Tag Archives: AWS Lambda

Automating Your Home with Grafana and Siemens Controllers

2021-08-04 Viktoria Semaan

Post Syndicated from Viktoria Semaan original https://aws.amazon.com/blogs/architecture/automating-your-home-with-grafana-and-siemens-controllers/

Imagine that you have access to a digital twin of your house that allows you to remotely monitor and control different devices inside your home. Forgot to turn off the heater or air conditioning? Didn’t close water faucets? Wondering how long your kids have been watching TV? Wouldn’t it be nice to have all the information from multiple devices in a single place?

Nowadays, many of us have smart things at home, such as thermostats, security cameras, wireless sensors, switches, etc. The problem is that most of these smart things come with different mobile applications. To get a full picture, we end up switching between applications that serve limited needs.

In this blog, we explain how to use Siemens controllers, AWS IoT, and the open-source visualization platform Grafana to quickly build a digital twin of any processes. This includes home automation, industrial applications, security systems, and others. As an example, we will monitor environmental conditions, including temperature and humidity sensors, thermostat settings, light switches, as well as monthly water and energy consumption. We will go through the architecture and steps required to integrate different building components to store data for historical analysis, enable voice control, and create interactive near real-time dashboards showing a digital representation of your house. If you would like to learn more about the solution, we will provide links to all the architecture components and detailed configuration steps.

Figure 1. Smart home automation solution with Siemens LOGO! compact controller

Architecture

In this solution overview, we are using a low-cost Siemens LOGO! controller (hardware version 8.3 or higher). This controller supports traditional industrial protocols such as Simatic S7 and Modbus TCP/IP as well as MQTT through the native AWS IoT Core interface. Automation controllers are the brains behind smart systems that allow orchestrating all the devices in your home. This reference architecture can be extended to other devices that support MQTT protocol, have programmatic APIs, or Software Development Kits (SDKs). It could serve as a starting point for building a home automation solution using AWS IoT and Grafana and further customized based on customer needs.

Figure 2. Reference architecture for smart home automation solution

The components of this solution are:

The LOGO! controller controls home automation equipment and ingests data to AWS IoT Core.
AWS IoT Core collects data at scale and routes messages to multiple AWS services.
AWS Lambda is called inside the AWS IoT Core statement to transform the incoming data prior to ingestion.
Amazon Timestream stores time series data and optimizes it for fast analytical queries.
AWS IoT SiteWise models and stores data from equipment for large scale deployments.
Grafana installed on Amazon Elastic Compute Cloud (Amazon EC2) visualizes data in near real-time using interactive dashboards.
The Alexa Skills Kit (ASK) allows interaction with devices using voice commands.

Figure 3. Remote monitoring dashboard allows homeowners to view and control conditions

Solution overview

Step 1: Ingest data to AWS IoT

The IoT-enabled LOGO! controller provides the out-of-box capability to send data to AWS IoT Core service. In a few clicks, you can configure variables and their update frequency to be published to the AWS Cloud. To get started with the LOGO! controller, please refer to Siemens E-learning portal. AWS IoT Core collects and processes messages from remote devices transmitted over the secured MQTT protocol.

The LOGO! controller publishes data to AWS IoT Core in hexadecimal format. The Lambda function converts the data from hexadecimal to the standard decimal numeric system. If your home automation equipment sends data in the standard decimal format, then AWS IoT Core can directly write data to other AWS services without Lambda.

Step 2: Store data in Timestream or AWS IoT SiteWise

The ingested IoT data is saved for historical analysis. Timestream is a serverless time series database service that is optimized for high throughput ingestion and has built-in analytical functions. It is one of the options you can use to store IoT data. Time series is a common data format to observe how things are changing over time and it is suitable for building IoT applications.

AWS IoT SiteWise is an alternative option to store and organize data at scale. It is beneficial for large-scale commercial building automation and management systems, including offices, hotels, and factories. You can structure data by using built-in asset modeling capabilities.

Step 3: Visualize data in Grafana dashboard

Once data is stored, it can be made available to multiple applications. Grafana is a data visualization platform that you can use to monitor data. It supports near real-time visualization with a refresh rate of 5 seconds or higher. You can visualize data from multiple AWS sources (such as AWS IoT SiteWise, Timestream, and Amazon CloudWatch) and other data sources with a single Grafana dashboard. Grafana can be installed on an Amazon Linux system, Windows, macOS, or deployed on Kubernetes (K8S) or Docker containers. For customers who don’t want to manage infrastructure and are interested in developing completely serverless solution, Amazon offers an Amazon Managed Service for Grafana. At the time of writing this post, this service is available in preview with a limited number of supported plugins.

To build Grafana dashboard and retrieve data from Timestream, you can use SQL queries. Timestream query example to retrieve humidity values and timestamps for the past 24 hours:

SELECT measure_value::double as humidity, time FROM "myhome_db"."livingroom" WHERE measure_name='humidity' and time >=ago(1d)

To retrieve data from AWS IoT SiteWise, you can select asset properties from the asset navigation tab, which makes it simple for non-technical users to build dashboards.

Figure 4. Grafana dashboard configuration with AWS IoT SiteWise

One of the common issues of operational dashboards is that it’s hard to get a physical representation by looking at a cluster of multiple readings. To reflect conditions of physical assets, the information from sensors must be overlaid on top of original physical objects. ImageIt Panel Plugin for Grafana allows you to overcome this issue. You can upload a picture of your house or a system and drag sensor readings to their exact locations, thus creating digital representations of physical objects.

Step 4: Control using Alexa

Using the Alexa Skills Kit, you can build voice skills to be used on devices enabled by Alexa globally. Alexa and AWS IoT enables you to create an end-to-end voice-controlled experience without using any additional hardware. Instead, your functions run on the cloud only when you invoke Alexa with voice commands.

The easiest way to build a custom Alexa skill is to use a Lambda function. You can upload the code for your Alexa skill to a Lambda function. The code will execute in response to Alexa voice interactions and send commands to the LOGO! controller.

Conclusion

In this blog, we reviewed how you can create a digital twin of your home automation or industrial systems using Siemens controllers, AWS IoT, and Grafana dashboards. Connecting the LOGO! controller to AWS gives it access to the Internet of Things (IoT) and opens many potential applications such as anomaly detection, predictive maintenance, intrusion detection, and others.

Building well-architected serverless applications: Building in resiliency – part 1

2021-08-03 Julian Wood

Post Syndicated from Julian Wood original https://aws.amazon.com/blogs/compute/building-well-architected-serverless-applications-building-in-resiliency-part-1/

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

Reliability question REL2: How do you build resiliency into your serverless application?

Evaluate scaling mechanisms for serverless and non-serverless resources to meet customer demand. Build resiliency into your workload to make your serverless application resilient to withstand partial and intermittent failures across components that may only surface in production.

Required practice: Manage transaction, partial, and intermittent failures

Whenever one service or system calls another, there is a chance that failures can happen. Services or systems often don’t fail as a single unit, but rather suffer partial or transient failures. Applications should be designed to handle component failures as part of the architecture. The system should be designed to detect failure and, ideally, automatically heal itself.

Transaction failures can occur when a component is unavailable or under high load. Partial failures can occur when a percentage of requests succeeds, including during batch processing. Intermittent failures might occur when a request fails for a short period of time due to network or other transient issues.

AWS serverless services, including AWS Lambda, are fault-tolerant and designed to handle failures. If a service invokes a Lambda function and there is a service disruption, Lambda invokes the function in a different Availability Zone.

When you invoke a function directly, you determine the strategy for handling errors. You can retry, send the event to a destination or queue for debugging, or ignore the error. Clients such as the AWS Command Line Interface (CLI) and the AWS SDK retry on client timeouts, throttling errors (429), and other errors that are not caused by a bad request.

When you invoke a function indirectly, you must be aware of the retry behavior of the invoker and any service that the request encounters along the way. For more information, see “Error handling and automatic retries in AWS Lambda”. You can configure Maximum Retry Attempts and Maximum Event Age for asynchronous invocations.

When reading from Amazon Kinesis Data Streams and Amazon DynamoDB Streams, Lambda retries the entire batch of items. Retries continue until the records expire or exceed the maximum age that you configure on the event source mapping. You can also configure the event source mapping to split a failed batch into two batches. Retrying with smaller batches isolates bad records and works around timeout issues.

Partial failures can occur in non-atomic operations. PutRecords for Kinesis and BatchWriteItem for DynamoDB return a successful response if at least one record is ingested successfully. Always inspect the response when using such operations and programmatically deal with partial failures.

Use exponential backoff with jitter

The simplest technique for dealing with failures in a networked environment is to retry calls until they succeed. This technique increases the reliability of the application and reduces operational costs for the developer.

However, it is not always safe to retry. A retry can further increase the load on the system being called if the system is already failing due to an overload. To avoid this problem, use backoff. Instead of retrying immediately and aggressively, the client waits some amount of time between tries. The most common pattern is an exponential backoff, which uses exponentially longer wait times between retries. This is typically capped to a maximum delay and number of retries.

If all backoff retries are still happening at the same time, this can still overload a system or cause contention. To avoid this problem, use jitter. Jitter adds some amount of randomness to the backoff to spread the retries around in time. This can help prevent large bursts by spreading out the rate when clients connect. For more information see the Amazon Builders’ Library article “Timeouts, retries, and backoff with jitter” and AWS Architecture blog post “Exponential Backoff And Jitter”.

Exponential backoff and jitter

When your application responds to callers in fail-fast scenarios and when performance is degraded, inform the caller via headers or metadata when they can retry.

Each AWS SDK implements automatic retry logic including exponential backoff. For downstream calls, you can adjust AWS and third-party SDK retries, backoffs, TCP, and HTTP timeouts. This helps you decide when to stop retrying. For more information, see the documentation and troubleshooting steps for Lambda and the AWS SDK.

Use a dead-letter queue mechanism to retain, investigate and retry failed transactions

There are a number of ways to handle message failures including destinations and dead-letter queues.

You can configure Lambda to send records of asynchronous invocations to another destination service. These include Amazon Simple Queue Service (SQS), Amazon Simple Notification Service (SNS), Lambda, and Amazon EventBridge. You can configure separate destinations for events that fail processing and events that are successfully processed. The invocation record contains details about the event, the response, and the reason that the record was sent.

The following example shows a function that sends a record of a successful invocation to an EventBridge event bus. When an event fails all processing attempts, Lambda sends an invocation record to an SQS queue. It includes the function’s response in the invocation record.

AWS Lambda destinations for asynchronous invocation

SNS, SQS, Lambda, and EventBridge support dead-letter queues (DLQs). DLQs make your applications more resilient and durable by storing messages or events that can’t be processed correctly into a dedicated SQS queue. This helps you debug your application by isolating the problematic messages to determine why their processing failed. One you have resolved the issue, re-process the failed message. For more information, see “When should I use a dead-letter queue?” There is an example serverless application to redrive the messages from an SQS DLQ back to its source SQS queue.

For Lambda, DLQs provide an alternative to a failure destination. Lambda destinations is preferable for asynchronous invocations.

Good practice: Orchestrate long-running transactions

Long-running transactions can be processed by one or multiple components. Consider implementing the saga pattern using state machines for these types of transactions.

The saga pattern coordinates transactions between multiple microservices as part of a state machine. Each service that performs a transaction publishes an event to trigger the next transaction in the saga. This continues until the transaction chain is complete. If a transaction fails, saga orchestrates a series of compensating transactions that undo the changes that were made by the preceding transactions.

This is preferable to handling complex or long-running transactions within application code. State machines prevent cascading failures and avoid tightly coupling components with orchestrating logic and business logic.

Use a state machine to visualize distributed transactions, and to separate business logic from orchestration logic.

AWS Step Functions lets you coordinate multiple AWS services into serverless workflows via state machines. Within Step Functions, you can set separate retries, backoff rates, max attempts, intervals, and timeouts. These are set for every step of your state machine using a declarative language.

In the serverless airline example used in this series, Step Functions is used to orchestrate the Booking microservice. The ProcessBooking state machine handles all the necessary steps to create bookings, including payment.

Booking service Step Functions state machine

The state machine uses a combination of service integrations using DynamoDB, SQS, and Lambda functions to coordinate transactions and handle failures.

For example, the Reserve Booking task invokes a Lambda function. The task has retry and error handling configured as part of the task definition.

"Reserve Booking": {
	"Type": "Task",
	"Resource": "${ReserveBooking.Arn}",
	"TimeoutSeconds": 5,
	"Retry": [
		{
			"ErrorEquals": [
				"BookingReservationException"
			],
			"IntervalSeconds": 1,
			"BackoffRate": 2,
			"MaxAttempts": 2
		}
	],
	"Catch": [
		{
			"ErrorEquals": [
				"States.ALL"
			],
			"ResultPath": "$.bookingError",
			"Next": "Cancel Booking"
		}
	],
	"ResultPath": "$.bookingId",
	"Next": "Collect Payment"
},

Step Functions supports direct service integrations, including DynamoDB. The Reserve Flight task directly updates the flightTable without requiring a Lambda function.

"Reserve Flight": {
	"Type": "Task",
	"Resource": "arn:aws:states:::dynamodb:updateItem",
	"Parameters": {
		"TableName.$": "$.flightTable",
		"Key": {
			"id": {
				"S.$": "$.outboundFlightId"
			}
		},
		"UpdateExpression": "SET seatCapacity = seatCapacity - :dec",
		"ExpressionAttributeValues": {
			":dec": {
				"N": "1"
			},
			":noSeat": {
				"N": "0"
			}
		},
		"ConditionExpression": "seatCapacity > :noSeat"
	},

By default, when a state reports an error, Step Functions causes the execution to fail entirely.

Utilize dead-letter queues in response to failed state machine executions

Any state within the Step Functions workflow can encounter runtime errors. These include state machine definition issues, task failures such as Lambda function exceptions, or transient issues such as network connectivity issues. For more information, see “Error handling in Step Functions”.

Use the Step Functions service integration with SQS to send failed transactions to a DLQ as the final step. This adds a higher level of durability within your state machines.

For example, the airline Notify Failed Booking final task catches failed states from four previous steps. It sends the results to the Booking DLQ.

Booking service Step Functions DLQ

The message includes the output of the previous failed states for further troubleshooting.

"Booking DLQ": {
	"Type": "Task",
	"Resource": "arn:aws:states:::sqs:sendMessage",
	"Parameters": {
		"QueueUrl": "${BookingsDLQ}",
		"MessageBody.$": "$"
	},
	"ResultPath": "$.deadLetterQueue",
	"Next": "Booking Failed"
},

The Step Functions documentation has more information on calling SQS.

Conclusion

Build resiliency into your workloads. This makes sure that your application can withstand partial and intermittent failures across components that may only surface in production.

In this post, I cover managing failures using retries, exponential backoff, and jitter. I explain how DLQs can isolate failed messages. I show how to use state machines to orchestrate long running transactions rather than handling these in application code.

This well-architected question continues in part 2 where I look at managing duplicate and unwanted events with idempotency and an event schema. I cover how to consider scaling patterns at burst rates by managing account limits and show relevant metrics to evaluate.

For more serverless learning resources, visit Serverless Land.

Expiring Amazon S3 Objects Based on Last Accessed Date to Decrease Costs

2021-08-03 Hareesh Singireddy

Post Syndicated from Hareesh Singireddy original https://aws.amazon.com/blogs/architecture/expiring-amazon-s3-objects-based-on-last-accessed-date-to-decrease-costs/

Organizations are using Amazon Simple Storage Service (S3) for building their data lakes, websites, mobile applications, and enterprise applications. As the number of objects within your S3 bucket increases, you may want to move older objects into lower-cost tiers of Amazon S3. In some cases you may want to delete the objects altogether to further reduce S3 storage costs. A common practice is to use S3 Lifecycle rules to achieve this. These rules can be applied to objects based on their creation date. In certain situations, you may want to keep objects available that are still being accessed, but transition or delete objects that are no longer in use.

In this post, we will demonstrate how you can create custom object expiry rules for Amazon S3 based on the last accessed date of the object. We will first walk through the various features used within the workflow, followed by an architecture diagram outlining the process flow.

Amazon S3 server access logging

S3 Server access logging provides detailed records of the requests that are made to objects in Amazon S3 buckets. Amazon S3 periodically collects access log records, consolidates the records in log files, and then uploads log files to your target bucket as log objects. Each log record consists of information such as bucket name, the operation in the request, and the time at which the request was received. S3 Server Access Log Format provides more details about the format of the log file.

Amazon S3 inventory

Amazon S3 inventory provides a list of your objects and the corresponding metadata on a daily or weekly basis, for an S3 bucket or a shared prefix. The inventory lists are stored as a comma-separated value (CSV) file compressed with GZIP, as an Apache optimized row columnar (ORC) file compressed with ZLIB, or as an Apache Parquet file compressed with Snappy.

Amazon S3 Lifecycle

Amazon S3 Lifecycle policies help you manage your objects through two types of actions, Transition and Expiration. In the architecture shown following in Figure 1, we create an S3 Lifecycle configuration rule that expires objects after ‘x’ days. It has a filter for an object tag of “delete=True”. You can configure the value of ‘x’ based on your requirements.

If you are using an S3 bucket to store short lived objects with unknown access patterns, you might want to keep the objects that are still being accessed, but delete the rest. This will let you retain objects in your S3 bucket even after their expiry date as per the S3 lifecycle rules, while saving you costs by deleting objects that are not needed anymore. The following diagram shows an architecture that considers the last accessed date of the object before deleting S3 objects.

Figure 1. Object expiry architecture flow

This architecture uses native S3 features mentioned earlier in combination with other AWS services to achieve the desired outcome.

Here is the architecture flow:

The S3 server access logs capture S3 object requests. These are generated and stored in the target S3 bucket.
An S3 inventory report is generated for the source bucket daily. It is written to the S3 inventory target bucket.
An Amazon EventBridge rule is configured that will initiate an AWS Lambda function once a day, or as desired.
The Lambda function initiates an S3 Batch Operation job to tag objects in the source bucket. These must be expired using the following logic:
- Capture the number of days (x) configuration from the S3 Lifecycle configuration.
- Run an Amazon Athena query that will get the list of objects from the S3 inventory report and server access logs. Create a delta list with objects that were created earlier than ‘x’ days, but not accessed during that time.
- Write a manifest file with the list of these objects to an S3 bucket.
- Create an S3 Batch operation job that will tag all objects in the manifest file with a tag of “delete=True”.
The Lifecycle rule on the source S3 bucket will expire all objects that were created prior to ‘x’ days. They will have the tag given via the S3 batch operation of “delete=True”.

The preceding architecture is built for fault tolerance. If a particular run fails, all the objects that must be expired will be picked up during the next run. You can configure error handling and automatic retries in your Lambda function. An Amazon Simple Notification Service (SNS) topic will send out a notification in the event of a failure.

Cost considerations

S3 server access logs, S3 inventory lists, and manifest files can accumulate many objects over time. We recommend you configure an S3 Lifecycle policy on the target bucket to periodically delete older objects. Although following the guidelines in this post can decrease some of your costs, S3 requests, S3 inventory, S3 Object Tagging, and Lifecycle transitions also have costs associated with them. Additional details can be found on the S3 pricing page.

Amazon Athena charges you based on the amount of data scanned by each query. But Amazon S3 inventory can also output files in Apache ORC or Apache Parquet format, which can reduce the amount data scanned by Athena. The Athena pricing page would be helpful to review.

AWS Lambda has a free usage tier of 1M free requests per month and 400,000 GB-seconds of compute time per month. However, you are charged based on the number of requests, the amount of memory allocated, and the runtime duration of the function. See more at the Lambda pricing page.

Conclusion

In this blog post, we showed how you can create a custom process to delete objects from your S3 bucket based on the last time the object was accessed. You can use this architecture to customize your object transitions, clean up your S3 buckets for any unnecessary objects, and keep your S3 buckets cost-effective. This architecture can also be used on versioned S3 buckets with some minor modifications.

We hope you found this blog post useful and welcome your feedback!

Read more about queries, rules, and tags:

Insights for CTOs: Part 1 – Building and Operating Cloud Applications

2021-08-02 Syed Jaffry

Post Syndicated from Syed Jaffry original https://aws.amazon.com/blogs/architecture/insights-for-ctos-part-1-building-and-operating-cloud-applications/

This 6-part series shares insights gained from various CTOs during their cloud adoption journeys at their respective organizations. This post takes those learnings and summarizes architecture best practices to help you build and operate applications successfully in the cloud. This series will also cover topics on cloud financial management, security, modern data and artificial intelligence (AI), cloud operating models, and strategies for cloud migration.

Optimize cost and performance with AWS services

Your technology costs vs. return on investment (ROI) is likely being constantly evaluated. In the cloud, you “pay as you go.” This means your technology spend is an operational cost rather than capital expenditure, as discussed in Part 3: Cloud economics – OPEX vs. CAPEX.

So, how do you maximize the ROI of your cloud spend? The following sections provide hosting options and to help you choose a hosting model that best suits your needs.

Evaluating your hosting options

EC2 instances and the lift and shift strategy

Using cloud native dynamic provisioning/de-provisioning of Amazon Elastic Compute Cloud (Amazon EC2) instances will help you meet business needs more accurately and optimize compute costs. EC2 instances allow you to use the “lift and shift” migration strategy for your applications. This helps you avoid overhead costs you may incur from upfront capacity planning.

Figure 1. Comparing on-premises vs. cloud infrastructure provisioning

Containerized hosting (with EC2 hosts)

Engineering teams already skilled in containerized hosting have saved additional costs by using Amazon Elastic Kubernetes Service (Amazon EKS) or Amazon Elastic Container Service (Amazon ECS). This is because your unit of deployment is a container instead of an entire instance, and Amazon EKS or Amazon ECS can pack multiple containers into a single instance. Application change management is also less risky because you can leverage Amazon EKS or Amazon ECS built-in orchestration to manage non-disruptive deployments.

Serverless architecture

Use AWS Lambda and AWS Fargate to scale to match unpredictable usage. We have seen AWS software as a service (SaaS) customers build better measures of “cost per user” of an application into their metering systems using serverless. This is because instead of paying for server uptime, you only pay for runtime usage (down to millisecond increments for Lambda) when you run your application.

Further considerations for choosing the right hosting platform

The following table provides considerations for implementing the most cost-effective model for some use cases you may encounter when building your architecture:

Building a cloud operating model and managing risk

Building an effective people, governance, and platform capability is summarized in the following sections and discussed in detail in Part 5: Organizing teams to enable effective build/run/manage.

People

If your team only builds applications on virtual machines, asking them to move to the cloud serverless model without sufficiently training them could go poorly. We suggest starting small. Select a handful of applications that have lower risk yet meaningful business value and allow your team to build their cloud “muscles.”

Governance

If your teams don’t have the “muscle memory” to make cloud architecture decisions, build a Cloud Center of Excellence (CCOE) to enforce a consistent approach to building in the cloud. Without this team, managing cost, security, and reliability will be harder. Ask the CCOE team to regularly review the application architecture suitability (cost, performance, resiliency) against changing business conditions. This will help you incrementally evolve architecture as appropriate.

Platform

In a typical on-premises environment, changes are deployed “in-place.” This requires a slow and “involve everyone” approach. Deploying in the cloud replaces the in-place approach with blue/green deployments, as shown in Figure 2.

With this strategy, new application versions can be deployed on new machines (green) running side by side with the old machines (blue). Once the new version is validated, switch traffic to the new (green) machines and they become production. This model reduces risk and increases velocity of change.

Figure 2. AWS blue/green deployment model

Securing your application and infrastructure

Security controls in the cloud are defined and enforced in software, which brings risks and opportunities. If not managed with a robust change management process, software-defined firewall misconfiguration can create unexpected threat vectors.

To avoid this, use cloud native patterns like “infrastructure as code” that express all infrastructure provisioning and configuration as declarative templates (JSON or YAML files). Then apply the same “Git pull request” process to infrastructure change management as you do for your applications to enforce strong governance. Use tools like AWS CloudFormation or AWS Cloud Development Kit (AWS CDK) to implement infrastructure templates into your cloud environment.

Apply a layered security model (“defense in depth”) to your application stack, as shown in Figure 3, to prevent against distributed denial of service (DDoS) and application layer attacks. Part 2: Protecting AWS account, data, and applications provides a detailed discussion on security.

Figure 3. Defense in depth

Data stores

How many is too many?

In on-premises environments, it is typically difficult to provision a separate database per microservice. As a result, the application or microservice isolation stops at the compute layer, and the database becomes the key shared dependency that slows down change.

The cloud provides API instantiable, fully managed databases like Amazon Relational Database Service (Amazon RDS) (SQL), Amazon DynamoDB (NoSQL), and others. This allows you to isolate your application end to end and create a more resilient architecture. For example, in a cell-based architecture where users are placed into self-contained, isolated application stack “cells,” the “blast radius” of an impact, such as application downtime or user experience degradation, is limited to each cell.

Database engines

Relational databases are typically the default starting point for many organizations. While relational databases offer speed and flexibility to bootstrap a new application, they bring complexity when you need to horizontally scale.

Your application needs will determine whether you use a relational or non-relational database. In the cloud, API instantiated, fully managed databases give you options to closely match your application’s use case. For example, in-memory databases like Amazon ElastiCache reduce latency for website content and key-value databases like DynamoDB provide a horizontally scalable backend for building an ecommerce shopping cart.

Summary

We acknowledge that CTO responsibilities can differ among organizations; however, this blog discusses common key considerations when building and operating an application in the cloud.

Choosing the right application hosting platform depends on your application’s use case and can impact the operational cost of your application in the cloud. Consider the people, governance, and platform aspects carefully because they will influence the success or failure of your cloud adoption. Use lower risk application deployment patterns in the cloud. Managed data stores in the cloud open your choice for data stores beyond relational. In the next post of this series, Part 2: Protecting AWS account, data, and applications, we will explore best practices and principles to apply when thinking about security in the cloud.

Related information

Part 2: Protecting AWS account, data and applications
Part 3: Cloud economics – OPEX vs CAPEX
Part 4: Building a modern data platform for AI
Part 5: Organizing teams to enable effective build/run/manage
Part 6: Strategies and lessons on migrating workloads to the cloud

Benefits of Modernizing On-premise Analytics with an AWS Lake House

2021-07-30 Vikas Nambiar

Post Syndicated from Vikas Nambiar original https://aws.amazon.com/blogs/architecture/benefits-of-modernizing-on-premise-analytics-with-an-aws-lake-house/

Organizational analytics systems have shifted from running in the background of IT systems to being critical to an organization’s health.

Analytics systems help businesses make better decisions, but they tend to be complex and are often not agile enough to scale quickly. To help with this, customers upgrade their traditional on-premises online analytic processing (OLAP) databases to hyper converged infrastructure (HCI) solutions. However, these systems incur operational overhead, are limited by proprietary formats, have limited elasticity, and tie customers into costly and inhibiting licensing agreements. These all bind an organization’s growth to the growth of the appliance provider.

In this post, we provide you a reference architecture and show you how an AWS lake house will help you overcome the aforementioned limitations. Our solution provides you the ability to scale, integrate with multiple sources, improve business agility, and help future proof your analytics investment.

High-level architecture for implementing an AWS lake house

Lake house architecture uses a ring of purpose-built data consumers and services centered around a data lake. This approach acknowledges that a one-size-fits-all approach to analytics eventually leads to compromises. These compromises can include agility associated with change management and impact of different business domain reporting requirements on the data from a central platform. As such, simply integrating a data lake with a data warehouse is not sufficient.

Each step in Figure 1 needs to be de-coupled to build a lake house.

Figure 1. Data flow in a lake house

Figure 2. High-level design for an AWS lake house implementation

Building a lake house on AWS

These steps summarize building a lake house on AWS:

Identify source system extraction capabilities to define an ingestion layer that loads data into a data lake.
Build data ingestion layer using services that support source systems extraction capabilities.
Build a governance and transformation layer to manipulate data.
Provide capability to consume and visualize information via purpose-built consumption/value layer.

This lake house architecture provides you a de-coupled architecture. Services can be added, removed, and updated independently when new data sources are identified like data sources to enrich data via AWS Data Exchange. This can happen while services in the purpose-built consumption layer address individual business unit requirements.

Building the data ingestion layer

Services in this layer work directly with the source systems based on their supported data extraction patterns. Data is then placed into a data lake.

Figure 3 shows the following services to be included in this layer:

AWS Transfer Family for SFTP integrates with source systems to extract data using secure shell (SSH), SFTP, and FTPS/FTP. This service is for systems that support batch transfer modes and have no real-time requirements, such as external data entities.
AWS Glue connects to real-time data streams to extract, load, transform, clean, and enrich data.
AWS Database Migration Service (AWS DMS) connects and migrates data from relational databases, data warehouses, and NoSQL databases.

Figure 3. Ingestion layer against source systems

Services in this layer are managed services that provide operational excellence by removing patching and upgrade overheads. Being managed services, they will also detect extraction spikes and scale automatically or on-demand based on your specifications.

Building the data lake layer

A data lake built on Amazon Simple Storage Service (Amazon S3) provides the ideal target layer to store, process, and cycle data over time. As the central aspect of the architecture, Amazon S3 allows the data lake to hold multiple data formats and datasets. It can also be integrated with most if not all AWS services and third-party applications.

Figure 4 shows the following services to be included in this layer:

Amazon S3 acts as the data lake to hold multiple data formats.
Amazon S3 Glacier provides the data archiving and long-term backup storage layer for processed data. It also reduces the amount of data indexed by transformation layer services.

Figure 4. Data lake integrated to ingestion layer

The data lake layer provides 99.999999999% data durability and supports various data formats, allowing you to future proof the data lake. Data lakes on Amazon S3 also integrate with other AWS ecosystem services (for example, AWS Athena for interactive querying or third-party tools running off Amazon Elastic Compute Cloud (Amazon EC2) instances).

Defining the governance and transformation layer

Services in this layer transform raw data in the data lake to a business consumable format, along with providing operational monitoring and governance capabilities.

Figure 5 shows the following services to be included in this layer:

AWS Glue discovers and transforms data, making it available for search and querying.
Amazon Redshift (Transient) functions as an extract, transform, and load (ETL) node using RA3 nodes. RA3 nodes can be paused outside ETL windows. Once paused, Amazon Redshift’s data sharing capability allows for live data sharing for read purposes, which reduces costs to customers. It also allows for creation of separate, smaller read-intensive business intelligence (BI) instances from the larger write-intensive ETL instances required during ETL runs.
Amazon CloudWatch monitors and observes your enabled services. It integrates with existing IT service management and change management systems such as ServiceNow for alerting and monitoring.
AWS Security Hub implements a single security pane by aggregating, organizing, and prioritizing security alerts from services used, such as Amazon GuardDuty, Amazon Inspector, Amazon Macie, AWS Identity and Access Management (IAM) Access Analyzer, AWS Systems Manager, and AWS Firewall Manager.
Amazon Managed Workflows for Apache Airflow (MWAA) sequences your workflow events to ingest, transform, and load data.
Amazon Lake Formation standardizes data lake provisioning.
AWS Lambda runs custom transformation jobs if required, or developed over a period of time that hold custom business logic IP.

Figure 5. Governance and transformation layer prepares data in the lake

This layer provides operational isolation wherein least privilege access control can be implemented to keep operational staff separate from the core services. It also lets you implement custom transformation tasks using Lambda. This allows you to consistently build lakes across all environments and single view of security via AWS Security Hub.

Building the value layer

This layer generates value for your business by provisioning decoupled, purpose-built visualization services, which decouples business units from change management impacts of other units.

Figure 6 shows the following services to be included in this value layer:

Amazon Redshift (BI cluster) acts as the final store for data processed by the governance and transformation layer.
Amazon Elasticsearch Service (Amazon ES) conducts log analytics and provides real-time application and clickstream analysis, including for data from previous layers.
Amazon SageMaker prepares, builds, trains, and deploys machine learning models that provide businesses insights on possible scenarios such as predictive maintenance, churn predictions, demand forecasting, etc.
Amazon QuickSight acts as the visualization layer, allowing business and support resources users to create reports, dashboards accessible across devices and embedded into other business applications, portals, and websites.

Figure 6. Value layer with services for purpose-built consumption

Conclusion

By using services managed by AWS as a starting point, you can build a data lake house on AWS. This open standard based, pay-as-you-go data lake will help future proof your analytics platform. With the AWS data lake house architecture provided in this post, you can expand your architecture, avoid excessive license costs associated with proprietary software and infrastructure (along with their ongoing support costs). These capabilities are typically unavailable in on-premises OLAP/HCI based data analytics platforms.

Related information

Build a Virtual Waiting Room with Amazon DynamoDB and AWS Lambda at SeatGeek

2021-07-29 Umesh Kalaspurkar

Post Syndicated from Umesh Kalaspurkar original https://aws.amazon.com/blogs/architecture/build-a-virtual-waiting-room-with-amazon-dynamodb-and-aws-lambda-at-seatgeek/

As retail sales, products, and customers continue to expand online, we’ve seen a trend towards releasing products in limited quantities to larger audiences. Demand of these products can be high, due to limited production capacity, venue capacity limits, or product exclusivity. Providers can then experience spikes in transaction volume, especially when multiple event sales occur simultaneously. This increased traffic and load can negatively impact customer experience and infrastructure.

To enhance the customer experience when releasing tickets to high demand events, SeatGeek has introduced a prioritization and queueing mechanism based on event type, venue, and customer type. For example, Dallas Cowboys’ tickets could have a different priority depending on seat type, or whether it’s a suite or a general admission ticket.

SeatGeek previously used a third-party waiting room solution, but it presented a number of shortcomings:

Lack of configuration and customization capabilities
More manual process that resulted in limiting the number of concurrent events could be set up
Inability to capture custom insights and metrics (for example, how long was the customer waiting in the queue before they dropped?)

Resolving these issues is crucial to improve the customer experience and audience engagement. SeatGeek decided to build a custom solution on AWS, in order to create a more robust system and address these third-party issues.

Virtual Waiting Room overview

Our solution redirects overflow customers waiting to complete their purchase to a separate queue. Personalized content is presented to improve the waiting experience. Public services such as school or voting registration can use this solution for limited spots or time slot management.

Figure 1. User path through a Virtual Waiting Room

During a sale event, all customers begin their purchase journey in the Virtual Waiting Room (see Figure 1). When the sale starts, they will be moved from the Virtual Waiting Room to the ticket selection page. This is referred to as the Protected Zone. Here is where the customer will complete their purchase. The Protected Zone is a group of customized pages that guide the user through the purchasing process.

When the virtual waiting room is enabled, it can operate in three modes: Waiting Room mode, Queueing mode, or a combination of the two.

In Waiting Room mode, any request made to an event ticketing page before the designated start time of sale is routed to a separate screen. This displays the on-sale information and other marketing materials. At the desired time, users are then routed to the event page at a predefined throughput rate. Figure 2 shows a screenshot of the Waiting Room mode:

Figure 2. Waiting Room mode

In Queueing mode, the event can be configured to allow a preset number of concurrent users to access the Protected Zone. Those beyond that preconfigured number wait in a First-In-First-Out (FIFO) queue. Exempt users, such as the event coordinator, can bypass the queue for management and operational visibility.

Figure 3. Queueing mode flow

Figure 4. Queueing mode

In some cases, the two modes can work together sequentially. This can occur when the Waiting Room mode is used before a sale starts and the Queueing mode takes over to control flow.

Once the customers move to the front of the queue, they are next in line for the Protected Zone. A ticket selection page, shown in Figure 5, must be protected from an overflow of customers, which could result in overselling.

Figure 5. Ticket selection page

Virtual Waiting Room implementation

In the following diagram, you can see the AWS services and flow that SeatGeek implemented for the Virtual Waiting Room solution. When a SeatGeek customer requests a protected resource like a concert ticket, a gate keeper application scans to see if the resource has an active waiting room. It also confirms if the configuration rules are satisfied in order to grant the customer access. If the customer isn’t allowed access to the protected resource for whatever reason, then that customer is redirected to the Virtual Waiting Room.

Figure 6. Architecture overview

SeatGeek built this initial iteration of the gate keeper service on Fastly’s [email protected] service to leverage its existing content delivery network (CDN) investment. However, similar functionality could be built using Amazon CloudFront and AWS [email protected].

The Bouncer, handling the user flow into either the protected zone or the waiting room, consists of 3 components – Amazon API Gateway, AWS Lambda, and a Token Service. The token service is at the heart of the Waiting Room’s core logic. Before a concert event sale goes live at SeatGeek, the number of access tokens generated is equivalent to the number of available tickets. The order of assigning access tokens to customers in the waiting room can be based on FIFO or customer status (VIP customers first). Tokens are allocated when the customer is admitted to the waiting room and expire when tickets are purchased or when the customer exits.

For data storage, SeatGeek uses Amazon DynamoDB to monitor protected resources, tokens, and queues. The key tables are:

Protected Zone table: This table contains metadata about available protected zones
Counters table: Monitors the number of access tokens issued per minute for a specific protected zone
User Connection table: Every time a customer connects to the Amazon API Gateway, a record is created in this table recording their visitor token and connection ID using AWS Lambda
Queue table: This is the main table where the visitor token to access token mapping is saved

For analytics, two types of metrics are captured to ensure operational integrity:

System metrics: These are built into the AWS runtime infrastructure, and are stored in Amazon CloudWatch. These metrics provide telemetry of each component of the solution: Lambda latency, DynamoDB throttle (read and write), API Gateway connections, and more.
Business metrics: These are used to understand previous user behavior to improve infrastructure provisioning and user experiences. SeatGeek uses an AWS Lambda function to capture metrics from data in a DynamoDB stream. It then forwards it to Amazon Timestream for time-based analytics processing. Metrics captured include queue length, waiting time per queue, number of users in the protected zone, and more.

For historical needs, long-lived data can be streamed to tiered data storage options such as Amazon Simple Storage Service (S3). They can then be used later for other purposes, such as auditing and data analysis.

Considerations and enhancements for the Virtual Waiting Room

Tokens: We recommend using first-party cookies and token confirmations to track the number of sessions. Use the same token at the same time to stop users from checking out multiple times and cutting in line.
DDoS protection: Token and first-party cookies usage must also comply with General Data Protection Regulation (GDPR) and California Consumer Privacy Act (CCPA) guidelines depending on the geographic region. This system is susceptible to DDoS attacks, XSS attacks, and others, like any web-based solution. But these threats can be mitigated by using AWS Shield, a DDoS protection service, and AWS WAF – Web Application Firewall. For more information on DDoS protection, read this security blog post.
Marketing: Opportunities to educate the customer about the venue or product(s) while they wait in the Virtual Waiting Room (for example, parking or food options).
Alerts: Customers can be alerted via SMS or voice when their turn is up by using Amazon Pinpoint as a marketing communication service.

Conclusion

We have shown how to set up a Virtual Waiting Room for your customers. This can be used to improve the customer experience while they wait to complete their registration or purchase through your website. The solution takes advantage of several AWS services like AWS Lambda, Amazon DynamoDB, and Amazon Timestream.

While this references a retail use case, the waiting room concept can be used whenever throttling access to a specific resource is required. It can be useful during an infrastructure or application outage. You can use it during a load spike, while more resources (EC2 instances) are being launched. To block access to an unreleased feature or product, temporarily place all users in the waiting room and let them in as needed per your own configuration.

Providing a friendly, streamlined, and responsive user experience, even during peak load times, is a valuable way to keep existing customers and gain new ones.

Be mindful that there are costs associated with running these services. To be cost-efficient, see the following pages for details: AWS Lambda, Amazon S3, Amazon DynamoDB, Amazon Timestream.

Building a serverless multiplayer game that scales: Part 2

2021-07-29 James Beswick

Post Syndicated from James Beswick original https://aws.amazon.com/blogs/compute/building-a-serverless-multiplayer-game-that-scales-part-2/

This post is written by Vito De Giosa, Sr. Solutions Architect and Tim Bruce, Sr. Solutions Architect, Developer Acceleration.

This series discusses solutions for scaling serverless games, using the Simple Trivia Service, a game that relies on user-generated content. Part 1 describes the overall architecture, how to deploy to your AWS account, and different communications methods.

This post discusses how to scale via automation and asynchronous processes. You can use automation to minimize the need to scale personnel to review player-generated content for acceptability. It also introduces asynchronous processing, which allows you to run non-critical processes in the background and batch data together. This helps to improve resource usage and game performance. Both scaling techniques can also reduce overall spend.

To set up the example, see the instructions in the GitHub repo and the README.md file. This example uses services beyond the AWS Free Tier and incurs charges. Instructions to remove the example application from your account are also in the README.md file.

Technical implementation

Games require a mechanism to support auto-moderated avatars. Specifically, this is an upload process to allow the player to send the content to the game. There is a content moderation process to remove unacceptable content and a messaging process to provide players with a status regarding their content.

Here is the architecture for this feature in Simple Trivia Service, which is combined within the avatar workflow:

This architecture processes images uploaded to Amazon S3 and notifies the user of the processing result via HTTP WebPush. This solution uses AWS Serverless services and the Amazon Rekognition moderation API.

Uploading avatars

Players start the process by uploading avatars via the game client. Using presigned URLs, the client allows players to upload images directly to S3 without sharing AWS credentials or exposing the bucket publicly.

The URL embeds all the parameters of the S3 request. It includes a SignatureV4 generated with AWS credentials from the backend allowing S3 to authorize the request.

The front end retrieves the presigned URL invoking an AWS Lambda function through an Amazon API Gateway HTTP API endpoint.
The front end uses the URL to send a PUT request to S3 with the image.

Processing avatars

After the upload completes, the backend performs a set of activities. These include content moderation, generating the thumbnail variant, and saving the image URL to the player profile. AWS Step Functions orchestrates the workflow by coordinating tasks and integrating with AWS services, such as Lambda and Amazon DynamoDB. Step Functions enables creating workflows without writing code and handles errors, retries, and state management. This enables traffic control to avoid overloading single components when traffic surges.

The avatar processing workflow runs asynchronously. This allows players to play the game without being blocked and enables you to batch the requests. The Step Functions workflow is triggered from an Amazon EventBridge event. When the user uploads an image to S3, an event is published to EventBridge. The event is routed to the avatar processing Step Functions workflow.

The single avatar feature runs in seconds and uses Step Functions Express Workflows, which are ideal for high-volume event-processing use cases. Step Functions can also support longer running processes and manual steps, depending on your requirements.

To keep performance at scale, the solution adopts four strategies. First, it moderates content automatically, requiring no human intervention. This is done via Amazon Rekognition moderation API, which can discover inappropriate content in uploaded avatars. Developers do not need machine learning expertise to use this API. If it identifies unacceptable content, the Step Functions workflow deletes the uploaded picture.

Second, it uses avatar thumbnails on the top navigation bar and on leaderboards. This speeds up page loading and uses less network bandwidth. Image-editing software runs in a Lambda function to modify the uploaded file and store the result in S3 with the original.

Third, it uses Amazon CloudFront as a content delivery network (CDN) with the S3 bucket hosting images. This improves performance by implementing caching and serving static content from locations closer to the player. Additionally, using CloudFront allows you to keep the bucket private and provide greater security for the content stored within S3.

Finally, it stores profile picture URLs in DynamoDB and replicates the thumbnail URL in an Amazon Cognito user attribute named picture. This allows the game to retrieve the avatar URL as part of the login process, saving an HTTP GET request for the player profile.

The last step of the workflow publishes the result via an event to EventBridge for downstream systems to consume. The service routes the event to the notification component to inform the player about the moderation status.

Notifying users of the processing result

The result of the avatar workflow to the player is important but not urgent. Players want to know the result but not impact their gameplay experience. A solution for this challenge is to use HTTP web push. It uses the HTTP protocol and does not require a constant communication channel between backend and front end. This allows players to play games without being blocked or by introducing latency to the game communications channel.

Applications requiring low latency fully bidirectional communication, such as highly interactive multi-player games, typically use WebSockets. This creates a persistent two-way channel for front end and backend to exchange information. The web push mechanism can provide non-urgent data and messages to the player without interrupting the WebSockets channel.

The web push protocol describes how to use a consolidated push service as a broker between the web-client and the backend. It accepts subscriptions from the client and receives push message delivery requests from the backend. Each browser vendor provides a push service implementation that is compliant with the W3C Push API specification and is external to both client and backend.

The web client is typically a browser where a JavaScript application interacts with the push service to subscribe and listen for incoming notifications. The backend is the application that notifies the front end. Here is an overview of the protocol with all the parties involved.

A component on the client subscribes to the configured push service by sending an HTTP POST request. The client keeps a background connection waiting for messages.
The push service returns a URL identifying a push resource that the client distributes to backend applications that are allowed to send notifications.
Backend applications request a message delivery by sending an HTTP POST request to the previously distributed URL.
The push service forwards the information to the client.

This approach has four advantages. First, it reduces the effort to manage the reliability of the delivery process by off-loading it to an external and standardized component. Second, it minimizes cost and resource consumption. This is because it doesn’t require the backend to keep a persistent communication channel or compute resources to be constantly available. Third, it keeps complexity to a minimum because it relies on HTTP only without requiring additional technologies. Finally, HTTP web push addresses concepts such as message urgency and time-to-live (TTL) by using a standard.

Serverless HTTP web push

The implementation of the web push protocol requires the following components, per the Push API specification. First, the front end is required to create a push subscription. This is implemented through a service worker, a script running in the origin of the application. The service worker exposes operations to access the push service either creating subscriptions or listening for push events.

The client uses the service worker to subscribe to the push service via the Push API.
The push service responds with a payload including a URL, which is the client’s push endpoint. The URL is used to create notification delivery requests.
The browser enriches the subscription with public cryptographic keys, which are used to encrypt messages ensuring confidentiality.
The backend must receive and store the subscription for when a delivery request is made to the push service. This is provided by API Gateway, Lambda, and DynamoDB. API Gateway exposes an HTTP API endpoint that accepts POST requests with the push service subscription as payload. The payload is stored in DynamoDB alongside the player identifier.

This front end code implements the process:

//Once service worker is ready
navigator.serviceWorker.ready
  .then(function (registration) {
    //Retrieve existing subscription or subscribe
    return registration.pushManager.getSubscription()
      .then(async function (subscription) {
        if (subscription) {
          console.log('got subscription!', subscription)
          return subscription;
        }
        /*
         * Using Public key of our backend to make sure only our
         * application backend can send notifications to the returned
         * endpoint
         */
        const convertedVapidKey = self.vapidKey;
        return registration.pushManager.subscribe({
          userVisibleOnly: true,
          applicationServerKey: convertedVapidKey
        });
      });
  }).then(function (subscription) {
    //Distributing the subscription to the application backend
    console.log('register!', subscription);
    const body = JSON.stringify(subscription);
    const parms = {jwt: jwt, playerName: playerName, subscription: body};
    //Call to the API endpoint to save the subscription
    const res = DataService.postPlayerSubscription(parms);
    console.log(res);
  });

Next, the backend reacts to the avatar workflow completed custom event to create a delivery request. This is accomplished with EventBridge and Lambda.

EventBridge routes the event to a Lambda function.
The function retrieves the player’s agent subscriptions, including push endpoint and encryption keys, from DynamoDB.
The function sends an HTTP POST to the push endpoint with the encrypted message as payload.
When the push service delivers the message, the browser activates the service worker updating local state and displaying the notification.

The push service allows creating delivery requests based on the knowledge of the endpoint and the front end allows the backend to deliver messages by distributing the endpoint. HTTPS provides encryption for data in transit while DynamoDB encrypts all your data at rest to provide confidentiality and security for the endpoint.

Security of WebPush can be further improved by using Voluntary Application Server Identification (VAPID). With WebPush, the clients authenticate messages at delivery time. VAPID allows the push service to perform message authentication on behalf of the web client avoiding denial-of-service risk. Without the additional security of VAPID, any application knowing the push service endpoint might successfully create delivery requests with an invalid payload. This can cause the player’s agent to accept messages from unauthorized services and, possibly, cause a denial-of-service to the client by overloading its capabilities.

VAPID requires backend applications to own a key pair. In Simple Trivia Service, a Lambda function, which is an AWS CloudFormation custom resource, generates the key pair when deploying the stack. It securely saves values in AWS System Manager (SSM) Parameter Store.

Here is a representation of VAPID in action:

The front end specifies which backend the push service can accept messages from. It does this by including the public key from VAPID in the subscription request.
When requesting a message delivery, the backend self-identifies by including the public key and a token signed with the private key in the HTTP Authorization header. If the keys match and the client uses the public key at subscription, the message is sent. If not, the message is blocked by the push service.

The Lambda function that sends delivery requests to the push service reads the key values from SSM. It uses them to generate the Authorization header to include in the request, allowing for successful delivery to the client endpoint.

Conclusion

This post shows how you can add scaling support for a game via automation. The example uses Amazon Rekognition to check images for unacceptable content and uses asynchronous architecture patterns with Step Functions and HTTP WebPush. These scaling approaches can help you to maximize your technical and personnel investments.

For more serverless learning resources, visit Serverless Land.

Field Notes: Build Dynamic IVR Menus with Amazon Connect and AWS Lambda

2021-07-28 Marius Cealera

Post Syndicated from Marius Cealera original https://aws.amazon.com/blogs/architecture/field-notes-build-dynamic-ivr-menus-with-amazon-connect-and-aws-lambda/

This post was co-written by Marius Cealera, Senior Partner Solutions Architect at AWS, and Zdenko Estok, Cloud Architect and DevOps Engineer at Accenture.

Modern interactive voice response (IVR) systems help customers find answers to their questions through a series of menus, usually relying on the customer to filter and select the right options. Adding more options in these IVR menus and hoping to increase the rate of self-serviced calls can be tempting, but it can also overwhelm customers and lead them to ‘zeroing out’. That is, they select to be transferred to a human agent, defeating the purpose of a self-service solution.

This post provides a technical overview of one of Accenture’s Advanced Customer Engagement (ACE+) solutions, explaining how to build a dynamic IVR menu in Amazon Connect, in combination with AWS Lambda and Amazon DynamoDB. The solution can help the zeroing out problem by providing each customer with a personalized list of menu options. Solutions architects, developers, and contact center administrators will learn how to use Lambda and DynamoDB to build Amazon Connect flows where menu options are customized for every known customer. We have provided code examples to deploy a similar solution.

Overview of solution

“Imagine a situation where a customer navigating a call center IVR needs to choose from many menu options – for example, an insurance company providing a self-service line for customers to check their policies. For dozens of insurance policy variations, the IVR would need a long and complex menu. Chances are that after the third or fourth menu choice the customers will be confused, irritated or may even forget what they are looking for,” says Zdenko Estok, Cloud Architect and Amazon Connect Specialist at Accenture.

“Even splitting the menu in submenus does not completely solve the problem. It is a step in the right direction as it can reduce the total time spent listening to menu options, but it has the potential to grow into a huge tree of choices.”

Figure 1. A static one-layer menu on the left, a three-layer menu on the right

One way to solve this issue is by presenting only relevant menu options to customers. This approach significantly reduces the time spent in the IVR menu, leading to a better customer experience. This also minimizes the chance the customer will require transfer to a human agent.

Figure 2. Selectively changing the IVR menu structure based on customer profile

For use cases with a limited number of menu options, the solution can be achieved directly in the Amazon Connect IVR designer through the use of the Check Contact Attributes block. However, this approach can lead to complex and hard to maintain flows for situations where dozens of menu variations are possible. A more scalable solution is to store customer information and menu options in DynamoDB and build the menu dynamically by using a series of Lambda functions (Figure 3).

Consider a customer with the following information stored in a database: phone number, name, and active insurance policies. A dynamic menu implementation will authenticate the user based on the phone number, retrieve the policy information from the database, and build the menu options.

The first Lambda function retrieves the customer’s active policies and builds the personalized greeting and menu selection prompt. The second Lambda function maps the customer’s menu selection to the correct menu path. This is required since the menu is dynamic and the items and ordering are different for different customers. This approach also allows administrators to add or change insurance types and their details, directly in the database, without the need to update the IVR structure. This can be useful when maintaining IVR flows for dozens of products or services.

Figure 3 – IVR flow leveraging dynamically generated menu options.

Walkthrough

Sample code for this solution is provided in this GitHub repo. The code is packaged as a CDK application, allowing the solution to be deployed in minutes. The deployment tasks are as follows:

Deploy the CDK app.
Update Amazon Connect instance settings.
Import the demo flow and data.

Prerequisites

For this walkthrough, you need the following prerequisites:

An AWS account.
AWS CLI access to the AWS account where you would like to deploy your solution.
An Amazon Connect instance. If you do not have an Amazon Connect instance, you can deploy one and claim a phone number with Set up your Amazon Connect instance.

Deploy the CDK application

The resources required for this demo are packaged as a CDK app. Before proceeding, confirm you have CLI access to the AWS account where you would like to deploy your solution.

Open a terminal window and clone the GitHub repository in a directory of your choice:

git clone [email protected]:aws-samples/amazon-connect-dynamic-ivr-menus.git

Navigate to the cdk-app directory and follow the deployment instructions. The default region is usually us-east-1. If you would like to deploy in another Region, you can run:

export AWS_DEFAULT_REGION=eu-central-1

Update Amazon Connect instance settings

You need to update your Amazon Connect instance settings to implement the Lambda functions created by the CDK app.

Log into the AWS console.
Navigate to Services > Amazon Connect. Select your Amazon Connect instance.
Select Contact Flows.
Scroll down to the Lambda section and add getCustomerDetails* and selectionFulfi lment* functions. If the Lambda functions are not listed, return to the Deploy the CDK application section and verify there are no deployment errors.
Select +Add Lambda function.

Import the demo flow

Download the DemoMenu Amazon Connect flow from the flow_archive section of the sample code repository.
Log in to the Amazon Connect console. You can find the Amazon Connect access url for your instance in the AWS Console, under Services > Amazon Connect > (Your Instance Name). The access url will have the following format: https://<your_instance_name>.awsapps.com/connect/login
Create a new contact flow by selecting ‘Contact Flows’ from the left side menu and then select Create New Contact Flow.
Select ‘Import Flow(beta)’ from the upper right corner menu and select the DemoMenu file downloaded at step 1.
Click on the first ‘Invoke Lambda’ block, and verify the getCustomerDetails* Lambda is selected.
Select the second Invoke Lambda block, and verify the selectionFulfilment*’Lambda is selected.
Select Publish.
Associate the new flow with your claimed phone number (phone numbers are listed in the left side menu).

Update the demo data and test

For the demo to work and recognize your phone number, you will need to enter your phone number into the demo customers table.
Navigate to the AWS console and select DynamoDB.
From the left hand side menu select Tables, open the CdkAppStack-policiesDb*table, and navigate to the Items tab. If the table is empty, verify you started the populateDBLamba, as mentioned in the CDK deployment instructions.
Select one of the customers in the table, then select Actions > Duplicate. In the new item, enter your phone number (in international format).
Select Save.
Dial your claimed Connect number. You should hear the menu options based on your database table entry.

Clean up

You can remove all resources provisioned for the CDK app by navigating to the cdk-app directory and running the following command:

cdk destroy

This will not remove your Amazon Connect instance. You can remove it by navigating to the AWS console > Services > Amazon Connect. Find your Connect instance and select Remove.

Conclusion

In this post we showed you how a dynamic IVR menu can be implemented in Amazon Connect. Using a dynamic menu can significantly reduce call durations by helping customers reach relevant content faster in the IVR system, which often leads to improved customer satisfaction. Furthermore, this approach to building IVR menus provides call center administrators with a way to manage menus with dozens or hundreds of branches directly in a backend database, as well as add or update menu options.

Field Notes provides hands-on technical guidance from AWS Solutions Architects, consultants, and technical account managers, based on their experiences in the field solving real-world business problems for customers.

Accelerating Innovation with the Accenture AWS Business Group (AABG)

By working with the Accenture AWS Business Group (AABG), you can learn from the resources, technical expertise, and industry knowledge of two leading innovators, helping you accelerate the pace of innovation to deliver disruptive products and services. The AABG helps customers ideate and innovate cloud solutions with customers through rapid prototype development.

Connect with our team at [email protected] to learn how to use machine learning in your products and services.

Building well-architected serverless applications: Regulating inbound request rates – part 2

2021-07-27 Julian Wood

Post Syndicated from Julian Wood original https://aws.amazon.com/blogs/compute/building-well-architected-serverless-applications-regulating-inbound-request-rates-part-2/

Reliability question REL1: How do you regulate inbound request rates?

This post continues part 1 of this security question. Previously, I cover controlling inbound request rates using throttling. I go through how to use throttling to control steady-rate and burst rate requests. I show some solutions for performance testing to identify the request rates that your workload can sustain before impacting performance.

Good practice: Use, analyze, and enforce API quotas

API quotas limit the maximum number of requests a given API key can submit within a specified time interval. Metering API consumers provides a better understanding of how different consumers use your workload at sustained and burst rates at any point in time. With this information, you can determine fine-grained rate limiting for multiple quota limits. These can be done according to a group of consumer needs, and can adjust their limits on a regular basis.

Segregate API consumers steady-rate requests and their quota into multiple buckets or tiers

Amazon API Gateway usage plans allow your API consumer to access selected APIs at agreed-upon request rates and quotas. These help your consumers meet their business requirements and budget constraints. Create and attach API keys to usage plans to control access to certain API stages. I show how to create usage plans and how to associate them with API keys in “Building well-architected serverless applications: Controlling serverless API access – part 2”.

API key associated with usage plan

You can extract utilization data from usage plans to analyze API usage on a per-API key basis. In the example, I show how to use usage plans to see how many requests are made.

View API key usage

This allows you to generate billing documents and determine whether your customers need higher or lower limits. Have a mechanism to allow customers to request higher limits preemptively. When customers anticipate greater API usage, they can take action proactively.

API Gateway Lambda authorizers can dynamically associate API keys to a given request. This can be used where you do not control API consumers, or want to associate API keys based on your own criteria. For more information, see the documentation.

You can also visualize usage plans with Amazon QuickSight using enriched API Gateway access logs.

Visualize usage plans with Amazon QuickSight

Define whether your API consumers are end users or machines

Understanding your API consumers helps you manage how they connect to your API. This helps you define a request access pattern strategy, which can distinguish between end users or machines.

Machine consumers make automated connections to your API, which may require a different access pattern to end users. You may decide to prioritize end user consumers to provide a better experience. Machine consumers may be able to handle request throttling automatically.

Best practice: Use mechanisms to protect non-scalable resources

Limit component throughput by enforcing how many transactions it can accept

AWS Lambda functions can scale faster than traditional resources, such as relational databases and cache systems. Protect your non-scalable resources by ensuring that components that scale quickly do not exceed the throughput of downstream systems. This can prevent system performance degrading. There are a number of ways to achieve this, either directly or via buffer mechanisms such as queues and streams.

For relational databases such as Amazon RDS, you can limit the number of connections per user, in addition to the global maximum number of connections. With Amazon RDS Proxy, your applications can pool and share database connections to improve their ability to scale.

Amazon RDS Proxy

For additional options for using RDS with Lambda, see the AWS Serverless Hero blog post “How To: Manage RDS Connections from AWS Lambda Serverless Functions”.

Cache results and only connect to, and fetch data from databases when needed. This reduces the load on the downstream database. Adjust the maximum number of connections for caching systems. Include a caching expiration mechanism to prevent serving stale records. For more information on caching implementation patterns and considerations, see “Caching Best Practices”.

Lambda provides managed scaling. When a function is first invoked, the Lambda service creates an instance of the function to process the event. This is called a cold start. After completion, the function remains available for a period of time to process subsequent events. These are called warm starts. If other events arrive while the function is busy, Lambda creates more instances of the function to handle these requests concurrently as cold starts. The following example shows 10 events processed in six concurrent requests.

Lambda concurrency

You can control the number of concurrent function invocations to both reserve and limit the maximum concurrency your function can achieve. You can configure reserved concurrency to set the maximum number of concurrent instances for the function. This can protect downstream resources such as a database by ensuring Lambda can only scale up to the number of connections the database can support.

For example, you may have a traditional database or external API that can only support a maximum of 50 concurrent connections. You can set the maximum number of concurrent Lambda functions using the function concurrency settings. Setting the value to 50 ensures that the traditional database or external API is not overwhelmed.

Edit Lambda concurrency

You can also set the Lambda function concurrency to 0, which disables the Lambda function in the event of anomalies.

Another solution to protect downstream resources is to use an intermediate buffer. A buffer can persistently store messages in a stream or queue until a receiver processes them. This helps you control how fast messages are processed, which can protect the load on downstream resources.

Amazon Kinesis Data Streams allows you to collect and process large streams of data records in real time, and can act as a buffer. Streams consist of a set of shards that contain a sequence of data records. When using Lambda to process records, it processes one batch of records at a time from each shard.

Kinesis Data Streams control concurrency at the shard level, meaning that a single shard has a single concurrent invocation. This can reduce downstream calls to non-scalable resources such as a traditional database. Kinesis Data Streams also support batch windows up to 5 minutes and batch record sizes. These can also be used to control how frequent invocations can occur.

To learn how to manage scaling with Kinesis, see the documentation. To learn more how Lambda works with Kinesis, read the blog series “Building serverless applications with streaming data”.

Lambda and Kinesis shards

Amazon Simple Queue Service (SQS) is a fully managed serverless message queuing service that enables you to decouple and scale microservices. You can offload tasks from one component of your application by sending them to a queue and processing them asynchronously.

SQS can act as a buffer, using a Lambda function to process the messages. Lambda polls the queue and invokes your Lambda function synchronously with an event that contains queue messages. Lambda reads messages in batches and invokes your function once for each batch. When your function successfully processes a batch, Lambda deletes its messages from the queue.

You can protect downstream resources using the Lambda concurrency controls. This limits the number of concurrent Lambda functions that pull messages off the queue. The messages persist in the queue until Lambda can process them. For more information see, “Using AWS Lambda with Amazon SQS”

Lambda and SQS

Conclusion

Regulating inbound requests helps you adapt different scaling mechanisms based on customer demand. You can achieve better throughput for your workloads and make them more reliable by controlling requests to a rate that your workload can support.

In this post, I cover using, analyzing, and enforcing API quotas using usage plans and API keys. I show mechanisms to protect non-scalable resources such as using RDS Proxy to protect downstream databases. I show how to control the number of Lambda invocations using concurrency controls to protect downstream resources. I explain how you can use streams and queues as an intermediate buffer to store messages persistently until a receiver processes them.

In the next post in the series, I cover the second reliability question from the Well-Architected Serverless Lens, building resiliency into serverless applications.

For more serverless learning resources, visit Serverless Land.

Synchronize and control your Amazon Redshift clusters maintenance windows

2021-07-22 Ahmed Gamaleldin

Post Syndicated from Ahmed Gamaleldin original https://aws.amazon.com/blogs/big-data/synchronize-and-control-your-amazon-redshift-clusters-maintenance-windows/

Amazon Redshift is a data warehouse that can expand to exabyte-scale. Today, tens of thousands of AWS customers (including NTT DOCOMO, Finra, and Johnson & Johnson) use Amazon Redshift to run mission-critical business intelligence dashboards, analyze real-time streaming data, and run predictive analytics jobs.

Amazon Redshift powers analytical workloads for Fortune 500 companies, startups, and everything in between. With the constant increase in generated data, Amazon Redshift customers continue to achieve successes in delivering better service to their end-users, improving their products, and running an efficient and effective business. Availability, therefore, is key in continuing to drive customer success, and AWS will use commercially reasonable efforts to make Amazon Redshift available with a Monthly Uptime Percentage for each multi-node cluster, during any monthly billing cycle, of at least 99.9% (our “Service Commitment”).

In this post, we present a solution to help you provide a predictable and repeatable experience to your Amazon Redshift end-users by taking control of recurring Amazon Redshift maintenance windows.

Amazon Redshift maintenance windows

Amazon Redshift periodically performs maintenance to apply fixes, enhancements, and new features to your cluster. This type of maintenance occurs during a 30-minute maintenance window set by default per Region from an 8-hour block on a random day of the week. You should change the scheduled maintenance window according to your business needs by modifying the cluster, either programmatically or by using the Amazon Redshift console. The window must be at least 30 minutes and not longer than 24 hours. For more information, see Managing clusters using the console.

If a maintenance event is scheduled for a given week, it starts during the assigned 30-minute maintenance window. While Amazon Redshift performs maintenance, it terminates any queries or other operations that are in progress. If there are no maintenance tasks to perform during the scheduled maintenance window, your cluster continues to operate normally until the next scheduled maintenance window. Amazon Redshift uses Amazon Simple Notification Service (Amazon SNS) to send notifications of Amazon Redshift events. You enable notifications by creating an Amazon Redshift event subscription. You can create an Amazon Redshift event notification subscription so you can be notified when an event occurs for a given cluster.

When an Amazon Redshift cluster is scheduled for maintenance, you receive an Amazon Redshift “Pending” event, as described in the following table.

Amazon Redshift category	Event ID	Event severity	Description
Pending	REDSHIFT-EVENT-2025	INFO	Your database for cluster <cluster name> will be updated between <start time> and <end time>. Your cluster will not be accessible. Plan accordingly.
Pending	REDSHIFT-EVENT-2026	INFO	Your cluster <cluster name> will be updated between <start time> and <end time>. Your cluster will not be accessible. Plan accordingly.

Amazon Redshift also gives you the option to reschedule your cluster’s maintenance window by deferring your upcoming maintenance by up to 45 days. This option is particularly helpful if you want to maximize your cluster uptime by deferring a future maintenance window. For example, if your cluster’s maintenance window is set to Wednesday 8:30–9:00 UTC and you need to have nonstop access to your cluster for the next 2 weeks, you can defer maintenance to a date 2 weeks from now. We don’t perform any maintenance on your cluster when you have specified a deferment.

Deferring a maintenance window doesn’t apply to mandatory Amazon Redshift updates, such as vital security patches. Scheduled maintenance is different from Amazon Redshift mandatory maintenance. If Amazon Redshift needs to update hardware or make other mandatory updates during your period of deferment, we notify you and make the required changes. Your cluster isn’t available during these updates and such maintenance can’t be deferred. If a hardware replacement is required, you receive an event notification through the AWS Management Console and your SNS subscription as a “Pending” item, as shown in the following table.

Amazon Redshift category	Event ID	Event severity	Description
Pending	REDSHIFT-EVENT-3601	INFO	A node on your cluster <cluster name> will be replaced between <start time> and <end time>. You can’t defer this maintenance. Plan accordingly.
Pending	REDSHIFT-EVENT-3602	INFO	A node on your cluster <cluster name> is scheduled to be replaced between <start time> and <end time>. Your cluster will not be accessible. Plan accordingly.

Challenge

As the number of the Amazon Redshift clusters you manage for an analytics application grows, the end-user experience becomes highly dependent on recurring maintenance. This means that you want to make sure maintenance windows across all clusters happen at the same time and fall on the same day each month. You want to avoid a situation in which, for example, your five Amazon Redshift clusters are each updated on a different day or week. Ultimately, you want to give your Amazon Redshift end-users an uninterrupted number of days where the clusters aren’t subject to any scheduled maintenance. This gives you the opportunity to announce a scheduled maintenance to your users well ahead of the maintenance date.

Amazon Redshift clusters are scheduled for maintenance depending on several factors, including when a cluster was created and its Region. For example, you may have two clusters on the same Amazon Redshift version that are scheduled for different maintenance windows. Regions implement the Amazon Redshift latest versions and patches at different times. A cluster running in us-east-1 might be scheduled for the same maintenance 1 week before another cluster in eu-west-1. This makes it harder for you to provide your end-users with a predictable maintenance schedule.

To solve this issue, you typically need to frequently check and synchronize the maintenance windows across all your clusters to a specific time, for example sat:06:00-sat:06:30. Additionally, you want to avoid having your clusters scheduled for maintenance at different intervals. For that, you need to defer maintenance across all your clusters to fall on the same exact day. For example, you can defer all maintenance across all clusters to happen 1 month from now regardless of when the cluster was last updated. This way you know that your clusters aren’t scheduled for maintenance for the next 30 days. This gives you enough time to announce the maintenance schedule to your Amazon Redshift users.

Solution overview

Having one day per month when Amazon Redshift scheduled maintenance occurs across all your clusters provides your users with a seamless experience. It gives you control and predictability over when clusters aren’t available. You can announce this maintenance window ahead of time to avoid sudden interruptions.

The following solution deploys an AWS Lambda function (RedshiftMaintenanceSynchronizer) to your AWS account. The function runs on a schedule configurable through an AWS CloudFormation template parameter frequency to run every 6, 12, or 24 hours. This function synchronizes maintenance schedules across all your Amazon Redshift clusters to happen at the same time on the same day. It also gives you the option to defer all future maintenance windows across all clusters by a number of days (deferment days) for up to 45 days. This enables you to provide your users with an uninterrupted number of days when your clusters aren’t subject to maintenance.

We use the following input parameters:

Deferment days – The number of days to defer all future scheduled maintenance windows. Amazon Redshift can defer maintenance windows by up to 45 days. The solution adds this number to the date of the last successfully completed maintenance across any of your clusters. The resulting date is the new maintenance date for all your clusters.
Frequency – The frequency to run this solution. You can configure it to run every 6, 12, or 24 hours.
Day – The preferred day of the week to schedule maintenance windows.
Hour – The preferred hour of the day to schedule maintenance windows (24-hour format).
Minute – The preferred minute of the hour to schedule maintenance windows.

The Lambda function performs the following steps:

Lists all your Amazon Redshift clusters in the Region.
Updates the maintenance window for all clusters to the same value of the day/hour/minute input parameters from the CloudFormation template.
Checks for the last successfully completed maintenance across all clusters.
Calculates the deferment maintenance date by adding the deferment input parameter to the date of the last successfully completed maintenance. For example, if the deferment parameter is 30 days and the last successful maintenance window completed on July 1, 2020, then the next deferment maintenance date is July 31, 2020.
Defers the next maintenance window across all clusters to the deferment date calculated in the previous step.

Launch the solution

To get started, deploy the cloudFormation template to your AWS account.

For Stack name, enter a name for your stack for easy reference.
For Day, choose the day of week for the maintenance window to occur.
For Hour, choose the hour for the window to start.
For Minute, choose the minute within the hour for the window to start.

Your window should be a time with the least cluster activity and during off-peak work hours.

For Deferment Days, choose the number of days to defer all future scheduled maintenance windows.
For Solution Run Frequency, choose the frequency of 6, 12, or 24 hours.

cloudFormation Template

After the template has successfully deployed, the following resources are available:

The RedshiftMaintenanceSync Lambda function. This is a Python 3.8 Lambda function that syncs and defers the maintenance windows across all your Amazon Redshift clusters.

lamda_console

The RedshiftMaintenanceSyncEventRule Amazon CloudWatch event rule. This rule triggers on a schedule based on the Frequency input parameter. It triggers the RedshiftMaintenanceSync Lambda function to run the solution logic.

When the Lambda function starts and detects an already available deferment on any of your clusters, it doesn’t attempt to modify the existing deferment, and exits instead.

The solution logs any deferment it performs on any cluster in the associated CloudWatch log group.

Synchronize and defer maintenance windows

To demonstrate this solution, I have two Amazon Redshift clusters with different preferred maintenance windows and scheduled intervals.

Cluster A (see the following screenshot) has a preferred maintenance window set to Friday at 4:30–5:00 PM. It’s scheduled for maintenance in 2 days.

Cluster B has a preferred maintenance window set to Tuesday at 9:45–10:15 AM. It’s scheduled for maintenance in 6 days.

This means that my Amazon Redshift users have a 30-minute interruption twice in the next 2 and 6 days. Also, these interruptions happen at completely different times.

Let’s launch the solution and see how the cluster maintenance windows and scheduling intervals change.

The Lambda function does the following every time it runs:

Lists all the clusters.
Checks if any of the clusters have a deferment enabled and exits if it finds any.
Syncs all preferred maintenance windows across all clusters to fall on the same time and day of week.
Checks for the latest successfully completed maintenance date.
Adds the deferment days to the last maintenance date. This becomes the new deferment date.
Applies the new deferment date to all clusters.

Cluster A’s maintenance window was synced to the input parameters I passed to the CloudFormation template. Additionally, the next maintenance window was deferred until June 21, 2021, 8:06 AM (UTC +02:00).

Cluster B’s maintenance window is also synced to the same value from Cluster A, and the next maintenance window was deferred to the same exact day as Cluster A: June 21, 2021, 8:06 AM (UTC +02:00).

Finally, let’s check the CloudWatch log group to understand what the solution did.

Now both clusters have the same maintenance window and next scheduled maintenance, which is a month from now. In a production scenario, this gives you enough lead time to announce the maintenance window to your Amazon Redshift end-users and provide them with the exact day and time when clusters aren’t available.

Summary

This solution can help you provide a predictable and repeatable experience to your Amazon Redshift end-users by taking control of recurring Amazon Redshift maintenance windows. It enables you to provide your users with an uninterrupted number of days where clusters are always available—barring any scheduled mandatory upgrades. Click here to get started with Amazon Redshift today.

About the Author

Ahmed_Gamaleldin

Ahmed Gamaleldin is a Senior Technical Account Manager (TAM) at Amazon Web Services. Ahmed helps customers run optimized workloads on AWS and make the best out of their cloud journey.

Building well-architected serverless applications: Regulating inbound request rates – part 1

2021-07-22 Julian Wood

Post Syndicated from Julian Wood original https://aws.amazon.com/blogs/compute/building-well-architected-serverless-applications-regulating-inbound-request-rates-part-1/

Reliability question REL1: How do you regulate inbound request rates?

Defining, analyzing, and enforcing inbound request rates helps achieve better throughput. Regulation helps you adapt different scaling mechanisms based on customer demand. By regulating inbound request rates, you can achieve better throughput, and adapt client request submissions to a request rate that your workload can support.

Required practice: Control inbound request rates using throttling

Throttle inbound request rates using steady-rate and burst rate requests

Throttling requests limits the number of requests a client can make during a certain period of time. Throttling allows you to control your API traffic. This helps your backend services maintain their performance and availability levels by limiting the number of requests to actual system throughput.

To prevent your API from being overwhelmed by too many requests, Amazon API Gateway throttles requests to your API. These limits are applied across all clients using the token bucket algorithm. API Gateway sets a limit on a steady-state rate and a burst of request submissions. The algorithm is based on an analogy of filling and emptying a bucket of tokens representing the number of available requests that can be processed.

Each API request removes a token from the bucket. The throttle rate then determines how many requests are allowed per second. The throttle burst determines how many concurrent requests are allowed. I explain the token bucket algorithm in more detail in “Building well-architected serverless applications: Controlling serverless API access – part 2”

Token bucket algorithm

API Gateway limits the steady-state rate and burst requests per second. These are shared across all APIs per Region in an account. For further information on account-level throttling per Region, see the documentation. You can request account-level rate limit increases using the AWS Support Center. For more information, see Amazon API Gateway quotas and important notes.

You can configure your own throttling levels, within the account and Region limits to improve overall performance across all APIs in your account. This restricts the overall request submissions so that they don’t exceed the account-level throttling limits.

You can also configure per-client throttling limits. Usage plans restrict client request submissions to within specified request rates and quotas. These are applied to clients using API keys that are associated with your usage policy as a client identifier. You can add throttling levels per API route, stage, or method that are applied in a specific order.

For more information on API Gateway throttling, see the AWS re:Invent presentation “I didn’t know Amazon API Gateway could do that”.

API Gateway throttling

You can also throttle requests by introducing a buffering layer using Amazon Kinesis Data Stream or Amazon SQS. Kinesis can limit the number of requests at the shard level while SQS can limit at the consumer level. For more information on using SQS as a buffer with Amazon Simple Notification Service (SNS), read “How To: Use SNS and SQS to Distribute and Throttle Events”.

Identify steady-rate and burst rate requests that your workload can sustain at any point in time before performance degraded

Load testing your serverless application allows you to monitor the performance of an application before it is deployed to production. Serverless applications can be simpler to load test, thanks to the automatic scaling built into many of the services. During a load test, you can identify quotas that may act as a limiting factor for the traffic you expect and take action.

Perform load testing for a sustained period of time. Gradually increase the traffic to your API to determine your steady-state rate of requests. Also use a burst strategy with no ramp up to determine the burst rates that your workload can serve without errors or performance degradation. There are a number of AWS Marketplace and AWS Partner Network (APN) solutions available for performance testing, Gatling Frontline, BlazeMeter, and Apica.

In the serverless airline example used in this series, you can run a performance test suite using Gatling, an open source tool.

To deploy the test suite, follow the instructions in the GitHub repository perf-tests directory. Uncomment the deploy.perftest line in the repository Makefile.

Perf-test makefile

Once the file is pushed to GitHub, AWS Amplify Console rebuilds the application, and deploys an AWS CloudFormation stack. You can run the load tests locally, or use an AWS Step Functions state machine to run the setup and Gatling load test simulation.

Performance test using Step Functions

The Gatling simulation script uses constantUsersPerSec and rampUsersPerSec to add users for a number of test scenarios. You can use the test to simulate load on the application. Once the tests run, it generates a downloadable report.

Gatling performance results

Artillery Community Edition is another open-source tool for testing serverless APIs. You configure the number of requests per second and overall test duration, and it uses a headless Chromium browser to run its test flows. For Artillery, the maximum number of concurrent tests is constrained by your local computing resources and network. To achieve higher throughput, you can use Serverless Artillery, which runs the Artillery package on Lambda functions. As a result, this tool can scale up to a significantly higher number of tests.

For more information on how to use Artillery, see “Load testing a web application’s serverless backend”. This runs tests against APIs in a demo application. For example, one of the tests fetches 50,000 questions per hour. This calls an API Gateway endpoint and tests whether the AWS Lambda function, which queries an Amazon DynamoDB table, can handle the load.

Artillery performance test

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

Performance test API results

Another consideration for API load testing is whether the authentication and authorization service can handle the load. For more information on load testing Amazon Cognito and API Gateway using Step Functions, see “Using serverless to load test Amazon API Gateway with authorization”.

API load testing with authentication and authorization

Conclusion

In this post, I cover controlling inbound request rates using throttling. I show how to use throttling to control steady-rate and burst rate requests. I show some solutions for performance testing to identify the request rates that your workload can sustain before performance degradation.

This well-architected question will be continued where I look at using, analyzing, and enforcing API quotas. I cover mechanisms to protect non-scalable resources.

For more serverless learning resources, visit Serverless Land.

Data Caching Across Microservices in a Serverless Architecture

2021-07-21 Irfan Saleem

Post Syndicated from Irfan Saleem original https://aws.amazon.com/blogs/architecture/data-caching-across-microservices-in-a-serverless-architecture/

Organizations are re-architecting their traditional monolithic applications to incorporate microservices. This helps them gain agility and scalability and accelerate time-to-market for new features.

Each microservice performs a single function. However, a microservice might need to retrieve and process data from multiple disparate sources. These can include data stores, legacy systems, or other shared services deployed on premises in data centers or in the cloud. These scenarios add latency to the microservice response time because multiple real-time calls are required to the backend systems. The latency often ranges from milliseconds to a few seconds depending on size of the data, network bandwidth, and processing logic. In certain scenarios, it makes sense to maintain a cache close to the microservices layer to improve performance by reducing or eliminating the need for the real-time backend calls.

Caches reduce latency and service-to-service communication of microservice architectures. A cache is a high-speed data storage layer that stores a subset of data. When data is requested from a cache, it is delivered faster than if you accessed the data’s primary storage location.

While working with our customers, we have observed use cases where data caching helps reduce latency in the microservices layer. Caching can be implemented in several ways. In this blog post, we discuss a couple of these use cases that customers have built. In both use cases, the microservices layer is created using Serverless on AWS offerings. It requires data from multiple data sources deployed locally in the cloud or on premises. The compute layer is built using AWS Lambda. Though Lambda functions are short-lived, the cached data can be used by subsequent instances of the same microservice to avoid backend calls.

Use case 1: On-demand cache to reduce real-time calls

In this use case, the Cache-Aside design pattern is used for lazy loading of frequently accessed data. This means that an object is only cached when it is requested by a consumer, and the respective microservice decides if the object is worth saving.

This use case is typically useful when the microservices layer makes multiple real-time calls to fetch and process data. These calls can be greatly reduced by caching frequently accessed data for a short period of time.

Let’s discuss a real-world scenario. Figure 1 shows a customer portal that provides a list of car loans, their status, and the net outstanding amount for a customer:

The Billing microservice gets a request. It then tries to get required objects (for example, the list of car loans, their status, and the net outstanding balance) from the cache using an object_key. If the information is available in the cache, a response is sent back to the requester using cached data.
If requested objects are not available in the cache (a cache miss), the Billing microservice makes multiple calls to local services, applications, and data sources to retrieve data. The result is compiled and sent back to the requester. It also resides in the cache for a short period of time.
Meanwhile, if a customer makes a payment using the Payment microservice, the balance amount in the cache must be invalidated/deleted. The Payment microservice processes the payment and invokes an asynchronous event (payment_processed) with the respective object key for the downstream processes that will remove respective objects from the cache.
The events are stored in the event store.
The CacheManager microservice gets the event (payment_processed) and makes a delete request to the cache for the respective object_key. If necessary, the CacheManager can also refresh cached data. It can call a resource within the Billing service or it can refresh data directly from the source system depending on the data refresh logic.

Figure 1. Reducing latency by caching frequently accessed data on demand

Figure 2 shows AWS services for use case 1. The microservices layer (Billing, Payments, and Profile) is created using Lambda. The Amazon API Gateway is exposing Lambda functions as API operations to the internal or external consumers.

Figure 2. Suggested AWS services for implementing use case 1

All three microservices are connected with the data cache and can save and retrieve objects from the cache. The cache is maintained in-memory using Amazon ElastiCache. The data objects are kept in cache for a short period of time. Every object has an associated TTL (time to live) value assigned to it. After that time period, the object expires. The custom events (such as payment_processed) are published to Amazon EventBridge for downstream processing.

Use case 2: Proactive caching of massive volumes of data

During large modernization and migration initiatives, not all data sources are colocated for a certain period of time. Some legacy systems, such as mainframe, require a longer decommissioning period. Many legacy backend systems process data through periodic batch jobs. In such scenarios, front-end applications can use cached data for a certain period of time (ranging from a few minutes to few hours) depending on nature of data and its usage. The real-time calls to the backend systems cannot deal with the extensive call volume on the front-end application.

In such scenarios, required data/objects can be identified up front and loaded directly into the cache through an automated process as shown in Figure 3:

An automated process loads data/objects in the cache during the initial load. Subsequent changes to the data sources (either in a mainframe database or another system of record) are captured and applied to the cache through an automated CDC (change data capture) pipeline.
Unlike use case 1, the microservices layer does not make real-time calls to load data into the cache. In this use case, microservices use data already cached for their processing.
However, the microservices layer may create an event if data in the cache is stale or specific objects have been changed by another service (for example, by the Payment service when a payment is made).
The events are stored in Event Manager. Upon receiving an event, the CacheManager initiates a backend process to refresh stale data on demand.
All data changes are sent directly to the system of record.

Figure 3. Eliminating real-time calls by caching massive data volumes proactively

As shown in Figure 4, the data objects are maintained in Amazon DynamoDB, which provides low-latency data access at any scale. The data retrieval is managed through DynamoDB Accelerator (DAX), a fully managed, highly available, in-memory cache. It delivers up to a 10 times performance improvement, even at millions of requests per second.

Figure 4. Suggested AWS services for implementing use case 2

The data in DynamoDB can be loaded through different methods depending on the customer use case and technology landscape. API Gateway, Lambda, and EventBridge are providing similar functionality as described in use case 1.

Use case 2 is also beneficial in scenarios where front-end applications must cache data for an extended period of time, such as a customer’s shopping cart.

In addition to caching, the following best practices can also be used to reduce latency and to improve performance within the Lambda compute layer:

Best practices for working with AWS Lambda functions shows you how to use execution environment reuse to improve the performance of your Lambda functions
The Introducing AWS Lambda Extensions blog post shows you how to implement configuration and data cache using AWS Lambda Extensions

Conclusion

The microservices architecture allows you to build several caching layers depending on your use case. In this blog, we discussed data caching within the compute layer to reduce latency when data is retrieved from disparate sources. The information from use case 1 can help you reduce real-time calls to your back-end system by saving frequently used data to the cache. Use case 2 helps you maintain large volumes of data in caches for extended periods of time when real-time calls to the backend system are not possible.

Query a Teradata database using Amazon Athena Federated Query and join with data in your Amazon S3 data lake

2021-07-20 Navnit Shukla

Post Syndicated from Navnit Shukla original https://aws.amazon.com/blogs/big-data/query-a-teradata-database-using-amazon-athena-federated-query-and-join-with-data-in-your-amazon-s3-data-lake/

If you use data lakes in Amazon Simple Storage Service (Amazon S3) and use Teradata as your transactional data store, you may need to join the data in your data lake with Teradata in the cloud, Teradata running on Amazon Elastic Compute Cloud (Amazon EC2), or with an on-premises Teradata database, for example to build a dashboard or create consolidated reporting.

In these use cases, the Amazon Athena Federated Query feature allows you to seamlessly access the data from Teradata database without having to move the data to your S3 data lake. This removes the overhead in managing such jobs.

In this post, we will walk you through a step-by-step configuration to set up Athena Federated Query using AWS Lambda to access data in a Teradata database running on premises.

For this post, we will be using the Oracle Athena Federated Query connector developed by Trianz. The runtime includes a Teradata instance on premises. Your Teradata instance can be on the cloud, on Amazon EC2, or on premises. You can deploy the Trianz Oracle Athena Federated Query connector from the AWS Serverless Application Repository.

Let’s start with discussing the solution and then detailing the steps involved.

Solution overview

Data federation is the capability to integrate data in another data store using a single interface (Athena). The following diagram depicts how Athena Federated Query works by using Lambda to integrate with a federated data source.

Athena is an interactive query service that makes it easy to analyze data in Amazon S3 using standard SQL. If you have data in sources other than Amazon S3, you can use Athena Federated Query to query the data in place or build pipelines to extract data from multiple data sources and store them in Amazon S3. With Athena Federated Query, you can run SQL queries across data stored in relational, non-relational, object, and custom data sources.

When a federated query is run, Athena identifies the parts of the query that should be routed to the data source connector and executes them with Lambda. The data source connector makes the connection to the source, runs the query, and returns the results to Athena. If the data doesn’t fit into Lambda RAM runtime memory, it spills the data to Amazon S3 and is later accessed by Athena.

Athena uses data source connectors which internally use Lambda to run federated queries. Data source connectors are pre-built and can be deployed from the Athena console or from the Serverless Application Repository. Based on the user submitting the query, connectors can provide or restrict access to specific data elements.

To implement this solution, we complete the following steps:

Create a secret for the Teradata instance using AWS Secrets Manager.
Create an S3 bucket and subfolder for Lambda to use.
Configure Athena federation with the Teradata instance.
Run federated queries with Athena.

Prerequisite

Before you start this walkthrough, make sure your Teradata database is up and running.

Create a secret for the Teradata instance

Our first step is to create a secret for the Teradata instance with a username and password using Secrets Manager.

On the Secrets Manager console, choose Secrets.
Choose Store a new secret.
Select Other types of secrets.
Set the credentials as key-value pairs (username, password) for your Teradata instance.

For Secret name, enter a name for your secret. Use the prefix TeradataAFQ so it’s easy to find.
Leave the remaining fields at their defaults and choose Next.
Complete your secret creation.

Set up your S3 bucket for Lambda

On the Amazon S3 console, create a new S3 bucket and subfolder for Lambda to use. For this post, we create athena-accelerator/teradata.

Configure Athena federation with the Teradata instance

To configure Athena federation with Teradata instance, complete the following steps:

On the AWS Serverless Application Repository console, choose Available applications.
Select Show apps that create custom IAM roles or resource policies.
In the search field, enter TrianzTeradataAthenaJDBC.
Choose the application.

For SecretNamePrefix, enter TeradataAFQ.
For SpillBucket, enter Athena-accelerator/teradata.
For JDBCConnectorConfig, use the format teradata://jdbc:teradata://hostname/user=testUser&password=testPassword.
For DisableSpillEncryption, enter false.
For LambdaFunctionName, enter teradataconnector.
For SecurityGroupID, enter the security group ID where the Teradata instance is deployed.

Make sure to apply valid inbound and outbound rules based on your connection.

For SpillPrefix, create a folder under the S3 bucket you created and specify the name (for example, athena-spill).
For Subnetids, use the subnets where the Teradata instance is running with comma separation.

Make sure the subnet is in a VPC and has NAT gateway and internet gateway attached.

Select the I acknowledge check box.
Choose Deploy.

Make sure that the AWS Identity and Access Management (IAM) roles have permissions to access AWS Serverless Application Repository, AWS CloudFormation, Amazon S3, Amazon CloudWatch, Amazon CloudTrail, Secrets Manager, Lambda, and Athena. For more information about Athena IAM access, see Example IAM Permissions Policies to Allow Athena Federated Query.

Run federated queries with Athena

Run your queries using lambda:teradataconnector to run against tables in the Teradata database. teradataconnector is the name of lambda function which we have created in step 7 of previous section of this blog.

lambda:teradataconnector references a data source connector Lambda function using the format lambda:MyLambdaFunctionName. For more information, see Writing Federated Queries.

The following screenshot shows the query that joins the dataset between Teradata and the S3 data lake.

Key performance best practices

If you’re considering Athena Federated Query with Teradata, we recommend the following best practices:

Athena Federated query works great for queries with predicate filtering because the predicates are pushed down to the Teradata database. Use filter and limited-range scans in your queries to avoid full table scans.
If your SQL query requires returning a large volume of data from the Teradata database to Athena (which could lead to query timeouts or slow performance), you may consider moving data from Teradata to your S3 data lake.
The star schema is a commonly used data model in Teradata. In the star schema model, unload your large fact tables into your S3 data lake and leave the dimension tables in Teradata. If large dimension tables are contributing to slow performance or query timeouts, unload those tables to your S3 data lake.
When you run federated queries, Athena spins up multiple Lambda functions, which causes a spike in database connections. It’s important to monitor the Teradata database WLM queue slots to ensure there is no queuing. Additionally, you can use concurrency scaling on your Teradata database cluster to benefit from concurrent connections to queue up.

Conclusion

In this post, you learned how to configure and use Athena Federated Query with Teradata. Now you don’t need to wait for all the data in your Teradata data warehouse to be unloaded to Amazon S3 and maintained on a day-to-day basis to run your queries.

You can use the best practices outlined in the post to help minimize the data transferred from Teradata for better performance. When queries are well written for Athena Federated Query, the performance penalties are negligible.

For more information, see the Athena User Guide and Using Amazon Athena Federated Query.

About the Author

Navnit Shukla is an AWS Specialist Solution Architect in Analytics. He is passionate about helping customers uncover insights from their data. He has been building solutions to help organizations make data-driven decisions.

How to restrict IAM roles to access AWS resources from specific geolocations using AWS Client VPN

2021-07-20 Artem Lovan

Post Syndicated from Artem Lovan original https://aws.amazon.com/blogs/security/how-to-restrict-iam-roles-to-access-aws-resources-from-specific-geolocations-using-aws-client-vpn/

You can improve your organization’s security posture by enforcing access to Amazon Web Services (AWS) resources based on IP address and geolocation. For example, users in your organization might bring their own devices, which might require additional security authorization checks and posture assessment in order to comply with corporate security requirements. Enforcing access to AWS resources based on geolocation can help you to automate compliance with corporate security requirements by auditing the connection establishment requests. In this blog post, we walk you through the steps to allow AWS Identity and Access Management (IAM) roles to access AWS resources only from specific geographic locations.

Solution overview

AWS Client VPN is a managed client-based VPN service that enables you to securely access your AWS resources and your on-premises network resources. With Client VPN, you can access your resources from any location using an OpenVPN-based VPN client. A client VPN session terminates at the Client VPN endpoint, which is provisioned in your Amazon Virtual Private Cloud (Amazon VPC) and therefore enables a secure connection to resources running inside your VPC network.

This solution uses Client VPN to implement geolocation authentication rules. When a client VPN connection is established, authentication is implemented at the first point of entry into the AWS Cloud. It’s used to determine if clients are allowed to connect to the Client VPN endpoint. You configure an AWS Lambda function as the client connect handler for your Client VPN endpoint. You can use the handler to run custom logic that authorizes a new connection. When a user initiates a new client VPN connection, the custom logic is the point at which you can determine the geolocation of this user. In order to enforce geolocation authorization rules, you need:

AWS WAF to determine the user’s geolocation based on their IP address.
A Network address translation (NAT) gateway to be used as the public origin IP address for all requests to your AWS resources.
An IAM policy that is attached to the IAM role and validated by AWS when the request origin IP address matches the IP address of the NAT gateway.

One of the key features of AWS WAF is the ability to allow or block web requests based on country of origin. When the client connection handler Lambda function is invoked by your Client VPN endpoint, the Client VPN service invokes the Lambda function on your behalf. The Lambda function receives the device, user, and connection attributes. The user’s public IP address is one of the device attributes that are used to identify the user’s geolocation by using the AWS WAF geolocation feature. Only connections that are authorized by the Lambda function are allowed to connect to the Client VPN endpoint.

Note: The accuracy of the IP address to country lookup database varies by region. Based on recent tests, the overall accuracy for the IP address to country mapping is 99.8 percent. We recommend that you work with regulatory compliance experts to decide if your solution meets your compliance needs.

A NAT gateway allows resources in a private subnet to connect to the internet or other AWS services, but prevents a host on the internet from connecting to those resources. You must also specify an Elastic IP address to associate with the NAT gateway when you create it. Since an Elastic IP address is static, any request originating from a private subnet will be seen with a public IP address that you can trust because it will be the elastic IP address of your NAT gateway.

AWS Identity and Access Management (IAM) is a web service for securely controlling access to AWS services. You manage access in AWS by creating policies and attaching them to IAM identities (users, groups of users, or roles) or AWS resources. A policy is an object in AWS that, when associated with an identity or resource, defines their permissions. In an IAM policy, you can define the global condition key aws:SourceIp to restrict API calls to your AWS resources from specific IP addresses.

Note: Throughout this post, the user is authenticating with a SAML identity provider (IdP) and assumes an IAM role.

Figure 1 illustrates the authentication process when a user tries to establish a new Client VPN connection session.

Figure 1: Enforce connection to Client VPN from specific geolocations

Let’s look at how the process illustrated in Figure 1 works.

The user device initiates a new client VPN connection session.
The Client VPN service redirects the user to authenticate against an IdP.
After user authentication succeeds, the client connects to the Client VPN endpoint.
The Client VPN endpoint invokes the Lambda function synchronously. The function is invoked after device and user authentication, and before the authorization rules are evaluated.
The Lambda function extracts the public-ip device attribute from the input and makes an HTTPS request to the Amazon API Gateway endpoint, passing the user’s public IP address in the X-Forwarded-For header.Because you’re using AWS WAF to protect API Gateway, and have geographic match conditions configured, a response with the status code 200 is returned only if the user’s public IP address originates from an allowed country of origin. Additionally, AWS WAF has another rule configured that blocks all requests to API Gateway if the request doesn’t originate from one of the NAT gateway IP addresses. Because Lambda is deployed in a VPC, it has a NAT gateway IP address, and therefore the request isn’t blocked by AWS WAF. To learn more about running a Lambda function in a VPC, see Configuring a Lambda function to access resources in a VPC.The following code example showcases Lambda code that performs the described step.

Note: Optionally, you can implement additional controls by creating specific authorization rules. Authorization rules act as ﬁrewall rules that grant access to networks. You should have an authorization rule for each network for which you want to grant access. To learn more, see Authorization rules.
The Lambda function returns the authorization request response to Client VPN.
When the Lambda function—shown following—returns an allow response, Client VPN establishes the VPN session.

import os
import http.client


cloud_front_url = os.getenv("ENDPOINT_DNS")
endpoint = os.getenv("ENDPOINT")
success_status_codes = [200]


def build_response(allow, status):
    return {
        "allow": allow,
        "error-msg-on-failed-posture-compliance": "Error establishing connection. Please contact your administrator.",
        "posture-compliance-statuses": [status],
        "schema-version": "v1"
    }


def handler(event, context):
    ip = event['public-ip']

    conn = http.client.HTTPSConnection(cloud_front_url)
    conn.request("GET", f'/{endpoint}', headers={'X-Forwarded-For': ip})
    r1 = conn.getresponse()
    conn.close()

    status_code = r1.status

    if status_code in success_status_codes:
        print("User's IP is based from an allowed country. Allowing the connection to VPN.")
        return build_response(True, 'compliant')

    print("User's IP is NOT based from an allowed country. Blocking the connection to VPN.")
    return build_response(False, 'quarantined')

After the client VPN session is established successfully, the request from the user device flows through the NAT gateway. The originating source IP address is recognized, because it is the Elastic IP address associated with the NAT gateway. An IAM policy is defined that denies any request to your AWS resources that doesn’t originate from the NAT gateway Elastic IP address. By attaching this IAM policy to users, you can control which AWS resources they can access.

Figure 2 illustrates the process of a user trying to access an Amazon Simple Storage Service (Amazon S3) bucket.

Figure 2: Enforce access to AWS resources from specific IPs

Let’s look at how the process illustrated in Figure 2 works.

A user signs in to the AWS Management Console by authenticating against the IdP and assumes an IAM role.
Using the IAM role, the user makes a request to list Amazon S3 buckets. The IAM policy of the user is evaluated to form an allow or deny decision.
If the request is allowed, an API request is made to Amazon S3.

The aws:SourceIp condition key is used in a policy to deny requests from principals if the origin IP address isn’t the NAT gateway IP address. However, this policy also denies access if an AWS service makes calls on a principal’s behalf. For example, when you use AWS CloudFormation to provision a stack, it provisions resources by using its own IP address, not the IP address of the originating request. In this case, you use aws:SourceIp with the aws:ViaAWSService key to ensure that the source IP address restriction applies only to requests made directly by a principal.

IAM deny policy

The IAM policy doesn’t allow any actions. What the policy does is deny any action on any resource if the source IP address doesn’t match any of the IP addresses in the condition. Use this policy in combination with other policies that allow specific actions.

Prerequisites

Make sure that you have the following in place before you deploy the solution:

Client VPN to connect to a Client VPN endpoint. You can follow the AWS Client VPN download instructions to download the desktop client.
You must generate and import a private certificate into AWS Certificate Manager (ACM). The certificate is used to establish mutual authentication. Client VPN uses certificates to perform authentication between the client and the server.
An IdP, such as AWS Directory Service for Microsoft Active Directory, or an external IdP for user-based client VPN authentication. Then you use the same user to federate the sign-in to the console. To learn more and to configure your IdP client or AWS Managed Microsoft AD for authorization, see client authorization.

Implementation and deployment details

In this section, you create a CloudFormation stack that creates AWS resources for this solution. To start the deployment process, select the following Launch Stack button.

You also can download the CloudFormation template if you want to modify the code before the deployment.

The template in Figure 3 takes several parameters. Let’s go over the key parameters.

Figure 3: CloudFormation stack parameters

The key parameters are:

AuthenticationOption: Information about the authentication method to be used to authenticate clients. You can choose either AWS Managed Microsoft AD or IAM SAML identity provider for authentication.
AuthenticationOptionResourceIdentifier: The ID of the AWS Managed Microsoft AD directory to use for Active Directory authentication, or the Amazon Resource Number (ARN) of the SAML provider for federated authentication.
ServerCertificateArn: The ARN of the server certificate. The server certificate must be provisioned in ACM.
CountryCodes: A string of comma-separated country codes. For example: US,GB,DE. The country codes must be alpha-2 country ISO codes of the ISO 3166 international standard.
LambdaProvisionedConcurrency: Provisioned concurrency for the client connection handler. We recommend that you configure provisioned concurrency for the Lambda function to enable it to scale without fluctuations in latency.

All other input fields have default values that you can either accept or override. Once you provide the parameter input values and reach the final screen, choose Create stack to deploy the CloudFormation stack.

This template creates several resources in your AWS account, as follows:

A VPC and associated resources, such as InternetGateway, Subnets, ElasticIP, NatGateway, RouteTables, and SecurityGroup.
A Client VPN endpoint, which provides connectivity to your VPC.
A Lambda function, which is invoked by the Client VPN endpoint to determine the country origin of the user’s IP address.
An API Gateway for the Lambda function to make an HTTPS request.
AWS WAF in front of API Gateway, which only allows requests to go through to API Gateway if the user’s IP address is based in one of the allowed countries.
A deny policy with a NAT gateway IP addresses condition. Attaching this policy to a role or user enforces that the user can’t access your AWS resources unless they are connected to your client VPN.

Note: CloudFormation stack deployment can take up to 20 minutes to provision all AWS resources.

After creating the stack, there are two outputs in the Outputs section, as shown in Figure 4.

Figure 4: CloudFormation stack outputs

ClientVPNConsoleURL: The URL where you can download the client VPN configuration file.
IAMRoleClientVpnDenyIfNotNatIP: The IAM policy to be attached to an IAM role or IAM user to enforce access control.

Attach the IAMRoleClientVpnDenyIfNotNatIP policy to a role

This policy is used to enforce access to your AWS resources based on geolocation. Attach this policy to the role that you are using for testing the solution. You can use the steps in Adding IAM identity permissions to do so.

Configure the AWS client VPN desktop application

When you open the URL that you see in ClientVPNConsoleURL, you see the newly provisioned Client VPN endpoint. Select Download Client Configuration to download the configuration file.

Figure 5: Client VPN endpoint

Confirm the download request by selecting Download.

Figure 6: Client VPN Endpoint – Download Client Configuration

To connect to the Client VPN endpoint, follow the steps in Connect to the VPN. After a successful connection is established, you should see the message Connected. in your AWS Client VPN desktop application.

Figure 7: AWS Client VPN desktop application – established VPN connection

Troubleshooting

If you can’t establish a Client VPN connection, here are some things to try:

Confirm that the Client VPN connection has successfully established. It should be in the Connected state. To troubleshoot connection issues, you can follow this guide.
If the connection isn’t establishing, make sure that your machine has TCP port 35001 available. This is the port used for receiving the SAML assertion.
Validate that the user you’re using for testing is a member of the correct SAML group on your IdP.
Confirm that the IdP is sending the right details in the SAML assertion. You can use browser plugins, such as SAML-tracer, to inspect the information received in the SAML assertion.

Test the solution

Now that you’re connected to Client VPN, open the console, sign in to your AWS account, and navigate to the Amazon S3 page. Since you’re connected to the VPN, your origin IP address is one of the NAT gateway IPs, and the request is allowed. You can see your S3 bucket, if any exist.

Figure 8: Amazon S3 service console view – user connected to AWS Client VPN

Now that you’ve verified that you can access your AWS resources, go back to the Client VPN desktop application and disconnect your VPN connection. Once the VPN connection is disconnected, go back to the Amazon S3 page and reload it. This time you should see an error message that you don’t have permission to list buckets, as shown in Figure 9.

Figure 9: Amazon S3 service console view – user is disconnected from AWS Client VPN

Access has been denied because your origin public IP address is no longer one of the NAT gateway IP addresses. As mentioned earlier, since the policy denies any action on any resource without an established VPN connection to the Client VPN endpoint, access to all your AWS resources is denied.

Scale the solution in AWS Organizations

With AWS Organizations, you can centrally manage and govern your environment as you grow and scale your AWS resources. You can use Organizations to apply policies that give your teams the freedom to build with the resources they need, while staying within the boundaries you set. By organizing accounts into organizational units (OUs), which are groups of accounts that serve an application or service, you can apply service control policies (SCPs) to create targeted governance boundaries for your OUs. To learn more about Organizations, see AWS Organizations terminology and concepts.

SCPs help you to ensure that your accounts stay within your organization’s access control guidelines across all your accounts within OUs. In particular, these are the key benefits of using SCPs in your AWS Organizations:

You don’t have to create an IAM policy with each new account, but instead create one SCP and apply it to one or more OUs as needed.
You don’t have to apply the IAM policy to every IAM user or role, existing or new.
This solution can be deployed in a separate account, such as a shared infrastructure account. This helps to decouple infrastructure tooling from business application accounts.

The following figure, Figure 10, illustrates the solution in an Organizations environment.

Figure 10: Use SCPs to enforce policy across many AWS accounts

The Client VPN account is the account the solution is deployed into. This account can also be used for other networking related services. The SCP is created in the Organizations root account and attached to one or more OUs. This allows you to centrally control access to your AWS resources.

Let’s review the new condition that’s added to the IAM policy:

"ArnNotLikeIfExists": {
    "aws:PrincipalARN": [
    "arn:aws:iam::*:role/service-role/*"
    ]
}

The aws:PrincipalARN condition key allows your AWS services to communicate to other AWS services even though those won’t have a NAT IP address as the source IP address. For instance, when a Lambda function needs to read a file from your S3 bucket.

Note: Appending policies to existing resources might cause an unintended disruption to your application. Consider testing your policies in a test environment or to non-critical resources before applying them to production resources. You can do that by attaching the SCP to a specific OU or to an individual AWS account.

Cleanup

After you’ve tested the solution, you can clean up all the created AWS resources by deleting the CloudFormation stack.

Conclusion

In this post, we showed you how you can restrict IAM users to access AWS resources from specific geographic locations. You used Client VPN to allow users to establish a client VPN connection from a desktop. You used an AWS client connection handler (as a Lambda function), and API Gateway with AWS WAF to identify the user’s geolocation. NAT gateway IPs served as trusted source IPs, and an IAM policy protects access to your AWS resources. Lastly, you learned how to scale this solution to many AWS accounts with Organizations.

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

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Query Snowflake using Athena Federated Query and join with data in your Amazon S3 data lake

2021-07-15 Navnit Shukla

Post Syndicated from Navnit Shukla original https://aws.amazon.com/blogs/big-data/query-snowflake-using-athena-federated-query-and-join-with-data-in-your-amazon-s3-data-lake/

If you use data lakes in Amazon Simple Storage Service (Amazon S3) and use Snowflake as your data warehouse solution, you may need to join your data in your data lake with Snowflake. For example, you may want to build a dashboard by joining historical data in your Amazon S3 data lake and the latest data in your Snowflake data warehouse or create consolidated reporting.

In such use cases, Amazon Athena Federated Query allows you to seamlessly access the data from Snowflake without building ETL pipelines to copy or unload the data to the S3 data lake or Snowflake. This removes the overhead of creating additional extract, transform, and load (ETL) processes and shortens the development cycle.

In this post, we will walk you through a step-by-step configuration to set up Athena Federated Query using AWS Lambda to access data in a Snowflake data warehouse.

For this post, we are using the Snowflake connector for Amazon Athena developed by Trianz.

Let’s start with discussing the solution and then detailing the steps involved.

Solution overview

Data Federation refers to the capability to query data in another data store using a single interface (Amazon Athena). The following diagram depicts how a single Amazon Athena federated query uses Lambda to query the underlying data source and parallelizes execution across many workers.

To implement this solution, we complete the following steps:

Create a secret for the Snowflake instance using AWS Secrets Manager.
Create an S3 bucket and subfolder for Lambda to use.
Configure Athena federation with the Snowflake instance.
Run federated queries with Athena.

Prerequisites

Before getting started, make sure you have a Snowflake data warehouse up and running.

Create a secret for the Snowflake instance

Our first step is to create a secret for the Snowflake instance with a username and password using Secrets Manager.

On the Secrets Manager console, choose Secrets.
Choose Store a new secret.
Select Other types of secrets.
Enter the credentials as key-value pairs (username, password) for your Snowflake instance.
For Secret name, enter a name for your secret. Use the prefix snowflake so it’s easy to find.

Leave the remaining fields at their defaults and choose Next.
Complete your secret creation.

Create an S3 bucket for Lambda

On the Amazon S3 console, create a new S3 bucket and subfolder for Lambda to use. For this post, we use athena-accelerator/snowflake.

Configure Athena federation with the Snowflake instance

To configure Athena data source connector for Snowflake with your Snowflake instance, complete the following steps:

On the AWS Serverless Application Repository console, choose Available applications.
In the search field, enter TrianzSnowflakeAthenaJDBC.

For Application name, enter TrianzSnowflakeAthenaJDBC.
For SecretNamePrefix, enter trianz-snowflake-athena.
For SpillBucket, enter Athena-accelerator/snowflake.
For JDBCConnectorConfig, use the format snowflake://jdbc:snowflake://{snowflake_instance_url}/?warehouse={warehousename}&db={databasename}&schema={schemaname}&${secretname}

For example, we enter snowflake://jdbc:snowflake://trianz.snowflakecomputing.com/?warehouse=ATHENA_WH&db=ATHENA_DEV&schema=ATHENA&${trianz-snowflake-athena}DisableSpillEncyption – False

For LambdaFunctionName, enter trsnowflake.
For SecurityGroupID, enter the security group ID where the Snowflake instance is deployed.

Make sure to apply valid inbound and outbound rules based on your connection.

For SpillPrefix, create a folder under the S3 bucket you created and specify the name (for example, athena-spill).
For Subnetids, use the subnets where the Snowflake instance is running with comma separation.

Make sure the subnet is in a VPC and has NAT gateway and internet gateway attached.

Select the I acknowledge check box.
Choose Deploy.

Make sure that the AWS Identity and Access Management (IAM) roles have permissions to access AWS Serverless Application Repository, AWS CloudFormation, Amazon S3, Amazon CloudWatch, AWS CloudTrail, Secrets Manager, Lambda, and Athena. For more information, see Example IAM Permissions Policies to Allow Athena Federated Query.

Run federated queries with Athena

Before running your federated query, be sure that you have selected Athena engine version 2. The current Athena engine version for any workgroup can be found in the Athena console page.

Run your federated queries using lambda:trsnowflake to run against tables in the Snowflake database. This is the name of lambda function which we have created in step 7 of previous section of this blog.

lambda:trsnowflake is a reference data source connector Lambda function using the format lambda:MyLambdaFunctionName. For more information, see Writing Federated Queries.

The following screenshot is a unionall query example of data in Amazon S3 with a table in the AWS Glue Data Catalog and a table in Snowflake.

Key performance best practices

If you’re considering Athena Federated Query with Snowflake, we recommend the following best practices:

Athena Federated query works great for queries with predicate filtering because the predicates are pushed down to the Snowflake database. Use filter and limited-range scans in your queries to avoid full table scans.
If your SQL query requires returning a large volume of data from Snowflake to Athena (which could lead to query timeouts or slow performance), you may consider copying data from Snowflake to your S3 data lake.
The Snowflake schema, which is an extension of the star schema, is used as a data model in Snowflake. In the Snowflake schema model, unload your large fact tables into your S3 data lake and leave the dimension tables in Snowflake. If large dimension tables are contributing to slow performance or query timeouts, unload those tables to your S3 data lake.
When you run federated queries, Athena spins up multiple Lambda functions, which causes a spike in database connections. It’s important to monitor the Snowflake database WLM queue slots to ensure there is no queuing. Additionally, you can use concurrency scaling on your Snowflake database cluster to benefit from concurrent connections to queue up.

Conclusion

In this post, you learned how to configure and use Athena federated with Snowflake using Lambda. With Athena Federated query user can leverage all of their data to produce analytics, derive business value without building ETL pipelines to bring data from different datastore such as Snowflake to Data Lake.

You can use the best practice considerations outlined in the post to help minimize the data transferred from Snowflake for better performance. When queries are well written for federation, the performance penalties are negligible.

For more information, see the Athena User Guide and Using Amazon Athena Federated Query.

About the Author

Navnit Shukla is AWS Specialist Solution Architect in Analytics. He is passionate about helping customers uncover insights from their data. He has been building solutions to help organizations make data-driven decisions.

Architecting a Highly Available Serverless, Microservices-Based Ecommerce Site

2021-07-15 Senthil Kumar

Post Syndicated from Senthil Kumar original https://aws.amazon.com/blogs/architecture/architecting-a-highly-available-serverless-microservices-based-ecommerce-site/

The number of ecommerce vendors is growing globally—they often handle large traffic at different times of the day and different days of the year. This, in addition to building, managing, and maintaining IT infrastructure on-premises data centers can present challenges to ecommerce businesses’ scalability and growth.

This blog provides you a Serverless on AWS solution that offloads the undifferentiated heavy lifting of managing resources and ensures your businesses’ architecture can handle peak traffic.

Common architecture set up versus serverless solution

The following sections describe a common monolithic architecture and our suggested alternative approach: setting up microservices-based order submission and product search modules. These modules are independently deployable and scalable.

Typical monolithic architecture

Figure 1 shows how a typical on-premises ecommerce infrastructure with different tiers is set up:

Web servers serve static assets and proxy requests to application servers
Application servers process ecommerce business logic and authentication logic
Databases store user and other dynamic data
Firewall and load balancers provide network components for load balancing and network security

Figure 1. Monolithic on-premises ecommerce infrastructure with different tiers

Monolithic architecture tightly couples different layers of the application. This prevents them from being independently deployed and scaled.

Microservices-based modules

Order submission workflow module

This three-layer architecture can be set up in the AWS Cloud using serverless components:

Static content layer (Amazon CloudFront and Amazon Simple Storage Service (Amazon S3)). This layer stores static assets on Amazon S3. By using CloudFront in front of the S3 storage cache, you can deliver assets to customers globally with low latency and high transfer speeds.
Authentication layer (Amazon Cognito or customer proprietary layer). Ecommerce sites deliver authenticated and unauthenticated content to the user. With Amazon Cognito, you can manage users’ sign-up, sign-in, and access controls, so this authentication layer ensures that only authenticated users have access to secure data.
Dynamic content layer (AWS Lambda and Amazon DynamoDB). All business logic required for the ecommerce site is handled by the dynamic content layer. Using Lambda and DynamoDB ensures that these components are scalable and can handle peak traffic.

As shown in Figure 2, the order submission workflow is split into two sections: synchronous and asynchronous.

By splitting the order submission workflow, you allow users to submit their order details and get an orderId. This makes sure that they don’t have to wait for backend processing to complete. This helps unburden your architecture during peak shopping periods when the backend process can get busy.

Figure 2. Microservices-based order submission workflow

The details of the order, such as credit card information in encrypted form, shipping information, etc., are stored in DynamoDB. This action invokes an asynchronous workflow managed by AWS Step Functions.

Figure 3 shows sample step functions from the asynchronous process. In this scenario, you are using external payment processing and shipping systems. When both systems get busy, step functions can manage long-running transactions and also the required retry logic. It uses a decision-based business workflow, so if a payment transaction fails, the order can be canceled. Or, once payment is successful, the order can proceed.

Amazon Simple Notification Service (Amazon SNS) notifies users whenever their order status changes. You can even extend Step Functions to have it react based on status of shipping.

Figure 3. Sample AWS Step Functions asynchronous workflow that uses external payment processing service and shipping system

Product search module

Our product search module is set up using the following serverless components:

Amazon Elasticsearch Service (Amazon ES) stores product data, which is updated whenever product-related data changes.
Lambda formats the data.
Amazon API Gateway allows users to search without authentication. As shown in Figure 4, searching for products on the ecommerce portal does not require users to log in. All traffic via API Gateway is unauthenticated.

Figure 4. Microservices-based product search workflow module with dynamic traffic through API Gateway

Replicating data across Regions

If your ecommerce application runs on multiple Regions, it may require the content and data to be replicated. This allows the application to handle local traffic from that Region and also act as a failover option if the application fails in another Region. The content and data are replicated using the multi-Region replication features of Amazon S3 and DynamoDB global tables.

Figure 5 shows a multi-Region ecommerce site built on AWS with serverless services. It uses the following features to make sure that data between all Regions are in sync for data/assets that do not need data residency compliance:

Amazon S3 multi-Region replication keeps static assets in sync for assets.
DynamoDB global tables keeps dynamic data in sync across Regions.

Assets that are specific to their Region are stored in Regional specific buckets.

Figure 5. Data replication for a multi-Region ecommerce website built using serverless components

Amazon Route 53 DNS web service manages traffic failover from one Region to another. Route 53 provides different routing policies, and depending on your business requirement, you can choose the failover routing policy.

Best practices

Now that we’ve shown you how to build these applications, make sure you follow these best practices to effectively build, deploy, and monitor the solution stack:

Infrastructure as Code (IaC). A well-defined, repeatable infrastructure is important for managing any solution stack. AWS CloudFormation allows you to treat your infrastructure as code and provides a relatively easy way to model a collection of related AWS and third-party resources.
AWS Serverless Application Model (AWS SAM). An open-source framework. Use it to build serverless applications on AWS.
Deployment automation. AWS CodePipeline is a fully managed continuous delivery service that automates your release pipelines for fast and reliable application and infrastructure updates.
AWS CodeStar. Allows you to quickly develop, build, and deploy applications on AWS. It provides a unified user interface, enabling you to manage all of your software development activities in one place.
AWS Well-Architected Framework. Provides a mechanism for regularly evaluating your workloads, identifying high risk issues, and recording your improvements.
Serverless Applications Lens. Documents how to design, deploy, and architect serverless application workloads.
Monitoring. AWS provides many services that help you monitor and understand your applications, including Amazon CloudWatch, AWS CloudTrail, and AWS X-Ray.

Conclusion

In this blog post, we showed you how to architect a highly available, serverless, and microservices-based ecommerce website that operates in multiple Regions.

We also showed you how to replicate data between different Regions for scaling and if your workload fails. These serverless services reduce the burden of building and managing physical IT infrastructure to help you focus more on building solutions.

Related information

10 Things Serverless Architects Should Know

Integrating Amazon Connect and Amazon Lex with Third-party Systems

2021-07-15 Steven Warwick

Post Syndicated from Steven Warwick original https://aws.amazon.com/blogs/architecture/integrating-amazon-connect-and-amazon-lex-with-third-party-systems/

AWS customers who provide software solutions that integrate with AWS often require design patterns that offer some flexibility. They must build, support, and expand products and solutions to meet their end user business requirements. These design patterns must use the underlying services and infrastructure through API operations. As we will show, third-party solutions can integrate with Amazon Connect to initiate customer-specific workflows. You don’t need specific utterances when using Amazon Lex to convert speech to text.

Introduction to Amazon Connect workflows

Platform as a service (PaaS) systems are built to handle a variety of use cases with various inputs. These inputs are provided by upstream systems and sometimes result in complex integrations. For example, when creating a call center management solution, these workflows may require opaque transcription data to be sent to downstream third-party system. This pattern allows the caller to interact with a third-party system with an Amazon Connect flow. The solution allows for communication to occur multiple times. Opaque transcription data is transferred between the Amazon Connect contact flow, through Amazon Lex, and then to the third-party system. The third-party system can modify and update workflows without affecting the Amazon Connect or Amazon Lex systems.

API workflow use case

AnyCompany Tech (our hypothetical company) is a PaaS company that allows other companies to quickly build workflows with their tools. It provides the ability to take customer calls with a request-response style interaction. AnyCompany built an API into the Amazon Connect flow to allow their end users to return various response types. Examples of the response types are “disconnect,” “speak,” and “failed.”

Using Amazon Connect, AnyCompany allows their end users to build complex workflows using a basic question-response API. Each customer of AnyCompany can build workflows that respond to a voice input. It is processed via the high-quality speech recognition and natural language understanding capabilities of Amazon Lex. The caller is prompted by “What is your question?” Amazon Lex processes the audio input then invokes a Lambda function that connects to AnyCompany Tech. They in turn initiate their customer’s unique workflow. The customer’s workflow may change over time without requiring any further effort from AnyCompany Tech.

Questions graph database use case

AnyCompany Storage is a company that has a graph database that stores documents and information correlating the business to its inventory, sales, marketing, and employees. Accessing this database will be done via a question-response API. For example, such questions might be: “What are our third quarter earnings?”, “Do we have product X in stock?”, or “When was Jane Doe hired?” The company wants the ability to have their employees call in and after proper authentication, ask any question of the system and receive a response. Using the architecture in Figure 1, the company can link their Amazon Connect implementation up to this API. The output from Amazon Lex is passed into the API, a response is received, and it is then passed to Amazon Connect.

Amazon Connect third-party system architecture

Figure 1. End-customer call flow

User calls Amazon Connect using the telephone number for the connect instance.
Amazon Connect receives the incoming call and starts an Amazon Connect contact flow. This Amazon Connect flow captures the caller’s utterance and forwards it to Amazon Lex.
Amazon Lex starts the requested bot. The Amazon Lex bot translates the caller’s utterance into text and sends it to AWS Lambda via an event.
AWS Lambda accepts the incoming data, transforms or enhances it as needed, and calls out to the external API via some transport
The external API processes the content sent to it from AWS Lambda.
The external API returns a response back to AWS Lambda.
AWS Lambda accepts the response from the external API, then forwards this response to Amazon Lex.
Amazon Lex returns the response content to Amazon Connect.
Amazon Connect processes the response.

Solution components

Amazon Connect

Amazon Connect allows customer calls to get information from the third-party system. An Amazon Connect contact flow is required to get the callers input, which is then sent to Amazon Lex. The Amazon Lex bot must be granted permission to interact with an Amazon Connect contact flow. As shown in Figure 2, the Get customer input block must call the fallback intent of the Amazon Lex bot. Figure 2 demonstrates a basic flow used to get input, check the response, and perform an action.

Figure 2. Basic Amazon Connect contact flow to integrate with Amazon Lex

Amazon Lex

Amazon Lex converts the voice given by a caller into text, which is then processed by a Lambda function. When setting up the Amazon Lex bot you will require one fallback intent (Figure 3), one unused intent (Figure 4), and one clarification prompts disabled (Figure 5).

Figure 3. Amazon Lex fallback intent

The fallback intent is created by using the pre-defined AMAZON.FallbackIntent and must be set up to call a Lambda function in the Fulfillment section. Using the fallback intent and Lambda fulfillment causes the system to ignore any utterance pattern and pass any translation directly to the Lambda function.

Figure 4. Amazon Lex unused intent

The unused intent is only created to satisfy Amazon Lex’s requirement for a bot to have at least one custom intent with a valid utterance.

Figure 5. Amazon Lex error handling clarification prompts

In the error handling section of the Amazon Lex bot, the clarification prompts must be disabled. Disabling the clarification prompts stops the Amazon Lex bot from asking the caller to clarify the input.

AWS Lambda

AWS Lambda is called by Amazon Lex, which is used to interact with the third-party system. The third-party system will return values, which the Lambda will add to its session attributes resulting object. The resulting object from AWS Lambda requires the dialog action to be set up with the type set to “Close,” fulfillmentState set to “Fulfilled,” and the message contentType set to “CustomPayload”. This will allow Amazon Lex to pass the values to Amazon Connect without speaking the results to the caller.

Conclusion

In this blog we showed how Amazon Connect, Amazon Lex, and AWS Lambda functions can be used together to create common interactions with third-party systems. This is a flexible architecture and requires few changes to the Amazon Connect contact flow. You don’t have to set up pre-defined utterances that limit the allowed inputs. Using this solution, AWS customers can provide flexible solutions that interact with third-party systems.

Related information

Auto scaling Amazon Kinesis Data Streams using Amazon CloudWatch and AWS Lambda

2021-07-14 Matthew Nolan

Post Syndicated from Matthew Nolan original https://aws.amazon.com/blogs/big-data/auto-scaling-amazon-kinesis-data-streams-using-amazon-cloudwatch-and-aws-lambda/

This post is co-written with Noah Mundahl, Director of Public Cloud Engineering at United Health Group.

In this post, we cover a solution to add auto scaling to Amazon Kinesis Data Streams. Whether you have one stream or many streams, you often need to scale them up when traffic increases and scale them down when traffic decreases. Scaling your streams manually can create a lot of operational overhead. If you leave your streams overprovisioned, costs can increase. If you want the best of both worlds—increased throughput and reduced costs—then auto scaling is a great option. This was the case for United Health Group. Their Director of Public Cloud Engineering, Noah Mundahl, joins us later in this post to talk about how adding this auto scaling solution impacted their business.

Overview of solution

In this post, we showcase a lightweight serverless architecture that can auto scale one or many Kinesis data streams based on throughput. It uses Amazon CloudWatch, Amazon Simple Notification Service (Amazon SNS), and AWS Lambda. A single SNS topic and Lambda function process the scaling of any number of streams. Each stream requires one scale-up and one scale-down CloudWatch alarm. For an architecture that uses Application Auto Scaling, see Scale Amazon Kinesis Data Streams with AWS Application Auto Scaling.

The workflow is as follows:

Metrics flow from the Kinesis data stream into CloudWatch (bytes/second, records/second).
Two CloudWatch alarms, scale-up and scale-down, evaluate those metrics and decide when to scale.
When one of these scaling alarms triggers, it sends a message to the scaling SNS topic.
The scaling Lambda function processes the SNS message:
1. The function scales the data stream up or down using UpdateShardCount:
  1. Scale-up events double the number of shards in the stream
  2. Scale-down events halve the number of shards in the stream
2. The function updates the metric math on the scale-up and scale-down alarms to reflect the new shard count.

Implementation

The scaling alarms rely on CloudWatch alarm metric math to calculate a stream’s maximum usage factor. This usage factor is a percentage calculation from 0.00–1.00, with 1.00 meaning the stream is 100% utilized in either bytes per second or records per second. We use the usage factor for triggering scale-up and scale-down events. Our alarms use the following usage factor thresholds to trigger scaling events: >= 0.75 for scale-up and < 0.25 for scale-down. We use 5-minute data points (period) on all alarms because they’re more resistant to Kinesis traffic micro spikes.

Scale-up usage factor

The following screenshot shows the metric math on a scale-up alarm.

The scale-up max usage factor for a stream is calculated as follows:

s1 = Current shard count of the stream
m1 = Incoming Bytes Per Period, directly from CloudWatch metrics
m2 = Incoming Records Per Period, directly from CloudWatch metrics
e1 = Incoming Bytes Per Period with missing data points filled by zeroes
e2 = Incoming Records Per Period with missing data points filled by zeroes
e3 = Incoming Bytes Usage Factor 
   = Incoming Bytes Per Period / Max Bytes Per Period
   = e1/(1024*1024*60*$kinesis_period_mins*s1)
e4 = Incoming Records Usage Factor  
   = Incoming Records Per Period / Max Records Per Period 
   = e2/(1000*60*$kinesis_period_mins*s1) 
e6 = Max Usage Factor: Incoming Bytes or Incoming Records 
   = MAX([e3,e4])

Scale-down usage factor

We calculate the scale-down usage factor the same as the scale-up usage factor with some additional metric math to (optionally) take into account the iterator age of the stream to block scale-downs when stream processing is falling behind. This is useful if you’re using Lambda functions per shard, known as the Parallelization Factor, to process your streams. If you have a backlog of data, scaling down reduces the number of Lambda functions you need to process that backlog.

The following screenshot shows the metric math on a scale-down alarm.

The scale-down max usage factor for a stream is calculated as follows:

s1 = Current shard count of the stream
s2 = Iterator Age (in minutes) after which we begin blocking scale downs	
m1 = Incoming Bytes Per Period, directly from CloudWatch metrics
m2 = Incoming Records Per Period, directly from CloudWatch metrics
e1 = Incoming Bytes Per Period with missing data points filled by zeroes
e2 = Incoming Records Per Period with missing data points filled by zeroes
e3 = Incoming Bytes Usage Factor 
   = Incoming Bytes Per Period / Max Bytes Per Period
   = e1/(1024*1024*60*$kinesis_period_mins*s1)
e4 = Incoming Records Usage Factor  
   = Incoming Records Per Period / Max Records Per Period 
   = e2/(1000*60*$kinesis_period_mins*s1)
e5 = Iterator Age Adjusted Factor 
   = Scale Down Threshold * (Iterator Age Minutes / Iterator Age Minutes to Block Scale Down)
   = $kinesis_scale_down_threshold * ((FILL(m3,0)*1000/60)/s2)
e6 = Max Usage Factor: Incoming Bytes, Incoming Records, or Iterator Age Adjusted Factor
   = MAX([e3,e4,e5])

Deployment

You can deploy this solution via AWS CloudFormation. For more information, see the GitHub repo.

If you need to generate traffic on your streams for testing, consider using the Amazon Kinesis Data Generator. For more information, see Test Your Streaming Data Solution with the New Amazon Kinesis Data Generator.

Optum’s story

As the health services innovation arm of UnitedHealth Group, Optum has been on a multi-year journey towards advancing maturity and capabilities in the public cloud. Our multi-cloud strategy includes using many cloud-native services offered by AWS. The elasticity and self-healing features of the public cloud are among of its many strengths, and we use the automation provided natively by AWS through auto scaling capabilities. However, some services don’t natively provide those capabilities, such as Kinesis Data Streams. That doesn’t mean that we’re complacent and accept inelasticity.

Reducing operational toil

At the scale Optum operates at in the public cloud, monitoring for errors or latency related to our Kinesis data stream shard count and manually adjusting those values in response could become a significant source of toil for our public cloud platform engineering teams. Rather than engaging in that toil, we prefer to engineer automated solutions that respond much faster than humans and help us maintain performance, data resilience, and cost-efficiency.

Serving our mission through engineering

Optum is a large organization with thousands of software engineers. Our mission is to help people live healthier lives and help make the health system work better for everyone. To accomplish that mission, our public cloud platform engineers must act as force multipliers across the organization. With solutions such as this, we ensure that our engineers can focus on building and not on responding to needless alerts.

Conclusion

In this post, we presented a lightweight auto scaling solution for Kinesis Data Streams. Whether you have one stream or many streams, this solution can handle scaling for you. The benefits include less operational overhead, increased throughput, and reduced costs. Everything you need to get started is available on the Kinesis Auto Scaling GitHub repo.

About the authors

Matthew Nolan is a Senior Cloud Application Architect at Amazon Web Services. He has over 20 years of industry experience and over 10 years of cloud experience. At AWS he helps customers rearchitect and reimagine their applications to take full advantage of the cloud. Matthew lives in New England and enjoys skiing, snowboarding, and hiking.

Paritosh Walvekar is a Cloud Application Architect with AWS Professional Services, where he helps customers build cloud native applications. He has a Master’s degree in Computer Science from University at Buffalo. In his free time, he enjoys watching movies and is learning to play the piano.

Noah Mundahl is Director of Public Cloud Engineering at United Health Group.

Intelligently Search Media Assets with Amazon Rekognition and Amazon ES

2021-07-14 Sridhar Chevendra

Post Syndicated from Sridhar Chevendra original https://aws.amazon.com/blogs/architecture/intelligently-search-media-assets-with-amazon-rekognition-and-amazon-es/

Media assets have become increasingly important to industries like media and entertainment, manufacturing, education, social media applications, and retail. This is largely due to innovations in digital marketing, mobile, and ecommerce.

Successfully locating a digital asset like a video, graphic, or image reduces costs related to reproducing or re-shooting. An efficient search engine is critical to quickly delivering something like the latest fashion trends. This in turn increases customer satisfaction, builds brand loyalty, and helps increase businesses’ online footprints, ultimately contributing towards revenue.

This blog post shows you how to build automated indexing and search functions using AWS serverless managed artificial intelligence (AI)/machine learning (ML) services. This architecture provides high scalability, reduces operational overhead, and scales out/in automatically based on the demand, with a flexible pay-as-you-go pricing model.

Automatic tagging and rich metadata with Amazon ES

Asset libraries for images and videos are growing exponentially. With Amazon Elasticsearch Service (Amazon ES), this media is indexed and organized, which is important for efficient search and quick retrieval.

Adding correct metadata to digital assets based on enterprise standard taxonomy will help you narrow down search results. This includes information like media formats, but also richer metadata like location, event details, and so forth. With Amazon Rekognition, an advanced ML service, you do not need to tag and index these media assets. This automatic tagging and organization frees you up to gain insights like sentiment analysis from social media.

Figure 1 is tagged using Amazon Rekognition. You can see how rich metadata (Apparel, T-Shirt, Person, and Pills) is extracted automatically. Without Amazon Rekognition, you would have to manually add tags and categorize the image. This means you could only do a keyword search on what’s manually tagged. If the image was not tagged, then you likely wouldn’t be able to find it in a search.

Figure 1. An image tagged automatically with Amazon Rekognition

Data ingestion, organization, and storage with Amazon S3

As shown in Figure 2, use Amazon Simple Storage Service (Amazon S3) to store your static assets. It provides high availability and scalability, along with unlimited storage. When you choose Amazon S3 as your content repository, multiple data providers are configured for data ingestion for future consumption by downstream applications. In addition to providing storage, Amazon S3 lets you organize data into prefixes based on the event type and captures S3 object mutations through S3 event notifications.

Figure 2. Solution overview diagram

S3 event notifications are invoked for a specific prefix, suffix, or combination of both. They integrate with Amazon Simple Queue Service (Amazon SQS), Amazon Simple Notification Service (Amazon SNS), and AWS Lambda as targets. (Refer to the Amazon S3 Event Notifications user guide for best practices). S3 event notification targets vary across use cases. For media assets, Amazon SQS is used to decouple the new data objects ingested into S3 buckets and downstream services. Amazon SQS provides flexibility over the data processing based on resource availability.

Data processing with Amazon Rekognition

Once media assets are ingested into Amazon S3, they are ready to be processed. Amazon Rekognition determines the entities within each asset. Amazon Rekognition then extracts the entities in JSON format and assigns a confidence score.

If the confidence score is below the defined threshold, use Amazon Augmented AI (A2I) for further review. A2I is an ML service that helps you build the workflows required for human review of ML predictions.

Amazon Rekognition also supports custom modeling to help identify entities within the images for specific business needs. For instance, a campaign may need images of products worn by a brand ambassador at a marketing event. Then they may need to further narrow their search down by the individual’s name or age demographic.

Using our solution, a Lambda function invokes Amazon Rekognition to extract the entities from the ingested assets. Lambda continuously polls the SQS queue for any new messages. Once a message is available, the Lambda function invokes the Amazon Rekognition endpoint to extract the relevant entities.

The following is a sample output from detect_labels API call in Amazon Rekognition and the transformed output that will be updated to downstream search engine:

{'Labels': [{'Name': 'Clothing', 'Confidence': 99.98137664794922, 'Instances': [], 'Parents': []}, {'Name': 'Apparel', 'Confidence': 99.98137664794922,'Instances': [], 'Parents': []}, {'Name': 'Shirt', 'Confidence': 97.00833129882812, 'Instances': [], 'Parents': [{'Name': 'Clothing'}]}, {'Name': 'T-Shirt', 'Confidence': 76.36670684814453, 'Instances': [{'BoundingBox': {'Width': 0.7963646650314331, 'Height': 0.6813027262687683, 'Left':
0.09593021124601364, 'Top': 0.1719706505537033}, 'Confidence': 53.39663314819336}], 'Parents': [{'Name': 'Clothing'}]}], 'LabelModelVersion': '2.0', 'ResponseMetadata': {'RequestId': '3a561e82-badc-4ba0-aa77-39a13f1bb3a6', 'HTTPStatusCode': 200, 'HTTPHeaders': {'content-type': 'application/x-amz-json-1.1', 'date': 'Mon, 17 May 2021 18:32:27 GMT', 'x-amzn-requestid': '3a561e82-badc-4ba0-aa77-39a13f1bb3a6','content-length': '542', 'connection': 'keep-alive'}, 'RetryAttempts': 0}}

As shown, the Lambda function submits an API call to Amazon Rekognition, where a T-shirt image in .jpeg format is provided as the input. Based on your confidence score threshold preference, Amazon Rekognition will prompt you to initiate a human review using Amazon A2I. It will also prompt you to use Amazon Rekognition Custom Labels to train the custom models. Lambda then identifies and arranges the labels and updates the specified index.

Indexing with Amazon ES

Amazon ES is a managed search engine service that provides enterprise-grade search engine capability for applications. In our solution, assets are searched based on entities that are used as metadata to update the index. Amazon ES is hosted as a public endpoint or a VPC endpoint for secure access within the specified AWS account.

Labels are identified and marked as tags, which are assigned to .jpeg formatted images. The following sample output shows the query on one of the tags issued on an Amazon ES cluster.

Query:

curl-XGET https://<ElasticSearch Endpoint>/<_IndexName>/_search?q=T-Shirt

Output:

{"took":140,"timed_out":false,"_shards":{"total":5,"successful":5,"skipped":0,"failed":0},"hits":{"total":{"value":1,"relation":"eq"},"max_score":0.05460011,"hits":[{"_index":"movies","_type":"_doc","_id":"15","_score":0.05460011,"_source":{"fileName":"s7-1370766_lifestyle.jpg","objectTags":["Clothing","Apparel","Sailor
Suit","Sleeve","T-Shirt","Shirt","Jersey"]}}]}}

In addition to photos, Amazon Rekognition also detects the labels on videos. It can recognize labels and identify characters and entities. These are then added to Amazon ES to enhance search capability. This allows users to skip to specific parts of a video for quick searchability. For instance, a marketer may need images of cashmere sweaters from a fashion show that was streamed and recorded.

Once the raw video clip is identified, it is then converted using Amazon Elastic Transcoder to play back on mobile devices, tablets, web browsers, and connected televisions. Elastic Transcoder is a highly scalable and cost-effective media transcoding service in the cloud. Segmented output renditions are created for delivery using the multiple protocols to compatible devices.

Conclusion

This blog describes AWS services that can be applied to diverse set of use cases for tagging and efficient search of images and videos. You can build automated indexing and search using AWS serverless managed AI/ML services. They provide high scalability, reduce operational overhead, and scale out/in automatically based on the demand, with a flexible pay-as-you-go pricing model.

To get started, use these references to create your own sample architectures:

Query your Oracle database using Athena Federated Query and join with data in your Amazon S3 data lake

2021-07-13 Navnit Shukla

Post Syndicated from Navnit Shukla original https://aws.amazon.com/blogs/big-data/query-your-oracle-database-using-athena-federated-query-and-join-with-data-in-your-amazon-s3-data-lake/

If you use data lakes in Amazon Simple Storage Service (Amazon S3) and use Oracle as your transactional data store, you may need to join the data in your data lake with Oracle on Amazon Relational Database Service (Amazon RDS), Oracle running on Amazon Elastic Compute Cloud (Amazon EC2), or an on-premises Oracle database, for example to build a dashboard or create consolidated reporting.

In these use cases, Amazon Athena Federated Query allows you to seamlessly access the data you’re your Oracle database without having to move the data to the S3 data lake. This removes the overhead in managing such jobs.

In this post, we walk you through a step-by-step configuration to set up Athena Federated query using AWS Lambda to access data in Oracle on Amazon RDS.

For this post, we will be using the Oracle Athena Federated query connector developed by Trianz. The runtime includes Oracle XE running on Amazon EC2 and Amazon RDS. Your Oracle instance can be on Amazon RDS, Amazon EC2, or on premises. You can deploy the Trianz Oracle AFQ connector available in the AWS Serverless Application Repository.

Let’s start with discussing the solution and then detailing the steps involved.

Solution overview

Data federation is the capability to integrate data in another data store using a single interface (Amazon Athena). The following diagram depicts how Athena federation works by using Lambda to integrate with a federated data source.

To implement this solution, we complete the following steps:

Create a secret for the Oracle instance using AWS Secrets Manager.
Create an S3 bucket and subfolder for Lambda to use.
Configure Athena federation with the Oracle XE instance.
Run federated queries with Athena.

Prerequisites

Before getting started, make sure you have an Oracle database up and running.

Create a secret for the Oracle instance

Our first step is to create a secret for the Oracle instance with a username and password using Secrets Manager.

On the Secrets Manager console, choose Secrets.
Choose Store a new secret.
Select Other types of secrets.
Enter the credentials as key-value pairs (username, password) for your Oracle XE instance.

For Secret name, enter a name for your secret. Use the prefix OracleAFQ so it’s easy to find.
Leave the remaining fields at their defaults and choose Next.
Complete your secret creation.

Create an S3 bucket for Lambda

On the Amazon S3 console, create a new S3 bucket and subfolder for Lambda to use. For this post, I use athena-accelerator/oracle.

Configure Athena federation with the Oracle XE instance

To configure Athena federation with your Oracle instance, complete the following steps:

On the AWS Serverless Application Repository console, choose Available applications.
In the search field, enter TrianzOracleAthenaJDBC.

For Application name, enter TrianzOracleAthenaJDBC.
For SecretNamePrefix, enter OracleAFQ_XE.
For SpillBucket, enter Athena-accelerator/oracle.
For JDBCConnectorConfig, use the format oracle://jdbc:oracle:thin:${secretname}@//hostname:port/servicename.

For example, we enter oracle://jdbc:oracle:thin:${OracleAFQ_XE}@//12.345.67.89:1521/xe.

For DisableSpillEncryption, enter false.
For LambdaFunctionName, enter oracleconnector.
For SecurityGroupID, enter the security group ID where the Oracle instance is deployed.

Make sure to apply valid inbound and outbound rules based on your connection.

For SpillPrefix, create a folder under the S3 bucket you created and specify the name (for example, athena-spill).
For Subnetids, use the subnets where the Oracle instance is running with comma separation.

Make sure the subnet is in a VPC and has NAT gateway and internet gateway attached.

Select the I acknowledge check box.
Choose Deploy.

Make sure that the AWS Identity and Access Management (IAM) roles have permissions to access AWS Serverless Application Repository, AWS CloudFormation, Amazon S3, Amazon CloudWatch, AWS CloudTrail, Secrets Manager, Lambda, and Athena. For more information, see Example IAM Permissions Policies to Allow Athena Federated Query.

Run federated queries with Athena

Run your federated queries using lambda:trianzoracle against tables in the Oracle database. trianzoracle is the name of lambda function which we have created in step 7 of previous section of this blog

lambda:trianzoracle is a reference data source connector Lambda function using the format lambda:MyLambdaFunctionName. For more information, see Writing Federated Queries.

The following query joins the dataset between Oracle and the S3 data lake.

Key performance best practices

If you’re considering Athena Federated query with Oracle, we recommend the following best practices:

Athena Federated query works great for queries with predicate filtering because the predicates are pushed down to the Oracle database. Use filter and limited-range scans in your queries to avoid full table scans.
If your SQL query requires returning a large volume of data from the Oracle database to Athena (which could lead to query timeouts or slow performance), unload the large tables in your query from Oracle to your S3 data lake.
The star schema is a commonly used data model in Oracle. In the star schema model, unload your large fact tables into your S3 data lake and leave the dimension tables in Oracle. If large dimension tables are contributing to slow performance or query timeouts, unload those tables to your S3 data lake.
When you run federated queries, Athena spins up multiple Lambda functions, which causes a spike in database connections. It’s important to monitor the Oracle database WLM queue slots to ensure there is no queuing. Additionally, you can use concurrency scaling on your Oracle database cluster to benefit from concurrent connections to queue up.

Conclusion

In this post, you learned how to configure and use Athena Federated query with Oracle. Now you don’t need to wait for all the data in your Oracle data warehouse to be unloaded to Amazon S3 and maintained on a day-to-day basis to run your queries.

You can use the best practice considerations outlined in the post to help minimize the data transferred from Oracle for better performance. When queries are well written for Federated query, the performance penalties are negligible.

For more information, see the Athena User Guide and Using Amazon Athena Federated Query.