Packet.net Guide
Introduction
Packet.net is a bare metal infrastructure host that’s supported by Ansible (>=2.3) via a dynamic inventory script and two cloud modules. The two modules are:
- packet_sshkey: adds a public SSH key from file or value to the Packet infrastructure. Every subsequently-created device will have this public key installed in .ssh/authorized_keys.
- packet_device: manages servers on Packet. You can use this module to create, restart and delete devices.
Note, this guide assumes you are familiar with Ansible and how it works. If you’re not, have a look at their docs before getting started.
Requirements
The Packet modules and inventory script connect to the Packet API using the packet-python package. You can install it with pip:
$ pip install packet-python
In order to check the state of devices created by Ansible on Packet, it’s a good idea to install one of the Packet CLI clients. Otherwise you can check them via the Packet portal.
To use the modules and inventory script you’ll need a Packet API token. You can generate an API token via the Packet portal here. The simplest way to authenticate yourself is to set the Packet API token in an environment variable:
$ export PACKET_API_TOKEN=Bfse9F24SFtfs423Gsd3ifGsd43sSdfs
If you’re not comfortable exporting your API token, you can pass it as a parameter to the modules.
On Packet, devices and reserved IP addresses belong to projects. In order to use the packet_device module, you need to specify the UUID of the project in which you want to create or manage devices. You can find a project’s UUID in the Packet portal here (it’s just under the project table) or via one of the available CLIs.
If you want to use a new SSH keypair in this tutorial, you can generate it to ./id_rsa
and ./id_rsa.pub
as:
$ ssh-keygen -t rsa -f ./id_rsa
If you want to use an existing keypair, just copy the private and public key over to the playbook directory.
Device Creation
The following code block is a simple playbook that creates one Type 0 server (the ‘plan’ parameter). You have to supply ‘plan’ and ‘operating_system’. ‘location’ defaults to ‘ewr1’ (Parsippany, NJ). You can find all the possible values for the parameters via a CLI client.
# playbook_create.yml - name: create ubuntu device hosts: localhost tasks: - packet_sshkey: key_file: ./id_rsa.pub label: tutorial key - packet_device: project_id: <your_project_id> hostnames: myserver operating_system: ubuntu_16_04 plan: baremetal_0 facility: sjc1
After running ansible-playbook playbook_create.yml
, you should have a server provisioned on Packet. You can verify via a CLI or in the Packet portal.
If you get an error with the message “failed to set machine state present, error: Error 404: Not Found”, please verify your project UUID.
Updating Devices
The two parameters used to uniquely identify Packet devices are: “device_ids” and “hostnames”. Both parameters accept either a single string (later converted to a one-element list), or a list of strings.
The ‘device_ids’ and ‘hostnames’ parameters are mutually exclusive. The following values are all acceptable:
- device_ids: a27b7a83-fc93-435b-a128-47a5b04f2dcf
- hostnames: mydev1
- device_ids: [a27b7a83-fc93-435b-a128-47a5b04f2dcf, 4887130f-0ccd-49a0-99b0-323c1ceb527b]
- hostnames: [mydev1, mydev2]
In addition, hostnames can contain a special ‘%d’ formatter along with a ‘count’ parameter that lets you easily expand hostnames that follow a simple name and number pattern; i.e. hostnames: "mydev%d", count: 2
will expand to [mydev1, mydev2].
If your playbook acts on existing Packet devices, you can only pass the ‘hostname’ and ‘device_ids’ parameters. The following playbook shows how you can reboot a specific Packet device by setting the ‘hostname’ parameter:
# playbook_reboot.yml - name: reboot myserver hosts: localhost tasks: - packet_device: project_id: <your_project_id> hostnames: myserver state: rebooted
You can also identify specific Packet devices with the ‘device_ids’ parameter. The device’s UUID can be found in the Packet Portal or by using a CLI. The following playbook removes a Packet device using the ‘device_ids’ field:
# playbook_remove.yml - name: remove a device hosts: localhost tasks: - packet_device: project_id: <your_project_id> device_ids: <myserver_device_id> state: absent
More Complex Playbooks
In this example, we’ll create a CoreOS cluster with user data.
The CoreOS cluster will use etcd for discovery of other servers in the cluster. Before provisioning your servers, you’ll need to generate a discovery token for your cluster:
$ curl -w "\n" 'https://discovery.etcd.io/new?size=3'
The following playbook will create an SSH key, 3 Packet servers, and then wait until SSH is ready (or until 5 minutes passed). Make sure to substitute the discovery token URL in ‘user_data’, and the ‘project_id’ before running ansible-playbook
. Also, feel free to change ‘plan’ and ‘facility’.
# playbook_coreos.yml - name: Start 3 CoreOS nodes in Packet and wait until SSH is ready hosts: localhost tasks: - packet_sshkey: key_file: ./id_rsa.pub label: new - packet_device: hostnames: [coreos-one, coreos-two, coreos-three] operating_system: coreos_beta plan: baremetal_0 facility: ewr1 project_id: <your_project_id> wait_for_public_IPv: 4 user_data: | #cloud-config coreos: etcd2: discovery: https://discovery.etcd.io/<token> advertise-client-urls: http://$private_ipv4:2379,http://$private_ipv4:4001 initial-advertise-peer-urls: http://$private_ipv4:2380 listen-client-urls: http://0.0.0.0:2379,http://0.0.0.0:4001 listen-peer-urls: http://$private_ipv4:2380 fleet: public-ip: $private_ipv4 units: - name: etcd2.service command: start - name: fleet.service command: start register: newhosts - name: wait for ssh wait_for: delay: 1 host: "{{ item.public_ipv4 }}" port: 22 state: started timeout: 500 loop: "{{ newhosts.results[0].devices }}"
As with most Ansible modules, the default states of the Packet modules are idempotent, meaning the resources in your project will remain the same after re-runs of a playbook. Thus, we can keep the packet_sshkey
module call in our playbook. If the public key is already in your Packet account, the call will have no effect.
The second module call provisions 3 Packet Type 0 (specified using the ‘plan’ parameter) servers in the project identified via the ‘project_id’ parameter. The servers are all provisioned with CoresOS beta (the ‘operating_system’ parameter) and are customized with cloud-config user data passed to the ‘user_data’ parameter.
The packet_device
module has a wait_for_public_IPv
that is used to specify the version of the IP address to wait for (valid values are 4
or 6
for IPv4 or IPv6). If specified, Ansible will wait until the GET API call for a device contains an Internet-routeable IP address of the specified version. When referring to an IP address of a created device in subsequent module calls, it’s wise to use the wait_for_public_IPv
parameter, or state: active
in the packet_device module call.
Run the playbook:
$ ansible-playbook playbook_coreos.yml
Once the playbook quits, your new devices should be reachable via SSH. Try to connect to one and check if etcd has started properly:
tomk@work $ ssh -i id_rsa core@$one_of_the_servers_ip core@coreos-one ~ $ etcdctl cluster-health
Once you create a couple of devices, you might appreciate the dynamic inventory script…
Dynamic Inventory Script
The dynamic inventory script queries the Packet API for a list of hosts, and exposes it to Ansible so you can easily identify and act on Packet devices. You can find it in Ansible’s git repo at contrib/inventory/packet_net.py.
The inventory script is configurable via a ini file.
If you want to use the inventory script, you must first export your Packet API token to a PACKET_API_TOKEN environment variable.
You can either copy the inventory and ini config out from the cloned git repo, or you can download it to your working directory like so:
$ wget https://github.com/ansible/ansible/raw/devel/contrib/inventory/packet_net.py $ chmod +x packet_net.py $ wget https://github.com/ansible/ansible/raw/devel/contrib/inventory/packet_net.ini
In order to understand what the inventory script gives to Ansible you can run:
$ ./packet_net.py --list
It should print a JSON document looking similar to following trimmed dictionary:
{ "_meta": { "hostvars": { "147.75.64.169": { "packet_billing_cycle": "hourly", "packet_created_at": "2017-02-09T17:11:26Z", "packet_facility": "ewr1", "packet_hostname": "coreos-two", "packet_href": "/devices/d0ab8972-54a8-4bff-832b-28549d1bec96", "packet_id": "d0ab8972-54a8-4bff-832b-28549d1bec96", "packet_locked": false, "packet_operating_system": "coreos_beta", "packet_plan": "baremetal_0", "packet_state": "active", "packet_updated_at": "2017-02-09T17:16:35Z", "packet_user": "core", "packet_userdata": "#cloud-config\ncoreos:\n etcd2:\n discovery: https://discovery.etcd.io/e0c8a4a9b8fe61acd51ec599e2a4f68e\n advertise-client-urls: http://$private_ipv4:2379,http://$private_ipv4:4001\n initial-advertise-peer-urls: http://$private_ipv4:2380\n listen-client-urls: http://0.0.0.0:2379,http://0.0.0.0:4001\n listen-peer-urls: http://$private_ipv4:2380\n fleet:\n public-ip: $private_ipv4\n units:\n - name: etcd2.service\n command: start\n - name: fleet.service\n command: start" } } }, "baremetal_0": [ "147.75.202.255", "147.75.202.251", "147.75.202.249", "147.75.64.129", "147.75.192.51", "147.75.64.169" ], "coreos_beta": [ "147.75.202.255", "147.75.202.251", "147.75.202.249", "147.75.64.129", "147.75.192.51", "147.75.64.169" ], "ewr1": [ "147.75.64.129", "147.75.192.51", "147.75.64.169" ], "sjc1": [ "147.75.202.255", "147.75.202.251", "147.75.202.249" ], "coreos-two": [ "147.75.64.169" ], "d0ab8972-54a8-4bff-832b-28549d1bec96": [ "147.75.64.169" ] }
In the ['_meta']['hostvars']
key, there is a list of devices (uniquely identified by their public IPv4 address) with their parameters. The other keys under ['_meta']
are lists of devices grouped by some parameter. Here, it is type (all devices are of type baremetal_0), operating system, and facility (ewr1 and sjc1).
In addition to the parameter groups, there are also one-item groups with the UUID or hostname of the device.
You can now target groups in playbooks! The following playbook will install a role that supplies resources for an Ansible target into all devices in the “coreos_beta” group:
# playbook_bootstrap.yml - hosts: coreos_beta gather_facts: false roles: - defunctzombie.coreos-boostrap
Don’t forget to supply the dynamic inventory in the -i
argument!
$ ansible-playbook -u core -i packet_net.py playbook_bootstrap.yml
If you have any questions or comments let us know! help@packet.net
© 2012–2018 Michael DeHaan
© 2018–2019 Red Hat, Inc.
Licensed under the GNU General Public License version 3.
https://docs.ansible.com/ansible/2.8/scenario_guides/guide_packet.html