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semaphore-service-mirror

Small app that watches for kubernetes services and endpoints in a target cluster and mirrors them in a local namespace. Can be used in conjunction with coredns in cases where pod networks are reachable between clusters and one needs to be able to route virtual services for remote pods.

Usage

Usage of ./semaphore-service-mirror:
  -config string
        (required)Path to the json config file
  -kube-config string
        Path of a kube config file, if not provided the app will try to get in cluster config
  -label-selector string
        Label of services and endpoints to watch and mirror
  -log-level string
        Log level (default "info")
  -mirror-ns string
        The namespace to create dummy mirror services in

You can set most flags via envvars instead, format: "SSM_FLAG_NAME". Example: -config can be set as SSM_CONFIG and -kube-config can be set as SSM_KUBE_CONFIG.

If both are present, flags take precedence over envvars.

The only mandatory flag is -config to point to a json formatted config file. Label selector and mirror namespace must also be set, but there is the option to do this via the json config (more details in the next section below). Flags will take precedence over static configuration from the file.

Configuration file

The operator expects a configuration file in json format. Here is a description of the configuration keys by scope:

Global

Contains configuration globally shared by all runners.

  • globalSvcLabelSelector: Labels used to select global services
  • globalSvcRoutingStrategyLabel: Labels used to instruct controller to try utilising Kubernetes topology aware hints to select local cluster targets first when routing global services.
  • mirrorSvcLabelSelector: Label used to select services to mirror
  • mirrorNamespace: Namespace used to locate/place mirrored objects
  • serviceSync: Whether to sync services on startup and delete records that cannot be located based on the label selector. Defaults to false

Local Cluster

Contains configuration needed to manage resources in the local cluster, where this operator runs.

  • name: A name for the local cluster
  • zones: A list of the availability zones for the local cluster. This will be used to allow topology aware routing for global services and the values should derive from kuberenetes nodes' topology.kubernetes.io/zone label.
  • kubeConfigPath: Path to a kube config file to access the local cluster. If not specified the operator will try to use in-cluster configuration with the pod's service account.

Remote clusters

Contains a list of keys to configure access to all remote cluster. Each list can include the following:

  • name: A name for the remote cluster
  • kubeConfigPath: Path to a kube config file to access the remote cluster.
  • remoteAPIURL: Address of the remote cluster API server
  • remoteCAURL: Address from where to fetch the public CA certificate to talk to the remote API server.
  • remoteSATokenPiath: Path to a service account token that will be used to access remote cluster resources.
  • resyncPeriod: Will trigger an onUpdate event for everything that is stored in the respective watchers cache. Defaults to 0 which equals disabled.
  • servicePrefix: How to prefix service names mirrored from that remote locally.

Either kubeConfigPath or remoteAPIURL,remoteCAURL and remoteSATokenPiath should be set to be able to successfully create a client to talk to the remote cluster.

Example

{
  "global": {
    "globalSvcLabelSelector": "mirror.semaphore.uw.io/global-service=true",
    "globalSvcRoutingStrategyLabel": "mirror.semaphore.uw.io/global-service-routing-strategy=local-first",
    "mirrorSvcLabelSelector": "mirror.semaphore.uw.io/mirror-service=true",
    "mirrorNamespace": "semaphore",
    "serviceSync": true,
    "endpointSliceSync": true
  },
  "localCluster": {
    "name": "local",
    "kubeConfigPath": "/path/to/local/kubeconfig"
  },
  "remoteClusters": [
    {
      "name": "clusterA",
      "remoteCAURL": "remote_ca_url",
      "remoteAPIURL": "remote_api_url",
      "remoteSATokenPath": "/path/to/token",
      "resyncPeriod": "10s",
      "servicePrefix": "cluster-A"
    }
  ]
}

Generating mirrored service names

In order to make regex matching easier for dns rewrite purposes (see coredns example bellow) we use a hardcoded separator between service names and namespaces on the generated name for mirrored service: 73736d.

The format of the generated name is: <prefix>-<namespace>-73736d-<name>.

It's possible for this name to exceed the 63 character limit imposed by Kubernetes so the operator should have a Gatekeeper / Kyverno rule to guard against exceeding this Service name length.

Coredns config example

To create a smoother experience when accessing a service coredns can be configured using the rewrite functionality:

cluster.example {
    errors
    health
    rewrite continue {
      name regex ([a-zA-Z0-9-_]*\.)?([a-zA-Z0-9-_]*)\.([a-zv0-9-_]*)\.svc\.cluster\.example {1}example-{3}-73736d-{2}.<namespace>.svc.cluster.local
      answer name ([a-zA-Z0-9-_]*\.)?example-([a-zA-Z0-9-_]*)-73736d-([a-zA-Z0-9-_]*)\.<namespace>\.svc\.cluster\.local {1}{3}.{2}.svc.cluster.example
    }
    kubernetes cluster.local in-addr.arpa ip6.arpa {
      pods insecure
      endpoint_pod_names
      upstream
      fallthrough in-addr.arpa ip6.arpa
    }
    forward . /etc/resolv.conf
    cache 30
    loop
    reload
    loadbalance
}
.:53 {
    errors
    health
    kubernetes cluster.local in-addr.arpa ip6.arpa {
      pods insecure
      endpoint_pod_names
      upstream
      fallthrough in-addr.arpa ip6.arpa
    }

    prometheus :9153
    forward . /etc/resolv.conf
    cache 30
    loop
    reload
    loadbalance
}

that way all queries for services under domain cluster.target will be rewritten to match services on the local namespace that the services are mirrored.

  • note that <target> and <namespace> should be replaced with a name for the target cluster and the local namespace that contains the mirrored services.
  • note that the above example assumes that you are running the mirroring service with a prefix flag that matches the target cluster name.

Global Services

The operator is also watching services based on a separate label, in order to create global services. A global service will gather endpoints from multiple remote clusters that live under the "same" namespace and name, into a single ocal service with endpoints in multiple clusters. For that purpose, it will create a single ClusterIP (or headless) service and mirror endpointslices from remote clusters to target the new "global" service.

The format of the name used for the global service is: gl-<namespace>-73736d-<name>.

For example, if we have the following services:

  • cluster: cA, namespace: example-ns, name: my-svc, endpoints: [eA]
  • cluster: cB, namespace: example-ns, name: my-svc, endpoints: [eB1, eB2] The operator will create a global service under the local "semaphore" namespace with a corresponding list of endpoints: [eA, eB1, eB2].
  • Global services will include endpoints from the local cluster as well, provided they are using the mirror label.
  • Global services will try to utilise Kubernetes topology aware hints to route to local endpoints first.

CoreDNS config for Global services

In order to be able to resolve the global services under cluster.global domain, the following CoreDNS block is needed:

cluster.global {
    cache 30
    errors
    forward . /etc/resolv.conf
    kubernetes cluster.local {
        pods insecure
        endpoint_pod_names
    }
    loadbalance
    loop
    prometheus
    reload
    rewrite continue {
        name regex ([\w-]*\.)?([\w-]*)\.([\w-]*)\.svc\.cluster\.global {1}gl-{3}-73736d-{2}.sys-semaphore.svc.cluster.local
        answer name ([\w-]*\.)?gl-([\w-]*)-73736d-([\w-]*)\.sys-semaphore\.svc\.cluster\.local {1}{3}.{2}.svc.cluster.global
    }
}

Topology routing

In some cases, it is preferable to route to endpoints which live closer to the caller when addressing global services (first hit available endpoints in the same cluster). For that purpose, one can use a label to instruct the controller to set service.kubernetes.io/topology-aware-hints=auto label in the generated global service and instruct Kubernetes to use topology hints for routing traffic to the service. In order for the hints to be effective, the operator reads the local configuration zones field and uses the list of zones defined there as hints for local endpoints. If this is not set, a dummy value will be used and topology aware routing will not be feasible. The operator also uses the dummy "remote" zone value as a hint for endpoits mirrored from remote clusters, to make sure that no routing decisions will be made on those and kube-proxy will not complain about missing hints. The label to enable the above is configurable via globalSvcTopologyLabel field in the global configuration.

Fungible values

Since service endpoints that will be involved in a global service come from multiple services in different clusters, based on the service name and namespace, certain parameters need to match across all those service definitions. In particular, service ports and topology labels values are fungible and if their values differ between definitions of services that feed endpoints to the same global service, there will be a race between services to force their attributes to the global service. For a predictable behaviour, make sure that ports match between services and either all or none set the topology label.

Metrics

There are separate metrics available that one can use to determine the status of the controller. The available metrics can give a visibility on errors from the Kubernetes clients, the watchers and the controller's queues.

Kubernetes Client Metrics

  • semaphore_service_mirror_kube_http_request_total: Total number of HTTP requests to the Kubernetes API by host, code and method.
  • semaphore_service_mirror_kube_http_request_duration_seconds: Histogram of latencies for HTTP requests to the Kubernetes API by host and method

Kubernetes Watcher Metrics

  • semaphore_service_mirror_kube_watcher_objects: Number of objects watched by watcher and kind
  • semaphore_service_mirror_kube_watcher_events_total: Number of events handled by watcher, kind and event_type

Because the controller runs multiple watchers in parallel, both for watching the remote clusters and the mirrored local objects, we use 2 labels to be able to distinguish between them.

  • watcher label follows the pattern <cluster-name>-[mirror]<watcherType>. For example watcher="aws-serviceWatcher" will contain metrics for watching services on a cluster called "aws", and watcher="aws-mirrorServiceWatcher" will contain metrics for the mirrored local services from "aws" cluster.
  • runner label follows the pattern [mirror|global]-<cluster-name> and should help distinguish if a watcher is used to create service mirrors or global services. Based on the above, one could use the following expression: semaphore_service_mirror_kube_watcher_objects{watcher=~".*-mirror.*"} - ignoring(watcher) semaphore_service_mirror_kube_watcher_objects{watcher!~".*-mirror.*"} to monitor if controllers are lagging. The runner label comes handy in the above query, to avoid finding duplicate series for the match group.

Queue Metrics

  • semaphore_service_mirror_queue_depth: Workqueue depth, by queue name.
  • semaphore_service_mirror_queue_adds_total: Workqueue adds, by queue name.
  • semaphore_service_mirror_queue_latency_duration_seconds: Workqueue latency, by queue name.
  • semaphore_service_mirror_queue_work_duration_seconds: Workqueue work duration, by queue name.
  • semaphore_service_mirror_queue_unfinished_work_seconds: Unfinished work in seconds, by queue name.
  • semaphore_service_mirror_queue_longest_running_processor_seconds: Longest running processor, by queue name.
  • semaphore_service_mirror_queue_retries_total: Workqueue retries, by queue name.
  • semaphore_service_mirror_queue_requeued_items: Items that have been requeued but not reconciled yet, by queue name.