aws-cdk.aws-stepfunctions 1.11.0

The CDK Construct Library for AWS::StepFunctions

AWS Step Functions Construct Library

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

This API is still under active development and subject to non-backward compatible changes or removal in any future version. Use of the API is not recommended in production environments. Experimental APIs are not subject to the Semantic Versioning model.

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The @aws-cdk/aws-stepfunctions package contains constructs for building serverless workflows using objects. Use this in conjunction with the @aws-cdk/aws-stepfunctions-tasks package, which contains classes used to call other AWS services.

Defining a workflow looks like this (for the Step Functions Job Poller example):

TypeScript example

import sfn = require('@aws-cdk/aws-stepfunctions');
import tasks = require('@aws-cdk/aws-stepfunctions-tasks');

const submitLambda = new lambda.Function(this, 'SubmitLambda', { ... });
const getStatusLambda = new lambda.Function(this, 'CheckLambda', { ... });

const submitJob = new sfn.Task(this, 'Submit Job', {
    task: new tasks.InvokeFunction(submitLambda),
    // Put Lambda's result here in the execution's state object
    resultPath: '$.guid',
});

const waitX = new sfn.Wait(this, 'Wait X Seconds', {
    duration: sfn.WaitDuration.secondsPath('$.wait_time'),
});

const getStatus = new sfn.Task(this, 'Get Job Status', {
    task: new tasks.InvokeFunction(getStatusLambda),
    // Pass just the field named "guid" into the Lambda, put the
    // Lambda's result in a field called "status"
    inputPath: '$.guid',
    resultPath: '$.status',
});

const jobFailed = new sfn.Fail(this, 'Job Failed', {
    cause: 'AWS Batch Job Failed',
    error: 'DescribeJob returned FAILED',
});

const finalStatus = new sfn.Task(this, 'Get Final Job Status', {
    task: new tasks.InvokeFunction(getStatusLambda),
    // Use "guid" field as input, output of the Lambda becomes the
    // entire state machine output.
    inputPath: '$.guid',
});

const definition = submitJob
    .next(waitX)
    .next(getStatus)
    .next(new sfn.Choice(this, 'Job Complete?')
        // Look at the "status" field
        .when(sfn.Condition.stringEquals('$.status', 'FAILED'), jobFailed)
        .when(sfn.Condition.stringEquals('$.status', 'SUCCEEDED'), finalStatus)
        .otherwise(waitX));

new sfn.StateMachine(this, 'StateMachine', {
    definition,
    timeout: Duration.minutes(5)
});

State Machine

A stepfunctions.StateMachine is a resource that takes a state machine definition. The definition is specified by its start state, and encompasses all states reachable from the start state:

const startState = new stepfunctions.Pass(this, 'StartState');

new stepfunctions.StateMachine(this, 'StateMachine', {
    definition: startState
});

State machines execute using an IAM Role, which will automatically have all permissions added that are required to make all state machine tasks execute properly (for example, permissions to invoke any Lambda functions you add to your workflow). A role will be created by default, but you can supply an existing one as well.

Amazon States Language

This library comes with a set of classes that model the Amazon States Language. The following State classes are supported:

• Task
• Pass
• Wait
• Choice
• Parallel
• Succeed
• Fail

An arbitrary JSON object (specified at execution start) is passed from state to state and transformed during the execution of the workflow. For more information, see the States Language spec.

Task

A Task represents some work that needs to be done. The exact work to be done is determine by a class that implements IStepFunctionsTask, a collection of which can be found in the @aws-cdk/aws-stepfunctions-tasks package. A couple of the tasks available are:

• tasks.InvokeActivity -- start an Activity (Activities represent a work queue that you poll on a compute fleet you manage yourself)
• tasks.InvokeFunction -- invoke a Lambda function with function ARN
• tasks.RunLambdaTask -- call Lambda as integrated service with magic ARN
• tasks.PublishToTopic -- publish a message to an SNS topic
• tasks.SendToQueue -- send a message to an SQS queue
• tasks.RunEcsFargateTask/ecs.RunEcsEc2Task -- run a container task, depending on the type of capacity.
• tasks.SagemakerTrainTask -- run a SageMaker training job
• tasks.SagemakerTransformTask -- run a SageMaker transform job
• tasks.StartExecution -- call StartExecution to a state machine of Step Functions

Except tasks.InvokeActivity and tasks.InvokeFunction, the service integration pattern (integrationPattern) are supposed to be given as parameter when customers want to call integrated services within a Task state. The default value is FIRE_AND_FORGET.

Task parameters from the state json

Many tasks take parameters. The values for those can either be supplied directly in the workflow definition (by specifying their values), or at runtime by passing a value obtained from the static functions on Data, such as Data.stringAt().

If so, the value is taken from the indicated location in the state JSON, similar to (for example) inputPath.

Lambda example - InvokeFunction

const task = new sfn.Task(this, 'Invoke1', {
    task: new tasks.InvokeFunction(myLambda),
    inputPath: '$.input',
    timeout: Duration.minutes(5),
});

// Add a retry policy
task.addRetry({
    interval: Duration.seconds(5),
    maxAttempts: 10
});

// Add an error handler
task.addCatch(errorHandlerState);

// Set the next state
task.next(nextState);

Lambda example - RunLambdaTask

  const task = new sfn.Task(stack, 'Invoke2', {
    task: new tasks.RunLambdaTask(myLambda, {
      integrationPattern: sfn.ServiceIntegrationPattern.WAIT_FOR_TASK_TOKEN,
      payload: {
        token: sfn.Context.taskToken
      }
    })
  });

SNS example

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

// ...

const topic = new sns.Topic(this, 'Topic');

// Use a field from the execution data as message.
const task1 = new sfn.Task(this, 'Publish1', {
    task: new tasks.PublishToTopic(topic, {
        integrationPattern: sfn.ServiceIntegrationPattern.FIRE_AND_FORGET,
        message: TaskInput.fromDataAt('$.state.message'),
    })
});

// Combine a field from the execution data with
// a literal object.
const task2 = new sfn.Task(this, 'Publish2', {
    task: new tasks.PublishToTopic(topic, {
        message: TaskInput.fromObject({
            field1: 'somedata',
            field2: Data.stringAt('$.field2'),
        })
    })
});

SQS example

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

// ...

const queue = new sns.Queue(this, 'Queue');

// Use a field from the execution data as message.
const task1 = new sfn.Task(this, 'Send1', {
    task: new tasks.SendToQueue(queue, {
        messageBody: TaskInput.fromDataAt('$.message'),
        // Only for FIFO queues
        messageGroupId: '1234'
    })
});

// Combine a field from the execution data with
// a literal object.
const task2 = new sfn.Task(this, 'Send2', {
    task: new tasks.SendToQueue(queue, {
        messageBody: TaskInput.fromObject({
            field1: 'somedata',
            field2: Data.stringAt('$.field2'),
        }),
        // Only for FIFO queues
        messageGroupId: '1234'
    })
});

ECS example

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

// See examples in ECS library for initialization of 'cluster' and 'taskDefinition'

const fargateTask = new ecs.RunEcsFargateTask({
  cluster,
  taskDefinition,
  containerOverrides: [
    {
      containerName: 'TheContainer',
      environment: [
        {
          name: 'CONTAINER_INPUT',
          value: Data.stringAt('$.valueFromStateData')
        }
      ]
    }
  ]
});

fargateTask.connections.allowToDefaultPort(rdsCluster, 'Read the database');

const task = new sfn.Task(this, 'CallFargate', {
    task: fargateTask
});

SageMaker Transform example

const transformJob = new tasks.SagemakerTransformTask(
    transformJobName: "MyTransformJob",
    modelName: "MyModelName",
    role,
    transformInput: {
        transformDataSource: {
            s3DataSource: {
                s3Uri: 's3://inputbucket/train',
                s3DataType: S3DataType.S3Prefix,
            }
        }
    },
    transformOutput: {
        s3OutputPath: 's3://outputbucket/TransformJobOutputPath',
    },
    transformResources: {
        instanceCount: 1,
        instanceType: ec2.InstanceType.of(ec2.InstanceClass.M4, ec2.InstanceSize.XLarge),
});

const task = new sfn.Task(this, 'Batch Inference', {
    task: transformJob
});

Step Functions example

// Define a state machine with one Pass state
const child = new sfn.StateMachine(stack, 'ChildStateMachine', {
    definition: sfn.Chain.start(new sfn.Pass(stack, 'PassState')),
});

// Include the state machine in a Task state with callback pattern
const task = new sfn.Task(stack, 'ChildTask', {
  task: new tasks.ExecuteStateMachine(child, {
    integrationPattern: sfn.ServiceIntegrationPattern.WAIT_FOR_TASK_TOKEN,
    input: {
      token: sfn.Context.taskToken,
      foo: 'bar'
    },
    name: 'MyExecutionName'
  })
});

// Define a second state machine with the Task state above
new sfn.StateMachine(stack, 'ParentStateMachine', {
  definition: task
});

Pass

A Pass state does no work, but it can optionally transform the execution's JSON state.

// Makes the current JSON state { ..., "subObject": { "hello": "world" } }
const pass = new stepfunctions.Pass(this, 'Add Hello World', {
    result: { hello: "world" },
    resultPath: '$.subObject',
});

// Set the next state
pass.next(nextState);

Wait

A Wait state waits for a given number of seconds, or until the current time hits a particular time. The time to wait may be taken from the execution's JSON state.

// Wait until it's the time mentioned in the the state object's "triggerTime"
// field.
const wait = new stepfunctions.Wait(this, 'Wait For Trigger Time', {
    duration: stepfunctions.WaitDuration.timestampPath('$.triggerTime'),
});

// Set the next state
wait.next(startTheWork);

Choice

A Choice state can take a differen path through the workflow based on the values in the execution's JSON state:

const choice = new stepfunctions.Choice(this, 'Did it work?');

// Add conditions with .when()
choice.when(stepfunctions.Condition.stringEqual('$.status', 'SUCCESS'), successState);
choice.when(stepfunctions.Condition.numberGreaterThan('$.attempts', 5), failureState);

// Use .otherwise() to indicate what should be done if none of the conditions match
choice.otherwise(tryAgainState);

If you want to temporarily branch your workflow based on a condition, but have all branches come together and continuing as one (similar to how an if ... then ... else works in a programming language), use the .afterwards() method:

const choice = new stepfunctions.Choice(this, 'What color is it?');
choice.when(stepfunctions.Condition.stringEqual('$.color', 'BLUE'), handleBlueItem);
choice.when(stepfunctions.Condition.stringEqual('$.color', 'RED'), handleRedItem);
choice.otherwise(handleOtherItemColor);

// Use .afterwards() to join all possible paths back together and continue
choice.afterwards().next(shipTheItem);

If your Choice doesn't have an otherwise() and none of the conditions match the JSON state, a NoChoiceMatched error will be thrown. Wrap the state machine in a Parallel state if you want to catch and recover from this.

Parallel

A Parallel state executes one or more subworkflows in parallel. It can also be used to catch and recover from errors in subworkflows.

const parallel = new stepfunctions.Parallel(this, 'Do the work in parallel');

// Add branches to be executed in parallel
parallel.branch(shipItem);
parallel.branch(sendInvoice);
parallel.branch(restock);

// Retry the whole workflow if something goes wrong
parallel.addRetry({ maxAttempts: 1 });

// How to recover from errors
parallel.addCatch(sendFailureNotification);

// What to do in case everything succeeded
parallel.next(closeOrder);

Succeed

Reaching a Succeed state terminates the state machine execution with a succesful status.

const success = new stepfunctions.Succeed(this, 'We did it!');

Fail

Reaching a Fail state terminates the state machine execution with a failure status. The fail state should report the reason for the failure. Failures can be caught by encompassing Parallel states.

const success = new stepfunctions.Fail(this, 'Fail', {
    error: 'WorkflowFailure',
    cause: "Something went wrong"
});

Task Chaining

To make defining work flows as convenient (and readable in a top-to-bottom way) as writing regular programs, it is possible to chain most methods invocations. In particular, the .next() method can be repeated. The result of a series of .next() calls is called a Chain, and can be used when defining the jump targets of Choice.on or Parallel.branch:

const definition = step1
    .next(step2)
    .next(choice
        .when(condition1, step3.next(step4).next(step5))
        .otherwise(step6)
        .afterwards())
    .next(parallel
        .branch(step7.next(step8))
        .branch(step9.next(step10)))
    .next(finish);

new stepfunctions.StateMachine(this, 'StateMachine', {
    definition,
});

If you don't like the visual look of starting a chain directly off the first step, you can use Chain.start:

const definition = stepfunctions.Chain
    .start(step1)
    .next(step2)
    .next(step3)
    // ...

State Machine Fragments

It is possible to define reusable (or abstracted) mini-state machines by defining a construct that implements IChainable, which requires you to define two fields:

• startState: State, representing the entry point into this state machine.
• endStates: INextable[], representing the (one or more) states that outgoing transitions will be added to if you chain onto the fragment.

Since states will be named after their construct IDs, you may need to prefix the IDs of states if you plan to instantiate the same state machine fragment multiples times (otherwise all states in every instantiation would have the same name).

The class StateMachineFragment contains some helper functions (like prefixStates()) to make it easier for you to do this. If you define your state machine as a subclass of this, it will be convenient to use:

interface MyJobProps {
    jobFlavor: string;
}

class MyJob extends stepfunctions.StateMachineFragment {
    public readonly startState: State;
    public readonly endStates: INextable[];

    constructor(parent: cdk.Construct, id: string, props: MyJobProps) {
        super(parent, id);

        const first = new stepfunctions.Task(this, 'First', { ... });
        // ...
        const last = new stepfunctions.Task(this, 'Last', { ... });

        this.startState = first;
        this.endStates = [last];
    }
}

// Do 3 different variants of MyJob in parallel
new stepfunctions.Parallel(this, 'All jobs')
    .branch(new MyJob(this, 'Quick', { jobFlavor: 'quick' }).prefixStates())
    .branch(new MyJob(this, 'Medium', { jobFlavor: 'medium' }).prefixStates())
    .branch(new MyJob(this, 'Slow', { jobFlavor: 'slow' }).prefixStates());

Activity

Activities represent work that is done on some non-Lambda worker pool. The Step Functions workflow will submit work to this Activity, and a worker pool that you run yourself, probably on EC2, will pull jobs from the Activity and submit the results of individual jobs back.

You need the ARN to do so, so if you use Activities be sure to pass the Activity ARN into your worker pool:

const activity = new stepfunctions.Activity(this, 'Activity');

// Read this CloudFormation Output from your application and use it to poll for work on
// the activity.
new cdk.CfnOutput(this, 'ActivityArn', { value: activity.activityArn });

Metrics

Task object expose various metrics on the execution of that particular task. For example, to create an alarm on a particular task failing:

new cloudwatch.Alarm(this, 'TaskAlarm', {
    metric: task.metricFailed(),
    threshold: 1,
    evaluationPeriods: 1,
});

There are also metrics on the complete state machine:

new cloudwatch.Alarm(this, 'StateMachineAlarm', {
    metric: stateMachine.metricFailed(),
    threshold: 1,
    evaluationPeriods: 1,
});

And there are metrics on the capacity of all state machines in your account:

new cloudwatch.Alarm(this, 'ThrottledAlarm', {
    metric: StateTransitionMetrics.metricThrottledEvents(),
    threshold: 10,
    evaluationPeriods: 2,
});

Future work

Contributions welcome:

• A single LambdaTask class that is both a Lambda and a Task in one might make for a nice API.
• Expression parser for Conditions.
• Simulate state machines in unit tests.