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You can gather metrics for hosted control planes by configuring metrics sets. The HyperShift Operator can create or delete monitoring dashboards in the management cluster for each hosted cluster that it manages.

Configuring metrics sets for hosted control planes

Hosted control planes for Red Hat OKD creates ServiceMonitor resources in each control plane namespace that allow a Prometheus stack to gather metrics from the control planes. The ServiceMonitor resources use metrics relabelings to define which metrics are included or excluded from a particular component, such as etcd or the Kubernetes API server. The number of metrics that are produced by control planes directly impacts the resource requirements of the monitoring stack that gathers them.

Instead of producing a fixed number of metrics that apply to all situations, you can configure a metrics set that identifies a set of metrics to produce for each control plane. The following metrics sets are supported:

  • Telemetry: These metrics are needed for telemetry. This set is the default set and is the smallest set of metrics.

  • SRE: This set includes the necessary metrics to produce alerts and allow the troubleshooting of control plane components.

  • All: This set includes all of the metrics that are produced by standalone OKD control plane components.

To configure a metrics set, set the METRICS_SET environment variable in the HyperShift Operator deployment by entering the following command:

$ oc set env -n hypershift deployment/operator METRICS_SET=All

Configuring the SRE metrics set

When you specify the SRE metrics set, the HyperShift Operator looks for a config map named sre-metric-set with a single key: config. The value of the config key must contain a set of RelabelConfigs that are organized by control plane component.

You can specify the following components:

  • etcd

  • kubeAPIServer

  • kubeControllerManager

  • openshiftAPIServer

  • openshiftControllerManager

  • openshiftRouteControllerManager

  • cvo

  • olm

  • catalogOperator

  • registryOperator

  • nodeTuningOperator

  • controlPlaneOperator

  • hostedClusterConfigOperator

A configuration of the SRE metrics set is illustrated in the following example:

kubeAPIServer:
  - action:       "drop"
    regex:        "etcd_(debugging|disk|server).*"
    sourceLabels: ["__name__"]
  - action:       "drop"
    regex:        "apiserver_admission_controller_admission_latencies_seconds_.*"
    sourceLabels: ["__name__"]
  - action:       "drop"
    regex:        "apiserver_admission_step_admission_latencies_seconds_.*"
    sourceLabels: ["__name__"]
  - action:       "drop"
    regex:        "scheduler_(e2e_scheduling_latency_microseconds|scheduling_algorithm_predicate_evaluation|scheduling_algorithm_priority_evaluation|scheduling_algorithm_preemption_evaluation|scheduling_algorithm_latency_microseconds|binding_latency_microseconds|scheduling_latency_seconds)"
    sourceLabels: ["__name__"]
  - action:       "drop"
    regex:        "apiserver_(request_count|request_latencies|request_latencies_summary|dropped_requests|storage_data_key_generation_latencies_microseconds|storage_transformation_failures_total|storage_transformation_latencies_microseconds|proxy_tunnel_sync_latency_secs)"
    sourceLabels: ["__name__"]
  - action:       "drop"
    regex:        "docker_(operations|operations_latency_microseconds|operations_errors|operations_timeout)"
    sourceLabels: ["__name__"]
  - action:       "drop"
    regex:        "reflector_(items_per_list|items_per_watch|list_duration_seconds|lists_total|short_watches_total|watch_duration_seconds|watches_total)"
    sourceLabels: ["__name__"]
  - action:       "drop"
    regex:        "etcd_(helper_cache_hit_count|helper_cache_miss_count|helper_cache_entry_count|request_cache_get_latencies_summary|request_cache_add_latencies_summary|request_latencies_summary)"
    sourceLabels: ["__name__"]
  - action:       "drop"
    regex:        "transformation_(transformation_latencies_microseconds|failures_total)"
    sourceLabels: ["__name__"]
  - action:       "drop"
    regex:        "network_plugin_operations_latency_microseconds|sync_proxy_rules_latency_microseconds|rest_client_request_latency_seconds"
    sourceLabels: ["__name__"]
  - action:       "drop"
    regex:        "apiserver_request_duration_seconds_bucket;(0.15|0.25|0.3|0.35|0.4|0.45|0.6|0.7|0.8|0.9|1.25|1.5|1.75|2.5|3|3.5|4.5|6|7|8|9|15|25|30|50)"
    sourceLabels: ["__name__", "le"]
kubeControllerManager:
  - action:       "drop"
    regex:        "etcd_(debugging|disk|request|server).*"
    sourceLabels: ["__name__"]
  - action:       "drop"
    regex:        "rest_client_request_latency_seconds_(bucket|count|sum)"
    sourceLabels: ["__name__"]
  - action:       "drop"
    regex:        "root_ca_cert_publisher_sync_duration_seconds_(bucket|count|sum)"
    sourceLabels: ["__name__"]
openshiftAPIServer:
  - action:       "drop"
    regex:        "etcd_(debugging|disk|server).*"
    sourceLabels: ["__name__"]
  - action:       "drop"
    regex:        "apiserver_admission_controller_admission_latencies_seconds_.*"
    sourceLabels: ["__name__"]
  - action:       "drop"
    regex:        "apiserver_admission_step_admission_latencies_seconds_.*"
    sourceLabels: ["__name__"]
  - action:       "drop"
    regex:        "apiserver_request_duration_seconds_bucket;(0.15|0.25|0.3|0.35|0.4|0.45|0.6|0.7|0.8|0.9|1.25|1.5|1.75|2.5|3|3.5|4.5|6|7|8|9|15|25|30|50)"
    sourceLabels: ["__name__", "le"]
openshiftControllerManager:
  - action:       "drop"
    regex:        "etcd_(debugging|disk|request|server).*"
    sourceLabels: ["__name__"]
openshiftRouteControllerManager:
  - action:       "drop"
    regex:        "etcd_(debugging|disk|request|server).*"
    sourceLabels: ["__name__"]
olm:
  - action:       "drop"
    regex:        "etcd_(debugging|disk|server).*"
    sourceLabels: ["__name__"]
catalogOperator:
  - action:       "drop"
    regex:        "etcd_(debugging|disk|server).*"
    sourceLabels: ["__name__"]
cvo:
  - action: drop
    regex: "etcd_(debugging|disk|server).*"
    sourceLabels: ["__name__"]

Enabling monitoring dashboards in a hosted cluster

To enable monitoring dashboards in a hosted cluster, complete the following steps:

Procedure
  1. Create the hypershift-operator-install-flags config map in the local-cluster namespace, being sure to specify the --monitoring-dashboards flag in the data.installFlagsToAdd section. For example:

    kind: ConfigMap
    apiVersion: v1
    metadata:
      name: hypershift-operator-install-flags
      namespace: local-cluster
    data:
      installFlagsToAdd: "--monitoring-dashboards"
      installFlagsToRemove: ""
  2. Wait a couple of minutes for the HyperShift Operator deployment in the hypershift namespace to be updated to include the following environment variable:

        - name: MONITORING_DASHBOARDS
          value: "1"

    When monitoring dashboards are enabled, for each hosted cluster that the HyperShift Operator manages, the Operator creates a config map named cp-<hosted_cluster_namespace>-<hosted_cluster_name> in the openshift-config-managed namespace, where <hosted_cluster_namespace> is the namespace of the hosted cluster and <hosted_cluster_name> is the name of the hosted cluster. As a result, a new dashboard is added in the administrative console of the management cluster.

  3. To view the dashboard, log in to the management cluster’s console and go to the dashboard for the hosted cluster by clicking Observe → Dashboards.

  4. Optional: To disable a monitoring dashboards in a hosted cluster, remove the --monitoring-dashboards flag from the hypershift-operator-install-flags config map. When you delete a hosted cluster, its corresponding dashboard is also deleted.

Dashboard customization

To generate dashboards for each hosted cluster, the HyperShift Operator uses a template that is stored in the monitoring-dashboard-template config map in the Operator namespace (hypershift). This template contains a set of Grafana panels that contain the metrics for the dashboard. You can edit the content of the config map to customize the dashboards.

When a dashboard is generated, the following strings are replaced with values that correspond to a specific hosted cluster:

Name

Description

__NAME__

The name of the hosted cluster

__NAMESPACE__

The namespace of the hosted cluster

__CONTROL_PLANE_NAMESPACE__

The namespace where the control plane pods of the hosted cluster are placed

__CLUSTER_ID__

The UUID of the hosted cluster, which matches the _id label of the hosted cluster metrics