Welcome to this week’s edition of the Threat Source newsletter.
A year ago, fresh off a layoff, I never would have guessed I’d be spending Halloween weekend bouncing between conversations about space policy, satellite hacking, and wedding plans. That’s exactly what happened when my space analyst friend came to stay with us for a few days. Between coffee runs, getting sneak peeks of his upcoming book, and painting on skull makeup for a party, we found ourselves deep in discussions about putting data centers in space and, inevitably, the world of satellite cybersecurity.
Somewhere within all of that, I realized I was on deck for the newsletter intro soon, and I did what any cyber newbie would do: I asked the nearest expert if there had ever been a well-known cyberattack on satellites. My friend didn’t even blink before answering, “KA-SAT.”
Some light research and a few Webex messages later, I was speaking with our own Joe Marshall — who, lucky for me, might be the only person at Cisco who’s been to satellite hacking training.
Joe walked me through how on Feb. 24, 2022, just hours before Russia’s invasion of Ukraine, a cyber attack targeted Viasat’s KA-SAT satellite network. The attackers exploited a vulnerability in a VPN appliance, gaining access to the network’s management systems. They then deployed a wiper malware called AcidRain, which was designed to erase data on modems and routers across Europe.
Satellite communications were disrupted for thousands of users in Ukraine, but surprisingly, beyond Ukraine’s borders, approximately 5,800 Enercon wind turbines in Germany lost connectivity for remote monitoring and control.
One surprise from the conversation was the overlap between the AcidRain wiper and VPNFilter, which you may remember from Joe’s September newsletter. AcidRain may be VPNFilter’s successor. Take a look:
Figure 1. Section headers strings tables for VPNFilter (left) and AcidRain (right). Credit: SentinelOne.
Identical, hinting at a shared compiler and other technical links, as SentinelOne’sblog details.
What followed this summary was a LOT of questions on my part. What was the VPN vulnerability? How did the wiper work, exactly? What are the pros and cons of replacing vs. fixing the modems, and what about the logistics of the winning decision? Ultimately, while the AcidRain attack was destructive, it was, in the context of what else was happening to Ukraine’s infrastructure, a blip.
As a newcomer to both cybersecurity and Talos, I keep discovering that there are always gaps in the story. I didn’t get all my questions answered because companies guard details, official statements leave out key information, and sometimes, even years later, we’re still piecing things together. Being okay with that is a tall order for people who scour logs looking for a needle in a stack of needles. But when attacks are raining down, customers aren’t asking you to send a flawless analysis. They want to know what you’redoing to keep them safe.
So, as I write this, still with more questions than answers about AcidRain and the KA-SAT attacks, I’m learning to find peace in knowing that curiosity is the foundation for future expertise. Keep acquiring knowledge, asking questions (both basic and complex), and being okay with some uncertainty.
The one big thing
Cisco Talos published a new blog today on the Kraken ransomware group. Linked to HelloKitty, they double-extort organizations globally with cross-platform attacks and use advanced techniques like encryption benchmarking and anti-analysis. Kraken has also launched a new underground forum to strengthen ties within the cybercrime community.
Why do I care?
Kraken’s advanced, cross-platform techniques — including encryption benchmarking and evasion methods — raise the threat level for organizations of all sizes, and may inspire similar advancements in future ransomware. Plus, their new secure underground forum may accelerate collaboration between threat actors, making robust, layered defenses and intelligence sharing among defenders even more critical.
So now what?
Prioritize patching known vulnerabilities (especially SMB), strengthen credential management, and implement comprehensive endpoint, network, and access security solutions. Continuous monitoring, incident response planning, and user awareness training are crucial to detect and contain threats early.
Top security headlines of the week
SAP fixes serious security issues – here’s how to stay safe A patch is now publicly available, and while SAP’s users were previously notified, the researchers are once again urging everyone to apply it as soon as possible since the risk is only going to get bigger going forward. (TechRadar)
Phishing tool uses smart redirects to bypass detection A new phishing tool targeting Microsoft 365 users called Quantum Route Redirect simplifies what was once a technically complex campaign flow, as well as offers a uniquely evasive redirect feature that can bypass even robust email protections. (Dark Reading)
Cisco finds open-weight AI models easy to exploit in long chats The report, titled Death by a Thousand Prompts: Open Model Vulnerability Analysis, analyzed eight leading open-weight language models and found that multi-turn attacks, where an attacker engages the model across multiple conversational steps, were up to ten times more effective than one-shot attempts. (HackRead)
Nearly 30 alleged victims of Oracle EBS hack named on Cl0p ransomware site The Cl0p website lists major organizations such as Logitech, The Washington Post, Cox Enterprises, Pan American Silver, LKQ Corporation, and Copeland. (SecurityWeek)
Kimsuky APT takes over South Korean Androids, abuses KakaoTalk One of North Korea’s formidable advanced persistent threat (APT) groups is targeting Android users in South Korea with a remote reset attack that exploits a feature in Google aimed at helping users find their devices. (Dark Reading)
Can’t get enough Talos?
The TTP: How Talos built an AI model into one of the internet’s most abused layers Hazel talks with Talos researcher David Rodriguez about how adversaries use DNS tunneling to sneak data out of networks, why it’s so difficult to spot in real time, and how Talos built an AI model to detect it without breaking anything important (like the internet).
The 2026 Snort Calendar is now available Snorty will pose as a new mythical creature each month. To get your copy, fill out our short survey. Calendars will begin shipping in December 2025. U.S. shipping only, available while supplies last.
Talos Takes: How attackers use your own tools against you From a wave of Toolshell events, to a rise in post-exploitation phishing, and the misuse of legitimate tools like Velociraptor, this quarter’s cases all point to a theme: attackers are getting very good at living off what’s already in your environment.
Do robots dream of secure networking? This blog demonstrates a proof of concept using LangChain and OpenAI, integrated with Cisco Umbrella API, to provide AI agents with real-time threat intelligence for evaluating domain dispositions.
https://www.backbox.org/wp-content/uploads/2018/09/website_backbox_text_black.png00adminhttps://www.backbox.org/wp-content/uploads/2018/09/website_backbox_text_black.pngadmin2025-11-13 19:06:332025-11-13 19:06:33Viasat and the terrible, horrible, no good, very bad day
Cybersecurity researchers have revealed a new attack method targeting AI browsers, which they refer to as AI sidebar spoofing. This attack exploits users’ growing habit of blindly trusting instructions they get from artificial intelligence. The researchers successfully implemented AI sidebar spoofing against two popular AI browsers: Comet by Perplexity and Atlas by OpenAI.
Initially, the researchers used Comet for their experiments, but later confirmed that the attack was viable in the Atlas browser as well. This post uses Comet as an example when explaining the mechanics of AI sidebar spoofing, but we urge the reader to remember that everything stated below also applies to Atlas.
How do AI browsers work?
To begin, let’s wrap our heads around AI browsers. The idea of artificial intelligence replacing, or at least transforming the familiar process of searching the internet began to generate buzz between 2023 and 2024. The same period saw the first-ever attempts to integrate AI into online searches.
Initially, these were supplementary features within conventional browsers — such as Microsoft Edge Copilot and Brave Leo — implemented as AI sidebars. They added built-in assistants to the browser interface for summarizing pages, answering questions, and navigating sites. By 2025, the evolution of this concept ushered in Comet from Perplexity AI — the first browser designed for user-AI interaction from the ground up.
This made artificial intelligence the centerpiece of Comet’s user interface, rather than just an add-on. It unified search, analysis, and work automation into a seamless experience. Shortly thereafter, in October 2025, OpenAI introduced its own AI browser, Atlas, which was built around the same concept.
Comet’s primary interface element is the input bar in the center of the screen, through which the user interacts with the AI. It’s the same with Atlas.
The home screens of Comet and Atlas demonstrate a similar concept: a minimalist interface with a central input bar and built-in AI that becomes the primary method of interacting with the web
Besides, AI browsers allow users to engage with the artificial intelligence right on the web page. They do this through a built-in sidebar that analyzes content and handles queries — all without having the user leave the page. The user can ask the AI to summarize an article, explain a term, compare data, or generate a command while remaining on the current page.
The sidebars in both Comet and Atlas allow users to query the AI without navigating to separate tabs — you can analyze the current site, and ask questions and receive answers within the context of the page you’re on
This level of integration conditions users to take the answers and instructions provided by the built-in AI for granted. When an assistant is seamlessly built into the user interface and feels like a natural part of the system, most people rarely stop to double-check the actions it suggests.
This trust is precisely what the attack demonstrated by the researchers exploits. A fake AI sidebar can issue false instructions — directing the user to execute malicious commands or visit phishing websites.
How did the researchers manage to execute the AI sidebar spoofing attack?
The attack starts with the user installing a malicious extension. To do its evil deeds, it needs permissions to view and modify data on all visited sites, as well as access to the client-side data storage API.
All of these are quite standard permissions; without the first one — no browser extension will work at all. Therefore, the chances that the user will get suspicious when a new extension requests these permissions are almost zero. You can read more about browser extensions and the permissions they request in our post Browser extensions: more dangerous than you think.
A list of installed extensions in the Comet user interface. The disguised malicious extension, AI Marketing Tool, is visible among them. Source
Once installed, the extension injects JavaScript into the web page and creates a counterfeit sidebar that looks strikingly similar to the real thing. This shouldn’t raise any red flags with the user: when the extension receives a query, it talks to the legitimate LLM and faithfully displays its response. The researchers used Google Gemini in their experiments, though OpenAI’s ChatGPT likely would have worked just as well.
The screenshot shows an example of a fake sidebar that’s visually very similar to the original Comet Assistant. Source
The fake sidebar can selectively manipulate responses to specific topics or key queries set in advance by the potential attacker. This means that in most cases, the extension will simply display legitimate AI responses, but in certain situations it will display malicious instructions, links, or commands instead.
How realistic is the scenario where an unsuspecting user installs a malicious extension capable of the actions described above? Experience shows it is highly probable. On our blog, we’ve repeatedly reported on dozens of malicious and suspicious extensions that successfully make it into the official Chrome Web Store. This continues to occur despite all the security checks conducted by the store and the vast resources at Google’s disposal. Read more about how malicious extensions end up in official stores in our post 57 shady Chrome extensions clock up six million installs.
Consequences of AI sidebar spoofing
Now let’s discuss what attackers can use a fake sidebar for. As noted by the researchers, the AI sidebar spoofing attack offers potential malicious actors ample opportunities to cause harm. To demonstrate this, the researchers described three possible attack scenarios and their consequences: crypto-wallet phishing, Google account theft, and device takeover. Let’s examine each of them in detail.
Using a fake AI sidebar to steal Binance credentials
In the first scenario, the user asks the AI in the sidebar how to sell their cryptocurrency on the Binance crypto exchange. The AI assistant provides a detailed answer that includes a link to the crypto exchange. But this link doesn’t lead to the real Binance site — it takes you to a remarkably convincing fake. The link points to the attacker’s phishing site, which uses the fake domain name binacee.
The fake login form on the domain login{.}binacee{.}com is nearly indistinguishable from the original, and is designed to steal user credentials. Source
Next, the unsuspecting user enters their Binance credentials and the code for two-factor authentication, if needed. After this, the attackers gain full access to the victim’s account and can siphon off all funds from their crypto wallets.
Using a fake AI sidebar to take over a Google account
The next attack variation also begins with a phishing link — in this case, to a fake file-sharing service. If the user clicks the link, they’re taken to a website where the landing page prompts them to sign in with their Google account right away.
After the user clicks this option, they’re redirected to the legitimate Google login page to enter their credentials there, but then the fake platform requests full access to the user’s Google Drive and Gmail.
The fake application share-sync-pro{.}vercel{.}app requests full access to the user’s Gmail and Google Drive. This gives the attackers control over the account. Source
If the user fails to scrutinize the page, and automatically clicks Allow, they grant attackers permissions for highly dangerous actions:
Viewing their emails and settings.
Reading, creating, and sending emails from their Gmail account.
Viewing and downloading all the files they store in Google Drive.
This level of access gives the cybercriminals the ability to steal the victim’s files, use services and accounts linked to that email address, and impersonate the account owner to disseminate phishing messages.
Reverse shell initiated through a fake AI-generated utility installation guide
Finally, in the last scenario, the user asks the AI how to install a certain application; the Homebrew utility was used in the example, but it could be anything. The sidebar shows the user a perfectly reasonable, AI-generated guide. All steps in it look plausible and correct up until the final stage, where the utility installation command is replaced with a reverse shell.
The guide for installing the utility as shown in the sidebar is almost entirely correct, but the last step contains a reverse shell command. Source
If the user follows the AI’s instructions by copying and pasting the malicious code into the terminal and then running it, their system will be compromised. The attackers will be able to download data from the device, monitor activity, or install malware and continue the attack. This scenario clearly demonstrates that a single replaced line of code in a trusted AI interface is capable of fully compromising a device.
How to avoid becoming a victim of fake AI-sidebars
The AI sidebar spoofing attack scheme is currently only theoretical. However, in recent years attackers have been very quick to turn hypothetical threats into practical attacks. Thus, it’s quite possible that some malware creator is already hard at work on a malicious extension using a fake AI-sidebar, or uploading one to an official extension store.
Therefore, it’s important to remember that even a familiar browser interface can be compromised. And even if instructions look convincing and come from the in-browser AI assistant, you shouldn’t blindly trust them. Here’s some final tips to help you avoid falling victim to an attack involving fake AI:
When using AI assistants, carefully check all commands and links before following the AI’s recommendations.
If the AI recommends executing any programming code, copy it and find out what it does by pasting it into a search engine in a different, non-AI browser.
Don’t install browser extensions — AI or otherwise — unless absolutely necessary. Regularly clean up and delete any extensions you no longer use.
Before installing an extension, read the user reviews. Most malicious extensions rack up heaps of scathing reviews from duped users long before store moderators get around to removing them.
Before entering credentials or other confidential information, always check that the website address doesn’t look suspicious or contain typos. Pay attention to the top-level domain, too: it should be the official one.
Use Kaspersky Password Manager to store passwords. If it doesn’t recognize the site and doesn’t automatically offer to fill in the login and password fields, this is a strong reason to ask yourself if you might be on a phishing page.
Install a reliable security solution that will alert you to suspicious activity on your device and prevent you from visiting a phishing site.
What other threats await you in browsers — AI-powered or regular:
https://www.backbox.org/wp-content/uploads/2018/09/website_backbox_text_black.png00adminhttps://www.backbox.org/wp-content/uploads/2018/09/website_backbox_text_black.pngadmin2025-11-13 18:07:222025-11-13 18:07:22How a fake AI sidebar can steal your data | Kaspersky official blog
In August 2025, Cisco Talos observed big-game hunting and double extortion attacks carried out by Kraken, a Russian-speaking group that has emerged from the remnants of the HelloKitty ransomware cartel.
Talos observed in one intrusion that the Kraken actor exploited Server Message Block (SMB) vulnerabilities for initial access, then used tools like Cloudflared for persistence and SSH Filesystem (SSHFS) for data exfiltration before encryption.
Kraken is a cross-platform ransomware with distinct encryptors for Windows, Linux, and VMware ESXi, targeting a wide range of enterprise environments.
Kraken ransomware benchmarks a victim machine before starting the encryption process, a feature rarely seen in ransomware.
Talos also observed the announcement of a new underground forum, “The Last Haven Board,” on Kraken’s data leak blog, aimed at creating an anonymous and secure communication channel for the cybercrime underground.
Who is Kraken?
The Kraken ransomware group, which emerged in February 2025, employs a double extortion technique and appears to be opportunistic, as it has not concentrated on any specific business verticals. According to Kraken’s leak site, victims span various geographies, including the United States, the United Kingdom, Canada, Denmark, Panama, and Kuwait.
Like other operators in the double extortion space, Kraken also operates a data leak site to disclose the stolen data of victims who do not meet their ransom demands.
Figure 1. Kraken data leak blog.
Kraken encrypts the victim’s environment, uses the .zpsc file extension for the encrypted files, and drops a ransom note titled “readme_you_ws_hacked.txt.” In the ransom note, the actor threatens the victims by stating that they have stolen and encrypted their confidential data. They instruct the victim to contact them using an onion URL to prevent posting to their leak site.
Figure 2. Kraken ransomnote.
Talos observed in one of the instances that the actor demanded a ransom of around 1 million USD to be paid in Bitcoin to the actor’s wallet address. Kraken assures victims that after the successful payment, they will decrypt the environment and guarantee the non-disclosure of stolen data.
Ties to HelloKitty
Kraken, a Russian-speaking gang, is suspected to have emerged from the ashes of the HelloKitty ransomware cartel or to have been established by some of its former members, according to external reports. The title of the Kraken data leak site explicitly mentions the HelloKitty ransomware group name. Additionally, Talos has observed that Kraken and HelloKitty use the same ransom note filename, indicating a possible link between the two groups.
In September 2025, the Kraken group announced a new underground forum called “The Last Haven Board” in their data leak blog. According to its description, Last Haven’s primary objective is to create an anonymous and secure environment for communication within the cybercrime underground. Talos observed that the Last Haven forum administrator announced support and collaboration from the HelloKitty team and WeaCorp, an exploit buyer organization, suggesting the possible involvement of HelloKitty operators with the Kraken group.
Figure3. Last Haven underground forum announcement on Kraken data leak blog.
Infection chain
Figure 4. Kraken infection chain.
In August 2025, Cisco Talos Incident Response (Talos IR) observed in one instance that the Kraken ransomware actor gained initial access to the victim’s machine by exploiting an existing vulnerability in the SMB service on servers exposed to the internet. Once they established their foothold on the victim’s machine, they extracted valid administrators’ and other privileged accounts’ credentials. Subsequently, they re-entered the victim environment through a Remote Desktop connection using the exfiltrated privileged account credentials.
After re-entering the victim machine, the attacker established a persistent connection by installing the Cloudflared tool and configuring a reverse tunnel on the victim’s machine. Additionally, the attacker installed the SSHFS tool on the victim machine, utilizing it to navigate the victim’s environment and exfiltrate sensitive data. The attacker then deployed the Kraken ransomware binary and moved laterally to other machines connected to the infected machine through Remote Desktop Protocol (RDP) connections, using the stolen privileged user accounts to deploy the ransomware binaries. Through this persistent remote connection, the attacker executed commands to run the ransomware on multiple systems within the victim’s environment.
Kraken ransomware analysis
Kraken ransomware is a sophisticated ransomware family with variants that target Windows, Linux, and ESXi systems. This ransomware offers extensive command-line options, providing operational flexibility for the actors who utilize Kraken ransomware in their attacks. It has the capability for either full or partial encryption of targeted files, along with features that allow for the encryption of specific files, including SQL databases and network shares.
To encrypt targeted files, Kraken ransomware employs RSA encryption algorithms with a key length of 4096 bits and ChaCha20 symmetric encryption. Additionally, the ransomware features encryption benchmarking capabilities to assess how quickly it can operate on the victim’s machine without causing system overload, ensuring maximum damage in minimal time while evading detection through resource exhaustion.
Talos observed that the attacker executed the commands on Windows and ESXi environments to run the encryptor program. The Kraken encryptor is engineered with various command line arguments that the attacker could leverage depending on the victim’s environment.
Delays the execution of the encryptor for N seconds
-solid
Full file encryption without blocks
-step N
Numbers of blocks of a file to encrypt
-limitN
Limit encryption to first N megabytes
-d
Runs asdaemonandexecution through remote SSH connection
–noteonly
Drops ransom note only without performing the encryption
-tests
Run encryption performance tests
–tempfile
Temporarytest file path
–tempsize
Test file size in megabytes
-all
Encrypt all files
–nolsof
Disablelsofchecking
–nokillallvms
Skip VM termination
Kraken Windows encryptor
The Windows version of Kraken ransomware is a 32-bit executable written in C++ and possibly obfuscated using a Golang-based packer. The ransomware exhibits features such as anti-reinfection checks, anti-analysis, and anti-recovery, and it encrypts the targeted files, appending the .zpsc file extension to the encrypted files.
Initial execution phase
In the initial phase of execution, Kraken processes the command line parameters and performs the anti-reinfection checks on the victim machine to avoid double-encryption. The actor has employed anti-reinfection checks to effectively manage the decryption keys.
Kraken ransomware disables the WoW64 filesystem redirection on the victim machine by using the function Wow64EnableWow64FsRedirection with the argument “ (False)” to enable the 32-bit binary to access the 64-bit files on Windows machine.
WoW64 is a compatibility layer on a 64-bit Windows operating system that allows 32-bit applications to run seamlessly. The key feature of WoW64 is file system redirection, which ensures that when a 32-bit application attempts to access the “C:WindowsSystem32” folder, WoW64 redirects it to “C:WindowsSysWoW64”, allowing the 32-bit application to load the correct 32-bit version of system DLLs.
Figure5. Function snippet disabling the WoW64 redirection.
Kraken ransomware, after disabling the WoW64 redirection, modifies its process token privilege, enabling the debugging rights. This privilege is essential for ransomware to access and encrypt files belonging to other processes. Further, the ransomware encrypts the local drives, network shares, and SQL database files and disables the backup services on the 64-bit Windows operating system. All these operations of the 32-bit ransomware binary would require access to the folder “C:WindowsSystem32”. Disabling the redirection in Wow64 will enable the 32-bit ransomware binary to access the “C:WindowsSystem32” folder on the 64-bit Windows operating system.
Anti-analysis and anti-recovery techniques
Kraken ransomware utilizes anti-analysis techniques to evade detection, complicate analysis, and prevent execution in sandbox environments.
The ransomware employs extensive control flow obfuscation with multiple conditional loops throughout the code, concealing the actual control flow paths and increasing complexity for static analysis and pattern matching for signature generation.
It also manipulates system exception handlers to prevent Windows error dialogs from appearing by executing SetErrorMode function with the value 0x8003 which is a bitwise OR combination of three Windows error mode flags:
SEM_FAILCRITICALERRORS (0x0001) – no critical error handler message box
SEM_NOGPFAULTERRORBOX (0x0002) – no general protection fault error box
SEM_NOOPENFILEERRORBOX (0x8000) – no open file error box
Figure 6. Function snippet sets the error mode flags.
It employs a sleep-based execution delay to evade sandbox analysis, stops the backup services, and executes the embedded command to remove all restore points on the victim machine.
vssadmin delete shadows /all /quite
It also deletes the recycle bin using the Windows function SHEmptyRecycleBinA.
Encryption performance testing and benchmarking
Kraken ransomware has the ability to conduct performance testing on the victim’s machine before initiating the actual encryption. An actor can use this feature through command line options such as “-tests,” “-tempfile,” and “-tempsize” to assess the victim machine’s performance and optimize the ransomware encryption process.
Kraken does this by first creating a temporary test file, using the path and filename specified via the “-tempfile” parameter. It then populates this file with random data, writing in 1MB chunks until the total size defined by the “-tempsize” parameter is reached. To time the core operation, the module records the start time with the clock_gettime function, performs the actual encryption on the test file, and then records the end time. Finally, it calculates the elapsed time and computes the encryption speed for the victim machine, expressed in MB/s, using the formula:
Based on the throughput results, the function validates if the attacker should choose full encryption mode or partial encryption mode with the maximum file size chunks to encrypt. After the performance testing process, it removes the test file using the function unlink() .
Parallel encryption operation
The Kraken Windows encryptor has four encryption modules including SQL database, Network share, Local drive, and Hyper-V encryption. Based on the command-line flags provided by the attacker, the encryptor determines which encryption module to execute.
The SQL database encryption module encrypts Microsoft SQL server databases. To target database files, the module accesses the Microsoft SQL Server registry keys on the victim machine, specifically querying “HKLMSOFTWAREMicrosoftMicrosoft SQL Server” and its “Instance NamesSQL” subkey to search for the “MSSQLSERVER” and “SQLEXPRESS” instances. Upon locating an instance, it retrieves the “SQLDataRoot” registry value to determine the path to the database files. The module then validates that these paths exist using the PathFileExistsWWindows API before proceeding to encrypt the database files.
The network share encryption module enumerates and encrypts accessible network shares by using Windows WNet APIs to detect both mapped and unmapped network locations, specifying RESOURCETYPE_DISK and RESOURCETYPE_ANY. During enumeration, it iterates through the discovered network resources but explicitly skips the ADMIN$ and IPC$ shares. For each accessible network shares it finds, the module creates dedicated encryption worker threads to handle the encryption process.
Figure 8. Function snippetenumeratesdifferent network resource types.
The local drive encryption module encrypts all locally attached drives by first using the GetLogicalDrives function to enumerate all available drive letters from A to Z. For each letter, it checks the drive type with the GetDriveTypeW function, targeting drives identified as DRIVE_REMOVABLE, DRIVE_FIXED, or DRIVE_REMOTE while excluding CD-ROM and network-only drives. After constructing the drive path (e.g., “X:”), it creates a dedicated encryption worker thread for each validated drive path.
The Hyper-V virtual machine encryption module targets virtual machine files by executing a series of embedded PowerShell commands. First, it disables PowerShell restrictions on the victim machine to ensure its commands run. It then discovers the virtual machine files by listing all VMs and extracting their corresponding hard disk file paths. To unlock these files for encryption, the module forcefully stops all running virtual machines. After these prerequisite steps, it creates encryption worker threads to encrypt the located virtual machine files. The PowerShell commands executed by the module:
The ransomware excludes the executables (.exe) and dynamic-link library (.dll) files along with the folders “Program Files”, “Program Files (X86)”, and “ProgramData” from the encryption processes on the victim machine, allowing the victims to still access the system to communicate with the threat actor.
Kraken Linux/ESXi encryptor
The Linux or ESXi version of the Kraken ransomware is 64-bit executable written in C++ and compiled using the tool crosstool-NG version 1.26.0.
In the initial phase of the execution, the Linux executable file version of Kraken ransomware processes the command-line parameters specified by the attacker.
Platform discovery
The ransomware runs the platform detection module to discover the type of victim machine by executing the commands mentioned below and adapting the behavior based on the detected platform.
System type
Command
ESXi
esxclisystem version get
Nutanix
uname–a with “nutanix”
Ubuntu Linux
uname–a with “ubuntu”
Synology NAS devices
cat/etc.defaults/VERSION with“dsm”
While targeting the ESXi environments, the ransomware lists any running virtual machines and forcefully attempts to kill them by executing the following commands embedded in the ransomware binary:
esxcli vm process list
esxcli vm process kill --type=force --world-id=
Encryption types
The ELF version of Kraken ransomware performs the multi-threaded encryption, supporting both “solid – Full encryption” and “setp – partial encryption”. It also employs the encryption performance benchmarking module that an attacker can leverage during the attack to calculate the encryption speed and decide if they want to perform full or partial encryption. The performance benchmarking algorithm is like the Windows version of Kraken ransomware described in the previous section.
It performs the recursive directory traversal and encrypts the file based on the type of encryption mode specified in the command line parameter by the attacker and appends the .zpsc file extension to the encrypted files.
Anti-analysis and detection evasion
The ELF version of Kraken ransomware employs control flow obfuscation with the complex loop structure to hinder the analysis and operates in daemon mode by forking into background process through fork_as_daemon() function and continues to run, performing the encryption in background. It also ignores the signal handlers SIGCHLD (child process termination) and SIGHUP (Terminal hangup).
The ransomware employs a multi-stage self-deletion and cleanup process to erase traces of its execution, leaving a minimal forensic artefact, after completing the encryption operation. Kraken creates a bash script “_bye_bye_.sh” in the same directory as the ransomware binary. It then builds the script with the commands to delete the log files, shell history, ransomware binary, and the script itself.
It executes the script using popen function popen(“sh ”<deletion_script_path>””,"r") which runs in a separate shell process, and the parent process can exit before the script finishes its execution which helps to delete itself before the completion of the execution.
Coverage
Ways our customers can detect and block this threat are listed below.
Cisco Secure Endpoint (formerly AMP for Endpoints) is ideally suited to prevent the execution of the malware detailed in this post. Try Secure Endpoint for free here.
Cisco Secure Email (formerly Cisco Email Security) can block malicious emails sent by threat actors as part of their campaign. You can try Secure Email for free here.
Cisco Secure Network/Cloud Analytics (Stealthwatch/Stealthwatch Cloud) analyzes network traffic automatically and alerts users of potentially unwanted activity on every connected device.
Cisco Secure Malware Analytics (Threat Grid) identifies malicious binaries and builds protection into all Cisco Secure products.
Cisco Secure Access is a modern cloud-delivered Security Service Edge (SSE) built on Zero Trust principles. Secure Access provides seamless transparent and secure access to the internet, cloud services or private application no matter where your users work. Please
contact your Cisco account representative or authorized partner if you are interested in a free trial of Cisco Secure Access.
Umbrella, Cisco’s secure internet gateway (SIG), blocks users from connecting to malicious domains, IPs and URLs, whether users are on or off the corporate network.
Cisco Secure Web Appliance (formerly Web Security Appliance) automatically blocks potentially dangerous sites and tests suspicious sites before users access them.
Additional protections with context to your specific environment and threat data are available from the Firewall Management Center.
Cisco Duo provides multi-factor authentication for users to ensure only those authorized are accessing your network.
Open-source Snort Subscriber Rule Set customers can stay up to date by downloading the latest rule pack available for purchase on Snort.org.
Snort SIDs for the threats are: 65480 and 65479.
ClamAV detections are also available for this threat:
Win.Ransomware.Kraken-10056931-0
Unix.Ransomware.Kraken-10057031-0
Indicators of compromise (IOCs)
The IOCs can also be found in our GitHub repository here.
https://www.backbox.org/wp-content/uploads/2018/09/website_backbox_text_black.png00adminhttps://www.backbox.org/wp-content/uploads/2018/09/website_backbox_text_black.pngadmin2025-11-13 11:07:032025-11-13 11:07:03Unleashing the Kraken ransomware group
How many real threats hide behind the noise your SOC faces every day?
When hundreds of alerts demand attention at once, even the best analysts start to lose focus. The nonstop pressure to react to everything drains energy, clouds judgment, and opens the door to real risk.
Teams using ANY.RUN have alreadyflipped that script:
90% of attacks become visible within 60 seconds, giving analysts instant context instead of endless guesswork.
94% of users report faster triage, cutting time spent on false positives and low-value alerts.
95% of SOC teams speed up investigations, easing the overload that leads to burnout.
Ready to see how to get there? This action plan lays out the steps CISOs can take to turn alert fatigue into lasting focus.
Step 1: Replace Guesswork with Real-Time Visibility
Alert fatigue often begins with uncertainty. Analysts spend hours dissecting fragmented data, trying to connect the dots between partial logs and incomplete alerts. When they can’t see the full story, every alert feels critical, and fatigue takes over.
Real-time behavioral visibility changes everything. With ANY.RUN’s interactive sandbox, your team watches the attack unfold in a safe environment. From the first process execution to registry changes and data exfiltration attempts, every move is mapped in real time.
That level of context replaces guesswork with confidence.
Real-time analysis of Clickup abuse fully exposed in 60 seconds
In the following example, analysts used the sandbox to expose a phishing attack that abused ClickUp to deliver a fake Microsoft 365 login page, uncovering the full chain in seconds.
With ANY.RUN’s real-time visibility, team achieve:
3× higher efficiency in daily operations
15 sec median MTTD
Fewer false positives and missed threats
Faster response and a calmer, more focused SOC
Bring real-time visibility to your SOC
with ANY.RUN’s Interactive Sandbox
Even the strongest SOCs lose precious hours to repetitive work, copying IOCs, exporting reports, updating tickets. None of these tasks strengthen defense; they just drain energy and attention. Over time, that’s how alert fatigue turns into burnout.
But not every task can or should be automated. Many modern threats still require human-like interaction to be revealed: clicking a phishing link, solving a CAPTCHA, or scanning a QR code that hides a malicious redirect. Traditional tools stop short there.
QR code–based phishing fully exposed inside ANY.RUN sandbox; the hidden malicious link and full attack chain revealed in under 60 seconds.
With ANY.RUN’s sandbox, analysts get the best of both worlds; automation that behaves like a human when automated interactivity is enabled. It clicks through phishing pages, solves CAPTCHAs, follows redirects, and even scans QR codes that hide malicious links. All of this happens automatically, revealing threats most tools would miss. And when deeper insight is needed, analysts can jump in at any point to interact directly.
Outcome of automation and interactivity:
Hidden threats revealed that traditional tools can’t detect
Faster investigations with less manual work
Lower analyst fatigue through balanced automation
Human control preserved for high-priority incidents
This combination helps analysts uncover complex threats in less time and enables Tier 1 teams to resolve more cases independently.
According to recent data among ANY.RUN’s users:
20% lower workload for Tier 1 analysts
30% fewer escalations from Tier 1 to Tier 2
Step 3: Integrate Live Threat Intelligence to Cut Through the Noise
Even the best SOCs struggle to stay focused when analysts waste hours chasing outdated data; verifying expired domains, checking inactive IOCs, or switching between disconnected tools just to confirm what’s real.
Alert fatigue is a major obstacle for SOCs around the world
You can easily solve this with the help of live, connected intelligence.
ANY.RUN’s Threat Intelligence Feeds pull verified indicators from 15,000 organizations and 500,000 analysts worldwide, all sourced from real-time sandbox investigations. This means your team acts on current data, active phishing kits, live redirect chains, and real attacker infrastructure, not last month’s reports.
ANY.RUN’s TI Feeds deliver 99% unique IOCs in real time
When this intelligence is integrated into your SOC tools, analysts no longer need to jump between platforms or second-guess stale alerts. Every IOC is backed by behavioral evidence and traceable to a live analysis.
With this setup, your team can:
Validate alerts instantly using verified, real-time data
Eliminate repetitive checks for outdated or inactive indicators
Trace every IOC back to its full attack chain
Make faster, evidence-based decisions without leaving their workflow
As a result, businesses achieve stronger detection, less context-switching, and sharper focus across all SOC operations.
Detect emerging threats early
with real-time intelligence from TI Feeds
Even the most advanced SOCs lose efficiency when investigations and follow-ups aren’t coordinated. Without clear ownership and visibility into who’s handling what, tasks overlap, progress stalls, and important findings slip through the cracks.
With ANY.RUN’s teamwork features, CISOs and SOC leads can manage investigations within a single workspace: assigning tasks, tracking analyst progress, and keeping every case organized.
Team management in ANY.RUN
Each analysis also generates a structured, shareable report, so findings are easy to review, reuse, or hand off across shifts.
This unified workflow keeps everyone aligned, from initial detection to final response, while ensuring accountability and consistency across the SOC.
With a unified response workflow, you can ensure:
Clear task ownership and visibility into investigation progress
Structured, shareable reports for faster knowledge transfer
Stronger coordination between analysts and response leads
Higher overall efficiency with no duplicated effort
Time to Give Your Team a Break from the Noise
Alert fatigue is a sign of systems that demand too much and explain too little. By giving your analysts real-time visibility, automation that understands context, and intelligence they can trust, you give them what they need most: focus.
When the noise quiets down, your team moves with intent; faster investigations, sharper decisions, and actions backed by real context instead of guesswork.
Built for modern SOC operations, ANY.RUN helps teams detect, analyze, and respond to threats in real time. Its Interactive Sandbox reveals full attack behavior, from process execution to network activity, giving analysts the clarity they need to act with confidence.
Compatible with Windows, Linux, and Android, the cloud-based sandbox provides deep behavioral visibility with no setup required. Integrated Threat Intelligence Lookup and TI Feeds deliver continuously updated, automation-ready IOCs that strengthen every layer of detection.
https://www.backbox.org/wp-content/uploads/2018/09/website_backbox_text_black.png00adminhttps://www.backbox.org/wp-content/uploads/2018/09/website_backbox_text_black.pngadmin2025-11-13 10:07:162025-11-13 10:07:16Solve Alert Fatigue, Focus on High-Risk Incidents: An Action Plan for CISOs
These days, attackers probing an organization’s infrastructure rarely come across the luxury of a workstation without an EDR agent, so malicious actors are focusing on compromising servers, or various specialized devices connected to the network with fairly broad access privileges yet lacking EDR protection and often even logging capabilities. We’ve previously written in detail about the types of vulnerable office devices. Real-world attacks in 2025 are focused on network devices (such as VPN gateways, firewalls, and routers), video surveillance systems, and the servers themselves. But printers shouldn’t be overlooked either, as independent researcher Peter Geissler reminded the audience at the Security Analyst Summit 2025. He described a vulnerability he’d found in Canon printers (CVE-2024-12649, CVSS 9.8), which allows executing malicious code on these devices. And the most interesting aspect regarding this vulnerability is that exploiting it merely requires sending an innocent-looking file to print.
Trojan Type Font: an attack via CVE-2024-12649
The attack begins with sending an XPS file to print. This format, created by Microsoft, contains all the prerequisites for successful document printing, and serves as an alternative to PDF. XPS is essentially a ZIP archive containing a detailed description of the document, all its images, and the fonts used. The fonts are usually stored in the popular TTF (TrueType Font) format invented by Apple. And it’s precisely the font itself — something not typically perceived as dangerous — that contains the malicious code.
The TTF format was designed to both make letters look identical on any medium, and scale correctly to any size — from the smallest character on a screen to the largest on a printed poster. To achieve this goal, each letter can have font hinting instructions written for it, which describe the nuances of displaying letters of small sizes. Hinting instructions are essentially commands for a compact virtual machine which, despite its simplicity, supports all the basic building blocks of programming: memory management, jumps, and branching. Geissler and his colleagues studied how this virtual machine is implemented in Canon printers. They discovered that some TTF hinting instructions are executed insecurely. For example, the virtual machine commands that manage the stack don’t check for overflow.
As a result, they succeeded in creating a malicious font. When a document containing it is printed on certain Canon printers, it causes a stack buffer overflow, writes data beyond the virtual machine’s buffers, and ultimately achieves code execution on the printer’s processor. The entire attack is conducted via the TTF file; the rest of the XPS file content is benign. In fact, detecting the malicious code even within the TTF file is quite difficult: it’s not very long, the first part consists of TTF virtual machine instructions, and the second part runs on the exotic, proprietary Canon operating system (DryOS).
It should be noted that in recent years Canon has focused on securing printer firmware. For example, it uses DACR registers and NX (no-execute) flags supported in ARM processors to limit the ability to modify system code or execute code in memory fragments intended solely for data storage. Despite these efforts, the overall DryOS architecture doesn’t allow for effective implementation of memory protection mechanisms, such as ASLR or stack canary, which are typical of larger modern operating systems. This is why researchers occasionally find ways to bypass the existing protection. For instance, in the attack we’re talking about, the malicious code was successfully executed by placing it, via the TTF trick, into a memory buffer intended for a different printing protocol — IPP.
Realistic exploitation scenario
In their bulletin describing the vulnerability, Canon asserts that the vulnerability can be exploited remotely if the printer is accessible via the internet. Consequently, they suggest configuring a firewall so the printer can only be used from the internal office network. While this is good advice and the printer should indeed be removed from public access, this isn’t the only attack scenario.
In his report, Peter Geissler pointed to a much more realistic, hybrid scenario in which the attacker sends an employee an attachment in an email or a messenger message and, under one pretext or another, suggests they print it. If the victim does send the document to print — within the internal organization network and without any internet exposure — the malicious code is executed on the printer. Naturally, the capabilities of the malware when running on the printer will be limited compared to malware that’s infected a full-fledged computer. However, it could, for example, create a tunnel by establishing a connection to the attacker’s server — allowing the attackers to target other computers in the organization. Another potential use case for this malware on the printer could result in the forwarding of all information being printed at the company directly to the attacker’s server. In certain organizations, such as law firms, this could lead to a critical data breach.
How to fend off this printer threat
The vulnerability CVE-2024-12649 and several closely related defects can be eliminated by installing the printer firmware update according to Canon’s instructions. Unfortunately, many organizations — even those that diligently update software on computers and servers — lack a systematic process for updating printer firmware. The process must be implemented for all equipment connected to the computer network.
However, security researchers emphasize that there’s a multitude of attack vectors targeting specialized equipment. Therefore, there’s no guarantee that attackers won’t arm themselves tomorrow with a similar exploit unknown to printer manufacturers or their customers. To minimize the risk of exploitation:
Segment the network — limiting the printer’s ability to establish outbound connections and to accept connections from devices and users not authorized to print.
Disable all unused services on the printer.
Set a unique, complex administrator password on each printer/device.
https://www.backbox.org/wp-content/uploads/2018/09/website_backbox_text_black.png00adminhttps://www.backbox.org/wp-content/uploads/2018/09/website_backbox_text_black.pngadmin2025-11-12 17:06:572025-11-12 17:06:57CVE-2024-12649: vulnerability in the Canon TTF interpreter
Eric Parker, a recognized cybersecurity expert, has recently released a video on ClickFix attacks, their detection, analysis, and gathering threat intelligence. Here is our recap highlighting the key points and practical advice.
ClickFix as the Signature Threat of 2025
In 2025 the internet saw a sharp surge in a deceptively simple but highly effective social-engineering technique known as ClickFix: fake CAPTCHA pages tricking victims into running commands or pasting paths that install malware on their devices. What began as isolated malvertising and phishing pages has evolved into cross-platform, professionally produced scam traps and the second most prevalent attack vector globally, trailing only traditional phishing.
ClickFix bypasses automated defenses by turning victims into unwitting accomplices, exploiting human psychology over technical tricks and vulnerabilities.
The Technique Essence in a Nutshell
ClickFix attack chain on the example of Rhadamanthys
An attacker presents a convincing CAPTCHA / verification / “fix this” UI that instructs the user to copy & paste a short snippet into a system dialog or terminal (for example: Run dialog, File Explorer address bar, or Terminal). JavaScript on the page often silently places an obfuscated command on the clipboard and/or shows an instruction video.
When the user pastes and hits Enter they execute that command which downloads and runs malware. The chain relies entirely on social engineering and trusted OS interfaces rather than exploit primitives.
ClickFix isn’t limited to Windows. In 2025 campaigns increasingly tailored payloads and instructions for macOS and Linux. Often they abused legitimate distribution/installation flows (for example, spoofing Homebrew install pages or using shell commands) making the technique even more stealthy on non-Windows platforms.
ClickFix is especially dangerous for organizations because:
It bypasses technical defenses — the user executes the malware themselves, making the activity look legitimate to EDR and antivirus.
It is cross-platform — targeting Windows, macOS, and Linux, and sometimes abusing legitimate package managers such as Homebrew on macOS.
It scales cheaply and quickly — attackers automate landing pages, videos, OS detection, and payload delivery.
It delivers high-impact threats — info-stealers, remote access trojans, and ransomware are already distributed via ClickFix and its variants (e.g., FileFix).
For businesses, this means that endpoint protection alone is not enough. Security teams must pair behavioral detection and browser controls with threat intelligence that tracks malicious domains, payloads, and evolving social-engineering patterns. The attack surface isn’t a vulnerability in code — it’s a vulnerability in human workflows.
We can discover ClickFix analyses simply by a threat’s name – although TI Lookup allows to combine over 40 search parameters for more complicated and precise queries. We can use the name of a file, the name of a process, and even a registry key; it is possible to find malware that does a specific thing like connecting to a certain domain or making some requests.
Sandbox detonation of fake update ClickFix variant
This is an example of a “fix-this” swindle persuading a user to run a command to complete a fake Windows update. What happens if they follow the instructions?
mshta.exe process is initiated (utilizing a somewhat unusual IP with a “0x” in it).
Malicious process featuring a suspicious IP address
It triggers a PowerShell command that drops an .exe file.
Malware delivered via PowerShell
It reads a specific registry key to check if the user is running a certain type of virtual machine and reads the BIOS version which belongs to yet another anti-analysis trick. Pay attention to the process OOBE-Maintenance.exe: looks like it has been injected since it’s a legitimate file, but it’s loading DLLs and demonstrates very suspicious activities.
Malware gathering the system information
So, we can classify this sample as malicious revealing info-stealer activity along with anti-analysis.
And here we see a malicious extension having been dropped. Google Chrome puts a lot of effort into making it hard for infostealers, but unfortunately infostealers worked around that.
The Sandbox allows to view and search files that are part of the attack
Detect threats faster with ANY.RUN’s Sandbox
See full attack chain in seconds
A typical ClickFix “CAPTCHA” making user run a malicious command
By running this command, we do mshta for a certain domain that drops payload. And then the system works like nothing has happened, and the CAPTCHA just worked, and everything is fine. But actually, this computer is completely pwned. A massive payload is delivered.
Here we see a “verification” website abusing CloudFlare services. Note that the first CAPTCHA is a genuine CloudFlare CAPTCHA:
An actual CloudFlare CAPTCHA: user just needs to check a box
And then there comes the tricky one:
Malicious CAPTCHA closely following the benign one
This sample is not as clever as the previous one: it’s not stealthy, a PowerShell window opens up and hints that something might be amiss here.
PowerShell spawns this GUI urging the user to click “Continue” which sends them to the actual Booking com so they might think everything is okay.
Fake verification form redirects the user to the real website but delivers malware along
Nothing could be further from the truth. The file travelsecurity.exe is dropped, creates persistence, and it all looks like a phishing attack.
The endpoint is now infested
Example 4: FileFix and Explorer Commands
This is a relatively new version: a Docusign scam. View analysis.
If you don’t look closely, it seems to be a perfectly legit document that just requires user signature. Eric says he’s been receiving a lot of those via email, usually disguised as sponsorship offers.
But there is the first possible-phishing red flag: the domain eu2-docusign[.]net is not a subdomain of Docusign, it masks like one using a hyphen.
FileFix variant of ClickFix: a fake document
We can call this attack variant FileFix as there is no CAPTCHA, just a path to copy into Windows Explorer and open a file to be signed.
(There is also a DocFix variant that masquerade as document viewer errors, particularly targeting Microsoft Office and PDF workflows. MeetFix exploits fake Google Meet errors.)
So the path is copied into the Explorer address bar… And Eric is surprised that you can run commands in Explorer. The command is separated from the path by a string of spaces and is not visible for the user unless they scroll the address bar.
What the user sees:
Instantly visible part of the command
What they can see after dragging their cursor to the right:
Unobvious part of the command containing PowerShell call
The string runs the PowerShell command:
The malicious process interferes with the system settings
And a couple of processes later we can welcome an info stealer in the system:
The malware steals credentials and other personal data
How to Keep Up with New ClickFix Attacks
So, this is how ClickFix technique works, and this is how it can be researched via Threat Intelligence Lookup and Interactive Sandbox. Over 15,000 SOC teams all over the world analyze fresh malware samples daily, generating loads of contextual data on prevalent and emerging threats.
Use TI Lookup to check IOCs for associations with ClickFix attacks and protect proactively:
Domain labelled by TI Lookup as an indicator of ClickFix attacks
Update blocklists, employ targeted preventative controls (e.g., clipboard-protection extensions, blocking certain address-bar patterns in enterprise policies), use TI to create detection rules (SIEM, EDR) that look for suspicious curl | sh, Run dialogue invocations, PowerShell one-liners, or unusual child processes after a browser session.
Conclusion
ClickFix is a human-centric, high-ROI social-engineering technique that matured into a major vector in 2025. It’s cross-platform, fast-evolving (FileFix and other address-bar / clipboard tricks), and amplified by automated tooling and AI.
As AI continues to enhance attack sophistication and lower barriers to entry, organizations must evolve their defenses beyond technical controls to include robust threat intelligence, user education, and behavioral detection. The ClickFix threat will persist and evolve—only through comprehensive, intelligence-driven security programs can organizations hope to stay ahead of this signature threat of 2025.
FAQ
Q1: What is ClickFix?
A: ClickFix is a social engineering technique that tricks users into running malicious commands (e.g., PowerShell scripts) via fake CAPTCHAs or error fixes, leading to self-infection without downloads.
Q2: How has ClickFix evolved in 2025?
A: It surged 517% in H1 2025, becoming the #2 vector after phishing, with cross-platform support and AI-enhanced lures boosting evasion and compliance.
Q3: Is ClickFix only for Windows?
A: No, it’s cross-platform, abusing Homebrew on macOS for root access and terminal commands on Linux, making it deadlier on non-Windows systems.
Q4: What are ClickFix variants like DocFix?
A: Variants include DocFix (HTML “docs” in emails), FileFix (File Explorer pastes), and MeetFix (fake Google Meet errors), all refining the manipulation.
Q5: Why did ClickFix explode in 2025?
A: Underground builders, nation-state adoption (e.g., APT28), and shifts to malvertising/compromised sites made it scalable and stealthy.
Q6: How does AI fuel ClickFix threats?
A: AI crafts personalized lures, injects prompts into summarizers, and generates obfuscated code, automating infections via browser agents.
A: They’re fileless, cross-platform, versatile (RATs to ransomware), and exploit psychology, bypassing AV for rapid data theft/escalation.
Q9: How does threat intelligence combat ClickFix?
A: TI maps IOCs, enables behavioral detection (e.g., EDR alerts), shares via alliances, and informs training/policies like Run dialog blocks.
Q10: How can I prevent ClickFix on my device?
A: Use EDR/AV, disable Win + R via GPO, train on suspicious prompts, block known C2 domains, and verify sources—never paste untrusted code.
About ANY.RUN
Trusted by over 500,000 cybersecurity professionals and 15,000+ organizations in finance, healthcare, manufacturing, and other critical industries, ANY.RUN helps security teams investigate threats faster and with greater accuracy.
Our Interactive Sandbox accelerates incident response by allowing you to analyze suspicious files in real time, watch behavior as it unfolds, and make confident, well-informed decisions.
https://www.backbox.org/wp-content/uploads/2018/09/website_backbox_text_black.png00adminhttps://www.backbox.org/wp-content/uploads/2018/09/website_backbox_text_black.pngadmin2025-11-12 07:06:472025-11-12 07:06:47Why shadow AI could be your biggest security blind spot
Microsoft has released its monthly security update for November 2025, which includes 63 vulnerabilities affecting a range of products, including 5 that Microsoft marked as “critical.” Current intelligence shows that one of the important vulnerabilities, CVE-2025-62215, has already been detected in the wild.
Out of five “Critical” entries, three are remote code execution (RCE) vulnerabilities in Microsoft Windows components including GDI+, Microsoft Office, and Visual Studio. One is an elevation of privilege vulnerability affecting the DirectX Graphics Kernel.
In the following sections we give a concise overview of the critical and important entries that are most relevant for defenders. The full catalogue of all reported issues can be found on Microsoft’s official update page.
Exploited in the Wild
One “important” vulnerability was confirmed to have been exploited in the wild.
CVE-2025-62215 is a Windows Kernel elevation of privilege vulnerability, given a CVSS 3.1 score of 7.8, where a race condition in Windows Kernel allows an authorized attacker to elevate privileges locally. Microsoft assessed that the attack complexity is “low”.
Critical Vulnerabilities
Among all the critical vulnerabilities, none of them were labelled as exploitation more likely. Five are considered exploitation less likely. Below we describe each of those five entries.
CVE-2025-60724 is a RCE vulnerability in GDI+, given a CVSS 3.1 score of 9.8, where a heap-based buffer overflow in Microsoft Graphics Component allows an unauthorized attacker to execute code over a network. The vulnerability can be triggered by convincing a victim to download and open a document that contains a specially crafted metafile. In the worst-case scenario, an attacker could trigger this vulnerability on web services by uploading documents containing a specially crafted metafile without user interaction. An attacker doesn’t require any privileges on the systems hosting the web services. Successful exploitation of this vulnerability could cause RCE or Information Disclosure on web services that are parsing documents that contain a specially crafted metafile, without the involvement of a victim user. Microsoft assessed that the attack complexity is “low”, and that exploitation is “less likely”.
CVE‑2025‑30398 is a Nuance PowerScribe 360 information disclosure vulnerability, given a CVSS 3.1 score of 8.1, where missing authorization in Nuance PowerScribe allows an unauthorized attacker to disclose information over a network. An unauthenticated attacker could exploit this vulnerability by making an API call to a specific endpoint. The attacker could then use the data to gain access to sensitive information (including PII data) on the server. Microsoft assessed that the attack complexity is “low”, and that exploitation is “less likely”.
CVE‑2025‑62199 is a RCE vulnerability in Microsoft Office applications, given a CVSS 3.1 score of 7.8, where a use‑after‑free flaw in Microsoft Office allows an unauthenticated attacker to execute code locally on a vulnerable workstation. To exploit this vulnerability, an attacker must send the user a malicious file and convince them to open it. Microsoft assessed that the attack complexity is “low”, and that exploitation is “less likely”.
CVE‑2025‑60716 is a DirectX Graphics kernel elevation of privilege vulnerability, given a CVSS 3.1 score of 7, where a use‑after‑free flaw in Windows DirectX allows an authorized attacker to elevate privileges locally. Successful exploitation of this vulnerability requires an attacker to win a race condition. Microsoft assessed that the attack complexity is “high”, and that exploitation is “less likely”.
CVE‑2025‑62214 is a RCE vulnerability in Visual Studio, given a CVSS 3.1 score of 6.7, where AI command injection in Visual Studio allows an authorized attacker to execute code locally. Exploitation is not trivial for this vulnerability as it requires multiple steps: prompt injection, Copilot Agent interaction, and triggering a build. Microsoft assessed that the attack complexity is “high”, and that exploitation is “less likely”.
Important Vulnerabilities
Talos would also like to highlight the following “important” vulnerabilities as Microsoft has determined that their exploitation is “more likely”:
CVE‑2025‑59512 – Customer Experience Improvement Program (CEIP) Elevation of Privilege Vulnerability.
CVE‑2025‑60705 – Windows CSC Service Elevation of Privilege Vulnerability
CVE-2025-60719 – Windows Ancillary Function Driver for WinSock Elevation of Privilege Vulnerability
CVE-2025-62217 – Windows Ancillary Function Driver for WinSock Elevation of Privilege Vulnerability
CVE-2025-62213 – Windows Ancillary Function Driver for WinSock Elevation of Privilege Vulnerability
A complete list of all the other vulnerabilities Microsoft disclosed this month is available on its update page.
In response to these vulnerability disclosures, Talos is releasing a new Snort ruleset that detects attempts to exploit some of them. Please note that additional rules may be released at a future date, and current rules are subject to change pending additional information. Cisco Security Firewall customers should use the latest update to their ruleset by updating their SRU. Open-source Snort Subscriber Ruleset customers can stay up to date by downloading the latest rule pack available for purchase on Snort.org.
The rules included in this release that protect against the exploitation of many of these vulnerabilities are 65496-65501, 65507-65510. There are also these Snort 3 rules: 301343-301345, 301347, 301348.
https://www.backbox.org/wp-content/uploads/2018/09/website_backbox_text_black.png00adminhttps://www.backbox.org/wp-content/uploads/2018/09/website_backbox_text_black.pngadmin2025-11-11 19:06:492025-11-11 19:06:49Microsoft Patch Tuesday for November 2025 — Snort rules and prominent vulnerabilities
Android constantly tightens app restrictions to prevent scammers from using malicious software to steal money, passwords, and users’ private secrets. However, a new vulnerability dubbed Pixnapping bypasses every protective layer and allows an attacker to imperceptibly read image pixels from the screen — essentially taking a screenshot. A malicious app with zero permissions can see passwords, bank account balances, one-time codes, and anything else the owner views on the screen. Fortunately, Pixnapping is currently a purely research-based project and is not yet being actively exploited by threat actors. The hope is that Google will thoroughly patch the vulnerability before the attack code is integrated into real-world malware. As of now, the Pixnapping vulnerability (CVE-2025-48561) likely affects all modern Android smartphones, including those running the latest Android versions.
Why screenshots, media projection and screen reading are dangerous
As demonstrated by the SparkCat OCR stealer we discovered, threat actors have already mastered image processing. If an image on a smartphone contains a valuable piece of information, the malware can detect it, perform optical character recognition directly on the phone, and then exfiltrate the extracted data to the attacker’s server. SparkCat is particularly noteworthy because it managed to infiltrate official app marketplaces including the App Store. It would not be difficult for a malicious Pixnapping-enabled app to replicate this trick, especially given that the attack requires zero special permissions. An app that appears to offer a legitimate, useful feature could simultaneously and silently send one-time multi-factor authentication codes, cryptowallet passwords, and any other information to scammers.
Another popular tactic used by malicious actors is to view the required data as it’s shown, in real-time. For this social engineering approach, the victim is contacted via a messaging app and, under various pretexts, convinced to enable screen sharing.
Anatomy of the Pixnapping attack
The researchers were able to screenshot content from other apps by combining previously known methods of stealing pixels from browsers and from ARM phone graphics processing units (GPUs). The attacking app silently overlays translucent windows atop the target information and then measures how the video system combines the pixels of these layered windows into a final image.
As far back as 2013, researchers described an attack that allowed one website to load another within part of its own window (via an iframe) and, by performing legitimate operations of image layering and transformation, infer exactly what was drawn or written on the other site. While modern browsers have mitigated that specific attack, a group of U.S. researchers have now figured out how to apply the same core principle to Android.
The malicious app first sends a system call to the target app. In Android, this is known as an intent. Intents typically enable not only simple app launching but also things like immediately opening a browser to a specific URL or a messaging app to a specific contact’s chat. The attacking app sends an intent designed to force the target app to draw the sensitive information onto the screen. Special hidden launch flags are used. The attacking app then sends a launch intent to itself. This specific combination of actions allows the victim app to not appear on the screen at all, yet it still renders the information sought by the attacker in its window, in the background.
In the second stage of the attack, the malicious app overlays the hidden window of the victim app with a series of translucent windows, each of which covers and blurs the content beneath it. This complex arrangement remains invisible to the user, but Android dutifully calculates how this combination of windows should look if the user were to bring it to the foreground.
The attacking app can only directly read the pixels from its own translucent windows; the final combined image, which incorporates the victim app’s screen content, is not directly accessible to the attacker. To bypass this restriction, the researchers employ two ingenious tricks. The specific pixel to be stolen is isolated from its surroundings by overlaying the victim app with a mostly opaque window that has a single transparent point precisely over the target pixel. A magnifying layer is then placed on top of this combination, consisting of a window with heavy blurring enabled.
How the Pixnapping vulnerability works
To decipher the resulting mush and determine the value of the pixel at the very bottom, the researchers leveraged another known vulnerability, GPU.zip (this may look like a file link, but it actually leads to a research paper site). This vulnerability is based on the fact that all modern smartphones compress the data of any images being sent from the CPU to the GPU. This compression is lossless (like a ZIP file), but the speed of packing and unpacking changes depending on the information being transmitted. GPU.zip permits an attacker to measure the time it takes to compress the information. By timing these operations, the attacker can infer what data is being transferred. With the help of GPU.zip, the isolated, blurred, and magnified single pixel from the victim app’s window can be successfully read by the attacking app.
Stealing something meaningful requires repeating the entire pixel-stealing process hundreds of times, as it needs to be applied to each point separately. However, this is entirely feasible within a short time frame. In a video demonstration of the attack, a six-digit code from Google Authenticator was successfully extracted in just 22 seconds, while it was still valid.
How Android protects screen confidentiality
Google engineers have nearly two decades of experience combating various privacy attacks, which has resulted in a layered defense built against illegal capture of screenshots and videos. A complete list of these measures would span several pages, so we only list some key protections:
The FLAG_SECURE window flag prevents the operating system from taking screenshots of content.
Access to media projection tools (capturing screen content as a media stream) requires explicit user confirmation and can only be performed by an app that is visible and active.
One-time passwords and other secret data are hidden automatically if media projection is detected.
Android restricts apps from accessing other apps’ data. Additionally, apps cannot request a full list of all installed apps on the smartphone.
Unfortunately, Pixnapping bypasses all these existing restrictions and requires absolutely no special permissions. The attacking app only needs two fundamental capabilities: to draw within its own windows and to send system calls (intents) to other apps. These are basic building blocks of Android functionality, so they are very difficult to restrict.
Which devices are affected by Pixnapping, and how to defend oneself
The attack’s viability was confirmed on Android versions 13–16 across Google Pixel devices from generations 6–9, as well as Samsung Galaxy S25. The researchers believe the attack will be functional on other Android devices as well, as all the mechanisms used are standard. However, there may be nuances related to the implementation of the second phase of the attack (the pixel magnification technique).
Google released a patch in September after being notified of the attack in February. Unfortunately, the chosen method for fixing the vulnerability proved to be insufficiently reliable, and the researchers quickly devised a way to bypass the patch. A new attempt to eliminate the vulnerability is planned for Google’s December update release. As for GPU.zip, there are no plans to issue a patch for this specific data leakage channel. At least, no smartphone GPU manufacturer has announced plans to that effect since the flaw became public knowledge in 2024.
User capabilities to defend against Pixnapping are limited. We recommend the following measures:
Promptly update to the latest version of Android with all current security patches.
Avoid installing apps from unofficial sources, and exercise caution with apps from official stores if they are too new, have low download counts, or are poorly rated.
Ensure a full-fledged security system is used on your phone, such as Kaspersky for Android.
What other non-standard Android attack methods exist:
https://www.backbox.org/wp-content/uploads/2018/09/website_backbox_text_black.png00adminhttps://www.backbox.org/wp-content/uploads/2018/09/website_backbox_text_black.pngadmin2025-11-11 18:06:522025-11-11 18:06:52What is the Pixnapping vulnerability, and how to protect your Android smartphone? | Kaspersky official blog
We recently covered the ClickFix technique. Now, malicious actors have begun deploying a new twist on it, which was dubbed “FileFix” by researchers. The core principle remains the same: using social engineering tactics to trick the victim into unwittingly executing malicious code on their own device. The difference between ClickFix and FileFix is essentially where the command is executed.
With ClickFix, attackers convince the victim to open the Windows Run dialog box and paste a malicious command into it. With FileFix, however, they manipulate the victim into pasting a command into the Windows File Explorer address bar. From a user perspective, this action doesn’t appear unusual — the File Explorer window is a familiar element, making its use less likely to be perceived as dangerous. Consequently, users unfamiliar with this particular ploy are significantly more prone to falling for the FileFix trick.
How attackers manipulate the victim into executing their code
Similar to ClickFix, a FileFix attack begins when a user is directed — most often via a phishing email — to a page that mimics the website of some legitimate online service. The fake site displays an error message preventing access to the service’s normal functionality. To resolve the issue, the user is told they need to perform a series of steps for an “environment check” or “diagnostic” process.
To do this, the user is told they need to run a specific file that, according to the attackers, is either already on the victim’s computer or has just been downloaded. All the user needs to do is copy the path to the local file and paste it into the Windows File Explorer address bar. Indeed, the field from which the user is instructed to copy the string shows the path to the file — which is why the attack is named “FileFix”. The user is then instructed to open File Explorer, press [CTRL] + [L] to focus on the address bar, paste the “file path” via [CTRL] + [V], and press [ENTER].
Here’s the trick: the visible file path is only the last few dozen characters of a much longer command. Preceding the file path is a string of spaces, and before that is the actual malicious payload the attackers intend to execute. The spaces are crucial for ensuring the user doesn’t see anything suspicious after pasting the command. Because the full string is significantly longer than the address bar’s visible area, only the benign file path remains in view. The true contents are only revealed if the information is pasted into a text file instead of the File Explorer window. For instance, in a Bleeping Computer article based on research by Expel, the actual command was found to launch a PowerShell script via conhost.exe.
The user believes they’re pasting a file path, but the command actually contains a PowerShell script. Source
What happens after the malicious script is run
A PowerShell script executed by a legitimate user can cause trouble in a multitude of ways. Everything depends on corporate security policies, the specific user’s privileges, and the presence of security solutions on the victim’s computer. In the case mentioned previously, the attack utilized a technique named “cache smuggling”. The same fake website that implemented the FileFix trick saved a file in JPEG format into the browser’s cache, but the file actually contained an archive with malware. The malicious script then extracted this malware and executed it on the victim’s computer. This method allows the final malicious payload to be delivered to the computer without overt file downloads or suspicious network requests, making it particularly stealthy.
How to defend your company against ClickFix and FileFix attacks
In our post about the ClickFix attack technique, we suggested that the simplest defense was to block the [Win] + [R] key combination on work devices. It’s extremely rare for a typical office employee to genuinely need to open the Run dialog box. In the case of FileFix, the situation is a bit more complex: copying a command into the address bar is perfectly normal user behavior.
Blocking the [CTRL] + [L] shortcut is generally undesirable for two reasons. First, this combination is frequently used in various applications for diverse, legitimate purposes. Second, it wouldn’t fully help, as users can still access the File Explorer address bar by simply clicking it with the mouse. Attackers often provide detailed instructions for users if the keyboard shortcut fails.
Therefore, for a truly effective defense against ClickFix, FileFix, and similar schemes, we recommend first and foremost deploying a reliable security solution on all employee work devices that can detect and block the execution of dangerous code in time.
Second, we advise regularly raising employee awareness about modern cyberthreats — particularly the social engineering methods employed in ClickFix and FileFix scenarios. The Kaspersky Automated Security Awareness Platform can help automate employee training.
https://www.backbox.org/wp-content/uploads/2018/09/website_backbox_text_black.png00adminhttps://www.backbox.org/wp-content/uploads/2018/09/website_backbox_text_black.pngadmin2025-11-10 17:06:382025-11-10 17:06:38What is FileFix — a ClickFix variation? | Kaspersky official blog
