# Hooks Helm provides a _hook_ mechanism to allow chart developers to intervene at certain points in a release's life cycle. For example, you can use hooks to: - Load a ConfigMap or Secret during install before any other charts are loaded. - Execute a Job to back up a database before installing a new chart, and then execute a second job after the upgrade in order to restore data. - Run a Job before deleting a release to gracefully take a service out of rotation before removing it. Hooks work like regular templates, but they have special annotations that cause Helm to utilize them differently. In this section, we cover the basic usage pattern for hooks. ## The Available Hooks The following hooks are defined: - pre-install: Executes after templates are rendered, but before any resources are created in Kubernetes. - post-install: Executes after all resources are loaded into Kubernetes - pre-delete: Executes on a deletion request before any resources are deleted from Kubernetes. - post-delete: Executes on a deletion request after all of the release's resources have been deleted. - pre-upgrade: Executes on an upgrade request after templates are rendered, but before any resources are loaded into Kubernetes (e.g. before a Kubernetes apply operation). - post-upgrade: Executes on an upgrade after all resources have been upgraded. - pre-rollback: Executes on a rollback request after templates are rendered, but before any resources have been rolled back. - post-rollback: Executes on a rollback request after all resources have been modified. ## Hooks and the Release Lifecycle Hooks allow you, the chart developer, an opportunity to perform operations at strategic points in a release lifecycle. For example, consider the lifecycle for a `helm install`. By default, the lifecycle looks like this: 1. User runs `helm install foo` 2. Chart is loaded into Tiller 3. After some verification, Tiller renders the `foo` templates 4. Tiller loads the resulting resources into Kubernetes 5. Tiller returns the release name (and other data) to the client 6. The client exits Helm defines two hooks for the `install` lifecycle: `pre-install` and `post-install`. If the developer of the `foo` chart implements both hooks, the lifecycle is altered like this: 1. User runs `helm install foo` 2. Chart is loaded into Tiller 3. After some verification, Tiller renders the `foo` templates 4. Tiller executes the `pre-install` hook (loading hook resources into Kubernetes) 5. Tiller waits until the hook is "Ready" 6. Tiller loads the resulting resources into Kubernetes. Note that if the `--wait` flag is set, Tiller will wait until all resources are in a ready state and will not run the `post-install` hook until they are ready. 7. Tiller executes the `post-install` hook (loading hook resources) 8. Tiller waits until the hook is "Ready" 9. Tiller returns the release name (and other data) to the client 10. The client exits What does it mean to wait until a hook is ready? This depends on the resource declared in the hook. If the resources is a `Job` kind, Tiller will wait until the job successfully runs to completion. And if the job fails, the release will fail. This is a _blocking operation_, so the Helm client will pause while the Job is run. For all other kinds, as soon as Kubernetes marks the resource as loaded (added or updated), the resource is considered "Ready". When many resources are declared in a hook, the resources are executed serially, but the order of their execution is not guaranteed. ### Hook resources are unmanaged The resources that a hook creates are not tracked or managed as part of the release. Once Tiller verifies that the hook has reached its ready state, it will leave the hook resource alone. Practically speaking, this means that if you create resources in a hook, you cannot rely upon `helm delete` to remove the resources. To destroy such resources, you need to write code to perform this operation in a `pre-delete` or `post-delete` hook. ## Writing a Hook Hooks are just Kubernetes manifest files with special annotations in the `metadata` section. Because they are template files, you can use all of the normal template features, including reading `.Values`, `.Release`, and `.Template`. For example, this template, stored in `templates/post-install-job.yaml`, declares a job to be run on `post-install`: ```yaml apiVersion: batch/v1 kind: Job metadata: name: "{{.Release.Name}}" labels: heritage: {{.Release.Service | quote }} release: {{.Release.Name | quote }} chart: "{{.Chart.Name}}-{{.Chart.Version}}" annotations: # This is what defines this resource as a hook. Without this line, the # job is considered part of the release. "helm.sh/hook": post-install spec: template: metadata: name: "{{.Release.Name}}" labels: heritage: {{.Release.Service | quote }} release: {{.Release.Name | quote }} chart: "{{.Chart.Name}}-{{.Chart.Version}}" spec: restartPolicy: Never containers: - name: post-install-job image: "alpine:3.3" command: ["/bin/sleep","{{default "10" .Values.sleepyTime}}"] ``` What makes this template a hook is the annotation: ``` annotations: "helm.sh/hook": post-install ``` One resource can implement multiple hooks: ``` annotations: "helm.sh/hook": post-install,post-upgrade ``` Similarly, there is no limit to the number of different resources that may implement a given hook. For example, one could declare both a secret and a config map as a pre-install hook. It is important to keep in mind, though, that there are no ordering guarantees about hooks. When subcharts declare hooks, those are also evaluated. There is no way for a top-level chart to disable the hooks declared by subcharts. And again, there is no guaranteed ordering.