Securing NGINX-ingress
This tutorial will detail how to install and secure ingress to your cluster using NGINX.
Step 0 - Install Helm Client
Skip this section if you have helm installed.
The easiest way to install cert-manager
is to use Helm
, a
templating and deployment tool for Kubernetes resources.
First, ensure the Helm client is installed following the Helm installation instructions.
For example, on MacOS:
$ brew install kubernetes-helm
Step 1 - Install Tiller
Skip this section if you have Tiller set-up. Ignore this part for Helm version 3
Tiller is Helm’s server-side component, which the helm
client uses to
deploy resources.
Deploying resources is a privileged operation; in the general case requiring arbitrary privileges. With this example, we give Tiller complete control of the cluster. View the documentation on securing helm for details on setting up appropriate permissions for your environment.
Create a ServiceAccount
for Tiller:
$ kubectl create serviceaccount tiller --namespace=kube-system
serviceaccount "tiller" created
Grant the tiller
service account cluster admin privileges:
$ kubectl create clusterrolebinding tiller-admin --serviceaccount=kube-system:tiller --clusterrole=cluster-admin
clusterrolebinding.rbac.authorization.k8s.io "tiller-admin" created
Install tiller with the tiller
service account:
$ helm init --service-account=tiller
$HELM_HOME has been configured at /Users/myaccount/.helm.
Tiller (the Helm server-side component) has been installed into your Kubernetes Cluster.
Please note: by default, Tiller is deployed with an insecure 'allow unauthenticated users' policy.
To prevent this, run `helm init` with the --tiller-tls-verify flag.
For more information on securing your installation see: https://docs.helm.sh/using_helm/#securing-your-helm-installation
Happy Helming!
Update the helm repository with the latest charts:
$ helm repo update
Hang tight while we grab the latest from your chart repositories...
...Skip local chart repository
...Successfully got an update from the "stable" chart repository
...Successfully got an update from the "coreos" chart repository
Update Complete. ⎈ Happy Helming!⎈
Step 2 - Deploy the NGINX Ingress Controller
A kubernetes ingress
controller
is
designed to be the access point for HTTP and HTTPS traffic to the software
running within your cluster. The nginx-ingress
controller does this by providing
an HTTP proxy service supported by your cloud provider’s load balancer.
You can get more details about nginx-ingress
and how it works from the
documentation for nginx-ingress
.
Use helm
to install an NGINX Ingress controller:
# for helm version 2
$ helm install stable/nginx-ingress --name quickstart
# for helm version 3
$ helm install quickstart stable/nginx-ingress
NAME: quickstart
LAST DEPLOYED: Sat Nov 10 10:25:06 2018
NAMESPACE: default
STATUS: DEPLOYED
RESOURCES:
==> v1/ConfigMap
NAME AGE
quickstart-nginx-ingress-controller 0s
==> v1beta1/ClusterRole
quickstart-nginx-ingress 0s
==> v1beta1/Deployment
quickstart-nginx-ingress-controller 0s
quickstart-nginx-ingress-default-backend 0s
==> v1/Pod(related)
NAME READY STATUS RESTARTS AGE
quickstart-nginx-ingress-controller-6cfc45747-wcxrg 0/1 ContainerCreating 0 0s
quickstart-nginx-ingress-default-backend-bf9db5c67-dkg4l 0/1 ContainerCreating 0 0s
==> v1/ServiceAccount
NAME AGE
quickstart-nginx-ingress 0s
==> v1beta1/ClusterRoleBinding
quickstart-nginx-ingress 0s
==> v1beta1/Role
quickstart-nginx-ingress 0s
==> v1beta1/RoleBinding
quickstart-nginx-ingress 0s
==> v1/Service
quickstart-nginx-ingress-controller 0s
quickstart-nginx-ingress-default-backend 0s
NOTES:
The nginx-ingress controller has been installed.
It may take a few minutes for the LoadBalancer IP to be available.
You can watch the status by running 'kubectl --namespace default get services -o wide -w quickstart-nginx-ingress-controller'
An example Ingress that makes use of the controller:
apiVersion: extensions/v1beta1
kind: Ingress
metadata:
annotations:
kubernetes.io/ingress.class: nginx
name: example
namespace: foo
spec:
rules:
- host: www.example.com
http:
paths:
- backend:
serviceName: exampleService
servicePort: 80
path: /
# This section is only required if TLS is to be enabled for the Ingress
tls:
- hosts:
- www.example.com
secretName: example-tls
If TLS is enabled for the Ingress, a Secret containing the certificate and key must also be provided:
apiVersion: v1
kind: Secret
metadata:
name: example-tls
namespace: foo
data:
tls.crt: <base64 encoded cert>
tls.key: <base64 encoded key>
type: kubernetes.io/tls
It can take a minute or two for the cloud provider to provide and link a public
IP address. When it is complete, you can see the external IP address using the
kubectl
command:
$ kubectl get svc
NAME TYPE CLUSTER-IP EXTERNAL-IP PORT(S) AGE
kubernetes ClusterIP 10.63.240.1 <none> 443/TCP 23m
quickstart-nginx-ingress-controller LoadBalancer 10.63.248.177 203.0.113.2 80:31345/TCP,443:31376/TCP 16m
quickstart-nginx-ingress-default-backend ClusterIP 10.63.250.234 <none> 80/TCP 16m
This command shows you all the services in your cluster (in the default
namespace), and any external IP addresses they have. When you first create the
controller, your cloud provider won’t have assigned and allocated an IP address
through the LoadBalancer
yet. Until it does, the external IP address for the
service will be listed as <pending>
.
Your cloud provider may have options for reserving an IP address prior to creating the ingress controller and using that IP address rather than assigning an IP address from a pool. Read through the documentation from your cloud provider on how to arrange that.
Step 3 - Assign a DNS name
The external IP that is allocated to the ingress-controller is the IP to which
all incoming traffic should be routed. To enable this, add it to a DNS zone you
control, for example as www.example.com
.
This quick-start assumes you know how to assign a DNS entry to an IP address and will do so.
Step 4 - Deploy an Example Service
Your service may have its own chart, or you may be deploying it directly with
manifests. This quick-start uses manifests to create and expose a sample service.
The example service uses
kuard
, a demo
application which makes an excellent back-end for examples.
The quick-start example uses three manifests for the sample. The first two are a sample deployment and an associated service:
apiVersion: apps/v1
kind: Deployment
metadata:
name: kuard
spec:
selector:
matchLabels:
app: kuard
replicas: 1
template:
metadata:
labels:
app: kuard
spec:
containers:
- image: gcr.io/kuar-demo/kuard-amd64:1
imagePullPolicy: Always
name: kuard
ports:
- containerPort: 8080
apiVersion: v1
kind: Service
metadata:
name: kuard
spec:
ports:
- port: 80
targetPort: 8080
protocol: TCP
selector:
app: kuard
You can create download and reference these files locally, or you can reference them from the GitHub source repository for this documentation. To install the example service from the tutorial files straight from GitHub, you may use the commands:
$ kubectl apply -f https://netlify.cert-manager.io/docs/tutorials/acme/example/deployment.yaml
deployment.extensions "kuard" created
$ kubectl apply -f https://netlify.cert-manager.io/docs/tutorials/acme/example/service.yaml
service "kuard" created
An ingress
resource
is
what Kubernetes uses to expose this example service outside the cluster. You
will need to download and modify the example manifest to reflect the domain that
you own or control to complete this example.
A sample ingress you can start with is:
apiVersion: extensions/v1beta1
kind: Ingress
metadata:
name: kuard
annotations:
kubernetes.io/ingress.class: "nginx"
#cert-manager.io/issuer: "letsencrypt-staging"
spec:
tls:
- hosts:
- example.example.com
secretName: quickstart-example-tls
rules:
- host: example.example.com
http:
paths:
- path: /
backend:
serviceName: kuard
servicePort: 80
You can download the sample manifest from GitHub , edit it, and submit the manifest to Kubernetes with the command. Edit the file in your editor, and once it is saved:
$ kubectl create --edit -f https://netlify.cert-manager.io/docs/tutorials/acme/example/ingress.yaml
ingress.extensions "kuard" created
Note: The ingress example we show above has a
host
definition within it. Thenginx-ingress-controller
will route traffic when the hostname requested matches the definition in the ingress. You can deploy an ingress without ahost
definition in the rule, but that pattern isn’t usable with a TLS certificate, which expects a fully qualified domain name.
Once it is deployed, you can use the command kubectl get ingress
to see the status
of the ingress:
NAME HOSTS ADDRESS PORTS AGE
kuard * 80, 443 17s
It may take a few minutes, depending on your service provider, for the ingress to be fully created. When it has been created and linked into place, the ingress will show an address as well:
NAME HOSTS ADDRESS PORTS AGE
kuard * 203.0.113.2 80 9m
Note: The IP address on the ingress may not match the IP address that the
nginx-ingress-controller
. This is fine, and is a quirk/implementation detail of the service provider hosting your Kubernetes cluster. Since we are using thenginx-ingress-controller
instead of any cloud-provider specific ingress backend, use the IP address that was defined and allocated for thenginx-ingress-service
LoadBalancer
resource as the primary access point for your service.
Make sure the service is reachable at the domain name you added above, for
example http://www.example.com
. The simplest way is to open a browser
and enter the name that you set up in DNS, and for which we just added the
ingress.
You may also use a command line tool like curl
to check the ingress.
$ curl -kivL -H 'Host: www.example.com' 'http://203.0.113.2'
The options on this curl command will provide verbose output, following any
redirects, show the TLS headers in the output, and not error on insecure
certificates. With nginx-ingress-controller
, the service will be available
with a TLS certificate, but it will be using a self-signed certificate
provided as a default from the nginx-ingress-controller
. Browsers will show
a warning that this is an invalid certificate. This is expected and normal,
as we have not yet used cert-manager to get a fully trusted certificate
for our site.
Warning: It is critical to make sure that your ingress is available and responding correctly on the internet. This quick-start example uses Let’s Encrypt to provide the certificates, which expects and validates both that the service is available and that during the process of issuing a certificate uses that validation as proof that the request for the domain belongs to someone with sufficient control over the domain.
Step 5 - Deploy Cert Manager
We need to install cert-manager to do the work with Kubernetes to request a certificate and respond to the challenge to validate it. We can use Helm or plain Kubernetes manifest to install cert-manager.
Read the getting started guide to install cert-manager using your preferred method.
Cert-manager uses two different custom resources, also known as
CRD
’s,
to configure and control how it operates, as well as share status of its
operation. These two resources are:
An Issuer is the definition for where cert-manager will get request TLS certificates. An Issuer is specific to a single namespace in Kubernetes, and a
ClusterIssuer
is meant to be a cluster-wide definition for the same purpose.Note that if you’re using this document as a guide to configure cert-manager for your own Issuer, you must create the Issuers in the same namespace as your Ingress resources by adding
-n my-namespace
to yourkubectl create
commands. Your other option is to replace your Issuers withClusterIssuers
.ClusterIssuer
resources apply across all Ingress resources in your cluster and don’t have this namespace-matching requirement.More information on the differences between
Issuers
andClusterIssuers
and when you might choose to use each can be found here.A certificate is the resource that cert-manager uses to expose the state of a request as well as track upcoming expiration.
Step 6 - Configure Let’s Encrypt Issuer
We will set up two issuers for Let’s Encrypt in this example. The Let’s Encrypt production issuer has very strict rate limits. When you are experimenting and learning, it is very easy to hit those limits, and confuse rate limiting with errors in configuration or operation.
Because of this, we will start with the Let’s Encrypt staging issuer, and once that is working switch to a production issuer.
Create this definition locally and update the email address to your own. This email required by Let’s Encrypt and used to notify you of certificate expiration and updates.
apiVersion: cert-manager.io/v1alpha2
kind: Issuer
metadata:
name: letsencrypt-staging
spec:
acme:
# The ACME server URL
server: https://acme-staging-v02.api.letsencrypt.org/directory
# Email address used for ACME registration
email: user@example.com
# Name of a secret used to store the ACME account private key
privateKeySecretRef:
name: letsencrypt-staging
# Enable the HTTP-01 challenge provider
solvers:
- http01:
ingress:
class: nginx
Once edited, apply the custom resource:
$ kubectl create --edit -f https://cert-manager.io/docs/tutorials/acme/example/staging-issuer.yaml
issuer.cert-manager.io "letsencrypt-staging" created
Also create a production issuer and deploy it. As with the staging issuer, you will need to update this example and add in your own email address.
apiVersion: cert-manager.io/v1alpha2
kind: Issuer
metadata:
name: letsencrypt-prod
spec:
acme:
# The ACME server URL
server: https://acme-v02.api.letsencrypt.org/directory
# Email address used for ACME registration
email: user@example.com
# Name of a secret used to store the ACME account private key
privateKeySecretRef:
name: letsencrypt-prod
# Enable the HTTP-01 challenge provider
solvers:
- http01:
ingress:
class: nginx
$ kubectl create --edit -f https://cert-manager.io/docs/tutorials/acme/example/production-issuer.yaml
issuer.cert-manager.io "letsencrypt-prod" created
Both of these issuers are configured to use the
HTTP01
challenge provider.
Check on the status of the issuer after you create it:
$ kubectl describe issuer letsencrypt-staging
Name: letsencrypt-staging
Namespace: default
Labels: <none>
Annotations: kubectl.kubernetes.io/last-applied-configuration={"apiVersion":"cert-manager.io/v1alpha2","kind":"Issuer","metadata":{"annotations":{},"name":"letsencrypt-staging","namespace":"default"},(...)}
API Version: cert-manager.io/v1alpha2
Kind: Issuer
Metadata:
Cluster Name:
Creation Timestamp: 2018-11-17T18:03:54Z
Generation: 0
Resource Version: 9092
Self Link: /apis/cert-manager.io/v1alpha2/namespaces/default/issuers/letsencrypt-staging
UID: 25b7ae77-ea93-11e8-82f8-42010a8a00b5
Spec:
Acme:
Email: email@example.com
Private Key Secret Ref:
Key:
Name: letsencrypt-staging
Server: https://acme-staging-v02.api.letsencrypt.org/directory
Solvers:
Http 01:
Ingress:
Class: nginx
Status:
Acme:
Uri: https://acme-staging-v02.api.letsencrypt.org/acme/acct/7374163
Conditions:
Last Transition Time: 2018-11-17T18:04:00Z
Message: The ACME account was registered with the ACME server
Reason: ACMEAccountRegistered
Status: True
Type: Ready
Events: <none>
You should see the issuer listed with a registered account.
Step 7 - Deploy a TLS Ingress Resource
With all the prerequisite configuration in place, we can now do the pieces to
request the TLS certificate. There are two primary ways to do this: using
annotations on the ingress with ingress-shim
or
directly creating a certificate resource.
In this example, we will add annotations to the ingress, and take advantage of ingress-shim to have it create the certificate resource on our behalf. After creating a certificate, the cert-manager will update or create a ingress resource and use that to validate the domain. Once verified and issued, cert-manager will create or update the secret defined in the certificate.
Note: The secret that is used in the ingress should match the secret defined in the certificate. There isn’t any explicit checking, so a typo will result in the
nginx-ingress-controller
falling back to its self-signed certificate. In our example, we are using annotations on the ingress (and ingress-shim) which will create the correct secrets on your behalf.
Edit the ingress add the annotations that were commented out in our earlier example:
apiVersion: extensions/v1beta1
kind: Ingress
metadata:
name: kuard
annotations:
kubernetes.io/ingress.class: "nginx"
cert-manager.io/issuer: "letsencrypt-staging"
spec:
tls:
- hosts:
- example.example.com
secretName: quickstart-example-tls
rules:
- host: example.example.com
http:
paths:
- path: /
backend:
serviceName: kuard
servicePort: 80
and apply it:
$ kubectl create --edit -f https://cert-manager.io/docs/tutorials/acme/example/ingress-tls.yaml
ingress.extensions "kuard" configured
Cert-manager will read these annotations and use them to create a certificate, which you can request and see:
$ kubectl get certificate
NAME READY SECRET AGE
quickstart-example-tls True quickstart-example-tls 16m
Cert-manager reflects the state of the process for every request in the
certificate object. You can view this information using the
kubectl describe
command:
$ kubectl describe certificate quickstart-example-tls
Name: quickstart-example-tls
Namespace: default
Labels: <none>
Annotations: <none>
API Version: cert-manager.io/v1alpha2
Kind: Certificate
Metadata:
Cluster Name:
Creation Timestamp: 2018-11-17T17:58:37Z
Generation: 0
Owner References:
API Version: extensions/v1beta1
Block Owner Deletion: true
Controller: true
Kind: Ingress
Name: kuard
UID: a3e9f935-ea87-11e8-82f8-42010a8a00b5
Resource Version: 9295
Self Link: /apis/cert-manager.io/v1alpha2/namespaces/default/certificates/quickstart-example-tls
UID: 68d43400-ea92-11e8-82f8-42010a8a00b5
Spec:
Dns Names:
www.example.com
Issuer Ref:
Kind: Issuer
Name: letsencrypt-staging
Secret Name: quickstart-example-tls
Status:
Acme:
Order:
URL: https://acme-staging-v02.api.letsencrypt.org/acme/order/7374163/13665676
Conditions:
Last Transition Time: 2018-11-17T18:05:57Z
Message: Certificate issued successfully
Reason: CertIssued
Status: True
Type: Ready
Events:
Type Reason Age From Message
---- ------ ---- ---- -------
Normal CreateOrder 9m cert-manager Created new ACME order, attempting validation...
Normal DomainVerified 8m cert-manager Domain "www.example.com" verified with "http-01" validation
Normal IssueCert 8m cert-manager Issuing certificate...
Normal CertObtained 7m cert-manager Obtained certificate from ACME server
Normal CertIssued 7m cert-manager Certificate issued Successfully
The events associated with this resource and listed at the bottom
of the describe
results show the state of the request. In the above
example the certificate was validated and issued within a couple of minutes.
Once complete, cert-manager will have created a secret with the details of the certificate based on the secret used in the ingress resource. You can use the describe command as well to see some details:
$ kubectl describe secret quickstart-example-tls
Name: quickstart-example-tls
Namespace: default
Labels: cert-manager.io/certificate-name=quickstart-example-tls
Annotations: cert-manager.io/alt-names=www.example.com
cert-manager.io/common-name=www.example.com
cert-manager.io/issuer-kind=Issuer
cert-manager.io/issuer-name=letsencrypt-staging
Type: kubernetes.io/tls
Data
====
tls.crt: 3566 bytes
tls.key: 1675 bytes
Now that we have confidence that everything is configured correctly, you can update the annotations in the ingress to specify the production issuer:
apiVersion: extensions/v1beta1
kind: Ingress
metadata:
name: kuard
annotations:
kubernetes.io/ingress.class: "nginx"
cert-manager.io/issuer: "letsencrypt-prod"
spec:
tls:
- hosts:
- example.example.com
secretName: quickstart-example-tls
rules:
- host: example.example.com
http:
paths:
- path: /
backend:
serviceName: kuard
servicePort: 80
$ kubectl create --edit -f https://cert-manager.io/docs/tutorials/acme/example/ingress-tls-final.yaml
ingress.extensions "kuard" configured
You will also need to delete the existing secret, which cert-manager is watching and will cause it to reprocess the request with the updated issuer.
$ kubectl delete secret quickstart-example-tls
secret "quickstart-example-tls" deleted
This will start the process to get a new certificate, and using describe you can see the status. Once the production certificate has been updated, you should see the example KUARD running at your domain with a signed TLS certificate.
$ kubectl describe certificate quickstart-example-tls
Name: quickstart-example-tls
Namespace: default
Labels: <none>
Annotations: <none>
API Version: cert-manager.io/v1alpha2
Kind: Certificate
Metadata:
Cluster Name:
Creation Timestamp: 2018-11-17T18:36:48Z
Generation: 0
Owner References:
API Version: extensions/v1beta1
Block Owner Deletion: true
Controller: true
Kind: Ingress
Name: kuard
UID: a3e9f935-ea87-11e8-82f8-42010a8a00b5
Resource Version: 283686
Self Link: /apis/cert-manager.io/v1alpha2/namespaces/default/certificates/quickstart-example-tls
UID: bdd93b32-ea97-11e8-82f8-42010a8a00b5
Spec:
Dns Names:
www.example.com
Issuer Ref:
Kind: Issuer
Name: letsencrypt-prod
Secret Name: quickstart-example-tls
Status:
Conditions:
Last Transition Time: 2019-01-09T13:52:05Z
Message: Certificate does not exist
Reason: NotFound
Status: False
Type: Ready
Events:
Type Reason Age From Message
---- ------ ---- ---- -------
Normal Generated 18s cert-manager Generated new private key
Normal OrderCreated 18s cert-manager Created Order resource "quickstart-example-tls-889745041"
You can see the current state of the ACME Order by running kubectl describe
on the Order resource that cert-manager has created for your Certificate:
$ kubectl describe order quickstart-example-tls-889745041
...
Events:
Type Reason Age From Message
---- ------ ---- ---- -------
Normal Created 90s cert-manager Created Challenge resource "quickstart-example-tls-889745041-0" for domain "www.example.com"
Here, we can see that cert-manager has created 1 ‘Challenge’ resource to fulfill
the Order. You can dig into the state of the current ACME challenge by running
kubectl describe
on the automatically created Challenge resource:
$ kubectl describe challenge quickstart-example-tls-889745041-0
...
Status:
Presented: true
Processing: true
Reason: Waiting for http-01 challenge propagation
State: pending
Events:
Type Reason Age From Message
---- ------ ---- ---- -------
Normal Started 15s cert-manager Challenge scheduled for processing
Normal Presented 14s cert-manager Presented challenge using http-01 challenge mechanism
From above, we can see that the challenge has been ‘presented’ and cert-manager is waiting for the challenge record to propagate to the ingress controller. You should keep an eye out for new events on the challenge resource, as a ‘success’ event should be printed after a minute or so (depending on how fast your ingress controller is at updating rules):
$ kubectl describe challenge quickstart-example-tls-889745041-0
...
Status:
Presented: false
Processing: false
Reason: Successfully authorized domain
State: valid
Events:
Type Reason Age From Message
---- ------ ---- ---- -------
Normal Started 71s cert-manager Challenge scheduled for processing
Normal Presented 70s cert-manager Presented challenge using http-01 challenge mechanism
Normal DomainVerified 2s cert-manager Domain "www.example.com" verified with "http-01" validation
Note: If your challenges are not becoming ‘valid’ and remain in the ‘pending’ state (or enter into a ‘failed’ state), it is likely there is some kind of configuration error. Read the Challenge resource reference docs for more information on debugging failing challenges.
Once the challenge(s) have been completed, their corresponding challenge resources will be deleted, and the ‘Order’ will be updated to reflect the new state of the Order:
$ kubectl describe order quickstart-example-tls-889745041
...
Events:
Type Reason Age From Message
---- ------ ---- ---- -------
Normal Created 90s cert-manager Created Challenge resource "quickstart-example-tls-889745041-0" for domain "www.example.com"
Normal OrderValid 16s cert-manager Order completed successfully
Finally, the ‘Certificate’ resource will be updated to reflect the state of the issuance process. If all is well, you should be able to ‘describe’ the Certificate and see something like the below:
$ kubectl describe certificate quickstart-example-tls
Status:
Conditions:
Last Transition Time: 2019-01-09T13:57:52Z
Message: Certificate is up to date and has not expired
Reason: Ready
Status: True
Type: Ready
Not After: 2019-04-09T12:57:50Z
Events:
Type Reason Age From Message
---- ------ ---- ---- -------
Normal Generated 11m cert-manager Generated new private key
Normal OrderCreated 11m cert-manager Created Order resource "quickstart-example-tls-889745041"
Normal OrderComplete 10m cert-manager Order "quickstart-example-tls-889745041" completed successfully