A deployment tool for Docker. Takes containers from a Docker registry and runs them on a fleet of hosts with the correct environment variables, host volume mappings, and port mappings. Supports rolling deployments out of the box, and makes it easy to ship applications to Docker servers.
We're using it to run our production infrastructure.
Centurion works in a two part deployment process where the build process ships a container to the registry, and Centurion ships containers from the registry to the Docker fleet. Registry support is handled by the Docker command line tools directly so you can use anything they currently support via the normal registry mechanism.
If you haven't been using a registry, you should read up on how to do that before trying to deploy anything with Centurion.
Commercial Docker Registry Providers:
- Docker, Inc. provides repositories, and hosts the main public Docker repository.
- Quay.io from the CoreOS team
Open-source:
- The Docker Distribution project, built and maintained by Docker. You host this yourself.
This project is under active development! The initial release on GitHub contains one roll-up commit of all our internal code. But all internal development will now be on public GitHub. See the CONTRIBUTORS file for the contributors to the original internal project.
Centurion is a Ruby gem. It assumes that you have a working, modern-ish Ruby
(1.9.3 or higher). On Ubuntu 12.04 you can install this with the ruby-1.9.1
system package, for example. On OSX this is best accomplished via rbenv
and
ruby-build
which can be installed with Homebrew or from
GitHub.
Once you have a running, modern Ruby, you simply:
$ gem install centurion
With rbenv you will now need to do an rbenv rehash
and the commands should
be available. With a non-rbenv install, assuming the gem dir is in your path,
the commands should just work now.
Centurion expects to find configuration tasks in the current working directory tree.
We recommend putting all your configuration for multiple applications into a single repo rather than spreading it around by project. This allows a central choke point on configuration changes between applications and tends to work well with the hand-off in many organizations between the build and deploy steps. If you only have one application, or don't need this you can decentralize the config into each repo.
It will look for configuration files in either ./config/centurion
or .
.
The pattern at New Relic is to have a configs repo with a Gemfile
that
sources the Centurion gem. If you want Centurion to set up the structure for
you and to create a sample config, you can simply run centurionize
once you
have the Ruby Gem installed.
Centurion ships with a simple scaffolding tool that will setup a new config repo for you, as well as scaffold individual project configs. Here's how you run it:
$ centurionize -p <your_project>
centurionize
relies on Bundler being installed already. Running the command
will have the following effects:
- Ensure that a
config/centurion
directory exists - Scaffold an example config for your project (you can specify the registry)
- Ensure that a Gemfile is present
- Ensure that Centurion is in the Gemfile (if absent it just appends it)
Any time you add a new project you can scaffold it in the same manner even in the same repo.
If you used centurionize
you will have a base config scaffolded for you.
But you'll still need to specify all of your configuration.
Configs are in the form of a Rake task that uses a built-in DSL to make them
easy to write. Here's a sample config for a project called "radio-radio" that
would go into config/centurion/radio-radio.rake
:
namespace :environment do
task :common do
set :image, 'example.com/newrelic/radio-radio'
host 'docker-server-1.example.com'
host 'docker-server-2.example.com'
end
desc 'Staging environment'
task :staging => :common do
set_current_environment(:staging)
env_vars YOUR_ENV: 'staging'
env_vars MY_DB: 'radio-db.example.com'
host_port 10234, container_port: 9292
host_port 10235, container_port: 9293
host_volume '/mnt/volume1', container_volume: '/mnt/volume2'
end
desc 'Production environment'
task :production => :common do
set_current_environment(:production)
env_vars YOUR_ENV: 'production'
env_vars MY_DB: 'radio-db-prod.example.com'
host_port 22234, container_port: 9292
host_port 23235, container_port: 9293
command ['/bin/bash', '-c', '/path/to/server -e production']
end
end
This sets up a staging and production environment and defines a common
task
that will be run in either case. Note the dependency call in the task
definition for the production
and staging
tasks. Additionally, it defines
some host ports to map, sets which servers to deploy to, and sets a custom
command. Some configuration will be provided to the containers at startup time,
in the form of environment variables.
Most of the DSL items (host_port
, host_volume
, env_vars
, host
) can be
specified more than once and will append to the configuration. However, there
can only be one command
; the last one will take priority.
You can cause your container to be started with a specific DNS server
IP address (the equivalent of docker run --dns 172.17.42.1 ...
) like this:
task :production => :common do
set :dns, [ '172.17.42.1' ]
# ...
end
This is the name that shows up in the docker ps
output. It's the name
of the container, not the hostname inside the container. By default
the container will be named using the name of the project as the base
of the name.
If you want to name your container something other than the project name,
use the name
setting. The actual name for the created container will
have a random hex string appended, to avoid name conflicts when you repeatedly
deploy a project:
task :common do
set :name, 'backend'
# ...
end
With this, the container will be named something like backend-4f692997
.
You may add arbitrary labels to your containers by calling labels
with a hash.
The call is cumulative, so you may express patterns like:
namespace :environment do
task :common do
set :image, 'example.com/newrelic/radio-radio'
host 'docker-server-1.example.com'
labels team: 'radio-ops'
end
desc 'Staging environment'
task :staging => :common do
labels environment: 'radio-staging'
env_vars YOUR_ENV: 'staging'
end
end
This would result in the container having two labels, as shown in a
docker inspect
example:
"Labels": {
"team": "radio-ops",
"environment": "radio-staging"
}
Hash keys and values will be stringified, so you may pass any object with a
#to_s
method.
If you don't specify a hostname to use inside your container, the container will be given a hostname matching the container ID. This probably is good for a lot of situations, but it might not be good for yours. If you need to have a specific hostname, you can ask Centurion to do that:
set :container_hostname, 'yourhostname'
That will make all of your containers named 'yourhostname'. If you want to do
something more dynamic, you can pass a Proc
or a lambda like this:
set :container_hostname, ->(hostname) { "#{hostname}.example.com" }
The lambda will be passed the current server's hostname. So, this example will cause ".example.com" to be appended to the hostname of each Docker host during deployment.
If you want to restore the old behavior from Centurion 1.6.0 and earlier, you can do the following:
set :container_hostname, ->(hostname) { hostname }
That will cause the container hostname to match the server's hostname.
You may specify the network mode you would like a container to use via:
set :network_mode, 'networkmode'
Docker (and therefore Centurion) supports one of bridge
(the default), host
,
and container:<container-id>
for this argument.
In host
and container...
network modes, you may specify a
host_port, container_port
mapping, however the port numbers will only be used
for container health checks. The mapping itself, while still passed via the API,
will be ignored by Docker.
Limits on memory and CPU can be specified with the memory
and cpu_shares
settings. Both of these expect a 64-bit integer describing the number of
bytes, and the number of CPU shares, respectively.
For example, to limit the memory to 1G, and the cpu time slice to half the normal length, include the following:
memory 1.gigabyte
cpu_shares 512
For more information on Docker's CGroup limits see the Docker docs.
Additional kernel capabilities may be granted to containers, permitting them device access they do not normally have. You may specify these as follows:
add_capability 'SOME_CAPABILITY'
add_capability 'ANOTHER_CAPABILITY'
drop_capability 'SOMEOTHER_CAPABILITY'
You may also ask for all but a few capabilities as follows:
add_capability 'ALL'
drop_capability 'SOME_CAPABILITY'
For more information on which kernel capabilities may be specified, see the Docker docs.
Some Docker platforms support container security overlays called seccomp
.
During container creation, you may specify security options to control the
seccomp permissions.
To set a seccomp path:
add_security_opt 'seccomp=/path/to/seccomp/profile.json'
Or, to unblock all syscalls in a container:
add_security_opt 'seccomp=unconfined'
For more information on this argument, see the Docker docs.
Currently there a couple of special strings for interpolation that can be added
to any env_var
value in the DSL. %DOCKER_HOSTNAME%
will be replaced with
the current server's hostname in the environment variable at deployment time.
Also %DOCKER_HOST_IP%
will be replaced with the public IP address of the
Docker server using a getaddrinfo
call on the client.
Centurion can use your existing Docker TLS certificates when using Docker with TLS support. In doing so you have 2 choices.
You just need to enable the tls mode as the following:
task :production => :common do
set :tlsverify, true
# ...
end
Centurion will only set the --tlsverify
to true and Docker will read your
certificate from the ~/.docker/
path.
Given your files are in /usr/local/certs/
You have to set the following keys:
task :production => :common do
set :tlsverify, true
set :tlscacert, '/usr/local/certs/ca.pem'
set :tlscert, '/usr/local/certs/ssl.crt'
set :tlskey, '/usr/local/certs/ssl.key'
# ...
end
Modify the paths as appropriate for your cert, ca, and key files.
Centurion supports a number of tasks out of the box that make working with distributed containers easy. Here are some examples:
A rolling deployment will stop and start each container one at a time to make
sure that the application stays available from the viewpoint of the load
balancer. As the deploy runs, a health check will hit each container to ensure
that the application booted correctly. By default, this will be a GET request to
the root path of the application. The healthcheck endpoint is configurable by adding
set(:status_endpoint, '/somewhere/else')
in your config. The status endpoint
must respond with a valid response in the 200 status range.
$ bundle exec centurion -p radio-radio -e staging -a rolling_deploy
Custom Health Check:
You can use a custom health check by specifying a callable object (anything that
responds to :call), e.g. a Proc, lambda, or method. This method will be invoked with
the host url, the port that needs to be checked, and the specified endpoint(via
set(:status_endpoint, '/somewhere/else')
). If the port is ready, health check
should return a truthy value, falsey otherwise. Here's an example of a custom
health check that verifies that an elasticsearch node is up and has joined the
cluster.
def cluster_green?(target_server, port, endpoint)
response = begin
Excon.get("http://#{target_server.hostname}:#{port}#{endpoint}")
rescue Excon::Errors::SocketError
warn "Elasticsearch node not yet up"
nil
end
return false unless response
!JSON.parse(response)['timed_out']
end
task :production => :common do
set_current_environment(:production)
set :status_endpoint, "/_cluster/health?wait_for_status=green&wait_for_nodes=2"
health_check method(:cluster_green?)
host_port 9200, container_port: 9200
host 'es-01.example.com'
host 'es-02.example.com'
end
Rolling Deployment Settings:
You can change the following settings in your config to tune how the rolling
deployment behaves. Each of these is controlled with set(:var_name, 'value')
.
These can be different for each environment or put into a common block if they
are the same everywhere. Settings are per-project.
rolling_deploy_check_interval
=> Controls how long Centurion will wait after seeing a container as up before moving on to the next one. This should be slightly longer than your load balancer check interval. Value in seconds. Defaults to 5 seconds.rolling_deploy_wait_time
=> The amount of time to wait between unsuccessful health checks before retrying. Value in seconds. Defaults to 5 seconds.rolling_deploy_retries
=> The number of times to retry a health check on the container once it is running. This count multiplied by therolling_deployment_wait_time
is the total time Centurion will wait for an individual container to come up before giving up as a failure. Defaults to 24 attempts.rolling_deploy_skip_ports
=> Either a single port, or an array of ports that should be skipped for status checks. By default status checking assumes an HTTP server is on the other end and if you are deploying a container where some ports are not HTTP services, this allows you to only health check the ports that are. The default is an empty array. If you have non-HTTP services that you want to check, see Custom Health Checks in the previous section.
This will hard stop, then start containers on all the specified hosts. This is not recommended for apps where one endpoint needs to be available at all times. It is fast.
$ bundle exec centurion -p radio-radio -e staging -a deploy
This will give you a command line shell with all of your existing environment
passed to the container. The CMD
from the Dockerfile
will be replaced
with /bin/bash
. It will use the first host from the host list.
$ bundle exec centurion -p radio-radio -e staging -a deploy_console
This will preform a health check on each host using rolling deployment health check settings and redeploy to the host if a health check fails.
$ bundle exec centurion -p radio-radio -e staging -a repair
Returns a nicely-formatted list of all the current tags and which machines they are running on. Gives a unique list of tags across all hosts as well. This is useful for validating the state of the deployment in the case where something goes wrong mid-deploy.
$ bundle exec centurion -p radio-radio -e staging -a list:running_container_tags
Returns a (as yet not very nicely formatted) list of all the containers for this project on each of the servers from the config.
$ bundle exec centurion -p radio-radio -e staging -a list:running_containers
Returns a list of all the images for this project in the registry.
$ bundle exec centurion -p radio-radio -e staging -a list
Centurion needs to have access to some registry in order to pull images to remote Docker servers. This needs to be either a hosted registry (public or private), or Dogestry.
If you are not using either Dogestry, or the public registry, you may need to provide authentication credentials. Centurion needs to access the Docker registry hosting your images directly to retrive image ids and tags. This is supported in both the config file and also as command line arguments.
The command line arguments are:
--registry-user
=> The username to pass to the registry--registry-password
=> The password
These correspond to the following settings:
registry_user
registry_password
Centurion normally uses the built-in registry support in the Docker daemon to handle pushing and pulling images. But Centurion also has the ability to use external tooling to support hosting your registry on Amazon S3. That tooling is from a project called Dogestry. We have recently improved that tooling substantially in coordination with the Centurion support.
Dogestry uses the Docker daemon's import/export functionality in combination with Amazon S3 to provide reliable hosting of images. Setting Centurion up to use Dogestry is pretty trivial:
- Create an S3 bucket and download the credentials to let you access the bucket. Generally these are IAM user keys.
- Install Dogestry binaries on the client from which Dogestry is run. Binaries are provided in the GitHub release.
- Add the settings necessary to get Centurion to pull from Dogestry. A config example is provided below:
namespace :environment do
task :common do
registry :dogestry # Required
set :aws_access_key_id, 'abc123' # Required
set :aws_secret_key, 'xyz' # Required
set :s3_bucket, 'docker-images-bucket' # Required
set :s3_region, 'us-east-1' # Optional
end
end
TLS with Dogestry: Because this involves a little passing around of both
settings and environment variables, there are a couple of things to verify to
make sure everything is passed properly between Centurion and Dogestry. If your
keys have the default names and are in located in the path represented by
DOCKER_CERT_PATH
in your environment, this should just work. Otherwise you'll
need to be sure to set :tlsverify, true
and also set the TLS cert names as
decribed above.
Centurion supports a few features to make development easier when building your deployment tooling or debugging your containers.
Sometimes when you're doing development you want to try out some configuration
settings in environment variables that aren't in the config yet. Or perhaps you
want to override existing settings to test with. You can provide the
--override-env
command line flag with some overrides or new variables to set.
Here's how to use it:
$ centurion -e development -a deploy -p radio-radio --override-env=SERVICE_PORT=8080,NAME=radio
Centurion is aimed at repeatable deployments so we don't recommend that you use this functionality for production deployments. It will work, but it means that the config is not the whole source of truth for your container configuration. Caveat emptor.
Sometimes you need to test how your code works inside the container and you
need to have all of your configuration exported. Centurion includes an action
that will let you do that. It exports all of your environment settings for the
environment you specify. It then partially sanitizes them to preserve things
like rbenv
settings. Then it executes /bin/bash
locally.
The action is named dev:export_only
and you call it like this:
$ bundle exec centurion -e development -p testing_project -a dev:export_only
$ bundle exec rake spec
It's important to note that the second line is actually being invoked with new environment exported.
We're currently looking at the following feature additions:
- etcd integration for configs and discovery
- Add the ability to show all the available tasks on the command line
Contributions are more than welcome. Bug reports with specific reproduction steps are great. If you have a code contribution you'd like to make, open a pull request with suggested code.
Note that PR's and issues are reviewed every ~2 weeks. If your PR or issue is critical in nature, please reflect that in the description so that it receives faster attention.
Pull requests should:
- Clearly state their intent in the title
- Have a description that explains the need for the changes
- Include tests!
- Not break the public API
- Add yourself to the CONTRIBUTORS file. I might forget.
If you are simply looking to contribute to the project, taking on one of the items in the "Future Additions" section above would be a great place to start. Ping us to let us know you're working on it by opening a GitHub Issue on the project.
By contributing to this project you agree that you are granting New Relic a non-exclusive, non-revokable, no-cost license to use the code, algorithms, patents, and ideas in that code in our products if we so choose. You also agree the code is provided as-is and you provide no warranties as to its fitness or correctness for any purpose
Copyright (c) 2014-2017 New Relic, Inc. All rights reserved.