DigitalOcean cloud controller manager runs service controller, which is
responsible for watching services of type LoadBalancer and creating DO
loadbalancers to satify its requirements. Here are some examples of how it's
used.
Not specifying any annotations to your service will create a simple TCP loadbalancer. Here's an example:
$ kubectl apply -f tcp-nginx.yml
service "tcp-lb" created
deployment "nginx-example" createdBy default, kubernetes names load balancers based on the UUID of the service.
$ doctl compute load-balancer list
ID IP Name Status Created At Algorithm Region Tag Droplet IDs SSL Sticky Sessions Health Check Forwarding Rules
44ff4bf9-34b9-4461-8442-80a90001cb0e ace288b51796411e7af69267d6e0a2ca new 2017-08-04T22:32:33Z round_robin tor1 55581290,55581291,55581292 false type:none,cookie_name:,cookie_ttl_seconds:0 protocol:tcp,port:31294,path:,check_interval_seconds:3,response_timeout_seconds:5,healthy_threshold:5,unhealthy_threshold:3 entry_protocol:tcp,entry_port:80,target_protocol:tcp,target_port:31294,certificate_id:,tls_passthrough:falseHere's an example on how to create a simple http load balancer backed by nginx pods
$ kubectl apply -f http-nginx.yml
service "http-lb" created
deployment "nginx-example" configuredThis creates a DO load balancer, using http as the default protocol and using the default load balancing algorithm: round robin.
$ doctl compute load-balancer list
ID IP Name Status Created At Algorithm Region Tag Droplet IDs SSL Sticky Sessions Health Check Forwarding Rules
5ceb1d26-e4cf-403b-8677-0e5232eec711 159.203.48.217 aeafab819796311e7af69267d6e0a2ca active 2017-08-04T22:26:12Z round_robin tor1 55581290,55581291,55581292 false type:none,cookie_name:,cookie_ttl_seconds:0 protocol:http,port:31018,path:/,check_interval_seconds:3,response_timeout_seconds:5,healthy_threshold:5,unhealthy_threshold:3 entry_protocol:http,entry_port:80,target_protocol:http,target_port:31018,certificate_id:,tls_passthrough:falseFor the sake of example, assume you have a valid key/cert pair for your HTTPS certificate at key.pem and cert.pem.
Now we can create a certificate to use for your loadbalancer:
doctl compute certificate create --name=lb-example --private-key-path=key.pem --leaf-certificate-path=cert.pem
ID Name SHA-1 Fingerprint Expiration Date Created At
29333fdc-733d-4523-8d79-31acc1544ee0 lb-example 4a55a37f89003a20881e67f1bcc85654fdacc525 2022-07-18T18:46:00Z 2017-08-04T23:01:14ZThe next example sets the annotation service.beta.kubernetes.io/do-loadbalancer-certificate-id to the certificate ID we want to use, in this case it's 29333fdc-733d-4523-8d79-31acc1544ee0.
$ kubectl apply -f https-with-cert-nginx.yml
service "https-with-cert" created
deployment "nginx-example" configured
$ doctl compute load-balancer list
ID IP Name Status Created At Algorithm Region Tag Droplet IDs SSL Sticky Sessions Health Check Forwarding Rules
20befcaf-533d-4fc9-bc4b-be31f957ad87 a83435adb796911e7af69267d6e0a2ca new 2017-08-04T23:06:15Z round_robin tor1 55581290,55581291,55581292 false type:none,cookie_name:,cookie_ttl_seconds:0 protocol:http,port:30361,path:/,check_interval_seconds:3,response_timeout_seconds:5,healthy_threshold:5,unhealthy_threshold:3 entry_protocol:http,entry_port:80,target_protocol:http,target_port:30361,certificate_id:,tls_passthrough:false entry_protocol:https,entry_port:443,target_protocol:http,target_port:32728,certificate_id:29333fdc-733d-4523-8d79-31acc1544ee0,tls_passthrough:falseYou can create a https loadbalancer that will pass encrypted data to your backends instead of doing TLS termination.
$ kubectl apply -f https-with-pass-through-nginx.yml
service "https-with-tls-pass-through" created
deployment "nginx-example" configured$ doctl compute load-balancer list
ID IP Name Status Created At Algorithm Region Tag Droplet IDs SSL Sticky Sessions Health Check Forwarding Rules
105c2071-dcfd-479c-8e84-883d66ba4dec 159.203.52.207 a16bdac1c797611e7af69267d6e0a2ca active 2017-08-05T00:36:16Z round_robin tor1 55581290,55581291,55581292 false type:none,cookie_name:,cookie_ttl_seconds:0 protocol:http,port:31644,path:/,check_interval_seconds:3,response_timeout_seconds:5,healthy_threshold:5,unhealthy_threshold:3 entry_protocol:http,entry_port:80,target_protocol:http,target_port:31644,certificate_id:,tls_passthrough:false entry_protocol:https,entry_port:443,target_protocol:https,target_port:30566,certificate_id:,tls_passthrough:trueBecause of an existing limitation in upstream Kubernetes, pods cannot talk to other pods via the IP address of an external load-balancer set up through a LoadBalancer-typed service. Kubernetes will cause the LB to be bypassed, potentially breaking workflows that expect TLS termination or proxy protocol handling to be applied consistently.
However, a workaround exists that takes advantage of the fact that bypassing only happens when the Service status field returns an IP address but not if it returns a hostname. To leverage it, a DNS record for a custom hostname (at a provider of your choice) must be set up that points to the external IP address of the load-balancer. Afterwards, digitalocean-cloud-controller-manager must be instructed to return the custom hostname (instead of the external LB IP address) in the service ingress status field status.Hostname by specifying the hostname in the service.beta.kubernetes.io/do-loadbalancer-hostname annotation. Clients may then connect to the hostname to reach the load-balancer from inside the cluster.
To make the load-balancer accessible through multiple hostnames, register additional CNAMEs that all point to the hostname. SSL certificates could then be associated with one or more of these hostnames.
The workflow for setting up the service.beta.kubernetes.io/do-loadbalancer-hostname annotation is generally:
- Deploy the manifest with your Service (example below).
- Wait for the service external IP to be available.
- Add a DNS record for your hostname pointing to the external IP.
- Add the hostname annotation to your manifest (example below). Apply it.
kind: Service
apiVersion: v1
metadata:
name: hello
annotations:
service.beta.kubernetes.io/do-loadbalancer-certificate-id: "1234-5678-9012-3456"
service.beta.kubernetes.io/do-loadbalancer-protocol: "https"
# Uncomment once hello.example.com points to the external IP address of the DO load-balancer.
# service.beta.kubernetes.io/do-loadbalancer-hostname: "hello.example.com"
spec:
type: LoadBalancer
selector:
app: hello
ports:
- name: https
protocol: TCP
port: 443
targetPort: 80
---
apiVersion: apps/v1
kind: Deployment
metadata:
name: hello
spec:
replicas: 3
selector:
matchLabels:
app: hello
template:
metadata:
labels:
app: hello
spec:
containers:
- name: hello
image: snormore/hello
ports:
- containerPort: 80
protocol: TCPIf your load balancer has UDP service ports you must configure a TCP service as a health check for the load balancer to work properly.
There is currently a bug in Kubernetes that prevents using the same port number across TCP and UDP. However, it only exhibits when updating an existing service; to work around this, simply delete and recreate the service with the additional port(s).
NOTE: This will cause the associated Load Balancer to be deleted and re-created as well, so the IP address of the Load Balancer may change. You can follow the steps below to work around that.
In general, multiple services (within the same cluster or across multiple clusters) should not be referencing the same load-balancer ID to avoid conflicting reconciliation. However, at times this may be desired in order to pass ownership of a load-balancer from one Service to another. A common use case is to migrate a load-balancer from one cluster to a new one in order to preserve its IP address.
This can be safely achieved by first "disowning" the load-balancer from the original Service, which turns all mutating actions (load balancer creates, updates, and deletes) into no-ops. Afterwards, the load-balancer can be taken over by a new Service by setting the kubernetes.digitalocean.com/load-balancer-id annotation accordingly.
Note: The new Service's cluster must reside in the same VPC as the original Service. Otherwise, ownership cannot be passed on. See the DigitalOcean VPC documentation for details.
The workflow below outlines the necessary steps.
Suppose you have a Service
# For the sake of this example, let's assume the Service lives in cluster "production-v1"
kind: Service
apiVersion: v1
metadata:
name: app
annotations:
kubernetes.digitalocean.com/load-balancer-id: c16b0b29-217b-48eb-907e-93cf2e01fb56
spec:
selector:
name: app
ports:
- name: http
protocol: TCP
port: 80
type: LoadBalancerin cluster production-v1. (Note the kubernetes.digitalocean.com/load-balancer-id annotation set by digitalocean-cloud-controller-managers.)
Here is how you would go about moving the load-balancer to a new cluster production-v2:
- Make sure that no load-balancer-related errors are reported from
digitalocean-cloud-controller-managersby checking for the absence of error events in your Service viakubectl describe service app. Fix any errors that may be reported to bring the Service into a stable state. - Mark the load-balancer as disowned by adding the
service.kubernetes.io/do-loadbalancer-disownannotation and assigning it a"true"value. Afterwards, the Service object should look like this:
kind: Service
apiVersion: v1
metadata:
name: app
annotations:
kubernetes.digitalocean.com/load-balancer-id: c16b0b29-217b-48eb-907e-93cf2e01fb56
service.kubernetes.io/do-loadbalancer-disown: "true"
spec:
selector:
name: app
ports:
- name: http
protocol: TCP
port: 80
type: LoadBalancer- Make sure the change is applied correctly by checking the Service events again. Once applied, all mutating requests directed at the load-balancer and driven through the Service object will be ignored.
(At this point, you could already delete the Service while the corresponding load-balancer would not be deleted.)
- In our hypthetical new cluster production-v2, create a new Service that is supposed to take over ownership and set the
kubernetes.digitalocean.com/load-balancer-idannotation right from the start:
# This would be in cluster "production-v2"
kind: Service
apiVersion: v1
metadata:
name: app
annotations:
kubernetes.digitalocean.com/load-balancer-id: c16b0b29-217b-48eb-907e-93cf2e01fb56
spec:
selector:
name: app
ports:
- name: http
protocol: TCP
port: 80
type: LoadBalancer(In the real-world, your Service may have a number of load-balancer-specific configuration annotation which you would transfer to the new Service as well.)
- Wait for
digitalocean-cloud-controller-managersto finish reconciliation by checking the Service events until things have settled down.
At this point, the load-balancer should be owned by the new Service, meaning that traffic should be routed into the new cluster.
- If you have not done so already: delete the Service in the old cluster (or change its type to something other than
LoadBalancerif you want to, say, continue using the Service for cluster-internal routing).
You're done!
To exclude a particular node from the load balancer target set, add the node.kubernetes.io/exclude-from-external-load-balancers= label to the node. (The value is not relevant.) This requires the ServiceNodeExclusion feature gate to be enabled, which is the default since Kubernetes 1.19.
Note: For services that use externalTrafficPolicy=Local, this may mean that any pods on excluded nodes are not reachable by those external load-balancers.
Cloud Controller Manager is using DigitalOcean API internally to provision a DigitalOcean load balancer. It might happen that provisioning will be unsuccessful, because of various reasons.
You can find provisioning status and all the reconciliation errors that Cloud Controller Manager encountered during the LoadBalancer service life-cycle in the service's event stream.
Provided that your kubernetes service name is my-svc, you can use following
commands to access events attached to this object:
$ kubectl describe service my-svcIn the above case, events should be available at the bottom of the description, if present.
To get only events for a given service, you can use following command:
$ kubectl get events --field-selector involvedObject.name=my-svc