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Containerless

Tired of JavaScript all the time?

Does your application not quite work in the constraints of the serverless future?

What if your Ruby/Go/Idris/Whatever application was almost (but not quite) as easy to deploy as a Lambda function?

Introducing containerless

Simple, declaratively configured container deployments for AWS.

Warning: may contain containers. Also, docker.

Containerless Logo

Installation

Inside your serverless project:

yarn add containerless

Add the following to serverless.yml:

plugins:
  - containerless

Commands

Configured Applications will be added to the stack as part of the serverless deploy command.

When deploying, you should provide the appropriate docker image tag to use

sls deploy --noDeploy --tag hello-world-1

Building

Containerless provides the cls-build command to build and push a set of docker images to the nominated repostory.

Each application is assumed to have a Dockerfile, and to be in a directory inside the serverless parent project.

sls cls-build

sls cls-build --tag hello-world-1

If a tag is not provided, a tag in the form {app-name}-{timestamp} is generated and used.

Configuration

Configuration lives in a custom.containerless namespace in your serverless.yml

Containerless can use an existing ECS Cluster or can be configured to create a new cluster.

Minimal Configuration Example

custom:
  containerless:    
    cluster:
      vpcId: vpc-000000000001
      subnets:
        - sg-000000000001
        - sg-000000000002
    repository: 000000000000.dkr.ecr.ap-southeast-2.amazonaws.com/containerless
    stage: dev
    applications:
      hello-world

Cluster

Required fields:

  • vpcId
  • subnets

A vpcId and one or more subnets in that VPC are required. If using an existing cluster, provide the VPC and subnets that the cluster has been created in. You can also use privateSubnets option (example below).

If you need to define a VPC, a sample CloudFormation template is provided in examples/vpc.cfn.yml. You can use the

Use Existing Cluster

Required Fields:

  • id (as aws arn)
  • security_group

If an existing cluster id is provided, a security group is required in order to configure a load balancer for mapping URLs to containers. Please see below for more details.

Existing Cluster Configuration Example

custom:
  containerless:    
    cluster:
      id: arn:aws:ecs:ap-southeast-2:000000000000:cluster/ECSCluster
      vpcId: vpc-000000000001      
      subnets:
        - sg-000000000001
        - sg-000000000002
      protocol: HTTPS
    repository: 000000000000.dkr.ecr.ap-southeast-2.amazonaws.com/containerless

Create New Cluster

Optional fields:

  • capacity (defaults to 1)
  • instance_type (defaults to 't2.micro')
  • region (defaults to 'ap-southeast-2')
  • size (defaults to 1)

A new cluster will be created in an AutoScalingGroup. Capacity is the DesiredCapacity of the ASG. Please refer to AWS docs for details.

New Cluster Configuration Example

custom:
  containerless:    
    cluster:
      region: us-west-2
      capacity: 3
      vpcId: vpc-000000000001      
      subnets:
        - sg-000000000001
        - sg-000000000002
      privateSubnets:
        - sg-000000000001
        - sg-000000000002
    repository: 000000000000.dkr.ecr.ap-southeast-2.amazonaws.com/containerless

If you need you can also use privateSubnets option. Example below.

Load Balancer

The ALB will default to HTTP, but either or both HTTP and HTTPS can be specified in the cluster properties. The default ports of 80 and 443 will be used.

cluster:
  protocol:
    - HTTP
    - HTTPS

If you use HTTPS, you will also need to add the ARN of a valid certificate to the cluster config.

cluster:
  certificate: arn:aws:acm:region:account:certificate/id

Note: these are the end-user public facing ports, not the ports that are mounted by a docker image, these are mapped internally by the Cluster.

Applications

Each application requires a Dockerfile with the relevant docker setup. Please refer to the examples provided for more details.

Fields:

  • src (if not provided will default to the application name)
  • memory (defaults to 128)
  • url
  • healthcheckPath (optional, default: /)
  • port
  • environment (optional array of key/values)

In order to map to the load balancer applications need to provide both a URL and Port.

If url and port are omitted, the application will not be routed, and will be run as a task in the container.

Ports do not have to be unique, the system will dyanmically map ports to the docker container.

You can use any valid AWS Application Load Balancer path pattern as the URL. You can also provide path for your application healthcheck (default /).

Only one application can be mounted to the root url '/', because of the way in which the load balancer routes paths. Other applications will be routed based on a pattern, and you will need to remember to mount your application on that route as the load balancer forwards the whole url.

For example, requests to the url /hello will be forwarded to the application retaining the /hello path, so your application needs to handle this.

custom:
  containerless:
    applications:
      hello-1:
        url: /
        port: 3000
        memory: 256
      hello-2:
        src: src-2
        url: /hello
        healthcheckPath: /_health
        port: 3000
        environment:  
          - KEY: 'value'
      hello-3

Security Group

If you are using an existing ECS Cluster, the load balancer needs to be part of a security group that can route traffic to the Cluster Instances on the ephermeral port range used to map to docker containers.

Sample Security Group Configuration

{
  'Type': 'AWS::EC2::SecurityGroupIngress',
  'Properties': {
    'IpProtocol': 'tcp',
    'FromPort': 31000,
    'ToPort': 61000,
    'GroupId': {
      'Ref': 'ContainerlessSecurityGroup'
    },
    'SourceSecurityGroupId': {
      'Ref': 'ContainerlessSecurityGroup'
    }
  }

Handy Hint

CloudFormation can export parameters that can be consumed by other cfn stacks, which makes using Resources in those stacks much simpler.

For example, in your VPC configuration you can export VpcId and Subnet parameters:

Outputs:
  VpcId:
    Description: VPC ID
    Value:
      Ref: Vpc
    Export:
      Name:
        Fn::Sub: "${AWS::StackName}-VpcID"

And then import these into your containerless configuration:

cluster:
  vpcId:
    Fn::ImportValue: vpc-VpcID
  subnets:
    - Fn::ImportValue: vpc-PublicSubnetAz1
    - Fn::ImportValue: vpc-PublicSubnetAz2
    - Fn::ImportValue: vpc-PublicSubnetAz3

The sample VPC CloudFormation template provided in examples/vpc.cfn.yml sets these exports up for you.

Contributing

This project has been written in typescript, which means you need to edit the .ts files, not the generated JavaScript files.

The Atom Typescript plugin is ace.

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Serverless plugin for configuring ECS deployment

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