Continuous Delivery is the concept of frequently delivering updates to your software application.
The idea is that by updating more often, you do not have to wait for a specific timed period, and your organization gets better at the process of responding to change.
Some Ansible users are deploying updates to their end users on an hourly or even more frequent basis – sometimes every time there is an approved code change. To achieve this, you need tools to be able to quickly apply those updates in a zero-downtime way.
This document describes in detail how to achieve this goal, using one of Ansible’s most complete example playbooks as a template: lamp_haproxy. This example uses a lot of Ansible features: roles, templates, and group variables, and it also comes with an orchestration playbook that can do zero-downtime rolling upgrades of the web application stack.
The playbooks deploy Apache, PHP, MySQL, Nagios, and HAProxy to a CentOS-based set of servers.
We’re not going to cover how to run these playbooks here. Read the included README in the github project along with the example for that information. Instead, we’re going to take a close look at every part of the playbook and describe what it does.
Let’s start with site.yml
. This is our site-wide deployment playbook. It can be used to initially deploy the site, as well as push updates to all of the servers:
--- # This playbook deploys the whole application stack in this site. # Apply common configuration to all hosts - hosts: all roles: - common # Configure and deploy database servers. - hosts: dbservers roles: - db # Configure and deploy the web servers. Note that we include two roles # here, the 'base-apache' role which simply sets up Apache, and 'web' # which includes our example web application. - hosts: webservers roles: - base-apache - web # Configure and deploy the load balancer(s). - hosts: lbservers roles: - haproxy # Configure and deploy the Nagios monitoring node(s). - hosts: monitoring roles: - base-apache - nagios
Note
If you’re not familiar with terms like playbooks and plays, you should review Playbooks.
In this playbook we have 5 plays. The first one targets all
hosts and applies the common
role to all of the hosts. This is for site-wide things like yum repository configuration, firewall configuration, and anything else that needs to apply to all of the servers.
The next four plays run against specific host groups and apply specific roles to those servers. Along with the roles for Nagios monitoring, the database, and the web application, we’ve implemented a base-apache
role that installs and configures a basic Apache setup. This is used by both the sample web application and the Nagios hosts.
By now you should have a bit of understanding about roles and how they work in Ansible. Roles are a way to organize content: tasks, handlers, templates, and files, into reusable components.
This example has six roles: common
, base-apache
, db
, haproxy
, nagios
, and web
. How you organize your roles is up to you and your application, but most sites will have one or more common roles that are applied to all systems, and then a series of application-specific roles that install and configure particular parts of the site.
Roles can have variables and dependencies, and you can pass in parameters to roles to modify their behavior. You can read more about roles in the Roles section.
Group variables are variables that are applied to groups of servers. They can be used in templates and in playbooks to customize behavior and to provide easily-changed settings and parameters. They are stored in a directory called group_vars
in the same location as your inventory. Here is lamp_haproxy’s group_vars/all
file. As you might expect, these variables are applied to all of the machines in your inventory:
--- httpd_port: 80 ntpserver: 192.0.2.23
This is a YAML file, and you can create lists and dictionaries for more complex variable structures. In this case, we are just setting two variables, one for the port for the web server, and one for the NTP server that our machines should use for time synchronization.
Here’s another group variables file. This is group_vars/dbservers
which applies to the hosts in the dbservers
group:
--- mysqlservice: mysqld mysql_port: 3306 dbuser: root dbname: foodb upassword: usersecret
If you look in the example, there are group variables for the webservers
group and the lbservers
group, similarly.
These variables are used in a variety of places. You can use them in playbooks, like this, in roles/db/tasks/main.yml
:
- name: Create Application Database mysql_db: name={{ dbname }} state=present - name: Create Application DB User mysql_user: name={{ dbuser }} password={{ upassword }} priv=*.*:ALL host='%' state=present
You can also use these variables in templates, like this, in roles/common/templates/ntp.conf.j2
:
driftfile /var/lib/ntp/drift restrict 127.0.0.1 restrict -6 ::1 server {{ ntpserver }} includefile /etc/ntp/crypto/pw keys /etc/ntp/keys
You can see that the variable substitution syntax of {{ and }} is the same for both templates and variables. The syntax inside the curly braces is Jinja2, and you can do all sorts of operations and apply different filters to the data inside. In templates, you can also use for loops and if statements to handle more complex situations, like this, in roles/common/templates/iptables.j2
:
{% if inventory_hostname in groups['dbservers'] %} -A INPUT -p tcp --dport 3306 -j ACCEPT {% endif %}
This is testing to see if the inventory name of the machine we’re currently operating on (inventory_hostname
) exists in the inventory group dbservers
. If so, that machine will get an iptables ACCEPT line for port 3306.
Here’s another example, from the same template:
{% for host in groups['monitoring'] %} -A INPUT -p tcp -s {{ hostvars[host].ansible_default_ipv4.address }} --dport 5666 -j ACCEPT {% endfor %}
This loops over all of the hosts in the group called monitoring
, and adds an ACCEPT line for each monitoring hosts’ default IPV4 address to the current machine’s iptables configuration, so that Nagios can monitor those hosts.
You can learn a lot more about Jinja2 and its capabilities here, and you can read more about Ansible variables in general in the Variables section.
Now you have a fully-deployed site with web servers, a load balancer, and monitoring. How do you update it? This is where Ansible’s orchestration features come into play. While some applications use the term ‘orchestration’ to mean basic ordering or command-blasting, Ansible refers to orchestration as ‘conducting machines like an orchestra’, and has a pretty sophisticated engine for it.
Ansible has the capability to do operations on multi-tier applications in a coordinated way, making it easy to orchestrate a sophisticated zero-downtime rolling upgrade of our web application. This is implemented in a separate playbook, called rolling_update.yml
.
Looking at the playbook, you can see it is made up of two plays. The first play is very simple and looks like this:
- hosts: monitoring tasks: []
What’s going on here, and why are there no tasks? You might know that Ansible gathers “facts” from the servers before operating upon them. These facts are useful for all sorts of things: networking information, OS/distribution versions, etc. In our case, we need to know something about all of the monitoring servers in our environment before we perform the update, so this simple play forces a fact-gathering step on our monitoring servers. You will see this pattern sometimes, and it’s a useful trick to know.
The next part is the update play. The first part looks like this:
- hosts: webservers user: root serial: 1
This is just a normal play definition, operating on the webservers
group. The serial
keyword tells Ansible how many servers to operate on at once. If it’s not specified, Ansible will parallelize these operations up to the default “forks” limit specified in the configuration file. But for a zero-downtime rolling upgrade, you may not want to operate on that many hosts at once. If you had just a handful of webservers, you may want to set serial
to 1, for one host at a time. If you have 100, maybe you could set serial
to 10, for ten at a time.
Here is the next part of the update play:
pre_tasks: - name: disable nagios alerts for this host webserver service nagios: action=disable_alerts host={{ inventory_hostname }} services=webserver delegate_to: "{{ item }}" with_items: "{{ groups.monitoring }}" - name: disable the server in haproxy shell: echo "disable server myapplb/{{ inventory_hostname }}" | socat stdio /var/lib/haproxy/stats delegate_to: "{{ item }}" with_items: "{{ groups.lbservers }}"
The pre_tasks
keyword just lets you list tasks to run before the roles are called. This will make more sense in a minute. If you look at the names of these tasks, you can see that we are disabling Nagios alerts and then removing the webserver that we are currently updating from the HAProxy load balancing pool.
The delegate_to
and with_items
arguments, used together, cause Ansible to loop over each monitoring server and load balancer, and perform that operation (delegate that operation) on the monitoring or load balancing server, “on behalf” of the webserver. In programming terms, the outer loop is the list of web servers, and the inner loop is the list of monitoring servers.
Note that the HAProxy step looks a little complicated. We’re using HAProxy in this example because it’s freely available, though if you have (for instance) an F5 or Netscaler in your infrastructure (or maybe you have an AWS Elastic IP setup?), you can use modules included in core Ansible to communicate with them instead. You might also wish to use other monitoring modules instead of nagios, but this just shows the main goal of the ‘pre tasks’ section – take the server out of monitoring, and take it out of rotation.
The next step simply re-applies the proper roles to the web servers. This will cause any configuration management declarations in web
and base-apache
roles to be applied to the web servers, including an update of the web application code itself. We don’t have to do it this way–we could instead just purely update the web application, but this is a good example of how roles can be used to reuse tasks:
roles: - common - base-apache - web
Finally, in the post_tasks
section, we reverse the changes to the Nagios configuration and put the web server back in the load balancing pool:
post_tasks: - name: Enable the server in haproxy shell: echo "enable server myapplb/{{ inventory_hostname }}" | socat stdio /var/lib/haproxy/stats delegate_to: "{{ item }}" with_items: "{{ groups.lbservers }}" - name: re-enable nagios alerts nagios: action=enable_alerts host={{ inventory_hostname }} services=webserver delegate_to: "{{ item }}" with_items: "{{ groups.monitoring }}"
Again, if you were using a Netscaler or F5 or Elastic Load Balancer, you would just substitute in the appropriate modules instead.
In this example, we use the simple HAProxy load balancer to front-end the web servers. It’s easy to configure and easy to manage. As we have mentioned, Ansible has built-in support for a variety of other load balancers like Citrix NetScaler, F5 BigIP, Amazon Elastic Load Balancers, and more. See the About Modules documentation for more information.
For other load balancers, you may need to send shell commands to them (like we do for HAProxy above), or call an API, if your load balancer exposes one. For the load balancers for which Ansible has modules, you may want to run them as a local_action
if they contact an API. You can read more about local actions in the Delegation, Rolling Updates, and Local Actions section. Should you develop anything interesting for some hardware where there is not a core module, it might make for a good module for core inclusion!
Now that you have an automated way to deploy updates to your application, how do you tie it all together? A lot of organizations use a continuous integration tool like Jenkins or Atlassian Bamboo to tie the development, test, release, and deploy steps together. You may also want to use a tool like Gerrit to add a code review step to commits to either the application code itself, or to your Ansible playbooks, or both.
Depending on your environment, you might be deploying continuously to a test environment, running an integration test battery against that environment, and then deploying automatically into production. Or you could keep it simple and just use the rolling-update for on-demand deployment into test or production specifically. This is all up to you.
For integration with Continuous Integration systems, you can easily trigger playbook runs using the ansible-playbook
command line tool, or, if you’re using Ansible Tower, the tower-cli
or the built-in REST API. (The tower-cli command ‘joblaunch’ will spawn a remote job over the REST API and is pretty slick).
This should give you a good idea of how to structure a multi-tier application with Ansible, and orchestrate operations upon that app, with the eventual goal of continuous delivery to your customers. You could extend the idea of the rolling upgrade to lots of different parts of the app; maybe add front-end web servers along with application servers, for instance, or replace the SQL database with something like MongoDB or Riak. Ansible gives you the capability to easily manage complicated environments and automate common operations.
See also
© 2012–2017 Michael DeHaan
© 2017 Red Hat, Inc.
Licensed under the GNU General Public License version 3.
https://docs.ansible.com/ansible/latest/guide_rolling_upgrade.html