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The CDK Construct Library for AWS::ECS

Project description

Amazon ECS Construct Library

---

cfn-resources: Stable

cdk-constructs: Stable


This package contains constructs for working with Amazon Elastic Container Service (Amazon ECS).

Amazon Elastic Container Service (Amazon ECS) is a fully managed container orchestration service.

For further information on Amazon ECS, see the Amazon ECS documentation

The following example creates an Amazon ECS cluster, adds capacity to it, and runs a service on it:

# vpc: ec2.Vpc


# Create an ECS cluster
cluster = ecs.Cluster(self, "Cluster",
    vpc=vpc
)

# Add capacity to it
cluster.add_capacity("DefaultAutoScalingGroupCapacity",
    instance_type=ec2.InstanceType("t2.xlarge"),
    desired_capacity=3
)

task_definition = ecs.Ec2TaskDefinition(self, "TaskDef")

task_definition.add_container("DefaultContainer",
    image=ecs.ContainerImage.from_registry("amazon/amazon-ecs-sample"),
    memory_limit_mi_b=512
)

# Instantiate an Amazon ECS Service
ecs_service = ecs.Ec2Service(self, "Service",
    cluster=cluster,
    task_definition=task_definition
)

For a set of constructs defining common ECS architectural patterns, see the @aws-cdk/aws-ecs-patterns package.

Launch Types: AWS Fargate vs Amazon EC2

There are two sets of constructs in this library; one to run tasks on Amazon EC2 and one to run tasks on AWS Fargate.

  • Use the Ec2TaskDefinition and Ec2Service constructs to run tasks on Amazon EC2 instances running in your account.
  • Use the FargateTaskDefinition and FargateService constructs to run tasks on instances that are managed for you by AWS.
  • Use the ExternalTaskDefinition and ExternalService constructs to run AWS ECS Anywhere tasks on self-managed infrastructure.

Here are the main differences:

  • Amazon EC2: instances are under your control. Complete control of task to host allocation. Required to specify at least a memory reservation or limit for every container. Can use Host, Bridge and AwsVpc networking modes. Can attach Classic Load Balancer. Can share volumes between container and host.
  • AWS Fargate: tasks run on AWS-managed instances, AWS manages task to host allocation for you. Requires specification of memory and cpu sizes at the taskdefinition level. Only supports AwsVpc networking modes and Application/Network Load Balancers. Only the AWS log driver is supported. Many host features are not supported such as adding kernel capabilities and mounting host devices/volumes inside the container.
  • AWS ECSAnywhere: tasks are run and managed by AWS ECS Anywhere on infrastructure owned by the customer. Only Bridge networking mode is supported. Does not support autoscaling, load balancing, cloudmap or attachment of volumes.

For more information on Amazon EC2 vs AWS Fargate, networking and ECS Anywhere see the AWS Documentation: AWS Fargate, Task Networking, ECS Anywhere

Clusters

A Cluster defines the infrastructure to run your tasks on. You can run many tasks on a single cluster.

The following code creates a cluster that can run AWS Fargate tasks:

# vpc: ec2.Vpc


cluster = ecs.Cluster(self, "Cluster",
    vpc=vpc
)

The following code imports an existing cluster using the ARN which can be used to import an Amazon ECS service either EC2 or Fargate.

cluster_arn = "arn:aws:ecs:us-east-1:012345678910:cluster/clusterName"

cluster = ecs.Cluster.from_cluster_arn(self, "Cluster", cluster_arn)

To use tasks with Amazon EC2 launch-type, you have to add capacity to the cluster in order for tasks to be scheduled on your instances. Typically, you add an AutoScalingGroup with instances running the latest Amazon ECS-optimized AMI to the cluster. There is a method to build and add such an AutoScalingGroup automatically, or you can supply a customized AutoScalingGroup that you construct yourself. It's possible to add multiple AutoScalingGroups with various instance types.

The following example creates an Amazon ECS cluster and adds capacity to it:

# vpc: ec2.Vpc


cluster = ecs.Cluster(self, "Cluster",
    vpc=vpc
)

# Either add default capacity
cluster.add_capacity("DefaultAutoScalingGroupCapacity",
    instance_type=ec2.InstanceType("t2.xlarge"),
    desired_capacity=3
)

# Or add customized capacity. Be sure to start the Amazon ECS-optimized AMI.
auto_scaling_group = autoscaling.AutoScalingGroup(self, "ASG",
    vpc=vpc,
    instance_type=ec2.InstanceType("t2.xlarge"),
    machine_image=ecs.EcsOptimizedImage.amazon_linux(),
    # Or use Amazon ECS-Optimized Amazon Linux 2 AMI
    # machineImage: EcsOptimizedImage.amazonLinux2(),
    desired_capacity=3
)

cluster.add_auto_scaling_group(auto_scaling_group)

If you omit the property vpc, the construct will create a new VPC with two AZs.

By default, all machine images will auto-update to the latest version on each deployment, causing a replacement of the instances in your AutoScalingGroup if the AMI has been updated since the last deployment.

If task draining is enabled, ECS will transparently reschedule tasks on to the new instances before terminating your old instances. If you have disabled task draining, the tasks will be terminated along with the instance. To prevent that, you can pick a non-updating AMI by passing cacheInContext: true, but be sure to periodically update to the latest AMI manually by using the CDK CLI context management commands:

# vpc: ec2.Vpc

auto_scaling_group = autoscaling.AutoScalingGroup(self, "ASG",
    machine_image=ecs.EcsOptimizedImage.amazon_linux(cached_in_context=True),
    vpc=vpc,
    instance_type=ec2.InstanceType("t2.micro")
)

Bottlerocket

Bottlerocket is a Linux-based open source operating system that is purpose-built by AWS for running containers. You can launch Amazon ECS container instances with the Bottlerocket AMI.

The following example will create a capacity with self-managed Amazon EC2 capacity of 2 c5.large Linux instances running with Bottlerocket AMI.

The following example adds Bottlerocket capacity to the cluster:

# cluster: ecs.Cluster


cluster.add_capacity("bottlerocket-asg",
    min_capacity=2,
    instance_type=ec2.InstanceType("c5.large"),
    machine_image=ecs.BottleRocketImage()
)

ARM64 (Graviton) Instances

To launch instances with ARM64 hardware, you can use the Amazon ECS-optimized Amazon Linux 2 (arm64) AMI. Based on Amazon Linux 2, this AMI is recommended for use when launching your EC2 instances that are powered by Arm-based AWS Graviton Processors.

# cluster: ecs.Cluster


cluster.add_capacity("graviton-cluster",
    min_capacity=2,
    instance_type=ec2.InstanceType("c6g.large"),
    machine_image=ecs.EcsOptimizedImage.amazon_linux2(ecs.AmiHardwareType.ARM)
)

Bottlerocket is also supported:

# cluster: ecs.Cluster


cluster.add_capacity("graviton-cluster",
    min_capacity=2,
    instance_type=ec2.InstanceType("c6g.large"),
    machine_image_type=ecs.MachineImageType.BOTTLEROCKET
)

Spot Instances

To add spot instances into the cluster, you must specify the spotPrice in the ecs.AddCapacityOptions and optionally enable the spotInstanceDraining property.

# cluster: ecs.Cluster


# Add an AutoScalingGroup with spot instances to the existing cluster
cluster.add_capacity("AsgSpot",
    max_capacity=2,
    min_capacity=2,
    desired_capacity=2,
    instance_type=ec2.InstanceType("c5.xlarge"),
    spot_price="0.0735",
    # Enable the Automated Spot Draining support for Amazon ECS
    spot_instance_draining=True
)

SNS Topic Encryption

When the ecs.AddCapacityOptions that you provide has a non-zero taskDrainTime (the default) then an SNS topic and Lambda are created to ensure that the cluster's instances have been properly drained of tasks before terminating. The SNS Topic is sent the instance-terminating lifecycle event from the AutoScalingGroup, and the Lambda acts on that event. If you wish to engage server-side encryption for this SNS Topic then you may do so by providing a KMS key for the topicEncryptionKey property of ecs.AddCapacityOptions.

# Given
# cluster: ecs.Cluster
# key: kms.Key

# Then, use that key to encrypt the lifecycle-event SNS Topic.
cluster.add_capacity("ASGEncryptedSNS",
    instance_type=ec2.InstanceType("t2.xlarge"),
    desired_capacity=3,
    topic_encryption_key=key
)

Task definitions

A task definition describes what a single copy of a task should look like. A task definition has one or more containers; typically, it has one main container (the default container is the first one that's added to the task definition, and it is marked essential) and optionally some supporting containers which are used to support the main container, doings things like upload logs or metrics to monitoring services.

To run a task or service with Amazon EC2 launch type, use the Ec2TaskDefinition. For AWS Fargate tasks/services, use the FargateTaskDefinition. For AWS ECS Anywhere use the ExternalTaskDefinition. These classes provide simplified APIs that only contain properties relevant for each specific launch type.

For a FargateTaskDefinition, specify the task size (memoryLimitMiB and cpu):

fargate_task_definition = ecs.FargateTaskDefinition(self, "TaskDef",
    memory_limit_mi_b=512,
    cpu=256
)

On Fargate Platform Version 1.4.0 or later, you may specify up to 200GiB of ephemeral storage:

fargate_task_definition = ecs.FargateTaskDefinition(self, "TaskDef",
    memory_limit_mi_b=512,
    cpu=256,
    ephemeral_storage_gi_b=100
)

To add containers to a task definition, call addContainer():

fargate_task_definition = ecs.FargateTaskDefinition(self, "TaskDef",
    memory_limit_mi_b=512,
    cpu=256
)
container = fargate_task_definition.add_container("WebContainer",
    # Use an image from DockerHub
    image=ecs.ContainerImage.from_registry("amazon/amazon-ecs-sample")
)

For a Ec2TaskDefinition:

ec2_task_definition = ecs.Ec2TaskDefinition(self, "TaskDef",
    network_mode=ecs.NetworkMode.BRIDGE
)

container = ec2_task_definition.add_container("WebContainer",
    # Use an image from DockerHub
    image=ecs.ContainerImage.from_registry("amazon/amazon-ecs-sample"),
    memory_limit_mi_b=1024
)

For an ExternalTaskDefinition:

external_task_definition = ecs.ExternalTaskDefinition(self, "TaskDef")

container = external_task_definition.add_container("WebContainer",
    # Use an image from DockerHub
    image=ecs.ContainerImage.from_registry("amazon/amazon-ecs-sample"),
    memory_limit_mi_b=1024
)

You can specify container properties when you add them to the task definition, or with various methods, e.g.:

To add a port mapping when adding a container to the task definition, specify the portMappings option:

# task_definition: ecs.TaskDefinition


task_definition.add_container("WebContainer",
    image=ecs.ContainerImage.from_registry("amazon/amazon-ecs-sample"),
    memory_limit_mi_b=1024,
    port_mappings=[ecs.PortMapping(container_port=3000)]
)

To add port mappings directly to a container definition, call addPortMappings():

# container: ecs.ContainerDefinition


container.add_port_mappings(
    container_port=3000
)

To add data volumes to a task definition, call addVolume():

fargate_task_definition = ecs.FargateTaskDefinition(self, "TaskDef",
    memory_limit_mi_b=512,
    cpu=256
)
volume = {
    # Use an Elastic FileSystem
    "name": "mydatavolume",
    "efs_volume_configuration": {
        "file_system_id": "EFS"
    }
}

container = fargate_task_definition.add_volume(volume)

Note: ECS Anywhere doesn't support volume attachments in the task definition.

To use a TaskDefinition that can be used with either Amazon EC2 or AWS Fargate launch types, use the TaskDefinition construct.

When creating a task definition you have to specify what kind of tasks you intend to run: Amazon EC2, AWS Fargate, or both. The following example uses both:

task_definition = ecs.TaskDefinition(self, "TaskDef",
    memory_mi_b="512",
    cpu="256",
    network_mode=ecs.NetworkMode.AWS_VPC,
    compatibility=ecs.Compatibility.EC2_AND_FARGATE
)

Images

Images supply the software that runs inside the container. Images can be obtained from either DockerHub or from ECR repositories, built directly from a local Dockerfile, or use an existing tarball.

  • ecs.ContainerImage.fromRegistry(imageName): use a public image.
  • ecs.ContainerImage.fromRegistry(imageName, { credentials: mySecret }): use a private image that requires credentials.
  • ecs.ContainerImage.fromEcrRepository(repo, tag): use the given ECR repository as the image to start. If no tag is provided, "latest" is assumed.
  • ecs.ContainerImage.fromAsset('./image'): build and upload an image directly from a Dockerfile in your source directory.
  • ecs.ContainerImage.fromDockerImageAsset(asset): uses an existing @aws-cdk/aws-ecr-assets.DockerImageAsset as a container image.
  • ecs.ContainerImage.fromTarball(file): use an existing tarball.
  • new ecs.TagParameterContainerImage(repository): use the given ECR repository as the image but a CloudFormation parameter as the tag.

Environment variables

To pass environment variables to the container, you can use the environment, environmentFiles, and secrets props.

# secret: secretsmanager.Secret
# db_secret: secretsmanager.Secret
# parameter: ssm.StringParameter
# task_definition: ecs.TaskDefinition
# s3_bucket: s3.Bucket


new_container = task_definition.add_container("container",
    image=ecs.ContainerImage.from_registry("amazon/amazon-ecs-sample"),
    memory_limit_mi_b=1024,
    environment={ # clear text, not for sensitive data
        "STAGE": "prod"},
    environment_files=[ # list of environment files hosted either on local disk or S3
        ecs.EnvironmentFile.from_asset("./demo-env-file.env"),
        ecs.EnvironmentFile.from_bucket(s3_bucket, "assets/demo-env-file.env")],
    secrets={ # Retrieved from AWS Secrets Manager or AWS Systems Manager Parameter Store at container start-up.
        "SECRET": ecs.Secret.from_secrets_manager(secret),
        "DB_PASSWORD": ecs.Secret.from_secrets_manager(db_secret, "password"),  # Reference a specific JSON field, (requires platform version 1.4.0 or later for Fargate tasks)
        "API_KEY": ecs.Secret.from_secrets_manager_version(secret, ecs.SecretVersionInfo(version_id="12345"), "apiKey"),  # Reference a specific version of the secret by its version id or version stage (requires platform version 1.4.0 or later for Fargate tasks)
        "PARAMETER": ecs.Secret.from_ssm_parameter(parameter)}
)
new_container.add_environment("QUEUE_NAME", "MyQueue")

The task execution role is automatically granted read permissions on the secrets/parameters. Support for environment files is restricted to the EC2 launch type for files hosted on S3. Further details provided in the AWS documentation about specifying environment variables.

System controls

To set system controls (kernel parameters) on the container, use the systemControls prop:

# task_definition: ecs.TaskDefinition


task_definition.add_container("container",
    image=ecs.ContainerImage.from_registry("amazon/amazon-ecs-sample"),
    memory_limit_mi_b=1024,
    system_controls=[ecs.SystemControl(
        namespace="net",
        value="ipv4.tcp_tw_recycle"
    )
    ]
)

Using Windows containers on Fargate

AWS Fargate supports Amazon ECS Windows containers. For more details, please see this blog post

# Create a Task Definition for the Windows container to start
task_definition = ecs.FargateTaskDefinition(self, "TaskDef",
    runtime_platform=ecs.RuntimePlatform(
        operating_system_family=ecs.OperatingSystemFamily.WINDOWS_SERVER_2019_CORE,
        cpu_architecture=ecs.CpuArchitecture.X86_64
    ),
    cpu=1024,
    memory_limit_mi_b=2048
)

task_definition.add_container("windowsservercore",
    logging=ecs.LogDriver.aws_logs(stream_prefix="win-iis-on-fargate"),
    port_mappings=[ecs.PortMapping(container_port=80)],
    image=ecs.ContainerImage.from_registry("mcr.microsoft.com/windows/servercore/iis:windowsservercore-ltsc2019")
)

Using Graviton2 with Fargate

AWS Graviton2 supports AWS Fargate. For more details, please see this blog post

# Create a Task Definition for running container on Graviton Runtime.
task_definition = ecs.FargateTaskDefinition(self, "TaskDef",
    runtime_platform=ecs.RuntimePlatform(
        operating_system_family=ecs.OperatingSystemFamily.LINUX,
        cpu_architecture=ecs.CpuArchitecture.ARM64
    ),
    cpu=1024,
    memory_limit_mi_b=2048
)

task_definition.add_container("webarm64",
    logging=ecs.LogDriver.aws_logs(stream_prefix="graviton2-on-fargate"),
    port_mappings=[ecs.PortMapping(container_port=80)],
    image=ecs.ContainerImage.from_registry("public.ecr.aws/nginx/nginx:latest-arm64v8")
)

Service

A Service instantiates a TaskDefinition on a Cluster a given number of times, optionally associating them with a load balancer. If a task fails, Amazon ECS automatically restarts the task.

# cluster: ecs.Cluster
# task_definition: ecs.TaskDefinition


service = ecs.FargateService(self, "Service",
    cluster=cluster,
    task_definition=task_definition,
    desired_count=5
)

ECS Anywhere service definition looks like:

# cluster: ecs.Cluster
# task_definition: ecs.TaskDefinition


service = ecs.ExternalService(self, "Service",
    cluster=cluster,
    task_definition=task_definition,
    desired_count=5
)

Services by default will create a security group if not provided. If you'd like to specify which security groups to use you can override the securityGroups property.

Deployment circuit breaker and rollback

Amazon ECS deployment circuit breaker automatically rolls back unhealthy service deployments without the need for manual intervention. Use circuitBreaker to enable deployment circuit breaker and optionally enable rollback for automatic rollback. See Using the deployment circuit breaker for more details.

# cluster: ecs.Cluster
# task_definition: ecs.TaskDefinition

service = ecs.FargateService(self, "Service",
    cluster=cluster,
    task_definition=task_definition,
    circuit_breaker=ecs.DeploymentCircuitBreaker(rollback=True)
)

Note: ECS Anywhere doesn't support deployment circuit breakers and rollback.

Include an application/network load balancer

Services are load balancing targets and can be added to a target group, which will be attached to an application/network load balancers:

# vpc: ec2.Vpc
# cluster: ecs.Cluster
# task_definition: ecs.TaskDefinition

service = ecs.FargateService(self, "Service", cluster=cluster, task_definition=task_definition)

lb = elbv2.ApplicationLoadBalancer(self, "LB", vpc=vpc, internet_facing=True)
listener = lb.add_listener("Listener", port=80)
target_group1 = listener.add_targets("ECS1",
    port=80,
    targets=[service]
)
target_group2 = listener.add_targets("ECS2",
    port=80,
    targets=[service.load_balancer_target(
        container_name="MyContainer",
        container_port=8080
    )]
)

Note: ECS Anywhere doesn't support application/network load balancers.

Note that in the example above, the default service only allows you to register the first essential container or the first mapped port on the container as a target and add it to a new target group. To have more control over which container and port to register as targets, you can use service.loadBalancerTarget() to return a load balancing target for a specific container and port.

Alternatively, you can also create all load balancer targets to be registered in this service, add them to target groups, and attach target groups to listeners accordingly.

# cluster: ecs.Cluster
# task_definition: ecs.TaskDefinition
# vpc: ec2.Vpc

service = ecs.FargateService(self, "Service", cluster=cluster, task_definition=task_definition)

lb = elbv2.ApplicationLoadBalancer(self, "LB", vpc=vpc, internet_facing=True)
listener = lb.add_listener("Listener", port=80)
service.register_load_balancer_targets(
    container_name="web",
    container_port=80,
    new_target_group_id="ECS",
    listener=ecs.ListenerConfig.application_listener(listener,
        protocol=elbv2.ApplicationProtocol.HTTPS
    )
)

Using a Load Balancer from a different Stack

If you want to put your Load Balancer and the Service it is load balancing to in different stacks, you may not be able to use the convenience methods loadBalancer.addListener() and listener.addTargets().

The reason is that these methods will create resources in the same Stack as the object they're called on, which may lead to cyclic references between stacks. Instead, you will have to create an ApplicationListener in the service stack, or an empty TargetGroup in the load balancer stack that you attach your service to.

See the ecs/cross-stack-load-balancer example for the alternatives.

Include a classic load balancer

Services can also be directly attached to a classic load balancer as targets:

# cluster: ecs.Cluster
# task_definition: ecs.TaskDefinition
# vpc: ec2.Vpc

service = ecs.Ec2Service(self, "Service", cluster=cluster, task_definition=task_definition)

lb = elb.LoadBalancer(self, "LB", vpc=vpc)
lb.add_listener(external_port=80)
lb.add_target(service)

Similarly, if you want to have more control over load balancer targeting:

# cluster: ecs.Cluster
# task_definition: ecs.TaskDefinition
# vpc: ec2.Vpc

service = ecs.Ec2Service(self, "Service", cluster=cluster, task_definition=task_definition)

lb = elb.LoadBalancer(self, "LB", vpc=vpc)
lb.add_listener(external_port=80)
lb.add_target(service.load_balancer_target(
    container_name="MyContainer",
    container_port=80
))

There are two higher-level constructs available which include a load balancer for you that can be found in the aws-ecs-patterns module:

  • LoadBalancedFargateService
  • LoadBalancedEc2Service

Task Auto-Scaling

You can configure the task count of a service to match demand. Task auto-scaling is configured by calling autoScaleTaskCount():

# target: elbv2.ApplicationTargetGroup
# service: ecs.BaseService

scaling = service.auto_scale_task_count(max_capacity=10)
scaling.scale_on_cpu_utilization("CpuScaling",
    target_utilization_percent=50
)

scaling.scale_on_request_count("RequestScaling",
    requests_per_target=10000,
    target_group=target
)

Task auto-scaling is powered by Application Auto-Scaling. See that section for details.

Integration with CloudWatch Events

To start an Amazon ECS task on an Amazon EC2-backed Cluster, instantiate an @aws-cdk/aws-events-targets.EcsTask instead of an Ec2Service:

# cluster: ecs.Cluster

# Create a Task Definition for the container to start
task_definition = ecs.Ec2TaskDefinition(self, "TaskDef")
task_definition.add_container("TheContainer",
    image=ecs.ContainerImage.from_asset(path.resolve(__dirname, "..", "eventhandler-image")),
    memory_limit_mi_b=256,
    logging=ecs.AwsLogDriver(stream_prefix="EventDemo", mode=ecs.AwsLogDriverMode.NON_BLOCKING)
)

# An Rule that describes the event trigger (in this case a scheduled run)
rule = events.Rule(self, "Rule",
    schedule=events.Schedule.expression("rate(1 min)")
)

# Pass an environment variable to the container 'TheContainer' in the task
rule.add_target(targets.EcsTask(
    cluster=cluster,
    task_definition=task_definition,
    task_count=1,
    container_overrides=[targets.ContainerOverride(
        container_name="TheContainer",
        environment=[targets.TaskEnvironmentVariable(
            name="I_WAS_TRIGGERED",
            value="From CloudWatch Events"
        )]
    )]
))

Log Drivers

Currently Supported Log Drivers:

  • awslogs
  • fluentd
  • gelf
  • journald
  • json-file
  • splunk
  • syslog
  • awsfirelens
  • Generic

awslogs Log Driver

# Create a Task Definition for the container to start
task_definition = ecs.Ec2TaskDefinition(self, "TaskDef")
task_definition.add_container("TheContainer",
    image=ecs.ContainerImage.from_registry("example-image"),
    memory_limit_mi_b=256,
    logging=ecs.LogDrivers.aws_logs(stream_prefix="EventDemo")
)

fluentd Log Driver

# Create a Task Definition for the container to start
task_definition = ecs.Ec2TaskDefinition(self, "TaskDef")
task_definition.add_container("TheContainer",
    image=ecs.ContainerImage.from_registry("example-image"),
    memory_limit_mi_b=256,
    logging=ecs.LogDrivers.fluentd()
)

gelf Log Driver

# Create a Task Definition for the container to start
task_definition = ecs.Ec2TaskDefinition(self, "TaskDef")
task_definition.add_container("TheContainer",
    image=ecs.ContainerImage.from_registry("example-image"),
    memory_limit_mi_b=256,
    logging=ecs.LogDrivers.gelf(address="my-gelf-address")
)

journald Log Driver

# Create a Task Definition for the container to start
task_definition = ecs.Ec2TaskDefinition(self, "TaskDef")
task_definition.add_container("TheContainer",
    image=ecs.ContainerImage.from_registry("example-image"),
    memory_limit_mi_b=256,
    logging=ecs.LogDrivers.journald()
)

json-file Log Driver

# Create a Task Definition for the container to start
task_definition = ecs.Ec2TaskDefinition(self, "TaskDef")
task_definition.add_container("TheContainer",
    image=ecs.ContainerImage.from_registry("example-image"),
    memory_limit_mi_b=256,
    logging=ecs.LogDrivers.json_file()
)

splunk Log Driver

# Create a Task Definition for the container to start
task_definition = ecs.Ec2TaskDefinition(self, "TaskDef")
task_definition.add_container("TheContainer",
    image=ecs.ContainerImage.from_registry("example-image"),
    memory_limit_mi_b=256,
    logging=ecs.LogDrivers.splunk(
        token=SecretValue.secrets_manager("my-splunk-token"),
        url="my-splunk-url"
    )
)

syslog Log Driver

# Create a Task Definition for the container to start
task_definition = ecs.Ec2TaskDefinition(self, "TaskDef")
task_definition.add_container("TheContainer",
    image=ecs.ContainerImage.from_registry("example-image"),
    memory_limit_mi_b=256,
    logging=ecs.LogDrivers.syslog()
)

firelens Log Driver

# Create a Task Definition for the container to start
task_definition = ecs.Ec2TaskDefinition(self, "TaskDef")
task_definition.add_container("TheContainer",
    image=ecs.ContainerImage.from_registry("example-image"),
    memory_limit_mi_b=256,
    logging=ecs.LogDrivers.firelens(
        options={
            "Name": "firehose",
            "region": "us-west-2",
            "delivery_stream": "my-stream"
        }
    )
)

To pass secrets to the log configuration, use the secretOptions property of the log configuration. The task execution role is automatically granted read permissions on the secrets/parameters.

# secret: secretsmanager.Secret
# parameter: ssm.StringParameter


task_definition = ecs.Ec2TaskDefinition(self, "TaskDef")
task_definition.add_container("TheContainer",
    image=ecs.ContainerImage.from_registry("example-image"),
    memory_limit_mi_b=256,
    logging=ecs.LogDrivers.firelens(
        options={},
        secret_options={ # Retrieved from AWS Secrets Manager or AWS Systems Manager Parameter Store
            "apikey": ecs.Secret.from_secrets_manager(secret),
            "host": ecs.Secret.from_ssm_parameter(parameter)}
    )
)

Generic Log Driver

A generic log driver object exists to provide a lower level abstraction of the log driver configuration.

# Create a Task Definition for the container to start
task_definition = ecs.Ec2TaskDefinition(self, "TaskDef")
task_definition.add_container("TheContainer",
    image=ecs.ContainerImage.from_registry("example-image"),
    memory_limit_mi_b=256,
    logging=ecs.GenericLogDriver(
        log_driver="fluentd",
        options={
            "tag": "example-tag"
        }
    )
)

CloudMap Service Discovery

To register your ECS service with a CloudMap Service Registry, you may add the cloudMapOptions property to your service:

# task_definition: ecs.TaskDefinition
# cluster: ecs.Cluster


service = ecs.Ec2Service(self, "Service",
    cluster=cluster,
    task_definition=task_definition,
    cloud_map_options=ecs.CloudMapOptions(
        # Create A records - useful for AWSVPC network mode.
        dns_record_type=cloudmap.DnsRecordType.A
    )
)

With bridge or host network modes, only SRV DNS record types are supported. By default, SRV DNS record types will target the default container and default port. However, you may target a different container and port on the same ECS task:

# task_definition: ecs.TaskDefinition
# cluster: ecs.Cluster


# Add a container to the task definition
specific_container = task_definition.add_container("Container",
    image=ecs.ContainerImage.from_registry("/aws/aws-example-app"),
    memory_limit_mi_b=2048
)

# Add a port mapping
specific_container.add_port_mappings(
    container_port=7600,
    protocol=ecs.Protocol.TCP
)

ecs.Ec2Service(self, "Service",
    cluster=cluster,
    task_definition=task_definition,
    cloud_map_options=ecs.CloudMapOptions(
        # Create SRV records - useful for bridge networking
        dns_record_type=cloudmap.DnsRecordType.SRV,
        # Targets port TCP port 7600 `specificContainer`
        container=specific_container,
        container_port=7600
    )
)

Associate With a Specific CloudMap Service

You may associate an ECS service with a specific CloudMap service. To do this, use the service's associateCloudMapService method:

# cloud_map_service: cloudmap.Service
# ecs_service: ecs.FargateService


ecs_service.associate_cloud_map_service(
    service=cloud_map_service
)

Capacity Providers

There are two major families of Capacity Providers: AWS Fargate (including Fargate Spot) and EC2 Auto Scaling Group Capacity Providers. Both are supported.

Fargate Capacity Providers

To enable Fargate capacity providers, you can either set enableFargateCapacityProviders to true when creating your cluster, or by invoking the enableFargateCapacityProviders() method after creating your cluster. This will add both FARGATE and FARGATE_SPOT as available capacity providers on your cluster.

# vpc: ec2.Vpc


cluster = ecs.Cluster(self, "FargateCPCluster",
    vpc=vpc,
    enable_fargate_capacity_providers=True
)

task_definition = ecs.FargateTaskDefinition(self, "TaskDef")

task_definition.add_container("web",
    image=ecs.ContainerImage.from_registry("amazon/amazon-ecs-sample")
)

ecs.FargateService(self, "FargateService",
    cluster=cluster,
    task_definition=task_definition,
    capacity_provider_strategies=[ecs.CapacityProviderStrategy(
        capacity_provider="FARGATE_SPOT",
        weight=2
    ), ecs.CapacityProviderStrategy(
        capacity_provider="FARGATE",
        weight=1
    )
    ]
)

Auto Scaling Group Capacity Providers

To add an Auto Scaling Group Capacity Provider, first create an EC2 Auto Scaling Group. Then, create an AsgCapacityProvider and pass the Auto Scaling Group to it in the constructor. Then add the Capacity Provider to the cluster. Finally, you can refer to the Provider by its name in your service's or task's Capacity Provider strategy.

By default, an Auto Scaling Group Capacity Provider will manage the Auto Scaling Group's size for you. It will also enable managed termination protection, in order to prevent EC2 Auto Scaling from terminating EC2 instances that have tasks running on them. If you want to disable this behavior, set both enableManagedScaling to and enableManagedTerminationProtection to false.

# vpc: ec2.Vpc


cluster = ecs.Cluster(self, "Cluster",
    vpc=vpc
)

auto_scaling_group = autoscaling.AutoScalingGroup(self, "ASG",
    vpc=vpc,
    instance_type=ec2.InstanceType("t2.micro"),
    machine_image=ecs.EcsOptimizedImage.amazon_linux2(),
    min_capacity=0,
    max_capacity=100
)

capacity_provider = ecs.AsgCapacityProvider(self, "AsgCapacityProvider",
    auto_scaling_group=auto_scaling_group
)
cluster.add_asg_capacity_provider(capacity_provider)

task_definition = ecs.Ec2TaskDefinition(self, "TaskDef")

task_definition.add_container("web",
    image=ecs.ContainerImage.from_registry("amazon/amazon-ecs-sample"),
    memory_reservation_mi_b=256
)

ecs.Ec2Service(self, "EC2Service",
    cluster=cluster,
    task_definition=task_definition,
    capacity_provider_strategies=[ecs.CapacityProviderStrategy(
        capacity_provider=capacity_provider.capacity_provider_name,
        weight=1
    )
    ]
)

Elastic Inference Accelerators

Currently, this feature is only supported for services with EC2 launch types.

To add elastic inference accelerators to your EC2 instance, first add inferenceAccelerators field to the Ec2TaskDefinition and set the deviceName and deviceType properties.

inference_accelerators = [{
    "device_name": "device1",
    "device_type": "eia2.medium"
}]

task_definition = ecs.Ec2TaskDefinition(self, "Ec2TaskDef",
    inference_accelerators=inference_accelerators
)

To enable using the inference accelerators in the containers, add inferenceAcceleratorResources field and set it to a list of device names used for the inference accelerators. Each value in the list should match a DeviceName for an InferenceAccelerator specified in the task definition.

# task_definition: ecs.TaskDefinition

inference_accelerator_resources = ["device1"]

task_definition.add_container("cont",
    image=ecs.ContainerImage.from_registry("test"),
    memory_limit_mi_b=1024,
    inference_accelerator_resources=inference_accelerator_resources
)

ECS Exec command

Please note, ECS Exec leverages AWS Systems Manager (SSM). So as a prerequisite for the exec command to work, you need to have the SSM plugin for the AWS CLI installed locally. For more information, see Install Session Manager plugin for AWS CLI.

To enable the ECS Exec feature for your containers, set the boolean flag enableExecuteCommand to true in your Ec2Service or FargateService.

# cluster: ecs.Cluster
# task_definition: ecs.TaskDefinition


service = ecs.Ec2Service(self, "Service",
    cluster=cluster,
    task_definition=task_definition,
    enable_execute_command=True
)

Enabling logging

You can enable sending logs of your execute session commands to a CloudWatch log group or S3 bucket by configuring the executeCommandConfiguration property for your cluster. The default configuration will send the logs to the CloudWatch Logs using the awslogs log driver that is configured in your task definition. Please note, when using your own logConfiguration the log group or S3 Bucket specified must already be created.

To encrypt data using your own KMS Customer Key (CMK), you must create a CMK and provide the key in the kmsKey field of the executeCommandConfiguration. To use this key for encrypting CloudWatch log data or S3 bucket, make sure to associate the key to these resources on creation.

# vpc: ec2.Vpc

kms_key = kms.Key(self, "KmsKey")

# Pass the KMS key in the `encryptionKey` field to associate the key to the log group
log_group = logs.LogGroup(self, "LogGroup",
    encryption_key=kms_key
)

# Pass the KMS key in the `encryptionKey` field to associate the key to the S3 bucket
exec_bucket = s3.Bucket(self, "EcsExecBucket",
    encryption_key=kms_key
)

cluster = ecs.Cluster(self, "Cluster",
    vpc=vpc,
    execute_command_configuration=ecs.ExecuteCommandConfiguration(
        kms_key=kms_key,
        log_configuration=ecs.ExecuteCommandLogConfiguration(
            cloud_watch_log_group=log_group,
            cloud_watch_encryption_enabled=True,
            s3_bucket=exec_bucket,
            s3_encryption_enabled=True,
            s3_key_prefix="exec-command-output"
        ),
        logging=ecs.ExecuteCommandLogging.OVERRIDE
    )
)

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