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AWS Fault Injection Service (FIS) helps you to put chaos engineering into practice at scale. Today we are launching new scenarios that will let you demonstrate that your applications perform as intended if an AWS Availability Zone experiences a full power interruption or connectivity from one AWS region to another is lost.

You can use the scenarios to conduct experiments that will build confidence that your application (whether single-region or multi-region) works as expected when something goes wrong, help you to gain a better understanding of direct and indirect dependencies, and test recovery time. After you have put your application through its paces and know that it works as expected, you can use the results of the experiment for compliance purposes. When used in conjunction with other parts of AWS Resilience Hub, FIS can help you to fully understand the overall resilience posture of your applications.

Intro to Scenarios
We launched FIS in 2021 to help you perform controlled experiments on your AWS applications. In the post that I wrote to announce that launch, I showed you how to create experiment templates and to use them to conduct experiments. The experiments are built using powerful, low-level actions that affect specified groups of AWS resources of a particular type. For example, the following actions operate on EC2 instances and Auto Scaling Groups:

With these actions as building blocks, we recently launched the AWS FIS Scenario Library. Each scenario in the library defines events or conditions that you can use to test the resilience of your applications:

Each scenario is used to create an experiment template. You can use the scenarios as-is, or you can take any template as a starting point and customize or enhance it as desired.

The scenarios can target resources in the same AWS account or in other AWS accounts:

New Scenarios
With all of that as background, let’s take a look at the new scenarios.

AZ Availability: Power Interruption – This scenario temporarily “pulls the plug” on a targeted set of your resources in a single Availability Zone including EC2 instances (including those in EKS and ECS clusters), EBS volumes, Auto Scaling Groups, VPC subnets, Amazon ElastiCache for Redis clusters, and Amazon Relational Database Service (RDS) clusters. In most cases you will run it on an application that has resources in more than one Availability Zone, but you can run it on a single-AZ app with an outage as the expected outcome. It targets a single AZ, and also allows you to disallow a specified set of IAM roles or Auto Scaling Groups from being able to launch fresh instances or start stopped instances during the experiment.

The New actions and targets experience makes it easy to see everything at a glance — the actions in the scenario and the types of AWS resources that they affect:

The scenarios include parameters that are used to customize the experiment template:

The Advanced parameters – targeting tags lets you control the tag keys and values that will be used to locate the resources targeted by experiments:

Cross-Region: Connectivity – This scenario prevents your application in a test region from being able to access resources in a target region. This includes traffic from EC2 instances, ECS tasks, EKS pods, and Lambda functions attached to a VPC. It also includes traffic flowing across Transit Gateways and VPC peering connections, as well as cross-region S3 and DynamoDB replication. The scenario looks like this out of the box:

This scenario runs for 3 hours (unless you change the disruptionDuration parameter), and isolates the test region from the target region in the specified ways, with advanced parameters to control the tags that are used to select the affected AWS resources in the isolated region:

You might also find that the Disrupt and Pause actions used in this scenario useful on their own:

For example, the aws:s3:bucket-pause-replication action can be used to pause replication within a region.

Things to Know
Here are a couple of things to know about the new scenarios:

Regions – The new scenarios are available in all commercial AWS Regions where FIS is available, at no additional cost.

Pricing – You pay for the action-minutes consumed by the experiments that you run; see the AWS Fault Injection Service Pricing Page for more info.

Naming – This service was formerly called AWS Fault Injection Simulator.

— Jeff;

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Today we’re launching zonal autoshift, a new capability of Amazon Route 53 Application Recovery Controller that you can enable to automatically and safely shift your workload’s traffic away from an Availability Zone when AWS identifies a potential failure affecting that Availability Zone and shift it back once the failure is resolved.

When deploying resilient applications, you typically deploy your resources across multiple Availability Zones in a Region. Availability Zones are distinct groups of physical data centers at a meaningful distance apart (typically miles) to make sure that they have diverse power, connectivity, network devices, and flood plains.

To help you protect against an application’s errors, like a failed deployment, an error of configuration, or an operator error, we introduced last year the ability to manually or programmatically trigger a zonal shift. This enables you to shift the traffic away from one Availability Zone when you observe degraded metrics in that zone. It does so by configuring your load balancer to direct all new connections to infrastructure in healthy Availability Zones only. This allows you to preserve your application’s availability for your customers while you investigate the root cause of the failure. Once fixed, you stop the zonal shift to ensure the traffic is distributed across all zones again.

Zonal shift works at the Application Load Balancer (ALB) or Network Load Balancer (NLB) level only when cross-zone load balancing is turned off, which is the default for NLB. In a nutshell, load balancers offer two levels of load balancing. The first level is configured in the DNS. Load balancers expose one or more IP addresses for each Availability Zone, offering a client-side load balancing between zones. Once the traffic hits an Availability Zone, the load balancer sends traffic to registered healthy targets, typically an Amazon Elastic Compute Cloud (Amazon EC2) instance. By default, ALBs send traffic to targets across all Availability Zones. For zonal shift to properly work, you must configure your load balancers to disable cross-zone load balancing.

When zonal shift starts, the DNS sends all traffic away from one Availability Zone, as illustrated by the following diagram.

Manual zonal shift helps to protect your workload against errors originating from your side. But when there is a potential failure in an Availability Zone, it is sometimes difficult for you to identify or detect the failure. Detecting an issue in an Availability Zone using application metrics is difficult because, most of the time, you don’t track metrics per Availability Zone. Moreover, your services often call dependencies across Availability Zone boundaries, resulting in errors seen in all Availability Zones. With modern microservice architectures, these detection and recovery steps must often be performed across tens or hundreds of discrete microservices, leading to recovery times of multiple hours.

Customers asked us if we could take the burden off their shoulders to detect a potential failure in an Availability Zone. After all, we might know about potential issues through our internal monitoring tools before you do.

With this launch, you can now configure zonal autoshift to protect your workloads against potential failure in an Availability Zone. We use our own AWS internal monitoring tools and metrics to decide when to trigger a network traffic shift. The shift starts automatically; there is no API to call. When we detect that a zone has a potential failure, such as a power or network disruption, we automatically trigger an autoshift of your infrastructure’s NLB or ALB traffic, and we shift the traffic back when the failure is resolved.

Obviously, shifting traffic away from an Availability Zone is a delicate operation that must be carefully prepared. We built a series of safeguards to ensure we don’t degrade your application availability by accident.

First, we have internal controls to ensure we shift traffic away from no more than one Availability Zone at a time. Second, we practice the shift on your infrastructure for 30 minutes every week. You can define blocks of time when you don’t want the practice to happen, for example, 08:00–18:00, Monday through Friday. Third, you can define two Amazon CloudWatch alarms to act as a circuit breaker during the practice run: one alarm to prevent starting the practice run at all and one alarm to monitor your application health during a practice run. When either alarm triggers during the practice run, we stop it and restore traffic to all Availability Zones. The state of application health alarm at the end of the practice run indicates its outcome: success or failure.

According to the principle of shared responsibility, you have two responsibilities as well.

First you must ensure there is enough capacity deployed in all Availability Zones to sustain the increase of traffic in remaining Availability Zones after traffic has shifted. We strongly recommend having enough capacity in remaining Availability Zones at all times and not relying on scaling mechanisms that could delay your application recovery or impact its availability. When zonal autoshift triggers, AWS Auto Scaling might take more time than usual to scale your resources. Pre-scaling your resource ensures a predictable recovery time for your most demanding applications.

Let’s imagine that to absorb regular user traffic, your application needs six EC2 instances across three Availability Zones (2×3 instances). Before configuring zonal autoshift, you should ensure you have enough capacity in the remaining Availability Zones to absorb the traffic when one Availability Zone is not available. In this example, it means three instances per Availability Zone (3×3 = 9 instances with three Availability Zones in order to keep 2×3 = 6 instances to handle the load when traffic is shifted to two Availability Zones).

In practice, when operating a service that requires high reliability, it’s normal to operate with some redundant capacity online for eventualities such as customer-driven load spikes, occasional host failures, etc. Topping up your existing redundancy in this way both ensures you can recover rapidly during an Availability Zone issue but can also give you greater robustness to other events.

Second, you must explicitly enable zonal autoshift for the resources you choose. AWS applies zonal autoshift only on the resources you chose. Applying a zonal autoshift will affect the total capacity allocated to your application. As I just described, your application must be prepared for that by having enough capacity deployed in the remaining Availability Zones.

Of course, deploying this extra capacity in all Availability Zones has a cost. When we talk about resilience, there is a business tradeoff to decide between your application availability and its cost. This is another reason why we apply zonal autoshift only on the resources you select.

Let’s see how to configure zonal autoshift
To show you how to configure zonal autoshift, I deploy my now-famous TicTacToe web application using a CDK script. I open the Route 53 Application Recovery Controller page of the AWS Management Console. On the left pane, I select Zonal autoshift. Then, on the welcome page, I select Configure zonal autoshift for a resource.

I select the load balancer of my demo application. Remember that currently, only load balancers with cross-zone load balancing turned off are eligible for zonal autoshift. As the warning on the console reminds me, I also make sure my application has enough capacity to continue to operate with the loss of one Availability Zone.

I scroll down the page and configure the times and days I don’t want AWS to run the 30-minute practice. At first, and until I’m comfortable with autoshift, I block the practice 08:00–18:00, Monday through Friday. Pay attention that hours are expressed in UTC, and they don’t vary with daylight saving time. You may use a UTC time converter application for help. While it is safe for you to exclude business hours at the start, we recommend configuring the practice run also during your business hours to ensure capturing issues that might not be visible when there is low or no traffic on your application. You probably most need zonal autoshift to work without impact at your peak time, but if you have never tested it, how confident are you? Ideally, you don’t want to block any time at all, but we recognize that’s not always practical.

Further down on the same page, I enter the two circuit breaker alarms. The first one prevents the practice from starting. You use this alarm to tell us this is not a good time to start a practice run. For example, when there is an issue ongoing with your application or when you’re deploying a new version of your application to production. The second CloudWatch alarm gives the outcome of the practice run. It enables zonal autoshift to judge how your application is responding to the practice run. If the alarm stays green, we know all went well.

If either of these two alarms triggers during the practice run, zonal autoshift stops the practice and restores the traffic to all Availability Zones.

Finally, I acknowledge that a 30-minute practice run will run weekly and that it might reduce the availability of my application.

Then, I select Create.

And that’s it.

After a few days, I see the history of the practice runs on the Zonal shift history for resource tab of the console. I monitor the history of my two circuit breaker alarms to stay confident everything is correctly monitored and configured.

It’s not possible to test an autoshift itself. It triggers automatically when we detect a potential issue in an Availability Zone. I asked the service team if we could shut down an Availability Zone to test the instructions I shared in this post; they politely declined my request :-).

To test your configuration, you can trigger a manual shift, which behaves identically to an autoshift.

A few more things to know
Zonal autoshift is now available at no additional cost in all AWS Regions, except for China and GovCloud.

We recommend applying the crawl, walk, run methodology. First, you get started with manual zonal shifts to acquire confidence in your application. Then, you turn on zonal autoshift configured with practice runs outside of your business hours. Finally, you modify the schedule to include practice zonal shifts during your business hours. You want to test your application response to an event when you least want it to occur.

We also recommend that you think holistically about how all parts of your application will recover when we move traffic away from one Availability Zone and then back. The list that comes to mind (although certainly not complete) is the following.

First, plan for extra capacity as I discussed already. Second, think about possible single points of failure in each Availability Zone, such as a self-managed database running on a single EC2 instance or a microservice that leaves in a single Availability Zone, and so on. I strongly recommend using managed databases, such as Amazon DynamoDB or Amazon Aurora for applications requiring zonal shifts. These have built-in replication and fail-over mechanisms in place. Third, plan the switch back when the Availability Zone will be available again. How much time do you need to scale your resources? Do you need to rehydrate caches?

You can learn more about resilient architectures and methodologies with this great series of articles from my colleague Adrian.

Finally, remember that only load balancers with cross-zone load balancing turned off are currently eligible for zonal autoshift. To turn off cross-zone load balancing from a CDK script, you need to remove stickinessCookieDuration and add load_balancing.cross_zone.enabled=false on the target group. Here is an example with CDK and Typescript:

    // Add the auto scaling group as a load balancing
    // target to the listener.
    const targetGroup = listener.addTargets('MyApplicationFleet', {
      port: 8080,
      // for zonal shift, stickiness & cross-zones load balancing must be disabled
      // stickinessCookieDuration: Duration.hours(1),
      targets: [asg]
    });    
    // disable cross zone load balancing
    targetGroup.setAttribute("load_balancing.cross_zone.enabled", "false");

Now it’s time for you to select your applications that would benefit from zonal autoshift. Start by reviewing your infrastructure capacity in each Availability Zone and then define the circuit breaker alarms. Once you are confident your monitoring is correctly configured, go and enable zonal autoshift.

— seb

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Today, we are announcing an improved Amazon SageMaker Studio experience! The new SageMaker Studio web-based interface loads faster and provides consistent access to your preferred integrated development environment (IDE) and SageMaker resources and tooling, irrespective of your IDE choice. In addition to JupyterLab and RStudio, SageMaker Studio now includes a fully managed Code Editor based on Code-OSS (Visual Studio Code Open Source).

Both Code Editor and JupyterLab can be launched using a flexible workspace. With spaces, you can scale the compute and storage for your IDE up and down as you go, customize runtime environments, and pause-and-resume coding anytime from anywhere. You can spin up multiple such spaces, each configured with a different combination of compute, storage, and runtimes.

SageMaker Studio now also comes with a streamlined onboarding and administration experience to help both individual users and enterprise administrators get started in minutes. Let me give you a quick tour of some of these highlights.

New SageMaker Studio web-based interface
The new SageMaker Studio web-based interface acts as a command center for launching your preferred IDE and accessing your SageMaker tools to build, train, tune, and deploy models. You can now view SageMaker training jobs and endpoints in SageMaker Studio and access foundation models (FMs) via SageMaker JumpStart. Also, you no longer need to manually upgrade SageMaker Studio.

New Code Editor based on Code-OSS (Visual Studio Code Open Source)
As a data scientist or machine learning (ML) practitioner, you can now sign in to SageMaker Studio and launch Code Editor directly from your browser. With Code Editor, you have access to thousands of VS Code compatible extensions from Open VSX registry and the preconfigured AWS toolkit for Visual Studio Code for developing and deploying applications on AWS. You can also use the artificial intelligence (AI)-powered coding companion and security scanning tool powered by Amazon CodeWhisperer and Amazon CodeGuru.

Launch Code Editor and JupyterLab in a flexible workspace
You can launch both Code Editor and JupyterLab using private spaces that only the user creating the space has access to. This flexible workspace is designed to provide a faster and more efficient coding environment.

The spaces come preconfigured with a SageMaker distribution that contains popular ML frameworks and Python packages. With the help of the AI-powered coding companions and security tools, you can quickly generate, debug, explain, and refactor your code.

In addition, SageMaker Studio comes with an improved collaboration experience. You can use the built-in Git integration to share and version code or bring your own shared file storage using Amazon EFS to access a collaborative filesystem across different users or teams.

Streamlined user onboarding and administration
With redesigned setup and onboarding workflows, you can now set up SageMaker Studio domains within minutes. As an individual user, you can now use a one-click experience to launch SageMaker Studio using default presets and without the need to learn about domains or AWS IAM roles.

As an enterprise administrator, step-by-step instructions help you choose the right authentication method, connect to your third-party identity providers, integrate networking and security configurations, configure fine-grained access policies, and choose the right applications to enable in SageMaker Studio. You can also update settings at any time.

To get started, navigate to the SageMaker console and select either Set up for single user or Set up for organization.

The single-user setup will start deploying a SageMaker Studio domain using default presets and will be ready within a few minutes. The setup for organizations will guide you through the configuration step-by-step. Note that you can choose to keep working with the classic SageMaker Studio experience or start exploring the new experience.

Now available
The new Amazon SageMaker Studio experience is available today in all AWS Regions where SageMaker Studio is available. Starting today, new SageMaker Studio domains will default to the new web-based interface. If you have an existing setup and want to start using the new experience, check out the SageMaker Developer Guide for instructions on how to migrate your existing domains.

Give it a try, and let us know what you think. You can send feedback to AWS re:Post for Amazon SageMaker Studio or through your usual AWS contacts.

Start building your ML projects with Amazon SageMaker Studio today!

— Antje

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One of the challenges with distributed systems is that they are made up of many interdependent services, which add a degree of complexity when you are trying to monitor their performance. Determining which services and APIs are experiencing high latencies or degraded availability requires manually putting together telemetry signals. This can result in time and effort establishing the root cause of any issues with the system due to the inconsistent experiences across metrics, traces, logs, real user monitoring, and synthetic monitoring.

You want to provide your customers with continuously available and high-performing applications. At the same time, the monitoring that assures this must be efficient, cost-effective, and without undifferentiated heavy lifting.

Amazon CloudWatch Application Signals helps you automatically instrument applications based on best practices for application performance. There is no manual effort, no custom code, and no custom dashboards. You get a pre-built, standardized dashboard showing the most important metrics, such as volume of requests, availability, latency, and more, for the performance of your applications. In addition, you can define Service Level Objectives (SLOs) on your applications to monitor specific operations that matter most to your business. An example of an SLO could be to set a goal that a webpage should render within 2000 ms 99.9 percent of the time in a rolling 28-day interval.

Application Signals automatically correlates telemetry across metrics, traces, logs, real user monitoring, and synthetic monitoring to speed up troubleshooting and reduce application disruption. By providing an integrated experience for analyzing performance in the context of your applications, Application Signals gives you improved productivity with a focus on the applications that support your most critical business functions.

My personal favorite is the collaboration between teams that’s made possible by Application Signals. I started this post by mentioning that distributed systems are made up of many interdependent services. On the Service Map, which we will look at later in this post, if you, as a service owner, identify an issue that’s caused by another service, you can send a link to the owner of the other service to efficiently collaborate on the triage tasks.

Getting started with Application Signals
You can easily collect application and container telemetry when creating new Amazon EKS clusters in the Amazon EKS console by enabling the new Amazon CloudWatch Observability EKS add-on. Another option is to enable for existing Amazon EKS Clusters or other compute types directly in the Amazon CloudWatch console.

After enabling Application Signals via the Amazon EKS add-on or Custom option for other compute types, Application Signals automatically discovers services and generates a standard set of application metrics such as volume of requests and latency spikes or availability drops for APIs and dependencies, to name a few.

All of the services discovered and their golden metrics (volume of requests, latency, faults and errors) are then automatically displayed on the Services page and the Service Map. The Service Map gives you a visual deep dive to evaluate the health of a service, its operations, dependencies, and all the call paths between an operation and a dependency.

The list of services that are enabled in Application Signals will also show in the services dashboard, along with operational metrics across all of your services and dependencies to easily spot anomalies. The Application column is auto-populated if the EKS cluster belongs to an application that’s tagged in AppRegistry. The Hosted In column automatically detects which EKS pod, cluster, or namespace combination the service requests are running in, and you can select one to go directly to Container Insights for detailed container metrics such as CPU or memory utilization, to name a few.

Team collaboration with Application Signals
Now, to expand on the team collaboration that I mentioned at the beginning of this post. Let’s say you consult the services dashboard to do sanity checks and you notice two SLO issues for one of your services named pet-clinic-frontend. Your company maintains a set of SLOs, and this is the view that you use to understand how the applications are performing against the objectives. For the services that are tagged in AppRegistry all teams have a central view of the definition and ownership of the application. Further navigation to the service map gives you even more details on the health of this service.

At this point you make the decision to send the link to thepet-clinic-frontendservice to Sarah whose details you found in the AppRegistry. Sarah is the person on-call for this service. The link allows you to efficiently collaborate with Sarah because it’s been curated to land directly on the triage view that is contextualized based on your discovery of the issue. Sarah notices that the POST /api/customer/owners latency has increased to 2k ms for a number of requests and as the service owner, dives deep to arrive at the root cause.

Clicking into the latency graph returns a correlated list of traces that correspond directly to the operation, metric, and moment in time, which helps Sarah to find the exact traces that may have led to the increase in latency.

Sarah uses Amazon CloudWatch Synthetics and Amazon CloudWatch RUM and has enabled the X-Ray active tracing integration to automatically see the list of relevant canaries and pages correlated to the service. This integrated view now helps Sarah gain multiple perspectives in the performance of the application and quickly troubleshoot anomalies in a single view.

Available now
Amazon CloudWatch Application Signals is available in preview and you can start using it today in the following AWS Regions: US East (N. Virginia), US East (Ohio), US West (Oregon), Europe (Ireland), Asia Pacific (Sydney), and Asia Pacific (Tokyo).

To learn more, visit the Amazon CloudWatch user guide and the One Observability Workshop. You can submit your questions to AWS re:Post for Amazon CloudWatch, or through your usual AWS Support contacts.

– Veliswa

This post was originally published on this site

Today, we are announcing the general availability of myApplications supporting application operations, a new set of capabilities that help you get started with your applications on AWS, operate them with less effort, and move faster at scale. With myApplication in the AWS Management Console, you can more easily manage and monitor the cost, health, security posture, and performance of your applications on AWS.

The myApplications experience is available in the Console Home, where you can access an Applications widget that lists the applications in an account. Now, you can create your applications more easily using the Create application wizard, connecting resources in your AWS account from one view in the console. The created application will automatically display in myApplications, and you can take action on your applications.

When you choose your application in the Applications widget in the console, you can see an at-a-glance view of key application metrics widgets in the applications dashboard. Here you can find, debug operational issues, and optimize your applications.

With a single action on the applications dashboard, you can dive deeper to act on specific resources in the relevant services, such as Amazon CloudWatch for application performance, AWS Cost Explorer for cost and usage, and AWS Security Hub for security findings.

Getting started with myApplications
To get started, on the AWS Management Console Home, choose Create application in the Applications widget. In the first step, input your application name and description.

In the next step, you can add your resources. Before you can search and add resources, you should turn on and set up AWS Resource Explorer, a managed capability that simplifies the search and discovery of your AWS resources across AWS Regions.

Choose Add resources and select the resources to add to your applications. You can also search by keyword, tag, or AWS CloudFormation stack to integrate groups of resources to manage the full lifecycle of your application.

After confirming, your resources are added, new awsApplication tags applied, and the myApplications dashboard will be automatically generated.

Now, let’s see which widgets can be useful.

The Application summary widget displays the name, description, and tag so you know which application you are working on. The Cost and usage widget visualizes your AWS resource costs and usage from AWS Cost Explorer, including the application’s current and forecasted month-end costs, top five billed services, and a monthly application resource cost trend chart. You can monitor spend, look for anomalies, and click to take action where needed.

The Compute widget summarizes of application compute resources, information about which are in alarm, and trend charts from CloudWatch showing basic metrics such as Amazon EC2 instance CPU utilization and AWS Lambda invocations. You also can assess application operations, look for anomalies, and take action.

The Monitoring and Operations widget displays alarms and alerts for resources associated with your application, service level objectives (SLOs), and standardized application performance metrics from CloudWatch Application Signals. You can monitor ongoing issues, assess trends, and quickly identify and drill down on any issues that might impact your application.

The Security widget shows the highest priority security findings identified by AWS Security Hub. Findings are listed by severity and service, so you can monitor their security posture and click to take action where needed.

The DevOps widget summarizes operational insights from AWS System Manager Application Manager, such as fleet management, state management, patch management, and configuration management status so you can assess compliance and take action.

You can also use the Tagging widget to assist you in reviewing and applying tags to your application.

Now available
You can enjoy this new myApplications capability, a new application-centric experience to easily manage and monitor applications on AWS. myApplications capability is available in the following AWS Regions: US East (Ohio, N. Virginia), US West (N. California, Oregon), South America (São Paulo), Asia Pacific (Hyderabad, Jakarta, Mumbai, Osaka, Seoul, Singapore, Sydney, Tokyo), Europe (Frankfurt, Ireland, London, Paris, Stockholm), Middle East (Bahrain) Regions.

AWS Premier Tier Services Partners— Escala24x7, IBM, Tech Mahindra, and Xebia will support application operations with complementary features and services.

Give it a try now in the AWS Management Console and send feedback to AWS re:Post for AWS Management Console, using the feedback link on the myApplications dashboard, or through your usual AWS Support contacts.

— Channy

This post was originally published on this site

Today we are excited to announce the general availability of SaaS Quick Launch, a new feature in AWS Marketplace that makes it easy and secure to deploy SaaS products.

Before SaaS Quick Launch, configuring and launching third-party SaaS products could be time-consuming and costly, especially in certain categories like security and monitoring. Some products require hours of engineering time to manually set up permissions policies and cloud infrastructure. Manual multistep configuration processes also introduce risks when buyers rely on unvetted deployment templates and instructions from third-party resources.

SaaS Quick Launch helps buyers make the deployment process easy, fast, and secure by offering step-by-step instructions and resource deployment using preconfigured AWS CloudFormation templates. The software vendor and AWS validate these templates to ensure that the configuration adheres to the latest AWS security standards.

Getting started with SaaS Quick Launch
It’s easy to find which SaaS products have Quick Launch enabled when you are browsing in AWS Marketplace. Products that have this feature configured have a Quick Launch tag in their description.

After completing the purchase process for a Quick Launch–enabled product, you will see a button to set up your account. That button will take you to the Configure and launch page, where you can complete the registration to set up your SaaS account, deploy any required AWS resources, and launch the SaaS product.

The first step ensures that your account has the required AWS permissions to configure the software.

The second step involves configuring the vendor account, either to sign in to an existing account or to create a new account on the vendor website. After signing in, the vendor site may pass essential keys and parameters that are needed in the next step to configure the integration.

The third step allows you to configure the software and AWS integration. In this step, the vendor provides one or more CloudFormation templates that provision the required AWS resources to configure and use the product.

The final step is to launch the software once everything is configured.

Availability
Sellers can enable this feature in their SaaS product. If you are a seller and want to learn how to set this up in your product, check the Seller Guide for detailed instructions.

To learn more about SaaS in AWS Marketplace, visit the service page and view all the available SaaS products currently in AWS Marketplace.

— Marcia

This post was originally published on this site

I’m happy to share that Amazon SageMaker now comes with an improved model deployment experience to help you deploy traditional machine learning (ML) models and foundation models (FMs) faster.

As a data scientist or ML practitioner, you can now use the new ModelBuilder class in the SageMaker Python SDK to package models, perform local inference to validate runtime errors, and deploy to SageMaker from your local IDE or SageMaker Studio notebooks.

In SageMaker Studio, new interactive model deployment workflows give you step-by-step guidance on which instance type to choose to find the most optimal endpoint configuration. SageMaker Studio also provides additional interfaces to add models, test inference, and enable auto scaling policies on the deployed endpoints.

New tools in SageMaker Python SDK
The SageMaker Python SDK has been updated with new tools, including ModelBuilder and SchemaBuilder classes that unify the experience of converting models into SageMaker deployable models across ML frameworks and model servers. Model builder automates the model deployment by selecting a compatible SageMaker container and capturing dependencies from your development environment. Schema builder helps to manage serialization and deserialization tasks of model inputs and outputs. You can use the tools to deploy the model in your local development environment to experiment with it, fix any runtime errors, and when ready, transition from local testing to deploy the model on SageMaker with a single line of code.

Let me show you how this works. In the following example, I choose the Falcon-7B model from the Hugging Face model hub. I first deploy the model locally, run a sample inference, perform local benchmarking to find the optimal configuration, and finally deploy the model with the suggested configuration to SageMaker.

First, import the updated SageMaker Python SDK and define a sample model input and output that matches the prompt format for the selected model.

import sagemaker
from sagemaker.serve.builder.model_builder import ModelBuilder
from sagemaker.serve.builder.schema_builder import SchemaBuilder
from sagemaker.serve import Mode

prompt = "Falcons are"
response = "Falcons are small to medium-sized birds of prey related to hawks and eagles."

sample_input = {
    "inputs": prompt,
    "parameters": {"max_new_tokens": 32}
}

sample_output = [{"generated_text": response}]

Then, create a ModelBuilder instance with the Hugging Face model ID, a SchemaBuilder instance with the sample model input and output, define a local model path, and set the mode to LOCAL_CONTAINER to deploy the model locally. The schema builder generates the required functions for serializing and deserializing the model inputs and outputs.

model_builder = ModelBuilder(
    model="tiiuae/falcon-7b",
    schema_builder=SchemaBuilder(sample_input, sample_output),
    model_path="/path/to/falcon-7b",
    mode=Mode.LOCAL_CONTAINER,
	env_vars={"HF_TRUST_REMOTE_CODE": "True"}
)

Next, call build() to convert the PyTorch model into a SageMaker deployable model. The build function generates the required artifacts for the model server, including the inferency.py and serving.properties files.

local_mode_model = model_builder.build()

For FMs, such as Falcon, you can optionally run tune() in local container mode that performs local benchmarking to find the optimal model serving configuration. This includes the tensor parallel degree that specifies the number of GPUs to use if your environment has multiple GPUs available. Once ready, call deploy() to deploy the model in your local development environment.

tuned_model = local_mode_model.tune()
tuned_model.deploy()

Let’s test the model.

updated_sample_input = model_builder.schema_builder.sample_input
print(updated_sample_input)

{'inputs': 'Falcons are',
 'parameters': {'max_new_tokens': 32}}
 
local_tuned_predictor.predict(updated_sample_input)[0]["generated_text"]

In my demo, the model returns the following response:

a type of bird that are known for their sharp talons and powerful beaks. They are also known for their ability to fly at high speeds […]

When you’re ready to deploy the model on SageMaker, call deploy() again, set the mode to SAGEMAKLER_ENDPOINT, and provide an AWS Identity and Access Management (IAM) role with appropriate permissions.

sm_predictor = tuned_model.deploy(
    mode=Mode.SAGEMAKER_ENDPOINT, 
	role="arn:aws:iam::012345678910:role/role_name"
)

This starts deploying your model on a SageMaker endpoint. Once the endpoint is ready, you can run predictions.

new_input = {'inputs': 'Eagles are','parameters': {'max_new_tokens': 32}}
sm_predictor.predict(new_input)[0]["generated_text"])

New SageMaker Studio model deployment experience
You can start the new interactive model deployment workflows by selecting one or more models to deploy from the models landing page or SageMaker JumpStart model details page or by creating a new endpoint from the endpoints details page.

The new workflows help you quickly deploy the selected model(s) with minimal inputs. If you used SageMaker Inference Recommender to benchmark your model, the dropdown will show instance recommendations from that benchmarking.

Without benchmarking your model, the dropdown will display prospective instances that SageMaker predicts could be a good fit based on its own heuristics. For some of the most popular SageMaker JumpStart models, you’ll see an AWS pretested optimal instance type. For other models, you’ll see generally recommended instance types. For example, if I select the Falcon 40B Instruct model in SageMaker JumpStart, I can see the recommended instance types.

However, if I want to optimize the deployment for cost or performance to meet my specific use cases, I could open the Alternate configurations panel to view more options based on data from before benchmarking.

Once deployed, you can test inference or manage auto scaling policies.

Things to know
Here are a couple of important things to know:

Supported ML models and frameworks – At launch, the new SageMaker Python SDK tools support model deployment for XGBoost and PyTorch models. You can deploy FMs by specifying the Hugging Face model ID or SageMaker JumpStart model ID using the SageMaker LMI container or Hugging Face TGI-based container. You can also bring your own container (BYOC) or deploy models using the Triton model server in ONNX format.

Now available
The new set of tools is available today in all AWS Regions where Amazon SageMaker real-time inference is available. There is no cost to use the new set of tools; you pay only for any underlying SageMaker resources that get created.

Learn more

• Amazon SageMaker Model Deployment
• SageMaker Developer Guide

Get started
Explore the new SageMaker model deployment experience in the AWS Management Console today!

— Antje

This post was originally published on this site

Today, I’m happy to introduce the ability to use natural language instructions in Amazon SageMaker Canvas to explore, visualize, and transform data for machine learning (ML).

SageMaker Canvas now supports using foundation model- (FM) powered natural language instructions to complement its comprehensive data preparation capabilities for data exploration, analysis, visualization, and transformation. Using natural language instructions, you can now explore and transform your data to build highly accurate ML models. This new capability is powered by Amazon Bedrock.

Data is the foundation for effective machine learning, and transforming raw data to make it suitable for ML model building and generating predictions is key to better insights. Analyzing, transforming, and preparing data to build ML models is often the most time-consuming part of the ML workflow. With SageMaker Canvas, data preparation for ML is seamless and fast with 300+ built-in transforms, analyses, and an in-depth data quality insights report without writing any code. Starting today, the process of data exploration and preparation is faster and simpler in SageMaker Canvas using natural language instructions for exploring, visualizing, and transforming data.

Data preparation tasks are now accelerated through a natural language experience using queries and responses. You can quickly get started with contextual, guided prompts to understand and explore your data.

Say I want to build an ML model to predict house prices Using SageMaker Canvas. First, I need to prepare my housing dataset to build an accurate model. To get started with the new natural language instructions, I open the SageMaker Canvas application, and in the left navigation pane, I choose Data Wrangler. Under the Data tab and from the list of available datasets, I select the canvas-housing-sample.csv as the dataset, then select Create a data flow and choose Create. I see the tabular view of my dataset and an introduction to the new Chat for data prep capability.

I select Chat for data prep, and it displays the chat interface with a set of guided prompts relevant to my dataset. I can use any of these prompts or query the data for something else.

First, I want to understand the quality of my dataset to identify any outliers or anomalies. I ask SageMaker Canvas to generate a data quality report to accomplish this task.

I see there are no major issues with my data. I would now like to visualize the distribution of a couple of features in the data. I ask SageMaker Canvas to plot a chart.

I now want to filter certain rows to transform my data. I ask SageMaker Canvas to remove rows where the population is less than 1,000. Canvas removes those rows, shows me a preview of the transformed data, and also gives me the option to view and update the code that generated the transform.

I am happy with the preview and add the transformed data to my list of data transform steps on the right. SageMaker Canvas adds the step along with the code.

Now that my data is transformed, I can go on to build my ML model to predict house prices and even deploy the model into production using the same visual interface of SageMaker Canvas, without writing a single line of code.

Data preparation has never been easier for ML!

Availability
The new capability in Amazon SageMaker Canvas to explore and transform data using natural language queries is available in all AWS Regions where Amazon SageMaker Canvas and Amazon Bedrock are supported.

Learn more
Amazon SageMaker Canvas product page

Go build!

— Irshad

This post was originally published on this site

Today, we are announcing new Amazon SageMaker inference capabilities that can help you optimize deployment costs and reduce latency. With the new inference capabilities, you can deploy one or more foundation models (FMs) on the same SageMaker endpoint and control how many accelerators and how much memory is reserved for each FM. This helps to improve resource utilization, reduce model deployment costs on average by 50 percent, and lets you scale endpoints together with your use cases.

For each FM, you can define separate scaling policies to adapt to model usage patterns while further optimizing infrastructure costs. In addition, SageMaker actively monitors the instances that are processing inference requests and intelligently routes requests based on which instances are available, helping to achieve on average 20 percent lower inference latency.

Key components
The new inference capabilities build upon SageMaker real-time inference endpoints. As before, you create the SageMaker endpoint with an endpoint configuration that defines the instance type and initial instance count for the endpoint. The model is configured in a new construct, an inference component. Here, you specify the number of accelerators and amount of memory you want to allocate to each copy of a model, together with the model artifacts, container image, and number of model copies to deploy.

Let me show you how this works.

New inference capabilities in action
You can start using the new inference capabilities from SageMaker Studio, the SageMaker Python SDK, and the AWS SDKs and AWS Command Line Interface (AWS CLI). They are also supported by AWS CloudFormation.

For this demo, I use the AWS SDK for Python (Boto3) to deploy a copy of the Dolly v2 7B model and a copy of the FLAN-T5 XXL model from the Hugging Face model hub on a SageMaker real-time endpoint using the new inference capabilities.

Create a SageMaker endpoint configuration

import boto3
import sagemaker

role = sagemaker.get_execution_role()
sm_client = boto3.client(service_name="sagemaker")

sm_client.create_endpoint_config(
    EndpointConfigName=endpoint_config_name,
    ExecutionRoleArn=role,
    ProductionVariants=[{
        "VariantName": "AllTraffic",
        "InstanceType": "ml.g5.12xlarge",
        "InitialInstanceCount": 1,
		"RoutingConfig": {
            "RoutingStrategy": "LEAST_OUTSTANDING_REQUESTS"
        }
    }]
)

Create the SageMaker endpoint

sm_client.create_endpoint(
    EndpointName=endpoint_name,
    EndpointConfigName=endpoint_config_name,
)

Before you can create the inference component, you need to create a SageMaker-compatible model and specify a container image to use. For both models, I use the Hugging Face LLM Inference Container for Amazon SageMaker. These deep learning containers (DLCs) include the necessary components, libraries, and drivers to host large models on SageMaker.

Prepare the Dolly v2 model

from sagemaker.huggingface import get_huggingface_llm_image_uri

# Retrieve the container image URI
hf_inference_dlc = get_huggingface_llm_image_uri(
  "huggingface",
  version="0.9.3"
)

# Configure model container
dolly7b = {
    'Image': hf_inference_dlc,
    'Environment': {
        'HF_MODEL_ID':'databricks/dolly-v2-7b',
        'HF_TASK':'text-generation',
    }
}

# Create SageMaker Model
sagemaker_client.create_model(
    ModelName        = "dolly-v2-7b",
    ExecutionRoleArn = role,
    Containers       = [dolly7b]
)

Prepare the FLAN-T5 XXL model

# Configure model container
flant5xxlmodel = {
    'Image': hf_inference_dlc,
    'Environment': {
        'HF_MODEL_ID':'google/flan-t5-xxl',
        'HF_TASK':'text-generation',
    }
}

# Create SageMaker Model
sagemaker_client.create_model(
    ModelName        = "flan-t5-xxl",
    ExecutionRoleArn = role,
    Containers       = [flant5xxlmodel]
)

Now, you’re ready to create the inference component.

Create an inference component for each model
Specify an inference component for each model you want to deploy on the endpoint. Inference components let you specify the SageMaker-compatible model and the compute and memory resources you want to allocate. For CPU workloads, define the number of cores to allocate. For accelerator workloads, define the number of accelerators. RuntimeConfig defines the number of model copies you want to deploy.

# Inference compoonent for Dolly v2 7B
sm_client.create_inference_component(
    InferenceComponentName="IC-dolly-v2-7b",
    EndpointName=endpoint_name,
    VariantName=variant_name,
    Specification={
        "ModelName": "dolly-v2-7b",
        "ComputeResourceRequirements": {
		    "NumberOfAcceleratorDevicesRequired": 2, 
			"NumberOfCpuCoresRequired": 2, 
			"MinMemoryRequiredInMb": 1024
	    }
    },
    RuntimeConfig={"CopyCount": 1},
)

# Inference component for FLAN-T5 XXL
sm_client.create_inference_component(
    InferenceComponentName="IC-flan-t5-xxl",
    EndpointName=endpoint_name,
    VariantName=variant_name,
    Specification={
        "ModelName": "flan-t5-xxl",
        "ComputeResourceRequirements": {
		    "NumberOfAcceleratorDevicesRequired": 2, 
			"NumberOfCpuCoresRequired": 1, 
			"MinMemoryRequiredInMb": 1024
	    }
    },
    RuntimeConfig={"CopyCount": 1},
)

Once the inference components have successfully deployed, you can invoke the models.

Run inference
To invoke a model on the endpoint, specify the corresponding inference component.

import json
sm_runtime_client = boto3.client(service_name="sagemaker-runtime")
payload = {"inputs": "Why is California a great place to live?"}

response_dolly = sm_runtime_client.invoke_endpoint(
    EndpointName=endpoint_name,
    InferenceComponentName = "IC-dolly-v2-7b",
    ContentType="application/json",
    Accept="application/json",
    Body=json.dumps(payload),
)

response_flant5 = sm_runtime_client.invoke_endpoint(
    EndpointName=endpoint_name,
    InferenceComponentName = "IC-flan-t5-xxl",
    ContentType="application/json",
    Accept="application/json",
    Body=json.dumps(payload),
)

result_dolly = json.loads(response_dolly['Body'].read().decode())
result_flant5 = json.loads(response_flant5['Body'].read().decode())

Next, you can define separate scaling policies for each model by registering the scaling target and applying the scaling policy to the inference component. Check out the SageMaker Developer Guide for detailed instructions.

The new inference capabilities provide per-model CloudWatch metrics and CloudWatch Logs and can be used with any SageMaker-compatible container image across SageMaker CPU- and GPU-based compute instances. Given support by the container image, you can also use response streaming.

Now available
The new Amazon SageMaker inference capabilities are available today in AWS Regions US East (Ohio, N. Virginia), US West (Oregon), Asia Pacific (Jakarta, Mumbai, Seoul, Singapore, Sydney, Tokyo), Canada (Central), Europe (Frankfurt, Ireland, London, Stockholm), Middle East (UAE), and South America (São Paulo). For pricing details, visit Amazon SageMaker Pricing. To learn more, visit Amazon SageMaker.

Get started
Log in to the AWS Management Console and deploy your FMs using the new SageMaker inference capabilities today!

— Antje