Skip to content

redhat-cop/global-load-balancer-operator

Repository files navigation

Global Load Balancer Operator

build status Go Report Card GitHub go.mod Go version CRD Docs

The global-load-balancer-operator implements automation to program a global load balancer for applications deployed to multiple OpenShift clusters. This operator is designed to be deployed to a control cluster which will watch the load balanced clusters (controlled clusters). A global load balancer can be implemented as a DNS or a global IP anycast configuration. There are two main concepts (APIs) provided by this operator:

  1. GlobalDNSZone: represents the global load balancer provider and DNS zone in which the global record will be created.
  2. GlobalDNSRecord: represent a globally load balancer application with a DNS record and a set of end points to be load balanced.

GlobalDNSZone

The GlobalDNSZone CR allows you to configure a zone which will contain global load balanced records and the provider used to populate it. Here is an example of GlobalDNSZone:

apiVersion: redhatcop.redhat.io/v1alpha1
kind: GlobalDNSZone
metadata:
  name: external-dns-zone
spec:
  # Add fields here
  domain: global.myzone.io
  provider:
    externalDNS:
      annotations:
        type: global

Here is a table summarizing the supported DNS-based load balancer providers and their capabilities:

Provider Supports Health Checks Supports Multivalue LB Supports Latency LB Supports GeoProximity LB
External-dns no yes no no
Route53 yes yes(*) yes(*) yes(*)
Azure Traffic Manager (**) yes yes yes yes

(*) only if all controlled clusters run on AWS. (**) currently all controlled clusters must be on Azure.

Here is a table summarizing the supported Anycast-based load balancer providers and their capabilities:

Provider Supports Health Checks Supports TCP-session affinity Supports Latency LB Supports GeoProximity LB
Google Global Load Balancer (***) yes yes client connection are routed to the closer endpoint in terms of network hops up to a maximum of 100 connections per VM N/A

(***) currently all controlled clusters must be on Google Cloud.

GlobalDNSRecord

The GlobalDNSRecord CR allows you to specify the intention to create a global dns record. Here is an example

apiVersion: redhatcop.redhat.io/v1alpha1
kind: GlobalDNSRecord
metadata:
  name: hello-global-record
spec:
  name: hello.global.myzone.io
  endpoints:
  - clusterName: cluster1
    clusterCredentialRef:
      name: kubeconfig
      namespace: cluster1
    loadBalancerServiceRef:
      name: router-default
      namespace: openshift-ingress
  - clusterName: cluster2
    clusterCredentialRef:
      name: kubeconfig
      namespace: cluster2
    loadBalancerServiceRef:
      name: router-default
      namespace: openshift-ingress
  - clusterName: cluster3
    clusterCredentialRef:
      name: kubeconfig
      namespace: cluster3
    loadBalancerServiceRef:
      name: router-default
      namespace: openshift-ingress
  ttl: 60
  loadBalancingPolicy: Multivalue
  globalZoneRef:
    name: external-dns-zone
  healthCheck:
    failureThreshold: 3
    httpGet:
      host: hello.global.myzone.io
      httpHeaders:
        - name: ciao
          value: hello
      path: /readyz
      port: 80
      scheme: HTTP
    periodSeconds: 10
    successThreshold: 1
    timeoutSeconds: 1

The list of endpoints identifies the set of LoadBalancer type of services to watch on the remote clusters (at the moment only LoadBalancer services are supported). These are the LoadBalancer services created by the ingress controller on which the routers rely. Each entry of this list requires a reference to the loadbalancer service on the remote cluster and a reference to a local secret containing the credential to connect to the remote cluster.

This secret must contain one entry called kubeconfig with a kubeconfig file with a default context pointing to the remote cluster. The account used by the kubeconfig file (presumably a service account) will require at a minimum cluster-level permissions as described in this cluster role.

The globalZoneRef field refers to a local (same namespace) GlobalZone CR. The DNS record represented by this GlobalDNSRecord, will be created in the referenced zone.

ttl is the TTL of the crated DNS record.

loadBalancingPolicy is the load balancing policy for this global record. It must match one of the policy supported by the provider of the referenced GlobalZone.

Finally, healthcheck represent a probe to be used to test the health of a record. This field will be ignored if the provider does not support health checks.

External DNS Provider

The external-dns provider delegates to external-dns the creation of the actual DNS records by creating a DNSEndpoint object. The DNSEndpoint object will be created in the same namespace as the GlobalDNSRecord and will be owned by it. The DNSEdnpoint object will have the same labels as the GlobalDNSRecord and the annotations specified in the GlobalDNSZone configuration. External-dns should be configured to watch for DNSEnpoints at the cluster level and to point to the desired provider. Details on configuration can be found at the external-dns git repository. The External-dns should be used as a fall back option when other options are not available as it does not support health checks and advanced load balancing policies.

AWS Route53 provider

AWS Route53 provider uses the Route53 service as a global loadbalancer and offers advanced routing capabilities via route53 traffic policies (note that traffic policies will trigger an expense). The following routing polices are currently supported:

  1. Multivalue.
  2. Geoproximity.
  3. Latency.

AWS Route53 provider at the moment requires that all the controlled clusters run in AWS.

If health checks are defined, a route53 health check originating from every region (you have to ensure connectivity) will be created for each of the endpoint. Because the endpoint represents a shared ELB (shared with other apps, that is) and the health check is app specific, we cannot use the ELB health check, so the route53 endpoint is created with one of the two IP exposed by the ELB. This is suboptimal, but it works in most situations.

Azure Traffic Manager provider

Azure traffic manager provider uses (Azure Traffic Manager)[] to create global load balancer configuration. The following routing policies are supported:

  1. Multivalue.
  2. Geographic.
  3. Performance.

This is an initial implementation which requires all of the controlled clusters to be on Azure and to be publicly exposed.

Health checks are supported by this provider.

Google Global Load Balancer provider

Google Global Load Balancer provider creates a global IP that will load balance directly to the nodes and node port of the service in the GlobalDNSRecord. It sets a maximum of 100 connections per node (currently hard coded). It supports TCP-session affinity. The loadBalancingPolicy field will be ignored by this provider.

Health checks are supported by this provider and are mandatory.

Global Route Auto Discovery

The above examples showed how to create global DNS records. This can be good in some situations, but most of the times in an openshift deployment global DNS records will point to routes that are intended to be global. The global-load-balancer operator can auto-discover these routes and automatically create the corresponding GloablDNSRecord. The GlobalRouteDiscovery CRD is used to configure the discovery process, here is an example:

apiVersion: redhatcop.redhat.io/v1alpha1
kind: GlobalRouteDiscovery
metadata:
  name: route53-globalroutediscovery
spec:
  clusters:
  - clusterName: cluster1
    clusterCredentialRef:
      name: ${cluster1_secret_name}
      namespace: cluster1
...
  routeSelector:
    matchLabels:
      route-type: global
  defaultLoadBalancingPolicy: Multivalue
  defaultTTL: 30
  globalZoneRef:
    name: route53-global-dns-zone

This global discovery route will discover routes in the provided list of cluster. Only the routes that match the route selector will be considered global. The default load balancing policy and default TTL can be expressed in the GlobalRouteDiscovery CR. However with the following annotations, it's possible to configure route-specific values:

  • global-load-balancer-operator.redhat-cop.io/load-balancing-policy to set the load balancing policy
  • global-load-balancer-operator.redhat-cop.io/ttl to set the TTL
  • global-load-balancer-operator.redhat-cop.io/health-check to set the health check. This must be a v1core.Probe object in json format.

As an example here is what a v1core.Probe object looks like in json format:

'{"httpGet":{"path":"health?ready=1","port":443,"scheme":"HTTPS"},"timeoutSeconds":1,"periodSeconds":10,"successThreshold":1,"failureThreshold":3}'

The globalZoneRef refers to the global zone to be used for the created GlobalDNSRecords.

If the health check annotation is not provided, the controller will try to automatically discover the health check. If the pods behind the route expose a readiness check of httpGet kind, that configuration will be used to create the GlobalDNSRecord health check. When more than one container is present in the pod, by default the first container will be examined for health check. This behavior can be overridden with the this annotation on the route: global-load-balancer-operator.redhat-cop.io/container-probe where the value will container the name of the container with teh correct readiness probe.

If routes with the same namespace and name exists in multiple cluster, the following conditions must be met:

  • all host names must be the same
  • all load balancing policy must be the same
  • all TTLs must be the same
  • all discovered readiness checks must be the same

Examples

These examples are intended to help you setting up working configuration with each of the providers

Cluster Set up

Two approaches for cluster setup are provided

  1. One cluster, three ingress-gateways. This approach is intended for development purposes and has the objective to keep resource consumption at the minimum.
  2. Control cluster and three controlled clusters in different regions.. This approach represents a more realistic set-up albeit it consumes more resources.

You can also set up the cluster on your own, at the end the following conditions must be met:

Three namespace cluster1 cluster2 cluster3 are created. the following environment variables are initialized for each cluster:

  1. <cluster>_secret_name. Pointing to a secret in each of the cluster namespaces containing a valid kubeconfig fot that cluster
  2. <cluster>_service_name. Pointing to the name of the loadbalancer service to be used for that cluster.
  3. <cluster>_service_namespace. Pointing to the namespace of the loadbalancer service to be used for that cluster.

Here are examples for the supported provider:

  1. Setting up external-dns as provider
  2. Setting up route53 as a provider
  3. Setting up Azure Traffic Manager as a provider
  4. Setting up Google Global Load Balancer as a provider

Deploying the Operator

This is a cluster-level operator that you can deploy in any namespace, global-load-balancer-operator is recommended.

It is recommended to deploy this operator via OperatorHub, but you can also deploy it using Helm.

Multiarch Support

Arch Support
amd64
arm64
ppc64le
s390x

Deploying from OperatorHub

Note: This operator supports being installed disconnected environments

If you want to utilize the Operator Lifecycle Manager (OLM) to install this operator, you can do so in two ways: from the UI or the CLI.

Deploying from OperatorHub UI

  • If you would like to launch this operator from the UI, you'll need to navigate to the OperatorHub tab in the console.Before starting, make sure you've created the namespace that you want to install this operator to with the following:
oc new-project global-load-balancer-operator
  • Once there, you can search for this operator by name: global loadbalancer. This will then return an item for our operator and you can select it to get started. Once you've arrived here, you'll be presented with an option to install, which will begin the process.
  • After clicking the install button, you can then select the namespace that you would like to install this to as well as the installation strategy you would like to proceed with (Automatic or Manual).
  • Once you've made your selection, you can select Subscribe and the installation will begin. After a few moments you can go ahead and check your namespace and you should see the operator running.

Global Load Balancer Operator

Deploying from OperatorHub using CLI

If you'd like to launch this operator from the command line, you can use the manifests contained in this repository by running the following:

oc new-project global-load-balancer-operator
oc apply -f config/operatorhub -n global-load-balancer-operator

This will create the appropriate OperatorGroup and Subscription and will trigger OLM to launch the operator in the specified namespace.

Deploying with Helm

Here are the instructions to install the latest release with Helm.

oc new-project global-load-balancer-operator
helm repo add global-load-balancer-operator https://redhat-cop.github.io/global-load-balancer-operator
helm repo update
helm install global-load-balancer-operator global-load-balancer-operator/global-load-balancer-operator

This can later be updated with the following commands:

helm repo update
helm upgrade global-load-balancer-operator global-load-balancer-operator/global-load-balancer-operator

Metrics

Prometheus compatible metrics are exposed by the Operator and can be integrated into OpenShift's default cluster monitoring. To enable OpenShift cluster monitoring, label the namespace the operator is deployed in with the label openshift.io/cluster-monitoring="true".

oc label namespace <namespace> openshift.io/cluster-monitoring="true"

Testing metrics

export operatorNamespace=global-load-balancer-operator-local # or global-load-balancer-operator
oc label namespace ${operatorNamespace} openshift.io/cluster-monitoring="true"
oc rsh -n openshift-monitoring -c prometheus prometheus-k8s-0 /bin/bash
export operatorNamespace=global-load-balancer-operator-local # or global-load-balancer-operator
curl -v -s -k -H "Authorization: Bearer $(cat /var/run/secrets/kubernetes.io/serviceaccount/token)" https://global-load-balancer-operator-controller-manager-metrics.${operatorNamespace}.svc.cluster.local:8443/metrics
exit

Development

Running the operator locally

make install
oc new-project global-load-balancer-operator-local
oc create serviceaccount global-load-balancer-controller-manager
kustomize build ./config/local-development | oc apply -f - -n global-load-balancer-operator-local
export token=$(oc serviceaccounts get-token 'global-load-balancer-controller-manager' -n global-load-balancer-operator-local)
oc login --token ${token}
make run ENABLE_WEBHOOKS=false NAMESPACE=global-load-balancer-operator-local

Test helm chart locally

Define an image and tag. For example...

export imageRepository="quay.io/redhat-cop/global-load-balancer-operator"
export imageTag="$(git -c 'versionsort.suffix=-' ls-remote --exit-code --refs --sort='version:refname' --tags https://github.com/redhat-cop/global-load-balancer-operator.git '*.*.*' | tail --lines=1 | cut --delimiter='/' --fields=3)"

Deploy chart...

make helmchart IMG=${imageRepository} VERSION=${imageTag}
helm upgrade -i global-load-balancer-operator-local charts/global-load-balancer-operator -n global-load-balancer-operator-local --create-namespace

Delete...

helm delete global-load-balancer-operator-local -n global-load-balancer-operator-local
kubectl delete -f charts/global-load-balancer-operator/crds/crds.yaml

Building/Pushing the operator image

export repo=raffaelespazzoli #replace with yours
docker login quay.io/$repo/global-load-balancer-operator
make docker-build IMG=quay.io/$repo/global-load-balancer-operator:latest
make docker-push IMG=quay.io/$repo/global-load-balancer-operator:latest

Deploy to OLM via bundle

make manifests
make bundle IMG=quay.io/$repo/global-load-balancer-operator:latest
operator-sdk bundle validate ./bundle --select-optional name=operatorhub
make bundle-build BUNDLE_IMG=quay.io/$repo/global-load-balancer-operator-bundle:latest
docker login quay.io/$repo/global-load-balancer-operator-bundle
podman push quay.io/$repo/global-load-balancer-operator-bundle:latest
operator-sdk bundle validate quay.io/$repo/global-load-balancer-operator-bundle:latest --select-optional name=operatorhub
oc new-project global-load-balancer-operator
oc label namespace global-load-balancer-operator openshift.io/cluster-monitoring="true"
operator-sdk cleanup global-load-balancer-operator -n global-load-balancer-operator
operator-sdk run bundle --install-mode AllNamespaces -n global-load-balancer-operator quay.io/$repo/global-load-balancer-operator-bundle:latest

Releasing

git tag -a "<tagname>" -m "<commit message>"
git push upstream <tagname>

If you need to remove a release:

git tag -d <tagname>
git push upstream --delete <tagname>

If you need to "move" a release to the current main

git tag -f <tagname>
git push upstream -f <tagname>

Cleaning up

operator-sdk cleanup global-load-balancer-operator -n global-load-balancer-operator
oc delete operatorgroup operator-sdk-og
oc delete catalogsource global-load-balancer-operator-catalog