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I’m excited to announce Amazon S3 Files, a new file system that seamlessly connects any AWS compute resource with Amazon Simple Storage Service (Amazon S3).

More than a decade ago, as an AWS trainer, I spent countless hours explaining the fundamental differences between object storage and file systems. My favorite analogy was comparing S3 objects to books in a library (you can’t edit a page, you need to replace the whole book) versus files on your computer that you can modify page by page. I drew diagrams, created metaphors, and helped customers understand why they needed different storage types for different workloads. Well, today that distinction becomes a bit more flexible.

With S3 Files, Amazon S3 is the first and only cloud object store that offers fully-featured, high-performance file system access to your data. It makes your buckets accessible as file systems. This means changes to data on the file system are automatically reflected in the S3 bucket and you have fine-grained control over synchronization. S3 Files can be attached to multiple compute resources enabling data sharing across clusters without duplication.

Until now, you had to choose between Amazon S3 cost, durability, and the services that can natively consume data from it or a file system’s interactive capabilities. S3 Files eliminates that tradeoff. S3 becomes the central hub for all your organization’s data. It’s accessible directly from any AWS compute instance, container, or function, whether you’re running production applications, training ML models, or building agentic AI systems.

You can access any general purpose bucket as a native file system on your Amazon Elastic Compute Cloud (Amazon EC2) instances, containers running on Amazon Elastic Container Service (Amazon ECS) or Amazon Elastic Kubernetes Service (Amazon EKS), or AWS Lambda functions. The file system presents S3 objects as files and directories, supporting all Network File System (NFS) v4.1+ operations like creating, reading, updating, and deleting files.

As you work with specific files and directories through the file system, associated file metadata and contents are placed onto the file system’s high-performance storage. By default, files that benefit from low-latency access are stored and served from the high performance storage. For files not stored on high performance storage such as those needing large sequential reads, S3 Files automatically serves those files directly from Amazon S3 to maximize throughput. For byte-range reads, only the requested bytes are transferred, minimizing data movement and costs.

The system also supports intelligent pre-fetching to anticipate your data access needs. You also have fine-grained control over what gets stored on the file system’s high performance storage. You can decide whether to load full file data or metadata only, which means you can optimize for your specific access patterns.

Under the hood, S3 Files uses Amazon Elastic File System (Amazon EFS) and delivers ~1ms latencies for active data. The file system supports concurrent access from multiple compute resources with NFS close-to-open consistency, making it ideal for interactive, shared workloads that mutate data, from agentic AI agents collaborating through file-based tools to ML training pipelines processing datasets.

Let me show you how to get started.
Creating my first Amazon S3 file system, mounting, and using it from an EC2 instance is straightforward.

I have an EC2 instance and a general purpose bucket. In this demo, I configure an S3 file system and access the bucket from an EC2 instance, using regular file system commands.

For this demo, I use the AWS Management Console. You can also use the AWS Command Line Interface (AWS CLI) or infrastructure as code (IaC).

Here is the architecture diagram for this demo.

Step 1: Create an S3 file system.

On the Amazon S3 section of the console, I choose File systems and then Create file system.

I enter the name of the bucket I want to expose as a file system and choose Create file system.

Step 2: Discover the mount target.

A mount target is a network endpoint that will live in my virtual private cloud (VPC). It allows my EC2 instance to access the S3 file system.

The console creates the mount targets automatically. I take notes of the Mount target IDs on the Mount targets tab.

When using the CLI, two separate commands are necessary to create the file system and its mount targets. First, I create the S3 file system with create-file-system. Then, I create the mount target with create-mount target.

Step 3: Mount the file system on my EC2 instance.

After it’s connected to an EC2 instance, I type:

sudo mkdir /home/ec2-user/s3files sudo mount -t s3files fs-0aa860d05df9afdfe:/ /home/ec2-user/s3files

I can now work with my S3 data directly through the mounted file system in ~/s3files, using standard file operations.

When I make updates to my files in the file system, S3 automatically manages and exports all updates as a new object or a new version on an existing object back in my S3 bucket within minutes.

Changes made to objects on the S3 bucket are visible in the file system within a few seconds but can sometimes take a minute or longer.

# Create a file on the EC2 file system 
echo "Hello S3 Files" > s3files/hello.txt 

# and verify it's here 
ls -al s3files/hello.txt
 -rw-r--r--. 1 ec2-user ec2-user 15 Oct 22 13:03 s3files/hello.txt 

# See? the file is also on S3 
aws s3 ls s3://s3files-aws-news-blog/hello.txt 
2025-10-22 13:04:04 15 hello.txt 

# And the content is identical! 
aws s3 cp s3://s3files-aws-news-blog/hello.txt . && cat hello.txt
Hello S3 Files

Things to know
Let me share some important technical details that I think you’ll find useful.

• S3 Files integrates with AWS Identity and Access Management (IAM) for access control and encryption. You can use identity and resource policies to manage permissions at both the file system and object level.
• Data is always encrypted in transit using TLS 1.3 and at rest using Amazon S3 managed keys (SSE-S3) or customer-managed keys with AWS Key Management Service (AWS KMS).
• S3 Files uses POSIX permissions for files and directories, checking user ID (UID) and group ID (GID) against file permissions stored as object metadata in the S3 bucket.
• Monitor S3 Files using Amazon CloudWatch metrics for drive performance and updates and AWS CloudTrail for logging management events.
• Verify that the latest version of the EFS driver (amazon-efs-utils package) is installed on your EC2 instances. This package is preinstalled on the Amazon Machine Image (AMI) provided by AWS. At the time of writing, you can update it to the latest version.
• In this post, I showed you how to use S3 Files from an EC2 instance. You can also mount your S3 bucket as a file system from your ECS or EKS containers, on AWS Fargate or not, and from your Lambda functions.

Another question I frequently hear in customer conversations is about choosing the right file service for your workloads. Yes, I know what you’re thinking: AWS and its seemingly overlapping services, keeping cloud architects entertained during their architecture review meetings. Let me help demystify this one.

S3 Files works best when you need interactive, shared access to data that lives in Amazon S3 through a high performance file system interface. It’s ideal for workloads where multiple compute resources—whether production applications, agentic AI agents using Python libraries and CLI tools, or machine learning (ML) training pipelines—need to read, write, and mutate data collaboratively. You get shared access across compute clusters without data duplication, sub-millisecond latency, and automatic synchronization with your S3 bucket.

For workloads migrating from on-premises NAS environments, Amazon FSx provides the familiar features and compatibility you need. Amazon FSx is also ideal for high-performance computing (HPC) and GPU cluster storage with Amazon FSx for Lustre. It’s particularly valuable when your applications require specific file system capabilities from Amazon FSx for NetApp ONTAP, Amazon FSx for OpenZFS, or Amazon FSx for Windows File Server.

Pricing and availability
S3 Files is available today in all commercial AWS Regions.

You pay for the portion of data stored in your S3 file system, for small file read and all write operations to the file system, and for S3 requests during data synchronization between the file system and the S3 bucket. The Amazon S3 pricing page has all the details.

From discussions with customers, I believe S3 Files helps simplify cloud architectures by eliminating data silos, synchronization complexity, and manual data movement between objects and files. Whether you’re running production tools that already work with file systems, building agentic AI systems that rely on file-based Python libraries and shell scripts, or preparing datasets for ML training, S3 Files lets these interactive, shared, hierarchical workloads access S3 data directly without choosing between the durability of Amazon S3 and cost benefits and a file system’s interactive capabilities. You can now use Amazon S3 as the place for all your organizations’ data, knowing the data is accessible directly from any AWS compute instance, container, and function.

To learn more and get started, visit the S3 Files documentation.

I’d love to hear how you use this new capability. Feel free to share your feedback in the comments below.

— seb

This post was originally published on this site

Today, we’re announcing the general availability of cross-account safeguards in Amazon Bedrock Guardrails, a new capability that enables centralized enforcement and management of safety controls across multiple AWS accounts within an organization.

With this new capability, you can specify a guardrail in a new Amazon Bedrock policy within the management account of your organization that automatically enforces configured safeguards across all member entities for every model invocation with Amazon Bedrock. This organization-wide implementation supports uniform protection across all accounts and generative AI applications with centralized control and management. This capability also offers flexibility to apply account-level and application-specific controls depending on use case requirements in addition to organizational safeguards.

• Organization-level enforcements apply a single guardrail from your organization’s management account to all entities within the organization through policy settings. This guardrail automatically enforces filters across all member entities, including organizational units (OUs) and individual accounts, for all Amazon Bedrock model invocations.
• Account-level enforcement enables automatic enforcement of configured safeguards across all Amazon Bedrock model invocations in your AWS account. The configured safeguards in the account-level guardrail apply to all inference API calls.

You can now establish and centrally manage dependable, comprehensive protection through a single, unified approach. This supports consistent adherence to corporate responsible AI requirements while significantly reducing the administrative burden of monitoring individual accounts and applications. Your security team no longer needs to oversee and verify configurations or compliance for each account independently.

Getting started with centralized enforcement in Amazon Bedrock Guardrails
You can get started with account-level and organization-level enforcement configuration in the Amazon Bedrock Guardrails console. Before the enforcement configuration, you need to create a guardrail with a particular version to support the guardrail configuration remains immutable and cannot be modified by member accounts and complete prerequisites for using the new capability such as resource-based policies for guardrails.

To enable account-level enforcement, choose Create in the section of Account-level enforcement configurations.

You can choose the guardrail and version to automatically apply to all Bedrock inference calls from this account in this Region. With general availability, we introduce the new feature defining which models will be affected by the enforcement with either Include or Exclude behavior.

You can also configure selective content guarding controls for system prompts and user prompts with either Comprehensive or Selective.

• Use Comprehensive when you want to enforce guardrails on everything, regardless of what the caller tags. This is the safer default when you don’t want to rely on callers to correctly identify sensitive content.
• Use Selective when you trust callers to tag the right content and want to reduce unnecessary guardrail processing. This is useful when callers handle a mix of pre-validated and user-generated content, and only need guardrails applied to specific portions.

After creating the enforcement, you can test and verify enforcement using a role in your account. The account-enforced guardrail should automatically apply to both prompts and outputs.

Check the response for guardrail assessment information. The guardrail response will include enforced guardrail information. You can also test by making a Bedrock inference call using InvokeModel, InvokeModelWithResponseStream, Converse, or ConverseStream APIs.

To enable organization-level enforcement, go to AWS Organizations console and choose Policies menu. You can enable the Bedrock policies in the console.

You can create a Bedrock policy that specifies your guardrail and attach it to your target accounts or OUs. Choose Bedrock policies enabled and Create policy. Specify your guardrail ARN and version and configure the input tags setting for in the AWS Organizations. To learn more, visit Amazon Bedrock policies in AWS Organizations and Amazon Bedrock policy syntax and examples.

After creating the policy, you can attach the policy to your desired organizational units, accounts, root in the Targets tab.

Search and select your organization root, OUs, or individual accounts to attach your policy, and choose Attach policy.

You can test that the guardrail is being enforced on member accounts and verify which guardrail is enforced. From a member account attached, you should see the organization enforced guardrail under the section Organization-level enforcement configurations.

The underlying safeguards within the specified guardrail are then automatically enforced for every model inference request across all member entities, ensuring consistent safety controls. To accommodate varying requirements of individual teams or applications, you can attach different policies with associated guardrails to different member entities through your organization.

Things to know
Here are key considerations to know about GA features:

• You can now choose to include or exclude specific models in Bedrock for inference, enabling centralized enforcement on model invocation calls. You can also choose to safeguard partial or complete system prompts and input prompts. To learn more, visit Apply cross-account safeguards with Amazon Bedrock Guardrails enforcement.
• Ensure you are specifying the accurate guardrail Amazon Resource Names (ARN) in the policy. Specifying an incorrect or invalid ARN will result in policy violations, non-enforcement of safeguards, and the inability to use the models in Amazon Bedrock for inference. To learn more, visit Best practices for using Amazon Bedrock policies.
• Automated Reasoning checks are not supported with this capability.

Now available
Cross-account safeguards in Amazon Bedrock Guardrails is generally available today in the all AWS commercial and GovCloud Regions where Bedrock Guardrails is available. For Regional availability and a future roadmap, visit the AWS Capabilities by Region. Charges apply to each enforced guardrail according to its configured safeguards. For detailed pricing information on individual safeguards, visit Amazon Bedrock Pricing page.

Give this capability a try in the Amazon Bedrock console and send feedback to AWS re:Post for Amazon Bedrock Guardrails or through your usual AWS Support contacts.

— Channy

This post was originally published on this site

Today, we’re announcing managed daemon support for Amazon Elastic Container Service (Amazon ECS) Managed Instances. This new capability extends the managed instances experience we introduced in September 2025, by giving platform engineers independent control over software agents such as monitoring, logging, and tracing tools, without requiring coordination with application development teams, while also improving reliability by ensuring every instance consistently runs required daemons and enabling comprehensive host-level monitoring.

When running containerized workloads at scale, platform engineers manage a wide range of responsibilities, from scaling and patching infrastructure to keeping applications running reliably and maintaining the operational agents that support those applications. Until now, many of these concerns were tightly coupled. Updating a monitoring agent meant coordinating with application teams, modifying task definitions, and redeploying entire applications, a significant operational burden when you’re managing hundreds or thousands of services.

Decoupled lifecycle management for daemons
Amazon ECS now introduces a dedicated managed daemons construct that enables platform teams to centrally manage operational tooling. This separation of concerns allows platform engineers to independently deploy and update monitoring, logging, and tracing agents to infrastructure, while enforcing consistent use of required tools across all instances, without requiring application teams to redeploy their services. Daemons are guaranteed to start before application tasks and drain last, ensuring that logging, tracing, and monitoring are always available when your application needs them.

Platform engineers can deploy managed daemons across multiple capacity providers, or target specific capacity providers, giving them flexibility in how they roll out agents across their infrastructure. Resource management is also centralized, allowing teams to define daemon CPU and memory parameters separately from application configurations with no need to rebuild AMIs or update task definitions, while optimizing resource utilization since each instance runs exactly one daemon copy shared across multiple application tasks.

Let’s try it out
To take ECS Managed Daemons for a spin, I decided to start with the Amazon CloudWatch Agent as my first managed daemon. I had previously set up an Amazon ECS cluster with a Managed Instance capacity provider using the documentation.

From the Amazon Elastic Container Service console, I noticed a new Daemon task definitions option in the navigation pane, where I can define my managed daemons.

I chose Create new daemon task definition to get started. For this example, I configured the CloudWatch Agent with 1 vCPU and 0.5 GB of memory. In the Daemon task definition family field, I entered a name I’d recognize later.

For the Task execution role, I selected ecsTaskExecutionRole from the dropdown. Under the Container section, I gave my container a descriptive name and pasted in the image URI: public.ecr.aws/cloudwatch-agent/cloudwatch-agent:latest along with a few additional details.

After reviewing everything, I chose Create.

Once my daemon task definition was created, I navigated to the Clusters page, selected my previously created cluster and found the new Daemons tab.

Here I can simply click the Create daemon button and complete the form to configure my daemon.

Under Daemon configuration, I selected my newly created daemon task definition family and then assigned my daemon a name. For Environment configuration, I selected the ECS Managed Instances capacity provider I had set up earlier. After confirming my settings, I chose Create.

Now ECS automatically ensures the daemon task launches first on every provisioned ECS managed instance in my selected capacity provider. To see this in action, I deployed a sample nginx web service as a test workload. Once my workload was deployed, I could see in the console that ECS Managed Daemons had automatically deployed the CloudWatch Agent daemon alongside my application, with no manual intervention required.

When I later updated my daemon, ECS handled the rolling deployment automatically by provisioning new instances with the updated daemon, starting the daemon first, then migrating application tasks to the new instances before terminating the old ones. This “start before stop” approach ensures continuous daemon coverage: your logging, monitoring, and tracing agents remain operational throughout the update with no gaps in data collection. The drain percentage I configured controlled the pace of this replacement, giving me complete control over addon updates without any application downtime.

How it works
The managed daemon experience introduces a new daemon task definition that is separate from task definitions, with its own parameters and validation scheme. A new daemon_bridge network mode enables daemons to communicate with application tasks while remaining isolated from application networking configurations.

Managed daemons support advanced host-level access capabilities that are essential for operational tooling. Platform engineers can configure daemon tasks as privileged containers, add additional Linux capabilities, and mount paths from the underlying host filesystem. These capabilities are particularly valuable for monitoring and security agents that require deep visibility into host-level metrics, processes, and system calls.

When a daemon is deployed, ECS launches exactly one daemon process per container instance before placing application tasks. This guarantees that operational tooling is in place before your application starts receiving traffic. ECS also supports rolling deployments with automatic rollbacks, so you can update agents with confidence.

Now available
Managed daemon support for Amazon ECS Managed Instances is available today in all AWS Regions. To get started, visit the Amazon ECS console or review the Amazon ECS documentation. You can also explore the new managed daemons Application Programming Interface (APIs) by visiting this website.

There is no additional cost to use managed daemons. You pay only for the standard compute resources consumed by your daemon tasks.