Tag Archives: AWS Lambda

AWS Week in Review – October 3, 2022

Post Syndicated from Danilo Poccia original https://aws.amazon.com/blogs/aws/aws-week-in-review-october-3-2022/

This post is part of our Week in Review series. Check back each week for a quick roundup of interesting news and announcements from AWS!

A new week and a new month just started. Curious which were the most significant AWS news from the previous seven days? I got you covered with this post.

Last Week’s Launches
Here are the launches that got my attention last week:

Amazon File Cache – A high performance cache on AWS that accelerates and simplifies demanding cloud bursting and hybrid workflows by giving access to files using a fast and familiar POSIX interface, no matter if the original files live on premises on any file system that can be accessed through NFS v3 or on S3.

Amazon Data Lifecycle Manager – You can now automatically archive Amazon EBS snapshots to save up to 75 percent on storage costs for those EBS snapshots that you intend to retain for more than 90 days and rarely access.

AWS App Runner – You can now build and run web applications and APIs from source code using the new Node.js 16 managed runtime.

AWS Copilot – The CLI for containerized apps adds IAM permission boundaries, support for FIFO SNS/SQS for the Copilot worker-service pattern, and using Amazon CloudFront for low-latency content delivery and fast TLS-termination for public load-balanced web services.

Bottlerocket – The Linux-based operating system purpose-built to run container workloads is now supported by Amazon Inspector. Amazon Inspector can now recommend an update of Bottlerocket if it finds a vulnerability.

Amazon SageMaker Canvas – Now supports mathematical functions and operators for richer data exploration and to understand the relationships between variables in your data.

AWS Compute Optimizer – Now provides cost and performance optimization recommendations for 37 new EC2 instance types, including bare metal instances (m6g.metal) and compute optimized instances (c7g.2xlarge, hpc6a.48xlarge), and new memory metrics for Windows instances.

AWS Budgets – Use a simplified 1-click workflow for common budgeting scenarios with step-by-step tutorials on how to use each template.

Amazon Connect – Now provides an updated flow designer UI that makes it easier and faster to build personalized and automated end-customer experiences, as well as a queue dashboard to view and compare real-time queue performance through time series graphs.

Amazon WorkSpaces – You can now provision Ubuntu desktops and use virtual desktops for new categories of workloads, such as for your developers, engineers, and data scientists.

Amazon WorkSpaces Core – A fully managed infrastructure-only solution for third-party Virtual Desktop Infrastructure (VDI) management software that simplifies VDI migration and combines your current VDI software with the security and reliability of AWS. Read more about it in this Desktop and Application Streaming blog post.

For a full list of AWS announcements, be sure to keep an eye on the What’s New at AWS page.

Other AWS News
A few more blog posts you might have missed:

Introducing new language extensions in AWS CloudFormation – In this Cloud Operations & Migrations blog post, we introduce the new language transform that enhances CloudFormation core language with intrinsic functions that simplify handling JSON strings (Fn::ToJsonString), array lengths (Fn::Length), and update and deletion policies.

Building a GraphQL API with Java and AWS Lambda – This blog shows different options for resolving GraphQL queries using serverless technologies on AWS.

For AWS open-source news and updates, here’s the latest newsletter curated by Ricardo to bring you the most recent updates on open-source projects, posts, events, and more.

Upcoming AWS Events
As usual, there are many opportunities to meet:

AWS Summits– Connect, collaborate, and learn about AWS at these free in-person events: Bogotá (October 4), and Singapore (October 6).

AWS Community DaysAWS Community Day events are community-led conferences to share and learn together. Join us in Amersfoort, Netherlands (on October 3, today), Warsaw, Poland (October 14), and Dresden, Germany (October 19).

That’s all from me for this week. Come back next Monday for another Week in Review!

Danilo

Amazon Personalize customer outreach on your ecommerce platform

Post Syndicated from Sridhar Chevendra original https://aws.amazon.com/blogs/architecture/amazon-personalize-customer-outreach-on-your-ecommerce-platform/

In the past, brick-and-mortar retailers leveraged native marketing and advertisement channels to engage with consumers. They have promoted their products and services through TV commercials, and magazine and newspaper ads. Many of them have started using social media and digital advertisements. Although marketing approaches are beginning to modernize and expand to digital channels, businesses still depend on expensive marketing agencies and inefficient manual processes to measure campaign effectiveness and understand buyer behavior. The recent pandemic has forced many retailers to take their businesses online. Those who are ready to embrace these changes have embarked on a technological and digital transformation to connect to their customers. As a result, they have begun to see greater business success compared to their peers.

Digitizing a business can be a daunting task, due to lack of expertise and high infrastructure costs. By using Amazon Web Services (AWS), retailers are able to quickly deploy their products and services online with minimal overhead. They don’t have to manage their own infrastructure. With AWS, retailers have no upfront costs, have minimal operational overhead, and have access to enterprise-level capabilities that scale elastically, based on their customers’ demands. Retailers can gain a greater understanding of customers’ shopping behaviors and personal preferences. Then, they are able to conduct effective marketing and advertisement campaigns, and develop and measure customer outreach. This results in increased satisfaction, higher retention, and greater customer loyalty. With AWS you can manage your supply chain and directly influence your bottom line.

Building a personalized shopping experience

Let’s dive into the components involved in building this experience. The first step in a retailer’s digital transformation journey is to create an ecommerce platform for their customers. This platform enables the organization to capture their customers’ actions, also referred to as ‘events’. Some examples of events are clicking on the shopping site to browse product categories, searching for a particular product, adding an item to the shopping cart, and purchasing a product. Each of these events gives the organization information about their customer’s intent, which is invaluable in creating a personalized experience for that customer. For instance, if a customer is browsing the “baby products” category, it indicates their interest in that category even if a purchase is not made. These insights are typically difficult to capture in an in-store experience. Online shopping makes gaining this knowledge much more straightforward and scalable.

The proposed solution outlines the use of AWS services to create a digital experience for a retailer and consumers. The three key areas are: 1) capturing customer interactions, 2) making real-time recommendations using AWS managed Artificial Intelligence/Machine Learning (AI/ML) services, and 3) creating an analytics platform to detect patterns and adjust customer outreach campaigns. Figure 1 illustrates the solution architecture.

Digital shopping experience architecture

Figure 1. Digital shopping experience architecture

For this use case, let’s assume that you are the owner of a local pizzeria, and you manage deliveries through an ecommerce platform like Shopify or WooCommerce. We will walk you through how to best serve your customer with a personalized experience based on their preferences.

The proposed solution consists of the following components:

  1. Data collection
  2. Promotion campaigns
  3. Recommendation engine
  4. Data analytics
  5. Customer reachability

Let’s explore each of these components separately.

Data collection with Amazon Kinesis Data Streams

When a customer uses your web/mobile application to order a pizza, the application captures their activity as click-stream ‘events’. These events provide valuable insights about your customers’ behavior. You can use these insights to understand the trends and browsing pattern of prospects who visited your web/mobile app, and use the data collected for creating promotion campaigns. As your business scales, you’ll need a durable system to preserve these events against system failures, and scale based on unpredictable traffic on your platform.

Amazon Kinesis is a Multi-AZ, managed streaming service that provides resiliency, scalability, and durability to capture an unlimited number of events without any additional operational overhead. Using Kinesis producers (Kinesis Agent, Kinesis Producer Library, and the Kinesis API), you can configure applications to capture your customer activity. You can ingest these events from the frontend, and then publish them to Amazon Kinesis Data Streams.

Let us start by setting up Amazon Kinesis Data Streams to capture the real-time sales transactions from the online channels like a portal or mobile app. For this blog post, we have used the Kaggle’s public data set as a reference. Figure 2 illustrates a snapshot of sample data to build personalized recommendations for a customer.

Sample sales transaction data

Figure 2. Sample sales transaction data

Promotion campaigns with AWS Lambda

One way to increase customer conversion is by offering discounts. When the customer adds a pizza to their cart, you want to make sure they are receiving the best deal. Let’s assume that by adding an additional item, your customer will receive the best possible discount. Just by knowing the total cost of added items to the cart, you can provide these relevant promotions to this customer.

For this scenario, the AWS Lambda service polls the Amazon Kinesis Data Streams to read all the events in the stream. It then matches the events based on your criteria of items in the cart. In turn, these events will be processed by the Lambda function. The Lambda function will read your up-to-date promotions stored in Amazon DynamoDB. As an option, caching recent or most popular promotions will improve your application response time, as well as improve the customer experience on your platform. Amazon DynamoDB DAX is an integrated caching for DynamoDB that caches the most recent or popular promotions or items.

For example, when the customer added the items to their shopping cart, Lambda will send promotion details to them based on the purchase amount. This can be for free shipping or discount of a certain percentage. Figure 3 illustrates the snapshot of sample promotions.

Promotions table in DynamoDB

Figure 3. Promotions table in DynamoDB

Recommendations engine with Amazon Personalize

In addition to sharing these promotions with your customer, you may also want to share the recommended add-ons. In order to understand your customer preferences, you must gather historical datasets to determine patterns and generate relevant recommendations. Since web activity consists of millions of events, this would be a daunting task for humans to review, determine the patterns, and make recommendations. And since user preferences change, you need a system that can use all this volume of data and provide accurate predictions.

Amazon Personalize is a managed AI/ML service that will help you to train an ML model based on datasets. It provides an inference point for real-time recommendations prior to having ML experience. Based on the datasets, Amazon Personalize also provides recipes to generate recommendations. As your customers interact on the ecommerce platform, your frontend application calls Amazon Personalize inference endpoints. It then retrieves a set of personalized recommendations based on your customer preferences.

Here is the sample Python code to display the list of available recommenders, and associated recommendations.

import boto3
import json
client = boto3.client('personalize')

# Connect to the personalize runtime for the customer recommendations

recomm_endpoint = boto3.client('personalize-runtime')
response = recomm_endpoint.get_recommendations(itemId='79323P',
  recommenderArn='arn:aws:personalize:us-east-1::recommender/my-items',
  numResults=5)

print(json.dumps(response['itemList'], indent=2))

[
  {
    "itemId": "79323W"
  },
  {
    "itemId": "79323GR"
  },
  {
    "itemId": "79323LP"
  },
  {
  "itemId": "79323B"
  },
  {
    "itemId": "79323G"
  }
]

You can use Amazon Kinesis Data Firehose to read the data near real time from the Amazon Kinesis Data Streams collected the data from the front-end applications. Then you can store this data in Amazon Simple Storage Service (S3). Amazon S3 is peta-byte scale storage help you scale and acts as a repository and single source of truth. We use S3 data as seed data to build a personalized recommendation engine using Amazon Personalize. As your customers interact on the ecommerce platform, call the Amazon Personalize inference endpoint to make personalized recommendations based on user preferences.

Customer reachability with Amazon Pinpoint

If a customer adds products to their cart but never checks out, you may want to send them a reminder. You can set up an email to suggest they re-order after a period of time after their first order. Or you may want to send them promotions based on their preferences. And as your customers’ behavior changes, you probably want to adapt your messaging accordingly.

Your customer may have a communication preference, such as phone, email, SMS, or in-app notifications. If an order has an issue, you can inform the customer as soon as possible using their preferred method of communication, and perhaps follow it up with a discount.

Amazon Pinpoint is a flexible and scalable outbound and inbound marketing communications service. You can add users to Audience Segments, create reusable content templates integrated with Amazon Personalize, and run scheduled campaigns. With Amazon Pinpoint journeys, you can send action or time-based notifications to your users.

The following workflow shown in Figure 4, illustrates customer communication workflow for promotion. A journey is created for a cohort of college students: a “Free Drink” promotion is offered with a new order. You can send this promotion over email. If the student opens the email, you can immediately send them a push notification reminding them to place an order. But if they didn’t open this email, you could wait three days, and follow up with a text message.

Promotion workflow in Amazon Pinpoint

Figure 4. Promotion workflow in Amazon Pinpoint

Data analytics with Amazon Athena and Amazon QuickSight

To understand the effectiveness of your campaigns, you can use S3 data as a source for Amazon Athena. Athena is an interactive query service that analyzes data in Amazon S3 using standard SQL. Athena is serverless, so there is no infrastructure to manage, and you pay only for the queries that you run.

There are different ways to create visualizations in Amazon QuickSight. For instance, you can use Amazon S3 as a data lake. One option is to import your data into SPICE (Super-fast, Parallel, In-memory Calculation Engine) to provide high performance and concurrency. You can also create a direct connection to the underlying data source. For this use case, we choose to import to SPICE, which provides faster visualization in a production setup. Schedule consistent refreshes to help ensure that dashboards are referring to the most current data.

Once your data is imported to your SPICE, review QuickSight’s visualization dashboard. Here, you’ll be able to choose from a wide variety of charts and tables, while adding interactive features like drill downs and filters.

The process following illustrates how to create a customer outreach strategy using ZIP codes, and allocate budgets to the marketing campaigns accordingly. First, we use this sample SQL command that we ran in Athena to query for top 10 pizza providers. The results are shown in Figure 5.

SELECT name, count(*) as total_count FROM "analyticsdemodb"."fooddatauswest2"
group by name
order by total_count desc
limit 10

Athena query results for top 10 pizza providers

Figure 5. Athena query results for top 10 pizza providers

Second, here is the sample SQL command that we ran in Athena to find Total pizza counts by postal code (ZIP code). Figure 6 shows a visualization to help create customer outreach strategy per ZIP codes and budget the marketing campaigns accordingly.

SELECT postalcode, count(*) as total_count FROM "analyticsdemodb"."fooddatauswest2"
where postalcode is not null
group by postalcode
order by total_count desc limit 50;

QuickSight visualization showing pizza orders by zip codes

Figure 6. QuickSight visualization showing pizza orders by zip codes

Conclusion

AWS enables you to build an ecommerce platform and scale your existing business with minimal operational overhead and no upfront costs. You can augment your ecommerce platform by building personalized recommendations and effective marketing campaigns based on your customer needs. The solution approach provided in the blog will help organizations build re-usable architecture pattern and personalization using AWS managed services.

Let’s Architect! Architecting with custom chips and accelerators

Post Syndicated from Luca Mezzalira original https://aws.amazon.com/blogs/architecture/lets-architect-custom-chips-and-accelerators/

It’s hard to imagine a world without computer chips. They are at the heart of the devices that we use to work and play every day. Currently, Amazon Web Services (AWS) is offering customers the next generation of computer chip, with lower cost, higher performance, and a reduced carbon footprint.

This edition of Let’s Architect! focuses on custom computer chips, accelerators, and technologies developed by AWS, such as AWS Nitro System, custom-designed Arm-based AWS Graviton processors that support data-intensive workloads, as well as AWS Trainium, and AWS Inferentia chips optimized for machine learning training and inference.

In this post, we discuss these new AWS technologies, their main characteristics, and how to take advantage of them in your architecture.

Deliver high performance ML inference with AWS Inferentia

As Deep Learning models become increasingly large and complex, the training cost for these models increases, as well as the inference time for serving.

With AWS Inferentia, machine learning practitioners can deploy complex neural-network models that are built and trained on popular frameworks, such as Tensorflow, PyTorch, and MXNet on AWS Inferentia-based Amazon EC2 Inf1 instances.

This video introduces you to the main concepts of AWS Inferentia, a service designed to reduce both cost and latency for inference. To speed up inference, AWS Inferentia: selects and shares a model across multiple chips, places pieces inside the on-chip cache, then streams the data via pipeline for low-latency predictions.

Presenters discuss through the structure of the chip, software considerations, as well as anecdotes from the Amazon Alexa team, who uses AWS Inferentia to serve predictions. If you want to learn more about high throughput coupled with low latency, explore Achieve 12x higher throughput and lowest latency for PyTorch Natural Language Processing applications out-of-the-box on AWS Inferentia on the AWS Machine Learning Blog.

AWS Inferentia shares a model across different chips to speed up inference

AWS Inferentia shares a model across different chips to speed up inference

AWS Lambda Functions Powered by AWS Graviton2 Processor – Run Your Functions on Arm and Get Up to 34% Better Price Performance

AWS Lambda is a serverless, event-driven compute service that enables code to run from virtually any type of application or backend service, without provisioning or managing servers. Lambda uses a high-availability compute infrastructure and performs all of the administration of the compute resources, including server- and operating-system maintenance, capacity-provisioning, and automatic scaling and logging.

AWS Graviton processors are designed to deliver the best price and performance for cloud workloads. AWS Graviton3 processors are the latest in the AWS Graviton processor family and provide up to: 25% increased compute performance, two-times higher floating-point performance, and two-times faster cryptographic workload performance compared with AWS Graviton2 processors. This means you can migrate AWS Lambda functions to Graviton in minutes, plus get as much as 19% improved performance at approximately 20% lower cost (compared with x86).

Comparison between x86 and Arm/Graviton2 results for the AWS Lambda function computing prime numbers

Comparison between x86 and Arm/Graviton2 results for the AWS Lambda function computing prime numbers (click to enlarge)

Powering next-gen Amazon EC2: Deep dive on the Nitro System

The AWS Nitro System is a collection of building-block technologies that includes AWS-built hardware offload and security components. It is powering the next generation of Amazon EC2 instances, with a broadening selection of compute, storage, memory, and networking options.

In this session, dive deep into the Nitro System, reviewing its design and architecture, exploring new innovations to the Nitro platform, and understanding how it allows for fasting innovation and increased security while reducing costs.

Traditionally, hypervisors protect the physical hardware and bios; virtualize the CPU, storage, networking; and provide a rich set of management capabilities. With the AWS Nitro System, AWS breaks apart those functions and offloads them to dedicated hardware and software.

AWS Nitro System separates functions and offloads them to dedicated hardware and software, in place of a traditional hypervisor

AWS Nitro System separates functions and offloads them to dedicated hardware and software, in place of a traditional hypervisor

How Amazon migrated a large ecommerce platform to AWS Graviton

In this re:Invent 2021 session, we learn about the benefits Amazon’s ecommerce Datapath platform has realized with AWS Graviton.

With a range of 25%-40% performance gains across 53,000 Amazon EC2 instances worldwide for Prime Day 2021, the Datapath team is lowering their internal costs with AWS Graviton’s improved price performance. Explore the software updates that were required to achieve this and the testing approach used to optimize and validate the deployments. Finally, learn about the Datapath team’s migration approach that was used for their production deployment.

AWS Graviton2: core components

AWS Graviton2: core components

See you next time!

Thanks for exploring custom computer chips, accelerators, and technologies developed by AWS. Join us in a couple of weeks when we talk more about architectures and the daily challenges faced while working with distributed systems.

Other posts in this series

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Lifting and shifting a web application to AWS Serverless: Part 2

Post Syndicated from Marcia Villalba original https://aws.amazon.com/blogs/compute/lifting-and-shifting-a-web-application-to-aws-serverless-part-2/

In part 1, you learn if it is possible to migrate a non-serverless web application to a serverless environment without changing much code. You learn different tools that can help you in this process, like Lambda Web Adaptor and AWS Amplify. By the end, you have migrated an application into a serverless environment.

However, if you test the migrated app, you find two issues. The first one is that the user session is not sticky. Every time you log in, you are logged out unexpectedly from the application. The second one is that when you create a new product, you cannot upload new images of that product.

This final post analyzes each of the problems in detail and shows solutions. In addition, it analyzes the cost and performance of the solution.

Authentication and authorization migration

The original application handled the authentication and authorization by itself. There is a user directory in the database, with the passwords and emails for each of the users. There are APIs and middleware that take care of validating that the user is logged in before showing the application. All the logic for this is developed inside the Node.js/Express application.

However, with the current migrated application every time you log in, you are logged out unexpectedly from the application. This is because the server code is responsible for handling the authentication and the authorization of the users, and now our server is running in an AWS Lambda function and functions are stateless. This means that there will be one function running per request—a request can load all the products in the landing page, get the details for a product, or log in to the site—and if you do something in one of these functions, the state is not shared across.

To solve this, you must remove the authentication and authorization mechanisms from the function and use a service that can preserve the state across multiple invocations of the functions.

There are many ways to solve this challenge. You can add a layer of authentication and session management with a database like Redis, or build a new microservice that is in charge of authentication and authorization that can handle the state, or use an existing managed service for this.

Because of the migration requirements, we want to keep the cost as low as possible, with the fewest changes to the application. The better solution is to use an existing managed service to handle authentication and authorization.

This demo uses Amazon Cognito, which provides user authentication and authorization to AWS resources in a managed, pay as you go way. One rapid approach is to replace all the server code with calls to Amazon Cognito using the AWS SDK. But this adds complexity that can be replaced completely by just invoking Amazon Cognito APIs from the React application.

Using Cognito

For example, when a new user is registered, the application creates the user in the Amazon Cognito user pool directory, as well as in the application database. But when a user logs in to the web app, the application calls Amazon Cognito API directly from the AWS Amplify application. This way minimizes the amount of code needed.

In the original application, all authenticated server APIs are secured with a middleware that validates that the user is authenticated by providing an access token. With the new setup that doesn’t change, but the token is generated by Amazon Cognito and then it can be validated in the backend.

let auth = (req, res, next) => {
    const token = req.headers.authorization;
    const jwtToken = token.replace('Bearer ', '');

    verifyToken(jwtToken)
        .then((valid) => {
            if (valid) {
                getCognitoUser(jwtToken).then((email) => {
                    User.findByEmail(email, (err, user) => {
                        if (err) throw err;
                        if (!user)
                            return res.json({
                                isAuth: false,
                                error: true,
                            });

                        req.user = user;
                        next();
                    });
                });
            } else {
                throw Error('Not valid Token');
            }
        })
        .catch((error) => {
            return res.json({
                isAuth: false,
                error: true,
            });
        });
};

You can see how this is implemented step by step in this video.

Storage migration

In the original application, when a new product is created, a new image is uploaded to the Node.js/Express server. However, now the application resides in a Lambda function. The code (and files) that are part of that function cannot change, unless the function is redeployed. Consequently, you must separate the user storage from the server code.

For doing this, there are a couple of solutions: using Amazon Elastic File System (EFS) or Amazon S3. EFS is a file storage, and you can use that to have a dynamic storage where you upload the new images. Using EFS won’t change much of the code, as the original implementation is using a directory inside the server as EFS provides. However, using EFS adds more complexity to the application, as functions that use EFS must be inside an Amazon Virtual Private Cloud (Amazon VPC).

Using S3 to upload your images to the application is simpler, as it only requires that an S3 bucket exists. For doing this, you must refactor the application, from uploading the image to the application API to use the AWS Amplify library that uploads and gets images from S3.

export function uploadImage(file) {
    const fileName = `uploads/${file.name}`;

    const request = Storage.put(fileName, file).then((result) => {
        return {
            image: fileName,
            success: true,
        };
    });

    return {
        type: IMAGE_UPLOAD,
        payload: request,
    };
}

An important benefit of using S3 is that you can also use Amazon CloudFront to accelerate the retrieval of the images from the cloud. In this way, you can speed up the loading time of your page. You can see how this is implemented step by step in this video.

How much does this application cost?

If you deploy this application in an empty AWS account, most of the usage of this application is covered by the AWS Free Tier. Serverless services, like Lambda and Amazon Cognito, have a forever free tier that gives you the benefits in pricing for the lifetime of hosting the application.

  • AWS Lambda—With 100 requests per hour, an average 10ms invocation and 1GB of memory configured, it costs 0 USD per month.
  • Amazon S3—Using S3 standard, hosting 1 GB per month and 10k PUT and GET requests per month costs 0.07 USD per month. This can be optimized using S3 Intelligent-Tiering.
  • Amazon Cognito—Provides 50,000 monthly active users for free.
  • AWS Amplify—If you build your client application once a week, serve 3 GB and store 1 GB per month, this costs 0.87 USD.
  • AWS Secrets Manager—There are two secrets stored using Secrets Manager and this costs 1.16 USD per month. This can be optimized by using AWS System Manager Parameter Store and AWS Key Management Service (AWS KMS).
  • MongoDB Atlas Forever free shared cluster.

The total monthly cost of this application is approximately 2.11 USD.

Performance analysis

After you migrate the application, you can run a page speed insight tool, to measure this application’s performance. This tool provides results mostly about the front end and the experience that the user perceives. The results are displayed in the following image. The performance of this website is good, according to the insight tool performance score – it responds quickly and the user experience is good.

Page speed insight tool results

After the application is migrated to a serverless environment, you can do some refactoring to improve further the overall performance. One alternative is whenever a new image is uploaded, it gets resized and formatted into the correct next-gen format automatically using the event driven capabilities that S3 provides. Another alternative is to use Lambda on Edge to serve the right image size for the device, as it is possible to format the images on the fly when serving them from a distribution.

You can run load tests for understanding how your backend and database will perform. For this, you can use Artillery, an open-source library that allows you to run load tests. You can run tests with the expected maximum load your site will get and ensure that your site can handle it.

For example, you can configure a test that sends 30 requests per seconds to see how your application reacts:

config:
  target: 'https://xxx.lambda-url.eu-west-1.on.aws'
  phases:
    - duration: 240
      arrivalRate: 30
      name: Testing
scenarios:
  - name: 'Test main page'
    flow:
      - post:
          url: '/api/product/getProducts/'

This test is performed on the backend APIs, not only testing your backend but also your integration with the MongoDB. After running it, you can see how the Lambda function performs on the Amazon CloudWatch dashboard.

Running this load test helps you understand the limitations of your system. For example, if you run a test with too many concurrent users, you might see that the number of throttles in your function increases. This means that you need to lift the limit of invocations of the functions you can have at the same time.

Or when increasing the requests per second, you may find that the MongoDB cluster starts throttling your requests. This is because you are using the free tier and that has a set number of connections. You might need a larger cluster or to migrate your database to another service that provides a large free tier, like Amazon DynamoDB.

Cloudwatch dashboard

Conclusion

In this two-part article, you learn if it is possible to migrate a non-serverless web application to a serverless environment without changing much code. You learn different tools that can help you in this process, like AWS Lambda Web Adaptor and AWS Amplify, and how to solve some of the typical challenges that we have, like storage and authentication.

After the application is hosted in a fully serverless environment, it can scale up and down to meet your needs. This web application is also performant once the backend is hosted in a Lambda function.

If you need, from here you can start using the strangler pattern to refactor the application to take advantage of the benefits of event-driven architecture.

To see all the steps of the migration, there is a playlist that contains all the tutorials for you to follow.

For more serverless learning resources, visit Serverless Land.

Lifting and shifting a web application to AWS Serverless: Part 1

Post Syndicated from Marcia Villalba original https://aws.amazon.com/blogs/compute/lifting-and-shifting-a-web-application-to-aws-serverless-part-1/

Customers migrating to the cloud often want to get the benefits of serverless architecture. But what is the best approach and is it possible? There are many strategies to do a migration, but lift and shift is often the fastest way to get to production with the migrated workload.

You might also wonder if it’s possible to lift and shift an existing application that runs in a traditional environment to serverless. This blog post shows how to do this for a Mongo, Express, React, and Node.js (MERN) stack web app. However, the discussions presented in this post apply to other stacks too.

Why do a lift and shift migration?

Lift and shift, or sometimes referred to as rehosting the application, is moving the application with as few changes as possible. Lift and shift migrations often allow you to get the new workload in production as fast as possible. When migrating to serverless, lift and shift can bring a workload that is not yet in the cloud or in a serverless environment to use managed and serverless services quickly.

Migrating a non-serverless workload to serverless with lift and shift might not bring all the serverless benefits right away, but it enables the development team to refactor, using the strangler pattern, the parts of the application that might benefit from what serverless technologies offer.

Why migrate a web app to serverless?

Web apps hosted in a serverless environment benefit most from the capability of serverless applications to scale automatically and for paying for what you use.

Imagine that you have a personal web app with little traffic. If you are hosting in a serverless environment, you don’t pay a fixed price to have the servers up and running. Your web app has only a few requests and the rest of the time is idle.

This benefit applies to the opposite case. For an owner of a small ecommerce site running on a server, imagine if a social media influencer with millions of followers recommends one of their products. Suddenly, thousands of requests arrive and make the site unavailable. If the site is hosted on a serverless platform, the application will scale to the traffic that it receives.

Requirements for migration

Before starting a migration, it is important to define the nonfunctional requirements that you need the new application to have. These requirements help when you must make architectural decisions during the migration process.

These are the nonfunctional requirements of this migration:

  • Environment that scales to zero and scales up automatically.
  • Pay as little as possible for idle time.
  • Configure as little infrastructure as possible.
  • Automatic high availability of the application.
  • Minimal changes to the original code.

Application overview

This blog post guides you on how to migrate a MERN application. The original application is hosted in two different servers: One contains the Mongo database and another contains the Node/js/Express and ReactJS applications.

Application overview

This demo application simulates a swag ecommerce site. The database layer stores the products, users, and the purchases history. The server layer takes care of the ecommerce business logic, hosting the product images, and user authentication and authorization. The web layer takes care of all the user interaction and communicates with the server layer using REST APIs.

How the application looks like

These are the changes that you must make to migrate to a serverless environment:

  • Database migration: Migrate the database from on-premises to MongoDB Atlas.
  • Backend migration: Migrate the NodeJS/Express application from on-premises to an AWS Lambda function.
  • Web app migration: Migrate the React web app from on-premises to AWS Amplify.
  • Authentication migration: Migrate the custom-built authentication to use Amazon Cognito.
  • Storage migration: Migrate the local storage of images to use Amazon S3 and Amazon CloudFront.

The following image shows the proposed solution for the migrated application:

Proposed architecture

Database migration

The database is already in a MongoDB vanilla container that has all the data for this application. As MongoDB is the database engine for our stack, their recommended solution to migrate to serverless is to use MongoDB Atlas. Atlas provides a database cluster in the cloud that scales automatically and you pay for what you use.

To get started, create a new Atlas cluster, then migrate the data from the existing database to the serverless one. To migrate the data, you can first dump all the content of the database to a dump folder and then restore it to the cloud:

mongodump --uri="mongodb://<localuser>:<localpassword>@localhost:27017"

mongorestore --uri="mongodb+srv://<user>:<password>@<clustername>.debkm.mongodb.net" .

After doing that, your data is now in the cloud. The next step is to change the configuration string in the server to point to the new database. To see this in action, check this video that shows a walkthrough of the migration.

Backend migration

Migrating the Node.js/Express backend is the most challenging of the layers to migrate to a serverless environment, as the server layer is a Node.js application that runs in a server.

One option for this migration is to use AWS Fargate. Fargate is a serverless container service that allows you to scale automatically and you pay as you go. Another option is to use AWS AppRunner, a container service that auto scales and you also pay as you go. However, neither of these options align with our migration requirements, as they don’t scale to zero.

Another option for the lift and shift migration of this Node.js application is to use Lambda with the AWS Lambda Web Adapter. The AWS Lambda Web Adapter is an open-source project that allows you to build web applications with familiar frameworks, like Express.js, Flask, SpringBoot, and run it on Lambda. You can learn more about this project in its GitHub repository.

Lambda Web Adapter

Using this project, you can create a new Lambda function that has the Express/NodeJS application as the function code. You can lift and shift all the code into the function. If you want a step-by-step tutorial on how to do this, check out this video.

const lambdaAdapterFunction = new Function(this,`${props.stage}-LambdaAdapterFunction`,
            {
                runtime: Runtime.NODEJS_16_X,
                code: Code.fromAsset('backend-app'),
                handler: 'run.sh',
                environment: {
                    AWS_LAMBDA_EXEC_WRAPPER: '/opt/bootstrap',
                    REGION: this.region,
                    ASYNC_INIT: 'true',
                },
                memorySize: 1024,
                layers: [layerLambdaAdapter],
                timeout: Duration.seconds(2),
                tracing: Tracing.ACTIVE,
            }
        );

The next step is to create an HTTP endpoint for the server application. There are three options for doing this: API Gateway, Application Load Balancer (ALB) , or to use Lambda Function URLs. All the options are compatible with Lambda Web Adapter and can solve the challenge for you.

For this demo, choose function URLs, as they are simple to configure and one function URL forwards all routes to the Express server. API Gateway and ALB require more configuration and have separate costs, while the cost of function URLs is included in the Lambda function.

Web app migration

The final layer to migrate is the React application. The best way to migrate the web layer and to adhere to the migration requirements is to use AWS Amplify to host it. AWS Amplify is a fully managed service that provides many features like hosting web applications and managing the CICD process for the web app. It provides client libraries to connect to different AWS resources, and many other features.

Migrating the React application is as simple as creating a new Amplify application in your AWS account and uploading the React application to a code repository like GitHub. This AWS Amplify application is connected to a GitHub branch, and when there is a new commit in this branch, AWS Amplify redeploys the code.

The Amplify application receives configuration parameters like the function URL endpoint (the server URL) using environmental variables.

const amplifyApp = new App(this, `${props.stage}-AmplifyReactShopApp`, {
            sourceCodeProvider: new GitHubSourceCodeProvider({
                owner: config.frontend.owner,
                repository: config.frontend.repository_name,
                oauthToken: SecretValue.secretsManager('github-token'),
            }),
            environmentVariables: {
                REGION: this.region,
                SERVER_URL: props.serverURL,
            },
        });

If you want to see a step-by-step guide on how to make your web layer serverless, you can check this video.

Next steps

However, if you test this migrated app, you will find two issues. The first one is that the user session is not sticky. Every time you log in, you are logged out unexpectedly from the application. The second one is that when you create a new product, you cannot upload new images of that product.

In part two, I analyze each of the problems in detail and find solutions. These issues arise because of the stateless and immutable characteristics of this solution. The next part of this article explains how to solve these issues, also it analyzes costs and performance of the solution.

Conclusion

In this article, you learn if it is possible to migrate a non-serverless web application to a serverless environment without changing much code. You learn different tools that can help you in this process, like the AWS Lambda Web Adaptor and AWS Amplify.

If you want to see the migration in action and learn all the steps for this, there is a playlist that contains all the tutorials for you to follow and learn how this is possible.

For more serverless learning resources, visit Serverless Land.

AWS Week in Review – September 5, 2022

Post Syndicated from Danilo Poccia original https://aws.amazon.com/blogs/aws/aws-week-in-review-september-5-2022/

This post is part of our Week in Review series. Check back each week for a quick roundup of interesting news and announcements from AWS!

As a new week begins, let’s quickly look back at the most significant AWS news from the previous seven days.

Last Week’s Launches
Here are the launches that got my attention last week:

AWS announces open-sourced credentials-fetcher to simplify Microsoft AD access from Linux containers. You can find more in the What’s New post.

AWS Step Functions now has 14 new intrinsic functions that help you process data more efficiently and make it easier to perform data processing tasks such as array manipulation, JSON object manipulation, and math functions within your workflows without having to invoke downstream services or add Task states.

AWS SAM CLI esbuild support is now generally available. You can now use esbuild in the SAM CLI build workflow for your JavaScript applications.

Amazon QuickSight launches a new user interface for dataset management that replaces the existing popup dialog modal with a full-page experience, providing a clearer breakdown of dataset management categories.

AWS GameKit adds Unity support. With this release for Unity, you can integrate cloud-based game features into Win64, MacOS, Android, or iOS games from both the Unreal and Unity engines with just a few clicks.

AWS and VMware announce VMware Cloud on AWS integration with Amazon FSx for NetApp ONTAP. Read more in Veliswa‘s blog post.

The AWS Region in the United Arab Emirates (UAE) is now open. More info in Marcia‘s blog post.

View of Abu Dhabi in the United Arab Emirates

For a full list of AWS announcements, be sure to keep an eye on the What’s New at AWS page.

Other AWS News
A few more blog posts you might have missed:

Easy analytics and cost-optimization with Amazon Redshift Serverless – Four different use cases of Redshift Serverless are discussed in this post.

Building cost-effective AWS Step Functions workflows – In this blog post, Ben explains the difference between Standard and Express Workflows, including costs, migrating from Standard to Express, and some interesting ways of using both together.

How to subscribe to the new Security Hub Announcements topic for Amazon SNS – You can now receive updates about new Security Hub services and features, newly supported standards and controls, and other Security Hub changes.

Deploying AWS Lambda functions using AWS Controllers for Kubernetes (ACK) – With the ACK service controller for AWS Lambda, you can provision and manage Lambda functions with kubectl and custom resources.

For AWS open-source news and updates, here’s the latest newsletter curated by Ricardo to bring you the most recent updates on open-source projects, posts, events, and more.

Upcoming AWS Events
Depending on where you are on this planet, there are many opportunities to meet and learn:

AWS Summits – Come together to connect, collaborate, and learn about AWS. Registration is open for the following in-person AWS Summits: Ottawa (September 8), New Delhi (September 9), Mexico City (September 21–22), Bogotá (October 4), and Singapore (October 6).

AWS Community DaysAWS Community Day events are community-led conferences to share and learn with one another. In September, the AWS community in the US will run events in the Bay Area, California (September 9) and Arlington, Virginia (September 30). In Europe, Community Day events will be held in October. Join us in Amersfoort, Netherlands (October 3), Warsaw, Poland (October 14), and Dresden, Germany (October 19).

That’s all from me for this week. Come back next Monday for another Week in Review!

Danilo

A multi-dimensional approach helps you proactively prepare for failures, Part 3: Operations and process resiliency

Post Syndicated from Piyali Kamra original https://aws.amazon.com/blogs/architecture/a-multi-dimensional-approach-helps-you-proactively-prepare-for-failures-part-3-operations-and-process-resiliency/

In Part 1 and Part 2 of this series, we discussed how to build application layer and infrastructure layer resiliency.

In Part 3, we explore how to develop resilient applications, and the need to test and break our operational processes and run books. Processes are needed to capture baseline metrics and boundary conditions. Detecting deviations from accepted baselines requires logging, distributed tracing, monitoring, and alerting. Testing automation and rollback are part of continuous integration/continuous deployment (CI/CD) pipelines. Keeping track of network, application, and system health requires automation.

In order to meet recovery time and point objective (RTO and RPO, respectively) requirements of distributed applications, we need automation to implement failover operations across multiple layers. Let’s explore how a distributed system’s operational resiliency needs to be addressed before it goes into production, after it’s live in production, and when a failure happens.

Pattern 1: Standardize and automate AWS account setup

Create processes and automation for onboarding users and providing access to AWS accounts according to their role and business unit, as defined by the organization. Federated access to AWS accounts and organizations simplifies cost management, security implementation, and visibility. Having a strategy for a suitable AWS account structure can reduce the blast radius in case of a compromise.

  1. Have auditing mechanisms in place. AWS CloudTrail monitors compliance, improving security posture, and auditing all the activity records across AWS accounts.
  2. Practice the least privilege security model when setting up access to the CloudTrail audit logs plus network and applications logs. Follow best practices on service control policies and IAM boundaries to help ensure your AWS accounts stay within your organization’s access control policies.
  3. Explore AWS Budgets, AWS Cost Anomaly Detection, and AWS Cost Explorer for cost-optimizing techniques. The AWS Compute Optimizer and Instance Scheduler on AWS resource resizing and auto-shutdown for non-working hours. A Beginner’s Guide to AWS Cost Management explores multiple cost-optimization techniques.
  4. Use AWS CloudFormation and AWS Config to detect infrastructure drift and take corrective actions to make resources compliant, as demonstrated in Figure 1.
Compliance control and drift detection

Figure 1. Compliance control and drift detection

Pattern 2: Documenting knowledge about the distributed system

Document high-level infrastructure and dependency maps.

Define availability characteristics of distributed system. Systems have components with varying RTO and RPO needs. Document application component boundaries and capture dependencies with other infrastructure components, including Domain Name System (DNS), IAM permissions; and access patterns, secrets, and certificates. Discover dependencies through solutions, such as Workload Discovery on AWS, to plan resiliency methods and ensure the order of execution of various steps during failover are correct.

Capture non-functional requirements (NFRs), such as business key performance indicators (KPIs), RTO, and RPO, for your composing services. NFRs are quantifiable and define system availability, reliability, and recoverability requirements. They should include throughput, page-load, and response time requirements. Quantify the RTO and RPO of different components of the distributed system by defining them. The KPIs measure if you are meeting the business objectives. As mentioned in Part 2: Infrastructure layer, RTO and RPO help define the failover and data recovery procedures.

Pattern 3: Define CI/CD pipelines for application code and infrastructure components

Establish a branching strategy. Implement automated checks for version and tagging compliance in feature/sprint/bug fix/hot fix/release candidate branches, according to your organization’s policies. Define appropriate release management processes and responsibility matrices, as demonstrated in Figures 2 and 3.

Test at all levels as part of an automated pipeline. This includes security, unit, and system testing. Create a feedback loop that provides the ability to detect issues and automate rollback in case of production failures, which are indicated by business KPI negative impact and other technical metrics.

Define the release management process

Figure 2. Define the release management process

Sample roles and responsibility matrix

Figure 3. Sample roles and responsibility matrix

Pattern 4: Keep code in a source control repository, regardless of GitOps

Merge requests and configuration changes follow the same process as application software. Just like application code, manage infrastructure as code (IaC) by checking the code into a source control repository, submitting pull requests, scanning code for vulnerabilities, alerting and sending notifications, running validation tests on deployments, and having an approval process.

You can audit your infrastructure drift, design reusable and repeatable patterns, and adhere to your distributed application’s RTO objectives by building your IaC (Figure 4). IaC is crucial for operational resilience.

CI/CD pipeline for deploying IaC

Figure 4. CI/CD pipeline for deploying IaC

Pattern 5: Immutable infrastructure

An immutable deployment pipeline launches a set of new instances running the new application version. You can customize immutability at different levels of granularity depending on which infrastructure part is being rebuilt for new application versions, as in Figure 5.

The more immutable infrastructure components being rebuilt, the more expensive deployments are in both deployment time and actual operational costs. Immutable infrastructure also is easier to rollback.

Different granularity levels of immutable infrastructure

Figure 5. Different granularity levels of immutable infrastructure

Pattern 6: Test early, test often

In a shift-left testing approach, begin testing in the early stages, as demonstrated in Figure 6. This can surface defects that can be resolved in a more time- and cost-effective manner compared with after code is released to production.

Shift-left test strategy

Figure 6. Shift-left test strategy

Continuous testing is an essential part of CI/CD. CI/CD pipelines can implement various levels of testing to reduce the likelihood of defects entering production. Testing can include: unit, functional, regression, load, and chaos.

Continuous testing requires testing and breaking existing boundary conditions, and updating test cases if the boundaries have changed. Test cases should test distributed systems’ idempotency. Chaos testing benefits our incidence response mechanisms for distributed systems that have multiple integration points. By testing our auto scaling and failover mechanisms, chaos testing improves application performance and resiliency.

AWS Fault Injection Simulator (AWS FIS) is a service for chaos testing. An experiment template contains actions, such as StopInstance and StartInstance, along with targets on which the test will be performed. In addition, you can mention stop conditions and check if they triggered the required Amazon CloudWatch alarms, as demonstrated in Figure 7.

AWS Fault Injection Simulator architecture for chaos testing

Figure 7. AWS Fault Injection Simulator architecture for chaos testing

Pattern 7: Providing operational visibility

In production, operational visibility across multiple dimensions is necessary for distributed systems (Figure 8). To identify performance bottlenecks and failures, use AWS X-Ray and other open-source libraries for distributed tracing.

Write application, infrastructure, and security logs to CloudWatch. When metrics breach alarm thresholds, integrate the corresponding alarms with Amazon Simple Notification Service or a third-party incident management system for notification.

Monitoring services, such as Amazon GuardDuty, are used to analyze CloudTrail, virtual private cloud flow logs, DNS logs, and Amazon Elastic Kubernetes Service audit logs to detect security issues. Monitor AWS Health Dashboard for maintenance, end-of-life, and service-level events that could affect your workloads. Follow the AWS Trusted Advisor recommendations to ensure your accounts follow best practices.

Dimensions for operational visibility

Figure 8. Dimensions for operational visibility (click the image to enlarge)

Figure 9 explores various application and infrastructure components integrating with AWS logging and monitoring components for increased problem detection and resolution, which can provide operational visibility.

Tooling architecture to provide operational visibility

Figure 9. Tooling architecture to provide operational visibility

Having an incident response management plan is an important mechanism for providing operational visibility. Successful execution of this requires educating the stakeholders on the AWS shared responsibility model, simulation of anticipated and unanticipated failures, documentation of the distributed system’s KPIs, and continuous iteration. Figure 10 demonstrates the features of a successful incidence response management plan.

An incidence response management plan

Figure 10. An incidence response management plan (click the image to enlarge)

Conclusion

In Part 3, we discussed continuous improvement of our processes by testing and breaking them. In order to understand the baseline level metrics, service-level agreements, and boundary conditions of our system, we need to capture NFRs. Operational capabilities are required to capture deviations from baseline, which is where alerting, logging, and distributed tracing come in. Processes should be defined for automating frequent testing in CI/CD pipelines, detecting network issues, and deploying alternate infrastructure stacks in failover regions based on RTOs and RPOs. Automating failover steps depends on metrics and alarms, and by using chaos testing, we can simulate failover scenarios.

Prepare for failure, and learn from it. Working to maintain resilience is an ongoing task.

Want to learn more?

Integrating Salesforce with AWS DynamoDB using Amazon AppFlow bi-directionally

Post Syndicated from Abhijit Vaidya original https://aws.amazon.com/blogs/architecture/integrating-salesforce-with-aws-dynamodb-using-amazon-appflow-bi-directionally/

In this blog post, we demonstrate how to integrate Salesforce Lightning with Amazon DynamoDB by using Amazon AppFlow and Amazon EventBridge services bi-directionally. This is an event-driven, serverless-based microservice, allowing Salesforce users to update configuration data stored in DynamoDB tables without giving AWS account access from AWS Command Line Interface or AWS Management Console.

This architecture describes a contact center application that utilizes DynamoDB database to store configuration data, including holiday data, across different global regions. Updating this data in a table is a manual process, which includes creating a support ticket and waiting for completion of the support request. The architecture herein allows authorized business users to update the configuration data in DynamoDB directly from the Salesforce screen and not relying on manual update process.

Solution overview

As demonstrated in Figure 1, Amazon AppFlow consumes events payload from salesforce and Lambda updates the DynamoDB table after processing the payload. In parallel, a scheduled based flow sends response back to salesforce object as a notification and sends a SNS email notification to users. Contact center application (Amazon Connect) reads data from DynamoDB table.

Architecture overview

Figure 1. Architecture overview

  1. Event (data add or delete) occurring on a particular object in Salesforce is captured by Amazon AppFlow (event-based flow); event payload displays as “Input” in AWS environment.
  2. An EventBridge bus receives the “Input” payload.
  3. The EventBridge bus triggers the AWS Lambda (Lambda-1).
  4. Lambda-1 processes the “Input” payload, then performs a write operation (data add or delete) on a DynamoDB table.
  5. A write operation on the table triggers DynamoDB streams.
  6. DynamoDB stream triggers Lambda (Lambda-2).
  7. Lambda-2 processes the payload from DynamoDB streams. It saves the results in .csv file format, with a “Success” or “Fail” flag. This .csv file is uploaded to an S3 bucket.
  8. A second flow (schedule-based) is configured in Amazon AppFlow. This reads the S3 bucket at a regular interval of time to find new .csv files created by Lambda-2.
  9. A schedule-based flow transfers the .csv file data as an event-status output to the Salesforce object, notifying the user that their event has been successfully handled in DynamoDB table.
  10. In parallel, DynamoDB streams trigger Lambda (Lambda-3), which processes the payload and initiates an Amazon Simple Notification Service (Amazon SNS) notification based on the status of the event request.
  11. Amazon SNS sends an email to the user detailing that the event created in the Salesforce object was successfully completed in DynamoDB table.
  12. If any of the two flows break due to any unforeseen events, their statuses are instantly captured and streamed to an EventBridge bus.
  13. The EventBridge bus triggers Lambda (Lambda-5).
  14. Lambda-5 tries to analyze the error causing failure and tries to get the flow to a working state again. If Lambda-5 fails, it initiates an Amazon SNS email to the solution support team to manually fix the Amazon AppFlow error and get the solution active again.
  15. Meanwhile, whenever an Amazon Connect contact center receives a call, it triggers Lambda (Lambda-4), which holds read-only access to DynamoDB table.
  16. Lambda-4 fetches the data stored by Lambda-1 in DynamoDB table and provides that data to a contact center in Amazon Connect.

Prerequisites

  • An AWS account with permissions to access all the required
  • An active Salesforce account with administration-level permissions set
  • Python 3.X version setup for developing Lambda-1 to -5

Implementation and development

1. Development steps on the Salesforce end

Note: We recommend working with a Salesforce expert. These steps can help initiate the development from Salesforce end.

a. Use the Platform Event feature to allow the data flow from Salesforce environment to AWS environment and then back to Salesforce from AWS environment using Amazon AppFlow.
b. Salesforce Connected Apps and web server flow used for integrating Amazon AppFlow with Salesforce.
c. New permissions set and new integration users are created to restrict the access to custom object.

2. Development steps on the AWS end

a. Create a new connection in Amazon AppFlow with “Salesforce” as the source
The “Client ID” and “Client Secret” of Salesforce Managed Connected App are stored in AWS Secrets Manager, which is encrypted by custom keys generated in AWS Key Management Service.

To setup an Amazon AppFlow connection with Salesforce, a stand-alone Lambda function is created using Python Boto3 API. This creates a connection in Amazon AppFlow using the “Client ID” and “Client Secret” of Salesforce connected app.

For more details regarding setting up the Salesforce connection in Amazon AppFlow, refer to the Amazon AppFlow User Guide.

b. Create new event-based input flow in Amazon AppFlow, using Salesforce as the source with the newly created connection
Select the “Salesforce events” option as per the business use case. For representation in this blog, “Telephony” is chosen as salesforce events. Select Amazon EventBridge as the destination. Create new “partner event source” for successful creation of input flow, as in Figure 2.

Configure an event-based flow in Amazon AppFlow

Figure 2. Configure an event-based flow in Amazon AppFlow

c. Handling large size input flow event payloads
Post successful creation of “Partner event source”, specify the S3 bucket for events that are larger than 256 KB, Amazon AppFlow sends a URL of the S3 object to the event bus instead of the event payload.

d. Configuring details for input flow
Select trigger pattern of input flow as “Run flow on event”, as shown in Figure 3.

Trigger pattern for creating input flow

Figure 3. Trigger pattern for creating input flow

As displayed in Figure 4, we can configure data field mapping, validation rules, and filters with Amazon AppFlow. This enables us to enrich and modify event data before it is sent to the event bus. Post this, input flow create action is complete.

Mapping Salesforce object fields with Amazon EventBridge bus

Figure 4. Mapping Salesforce object fields with Amazon EventBridge bus

e. Associating Amazon AppFlow generated partner event source with the event bus in the Amazon EventBridge dashboard
Before activating the flow, access the Amazon EventBridge console to associate the AppFlow generated partner-event-source with the event bus (Figure 5).

Associating input flow partner event source with the Amazon EventBridge bus

Figure 5. Associating input flow partner event source with the Amazon EventBridge bus

f. Post Amazon EventBridge bus association, activate the input flow
After associating the bus with input flow, navigate back to Amazon AppFlow console and click the “Activate flow” button for the input flow. Once active, input flow is ready to consume the event payload from Salesforce.

g. Amazon EventBridge bus triggering Lambda function
The EventBridge bus receives an event payload from the input flow and triggers Lambda (Lambda-1) to process that raw event payload and write the output results in a designated DynamoDB table. A sample of event input payload is in Figure 6. This payload content depends on the use case for which developer is working.

Input event payload sample from Salesforce

Figure 6. Input event payload sample from Salesforce

Lambda-1 adds the record-ID in the DynamoDB table, which is a unique event ID for each Salesforce event as shown in Figure 7.

Data added in Amazon DynamoDB table by Lambda-1

Figure 7. Data added in Amazon DynamoDB table by Lambda-1

h. Configuring DynamoDB streams
Within “Export and Streams” option in the DynamoDB table, enable the “DynamoDB stream details” and in the trigger section click on “Create trigger” option and select  Lambda-2 and Lambda -3, as detailed in Figure 8.

Configuring Amazon DynamoDB streams

Figure 8. Configuring Amazon DynamoDB streams

Lambda-2 stores the event output results and a success flag value in a .csv file that is created for every unique event; the .csv file is uploaded to an S3 bucket with the file name structure “Salesforce event recorded-event action-timestamp.csv”. For example:

Example 1: “abcd1234-event-created- 2022-05-19-11_23_51.csv” (data added)
Example 2: “abcd1234-event-deleted- 2022-05-19-11_24_50.csv” (data deleted)

i. Create new schedule-based flow (output flow) in Amazon AppFlow
The source is the S3 bucket folder where the .csv file is uploaded by Lambda-2. Select the destination as “Salesforce”, and choose the Salesforce object that is used to create the input flow (Figure 9). Revisit Step b for reference.

Configuring a schedule-based output flow

Figure 9. Configuring a schedule-based output flow

Output flow sends a response back to the same Salesforce object from which data addition/deletion event request was made. This confirms to the user that a data addition/deletion event created in Salesforce was successfully invoked in Dynamo DB table as well.

j. Error handling in output flow
In case output flow fails to write the response back to the Salesforce object, choose the option “Stop the current flow run”.

k. Configuring output flow as a run-on schedule
Output flow is a schedule-based flow that runs at specific time. Within the flow trigger window, select “Run flow on schedule”. Update the other fields, such as “Repeats”, “Every”, “Start date”, and “Starting at” per your specific needs. Within “Transfer mode”, select “Incremental transfer”. Refer to Figure 10.

Trigger pattern for schedule-based output flow

Figure 10. Trigger pattern for schedule-based output flow

l. Amazon AppFlow to Salesforce object mapping for output flow
Select Mapping method as “Manually map fields” and Destination record preference as “Upsert records”, as in Figure 11.

Output Flow will update the event record status in the Salesforce object, with success status flag value in the .csv file based on the unique “Record ID” that every Salesforce event payload contains. Once the field mapping is completed, output flow is active.

Manually mapping data fields with Salesforce

Figure 11. Manually mapping data fields with Salesforce

m. Real-time monitoring and failure handling
In case input/output flow breaks for unforeseen reasons, a rule is configured in EventBridge bus console that invokes Lambda (Lambda-5). Lambda-5 tries to handle the error and reactivate the flow. In case this action fails, Lambda sends an Amazon SNS email to the solution support team informing of the failure in Amazon AppFlow and the cause.

n. Integrating DynamoDB with Amazon Connect
Lambda (Lambda-4) is configured with contact center in Amazon Connect. As the call comes to contact center, Lambda-4 fetches the relevant data from the DynamoDB table. Amazon Connect operates per this data.

Cleanup

To avoid incurring future charges, delete any AWS resources that are no longer needed.

Conclusion

This post demonstrates the approach for developing an event-driven, serverless application that integrates DynamoDB with Salesforce using Amazon AppFlow bi-directionally. The contact center is based in Amazon Connect and functions dependent on the real-time data in a DynamoDB table—without manual intervention. The manual process can take a minimum of 24 hours, but the same action can be automatically completed using a self-service, UI-based form in the user’s Salesforce account.

This solution can be tailored depending on the business or technical requirement, differing how the data is consumed by multiple AWS services.

Deploying AWS Lambda functions using AWS Controllers for Kubernetes (ACK)

Post Syndicated from James Beswick original https://aws.amazon.com/blogs/compute/deploying-aws-lambda-functions-using-aws-controllers-for-kubernetes-ack/

This post is written by Rajdeep Saha, Sr. SSA, Containers/Serverless.

AWS Controllers for Kubernetes (ACK) allows you to manage AWS services directly from Kubernetes. With the ACK service controller for AWS Lambda, you can provision and manage Lambda functions with kubectl and custom resources. With ACK, you can have a single consolidated approach to managing container workloads and other AWS services, such as Lambda, directly from Kubernetes without needing additional infrastructure automation tools.

This post walks you through deploying a sample Lambda function from a Kubernetes cluster provided by Amazon EKS.

Use cases

Some of the use cases for provisioning Lambda functions from ACK include:

  • Your organization already has a DevOps process to deploy resources into the Amazon EKS cluster using Kubernetes declarative YAMLs (known as manifest files). With ACK for AWS Lambda, you can now use manifest files to provision Lambda functions without creating separate infrastructure as a code template.
  • Your project has implemented GitOps with Kubernetes. With GitOps, git becomes the single source of truth, and all the changes are done via git repo. In this model, Kubernetes continuously reconciles the git repo (desired state) with the resources running inside the cluster (current state). If any differences are found, the GitOps process automatically implements changes to the cluster from the git repo. Using ACK for AWS Lambda, since you are creating the Lambda function using Kubernetes custom resource, the GitOps model is applied for Lambda.
  • Your organization has established permissions boundaries for different users and groups using role-based access control (RBAC) and IAM roles for service accounts (IRSA). You can reuse this security model for Lambda without having to create new users and policies.

How ACK for AWS Lambda works

  1. The ‘Ops’ team deploys the ACK service controller for Lambda. This controller runs as a pod within the Amazon EKS cluster.
  2. The controller pod needs permission to read the Lambda function code and create the Lambda function. The Lambda function code is stored as a zip file in an S3 bucket for this example. The permissions are granted to the pod using IRSA.
  3. Each AWS service has separate ACK service controllers. This specific controller for AWS Lambda can act on the custom resource type ‘Function’.
  4. The ‘Dev’ team deploys Kubernetes manifest file with custom resource type ‘Function’. This manifest file defines the necessary fields required to create the function, such as S3 bucket name, zip file name, Lambda function IAM role, etc.
  5. The ACK service controller creates the Lambda function using the values from the manifest file.

Prerequisites

You need a few tools before deploying the sample application. Ensure that you have each of the following in your working environment:

This post uses shell variables to make it easier to substitute the actual names for your deployment. When you see placeholders like NAME=<your xyz name>, substitute in the name for your environment.

Setting up the Amazon EKS cluster

  1. Run the following to create an Amazon EKS cluster. The following single command creates a two-node Amazon EKS cluster with a unique name. 
    eksctl create cluster
  2. It may take 15–30 minutes to provision the Amazon EKS cluster. When the cluster is ready, run: 
    kubectl get nodes
  3. The output shows the following:
    Output
  4. To get the Amazon EKS cluster name to use throughout the walkthrough, run: 
    eksctl get cluster

export EKS_CLUSTER_NAME=<provide the name from the previous command>

Setting up the ACK Controller for Lambda

To set up the ACK Controller for Lambda:

  1. Install an ACK Controller with Helm by following these instructions:
    – Change ‘export SERVICE=s3’ to ‘export SERVICE=lambda’.
    – Change ‘export AWS_REGION=us-west-2’ to reflect your Region appropriately.
  2. To configure IAM permissions for the pod running the Lambda ACK Controller to permit it to create Lambda functions, follow these instructions.
    – Replace ‘SERVICE=”s3”’ with ‘SERVICE=”lambda”’.
  3. Validate that the ACK Lambda controller is running: 
    kubectl get pods -n ack-system
  4. The output shows the running ACK Lambda controller pod:
    Output

Provisioning a Lambda function from the Kubernetes cluster

In this section, you write a sample “Hello world” Lambda function. You zip up the code and upload the zip file to an S3 bucket. Finally, you deploy that zip file to a Lambda function using the ACK Controller from the EKS cluster you created earlier. For this example, use Python3.9 as your language runtime.

To provision the Lambda function:

  1. Run the following to create the sample “Hello world” Lambda function code, and then zip it up: 
    mkdir my-helloworld-function
cd my-helloworld-function
cat << EOF > lambda_function.py 
import json

def lambda_handler(event, context):
    # TODO implement
    return {
        'statusCode': 200,
        'body': json.dumps('Hello from Lambda!')
    }
EOF
zip my-deployment-package.zip lambda_function.py
  2. Create an S3 bucket following the instructions here. Alternatively, you can use an existing S3 bucket in the same Region of the Amazon EKS cluster.
  3. Run the following to upload the zip file into the S3 bucket from the previous step: 
    export BUCKET_NAME=<provide the bucket name from step 2>
aws s3 cp  my-deployment-package.zip s3://${BUCKET_NAME}
  4. The output shows:
    upload: ./my-deployment-package.zip to s3://<BUCKET_NAME>/my-deployment-package.zip
  5. Create your Lambda function using the ACK Controller. The full spec with all the available fields is listed here. First, provide a name for the function: 
    export FUNCTION_NAME=hello-world-s3-ack
  6. Create and deploy the Kubernetes manifest file. The command at the end, kubectl create -f function.yaml submits the manifest file, with kind as ‘Function’. The ACK Controller for Lambda identifies this custom ‘Function’ object and deploys the Lambda function based on the manifest file. 
    export AWS_ACCOUNT_ID=$(aws sts get-caller-identity --query "Account" --output text)
export LAMBDA_ROLE="arn:aws:iam::${AWS_ACCOUNT_ID}:role/lambda_basic_execution"

cat << EOF > lambdamanifest.yaml 
apiVersion: lambda.services.k8s.aws/v1alpha1
kind: Function
metadata:
 name: $FUNCTION_NAME
 annotations:
   services.k8s.aws/region: $AWS_REGION
spec:
 name: $FUNCTION_NAME
 code:
   s3Bucket: $BUCKET_NAME
   s3Key: my-deployment-package.zip
 role: $LAMBDA_ROLE
 runtime: python3.9
 handler: lambda_function.lambda_handler
 description: function created by ACK lambda-controller e2e tests
EOF
kubectl create -f lambdamanifest.yaml
  7. The output shows:
    function.lambda.services.k8s.aws/< FUNCTION_NAME> created
  8. To retrieve the details of the function using a Kubernetes command, run: 
    kubectl describe function/$FUNCTION_NAME
  9. This Lambda function returns a “Hello world” message. To invoke the function, run: 
    aws lambda invoke --function-name $FUNCTION_NAME  response.json
cat response.json
  10. The Lambda function returns the following output:
    {"statusCode": 200, "body": "\"Hello from Lambda!\""}

Congratulations! You created a Lambda function from your Kubernetes cluster.

To learn how to provision the Lambda function using the ACK controller from an OCI container image instead of a zip file in an S3 bucket, follow these instructions.

Cleaning up

This section cleans up all the resources that you have created. To clean up:

  1. Delete the Lambda function: 
    kubectl delete function $FUNCTION_NAME
  2. If you have created a new S3 bucket, delete it by running: 
    aws s3 rm s3://${BUCKET_NAME} --recursive
aws s3api delete-bucket --bucket ${BUCKET_NAME}
  3. Delete the EKS cluster: 
    eksctl delete cluster --name $EKS_CLUSTER_NAME
  4. Delete the IAM role created for the ACK Controller. Get the IAM role name by running the following command, then delete the role from the IAM console: 
    echo $ACK_CONTROLLER_IAM_ROLE

Conclusion

This blog post shows how AWS Controllers for Kubernetes enables you to deploy a Lambda function directly from your Amazon EKS environment. AWS Controllers for Kubernetes provides a convenient way to connect your Kubernetes applications to AWS services directly from Kubernetes.

ACK is open source: you can request new features and report issues on the ACK community GitHub repository.

For more serverless learning resources, visit Serverless Land.

A multi-dimensional approach helps you proactively prepare for failures, Part 2: Infrastructure layer

Post Syndicated from Piyali Kamra original https://aws.amazon.com/blogs/architecture/a-multi-dimensional-approach-helps-you-proactively-prepare-for-failures-part-2-infrastructure-layer/

Distributed applications resiliency is a cumulative resiliency of applications, infrastructure, and operational processes. Part 1 of this series explored application layer resiliency. In Part 2, we discuss how using Amazon Web Services (AWS) managed services, redundancy, high availability, and infrastructure failover patterns based on recovery time and point objectives (RTO and RPO, respectively) can help in building more resilient infrastructures.

Pattern 1: Recognize high impact/likelihood infrastructure failures

To ensure cloud infrastructure resilience, we need to understand the likelihood and impact of various infrastructure failures, so we can mitigate them. Figure 1 illustrates that most of the failures with high likelihood happen because of operator error or poor deployments.

Automated testing, automated deployments, and solid design patterns can mitigate these failures. There could be datacenter failures—like whole rack failures—but deploying applications using auto scaling and multi-availability zone (multi-AZ) deployment, plus resilient AWS cloud native services, can mitigate the impact.

Likelihood and impact of failure events

Figure 1. Likelihood and impact of failure events

As demonstrated in the Figure 1, infrastructure resiliency is a combination of high availability (HA) and disaster recovery (DR). HA involves increasing the availability of the system by implementing redundancy among the application components and removing single points of failure.

Application layer decisions, like creating stateless applications, make it simpler to implement HA at the infrastructure layer by allowing it to scale using Auto Scaling groups and distributing the redundant applications across multiple AZs.

Pattern 2: Understanding and controlling infrastructure failures

Building a resilient infrastructure requires understanding which infrastructure failures are under control and which ones are not, as demonstrated in Figure 2.

These insights allow us to automate the detection of failures, control them, and employ pro-active patterns, such as static stability, to mitigate the need to scale up the infrastructure by over-provisioning it in advance.

Proactively designing systems in the event of failure

Figure 2. Proactively designing systems in the event of failure

The infrastructure decisions under our control that can increase the infrastructure resiliency of our system, include:

  • AWS services have control and data planes designed for minimum blast radius. Data planes typically have higher availability design goals than control planes and are usually less complex. When implementing recovery or mitigation responses to events that can affect resiliency, using control plane operations can lower the overall resiliency of your architectures. For example, Amazon Route 53 (Route 53) has a data plane designed for a 100% availability SLA. A good fail-over mechanism should rely on the data plane and not the control plane, as explained in Creating Disaster Recovery Mechanisms Using Amazon Route 53.
  • Understanding networking design and routes implemented in a virtual private cloud (VPC) are critical when testing the flow of traffic in our application. Understanding the flow of traffic helps us design better applications and see how one component failure can affect overall ingress/egress traffic. To achieve better network resiliency, it’s important to implement a good subnet strategy and manage our IP addresses to avoid fail-over issues and asymmetric routing in hybrid architectures. Use IP address management tools for established subnet strategies and routing decisions.
  • When designing VPCs and AZs, understanding the service limits, deploying independent routing tables and components in each zone increases availability. For example, highly available NAT gateways are preferred over NAT instances, as noted in the comparison provided in the Amazon VPC documentation.

Pattern 3: Considering different ways of increasing HA at the infrastructure layer

As already detailed, infrastructure resiliency = HA + DR.

Different ways by which system availability can be increased include:

  • Building for redundancy: Redundancy is the duplication of application components to increase the overall availability of the distributed system. After following application layer best practices, we can build auto healing mechanisms at the infrastructure layer.

We can take advantage of auto scaling features and use Amazon CloudWatch metrics and alarms to set up auto scaling triggers and deploy redundant copies of our applications across multiple AZs. This protects workloads from AZ failures, as shown in Figure 3.

Redundancy increases availability

Figure 3. Redundancy increases availability

  • Auto scale your infrastructure: When there are AZ failures, infrastructure auto scaling maintains the desired number of redundant components, which helps maintain the base level application throughput. This way, HA system and manage costs are maintained. Auto scaling uses metrics to scale in and out, appropriately, as shown in Figure 4.
How auto scaling improves availability

Figure 4. How auto scaling improves availability

  • Implement resilient network connectivity patterns: While building highly resilient distributed systems, network access to AWS infrastructure also needs to be highly resilient. While deploying hybrid applications, the capacity needed for hybrid applications to communicate with their cloud native application counterparts is an important consideration in designing the network access using AWS Direct Connect or VPNs.

Testing failover and fallback scenarios helps validate that network paths operate as expected and routes fail over as expected to meet RTO objectives. As the number of connection points between the data center and AWS VPCs increases, a hub and spoke configuration provided by the Direct Connect gateway and transit gateways simplify network topology, testing, and fail over. For more information, visit the AWS Direct Connect Resiliency Recommendations.

  • Whenever possible, use the AWS networking backbone to increase security, resiliency, and lower cost. AWS PrivateLink provides secure access to AWS services and exposes the application’s functionalities and APIs to other business units or partner accounts hosted on AWS.
  • Security appliances need to be set up in HA configuration, so that even if one AZ is unavailable, security inspection can be taken over by the redundant appliances in the other AZs.
  • Think ahead about DNS resolution: DNS is a critical infrastructure component; hybrid DNS resolution should be designed carefully with Route 53 HA inbound and outbound resolver endpoints instead of using self-managed proxies.

Implement a good strategy to share DNS resolver rules across AWS accounts and VPC’s with Resource Access Manager. Network failover tests are an important part of Disaster Recovery and Business Continuity Plans. To learn more, visit Set up integrated DNS resolution for hybrid networks in Amazon Route 53.

Additionally, ELB uses health checks to make sure that requests will route to another component if the underlying traffic application component fails. This improves the distributed system’s availability, as it is the cumulative availability of all different layers in our system. Figure 5 details advantages of some AWS managed services.

AWS managed services help in building resilient infrastructures (click the image to enlarge)

Figure 5. AWS managed services help in building resilient infrastructures (click the image to enlarge)

Pattern 4: Use RTO and RPO requirements to determine the correct failover strategy for your application

Capture RTO and RPO requirements early on to determine solid failover strategies (Figure 6). Disaster recovery strategies within AWS range from low cost and complexity (like backup and restore), to more complex strategies when lower values of RTO and RPO are required.

In pilot light and warm standby, only the primary region receives traffic. Pilot light only critical infrastructure components run in the backup region. Automation is used to check failures in the primary region using health checks and other metrics.

When health checks fail, use a combination of auto scaling groups, automation, and Infrastructure as Code (IaC) for quick deployment of other infrastructure components.

Note: This strategy depends on control plane availability in the secondary region for deploying the resources; keep this point in mind if you don’t have compute pre-provisioned in the secondary region. Carefully consider the business requirements and a distributed system’s application-level characteristics before deciding on a failover strategy. To understand all the factors and complexities involved in each of these disaster recovery strategies refer to disaster recovery options in the cloud.

Relationship between RTO, RPO, cost, data loss, and length of service interruption

Figure 6. Relationship between RTO, RPO, cost, data loss, and length of service interruption

Conclusion

In Part 2 of this series, we discovered that infrastructure resiliency is a combination of HA and DR. It is important to consider likelihood and impact of different failure events on availability requirements. Building in application layer resiliency patterns (Part 1 of this series), along with early discovery of the RTO/RPO requirements, as well as operational and process resiliency of an organization helps in choosing the right managed services and putting in place the appropriate failover strategies for distributed systems.

It’s important to differentiate between normal and abnormal load threshold for applications in order to put automation, alerts, and alarms in place. This allows us to auto scale our infrastructure for normal expected load, plus implement corrective action and automation to root out issues in case of abnormal load. Use IaC for quick failover and test failover processes.

Stay tuned for Part 3, in which we discuss operational resiliency!

How to export AWS Security Hub findings to CSV format

Post Syndicated from Andy Robinson original https://aws.amazon.com/blogs/security/how-to-export-aws-security-hub-findings-to-csv-format/

AWS Security Hub is a central dashboard for security, risk management, and compliance findings from AWS Audit Manager, AWS Firewall Manager, Amazon GuardDuty, IAM Access Analyzer, Amazon Inspector, and many other AWS and third-party services. You can use the insights from Security Hub to get an understanding of your compliance posture across multiple AWS accounts. It is not unusual for a single AWS account to have more than a thousand Security Hub findings. Multi-account and multi-Region environments may have tens or hundreds of thousands of findings. With so many findings, it is important for you to get a summary of the most important ones. Navigating through duplicate findings, false positives, and benign positives can take time.

In this post, we demonstrate how to export those findings to comma separated values (CSV) formatted files in an Amazon Simple Storage Service (Amazon S3) bucket. You can analyze those files by using a spreadsheet, database applications, or other tools. You can use the CSV formatted files to change a set of status and workflow values to align with your organizational requirements, and update many or all findings at once in Security Hub.

The solution described in this post, called CSV Manager for Security Hub, uses an AWS Lambda function to export findings to a CSV object in an S3 bucket, and another Lambda function to update Security Hub findings by modifying selected values in the downloaded CSV file from an S3 bucket. You use an Amazon EventBridge scheduled rule to perform periodic exports (for example, once a week). CSV Manager for Security Hub also has an update function that allows you to update the workflow, customer-specific notation, and other customer-updatable values for many or all findings at once. If you’ve set up a Region aggregator in Security Hub, you should configure the primary CSV Manager for Security Hub stack to export findings only from the aggregator Region. However, you may configure other CSV Manager for Security Hub stacks that export findings from specific Regions or from all applicable Regions in specific accounts. This allows application and account owners to view their own Security Hub findings without having access to other findings for the organization.

How it works

CSV Manager for Security Hub has two main features:

  • Export Security Hub findings to a CSV object in an S3 bucket
  • Update Security Hub findings from a CSV object in an S3 bucket

Overview of the export function

The overview of the export function CsvExporter is shown in Figure 1.

Figure 1: Architecture diagram of the export function

Figure 1: Architecture diagram of the export function

Figure 1 shows the following numbered steps:

  1. In the AWS Management Console, you invoke the CsvExporter Lambda function with a test event.
  2. The export function calls the Security Hub GetFindings API action and gets a list of findings to export from Security Hub.
  3. The export function converts the most important fields to identify and sort findings to a 37-column CSV format (which includes 12 updatable columns) and writes to an S3 bucket.

Overview of the update function

To update existing Security Hub findings that you previously exported, you can use the update function CsvUpdater to modify the respective rows and columns of the CSV file you exported, as shown in Figure 2. There are 12 modifiable columns out of 37 (any changes to other columns are ignored), which are described in more detail in Step 3: View or update findings in the CSV file later in this post.

Figure 2: Architecture diagram of the update function

Figure 2 shows the following numbered steps:

Figure 2 shows the following numbered steps:

  1. You download the CSV file that the CsvExporter function generated from the S3 bucket and update as needed.
  2. You upload the CSV file that contains your updates to the S3 bucket.
  3. In the AWS Management Console, you invoke the CsvUpdater Lambda function with a test event containing the URI of the CSV file.
  4. CsvUpdater reads the updated CSV file from the S3 bucket.
  5. CsvUpdater identifies the minimum set of updates and invokes the Security Hub BatchUpdateFindings API action.

Step 1: Use the CloudFormation template to deploy the solution

You can set up and use CSV Manager for Security Hub by using either AWS CloudFormation or the AWS Cloud Development Kit (AWS CDK).

To deploy the solution (AWS CDK)

You can find the latest code in the aws-security-hub-csv-manager GitHub repository, where you can also contribute to the sample code. The following commands show how to deploy the solution by using the AWS CDK. First, the AWS CDK initializes your environment and uploads the AWS Lambda assets to an S3 bucket. Then, you deploy the solution to your account by using the following commands. Replace <INSERT_AWS_ACCOUNT> with your account number, and replace <INSERT_REGION> with the AWS Region that you want the solution deployed to, for example us-east-1.

cdk bootstrap aws://<INSERT_AWS_ACCOUNT>/<INSERT_REGION>
cdk deploy

To deploy the solution (CloudFormation)

  1. Choose the following Launch Stack button to open the AWS CloudFormation console pre-loaded with the template for this solution:

    Launch Stack

  2. In the Parameters section, as shown in Figure 3, enter your values.
    Figure 3: CloudFormation template variables

    Figure 3: CloudFormation template variables

    1. For What folder for CSV Manager for Security Hub Lambda code, leave the default Code. For What folder for CSV Manager for Security Hub exports, leave the default Findings.

      These are the folders within the S3 bucket that the CSV Manager for Security Hub CloudFormation template creates to store the Lambda code, as well as where the findings are exported by the Lambda function.

    2. For Frequency, for this solution you can leave the default value cron(0 8 ? * SUN *). This default causes automatic exports to occur every Sunday at 8:00 AM local time using an EventBridge scheduled rule. For more information about how to update this value to meet your needs, see Schedule Expressions for Rules in the Amazon CloudWatch Events User Guide.
    3. The values you enter for the Regions field depend on whether you have configured an aggregation Region in Security Hub.
      • If you have configured an aggregation Region, enter only that Region code, for example eu-north-1, as shown in Figure 3.
      • If you haven’t configured an aggregation Region, enter a comma-separated list of Regions in which you have enabled Security Hub, for example us-east-1, eu-west-1, eu-west-2.
      • If you would like to export findings from all Regions where Security Hub is enabled, leave the Regions field blank. Regions where Security Hub is not enabled will generate a message and will be skipped.
  3. Choose Next.

The CloudFormation stack deploys the necessary resources, including an EventBridge scheduling rule, AWS System Managers Automation documents, an S3 bucket, and Lambda functions for exporting and updating Security Hub findings.

After you deploy the CloudFormation stack

After you create the CSV Manager for Security Hub stack, you can do the following:

  1. Perform the export function to write some or all Security Hub findings to a CSV file by following the instructions in Step 2: Export Security Hub findings to a CSV file later in this post.
  2. Perform a bulk update of Security Hub findings by following the instructions in Step 3: View or update findings in the CSV file later in this post. You can make changes to one or more of the 12 updatable columns of the CSV file, and perform the update function to update some or all Security Hub findings.

Step 2: Export Security Hub findings to a CSV file

You can export Security Hub findings from the AWS Lambda console. To do this, you create a test event and invoke the CsvExporter Lambda function. CsvExporter exports all Security Hub findings from all applicable Regions to a single CSV file in the S3 bucket for CSV Manager for Security Hub.

To export Security Hub findings to a CSV file

  1. In the AWS Lambda console, find the CsvExporter Lambda function and select it.
  2. On the Code tab, choose the down arrow at the right of the Test button, as shown in Figure 4, and select Configure test event.
    Figure 4: The down arrow at the right of the Test button

    Figure 4: The down arrow at the right of the Test button

  3. To create an empty test event, on the Configure test event page, do the following:
    1. Choose Create a new event.
    2. Enter an event name; in this example we used testEvent.
    3. For Template, leave the default hello-world.
    4. For Event JSON, enter the JSON object {} as shown in Figure 5.
    Figure 5: Creating an empty test event

    Figure 5: Creating an empty test event

  4. Choose Save to save the empty test event.
  5. To invoke the Lambda function, choose the Test button, as shown in Figure 6.
    Figure 6: Test button to invoke the Lambda function

    Figure 6: Test button to invoke the Lambda function

  6. On the Execution Results tab, note the following details, which you will need for the next step. 
    {
"message": "Export succeeded", 
"bucket": DOC-EXAMPLE-BUCKET,
"exportKey”: DOC-EXAMPLE-OBJECT,
"resultCode": 200
}

  7. Locate the CSV object that matches the value of “exportKey” (in this example, DOC-EXAMPLE-OBJECT) in the S3 bucket that matches the value of “bucket” (in this example, DOC-EXAMPLE-BUCKET).

Now you can view or update the findings in the CSV file, as described in the next section.

Step 3: (Optional) Using filters to limit CSV results

In your test event, you can specify any filter that is accepted by the GetFindings API action. You do this by adding a filter key to your test event. The filter key can either contain the word HighActive (which is a predefined filter configured as a default for selecting active high-severity and critical findings, as shown in Figure 8), or a JSON filter object.

Figure 8 depicts an example JSON filter that performs the same filtering as the HighActive predefined filter.

To use filters to limit CSV results

  1. In the AWS Lambda console, find the CsvExporter Lambda function and select it.
  2. On the Code tab, choose the down arrow at the right of the Test button, as shown in Figure 7, and select Configure test event.
    Figure 7: The down arrow at the right of the Test button

    Figure 7: The down arrow at the right of the Test button

  3. To create a test event containing a filter, on the Configure test event page, do the following:
    1. Choose Create a new event.
    2. Enter an event name; in this example we used filterEvent.
    3. For Template, select testEvent,
    4. For Event JSON, enter the following JSON object, as shown in Figure 8. 
      {
   "SeverityLabel":[
      {
         "Value":"CRITICAL",
         "Comparison":"EQUALS"
      },
      {
         "Value":"HIGH",
         "Comparison":"EQUALS"
      }
   ],
   "RecordState":[
      {
         "Comparison":"EQUALS",
         "Value":"ACTIVE"
      }
   ]
}

      Figure 8: Test button to invoke the Lambda function

      Figure 8: Test button to invoke the Lambda function

    5. Choose Save.
  4. To invoke the Lambda function, choose the Test button as shown in Figure 9.
    Figure 9: Test button to invoke the Lambda function

    Figure 9: Test button to invoke the Lambda function

  5. On the Execution Results tab, note the following details, which you will need for the next step. 
    {
"message": "Export succeeded", 
"bucket": DOC-EXAMPLE-BUCKET,
"exportKey": DOC-EXAMPLE-OBJECT,
"resultCode": 200
}

  6. Locate the CSV object that matches the value of “exportKey” (in this example, DOC-EXAMPLE-OBJECT) in the S3 bucket that matches the value of “bucket” (in this example, DOC-EXAMPLE-BUCKET).

The results in this CSV file should be a filtered set of Security Hub findings according to the filter you specified above. You can now proceed to step 4 if you want to view or update findings.

Step 4: View or update findings in the CSV file

You can use any program that allows you to view or edit CSV files, such as Microsoft Excel. The first row in the CSV file are the column names. These column names correspond to fields in the JSON objects that are returned by the GetFindings API action.

Warning: Do not modify the first two columns, Id (column A) or ProductArn (column B). If you modify these columns, Security Hub will not be able to locate the finding to update, and any other changes to that finding will be discarded.

You can locally modify any of the columns in the CSV file, but only 12 columns out of 37 columns will actually be updated if you use CsvUpdater to update Security Hub findings. The following are the 12 columns you can update. These correspond to columns C through N in the CSV file.

Column name Spreadsheet column Description
Criticality C An integer value between 0 and 100.
Confidence D An integer value between 0 and 100.
NoteText E Any text you wish
NoteUpdatedBy F Automatically updated with your AWS principal user ID.
CustomerOwner* G Information identifying the owner of this finding (for example, email address).
CustomerIssue* H A Jira issue or another identifier tracking a specific issue.
CustomerTicket* I A ticket number or other trouble/problem tracking identification.
ProductSeverity** J A floating-point number from 0.0 to 99.9.
NormalizedSeverity** K An integer between 0 and 100.
SeverityLabel L One of the following:

  • INFORMATIONAL
  • LOW
  • MEDIUM
  • HIGH
  • HIGH
  • CRITICAL
VerificationState M One of the following:

  • UNKNOWN — Finding has not been verified yet.
  • TRUE_POSITIVE — This is a valid finding and should be treated as a risk.
  • FALSE_POSITIVE — This an incorrect finding and should be ignored or suppressed.
  • BENIGN_POSITIVE — This is a valid finding, but the risk is not applicable or has been accepted, transferred, or mitigated.
Workflow N One of the following:

  • NEW — This is a new finding that has not been reviewed.
  • NOTIFIED — The responsible party or parties have been notified of this finding.
  • RESOLVED — The finding has been resolved.
  • SUPPRESSED — A false or benign finding has been suppressed so that it does not appear as a current finding in Security Hub.

* These columns are stored inside the UserDefinedFields field of the updated findings. The column names imply a certain kind of information, but you can put any information you wish.

** These columns are stored inside the Severity field of the updated findings. These values have a fixed format and will be rejected if they do not meet that format.

Columns with fixed text values (L, M, N) in the previous table can be specified in mixed case and without underscores—they will be converted to all uppercase and underscores added in the CsvUpdater Lambda function. For example, “false positive” will be converted to “FALSE_POSITIVE”.

Step 5: Create a test event and update Security Hub by using the CSV file

If you want to update Security Hub findings, make your changes to columns C through N as described in the previous table. After you make your changes in the CSV file, you can update the findings in Security Hub by using the CSV file and the CsvUpdater Lambda function.

Use the following procedure to create a test event and run the CsvUpdater Lambda function.

To create a test event and run the CsvUpdater Lambda function

  1. In the AWS Lambda console, find the CsvUpdater Lambda function and select it.
  2. On the Code tab, choose the down arrow to the right of the Test button, as shown in Figure 10, and select Configure test event.
    Figure 10: The down arrow to the right of the Test button

    Figure 10: The down arrow to the right of the Test button

  3. To create a test event as shown in Figure 11, on the Configure test event page, do the following:
    1. Choose Create a new event.
    2. Enter an event name; in this example we used testEvent.
    3. For Template, leave the default hello-world.
    4. For Event JSON, enter the following: 
      {
"input": <s3ObjectUri>,
"primaryRegion": <aggregationRegionName>
}

      Replace <s3ObjectUri> with the full URI of the S3 object where the updated CSV file is located.

      Replace <aggregationRegionName> with your Security Hub aggregation Region, or the primary Region in which you initially enabled Security Hub.

      Figure 11: Create and save a test event for the CsvUpdater Lambda function

      Figure 11: Create and save a test event for the CsvUpdater Lambda function

  4. Choose Save.
  5. Choose the Test button, as shown in Figure 12, to invoke the Lambda function.
    Figure 12: Test button to invoke the Lambda function

    Figure 12: Test button to invoke the Lambda function

  6. To verify that the Lambda function ran successfully, on the Execution Results tab, review the results for “message”: “Success”, as shown in the following example. Note that the results may be thousands of lines long. 
    {
"message": "Success",
"details": {
"processed": [{"Id": arn:aws:securityhub:us-east-1: 111122223333:subscription/cis-aws-foundations-benchmark/v/1.2.0/1.7/finding/6d543b22-6a3d-405c-ae7f-224469bde7d2, "ProductArn": arn:aws:securityhub:us-east-1::product/aws/securityhub}, … ],
"unprocessed": [],
"message": "Updated succeeded",
"success": true
},
"input": s3://DOC-EXAMPLE-BUCKET/DOC-EXAMPLE-OBJECT,
"resultCode": 200
}

    The processed array lists every successfully updated finding by Id and ProductArn.

    If any of the findings were not successfully updated, their Id and ProductArn appear in the unprocessed array. In the previous example, no findings were unprocessed.

    The value s3://DOC-EXAMPLE-BUCKET/DOC-EXAMPLE-OBJECT is the URI of the S3 object from which your updates were read.

Cleaning up

To avoid incurring future charges, first delete the CloudFormation stack that you deployed in Step 1: Use the CloudFormation template to deploy the solution. Next, you need to manually delete the S3 bucket deployed with the stack. For instructions, see Deleting a bucket in the Amazon Simple Storage Service User Guide.

Conclusion

In this post, we showed you how you can export Security Hub findings to a CSV file in an S3 bucket and update the exported findings by using CSV Manager for Security Hub. We showed you how you can automate this process by using AWS Lambda, Amazon S3, and AWS Systems Manager. Full documentation for CSV Manager for Security Hub is available in the aws-security-hub-csv-manager GitHub repository. You can also investigate other ways to manage Security Hub findings by checking out our blog posts about Security Hub integration with Amazon OpenSearch Service, Amazon QuickSight, Slack, PagerDuty, Jira, or ServiceNow.

If you have feedback about this post, submit comments in the Comments section below. If you have questions about this post, start a new thread on the Security Hub re:Post. To learn more or get started, visit AWS Security Hub.

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Andy Robinson

Andy Robinson

Andy wrote CSV Manager for Security Hub in response to requests from several customers. He is an AWS Professional Services Senior Security Consultant with over 30 years of security, software product management, and software design experience. Andy is also a pilot, scuba instructor, martial arts instructor, ham radio enthusiast, and photographer.

Murat Eksi

Murat Eksi

Murat is a full-stack technologist at AWS Professional Services. He has worked with various industries, including finance, sports, media, gaming, manufacturing, and automotive, to accelerate their business outcomes through application development, security, IoT, analytics, devops and infrastructure. Outside of work, he loves traveling around the world, learning new languages while setting up local events for entrepreneurs and business owners in Stockholm, or taking flight lessons.

Shikhar Mishra

Shikhar Mishra

Shikhar is a Senior Solutions Architect at Amazon Web Services. He is a cloud security enthusiast and enjoys helping customers design secure, reliable, and cost-effective solutions on AWS.

Rohan Raizada

Rohan Raizada

Rohan is a Solutions Architect for Amazon Web Services. He works with enterprises of all sizes with their cloud adoption to build scalable and secure solutions using AWS. During his free time, he likes to spend time with family and go cycling outdoors.

Jonathan Nguyen

Jonathan Nguyen

Jonathan is a Shared Delivery Team Senior Security Consultant at AWS. His background is in AWS Security with a focus on threat detection and incident response. Today, he helps enterprise customers develop a comprehensive security strategy and deploy security solutions at scale, and he trains customers on AWS Security best practices.

Sequence Diagrams enrich your understanding of distributed architectures

Post Syndicated from Kevin Hakanson original https://aws.amazon.com/blogs/architecture/sequence-diagrams-enrich-your-understanding-of-distributed-architectures/

Architecture diagrams visually communicate and document the high-level design of a solution. As the level of detail increases, so does the diagram’s size, density, and layout complexity. Using Sequence Diagrams, you can explore additional usage scenarios and enrich your understanding of the distributed architecture while continuing to communicate visually.

This post takes a sample architecture and iteratively builds out a set of Sequence Diagrams. Each diagram adds to the vocabulary and graphical notation of Sequence Diagrams, then shows how the diagram deepened understanding of the architecture. All diagrams in this post were rendered from a text-based domain specific language using a diagrams-as-code tool instead of being drawn with graphical diagramming software.

Sample architecture

The architecture is based on Implementing header-based API Gateway versioning with Amazon CloudFront from the AWS Compute Blog, which uses the AWS [email protected] feature to dynamically route the request to the targeted API version.

Amazon API Gateway is a fully managed service that makes it easier for developers to create, publish, maintain, monitor, and secure APIs at any scale. Amazon CloudFront is a global content delivery network (CDN) service built for high-speed, low-latency performance, security, and developer ease-of-use. [email protected] lets you run functions that customize the content that CloudFront delivers.

The numbered labels in Figure 1 correspond to the following text descriptions:

  1. User sends an HTTP request to CloudFront, including a version header.
  2. CloudFront invokes the [email protected] function for the Origin Request event.
  3. The function matches the header value to data fetched from an Amazon DynamoDB table, then modifies the Host header and path of the request and returns it to CloudFront.
  4. CloudFront routes the HTTP request to the matching API Gateway.

Figure 1 architecture diagram is a free-form mixture between a structure diagram and a behavior diagram. It includes structural aspects from a high-level Deployment Diagram, which depicts network connections between AWS services. It also demonstrates behavioral aspects from a Communication Diagram, which uses messages represented by arrows labeled with chronological numbers.

High-level architecture diagram

Figure 1. High-level architecture diagram

Sequence Diagrams

Sequence Diagrams are part of a subset of behavior diagrams known as interaction diagrams, which emphasis control and data flow. Sequence Diagrams model the ordered logic of usage scenarios in a consistent visual manner and capture detailed behaviors. I use this diagram type for analysis and design purposes and to validate my assumptions about data flows in distributed architectures. Let’s investigate the system use case where the API is called without a header indicating the requested version using a Sequence Diagram.

Examining the system use case

In Figure 2, User, Web Distribution, and Origin Request are each actors or system participants. The parallel vertical lines underneath these participants are lifelines. The horizontal arrows between participants are messages, with the arrowhead indicating message direction. Messages are arranged in time sequence from top to bottom. The dashed lines represent reply messages. The text inside guillemets («like this») indicate a stereotype, which refines the meaning of a model element. The rectangle with the bent upper-right corner is a note containing additional useful information.

Missing accept-version header

Figure 2. Missing accept-version header

The message from User to Web Distribution lacks any HTTP header that indicates the version, which precipitates the choice of Accept-Version for this name. The return message requires a decision about HTTP status code for this error case (400). The interaction with the Origin Request prompts a selection of Lambda runtimes (nodejs14.x) and understanding the programming model for generating an HTTP response for this request.

Designing the interaction

Next, let’s design the interaction when the Accept-Version header is present, but the corresponding value is not found in the Version Mappings table.

Figure 3 adds new notation to the diagram. The rectangle with “opt” in the upper-left corner and bolded text inside square brackets is an interaction fragment. The “opt” indicates this operation is an option based on the constraint (or guard) that “version mappings not cached” is true.

API version not found

Figure 3. API version not found

A DynamoDB scan operation on every request consumes table read capacity. Caching Version Mappings data inside the [email protected] function’s memory optimizes for on-demand capacity mode. The «on-demand» stereotype on the DynamoDB participant succinctly communicates this decision. The “API V3 not found” note on Figure 3 provides clarity to the reader. The HTTP status code for this error case is decided as 404 with a custom description of “API Version Not Found.”

Now, let’s design the interaction where the API version is found and the caller receives a successful response.

Figure 4 is similar to Figure 3 up until the note, which now indicates “API V1 found.” Consulting the documentation for Writing functions for [email protected], the request event is updated with the HTTP Host header and path for the “API V1” Amazon API Gateway.

API version found

Figure 4. API version found

Instead of three separate diagrams for these individual scenarios, a single, combined diagram can represent the entire set of use cases. Figure 5 includes two new “alt” interaction fragments that represent choices of alternative behaviors.

The first “alt” has a guard of “missing Accept-Version header” mapping to our Figure 2 use case. The “else” guard encompasses the remaining use cases containing a second “alt” splitting where Figure 3 and Figure 4 diverge. That “version not found” guard is the Figure 3 use case returning the 404, while that “else” guard is the Figure 4 success condition. The added notes improve visual clarity.

Header-based API Gateway versioning with CloudFront

Figure 5. Header-based API Gateway versioning with CloudFront

Diagrams as code

After diagrams are created, the next question is where to save them and how to keep them updated. Because diagrams-as-code use text-based files, they can be stored and versioned in the same source control system as application code. Also consider an architectural decision record (ADR) process to document and communicate architecturally significant decisions. Then as application code is updated, team members can revise both the ADR narrative and the text-based diagram source. Up-to-date documentation is important for operationally supporting production deployments, and these diagrams quickly provide a visual understanding of system component interactions.

Conclusion

This post started with a high-level architecture diagram and ended with an additional Sequence Diagram that captures multiple usage scenarios. This improved understanding of the system design across success and error use cases. Focusing on system interactions prior to coding facilitates the interface definition and emergent properties discovery, before thinking in terms of programming language specific constructs and SDKs.

Experiment to see if Sequence Diagrams improve the analysis and design phase of your next project. View additional examples of diagrams-as-code from the AWS Icons for PlantUML GitHub repository. The Workload Discovery on AWS solution can even build detailed architecture diagrams of your workloads based on live data from AWS.

For vetted architecture solutions and reference architecture diagrams, visit the AWS Architecture Center. For more serverless learning resources, visit Serverless Land.

Related information

  • The Unified Modeling Language specification provides the full definition of Sequence Diagrams. This includes notations for additional interaction frame operators, using open arrow heads to represent asynchronous messages, and more.
  • Diagrams were created for this blog post using PlantUML and the AWS Icons for PlantUML. PlantUML integrates with IDEs, wikis, and other external tools. PlantUML is distributed under multiple open-source licenses, allowing local server rendering for diagrams containing sensitive information. AWS Icons for PlantUML include the official AWS Architecture Icons.

Using custom consumer group ID support for the AWS Lambda event sources for MSK and self-managed Kafka

Post Syndicated from James Beswick original https://aws.amazon.com/blogs/compute/using-custom-consumer-group-id-support-for-the-aws-lambda-event-sources-for-msk-and-self-managed-kafka/

This post is written by Adam Wagner, Principal Serverless Specialist SA.

AWS Lambda already supports Amazon Managed Streaming for Apache Kafka (MSK) and self-managed Apache Kafka clusters as event sources. Today, AWS adds support for specifying a custom consumer group ID for the Lambda event source mappings (ESMs) for MSK and self-managed Kafka event sources.

With this feature, you can create a Lambda ESM that uses a consumer group that has already been created. This enables you to use Lambda as a Kafka consumer for topics that are replicated with MirrorMaker v2 or with consumer groups you create to start consuming at a particular offset or timestamp.

Overview

This blog post shows how to use this feature to enable Lambda to consume a Kafka topic starting at a specific timestamp. This can be useful if you must reprocess some data but don’t want to reprocess all of the data in the topic.

In this example application, a client application writes to a topic on the MSK cluster. It creates a consumer group that points to a specific timestamp within that topic as the starting point for consuming messages. A Lambda ESM is created using that existing consumer group that triggers a Lambda function. This processes and writes the messages to an Amazon DynamoDB table.

Reference architecture

  1. A Kafka client writes messages to a topic in the MSK cluster.
  2. A Kafka consumer group is created with a starting point of a specific timestamp
  3. The Lambda ESM polls the MSK topic using the existing consumer group and triggers the Lambda function with batches of messages.
  4. The Lambda function writes the messages to DynamoDB

Step-by-step instructions

To get started, create an MSK cluster and a client Amazon EC2 instance from which to create topics and publish messages. If you don’t already have an MSK cluster, follow this blog on setting up an MSK cluster and using it as an event source for Lambda.

  1. On the client instance, set an environment variable to the MSK cluster bootstrap servers to make it easier to reference them in future commands: 
    export MSKBOOTSTRAP='b-1.mskcluster.oy1hqd.c23.kafka.us-east-1.amazonaws.com:9094,b-2.mskcluster.oy1hqd.c23.kafka.us-east-1.amazonaws.com:9094,b-3.mskcluster.oy1hqd.c23.kafka.us-east-1.amazonaws.com:9094'
  2. Create the topic. This example has a three-node MSK cluster so the replication factor is also set to three. The partition count is set to three in this example. In your applications, set this according to throughput and parallelization needs. 
    ./bin/kafka-topics.sh --create --bootstrap-server $MSKBOOT --replication-factor 3 --partitions 3 --topic demoTopic01
  3. Write messages to the topic using this Python script: 
    #!/usr/bin/env python3
import json
import time
from random import randint
from uuid import uuid4
from kafka import KafkaProducer

BROKERS = ['b-1.mskcluster.oy1hqd.c23.kafka.us-east-1.amazonaws.com:9094', 
        'b-2.mskcluster.oy1hqd.c23.kafka.us-east-1.amazonaws.com:9094',
        'b-3.mskcluster.oy1hqd.c23.kafka.us-east-1.amazonaws.com:9094']
TOPIC = 'demoTopic01'

producer = KafkaProducer(bootstrap_servers=BROKERS, security_protocol='SSL',
        value_serializer=lambda x: json.dumps(x).encode('utf-8'))

def create_record(sequence_num):
    number = randint(1000000,10000000)
    record = {"id": sequence_num, "record_timestamp": int(time.time()), "random_number": number, "producer_id": str(uuid4()) }
    print(record)
    return record

def publish_rec(seq):
    data = create_record(seq)
    producer.send(TOPIC, value=data).add_callback(on_send_success).add_errback(on_send_error)
    producer.flush()

def on_send_success(record_metadata):
    print(record_metadata.topic, record_metadata.partition, record_metadata.offset)

def on_send_error(excp):
    print('error writing to kafka', exc_info=excp)

for num in range(1,10000000):
    publish_rec(num)
    time.sleep(0.5)
  4. Copy the script into a file on the client instance named producer.py. The script uses the kafka-python library, so first create a virtual environment and install the library. 
    python3 -m venv venv
source venv/bin/activate
pip3 install kafka-python
  5. Start the script. Leave it running for a few minutes to accumulate some messages in the topic.
    Output
  6. Previously, a Lambda function would choose between consuming messages starting at the beginning of the topic or starting with the latest messages. In this example, it starts consuming messages from a few hours ago at 14:30 UTC. To do this, first create a new consumer group on the client instance: 
    ./bin/kafka-consumer-groups.sh --command-config client.properties --bootstrap-server $MSKBOOTSTRAP --topic demoTopic01 --group specificTimeCG --to-datetime 2022-08-10T16:00:00.000 --reset-offsets --execute
  7. In this case, specificTimeCG is the consumer group ID used when creating the Lambda ESM. Listing the consumer groups on the cluster shows the new group: 
    ./bin/kafka-consumer-groups.sh --list --command-config client.properties --bootstrap-server $MSKBOOTSTRAP

    Output

  8. With the consumer group created, create the Lambda function along with the Event Source Mapping that uses this new consumer group. In this case, the Lambda function and DynamoDB table are already created. Create the ESM with the following AWS CLI Command: 
    aws lambda create-event-source-mapping --region us-east-1 --event-source-arn arn:aws:kafka:us-east-1:0123456789:cluster/demo-us-east-1/78a8d1c1-fa31-4f59-9de3-aacdd77b79bb-23 --function-name msk-consumer-demo-ProcessMSKfunction-IrUhEoDY6X9N --batch-size 3 --amazon-managed-kafka-event-source-config '{"ConsumerGroupId":"specificTimeCG"}' --topics demoTopic01

    The event source in the Lambda console or CLI shows the starting position set to TRIM_HORIZON. However, if you specify a custom consumer group ID that already has existing offsets, those offsets take precedent.

  9. With the event source created, navigate to the DynamoDB console. Locate the DynamoDB table to see the records written by the Lambda function.
    DynamoDB table

Converting the record timestamp of the earliest record in DynamoDB, 1660147212, to a human-readable date shows that the first record was created on 2022-08-10T16:00:12.

In this example, the consumer group is created before the Lambda ESM so that you can specify the timestamp to start from.

If you create an ESM and specify a custom consumer group ID that does not exist, it is created. This is a convenient way to create a new consumer group for an ESM with an ID of your choosing.

Deleting an ESM does not delete the consumer group, regardless of whether it is created before, or during, the ESM creation.

Using the AWS Serverless Application Model (AWS SAM)

To create the event source mapping with a custom consumer group using an AWS Serverless Application Model (AWS SAM) template, use the following snippet:

Events:
  MyMskEvent:
    Type: MSK
    Properties:
      Stream: !Sub arn:aws:kafka:${AWS::Region}:012345678901:cluster/ demo-us-east-1/78a8d1c1-fa31-4f59-9de3-aacdd77b79bb-23
      Topics:
        - "demoTopic01"
      ConsumerGroupId: specificTimeCG

Other types of Kafka clusters

This example uses the custom consumer group ID feature when consuming a Kafka topic from an MSK cluster. In addition to MSK clusters, this feature also supports self-managed Kafka clusters. These could be clusters running on EC2 instances or managed Kafka clusters from a partner such as Confluent.

Conclusion

This post shows how to use the new custom consumer group ID feature of the Lambda event source mapping for Amazon MSK and self-managed Kafka. This feature can be used to consume messages with Lambda starting at a specific timestamp or offset within a Kafka topic. It can also be used to consume messages from a consumer group that is replicated from another Kafka cluster using MirrorMaker v2.

For more serverless learning resources, visit Serverless Land.

Build a pseudonymization service on AWS to protect sensitive data, part 1

Post Syndicated from Rahul Shaurya original https://aws.amazon.com/blogs/big-data/part-1-build-a-pseudonymization-service-on-aws-to-protect-sensitive-data/

According to an article in MIT Sloan Management Review, 9 out of 10 companies believe their industry will be digitally disrupted. In order to fuel the digital disruption, companies are eager to gather as much data as possible. Given the importance of this new asset, lawmakers are keen to protect the privacy of individuals and prevent any misuse. Organizations often face challenges as they aim to comply with data privacy regulations like Europe’s General Data Protection Regulation (GDPR) and the California Consumer Privacy Act (CCPA). These regulations demand strict access controls to protect sensitive personal data.

This is a two-part post. In part 1, we walk through a solution that uses a microservice-based approach to enable fast and cost-effective pseudonymization of attributes in datasets. The solution uses the AES-GCM-SIV algorithm to pseudonymize sensitive data. In part 2, we will walk through useful patterns for dealing with data protection for varying degrees of data volume, velocity, and variety using Amazon EMR, AWS Glue, and Amazon Athena.

Data privacy and data protection basics

Before diving into the solution architecture, let’s look at some of the basics of data privacy and data protection. Data privacy refers to the handling of personal information and how data should be handled based on its relative importance, consent, data collection, and regulatory compliance. Depending on your regional privacy laws, the terminology and definition in scope of personal information may differ. For example, privacy laws in the United States use personally identifiable information (PII) in their terminology, whereas GDPR in the European Union refers to it as personal data. Techgdpr explains in detail the difference between the two. Through the rest of the post, we use PII and personal data interchangeably.

Data anonymization and pseudonymization can potentially be used to implement data privacy to protect both PII and personal data and still allow organizations to legitimately use the data.

Anonymization vs. pseudonymization

Anonymization refers to a technique of data processing that aims to irreversibly remove PII from a dataset. The dataset is considered anonymized if it can’t be used to directly or indirectly identify an individual.

Pseudonymization is a data sanitization procedure by which PII fields within a data record are replaced by artificial identifiers. A single pseudonym for each replaced field or collection of replaced fields makes the data record less identifiable while remaining suitable for data analysis and data processing. This technique is especially useful because it protects your PII data at record level for analytical purposes such as business intelligence, big data, or machine learning use cases.

The main difference between anonymization and pseudonymization is that the pseudonymized data is reversible (re-identifiable) to authorized users and is still considered personal data.

Solution overview

The following architecture diagram provides an overview of the solution.

Solution overview

This architecture contains two separate accounts:

  • Central pseudonymization service: Account 111111111111 – The pseudonymization service is running in its own dedicated AWS account (right). This is a centrally managed pseudonymization API that provides access to two resources for pseudonymization and reidentification. With this architecture, you can apply authentication, authorization, rate limiting, and other API management tasks in one place. For this solution, we’re using API keys to authenticate and authorize consumers.
  • Compute: Account 222222222222 – The account on the left is referred to as the compute account, where the extract, transform, and load (ETL) workloads are running. This account depicts a consumer of the pseudonymization microservice. The account hosts the various consumer patterns depicted in the architecture diagram. These solutions are covered in detail in part 2 of this series.

The pseudonymization service is built using AWS Lambda and Amazon API Gateway. Lambda enables the serverless microservice features, and API Gateway provides serverless APIs for HTTP or RESTful and WebSocket communication.

We create the solution resources via AWS CloudFormation. The CloudFormation stack template and the source code for the Lambda function are available in GitHub Repository.

We walk you through the following steps:

  1. Deploy the solution resources with AWS CloudFormation.
  2. Generate encryption keys and persist them in AWS Secrets Manager.
  3. Test the service.

Demystifying the pseudonymization service

Pseudonymization logic is written in Java and uses the AES-GCM-SIV algorithm developed by codahale. The source code is hosted in a Lambda function. Secret keys are stored securely in Secrets Manager. AWS Key Management System (AWS KMS) makes sure that secrets and sensitive components are protected at rest. The service is exposed to consumers via API Gateway as a REST API. Consumers are authenticated and authorized to consume the API via API keys. The pseudonymization service is technology agnostic and can be adopted by any form of consumer as long as they’re able to consume REST APIs.

As depicted in the following figure, the API consists of two resources with the POST method:

API Resources

  • Pseudonymization – The pseudonymization resource can be used by authorized users to pseudonymize a given list of plaintexts (identifiers) and replace them with a pseudonym.
  • Reidentification – The reidentification resource can be used by authorized users to convert pseudonyms to plaintexts (identifiers).

The request response model of the API utilizes Java string arrays to store multiple values in a single variable, as depicted in the following code.

Request/Response model

The API supports a Boolean type query parameter to decide whether encryption is deterministic or probabilistic.

The implementation of the algorithm has been modified to add the logic to generate a nonce, which is dependent on the plaintext being pseudonymized. If the incoming query parameters key deterministic has the value True, then the overloaded version of the encrypt function is called. This generates a nonce using the HmacSHA256 function on the plaintext, and takes 12 sub-bytes from a predetermined position for nonce. This nonce is then used for the encryption and prepended to the resulting ciphertext. The following is an example:

  • IdentifierVIN98765432101234
  • NonceNjcxMDVjMmQ5OTE5
  • PseudonymNjcxMDVjMmQ5OTE5q44vuub5QD4WH3vz1Jj26ZMcVGS+XB9kDpxp/tMinfd9

This approach is useful especially for building analytical systems that may require PII fields to be used for joining datasets with other pseudonymized datasets.

The following code shows an example of deterministic encryption.Deterministic Encryption

If the incoming query parameters key deterministic has the value False, then the encrypt method is called without the deterministic parameter and the nonce generated is a random 12 bytes. This generates a different ciphertext for the same incoming plaintext.

The following code shows an example of probabilistic encryption.

Probabilistic Encryption

The Lambda function utilizes a couple of caching mechanisms to boost the performance of the function. It uses Guava to build a cache to avoid generation of the pseudonym or identifier if it’s already available in the cache. For the probabilistic approach, the cache isn’t utilized. It also uses SecretCache, an in-memory cache for secrets requested from Secrets Manager.

Prerequisites

For this walkthrough, you should have the following prerequisites:

Deploy the solution resources with AWS CloudFormation

The deployment is triggered by running the deploy.sh script. The script runs the following phases:

  1. Checks for dependencies.
  2. Builds the Lambda package.
  3. Builds the CloudFormation stack.
  4. Deploys the CloudFormation stack.
  5. Prints to standard out the stack output.

The following resources are deployed from the stack:

  • An API Gateway REST API with two resources:
    • /pseudonymization
    • /reidentification
  • A Lambda function
  • A Secrets Manager secret
  • A KMS key
  • IAM roles and policies
  • An Amazon CloudWatch Logs group

You need to pass the following parameters to the script for the deployment to be successful:

  • STACK_NAME – The CloudFormation stack name.
  • AWS_REGION – The Region where the solution is deployed.
  • AWS_PROFILE – The named profile that applies to the AWS Command Line Interface (AWS CLI). command
  • ARTEFACT_S3_BUCKET – The S3 bucket where the infrastructure code is stored. The bucket must be created in the same account and Region where the solution lives.

Use the following commands to run the ./deployments_scripts/deploy.sh script:

chmod +x ./deployment_scripts/deploy.sh ./deployment_scripts/deploy.sh -s STACK_NAME -b ARTEFACT_S3_BUCKET -r AWS_REGION -p AWS_PROFILE AWS_REGION

Upon successful deployment, the script displays the stack outputs, as depicted in the following screenshot. Take note of the output, because we use it in subsequent steps.

Stack Output

Generate encryption keys and persist them in Secrets Manager

In this step, we generate the encryption keys required to pseudonymize the plain text data. We generate those keys by calling the KMS key we created in the previous step. Then we persist the keys in a secret. Encryption keys are encrypted at rest and in transit, and exist in plain text only in-memory when the function calls them.

To perform this step, we use the script key_generator.py. You need to pass the following parameters for the script to run successfully:

  • KmsKeyArn – The output value from the previous stack deployment
  • AWS_PROFILE – The named profile that applies to the AWS CLI command
  • AWS_REGION – The Region where the solution is deployed
  • SecretName – The output value from the previous stack deployment

Use the following command to run ./helper_scripts/key_generator.py:

python3 ./helper_scripts/key_generator.py -k KmsKeyArn -s SecretName -p AWS_PROFILE -r AWS_REGION

Upon successful deployment, the secret value should look like the following screenshot.

Encryption Secrets

Test the solution

In this step, we configure Postman and query the REST API, so you need to make sure Postman is installed in your machine. Upon successful authentication, the API returns the requested values.

The following parameters are required to create a complete request in Postman:

  • PseudonymizationUrl – The output value from stack deployment
  • ReidentificationUrl – The output value from stack deployment
  • deterministic – The value True or False for the pseudonymization call
  • API_Key – The API key, which you can retrieve from API Gateway console

Follow these steps to set up Postman:

  1. Start Postman in your machine.
  2. On the File menu, choose Import.
  3. Import the Postman collection.
  4. From the collection folder, navigate to the pseudonymization request.
  5. To test the pseudonymization resource, replace all variables in the sample request with the parameters mentioned earlier.

The request template in the body already has some dummy values provided. You can use the existing one or exchange with your own.

  1. Choose Send to run the request.

The API returns in the body of the response a JSON data type.

Reidentification

  1. From the collection folder, navigate to the reidentification request.
  2. To test the reidentification resource, replace all variables in the sample request with the parameters mentioned earlier.
  3. Pass to the response template in the body the pseudonyms output from earlier.
  4. Choose Send to run the request.

The API returns in the body of the response a JSON data type.

Pseudonyms

Cost and performance

There are many factors that can determine the cost and performance of the service. Performance especially can be influenced by payload size, concurrency, cache hit, and managed service limits on the account level. The cost is mainly influenced by how much the service is being used. For our cost and performance exercise, we consider the following scenario:

The REST API is used to pseudonymize Vehicle Identification Numbers (VINs). On average, consumers request pseudonymization of 1,000 VINs per call. The service processes on average 40 requests per second, or 40,000 encryption or decryption operations per second. The average process time per request is as follows:

  • 15 milliseconds for deterministic encryption
  • 23 milliseconds for probabilistic encryption
  • 6 milliseconds for decryption

The number of calls hitting the service per month is distributed as follows:

  • 50 million calls hitting the pseudonymization resource for deterministic encryption
  • 25 million calls hitting the pseudonymization resource for probabilistic encryption
  • 25 million calls hitting the reidentification resource for decryption

Based on this scenario, the average cost is $415.42 USD per month. You may find the detailed cost breakdown in the estimate generated via the AWS Pricing Calculator.

We use Locust to simulate a similar load to our scenario. Measurements from Amazon CloudWatch metrics are depicted in the following screenshots (network latency isn’t considered during our measurement).

The following screenshot shows API Gateway latency and Lambda duration for deterministic encryption. Latency is high at the beginning due to the cold start, and flattens out over time.

API Gateway Latency & Lamdba Duration for deterministic encryption. Latency is high at the beginning due to the cold start and flattens out over time.

The following screenshot shows metrics for probabilistic encryption.

metrics for probabilistic encryption

The following shows metrics for decryption.

metrics for decryption

Clean up

To avoid incurring future charges, delete the CloudFormation stack by running the destroy.sh script. The following parameters are required to run the script successfully:

  • STACK_NAME – The CloudFormation stack name
  • AWS_REGION – The Region where the solution is deployed
  • AWS_PROFILE – The named profile that applies to the AWS CLI command

Use the following commands to run the ./deployment_scripts/destroy.sh script:

chmod +x ./deployment_scripts/destroy.sh ./deployment_scripts/destroy.sh -s STACK_NAME -r AWS_REGION -p AWS_PROFILE

Conclusion

In this post, we demonstrated how to build a pseudonymization service on AWS. The solution is technology agnostic and can be adopted by any form of consumer as long as they’re able to consume REST APIs. We hope this post helps you in your data protection strategies.

Stay tuned for part 2, which will cover consumption patterns of the pseudonymization service.

About the authors

Edvin Hallvaxhiu is a Senior Global Security Architect with AWS Professional Services and is passionate about cybersecurity and automation. He helps customers build secure and compliant solutions in the cloud. Outside work, he likes traveling and sports.

Rahul Shaurya is a Senior Big Data Architect with AWS Professional Services. He helps and works closely with customers building data platforms and analytical applications on AWS. Outside of work, Rahul loves taking long walks with his dog Barney.

Andrea Montanari is a Big Data Architect with AWS Professional Services. He actively supports customers and partners in building analytics solutions at scale on AWS.

María Guerra is a Big Data Architect with AWS Professional Services. Maria has a background in data analytics and mechanical engineering. She helps customers architecting and developing data related workloads in the cloud.

Pushpraj is a Data Architect with AWS Professional Services. He is passionate about Data and DevOps engineering. He helps customers build data driven applications at scale.

Building AWS Lambda governance and guardrails

Post Syndicated from Julian Wood original https://aws.amazon.com/blogs/compute/building-aws-lambda-governance-and-guardrails/

When building serverless applications using AWS Lambda, there are a number of considerations regarding security, governance, and compliance. This post highlights how Lambda, as a serverless service, simplifies cloud security and compliance so you can concentrate on your business logic. It covers controls that you can implement for your Lambda workloads to ensure that your applications conform to your organizational requirements.

The Shared Responsibility Model

The AWS Shared Responsibility Model distinguishes between what AWS is responsible for and what customers are responsible for with cloud workloads. AWS is responsible for “Security of the Cloud” where AWS protects the infrastructure that runs all the services offered in the AWS Cloud. Customers are responsible for “Security in the Cloud”, managing and securing their workloads. When building traditional applications, you take on responsibility for many infrastructure services, including operating systems and network configuration.

Traditional application shared responsibility

Traditional application shared responsibility

One major benefit when building serverless applications is shifting more responsibility to AWS so you can concentrate on your business applications. AWS handles managing and patching the underlying servers, operating systems, and networking as part of running the services.

Serverless application shared responsibility

Serverless application shared responsibility

For Lambda, AWS manages the application platform where your code runs, which includes patching and updating the managed language runtimes. This reduces the attack surface while making cloud security simpler. You are responsible for the security of your code and AWS Identity and Access Management (IAM) to the Lambda service and within your function.

Lambda is SOCHIPAAPCI, and ISO-compliant. For more information, see Compliance validation for AWS Lambda and the latest Lambda certification and compliance readiness services in scope.

Lambda isolation

Lambda functions run in separate isolated AWS accounts that are dedicated to the Lambda service. Lambda invokes your code in a secure and isolated runtime environment within the Lambda service account. A runtime environment is a collection of resources running in a dedicated hardware-virtualized Micro Virtual Machines (MVM) on a Lambda worker node.

Lambda workers are bare metalEC2 Nitro instances, which are managed and patched by the Lambda service team. They have a maximum lease lifetime of 14 hours to keep the underlying infrastructure secure and fresh. MVMs are created by Firecracker, an open source virtual machine monitor (VMM) that uses Linux’s Kernel-based Virtual Machine (KVM) to create and manage MVMs securely at scale.

MVMs maintain a strong separation between runtime environments at the virtual machine hardware level, which increases security. Runtime environments are never reused across functions, function versions, or AWS accounts.

Isolation model for AWS Lambda workers

Isolation model for AWS Lambda workers

Network security

Lambda functions always run inside secure Amazon Virtual Private Cloud (Amazon VPCs) owned by the Lambda service. This gives the Lambda function access to AWS services and the public internet. There is no direct network inbound access to Lambda workers, runtime environments, or Lambda functions. All inbound access to a Lambda function only comes via the Lambda Invoke API, which sends the event object to the function handler.

You can configure a Lambda function to connect to private subnets in a VPC in your account if necessary, which you can control with IAM condition keys . The Lambda function still runs inside the Lambda service VPC but sends all network traffic through your VPC. Function outbound traffic comes from your own network address space.

AWS Lambda service VPC with VPC-to-VPC NAT to customer VPC

AWS Lambda service VPC with VPC-to-VPC NAT to customer VPC

To give your VPC-connected function access to the internet, route outbound traffic to a NAT gateway in a public subnet. Connecting a function to a public subnet doesn’t give it internet access or a public IP address, as the function is still running in the Lambda service VPC and then routing network traffic into your VPC.

All internal AWS traffic uses the AWS Global Backbone rather than traversing the internet. You do not need to connect your functions to a VPC to avoid connectivity to AWS services over the internet. VPC connected functions allow you to control and audit outbound network access.

You can use security groups to control outbound traffic for VPC-connected functions and network ACLs to block access to CIDR IP ranges or ports. VPC endpoints allow you to enable private communications with supported AWS services without internet access.

You can use VPC Flow Logs to audit traffic going to and from network interfaces in your VPC.

Runtime environment re-use

Each runtime environment processes a single request at a time. After Lambda finishes processing the request, the runtime environment is ready to process an additional request for the same function version. For more information on how Lambda manages runtime environments, see Understanding AWS Lambda scaling and throughput.

Data can persist in the local temporary filesystem path, in globally scoped variables, and in environment variables across subsequent invocations of the same function version. Ensure that you only handle sensitive information within individual invocations of the function by processing it in the function handler, or using local variables. Do not re-use files in the local temporary filesystem to process unencrypted sensitive data. Do not put sensitive or confidential information into Lambda environment variables, tags, or other freeform fields such as Name fields.

For more Lambda security information, see the Lambda security whitepaper.

Multiple accounts

AWS recommends using multiple accounts to isolate your resources because they provide natural boundaries for security, access, and billing. Use AWS Organizations to manage and govern individual member accounts centrally. You can use AWS Control Tower to automate many of the account build steps and apply managed guardrails to govern your environment. These include preventative guardrails to limit actions and detective guardrails to detect and alert on non-compliance resources for remediation.

Lambda access controls

Lambda permissions define what a Lambda function can do, and who or what can invoke the function. Consider the following areas when applying access controls to your Lambda functions to ensure least privilege:

Execution role

Lambda functions have permission to access other AWS resources using execution roles. This is an AWS principal that the Lambda service assumes which grants permissions using identity policy statements assigned to the role. The Lambda service uses this role to fetch and cache temporary security credentials, which are then available as environment variables during a function’s invocation. It may re-use them across different runtime environments that use the same execution role.

Ensure that each function has its own unique role with the minimum set of permissions..

Identity/user policies

IAM identity policies are attached to IAM users, groups, or roles. These policies allow users or callers to perform operations on Lambda functions. You can restrict who can create functions, or control what functions particular users can manage.

Resource policies

Resource policies define what identities have fine-grained inbound access to managed services. For example, you can restrict which Lambda function versions can add events to a specific Amazon EventBridge event bus. You can use resource-based policies on Lambda resources to control what AWS IAM identities and event sources can invoke a specific version or alias of your function. You also use a resource-based policy to allow an AWS service to invoke your function on your behalf. To see which services support resource-based policies, see “AWS services that work with IAM”.

Attribute-based access control (ABAC)

With attribute-based access control (ABAC), you can use tags to control access to your Lambda functions. With ABAC, you can scale an access control strategy by setting granular permissions with tags without requiring permissions updates for every new user or resource as your organization scales. You can also use tag policies with AWS Organizations to standardize tags across resources.

Permissions boundaries

Permissions boundaries are a way to delegate permission management safely. The boundary places a limit on the maximum permissions that a policy can grant. For example, you can use boundary permissions to limit the scope of the execution role to allow only read access to databases. A builder with permission to manage a function or with write access to the applications code repository cannot escalate the permissions beyond the boundary to allow write access.

Service control policies

When using AWS Organizations, you can use Service control policies (SCPs) to manage permissions in your organization. These provide guardrails for what actions IAM users and roles within the organization root or OUs can do. For more information, see the AWS Organizations documentation, which includes example service control policies.

Code signing

As you are responsible for the code that runs in your Lambda functions, you can ensure that only trusted code runs by using code signing with the AWS Signer service. AWS Signer digitally signs your code packages and Lambda validates the code package before accepting the deployment, which can be part of your automated software deployment process.

Auditing Lambda configuration, permissions and access

You should audit access and permissions regularly to ensure that your workloads are secure. Use the IAM console to view when an IAM role was last used.

IAM last used

IAM last used

IAM access advisor

Use IAM access advisor on the Access Advisor tab in the IAM console to review when was the last time an AWS service was used from a specific IAM user or role. You can use this to remove IAM policies and access from your IAM roles.

IAM access advisor

IAM access advisor

AWS CloudTrail

AWS CloudTrail helps you monitor, log, and retain account activity to provide a complete event history of actions across your AWS infrastructure. You can monitor Lambda API actions to ensure that only appropriate actions are made against your Lambda functions. These include CreateFunction, DeleteFunction, CreateEventSourceMapping, AddPermission, UpdateEventSourceMapping,  UpdateFunctionConfiguration, and UpdateFunctionCode.

AWS CloudTrail

AWS CloudTrail

IAM Access Analyzer

You can validate policies using IAM Access Analyzer, which provides over 100 policy checks with security warnings for overly permissive policies. To learn more about policy checks provided by IAM Access Analyzer, see “IAM Access Analyzer policy validation”.

You can also generate IAM policies based on access activity from CloudTrail logs, which contain the permissions that the role used in your specified date range.

IAM Access Analyzer

IAM Access Analyzer

AWS Config

AWS Config provides you with a record of the configuration history of your AWS resources. AWS Config monitors the resource configuration and includes rules to alert when they fall into a non-compliant state.

For Lambda, you can track and alert on changes to your function configuration, along with the IAM execution role. This allows you to gather Lambda function lifecycle data for potential audit and compliance requirements. For more information, see the Lambda Operators Guide.

AWS Config includes Lambda managed config rules such as lambda-concurrency-check, lambda-dlq-check, lambda-function-public-access-prohibited, lambda-function-settings-check, and lambda-inside-vpc. You can also write your own rules.

There are a number of other AWS services to help with security compliance.

  1. AWS Audit Manager: Collect evidence to help you audit your use of cloud services.
  2. Amazon GuardDuty: Detect unexpected and potentially unauthorized activity in your AWS environment.
  3. Amazon Macie: Evaluates your content to identify business-critical or potentially confidential data.
  4. AWS Trusted Advisor: Identify opportunities to improve stability, save money, or help close security gaps.
  5. AWS Security Hub: Provides security checks and recommendations across your organization.

Conclusion

Lambda makes cloud security simpler by taking on more responsibility using the AWS Shared Responsibility Model. Lambda implements strict workload security at scale to isolate your code and prevent network intrusion to your functions. This post provides guidance on assessing and implementing best practices and tools for Lambda to improve your security, governance, and compliance controls. These include permissions, access controls, multiple accounts, and code security. Learn how to audit your function permissions, configuration, and access to ensure that your applications conform to your organizational requirements.

For more serverless learning resources, visit Serverless Land.

AWS Week in Review – August 8, 2022

Post Syndicated from Steve Roberts original https://aws.amazon.com/blogs/aws/aws-week-in-review-august-8-2022/

As an ex-.NET developer, and now Developer Advocate for .NET at AWS, I’m excited to bring you this week’s Week in Review post, for reasons that will quickly become apparent! There are several updates, customer stories, and events I want to bring to your attention, so let’s dive straight in!

Last Week’s launches
.NET developers, here are two new updates to be aware of—and be sure to check out the events section below for another big announcement:

Tiered pricing for AWS Lambda will interest customers running large workloads on Lambda. The tiers, based on compute duration (measured in GB-seconds), help you save on monthly costs—automatically. Find out more about the new tiers, and see some worked examples showing just how they can help reduce costs, in this AWS Compute Blog post by Heeki Park, a Principal Solutions Architect for Serverless.

Amazon Relational Database Service (RDS) released updates for several popular database engines:

  • RDS for Oracle now supports the April 2022 patch.
  • RDS for PostgreSQL now supports new minor versions. Besides the version upgrades, there are also updates for the PostgreSQL extensions pglogical, pg_hint_plan, and hll.
  • RDS for MySQL can now enforce SSL/TLS for client connections to your databases to help enhance transport layer security. You can enforce SSL/TLS by simply enabling the require_secure_transport parameter (disabled by default) via the Amazon RDS Management console, the AWS Command Line Interface (AWS CLI), AWS Tools for PowerShell, or using the API. When you enable this parameter, clients will only be able to connect if an encrypted connection can be established.

Amazon Elastic Compute Cloud (Amazon EC2) expanded availability of the latest generation storage-optimized Is4gen and Im4gn instances to the Asia Pacific (Sydney), Canada (Central), Europe (Frankfurt), and Europe (London) Regions. Built on the AWS Nitro System and powered by AWS Graviton2 processors, these instance types feature up to 30 TB of storage using the new custom-designed AWS Nitro System SSDs. They’re ideal for maximizing the storage performance of I/O intensive workloads that continuously read and write from the SSDs in a sustained manner, for example SQL/NoSQL databases, search engines, distributed file systems, and data analytics.

Lastly, there’s a new URL from AWS Support API to use when you need to access the AWS Support Center console. I recommend bookmarking the new URL, https://support.console.aws.amazon.com/, which the team built using the latest architectural standards for high availability and Region redundancy to ensure you’re always able to contact AWS Support via the console.

For a full list of AWS announcements, be sure to keep an eye on the What’s New at AWS page.

Other AWS News
Here’s some other news items and customer stories that you may find interesting:

AWS Open Source News and Updates – Catch up on all the latest open-source projects, tools, and demos from the AWS community in installment #123 of the weekly open source newsletter.

In one recent AWS on Air livestream segment from AWS re:MARS, discussing the increasing scale of machine learning (ML) models, our guests mentioned billion-parameter ML models which quite intrigued me. As an ex-developer, my mental model of parameters is a handful of values, if that, supplied to methods or functions—not billions. Of course, I’ve since learned they’re not the same thing! As I continue my own ML learning journey I was particularly interested in reading this Amazon Science blog on 20B-parameter Alexa Teacher Models (AlexaTM). These large-scale multilingual language models can learn new concepts and transfer knowledge from one language or task to another with minimal human input, given only a few examples of a task in a new language.

When developing games intended to run fully in the cloud, what benefits might there be in going fully cloud-native and moving the entire process into the cloud? Find out in this customer story from Return Entertainment, who did just that to build a cloud-native gaming infrastructure in a few months, reducing time and cost with AWS services.

Upcoming events
Check your calendar and sign up for these online and in-person AWS events:

AWS Storage Day: On August 10, tune into this virtual event on twitch.tv/aws, 9:00 AM–4.30 PM PT, where we’ll be diving into building data resiliency into your organization, and how to put data to work to gain insights and realize its potential, while also optimizing your storage costs. Register for the event here.

AWS SummitAWS Global Summits: These free events bring the cloud computing community together to connect, collaborate, and learn about AWS. Registration is open for the following AWS Summits in August:

AWS .NET Enterprise Developer Days 2022 – North America: Registration for this free, 2-day, in-person event and follow-up 2-day virtual event opened this past week. The in-person event runs September 7–8, at the Palmer Events Center in Austin, Texas. The virtual event runs September 13–14. AWS .NET Enterprise Developer Days (.NET EDD) runs as a mini-conference within the DeveloperWeek Cloud conference (also in-person and virtual). Anyone registering for .NET EDD is eligible for a free pass to DeveloperWeek Cloud, and vice versa! I’m super excited to be helping organize this third .NET event from AWS, our first that has an in-person version. If you’re a .NET developer working with AWS, I encourage you to check it out!

That’s all for this week. Be sure to check back next Monday for another Week in Review roundup!

— Steve
This post is part of our Week in Review series. Check back each week for a quick roundup of interesting news and announcements from AWS!

Estimating cost for Amazon SQS message processing using AWS Lambda

Post Syndicated from James Beswick original https://aws.amazon.com/blogs/compute/estimating-cost-for-amazon-sqs-message-processing-using-aws-lambda/

This post was written by Sabha Parameswaran, Senior Solutions Architect.

AWS Lambda enables fully managed asynchronous messaging processing through integration with Amazon SQS. This blog post helps estimate the cost and performance benefits when using Lambda to handle millions of messages per day by using a simulated setup.

Overview

Lambda supports asynchronous handling of messages using SQS integration as an event source and can scale for handling millions of messages per day. Customers often ask about the cost of implementing a Lambda-based messaging solution.

There are multiple variables like Lambda function runtime, individual message size, batch size for consuming from SQS, processing latency per message (depending on the backend services invoked), and function memory size settings. These can determine the overall performance and associated cost of a Lambda-based messaging solution.

This post provides cost estimation using these variables, along with guidance around optimization. The estimates focus on consuming from standard queues and not FIFO queues.

SQS event source

The Lambda event source mapping supports integration for SQS. Lambda users specify the SQS queue to consume messages. Lambda internally polls the queue and invokes the function synchronously with an event containing the queue messages.

The configuration controls in Lambda for consuming messages from an SQS queue are:

  • Batch size: The maximum number of records that can be batched as one event delivered to the consuming Lambda function. The maximum batch size is 10,000 records.
  • Batch window: The maximum time (in seconds) to gather records as a single batch. A larger batch window size means waiting longer for a larger SQS batch of messages before passing to the Lambda function.
  • SQS content filtering: Selecting only the messages that match a defined content criteria. This can reduce cost by removing unwanted or irrelevant messages. Lambda now supports content filtering (for SQS, Kinesis, and DynamoDB) and developers can use the filtering capabilities to avoid processing SQS messages, reducing unnecessary invocations and associated cost.

Lambda sends as many records in a single batch as allowed by the batch size, as long as it’s earlier than the batch window value, and smaller than the maximum payload size of 6 MB. Having large batch sizes means that a single Lambda invocation can handle more messages rather than multiple Lambda invocations to handle smaller batches (which translates to setting higher concurrency limits).

The cost and time to process might vary based on the actual number of messages in the batch. A larger batch size can imply longer processing but requires lower concurrency (number of concurrent Lambda invocations).

Lambda configurations

Lambda function costs are calculated based on memory used and time spent (in GB-second) in execution of a function. Aside from the event source configuration, there are several other Lambda function configurations that impact cost and performance:

  • Processor type: Lambda functions provide options to choose between x86 and Arm/Graviton processors. The newer Arm/Graviton processors can yield a higher performance and lower cost compared to x86 based on the workload. Compare the options and run tests before selecting.
  • Memory allotted: This is directly proportional to the CPU allotted to the function and translates to price for each invocation. Higher memory can lead to faster execution but also higher cost. The optimal memory required for a small batch versus large batch can vary based on the workload, size of incoming messages, transformations, requirements to store intermediate, or final results. Optimal tuning of the memory configurations is key to ensuring right cost versus performance. See the AWS Lambda Power Tuning documentation for more details on identifying the optimal memory versus performance for a fixed batch size and then extrapolate the memory settings for larger batch sizes.
  • Lambda function runtime: Some runtimes have a smaller memory footprint and may be more cost effective than others that are memory intensive. Choosing the runtime affects the memory allocation.
  • Function performance: This can be considered as TPS – total number of requests completed per second. Or conversely measured as time to complete one request. The performance – time to finish a function execution can be dependent on the event containing the batch of messages; bigger batches mean more time to complete an event and complexity and dependencies (performance of the backend that needs to be invoked) of the message processing. The calculations are based on the assumption that the Lambda function and related dependencies have been optimized and tuned to scale linearly with various batch sizes and number of invocations.
  • Concurrency: Number of concurrent Lambda function executions. Concurrency is important for scaling of Lambda functions, allowing users to delegate the capacity planning and scaling to thee Lambda service.

The higher the concurrency, the more workloads it can process in a shorter time, allowing better performance, but this does not change the overall cost. Concurrency is not equivalent to TPS: it is more of a scaling factor in overall TPS. For example, a workload comprised of a set of messages takes 20 seconds to complete. 100 workloads would mean 2000 seconds to complete. With a concurrency of 10, it takes 200 seconds. With a concurrency of 100, the time drops to 20 seconds as each of the 100 workloads are handled concurrently. But each function essentially runs for the same duration and memory, regardless of concurrency. So the cost remains the same, as it is measured in GB-hours (memory multiplied by time). But the performance view differs. So, the cost estimations do not consider the concurrency settings of Lambda functions as the workloads have to be processed either sequential or concurrently.

Assumptions

The cost estimation tool presented helps users estimate monthly Lambda function costs for processing SQS standard queue messages based on the following assumptions:

  • The system has reached steady state and has millions of messages available to be consumed per day in standard queues. The number of messages per day remains constant throughout the entire month.
  • Since it’s a steady state, there are no associated Lambda function cold start delays.
  • All SQS messages that need to be processed successfully have already met the filter criteria. Also, no poison messages that have to be re-tried repeatedly. Messages are not going to be rejected, unacknowledged, or reprocessed.
  • The workload scales linearly in performance versus batch size. All the associated dependencies can scale linearly and a batch of N messages should take the same time as N x a single message with a fixed overhead per function invocation irrespective of the batch size. For example, a function’s overhead is 50 ms irrespective of the batch size. Processing a single message takes 20 ms. So a batch of 20 messages should take 490 ms (50 + 20*20) versus a batch of 5 messages takes 150 ms (50 + 5*20).
  • Function memory increases in steps, based on increasing the batch size. For example, 100 messages uses a 256 MB of baseline memory. Every additional 500 messages require additional 128 MB of memory. A sliding window of memory to batch size:
Batch size Memory
1–100 256 MB
100–600 384 MB
600–1100 512 MB
1100–1600 640 MB

Lambda uses SQS APIs internally to poll and dequeue the messages. The costs for the polling and dequeue operations using SQS APIs are not included as part of the estimations. The internal SQS dequeue portion is outside the control of the Lambda developer and the cost estimates only cover the message processing using Lambda. Also, the tool does not consider any reprocessing or duplicate processing of messages due to exceptions or errors that can vary the cost.

Using the cost estimation tool

The estimator tool is a Python-based command line program that takes in an input properties file that specifies the various input parameters to come up with Lambda function cost versus performance estimations for various batch sizes, messages per day, etc. The tool does take into account the eligible monthly free tier for Lambda function executions.

Pre-requisites: Running the tool requires Python 3.9 and installation of Plotly package (5.7.+) or creating and using Docker images.

To run the tool:

  1. Clone the repo: 
    git clone https://github.com/aws-samples/aws-lambda-sqs-cost-estimator
  2. Install the tool: 
    cd aws-lambda-sqs-cost-estimator/code
pip3 install -r requirements.txt
  3. Edit the input.prop file and run the tool to generate cost estimations: 
    python3 LambdaPlotly.py

This shows the cost estimates on a local browser instance. Running the code as a Docker image is also supported. Refer to the GitHub repo for additional instructions.

  1. Clone the repo and build the Docker container: 
    git clone https://github.com/aws-samples/aws-lambda-sqs-cost-estimator
cd aws-lambda-sqs-cost-estimator/code
docker build -t lambda-dash .
  2. Edit the input.prop file and run the tool to generate cost estimations: 
    docker run -it -v `pwd`:/app -p 8080:8080 lambda-dash
  3. Navigate to http://0.0.0.0:8080/app in a browser to view the generated cost estimate plot.

There are various input parameters for the cost estimations specified inside the input.prop file. Tune the input parameters as needed:

Parameter Description Sample value (units not included)
base_lambda_memory_mb Baseline memory for the Lambda function (in MB) 128
warm_latency_ms Invocation time for Lambda handler method (going with warm start) irrespective of batch size in the incoming event payload in ms 20
process_per_message_ms Time to process a single message (linearly scales with number of messages per batch in event payload) in ms 10
max_batch_size Maximum batch size per event payload processed by a single Lambda instance 1000 (max is 10000)
batch_memory_overhead_mb Additional memory for processing increments in batch size (in MB) 128
batch_increment Increments of batch size for increased memory 300

The following is sample input.prop file content:

base_lambda_memory_mb=128

# Total process time for N messages in batch = warm_latency_ms + (process_per_message_ms * N)

# Time spent in function initialization/warm-up

warm_latency_ms=20

# Time spent for processing each message in milliseconds

process_per_message_ms=10

# Max batch size

max_batch_size=1000

# Additional lambda memory X mb required for managing/parsing/processing N additional messages processed when using variable batch sizes

#batch_memory_overhead_mb=X

#batch_increment=N

batch_memory_overhead_mb=128

batch_increment=300

The tool generates a page with plot graphs and tables with 3 sections:

Cost example

There is an accompanying interactive legend showing cost and batch size. The top section shows a graph of cost versus message volumes versus batch size:

cost versus message volumes vs Batch size

The second section shows the actual cost variation for different batch sizes for 10 million messages:

actual cost variation for different batch sizes for 10 million messages.

The third section shows the memory and time required to process with different batch sizes:

memory and time required to process with different batch sizes

The various control input parameters used for graph generation are shown at the bottom of the page.

Double-clicking on a specific batch size or line on the right-hand legend displays that specific plot with its pricing details.

specific plot to be displayed with its pricing details

You can modify the input parameters with different settings for memory, batch sizes, memory for increased batches and rerun the program to create different cost estimations. You can also export the generated graphs as PNG image files for reference.

Conclusion

You can use Lambda functions to handle fully managed asynchronous processing of SQS messages. Estimating the cost and optimal setup depends on leveraging the various configurations of SQS and Lambda functions. The cost estimator tool presented in this blog should help you understand these configurations and their impact on the overall cost and performance of the Lambda function-based messaging solutions.

For more serverless learning resources, visit Serverless Land.

Coordinating large messages across accounts and Regions with Amazon SNS and SQS

Post Syndicated from Mrudhula Balasubramanyan original https://aws.amazon.com/blogs/architecture/coordinating-large-messages-across-accounts-and-regions-with-amazon-sns-and-sqs/

Many organizations have applications distributed across various business units. Teams in these business units may develop their applications independent of each other to serve their individual business needs. Applications can reside in a single Amazon Web Services (AWS) account or be distributed across multiple accounts. Applications may be deployed to a single AWS Region or span multiple Regions.

Irrespective of how the applications are owned and operated, these applications need to communicate with each other. Within an organization, applications tend to be part of a larger system, therefore, communication and coordination among these individual applications is critical to overall operation.

There are a number of ways to enable coordination among component applications. It can be done either synchronously or asynchronously:

  • Synchronous communication uses a traditional request-response model, in which the applications exchange information in a tightly coupled fashion, introducing multiple points of potential failure.
  • Asynchronous communication uses an event-driven model, in which the applications exchange messages as events or state changes and are loosely coupled. Loose coupling allows applications to evolve independently of each other, increasing scalability and fault-tolerance in the overall system.

Event-driven architectures use a publisher-subscriber model, in which events are emitted by the publisher and consumed by one or more subscribers.

A key consideration when implementing an event-driven architecture is the size of the messages or events that are exchanged. How can you implement an event-driven architecture for large messages, beyond the default maximum of the services? How can you architect messaging and automation of applications across AWS accounts and Regions?

This blog presents architectures for enhancing event-driven models to exchange large messages. These architectures depict how to coordinate applications across AWS accounts and Regions.

Challenge with application coordination

A challenge with application coordination is exchanging large messages. For the purposes of this post, a large message is defined as an event payload between 256 KB and 2 GB. This stems from the fact that Amazon Simple Notification Service (Amazon SNS) and Amazon Simple Queue Service (Amazon SQS) currently have a maximum event payload size of 256 KB. To exchange messages larger than 256 KB, an intermediate data store must be used.

To exchange messages across AWS accounts and Regions, set up the publisher access policy to allow subscriber applications in other accounts and Regions. In the case of large messages, also set up a central data repository and provide access to subscribers.

Figure 1 depicts a basic schematic of applications distributed across accounts communicating asynchronously as part of a larger enterprise application.

Asynchronous communication across applications

Figure 1. Asynchronous communication across applications

Architecture overview

The overview covers two scenarios:

  1. Coordination of applications distributed across AWS accounts and deployed in the same Region
  2. Coordination of applications distributed across AWS accounts and deployed to different Regions

Coordination across accounts and single AWS Region

Figure 2 represents an event-driven architecture, in which applications are distributed across AWS Accounts A, B, and C. The applications are all deployed to the same AWS Region, us-east-1. A single Region simplifies the architecture, so you can focus on application coordination across AWS accounts.

Application coordination across accounts and single AWS Region

Figure 2. Application coordination across accounts and single AWS Region

The application in Account A (Application A) is implemented as an AWS Lambda function. This application communicates with the applications in Accounts B and C. The application in Account B is launched with AWS Step Functions (Application B), and the application in Account C runs on Amazon Elastic Container Service (Application C).

In this scenario, Applications B and C need information from upstream Application A. Application A publishes this information as an event, and Applications B and C subscribe to an SNS topic to receive the events. However, since they are in other accounts, you must define an access policy to control who can access the SNS topic. You can use sample Amazon SNS access policies to craft your own.

If the event payload is in the 256 KB to 2 GB range, you can use Amazon Simple Storage Service (Amazon S3) as the intermediate data store for your payload. Application A uses the Amazon SNS Extended Client Library for Java to upload the payload to an S3 bucket and publish a message to an SNS topic, with a reference to the stored S3 object. The message containing the metadata must be within the SNS maximum message limit of 256 KB. Amazon EventBridge is used for routing events and handling authentication.

The subscriber Applications B and C need to de-reference and retrieve the payloads from Amazon S3. The SQS queue in Account B and Lambda function in Account C subscribe to the SNS topic in Account A. In Account B, a Lambda function is used to poll the SQS queue and read the message with the metadata. The Lambda function uses the Amazon SQS Extended Client Library for Java to retrieve the S3 object referenced in the message.

The Lambda function in Account C uses the Payload Offloading Java Common Library for AWS to get the referenced S3 object.

Once the S3 object is retrieved, the Lambda functions in Accounts B and C process the data and pass on the information to downstream applications.

This architecture uses Amazon SQS and Lambda as subscribers because they provide libraries that support offloading large payloads to Amazon S3. However, you can use any Java-enabled endpoint, such as an HTTPS endpoint that uses Payload Offloading Java Common Library for AWS to de-reference the message content.

Coordination across accounts and multiple AWS Regions

Sometimes applications are spread across AWS Regions, leading to increased latency in coordination. For existing applications, it could take substantive effort to consolidate to a single Region. Hence, asynchronous coordination would be a good fit for this scenario. Figure 3 expands on the architecture presented earlier to include multiple AWS Regions.

Application coordination across accounts and multiple AWS Regions

Figure 3. Application coordination across accounts and multiple AWS Regions

The Lambda function in Account C is in the same Region as the upstream application in Account A, but the Lambda function in Account B is in a different Region. These functions must retrieve the payload from the S3 bucket in Account A.

To provide access, configure the AWS Lambda execution role with the appropriate permissions. Make sure that the S3 bucket policy allows access to the Lambda functions from Accounts B and C.

Considerations

For variable message sizes, you can specify if payloads are always stored in Amazon S3 regardless of their size, which can help simplify the design.

If the application that publishes/subscribes large messages is implemented using the AWS Java SDK, it must be Java 8 or higher. Service-specific client libraries are also available in Python, C#, and Node.js.

An Amazon S3 Multi-Region Access Point can be an alternative to a centralized bucket for the payloads. It has not been explored in this post due to the asynchronous nature of cross-region replication.

In general, retrieval of data across Regions is slower than in the same Region. For faster retrieval, workloads should be run in the same AWS Region.

Conclusion

This post demonstrates how to use event-driven architectures for coordinating applications that need to exchange large messages across AWS accounts and Regions. The messaging and automation are enabled by the Payload Offloading Java Common Library for AWS and use Amazon S3 as the intermediate data store. These components can simplify the solution implementation and improve scalability, fault-tolerance, and performance of your applications.

Ready to get started? Explore SQS Large Message Handling.

Securely retrieving secrets with AWS Lambda

Post Syndicated from Julian Wood original https://aws.amazon.com/blogs/compute/securely-retrieving-secrets-with-aws-lambda/

AWS Lambda functions often need to access secrets, such as certificates, API keys, or database passwords. Storing secrets outside the function code in an external secrets manager helps to avoid exposing secrets in application source code. Using a secrets manager also allows you to audit and control access, and can help with secret rotation. Do not store secrets in Lambda environment variables, as these are visible to anyone who has access to view function configuration.

This post highlights some solutions to store secrets securely and retrieve them from within your Lambda functions.

AWS Partner Network (APN) member Hashicorp provides Vault to secure secrets and application data. Vault allows you to control access to your secrets centrally, across applications, systems, and infrastructure. You can store secrets in Vault and access them from a Lambda function to access a database, for example. The Vault Agent for AWS helps you authenticate with Vault, retrieve the database credentials, and then perform the queries. You can also use the Vault AWS Lambda extension to manage connectivity to Vault.

AWS Systems Manager Parameter Store enables you to store configuration data securely, including secrets, as parameter values. For information on Parameter Store pricing, see the documentation.

AWS Secrets Manager allows you to replace hardcoded credentials in your code with an API call to Secrets Manager to retrieve the secret programmatically. You can generate, protect, rotate, manage, and retrieve secrets throughout their lifecycle. By default, Secrets Manager does not write or cache the secret to persistent storage. Secrets Manager supports cross-account access to secrets. For information on Secrets Manager pricing, see the documentation.

Parameter Store integrates directly with Secrets Manager as a pass-through service for references to Secrets Manager secrets. Use this integration if you prefer using Parameter Store as a consistent solution for calling and referencing secrets across your applications. For more information, see “Referencing AWS Secrets Manager secrets from Parameter Store parameters.”

For an example application to show Secrets Manager functionality, deploy the example detailed in “How to securely provide database credentials to Lambda functions by using AWS Secrets Manager”.

When to retrieve secrets

When Lambda first invokes your function, it creates a runtime environment. It runs the function’s initialization (init) code, which is the code outside the main handler. Lambda then runs the function handler code as the invocation. This receives the event payload and processes your business logic. Subsequent invocations can use the same runtime environment.

You can retrieve secrets during each function invocation from within your handler code. This ensures that the secret value is always up to date but can lead to increased function duration and cost, as the function calls the secret manager during each invocation. There may also be additional retrieval costs from Secret Manager.

Retrieving secret during each invocation

Retrieving secret during each invocation

You can reduce costs and improve performance by retrieving the secret during the function init process. During subsequent invocations using the same runtime environment, your handler code can use the same secret.

Retrieving secret during function initialization.

Retrieving secret during function initialization.

The Serverless Land pattern example shows how to retrieve a secret during the init phase using Node.js and top-level await.

If a secret may change between subsequent invocations, ensure that your handler can check for the secret validity and, if necessary, retrieve the secret again.

Retrieve changed secret during subsequent invocation.

Retrieve changed secret during subsequent invocation.

You can also use Lambda extensions to retrieve secrets from Secrets Manager, cache them, and automatically refresh the cache based on a time value. The extension retrieves the secret from Secrets Manager before the init process and makes it available via a local HTTP endpoint. The function then retrieves the secret from the local HTTP endpoint, rather than directly from Secrets Manager, increasing performance. You can also share the extension with multiple functions, which can reduce function code. The extension handles refreshing the cache based on a configurable timeout value. This ensures that the function has the updated value, without handling the refresh in your function code, which increases reliability.

Using Lambda extensions to cache and refresh secret.

Using Lambda extensions to cache and refresh secret.

You can deploy the solution using the steps in Cache secrets using AWS Lambda extensions.

Lambda Powertools

Lambda Powertools provides a suite of utilities for Lambda functions to simplify the adoption of serverless best practices. AWS Lambda Powertools for Python and AWS Lambda Powertools for Java both provide a parameters utility that integrates with Secrets Manager.

from aws_lambda_powertools.utilities import parameters
def handler(event, context):
    # Retrieve a single secret
    value = parameters.get_secret("my-secret")
import software.amazon.lambda.powertools.parameters.SecretsProvider;
import software.amazon.lambda.powertools.parameters.ParamManager;

public class AppWithSecrets implements RequestHandler<APIGatewayProxyRequestEvent, APIGatewayProxyResponseEvent> {
    // Get an instance of the Secrets Provider
    SecretsProvider secretsProvider = ParamManager.getSecretsProvider();

    // Retrieve a single secret
    String value = secretsProvider.get("/my/secret");

Rotating secrets

You should rotate secrets to prevent the misuse of your secrets. This helps you to replace long-term secrets with short-term ones, which reduces the risk of compromise.

Secrets Manager has built-in functionality to rotate secrets on demand or according to a schedule. Secrets Manager has native integrations with Amazon RDS, Amazon DocumentDB, and Amazon Redshift, using a Lambda function to manage the rotation process for you. It deploys an AWS CloudFormation stack and populates the function with the Amazon Resource Name (ARN) of the secret. You specify the permissions to rotate the credentials, and how often you want to rotate the secret. You can view and edit Secrets Manager rotation settings in the Secrets Manager console.

Secrets Manager rotation settings

Secrets Manager rotation settings

You can also create your own rotation Lambda function for other services.

Auditing secrets access

You should continually review how applications are using your secrets to ensure that the usage is as you expect. You should also log any changes to them so you can investigate any potential issues, and roll back changes if necessary.

When using Hashicorp Vault, use Audit devices to log all requests and responses to Vault. Audit devices can append logs to a file, write to syslog, or write to a socket.

Secrets Manager supports logging API calls using AWS CloudTrail. CloudTrail monitors and records all API calls for Secrets Manager as events. This includes calls from code calling the Secrets Manager APIs and access via the Secrets Manager console. CloudTrail data is considered sensitive, so you should use AWS KMS encryption to protect it.

The CloudTrail event history shows the requests to secretsmanager.amazonaws.com.

Viewing CloudTrail access to Secrets Manager

Viewing CloudTrail access to Secrets Manager

You can use Amazon EventBridge to respond to alerts based on specific operations recorded in CloudTrail. These include secret rotation or deleted secrets. You can also generate an alert if someone tries to use a version of a secret version while it is pending deletion. This may help identify and alert you when an outdated certificate is used.

Securing secrets

You must tightly control access to secrets because of their sensitive nature. Create AWS Identity and Access Management (IAM) policies and resource policies to enable minimal access to secrets. You can use role-based, as well as attribute-based, access control. This can prevent credentials from being accidentally used or compromised. For more information, see “Authentication and access control for AWS Secrets Manager”.

Secrets Manager supports encryption at rest using AWS Key Management Service (AWS KMS) using keys that you manage. Secrets are encrypted in transit using TLS by default, which requires request signing.

You can access secrets from inside an Amazon Virtual Private Cloud (Amazon VPC) without requiring internet access. Use AWS PrivateLink and configure a Secrets Manager specific VPC endpoint.

Do not store plaintext secrets in Lambda environment variables. Ensure that you do not embed secrets directly in function code, commit these secrets to code repositories, or log the secret to CloudWatch.

Conclusion

Using a secrets manager to store secrets such as certificates, API keys or database passwords helps to avoid exposing secrets in application source code. This post highlights some AWS and third-party solutions, such as Hashicorp Vault, to store secrets securely and retrieve them from within your Lambda functions.

Secrets Manager is the preferred AWS solution for storing and managing secrets. I explain when to retrieve secrets, including using Lambda extensions to cache secrets, which can reduce cost and improve performance.

You can use the Lambda Powertools parameters utility, which integrates with Secrets Manager. Rotating secrets reduces the risk of compromise and you can audit secrets using CloudTrail and respond to alerts using EventBridge. I also cover security considerations for controlling access to your secrets.

For more serverless learning resources, visit Serverless Land.