--- assignees: - mikedanese --- Objects of type `secret` are intended to hold sensitive information, such as passwords, OAuth tokens, and ssh keys. Putting this information in a `secret` is safer and more flexible than putting it verbatim in a `pod` definition or in a docker image. See [Secrets design document](https://github.com/kubernetes/kubernetes/blob/{{page.githubbranch}}/docs/design/secrets.md) for more information. * TOC {:toc} ## Overview of Secrets A Secret is an object that contains a small amount of sensitive data such as a password, a token, or a key. Such information might otherwise be put in a Pod specification or in an image; putting it in a Secret object allows for more control over how it is used, and reduces the risk of accidental exposure. Users can create secrets, and the system also creates some secrets. To use a secret, a pod needs to reference the secret. A secret can be used with a pod in two ways: as files in a [volume](/docs/user-guide/volumes) mounted on one or more of its containers, or used by kubelet when pulling images for the pod. ### Built-in Secrets #### Service Accounts Automatically Create and Attach Secrets with API Credentials Kubernetes automatically creates secrets which contain credentials for accessing the API and it automatically modifies your pods to use this type of secret. The automatic creation and use of API credentials can be disabled or overridden if desired. However, if all you need to do is securely access the apiserver, this is the recommended workflow. See the [Service Account](/docs/user-guide/service-accounts) documentation for more information on how Service Accounts work. ### Creating your own Secrets #### Creating a Secret Using kubectl create secret Say that some pods need to access a database. The username and password that the pods should use is in the files `./username.txt` and `./password.txt` on your local machine. ```shell # Create files needed for rest of example. $ echo -n "admin" > ./username.txt $ echo -n "1f2d1e2e67df" > ./password.txt ``` The `kubectl create secret` command packages these files into a Secret and creates the object on the Apiserver. ```shell $ kubectl create secret generic db-user-pass --from-file=./username.txt --from-file=./password.txt secret "db-user-pass" created ``` You can check that the secret was created like this: ```shell $ kubectl get secrets NAME TYPE DATA AGE db-user-pass Opaque 2 51s $ kubectl describe secrets/db-user-pass Name: db-user-pass Namespace: default Labels: Annotations: Type: Opaque Data ==== password.txt: 13 bytes username.txt: 6 bytes ``` Note that neither `get` nor `describe` shows the contents of the file by default. This is to protect the secret from being exposed accidentally to someone looking or from being stored in a terminal log. See [decoding a secret](#decoding-a-secret) for how to see the contents. #### Creating a Secret Manually You can also create a secret object in a file first, in json or yaml format, and then create that object. Each item must be base64 encoded: ```shell $ echo -n "admin" | base64 YWRtaW4= $ echo -n "1f2d1e2e67df" | base64 MWYyZDFlMmU2N2Rm ``` Now write a secret object that looks like this: ```yaml apiVersion: v1 kind: Secret metadata: name: mysecret type: Opaque data: password: MWYyZDFlMmU2N2Rm username: YWRtaW4= ``` The data field is a map. Its keys must match [`DNS_SUBDOMAIN`](https://github.com/kubernetes/kubernetes/tree/{{page.githubbranch}}/docs/design/identifiers.md), except that leading dots are also allowed. The values are arbitrary data, encoded using base64. Create the secret using [`kubectl create`](/docs/user-guide/kubectl/kubectl_create/): ```shell $ kubectl create -f ./secret.yaml secret "mysecret" created ``` **Encoding Note:** The serialized JSON and YAML values of secret data are encoded as base64 strings. Newlines are not valid within these strings and must be omitted. When using the `base64` utility on Darwin/OS X users should avoid using the `-b` option to split long lines. Conversely Linux users *should* add the option `-w 0` to `base64` commands. #### Decoding a Secret Get back the secret created in the previous section: ```shell $ kubectl get secret mysecret -o yaml apiVersion: v1 data: password: MWYyZDFlMmU2N2Rm username: YWRtaW4= kind: Secret metadata: creationTimestamp: 2016-01-22T18:41:56Z name: mysecret namespace: default resourceVersion: "164619" selfLink: /api/v1/namespaces/default/secrets/mysecret uid: cfee02d6-c137-11e5-8d73-42010af00002 type: Opaque ``` Decode the password field: ```shell $ echo "MWYyZDFlMmU2N2Rm" | base64 -d 1f2d1e2e67df ``` ### Using Secrets Secrets can be mounted as data volumes or be exposed as environment variables to be used by a container in a pod. They can also be used by other parts of the system, without being directly exposed to the pod. For example, they can hold credentials that other parts of the system should use to interact with external systems on your behalf. #### Using Secrets as Files from a Pod To consume a Secret in a volume in a Pod: 1. Create a secret or use an existing one. Multiple pods can reference the same secret. 1. Modify your Pod definition to add a volume under `spec.volumes[]`. Name the volume anything, and have a `spec.volumes[].secret.secretName` field equal to the name of the secret object. 1. Add a `spec.containers[].volumeMounts[]` to each container that needs the secret. Specify `spec.containers[].volumeMounts[].readOnly = true` and `spec.containers[].volumeMounts[].mountPath` to an unused directory name where you would like the secrets to appear. 1. Modify your image and/or command line so that the program looks for files in that directory. Each key in the secret `data` map becomes the filename under `mountPath`. This is an example of a pod that mounts a secret in a volume: ```json { "apiVersion": "v1", "kind": "Pod", "metadata": { "name": "mypod", "namespace": "myns" }, "spec": { "containers": [{ "name": "mypod", "image": "redis", "volumeMounts": [{ "name": "foo", "mountPath": "/etc/foo", "readOnly": true }] }], "volumes": [{ "name": "foo", "secret": { "secretName": "mysecret" } }] } } ``` Each secret you want to use needs to be referred to in `spec.volumes`. If there are multiple containers in the pod, then each container needs its own `volumeMounts` block, but only one `spec.volumes` is needed per secret. You can package many files into one secret, or use many secrets, whichever is convenient. **Projection of secret keys to specific paths** We can also control the paths within the volume where Secret keys are projected. You can use `spec.volumes[].secret.items` field to change target path of each key: ```json { "apiVersion": "v1", "kind": "Pod", "metadata": { "name": "mypod", "namespace": "myns" }, "spec": { "containers": [{ "name": "mypod", "image": "redis", "volumeMounts": [{ "name": "foo", "mountPath": "/etc/foo", "readOnly": true }] }], "volumes": [{ "name": "foo", "secret": { "secretName": "mysecret", "items": [{ "key": "username", "path": "my-group/my-username" }] } }] } } ``` What will happen: * `username` secret is stored under `/etc/foo/my-group/my-username` file instead of `/etc/foo/username`. * `password` secret is not projected If `spec.volumes[].secret.items` is used, only keys specified in `items` are projected. To consume all keys from the secret, all of them must be listed in the `items` field. All listed keys must exist in the corresponding secret. Otherwise, the volume is not created. **Secret files permissions** You can also specify the permission mode bits files part of a secret will have. If you don't specify any, `0644` is used by default. You can sepecify a default mode for the whole secret volume and override per key if needed. For example, you can specify a default mode like this: ```json { "apiVersion": "v1", "kind": "Pod", "metadata": { "name": "mypod", "namespace": "myns" }, "spec": { "containers": [{ "name": "mypod", "image": "redis", "volumeMounts": [{ "name": "foo", "mountPath": "/etc/foo" }] }], "volumes": [{ "name": "foo", "secret": { "secretName": "mysecret", "defaultMode": 256 } }] } } ``` Then, the secret will be mounted on `/etc/foo` and all the files created by the secret volume mount will have permission `0400`. Note that the JSON spec doesn't support octal notation, so use the value 256 for 0400 permissions. If you use yaml instead of json for the pod, you can use octal notation to specify permissions in a more natural way. You can also use mapping, as in the previous example, and specify different permission for different files like this: ```json { "apiVersion": "v1", "kind": "Pod", "metadata": { "name": "mypod", "namespace": "myns" }, "spec": { "containers": [{ "name": "mypod", "image": "redis", "volumeMounts": [{ "name": "foo", "mountPath": "/etc/foo" }] }], "volumes": [{ "name": "foo", "secret": { "secretName": "mysecret", "items": [{ "key": "username", "path": "my-group/my-username", "mode": 511 }] } }] } } ``` In this case, the file resulting in `/etc/foo/my-group/my-username` will have permission value of `0777`. Owing to JSON limitations, you must specify the mode in decimal notation. Note that this permission value might be displayed in decimal notation if you read it later. **Consuming Secret Values from Volumes** Inside the container that mounts a secret volume, the secret keys appear as files and the secret values are base-64 decoded and stored inside these files. This is the result of commands executed inside the container from the example above: ```shell $ ls /etc/foo/ username password $ cat /etc/foo/username admin $ cat /etc/foo/password 1f2d1e2e67df ``` The program in a container is responsible for reading the secret(s) from the files. **Mounted Secrets are updated automatically** When a secret being already consumed in a volume is updated, projected keys are eventually updated as well. The update time depends on the kubelet syncing period. #### Using Secrets as Environment Variables To use a secret in an environment variable in a pod: 1. Create a secret or use an existing one. Multiple pods can reference the same secret. 1. Modify your Pod definition in each container that you wish to consume the value of a secret key to add an environment variable for each secret key you wish to consume. The environment variable that consumes the secret key should populate the secret's name and key in `env[x].valueFrom.secretKeyRef`. 1. Modify your image and/or command line so that the program looks for values in the specified environment variables This is an example of a pod that uses secrets from environment variables: ```yaml apiVersion: v1 kind: Pod metadata: name: secret-env-pod spec: containers: - name: mycontainer image: redis env: - name: SECRET_USERNAME valueFrom: secretKeyRef: name: mysecret key: username - name: SECRET_PASSWORD valueFrom: secretKeyRef: name: mysecret key: password restartPolicy: Never ``` **Consuming Secret Values from Environment Variables** Inside a container that consumes a secret in an environment variables, the secret keys appear as normal environment variables containing the base-64 decoded values of the secret data. This is the result of commands executed inside the container from the example above: ```shell $ echo $SECRET_USERNAME admin $ echo $SECRET_PASSWORD 1f2d1e2e67df ``` #### Using imagePullSecrets An imagePullSecret is a way to pass a secret that contains a Docker (or other) image registry password to the Kubelet so it can pull a private image on behalf of your Pod. **Manually specifying an imagePullSecret** Use of imagePullSecrets is described in the [images documentation](/docs/user-guide/images/#specifying-imagepullsecrets-on-a-pod) ### Arranging for imagePullSecrets to be Automatically Attached You can manually create an imagePullSecret, and reference it from a serviceAccount. Any pods created with that serviceAccount or that default to use that serviceAccount, will get their imagePullSecret field set to that of the service account. See [here](/docs/user-guide/service-accounts/#adding-imagepullsecrets-to-a-service-account) for a detailed explanation of that process. #### Automatic Mounting of Manually Created Secrets We plan to extend the service account behavior so that manually created secrets (e.g. one containing a token for accessing a github account) can be automatically attached to pods based on their service account. *This is not implemented yet. See [issue 9902](http://issue.k8s.io/9902).* ## Details ### Restrictions Secret volume sources are validated to ensure that the specified object reference actually points to an object of type `Secret`. Therefore, a secret needs to be created before any pods that depend on it. Secret API objects reside in a namespace. They can only be referenced by pods in that same namespace. Individual secrets are limited to 1MB in size. This is to discourage creation of very large secrets which would exhaust apiserver and kubelet memory. However, creation of many smaller secrets could also exhaust memory. More comprehensive limits on memory usage due to secrets is a planned feature. Kubelet only supports use of secrets for Pods it gets from the API server. This includes any pods created using kubectl, or indirectly via a replication controller. It does not include pods created via the kubelets `--manifest-url` flag, its `--config` flag, or its REST API (these are not common ways to create pods.) ### Secret and Pod Lifetime interaction When a pod is created via the API, there is no check whether a referenced secret exists. Once a pod is scheduled, the kubelet will try to fetch the secret value. If the secret cannot be fetched because it does not exist or because of a temporary lack of connection to the API server, kubelet will periodically retry. It will report an event about the pod explaining the reason it is not started yet. Once the secret is fetched, the kubelet will create and mount a volume containing it. None of the pod's containers will start until all the pod's volumes are mounted. ## Use cases ### Use-Case: Pod with ssh keys Create a secret containing some ssh keys: ```shell $ kubectl create secret generic ssh-key-secret --from-file=ssh-privatekey=/path/to/.ssh/id_rsa --from-file=ssh-publickey=/path/to/.ssh/id_rsa.pub ``` **Security Note:** think carefully before sending your own ssh keys: other users of the cluster may have access to the secret. Use a service account which you want to have accessible to all the users with whom you share the kubernetes cluster, and can revoke if they are compromised. Now we can create a pod which references the secret with the ssh key and consumes it in a volume: ```json { "kind": "Pod", "apiVersion": "v1", "metadata": { "name": "secret-test-pod", "labels": { "name": "secret-test" } }, "spec": { "volumes": [ { "name": "secret-volume", "secret": { "secretName": "ssh-key-secret" } } ], "containers": [ { "name": "ssh-test-container", "image": "mySshImage", "volumeMounts": [ { "name": "secret-volume", "readOnly": true, "mountPath": "/etc/secret-volume" } ] } ] } } ``` When the container's command runs, the pieces of the key will be available in: ```shell /etc/secret-volume/id-rsa.pub /etc/secret-volume/id-rsa ``` The container is then free to use the secret data to establish an ssh connection. ### Use-Case: Pods with prod / test credentials This example illustrates a pod which consumes a secret containing prod credentials and another pod which consumes a secret with test environment credentials. Make the secrets: ```shell $ kubectl create secret generic prod-db-secret --from-literal=username=produser --from-literal=password=Y4nys7f11 secret "prod-db-secret" created $ kubectl create secret generic test-db-secret --from-literal=username=testuser --from-literal=password=iluvtests secret "test-db-secret" created ``` Now make the pods: ```json { "apiVersion": "v1", "kind": "List", "items": [{ "kind": "Pod", "apiVersion": "v1", "metadata": { "name": "prod-db-client-pod", "labels": { "name": "prod-db-client" } }, "spec": { "volumes": [ { "name": "secret-volume", "secret": { "secretName": "prod-db-secret" } } ], "containers": [ { "name": "db-client-container", "image": "myClientImage", "volumeMounts": [ { "name": "secret-volume", "readOnly": true, "mountPath": "/etc/secret-volume" } ] } ] } }, { "kind": "Pod", "apiVersion": "v1", "metadata": { "name": "test-db-client-pod", "labels": { "name": "test-db-client" } }, "spec": { "volumes": [ { "name": "secret-volume", "secret": { "secretName": "test-db-secret" } } ], "containers": [ { "name": "db-client-container", "image": "myClientImage", "volumeMounts": [ { "name": "secret-volume", "readOnly": true, "mountPath": "/etc/secret-volume" } ] } ] } }] } ``` Both containers will have the following files present on their filesystems: ```shell /etc/secret-volume/username /etc/secret-volume/password ``` Note how the specs for the two pods differ only in one field; this facilitates creating pods with different capabilities from a common pod config template. You could further simplify the base pod specification by using two Service Accounts: one called, say, `prod-user` with the `prod-db-secret`, and one called, say, `test-user` with the `test-db-secret`. Then, the pod spec can be shortened to, for example: ```json { "kind": "Pod", "apiVersion": "v1", "metadata": { "name": "prod-db-client-pod", "labels": { "name": "prod-db-client" } }, "spec": { "serviceAccount": "prod-db-client", "containers": [ { "name": "db-client-container", "image": "myClientImage" } ] } } ``` ### Use-case: Dotfiles in secret volume In order to make piece of data 'hidden' (ie, in a file whose name begins with a dot character), simply make that key begin with a dot. For example, when the following secret is mounted into a volume: ```json { "kind": "Secret", "apiVersion": "v1", "metadata": { "name": "dotfile-secret" }, "data": { ".secret-file": "dmFsdWUtMg0KDQo=" } } { "kind": "Pod", "apiVersion": "v1", "metadata": { "name": "secret-dotfiles-pod" }, "spec": { "volumes": [ { "name": "secret-volume", "secret": { "secretName": "dotfile-secret" } } ], "containers": [ { "name": "dotfile-test-container", "image": "gcr.io/google_containers/busybox", "command": "ls -l /etc/secret-volume", "volumeMounts": [ { "name": "secret-volume", "readOnly": true, "mountPath": "/etc/secret-volume" } ] } ] } } ``` The `secret-volume` will contain a single file, called `.secret-file`, and the `dotfile-test-container` will have this file present at the path `/etc/secret-volume/.secret-file`. **NOTE** Files beginning with dot characters are hidden from the output of `ls -l`; you must use `ls -la` to see them when listing directory contents. ### Use-case: Secret visible to one container in a pod Consider a program that needs to handle HTTP requests, do some complex business logic, and then sign some messages with an HMAC. Because it has complex application logic, there might be an unnoticed remote file reading exploit in the server, which could expose the private key to an attacker. This could be divided into two processes in two containers: a frontend container which handles user interaction and business logic, but which cannot see the private key; and a signer container that can see the private key, and responds to simple signing requests from the frontend (e.g. over localhost networking). With this partitioned approach, an attacker now has to trick the application server into doing something rather arbitrary, which may be harder than getting it to read a file. ## Security Properties ### Protections Because `secret` objects can be created independently of the `pods` that use them, there is less risk of the secret being exposed during the workflow of creating, viewing, and editing pods. The system can also take additional precautions with `secret` objects, such as avoiding writing them to disk where possible. A secret is only sent to a node if a pod on that node requires it. It is not written to disk. It is stored in a tmpfs. It is deleted once the pod that depends on it is deleted. On most Kubernetes-project-maintained distributions, communication between user to the apiserver, and from apiserver to the kubelets, is protected by SSL/TLS. Secrets are protected when transmitted over these channels. Secret data on nodes is stored in tmpfs volumes and thus does not come to rest on the node. There may be secrets for several pods on the same node. However, only the secrets that a pod requests are potentially visible within its containers. Therefore, one Pod does not have access to the secrets of another pod. There may be several containers in a pod. However, each container in a pod has to request the secret volume in its `volumeMounts` for it to be visible within the container. This can be used to construct useful [security partitions at the Pod level](#use-case-secret-visible-to-one-container-in-a-pod). ### Risks - In the API server secret data is stored as plaintext in etcd; therefore: - Administrators should limit access to etcd to admin users - Secret data in the API server is at rest on the disk that etcd uses; admins may want to wipe/shred disks used by etcd when no longer in use - Applications still need to protect the value of secret after reading it from the volume, such as not accidentally logging it or transmitting it to an untrusted party. - A user who can create a pod that uses a secret can also see the value of that secret. Even if apiserver policy does not allow that user to read the secret object, the user could run a pod which exposes the secret. - If multiple replicas of etcd are run, then the secrets will be shared between them. By default, etcd does not secure peer-to-peer communication with SSL/TLS, though this can be configured. - It is not possible currently to control which users of a Kubernetes cluster can access a secret. Support for this is planned. - Currently, anyone with root on any node can read any secret from the apiserver, by impersonating the kubelet. It is a planned feature to only send secrets to nodes that actually require them, to restrict the impact of a root exploit on a single node.