README
¶
k8s-admission-webhook 
| Kubernetes version | v1.9 | v1.10 | v1.11 | v1.12 | v1.13 |
|---|---|---|---|---|---|
| Build status |
A general-purpose Kubernetes admission webhook to aid with enforcing best practices within your cluster.
Apart from webhook validation, this tool can also do one-time outside of cluster scan for objects that are violating validation rules.
Can be set up to validate that:
- containers have their resource limits specified (
memory,cpu) - containers have their resource requests specified (
memory,cpu) - containers have readonly root filesystem
- ingress rules hosts and paths match regex
- ingress rules hosts and paths are not in collision with definitions already in the cluster
- ingress tls hosts match regex
- ingress tls hosts are not in collision with definitions already in the cluster
Resource spec validation operates on:
PodsDeploymentsReplicaSetsDaemonSetsJobsCronJobsStatefulSets
Host and path validation operates on:
Ingresses
Introduction
As per Kubernetes docs, admission webhooks are
HTTP callbacks that receive admission requests and do something with them. You can define two types of admission webhooks, validating admission webhook and mutating admission webhook. With validating admission Webhooks, you may reject requests to enforce custom admission policies. With mutating admission Webhooks, you may change requests to enforce custom defaults.
This implementation currently acts as a validating admission webhook to validate resources against a predefined opinionated set of rules that have to be individually enabled.
Configuration options
The webhook application can be configured using the flags outlined below.
Note that every option can also be specified via an environment variable. Environment variables should be in uppercase, using _ instead of - as seen in the flag name. E.g.: --rule-resource-limit-cpu-required can be alternatively set via an environment variable RULE_RESOURCE_LIMIT_CPU_REQUIRED=1.
--listen-port int32 Port to listen on. (default 443)
--no-tls Do not use TLS.
--rule-resource-limit-cpu-must-be-nonzero Whether 'cpu' limit in resource specifications must be a nonzero value.
--rule-resource-limit-cpu-required Whether 'cpu' limit in resource specifications is required.
--rule-resource-limit-memory-must-be-nonzero Whether 'memory' limit in resource specifications must be a nonzero value.
--rule-resource-limit-memory-required Whether 'memory' limit in resource specifications is required.
--rule-resource-request-cpu-must-be-nonzero Whether 'cpu' request in resource specifications must be a nonzero value.
--rule-resource-request-cpu-required Whether 'cpu' request in resource specifications is required.
--rule-resource-request-memory-must-be-nonzero Whether 'memory' request in resource specifications must be a nonzero value.
--rule-resource-request-memory-required Whether 'memory' request in resource specifications is required.
--rule-security-readonly-rootfs-required Whether 'readOnlyRootFilesystem' in security context specifications is required.
--rule-security-readonly-rootfs-required-whitelist-enabled Whether rule 'readOnlyRootFilesystem' in security context can be ignored by container whitelisting.
--rule-resource-violation-message Additional message to be included whenever any of the resource-related rules are violated.
--rule-ingress-collision Whether ingress tls and host collision should be checked
--rule-ingress-violation-message Additional message to be included whenever any of the ingress-related rules are violated.
--tls-cert-file string Path to the certificate file. Required, unless --no-tls is set.
--tls-private-key-file string Path to the certificate key file. Required, unless --no-tls is set.
--annotations-prefix What prefix should be used for admission validation annotations.
In case you want to check readOnlyRootFilesystem property globally but also allow some containers requiring writable root filesystem, they can be whitelisted by using annotations.
In order to do that you need to:
- Allow whitelisting of containers for this option by
--rule-security-readonly-rootfs-required-whitelist-enabledoption - Provide annotation
admission.validation.avast.com/readonly-rootfs-containers-whitelistat Pod level (prefix can be changed by--annotations-prefixoption)
Example usage:
apiVersion: v1
kind: Pod
metadata:
name: pod-name
namespace: test
annotations:
admission.validation.avast.com/readonly-rootfs-containers-whitelist: "container-name-1, container-name-2"
spec:
containers:
- name: container-name-1
image: .....
command: .....
resources:
.....
- name: container-name-2
image: .....
command: .....
resources:
.....
Installation
The following instructions assume that you will want to deploy the admission webhook inside the cluster, running as a Kubernetes service.
The following Kubernetes resources need to be set up:
- A
Deploymentwith the actual webhook container. It runs the HTTP server, which must use TLS with a certificate signed by the Kubernetes cluster CA. - A
Service. - A
ValidatingWebhookConfiguration, specifying which resource types are to be validated, pointing to the webhook'sService. Its configuration must include the cluster's CA bundle.
Because of the above, the necessary Kubernetes manifests will vary based on your cluster configuration.
Example configuration
See test/webhook.template.yaml, which contains an example definition of the various Kubernetes resources that might be typically involved when configuring the webhook.
Certain places of the example configuration YAML contain references to variables:
${WEBHOOK_IMAGE_NAME}(inDeployment): the Docker image name, e.g.avastsoftware/k8s-admission-webhook:v0.0.1${WEBHOOK_TLS_CERT}(in theConfigMap) and${WEBHOOK_TLS_PRIVATE_KEY_B64}in the (Secret): webhook server's TLS certificate- You can generate an appropriate certificate by running
./test/create-signed-cert.sh --namespace default --service k8s-admission-webhook.default.svc. You'll need to havekubectlon yourPATH, with its current context pointing at the target cluster. --namespaceand--servicein the above command need to reflect the namespace and name of webhook'sService, and also need to match the related configuration in theValidatingWebhookConfigurationand theServiceitself.- Running the above command will drop
test/server-cert.pemandtest/server-key.pem, which correspond to the server certificate and its private key, respectively. ${WEBHOOK_TLS_CERT}(in theConfigMap) is the contents of the generatedtest/server-cert.pem.${WEBHOOK_TLS_PRIVATE_KEY_B64}(in theSecret) is the base-64 encoded contents of the generatedtest/server-key.pem. (E.g.WEBHOOK_TLS_PRIVATE_KEY_B64=$(cat test/server-key.pem | base64 | tr -d '\n'))
- You can generate an appropriate certificate by running
${WEBHOOK_CA_BUNDLE}(inValidatingWebhookConfiguration) is the cluster's CA bundle.- This can be retrieved by running
$(kubectl get configmap -n kube-system extension-apiserver-authentication -o=jsonpath='{.data.client-ca-file}' | base64 | tr -d '\n'). You'll need to havekubectlon yourPATH, with its current context pointing at the target cluster.
- This can be retrieved by running
On-demand outside of cluster scan
This tool provides also function to scan cluster (based on current context from ~/.kube/config) for objects that are violating given rules.
Usage:
- Create binary via
make build-binary - Run
./k8s-admission-webhook scanner [options]
Configuration options for cluster scanner:
--namespace Whether specific namespace should be scanned. If omitted, all namespaces are scanned.
--rule-resource-limit-cpu-must-be-nonzero Whether 'cpu' limit in resource specifications must be a nonzero value.
--rule-resource-limit-cpu-required Whether 'cpu' limit in resource specifications is required.
--rule-resource-limit-memory-must-be-nonzero Whether 'memory' limit in resource specifications must be a nonzero value.
--rule-resource-limit-memory-required Whether 'memory' limit in resource specifications is required.
--rule-resource-request-cpu-must-be-nonzero Whether 'cpu' request in resource specifications must be a nonzero value.
--rule-resource-request-cpu-required Whether 'cpu' request in resource specifications is required.
--rule-resource-request-memory-must-be-nonzero Whether 'memory' request in resource specifications must be a nonzero value.
--rule-resource-request-memory-required Whether 'memory' request in resource specifications is required.
--rule-security-readonly-rootfs-required Whether 'readOnlyRootFilesystem' in security context specifications is required.
--rule-security-readonly-rootfs-required-whitelist-enabled Whether rule 'readOnlyRootFilesystem' in security context can be ignored by container whitelisting.
--rule-resource-violation-message Additional message to be included whenever any of the resource-related rules are violated.
--rule-ingress-collision Whether ingress tls and host collision should be checked
--rule-ingress-violation-message Additional message to be included whenever any of the ingress-related rules are violated.
--annotations-prefix What prefix should be used for admission validation annotations.
Note that every option can also be specified via an environment variable. Environment variables should be in uppercase, using _ instead of - as seen in the flag name. E.g.: --rule-resource-limit-cpu-required can be alternatively set via an environment variable RULE_RESOURCE_LIMIT_CPU_REQUIRED=1.
Development
The webhook is written in Go and uses Glide for dependency management.
Development cluster & webhook deployment automation
One of the more convenient ways to spin up a dev Kubernetes cluster for local testing is kubeadm-dind-cluster, which runs the cluster using Docker-in-Docker. Makefile targets in this project make use of it to aid with most common development tasks and also enable running integration tests in Travis. You can use the more traditional minikube if you want, but you'll need to set up the webhook manually or write your own automation scripts.
These are some make targets intended to be used during local development. Note that they require docker, wget, openssl and envsubst on your PATH and have only been tested on Linux.
make dev-start: Starts the Docker-in-Docker Kubernetes cluster.make deploy-webhook-for-test: Builds the webhook Docker image and configures the local cluster to use it. This is one of the more involved scripts because it includes generation of an appropriate TLS certificate, retrieving cluster's CA bundle and injecting those into the webhook config. Also, pushes the image to a temporary Docker registry reachable from within the local cluster.make dev-stop: Stops the local cluster and performs additional cleanup.
Running the end-to-end tests
On the CI server, end-to-end tests are run via:
make ci-e2e-test KUBERNETES_VERSION=1.13
Tests can currently run against versions 1.9 to 1.13 (see .travis.yml for more details).
While ci-e2e-test spins up the whole cluster on every run, a more convenient workflow to run end-to-end tests during
local development is available via:
make dev-start- make changes to code +
make dev-e2e-test, rinse and repeat make dev-stop(cleans up the development cluster)
Why Glide for Go dependency management?
This project makes use of the official Go client for Kubernetes, which as of this writing does not support the now-standard dep for dependency management. This is discussed in more detail in the "Dep (Not supported yet!)" section of client-go's installation docs, which also suggest Glide as a viable alternative.
License
Copyright © 2018, Petr Krebs, Avast Software. Released under the MIT License.
Documentation
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