Before we get started, this post is not meant to be an introduction to AWS infrastructure in general. It has the assumption that you are familiar with the basics of AWS.

Additional Information

I put together a quick follow up to this article to cover some gotchas, tips and tricks.

What the heck is a CDK?

The AWS Cloud Development Kit is an open source development framework designed to help you provision AWS resources using familiar programming languages.

Ummmmm… What?

Right, so it’s basically a set of tools that are designed to describe a CloudFormation Stack. The stack can then be deployed, updated, and destroyed using the CDK cli.

I can hear you out there thinking about serverless.io, terraform, and other infrastructure as code solutions. The main differentiator with the AWS CDK is that it’s designed with your language in mind. The challenge with serverless.io, terraform, etc is you have to learn a new syntax in order to get anything done. This increases the learning curve for picking up new tooling.

Currently the supported languages are:

Javascript

Typescript

Python

Java

C# (both .NET Core and .NET Framework)

For the rest of this post I’m going to focus on Javascript because it is my language of choice, but all of the example should translate to other languages easily.

Let’s init a project

The CDK cli has the ability to initialize a project. If you’re like me, I like to avoid installing npm dependencies globally. To run the CDK cli without installing globally you can run

mkdir my-first-cdk-app cd my-first-cdk-app npx aws-cdk init --language javascript

This set of commands will create a new directory for our project, move us into the directory, and initialize a CDK project including all of the necessary files and dependencies needed to get running.

You’ll see a set of commands output for using the CDK cli, but we’ll come back to those in a bit.

It starts with a stack

Because the CDK is just spitting out CloudFormation, we have to start with defining a CloudFormation Stack. The stack will be the container that holds all of the AWS resources we want to create.

The init command sets up two files: bin/my-first-cdk-app.js and lib/my-first-cdk-app-stack.js . The file in the bin directory is the entry point the CDK will use when running. It’s not magic though, there is a cdk.json file in the root that identifies the app you are going to be working with.

Let’s look at bin/my-first-cdk-app.js first:

# ! / usr / bin / env node const cdk = require ( '@aws-cdk/core' ) ; const { MyFirstCdkAppStack } = require ( '../lib/my-first-cdk-app-stack' ) ; const app = new cdk . App ( ) ; new MyFirstCdkAppStack ( app , 'MyFirstCdkAppStack' ) ;

As you can see, it’s pretty thin. It defines a new cdk.App() and passes that as the scope for a new stack called MyFirstCdkAppStack . The MyFirstCdkAppStack is defined in lib/my-first-cdk-app-stack.js so let’s look at that next.

const cdk = require ( '@aws-cdk/core' ) ; class MyFirstCdkAppStack extends cdk . Stack { constructor ( scope , id , props ) { super ( scope , id , props ) ; } } module . exports = { MyFirstCdkAppStack }

My first thought looking at this file was “AHHHHHHHHHHH! INHERITANCE!” However, this is one of the parts of the CDK that provides its power. The inheritance model of functionality adoption allow the CDK to hide a lot of the wiring needed to bring together resources within the stack.

Now that we have our stack we can start adding resources to it. Let’s start with a fairly common model at this point: serverless.

Creating a serverless application

The basic building blocks we’re going to create will be an API Gateway with a Lambda Function defined as its handler.

Let’s start with the lambda function inside the constructor of our MyFirstCdkAppStack . We’ll need to install the dependencies that allow us to create lambda functions.

npm i --save-dev @aws-cdk/aws-lambda

This is a good time to mention how all of the CDK packages are organized. The @aws-cdk namespace will have all of the different modules you’ll need to compile any resource currently supported by the CDK.

With the CDK we can define the lambda function in the same project as the infrastructure. This helps ensure our infrastructure and code are in sync with one another.

The recommended approach is to put the files for your lambda into a resources folder. This will be the location we reference from our CDK script.

Let’s create a quick hello world:

exports . handler = async function ( event , context ) { return { statusCode : 200 , headers : { } , body : JSON . stringify ( { message : 'Hello World!' } ) ; } ; }

This is an extremely over simplified example. We’ll get into more advanced use cases in a bit.

Now that we have a handler for our lambda let’s define it in the MyFirstCdkAppStack constructor:

const cdk = require ( '@aws-cdk/core' ) ; const lambda = require ( "@aws-cdk/aws-lambda" ) ; class MyFirstCdkAppStack extends cdk . Stack { constructor ( scope , id , props ) { super ( scope , id , props ) ; new lambda . Function ( this , "WidgetHandler" , { runtime : lambda . Runtime . NODEJS_12_X , code : lambda . Code . asset ( "resources" ) , handler : "hello.handler" , } ) ; } } module . exports = { MyFirstCdkAppStack } ;

I want to point out that we don’t have to keep a reference to the lambda we’ve just created. This is because we are passing this into the functions constructor which give the stack all of the reference it needs to keep track of the function. This goes against what we traditionally need to do in javascript, so it’s important to know.

If you are familiar with the CloudFormation definition of a lambda this example will look pretty familiar. This will automatically bring in the code from the resources directory as the code for the lambda. Then we tell it how to locate the handler using [FILE_NAME].[EXPORT_NAME] . This is an extremely simplified example. You can add other properties to be more specific in your setup.

Other properties include (but are not limited to):

deadLetterQueue - The dead letter queue for execution failures

deadLetterQueueEnabled

functionName

initialPolicy - An array of PolicyStatement for the created lambda role

logRetention - The number of days logs for the lambda should be retained

memorySize - The amount of memory to be allocated to the lambda (See docs for more info)

reservedConcurrentExecutions - The maximum of concurrent executions you want to reserve for the function

roles - The role that will be assumed by the function during execution

timeout - The maximum run time of the lambda in seconds

tracing - Enable X-Ray tracing

There’s a lot that can be configured on a lambda, and this is definitely NOT an exhaustive list.

Adding in API Gateway

We have a lambda to say hello to everyone, but we need a way to expose it to the world. Let’s create an API gateway.

Just like with lambda, we’ll need to start by installing the api gateway node dependency:

npm i --save-dev @aws-cdk/aws-apigateway

Now that we have the classes we need installed, let’s create an api gateway that will use our lambda as a handler.

const cdk = require ( '@aws-cdk/core' ) ; const apigateway = require ( "@aws-cdk/aws-apigateway" ) ; const lambda = require ( "@aws-cdk/aws-lambda" ) ; class MyFirstCdkAppStack extends cdk . Stack { constructor ( scope , id , props ) { super ( scope , id , props ) ; const lambdaFunction = new lambda . Function ( this , "HelloHandler" , { runtime : lambda . Runtime . NODEJS_12_X , code : lambda . Code . asset ( "resources" ) , handler : "hello.handler" , } ) ; const api = new apigateway . RestApi ( this , "hello-api" , { restApiName : "Hello World Service" , description : "This service says hello world" } ) ; const lambdaIntegration = new apigateway . LambdaIntegration ( lambdaFunction , { requestTemplates : { "application/json" : '{ "statusCode": "200" }' } } ) ; api . root . addMethod ( "GET" , lambdaIntegration ) ; } } module . exports = { MyFirstCdkAppStack } ;

Unlike in the previous example we need to maintain a reference to the lambda in order to set an api gateway integration properly. The CDK uses references as inputs to other classes as a way to convey all the needed references for CloudFormation to function properly.

Api gateway is a much more complex resource than lambda, and because of this it takes more moving parts to get it completely wired. We first create the api gateway with a name and description (These are only used for the console and reporting purposes). Then we have to create the lambda integration which will allow api gateway to wire our lambda to respond to requests. Last we wire the lambda integration to the GET method at the root route (the / route).

And with that we have a stack we can deploy!

Synthesizing

Before we deploy the stack it’s a good idea to make sure the CloudFormation it’s producing is what we want. We can do this by running the cdk command:

npm run cdk synth

This will output all of the CloudFormation the CDK generates to the console. Then we can do a quick review to make sure we’re getting everything we were expecting.

Deploying

Once we’re confident we’re getting the resources we’re expecting, we can deploy with a single CDK command as well!

npm run cdk deploy

This will first spit out a table based diff to show us what will actually be created. This is a good time to validate our checks from the synth step. The CDK will pause and wait for us to confirm that we’re happy with all of the resources being created.

Once we confirm, it will create a CloudFormation stack with the name designated in new MyFirstCdkAppStack(app, 'MyFirstCdkAppStack'); . In this case it will be MyFirstCdkAppStack .

Wrapping up

This was just a first glimpse into the capabilities of the AWS CDK. You can create almost any resource AWS has to offer. The power here will come from the ability to re-use and encapsulate code using design paradigms we’re already familiar with in our own language of choice.