AWS

Top announcements of the What’s Next with AWS, 2026

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Today at the What’s Next with AWS, Matt Garman, CEO of AWS, Colleen Aubrey, SVP Amazon Applied AI Solutions, Julia White, CMO of AWS, and OpenAI leaders discussed how they and their customers are changing how businesses operate with agents.

Here’s our roundup of the biggest announcements from the event:

Amazon Quick is an AI assistant for work that connects to all of them, learns what matters to you, and takes action on your behalf. Starting today, you can use the new desktop app, sign up for Free and Plus pricing plans, generate visual assets in the chat, and easily connect Quick to even more apps.

  • Quick’s new desktop app (Preview): You can create a personalized experience by staying connected to your local files, calendar, and communications without opening a browser.
  • New Free and Plus pricing plans for Quick: You can sign up within minutes using your personal email address or existing Google, Apple, Github, or Amazon credentials—no AWS account required.
  • Generate visual assets on the fly: Available today, Quick now lets you create polished documents, presentations, infographics, and images directly from the chat interface, no design skills or hours of formatting required.
  • Easily connect Quick to even more apps: Also available today, Quick is expanding its native integrations to include Google Workspace, Zoom, Airtable, Dropbox, and Microsoft Teams.

To learn more, visit the About Amazon News post.

Amazon Connect is expanding from a single product into a set of four agentic AI solutions designed to work within your existing workflows: Amazon Connect Decisions (supply chains), Talent (hiring), Customer (customer experience), and Health (health care).

  • Amazon Connect Decisions is a supply chain planning and intelligence solution that shifts teams from crisis management to proactive planning and decisioning. AI teammates, combining 30 years of Amazon operational science and 25+ specialized supply chain tools, adapt to your business, learn from your team, and continuously improve your operations.
  • Amazon Connect Talent (Preview) is an agentic AI hiring solution built for talent acquisition leaders managing scaled hiring. It delivers AI-led interviews, science-backed assessments, and consistent evaluation, helping recruiters hire high quality candidates faster while providing applicants with a flexible interview experience that reduces human preconceptions.
  • Amazon Connect Customer, previously known as Amazon Connect, delivers intelligent, personalized customer experiences across voice, chat, and digital channels. Amazon Connect Customer now offers new configuration capabilities that enable organizations to set up conversational AI in weeks, not months, and configure experiences without technical expertise.
  • Amazon Connect Health delivers agentic patient verification, appointment management, patient insights, ambient documentation, and medical coding — giving patients faster access to care, clinicians more time for care, and staff capacity for specialized work.

To learn more, visit the About Amazon News post.

AWS and OpenAI extended partnership
AWS and OpenAI are bringing the latest OpenAI models to Amazon Bedrock, launching Codex on Amazon Bedrock, and launching Amazon Bedrock Managed Agents, powered by OpenAI (all in limited preview), giving enterprises the frontier intelligence they want on the infrastructure they trust.

  • OpenAI models on Amazon Bedrock (Limited preview): The latest OpenAI models, including GPT-5.5 and GPT-5.4, will be available in preview on Amazon Bedrock. Use OpenAI’s frontier models through the same Bedrock APIs you already rely on, with unified security, governance, and cost controls. No additional infrastructure to configure, no new security model to learn.
  • Codex on Amazon Bedrock (Limited preview): You can access the OpenAI coding agent within the AWS environments where they already operate at scale. You can authenticate using their AWS credentials, process inference through Amazon Bedrock infrastructure, and apply Codex usage toward their AWS cloud commitments. Codex on Bedrock is available through the Bedrock API, starting with the Codex CLI, the Codex desktop app, and Visual Studio Code extension.
  • Amazon Bedrock Managed Agents, powered by OpenAI (Limited preview): Amazon Bedrock Managed Agents combines frontier AI models with trusted AWS infrastructure, enabling customers to quickly and easily build production-ready OpenAI-powered agents in the cloud. It is built with the OpenAI harness, which is engineered to unlock the full potential of OpenAI frontier models, delivering faster execution, sharper reasoning, and reliable steering of long-running tasks.

To learn more, visit the AWS What’s New post and About Amazon News post.

Security

HTTP Requests with X-Vercel-Set-Bypass-Cookie Header, (Tue, Apr 28th)

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This weekend, we saw a few requests to our honeypot that included an "X-Vercel-Set-Bypass-Cookie" header. A sample request:

GET / HTTP/1.1
User-Agent: Mozilla/5.0 (Windows NT 10.0; Win64; x64) AppleWebKit/537.36 (KHTML, like Gecko) Chrome/124.0.0.0 Safari/537.36
Accept: text/html,application/xhtml+xml,application/xml;q=0.9,image/avif,image/webp,*/ *;q=0.8
Accept-Language: en-US,en;q=0.5
Accept-Encoding: gzip, deflate, br
Cache-Control: no-cache
Pragma: no-cache
Connection: keep-alive
X-Vercel-Set-Bypass-Cookie: samesite-none-secure
Upgrade-Insecure-Requests: 1
X-Forwarded-From: 21.235.92.139
X-Real-Iphone: 21.235.92.139
Referer: [redacted, same as "Host" header]
Host: [redacted]

Vercel documents the "x-vercel-protection-bypass" header(note: no "Cookie" part) as a secret that can be configured to disable certain protections during testing. This type of bypass feature is common in various platforms. In particular, web application firewall features often need to be disabled to allow higher request rates during CI/CD pipeline operations. The value set in the header is a user-configurable secret[1].

The X-Vercel-Set-Bypass-Cookie allows testing in browsers and maintains the bypass by having the server set a cookie to indicate the bypass. There are two options according to Vercel's documentation:

  1. True: enables the cookie
  2. samesitenone: enables the cookie, and set the same-site property to none.

I did not see the "samesite-none-secure" documented by Vercel.

The most likely intention of the header is to relax security settings, maybe even steal secrets, should Vercel expose them in the cookie. I have not had a chance to test the request against a Vercel website. Any input as to the intent is welcome.

The request was also set via an open proxy, likely to protect the attacker's identity, but it failed due to the configured proxy headers.

[1] https://vercel.com/docs/deployment-protection/methods-to-bypass-deployment-protection/protection-bypass-automation 


Johannes B. Ullrich, Ph.D. , Dean of Research, SANS.edu
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(c) SANS Internet Storm Center. https://isc.sans.edu Creative Commons Attribution-Noncommercial 3.0 United States License.

Security

TeamPCP Supply Chain Campaign: Update 008 – 26-Day Pause Ends with Three Concurrent Compromises (Checkmarx KICS, Bitwarden CLI Cascade, xinference PyPI), CanisterSprawl npm Worm Identified, and Tier 1 Coverage Returns, (Mon, Apr 27th)

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This update succeeds TeamPCP Supply Chain Campaign Update 007, published April 8, 2026, which left the campaign in credential-monetization mode following the Cisco source code theft via Trivy-linked credentials, Google GTIG's formal designation of the operators as UNC6780 (with their credential stealer named SANDCLOCK), and the lapsed CISA KEV remediation deadline for CVE-2026-33634 with no standalone federal advisory. The Sportradar publication deadline flagged in Update 007 (approximately April 10 to 11) lapsed without a public CipherForce dump, and CipherForce's leak infrastructure has remained offline. Twelve days after Update 007, the technical compromise picture changed sharply across the W17 window (April 20 through April 26).

Security

Apple Patches Exploited Notification Flaw, (Thu, Apr 23rd)

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Apple yesterday released iOS/iPadOS 26.4.2 and iOS/iPadOS 18.7.8. This update fixes a single Notification Services vulnerability, CVE-2026-28950:

Impact: Notifications marked for deletion could be unexpectedly retained on the device

Description: A logging issue was addressed with improved data redaction.

Apple did not mark the vulnerability as exploited. However, recent news articles reported that the FBI used this vulnerability to extract Signal messages from a device seized in a criminal case. The suspect in the case used Signal to communicate. Signal is encrypted end-to-end and attempts not to store retrievable data on the device itself. However, Signal may display a notification on the screen whenever a new message is received. These notifications may include the sender's username and some of the message's content. Signal used Apple's Notification Services framework to generate these notifications, and iOS did not delete their contents even when they were marked for deletion. 

The use of OS libraries and APIs like that has caused problems before, as they may not be designed with the same threat model in mind as the one used to create secure messaging applications.


Johannes B. Ullrich, Ph.D. , Dean of Research, SANS.edu
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(c) SANS Internet Storm Center. https://isc.sans.edu Creative Commons Attribution-Noncommercial 3.0 United States License.

Security

[Guest Diary] Beyond Cryptojacking: Telegram tdata as a Credential Harvesting Vector, Lessons from a Honeypot Incident, (Wed, Apr 22nd)

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[This is a Guest Diary by L. Carty, an ISC intern as part of the SANS.edu Bachelor's Degree in Applied Cybersecurity (BACS) program [1].]

Introduction

A few weeks ago, my honeypot logged an incident that changed how I think about modern attacks. A threat actor broke into my system using weak SSH credentials and immediately started running commands. What started as a routine resource-hijacking attempt was followed by credential harvesting targeting Telegram Desktop session data.

This incident isn't just another story about cryptocurrency mining malware. It's a window into how modern threat actors are evolving their tactics – chaining initial access with credential theft to enable persistent, multi-layered exploitation. The commands I observed tell a story of methodical reconnaissance, from checking for competing miners to hunting for Telegram's tdata directory.

In this post, I'll walk through what I found, explain why the tdata folder is so valuable to threat actors, and share practical ways to protect it and manage your sessions.

The Attack Chain: A Conceptual Overview

Before diving into the actual commands, let's establish what we're looking at. Modern attacks rarely consist of a single malicious action and instead follow a progression. Below is the attack chain and corresponding MITRE ATT&CK Techniques. [2]

  1. Initial Access – Weak SSH credentials, phishing, or vulnerabilities /T1110/001/
  2. Reconnaissance – System enumeration, identifying valuable targets /T1082/ /T1083/
  3. Credential Harvesting – Extracting session tokens, passwords, or authentication data /T1555/ /T1005/
  4. Account Takeover – Using stolen credentials for further access /T1078/
  5. Exploitation – Social engineering, lateral movement, or monetization /T1041/

What made this particular attack notable was the explicit targeting of Telegram's local session data. Threat actors aren't just after CPU cycles anymore—they're after persistent access through compromised accounts that can be leveraged for ongoing exploitation.

The Evidence: Live from the Honeypot

The following commands were captured in the honeypot's SSH logs immediately after the threat actor gained access. They show the threat actor’s intent to map the system, check for competition, and locate the tdata directory.

Commands Captured

  • /ip cloud print
  • ifconfig
  • uname -a cat /proc/cpuinfo #looks to have an issue with cloudflare
  • ps | grep '[Mm]iner' ps -ef | grep '[Mm]iner'
  • ls -la ~/.local/share/TelegramDesktop/tdata /home/*/.local/share/TelegramDesktop/tdata /dev/ttyGSM* /dev/ttyUSB-mod* /var/spool/sms/* /var/log/smsd.log /etc/smsd.conf* /usr/bin/qmuxd /var/qmux_connect_socket /etc/config/simman /dev/modem* /var/config/sms/*
  • locate D877F783D5D3EF8Cs
  • echo Hi | cat -n

A Command Timeline Visualization

[Initial SSH Access]
         |
_________V_________________________________________________________
| RECONNAISSANCE PHASE                                            |
| • /ip cloud print → MikroTik RouterOS status,configuration      |
| • ifconfig → Network interface enumeration                      |
| • uname -a → OS/kernel identification                           |
| • cat /proc/cpuinfo → Hardware capability assessment            |
___________________________________________________________________
         |
_________V_________________________________________________________
| MINER DETECTION                                                 |
| • ps | grep '[Mm]iner' → Check for competing miners             |
| • ps -ef | grep... → Full process list scan                     |
__________________________________________________________________
         |
_________V_________________________________________________________
| CREDENTIAL HARVESTING                                           |
| • ls -la .../tdata → Locate Telegram session directory          |
| • /home/*/... → Wildcard search for user accounts               |
| • /dev/ttyGSM*, etc. → Modem/SMS 2FA bypass attempts            |
___________________________________________________________________
         |
_________V_________________________________________________________
| EXFILTRATION PREPARATION                                        |
| • locate D877F783... → Specific tdata folder lookup             |
| • echo Hi | cat -n → Shell verification                         |
| • [Compress & upload] → Likely next step (not captured)         |
__________________________________________________________________

Operational Context: Connecting the Dots

While the timeline shows what happened, understanding the why requires looking at the attack from a strategic view. Each command serves a specific purpose in a larger plan.

The initial reconnaissance (ifconfig, uname -a) was an attempt to confirm the system had the processing power to support a cryptominer and the network connectivity to send data out. Next came the miner detection phase (ps | grep). If the threat actor found an existing miner, they would need to remove those processes to free up resources and avoid conflicts before installing their own.

The next set of commands gets interesting as the threat actor shifts focus to Telegram Desktop tdata. This move reveals that stealing CPU cycles is a short-term gain, whereas stealing the Telegram session is a long-term asset. The threat actor searched for modem devices and SMS logs to get around the victim's two-factor authentication (2FA). This ensured that even if the stolen session stopped working, the threat actor could still reset the account password via SMS to take full control. This shows a clear shift from just using someone's computer for a quick profit to stealing their digital identity for long-term use.

Deep Dive: The Critical Risk of tdata Exposure

Understanding why the tdata folder is so valuable is essential for defense. This directory contains the session data that authenticates the user to Telegram's servers.

The Mechanics of Session Theft

According to an Imperva Threat Research report from 2025 regarding the sale of Telegram identities [3], copying the tdata folder to another machine grants a threat actor full access to the victim's Telegram account without needing the phone number or two-factor authentication code.

The session information stored in tdata acts as persistent login credentials. Because the authentication tokens are self-contained within the folder, the threat actor doesn't need to re-authenticate or bypass 2FA. They simply need to move the folder to a machine where they can run Telegram.

This flexibility is what makes the attack so dangerous. The threat actor does not need a specific version of the software, such as ‘Telegram Portable.’ Any standard Telegram Desktop client works because:

  • Same Authentication Method: All Telegram Desktop clients (standard or portable) use the identical tdata folder structure, and
  • No Installation Required: The session information is self-contained. A threat actor can copy the folder to a fresh installation of Telegram on their own machine, and it will log in immediately.

Below are scenarios on how a threat actor may use stolen tdata:

Scenario 1: Direct Import

  1. Threat actor copies the tdata folder from the victim's system.
  2. Threat actor installs Telegram Desktop on their own computer.
  3. Threat actor replaces their own tdata folder with the victim's copy.
  4. When Telegram launches, it reads the stolen session tokens and logs in as the victim.

Scenario 2: Cloud Exfiltration

  1. Threat actor compresses the tdata folder on the victim's system.
  2. Threat actor uploads it to their own cloud storage or server.
  3. Later, threat actor downloads it to their machine.
  4. Threat actor places it in their Telegram Desktop directory.
  5. Telegram authenticates using the stolen session tokens.

Scenario 3: Portable Client

  1. Threat actor copies tdata to a USB drive or portable installation.
  2. Threat actor can run Telegram Portable from anywhere without installation.
  3. All session data travels with the portable folder.

Because the session appears as a legitimate login from a new device, it is often indistinguishable from normal user activity, making detection difficult without specific monitoring of the tdata directory.

What You Can Do: Protecting tdata and Managing Sessions

Here are the most effective steps to protect your system and your Telegram account.

Protect the tdata Folder

Implement File Integrity Monitoring by setting up alerts for any access to the tdata directory. If a process other than Telegram itself tries to read or copy files in that folder, you want to know immediately.

Harden SSH Access since many of these attacks begin with weak SSH credentials. The most effective fix is to disable password authentication and use SSH keys instead. If you must use passwords, make them long and unique.

Monitor for Reconnaissance Commands such as grep, '[Mm]iner', ls -la …/tdata, or searches for modem devices /dev/ttyGSM*, and treat them as critical alerts. These aren't normal user activities and usually indicate a threat actor is mapping your system.

Manage Your Sessions

Conduct Regular Session Audits by navigating to Telegram Settings > Privacy and Security > Active Sessions. If you see a device or location you don't recognize, terminate it immediately. This is your first line of defense if tdata is stolen.

Log Out of Unused Devices because every device you're logged into is a potential entry point. If you're not actively using Telegram on a laptop or tablet, log out. Fewer active sessions mean fewer targets for threat actors.

Consider Mobile Usage as these devices offer better session controls. Telegram on iOS and Android supports biometric authentication and makes it harder to exfiltrate session data via file copying. If you're concerned about tdata theft, use Telegram primarily on mobile.

Enable Two-Factor Authentication (2FA) even though tdata theft bypasses it. 2FA protects against standard account takeovers where the threat actor doesn't have your session token, and it could make it harder for the threat actor to reset the password after the session expires.

Network-Level Detection

Monitor for Telegram Bot API Traffic since threat actors often use the Telegram Bot API to send stolen data or receive commands. Research by SonicWall [4] has documented campaigns where phishing emails deliver HTML attachments that exfiltrate credentials directly to Telegram bots, highlighting the need to monitor for this traffic.

Block Known Malicious IPs as many of these attacks come from known command-and-control servers. Subscribe to threat intelligence feeds that track Telegram-based attack infrastructure and block those IPs at your firewall.

The Bigger Picture: Why Telegram Remains a Target

Despite Telegram banning millions of accounts, threat actors continue to migrate to the platform due to its infrastructure simplicity, encryption, and massive scale. The platform's marketplace ecosystem and resilience against take-downs make it an attractive venue for criminal activity. According to Beeble.com's analysis ‘The Great Telegram Purge: Why 43 Million Bans Couldn’t Break the Cybercrime Grip’ [5], Telegram has evolved from a messaging app into a comprehensive criminal infrastructure platform.

Silobreaker's research [6] further indicates that ransomware groups like BlackCat use Telegram for both data exfiltration and selling stolen credentials on public marketplaces, while Kaspersky [7] notes that Telegram has become a hub for crypto scams, generating millions in fraudulent revenue through fake support bots and investment channels.

Conclusion

The multi-layered attack captured in my honeypot reflects current priorities in the threat landscape. The combination of cryptojacking reconnaissance with Telegram credential harvesting demonstrates that threat actors are thinking beyond simple resource theft. They are building persistent access through account takeover to enable ongoing exploitation.

The key insight is that Telegram's features, while legitimate for many users, have been repurposed by threat actors for credential theft, C2 communication, and data exfiltration. Defenders must monitor not just for malware installation, but for the specific indicators of credential harvesting that enable account takeover and lateral movement through social channels.

By understanding the attack chain, recognizing the indicators, and implementing robust protections for the tdata folder and session management, we can better protect ourselves against these evolving threats.

Key Takeaways

  • Telegram tdata is a high-value target: Session tokens in this folder allow threat actors to bypass 2FA and take over accounts instantly.
  • Attack chains are evolving: Modern threats combine cryptojacking reconnaissance with credential harvesting for multi-layered exploitation.
  • Monitor for specific indicators: File access to tdata, modem device enumeration, and 'miner' process searches are critical warning signs.
  • Telegram Portable enables persistence: Threat actors can copy tdata to portable installations for seamless account takeover without detection.
  • Defense requires multiple layers: SSH hardening, file integrity monitoring, and session auditing are all necessary to protect against this attack pattern.

Acknowledgments: This analysis was assisted by Lumo AI (Proton) [8] for content organization and structuring.

[1] https://www.sans.edu/cyber-security-programs/bachelors-degree/
[2] https://attack.mitre.org/techniques/
[3] https://www.imperva.com/blog/telegram-identity-theft/
[4] https://www.sonicwall.com/blog/threat-actors-caught-using-telegram-bot-to-harvest-credentials
[5] https://beeble.com/en/blog/the-great-telegram-purge-why-43-million-bans-couldn-t-break-the-cybercrime-grip
[6] https://www.silobreaker.com/blog/cyber-threats/mapping-threat-actor-abuse-of-telegram-from-c2-to-hacktivism/
[7] https://www.kaspersky.com/blog/phishing-and-scam-in-telegram-2025/54090/
[8] https://lumo.proton.me

 


Jesse La Grew
Senior Handler

(c) SANS Internet Storm Center. https://isc.sans.edu Creative Commons Attribution-Noncommercial 3.0 United States License.

Security

A .WAV With A Payload, (Tue, Apr 21st)

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There have been reports of threat actors using a .wav file as a vector for malware.

It's a proper .wav file, but they didn't use staganography. The .wav file will play, but you'll just hear noise:

That's because the TAs have just replaced the bytes that encode the sound with the BASE64 representation of their payload:

Thus I don't need a .wav parser to extract the encoded payload, I can just use my base64dump.py tool:

The BASE64-decoded payload is an XOR-encoded PE file. So I don't need to make a custom decoder, I can just perform a known-plaintext attack looking for the DOS header with my xor-kpa.py tool:

The XOR key was found. Thus we can easily dump the decoded PE file and see the MZ header at position 0x08 and a bit further down the DOS header we used in the known-plaintext-attack:

And my tool pecheck.py can extract an analyse the sample:

Didier Stevens
Senior handler
blog.DidierStevens.com

(c) SANS Internet Storm Center. https://isc.sans.edu Creative Commons Attribution-Noncommercial 3.0 United States License.

Security

Lumma Stealer infection with Sectop RAT (ArechClient2), (Fri, Apr 17th)

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Introduction

This diary provides indicators from a Lumma Stealer infection that was followed by Sectop RAT (ArechClient2). I searched for cracked versions of popular copyright-protected software, and I downloaded the initial malware after following the results of one such search. This is a common distribution technique for various families of malware, and I often find Lumma Stealer this way.

In this case, the initial malware for Lumma Stealer was delivered as a password-protected 7-zip archive. The extracted malware is an inflated Windows executable (EXE) file at 806 MB. The EXE is padded with null-bytes (0x00), a technical which increases the EXE size while allowing the compressed archive file to be much smaller. The password-protected archive and inflated EXE file are designed to avoid detection.

Images from the infection


Shown above: Example of a page with instructions to download the initial malware file.


Shown above: Traffic from the infection filtered in Wireshark.


Shown above: Sectop RAT persistent on an infected Windows host.

Indicators of Compromise

Example of download link from the site advertising cracked versions of copyright-protected software:

hxxps[:]//incolorand[.]com/how-visual-patch-enhances-ui-consistency-across-releases/?utm_source={CID}&utm_term=Adobe%20Premiere%20Pro%20(2026)%20Full%20v26.0.2%20Espa%C3%B1ol%20[Mega]&utm_content={SUBID1}&utm_medium={SUBID2}

Example of URL for page with the file download instructions:

hxxps[:]//mega-nz.goldeneagletransport[.]com/Adobe_Premiere_Pro_%282026%29_Full_v26.0.2_Espa%C3%B1ol_%5BMega%5D.zip?c=ABUZ4WkRgQUA_YUCAFVTFwASAAAAAACh&s=360721

Example of URL for file download from site above site impersonating MEGA:

hxxps[:]//arch.primedatahost3[.]cfd/auth/media/JvWcFd5vUoYTrImvtWQAASTh/Adobe_Premiere_Pro_(2026)_Full_v26.0.2_Espa%C3%B1ol_%5BMega%5D.zip

Downloaded file:

Extracted malware:

  • SHA256 hash: 4849f76dafbef516df91fecfc23a72afffaf77ade51f805eae5ad552bed88923
  • File size: 806,127,604 bytes
  • File name: appFile.exe
  • File type: PE32 executable (GUI) Intel 80386, for MS Windows
  • File description: Inflated Windows EXE file for Lumma Stealer, padded with null-bytes

Deflated malware:

Lumma Stealer command and control (C2) domains from Triage sandbox analysis:

  • cankgmr[.]cyou
  • carytui[.]vu
  • decrnoj[.]club
  • genugsq[.]best
  • longmbx[.]click
  • mushxhb[.]best
  • pomflgf[.]vu
  • strikql[.]shop
  • ulmudhw[.]shop

Follow-up malware:

Example of Sectop RAT C2 traffic from an infected Windows host:

  • hxxp[:]//91.92.241[.]102:9000/wmglb
  • hxxp[:]//91.92.241[.]102:9000/wbinjget?q=66B553A8B94CE37C16F4EBC863D51FCC
  • tcp[:]//91.92.241[.]102:443/ – encoded or otherwise encrypted traffic (not HTTPS/TLS)


Bradley Duncan
brad [at] malware-traffic-analysis.net

(c) SANS Internet Storm Center. https://isc.sans.edu Creative Commons Attribution-Noncommercial 3.0 United States License.

AWS

Introducing Anthropic’s Claude Opus 4.7 model in Amazon Bedrock

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Today, we’re announcing Claude Opus 4.7 in Amazon Bedrock, Anthropic’s most intelligent Opus model for advancing performance across coding, long-running agents, and professional work.

Claude Opus 4.7 is powered by Amazon Bedrock’s next generation inference engine, delivering enterprise-grade infrastructure for production workloads. Bedrock’s new inference engine has brand-new scheduling and scaling logic which dynamically allocates capacity to requests, improving availability particularly for steady-state workloads while making room for rapidly scaling services. It provides zero operator access—meaning customer prompts and responses are never visible to Anthropic or AWS operators—keeping sensitive data private.

According to Anthropic, Claude Opus 4.7 model provides improvements across the workflows that teams run in production such as agentic coding, knowledge work, visual understanding,long-running tasks. Opus 4.7 works better through ambiguity, is more thorough in its problem solving, and follows instructions more precisely.

  • Agentic coding: The model extends Opus 4.6’s lead in agentic coding, with stronger performance on long-horizon autonomy, systems engineering, and complex code reasoning tasks. According to Anthropic, the model records high-performance scores with 64.3% on SWE-bench Pro, 87.6% on SWE-bench Verified, and 69.4% on Terminal-Bench 2.0.
  • Knowledge work: The model advances professional knowledge work, with stronger performance on document creation, financial analysis, and multi-step research workflows. The model reasons through underspecified requests, making sensible assumptions and stating them clearly, and self-verifies its output to improve quality on the first step. According to Anthropic, the model reaches 64.4% on Finance Agent v1.1.
  • Long-running tasks: The model stays on track over longer horizons, with stronger performance over its full 1M token context window as it reasons through ambiguity and self-verifies its output.
  • Vision: the model adds high-resolution image support, improving accuracy on charts, dense documents, and screen UIs where fine detail matters.

The model is an upgrade from Opus 4.6 but may require prompting changes and harness tweaks to get the most out of the model. To learn more, visit Anthropic’s prompting guide.

Claude Opus 4.7 model in action
You can get started with Claude Opus 4.7 model in Amazon Bedrock console. Choose Playground under Test menu and choose Claude Opus 4.7 when you select model. Now, you can test your complex coding prompt with the model.

I run the following prompt example about technical architecture decision:
Design a distributed architecture on AWS in Python that should support 100k requests per second across multiple geographic regions.

You can also access the model programmatically using the Anthropic Messages API to call the bedrock-runtime through Anthropic SDK or bedrock-mantle endpoints, or keep using the Invoke and Converse API on bedrock-runtime through the AWS Command Line Interface (AWS CLI) and AWS SDK.

To get started with making your first API call to Amazon Bedrock in minutes, choose Quickstart in the left navigation pane in the console. After choosing your use case, you can generate a short term API key to authenticate your requests as testing purpose.

When you choose the API method such as the OpenAI-compatible Responses API, you can get sample codes to run your prompt to make your inference request using the model.


To invoke the model through the Anthropic Claude Messages API, you can proceed as follows using anthropic[bedrock] SDK package for a streamlined experience:

from anthropic import AnthropicBedrockMantle
# Initialize the Bedrock Mantle client (uses SigV4 auth automatically)
mantle_client = AnthropicBedrockMantle(aws_region=REGION)
# Create a message using the Messages API
message = mantle_client.messages.create(
    model="anthropic.claude-opus-4-7",
    max_tokens=2048,
    messages=[ 
	    {"role": "user", "content": "Design a distributed architecture on AWS in Python that should support 100k requests per second across multiple geographic regions"}
    ]
)
print(message.content[0].text)

You can also run the following command to invoke the model directly to bedrock-runtime endpoint using the AWS CLI and the Invoke API:

aws bedrock-runtime invoke-model  
 --model-id anthropic.claude-opus-4-7  
 --region us-east-1  
 --body '{"messages": [{"role": "user", "content": "Design a distributed architecture on AWS in Python that should support 100k requests per second across multiple geographic regions."}], "max_tokens": 512, "temperature": 0.5, "top_p": 0.9}'  
 --cli-binary-format raw-in-base64-out  
invoke-model-output.txt

For more intelligent reasoning capability, you can use Adaptive thinking with Claude Opus 4.7, which lets Claude dynamically allocate thinking token budgets based on the complexity of each request.

To learn more, visit the Anthropic Claude Messages API and check out code examples for multiple use cases and a variety of programming languages.

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

  • Choosing APIs: You can choose from a variety of Bedrock APIs for model inference, as well as the Anthropic Messages API. The Bedrock-native Converse API supports multi-turn conversations and Guardrails integration. The Invoke API provides direct model invocation and lowest-level control.
  • Scaling and capacity: Bedrock’s new inference engine is designed to rapidly provision and serve capacity across many different models. When accepting requests, we prioritize keeping steady state workloads running, and ramp usage and capacity rapidly in response to changes in demand. During periods of high demand, requests are queued, rather than rejected. Up to 10,000 requests per minute (RPM) per account per Region are available immediately, with more available upon request.

Now available
Anthropic’s Claude Opus 4.7 model is available today in the US East (N. Virginia), Asia Pacific (Tokyo), Europe (Ireland), and Europe (Stockholm) Regions; check the full list of Regions for future updates. To learn more, visit the Claude by Anthropic in Amazon Bedrock page and the Amazon Bedrock pricing page.

Give Anthropic’s Claude Opus 4.7 a try in the Amazon Bedrock console today and send feedback to AWS re:Post for Amazon Bedrock or through your usual AWS Support contacts.

Channy