Dr. Werner Vogels wrote Farewell EC2-Classic, it’s been swell, celebrating the 17 years of loyal duty of the original version that started what we now know as cloud computing. You can read how it made the process of acquiring compute resources simple, even though the stack running behind the scenes was incredibly complex.
We have come a long way since 2006, and we’re not done innovating for our customers. As celebrated in this year’s AWS Storage Day, Amazon EBS was launched 15 years ago this month. James Hamilton, SVP and distinguished engineer at Amazon, wrote Amazon EBS at 15 Years, about how the service has evolved to handle over 100 trillion I/O operations a day, and transfers over 13 exabytes of data daily.
As Dr. Werner said in his piece, “it’s a reminder that building evolvable systems is a strategy, and revisiting your architectures with an open mind is a must.” Our innovation efforts driven by customer feedback continue today, and this week is no different.
Last Week’s Launches Here are some launches that got my attention:
Renaming Amazon Kinesis Data Analytics to Amazon Managed Service for Apache Flink – You can now use Amazon Managed Service for Apache Flink, a fully managed and serverless service for you to build and run real-time streaming applications using Apache Flink. All your existing running applications in Kinesis Data Analytics will work as-is, without any changes. To learn more, see my blog post.
Extended Support for Amazon Aurora and Amazon RDS – You can now get more time for support, up to three years, for Amazon Aurora and Amazon RDS database instances running MySQL 5.7, PostgreSQL 11, and higher major versions. This e will allow you time to upgrade to a new major version to help you meet your business requirements even after the community ends support for these versions.
Enhanced Starter Template for AWS Step Functions Workflow Studio – You can now use starter templates to streamline the process of creating and prototyping workflows swiftly, plus a new code mode, which enables builders to move easily between design and code authoring views. With the improved authoring experience in Workflow Studio, you can seamlessly alternate between a drag-and-drop visual builder experience or the new code editor so that you can pick your preferred tool to accelerate development.
Email Delivery History for Every Email in Amazon SES – You can now troubleshoot individual email delivery problems, confirm delivery of critical messages, and identify engaged recipients on a granular, single email basis. Email senders can investigate trends in delivery performance and see delivery and engagement status for each email sent using Amazon SES Virtual Deliverability Manager.
Response Streaming through Amazon SageMaker Real-time Inference – You can now continuously stream inference responses back to the client to help you build interactive experiences for various generative AI applications such as chatbots, virtual assistants, and music generators.
Other AWS News Some other updates and news that you might have missed:
AI & Sports: How AWS & the NFL are Changing the Game – Over the last 5 years, AWS has partnered with the National Football League (NFL), helping fans better understand the game, helping broadcasters tell better stories, and helping teams use data to improve operations and player safety. Watch AWS CEO, Adam Selipsky, former NFL All-Pro Larry Fitzgerald, and the NFL Network’s Cynthia Frelund during their earlier livestream discussing the intersection of artificial intelligence and machine learning in sports.
Amazon Bedrock Story from Amazon Science – This is a good article explaining the benefits of using Amazon Bedrock to build and scale generative AI applications with leading foundation models, including Amazon’s Titan FMs, which focus on responsible AI to avoid toxic content.
Amazon EC2 Flexibility Score– This is an open source tool developed by AWS to assess any configuration used to launch instances through an Auto Scaling Group (ASG) against the recommended EC2 best practices. It converts the best practice adoption into a “flexibility score” that can be used to identify, improve, and monitor the configurations.
To learn more open-source news and updates, see this newsletter curated by my colleague Ricardo to bring you the latest open source projects, posts, events, and more.
Upcoming AWS Events Check your calendars and sign up for these AWS events:
AWS re:Invent – Ready to start planning your re:Invent? Browse the session catalog now. Join us to hear the latest from AWS, learn from experts, and connect with the global cloud community.
AWS Global Summits – The last in-person AWS Summit will be held in Johannesburg on Sept. 26.
AWS Community Days– Join a community-led conference run by AWS user group leaders in your region: Aotearoa (Sept. 6), Lebanon (Sept. 9), Munich (Sept. 14), Argentina (Sept. 16), Spain (Sept. 23), and Chile (Sept. 30). Visit the landing page to check out all the upcoming AWS Community Days.
CDK Day – A community-led fully virtual event on Sept. 29 with tracks in English and Spanish about CDK and related projects. Learn more at the website.
The post Archive and Purge Data for Amazon RDS for PostgreSQL and Amazon Aurora with PostgreSQL Compatibility using pg_partman and Amazon S3 proposes data archival as a critical part of data management and shows how to efficiently use PostgreSQL’s native range partition to partition current (hot) data with pg_partman and archive historical (cold) data in Amazon Simple Storage Service (Amazon S3). Customers need a cloud-native automated solution to archive historical data from their databases. Customers want the business logic to be maintained and run from outside the database to reduce the compute load on the database server. This post proposes an automated solution by using AWS Glue for automating the PostgreSQL data archiving and restoration process, thereby streamlining the entire procedure.
AWS Glue is a serverless data integration service that makes it easier to discover, prepare, move, and integrate data from multiple sources for analytics, machine learning (ML), and application development. There is no need to pre-provision, configure, or manage infrastructure. It can also automatically scale resources to meet the requirements of your data processing job, providing a high level of abstraction and convenience. AWS Glue integrates seamlessly with AWS services like Amazon S3, Amazon Relational Database Service (Amazon RDS), Amazon Redshift, Amazon DynamoDB, Amazon Kinesis Data Streams, and Amazon DocumentDB (with MongoDB compatibility) to offer a robust, cloud-native data integration solution.
The features of AWS Glue, which include a scheduler for automating tasks, code generation for ETL (extract, transform, and load) processes, notebook integration for interactive development and debugging, as well as robust security and compliance measures, make it a convenient and cost-effective solution for archival and restoration needs.
Solution overview
The solution combines PostgreSQL’s native range partitioning feature with pg_partman, the Amazon S3 export and import functions in Amazon RDS, and AWS Glue as an automation tool.
The solution involves the following steps:
Provision the required AWS services and workflows using the provided AWS Cloud Development Kit (AWS CDK) project.
Set up your database.
Archive the older table partitions to Amazon S3 and purge them from the database with AWS Glue.
Restore the archived data from Amazon S3 to the database with AWS Glue when there is a business need to reload the older table partitions.
The solution is based on AWS Glue, which takes care of archiving and restoring databases with Availability Zone redundancy. The solution is comprised of the following technical components:
An S3 bucket stores Python scripts and database archives.
An S3 Gateway endpoint allows Amazon RDS and AWS Glue to communicate privately with the Amazon S3.
AWS Glue uses a Secrets Manager interface endpoint to retrieve database secrets from Secrets Manager.
AWS Glue ETL jobs run in either private subnet. They use the S3 endpoint to retrieve Python scripts. The AWS Glue jobs read the database credentials from Secrets Manager to establish JDBC connections to the database.
You can create an AWS Cloud9 environment in one of the private subnets available in your AWS account to set up test data in Amazon RDS. The following diagram illustrates the solution architecture.
Prerequisites
For instructions to set up your environment for implementing the solution proposed in this post, refer to Deploy the application in the GitHub repo.
Provision the required AWS resources using AWS CDK
Complete the following steps to provision the necessary AWS resources:
Clone the repository to a new folder on your local desktop.
Create a virtual environment and install the project dependencies.
The CDK project includes three stacks: vpcstack, dbstack, and gluestack, implemented in the vpc_stack.py, db_stack.py, and glue_stack.py modules, respectively.
These stacks have preconfigured dependencies to simplify the process for you. app.py declares Python modules as a set of nested stacks. It passes a reference from vpcstack to dbstack, and a reference from both vpcstack and dbstack to gluestack.
gluestack reads the following attributes from the parent stacks:
The S3 bucket, VPC, and subnets from vpcstack
The secret, security group, database endpoint, and database name from dbstack
The deployment of the three stacks creates the technical components listed earlier in this post.
Archive the historical table partition to Amazon S3 and purge it from the database with AWS Glue
The “Maintain and Archive” AWS Glue workflow created in the first step consists of two jobs: “Partman run maintenance” and “Archive Cold Tables.”
The “Partman run maintenance” job runs the Partman.run_maintenance_proc() procedure to create new partitions and detach old partitions based on the retention setup in the previous step for the configured table. The “Archive Cold Tables” job identifies the detached old partitions and exports the historical data to an Amazon S3 destination using aws_s3.query_export_to_s3. In the end, the job drops the archived partitions from the database, freeing up storage space. The following screenshot shows the results of running this workflow on demand from the AWS Glue console.
Additionally, you can set up this AWS Glue workflow to be triggered on a schedule, on demand, or with an Amazon EventBridge event. You need to use your business requirement to select the right trigger.
Restore archived data from Amazon S3 to the database
The “Restore from S3” Glue workflow created in the first step consists of one job: “Restore from S3.”
This job initiates the run of the partman.create_partition_time procedure to create a new table partition based on your specified month. It subsequently calls aws_s3.table_import_from_s3 to restore the matched data from Amazon S3 to the newly created table partition.
To start the “Restore from S3” workflow, navigate to the workflow on the AWS Glue console and choose Run.
The following screenshot shows the “Restore from S3” workflow run details.
Validate the results
The solution provided in this post automated the PostgreSQL data archival and restoration process using AWS Glue.
You can use the following steps to confirm that the historical data in the database is successfully archived after running the “Maintain and Archive” AWS Glue workflow:
On the Amazon S3 console, navigate to your S3 bucket.
Confirm the archived data is stored in an S3 object as shown in the following screenshot.
From a psql command line tool, use the \dt command to list the available tables and confirm the archived table ticket_purchase_hist_p2020_01 does not exist in the database.
You can use the following steps to confirm that the archived data is restored to the database successfully after running the “Restore from S3” AWS Glue workflow.
From a psql command line tool, use the \dt command to list the available tables and confirm the archived table ticket_history_hist_p2020_01 is restored to the database.
Clean up
Use the information provided in Cleanup to clean up your test environment created for testing the solution proposed in this post.
Summary
This post showed how to use AWS Glue workflows to automate the archive and restore process in RDS for PostgreSQL database table partitions using Amazon S3 as archive storage. The automation is run on demand but can be set up to be trigged on a recurring schedule. It allows you to define the sequence and dependencies of jobs, track the progress of each workflow job, view run logs, and monitor the overall health and performance of your tasks. Although we used Amazon RDS for PostgreSQL as an example, the same solution works for Amazon Aurora-PostgreSQL Compatible Edition as well. Modernize your database cron jobs using AWS Glue by using this post and the GitHub repo. Gain a high-level understanding of AWS Glue and its components by using the following hands-on workshop.
About the Authors
Anand Komandooru is a Senior Cloud Architect at AWS. He joined AWS Professional Services organization in 2021 and helps customers build cloud-native applications on AWS cloud. He has over 20 years of experience building software and his favorite Amazon leadership principle is “Leaders are right a lot.”
Li Liu is a Senior Database Specialty Architect with the Professional Services team at Amazon Web Services. She helps customers migrate traditional on-premise databases to the AWS Cloud. She specializes in database design, architecture, and performance tuning.
Neil Potter is a Senior Cloud Application Architect at AWS. He works with AWS customers to help them migrate their workloads to the AWS Cloud. He specializes in application modernization and cloud-native design and is based in New Jersey.
Vivek Shrivastava is a Principal Data Architect, Data Lake in AWS Professional Services. He is a big data enthusiast and holds 14 AWS Certifications. He is passionate about helping customers build scalable and high-performance data analytics solutions in the cloud. In his spare time, he loves reading and finds areas for home automation.
An increasing number of software as a service (SaaS) providers are considering the move from single to multi-tenant to utilize resources more efficiently and reduce operational costs. This blog aims to inform customers of considerations when evaluating a transformation to multi-tenancy in the Amazon Web Services (AWS) Cloud. You’ll find valuable information on how to optimize your cloud-based SaaS design to reduce operating expenses, increase resiliency, and offer a high-performing experience for your customers.
Single versus multi-tenancy
In a multi-tenant architecture, resources like compute, storage, and databases can be shared among independent tenants. In contrast, a single-tenant architecture allocates exclusive resources to each tenant.
Let’s consider a SaaS product that needs to support many customers, each with their own independent deployed website. Using a single-tenant model (see Figure 1), the SaaS provider may opt to utilize a dedicated AWS account to host each tenant’s workloads. To contain their respective workloads, each tenant would have their own Amazon Elastic Compute Cloud (Amazon EC2) instances organized within an Auto Scaling group. Access to the applications running in these EC2 instances would be done via an Application Load Balancer (ALB). Each tenant would be allocated their own database environment using Amazon Relational Database Service (RDS). The website’s storage (consisting of PHP, JavaScript, CSS, and HTML files) would be provided by Amazon Elastic Block Store (EBS) volumes attached to the EC2 instances. The SaaS provider would have a control plane AWS account used to create and modify these tenant-specific accounts.
Figure 1. Single-tenant configuration
To transition to a multi-tenant pattern, the SaaS provider can use containerization to package each website, and a container orchestrator to deploy the websites across shared compute nodes (EC2 instances). Kubernetes can be employed as a container orchestrator, and a website would then be represented by a Kubernetes deployment and its associated pods. A Kubernetes namespace would serve as the logical encapsulation of the tenant-specific resources, as each tenant would be mapped to one Kubernetes namespace. The Kubernetes HorizontalPodAutoscaler can be utilized for autoscaling purposes, dynamically adjusting the number of replicas in the deployment on a given namespace based on workload demands.
When additional compute resources are required, tools such as the Cluster Autoscaler, or Karpenter, can dynamically add more EC2 instances to the shared Kubernetes Cluster. An ALB can be reused by multiple tenants to route traffic to the appropriate pods. For RDS, SaaS providers can use tenant-specific database schemas to separate tenant data. For static data, Amazon Elastic File System (EFS) and tenant-specific directories can be employed. The SaaS provider would still have a control plane AWS account that would now interact with the Kubernetes and AWS APIs to create and update tenant-specific resources.
This transition to a multi-tenant design utilizing Kubernetes, Amazon Elastic Kubernetes Service (EKS), and other managed services offers numerous advantages. It enables efficient resource utilization by leveraging containerization and auto-scaling capabilities, reducing costs, and optimizing performance (see Figure 2).
Figure 2. Multi-tenant configuration
EKS cluster sizing and customer segmentation considerations in multi-tenancy designs
A high concentration of SaaS tenants hosted within the same system results in a large “blast radius.” This means a failure within the system has the potential to impact all resident tenants. This situation can lead to downtime for multiple tenants at once. To address this problem, SaaS providers are encouraged to partition their customers amongst multiple AWS accounts, each with their own deployments of this multi-tenant architecture. The number of tenants that can be present in a single cluster is a determination that can only be made by the SaaS provider after weighing the risks. Compare the shared fate of some subset of their customers, against the possible efficiency benefits of a multi-tenant architecture.
EKS security
SaaS providers must evaluate whether it’s appropriate for them to make use of containers as a workload isolation boundary. This is of particular importance in multi-tenant Kubernetes architectures, given that containers running on a single Amazon EC2 instance will share the underlying Linux kernel. Security vulnerabilities place this shared resource (the EC2 instance) at risk from attack vectors from the host Linux instance. Risk is elevated when any container running in a Kubernetes Pod cluster initiates untrusted code. This risk is heightened if SaaS providers permit tenants to “bring their code”. Kubernetes is a single tenant orchestrator, but with a multi-tenant approach to SaaS architectures, a single instance of the Amazon EKS control plane will be shared among all the workloads running within a cluster. Amazon EKS considers the cluster as the hard isolation security boundary. Every Amazon EKS managed Kubernetes cluster is isolated in a dedicated single-tenant Amazon VPC. At present, hard multi-tenancy can only be implemented by provisioning a unique cluster for each tenant.
EFS considerations
A SaaS provider may consider EFS as the storage solution for the static content of the multiple tenants. This provides them with a straightforward, serverless, and elastic file system. Directories may be used to separate the content for each tenant. While this approach of creating tenant-specific directories in EFS provides many benefits, there may be challenges harvesting per-tenant utilization and performance metrics. This can result in operational challenges for providers that need to granularly meter per-tenant usage of resources. Consequently, noisy neighbors will be difficult to identify and remediate. To resolve this, SaaS providers should consider building a custom solution to monitor the individual tenants in the multi-tenant file system by leveraging storage and throughput/IOPS metrics.
RDS considerations
Multi-tenant workloads, where data for multiple customers or end users is consolidated in the same RDS database cluster, can present operational challenges regarding per-tenant observability. Both MySQL Community Edition and open-source PostgreSQL have limited ability to provide per-tenant observability and resource governance. AWS customers operating multi-tenant workloads often use a combination of ‘database’ or ‘schema’ and ‘database user’ accounts as substitutes. AWS customers should use alternate mechanisms to establish a mapping between a tenant and these substitutes. This will give you the ability to process raw observability data from the database engine externally. You can then map these substitutes back to tenants, and distinguish tenants in the observability data.
Conclusion
In this blog, we’ve shown what to consider when moving to a multi-tenancy SaaS solution in the AWS Cloud, how to optimize your cloud-based SaaS design, and some challenges and remediations. Invest effort early in your SaaS design strategy to explore your customer requirements for tenancy. Work backwards from your SaaS tenants end goals. What level of computing performance do they require? What are the required cyber security features? How will you, as the SaaS provider, monitor and operate your platform with the target tenancy configuration? Your respective AWS account team is highly qualified to advise on these design decisions. Take advantage of reviewing and improving your design using the AWS Well-Architected Framework. The tenancy design process should be followed by extensive prototyping to validate functionality before production rollout.
The US celebrated Independence Day last week on July 4 with fireworks and barbecues across the country. But fireworks weren’t the only thing that launched last week. Let’s have a look!
Last Week’s Launches Here are some launches that got my attention:
AWS Glue – AWS Glue Crawlers now supports Apache Iceberg tables. Apache Iceberg is an open-source table format for data stored in data lakes. You can now automatically register Apache Iceberg tables into AWS Glue Data Catalog by running the Glue Crawler. You can then query Glue Catalog Iceberg tables across various analytics engines and apply AWS Lake Formation fine-grained permissions when querying from Amazon Athena. Check out the AWS Glue Crawler documentation to learn more.
In addition, Amazon RDS for PostgreSQL Multi-AZ Deployments with two readable standbys now supports logical replication. With logical replication, you can stream data changes from Amazon RDS for PostgreSQL to other databases for use cases such as data consolidation for analytical applications, change data capture (CDC), replicating select tables rather than the entire database, or for replicating data between different major versions of PostgreSQL. Check out the Amazon RDS User Guide for more details.
Amazon CloudWatch – Amazon CloudWatch now supports Service Quotas in cross-account observability. With this, you can track and visualize resource utilization and limits across various AWS services from multiple AWS accounts within a region using a central monitoring account. You no longer have to track the quotas by logging in to individual accounts, instead from a central monitoring account, you can create dashboards and alarms for the AWS service quota usage across all your source accounts from a central monitoring account. Setup CloudWatch cross-account observability to get started.
Amazon SageMaker – You can now associate a SageMaker Model Card with a specific model version in SageMaker Model Registry. This lets you establish a single source of truth for your registered model versions, with comprehensive, centralized, and standardized documentation across all stages of the model’s journey on SageMaker, facilitating discoverability and promoting governance, compliance, and accountability throughout the model lifecycle. Learn more about SageMaker Model Cards in the developer guide.
Other AWS News Here are some additional blog posts and news items that you might find interesting:
Building generative AI applications for your startup – In this AWS Startups Blog post, Hrushikesh explains various approaches to build generative AI applications, and reviews their key component. Read the full post for the details.
Components of the generative AI landscape.
How Alexa learned to speak with an Irish accent – If you’re curious how Amazon researchers used voice conversation to generate Irish-accented training data in Alexa’s own voice, check out this Amazon Science Blog post.
AWS open-source news and updates – My colleague Ricardo writes this weekly open-source newsletter in which he highlights new open-source projects, tools, and demos from the AWS Community.
Upcoming AWS Events Check your calendars and sign up for these AWS events:
AWS Global Summits – Check your calendars and sign up for the AWS Summit close to where you live or work: Hong Kong (July 20), New York City (July 26), Taiwan (August 2-3), São Paulo (August 3), and Mexico City (August 30).
AWS Community Days – Join a community-led conference run by AWS user group leaders in your region: Malaysia (July 22), Philippines (July 29-30), Colombia (August 12), and West Africa (August 19).
AWS re:Invent (November 27 – December 1) – Join us to hear the latest from AWS, learn from experts, and connect with the global cloud community. Registration is now open.
This post is written by Enrico Liguori, Networking Solutions Architect, Hybrid Cloud and Sumeeth Siriyur, Sr. Hybrid Cloud Solutions Architect.
AWS Outposts is a fully managed service that brings the same AWS infrastructure, services, APIs, and tools to virtually any data center, colocation space, manufacturing floor, or on-premises facility where it might be needed. With Outposts, you can run some AWS services on-premises and connect to a broad range of services available in the local AWS Region. Outposts supports workloads requiring low latency, local data processing, data residency, and application migration.
Outposts capacity is driven as per your compute and storage requirements to run workloads. You can monitor Outposts resources using metrics gathered by Amazon CloudWatch. Using these metrics, you can effectively monitor and manage the Outposts resources as they would in the Region, levereging cloud native tools such as CloudWatch dashboards. Check the Monitoring best practices for AWS Outposts blog post to dive deep into the available monitoring options for Outposts.
CloudWatch dashboards are customizable home pages in the CloudWatch console that can be used to monitor resources running on Outposts in a single view. For example, you can monitor in a single pane the number Amazon EC2 instances used per EC2 instance type, the available capacity of Amazon EBS volumes and Amazon S3 buckets, and the operational status of the service link of Outposts.
As a you start deploying additional Outposts resources as a part of their capacity expansion, they must all be integrated and visualized within CloudWatch in an automated way. Traditionally CloudWatch dashboards are built manually and may be time consuming to tune. This post provides also an overview of building CloudWatch dashboards in an automated way using AWS Cloud Development Kit (AWS CDK).
Overview
CloudWatch metrics available to monitor Outposts resources and capacity
CloudWatch metrics for Outposts are available to customers in all public AWS Regions and AWS GovCloud (US) at no additional cost. We can classify the available metrics in two main categories:
To identify the metrics published under the service specific namespaces, we can leverage metadata in the form of tags. A tag is a label that you assign to an AWS resource and consists of a key and an optional value. For the purpose of the monitoring strategy described in this post, we use a tag that contains the OutpostID of the Outpost where the resource is deployed. In this way, we can easily filter the CloudWatch metrics that we would like to show in our dashboard.
The following sections describe two different methods to build a CloudWatch dashboard that includes the different types of metrics described so far. In both cases, we see how particularly useful the presence of tags is to identify the service-specific metrics.
Manual approach to building a CloudWatch dashboard for Outposts
This section describes a manual (i.e., non-automated) approach to building a dashboard that could summarize both the capacity utilization metrics and the service specific metrics for your resources running on Outposts.
The benefit of this approach is that we can implement a fully operational dashboard directly from the CloudWatch console. However, it will simultaneously require more effort to properly tune the dashboard to satisfy your monitoring requirements.
You can start creating the dashboard opening the CloudWatch console and following the steps listed in the public documentation.
To display a metric under AWS/Outposts namespace we can choose any of the widgets available. Based on the nature of the data, we can choose different types of Widgets such as Number, Line, Gauge, Explorer, or you can even build your own custom widget.
Together with the Widget type, we must select Outposts namespace in the metric graph dialog box and then navigate to the specific metric of interest.
In case we are creating the dashboard in a different account than the Outposts owner, we must select the right account in the View data drop-down menu to see the Outposts metric in which we are interested.
After selecting one or more metrics we can select Create widget button.
For the service specific metrics, we recommend using the explorer widget. In this way, we can utilize the tagging strategy described earlier to automatically identify the metrics belonging to the resources running on Outposts. Check the documentation page for a step-by-step guide for creating an explorer widget based on tags.
Automated outpost dashboard
After we’ve seen how to build a dashboard manually from the console, in this secton we describe an automated approach to deploy a dashboard for Outposts through AWS CDK.
AWS CDK is an open source software development framework to model and provision your cloud application resources using familiar programming languages, including TypeScript, JavaScript, Python, C#, and Java. For the solution in this post, we use Python.
Architecture overview
The AWS CDK stack described in this post, assumes that the resources running on Outposts (EC2 instances, S3 buckets, Application Load Balancers (ALBs), and RDS instances) are tagged using the tagging strategy described earlier.
Specifying a tag name and a tag value in a configuration file automatically discovers the resources with that tag and adds the related metrics to the CloudWatch dashboard.
Together with the service specific metrics, it creates a series of widgets that we can use to monitor the capacity available and utilized in each Outpost that belongs to the account where the script is running.
The workflow is made of the following phases:
The AWS CDK stack creates an AWS CodeCommit repository and uploads its own code into it. The code contains a series of modules, one for each section of the CloudWatch dashboard. A section of the dashboard contains one or more widgets showing the metrics of a specific service.
To maintain the CloudWatch dashboard always up-to-date with the resources matching the tag, it creates a pipeline in AWS CodePipeline that can dynamically create and or update the dashboard. The pipeline runs the code in the CodeCommit repository and is made of two stages. In the first one, the build stage, it builds the dependencies needed by the AWS CDK stack. In the second stage, the Deploy stage, it loads and runs the modules used to build the dashboard.
Each module contains the code to automatically discover the tagged resources of a specific service. This discovery phase uses standard AWS APIs called through the Python SDK Boto3.
Based on the results of the discovery phase, AWS CDK produces an AWS CloudFormation template containing the definition of the CloudWatch dashboard sections. The template is submitted to CloudFormation.
CloudFormation creates or, if already defined, updates the CloudWatch dashboard.
Together with the dashboard, the AWS CDK script also contains the definition of a CloudWatch Event that, once deployed, triggers the pipeline each time a resource tagged with the specified tag is created or destroyed.
Prerequisites
To implement the solution presented in this post, you must configure:
b. Go through the AWS CDK bootstrapping process. This is required only for the first time that we use AWS CDK in a specific AWS environment (an AWS environment is a combination of an AWS account and Region).
Step 3: Install the needed Python dependencies with:
$ pip install -r requirements.txt
Step 4: Modify the configuration file
Before deploying the stack, we must modify the configuration file to specify the tag we use for identifying our resources running on Outposts. Open the file with the name config.yaml with your preferred text editor and specify:
A name for the dashboard. The default name used is Automated-CloudWatch-Dashboard.
Replace <tag_name> placeholder following the tag_name variable with the tag name used to tag the resources that you want to include in the dashboard.
Replace <tag_value> placeholder under tag_values variable with the tag value that you used.
Here is an example config.yaml configuration file:
At the end of the deployment process, the pipeline that creates the dashboard is provisioned. You can now go to your CloudWatch console to view it.
Automated Outposts dashboard overview
Now that we have built our dashboard, let’s review each section:
Outpost capacity
The AWS CDK stacks define a capacity section for each Outpost available to the AWS account where the script runs.
In this section, we find four widgets showing metrics published under the AWS/Outpost namespace. The first widget shows for each EC2 instance type available on the Outposts the number of instances utilized and available for that instance type. In the second row, we can visualize the available capacity for the Amazon EBS volumes and for the S3 buckets. The last widget shows the operational status of the service link of Outposts.
2. EC2 instances
In this section of the dashboard, we find the metrics showing the CPU, Network, and Disk Utilization for an EC2 instance. It has defined a section of this type for each EC2 instance with a tag assigned matching the name and the value specified in the configuration file of the script.
3. Application Load Balancer
The ALB section aggregates metrics showing the operational status of a load balancer hosted on Outposts. A section of this type is defined for each ALB with an assigned tag matching the one specified in the configuration file.
4. S3 buckets
The S3 buckets section is defined only once and aggregates the utilization metrics for all S3 buckets with an assigned tag.
5. AutoScaling group
The AutoScaling group section can be used to monitor the number of instances in service in a specific AS group with a tag assigned. This section is defined once and can aggregate the metrics for multiple AutoScaling groups.
Clean up
To terminate the resources that we created in this post, run the following:
$ cdk destroy
Then, go to the Cloudformation console and delete the stack with the name “Deploy-AutomatedCloudWatchDashboard”.
Conclusion
In conclusion, this post demonstrates a manual way of creating CloudWatch Metrics dashboard using the CloudWatch console and an automated way using AWS CDK. The automated approach is also scalable by automatically discovering any new resources added to the existing Outposts in the your environment without any changes to the code.
With Amazon Relational Database Service (Amazon RDS), you can set up, operate, and scale a relational database in the AWS Cloud. Amazon RDS provides cost-efficient, resizable capacity for an industry-standard relational database and manages common database administration tasks.
If you use Amazon RDS for your workloads, you can now use Amazon GuardDutyRDS Protection to help detect threats to your data stored in Amazon Aurora databases. GuardDuty is a continuous security monitoring service that can help you identify and prioritize potential threats in your AWS environment. By analyzing and profiling RDS login activity to your Aurora databases, GuardDuty can detect threats, such as high severity brute force events, suspicious logins, access from Tor, and access by known threat actors.
In this post, we will provide an overview of how to get started with RDS Protection, dive into its finding types, and walk you through examples of how to investigate and remediate findings.
Overview of RDS Protection
RDS Protection in GuardDuty analyzes and profiles Amazon RDS login activity to identify potential threats to your data stored in Aurora databases by using a combination of threat intelligence and machine learning. At launch, RDS Protection supports Aurora MySQL versions 2.10.2 and 3.2.1 or later and Aurora PostgreSQL versions 10.17, 11.12, 12.7, 13.3, and 14.3 or later. An updated list of the supported engines and versions is available in the GuardDuty documentation. RDS Protection doesn’t require additional infrastructure, and you don’t need to configure, collect, or store RDS logs in your own account. RDS Protection is also designed to have no impact on the performance of your database instances so that you don’t have to worry about compromising performance to better secure your data stored in Amazon RDS.
When RDS Protection detects a suspicious or anomalous login attempt that indicates a potential threat to your database instance, GuardDuty generates a finding with details to help you quickly identify relevant information to assist in remediation. RDS Protection findings include details on both anomalous and normal login activity in addition to information such as database instance details, database user details, action information, and actor information. These findings are available to you in the GuardDuty console, AWS Command Line Interface (AWS CLI), and API, and all GuardDuty findings are sent to Amazon EventBridge and AWS Security Hub, giving you options to respond by sending alerts to chat or ticketing systems, or by using AWS Lambda and AWS Systems Manager for automatic remediation.
Enable RDS Protection
Getting started with RDS Protection is simple, and you can do it with just a few steps in the console. Both new and existing GuardDuty customers can take advantage of the GuardDuty RDS Protection 30-day free trial. You can turn RDS Protection on or off for each of your accounts in supported AWS Regions. If you already use GuardDuty, you will need to enable RDS Protection either in the console or CLI, or through the API. You will have the option to enable it in the account that you are currently in, or if you are using a GuardDuty delegated administrator account (as shown in Figure 1), you can enable it for all accounts in your AWS Organizations organization. You’ll also have the ability to auto-enable. The auto-enable feature helps ensure that RDS Protection is enabled for each new account added to your organization, without the need for you to configure anything in each member account. If you are turning on GuardDuty for the first time, RDS Protection is enabled by default.
After GuardDuty generates a finding, you will need to analyze the finding so that you understand the potential impact to your environment. We recommend that you familiarize yourself with the GuardDuty finding types. Understanding GuardDuty finding types can help you understand the types of activity that GuardDuty is looking for and help you prepare for how to respond if they occur in your environment.
As adversaries become more sophisticated, it becomes even more important for you to align to a common framework to understand the tactics, techniques, and procedures (TTPs) behind an individual event. GuardDuty aligns findings using the MITRE ATT&CK framework, which is a globally-accessible knowledge base of adversary tactics and techniques based on real-world observations. GuardDuty findings have a specific finding format that helps you understand the details of each finding. You can examine the Threat Purpose section of the GuardDuty finding types to see finding types associated with various MITRE ATT&CK tactics, including CredentialAccess and Discovery. This can help you identify and understand the type of activity associated with a finding.
For example, consider two finding types that seem similar: CredentialAccess:RDS/MaliciousIPCaller.SuccessfulLoginand Discovery:RDS/MaliciousIPCaller. The difference between them is the ThreatPurpose aspect, located at the beginning of the finding type. GuardDuty has determined that both are involved with MaliciousIPCaller, and the difference is the intent of the activity associated with each finding. CredentialAccess SuccessfulLogin indicates that there was a successful login to your RDS database from a known malicious IP address. Discovery indicates that a threat actor opened a connection to the database, but didn’t attempt to authenticate. This indicates scanning behavior, but it might not be targeted at RDS instances. For more information, see GuardDuty RDS Protection finding types.
GuardDuty uses threat intelligence and machine learning to continually monitor and identify potential threats in your environment. To understand how to investigate RDS Protection finding types, you need to understand the details of a finding type that are derived from machine learning. As shown in Figure 2, RDS Protection finding types have two sections: one that shows the unusual behavior and one that shows the normal, historical behavior. To determine this, GuardDuty uses machine learning models to evaluate API requests to your account and identify anomalous events that are associated with tactics used by adversaries. The machine learning model tracks various factors of the API request, such as the user that made the request, the location the request was made from, and the specific API that was requested. It also looks at information such as successfulLoginCount, failedLoginCount, and incompleteConnectionCount for anomalies based on login activity. For more information about anomalous activity in GuardDuty findings, see Anomalous behavior.
With RDS Protection, you now have an additional mechanism to gain insight into your Amazon RDS databases across your accounts to continuously monitor for suspicious activity. RDS Protection can alert you to suspicious activity in Amazon RDS, such as a potentially suspicious or anomalous login attempt, unusual pattern in a series of successful, failed, or incomplete login attempts, and unauthorized access to your database instance from a previously unseen internal or external actor. With this new feature, GuardDuty also extends support for finding types that you might already be familiar with that also apply to RDS databases. These finding types include calls to an RDS database API from a Tor node, or calls to an RDS database from a known malicious IP address, which can indicate that there are interactions with your RDS database from sources that are associated with known malicious activity.
Remediate RDS Protection findings
In this section, we describe two RDS Protection findings and how you can investigate and remediate them. Understanding how to remediate these findings can help you maintain the integrity of your database. We share recommendations that focus specifically on security groups, network access control lists (network ACLs), and firewall rules.
The CredentialAccess:RDS/AnomalousBehavior.SuccessfulLogin finding informs you that an anomalous successful login was observed on an RDS database in your AWS environment. It might indicate that a previous unseen user logged in to an RDS database for the first time. A common scenario involves an internal user logging in to a database that is accessed programmatically by applications and not by individual users. A potential malicious actor might have compromised and accessed the role on your RDS database. The default Severity for this finding varies, depending on the anomalous behavior associated with the finding.
Figure 3 shows an example of this finding.
Figure 3: Finding of an anomalous behavior successful login
How to remediate
If the activity is unexpected for the associated database, AWS recommends that you change the password of the associated database user, and review available audit logs for activity that the user performed. Medium and high severity findings might indicate an overly permissive access policy to the database, and user credentials might have been exposed or compromised. We recommend that you place the database in a private virtual private cloud (VPC), and limit the security group rules to allow traffic only from necessary sources. For more information, see Remediating potentially compromised database with successful login events.
We recommend that you take the following steps to remediate this finding:
Remediation step 1: Identify the affected database and user
Identify the affected database and user and confirm whether the behavior is expected or unexpected by looking through the GuardDuty finding details, which provide the name of the affected database instance and the corresponding user details. Use the findings to confirm if the behavior is expected or not—for example, the findings might help you identify a user who logs in to their database instance after a long time has passed; a user who logs in to their database instance only occasionally, such as a financial analyst who logs in each quarter; or a suspicious actor who is involved in a successful login attempt that isn’t authorized and potentially compromises the database instance. Review the IP address of the finding. Public IP addresses might signify overly permissive access if it’s not a known network associated with your account.
Figure 4: Finding with details showing Amazon RDS database instance and user details
If the behavior is unexpected, complete the following steps:
Restrict database instance access for the suspected accounts and the source of the login activity. For more information, see Remediating potentially compromised credentials and Restrict network access. You can identify the user in the RDS DB user details section within the finding panel in the console, or within the resource.rdsDbUserDetails of the findings JSON. These user details include user name, application used, database accessed, SSL version, and authentication method.
The following CLI command is an example of how to revoke access to a user in a MySQL database. If the behavior is unexpected, you can revoke the privileges while you assess if the user is malicious.
REVOKE CONNECTION_ADMIN ON *.* FROM 'fakeadmin'@'%';
You can revoke privileges from the user, but when taking this action, you should make sure that the user isn’t vital to your system and that revoking permissions won’t break your production or development application. The following CLI command is an example of how to revoke privileges from a user:
REVOKE ALL PRIVILEGES ON *.* FROM 'fakeadmin'@'%';
If you know that the user isn’t necessary for your database or application to function, then you can remove the user from the system. To make sure that your security team can run forensics, check your company’s incident response policy. If you need help getting started with incident response, see AWS sample incident response playbooks. The following CLI command is an example of how to remove a user:
DROP USER 'fakeadmin'@'%';
Let’s say that you find the behavior unexpected, but the user turns out to be the application user, and making a change to the database credential will break your application. You can use AWS Systems Manager to help in this scenario, in which the affected RDS user is the account that is tied to your application. In many cases, a password rotation can break your application, depending on how you connect. If you rotate the password without notifying your application, the application might require additional cascading changes. You could lose connectivity to your application because the credentials that your application is using to connect to your database didn’t change, and now you are experiencing an outage that will remain until you update the credentials. Systems Manager can tie into your application code to automatically update the rotated database credentials in your application. For more information, see Rotate Amazon RDS database credentials automatically with AWS Secrets Manager.
The following figure shows a CLI command to get a secret from Secrets Manager — for this example, we assume the secret is compromised.
Figure 5: Example compromised credentials
The following figures shows that we have a new set of credentials that replace our old credentials, as indicated by “CreatedDate”.
Figure 6: Example remediated credentials
Remediation step 3: Assess the impact and determine what information was accessed
To learn how to restrict IP access on a security group, see Control traffic to resources using security groups. You can identify the user in the RDS DB user details section within the finding panel in the console, or within the resource.rdsDbUserDetails of the findings JSON. These user details include user name, application used, database accessed, SSL version, and authentication method.
Remediation step 5: Perform root-cause analysis and determine the steps that potentially led to this activity
Implementing a lessons-learned framework and methodology can help improve your incident response capabilities and also help prevent the incident from recurring. By learning from each incident, you can help avoid repeating the same mistakes, exposures, or misconfigurations, which can both improve your security posture and reduce the time lost to preventable situations. To learn more about post-incident activity, see AWS Security Incident Response Guide.
The CredentialAccess:RDS/AnomalousBehavior.successfulBruteForce finding informs you that an anomalous login occurred that is indicative of a successful brute force event, as observed on an RDS database in your AWS environment. Before the anomalous successful login, a consistent pattern of unusual failed login attempts was observed. This indicates that the user and password associated with the RDS database in your account might have been compromised, and a potentially malicious actor might have accessed the RDS database. The Severity of this finding is high. Figure 7 shows an example of this finding.
Figure 7: Example of an anomalous successful brute force finding
How to remediate
This activity indicates that database credentials might have been exposed or compromised. We recommend that you change the password of the associated database user, and review available audit logs for activity performed by the potentially compromised user. A consistent pattern of unusual failed login attempts indicates an overly permissive access policy to the database, or that the database might also have been publicly exposed. AWS recommends that you place the database in a private VPC, and limit the security group rules to allow traffic only from necessary sources. For more information, see Remediating potentially compromised database with successful login events.
We recommend that you take the following steps to remediate this finding
Remediation step 1: Identify the affected database and user
The generated GuardDuty finding provides the name of the affected database instance and the corresponding user details. For more information, see Finding details.
Figure 8: Finding details showing Amazon RDS database instance and user details
Remediation step 2: Identify the source of the failed login attempts
In the generated GuardDuty finding, you can find the IP address, and if it was a public connection, the ASN organization in the Actor section of the finding panel. An autonomous system is a group of one or more IP prefixes (lists of IP addresses accessible on a network) run by one or more network operators that maintain a single, clearly-defined routing policy. Network operators need autonomous system numbers (ASNs) to control routing within their networks and to exchange routing information with other internet service providers.
Figure 9: Action and actor details related to GuardDuty brute force finding
Remediation step 3: Confirm that the behavior is unexpected
Examine if this activity represents an attempt to gain additional unauthorized access to the database instance as follows:
If the source is internal to your network, examine if an application is misconfigured and attempting a connection repeatedly.
If this is an external actor, examine whether the corresponding database instance is public facing or is misconfigured and thus allowing potential malicious actors to attempt to log in with common user names.
If the behavior is unexpected, complete the following steps:
As discussed previously for the CredentialAccess:RDS/AnomalousBehavior.SuccessfulLogin finding, you can restrict access to the database through credentials or network access:
Remediation step 5: Perform root-cause analysis and determine the steps that potentially led to this activity
By learning from each incident, you can help avoid repeating the same mistakes, exposures, or misconfigurations, which can both improve your security posture and reduce time lost to preventable situations.
Conclusion
In this post, you learned about the new GuardDuty RDS Protection feature and how to understand, operationalize, and respond to the new findings. You can enable this feature through the GuardDuty console, CLI, or APIs to start monitoring your Amazon RDS workloads today.
If you’ve created EventBridge rules to send findings from GuardDuty to a target, make sure that you’ve configured your rules to deliver the newly added findings. After you enable GuardDuty findings, consider creating IR playbooks, doing tabletops and AWS gamedays, and mapping out what you want to automate. For more information, see the AWS Security Incident Response Guide and AWS Incident Response Playbook resources. To gain hands-on experience with different AWS Security services, see AWS Activation Days. The Activation Days workshops begin with hands-on work with different services in sandbox accounts, and then take you through the steps to deploy them across your organization.
To make it more efficient for you to operate securely on AWS, we are committed to continually improving GuardDuty, and we value your feedback. If you have feedback about this post, submit comments in the Comments section below. If you have questions about this post, start a new thread on AWS re:Post or contact AWS Support.
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Amazon RDS now offers integration with Secrets Manager to manage master database credentials. You no longer have to manage master database credentials, such as creating a secret in Secrets Manager or setting up rotation, because Amazon RDS does it for you.
In this blog post, you will learn how to set up an Amazon RDS database instance and use the Secrets Manager integration to manage master database credentials. You will also learn how to set up alternating users rotation for application credentials.
Benefits of the integration
Managing Amazon RDS master database credentials with Secrets Manager provides the following benefits:
Amazon RDS automatically generates and helps secure master database credentials, so that you don’t have to do the heavy lifting of securely managing credentials.
Amazon RDS automatically stores and manages database credentials in Secrets Manager.
Amazon RDS rotates database credentials regularly without requiring application changes.
Secrets Manager helps to secure database credentials from human access and plaintext view.
Secrets Manager allows retrieval of database credentials using its API or the console.
In this blog post, we’ll show you how to use the console to do the following:
Manage master database credentials for new Amazon RDS instances in Secrets Manager. We will use the MySQL engine, but you can also use this process for other Amazon RDS database engines.
Use the managed master database secret to set up alternating users rotation for a new database user.
Manage Amazon RDS master database credentials in Secrets Manager
In this section, you will create a database instance with Secrets Manager integration.
To manage Amazon RDS master database credentials in Secrets Manager:
For Choose a database creation method, choose Standard create.
In Engine options, for Engine type, choose MySQL.
In Settings, under Credentials Settings, select Manage master credentials in AWS Secrets Manager.
Figure 1: Select Secrets Manager integration
You will have the option to encrypt the managed master database credentials. In this example, we will use the default KMS key.
Figure 2: Choose KMS key
(Optional) Choose other settings to meet your requirements. For more information, see Settings for DB instances.
Choose Create Database, and wait a few minutes for the database to be created.
After the database is created, from the Instances dashboard in the Amazon RDS console, navigate to your new Amazon RDS instance.
Choose the Configuration tab, and under Master Credentials ARN, you will find the secret that contains your master database credentials.
Create a new database user by using the master database credentials
In this section you will learn how to create and secure a credential that could be used in your application to connect to the database. You will learn how to access the master database credentials and use the master database credentials to create and set up rotation on child (application) credentials.
To create a new database user by using the master database credentials
Retrieve the master database credentials from Secrets Manager as follows:
Choose the Configuration tab of your RDS instance dashboard, and under Master Credentials ARN, choose Manage in Secrets Manager to open your managed master database secret in Secrets Manager.
Figure 3: View DB configuration
You can see that Amazon RDS has added some system tags to the secret and that rotation is turned on by default.
Figure 4: View secret details
To see the password, in the Secret value section, choose Retrieve secret value.
For the master database, create a new database user with the permissions that you want by running the following SQL command. Make sure to replace <password> with your own information, and make sure to use a strong password.
For Secret type, select Credentials for Amazon RDS database.
In the Credentials section, enter the username and password of the new database user.
In the Database section, select your Amazon RDS instance, and then choose Next, as shown in Figure 5.
Figure 5: Select the RDS instance
On the Configure secret page, give the secret a name and description. No other configuration is needed.
On the Configure rotation – optional page, turn on Automatic rotation.
Figure 6: Select automatic rotation
In the Rotation schedule section, configure the rotation schedule according to your needs.
In the Rotation function section, do the following:
Enter a descriptive name for the Lambda function that will be created.
For Use separate credentials to rotate this secret, select Yes.
For Secrets, choose the master database secret that was created by Amazon RDS.
Note: To find the name of your master database secret, in the Amazon RDS console, on your Amazon RDS instance details page, choose the Configuration tab and then see the Master Credentials ARN.
Figure 7: Select separate credentials for rotation
Choose Next, and then on the Review page, choose Store.
It will take a few minutes for the Secrets Manager workflow to set up the rotation Lambda function before the new database user secret is ready to be rotated.
To check that rotation is enabled
In the Secrets Manager console, navigate to the new database user secret.
Figure 8: View the child secret
In the Rotation configuration section, verify that Rotation status is Enabled.
In the Rotation configuration section, choose the Lambda rotation function.
Figure 12: View the rotation function
In the Lambda console, under Application, select the application.
Figure 13: Open application
On the Deployments tab, choose CloudFormation stack.
Choose Delete and then follow the Delete menu steps. You might need to navigate to the root stack and choose Delete again. You might also need to disable termination protection for the stack. The console will guide you through that.
Figure 14: Choose delete
Now that you have cleaned up rotation for the new database user secret, you need to delete the child secret. Navigate to the Secrets Manager console and select the secret that you want to delete.
In the Actions dropdown, select Delete secret to delete the secret.
Figure 15: Delete child secret
Summary
Amazon RDS integration with Secrets Manager helps you better secure and manage master DB credentials. This integration helps you store the credentials when the DB instances are created and eliminates the effort for you to set up credential rotation.
In this blog post, you learned how to do the following:
Set up an Amazon RDS instance that uses Secrets Manager to store the master database credentials
View the credentials in Secrets Manager and confirm that rotation is set up
Use the master database credentials to create database user credentials
Set up alternating users rotation on database user credentials
Additional resources
For instructions on how to create database users for other Amazon RDS engine types, see the following resources:
If you are looking for a new year challenge, the Serverless Developer Advocate team launched the 30 days of Serverless. You can follow the hashtag #30DaysServerless on LinkedIn, Twitter, or Instagram or visit the challenge page and learn a new Serverless concept every day.
Last Week’s Launches Here are some launches that got my attention during the previous week.
List the URLs of the Amazon API Gateway or AWS Lambda function URL. $ sam list endpoints
List the outputs of the deployed stack. $ sam list outputs
List the resources in the local stack. If a stack name is provided, it also shows the corresponding deployed resources and the ids. $ sam list resources
Amazon RDS – Now supports increasing the allocated storage size when creating read replicas or when restoring a database from snapshots. This is very useful when your primary instances are near their maximum allocated storage capacity.
Amazon QuickSight – Allows you to create Radar charts. Radar charts are a way to visualize multivariable data that are used to plot one or more groups of values over multiple common variables.
AWS Systems Manager Automation – Now integrates with Systems Manager Change Calendar. Now you can reduce the risks associated with changes in your production environment by allowing Automation runbooks to run during an allowed time window configured in the Change Calendar.
Other AWS News Some other updates and news that you may have missed:
AWS Cloud Clubs – Cloud Clubs are peer-to-peer user groups for students and young people aged 18–28. In these clubs, you can network, attend career-building events, earn benefits like AWS credits, and more. Learn more about the clubs in your region in the AWS student portal.
Get AWS Certified: Profesional challenge – You can register now for the certification challenge. Prepare for your AWS Professional Certification exam and get a 50 percent discount for the certification exam. Learn more about the challenge on the official page.
Podcast Charlas Técnicas de AWS – If you understand Spanish, this podcast is for you. Podcast Charlas Técnicas is one of the official AWS podcasts in Spanish, and every other week, there is a new episode. The podcast is for builders, and it shares stories about how customers implemented and learned AWS services, how to architect applications, and how to use new services. You can listen to all the episodes directly from your favorite podcast app or at AWS Podcasts en Español.
AWS Open-Source News and Updates – This is a newsletter curated by my colleague Ricardo to bring you the latest open-source projects, posts, events, and more.
Upcoming AWS Events Check your calendars and sign up for these AWS events:
AWS re:Invent recaps – We had a lot of announcements during re:Invent. If you want to learn them all in your language and in your area, check the re: Invent recaps. All the upcoming ones are posted on this site, so check it regularly to find an event nearby.
AWS Innovate Data and AI/ML edition – AWS Innovate is a free online event to learn the latest from AWS experts and get step-by-step guidance on using AI/ML to drive fast, efficient, and measurable results.
AWS Innovate Data and AI/ML edition for Asia Pacific and Japan is taking place on February 22, 2023. Register here.
Registrations for AWS Innovate EMEA (March 9, 2023) and the Americas (March 14, 2023) will open soon. Check the AWS Innovate page for updates.
This blog is written by Mark Rogers, SDE II – Customer Engineering AWS.
In part 1, I showed you how to run Apache CloudStack with KVM on a single Amazon Elastic Compute Cloud (Amazon EC2) instance. That simple setup is great for experimentation and light workloads. In this post, things will get a lot more interesting. I’ll show you how to create an overlay network in your Amazon Virtual Private Cloud (Amazon VPC) that allows CloudStack to scale horizontally across multiple EC2 instances. This same method could work with other hypervisors, too.
If you haven’t read it yet, then start with part 1. It explains why this network setup is necessary. The same prerequisites apply to both posts.
Making things easier
I wrote some scripts to automate the CloudStack installation and OS configuration on CentOS 7. You can customize them to meet your needs. I also wrote some AWS CloudFormation templates you can copy in order to create a demo environment. The README file has more details.
The scalable method
Our team started out using a single EC2 instance, as described in my last post. That worked at first, but it didn’t have the capacity we needed. We were limited to a couple of dozen VMs, but we needed hundreds. We also needed to scale up and down as our needs changed. This meant we needed the ability to add and remove CloudStack hosts. Using a Linux bridge as a virtual subnet was no longer adequate.
To support adding hosts, we need a subnet that spans multiple instances. The solution I found is Virtual Extensible LAN (VXLAN). It’s lightweight, easy to configure, and included in the Linux kernel. VXLAN creates a layer 2 overlay network that abstracts away the details of the underlying network. It allows machines in different parts of a network to communicate as if they’re all attached to the same simple network switch.
Another example of an overlay network is an Amazon VPC. It acts like a physical network, but it’s actually a layer on top of other networks. It’s networks all the way down. VXLAN provides a top layer where CloudStack can sit comfortably, handling all of your VM needs, blissfully unaware of the world below it.
An overlay network comes with some big advantages. The biggest improvement is that you can have multiple hosts, allowing for horizontal scaling. Having more hosts not only gives you more computing power, but also lets you do rolling maintenance. Instead of putting the database and file storage on the management server, I’ll show you how to use Amazon Elastic File System (Amazon EFS) and Amazon Relational Database Service (Amazon RDS) for scalable and reliable storage.
EC2 Instances
Let’s start with three Amazon EC2 instances. One will be a router between the overlay network and your Amazon VPC, the second one will be your CloudStack management server, and the third one will be your VM host. You’ll also need a way to connect to your instances, such as a bastion host or a VPN endpoint.
The router won’t need much computing power, but it will need enough network bandwidth to meet your needs. If you put Amazon EFS in the same subnet as your instances, then they’ll communicate with it directly, thereby reducing the load on the router. Decide how much network throughput you want, and then pick a suitable Nitro instance type.
After creating the router instance, configure AWS to use it as a router. Stop source/destination checking in the instance’s network settings. Then update the applicable AWS route tables to use the router as the target for the overlay network. The router’s security group needs to allow ingress to the CloudStack UI (TCP port 8080) and any services you plan to offer from VMs.
For the management server, you’ll want a Nitro instance type. It’s going to use more CPU than your router, so plan accordingly.
In addition to being a Nitro type, the host instance must also be a metal type. Metal instances have hardware virtualization support, which is needed by KVM. If you have a new AWS account with a low on-demand vCPU limit, then consider starting with an m5zn.metal, which has 48 vCPUs. Otherwise, I suggest going directly to a c5.metal because it provides 96 vCPUs for a similar price. There are bigger types available depending on your compute needs, budget, and vCPU limit. If your account’s on-demand vCPU limit is too low, then you can file a support ticket to have it raised.
Networking
All of the instances should be on a dedicated subnet. Sharing the subnet with other instances can cause communication issues. For an example, refer to the following figure. The subnet has an instance named TroubleMaker that’s not on the overlay network. If TroubleMaker sends a request to the management instance’s overlay network address, then here’s what happens:
The request goes through the AWS subnet to the router.
The router forwards the request via the overlay network.
The CloudStack management instance has a connection to the same AWS subnet that TroubleMaker is on. Therefore, it responds directly instead of using the router. This isn’t the return path that AWS is expecting, so the response is dropped.
If you move TroubleMaker to a different subnet, then the requests and responses will all go through the router. That will fix the communication issues.
The instances in the overlay network will use special interfaces that serve as VXLAN tunnel endpoints (VTEPs). The VTEPs must know how to contact each other via the underlay network. You could manually give each instance a list of all of the other instances, but that’s a maintenance nightmare. It’s better to let the VTEPs discover each other, which they can do using multicast. You can add multicast support using AWS Transit Gateway.
Here are the steps to make VXLAN multicasts work:
Enable multicast support when you create the transit gateway.
Attach the transit gateway to your subnet.
Create a transit gateway multicast domain with IGMPv2 support enabled.
Associate the multicast domain with your subnet.
Configure the eth0 interface on each instance to use IGMPv2. The following sample code shows how to do this.
Make sure that your instance security groups allow ingress for IGMP queries (protocol 2 traffic from 0.0.0.0/32) and VXLAN traffic (UDP port 4789 from the other instances).
CloudStack VMs must connect to the same bridge as the VXLAN interface. As mentioned in the previous post, CloudStack cares about names. I recommend giving the interface a name starting with “eth”. Moreover, this naming convention tells CloudStack which bridge to use, thereby avoiding the need for a dummy interface like the one in the simple setup.
The following snippet shows how I configured the networking in CentOS 7. You must provide values for these variables:
$overlay_host_ip_address, $overlay_netmask, and $overlay_gateway_ip: Use values for the overlay network that you’re creating.
$multicast_address: The multicast address that you want VXLAN to use. Pick something in the multicast range that won’t conflict with anything else. I recommend choosing from the IPv4 local scope (239.255.0.0/16).
$interface_name: The name of the interface VXLAN should use to communicate with the physical network. This is typically eth0.
A couple of the steps are different for the router instance than for the other instances. Pay attention to the comments!
yum install -y bridge-utils net-tools
# IMPORTANT: Omit the GATEWAY setting on the router instance!
cat << EOF > /etc/sysconfig/network-scripts/ifcfg-cloudbr0
DEVICE=cloudbr0
TYPE=Bridge
ONBOOT=yes
BOOTPROTO=none
IPV6INIT=no
IPV6_AUTOCONF=no
DELAY=5
STP=no
USERCTL=no
NM_CONTROLLED=no
IPADDR=$overlay_host_ip_address
NETMASK=$overlay_netmask
DNS1=$dns_address
GATEWAY=$overlay_gateway_ip
EOF
cat << EOF > /sbin/ifup-local
#!/bin/bash
# Set up VXLAN once cloudbr0 is available.
if [[ \$1 == "cloudbr0" ]]
then
ip link add ethvxlan0 type vxlan id 100 dstport 4789 group "$multicast_address" dev "$interface_name"
brctl addif cloudbr0 ethvxlan0
ip link set up dev ethvxlan0
fi
EOF
chmod +x /sbin/ifup-local
# Transit Gateway requires IGMP version 2
echo "net.ipv4.conf.$interface_name.force_igmp_version=2" >> /etc/sysctl.conf
sysctl -p
# Enable IPv4 forwarding
# IMPORTANT: Only do this on the router instance!
echo 'net.ipv4.ip_forward=1' >> /etc/sysctl.conf
sysctl -p
# Restart the network service to make the changes take effect.
systemctl restart network
Storage
Let’s look at storage. Create an Amazon RDS database using the MySQL 8.0 engine, and set a master password for CloudStack’s database setup tool to use. Refer to the CloudStack documentation to find the MySQL settings that you’ll need. You can put the settings in an RDS parameter group. In case you’re wondering why I’m not using Amazon Aurora, it’s because CloudStack needs the MyISAM storage engine, which isn’t available in Aurora.
I recommend Amazon EFS for file storage. For efficiency, create a mount target in the subnet with your EC2 instances. That will enable them to communicate directly with the mount target, thereby bypassing the overlay network and router. Note that the system VMs will use Amazon EFS via the router.
If you want, you can consolidate your CloudStack file systems. Just create a single file system with directories for each zone and type of storage. For example, I use directories named /zone1/primary, /zone1/secondary, /zone2/primary, etc. You should also consider enabling provisioned throughput on the file system, or you may run out of bursting credits after booting a few VMs.
One consequence of the file system’s scalability is that the amount of free space (8 exabytes) will cause an integer overflow in CloudStack! To avoid this problem, reduce storage.overprovisioning.factor in CloudStack’s global settings from 2 to 1.
When your environment is ready, install CloudStack. When it asks for a default gateway, remember to use the router’s overlay network address. When you add a host, make sure that you use the host’s overlay network IP address.
The security groups that you created for the instances, database, and file system
Conclusion
The approach I shared has many steps, but they’re not bad when you have a plan. Whether you need a simple setup for experiments, or you need a scalable environment for a data center migration, you now have a path forward. Give it a try, and comment here about the things you learned. I hope you find it useful and fun!
“Apache”, “Apache CloudStack”, and “CloudStack” are trademarks of the Apache Software Foundation.
This blog is written by Mark Rogers, SDE II – Customer Engineering AWS.
How do you put a cloud inside another cloud? Some features that make Amazon Elastic Compute Cloud (Amazon EC2) secure and wonderful also make running CloudStack difficult. The biggest obstacle is that AWS and CloudStack both want to manage network resources. Therefore, we must keep them out of each other’s way. This requires some steps that aren’t obvious, and it took a long time to figure out. I’m going to share what I learned, so that you can navigate the process more easily.
Apache CloudStack is an open-source platform for deploying and managing virtual machines (VMs) and the associated network and storage infrastructure. You would normally run it on your own hardware to create your own cloud. But there can be advantages to running it inside of an Amazon Virtual Private Cloud (Amazon VPC), including how it could help you migrate out of a data center. It’s a great way to create disposable environments for experiments or training. Furthermore, it’s a convenient way to test-drive the new CloudStack support in Amazon Elastic Kubernetes Service (Amazon EKS) Anywhere. In my case, I needed to create development and test environments for a project that uses the CloudStack API. The environments needed to be shared and scalable. Our build pipelines were already in AWS, so it made sense to put the new environments there, too.
CloudStack can work with a number of hypervisors. The instructions in this article will use Kernel-based Virtual Machine (KVM) on Linux. KVM will manage the VMs at a low level, and CloudStack will manage KVM.
Prerequisites
Most of the information in this article should be applicable to a range of CloudStack versions. I targeted CloudStack 4.14 on CentOS 7. I also tested CloudStack versions 4.16 and 4.17, and I recommend them.
The official CentOS 7 x86_64 HVM image works well. If you use a different Linux flavor or version, then you might have to modify some of the implementation details.
You’ll need to know the basics of CloudStack. The scope of this article is making CloudStack and AWS coexist peacefully. Once CloudStack is running, I’m assuming that you’ll handle things from there. Refer to the AWS documentation and CloudStack documentation for information on security and other best practices.
Making things easier
I wrote some scripts to automate the installation. You can run them on EC2 instances with CentOS 7, and they’ll do all the installation and OS configuration for you. You can use them as they are, or customize them to meet your needs. I also wrote some AWS CloudFormation templates you can copy in order to create a demo environment. The README file has more details.
I like c5.metal because it’s one of the least expensive metal types, and has a low cost per vCPU. It has 96 vCPUs and 192 GiB of memory. If you run 20 VMs on it, with 4 CPU cores and 8 GiB of memory each, then you’d still have 16 vCPUs and 32 GiB to share between the operating system, CloudStack, and MySQL. Using CloudStack’s overprovisioning feature, you could fit even more VMs if they’re running light loads.
Networking
The biggest challenge is the network. AWS knows which IP and MAC addresses should exist, and it knows the machines to which they should belong. It blocks any traffic that doesn’t fit its idea of how the network should behave. Simultaneously, CloudStack assumes that any IP or MAC address it invents should work just fine. When CloudStack assigns addresses to VMs on an AWS subnet, their network traffic gets blocked.
You could get around this by enabling network address translation (NAT) on the instance running CloudStack. That’s a great solution if it fits your needs, but it makes it hard for other machines in your Amazon VPC to contact your VMs. I recommend a different approach.
Although AWS restricts what you can do with its layer 2 network, it’s perfectly happy to let you run your own layer 3 router. Your EC2 instance can act as a router to a new virtual subnet that’s outside of the jurisdiction of AWS. The instance integrates with AWS just like a VPN appliance, routing traffic to wherever it needs to go. CloudStack can do whatever it wants in the virtual subnet, and everybody’s happy.
What do I mean by a virtual subnet? This is a subnet that exists only inside the EC2 instance. It consists of logical network interfaces attached to a Linux bridge. The entire subnet exists inside a single EC2 instance. It doesn’t scale well, but it’s simple. In my next post, I’ll cover a more complicated setup with an overlay network that spans multiple instances to allow horizontal scaling.
The simple way
The simple way is to put everything in one EC2 instance, including the database, file storage, and a virtual subnet. Because everything’s stored locally, allocate enough disk space for your needs. 500 GB will be enough to support a few basic VMs. Create or select a security group for your instance that gives users access to the CloudStack UI (TCP port 8080). The security group should also allow access to any services that you’ll offer from your VMs.
When you have your instance, configure AWS to treat it as a router.
a. Go to the VPC settings, and select Route Tables.
b. Identify the tables for subnets that need CloudStack access.
c. In each of these tables, add a route to the new virtual subnet. The route target should be your EC2 instance.
4. Depending on your network needs, you may also need to add routes to transit gateways, VPN endpoints, etc.
Because everything will be on one server, creating a virtual subnet is simply a matter of creating a Linux bridge. CloudStack must find a network adapter attached to the bridge. Therefore, add a dummy interface with a name that CloudStack will recognize.
The following snippet shows how I configure networking in CentOS 7. You must provide values for the variables $virutal_host_ip_address and $virtual_netmask to reflect the virtual subnet that you want to create. For $dns_address, I recommend the base of the VPC IPv4 network range, plus two. You shouldn’t use 169.654.169.253 because CloudStack reserves link-local addresses for its own use.
yum install -y bridge-utils net-tools
# The bridge must be named cloudbr0.
cat << EOF > /etc/sysconfig/network-scripts/ifcfg-cloudbr0
DEVICE=cloudbr0
TYPE=Bridge
ONBOOT=yes
BOOTPROTO=none
IPV6INIT=no
IPV6_AUTOCONF=no
DELAY=5
STP=yes
USERCTL=no
NM_CONTROLLED=no
IPADDR=$virtual_host_ip_address
NETMASK=$virtual_netmask
DNS1=$dns_address
EOF
# Create a dummy network interface.
cat << EOF > /etc/sysconfig/modules/dummy.modules
#!/bin/sh
/sbin/modprobe dummy numdummies=1
/sbin/ip link set name ethdummy0 dev dummy0
EOF
chmod +x /etc/sysconfig/modules/dummy.modules
/etc/sysconfig/modules/dummy.modules
cat << EOF > /etc/sysconfig/network-scripts/ifcfg-ethdummy0
TYPE=Ethernet
BOOTPROTO=none
NAME=ethdummy0
DEVICE=ethdummy0
ONBOOT=yes
BRIDGE=cloudbr0
NM_CONTROLLED=no
EOF
# Turn the instance into a router
echo 'net.ipv4.ip_forward=1' >> /etc/sysctl.conf
sysctl -p
# Must kill dhclient or the network service won't restart properly.
# A reboot would also work, if you’d rather do that.
pkill dhclient
systemctl restart network
CloudStack must know which IP addresses to use for inter-service communication. It will select by resolving the machine’s fully qualified domain name (FQDN) to an address. The following commands will make it to choose the right one. You must provide a value for $virtual_host_ip_address.
Remember that CloudStack is only directly connected to your virtual network. The EC2 instance is the router that connects the virtual subnet to the Amazon VPC. When you’re configuring CloudStack, use your instance’s virtual subnet address as the default gateway.
To access CloudStack from your workstation, you’ll need a connection to your VPC. This can be through a client VPN or a bastion host. If you use a bastion, its subnet needs a route to your virtual subnet, and you’ll need an SSH tunnel for your browser to access the CloudStack UI. The UI is at http://x.x.x.x:8080/client/, where x.x.x.x is your CloudStack instance’s virtual subnet address. Note that CloudStack’s console viewer won’t work if you’re using an SSH tunnel.
If you’re just experimenting with CloudStack, then I suggest saving money by stopping your instance when it isn’t needed. The safe way to do that is:
Disable your zone in the CloudStack UI.
Put the primary storage into maintenance mode.
Wait for the switch to maintenance mode to be complete.
Stop the EC2 instance.
When you’re ready to turn everything back on, simply reverse those steps. If you have any virtual routers in CloudStack, then you may need to start those, too.
Getting CloudStack to run on AWS isn’t so bad. The hardest part is simply knowing how. The setup explained here is great for small installations, but it can only scale vertically. In my next post, I’ll show you how to create an installation that scales horizontally. Instead of using a virtual subnet that exists in a single EC2 instance, we’ll build an overlay network that spans multiple instances. It will use more components and features, including some that might be new to you. I hope you find it interesting!
Now that you can create a simple setup, give it a try! I hope you have fun and learn something new along the way. Comment with the results of your experiments.
“Apache”, “Apache CloudStack”, and “CloudStack” are trademarks of the Apache Software Foundation.
We are half way between the re:Invent conference and the end-of-year holidays, and I did expect the cadence of releases and news to slow down a bit, but nothing is further away from reality. Our teams continue to listen to your feedback and release new capabilities and incremental improvements.
This week, many items caught my attention. Here is my summary.
The AWS Pricing Calculator for Amazon EC2 is getting a redesign to provide you with a simplified, consistent, and efficient calculator to estimate costs. It also added a way to bulk estimate costs for EC2 instances, EC2 Dedicated Hosts, and Amazon EBS services. Try it for yourself today.
Amazon CloudWatch Metrics Insights alarms now enables you to trigger alarms on entire fleets of dynamically changing resources (such as automatically scaling EC2 instances) with a single alarm using standard SQL queries. For example, you can now write a query like this to collect data about CPU utilization over your entire dynamic fleet of EC2 instances.
SELECT AVG(CPUUtilization) FROM SCHEMA("AWS/EC2", InstanceId)
AWS Amplify is a command line tool and a set of libraries to help you to build web and mobile applications connected to a cloud backend. We released Amplify Library for Android 2.0, with improvements and simplifications for user authentication. The team also released Amplify JavaScript library version 5, with improvements for React and React Native developers, such as a new notifications channel, also known as in-app messaging, that developers can use to display contextual messages to their users based on their behavior. The Amplify JavaScript library has also received improvements to reduce the overall bundle size and installation size.
Amazon RDS Proxynow supports PostgreSQL major version 14. RDS Proxy is a fully managed, highly available database proxy for Amazon Relational Database Service (Amazon RDS) that makes applications more scalable, more resilient to database failures, and more secure. It is typically used by serverless applications that can have a large number of open connections to the database server and may open and close database connections at a high rate, exhausting database memory and compute resources.
AWS Gateway Load Balancer endpoints now support Ipv6 addresses. You can now send IPv6 traffic through Gateway Load Balancers and its endpoints to distribute traffic flows to dual stack appliance targets.
Amazon Location Service now provides Open Data Maps maps, in addition to ESRI and Here maps. I also noticed that Amazon is a core member of the new Overture Maps Foundation, officially hosted by the Linux Foundation. The mission of the Overture Maps Foundation is to power new map products through openly available datasets that can be used and reused across applications and businesses. The program is driven by Amazon Web Services (AWS), Facebook’s parent company Meta, Microsoft, and Dutch mapping company TomTom.
X in Y. Jeff started this section a while ago to list the expansion of new services and capabilities to additional Regions. I noticed 11 Regional expansions this week:
Upcoming AWS Events Check your calendars and sign up for these AWS events:
AWS re:Invent recaps in your area. During the re:Invent week, we had lots of new announcements, and in the next weeks, you can find in your area a recap of all these launches. All the events will be posted on this site, so check it regularly to find an event nearby.
AWS re:Invent keynotes, leadership sessions, and breakout sessions are available on demand. I recommend that you check the playlists and find the talks about your favorite topics in one collection.
Stay Informed That is my selection for this week! Heads up – the Week in Review will be taking a short break for the end of the year, but we’ll be back with regular updates starting on January 9, 2023. To better keep up with all of this news, do not forget to check out the following resources:
The Official AWS Podcast – Listen each week for updates on the latest AWS news and deep dives into exciting use cases. There are also official AWS podcasts in your local languages. Check the ones in French, German, Italian, and Spanish.
Application migrations, especially from legacy/mainframe to the cloud, are done in phases that sometimes span multiple years. Each phase migrates a set of applications, data, and other resources to the cloud. During the transition phases, applications might require access to both on-premises and cloud-based resources to perform their function. While working with our customers, we observed that the most common resources that applications require access to are databases, file storage, and shared services.
This blog post includes architecture guidelines for setting up access to commonly used resources by building a security model in Amazon Web Services (AWS). As you move your legacy applications to the cloud, you can apply Zero Trust concepts and security best practices according to your security needs. With AWS, you can build strong identity and access management with centralized control and set up and manage guardrails and fine-grained access controls for your workforce and applications.
In large organizations, on-premises applications rely on mainframe-based security services, an Identity Provider (IdP) platform, or a combination of both.
A mainframe-based control facility enables on-premises applications to:
Identify and verify users.
Establish an authority (authorize users and backend programs to access protected resources) through privileges defined in the control facility.
The backend programs use a unique identifier (or surrogate key) and run under the authority defined by the privileges assigned to the unique identifier.This security mechanism needs to be transformed into a role-based security model in AWS as applications are moved to the cloud. You assign permissions to a role, which is assumed by an application to get access to resources in AWS, similar to an authority defined in the legacy environment.
An IdP platform (such as Octa or Ping Identify) provides capabilities such as centralized access management and identity federation using SAML 2.0 or OpenID Connect (OIDC), that builds a system of trust between on-premises IdP and AWS. Once the federation is set up, on-premises applications can access AWS resources using AWS Identity and Access Management (IAM) roles, as explained in the next section.
Setting up a scalable security model in AWS
Figure 1 shows an on-premises environment where enterprise identity management is integrated with the mainframe and provides authentication and authorization to applications running off the mainframe. Generally, mainframe-based security controls (users, resources, and profiles) are replicated to the enterprise identity platform and are kept in sync through a change data capture process.
Figure 1. Access to AWS resources from on-premises
To enable your on-premises applications to access AWS resources, the applications need valid AWS credentials for making AWS API requests. Avoid using long-term access keys (such as those associated with IAM users) because they remain valid until you remove them. The following two methods can be used to assume an IAM role and get temporary security credentials to gain access to the AWS resources:
SAML based Identity federation – AWS supports identity federation with SAML. It allows federated access to users and applications in your organization by assuming an IAM role created for SAML federation to get temporary credentials. This method is helpful:
If your application uses a service account to manage AWS resource access, regardless of who is logged in.
IAM Roles Anywhere – Your on-premises applications will exchange X.509 certificates so that they can assume a role and get temporary credentials. This method is helpful if your application needs access to an AWS resource based on a service account.
In both of these cases, authenticated requests assume an IAM role, get temporary security credentials, and perform certain actions using AWS command line interface (CLI) and AWS SDKs. The IAM role has attached permissions for AWS resources such as Amazon Simple Storage Service (Amazon S3), Amazon DynamoDB, and Amazon Relational Database Service (Amazon RDS).
The temporary credentials expire when the session expires. By default, the session duration is one hour; you can request longer duration and session refresh.
To understand better, let’s consider the use case in Figure 2, where on-premises applications need access to AWS resources.
Figure 2. Access to resources that are created or already migrated to AWS from on-premises
Applications can get temporary security credentials through SAML or IAM Roles Anywhere as explained earlier. The next sections explain setting up access to the resources in Figure 2 using temporary credentials.
1. Amazon S3
On-premises applications can access Amazon S3 using the REST API or the AWS SDK to perform certain actions (such as GetObjects or ListObjects):
You can also simplify by creating Amazon S3 access points for your application to perform object-level operations in your S3 bucket. Each access point has distinct permissions and network controls that S3 applies for any request made through it.
2. Amazon RDS and Amazon Aurora
AWS Secrets Manager helps you store credentials for Amazon RDS and Amazon Aurora. You can also set up automatic rotation of your database secrets to meet your security and compliance needs. Applications can retrieve secrets using AWS SDKs and AWS CLI.
Additional configuration values can be stored in AWS Systems Manager Parameter Store, which provides secure, hierarchical storage for configuration data management such as passwords, database strings and license codes as parameter values rather than hard coding them in the code.
To access Amazon RDS and Amazon Aurora:
You can launch Amazon RDS DB instances into a virtual private cloud (VPC). A client application can access DB instance through the internet or through the private network only using an established connection from on-premises to the AWS environment.
On-premises applications can connect to a relational database using a database driver such as Java Database Connectivity (JDBC). The application can retrieve database connection details (such as database URL, port, or credentials) from AWS Secrets Manager and AWS Systems Manager Parameter Store through API calls and can use them for the database connection.
Database admins can access AWS Management Console through an assumed role and can have access to database credentials from AWS Secrets Manager in order to connect directly with the database. For certain administration tasks (such as cluster setup, backup, recovery, maintenance, and management), they will need access to the Amazon RDS management console.
Amazon RDS also provides IAM database authentication option for MariaDB, MySQL, and PostgreSQL. You can authenticate without a password when you connect to a DB instance. Instead, you use an authentication token. For more information, go to IAM database authentication.
This blog helps you architect an application security model in AWS to provide on-premises access to commonly used resources in AWS.
You can apply security best practices and Zero Trust concepts as you move your legacy applications to the cloud. With AWS, you can build identity and access management with centralized and fine-grained access controls for your workforce and applications.
The world is asynchronous, is what Werner Vogels, Amazon CTO, reminded us during his keynote last week at AWS re:Invent. At the beginning of the keynote, he showed us how weird a synchronous world would be and how everything in nature is asynchronous. One example of an event-driven application he showcased during his keynote is Serverlesspresso, a project my team has been working on for the last year. And last week, we announced Serverlesspresso extensions, a new program that lets you contribute to Serverlesspresso and learn how event-driven applications can be extended.
Last Week’s Launches Here are some launches that got my attention during the previous week.
Amazon RDS Proxynow supports creating proxies in Amazon Aurora Global Database primary and secondary Regions. Now, building multi-Region applications with Amazon Aurora is simpler. RDS proxy sits between your application and the database pool and shares established database connections.
Other AWS News Some other updates and news that you may have missed:
I would like to recommend this really interesting Amazon Science article about federated learning. This is a framework that allows edge devices to work together to train a global model while keeping customers’ data on-device.
Podcast Charlas Técnicas de AWS – If you understand Spanish, this podcast is for you. Podcast Charlas Técnicas is one of the official AWS podcasts in Spanish, and every other week there is a new episode. Today the final episode for season three launched, and in it, we discussed many of the re:Invent launches. You can listen to all the episodes directly from your favorite podcast app or at AWS Podcasts en español.
AWS open-source news and updates–This is a newsletter curated by my colleague Ricardo to bring you the latest open-source projects, posts, events, and more.
Upcoming AWS Events Check your calendars and sign up for these AWS events:
AWS Resiliency Hub Activation Day is a half-day technical virtual session to deep dive into the features and functionality of Resiliency Hub. You can register for free here.
AWS re:Invent recaps in your area. During the re:Invent week, we had lots of new announcements, and in the next weeks you can find in your area a recap of all these launches. All the events will be posted on this site, so check it regularly to find an event nearby.
AWS re:Invent keynotes, leadership sessions, and breakout sessions are available on demand. I recommend that you check the playlists and find the talks about your favorite topics in one collection.
That’s all for this week. Check back next Monday for another Week in Review!
PostgreSQL has become the preferred open-source relational database for many enterprises and start-ups with its extensible design for developers. One of the reasons developers use PostgreSQL is it allows them to add database functionality by building extensions with their preferred programming languages.
Today, we are announcing the general availability of Trusted Language Extensions for PostgreSQL (pg_tle), a new open-source development kit for building PostgreSQL extensions. With Trusted Language Extensions for PostgreSQL, developers can build high-performance extensions that run safely on PostgreSQL.
Trusted Language Extensions for PostgreSQL provides database administrators control over who can install extensions and a permissions model for running them, letting application developers deliver new functionality as soon as they determine an extension meets their needs.
To start building with Trusted Language Extensions, you can use trusted languages such as JavaScript, Perl, and PL/pgSQL. These trusted languages have safety attributes, including restricting direct access to the file system and preventing unwanted privilege escalations. You can easily install extensions written in a trusted language on Amazon Aurora PostgreSQL-Compatible Edition 14.5 and Amazon RDS for PostgreSQL 14.5 or a newer version.
Trusted Language Extensions for PostgreSQL is an open-source project licensed under Apache License 2.0 on GitHub. You can comment or suggest items on the Trusted Language Extensions for PostgreSQL roadmap and help us support this project across multiple programming languages, and more. Doing this as a community will help us make it easier for developers to use the best parts of PostgreSQL to build extensions.
Let’s explore how we can use Trusted Language Extensions for PostgreSQL to build a new PostgreSQL extension for Amazon Aurora and Amazon RDS.
Setting up Trusted Language Extensions for PostgreSQL To use pg_tle with Amazon Aurora or Amazon RDS for PostgreSQL, you need to set up a parameter group that loads pg_tle in the PostgreSQL shared_preload_libraries setting. Choose Parameter groups in the left navigation pane in the Amazon RDS console and Create parameter group to make a new parameter group.
Choose Create after you select postgres14 with Amazon RDS for PostgreSQL in the Parameter group family and pg_tle in the Group Name. You can select aurora-postgresql14 for an Amazon Aurora PostgreSQL-Compatible cluster.
Choose a created pgtle parameter group and Edit in the Parameter group actions dropbox menu. You can search shared_preload_library in the search box and choose Edit parameter. You can add your preferred values, including pg_tle, and choose Save changes.
You can also do the same job in the AWS Command Line Interface (AWS CLI).
Now, you can add the pgtle parameter group to your Amazon Aurora or Amazon RDS for PostgreSQL database. If you have a database instance called testing-pgtle, you can add the pgtle parameter group to the database instance using the command below. Please note that this will cause an active instance to reboot.
Verify that the pg_tle library is available on your Amazon Aurora or Amazon RDS for PostgreSQL instance. Run the following command on your PostgreSQL instance:
SHOW shared_preload_libraries;
pg_tle should appear in the output.
Now, we need to create the pg_tle extension in your current database to run the command:
CREATE EXTENSION pg_tle;
You can now create and install Trusted Language Extensions for PostgreSQL in your current database. If you create a new extension, you should grant the pgtle_admin role to your primary user (e.g., postgres) with the following command:
GRANT pgtle_admin TO postgres;
Let’s now see how to create our first pg_tle extension!
Building a Trusted Language Extension for PostgreSQL For this example, we are going to build a pg_tle extension to validate that a user is not setting a password that’s found in a common password dictionary. Many teams have rules around the complexity of passwords, particularly for database users. PostgreSQL allows developers to help enforce password complexity using the check_password_hook.
In this example, you will build a password check hook using PL/pgSQL. In the hook, you can check to see if the user-supplied password is in a dictionary of 10 of the most common password values:
SELECT pgtle.install_extension (
'my_password_check_rules',
'1.0',
'Do not let users use the 10 most commonly used passwords',
$_pgtle_$
CREATE SCHEMA password_check;
REVOKE ALL ON SCHEMA password_check FROM PUBLIC;
GRANT USAGE ON SCHEMA password_check TO PUBLIC;
CREATE TABLE password_check.bad_passwords (plaintext) AS
VALUES
('123456'),
('password'),
('12345678'),
('qwerty'),
('123456789'),
('12345'),
('1234'),
('111111'),
('1234567'),
('dragon');
CREATE UNIQUE INDEX ON password_check.bad_passwords (plaintext);
CREATE FUNCTION password_check.passcheck_hook(username text, password text, password_type pgtle.password_types, valid_until timestamptz, valid_null boolean)
RETURNS void AS $$
DECLARE
invalid bool := false;
BEGIN
IF password_type = 'PASSWORD_TYPE_MD5' THEN
SELECT EXISTS(
SELECT 1
FROM password_check.bad_passwords bp
WHERE ('md5' || md5(bp.plaintext || username)) = password
) INTO invalid;
IF invalid THEN
RAISE EXCEPTION 'password must not be found on a common password dictionary';
END IF;
ELSIF password_type = 'PASSWORD_TYPE_PLAINTEXT' THEN
SELECT EXISTS(
SELECT 1
FROM password_check.bad_passwords bp
WHERE bp.plaintext = password
) INTO invalid;
IF invalid THEN
RAISE EXCEPTION 'password must not be found on a common password dictionary';
END IF;
END IF;
END
$$ LANGUAGE plpgsql SECURITY DEFINER;
GRANT EXECUTE ON FUNCTION password_check.passcheck_hook TO PUBLIC;
SELECT pgtle.register_feature('password_check.passcheck_hook', 'passcheck');
$_pgtle_$
);
You need to enable the hook through the pgtle.enable_password_check configuration parameter. On Amazon Aurora and Amazon RDS for PostgreSQL, you can do so with the following command:
It may take several minutes for these changes to propagate. You can check that the value is set using the SHOW command:
SHOW pgtle.enable_password_check;
If the value is on, you will see the following output:
pgtle.enable_password_check
-----------------------------
on
Now you can create this extension in your current database and try setting your password to one of the dictionary passwords and observe how the hook rejects it:
CREATE EXTENSION my_password_check_rules;
CREATE ROLE test_role PASSWORD '123456';
ERROR: password must not be found on a common password dictionary
CREATE ROLE test_role;
SET SESSION AUTHORIZATION test_role;
SET password_encryption TO 'md5';
\password
-- set to "password"
ERROR: password must not be found on a common password dictionary
To disable the hook, set the value of pgtle.enable_password_check to off:
You can uninstall this pg_tle extension from your database and prevent anyone else from running CREATE EXTENSION on my_password_check_rules with the following command:
DROP EXTENSION my_password_check_rules;
SELECT pgtle.uninstall_extension('my_password_check_rules');
You can find more sample extensions and give them a try. To build and test your Trusted Language Extensions in your local PostgreSQL database, you can build from our source code after cloning the repository.
Join Our Community! The Trusted Language Extensions for PostgreSQL community is open to everyone. Give it a try, and give us feedback on what you would like to see in future releases. We welcome any contributions, such as new features, example extensions, additional documentation, or any bug reports in GitHub.
When updating databases, using a blue/green deployment technique is an appealing option for users to minimize risk and downtime. This method of making database updates requires two database environments—your current production environment, or blue environment, and a staging environment, or green environment. You must then keep these two environments in sync with each other so you may safely test and upgrade your changes to production.
Amazon Aurora and Amazon Relational Database Service (Amazon RDS) customers can use database cloning and promotable read replicas to help self-manage a blue/green deployment. However, self-managing a blue/green deployment can be costly and complex to build and manage. As a result, customers sometimes delay implementing database updates, choosing availability over the benefits that they would gain from updating their databases.
Today, we are announcing the general availability of Amazon RDS Blue/Green Deployments, a new feature for Amazon Aurora with MySQL compatibility, Amazon RDS for MySQL, and Amazon RDS for MariaDB that enables you to make database updates safer, simpler, and faster.
With just a few steps, you can use Blue/Green Deployments to create a separate, synchronized, fully managed staging environment that mirrors the production environment. The staging environment clones your production environment’s primary database and in-Region read replicas. Blue/Green Deployments keep these two environments in sync using logical replication.
In as fast as a minute, you can promote the staging environment to be the new production environment with no data loss. During switchover, Blue/Green Deployments blocks writes on blue and green environments so that the green catches up with the blue, ensuring no data loss. Then, Blue/Green Deployments redirects production traffic to the newly promoted staging environment, all without any code changes to your application.
With Blue/Green Deployments, you can make changes, such as major and minor version upgrades, schema modifications, and operating system or maintenance updates, to the staging environment without impacting the production workload.
Getting Started with Blue/Green Deployments for MySQL Clusters You can start updating your databases with just a few clicks in the AWS Management Console. To get started, simply select the database that needs to be updated in the console and click Create Blue/Green Deployment under the Actions dropdown menu.
You can set a Blue/Green Deployment identifier and the attributes of your database to be modified, such as the engine version, DB cluster parameter group, and DB parameter group for green databases. To use a Blue/Green Deployment in your Aurora MySQL DB cluster, you should turn on binary logging, changing the value for the binlog_format parameter from OFF to MIXED in the DB cluster parameter group.
When you choose Create Blue/Green Deployment, it creates a new staging environment and runs automated tasks to prepare the database for production. Note, you will be charged the cost of the green database, including read replicas and DB instances in Multi-AZ deployments, and any other features such as Amazon RDS Performance Insights that you may have enabled on green.
You can also do the same job in the AWS Command Line Interface (AWS CLI). To perform an engine version upgrade, simply add a targetEngineVersion parameter and specify the engine version you’d like to upgrade to. This parameter works with both minor and major version upgrades, and it accepts short versions like 5.7 for Amazon Aurora MySQL-Compatible.
After creation is complete, you now have a staging environment that is ready for test and validation before promoting it to be the new production environment.
When testing and qualification of changes are complete, you can choose Switch over in the Actions dropdown menu to promote the staging environment marked as Green to be the new production system.
Now you are nearly ready to switch over your green databases to production. Check the settings of your green databases to verify that they are ready for the switchover. You may also set a timeout setting to determine the maximum time limit for your switchover. If Blue/Green Deployments’ switchover guardrails detect that it would take longer than the specified duration, then the switchover is canceled, and no changes are made to the environments. We recommend that you identify times of low or moderate production traffic to initiate a switchover.
After switchover, Blue/Green Deployments does not delete your old production environment. You may access it for additional validations and performance/regression testing, if needed. Please note that it is your responsibility to delete the old production environment when you no longer need it. Standard billing charges apply on old production instances until you delete them.
Now Available Amazon RDS Blue/Green Deployments is available today on Amazon Aurora with MySQL Compatibility 5.6 or higher, Amazon RDS for MySQL major version 5.6 or higher, and Amazon RDS for MariaDB 10.2 and higher in all AWS commercial Regions, excluding China, and AWS GovCloud Regions.
A new week starts, and the News Blog team is getting ready for AWS re:Invent! Many of us will be there next week and it would be great to meet in person. If you’re coming, do you know about PeerTalk? It’s an onsite networking program for re:Invent attendees available through the AWS Events mobile app (which you can get on Google Play or Apple App Store) to help facilitate connections among the re:Invent community.
Amazon EventBridge – With these additional filtering capabilities, you can now filter events by suffix, ignore case, and match if at least one condition is true. This makes it easier to write complex rules when building event-driven applications.
AWS Controllers for Kubernetes (ACK) – The ACK for Amazon Elastic Compute Cloud (Amazon EC2) is now generally available and lets you provision and manage EC2 networking resources, such as VPCs, security groups and internet gateways using the Kubernetes API. Also, the ACK for Amazon EMR on EKS is now generally available to allow you to declaratively define and manage EMR on EKS resources such as virtual clusters and job runs as Kubernetes custom resources. Learn more about ACK for Amazon EMR on EKS in this blog post.
Amazon HealthLake – New analytics capabilities make it easier to query, visualize, and build machine learning (ML) models. Now HealthLake transforms customer data into an analytics-ready format in near real-time so that you can query, and use the resulting data to build visualizations or ML models. Also new is Amazon HealthLake Imaging (preview), a new HIPAA-eligible capability that enables you to easily store, access, and analyze medical images at any scale. More on HealthLake Imaging can be found in this blog post.
Amazon RDS – You can now transfer files betweenAmazon Relational Database Service (RDS) for Oracle and an Amazon Elastic File System (Amazon EFS) file system. You can use this integration to stage files like Oracle Data Pump export files when you import them. You can also use EFS to share a file system between an application and one or more RDS Oracle DB instances to address specific application needs.
AWS Fargate – Adds the ability to monitor the utilization of the ephemeral storage attached to an Amazon ECS task. You can track the storage utilization with Amazon CloudWatch Container Insights and ECS Task Metadata endpoint.
Amazon ElastiCache – You can now use IAM authentication to access Redis clusters. With this new capability, IAM users and roles can be associated with ElastiCache for Redis users to manage their cluster access.
Amazon CloudWatch RUM – You can now send custom events (in addition to predefined events) for better troubleshooting and application specific monitoring. In this way, you can monitor specific functions of your application and troubleshoot end user impacting issues unique to the application components.
AWS AppSync – You can now define GraphQL API resolvers using JavaScript. You can also mix functions written in JavaScript and Velocity Template Language (VTL) inside a single pipeline resolver. To simplify local development of resolvers, AppSync released two new NPM libraries and a new API command. More info can be found in this blog post.
AWS Console – With the new Applications widget on the Console home, you have one-click access to applications in AWS Systems Manager Application Manager and their resources, code, and related data. From Application Manager, you can view the resources that power your application and your costs using AWS Cost Explorer.
Other AWS News A few more stuff you might have missed:
Introducing our final AWS Heroes of the year – As the end of 2022 approaches, we are recognizing individuals whose enthusiasm for knowledge-sharing has a real impact with the AWS community. Please meet them here!
The Distributed Computing Manifesto – Werner Vogles, VP & CTO at Amazon.com, shared the Distributed Computing Manifesto, a canonical document from the early days of Amazon that transformed the way we built architectures and highlights the challenges faced at the end of the 20th century.
AWS re:Post – To make this community more accessible globally, we expanded the user experience to support five additional languages. You can now interact with AWS re:Post also using Traditional Chinese, Simplified Chinese, French, Japanese, and Korean.
For AWS open-source news and updates, here’s the latest newsletter curated by Ricardo to bring you the most recent updates on open-source projects, posts, events, and more.
Upcoming AWS Events As usual, there are many opportunities to meet:
That’s all from me for this week. Next week we’ll focus on re:Invent, and then we’ll take a short break. We’ll be back with the next Week in Review on December 12!
How do you securely access Amazon Relational Database Service (Amazon RDS) instances from a developer’s laptop? Online travel marketplace, Wego, shares their journey from bastion hosts in the public subnet to lightweight VPN tunnels on top of Session Manager, a capability of AWS Systems Manager, using temporary access keys.
In this post, we explore how developers get access to allow-listed resources in their virtual private cloud (VPC) directly from their workstation, by tunnelling VPN over secure shell (SSH), which, in turn, is tunneled over Session Manager.
Note: This blog post is not intended as a step-by-step, how-to guide. Commands stated here are for illustrative purposes and may need customization.
Wego’s architecture before starting this journey
In 2021, Wego’s developer connectivity architecture was based on jump hosts in a public subnet, as illustrated in Figure 1.
Figure 1. Original Wego architecture
Figure 1 demonstrates a network architecture with both public and private subnets. The public subnet contains an Amazon Elastic Compute Cloud (Amazon EC2) instance that serves as jump host. The diagram illustrates a VPN tunnel between the developer’s desktop and the VPC.
In Wego’s previous architecture, the jump host was connected to the internet for terminal access through the secure shell (SSH) protocol, which accepts traffic at Port 22. Despite restrictions to the allowed source IP addresses, exposing Port 22 to the internet can increase the likeliness of a security breach; it is possible to spoof (mimic) an allowed IP address and attempt a denial of service attack.
Moving the jump host to a private subnet with Session Manager
Session Manager helps minimize the likeliness of a security breach. Figure 2 demonstrates how Wego moved the jump host from a public subnet to a private subnet. In this architecture, Session Manager serves as the main entry point for incoming network traffic.
Figure 2. Wego’s new architecture using Session Manager
We will explore how developers connect to Amazon RDS directly from their workstation in this architecture.
Tunnel TCP traffic through Session Manager
Session Manager is best known for its terminal access capability, but it can also tunnel TCP connections. This is helpful if you want to access EC2 instances from your local workstation (Figure 3).
Figure 3. Tunneling TCP traffic over Session Manager
Here’s an example command to forward traffic from local host Port 8888 to an EC2 instance:
You can now connect to the EC2 instance over SSH with the following command:
ssh -i <key-file> <username>@<ec2-instance-id>
For example:
ssh -i my_key ec2-user@i-1234567890abcdef0
Ideally, your key-file is a short-lived credential, as recommended by the AWS Well-Architected Framework, as it narrows the window of opportunity for a security breach. However, it can be tedious to manage short-lived credentials. This is where EC2 Instance Connect comes to the rescue!
Replace SSH keys with EC2 Instance Connect
EC2 Instance Connect is available both on the AWS console and the command line. It makes it easier to work with short-lived keys. On the command line, it allows us to install our own temporary access credentials into a private EC2 instance for the duration of 60 seconds (Figure 5).
This blog post assumes you are using Amazon Linux on the EC2 instance with all pre-requisites installed. Make sure your IAM role or user has the required permissions.
To generate a temporary SSH key pair, insert:
$ ssh-keygen -t rsa -f my_key
$ ssh-add my_key
To install the public key into the EC2 instance, insert:
Connect to the EC2 instance within 60 seconds and delete the key after use.
Tunneling VPN over SSH, then over Session Manager
In this section, we adopt a third-party, open-source tool that is not supported by AWS, called sshuttle. sshuttle is a transparent proxy server that works as a VPN over SSH. It is based on Python and released under the LGPL 2.1 license. It runs across a wide range of Linux distributions and on macOS (Figure 6).
Figure 6. Tunneling VPN over SSH over Session Manager
Why do we need to tunnel VPN over SSH, rather than using the earlier TCP over Session Manager? Keep in mind that the developer’s goal is to connect to Amazon RDS, not Amazon EC2. The SSM tunnel only works for connections to EC2 instances, not Amazon RDS.
A lightweight VPN solution, like sshuttle, bridges this gap by allowing you to forward traffic from Amazon EC2 to Amazon RDS. From the developer’s perspective, this works transparently, as if it is regular network traffic.
Make sure the security group for the RDS DB instance allows network access from the jump host. You can now connect directly from the developer’s workstation to the RDS DB instance based on its IP address.
Advantages of this architecture
In this blog post, we layered a VPN over SSH that, in turn, is layered over Session Manager, plus we used temporary SSH keys.
Wego designed this architecture, and it was practical and stable for day-to-day use. They found that this solution runs at lower cost than AWS Client VPN and is sufficient for the use case of developers accessing online development environments.
Wego’s new architecture has a number of advantages, including:
More easily connecting to workloads in private and isolated subnets
Inbound security group rules are not required for the jump host, as Session Manager is an outbound connection
Access control uses standard IAM policies, including tag-based resource access
Security groups and network access control lists still apply to “allow” or “deny” traffic to specific destinations
SSH keys are installed only temporarily for 60 seconds through EC2 Instance Connect
Conclusion
In this blog post, we explored Wego’s access patterns that can help you reduce your exposure to potential security attacks. Whether you adopt Wego’s full architecture or only adopt intermediary steps (like SSH over Session Manager and EC2 Instance Connect), reducing exposure to the public subnet and shortening the lifetime of access credentials can improve your security posture!
Last week, we announced plans to launch the AWS Asia Pacific (Bangkok) Region, which will become our third AWS Region in Southeast Asia. This Region will have three Availability Zones and will give AWS customers in Thailand the ability to run workloads and store data that must remain in-country.
In the Works – AWS Region in Thailand With this big news, AWS announced a 190 billion baht (US 5 billion dollars) investment to drive Thailand’s digital future over the next 15 years. It includes capital expenditures on the construction of data centers, operational expenses related to ongoing utilities and facility costs, and the purchase of goods and services from Regional businesses.
Since we first opened an office in Bangkok in 2015, AWS has launched 10 Amazon CloudFront edge locations, a highly secure and programmable content delivery network (CDN) in Bangkok. In 2020, we launched AWS Outposts, a family of fully managed solutions delivering AWS infrastructure and services to virtually any on-premises or edge location for a truly consistent hybrid experience in Thailand. This year, we also plan the upcoming launch of an AWS Local Zone in Bangkok, which will enable customers to deliver applications that require single-digit millisecond latency to end users in Thailand.
Photo courtesy of Conor McNamara, Managing Director, ASEAN at AWS
The new AWS Region in Thailand is also part of our broader, multifaceted investment in the country, covering our local team, partners, skills, and the localization of services, including Amazon Transcribe, Amazon Translate, and Amazon Connect.
Many Thailand customers have chosen AWS to run their workloads to accelerate innovation, increase agility, and drive cost savings, such as 2C2P, CP All Plc., Digital Economy Promotion Agency, Energy Response Co. Ltd. (ENRES), PTT Global Public Company Limited (PTT), Siam Cement Group (SCG), Sukhothai Thammathirat Open University, The Stock Exchange of Thailand, Papyrus Studio, and more.
For example, Dr. Werner Vogels, CTO of Amazon.com, introduced the story of Papyrus Studio, a large film studio and one of the first customers in Thailand.
“Customer stories like Papyrus Studio inspire us at AWS. The cloud can allow a small company to rapidly scale and compete globally. It also provides new opportunities to create, innovate, and identify business opportunities that just aren’t possible with conventional infrastructure.”
For more information on how to enable AWS and get support in Thailand, contact our AWS Thailand team.
Last Week’s Launches My favorite news of last week was to launch dark mode as a beta feature in the AWS Management Console. In Unified Settings, you can choose between three settings for visual mode: Browser default, Light, and Dark. Browser default applies the default dark or light setting of the browser, dark applies the new built-in dark mode, and light maintains the current look and feel of the AWS console. Choose your favorite!
Here are some launches that caught my eye for web, mobile, and IoT application developers:
New AWS Amplify Library for Swift – We announce the general availability of Amplify Library for Swift (previously Amplify iOS). Developers can use Amplify Library for Swift via the Swift Package Manager to build apps for iOS and macOS (currently in beta) platforms with Auth, Storage, Geo, and more features.
New Amazon IVS Chat SDKs – Amazon Interactive Video Service (Amazon IVS) now provides SDKs for stream chat with support for web, Android, and iOS. The Amazon IVS stream chat SDKs support common functions for chat room resource management, sending and receiving messages, and managing chat room participants.
Amazon IVS is a managed, live-video streaming service using the broadcast SDKs or standard streaming software such as Open Broadcaster Software (OBS). The service provides cross-platform player SDKs for playback of Amazon IVS streams you need to make low-latency live video available to any viewer around the world. Also, it offers Chat Client Messaging SDK. For more information, see Getting Started with Amazon IVS Chat in the AWS documentation.
New AWS Parameters and Secrets Lambda Extension – This is new extension for AWS Lambda developers to retrieve parameters from AWS Systems Manager Parameter Store and secrets from AWS Secrets Manager. Lambda function developers can leverage this extension to improve their application performance as it decreases the latency and the cost of retrieving parameters and secrets.
New FreeRTOS Long Term Support Version – We announce the second release of FreeRTOS Long Term Support (LTS) – FreeRTOS 202210.00 LTS. FreeRTOS LTS offers a more stable foundation than standard releases as manufacturers deploy and later update devices in the field. This release includes new and upgraded libraries such as AWS IoT Fleet Provisioning, Cellular LTE-M Interface, coreMQTT, and FreeRTOS-Plus-TCP.
All libraries included in this FreeRTOS LTS version will receive security and critical bug fixes until October 2024. With an LTS release, you can continue to maintain your existing FreeRTOS code base and avoid any potential disruptions resulting from FreeRTOS version upgrades. To learn more, see the FreeRTOS announcement.
Here is some news on performance improvement and increasing capacity:
Up to 10X Improving Amazon Aurora Snapshot Exporting Speed – Amazon Aurora MySQL-Compatible Edition for MySQL 5.7 and 8.0 now speed up to 10x faster snapshot exports to Amazon S3. The performance improvement is automatically applied to all types of database snapshot exports, including manual snapshots, automated system snapshots, and snapshots created by the AWS Backup service. For more information, see Exporting DB cluster snapshot data to Amazon S3 in the Amazon Aurora documentation.
3X Increasing Amazon RDS Read Capacity – Amazon Relational Database Service (RDS) for MySQL, MariaDB, and PostgreSQL now supports 15 read replicas per instance, including up to 5 cross-Region read replicas, delivering up to 3x the previous read capacity. For more information, see Working with read replicas in the Amazon RDS documentation.
2X Increasing AWS Snowball Edge Compute Capacity – The AWS Snowball Edge Compute Optimized device doubled the compute capacity up to 104 vCPUs, doubled the memory capacity up to 416GB RAM, and is now fully SSD with 28TB NVMe storage. The updated device is ideal when you need dense compute resources to run complex workloads such as machine learning inference or video analytics at the rugged, mobile edge such as trucks, aircraft or ships. You can get started by ordering a Snowball Edge device on the AWS Snow Family console.
2X Increasing Amazon SQS FIFO Default Quota – Amazon Simple Queue Service (SQS) announces the increase of default quota up to 6,000 transactions per second per API action. It is double the previous 3,000 throughput quota for a high throughput mode for FIFO (first in, first out) queues in all AWS Regions where Amazon SQS FIFO queue is available. For a detailed breakdown of default throughput quotas per Region, see Quotas related to messages in the Amazon SQS documentation.
Sustainability with AWS Partners (ft. AWS On Air) – This episode covers a broad discipline of environmental, social, and governance (ESG) issues across all regions, organization types, and industries. AWS Sustainability & Climate Tech provides a comprehensive portfolio of AWS Partner solutions built on AWS that address climate change events and the United Nation’s Sustainable Development Goals (SDG).
Upcoming AWS Events Check your calendars and sign up for these AWS events:
AWS re:Invent 2022 Attendee Guide – Browse re:Invent 2022 attendee guides, curated by AWS Heroes, AWS industry teams, and AWS Partners. Each guide contains recommended sessions, tips and tricks for building your agenda, and other useful resources. Also, seat reservations for all sessions are now open for all re:Invent attendees. You can still register for AWS re:Invent either offline or online.
AWS AI/ML Innovation Day on October 25 – Join us for this year’s AWS AI/ML Innovation Day, where you’ll hear from Bratin Saha and other leaders in the field about the great strides AI/ML has made in the past and the promises awaiting us in the future.
AWS Container Day at Kubecon 2022 on October 25–28– Come join us at KubeCon + CloudNativeCon North America 2022, where we’ll be hosting AWS Container Day Featuring Kubernetes on October 25 and educational sessions at our booth on October 26–28. Throughout the event, our sessions focus on security, cost optimization, GitOps/multi-cluster management, hybrid and edge compute, and more.
Shiji Group provides global software solutions for the hospitality industry. The Shiji Enterprise Platform enables customers to manage large hotel property portfolios using software as a service (SaaS). Among functionalities such as reservations, housekeeping, finance, and integrations with external systems, the guest profile is a key aspect of the system. Besides personal information (such as name and address) and billing details, the guest profile can include room preferences and entertainment options.
A property portfolio can span multiple hotels across the globe, and each hotel location can offer better customer service by consolidating data. Once the guest gives their cross-border data processing consent (CBDPC), profile information can be shared between properties. This provides a centralized and seamless experience for the hotel guest no matter which hotel in the portfolio was chosen.
In the following blog post, you will explore the architecture of the guest profile store that replicates the profile across multiple geographic areas. We will review the single Region design first and its infrastructure components and architectural patterns. We will then show the evolution to a multi-Region architecture.
Single Region architecture with CQRS
The ability to find relevant guest profile data fast is essential in the day-to-day hospitality business. Therefore, the following architecture uses the command query responsibility segregation (CQRS) pattern to provide high scalability and rich full-text search capabilities without sacrificing performance. With CQRS, write requests (commands) are targeting a different service than read requests (queries). This allows systems to store an item (such as a profile) in a search-optimized format for serving reads, while providing a simple schema for writes.
The following diagram provides a walk through the single Region architecture:
Figure 1. Single Region architecture with CQRS
The front desk employee creates the Guest Profile upon first interaction with the hotel guest (name, address, billing, and room preferences).
The request is routed to the Kong API Management Solution that is running in an Amazon EKS Kubernetes cluster. It acts as the single entry-point to the system. It identifies the type of request by parsing the URL and forwarding write requests to the profile-write-model-service.
The service validates the request. It stores the data and ProfileCreated event in the PostgreSQL database, Amazon RDS.
A change data capture (CDC) mechanism publishes the ProfileCreated event to an Apache Kafka Local Profiles topic.
The profile-read-model-service subscribes to the Local Profiles topic and stores the profile in an optimized read format in Amazon OpenSearch. Whenever the hotel performs a guest profile search, results will now be provided via the profile-read-model-service.
Multi-Region networking setup
Shiji operates in multiple AWS Regions to provide low latency, regulatory requirements, and resilience across the globe. The previously presented single Region architecture can be replicated to multiple AWS Regions (eu-central-1 and ap-southeast-1, for example). Hotels with a given property portfolio that operate in the same Region can reuse the profile store of the Shiji Enterprise Platform. However, hotels that are being operated in a different AWS Region can be interconnected as well.
This is achieved by providing an AWS Transit Gateway in a separate networking account that connects the different Regions with a VPC attachment:
Figure 2. Multi-Region networking setup
The account segregation provides an additional layer of flexibility to add further Regions in the future.
Multi-Region event replication
Upon first arrival, guests can choose to sign a cross-border-data processing consent (CBDPC). This permits the hotel to share the profile information globally. If accepted, the profile-write-model-service creates an additional ProfileCreated event that gets published to a GlobalProfilesEU Apache Kafka topic. This topic is accessible for subscribers in the target Region, which replicates relevant profiles into the local database as follows.
A replicator-service in the target Region (ap-souteast-1) is now able to subscribe to the GlobalProfileEU topic in (eu-central-1), via the established network connection from the previous section. It republishes the event to a local ReplicatedProfiles topic that the profile-write-model-service subscribes to and saves to the local database:
Figure 3. Event replication
Putting it all together: The multi-Region guest profile store
The following diagram combines all the components from the previous sections. It provides an end-to-end look at the multi-Region guest profile architecture. Due to the event driven nature of the system, the architecture can be extended without changing the initial flow outlined in the single Region design.
Figure 4. Multi-Region guest profile architecture
If the hotel guest signed a cross-border data processing consent (CBDPC), the ProfileCreated event will also be published to a Global Profiles topic.
The replicator-service in the target Region (for example, ap-southeast-1) subscribes to the Global Profiles topic of the source Region (for example, eu-central-1). It then publishes the event to its local Replicated Profiles topic.
The profile-write-model-service in the target Region subscribes to the Replicated Profiles topic and records the item in the Amazon RDS PostgreSQL database with information about the source Region. This will initiate the local replication similar to the single Region design, and therefore creates a consistent experience between both Regions.
Conclusion and outlook
In this blog post, we showed how Shiji built a modern multi-Region microservice architecture on AWS. You have learned about patterns such as CQRS, which provide a scalable solution for both read and write traffic. We’ve also shown what is needed to interconnect two physically separated Regions. With cross-border data processing consent (CBDPC), you have seen how the ownership of guest data can be secured and utilized. The single Region architecture already provided a solid baseline for this solution architecture. The event-driven nature of the system permitted us to add additional functionality for the final multi-Region architecture.
The ability to manage a global guest profile within the main system as well as at the property itself is a huge advantage for enterprise hotel companies. It permits hotels to deliver a unified experience to their guests no matter where the guest is within the hotel or on their journey. Food preferences, spa, room, and more, can all be managed from a single guest profile. This centralized information hasn’t been possible within the hotel’s property management system (PMS) until recently.
This is post is co-authored by Manish Mehra, Anirudh Vohra, Sidrah Sayyad, and Abhishek I S (from ZS), and Parnab Basak (from AWS). The team at ZS collaborated closely with AWS to build a modern, cloud-native data orchestration platform.
ZS is a management consulting and technology firm focused on transforming global healthcare and beyond. We leverage our leading-edge analytics, plus the power of data, science, and products, to help our clients make more intelligent decisions, deliver innovative solutions, and improve outcomes for all. Founded in 1983, ZS has more than 12,000 employees in 35 offices worldwide.
ZAIDYNTM by ZS is an intelligent, cloud-native platform that helps life sciences organizations shape the future. Its analytics, algorithms, and workflows empower people, transform processes, and unlock real value. Designed to learn and grow with our clients, the platform is modular, future-ready, and fueled by global connectivity. And as more people engage, share, and build, our platform gets smarter—helping organizations fuel discovery, connect with customers, deliver treatments, and improve lives. ZAIDYN is helping companies of all sizes gain fluency in the full spectrum of life sciences so they can move faster, together through its Data & Analytics, Customer Engagement, Field Performance and Clinical Development offerings.
ZAIDYN Data & Analytics apps provide business users with self-service tools to innovate and scale insights delivery across the enterprise. ZAIDYN Data Hub (a part of the Data & Analytics product category) provides self-service options for guided workflows, data connectors, quality checks, and more. The elastic data processing offered by AWS helps prioritize processing speeds.
Data Hub customers wanted a one-stop solution for managing their data pipelines. A solution that does not require end users to gain additional knowledge about the nitty-gritties of the tool, one which is easy for users to get onboarded on, thereby increasing the demand for data orchestration capabilities within the application. A few of the sophisticated asks like start and stop of workflows, maintaining history of past runs, and providing real-time status updates for individual tasks of the workflow became increasingly important for end clients. We needed a mature orchestration tool, which led us to Amazon Managed Workflows for Apache Airflow (Amazon MWAA).
Amazon MWAA is a managed orchestration service for Apache Airflow that makes it easier to set up and operate end-to-end data pipelines in the cloud at scale.
In this post, we share how ZS created a multi-tenant self-service data orchestration platform using Amazon MWAA.
Why we chose Amazon MWAA
Choosing the right orchestration tool was critical for us because we had to ensure that the service was operationally efficient and cost-effective, provided high availability, had extensive features to support our business cases, and yet was easy to adapt for our end-users (data engineers). We evaluated and experimented among Amazon MWAA, Azkaban on Amazon EMR, and AWS Step Functions before project initiation.
The following benefits of Amazon MWAA convinced us to adopt it:
AWS managed service – With Amazon MWAA, we don’t have to manage the underlying infrastructure for scalability and availability to maintain quality of service. The built-in autoscaling mechanism of Amazon MWAA automatically increases the number of Apache Airflow workers in response to running and queued tasks, and disposes of extra workers when there are no more tasks queued or running. The default environment is already built for high availability with multiple Airflow schedulers and workers, and the metadata database distributed across multiple Availability Zones. We also evaluated hosting open-source Airflow on our ZS infrastructure. However, due to infrastructure maintenance overhead and the high investment needed to make and maintain it at production grade, we decided to drop that option.
Security – With Amazon MWAA, our data is secure by default because workloads run in our own isolated and secure cloud environment using Amazon Virtual Private Cloud (Amazon VPC), and data is automatically encrypted using AWS Key Management Service (AWS KMS). We can control role-based authentication and authorization for Apache Airflow’s user interface via AWS Identity and Access Management (IAM), providing users single sign-on (SSO) access for scheduling and viewing workflow runs.
Compatibility and active community support – Amazon MWAA hosts the same open-source Apache Airflow version without any forks. The open-source community for Apache Airflow is very active with multiple commits, files changes, issue resolutions, and community advice.
Language and connector support – The flow definitions for Apache Airflow are based on Python, which is easy for our engineers to adapt. An extensive list of features and connectors is available out of the box in Amazon MWAA, including connectors for Hive, Amazon EMR, Livy, and Kubernetes. We needed to run all our Data Hub jobs (ingestion, applying custom rules and quality checks, or exporting data to third-party systems) on Amazon EMR. The necessary Amazon EMR operators are already available as a part of the Amazon-provided package for Airflow (apache-airflow-providers-amazon), which we could supplement rather than construct one from the ground up.
Cost – Cost was the most important aspect for us when adopting Amazon MWAA. Amazon MWAA is useful for those who are running thousands of tasks in the prod environment, which is why we decided to the make the Amazon MWAA environment multi-tenant such that the cost can be shared among clients. With our large Amazon MWAA environment, we only pay for what we use, with no minimum fees or upfront commitments. We estimated paying less than $1,000 per month, combined for our environment usage and additional worker instance pricing, yet achieve the scale of being able to run 200 concurrent tasks running 3 hours per day over 10 concurrent workers. This meant reduced operational costs and engineering overhead while meeting the on-demand monitoring needs of end-to-end data pipeline orchestration.
Solution overview
The following diagram illustrates the solution architecture.
We have a common control tier account where we host our software as a service application (Data Hub) on Amazon Elastic Compute Cloud (Amazon EC2) instances. Each client has their own version of this application deployed on this shared infrastructure. Amazon MWAA is also hosted in the same common control tier account. The control tier account has connectivity with tenant-specific AWS accounts. This is to maintain strong physical isolation of client data by segregating the AWS accounts for each client. Each client-specific account hosts EMR clusters where data processing takes place. When a processing job is complete, data may reside on Amazon EMR (an HDFS cluster) or on Amazon Simple Storage Service (Amazon S3), an EMRFS cluster, depending on configuration. The DAG files generated by our Data Hub application contain metadata of the processes, and don’t contain any sensitive client information. When a job is submitted from Data Hub, the API request contains tenant-specific information needed to pull up the corresponding AWS connection details, which are stored as Airflow connection objects. These connection details are consumed by our custom implementation of Airflow EMR step operators (add and watch) to perform operations on the tenant EMR clusters.
Because the data orchestration capability is an application offering, the client teams create their processes on the Data Hub UI and don’t have access to the underlying Amazon MWAA environment.
The following screenshot shows how an end-user can configure Data Hub process on the application UI.
How Data Hub processes map to Amazon MWAA DAGs
Data Hub processes map to Amazon MWAA DAGs as follows:
Each process in Data Hub corresponds to a DAG in Amazon MWAA, and each component is a task (denoted by Sn) that is submitted as a step on the client EMR clusters.
The application generates the DAG file dynamically and updates it on the S3 bucket linked to the Amazon MWAA environment.
Parsing dedicated structures representing a given process and submitting or tracking the Amazon EMR steps is abstracted from the end-user. Dynamic DAG generation is responsible for using the latest version of the underlying components and helps in managing the DAG schedule.
Some Airflow tasks are created as a part of the DAG, which take care of interacting with the application APIs to ensure that the required metadata is captured in a separate Amazon Relational Database Service (Amazon RDS) database instance.
A user can trigger a given process to run from the Data Hub UI or can schedule it to run at a specified time. Because a single Amazon MWAA environment is responsible for the data orchestration needs of multiple clients, our DAG decode logic ensures that the correct EMR cluster ID and Airflow connection ID are picked up at runtime. The configs responsible for storing these details are placed and updated on the S3 buckets via an automated deployment pipeline. A dedicated connection ID is created per client in Airflow, which is then utilized in our custom implementation of EmrAddStepsOperator. The connection ID captures the Region and role ARN to be assumed to interact with the EMR cluster in the client account. These cross-account roles have access to limited resources in each client account, following the principle of least privilege.
Generating a DAG from a process defined on Data Hub UI
Our front-end application is built using Angular (version 11) and uses a third-party library that facilitates drag-and-drop of components from the left pane on a canvas. Components are stitched together with connections defining dependencies to form a process. This process is translated by our custom engine to generate a dynamic Airflow DAG. A sample DAG generated from the preceding example process defined on the UI looks like the following figure.
We wrap the DAG by PEntry and PExit Python operators, and for each of the components on the Data Hub UI, we create two tasks: Cn and Wn.
The relevant terms for this solution are as follows:
PEntry – The Python operator used to insert an entry in the RDS database that the process run has started via API call.
Cn – The ZS custom implementation of EMRAddStepsOperator used to submit a job (Data Hub component) on a running EMR cluster. This is followed by an API call to insert an entry in the database that the component job has started.
Wn – The custom implementation of Airflow Watcher (EmrStepSensor), which checks the status of the step from our metadata database.
PExit – The Python operator used to update an entry in the RDS database (more of a finally block) via API call.
Lessons learned during the implementation
When implementing this solution, we learned the following:
We faced challenges in being able to consistently predict when a DAG will be parsed and made available in the Airflow UI in Amazon MWAA after the DAG file is synced to the linked S3 bucket. Depending on how complex the DAG is, it could happen within seconds or several minutes. Due to the lack of availability of an API or AWS Command Line Interface (AWS CLI) command to ascertain this, we put in some blanket restrictions (delay) on user operations from our UI to overcome this limitation.
Within Airflow, data pipelines are represented by DAGs, and these DAGs change over time as business needs evolve. A key challenge faced by Airflow users is looking at how a DAG was run in the past, and when it was replaced by a newer version of the DAG. This is because within Airflow (as of this writing), only the current (latest) version of the DAG is represented within the user interface, without any reference to prior versions of the DAG. To overcome this limitation, we implemented a backend way of generating a DAG from the available metadata, and use it to version control over runs.
Airflow CLI commands when invoked in DAGs always return an HTTP 200 response. You can’t solely rely on the HTTP response code to ascertain the status of commands. We applied additional parsing logic (particularly to analyze the errors on failure) to determine the true status of commands.
Airflow doesn’t have a command to gracefully stop a DAG that is currently running. You can stop a DAG (unmark as running) and clear the task’s state or even delete it in the UI. The actual running tasks in the executor won’t stop, but might be stopped if the executor realizes that it’s not in the database anymore.
Conclusion
Amazon MWAA sets up Apache Airflow for you using the same Apache Airflow user interface and open-source code. With Amazon MWAA, you can use Airflow and Python to create workflows without having to manage the underlying infrastructure for scalability, availability, and security. Amazon MWAA automatically scales its workflow run capacity to meet your needs, and is integrated with AWS security services to help provide you with fast and secure access to your data. In this post, we discussed how you can build a bridge tenancy isolation model with a central Amazon MWAA orchestrating task against independent infrastructure stacks in dedicated accounts deployed for each of your tenants. Through a custom UI, you can enable self-service workflow runs via Airflow dynamic DAGs using the power and flexibility of Python. This enables you to achieve economies of scale and operational efficiency while meeting your regulatory, security, and cost considerations.
About the Authors
Manish Mehra is a Software Architect, working with the SD group in ZS. He has more than 11 years of experience working in banking, gaming, and life science domains. He is currently looking into the architecture of the Data & Analytics product category of the ZAIDYN Platform. He has expertise in full-stack application development and building robust, scalable, enterprise-grade big data applications.
Anirudh Vohra is a Director of Cloud Architecture, working within the Cloud Center of Excellence space at ZS. He is passionate about being a developer advocate for internal engineering teams, also designing and building cloud platforms and abstractions to empower developers and troubleshoot complex systems.
Abhishek I S is Associate Cloud Architect at ZS Associates working within the Cloud Centre of Excellence space. He has diverse experience ranging from application development to cloud engineering. Currently, he is primarily focusing on architecture design and automation for the cloud-native solutions of various ZS products.
Sidrah Sayyad is an Associate Software Architect at ZS working within the Software Development (SD) group. She has 9 years of experience, which includes working on identity management, infrastructure management, and ETL applications. She is passionate about coding and helps architect and build applications to achieve business outcomes.
Parnab Basak is a Solutions Architect and a Serverless Specialist at AWS. He specializes in creating new solutions that are cloud native using modern software development practices like serverless, DevOps, and analytics. Parnab was closely involved with the engagement with ZS, providing architectural guidance as well as helping the team overcome technical challenges during the implementation.
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