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Expose Pod Information to Containers Through Files
This page shows how a Pod can use a
downwardAPI
volume,
to expose information about itself to containers running in the Pod.
A downwardAPI
volume can expose Pod fields and container fields.
In Kubernetes, there are two ways to expose Pod and container fields to a running container:
- Environment variables
- Volume files, as explained in this task
Together, these two ways of exposing Pod and container fields are called the downward API.
Before you begin
You need to have a Kubernetes cluster, and the kubectl command-line tool must be configured to communicate with your cluster. It is recommended to run this tutorial on a cluster with at least two nodes that are not acting as control plane hosts. If you do not already have a cluster, you can create one by using minikube or you can use one of these Kubernetes playgrounds:
Store Pod fields
In this part of exercise, you create a Pod that has one container, and you project Pod-level fields into the running container as files. Here is the manifest for the Pod:
apiVersion: v1
kind: Pod
metadata:
name: kubernetes-downwardapi-volume-example
labels:
zone: us-est-coast
cluster: test-cluster1
rack: rack-22
annotations:
build: two
builder: john-doe
spec:
containers:
- name: client-container
image: registry.k8s.io/busybox
command: ["sh", "-c"]
args:
- while true; do
if [[ -e /etc/podinfo/labels ]]; then
echo -en '\n\n'; cat /etc/podinfo/labels; fi;
if [[ -e /etc/podinfo/annotations ]]; then
echo -en '\n\n'; cat /etc/podinfo/annotations; fi;
sleep 5;
done;
volumeMounts:
- name: podinfo
mountPath: /etc/podinfo
volumes:
- name: podinfo
downwardAPI:
items:
- path: "labels"
fieldRef:
fieldPath: metadata.labels
- path: "annotations"
fieldRef:
fieldPath: metadata.annotations
In the manifest, you can see that the Pod has a downwardAPI
Volume,
and the container mounts the volume at /etc/podinfo
.
Look at the items
array under downwardAPI
. Each element of the array
defines a downwardAPI
volume.
The first element specifies that the value of the Pod's
metadata.labels
field should be stored in a file named labels
.
The second element specifies that the value of the Pod's annotations
field should be stored in a file named annotations
.
Create the Pod:
kubectl apply -f https://k8s.io/examples/pods/inject/dapi-volume.yaml
Verify that the container in the Pod is running:
kubectl get pods
View the container's logs:
kubectl logs kubernetes-downwardapi-volume-example
The output shows the contents of the labels
file and the annotations
file:
cluster="test-cluster1"
rack="rack-22"
zone="us-est-coast"
build="two"
builder="john-doe"
Get a shell into the container that is running in your Pod:
kubectl exec -it kubernetes-downwardapi-volume-example -- sh
In your shell, view the labels
file:
/# cat /etc/podinfo/labels
The output shows that all of the Pod's labels have been written
to the labels
file:
cluster="test-cluster1"
rack="rack-22"
zone="us-est-coast"
Similarly, view the annotations
file:
/# cat /etc/podinfo/annotations
View the files in the /etc/podinfo
directory:
/# ls -laR /etc/podinfo
In the output, you can see that the labels
and annotations
files
are in a temporary subdirectory: in this example,
..2982_06_02_21_47_53.299460680
. In the /etc/podinfo
directory, ..data
is
a symbolic link to the temporary subdirectory. Also in the /etc/podinfo
directory,
labels
and annotations
are symbolic links.
drwxr-xr-x ... Feb 6 21:47 ..2982_06_02_21_47_53.299460680
lrwxrwxrwx ... Feb 6 21:47 ..data -> ..2982_06_02_21_47_53.299460680
lrwxrwxrwx ... Feb 6 21:47 annotations -> ..data/annotations
lrwxrwxrwx ... Feb 6 21:47 labels -> ..data/labels
/etc/..2982_06_02_21_47_53.299460680:
total 8
-rw-r--r-- ... Feb 6 21:47 annotations
-rw-r--r-- ... Feb 6 21:47 labels
Using symbolic links enables dynamic atomic refresh of the metadata; updates are
written to a new temporary directory, and the ..data
symlink is updated
atomically using rename(2).
Exit the shell:
/# exit
Store container fields
The preceding exercise, you made Pod-level fields accessible using the downward API. In this next exercise, you are going to pass fields that are part of the Pod definition, but taken from the specific container rather than from the Pod overall. Here is a manifest for a Pod that again has just one container:
apiVersion: v1
kind: Pod
metadata:
name: kubernetes-downwardapi-volume-example-2
spec:
containers:
- name: client-container
image: registry.k8s.io/busybox:1.24
command: ["sh", "-c"]
args:
- while true; do
echo -en '\n';
if [[ -e /etc/podinfo/cpu_limit ]]; then
echo -en '\n'; cat /etc/podinfo/cpu_limit; fi;
if [[ -e /etc/podinfo/cpu_request ]]; then
echo -en '\n'; cat /etc/podinfo/cpu_request; fi;
if [[ -e /etc/podinfo/mem_limit ]]; then
echo -en '\n'; cat /etc/podinfo/mem_limit; fi;
if [[ -e /etc/podinfo/mem_request ]]; then
echo -en '\n'; cat /etc/podinfo/mem_request; fi;
sleep 5;
done;
resources:
requests:
memory: "32Mi"
cpu: "125m"
limits:
memory: "64Mi"
cpu: "250m"
volumeMounts:
- name: podinfo
mountPath: /etc/podinfo
volumes:
- name: podinfo
downwardAPI:
items:
- path: "cpu_limit"
resourceFieldRef:
containerName: client-container
resource: limits.cpu
divisor: 1m
- path: "cpu_request"
resourceFieldRef:
containerName: client-container
resource: requests.cpu
divisor: 1m
- path: "mem_limit"
resourceFieldRef:
containerName: client-container
resource: limits.memory
divisor: 1Mi
- path: "mem_request"
resourceFieldRef:
containerName: client-container
resource: requests.memory
divisor: 1Mi
In the manifest, you can see that the Pod has a
downwardAPI
volume,
and that the single container in that Pod mounts the volume at /etc/podinfo
.
Look at the items
array under downwardAPI
. Each element of the array
defines a file in the downward API volume.
The first element specifies that in the container named client-container
,
the value of the limits.cpu
field in the format specified by 1m
should be
published as a file named cpu_limit
. The divisor
field is optional and has the
default value of 1
. A divisor of 1 means cores for cpu
resources, or
bytes for memory
resources.
Create the Pod:
kubectl apply -f https://k8s.io/examples/pods/inject/dapi-volume-resources.yaml
Get a shell into the container that is running in your Pod:
kubectl exec -it kubernetes-downwardapi-volume-example-2 -- sh
In your shell, view the cpu_limit
file:
# Run this in a shell inside the container
cat /etc/podinfo/cpu_limit
You can use similar commands to view the cpu_request
, mem_limit
and
mem_request
files.
Project keys to specific paths and file permissions
You can project keys to specific paths and specific permissions on a per-file basis. For more information, see Secrets.
What's next
- Read the
spec
API definition for Pod. This includes the definition of Container (part of Pod). - Read the list of available fields that you can expose using the downward API.
Read about volumes in the legacy API reference:
- Check the
Volume
API definition which defines a generic volume in a Pod for containers to access. - Check the
DownwardAPIVolumeSource
API definition which defines a volume that contains Downward API information. - Check the
DownwardAPIVolumeFile
API definition which contains references to object or resource fields for populating a file in the Downward API volume. - Check the
ResourceFieldSelector
API definition which specifies the container resources and their output format.