惯性聚合 高效追踪和阅读你感兴趣的博客、新闻、科技资讯
阅读原文 在惯性聚合中打开

推荐订阅源

Cyberwarzone
Cyberwarzone
V
Vulnerabilities – Threatpost
T
Tenable Blog
Forbes - Security
Forbes - Security
Simon Willison's Weblog
Simon Willison's Weblog
AWS News Blog
AWS News Blog
G
GRAHAM CLULEY
Know Your Adversary
Know Your Adversary
S
Securelist
C
Cybersecurity and Infrastructure Security Agency CISA
Project Zero
Project Zero
C
CXSECURITY Database RSS Feed - CXSecurity.com
V
Visual Studio Blog
WordPress大学
WordPress大学
Latest news
Latest news
K
Kaspersky official blog
T
Tailwind CSS Blog
T
Threat Research - Cisco Blogs
B
Blog RSS Feed
C
Cisco Blogs
博客园 - 聂微东
Martin Fowler
Martin Fowler
T
The Blog of Author Tim Ferriss
小众软件
小众软件
L
LangChain Blog
阮一峰的网络日志
阮一峰的网络日志
L
LINUX DO - 热门话题
Stack Overflow Blog
Stack Overflow Blog
罗磊的独立博客
P
Proofpoint News Feed
CTFtime.org: upcoming CTF events
CTFtime.org: upcoming CTF events
P
Privacy International News Feed
Cyber Security Advisories - MS-ISAC
Cyber Security Advisories - MS-ISAC
C
CERT Recently Published Vulnerability Notes
Cisco Talos Blog
Cisco Talos Blog
S
SegmentFault 最新的问题
Security Latest
Security Latest
Y
Y Combinator Blog
爱范儿
爱范儿
aimingoo的专栏
aimingoo的专栏
P
Privacy & Cybersecurity Law Blog
L
LINUX DO - 最新话题
月光博客
月光博客
The GitHub Blog
The GitHub Blog
博客园 - 三生石上(FineUI控件)
S
Security Affairs
P
Proofpoint News Feed
D
DataBreaches.Net
有赞技术团队
有赞技术团队
云风的 BLOG
云风的 BLOG

Darktrace Blog

Why behavioral AI is the answer to Mythos 7 MCP Risks CISO’s Should Consider and How to Prepare How To Secure AI And Find The Gaps In Your Security Operations 92% of Security Pros Concerned About AI Agents Darktrace Launches Unified Security Awareness Training and Messaging Security Darktrace Identifies Encryption in a World Leaks Ransomware Attack NetSupport RAT: Why Legitimate Tools Are as Damaging as Malware What the Darktrace Annual Threat Report 2026 Means for Security Leaders CVE-2026-1731: How Darktrace Sees the BeyondTrust Exploitation Wave Unfolding AppleScript Abuse: Unpacking a macOS Phishing Campaign Darktrace Identifies Campaign Targeting South Korea Leveraging VS Code for Remote Access Medusa Ransomware 2025: RMM Abuse in Ransomware Campaigns How a Leading Bank is Prioritizing Risk Management with Darktrace A framework for securing AI in the enterprise The Year Ahead: AI Cybersecurity Trends to Watch in 2026 Phishing attacks surge by 620% in the lead-up to Black Friday How to Manage Risk in Amazon Bedrock Vo1d Botnet Exposed: How Darktrace Detected a Global Android Threat Tracking a Dragon: Investigating a DragonForce-affiliated ransomware attack with Darktrace Why API + Journaling Delivers Faster, SLA-Backed Email Security for Microsoft 365 Darktrace delivers the next evolution of unified and proactive NDR Salty Much: Darktrace’s take on a recent Salt Typhoon intrusion Akira SonicWall Campaign Uncovered Detecting Vendor Compromise and Trusted Relationship Abuse with Darktrace Industry-First Automated Cloud Forensics SEO Poisoning and Fake PuTTY sites: Darktrace’s Investigation into the Oyster backdoor Why Unifying Email and Network Security Is Critical for Modern Cyber Defense What is a VPS and How Do Attackers Abuse Virtual Servers? Investigating the Ivanti Endpoint Manager Mobile Vulnerabilities 2025 Cyber Threats: A Mid‑Year Review AI Analyst in Action: 4 Real-World Investigations using AI Investigations AI Maturity Model: A Roadmap for Security 5 Core Capabilities for Cloud Forensics and IR Wallet Drainers: How Scams Steal Funds Top Eight Threats to SaaS Security and How to Combat Them Darktrace Tracks CVE‑2025‑31324 Activity UK Cyber Bill: What CISOs Need to Know Unpacking ClickFix: Darktrace Detection Insights Darktrace Recognized as a Leader in the 2025 Gartner® Magic Quadrant™ for Network Detection and Response Evaluating Email Security: How to Select the Best Solution for Your Organization AsyncRAT Exposed: Signals and Mitigations Anomaly-Based Threat Hunting: Darktrace's Approach in Action Darktrace Tracks SocGholish to RansomHub How NDR and Secure Access Service Edge (SASE) Work Together to Achieve Network Security Outcomes Force Multiply Your Security Team with Agentic AI: How the Industry’s Only True Cyber AI Analyst™ Saves Time and Stop Threats Why Data Classification Isn’t Enough to Prevent Data Loss Email bombing exposed: Darktrace’s email defense in action Global Technology Provider Transforms Email Threat Detection with Darktrace Survey findings: How is AI Impacting the SOC? Our Annual Survey Reveals How Security Teams Are Adapting to AI-Powered Threats New Threat on the Prowl: Investigating Lynx Ransomware Why Darktrace / EMAIL Excels Against APTs RansomHub’s Rise: RaaS Market Insights CNAPP Alone Isn’t Enough: Focusing on CDR for Real-Time Cross Domain Protection Reimagining Your SOC: How to Shift Away From Reactive Network Security RansomHub Ransomware: Darktrace’s Investigation of the Newest Tool in ShadowSyndicate's Arsenal Why AI-powered Email Protection Became Essential for this Global Financial Services Leader Agent vs. Agentless Cloud Security: Why Deployment Methods Matter Defending AITM Phishing and Mamba Attacks Breaking Down Nation State Attacks on Supply Chains Darktrace is Positioned as a Leader in the IDC MarketScape: Worldwide Network Detection and Response 2024 Vendor Assessment Protecting Your Hybrid Cloud: The Future of Cloud Security in 2025 and Beyond Phishing Attacks Surge Over 600% in the Buildup to Black Friday Why Artificial Intelligence is the Future of Cybersecurity Darktrace Leading the Future of Network Detection and Response With Recognition from KuppingerCole AI and Cybersecurity: Predictions for 2025 Navigating Buying and Adoption Journeys for AI Cybersecurity Tools How Darktrace won an email security trial by learning the business, not the breach Introducing Real-Time Multi-Cloud Detection & Response Powered by AI From Call to Compromise: Darktrace’s Response to a Vishing-Induced Network Attack Business Email Compromise (BEC) in the Age of AI How AI can help CISOs navigate the global cyber talent shortage What you need to know about FAA Security Protection Regulations 2024 Introducing ‘Defend Beyond’: Our promise to customers in the face of evolving threats How Darktrace’s AI Applies a Zero-Trust Mentality within Critical Infrastructure Supply Chains Darktrace Releases 2024 Half-Year Threat Insights Safelink Smuggling: Enhancing Resilience Against Malicious Links CDR is just NDR for the Cloud... Right? Qilin RaaS: Darktrace Detection Insights Elevating Network Security: Confronting Trust, Ransomware, & Novel Attacks Safeguarding Distribution Centers in the Digital Age Darktrace Investigation Into Medusa Ransomware Exploring the Benefits and Risks of Third-Party Data Solutions Strategies to Combat Microsoft Teams Phishing Attacks Lost in Translation: Darktrace Blocks Non-English Phishing Campaign Concealing Hidden Payloads How Empowering End Users can Improve Your Email Security and Decrease the Burden on the SOC The Rise of Alternative Access in Cloud Attacks The State of AI in Cybersecurity: How AI will impact the cyber threat landscape in 2024 Moving Beyond XDR to Achieve True Cyber Resilience with Darktrace ActiveAI Security Platform The State of AI in Cybersecurity: Unveiling Global Insights from 1,800 Security Practitioners Balada Injector: Darktrace’s Investigation into the Malware Exploiting WordPress Vulnerabilities Looking Beyond Secure Email Gateways with the Latest Innovations to Darktrace / EMAIL Utilizing AI Security Against Phishing Campaigns AI Function Assistance to Humans in Cyber Crises How Darktrace SOC Thwarted a BEC Attack Understanding Email Security & the Psychology of Trust Breaking Down "ICES": An Umbrella Term With Wide Variety Boosting Security Posture with Email Integration Enhancing Darktrace with Microsoft Defender Flexible Deployments for Enhanced Email Security
ShadowV2: An emerging DDoS for hire botnet
Nate Bill · 2025-09-23 · via Darktrace Blog

Introduction: ShadowV2 DDoS

Darktrace's latest investigation uncovered a novel campaign that blends traditional malware with modern devops technology.

At the center of this campaign is a Python-based command-and-control (C2) framework hosted on GitHub CodeSpaces. This campaign also utilizes a Python based spreader with a multi-stage Docker deployment as the initial access vector.

The campaign further makes use of a Go-based Remote Access Trojan (RAT) that implements a RESTful registration and polling mechanism, enabling command execution and communication with its operators.

ShadowV2 attack techniques

What sets this campaign apart is the sophistication of its attack toolkit.

The threat actors employ advanced methods such as HTTP/2 rapid reset, a Cloudflare under attack mode (UAM) bypass, and large-scale HTTP floods, demonstrating a capability to combine distributed denial-of-service (DDoS) techniques with targeted exploitation.

With the inclusion of an OpenAPI specification, implemented with FastAPI and Pydantic and a fully developed login panel and operator interface, the infrastructure seems to resemble a “DDoS-as-a-service” platform rather than a traditional botnet, showing the extent to which modern malware increasingly mirrors legitimate cloud-native applications in both design and usability.

Analysis of a ShadowV2 attack

Initial access

The initial compromise originates from a Python script hosted on GitHub CodeSpaces. This can be inferred from the observed headers:

User-Agent: docker-sdk-python/7.1.0

X-Meta-Source-Client: github/codespaces

The user agent shows that the attacker is using the Python Docker SDK, a library for Python programs that allows them to interact with Docker to create containers. The X-Meta-Source-Client appears to have been injected by GitHub into the request to allow for attribution, although there is no documentation online about this header.

The IP the connections originate from is 23.97.62[.]139, which is a Microsoft IP based in Singapore. This aligns with expectations as GitHub is owned by Microsoft.

This campaign targets exposed Docker daemons, specifically those running on AWS EC2. Darktrace runs a number of honeypots across multiple cloud providers and has only observed attacks against honeypots running on AWS EC2. By default, Docker is not accessible to the Internet, however, can be configured to allow external access. This can be useful for managing complex deployments where remote access to the Docker API is needed.

Typically, most campaigns targeting Docker will either take an existing image from Docker Hub and deploy their tools within it, or upload their own pre-prepared image to deploy. This campaign works slightly differently; it first spawns a generic “setup” container and installs a number of tools within it. This container is then imaged and deployed as a live container with the malware arguments passed in via environmental variables.

Attacker creates a blank container from an Ubuntu image.

Figure 1: Attacker creates a blank container from an Ubuntu image.

Attacker sets up their tools for the attack.

Figure 2: Attacker sets up their tools for the attack.

 Attacker deploys a new container using the image from the setup container.

Figure 3: Attacker deploys a new container using the image from the setup container.

It is unclear why the attackers chose this approach - one possibility is that the actor is attempting to avoid inadvertently leaving forensic artifacts by performing the build on the victim machine, rather than building it themselves and uploading it.

Malware analysis

The Docker container acts as a wrapper around a single binary, dropped in /app/deployment. This is an ELF binary written in Go, a popular choice for modern malware. Helpfully, the binary is unstripped, making analysis significantly easier.

The current version of the malware has not been reported by OSINT providers such as VirusTotal. Using the domain name from the MASTER_ADDR variable and other IoCs, we were able to locate two older versions of the malware that were submitted to VirusTotal on the June 25 and July 30 respectively [1] [2].  Neither of these had any detections and were only submitted once each using the web portal from the US and Canada respectively. Darktrace first observed the attack against its honeypot on June 24, so it could be a victim of this campaign submitting the malware to VirusTotal. Due to the proximity of the start of the attacks, it could also be the attacker testing for detections, however it is not possible to know for certain.

The malware begins by phoning home, using the MASTER_ADDR and VPS_NAME identifiers passed in from the Docker run environmental variables. In addition, the malware derives a unique VPS_ID, which is the VPS_NAME concatenated with the current unix timestamp. The VPS_ID is used for all communications with the C2 server as the identifier for the specific implant. If the malware is restarted, or the victim is re-infected, the C2 server will inform the implant of its original VPS_ID to ensure continuity.

Snippet that performs the registration by sending a POST request to the C2 API with a JSON structure.

Figure 4: Snippet that performs the registration by sending a POST request to the C2 API with a JSON structure.

From there, the malware then spawns two main loops that will remain active for the lifetime of the implant. Every second, it sends a heartbeat to the C2 by sending the VPS_ID to hxxps://shadow.aurozacloud[.]xyz/api/vps/heartbeat via POST request. Every 5 seconds, it retrieves hxxps://shadow.aurozacloud[.]xyz/api/vps/poll/<VPS ID> via a GET request to poll for new commands.

The poll mechanism shadow v2

Figure 5: The poll mechanism.

At this stage, Darktrace security researchers wrote a custom client that ran on the server infected by the attacker that mimicked their implant. The goal was to intercept commands from the C2. Based on this, it was observed initiating an attack against chache08[.]werkecdn[.]me using a 120 thread HTTP2 rapid reset attack. This site appears to be hosted on an Amsterdam VPS provided by FDCServers, a server hosting company. It was not possible to identify what normally runs on this site, as it returns a 403 Forbidden error when visited.

Darktrace’s code analysis found that the returned commands contain the following fields:

  • Method (e.g. GET, POST)
  • A unique ID for the attack
  • A URL endpoint used to report attack statistics
  • The target URL & port
  • The duration of the attack
  • The number of threads to use
  • An optional proxy to send HTTP requests through

The malware then spins up several threads, each running a configurable number of HTTP clients using Valyala’s fasthttp library, an open source Go library for making high-performance HTTP requests. After this is complete, it uses these clients to perform an HTTP flood attack against the target.

A snippet showing the fasthttp client creation loop, as well as a function to report the worker count back to the C2.

Figure 6: A snippet showing the fasthttp client creation loop, as well as a function to report the worker count back to the C2.

In addition, it also features several flags to enable different bypass mechanisms to augment the malware:

  • WordPress bypass (does not appear to be implemented - the flag is not used anywhere)
  • Random query strings appended to the URL
  • Spoofed forwarding headers with random IP addresses
  • Cloudflare under-attack-mode (UAM) bypass
  • HTTP2 rapid reset

The most interesting of these is the Cloudflare UAM bypass mechanism. When this is enabled, the malware will attempt to use a bundled ChromeDP binary to solve the Cloudflare JavaScript challenge that is presented to new visitors. If this succeeds, the clearance cookie obtained is then included in subsequent requests. This is unlikely to work in most cases as headless Chrome browsers are often flagged, and a regular CAPTCHA is instead served.

The UAM bypass success snippet.

Figure 7: The UAM bypass success snippet.

Additionally, the malware has a flag to enable an HTTP2 rapid reset attack mode instead of a regular HTTP flood. In HTTP2, a client can create thousands of requests within a single connection using multiplexing, allowing sites to load faster. The number of request streams per connection is capped however, so in a rapid reset attack many requests are made and then immediately cancelled to allow more requests to be created. This allows a single client to execute vastly more requests per second and use more server resources than it otherwise would, allowing for more effective denial-of-service (DoS) attacks.

 The HTTP2 rapid reset snippet from the main attack function.

Figure 8: The HTTP2 rapid reset snippet from the main attack function.

API/C2 analysis

As mentioned throughout the malware analysis section, the malware communicates with a C2 server using HTTP. The server is behind Cloudflare, which obscures its hosting location and prevents analysis. However, based on analysis of the spreader, it's likely running on GitHub CodeSpaces.

When sending a malformed request to the API, an error generated by the Pydantic library is returned:

{"detail":[{"type":"missing","loc":["body","vps_id"],"msg":"Field required","input":{"vps_name":"xxxxx"},"url":"https://errors.pydantic.dev/2.11/v/missing"}]}

This shows they are using Python for the API, which is the same language that the spreader is written in.

One of the larger frameworks that ships with Pydantic is FastAPI, which also ships with Swagger. The malware author left this publicly exposed, and Darktrace’s researchers were able to obtain a copy of their API documentation. The author appears to have noticed this however, as subsequent attempts to access it now returns a HTTP 404 Not Found error.

Swagger UI view based on the obtained OpenAPI spec.

Figure 9: Swagger UI view based on the obtained OpenAPI spec.

This is useful to have as it shows all the API endpoints, including the exact fields they take and return, along with comments on each endpoint written by the attacker themselves.

It is very likely a DDoS for hire platform (or at the very least, designed for multi-tenant use) based on the extensive user API, which features authentication, distinctions between privilege level (admin vs user), and limitations on what types of attack a user can execute. The screenshot below shows the admin-only user create endpoint, with the default limits.

The admin-only user create endpoint shadow v2

Figure 10: The admin-only user create endpoint.

The endpoint used to launch attacks can also be seen, which lines up with the options previously seen in the malware itself. Interestingly, this endpoint requires a list of zombie systems to launch the attack from. This is unusual as most DDoS for hire services will decide this internally or just launch the attack from every infected host (zombie). No endpoints that returned a list of zombies were found, however, it’s possible one exists as the return types are not documented for all the API endpoints.

The attack start endpoint shadow v2

Figure 11: The attack start endpoint.

There is also an endpoint to manage a blacklist of hosts that cannot be attacked. This could be to stop users from launching attacks against sites operated by the malware author, however it’s also possible the author could be attempting to sell protection to victims, which has been seen previously with other DDoS for hire services.

Blacklist endpoints shadow v2 DDoS

Figure 12: Blacklist endpoints.

Attempting to visit shadow[.]aurozacloud[.]xyz results in a seizure notice. It is most likely fake the same backend is still in use and all of the API endpoints continue to work. Appending /login to the end of the path instead brings up the login screen for the DDoS platform. It describes itself as an “advanced attack platform”, which highlights that it is almost certainly a DDoS for hire service. The UI is high quality, written in Tailwind, and even features animations.

The fake seizure notice.

Figure 13: The fake seizure notice.

The login UI at /login.

Figure 14: The login UI at /login.

Conclusion

By leveraging containerization, an extensive API, and with a full user interface, this campaign shows the continued development of cybercrime-as-a-service. The ability to deliver modular functionality through a Go-based RAT and expose a structured API for operator interaction highlights how sophisticated some threat actors are.

For defenders, the implications are significant. Effective defense requires deep visibility into containerized environments, continuous monitoring of cloud workloads, and behavioral analytics capable of identifying anomalous API usage and container orchestration patterns. The presence of a DDoS-as-a-service panel with full user functionality further emphasizes the need for defenders to think of these campaigns not as isolated tools but as evolving platforms.

Appendices

References

1. https://www.virustotal.com/gui/file/1b552d19a3083572bc433714dfbc2b75eb6930a644696dedd600f9bd755042f6

2. https://www.virustotal.com/gui/file/1f70c78c018175a3e4fa2b3822f1a3bd48a3b923d1fbdeaa5446960ca8133e9c

IoCs

Malware hashes (SHA256)

●      2462467c89b4a62619d0b2957b21876dc4871db41b5d5fe230aa7ad107504c99

●      1b552d19a3083572bc433714dfbc2b75eb6930a644696dedd600f9bd755042f6

●      1f70c78c018175a3e4fa2b3822f1a3bd48a3b923d1fbdeaa5446960ca8133e9c

C2 domain

●      shadow.aurozacloud[.]xyz

Spreader IPs

●      23.97.62[.]139

●      23.97.62[.]136

Yara rule

rule ShadowV2 {

meta:

author = "[email protected]"

description = "Detects ShadowV2 botnet implant"

strings:

$string1 = "shadow-go"

$string2 = "shadow.aurozacloud.xyz"

$string3 = "[SHADOW-NODE]"

$symbol1 = "main.registerWithMaster"

$symbol2 = "main.handleStartAttack"

$symbol3 = "attacker.bypassUAM"

$symbol4 = "attacker.performHTTP2RapidReset"

$code1 = { 48 8B 05 ?? ?? ?? ?? 48 8B 1D ?? ?? ?? ?? E8 ?? ?? ?? ?? 48 8D 0D ?? ?? ?? ?? 48 89 8C 24 38 01 00 00 48 89 84 24 40 01 00 00 48 8B 4C 24 40 48 BA 00 09 6E 88 F1 FF FF FF 48 8D 04 0A E8 ?? ?? ?? ?? 48 8D 0D ?? ?? ?? ?? 48 89 8C 24 48 01 00 00 48 89 84 24 50 01 00 00 48 8D 05 ?? ?? ?? ?? BB 05 00 00 00 48 8D 8C 24 38 01 00 00 BF 02 00 00 00 48 89 FE E8 ?? ?? ?? ?? }

$code2 = { 48 89 35 ?? ?? ?? ?? 0F B6 94 24 80 02 00 00 88 15 ?? ?? ?? ?? 0F B6 94 24 81 02 00 00 88 15 ?? ?? ?? ?? 0F B6 94 24 82 02 00 00 88 15 ?? ?? ?? ?? 0F B6 94 24 83 02 00 00 88 15 ?? ?? ?? ?? 48 8B 05 ?? ?? ?? ?? }

$code3 = { 48 8D 15 ?? ?? ?? ?? 48 89 94 24 68 04 00 00 48 C7 84 24 78 04 00 00 15 00 00 00 48 8D 15 ?? ?? ?? ?? 48 89 94 24 70 04 00 00 48 8D 15 ?? ?? ?? ?? 48 89 94 24 80 04 00 00 48 8D 35 ?? ?? ?? ?? 48 89 B4 24 88 04 00 00 90 }

condition:

uint16(0) == 0x457f and (2 of ($string*) or 2 of ($symbol*) or any of ($code*))

}

The content provided in this blog is published by Darktrace for general informational purposes only and reflects our understanding of cybersecurity topics, trends, incidents, and developments at the time of publication. While we strive to ensure accuracy and relevance, the information is provided “as is” without any representations or warranties, express or implied. Darktrace makes no guarantees regarding the completeness, accuracy, reliability, or timeliness of any information presented and expressly disclaims all warranties.

Nothing in this blog constitutes legal, technical, or professional advice, and readers should consult qualified professionals before acting on any information contained herein. Any references to third-party organizations, technologies, threat actors, or incidents are for informational purposes only and do not imply affiliation, endorsement, or recommendation.

Darktrace, its affiliates, employees, or agents shall not be held liable for any loss, damage, or harm arising from the use of or reliance on the information in this blog.

The cybersecurity landscape evolves rapidly, and blog content may become outdated or superseded. We reserve the right to update, modify, or remove any content without notice.