Named Templates

It is time to move beyond one template, and begin to create others. In this section, we will see how to define named templates in one file, and then use them elsewhere. A named template (sometimes called a partial or a subtemplate) is simply a template defined inside of a file, and given a name. We'll see two ways to create them, and a few different ways to use them.

In the Flow Control section we introduced three actions for declaring and managing templates: define, template, and block. In this section, we'll cover those three actions, and also introduce a special-purpose include function that works similarly to the template action.

An important detail to keep in mind when naming templates: template names are global. If you declare two templates with the same name, whichever one is loaded last will be the one used. Because templates in subcharts are compiled together with top-level templates, you should be careful to name your templates with chart-specific names.

One popular naming convention is to prefix each defined template with the name of the chart: {{ define "mychart.labels" }}. By using the specific chart name as a prefix we can avoid any conflicts that may arise due to two different charts that implement templates of the same name.

This behavior also applies to different versions of a chart. If you have mychart version 1.0.0 that defines a template one way, and a mychart version 2.0.0 that modifies the existing named template, it will use the one that was loaded last. You can work around this issue by also adding a version in the name of the chart: {{ define "mychart.v1.labels" }} and {{ define "mychart.v2.labels" }}.

Partials and _ files

So far, we've used one file, and that one file has contained a single template. But Helm's template language allows you to create named embedded templates, that can be accessed by name elsewhere.

Before we get to the nuts-and-bolts of writing those templates, there is file naming convention that deserves mention:

  • Most files in templates/ are treated as if they contain Kubernetes manifests
  • The NOTES.txt is one exception
  • But files whose name begins with an underscore (_) are assumed to not have a manifest inside. These files are not rendered to Kubernetes object definitions, but are available everywhere within other chart templates for use.

These files are used to store partials and helpers. In fact, when we first created mychart, we saw a file called _helpers.tpl. That file is the default location for template partials.

Declaring and using templates with define and template

The define action allows us to create a named template inside of a template file. Its syntax goes like this:

{{- define "MY.NAME" }}
  # body of template here
{{- end }}

For example, we can define a template to encapsulate a Kubernetes block of labels:

{{- define "mychart.labels" }}
  labels:
    generator: helm
    date: {{ now | htmlDate }}
{{- end }}

Now we can embed this template inside of our existing ConfigMap, and then include it with the template action:

{{- define "mychart.labels" }}
  labels:
    generator: helm
    date: {{ now | htmlDate }}
{{- end }}
apiVersion: v1
kind: ConfigMap
metadata:
  name: {{ .Release.Name }}-configmap
  {{- template "mychart.labels" }}
data:
  myvalue: "Hello World"
  {{- range $key, $val := .Values.favorite }}
  {{ $key }}: {{ $val | quote }}
  {{- end }}

When the template engine reads this file, it will store away the reference to mychart.labels until template "mychart.labels" is called. Then it will render that template inline. So the result will look like this:

# Source: mychart/templates/configmap.yaml
apiVersion: v1
kind: ConfigMap
metadata:
  name: running-panda-configmap
  labels:
    generator: helm
    date: 2016-11-02
data:
  myvalue: "Hello World"
  drink: "coffee"
  food: "pizza"

Note: a define does not produce output unless it is called with a template, as in this example.

Conventionally, Helm charts put these templates inside of a partials file, usually _helpers.tpl. Let's move this function there:

{{/* Generate basic labels */}}
{{- define "mychart.labels" }}
  labels:
    generator: helm
    date: {{ now | htmlDate }}
{{- end }}

By convention, define functions should have a simple documentation block ({{/* ... */}}) describing what they do.

Even though this definition is in _helpers.tpl, it can still be accessed in configmap.yaml:

apiVersion: v1
kind: ConfigMap
metadata:
  name: {{ .Release.Name }}-configmap
  {{- template "mychart.labels" }}
data:
  myvalue: "Hello World"
  {{- range $key, $val := .Values.favorite }}
  {{ $key }}: {{ $val | quote }}
  {{- end }}

As mentioned above, template names are global. As a result of this, if two templates are declared with the same name the last occurrence will be the one that is used. Since templates in subcharts are compiled together with top-level templates, it is best to name your templates with chart specific names. A popular naming convention is to prefix each defined template with the name of the chart: {{ define "mychart.labels" }}.

Setting the scope of a template

In the template we defined above, we did not use any objects. We just used functions. Let's modify our defined template to include the chart name and chart version:

{{/* Generate basic labels */}}
{{- define "mychart.labels" }}
  labels:
    generator: helm
    date: {{ now | htmlDate }}
    chart: {{ .Chart.Name }}
    version: {{ .Chart.Version }}
{{- end }}

If we render this, we will get an error like this:

$ helm install --dry-run moldy-jaguar ./mychart
Error: unable to build kubernetes objects from release manifest: error validating "": error validating data: [unknown object type "nil" in ConfigMap.metadata.labels.chart, unknown object type "nil" in ConfigMap.metadata.labels.version]

To see what rendered, re-run with --disable-openapi-validation: helm install --dry-run --disable-openapi-validation moldy-jaguar ./mychart. The result will not be what we expect:

# Source: mychart/templates/configmap.yaml
apiVersion: v1
kind: ConfigMap
metadata:
  name: moldy-jaguar-configmap
  labels:
    generator: helm
    date: 2021-03-06
    chart:
    version:

What happened to the name and version? They weren't in the scope for our defined template. When a named template (created with define) is rendered, it will receive the scope passed in by the template call. In our example, we included the template like this:

{{- template "mychart.labels" }}

No scope was passed in, so within the template we cannot access anything in .. This is easy enough to fix, though. We simply pass a scope to the template:

apiVersion: v1
kind: ConfigMap
metadata:
  name: {{ .Release.Name }}-configmap
  {{- template "mychart.labels" . }}

Note that we pass . at the end of the template call. We could just as easily pass .Values or .Values.favorite or whatever scope we want. But what we want is the top-level scope.

Now when we execute this template with helm install --dry-run --debug plinking-anaco ./mychart, we get this:

# Source: mychart/templates/configmap.yaml
apiVersion: v1
kind: ConfigMap
metadata:
  name: plinking-anaco-configmap
  labels:
    generator: helm
    date: 2021-03-06
    chart: mychart
    version: 0.1.0

Now {{ .Chart.Name }} resolves to mychart, and {{ .Chart.Version }} resolves to 0.1.0.

The include function

Say we've defined a simple template that looks like this:

{{- define "mychart.app" -}}
app_name: {{ .Chart.Name }}
app_version: "{{ .Chart.Version }}"
{{- end -}}

Now say I want to insert this both into the labels: section of my template, and also the data: section:

apiVersion: v1
kind: ConfigMap
metadata:
  name: {{ .Release.Name }}-configmap
  labels:
    {{ template "mychart.app" . }}
data:
  myvalue: "Hello World"
  {{- range $key, $val := .Values.favorite }}
  {{ $key }}: {{ $val | quote }}
  {{- end }}
{{ template "mychart.app" . }}

If we render this, we will get an error like this:

$ helm install --dry-run measly-whippet ./mychart
Error: unable to build kubernetes objects from release manifest: error validating "": error validating data: [ValidationError(ConfigMap): unknown field "app_name" in io.k8s.api.core.v1.ConfigMap, ValidationError(ConfigMap): unknown field "app_version" in io.k8s.api.core.v1.ConfigMap]

To see what rendered, re-run with --disable-openapi-validation: helm install --dry-run --disable-openapi-validation measly-whippet ./mychart. The output will not be what we expect:

# Source: mychart/templates/configmap.yaml
apiVersion: v1
kind: ConfigMap
metadata:
  name: measly-whippet-configmap
  labels:
    app_name: mychart
app_version: "0.1.0"
data:
  myvalue: "Hello World"
  drink: "coffee"
  food: "pizza"
app_name: mychart
app_version: "0.1.0"

Note that the indentation on app_version is wrong in both places. Why? Because the template that is substituted in has the text aligned to the left. Because template is an action, and not a function, there is no way to pass the output of a template call to other functions; the data is simply inserted inline.

To work around this case, Helm provides an alternative to template that will import the contents of a template into the present pipeline where it can be passed along to other functions in the pipeline.

Here's the example above, corrected to use indent to indent the mychart.app template correctly:

apiVersion: v1
kind: ConfigMap
metadata:
  name: {{ .Release.Name }}-configmap
  labels:
{{ include "mychart.app" . | indent 4 }}
data:
  myvalue: "Hello World"
  {{- range $key, $val := .Values.favorite }}
  {{ $key }}: {{ $val | quote }}
  {{- end }}
{{ include "mychart.app" . | indent 2 }}

Now the produced YAML is correctly indented for each section:

# Source: mychart/templates/configmap.yaml
apiVersion: v1
kind: ConfigMap
metadata:
  name: edgy-mole-configmap
  labels:
    app_name: mychart
    app_version: "0.1.0"
data:
  myvalue: "Hello World"
  drink: "coffee"
  food: "pizza"
  app_name: mychart
  app_version: "0.1.0"

It is considered preferable to use include over template in Helm templates simply so that the output formatting can be handled better for YAML documents.

Sometimes we want to import content, but not as templates. That is, we want to import files verbatim. We can achieve this by accessing files through the .Files object described in the next section.