Managing your Infrastructure as Code provides great benefits and is often a stepping stone for a successful application of DevOps practices. In this way, instead of relying on manually performed steps, both administrators and developers can automate provisioning of compute, storage, network, and application services required by their applications using configuration files.

For example, defining your Infrastructure as Code makes it possible to:

• Keep infrastructure and application code in the same repository
• Make infrastructure changes repeatable and predictable across different environments, AWS accounts, and AWS regions
• Replicate production in a staging environment to enable continuous testing
• Replicate production in a performance test environment that you use just for the time required to run a stress test
• Release infrastructure changes using the same tools as code changes, so that deployments include infrastructure updates
• Apply software development best practices to infrastructure management, such as code reviews, or deploying small changes frequently

Configuration files used to manage your infrastructure are traditionally implemented as YAML or JSON text files, but in this way you’re missing most of the advantages of modern programming languages. Specifically with YAML, it can be very difficult to detect a file truncated while transferring to another system, or a missing line when copying and pasting from one template to another.

Wouldn’t it be better if you could use the expressive power of your favorite programming language to define your cloud infrastructure? For this reason, we introduced last year in developer preview the AWS Cloud Development Kit (CDK), an extensible open-source software development framework to model and provision your cloud infrastructure using familiar programming languages.

I am super excited to share that the AWS CDK for TypeScript and Python is generally available today!

With the AWS CDK you can design, compose, and share your own custom components that incorporate your unique requirements. For example, you can create a component setting up your own standard VPC, with its associated routing and security configurations. Or a standard CI/CD pipeline for your microservices using tools like AWS CodeBuild and CodePipeline.

Personally I really like that by using the AWS CDK, you can build your application, including the infrastructure, in your IDE, using the same programming language and with the support of autocompletion and parameter suggestion that modern IDEs have built in, without having to do a mental switch between one tool, or technology, and another. The AWS CDK makes it really fun to quickly code up your AWS infrastructure, configure it, and tie it together with your application code!

How the AWS CDK works
Everything in the AWS CDK is a construct. You can think of constructs as cloud components that can represent architectures of any complexity: a single resource, such as an S3 bucket or an SNS topic, a static website, or even a complex, multi-stack application that spans multiple AWS accounts and regions. To foster reusability, constructs can include other constructs. You compose constructs together into stacks, that you can deploy into an AWS environment, and apps, a collection of one of more stacks.

How to use the AWS CDK
We continuously add new features based on the feedback of our customers. That means that when creating an AWS resource, you often have to specify many options and dependencies. For example, if you create a VPC you have to think about how many Availability Zones (AZs) to use and how to configure subnets to give private and public access to the resources that will be deployed in the VPC.

To make it easy to define the state of AWS resources, the AWS Construct Library exposes the full richness of many AWS services with sensible defaults that you can customize as needed. In the case above, the VPC construct creates by default public and private subnets for all the AZs in the VPC, using 3 AZs if not specified.

For creating and managing CDK apps, you can use the AWS CDK Command Line Interface (CLI), a command-line tool that requires Node.js and can be installed quickly with:

npm install -g aws-cdk

After that, you can use the CDK CLI with different commands:

• cdk init to initialize in the current directory a new CDK project in one of the supported programming languages
• cdk synth to print the CloudFormation template for this app
• cdk deploy to deploy the app in your AWS Account
• cdk diff to compare what is in the project files with what has been deployed

Just run cdk to see more of the available commands and options.

You can easily include the CDK CLI in your deployment automation workflow, for example using Jenkins or AWS CodeBuild.

Let’s use the AWS CDK to build two sample projects, using different programming languages.

An example in TypeScript
For the first project I am using TypeScript to define the infrastructure:

cdk init app --language=typescript

Here’s a simplified view of what I want to build, not entering into the details of the public/private subnets in the VPC. There is an online frontend, writing messages in a queue, and an asynchronous backend, consuming messages from the queue:

Inside the stack, the following TypeScript code defines the resources I need, and their relations:

• First I define the VPC and an Amazon ECS cluster in that VPC. By using the defaults provided by the AWS Construct Library, I don’t need to specify any parameter here.
• Then I use an ECS pattern that in a few lines of code sets up an Amazon SQS queue and an ECS service running on AWS Fargate to consume the messages in that queue.
• The ECS pattern library provides higher-level ECS constructs which follow common architectural patterns, such as load balanced services, queue processing, and scheduled tasks.
• A Lambda function has the name of the queue, created by the ECS pattern, passed as an environment variable and is granted permissions to send messages to the queue.
• The code of the Lambda function and the Docker image are passed as assets. Assets allow you to bundle files or directories from your project and use them with Lambda or ECS.
• Finally, an Amazon API Gateway endpoint provides an HTTPS REST interface to the function.

const myVpc = new ec2.Vpc(this, "MyVPC");

const myCluster = new ecs.Cluster(this, "MyCluster", {
  vpc: myVpc
});

const myQueueProcessingService = new ecs_patterns.QueueProcessingFargateService(
  this, "MyQueueProcessingService", {
    cluster: myCluster,
    memoryLimitMiB: 512,
    image: ecs.ContainerImage.fromAsset("my-queue-consumer")
  });

const myFunction = new lambda.Function(
  this, "MyFrontendFunction", {
    runtime: lambda.Runtime.NODEJS_10_X,
    timeout: Duration.seconds(3),
    handler: "index.handler",
    code: lambda.Code.asset("my-front-end"),
    environment: {
      QUEUE_NAME: myQueueProcessingService.sqsQueue.queueName
    }
  });

myQueueProcessingService.sqsQueue.grantSendMessages(myFunction);

const myApi = new apigateway.LambdaRestApi(
  this, "MyFrontendApi", {
    handler: myFunction
  });

I find this code very readable and easier to maintain than the corresponding JSON or YAML. By the way, cdk synth in this case outputs more than 800 lines of plain CloudFormation YAML.

An example in Python
For the second project I am using Python:

cdk init app --language=python

I want to build a Lambda function that is executed every 10 minutes:

When you initialize a CDK project in Python, a virtualenv is set up for you. You can activate the virtualenv and install your project requirements with:

source .env/bin/activate

pip install -r requirements.txt

Note that Python autocompletion may not work with some editors, like Visual Studio Code, if you don’t start the editor from an active virtualenv.

Inside the stack, here’s the Python code defining the Lambda function and the CloudWatch Event rule to invoke the function periodically as target:

myFunction = aws_lambda.Function(
    self, "MyPeriodicFunction",
    code=aws_lambda.Code.asset("src"),
    handler="index.main",
    timeout=core.Duration.seconds(30),
    runtime=aws_lambda.Runtime.PYTHON_3_7,
)

myRule = aws_events.Rule(
    self, "MyRule",
    schedule=aws_events.Schedule.rate(core.Duration.minutes(10)),
)
myRule.add_target(aws_events_targets.LambdaFunction(myFunction))

Again, this is easy to understand even if you don’t know the details of AWS CDK. For example, durations include the time unit and you don’t have to wonder if they are expressed in seconds, milliseconds, or days. The output of cdk synth in this case is more than 90 lines of plain CloudFormation YAML.

Available Now
There is no charge for using the AWS CDK, you pay for the AWS resources that are deployed by the tool.

To quickly get hands-on with the CDK, start with this awesome step-by-step online tutorial!

More examples of CDK projects, using different programming languages, are available in this repository:

https://github.com/aws-samples/aws-cdk-examples

You can find more information on writing your own constructs here.

The AWS CDK is open source and we welcome your contribution to make it an even better tool:

https://github.com/awslabs/aws-cdk

Check out our source code on GitHub, start building your infrastructure today using TypeScript or Python, or try different languages in developer preview, such as C# and Java, and give us your feedback!

Many AWS customers also make great use of SaaS (Software as a Service) applications. For example, they use Zendesk to manage customer service & support tickets, PagerDuty to handle incident response, and SignalFx for real-time monitoring. While these applications are quite powerful on their own, they are even more so when integrated into a customer’s own systems, databases, and workflows.

New Amazon EventBridge
In order to support this increasingly common use case, we are launching Amazon EventBridge today. Building on the powerful event processing model that forms the basis for CloudWatch Events, EventBridge makes it easy for our customers to integrate their own AWS applications with SaaS applications. The SaaS applications can be hosted anywhere, and simply publish events to an event bus that is specific to each AWS customer. The asynchronous, event-based model is fast, clean, and easy to use. The publisher (SaaS application) and the consumer (code running on AWS) are completely decoupled, and are not dependent on a shared communication protocol, runtime environment, or programming language. You can use simple Lambda functions to handle events that come from a SaaS application, and you can also route events to a wide variety of other AWS targets. You can store incident or ticket data in Amazon Redshift, train a machine learning model on customer support queries, and much more.

Everything that you already know (and hopefully love) about CloudWatch Events continues to apply, with one important change. In addition to the existing default event bus that accepts events from AWS services, calls to PutEvents, and from other authorized accounts, each partner application that you subscribe to will also create an event source that you can then associate with an event bus in your AWS account. You can select any of your event buses, create EventBridge Rules, and select Targets to invoke when an incoming event matches a rule.

As part of today’s launch we are also opening up a partner program. The integration process is simple and straightforward, and generally requires less than one week of developer time.

All About Amazon EventBridge
Here are some terms that you need to know in order to understand how to use Amazon EventBridge:

Partner – An organization that has integrated their SaaS application with EventBridge.

Customer – An organization that uses AWS, and that has subscribed to a partner’s SaaS application.

Partner Name – A unique name that identifies an Amazon EventBridge partner.

Partner Event Bus – An Event Bus that is used to deliver events from a partner to AWS.

EventBridge can be accessed from the AWS Management Console, AWS Command Line Interface (CLI), or via the AWS SDKs. There are distinct commands and APIs for partners and for customers. Here are some of the most important ones:

Partners – CreatePartnerEventSource, ListPartnerEventSourceAccounts, ListPartnerEventSources, PutPartnerEvents.

Customers – ListEventSources, ActivateEventSource, CreateEventBus, ListEventBuses, PutRule, PutTargets.

Amazon EventBridge for Partners & Customers
As I noted earlier, the integration process is simple and straightforward. You need to allow your customers to enter an AWS account number and to select an AWS region. With that information in hand, you call CreatePartnerEventSource in the desired region, inform the customer of the event source name and tell them that they can accept the invitation to connect, and wait for the status of the event source to change to ACTIVE. Then, each time an event of interest to the customer occurs, you call PutPartnerEvents and reference the event source.

The process is just as simple on the customer side. You accept the invitation to connect by calling CreateEventBus to create an event bus associated with the event source. You add rules and targets to the event bus, and prepare your Lambda functions to process the events. Associating the event source with an event bus also activates the source and starts the flow of events. You can use DeActivateEventSource and ActivateEventSource to control the flow.

Here’s the overall flow (diagram created using SequenceDiagram):

Each partner has the freedom to choose the events that are relevant to their application, and to define the data elements that are included with each event.

Using EventBridge
Starting from the EventBridge Console, I click Partner event sources, find the partner of interest, and click it to learn more:

Each partner page contains additional information about the integration. I read the info, and click Set up to proceed:

The page provides me with a simple, three-step procedure to set up my event source:

After the partner creates the event source, I return to Partner event sources and I can see that the Zendesk event source is Pending:

I click the pending event source, review the details, and then click Associate with event bus:

I have the option to allow other AWS accounts, my Organization, or another Organization to access events on the event bus that I am about to create. After I have confirmed that I trust the origin and have added any additional permissions, I click Associate:

My new event bus is now available, and is listed as a Custom event bus:

I click Rules, select the event bus, and see the rules (none so far) associated with it. Then I click Create rule to make my first rule:

I enter a name and a description for my first rule:

Then I define a pattern, choosing Zendesk as the Service name:

Next, I select a Lambda function as my target:

I can also choose from many other targets:

After I create my rule, it will be activated in response to activities that occur within my Zendesk account. The initial set of events includes TicketCreated, CommentCreated, TagsChanged, AgentAssignmentChanged, GroupAssignmentChanged, FollowersChanged, EmailCCsChanged, CustomFieldChanged, and StatusChanged. Each event includes a rich set of properties; you’ll need to consult the documentation to learn more.

Partner Event Sources
We are launching with ten partner event sources, with more to come:

• Datadog
• Zendesk
• PagerDuty
• Whispir
• Saviynt
• Segment
• SignalFx
• SugarCRM
• OneLogin
• Symantec

If you have a SaaS application and you are ready to integrate, read more about EventBridge Partner Integration.

Now Available
Amazon EventBridge is available now and you can start using it today in all public AWS regions in the aws partition. Support for the AWS regions in China, and for the Asia Pacific (Osaka) Local Region, is in the works.

Pricing is based on the number of events published to the event buses in your account, billed at $1 for every million events. There is no charge for events published by AWS services.

— Jeff;

PS – As you can see from this post, we are paying even more attention to the overall AWS event model, and have a lot of interesting goodies on the drawing board. With this launch, CloudWatch Events has effectively earned a promotion to a top-level service, and I’ll have a lot more to say about that in the future!

The database is usually the most critical part of a software architecture and managing databases, especially relational ones, has never been easy. For this reason, we created Amazon Aurora Serverless, an auto-scaling version of Amazon Aurora that automatically starts up, shuts down and scales up or down based on your application workload.

The MySQL-compatible edition of Aurora Serverless has been available for some time now. I am pleased to announce that the PostgreSQL-compatible edition of Aurora Serverless is generally available today.

Before moving on with details, I take the opportunity to congratulate the Amazon Aurora development team that has just won the 2019 Association for Computing Machinery’s (ACM) Special Interest Group on Management of Data (SIGMOD) Systems Award!

When you create a database with Aurora Serverless, you set the minimum and maximum capacity. Your client applications transparently connect to a proxy fleet that routes the workload to a pool of resources that are automatically scaled. Scaling is very fast because resources are “warm” and ready to be added to serve your requests.

There is no change with Aurora Serverless on how storage is managed by Aurora. The storage layer is independent from the compute resources used by the database. There is no need to provision storage in advance. The minimum storage is 10GB and, based on the database usage, the Amazon Aurora storage will automatically grow, up to 64 TB, in 10GB increments with no impact to database performance.

Creating an Aurora Serverless PostgreSQL Database
Let’s start an Aurora Serverless PostgreSQL database and see the automatic scalability at work. From the Amazon RDS console, I select to create a database using Amazon Aurora as engine. Currently, Aurora serverless is compatible with PostgreSQL version 10.5. Selecting that version, the serverless option becomes available.

I give the new DB cluster an identifier, choose my master username, and let Amazon RDS generate a password for me. I will be able to retrieve my credentials during database creation.

I can now select the minimum and maximum capacity for my database, in terms of Aurora Capacity Units (ACUs), and in the additional scaling configuration I choose to pause compute capacity after 5 minutes of inactivity. Based on my settings, Aurora Serverless automatically creates scaling rules for thresholds for CPU utilization, connections, and available memory.

Testing Some Load on the Database
To generate some load on the database I am using sysbench on an EC2 instance. There are a couple of Lua scripts bundled with sysbench that can help generate an online transaction processing (OLTP) workload:

• The first script, parallel_prepare.lua, generates 100,000 rows per table for 24 tables.
• The second script, oltp.lua, generates workload against those data using 64 worker threads.

By using those scripts, I start generating load on my database cluster. As you can see from this graph, taken from the RDS console monitoring tab, the serverless database capacity grows and shrinks to follow my requirements. The metric shown on this graph is the number of ACUs used by the database cluster. First it scales up to accommodate the sysbench workload. When I stop the load generator, it scales down and then pauses.

Available Now
Aurora Serverless PostgreSQL is available now in US East (N. Virginia), US East (Ohio), US West (Oregon), EU (Ireland), and Asia Pacific (Tokyo). With Aurora Serverless, you pay on a per-second basis for the database capacity you use when the database is active, plus the usual Aurora storage costs.

For more information on Amazon Aurora, I recommend this great post explaining why and how it was created:

Amazon Aurora ascendant: How we designed a cloud-native relational database

It’s never been so easy to use a relational database in production. I am so excited to see what you are going to use it for!