cafaf2e2ee
* e2e: cleanup podman installation in jammy image The original steps were copied over from the bionic image and does a lot of hoop jumping we do not need anymore. For the moment just hard-code installing the v0.4.2 version of the driver, but I may follow up and modify hc-install to support installing @latest like go itself. * use releases for hc-install |
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.. | ||
etc | ||
hcp-vault-auth | ||
packer | ||
provision-nomad | ||
scripts | ||
uploads | ||
userdata | ||
.gitignore | ||
.terraform.lock.hcl | ||
compute.tf | ||
ecs-task.json | ||
ecs.tf | ||
hcp_consul.tf | ||
hcp_vault.tf | ||
iam.tf | ||
main.tf | ||
Makefile | ||
network.tf | ||
nomad-acls.tf | ||
nomad.tf | ||
outputs.tf | ||
README.md | ||
terraform.tfvars | ||
tls_ca.tf | ||
tls_client.tf | ||
variables.tf | ||
versions.tf | ||
volumes.tf |
Terraform infrastructure
This folder contains Terraform resources for provisioning a Nomad cluster on EC2 instances on AWS to use as the target of end-to-end tests.
Terraform provisions the AWS infrastructure assuming that EC2 AMIs have already been built via Packer and HCP Consul and HCP Vault clusters are already running. It deploys a build of Nomad from your local machine along with configuration files.
Setup
You'll need a recent version of Terraform (1.1+ recommended), as well
as AWS credentials to create the Nomad cluster and credentials for
HCP. This Terraform stack assumes that an appropriate instance role
has been configured elsewhere and that you have the ability to
AssumeRole
into the AWS account.
Configure the following environment variables. For HashiCorp Nomad
developers, this configuration can be found in 1Pass in the Nomad
team's vault under nomad-e2e
.
export HCP_CLIENT_ID=
export HCP_CLIENT_SECRET=
export CONSUL_HTTP_TOKEN=
export CONSUL_HTTP_ADDR=
The Vault admin token will expire after 6 hours. If you haven't
created one already use the separate Terraform configuration found in
the hcp-vault-auth
directory. The following will set the correct
values for VAULT_TOKEN
, VAULT_ADDR
, and VAULT_NAMESPACE
:
cd ./hcp-vault-auth
terraform init
terraform apply --auto-approve
$(terraform output --raw environment)
Optionally, edit the terraform.tfvars
file to change the number of
Linux clients or Windows clients.
region = "us-east-1"
instance_type = "t2.medium"
server_count = "3"
client_count_ubuntu_jammy_amd64 = "4"
client_count_windows_2016_amd64 = "1"
Optionally, edit the nomad_local_binary
variable in the
terraform.tfvars
file to change the path to the local binary of
Nomad you'd like to upload.
Run Terraform apply to deploy the infrastructure:
cd e2e/terraform/
terraform init
terraform apply
Note: You will likely see "Connection refused" or "Permission denied" errors in the logs as the provisioning script run by Terraform hits an instance where the ssh service isn't yet ready. That's ok and expected; they'll get retried. In particular, Windows instances can take a few minutes before ssh is ready.
Also note: When ACLs are being bootstrapped, you may see "No cluster leader" in the output several times while the ACL bootstrap script polls the cluster to start and and elect a leader.
Configuration
The files in etc
are template configuration files for Nomad and the
Consul agent. Terraform will render these files to the uploads
folder and upload them to the cluster during provisioning.
etc/nomad.d
are the Nomad configuration files.base.hcl
,tls.hcl
,consul.hcl
, andvault.hcl
are shared.server-linux.hcl
,client-linux.hcl
, andclient-windows.hcl
are role and platform specific.client-linux-0.hcl
, etc. are specific to individual instances.
etc/consul.d
are the Consul agent configuration files.etc/acls
are ACL policy files for Consul and Vault.
Web UI
To access the web UI, deploy a reverse proxy to the cluster. All
clients have a TLS proxy certificate at /etc/nomad.d/tls_proxy.crt
and a self-signed cert at /etc/nomad.d/self_signed.crt
. See
../ui/inputs/proxy.nomad
for an example of using this. Deploy as follows:
nomad namespace apply proxy
nomad job run ../ui/input/proxy.nomad
You can get the public IP for the proxy allocation from the following nested query:
nomad node status -json -verbose \
$(nomad operator api '/v1/allocations?namespace=proxy' | jq -r '.[] | select(.JobID == "nomad-proxy") | .NodeID') \
| jq '.Attributes."unique.platform.aws.public-ipv4"'
Outputs
After deploying the infrastructure, you can get connection information about the cluster:
$(terraform output --raw environment)
will set your current shell'sNOMAD_ADDR
andCONSUL_HTTP_ADDR
to point to one of the cluster's server nodes, and set theNOMAD_E2E
variable.terraform output servers
will output the list of server node IPs.terraform output linux_clients
will output the list of Linux client node IPs.terraform output windows_clients
will output the list of Windows client node IPs.
SSH
You can use Terraform outputs above to access nodes via ssh:
ssh -i keys/nomad-e2e-*.pem ubuntu@${EC2_IP_ADDR}
The Windows client runs OpenSSH for convenience, but has a different user and will drop you into a Powershell shell instead of bash:
ssh -i keys/nomad-e2e-*.pem Administrator@${EC2_IP_ADDR}
Teardown
The terraform state file stores all the info.
cd e2e/terraform/
terraform destroy
FAQ
E2E Provisioning Goals
- The provisioning process should be able to run a nightly build against a variety of OS targets.
- The provisioning process should be able to support update-in-place tests. (See #7063)
- A developer should be able to quickly stand up a small E2E cluster and provision it with a version of Nomad they've built on their laptop. The developer should be able to send updated builds to that cluster with a short iteration time, rather than having to rebuild the cluster.
Why not just drop all the provisioning into the AMI?
While that's the "correct" production approach for cloud infrastructure, it creates a few pain points for testing:
- Creating a Linux AMI takes >10min, and creating a Windows AMI can take 15-20min. This interferes with goal (3) above.
- We won't be able to do in-place upgrade testing without having an in-place provisioning process anyways. This interferes with goals (2) above.
Why not just drop all the provisioning into the user data?
- Userdata is executed on boot, which prevents using them for in-place upgrade testing.
- Userdata scripts are not very observable and it's painful to determine whether they've failed or simply haven't finished yet before trying to run tests.