Tag Archives: AWS Lambda

Load testing a web application’s serverless backend

2020-07-06 James Beswick

Post Syndicated from James Beswick original https://aws.amazon.com/blogs/compute/load-testing-a-web-applications-serverless-backend/

Many web applications experience high levels of traffic and spiky load patterns. The goal of load testing is to ensure that the architecture and system design works for the amount of traffic expected. It can help developers find bottlenecks and unexpected behavior before a system is deployed to production. This post uses the Ask Around Me application as an example to show how to test load in a serverless architecture.

In Ask Around Me, users ask and answer questions in their local geographic area. The expected hourly load is 1,000 new questions, 10,000 new answers, and 50,000 question lookup queries. I use these numbers as a baseline for the tests. This is the architecture of the Ask Around Me backend application:

Focus areas for load testing

In serverless architectures using AWS services, you can perform a round-trip test from an API endpoint. You can also isolate areas in the design where you should test performance. API testing provides the best approximation of the performance that users experience but it may not always be possible. You can also isolate microservices consuming from SQS queue or receive events from Amazon EventBridge, and test only those parts of the infrastructure.

While AWS services are built to withstand high levels of traffic, it’s important to consider the effect of Service Quotas on your application. Service Quotas are applied at the Region and account levels depending upon the service. You can view all your quotas in one place from the Service Quotas console. These are designed to protect you and other customers if your applications use more resources than planned. These quotas consist of hard and soft limits. For soft limits, you can request quota increases by opening a support ticket.

You must also consider downstream services. While serverless services like Lambda scale on your behalf, you may use downstream services that could be overwhelmed when traffic increases. Load testing can help identify these areas. You can implement mechanisms like queuing, caching, or pooling to protect those non-serverless parts of your infrastructure. If you are using Amazon RDS, for example, you might implement Amazon RDS Proxy to help pool and scale resources.

Finally, load testing can help identify custom code in Lambda functions that may not run efficiently as traffic scales up. Typically, these issues are caused by the code itself or the function configuration. For example, code may process event batches effectively or may not be configured with the appropriate concurrency or memory configuration. Frequently these issues are unnoticed in development but resurface in a load test.

Load testing tools

Load testing serverless infrastructure can be both inexpensive and systematic. There are several tools available for serverless developers to perform this task. One of the most popular is Artillery Community Edition, which is an open-source tool for testing serverless APIs. You configure the number of requests per second and overall test duration, and it uses a headless Chromium browser to run its test flows.

The performance report measures the roundtrip time from the client device, so can be affected by your machine’s performance and network. One way to eliminate your local network’s impact on the results is to use AWS Cloud9 to run the tests remotely.

For Artillery, the maximum number of concurrent tests is constrained by your local computing resources and network. To achieve higher throughput, you can use Serverless Artillery, which runs the Artillery package on Lambda functions. As a result, this tool can scale up to a significantly higher number of tests.

The Ask Around Me application is deployed in my AWS account – see the application’s blog series to learn more about the deployment process. I use an AWS Cloud9 instance to run these API tests:

Adding 1,000 questions per hour using the POST /questions API.
Adding 10,000 answers per hour using the POST /answers API.
Fetching 50,000 questions per hour based upon random geo-location using the GET /questions API.

You can find the test scripts and Artillery configurations in the testing directory of the application’s GitHub repo.

Artillery also enables you to specify custom functions to provide randomized data and custom query parameters, as required by your API. The loadTestFunction.js file contains a function to return randomized geo-point and rating data per test:

// Sets a bounding box around an area in Virginia, USA
const bounds = {
  latMax: 38.735083,
  latMin: 40.898677,
  lngMax: -77.109339,
  lngMin: -81.587841
}

const generateRandomData = (userContext, events, done) => {
  const randomLat = ((bounds.latMax-bounds.latMin) * Math.random()) + bounds.latMin
  const randomLng = ((bounds.lngMax-bounds.lngMin) * Math.random()) + bounds.lngMin

  const id = parseInt(Math.random()*1000000)+1  //random 0-1000000
  const rating = parseInt(Math.random()*5)+1    //returns 1-5

  userContext.vars.lat = randomLat.toFixed(7)
  userContext.vars.lng = randomLng.toFixed(7)
  userContext.vars.id = id
  userContext.vars.rating = rating

  return done()
}

module.exports = { generateRandomData }

Test #1: Adding 1,000 questions per hour

The POST questions API has the following architecture:

The Artillery configuration file 1-test.yaml is set to create three requests per second over a 5-minute duration. This equates to 10,800 questions per hour, significantly higher than the estimated load for this function. The scenario specifies the JSON payload expected by the questions API:

config:
  target: 'https://abcd1234567.execute-api.us-east-1.amazonaws.com'
  phases:
    - duration: 300
      arrivalRate: 3
  processor: "./loadTestFunction.js"          
  defaults:
    headers:
      Authorization: 'Bearer <<enter your valid JWT token>>'
scenarios:
  - flow:
    - function: "generateRandomData"
    - post:
        url: "/questions"
        json:
          question: "This is a load test question - #{{ id }}"
          type: "Star rating"
          position:
            latitude: {{ lat }}
            longitude: {{ lng }}
    - log: "Sent POST request to / with {{ lat }}, {{ lng }}"

You execute the Artillery test with the command artillery run ./1-test.yaml. My test concludes with the following results:

Over 300 requests, the median response time is 114 ms. The p95 response time shows that 95% of all responses are served within 376 ms. The slowest response of 1401 ms is caused by cold starts when the Lambda service scales up the underlying function due to load.

As this process writes to a DynamoDB table, I can also see how many write capacity units (WCUs) are consumed by the test. From the DynamoDB console, select the table aamQuestions, then choose the Metrics tab. This shows the Write capacity metric:

Test #2: Adding 10,000 answers per hour.

The POST answers API has the following architecture:

The Artillery configuration in 2-test.yaml creates 10 answers per second over a 5-minute duration. This equates to 36,000 per hour, much higher than the estimated load. The scenario defines the randomized rating used by the testing process:

config:
  target: 'https://abcd1234567.execute-api.us-east-1.amazonaws.com'
  phases:
    - duration: 300
      arrivalRate: 10
  processor: "./loadTestFunction.js"          
  defaults:
    headers:
      Authorization: 'Bearer <<enter your valid JWT token>>’
scenarios:
  - flow:
    - function: "generateRandomData"
    - post:
        url: "/answers"
        json:
          type: "Star"
          rating: "{{ rating }}"
          question: 
            type: "Star"
            latitude: 39.08259127440097
            longitude: -77.46246339003038
            rangeKey: "testuser|1-1589380702281"
    - log: "Sent POST request to / with {{ rating }}"

The test results show a median response time of 111 ms with a p95 time of 218 ms. In the worst case, a request took 1102 ms to complete:

Checking the Metrics tab for the aaAnswers table, this test consumed just under 11 WCUs at peak:

Test #3: Fetching 50,000 questions per hour

The GET questions API invokes a Lambda function that uses the Geo Library for Amazon DynamoDB:

This process is read-intensive on the underlying DynamoDB table. The testing configuration simulates 20 queries per second over 2 minutes for random locations in a bounding box around Virginia, USA:

config:
  target: 'https://abcd1234567.execute-api.us-east-1.amazonaws.com'
  phases:
    - duration: 120
      arrivalRate: 20
  processor: "./loadTestFunction.js"          
  defaults:
    headers:
      Authorization: 'Bearer <<enter your valid JWT token>>’
scenarios:
  - flow:
    - function: "generateRandomData"
    - get:
        url: "/questions"
        qs:
          lat: "{{ lat }}"
          lng: "{{ lng }}"
    - log: "Sent POST request to / with {{ lat }}, {{ lng }}"

This is a synchronous API so the performance directly impacts the user’s experience of the application. This test shows that the median response time is 165 ms with a p95 time of 201 ms:

This level of load equates to 72,000 queries per hour, almost 50% above the expected usage. The DynamoDB metrics show a peak consumption of 82 read capacity units:

Testing authenticated routes

These API routes are protected from public access and require authorization. This application uses HTTP APIs, which accepts JWT tokens, and it uses Auth0 in the frontend application to generate these tokens. When you are load testing API Gateway routes with custom authorizers, you have a number of options.

At the early development stage, you may choose to remove the authentication to perform load tests. This simplifies the process but is not recommended beyond research and prototyping. If you turn off authentication for testing, there is a risk that it is not enabled again for production. This would leave your routes open to the public.

A better approach is to create a test user in your identity provider and use the JWT token for testing. Auth0 allows you to obtain a token manually, and use this in the Artillery configuration for the authorization header:

Since custom code frequently uses the decoded identity in processing, supplying a test token provides the closest simulation of actual usage. You must refresh this token in the test scripts periodically, and you can change scopes as needed.

The testing directory in the GitHub repo also includes a script for testing functions that consume from SQS queues. This allows you to test microservices further down in your infrastructure stack. This script injects messages into the SQS queue, simulating upstream processes.

Conclusion

In this post, I discuss focus areas for load testing of serverless applications, and highlight two tools commonly used. I show how to configure Artillery with customized functions, and how to run tests to simulate load on the Ask Around Me application.

I cover some of the options for testing authenticated API Gateway routes and how you can use JWT tokens in your load testing configuration. You can also test microservices within a serverless architecture by injecting messages into SQS queues to simulate upstream load.

To learn more about the Ask Around Me serverless applications, read the blog series.

Using AWS ParallelCluster serverless API for AWS Batch

2020-06-30 James Beswick

Post Syndicated from James Beswick original https://aws.amazon.com/blogs/compute/using-aws-parallelcluster-serverless-api-for-aws-batch/

This post is courtesy of Dario La Porta, Senior Consultant, HPC.

This blog is a continuation of a series of posts demonstrating how to create serverless architectures to support HPC workloads run with AWS ParallelCluster.

The first post, Using AWS ParallelCluster with a serverless API, explains how to create a serverless API for the AWS ParallelCluster command line interface. The second post, Amazon API Gateway for HPC job submission, shows how to submit jobs to a cluster that uses a Slurm job scheduler through a similar serverless API. In this post, I create a serverless API of the AWS Batch command line interface inside ParallelCluster. This uses AWS ParallelCluster, Amazon API Gateway, and AWS Lambda.

The integration of ParallelCluster with AWS Batch replaces the need of third-party batch processing solutions. It also natively integrates with the AWS Cloud.

Many use cases can benefit from this approach. The financial services industry can automate the resourcing and scheduling of the jobs to accelerate decision-making and reduce cost. Life sciences companies can discover new drugs in a more efficient way.

Submitting HPC workloads through a serverless API enables additional workflows. You can extend on-premises clusters to run specific jobs on AWS’ scalable infrastructure to leverage its elasticity and scale. For example, you can create event-driven workflows that run in response to new data being stored in an S3 bucket.

Using a serverless API as described in this post can improve security by removing the need to log in to EC2 instances to use the AWS Batch CLI in AWS ParallelCluster.

Together, this class of workflow can further improve the security of your infrastructure and dat. It can also help optimize researchers’ time and efficiency.

In this post, I show how to create the AWS Batch cluster using AWS ParallelCluster. I then explain how to build the serverless API used for the interaction with the cluster. Finally, I explain how to use the API to query the resources of the cluster and submit jobs.

This diagram shows the different components of the solution.

AWS ParallelCluster configuration

AWS ParallelCluster is an open source cluster management tool to deploy and manage HPC clusters in the AWS Cloud.

The same procedure, described in the Using AWS ParallelCluster with a serverless API post, is used to create the AWS Batch cluster in the new template.yml and pcluster.conf file. The template.yml file contains the required policies for the Lambda function to build the AWS Batch cluster. Be sure to modify <AWS ACCOUNT ID> and <REGION> to match the value for your account.

The pcluster.conf file contains the AWS ParallelCluster configuration to build a cluster using AWS Batch as the job scheduler. The master_subnet_id is the id of the created public subnet and the compute_subnet_id is the private one. More information about ParallelCluster configuration file options and syntax are explained in the ParallelCluster documentation.

Deploy the API with AWS SAM

The code used for this example can be downloaded from this repo. Inside the repo:

The sam-app folder in the aws-sample repository contains the code required to build the AWS ParallelCluster serverless API for AWS Batch.
sam-app/template.yml contains the policy required for the Lambda function for the creation of the AWS Batch cluster. Be sure to modify <AWS ACCOUNT ID> and <REGION>to match the value for your account.

AWS Identity and Access Management Roles in AWS ParallelCluster contains the latest version of the policy. See the ParallelClusterInstancePolicy section related to the awsbatch scheduler.

To deploy the application, run the following commands:

cd sam-app
sam build
sam deploy --guided

From here, provide parameter values for the SAM deployment wizard for your preferred Region and AWS account. After the deployment, note the outputs:

SAM deploying:

The API Gateway endpoint URL is used to interact with the API. It has the following format:

https://<ServerlessRestApi>.execute-api.eu-west-1.amazonaws.com/Prod/pclusterbatch

Interact with the AWS Batch cluster using the deployed API

The deployed pclusterbatch API requires some parameters:

command – the pcluster Batch command to execute. A detailed list is available commands is available in the AWS ParallelCluster CLI Commands for AWS Batch page.
cluster_name – the name of the cluster.
jobid – the jobid string.
compute_node – parameter used to retrieve the output of the specified compute node number in a mpi job.
--data-binary "$(base64 /path/to/script.sh)" – parameter used to pass the job script to the API.
-H "additional_parameters: <param1> <param2> <...>" – used to pass additional parameters.

The cluster’s queue can be listed with the following:

$ curl --request POST -H "additional_parameters: "  "https://<ServerlessRestApi>.execute-api.eu-west-1.amazonaws.com/Prod/pclusterbatch?command=awsbqueues&cluster=cluster1"

A cluster job can be submitted with the following command. The job_script.sh is an example script used for the job.

$ curl --request POST -H "additional_parameters: -jn hello" --data-binary "$(base64 /path/to/job_script.sh)" "https://<ServerlessRestApi>.execute-api.eu-west-1.amazonaws.com/Prod/pclusterbatch?command=awsbsub&cluster=cluster1"

This command is used to check the status of the job:

$ curl --request POST -H "additional_parameters: "  "https://<ServerlessRestApi>.execute-api.eu-west-1.amazonaws.com/Prod/pclusterbatch?command=awsbstat&cluster=cluster1&jobid=3d3e092d-ca12-4070-a53a-9a1ec5c98ca0"

The output of the job can be retrieved with the following:

$ curl --request POST -H "additional_parameters: "  "https://<ServerlessRestApi>.execute-api.eu-west-1.amazonaws.com/Prod/pclusterbatch?command=awsbout&cluster=cluster1&jobid=3d3e092d-ca12-4070-a53a-9a1ec5c98ca0"

The following command can be used to list the cluster’s hosts:

$ curl –request POST –H “additional_parameters: “  “https://<ServerlessRestApi>.execute-api.eu-west-1.amazonaws.com/Prod/pclusterbatch?command=awsbhosts&cluster=cluster1”

You can also use the API to submit MPI jobs to the AWS Batch cluster. The mpi_job_script.sh can be used for the following three nodes MPI job:

curl --request POST -H "additional_parameters: -n 3" --data-binary "$(base64 mpi_script.sh)" "https://<ServerlessRestApi>.execute-api.eu-west-1.amazonaws.com/Prod/pclusterbatch?command=awsbsub&cluster=cluster1"

Retrieve the job output from the first node using the following:

$ curl --request POST -H "additional_parameters: "  "https://<ServerlessRestApi>.execute-api.eu-west-1.amazonaws.com/Prod/pclusterbatch?command=awsbout&cluster=cluster1&jobid=085b8e31-21cc-4f8e-8ab5-bdc1aff960d9&compute_node=0"

Teardown

You can destroy the resources by deleting the CloudFormation stacks created during installation. Deleting a Stack on the AWS CloudFormation Console explains the required steps.

Conclusion

In this post, I show how to integrate the AWS Batch CLI by AWS ParallelCluster with API Gateway. I explain the lifecycle of the job submission with AWS Batch using this API. API Gateway and Lambda run a serverless implementation of the CLI. It facilitates programmatic integration with AWS ParallelCluster with your on-premises or AWS Cloud applications.

You can also use this approach to integrate with the previous APIs developed in the Using AWS ParallelCluster with a serverless API and Amazon API Gateway for HPC job submission posts. By combining these different APIs, it is possible to create event-driven workflows for HPC. You can create scriptable workflows to extend on-premises infrastructure. You can also improve the security of HPC clusters by avoiding the need to use IAM roles and security groups that must otherwise be granted to individual users.

To learn more, read more about how to use AWS ParallelCluster and AWS Batch.

How Wind Mobility built a serverless data architecture

2020-06-29 Pablo Giner

Post Syndicated from Pablo Giner original https://aws.amazon.com/blogs/big-data/how-wind-mobility-built-a-serverless-data-architecture/

Guest post by Pablo Giner, Head of BI, Wind Mobility.

Over the past few years, urban micro-mobility has become a trending topic. With the contamination indexes hitting historic highs, cities and companies worldwide have been introducing regulations and working on a wide spectrum of solutions to alleviate the situation.

We at Wind Mobility strive to make commuters’ life more sustainable and convenient by bringing short distance urban transportation to cities worldwide.

At Wind Mobility, we scale our services at the same pace as our users demand them, and we do it in an economically and environmentally viable way. We optimize our fleet distribution to avoid overcrowding cities with more scooters than those that are actually going to be used, and we position them just meters away from where our users need them and at the time of the day when they want them.

How do we do that? By optimizing our operations to their fullest. To do so, we need to be very well informed about our users’ behavior under varying conditions and understand our fleet’s potential.

Scalability and flexibility for rapid growth

We knew that before we could solve this challenge, we needed to collect data from many different sources, such as user interactions with our application, user demand, IoT signals from our scooters, and operational metrics. To analyze the numerous datasets collected and extract actionable insights, we needed to build a data lake. While the high-level goal was clear, the scope was less so. We were working hard to scale our operation as we continued to launch new markets. The rapid growth and expansion made it very difficult to predict the volume of data we would need to consume. We were also launching new microservices to support our growth, which resulted in more data sources to ingest. We needed an architecture that allowed us to be agile and quickly adopt to meet our growth. It became clear that a serverless architecture was best positioned to meet those needs, so we started to design our 100% serverless infrastructure.

The first challenge was ingesting and storing data from our scooters in the field, events from our mobile app, operational metrics, and partner APIs. We use AWS Lambda to capture changes in our operational databases and mobile app and push the events to Amazon Kinesis Data Streams, which allows us to take action in real time. We also use Amazon Kinesis Data Firehose to write the data to Amazon Simple Storage Service (Amazon S3), which we use for analytics.

After we were in Amazon S3 and adequately partitioned as per its most common use cases (we partition by date, region, and business line, depending on the data source), we had to find a way to query this data for both data profiling (understanding structure, content, and interrelationships) and ad hoc analysis. For that we chose AWS Glue crawlers to catalog our data and Amazon Athena to read from the AWS Glue Data Catalog and run queries. However, ad hoc analysis and data profiling are relatively sporadic tasks in our team, because most of the data processing computing hours are actually dedicated to transforming the multiple data sources into our data warehouse, consolidating the raw data, modeling it, adding new attributes, and picking the data elements, which constitute 95% of our analytics and predictive needs.

This is where all the heavy lifting takes place. We parse through millions of scooter and user events generated daily (over 300 events per second) to extract actionable insight. We selected AWS Glue to perform this task. Our primary ETL job reads the newly added raw event data from Amazon S3, processes it using Apache Spark, and writes the results to our Amazon Redshift data warehouse. AWS Glue plays a critical role in our ability to scale on demand. After careful evaluation and testing, we concluded that AWS Glue ETL jobs meet all our needs and free us from procuring and managing infrastructure.

Architecture overview

The following diagram represents our current data architecture, showing two serverless data collection, processing, and reporting pipelines:

Operational databases from Amazon Relational Database Service (Amazon RDS) and MongoDB
IoT and application events, followed by Athena for data profiling and Amazon Redshift for reporting

Our data is curated and transformed multiple times a day using an automated pipeline running on AWS Glue. The team can now focus on analyzing the data and building machine learning (ML) applications.

We chose Amazon QuickSight as our business intelligence tool to help us visualize and better understand our operational KPIs. Additionally, we use Amazon Elastic Container Registry (Amazon ECR) to store our Docker images containing our custom ML algorithms and Amazon Elastic Container Service (Amazon ECS) where we train, evaluate, and host our ML models. We schedule our models to be trained and evaluated multiple times a day. Taking as input curated data about demand, conversion, and flow of scooters, we run the models to help us optimize fleet utilization for a particular city at any given time.

The following diagram represents how data from the data lake is incorporated into our ML training, testing, and serving system. First, our developers work in the application code and commit their changes, which are built into new Docker images by our CI/CD pipeline and stored in the Amazon ECR registry. These images are pushed into Amazon ECS and tested in DEV and UAT environments before moving to PROD (where they are triggered by the Amazon ECS task scheduler). During their execution, the Amazon ECS tasks (some train the demand and usage forecasting models, some produce the daily and hourly predictions, and others optimize the fleet distribution to satisfy the forecast) read their configuration and pull data from Amazon S3 (which has been previously produced by scheduled AWS Glue jobs), finally storing their results back into Amazon S3. Executions of these pipelines are tracked via MLFlow (in a dedicated Amazon Elastic Compute Cloud (Amazon EC2) server) and the final result indicating the fleet operations required is fit into a Kepler map, which is then consumed by the operators on the field.

Conclusion

We at Wind Mobility place data at the forefront of our operations. For that, we need our data infrastructure to be as flexible as the industry and the context we operate in, which is why we chose serverless. Over the course of a year, we have built a data lake, a data warehouse, a BI suite, and a variety of (production) data science applications. All of that with a very small team.

Also, within the last 12 months, we have scaled up several of our data pipelines by a factor of 10, without slowing our momentum or redesigning any part of our architecture. When it came to double our fleet in 1 week and increase the frequency at which we capture data from scooters by a factor of 10, our serverless data architecture scaled with no issues. This allowed us to focus on adding value by simplifying our operation, reacting to changes quickly, and delighting our users.

We have measured our success in multiple dimensions:

Speed – Serverless is faster to deploy and expand; we believe we have reduced our time to market for the entire infrastructure by a factor of 2
Visibility – We have 360 degree visibility of our operations worldwide, accessible by our city managers, finance team, and management board
Optimized fleet deployment – We know, at any minute of the day, the number of scooters that our customers need over the next few hours, which reduces unsatisfied demand by more than 50%

If you face a similar challenge, our advice is clear: go fully serverless and use the spectrum of solutions available from AWS.

About the Author

Pablo Giner is Head of BI at Wind Mobility. Pablo’s background is in wheels (motorcycle racing > vehicle engineering > collision insurance > eScooters sharing…) and for the last few years he has specialized in forming and developing data teams. At Wind Mobility, he leads the data function (data engineering + analytics + data science), and the project he is most proud of is what they call smart fleet rebalancing, an AI backed solution to reposition their fleet in real-time. “In God we trust. All others must bring data.” – W. Edward Deming

Managing backend requests and frontend notifications in serverless web apps

2020-06-29 James Beswick

Post Syndicated from James Beswick original https://aws.amazon.com/blogs/compute/managing-backend-requests-and-frontend-notifications-in-serverless-web-apps/

Web and mobile applications usually interact with a backend service, often via an API. Many front-end applications pass requests for processing, wait for a result, and then display this to the user. This synchronous approach is only one way to handle messages, but modern applications have alternatives to provide a better user experience.

There are three common ways to make and manage requests from your frontend. This blog post explains the benefits and use-cases of each approach. This post references the Ask Around Me example application, which allows users to ask and answer questions in their local geographic area in real time. To learn more, refer to part 1 of the blog application series.

The synchronous model

The synchronous call is the most common API request pattern, where the caller makes a request to an API and then waits for the response:

This type of request is easy to implement and understand because it mirrors the functional call-response pattern many developers are familiar with. The requestor is blocked until the calls completes, so it is well suited to simple requests with short execution times. Use cases include: retrieving the contents of a shopping cart, looking up a value in a database, or submitting an email address from a web form.

However, when your API interacts with other services or external workflows, the synchronous model can have limitations. In the following ecommerce example, any slow performance in the downstream services delays the entire roundtrip performance. Additionally, any outages in one of those services may result in an apparent failure of the entire service.

For services with lengthy workflows, you may reach API Gateway’s 29-second integration timeout. In the following ride sharing example, the service responsible for finding available drivers may have a highly variable response time. This request may time out. It also provides a poor user experience, as there is no feedback to the user for a considerable period.

Synchronous requests also have others limitations. You cannot receive more than one response per request, nor can you subscribe to future changes in data. In this example, the API request can only inform callers about drivers at the end of the length process request.

The asynchronous model

Asynchronous tasks are common in serverless applications and distributed applications. They allow separate parts of an application to communicate without needing to wait for a synchronous response. Asynchronous workloads often use queues between services to help manage throughout and assist with retry logic.

With asynchronous tasks, the caller hands off the event and continues on to the next task after receiving the acknowledgment response. The caller does not wait for the entire task to complete. The downstream service works on this event while the caller continues servicing other requests. The ecommerce example, converted to an asynchronous flow, looks like this:

In this example, a caller submits an order and receives a response from API Gateway almost immediately. With service integrations, API Gateway then stores the request directly in a durable store such as Amazon SQS or DynamoDB, before any processing has occurred. This results in a relatively consistent caller response time, regardless of downstream service processing time.

The downstream services fetch messages from the SQS queue or the DynamoDB table for processing. If there is a downstream outage, messages are persisted in the queue and may be retried later. From the user’s perspective, the request has been successfully submitted.

The Ask Around Me application handles the publishing of both questions and answers asynchronously. The API passes the user data to a Lambda function that stores the message in an SQS queue. SQS responds immediately to indicate that the message has been stored successfully, ending the API response. Another Lambda function then takes the messages from the SQS queue and processes these independently.

Both synchronous and asynchronous requests are useful for different functions in web applications, so it can be helpful to compare their features and behaviors:

Synchronous requests	Asynchronous requests
The caller waits until the end of processing for a response.	The caller receives an acknowledgment quickly while processing continues.
Waiting may incur cost.	Minimizes the cost of waiting.
Downstream slowness or outages affects the overall request.	Queuing separates ingestion of the request from the processing of the request.
Passes payloads between steps.	More often passes transaction identifiers.
Failure affects entire request.	Failure only affects segment of request.
Easy to implement.	Moderate complexity in implementation

Handling response values and state for asynchronous requests

With asynchronous processes, you cannot pass a return value back to the caller in the same way as you can for synchronous processes. Beyond the initial acknowledgment that the request has been received, there is no return path to provide further information. There are a couple of options available to web and mobile developers to track the state of inflight requests:

Polling: the initial request returns a tracking identifier. You create a second API endpoint for the frontend to check the status of the request, referencing the tracking ID. Use DynamoDB or another data store to track the state of the request.
WebSocket: this is a bidirectional connection between the frontend client and the backend service. It allows you to send additional information after the initial request is completed. Your backend services can continue to send data back to the client by using a WebSocket connection.

Polling is a simple mechanism to implement for many systems but can result in many empty calls. There is also a delay between data availability and the client being notified. WebSockets provide notifications that are closer to real time and reduce the number of messages between the client and backend system. However, implementing WebSockets is often more complex.

Using AWS IoT Core for real-time messaging

In both the synchronous and asynchronous models, it’s assumed that the caller makes a request and is only interested in the final result of that request. This doesn’t allow for partial information, such as the percentage of a task complete, or being notified continuously as data changes.

Modern web applications commonly use the publish-subscribe pattern to receive notifications as data changes. From receiving alerts when new email arrives to providing dashboard analytics, this method allows for much richer streams of event from backend systems.

In Ask Around Me, the application uses this pattern when listening for new questions from the user’s local area. The frontend subscribes to the geohash value of the user’s location via the AWS SDK. It then waits for messages published by the backend to this topic.

The SDK automatically manages the WebSocket connection and also handles many common connectivity issues in web apps. The messages are categorized using topics, which are strings defining channels of messages.

The AWS IoT Core service manages broadcasts between backend publishers and frontend subscribers. This enables fan-out functionality, which occurs when multiple subscribers are listening to the same topic. You can broadcast messages to thousands of frontend devices using this mechanism. For web application integration, this is the preferable way to implement publish-subscribe than using Amazon SNS.

The IotData class in the AWS SDK returns a client that uses the MQTT protocol. Once the frontend application establishes the connection, it returns messages, errors, and the connection status via callbacks:

        mqttClient.on('connect', function () {
          console.log('mqttClient connected')
        })

        mqttClient.on('error', function (err) {
          console.log('mqttClient error: ', err)
        })

        mqttClient.on('message', function (topic, payload) {
          const msg = JSON.parse(payload.toString())
          console.log('IoT msg: ', topic, msg)
        })

For more details on how to implement MQTT WebSocket connectivity for your application, see the Ask Around Me sample application code.

Combining multiple approaches for your frontend application

Many frontend applications can combine these models depending on the request type. The Ask Around Me application uses multiple approaches in managing the state of user questions:

When the application starts, it retrieves an initial set of questions from the synchronous API endpoint. This returns the available list of questions up to this point in time.
Simultaneously, the frontend subscribes to the geohash topic via AWS IoT Core. Any new questions for this geohash location are sent from the backend processing service to the frontend via this topic. This allows the frontend to receive new questions without subsequent API calls.
When a new question is posted, it is saved to the relevant SQS queue and acknowledged. The question is processed asynchronously by a backend process, which sends updates to the topic.

There are several benefits to combining synchronous, asynchronous, and real-time messaging approaches like this. Most importantly, the user experience remains consistent. The user receives immediate feedback to posting new questions and answers, while longer-running processes are managed asynchronously.

When new information becomes available, the frontend is notified in near-real time. This happens without needing to poll an API endpoint or have the user refresh the user interface. This also reduces the number of unnecessary API calls on the backend service, reducing the cost of running this application. Finally, this uses scalable managed services so the frontend application can support large numbers of users without impacting performance.

Conclusion

Web applications commonly use synchronous APIs when communicating with backend services. For longer-running processes, asynchronous workflows can offer an improved user experience and help manage scaling. By using durable message stores like SQS or DynamoDB, you can separate the request ingestion and response from the request processing.

In this post, I show how modern web applications use real-time messaging via WebSockets to improve the user experience. This provides a transport mechanism for pushing state updates from the backend to the frontend client. The AWS IoT Core service can fan out messages using topics, broadcasting messages to large numbers of frontend subscribers.

To see these three methods in an example frontend application, read more about the Ask Around Me example application.

Adding voice to a CircuitPython project using Amazon Polly

2020-06-24 Moheeb Zara

Post Syndicated from Moheeb Zara original https://aws.amazon.com/blogs/compute/adding-voice-to-a-circuitpython-project-using-amazon-polly/

An Adafruit PyPortal displaying a quote while synthesizing and playing speech using Amazon Polly.

As a natural means of communication, voice is a powerful way to humanize an experience. What if you could make anything talk? This guide walks through how to leverage the cloud to add voice to an off-the-shelf microcontroller. Use it to develop more advanced ideas, like a talking toaster that encourages healthy breakfast habits or a house plant that can express its needs.

This project uses an Adafruit PyPortal, an open-source IoT touch display programmed using CircuitPython, a lightweight version of Python that works on embedded hardware. You copy your code to the PyPortal like you would to a thumb drive and it runs. Random quotes from the PaperQuotes API are periodically displayed on the PyPortal LCD.

A microcontroller can’t do speech synthesis on its own so I use Amazon Polly, a natural text to speech synthesis service, to generate audio. Adding speech also extends accessibility to the visually impaired. This project includes an example for requesting arbitrary speech in addition to random quotes. Use this example to add a voice to any CircuitPython project.

An Adafruit PyPortal, an external speaker, and a microSD card.

I deploy the backend to the AWS Cloud using the AWS Serverless Application Repository. The code on the PyPortal makes a REST call to the backend to fetch a quote and synthesize speech audio for playback on the device.

Prerequisites

You need the following to complete the project:

An Adafruit PyPortal.
Mini Oval speaker (this is much louder than the built-in speaker).
A microSD card.
An AWS account. This project can be completed using the AWS Free Tier.

Deploy the backend application

An architecture diagram of the serverless backend when requesting speech synthesis of a text string.

The serverless backend consists of an Amazon API Gateway endpoint that invokes an AWS Lambda function. If called with a JSON object containing text and voiceId attributes, it uses Amazon Polly to synthesize speech and uploads an MP3 file as a public object to Amazon S3. Upon completion, it returns the URL for downloading the audio file. It also processes the submitted text and adds return lines so that it can appear text-wrapped when displayed on the PyPortal. For a full list of voices, see the Amazon Polly documentation. An example response:

To fetch quotes instead of a text field, call the endpoint with a comma-separated list of tags as shown in the following diagram. The Lambda function then calls the PaperQuotes API. It fetches up to 50 quotes per tag and selects a random one to synthesize as speech. As with arbitrary text, it returns a URL and a text-wrapped representation of the quote.

An architecture diagram of the serverless backend when requesting a random quote from the PaperQuotes API to synthesize as speech.

I use the AWS Serverless Application Model (AWS SAM) to create the backend template. While it can be deployed using the AWS SAM CLI, you can also deploy from the AWS Management Console:

Generate a free PaperQuotes API key at paperquotes.com. The serverless backend requires this to fetch quotes.
Navigate to the aws-serverless-pyportal-polly application in the AWS Serverless Application Repository.
Under Application settings, enter the parameter, PaperQuotesAPIKey.
Choose Deploy.
Once complete, choose View CloudFormation Stack.
Select the Outputs tab and make a note of the SpeechApiUrl. This is required for configuring the PyPortal.
Click the link listed for SpeechApiKey in the Outputs tab.
Click Show to reveal the API key. Make a note of this. This is required for authenticating requests from the PyPortal to the SpeechApiUrl.

PyPortal setup

The following instructions walk through installing the latest version of the Adafruit CircuityPython libraries and firmware. It also shows how to enable an external speaker module.

Follow these instructions from Adafruit to install the latest version of the CircuitPython bootloader. At the time of writing, the latest version is 5.3.0.
Follow these instructions to install the latest Adafruit CircuitPython library bundle. I use bundle version 5.x.
Insert the microSD card in the slot located on the back of the device.
Cut the jumper pad on the back of the device labeled A0. This enables you to use an external speaker instead of the built-in speaker.
Plug the external speaker connector into the port labeled SPEAKER on the back of the device.
Optionally install the Mu Editor, a multi-platform code editor and serial debugger compatible with Adafruit CircuitPython boards. This can help with troubleshooting issues.
Optionally if you have a 3D printer at home, you can print a case for your PyPortal. This can protect and showcase your project.

Code PyPortal

As with regular Python, CircuitPython does not need to be compiled to execute. You can flash new firmware on the PyPortal by copying a Python file and necessary assets to a mounted volume. The bootloader runs code.py anytime the device starts or any files are updated.

Use a USB cable to plug the PyPortal into your computer and wait until a new mounted volume CIRCUITPY is available.
Download the project from GitHub. Inside the project, copy the contents of /circuit-python on to the CIRCUITPY volume.
Inside the volume, open and edit the secrets.py file. Include your Wi-Fi credentials along with the SpeechApiKey and SpeechApiUrl API Gateway endpoint. These can be found under Outputs in the AWS CloudFormation stack created by the AWS Serverless Application Repository.
Save the file, and the device restarts. It takes a moment to connect to Wi-Fi and make the first request.
Optionally, if you installed the Mu Editor, you can click on “Serial” to follow along the device log.

The PyPortal takes a few moments to connect to the Wi-Fi network and make its first request. On success, you hear it greet you and describe itself. The default interval is set to then display and read a quote every five minutes.

Understanding the CircuitPython code

See the bottom of circuit-python/code.py from the GitHub project. When the PyPortal connects to Wi-Fi, the first thing it does is synthesize an arbitrary “hello world” text for display. It then begins periodically displaying and “speaking” quotes.

# Connect to WiFi
print("Connecting to WiFi...")
wifi.connect()
print("Connected!")

displayQuote("Ready!")

speakText('Hello world! I am an Adafruit PyPortal running Circuit Python speaking to you using AWS Serverless', 'Joanna')

while True:
    speakQuote('equality, humanity', 'Joanna')
    time.sleep(60*secrets['interval'])

Both the speakText and speakQuote function call the synthesizeSpeech function. The difference is whether text or tags are passed to the API.

def speakText(text, voice):
    data = { "text": text, "voiceId": voice }
    synthesizeSpeech(data)

def speakQuote(tags, voice):
    data = { "tags": tags, "voiceId": voice }
    synthesizeSpeech(data)

The synthesizeSpeech function posts the data to the API Gateway endpoint. It then invokes the Lambda function and returns the MP3 URL and the formatted text. The downloadfile function is called to fetch the MP3 file and store it on the SD card. displayQuote is called to display the quote on the LCD. Finally, the playMP3 opens the file and plays the speech audio using the built-in or external speaker.

def synthesizeSpeech(data):
    response = postToAPI(secrets['endpoint'], data)
    downloadfile(response['url'], '/sd/cache.mp3')
    displayQuote(response['text'])
    playMP3("/sd/cache.mp3")

Modifying the Lambda function

The serverless application includes a Lambda function, SynthesizeSpeechFunction, which can be modified directly in the Lambda console. The AWS SAM template used to deploy the AWS Serverless Application Repository application adds policies for accessing the S3 bucket where audio is stored. It also grants access to Amazon Polly for synthesizing speech. It also adds the PaperQuote API token as an environment variable and sets API Gateway as an event source.

SynthesizeSpeechFunction:
    Type: AWS::Serverless::Function
    Properties:
      CodeUri: lambda_functions/SynthesizeSpeech/
      Handler: app.lambda_handler
      Runtime: python3.8
      Policies:
        - S3FullAccessPolicy:
            BucketName: !Sub "${AWS::StackName}-audio"
        - Version: '2012-10-17'
          Statement:
            - Effect: Allow
              Action:
                - polly:*
              Resource: '*'
      Environment:
        Variables:
          BUCKET_NAME: !Sub "${AWS::StackName}-audio"
          PAPER_QUOTES_TOKEN: !Ref PaperQuotesAPIKey
      Events:
        Speech:
          Type: Api
          Properties:
            RestApiId: !Ref SpeechApi
            Path: /speech
            Method: post

To edit the Lambda function, navigate back to the CloudFormation stack and click on the SpeechSynthesizeFunction under the Resources tab.

From here, you can edit the Lambda function code directly. Clicking Save deploys the new code.

The getQuotes function is called to fetch quotes from the PaperQuotes API. You can change this to call from a different source, such as a custom selection of quotes. Try modifying it to fetch social media posts or study questions.

Conclusion

I show how to add natural sounding text to speech on a microcontroller using a serverless backend. This is accomplished by deploying an application through the AWS Serverless Application Repository. The deployed API uses API Gateway to securely invoke a Lambda function that fetches quotes from the PaperQuotes API and generates speech using Amazon Polly. The speech audio is uploaded to S3.

I then show how to program a microcontroller, the Adafruit PyPortal, using CircuitPython. The code periodically calls the serverless API to fetch a quote and to download speech audio for playback. The sample code also demonstrates synthesizing arbitrary text to speech, meaning it can be used for any project you can conceive. Check out my previous guide on using the PyPortal to create a Martian weather display for inspiration.

Serverless Architecture for a Web Scraping Solution

2020-06-23 Dzidas Martinaitis

Post Syndicated from Dzidas Martinaitis original https://aws.amazon.com/blogs/architecture/serverless-architecture-for-a-web-scraping-solution/

If you are interested in serverless architecture, you may have read many contradictory articles and wonder if serverless architectures are cost effective or expensive. I would like to clear the air around the issue of effectiveness through an analysis of a web scraping solution. The use case is fairly simple: at certain times during the day, I want to run a Python script and scrape a website. The execution of the script takes less than 15 minutes. This is an important consideration, which we will come back to later. The project can be considered as a standard extract, transform, load process without a user interface and can be packed into a self-containing function or a library.

Subsequently, we need an environment to execute the script. We have at least two options to consider: on-premises (such as on your local machine, a Raspberry Pi server at home, a virtual machine in a data center, and so on) or you can deploy it to the cloud. At first glance, the former option may feel more appealing — you have the infrastructure available free of charge, why not to use it? The main concern of an on-premises hosted solution is the reliability — can you assure its availability in case of a power outage or a hardware or network failure? Additionally, does your local infrastructure support continuous integration and continuous deployment (CI/CD) tools to eliminate any manual intervention? With these two constraints in mind, I will continue the analysis of the solutions in the cloud rather than on-premises.

Let’s start with the pricing of three cloud-based scenarios and go into details below.

Pricing table of three cloud-based scenarios

*The AWS Lambda free usage tier includes 1M free requests per month and 400,000 GB-seconds of compute time per month. Review AWS Lambda pricing.

Option #1

The first option, an instance of a virtual machine in AWS (called Amazon Elastic Cloud Compute or EC2), is the most primitive one. However, it definitely does not resemble any serverless architecture, so let’s consider it as a reference point or a baseline. This option is similar to an on-premises solution giving you full control of the instance, but you would need to manually spin an instance, install your environment, set up a scheduler to execute your script at a specific time, and keep it on for 24×7. And don’t forget the security (setting up a VPC, route tables, etc.). Additionally, you will need to monitor the health of the instance and maybe run manual updates.

Option #2

The second option is to containerize the solution and deploy it on Amazon Elastic Container Service (ECS). The biggest advantage to this is platform independence. Having a Docker file (a text document that contains all the commands you could call on the command line to assemble an image) with a copy of your environment and the script enables you to reuse the solution locally—on the AWS platform, or somewhere else. A huge advantage to running it on AWS is that you can integrate with other services, such as AWS CodeCommit, AWS CodeBuild, AWS Batch, etc. You can also benefit from discounted compute resources such as Amazon EC2 Spot instances.

Architecture of CloudWatch, Batch, ECR

The architecture, seen in the diagram above, consists of Amazon CloudWatch, AWS Batch, and Amazon Elastic Container Registry (ECR). CloudWatch allows you to create a trigger (such as starting a job when a code update is committed to a code repository) or a scheduled event (such as executing a script every hour). We want the latter: executing a job based on a schedule. When triggered, AWS Batch will fetch a pre-built Docker image from Amazon ECR and execute it in a predefined environment. AWS Batch is a free-of-charge service and allows you to configure the environment and resources needed for a task execution. It relies on ECS, which manages resources at the execution time. You pay only for the compute resources consumed during the execution of a task.

You may wonder where the pre-built Docker image came from. It was pulled from Amazon ECR, and now you have two options to store your Docker image there:

You can build a Docker image locally and upload it to Amazon ECR.
You just commit few configuration files (such as Dockerfile, buildspec.yml, etc.) to AWS CodeCommit (a code repository) and build the Docker image on the AWS platform.This option, shown in the image below, allows you to build a full CI/CD pipeline. After updating a script file locally and committing the changes to a code repository on AWS CodeCommit, a CloudWatch event is triggered and AWS CodeBuild builds a new Docker image and commits it to Amazon ECR. When a scheduler starts a new task, it fetches the new image with your updated script file. If you feel like exploring further or you want actually implement this approach please take a look at the example of the project on GitHub.

CodeCommit. CodeBuild, ECR

Option #3

The third option is based on AWS Lambda, which allows you to build a very lean infrastructure on demand, scales continuously, and has generous monthly free tier. The major constraint of Lambda is that the execution time is capped at 15 minutes. If you have a task running longer than 15 minutes, you need to split it into subtasks and run them in parallel, or you can fall back to Option #2.

By default, Lambda gives you access to standard libraries (such as the Python Standard Library). In addition, you can build your own package to support the execution of your function or use Lambda Layers to gain access to external libraries or even external Linux based programs.

Lambda Layer

You can access AWS Lambda via the web console to create a new function, update your Lambda code, or execute it. However, if you go beyond the “Hello World” functionality, you may realize that online development is not sustainable. For example, if you want to access external libraries from your function, you need to archive them locally, upload to Amazon Simple Storage Service (Amazon S3), and link it to your Lambda function.

One way to automate Lambda function development is to use AWS Cloud Development Kit (AWS CDK), which is an open source software development framework to model and provision your cloud application resources using familiar programming languages. Initially, the setup and learning might feel strenuous; however the benefits are worth of it. To give you an example, please take a look at this Python class on GitHub, which creates a Lambda function, a CloudWatch event, IAM policies, and Lambda layers.

In a summary, the AWS CDK allows you to have infrastructure as code, and all changes will be stored in a code repository. For a deployment, AWS CDK builds an AWS CloudFormation template, which is a standard way to model infrastructure on AWS. Additionally, AWS Serverless Application Model (SAM) allows you to test and debug your serverless code locally, meaning that you can indeed create a continuous integration.

See an example of a Lambda-based web scraper on GitHub.

Conclusion

In this blog post, we reviewed two serverless architectures for a web scraper on AWS cloud. Additionally, we have explored the ways to implement a CI/CD pipeline in order to avoid any future manual interventions.

Implementing geohashing at scale in serverless web applications

2020-06-22 James Beswick

Post Syndicated from James Beswick original https://aws.amazon.com/blogs/compute/implementing-geohashing-at-scale-in-serverless-web-applications/

Many web and mobile applications use geospatial data, often used with map overlays. This results in dataset queries based upon proximity, for questions such as “How far is the nearest business?” or “How many users are nearby?” Applications with significant traffic need an efficient way to handle geolocation queries. This blog post explores a simple geohashing solution for serverless applications, and how this can work at scale.

Geohashing is a popular public domain geocode system that converts geographic information into an alphanumeric hash. A geohash is used to identify a rectangular area around a fixed point. The length of the hash determines the precision of the area identified. This allows you to use a hierarchical search where the length of the geohash corresponds to the size of a search area.

This blog post references the Ask Around Me example application, which helps users ask and answer questions in their local geographic area. This post explores a solution suited for the expected volumes in this web application. See part 1 of the blog application series to learn more.

Choosing geohashing precision for your application

One of the most important considerations in using geohashing is understanding the expected distribution of the locations and the size of the search area. Selecting the correct geohash length is important for the efficiency of the search. There is a balance between the number of cells searched and the number of items within each cell.

A geohash corresponds to a grid cell but a typical search corresponds to multiple overlapping cells. In the following diagram, the search radius overlaps nine distinct geohash cells. The query returns all location pins within the cells but only the green pins are relevant to the radial search. The gray pins are outside of the overlapping geohash cells so are immediately discarded in the query:

If the geohash is too precise, meaning the cell is small, the search radius may include many more cells:

If the geohash is too coarse, meaning the cell is too large, the query may return too many results for a single cell for the search to be efficient. You may also find a large number of results in those cells are not within the search radius:

The geohashing algorithm creates a hash that makes it easy to find the neighboring eight cells of any target cell. For optimal performance, you should ideally select a hashing resolution where most queries are resolved by searching only the target cell and its immediate neighbors.

In the canonical implementation of geohash, there are some areas on the globe where physically neighboring cells are not logically close. This can cause errors in these edge cases where there are “seams”. The S2 geometry library solves this problem by using a spherical reference, meaning you can use this approach anywhere in the world. The library has been ported to TypeScript and is available as an npm package called nodes2ts.

Using Amazon DynamoDB for geohashing queries

Amazon DynamoDB is a serverless NoSQL database that offers single-digit millisecond performance at any scale. For an application with moderate load, you can set read and write capacity to allocate a dedicated amount of throughout, or you can set the provisioning to On-Demand. DynamoDB is well suited to key-based queries needing fast, consistent performance.

For web application developers using Node.js or JavaScript, there is an npm package called dynamodb-geo that ports the Java Geo Library for DynamoDB. Both packages are based on the S2 geometry library. This provides a simple interface to use DynamoDB for geospatial data. The library is a wrapper for DynamoDB and maintains an underlying table. After configuring the table and the library, you interact with the data using the library’s API.

For example, to add a new geospatial item:

    // Add a new location to the database
const result = await myGeoTableManager.putPoint({
        RangeKeyValue: { S: 'location-id-1234' }, // unique ID
        GeoPoint: { 
            latitude: 40.6892534,
            longitude: -74.0466891
        },
        PutItemInput: { 
            Item: { 
                country: { S: 'USA' },
                state: { S: 'New York' },
                pointOfInterest: { S: 'Statue of Liberty' }
            }
        }
    }).promise()

The library also provides methods for updating and deleting data points, and supports DynamoDB batch operations. Querying the data via the API can only be done via geo-point requests. You can retrieve a dataset of items based around a rectangular or radial area:

    // Querying 10km (~6.2 miles) around Boston, Massachusetts.

    const result = await myGeoTableManager.queryRadius({
        RadiusInMeter: 10000,
        CenterPoint: {
            latitude: 42.3145186,
            longitude: -71.1103666
        }
    }).promise()

    // Outputs results as an array of DynamoDB.AttributeMaps
    console.log(result)

Moving locations and moving consumers

In Ask Around Me, questions have a fixed latitude and longitude – once a question is asked, the location never changes. The dynamodb-geo library uses the hashKey as a primary key in the underlying DynamoDB table. To update the primary key of a DynamoDB item, you must delete and recreate the entire item.

Many geolocation implementations use static data, such as a list of retail store locations. But if you need to track moving locations, such as the location of mobile users, this is not the best approach. As a result, this library works well for static data (or data where the location rarely changes) but is not suitable where locations change frequently.

In the Ask Around Me app, users receive alerts when new questions appear around their current location. Real-time messaging is implemented using AWS IoT Core, where publish-subscribe topics connect the frontend and backend.

The application retrieves the current latitude and longitude via the browser and uses the S2 geometry library to convert this to a geohash key. It then subscribes to this geohash topic. On the backend, when new questions are saved, these are published to a topic using the geohash key. As a result, users in the same geohash area receive notifications when new questions are asked nearby.

This broadcast pattern allows the application to fan out a single new question in the DynamoDB table to thousands of live users in frontend application. As users move their location, the front-end application can detect if they moved from one geohash cell to another. If so, the frontend unsubscribes from the outdated geohash identifier, and subscribes to the new. This ensures that moving consumers are always listening to questions near their current location. For more information on the broadcast pattern, see the AWS whitepaper, Designing MQTT Topics for AWS IoT Core.

Sorting, aging, and expiring location data

For an application with many writes to the underlying geolocation table, the user may expect to see newer data first. Also, you may need a strategy for removing stale data from the table. Even with a highly performant database like DynamoDB, you must ensure the first page of results return the most relevant items.

The dynamodb-geo library uses the geohash identifier as a primary key, but allows the developer to choose an identifying range key. You need this key to uniquely identify items that have the same geohash. However, you can also use this key to for sorting and paging data that’s returned by the library’s search APIs.

The Ask Around Me app uses a concatenated userId-timestamp pattern as a range key, for example jbeswick-1589202456. This helps in implementing two data access patterns:

Finding by user: using the begins_with operator, you can identify questions asked by a specific user. For example, begins_with(‘jbeswick’) returns all the questions for this user.
Sorting results by time added: as query results are always sorted by the sort key value, the Unix timestamp ensures that these are returned from oldest to newest. You can reverse this order to return newest first by setting ScanIndexForward to false in the DynamoDB query.

In this application, you might decide that questions more than a year old should be expired from the table. You can have DynamoDB expire items automatically using the time to live (TTL) feature.

To use this, create a custom numeric attribute in the table that contains the expiration time of the item, set as a Unix timestamp. For example, an item expiring on a midnight on January 1, 2023 uses the timestamp 1672531200.

When you enable TTL on a DynamoDB table, you specify which attribute contains the expiration value. A background job checks the TTL values against the current time. For any items found where the TTL timestamp is older than the current time, it expires those items within a 48-hour time window.

Conclusion

This blog post explores how you can solve geolocation queries using geohashing. I discuss how you should decide on the resolution of a geohash for your specific workload.

I explain why DynamoDB is a good fit for many geohashing applications. I cover how you can use the dynamodb-geo library to easily implement location queries in your web applications. Using AWS IoT Core, you can also use MQTT topics to fan out updates to moving subscribers.

Finally, I show how to use the DynamoDB table’s range key to help with sorting data by age and supporting addition access patterns. For application with many writes, you can also automatically expire items using DynamoDB’s TTL feature.

To learn more about how the Ask Around Me application implements geolocation queries, see the blog series.

Building well-architected serverless applications: Approaching application lifecycle management – part 3

2020-06-18 Julian Wood

Post Syndicated from Julian Wood original https://aws.amazon.com/blogs/compute/building-well-architected-serverless-applications-approaching-application-lifecycle-management-part-3/

This series of blog posts uses the AWS Well-Architected Tool with the Serverless Lens to help customers build and operate applications using best practices. In each post, I address the nine serverless-specific questions identified by the Serverless Lens along with the recommended best practices. See the Introduction post for a table of contents and explanation of the example application.

Question OPS2: How do you approach application lifecycle management?

This post continues part 2 of this Operational Excellence question where I look at deploying to multiple stages using temporary environments, and rollout deployments. In part 1, I cover using infrastructure as code with version control to deploy applications in a repeatable manner.

Good practice: Use configuration management

Use environment variables and configuration management systems to make and track configuration changes. These systems reduce errors caused by manual processes, reduce the level of effort to deploy changes, and help isolate configuration from business logic.

Environment variables are suited for infrequently changing configuration options such as logging levels, and database connection strings. Configuration management systems are for dynamic configuration that might change frequently or contain sensitive data such as secrets.

Environment variables

The serverless airline example used in this series uses AWS Amplify Console environment variables to store application-wide settings.

For example, the Stripe payment keys for all branches, and names for individual branches, are visible within the Amplify Console in the Environment variables section.

AWS Amplify environment variables

AWS Lambda environment variables are set up as part of the function configuration stored using the AWS Serverless Application Model (AWS SAM).

For example, the airline booking ReserveBooking AWS SAM template sets global environment variables including the LOG_LEVEL with the following code.

Globals:
    Function:
        Environment:
            Variables:
                LOG_LEVEL: INFO

This is visible in the AWS Lambda console within the function configuration.

AWS Lambda environment variables in console

See the AWS Documentation for more information on using AWS Lambda environment variables and also how to store sensitive data. Amazon API Gateway can also pass stage-specific metadata to Lambda functions.

Dynamic configuration

Dynamic configuration is also stored in configuration management systems to specify external values and is unique to each environment. This configuration may include values such as an Amazon Simple Notification Service (Amazon SNS) topic, Lambda function name, or external API credentials. AWS System Manager Parameter Store, AWS Secrets Manager, and AWS AppConfig have native integrations with AWS CloudFormation to store dynamic configuration. For more information, see the examples for referencing dynamic configuration from within AWS CloudFormation.

For the serverless airline application, dynamic configuration is stored in AWS Systems Manager Parameter Store. During CloudFormation stack deployment, a number of parameters are stored in Systems Manager. For example, in the booking service AWS SAM template, the booking SNS topic ARN is stored.

BookingTopicParameter:
    Type: "AWS::SSM::Parameter"
    Properties:
        Name: !Sub /${Stage}/service/booking/messaging/bookingTopic
        Description: Booking SNS Topic ARN
        Type: String
        Value: !Ref BookingTopic

View the stored SNS topic value by navigating to the Parameter Store console, and search for BookingTopic.

Finding Systems Manager Parameter Store values

Select the Parameter name and see the Amazon SNS ARN.

Viewing SNS topic value

The loyalty service then references this value within another stack.

When the Amplify Console Makefile deploys the loyalty service, it retrieves this value for the booking service from Parameter Store, and references it as a parameter-override. The deployment is also parametrized with the $${AWS_BRANCH} environment variable if there are multiple environments within the same AWS account and Region.

sam deploy \
	--parameter-overrides \
	BookingSNSTopic=/$${AWS_BRANCH}/service/booking/messaging/bookingTopic

Environment variables and configuration management systems help with managing application configuration.

Improvement plan summary

Use environment variables for configuration options that change infrequently such as logging levels, and database connection strings.
Use a configuration management system for dynamic configuration that might change frequently or contain sensitive data such as secrets.

Best practice: Use CI/CD including automated testing across separate accounts

Continuous integration/delivery/deployment is one of the cornerstones of cloud application development and a vital part of a DevOps initiative.

Explanation of CI/CD stages

Building CI/CD pipelines increases software delivery quality and feedback time for detecting and resolving errors. I cover how to deploy multiple stages in isolated environments and accounts, which helps with creating separate testing CI/CD pipelines in part 2. As the serverless airline example is using AWS Amplify Console, this comes with a built-in CI/CD pipeline.

Automate the build, deployment, testing, and rollback of the workload using KPI and operational alerts. This eases troubleshooting, enables faster remediation and feedback time, and enables automatic and manual rollback/roll-forward should an alert trigger.

I cover metrics, KPIs, and operational alerts in this series in the Application Health part 1, and part 2 posts. I cover rollout deployments with traffic shifting based on metrics in this question’s part 2.

CI/CD pipelines should include integration, and end-to-end tests. I cover local unit testing for Lambda and API Gateway in part 2.

Add an optional testing stage to Amplify Console to catch regressions before pushing code to production. Use the test step to run any test commands at build time using any testing framework of your choice. Amplify Console has deeper integration with the Cypress test suite that allows you to generate a UI report for your tests. Here is an example to set up end-to-end tests with Cypress.

Cypress testing example

There are a number of AWS and third-party solutions to host code and create CI/CD pipelines for serverless applications.

AWS CodeCommit is a fully managed git-based source control service for hosting code.
AWS CodeBuild is a fully managed continuous integration service for compiling code, running tests, and producing deployment artifacts.
AWS CodePipeline is a fully managed continuous delivery service to automate release pipelines.
AWS CodeDeploy is a fully managed software deployment service to deploy code to a number of compute services such as Lambda.

AWS Code Suite

For more information on how to use the AWS Code* services together, see the detailed Quick Start deployment guide Serverless CI/CD for the Enterprise on AWS.

All these AWS services have a number of integrations with third-party products so you can integrate your serverless applications with your existing tools. For example, CodeBuild can build from GitHub and Atlassian Bitbucket repositories. CodeDeploy integrates with a number of developer tools and configuration management systems. CodePipeline has a number of pre-built integrations to use existing tools for your serverless applications. For more information specifically on using CircleCI for serverless applications, see Simplifying Serverless CI/CD with CircleCI and the AWS Serverless Application Model.

Improvement plan summary

Use a continuous integration/continuous deployment (CI/CD) pipeline solution that deploys multiple stages in isolated environments/accounts.
Automate testing including but not limited to unit, integration, and end-to-end tests.
Favor rollout deployments over all-at-once deployments for more resilience, and gradually learn what metrics best determine your workload’s health to appropriately alert on.
Use a deployment system that supports traffic shifting as part of your pipeline, and rollback/roll-forward traffic to previous versions if an alert is triggered.

Good practice: Review function runtime deprecation policy

Lambda functions created using AWS provided runtimes follow official long-term support deprecation policies. Third-party provided runtime deprecation policy may differ from official long-term support. Review your runtime deprecation policy and have a mechanism to report on runtimes that, if deprecated, may affect your workload to operate as intended.

Review the AWS Lambda runtime policy support page to understand the deprecation schedule for your runtime.

AWS Health provides ongoing visibility into the state of your AWS resources, services, and accounts. Use the AWS Personal Health Dashboard for a personalized view and automate custom notifications to communication channels other than your AWS Account email.

Use AWS Config to report on AWS Lambda function runtimes that might be near their deprecation. Run compliance and operational checks with AWS Config for Lambda functions.

If you are unable to migrate to newer runtimes within the deprecation schedule, use AWS Lambda custom runtimes as an interim solution.

Improvement plan summary

Identify and report runtimes that might deprecate and their support policy.

Conclusion

Introducing application lifecycle management improves the development, deployment, and management of serverless applications. In part 1, I cover using infrastructure as code with version control to deploy applications in a repeatable manner. This reduces errors caused by manual processes and gives you more confidence your application works as expected. In part 2, I cover prototyping new features using temporary environments, and rollout deployments to gradually shift traffic to new application code.

In this post I cover configuration management, CI/CD for serverless applications, and managing function runtime deprecation.

In an upcoming post, I will cover the first Security question from the Well-Architected Serverless Lens – Controlling access to serverless APIs.

Using Amazon EFS for AWS Lambda in your serverless applications

2020-06-18 James Beswick

Post Syndicated from James Beswick original https://aws.amazon.com/blogs/compute/using-amazon-efs-for-aws-lambda-in-your-serverless-applications/

Serverless applications are event-driven, using ephemeral compute functions to integrate services and transform data. While AWS Lambda includes a 512-MB temporary file system for your code, this is an ephemeral scratch resource not intended for durable storage.

Amazon EFS is a fully managed, elastic, shared file system designed to be consumed by other AWS services, such as Lambda. With the release of Amazon EFS for Lambda, you can now easily share data across function invocations. You can also read large reference data files, and write function output to a persistent and shared store. There is no additional charge for using file systems from your Lambda function within the same VPC.

EFS for Lambda makes it simpler to use a serverless architecture to implement many common workloads. It opens new capabilities, such as building and importing large code libraries directly into your Lambda functions. Since the code is loaded dynamically, you can also ensure that the latest version of these libraries is always used by every new execution environment. For appending to existing files, EFS is also a preferred option to using Amazon S3.

This blog post shows how to enable EFS for Lambda in your AWS account, and walks through some common use-cases.

Capabilities and behaviors of Lambda with EFS

EFS is built to scale on demand to petabytes of data, growing and shrinking automatically as files are written and deleted. When used with Lambda, your code has low-latency access to a file system where data is persisted after the function terminates.

EFS is a highly reliable NFS-based regional service, with all data stored durably across multiple Availability Zones. It is cost-optimized, due to no provisioning requirements, and no purchase commitments. It uses built-in lifecycle management to optimize between SSD-performance class and an infrequent access class that offer 92% lower cost.

EFS offers two performance modes – general purpose and MaxIO. General purpose is suitable for most Lambda workloads, providing lower operational latency and higher performance for individual files.

You also choose between two throughput modes – bursting and provisioned. The bursting mode uses a credit system to determine when a file system can burst. With bursting, your throughput is calculated based upon the amount of data you are storing. Provisioned throughput is useful when you need more throughout than provided by the bursting mode. Total throughput available is divided across the number of concurrent Lambda invocations.

The Lambda service mounts EFS file systems when the execution environment is prepared. This adds minimal latency when the function is invoked for the first time, often within hundreds of milliseconds. When the execution environment is already warm from previous invocations, the EFS mount is already available.

EFS can be used with Provisioned Concurrency for Lambda. When the reserved capacity is prepared, the Lambda service also configures and mounts EFS file system. Since Provisioned Concurrency executes any initialization code, any libraries or packages consumed from EFS at this point are downloaded. In this use-case, it’s recommended to use provisioned throughout when configuring EFS.

The EFS file system is shared across Lambda functions as it scales up the number of concurrent executions. As files are written by one instance of a Lambda function, all other instances can access and modify this data, depending upon the access point permissions. The EFS file system scales with your Lambda functions, supporting up to 25,000 concurrent connections.

Creating an EFS file system

Configuring EFS for Lambda is straight-forward. I show how to do this in the AWS Management Console but you can also use the AWS CLI, AWS SDK, AWS Serverless Application Model (AWS SAM), and AWS CloudFormation. EFS file systems are always created within a customer VPC, so Lambda functions using the EFS file system must all reside in the same VPC.

To create an EFS file system:

Navigate to the EFS console.
Choose Create File System.
On the Configure network access page, select your preferred VPC. Only resources within this VPC can access this EFS file system. Accept the default mount targets, and choose Next Step.
On Configure file system settings, you can choose to enable encryption of data at rest. Review this setting, then accept the other defaults and choose Next Step. This uses bursting mode instead of provisioned throughout.
On the Configure client access page, choose Add access point.
Enter the following parameters. This configuration creates a file system with open read/write permissions – read more about settings to secure your access points. Choose Next Step.
On the Review and create page, check your settings and choose Create File System.
In the EFS console, you see the new file system and its configuration. Wait until the Mount target state changes to Available before proceeding to the next steps.

Alternatively, you can use CloudFormation to create the EFS access point. With the AWS::EFS::AccessPoint resource, the preceding configuration is defined as follows:

  AccessPointResource:
    Type: 'AWS::EFS::AccessPoint'
    Properties:
      FileSystemId: !Ref FileSystemResource
      PosixUser:
        Uid: "1000"
        Gid: "1000"
      RootDirectory:
        CreationInfo:
          OwnerGid: "1000"
          OwnerUid: "1000"
          Permissions: "0777"
        Path: "/lambda"

For more information, see the example setup template in the code repository.

Working with AWS Cloud9 and Amazon EC2

You can mount EFS access points on Amazon EC2 instances. This can be useful for browsing file systems contents and downloading files from other locations. The EFS console shows customized mount instructions directly under each created file system:

The instance must have access to the same security group and reside in the same VPC as the EFS file system. After connecting via SSH to the EC2 instance, you mount the EFS mount target to a directory. You can also mount EFS in AWS Cloud9 instances using the terminal window.

Any files you write into the EFS file system are available to any Lambda functions using the same EFS file system. Similarly, any files written by Lambda functions are available to the EC2 instance.

Sharing large code packages with Lambda

EFS is useful for sharing software packages or binaries that are otherwise too large for Lambda layers. You can copy these to EFS and have Lambda use these packages as if there are installed in the Lambda deployment package.

For example, on EFS you can install Puppeteer, which runs a headless Chromium browser, using the following script run on an EC2 instance or AWS Cloud9 terminal:

  mkdir node && cd node
  npm init -y
  npm i puppeteer --save

You can then use this package from a Lambda function connected to this folder in the EFS file system. You include the Puppeteer package with the mount path in the require declaration:

const puppeteer = require ('/mnt/efs/node/node_modules/puppeteer')

In Node.js, to avoid changing declarations manually, you can add the EFS mount path to the Node.js module search path by using app-module-path. Lambda functions support a range of other runtimes, including Python, Java, and Go. Many other runtimes offer similar ways to add the EFS path to the list of default package locations.

There is an important difference between using packages in EFS compared with Lambda layers. When you use Lambda layers to include packages, these are downloaded to an immutable code package. Any changes to the underlying layer do not affect existing functions published using that layer.

Since EFS is a dynamic binding, any changes or upgrades to packages are available immediately to the Lambda function when the execution environment is prepared. This means you can output a build process to an EFS mount, and immediately consume any new versions of the build from a Lambda function.

Configuring AWS Lambda to use EFS

Lambda functions that access EFS must run from within a VPC. Read this guide to learn more about setting up Lambda functions to access resources from a VPC. There are also sample CloudFormation templates you can use to configure private and public VPC access.

The execution role for Lambda function must provide access to the VPC and EFS. For development and testing purposes, this post uses the AWSLambdaVPCAccessExecutionRole and AmazonElasticFileSystemClientFullAccess managed policies in IAM. For production systems, you should use more restrictive policies to control access to EFS resources.

Once your Lambda function is configured to use a VPC, next configure EFS in Lambda:

Navigate to the Lambda console and select your function from the list.
Scroll down to the File system panel, and choose Add file system.
In the File system configuration:

From the EFS file system dropdown, select the required file system. From the Access point dropdown, choose the required EFS access point.
In the Local mount path, enter the path your Lambda function uses to access this resource. Enter an absolute path.
Choose Save.

The File system panel now shows the configuration of the EFS mount, and the function is ready to use EFS. Alternatively, you can use an AWS Serverless Application Model (SAM) template to add the EFS configuration to a function resource:

AWSTemplateFormatVersion: '2010-09-09'
Resources:
  MyLambdaFunction:
    Type: AWS::Serverless::Function
    Properties:
	...
      FileSystemConfigs:
      - Arn: arn:aws:elasticfilesystem:us-east-1:xxxxxx:accesspoint/
fsap-123abcdef12abcdef
        LocalMountPath: /mnt/efs

To learn more, see the SAM documentation on this feature.

Example applications

You can view and download these examples from this GitHub repository. To deploy, follow the instructions in the repo’s README.md file.

1. Processing large video files

The first example uses EFS to process a 60-minute MP4 video and create screenshots for each second of the recording. This uses to the FFmpeg Linux package to process the video. After copying the MP4 to the EFS file location, invoke the Lambda function to create a series of JPG frames. This uses the following code to execute FFmpeg and pass the EFS mount path and input file parameters:

const os = require('os')

const inputFile = process.env.INPUT_FILE
const efsPath = process.env.EFS_PATH

const { exec } = require('child_process')

const execPromise = async (command) => {
	console.log(command)
	return new Promise((resolve, reject) => {
		const ls = exec(command, function (error, stdout, stderr) {
		  if (error) {
		    console.log('Error: ', error)
		    reject(error)
		  }
		  console.log('stdout: ', stdout);
		  console.log('stderr: ' ,stderr);
		})
		
		ls.on('exit', function (code) {
		  console.log('Finished: ', code);
		  resolve()
		})
	})
}

// The Lambda handler
exports.handler = async function (eventObject, context) {
	await execPromise(`/opt/bin/ffmpeg -loglevel error -i ${efsPath}/${inputFile} -s 240x135 -vf fps=1 ${efsPath}/%d.jpg`)
}

In this example, the process writes more than 2000 individual JPG files back to the EFS file system during a single invocation:

Console output from sample application

2. Archiving large numbers of files

Using the output from the first application, the second example creates a single archive file from the JPG files. The code uses the Node.js archiver package for processing:

const outputFile = process.env.OUTPUT_FILE
const efsPath = process.env.EFS_PATH

const fs = require('fs')
const archiver = require('archiver')

// The Lambda handler
exports.handler = function (event) {

  const output = fs.createWriteStream(`${efsPath}/${outputFile}`)
  const archive = archiver('zip', {
    zlib: { level: 9 } // Sets the compression level.
  })
  
  output.on('close', function() {
    console.log(archive.pointer() + ' total bytes')
  })
  
  output.on('end', function() {
    console.log('Data has been drained')
  })
  
  archive.pipe(output)  

  // append files from a glob pattern
  archive.glob(`${efsPath}/*.jpg`)
  archive.finalize()
}

After executing this Lambda function, the resulting ZIP file is written back to the EFS file system:

3. Unzipping archives with a large number of files

The last example shows how to unzip an archive containing many files. This uses the Node.js unzipper package for processing:

const inputFile = process.env.INPUT_FILE
const efsPath = process.env.EFS_PATH
const destinationDir = process.env.DESTINATION_DIR

const fs = require('fs')
const unzipper = require('unzipper')

// The Lambda handler
exports.handler = function (event) {

  fs.createReadStream(`${efsPath}/${inputFile}`)
    .pipe(unzipper.Extract({ path: `${efsPath}/${destinationDir}` }))

}

Once this Lambda function is executed, the archive is unzipped into a destination direction in the EFS file system. This example shows the screenshots unzipped into the frames subdirectory:

Conclusion

EFS for Lambda allows you to share data across function invocations, read large reference data files, and write function output to a persistent and shared store. After configuring EFS, you provide the Lambda function with an access point ARN, allowing you to read and write to this file system. Lambda securely connects the function instances to the EFS mount targets in the same Availability Zone and subnet.

EFS opens a range of potential new use-cases for Lambda. In this post, I show how this enables you to access large code packages and binaries, and process large numbers of files. You can interact with the file system via EC2 or AWS Cloud9 and pass information to and from your Lambda functions.

EFS for Lambda is supported at launch in APN Partner solutions, including Epsagon, Lumigo, Datadog, HashiCorp Terraform, and Pulumi. To learn more about how to use EFS for Lambda, see the AWS News Blog post and read the documentation.

Creating serverless applications with the AWS Cloud Development Kit

2020-06-18 Eric Johnson

Post Syndicated from Eric Johnson original https://aws.amazon.com/blogs/compute/creating-serverless-applications-with-the-aws-cloud-development-kit/

This post is contributed by Daniele Stroppa, Sr. Solutions Architect

In October 2019, AWS released an improvement to the getting started experience in the AWS Lambda console. This enables you to create applications that follow common best practices, using infrastructure as code (IaC). It also provides a continuous integration and continuous deployment (CI/CD) pipeline for deployment.

Today, we are releasing a new set of ready-to-use examples that use the AWS Cloud Development Kit (AWS CDK) to model application resources. The AWS CDK is an open-source software development framework for defining your cloud infrastructure in code and provisioning it through AWS CloudFormation.

The AWS CDK allows developers to define their infrastructure in familiar programming languages. These include TypeScript, JavaScript, Python, C# and Java. The AWS CDK allows you to take advantage of familiar features that those languages provide, such as objects, loops, and conditions. It provides high-level constructs that preconfigure cloud resources with defaults to help developers build cloud applications.

In this post, I walk through creating a serverless application with the AWS CDK.

Create an application

An AWS Lambda application is a combination of Lambda functions, event sources, and other resources that work together to perform tasks. Create a new application in the AWS Lambda console:

On the left menu, choose Applications.
Choose Create application and then choose Serverless API backend from the list of examples.
Review the setup and configuration of the application and then choose Next.
Configure application settings:
- Application name – serverless-api-cdk.
- Application description – A simple serverless API application.
- Runtime – Node.js 10.x.
- Template format – AWS CDK (TypeScript).
- Repository provider – CodeCommit. (Note: If you choose GitHub, you must connect to your GitHub account for authorization).
- Repository name – serverless-api-cdk.
- Permissions – Check Create roles and permissions boundary.
Choose Create.

This creates a new serverless application from the Lambda console. The console creates the pipeline and related resources. It also commits the sample application code to the Git repository. Resources appear in the overview page as they are created. Next, I explore the CDK models used to create the application resources.

Clone the application repository

When you create the application, the Lambda console creates a Git repository that contains the sample application. Clone the project repository in your local development environment:

Find your application in the Lambda console.
Choose the Code tab.
Copy the HTTP or SSH repository URI, depending on the authentication mode that you configured during setup.
Clone the repository on your local machine.
$ git clone ssh://git-codecommit.us-east-1.amazonaws.com/v1/repos/serverless-api-cdk

NOTE: your repository URL might differ from the one above if you are running in a different Region.

The repository contains the CDK models for the application, a build specification, and the application code.

Install the AWS CDK in your local environment

If you haven’t already, install the AWS CDK in your local environment using the following command:

$ npm install -g [email protected]

Run the following command to verify the version number of the CDK:

$ cdk --version

You should see the following output:

$ 1.42.0 (build 3b64241)

Explore the CDK application

A CDK application is composed of building blocks called constructs. These are cloud components that can represent architectures of any complexity. For example, a single resource, such as an Amazon S3 bucket or an Amazon SNS topic, a static website, or even a complex, multi-stack application that spans multiple AWS accounts and Regions.

To enable reusability, constructs can include other constructs. You compose constructs together into stacks that you can deploy into an AWS environment, and apps, a collection of one of more stacks. Learn more about AWS CDK concepts in the AWS documentation.

The sample application defines a CDK app in the serverless-api-cdk/cdk/bin/cdk.ts file:

Sample app definition

The CDK app is composed of a single CDK stack, defined in the cdk/lib/cdk-stack.ts:

CDK stack definition

The CDK stack first declares an Amazon DynamoDB table used by the API, specifying the partition key and the provisioned read and write capacity units:

DynamoDB declaration

Then, it declares a set of common configuration options for the application’s Lambda functions. These includes an environment variable referencing the DynamoDB table and the S3 location for the function’s code artifact.

S3 declaration

Each Lambda function is declared individually, specifying the function code and configuration. There is a reference to the DynamoDB table resource, passed as an environment variable:

Lambda declaration

The last line in the code is the short form to declare what IAM permissions the function requires. When the CDK app is synthesized, the CDK CLI generates the required IAM role and policy, following the principle of least privilege.

Lastly, the CDK stack declares the APIs:

API Gateway declaration

View the synthesized CloudFormation template

A CloudFormation template is created based on the code. Before you can generate the CloudFormation template, you must install the required npm packages. Execute the following command from the serverless-api-cdk/cdk/ directory:

$ cd serverless-api-cdk/cdk/
$ npm install

The Lambda function’s configuration uses two environment variables that are defined during the build process, S3_BUCKET and CODEBUILD_BUILD_ID. To synthesize the CloudFormation template, you must define these two variables locally:

$ export S3_BUCKET="my_artifact_bucket"
$ export CODEBUILD_BUILD_ID="1234567"

NOTE: actual values of the variables do not matter until you provision resources. The correct values are injected during the build and deploy phase.

From the serverless-api-cdk/cdk/ folder, run the cdk synth command. A CloudFormation template that is generated based on the sample application code is displayed in the console and also available in the serverless-api-cdk/cdk/cdk.out directory.

Sample CloudFormation output

Conclusion

In this post, I show how to create a serverless application with the AWS Cloud Development Kit (AWS CDK). I also show how to create a pipeline to automatically deploy your changes. We also explore some of the CDK constructs you can use to model our cloud resources.

To learn more, see the CDK examples available in the Lambda console.

Building well-architected serverless applications: Approaching application lifecycle management – part 2

2020-06-17 Julian Wood

Post Syndicated from Julian Wood original https://aws.amazon.com/blogs/compute/building-well-architected-serverless-applications-approaching-application-lifecycle-management-part-2/

Question OPS2: How do you approach application lifecycle management?

This post continues part 1 of this Operational Excellence question. Previously, I covered using infrastructure as code with version control to deploy applications in a repeatable manner.

Good practice: Prototype new features using temporary environments

Storing application configuration as infrastructure as code allows deployment of multiple, repeatable, isolated versions of an application.

Create multiple temporary environments for new features you may need to prototype, and tear them down as you complete them. Temporary environments enable fine grained feature isolation and higher fidelity development when interacting with managed services. This allows you to gain confidence your workload integrates and operates as intended.

These environments can also be in separate accounts which help isolate limits, access to data, and resiliency. For best practices on multi-account deployments, see the AWS Partner Network blog post: Best Practices Guide for Multi-Account AWS Deployments.

There are a number of ways to deploy separate environments for an application. To make the deployment simpler, it is good practice to separate dynamic configuration from your infrastructure logic.

For an application managed via the AWS Serverless Application Model (AWS SAM), use an AWS SAM CLI parameter to specify a new stack-name which deploys a new copy of the application as a separate stack.

For example, there is an existing AWS SAM application with a stack-name of app-test. To deploy a new copy, specify a new stack-name of app-newtest with the following command line:

sam deploy --stack-name app-newtest

This deploys a whole new copy of the application in the same account as a separate stack.

For the serverless airline example used in this series, deploy a whole new copy of the application following the deployment instructions, either into the same AWS account, or a completely different account. This is useful when each developer in a team has a sandbox environment. In this example, you only need to configure payment provider credentials as environment variables and seed the database with possible flights as these are currently manual post installation tasks.

However, maintaining an entirely separate codebase copy of an application becomes difficult to manage and reconcile over time.

As the airline application code is stored in a fork in a GitHub account, use git branches for separate environments. In typical development teams, developers may deploy a main branch to production, have a dev branch as staging, and create feature branches when working on new functionality. This allows safe prototyping in sandbox environments without affecting the main codebase, and use git as a mechanism to merge code and resolve conflicts. Changes are automatically pushed to production once they are merged into the main (or production) branch.

Git branching flow

As the airline example is using AWS Amplify Console, there are a few different options to create a new environment linked to a feature branch.

You can create a whole new Amplify Console app deployment, either in a separate Region, or in a separate AWS account, which then connects to a feature branch by following the deployment instructions. Create a new branch called new-feature in GitHub and in the Amplify Console, select Connect App, and navigate to the repository and the new-feature branch. Configure the payment provider credentials as environment variables.

You can also connect the existing Amplify Console deployment to a git branch, deploying the new-feature branch into the same AWS account and Region.

Amplify Environments

In the Amplify Console, navigate to the existing app, select Connect Branch, and choose the new-feature branch. Create a new Backend environment to deploy the full stack. If the feature branch is only frontend code changes, you can choose to use the same backend components.

Connect Amplify Console to feature branch

Amplify Console then deploys a new stack in addition to the develop branch based on the code in the feature-branch.

New feature branch deploying within existing deployment.

You do not need to add the payment provider environment variables as these are stored per application, per Region, for all branches.

Amplify environment variables for All Branches.

Using git and branching with Amplify Console, you have automatic deployments when any changes are pushed to the GitHub repository. If there are any issues with a particular deployment, you can revert the changes in git which will kick off a redeploy to a known good version. Once you are happy with the feature, you can merge the changes into the production branch which will again kick off another deployment.

As it is simple to set up multiple test environments, make sure to practice good application hygiene, as well as cost management, by identifying and deleting any temporary environments that are no longer required. It may be helpful to include the stack owner’s contact details via CloudFormation tags. Use Amazon CloudWatch scheduled tasks to notify and tag temporary environments for deletion, and provide a mechanism to delay its deletion if needed.

Prototyping locally

With AWS SAM or a third-party framework, you can run API Gateway, and invoke Lambda function code locally for faster development iteration. Local debugging and testing can help for quick confirmation that function code is working, and is also useful for some unit tests. Local testing cannot duplicate the full functionality of the cloud. It is suited to testing services with custom logic, such as Lambda, rather than trying to duplicate all cloud managed services such as Amazon SNS, or Amazon S3 locally. Don’t try to bring the cloud to the test, rather bring the testing to the cloud.

Here is an example of executing a function locally.

I use AWS SAM CLI to invoke the Airline-GetLoyalty Lambda function locally to test some functionality. AWS SAM CLI uses Docker to simulate the Lambda runtime. As the function only reads from DynamoDB, I use stubbed data, or can set up DynamoDB Local.

1. I pass a JSON event to the function to simulate the event from API Gateway, as well as passing in environment variables as JSON. Create sample events using sam local generate-event.

2. I run sam build GetFunc to build the function dependencies, in this case NodeJS.

$ sam build GetFunc
Building resource 'GetFunc'
Running NodejsNpmBuilder:NpmPack
Running NodejsNpmBuilder:CopyNpmrc
Running NodejsNpmBuilder:CopySource
Running NodejsNpmBuilder:NpmInstall
Running NodejsNpmBuilder:CleanUpNpmrc

Build Succeeded

3. I run sam local invoke passing in the event payload and environment variables. This spins up a Docker container, executes the function, and returns the result.

$ sam local invoke --event src/get/event.json --env-vars local-env-vars.json GetFunc
Invoking index.handler (nodejs10.x)

Fetching lambci/lambda:nodejs10.x Docker container image......
Mounting /home/ec2-user/environment/samples/aws-serverless-airline-booking/src/backend/loyalty/.aws-sam/build/GetFunc as /var/task:ro,delegated inside runtime container
START RequestId: 7be7e9a5-9f2f-1520-fbd1-a013485105d3 Version: $LATEST
END RequestId: 7be7e9a5-9f2f-1520-fbd1-a013485105d3
REPORT RequestId: 7be7e9a5-9f2f-1520-fbd1-a013485105d3 Init Duration: 249.89 ms Duration: 76.40 ms Billed Duration: 100 ms Memory Size: 512 MB Max Memory Used: 54 MB

{"statusCode": 200,"body": "{\"points\":0,\"level\":\"bronze\",\"remainingPoints\":50000}"}

For more information on using AWS SAM to run API Gateway, and invoke Lambda functions locally, see the AWS Documentation. For third-part framework solutions, see Invoking AWS Lambda functions locally with Serverless framework and Develop locally against cloud services with Stackery.

Improvement plan summary:

Use a serverless framework to deploy temporary environments named after a feature.
Implement a process to identify temporary environments that may not have been deleted over an extended period of time
Prototype application code locally and test integrations directly with managed services

Good practice: Use a rollout deployment mechanism

Use a rollout deployment for production workloads as opposed to all-at-once mechanisms. Rollout deployments reduce the risk of a failed deployment by gradually deploying application changes to a limited set of customers. Use all-at-once deployments to deploy the entire application. This is best suited for non-production systems.

AWS Lambda versions and aliases

For production Lambda functions, it is best to deploy a new function version for every deployment. Versions can represent the stable version or reflect particular features. Create Lambda aliases which are pointers to particular function versions. Invoke Lambda functions using the aliases, with a specific alias for the stable production version. If an alias is not specified, the latest application code deployment is invoked which may not reflect a stable version or a desired feature. Use the new feature alias version for testing without affecting users of the stable production version.

AWS Lambda function versions and aliases

See AWS Documentation to manage Lambda function versions and aliases using the AWS Management Console, or Lambda API.

Alias routing

Use Lambda alias’ routing configuration to introduce traffic shifting to send a small percentage of traffic to a second function alias or version for a rolling deployment. This is commonly called a canary release.

For example, configure Lambda alias named stable to point to function version 2. A new function version 3 is deployed with alias new-feature. Use the new-feature alias to test the new deployment without impacting production traffic to the stable version.

During production rollout, use alias routing. For example, 90% of invocations route to the stable version while 10% route to alias new-feature pointing to version 3. If the 10% is successful, deployment can continue until all traffic is migrated to version 3, and the stable alias is then pointed to version 3.

AWS Lambda alias routing

AWS SAM supports gradual Lambda deployments with a feature called Safe Lambda deployments using AWS CodeDeploy. This creates new versions of a Lambda function, and automatically creates aliases pointing to the new version. Customer traffic gradually shifts to the new version or rolls back automatically if any specified CloudWatch alarms trigger. AWS SAM supports canary, linear, and all-at-once deployments preference types.

Pre-traffic and post-traffic Lambda functions can also verify if the newly deployed code is working as expected.

In the airline example, create a safe deployment for the ReserveBooking Lambda function by adding the example AWS SAM template code specified in the instructions. This migrates 10 percent of traffic every 10 minutes with CloudWatch alarms to check for any function errors. You could also alarm on latency, or any custom metric.

During the Amplify Console build phase, the safe deployment is initiated. Navigate to the CodeDeploy console and see the deployment in progress.

AWS CodeDeploy deployment in progress

Selecting the deployment, you can see the Traffic shifting progress and the Deployment details.

AWS CodeDeploy traffic shifting in progress.

Within Deployment details, select the DeploymentGroup, and view the CloudWatch Alarms CodeDeploy is using to test the rollout.

Amazon CloudWatch Alarms AWS CodeDeploy is using to test the rollout

Within Deployment details, select the Application, select the Revisions tab, and select the latest Revision location and view the CurrentVersion and TargetVersion for this deployment.

View deployment versions

View Deployment status and see the traffic has now shifted to the new version. The Amplify Console build also continues.

Traffic shifting complete

View the Lambda function versions and aliases in the Lambda console, selecting Qualifiers.

Viewing Lambda function version and aliases

Amazon API Gateway also supports canary release deployments at the API layer.

A rollout deployment provides traffic shifting, A/B testing, and the ability to roll back to any version at any point in time. AWS SAM makes it simple to add safe deployments to serverless applications.

Improvement plan summary

For production systems, use a linear deployment strategy to gradually rollout changes to customers.
For high volume production systems, use a canary deployment strategy when you want to limit changes to a fixed percentage of customers for an extended period of time.

Conclusion

Introducing application lifecycle management improves the development, deployment, and management of serverless applications. In this post I cover a number of methods to prototype new features using temporary environments. I show how to use rollout deployments to gradually shift traffic to new application code.

This well-architected question will continue in an upcoming post where I look at configuration management, CI/CD for serverless applications, and managing function runtime deprecation.

New – A Shared File System for Your Lambda Functions

2020-06-16 Danilo Poccia

Post Syndicated from Danilo Poccia original https://aws.amazon.com/blogs/aws/new-a-shared-file-system-for-your-lambda-functions/

I am very happy to announce that AWS Lambda functions can now mount an Amazon Elastic File System (EFS), a scalable and elastic NFS file system storing data within and across multiple availability zones (AZ) for high availability and durability. In this way, you can use a familiar file system interface to store and share data across all concurrent execution environments of one, or more, Lambda functions. EFS supports full file system access semantics, such as strong consistency and file locking.

To connect an EFS file system with a Lambda function, you use an EFS access point, an application-specific entry point into an EFS file system that includes the operating system user and group to use when accessing the file system, file system permissions, and can limit access to a specific path in the file system. This helps keeping file system configuration decoupled from the application code.

You can access the same EFS file system from multiple functions, using the same or different access points. For example, using different EFS access points, each Lambda function can access different paths in a file system, or use different file system permissions.

You can share the same EFS file system with Amazon Elastic Compute Cloud (EC2) instances, containerized applications using Amazon ECS and AWS Fargate, and on-premises servers. Following this approach, you can use different computing architectures (functions, containers, virtual servers) to process the same files. For example, a Lambda function reacting to an event can update a configuration file that is read by an application running on containers. Or you can use a Lambda function to process files uploaded by a web application running on EC2.

In this way, some use cases are much easier to implement with Lambda functions. For example:

Processing or loading data larger than the space available in /tmp (512MB).
Loading the most updated version of files that change frequently.
Using data science packages that require storage space to load models and other dependencies.
Saving function state across invocations (using unique file names, or file system locks).
Building applications requiring access to large amounts of reference data.
Migrating legacy applications to serverless architectures.
Interacting with data intensive workloads designed for file system access.
Partially updating files (using file system locks for concurrent access).
Moving a directory and all its content within a file system with an atomic operation.

Creating an EFS File System
To mount an EFS file system, your Lambda functions must be connected to an Amazon Virtual Private Cloud that can reach the EFS mount targets. For simplicity, I am using here the default VPC that is automatically created in each AWS Region.

Note that, when connecting Lambda functions to a VPC, networking works differently. If your Lambda functions are using Amazon Simple Storage Service (S3) or Amazon DynamoDB, you should create a gateway VPC endpoint for those services. If your Lambda functions need to access the public internet, for example to call an external API, you need to configure a NAT Gateway. I usually don’t change the configuration of my default VPCs. If I have specific requirements, I create a new VPC with private and public subnets using the AWS Cloud Development Kit, or use one of these AWS CloudFormation sample templates. In this way, I can manage networking as code.

In the EFS console, I select Create file system and make sure that the default VPC and its subnets are selected. For all subnets, I use the default security group that gives network access to other resources in the VPC using the same security group.

In the next step, I give the file system a Name tag and leave all other options to their default values.

Then, I select Add access point. I use 1001 for the user and group IDs and limit access to the /message path. In the Owner section, used to create the folder automatically when first connecting to the access point, I use the same user and group IDs as before, and 750 for permissions. With this permissions, the owner can read, write, and execute files. Users in the same group can only read. Other users have no access.

I go on, and complete the creation of the file system.

Using EFS with Lambda Functions
To start with a simple use case, let’s build a Lambda function implementing a MessageWall API to add, read, or delete text messages. Messages are stored in a file on EFS so that all concurrent execution environments of that Lambda function see the same content.

In the Lambda console, I create a new MessageWall function and select the Python 3.8 runtime. In the Permissions section, I leave the default. This will create a new AWS Identity and Access Management (IAM) role with basic permissions.

When the function is created, in the Permissions tab I click on the IAM role name to open the role in the IAM console. Here, I select Attach policies to add the AWSLambdaVPCAccessExecutionRole and AmazonElasticFileSystemClientReadWriteAccess AWS managed policies. In a production environment, you can restrict access to a specific VPC and EFS access point.

Back in the Lambda console, I edit the VPC configuration to connect the MessageWall function to all subnets in the default VPC, using the same default security group I used for the EFS mount points.

Now, I select Add file system in the new File system section of the function configuration. Here, I choose the EFS file system and accesss point I created before. For the local mount point, I use /mnt/msg and Save. This is the path where the access point will be mounted, and corresponds to the /message folder in my EFS file system.

In the Function code editor of the Lambda console, I paste the following code and Save.

import os
import fcntl

MSG_FILE_PATH = '/mnt/msg/content'


def get_messages():
    try:
        with open(MSG_FILE_PATH, 'r') as msg_file:
            fcntl.flock(msg_file, fcntl.LOCK_SH)
            messages = msg_file.read()
            fcntl.flock(msg_file, fcntl.LOCK_UN)
    except:
        messages = 'No message yet.'
    return messages


def add_message(new_message):
    with open(MSG_FILE_PATH, 'a') as msg_file:
        fcntl.flock(msg_file, fcntl.LOCK_EX)
        msg_file.write(new_message + "\n")
        fcntl.flock(msg_file, fcntl.LOCK_UN)


def delete_messages():
    try:
        os.remove(MSG_FILE_PATH)
    except:
        pass


def lambda_handler(event, context):
    method = event['requestContext']['http']['method']
    if method == 'GET':
        messages = get_messages()
    elif method == 'POST':
        new_message = event['body']
        add_message(new_message)
        messages = get_messages()
    elif method == 'DELETE':
        delete_messages()
        messages = 'Messages deleted.'
    else:
        messages = 'Method unsupported.'
    return messages

I select Add trigger and in the configuration I select the Amazon API Gateway. I create a new HTTP API. For simplicity, I leave my API endpoint open.

With the API Gateway trigger selected, I copy the endpoint of the new API I just created.

I can now use curl to test the API:

$ curl https://1a2b3c4d5e.execute-api.us-east-1.amazonaws.com/default/MessageWall
No message yet.
$ curl -X POST -H "Content-Type: text/plain" -d 'Hello from EFS!' https://1a2b3c4d5e.execute-api.us-east-1.amazonaws.com/default/MessageWall
Hello from EFS!

$ curl -X POST -H "Content-Type: text/plain" -d 'Hello again :)' https://1a2b3c4d5e.execute-api.us-east-1.amazonaws.com/default/MessageWall
Hello from EFS!
Hello again :)

$ curl https://1a2b3c4d5e.execute-api.us-east-1.amazonaws.com/default/MessageWall
Hello from EFS!
Hello again :)

$ curl -X DELETE https://1a2b3c4d5e.execute-api.us-east-1.amazonaws.com/default/MessageWall
Messages deleted.

$ curl https://1a2b3c4d5e.execute-api.us-east-1.amazonaws.com/default/MessageWall
No message yet.

It would be relatively easy to add unique file names (or specific subdirectories) for different users and extend this simple example into a more complete messaging application. As a developer, I appreciate the simplicity of using a familiar file system interface in my code. However, depending on your requirements, EFS throughput configuration must be taken into account. See the section Understanding EFS performance later in the post for more information.

Now, let’s use the new EFS file system support in AWS Lambda to build something more interesting. For example, let’s use the additional space available with EFS to build a machine learning inference API processing images.

Building a Serverless Machine Learning Inference API
To create a Lambda function implementing machine learning inference, I need to be able, in my code, to import the necessary libraries and load the machine learning model. Often, when doing so, the overall size of those dependencies goes beyond the current AWS Lambda limits in the deployment package size. One way of solving this is to accurately minimize the libraries to ship with the function code, and then download the model from an S3 bucket straight to memory (up to 3 GB, including the memory required for processing the model) or to /tmp (up 512 MB). This custom minimization and download of the model has never been easy to implement. Now, I can use an EFS file system.

The Lambda function I am building this time needs access to the public internet to download a pre-trained model and the images to run inference on. So I create a new VPC with public and private subnets, and configure a NAT Gateway and the route table used by the the private subnets to give access to the public internet. Using the AWS Cloud Development Kit, it’s just a few lines of code.

I create a new EFS file system and an access point in the new VPC using similar configurations as before. This time, I use /ml for the access point path.

Then, I create a new MLInference Lambda function with the same set up as before for permissions and connect the function to the private subnets of the new VPC. Machine learning inference is quite a heavy workload, so I select 3 GB for memory and 5 minutes for timeout. In the File system configuration, I add the new access point and mount it under /mnt/inference.

The machine learning framework I am using for this function is PyTorch, and I need to put the libraries required to run inference in the EFS file system. I launch an Amazon Linux EC2 instance in a public subnet of the new VPC. In the instance details, I select one of the availability zones where I have an EFS mount point, and then Add file system to automatically mount the same EFS file system I am using for the function. For the security groups of the EC2 instance, I select the default security group (to be able to mount the EFS file system) and one that gives inbound access to SSH (to be able to connect to the instance).

I connect to the instance using SSH and create a requirements.txt file containing the dependencies I need:

torch
torchvision
numpy

The EFS file system is automatically mounted by EC2 under /mnt/efs/fs1. There, I create the /ml directory and change the owner of the path to the user and group I am using now that I am connected (ec2-user).

$ sudo mkdir /mnt/efs/fs1/ml
$ sudo chown ec2-user:ec2-user /mnt/efs/fs1/ml

I install Python 3 and use pip to install the dependencies in the /mnt/efs/fs1/ml/lib path:

$ sudo yum install python3
$ pip3 install -t /mnt/efs/fs1/ml/lib -r requirements.txt

Finally, I give ownership of the whole /ml path to the user and group I used for the EFS access point:

$ sudo chown -R 1001:1001 /mnt/efs/fs1/ml

Overall, the dependencies in my EFS file system are using about 1.5 GB of storage.

I go back to the MLInference Lambda function configuration. Depending on the runtime you use, you need to find a way to tell where to look for dependencies if they are not included with the deployment package or in a layer. In the case of Python, I set the PYTHONPATH environment variable to /mnt/inference/lib.

I am going to use PyTorch Hub to download this pre-trained machine learning model to recognize the kind of bird in a picture. The model I am using for this example is relatively small, about 200 MB. To cache the model on the EFS file system, I set the TORCH_HOME environment variable to /mnt/inference/model.

All dependencies are now in the file system mounted by the function, and I can type my code straight in the Function code editor. I paste the following code to have a machine learning inference API:

import urllib
import json
import os

import torch
from PIL import Image
from torchvision import transforms

transform_test = transforms.Compose([
    transforms.Resize((600, 600), Image.BILINEAR),
    transforms.CenterCrop((448, 448)),
    transforms.ToTensor(),
    transforms.Normalize((0.485, 0.456, 0.406), (0.229, 0.224, 0.225)),
])

model = torch.hub.load('nicolalandro/ntsnet-cub200', 'ntsnet', pretrained=True,
                       **{'topN': 6, 'device': 'cpu', 'num_classes': 200})
model.eval()


def lambda_handler(event, context):
    url = event['queryStringParameters']['url']

    img = Image.open(urllib.request.urlopen(url))
    scaled_img = transform_test(img)
    torch_images = scaled_img.unsqueeze(0)

    with torch.no_grad():
        top_n_coordinates, concat_out, raw_logits, concat_logits, part_logits, top_n_index, top_n_prob = model(torch_images)

        _, predict = torch.max(concat_logits, 1)
        pred_id = predict.item()
        bird_class = model.bird_classes[pred_id]
        print('bird_class:', bird_class)

    return json.dumps({
        "bird_class": bird_class,
    })

I add the API Gateway as trigger, similarly to what I did before for the MessageWall function. Now, I can use the serverless API I just created to analyze pictures of birds. I am not really an expert in the field, so I looked for a couple of interesting images on Wikipedia:

An atlantic puffin.
A western grebe.

I call the API to get a prediction for these two pictures:

$ curl https://1a2b3c4d5e.execute-api.us-east-1.amazonaws.com/default/MLInference?url=https://path/to/image/atlantic-puffin.jpg

{"bird_class": "106.Horned_Puffin"}

$ curl https://1a2b3c4d5e.execute-api.us-east-1.amazonaws.com/default/MLInference?url=https://path/to/image/western-grebe.jpg

{"bird_class": "053.Western_Grebe"}

It works! Looking at Amazon CloudWatch Logs for the Lambda function, I see that the first invocation, when the function loads and prepares the pre-trained model for inference on CPUs, takes about 30 seconds. To avoid a slow response, or a timeout from the API Gateway, I use Provisioned Concurrency to keep the function ready. The next invocations take about 1.8 seconds.

Understanding EFS Performance
When using EFS with your Lambda function, is very important to understand how EFS performance works. For throughput, each file system can be configured to use bursting or provisioned mode.

When using bursting mode, all EFS file systems, regardless of size, can burst at least to 100 MiB/s of throughput. Those over 1 TiB in the standard storage class can burst to 100 MiB/s per TiB of data stored in the file system. EFS uses a credit system to determine when file systems can burst. Each file system earns credits over time at a baseline rate that is determined by the size of the file system that is stored in the standard storage class. A file system uses credits whenever it reads or writes data. The baseline rate is 50 KiB/s per GiB of storage.

You can monitor the use of credits in CloudWatch, each EFS file system has a BurstCreditBalance metric. If you see that you are consuming all credits, and the BurstCreditBalance metric is going to zero, you should enable provisioned throughput mode for the file system, from 1 to 1024 MiB/s. There is an additional cost when using provisioned throughput, based on how much throughput you are adding on top of the baseline rate.

To avoid running out of credits, you should think of the throughput as the average you need during the day. For example, if you have a 10GB file system, you have 500 KiB/s of baseline rate, and every day you can read/write 500 KiB/s * 3600 seconds * 24 hours = 43.2 GiB.

If the libraries and everything you function needs to load during initialization are about 2 GiB, and you only access the EFS file system during function initialization, like in the MLInference Lambda function above, that means you can initialize your function (for example because of updates or scaling up activities) about 20 times per day. That’s not a lot, and you would probably need to configure provisioned throughput for the EFS file system.

If you have 10 MiB/s of provisioned throughput, then every day you have 10 MiB/s * 3600 seconds * 24 hours = 864 GiB to read or write. If you only use the EFS file system at function initialization to read about 2 GB of dependencies, it means that you can have 400 initializations per day. That may be enough for your use case.

In the Lambda function configuration, you can also use the reserve concurrency control to limit the maximum number of execution environments used by a function.

If, by mistake, the BurstCreditBalance goes down to zero, and the file system is relatively small (for example, a few GiBs), there is the possibility that your function gets stuck and can’t execute fast enough before reaching the timeout. In that case, you should enable (or increase) provisioned throughput for the EFS file system, or throttle your function by setting the reserved concurrency to zero to avoid all invocations until the EFS file system has enough credits.

Understanding Security Controls
When using EFS file systems with AWS Lambda, you have multiple levels of security controls. I’m doing a quick recap here because they should all be considered during the design and implementation of your serverless applications. You can find more info on using IAM authorization and access points with EFS in this post.

To connect a Lambda function to an EFS file system, you need:

Network visibility in terms of VPC routing/peering and security group.
IAM permissions for the Lambda function to access the VPC and mount (read only or read/write) the EFS file system.
You can specify in the IAM policy conditions which EFS access point the Lambda function can use.
The EFS access point can limit access to a specific path in the file system.
File system security (user ID, group ID, permissions) can limit read, write, or executable access for each file or directory mounted by a Lambda function.

The Lambda function execution environment and the EFS mount point uses industry standard Transport Layer Security (TLS) 1.2 to encrypt data in transit. You can provision Amazon EFS to encrypt data at rest. Data encrypted at rest is transparently encrypted while being written, and transparently decrypted while being read, so you don’t have to modify your applications. Encryption keys are managed by the AWS Key Management Service (KMS), eliminating the need to build and maintain a secure key management infrastructure.

Available Now
This new feature is offered in all regions where AWS Lambda and Amazon EFS are available, with the exception of the regions in China, where we are working to make this integration available as soon as possible. For more information on availability, please see the AWS Region table. To learn more, please see the documentation.

EFS for Lambda can be configured using the console, the AWS Command Line Interface (CLI), the AWS SDKs, and the Serverless Application Model. This feature allows you to build data intensive applications that need to process large files. For example, you can now unzip a 1.5 GB file in a few lines of code, or process a 10 GB JSON document. You can also load libraries or packages that are larger than the 250 MB package deployment size limit of AWS Lambda, enabling new machine learning, data modelling, financial analysis, and ETL jobs scenarios.

Amazon EFS for Lambda is supported at launch in AWS Partner Network solutions, including Epsagon, Lumigo, Datadog, HashiCorp Terraform, and Pulumi.

There is no additional charge for using EFS from Lambda functions. You pay the standard price for AWS Lambda and Amazon EFS. Lambda execution environments always connect to the right mount target in an AZ and not across AZs. You can connect to EFS in the same AZ via cross account VPC but there can be data transfer costs for that. We do not support cross region, or cross AZ connectivity between EFS and Lambda.

— Danilo

Introducing the serverless LAMP stack – part 2 relational databases

2020-06-16 Benjamin Smith

Post Syndicated from Benjamin Smith original https://aws.amazon.com/blogs/compute/introducing-the-serverless-lamp-stack-part-2-relational-databases/

In this post, you learn how to use an Amazon Aurora MySQL relational database in your serverless applications. I show how to pool and share connections to the database with Amazon RDS Proxy, and how to choose configurations. The code examples in this post are written in PHP and can be found in this GitHub repository. The concepts can be applied to any AWS Lambda supported runtime.

The serverless LAMP stack

This serverless LAMP stack architecture is first discussed in this post. This architecture uses a PHP Lambda function (or multiple functions) to read and write to an Amazon Aurora MySQL database.

Amazon Aurora provides high performance and availability for MySQL and PostgreSQL databases. The underlying storage scales automatically to meet demand, up to 64 tebibytes (TiB). An Amazon Aurora DB instance is created inside a virtual private cloud (VPC) to prevent public access. To connect to the Aurora database instance from a Lambda function, that Lambda function must be configured to access the same VPC.

Database memory exhaustion can occur when connecting directly to an RDS database. This is caused by a surge in database connections or by a large number of connections opening and closing at a high rate. This can lead to slower queries and limited application scalability. Amazon RDS Proxy is implemented to solve this problem. RDS Proxy is a fully managed database proxy feature for Amazon RDS. It establishes a database connection pool that sits between your application and your relational database and reuses connections in this pool. This protects the database against oversubscription, without the memory and CPU overhead of opening a new database connection each time. Credentials for the database connection are securely stored in AWS Secrets Manager. They are accessed via an AWS Identity and Access Management (IAM) role. This enforces strong authentication requirements for database applications without a costly migration effort for the DB instances themselves.

The following steps show how to connect to an Amazon Aurora MySQL database running inside a VPC. The connection is made from a Lambda function running PHP. The Lambda function connects to the database via RDS Proxy. The database credentials that RDS Proxy uses are held in Secrets Manager and accessed via IAM authentication.

RDS Proxy with IAM authentication

Getting started

RDS Proxy is currently in preview and not recommended for production workloads. For a full list of available Regions, refer to the RDS Proxy pricing page.

Creating an Amazon RDS Aurora MySQL database

Before creating an Aurora DB cluster, you must meet the prerequisites, such as creating a VPC and an RDS DB subnet group. For more information on how to set this up, see DB cluster prerequisites.

Call the create-db-cluster AWS CLI command to create the Aurora MySQL DB cluster.

aws rds create-db-cluster \
--db-cluster-identifier sample-cluster \
--engine aurora-mysql \
--engine-version 5.7.12 \
--master-username admin \
--master-user-password secret99 \
--db-subnet-group-name default-vpc-6cc1cf0a \
--vpc-security-group-ids sg-d7cf52a3 \
--enable-iam-database-authentication true

Add a new DB instance to the cluster.

aws rds create-db-instance \
    --db-instance-class db.r5.large \
    --db-instance-identifier sample-instance \
    --engine aurora-mysql  \
    --db-cluster-identifier sample-cluster

Store the database credentials as a secret in AWS Secrets Manager.

aws secretsmanager create-secret \
--name MyTestDatabaseSecret \
--description "My test database secret created with the CLI" \
--secret-string '{"username":"admin","password":"secret99","engine":"mysql","host":"<REPLACE-WITH-YOUR-DB-WRITER-ENDPOINT>","port":"3306","dbClusterIdentifier":"<REPLACE-WITH-YOUR-DB-CLUSTER-NAME>"}'

Make a note of the resulting ARN for later

{
    "VersionId": "eb518920-4970-419f-b1c2-1c0b52062117", 
    "Name": "MySampleDatabaseSecret", 
    "ARN": "arn:aws:secretsmanager:eu-west-1:1234567890:secret:MySampleDatabaseSecret-JgEWv1"
}

This secret is used by RDS Proxy to maintain a connection pool to the database. To access the secret, the RDS Proxy service requires permissions to be explicitly granted.

Create an IAM policy that provides secretsmanager permissions to the secret.

aws iam create-policy \
--policy-name my-rds-proxy-sample-policy \
--policy-document '{
  "Version": "2012-10-17",
  "Statement": [
    {
      "Sid": "VisualEditor0",
      "Effect": "Allow",
      "Action": [
        "secretsmanager:GetResourcePolicy",
        "secretsmanager:GetSecretValue",
        "secretsmanager:DescribeSecret",
        "secretsmanager:ListSecretVersionIds"
      ],
      "Resource": [
        "<the-arn-of-the-secret>”
      ]
    },
    {
      "Sid": "VisualEditor1",
      "Effect": "Allow",
      "Action": [
        "secretsmanager:GetRandomPassword",
        "secretsmanager:ListSecrets"
      ],
      "Resource": "*"
    }
  ]
}'

Make a note of the resulting policy ARN, which you need to attach to a new role.

{
    "Policy": {
        "PolicyName": "my-rds-proxy-sample-policy", 
        "PermissionsBoundaryUsageCount": 0, 
        "CreateDate": "2020-06-04T12:21:25Z", 
        "AttachmentCount": 0, 
        "IsAttachable": true, 
        "PolicyId": "ANPA6JE2MLNK3Z4EFQ5KL", 
        "DefaultVersionId": "v1", 
        "Path": "/", 
        "Arn": "arn:aws:iam::1234567890112:policy/my-rds-proxy-sample-policy", 
        "UpdateDate": "2020-06-04T12:21:25Z"
     }
}

Create an IAM Role that has a trust relationship with the RDS Proxy service. This allows the RDS Proxy service to assume this role to retrieve the database credentials.

aws iam create-role --role-name my-rds-proxy-sample-role --assume-role-policy-document '{
 "Version": "2012-10-17",
 "Statement": [
  {
   "Sid": "",
   "Effect": "Allow",
   "Principal": {
    "Service": "rds.amazonaws.com"
   },
   "Action": "sts:AssumeRole"
  }
 ]
}'

Attach the new policy to the role:

aws iam attach-role-policy \
--role-name my-rds-proxy-sample-role \
--policy-arn arn:aws:iam::123456789:policy/my-rds-proxy-sample-policy

Create an RDS Proxy

Use the AWS CLI to create a new RDS Proxy. Replace the – -role-arn and SecretArn value to those values created in the previous steps.
```
aws rds create-db-proxy \
--db-proxy-name sample-db-proxy \
--engine-family MYSQL \
--auth '{
        "AuthScheme": "SECRETS",
        "SecretArn": "arn:aws:secretsmanager:eu-west-1:123456789:secret:exampleAuroraRDSsecret1-DyCOcC",
         "IAMAuth": "REQUIRED"
      }' \
--role-arn arn:aws:iam::123456789:role/my-rds-proxy-sample-role \
--vpc-subnet-ids  subnet-c07efb9a subnet-2bc08b63 subnet-a9007bcf
```
To enforce IAM authentication for users of the RDS Proxy, the IAMAuth value is set to REQUIRED. This is a more secure alternative to embedding database credentials in the application code base.
The Aurora DB cluster and its associated instances are referred to as the targets of that proxy.

Add the database cluster to the proxy with the register-db-proxy-targets command.

aws rds register-db-proxy-targets \
--db-proxy-name sample-db-proxy \
--db-cluster-identifiers sample-cluster

Deploying a PHP Lambda function with VPC configuration

This GitHub repository contains a Lambda function with a PHP runtime provided by a Lambda layer. The function uses the MySQLi PHP extension to connect to the RDS Proxy. The extension has been installed and compiled along with a PHP executable using this command:

The PHP executable is packaged together with a Lambda bootstrap file to create a PHP custom runtime. More information on building your own custom runtime for PHP can be found in this post.

Deploy the application stack using the AWS Serverless Application Model (AWS SAM) CLI:

sam deploy -g

When prompted, enter the SecurityGroupIds and the SubnetIds for your Aurora DB cluster.

The SAM template attaches the SecurityGroupIds and SubnetIds parameters to the Lambda function using the VpcConfig sub-resource.

Lambda creates an elastic network interface for each combination of security group and subnet in the function’s VPC configuration. The function can only access resources (and the internet) through that VPC.

Adding RDS Proxy to a Lambda Function

Go to the Lambda console.
Choose the PHPHelloFunction that you just deployed.
Choose Add database proxy at the bottom of the page.
Choose existing database proxy then choose sample-db-proxy.
Choose Add.

Using the RDS Proxy from within the Lambda function

The Lambda function imports three libraries from the AWS PHP SDK. These are used to generate a password token from the database credentials stored in Secrets Manager.

The AWS PHP SDK libraries are provided by the PHP-example-vendor layer. Using Lambda layers in this way creates a mechanism for incorporating additional libraries and dependencies as the application evolves.

The function’s handler named index, is the entry point of the function code. First, getenv() is called to retrieve the environment variables set by the SAM application’s deployment. These are saved as local variables and available for the duration of the Lambda function’s execution.

The AuthTokenGenerator class generates an RDS auth token for use with IAM authentication. This is initialized by passing in the credential provider to the SDK client constructor. The createToken() method is then invoked, with the Proxy endpoint, port number, Region, and database user name provided as method parameters. The resultant temporary token is then used to connect to the proxy.

The PHP mysqli class represents a connection between PHP and a MySQL database. The real_connect() method is used to open a connection to the database via RDS Proxy. Instead of providing the database host endpoint as the first parameter, the proxy endpoint is given. The database user name, temporary token, database name, and port number are also provided. The constant MYSQLI_CLIENT_SSL is set to ensure that the connection uses SSL encryption.

Once a connection has been established, the connection object can be used. In this example, a SHOW TABLES query is executed. The connection is then closed, and the result is encoded to JSON and returned from the Lambda function.

This is the output:

RDS Proxy monitoring and performance tuning

RDS Proxy allows you to monitor and adjust connection limits and timeout intervals without changing application code.

Limit the timeout wait period that is most suitable for your application with the connection borrow timeout option. This specifies how long to wait for a connection to become available in the connection pool before returning a timeout error.

Adjust the idle connection timeout interval to help your applications handle stale resources. This can save your application from mistakenly leaving open connections that hold important database resources.

Multiple applications using a single database can each use an RDS Proxy to divide the connection quotas across each application. Set the maximum proxy connections as a percentage of the max_connections configuration (for MySQL).

The following example shows how to change the MaxConnectionsPercent setting for a proxy target group.

aws rds modify-db-proxy-target-group \
--db-proxy-name sample-db-proxy \
--target-group-name default \
--connection-pool-config '{"MaxConnectionsPercent": 75 }'

Response:

{
    "TargetGroups": [
        {
            "DBProxyName": "sample-db-proxy",
            "TargetGroupName": "default",
            "TargetGroupArn": "arn:aws:rds:eu-west-1:####:target-group:prx-tg-03d7fe854604e0ed1",
            "IsDefault": true,
            "Status": "available",
            "ConnectionPoolConfig": {
            "MaxConnectionsPercent": 75,
            "MaxIdleConnectionsPercent": 50,
            "ConnectionBorrowTimeout": 120,
            "SessionPinningFilters": []
        	},            
"CreatedDate": "2020-06-04T16:14:35.858000+00:00",
            "UpdatedDate": "2020-06-09T09:08:50.889000+00:00"
        }
    ]
}

RDS Proxy may keep a session on the same connection until the session ends when it detects a session state change that isn’t appropriate for reuse. This behavior is called pinning. Performance tuning for RDS Proxy involves maximizing connection reuse by minimizing pinning.

The Amazon CloudWatch metric DatabaseConnectionsCurrentlySessionPinned can be monitored to see how frequently pinning occurs in your application.

Amazon CloudWatch collects and processes raw data from RDS Proxy into readable, near real-time metrics. Use these metrics to observe the number of connections and the memory associated with connection management. This can help identify if a database instance or cluster would benefit from using RDS Proxy. For example, if it is handling many short-lived connections, or opening and closing connections at a high rate.

Conclusion

In this post, you learn how to create and configure an RDS Proxy to manage connections from a PHP Lambda function to an Aurora MySQL database. You see how to enforce strong authentication requirements by using Secrets Manager and IAM authentication. You deploy a Lambda function that uses Lambda layers to store the AWS PHP SDK as a dependency.

You can create secure, scalable, and performant serverless applications with relational databases. Do this by placing the RDS Proxy service between your database and your Lambda functions. You can also migrate your existing MySQL database to an Aurora DB cluster without altering the database. Using RDS Proxy and Lambda, you can build serverless PHP applications faster, with less code.

Find more PHP examples with the Serverless LAMP stack.

Building well-architected serverless applications: Approaching application lifecycle management – part 1

2020-06-15 Julian Wood

Post Syndicated from Julian Wood original https://aws.amazon.com/blogs/compute/building-well-architected-serverless-applications-approaching-application-lifecycle-management-part-1/

Question OPS2: How do you approach application lifecycle management?

Adopt lifecycle management approaches that improve the flow of changes to production with higher fidelity, fast feedback on quality, and quick bug fixing. These practices help you rapidly identify, remediate, and limit changes that impact customer experience. By having an approach to application lifecycle management, you can reduce errors caused by manual process and increase the levels of control to gain confidence your workload operates as intended.

Required practice: Use infrastructure as code and stages isolated in separate environments

Infrastructure as code is a process of provisioning and managing cloud resources by storing application configuration in a template file. Using infrastructure as code helps to deploy applications in a repeatable manner, reducing errors caused by manual processes such as creating resources in the AWS Management Console.

Storing code in a version control system enables tracking and auditing of changes and releases over time. This is used to roll back changes safely to a known working state if there is an issue with an application deployment.

Infrastructure as code

For AWS Cloud development the built-in choice for infrastructure as code is AWS CloudFormation. The template file, written in JSON or YAML, contains a description of the resources an application needs. CloudFormation automates the deployment and ongoing updates of the resources by creating CloudFormation stacks.

CloudFormation code example creating infrastructure

There are a number of higher-level tools and frameworks that abstract and then generate CloudFormation. A serverless specific framework helps model the infrastructure necessary for serverless workloads, providing either declarative or imperative mechanisms to define event sources for functions. It wires permissions between resources automatically, adds resource configuration, code packaging, and any infrastructure necessary for a serverless application to run.

The AWS Serverless Application Model (AWS SAM) is an AWS open-source framework optimized for serverless applications. The AWS Cloud Development Kit allows you to provision cloud resources using familiar programming languages such as TypeScript, JavaScript, Python, Java, and C#/.Net. There are also third-party solutions for creating serverless cloud resources such as the Serverless Framework.

The AWS Amplify Console provides a git-based workflow for building, deploying, and hosting serverless applications including both the frontend and backend. The AWS Amplify CLI toolchain enables you to add backend resources using CloudFormation.

For a large number of resources, consider breaking common functionality such as monitoring, alarms, or dashboards into separate infrastructure as code templates. With CloudFormation, use nested stacks to help deploy them as part of your serverless application stack. When using AWS SAM, import these nested stacks as nested applications from the AWS Serverless Application Repository.

AWS CloudFormation nested stacks

Here is an example AWS SAM template using nested stacks. There are two AWS::Serverless::Application nested resources, api.template.yaml and database.template.yaml. For more information on nested stacks, see the AWS Partner Network blog post: CloudFormation Nested Stacks Primer.

Version control

The serverless airline example application used in this series uses Amplify Console to provide part of the backend resources, including authentication using Amazon Cognito, and a GraphQL API using AWS AppSync.

The airline application code is stored in GitHub as a version control system. Fork, or copy, the application to your GitHub account. Configure Amplify Console to connect to the GitHub fork.

When pushing code changes to a fork, Amplify Console automatically deploys these backend resources along with the rest of the application. It hosts the application at the Production branch URL, and you can also configure a custom domain name if needed.

AWS Amplify Console App details

The Amplify Console configuration to create the API and Authentication backend resources is found in the backend-config.json file. The resources are provisioned during the Amplify Console build phase.

To view the deployed resources, within the Amplify Console, navigate to the awsserverlessairline application. Select Backend environments and then select an environment, in this example sampledev.

Select the API and Authentication tabs to view the created backend resources.

AWS Amplify Console deployed backend resources

Using multiple tools

Applications can use multiple tools and frameworks even within a single project to manage the infrastructure as code. Within the airline application, AWS SAM is also used to provision the rest of the serverless infrastructure using nested stacks. During the Amplify Console build process, the Makefile contains the AWS SAM build instructions for each application service.

For example, the AWS SAM build instructions to deploy the booking service are as follows:

deploy.booking: ##=> Deploy booking service using SAM
	$(info [*] Packaging and deploying Booking service...)
	cd src/backend/booking && \
		sam build && \
		sam package \
			--s3-bucket $${DEPLOYMENT_BUCKET_NAME} \
			--output-template-file packaged.yaml && \
		sam deploy \
			--template-file packaged.yaml \
			--stack-name $${STACK_NAME}-booking-$${AWS_BRANCH} \
			--capabilities CAPABILITY_IAM \
			--parameter-overrides \
	BookingTable=/$${AWS_BRANCH}/service/amplify/storage/table/booking \
	FlightTable=/$${AWS_BRANCH}/service/amplify/storage/table/flight \
	CollectPaymentFunction=/$${AWS_BRANCH}/service/payment/function/collect \
	RefundPaymentFunction=/$${AWS_BRANCH}/service/payment/function/refund \
	AppsyncApiId=/$${AWS_BRANCH}/service/amplify/api/id \
	Stage=$${AWS_BRANCH}

Each service has its own AWS SAM template.yml file. The files contain the resources for each of the booking, catalog, log-processing, loyalty, and payment services. This means that the services can be managed independently within the application as separate stacks. In larger applications, these services may be managed by separate teams, or be in separate repositories, environments or AWS accounts. It may make sense to split out some common functionality such as alarms, or dashboards into separate infrastructure as code templates.

AWS SAM can also use IAM roles to assume temporary credentials and deploy a serverless application to separate AWS accounts.

For more information on managing serverless code, see Best practices for organizing larger serverless applications.

View the deployed resources in the AWS CloudFormation Console. Select Stacks from the left-side navigation bar, and select the View nested toggle.

Viewing CloudFormation nested stacks

The serverless airline application is a more complex example application comprising multiple services composed of multiple CloudFormation stacks. Some stacks are managed via Amplify Console and others via AWS SAM. Using infrastructure as code is not only for large and complex applications. As a best practice, we suggest using SAM or another framework for even simple, small serverless applications with a single stack. For a getting started tutorial, see the example Deploying a Hello World Application.

Improvement plan summary:

Use a serverless framework to help you execute functions locally, build and package application code. Separate packaging from deployment, deploy to isolated stages in separate environments, and support secrets via configuration management systems.
For a large number of resources, consider breaking common functionalities such as alarms into separate infrastructure as code templates.

Conclusion

Introducing application lifecycle management improves the development, deployment, and management of serverless applications. In this post I cover using infrastructure as code with version control to deploy applications in a repeatable manner. This reduces errors caused by manual processes and gives you more confidence your application works as expected.

This well-architected question will continue in an upcoming post where I look further at deploying to multiple stages using temporary environments, and rollout deployments.

Building a location-based, scalable, serverless web app – part 3

2020-06-15 James Beswick

Post Syndicated from James Beswick original https://aws.amazon.com/blogs/compute/building-a-location-based-scalable-serverless-web-app-part-3/

In part 2, I cover the API configuration, geohashing algorithm, and real-time messaging architecture used in the Ask Around Me web application. These are needed for receiving and processing questions and answers, and sending results back to users in real time.

In this post, I explain the backend processing architecture, how data is aggregated, and how to deploy the final application to production. The code and instructions for this application are available in the GitHub repo.

Processing questions

The frontend sends new user questions to the backend via the POST questions API. While the predicted volume of questions is only 1,000 per hour, it’s possible for usage to spike unexpectedly. To help handle this load, the PostQuestions Lambda function puts incoming questions onto an Amazon SQS queue. The ProcessQuestions function takes messages from the Questions queue in batches of 10, and loads these into the Questions table in Amazon DynamoDB.

This asynchronous process smooths out traffic spikes, ensuring that the application is not throttled by DynamoDB. It also provides consistent response times to the front-end POST request, since the API call returns as soon as the message is durably persisted to the queue.

Currently, the ProcessQuestions function does not parse or validate user questions. It would be easy to add message filtering at this stage, using Amazon Comprehend to detect sentiment or inappropriate language. These changes would increase the processing time per question, but by handling this asynchronously, the initial POST API latency is not adversely affected.

The ProcessQuestions function uses the Geo Library for Amazon DynamoDB that converts the question’s latitude and longitude into a geohash. This geohash attribute is one of the indexes in the underlying DynamoDB table. The GetQuestions function using the same library for efficiently querying questions based on proximity to the user.

There are a couple of different mechanisms used to pass information between the frontend and backend applications. When the frontend first initializes, it retrieves the current location of the user from the browser. It then calls the questions API to get a list of active questions within 5 miles of the current location. This retrieves the state up to this point in time. To receive notifications of new messages posted in the user’s area, the frontend also subscribes to the geohash topic in AWS IoT Core.

Processing answers

The application allows two types of question that have different answer types. First, the rating questions accept an answer with a 0–5 score range. Second, the geography questions accept a geo-point, which is a latitude and longitude representing a location.

Similar to the way questions are handled, answers are also queued before processing. However, the PostAnswers Lambda function sends answers to different queues, depending on question type. Ratings messages are sent to the StarAnswers queue, while geography messages are routed to the GeoAnswers queue. Star ratings are saved as raw data in the Answers table by the ProcessAnswerStar function. Geography answers are first converted to a geohash before they are stored.

It’s possible for users to submit updates to their answers. For a star rating, the processing function simply saves the new score. For geography answers, if the updated answer contains a latitude and longitude close enough to the original answer, it results in the same geohash. This is due to the different aggregation processes used for these types of answers.

Aggregating data

In this application, the users asking questions are seeking aggregated answers instead of raw data. For example, “How do you rate the park?” shows an average score from users instead of thousands of individual ratings. To maintain performance, this aggregation occurs when new answers are saved to the database, not when the application fetches the question list.

The Answers table emits updates to a DynamoDB stream whenever new items are inserted or updated. The StreamSpecification parameter in the table definition is set to NEW_AND_OLD_IMAGES, meaning the stream record contains both the new and old item record.

New answers to questions are new items in the table, so the stream record only contains the new image. If users update their answers, this creates an updated item in the table, and the stream record contains both the new and old images of the item.

For star ratings, when receiving an updated rating, the Aggregation function uses both images to calculate the delta in the score. For example, if the old rating was 2 and the user changes this to 5, then the delta is 3. The summary score related to the answer is updated in the Questions table, using a DynamoDB update expression:

    const result = await myGeoTableManager.updatePoint({
      RangeKeyValue: { S: update }, 
      GeoPoint: {
        latitude: item.lat,
        longitude: item.lng
      },
      UpdateItemInput: {
        UpdateExpression: 'ADD answers :deltaAnswers, totalScore :deltaTotalScore',
        ExpressionAttributeValues: {
          ':deltaAnswers': { N: item.deltaAnswers.toString()},
          ':deltaTotalScore': { N: item.deltaValue.toString()}
        }
      }
    }).promise()

For geo-point ratings, the same approach is used but if the geohash changes, then the delta is -1 for the geohash in the old image, and +1 for the geohash in the new image. The update expression automatically creates a new geohash attribute on the DynamoDB item if it is not already present:

    const result = await myGeoTableManager.updatePoint({
      RangeKeyValue: { S: item.ID }, 
      GeoPoint: {
        latitude: item.lat,
        longitude: item.lng
      },
      UpdateItemInput: {
        UpdateExpression: `ADD ${item.geohash} :deltaAnswers, answers :deltaAnswers`,
        ExpressionAttributeValues: {
          ':deltaAnswers': { N: item.deltaAnswers.toString() }          
        }
      }
    }).promise()

By using a Lambda function as a DynamoDB stream processor, you can aggregate large amounts of data in near real time. The Questions and Answers tables have a one-to-many relationship – many answers belong to one question. As answers are saved, the aggregation process updates the summaries in the Questions table.

The Questions table also publishes updates to another DynamoDB stream. These are consumed by a Lambda function that sends the aggregated update to topics in AWS IoT Core. This is how updated scores are sent back to the frontend client application.

Publishing to production with Amplify Console

At this point, you can run the application on your local development machine and view the application via the localhost Vue.js server. Once you are ready to launch the application to users, you must deploy to production.

Single-page applications are easy to deploy publicly. The build process creates static HTML, JS, and CSS files. These can be served via Amazon S3 and Amazon CloudFront, together with any image and media assets used. The process of running the build process and managing the deployment can be automated using AWS Amplify Console.

In this walk through, I use GitHub as the repo provider. You can also use AWS CodeCommit, Bitbucket, GitLab, or upload the build directory from your machine.

To deploy the front end via Amplify Console:

From the AWS Management Console, select the Services dropdown and choose AWS Amplify. From the initial splash screen, choose Get Started under Deploy.
Select GitHub as the repository provider, then choose Continue:
Follow the prompts to enable GitHub access, then select the repository dropdown and choose the repo. In the Branch dropdown, choose master. Choose Next.
In the App build and test settings page, choose Next.
In the Review page, choose Save and deploy.
The final screen shows the deployment pipeline for the connected repo, starting at the Provision phase:

After a few minutes, the Build, Deploy, and Verify steps show green checkmarks. Open the URL in a browser, and you see that the application is now served by the public URL:

Finally, before logging in, you must add the URL to the list of allowed URLs in the Auth0 settings:

Log into Auth0 and navigate to the dashboard.
Choose Applications in the menu, then select Ask Around Me from the list of applications.
On the Settings tab, add the application’s URL to Allowed Callback URLs, Allowed Logout URLs, and Allowed Web Origins. Separate from the existing values using a comma.
Choose Save changes. This allows the new published domain name to interact with Auth0 for authentication your application’s users.

Anytime you push changes to the code repository, Amplify Console detects the commit and redeploys the application. If errors are detected, the existing version is presented to users. If there are no errors, the new version is served to visitors.

Conclusion

In the last part of this series, I show how the application queues posted questions and answers. I explain how this asynchronous approach smooths traffic spikes and helps maintain responsive APIs.

I cover how answers are collected from thousands of users and are aggregated using DynamoDB streams. These totals are saved as summaries in the Questions table, and live updates are pushed via AWS IoT Core back to the frontend.

Finally, I show how you can automate deployment using Amplify Console. By connecting the service directly with your code repository, it publishes and serves your application with no need to manually copy files.

To learn more about this application, see the accompanying GitHub repo.

Building a location-based, scalable, serverless web app – part 2

2020-06-10 James Beswick

Post Syndicated from James Beswick original https://aws.amazon.com/blogs/compute/building-a-location-based-scalable-serverless-web-app-part-2/

Part 1 introduces the Ask Around Me web application that allows users to send questions to other local users in real time. I explain the app’s functionality and how using a single-page application (SPA) framework complements a serverless backend. I configure Auth0 for authentication and show how to deploy the frontend and backend. I also introduce how SPA frontends can send and receive data using both a traditional API and real-time messaging via a WebSocket.

In this post, I review the backend architecture, Amazon API Gateway’s HTTP APIs, and the geohashing implementation. The code and instructions for this application are available in the GitHub repo.

Architecture overview

After deploying the application using the repo’s README.md instructions, the backend architecture looks like this:

The Vue.js frontend primarily interacts with the backend via HTTP APIs using Amazon API Gateway. When users submit questions or answers, the data is sent via the POST API endpoints. When the frontend requests lists of questions or answers, this occurs via the GET API endpoints.

Incoming questions and answers are posted to separate Amazon SQS queues. These queues invoke AWS Lambda functions that process and store the data in the application’s Amazon DynamoDB tables. In the Questions table, the application saves geo-location data and aggregated statistics for each question. The Answers table maintains a record of user IDs and answers to ensure that each user can only post one answer per question.

When new answers are stored in the Answers tables, a DynamoDB stream triggers a Lambda aggregation function with the update. This calculates average scores for questions and aggregates data for the heat map, then stores the result in the main Questions table. When the Questions table is updated, this DynamoDB stream invokes the Publish Lambda function. This publishes updates to the relevant topic in AWS IoT Core, which the front-end application subscribes to.

Using HTTP APIs

API Gateway is a common integration service used between the frontend and backend of serverless web applications. You can choose between the standard REST APIs, and the newer HTTP APIs. The choice depends upon which features you need, and cost considerations for your workload.

This application uses JWT authentication via Auth0 and Lambda proxy integration, and both are supported by HTTP APIs. Many advanced features like API key management, Amazon Cognito integration, and usage plans are not required in this application. It’s also important to compare to cost of each service:

API type	Hourly	Daily	Annually
PUT questions	1,000	24,000	8,760,000
GET questions	50,000	1,200,000	438,000,000
PUT answers	10,000	240,000	87,600,000

Total API requests			534,360,000

REST APIs cost			$1,870.26
HTTP APIs			$534.36

Using the predicted API usage covered in part 1, you can compare the REST APIs and HTTP APIs overall cost. At an estimated $534 annually, the HTTP APIs option is approximately 30% of the cost of REST APIs.

The AWS Serverless Application Model (SAM) template in the repo defines the HTTP API resource and CORS configuration. It also includes the Auth0 authorizer used to validate each API request:

  MyApi:
    Type: AWS::Serverless::HttpApi
    Properties:
     Auth:
        Authorizers:
          MyAuthorizer:
            JwtConfiguration:
              issuer: !Ref Auth0issuer
              audience:
                - https://auth0-jwt-authorizer
            IdentitySource: "$request.header.Authorization"
        DefaultAuthorizer: MyAuthorizer

      CorsConfiguration:
        AllowMethods:
          - GET
          - POST
          - DELETE
          - OPTIONS
        AllowHeaders:
          - "*"   
        AllowOrigins: 
          - "*"

With the HTTP API resource defined, each Lambda function has an event configuration referencing this resource. All the functions referencing the HTTP API resource automatically use the Auth0 authorizer.

  GetAnswersFunction: 
    Type: AWS::Serverless::Function
    Properties:
      Description: Get all answers for a question
      ... 
      Events:
        Get:
          Type: HttpApi
          Properties:
            Path: /answers/{Key}
            Method: get
            ApiId: !Ref MyApi

Using geohashing in web applications

A key part of the functionality in Ask Around Me is the ability to find and answer questions near the user. Given the expected volume of questions in this system, this requires an efficient way to query based upon location that maintains performance as traffic grows.

In a naïve implementation, you might compare the current geographical position of the user with the geo-location of each question and answer in the database. But with an expected 1,000 questions per hour, this would soon become a slow operation with O(n) performance.

A more efficient solution is geohashing. This divides the geographical area of the planet into series of grid cells that are identified by an alphanumeric hash. The first character of the hash identifies one of 32 cells in the grid, roughly 5000 km x 5000 km on the planet. The second character identifies one of 32 squares in that first cell, so combining the first two characters provides a resolution of approximately 1250 km x 1250 km. By the 12th character in the hash, you can identify an area as small as a couple of square inches on Earth. For a more detailed explanation, see this geohashing site.

When using this algorithm, it’s important to choose the correct level of resolution. For Ask Around Me, the frontend searches for questions within 5 miles of the user. You can identify these areas with a 5-character hash. This means you can compare the user’s current location using their geohash, to the geohash stored in the Questions table. This comparison allows you to immediately discard most questions from the search and quickly find the relevant items.

This solution uses the Geo Library for Amazon DynamoDB npm library. Both the GET and POST questions APIs use this library to calculate the geohash when storing and fetching questions. The library requires a dedicated DynamoDB table, which is why user answers are stored in a separate table.

The GET questions API uses the latitude and longitude from the query parameters to query the underlying DynamoDB using this library:

const AWS = require('aws-sdk')
AWS.config.update({region: process.env.AWS_REGION})

const ddb = new AWS.DynamoDB() 
const ddbGeo = require('dynamodb-geo')
const config = new ddbGeo.GeoDataManagerConfiguration(ddb, process.env.TableName)
config.hashKeyLength = 5

const myGeoTableManager = new ddbGeo.GeoDataManager(config)
const SEARCH_RADIUS_METERS = 4000

exports.handler = async (event) => {

  const latitude = parseFloat(event.queryStringParameters.lat)
  const longitude = parseFloat(event.queryStringParameters.lng)

  // Get questions within geo range
  const result = await myGeoTableManager.queryRadius({
    RadiusInMeter: SEARCH_RADIUS_METERS,
    CenterPoint: {
      latitude,
      longitude
    }
  })

  return {
    statusCode: 200,
    body: JSON.stringify(result)
  }
}

The publish/subscribe pattern for real time in web apps

Modern web applications frequently use real-time notifications to keep users informed of state changes. You could achieve this with frequently polling of the APIs to fetch new information. However, this approach is usually wasteful, both in cost and compute terms, because most API calls do not return new information. Additionally, if updates are evenly distributed and you poll every n seconds, there is an average delay of n/2 seconds between data becoming available and your application receiving it.

Instead of polling, a better option for many web applications is a WebSocket. Data availability is closer to real time, and the messaging is less frequent. This can be important for web applications used on mobile devices where unnecessary messaging can impact battery life.

This approach uses the publish-subscribe pattern. The frontend makes subscriptions to a backend service, indicating topics of interest. The backend service receives messages from publishers, which are upstream processes in the application. It filters the messages and routes to the appropriate subscribers.

Although powerful, this can be complex to implement due to connectivity issues over networks. For a web application, users may turn off their devices, disconnect Wi-Fi, or become unreachable due to limited coverage. This pattern is generally forward-only, meaning you only receive messages after the point of subscription.

AWS IoT Core simplifies this process, and the JavaScript SDK handles the common reconnection issues. The backend application sends messages to topics in AWS IoT Core, and the frontend application subscribes to topics of interest. The service maintains the list of active publishers and subscribers, and routes messages between the two. It also automatically manages fan-out, which occurs when there are many subscribers to a single topic.

From a pricing perspective, this is also a cost-efficient approach. At the time of writing, AWS IoT Core costs $0.08 per million minutes of connection, and $1.00 per million messages. There are also no servers to manage, and the service scales automatically to handle your application’s load.

In the example application, the real-time connection is configured and managed in a single component, IoT.vue. This initiates a connection to an IoT endpoint when the application first starts, and listens for messages on subscribed topics. It passes data back to the global Vuex store so other components automatically receive updates with no dependency on the IoT component.

Choosing publish-subscribe topics for web apps

In a typical synchronous API call, the client application makes a specific request and receives a response from a backend service. With a topic-based subscription, the topic itself is the equivalent of the request, but you usually don’t receive immediate information.

In this web application, there are a number of topics that are potentially important to users. Some topics are shared across multiple users, while other are private to a single user:

Account-level topic: messages relating only to a single user ID, such as billing and notifications. These are intended for any devices where that user is logged in.
Per-question topic: when a user asks a question, they need alerts when new answers arrive. Each question ID maps to an individual topic. Anyone who asks or watches a question subscribes to this topic.
Geo-fenced alert topic: a user receives alerts when new questions are asked in their local area. In this case, the geohash of their location is the topic identifier. New questions are published to their geohash topics, and users within the same geohash area receive those messages.
A system-wide topic: this is a single topic that all users subscribe to. This is reserved for important messages for all application users.

In web applications, you subscribe to some topics when the application initializes, such as account-level or system-wide topics. Other subscriptions are dynamic. For example, you subscribe to a question ID topic only after posting a question, or subscribe to different geo-fence hashes when the user’s location changes.

Conclusion

This post explores the backend architecture of the Ask Around Me application. I compare the cost and features in deciding between REST APIs and HTTP APIs in API Gateway. I introduce geohashing and the npm library used to handle geo-location queries in DynamoDB. And I show how you can build real-time messaging into your web applications using the publish-subscribe pattern with AWS IoT Core.

To learn more, visit the application’s code repo on GitHub.

Introducing the new Serverless LAMP stack

2020-06-09 Benjamin Smith

Post Syndicated from Benjamin Smith original https://aws.amazon.com/blogs/compute/introducing-the-new-serverless-lamp-stack/

This is the first in a series of posts for PHP developers. The series will explain how to use serverless technologies with PHP. It covers the available tools, frameworks and strategies to build serverless applications, and why now is the right time to start.

In future posts, I demonstrate how to use AWS Lambda for web applications built with PHP frameworks such as Laravel and Symphony. I show how to move from using Lambda as a replacement for web hosting functionality to a decoupled, event-driven approach. I cover how to combine multiple Lambda functions of minimal scope with other serverless services to create performant scalable microservices.

In this post, you learn how to use PHP with Lambda via the custom runtime API. Visit this GitHub repository for the sample code.

The Serverless LAMP stack

The challenges with traditional PHP applications

Scalability is an inherent challenge with the traditional LAMP stack. A scalable application is one that can handle highly variable levels of traffic. PHP applications are often scaled horizontally, by adding more web servers as needed. This is managed via a load balancer, which directs requests to various web servers. Each additional server brings additional overhead with networking, administration, storage capacity, backup and restore systems, and an update to asset management inventories. Additionally, each horizontally scaled server runs independently. This can result in configuration synchronization challenges.

Horizontal scaling with traditional LAMP stack applications.

New storage challenges arise as each server has its own disks and filesystem, often requiring developers to add a mechanism to handle user sessions. Using serverless technologies, scalability is managed for the developer.

If traffic surges, the services scale to meet the demand without having to deploy additional servers. This allows applications to quickly transition from prototype to production.

The serverless LAMP architecture

A traditional web application can be split in to two components:

The static assets (media files, css, js)
The dynamic application (PHP, MySQL)

A serverless approach to serving these two components is illustrated below:

The serverless LAMP stack

All requests for dynamic content (anything excluding /assets/*) are forwarded to Amazon API Gateway. This is a fully managed service for creating, publishing, and securing APIs at any scale. It acts as the “front door” to the PHP application, routing requests downstream to Lambda functions. The Lambda functions contain the business logic and interaction with the MySQL database. You can pass the input to the Lambda function as any combination of request headers, path variables, query string parameters, and body.

Notable AWS features for PHP developers

Amazon Aurora Serverless

During re:Invent 2017, AWS announced Aurora Serverless, an on-demand serverless relational database with a pay-per-use cost model. This manages the responsibility of relational database provisioning and scaling for the developer.

Lambda Layers and custom runtime API.

At re:Invent 2018, AWS announced two new Lambda features. These enable developers to build custom runtimes, and share and manage common code between functions.

Improved VPC networking for Lambda functions.

In September 2019, AWS announced significant improvements in cold starts for Lambda functions inside a VPC. This results in faster function startup performance and more efficient usage of elastic network interfaces, reducing VPC cold starts.

Amazon RDS Proxy

At re:Invent 2019, AWS announced the launch of a new service called Amazon RDS Proxy. A fully managed database proxy that sits between your application and your relational database. It efficiently pools and shares database connections to improve the scalability of your application.

Significant moments in the serverless LAMP stack timeline

Combining these services, it is now it is possible to build secure and performant scalable serverless applications with PHP and relational databases.

Custom runtime API

The custom runtime API is a simple interface to enable Lambda function execution in any programming language or a specific language version. The custom runtime API requires an executable text file called a bootstrap. The bootstrap file is responsible for the communication between your code and the Lambda environment.

To create a custom runtime, you must first compile the required version of PHP in an Amazon Linux environment compatible with the Lambda execution environment .To do this, follow these step-by-step instructions.

The bootstrap file

The file below is an example of a basic PHP bootstrap file. This example is for explanation purposes as there is no error handling or abstractions taking place. To ensure that you handle exceptions appropriately, consult the runtime API documentation as you build production custom runtimes.

#!/opt/bin/php
<?PHP

// This invokes Composer's autoloader so that we'll be able to use Guzzle and any other 3rd party libraries we need.
require __DIR__ . '/vendor/autoload.php;

// This is the request processing loop. Barring unrecoverable failure, this loop runs until the environment shuts down.
do {
    // Ask the runtime API for a request to handle.
    $request = getNextRequest();

    // Obtain the function name from the _HANDLER environment variable and ensure the function's code is available.
    $handlerFunction = array_slice(explode('.', $_ENV['_HANDLER']), -1)[0];
    require_once $_ENV['LAMBDA_TASK_ROOT'] . '/src/' . $handlerFunction . '.php;

    // Execute the desired function and obtain the response.
    $response = $handlerFunction($request['payload']);

    // Submit the response back to the runtime API.
    sendResponse($request['invocationId'], $response);
} while (true);

function getNextRequest()
{
    $client = new \GuzzleHttp\Client();
    $response = $client->get('http://' . $_ENV['AWS_LAMBDA_RUNTIME_API'] . '/2018-06-01/runtime/invocation/next');

    return [
      'invocationId' => $response->getHeader('Lambda-Runtime-Aws-Request-Id')[0],
      'payload' => json_decode((string) $response->getBody(), true)
    ];
}

function sendResponse($invocationId, $response)
{
    $client = new \GuzzleHttp\Client();
    $client->post(
    'http://' . $_ENV['AWS_LAMBDA_RUNTIME_API'] . '/2018-06-01/runtime/invocation/' . $invocationId . '/response',
       ['body' => $response]
    );
}

The #!/opt/bin/php declaration instructs the program loader to use the PHP binary compiled for Amazon Linux.

The bootstrap file performs the following tasks, in an operational loop:

Obtains the next request.
Executes the code to handle the request.
Returns a response.

Follow these steps to package the bootstrap and compiled PHP binary together into a `runtime.zip`.

Libraries and dependencies

The runtime bootstrap uses an HTTP-based local interface. This retrieves the event payload for each Lambda function invocation and returns back the response from the function. This bootstrap file uses Guzzle, a popular PHP HTTP client, to make requests to the custom runtime API. The Guzzle package is installed using Composer package manager. Installing packages in this way creates a mechanism for incorporating additional libraries and dependencies as the application evolves.

Follow these steps to create and package the runtime dependencies into a `vendors.zip` binary.

Lambda Layers provides a mechanism to centrally manage code and data that is shared across multiple functions. When a Lambda function is configured with a layer, the layer’s contents are put into the /opt directory of the execution environment. You can include a custom runtime in your function’s deployment package, or as a layer. Lambda executes the bootstrap file in your deployment package, if available. If not, Lambda looks for a runtime in the function’s layers. There are several open source PHP runtime layers available today, most notably:

The following steps show how to publish the `runtime.zip` and `vendor.zip` binaries created earlier into Lambda layers and use them to build a Lambda function with a PHP runtime:

Use the AWS Command Line Interface (CLI) to publish layers from the binaries created earlier

aws lambda publish-layer-version \
    --layer-name PHP-example-runtime \
    --zip-file fileb://runtime.zip \
    --region eu-west-1

aws lambda publish-layer-version \
    --layer-name PHP-example-vendor \
    --zip-file fileb://vendors.zip \
    --region eu-west-1

Make note of each command’s LayerVersionArn output value (for example arn:aws:lambda:eu-west-1:XXXXXXXXXXXX:layer:PHP-example-runtime:1), which you’ll need for the next steps.

Creating a PHP Lambda function

You can create a Lambda function via the AWS CLI, the AWS Serverless Application Model (SAM), or directly in the AWS Management Console. To do this using the console:

Navigate to the Lambda section of the AWS Management Console and choose Create function.
Enter “PHPHello” into the Function name field, and choose Provide your own bootstrap in the Runtime field. Then choose Create function.
Right click on bootstrap.sample and choose Delete.
Choose the layers icon and choose Add a layer.
Choose Provide a layer version ARN, then copy and paste the ARN of the custom runtime layer from in step 1 into the Layer version ARN field.
Repeat steps 6 and 7 for the vendor ARN.
In the Function Code section, create a new folder called src and inside it create a new file called index.php.

Paste the following code into index.php:

//index function
function index($data)
{
 return "Hello, ". $data['name'];
}

Insert “index” into the Handler input field. This instructs Lambda to run the index function when invoked.
Choose Save at the top right of the page.
Choose Test at the top right of the page, and enter “PHPTest” into the Event name field. Enter the following into the event payload field and then choose Create:{ "name": "world"}
Choose Test and Select the dropdown next to the execution result heading.

You can see that the event payload “name” value is used to return “hello world”. This is taken from the $data['name'] parameter provided to the Lambda function. The log output provides details about the actual duration, billed duration, and amount of memory used to execute the code.

Conclusion

This post explains how to create a Lambda function with a PHP runtime using Lambda Layers and the custom runtime API. It introduces the architecture for a serverless LAMP stack that scales with application traffic.

Lambda allows for functions with mixed runtimes to interact with each other. Now, PHP developers can join other serverless development teams focusing on shipping code. With serverless technologies, you no longer have to think about restarting webhosts, scaling or hosting.

Start building your own custom runtime for Lambda.

Building a location-based, scalable, serverless web app – part 1

2020-06-01 James Beswick

Post Syndicated from James Beswick original https://aws.amazon.com/blogs/compute/building-a-location-based-scalable-serverless-web-app-part-1/

Web applications represent a major category of serverless usage. When used with single-page application (SPA) frameworks for front-end development, you can create highly responsive apps. With a serverless backend, these apps can scale to hundreds of thousands of users without you managing a single server.

In this 3-part series, I demonstrate how to build an example serverless web application. The application includes authentication, real-time updates, and location-specific features. I explore the functionality, architecture, and design choices involved. I provide a complete code repository for both the front-end and backend. By the end of these posts, you can use these patterns and examples in your own web applications.

In this series:

Part 1: Deploy the frontend and backend applications, and learn about how SPA web applications interact with serverless backends.
Part 2: Review the backend architecture, Amazon API Gateway HTTP APIs, and the geohashing implementation.
Part 3: Understand the backend data processing and aggregation with Amazon DynamoDB, and the final deployment of the application to production.

The code uses the AWS Serverless Application Model (SAM), enabling you to deploy the application easily in your own AWS account. This walkthrough creates resources covered in the AWS Free Tier but you may incur cost for usage beyond development and testing.

To set up the example, visit the GitHub repo and follow the instructions in the README.md file.

Introducing “Ask Around Me” – The app for finding answers from local users

Ask Around Me is a web application that allows you to ask questions to a community of local users. It’s designed to be used on a smartphone browser.

The front-end uses Auth0 for authentication. For simplicity, it supports social logins with other identity providers. Once a user is logged in, the app displays their local area:

Users can then post questions to the neighborhood. Questions can be ratings-based (“How relaxing is the park?”) or geography-based (“Where is best coffee?”).

Posted questions are published to users within a 5-mile radius. Any user in this area sees new questions appear in the list automatically:

Other users answer questions by providing a star-rating or dropping a pin on a map. As the question owner, you see real-time average scores or a heat map, depending on the question type:

The app is designed to be fun and easy to use. It uses authentication to ensure that votes are only counted once per user ID. It uses geohashing to ensure that users only see and answer questions within their local area. It also keeps the question list and answers up to date in real time to create a sense of immediacy.

In terms of traffic, the app is expected to receive 1,000 questions and 10,000 answers posted per hour. The query that retrieves local questions is likely to receive 50,000 requests per hour. In the course of these posts, I explore the architecture and services chosen to handle this volume. All of this is built serverlessly with cost effectiveness in mind. The cost scales in line with usage, and I discuss how to make the best use of the app budget in this scenario.

SPA frameworks and serverless backends

While you can apply a serverless backend to almost any type of web or mobile framework, SPA frameworks can make development much easier. For modern web development, SPA frameworks like React.js, Vue.js, Angular have grown in popularity for serverless development. They have become the standard way to build complex, rich front-ends.

These frameworks offer benefits to both front-end developers and users. For developers, you can create the application within an IDE and test locally with hot reloading, which renders new content in the same context in the browser. For users, it creates a web experience that’s similar to a traditional application, with reactive content and faster interactive capabilities.

When you build a SPA-based application, the build process creates HTML, JavaScript, and CSS files. You serve these static assets from an Amazon CloudFront distribution with an Amazon S3 bucket set as the origin. CloudFront serves these files from 216 global points of presence, resulting in low latency downloads regardless of where the user is located.

You can also use AWS Amplify Console, which can automate the build and deployment process. This is triggered by build events in your code repo so once you commit code changes, these are automatically deployed to production.

A traditional webserver often serves both the application’s static assets together with dynamic content. In this model, you offload the serving of all of the application assets to a global CDN. The dynamic application is a serverless backend powered by Amazon API Gateway and AWS Lambda. By using a SPA framework with a serverless backend, you can create performant, highly scalable web applications that are also easy to develop.

Configuring Auth0

This application integrates Auth0 for user authentication. The front-end calls out to this service when users are not logged in, and Auth0 provides an open standard JWT token after the user is authenticated. Before you can install and use the application, you must sign up for an Auth0 account and configure the application:

Navigate to https://auth0.com/ and choose Sign Up. Complete the account creation process.
From the dashboard, choose Create Application. Enter AskAroundMe as the name and select Single Page Web Applications for the Application Type. Choose Create.
In the next page, choose the Settings tab. Copy the Client ID and Domain values to a text editor – you need these for setting up the Vue.js application later.
Further down on this same tab, enter the value http://localhost:8080 into the Allowed Logout URLs, Allowed Callback URLs and Allowed Web Origins fields. Choose Save Changes.
On the Connections tab, in the Social section, add google-oauth2 and twitter and ensure that the toggles are selected. This enables social sign-in for your application.

This configuration allows the application to interact with the Auth0 service from your local machine. In production, you must enter the domain name of the application in these fields. For more information, see Auth0’s documentation for Application Settings.

Deploying the application

In the code repo, there are separate directories for the front-end and backend applications. You must install the backend first. To complete this step, follow the detailed instructions in the repo’s README.md.

There are several important environment variables to note from the backend installation process:

IoT endpoint address and Cognito Pool ID: these are used for real-time messaging between the backend and frontend applications.
API endpoint: the base URL path for the backend’s APIs.
Region: the AWS Region where you have deployed the application.

Next, you deploy the Vue.js application from the frontend directory:

The application uses the Google Maps API – sign up for a developer account and make a note of your API key.
Open the main.js file in the src directory. Lines 45 through 62 contain the configuration section where you must add the environment variables above:

Ensure you complete the Auth0 configuration and remaining steps in the README.md file, then you are ready to test.

To launch the frontend application, run npm run serve to start the development server. The terminal shows the local URL where the application is now running:

Open a web browser and navigate to http://localhost:8080 to see the application.

How Vue.js applications work with a serverless backend

Unlike a traditional web application, SPA applications are loaded in the user’s browser and start executing JavaScript on the client-side. The app loads assets and initializes itself before communicating with the serverless backend. This lifecycle and behavior is comparable to a conventional desktop or mobile application.

Vue.js is a component-based framework. Each component optionally contains a user interface with related code and styling. Overall application state may be managed by a store – this example uses Vuex. You can use many of the patterns employed in this application in your own apps.

Auth0 provides a Vue.js component that automates storing and parsing the JWT token in the local browser. Each time the app starts, this component verifies the token and makes it available to your code. This app uses Vuex to manage the timing between the token becoming available and the app needing to request data.

The application completes several initialization steps before querying the backend for a list of questions to display:

Several components can request data from the serverless backend via API Gateway endpoints. In src/views/HomeView.vue, the component loads a list of questions when it determines the location of the user:

const token = await this.$auth.getTokenSilently()
const url = `${this.$APIurl}/questions?lat=${this.currentLat}&lng=${this.currentLng}`
console.log('URL: ', url)
// Make API request with JWT authorization
const { data } = await axios.get(url, {
  headers: {
    // send access token through the 'Authorization' header
    Authorization: `Bearer ${token}`   
  }
})

// Commit question list to global store
this.$store.commit('setAllQuestions', data)

This process uses the Axios library to manage the HTTP request and pass the authentication token in the Authorization header. The resulting dataset is saved in the Vuex store. Since SPA applications react to changes in data, any frontend component displaying data is automatically refreshed when it changes.

The src/components/IoT.vue component uses MQTT messaging via AWS IoT Core. This manages real-time updates published to the frontend. When a question receives a new answer, this component receives an update. The component updates the question status in the global store, and all other components watching this data automatically receive those updates:

        mqttClient.on('message', function (topic, payload) {
          const msg = JSON.parse(payload.toString())
          
          if (topic === 'new-answer') {
            _store.commit('updateQuestion', msg)
          } else {
            _store.commit('saveQuestion', msg)
          }
        })

The application uses both API Gateway synchronous queries and MQTT WebSocket updates to communicate with the backend application. As a result, you have considerable flexibility for tracking overall application state and providing your users with a responsive application experience.

Conclusion

In this post, I introduce the Ask Around Me example web application. I discuss the benefits of using single-page application (SPA) frameworks for both developers and users. I cover how they can create highly scalable and performant web applications when powered with a serverless backend.

In this section, you configure Auth0 and deploy the frontend and backend from the application’s GitHub repo. I review the backend SAM template and the architecture it deploys.

In part 2, I will explain the backend architecture, the Amazon API Gateway configuration, and the geohashing implementation.

How to create SAML providers with AWS CloudFormation

2020-05-27 Rich McDonough

Post Syndicated from Rich McDonough original https://aws.amazon.com/blogs/security/how-to-create-saml-providers-with-aws-cloudformation/

As organizations grow, they often experience an inflection point where it becomes impractical to manually manage separate user accounts in disparate systems. Managing multiple AWS accounts is no exception. Many large organizations have dozens or even hundreds of AWS accounts spread across multiple business units.

AWS provides many solutions that can orchestrate a person’s identity across multiple accounts. AWS Identity and Access Management (IAM), SAML, and OpenID can all help. The solution I describe in this post uses these features and services and can scale to thousands of AWS accounts. It provides a repeatable and automated means for deploying a unified identity management structure across all of your AWS environments. It does this while extending existing identity management into AWS without needing to change your current sources of user information.

About multi-account management

This approach uses AWS CloudFormation StackSets to deploy an identity provider and AWS IAM roles into multiple accounts. Roles may be tailored for your business needs and mapped to administrators, power users, or highly specialized roles that perform domain-specific tasks within your environment. StackSets are a highly scalable tool for multi-account orchestration and enforcement of policies across an organization.

Before deploying this solution across your organization, I recommend that you deploy the stack below into a single AWS account for testing purposes. Then, extend the solution using StackSets across your organization once tested. For more information about AWS CloudFormation Stacks and StackSets, see our documentation.

About SAML and SAML providers

Security Assertion Markup Language 2.0 (SAML) is an open standard for exchanging identity and security information with applications and other external systems. For example, if your organization uses Microsoft Active Directory, you can federate your user accounts to other organizations by way of SAML assertions. Actions that users take in the external organization can then be mapped to the identity of the original user and executed with a role that has predetermined privileges.

If you’re new to SAML, don’t worry! Not only is it ubiquitous, it’s also well documented. Many websites use it to drive their security and infrastructure, and you may have already used it without knowing it. For more information about SAML and AWS, I suggest you start with Enabling SAML for Your AWS Resources.

Properly configured SAML federation provides core security requirements for authentication and authorization, while maintaining a single source of truth for who your users are. It also enables important constraints such as multi-factor authentication and centralized access management. Within AWS IAM, you setup a SAML trust by configuring your identity provider with information about AWS and the AWS IAM roles that you want your federated users to use. SAML is secured using public key authentication.

This solution is a companion to the blog post AWS Federated Authentication with Active Directory Federation Services (AD FS), but it can be applied to any SAML provider.

Solution overview

To orchestrate SAML providers across multiple accounts, you will need the following:

A basic understanding of federated users.
An identity provider that supports SAML, such as Active Directory Federation Services (AD FS), or Shibboleth.
An Amazon Simple Storage Service (Amazon S3) bucket to host the provider’s federation metadata file.
An AWS account that can create StackSets in other accounts. Usually, this is an AWS Organizations master account, with StackSets provisioned into member accounts. See the AWS Organizations User Guide for more details.

Note: You can adapt this solution to retrieve federation metadata from a HTTPS endpoint, such as those published by publicly hosted identity providers, but this solution does not currently offer that.

At this time, CloudFormation does not directly support provisioning a SAML provider. However, you can accomplish this by using a custom resource Lambda function. The sample code provided in this post takes this one step further and deploys your federation metadata from a secure Amazon S3 bucket, as some organizations have requirements about how this metadata is stored.

Figure 1: Architecture diagram

Here’s what the solution architecture looks like, as shown in Figure 1:

An AWS CloudFormation template is created within an AWS account. Most commonly this is your master account within AWS Organizations, but it can be a standalone account as well.
The AWS CloudFormation template is deployed to other AWS accounts within your organization using AWS CloudFormation StackSets.
The AWS CloudFormation StackSet creates the following resources:
1. A new read-only role within AWS IAM that uses the new identity provider as the principal in the IAM role’s trust policy. This is a sample that I use to demonstrate how you can deploy IAM Roles that are bound to a single, dedicated identity provider.
2. An execution role for a custom resource AWS Lambda function.
3. The AWS Lambda function, which creates the identity provider within the destination account.
The new AWS Lambda function is executed, pulling your federation metadata from the master account’s S3 Bucket and creating the new Identity Provider.

Step 1: Upload your federation metadata to a restricted S3 bucket

To ensure that your SAML provider’s federation metadata is exposed only to accounts within your AWS organization, you can upload the metadata to an Amazon S3 bucket and then restrict access to accounts within your organization. The bucket policy follows this template:


{
    "Version": "2012-10-17",
    "Id": "Policy1545178796950",
    "Statement": [
        {
            "Effect": "Allow",
            "Principal": {
                "AWS": "*"
            },
            "Action": "s3:GetObject",
            "Resource": "arn:aws:s3:::<replace with bucket name>/*",
            "Condition": {
                "StringEquals": {
                    "aws:PrincipalOrgID": "<replace with organization ID>"
                }
            }
        }
    ]
}

Once this Amazon S3 bucket policy is in place, upload your federation metadata document to the bucket and note the object URL.

If your organization can share your federation metadata publicly, then there’s no need for this bucket policy. Simply upload your file to the S3 bucket, and make the bucket publicly accessible.

Step 2: Launch the CloudFormation template

To create the SAML provider within AWS IAM, this solution uses a custom resource Lambda function, as CloudFormation does not currently offer the ability to create the configuration directly. In this case, I show you how to use the AWS API to create a SAML provider in each of your member accounts, pulling the federation metadata from an S3 bucket owned by the organization master account.

The actual CloudFormation template follows. A sample read-only role has been included, but I encourage you to replace this with IAM roles that make sense for your environment. Save this template to your local workstation, or to your code repository for tracking infrastructure changes (if you need a source code management system, we recommend AWS CodeCommit).


---
AWSTemplateFormatVersion: 2010-09-09
Description: Create SAML provider

Parameters:
  FederationName:
    Type: String
    Description: Name of SAML provider being created in IAM
  FederationBucket:
    Type: String
    Description: Bucket containing federation metadata
  FederationFile:
    Type: String
    Description: Name of file containing the federation metadata

Resources:
  FederatedReadOnlyRole:
    Type: AWS::IAM::Role
    Properties:
      RoleName: Federated-ReadOnly
      AssumeRolePolicyDocument:
        Version: '2012-10-17'
        Statement:
          - Effect: Allow
            Action: sts:AssumeRoleWithSAML
            Principal:
              Federated: !Sub arn:aws:iam::${AWS::AccountId}:saml-provider/${FederationName}
            Condition:
              StringEquals:
                SAML:aud: https://signin.aws.amazon.com/saml
      Path: '/'
      ManagedPolicyArns:
        - arn:aws:iam::aws:policy/ReadOnlyAccess

  SAMLProviderCustomResourceLambdaExecutionRole:
    Type: AWS::IAM::Role
    Properties:
      AssumeRolePolicyDocument:
        Version: '2012-10-17'
        Statement:
          - Effect: Allow
            Principal:
              Service:
                - lambda.amazonaws.com
            Action:
              - sts:AssumeRole
      Path: "/"
      Policies:
        - PolicyName: root
          PolicyDocument:
            Version: '2012-10-17'
            Statement:
              - Effect: Allow
                Action:
                  - logs:CreateLogGroup
                  - logs:CreateLogStream
                  - logs:PutLogEvents
                Resource: 'arn:aws:logs:*:*:log-group:/aws/lambda/*-SAMLProviderCustomResourceLambda-*:*'
              - Effect: Allow
                Action:
                  - iam:CreateSAMLProvider
                  - iam:DeleteSAMLProvider
                Resource: !Sub arn:aws:iam::${AWS::AccountId}:saml-provider/${FederationName}
              - Effect: Allow
                Action:
                  - iam:ListSAMLProviders
                Resource: '*'
              - Effect: Allow
                Action:
                  - s3:GetObject
                Resource: !Sub 'arn:aws:s3:::${FederationBucket}/*'

  CustomResource:
    Type: Custom::CustomResource
    DependsOn:
      - SAMLProviderCustomResourceLambda
      - SAMLProviderCustomResourceLambdaExecutionRole
    Properties:
      ServiceToken: !GetAtt SAMLProviderCustomResourceLambda.Arn

  SAMLProviderCustomResourceLambda:
    Type: "AWS::Lambda::Function"
    Properties:
      Handler: index.lambda_handler
      Role: !GetAtt SAMLProviderCustomResourceLambdaExecutionRole.Arn
      Runtime: python3.7
      Timeout: 300
      Environment:
        Variables:
          FEDERATION_NAME: !Ref FederationName
          FEDERATION_BUCKET: !Ref FederationBucket
          FEDERATION_FILE: !Ref FederationFile
      Code:
        ZipFile: |
          import boto3, json, os, urllib.request, ssl, time, traceback


          BUCKET = os.getenv('FEDERATION_BUCKET')
          FILE = os.getenv('FEDERATION_FILE')
          NAME = os.getenv('FEDERATION_NAME')


          class SAMLProvider(object):
              def __init__(self):
                  self.iam_client = boto3.client('iam')
                  self.existing_providers = []
                  self._list_saml_providers()
                  self.s3 = boto3.resource('s3')

              def get_federation_metadata(self):
                  try:
                      self.s3.Bucket(BUCKET).download_file(FILE, '/tmp/' + FILE)
                      handle = open('/tmp/' + FILE)
                      data = handle.read()
                      handle.close()
                      os.remove('/tmp/' + FILE)
                      return data
                  except:
                      traceback.print_exc()
                      raise

              def _list_saml_providers(self):
                  providers = []
                  response = self.iam_client.list_saml_providers()
                  for provider in response['SAMLProviderList']:
                      self.existing_providers.append(provider['Arn'])

              def add_saml_provider(self, name):
                  for arn in self.existing_providers:
                      if arn.split('/')[1] == name:
                          print(name + ' already exists as a provider')
                          return False
                  response = self.iam_client.create_saml_provider(SAMLMetadataDocument=self.get_federation_metadata(), Name=name)
                  print('Create response: ' + str(response))
                  return True

              def delete_saml_provider(self, name):
                  for arn in self.existing_providers:
                      if arn.split('/')[1] == name:
                          response = self.iam_client.delete_saml_provider(SAMLProviderArn=arn)
                          print('Delete response: ' + str(response))

          def send_response(event, context, response_status, response_data):
              response_body = json.dumps({
                  'Status': response_status,
                  'Reason': 'See the details in CloudWatch Log Stream: ' + context.log_stream_name,
                  'PhysicalResourceId': context.log_stream_name,
                  'StackId': event['StackId'],
                  'RequestId': event['RequestId'],
                  'LogicalResourceId': event['LogicalResourceId'],
                  'Data': response_data
              })
              print('ResponseURL: %s', event['ResponseURL'])
              print('ResponseBody: %s', response_body)
              try:
                  opener = urllib.request.build_opener(urllib.request.HTTPHandler)
                  request = urllib.request.Request(event['ResponseURL'], data=response_body.encode())
                  request.add_header('Content-Type', '')
                  request.add_header('Content-Length', len(response_body))
                  request.get_method = lambda: 'PUT'
                  response = opener.open(request)
                  print("Status code: %s", response.getcode())
                  print("Status message: %s", response.msg)
              except:
                  traceback.print_exc()


          def lambda_handler(event, context):
              print(event)
              print(context)
              saml = SAMLProvider()
              try:
                  if event['RequestType'] == 'Create':
                      saml.add_saml_provider(NAME)
                      send_response(event, context, 'SUCCESS', {"Message": "Resource creation successful!"})
                  if event['RequestType'] == 'Update':
                      saml.delete_saml_provider(NAME)
                      time.sleep(10)
                      saml.add_saml_provider(NAME)
                      send_response(event, context, 'SUCCESS', {"Message": "Resource update successful!"})
                  if event['RequestType'] == 'Delete':
                      saml.delete_saml_provider(NAME)
                      send_response(event, context, 'SUCCESS', {"Message": "Resource deletion successful!"})
              except:
                  send_response(event, context, "FAILED", {"Message": "Exception during processing"})
                  traceback.print_exc()

As you review this template, note that a Python Lambda function is embedded in the template body itself. This is a useful way to package code along with your CloudFormation templates. The limit for the length of code inline within a CloudFormation template is fixed, as detailed in the AWS CloudFormation user guide. Code that exceeds this length must be saved to a separate location within an Amazon S3 bucket and referenced from your template. However, the preceding snippet is short enough to be included all in one CloudFormation template.

Step 3: Create the StackSet

With your SAML provider metadata securely uploaded to your Amazon S3 bucket, it’s time to create the StackSet.

First, navigate to the CloudFormation console and select StackSets, then Create StackSet.

Figure 2: Creating a new StackSet
Select Template is ready, then Upload a template file. Select Choose file to choose the location of the CloudFormation template, then select Next.

Figure 3: Specifying the template details
Enter a value for StackSet name. Then provide the following configuration parameters and select Next:
1. FederationName: The name of the SAML provider. This is the name of the provider as you see it in IAM once provisioned, and it appears in the ARN of the SAML provider.
2. FederationFile: The file name within S3.
3. FederationBucket: The name of the S3 bucket.
Figure 4: Specifying the StackSet parameters
In the Account numbers field, enter the list of accounts into which you wish to provision this stack. Select a Region from the drop-down menu, then select any concurrent deployment options that you need. For most customers, the concurrent and failure tolerance options generally remain unmodified.

Important: When you enter your list of accounts, you must use the 12-digit account number for each destination, without spaces, and separated by commas.
Because IAM is a global service, there is no need to deploy this to multiple regions. The template must be deployed once per AWS account, although it is managed by a CloudFormation Stack that exists in a single Region.

Figure 5: Selecting your deployment options
Depending on your organization’s security posture, you may have chosen to use self-managed permissions. If that is the case, then you must specify an AWS IAM role that is permitted to execute StackSet deployments, as well as an execution role in the destination accounts. For more info, visit the StackSets’ Grant Self-Managed Permissions documentation page.
Review your selections, accept the IAM role creation acknowledgment, and click Submit to create your stacks. Once completed, ensure that the new identity provider is present in each account by visiting the AWS IAM console.

Summary

Creating a SAML provider across multiple AWS accounts enables enterprises to extend their existing authentication infrastructure into the cloud.

You can extend the solution provided here to deploy different federation metadata to AWS accounts based on specific criteria—for example, if your development and staging accounts have a separate identity provider. You can also add simple logic to the Lambda function that I’ve included in the CloudFormation template. Additionally, you might need to create any number of predefined roles within your AWS organization—using the StackSets approach enables a zero-touch means for creating these roles from a central location.

Organizations looking for even stronger controls over multiple accounts should implement this solution with AWS Organizations. Combined with federated access and centrally managed IAM roles, Organizations provides Service Control Policies and a common framework for deploying CloudFormation Stacks across multiple business units.

If you have feedback about this post, submit comments in the Comments section below. If you have questions about this post, contact AWS Support.

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Building scalable serverless applications with Amazon S3 and AWS Lambda

2020-05-26 James Beswick

Post Syndicated from James Beswick original https://aws.amazon.com/blogs/compute/building-scalable-serverless-applications-with-amazon-s3-and-aws-lambda/

Well-designed serverless applications are typically a combination of managed services connected by custom business logic. One of the most powerful combinations for enterprise application development is Amazon S3 and AWS Lambda. S3 is a highly durable, highly available object store that scales to meet your storage needs. Lambda runs custom code in response to events, automatically scaling with the size of the workload. When you use the two services together, they can provide a scalable core for serverless solutions.

This blog post shows how to design and deploy serverless applications designed around S3 events. The solutions presented use AWS services to create scalable serverless architectures, using minimal custom code. This is the conclusion of a series showing how the S3-to-Lambda pattern can implement the following business solutions:

Translating documents at scale, by using Amazon Translate in response to S3 events.
Automating data imports to DynamoDB tables using objects stored in an S3 bucket.
Creating a searchable enterprise document repository, using S3 and Amazon ML services.
Automating scalable business workflows, integrating S3 and AWS Step Functions.
Converting call center recordings into useful data for analytics, using S3 with Amazon Transcribe.

Bringing the compute layer to the data

Much traditional software operates by bringing data to the compute layer. This means that processes run on batches of data in files, databases, and other sources. This is inherently harder to scale as data volumes grow, often needing a fleet of servers to scale out at peak times. For the developer, this creates operational overhead to ensure that the compute capacity is keeping pace with the data volume.

The S3-to-Lambda serverless pattern instead brings the compute layer to the data. As data arrives, the compute process scales up and down automatically to meet the demand. This allows developers to focus on building business logic for a single item of data, and the execution at scale is handled by the Lambda service.

The image optimization application is a good example for comparing the traditional and serverless approaches. For a busy media site, capturing hundreds of images per minute in an S3 bucket, the operations overhead becomes clearer. A script running on a server must scale up across multiple instances to keep pace with this level of traffic. Compare this to the Lambda-based approach, which scales on-demand. The code itself does not change, whether it is used for a single image or thousands.

Receiving and processing events from S3 in custom code

S3 raises events when objects are put, copied, or deleted in a bucket. It also raises a broad number of other notifications, such as when lifecycle events occur. You can configure S3 to invoke Lambda from these events by using the S3 console, Lambda console, AWS CLI, or AWS Serverless Application Model (SAM) templates.

S3 passes details of the event, not the object itself, to the Lambda function in a JSON object. This object contains an array of records, so it’s possible to receive more than one S3 event per invocation:

As the Lambda handler may receive more than one record, it should iterate through the records collection. It’s best practice to keep the handler small and generic, calling out to the business logic in a separate function or file:

const processEvent = require('my-custom-logic’)

// A Node.js Lambda handler
exports.handler = async (event) => {

  // Capture event – can be used to create mock events
  console.log (JSON.stringify(event, null, 2))  

  // Handle each incoming S3 object in the event
  await Promise.all(
    event.Records.map(async (event) => {
      try {
	  // Pass each event to the business logic handler
        await processEvent(event)
      } catch (err) {
        console.error('Handler error: ', err)
      }
    })
  )
}

This code example takes advantage of concurrent asynchronous executions available in Node.js but similar constructs are available in many other languages. This means that multiple objects are processed in parallel to minimize the overall function execution time.

Instead of handling and logging any errors within the function’s code, it’s also possible to use destinations for asynchronous invocations. You use an On failure condition to route the error to various potential targets, including another Lambda function or other AWS services. For complex applications or those handling large volumes, this provides greater control for managing events that fail processing.

During the development process, you can debug and test the S3-to-Lambda integration locally. First, capture a sample event during development to create a mock event for local testing. The sample applications in this series each use a test harness so the developer can test the handler on a local machine. The test harness invokes the handler locally, providing mock environment variables:

// Mock event
const event = require('./localTestEvent')

// Mock environment variables
process.env.AWS_REGION = 'us-east-1'
process.env.localTest = true
process.env.language = 'en'

// Lambda handler
const { handler } = require('./app')

const main = async () => {
  console.time('localTest')
  await handler(event)
  console.timeEnd('localTest')
}

main().catch(error => console.error(error))

Scaling up when more data arrives

The Lambda service scales up if S3 sends multiple events simultaneously. How this works depends on several factors. If the target Lambda function has sufficient concurrency available, and if any active instances of the function are already processing events, the Lambda service scales up.

The function does not scale up if the reserved concurrency is set to 1 or the scaling capacity is fully consumed for a Region in your account. In this case, the events from S3 are queued internally until a Lambda instance is available for processing. You can request to increase the regional concurrency limit by submitting a request in the Support Center console. You may also intend to perform one-at-a-time processing by setting the reserved concurrency to 1.

Generally, multiple instances of a function are invoked simultaneously when S3 receives multiple objects, to process the events as quickly as possible. It’s this rapid scaling and parallelization in both S3 and Lambda that make this pattern such a powerful core architecture for many applications.

Amazon SNS and Amazon SQS integrations

The native S3 to Lambda integration provides a reliable way to invoke one function per prefix or suffix-pattern per bucket. In example, invoking a function when object keys end in .pdf in a single bucket. This works well for the vast majority of use-cases but you may want to invoke multiple Lambda functions per S3 event.

In this case, S3 can publish notifications to SNS, where events are delivered to a range of targets. These include Lambda functions, SQS queues, HTTP endpoints, email, text messages and push notifications. SNS provides fan-out capability, enabling one event to be delivered to multiple destinations, such as Lambda functions or web hooks, for example.

In busy applications, the volume of S3 events may be too large for a downstream system, such as a non-serverless service. In this case, you can also use an SQS queue as a notification target. After events are published to a queue, they can be consumed by Lambda functions and other services. The queue acts as a buffer and can help smooth out traffic for systems consuming these events. See the DynamoDB importer repository for an example.

Uploading data to S3 in upstream applications

You may have upstream services in your architecture that generate the data stored in S3. Some upstream workloads have spiky usage patterns and large numbers of users, like web or mobile applications. You may increase the performance and throughput of these workloads by uploading directly to S3. This avoids proxying binary data through an API Gateway endpoint or web server.

For example, for a mobile application uploading user photos, S3 and Lambda can handle the upload process for large of numbers of users:

The upstream process, in this case a mobile client, requests a presigned URL from an API Gateway endpoint.
This invokes a Lambda function that requests a presigned URL for the S3 bucket, and returns this back via the API call.
The mobile client sends the data directly to the presigned S3 URL using HTTPS POST. The upload is managed directly by S3.

This simple pattern can be a scalable and cost-effective way to upload large binary data into your applications. After the object successfully uploads, the S3 put event can then asynchronously invoke downstream workflows.

Visit this repository to see an example of a serverless S3 uploader application. You can also see a walkthrough of this process in this YouTube video.

Developing larger applications

As you develop larger serverless applications, it often becomes more practical to split applications into multiple services and repositories for separate teams. Often, individual services must integrate with existing S3 buckets, not create these in the application templates. You may also have to integrate a single service with multiple S3 buckets.

In decoupling larger applications with Amazon EventBridge, I show how you can decouple services within an application using an event bus. This pattern helps separate the producers and consumers of events in your workload. This can make each service become more independent and more resilient to changes with the overall application.

This example demonstrates how the document repository solution can be refactored into several smaller applications that communicate using events. This uses Amazon EventBridge as the event router coordinating the flow. Each application contains a SAM template that defines the EventBridge rule to filter for events, and publishes data back to the event bus after processing is complete.

One of the major benefits to using an event-based architecture is that development teams retain flexibility even as the application grows. It allows developers to separate AWS resources like S3 buckets and DynamoDB tables, from the compute resources, like Lambda functions. This decoupling can simplify the deployment process, help avoid building monoliths, and reduce the cognitive load of developing in large applications.

Conclusion

S3 and Lambda are two highly scalable AWS services that can be powerful when combined in serverless applications. In this post, I summarize many of the patterns shown across this series. I explain the integration pattern and the scaling behavior, and how you can use mock events for local testing and development. You can also use SNS and SQS in some applications for fan-out and buffering of events.

Upstream applications can upload data directly to S3 to achieve greater scalability by avoiding proxies. For larger applications, I show how using an event-based architecture modeled around EventBridge can help decouple application services. This can promote service independence, and help maintain flexibility as applications grow.

To learn more about the S3-to-Lambda architecture pattern, watch the YouTube video series, or explore the articles listed at top of this post.