Prepare Your Environment
You need to do these steps before creating clusters or pairing profiles in the PCE, or subsequent deployment.
Caution
If the prerequisite steps are not done before deployment, then containerized environments and Kubelink can get disrupted.
Unique Machine ID
Some of the functionality and services provided by the Illumio C-VEN and Kubelink depend on the Linux machine-id of each Kubernetes cluster node. Each machine-id must be unique in order to take advantage of the functionality. By default, the Linux operating system generates a random machine-id to give each Linux host uniqueness. However, there are cases when machine-id's can be duplicated across machines. This is common across deployments that clone machines from a golden image, for example, spinning up virtual machines from VMware templates, creating compute instances from a reference image, or from a template from a Public Cloud provider.
Important
Illumio Core requires a unique machine-id on all nodes. This issue is more likely to occur with on-premises or IaaS deployments, rather than with Managed Kubernetes Services (from Cloud Service Providers). For more information on how to create a new unique machine-id, see Troubleshooting.
Create Labels
For details on creating labels, see "Labels and Label Groups" in Security Policy Guide. The labels shown below are used in examples throughout this document. You are not required to use the same labels
Name | Label Type |
---|---|
Kubernetes Cluster | Application |
OpenShift Cluster | Application |
Production | Environment |
Development | Environment |
Data Center | Location |
Cloud | Location |
Kubelink | Role |
Node | Role |
Master | Role |
Worker | Role |
Configure Calico in Append Mode
In case your cluster is configured with Calico as the network plugin (usually for Kubernetes and not for OpenShift), both Calico and Illumio Core will write iptables rules on the cluster nodes.
Calico - Needs to write iptables rules to instruct the host how to forward packets (overlay, IPIP, NAT, and so on).
Illumio Core - Needs to write iptables rules to secure communications between nodes and/or Pods.
You should establish a hierarchy to make the firewall coexistence work smoothly because Illumio Core and Calico will write rules at the same time. By default, both solutions are configured to insert rules first in the iptables chains/tables and Illumio Core will remove other rules added by a third-party software (in the Exclusive mode).
To allow Calico to write rules along with Illumio without flushing rules from one another, you should:
Configure Illumio to work in Firewall Coexistence mode (default for workloads that are part of a container cluster).
Configure Calico to work in Append mode (default is Insert mode).
To configure Calico to work in Append mode with iptables:
Edit the Calico DaemonSet:
kubectl -n kube-system edit ds calico-node
Locate the
spec: > template: > spec: > containers:
section inside theYAML
file and change ChainInsertMode by adding the following code block:- name: FELIX_CHAININSERTMODE value: Append
Save your changes and exit.
Kubernetes will restart all Calico Pods in a rolling update.
For more information on changing Calico ChainInsertMode, see Calico documentation.
Create Illumio Namespace
Create Illumio Namespace
Illumio Core for containers is deployed in a dedicated namespace illumio-system, by default. This namespace has the minimum privileges in the cluster required to run Illumio Core and can tie into the Kubernetes and OpenShift RBAC models.
To create the illumio-system
namespace for Kubernetes, use the following command:
kubectl create namespace illumio-system
Note
Illumio provides a yaml manifest file to create the namespace in the Kubelink tarball illumio-kubelink-namespace.yml
. You can create this namespace by applying this manifest file to your Kubernetes cluster, using the following command:
kubectl apply -f illumio-kubelink-namespace.yml
To create the illumio-system
project for OpenShift, use the following command:
oc new-project illumio-system
Authenticate Kubernetes Cluster with Container Registry
Note
Depending on your deployment, the steps in the Authenticate Kubernetes Cluster with Container Registry, Create a ConfigMap to Store Your Root CA Certificate, and Configure Calico in Append Mode topics are optional.
When storing container images in a private container registry, it is often required and strongly recommended to authenticate against the registry to be able to pull an image from it. In order to do this, the Kubernetes or OpenShift cluster must have the credentials configured and stored in a secret file to be able to pull container images.
To configure a secret to store your container registry credentials, use the following command:
kubectl create secret docker-registry <container-registry-secret-name> -n illumio-system --docker-server=<container-registry> --docker-username=<username> --docker-password=<password>
To verify that the secret has been created, use the following command:
kubectl get secret -n illumio-system | grep <container-registry-secret-name>
Important
The above commands are valid for deployments with your own private container registry, but may not be valid for a cloud-managed private container registry. For more information, refer to your Cloud Service Provider documentation.
Create a ConfigMap to Store Your Root CA Certificate
This section describes how to implement Kubelink with a PCE using a certificate signed by a private PKI. It describes how to configure Kubelink and C-VEN to accept the certificate from the PCE signed by a private root or intermediate Certificate Authority (CA) and ensure that Kubelink can communicate in a secure way with the PCE.
Prerequisites
Access to the root CA to download the root CA certificate.
Access to your Kubernetes cluster and can run
kubectl
commands.Correct privileges in your Kubernetes cluster to create resources like a configmaps, secrets, and Pods.
Access to the PCE web console as a Global Organization Owner.
Download the Root CA Certificate
Before you begin, ensure that you have access to the root CA certificate. The root CA certificate is a file that can be exported from the root CA without compromising the security of the company. It is usually made available to external entities to ensure a proper SSL handshake between a server and its clients.
You can download the root CA cert in the CRT format on your local machine. Below is an example of a root CA certificate:
$ cat root.democa.illumio-demo.com.crt -----BEGIN CERTIFICATE----- MIIGSzCCBDOgAwIBAgIUAPw0NfPAivJW4YmKZ499eHZH3S8wDQYJKoZIhvcNAQEL ---output suppressed--- wPG0lug46K1EPQqMA7YshmrwOd6ESy6RGNFFZdhk9Q== -----END CERTIFICATE-----
You can also get the content of your root CA certificate in a readable output format by using the following command:
$ openssl x509 -text -noout -in ./root.democa.illumio-demo.com.crt Certificate: Data: Version: 3 (0x2) Serial Number: fc:34:35:f3:c0:8a:f2:56:e1:89:8a:67:8f:7d:78:76:47:dd:2f Signature Algorithm: sha256WithRSAEncryption Issuer: C=US, ST=California, L=Sunnyvale, O=Illumio, OU=Technical Marketing, CN=Illumio Demo Root CA 1/[email protected] Validity Not Before: Jan 20 00:05:36 2020 GMT Not After : Jan 17 00:05:36 2030 GMT Subject: C=US, ST=California, L=Sunnyvale, O=Illumio, OU=Technical Marketing, CN=Illumio Demo Root CA 1/[email protected] Subject Public Key Info: Public Key Algorithm: rsaEncryption Public-Key: (4096 bit) Modulus: 00:c0:e5:48:7d:97:f8:5b:8c:ef:ac:16:a8:8c:aa: 68:b8:48:af:28:cd:17:8f:02:c8:82:e9:69:62:e2: 89:2b:be:bd:34:fc:e3:4d:3f:86:5e:d7:e6:89:34: 71:60:e6:54:61:ac:0f:26:1c:99:6f:80:89:3f:36: b3:ad:78:d1:6c:3f:d7:23:1e:ea:51:14:48:74:c3: e8:6e:a2:79:b1:60:4c:65:14:2a:f1:a0:97:6c:97: 50:43:67:07:b7:51:5d:2c:12:49:81:dc:01:c9:d1: 57:48:32:2e:87:a8:d2:c0:b9:f8:43:b2:58:10:af: 54:59:09:05:cb:3e:f0:d7:ef:70:cc:fc:53:48:ee: a4:a4:61:f1:d7:5b:7c:a9:a8:92:dc:77:74:f4:4a: c0:4a:90:71:0f:6d:9e:e7:4f:11:ab:a5:3d:cd:4b: 8b:79:fe:82:1b:16:27:94:8e:35:37:db:dd:b8:fe: fa:6d:d9:be:57:f3:ca:f3:56:aa:be:c8:57:a1:a8: c9:83:dd:5a:96:5a:6b:32:2d:5e:ae:da:fc:85:76: bb:77:d5:c2:53:f3:5b:61:74:e7:f3:3e:4e:ad:10: 7d:4f:ff:90:69:7c:1c:41:2f:67:e4:13:5b:e6:3a: a3:2f:93:61:3b:07:56:59:5a:d9:bc:34:4d:b3:54: b5:c6:e5:0a:88:e9:62:7b:4b:85:d2:9e:4c:ee:0b: 0d:f4:72:b1:1b:44:04:93:cf:cc:bb:18:31:3a:d4: 83:4a:ff:15:42:2d:91:ca:d0:cb:36:d9:8d:62:c0: 41:59:1a:93:c7:27:79:08:94:b2:a2:50:3c:57:27: 33:af:f0:b6:92:44:49:c5:09:15:a7:43:2a:0f:a9: 02:61:b3:66:4f:c3:de:d3:63:1e:08:b1:23:ea:69: 90:db:e8:e9:1e:21:84:e0:56:e1:8e:a1:fa:3f:7a: 08:0f:54:0a:82:41:08:6b:6e:bb:cf:d6:5b:80:c6: ea:0c:80:92:96:ab:95:5d:38:6d:4d:da:38:6b:42: ef:7c:88:58:83:88:6d:da:28:62:62:1f:e5:a7:0d: 04:9f:0d:d9:52:39:46:ba:56:7c:1d:77:38:26:7c: 86:69:58:4d:b0:47:3a:e2:be:ee:1a:fc:4c:de:67: f3:d5:fe:e6:27:a2:ef:26:86:19:5b:05:85:9c:4c: 02:24:76:58:42:1a:f8:e0:e0:ed:78:f2:8f:c8:5a: 20:a9:2d:0b:d4:01:fa:57:d4:6f:1c:0a:31:30:8c: 32:7f:b0:01:1e:fe:94:96:03:ee:01:d7:f4:4a:83: f5:06:fa:60:43:15:05:9a:ca:88:59:5c:f5:13:09: 82:69:7f Exponent: 65537 (0x10001) X509v3 extensions: X509v3 Subject Key Identifier: 3D:3D:3D:61:E6:88:09:FE:34:0F:1D:5E:5E:52:72:71:C7: DE:15:92 X509v3 Authority Key Identifier: keyid:3D:3D:3D:61:E6:88:09:FE:34:0F:1D:5E:5E:52:72:71: C7:DE:15:92 X509v3 Basic Constraints: critical CA:TRUE X509v3 Key Usage: critical Digital Signature, Certificate Sign, CRL Sign Signature Algorithm: sha256WithRSAEncryption 28:24:86:91:a6:4a:88:e4:8d:6b:fc:67:2a:68:08:67:35:e5: a6:77:ff:07:4b:89:53:99:2e:6d:95:df:12:81:28:6a:8e:6f: 5a:98:95:5b:4a:21:ae:f0:20:a4:4e:06:b2:4e:5a:67:c1:6a: 06:f1:0f:c1:f7:7e:f2:e0:b3:9d:d8:54:26:6a:b2:1c:19:b8: b5:5c:c7:03:6b:f7:70:9e:72:85:c9:29:55:f9:f4:a4:f2:b4: 3b:3d:ce:25:96:67:32:1e:8d:e2:00:22:55:4b:05:4f:ee:0e: 67:ac:db:1b:61:da:5f:9c:10:1c:0c:05:66:c0:5b:5f:b9:95: 59:a9:58:5b:e7:69:ac:b0:bd:b3:c2:a3:35:58:01:a4:ff:c0: 8d:ac:1c:19:21:41:50:fb:8e:e0:f5:a9:ad:ec:de:cb:53:04: a9:d8:ac:76:8a:09:0d:7c:c6:1a:bc:06:74:bb:10:1c:aa:07: f6:cb:b2:1b:0c:0c:65:03:45:2b:51:d5:6e:a0:4d:91:ce:c5: ed:8d:a9:e7:f6:37:7d:ab:1b:a4:a2:a3:3b:76:17:5b:d9:3a: 9c:c1:df:cc:cd:a0:b0:a9:5c:74:61:d7:a0:1d:04:67:68:ee: a6:7b:1e:41:a4:02:fc:65:9e:e3:c1:c2:57:b2:2e:b0:ff:a9: 86:82:35:4d:29:b2:fe:74:2e:b8:37:5d:2b:e8:69:f2:80:29: 19:f1:1e:7a:5d:e3:d2:51:50:46:30:54:7e:b8:ad:59:61:24: 45:a8:5a:fe:19:ff:09:31:d0:50:8b:e2:15:c0:a2:f1:20:95: 63:55:18:a7:a2:ad:16:25:c7:a3:d1:f2:e5:be:6d:c0:50:4b: 15:ac:e0:10:5e:f3:7b:90:9c:75:1a:6b:e3:fb:39:88:e4:e6: 9f:4c:85:60:67:e8:7d:2e:85:3d:87:ed:06:1d:13:0b:76:d7: 97:a5:b8:05:76:67:d6:41:06:c5:c0:7a:bd:f4:c6:5b:b2:fd: 23:6f:1f:57:2e:df:95:3f:26:a5:13:4d:6d:96:12:56:98:db: 2e:7d:fd:56:f5:71:b7:19:2b:c9:de:2d:b9:c8:17:cc:20:de: 7c:19:7a:aa:12:97:1c:80:b7:d3:67:d3:b7:a7:96:f0:c9:4d: f5:8b:0e:10:3b:b9:4e:09:90:5a:3b:51:c9:48:a2:ca:9f:db: 72:44:87:59:db:49:fa:75:44:b5:f6:7f:c5:26:e1:01:ae:7b: 6f:4a:75:d1:b5:b3:68:c0:31:48:f8:5c:06:c0:f1:b4:96:e8: 38:e8:ad:44:3d:0a:8c:03:b6:2c:86:6a:f0:39:de:84:4b:2e: 91:18:d1:45:65:d8:64:f5
Create a configmap in Kubernetes Cluster
After downloading the certificate locally on your machine, create a configmap in the Kubernetes cluster that will copy the root CA certificate on your local machine into the Kubernetes cluster.
To create configmap, use the following command:
$ kubectl -n illumio-system create configmap root-ca-config \ --from-file=./certs/root.democa.illumio-demo.com.crt
The --from-file
option points to the path where the root CA certificate is stored on your local machine.
To verify that configmap was created correctly, use the following command:
$ kubectl -n illumio-system create configmap root-ca-config \ > --from-file=./certs/root.democa.illumio-demo.com.crt configmap/root-ca-config created $ $ kubectl -n illumio-system get configmap NAME DATA AGE root-ca-config 1 12s $ $ kubectl -n illumio-system describe configmap root-ca-config Name: root-ca-config Namespace: illumio-system Labels: <none> Annotations: <none> Data ==== root.democa.illumio-demo.com.crt: ---- -----BEGIN CERTIFICATE----- MIIGSzCCBDOgAwIBAgIUAPw0NfPAivJW4YmKZ499eHZH3S8wDQYJKoZIhvcNAQEL ---output suppressed--- wPG0lug46K1EPQqMA7YshmrwOd6ESy6RGNFFZdhk9Q== -----END CERTIFICATE----- Events: <none> $
root-ca-config
is the name used to designate configmap. You can modify it according to your naming convention.
Configure Calico in Append Mode
In case your cluster is configured with Calico as the network plugin (usually for Kubernetes and not for OpenShift), both Calico and Illumio Core will write iptables rules on the cluster nodes.
Calico - Needs to write iptables rules to instruct the host how to forward packets (overlay, IPIP, NAT, and so on).
Illumio Core - Needs to write iptables rules to secure communications between nodes and/or Pods.
You should establish a hierarchy to make the firewall coexistence work smoothly because Illumio Core and Calico will write rules at the same time. By default, both solutions are configured to insert rules first in the iptables chains/tables and Illumio Core will remove other rules added by a third-party software (in the Exclusive mode).
To allow Calico to write rules along with Illumio without flushing rules from one another, you should:
Configure Illumio to work in Firewall Coexistence mode (default for workloads that are part of a container cluster).
Configure Calico to work in Append mode (default is Insert mode).
To configure Calico to work in Append mode with iptables:
Edit the calico DaemonSet.
kubectl -n kube-system edit ds calico-node
Locate the
spec: > template: > spec: > containers:
section inside theYAML
file and change ChainInsertMode by adding the following code block:- name: FELIX_CHAININSERTMODE value: Append
Save your changes and exit.
Kubernetes will restart all Calico Pods in a rolling update.
For more information on changing Calico ChainInsertMode, see Calico documentation.