Terraform module to provision an EKS cluster on AWS.
This project is part of our comprehensive "SweetOps" approach towards DevOps.
It's 100% Open Source and licensed under the APACHE2.
We literally have hundreds of terraform modules that are Open Source and well-maintained. Check them out!
The module provisions the following resources:
- EKS cluster of master nodes that can be used together with the terraform-aws-eks-workers, terraform-aws-eks-node-group and terraform-aws-eks-fargate-profile modules to create a full-blown cluster
- IAM Role to allow the cluster to access other AWS services
- Security Group which is used by EKS workers to connect to the cluster and kubelets and pods to receive communication from the cluster control plane
- The module creates and automatically applies an authentication ConfigMap to allow the workers nodes to join the cluster and to add additional users/roles/accounts
NOTE: The module works with Terraform Cloud.
NOTE: Every Terraform module that provisions an EKS cluster has faced the challenge that access to the cluster
is partly controlled by a resource inside the cluster, a ConfigMap called aws-auth
. You need to be able to access
the cluster through the Kubernetes API to modify the ConfigMap, because there is no AWS API for it. This presents
a problem: how do you authenticate to an API endpoint that you have not yet created?
We use the Terraform Kubernetes provider to access the cluster, and it uses the same underlying library
that kubectl
uses, so configuration is very similar. However, every kind of configuration we have tried
has failed at some point.
- After creating the EKS cluster, we can generate a
kubeconfig
file that configures access to it. This works most of the time, but if the file was present and used as part of the configuration to create the cluster, and then the file is deleted (as would happen in a CI system like Terraform Cloud), Terraform would not cause the file to be regenerated in time to use it to refresh Terraform's state and the "plan" phase will fail. - An authentication token can be retrieved using the
aws_eks_cluster_auth
data source. Again, this works, as long as the token does not expire while Terraform is running, and the token is refreshed during the "plan" phase before trying to refresh the state. Unfortunately, failures of both types have been seen. - An authentication token can be retrieved on demand by using the
exec
feature of the Kubernetes provider to callaws eks get-token
. This requires that theaws
CLI be installed and available to Terraform and that it has access to sufficient credentials to perform the authentication and is configured to use them.
All of the above methods can face additional challenges when using terraform import
to import
resources into the Terraform state. The KUBECONFG file is the most reliable, and probably what you
would want to use when importing objects if your usual method does not work. You will need to create
the file, of course, but that is easily done with aws eks update-kubeconfig
.
At the moment, the exec
option appears to be the most reliable method, so we recommend using it if possible,
but because of the extra requirements it has, we use the data source as the default authentication method.
NOTE: We give you the kubernetes_config_map_ignore_role_changes
option and default it to true
for the following reasons:
- We provision the EKS cluster
- Then we wait for the cluster to become available (see
null_resource.wait_for_cluster
in auth.tf - Then we provision the Kubernetes Auth ConfigMap to map and add additional roles/users/accounts to Kubernetes groups
- That is all we do in this module, but after that, we expect you to use terraform-aws-eks-node-group to provision a managed Node Group
- Then EKS updates the Auth ConfigMap and adds worker roles to it (for the worker nodes to join the cluster)
- Since the ConfigMap is modified outside of Terraform state, Terraform wants to update it to to remove the worker roles EKS added
- If you update the ConfigMap without including the worker nodes that EKS added, you will disconnect them from the cluster
However, it is possible to get the worker node roles from the terraform-aws-eks-node-group via Terraform "remote state" and include them with any other roles you want to add (example code to be published later), so we make ignoring the role changes optional. If you do not ignore changes then you will have no problem with making future intentional changes.
The downside of having kubernetes_config_map_ignore_role_changes
set to true is that if you later want to make changes,
such as adding other IAM roles to Kubernetes groups, you cannot do so via Terraform, because the role changes are ignored.
Because of Terraform restrictions, you cannot simply change kubernetes_config_map_ignore_role_changes
from true
to false
, apply changes, and set it back to true
again. Terraform does not allow the
"ignore" settings to be changed on a resource, so kubernetes_config_map_ignore_role_changes
is implemented as
2 different resources, one with ignore settings and one without. If you want to switch from ignoring to not ignoring,
or vice versa, you must manually move the aws_auth
resource in the terraform state. Change the setting of
kubernetes_config_map_ignore_role_changes
, run terraform plan
, and you will see that an aws_auth
resource
is planned to be destroyed and another one is planned to be created. Use terraform state mv
to move the destroyed
resource to the created resource "address", something like
terraform state mv 'module.eks_cluster.kubernetes_config_map.aws_auth_ignore_changes[0]' 'module.eks_cluster.kubernetes_config_map.aws_auth[0]'
Then run terraform plan
again and you should see only your desired changes made "in place". After applying your
changes, if you want to set kubernetes_config_map_ignore_role_changes
back to true
, you will again need to use
terraform state mv
to move the auth-map
back to its old "address".
Security scanning is graciously provided by Bridgecrew. Bridgecrew is the leading fully hosted, cloud-native solution providing continuous Terraform security and compliance.
IMPORTANT: We do not pin modules to versions in our examples because of the difficulty of keeping the versions in the documentation in sync with the latest released versions. We highly recommend that in your code you pin the version to the exact version you are using so that your infrastructure remains stable, and update versions in a systematic way so that they do not catch you by surprise.
Also, because of a bug in the Terraform registry (hashicorp/terraform#21417), the registry shows many of our inputs as required when in fact they are optional. The table below correctly indicates which inputs are required.
For a complete example, see examples/complete.
For automated tests of the complete example using bats and Terratest (which tests and deploys the example on AWS), see test.
Other examples:
- terraform-root-modules/eks - Cloud Posse's service catalog of "root module" invocations for provisioning reference architectures
- terraform-root-modules/eks-backing-services-peering - example of VPC peering between the EKS VPC and backing services VPC
provider "aws" {
region = var.region
}
module "label" {
source = "cloudposse/label/null"
# Cloud Posse recommends pinning every module to a specific version
# version = "x.x.x"
namespace = var.namespace
name = var.name
stage = var.stage
delimiter = var.delimiter
attributes = ["cluster"]
tags = var.tags
}
locals {
# Prior to Kubernetes 1.19, the usage of the specific kubernetes.io/cluster/* resource tags below are required
# for EKS and Kubernetes to discover and manage networking resources
# https://www.terraform.io/docs/providers/aws/guides/eks-getting-started.html#base-vpc-networking
tags = { "kubernetes.io/cluster/${module.label.id}" = "shared" }
}
module "vpc" {
source = "cloudposse/vpc/aws"
# Cloud Posse recommends pinning every module to a specific version
# version = "x.x.x"
cidr_block = "172.16.0.0/16"
tags = local.tags
context = module.label.context
}
module "subnets" {
source = "cloudposse/dynamic-subnets/aws"
# Cloud Posse recommends pinning every module to a specific version
# version = "x.x.x"
availability_zones = var.availability_zones
vpc_id = module.vpc.vpc_id
igw_id = module.vpc.igw_id
cidr_block = module.vpc.vpc_cidr_block
nat_gateway_enabled = true
nat_instance_enabled = false
tags = local.tags
context = module.label.context
}
module "eks_node_group" {
source = "cloudposse/eks-node-group/aws"
# Cloud Posse recommends pinning every module to a specific version
# version = "x.x.x"
instance_types = [var.instance_type]
subnet_ids = module.subnets.public_subnet_ids
health_check_type = var.health_check_type
min_size = var.min_size
max_size = var.max_size
cluster_name = module.eks_cluster.eks_cluster_id
# Enable the Kubernetes cluster auto-scaler to find the auto-scaling group
cluster_autoscaler_enabled = var.autoscaling_policies_enabled
context = module.label.context
# Ensure the cluster is fully created before trying to add the node group
module_depends_on = module.eks_cluster.kubernetes_config_map_id
}
module "eks_cluster" {
source = "cloudposse/eks-cluster/aws"
# Cloud Posse recommends pinning every module to a specific version
# version = "x.x.x"
vpc_id = module.vpc.vpc_id
subnet_ids = module.subnets.public_subnet_ids
kubernetes_version = var.kubernetes_version
oidc_provider_enabled = true
context = module.label.context
}
Module usage with two worker groups:
locals {
# Unfortunately, the `aws_ami` data source attribute `most_recent` (https://github.com/cloudposse/terraform-aws-eks-workers/blob/34a43c25624a6efb3ba5d2770a601d7cb3c0d391/main.tf#L141)
# does not work as you might expect. If you are not going to use a custom AMI you should
# use the `eks_worker_ami_name_filter` variable to set the right kubernetes version for EKS workers,
# otherwise the first version of Kubernetes supported by AWS (v1.11) for EKS workers will be selected, but
# EKS control plane will ignore it to use one that matches the version specified by the `kubernetes_version` variable.
eks_worker_ami_name_filter = "amazon-eks-node-${var.kubernetes_version}*"
}
module "eks_workers" {
source = "cloudposse/eks-workers/aws"
# Cloud Posse recommends pinning every module to a specific version
# version = "x.x.x"
attributes = ["small"]
instance_type = "t3.small"
eks_worker_ami_name_filter = local.eks_worker_ami_name_filter
vpc_id = module.vpc.vpc_id
subnet_ids = module.subnets.public_subnet_ids
health_check_type = var.health_check_type
min_size = var.min_size
max_size = var.max_size
wait_for_capacity_timeout = var.wait_for_capacity_timeout
cluster_name = module.label.id
cluster_endpoint = module.eks_cluster.eks_cluster_endpoint
cluster_certificate_authority_data = module.eks_cluster.eks_cluster_certificate_authority_data
cluster_security_group_id = module.eks_cluster.security_group_id
# Auto-scaling policies and CloudWatch metric alarms
autoscaling_policies_enabled = var.autoscaling_policies_enabled
cpu_utilization_high_threshold_percent = var.cpu_utilization_high_threshold_percent
cpu_utilization_low_threshold_percent = var.cpu_utilization_low_threshold_percent
context = module.label.context
}
module "eks_workers_2" {
source = "cloudposse/eks-workers/aws"
# Cloud Posse recommends pinning every module to a specific version
# version = "x.x.x"
attributes = ["medium"]
instance_type = "t3.medium"
eks_worker_ami_name_filter = local.eks_worker_ami_name_filter
vpc_id = module.vpc.vpc_id
subnet_ids = module.subnets.public_subnet_ids
health_check_type = var.health_check_type
min_size = var.min_size
max_size = var.max_size
wait_for_capacity_timeout = var.wait_for_capacity_timeout
cluster_name = module.label.id
cluster_endpoint = module.eks_cluster.eks_cluster_endpoint
cluster_certificate_authority_data = module.eks_cluster.eks_cluster_certificate_authority_data
cluster_security_group_id = module.eks_cluster.security_group_id
# Auto-scaling policies and CloudWatch metric alarms
autoscaling_policies_enabled = var.autoscaling_policies_enabled
cpu_utilization_high_threshold_percent = var.cpu_utilization_high_threshold_percent
cpu_utilization_low_threshold_percent = var.cpu_utilization_low_threshold_percent
context = module.label.context
}
module "eks_cluster" {
source = "cloudposse/eks-cluster/aws"
# Cloud Posse recommends pinning every module to a specific version
# version = "x.x.x"
vpc_id = module.vpc.vpc_id
subnet_ids = module.subnets.public_subnet_ids
kubernetes_version = var.kubernetes_version
oidc_provider_enabled = false
workers_role_arns = [module.eks_workers.workers_role_arn, module.eks_workers_2.workers_role_arn]
workers_security_group_ids = [module.eks_workers.security_group_id, module.eks_workers_2.security_group_id]
context = module.label.context
}
Available targets:
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lint Lint terraform code
Name | Version |
---|---|
terraform | >= 0.13.0 |
aws | >= 3.38 |
kubernetes | >= 1.13 |
local | >= 1.3 |
null | >= 2.0 |
tls | >= 2.2.0 |
Name | Version |
---|---|
aws | >= 3.38 |
kubernetes | >= 1.13 |
null | >= 2.0 |
tls | >= 2.2.0 |
Name | Source | Version |
---|---|---|
label | cloudposse/label/null | 0.25.0 |
this | cloudposse/label/null | 0.25.0 |
Name | Description | Type | Default | Required |
---|---|---|---|---|
additional_tag_map | Additional key-value pairs to add to each map in tags_as_list_of_maps . Not added to tags or id .This is for some rare cases where resources want additional configuration of tags and therefore take a list of maps with tag key, value, and additional configuration. |
map(string) |
{} |
no |
addons | Manages aws_eks_addon resources. |
list(object({ |
[] |
no |
allowed_cidr_blocks | List of CIDR blocks to be allowed to connect to the EKS cluster | list(string) |
[] |
no |
allowed_security_groups | List of Security Group IDs to be allowed to connect to the EKS cluster | list(string) |
[] |
no |
apply_config_map_aws_auth | Whether to apply the ConfigMap to allow worker nodes to join the EKS cluster and allow additional users, accounts and roles to acces the cluster | bool |
true |
no |
attributes | ID element. Additional attributes (e.g. workers or cluster ) to add to id ,in the order they appear in the list. New attributes are appended to the end of the list. The elements of the list are joined by the delimiter and treated as a single ID element. |
list(string) |
[] |
no |
aws_auth_yaml_strip_quotes | If true, remove double quotes from the generated aws-auth ConfigMap YAML to reduce spurious diffs in plans | bool |
true |
no |
cluster_encryption_config_enabled | Set to true to enable Cluster Encryption Configuration |
bool |
true |
no |
cluster_encryption_config_kms_key_deletion_window_in_days | Cluster Encryption Config KMS Key Resource argument - key deletion windows in days post destruction | number |
10 |
no |
cluster_encryption_config_kms_key_enable_key_rotation | Cluster Encryption Config KMS Key Resource argument - enable kms key rotation | bool |
true |
no |
cluster_encryption_config_kms_key_id | KMS Key ID to use for cluster encryption config | string |
"" |
no |
cluster_encryption_config_kms_key_policy | Cluster Encryption Config KMS Key Resource argument - key policy | string |
null |
no |
cluster_encryption_config_resources | Cluster Encryption Config Resources to encrypt, e.g. ['secrets'] | list(any) |
[ |
no |
cluster_log_retention_period | Number of days to retain cluster logs. Requires enabled_cluster_log_types to be set. See https://docs.aws.amazon.com/en_us/eks/latest/userguide/control-plane-logs.html. |
number |
0 |
no |
context | Single object for setting entire context at once. See description of individual variables for details. Leave string and numeric variables as null to use default value.Individual variable settings (non-null) override settings in context object, except for attributes, tags, and additional_tag_map, which are merged. |
any |
{ |
no |
create_eks_service_role | Set false to use existing eks_cluster_service_role_arn instead of creating one |
bool |
true |
no |
delimiter | Delimiter to be used between ID elements. Defaults to - (hyphen). Set to "" to use no delimiter at all. |
string |
null |
no |
descriptor_formats | Describe additional descriptors to be output in the descriptors output map.Map of maps. Keys are names of descriptors. Values are maps of the form {<br> format = string<br> labels = list(string)<br>} (Type is any so the map values can later be enhanced to provide additional options.)format is a Terraform format string to be passed to the format() function.labels is a list of labels, in order, to pass to format() function.Label values will be normalized before being passed to format() so they will beidentical to how they appear in id .Default is {} (descriptors output will be empty). |
any |
{} |
no |
dummy_kubeapi_server | URL of a dummy API server for the Kubernetes server to use when the real one is unknown. This is a workaround to ignore connection failures that break Terraform even though the results do not matter. You can disable it by setting it to null ; however, as of Kubernetes provider v2.3.2, doing so _will_cause Terraform to fail in several situations unless you provide a valid kubeconfig filevia kubeconfig_path and set kubeconfig_path_enabled to true . |
string |
"https://jsonplaceholder.typicode.com" |
no |
eks_cluster_service_role_arn | The ARN of an IAM role for the EKS cluster to use that provides permissions for the Kubernetes control plane to perform needed AWS API operations. Required if create_eks_service_role is false , ignored otherwise. |
string |
null |
no |
enabled | Set to false to prevent the module from creating any resources | bool |
null |
no |
enabled_cluster_log_types | A list of the desired control plane logging to enable. For more information, see https://docs.aws.amazon.com/en_us/eks/latest/userguide/control-plane-logs.html. Possible values [api , audit , authenticator , controllerManager , scheduler ] |
list(string) |
[] |
no |
endpoint_private_access | Indicates whether or not the Amazon EKS private API server endpoint is enabled. Default to AWS EKS resource and it is false | bool |
false |
no |
endpoint_public_access | Indicates whether or not the Amazon EKS public API server endpoint is enabled. Default to AWS EKS resource and it is true | bool |
true |
no |
environment | ID element. Usually used for region e.g. 'uw2', 'us-west-2', OR role 'prod', 'staging', 'dev', 'UAT' | string |
null |
no |
id_length_limit | Limit id to this many characters (minimum 6).Set to 0 for unlimited length.Set to null for keep the existing setting, which defaults to 0 .Does not affect id_full . |
number |
null |
no |
kube_data_auth_enabled | If true , use an aws_eks_cluster_auth data source to authenticate to the EKS cluster.Disabled by kubeconfig_path_enabled or kube_exec_auth_enabled . |
bool |
true |
no |
kube_exec_auth_aws_profile | The AWS config profile for aws eks get-token to use |
string |
"" |
no |
kube_exec_auth_aws_profile_enabled | If true , pass kube_exec_auth_aws_profile as the profile to aws eks get-token |
bool |
false |
no |
kube_exec_auth_enabled | If true , use the Kubernetes provider exec feature to execute aws eks get-token to authenticate to the EKS cluster.Disabled by kubeconfig_path_enabled , overrides kube_data_auth_enabled . |
bool |
false |
no |
kube_exec_auth_role_arn | The role ARN for aws eks get-token to use |
string |
"" |
no |
kube_exec_auth_role_arn_enabled | If true , pass kube_exec_auth_role_arn as the role ARN to aws eks get-token |
bool |
false |
no |
kubeconfig_path | The Kubernetes provider config_path setting to use when kubeconfig_path_enabled is true |
string |
"" |
no |
kubeconfig_path_enabled | If true , configure the Kubernetes provider with kubeconfig_path and use it for authenticating to the EKS cluster |
bool |
false |
no |
kubernetes_config_map_ignore_role_changes | Set to true to ignore IAM role changes in the Kubernetes Auth ConfigMap |
bool |
true |
no |
kubernetes_version | Desired Kubernetes master version. If you do not specify a value, the latest available version is used | string |
"1.15" |
no |
label_key_case | Controls the letter case of the tags keys (label names) for tags generated by this module.Does not affect keys of tags passed in via the tags input.Possible values: lower , title , upper .Default value: title . |
string |
null |
no |
label_order | The order in which the labels (ID elements) appear in the id .Defaults to ["namespace", "environment", "stage", "name", "attributes"]. You can omit any of the 6 labels ("tenant" is the 6th), but at least one must be present. |
list(string) |
null |
no |
label_value_case | Controls the letter case of ID elements (labels) as included in id ,set as tag values, and output by this module individually. Does not affect values of tags passed in via the tags input.Possible values: lower , title , upper and none (no transformation).Set this to title and set delimiter to "" to yield Pascal Case IDs.Default value: lower . |
string |
null |
no |
labels_as_tags | Set of labels (ID elements) to include as tags in the tags output.Default is to include all labels. Tags with empty values will not be included in the tags output.Set to [] to suppress all generated tags.Notes: The value of the name tag, if included, will be the id , not the name .Unlike other null-label inputs, the initial setting of labels_as_tags cannot bechanged in later chained modules. Attempts to change it will be silently ignored. |
set(string) |
[ |
no |
local_exec_interpreter | shell to use for local_exec | list(string) |
[ |
no |
map_additional_aws_accounts | Additional AWS account numbers to add to config-map-aws-auth ConfigMap |
list(string) |
[] |
no |
map_additional_iam_roles | Additional IAM roles to add to config-map-aws-auth ConfigMap |
list(object({ |
[] |
no |
map_additional_iam_users | Additional IAM users to add to config-map-aws-auth ConfigMap |
list(object({ |
[] |
no |
name | ID element. Usually the component or solution name, e.g. 'app' or 'jenkins'. This is the only ID element not also included as a tag .The "name" tag is set to the full id string. There is no tag with the value of the name input. |
string |
null |
no |
namespace | ID element. Usually an abbreviation of your organization name, e.g. 'eg' or 'cp', to help ensure generated IDs are globally unique | string |
null |
no |
oidc_provider_enabled | Create an IAM OIDC identity provider for the cluster, then you can create IAM roles to associate with a service account in the cluster, instead of using kiam or kube2iam. For more information, see https://docs.aws.amazon.com/eks/latest/userguide/enable-iam-roles-for-service-accounts.html | bool |
false |
no |
permissions_boundary | If provided, all IAM roles will be created with this permissions boundary attached. | string |
null |
no |
public_access_cidrs | Indicates which CIDR blocks can access the Amazon EKS public API server endpoint when enabled. EKS defaults this to a list with 0.0.0.0/0. | list(string) |
[ |
no |
regex_replace_chars | Terraform regular expression (regex) string. Characters matching the regex will be removed from the ID elements. If not set, "/[^a-zA-Z0-9-]/" is used to remove all characters other than hyphens, letters and digits. |
string |
null |
no |
region | AWS Region | string |
n/a | yes |
stage | ID element. Usually used to indicate role, e.g. 'prod', 'staging', 'source', 'build', 'test', 'deploy', 'release' | string |
null |
no |
subnet_ids | A list of subnet IDs to launch the cluster in | list(string) |
n/a | yes |
tags | Additional tags (e.g. {'BusinessUnit': 'XYZ'} ).Neither the tag keys nor the tag values will be modified by this module. |
map(string) |
{} |
no |
tenant | ID element _(Rarely used, not included by default)_. A customer identifier, indicating who this instance of a resource is for | string |
null |
no |
vpc_id | VPC ID for the EKS cluster | string |
n/a | yes |
wait_for_cluster_command | local-exec command to execute to determine if the EKS cluster is healthy. Cluster endpoint are available as environment variable ENDPOINT |
string |
"curl --silent --fail --retry 60 --retry-delay 5 --retry-connrefused --insecure --output /dev/null $ENDPOINT/healthz" |
no |
workers_role_arns | List of Role ARNs of the worker nodes | list(string) |
[] |
no |
workers_security_group_ids | Security Group IDs of the worker nodes | list(string) |
[] |
no |
Name | Description |
---|---|
cluster_encryption_config_enabled | If true, Cluster Encryption Configuration is enabled |
cluster_encryption_config_provider_key_alias | Cluster Encryption Config KMS Key Alias ARN |
cluster_encryption_config_provider_key_arn | Cluster Encryption Config KMS Key ARN |
cluster_encryption_config_resources | Cluster Encryption Config Resources |
eks_cluster_arn | The Amazon Resource Name (ARN) of the cluster |
eks_cluster_certificate_authority_data | The Kubernetes cluster certificate authority data |
eks_cluster_endpoint | The endpoint for the Kubernetes API server |
eks_cluster_id | The name of the cluster |
eks_cluster_identity_oidc_issuer | The OIDC Identity issuer for the cluster |
eks_cluster_identity_oidc_issuer_arn | The OIDC Identity issuer ARN for the cluster that can be used to associate IAM roles with a service account |
eks_cluster_managed_security_group_id | Security Group ID that was created by EKS for the cluster. EKS creates a Security Group and applies it to ENI that is attached to EKS Control Plane master nodes and to any managed workloads |
eks_cluster_role_arn | ARN of the EKS cluster IAM role |
eks_cluster_version | The Kubernetes server version of the cluster |
kubernetes_config_map_id | ID of aws-auth Kubernetes ConfigMap |
security_group_arn | ARN of the EKS cluster Security Group |
security_group_id | ID of the EKS cluster Security Group |
security_group_name | Name of the EKS cluster Security Group |
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We are a DevOps Accelerator. We'll help you build your cloud infrastructure from the ground up so you can own it. Then we'll show you how to operate it and stick around for as long as you need us.
Work directly with our team of DevOps experts via email, slack, and video conferencing.
We deliver 10x the value for a fraction of the cost of a full-time engineer. Our track record is not even funny. If you want things done right and you need it done FAST, then we're your best bet.
- Reference Architecture. You'll get everything you need from the ground up built using 100% infrastructure as code.
- Release Engineering. You'll have end-to-end CI/CD with unlimited staging environments.
- Site Reliability Engineering. You'll have total visibility into your apps and microservices.
- Security Baseline. You'll have built-in governance with accountability and audit logs for all changes.
- GitOps. You'll be able to operate your infrastructure via Pull Requests.
- Training. You'll receive hands-on training so your team can operate what we build.
- Questions. You'll have a direct line of communication between our teams via a Shared Slack channel.
- Troubleshooting. You'll get help to triage when things aren't working.
- Code Reviews. You'll receive constructive feedback on Pull Requests.
- Bug Fixes. We'll rapidly work with you to fix any bugs in our projects.
Join our Open Source Community on Slack. It's FREE for everyone! Our "SweetOps" community is where you get to talk with others who share a similar vision for how to rollout and manage infrastructure. This is the best place to talk shop, ask questions, solicit feedback, and work together as a community to build totally sweet infrastructure.
Participate in our Discourse Forums. Here you'll find answers to commonly asked questions. Most questions will be related to the enormous number of projects we support on our GitHub. Come here to collaborate on answers, find solutions, and get ideas about the products and services we value. It only takes a minute to get started! Just sign in with SSO using your GitHub account.
Sign up for our newsletter that covers everything on our technology radar. Receive updates on what we're up to on GitHub as well as awesome new projects we discover.
Join us every Wednesday via Zoom for our weekly "Lunch & Learn" sessions. It's FREE for everyone!
Please use the issue tracker to report any bugs or file feature requests.
If you are interested in being a contributor and want to get involved in developing this project or help out with our other projects, we would love to hear from you! Shoot us an email.
In general, PRs are welcome. We follow the typical "fork-and-pull" Git workflow.
- Fork the repo on GitHub
- Clone the project to your own machine
- Commit changes to your own branch
- Push your work back up to your fork
- Submit a Pull Request so that we can review your changes
NOTE: Be sure to merge the latest changes from "upstream" before making a pull request!
Copyright © 2017-2021 Cloud Posse, LLC
See LICENSE for full details.
Licensed to the Apache Software Foundation (ASF) under one
or more contributor license agreements. See the NOTICE file
distributed with this work for additional information
regarding copyright ownership. The ASF licenses this file
to you under the Apache License, Version 2.0 (the
"License"); you may not use this file except in compliance
with the License. You may obtain a copy of the License at
https://www.apache.org/licenses/LICENSE-2.0
Unless required by applicable law or agreed to in writing,
software distributed under the License is distributed on an
"AS IS" BASIS, WITHOUT WARRANTIES OR CONDITIONS OF ANY
KIND, either express or implied. See the License for the
specific language governing permissions and limitations
under the License.
All other trademarks referenced herein are the property of their respective owners.
This project is maintained and funded by Cloud Posse, LLC. Like it? Please let us know by leaving a testimonial!
We're a DevOps Professional Services company based in Los Angeles, CA. We ❤️ Open Source Software.
We offer paid support on all of our projects.
Check out our other projects, follow us on twitter, apply for a job, or hire us to help with your cloud strategy and implementation.
Erik Osterman |
Andriy Knysh |
Igor Rodionov |
Oscar |
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