Skip to content

Highly opinionated gradle plugin to start (Up), pause (Stop), and delete (Down) an arbitrary dockerized application.

License

Notifications You must be signed in to change notification settings

project-aries/gradle-docker-applications-plugin

Repository files navigation

gradle-docker-applications-plugin

Highly opinionated gradle plugin to start (Up), pause (Stop), and delete (Down) an arbitrary docker application.

Status

CI Codecov Docs Questions Release
Build Status codecov Docs Stack Overflow gradle-docker-applications-plugin

Motivation, Design Goals, and who is this plugin for?

As maintainer of the gradle-docker-plugin I often get questions about how best to use said plugin for standing up a given companies dockerized application in a gradle context. As the aforementioned plugin is compromised of many tasks, each acting as a low-level building block, it can be daunting for new users to understand how all of these tasks are wired together. That's where the gradle-docker-applications-plugin comes in. Being built on top of the gradle-docker-plugin it provides an easy and intuitive way to define and configure your applications and then creates exactly 3 high-level tasks for you to manage them (more on that below).

When designing this plugin I wanted to get the following right without any compromises:

  • Provide exactly 3 high-level tasks with which to manage a dockerized-application: Up, Stop, and Down.
  • Allow for defining up to N number of dockerized-application(s) for highly complex workloads.
  • Be able to work in a multi-project build with synchronization around all high-level tasks.
  • Fail ONLY when necessary (i.e. invoking Down on an application that does not exist does not fail).
  • Applications, by default, get their own private network.
  • Highly opinionated design for dockerized-application(s) based off of best practices.

Furthermore, this plugin solves the following problems for developers, devops, and site-reliability engineers:

  • No longer need to maintain site specific images for minor changes (i.e. new tomcat image with added war file).
  • Ability to stand-up a single dockerized-application(s) for integration testing which in turn can be shared and managed across multiple project(s).
  • Well defined DSL to easily script the defintion of your dockerized-application.
  • Removal of having to understand the inner workings of docker, or the gradle-docker-plugin, providing a fast way to get your dockerized-application defined and up and running with minimal effort.

Getting Started

buildscript() {
    repositories {
        jcenter()
    }
    dependencies {
        classpath group: 'com.aries', name: 'gradle-docker-applications-plugin', version: 'X.Y.Z'
    }
}

apply plugin: 'gradle-docker-applications-plugin'

Backend powered by gradle-docker-plugin

Because we use the gradle-docker-plugin to drive this one: you are free to use the docker extension point to configure your docker connection as is described in more detail HERE.

On the applications extension point and DSL

This plugin is built around the idea that users will define N number of dockerized-application(s) and we will hand back 3 appropriately named high-level tasks for you to manage said application. With this in mind we provide the applications extension point, which in turn is a gradle container, for you to define as many apps as you need:

applications {
    myPostgresStackOne {
    
    }
    myPostgresStackTwo {
    
    }
    myPostgresStackThree {
    
    }
}

Each app in turn is what we would call a dockerized-application and is just an instance of AbstractApplication. These applications contain various properties and methods you can set and override as you see fit.

Furthermore each application allows you to define a main and optionally a data container like so:

applications {
   myPostgresStack {
      main { // required
      
      }
      data { // optional and will inherit image properties from `main` if not defined
      
      }
   }
}

Each dockerized-application gets exactly 2 containers created: main and data. The main container is your runtime or the thing that's actually running the application. The data container is the place the main container will write its data (or state) too thereby having a clear separation between the running instance and the data it creates.

The main container is an instance of MainContainer with the data container being an instance of DataContainer and both inherit from AbstractContainer. In the end each are just mapped to docker containers with the caveat that the data container only ever gets created while the main container is not only created but is started and expected to stay running.

Requirements and Options

Both the main and data containers have a handful of closures/options for you to configure your dockerized application with. The only real requirement is a defined main container with at least the image repository set like so:

applications {
    myPostgresStack {
        id('hello-world-123') // Optional. Overrides the appName (e.g. myPostgresStack) when naming containers. Defaults to null.
        network('hello-world') // Optional. Sets custom network name. Defaults to appName if not set. Set to null to skip custom network.
        count(2) // Optional. Number of instances to start. Defaults to 1.
        dependsOn(Object...) // Optional. Sets these _dependsOn_ to the executing **Up** task.
        dependsOnParallel(Object...) // Optional. Runs these _dependsOnParallel_ asynchronously to the executing **Up** task.
        main {
            repository = 'postgres'
            tag = 'alpine' // optional and defaults to 'latest' if not set
        }
    }
}

So long as the image you're using starts an application, either through an entrypoint or command, and things stay in a running state, you're good to go.

The data container is also entirely optional and if not defined we will inherit the image options (e.g. repository and tag) from the main container but NOTHING else.

Options available for both main and data container(s)

create (Optional)

The create closure maps to DockerCreateContainer and can optionally be defined N number of times. This allows you to configure the creation of either container should the need arise:

applications {
    myPostgresStack {
        main {
            create {
                envVars = ['MAIN_CONTAINER' : 'true']
            }
            create {
                shmSize = 123456789
            }
        }
        data {
            create {
                withEnvVar('DATA_CONTAINER', 'true')
                withEnvVar('DEVOPS', 'ROCKS')
            }
        }
    }
}
files (Optional)

The files closure maps to DockerCopyFileToContainer and can optionally be defined N number of times. This allows you to add an arbitrary number of files to either container just after they've been created but just before they've been started:

// splitting things up into multiple files only to show that the user
// can add as many files as they want and can do so either outside
// of the _files_ closure as we're doing here or inside as is shown
// further below.
final File createDatabase = new File("$buildDir/CREATE_DATABASE.sql")
createDatabase.withWriter('UTF-8') {
    it.println('CREATE DATABASE docker;')
    createDatabase
}

final File grantPrivileges = new File("$buildDir/CREATE_DATABASE_USER_PRIVS.sql")
grantPrivileges.withWriter('UTF-8') {
    it.println('GRANT ALL PRIVILEGES ON DATABASE docker TO docker;')
    grantPrivileges
}

final File createCookie = new File("$buildDir/cookie.txt")
createCookie.withWriter('UTF-8') {
    it.println('Somebody Was Here')
    createCookie
}

applications {
    myPostgresStack {
        main {
            files {

                // demo adding files with string paths
                withFile("${createDatabase.path}", '/docker-entrypoint-initdb.d')

                // demo adding files with closures
                withFile({
                    final File createUser = new File("$buildDir/CREATE_DATABASE_USER.sql")
                    createUser.withWriter('UTF-8') {
                        it.println('CREATE USER docker;')
                        createUser
                    }
                }, { '/docker-entrypoint-initdb.d' })
            }
            files {

                // demo adding files with file objects
                withFile(project.file("${grantPrivileges.path}"), '/docker-entrypoint-initdb.d')
            }
        }
        data {
            files {
                withFile(project.file("$buildDir/cookie.txt"), '/') // demo with files
            }
        }
    }
}

Options available for the main container

liveness (Optional)

The liveness closure maps to DockerLivenessContainer and can optionally be defined N number of times. This allows you to configure the liveness probe, which runs just after the container is started, and probes (or polls) the running container for an arbitrary amount of time waiting for the passed in String to become present in the container logs:

applications {
    myPostgresStack {
        main {
            liveness {

                // wait at most for 300000 milliseconds, probing every 10000 milliseconds, for
                // the log String noted below to be present.
                livenessProbe(300000, 10000, 'database system is ready to accept connections')
            }
        }
    }
}
exec (Optional)

The exec closure maps to DockerExecContainer and can optionally be defined N number of times. This allows you to execute an arbitrary number of commands on the main container AFTER we have deemed it to be live or in a running state:

applications {
    myPostgresStack {
        main {
            exec {
                withCommand(['su', 'postgres', "-c", "/usr/local/bin/psql -c 'CREATE DATABASE devops'"])
                withCommand(['su', 'postgres', "-c", "/usr/local/bin/psql -c 'CREATE USER devops'"])
                successOnExitCodes = [0] // if not defined will ignore all exit codes
            }
            exec {
                withCommand(['su', 'postgres', "-c", "/usr/local/bin/psql -c 'GRANT ALL PRIVILEGES ON DATABASE devops TO devops'"])
                successOnExitCodes = [0]
            }
        }
    }
}
stop (Optional)

The stop closure maps to DockerExecStopContainer and can optionally be defined N number of times. This allows you to configure an optional exec command to be run within the main container to bring it down gracefully. If not defined we revert back to just issueing a "stop" on the main container:

applications {
    myPostgresStack {
        main {
            stop {
                withCommand(['su', 'postgres', "-c", "/usr/local/bin/pg_ctl stop -m fast"])
                successOnExitCodes = [0, 127, 137]
                execStopProbe(60000, 10000) // time we wait for command(s) to finish

                // if above not defined this is the amount of time we will wait for container
                // to stop after issuing a "stop" request.
                timeout = 60000
            }
        }
    }
}

Complete example

applications {
    myPostgresStack {
        main {
            repository = 'postgres'
            tag = 'alpine'
            create {
                envVars = ['MAIN_CONTAINER' : 'true']
            }
            files {

                // create a new database, user, and privs with SQL file inside the main/runtime
                // container which will be invoked on initial start of the container only.
                // this is a postgres specific thing and is shown here only to document how one
                // might add/create/script a file dynamically.
                withFile({
                    final File createUser = new File("$buildDir/CREATE_DATABASE_AND_USER_WITH_PRIVS.sql")
                    createUser.withWriter('UTF-8') {
                        it.println('CREATE DATABASE docker;')
                        it.println('CREATE USER docker;')
                        it.println('GRANT ALL PRIVILEGES ON DATABASE docker TO docker;')
                        createUser
                    }
                }, { '/docker-entrypoint-initdb.d' })
            }
            exec {

                // create a new database, user, and privs AFTER container has started but BEFORE
                // the **UP** task-chain has finished using commands inside the container.
                withCommand(['su', 'postgres', "-c", "/usr/local/bin/psql -c 'CREATE DATABASE devops'"])
                withCommand(['su', 'postgres', "-c", "/usr/local/bin/psql -c 'CREATE USER devops'"])
                withCommand(['su', 'postgres', "-c", "/usr/local/bin/psql -c 'GRANT ALL PRIVILEGES ON DATABASE devops TO devops'"])
                successOnExitCodes = [0]
            }
            liveness {
                livenessProbe(300000, 10000, 'database system is ready to accept connections')
            }
            stop {
                withCommand(['su', 'postgres', "-c", "/usr/local/bin/pg_ctl stop -m fast"])
                successOnExitCodes = [0, 127, 137]
                timeout = 60000
                execStopProbe(60000, 10000)
            }
        }
        data {
            create {
                envVars = ['DATA_CONTAINER' : 'true']
            }
        }
    }
}

On Up, Stop, and Down tasks

Once an application is defined we create these 3 high-level tasks for the end-user to work with in whatever way they see fit.

Up

Using the example from above: if your application is named myPostgresStack we will create a task appropriately named myPostgresStackUp to start your dockerized application. This task, after run the first time and the dockerized application started, can be run repeatedly but more/less amounts to a no-op. We recognize that the instance is already started and simply print out a banner saying things are live and allow you to continue with the rest of your automation.

The Up task is the main workhorse of this project and as such has a bit more responsibility in providing the user with the final state of the task-chain. If for example you started a dockerized tomcat application that you created you would see output similar to the following:

> Task :tomcatUp
=====================================================================
ID = d0a676a06b666ed28132ad1e8120f850ad4011fd472f189c3525c0fd87ee117f
NAME = myTomcatServer-tomcat
IMAGE = tomcat:8.5-alpine
COMMAND = run
CREATED = 2018-06-30T12:05:48.222160433Z
PORTS = 32789->8080
ADDRESS = 172.23.0.2
GATEWAY = 172.23.0.1
NETWORK = myTomcatServer
=====================================================================

Once the Up task has completed this banner is displayed giving you some basic information about the running dockerized application(s). Each of these properties, as well as an InspectContainerResponse object of the running container, are available to you as gradle extension properties on the Up task itself but are ONLY set once the task has completed. An example of how you might access these could look like:

task myDownstreamTask(dependsOn: tomcatUp) {
    doLast {
        println tomcatUp.reports().get(0).id // String
        println tomcatUp.reports().get(0).name // String
        println tomcatUp.reports().get(0).image // String
        println tomcatUp.reports().get(0).command // List<String>
        println tomcatUp.reports().get(0).created // String
        println tomcatUp.reports().get(0).ports // Map<String, String>
        println tomcatUp.reports().get(0).address // String
        println tomcatUp.reports().get(0).gateway // String
        println tomcatUp.reports().get(0).network // String

        // the actual inspection object itself which contains all of the
        // above as well as every other property/object attached to an
        // inspection you can think of.
        println tomcatUp.reports().get(0).inspection
    }
}

Because each application can start multiple instances of itself it is necessary to use the above noted syntax in order to get the details surrounding the specific instance you're interested in.

Stop

Using the example from above: if your application is named myPostgresStack we will create a task appropriately named myPostgresStackStop to pause your dockerized application. This task, after run the first time and the dockerized application stopped, can be run repeatedly but more/less amounts to a no-op. We recognize that the instance is already paused, print out a message saying as much, and allow you to continue with the rest of your automation.

Down

Using the example from above: if your application is named myPostgresStack we will create a task appropriately named myPostgresStackDown to delete your dockerized application. This task, after run the first time and the dockerized application deleted, can be run repeatedly but more/less amounts to a no-op. We recognize that the instance is already deleted, print out a message saying as much, and allow you to continue with the rest of your automation.

Tying it all together and basic usage

Now that you've defined your application you can can execute the generated tasks from the command line like so:

// kick tasks from gradle command line
cdancy@gandalf:~$ ./gradle myPostgresStackUp myPostgresStackStop myPostgresStackDown

Or define more appropriately named tasks for your users to use:

task up(dependsOn: ['myPostgresStackUp'])

task stop(dependsOn: ['myPostgresStackStop'])

task down(dependsOn: ['myPostgresStackDown'])

check.dependsOn up
build.dependsOn stop
test.finalizedBy down

On container naming

The created container names themselves are built from a concatenation of the name of the application and the last part of the repository (anything past last / or the whole repository name if none found). In turn you can expect 2 containers to be be made and named:

  • myPostgresStack-postgres // started and expected to be in a running state
  • myPostgresStack-postgres-data // never started and expected to be in a created state

On Task Chain Synchronization

Each of our high-level tasks are considered a task-chain. The execution of these task-chains are synchronized amongst the container names as is detailed further above.

Within a given single/multi gradle project ONLY ONE invocation of our 3 high-level task-chains will be executed so as to ensure we don't clobber the docker workload (i.e. task trying to delete a container while another is creating it). For example: if you have 10 sub-projects and all attempt to start your dockerized application ONLY ONE will be allowed to do so putting the other 9 in a waiting state. Once the task-chain has finished the next task-chain waiting for the lock will kick. While any task-chain is in a waiting state it will output a gradle progress logger to let the user know how long its been waiting.

About

Highly opinionated gradle plugin to start (Up), pause (Stop), and delete (Down) an arbitrary dockerized application.

Topics

Resources

License

Code of conduct

Stars

Watchers

Forks

Packages

No packages published

Languages