service-name: Identifies the name of Kubernetes Service that selects the Pod. Example: demo-app.
  • k8s.kuma.io/service-port: Identifies the port of Kubernetes Service that selects the Pod. Example: 80.

  • If a Kubernetes service exposes more than 1 port, multiple inbounds will be generated all with different kuma.io/service.

  • If a pod is attached to more than one Kubernetes service, multiple inbounds will also be generated.

Example

  1. apiVersion: v1
  2. kind: Pod
  3. metadata:
  4. name: my-app
  5. namespace: my-namespace
  6. labels:
  7. foo: bar
  8. app: my-app
  9. spec:
  10. # ...
  11. ---
  12. apiVersion: v1
  13. kind: Service
  14. metadata:
  15. name: my-service
  16. namespace: my-namespace
  17. spec:
  18. selector:
  19. app: my-app
  20. type: ClusterIP
  21. ports:
  22. - name: port1
  23. protocol: TCP
  24. appProtocol: http
  25. port: 80
  26. targetPort: 8080
  27. - name: port2
  28. protocol: TCP
  29. appProtocol: grpc
  30. port: 1200
  31. targetPort: 8081
  32. ---
  33. apiVersion: v1
  34. kind: Service
  35. metadata:
  36. name: my-other-service
  37. namespace: my-namespace
  38. spec:
  39. selector:
  40. foo: bar
  41. type: ClusterIP
  42. ports:
  43. - protocol: TCP
  44. appProtocol: http
  45. port: 81
  46. targetPort: 8080

Will generate the following inbounds in your Kuma dataplane:

  1. ...
  2. inbound:
  3. - port: 8080
  4. tags:
  5. kuma.io/protocol: http
  6. kuma.io/service: my-service_my-namespace_svc_80
  7. k8s.kuma.io/service-name: my-service
  8. k8s.kuma.io/service-port: "80"
  9. k8s.kuma.io/namespace: my-namespace
  10. # Labels coming from your pod
  11. app: my-app
  12. foo: bar
  13. - port: 8081
  14. tags:
  15. kuma.io/protocol: grpc
  16. kuma.io/service: my-service_my-namespace_svc_1200
  17. k8s.kuma.io/service-name: my-service
  18. k8s.kuma.io/service-port: "1200"
  19. k8s.kuma.io/namespace: my-namespace
  20. # Labels coming from your pod
  21. app: my-app
  22. foo: bar
  23. - port: 8080
  24. tags:
  25. kuma.io/protocol: http
  26. kuma.io/service: my-other-service_my-namespace_svc_81
  27. k8s.kuma.io/service-name: my-other-service
  28. k8s.kuma.io/service-port: "81"
  29. k8s.kuma.io/namespace: my-namespace
  30. # Labels coming from your pod
  31. app: my-app
  32. foo: bar

Notice how kuma.io/service is built on <serviceName>_<namespace>_svc_<port> and kuma.io/protocol is the appProtocol field of your service entry.

Lifecycle

Joining the mesh

On Kubernetes, Dataplane resource is automatically created by kuma-cp. For each Pod with sidecar-injection label, a new Dataplane resource will be created.

To join the mesh in a graceful way, we need to first make sure the application is ready to serve traffic before it can be considered a valid traffic destination.

When Pod is converted to a Dataplane object it will be marked as unhealthy until Kubernetes considers all containers to be ready.

Leaving the mesh

To leave the mesh in a graceful shutdown, we need to remove the traffic destination from all the clients before shutting it down.

When the Kuma sidecar receives a SIGTERM signal it:

  1. Starts draining Envoy listeners.
  2. Waits the entire drain time.
  3. Terminates.

While draining, Envoy can still accept connections, however:

  1. It is marked unhealthy on the Envoy Admin /ready endpoint.
  2. It sends connection: close for HTTP/1.1 requests and the GOAWAY frame for HTTP/2. This forces clients to close their connection and reconnect to the new instance.

You can read the Kubernetes docs to learn how Kubernetes handles the Pod lifecycle. Here is the summary including the parts relevant for Kuma.

Whenever a user or system deletes a Pod, Kubernetes does the following:

  1. It marks the Pod as terminated.
  2. For every container concurrently it:
    1. Executes any pre stop hook if defined.
    2. Sends a SIGTERM signal.
    3. Waits until container is terminated for maximum of graceful termination time (by default 60s).
    4. Sends a SIGKILL to the container.
  3. It removes the Pod object from the system.

When Pod is marked as terminated, Kuma, the CP marks the Dataplane object unhealthy, which triggers a configuration update to all the clients in order to remove it as a destination. This can take a couple of seconds depending on the size of the mesh, resources available to the CP, XDS configuration interval, etc.

If the application served by the Kuma sidecar quits immediately after the SIGTERM signal, there is a high chance that clients will still try to send traffic to this destination.

To mitigate this, we need to either

  • Support graceful shutdown in the application. For example, the application should wait X seconds to exit after receiving the first SIGTERM signal.
  • Add a pre-stop hook to postpone stopping the application container. Example:

    1. apiVersion: apps/v1
    2. kind: Deployment
    3. metadata:
    4. name: redis
    5. spec:
    6. template:
    7. spec:
    8. containers:
    9. - name: redis
    10. image: "redis"
    11. lifecycle:
    12. preStop:
    13. exec:
    14. command: ["/bin/sleep", "30"]

When a Pod is deleted, its matching Dataplane resource is deleted as well. This is possible thanks to the owner reference set on the Dataplane resource.

Custom Container Configuration

If you want to modify the default container configuration you can use the ContainerPatch Kubernetes CRD. It allows configuration of both sidecar and init containers. ContainerPatch resources are namespace scoped and can only be applied in a namespace where Kuma CP is running.

In the vast majority of cases you shouldn’t need to override the sidecar and init-container configurations. ContainerPatch is a feature which requires good understanding of both Kuma and Kubernetes.

The specification of ContainerPatch consists of the list of jsonpatch strings which describe the modifications to be performed.

Example

When using ContainerPath, every value field must be valid JSON.

  1. apiVersion: kuma.io/v1alpha1
  2. kind: ContainerPatch
  3. metadata:
  4. name: container-patch-1
  5. namespace: kuma-system
  6. spec:
  7. sidecarPatch:
  8. - op: add
  9. path: /securityContext/privileged
  10. value: "true"
  11. - op: add
  12. path: /resources/requests/cpu
  13. value: '"100m"'
  14. - op: add
  15. path: /resources/limits
  16. value: '{
  17. "cpu": "500m",
  18. "memory": "256Mi"
  19. }'
  20. initPatch:
  21. - op: add
  22. path: /securityContext/runAsNonRoot
  23. value: "true"
  24. - op: remove
  25. path: /securityContext/runAsUser

This will change the securityContext section of kuma-sidecar container from:

  1. securityContext:
  2. runAsGroup: 5678
  3. runAsUser: 5678

to:

  1. securityContext:
  2. runAsGroup: 5678
  3. runAsUser: 5678
  4. privileged: true

and similarly change the securityContext section of the init container from:

  1. securityContext:
  2. capabilities:
  3. add:
  4. - NET_ADMIN
  5. - NET_RAW
  6. runAsGroup: 0
  7. runAsUser: 0

to:

  1. securityContext:
  2. capabilities:
  3. add:
  4. - NET_ADMIN
  5. - NET_RAW
  6. runAsGroup: 0
  7. runAsNonRoot: true

Resources requests cpu will be changed from:

  1. requests:
  2. cpu: 50m

to:

  1. requests:
  2. cpu: 100m

Resources limits will be changed from:

  1. limits:
  2. cpu: 1000m
  3. memory: 512Mi

to:

  1. limits:
  2. cpu: 500m
  3. memory: 256Mi

Workload matching

A ContainerPatch is matched to a Pod via an kuma.io/container-patches annotation on the workload. Each annotation may be an ordered list of ContainerPatch names, which will be applied in the order specified.

If a workload refers to a ContainerPatch which does not exist, the injection will explicitly fail and log the failure.

Example

  1. apiVersion: apps/v1
  2. kind: Deployment
  3. metadata:
  4. namespace: app-ns
  5. name: app-deployment
  6. spec:
  7. replicas: 1
  8. selector:
  9. matchLabels:
  10. app: app-deployment
  11. template:
  12. metadata:
  13. labels:
  14. app: app-deployment
  15. annotations:
  16. kuma.io/container-patches: container-patch-1,container-patch-2
  17. spec: [...]

Default patches

You can configure kuma-cp to apply the list of default patches for workloads which don’t specify their own patches by modifying the containerPatches value from the kuma-dp configuration:

  1. [...]
  2. runtime:
  3. kubernetes:
  4. injector:
  5. containerPatches: [ ]
  6. [...]

If you specify the list of default patches (i.e. ["default-patch-1", "default-patch-2]) but your workload will be annotated with its own list of patches (i.e. ["pod-patch-1", "pod-patch-2]) only the latter will be applied.

To install a CP with env vars you can do:

  1. kumactl install control-plane --env-var "KUMA_RUNTIME_KUBERNETES_INJECTOR_CONTAINER_PATCHES=patch1,patch2"

Error modes and validation

When applying ContainerPatch Kuma will validate that the rendered container spec meets the Kubernetes specification. Kuma will not validate that it is a sane configuration.

If a workload refers to a ContainerPatch which does not exist, the injection will explicitly fail and log the failure.

Schema

Direct access to services

By default, on Kubernetes data plane proxies communicate with each other by leveraging the ClusterIP address of the Service resources. Also by default, any request made to another service is automatically load balanced client-side by the data plane proxy that originates the request (they are load balanced by the local Envoy proxy sidecar proxy).

There are situations where we may want to bypass the client-side load balancing and directly access services by using their IP address (ie: in the case of Prometheus wanting to scrape metrics from services by their individual IP address).

When an originating service wants to directly consume other services by their IP address, the originating service’s Deployment resource must include the following annotation:

  1. kuma.io/direct-access-services: Service1, Service2, ServiceN

Where the value is a comma separated list of Kuma services that will be consumed directly. For example:

  1. apiVersion: apps/v1
  2. kind: Deployment
  3. metadata:
  4. name: example-app
  5. namespace: kuma-example
  6. spec:
  7. ...
  8. template:
  9. metadata:
  10. ...
  11. annotations:
  12. kuma.io/direct-access-services: "backend_example_svc_1234,backend_example_svc_1235"
  13. spec:
  14. containers:
  15. ...

Note: When using direct access with headless service, destination service will be accessible at: Kuma-service.pod-name.mesh

We can also use * to indicate direct access to every service in the Mesh:

  1. kuma.io/direct-access-services: *

Using * to directly access every service is a resource intensive operation, so we must use it carefully.