Highly configurable Docker images running Alpine linux and s6 process management.
Table of contents
- Goals
- Docker and microservices
- Image design
- Consul and service discovery
- Examples
- Images
- Usage
- Customization
- Versioning
- FAQ
- Further reading
- Changelog
- Contributing
- Contributors
This project has the following goals:
- To produce small Docker images.
- To provide Docker images that are easily configurable.
- To provide Docker images that are highly stable.
- To quickly enable a microservices architecture using Docker.
To meet these goals, we're using:
- Alpine linux (very small but capable Linux distribution).
- s6 for process management for both easily configurable, and highly stable images.
Using Docker makes your infrastructure and environment consistent, testable, scalable and repeatable.
Microservices are isolated components (of a whole) doing one thing, and doing it well. These microservices are pulled together to provide a complete platform. For example, each of the following microservices would exist within one Docker container:
- A stateless web application running in Node.js.
- Session data for the Node.js web application provided by Redis.
- MongoDB as the database for the Node.js web application.
- Nginx web server proxying requests to Node.js.
That's called service discovery. We solve that problem using Consul (which is a distributed service discovery tool, with built-in health checks). Each container advertises their service (IP and port) via Consul.
Each container with a service, connects to a member of the Consul cluster. Consul then talks to all members to enable service discovery via HTTP and DNS.
A good example is a container with Nginx that will query Consul for the IP address of the Node.js container so that it can proxy an incoming request through to the Node.js application.
Setting up your infrastructure using microservices makes scalability a breeze.
There is an example showing Nginx load balancing incoming requests to multiple Node.js containers.
These images are used heavily in production by a number of different companies. They've been designed as great starting points to easily customize and use within your own platforms.
The following are common to all images within this repository.
Alpine Linux provides the foundation for all images in this repository. It's small, fast and perfect for Docker.
s6 is a unix service supervisor (much like runit and supervisord only better).
While it's true that Docker containers should have one clear focus, more often than not, you'll need to run multiple processes within the container.
Consul is a great example; you need the Consul agent to join a Consul cluster and the primary service such as Nginx or Node.js. Log management is also a key consideration in which another process might need to run.
s6-overlay is s6 Dockerized! It makes working with Docker and process management via s6 super easy. It also features some really nice extras such as container initialization and finalization stages (run custom scripts during these phases to setup services or tidy up from crashes).
go-dnsmasq has been added into the mix to add support for the DNS search
keyword which doesn't come standard in Alpine Linux.
These images work well with the embedded DNS service that comes with Docker 1.10+.
Configuration is a key step within a Docker-based microservices architecture. You must configure your services to interact with each other.
All Consul-based images come with consul-template
for easy configuration based on changes within Consul.
All non-Consul-based images come with confd
.
All Consul-related containers have been design for use in production and development.
These containers have been configured for zero-conf Consul bootstrapping. To achieve this, docker-engine
v1.10+ is required. along with a docker-compose.yml
file written in the version 2
format (see the example).
To achieve zero-conf Consul bootstrapping, Docker's new embedded DNS server is used within each container to find the IP of a consul container (note: there is a requirement that all Consul server services in docker-compose.yml
are called consul
for this to work).
Note:: this can work in older versions of Docker however (using service links with the name consul).
The Consul-based images in this repository have been designed to meet the following requirements:
Containers running Consul in server mode:
- When Consul dies: kill the container immediately.
- When Consul starts: remove all data associated with Consul so everything starts afresh.
Containers running Consul in agent mode:
- When Consul dies: immediately restart it using s6.
- When Consul starts: it will use the Consul data previously create to quickly rejoin a cluster.
- When the primary service dies: kill the container immediately.
We've found this to be the most consistent way to effectively run Consul in production. This also supports the development workflow in which you CTRL+C
to stop a container from running.
Most images have an example in the examples folder.
There is also a complete example which demonstrates:
- Zero-configuration Consul bootstrapping.
- Stateless application.
- Load balanced Nginx proxies.
- Scaled web application.
You can read more about the example.
The following describes the images that are available and the inheritance chain.
└─ alpine-base
├─ alpine-apache
├─ alpine-confd
| └─ alpine-rabbitmq
├─ alpine-nginx
| └─ alpine-nginx-nodejs
├─ alpine-nodejs
└─ alpine-redis
└─ alpine-base
└─ alpine-consul
├─ alpine-consul-ui
└─ alpine-consul-base
├─ alpine-consul-apache
├─ alpine-consul-nodejs
├─ alpine-consul-nginx
| └─ alpine-consul-nginx-nodejs
└─ alpine-consul-redis
This image is the base for all containers. All other Docker images within this repository inherit from this Container.
Latest version is 3.2.0
, or latest
.
This image includes Apache HTTPD with a very basic configuration.
Latest version is 2.0.1
, or latest
.
This image adds confd. It should be seen as a base image suitable for heavy customisation.
Latest version is 3.1.0
, or latest
.
This image adds Consul.
If you want to create a Docker image to run as a Consul agent in server mode (i.e. part of a cluster) start with this image.
Latest version is 3.2.0
, or latest
.
This image inherits from alpine-consul
and is designed as a base image for other Docker images which will join to a Consul cluster.
If you want to create a Docker image to advertise a service in Consul start with this image.
Latest version is 4.2.0
, or latest
.
This image is designed to run Apache within the context of service discovery (via Consul).
It is suited to running Apache as a proxy to another Docker container.
Latest version is 2.0.0
, or latest
.
This image is designed to run a Node.js application within the context of service discovery (via Consul).
Latest version is 5.11.0
, or latest
.
This image is designed to run Nginx within the context of service discovery (via Consul).
It's suited for running an Nginx proxy or to load balance with Nginx to another container.
Latest version is 3.2.0
, or latest
.
This image is designed to run both Nginx and Node.js on the same container. It's a shortcut to running alpine-consul-nodejs
via a proxy from alpine-consul-nodejs
.
Latest version is 2.0.0
, or latest
.
This image has been designed to run Redis within the context of service discovery (via Consul).
Latest version is 2.1.0
, or latest
.
This image has been designed to connect to a Consul cluster (from alpine-consul
) and make the Consul admin UI accessible.
Latest version is 2.2.0
, or latest
.
This image includes Nginx with a very basic setup.
Latest version is 3.0.0
, or latest
.
This image includes both Nginx and Node.js. It's suitable if you want to have Node.js perform configuration for Nginx.
Latest version is 4.4.0
, or latest
.
This includes Node.js.
Latest version is 6.8.4
, or latest
.
This image inherits from alpine-confd
, and includes RabbitMQ with a basic setup.
Latest version is 2.1.1
, or latest
.
This image includes Redis.
Latest version is 1.0.0
, or latest
.
All containers come with the following features (most of them come from s6-overlay):
- User hooks for container initialization, ownership and permissions management, and finalization tasks.
- Easily drop privileges before starting a service.
- Start and finish scripts for service management.
- Environment management.
As a general rule, these images eschew the CMD
option that Dockerfile provides. These images are oriented towards running multiple services.
However, alpine-base
is a minimalist image that can be used with CMD
. Your command can be provided in the Dockerfile or at runtime and it will be run under the s6 supervisor. When the command fails or exits, the container will also exit (falling back to Docker restart rules or other platform controls to manage container availability).
For example:
vagrant@ubuntu-14:/vagrant$ docker run -it smebberson/alpine-base with-contenv sh
[s6-init] making user provided files available at /var/run/s6/etc...exited 0.
[s6-init] ensuring user provided files have correct perms...exited 0.
[fix-attrs.d] applying ownership & permissions fixes...
[fix-attrs.d] done.
[cont-init.d] executing container initialization scripts...
[cont-init.d] 30-resolver: executing...
[cont-init.d] 30-resolver: exited 0.
[cont-init.d] 40-resolver: executing...
[cont-init.d] 40-resolver: exited 0.
[cont-init.d] done.
[services.d] starting services
[services.d] done.
/ # env
HOSTNAME=63d07768fdc5
SHLVL=1
HOME=/root
GO_DNSMASQ_LOG_FILE=/var/log/go-dnsmasq/go-dnsmasq.log
GODNSMASQ_VERSION=1.0.5
TERM=xterm
S6_OVERLAY_VERSION=v1.19.1.1
PATH=/usr/local/sbin:/usr/local/bin:/usr/sbin:/usr/bin:/sbin:/bin
PWD=/
/ # exit
with-contenv exited 0
[cont-finish.d] executing container finish scripts...
[cont-finish.d] done.
[s6-finish] syncing disks.
[s6-finish] sending all processes the TERM signal.
[s6-finish] sending all processes the KILL signal and exiting.
vagrant@ubuntu-14:/vagrant$
s6 provides us a clean and simple way to run services within these images. For example alpine-consul runs both go-dnsmasq and Consul via services, and alpine-consul-nginx adds Nginx, also via services.
To write a service script, create a directory with the name of your service in the /etc/services.d/
directory. In that directory create an executable script named run
. In your run script, start your service (be sure to make sure it doesn't background as s6 will attempt to start it again). For example:
# /etc/services.d/nginx/run
#!/usr/bin/with-contenv sh
nginx -g "daemon off;"
s6 will start your service and monitor it. Should your service exit or fail, s6 will execute your run script again to restart the service.
s6 also provides you a hook to run tasks in between a service exiting or failing, and it being restarted. Simple create an executable script named finish
next to your run
script.
This script should execute fast. It has about 3 seconds to do what it needs to before it will be killed by s6, and the run
script executed. You can also do any tasks as required in your run
before you start your long running process.
If you'd like to bring down a container if a particular service restarts, use this as the contents of a finish
script:
#!/usr/bin/execlineb -S1
# only tell s6 to bring down the entire container, if it isn't already doing so
# http://skarnet.org/software/s6/s6-supervise.html
if { s6-test ${1} -ne 0 }
if { s6-test ${1} -ne 256 }
s6-svscanctl -t /var/run/s6/services
The docker-alpine images are highly customizable. You can customize them with the following:
- Setting ENV variables to change settings.
- Overwrite a configuration file (not all images have these) to alter an application.
- Overwrite run scripts to change application start process.
They've also been designed so that it's easy to use these images in a non-standard context such as Docker Cloud and Rancher.
The following cover customization that is common to all images. Review the documentation for each image for image-specific customization options.
This file is used in other scripts to determine the IP of the container in which a script is running.
Overwrite it as required to produce a correct value for your environment. Review the file itself for output requirements.
If your environment uses an overlay network (Docker Cloud, Rancher), you should change this file.
This file (Consul-only containers) is used within other scripts to determine the IP address(es) of other containers by name.
By default, it uses dig
to DNS query for the IP address of a container by name. container-find
will DNS query for consul
(the default). container-find static
will DNS query for static
. container-find static.service.consul
will hand-off the DNS query to Consul.
Each image has it's own version and will be updated independently. All versions follow semver. If a software package or the operating system the image uses is updated, the level of update will be reflected in the new version number, for example:
- if Alpine Linux is upgraded from 3.2 to 3.3, then the image version will receive a minor increment
- if Alpine Linux is upgraded from 3.3 to 4, then the image version will receive a major increment
- if s6-overlay is upgraded to the latest patch upgrade, and nginx is upgraded to the latest minor upgrade, then the image version will will receive a minor increment
These images are a little different from your standard Docker images. The following should explain most of the differences.
By default, Alpine Linux <= v3.4 doesn't support DNS search
. This has been enabled through the use of go-dnsmasq
.
These images don't contain Bash by default. They're defaulted to use sh
.
You can either write your scripts such that they're posix compliant or install Bash with apk add --no-cache bash
.
By default, sh
has no environment. If you need access to environment variables in scripts or when using docker exec
you should use:
#!/usr/bin/with-contenv sh
docker exec -it complete_consul_1 with-contenv
There are two ways to set environment variables. In your Dockerfile
like any other containers or from within a custom script using set-contenv
for example set-contenv VAR_NAME var_value
.
If you'd like to read more about operating environment of these images, start here:
Read the CHANGELOG.md for a chronological record of events. Each image also has it's own CHANGELOG.
We love contributors. Read CONTRIBUTING.md for more information on how to contribute to this project.
You can view more information about the contributors here.