Declarative Setup
Argo CD applications, projects and settings can be defined declaratively using Kubernetes manifests. These can be updated using kubectl apply
, without needing to touch the argocd
command-line tool.
Quick Reference
All resources, including Application
and AppProject
specs, have to be installed in the Argo CD namespace (by default argocd
).
Atomic configuration
Sample File | Resource Name | Kind | Description |
---|---|---|---|
argocd-cm.yaml | argocd-cm | ConfigMap | General Argo CD configuration |
argocd-repositories.yaml | my-private-repo / istio-helm-repo / private-helm-repo / private-repo | Secrets | Sample repository connection details |
argocd-repo-creds.yaml | argoproj-https-creds / argoproj-ssh-creds / github-creds / github-enterprise-creds | Secrets | Sample repository credential templates |
argocd-cmd-params-cm.yaml | argocd-cmd-params-cm | ConfigMap | Argo CD env variables configuration |
argocd-secret.yaml | argocd-secret | Secret | User Passwords, Certificates (deprecated), Signing Key, Dex secrets, Webhook secrets |
argocd-rbac-cm.yaml | argocd-rbac-cm | ConfigMap | RBAC Configuration |
argocd-tls-certs-cm.yaml | argocd-tls-certs-cm | ConfigMap | Custom TLS certificates for connecting Git repositories via HTTPS (v1.2 and later) |
argocd-ssh-known-hosts-cm.yaml | argocd-ssh-known-hosts-cm | ConfigMap | SSH known hosts data for connecting Git repositories via SSH (v1.2 and later) |
For each specific kind of ConfigMap and Secret resource, there is only a single supported resource name (as listed in the above table) - if you need to merge things you need to do it before creating them.
A note about ConfigMap resources
Be sure to annotate your ConfigMap resources using the label app.kubernetes.io/part-of: argocd
, otherwise Argo CD will not be able to use them.
Multiple configuration objects
Sample File | Kind | Description |
---|---|---|
application.yaml | Application | Example application spec |
project.yaml | AppProject | Example project spec |
- | Secret | Repository credentials |
For Application
and AppProject
resources, the name of the resource equals the name of the application or project within Argo CD. This also means that application and project names are unique within a given Argo CD installation - you cannot have the same application name for two different applications.
Applications
The Application CRD is the Kubernetes resource object representing a deployed application instance in an environment. It is defined by two key pieces of information:
source
reference to the desired state in Git (repository, revision, path, environment)destination
reference to the target cluster and namespace. For the cluster one of server or name can be used, but not both (which will result in an error). Under the hood when the server is missing, it is calculated based on the name and used for any operations.
A minimal Application spec is as follows:
apiVersion: argoproj.io/v1alpha1
kind: Application
metadata:
name: guestbook
namespace: argocd
spec:
project: default
source:
repoURL: https://github.com/argoproj/argocd-example-apps.git
targetRevision: HEAD
path: guestbook
destination:
server: https://kubernetes.default.svc
namespace: guestbook
See application.yaml for additional fields. As long as you have completed the first step of Getting Started, you can apply this with kubectl apply -n argocd -f application.yaml
and Argo CD will start deploying the guestbook application.
Note
The namespace must match the namespace of your Argo CD instance - typically this is argocd
.
Note
When creating an application from a Helm repository, the chart
attribute must be specified instead of the path
attribute within spec.source
.
spec:
source:
repoURL: https://argoproj.github.io/argo-helm
chart: argo
Warning
Without the resources-finalizer.argocd.argoproj.io
finalizer, deleting an application will not delete the resources it manages. To perform a cascading delete, you must add the finalizer. See App Deletion.
metadata:
finalizers:
- resources-finalizer.argocd.argoproj.io
App of Apps
You can create an app that creates other apps, which in turn can create other apps. This allows you to declaratively manage a group of apps that can be deployed and configured in concert.
Projects
The AppProject CRD is the Kubernetes resource object representing a logical grouping of applications. It is defined by the following key pieces of information:
sourceRepos
reference to the repositories that applications within the project can pull manifests from.destinations
reference to clusters and namespaces that applications within the project can deploy into.roles
list of entities with definitions of their access to resources within the project.
Projects which can deploy to the Argo CD namespace grant admin access
If a Project’s destinations
configuration allows deploying to the namespace in which Argo CD is installed, then Applications under that project have admin-level access. RBAC access to admin-level Projects should be carefully restricted, and push access to allowed sourceRepos
should be limited to only admins.
An example spec is as follows:
apiVersion: argoproj.io/v1alpha1
kind: AppProject
metadata:
name: my-project
namespace: argocd
# Finalizer that ensures that project is not deleted until it is not referenced by any application
finalizers:
- resources-finalizer.argocd.argoproj.io
spec:
description: Example Project
# Allow manifests to deploy from any Git repos
sourceRepos:
- '*'
# Only permit applications to deploy to the guestbook namespace in the same cluster
destinations:
- namespace: guestbook
server: https://kubernetes.default.svc
# Deny all cluster-scoped resources from being created, except for Namespace
clusterResourceWhitelist:
- group: ''
kind: Namespace
# Allow all namespaced-scoped resources to be created, except for ResourceQuota, LimitRange, NetworkPolicy
namespaceResourceBlacklist:
- group: ''
kind: ResourceQuota
- group: ''
kind: LimitRange
- group: ''
kind: NetworkPolicy
# Deny all namespaced-scoped resources from being created, except for Deployment and StatefulSet
namespaceResourceWhitelist:
- group: 'apps'
kind: Deployment
- group: 'apps'
kind: StatefulSet
roles:
# A role which provides read-only access to all applications in the project
- name: read-only
description: Read-only privileges to my-project
policies:
- p, proj:my-project:read-only, applications, get, my-project/*, allow
groups:
- my-oidc-group
# A role which provides sync privileges to only the guestbook-dev application, e.g. to provide
# sync privileges to a CI system
- name: ci-role
description: Sync privileges for guestbook-dev
policies:
- p, proj:my-project:ci-role, applications, sync, my-project/guestbook-dev, allow
# NOTE: JWT tokens can only be generated by the API server and the token is not persisted
# anywhere by Argo CD. It can be prematurely revoked by removing the entry from this list.
jwtTokens:
- iat: 1535390316
Repositories
Note
Some Git hosters - notably GitLab and possibly on-premise GitLab instances as well - require you to specify the .git
suffix in the repository URL, otherwise they will send a HTTP 301 redirect to the repository URL suffixed with .git
. Argo CD will not follow these redirects, so you have to adjust your repository URL to be suffixed with .git
.
Repository details are stored in secrets. To configure a repo, create a secret which contains repository details. Consider using bitnami-labs/sealed-secrets to store an encrypted secret definition as a Kubernetes manifest. Each repository must have a url
field and, depending on whether you connect using HTTPS, SSH, or GitHub App, username
and password
(for HTTPS), sshPrivateKey
(for SSH), or githubAppPrivateKey
(for GitHub App).
Warning
When using bitnami-labs/sealed-secrets the labels will be removed and have to be readded as described here: https://github.com/bitnami-labs/sealed-secrets#sealedsecrets-as-templates-for-secrets
Example for HTTPS:
apiVersion: v1
kind: Secret
metadata:
name: private-repo
namespace: argocd
labels:
argocd.argoproj.io/secret-type: repository
stringData:
type: git
url: https://github.com/argoproj/private-repo
password: my-password
username: my-username
Example for SSH:
apiVersion: v1
kind: Secret
metadata:
name: private-repo
namespace: argocd
labels:
argocd.argoproj.io/secret-type: repository
stringData:
type: git
url: git@github.com:argoproj/my-private-repository.git
sshPrivateKey: |
-----BEGIN OPENSSH PRIVATE KEY-----
...
-----END OPENSSH PRIVATE KEY-----
Example for GitHub App:
apiVersion: v1
kind: Secret
metadata:
name: github-repo
namespace: argocd
labels:
argocd.argoproj.io/secret-type: repository
stringData:
type: git
url: https://github.com/argoproj/my-private-repository
githubAppID: 1
githubAppInstallationID: 2
githubAppPrivateKey: |
-----BEGIN OPENSSH PRIVATE KEY-----
...
-----END OPENSSH PRIVATE KEY-----
---
apiVersion: v1
kind: Secret
metadata:
name: github-enterprise-repo
namespace: argocd
labels:
argocd.argoproj.io/secret-type: repository
stringData:
type: git
url: https://ghe.example.com/argoproj/my-private-repository
githubAppID: 1
githubAppInstallationID: 2
githubAppEnterpriseBaseUrl: https://ghe.example.com/api/v3
githubAppPrivateKey: |
-----BEGIN OPENSSH PRIVATE KEY-----
...
-----END OPENSSH PRIVATE KEY-----
Example for Google Cloud Source repositories:
kind: Secret
metadata:
name: github-repo
namespace: argocd
labels:
argocd.argoproj.io/secret-type: repository
stringData:
type: git
url: https://source.developers.google.com/p/my-google-project/r/my-repo
gcpServiceAccountKey: |
{
"type": "service_account",
"project_id": "my-google-project",
"private_key_id": "REDACTED",
"private_key": "-----BEGIN PRIVATE KEY-----\nREDACTED\n-----END PRIVATE KEY-----\n",
"client_email": "argocd-service-account@my-google-project.iam.gserviceaccount.com",
"client_id": "REDACTED",
"auth_uri": "https://accounts.google.com/o/oauth2/auth",
"token_uri": "https://oauth2.googleapis.com/token",
"auth_provider_x509_cert_url": "https://www.googleapis.com/oauth2/v1/certs",
"client_x509_cert_url": "https://www.googleapis.com/robot/v1/metadata/x509/argocd-service-account%40my-google-project.iam.gserviceaccount.com"
}
Tip
The Kubernetes documentation has instructions for creating a secret containing a private key.
Repository Credentials
If you want to use the same credentials for multiple repositories, you can configure credential templates. Credential templates can carry the same credentials information as repositories.
apiVersion: v1
kind: Secret
metadata:
name: first-repo
namespace: argocd
labels:
argocd.argoproj.io/secret-type: repository
stringData:
type: git
url: https://github.com/argoproj/private-repo
---
apiVersion: v1
kind: Secret
metadata:
name: second-repo
namespace: argocd
labels:
argocd.argoproj.io/secret-type: repository
stringData:
type: git
url: https://github.com/argoproj/other-private-repo
---
apiVersion: v1
kind: Secret
metadata:
name: private-repo-creds
namespace: argocd
labels:
argocd.argoproj.io/secret-type: repo-creds
stringData:
type: git
url: https://github.com/argoproj
password: my-password
username: my-username
In the above example, every repository accessed via HTTPS whose URL is prefixed with https://github.com/argoproj
would use a username stored in the key username
and a password stored in the key password
of the secret private-repo-creds
for connecting to Git.
In order for Argo CD to use a credential template for any given repository, the following conditions must be met:
- The repository must either not be configured at all, or if configured, must not contain any credential information (i.e. contain none of
sshPrivateKey
,username
,password
) - The URL configured for a credential template (e.g.
https://github.com/argoproj
) must match as prefix for the repository URL (e.g.https://github.com/argoproj/argocd-example-apps
).
Note
Matching credential template URL prefixes is done on a best match effort, so the longest (best) match will take precedence. The order of definition is not important, as opposed to pre v1.4 configuration.
The following keys are valid to refer to credential secrets:
SSH repositories
sshPrivateKey
refers to the SSH private key for accessing the repositories
HTTPS repositories
username
andpassword
refer to the username and/or password for accessing the repositoriestlsClientCertData
andtlsClientCertKey
refer to secrets where a TLS client certificate (tlsClientCertData
) and the corresponding private keytlsClientCertKey
are stored for accessing the repositories
GitHub App repositories
githubAppPrivateKey
refers to the GitHub App private key for accessing the repositoriesgithubAppID
refers to the GitHub Application ID for the application you created.githubAppInstallationID
refers to the Installation ID of the GitHub app you created and installed.githubAppEnterpriseBaseUrl
refers to the base api URL for GitHub Enterprise (e.g.https://ghe.example.com/api/v3
)tlsClientCertData
andtlsClientCertKey
refer to secrets where a TLS client certificate (tlsClientCertData
) and the corresponding private keytlsClientCertKey
are stored for accessing GitHub Enterprise if custom certificates are used.
Repositories using self-signed TLS certificates (or are signed by custom CA)
You can manage the TLS certificates used to verify the authenticity of your repository servers in a ConfigMap object named argocd-tls-certs-cm
. The data section should contain a map, with the repository server’s hostname part (not the complete URL) as key, and the certificate(s) in PEM format as data. So, if you connect to a repository with the URL https://server.example.com/repos/my-repo
, you should use server.example.com
as key. The certificate data should be either the server’s certificate (in case of self-signed certificate) or the certificate of the CA that was used to sign the server’s certificate. You can configure multiple certificates for each server, e.g. if you are having a certificate roll-over planned.
If there are no dedicated certificates configured for a repository server, the system’s default trust store is used for validating the server’s repository. This should be good enough for most (if not all) public Git repository services such as GitLab, GitHub and Bitbucket as well as most privately hosted sites which use certificates from well-known CAs, including Let’s Encrypt certificates.
An example ConfigMap object:
apiVersion: v1
kind: ConfigMap
metadata:
name: argocd-tls-certs-cm
namespace: argocd
labels:
app.kubernetes.io/name: argocd-cm
app.kubernetes.io/part-of: argocd
data:
server.example.com: |
-----BEGIN CERTIFICATE-----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-----END CERTIFICATE-----
Note
The argocd-tls-certs-cm
ConfigMap will be mounted as a volume at the mount path /app/config/tls
in the pods of argocd-server
and argocd-repo-server
. It will create files for each data key in the mount path directory, so above example would leave the file /app/config/tls/server.example.com
, which contains the certificate data. It might take a while for changes in the ConfigMap to be reflected in your pods, depending on your Kubernetes configuration.
SSH known host public keys
If you are configuring repositories to use SSH, Argo CD will need to know their SSH public keys. In order for Argo CD to connect via SSH the public key(s) for each repository server must be pre-configured in Argo CD (unlike TLS configuration), otherwise the connections to the repository will fail.
You can manage the SSH known hosts data in the argocd-ssh-known-hosts-cm
ConfigMap. This ConfigMap contains a single entry, ssh_known_hosts
, with the public keys of the SSH servers as its value. The value can be filled in from any existing ssh_known_hosts
file, or from the output of the ssh-keyscan
utility (which is part of OpenSSH’s client package). The basic format is <server_name> <keytype> <base64-encoded_key>
, one entry per line.
Here is an example of running ssh-keyscan
:
$ for host in bitbucket.org github.com gitlab.com ssh.dev.azure.com vs-ssh.visualstudio.com ; do ssh-keyscan $host 2> /dev/null ; done
bitbucket.org ssh-rsa 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
github.com ssh-ed25519 AAAAC3NzaC1lZDI1NTE5AAAAIOMqqnkVzrm0SdG6UOoqKLsabgH5C9okWi0dh2l9GKJl
github.com ssh-rsa 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
github.com ecdsa-sha2-nistp256 AAAAE2VjZHNhLXNoYTItbmlzdHAyNTYAAAAIbmlzdHAyNTYAAABBBEmKSENjQEezOmxkZMy7opKgwFB9nkt5YRrYMjNuG5N87uRgg6CLrbo5wAdT/y6v0mKV0U2w0WZ2YB/++Tpockg=
gitlab.com ecdsa-sha2-nistp256 AAAAE2VjZHNhLXNoYTItbmlzdHAyNTYAAAAIbmlzdHAyNTYAAABBBFSMqzJeV9rUzU4kWitGjeR4PWSa29SPqJ1fVkhtj3Hw9xjLVXVYrU9QlYWrOLXBpQ6KWjbjTDTdDkoohFzgbEY=
gitlab.com ssh-ed25519 AAAAC3NzaC1lZDI1NTE5AAAAIAfuCHKVTjquxvt6CM6tdG4SLp1Btn/nOeHHE5UOzRdf
gitlab.com ssh-rsa AAAAB3NzaC1yc2EAAAADAQABAAABAQCsj2bNKTBSpIYDEGk9KxsGh3mySTRgMtXL583qmBpzeQ+jqCMRgBqB98u3z++J1sKlXHWfM9dyhSevkMwSbhoR8XIq/U0tCNyokEi/ueaBMCvbcTHhO7FcwzY92WK4Yt0aGROY5qX2UKSeOvuP4D6TPqKF1onrSzH9bx9XUf2lEdWT/ia1NEKjunUqu1xOB/StKDHMoX4/OKyIzuS0q/T1zOATthvasJFoPrAjkohTyaDUz2LN5JoH839hViyEG82yB+MjcFV5MU3N1l1QL3cVUCh93xSaua1N85qivl+siMkPGbO5xR/En4iEY6K2XPASUEMaieWVNTRCtJ4S8H+9
ssh.dev.azure.com ssh-rsa AAAAB3NzaC1yc2EAAAADAQABAAABAQC7Hr1oTWqNqOlzGJOfGJ4NakVyIzf1rXYd4d7wo6jBlkLvCA4odBlL0mDUyZ0/QUfTTqeu+tm22gOsv+VrVTMk6vwRU75gY/y9ut5Mb3bR5BV58dKXyq9A9UeB5Cakehn5Zgm6x1mKoVyf+FFn26iYqXJRgzIZZcZ5V6hrE0Qg39kZm4az48o0AUbf6Sp4SLdvnuMa2sVNwHBboS7EJkm57XQPVU3/QpyNLHbWDdzwtrlS+ez30S3AdYhLKEOxAG8weOnyrtLJAUen9mTkol8oII1edf7mWWbWVf0nBmly21+nZcmCTISQBtdcyPaEno7fFQMDD26/s0lfKob4Kw8H
vs-ssh.visualstudio.com ssh-rsa AAAAB3NzaC1yc2EAAAADAQABAAABAQC7Hr1oTWqNqOlzGJOfGJ4NakVyIzf1rXYd4d7wo6jBlkLvCA4odBlL0mDUyZ0/QUfTTqeu+tm22gOsv+VrVTMk6vwRU75gY/y9ut5Mb3bR5BV58dKXyq9A9UeB5Cakehn5Zgm6x1mKoVyf+FFn26iYqXJRgzIZZcZ5V6hrE0Qg39kZm4az48o0AUbf6Sp4SLdvnuMa2sVNwHBboS7EJkm57XQPVU3/QpyNLHbWDdzwtrlS+ez30S3AdYhLKEOxAG8weOnyrtLJAUen9mTkol8oII1edf7mWWbWVf0nBmly21+nZcmCTISQBtdcyPaEno7fFQMDD26/s0lfKob4Kw8H
Here is an example ConfigMap
object using the output from ssh-keyscan
above:
apiVersion: v1
kind: ConfigMap
metadata:
labels:
app.kubernetes.io/name: argocd-ssh-known-hosts-cm
app.kubernetes.io/part-of: argocd
name: argocd-ssh-known-hosts-cm
data:
ssh_known_hosts: |
# This file was automatically generated by hack/update-ssh-known-hosts.sh. DO NOT EDIT
[ssh.github.com]:443 ecdsa-sha2-nistp256 AAAAE2VjZHNhLXNoYTItbmlzdHAyNTYAAAAIbmlzdHAyNTYAAABBBEmKSENjQEezOmxkZMy7opKgwFB9nkt5YRrYMjNuG5N87uRgg6CLrbo5wAdT/y6v0mKV0U2w0WZ2YB/++Tpockg=
[ssh.github.com]:443 ssh-ed25519 AAAAC3NzaC1lZDI1NTE5AAAAIOMqqnkVzrm0SdG6UOoqKLsabgH5C9okWi0dh2l9GKJl
[ssh.github.com]:443 ssh-rsa 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
bitbucket.org ecdsa-sha2-nistp256 AAAAE2VjZHNhLXNoYTItbmlzdHAyNTYAAAAIbmlzdHAyNTYAAABBBPIQmuzMBuKdWeF4+a2sjSSpBK0iqitSQ+5BM9KhpexuGt20JpTVM7u5BDZngncgrqDMbWdxMWWOGtZ9UgbqgZE=
bitbucket.org ssh-ed25519 AAAAC3NzaC1lZDI1NTE5AAAAIIazEu89wgQZ4bqs3d63QSMzYVa0MuJ2e2gKTKqu+UUO
bitbucket.org ssh-rsa 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
github.com ecdsa-sha2-nistp256 AAAAE2VjZHNhLXNoYTItbmlzdHAyNTYAAAAIbmlzdHAyNTYAAABBBEmKSENjQEezOmxkZMy7opKgwFB9nkt5YRrYMjNuG5N87uRgg6CLrbo5wAdT/y6v0mKV0U2w0WZ2YB/++Tpockg=
github.com ssh-ed25519 AAAAC3NzaC1lZDI1NTE5AAAAIOMqqnkVzrm0SdG6UOoqKLsabgH5C9okWi0dh2l9GKJl
github.com ssh-rsa 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
gitlab.com ecdsa-sha2-nistp256 AAAAE2VjZHNhLXNoYTItbmlzdHAyNTYAAAAIbmlzdHAyNTYAAABBBFSMqzJeV9rUzU4kWitGjeR4PWSa29SPqJ1fVkhtj3Hw9xjLVXVYrU9QlYWrOLXBpQ6KWjbjTDTdDkoohFzgbEY=
gitlab.com ssh-ed25519 AAAAC3NzaC1lZDI1NTE5AAAAIAfuCHKVTjquxvt6CM6tdG4SLp1Btn/nOeHHE5UOzRdf
gitlab.com ssh-rsa AAAAB3NzaC1yc2EAAAADAQABAAABAQCsj2bNKTBSpIYDEGk9KxsGh3mySTRgMtXL583qmBpzeQ+jqCMRgBqB98u3z++J1sKlXHWfM9dyhSevkMwSbhoR8XIq/U0tCNyokEi/ueaBMCvbcTHhO7FcwzY92WK4Yt0aGROY5qX2UKSeOvuP4D6TPqKF1onrSzH9bx9XUf2lEdWT/ia1NEKjunUqu1xOB/StKDHMoX4/OKyIzuS0q/T1zOATthvasJFoPrAjkohTyaDUz2LN5JoH839hViyEG82yB+MjcFV5MU3N1l1QL3cVUCh93xSaua1N85qivl+siMkPGbO5xR/En4iEY6K2XPASUEMaieWVNTRCtJ4S8H+9
ssh.dev.azure.com ssh-rsa AAAAB3NzaC1yc2EAAAADAQABAAABAQC7Hr1oTWqNqOlzGJOfGJ4NakVyIzf1rXYd4d7wo6jBlkLvCA4odBlL0mDUyZ0/QUfTTqeu+tm22gOsv+VrVTMk6vwRU75gY/y9ut5Mb3bR5BV58dKXyq9A9UeB5Cakehn5Zgm6x1mKoVyf+FFn26iYqXJRgzIZZcZ5V6hrE0Qg39kZm4az48o0AUbf6Sp4SLdvnuMa2sVNwHBboS7EJkm57XQPVU3/QpyNLHbWDdzwtrlS+ez30S3AdYhLKEOxAG8weOnyrtLJAUen9mTkol8oII1edf7mWWbWVf0nBmly21+nZcmCTISQBtdcyPaEno7fFQMDD26/s0lfKob4Kw8H
vs-ssh.visualstudio.com ssh-rsa AAAAB3NzaC1yc2EAAAADAQABAAABAQC7Hr1oTWqNqOlzGJOfGJ4NakVyIzf1rXYd4d7wo6jBlkLvCA4odBlL0mDUyZ0/QUfTTqeu+tm22gOsv+VrVTMk6vwRU75gY/y9ut5Mb3bR5BV58dKXyq9A9UeB5Cakehn5Zgm6x1mKoVyf+FFn26iYqXJRgzIZZcZ5V6hrE0Qg39kZm4az48o0AUbf6Sp4SLdvnuMa2sVNwHBboS7EJkm57XQPVU3/QpyNLHbWDdzwtrlS+ez30S3AdYhLKEOxAG8weOnyrtLJAUen9mTkol8oII1edf7mWWbWVf0nBmly21+nZcmCTISQBtdcyPaEno7fFQMDD26/s0lfKob4Kw8H
Note
The argocd-ssh-known-hosts-cm
ConfigMap will be mounted as a volume at the mount path /app/config/ssh
in the pods of argocd-server
and argocd-repo-server
. It will create a file ssh_known_hosts
in that directory, which contains the SSH known hosts data used by Argo CD for connecting to Git repositories via SSH. It might take a while for changes in the ConfigMap to be reflected in your pods, depending on your Kubernetes configuration.
Configure repositories with proxy
Proxy for your repository can be specified in the proxy
field of the repository secret, along with other repository configurations. Argo CD uses this proxy to access the repository. Argo CD looks for the standard proxy environment variables in the repository server if the custom proxy is absent.
An example repository with proxy:
apiVersion: v1
kind: Secret
metadata:
name: private-repo
namespace: argocd
labels:
argocd.argoproj.io/secret-type: repository
stringData:
type: git
url: https://github.com/argoproj/private-repo
proxy: https://proxy-server-url:8888
password: my-password
username: my-username
Legacy behaviour
In Argo CD version 2.0 and earlier, repositories were stored as part of the argocd-cm
config map. For backward-compatibility, Argo CD will still honor repositories in the config map, but this style of repository configuration is deprecated and support for it will be removed in a future version.
apiVersion: v1
kind: ConfigMap
data:
repositories: |
- url: https://github.com/argoproj/my-private-repository
passwordSecret:
name: my-secret
key: password
usernameSecret:
name: my-secret
key: username
repository.credentials: |
- url: https://github.com/argoproj
passwordSecret:
name: my-secret
key: password
usernameSecret:
name: my-secret
key: username
---
apiVersion: v1
kind: Secret
metadata:
name: my-secret
namespace: argocd
stringData:
password: my-password
username: my-username
Clusters
Cluster credentials are stored in secrets same as repositories or repository credentials. Each secret must have label argocd.argoproj.io/secret-type: cluster
.
The secret data must include following fields:
name
- cluster nameserver
- cluster api server urlnamespaces
- optional comma-separated list of namespaces which are accessible in that cluster. Cluster level resources would be ignored if namespace list is not empty.clusterResources
- optional boolean string ("true"
or"false"
) determining whether Argo CD can manage cluster-level resources on this cluster. This setting is used only if the list of managed namespaces is not empty.project
- optional string to designate this as a project-scoped cluster.config
- JSON representation of following data structure:
# Basic authentication settings
username: string
password: string
# Bearer authentication settings
bearerToken: string
# IAM authentication configuration
awsAuthConfig:
clusterName: string
roleARN: string
profile: string
# Configure external command to supply client credentials
# See https://godoc.org/k8s.io/client-go/tools/clientcmd/api#ExecConfig
execProviderConfig:
command: string
args: [
string
]
env: {
key: value
}
apiVersion: string
installHint: string
# Transport layer security configuration settings
tlsClientConfig:
# Base64 encoded PEM-encoded bytes (typically read from a client certificate file).
caData: string
# Base64 encoded PEM-encoded bytes (typically read from a client certificate file).
certData: string
# Server should be accessed without verifying the TLS certificate
insecure: boolean
# Base64 encoded PEM-encoded bytes (typically read from a client certificate key file).
keyData: string
# ServerName is passed to the server for SNI and is used in the client to check server
# certificates against. If ServerName is empty, the hostname used to contact the
# server is used.
serverName: string
Note that if you specify a command to run under execProviderConfig
, that command must be available in the Argo CD image. See BYOI (Build Your Own Image).
Cluster secret example:
apiVersion: v1
kind: Secret
metadata:
name: mycluster-secret
labels:
argocd.argoproj.io/secret-type: cluster
type: Opaque
stringData:
name: mycluster.example.com
server: https://mycluster.example.com
config: |
{
"bearerToken": "<authentication token>",
"tlsClientConfig": {
"insecure": false,
"caData": "<base64 encoded certificate>"
}
}
EKS
EKS cluster secret example using argocd-k8s-auth and IRSA:
apiVersion: v1
kind: Secret
metadata:
name: mycluster-secret
labels:
argocd.argoproj.io/secret-type: cluster
type: Opaque
stringData:
name: "mycluster.example.com"
server: "https://mycluster.example.com"
config: |
{
"awsAuthConfig": {
"clusterName": "my-eks-cluster-name",
"roleARN": "arn:aws:iam::<AWS_ACCOUNT_ID>:role/<IAM_ROLE_NAME>"
},
"tlsClientConfig": {
"insecure": false,
"caData": "<base64 encoded certificate>"
}
}
Note that you should have IRSA enabled on your EKS cluster, create an appropriate IAM role which allows it to assume other IAM roles (whichever roleARN
s that Argo CD needs to assume) and have an assume role policy which allows the argocd-application-controller and argocd-server pods to assume said role via OIDC.
Example trust relationship config for <arn:aws:iam::<AWS_ACCOUNT_ID>:role/<ARGO_CD_MANAGEMENT_IAM_ROLE_NAME>
, which is required for Argo CD to perform actions via IAM. Ensure that the cluster has an IAM OIDC provider configured for it.
{
"Version": "2012-10-17",
"Statement": [
{
"Effect": "Allow",
"Principal": {
"Federated": "arn:aws:iam::<AWS_ACCOUNT_ID>:oidc-provider/oidc.eks.<AWS_REGION>.amazonaws.com/id/EXAMPLED539D4633E53DE1B71EXAMPLE"
},
"Action": "sts:AssumeRoleWithWebIdentity",
"Condition": {
"StringEquals": {
"oidc.eks.<AWS_REGION>.amazonaws.com/id/EXAMPLED539D4633E53DE1B71EXAMPLE:sub": ["system:serviceaccount:argocd:argocd-application-controller", "system:serviceaccount:argocd:argocd-server"],
"oidc.eks.<AWS_REGION>.amazonaws.com/id/EXAMPLED539D4633E53DE1B71EXAMPLE:aud": "sts.amazonaws.com"
}
}
}
]
}
The Argo CD management role also needs to be allowed to assume other roles, in this case we want it to assume arn:aws:iam::<AWS_ACCOUNT_ID>:role/<IAM_ROLE_NAME>
so that it can manage the cluster mapped to that role. This can be extended to allow assumption of multiple roles, either as an explicit array of role ARNs or by using *
where appropriate.
{
"Version" : "2012-10-17",
"Statement" : {
"Effect" : "Allow",
"Action" : "sts:AssumeRole",
"Resource" : [
"<arn:aws:iam::<AWS_ACCOUNT_ID>:role/<IAM_ROLE_NAME>"
]
}
}
Example service account configs for argocd-application-controller
and argocd-server
.
Warning
Once the annotations have been set on the service accounts, both the application controller and server pods need to be restarted.
apiVersion: v1
kind: ServiceAccount
metadata:
annotations:
eks.amazonaws.com/role-arn: "<arn:aws:iam::<AWS_ACCOUNT_ID>:role/<ARGO_CD_MANAGEMENT_IAM_ROLE_NAME>"
name: argocd-application-controller
---
apiVersion: v1
kind: ServiceAccount
metadata:
annotations:
eks.amazonaws.com/role-arn: "<arn:aws:iam::<AWS_ACCOUNT_ID>:role/<ARGO_CD_MANAGEMENT_IAM_ROLE_NAME>"
name: argocd-server
In turn, the roleARN
of each managed cluster needs to be added to each respective cluster’s aws-auth
config map (see Enabling IAM principal access to your cluster), as well as having an assume role policy which allows it to be assumed by the Argo CD pod role.
Example assume role policy for a cluster which is managed by Argo CD:
{
"Version" : "2012-10-17",
"Statement" : {
"Effect" : "Allow",
"Action" : "sts:AssumeRole",
"Principal" : {
"AWS" : "<arn:aws:iam::<AWS_ACCOUNT_ID>:role/<ARGO_CD_MANAGEMENT_IAM_ROLE_NAME>"
}
}
}
Example kube-system/aws-auth configmap for your cluster managed by Argo CD:
apiVersion: v1
data:
# Other groups and accounts omitted for brevity. Ensure that no other rolearns and/or groups are inadvertently removed,
# or you risk borking access to your cluster.
#
# The group name is a RoleBinding which you use to map to a [Cluster]Role. See https://kubernetes.io/docs/reference/access-authn-authz/rbac/#role-binding-examples
mapRoles: |
- "groups":
- "<GROUP-NAME-IN-K8S-RBAC>"
"rolearn": "<arn:aws:iam::<AWS_ACCOUNT_ID>:role/<IAM_ROLE_NAME>"
"username": "<some-username>"
Alternative EKS Authentication Methods
In some scenarios it may not be possible to use IRSA, such as when the Argo CD cluster is running on a different cloud provider’s platform. In this case, there are two options: 1. Use execProviderConfig
to call the AWS authentication mechanism which enables the injection of environment variables to supply credentials 2. Leverage the new AWS profile option available in Argo CD release 2.10
Both of these options will require the steps involving IAM and the aws-auth
config map (defined above) to provide the principal with access to the cluster.
Using execProviderConfig with Environment Variables
---
apiVersion: v1
kind: Secret
metadata:
name: mycluster-secret
labels:
argocd.argoproj.io/secret-type: cluster
type: Opaque
stringData:
name: mycluster
server: https://mycluster.example.com
namespaces: "my,managed,namespaces"
clusterResources: "true"
config: |
{
"execProviderConfig": {
"command": "argocd-k8s-auth",
"args": ["aws", "--cluster-name", "my-eks-cluster"],
"apiVersion": "client.authentication.k8s.io/v1beta1",
"env": {
"AWS_REGION": "xx-east-1",
"AWS_ACCESS_KEY_ID": "{{ .aws_key_id }}",
"AWS_SECRET_ACCESS_KEY": "{{ .aws_key_secret }}",
"AWS_SESSION_TOKEN": "{{ .aws_token }}"
}
},
"tlsClientConfig": {
"insecure": false,
"caData": "{{ .cluster_cert }}"
}
}
This example assumes that the role being attached to the credentials that have been supplied, if this is not the case the role can be appended to the args
section like so:
...
"args": ["aws", "--cluster-name", "my-eks-cluster", "--roleARN", "arn:aws:iam::<AWS_ACCOUNT_ID>:role/<IAM_ROLE_NAME>"],
...
This construct can be used in conjunction with something like the External Secrets Operator to avoid storing the keys in plain text and additionally helps to provide a foundation for key rotation.
Using An AWS Profile For Authentication
The option to use profiles, added in release 2.10, provides a method for supplying credentials while still using the standard Argo CD EKS cluster declaration with an additional command flag that points to an AWS credentials file:
apiVersion: v1
kind: Secret
metadata:
name: mycluster-secret
labels:
argocd.argoproj.io/secret-type: cluster
type: Opaque
stringData:
name: "mycluster.com"
server: "https://mycluster.com"
config: |
{
"awsAuthConfig": {
"clusterName": "my-eks-cluster-name",
"roleARN": "arn:aws:iam::<AWS_ACCOUNT_ID>:role/<IAM_ROLE_NAME>",
"profile": "/mount/path/to/my-profile-file"
},
"tlsClientConfig": {
"insecure": false,
"caData": "<base64 encoded certificate>"
}
}
This will instruct ArgoCD to read the file at the provided path and use the credentials defined within to authenticate to AWS. The profile must be mounted in order for this to work. For example, the following values can be defined in a Helm based ArgoCD deployment:
controller:
extraVolumes:
- name: my-profile-volume
secret:
secretName: my-aws-profile
items:
- key: my-profile-file
path: my-profile-file
extraVolumeMounts:
- name: my-profile-mount
mountPath: /mount/path/to
readOnly: true
server:
extraVolumes:
- name: my-profile-volume
secret:
secretName: my-aws-profile
items:
- key: my-profile-file
path: my-profile-file
extraVolumeMounts:
- name: my-profile-mount
mountPath: /mount/path/to
readOnly: true
Where the secret is defined as follows:
apiVersion: v1
kind: Secret
metadata:
name: my-aws-profile
type: Opaque
stringData:
my-profile-file: |
[default]
region = <aws_region>
aws_access_key_id = <aws_access_key_id>
aws_secret_access_key = <aws_secret_access_key>
aws_session_token = <aws_session_token>
⚠️ Secret mounts are updated on an interval, not real time. If rotation is a requirement ensure the token lifetime outlives the mount update interval and the rotation process doesn’t immediately invalidate the existing token
GKE
GKE cluster secret example using argocd-k8s-auth and Workload Identity:
apiVersion: v1
kind: Secret
metadata:
name: mycluster-secret
labels:
argocd.argoproj.io/secret-type: cluster
type: Opaque
stringData:
name: mycluster.example.com
server: https://mycluster.example.com
config: |
{
"execProviderConfig": {
"command": "argocd-k8s-auth",
"args": ["gcp"],
"apiVersion": "client.authentication.k8s.io/v1beta1"
},
"tlsClientConfig": {
"insecure": false,
"caData": "<base64 encoded certificate>"
}
}
Note that you must enable Workload Identity on your GKE cluster, create GCP service account with appropriate IAM role and bind it to Kubernetes service account for argocd-application-controller and argocd-server (showing Pod logs on UI). See Use Workload Identity and Authenticating to the Kubernetes API server.
AKS
Azure cluster secret example using argocd-k8s-auth and kubelogin. The option azure to the argocd-k8s-auth execProviderConfig encapsulates the get-token command for kubelogin. Depending upon which authentication flow is desired (devicecode, spn, ropc, msi, azurecli, workloadidentity), set the environment variable AAD_LOGIN_METHOD with this value. Set other appropriate environment variables depending upon which authentication flow is desired.
Variable Name | Description |
---|---|
AAD_LOGIN_METHOD | One of devicecode, spn, ropc, msi, azurecli, or workloadidentity |
AAD_SERVICE_PRINCIPAL_CLIENT_CERTIFICATE | AAD client cert in pfx. Used in spn login |
AAD_SERVICE_PRINCIPAL_CLIENT_ID | AAD client application ID |
AAD_SERVICE_PRINCIPAL_CLIENT_SECRET | AAD client application secret |
AAD_USER_PRINCIPAL_NAME | Used in the ropc flow |
AAD_USER_PRINCIPAL_PASSWORD | Used in the ropc flow |
AZURE_TENANT_ID | The AAD tenant ID. |
AZURE_AUTHORITY_HOST | Used in the WorkloadIdentityLogin flow |
AZURE_FEDERATED_TOKEN_FILE | Used in the WorkloadIdentityLogin flow |
AZURE_CLIENT_ID | Used in the WorkloadIdentityLogin flow |
In addition to the environment variables above, argocd-k8s-auth accepts two extra environment variables to set the AAD environment, and to set the AAD server application ID. The AAD server application ID will default to 6dae42f8-4368-4678-94ff-3960e28e3630 if not specified. See here for details.
Variable Name | Description |
---|---|
AAD_ENVIRONMENT_NAME | The azure environment to use, default of AzurePublicCloud |
AAD_SERVER_APPLICATION_ID | The optional AAD server application ID, defaults to 6dae42f8-4368-4678-94ff-3960e28e3630 |
This is an example of using the federated workload login flow. The federated token file needs to be mounted as a secret into argoCD, so it can be used in the flow. The location of the token file needs to be set in the environment variable AZURE_FEDERATED_TOKEN_FILE.
If your AKS cluster utilizes the Mutating Admission Webhook from the Azure Workload Identity project, follow these steps to enable the argocd-application-controller
and argocd-server
pods to use the federated identity:
Label the Pods: Add the
azure.workload.identity/use: "true"
label to theargocd-application-controller
andargocd-server
pods.Create Federated Identity Credential: Generate an Azure federated identity credential for the
argocd-application-controller
andargocd-server
service accounts. Refer to the Federated Identity Credential documentation for detailed instructions.Add Annotations to Service Account Add
"azure.workload.identity/client-id": "$CLIENT_ID"
and"azure.workload.identity/tenant-id": "$TENANT_ID"
annotations to theargocd-application-controller
andargocd-server
service accounts using the details from the federated credential.Set the AZURE_CLIENT_ID: Update the
AZURE_CLIENT_ID
in the cluster secret to match the client id of the newly created federated identity credential.
apiVersion: v1
kind: Secret
metadata:
name: mycluster-secret
labels:
argocd.argoproj.io/secret-type: cluster
type: Opaque
stringData:
name: mycluster.example.com
server: https://mycluster.example.com
config: |
{
"execProviderConfig": {
"command": "argocd-k8s-auth",
"env": {
"AAD_ENVIRONMENT_NAME": "AzurePublicCloud",
"AZURE_CLIENT_ID": "fill in client id",
"AZURE_TENANT_ID": "fill in tenant id", # optional, injected by workload identity mutating admission webhook if enabled
"AZURE_FEDERATED_TOKEN_FILE": "/opt/path/to/federated_file.json", # optional, injected by workload identity mutating admission webhook if enabled
"AZURE_AUTHORITY_HOST": "https://login.microsoftonline.com/", # optional, injected by workload identity mutating admission webhook if enabled
"AAD_LOGIN_METHOD": "workloadidentity"
},
"args": ["azure"],
"apiVersion": "client.authentication.k8s.io/v1beta1"
},
"tlsClientConfig": {
"insecure": false,
"caData": "<base64 encoded certificate>"
}
}
This is an example of using the spn (service principal name) flow.
apiVersion: v1
kind: Secret
metadata:
name: mycluster-secret
labels:
argocd.argoproj.io/secret-type: cluster
type: Opaque
stringData:
name: mycluster.example.com
server: https://mycluster.example.com
config: |
{
"execProviderConfig": {
"command": "argocd-k8s-auth",
"env": {
"AAD_ENVIRONMENT_NAME": "AzurePublicCloud",
"AAD_SERVICE_PRINCIPAL_CLIENT_SECRET": "fill in your service principal client secret",
"AZURE_TENANT_ID": "fill in tenant id",
"AAD_SERVICE_PRINCIPAL_CLIENT_ID": "fill in your service principal client id",
"AAD_LOGIN_METHOD": "spn"
},
"args": ["azure"],
"apiVersion": "client.authentication.k8s.io/v1beta1"
},
"tlsClientConfig": {
"insecure": false,
"caData": "<base64 encoded certificate>"
}
}
Helm Chart Repositories
Non standard Helm Chart repositories have to be registered explicitly. Each repository must have url
, type
and name
fields. For private Helm repos you may need to configure access credentials and HTTPS settings using username
, password
, tlsClientCertData
and tlsClientCertKey
fields.
Example:
apiVersion: v1
kind: Secret
metadata:
name: istio
namespace: argocd
labels:
argocd.argoproj.io/secret-type: repository
stringData:
name: istio.io
url: https://storage.googleapis.com/istio-prerelease/daily-build/master-latest-daily/charts
type: helm
---
apiVersion: v1
kind: Secret
metadata:
name: argo-helm
namespace: argocd
labels:
argocd.argoproj.io/secret-type: repository
stringData:
name: argo
url: https://argoproj.github.io/argo-helm
type: helm
username: my-username
password: my-password
tlsClientCertData: ...
tlsClientCertKey: ...
Resource Exclusion/Inclusion
Resources can be excluded from discovery and sync so that Argo CD is unaware of them. For example, the apiGroup/kind events.k8s.io/*
, metrics.k8s.io/*
, coordination.k8s.io/Lease
, and ""/Endpoints
are always excluded. Use cases:
- You have temporal issues and you want to exclude problematic resources.
- There are many of a kind of resources that impacts Argo CD’s performance.
- Restrict Argo CD’s access to certain kinds of resources, e.g. secrets. See security.md#cluster-rbac.
To configure this, edit the argocd-cm
config map:
kubectl edit configmap argocd-cm -n argocd
Add resource.exclusions
, e.g.:
apiVersion: v1
data:
resource.exclusions: |
- apiGroups:
- "*"
kinds:
- "*"
clusters:
- https://192.168.0.20
kind: ConfigMap
The resource.exclusions
node is a list of objects. Each object can have:
apiGroups
A list of globs to match the API group.kinds
A list of kinds to match. Can be"*"
to match all.clusters
A list of globs to match the cluster.
If all three match, then the resource is ignored.
In addition to exclusions, you might configure the list of included resources using the resource.inclusions
setting. By default, all resource group/kinds are included. The resource.inclusions
setting allows customizing the list of included group/kinds:
apiVersion: v1
data:
resource.inclusions: |
- apiGroups:
- "*"
kinds:
- Deployment
clusters:
- https://192.168.0.20
kind: ConfigMap
The resource.inclusions
and resource.exclusions
might be used together. The final list of resources includes group/kinds specified in resource.inclusions
minus group/kinds specified in resource.exclusions
setting.
Notes:
- Quote globs in your YAML to avoid parsing errors.
- Invalid globs result in the whole rule being ignored.
- If you add a rule that matches existing resources, these will appear in the interface as
OutOfSync
.
Auto respect RBAC for controller
Argocd controller can be restricted from discovering/syncing specific resources using just controller rbac, without having to manually configure resource exclusions. This feature can be enabled by setting resource.respectRBAC
key in argocd cm, once it is set the controller will automatically stop watching for resources that it does not have the permission to list/access. Possible values for resource.respectRBAC
are: - strict
: This setting checks whether the list call made by controller is forbidden/unauthorized and if it is, it will cross-check the permission by making a SelfSubjectAccessReview
call for the resource. - normal
: This will only check whether the list call response is forbidden/unauthorized and skip SelfSubjectAccessReview
call, to minimize any extra api-server calls. - unset/empty (default) : This will disable the feature and controller will continue to monitor all resources.
Users who are comfortable with an increase in kube api-server calls can opt for strict
option while users who are concerned with higher api calls and are willing to compromise on the accuracy can opt for the normal
option.
Notes:
- When set to use
strict
mode controller must have rbac permission tocreate
aSelfSubjectAccessReview
resource - The
SelfSubjectAccessReview
request will be only made for thelist
verb, it is assumed that iflist
is allowed for a resource then all other permissions are also available to the controller.
Example argocd cm with resource.respectRBAC
set to strict
:
apiVersion: v1
kind: ConfigMap
metadata:
name: argocd-cm
data:
resource.respectRBAC: "strict"
Resource Custom Labels
Custom Labels configured with resource.customLabels
(comma separated string) will be displayed in the UI (for any resource that defines them).
Labels on Application Events
An optional comma-separated list of metadata.labels
keys can be configured with resource.includeEventLabelKeys
to add to Kubernetes events generated for Argo CD Applications. When events are generated for Applications containing the specified labels, the controller adds the matching labels to the event. This establishes an easy link between the event and the application, allowing for filtering using labels. In case of conflict between labels on the Application and AppProject, the Application label values are prioritized and added to the event.
resource.includeEventLabelKeys: team,env*
To exclude certain labels from events, use the resource.excludeEventLabelKeys
key, which takes a comma-separated list of metadata.labels
keys.
resource.excludeEventLabelKeys: environment,bu
Both resource.includeEventLabelKeys
and resource.excludeEventLabelKeys
support wildcards.
SSO & RBAC
Manage Argo CD Using Argo CD
Argo CD is able to manage itself since all settings are represented by Kubernetes manifests. The suggested way is to create Kustomize based application which uses base Argo CD manifests from https://github.com/argoproj/argo-cd and apply required changes on top.
Example of kustomization.yaml
:
# additional resources like ingress rules, cluster and repository secrets.
resources:
- github.com/argoproj/argo-cd//manifests/cluster-install?ref=stable
- clusters-secrets.yaml
- repos-secrets.yaml
# changes to config maps
patches:
- path: overlays/argo-cd-cm.yaml
The live example of self managed Argo CD config is available at https://cd.apps.argoproj.io and with configuration stored at argoproj/argoproj-deployments.
Note
You will need to sign-in using your GitHub account to get access to https://cd.apps.argoproj.io