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Chapter 7. Post-installation network configuration
After installing OpenShift Container Platform, you can further expand and customize your network to your requirements.
7.1. Cluster Network Operator configuration
The configuration for the cluster network is specified as part of the Cluster Network Operator (CNO) configuration and stored in a custom resource (CR) object that is named cluster
. The CR specifies the fields for the Network
API in the operator.openshift.io
API group.
The CNO configuration inherits the following fields during cluster installation from the Network
API in the Network.config.openshift.io
API group and these fields cannot be changed:
clusterNetwork
- IP address pools from which pod IP addresses are allocated.
serviceNetwork
- IP address pool for services.
defaultNetwork.type
- Cluster network provider, such as OpenShift SDN or OVN-Kubernetes.
After cluster installation, you cannot modify the fields listed in the previous section.
7.2. Enabling the cluster-wide proxy
The Proxy
object is used to manage the cluster-wide egress proxy. When a cluster is installed or upgraded without the proxy configured, a Proxy
object is still generated but it will have a nil spec
. For example:
apiVersion: config.openshift.io/v1 kind: Proxy metadata: name: cluster spec: trustedCA: name: "" status:
A cluster administrator can configure the proxy for OpenShift Container Platform by modifying this cluster
Proxy
object.
Only the Proxy
object named cluster
is supported, and no additional proxies can be created.
Prerequisites
- Cluster administrator permissions
-
OpenShift Container Platform
oc
CLI tool installed
Procedure
Create a config map that contains any additional CA certificates required for proxying HTTPS connections.
NoteYou can skip this step if the proxy’s identity certificate is signed by an authority from the RHCOS trust bundle.
Create a file called
user-ca-bundle.yaml
with the following contents, and provide the values of your PEM-encoded certificates:apiVersion: v1 data: ca-bundle.crt: | 1 <MY_PEM_ENCODED_CERTS> 2 kind: ConfigMap metadata: name: user-ca-bundle 3 namespace: openshift-config 4
Create the config map from this file:
$ oc create -f user-ca-bundle.yaml
Use the
oc edit
command to modify theProxy
object:$ oc edit proxy/cluster
Configure the necessary fields for the proxy:
apiVersion: config.openshift.io/v1 kind: Proxy metadata: name: cluster spec: httpProxy: http://<username>:<pswd>@<ip>:<port> 1 httpsProxy: https://<username>:<pswd>@<ip>:<port> 2 noProxy: example.com 3 readinessEndpoints: - http://www.google.com 4 - https://www.google.com trustedCA: name: user-ca-bundle 5
- 1
- A proxy URL to use for creating HTTP connections outside the cluster. The URL scheme must be
http
. - 2
- A proxy URL to use for creating HTTPS connections outside the cluster. The URL scheme must be either
http
orhttps
. Specify a URL for the proxy that supports the URL scheme. For example, most proxies will report an error if they are configured to usehttps
but they only supporthttp
. This failure message may not propagate to the logs and can appear to be a network connection failure instead. If using a proxy that listens forhttps
connections from the cluster, you may need to configure the cluster to accept the CAs and certificates that the proxy uses. - 3
- A comma-separated list of destination domain names, domains, IP addresses or other network CIDRs to exclude proxying.
Preface a domain with
.
to match subdomains only. For example,.y.com
matchesx.y.com
, but noty.com
. Use*
to bypass proxy for all destinations. If you scale up workers that are not included in the network defined by thenetworking.machineNetwork[].cidr
field from the installation configuration, you must add them to this list to prevent connection issues.This field is ignored if neither the
httpProxy
orhttpsProxy
fields are set. - 4
- One or more URLs external to the cluster to use to perform a readiness check before writing the
httpProxy
andhttpsProxy
values to status. - 5
- A reference to the config map in the
openshift-config
namespace that contains additional CA certificates required for proxying HTTPS connections. Note that the config map must already exist before referencing it here. This field is required unless the proxy’s identity certificate is signed by an authority from the RHCOS trust bundle.
- Save the file to apply the changes.
7.3. Setting DNS to private
After you deploy a cluster, you can modify its DNS to use only a private zone.
Procedure
Review the
DNS
custom resource for your cluster:$ oc get dnses.config.openshift.io/cluster -o yaml
Example output
apiVersion: config.openshift.io/v1 kind: DNS metadata: creationTimestamp: "2019-10-25T18:27:09Z" generation: 2 name: cluster resourceVersion: "37966" selfLink: /apis/config.openshift.io/v1/dnses/cluster uid: 0e714746-f755-11f9-9cb1-02ff55d8f976 spec: baseDomain: <base_domain> privateZone: tags: Name: <infrastructure_id>-int kubernetes.io/cluster/<infrastructure_id>: owned publicZone: id: Z2XXXXXXXXXXA4 status: {}
Note that the
spec
section contains both a private and a public zone.Patch the
DNS
custom resource to remove the public zone:$ oc patch dnses.config.openshift.io/cluster --type=merge --patch='{"spec": {"publicZone": null}}' dns.config.openshift.io/cluster patched
Because the Ingress Controller consults the
DNS
definition when it createsIngress
objects, when you create or modifyIngress
objects, only private records are created.ImportantDNS records for the existing Ingress objects are not modified when you remove the public zone.
Optional: Review the
DNS
custom resource for your cluster and confirm that the public zone was removed:$ oc get dnses.config.openshift.io/cluster -o yaml
Example output
apiVersion: config.openshift.io/v1 kind: DNS metadata: creationTimestamp: "2019-10-25T18:27:09Z" generation: 2 name: cluster resourceVersion: "37966" selfLink: /apis/config.openshift.io/v1/dnses/cluster uid: 0e714746-f755-11f9-9cb1-02ff55d8f976 spec: baseDomain: <base_domain> privateZone: tags: Name: <infrastructure_id>-int kubernetes.io/cluster/<infrastructure_id>-wfpg4: owned status: {}
7.4. Configuring ingress cluster traffic
OpenShift Container Platform provides the following methods for communicating from outside the cluster with services running in the cluster:
- If you have HTTP/HTTPS, use an Ingress Controller.
- If you have a TLS-encrypted protocol other than HTTPS, such as TLS with the SNI header, use an Ingress Controller.
- Otherwise, use a load balancer, an external IP, or a node port.
Method | Purpose |
---|---|
Allows access to HTTP/HTTPS traffic and TLS-encrypted protocols other than HTTPS, such as TLS with the SNI header. | |
Automatically assign an external IP by using a load balancer service | Allows traffic to non-standard ports through an IP address assigned from a pool. |
Allows traffic to non-standard ports through a specific IP address. | |
Expose a service on all nodes in the cluster. |
7.5. Configuring the node port service range
As a cluster administrator, you can expand the available node port range. If your cluster uses of a large number of node ports, you might need to increase the number of available ports.
The default port range is 30000-32767
. You can never reduce the port range, even if you first expand it beyond the default range.
7.5.1. Prerequisites
-
Your cluster infrastructure must allow access to the ports that you specify within the expanded range. For example, if you expand the node port range to
30000-32900
, the inclusive port range of32768-32900
must be allowed by your firewall or packet filtering configuration.
7.5.1.1. Expanding the node port range
You can expand the node port range for the cluster.
Prerequisites
-
Install the OpenShift CLI (
oc
). -
Log in to the cluster with a user with
cluster-admin
privileges.
Procedure
To expand the node port range, enter the following command. Replace
<port>
with the largest port number in the new range.$ oc patch network.config.openshift.io cluster --type=merge -p \ '{ "spec": { "serviceNodePortRange": "30000-<port>" } }'
TipYou can alternatively apply the following YAML to update the node port range:
apiVersion: config.openshift.io/v1 kind: Network metadata: name: cluster spec: serviceNodePortRange: "30000-<port>"
Example output
network.config.openshift.io/cluster patched
To confirm that the configuration is active, enter the following command. It can take several minutes for the update to apply.
$ oc get configmaps -n openshift-kube-apiserver config \ -o jsonpath="{.data['config\.yaml']}" | \ grep -Eo '"service-node-port-range":["[[:digit:]]+-[[:digit:]]+"]'
Example output
"service-node-port-range":["30000-33000"]
7.6. Configuring network policy
As a cluster administrator or project administrator, you can configure network policies for a project.
7.6.1. About network policy
In a cluster using a Kubernetes Container Network Interface (CNI) plugin that supports Kubernetes network policy, network isolation is controlled entirely by NetworkPolicy
objects.
In OpenShift Container Platform 4.10, OpenShift SDN supports using network policy in its default network isolation mode.
The OpenShift SDN cluster network provider now supports the egress network policy as specified by the egress
field.
Network policy does not apply to the host network namespace. Pods with host networking enabled are unaffected by network policy rules. However, pods connecting to the host-networked pods might be affected by the network policy rules.
Network policies cannot block traffic from localhost or from their resident nodes.
By default, all pods in a project are accessible from other pods and network endpoints. To isolate one or more pods in a project, you can create NetworkPolicy
objects in that project to indicate the allowed incoming connections. Project administrators can create and delete NetworkPolicy
objects within their own project.
If a pod is matched by selectors in one or more NetworkPolicy
objects, then the pod will accept only connections that are allowed by at least one of those NetworkPolicy
objects. A pod that is not selected by any NetworkPolicy
objects is fully accessible.
A network policy applies to only the TCP, UDP, and SCTP protocols. Other protocols are not affected.
The following example NetworkPolicy
objects demonstrate supporting different scenarios:
Deny all traffic:
To make a project deny by default, add a
NetworkPolicy
object that matches all pods but accepts no traffic:kind: NetworkPolicy apiVersion: networking.k8s.io/v1 metadata: name: deny-by-default spec: podSelector: {} ingress: []
Only allow connections from the OpenShift Container Platform Ingress Controller:
To make a project allow only connections from the OpenShift Container Platform Ingress Controller, add the following
NetworkPolicy
object.apiVersion: networking.k8s.io/v1 kind: NetworkPolicy metadata: name: allow-from-openshift-ingress spec: ingress: - from: - namespaceSelector: matchLabels: network.openshift.io/policy-group: ingress podSelector: {} policyTypes: - Ingress
Only accept connections from pods within a project:
To make pods accept connections from other pods in the same project, but reject all other connections from pods in other projects, add the following
NetworkPolicy
object:kind: NetworkPolicy apiVersion: networking.k8s.io/v1 metadata: name: allow-same-namespace spec: podSelector: {} ingress: - from: - podSelector: {}
Only allow HTTP and HTTPS traffic based on pod labels:
To enable only HTTP and HTTPS access to the pods with a specific label (
role=frontend
in following example), add aNetworkPolicy
object similar to the following:kind: NetworkPolicy apiVersion: networking.k8s.io/v1 metadata: name: allow-http-and-https spec: podSelector: matchLabels: role: frontend ingress: - ports: - protocol: TCP port: 80 - protocol: TCP port: 443
Accept connections by using both namespace and pod selectors:
To match network traffic by combining namespace and pod selectors, you can use a
NetworkPolicy
object similar to the following:kind: NetworkPolicy apiVersion: networking.k8s.io/v1 metadata: name: allow-pod-and-namespace-both spec: podSelector: matchLabels: name: test-pods ingress: - from: - namespaceSelector: matchLabels: project: project_name podSelector: matchLabels: name: test-pods
NetworkPolicy
objects are additive, which means you can combine multiple NetworkPolicy
objects together to satisfy complex network requirements.
For example, for the NetworkPolicy
objects defined in previous samples, you can define both allow-same-namespace
and allow-http-and-https
policies within the same project. Thus allowing the pods with the label role=frontend
, to accept any connection allowed by each policy. That is, connections on any port from pods in the same namespace, and connections on ports 80
and 443
from pods in any namespace.
7.6.2. Example NetworkPolicy object
The following annotates an example NetworkPolicy object:
kind: NetworkPolicy apiVersion: networking.k8s.io/v1 metadata: name: allow-27107 1 spec: podSelector: 2 matchLabels: app: mongodb ingress: - from: - podSelector: 3 matchLabels: app: app ports: 4 - protocol: TCP port: 27017
- 1
- The name of the NetworkPolicy object.
- 2
- A selector that describes the pods to which the policy applies. The policy object can only select pods in the project that defines the NetworkPolicy object.
- 3
- A selector that matches the pods from which the policy object allows ingress traffic. The selector matches pods in the same namespace as the NetworkPolicy.
- 4
- A list of one or more destination ports on which to accept traffic.
7.6.3. Creating a network policy
To define granular rules describing ingress or egress network traffic allowed for namespaces in your cluster, you can create a network policy.
If you log in with a user with the cluster-admin
role, then you can create a network policy in any namespace in the cluster.
Prerequisites
-
Your cluster uses a cluster network provider that supports
NetworkPolicy
objects, such as the OpenShift SDN network provider withmode: NetworkPolicy
set. This mode is the default for OpenShift SDN. -
You installed the OpenShift CLI (
oc
). -
You are logged in to the cluster with a user with
admin
privileges. - You are working in the namespace that the network policy applies to.
Procedure
Create a policy rule:
Create a
<policy_name>.yaml
file:$ touch <policy_name>.yaml
where:
<policy_name>
- Specifies the network policy file name.
Define a network policy in the file that you just created, such as in the following examples:
Deny ingress from all pods in all namespaces
kind: NetworkPolicy apiVersion: networking.k8s.io/v1 metadata: name: deny-by-default spec: podSelector: ingress: []
.Allow ingress from all pods in the same namespace
kind: NetworkPolicy apiVersion: networking.k8s.io/v1 metadata: name: allow-same-namespace spec: podSelector: ingress: - from: - podSelector: {}
To create the network policy object, enter the following command:
$ oc apply -f <policy_name>.yaml -n <namespace>
where:
<policy_name>
- Specifies the network policy file name.
<namespace>
- Optional: Specifies the namespace if the object is defined in a different namespace than the current namespace.
Example output
networkpolicy.networking.k8s.io/default-deny created
If you log in to the web console with cluster-admin
privileges, you have a choice of creating a network policy in any namespace in the cluster directly in YAML or from a form in the web console.
7.6.4. Configuring multitenant isolation by using network policy
You can configure your project to isolate it from pods and services in other project namespaces.
Prerequisites
-
Your cluster uses a cluster network provider that supports
NetworkPolicy
objects, such as the OpenShift SDN network provider withmode: NetworkPolicy
set. This mode is the default for OpenShift SDN. -
You installed the OpenShift CLI (
oc
). -
You are logged in to the cluster with a user with
admin
privileges.
Procedure
Create the following
NetworkPolicy
objects:A policy named
allow-from-openshift-ingress
.$ cat << EOF| oc create -f - apiVersion: networking.k8s.io/v1 kind: NetworkPolicy metadata: name: allow-from-openshift-ingress spec: ingress: - from: - namespaceSelector: matchLabels: policy-group.network.openshift.io/ingress: "" podSelector: {} policyTypes: - Ingress EOF
Notepolicy-group.network.openshift.io/ingress: ""
is the preferred namespace selector label for OpenShift SDN. You can use thenetwork.openshift.io/policy-group: ingress
namespace selector label, but this is a legacy label.A policy named
allow-from-openshift-monitoring
:$ cat << EOF| oc create -f - apiVersion: networking.k8s.io/v1 kind: NetworkPolicy metadata: name: allow-from-openshift-monitoring spec: ingress: - from: - namespaceSelector: matchLabels: network.openshift.io/policy-group: monitoring podSelector: {} policyTypes: - Ingress EOF
A policy named
allow-same-namespace
:$ cat << EOF| oc create -f - kind: NetworkPolicy apiVersion: networking.k8s.io/v1 metadata: name: allow-same-namespace spec: podSelector: ingress: - from: - podSelector: {} EOF
A policy named
allow-from-kube-apiserver-operator
:$ cat << EOF| oc create -f - apiVersion: networking.k8s.io/v1 kind: NetworkPolicy metadata: name: allow-from-kube-apiserver-operator spec: ingress: - from: - namespaceSelector: matchLabels: kubernetes.io/metadata.name: openshift-kube-apiserver-operator podSelector: matchLabels: app: kube-apiserver-operator policyTypes: - Ingress EOF
For more details, see New
kube-apiserver-operator
webhook controller validating health of webhook.
Optional: To confirm that the network policies exist in your current project, enter the following command:
$ oc describe networkpolicy
Example output
Name: allow-from-openshift-ingress Namespace: example1 Created on: 2020-06-09 00:28:17 -0400 EDT Labels: <none> Annotations: <none> Spec: PodSelector: <none> (Allowing the specific traffic to all pods in this namespace) Allowing ingress traffic: To Port: <any> (traffic allowed to all ports) From: NamespaceSelector: network.openshift.io/policy-group: ingress Not affecting egress traffic Policy Types: Ingress Name: allow-from-openshift-monitoring Namespace: example1 Created on: 2020-06-09 00:29:57 -0400 EDT Labels: <none> Annotations: <none> Spec: PodSelector: <none> (Allowing the specific traffic to all pods in this namespace) Allowing ingress traffic: To Port: <any> (traffic allowed to all ports) From: NamespaceSelector: network.openshift.io/policy-group: monitoring Not affecting egress traffic Policy Types: Ingress
7.6.5. Creating default network policies for a new project
As a cluster administrator, you can modify the new project template to automatically include NetworkPolicy
objects when you create a new project.
7.6.6. Modifying the template for new projects
As a cluster administrator, you can modify the default project template so that new projects are created using your custom requirements.
To create your own custom project template:
Procedure
-
Log in as a user with
cluster-admin
privileges. Generate the default project template:
$ oc adm create-bootstrap-project-template -o yaml > template.yaml
-
Use a text editor to modify the generated
template.yaml
file by adding objects or modifying existing objects. The project template must be created in the
openshift-config
namespace. Load your modified template:$ oc create -f template.yaml -n openshift-config
Edit the project configuration resource using the web console or CLI.
Using the web console:
-
Navigate to the Administration
Cluster Settings page. - Click Configuration to view all configuration resources.
- Find the entry for Project and click Edit YAML.
-
Navigate to the Administration
Using the CLI:
Edit the
project.config.openshift.io/cluster
resource:$ oc edit project.config.openshift.io/cluster
Update the
spec
section to include theprojectRequestTemplate
andname
parameters, and set the name of your uploaded project template. The default name isproject-request
.Project configuration resource with custom project template
apiVersion: config.openshift.io/v1 kind: Project metadata: ... spec: projectRequestTemplate: name: <template_name>
- After you save your changes, create a new project to verify that your changes were successfully applied.
7.6.6.1. Adding network policies to the new project template
As a cluster administrator, you can add network policies to the default template for new projects. OpenShift Container Platform will automatically create all the NetworkPolicy
objects specified in the template in the project.
Prerequisites
-
Your cluster uses a default CNI network provider that supports
NetworkPolicy
objects, such as the OpenShift SDN network provider withmode: NetworkPolicy
set. This mode is the default for OpenShift SDN. -
You installed the OpenShift CLI (
oc
). -
You must log in to the cluster with a user with
cluster-admin
privileges. - You must have created a custom default project template for new projects.
Procedure
Edit the default template for a new project by running the following command:
$ oc edit template <project_template> -n openshift-config
Replace
<project_template>
with the name of the default template that you configured for your cluster. The default template name isproject-request
.In the template, add each
NetworkPolicy
object as an element to theobjects
parameter. Theobjects
parameter accepts a collection of one or more objects.In the following example, the
objects
parameter collection includes severalNetworkPolicy
objects.objects: - apiVersion: networking.k8s.io/v1 kind: NetworkPolicy metadata: name: allow-from-same-namespace spec: podSelector: {} ingress: - from: - podSelector: {} - apiVersion: networking.k8s.io/v1 kind: NetworkPolicy metadata: name: allow-from-openshift-ingress spec: ingress: - from: - namespaceSelector: matchLabels: network.openshift.io/policy-group: ingress podSelector: {} policyTypes: - Ingress - apiVersion: networking.k8s.io/v1 kind: NetworkPolicy metadata: name: allow-from-kube-apiserver-operator spec: ingress: - from: - namespaceSelector: matchLabels: kubernetes.io/metadata.name: openshift-kube-apiserver-operator podSelector: matchLabels: app: kube-apiserver-operator policyTypes: - Ingress ...
Optional: Create a new project to confirm that your network policy objects are created successfully by running the following commands:
Create a new project:
$ oc new-project <project> 1
- 1
- Replace
<project>
with the name for the project you are creating.
Confirm that the network policy objects in the new project template exist in the new project:
$ oc get networkpolicy NAME POD-SELECTOR AGE allow-from-openshift-ingress <none> 7s allow-from-same-namespace <none> 7s
7.7. Supported configurations
The following configurations are supported for the current release of Red Hat OpenShift Service Mesh.
7.7.1. Supported platforms
The Red Hat OpenShift Service Mesh Operator supports multiple versions of the ServiceMeshControlPlane
resource. Version 2.4 Service Mesh control planes are supported on the following platform versions:
- Red Hat OpenShift Container Platform version 4.10 or later.
- Red Hat OpenShift Dedicated version 4.
- Azure Red Hat OpenShift (ARO) version 4.
- Red Hat OpenShift Service on AWS (ROSA).
7.7.2. Unsupported configurations
Explicitly unsupported cases include:
- OpenShift Online is not supported for Red Hat OpenShift Service Mesh.
- Red Hat OpenShift Service Mesh does not support the management of microservices outside the cluster where Service Mesh is running.
7.7.3. Supported network configurations
Red Hat OpenShift Service Mesh supports the following network configurations.
- OpenShift-SDN
- OVN-Kubernetes is available on all supported versions of OpenShift Container Platform.
- Third-Party Container Network Interface (CNI) plugins that have been certified on OpenShift Container Platform and passed Service Mesh conformance testing. See Certified OpenShift CNI Plug-ins for more information.
7.7.4. Supported configurations for Service Mesh
This release of Red Hat OpenShift Service Mesh is only available on OpenShift Container Platform x86_64, IBM Z, and IBM Power.
- IBM Z is only supported on OpenShift Container Platform 4.10 and later.
- IBM Power is only supported on OpenShift Container Platform 4.10 and later.
- Configurations where all Service Mesh components are contained within a single OpenShift Container Platform cluster.
- Configurations that do not integrate external services such as virtual machines.
-
Red Hat OpenShift Service Mesh does not support
EnvoyFilter
configuration except where explicitly documented.
7.7.5. Supported configurations for Kiali
- The Kiali console is only supported on the two most recent releases of the Google Chrome, Microsoft Edge, Mozilla Firefox, or Apple Safari browsers.
-
The
openshift
authentication strategy is the only supported authentication configuration when Kiali is deployed with Red Hat OpenShift Service Mesh (OSSM). Theopenshift
strategy controls access based on the individual’s role-based access control (RBAC) roles of the OpenShift Container Platform.
7.7.6. Supported configurations for Distributed Tracing
- Jaeger agent as a sidecar is the only supported configuration for Jaeger. Jaeger as a daemonset is not supported for multitenant installations or OpenShift Dedicated.
7.7.7. Supported WebAssembly module
- 3scale WebAssembly is the only provided WebAssembly module. You can create custom WebAssembly modules.
7.7.8. Operator overview
Red Hat OpenShift Service Mesh requires the following four Operators:
- OpenShift Elasticsearch - (Optional) Provides database storage for tracing and logging with the distributed tracing platform. It is based on the open source Elasticsearch project.
- Red Hat OpenShift distributed tracing platform - Provides distributed tracing to monitor and troubleshoot transactions in complex distributed systems. It is based on the open source Jaeger project.
- Kiali Operator provided by Red Hat - Provides observability for your service mesh. You can view configurations, monitor traffic, and analyze traces in a single console. It is based on the open source Kiali project.
-
Red Hat OpenShift Service Mesh - Allows you to connect, secure, control, and observe the microservices that comprise your applications. The Service Mesh Operator defines and monitors the
ServiceMeshControlPlane
resources that manage the deployment, updating, and deletion of the Service Mesh components. It is based on the open source Istio project.
Next steps
- Install Red Hat OpenShift Service Mesh in your OpenShift Container Platform environment.
7.8. Optimizing routing
The OpenShift Container Platform HAProxy router can be scaled or configured to optimize performance.
7.8.1. Baseline Ingress Controller (router) performance
The OpenShift Container Platform Ingress Controller, or router, is the ingress point for ingress traffic for applications and services that are configured using routes and ingresses.
When evaluating a single HAProxy router performance in terms of HTTP requests handled per second, the performance varies depending on many factors. In particular:
- HTTP keep-alive/close mode
- Route type
- TLS session resumption client support
- Number of concurrent connections per target route
- Number of target routes
- Back end server page size
- Underlying infrastructure (network/SDN solution, CPU, and so on)
While performance in your specific environment will vary, Red Hat lab tests on a public cloud instance of size 4 vCPU/16GB RAM. A single HAProxy router handling 100 routes terminated by backends serving 1kB static pages is able to handle the following number of transactions per second.
In HTTP keep-alive mode scenarios:
Encryption | LoadBalancerService | HostNetwork |
---|---|---|
none | 21515 | 29622 |
edge | 16743 | 22913 |
passthrough | 36786 | 53295 |
re-encrypt | 21583 | 25198 |
In HTTP close (no keep-alive) scenarios:
Encryption | LoadBalancerService | HostNetwork |
---|---|---|
none | 5719 | 8273 |
edge | 2729 | 4069 |
passthrough | 4121 | 5344 |
re-encrypt | 2320 | 2941 |
The default Ingress Controller configuration was used with the spec.tuningOptions.threadCount
field set to 4
. Two different endpoint publishing strategies were tested: Load Balancer Service and Host Network. TLS session resumption was used for encrypted routes. With HTTP keep-alive, a single HAProxy router is capable of saturating a 1 Gbit NIC at page sizes as small as 8 kB.
When running on bare metal with modern processors, you can expect roughly twice the performance of the public cloud instance above. This overhead is introduced by the virtualization layer in place on public clouds and holds mostly true for private cloud-based virtualization as well. The following table is a guide to how many applications to use behind the router:
Number of applications | Application type |
---|---|
5-10 | static file/web server or caching proxy |
100-1000 | applications generating dynamic content |
In general, HAProxy can support routes for up to 1000 applications, depending on the technology in use. Ingress Controller performance might be limited by the capabilities and performance of the applications behind it, such as language or static versus dynamic content.
Ingress, or router, sharding should be used to serve more routes towards applications and help horizontally scale the routing tier.
7.9. Post-installation RHOSP network configuration
You can configure some aspects of an OpenShift Container Platform on Red Hat OpenStack Platform (RHOSP) cluster after installation.
7.9.1. Configuring application access with floating IP addresses
After you install OpenShift Container Platform, configure Red Hat OpenStack Platform (RHOSP) to allow application network traffic.
You do not need to perform this procedure if you provided values for platform.openstack.apiFloatingIP
and platform.openstack.ingressFloatingIP
in the install-config.yaml
file, or os_api_fip
and os_ingress_fip
in the inventory.yaml
playbook, during installation. The floating IP addresses are already set.
Prerequisites
- OpenShift Container Platform cluster must be installed
- Floating IP addresses are enabled as described in the OpenShift Container Platform on RHOSP installation documentation.
Procedure
After you install the OpenShift Container Platform cluster, attach a floating IP address to the ingress port:
Show the port:
$ openstack port show <cluster_name>-<cluster_ID>-ingress-port
Attach the port to the IP address:
$ openstack floating ip set --port <ingress_port_ID> <apps_FIP>
Add a wildcard
A
record for*apps.
to your DNS file:*.apps.<cluster_name>.<base_domain> IN A <apps_FIP>
If you do not control the DNS server but want to enable application access for non-production purposes, you can add these hostnames to /etc/hosts
:
<apps_FIP> console-openshift-console.apps.<cluster name>.<base domain> <apps_FIP> integrated-oauth-server-openshift-authentication.apps.<cluster name>.<base domain> <apps_FIP> oauth-openshift.apps.<cluster name>.<base domain> <apps_FIP> prometheus-k8s-openshift-monitoring.apps.<cluster name>.<base domain> <apps_FIP> grafana-openshift-monitoring.apps.<cluster name>.<base domain> <apps_FIP> <app name>.apps.<cluster name>.<base domain>
7.9.2. Kuryr ports pools
A Kuryr ports pool maintains a number of ports on standby for pod creation.
Keeping ports on standby minimizes pod creation time. Without ports pools, Kuryr must explicitly request port creation or deletion whenever a pod is created or deleted.
The Neutron ports that Kuryr uses are created in subnets that are tied to namespaces. These pod ports are also added as subports to the primary port of OpenShift Container Platform cluster nodes.
Because Kuryr keeps each namespace in a separate subnet, a separate ports pool is maintained for each namespace-worker pair.
Prior to installing a cluster, you can set the following parameters in the cluster-network-03-config.yml
manifest file to configure ports pool behavior:
-
The
enablePortPoolsPrepopulation
parameter controls pool prepopulation, which forces Kuryr to add Neutron ports to the pools when the first pod that is configured to use the dedicated network for pods is created in a namespace. The default value isfalse
. -
The
poolMinPorts
parameter is the minimum number of free ports that are kept in the pool. The default value is1
. The
poolMaxPorts
parameter is the maximum number of free ports that are kept in the pool. A value of0
disables that upper bound. This is the default setting.If your OpenStack port quota is low, or you have a limited number of IP addresses on the pod network, consider setting this option to ensure that unneeded ports are deleted.
-
The
poolBatchPorts
parameter defines the maximum number of Neutron ports that can be created at once. The default value is3
.
7.9.3. Adjusting Kuryr ports pool settings in active deployments on RHOSP
You can use a custom resource (CR) to configure how Kuryr manages Red Hat OpenStack Platform (RHOSP) Neutron ports to control the speed and efficiency of pod creation on a deployed cluster.
Procedure
From a command line, open the Cluster Network Operator (CNO) CR for editing:
$ oc edit networks.operator.openshift.io cluster
Edit the settings to meet your requirements. The following file is provided as an example:
apiVersion: operator.openshift.io/v1 kind: Network metadata: name: cluster spec: clusterNetwork: - cidr: 10.128.0.0/14 hostPrefix: 23 serviceNetwork: - 172.30.0.0/16 defaultNetwork: type: Kuryr kuryrConfig: enablePortPoolsPrepopulation: false 1 poolMinPorts: 1 2 poolBatchPorts: 3 3 poolMaxPorts: 5 4
- 1
- Set
enablePortPoolsPrepopulation
totrue
to make Kuryr create Neutron ports when the first pod that is configured to use the dedicated network for pods is created in a namespace. This setting raises the Neutron ports quota but can reduce the time that is required to spawn pods. The default value isfalse
. - 2
- Kuryr creates new ports for a pool if the number of free ports in that pool is lower than the value of
poolMinPorts
. The default value is1
. - 3
poolBatchPorts
controls the number of new ports that are created if the number of free ports is lower than the value ofpoolMinPorts
. The default value is3
.- 4
- If the number of free ports in a pool is higher than the value of
poolMaxPorts
, Kuryr deletes them until the number matches that value. Setting the value to0
disables this upper bound, preventing pools from shrinking. The default value is0
.
- Save your changes and quit the text editor to commit your changes.
Modifying these options on a running cluster forces the kuryr-controller and kuryr-cni pods to restart. As a result, the creation of new pods and services will be delayed.
7.9.4. Enabling OVS hardware offloading
OVS hardware offloading is a Technology Preview feature only. Technology Preview features are not supported with Red Hat production service level agreements (SLAs) and might not be functionally complete. Red Hat does not recommend using them in production. These features provide early access to upcoming product features, enabling customers to test functionality and provide feedback during the development process.
For more information about the support scope of Red Hat Technology Preview features, see Technology Preview Features Support Scope.
For clusters that run on Red Hat OpenStack Platform (RHOSP), you can enable Open vSwitch (OVS) hardware offloading.
OVS is a multi-layer virtual switch that enables large-scale, multi-server network virtualization.
Prerequisites
- You installed a cluster on RHOSP that is configured for single-root input/output virtualization (SR-IOV).
- You installed the SR-IOV Network Operator on your cluster.
-
You created two
hw-offload
type virtual function (VF) interfaces on your cluster.
Procedure
From a command line, enter the following command to disable the admission webhook:
$ oc patch sriovoperatorconfig default --type=merge -n openshift-sriov-network-operator --patch '{ "spec": { "enableOperatorWebhook": false } }'
Create an
SriovNetworkNodePolicy
policy for the twohw-offload
type VF interfaces that are on your cluster:The first virtual function interface
apiVersion: sriovnetwork.openshift.io/v1 kind: SriovNetworkNodePolicy 1 metadata: name: "hwoffload9" namespace: openshift-sriov-network-operator spec: deviceType: netdevice isRdma: true nicSelector: pfNames: 2 - ens6 nodeSelector: feature.node.kubernetes.io/network-sriov.capable: 'true' numVfs: 1 priority: 99 resourceName: "hwoffload9"
The second virtual function interface
apiVersion: sriovnetwork.openshift.io/v1 kind: SriovNetworkNodePolicy 1 metadata: name: "hwoffload10" namespace: openshift-sriov-network-operator spec: deviceType: netdevice isRdma: true nicSelector: pfNames: 2 - ens5 nodeSelector: feature.node.kubernetes.io/network-sriov.capable: 'true' numVfs: 1 priority: 99 resourceName: "hwoffload10"
Create
NetworkAttachmentDefinition
resources for the two interfaces:A
NetworkAttachmentDefinition
resource for the first interfaceapiVersion: k8s.cni.cncf.io/v1 kind: NetworkAttachmentDefinition metadata: annotations: k8s.v1.cni.cncf.io/resourceName: openshift.io/hwoffload9 name: hwoffload9 namespace: default spec: config: '{ "cniVersion":"0.3.1", "name":"hwoffload9","type":"host-device","device":"ens6" }'
A
NetworkAttachmentDefinition
resource for the second interfaceapiVersion: k8s.cni.cncf.io/v1 kind: NetworkAttachmentDefinition metadata: annotations: k8s.v1.cni.cncf.io/resourceName: openshift.io/hwoffload10 name: hwoffload10 namespace: default spec: config: '{ "cniVersion":"0.3.1", "name":"hwoffload10","type":"host-device","device":"ens5" }'
Use the interfaces that you created with a pod. For example:
A pod that uses the two OVS offload interfaces
apiVersion: v1 kind: Pod metadata: name: dpdk-testpmd namespace: default annotations: irq-load-balancing.crio.io: disable cpu-quota.crio.io: disable k8s.v1.cni.cncf.io/networks: '[ { "name": "hwoffload9", "namespace": "default" }, { "name": "hwoffload10", "namespace": "default" } ]' spec: restartPolicy: Never containers: - name: dpdk-testpmd image: quay.io/krister/centos8_nfv-container-dpdk-testpmd:latest