$ oc -n openshift-user-workload-monitoring edit configmap user-workload-monitoring-config
This section explains what configuration is supported, shows how to configure the monitoring stack for user-defined projects, and demonstrates several common configuration scenarios.
Not all configuration parameters for the monitoring stack are exposed. Only the parameters and fields listed in the Config map reference for the Cluster Monitoring Operator are supported for configuration. |
Not all configuration options for the monitoring stack are exposed. The only supported way of configuring OpenShift Dedicated monitoring is by configuring the Cluster Monitoring Operator (CMO) using the options described in the Config map reference for the Cluster Monitoring Operator. Do not use other configurations, as they are unsupported.
Configuration paradigms might change across Prometheus releases, and such cases can only be handled gracefully if all configuration possibilities are controlled. If you use configurations other than those described in the Config map reference for the Cluster Monitoring Operator, your changes will disappear because the CMO automatically reconciles any differences and resets any unsupported changes back to the originally defined state by default and by design.
Installing another Prometheus instance is not supported by the Red Hat Site Reliability Engineers (SRE). |
Backward compatibility for metrics, recording rules, or alerting rules is not guaranteed. |
The following modifications are explicitly not supported:
Installing custom Prometheus instances on OpenShift Dedicated. A custom instance is a Prometheus custom resource (CR) managed by the Prometheus Operator.
Modifying the default platform monitoring components. You should not modify any of the components defined in the cluster-monitoring-config
config map. Red Hat SRE uses these components to monitor the core cluster components and Kubernetes services.
The following matrix contains information about versions of monitoring components for OpenShift Dedicated 4.12 and later releases:
OpenShift Dedicated | Prometheus Operator | Prometheus | Metrics Server | Alertmanager | kube-state-metrics agent | monitoring-plugin | node-exporter agent | Thanos |
---|---|---|---|---|---|---|---|---|
4.17 |
0.75.2 |
2.53.1 |
0.7.1 |
0.27.0 |
2.13.0 |
1.0.0 |
1.8.2 |
0.35.1 |
4.16 |
0.73.2 |
2.52.0 |
0.7.1 |
0.26.0 |
2.12.0 |
1.0.0 |
1.8.0 |
0.35.0 |
4.15 |
0.70.0 |
2.48.0 |
0.6.4 |
0.26.0 |
2.10.1 |
1.0.0 |
1.7.0 |
0.32.5 |
4.14 |
0.67.1 |
2.46.0 |
N/A |
0.25.0 |
2.9.2 |
1.0.0 |
1.6.1 |
0.30.2 |
4.13 |
0.63.0 |
2.42.0 |
N/A |
0.25.0 |
2.8.1 |
N/A |
1.5.0 |
0.30.2 |
4.12 |
0.60.1 |
2.39.1 |
N/A |
0.24.0 |
2.6.0 |
N/A |
1.4.0 |
0.28.1 |
The openshift-state-metrics agent and Telemeter Client are OpenShift-specific components. Therefore, their versions correspond with the versions of OpenShift Dedicated. |
In OpenShift Dedicated, you can configure the stack that monitors workloads for user-defined projects by using the user-workload-monitoring-config
ConfigMap
object. Config maps configure the Cluster Monitoring Operator (CMO), which in turn configures the components of the stack.
You have access to the cluster as a user with the dedicated-admin
role.
The user-workload-monitoring-config
ConfigMap
object exists. This object is created by default when the cluster is created.
You have installed the OpenShift CLI (oc
).
Edit the ConfigMap
object.
Edit the user-workload-monitoring-config
ConfigMap
object in the openshift-user-workload-monitoring
project:
$ oc -n openshift-user-workload-monitoring edit configmap user-workload-monitoring-config
Add your configuration under data/config.yaml
as a key-value pair <component_name>: <component_configuration>
:
apiVersion: v1
kind: ConfigMap
metadata:
name: user-workload-monitoring-config
namespace: openshift-user-workload-monitoring
data:
config.yaml: |
<component>:
<configuration_for_the_component>
Substitute <component>
and <configuration_for_the_component>
accordingly.
The following example ConfigMap
object configures a data retention period and minimum container resource requests for Prometheus. This relates to the Prometheus instance that monitors user-defined projects only:
apiVersion: v1
kind: ConfigMap
metadata:
name: user-workload-monitoring-config
namespace: openshift-user-workload-monitoring
data:
config.yaml: |
prometheus: (1)
retention: 24h (2)
resources:
requests:
cpu: 200m (3)
memory: 2Gi (4)
1 | Defines the Prometheus component and the subsequent lines define its configuration. |
2 | Configures a twenty-four hour data retention period for the Prometheus instance that monitors user-defined projects. |
3 | Defines a minimum resource request of 200 millicores for the Prometheus container. |
4 | Defines a minimum pod resource request of 2 GiB of memory for the Prometheus container. |
Save the file to apply the changes to the ConfigMap
object.
Different configuration changes to the
Each procedure that requires a change in the config map includes its expected outcome. |
Configuration reference for the user-workload-monitoring-config
config map
This table shows the monitoring components you can configure and the keys used to specify the components in the
user-workload-monitoring-config
ConfigMap
objects.
Do not modify the monitoring components in the |
Component | user-workload-monitoring-config config map key |
---|---|
Alertmanager |
|
Prometheus Operator |
|
Prometheus |
|
Thanos Ruler |
|
By using the nodeSelector
constraint with labeled nodes, you can move any of the monitoring stack components to specific nodes.
By doing so, you can control the placement and distribution of the monitoring components across a cluster.
By controlling placement and distribution of monitoring components, you can optimize system resource use, improve performance, and segregate workloads based on specific requirements or policies.
If you move monitoring components by using node selector constraints, be aware that other constraints to control pod scheduling might exist for a cluster:
Topology spread constraints might be in place to control pod placement.
Hard anti-affinity rules are in place for Prometheus, Thanos Querier, Alertmanager, and other monitoring components to ensure that multiple pods for these components are always spread across different nodes and are therefore always highly available.
When scheduling pods onto nodes, the pod scheduler tries to satisfy all existing constraints when determining pod placement. That is, all constraints compound when the pod scheduler determines which pods will be placed on which nodes.
Therefore, if you configure a node selector constraint but existing constraints cannot all be satisfied, the pod scheduler cannot match all constraints and will not schedule a pod for placement onto a node.
To maintain resilience and high availability for monitoring components, ensure that enough nodes are available and match all constraints when you configure a node selector constraint to move a component.
You can move any of the components that monitor workloads for user-defined projects to specific worker nodes. It is not permitted to move components to control plane or infrastructure nodes.
You have access to the cluster as a user with the dedicated-admin
role.
The user-workload-monitoring-config
ConfigMap
object exists. This object is created by default when the cluster is created.
You have installed the OpenShift CLI (oc
).
If you have not done so yet, add a label to the nodes on which you want to run the monitoring components:
$ oc label nodes <node-name> <node-label>
Edit the ConfigMap
object:
Edit the user-workload-monitoring-config
ConfigMap
object in the openshift-user-workload-monitoring
project:
$ oc -n openshift-user-workload-monitoring edit configmap user-workload-monitoring-config
Specify the node labels for the nodeSelector
constraint for the component under data/config.yaml
:
apiVersion: v1
kind: ConfigMap
metadata:
name: user-workload-monitoring-config
namespace: openshift-user-workload-monitoring
data:
config.yaml: |
<component>: (1)
nodeSelector:
<node-label-1> (2)
<node-label-2> (3)
<...>
1 | Substitute <component> with the appropriate monitoring stack component name. |
2 | Substitute <node-label-1> with the label you added to the node. |
3 | Optional: Specify additional labels. If you specify additional labels, the pods for the component are only scheduled on the nodes that contain all of the specified labels. |
If monitoring components remain in a |
Save the file to apply the changes. The components specified in the new configuration are automatically moved to the new nodes, and the pods affected by the new configuration are redeployed.
See the Kubernetes documentation for details on the nodeSelector
constraint
You can assign tolerations to the components that monitor user-defined projects, to enable moving them to tainted worker nodes. Scheduling is not permitted on control plane or infrastructure nodes.
You have access to the cluster as a user with the dedicated-admin
role.
The user-workload-monitoring-config
ConfigMap
object exists in the openshift-user-workload-monitoring
namespace. This object is created by default when the cluster is created.
You have installed the OpenShift CLI (oc
).
Edit the ConfigMap
object:
Edit the user-workload-monitoring-config
ConfigMap
object in the openshift-user-workload-monitoring
project:
$ oc -n openshift-user-workload-monitoring edit configmap user-workload-monitoring-config
Specify tolerations
for the component:
apiVersion: v1
kind: ConfigMap
metadata:
name: user-workload-monitoring-config
namespace: openshift-user-workload-monitoring
data:
config.yaml: |
<component>:
tolerations:
<toleration_specification>
Substitute <component>
and <toleration_specification>
accordingly.
For example, oc adm taint nodes node1 key1=value1:NoSchedule
adds a taint to node1
with the key key1
and the value value1
. This prevents monitoring components from deploying pods on node1
unless a toleration is configured for that taint. The following example configures the thanosRuler
component to tolerate the example taint:
apiVersion: v1
kind: ConfigMap
metadata:
name: user-workload-monitoring-config
namespace: openshift-user-workload-monitoring
data:
config.yaml: |
thanosRuler:
tolerations:
- key: "key1"
operator: "Equal"
value: "value1"
effect: "NoSchedule"
Save the file to apply the changes. The pods affected by the new configuration are automatically redeployed.
See the Kubernetes documentation on taints and tolerations
You can ensure that the containers that run monitoring components have enough CPU and memory resources by specifying values for resource limits and requests for those components.
You can configure these limits and requests for core platform monitoring components in the openshift-monitoring
namespace and for the components that monitor user-defined projects in the openshift-user-workload-monitoring
namespace.
You can configure resource limits and request settings for core platform monitoring components and for the components that monitor user-defined projects, including the following components:
Alertmanager (for core platform monitoring and for user-defined projects)
kube-state-metrics
monitoring-plugin
node-exporter
openshift-state-metrics
Prometheus (for core platform monitoring and for user-defined projects)
Metrics Server
Prometheus Operator and its admission webhook service
Telemeter Client
Thanos Querier
Thanos Ruler
By defining resource limits, you limit a container’s resource usage, which prevents the container from exceeding the specified maximum values for CPU and memory resources.
By defining resource requests, you specify that a container can be scheduled only on a node that has enough CPU and memory resources available to match the requested resources.
To configure CPU and memory resources, specify values for resource limits and requests in the appropriate ConfigMap
object for the namespace in which the monitoring component is located:
The cluster-monitoring-config
config map in the openshift-monitoring
namespace for core platform monitoring
The user-workload-monitoring-config
config map in the openshift-user-workload-monitoring
namespace for components that monitor user-defined projects
If you are configuring core platform monitoring components:
You have access to the cluster as a user with the cluster-admin
cluster role.
You have created a ConfigMap
object named cluster-monitoring-config
.
If you are configuring components that monitor user-defined projects:
You have access to the cluster as a user with the cluster-admin
cluster role, or as a user with the user-workload-monitoring-config-edit
role in the openshift-user-workload-monitoring
project.
You have installed the OpenShift CLI (oc
).
To configure core platform monitoring components, edit the cluster-monitoring-config
config map object in the openshift-monitoring
namespace:
$ oc -n openshift-monitoring edit configmap cluster-monitoring-config
Add values to define resource limits and requests for each core platform monitoring component you want to configure.
Make sure that the value set for a limit is always higher than the value set for a request. Otherwise, an error will occur, and the container will not run. |
apiVersion: v1
kind: ConfigMap
metadata:
name: cluster-monitoring-config
namespace: openshift-monitoring
data:
config.yaml: |
alertmanagerMain:
resources:
limits:
cpu: 500m
memory: 1Gi
requests:
cpu: 200m
memory: 500Mi
prometheusK8s:
resources:
limits:
cpu: 500m
memory: 3Gi
requests:
cpu: 200m
memory: 500Mi
prometheusOperator:
resources:
limits:
cpu: 500m
memory: 1Gi
requests:
cpu: 200m
memory: 500Mi
metricsServer:
resources:
requests:
cpu: 10m
memory: 50Mi
limits:
cpu: 50m
memory: 500Mi
kubeStateMetrics:
resources:
limits:
cpu: 500m
memory: 1Gi
requests:
cpu: 200m
memory: 500Mi
telemeterClient:
resources:
limits:
cpu: 500m
memory: 1Gi
requests:
cpu: 200m
memory: 500Mi
openshiftStateMetrics:
resources:
limits:
cpu: 500m
memory: 1Gi
requests:
cpu: 200m
memory: 500Mi
thanosQuerier:
resources:
limits:
cpu: 500m
memory: 1Gi
requests:
cpu: 200m
memory: 500Mi
nodeExporter:
resources:
limits:
cpu: 50m
memory: 150Mi
requests:
cpu: 20m
memory: 50Mi
monitoringPlugin:
resources:
limits:
cpu: 500m
memory: 1Gi
requests:
cpu: 200m
memory: 500Mi
prometheusOperatorAdmissionWebhook:
resources:
limits:
cpu: 50m
memory: 100Mi
requests:
cpu: 20m
memory: 50Mi
Save the file to apply the changes. The pods affected by the new configuration are automatically redeployed.
Run cluster monitoring with persistent storage to gain the following benefits:
Protect your metrics and alerting data from data loss by storing them in a persistent volume (PV). As a result, they can survive pods being restarted or recreated.
Avoid getting duplicate notifications and losing silences for alerts when the Alertmanager pods are restarted.
For production environments, it is highly recommended to configure persistent storage.
In multi-node clusters, you must configure persistent storage for Prometheus, Alertmanager, and Thanos Ruler to ensure high availability. |
To use a persistent volume (PV) for monitoring components, you must configure a persistent volume claim (PVC).
You have access to the cluster as a user with the dedicated-admin
role.
The user-workload-monitoring-config
ConfigMap
object exists. This object is created by default when the cluster is created.
You have installed the OpenShift CLI (oc
).
Edit the ConfigMap
object:
Edit the user-workload-monitoring-config
ConfigMap
object in the openshift-user-workload-monitoring
project:
$ oc -n openshift-user-workload-monitoring edit configmap user-workload-monitoring-config
Add your PVC configuration for the component under data/config.yaml
:
apiVersion: v1
kind: ConfigMap
metadata:
name: user-workload-monitoring-config
namespace: openshift-user-workload-monitoring
data:
config.yaml: |
<component>: (1)
volumeClaimTemplate:
spec:
storageClassName: <storage_class> (2)
resources:
requests:
storage: <amount_of_storage> (3)
1 | Specify the component for user-defined monitoring for which you want to configure the PVC. |
2 | Specify an existing storage class. If a storage class is not specified, the default storage class is used. |
3 | Specify the amount of required storage. |
See the Kubernetes documentation on PersistentVolumeClaims for information on how to specify volumeClaimTemplate
.
The following example configures a PVC that claims persistent storage for Thanos Ruler:
apiVersion: v1
kind: ConfigMap
metadata:
name: user-workload-monitoring-config
namespace: openshift-user-workload-monitoring
data:
config.yaml: |
thanosRuler:
volumeClaimTemplate:
spec:
storageClassName: my-storage-class
resources:
requests:
storage: 10Gi
Storage requirements for the |
Save the file to apply the changes. The pods affected by the new configuration are automatically redeployed and the new storage configuration is applied.
When you update the config map with a PVC configuration, the affected |
By default, Prometheus retains metrics data for the following durations:
Core platform monitoring: 15 days
Monitoring for user-defined projects: 24 hours
You can modify the retention time for the Prometheus instance that monitors user-defined projects, to change how soon the data is deleted. You can also set the maximum amount of disk space the retained metrics data uses. If the data reaches this size limit, Prometheus deletes the oldest data first until the disk space used is again below the limit.
Note the following behaviors of these data retention settings:
The size-based retention policy applies to all data block directories in the /prometheus
directory, including persistent blocks, write-ahead log (WAL) data, and m-mapped chunks.
Data in the /wal
and /head_chunks
directories counts toward the retention size limit, but Prometheus never purges data from these directories based on size- or time-based retention policies.
Thus, if you set a retention size limit lower than the maximum size set for the /wal
and /head_chunks
directories, you have configured the system not to retain any data blocks in the /prometheus
data directories.
The size-based retention policy is applied only when Prometheus cuts a new data block, which occurs every two hours after the WAL contains at least three hours of data.
If you do not explicitly define values for either retention
or retentionSize
, retention time defaults to 15 days for core platform monitoring and 24 hours for user-defined project monitoring. Retention size is not set.
If you define values for both retention
and retentionSize
, both values apply.
If any data blocks exceed the defined retention time or the defined size limit, Prometheus purges these data blocks.
If you define a value for retentionSize
and do not define retention
, only the retentionSize
value applies.
If you do not define a value for retentionSize
and only define a value for retention
, only the retention
value applies.
If you set the retentionSize
or retention
value to 0
, the default settings apply. The default settings set retention time to 15 days for core platform monitoring and 24 hours for user-defined project monitoring. By default, retention size is not set.
Data compaction occurs every two hours. Therefore, a persistent volume (PV) might fill up before compaction, potentially exceeding the |
You have access to the cluster as a user with the dedicated-admin
role.
The user-workload-monitoring-config
ConfigMap
object exists. This object is created by default when the cluster is created.
You have installed the OpenShift CLI (oc
).
Edit the ConfigMap
object:
Edit the user-workload-monitoring-config
ConfigMap
object in the openshift-user-workload-monitoring
project:
$ oc -n openshift-user-workload-monitoring edit configmap user-workload-monitoring-config
Add the retention time and size configuration under data/config.yaml
:
apiVersion: v1
kind: ConfigMap
metadata:
name: user-workload-monitoring-config
namespace: openshift-user-workload-monitoring
data:
config.yaml: |
prometheus:
retention: <time_specification> (1)
retentionSize: <size_specification> (2)
1 | The retention time: a number directly followed by ms (milliseconds), s (seconds), m (minutes), h (hours), d (days), w (weeks), or y (years).
You can also combine time values for specific times, such as 1h30m15s . |
2 | The retention size: a number directly followed by B (bytes), KB (kilobytes), MB (megabytes), GB (gigabytes), TB (terabytes), PB (petabytes), or EB (exabytes). |
The following example sets the retention time to 24 hours and the retention size to 10 gigabytes for the Prometheus instance that monitors user-defined projects:
apiVersion: v1
kind: ConfigMap
metadata:
name: user-workload-monitoring-config
namespace: openshift-user-workload-monitoring
data:
config.yaml: |
prometheus:
retention: 24h
retentionSize: 10GB
Save the file to apply the changes. The pods affected by the new configuration are automatically redeployed.
By default, for user-defined projects, Thanos Ruler automatically retains metrics data for 24 hours. You can modify the retention time to change how long this data is retained by specifying a time value in the user-workload-monitoring-config
config map in the openshift-user-workload-monitoring
namespace.
You have access to the cluster as a user with the dedicated-admin
role.
The user-workload-monitoring-config
ConfigMap
object exists. This object is created by default when the cluster is created.
You have installed the OpenShift CLI (oc
).
Edit the user-workload-monitoring-config
ConfigMap
object in the openshift-user-workload-monitoring
project:
$ oc -n openshift-user-workload-monitoring edit configmap user-workload-monitoring-config
Add the retention time configuration under data/config.yaml
:
apiVersion: v1
kind: ConfigMap
metadata:
name: user-workload-monitoring-config
namespace: openshift-user-workload-monitoring
data:
config.yaml: |
thanosRuler:
retention: <time_specification> (1)
1 | Specify the retention time in the following format: a number directly followed by ms (milliseconds), s (seconds), m (minutes), h (hours), d (days), w (weeks), or y (years).
You can also combine time values for specific times, such as 1h30m15s .
The default is 24h . |
The following example sets the retention time to 10 days for Thanos Ruler data:
apiVersion: v1
kind: ConfigMap
metadata:
name: user-workload-monitoring-config
namespace: openshift-user-workload-monitoring
data:
config.yaml: |
thanosRuler:
retention: 10d
Save the file to apply the changes. The pods affected by the new configuration are automatically redeployed.
You can configure remote write storage to enable Prometheus to send ingested metrics to remote systems for long-term storage. Doing so has no impact on how or for how long Prometheus stores metrics.
You have access to the cluster as a user with the dedicated-admin
role.
The user-workload-monitoring-config
ConfigMap
object exists. This object is created by default when the cluster is created.
You have installed the OpenShift CLI (oc
).
You have set up a remote write compatible endpoint (such as Thanos) and know the endpoint URL. See the Prometheus remote endpoints and storage documentation for information about endpoints that are compatible with the remote write feature.
Red Hat only provides information for configuring remote write senders and does not offer guidance on configuring receiver endpoints. Customers are responsible for setting up their own endpoints that are remote-write compatible. Issues with endpoint receiver configurations are not included in Red Hat production support. |
You have set up authentication credentials in a Secret
object for the remote write endpoint. You must create the secret in the
openshift-user-workload-monitoring
namespace.
To reduce security risks, use HTTPS and authentication to send metrics to an endpoint. |
Edit the ConfigMap
object:
Edit the user-workload-monitoring-config
ConfigMap
object in the openshift-user-workload-monitoring
project:
$ oc -n openshift-user-workload-monitoring edit configmap user-workload-monitoring-config
Add a remoteWrite:
section under data/config.yaml/prometheus
, as shown in the following example:
apiVersion: v1
kind: ConfigMap
metadata:
name: user-workload-monitoring-config
namespace: openshift-user-workload-monitoring
data:
config.yaml: |
prometheus:
remoteWrite:
- url: "https://remote-write-endpoint.example.com" (1)
<endpoint_authentication_credentials> (2)
1 | The URL of the remote write endpoint. |
2 | The authentication method and credentials for the endpoint.
Currently supported authentication methods are AWS Signature Version 4, authentication using HTTP an Authorization request header, basic authentication, OAuth 2.0, and TLS client.
See Supported remote write authentication settings below for sample configurations of supported authentication methods. |
Add write relabel configuration values after the authentication credentials:
apiVersion: v1
kind: ConfigMap
metadata:
name: user-workload-monitoring-config
namespace: openshift-user-workload-monitoring
data:
config.yaml: |
prometheus:
remoteWrite:
- url: "https://remote-write-endpoint.example.com"
<endpoint_authentication_credentials>
writeRelabelConfigs:
- <your_write_relabel_configs> (1)
1 | Add configuration for metrics that you want to send to the remote endpoint. |
my_metric
apiVersion: v1
kind: ConfigMap
metadata:
name: user-workload-monitoring-config
namespace: openshift-user-workload-monitoring
data:
config.yaml: |
prometheus:
remoteWrite:
- url: "https://remote-write-endpoint.example.com"
writeRelabelConfigs:
- sourceLabels: [__name__]
regex: 'my_metric'
action: keep
my_metric_1
and my_metric_2
in my_namespace
namespaceapiVersion: v1
kind: ConfigMap
metadata:
name: user-workload-monitoring-config
namespace: openshift-user-workload-monitoring
data:
config.yaml: |
prometheus:
remoteWrite:
- url: "https://remote-write-endpoint.example.com"
writeRelabelConfigs:
- sourceLabels: [__name__,namespace]
regex: '(my_metric_1|my_metric_2);my_namespace'
action: keep
Save the file to apply the changes. The new configuration is applied automatically.
You can use different methods to authenticate with a remote write endpoint. Currently supported authentication methods are AWS Signature Version 4, basic authentication, authorization, OAuth 2.0, and TLS client. The following table provides details about supported authentication methods for use with remote write.
Authentication method | Config map field | Description |
---|---|---|
AWS Signature Version 4 |
|
This method uses AWS Signature Version 4 authentication to sign requests. You cannot use this method simultaneously with authorization, OAuth 2.0, or Basic authentication. |
Basic authentication |
|
Basic authentication sets the authorization header on every remote write request with the configured username and password. |
authorization |
|
Authorization sets the |
OAuth 2.0 |
|
An OAuth 2.0 configuration uses the client credentials grant type.
Prometheus fetches an access token from |
TLS client |
|
A TLS client configuration specifies the CA certificate, the client certificate, and the client key file information used to authenticate with the remote write endpoint server using TLS. The sample configuration assumes that you have already created a CA certificate file, a client certificate file, and a client key file. |
The following samples show different authentication settings you can use to connect to a remote write endpoint. Each sample also shows how to configure a corresponding Secret
object that contains authentication credentials and other relevant settings. Each sample configures authentication for use with
monitoring user-defined projects
in the openshift-user-workload-monitoring
namespace.
The following shows the settings for a sigv4
secret named sigv4-credentials
in the openshift-user-workload-monitoring
namespace.
apiVersion: v1
kind: Secret
metadata:
name: sigv4-credentials
namespace: openshift-user-workload-monitoring
stringData:
accessKey: <AWS_access_key> (1)
secretKey: <AWS_secret_key> (2)
type: Opaque
1 | The AWS API access key. |
2 | The AWS API secret key. |
The following shows sample AWS Signature Version 4 remote write authentication settings that use a Secret
object named sigv4-credentials
in the openshift-user-workload-monitoring
namespace:
apiVersion: v1
kind: ConfigMap
metadata:
name: user-workload-monitoring-config
namespace: openshift-user-workload-monitoring
data:
config.yaml: |
prometheus:
remoteWrite:
- url: "https://authorization.example.com/api/write"
sigv4:
region: <AWS_region> (1)
accessKey:
name: sigv4-credentials (2)
key: accessKey (3)
secretKey:
name: sigv4-credentials (2)
key: secretKey (4)
profile: <AWS_profile_name> (5)
roleArn: <AWS_role_arn> (6)
1 | The AWS region. |
2 | The name of the Secret object containing the AWS API access credentials. |
3 | The key that contains the AWS API access key in the specified Secret object. |
4 | The key that contains the AWS API secret key in the specified Secret object. |
5 | The name of the AWS profile that is being used to authenticate. |
6 | The unique identifier for the Amazon Resource Name (ARN) assigned to your role. |
The following shows sample Basic authentication settings for a Secret
object named rw-basic-auth
in the openshift-user-workload-monitoring
namespace:
apiVersion: v1
kind: Secret
metadata:
name: rw-basic-auth
namespace: openshift-user-workload-monitoring
stringData:
user: <basic_username> (1)
password: <basic_password> (2)
type: Opaque
1 | The username. |
2 | The password. |
The following sample shows a basicAuth
remote write configuration that uses a Secret
object named rw-basic-auth
in the openshift-user-workload-monitoring
namespace.
It assumes that you have already set up authentication credentials for the endpoint.
apiVersion: v1
kind: ConfigMap
metadata:
name: user-workload-monitoring-config
namespace: openshift-user-workload-monitoring
data:
config.yaml: |
prometheus:
remoteWrite:
- url: "https://basicauth.example.com/api/write"
basicAuth:
username:
name: rw-basic-auth (1)
key: user (2)
password:
name: rw-basic-auth (1)
key: password (3)
1 | The name of the Secret object that contains the authentication credentials. |
2 | The key that contains the username in the specified Secret object. |
3 | The key that contains the password in the specified Secret object. |
Secret
ObjectThe following shows bearer token settings for a Secret
object named rw-bearer-auth
in the openshift-user-workload-monitoring
namespace:
apiVersion: v1
kind: Secret
metadata:
name: rw-bearer-auth
namespace: openshift-user-workload-monitoring
stringData:
token: <authentication_token> (1)
type: Opaque
1 | The authentication token. |
The following shows sample bearer token config map settings that use a Secret
object named rw-bearer-auth
in the openshift-user-workload-monitoring
namespace:
apiVersion: v1
kind: ConfigMap
metadata:
name: user-workload-monitoring-config
namespace: openshift-user-workload-monitoring
data:
config.yaml: |
enableuserWorkload: true
prometheus:
remoteWrite:
- url: "https://authorization.example.com/api/write"
authorization:
type: Bearer (1)
credentials:
name: rw-bearer-auth (2)
key: token (3)
1 | The authentication type of the request. The default value is Bearer . |
2 | The name of the Secret object that contains the authentication credentials. |
3 | The key that contains the authentication token in the specified Secret object. |
The following shows sample OAuth 2.0 settings for a Secret
object named oauth2-credentials
in the openshift-user-workload-monitoring
namespace:
apiVersion: v1
kind: Secret
metadata:
name: oauth2-credentials
namespace: openshift-user-workload-monitoring
stringData:
id: <oauth2_id> (1)
secret: <oauth2_secret> (2)
type: Opaque
1 | The Oauth 2.0 ID. |
2 | The OAuth 2.0 secret. |
The following shows an oauth2
remote write authentication sample configuration that uses a Secret
object named oauth2-credentials
in the openshift-user-workload-monitoring
namespace:
apiVersion: v1
kind: ConfigMap
metadata:
name: user-workload-monitoring-config
namespace: openshift-user-workload-monitoring
data:
config.yaml: |
prometheus:
remoteWrite:
- url: "https://test.example.com/api/write"
oauth2:
clientId:
secret:
name: oauth2-credentials (1)
key: id (2)
clientSecret:
name: oauth2-credentials (1)
key: secret (2)
tokenUrl: https://example.com/oauth2/token (3)
scopes: (4)
- <scope_1>
- <scope_2>
endpointParams: (5)
param1: <parameter_1>
param2: <parameter_2>
1 | The name of the corresponding Secret object. Note that ClientId can alternatively refer to a ConfigMap object, although clientSecret must refer to a Secret object. |
2 | The key that contains the OAuth 2.0 credentials in the specified Secret object. |
3 | The URL used to fetch a token with the specified clientId and clientSecret . |
4 | The OAuth 2.0 scopes for the authorization request. These scopes limit what data the tokens can access. |
5 | The OAuth 2.0 authorization request parameters required for the authorization server. |
The following shows sample TLS client settings for a tls
Secret
object named mtls-bundle
in the openshift-user-workload-monitoring
namespace.
apiVersion: v1
kind: Secret
metadata:
name: mtls-bundle
namespace: openshift-user-workload-monitoring
data:
ca.crt: <ca_cert> (1)
client.crt: <client_cert> (2)
client.key: <client_key> (3)
type: tls
1 | The CA certificate in the Prometheus container with which to validate the server certificate. |
2 | The client certificate for authentication with the server. |
3 | The client key. |
The following sample shows a tlsConfig
remote write authentication configuration that uses a TLS Secret
object named mtls-bundle
.
apiVersion: v1
kind: ConfigMap
metadata:
name: user-workload-monitoring-config
namespace: openshift-user-workload-monitoring
data:
config.yaml: |
prometheus:
remoteWrite:
- url: "https://remote-write-endpoint.example.com"
tlsConfig:
ca:
secret:
name: mtls-bundle (1)
key: ca.crt (2)
cert:
secret:
name: mtls-bundle (1)
key: client.crt (3)
keySecret:
name: mtls-bundle (1)
key: client.key (4)
1 | The name of the corresponding Secret object that contains the TLS authentication credentials. Note that ca and cert can alternatively refer to a ConfigMap object, though keySecret must refer to a Secret object. |
2 | The key in the specified Secret object that contains the CA certificate for the endpoint. |
3 | The key in the specified Secret object that contains the client certificate for the endpoint. |
4 | The key in the specified Secret object that contains the client key secret. |
You can use the queueConfig
object for remote write to tune the remote write queue parameters. The following example shows the queue parameters with their default values for
monitoring for user-defined projects
in the openshift-user-workload-monitoring
namespace.
apiVersion: v1
kind: ConfigMap
metadata:
name: user-workload-monitoring-config
namespace: openshift-user-workload-monitoring
data:
config.yaml: |
prometheus:
remoteWrite:
- url: "https://remote-write-endpoint.example.com"
<endpoint_authentication_credentials>
queueConfig:
capacity: 10000 (1)
minShards: 1 (2)
maxShards: 50 (3)
maxSamplesPerSend: 2000 (4)
batchSendDeadline: 5s (5)
minBackoff: 30ms (6)
maxBackoff: 5s (7)
retryOnRateLimit: false (8)
sampleAgeLimit: 0s (9)
1 | The number of samples to buffer per shard before they are dropped from the queue. |
2 | The minimum number of shards. |
3 | The maximum number of shards. |
4 | The maximum number of samples per send. |
5 | The maximum time for a sample to wait in buffer. |
6 | The initial time to wait before retrying a failed request. The time gets doubled for every retry up to the maxbackoff time. |
7 | The maximum time to wait before retrying a failed request. |
8 | Set this parameter to true to retry a request after receiving a 429 status code from the remote write storage. |
9 | The samples that are older than the sampleAgeLimit limit are dropped from the queue. If the value is undefined or set to 0s , the parameter is ignored. |
Setting up remote write compatible endpoints (Prometheus documentation)
Tuning remote write settings (Prometheus documentation)
If you manage multiple OpenShift Dedicated clusters and use the remote write feature to send metrics data from these clusters to an external storage location, you can add cluster ID labels to identify the metrics data coming from different clusters. You can then query these labels to identify the source cluster for a metric and distinguish that data from similar metrics data sent by other clusters.
This way, if you manage many clusters for multiple customers and send metrics data to a single centralized storage system, you can use cluster ID labels to query metrics for a particular cluster or customer.
Creating and using cluster ID labels involves three general steps:
Configuring the write relabel settings for remote write storage.
Adding cluster ID labels to the metrics.
Querying these labels to identify the source cluster or customer for a metric.
You can create cluster ID labels for metrics by editing the settings in the user-workload-monitoring-config
config map in the openshift-user-workload-monitoring
namespace.
You have access to the cluster as a user with the dedicated-admin
role.
The user-workload-monitoring-config
ConfigMap object exists. This object is created by default when the cluster is created.
You have installed the OpenShift CLI (oc
).
You have configured remote write storage.
Edit the ConfigMap
object:
Edit the user-workload-monitoring-config
ConfigMap
object in the openshift-user-workload-monitoring
project:
$ oc -n openshift-user-workload-monitoring edit configmap user-workload-monitoring-config
In the writeRelabelConfigs:
section under data/config.yaml/prometheus/remoteWrite
, add cluster ID relabel configuration values:
apiVersion: v1
kind: ConfigMap
metadata:
name: user-workload-monitoring-config
namespace: openshift-user-workload-monitoring
data:
config.yaml: |
prometheus:
remoteWrite:
- url: "https://remote-write-endpoint.example.com"
<endpoint_authentication_credentials>
writeRelabelConfigs: (1)
- <relabel_config> (2)
1 | Add a list of write relabel configurations for metrics that you want to send to the remote endpoint. |
2 | Substitute the label configuration for the metrics sent to the remote write endpoint. |
The following sample shows how to forward a metric with the cluster ID label cluster_id
in user-workload monitoring:
apiVersion: v1
kind: ConfigMap
metadata:
name: user-workload-monitoring-config
namespace: openshift-user-workload-monitoring
data:
config.yaml: |
prometheus:
remoteWrite:
- url: "https://remote-write-endpoint.example.com"
writeRelabelConfigs:
- sourceLabels:
- __tmp_openshift_cluster_id__ (1)
targetLabel: cluster_id (2)
action: replace (3)
1 | The system initially applies a temporary cluster ID source label named __tmp_openshift_cluster_id__ . This temporary label gets replaced by the cluster ID label name that you specify. |
2 | Specify the name of the cluster ID label for metrics sent to remote write storage. If you use a label name that already exists for a metric, that value is overwritten with the name of this cluster ID label. For the label name, do not use __tmp_openshift_cluster_id__ . The final relabeling step removes labels that use this name. |
3 | The replace write relabel action replaces the temporary label with the target label for outgoing metrics. This action is the default and is applied if no action is specified. |
Save the file to apply the changes. The new configuration is applied automatically.
Developers can create labels to define attributes for metrics in the form of key-value pairs. The number of potential key-value pairs corresponds to the number of possible values for an attribute. An attribute that has an unlimited number of potential values is called an unbound attribute. For example, a customer_id
attribute is unbound because it has an infinite number of possible values.
Every assigned key-value pair has a unique time series. The use of many unbound attributes in labels can result in an exponential increase in the number of time series created. This can impact Prometheus performance and can consume a lot of disk space.
A dedicated-admin
can use the following measures to control the impact of unbound metrics attributes in user-defined projects:
Limit the number of samples that can be accepted per target scrape in user-defined projects
Limit the number of scraped labels, the length of label names, and the length of label values
Create alerts that fire when a scrape sample threshold is reached or when the target cannot be scraped
Limiting scrape samples can help prevent the issues caused by adding many unbound attributes to labels. Developers can also prevent the underlying cause by limiting the number of unbound attributes that they define for metrics. Using attributes that are bound to a limited set of possible values reduces the number of potential key-value pair combinations. |
You can limit the number of samples that can be accepted per target scrape in user-defined projects. You can also limit the number of scraped labels, the length of label names, and the length of label values.
If you set sample or label limits, no further sample data is ingested for that target scrape after the limit is reached. |
You have access to the cluster as a user with the dedicated-admin
role.
The user-workload-monitoring-config
ConfigMap
object exists. This object is created by default when the cluster is created.
You have installed the OpenShift CLI (oc
).
Edit the user-workload-monitoring-config
ConfigMap
object in the openshift-user-workload-monitoring
project:
$ oc -n openshift-user-workload-monitoring edit configmap user-workload-monitoring-config
Add the enforcedSampleLimit
configuration to data/config.yaml
to limit the number of samples that can be accepted per target scrape in user-defined projects:
apiVersion: v1
kind: ConfigMap
metadata:
name: user-workload-monitoring-config
namespace: openshift-user-workload-monitoring
data:
config.yaml: |
prometheus:
enforcedSampleLimit: 50000 (1)
1 | A value is required if this parameter is specified. This enforcedSampleLimit example limits the number of samples that can be accepted per target scrape in user-defined projects to 50,000. |
Add the enforcedLabelLimit
, enforcedLabelNameLengthLimit
, and enforcedLabelValueLengthLimit
configurations to data/config.yaml
to limit the number of scraped labels, the length of label names, and the length of label values in user-defined projects:
apiVersion: v1
kind: ConfigMap
metadata:
name: user-workload-monitoring-config
namespace: openshift-user-workload-monitoring
data:
config.yaml: |
prometheus:
enforcedLabelLimit: 500 (1)
enforcedLabelNameLengthLimit: 50 (2)
enforcedLabelValueLengthLimit: 600 (3)
1 | Specifies the maximum number of labels per scrape.
The default value is 0 , which specifies no limit. |
2 | Specifies the maximum length in characters of a label name.
The default value is 0 , which specifies no limit. |
3 | Specifies the maximum length in characters of a label value.
The default value is 0 , which specifies no limit. |
Save the file to apply the changes. The limits are applied automatically.
The OpenShift Dedicated monitoring stack includes a local Alertmanager instance that routes alerts from Prometheus. You can add external Alertmanager instances to route alerts for user-defined projects.
If you add the same external Alertmanager configuration for multiple clusters and disable the local instance for each cluster, you can then manage alert routing for multiple clusters by using a single external Alertmanager instance.
You have access to the cluster as a user with the dedicated-admin
role.
The user-workload-monitoring-config
ConfigMap
object exists. This object is created by default when the cluster is created.
You have installed the OpenShift CLI (oc
).
Edit the ConfigMap
object.
Edit the user-workload-monitoring-config
config map in the openshift-user-workload-monitoring
project:
$ oc -n openshift-user-workload-monitoring edit configmap user-workload-monitoring-config
Add a <component>/additionalAlertmanagerConfigs:
section under data/config.yaml/
.
Add the configuration details for additional Alertmanagers in this section:
apiVersion: v1
kind: ConfigMap
metadata:
name: user-workload-monitoring-config
namespace: openshift-user-workload-monitoring
data:
config.yaml: |
<component>:
additionalAlertmanagerConfigs:
- <alertmanager_specification>
For <component>
, substitute one of two supported external Alertmanager components: prometheus
or thanosRuler
.
For <alertmanager_specification>
, substitute authentication and other configuration details for additional Alertmanager instances. Currently supported authentication methods are bearer token (bearerToken
) and client TLS (tlsConfig
). The following sample config map configures an additional Alertmanager using Thanos Ruler with a bearer token and client TLS authentication:
apiVersion: v1
kind: ConfigMap
metadata:
name: user-workload-monitoring-config
namespace: openshift-user-workload-monitoring
data:
config.yaml: |
thanosRuler:
additionalAlertmanagerConfigs:
- scheme: https
pathPrefix: /
timeout: "30s"
apiVersion: v1
bearerToken:
name: alertmanager-bearer-token
key: token
tlsConfig:
key:
name: alertmanager-tls
key: tls.key
cert:
name: alertmanager-tls
key: tls.crt
ca:
name: alertmanager-tls
key: tls.ca
staticConfigs:
- external-alertmanager1-remote.com
- external-alertmanager1-remote2.com
Save the file to apply the changes. The pods affected by the new configuration are automatically redeployed.
The OpenShift Dedicated monitoring stack includes Alertmanager, which routes alerts from Prometheus to endpoint receivers. If you need to authenticate with a receiver so that Alertmanager can send alerts to it, you can configure Alertmanager to use a secret that contains authentication credentials for the receiver.
For example, you can configure Alertmanager to use a secret to authenticate with an endpoint receiver that requires a certificate issued by a private Certificate Authority (CA).
You can also configure Alertmanager to use a secret to authenticate with a receiver that requires a password file for Basic HTTP authentication.
In either case, authentication details are contained in the Secret
object rather than in the ConfigMap
object.
You can add secrets to the Alertmanager configuration for user-defined projects by editing the user-workload-monitoring-config
config map in the openshift-user-workload-monitoring
project.
After you add a secret to the config map, the secret is mounted as a volume at /etc/alertmanager/secrets/<secret_name>
within the alertmanager
container for the Alertmanager pods.
You have access to the cluster as a user with the dedicated-admin
role.
The user-workload-monitoring-config
ConfigMap
object exists. This object is created by default when the cluster is created.
You have created the secret to be configured in Alertmanager in the openshift-user-workload-monitoring
project.
You have installed the OpenShift CLI (oc
).
Edit the ConfigMap
object.
Edit the user-workload-monitoring-config
config map in the openshift-user-workload-monitoring
project:
$ oc -n openshift-user-workload-monitoring edit configmap user-workload-monitoring-config
Add a secrets:
section under data/config.yaml/alertmanager/secrets
with the following configuration:
apiVersion: v1
kind: ConfigMap
metadata:
name: user-workload-monitoring-config
namespace: openshift-user-workload-monitoring
data:
config.yaml: |
alertmanager:
secrets: (1)
- <secret_name_1> (2)
- <secret_name_2>
1 | This section contains the secrets to be mounted into Alertmanager. The secrets must be located within the same namespace as the Alertmanager object. |
2 | The name of the Secret object that contains authentication credentials for the receiver. If you add multiple secrets, place each one on a new line. |
The following sample config map settings configure Alertmanager to use two Secret
objects named test-secret
and test-secret-api-token
:
apiVersion: v1
kind: ConfigMap
metadata:
name: user-workload-monitoring-config
namespace: openshift-user-workload-monitoring
data:
config.yaml: |
alertmanager:
enabled: true
secrets:
- test-secret
- test-api-receiver-token
Save the file to apply the changes. The new configuration is applied automatically.
You can attach custom labels to all time series and alerts leaving Prometheus by using the external labels feature of Prometheus.
You have access to the cluster as a user with the dedicated-admin
role.
The user-workload-monitoring-config
ConfigMap
object exists. This object is created by default when the cluster is created.
You have installed the OpenShift CLI (oc
).
Edit the ConfigMap
object:
Edit the user-workload-monitoring-config
ConfigMap
object in the openshift-user-workload-monitoring
project:
$ oc -n openshift-user-workload-monitoring edit configmap user-workload-monitoring-config
Define a map of labels you want to add for every metric under data/config.yaml
:
apiVersion: v1
kind: ConfigMap
metadata:
name: user-workload-monitoring-config
namespace: openshift-user-workload-monitoring
data:
config.yaml: |
prometheus:
externalLabels:
<key>: <value> (1)
1 | Substitute <key>: <value> with a map of key-value pairs where <key> is a unique name for the new label and <value> is its value. |
|
In the |
For example, to add metadata about the region and environment to all time series and alerts related to user-defined projects, use the following example:
apiVersion: v1
kind: ConfigMap
metadata:
name: user-workload-monitoring-config
namespace: openshift-user-workload-monitoring
data:
config.yaml: |
prometheus:
externalLabels:
region: eu
environment: prod
Save the file to apply the changes. The pods affected by the new configuration are automatically redeployed.
You can use pod topology spread constraints to control how the pods for user-defined monitoring are spread across a network topology when OpenShift Dedicated pods are deployed in multiple availability zones.
Pod topology spread constraints are suitable for controlling pod scheduling within hierarchical topologies in which nodes are spread across different infrastructure levels, such as regions and zones within those regions. Additionally, by being able to schedule pods in different zones, you can improve network latency in certain scenarios.
You can configure pod topology spread constraints for all the pods for user-defined monitoring to control how pod replicas are scheduled to nodes across zones. This ensures that the pods are highly available and run more efficiently, because workloads are spread across nodes in different data centers or hierarchical infrastructure zones.
You can configure pod topology spread constraints for monitoring pods by using
the user-workload-monitoring-config
config map.
You have access to the cluster as a user with the dedicated-admin
role.
The user-workload-monitoring-config
ConfigMap
object exists. This object is created by default when the cluster is created.
You have installed the OpenShift CLI (oc
).
Edit the user-workload-monitoring-config
config map in the openshift-user-workload-monitoring
project:
$ oc -n openshift-user-workload-monitoring edit configmap user-workload-monitoring-config
Add the following settings under the data/config.yaml
field to configure pod topology spread constraints:
apiVersion: v1
kind: ConfigMap
metadata:
name: user-workload-monitoring-config
namespace: openshift-user-workload-monitoring
data:
config.yaml: |
<component>: (1)
topologySpreadConstraints:
- maxSkew: <n> (2)
topologyKey: <key> (3)
whenUnsatisfiable: <value> (4)
labelSelector: (5)
<match_option>
1 | Specify a name of the component for which you want to set up pod topology spread constraints. |
2 | Specify a numeric value for maxSkew , which defines the degree to which pods are allowed to be unevenly distributed. |
3 | Specify a key of node labels for topologyKey .
Nodes that have a label with this key and identical values are considered to be in the same topology.
The scheduler tries to put a balanced number of pods into each domain. |
4 | Specify a value for whenUnsatisfiable .
Available options are DoNotSchedule and ScheduleAnyway .
Specify DoNotSchedule if you want the maxSkew value to define the maximum difference allowed between the number of matching pods in the target topology and the global minimum.
Specify ScheduleAnyway if you want the scheduler to still schedule the pod but to give higher priority to nodes that might reduce the skew. |
5 | Specify labelSelector to find matching pods.
Pods that match this label selector are counted to determine the number of pods in their corresponding topology domain. |
apiVersion: v1
kind: ConfigMap
metadata:
name: user-workload-monitoring-config
namespace: openshift-user-workload-monitoring
data:
config.yaml: |
thanosRuler:
topologySpreadConstraints:
- maxSkew: 1
topologyKey: monitoring
whenUnsatisfiable: ScheduleAnyway
labelSelector:
matchLabels:
app.kubernetes.io/name: thanos-ruler
Save the file to apply the changes. The pods affected by the new configuration are automatically redeployed.
You can configure the log level for Alertmanager, Prometheus Operator, Prometheus, and Thanos Ruler.
The following log levels can be applied to the relevant component in the
user-workload-monitoring-config
ConfigMap
objects:
debug
. Log debug, informational, warning, and error messages.
info
. Log informational, warning, and error messages.
warn
. Log warning and error messages only.
error
. Log error messages only.
The default log level is info
.
You have access to the cluster as a user with the dedicated-admin
role.
The user-workload-monitoring-config
ConfigMap
object exists. This object is created by default when the cluster is created.
You have installed the OpenShift CLI (oc
).
Edit the ConfigMap
object:
Edit the user-workload-monitoring-config
ConfigMap
object in the openshift-user-workload-monitoring
project:
$ oc -n openshift-user-workload-monitoring edit configmap user-workload-monitoring-config
Add logLevel: <log_level>
for a component under data/config.yaml
:
apiVersion: v1
kind: ConfigMap
metadata:
name: user-workload-monitoring-config
namespace: openshift-user-workload-monitoring
data:
config.yaml: |
<component>: (1)
logLevel: <log_level> (2)
1 | The monitoring stack component for which you are setting a log level.
For user workload monitoring, available component values are alertmanager , prometheus , prometheusOperator , and thanosRuler . |
2 | The log level to apply to the component. The available values are error , warn , info , and debug . The default value is info . |
Save the file to apply the changes. The pods affected by the new configuration are automatically redeployed.
Confirm that the log-level has been applied by reviewing the deployment or pod configuration in the related project. The following example checks the log level in the prometheus-operator
deployment in the openshift-user-workload-monitoring
project:
$ oc -n openshift-user-workload-monitoring get deploy prometheus-operator -o yaml | grep "log-level"
- --log-level=debug
Check that the pods for the component are running. The following example lists the status of pods in the openshift-user-workload-monitoring
project:
$ oc -n openshift-user-workload-monitoring get pods
If an unrecognized |
You can configure Prometheus to write all queries that have been run by the engine to a log file.
Because log rotation is not supported, only enable this feature temporarily when you need to troubleshoot an issue. After you finish troubleshooting, disable query logging by reverting the changes you made to the |
You have access to the cluster as a user with the dedicated-admin
role.
The user-workload-monitoring-config
ConfigMap
object exists. This object is created by default when the cluster is created.
You have installed the OpenShift CLI (oc
).
Edit the user-workload-monitoring-config
ConfigMap
object in the openshift-user-workload-monitoring
project:
$ oc -n openshift-user-workload-monitoring edit configmap user-workload-monitoring-config
Add queryLogFile: <path>
for prometheus
under data/config.yaml
:
apiVersion: v1
kind: ConfigMap
metadata:
name: user-workload-monitoring-config
namespace: openshift-user-workload-monitoring
data:
config.yaml: |
prometheus:
queryLogFile: <path> (1)
1 | The full path to the file in which queries will be logged. |
Save the file to apply the changes. The pods affected by the new configuration are automatically redeployed.
Verify that the pods for the component are running. The following example command lists the status of pods in the openshift-user-workload-monitoring
project:
$ oc -n openshift-user-workload-monitoring get pods
Read the query log:
$ oc -n openshift-user-workload-monitoring exec prometheus-user-workload-0 -- cat <path>
Revert the setting in the config map after you have examined the logged query information. |