Chapter 3. Installing the logging subsystem for Red Hat OpenShift
You can install the logging subsystem for Red Hat OpenShift by deploying the OpenShift Elasticsearch and Red Hat OpenShift Logging Operators. The OpenShift Elasticsearch Operator creates and manages the Elasticsearch cluster used by OpenShift Logging. The logging subsystem Operator creates and manages the components of the logging stack.
The process for deploying the logging subsystem to OpenShift Container Platform involves:
- Reviewing the Logging subsystem storage considerations.
- Installing the OpenShift Elasticsearch Operator and Red Hat OpenShift Logging Operator using the OpenShift Container Platform web console or CLI.
3.1. Installing the logging subsystem for Red Hat OpenShift using the web console
You can use the OpenShift Container Platform web console to install the OpenShift Elasticsearch and Red Hat OpenShift Logging Operators.
If you do not want to use the default Elasticsearch log store, you can remove the internal Elasticsearch logStore
and Kibana visualization
components from the ClusterLogging
custom resource (CR). Removing these components is optional but saves resources. For more information, see Removing unused components if you do not use the default Elasticsearch log store.
Prerequisites
Ensure that you have the necessary persistent storage for Elasticsearch. Note that each Elasticsearch node requires its own storage volume.
NoteIf you use a local volume for persistent storage, do not use a raw block volume, which is described with
volumeMode: block
in theLocalVolume
object. Elasticsearch cannot use raw block volumes.Elasticsearch is a memory-intensive application. By default, OpenShift Container Platform installs three Elasticsearch nodes with memory requests and limits of 16 GB. This initial set of three OpenShift Container Platform nodes might not have enough memory to run Elasticsearch within your cluster. If you experience memory issues that are related to Elasticsearch, add more Elasticsearch nodes to your cluster rather than increasing the memory on existing nodes.
Procedure
To install the OpenShift Elasticsearch Operator and Red Hat OpenShift Logging Operator using the OpenShift Container Platform web console:
Install the OpenShift Elasticsearch Operator:
-
In the OpenShift Container Platform web console, click Operators
OperatorHub. - Choose OpenShift Elasticsearch Operator from the list of available Operators, and click Install.
- Ensure that the All namespaces on the cluster is selected under Installation Mode.
Ensure that openshift-operators-redhat is selected under Installed Namespace.
You must specify the
openshift-operators-redhat
namespace. Theopenshift-operators
namespace might contain Community Operators, which are untrusted and could publish a metric with the same name as an OpenShift Container Platform metric, which would cause conflicts.Select Enable operator recommended cluster monitoring on this namespace.
This option sets the
openshift.io/cluster-monitoring: "true"
label in the Namespace object. You must select this option to ensure that cluster monitoring scrapes theopenshift-operators-redhat
namespace.- Select stable-5.x as the Update Channel.
Select an Approval Strategy.
- The Automatic strategy allows Operator Lifecycle Manager (OLM) to automatically update the Operator when a new version is available.
- The Manual strategy requires a user with appropriate credentials to approve the Operator update.
- Click Install.
-
Verify that the OpenShift Elasticsearch Operator installed by switching to the Operators
Installed Operators page. - Ensure that OpenShift Elasticsearch Operator is listed in all projects with a Status of Succeeded.
-
In the OpenShift Container Platform web console, click Operators
Install the Red Hat OpenShift Logging Operator:
-
In the OpenShift Container Platform web console, click Operators
OperatorHub. - Choose Red Hat OpenShift Logging from the list of available Operators, and click Install.
- Ensure that the A specific namespace on the cluster is selected under Installation Mode.
- Ensure that Operator recommended namespace is openshift-logging under Installed Namespace.
Select Enable operator recommended cluster monitoring on this namespace.
This option sets the
openshift.io/cluster-monitoring: "true"
label in the Namespace object. You must select this option to ensure that cluster monitoring scrapes theopenshift-logging
namespace.- Select stable-5.x as the Update Channel.
Select an Approval Strategy.
- The Automatic strategy allows Operator Lifecycle Manager (OLM) to automatically update the Operator when a new version is available.
- The Manual strategy requires a user with appropriate credentials to approve the Operator update.
- Click Install.
-
Verify that the Red Hat OpenShift Logging Operator installed by switching to the Operators
Installed Operators page. Ensure that Red Hat OpenShift Logging is listed in the openshift-logging project with a Status of Succeeded.
If the Operator does not appear as installed, to troubleshoot further:
-
Switch to the Operators
Installed Operators page and inspect the Status column for any errors or failures. -
Switch to the Workloads
Pods page and check the logs in any pods in the openshift-logging
project that are reporting issues.
-
Switch to the Operators
-
In the OpenShift Container Platform web console, click Operators
Create an OpenShift Logging instance:
-
Switch to the Administration
Custom Resource Definitions page. - On the Custom Resource Definitions page, click ClusterLogging.
- On the Custom Resource Definition details page, select View Instances from the Actions menu.
On the ClusterLoggings page, click Create ClusterLogging.
You might have to refresh the page to load the data.
In the YAML field, replace the code with the following:
NoteThis default OpenShift Logging configuration should support a wide array of environments. Review the topics on tuning and configuring logging subsystem components for information on modifications you can make to your OpenShift Logging cluster.
apiVersion: "logging.openshift.io/v1" kind: "ClusterLogging" metadata: name: "instance" 1 namespace: "openshift-logging" spec: managementState: "Managed" 2 logStore: type: "elasticsearch" 3 retentionPolicy: 4 application: maxAge: 1d infra: maxAge: 7d audit: maxAge: 7d elasticsearch: nodeCount: 3 5 storage: storageClassName: "<storage_class_name>" 6 size: 200G resources: 7 limits: memory: "16Gi" requests: memory: "16Gi" proxy: 8 resources: limits: memory: 256Mi requests: memory: 256Mi redundancyPolicy: "SingleRedundancy" visualization: type: "kibana" 9 kibana: replicas: 1 collection: logs: type: "fluentd" 10 fluentd: {}
- 1
- The name must be
instance
. - 2
- The OpenShift Logging management state. In some cases, if you change the OpenShift Logging defaults, you must set this to
Unmanaged
. However, an unmanaged deployment does not receive updates until OpenShift Logging is placed back into a managed state. - 3
- Settings for configuring Elasticsearch. Using the CR, you can configure shard replication policy and persistent storage.
- 4
- Specify the length of time that Elasticsearch should retain each log source. Enter an integer and a time designation: weeks(w), hours(h/H), minutes(m) and seconds(s). For example,
7d
for seven days. Logs older than themaxAge
are deleted. You must specify a retention policy for each log source or the Elasticsearch indices will not be created for that source. - 5
- Specify the number of Elasticsearch nodes. See the note that follows this list.
- 6
- Enter the name of an existing storage class for Elasticsearch storage. For best performance, specify a storage class that allocates block storage. If you do not specify a storage class, OpenShift Logging uses ephemeral storage.
- 7
- Specify the CPU and memory requests for Elasticsearch as needed. If you leave these values blank, the OpenShift Elasticsearch Operator sets default values that should be sufficient for most deployments. The default values are
16Gi
for the memory request and1
for the CPU request. - 8
- Specify the CPU and memory requests for the Elasticsearch proxy as needed. If you leave these values blank, the OpenShift Elasticsearch Operator sets default values that should be sufficient for most deployments. The default values are
256Mi
for the memory request and100m
for the CPU request. - 9
- Settings for configuring Kibana. Using the CR, you can scale Kibana for redundancy and configure the CPU and memory for your Kibana nodes. For more information, see Configuring the log visualizer.
- 10
- Settings for configuring Fluentd. Using the CR, you can configure Fluentd CPU and memory limits. For more information, see Configuring Fluentd.
NoteThe maximum number of Elasticsearch control plane nodes is three. If you specify a
nodeCount
greater than3
, OpenShift Container Platform creates three Elasticsearch nodes that are Master-eligible nodes, with the master, client, and data roles. The additional Elasticsearch nodes are created as Data-only nodes, using client and data roles. Control plane nodes perform cluster-wide actions such as creating or deleting an index, shard allocation, and tracking nodes. Data nodes hold the shards and perform data-related operations such as CRUD, search, and aggregations. Data-related operations are I/O-, memory-, and CPU-intensive. It is important to monitor these resources and to add more Data nodes if the current nodes are overloaded.For example, if
nodeCount=4
, the following nodes are created:$ oc get deployment
Example output
cluster-logging-operator 1/1 1 1 18h elasticsearch-cd-x6kdekli-1 0/1 1 0 6m54s elasticsearch-cdm-x6kdekli-1 1/1 1 1 18h elasticsearch-cdm-x6kdekli-2 0/1 1 0 6m49s elasticsearch-cdm-x6kdekli-3 0/1 1 0 6m44s
The number of primary shards for the index templates is equal to the number of Elasticsearch data nodes.
-
Click Create. This creates the logging subsystem components, the
Elasticsearch
custom resource and components, and the Kibana interface.
-
Switch to the Administration
Verify the install:
-
Switch to the Workloads
Pods page. Select the openshift-logging project.
You should see several pods for OpenShift Logging, Elasticsearch, Fluentd, and Kibana similar to the following list:
- cluster-logging-operator-cb795f8dc-xkckc
- elasticsearch-cdm-b3nqzchd-1-5c6797-67kfz
- elasticsearch-cdm-b3nqzchd-2-6657f4-wtprv
- elasticsearch-cdm-b3nqzchd-3-588c65-clg7g
- fluentd-2c7dg
- fluentd-9z7kk
- fluentd-br7r2
- fluentd-fn2sb
- fluentd-pb2f8
- fluentd-zqgqx
- kibana-7fb4fd4cc9-bvt4p
-
Switch to the Workloads
Additional resources
3.2. Post-installation tasks
If you plan to use Kibana, you must manually create your Kibana index patterns and visualizations to explore and visualize data in Kibana.
If your cluster network provider enforces network isolation, allow network traffic between the projects that contain the logging subsystem Operators.
3.3. Installing the logging subsystem for Red Hat OpenShift using the CLI
You can use the OpenShift Container Platform CLI to install the OpenShift Elasticsearch and Red Hat OpenShift Logging Operators.
Prerequisites
Ensure that you have the necessary persistent storage for Elasticsearch. Note that each Elasticsearch node requires its own storage volume.
NoteIf you use a local volume for persistent storage, do not use a raw block volume, which is described with
volumeMode: block
in theLocalVolume
object. Elasticsearch cannot use raw block volumes.Elasticsearch is a memory-intensive application. By default, OpenShift Container Platform installs three Elasticsearch nodes with memory requests and limits of 16 GB. This initial set of three OpenShift Container Platform nodes might not have enough memory to run Elasticsearch within your cluster. If you experience memory issues that are related to Elasticsearch, add more Elasticsearch nodes to your cluster rather than increasing the memory on existing nodes.
Procedure
To install the OpenShift Elasticsearch Operator and Red Hat OpenShift Logging Operator using the CLI:
Create a namespace for the OpenShift Elasticsearch Operator.
Create a namespace object YAML file (for example,
eo-namespace.yaml
) for the OpenShift Elasticsearch Operator:apiVersion: v1 kind: Namespace metadata: name: openshift-operators-redhat 1 annotations: openshift.io/node-selector: "" labels: openshift.io/cluster-monitoring: "true" 2
- 1
- You must specify the
openshift-operators-redhat
namespace. To prevent possible conflicts with metrics, you should configure the Prometheus Cluster Monitoring stack to scrape metrics from theopenshift-operators-redhat
namespace and not theopenshift-operators
namespace. Theopenshift-operators
namespace might contain community Operators, which are untrusted and could publish a metric with the same name as an OpenShift Container Platform metric, which would cause conflicts. - 2
- String. You must specify this label as shown to ensure that cluster monitoring scrapes the
openshift-operators-redhat
namespace.
Create the namespace:
$ oc create -f <file-name>.yaml
For example:
$ oc create -f eo-namespace.yaml
Create a namespace for the Red Hat OpenShift Logging Operator:
Create a namespace object YAML file (for example,
olo-namespace.yaml
) for the Red Hat OpenShift Logging Operator:apiVersion: v1 kind: Namespace metadata: name: openshift-logging annotations: openshift.io/node-selector: "" labels: openshift.io/cluster-monitoring: "true"
Create the namespace:
$ oc create -f <file-name>.yaml
For example:
$ oc create -f olo-namespace.yaml
Install the OpenShift Elasticsearch Operator by creating the following objects:
Create an Operator Group object YAML file (for example,
eo-og.yaml
) for the OpenShift Elasticsearch Operator:apiVersion: operators.coreos.com/v1 kind: OperatorGroup metadata: name: openshift-operators-redhat namespace: openshift-operators-redhat 1 spec: {}
- 1
- You must specify the
openshift-operators-redhat
namespace.
Create an Operator Group object:
$ oc create -f <file-name>.yaml
For example:
$ oc create -f eo-og.yaml
Create a Subscription object YAML file (for example,
eo-sub.yaml
) to subscribe a namespace to the OpenShift Elasticsearch Operator.Example Subscription
apiVersion: operators.coreos.com/v1alpha1 kind: Subscription metadata: name: "elasticsearch-operator" namespace: "openshift-operators-redhat" 1 spec: channel: "stable-5.1" 2 installPlanApproval: "Automatic" 3 source: "redhat-operators" 4 sourceNamespace: "openshift-marketplace" name: "elasticsearch-operator"
- 1
- You must specify the
openshift-operators-redhat
namespace. - 2
- Specify
stable
, orstable-5.<x>
as the channel. See the following note. - 3
Automatic
allows the Operator Lifecycle Manager (OLM) to automatically update the Operator when a new version is available.Manual
requires a user with appropriate credentials to approve the Operator update.- 4
- Specify
redhat-operators
. If your OpenShift Container Platform cluster is installed on a restricted network, also known as a disconnected cluster, specify the name of the CatalogSource object created when you configured the Operator Lifecycle Manager (OLM).
NoteSpecifying
stable
installs the current version of the latest stable release. Usingstable
withinstallPlanApproval: "Automatic"
, will automatically upgrade your operators to the latest stable major and minor release.Specifying
stable-5.<x>
installs the current minor version of a specific major release. Usingstable-5.<x>
withinstallPlanApproval: "Automatic"
, will automatically upgrade your operators to the latest stable minor release within the major release you specify withx
.Create the Subscription object:
$ oc create -f <file-name>.yaml
For example:
$ oc create -f eo-sub.yaml
The OpenShift Elasticsearch Operator is installed to the
openshift-operators-redhat
namespace and copied to each project in the cluster.Verify the Operator installation:
$ oc get csv --all-namespaces
Example output
NAMESPACE NAME DISPLAY VERSION REPLACES PHASE default elasticsearch-operator.5.1.0-202007012112.p0 OpenShift Elasticsearch Operator 5.1.0-202007012112.p0 Succeeded kube-node-lease elasticsearch-operator.5.1.0-202007012112.p0 OpenShift Elasticsearch Operator 5.1.0-202007012112.p0 Succeeded kube-public elasticsearch-operator.5.1.0-202007012112.p0 OpenShift Elasticsearch Operator 5.1.0-202007012112.p0 Succeeded kube-system elasticsearch-operator.5.1.0-202007012112.p0 OpenShift Elasticsearch Operator 5.1.0-202007012112.p0 Succeeded openshift-apiserver-operator elasticsearch-operator.5.1.0-202007012112.p0 OpenShift Elasticsearch Operator 5.1.0-202007012112.p0 Succeeded openshift-apiserver elasticsearch-operator.5.1.0-202007012112.p0 OpenShift Elasticsearch Operator 5.1.0-202007012112.p0 Succeeded openshift-authentication-operator elasticsearch-operator.5.1.0-202007012112.p0 OpenShift Elasticsearch Operator 5.1.0-202007012112.p0 Succeeded openshift-authentication elasticsearch-operator.5.1.0-202007012112.p0 OpenShift Elasticsearch Operator 5.1.0-202007012112.p0 Succeeded ...
There should be an OpenShift Elasticsearch Operator in each namespace. The version number might be different than shown.
Install the Red Hat OpenShift Logging Operator by creating the following objects:
Create an Operator Group object YAML file (for example,
olo-og.yaml
) for the Red Hat OpenShift Logging Operator:apiVersion: operators.coreos.com/v1 kind: OperatorGroup metadata: name: cluster-logging namespace: openshift-logging 1 spec: targetNamespaces: - openshift-logging 2
Create the OperatorGroup object:
$ oc create -f <file-name>.yaml
For example:
$ oc create -f olo-og.yaml
Create a Subscription object YAML file (for example,
olo-sub.yaml
) to subscribe a namespace to the Red Hat OpenShift Logging Operator.apiVersion: operators.coreos.com/v1alpha1 kind: Subscription metadata: name: cluster-logging namespace: openshift-logging 1 spec: channel: "stable" 2 name: cluster-logging source: redhat-operators 3 sourceNamespace: openshift-marketplace
- 1
- You must specify the
openshift-logging
namespace. - 2
- Specify
stable
, orstable-5.<x>
as the channel. - 3
- Specify
redhat-operators
. If your OpenShift Container Platform cluster is installed on a restricted network, also known as a disconnected cluster, specify the name of the CatalogSource object you created when you configured the Operator Lifecycle Manager (OLM).
$ oc create -f <file-name>.yaml
For example:
$ oc create -f olo-sub.yaml
The Red Hat OpenShift Logging Operator is installed to the
openshift-logging
namespace.Verify the Operator installation.
There should be a Red Hat OpenShift Logging Operator in the
openshift-logging
namespace. The Version number might be different than shown.$ oc get csv -n openshift-logging
Example output
NAMESPACE NAME DISPLAY VERSION REPLACES PHASE ... openshift-logging clusterlogging.5.1.0-202007012112.p0 OpenShift Logging 5.1.0-202007012112.p0 Succeeded ...
Create an OpenShift Logging instance:
Create an instance object YAML file (for example,
olo-instance.yaml
) for the Red Hat OpenShift Logging Operator:NoteThis default OpenShift Logging configuration should support a wide array of environments. Review the topics on tuning and configuring logging subsystem components for information on modifications you can make to your OpenShift Logging cluster.
apiVersion: "logging.openshift.io/v1" kind: "ClusterLogging" metadata: name: "instance" 1 namespace: "openshift-logging" spec: managementState: "Managed" 2 logStore: type: "elasticsearch" 3 retentionPolicy: 4 application: maxAge: 1d infra: maxAge: 7d audit: maxAge: 7d elasticsearch: nodeCount: 3 5 storage: storageClassName: "<storage-class-name>" 6 size: 200G resources: 7 limits: memory: "16Gi" requests: memory: "16Gi" proxy: 8 resources: limits: memory: 256Mi requests: memory: 256Mi redundancyPolicy: "SingleRedundancy" visualization: type: "kibana" 9 kibana: replicas: 1 collection: logs: type: "fluentd" 10 fluentd: {}
- 1
- The name must be
instance
. - 2
- The OpenShift Logging management state. In some cases, if you change the OpenShift Logging defaults, you must set this to
Unmanaged
. However, an unmanaged deployment does not receive updates until OpenShift Logging is placed back into a managed state. Placing a deployment back into a managed state might revert any modifications you made. - 3
- Settings for configuring Elasticsearch. Using the custom resource (CR), you can configure shard replication policy and persistent storage.
- 4
- Specify the length of time that Elasticsearch should retain each log source. Enter an integer and a time designation: weeks(w), hours(h/H), minutes(m) and seconds(s). For example,
7d
for seven days. Logs older than themaxAge
are deleted. You must specify a retention policy for each log source or the Elasticsearch indices will not be created for that source. - 5
- Specify the number of Elasticsearch nodes. See the note that follows this list.
- 6
- Enter the name of an existing storage class for Elasticsearch storage. For best performance, specify a storage class that allocates block storage. If you do not specify a storage class, OpenShift Container Platform deploys OpenShift Logging with ephemeral storage only.
- 7
- Specify the CPU and memory requests for Elasticsearch as needed. If you leave these values blank, the OpenShift Elasticsearch Operator sets default values that are sufficient for most deployments. The default values are
16Gi
for the memory request and1
for the CPU request. - 8
- Specify the CPU and memory requests for the Elasticsearch proxy as needed. If you leave these values blank, the OpenShift Elasticsearch Operator sets default values that should be sufficient for most deployments. The default values are
256Mi
for the memory request and100m
for the CPU request. - 9
- Settings for configuring Kibana. Using the CR, you can scale Kibana for redundancy and configure the CPU and memory for your Kibana pods. For more information, see Configuring the log visualizer.
- 10
- Settings for configuring Fluentd. Using the CR, you can configure Fluentd CPU and memory limits. For more information, see Configuring Fluentd.
NoteThe maximum number of Elasticsearch control plane nodes is three. If you specify a
nodeCount
greater than3
, OpenShift Container Platform creates three Elasticsearch nodes that are Master-eligible nodes, with the master, client, and data roles. The additional Elasticsearch nodes are created as Data-only nodes, using client and data roles. Control plane nodes perform cluster-wide actions such as creating or deleting an index, shard allocation, and tracking nodes. Data nodes hold the shards and perform data-related operations such as CRUD, search, and aggregations. Data-related operations are I/O-, memory-, and CPU-intensive. It is important to monitor these resources and to add more Data nodes if the current nodes are overloaded.For example, if
nodeCount=4
, the following nodes are created:$ oc get deployment
Example output
cluster-logging-operator 1/1 1 1 18h elasticsearch-cd-x6kdekli-1 1/1 1 0 6m54s elasticsearch-cdm-x6kdekli-1 1/1 1 1 18h elasticsearch-cdm-x6kdekli-2 1/1 1 0 6m49s elasticsearch-cdm-x6kdekli-3 1/1 1 0 6m44s
The number of primary shards for the index templates is equal to the number of Elasticsearch data nodes.
Create the instance:
$ oc create -f <file-name>.yaml
For example:
$ oc create -f olo-instance.yaml
This creates the logging subsystem components, the
Elasticsearch
custom resource and components, and the Kibana interface.
Verify the installation by listing the pods in the openshift-logging project.
You should see several pods for components of the Logging subsystem, similar to the following list:
$ oc get pods -n openshift-logging
Example output
NAME READY STATUS RESTARTS AGE cluster-logging-operator-66f77ffccb-ppzbg 1/1 Running 0 7m elasticsearch-cdm-ftuhduuw-1-ffc4b9566-q6bhp 2/2 Running 0 2m40s elasticsearch-cdm-ftuhduuw-2-7b4994dbfc-rd2gc 2/2 Running 0 2m36s elasticsearch-cdm-ftuhduuw-3-84b5ff7ff8-gqnm2 2/2 Running 0 2m4s collector-587vb 1/1 Running 0 2m26s collector-7mpb9 1/1 Running 0 2m30s collector-flm6j 1/1 Running 0 2m33s collector-gn4rn 1/1 Running 0 2m26s collector-nlgb6 1/1 Running 0 2m30s collector-snpkt 1/1 Running 0 2m28s kibana-d6d5668c5-rppqm 2/2 Running 0 2m39s
3.4. Post-installation tasks
If you plan to use Kibana, you must manually create your Kibana index patterns and visualizations to explore and visualize data in Kibana.
If your cluster network provider enforces network isolation, allow network traffic between the projects that contain the logging subsystem Operators.
3.4.1. Defining Kibana index patterns
An index pattern defines the Elasticsearch indices that you want to visualize. To explore and visualize data in Kibana, you must create an index pattern.
Prerequisites
A user must have the
cluster-admin
role, thecluster-reader
role, or both roles to view the infra and audit indices in Kibana. The defaultkubeadmin
user has proper permissions to view these indices.If you can view the pods and logs in the
default
,kube-
andopenshift-
projects, you should be able to access these indices. You can use the following command to check if the current user has appropriate permissions:$ oc auth can-i get pods/log -n <project>
Example output
yes
NoteThe audit logs are not stored in the internal OpenShift Container Platform Elasticsearch instance by default. To view the audit logs in Kibana, you must use the Log Forwarding API to configure a pipeline that uses the
default
output for audit logs.- Elasticsearch documents must be indexed before you can create index patterns. This is done automatically, but it might take a few minutes in a new or updated cluster.
Procedure
To define index patterns and create visualizations in Kibana:
- In the OpenShift Container Platform console, click the Application Launcher and select Logging.
Create your Kibana index patterns by clicking Management
Index Patterns Create index pattern: -
Each user must manually create index patterns when logging into Kibana the first time to see logs for their projects. Users must create an index pattern named
app
and use the@timestamp
time field to view their container logs. -
Each admin user must create index patterns when logged into Kibana the first time for the
app
,infra
, andaudit
indices using the@timestamp
time field.
-
Each user must manually create index patterns when logging into Kibana the first time to see logs for their projects. Users must create an index pattern named
- Create Kibana Visualizations from the new index patterns.
3.4.2. Allowing traffic between projects when network isolation is enabled
Your cluster network provider might enforce network isolation. If so, you must allow network traffic between the projects that contain the operators deployed by OpenShift Logging.
Network isolation blocks network traffic between pods or services that are in different projects. The logging subsystem installs the OpenShift Elasticsearch Operator in the openshift-operators-redhat
project and the Red Hat OpenShift Logging Operator in the openshift-logging
project. Therefore, you must allow traffic between these two projects.
OpenShift Container Platform offers two supported choices for the default Container Network Interface (CNI) network provider, OpenShift SDN and OVN-Kubernetes. These two providers implement various network isolation policies.
OpenShift SDN has three modes:
- network policy
- This is the default mode. If no policy is defined, it allows all traffic. However, if a user defines a policy, they typically start by denying all traffic and then adding exceptions. This process might break applications that are running in different projects. Therefore, explicitly configure the policy to allow traffic to egress from one logging-related project to the other.
- multitenant
- This mode enforces network isolation. You must join the two logging-related projects to allow traffic between them.
- subnet
- This mode allows all traffic. It does not enforce network isolation. No action is needed.
OVN-Kubernetes always uses a network policy. Therefore, as with OpenShift SDN, you must configure the policy to allow traffic to egress from one logging-related project to the other.
Procedure
If you are using OpenShift SDN in multitenant mode, join the two projects. For example:
$ oc adm pod-network join-projects --to=openshift-operators-redhat openshift-logging
Otherwise, for OpenShift SDN in network policy mode and OVN-Kubernetes, perform the following actions:
Set a label on the
openshift-operators-redhat
namespace. For example:$ oc label namespace openshift-operators-redhat project=openshift-operators-redhat
Create a network policy object in the
openshift-logging
namespace that allows ingress from theopenshift-operators-redhat
,openshift-monitoring
andopenshift-ingress
projects to the openshift-logging project. For example:apiVersion: networking.k8s.io/v1 kind: NetworkPolicy metadata: name: allow-from-openshift-monitoring-ingress-operators-redhat spec: ingress: - from: - podSelector: {} - from: - namespaceSelector: matchLabels: project: "openshift-operators-redhat" - from: - namespaceSelector: matchLabels: name: "openshift-monitoring" - from: - namespaceSelector: matchLabels: network.openshift.io/policy-group: ingress podSelector: {} policyTypes: - Ingress