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CDK Constructs for AWS EC2

Project description

Amazon EC2 Construct Library


Stability: Stable

This is a developer preview (public beta) module. Releases might lack important features and might have future breaking changes.


The @aws-cdk/aws-ec2 package contains primitives for setting up networking and instances.

VPC

Most projects need a Virtual Private Cloud to provide security by means of network partitioning. This is easily achieved by creating an instance of Vpc:

import ec2 = require('@aws-cdk/aws-ec2');

const vpc = new ec2.Vpc(this, 'VPC');

All default Constructs requires EC2 instances to be launched inside a VPC, so you should generally start by defining a VPC whenever you need to launch instances for your project.

Our default Vpc class creates a private and public subnet for every availability zone. Classes that use the VPC will generally launch instances into all private subnets, and provide a parameter called vpcSubnets to allow you to override the placement. Read more about subnets.

Advanced Subnet Configuration

If you require the ability to configure subnets the Vpc can be customized with SubnetConfiguration array. This is best explained by an example:

import ec2 = require('@aws-cdk/aws-ec2');

const vpc = new ec2.Vpc(this, 'TheVPC', {
  cidr: '10.0.0.0/21',
  subnetConfiguration: [
    {
      cidrMask: 24,
      name: 'Ingress',
      subnetType: SubnetType.Public,
    },
    {
      cidrMask: 24,
      name: 'Application',
      subnetType: SubnetType.Private,
    },
    {
      cidrMask: 28,
      name: 'Database',
      subnetType: SubnetType.Isolated,
    }
  ],
});

The example above is one possible configuration, but the user can use the constructs above to implement many other network configurations.

The Vpc from the above configuration in a Region with three availability zones will be the following:

  • IngressSubnet1: 10.0.0.0/24
  • IngressSubnet2: 10.0.1.0/24
  • IngressSubnet3: 10.0.2.0/24
  • ApplicationSubnet1: 10.0.3.0/24
  • ApplicationSubnet2: 10.0.4.0/24
  • ApplicationSubnet3: 10.0.5.0/24
  • DatabaseSubnet1: 10.0.6.0/28
  • DatabaseSubnet2: 10.0.6.16/28
  • DatabaseSubnet3: 10.0.6.32/28

Each Public Subnet will have a NAT Gateway. Each Private Subnet will have a route to the NAT Gateway in the same availability zone. Each Isolated subnet will not have a route to the internet, but is routeable inside the VPC. The numbers [1-3] will consistently map to availability zones (e.g. IngressSubnet1 and ApplicationSubnet1 will be in the same avialbility zone).

Isolated Subnets provide simplified secure networking principles, but come at an operational complexity. The lack of an internet route means that if you deploy instances in this subnet you will not be able to patch from the internet, this is commonly reffered to as fully baked images. Features such as cfn-signal are also unavailable. Using these subnets for managed services (RDS, Elasticache, Redshift) is a very practical use because the managed services do not incur additional operational overhead.

Many times when you plan to build an application you don't know how many instances of the application you will need and therefore you don't know how much IP space to allocate. For example, you know the application will only have Elastic Loadbalancers in the public subnets and you know you will have 1-3 RDS databases for your data tier, and the rest of the IP space should just be evenly distributed for the application.

import ec2 = require('@aws-cdk/aws-ec2');

const vpc = new ec2.Vpc(this, 'TheVPC', {
  cidr: '10.0.0.0/16',
  natGateways: 1,
  subnetConfiguration: [
    {
      cidrMask: 26,
      name: 'Public',
      subnetType: SubnetType.Public,
    },
    {
      name: 'Application',
      subnetType: SubnetType.Private,
    },
    {
      cidrMask: 27,
      name: 'Database',
      subnetType: SubnetType.Isolated,
    }
  ],
});

The Vpc from the above configuration in a Region with three availability zones will be the following:

  • PublicSubnet1: 10.0.0.0/26
  • PublicSubnet2: 10.0.0.64/26
  • PublicSubnet3: 10.0.2.128/26
  • DatabaseSubnet1: 10.0.0.192/27
  • DatabaseSubnet2: 10.0.0.224/27
  • DatabaseSubnet3: 10.0.1.0/27
  • ApplicationSubnet1: 10.0.64.0/18
  • ApplicationSubnet2: 10.0.128.0/18
  • ApplicationSubnet3: 10.0.192.0/18

Any subnet configuration without a cidrMask will be counted up and allocated evenly across the remaining IP space.

Teams may also become cost conscious and be willing to trade availability for cost. For example, in your test environments perhaps you would like the same VPC as production, but instead of 3 NAT Gateways you would like only 1. This will save on the cost, but trade the 3 availability zone to a 1 for all egress traffic. This can be accomplished with a single parameter configuration:

import ec2 = require('@aws-cdk/aws-ec2');

const vpc = new ec2.Vpc(this, 'TheVPC', {
  cidr: '10.0.0.0/16',
  natGateways: 1,
  natGatewayPlacement: {subnetName: 'Public'},
  subnetConfiguration: [
    {
      cidrMask: 26,
      name: 'Public',
      subnetType: SubnetType.Public,
      natGateway: true,
    },
    {
      name: 'Application',
      subnetType: SubnetType.Private,
    },
    {
      cidrMask: 27,
      name: 'Database',
      subnetType: SubnetType.Isolated,
    }
  ],
});

The Vpc above will have the exact same subnet definitions as listed above. However, this time the VPC will have only 1 NAT Gateway and all Application subnets will route to the NAT Gateway.

Reserving subnet IP space

There are situations where the IP space for a subnet or number of subnets will need to be reserved. This is useful in situations where subnets would need to be added after the vpc is originally deployed, without causing IP renumbering for existing subnets. The IP space for a subnet may be reserved by setting the reserved subnetConfiguration property to true, as shown below:

import ec2 = require('@aws-cdk/aws-ec2');
const vpc = new ec2.Vpc(this, 'TheVPC', {
  cidr: '10.0.0.0/16',
  natGateways: 1,
  subnetConfiguration: [
    {
      cidrMask: 26,
      name: 'Public',
      subnetType: SubnetType.Public,
    },
    {
      cidrMask: 26,
      name: 'Application1',
      subnetType: SubnetType.Private,
    },
    {
      cidrMask: 26,
      name: 'Application2',
      subnetType: SubnetType.Private,
      reserved: true,
    },
    {
      cidrMask: 27,
      name: 'Database',
      subnetType: SubnetType.Isolated,
    }
  ],
});

In the example above, the subnet for Application2 is not actually provisioned but its IP space is still reserved. If in the future this subnet needs to be provisioned, then the reserved: true property should be removed. Most importantly, this action would not cause the Database subnet to get renumbered, but rather the IP space that was previously reserved will be used for the subnet provisioned for Application2. The reserved property also takes into consideration the number of availability zones when reserving IP space.

Sharing VPCs between stacks

If you are creating multiple Stacks inside the same CDK application, you can reuse a VPC defined in one Stack in another by using export() and import():

/**
 * Stack1 creates the VPC
 */
class Stack1 extends cdk.Stack {
  public readonly vpc: ec2.Vpc;

  constructor(scope: cdk.App, id: string, props?: cdk.StackProps) {
    super(scope, id, props);

    this.vpc = new ec2.Vpc(this, 'VPC');
  }
}

interface Stack2Props extends cdk.StackProps {
  vpc: ec2.IVpc;
}

/**
 * Stack2 consumes the VPC
 */
class Stack2 extends cdk.Stack {
  constructor(scope: cdk.App, id: string, props: Stack2Props) {
    super(scope, id, props);

    // Pass the VPC to a construct that needs it
    new ConstructThatTakesAVpc(this, 'Construct', {
      vpc: props.vpc
    });
  }
}

const stack1 = new Stack1(app, 'Stack1');
const stack2 = new Stack2(app, 'Stack2', {
  vpc: stack1.vpc,
});

Importing an existing VPC

If your VPC is created outside your CDK app, you can use fromLookup():

const vpc = ec2.Vpc.fromLookup(stack, 'VPC', {
  // This imports the default VPC but you can also
  // specify a 'vpcName' or 'tags'.
  isDefault: true
});

Allowing Connections

In AWS, all network traffic in and out of Elastic Network Interfaces (ENIs) is controlled by Security Groups. You can think of Security Groups as a firewall with a set of rules. By default, Security Groups allow no incoming (ingress) traffic and all outgoing (egress) traffic. You can add ingress rules to them to allow incoming traffic streams. To exert fine-grained control over egress traffic, set allowAllOutbound: false on the SecurityGroup, after which you can add egress traffic rules.

You can manipulate Security Groups directly:

const mySecurityGroup = new ec2.SecurityGroup(this, 'SecurityGroup', {
  vpc,
  description: 'Allow ssh access to ec2 instances',
  allowAllOutbound: true   // Can be set to false
});
mySecurityGroup.addIngressRule(new ec2.AnyIPv4(), new ec2.TcpPort(22), 'allow ssh access from the world');

All constructs that create ENIs on your behalf (typically constructs that create EC2 instances or other VPC-connected resources) will all have security groups automatically assigned. Those constructs have an attribute called connections, which is an object that makes it convenient to update the security groups. If you want to allow connections between two constructs that have security groups, you have to add an Egress rule to one Security Group, and an Ingress rule to the other. The connections object will automatically take care of this for you:

// Allow connections from anywhere
loadBalancer.connections.allowFromAnyIpv4(new ec2.TcpPort(443), 'Allow inbound HTTPS');

// The same, but an explicit IP address
loadBalancer.connections.allowFrom(new ec2.CidrIpv4('1.2.3.4/32'), new ec2.TcpPort(443), 'Allow inbound HTTPS');

// Allow connection between AutoScalingGroups
appFleet.connections.allowTo(dbFleet, new ec2.TcpPort(443), 'App can call database');

Connection Peers

There are various classes that implement the connection peer part:

// Simple connection peers
let peer = new ec2.CidrIp("10.0.0.0/16");
let peer = new ec2.AnyIPv4();
let peer = new ec2.CidrIpv6("::0/0");
let peer = new ec2.AnyIPv6();
let peer = new ec2.PrefixList("pl-12345");
fleet.connections.allowTo(peer, new ec2.TcpPort(443), 'Allow outbound HTTPS');

Any object that has a security group can itself be used as a connection peer:

// These automatically create appropriate ingress and egress rules in both security groups
fleet1.connections.allowTo(fleet2, new ec2.TcpPort(80), 'Allow between fleets');

fleet.connections.allowTcpPort(80), 'Allow from load balancer');

Port Ranges

The connections that are allowed are specified by port ranges. A number of classes provide the connection specifier:

new ec2.TcpPort(80)
new ec2.TcpPortRange(60000, 65535)
new ec2.TcpAllPorts()
new ec2.AllConnections()

NOTE: This set is not complete yet; for example, there is no library support for ICMP at the moment. However, you can write your own classes to implement those.

Default Ports

Some Constructs have default ports associated with them. For example, the listener of a load balancer does (it's the public port), or instances of an RDS database (it's the port the database is accepting connections on).

If the object you're calling the peering method on has a default port associated with it, you can call allowDefaultPortFrom() and omit the port specifier. If the argument has an associated default port, call allowToDefaultPort().

For example:

// Port implicit in listener
listener.connections.allowDefaultPortFromAnyIpv4('Allow public');

// Port implicit in peer
fleet.connections.allowToDefaultPort(rdsDatabase, 'Fleet can access database');

Machine Images (AMIs)

AMIs control the OS that gets launched when you start your EC2 instance. The EC2 library contains constructs to select the AMI you want to use.

Depending on the type of AMI, you select it a different way.

The latest version of Amazon Linux and Microsoft Windows images are selectable by instantiating one of these classes:

// Pick a Windows edition to use
const windows = new ec2.WindowsImage(ec2.WindowsVersion.WINDOWS_SERVER_2019_ENGLISH_FULL_BASE);

// Pick the right Amazon Linux edition. All arguments shown are optional
// and will default to these values when omitted.
const amznLinux = new ec2.AmazonLinuxImage({
  generation: ec2.AmazonLinuxGeneration.AMAZON_LINUX,
  edition: ec2.AmazonLinuxEdition.STANDARD,
  virtualization: ec2.AmazonLinuxVirt.HVM,
  storage: ec2.AmazonLinuxStorage.GENERAL_PURPOSE,
});

// For other custom (Linux) images, instantiate a `GenericLinuxImage` with
// a map giving the AMI to in for each region:

const linux = new ec2.GenericLinuxImage({
    'us-east-1': 'ami-97785bed',
    'eu-west-1': 'ami-12345678',
    // ...
});

NOTE: The Amazon Linux images selected will be cached in your cdk.json, so that your AutoScalingGroups don't automatically change out from under you when you're making unrelated changes. To update to the latest version of Amazon Linux, remove the cache entry from the context section of your cdk.json.

We will add command-line options to make this step easier in the future.

VPN connections to a VPC

Create your VPC with VPN connections by specifying the vpnConnections props (keys are construct ids):

const vpc = new ec2.Vpc(stack, 'MyVpc', {
  vpnConnections: {
    dynamic: { // Dynamic routing (BGP)
      ip: '1.2.3.4'
    },
    static: { // Static routing
      ip: '4.5.6.7',
      staticRoutes: [
        '192.168.10.0/24',
        '192.168.20.0/24'
      ]
    }
  }
});

To create a VPC that can accept VPN connections, set vpnGateway to true:

const vpc = new ec2.Vpc(stack, 'MyVpc', {
  vpnGateway: true
});

VPN connections can then be added:

vpc.addVpnConnection('Dynamic', {
  ip: '1.2.3.4'
});

Routes will be propagated on the route tables associated with the private subnets.

VPN connections expose metrics (cloudwatch.Metric) across all tunnels in the account/region and per connection:

// Across all tunnels in the account/region
const allDataOut = VpnConnection.metricAllTunnelDataOut();

// For a specific vpn connection
const vpnConnection = vpc.addVpnConnection('Dynamic', {
  ip: '1.2.3.4'
});
const state = vpnConnection.metricTunnelState();

VPC endpoints

A VPC endpoint enables you to privately connect your VPC to supported AWS services and VPC endpoint services powered by PrivateLink without requiring an internet gateway, NAT device, VPN connection, or AWS Direct Connect connection. Instances in your VPC do not require public IP addresses to communicate with resources in the service. Traffic between your VPC and the other service does not leave the Amazon network.

Endpoints are virtual devices. They are horizontally scaled, redundant, and highly available VPC components that allow communication between instances in your VPC and services without imposing availability risks or bandwidth constraints on your network traffic.

    // Add gateway endpoints when creating the VPC
    const vpc = new ec2.Vpc(this, 'MyVpc', {
      gatewayEndpoints: {
        S3: {
          service: ec2.GatewayVpcEndpointAwsService.S3
        }
      }
    });

    // Alternatively gateway endpoints can be added on the VPC
    const dynamoDbEndpoint = vpc.addGatewayEndpoint('DynamoDbEndpoint', {
      service: ec2.GatewayVpcEndpointAwsService.DYNAMODB
    });

    // This allows to customize the endpoint policy
    dynamoDbEndpoint.addToPolicy(
      new iam.PolicyStatement({ // Restrict to listing and describing tables
        principals: [new iam.AnyPrincipal()],
        actions: ['dynamodb:DescribeTable', 'dynamodb:ListTables'],
        resources: ['*'],
    }));

    // Add an interface endpoint
    const ecrDockerEndpoint = vpc.addInterfaceEndpoint('EcrDockerEndpoint', {
      service: ec2.InterfaceVpcEndpointAwsService.ECR_DOCKER
    });

    // When working with an interface endpoint, use the connections object to
    // allow traffic to flow to the endpoint.
    ecrDockerEndpoint.connections.allowDefaultPortFromAnyIpv4();

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