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Overview

This repository demonstrates one way of building an autoscaling app on AWS using Ansible, CloudFormation, and CodeDeploy.

A presentation explaining how this fits together is available in the docs/ directory.

There's also a simplistic matching application available at https://github.com/unboxed/aws-ansible-autoscaling-and-code-deploy-app which shows how the CodeDeploy steps work.

Important Note

Make sure you read the LICENSE.txt file!

This is a demo environment. Your mileage may vary! Make sure you understand the cost and security implementations of running this against your AWS account.

You should probably create an AWS sub-account to ensure you don't break anything important in your real environment. http://docs.aws.amazon.com/awsaccountbilling/latest/aboutv2/consolidated-billing.html has more information.

Assumptions

To try and keep this as simple as possible, I've made various assumptions about your environment.

  1. We only currently support the EU-WEST-1 region (Ireland). A search-and-replace should fix that.
  2. This repository only supports Ubuntu 14.04
  3. You want O/S security upgrades applied everywhere automatically. (See the ansible-apt section of ansible/host_vars/all for details)
  4. SSL only site. This does mean you need to create an SSL certificate, or change the Nginx config to avoid redirecting non-SSL traffic
  5. You want each individual to have their own account. See the "System Users" section of ansible/host_vars/all for more details
  6. All users will use SSH key-only authentication (set sshd_config_password_authentication to true in ansible/host_vars/all if not)
  7. You are aiming for a high-traffic site - so you want Nginx and Kernel parameters that are optimised towards a busy server.

Setting up a Demo System

AWS Prep

  1. Install the most recent AWS CLI tools (brew install awscli if you are on a mac with homebrew, or see http://docs.aws.amazon.com/cli/latest/userguide/installing.html for more details)

  2. Create AWS account or sub-account.

  3. On your command line, set these environment variables (assuming the bash shell)

     export AWS_DEFAULT_REGION='eu-west-1'
     export AWS_ACCESS_KEY_ID='AKI...'
     export AWS_SECRET_ACCESS_KEY='...'
    
  4. Create a test SSL key and upload it. Take note of the 'ArnId' of the uploaded key: (You can retrieve it later with 'aws iam list-server-certificates')

     openssl genrsa -out $HOME/Documents/blog.example.key 2048
     openssl req -new -x509 -key $HOME/Documents/blog.example.key -out $HOME/Documents/blog.example.cert -days 3650 -subj /CN=blog.example
     aws iam upload-server-certificate --server-certificate-name blog.example --certificate-body file://$HOME/Documents/blog.example.cert --private-key file://$HOME/Documents/blog.example.key
    

Build S3 Bucket Stack

First off, you're going to upload the Ansible config and the App to an S3 bucket. This has to happen first, since when the server instances come up, they need to download and install this software. Without this, they won't come up correctly.

I've included a simple cloudformation stack to create the buckets for you. To use it:

Log into the AWS web console and make sure you are in the 'Ireland' (EU-West-1) region. Then:

  1. Click on the "Cloudformation" service
  2. Click "Create Stack"
  3. Enter "blog-dev-s3-buckets" as the stack name (you will have multiple stacks eventually: one for dev, one for staging, etc) The exact name doesn't really matter.
  4. Click "Choose File" and select the s3-buckets.json file you created. Then click Next.
  5. Set System Parameters:
  • AppName: Choose 'blog' (lower-case) for this example.
  • BucketPrefix: Set this to something unique to you, so that you don't conflict with other users of this repo. use something like your-name or yourname or your-organisation-name (keep it lower-case and use hyphens, not underscores).
  1. Click "Next", and "Next" again to go through the advanced options.
  2. Click "Create"
  3. Wait for the stack to build. If everything is successful, it should change to state 'CREATE_COMPLETE'.

Repository Preparation

The next step is to configure your application - it's hostname, the environment variables it needs, and similar.

  1. Edit facts/dev/app.fact and set the hostname you want the server to respond to. You can also set any environment variables or similar in the same location.
  2. Configure your personal account details by editing ansible/group_vars/all Add an entry to the sysadmin_users array - by commenting out the 'sysadmin_users: []' line and adding a user in the format explained in that section.

Upload the Ansible Configs

$ export AWS_DEFAULT_REGION='eu-west-1'
$ export AWS_ACCESS_KEY_ID='AKI...'
$ export AWS_SECRET_ACCESS_KEY='...'
$ # Upload the ansible config - note that you must pass parameters that match
$ # the parameters you supplied to the S3 bucket stack.
$ scripts/push-config-to-s3 bucketprefix blog dev
Copying fact files to S3
...
SUCCESS
$

Build the CloudFormation Stack

AWS Cloudformation configs are limited to around 50kb - and whitespace counts against you. So you need to strip out the whitespace before doing the upload. The simplest way to do this is to use jq:

  1. Make sure you have the 'jq' app installed (brew install jq on a mac with Homebrew)
  2. Compact the CloudFormation config on the command line with the command jq < stack.json > stack-compact.json.

Log into the AWS web console and make sure you are in the 'Ireland' (EU-West-1) region. Then:

  1. Click on the "Cloudformation" service
  2. Click "Create Stack"
  3. Enter "blog-dev" as the stack name (you will have multiple stacks eventually: one for dev, one for staging, etc) The exact name doesn't really matter.
  4. Click "Choose File" and select the stack-compact.json file you created. Then click Next.
  5. Set System Parameters:
  • AppName: Choose 'blog' (lower-case) for this example.
  • BucketPrefix: Set this to something unique to you, so that you don't conflict with other users of this repo. use something like your-name or yourname or your-organisation-name (keep it lower-case and use hyphens, not underscores). This must match the value you previously set for the S3 stack.
  • DBAllocatedStorage: How many gigabytes of DB space to add to the server. Note that due to AWS pricing rules, you will have very poor performance if you create a DB of less than 100GB. You will hit your burst performance limit quickly. See http://docs.aws.amazon.com/AmazonRDS/latest/UserGuide/CHAP_Storage.html for more info. Obviously the higher the number, the bigger the cost.
  • DBInstanceType: Set this to whatever DB instance type you want. Note that small RDS instances can take a very long time to create, and don't support full encryption.
  • DBMaxConnections: How many DB connections you want. This reduces memory on your database, but allows you to set your DB pool size higher than the RDS defaults. https://wiki.postgresql.org/wiki/Number_Of_Database_Connections has more info on memory vs connection count tradeoffs. You probably want your connection count to be in the region of NumberOfRubyServers * NumberOfWorkers * NumberOfThreads - and the default app expects up 1 server, 4 workers, and up to 32 threads (128 connections per server.)
  • DBMultiAZ: If you're just testing things, you might want to run a single availability zone DB. Set to true if you want any reliability. See http://aws.amazon.com/rds/details/multi-az/ for details and cost implications, since multi-AZ dbs are expensive.
  • DBName: Set the name of the db - this will automatically have the environment appended to it. For this example - set it to 'blog', so that the db name will be created as 'blog_dev'. The associated user will be 'blog_dev_user'
  • DBPassword: set a long and complicated password that your DB will use. The app will be passed this through a DATABASE_URL environment variable. See http://12factor.net/config for details.
  • DBStorageEncrypted: Set to true if you want your DB to be encrypted at rest. Note that not all instance types (DBInstanceType param) support encryption. See http://docs.aws.amazon.com/AmazonRDS/latest/UserGuide/Overview.Encryption.html for info.
  • DBStorageType: Set the storage type. You probably want SSD (gpt).
  • EnvironmentName: What environment is this? Choose Dev for testing purposes. This is used for naming S3 buckets, and setting server instance permissions so that they can read from those buckets. Note that it is NOT used for setting the RAILS_ENV environment parameter. You should set that in the facts/*/app.fact file, in the app_environment section.
  • SecretKeyBase: This is critical for the security of your app. You will likely want to run bundle exec rake secret in a Rails app directory to generate this. This is passed into the application as an environment variable, so you can use it in secrets.yml in your Rails app.
  • ServerAMIID: Which AWS/Ubuntu AMI to run. See http://cloud-images.ubuntu.com/trusty/current/ You must choose a 'hvm-ssd' style kernel. To reduce the time spent applying security upgrades, and to avoid requiring a reboot when the kernel upgrades, you should keep this current with the latest daily Ubuntu AMI build. You will need to choose an AMI related to your chosen region. By default this is eu-west-1
  • SSHKeyName: Select your SSH key from the dropdown. For your first trial run you will use this key to ssh in - but in the Next Steps section of this document we will move to individual accounts.
  • SSHLocation: The IP address range that you want SSH to be allow in from. This configures AWS security groups to limit incoming SSH access. Leave it as 0.0.0.0/0 for a global allow for this test.
  • SSLCertificateIdArn: The Arn of the SSL key you generated earlier. You can find instructions for locating it above if needs be.
  • WebServerCountDesired / WebServerCountMax / WebServerCountMin: The number of entries in the WebServer auto scaling group. See http://docs.aws.amazon.com/AutoScaling/latest/DeveloperGuide/as-maintain-instance-levels.html for details. Leave this as 1/1/1 for this demo.
  • WebServerHealthCheckType: Set this to EC2 for now - we'll cover it in more detail below.
  • WebserverInstanceType: Which EC2 server to use for webservers. We've had success with the c4.xlarge instance type - but you can use any SSD-HVM supporting instance here if you want. Note that the smaller you go, the longer the systems take to start and build.
  1. Click "Next", and "Next" again to go through the advanced options.
  2. Acknowledge the warning about the creation of IAM resources. These Roles and permissions are detailed in the stack.json file, along with related URLs in the comment section if you are concerned.
  3. Click "Create"
  4. Wait for the stack to build. If everything is successful, it should change to state 'CREATE_COMPLETE'.

Once the stack is built, you should have one or more servers in the EC2 console.

Additionally, you should see Elastic Load Balancers and auto scaling groups in the EC2 console.

Create CodeDeploy Configs

Once the app has been built, create a CodeDeploy configuration.

Log into the AWS web console and make sure you are in the 'Ireland' (EU-West-1) region. Then:

  1. Services -> CodeDeploy
  2. Create a new CodeDeploy config ("Get Started Now")
  3. Choose "Custom Deployment" and "Skip Walkthrough", since you don't want ot install the demo app
  4. Set Application Name to "blog-yourname-production", "blog-yourname-preview", "blog-yourname-dev", or similar (note that this is case-sensitive, and the deployment script expects an exact match to be able to do the deploy.
  5. Set the Deployment Group Name to "RailsAppServers" (again - case and naming is important so that the deploy scripts can locate this item correctly!)
  6. In "Add Instances", change the Tag Type to "Auto Scaling Group", and add the correct WebServerGroup for the env you are working on (eg: staging-WebServerGroup-something-here)
  7. Set the "Deployment Config" to be "CodeDeployDefault.OneAtATime" (the default)
  8. Set the "Service Role ARN" to the CodeDeployTrustRole of your environment (eg: staging-CodeDeployTrustRole-something-here). Take care not to select the InstanceRole!
  9. Click "Create Application"

Deploy the App

Next, you'll need to upload the application itself. To do this, you need a checked-out git copy of http://github.com/unboxed/aws-ansible-autoscaling-and-code-deploy-app

$ # These should be set from earlier:
$ export AWS_DEFAULT_REGION='eu-west-1'
$ export AWS_ACCESS_KEY_ID='AKI...'
$ export AWS_SECRET_ACCESS_KEY='...'
$ # Upload the app itself - note that you must pass the parameter that matches
$ # the parameters you supplied to the S3 bucket stack.
$ # Note that we supply a branch or tag or SHA to the push:
$ scripts/push-release-to-s3.sh bucketprefix blog dev HEAD
Copying fact files to S3
...
SUCCESS

Have a look on the CodeDeploy UI - you should see CodeDeploy rolling out the new version of the codebase to your servers.

Testing the App

To test the app, you'll either need to edit your /etc/hosts file, or set up a DNS record as per http://docs.aws.amazon.com/ElasticLoadBalancing/latest/DeveloperGuide/using-domain-names-with-elb.html

To locate the DNS name of the Load Balancer, go to the AWS console, select EC2, select Load Balancers, and select the Load balancer. You will see "DNS Name" listed in the bottom section - something like 'blog-somethingoverhere-123123123.eu-west-1.elb.amazonaws.com'

If you want to test from the command line, grab the hostname of the Elastic Load Balancer, and run curl. You should see the rails app response. You'll need to make sure that the hostname matches the value you set in the webserver_hostname parameter of facts/dev/app.fact

curl -k -H 'Host: blog-dev.example.com' https://blog-dev-123123123.eu-west-1.elb.amazonaws.com

Next Steps

Switch to ELB Healthchecks

When you first create the stack, we default to "EC2 healthchecks". If we defaulted to ELB healthchecks up front, we'd be in a catch-22. The servers would come up without a webserver app (since we only create the deployment in the following step).

As the app isn't running, the ELB would consider the servers to be down. It then classify them as unhealthy. The autoscaling group would delete them and create a new server in it's place. Servers would be created and destroyed until you went through the "Deploy the App" step above.

Once you've got a working app up and running - you should change the healthcheck to be an ELB healthcheck rather than an EC2 healthcheck.

To do this, Log into the AWS UI, go to the CloudFormation Service, and update the Cloudformation stack, re-upload the stack file, and select ELB instead of EC2. You should check the 'Use existing value' value is ticked for all items that had passwords or similar.

This way, if your webserver stops responding, ELB will replace it.

Configure Individual Accounts

You probably want individual account access, rather than logging in as ubuntu.

Note that if all goes well with the server build, you will not be able to log in with that key - you should instead use your own configured username and key from the ansible/group_vars/all file

Diagnosing Problems

If your server doesn't come up correctly, you can check the logs by sshing in as ubuntu and viewing /var/log/cloud-init.log

If you are having problems with an existing system, you can view the system logs via the AWS CloudWatch interface. Log in, click on the CloudWatch service, select "Logs", select the type of log and then the instance ID.

A Word of Warning

You should be very careful when updating the CloudFormation stack. You should take care to test your changes on a matching stack before making any changes to production.

Additionally - you should strongly avoid making changes to the AWS infrastructure other than through CloudFormation uploads.

It's possible that Cloudformation could try and update your stack config, run into problems, and then revert to the previous config.

If you've made manual changes to the stack, your rolled-back version of the stack won't be as you expect. This could lead to a double failure in Cloudformation: The stack can't roll forward - but it also can't roll back.

In that case, your only option is to delete the stack! Doing so will delete your RDS database too - AND it's backups. So you must be VERY careful to only do this if you've made manual Postgres DB Backups, or are comfortable restoring your DB from a manual RDS backup!